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A Blockchain Platform for the Enterprise¶

Enterprise grade permissioned distributed ledger platform that offers
modularity and versatility for a broad set of industry use cases.

Introduction¶
In general terms, a blockchain is an immutable transaction ledger, maintained
within a distributed network of peer nodes. These nodes each maintain a copy
of the ledger by applying transactions that have been validated by a consensus
protocol, grouped into blocks that include a hash that bind each block to the
preceding block.
The first and most widely recognized application of blockchain is the
Bitcoin cryptocurrency, though others
have followed in its footsteps. Ethereum, an alternative cryptocurrency, took a
different approach, integrating many of the same characteristics as Bitcoin but
adding smart contracts to create a platform for distributed applications.
Bitcoin and Ethereum fall into a class of blockchain that we would classify as
public permissionless blockchain technology. Basically, these are public
networks, open to anyone, where participants interact anonymously.
As the popularity of Bitcoin, Ethereum and a few other derivative technologies
grew, interest in applying the underlying technology of the blockchain,
distributed ledger and distributed application platform to more innovative
enterprise use cases also grew. However, many enterprise use cases require
performance characteristics that the permissionless blockchain technologies are
unable (presently) to deliver. In addition, in many use cases, the identity of
the participants is a hard requirement, such as in the case of financial
transactions where Know-Your-Customer (KYC) and Anti-Money Laundering (AML)
regulations must be followed.
For enterprise use, we need to consider the following requirements:

Participants must be identified/identifiable
Networks need to be permissioned
High transaction throughput performance
Low latency of transaction confirmation
Privacy and confidentiality of transactions and data pertaining to business
transactions

While many early blockchain platforms are currently being adapted for
enterprise use, Hyperledger Fabric has been designed for enterprise use from
the outset. The following sections describe how Hyperledger Fabric (Fabric)
differentiates itself from other blockchain platforms and describes some of the
motivation for its architectural decisions.

Hyperledger Fabric¶
Hyperledger Fabric is an open source enterprise-grade permissioned distributed
ledger technology (DLT) platform, designed for use in enterprise contexts,
that delivers some key differentiating capabilities over other popular
distributed ledger or blockchain platforms.
One key point of differentiation is that Hyperledger was established under the
Linux Foundation, which itself has a long and very successful history of
nurturing open source projects under open governance that grow strong
sustaining communities and thriving ecosystems. Hyperledger is governed by a
diverse technical steering committee, and the Hyperledger Fabric project by a
diverse set of maintainers from multiple organizations. It has a development
community that has grown to over 35 organizations and nearly 200 developers
since its earliest commits.
Fabric has a highly modular and configurable architecture, enabling
innovation, versatility and optimization for a broad range of industry use cases
including banking, finance, insurance, healthcare, human resources, supply
chain and even digital music delivery.
Fabric is the first distributed ledger platform to support smart contracts
authored in general-purpose programming languages such as Java, Go and
Node.js, rather than constrained domain-specific languages (DSL). This means
that most enterprises already have the skill set needed to develop smart
contracts, and no additional training to learn a new language or DSL is needed.
The Fabric platform is also permissioned, meaning that, unlike with a public
permissionless network, the participants are known to each other, rather than
anonymous and therefore fully untrusted. This means that while the participants
may not fully trust one another (they may, for example, be competitors in the
same industry), a network can be operated under a governance model that is built
off of what trust does exist between participants, such as a legal agreement
or framework for handling disputes.
One of the most important of the platform’s differentiators is its support for
pluggable consensus protocols that enable the platform to be more
effectively customized to fit particular use cases and trust models. For
instance, when deployed within a single enterprise, or operated by a trusted
authority, fully byzantine fault tolerant consensus might be considered
unnecessary and an excessive drag on performance and throughput. In situations
such as that, a
crash fault-tolerant (CFT)
consensus protocol might be more than adequate whereas, in a multi-party,
decentralized use case, a more traditional
byzantine fault tolerant
(BFT) consensus protocol might be required.
Fabric can leverage consensus protocols that do not require a native
cryptocurrency to incent costly mining or to fuel smart contract execution.
Avoidance of a cryptocurrency reduces some significant risk/attack vectors,
and absence of cryptographic mining operations means that the platform can be
deployed with roughly the same operational cost as any other distributed system.
The combination of these differentiating design features makes Fabric one of
the better performing platforms available today both in terms of transaction
processing and transaction confirmation latency, and it enables privacy and confidentiality of transactions and the smart contracts (what Fabric calls
“chaincode”) that implement them.
Let’s explore these differentiating features in more detail.

Modularity¶
Hyperledger Fabric has been specifically architected to have a modular
architecture. Whether it is pluggable consensus, pluggable identity management
protocols such as LDAP or OpenID Connect, key management protocols or
cryptographic libraries, the platform has been designed at its core to be
configured to meet the diversity of enterprise use case requirements.
At a high level, Fabric is comprised of the following modular components:

A pluggable ordering service establishes consensus on the order of
transactions and then broadcasts blocks to peers.
A pluggable membership service provider is responsible for associating
entities in the network with cryptographic identities.
An optional peer-to-peer gossip service disseminates the blocks output by
ordering service to other peers.
Smart contracts (“chaincode”) run within a container environment (e.g. Docker)
for isolation. They can be written in standard programming languages but do not
have direct access to the ledger state.
The ledger can be configured to support a variety of DBMSs.
A pluggable endorsement and validation policy enforcement that can be
independently configured per application.

There is fair agreement in the industry that there is no “one blockchain to
rule them all”. Hyperledger Fabric can be configured in multiple ways to
satisfy the diverse solution requirements for multiple industry use cases.

Permissioned vs Permissionless Blockchains¶
In a permissionless blockchain, virtually anyone can participate, and every
participant is anonymous. In such a context, there can be no trust other than
that the state of the blockchain, prior to a certain depth, is immutable. In
order to mitigate this absence of trust, permissionless blockchains typically
employ a “mined” native cryptocurrency or transaction fees to provide economic
incentive to offset the extraordinary costs of participating in a form of
byzantine fault tolerant consensus based on “proof of work” (PoW).
Permissioned blockchains, on the other hand, operate a blockchain amongst
a set of known, identified and often vetted participants operating under a
governance model that yields a certain degree of trust. A permissioned
blockchain provides a way to secure the interactions among a group of entities
that have a common goal but which may not fully trust each other. By relying on
the identities of the participants, a permissioned blockchain can use more
traditional crash fault tolerant (CFT) or byzantine fault tolerant (BFT)
consensus protocols that do not require costly mining.
Additionally, in such a permissioned context, the risk of a participant
intentionally introducing malicious code through a smart contract is diminished.
First, the participants are known to one another and all actions, whether
submitting application transactions, modifying the configuration of the network
or deploying a smart contract are recorded on the blockchain following an
endorsement policy that was established for the network and relevant transaction
type. Rather than being completely anonymous, the guilty party can be easily
identified and the incident handled in accordance with the terms of the
governance model.

Smart Contracts¶
A smart contract, or what Fabric calls “chaincode”, functions as a trusted
distributed application that gains its security/trust from the blockchain and
the underlying consensus among the peers. It is the business logic of a
blockchain application.
There are three key points that apply to smart contracts, especially when
applied to a platform:

many smart contracts run concurrently in the network,
they may be deployed dynamically (in many cases by anyone), and
application code should be treated as untrusted, potentially even
malicious.

Most existing smart-contract capable blockchain platforms follow an
order-execute architecture in which the consensus protocol:

validates and orders transactions then propagates them to all peer nodes,
each peer then executes the transactions sequentially.

The order-execute architecture can be found in virtually all existing blockchain
systems, ranging from public/permissionless platforms such as
Ethereum (with PoW-based consensus) to permissioned
platforms such as Tendermint,
Chain, and Quorum.
Smart contracts executing in a blockchain that operates with the order-execute
architecture must be deterministic; otherwise, consensus might never be reached.
To address the non-determinism issue, many platforms require that the smart
contracts be written in a non-standard, or domain-specific language
(such as Solidity) so that
non-deterministic operations can be eliminated. This hinders wide-spread
adoption because it requires developers writing smart contracts to learn a new
language and may lead to programming errors.
Further, since all transactions are executed sequentially by all nodes,
performance and scale is limited. The fact that the smart contract code executes
on every node in the system demands that complex measures be taken to protect
the overall system from potentially malicious contracts in order to ensure
resiliency of the overall system.

A New Approach¶
Fabric introduces a new architecture for transactions that we call
execute-order-validate. It addresses the resiliency, flexibility,
scalability, performance and confidentiality challenges faced by the
order-execute model by separating the transaction flow into three steps:

execute a transaction and check its correctness, thereby endorsing it,
order transactions via a (pluggable) consensus protocol, and
validate transactions against an application-specific endorsement policy
before committing them to the ledger

This design departs radically from the order-execute paradigm in that Fabric
executes transactions before reaching final agreement on their order.
In Fabric, an application-specific endorsement policy specifies which peer
nodes, or how many of them, need to vouch for the correct execution of a given
smart contract. Thus, each transaction need only be executed (endorsed) by the
subset of the peer nodes necessary to satisfy the transaction’s endorsement
policy. This allows for parallel execution increasing overall performance and
scale of the system. This first phase also eliminates any non-determinism,
as inconsistent results can be filtered out before ordering.
Because we have eliminated non-determinism, Fabric is the first blockchain
technology that enables use of standard programming languages.

Privacy and Confidentiality¶
As we have discussed, in a public, permissionless blockchain network that
leverages PoW for its consensus model, transactions are executed on every node.
This means that neither can there be confidentiality of the contracts
themselves, nor of the transaction data that they process. Every transaction,
and the code that implements it, is visible to every node in the network. In
this case, we have traded confidentiality of contract and data for byzantine
fault tolerant consensus delivered by PoW.
This lack of confidentiality can be problematic for many business/enterprise use
cases. For example, in a network of supply-chain partners, some consumers might
be given preferred rates as a means of either solidifying a relationship, or
promoting additional sales. If every participant can see every contract and
transaction, it becomes impossible to maintain such business relationships in a
completely transparent network — everyone will want the preferred rates!
As a second example, consider the securities industry, where a trader building
a position (or disposing of one) would not want her competitors to know of this,
or else they will seek to get in on the game, weakening the trader’s gambit.
In order to address the lack of privacy and confidentiality for purposes of
delivering on enterprise use case requirements, blockchain platforms have
adopted a variety of approaches. All have their trade-offs.
Encrypting data is one approach to providing confidentiality; however, in a
permissionless network leveraging PoW for its consensus, the encrypted data is
sitting on every node. Given enough time and computational resource, the
encryption could be broken. For many enterprise use cases, the risk that their
information could become compromised is unacceptable.
Zero knowledge proofs (ZKP) are another area of research being explored to
address this problem, the trade-off here being that, presently, computing a ZKP
requires considerable time and computational resources. Hence, the trade-off in
this case is performance for confidentiality.
In a permissioned context that can leverage alternate forms of consensus, one
might explore approaches that restrict the distribution of confidential
information exclusively to authorized nodes.
Hyperledger Fabric, being a permissioned platform, enables confidentiality
through its channel architecture and private data
feature. In channels, participants on a Fabric network establish a sub-network
where every member has visibility to a particular set of transactions. Thus, only
those nodes that participate in a channel have access to the smart contract
(chaincode) and data transacted, preserving the privacy and confidentiality of
both. Private data allows collections between members on a channel, allowing
much of the same protection as channels without the maintenance overhead of
creating and maintaining a separate channel.

Pluggable Consensus¶
The ordering of transactions is delegated to a modular component for consensus
that is logically decoupled from the peers that execute transactions and
maintain the ledger. Specifically, the ordering service. Since consensus is
modular, its implementation can be tailored to the trust assumption of a
particular deployment or solution. This modular architecture allows the platform
to rely on well-established toolkits for CFT (crash fault-tolerant) or BFT
(byzantine fault-tolerant) ordering.
Fabric currently offers a CFT ordering service implementation
based on the etcd library of the Raft protocol.
For information about currently available ordering services, check
out our conceptual documentation about ordering.
Note also that these are not mutually exclusive. A Fabric network can have
multiple ordering services supporting different applications or application
requirements.

Performance and Scalability¶
Performance of a blockchain platform can be affected by many variables such as
transaction size, block size, network size, as well as limits of the hardware,
etc. The Hyperledger Fabric Performance and Scale working group
currently works on a benchmarking framework called Hyperledger Caliper.
Several research papers have been published studying and testing the performance
capabilities of Hyperledger Fabric. The latest scaled Fabric to 20,000 transactions per second.

Conclusion¶
Any serious evaluation of blockchain platforms should include Hyperledger Fabric
in its short list.
Combined, the differentiating capabilities of Fabric make it a highly scalable
system for permissioned blockchains supporting flexible trust assumptions that
enable the platform to support a wide range of industry use cases ranging from
government, to finance, to supply-chain logistics, to healthcare and so much
more.
Hyperledger Fabric is the most active of the Hyperledger projects. The community
building around the platform is growing steadily, and the innovation delivered
with each successive release far out-paces any of the other enterprise blockchain
platforms.

Acknowledgement¶
The preceding is derived from the peer reviewed
“Hyperledger Fabric: A Distributed Operating System for Permissioned Blockchains” - Elli Androulaki, Artem
Barger, Vita Bortnikov, Christian Cachin, Konstantinos Christidis, Angelo De
Caro, David Enyeart, Christopher Ferris, Gennady Laventman, Yacov Manevich,
Srinivasan Muralidharan, Chet Murthy, Binh Nguyen, Manish Sethi, Gari Singh,
Keith Smith, Alessandro Sorniotti, Chrysoula Stathakopoulou, Marko Vukolic,
Sharon Weed Cocco, Jason Yellick

What’s new in Hyperledger Fabric v2.x¶
The first Hyperledger Fabric major release since v1.0, Fabric v2.0
delivers important new features and changes for users and operators alike,
including support for new application and privacy patterns, enhanced
governance around smart contracts, and new options for operating nodes.
Each v2.x minor release builds on the v2.0 release with minor features,
improvements, and bug fixes.
Let’s take a look at some of the highlights of the Fabric v2.0 release…

Decentralized governance for smart contracts¶
Fabric v2.0 introduces decentralized governance for smart contracts, with a new
process for installing a chaincode on your peers and starting it on a channel.
The new Fabric chaincode lifecycle allows multiple organizations to come to
agreement on the parameters of a chaincode, such as the chaincode endorsement
policy, before it can be used to interact with the ledger. The new model
offers several improvements over the previous lifecycle:

Multiple organizations must agree to the parameters of a chaincode
In the release 1.x versions of Fabric, one organization had the ability to
set parameters of a chaincode (for instance the endorsement policy) for all
other channel members, who only had the power to refuse to install the chaincode
and therefore not take part in transactions invoking it. The new Fabric
chaincode lifecycle is more flexible since it supports both centralized
trust models (such as that of the previous lifecycle model) as well as
decentralized models requiring a sufficient number of organizations to
agree on an endorsement policy and other details before the chaincode
becomes active on a channel.
More deliberate chaincode upgrade process In the previous chaincode
lifecycle, the upgrade transaction could be issued by a single organization,
creating a risk for a channel member that had not yet installed the new
chaincode. The new model allows for a chaincode to be upgraded only after
a sufficient number of organizations have approved the upgrade.
Simpler endorsement policy and private data collection updates
Fabric lifecycle allows you to change an endorsement policy or private
data collection configuration without having to repackage or reinstall
the chaincode. Users can also take advantage of a new default endorsement
policy that requires endorsement from a majority of organizations on the
channel. This policy is updated automatically when organizations are
added or removed from the channel.
Inspectable chaincode packages The Fabric lifecycle packages chaincode
in easily readable tar files. This makes it easier to inspect the chaincode
package and coordinate installation across multiple organizations.
Start multiple chaincodes on a channel using one package The previous
lifecycle defined each chaincode on the channel using a name and version
that was specified when the chaincode package was installed. You can now
use a single chaincode package and deploy it multiple times with different
names on the same channel or on different channels. For example, if you’d
like to track different types of assets in their own ‘copy’ of the chaincode.
Chaincode packages do not need to be identical across channel members
Organizations can extend a chaincode for their own use case, for example
to perform different validations in the interest of their organization.
As long as the required number of organizations endorse chaincode transactions
with matching results, the transaction will be validated and committed to the
ledger.  This also allows organizations to individually roll out minor fixes
on their own schedules without requiring the entire network to proceed in lock-step.

Using the new chaincode lifecycle¶
For existing Fabric deployments, you can continue to use the prior chaincode
lifecycle with Fabric v2.0. The new chaincode lifecycle will become effective
only when the channel application capability is updated to v2.0.
See the Fabric chaincode lifecycle concept topic for an overview of the new
chaincode lifecycle.

New chaincode application patterns for collaboration and consensus¶
The same decentralized methods of coming to agreement that underpin the
new chaincode lifecycle management can also be used in your own chaincode
applications to ensure organizations consent to data transactions before
they are committed to the ledger.

Automated checks As mentioned above, organizations can add automated
checks to chaincode functions to validate additional information before
endorsing a transaction proposal.
Decentralized agreement Human decisions can be modeled into a chaincode process
that spans multiple transactions. The chaincode may require actors from
various organizations to indicate their terms and conditions of agreement
in a ledger transaction. Then, a final chaincode proposal can
verify that the conditions from all the individual transactors are met,
and “settle” the business transaction with finality across all channel
members. For a concrete example of indicating terms and conditions in private,
see the asset transfer scenario in the Private data documentation.

Private data enhancements¶
Fabric v2.0 also enables new patterns for working with and sharing private data,
without the requirement of creating private data collections for all
combinations of channel members that may want to transact. Specifically,
instead of sharing private data within a collection of multiple members,
you may want to share private data across collections, where each collection
may include a single organization, or perhaps a single organization along
with a regulator or auditor.
Several enhancements in Fabric v2.0 make these new private data patterns possible:

Sharing and verifying private data When private data is shared with a
channel member who is not a member of a collection, or shared with another
private data collection that contains one or more channel members (by writing
a key to that collection), the receiving parties can utilize the
GetPrivateDataHash() chaincode API to verify that the private data matches the
on-chain hashes that were created from private data in previous transactions.
Collection-level endorsement policies Private data collections can now
optionally be defined with an endorsement policy that overrides the
chaincode-level endorsement policy for keys within the collection. This
feature can be used to restrict which organizations can write data to a
collection, and is what enables the new chaincode lifecycle and chaincode
application patterns mentioned earlier. For example, you may have a chaincode
endorsement policy that requires a majority of organizations to endorse,
but for any given transaction, you may need two transacting organizations
to individually endorse their agreement in their own private data collections.
Implicit per-organization collections If you’d like to utilize
per-organization private data patterns, you don’t even need to define the
collections when deploying chaincode in Fabric v2.0.  Implicit
organization-specific collections can be used without any upfront definition.

To learn more about the new private data patterns, see the Private data (conceptual
documentation). For details about private data collection configuration and
implicit collections, see the Private Data (reference documentation).

External chaincode launcher¶
The external chaincode launcher feature empowers operators to build and launch
chaincode with the technology of their choice. Use of external builders and launchers
is not required as the default behavior builds and runs chaincode in the same manner
as prior releases using the Docker API.

Eliminate Docker daemon dependency Prior releases of Fabric required
peers to have access to a Docker daemon in order to build and launch
chaincode - something that may not be desirable in production environments
due to the privileges required by the peer process.
Alternatives to containers Chaincode is no longer required to be run
in Docker containers, and may be executed in the operator’s choice of
environment (including containers).
External builder executables An operator can provide a set of external
builder executables to override how the peer builds and launches chaincode.
Chaincode as an external service Traditionally, chaincodes are launched
by the peer, and then connect back to the peer. It is now possible to run chaincode as
an external service, for example in a Kubernetes pod, which a peer can
connect to and utilize for chaincode execution. See Chaincode as an external service for more
information.

See External Builders and Launchers to learn more about the external chaincode launcher feature.

State database cache for improved performance on CouchDB¶

When using external CouchDB state database, read delays during endorsement
and validation phases have historically been a performance bottleneck.
With Fabric v2.0, a new peer cache replaces many of these expensive lookups
with fast local cache reads. The cache size can be configured by using the
core.yaml property cacheSize.

Alpine-based docker images¶
Starting with v2.0, Hyperledger Fabric Docker images will use Alpine Linux,
a security-oriented, lightweight Linux distribution. This means that Docker
images are now much smaller, providing faster download and startup times,
as well as taking up less disk space on host systems. Alpine Linux is designed
from the ground up with security in mind, and the minimalist nature of the Alpine
distribution greatly reduces the risk of security vulnerabilities.

Sample test network¶
The fabric-samples repository now includes a new Fabric test network. The test
network is built to be a modular and user friendly sample Fabric network that
makes it easy to test your applications and smart contracts. The network also
supports the ability to deploy your network using Certificate Authorities,
in addition to cryptogen.
For more information about this network, check out Using the Fabric test network.

Upgrading to Fabric v2.x¶
A major new release brings some additional upgrade considerations. Rest assured
though, that rolling upgrades from v1.4.x to v2.x are supported, so that network
components can be upgraded one at a time with no downtime.
The upgrade docs have been significantly expanded and reworked, and now have a
standalone home in the documentation: Upgrading to the latest release. Here you’ll find documentation on
Upgrading your components and Updating the capability level of a channel, as well as a
specific look  at the considerations for upgrading to v2.0, Considerations for getting to v2.x.

Release notes¶
The release notes provide more details for users moving to the new release.
Specifically, take a look at the changes and deprecations that are being
announced with the new Fabric v2.0 release, and the changes introduced in v2.1.

Fabric v2.0.0 release notes.
Fabric v2.0.1 release notes.
Fabric v2.1.0 release notes.
Fabric v2.1.1 release notes.

Key Concepts¶

Introduction¶
Hyperledger Fabric is a platform for distributed ledger solutions underpinned
by a modular architecture delivering high degrees of confidentiality,
resiliency, flexibility, and scalability. It is designed to support pluggable
implementations of different components and accommodate the complexity and
intricacies that exist across the economic ecosystem.
We recommend first-time users begin by going through the rest of the
introduction below in order to gain familiarity with how blockchains work
and with the specific features and components of Hyperledger Fabric.
Once comfortable — or if you’re already familiar with blockchain and
Hyperledger Fabric — go to Getting Started and from there explore the
demos, technical specifications, APIs, etc.

What is a Blockchain?¶
A Distributed Ledger
At the heart of a blockchain network is a distributed ledger that records all
the transactions that take place on the network.
A blockchain ledger is often described as decentralized because it is replicated
across many network participants, each of whom collaborate in its maintenance.
We’ll see that decentralization and collaboration are powerful attributes that
mirror the way businesses exchange goods and services in the real world.

In addition to being decentralized and collaborative, the information recorded
to a blockchain is append-only, using cryptographic techniques that guarantee
that once a transaction has been added to the ledger it cannot be modified.
This property of “immutability” makes it simple to determine the provenance of
information because participants can be sure information has not been changed
after the fact. It’s why blockchains are sometimes described as systems of proof.
Smart Contracts
To support the consistent update of information — and to enable a whole host of
ledger functions (transacting, querying, etc) — a blockchain network uses smart
contracts to provide controlled access to the ledger.

Smart contracts are not only a key mechanism for encapsulating information
and keeping it simple across the network, they can also be written to allow
participants to execute certain aspects of transactions automatically.
A smart contract can, for example, be written to stipulate the cost of shipping
an item where the shipping charge changes depending on how quickly the item arrives.
With the terms agreed to by both parties and written to the ledger,
the appropriate funds change hands automatically when the item is received.
Consensus
The process of keeping the ledger transactions synchronized across the network —
to ensure that ledgers update only when transactions are approved by the appropriate
participants, and that when ledgers do update, they update with the
same transactions in the same order — is called consensus.

You’ll learn a lot more about ledgers, smart contracts and consensus later. For
now, it’s enough to think of a blockchain as a shared, replicated transaction
system which is updated via smart contracts and kept consistently
synchronized through a collaborative process called consensus.

Why is a Blockchain useful?¶
Today’s Systems of Record
The transactional networks of today are little more than slightly updated
versions of networks that have existed since business records have been kept.
The members of a business network transact with each other, but they maintain
separate records of their transactions. And the things they’re transacting —
whether it’s Flemish tapestries in the 16th century or the securities of today
— must have their provenance established each time they’re sold to ensure that
the business selling an item possesses a chain of title verifying their
ownership of it.
What you’re left with is a business network that looks like this:

Modern technology has taken this process from stone tablets and paper folders
to hard drives and cloud platforms, but the underlying structure is the same.
Unified systems for managing the identity of network participants do not exist,
establishing provenance is so laborious it takes days to clear securities
transactions (the world volume of which is numbered in the many trillions of
dollars), contracts must be signed and executed manually, and every database in
the system contains unique information and therefore represents a single point
of failure.
It’s impossible with today’s fractured approach to information and
process sharing to build a system of record that spans a business network, even
though the needs of visibility and trust are clear.
The Blockchain Difference
What if, instead of the rat’s nest of inefficiencies represented by the “modern”
system of transactions, business networks had standard methods for establishing
identity on the network, executing transactions, and storing data? What
if establishing the provenance of an asset could be determined by looking
through a list of transactions that, once written, cannot be changed, and can
therefore be trusted?
That business network would look more like this:

This is a blockchain network, wherein every participant has their own replicated
copy of the ledger. In addition to ledger information being shared, the processes
which update the ledger are also shared. Unlike today’s systems, where a
participant’s private programs are used to update their private ledgers,
a blockchain system has shared programs to update shared ledgers.
With the ability to coordinate their business network through a shared ledger,
blockchain networks can reduce the time, cost, and risk associated with private
information and processing while improving trust and visibility.
You now know what blockchain is and why it’s useful. There are a lot of other
details that are important, but they all relate to these fundamental ideas of
the sharing of information and processes.

What is Hyperledger Fabric?¶
The Linux Foundation founded the Hyperledger project in 2015 to advance
cross-industry blockchain technologies. Rather than declaring a single
blockchain standard, it encourages a collaborative approach to developing
blockchain technologies via a community process, with intellectual property
rights that encourage open development and the adoption of key standards over
time.
Hyperledger Fabric is one of the blockchain projects within Hyperledger.
Like other blockchain technologies, it has a ledger, uses smart contracts,
and is a system by which participants manage their transactions.
Where Hyperledger Fabric breaks from some other blockchain systems is that
it is private and permissioned. Rather than an open permissionless system
that allows unknown identities to participate in the network (requiring protocols
like “proof of work” to validate transactions and secure the network), the members
of a Hyperledger Fabric network enroll through a trusted Membership Service Provider (MSP).
Hyperledger Fabric also offers several pluggable options. Ledger data can be
stored in multiple formats, consensus mechanisms can be swapped in and out,
and different MSPs are supported.
Hyperledger Fabric also offers the ability to create channels, allowing a group of
participants to create a separate ledger of transactions. This is an especially
important option for networks where some participants might be competitors and not
want every transaction they make — a special price they’re offering to some participants
and not others, for example — known to every participant. If two participants
form a channel, then those participants — and no others — have copies of the ledger
for that channel.
Shared Ledger
Hyperledger Fabric has a ledger subsystem comprising two components: the world
state and the transaction log. Each participant has a copy of the ledger to
every Hyperledger Fabric network they belong to.
The world state component describes the state of the ledger at a given point
in time. It’s the database of the ledger. The transaction log component records
all transactions which have resulted in the current value of the world state;
it’s the update history for the world state. The ledger, then, is a combination
of the world state database and the transaction log history.
The ledger has a replaceable data store for the world state. By default, this
is a LevelDB key-value store database. The transaction log does not need to be
pluggable. It simply records the before and after values of the ledger database
being used by the blockchain network.
Smart Contracts
Hyperledger Fabric smart contracts are written in chaincode and are invoked
by an application external to the blockchain when that application needs to
interact with the ledger. In most cases, chaincode interacts only with the
database component of the ledger, the world state (querying it, for example), and
not the transaction log.
Chaincode can be implemented in several programming languages. Currently, Go and
Node are supported.
Privacy
Depending on the needs of a network, participants in a Business-to-Business
(B2B) network might be extremely sensitive about how much information they share.
For other networks, privacy will not be a top concern.
Hyperledger Fabric supports networks where privacy (using channels) is a key
operational requirement as well as networks that are comparatively open.
Consensus
Transactions must be written to the ledger in the order in which they occur,
even though they might be between different sets of participants within the
network. For this to happen, the order of transactions must be established
and a method for rejecting bad transactions that have been inserted into the
ledger in error (or maliciously) must be put into place.
This is a thoroughly researched area of computer science, and there are many
ways to achieve it, each with different trade-offs. For example, PBFT (Practical
Byzantine Fault Tolerance) can provide a mechanism for file replicas to
communicate with each other to keep each copy consistent, even in the event
of corruption. Alternatively, in Bitcoin, ordering happens through a process
called mining where competing computers race to solve a cryptographic puzzle
which defines the order that all processes subsequently build upon.
Hyperledger Fabric has been designed to allow network starters to choose a
consensus mechanism that best represents the relationships that exist between
participants. As with privacy, there is a spectrum of needs; from networks
that are highly structured in their relationships to those that are more
peer-to-peer.

Hyperledger Fabric Model¶
This section outlines the key design features woven into Hyperledger Fabric that
fulfill its promise of a comprehensive, yet customizable, enterprise blockchain solution:

Assets — Asset definitions enable the exchange of almost anything with
monetary value over the network, from whole foods to antique cars to currency
futures.
Chaincode — Chaincode execution is partitioned from transaction ordering,
limiting the required levels of trust and verification across node types, and
optimizing network scalability and performance.
Ledger Features — The immutable, shared ledger encodes the entire
transaction history for each channel, and includes SQL-like query capability
for efficient auditing and dispute resolution.
Privacy — Channels and private data collections enable private and
confidential multi-lateral transactions that are usually required by
competing businesses and regulated industries that exchange assets on a common
network.
Security & Membership Services — Permissioned membership provides a
trusted blockchain network, where participants know that all transactions can
be detected and traced by authorized regulators and auditors.
Consensus — A unique approach to consensus enables the
flexibility and scalability needed for the enterprise.

Assets¶
Assets can range from the tangible (real estate and hardware) to the intangible
(contracts and intellectual property).  Hyperledger Fabric provides the
ability to modify assets using chaincode transactions.
Assets are represented in Hyperledger Fabric as a collection of
key-value pairs, with state changes recorded as transactions on a Channel
ledger.  Assets can be represented in binary and/or JSON form.

Chaincode¶
Chaincode is software defining an asset or assets, and the transaction instructions for
modifying the asset(s); in other words, it’s the business logic.  Chaincode enforces the rules for reading
or altering key-value pairs or other state database information. Chaincode functions execute against
the ledger’s current state database and are initiated through a transaction proposal. Chaincode execution
results in a set of key-value writes (write set) that can be submitted to the network and applied to
the ledger on all peers.

Ledger Features¶
The ledger is the sequenced, tamper-resistant record of all state transitions in the fabric.  State
transitions are a result of chaincode invocations (‘transactions’) submitted by participating
parties.  Each transaction results in a set of asset key-value pairs that are committed to the
ledger as creates, updates, or deletes.
The ledger is comprised of a blockchain (‘chain’) to store the immutable, sequenced record in
blocks, as well as a state database to maintain current fabric state.  There is one ledger per
channel. Each peer maintains a copy of the ledger for each channel of which they are a member.
Some features of a Fabric ledger:

Query and update ledger using key-based lookups, range queries, and composite key queries
Read-only queries using a rich query language (if using CouchDB as state database)
Read-only history queries — Query ledger history for a key, enabling data provenance scenarios
Transactions consist of the versions of keys/values that were read in chaincode (read set) and keys/values that were written in chaincode (write set)
Transactions contain signatures of every endorsing peer and are submitted to ordering service
Transactions are ordered into blocks and are “delivered” from an ordering service to peers on a channel
Peers validate transactions against endorsement policies and enforce the policies
Prior to appending a block, a versioning check is performed to ensure that states for assets that were read have not changed since chaincode execution time
There is immutability once a transaction is validated and committed
A channel’s ledger contains a configuration block defining policies, access control lists, and other pertinent information
Channels contain Membership Service Provider instances allowing for crypto materials to be derived from different certificate authorities

See the Ledger topic for a deeper dive on the databases, storage structure, and “query-ability.”

Privacy¶
Hyperledger Fabric employs an immutable ledger on a per-channel basis, as well as
chaincode that can manipulate and modify the current state of assets (i.e. update
key-value pairs).  A ledger exists in the scope of a channel — it can be shared
across the entire network (assuming every participant is operating on one common
channel) — or it can be privatized to include only a specific set of participants.
In the latter scenario, these participants would create a separate channel and
thereby isolate/segregate their transactions and ledger.  In order to solve
scenarios that want to bridge the gap between total transparency and privacy,
chaincode can be installed only on peers that need to access the asset states
to perform reads and writes (in other words, if a chaincode is not installed on
a peer, it will not be able to properly interface with the ledger).
When a subset of organizations on that channel need to keep their transaction
data confidential, a private data collection (collection) is used to segregate
this data in a private database, logically separate from the channel ledger,
accessible only to the authorized subset of organizations.
Thus, channels keep transactions private from the broader network whereas
collections keep data private between subsets of organizations on the channel.
To further obfuscate the data, values within chaincode can be encrypted
(in part or in total) using common cryptographic algorithms such as AES before
sending transactions to the ordering service and appending blocks to the ledger.
Once encrypted data has been written to the ledger, it can be decrypted only by
a user in possession of the corresponding key that was used to generate the cipher
text.
See the Private Data topic for more details on how to achieve
privacy on your blockchain network.

Security & Membership Services¶
Hyperledger Fabric underpins a transactional network where all participants have
known identities.  Public Key Infrastructure is used to generate cryptographic
certificates which are tied to organizations, network components, and end users
or client applications.  As a result, data access control can be manipulated and
governed on the broader network and on channel levels.  This “permissioned” notion
of Hyperledger Fabric, coupled with the existence and capabilities of channels,
helps address scenarios where privacy and confidentiality are paramount concerns.
See the Membership Service Providers (MSP) topic to better understand cryptographic
implementations, and the sign, verify, authenticate approach used in
Hyperledger Fabric.

Consensus¶
In distributed ledger technology, consensus has recently become synonymous with
a specific algorithm, within a single function. However, consensus encompasses more
than simply agreeing upon the order of transactions, and this differentiation is
highlighted in Hyperledger Fabric through its fundamental role in the entire
transaction flow, from proposal and endorsement, to ordering, validation and commitment.
In a nutshell, consensus is defined as the full-circle verification of the correctness of
a set of transactions comprising a block.
Consensus is achieved ultimately when the order and results of a block’s
transactions have met the explicit policy criteria checks. These checks and balances
take place during the lifecycle of a transaction, and include the usage of
endorsement policies to dictate which specific members must endorse a certain
transaction class, as well as system chaincodes to ensure that these policies
are enforced and upheld.  Prior to commitment, the peers will employ these
system chaincodes to make sure that enough endorsements are present, and that
they were derived from the appropriate entities.  Moreover, a versioning check
will take place during which the current state of the ledger is agreed or
consented upon, before any blocks containing transactions are appended to the ledger.
This final check provides protection against double spend operations and other
threats that might compromise data integrity, and allows for functions to be
executed against non-static variables.
In addition to the multitude of endorsement, validity and versioning checks that
take place, there are also ongoing identity verifications happening in all
directions of the transaction flow.  Access control lists are implemented on
hierarchical layers of the network (ordering service down to channels), and
payloads are repeatedly signed, verified and authenticated as a transaction proposal passes
through the different architectural components.  To conclude, consensus is not
merely limited to the agreed upon order of a batch of transactions; rather,
it is an overarching characterization that is achieved as a byproduct of the ongoing
verifications that take place during a transaction’s journey from proposal to
commitment.
Check out the Transaction Flow diagram for a visual representation
of consensus.

Blockchain network¶
This topic will describe, at a conceptual level, how Hyperledger Fabric
allows organizations to collaborate in the formation of blockchain networks.  If
you’re an architect, administrator or developer, you can use this topic to get a
solid understanding of the major structure and process components in a
Hyperledger Fabric blockchain network. This topic will use a manageable worked
example that introduces all of the major components in a blockchain network.
After reading this topic and understanding the concept of policies, you will
have a solid understanding of the decisions that organizations need to make to
establish the policies that control a deployed Hyperledger Fabric network.
You’ll also understand how organizations manage network evolution using
declarative policies – a key feature of Hyperledger Fabric. In a nutshell,
you’ll understand the major technical components of Hyperledger Fabric and the
decisions organizations need to make about them.

What is a blockchain network?¶
A blockchain network is a technical infrastructure that provides ledger and
smart contract (chaincode) services to applications. Primarily, smart contracts
are used to generate transactions which are subsequently distributed to every
peer node in the network where they are immutably recorded on their copy of the
ledger. The users of applications might be end users using client applications
or blockchain network administrators.
In most cases, multiple organizations come
together as a consortium to form the network and
their permissions are determined by a set of policies
that are agreed by the consortium when the network is originally configured.
Moreover, network policies can change over time subject to the agreement of the
organizations in the consortium, as we’ll discover when we discuss the concept
of modification policy.

The sample network¶
Before we start, let’s show you what we’re aiming at! Here’s a diagram
representing the final state of our sample network.
Don’t worry that this might look complicated! As we go through this topic, we
will build up the network piece by piece, so that you see how the organizations
R1, R2, R3 and R4 contribute infrastructure to the network to help form it. This
infrastructure implements the blockchain network, and it is governed by policies
agreed by the organizations who form the network – for example, who can add new
organizations. You’ll discover how applications consume the ledger and smart
contract services provided by the blockchain network.

Four organizations, R1, R2, R3 and R4 have jointly decided, and written into an
agreement, that they will set up and exploit a Hyperledger Fabric
network. R4 has been assigned to be the network initiator  – it has been given
the power to set up the initial version of the network. R4 has no intention to
perform business transactions on the network. R1 and R2 have a need for a
private communications within the overall network, as do R2 and R3.
Organization R1 has a client application that can perform business transactions
within channel C1. Organization R2 has a client application that can do similar
work both in channel C1 and C2. Organization R3 has a client application that
can do this on channel C2. Peer node P1 maintains a copy of the ledger L1
associated with C1. Peer node P2 maintains a copy of the ledger L1 associated
with C1 and a copy of ledger L2 associated with C2. Peer node P3 maintains a
copy of the ledger L2 associated with C2. The network is governed according to
policy rules specified in network configuration NC4, the network is under the
control of organizations R1 and R4. Channel C1 is governed according to the
policy rules specified in channel configuration CC1; the channel is under the
control of organizations R1 and R2.  Channel C2 is governed according to the
policy rules specified in channel configuration CC2; the channel is under the
control of organizations R2 and R3. There is an ordering service O4 that
services as a network administration point for N, and uses the system channel.
The ordering service also supports application channels C1 and C2, for the
purposes of transaction ordering into blocks for distribution. Each of the four
organizations has a preferred Certificate Authority.

Creating the Network¶
Let’s start at the beginning by creating the basis for the network:

The network is formed when an orderer is started. In our example network, N,
the ordering service comprising a single node, O4, is configured according to a
network configuration NC4, which gives administrative rights to organization
R4. At the network level, Certificate Authority CA4 is used to dispense
identities to the administrators and network nodes of the R4 organization.
We can see that the first thing that defines a network, N, is an ordering
service, O4. It’s helpful to think of the ordering service as the initial
administration point for the network. As agreed beforehand, O4 is initially
configured and started by an administrator in organization R4, and hosted in R4.
The configuration NC4 contains the policies that describe the starting set of
administrative capabilities for the network. Initially this is set to only give
R4 rights over the network. This will change, as we’ll see later, but for now R4
is the only member of the network.

Certificate Authorities¶
You can also see a Certificate Authority, CA4, which is used to issue
certificates to administrators and network nodes. CA4 plays a key role in our
network because it dispenses X.509 certificates that can be used to identify
components as belonging to organization R4. Certificates issued by CAs
can also be used to sign transactions to indicate that an organization endorses
the transaction result – a precondition of it being accepted onto the
ledger. Let’s examine these two aspects of a CA in a little more detail.
Firstly, different components of the blockchain network use certificates to
identify themselves to each other as being from a particular organization.
That’s why there is usually more than one CA supporting a blockchain network –
different organizations often use different CAs. We’re going to use four CAs in
our network; one for each organization. Indeed, CAs are so important that
Hyperledger Fabric provides you with a built-in one (called Fabric-CA) to help
you get going, though in practice, organizations will choose to use their own
CA.
The mapping of certificates to member organizations is achieved by via
a structure called a
Membership Services Provider (MSP).
Network configuration NC4 uses a named
MSP to identify the properties of certificates dispensed by CA4 which associate
certificate holders with organization R4. NC4 can then use this MSP name in
policies to grant actors from R4 particular
rights over network resources. An example of such a policy is to identify the
administrators in R4 who can add new member organizations to the network. We
don’t show MSPs on these diagrams, as they would just clutter them up, but they
are very important.
Secondly, we’ll see later how certificates issued by CAs are at the heart of the
transaction generation and validation process.
Specifically, X.509 certificates are used in client application
transaction proposals and smart contract
transaction responses to digitally sign
transactions.  Subsequently the network nodes
who host copies of the ledger verify that transaction signatures are valid
before accepting transactions onto the ledger.
Let’s recap the basic structure of our example blockchain network. There’s a
resource, the network N, accessed by a set of users defined by a Certificate
Authority CA4, who have a set of rights over the resources in the network N as
described by policies contained inside a network configuration NC4.  All of this
is made real when we configure and start the ordering service node O4.

Adding Network Administrators¶
NC4 was initially configured to only allow R4 users administrative rights over
the network. In this next phase, we are going to allow organization R1 users to
administer the network. Let’s see how the network evolves:

Organization R4 updates the network configuration to make organization R1 an
administrator too.  After this point R1 and R4 have equal rights over the
network configuration.
We see the addition of a new organization R1 as an administrator – R1 and R4
now have equal rights over the network. We can also see that certificate
authority CA1 has been added – it can be used to identify users from the R1
organization. After this point, users from both R1 and R4 can administer the
network.
Although the orderer node, O4, is running on R4’s infrastructure, R1 has shared
administrative rights over it, as long as it can gain network access. It means
that R1 or R4 could update the network configuration NC4 to allow the R2
organization a subset of network operations.  In this way, even though R4 is
running the ordering service, and R1 has full administrative rights over it, R2
has limited rights to create new consortia.
In its simplest form, the ordering service is a single node in the network, and
that’s what you can see in the example. Ordering services are usually
multi-node, and can be configured to have different nodes in different
organizations. For example, we might run O4 in R4 and connect it to O2, a
separate orderer node in organization R1.  In this way, we would have a
multi-site, multi-organization administration structure.
We’ll discuss the ordering service a little later in this topic,
but for now just think of the ordering service as an administration point which
provides different organizations controlled access to the network.

Defining a Consortium¶
Although the network can now be administered by R1 and R4, there is very little
that can be done. The first thing we need to do is define a consortium. This
word literally means “a group with a shared destiny”, so it’s an appropriate
choice for a set of organizations in a blockchain network.
Let’s see how a consortium is defined:

A network administrator defines a consortium X1 that contains two members,
the organizations R1 and R2. This consortium definition is stored in the
network configuration NC4, and will be used at the next stage of network
development. CA1 and CA2 are the respective Certificate Authorities for these
organizations.
Because of the way NC4 is configured, only R1 or R4 can create new consortia.
This diagram shows the addition of a new consortium, X1, which defines R1 and R2
as its constituting organizations.  We can also see that CA2 has been added to
identify users from R2. Note that a consortium can have any number of
organizational members – we have just shown two as it is the simplest
configuration.
Why are consortia important? We can see that a consortium defines the set of
organizations in the network who share a need to transact with one another –
in this case R1 and R2. It really makes sense to group organizations together if
they have a common goal, and that’s exactly what’s happening.
The network, although started by a single organization, is now controlled by a
larger set of organizations.  We could have started it this way, with R1, R2 and
R4 having shared control, but this build up makes it easier to understand.
We’re now going to use consortium X1 to create a really important part of a
Hyperledger Fabric blockchain – a channel.

Creating a channel for a consortium¶
So let’s create this key part of the Fabric blockchain network – a channel.
A channel is a primary communications mechanism by which the members of a
consortium can communicate with each other. There can be multiple channels in a
network, but for now, we’ll start with one.
Let’s see how the first channel has been added to the network:

A channel C1 has been created for R1 and R2 using the consortium definition X1.
The channel is governed by a channel configuration CC1, completely separate to
the network configuration.  CC1 is managed by R1 and R2 who have equal rights
over C1. R4 has no rights in CC1 whatsoever.
The channel C1 provides a private communications mechanism for the consortium
X1. We can see channel C1 has been connected to the ordering service O4 but that
nothing else is attached to it. In the next stage of network development, we’re
going to connect components such as client applications and peer nodes. But at
this point, a channel represents the potential for future connectivity.
Even though channel C1 is a part of the network N, it is quite distinguishable
from it. Also notice that organizations R3 and R4 are not in this channel – it
is for transaction processing between R1 and R2. In the previous step, we saw
how R4 could grant R1 permission to create new consortia. It’s helpful to
mention that R4 also allowed R1 to create channels! In this diagram, it
could have been organization R1 or R4 who created a channel C1. Again, note
that a channel can have any number of organizations connected to it – we’ve
shown two as it’s the simplest configuration.
Again, notice how channel C1 has a completely separate configuration, CC1, to
the network configuration NC4. CC1 contains the policies that govern the
rights that R1 and R2 have over the channel C1 – and as we’ve seen, R3 and
R4 have no permissions in this channel. R3 and R4 can only interact with C1 if
they are added by R1 or R2 to the appropriate policy in the channel
configuration CC1. An example is defining who can add a new organization to the
channel. Specifically, note that R4 cannot add itself to the channel C1 – it
must, and can only, be authorized by R1 or R2.
Why are channels so important? Channels are useful because they provide a
mechanism for private communications and private data between the members of a
consortium. Channels provide privacy from other channels, and from the network.
Hyperledger Fabric is powerful in this regard, as it allows organizations to
share infrastructure and keep it private at the same time.  There’s no
contradiction here – different consortia within the network will have a need
for different information and processes to be appropriately shared, and channels
provide an efficient mechanism to do this.  Channels provide an efficient
sharing of infrastructure while maintaining data and communications privacy.
We can also see that once a channel has been created, it is in a very real sense
“free from the network”. It is only organizations that are explicitly specified
in a channel configuration that have any control over it, from this time forward
into the future. Likewise, any updates to network configuration NC4 from this
time onwards will have no direct effect on channel configuration CC1; for
example if consortia definition X1 is changed, it will not affect the members of
channel C1. Channels are therefore useful because they allow private
communications between the organizations constituting the channel. Moreover, the
data in a channel is completely isolated from the rest of the network, including
other channels.
As an aside, there is also a special system channel defined for use by the
ordering service.  It behaves in exactly the same way as a regular channel,
which are sometimes called application channels for this reason.  We don’t
normally need to worry about this channel, but we’ll discuss a little bit more
about it later in this topic.

Peers and Ledgers¶
Let’s now start to use the channel to connect the blockchain network and the
organizational components together. In the next stage of network development, we
can see that our network N has just acquired two new components, namely a peer
node P1 and a ledger instance, L1.

A peer node P1 has joined the channel C1. P1 physically hosts a copy of the
ledger L1. P1 and O4 can communicate with each other using channel C1.
Peer nodes are the network components where copies of the blockchain ledger are
hosted!  At last, we’re starting to see some recognizable blockchain components!
P1’s purpose in the network is purely to host a copy of the ledger L1 for others
to access. We can think of L1 as being physically hosted on P1, but
logically hosted on the channel C1. We’ll see this idea more clearly when we
add more peers to the channel.
A key part of a P1’s configuration is an X.509 identity issued by CA1 which
associates P1 with organization R1. Once P1 is started, it can join channel
C1 using the orderer O4. When O4 receives this join request, it uses the channel
configuration CC1 to determine P1’s permissions on this channel. For example,
CC1 determines whether P1 can read and/or write information to the ledger L1.
Notice how peers are joined to channels by the organizations that own them, and
though we’ve only added one peer, we’ll see how  there can be multiple peer
nodes on multiple channels within the network. We’ll see the different roles
that peers can take on a little later.

Applications and Smart Contract chaincode¶
Now that the channel C1 has a ledger on it, we can start connecting client
applications to consume some of the services provided by workhorse of the
ledger, the peer!
Notice how the network has grown:

A smart contract S5 has been installed onto P1.  Client application A1 in
organization R1 can use S5 to access the ledger via peer node P1. A1, P1 and
O4 are all joined to channel C1, i.e. they can all make use of the
communication facilities provided by that channel.
In the next stage of network development, we can see that client application A1
can use channel C1 to connect to specific network resources – in this case A1
can connect to both peer node P1 and orderer node O4. Again, see how channels
are central to the communication between network and organization components.
Just like peers and orderers, a client application will have an identity that
associates it with an organization.  In our example, client application A1 is
associated with organization R1; and although it is outside the Fabric
blockchain network, it is connected to it via the channel C1.
It might now appear that A1 can access the ledger L1 directly via P1, but in
fact, all access is managed via a special program called a smart contract
chaincode, S5. Think of S5 as defining all the common access patterns to the
ledger; S5 provides a well-defined set of ways by which the ledger L1 can
be queried or updated. In short, client application A1 has to go through smart
contract S5 to get to ledger L1!
Smart contracts can be created by application developers in each organization to
implement a business process shared by the consortium members. Smart contracts
are used to help generate transactions which can be subsequently distributed to
every node in the network. We’ll discuss this idea a little later; it’ll be
easier to understand when the network is bigger. For now, the important thing to
understand is that to get to this point two operations must have been performed
on the smart contract; it must have been installed on peers, and then
defined on a channel.
Hyperledger Fabric users often use the terms smart contract and
chaincode interchangeably. In general, a smart contract defines the
transaction logic that controls the lifecycle of a business object contained
in the world state. It is then packaged into a chaincode which is then deployed
to a blockchain network. Think of smart contracts as governing transactions,
whereas chaincode governs how smart contracts are packaged for deployment.

Installing a chaincode package¶
After a smart contract S5 has been developed, an administrator in organization
R1 must create a chaincode package and install it
onto peer node P1. This is a straightforward operation; once completed, P1 has
full knowledge of S5. Specifically, P1 can see the implementation logic of
S5 – the program code that it uses to access the ledger L1. We contrast this to
the S5 interface which merely describes the inputs and outputs of S5,
without regard to its implementation.
When an organization has multiple peers in a channel, it can choose the peers
upon which it installs smart contracts; it does not need to install a smart
contract on every peer.

Defining a chaincode¶
Although a chaincode is installed on the peers of individual organizations, it
is governed and operated in the scope of a channel. Each organization needs to
approve a chaincode definition, a set of parameters that establish how a
chaincode will be used on a channel. An organization must approve a chaincode
definition in order to use the installed smart contract to query the ledger
and endorse transactions. In our example, which only has a single peer node P1,
an administrator in organization R1 must approve a chaincode definition for S5.
A sufficient number of organizations need to approve a chaincode definition (A
majority, by default) before the chaincode definition can be committed to the
channel and used to interact with the channel ledger. Because the channel only
has one member, the administrator of R1 can commit the chaincode definition of
S5 to the channel C1. Once the definition has been committed, S5 can now be
invoked by client application A1!
Note that although every component on the channel can now access S5, they are
not able to see its program logic.  This remains private to those nodes who have
installed it; in our example that means P1. Conceptually this means that it’s
the smart contract interface that is defined and committed to a channel, in
contrast to the smart contract implementation that is installed. To reinforce
this idea; installing a smart contract shows how we think of it being
physically hosted on a peer, whereas a smart contract that has been defined
on a channel shows how we consider it logically hosted by the channel.

Endorsement policy¶
The most important piece of information supplied within the chaincode definition
is the endorsement policy. It describes
which organizations must approve transactions before they will be accepted by other
organizations onto their copy of the ledger. In our sample network, transactions
can only be accepted onto ledger L1 if R1 or R2 endorse them.
Committing the chaincode definition to the channel places the endorsement policy
on the channel ledger; it enables it to be accessed by any member of the channel.
You can read more about endorsement policies in the transaction flow topic.

Invoking a smart contract¶
Once a smart contract has been installed on a peer node and defined on a
channel it can be invoked by a client application.
Client applications do this by sending transaction proposals to peers owned by
the organizations specified by the smart contract endorsement policy. The
transaction proposal serves as input to the smart contract, which uses it to
generate an endorsed transaction response, which is returned by the peer node to
the client application.
It’s these transactions responses that are packaged together with the
transaction proposal to form a fully endorsed transaction, which can be
distributed to the entire network.  We’ll look at this in more detail later  For
now, it’s enough to understand how applications invoke smart contracts to
generate endorsed transactions.
By this stage in network development we can see that organization R1 is fully
participating in the network. Its applications – starting with A1 – can access
the ledger L1 via smart contract S5, to generate transactions that will be
endorsed by R1, and therefore accepted onto the ledger because they conform to
the endorsement policy.

Network completed¶
Recall that our objective was to create a channel for consortium X1 –
organizations R1 and R2. This next phase of network development sees
organization R2 add its infrastructure to the network.
Let’s see how the network has evolved:

The network has grown through the addition of infrastructure from
organization R2. Specifically, R2 has added peer node P2, which hosts a copy of
ledger L1, and chaincode S5. R2 approves the same chaincode definition as R1.
P2 has also joined channel C1, as has application A2. A2 and P2 are identified
using certificates from CA2. All of this means that both applications A1 and A2
can invoke S5 on C1 either using peer node P1 or P2.
We can see that organization R2 has added a peer node, P2, on channel C1. P2
also hosts a copy of the ledger L1 and smart contract S5. We can see that R2 has
also added client application A2 which can connect to the network via channel
C1. To achieve this, an administrator in organization R2 has created peer node
P2 and joined it to channel C1, in the same way as an administrator in R1. The
administrator also has to approve the same chaincode definition as R1.
We have created our first operational network! At this stage in network
development, we have a channel in which organizations R1 and R2 can fully
transact with each other. Specifically, this means that applications A1 and A2
can generate transactions using smart contract S5 and ledger L1 on channel C1.

Generating and accepting transactions¶
In contrast to peer nodes, which always host a copy of the ledger, we see that
there are two different kinds of peer nodes; those which host smart contracts
and those which do not. In our network, every peer hosts a copy of the smart
contract, but in larger networks, there will be many more peer nodes that do not
host a copy of the smart contract. A peer can only run a smart contract if it
is installed on it, but it can know about the interface of a smart contract by
being connected to a channel.
You should not think of peer nodes which do not have smart contracts installed
as being somehow inferior. It’s more the case that peer nodes with smart
contracts have a special power – to help generate transactions. Note that
all peer nodes can validate and subsequently accept or reject
transactions onto their copy of the ledger L1. However, only peer nodes with a
smart contract installed can take part in the process of transaction
endorsement which is central to the generation of valid transactions.
We don’t need to worry about the exact details of how transactions are
generated, distributed and accepted in this topic – it is sufficient to
understand that we have a blockchain network where organizations R1 and R2 can
share information and processes as ledger-captured transactions.  We’ll learn a
lot more about transactions, ledgers, smart contracts in other topics.

Types of peers¶
In Hyperledger Fabric, while all peers are the same, they can assume multiple
roles depending on how the network is configured.  We now have enough
understanding of a typical network topology to describe these roles.

Committing peer. Every peer node in a
channel is a committing peer. It receives blocks of generated transactions,
which are subsequently validated before they are committed to the peer
node’s copy of the ledger as an append operation.

Endorsing peer. Every peer with a smart
contract can be an endorsing peer if it has a smart contract installed.
However, to actually be an endorsing peer, the smart contract on the peer
must be used by a client application to generate a digitally signed
transaction response. The term endorsing peer is an explicit reference to
this fact.
An endorsement policy for a smart contract identifies the
organizations whose peer should digitally sign a generated transaction
before it can be accepted onto a committing peer’s copy of the ledger.

These are the two major types of peer; there are two other roles a peer can
adopt:

Leader peer. When an organization has
multiple peers in a channel, a leader peer is a node which takes
responsibility for distributing transactions from the orderer to the other
committing peers in the organization.  A peer can choose to participate in
static or dynamic leadership selection.
It is helpful, therefore to think of two sets of peers from leadership
perspective – those that have static leader selection, and those with
dynamic leader selection. For the static set, zero or more peers can be
configured as leaders. For the dynamic set, one peer will be elected leader
by the set. Moreover, in the dynamic set, if a leader peer fails, then the
remaining peers will re-elect a leader.
It means that an organization’s peers can have one or more leaders connected
to the ordering service. This can help to improve resilience and scalability
in large networks which process high volumes of transactions.

Anchor peer. If a peer needs to
communicate with a peer in another organization, then it can use one of the
anchor peers defined in the channel configuration for that organization.
An organization can have zero or more anchor peers defined for it, and an
anchor peer can help with many different cross-organization communication
scenarios.

Note that a peer can be a committing peer, endorsing peer, leader peer and
anchor peer all at the same time! Only the anchor peer is optional – for all
practical purposes there will always be a leader peer and at least one
endorsing peer and at least one committing peer.

Adding organizations and peers to the channel¶
When R2 joins the channel, the organization must install smart contract S5
onto its peer node, P2. That’s obvious – if applications A1 or A2 wish to use
S5 on peer node P2 to generate transactions, it must first be present;
installation is the mechanism by which this happens. At this point, peer node P2
has a physical copy of the smart contract and the ledger; like P1, it can both
generate and accept transactions onto its copy of ledger L1.
R2 must approve the same chaincode definition as was approved by R1 in order to
use smart contract S5. Because the chaincode definition has already been
committed to the channel by organization R1, R2 can use the chaincode as soon as
the organization approves the chaincode definition and installs the chaincode
package. The commit transaction only needs to happen once. A new organization
can use the chaincode as soon as they approve the chaincode parameters agreed to
by other members of the channel. Because the approval of a chaincode definition
occurs at the organization level, R2 can approve the chaincode definition once
and join multiple peers to the channel with the chaincode package installed.
However, if R2 wanted to change the chaincode definition, both R1 and R2 would
need to approve a new definition for their organization, and then one of the
organizations would need to commit the definition to the channel.
In our network, we can see that channel C1 connects two client applications, two
peer nodes and an ordering service.  Since there is only one channel, there is
only one logical ledger with which these components interact. Peer nodes P1
and P2 have identical copies of ledger L1. Copies of smart contract S5 will
usually be identically implemented using the same programming language, but
if not, they must be semantically equivalent.
We can see that the careful addition of peers to the network can help support
increased throughput, stability, and resilience. For example, more peers in a
network will allow more applications to connect to it; and multiple peers in an
organization will provide extra resilience in the case of planned or unplanned
outages.
It all means that it is possible to configure sophisticated topologies which
support a variety of operational goals – there is no theoretical limit to how
big a network can get. Moreover, the technical mechanism by which peers within
an individual organization efficiently discover and communicate with each other –
the gossip protocol – will accommodate a
large number of peer nodes in support of such topologies.
The careful use of network and channel policies allow even large networks to be
well-governed.  Organizations are free to add peer nodes to the network so long
as they conform to the policies agreed by the network. Network and channel
policies create the balance between autonomy and control which characterizes a
de-centralized network.

Simplifying the visual vocabulary¶
We’re now going to simplify the visual vocabulary used to represent our sample
blockchain network. As the size of the network grows, the lines initially used
to help us understand channels will become cumbersome. Imagine how complicated
our diagram would be if we added another peer or client application, or another
channel?
That’s what we’re going to do in a minute, so before we do, let’s simplify the
visual vocabulary. Here’s a simplified representation of the network we’ve
developed so far:

The diagram shows the facts relating to channel C1 in the network N as follows:
Client applications A1 and A2 can use channel C1 for communication with peers
P1 and P2, and orderer O4. Peer nodes P1 and P2 can use the communication
services of channel C1. Ordering service O4 can make use of the communication
services of channel C1. Channel configuration CC1 applies to channel C1.
Note that the network diagram has been simplified by replacing channel lines
with connection points, shown as blue circles which include the channel number.
No information has been lost. This representation is more scalable because it
eliminates crossing lines. This allows us to more clearly represent larger
networks. We’ve achieved this simplification by focusing on the connection
points between components and a channel, rather than the channel itself.

Adding another consortium definition¶
In this next phase of network development, we introduce organization R3.  We’re
going to give organizations R2 and R3 a separate application channel which
allows them to transact with each other.  This application channel will be
completely separate to that previously defined, so that R2 and R3 transactions
can be kept private to them.
Let’s return to the network level and define a new consortium, X2, for R2 and
R3:

A network administrator from organization R1 or R4 has added a new consortium
definition, X2, which includes organizations R2 and R3. This will be used to
define a new channel for X2.
Notice that the network now has two consortia defined: X1 for organizations R1
and R2 and X2 for organizations R2 and R3. Consortium X2 has been introduced in
order to be able to create a new channel for R2 and R3.
A new channel can only be created by those organizations specifically identified
in the network configuration policy, NC4, as having the appropriate rights to do
so, i.e. R1 or R4. This is an example of a policy which separates organizations
that can manage resources at the network level versus those who can manage
resources at the channel level. Seeing these policies at work helps us
understand why Hyperledger Fabric has a sophisticated tiered policy
structure.
In practice, consortium definition X2 has been added to the network
configuration NC4. We discuss the exact mechanics of this operation elsewhere in
the documentation.

Adding a new channel¶
Let’s now use this new consortium definition, X2, to create a new channel, C2.
To help reinforce your understanding of the simpler channel notation, we’ve used
both visual styles – channel C1 is represented with blue circular end points,
whereas channel C2 is represented with red connecting lines:

A new channel C2 has been created for R2 and R3 using consortium definition X2.
The channel has a channel configuration CC2, completely separate to the network
configuration NC4, and the channel configuration CC1. Channel C2 is managed by
R2 and R3 who have equal rights over C2 as defined by a policy in CC2. R1 and
R4 have no rights defined in CC2 whatsoever.
The channel C2 provides a private communications mechanism for the consortium
X2. Again, notice how organizations united in a consortium are what form
channels. The channel configuration CC2 now contains the policies that govern
channel resources, assigning management rights to organizations R2 and R3 over
channel C2. It is managed exclusively by R2 and R3; R1 and R4 have no power in
channel C2. For example, channel configuration CC2 can subsequently be updated
to add organizations to support network growth, but this can only be done by R2
or R3.
Note how the channel configurations CC1 and CC2 remain completely separate from
each other, and completely separate from the network configuration, NC4. Again
we’re seeing the de-centralized nature of a Hyperledger Fabric network; once
channel C2 has been created, it is managed by organizations R2 and R3
independently to other network elements. Channel policies always remain separate
from each other and can only be changed by the organizations authorized to do so
in the channel.
As the network and channels evolve, so will the network and channel
configurations. There is a process by which this is accomplished in a controlled
manner – involving configuration transactions which capture the change to these
configurations. Every configuration change results in a new configuration block
transaction being generated, and later in this topic,
we’ll see how these blocks are validated and accepted to create updated network
and channel configurations respectively.

Network and channel configurations¶
Throughout our sample network, we see the importance of network and channel
configurations. These configurations are important because they encapsulate the
policies agreed by the network members, which provide a shared reference for
controlling access to network resources. Network and channel configurations also
contain facts about the network and channel composition, such as the name of
consortia and its organizations.
For example, when the network is first formed using the ordering service node
O4, its behaviour is governed by the network configuration NC4. The initial
configuration of NC4 only contains policies that permit organization R4 to
manage network resources. NC4 is subsequently updated to also allow R1 to manage
network resources. Once this change is made, any administrator from organization
R1 or R4 that connects to O4 will have network management rights because that is
what the policy in the network configuration NC4 permits. Internally, each node
in the ordering service records each channel in the network configuration, so
that there is a record of each channel created, at the network level.
It means that although ordering service node O4 is the actor that created
consortia X1 and X2 and channels C1 and C2, the intelligence of the network
is contained in the network configuration NC4 that O4 is obeying.  As long as O4
behaves as a good actor, and correctly implements the policies defined in NC4
whenever it is dealing with network resources, our network will behave as all
organizations have agreed. In many ways NC4 can be considered more important
than O4 because, ultimately, it controls network access.
The same principles apply for channel configurations with respect to peers. In
our network, P1 and P2 are likewise good actors. When peer nodes P1 and P2 are
interacting with client applications A1 or A2 they are each using the policies
defined within channel configuration CC1 to control access to the channel C1
resources.
For example, if A1 wants to access the smart contract chaincode S5 on peer nodes
P1 or P2, each peer node uses its copy of CC1 to determine the operations that
A1 can perform. For example, A1 may be permitted to read or write data from the
ledger L1 according to policies defined in CC1. We’ll see later the same pattern
for actors in channel and its channel configuration CC2.  Again, we can see that
while the peers and applications are critical actors in the network, their
behaviour in a channel is dictated more by the channel configuration policy than
any other factor.
Finally, it is helpful to understand how network and channel configurations are
physically realized. We can see that network and channel configurations are
logically singular – there is one for the network, and one for each channel.
This is important; every component that accesses the network or the channel must
have a shared understanding of the permissions granted to different
organizations.
Even though there is logically a single configuration, it is actually replicated
and kept consistent by every node that forms the network or channel. For
example, in our network peer nodes P1 and P2 both have a copy of channel
configuration CC1, and by the time the network is fully complete, peer nodes P2
and P3 will both have a copy of channel configuration CC2. Similarly ordering
service node O4 has a copy of the network configuration, but in a multi-node
configuration, every ordering service node will have its
own copy of the network configuration.
Both network and channel configurations are kept consistent using the same
blockchain technology that is used for user transactions – but for
configuration transactions. To change a network or channel configuration, an
administrator must submit a configuration transaction to change the network or
channel configuration. It must be signed by the organizations identified in the
appropriate policy as being responsible for configuration change. This policy is
called the mod_policy and we’ll discuss it later.
Indeed, the ordering service nodes operate a mini-blockchain, connected via the
system channel we mentioned earlier. Using the system channel ordering
service nodes distribute network configuration transactions. These transactions
are used to co-operatively maintain a consistent copy of the network
configuration at each ordering service node. In a similar way, peer nodes in an
application channel can distribute channel configuration transactions.
Likewise, these transactions are used to maintain a consistent copy of the
channel configuration at each peer node.
This balance between objects that are logically singular, by being physically
distributed is a common pattern in Hyperledger Fabric. Objects like network
configurations, that are logically single, turn out to be physically replicated
among a set of ordering services nodes for example. We also see it with channel
configurations, ledgers, and to some extent smart contracts which are installed
in multiple places but whose interfaces exist logically at the channel level.
It’s a pattern you see repeated time and again in Hyperledger Fabric, and
enables Hyperledger Fabric to be both de-centralized and yet manageable at the
same time.

Adding another peer¶
Now that organization R3 is able to fully participate in channel C2, let’s add
its infrastructure components to the channel.  Rather than do this one component
at a time, we’re going to add a peer, its local copy of a ledger, a smart
contract and a client application all at once!
Let’s see the network with organization R3’s components added:

The diagram shows the facts relating to channels C1 and C2 in the network N as
follows: Client applications A1 and A2 can use channel C1 for communication
with peers P1 and P2, and ordering service O4; client applications A3 can use
channel C2 for communication with peer P3 and ordering service O4. Ordering
service O4 can make use of the communication services of channels C1 and C2.
Channel configuration CC1 applies to channel C1, CC2 applies to channel C2.
First of all, notice that because peer node P3 is connected to channel C2, it
has a different ledger – L2 – to those peer nodes using channel C1.  The
ledger L2 is effectively scoped to channel C2. The ledger L1 is completely
separate; it is scoped to channel C1.  This makes sense – the purpose of the
channel C2 is to provide private communications between the members of the
consortium X2, and the ledger L2 is the private store for their transactions.
In a similar way, the smart contract S6, installed on peer node P3, and defined
on channel C2, is used to provide controlled access to ledger L2. Application A3
can now use channel C2 to invoke the services provided by smart contract S6 to
generate transactions that can be accepted onto every copy of the ledger L2 in
the network.
At this point in time, we have a single network that has two completely separate
channels defined within it.  These channels provide independently managed
facilities for organizations to transact with each other. Again, this is
de-centralization at work; we have a balance between control and autonomy. This
is achieved through policies which are applied to channels which are controlled
by, and affect, different organizations.

Joining a peer to multiple channels¶
In this final stage of network development, let’s return our focus to
organization R2. We can exploit the fact that R2 is a member of both consortia
X1 and X2 by joining it to multiple channels:

The diagram shows the facts relating to channels C1 and C2 in the network N as
follows: Client applications A1 can use channel C1 for communication with peers
P1 and P2, and ordering service O4; client application A2 can use channel C1
for communication with peers P1 and P2 and channel C2 for communication with
peers P2 and P3 and ordering service O4; client application A3 can use channel
C2 for communication with peer P3 and P2 and ordering service O4. Ordering service O4
can make use of the communication services of channels C1 and C2. Channel
configuration CC1 applies to channel C1, CC2 applies to channel C2.
We can see that R2 is a special organization in the network, because it is the
only organization that is a member of two application channels!  It is able to
transact with organization R1 on channel C1, while at the same time it can also
transact with organization R3 on a different channel, C2.
Notice how peer node P2 has smart contract S5 installed for channel C1 and smart
contract S6 installed for channel C2. Peer node P2 is a full member of both
channels at the same time via different smart contracts for different ledgers.
This is a very powerful concept – channels provide both a mechanism for the
separation of organizations, and a mechanism for collaboration between
organizations. All the while, this infrastructure is provided by, and shared
between, a set of independent organizations.
It is also important to note that peer node P2’s behaviour is controlled very
differently depending upon the channel in which it is transacting. Specifically,
the policies contained in channel configuration CC1 dictate the operations
available to P2 when it is transacting in channel C1, whereas it is the policies
in channel configuration CC2 that control P2’s behaviour in channel C2.
Again, this is desirable – R2 and R1 agreed the rules for channel C1, whereas
R2 and R3 agreed the rules for channel C2. These rules were captured in the
respective channel policies – they can and must be used by every
component in a channel to enforce correct behaviour, as agreed.
Similarly, we can see that client application A2 is now able to transact on
channels C1 and C2.  And likewise, it too will be governed by the policies in
the appropriate channel configurations.  As an aside, note that client
application A2 and peer node P2 are using a mixed visual vocabulary – both
lines and connections. You can see that they are equivalent; they are visual
synonyms.

The ordering service¶
The observant reader may notice that the ordering service node appears to be a
centralized component; it was used to create the network initially, and connects
to every channel in the network.  Even though we added R1 and R4 to the network
configuration policy NC4 which controls the orderer, the node was running on
R4’s infrastructure. In a world of de-centralization, this looks wrong!
Don’t worry! Our example network showed the simplest ordering service
configuration to help you understand the idea of a network administration point.
In fact, the ordering service can itself too be completely de-centralized!  We
mentioned earlier that an ordering service could be comprised of many individual
nodes owned by different organizations, so let’s see how that would be done in
our sample network.
Let’s have a look at a more realistic ordering service node configuration:

A multi-organization ordering service.  The ordering service comprises ordering
service nodes O1 and O4. O1 is provided by organization R1 and node O4 is
provided by organization R4. The network configuration NC4 defines network
resource permissions for actors from both organizations R1 and R4.
We can see that this ordering service completely de-centralized – it runs in
organization R1 and it runs in organization R4. The network configuration
policy, NC4, permits R1 and R4 equal rights over network resources.  Client
applications and peer nodes from organizations R1 and R4 can manage network
resources by connecting to either node O1 or node O4, because both nodes behave
the same way, as defined by the policies in network configuration NC4. In
practice, actors from a particular organization tend to use infrastructure
provided by their home organization, but that’s certainly not always the case.

De-centralized transaction distribution¶
As well as being the management point for the network, the ordering service also
provides another key facility – it is the distribution point for transactions.
The ordering service is the component which gathers endorsed transactions
from applications and orders them into transaction blocks, which are
subsequently distributed to every peer node in the channel. At each of these
committing peers, transactions are recorded, whether valid or invalid, and their
local copy of the ledger updated appropriately.
Notice how the ordering service node O4 performs a very different role for the
channel C1 than it does for the network N. When acting at the channel level,
O4’s role is to gather transactions and distribute blocks inside channel C1. It
does this according to the policies defined in channel configuration CC1. In
contrast, when acting at the network level, O4’s role is to provide a management
point for network resources according to the policies defined in network
configuration NC4. Notice again how these roles are defined by different
policies within the channel and network configurations respectively. This should
reinforce to you the importance of declarative policy based configuration in
Hyperledger Fabric. Policies both define, and are used to control, the agreed
behaviours by each and every member of a consortium.
We can see that the ordering service, like the other components in Hyperledger
Fabric, is a fully de-centralized component. Whether acting as a network
management point, or as a distributor of blocks in a channel, its nodes can be
distributed as required throughout the multiple organizations in a network.

Changing policy¶
Throughout our exploration of the sample network, we’ve seen the importance of
the policies to control the behaviour of the actors in the system. We’ve only
discussed a few of the available policies, but there are many that can be
declaratively defined to control every aspect of behaviour. These individual
policies are discussed elsewhere in the documentation.
Most importantly of all, Hyperledger Fabric provides a uniquely powerful policy
that allows network and channel administrators to manage policy change itself!
The underlying philosophy is that policy change is a constant, whether it occurs
within or between organizations, or whether it is imposed by external
regulators. For example, new organizations may join a channel, or existing
organizations may have their permissions increased or decreased. Let’s
investigate a little more how change policy is implemented in Hyperledger
Fabric.
The key point of understanding is that policy change is managed by a
policy within the policy itself.  The modification policy, or
mod_policy for short, is a first class policy within a network or channel
configuration that manages change. Let’s give two brief examples of how we’ve
already used mod_policy to manage change in our network!
The first example was when the network was initially set up. At this time, only
organization R4 was allowed to manage the network. In practice, this was
achieved by making R4 the only organization defined in the network configuration
NC4 with permissions to network resources.  Moreover, the mod_policy for NC4
only mentioned organization R4 – only R4 was allowed to change this
configuration.
We then evolved the network N to also allow organization R1 to administer the
network.  R4 did this by adding R1 to the policies for channel creation and
consortium creation. Because of this change, R1 was able to define the
consortia X1 and X2, and create the channels C1 and C2. R1 had equal
administrative rights over the channel and consortium policies in the network
configuration.
R4 however, could grant even more power over the network configuration to R1! R4
could add R1 to the mod_policy such that R1 would be able to manage change of
the network policy too.
This second power is much more powerful than the first, because R1 now has
full control over the network configuration NC4! This means that R1 can, in
principle remove R4’s management rights from the network.  In practice, R4 would
configure the mod_policy such that R4 would need to also approve the change, or
that all organizations in the mod_policy would have to approve the change.
There’s lots of flexibility to make the mod_policy as sophisticated as it needs
to be to support whatever change process is required.
This is mod_policy at work – it has allowed the graceful evolution of a basic
configuration into a sophisticated one. All the time this has occurred with the
agreement of all organization involved. The mod_policy behaves like every other
policy inside a network or channel configuration; it defines a set of
organizations that are allowed to change the mod_policy itself.
We’ve only scratched the surface of the power of policies and mod_policy in
particular in this subsection. It is discussed at much more length in the policy
topic, but for now let’s return to our finished network!

Network fully formed¶
Let’s recap what our network looks like using a consistent visual vocabulary.
We’ve re-organized it slightly using our more compact visual syntax, because it
better accommodates larger topologies:

In this diagram we see that the Fabric blockchain network consists of two
application channels and one ordering channel. The organizations R1 and R4 are
responsible for the ordering channel, R1 and R2 are responsible for the blue
application channel while R2 and R3 are responsible for the red application
channel. Client applications A1 is an element of organization R1, and CA1 is
it’s certificate authority. Note that peer P2 of organization R2 can use the
communication facilities of the blue and the red application channel. Each
application channel has its own channel configuration, in this case CC1 and
CC2. The channel configuration of the system channel is part of the network
configuration, NC4.
We’re at the end of our conceptual journey to build a sample Hyperledger Fabric
blockchain network. We’ve created a four organization network with two channels
and three peer nodes, with two smart contracts and an ordering service.  It is
supported by four certificate authorities. It provides ledger and smart contract
services to three client applications, who can interact with it via the two
channels. Take a moment to look through the details of the network in the
diagram, and feel free to read back through the topic to reinforce your
knowledge, or go to a more detailed topic.

Summary of network components¶
Here’s a quick summary of the network components we’ve discussed:

Ledger. One per channel. Comprised of the
Blockchain and
the World state
Smart contract (aka chaincode)
Peer nodes
Ordering service
Channel
Certificate Authority

Network summary¶
In this topic, we’ve seen how different organizations share their infrastructure
to provide an integrated Hyperledger Fabric blockchain network.  We’ve seen how
the collective infrastructure can be organized into channels that provide
private communications mechanisms that are independently managed.  We’ve seen
how actors such as client applications, administrators, peers and orderers are
identified as being from different organizations by their use of certificates
from their respective certificate authorities.  And in turn, we’ve seen the
importance of policy to define the agreed permissions that these organizational
actors have over network and channel resources.

Identity¶

What is an Identity?¶
The different actors in a blockchain network include peers, orderers, client
applications, administrators and more. Each of these actors — active elements
inside or outside a network able to consume services — has a digital identity
encapsulated in an X.509 digital certificate. These identities really matter
because they determine the exact permissions over resources and access to
information that actors have in a blockchain network.
A digital identity furthermore has some additional attributes that Fabric uses
to determine permissions, and it gives the union of an identity and the associated
attributes a special name — principal. Principals are just like userIDs or
groupIDs, but a little more flexible because they can include a wide range of
properties of an actor’s identity, such as the actor’s organization, organizational
unit, role or even the actor’s specific identity. When we talk about principals,
they are the properties which determine their permissions.
For an identity to be verifiable, it must come from a trusted authority.
A membership service provider
(MSP) is that trusted authority in Fabric. More specifically, an MSP is a component
that defines the rules that govern the valid identities for this organization.
The default MSP implementation in Fabric uses X.509 certificates as identities,
adopting a traditional Public Key Infrastructure (PKI) hierarchical model (more
on PKI later).

A Simple Scenario to Explain the Use of an Identity¶
Imagine that you visit a supermarket to buy some groceries. At the checkout you see
a sign that says that only Visa, Mastercard and AMEX cards are accepted. If you try to
pay with a different card — let’s call it an “ImagineCard” — it doesn’t matter whether
the card is authentic and you have sufficient funds in your account. It will be not be
accepted.

Having a valid credit card is not enough — it must also be accepted by the store! PKIs
and MSPs work together in the same way — a PKI provides a list of identities,
and an MSP says which of these are members of a given organization that participates in
the network.
PKI certificate authorities and MSPs provide a similar combination of functionalities.
A PKI is like a card provider — it dispenses many different types of verifiable
identities. An MSP, on the other hand, is like the list of card providers accepted
by the store, determining which identities are the trusted members (actors)
of the store payment network. MSPs turn verifiable identities into the members
of a blockchain network.
Let’s drill into these concepts in a little more detail.

What are PKIs?¶
A public key infrastructure (PKI) is a collection of internet technologies that provides
secure communications in a network. It’s PKI that puts the S in HTTPS — and if
you’re reading this documentation on a web browser, you’re probably using a PKI to make
sure it comes from a verified source.

The elements of Public Key Infrastructure (PKI). A PKI is comprised of Certificate
Authorities who issue digital certificates to parties (e.g., users of a service, service
provider), who then use them to authenticate themselves in the messages they exchange
in their environment. A CA’s Certificate Revocation List (CRL) constitutes a reference
for the certificates that are no longer valid. Revocation of a certificate can happen for
a number of reasons. For example, a certificate may be revoked because the cryptographic
private material associated to the certificate has been exposed.
Although a blockchain network is more than a communications network, it relies on the
PKI standard to ensure secure communication between various network participants, and to
ensure that messages posted on the blockchain are properly authenticated.
It’s therefore important to understand the basics of PKI and then why MSPs are
so important.
There are four key elements to PKI:

Digital Certificates
Public and Private Keys
Certificate Authorities
Certificate Revocation Lists

Let’s quickly describe these PKI basics, and if you want to know more details,
Wikipedia is a good
place to start.

Digital Certificates¶
A digital certificate is a document which holds a set of attributes relating to
the holder of the certificate. The most common type of certificate is the one
compliant with the X.509 standard, which
allows the encoding of a party’s identifying details in its structure.
For example, Mary Morris in the Manufacturing Division of Mitchell Cars in Detroit,
Michigan might have a digital certificate with a SUBJECT attribute of C=US,
ST=Michigan, L=Detroit, O=Mitchell Cars, OU=Manufacturing, CN=Mary Morris /UID=123456.
Mary’s certificate is similar to her government identity card — it provides
information about Mary which she can use to prove key facts about her. There are
many other attributes in an X.509 certificate, but let’s concentrate on just these
for now.

A digital certificate describing a party called Mary Morris. Mary is the SUBJECT of the
certificate, and the highlighted SUBJECT text shows key facts about Mary. The
certificate also holds many more pieces of information, as you can see. Most importantly,
Mary’s public key is distributed within her certificate, whereas her private signing key
is not. This signing key must be kept private.
What is important is that all of Mary’s attributes can be recorded using a mathematical
technique called cryptography (literally, “secret writing”) so that tampering will
invalidate the certificate. Cryptography allows Mary to present her certificate to others
to prove her identity so long as the other party trusts the certificate issuer, known
as a Certificate Authority (CA). As long as the CA keeps certain cryptographic
information securely (meaning, its own private signing key), anyone reading the
certificate can be sure that the information about Mary has not been tampered with —
it will always have those particular attributes for Mary Morris. Think of Mary’s X.509
certificate as a digital identity card that is impossible to change.

Authentication, Public keys, and Private Keys¶
Authentication and message integrity are important concepts in secure
communications. Authentication requires that parties who exchange messages
are assured of the identity that created a specific message. For a message to have
“integrity” means that cannot have been modified during its transmission.
For example, you might want to be sure you’re communicating with the real Mary
Morris rather than an impersonator. Or if Mary has sent you a message, you might want
to be sure that it hasn’t been tampered with by anyone else during transmission.
Traditional authentication mechanisms rely on digital signatures that,
as the name suggests, allow a party to digitally sign its messages. Digital
signatures also provide guarantees on the integrity of the signed message.
Technically speaking, digital signature mechanisms require each party to
hold two cryptographically connected keys: a public key that is made widely available
and acts as authentication anchor, and a private key that is used to produce
digital signatures on messages. Recipients of digitally signed messages can verify
the origin and integrity of a received message by checking that the
attached signature is valid under the public key of the expected sender.
The unique relationship between a private key and the respective public key is the
cryptographic magic that makes secure communications possible. The unique
mathematical relationship between the keys is such that the private key can be used to
produce a signature on a message that only the corresponding public key can match, and
only on the same message.

In the example above, Mary uses her private key to sign the message. The signature
can be verified by anyone who sees the signed message using her public key.

Certificate Authorities¶
As you’ve seen, an actor or a node is able to participate in the blockchain network,
via the means of a digital identity issued for it by an authority trusted by the
system. In the most common case, digital identities (or simply identities) have
the form of cryptographically validated digital certificates that comply with X.509
standard and are issued by a Certificate Authority (CA).
CAs are a common part of internet security protocols, and you’ve probably heard of
some of the more popular ones: Symantec (originally Verisign), GeoTrust, DigiCert,
GoDaddy, and Comodo, among others.

A Certificate Authority dispenses certificates to different actors. These certificates
are digitally signed by the CA and bind together the actor with the actor’s public key
(and optionally with a comprehensive list of properties). As a result, if one trusts
the CA (and knows its public key), it can trust that the specific actor is bound
to the public key included in the certificate, and owns the included attributes,
by validating the CA’s signature on the actor’s certificate.
Certificates can be widely disseminated, as they do not include either the
actors’ nor the CA’s private keys. As such they can be used as anchor of
trusts for authenticating messages coming from different actors.
CAs also have a certificate, which they make widely available. This allows the
consumers of identities issued by a given CA to verify them by checking that the
certificate could only have been generated by the holder of the corresponding
private key (the CA).
In a blockchain setting, every actor who wishes to interact with the network
needs an identity. In this setting, you might say that one or more CAs can be used
to define the members of an organization’s from a digital perspective. It’s
the CA that provides the basis for an organization’s actors to have a verifiable
digital identity.

Root CAs, Intermediate CAs and Chains of Trust¶
CAs come in two flavors: Root CAs and Intermediate CAs. Because Root CAs
(Symantec, Geotrust, etc) have to securely distribute hundreds of millions
of certificates to internet users, it makes sense to spread this process out
across what are called Intermediate CAs. These Intermediate CAs have their
certificates issued by the root CA or another intermediate authority, allowing
the establishment of a “chain of trust” for any certificate that is issued by
any CA in the chain. This ability to track back to the Root CA not only allows
the function of CAs to scale while still providing security — allowing
organizations that consume certificates to use Intermediate CAs with confidence
— it limits the exposure of the Root CA, which, if compromised, would endanger
the entire chain of trust. If an Intermediate CA is compromised, on the other
hand, there will be a much smaller exposure.

A chain of trust is established between a Root CA and a set of Intermediate CAs
as long as the issuing CA for the certificate of each of these Intermediate CAs is
either the Root CA itself or has a chain of trust to the Root CA.
Intermediate CAs provide a huge amount of flexibility when it comes to the issuance
of certificates across multiple organizations, and that’s very helpful in a
permissioned blockchain system (like Fabric). For example, you’ll see that
different organizations may use different Root CAs, or the same Root CA with
different Intermediate CAs — it really does depend on the needs of the network.

Fabric CA¶
It’s because CAs are so important that Fabric provides a built-in CA component to
allow you to create CAs in the blockchain networks you form. This component — known
as Fabric CA is a private root CA provider capable of managing digital identities of
Fabric participants that have the form of X.509 certificates.
Because Fabric CA is a custom CA targeting the Root CA needs of Fabric,
it is inherently not capable of providing SSL certificates for general/automatic use
in browsers. However, because some CA must be used to manage identity
(even in a test environment), Fabric CA can be used to provide and manage
certificates. It is also possible — and fully appropriate — to use a
public/commercial root or intermediate CA to provide identification.
If you’re interested, you can read a lot more about Fabric CA
in the CA documentation section.

Certificate Revocation Lists¶
A Certificate Revocation List (CRL) is easy to understand — it’s just a list of
references to certificates that a CA knows to be revoked for one reason or another.
If you recall the store scenario, a CRL would be like a list of stolen credit cards.
When a third party wants to verify another party’s identity, it first checks the
issuing CA’s CRL to make sure that the certificate has not been revoked. A
verifier doesn’t have to check the CRL, but if they don’t they run the risk of
accepting a compromised identity.

Using a CRL to check that a certificate is still valid. If an impersonator tries to
pass a compromised digital certificate to a validating party, it can be first
checked against the issuing CA’s CRL to make sure it’s not listed as no longer valid.
Note that a certificate being revoked is very different from a certificate expiring.
Revoked certificates have not expired — they are, by every other measure, a fully
valid certificate. For more in-depth information about CRLs, click here.
Now that you’ve seen how a PKI can provide verifiable identities through a chain of
trust, the next step is to see how these identities can be used to represent the
trusted members of a blockchain network. That’s where a Membership Service Provider
(MSP) comes into play — it identifies the parties who are the members of a
given organization in the blockchain network.
To learn more about membership, check out the conceptual documentation on MSPs.

Membership Service Provider (MSP)¶

Why do I need an MSP?¶
Because Fabric is a permissioned network, blockchain participants need a way to prove their identity to the rest of the network in order to transact on the network. If you’ve read through the documentation on Identity
you’ve seen how a Public Key Infrastructure (PKI) can provide verifiable identities through a chain of trust. How is that chain of trust used by the blockchain network?
Certificate Authorities issue identities by generating a public and private key which forms a key-pair that can be used to prove identity. Because a private key can never be shared publicly, a mechanism is required to enable that proof which is where the MSP comes in. For example, a peer uses its private key to digitally sign, or endorse, a transaction.  The MSP on the ordering service contains the peer’s public key which is then used to verify that the signature attached to the transaction is valid. The private key is used to produce a signature on a transaction that only the corresponding public key, that is part of an MSP, can match. Thus, the MSP is the mechanism that allows that identity to be trusted and recognized by the rest of the network without ever revealing the member’s private key.
Recall from the credit card scenario in the Identity topic that the Certificate Authority is like a card provider — it dispenses many different types of verifiable identities. An MSP, on the other hand, determines which credit card providers are accepted at the store. In this way, the MSP turns an identity (the credit card) into a role (the ability to buy things at the store).
This ability to turn verifiable identities into roles is fundamental to the way Fabric networks function, since it allows organizations, nodes, and channels the ability establish MSPs that determine who is allowed to do what at the organization, node, and channel level.

Identities are similar to your credit cards that are used to prove you can pay. The MSP is similar to the list of accepted credit cards.
Consider a consortium of banks that operate a blockchain network. Each bank operates peer and ordering nodes, and the peers endorse transactions submitted to the network. However, each bank would also have departments and account holders. The account holders would belong to each organization, but would not run nodes on the network. They would only interact with the system from their mobile or web application. So how does the network recognize and differentiate these identities? A CA was used to create the identities, but like the card example, those identities can’t just be issued, they need to be recognized by the network. MSPs are used to define the organizations that are trusted by the network members. MSPs are also the mechanism that provide members with a set of roles and permissions within the network. Because the MSPs defining these organizations are known to the members of a network, they can then be used to validate that network entities that attempt to perform actions are allowed to.
Finally, consider if you want to join an existing network, you need a way to turn your identity into something that is recognized by the network. The MSP is the mechanism that enables you to participate on a permissioned blockchain network. To transact on a Fabric network a member needs to:

Have an identity issued by a CA that is trusted by the network.
Become a member of an organization that is recognized and approved by the network members. The MSP is how the identity is linked to the membership of an organization. Membership is achieved by adding the member’s public key (also known as certificate, signing cert, or signcert) to the organization’s MSP.
Add the MSP to either a consortium on the network or a channel.
Ensure the MSP is included in the policy definitions on the network.

What is an MSP?¶
Despite its name, the Membership Service Provider does not actually provide anything. Rather, the implementation of the MSP requirement is a set of folders that are added to the configuration of the network and is used to define an organization both inwardly (organizations decide who its admins are) and outwardly (by allowing other organizations to validate that entities have the authority to do what they are attempting to do).  Whereas Certificate Authorities generate the certificates that represent identities, the MSP contains a list of permissioned identities.
The MSP identifies which Root CAs and Intermediate CAs are accepted to define the members of a trust domain by listing the identities of their members, or by identifying which CAs are authorized to issue valid identities for their members.
But the power of an MSP goes beyond simply listing who is a network participant or member of a channel. It is the MSP that turns an identity into a role by identifying specific privileges an actor has on a node or channel. Note that when a user is registered with a Fabric CA, a role of admin, peer, client, orderer, or member must be associated with the user. For example, identities registered with the “peer” role should, naturally, be given to a peer. Similarly, identities registered with the “admin” role should be given to organization admins. We’ll delve more into the significance of these roles later in the topic.
In addition, an MSP can allow for the identification of a list of identities that have been revoked — as discussed in the Identity documentation — but we will talk about how that process also extends to an MSP.

MSP domains¶
MSPs occur in two domains in a blockchain network:

Locally on an actor’s node (local MSP)
In channel configuration (channel MSP)

The key difference between local and channel MSPs is not how they function – both turn identities into roles – but their scope. Each MSP lists roles and permissions at a particular level of administration.

Local MSPs¶
Local MSPs are defined for clients and for nodes (peers and orderers).
Local MSPs define the permissions for a node (who are the peer admins who can operate the node, for example). The local MSPs of clients (the account holders in the banking scenario above), allow the user to authenticate itself in its transactions as a member of a channel (e.g. in chaincode transactions), or as the owner of a specific role into the system such as an organization admin, for example, in configuration transactions.
Every node must have a local MSP defined, as it defines who has administrative or participatory rights at that level (peer admins will not necessarily be channel admins, and vice versa).  This allows for authenticating member messages outside the context of a channel and to define the permissions over a particular node (who has the ability to install chaincode on a peer, for example). Note that one or more nodes can be owned by an organization. An MSP defines the organization admins. And the organization, the admin of the organization, the admin of the node, and the node itself should all have the same root of trust.
An orderer local MSP is also defined on the file system of the node and only applies to that node. Like peer nodes, orderers are also owned by a single organization and therefore have a single MSP to list the actors or nodes it trusts.

Channel MSPs¶
In contrast, channel MSPs define administrative and participatory rights at the channel level. Peers and ordering nodes on an application channel share the same view of channel MSPs, and will therefore be able to correctly authenticate the channel participants. This means that if an organization wishes to join the channel, an MSP incorporating the chain of trust for the organization’s members would need to be included in the channel configuration. Otherwise transactions originating from this organization’s identities will be rejected. Whereas local MSPs are represented as a folder structure on the file system, channel MSPs are described in a channel configuration.

Snippet from a channel config.json file that includes two organization MSPs.
Channel MSPs identify who has authorities at a channel level.
The channel MSP defines the relationship between the identities of channel members (which themselves are MSPs) and the enforcement of channel level policies. Channel MSPs contain the MSPs of the organizations of the channel members.
Every organization participating in a channel must have an MSP defined for it. In fact, it is recommended that there is a one-to-one mapping between organizations and MSPs. The MSP defines which members are empowered to act on behalf of the organization. This includes configuration of the MSP itself as well as approving administrative tasks that the organization has role, such as adding new members to a channel. If all network members were part of a single organization or MSP, data privacy is sacrificed. Multiple organizations facilitate privacy by segregating ledger data to only channel members. If more granularity is required within an organization, the organization can be further divided into organizational units (OUs) which we describe in more detail later in this topic.
The system channel MSP includes the MSPs of all the organizations that participate in an ordering service. An ordering service will likely include ordering nodes from multiple organizations and collectively these organizations run the ordering service, most importantly managing the consortium of organizations and the default policies that are inherited by the application channels.
Local MSPs are only defined on the file system of the node or user to which they apply. Therefore, physically and logically there is only one local MSP per
node. However, as channel MSPs are available to all nodes in the channel, they are logically defined once in the channel configuration. However, a channel MSP is also instantiated on the file system of every node in the channel and kept synchronized via consensus. So while there is a copy of each channel MSP on the local file system of every node, logically a channel MSP resides on and is maintained by the channel or the network.
The following diagram illustrates how local and channel MSPs coexist on the network:

The MSPs for the peer and orderer are local, whereas the MSPs for a channel (including the network configuration channel, also known as the system channel) are global, shared across all participants of that channel. In this figure, the network system channel is administered by ORG1, but another application channel can be managed by ORG1 and ORG2. The peer is a member of and managed by ORG2, whereas ORG1 manages the orderer of the figure. ORG1 trusts identities from RCA1, whereas ORG2 trusts identities from RCA2. It is important to note that these are administration identities, reflecting who can administer these components. So while ORG1 administers the network, ORG2.MSP does exist in the network definition.

What role does an organization play in an MSP?¶
An organization is a logical managed group of members. This can be something as big as a multinational corporation or a small as a flower shop. What’s most important about organizations (or orgs) is that they manage their members under a single MSP. The MSP allows an identity to be linked to an organization. Note that this is different from the organization concept defined in an X.509 certificate, which we mentioned above.
The exclusive relationship between an organization and its MSP makes it sensible to name the MSP after the organization, a convention you’ll find adopted in most policy configurations. For example, organization ORG1 would likely have an MSP called something like ORG1-MSP. In some cases an organization may require multiple membership groups — for example, where channels are used to perform very different business functions between organizations. In these cases it makes sense to have multiple MSPs and name them accordingly, e.g., ORG2-MSP-NATIONAL and ORG2-MSP-GOVERNMENT, reflecting the different membership roots of trust within ORG2 in the NATIONAL sales channel compared to the GOVERNMENT regulatory channel.

Organizational Units (OUs) and MSPs¶
An organization can also be divided into multiple organizational units, each of which has a certain set of responsibilities, also referred to as affiliations. Think of an OU as a department inside an organization. For example, the ORG1 organization might have both ORG1.MANUFACTURING and ORG1.DISTRIBUTION OUs to reflect these separate lines of business. When a CA issues X.509 certificates, the OU field in the certificate specifies the line of business to which the identity belongs. A benefit of using OUs like this is that these values can then be used in policy definitions in order to restrict access or in smart contracts for attribute-based access control. Otherwise, separate MSPs would need to be created for each organization.
Specifying OUs is optional. If OUs are not used, all of the identities that are part of an MSP — as identified by the Root CA and Intermediate CA folders — will be considered members of the organization.

Node OU Roles and MSPs¶
Additionally, there is a special kind of OU, sometimes referred to as a Node OU, that can be used to confer a role onto an identity. These Node OU roles are defined in the $FABRIC_CFG_PATH/msp/config.yaml file and contain a list of organizational units whose members are considered to be part of the organization represented by this MSP. This is particularly useful when you want to restrict the members of an organization to the ones holding an identity (signed by one of MSP designated CAs) with a specific Node OU role in it. For example, with node OU’s you can implement a more granular endorsement policy that requires Org1 peers to endorse a transaction, rather than any member of Org1.
In order to use the Node OU roles, the “identity classification” feature must be enabled for the network. When using the folder-based MSP structure, this is accomplished by enabling “Node OUs” in the config.yaml file which resides in the root of the MSP folder:
NodeOUs:
  Enable: true
  ClientOUIdentifier:
    Certificate: cacerts/ca.sampleorg-cert.pem
    OrganizationalUnitIdentifier: client
  PeerOUIdentifier:
    Certificate: cacerts/ca.sampleorg-cert.pem
    OrganizationalUnitIdentifier: peer
  AdminOUIdentifier:
    Certificate: cacerts/ca.sampleorg-cert.pem
    OrganizationalUnitIdentifier: admin
  OrdererOUIdentifier:
    Certificate: cacerts/ca.sampleorg-cert.pem
    OrganizationalUnitIdentifier: orderer

In the example above, there are 4 possible Node OU ROLES for the MSP:

client
peer
admin
orderer

This convention allows you to distinguish MSP roles by the OU present in the CommonName attribute of the X509 certificate. The example above says that any certificate issued by cacerts/ca.sampleorg-cert.pem in which OU=client will identified as a client, OU=peer as a peer, etc. Starting with Fabric v1.4.3, there is also an OU for the orderer and for admins. The new admins role means that you no longer have to explicitly place certs in the admincerts folder of the MSP directory. Rather, the admin role present in the user’s signcert qualifies the identity as an admin user.
These Role and OU attributes are assigned to an identity when the Fabric CA or SDK is used to register a user with the CA. It is the subsequent enroll user command that generates the certificates in the users’ /msp folder.

The resulting ROLE and OU attributes are visible inside the X.509 signing certificate located in the /signcerts folder. The ROLE attribute is identified as hf.Type and  refers to an actor’s role within its organization, (specifying, for example, that an actor is a peer). See the following snippet from a signing certificate shows how the Roles and OUs are represented in the certificate.

Note: For Channel MSPs, just because an actor has the role of an administrator it doesn’t mean that they can administer particular resources. The actual power a given identity has with respect to administering the system is determined by the policies that manage system resources. For example, a channel policy might specify that ORG1-MANUFACTURING administrators, meaning identities with a role of admin and a Node OU of  ORG1-MANUFACTURING, have the rights to add new organizations to the channel, whereas the ORG1-DISTRIBUTION administrators have no such rights.
Finally, OUs could be used by different organizations in a consortium to distinguish each other. But in such cases, the different organizations have to use the same Root CAs and Intermediate CAs for their chain of trust, and assign the OU field to identify members of each organization. When every organization has the same CA or chain of trust, this makes the system more centralized than what might be desirable and therefore deserves careful consideration on a blockchain network.

MSP Structure¶
Let’s explore the MSP elements that render the functionality we’ve described so far.
A local MSP folder contains the following sub-folders:

The figure above shows the subfolders in a local MSP on the file system

config.yaml:  Used to configure the identity classification feature in Fabric by enabling “Node OUs” and defining the accepted roles.

cacerts: This folder contains a list of self-signed X.509 certificates of the Root CAs trusted by the organization represented by this MSP. There must be at least one Root CA certificate in this MSP folder.
This is the most important folder because it identifies the CAs from which all other certificates must be derived to be considered members of the
corresponding organization to form the chain of trust.

intermediatecerts: This folder contains a list of X.509 certificates of the Intermediate CAs trusted by this organization. Each certificate must be signed by one of the Root CAs in the MSP or by any Intermediate CA whose issuing CA chain ultimately leads back to a trusted Root CA.
An intermediate CA may represent a different subdivision of the organization (like ORG1-MANUFACTURING and ORG1-DISTRIBUTION do for ORG1), or the
organization itself (as may be the case if a commercial CA is leveraged for the organization’s identity management). In the latter case intermediate CAs
can be used to represent organization subdivisions. Here you may find more information on best practices for MSP configuration. Notice, that
it is possible to have a functioning network that does not have an Intermediate CA, in which case this folder would be empty.
Like the Root CA folder, this folder defines the CAs from which certificates must be issued to be considered members of the organization.

admincerts (Deprecated from Fabric v1.4.3 and higher): This folder contains a list of identities that define the actors who have the role of administrators for this organization. In general, there should be one or more X.509 certificates in this list.
Note: Prior to Fabric v1.4.3, admins were defined by explicitly putting certs in the admincerts folder in the local MSP directory of your peer. With Fabric v1.4.3 or higher, certificates in this folder are no longer required. Instead, it is recommended that when the user is registered with the CA, that the admin role is used to designate the node administrator. Then, the identity is recognized as an admin by the Node OU role value in their signcert. As a reminder, in order to leverage the admin role, the “identity classification” feature must be enabled in the config.yaml above by setting “Node OUs” to Enable: true. We’ll explore this more later.
And as a reminder, for Channel MSPs, just because an actor has the role of an administrator it doesn’t mean that they can administer particular resources. The actual power a given identity has with respect to administering the system is determined by the policies that manage system resources. For example, a channel policy might specify that ORG1-MANUFACTURING administrators have the rights to add new organizations to the channel, whereas the ORG1-DISTRIBUTION administrators have no such rights.

keystore: (private Key) This folder is defined for the local MSP of a peer or orderer node (or in a client’s local MSP), and contains the node’s private key. This key is used to sign data — for example to sign a transaction proposal response, as part of the endorsement phase.
This folder is mandatory for local MSPs, and must contain exactly one private key. Obviously, access to this folder must be limited only to the identities of users who have administrative responsibility on the peer.
The channel MSP configuration does not include this folder, because channel MSPs solely aim to offer identity validation functionalities and not signing abilities.
Note: If you are using a Hardware Security Module(HSM) for key management, this folder is empty because the private key is generated by and stored in the HSM.

signcert: For a peer or orderer node (or in a client’s local MSP) this folder contains the node’s signing key. This key matches cryptographically the node’s identity included in Node Identity folder and is used to sign data — for example to sign a transaction proposal response, as part of the endorsement phase.
This folder is mandatory for local MSPs, and must contain exactly one public key. Obviously, access to this folder must be limited only to the identities of users who have  administrative responsibility on the peer.
Configuration of a channel MSP does not include this folder, as channel MSPs solely aim to offer identity validation functionalities and not signing abilities.

tlscacerts: This folder contains a list of self-signed X.509 certificates of the Root CAs trusted by this organization for secure communications between nodes using TLS. An example of a TLS communication would be when a peer needs to connect to an orderer so that it can receive ledger updates.
MSP TLS information relates to the nodes inside the network — the peers and the orderers, in other words, rather than the applications and administrations that consume the network.
There must be at least one TLS Root CA certificate in this folder. For more information about TLS, see Securing Communication with Transport Layer Security (TLS).

tlsintermediatecacerts: This folder contains a list intermediate CA certificates CAs trusted by the organization represented by this MSP for secure communications between nodes using TLS. This folder is specifically useful when commercial CAs are used for TLS certificates of an organization. Similar to membership intermediate CAs, specifying intermediate TLS CAs is optional.

operationscerts: This folder contains the certificates required to communicate with the Fabric Operations Service API.

A channel MSP includes the following additional folder:

Revoked Certificates: If the identity of an actor has been revoked, identifying information about the identity — not the identity itself — is held in this folder. For X.509-based identities, these identifiers are pairs of strings known as Subject Key Identifier (SKI) and Authority Access Identifier (AKI), and are checked whenever the certificate is being used to make sure the certificate has not been revoked.
This list is conceptually the same as a CA’s Certificate Revocation List (CRL), but it also relates to revocation of membership from the organization. As a result, the administrator of a channel MSP can quickly revoke an actor or node from an organization by advertising the updated CRL of the CA. This “list of lists” is optional. It will only become populated as certificates are revoked.

If you’ve read this doc as well as our doc on Identity, you
should now have a pretty good grasp of how identities and MSPs work in Hyperledger Fabric.
You’ve seen how a PKI and MSPs are used to identify the actors collaborating in a blockchain
network. You’ve learned how certificates, public/private keys, and roots of trust work,
in addition to how MSPs are physically and logically structured.

Policies¶
Audience: Architects, application and smart contract developers,
administrators
In this topic, we’ll cover:

What is a policy
Why are policies needed
How are policies implemented throughout Fabric
Fabric policy domains
How do you write a policy in Fabric
Fabric chaincode lifecycle
Overriding policy definitions

What is a policy¶
At its most basic level, a policy is a set of rules that define the structure
for how decisions are made and specific outcomes are reached. To that end,
policies typically describe a who and a what, such as the access or
rights that an individual has over an asset. We can see that policies are
used throughout our daily lives to protect assets of value to us, from car
rentals, health, our homes, and many more.
For example, an insurance policy defines the conditions, terms, limits, and
expiration under which an insurance payout will be made. The policy is
agreed to by the policy holder and the insurance company, and defines the rights
and responsibilities of each party.
Whereas an insurance policy is put in place for risk management, in Hyperledger
Fabric, policies are the mechanism for infrastructure management. Fabric policies
represent how members come to agreement on accepting or rejecting changes to the
network, a channel, or a smart contract. Policies are agreed to by the consortium
members when a network is originally configured, but they can also be modified
as the network evolves. For example, they describe the criteria for adding or
removing members from a channel, change how blocks are formed, or specify the
number of organizations required to endorse a smart contract. All of these
actions are described by a policy which defines who can perform the action.
Simply put, everything you want to do on a Fabric network is controlled by a
policy.

Why are policies needed¶
Policies are one of the things that make Hyperledger Fabric different from other
blockchains like Ethereum or Bitcoin. In those systems, transactions can be
generated and validated by any node in the network. The policies that govern the
network are fixed at any point in time and can only be changed using the same
process that governs the code. Because Fabric is a permissioned blockchain whose
users are recognized by the underlying infrastructure, those users have the
ability to decide on the governance of the network before it is launched, and
change the governance of a running network.
Policies allow members to decide which organizations can access or update a Fabric
network, and provide the mechanism to enforce those decisions. Policies contain
the lists of organizations that have access to a given resource, such as a
user or system chaincode. They also specify how many organizations need to agree
on a proposal to update a resource, such as a channel or smart contracts. Once
they are written, policies evaluate the collection of signatures attached to
transactions and proposals and validate if the signatures fulfill the governance
agreed to by the network.

How are policies implemented throughout Fabric¶
Policies are implemented at different levels of a Fabric network. Each policy
domain governs different aspects of how a network operates.
 A visual representation
of the Fabric policy hierarchy.

System channel configuration¶
Every network begins with an ordering system channel. There must be exactly
one ordering system channel for an ordering service, and it is the first channel
to be created. The system channel also contains the organizations who are the
members of the ordering service (ordering organizations) and those that are
on the networks to transact (consortium organizations).
The policies in the ordering system channel configuration blocks govern the
consensus used by the ordering service and define how new blocks are created.
The system channel also governs which members of the consortium are allowed to
create new channels.

Application channel configuration¶
Application channels are used to provide a private communication mechanism
between organizations in the consortium.
The policies in an application channel govern the ability to add or remove
members from the channel. Application channels also govern which organizations
are required to approve a chaincode before the chaincode is defined and
committed to a channel using the Fabric chaincode lifecyle. When an application
channel is initially created, it inherits all the ordering service parameters
from the orderer system channel by default. However, those parameters (and the
policies governing them) can be customized in each channel.

Access control lists (ACLs)¶
Network administrators will be especially interested in the Fabric use of ACLs,
which provide the ability to configure access to resources by associating those
resources with existing policies. These “resources” could be functions on system
chaincode (e.g., “GetBlockByNumber” on the “qscc” system chaincode) or other
resources (e.g.,who can receive Block events). ACLs refer to policies
defined in an application channel configuraton and extends them to control
additional resources. The default set of Fabric ACLs is visible in the
configtx.yaml file under the Application: &ApplicationDefaults section but
they can and should be overridden in a production environment. The list of
resources named in configtx.yaml is the complete set of all internal resources
currently defined by Fabric.
In that file, ACLs are expressed using the following format:
# ACL policy for chaincode to chaincode invocation
peer/ChaincodeToChaincode: /Channel/Application/Readers

Where peer/ChaincodeToChaincode represents the resource being secured and
/Channel/Application/Readers refers to the policy which must be satisfied for
the associated transaction to be considered valid.
For a deeper dive into ACLS, refer to the topic in the Operations Guide on ACLs.

Smart contract endorsement policies¶
Every smart contract inside a chaincode package has an endorsement policy that
specifies how many peers belonging to different channel members need to execute
and validate a transaction against a given smart contract in order for the
transaction to be considered valid. Hence, the endorsement policies define the
organizations (through their peers) who must “endorse” (i.e., approve of) the
execution of a proposal.

Modification policies¶
There is one last type of policy that is crucial to how policies work in Fabric,
the Modification policy. Modification policies specify the group of identities
required to sign (approve) any configuration update. It is the policy that
defines how the policy is updated. Thus, each channel configuration element
includes a reference to a policy which governs its modification.

The Fabric policy domains¶
While Fabric policies are flexible and can be configured to meet the needs of a
network, the policy structure naturally leads to a division between the domains
governed by either the Ordering Service organizations or the members of the
consortium. In the following diagram you can see how the default policies
implement control over the Fabric policy domains below.
 A more detailed look at the
policy domains governed by the Orderer organizations and consortium organizations.
A fully functional Fabric network can feature many organizations with different
responsibilities. The domains provide the ability to extend different privileges
and roles to different organizations by allowing the founders of the ordering
service the ability to establish the initial rules and membership of the
consortium. They also allow the organizations that join the consortium to create
private application channels, govern their own business logic, and restrict
access to the data that is put on the network.
The system channel configuration and a portion of each application channel
configuration provides the ordering organizations control over which organizations
are members of the consortium, how blocks are delivered to channels, and the
consensus mechanism used by the nodes of the ordering service.
The system channel configuration provides members of the consortium the ability
to create channels. Application channels and ACLs are the mechanism that
consortium organizations use to add or remove members from a channel and restrict
access to data and smart contracts on a channel.

How do you write a policy in Fabric¶
If you want to change anything in Fabric, the policy associated with the resource
describes who needs to approve it, either with an explicit sign off from
individuals, or an implicit sign off by a group. In the insurance domain, an
explicit sign off could be a single member of the homeowners insurance agents
group. And an implicit sign off would be analogous to requiring approval from a
majority of the managerial members of the homeowners insurance group. This is
particularly useful because the members of that group can change over time
without requiring that the policy be updated. In Hyperledger Fabric, explicit
sign offs in policies are expressed using the Signature syntax and implicit
sign offs use the ImplicitMeta syntax.

Signature policies¶
Signature policies define specific types of users who must sign in order for a
policy to be satisfied such as Org1.Peer OR Org2.Peer. These policies are
considered the most versatile because they allow for the construction of
extremely specific rules like: “An admin of org A and 2 other admins, or 5 of 6
organization admins”. The syntax supports arbitrary combinations of AND, OR
and NOutOf. For example, a policy can be easily expressed by using AND (Org1, Org2) which means that a signature from at least one member in Org1 AND
one member in Org2 is required for the policy to be satisfied.

ImplicitMeta policies¶
ImplicitMeta policies are only valid in the context of channel configuration
which is based on a tiered hierarchy of policies in a configuration tree. ImplicitMeta
policies aggregate the result of policies deeper in the configuration tree that
are ultimately defined by Signature policies. They are Implicit because they
are constructed implicitly based on the current organizations in the
channel configuration, and they are Meta because their evaluation is not
against specific MSP principals, but rather against other sub-policies below
them in the configuration tree.
The following diagram illustrates the tiered policy structure for an application
channel and shows how the ImplicitMeta channel configuration admins policy,
named /Channel/Admins, is resolved when the sub-policies named Admins below it
in the configuration hierarchy are satisfied where each check mark represents that
the conditions of the sub-policy were satisfied.

As you can see in the diagram above, ImplicitMeta policies, Type = 3, use a
different syntax, "<ANY|ALL|MAJORITY> <SubPolicyName>", for example:
`MAJORITY sub policy: Admins`

The diagram shows a sub-policy Admins, which refers to all the Admins policy
below it in the configuration tree. You can create your own sub-policies
and name them whatever you want and then define them in each of your
organizations.
As mentioned above, a key benefit of an ImplicitMeta policy such as MAJORITY Admins is that when you add a new admin organization to the channel, you do not
have to update the channel policy. Therefore ImplicitMeta policies are
considered to be more flexible as the consortium members change. The consortium
on the orderer can change as new members are added or an existing member leaves
with the consortium members agreeing to the changes, but no policy updates are
required. Recall that ImplicitMeta policies ultimately resolve the
Signature sub-policies underneath them in the configuration tree as the
diagram shows.
You can also define an application level implicit policy to operate across
organizations, in a channel for example, and either require that ANY of them
are satisfied, that ALL are satisfied, or that a MAJORITY are satisfied. This
format lends itself to much better, more natural defaults, so that each
organization can decide what it means for a valid endorsement.
Further granularity and control can be achieved if you include NodeOUs in your
organization definition. Organization Units (OUs) are defined in the Fabric CA
client configuration file and can be associated with an identity when it is
created. In Fabric, NodeOUs provide a way to classify identities in a digital
certificate hierarchy. For instance, an organization having specific NodeOUs
enabled could require that a ‘peer’ sign for it to be a valid endorsement,
whereas an organization without any might simply require that any member can
sign.

An example: channel configuration policy¶
Understanding policies begins with examining the configtx.yaml where the
channel policies are defined. We can use the configtx.yaml file in the Fabric
test network to see examples of both policy syntax types. We are going to examine
the configtx.yaml file used by the fabric-samples/test-network sample.
The first section of the file defines the organizations of the network. Inside each
organization definition are the default policies for that organization, Readers, Writers,
Admins, and Endorsement, although you can name your policies anything you want.
Each policy has a Type which describes how the policy is expressed (Signature
or ImplicitMeta) and a Rule.
The test network example below shows the Org1 organization definition in the system
channel, where the policy Type is Signature and the endorsement policy rule
is defined as "OR('Org1MSP.peer')". This policy specifies that a peer that is
a member of Org1MSP is required to sign. It is these signature policies that
become the sub-policies that the ImplicitMeta policies point to.

Click here to see an example of an organization defined with signature policies

 - &Org1
        # DefaultOrg defines the organization which is used in the sampleconfig
        # of the fabric.git development environment
        Name: Org1MSP

        # ID to load the MSP definition as
        ID: Org1MSP

        MSPDir: crypto-config/peerOrganizations/org1.example.com/msp

        # Policies defines the set of policies at this level of the config tree
        # For organization policies, their canonical path is usually
        #   /Channel/<Application|Orderer>/<OrgName>/<PolicyName>
        Policies:
            Readers:
                Type: Signature
                Rule: "OR('Org1MSP.admin', 'Org1MSP.peer', 'Org1MSP.client')"
            Writers:
                Type: Signature
                Rule: "OR('Org1MSP.admin', 'Org1MSP.client')"
            Admins:
                Type: Signature
                Rule: "OR('Org1MSP.admin')"
            Endorsement:
                Type: Signature
                Rule: "OR('Org1MSP.peer')"

The next example shows the ImplicitMeta policy type used in the Application
section of the configtx.yaml. These set of policies lie on the
/Channel/Application/ path. If you use the default set of Fabric ACLs, these
policies define the behavior of many important features of application channels,
such as who can query the channel ledger, invoke a chaincode, or update a channel
config. These policies point to the sub-policies defined for each organization.
The Org1 defined in the section above contains Reader, Writer, and Admin
sub-policies that are evaluated by the Reader, Writer, and Admin ImplicitMeta
policies in the Application section. Because the test network is built with the
default policies, you can use the example Org1 to query the channel ledger, invoke a
chaincode, and approve channel updates for any test network channel that you
create.

Click here to see an example of ImplicitMeta policies

################################################################################
#
#   SECTION: Application
#
#   - This section defines the values to encode into a config transaction or
#   genesis block for application related parameters
#
################################################################################
Application: &ApplicationDefaults

    # Organizations is the list of orgs which are defined as participants on
    # the application side of the network
    Organizations:

    # Policies defines the set of policies at this level of the config tree
    # For Application policies, their canonical path is
    #   /Channel/Application/<PolicyName>
    Policies:
        Readers:
            Type: ImplicitMeta
            Rule: "ANY Readers"
        Writers:
            Type: ImplicitMeta
            Rule: "ANY Writers"
        Admins:
            Type: ImplicitMeta
            Rule: "MAJORITY Admins"
        LifecycleEndorsement:
            Type: ImplicitMeta
            Rule: "MAJORITY Endorsement"
        Endorsement:
            Type: ImplicitMeta
            Rule: "MAJORITY Endorsement"

Fabric chaincode lifecycle¶
In the Fabric 2.0 release, a new chaincode lifecycle process was introduced,
whereby a more democratic process is used to govern chaincode on the network.
The new process allows multiple organizations to vote on how a chaincode will
be operated before it can be used on a channel. This is significant because it is
the combination of this new lifecycle process and the policies that are
specified during that process that dictate the security across the network. More details on
the flow are available in the Fabric chaincode lifecyle
concept topic, but for purposes of this topic you should understand how policies are
used in this flow. The new flow includes two steps where policies are specified:
when chaincode is approved by organization members, and when it is committed
to the channel.
The Application section of  the configtx.yaml file includes the default
chaincode lifecycle endorsement policy. In a production environment you would
customize this definition for your own use case.
################################################################################
#
#   SECTION: Application
#
#   - This section defines the values to encode into a config transaction or
#   genesis block for application related parameters
#
################################################################################
Application: &ApplicationDefaults

    # Organizations is the list of orgs which are defined as participants on
    # the application side of the network
    Organizations:

    # Policies defines the set of policies at this level of the config tree
    # For Application policies, their canonical path is
    #   /Channel/Application/<PolicyName>
    Policies:
        Readers:
            Type: ImplicitMeta
            Rule: "ANY Readers"
        Writers:
            Type: ImplicitMeta
            Rule: "ANY Writers"
        Admins:
            Type: ImplicitMeta
            Rule: "MAJORITY Admins"
        LifecycleEndorsement:
            Type: ImplicitMeta
            Rule: "MAJORITY Endorsement"
        Endorsement:
            Type: ImplicitMeta
            Rule: "MAJORITY Endorsement"

The LifecycleEndorsement policy governs who needs to approve a chaincode
definition.
The Endorsement policy is the default endorsement policy for
a chaincode. More on this below.

Chaincode endorsement policies¶
The endorsement policy is specified for a chaincode when it is approved
and committed to the channel using the Fabric chaincode lifecycle (that is, one
endorsement policy covers all of the state associated with a chaincode). The
endorsement policy can be specified either by reference to an endorsement policy
defined in the channel configuration or by explicitly specifying a Signature policy.
If an endorsement policy is not explicitly specified during the approval step,
the default Endorsement policy "MAJORITY Endorsement" is used which means
that a majority of the peers belonging to the different channel members
(organizations) need to execute and validate a transaction against the chaincode
in order for the transaction to be considered valid.  This default policy allows
organizations that join the channel to become automatically added to the chaincode
endorsement policy. If you don’t want to use the default endorsement
policy, use the Signature policy format to specify a more complex endorsement
policy (such as requiring that a chaincode be endorsed by one organization, and
then one of the other organizations on the channel).
Signature policies also allow you to include principals which are simply a way
of matching an identity to a role. Principals are just like user IDs or group
IDs, but they are more versatile because they can include a wide range of
properties of an actor’s identity, such as the actor’s organization,
organizational unit, role or even the actor’s specific identity. When we talk
about principals, they are the properties which determine their permissions.
Principals are described as ‘MSP.ROLE’, where MSP represents the required MSP
ID (the organization),  and ROLE represents one of the four accepted roles:
Member, Admin, Client, and Peer. A role is associated to an identity when a user
enrolls with a CA. You can customize the list of roles available on your Fabric
CA.
Some examples of valid principals are:

‘Org0.Admin’: an administrator of the Org0 MSP
‘Org1.Member’: a member of the Org1 MSP
‘Org1.Client’: a client of the Org1 MSP
‘Org1.Peer’: a peer of the Org1 MSP
‘OrdererOrg.Orderer’: an orderer in the OrdererOrg MSP

There are cases where it may be necessary for a particular state
(a particular key-value pair, in other words) to have a different endorsement
policy. This state-based endorsement allows the default chaincode-level
endorsement policies to be overridden by a different policy for the specified
keys.
For a deeper dive on how to write an endorsement policy refer to the topic on
Endorsement policies in the Operations Guide.
Note:  Policies work differently depending on which version of Fabric you are
using:

In Fabric releases prior to 2.0, chaincode endorsement policies can be
updated during chaincode instantiation or by using the chaincode lifecycle
commands. If not specified at instantiation time, the endorsement policy
defaults to “any member of the organizations in the channel”. For example,
a channel with “Org1” and “Org2” would have a default endorsement policy of
“OR(‘Org1.member’, ‘Org2.member’)”.
Starting with Fabric 2.0, Fabric introduced a new chaincode
lifecycle process that allows multiple organizations to agree on how a
chaincode will be operated before it can be used on a channel.  The new process
requires that organizations agree to the parameters that define a chaincode,
such as name, version, and the chaincode endorsement policy.

Overriding policy definitions¶
Hyperledger Fabric includes default policies which are useful for getting started,
developing, and testing your blockchain, but they are meant to be customized
in a production environment. You should be aware of the default policies
in the configtx.yaml file. Channel configuration policies can be extended
with arbitrary verbs, beyond the default Readers, Writers, Admins in
configtx.yaml. The orderer system and application channels are overridden by
issuing a config update when you override the default policies by editing the
configtx.yaml for the orderer system channel or the configtx.yaml for a
specific channel.
See the topic on
Updating a channel configuration
for more information.

Peers¶
A blockchain network is comprised primarily of a set of peer nodes (or, simply, peers).
Peers are a fundamental element of the network because they host ledgers and smart
contracts. Recall that a ledger immutably records all the transactions generated
by smart contracts (which in Hyperledger Fabric are contained in a chaincode,
more on this later). Smart contracts and ledgers are used to encapsulate the
shared processes and shared information in a network, respectively. These
aspects of a peer make them a good starting point to understand a Fabric network.
Other elements of the blockchain network are of course important: ledgers and
smart contracts, orderers, policies, channels, applications, organizations,
identities, and membership, and you can read more about them in their own
dedicated sections. This section focusses on peers, and their relationship to those
other elements in a Fabric network.

A blockchain network is comprised of peer nodes, each of which can hold copies
of ledgers and copies of smart contracts. In this example, the network N
consists of peers P1, P2 and P3, each of which maintain their own instance of
the distributed ledger L1. P1, P2 and P3 use the same chaincode, S1, to access
their copy of that distributed ledger.
Peers can be created, started, stopped, reconfigured, and even deleted. They
expose a set of APIs that enable administrators and applications to interact
with the services that they provide. We’ll learn more about these services in
this section.

A word on terminology¶
Fabric implements smart contracts with a technology concept it calls
chaincode — simply a piece of code that accesses the ledger, written in
one of the supported programming languages. In this topic, we’ll usually use the
term chaincode, but feel free to read it as smart contract if you’re
more used to that term. It’s the same thing! If you want to learn more about
chaincode and smart contracts, check out our documentation on smart contracts
and chaincode.

Ledgers and Chaincode¶
Let’s look at a peer in a little more detail. We can see that it’s the peer that
hosts both the ledger and chaincode. More accurately, the peer actually hosts
instances of the ledger, and instances of chaincode. Note that this provides
a deliberate redundancy in a Fabric network — it avoids single points of
failure. We’ll learn more about the distributed and decentralized nature of a
blockchain network later in this section.

A peer hosts instances of ledgers and instances of chaincodes. In this example,
P1 hosts an instance of ledger L1 and an instance of chaincode S1. There
can be many ledgers and chaincodes hosted on an individual peer.
Because a peer is a host for ledgers and chaincodes, applications and
administrators must interact with a peer if they want to access these resources.
That’s why peers are considered the most fundamental building blocks of a
Fabric network. When a peer is first created, it has neither ledgers nor
chaincodes. We’ll see later how ledgers get created, and how chaincodes get
installed, on peers.

Multiple Ledgers¶
A peer is able to host more than one ledger, which is helpful because it allows
for a flexible system design. The simplest configuration is for a peer to manage a
single ledger, but it’s absolutely appropriate for a peer to host two or more
ledgers when required.

A peer hosting multiple ledgers. Peers host one or more ledgers, and each
ledger has zero or more chaincodes that apply to them. In this example, we
can see that the peer P1 hosts ledgers L1 and L2. Ledger L1 is accessed using
chaincode S1. Ledger L2 on the other hand can be accessed using chaincodes S1 and S2.
Although it is perfectly possible for a peer to host a ledger instance without
hosting any chaincodes which access that ledger, it’s rare that peers are configured
this way. The vast majority of peers will have at least one chaincode installed
on it which can query or update the peer’s ledger instances. It’s worth
mentioning in passing that, whether or not users have installed chaincodes for use by
external applications, peers also have special system chaincodes that are
always present. These are not discussed in detail in this topic.

Multiple Chaincodes¶
There isn’t a fixed relationship between the number of ledgers a peer has and
the number of chaincodes that can access that ledger. A peer might have
many chaincodes and many ledgers available to it.

An example of a peer hosting multiple chaincodes. Each ledger can have
many chaincodes which access it. In this example, we can see that peer P1
hosts ledgers L1 and L2, where L1 is accessed by chaincodes S1 and S2, and
L2 is accessed by S1 and S3. We can see that S1 can access both L1 and L2.
We’ll see a little later why the concept of channels in Fabric is important
when hosting multiple ledgers or multiple chaincodes on a peer.

Applications and Peers¶
We’re now going to show how applications interact with peers to access the
ledger. Ledger-query interactions involve a simple three-step dialogue between
an application and a peer; ledger-update interactions are a little more
involved, and require two extra steps. We’ve simplified these steps a little to
help you get started with Fabric, but don’t worry — what’s most important to
understand is the difference in application-peer interactions for ledger-query
compared to ledger-update transaction styles.
Applications always connect to peers when they need to access ledgers and
chaincodes. The Fabric Software Development Kit (SDK) makes this
easy for programmers — its APIs enable applications to connect to peers, invoke
chaincodes to generate transactions, submit transactions to the network that
will get ordered, validated and committed to the distributed ledger, and receive
events when this process is complete.
Through a peer connection, applications can execute chaincodes to query or
update a ledger. The result of a ledger query transaction is returned
immediately, whereas ledger updates involve a more complex interaction between
applications, peers and orderers. Let’s investigate this in a little more detail.

Peers, in conjunction with orderers, ensure that the ledger is kept up-to-date
on every peer. In this example, application A connects to P1 and invokes
chaincode S1 to query or update the ledger L1. P1 invokes S1 to generate a
proposal response that contains a query result or a proposed ledger update.
Application A receives the proposal response and, for queries,
the process is now complete. For updates, A builds a transaction
from all of the responses, which it sends to O1 for ordering. O1 collects
transactions from across the network into blocks, and distributes these to all
peers, including P1. P1 validates the transaction before committing to L1. Once L1
is updated, P1 generates an event, received by A, to signify completion.
A peer can return the results of a query to an application immediately since
all of the information required to satisfy the query is in the peer’s local copy of
the ledger. Peers never consult with other peers in order to respond to a query from
an application. Applications can, however, connect to one or more peers to issue
a query; for example, to corroborate a result between multiple peers, or
retrieve a more up-to-date result from a different peer if there’s a suspicion
that information might be out of date. In the diagram, you can see that ledger
query is a simple three-step process.
An update transaction starts in the same way as a query transaction, but has two
extra steps. Although ledger-updating applications also connect to peers to
invoke a chaincode, unlike with ledger-querying applications, an individual peer
cannot perform a ledger update at this time, because other peers must first
agree to the change — a process called consensus. Therefore, peers return
to the application a proposed update — one that this peer would apply
subject to other peers’ prior agreement. The first extra step — step four —
requires that applications send an appropriate set of matching proposed updates
to the entire network of peers as a transaction for commitment to their
respective ledgers. This is achieved by the application by using an orderer to
package transactions into blocks, and distributing them to the entire network of
peers, where they can be verified before being applied to each peer’s local copy
of the ledger. As this whole ordering processing takes some time to complete
(seconds), the application is notified asynchronously, as shown in step five.
Later in this section, you’ll learn more about the detailed nature of this
ordering process — and for a really detailed look at this process see the
Transaction Flow topic.

Peers and Channels¶
Although this section is about peers rather than channels, it’s worth spending a
little time understanding how peers interact with each other, and with applications,
via channels — a mechanism by which a set of components within a blockchain
network can communicate and transact privately.
These components are typically peer nodes, orderer nodes and applications and,
by joining a channel, they agree to collaborate to collectively share and
manage identical copies of the ledger associated with that channel. Conceptually, you can
think of channels as being similar to groups of friends (though the members of a
channel certainly don’t need to be friends!). A person might have several groups
of friends, with each group having activities they do together. These groups
might be totally separate (a group of work friends as compared to a group of
hobby friends), or there can be some crossover between them. Nevertheless, each group
is its own entity, with “rules” of a kind.

Channels allow a specific set of peers and applications to communicate with
each other within a blockchain network. In this example, application A can
communicate directly with peers P1 and P2 using channel C. You can think of the
channel as a pathway for communications between particular applications and
peers. (For simplicity, orderers are not shown in this diagram, but must be
present in a functioning network.)
We see that channels don’t exist in the same way that peers do — it’s more
appropriate to think of a channel as a logical structure that is formed by a
collection of physical peers. It is vital to understand this point — peers
provide the control point for access to, and management of, channels.

Peers and Organizations¶
Now that you understand peers and their relationship to ledgers, chaincodes
and channels, you’ll be able to see how multiple organizations come together to
form a blockchain network.
Blockchain networks are administered by a collection of organizations rather
than a single organization. Peers are central to how this kind of distributed
network is built because they are owned by — and are the connection points to
the network for — these organizations.

Peers in a blockchain network with multiple organizations. The blockchain
network is built up from the peers owned and contributed by the different
organizations. In this example, we see four organizations contributing eight
peers to form a network. The channel C connects five of these peers in the
network N — P1, P3, P5, P7 and P8. The other peers owned by these
organizations have not been joined to this channel, but are typically joined to
at least one other channel. Applications that have been developed by a
particular organization will connect to their own organization’s peers as well
as those of different organizations. Again,
for simplicity, an orderer node is not shown in this diagram.
It’s really important that you can see what’s happening in the formation of a
blockchain network. The network is both formed and managed by the multiple
organizations who contribute resources to it. Peers are the resources that
we’re discussing in this topic, but the resources an organization provides are
more than just peers. There’s a principle at work here — the network literally
does not exist without organizations contributing their individual resources to
the collective network. Moreover, the network grows and shrinks with the
resources that are provided by these collaborating organizations.
You can see that (other than the ordering service) there are no centralized
resources — in the example above, the network, N, would not exist
if the organizations did not contribute their peers. This reflects the fact that
the network does not exist in any meaningful sense unless and until
organizations contribute the resources that form it. Moreover, the network does
not depend on any individual organization — it will continue to exist as long
as one organization remains, no matter which other organizations may come and
go. This is at the heart of what it means for a network to be decentralized.
Applications in different organizations, as in the example above, may
or may not be the same. That’s because it’s entirely up to an organization as to how
its applications process their peers’ copies of the ledger. This means that both
application and presentation logic may vary from organization to organization
even though their respective peers host exactly the same ledger data.
Applications connect either to peers in their organization, or peers in another
organization, depending on the nature of the ledger interaction that’s required.
For ledger-query interactions, applications typically connect to their own
organization’s peers. For ledger-update interactions, we’ll see later why
applications need to connect to peers representing every organization that is
required to endorse the ledger update.

Peers and Identity¶
Now that you’ve seen how peers from different organizations come together to
form a blockchain network, it’s worth spending a few moments understanding how
peers get assigned to organizations by their administrators.
Peers have an identity assigned to them via a digital certificate from a
particular certificate authority. You can read lots more about how X.509
digital certificates work elsewhere in this guide but, for now, think of a
digital certificate as being like an ID card that provides lots of verifiable
information about a peer. Each and every peer in the network is assigned a
digital certificate by an administrator from its owning organization.

When a peer connects to a channel, its digital certificate identifies its
owning organization via a channel MSP. In this example, P1 and P2 have
identities issued by CA1. Channel C determines from a policy in its channel
configuration that identities from CA1 should be associated with Org1 using
ORG1.MSP. Similarly, P3 and P4 are identified by ORG2.MSP as being part of
Org2.
Whenever a peer connects using a channel to a blockchain network, a policy in
the channel configuration uses the peer’s identity to determine its
rights. The mapping of identity to organization is provided by a component
called a Membership Service Provider (MSP) — it determines how a peer gets
assigned to a specific role in a particular organization and accordingly gains
appropriate access to blockchain resources. Moreover, a peer can be owned only
by a single organization, and is therefore associated with a single MSP. We’ll
learn more about peer access control later in this section, and there’s an entire
section on MSPs and access control policies elsewhere in this guide. But for now,
think of an MSP as providing linkage between an individual identity and a
particular organizational role in a blockchain network.
To digress for a moment, peers as well as everything that interacts with a
blockchain network acquire their organizational identity from their digital
certificate and an MSP. Peers, applications, end users, administrators and
orderers must have an identity and an associated MSP if they want to interact
with a blockchain network. We give a name to every entity that interacts with
a blockchain network using an identity — a principal. You can learn lots
more about principals and organizations elsewhere in this guide, but for now
you know more than enough to continue your understanding of peers!
Finally, note that it’s not really important where the peer is physically
located — it could reside in the cloud, or in a data centre owned by one
of the organizations, or on a local machine — it’s the digital certificate
associated with it that identifies it as being owned by a particular organization.
In our example above, P3 could be hosted in Org1’s data center, but as long as the
digital certificate associated with it is issued by CA2, then it’s owned by
Org2.

Peers and Orderers¶
We’ve seen that peers form the basis for a blockchain network, hosting ledgers
and smart contracts which can be queried and updated by peer-connected applications.
However, the mechanism by which applications and peers interact with each other
to ensure that every peer’s ledger is kept consistent with each other is mediated
by special nodes called orderers, and it’s to these nodes we now turn our
attention.
An update transaction is quite different from a query transaction because a single
peer cannot, on its own, update the ledger — updating requires the consent of other
peers in the network. A peer requires other peers in the network to approve a
ledger update before it can be applied to a peer’s local ledger. This process is
called consensus, which takes much longer to complete than a simple query. But when
all the peers required to approve the transaction    do so, and the transaction is
committed to the ledger, peers will notify their connected applications that the
ledger has been updated. You’re about to be shown a lot more detail about how
peers and orderers manage the consensus process in this section.
Specifically, applications that want to update the ledger are involved in a
3-phase process, which ensures that all the peers in a blockchain network keep
their ledgers consistent with each other.

In the first phase, applications work with a subset of endorsing peers, each of
which provide an endorsement of the proposed ledger update to the application,
but do not apply the proposed update to their copy of the ledger.
In the second phase, these separate endorsements are collected together
as transactions and packaged into blocks.
In the third and final phase, these blocks are distributed back to every peer where
each transaction is validated before being committed to that peer’s copy of the ledger.

As you will see, orderer nodes are central to this process, so let’s
investigate in a little more detail how applications and peers use orderers to
generate ledger updates that can be consistently applied to a distributed,
replicated ledger.

Phase 1: Proposal¶
Phase 1 of the transaction workflow involves an interaction between an
application and a set of peers — it does not involve orderers. Phase 1 is only
concerned with an application asking different organizations’ endorsing peers to
agree to the results of the proposed chaincode invocation.
To start phase 1, applications generate a transaction proposal which they send
to each of the required set of peers for endorsement. Each of these endorsing peers then
independently executes a chaincode using the transaction proposal to
generate a transaction proposal response. It does not apply this update to the
ledger, but rather simply signs it and returns it to the application. Once the
application has received a sufficient number of signed proposal responses,
the first phase of the transaction flow is complete. Let’s examine this phase in
a little more detail.

Transaction proposals are independently executed by peers who return endorsed
proposal responses. In this example, application A1 generates transaction T1
proposal P which it sends to both peer P1 and peer P2 on channel C. P1 executes
S1 using transaction T1 proposal P generating transaction T1 response R1 which
it endorses with E1. Independently, P2 executes S1 using transaction T1
proposal P generating transaction T1 response R2 which it endorses with E2.
Application A1 receives two endorsed responses for transaction T1, namely E1
and E2.
Initially, a set of peers are chosen by the application to generate a set of
proposed ledger updates. Which peers are chosen by the application? Well, that
depends on the endorsement policy (defined for a chaincode), which defines
the set of organizations that need to endorse a proposed ledger change before it
can be accepted by the network. This is literally what it means to achieve
consensus — every organization who matters must have endorsed the proposed
ledger change before it will be accepted onto any peer’s ledger.
A peer endorses a proposal response by adding its digital signature, and signing
the entire payload using its private key. This endorsement can be subsequently
used to prove that this organization’s peer generated a particular response. In
our example, if peer P1 is owned by organization Org1, endorsement E1
corresponds to a digital proof that “Transaction T1 response R1 on ledger L1 has
been provided by Org1’s peer P1!”.
Phase 1 ends when the application receives signed proposal responses from
sufficient peers. We note that different peers can return different and
therefore inconsistent transaction responses to the application for the same
transaction proposal. It might simply be that the result was generated at
different times on different peers with ledgers at different states, in which
case an application can simply request a more up-to-date proposal response. Less
likely, but much more seriously, results might be different because the chaincode
is non-deterministic. Non-determinism is the enemy of chaincodes
and ledgers and if it occurs it indicates a serious problem with the proposed
transaction, as inconsistent results cannot, obviously, be applied to ledgers.
An individual peer cannot know that their transaction result is
non-deterministic — transaction responses must be gathered together for
comparison before non-determinism can be detected. (Strictly speaking, even this
is not enough, but we defer this discussion to the transaction section, where
non-determinism is discussed in detail.)
At the end of phase 1, the application is free to discard inconsistent
transaction responses if it wishes to do so, effectively terminating the
transaction workflow early. We’ll see later that if an application tries to use
an inconsistent set of transaction responses to update the ledger, it will be
rejected.

Phase 2: Ordering and packaging transactions into blocks¶
The second phase of the transaction workflow is the packaging phase. The orderer
is pivotal to this process — it receives transactions containing endorsed
transaction proposal responses from many applications, and orders the
transactions into blocks. For more details about the
ordering and packaging phase, check out our
conceptual information about the ordering phase.

Phase 3: Validation and commit¶
At the end of phase 2, we see that orderers have been responsible for the simple
but vital processes of collecting proposed transaction updates, ordering them,
and packaging them into blocks, ready for distribution to the peers.
The final phase of the transaction workflow involves the distribution and
subsequent validation of blocks from the orderer to the peers, where they can be
committed to the ledger. Specifically, at each peer, every transaction within a
block is validated to ensure that it has been consistently endorsed by all
relevant organizations before it is committed to the ledger. Failed transactions
are retained for audit, but are not committed to the ledger.

The second role of an orderer node is to distribute blocks to peers. In this
example, orderer O1 distributes block B2 to peer P1 and peer P2. Peer P1
processes block B2, resulting in a new block being added to ledger L1 on P1.
In parallel, peer P2 processes block B2, resulting in a new block being added
to ledger L1 on P2. Once this process is complete, the ledger L1 has been
consistently updated on peers P1 and P2, and each may inform connected
applications that the transaction has been processed.
Phase 3 begins with the orderer distributing blocks to all peers connected to
it. Peers are connected to orderers on channels such that when a new block is
generated, all of the peers connected to the orderer will be sent a copy of the
new block. Each peer will process this block independently, but in exactly the
same way as every other peer on the channel. In this way, we’ll see that the
ledger can be kept consistent. It’s also worth noting that not every peer needs
to be connected to an orderer — peers can cascade blocks to other peers using
the gossip protocol, who also can process them independently. But let’s
leave that discussion to another time!
Upon receipt of a block, a peer will process each transaction in the sequence in
which it appears in the block. For every transaction, each peer will verify that
the transaction has been endorsed by the required organizations according to the
endorsement policy of the chaincode which generated the transaction. For
example, some transactions may only need to be endorsed by a single
organization, whereas others may require multiple endorsements before they are
considered valid. This process of validation verifies that all relevant
organizations have generated the same outcome or result. Also note that this
validation is different than the endorsement check in phase 1, where it is the
application that receives the response from endorsing peers and makes the
decision to send the proposal transactions. In case the application violates
the endorsement policy by sending wrong transactions, the peer is still able to
reject the transaction in the validation process of phase 3.
If a transaction has been endorsed correctly, the peer will attempt to apply it
to the ledger. To do this, a peer must perform a ledger consistency check to
verify that the current state of the ledger is compatible with the state of the
ledger when the proposed update was generated. This may not always be possible,
even when the transaction has been fully endorsed. For example, another
transaction may have updated the same asset in the ledger such that the
transaction update is no longer valid and therefore can no longer be applied. In
this way, the ledger is kept consistent across each peer in the channel because
they each follow the same rules for validation.
After a peer has successfully validated each individual transaction, it updates
the ledger. Failed transactions are not applied to the ledger, but they are
retained for audit purposes, as are successful transactions. This means that
peer blocks are almost exactly the same as the blocks received from the orderer,
except for a valid or invalid indicator on each transaction in the block.
We also note that phase 3 does not require the running of chaincodes — this is
done only during phase 1, and that’s important. It means that chaincodes only have
to be available on endorsing nodes, rather than throughout the blockchain
network. This is often helpful as it keeps the logic of the chaincode
confidential to endorsing organizations. This is in contrast to the output of
the chaincodes (the transaction proposal responses) which are shared with every
peer in the channel, whether or not they endorsed the transaction. This
specialization of endorsing peers is designed to help scalability and confidentiality.
Finally, every time a block is committed to a peer’s ledger, that peer
generates an appropriate event. Block events include the full block content,
while block transaction events include summary information only, such as
whether each transaction in the block has been validated or invalidated.
Chaincode events that the chaincode execution has produced can also be
published at this time. Applications can register for these event types so
that they can be notified when they occur. These notifications conclude the
third and final phase of the transaction workflow.
In summary, phase 3 sees the blocks which are generated by the orderer
consistently applied to the ledger. The strict ordering of transactions into
blocks allows each peer to validate that transaction updates are consistently
applied across the blockchain network.

Orderers and Consensus¶
This entire transaction workflow process is called consensus because all peers
have reached agreement on the order and content of transactions, in a process
that is mediated by orderers. Consensus is a multi-step process and applications
are only notified of ledger updates when the process is complete — which may
happen at slightly different times on different peers.
We will discuss orderers in a lot more detail in a future orderer topic, but for
now, think of orderers as nodes which collect and distribute proposed ledger
updates from applications for peers to validate and include on the ledger.
That’s it! We’ve now finished our tour of peers and the other components that
they relate to in Fabric. We’ve seen that peers are in many ways the
most fundamental element — they form the network, host chaincodes and the
ledger, handle transaction proposals and responses, and keep the ledger
up-to-date by consistently applying transaction updates to it.

Ledger¶
Audience: Architects, Application and smart contract developers,
administrators
A ledger is a key concept in Hyperledger Fabric; it stores important factual
information about business objects; both the current value of the attributes of
the objects, and the history of transactions that resulted in these current
values.
In this topic, we’re going to cover:

What is a Ledger?
Storing facts about business objects
A blockchain ledger
The world state
The blockchain data structure
How blocks are stored in a blockchain
Transactions
World state database options
The Fabcar example ledger
Ledgers and namespaces
Ledgers and channels

What is a Ledger?¶
A ledger contains the current state of a business as a journal of transactions.
The earliest European and Chinese ledgers date from almost 1000 years ago, and
the Sumerians had stone
ledgers
4000 years ago – but let’s start with a more up-to-date example!
You’re probably used to looking at your bank account. What’s most important to
you is the available balance – it’s what you’re able to spend at the current
moment in time. If you want to see how your balance was derived, then you can
look through the transaction credits and debits that determined it. This is a
real life example of a ledger – a state (your bank balance), and a set of
ordered transactions (credits and debits) that determine it. Hyperledger Fabric
is motivated by these same two concerns – to present the current value of a set
of ledger states, and to capture the history of the transactions that determined
these states.

Ledgers, Facts, and States¶
A ledger doesn’t literally store business objects – instead it stores facts
about those objects. When we say “we store a business object in a ledger” what
we really mean is that we’re recording the facts about the current state of an
object, and the facts about the history of transactions that led to the current
state. In an increasingly digital world, it can feel like we’re looking at an
object, rather than facts about an object. In the case of a digital object, it’s
likely that it lives in an external datastore; the facts we store in the ledger
allow us to identify its location along with other key information about it.
While the facts about the current state of a business object may change, the
history of facts about it is immutable, it can be added to, but it cannot be
retrospectively changed. We’re going to see how thinking of a blockchain as an
immutable history of facts about business objects is a simple yet powerful way
to understand it.
Let’s now take a closer look at the Hyperledger Fabric ledger structure!

The Ledger¶
In Hyperledger Fabric, a ledger consists of two distinct, though related, parts
– a world state and a blockchain. Each of these represents a set of facts about
a set of business objects.
Firstly, there’s a world state – a database that holds current values
of a set of ledger states. The world state makes it easy for a program to directly
access the current value of a state rather than having to calculate it by traversing
the entire transaction log. Ledger states are, by default, expressed as key-value pairs,
and we’ll see later how Hyperledger Fabric provides flexibility in this regard.
The world state can change frequently, as states can be created, updated and deleted.
Secondly, there’s a blockchain – a transaction log that records all the
changes that have resulted in the current the world state. Transactions are
collected inside blocks that are appended to the blockchain – enabling you to
understand the history of changes that have resulted in the current world state.
The blockchain data structure is very different to the world state because once
written, it cannot be modified; it is immutable.
 A Ledger L comprises blockchain B and
world state W, where blockchain B determines world state W. We can also say that
world state W is derived from blockchain B.
It’s helpful to think of there being one logical ledger in a Hyperledger
Fabric network. In reality, the network maintains multiple copies of a ledger –
which are kept consistent with every other copy through a process called
consensus. The term Distributed Ledger Technology (DLT) is often
associated with this kind of ledger – one that is logically singular, but has
many consistent copies distributed throughout a network.
Let’s now examine the world state and blockchain data structures in more detail.

World State¶
The world state holds the current value of the attributes of a business object
as a unique ledger state. That’s useful because programs usually require the
current value of an object; it would be cumbersome to traverse the entire
blockchain to calculate an object’s current value – you just get it directly
from the world state.
 A ledger world state containing
two states. The first state is: key=CAR1 and value=Audi. The second state has a
more complex value: key=CAR2 and value={model:BMW, color=red, owner=Jane}. Both
states are at version 0.
A ledger state records a set of facts about a particular business object. Our
example shows ledger states for two cars, CAR1 and CAR2, each having a key and a
value. An application program can invoke a smart contract which uses simple
ledger APIs to get, put and delete states. Notice how a state value
can be simple (Audi…) or compound (type:BMW…). The world state is often
queried to retrieve objects with certain attributes, for example to find all red
BMWs.
The world state is implemented as a database. This makes a lot of sense because
a database provides a rich set of operators for the efficient storage and
retrieval of states.  We’ll see later that Hyperledger Fabric can be configured
to use different world state databases to address the needs of different types
of state values and the access patterns required by applications, for example in
complex queries.
Applications submit transactions which capture changes to the world state, and
these transactions end up being committed to the ledger blockchain. Applications
are insulated from the details of this consensus mechanism by
the Hyperledger Fabric SDK; they merely invoke a smart contract, and are
notified when the transaction has been included in the blockchain (whether valid
or invalid). The key design point is that only transactions that are signed
by the required set of endorsing organizations will result in an update to
the world state. If a transaction is not signed by sufficient endorsers, it will
not result in a change of world state. You can read more about how applications
use smart contracts, and how to develop
applications.
You’ll also notice that a state has a version number, and in the diagram above,
states CAR1 and CAR2 are at their starting versions, 0. The version number is for
internal use by Hyperledger Fabric, and is incremented every time the state
changes. The version is checked whenever the state is updated to make sure the
current states matches the version at the time of endorsement. This ensures that
the world state is changing as expected; that there has not been a concurrent
update.
Finally, when a ledger is first created, the world state is empty. Because any
transaction which represents a valid change to world state is recorded on the
blockchain, it means that the world state can be re-generated from the
blockchain at any time. This can be very convenient – for example, the world
state is automatically generated when a peer is created. Moreover, if a peer
fails abnormally, the world state can be regenerated on peer restart, before
transactions are accepted.

Blockchain¶
Let’s now turn our attention from the world state to the blockchain. Whereas the
world state contains a set of facts relating to the current state of a set of
business objects, the blockchain is an historical record of the facts about how
these objects arrived at their current states. The blockchain has recorded every
previous version of each ledger state and how it has been changed.
The blockchain is structured as sequential log of interlinked blocks, where each
block contains a sequence of transactions, each transaction representing a query
or update to the world state. The exact mechanism by which transactions are
ordered is discussed elsewhere;
what’s important is that block sequencing, as well as transaction sequencing
within blocks, is established when blocks are first created by a Hyperledger
Fabric component called the ordering service.
Each block’s header includes a hash of the block’s transactions, as well a hash
of the prior block’s header. In this way, all transactions on the ledger are sequenced
and cryptographically linked together. This hashing and linking makes the ledger data
very secure. Even if one node hosting the ledger was tampered with, it would not be able to
convince all the other nodes that it has the ‘correct’ blockchain because the ledger is
distributed throughout a network of independent nodes.
The blockchain is always implemented as a file, in contrast to the world state,
which uses a database. This is a sensible design choice as the blockchain data
structure is heavily biased towards a very small set of simple operations.
Appending to the end of the blockchain is the primary operation, and query is
currently a relatively infrequent operation.
Let’s have a look at the structure of a blockchain in a little more detail.
 A blockchain B containing blocks
B0, B1, B2, B3. B0 is the first block in the blockchain, the genesis block.
In the above diagram, we can see that block B2 has a block data D2 which
contains all its transactions: T5, T6, T7.
Most importantly, B2 has a block header H2, which contains a cryptographic
hash of all the transactions in D2 as well as a hash of H1. In this way,
blocks are inextricably and immutably linked to each other, which the term blockchain
so neatly captures!
Finally, as you can see in the diagram, the first block in the blockchain is
called the genesis block.  It’s the starting point for the ledger, though it
does not contain any user transactions. Instead, it contains a configuration
transaction containing the initial state of the network channel (not shown). We
discuss the genesis block in more detail when we discuss the blockchain network
and channels in the documentation.

Blocks¶
Let’s have a closer look at the structure of a block. It consists of three
sections

Block Header
This section comprises three fields, written when a block is created.

Block number: An integer starting at 0 (the genesis block), and
increased by 1 for every new block appended to the blockchain.
Current Block Hash: The hash of all the transactions contained in the
current block.
Previous Block Header Hash: The hash from the previous block header.

These fields are internally derived by cryptographically hashing the block
data. They ensure that each and every block is inextricably linked to its
neighbour, leading to an immutable ledger.
 Block header details. The header H2
of block B2 consists of block number 2, the hash CH2 of the current block data
D2, and the hash of the prior block header H1.

Block Data
This section contains a list of transactions arranged in order. It is written
when the block is created by the ordering service. These transactions have a
rich but straightforward structure, which we describe later
in this topic.

Block Metadata
This section contains the certificate and signature of the block creator which is used to verify
the block by network nodes.
Subsequently, the block committer adds a valid/invalid indicator for every transaction into
a bitmap that also resides in the block metadata, as well as a hash of the cumulative state updates
up until and including that block, in order to detect a state fork.
Unlike the block data  and header fields, this section is not an input to the block hash computation.

Transactions¶
As we’ve seen, a transaction captures changes to the world state. Let’s have a
look at the detailed blockdata structure which contains the transactions in
a block.
 Transaction details. Transaction
T4 in blockdata D1 of block B1 consists of transaction header, H4, a transaction
signature, S4, a transaction proposal P4, a transaction response, R4, and a list
of endorsements, E4.
In the above example, we can see the following fields:

Header
This section, illustrated by H4, captures some essential metadata about the
transaction – for example, the name of the relevant chaincode, and its
version.

Signature
This section, illustrated by S4, contains a cryptographic signature, created
by the client application. This field is used to check that the transaction
details have not been tampered with, as it requires the application’s private
key to generate it.

Proposal
This field, illustrated by P4, encodes the input parameters supplied by an
application to the smart contract which creates the proposed ledger update.
When the smart contract runs, this proposal provides a set of input
parameters, which, in combination with the current world state, determines the
new world state.

Response
This section, illustrated by R4, captures the before and after values of the
world state, as a Read Write set (RW-set). It’s the output of a smart
contract, and if the transaction is successfully validated, it will be applied
to the ledger to update the world state.

Endorsements
As shown in E4, this is a list of signed transaction responses from each
required organization sufficient to satisfy the endorsement policy. You’ll
notice that, whereas only one transaction response is included in the
transaction, there are multiple endorsements. That’s because each endorsement
effectively encodes its organization’s particular transaction response –
meaning that there’s no need to include any transaction response that doesn’t
match sufficient endorsements as it will be rejected as invalid, and not
update the world state.

That concludes the major fields of the transaction – there are others, but
these are the essential ones that you need to understand to have a solid
understanding of the ledger data structure.

World State database options¶
The world state is physically implemented as a database, to provide simple and
efficient storage and retrieval of ledger states. As we’ve seen, ledger states
can have simple or compound values, and to accommodate this, the world state
database implementation can vary, allowing these values to be efficiently
implemented. Options for the world state database currently include LevelDB and
CouchDB.
LevelDB is the default and is particularly appropriate when ledger states are
simple key-value pairs. A LevelDB database is co-located with the peer
node – it is embedded within the same operating system process.
CouchDB is a particularly appropriate choice when ledger states are structured
as JSON documents because CouchDB supports the rich queries and update of richer
data types often found in business transactions. Implementation-wise, CouchDB
runs in a separate operating system process, but there is still a 1:1 relation
between a peer node and a CouchDB instance. All of this is invisible to a smart
contract. See CouchDB as the StateDatabase
for more information on CouchDB.
In LevelDB and CouchDB, we see an important aspect of Hyperledger Fabric – it
is pluggable. The world state database could be a relational data store, or a
graph store, or a temporal database.  This provides great flexibility in the
types of ledger states that can be efficiently accessed, allowing Hyperledger
Fabric to address many different types of problems.

Example Ledger: fabcar¶
As we end this topic on the ledger, let’s have a look at a sample ledger. If
you’ve run the fabcar sample application, then you’ve
created this ledger.
The fabcar sample app creates a set of 10 cars each with a unique identity; a
different color, make, model and owner. Here’s what the ledger looks like after
the first four cars have been created.
 The ledger, L, comprises a world
state, W and a blockchain, B. W contains four states with keys: CAR0, CAR1, CAR2
and CAR3. B contains two blocks, 0 and 1. Block 1 contains four transactions:
T1, T2, T3, T4.
We can see that the world state contains states that correspond to CAR0, CAR1,
CAR2 and CAR3. CAR0 has a value which indicates that it is a blue Toyota Prius,
currently owned by Tomoko, and we can see similar states and values for the
other cars. Moreover, we can see that all car states are at version number 0,
indicating that this is their starting version number – they have not been
updated since they were created.
We can also see that the blockchain contains two blocks.  Block 0 is the genesis
block, though it does not contain any transactions that relate to cars. Block 1
however, contains transactions T1, T2, T3, T4 and these correspond to
transactions that created the initial states for CAR0 to CAR3 in the world
state. We can see that block 1 is linked to block 0.
We have not shown the other fields in the blocks or transactions, specifically
headers and hashes.  If you’re interested in the precise details of these, you
will find a dedicated reference topic elsewhere in the documentation. It gives
you a fully worked example of an entire block with its transactions in glorious
detail – but for now, you have achieved a solid conceptual understanding of a
Hyperledger Fabric ledger. Well done!

Namespaces¶
Even though we have presented the ledger as though it were a single world state
and single blockchain, that’s a little bit of an over-simplification. In
reality, each chaincode has its own world state that is separate from all other
chaincodes. World states are in a namespace so that only smart contracts within
the same chaincode can access a given namespace.
A blockchain is not namespaced. It contains transactions from many different
smart contract namespaces. You can read more about chaincode namespaces in this
topic.
Let’s now look at how the concept of a namespace is applied within a Hyperledger
Fabric channel.

Channels¶
In Hyperledger Fabric, each channel has a completely
separate ledger. This means a completely separate blockchain, and completely
separate world states, including namespaces. It is possible for applications and
smart contracts to communicate between channels so that ledger information can
be accessed between them.
You can read more about how ledgers work with channels in this
topic.

More information¶
See the Transaction Flow,
Read-Write set semantics and
CouchDB as the StateDatabase topics for a
deeper dive on transaction flow, concurrency control, and the world state
database.

The Ordering Service¶
Audience: Architects, ordering service admins, channel creators
This topic serves as a conceptual introduction to the concept of ordering, how
orderers interact with peers, the role they play in a transaction flow, and an
overview of the currently available implementations of the ordering service,
with a particular focus on the recommended Raft ordering service implementation.

What is ordering?¶
Many distributed blockchains, such as Ethereum and Bitcoin, are not permissioned,
which means that any node can participate in the consensus process, wherein
transactions are ordered and bundled into blocks. Because of this fact, these
systems rely on probabilistic consensus algorithms which eventually
guarantee ledger consistency to a high degree of probability, but which are
still vulnerable to divergent ledgers (also known as a ledger “fork”), where
different participants in the network have a different view of the accepted
order of transactions.
Hyperledger Fabric works differently. It features a node called an
orderer (it’s also known as an “ordering node”) that does this transaction
ordering, which along with other orderer nodes forms an ordering service.
Because Fabric’s design relies on deterministic consensus algorithms, any block
validated by the peer is guaranteed to be final and correct. Ledgers cannot fork
the way they do in many other distributed and permissionless blockchain networks.
In addition to promoting finality, separating the endorsement of chaincode
execution (which happens at the peers) from ordering gives Fabric advantages
in performance and scalability, eliminating bottlenecks which can occur when
execution and ordering are performed by the same nodes.

Orderer nodes and channel configuration¶
In addition to their ordering role, orderers also maintain the list of
organizations that are allowed to create channels. This list of organizations is
known as the “consortium”, and the list itself is kept in the configuration of
the “orderer system channel” (also known as the “ordering system channel”). By
default, this list, and the channel it lives on, can only be edited by the
orderer admin. Note that it is possible for an ordering service to hold several
of these lists, which makes the consortium a vehicle for Fabric multi-tenancy.
Orderers also enforce basic access control for channels, restricting who can
read and write data to them, and who can configure them. Remember that who
is authorized to modify a configuration element in a channel is subject to the
policies that the relevant administrators set when they created the consortium
or the channel. Configuration transactions are processed by the orderer,
as it needs to know the current set of policies to execute its basic
form of access control. In this case, the orderer processes the
configuration update to make sure that the requestor has the proper
administrative rights. If so, the orderer validates the update request against
the existing configuration, generates a new configuration transaction,
and packages it into a block that is relayed to all peers on the channel. The
peers then processs the configuration transactions in order to verify that the
modifications approved by the orderer do indeed satisfy the policies defined in
the channel.

Orderer nodes and Identity¶
Everything that interacts with a blockchain network, including peers,
applications, admins, and orderers, acquires their organizational identity from
their digital certificate and their Membership Service Provider (MSP) definition.
For more information about identities and MSPs, check out our documentation on
Identity and Membership.
Just like peers, ordering nodes belong to an organization. And similar to peers,
a separate Certificate Authority (CA) should be used for each organization.
Whether this CA will function as the root CA, or whether you choose to deploy
a root CA and then intermediate CAs associated with that root CA, is up to you.

Orderers and the transaction flow¶

Phase one: Proposal¶
We’ve seen from our topic on Peers that they form the basis
for a blockchain network, hosting ledgers, which can be queried and updated by
applications through smart contracts.
Specifically, applications that want to update the ledger are involved in a
process with three phases that ensures all of the peers in a blockchain network
keep their ledgers consistent with each other.
In the first phase, a client application sends a transaction proposal to
a subset of peers that will invoke a smart contract to produce a proposed
ledger update and then endorse the results. The endorsing peers do not apply
the proposed update to their copy of the ledger at this time. Instead, the
endorsing peers return a proposal response to the client application. The
endorsed transaction proposals will ultimately be ordered into blocks in phase
two, and then distributed to all peers for final validation and commit in
phase three.
For an in-depth look at the first phase, refer back to the Peers topic.

Phase two: Ordering and packaging transactions into blocks¶
After the completion of the first phase of a transaction, a client
application has received an endorsed transaction proposal response from a set of
peers. It’s now time for the second phase of a transaction.
In this phase, application clients submit transactions containing endorsed
transaction proposal responses to an ordering service node. The ordering service
creates blocks of transactions which will ultimately be distributed to
all peers on the channel for final validation and commit in phase three.
Ordering service nodes receive transactions from many different application
clients concurrently. These ordering service nodes work together to collectively
form the ordering service. Its job is to arrange batches of submitted transactions
into a well-defined sequence and package them into blocks. These blocks will
become the blocks of the blockchain!
The number of transactions in a block depends on channel configuration
parameters related to the desired size and maximum elapsed duration for a
block (BatchSize and BatchTimeout parameters, to be exact). The blocks are
then saved to the orderer’s ledger and distributed to all peers that have joined
the channel. If a peer happens to be down at this time, or joins the channel
later, it will receive the blocks after reconnecting to an ordering service
node, or by gossiping with another peer. We’ll see how this block is processed
by peers in the third phase.

The first role of an ordering node is to package proposed ledger updates. In
this example, application A1 sends a transaction T1 endorsed by E1 and E2 to
the orderer O1. In parallel, Application A2 sends transaction T2 endorsed by E1
to the orderer O1. O1 packages transaction T1 from application A1 and
transaction T2 from application A2 together with other transactions from other
applications in the network into block B2. We can see that in B2, the
transaction order is T1,T2,T3,T4,T6,T5 – which may not be the order in which
these transactions arrived at the orderer! (This example shows a very
simplified ordering service configuration with only one ordering node.)
It’s worth noting that the sequencing of transactions in a block is not
necessarily the same as the order received by the ordering service, since there
can be multiple ordering service nodes that receive transactions at approximately
the same time.  What’s important is that the ordering service puts the transactions
into a strict order, and peers will use this order when validating and committing
transactions.
This strict ordering of transactions within blocks makes Hyperledger Fabric a
little different from other blockchains where the same transaction can be
packaged into multiple different blocks that compete to form a chain.
In Hyperledger Fabric, the blocks generated by the ordering service are
final. Once a transaction has been written to a block, its position in the
ledger is immutably assured. As we said earlier, Hyperledger Fabric’s finality
means that there are no ledger forks — validated transactions will never
be reverted or dropped.
We can also see that, whereas peers execute smart contracts and process transactions,
orderers most definitely do not. Every authorized transaction that arrives at an
orderer is mechanically packaged in a block — the orderer makes no judgement
as to the content of a transaction (except for channel configuration transactions,
as mentioned earlier).
At the end of phase two, we see that orderers have been responsible for the simple
but vital processes of collecting proposed transaction updates, ordering them,
and packaging them into blocks, ready for distribution.

Phase three: Validation and commit¶
The third phase of the transaction workflow involves the distribution and
subsequent validation of blocks from the orderer to the peers, where they can be
committed to the ledger.
Phase 3 begins with the orderer distributing blocks to all peers connected to
it. It’s also worth noting that not every peer needs to be connected to an orderer —
peers can cascade blocks to other peers using the gossip
protocol.
Each peer will validate distributed blocks independently, but in a deterministic
fashion, ensuring that ledgers remain consistent. Specifically, each peer in the
channel will validate each transaction in the block to ensure it has been endorsed
by the required organization’s peers, that its endorsements match, and that
it hasn’t become invalidated by other recently committed transactions which may
have been in-flight when the transaction was originally endorsed. Invalidated
transactions are still retained in the immutable block created by the orderer,
but they are marked as invalid by the peer and do not update the ledger’s state.

The second role of an ordering node is to distribute blocks to peers. In this
example, orderer O1 distributes block B2 to peer P1 and peer P2. Peer P1
processes block B2, resulting in a new block being added to ledger L1 on P1. In
parallel, peer P2 processes block B2, resulting in a new block being added to
ledger L1 on P2. Once this process is complete, the ledger L1 has been
consistently updated on peers P1 and P2, and each may inform connected
applications that the transaction has been processed.
In summary, phase three sees the blocks generated by the ordering service applied
consistently to the ledger. The strict ordering of transactions into blocks
allows each peer to validate that transaction updates are consistently applied
across the blockchain network.
For a deeper look at phase 3, refer back to the Peers topic.

Ordering service implementations¶
While every ordering service currently available handles transactions and
configuration updates the same way, there are nevertheless several different
implementations for achieving consensus on the strict ordering of transactions
between ordering service nodes.
For information about how to stand up an ordering node (regardless of the
implementation the node will be used in), check out our documentation on standing up an ordering node.

Raft (recommended)
New as of v1.4.1, Raft is a crash fault tolerant (CFT) ordering service
based on an implementation of Raft protocol
in etcd. Raft follows a “leader and
follower” model, where a leader node is elected (per channel) and its decisions
are replicated by the followers. Raft ordering services should be easier to set
up and manage than Kafka-based ordering services, and their design allows
different organizations to contribute nodes to a distributed ordering service.

Kafka (deprecated in v2.0)
Similar to Raft-based ordering, Apache Kafka is a CFT implementation that uses
a “leader and follower” node configuration. Kafka utilizes a ZooKeeper
ensemble for management purposes. The Kafka based ordering service has been
available since Fabric v1.0, but many users may find the additional
administrative overhead of managing a Kafka cluster intimidating or undesirable.

Solo (deprecated in v2.0)
The Solo implementation of the ordering service is intended for test only and
consists only of a single ordering node.  It has been deprecated and may be
removed entirely in a future release.  Existing users of Solo should move to
a single node Raft network for equivalent function.

Raft¶
For information on how to configure a Raft ordering service, check out our
documentation on configuring a Raft ordering service.
The go-to ordering service choice for production networks, the Fabric
implementation of the established Raft protocol uses a “leader and follower”
model, in which a leader is dynamically elected among the ordering
nodes in a channel (this collection of nodes is known as the “consenter set”),
and that leader replicates messages to the follower nodes. Because the system
can sustain the loss of nodes, including leader nodes, as long as there is a
majority of ordering nodes (what’s known as a “quorum”) remaining, Raft is said
to be “crash fault tolerant” (CFT). In other words, if there are three nodes in a
channel, it can withstand the loss of one node (leaving two remaining). If you
have five nodes in a channel, you can lose two nodes (leaving three
remaining nodes).
From the perspective of the service they provide to a network or a channel, Raft
and the existing Kafka-based ordering service (which we’ll talk about later) are
similar. They’re both CFT ordering services using the leader and follower
design. If you are an application developer, smart contract developer, or peer
administrator, you will not notice a functional difference between an ordering
service based on Raft versus Kafka. However, there are a few major differences worth
considering, especially if you intend to manage an ordering service:

Raft is easier to set up. Although Kafka has many admirers, even those
admirers will (usually) admit that deploying a Kafka cluster and its ZooKeeper
ensemble can be tricky, requiring a high level of expertise in Kafka
infrastructure and settings. Additionally, there are many more components to
manage with Kafka than with Raft, which means that there are more places where
things can go wrong. And Kafka has its own versions, which must be coordinated
with your orderers. With Raft, everything is embedded into your ordering node.
Kafka and Zookeeper are not designed to be run across large networks. While
Kafka is CFT, it should be run in a tight group of hosts. This means that
practically speaking you need to have one organization run the Kafka cluster.
Given that, having ordering nodes run by different organizations when using Kafka
(which Fabric supports) doesn’t give you much in terms of decentralization because
the nodes will all go to the same Kafka cluster which is under the control of a
single organization. With Raft, each organization can have its own ordering
nodes, participating in the ordering service, which leads to a more decentralized
system.
Raft is supported natively, which means that users are required to get the requisite images and
learn how to use Kafka and ZooKeeper on their own. Likewise, support for
Kafka-related issues is handled through Apache, the
open-source developer of Kafka, not Hyperledger Fabric. The Fabric Raft implementation,
on the other hand, has been developed and will be supported within the Fabric
developer community and its support apparatus.
Where Kafka uses a pool of servers (called “Kafka brokers”) and the admin of
the orderer organization specifies how many nodes they want to use on a
particular channel, Raft allows the users to specify which ordering nodes will
be deployed to which channel. In this way, peer organizations can make sure
that, if they also own an orderer, this node will be made a part of a ordering
service of that channel, rather than trusting and depending on a central admin
to manage the Kafka nodes.
Raft is the first step toward Fabric’s development of a byzantine fault tolerant
(BFT) ordering service. As we’ll see, some decisions in the development of
Raft were driven by this. If you are interested in BFT, learning how to use
Raft should ease the transition.

For all of these reasons, support for Kafka-based ordering service is being
deprecated in Fabric v2.0.
Note: Similar to Solo and Kafka, a Raft ordering service can lose transactions
after acknowledgement of receipt has been sent to a client. For example, if the
leader crashes at approximately the same time as a follower provides
acknowledgement of receipt. Therefore, application clients should listen on peers
for transaction commit events regardless (to check for transaction validity), but
extra care should be taken to ensure that the client also gracefully tolerates a
timeout in which the transaction does not get committed in a configured timeframe.
Depending on the application, it may be desirable to resubmit the transaction or
collect a new set of endorsements upon such a timeout.

Raft concepts¶
While Raft offers many of the same features as Kafka — albeit in a simpler and
easier-to-use package — it functions substantially different under the covers
from Kafka and introduces a number of new concepts, or twists on existing
concepts, to Fabric.
Log entry. The primary unit of work in a Raft ordering service is a “log
entry”, with the full sequence of such entries known as the “log”. We consider
the log consistent if a majority (a quorum, in other words) of members agree on
the entries and their order, making the logs on the various orderers replicated.
Consenter set. The ordering nodes actively participating in the consensus
mechanism for a given channel and receiving replicated logs for the channel.
This can be all of the nodes available (either in a single cluster or in
multiple clusters contributing to the system channel), or a subset of those
nodes.
Finite-State Machine (FSM). Every ordering node in Raft has an FSM and
collectively they’re used to ensure that the sequence of logs in the various
ordering nodes is deterministic (written in the same sequence).
Quorum. Describes the minimum number of consenters that need to affirm a
proposal so that transactions can be ordered. For every consenter set, this is a
majority of nodes. In a cluster with five nodes, three must be available for
there to be a quorum. If a quorum of nodes is unavailable for any reason, the
ordering service cluster becomes unavailable for both read and write operations
on the channel, and no new logs can be committed.
Leader. This is not a new concept — Kafka also uses leaders, as we’ve said —
but it’s critical to understand that at any given time, a channel’s consenter set
elects a single node to be the leader (we’ll describe how this happens in Raft
later). The leader is responsible for ingesting new log entries, replicating
them to follower ordering nodes, and managing when an entry is considered
committed. This is not a special type of orderer. It is only a role that
an orderer may have at certain times, and then not others, as circumstances
determine.
Follower. Again, not a new concept, but what’s critical to understand about
followers is that the followers receive the logs from the leader and
replicate them deterministically, ensuring that logs remain consistent. As
we’ll see in our section on leader election, the followers also receive
“heartbeat” messages from the leader. In the event that the leader stops
sending those message for a configurable amount of time, the followers will
initiate a leader election and one of them will be elected the new leader.

Raft in a transaction flow¶
Every channel runs on a separate instance of the Raft protocol, which allows
each instance to elect a different leader. This configuration also allows
further decentralization of the service in use cases where clusters are made up
of ordering nodes controlled by different organizations. While all Raft nodes
must be part of the system channel, they do not necessarily have to be part of
all application channels. Channel creators (and channel admins) have the ability
to pick a subset of the available orderers and to add or remove ordering nodes
as needed (as long as only a single node is added or removed at a time).
While this configuration creates more overhead in the form of redundant heartbeat
messages and goroutines, it lays necessary groundwork for BFT.
In Raft, transactions (in the form of proposals or configuration updates) are
automatically routed by the ordering node that receives the transaction to the
current leader of that channel. This means that peers and applications do not
need to know who the leader node is at any particular time. Only the ordering
nodes need to know.
When the orderer validation checks have been completed, the transactions are
ordered, packaged into blocks, consented on, and distributed, as described in
phase two of our transaction flow.

Architectural notes¶

How leader election works in Raft¶
Although the process of electing a leader happens within the orderer’s internal
processes, it’s worth noting how the process works.
Raft nodes are always in one of three states: follower, candidate, or leader.
All nodes initially start out as a follower. In this state, they can accept
log entries from a leader (if one has been elected), or cast votes for leader.
If no log entries or heartbeats are received for a set amount of time (for
example, five seconds), nodes self-promote to the candidate state. In the
candidate state, nodes request votes from other nodes. If a candidate receives a
quorum of votes, then it is promoted to a leader. The leader must accept new
log entries and replicate them to the followers.
For a visual representation of how the leader election process works, check out
The Secret Lives of Data.

Snapshots¶
If an ordering node goes down, how does it get the logs it missed when it is
restarted?
While it’s possible to keep all logs indefinitely, in order to save disk space,
Raft uses a process called “snapshotting”, in which users can define how many
bytes of data will be kept in the log. This amount of data will conform to a
certain number of blocks (which depends on the amount of data in the blocks.
Note that only full blocks are stored in a snapshot).
For example, let’s say lagging replica R1 was just reconnected to the network.
Its latest block is 100. Leader L is at block 196, and is configured to
snapshot at amount of data that in this case represents 20 blocks. R1 would
therefore receive block 180 from L and then make a Deliver request for
blocks 101 to 180. Blocks 180 to 196 would then be replicated to R1
through the normal Raft protocol.

Kafka (deprecated in v2.0)¶
The other crash fault tolerant ordering service supported by Fabric is an
adaptation of a Kafka distributed streaming platform for use as a cluster of
ordering nodes. You can read more about Kafka at the Apache Kafka Web site,
but at a high level, Kafka uses the same conceptual “leader and follower”
configuration used by Raft, in which transactions (which Kafka calls “messages”)
are replicated from the leader node to the follower nodes. In the event the
leader node goes down, one of the followers becomes the leader and ordering can
continue, ensuring fault tolerance, just as with Raft.
The management of the Kafka cluster, including the coordination of tasks,
cluster membership, access control, and controller election, among others, is
handled by a ZooKeeper ensemble and its related APIs.
Kafka clusters and ZooKeeper ensembles are notoriously tricky to set up, so our
documentation assumes a working knowledge of Kafka and ZooKeeper. If you decide
to use Kafka without having this expertise, you should complete, at a minimum,
the first six steps of the Kafka Quickstart guide before experimenting with the
Kafka-based ordering service. You can also consult
this sample configuration file
for a brief explanation of the sensible defaults for Kafka and ZooKeeper.
To learn how to bring up a a Kafka-based ordering service, check out our documentation on Kafka.

Smart Contracts and Chaincode¶
Audience: Architects, application and smart contract developers,
administrators
From an application developer’s perspective, a smart contract, together with
the ledger, form the heart of a Hyperledger Fabric
blockchain system. Whereas a ledger holds facts about the current and historical
state of a set of business objects, a smart contract defines the executable
logic that generates new facts that are added to the ledger. A chaincode
is typically used by administrators to group related smart contracts for
deployment, but can also be used for low level system programming of Fabric. In
this topic, we’ll focus on why both smart contracts and chaincode exist,
and how and when to use them.
In this topic, we’ll cover:

What is a smart contract
A note on terminology
Smart contracts and the ledger
How to develop a smart contract
The importance of endorsement policies
Valid transactions
Channels and chaincode definitions
Communicating between smart contracts
What is system chaincode?

Smart contract¶
Before businesses can transact with each other, they must define a common set of
contracts covering common terms, data, rules, concept definitions, and
processes. Taken together, these contracts lay out the business model that
govern all of the interactions between transacting parties.
 A smart contract defines the
rules between different organizations in executable code. Applications invoke a
smart contract to generate transactions that are recorded on the ledger.
Using a blockchain network, we can turn these contracts into executable programs
– known in the industry as smart contracts – to open up a wide variety of
new possibilities. That’s because a smart contract can implement the governance
rules for any type of business object, so that they can be automatically
enforced when the smart contract is executed. For example, a smart contract
might ensure that a new car delivery is made within a specified timeframe, or
that funds are released according to prearranged terms, improving the flow of
goods or capital respectively. Most importantly however, the execution of a
smart contract is much more efficient than a manual human business process.
In the diagram above, we can see how two organizations,
ORG1 and ORG2 have defined a car smart contract to query, transfer and
update cars.  Applications from these organizations invoke this smart contract
to perform an agreed step in a business process, for example to transfer
ownership of a specific car from ORG1 to ORG2.

Terminology¶
Hyperledger Fabric users often use the terms smart contract and
chaincode interchangeably. In general, a smart contract defines the
transaction logic that controls the lifecycle of a business object contained
in the world state. It is then packaged into a chaincode which is then deployed
to a blockchain network.  Think of smart contracts as governing transactions,
whereas chaincode governs how smart contracts are packaged for deployment.
 A smart contract is defined
within a chaincode.  Multiple smart contracts can be defined within the same
chaincode. When a chaincode is deployed, all smart contracts within it are made
available to applications.
In the diagram, we can see a vehicle chaincode that contains three smart
contracts: cars, boats and trucks.  We can also see an insurance
chaincode that contains four smart contracts: policy, liability,
syndication and securitization.  In both cases these contracts cover key
aspects of the business process relating to vehicles and insurance. In this
topic, we will use the car contract as an example. We can see that a smart
contract is a domain specific program which relates to specific business
processes, whereas a chaincode is a technical container of a group of related
smart contracts.

Ledger¶
At the simplest level, a blockchain immutably records transactions which update
states in a ledger. A smart contract programmatically accesses two distinct
pieces of the ledger – a blockchain, which immutably records the history of
all transactions, and a world state that holds a cache of the current value
of these states, as it’s the current value of an object that is usually
required.
Smart contracts primarily put, get and delete states in the world
state, and can also query the immutable blockchain record of transactions.

A get typically represents a query to retrieve information about the
current state of a business object.
A put typically creates a new business object or modifies an existing one
in the ledger world state.
A delete typically represents the removal of a business object from the
current state of the ledger, but not its history.

Smart contracts have many
APIs available to them.
Critically, in all cases, whether transactions create, read, update or delete
business objects in the world state, the blockchain contains an immutable
record of these changes.

Development¶
Smart contracts are the focus of application development, and as we’ve seen, one
or more smart contracts can be defined within a single chaincode.  Deploying a
chaincode to a network makes all its smart contracts available to the
organizations in that network. It means that only administrators need to worry
about chaincode; everyone else can think in terms of smart contracts.
At the heart of a smart contract is a set of transaction definitions. For
example, look at fabcar.js
here,
where you can see a smart contract transaction that creates a new car:
async createCar(ctx, carNumber, make, model, color, owner) {

    const car = {
        color,
        docType: 'car',
        make,
        model,
        owner,
    };

    await ctx.stub.putState(carNumber, Buffer.from(JSON.stringify(car)));
}

You can learn more about the Fabcar smart contract in the Writing your
first application tutorial.
A smart contract can describe an almost infinite array of business use cases
relating to immutability of data in multi-organizational decision making. The
job of a smart contract developer is to take an existing business process that
might govern financial prices or delivery conditions, and express it as
a smart contract in a programming language such as JavaScript, Go, or Java.
The legal and technical skills required to convert centuries of legal language
into programming language is increasingly practiced by smart contract
auditors. You can learn about how to design and develop a smart contract in
the Developing applications
topic.

Endorsement¶
Associated with every chaincode is an endorsement policy that applies to all of
the smart contracts defined within it. An endorsement policy is very important;
it indicates which organizations in a blockchain network must sign a transaction
generated by a given smart contract in order for that transaction to be declared
valid.
 Every smart contract has an
endorsement policy associated with it. This endorsement policy identifies which
organizations must approve transactions generated by the smart contract before
those transactions can be identified as valid.
An example endorsement policy might define that three of the four organizations
participating in a blockchain network must sign a transaction before it is
considered valid. All transactions, whether valid or invalid are
added to a distributed ledger, but only valid transactions update the world
state.
If an endorsement policy specifies that more than one organization must sign a
transaction, then the smart contract must be executed by a sufficient set of
organizations in order for a valid transaction to be generated. In the example
above, a smart contract transaction to transfer a car would
need to be executed and signed by both ORG1 and ORG2 for it to be valid.
Endorsement policies are what make Hyperledger Fabric different to other
blockchains like Ethereum or Bitcoin. In these systems valid transactions can be
generated by any node in the network. Hyperledger Fabric more realistically
models the real world; transactions must be validated by trusted organizations
in a network. For example, a government organization must sign a valid
issueIdentity transaction, or both the buyer and seller of a car must sign
a car transfer transaction. Endorsement policies are designed to allow
Hyperledger Fabric to better model these types of real-world interactions.
Finally, endorsement policies are just one example of
policy in Hyperledger Fabric. Other policies
can be defined to identify who can query or update the ledger, or add or remove
participants from the network. In general, policies should be agreed in advance
by the consortium of organizations in a blockchain network, although they are
not set in stone. Indeed, policies themselves can define the rules by which they
can be changed. And although an advanced topic, it is also possible to define
custom endorsement policy rules
over and above those provided by Fabric.

Valid transactions¶
When a smart contract executes, it runs on a peer node owned by an organization
in the blockchain network. The contract takes a set of input parameters called
the transaction proposal and uses them in combination with its program logic
to read and write the ledger. Changes to the world state are captured as a
transaction proposal response (or just transaction response) which
contains a read-write set with both the states that have been read, and the
new states that are to be written if the transaction is valid. Notice that the
world state is not updated when the smart contract is executed!
 All transactions have an
identifier, a proposal, and a response signed by a set of organizations. All
transactions are recorded on the blockchain, whether valid or invalid, but only
valid transactions contribute to the world state.
Examine the car transfer transaction. You can see a transaction t3 for a car
transfer between ORG1 and ORG2. See how the transaction has input {CAR1, ORG1, ORG2} and output {CAR1.owner=ORG1, CAR1.owner=ORG2}, representing the
change of owner from ORG1 to ORG2. Notice how the input is signed by the
application’s organization ORG1, and the output is signed by both
organizations identified by the endorsement policy, ORG1 and ORG2.  These
signatures were generated by using each actor’s private key, and mean that
anyone in the network can verify that all actors in the network are in agreement
about the transaction details.
A transaction that is distributed to all peer nodes in the network is
validated in two phases by each peer. Firstly, the transaction is checked to
ensure it has been signed by sufficient organizations according to the endorsement
policy. Secondly, it is checked to ensure that the current value of the world state
matches the read set of the transaction when it was signed by the endorsing peer
nodes; that there has been no intermediate update. If a transaction passes both
these tests, it is marked as valid. All transactions are added to the
blockchain history, whether valid or invalid, but only valid
transactions result in an update to the world state.
In our example, t3 is a valid transaction, so the owner of CAR1 has been
updated to ORG2. However, t4 (not shown) is an invalid transaction, so while
it was recorded in the ledger, the world state was not updated, and CAR2
remains owned by ORG2.
Finally, to understand how to use a smart contract or chaincode with world
state, read the chaincode namespace
topic.

Channels¶
Hyperledger Fabric allows an organization to simultaneously participate in
multiple, separate blockchain networks via channels. By joining multiple
channels, an organization can participate in a so-called network of networks.
Channels provide an efficient sharing of infrastructure while maintaining data
and communications privacy. They are independent enough to help organizations
separate their work traffic with different counterparties, but integrated enough
to allow them to coordinate independent activities when necessary.
 A channel provides a
completely separate communication mechanism between a set of organizations. When
a chaincode definition is committed to a channel, all the smart contracts within
the chaincode are made available to the applications on that channel.
While the smart contract code is installed inside a chaincode package on an
organizations peers, channel members can only execute a smart contract after
the chaincode has been defined on a channel. The chaincode definition is a
struct that contains the parameters that govern how a chaincode operates. These
parameters include the chaincode name, version, and the endorsement policy.
Each channel member agrees to the parameters of a chaincode by approving a
chaincode definition for their organization. When a sufficient number of
organizations (a majority by default) have approved to the same chaincode
definition, the definition can be committed to the channel. The smart contracts
inside the chaincode can then be executed by channel members, subject to the
endorsement policy specified in the chaincode definition. The endorsement policy
applies equally to all smart contracts defined within the same chaincode.
In the example above, a car contract is defined on the VEHICLE
channel, and an insurance contract is defined on the INSURANCE channel.
The chaincode definition of car specifies an endorsement policy that requires
both ORG1 and ORG2 to sign transactions before they can be considered valid.
The chaincode definition of the insurance contract specifies that only ORG3
is required to endorse a transaction. ORG1 participates in two networks, the
VEHICLE channel and the INSURANCE network, and can coordinate activity with
ORG2 and ORG3 across these two networks.
The chaincode definition provides a way for channel members to agree on the
governance of a chaincode before they start using the smart contract to
transact on the channel. Building on the example above, both ORG1 and ORG2
want to endorse transactions that invoke the car contract. Because the default
policy requires that a majority of organizations approve a chaincode definition,
both organizations need to approve an endorsement policy of AND{ORG1,ORG2}.
Otherwise, ORG1 and ORG2 would approve different chaincode definitions and
would be unable to commit the chaincode definition to the channel as a result.
This process guarantees that a transaction from the car smart contract needs
to be approved by both organizations.

Intercommunication¶
A Smart Contract can call other smart contracts both within the same
channel and across different channels. It this way, they can read and write
world state data to which they would not otherwise have access due to smart
contract namespaces.
There are limitations to this inter-contract communication, which are described
fully in the chaincode namespace topic.

System chaincode¶
The smart contracts defined within a chaincode encode the domain dependent rules
for a business process agreed between a set of blockchain organizations.
However, a chaincode can also define low-level program code which corresponds to
domain independent system interactions, unrelated to these smart contracts
for business processes.
The following are the different types of system chaincodes and their associated
abbreviations:

_lifecycle runs in all peers and manages the installation of chaincode on
your peers, the approval of chaincode definitions for your organization, and
the committing of chaincode definitions to channels. You can read more about
how _lifecycle implements the Fabric chaincode lifecycle process.
Lifecycle system chaincode (LSCC) manages the chaincode lifecycle for the
1.x releases of Fabric. This version of lifecycle required that chaincode be
instantiated or upgraded on channels. You can still use LSCC to manage your
chaincode if you have the channel application capability set to V1_4_x or below.
Configuration system chaincode (CSCC) runs in all peers to handle changes to a
channel configuration, such as a policy update.  You can read more about this
process in the following chaincode
topic.
Query system chaincode (QSCC) runs in all peers to provide ledger APIs which
include block query, transaction query etc. You can read more about these
ledger APIs in the transaction context
topic.
Endorsement system chaincode (ESCC) runs in endorsing peers to
cryptographically sign a transaction response. You can read more about how
the ESCC implements this process.
Validation system chaincode (VSCC) validates a transaction, including checking
endorsement policy and read-write set versioning. You can read more about the
VSCC implements this process.

It is possible for low level Fabric developers and administrators to modify
these system chaincodes for their own uses. However, the development and
management of system chaincodes is a specialized activity, quite separate from
the development of smart contracts, and is not normally necessary. Changes to
system chaincodes must be handled with extreme care as they are fundamental to
the correct functioning of a Hyperledger Fabric network. For example, if a
system chaincode is not developed correctly, one peer node may update its copy
of the world state or blockchain differently compared to another peer node. This
lack of consensus is one form of a ledger fork, a very undesirable situation.

Fabric chaincode lifecycle¶

What is Chaincode?¶
Chaincode is a program, written in Go, Node.js,
or Java that implements a prescribed interface.
Chaincode runs in a secured Docker container isolated from the endorsing peer
process. Chaincode initializes and manages ledger state through transactions
submitted by applications.
A chaincode typically handles business logic agreed to by members of the
network, so it may be considered as a “smart contract”. Ledger updates created
by a chaincode are scoped exclusively to that chaincode and can’t be accessed
directly by another chaincode. However, within the same network, given the
appropriate permission a chaincode may invoke another chaincode to access
its state.
In this concept topic, we will explore chaincode through the eyes of a
blockchain network operator rather than an application developer. Chaincode
operators can use this topic as a guide to how to use the Fabric chainode
lifecycle to deploy and manage chaincode on their network.

Deploying a chaincode¶
The Fabric chaincode lifecycle is a process that allows multiple organizations
to agree on how a chaincode will be operated before it can be used on a channel.
A network operator would use the Fabric lifecycle to perform the following tasks:

Install and define a chaincode
Upgrade a chaincode
Deployment Scenarios
Migrate to the new Fabric lifecycle

You can use the Fabric chaincode lifecycle by creating a new channel and setting
the channel capabilities to V2_0. You will not be able to use the old lifecycle
to install, instantiate, or update a chaincode on channels with V2_0 capabilities
enabled. However, you can still invoke chaincode installed using the previous
lifecycle model after you enable V2_0 capabilities. If you are upgrading from a
v1.4.x network and need to edit your channel configurations to enable the new
lifecycle, check out Enabling the new chaincode lifecycle.

Install and define a chaincode¶
Fabric chaincode lifecycle requires that organizations agree to the parameters
that define a chaincode, such as name, version, and the chaincode endorsement
policy. Channel members come to agreement using the following four steps. Not
every organization on a channel needs to complete each step.

Package the chaincode: This step can be completed by one organization or
by each organization.
Install the chaincode on your peers: Every organization that will use the
chaincode to endorse a transaction or query the ledger needs to complete this
step.
Approve a chaincode definition for your organization: Every organization
that will use the chaincode needs to complete this step. The chaincode
definition needs to be approved by a sufficient number of organizations
to satisfy the channel’s LifecycleEndorsment policy (a majority, by default)
before the chaincode can be started on the channel.
Commit the chaincode definition to the channel: The commit transaction
needs to be submitted by one organization once the required number of
organizations on the channel have approved. The submitter first collects
endorsements from enough peers of the organizations that have approved, and
then submits the transaction to commit the chaincode definition.

This topic provides a detailed overview of the operations of the Fabric
chaincode lifecycle rather than the specific commands. To learn more about how
to use the Fabric lifecycle using the Peer CLI, see the
Deploying a smart contract to a channel tutorial
or the peer lifecycle command reference.

Step One: Packaging the smart contract¶
Chaincode needs to be packaged in a tar file before it can be installed on your
peers. You can package a chaincode using the Fabric peer binaries, the Node
Fabric SDK, or a third party tool such as GNU tar. When you create a chaincode
package, you need to provide a chaincode package label to create a succinct and
human readable description of the package.
If you use a third party tool to package the chaincode, the resulting file needs
to be in the format below. The Fabric peer binaries and the Fabric SDKs will
automatically create a file in this format.

The chaincode needs to be packaged in a tar file, ending with a .tar.gz file
extension.

The tar file needs to contain two files (no directory): a metadata file
“metadata.json” and another tar containing the chaincode files.

“metadata.json” contains JSON that specifies the
chaincode language, code path, and package label. You can see an example of
a metadata file below:
{"Path":"fabric-samples/chaincode/fabcar/go","Type":"golang","Label":"fabcarv1"}

The chaincode is packaged separately by Org1 and Org2. Both organizations use
MYCC_1 as their package label in order to identify the package using the name
and version. It is not necessary for organizations to use the same package
label.

Step Two: Install the chaincode on your peers¶
You need to install the chaincode package on every peer that will execute and
endorse transactions. Whether using the CLI or an SDK, you need to complete this
step using your Peer Administrator. Your peer will build the chaincode
after the chaincode is installed, and return a build error if there is a problem
with your chaincode. It is recommended that organizations only package a chaincode
once, and then install the same package on every peer that belongs to their org.
If a channel wants to ensure that each organization is running the same chaincode,
one organization can package a chaincode and send it to other channel members
out of band.
A successful install command will return a chaincode package identifier, which
is the package label combined with a hash of the package. This package
identifier is used to associate a chaincode package installed on your peers with
a chaincode definition approved by your organization. Save the identifier
for next step. You can also find the package identifier by querying the packages
installed on your peer using the Peer CLI.

A peer administrator from Org1 and Org2 installs the chaincode package MYCC_1
on the peers joined to the channel. Installing the chaincode package builds the
chaincode and creates a package identifier of MYCC_1:hash.

Step Three: Approve a chaincode definition for your organization¶
The chaincode is governed by a chaincode definition. When channel members
approve a chaincode definition, the approval acts as a vote by an organization
on the chaincode parameters it accepts. These approved organization definitions
allow channel members to agree on a chaincode before it can be used on a channel.
The chaincode definition includes the following parameters, which need to be
consistent across organizations:

Name: The name that applications will use when invoking the chaincode.

Version: A version number or value associated with a given chaincodes
package. If you upgrade the chaincode binaries, you need to change your
chaincode version as well.

Sequence: The number of times the chaincode has been defined. This value
is an integer, and is used to keep track of chaincode upgrades. For example,
when you first install and approve a chaincode definition, the sequence number
will be 1. When you next upgrade the chaincode, the sequence number will be
incremented to 2.

Endorsement Policy: Which organizations need to execute and validate the
transaction output. The endorsement policy can be expressed as a string passed
to the CLI, or it can reference a policy in the channel config. By
default, the endorsement policy is set to Channel/Application/Endorsement,
which defaults to require that a majority of organizations in the channel
endorse a transaction.

Collection Configuration: The path to a private data collection definition
file associated with your chaincode. For more information about private data
collections, see the Private Data architecture reference.

ESCC/VSCC Plugins: The name of a custom endorsement or validation
plugin to be used by this chaincode.

Initialization: If you use the low level APIs provided by the Fabric Chaincode
Shim API, your chaincode needs to contain an Init function that is used to
initialize the chaincode. This function is required by the chaincode interface,
but does not necessarily need to invoked by your applications. When you approve
a chaincode definition, you can specify whether Init must be called prior to
Invokes. If you specify that Init is required, Fabric will ensure that the Init
function is invoked before any other function in the chaincode and is only invoked
once. Requesting the execution of the Init function allows you to implement
logic that is run when the chaincode is initialized, for example to set some
initial state. You will need to call Init to initialize the chaincode every
time you increment the version of a chaincode, assuming the chaincode definition
that increments the version indicates that Init is required.
If you are using the Fabric peer CLI, you can use the --init-required flag
when you approve and commit the chaincode definition to indicate that the Init
function must be called to initialize the new chaincode version. To call Init
using the Fabric peer CLI, use the peer chaincode invoke command and pass the
--isInit flag.
If you are using the Fabric contract API, you do not need to include an Init
method in your chaincode. However, you can still use the --init-required flag
to request that the chaincode be initialized by a call from your applications.
If you use the --init-required flag, you will need to pass the --isInit flag
or parameter to a chaincode call in order to initialize the chaincode every time
you increment the chaincode version. You can pass --isInit and initialize the
chaincode using any function in your chaincode.

The chaincode definition also includes the Package Identifier. This is a
required parameter for each organization that wants to use the chaincode. The
package ID does not need to be the same for all organizations. An organization
can approve a chaincode definition without installing a chaincode package or
including the identifier in the definition.
Each channel member that wants to use the chaincode needs to approve a chaincode
definition for their organization. This approval needs to be submitted to the
ordering service, after which it is distributed to all peers. This approval
needs to be submitted by your Organization Administrator. After the approval
transaction has been successfully submitted, the approved definition is stored
in a collection that is available to all the peers of your organization. As a
result you only need to approve a chaincode for your organization once, even if
you have multiple peers.

An organization administrator from Org1 and Org2 approve the chaincode definition
of MYCC for their organization. The chaincode definition includes the chaincode
name, version, and the endorsement policy, among other fields. Since both
organizations will use the chaincode to endorse transactions, the approved
definitions for both organizations need to include the packageID.

Step Four: Commit the chaincode definition to the channel¶
Once a sufficient number of channel members have approved a chaincode definition,
one organization can commit the definition to the channel. You can use the
checkcommitreadiness command to check whether committing the chaincode
definition should be successful based on which channel members have approved a
definition before committing it to the channel using the peer CLI. The commit
transaction proposal is first sent to the peers of channel members, who query the
chaincode definition approved for their organizations and endorse the definition
if their organization has approved it. The transaction is then submitted to the
ordering service, which then commits the chaincode definition to the channel.
The commit definition transaction needs to be submitted as the Organization
Administrator.
The number of organizations that need to approve a definition before it can be
successfully committed to the channel is governed by the
Channel/Application/LifecycleEndorsement policy. By default, this policy
requires that a majority of organizations in the channel endorse the transaction.
The LifecycleEndorsement policy is separate from the chaincode endorsement
policy. For example, even if a chaincode endorsement policy only requires
signatures from one or two organizations, a majority of channel members still
need to approve the chaincode definition according to the default policy. When
committing a channel definition, you need to target enough peer organizations in
the channel to satisfy your LifecycleEndorsement policy. You can learn more
about the Fabric chaincode lifecycle policies in the Policies concept topic.
You can also set the Channel/Application/LifecycleEndorsement policy to be a
signature policy and explicitly specify the set of organizations on the channel
that can approve a chaincode definition. This allows you to create a channel where
a select number of organizations act as chaincode administrators and govern the
business logic used by the channel. You can also use a signature policy if your
channel has a large number Idemix organizations, which cannot approve
chaincode definitions or endorse chaincode and may prevent the channel from
reaching a majority as a result.

One organization administrator from Org1 or Org2 commits the chaincode definition
to the channel. The definition on the channel does not include the packageID.
An organization can approve a chaincode definition without installing the
chaincode package. If an organization does not need to use the chaincode, they
can approve a chaincode definition without a package identifier to ensure that
the Lifecycle Endorsement policy is satisfied.
After the chaincode definition has been committed to the channel, the chaincode
container will launch on all of the peers where the chaincode has been installed,
allowing channel members to start using the chaincode. It may take a few minutes for
the chaincode container to start. You can use the chaincode definition to require
the invocation of the Init function to initialize the chaincode. If the
invocation of the Init function is requested, the first invoke of the
chaincode must be a call to the Init function. The invoke of the Init
function is subject to the chaincode endorsement policy.

Once MYCC is defined on the channel, Org1 and Org2 can start using the chaincode. The first invoke of the chaincode on each peer starts the chaincode
container on that peer.

Upgrade a chaincode¶
You can upgrade a chaincode using the same Fabric lifecycle process as you used
to install and start the chainocode. You can upgrade the chaincode binaries, or
only update the chaincode policies. Follow these steps to upgrade a chaincode:

Repackage the chaincode: You only need to complete this step if you are
upgrading the chaincode binaries.

Org1 and Org2 upgrade the chaincode binaries and repackage the chaincode. Both organizations use a different package label.

Install the new chaincode package on your peers: Once again, you only
need to complete this step if you are upgrading the chaincode binaries.
Installing the new chaincode package will generate a package ID, which you will
need to pass to the new chaincode definition. You also need to change the
chaincode version, which is used by the lifecycle process to track if the
chaincode binaries have been upgraded.

Org1 and Org2 install the new package on their peers. The installation creates a new packageID.

Approve a new chaincode definition: If you are upgrading the chaincode
binaries, you need to update the chaincode version and the package ID in the
chaincode definition. You can also update your chaincode endorsement policy
without having to repackage your chaincode binaries. Channel members simply
need to approve a definition with the new policy. The new definition needs to
increment the sequence variable in the definition by one.

Organization administrators from Org1 and Org2 approve the new chaincode definition for their respective organizations. The new definition references the new packageID and changes the chaincode version. Since this is the first update of the chaincode, the sequence is incremented from one to two.

Commit the definition to the channel: When a sufficient number of channel
members have approved the new chaincode definition, one organization can
commit the new definition to upgrade the chaincode definition to the channel.
There is no separate upgrade command as part of the lifecycle process.

An organization administrator from Org1 or Org2 commits the new chaincode definition to the channel.

After you commit the chaincode definition, a new chaincode container will
launch with the code from the upgraded chaincode binaries. If you requested the
execution of the Init function in the chaincode definition, you need to
initialize the upgraded chaincode by invoking the Init function again after
the new definition is successfully committed. If you updated the chaincode
definition without changing the chaincode version, the chaincode container will
remain the same and you do not need to invoke Init function.

Once the new definition has been committed to the channel, each peer will automatically start the new chaincode container.
The Fabric chaincode lifecycle uses the sequence in the chaincode definition
to keep track of upgrades. All channel members need to increment the sequence
number by one and approve a new definition to upgrade the chaincode. The version
parameter is used to track the chaincode binaries, and needs to be changed only
when you upgrade the chaincode binaries.

Deployment scenarios¶
The following examples illustrate how you can use the Fabric chaincode lifecycle
to manage channels and chaincode.

Joining a channel¶
A new organization can join a channel with a chaincode already defined, and start
using the chaincode after installing the chaincode package and approving the
chaincode definition that has already been committed to the channel.

Org3 joins the channel and approves the same chaincode definition that was
previously committed to the channel by Org1 and Org2.
After approving the chaincode definition, the new organization can start using
the chaincode after the package has been installed on their peers. The definition
does not need to be committed again. If the endorsement policy is set the default
policy that requires endorsements from a majority of channel members, then the
endorsement policy will be updated automatically to include the new organization.

The chaincode container will start after the first invoke of the chaincode on
the Org3 peer.

Updating an endorsement policy¶
You can use the chaincode definition to update an endorsement policy without
having to repackage or re-install the chaincode. Channel members can approve
a chaincode definition with a new endorsement policy and commit it to the
channel.

Org1, Org2, and Org3 approve a new endorsement policy requiring that all three
organizations endorse a transaction. They increment the definition sequence from
one to two, but do not need to update the chaincode version.
The new endorsement policy will take effect after the new definition is
committed to the channel. Channel members do not have to restart the chaincode
container by invoking the chaincode or executing the Init function in order to
update the endorsement policy.

One organization commits the new chaincode definition to the channel to
update the endorsement policy.

Approving a definition without installing the chaincode¶
You can approve a chaincode definition without installing the chaincode package.
This allows you to endorse a chaincode definition before it is committed to the
channel, even if you do not want to use the chaincode to endorse transactions or
query the ledger. You need to approve the same parameters as other members of the
channel, but not need to include the packageID as part of the chaincode
definition.

Org3 does not install the chaincode package. As a result, they do not need to
provide a packageID as part of chaincode definition. However, Org3 can still
endorse the definition of MYCC that has been committed to the channel.

One organization disagrees on the chaincode definition¶
An organization that does not approve a chaincode definition that has been
committed to the channel cannot use the chaincode. Organizations that have
either not approved a chaincode definition, or approved a different chaincode
definition will not be able to execute the chaincode on their peers.

Org3 approves a chaincode definition with a different endorsement policy than
Org1 and Org2. As a result, Org3 cannot use the MYCC chaincode on the channel.
However, Org1 or Org2 can still get enough endorsements to commit the definition
to the channel and use the chaincode. Transactions from the chaincode will still
be added to the ledger and stored on the Org3 peer. However, the Org3 will not
be able to endorse transactions.
An organization can approve a new chaincode definition with any sequence number
or version. This allows you to approve the definition that has been committed
to the channel and start using the chaincode. You can also approve a new
chaincode definition in order to correct any mistakes made in the process of
approving or packaging a chaincode.

The channel does not agree on a chaincode definition¶
If the organizations on a channel do not agree on a chaincode definition, the
definition cannot be committed to the channel. None of the channel members will
be able to use the chaincode.

Org1, Org2, and Org3 all approve different chaincode definitions. As a result,
no member of the channel can get enough endorsements to commit a chaincode
definition to the channel. No channel member will be able to use the chaincode.

Organizations install different chaincode packages¶
Each organization can use a different packageID when they approve a chaincode
definition. This allows channel members to install different chaincode binaries
that use the same endorsement policy and read and write to data in the same
chaincode namespace.
Organizations can use this capability to install smart contracts that
contain business logic that is specific to their organization. Each
organization’s smart contract could contain additional validation that the
organization requires before their peers endorse a transaction. Each organization
can also write code that helps integrate the smart contract with data from their
existing systems.

Org1 and Org2 each install versions of the MYCC chaincode containing business
logic that is specific to their organization.

Creating multiple chaincodes using one package¶
You can use one chaincode package to create multiple chaincode instances on a
channel by approving and committing multiple chaincode definitions. Each
definition needs to specify a different chaincode name. This allows you to run
multiple instances of a smart contract on a channel, but have the contract be
subject to different endorsement policies.

Org1 and Org2 use the MYCC_1 chaincode package to approve and commit two
different chaincode definitions. As a result, both peers have two chaincode
containers running on their peers. MYCC1 has an endorsement policy of 1 out of 2,
while MYCC2 has an endorsement policy of 2 out of 2.

Migrate to the new Fabric lifecycle¶
For information about migrating to the new lifecycle, check out Considerations for getting to v2.0.
If you need to update your channel configurations to enable the new lifecycle, check out Enabling the new chaincode lifecycle.

More information¶
You can watch video below to learn more about the motivation of the new Fabric chaincode lifecycle and how it is implemented.

Private data¶

What is private data?¶
In cases where a group of organizations on a channel need to keep data private from
other organizations on that channel, they have the option to create a new channel
comprising just the organizations who need access to the data. However, creating
separate channels in each of these cases creates additional administrative overhead
(maintaining chaincode versions, policies, MSPs, etc), and doesn’t allow for use
cases in which you want all channel participants to see a transaction while keeping
a portion of the data private.
That’s why Fabric offers the ability to create
private data collections, which allow a defined subset of organizations on a
channel the ability to endorse, commit, or query private data without having to
create a separate channel.

What is a private data collection?¶
A collection is the combination of two elements:

The actual private data, sent peer-to-peer via gossip protocol
to only the organization(s) authorized to see it. This data is stored in a
private state database on the peers of authorized organizations,
which can be accessed from chaincode on these authorized peers.
The ordering service is not involved here and does not see the
private data. Note that because gossip distributes the private data peer-to-peer
across authorized organizations, it is required to set up anchor peers on the channel,
and configure CORE_PEER_GOSSIP_EXTERNALENDPOINT on each peer,
in order to bootstrap cross-organization communication.
A hash of that data, which is endorsed, ordered, and written to the ledgers
of every peer on the channel. The hash serves as evidence of the transaction and
is used for state validation and can be used for audit purposes.

The following diagram illustrates the ledger contents of a peer authorized to have
private data and one which is not.

Collection members may decide to share the private data with other parties if they
get into a dispute or if they want to transfer the asset to a third party. The
third party can then compute the hash of the private data and see if it matches the
state on the channel ledger, proving that the state existed between the collection
members at a certain point in time.
In some cases, you may decide to have a set of collections each comprised of a
single organization. For example an organization may record private data in their own
collection, which could later be shared with other channel members and
referenced in chaincode transactions. We’ll see examples of this in the sharing
private data topic below.

When to use a collection within a channel vs. a separate channel¶

Use channels when entire transactions (and ledgers) must be kept
confidential within a set of organizations that are members of the channel.
Use collections when transactions (and ledgers) must be shared among a set
of organizations, but when only a subset of those organizations should have
access to some (or all) of the data within a transaction.  Additionally,
since private data is disseminated peer-to-peer rather than via blocks,
use private data collections when transaction data must be kept confidential
from ordering service nodes.

A use case to explain collections¶
Consider a group of five organizations on a channel who trade produce:

A Farmer selling his goods abroad
A Distributor moving goods abroad
A Shipper moving goods between parties
A Wholesaler purchasing goods from distributors
A Retailer purchasing goods from shippers and wholesalers

The Distributor might want to make private transactions with the
Farmer and Shipper to keep the terms of the trades confidential from
the Wholesaler and the Retailer (so as not to expose the markup they’re
charging).
The Distributor may also want to have a separate private data relationship
with the Wholesaler because it charges them a lower price than it does the
Retailer.
The Wholesaler may also want to have a private data relationship with the
Retailer and the Shipper.
Rather than defining many small channels for each of these relationships, multiple
private data collections (PDC) can be defined to share private data between:

PDC1: Distributor, Farmer and Shipper
PDC2: Distributor and Wholesaler
PDC3: Wholesaler, Retailer and Shipper

Using this example, peers owned by the Distributor will have multiple private
databases inside their ledger which includes the private data from the
Distributor, Farmer and Shipper relationship and the
Distributor and Wholesaler relationship.

Transaction flow with private data¶
When private data collections are referenced in chaincode, the transaction flow
is slightly different in order to protect the confidentiality of the private
data as transactions are proposed, endorsed, and committed to the ledger.
For details on transaction flows that don’t use private data refer to our
documentation on transaction flow.

The client application submits a proposal request to invoke a chaincode
function (reading or writing private data) to endorsing peers which are
part of authorized organizations of the collection. The private data, or
data used to generate private data in chaincode, is sent in a transient
field of the proposal.
The endorsing peers simulate the transaction and store the private data in
a transient data store (a temporary storage local to the peer). They
distribute the private data, based on the collection policy, to authorized peers
via gossip.
The endorsing peer sends the proposal response back to the client. The proposal
response includes the endorsed read/write set, which includes public
data, as well as a hash of any private data keys and values. No private data is
sent back to the client. For more information on how endorsement works with
private data, click here.
The client application submits the transaction (which includes the proposal
response with the private data hashes) to the ordering service. The transactions
with the private data hashes get included in blocks as normal.
The block with the private data hashes is distributed to all the peers. In this way,
all peers on the channel can validate transactions with the hashes of the private
data in a consistent way, without knowing the actual private data.
At block commit time, authorized peers use the collection policy to
determine if they are authorized to have access to the private data. If they do,
they will first check their local transient data store to determine if they
have already received the private data at chaincode endorsement time. If not,
they will attempt to pull the private data from another authorized peer. Then they
will validate the private data against the hashes in the public block and commit the
transaction and the block. Upon validation/commit, the private data is moved to
their copy of the private state database and private writeset storage. The
private data is then deleted from the transient data store.

Sharing private data¶
In many scenarios private data keys/values in one collection may need to be shared with
other channel members or with other private data collections, for example when you
need to transact on private data with a channel member or group of channel members
who were not included in the original private data collection. The receiving parties
will typically want to verify the private data against the on-chain hashes
as part of the transaction.
There are several aspects of private data collections that enable the
sharing and verification of private data:

First, you don’t necessarily have to be a member of a collection to write to a key in
a collection, as long as the endorsement policy is satisfied.
Endorsement policy can be defined at the chaincode level, key level (using state-based
endorsement), or collection level (starting in Fabric v2.0).
Second, starting in v1.4.2 there is a chaincode API GetPrivateDataHash() that allows
chaincode on non-member peers to read the hash value of a private key. This is an
important feature as you will see later, because it allows chaincode to verify private
data against the on-chain hashes that were created from private data in previous transactions.

This ability to share and verify private data should be considered when designing
applications and the associated private data collections.
While you can certainly create sets of multilateral private data collections to share data
among various combinations of channel members, this approach may result in a large
number of collections that need to be defined.
Alternatively, consider using a smaller number of private data collections (e.g.
one collection per organization, or one collection per pair of organizations), and
then sharing private data with other channel members, or with other
collections as the need arises. Starting in Fabric v2.0, implicit organization-specific
collections are available for any chaincode to utilize,
so that you don’t even have to define these per-organization collections when
deploying chaincode.

Private data sharing patterns¶
When modeling private data collections per organization, multiple patterns become available
for sharing or transferring private data without the overhead of defining many multilateral
collections. Here are some of the sharing patterns that could be leveraged in chaincode
applications:

Use a corresponding public key for tracking public state -
You can optionally have a matching public key for tracking public state (e.g. asset
properties, current ownership. etc), and for every organization that should have access
to the asset’s corresponding private data, you can create a private key/value in each
organization’s private data collection.
Chaincode access control -
You can implement access control in your chaincode, to specify which clients can
query private data in a collection. For example, store an access control list
for a private data collection key or range of keys, then in the chaincode get the
client submitter’s credentials (using GetCreator() chaincode API or CID library API
GetID() or GetMSPID() ), and verify they have access before returning the private
data. Similarly you could require a client to pass a passphrase into chaincode,
which must match a passphrase stored at the key level, in order to access the
private data. Note, this pattern can also be used to restrict client access to public
state data.
Sharing private data out of band -
As an off-chain option, you could share private data out of band with other
organizations, and they can hash the key/value to verify it matches
the on-chain hash by using GetPrivateDataHash() chaincode API. For example,
an organization that wishes to purchase an asset from you may want to verify
an asset’s properties and that you are the legitimate owner by checking the
on-chain hash, prior to agreeing to the purchase.
Sharing private data with other collections -
You could ‘share’ the private data on-chain with chaincode that creates a matching
key/value in the other organization’s private data collection. You’d pass the
private data key/value to chaincode via transient field, and the chaincode
could confirm a hash of the passed private data matches the on-chain hash from
your collection using GetPrivateDataHash(), and then write the private data to
the other organization’s private data collection.
Transferring private data to other collections -
You could ‘transfer’ the private data with chaincode that deletes the private data
key in your collection, and creates it in another organization’s collection.
Again, use the transient field to pass the private data upon chaincode invoke,
and in the chaincode use GetPrivateDataHash() to confirm that the data exists in
your private data collection, before deleting the key from your collection and
creating the key in another organization’s collection. To ensure that a
transaction always deletes from one collection and adds to another collection,
you may want to require endorsements from additional parties, such as a
regulator or auditor.
Using private data for transaction approval -
If you want to get a counterparty’s approval for a transaction before it is
completed (e.g. an on-chain record that they agree to purchase an asset for
a certain price), the chaincode can require them to ‘pre-approve’ the transaction,
by either writing a private key to their private data collection or your collection,
which the chaincode will then check using GetPrivateDataHash(). In fact, this is
exactly the same mechanism that the built-in lifecycle system chaincode uses to
ensure organizations agree to a chaincode definition before it is committed to
a channel. Starting with Fabric v2.0, this pattern
becomes more powerful with collection-level endorsement policies, to ensure
that the chaincode is executed and endorsed on the collection owner’s own trusted
peer. Alternatively, a mutually agreed key with a key-level endorsement policy
could be used, that is then updated with the pre-approval terms and endorsed
on peers from the required organizations.
Keeping transactors private -
Variations of the prior pattern can also eliminate leaking the transactors for a given
transaction. For example a buyer indicates agreement to buy on their own collection,
then in a subsequent transaction seller references the buyer’s private data in
their own private data collection. The proof of transaction with hashed references
is recorded on-chain, only the buyer and seller know that they are the transactors,
but they can reveal the pre-images if a need-to-know arises, such as in a subsequent
transaction with another party who could verify the hashes.

Coupled with the patterns above, it is worth noting that transactions with private
data can be bound to the same conditions as regular channel state data, specifically:

Key level transaction access control -
You can include ownership credentials in a private data value, so that subsequent
transactions can verify that the submitter has ownership privilege to share or transfer
the data. In this case the chaincode would get the submitter’s credentials
(e.g. using GetCreator() chaincode API or CID library API GetID() or GetMSPID() ),
combine it with other private data that gets passed to the chaincode, hash it,
and use GetPrivateDataHash() to verify that it matches the on-chain hash before
proceeding with the transaction.
Key level endorsement policies -
And also as with normal channel state data, you can use state-based endorsement
to specify which organizations must endorse transactions that share or transfer
private data, using SetPrivateDataValidationParameter() chaincode API,
for example to specify that only an owner’s organization peer, custodian’s organization
peer, or other third party must endorse such transactions.

Example scenario: Asset transfer using private data collections¶
The private data sharing patterns mentioned above can be combined to enable powerful
chaincode-based applications. For example, consider how an asset transfer scenario
could be implemented using per-organization private data collections:

An asset may be tracked by a UUID key in public chaincode state. Only the asset’s
ownership is recorded, nothing else is known about the asset.
The chaincode will require that any transfer request must originate from the owning client,
and the key is bound by state-based endorsement requiring that a peer from the
owner’s organization and a regulator’s organization must endorse any transfer requests.
The asset owner’s private data collection contains the private details about
the asset, keyed by a hash of the UUID. Other organizations and the ordering
service will only see a hash of the asset details.
Let’s assume the regulator is a member of each collection as well, and therefore
persists the private data, although this need not be the case.

A transaction to trade the asset would unfold as follows:

Off-chain, the owner and a potential buyer strike a deal to trade the asset
for a certain price.
The seller provides proof of their ownership, by either passing the private details
out of band, or by providing the buyer with credentials to query the private
data on their node or the regulator’s node.
Buyer verifies a hash of the private details matches the on-chain public hash.
The buyer invokes chaincode to record their bid details in their own private data collection.
The chaincode is invoked on buyer’s peer, and potentially on regulator’s peer if required
by the collection endorsement policy.
The current owner (seller) invokes chaincode to sell and transfer the asset, passing in the
private details and bid information. The chaincode is invoked on peers of the
seller, buyer, and regulator, in order to meet the endorsement policy of the public
key, as well as the endorsement policies of the buyer and seller private data collections.
The chaincode verifies that the submitting client is the owner, verifies the private
details against the hash in the seller’s collection, and verifies the bid details
against the hash in the buyer’s collection. The chaincode then writes the proposed
updates for the public key (setting ownership to the buyer, and setting endorsement
policy to be the buying organization and regulator), writes the private details to the
buyer’s private data collection, and potentially deletes the private details from seller’s
collection. Prior to final endorsement, the endorsing peers ensure private data is
disseminated to any other authorized peers of the seller and regulator.
The seller submits the transaction with the public data and private data hashes
for ordering, and it is distributed to all channel peers in a block.
Each peer’s block validation logic will consistently verify the endorsement policy
was met (buyer, seller, regulator all endorsed), and verify that public and private
state that was read in the chaincode has not been modified by any other transaction
since chaincode execution.
All peers commit the transaction as valid since it passed validation checks.
Buyer peers and regulator peers retrieve the private data from other authorized
peers if they did not receive it at endorsement time, and persist the private
data in their private data state database (assuming the private data matched
the hashes from the transaction).
With the transaction completed, the asset has been transferred, and other
channel members interested in the asset may query the history of the public
key to understand its provenance, but will not have access to any private
details unless an owner shares it on a need-to-know basis.

The basic asset transfer scenario could be extended for other considerations,
for example the transfer chaincode could verify that a payment record is available
to satisfy payment versus delivery requirements, or verify that a bank has
submitted a letter of credit, prior to the execution of the transfer chaincode.
And instead of transactors directly hosting peers, they could transact through
custodian organizations who are running peers.

Purging private data¶
For very sensitive data, even the parties sharing the private data might want
— or might be required by government regulations — to periodically “purge” the data
on their peers, leaving behind a hash of the data on the blockchain
to serve as immutable evidence of the private data.
In some of these cases, the private data only needs to exist on the peer’s private
database until it can be replicated into a database external to the peer’s
blockchain. The data might also only need to exist on the peers until a chaincode business
process is done with it (trade settled, contract fulfilled, etc).
To support these use cases, private data can be purged if it has not been modified
for a configurable number of blocks. Purged private data cannot be queried from chaincode,
and is not available to other requesting peers.

How a private data collection is defined¶
For more details on collection definitions, and other low level information about
private data and collections, refer to the private data reference topic.

Channel capabilities¶
Audience: Channel administrators, node administrators
Note: this is an advanced Fabric concept that is not necessary for new users or application developers to understand. However, as channels and networks mature, understanding and managing capabilities becomes vital. Furthermore, it is important to recognize that updating capabilities is a different, though often related, process to upgrading nodes. We’ll describe this in detail in this topic.
Because Fabric is a distributed system that will usually involve multiple organizations, it is possible (and typical) that different versions of Fabric code will exist on different nodes within the network as well as on the channels in that network. Fabric allows this — it is not necessary for every peer and ordering node to be at the same version level. In fact, supporting different version levels is what enables rolling upgrades of Fabric nodes.
What is important is that networks and channels process things in the same way, creating deterministic results for things like channel configuration updates and chaincode invocations. Without deterministic results, one peer on a channel might invalidate a transaction while another peer may validate it.
To that end, Fabric defines levels of what are called “capabilities”. These capabilities, which are defined in the configuration of each channel, ensure determinism by defining a level at which behaviors produce consistent results. As you’ll see, these capabilities have versions which are closely related to node binary versions. Capabilities enable nodes running at different version levels to behave in a compatible and consistent way given the channel configuration at a specific block height. You will also see that capabilities exist in many parts of the configuration tree, defined along the lines of administration for particular tasks.
As you’ll see, sometimes it is necessary to update your channel to a new capability level to enable a new feature.

Node versions and capability versions¶
If you’re familiar with Hyperledger Fabric, you’re aware that it follows a typical versioning pattern: v1.1, v1.2.1, v2.0, etc. These versions refer to releases and their related binary versions.
Capabilities follow the same versioning convention. There are v1.1 capabilities and v1.2 capabilities and 2.0 capabilities and so on. But it’s important to note a few distinctions.

There is not necessarily a new capability level with each release.
The need to establish a new capability is determined on a case by case basis and relies chiefly on the backwards compatibility of new features and older binary versions. Adding Raft ordering services in v1.4.1, for example, did not change the way either transactions or ordering service functions were handled and thus did not require the establishment of any new capabilities. Private Data, on the other hand, could not be handled by peers before v1.2, requiring the establishment of a v1.2 capability level. Because not every release contains a new feature (or a bug fix) that changes the way transactions are processed, certain releases will not require any new capabilities (for example, v1.4) while others will only have new capabilities at particular levels (such as v1.2 and v1.3). We’ll discuss the “levels” of capabilities and where they reside in the configuration tree later.
Nodes must be at least at the level of certain capabilities in a channel.
When a peer joins a channel, it reads all of the blocks in the ledger sequentially, starting with the genesis block of the channel and continuing through the transaction blocks and any subsequent configuration blocks. If a node, for example a peer, attempts to read a block containing an update to a capability it doesn’t understand (for example, a v1.4.x peer trying to read a block containing a v2.0 application capability), the peer will crash. This crashing behavior is intentional, as a v1.4.x peer should not attempt validate or commit any transactions past this point. Before joining a channel, make sure the node is at least the Fabric version (binary) level of the capabilities specified in the channel config relevant to the node. We’ll discuss which capabilities are relevant to which nodes later. However, because no user wants their nodes to crash, it is strongly recommended to update all nodes to the required level (preferably, to the latest release) before attempting to update capabilities. This is in line with the default Fabric recommendation to always be at the latest binary and capability levels.

If users are unable to upgrade their binaries, then capabilities must be left at their lower levels. Lower level binaries and capabilities will still work together as they’re meant to. However, keep in mind that it is a best practice to always update to new binaries even if a user chooses not to update their capabilities. Because capabilities themselves also include bug-fixes, it is always recommended to update capabilities once the network binaries support them.

Capability configuration groupings¶
As we discussed earlier, there is not a single capability level encompassing an entire channel. Rather, there are three capabilities, each representing an area of administration.

Orderer: These capabilities govern tasks and processing exclusive to the ordering service. Because these capabilities do not involve processes that affect transactions or the peers, updating them falls solely to the ordering service admins (peers do not need to understand orderer capabilities and will therefore not crash no matter what the orderer capability is updated to). Note that these capabilities did not change between v1.1 and v1.4.2. However, as we’ll see in the channel section, this does not mean that v1.1 ordering nodes will work on all channels with capability levels below v1.4.2.
Application: These capabilities govern tasks and processing exclusive to the peers. Because ordering service admins have no role in deciding the nature of transactions between peer organizations, changing this capability level falls exclusively to peer organizations. For example, Private Data can only be enabled on a channel with the v1.2 (or higher) application group capability enabled. In the case of Private Data, this is the only capability that must be enabled, as nothing about the way Private Data works requires a change to channel administration or the way the ordering service processes transactions.
Channel: This grouping encompasses tasks that are jointly administered by the peer organizations and the ordering service. For example, this is the capability that defines the level at which channel configuration updates, which are initiated by peer organizations and orchestrated by the ordering service, are processed. On a practical level, this grouping defines the minimum level for all of the binaries in a channel, as both ordering nodes and peers must be at least at the binary level corresponding to this capability in order to process the capability.

The orderer and channel capabilities of a channel are inherited by default from the ordering system channel, where modifying them are the exclusive purview of ordering service admins. As a result, peer organizations should inspect the genesis block of a channel prior to joining their peers to that channel. Although the channel capability is administered by the orderers in the orderer system channel (just as the consortium membership is), it is typical and expected that the ordering admins will coordinate with the consortium admins to ensure that the channel capability is only upgraded when the consortium is ready for it.
Because the ordering system channel does not define an application capability, this capability must be specified in the channel profile when creating the genesis block for the channel.
Take caution when specifying or modifying an application capability. Because the ordering service does not validate that the capability level exists, it will allow a channel to be created (or modified) to contain, for example, a v1.8 application capability even if no such capability exists. Any peer attempting to read a configuration block with this capability would, as we have shown, crash, and even if it was possible to modify the channel once again to a valid capability level, it would not matter, as no peer would be able to get past the block with the invalid v1.8 capability.
For a full look at the current valid orderer, application, and channel capabilities check out a sample configtx.yaml file, which lists them in the “Capabilities” section.
For more specific information about capabilities and where they reside in the channel configuration, check out defining capability requirements.

Use Cases¶
The Hyperledger Requirements WG is documenting a number of blockchain use
cases and maintaining an inventory
here.

Getting Started¶

Prerequisites¶
Before you begin, you should confirm that you have installed all the prerequisites below on the platform where you will be running Hyperledger Fabric.

Note
These prerequisites are recommended for Fabric users. If you are a Fabric developer you should refer to the instructions for Setting up the development environment.

Install Git¶
Download the latest version of git if it is not already installed,
or if you have problems running the curl commands.

Install cURL¶
Download the latest version of the cURL tool if it is not already
installed or if you get errors running the curl commands from the
documentation.

Note
If you’re on Windows please see the specific note on Windows
extras below.

Docker and Docker Compose¶
You will need the following installed on the platform on which you will be
operating, or developing on (or for), Hyperledger Fabric:

MacOSX, *nix, or Windows 10: Docker
Docker version 17.06.2-ce or greater is required.
Older versions of Windows: Docker
Toolbox -
again, Docker version Docker 17.06.2-ce or greater is required.

You can check the version of Docker you have installed with the following
command from a terminal prompt:
docker --version

Note
The following applies to linux systems running systemd.

Make sure the docker daemon is running.
sudo systemctl start docker

Optional: If you want the docker daemon to start when the system starts, use the following:
sudo systemctl enable docker

Add your user to the docker group.
sudo usermod -a -G docker <username>

Note
Installing Docker for Mac or Windows, or Docker Toolbox will also
install Docker Compose. If you already had Docker installed, you
should check that you have Docker Compose version 1.14.0 or greater
installed. If not, we recommend that you install a more recent
version of Docker.

You can check the version of Docker Compose you have installed with the
following command from a terminal prompt:
docker-compose --version

Windows extras¶
On Windows 10 you should use the native Docker distribution and you
may use the Windows PowerShell. However, for the binaries
command to succeed you will still need to have the uname command
available. You can get it as part of Git but beware that only the
64bit version is supported.
Before running any git clone commands, run the following commands:
git config --global core.autocrlf false
git config --global core.longpaths true

You can check the setting of these parameters with the following commands:
git config --get core.autocrlf
git config --get core.longpaths

These need to be false and true respectively.
The curl command that comes with Git and Docker Toolbox is old and
does not handle properly the redirect used in
Getting Started. Make sure you have and use a newer version
which can be downloaded from the cURL downloads page

Note
If you have questions not addressed by this documentation, or run into
issues with any of the tutorials, please visit the Still Have Questions?
page for some tips on where to find additional help.

Install Samples, Binaries, and Docker Images¶
While we work on developing real installers for the Hyperledger Fabric
binaries, we provide a script that will download and install samples and
binaries to your system. We think that you’ll find the sample applications
installed useful to learn more about the capabilities and operations of
Hyperledger Fabric.

Note
If you are running on Windows you will want to make use of the
Docker Quickstart Terminal for the upcoming terminal commands.
Please visit the Prerequisites if you haven’t previously installed
it.
If you are using Docker Toolbox or macOS, you
will need to use a location under /Users (macOS) when installing and running the samples.
If you are using Docker for Mac, you will need to use a location
under /Users, /Volumes, /private, or /tmp.  To use a different
location, please consult the Docker documentation for
file sharing.
If you are using Docker for Windows, please consult the Docker
documentation for shared drives
and use a location under one of the shared drives.

Determine a location on your machine where you want to place the fabric-samples
repository and enter that directory in a terminal window. The
command that follows will perform the following steps:

If needed, clone the hyperledger/fabric-samples repository
Checkout the appropriate version tag
Install the Hyperledger Fabric platform-specific binaries and config files
for the version specified into the /bin and /config directories of fabric-samples
Download the Hyperledger Fabric docker images for the version specified

Once you are ready, and in the directory into which you will install the
Fabric Samples and binaries, go ahead and execute the command to pull down
the binaries and images.

Note
If you want the latest production release, omit all version identifiers.

curl -sSL https://bit.ly/2ysbOFE | bash -s

Note
If you want a specific release, pass a version identifier for Fabric,
Fabric-ca and thirdparty Docker images.
The command below demonstrates how to download the latest production releases -
Fabric v2.1.1 and Fabric CA v1.4.7

curl -sSL https://bit.ly/2ysbOFE | bash -s -- <fabric_version> <fabric-ca_version> <thirdparty_version>
curl -sSL https://bit.ly/2ysbOFE | bash -s -- 2.1.1 1.4.7 0.4.20

Note
If you get an error running the above curl command, you may
have too old a version of curl that does not handle
redirects or an unsupported environment.
Please visit the Prerequisites page for additional
information on where to find the latest version of curl and
get the right environment. Alternately, you can substitute
the un-shortened URL:
https://raw.githubusercontent.com/hyperledger/fabric/master/scripts/bootstrap.sh

The command above downloads and executes a bash script
that will download and extract all of the platform-specific binaries you
will need to set up your network and place them into the cloned repo you
created above. It retrieves the following platform-specific binaries:

configtxgen,
configtxlator,
cryptogen,
discover,
idemixgen
orderer,
peer,
fabric-ca-client,
fabric-ca-server

and places them in the bin sub-directory of the current working
directory.
You may want to add that to your PATH environment variable so that these
can be picked up without fully qualifying the path to each binary. e.g.:
export PATH=<path to download location>/bin:$PATH

Finally, the script will download the Hyperledger Fabric docker images from
Docker Hub into
your local Docker registry and tag them as ‘latest’.
The script lists out the Docker images installed upon conclusion.
Look at the names for each image; these are the components that will ultimately
comprise our Hyperledger Fabric network.  You will also notice that you have
two instances of the same image ID - one tagged as “amd64-1.x.x” and
one tagged as “latest”. Prior to 1.2.0, the image being downloaded was determined
by uname -m and showed as “x86_64-1.x.x”.

Note
On different architectures, the x86_64/amd64 would be replaced
with the string identifying your architecture.

Note
If you have questions not addressed by this documentation, or run into
issues with any of the tutorials, please visit the Still Have Questions?
page for some tips on where to find additional help.

Using the Fabric test network¶
After you have downloaded the Hyperledger Fabric Docker images and samples, you
can deploy a test network by using scripts that are provided in the
fabric-samples repository. You can use the test network to learn about Fabric
by running nodes on your local machine. More experienced developers can use the
network to test their smart contracts and applications. The network is meant to
be used only as a tool for education and testing. It should not be used as a
template for deploying a production network. The test network is being introduced
in Fabric v2.0 as the long term replacement for the first-network sample.
The sample network deploys a Fabric network with Docker Compose. Because the
nodes are isolated within a Docker Compose network, the test network is not
configured to connect to other running fabric nodes.
Note: These instructions have been verified to work against the
latest stable Docker images and the pre-compiled setup utilities within the
supplied tar file. If you run these commands with images or tools from the
current master branch, it is possible that you will encounter errors.

Before you begin¶
Before you can run the test network, you need to clone the fabric-samples
repository and download the Fabric images. Make sure that you have installed
the Prerequisites and Installed the Samples, Binaries and Docker Images.

Bring up the test network¶
You can find the scripts to bring up the network in the test-network directory
of the fabric-samples repository. Navigate to the test network directory by
using the following command:
cd fabric-samples/test-network

In this directory, you can find an annotated script, network.sh, that stands
up a Fabric network using the Docker images on your local machine. You can run
./network.sh -h to print the script help text:
Usage:
  network.sh <Mode> [Flags]
    <Mode>
      - 'up' - bring up fabric orderer and peer nodes. No channel is created
      - 'up createChannel' - bring up fabric network with one channel
      - 'createChannel' - create and join a channel after the network is created
      - 'deployCC' - deploy the fabcar chaincode on the channel
      - 'down' - clear the network with docker-compose down
      - 'restart' - restart the network

    Flags:
    -ca <use CAs> -  create Certificate Authorities to generate the crypto material
    -c <channel name> - channel name to use (defaults to "mychannel")
    -s <dbtype> - the database backend to use: goleveldb (default) or couchdb
    -r <max retry> - CLI times out after certain number of attempts (defaults to 5)
    -d <delay> - delay duration in seconds (defaults to 3)
    -l <language> - the programming language of the chaincode to deploy: go (default), java, javascript, typescript
    -v <version>  - chaincode version. Must be a round number, 1, 2, 3, etc
    -i <imagetag> - the tag to be used to launch the network (defaults to "latest")
    -cai <ca_imagetag> - the image tag to be used for CA (defaults to "1.4.6")
    -verbose - verbose mode
  network.sh -h (print this message)

 Possible Mode and flags
  network.sh up -ca -c -r -d -s -i -verbose
  network.sh up createChannel -ca -c -r -d -s -i -verbose
  network.sh createChannel -c -r -d -verbose
  network.sh deployCC -l -v -r -d -verbose

 Taking all defaults:
    network.sh up

 Examples:
  network.sh up createChannel -ca -c mychannel -s couchdb -i 2.0.0
  network.sh createChannel -c channelName
  network.sh deployCC -l javascript

From inside the test-network directory, run the following command to remove
any containers or artifacts from any previous runs:
./network.sh down

You can then bring up the network by issuing the following command. You will
experience problems if you try to run the script from another directory:
./network.sh up

This command creates a Fabric network that consists of two peer nodes, one
ordering node. No channel is created when you run ./network.sh up, though we
will get there in a future step. If the command completes
successfully, you will see the logs of the nodes being created:
Creating network "net_test" with the default driver
Creating volume "net_orderer.example.com" with default driver
Creating volume "net_peer0.org1.example.com" with default driver
Creating volume "net_peer0.org2.example.com" with default driver
Creating orderer.example.com    ... done
Creating peer0.org2.example.com ... done
Creating peer0.org1.example.com ... done
CONTAINER ID        IMAGE                               COMMAND             CREATED             STATUS                  PORTS                              NAMES
8d0c74b9d6af        hyperledger/fabric-orderer:latest   "orderer"           4 seconds ago       Up Less than a second   0.0.0.0:7050->7050/tcp             orderer.example.com
ea1cf82b5b99        hyperledger/fabric-peer:latest      "peer node start"   4 seconds ago       Up Less than a second   0.0.0.0:7051->7051/tcp             peer0.org1.example.com
cd8d9b23cb56        hyperledger/fabric-peer:latest      "peer node start"   4 seconds ago       Up 1 second             7051/tcp, 0.0.0.0:9051->9051/tcp   peer0.org2.example.com

If you don’t get this result, jump down to Troubleshooting
for help on what might have gone wrong. By default, the network uses the
cryptogen tool to bring up the network. However, you can also
bring up the network with Certificate Authorities.

The components of the test network¶
After your test network is deployed, you can take some time to examine its
components. Run the following command to list all of Docker containers that
are running on your machine. You should see the three nodes that were created by
the network.sh script:
docker ps -a

Each node and user that interacts with a Fabric network needs to belong to an
organization that is a network member. The group of organizations that are
members of a Fabric network are often referred to as the consortium. The test
network has two consortium members, Org1 and Org2. The network also includes one
orderer organization that maintains the ordering service of the network.
Peers are the fundamental components of any Fabric network.
Peers store the blockchain ledger and validate transactions before they are
committed to the ledger. Peers run the smart contracts that contain the business
logic that is used to manage the assets on the blockchain ledger.
Every peer in the network needs to belong to a member of the consortium. In the
test network, each organization operates one peer each, peer0.org1.example.com
and peer0.org2.example.com.
Every Fabric network also includes an ordering service.
While peers validate transactions and add blocks of transactions to the
blockchain ledger, they do not decide on the order of transactions or include
them into new blocks. On a distributed network, peers may be running far away
from each other and not have a common view of when a transaction was created.
Coming to consensus on the order of transactions is a costly process that would
create overhead for the peers.
An ordering service allows peers to focus on validating transactions and
committing them to the ledger. After ordering nodes receive endorsed transactions
from clients, they come to consensus on the order of transactions and then add
them to blocks. The blocks are then distributed to peer nodes, which add the
blocks the blockchain ledger. Ordering nodes also operate the system channel
that defines the capabilities of a Fabric network, such as how blocks are made
and which version of Fabric that nodes can use. The system channel defines which
organizations are members of the consortium.
The sample network uses a single node Raft ordering service that is operated by
the ordering organization. You can see the ordering node running on your machine
as orderer.example.com. While the test network only uses a single node ordering
service, a real network would have multiple ordering nodes, operated by one or
multiple orderer organizations. The different ordering nodes would use the Raft
consensus algorithm to come to agreement on the order of transactions across
the network.

Creating a channel¶
Now that we have peer and orderer nodes running on our machine, we can use the
script to create a Fabric channel for transactions between Org1 and Org2.
Channels are a private layer of communication between specific network members.
Channels can be used only by organizations that are invited to the channel, and
are invisible to other members of the network. Each channel has a separate
blockchain ledger. Organizations that have been invited “join” their peers to
the channel to store the channel ledger and validate the transactions on the
channel.
You can use the network.sh script to create a channel between Org1 and Org2
and join their peers to the channel. Run the following command to create a
channel with the default name of mychannel:
./network.sh createChannel

If the command was successful, you can see the following message printed in your
logs:
========= Channel successfully joined ===========

You can also use the channel flag to create a channel with custom name. As an
example, the following command would create a channel named channel1:
./network.sh createChannel -c channel1

The channel flag also allows you to create multiple channels by specifying
different channel names. After you create mychannel or channel1, you can use
the command below to create a second channel named channel2:
./network.sh createChannel -c channel2

If you want to bring up the network and create a channel in a single step, you
can use the up and createChannel modes together:
./network.sh up createChannel

Starting a chaincode on the channel¶
After you have created a channel, you can start using smart contracts to
interact with the channel ledger. Smart contracts contain the business logic
that governs assets on the blockchain ledger. Applications run by members of the
network can invoke smart contracts to create assets on the ledger, as well as
change and transfer those assets. Applications also query smart contracts to
read data on the ledger.
To ensure that transactions are valid, transactions created using smart contracts
typically need to be signed by multiple organizations to be committed to the
channel ledger. Multiple signatures are integral to the trust model of Fabric.
Requiring multiple endorsements for a transaction prevents one organization on
a channel from tampering with the ledger on their peer or using business logic
that was not agreed to. To sign a transaction, each organization needs to invoke
and execute the smart contract on their peer, which then signs the output of the
transaction. If the output is consistent and has been signed by enough
organizations, the transaction can be committed to the ledger. The policy that
specifies the set organizations on the channel that need to execute the smart
contract is referred to as the endorsement policy, which is set for each
chaincode as part of the chaincode definition.
In Fabric, smart contracts are deployed on the network in packages referred to
as chaincode. A Chaincode is installed on the peers of an organization and then
deployed to a channel, where it can then be used to endorse transactions and
interact with the blockchain ledger. Before a chaincode can be deployed to a
channel, the members of the channel need to agree on a chaincode definition that
establishes chaincode governance. When the required number of organizations
agree, the chaincode definition can be committed to the channel, and the
chaincode is ready to be used.
After you have used the network.sh to create a channel, you can start a
chaincode on the channel using the following command:
./network.sh deployCC

The deployCC subcommand will install the fabcar chaincode on
peer0.org1.example.com and peer0.org2.example.com and then deploy
the chaincode on the channel specified using the channel flag (or mychannel
if no channel is specified).  If you are deploying a chaincode for the first
time, the script will install the chaincode dependencies. By default, The script
installs the Go version of the fabcar chaincode. However, you can use the
language flag, -l, to install the Java or javascript versions of the chaincode.
You can find the Fabcar chaincode in the chaincode folder of the fabric-samples
directory. This folder contains sample chaincode that are provided as examples and
used by tutorials to highlight Fabric features.
After the fabcar chaincode definition has been committed to the channel, the
script initializes the chaincode by invoking the init function and then invokes
the chaincode to put an initial list of cars on the ledger. The script then
queries the chaincode to verify the that the data was added. If the chaincode was
installed, deployed, and invoked correctly, you should see the following list of
cars printed in your logs:
[{"Key":"CAR0", "Record":{"make":"Toyota","model":"Prius","colour":"blue","owner":"Tomoko"}},
{"Key":"CAR1", "Record":{"make":"Ford","model":"Mustang","colour":"red","owner":"Brad"}},
{"Key":"CAR2", "Record":{"make":"Hyundai","model":"Tucson","colour":"green","owner":"Jin Soo"}},
{"Key":"CAR3", "Record":{"make":"Volkswagen","model":"Passat","colour":"yellow","owner":"Max"}},
{"Key":"CAR4", "Record":{"make":"Tesla","model":"S","colour":"black","owner":"Adriana"}},
{"Key":"CAR5", "Record":{"make":"Peugeot","model":"205","colour":"purple","owner":"Michel"}},
{"Key":"CAR6", "Record":{"make":"Chery","model":"S22L","colour":"white","owner":"Aarav"}},
{"Key":"CAR7", "Record":{"make":"Fiat","model":"Punto","colour":"violet","owner":"Pari"}},
{"Key":"CAR8", "Record":{"make":"Tata","model":"Nano","colour":"indigo","owner":"Valeria"}},
{"Key":"CAR9", "Record":{"make":"Holden","model":"Barina","colour":"brown","owner":"Shotaro"}}]
===================== Query successful on peer0.org1 on channel 'mychannel' =====================

Interacting with the network¶
After you bring up the test network, you can use the peer CLI to interact
with your network. The peer CLI allows you to invoke deployed smart contracts,
update channels, or install and deploy new smart contracts from the CLI.
Make sure that you are operating from the test-network directory. If you
followed the instructions to install the Samples, Binaries and Docker Images,
You can find the peer binaries in the bin folder of the fabric-samples
repository. Use the following command to add those binaries to your CLI Path:
export PATH=${PWD}/../bin:$PATH

You also need to set the FABRIC_CFG_PATH to point to the core.yaml file in
the fabric-samples repository:
export FABRIC_CFG_PATH=$PWD/../config/

You can now set the environment variables that allow you to operate the peer
CLI as Org1:
# Environment variables for Org1

export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

The CORE_PEER_TLS_ROOTCERT_FILE and CORE_PEER_MSPCONFIGPATH environment
variables point to the Org1 crypto material in the organizations folder.
If you used ./network.sh deployCC to install and start the fabcar chaincode,
you can now query the ledger from your CLI. Run the following command to get the
list of cars that were added to your channel ledger:
peer chaincode query -C mychannel -n fabcar -c '{"Args":["queryAllCars"]}'

If the command is successful, you can see the same list of cars that were printed
in the logs when you ran the script:
[{"Key":"CAR0", "Record":{"make":"Toyota","model":"Prius","colour":"blue","owner":"Tomoko"}},
{"Key":"CAR1", "Record":{"make":"Ford","model":"Mustang","colour":"red","owner":"Brad"}},
{"Key":"CAR2", "Record":{"make":"Hyundai","model":"Tucson","colour":"green","owner":"Jin Soo"}},
{"Key":"CAR3", "Record":{"make":"Volkswagen","model":"Passat","colour":"yellow","owner":"Max"}},
{"Key":"CAR4", "Record":{"make":"Tesla","model":"S","colour":"black","owner":"Adriana"}},
{"Key":"CAR5", "Record":{"make":"Peugeot","model":"205","colour":"purple","owner":"Michel"}},
{"Key":"CAR6", "Record":{"make":"Chery","model":"S22L","colour":"white","owner":"Aarav"}},
{"Key":"CAR7", "Record":{"make":"Fiat","model":"Punto","colour":"violet","owner":"Pari"}},
{"Key":"CAR8", "Record":{"make":"Tata","model":"Nano","colour":"indigo","owner":"Valeria"}},
{"Key":"CAR9", "Record":{"make":"Holden","model":"Barina","colour":"brown","owner":"Shotaro"}}]

Chaincodes are invoked when a network member wants to transfer or change an
asset on the ledger. Use the following command to change the owner of a car on
the ledger by invoking the fabcar chaincode:
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n fabcar --peerAddresses localhost:7051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses localhost:9051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"function":"changeCarOwner","Args":["CAR9","Dave"]}'

If the command is successful, you should see the following response:
2019-12-04 17:38:21.048 EST [chaincodeCmd] chaincodeInvokeOrQuery -> INFO 001 Chaincode invoke successful. result: status:200

Note: If you deployed the Java chaincode, run the invoke command with the
following arguments instead: '{"function":"changeCarOwner","Args":["CAR009","Dave"]}'
The Fabcar chaincode written in Java uses a different index than the chaincode
written in Javascipt or Go.
Because the endorsement policy for the fabcar chaincode requires the transaction
to be signed by Org1 and Org2, the chaincode invoke command needs to target both
peer0.org1.example.com and peer0.org2.example.com using the --peerAddresses
flag. Because TLS is enabled for the network, the command also needs to reference
the TLS certificate for each peer using the --tlsRootCertFiles flag.
After we invoke the chaincode, we can use another query to see how the invoke
changed the assets on the blockchain ledger. Since we already queried the Org1
peer, we can take this opportunity to query the chaincode running on the Org2
peer. Set the following environment variables to operate as Org2:
# Environment variables for Org2

export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

You can now query the fabcar chaincode running on peer0.org2.example.com:
peer chaincode query -C mychannel -n fabcar -c '{"Args":["queryCar","CAR9"]}'

The result will show that "CAR9" was transferred to Dave:
{"make":"Holden","model":"Barina","colour":"brown","owner":"Dave"}

Bring down the network¶
When you are finished using the test network, you can bring down the network
with the following command:
./network.sh down

The command will stop and remove the node and chaincode containers, delete the
organization crypto material, and remove the chaincode images from your Docker
Registry. The command also removes the channel artifacts and docker volumes from
previous runs, allowing you to run ./network.sh up again if you encountered
any problems.

Next steps¶
Now that you have used the test network to deploy Hyperledger Fabric on your
local machine, you can use the tutorials to start developing your own solution:

Learn how to deploy your own smart contracts to the test network using the
Deploying a smart contract to a channel tutorial.
Visit the Writing Your First Application tutorial
to learn how to use the APIs provided by the Fabric SDKs to invoke smart
contracts from your client applications.
If you are ready to deploy a more complicated smart contract to the network, follow
the commercial paper tutorial to explore a
use case in which two organizations use a blockchain network to trade commercial
paper.

You can find the the complete list of Fabric tutorials on the tutorials
page.

Bring up the network with Certificate Authorities¶
Hyperledger Fabric uses public key infrastructure (PKI) to verify the actions of
all network participants. Every node, network administrator, and user submitting
transactions needs to have a public certificate and private key to verify their
identity. These identities need to have a valid root of trust, establishing
that the certificates were issued by an organization that is a member of the
network. The network.sh script creates all of the cryptographic material
that is required to deploy and operate the network before it creates the peer
and ordering nodes.
By default, the script uses the cryptogen tool to create the certificates
and keys. The tool is provided for development and testing, and can quickly
create the required crypto material for Fabric organizations with a valid root
of trust. When you run ./network.sh up, you can see the cryptogen tool creating
the certificates and keys for Org1, Org2, and the Orderer Org.
creating Org1, Org2, and ordering service organization with crypto from 'cryptogen'

/Usr/fabric-samples/test-network/../bin/cryptogen

##########################################################
##### Generate certificates using cryptogen tool #########
##########################################################

##########################################################
############ Create Org1 Identities ######################
##########################################################
+ cryptogen generate --config=./organizations/cryptogen/crypto-config-org1.yaml --output=organizations
org1.example.com
+ res=0
+ set +x
##########################################################
############ Create Org2 Identities ######################
##########################################################
+ cryptogen generate --config=./organizations/cryptogen/crypto-config-org2.yaml --output=organizations
org2.example.com
+ res=0
+ set +x
##########################################################
############ Create Orderer Org Identities ###############
##########################################################
+ cryptogen generate --config=./organizations/cryptogen/crypto-config-orderer.yaml --output=organizations
+ res=0
+ set +x

However, the test network script also provides the option to bring up the network using
Certificate Authorities (CAs). In a production network, each organization
operates a CA (or multiple intermediate CAs) that creates the identities that
belong to their organization. All of the identities created by a CA run by the
organization share the same root of trust. Although it takes more time than
using cryptogen, bringing up the test network using CAs provides an introduction
to how a network is deployed in production. Deploying CAs also allows you to enroll
client identities with the Fabric SDKs and create a certificate and private key
for your applications.
If you would like to bring up a network using Fabric CAs, first run the following
command to bring down any running networks:
./network.sh down

You can then bring up the network with the CA flag:
./network.sh up -ca

After you issue the command, you can see the script bringing up three CAs, one
for each organization in the network.
##########################################################
##### Generate certificates using Fabric CA's ############
##########################################################
Creating network "net_default" with the default driver
Creating ca_org2    ... done
Creating ca_org1    ... done
Creating ca_orderer ... done

It is worth taking time to examine the logs generated by the ./network.sh
script after the CAs have been deployed. The test network uses the Fabric CA
client to register node and user identities with the CA of each organization. The
script then uses the enroll command to generate an MSP folder for each identity.
The MSP folder contains the certificate and private key for each identity, and
establishes the identity’s role and membership in the organization that operated
the CA. You can use the following command to examine the MSP folder of the Org1
admin user:
tree organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/

The command will reveal the MSP folder structure and configuration file:
organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/
└── msp
    ├── IssuerPublicKey
    ├── IssuerRevocationPublicKey
    ├── cacerts
    │   └── localhost-7054-ca-org1.pem
    ├── config.yaml
    ├── keystore
    │   └── 58e81e6f1ee8930df46841bf88c22a08ae53c1332319854608539ee78ed2fd65_sk
    ├── signcerts
    │   └── cert.pem
    └── user

You can find the certificate of the admin user in the signcerts folder and the
private key in the keystore folder. To learn more about MSPs, see the Membership Service Provider
concept topic.
Both cryptogen and the Fabric CAs generate the cryptographic material for each organization
in the organizations folder. You can find the commands that are used to set up the
network in the registerEnroll.sh script in the organizations/fabric-ca directory.
To learn more about how you would use the Fabric CA to deploy a Fabric network,
visit the Fabric CA operations guide.
You can learn more about how Fabric uses PKI by visiting the identity
and membership concept topics.

What’s happening behind the scenes?¶
If you are interested in learning more about the sample network, you can
investigate the files and scripts in the test-network directory. The steps
below provide a guided tour of what happens when you issue the command of
./network.sh up.

./network.sh creates the certificates and keys for two peer organizations
and the orderer organization. By default, the script uses the cryptogen tool
using the configuration files located in the organizations/cryptogen folder.
If you use the -ca flag to create Certificate Authorities, the script uses
Fabric CA server configuration files and registerEnroll.sh script located in
the organizations/fabric-ca folder. Both cryptogen and the Fabric CAs create
the crypto material and MSP folders for all three organizations in the
organizations folder.
The script uses configtxgen tool to create the system channel genesis block.
Configtxgen consumes the TwoOrgsOrdererGenesis  channel profile in the
configtx/configtx.yaml file to create the genesis block. The block is stored
in the system-genesis-block folder.
Once the organization crypto material and the system channel genesis block have
been generated, the network.sh can bring up the nodes of the network. The
script uses the docker-compose-test-net.yaml file in the docker folder
to create the peer and orderer nodes. The docker folder also contains the
docker-compose-e2e.yaml file that brings up the nodes of the network
alongside three Fabric CAs. This file is meant to be used to run end-to-end
tests by the Fabric SDK. Refer to the Node SDK
repo for details on running these tests.
If you use the createChannel subcommand, ./network.sh runs the
createChannel.sh script in the scripts folder to create a channel
using the supplied channel name. The script uses the configtx.yaml file to
create the channel creation transaction, as well as two anchor peer update
transactions. The script uses the peer cli to create the channel, join
peer0.org1.example.com and peer0.org2.example.com to the channel, and
make both of the peers anchor peers.
If you issue the deployCC command, ./network.sh runs the deployCC.sh
script to install the fabcar chaincode on both peers and then define then
chaincode on the channel. Once the chaincode definition is committed to the
channel, the peer cli initializes the chainocde using the Init and invokes
the chaincode to put initial data on the ledger.

Troubleshooting¶
If you have any problems with the tutorial, review the following:

You should always start your network fresh. You can use the following command
to remove the artifacts, crypto material, containers, volumes, and chaincode
images from previous runs:
./network.sh down

You will see errors if you do not remove old containers, images, and
volumes.

If you see Docker errors, first check your Docker version (Prerequisites),
and then try restarting your Docker process. Problems with Docker are
oftentimes not immediately recognizable. For example, you may see errors
that are the result of your node not being able to access the crypto material
mounted within a container.
If problems persist, you can remove your images and start from scratch:
docker rm -f $(docker ps -aq)
docker rmi -f $(docker images -q)

If you see errors on your create, approve, commit, invoke or query commands,
make sure you have properly updated the channel name and chaincode name.
There are placeholder values in the supplied sample commands.

If you see the error below:
Error: Error endorsing chaincode: rpc error: code = 2 desc = Error installing chaincode code mycc:1.0(chaincode /var/hyperledger/production/chaincodes/mycc.1.0 exits)

You likely have chaincode images (e.g. dev-peer1.org2.example.com-fabcar-1.0 or
dev-peer0.org1.example.com-fabcar-1.0) from prior runs. Remove them and try
again.
docker rmi -f $(docker images | grep dev-peer[0-9] | awk '{print $3}')

If you see the below error:
[configtx/tool/localconfig] Load -> CRIT 002 Error reading configuration: Unsupported Config Type ""
panic: Error reading configuration: Unsupported Config Type ""

Then you did not set the FABRIC_CFG_PATH environment variable properly. The
configtxgen tool needs this variable in order to locate the configtx.yaml. Go
back and execute an export FABRIC_CFG_PATH=$PWD/configtx/configtx.yaml,
then recreate your channel artifacts.

If you see an error stating that you still have “active endpoints”, then prune
your Docker networks. This will wipe your previous networks and start you with a
fresh environment:
docker network prune

You will see the following message:
WARNING! This will remove all networks not used by at least one container.
Are you sure you want to continue? [y/N]

Select y.

If you see an error similar to the following:
/bin/bash: ./scripts/createChannel.sh: /bin/bash^M: bad interpreter: No such file or directory

Ensure that the file in question (createChannel.sh in this example) is
encoded in the Unix format. This was most likely caused by not setting
core.autocrlf to false in your Git configuration (see
Windows extras). There are several ways of fixing this. If you have
access to the vim editor for instance, open the file:
vim ./fabric-samples/test-network/scripts/createChannel.sh

Then change its format by executing the following vim command:
:set ff=unix

If your orderer exits upon creation or if you see that the create channel
command fails due to an inability to connect to your ordering service, use
the docker logs command to read the logs from the ordering node. You may see
the following message:
PANI 007 [channel system-channel] config requires unsupported orderer capabilities: Orderer capability V2_0 is required but not supported: Orderer capability V2_0 is required but not supported

This occurs when you are trying to run the network using Fabric version 1.4.x
docker images. The test network needs to run using Fabric version 2.x.

If you continue to see errors, share your logs on the fabric-questions
channel on Hyperledger Rocket Chat or on
StackOverflow.

Before we begin, if you haven’t already done so, you may wish to check that
you have all the Prerequisites installed on the platform(s)
on which you’ll be developing blockchain applications and/or operating
Hyperledger Fabric.
Once you have the prerequisites installed, you are ready to download and
install HyperLedger Fabric. While we work on developing real installers for the
Fabric binaries, we provide a script that will Install Samples, Binaries, and Docker Images to your system.
The script also will download the Docker images to your local registry.
After you have downloaded the Fabric Samples and Docker images to your local
machine, you can get started working with Fabric with the
Using the Fabric test network tutorial.

Hyperledger Fabric smart contract (chaincode) APIs¶
Hyperledger Fabric offers a number of APIs to support developing smart contracts (chaincode)
in various programming languages. Smart contract APIs are available for Go, Node.js, and Java:

Go contract-api.
Node.js contract API and Node.js contract API documentation.
Java contract API and Java contract API documentation.

Hyperledger Fabric application SDKs¶
Hyperledger Fabric offers a number of SDKs to support developing applications in various programming languages. SDKs are available for Node.js and Java:

Node.js SDK and Node.js SDK documentation.
Java SDK and Java SDK documentation.

Prerequisites for developing with the SDKs can be found in the Node.js SDK README and Java SDK README.

In addition, there are two more application SDKs that have not yet been officially released
(for Python and Go), but they are still available for downloading and testing:

Python SDK.
Go SDK.

Currently, Node.js and Java support the new application programming model delivered in Hyperledger Fabric v1.4. Support for Go is planned to be delivered in a later release.

Hyperledger Fabric CA¶
Hyperledger Fabric provides an optional
certificate authority service
that you may choose to use to generate the certificates and key material
to configure and manage identity in your blockchain network. However, any CA
that can generate ECDSA certificates may be used.

Developing Applications¶

The scenario¶
Audience: Architects, Application and smart contract developers, Business
professionals
In this topic, we’re going to describe a business scenario involving six
organizations who use PaperNet, a commercial paper network built on Hyperledger
Fabric, to issue, buy and redeem commercial paper. We’re going to use the
scenario to outline requirements for the development of commercial paper
applications and smart contracts used by the participant organizations.

PaperNet network¶
PaperNet is a commercial paper network that allows suitably authorized
participants to issue, trade, redeem and rate commercial paper.

The PaperNet commercial paper network. Six organizations currently use PaperNet
network to issue, buy, sell, redeem and rate commercial paper. MagentoCorp
issues and redeems commercial paper.  DigiBank, BigFund, BrokerHouse and
HedgeMatic all trade commercial paper with each other. RateM provides various
measures of risk for commercial paper.
Let’s see how MagnetoCorp uses PaperNet and commercial paper to help its
business.

Introducing the actors¶
MagnetoCorp is a well-respected company that makes self-driving electric
vehicles. In early April 2020, MagnetoCorp won a large order to manufacture
10,000 Model D cars for Daintree, a new entrant in the personal transport
market. Although the order represents a significant win for MagnetoCorp,
Daintree will not have to pay for the vehicles until they start to be delivered
on November 1, six months after the deal was formally agreed between MagnetoCorp
and Daintree.
To manufacture the vehicles, MagnetoCorp will need to hire 1000 workers for at
least 6 months. This puts a short term strain on its finances – it will require
an extra 5M USD each month to pay these new employees. Commercial paper is
designed to help MagnetoCorp overcome its short term financing needs – to meet
payroll every month based on the expectation that it will be cash rich when
Daintree starts to pay for its new Model D cars.
At the end of May, MagnetoCorp needs 5M USD to meet payroll for the extra
workers it hired on May 1. To do this, it issues a commercial paper with a face
value of 5M USD with a maturity date 6 months in the future – when it expects
to see cash flow from Daintree. DigiBank thinks that MagnetoCorp is
creditworthy, and therefore doesn’t require much of a premium above the central
bank base rate of 2%, which would value 4.95M USD today at 5M USD in 6 months
time. It therefore purchases the MagnetoCorp 6 month commercial paper for 4.94M
USD – a slight discount compared to the 4.95M USD it is worth. DigiBank fully
expects that it will be able to redeem 5M USD from MagnetoCorp in 6 months time,
making it a profit of 10K USD for bearing the increased risk associated with
this commercial paper. This extra 10K means it receives a 2.4% return on
investment – significantly better than the risk free return of 2%.
At the end of June, when MagnetoCorp issues a new commercial paper for 5M USD to
meet June’s payroll, it is purchased by BigFund for 4.94M USD.  That’s because
the commercial conditions are roughly the same in June as they are in May,
resulting in BigFund valuing MagnetoCorp commercial paper at the same price that
DigiBank did in May.
Each subsequent month, MagnetoCorp can issue new commercial paper to meet its
payroll obligations, and these may be purchased by DigiBank, or any other
participant in the PaperNet commercial paper network – BigFund, HedgeMatic or
BrokerHouse. These organizations may pay more or less for the commercial paper
depending on two factors – the central bank base rate, and the risk associated
with MagnetoCorp. This latter figure depends on a variety of factors such as the
production of Model D cars, and the creditworthiness of MagnetoCorp as assessed
by RateM, a ratings agency.
The organizations in PaperNet have different roles, MagnetoCorp issues paper,
DigiBank, BigFund, HedgeMatic and BrokerHouse trade paper and RateM rates paper.
Organizations of the same role, such as DigiBank, Bigfund, HedgeMatic and
BrokerHouse are competitors. Organizations of different roles are not
necessarily competitors, yet might still have opposing business interest, for
example MagentoCorp will desire a high rating for its papers to sell them at
a high price, while DigiBank would benefit from a low rating, such that it can
buy them at a low price. As can be seen, even a seemingly simple network such
as PaperNet can have complex trust relationships. A blockchain can help
establish trust among organizations that are competitors or have opposing
business interests that might lead to disputes. Fabric in particular has the
means to capture even fine-grained trust relationships.
Let’s pause the MagnetoCorp story for a moment, and develop the client
applications and smart contracts that PaperNet uses to issue, buy, sell and
redeem commercial paper as well as capture the trust relationships between
the organizations.  We’ll come back to the role of the rating agency,
RateM, a little later.

Analysis¶
Audience: Architects, Application and smart contract developers, Business
professionals
Let’s analyze commercial paper in a little more detail. PaperNet participants
such as MagnetoCorp and DigiBank use commercial paper transactions to achieve
their business objectives – let’s examine the structure of a commercial paper
and the transactions that affect it over time. We will also consider which
organizations in PaperNet need to sign off on a transaction based on the trust
relationships among the organizations in the network. Later we’ll focus on how
money flows between buyers and sellers; for now, let’s focus on the first paper
issued by MagnetoCorp.

Commercial paper lifecycle¶
A paper 00001 is issued by MagnetoCorp on May 31. Spend a few moments looking at
the first state of this paper, with its different properties and values:
Issuer = MagnetoCorp
Paper = 00001
Owner = MagnetoCorp
Issue date = 31 May 2020
Maturity = 30 November 2020
Face value = 5M USD
Current state = issued

This paper state is a result of the issue transaction and it brings
MagnetoCorp’s first commercial paper into existence! Notice how this paper has a
5M USD face value for redemption later in the year. See how the Issuer and
Owner are the same when paper 00001 is issued. Notice that this paper could be
uniquely identified as MagnetoCorp00001 – a composition of the Issuer and
Paper properties. Finally, see how the property Current state = issued
quickly identifies the stage of MagnetoCorp paper 00001 in its lifecycle.
Shortly after issuance, the paper is bought by DigiBank. Spend a few moments
looking at how the same commercial paper has changed as a result of this buy
transaction:
Issuer = MagnetoCorp
Paper = 00001
Owner = DigiBank
Issue date = 31 May 2020
Maturity date = 30 November 2020
Face value = 5M USD
Current state = trading

The most significant change is that of Owner – see how the paper initially
owned by MagnetoCorp is now owned by DigiBank.  We could imagine how the
paper might be subsequently sold to BrokerHouse or HedgeMatic, and the
corresponding change to Owner. Note how Current state allow us to easily
identify that the paper is now trading.
After 6 months, if DigiBank still holds the commercial paper, it can redeem
it with MagnetoCorp:
Issuer = MagnetoCorp
Paper = 00001
Owner = MagnetoCorp
Issue date = 31 May 2020
Maturity date = 30 November 2020
Face value = 5M USD
Current state = redeemed

This final redeem transaction has ended the commercial paper’s lifecycle –
it can be considered closed. It is often mandatory to keep a record of redeemed
commercial papers, and the redeemed state allows us to quickly identify these.
The value of Owner of a paper can be used to perform access control on the
redeem transaction, by comparing the Owner against the identity of the
transaction creator. Fabric supports this through the
getCreator() chaincode API.
If Go is used as a chaincode language, the client identity chaincode library
can be used to retrieve additional attributes of the transaction creator.

Transactions¶
We’ve seen that paper 00001’s lifecycle is relatively straightforward – it
moves between issued, trading and redeemed as a result of an issue,
buy, or redeem transaction.
These three transactions are initiated by MagnetoCorp and DigiBank (twice), and
drive the state changes of paper 00001. Let’s have a look at the transactions
that affect this paper in a little more detail:

Issue¶
Examine the first transaction initiated by MagnetoCorp:
Txn = issue
Issuer = MagnetoCorp
Paper = 00001
Issue time = 31 May 2020 09:00:00 EST
Maturity date = 30 November 2020
Face value = 5M USD

See how the issue transaction has a structure with properties and values.
This transaction structure is different to, but closely matches, the structure
of paper 00001. That’s because they are different things – paper 00001 reflects
a state of PaperNet that is a result of the issue transaction. It’s the
logic behind the issue transaction (which we cannot see) that takes these
properties and creates this paper. Because the transaction creates the
paper, it means there’s a very close relationship between these structures.
The only organization that is involved in the issue transaction is MagnetoCorp.
Naturally, MagnetoCorp needs to sign off on the transaction. In general, the issuer
of a paper is required to sign off on a transaction that issues a new paper.

Buy¶
Next, examine the buy transaction which transfers ownership of paper 00001
from MagnetoCorp to DigiBank:
Txn = buy
Issuer = MagnetoCorp
Paper = 00001
Current owner = MagnetoCorp
New owner = DigiBank
Purchase time = 31 May 2020 10:00:00 EST
Price = 4.94M USD

See how the buy transaction has fewer properties that end up in this paper.
That’s because this transaction only modifies this paper. It’s only New owner = DigiBank that changes as a result of this transaction; everything else
is the same. That’s OK – the most important thing about the buy transaction
is the change of ownership, and indeed in this transaction, there’s an
acknowledgement of the current owner of the paper, MagnetoCorp.
You might ask why the Purchase time and Price properties are not captured in
paper 00001? This comes back to the difference between the transaction and the
paper. The 4.94 M USD price tag is actually a property of the transaction,
rather than a property of this paper. Spend a little time thinking about
this difference; it is not as obvious as it seems. We’re going to see later
that the ledger will record both pieces of information – the history of all
transactions that affect this paper, as well its latest state. Being clear on
this separation of information is really important.
It’s also worth remembering that paper 00001 may be bought and sold many times.
Although we’re skipping ahead a little in our scenario, let’s examine what
transactions we might see if paper 00001 changes ownership.
If we have a purchase by BigFund:
Txn = buy
Issuer = MagnetoCorp
Paper = 00001
Current owner = DigiBank
New owner = BigFund
Purchase time = 2 June 2020 12:20:00 EST
Price = 4.93M USD

Followed by a subsequent purchase by HedgeMatic:
Txn = buy
Issuer = MagnetoCorp
Paper = 00001
Current owner = BigFund
New owner = HedgeMatic
Purchase time = 3 June 2020 15:59:00 EST
Price = 4.90M USD

See how the paper owners changes, and how in our example, the price changes. Can
you think of a reason why the price of MagnetoCorp commercial paper might be
falling?
Intuitively, a buy transaction demands that both the selling as well as the
buying organization need to sign off on such a transaction such that there is
proof of the mutual agreement among the two parties that are part of the deal.

Redeem¶
The redeem transaction for paper 00001 represents the end of its lifecycle.
In our relatively simple example, HedgeMatic initiates the transaction which
transfers the commercial paper back to MagnetoCorp:
Txn = redeem
Issuer = MagnetoCorp
Paper = 00001
Current owner = HedgeMatic
Redeem time = 30 Nov 2020 12:00:00 EST

Again, notice how the redeem transaction has very few properties; all of the
changes to paper 00001 can be calculated data by the redeem transaction logic:
the Issuer will become the new owner, and the Current state will change to
redeemed. The Current owner property is specified in our example, so that it
can be checked against the current holder of the paper.
From a trust perspective, the same reasoning of the buy transaction also
applies to the redeem instruction: both organizations involved in the
transaction are required to sign off on it.

The Ledger¶
In this topic, we’ve seen how transactions and the resultant paper states are
the two most important concepts in PaperNet. Indeed, we’ll see these two
fundamental elements in any Hyperledger Fabric distributed
ledger – a world state, that contains the current
value of all objects, and a blockchain that records the history of all
transactions that resulted in the current world state.
The required sign-offs on transactions are enforced through rules, which
are evaluated before appending a transaction to the ledger. Only if the
required signatures are present, Fabric will accept a transaction as valid.
You’re now in a great place translate these ideas into a smart contract. Don’t
worry if your programming is a little rusty, we’ll provide tips and pointers to
understand the program code. Mastering the commercial paper smart contract is
the first big step towards designing your own application. Or, if you’re a
business analyst who’s comfortable with a little programming, don’t be afraid to
keep dig a little deeper!

Process and Data Design¶
Audience: Architects, Application and smart contract developers, Business
professionals
This topic shows you how to design the commercial paper processes and their
related data structures in PaperNet. Our analysis highlighted
that modelling PaperNet using states and transactions provided a precise way to
understand what’s happening. We’re now going to elaborate on these two strongly
related concepts to help us subsequently design the smart contracts and
applications of PaperNet.

Lifecycle¶
As we’ve seen, there are two important concepts that concern us when dealing
with commercial paper; states and transactions. Indeed, this is true for
all blockchain use cases; there are conceptual objects of value, modeled as
states, whose lifecycle transitions are described by transactions. An effective
analysis of states and transactions is an essential starting point for a
successful implementation.
We can represent the life cycle of a commercial paper using a state transition
diagram:
 The state transition
diagram for commercial paper. Commercial papers transition between issued,
trading and redeemed states by means of the issue, buy and
redeem transactions.
See how the state diagram describes how commercial papers change over time, and
how specific transactions govern the life cycle transitions. In Hyperledger
Fabric, smart contracts implement transaction logic that transition commercial
papers between their different states. Commercial paper states are actually held
in the ledger world state; so let’s take a closer look at them.

Ledger state¶
Recall the structure of a commercial paper:
 A commercial paper can be
represented as a set of properties, each with a value. Typically, some
combination of these properties will provide a unique key for each paper.
See how a commercial paper Paper property has value 00001, and the Face value property has value 5M USD. Most importantly, the Current state
property indicates whether the commercial paper is issued,trading or
redeemed. In combination, the full set of properties make up the state of
a commercial paper. Moreover, the entire collection of these individual
commercial paper states constitutes the ledger
world state.
All ledger state share this form; each has a set of properties, each with a
different value. This multi-property aspect of states is a powerful feature –
it allows us to think of a Fabric state as a vector rather than a simple scalar.
We then represent facts about whole objects as individual states, which
subsequently undergo transitions controlled by transaction logic. A Fabric state
is implemented as a key/value pair, in which the value encodes the object
properties in a format that captures the object’s multiple properties, typically
JSON. The ledger
database can support
advanced query operations against these properties, which is very helpful for
sophisticated object retrieval.
See how MagnetoCorp’s paper 00001 is represented as a state vector that
transitions according to different transaction stimuli:
 A commercial paper state is
brought into existence and transitions as a result of different transactions.
Hyperledger Fabric states have multiple properties, making them vectors rather
than scalars.
Notice how each individual paper starts with the empty state, which is
technically a nil state for the
paper, as it doesn’t exist! See how paper 00001 is brought into existence by
the issue transaction, and how it is subsequently updated as a result of the
buy and redeem transactions.
Notice how each state is self-describing; each property has a name and a value.
Although all our commercial papers currently have the same properties, this need
not be the case for all time, as Hyperledger Fabric supports different states
having different properties. This allows the same ledger world state to contain
different forms of the same asset as well as different types of asset. It also
makes it possible to update a state’s structure; imagine a new regulation that
requires an additional data field. Flexible state properties support the
fundamental requirement of data evolution over time.

State keys¶
In most practical applications, a state will have a combination of properties
that uniquely identify it in a given context – it’s key. The key for a
PaperNet commercial paper is formed by a concatenation of the Issuer and
paper properties; so for MagnetoCorp’s first paper, it’s MagnetoCorp00001.
A state key allows us to uniquely identify a paper; it is created as a result
of the issue transaction and subsequently updated by buy and redeem.
Hyperledger Fabric requires each state in a ledger to have a unique key.
When a unique key is not available from the available set of properties, an
application-determined unique key is specified as an input to the transaction
that creates the state. This unique key is usually with some form of
UUID, which
although less readable, is a standard practice. What’s important is that every
individual state object in a ledger must have a unique key.
Note: You should avoid using U+0000 (nil byte) in keys.

Multiple states¶
As we’ve seen, commercial papers in PaperNet are stored as state vectors in a
ledger. It’s a reasonable requirement to be able to query different commercial
papers from the ledger; for example: find all the papers issued by MagnetoCorp,
or: find all the papers issued by MagnetoCorp in the redeemed state.
To make these kinds of search tasks possible, it’s helpful to group all related
papers together in a logical list. The PaperNet design incorporates the idea of
a commercial paper list – a logical container which is updated whenever
commercial papers are issued or otherwise changed.

Logical representation¶
It’s helpful to think of all PaperNet commercial papers being in a single list
of commercial papers:
 MagnetoCorp’s
newly created commercial  paper 00004 is added to the list of existing
commercial papers.
New papers can be added to the list as a result of an issue transaction, and
papers already in the list can be updated with buy or redeem
transactions. See how the list has a descriptive name: org.papernet.papers;
it’s a really good idea to use this kind of DNS
name because well-chosen
names will make your blockchain designs intuitive to other people. This idea
applies equally well to smart contract names.

Physical representation¶
While it’s correct to think of a single list of papers in PaperNet –
org.papernet.papers – lists are best implemented as a set of individual
Fabric states, whose composite key associates the state with its list. In this
way, each state’s composite key is both unique and supports effective list query.
 Representing a list of
PaperNet commercial papers as a set of distinct Hyperledger Fabric states
Notice how each paper in the list is represented by a vector state, with a
unique composite key formed by the concatenation of org.papernet.paper,
Issuer and Paper properties. This structure is helpful for two reasons:

It allows us to examine any state vector in the ledger to determine which
list it’s in, without reference to a separate list. It’s analogous to
looking at set of sports fans, and identifying which team they support by
the colour of the shirt they are wearing. The sports fans self-declare their
allegiance; we don’t need a list of fans.

Hyperlegder Fabric internally uses a concurrency control
mechanism 
to update a ledger, such that keeping papers in separate state vectors vastly
reduces the opportunity for shared-state collisions. Such collisions require
transaction re-submission, complicate application design, and decrease
performance.

This second point is actually a key take-away for Hyperledger Fabric; the
physical design of state vectors is very important to optimum performance
and behaviour. Keep your states separate!

Trust relationships¶
We have discussed how the different roles in a network, such as issuer, trader
or rating agencies as well as different business interests determine who needs
to sign off on a transaction. In Fabric, these rules are captured by so-called
endorsement policies. The rules can be set on
a chaincode granularity, as well as for individual state keys.
This means that in PaperNet, we can set one rule for the whole namespace that
determines which organizations can issue new papers. Later, rules can be set
and updated for individual papers to capture the trust relationships of buy
and redeem transactions.
In the next topic, we will show you how to combine these design concepts to
implement the PaperNet commercial paper smart contract, and then an application
in exploits it!

Smart Contract Processing¶
Audience: Architects, Application and smart contract developers
At the heart of a blockchain network is a smart contract. In PaperNet, the code
in the commercial paper smart contract defines the valid states for commercial
paper, and the transaction logic that transition a paper from one state to
another. In this topic, we’re going to show you how to implement a real world
smart contract that governs the process of issuing, buying and redeeming
commercial paper.
We’re going to cover:

What is a smart contract and why it’s important
How to define a smart contract
How to define a transaction
How to implement a transaction
How to represent a business object in a smart contract
How to store and retrieve an object in the ledger

If you’d like, you can download the sample and even run it
locally. It is written in JavaScript and Java, but
the logic is quite language independent, so you’ll easily be able to see what’s
going on! (The sample will become available for Go as well.)

Smart Contract¶
A smart contract defines the different states of a business object and governs
the processes that move the object between these different states. Smart
contracts are important because they allow architects and smart contract
developers to define the key business processes and data that are shared across
the different organizations collaborating in a blockchain network.
In the PaperNet network, the smart contract is shared by the different network
participants, such as MagnetoCorp and DigiBank.  The same version of the smart
contract must be used by all applications connected to the network so that they
jointly implement the same shared business processes and data.

Implementation Languages¶
There are two runtimes that are supported, the Java Virtual Machine and Node.js. This
gives the opportunity to use one of JavaScript, TypeScript, Java or any other language
that can run on one of these supported runtimes.
In Java and TypeScript, annotations or decorators are used to provide information about
the smart contract and it’s structure. This allows for a richer development experience —
for example, author information or return types can be enforced. Within JavaScript,
conventions must be followed, therefore, there are limitations around what can be
determined automatically.
Examples here are given in both JavaScript and Java.

Contract class¶
A copy of the PaperNet commercial paper smart contract is contained in a single
file. View it with your browser, or open it in your favorite editor if you’ve downloaded it.

papercontract.js - JavaScript version
CommercialPaperContract.java - Java version

You may notice from the file path that this is MagnetoCorp’s copy of the smart
contract.  MagnetoCorp and DigiBank must agree on the version of the smart contract
that they are going to use. For now, it doesn’t matter which organization’s copy
you use, they are all the same.
Spend a few moments looking at the overall structure of the smart contract;
notice that it’s quite short! Towards the top of the file, you’ll see
that there’s a definition for the commercial paper smart contract:

JavaScript

class CommercialPaperContract extends Contract {...}

Java

@Contract(...)
@Default
public class CommercialPaperContract implements ContractInterface {...}

The CommercialPaperContract class contains the transaction definitions for commercial paper – issue, buy
and redeem. It’s these transactions that bring commercial papers into
existence and move them through their lifecycle. We’ll examine these
transactions soon, but for now notice for JavaScript, that the
CommericalPaperContract extends the Hyperledger Fabric Contract
class.
With Java, the class must be decorated with the @Contract(...) annotation. This provides the opportunity
to supply additional information about the contract, such as license and author. The @Default() annotation
indicates that this contract class is the default contract class. Being able to mark a contract class as the
default contract class is useful in some smart contracts which have multiple contract classes.
If you are using a TypeScript implementation, there are similar @Contract(...) annotations that fulfill the same purpose as in Java.
For more information on the available annotations, consult the available API documentation:

API documentation for Java smart contracts
API documentation for Node.js smart contracts

The Fabric contract class is also available for smart contracts written in Go. While we do not discuss the Go contract API in this topic, it uses similar concepts as the API for Java and JavaScript:

API documentation for Go smart contracts

These classes, annotations, and the Context class, were brought into scope earlier:

JavaScript

const { Contract, Context } = require('fabric-contract-api');

Java

import org.hyperledger.fabric.contract.Context;
import org.hyperledger.fabric.contract.ContractInterface;
import org.hyperledger.fabric.contract.annotation.Contact;
import org.hyperledger.fabric.contract.annotation.Contract;
import org.hyperledger.fabric.contract.annotation.Default;
import org.hyperledger.fabric.contract.annotation.Info;
import org.hyperledger.fabric.contract.annotation.License;
import org.hyperledger.fabric.contract.annotation.Transaction;

Our commercial paper contract will use built-in features of these classes, such
as automatic method invocation, a
per-transaction context,
transaction handlers, and class-shared state.
Notice also how the JavaScript class constructor uses its
superclass
to initialize itself with an explicit contract name:
constructor() {
    super('org.papernet.commercialpaper');
}

With the Java class, the constructor is blank as the explicit contract name can be specified in the @Contract() annotation. If it’s absent, then the name of the class is used.
Most importantly, org.papernet.commercialpaper is very descriptive – this smart
contract is the agreed definition of commercial paper for all PaperNet
organizations.
Usually there will only be one smart contract per file – contracts tend to have
different lifecycles, which makes it sensible to separate them. However, in some
cases, multiple smart contracts might provide syntactic help for applications,
e.g. EuroBond, DollarBond, YenBond, but essentially provide the same
function. In such cases, smart contracts and transactions can be disambiguated.

Transaction definition¶
Within the class, locate the issue method.

JavaScript

async issue(ctx, issuer, paperNumber, issueDateTime, maturityDateTime, faceValue) {...}

Java

@Transaction
public CommercialPaper issue(CommercialPaperContext ctx,
                             String issuer,
                             String paperNumber,
                             String issueDateTime,
                             String maturityDateTime,
                             int faceValue) {...}

The Java annotation @Transaction is used to mark this method as a transaction definition; TypeScript has an equivalent annotation.
This function is given control whenever this contract is called to issue a
commercial paper. Recall how commercial paper 00001 was created with the
following transaction:
Txn = issue
Issuer = MagnetoCorp
Paper = 00001
Issue time = 31 May 2020 09:00:00 EST
Maturity date = 30 November 2020
Face value = 5M USD

We’ve changed the variable names for programming style, but see how these
properties map almost directly to the issue method variables.
The issue method is automatically given control by the contract whenever an
application makes a request to issue a commercial paper. The transaction
property values are made available to the method via the corresponding
variables. See how an application submits a transaction using the Hyperledger
Fabric SDK in the application topic, using a sample
application program.
You might have noticed an extra variable in the issue definition – ctx.
It’s called the transaction context, and it’s
always first. By default, it maintains both per-contract and per-transaction
information relevant to transaction logic. For example, it
would contain MagnetoCorp’s specified transaction identifier, a MagnetoCorp
issuing user’s digital certificate, as well as access to the ledger API.
See how the smart contract extends the default transaction context by
implementing its own createContext() method rather than accepting the
default implementation:

JavaScript

createContext() {
  return new CommercialPaperContext()
}

Java

@Override
public Context createContext(ChaincodeStub stub) {
     return new CommercialPaperContext(stub);
}

This extended context adds a custom property paperList to the defaults:

JavaScript

class CommercialPaperContext extends Context {

  constructor() {
    super();
    // All papers are held in a list of papers
    this.paperList = new PaperList(this);
}

Java

class CommercialPaperContext extends Context {
    public CommercialPaperContext(ChaincodeStub stub) {
        super(stub);
        this.paperList = new PaperList(this);
    }
    public PaperList paperList;
}

We’ll soon see how ctx.paperList can be subsequently used to help store and
retrieve all PaperNet commercial papers.
To solidify your understanding of the structure of a smart contract transaction,
locate the buy and redeem transaction definitions, and see if you can
see how they map to their corresponding commercial paper transactions.
The buy transaction:
Txn = buy
Issuer = MagnetoCorp
Paper = 00001
Current owner = MagnetoCorp
New owner = DigiBank
Purchase time = 31 May 2020 10:00:00 EST
Price = 4.94M USD

JavaScript

async buy(ctx, issuer, paperNumber, currentOwner, newOwner, price, purchaseTime) {...}

Java

@Transaction
public CommercialPaper buy(CommercialPaperContext ctx,
                           String issuer,
                           String paperNumber,
                           String currentOwner,
                           String newOwner,
                           int price,
                           String purchaseDateTime) {...}

The redeem transaction:
Txn = redeem
Issuer = MagnetoCorp
Paper = 00001
Redeemer = DigiBank
Redeem time = 31 Dec 2020 12:00:00 EST

JavaScript

async redeem(ctx, issuer, paperNumber, redeemingOwner, redeemDateTime) {...}

Java

@Transaction
public CommercialPaper redeem(CommercialPaperContext ctx,
                              String issuer,
                              String paperNumber,
                              String redeemingOwner,
                              String redeemDateTime) {...}

In both cases, observe the 1:1 correspondence between the commercial paper
transaction and the smart contract method definition.
All of the JavaScript functions use the async and await
keywords which allow JavaScript functions to be treated as if they were synchronous function calls.

Transaction logic¶
Now that you’ve seen how contracts are structured and transactions are defined,
let’s focus on the logic within the smart contract.
Recall the first issue transaction:
Txn = issue
Issuer = MagnetoCorp
Paper = 00001
Issue time = 31 May 2020 09:00:00 EST
Maturity date = 30 November 2020
Face value = 5M USD

It results in the issue method being passed control:

JavaScript

async issue(ctx, issuer, paperNumber, issueDateTime, maturityDateTime, faceValue) {

   // create an instance of the paper
  let paper = CommercialPaper.createInstance(issuer, paperNumber, issueDateTime, maturityDateTime, faceValue);

  // Smart contract, rather than paper, moves paper into ISSUED state
  paper.setIssued();

  // Newly issued paper is owned by the issuer
  paper.setOwner(issuer);

  // Add the paper to the list of all similar commercial papers in the ledger world state
  await ctx.paperList.addPaper(paper);

  // Must return a serialized paper to caller of smart contract
  return paper.toBuffer();
}

Java

@Transaction
public CommercialPaper issue(CommercialPaperContext ctx,
                              String issuer,
                              String paperNumber,
                              String issueDateTime,
                              String maturityDateTime,
                              int faceValue) {

    System.out.println(ctx);

    // create an instance of the paper
    CommercialPaper paper = CommercialPaper.createInstance(issuer, paperNumber, issueDateTime, maturityDateTime,
            faceValue,issuer,"");

    // Smart contract, rather than paper, moves paper into ISSUED state
    paper.setIssued();

    // Newly issued paper is owned by the issuer
    paper.setOwner(issuer);

    System.out.println(paper);
    // Add the paper to the list of all similar commercial papers in the ledger
    // world state
    ctx.paperList.addPaper(paper);

    // Must return a serialized paper to caller of smart contract
    return paper;
}

The logic is simple: take the transaction input variables, create a new
commercial paper paper, add it to the list of all commercial papers using
paperList, and return the new commercial paper (serialized as a buffer) as the
transaction response.
See how paperList is retrieved from the transaction context to provide access
to the list of commercial papers. issue(), buy() and redeem() continually
re-access ctx.paperList to keep the list of commercial papers up-to-date.
The logic for the buy transaction is a little more elaborate:

JavaScript

async buy(ctx, issuer, paperNumber, currentOwner, newOwner, price, purchaseDateTime) {

  // Retrieve the current paper using key fields provided
  let paperKey = CommercialPaper.makeKey([issuer, paperNumber]);
  let paper = await ctx.paperList.getPaper(paperKey);

  // Validate current owner
  if (paper.getOwner() !== currentOwner) {
      throw new Error('Paper ' + issuer + paperNumber + ' is not owned by ' + currentOwner);
  }

  // First buy moves state from ISSUED to TRADING
  if (paper.isIssued()) {
      paper.setTrading();
  }

  // Check paper is not already REDEEMED
  if (paper.isTrading()) {
      paper.setOwner(newOwner);
  } else {
      throw new Error('Paper ' + issuer + paperNumber + ' is not trading. Current state = ' +paper.getCurrentState());
  }

  // Update the paper
  await ctx.paperList.updatePaper(paper);
  return paper.toBuffer();
}

Java

@Transaction
public CommercialPaper buy(CommercialPaperContext ctx,
                           String issuer,
                           String paperNumber,
                           String currentOwner,
                           String newOwner,
                           int price,
                           String purchaseDateTime) {

    // Retrieve the current paper using key fields provided
    String paperKey = State.makeKey(new String[] { paperNumber });
    CommercialPaper paper = ctx.paperList.getPaper(paperKey);

    // Validate current owner
    if (!paper.getOwner().equals(currentOwner)) {
        throw new RuntimeException("Paper " + issuer + paperNumber + " is not owned by " + currentOwner);
    }

    // First buy moves state from ISSUED to TRADING
    if (paper.isIssued()) {
        paper.setTrading();
    }

    // Check paper is not already REDEEMED
    if (paper.isTrading()) {
        paper.setOwner(newOwner);
    } else {
        throw new RuntimeException(
                "Paper " + issuer + paperNumber + " is not trading. Current state = " + paper.getState());
    }

    // Update the paper
    ctx.paperList.updatePaper(paper);
    return paper;
}

See how the transaction checks currentOwner and that paper is TRADING
before changing the owner with paper.setOwner(newOwner). The basic flow is
simple though – check some pre-conditions, set the new owner, update the
commercial paper on the ledger, and return the updated commercial paper
(serialized as a buffer) as the transaction response.
Why don’t you see if you can understand the logic for the redeem
transaction?

Representing an object¶
We’ve seen how to define and implement the issue, buy and redeem
transactions using the CommercialPaper and PaperList classes. Let’s end
this topic by seeing how these classes work.
Locate the CommercialPaper class:

JavaScript
In the
paper.js file:
class CommercialPaper extends State {...}

Java
In the CommercialPaper.java file:
@DataType()
public class CommercialPaper extends State {...}

This class contains the in-memory representation of a commercial paper state.
See how the createInstance method initializes a new commercial paper with the
provided parameters:

JavaScript

static createInstance(issuer, paperNumber, issueDateTime, maturityDateTime, faceValue) {
  return new CommercialPaper({ issuer, paperNumber, issueDateTime, maturityDateTime, faceValue });
}

Java

public static CommercialPaper createInstance(String issuer, String paperNumber, String issueDateTime,
        String maturityDateTime, int faceValue, String owner, String state) {
    return new CommercialPaper().setIssuer(issuer).setPaperNumber(paperNumber).setMaturityDateTime(maturityDateTime)
            .setFaceValue(faceValue).setKey().setIssueDateTime(issueDateTime).setOwner(owner).setState(state);
}

Recall how this class was used by the issue transaction:

JavaScript

let paper = CommercialPaper.createInstance(issuer, paperNumber, issueDateTime, maturityDateTime, faceValue);

Java

CommercialPaper paper = CommercialPaper.createInstance(issuer, paperNumber, issueDateTime, maturityDateTime,
        faceValue,issuer,"");

See how every time the issue transaction is called, a new in-memory instance of
a commercial paper is created containing the transaction data.
A few important points to note:

This is an in-memory representation; we’ll see
later how it appears on the ledger.

The CommercialPaper class extends the State class. State is an
application-defined class which creates a common abstraction for a state.
All states have a business object class which they represent, a composite
key, can be serialized and de-serialized, and so on.  State helps our code
be more legible when we are storing more than one business object type on
the ledger. Examine the State class in the state.js
file.

A paper computes its own key when it is created – this key will be used
when the ledger is accessed. The key is formed from a combination of
issuer and paperNumber.
constructor(obj) {
  super(CommercialPaper.getClass(), [obj.issuer, obj.paperNumber]);
  Object.assign(this, obj);
}

A paper is moved to the ISSUED state by the transaction, not by the paper
class. That’s because it’s the smart contract that governs the lifecycle
state of the paper. For example, an import transaction might create a new
set of papers immediately in the TRADING state.

The rest of the CommercialPaper class contains simple helper methods:
getOwner() {
    return this.owner;
}

Recall how methods like this were used by the smart contract to move the
commercial paper through its lifecycle. For example, in the redeem
transaction we saw:
if (paper.getOwner() === redeemingOwner) {
  paper.setOwner(paper.getIssuer());
  paper.setRedeemed();
}

Access the ledger¶
Now locate the PaperList class in the paperlist.js
file:
class PaperList extends StateList {

This utility class is used to manage all PaperNet commercial papers in
Hyperledger Fabric state database. The PaperList data structures are described
in more detail in the architecture topic.
Like the CommercialPaper class, this class extends an application-defined
StateList class which creates a common abstraction for a list of states – in
this case, all the commercial papers in PaperNet.
The addPaper() method is a simple veneer over the StateList.addState()
method:
async addPaper(paper) {
  return this.addState(paper);
}

You can see in the StateList.js
file
how the StateList class uses the Fabric API putState() to write the
commercial paper as state data in the ledger:
async addState(state) {
  let key = this.ctx.stub.createCompositeKey(this.name, state.getSplitKey());
  let data = State.serialize(state);
  await this.ctx.stub.putState(key, data);
}

Every piece of state data in a ledger requires these two fundamental elements:

Key: key is formed with createCompositeKey() using a fixed name and
the key of state. The name was assigned when the PaperList object was
constructed, and state.getSplitKey() determines each state’s unique key.

Data: data is simply the serialized form of the commercial paper
state, created using the State.serialize() utility method. The State
class serializes and deserializes data using JSON, and the State’s business
object class as required, in our case CommercialPaper, again set when the
PaperList object was constructed.

Notice how a StateList doesn’t store anything about an individual state or the
total list of states – it delegates all of that to the Fabric state database.
This is an important design pattern – it reduces the opportunity for ledger
MVCC collisions in Hyperledger Fabric.
The StateList getState() and updateState() methods work in similar ways:
async getState(key) {
  let ledgerKey = this.ctx.stub.createCompositeKey(this.name, State.splitKey(key));
  let data = await this.ctx.stub.getState(ledgerKey);
  let state = State.deserialize(data, this.supportedClasses);
  return state;
}

async updateState(state) {
  let key = this.ctx.stub.createCompositeKey(this.name, state.getSplitKey());
  let data = State.serialize(state);
  await this.ctx.stub.putState(key, data);
}

See how they use the Fabric APIs putState(), getState() and
createCompositeKey() to access the ledger. We’ll expand this smart contract
later to list all commercial papers in paperNet – what might the method look
like to implement this ledger retrieval?
That’s it! In this topic you’ve understood how to implement the smart contract
for PaperNet.  You can move to the next sub topic to see how an application
calls the smart contract using the Fabric SDK.

Application¶
Audience: Architects, Application and smart contract developers
An application can interact with a blockchain network by submitting transactions
to a ledger or querying ledger content. This topic covers the mechanics of how
an application does this; in our scenario, organizations access PaperNet using
applications which invoke issue, buy and redeem transactions
defined in a commercial paper smart contract. Even though MagnetoCorp’s
application to issue a commercial paper is basic, it covers all the major points
of understanding.
In this topic, we’re going to cover:

The application flow to invoke a smart contract
How an application uses a wallet and identity
How an application connects using a gateway
How to access a particular network
How to construct a transaction request
How to submit a transaction
How to process a transaction response

To help your understanding, we’ll make reference to the commercial paper sample
application provided with Hyperledger Fabric. You can download
it and run it locally. It
is written in both JavaScript and Java, but the logic is quite language independent, so you’ll
easily be able to see what’s going on! (The sample will become available for  Go as well.)

Basic Flow¶
An application interacts with a blockchain network using the Fabric SDK. Here’s
a simplified diagram of how an application invokes a commercial paper smart
contract:
 A PaperNet application invokes
the commercial paper smart contract to submit an issue transaction request.
An application has to follow six basic steps to submit a transaction:

Select an identity from a wallet
Connect to a gateway
Access the desired network
Construct a transaction request for a smart contract
Submit the transaction to the network
Process the response

You’re going to see how a typical application performs these six steps using the
Fabric SDK. You’ll find the application code in the issue.js file. View
it
in your browser, or open it in your favourite editor if you’ve downloaded it.
Spend a few moments looking at the overall structure of the application; even
with comments and spacing, it’s only 100 lines of code!

Wallet¶
Towards the top of issue.js, you’ll see two Fabric classes are brought
into scope:
const { Wallets, Gateway } = require('fabric-network');

You can read about the fabric-network classes in the
node SDK documentation, but for
now, let’s see how they are used to connect MagnetoCorp’s application to
PaperNet. The application uses the Fabric Wallet class as follows:
const wallet = await Wallets.newFileSystemWallet('../identity/user/isabella/wallet');

See how wallet locates a wallet in the local filesystem. The
identity retrieved from the wallet is clearly for a user called Isabella, who is
using the issue application. The wallet holds a set of identities – X.509
digital certificates – which can be used to access PaperNet or any other Fabric
network. If you run the tutorial, and look in this directory, you’ll see the
identity credentials for Isabella.
Think of a wallet holding the digital equivalents of your
government ID, driving license or ATM card. The X.509 digital certificates
within it will associate the holder with a organization, thereby entitling them
to rights in a network channel. For example, Isabella might be an
administrator in MagnetoCorp, and this could give her more privileges than a
different user – Balaji from DigiBank.  Moreover, a smart contract can
retrieve this identity during smart contract processing using the transaction
context.
Note also that wallets don’t hold any form of cash or tokens – they hold
identities.

Gateway¶
The second key class is a Fabric Gateway. Most importantly, a
gateway identifies one or more peers that provide access to a
network – in our case, PaperNet. See how issue.js connects to its gateway:
await gateway.connect(connectionProfile, connectionOptions);

gateway.connect() has two important parameters:

connectionProfile: the file system location of a
connection profile that identifies
a set of peers as a gateway to PaperNet
connectionOptions: a set of options used to control how issue.js
interacts with PaperNet

See how the client application uses a gateway to insulate itself from the
network topology, which might change. The gateway takes care of sending the
transaction proposal to the right peer nodes in the network using the
connection profile and connection
options.
Spend a few moments examining the connection
profile
./gateway/connectionProfile.yaml. It uses
YAML, making it easy to read.
It was loaded and converted into a JSON object:
let connectionProfile = yaml.safeLoad(file.readFileSync('./gateway/connectionProfile.yaml', 'utf8'));

Right now, we’re only interested in the channels: and peers: sections of the
profile: (We’ve modified the details slightly to better explain what’s
happening.)
channels:
  papernet:
    peers:
      peer1.magnetocorp.com:
        endorsingPeer: true
        eventSource: true

      peer2.digibank.com:
        endorsingPeer: true
        eventSource: true

peers:
  peer1.magnetocorp.com:
    url: grpcs://localhost:7051
    grpcOptions:
      ssl-target-name-override: peer1.magnetocorp.com
      request-timeout: 120
    tlsCACerts:
      path: certificates/magnetocorp/magnetocorp.com-cert.pem

  peer2.digibank.com:
    url: grpcs://localhost:8051
    grpcOptions:
      ssl-target-name-override: peer1.digibank.com
    tlsCACerts:
      path: certificates/digibank/digibank.com-cert.pem

See how channel: identifies the PaperNet: network channel, and two of its
peers. MagnetoCorp has peer1.magenetocorp.com and DigiBank has
peer2.digibank.com, and both have the role of endorsing peers. Link to these
peers via the peers: key, which contains details about how to connect to them,
including their respective network addresses.
The connection profile contains a lot of information – not just peers – but
network channels, network orderers, organizations, and CAs, so don’t worry if
you don’t understand all of it!
Let’s now turn our attention to the connectionOptions object:
let connectionOptions = {
    identity: userName,
    wallet: wallet,
    discovery: { enabled:true, asLocalhost: true }
};

See how it specifies that identity, userName, and wallet, wallet, should be
used to connect to a gateway. These were assigned values earlier in the code.
There are other connection options which an
application could use to instruct the SDK to act intelligently on its behalf.
For example:
let connectionOptions = {
  identity: userName,
  wallet: wallet,
  eventHandlerOptions: {
    commitTimeout: 100,
    strategy: EventStrategies.MSPID_SCOPE_ANYFORTX
  },
}

Here, commitTimeout tells the SDK to wait 100 seconds to hear whether a
transaction has been committed. And strategy: EventStrategies.MSPID_SCOPE_ANYFORTX specifies that the SDK can notify an
application after a single MagnetoCorp peer has confirmed the transaction, in
contrast to strategy: EventStrategies.NETWORK_SCOPE_ALLFORTX which requires
that all peers from MagnetoCorp and DigiBank to confirm the transaction.
If you’d like to, read more about how connection
options allow applications to specify goal-oriented behaviour without having to
worry about how it is achieved.

Network channel¶
The peers defined in the gateway connectionProfile.yaml provide
issue.js with access to PaperNet. Because these peers can be joined to
multiple network channels, the gateway actually provides the application with
access to multiple network channels!
See how the application selects a particular channel:
const network = await gateway.getNetwork('PaperNet');

From this point onwards, network will provide access to PaperNet.  Moreover,
if the application wanted to access another network, BondNet, at the same
time, it is easy:
const network2 = await gateway.getNetwork('BondNet');

Now our application has access to a second network, BondNet, simultaneously
with PaperNet!
We can see here a powerful feature of Hyperledger Fabric – applications can
participate in a network of networks, by connecting to multiple gateway
peers, each of which is joined to multiple network channels. Applications will
have different rights in different channels according to their wallet identity
provided in gateway.connect().

Construct request¶
The application is now ready to issue a commercial paper.  To do this, it’s
going to use CommercialPaperContract and again, its fairly straightforward to
access this smart contract:
const contract = await network.getContract('papercontract', 'org.papernet.commercialpaper');

Note how the application provides a name – papercontract – and an explicit
contract name: org.papernet.commercialpaper! We see how a contract
name picks out one contract from the papercontract.js
chaincode file that contains many contracts. In PaperNet, papercontract.js was
installed and deployed to the channel with the name papercontract, and if you’re
interested, read how to deploy a chaincode containing
multiple smart contracts.
If our application simultaneously required access to another contract in
PaperNet or BondNet this would be easy:
const euroContract = await network.getContract('EuroCommercialPaperContract');

const bondContract = await network2.getContract('BondContract');

In these examples, note how we didn’t use a qualifying contract name – we have
only one smart contract per file, and getContract() will use the first
contract it finds.
Recall the transaction MagnetoCorp uses to issue its first commercial paper:
Txn = issue
Issuer = MagnetoCorp
Paper = 00001
Issue time = 31 May 2020 09:00:00 EST
Maturity date = 30 November 2020
Face value = 5M USD

Let’s now submit this transaction to PaperNet!

Submit transaction¶
Submitting a transaction is a single method call to the SDK:
const issueResponse = await contract.submitTransaction('issue', 'MagnetoCorp', '00001', '2020-05-31', '2020-11-30', '5000000');

See how the submitTransaction() parameters match those of the transaction
request.  It’s these values that will be passed to the issue() method in the
smart contract, and used to create a new commercial paper.  Recall its
signature:
async issue(ctx, issuer, paperNumber, issueDateTime, maturityDateTime, faceValue) {...}

It might appear that a smart contract receives control shortly after the
application issues submitTransaction(), but that’s not the case. Under the
covers, the SDK uses the connectionOptions and connectionProfile details to
send the transaction proposal to the right peers in the network, where it can
get the required endorsements. But the application doesn’t need to worry about
any of this – it just issues submitTransaction and the SDK takes care of it
all!
Note that the submitTransaction API includes a process for listening for
transaction commits. Listening for commits is required because without it,
you will not know whether your transaction has successfully been orderered,
validated, and committed to the ledger.
Let’s now turn our attention to how the application handles the response!

Process response¶
Recall from papercontract.js how the issue transaction returns a
commercial paper response:
return paper.toBuffer();

You’ll notice a slight quirk – the new paper needs to be converted to a
buffer before it is returned to the application. Notice how issue.js uses the
class method CommercialPaper.fromBuffer() to rehydrate the response buffer as
a commercial paper:
let paper = CommercialPaper.fromBuffer(issueResponse);

This allows paper to be used in a natural way in a descriptive completion
message:
console.log(`${paper.issuer} commercial paper : ${paper.paperNumber} successfully issued for value ${paper.faceValue}`);

See how the same paper class has been used in both the application and smart
contract – if you structure your code like this, it’ll really help readability
and reuse.
As with the transaction proposal, it might appear that the application receives
control soon after the smart contract completes, but that’s not the case. Under
the covers, the SDK manages the entire consensus process, and notifies the
application when it is complete according to the strategy connectionOption. If
you’re interested in what the SDK does under the covers, read the detailed
transaction flow.
That’s it! In this topic you’ve understood how to call a smart contract from a
sample application by examining how MagnetoCorp’s application issues a new
commercial paper in PaperNet. Now examine the key ledger and smart contract data
structures are designed by in the architecture topic behind
them.

Application design elements¶
This section elaborates the key features for client application and smart
contract development found in Hyperledger Fabric. A solid understanding of
the features will help you design and implement efficient and effective
solutions.

Contract names¶
Audience: Architects, application and smart contract developers,
administrators
A chaincode is a generic container for deploying code to a Hyperledger Fabric
blockchain network. One or more related smart contracts are defined within a
chaincode. Every smart contract has a name that uniquely identifies it within a
chaincode. Applications access a particular smart contract within a chaincode
using its contract name.
In this topic, we’re going to cover:

How a chaincode contains multiple smart contracts
How to assign a smart contract name
How to use a smart contract from an application
The default smart contract

Chaincode¶
In the Developing Applications topic, we can
see how the Fabric SDKs provide high level programming abstractions which help
application and smart contract developers to focus on their business problem,
rather than the low level details of how to interact with a Fabric network.
Smart contracts are one example of a high level programming abstraction, and it
is possible to define smart contracts within in a chaincode container. When a
chaincode is installed on your peer and deployed to a channel, all the smart
contracts within it are made available to your applications.
 Multiple smart contracts can be
defined within a chaincode. Each is uniquely identified by their name within a
chaincode.
In the diagram above, chaincode A has three smart contracts
defined within it, whereas chaincode B has four smart contracts. See how the
chaincode name is used to fully qualify a particular smart contract.
The ledger structure is defined by a set of deployed smart contracts. That’s
because the ledger contains facts about the business objects of interest to the
network (such as commercial paper within PaperNet), and these business objects
are moved through their lifecycle (e.g. issue, buy, redeem) by the transaction
functions defined within a smart contract.
In most cases, a chaincode will only have one smart contract defined within it.
However, it can make sense to keep related smart contracts together in a single
chaincode. For example, commercial papers denominated in different currencies
might have contracts EuroPaperContract, DollarPaperContract,
YenPaperContract which might need to be kept synchronized with each other in
the channel to which they are deployed.

Name¶
Each smart contract within a chaincode is uniquely identified by its contract
name. A smart contract can explicitly assign this name when the class is
constructed, or let the Contract class implicitly assign a default name.
Examine the papercontract.js chaincode
file:
class CommercialPaperContract extends Contract {

    constructor() {
        // Unique name when multiple contracts per chaincode file
        super('org.papernet.commercialpaper');
    }

See how the CommercialPaperContract constructor specifies the contract name as
org.papernet.commercialpaper. The result is that within the papercontract
chaincode, this smart contract is now associated with the contract name
org.papernet.commercialpaper.
If an explicit contract name is not specified, then a default name is assigned
– the name of the class.  In our example, the default contract name would be
CommercialPaperContract.
Choose your names carefully. It’s not just that each smart contract must have a
unique name; a well-chosen name is illuminating. Specifically, using an explicit
DNS-style naming convention is recommended to help organize clear and meaningful
names; org.papernet.commercialpaper conveys that the PaperNet network has
defined a standard commercial paper smart contract.
Contract names are also helpful to disambiguate different smart contract
transaction functions with the same name in a given chaincode. This happens when
smart contracts are closely related; their transaction names will tend to be the
same. We can see that a transaction is uniquely defined within a channel by the
combination of its chaincode and smart contract name.
Contract names must be unique within a chaincode file. Some code editors will
detect multiple definitions of the same class name before deployment. Regardless
the chaincode will return an error if multiple classes with the same contract
name are explicitly or implicitly specified.

Application¶
Once a chaincode has been installed on a peer and deployed to a channel, the
smart contracts in it are accessible to an application:
const network = await gateway.getNetwork(`papernet`);

const contract = await network.getContract('papercontract', 'org.papernet.commercialpaper');

const issueResponse = await contract.submitTransaction('issue', 'MagnetoCorp', '00001', '2020-05-31', '2020-11-30', '5000000');

See how the application accesses the smart contract with the
network.getContract() method. The papercontract chaincode name
org.papernet.commercialpaper returns a contract reference which can be
used to submit transactions to issue commercial paper with the
contract.submitTransaction() API.

Default contract¶
The first smart contract defined in a chaincode is called the default
smart contract. A default is helpful because a chaincode will usually have one
smart contract defined within it; a default allows the application to access
those transactions directly – without specifying a contract name.
 A default smart contract is the
first contract defined in a chaincode.
In this diagram, CommercialPaperContract is the default smart contract. Even
though we have two smart contracts, the default smart contract makes our
previous example easier to write:
const network = await gateway.getNetwork(`papernet`);

const contract = await network.getContract('papercontract');

const issueResponse = await contract.submitTransaction('issue', 'MagnetoCorp', '00001', '2020-05-31', '2020-11-30', '5000000');

This works because the default smart contract in papercontract is
CommercialPaperContract and it has an issue transaction. Note that the
issue transaction in BondContract can only be invoked by explicitly
addressing it. Likewise, even though the cancel transaction is unique, because
BondContract is not the default smart contract, it must also be explicitly
addressed.
In most cases, a chaincode will only contain a single smart contract, so careful
naming of the chaincode can reduce the need for developers to care about
chaincode as a concept. In the example code above it feels
like papercontract is a smart contract.
In summary, contract names are a straightforward mechanism to identify
individual smart contracts within a given chaincode. Contract names make it easy
for applications to find a particular smart contract and use it to access the
ledger.

Chaincode namespace¶
Audience: Architects, application and smart contract developers,
administrators
A chaincode namespace allows it to keep its world state separate from other
chaincodes. Specifically, smart contracts in the same chaincode share direct
access to the same world state, whereas smart contracts in different chaincodes
cannot directly access each other’s world state. If a smart contract needs to
access another chaincode world state, it can do this by performing a
chaincode-to-chaincode invocation. Finally, a blockchain can contain
transactions which relate to different world states.
In this topic, we’re going to cover:

The importance of namespaces
What is a chaincode namespace
Channels and namespaces
How to use chaincode namespaces
How to access world states across smart contracts
Design considerations for chaincode namespaces

Motivation¶
A namespace is a common concept. We understand that Park Street, New York and
Park Street, Seattle are different streets even though they have the same
name. The city forms a namespace for Park Street, simultaneously providing
freedom and clarity.
It’s the same in a computer system. Namespaces allow different users to program
and operate different parts of a shared system, without getting in each other’s
way. Many programming languages have namespaces so that programs can freely
assign unique identifiers, such as variable names, without worrying about other
programs doing the same. We’ll see that Hyperledger Fabric uses namespaces to
help smart contracts keep their ledger world state separate from other smart
contracts.

Scenario¶
Let’s examine how the ledger world state organizes facts about business objects
that are important to the organizations in a channel using the diagram below.
Whether these objects are commercial papers, bonds, or vehicle registrations,
and wherever they are in their lifecycle, they are maintained as states within
the ledger world state database. A smart contract manages these business objects
by interacting with the ledger (world state and blockchain), and in most cases
this will involve it querying or updating the ledger world state.
It’s vitally important to understand that the ledger world state is partitioned
according to the chaincode of the smart contract that accesses it, and this
partitioning, or namespacing is an important design consideration for
architects, administrators and programmers.
 The ledger world state is
separated into different namespaces according to the chaincode that accesses it.
Within a given channel, smart contracts in the same chaincode share the same
world state, and smart contracts in different chaincodes cannot directly access
each other’s world state. Likewise, a blockchain can contain transactions that
relate to different chaincode world states.
In our example, we can see four smart contracts defined in two different
chaincodes, each of which is in their own chaincode container. The euroPaper
and yenPaper smart contracts are defined in the papers chaincode. The
situation is similar for the euroBond and yenBond smart contracts  – they
are defined in the bonds chaincode. This design helps application programmers
understand whether they are working with commercial papers or bonds priced in
Euros or Yen, and because the rules for each financial product don’t really
change for different currencies, it makes sense to manage their deployment in
the same chaincode.
The diagram also shows the consequences of this deployment choice.
The database management system (DBMS) creates different world state databases
for the papers and bonds chaincodes and the smart contracts contained within
them. World state A and world state B are each held within distinct
databases; the data are isolated from each other such that a single world state
query (for example) cannot access both world states. The world state is said to
be namespaced according to its chaincode.
See how world state A contains two lists of commercial papers paperListEuro
and paperListYen. The states PAP11 and PAP21 are instances of each paper
managed by the euroPaper and yenPaper smart contracts respectively. Because
they share the same chaincode namespace, their keys (PAPxyz) must be unique
within the namespace of the papers chaincode, a little like a street name is
unique within a town. Notice how it would be possible to write a smart contract
in the papers chaincode that performed an aggregate calculation over all the
commercial papers – whether priced in Euros or Yen – because they share the
same namespace. The situation is similar for bonds – they are held within
world state B which maps to a separate bonds database, and their keys must
be unique.
Just as importantly, namespaces mean that euroPaper and yenPaper cannot
directly access world state B, and that euroBond and yenBond cannot
directly access world state A. This isolation is helpful, as commercial papers
and bonds are very distinct financial instruments; they have different
attributes and are subject to different rules. It also means that papers and
bonds could have the same keys, because they are in different namespaces. This
is helpful; it provides a significant degree of freedom for naming. Use this
freedom to name different business objects meaningfully.
Most importantly, we can see that a blockchain is associated with the peer
operating in a particular channel, and that it contains transactions that affect
both world state A and world state B. That’s because the blockchain is the
most fundamental data structure contained in a peer. The set of world states can
always be recreated from this blockchain, because they are the cumulative
results of the blockchain’s transactions. A world state helps simplify smart
contracts and improve their efficiency, as they usually only require the current
value of a state. Keeping world states separate via namespaces helps smart
contracts isolate their logic from other smart contracts, rather than having to
worry about transactions that correspond to different world states. For example,
a bonds contract does not need to worry about paper transactions, because it
cannot see their resultant world state.
It’s also worth noticing that the peer, chaincode containers and DBMS all are
logically different processes. The peer and all its chaincode containers are
always in physically separate operating system processes, but the DBMS can be
configured to be embedded or separate, depending on its
type. For LevelDB, the
DBMS is wholly contained within the peer, but for CouchDB, it is a separate
operating system process.
It’s important to remember that namespace choices in this example are the result
of a business requirement to share commercial papers in different currencies but
isolate them separate from bonds. Think about how the namespace structure would
be modified to meet a business requirement to keep every financial asset class
separate, or share all commercial papers and bonds?

Channels¶
If a peer is joined to multiple channels, then a new blockchain is created
and managed for each channel. Moreover, every time a chaincode is deployed to
a new channel, a new world state database is created for it. It means that
the channel also forms a kind of namespace alongside that of the chaincode for
the world state.
However, the same peer and chaincode container processes can be simultaneously
joined to multiple channels – unlike blockchains, and world state databases,
these processes do not increase with the number of channels joined.
For example, if you deployed the papers and bonds chaincode to a new
channel, there would a totally separate blockchain created, and two new world
state databases created. However, the peer and chaincode containers would not
increase; each would just be connected to multiple channels.

Usage¶
Let’s use our commercial paper example to show how an application
uses a smart contract with namespaces. It’s worth noting that an application
communicates with the peer, and the peer routes the request to the appropriate
chaincode container which then accesses the DBMS. This routing is done by the
peer core component shown in the diagram.
Here’s the code for an application that uses both commercial papers and bonds,
priced in Euros and Yen. The code is fairly self-explanatory:
const euroPaper = network.getContract(papers, euroPaper);
paper1 = euroPaper.submit(issue, PAP11);

const yenPaper = network.getContract(papers, yenPaper);
paper2 = yenPaper.submit(redeem, PAP21);

const euroBond = network.getContract(bonds, euroBond);
bond1 = euroBond.submit(buy, BON31);

const yenBond = network.getContract(bonds, yenBond);
bond2 = yenBond.submit(sell, BON41);

See how the application:

Accesses the euroPaper and yenPaper contracts using the getContract()
API specifying the papers chaincode. See interaction points 1a and
2a.
Accesses the euroBond and yenBond contracts using the getContract() API
specifying the bonds chaincode. See interaction points 3a and 4a.
Submits an issue transaction to the network for commercial paper PAP11
using the euroPaper contract. See interaction point 1a. This results in
the creation of a commercial paper represented by state PAP11 in world state A; interaction point 1b. This operation is captured as a
transaction in the blockchain at interaction point 1c.
Submits a redeem transaction to the network for commercial paper PAP21
using the yenPaper contract. See interaction point 2a. This results in
the creation of a commercial paper represented by state PAP21 in world state A; interaction point 2b. This operation is captured as a
transaction in the blockchain at interaction point 2c.
Submits a buy transaction to the network for bond BON31 using the
euroBond contract. See interaction point 3a. This results in the
creation of a bond represented by state BON31 in world state B;
interaction point 3b. This operation is captured as a transaction in the
blockchain at interaction point 3c.
Submits a sell transaction to the network for bond BON41 using the
yenBond contract. See interaction point 4a. This results in the creation
of a bond represented by state BON41 in world state B; interaction point
4b. This operation is captured as a transaction in the blockchain at
interaction point 4c.

See how smart contracts interact with the world state:

euroPaper and yenPaper contracts can directly access world state A, but
cannot directly access world state B. World state A is physically held in
the papers database in the database management system (DBMS) corresponding
to the papers chaincode.
euroBond and yenBond contracts can directly access world state B, but
cannot directly access world state A. World state B is physically held in
the bonds database in the database management system (DBMS) corresponding to
the bonds chaincode.

See how the blockchain captures transactions for all world states:

Interactions 1c and 2c correspond to transactions create and update
commercial papers PAP11 and PAP21 respectively. These are both contained
within world state A.
Interactions 3c and 4c correspond to transactions both update bonds
BON31 and BON41. These are both contained within world state B.
If world state A or world state B were destroyed for any reason, they
could be recreated by replaying all the transactions in the blockchain.

Cross chaincode access¶
As we saw in our example scenario, euroPaper and yenPaper
cannot directly access world state B.  That’s because we have designed our
chaincodes and smart contracts so that these chaincodes and world states are
kept separately from each other.  However, let’s imagine that euroPaper needs
to access world state B.
Why might this happen? Imagine that when a commercial paper was issued, the
smart contract wanted to price the paper according to the current return on
bonds with a similar maturity date.  In this case it will be necessary for the
euroPaper contract to be able to query the price of bonds in world state B.
Look at the following diagram to see how we might structure this interaction.
 How chaincodes and smart
contracts can indirectly access another world state – via its chaincode.
Notice how:

the application submits an issue transaction in the euroPaper smart
contract to issue PAP11. See interaction 1a.
the issue transaction in the euroPaper smart contract calls the query
transaction in the euroBond smart contract. See interaction point 1b.
the queryin euroBond can retrieve information from world state B. See
interaction point 1c.
when control returns to the issue transaction, it can use the information in
the response to price the paper and update world state A with information.
See interaction point 1d.
the flow of control for issuing commercial paper priced in Yen is the same.
See interaction points 2a, 2b, 2c and 2d.

Control is passed between chaincode using the invokeChaincode()
API.
This API passes control from one chaincode to another chaincode.
Although we have only discussed query transactions in the example, it is
possible to invoke a smart contract which will update the called chaincode’s
world state.  See the considerations below.

Considerations¶

In general, each chaincode will have a single smart contract in it.
Multiple smart contracts should only be deployed in the same chaincode if they
are very closely related.  Usually, this is only necessary if they share the
same world state.
Chaincode namespaces provide isolation between different world states. In
general it makes sense to isolate unrelated data from each other. Note that
you cannot choose the chaincode namespace; it is assigned by Hyperledger
Fabric, and maps directly to the name of the chaincode.
For chaincode to chaincode interactions using the invokeChaincode() API,
both chaincodes must be installed on the same peer.
For interactions that only require the called chaincode’s world state to
be queried, the invocation can be in a different channel to the caller’s
chaincode.
For interactions that require the called chaincode’s world state to be
updated, the invocation must be in the same channel as the caller’s
chaincode.

Transaction context¶
Audience: Architects, application and smart contract developers
A transaction context performs two functions. Firstly, it allows a developer to
define and maintain user variables across transaction invocations within a smart
contract. Secondly, it provides access to a wide range of Fabric APIs that allow
smart contract developers to perform operations relating to detailed transaction
processing. These range from querying or updating the ledger, both the immutable
blockchain and the modifiable world state, to retrieving the
transaction-submitting application’s digital identity.
A transaction context is created when a smart contract is deployed to a channel and
made available to every subsequent transaction invocation. A transaction context
helps smart contract developers write programs that are powerful, efficient and
easy to reason about.

Why a transaction context is important
How to use a transaction context
What’s in a transaction context
Using a context stub
Using a context clientIdentity

Scenario¶
In the commercial paper sample,
papercontract
initially defines the name of the list of commercial papers for which it’s
responsible. Each transaction subsequently refers to this list; the issue
transaction adds new papers to it, the buy transaction changes its owner, and
the redeem transaction marks it as complete. This is a common pattern; when
writing a smart contract it’s often helpful to initialize and recall particular
variables in sequential transactions.
 A smart contract transaction
context allows smart contracts to define and maintain user variables across
transaction invocations. Refer to the text for a detailed explanation.

Programming¶
When a smart contract is constructed, a developer can optionally override the
built-in Context class createContext method to create a custom context:
createContext() {
    new CommercialPaperContext();
}

In our example, the CommercialPaperContext is specialized for
CommercialPaperContract. See how the custom context, addressed through this,
adds the specific variable PaperList to itself:
CommercialPaperContext extends Context {
    constructor () {
        this.paperList = new PaperList(this);
    }
}

When the createContext() method returns at point (1) in the diagram
above, a custom context ctx has been created which contains
paperList as one of its variables.
Subsequently, whenever a smart contract transaction such as issue, buy or redeem
is called, this context will be passed to it. See how at points (2), (3)
and (4) the same commercial paper context is passed into the transaction
method using the ctx variable.
See how the context is then used at point (5):
ctx.paperList.addPaper(...);
ctx.stub.putState(...);

Notice how paperList created in CommercialPaperContext is available to the
issue transaction. See how paperList is similarly used by the redeem and
buy transactions; ctx makes the smart contracts efficient and easy to
reason about.
You can also see that there’s another element in the context – ctx.stub –
which was not explictly added by CommercialPaperContext. That’s because stub
and other variables are part of the built-in context. Let’s now examine the
structure of this built-in context, these implicit variables and how to use
them.

Structure¶
As we’ve seen from the example, a transaction context can
contain any number of user variables such as paperList.
The transaction context also contains two built-in elements that provide access
to a wide range of Fabric functionality ranging from the client application that
submitted the transaction to ledger access.

ctx.stub is used to access APIs that provide a broad range of transaction
processing operations from putState() and getState() to access the
ledger, to getTxID() to retrieve the current transaction ID.
ctx.clientIdentity is used to get information about the identity of the
user who submitted the transaction.

We’ll use the following diagram to show you what a smart contract can do using
the stub and clientIdentity using the APIs available to it:
 A smart contract can access a
range of functionality in a smart contract via the transaction context stub
and clientIdentity. Refer to the text for a detailed explanation.

Stub¶
The APIs in the stub fall into the following categories:

World state data APIs. See interaction point (1). These APIs enable
smart contracts to get, put and delete state corresponding to individual
objects from the world state, using their key:

getState()
putState()
deleteState()

 These basic APIs are complemented by query APIs which enable contracts to
retrieve a set of states, rather than an individual state. See interaction
point (2). The set is either defined by a range of key values, using full
or partial keys, or a query according to values in the underlying world state
database.  For large
queries, the result sets can be paginated to reduce storage requirements:

getStateByRange()
getStateByRangeWithPagination()
getStateByPartialCompositeKey()
getStateByPartialCompositeKeyWithPagination()
getQueryResult()
getQueryResultWithPagination()

Private data APIs. See interaction point (3). These APIs enable smart
contracts to interact with a private data collection. They are analogous to
the APIs for world state interactions, but for private data. There are APIs to
get, put and delete a private data state by its key:

getPrivateData()
putPrivateData()
deletePrivateData()

 This set is complemented by set of APIs to query private data (4).
These APIs allow smart contracts to retrieve a set of states from a private
data collection, according to a range of key values, either full or partial
keys, or a query according to values in the underlying world state
database. There are
currently no pagination APIs for private data collections.

getPrivateDataByRange()
getPrivateDataByPartialCompositeKey()
getPrivateDataQueryResult()

Transaction APIs. See interaction point (5). These APIs are used by a
smart contract to retrieve details about the current transaction proposal
being processed by the smart contract. This includes the transaction
identifier and the time when the transaction proposal was created.

getTxID()
returns the identifier of the current transaction proposal (5).
getTxTimestamp()
returns the timestamp when the current transaction proposal was created by
the application (5).
getCreator()
returns the raw identity (X.509 or otherwise) of the creator of
transaction proposal. If this is an X.509 certificate then it is often
more appropriate to use ctx.ClientIdentity.
getSignedProposal()
returns a signed copy of the current transaction proposal being processed
by the smart contract.
getBinding()
is used to prevent transactions being maliciously or accidentally replayed
using a nonce. (For practical purposes, a nonce is a random number
generated by the client application and incorporated in a cryptographic
hash.) For example, this API could be used by a smart contract at (1)
to detect a replay of the transaction (5).
getTransient()
allows a smart contract to access the transient data an application passes
to a smart contract. See interaction points (9) and (10).
Transient data is private to the application-smart contract interaction.
It is not recorded on the ledger and is often used in conjunction with
private data collections (3).

Key APIs are used by smart contracts to manipulate state key in the world
state or a private data collection. See interaction points 2 and 4.
The simplest of these APIs allows smart contracts to form and split composite
keys from their individual components. Slightly more advanced are the
ValidationParameter() APIs which get and set the state based endorsement
policies for world state (2) and private data (4). Finally,
getHistoryForKey() retrieves the history for a state by returning the set of
stored values, including the transaction identifiers that performed the state
update, allowing the transactions to be read from the blockchain (10).

createCompositeKey()
splitCompositeKey()
setStateValidationParameter()
getStateValidationParameter()
getPrivateDataValidationParameter()
setPrivateDataValidationParameter()
getHistoryForKey()

Event APIs are used to manage event processing in a smart contract.

setEvent()

  Smart contracts use this API to add user events to a transaction response.
  See interaction point **(5)**. These events are ultimately recorded on the
  blockchain and sent to listening applications at interaction point
  **(11)**.

<br>

Utility APIs are a collection of useful APIs that don’t easily fit in a
pre-defined category, so we’ve grouped them together! They include retrieving
the current channel name and passing control to a different chaincode on the
same peer.

getChannelID()
See interaction point (13).  A smart contract running on any peer can
use this API to determined on which channel the application invoked the
smart contract.

invokeChaincode()
See interaction point (14).  Peer3 owned by MagnetoCorp has multiple
smart contracts installed on it.  These smart contracts are able to call
each other using this API. The smart contracts must be collocated; it is
not possible to call a smart contract on a different peer.

 Some of these utility APIs are only used if you’re using low-level
chaincode, rather than smart contracts. These APIs are primarily for the
detailed manipulation of chaincode input; the smart contract Contract class
does all of this parameter marshalling automatically for developers.

getFunctionAndParameters()
getStringArgs()
getArgs()

ClientIdentity¶
In most cases, the application submitting a transaction will be using an X.509
certificate. In the example, an X.509 certificate (6) issued
by CA1 (7) is being used by Isabella (8) in her application to sign
the proposal in transaction t6 (5).
ClientIdentity takes the information returned by getCreator() and puts a set
of X.509 utility APIs on top of it to make it easier to use for this common use
case.

getX509Certificate()
returns the full X.509 certificate of the transaction submitter, including all
its attributes and their values. See interaction point (6).
getAttributeValue()
returns the value of a particular X.509 attribute, for example, the
organizational unit OU, or distinguished name DN. See interaction point
(6).
assertAttributeValue()
returns TRUE if the specified attribute of the X.509 attribute has a
specified value. See interaction point (6).
getID()
returns the unique identity of the transaction submitter, according to their
distinguished name and the issuing CA’s distinguished name. The format is
x509::{subject DN}::{issuer DN}. See interaction point (6).
getMSPID()
returns the channel MSP of the transaction submitter. This allows a smart
contract to make processing decisions based on the submitter’s organizational
identity. See interaction point (15) or (16).

Transaction handlers¶
Audience: Architects, Application and smart contract developers
Transaction handlers allow smart contract developers to define common processing
at key points during the interaction between an application and a smart
contract. Transaction handlers are optional but, if defined, they will receive
control before or after every transaction in a smart contract is invoked. There
is also a specific handler which receives control when a request is made to
invoke a transaction not defined in a smart contract.
Here’s an example of transaction handlers for the commercial paper smart
contract sample:

Before, After and Unknown transaction handlers. In this example,
beforeTransaction() is called before the issue, buy and redeem
transactions. afterTransaction() is called after the issue, buy and
redeem transactions. unknownTransaction() is only called if a request is
made to invoke a transaction not defined in the smart contract.  (The diagram is
simplified by not repeating beforeTransaction and afterTransaction boxes for
each transaction.)

Types of handler¶
There are three types of transaction handlers which cover different aspects
of the interaction between an application and a smart contract:

Before handler: is called before every smart contract transaction is
invoked. The handler will usually modify the transaction context to be used
by the transaction. The handler has access to the full range of Fabric APIs;
for example, it can issue getState() and putState().

After handler: is called after every smart contract transaction is
invoked. The handler will usually perform post-processing common to all
transactions, and also has full access to the Fabric APIs.

Unknown handler: is called if an attempt is made to invoke a transaction
that is not defined in a smart contract. Typically, the handler will record
the failure for subsequent processing by an administrator. The handler has
full access to the Fabric APIs.

Defining a transaction handler is optional; a smart contract will perform
correctly without handlers being defined. A smart contract can define at most
one handler of each type.

Defining a handler¶
Transaction handlers are added to the smart contract as methods with well
defined names.  Here’s an example which adds a handler of each type:
CommercialPaperContract extends Contract {

    ...

    async beforeTransaction(ctx) {
        // Write the transaction ID as an informational to the console
        console.info(ctx.stub.getTxID());
    };

    async afterTransaction(ctx, result) {
        // This handler interacts with the ledger
        ctx.stub.cpList.putState(...);
    };

    async unknownTransaction(ctx) {
        // This handler throws an exception
        throw new Error('Unknown transaction function');
    };

}

The form of a transaction handler definition is the similar for all handler
types, but notice how the afterTransaction(ctx, result) also receives any
result returned by the transaction. The API
documentation
shows you the exact form of these handlers.

Handler processing¶
Once a handler has been added to the smart contract, it will be invoked during
transaction processing. During processing, the handler receives ctx, the
transaction context, performs some processing, and
returns control as it completes. Processing continues as follows:

Before handler: If the handler completes successfully, the transaction is
called with the updated context. If the handler throws an exception, then the
transaction is not called and the smart contract fails with the exception
error message.

After handler: If the handler completes successfully, then the smart
contract completes as determined by the invoked transaction. If the handler
throws an exception, then the transaction fails with the exception error
message.

Unknown handler: The handler should complete by throwing an exception with
the required error message. If an Unknown handler is not specified, or an
exception is not thrown by it, there is sensible default processing; the smart
contract will fail with an unknown transaction error message.

If the handler requires access to the function and parameters, then it is easy to do this:
async beforeTransaction(ctx) {
    // Retrieve details of the transaction
    let txnDetails = ctx.stub.getFunctionAndParameters();

    console.info(`Calling function: ${txnDetails.fcn} `);
    console.info(util.format(`Function arguments : %j ${stub.getArgs()} ``);
}

See how this handler uses the utility API getFunctionAndParameters via the
transaction context.

Multiple handlers¶
It is only possible to define at most one handler of each type for a smart
contract. If a smart contract needs to invoke multiple functions during before,
after or unknown handling, it should coordinate this from within the appropriate
function.

Endorsement policies¶
Audience: Architects, Application and smart contract developers
Endorsement policies define the smallest set of organizations that are required
to endorse a transaction in order for it to be valid. To endorse, an organization’s
endorsing peer needs to run the smart contract associated with the transaction
and sign its outcome. When the ordering service sends the transaction to the
committing peers, they will each individually check whether the endorsements in
the transaction fulfill the endorsement policy. If this is not the case, the
transaction is invalidated and it will have no effect on world state.
Endorsement policies work at two different granularities: they can be set for an
entire namespace, as well as for individual state keys. They are formulated using
basic logic expressions such as AND and OR. For example, in PaperNet this
could be used as follows: the endorsement policy for a paper that has been sold
from MagnetoCorp to DigiBank could be set to AND(MagnetoCorp.peer, DigiBank.peer),
requiring any changes to this paper to be endorsed by both MagnetoCorp and DigiBank.

Connection Profile¶
Audience: Architects, application and smart contract developers
A connection profile describes a set of components, including peers, orderers
and certificate authorities in a Hyperledger Fabric blockchain network. It also
contains channel and organization information relating to these components. A
connection profile is primarily used by an application to configure a
gateway that handles all network interactions, allowing it
to focus on business logic. A connection profile is normally created by an
administrator who understands the network topology.
In this topic, we’re going to cover:

Why connection profiles are important
How applications use a connection profile
How to define a connection profile

Scenario¶
A connection profile is used to configure a gateway. Gateways are important for
many reasons, the primary being to simplify an application’s
interaction with a network channel.
 Two applications, issue and buy,
use gateways 1&2 configured with connection profiles 1&2. Each profile
describes a different subset of MagnetoCorp and DigiBank network components.
Each connection profile must contain sufficient information for a gateway to
interact with the network on behalf of the issue and buy applications. See the
text for a detailed explanation.
A connection profile contains a description of a network view, expressed in a
technical syntax, which can either be JSON or YAML. In this topic, we use the
YAML representation, as it’s easier for you to read. Static gateways need more
information than dynamic gateways because the latter can use service
discovery to dynamically augment the information in
a connection profile.
A connection profile should not be an exhaustive description of a network
channel; it just needs to contain enough information sufficient for a gateway
that’s using it. In the network above, connection profile 1 needs to contain at
least the endorsing organizations and peers for the issue transaction, as well
as identifying the peers that will notify the gateway when the transaction has
been committed to the ledger.
It’s easiest to think of a connection profile as describing a view of the
network. It could be a comprehensive view, but that’s unrealistic for a few
reasons:

Peers, orderers, certificate authorities, channels, and organizations are
added and removed according to demand.
Components can start and stop, or fail unexpectedly (e.g. power outage).
A gateway doesn’t need a view of the whole network, only what’s necessary to
successfully handle transaction submission or event notification for example.
Service Discovery can augment the information in a connection profile.
Specifically, dynamic gateways can be configured with minimal Fabric topology
information; the rest can be discovered.

A static connection profile is normally created by an administrator who
understands the network topology in detail. That’s because a static profile can
contain quite a lot of information, and an administrator needs to capture this
in the corresponding connection profile. In contrast, dynamic profiles minimize
the amount of definition required and therefore can be a better choice for
developers who want to get going quickly, or administrators who want to create a
more responsive gateway. Connection profiles are created in either the YAML or
JSON format using an editor of choice.

Usage¶
We’ll see how to define a connection profile in a moment; let’s first see how it
is used by a sample MagnetoCorp issue application:
const yaml = require('js-yaml');
const { Gateway } = require('fabric-network');

const connectionProfile = yaml.safeLoad(fs.readFileSync('../gateway/paperNet.yaml', 'utf8'));

const gateway = new Gateway();

await gateway.connect(connectionProfile, connectionOptions);

After loading some required classes, see how the paperNet.yaml gateway file is
loaded from the file system, converted to a JSON object using the
yaml.safeLoad() method, and used to configure a gateway using its connect()
method.
By configuring a gateway with this connection profile, the issue application is
providing the gateway with the relevant network topology it should use to
process transactions. That’s because the connection profile contains sufficient
information about the PaperNet channels, organizations, peers, orderers and CAs
to ensure transactions can be successfully processed.
It’s good practice for a connection profile to define more than one peer for any
given organization – it prevents a single point of failure. This practice also
applies to dynamic gateways; to provide more than one starting point for service
discovery.
A DigiBank buy application would typically configure its gateway with a
similar connection profile, but with some important differences. Some elements
will be the same, such as the channel; some elements will overlap, such as the
endorsing peers. Other elements will be completely different, such as
notification peers or certificate authorities for example.
The connectionOptions passed to a gateway complement the connection profile.
They allow an application to declare how it would like the gateway to use the
connection profile. They are interpreted by the SDK to control interaction
patterns with network components, for example to select which identity to
connect with, or which peers to use for event notifications. Read
about the list of available connection options and
when to use them.

Structure¶
To help you understand the structure of a connection profile, we’re going to
step through an example for the network shown above. Its connection
profile is based on the PaperNet commercial paper sample, and
stored
in the GitHub repository. For convenience, we’ve reproduced it below.
You will find it helpful to display it in another browser window as you now read
about it:

Line 9: name: "papernet.magnetocorp.profile.sample"
This is the name of the connection profile. Try to use DNS style names; they
are a very easy way to convey meaning.

Line 16: x-type: "hlfv1"
Users can add their own x- properties that are “application-specific” –
just like with HTTP headers. They are provided primarily for future use.

Line 20: description: "Sample connection profile for documentation topic"
A short description of the connection profile. Try to make this helpful for
the reader who might be seeing this for the first time!

Line 25: version: "1.0"
The schema version for this connection profile.  Currently only version 1.0 is
supported, and it is not envisioned that this schema will change frequently.

Line 32: channels:
This is the first really important line. channels: identifies that what
follows are all the channels that this connection profile describes. However,
it is good practice to keep different channels in different connection
profiles, especially if they are used independently of each other.

Line 36: papernet:
Details of papernet, the first channel in this connection profile, will
follow.

Line 41: orderers:
Details of all the orderers for papernet follow. You can see in line 45 that
the orderer for this channel is orderer1.magnetocorp.example.com. This is
just a logical name; later in the connection profile (lines 134 - 147), there
will be details of how to connect to this orderer. Notice that
orderer2.digibank.example.com is not in this list; it makes sense that
applications use their own organization’s orderers, rather than those from a
different organization.

Line 49: peers:
Details of all the peers for papernet will follow.
You can see three peers listed from MagnetoCorp:
peer1.magnetocorp.example.com, peer2.magnetocorp.example.com and
peer3.magnetocorp.example.com. It’s not necessary to list all the peers in
MagnetoCorp, as has been done here. You can see only one peer listed from
DigiBank: peer9.digibank.example.com; including this peer starts to imply
that the endorsement policy requires MagnetoCorp and DigiBank to endorse
transactions, as we’ll now confirm. It’s good practice to have multiple peers
to avoid single points of failure.
Underneath each peer you can see four non-exclusive roles: endorsingPeer,
chaincodeQuery, ledgerQuery and eventSource. See how peer1 and
peer2 can perform all roles as they host papercontract. Contrast to
peer3, which can only be used for notifications, or ledger queries that
access the blockchain component of the ledger rather than the world state, and
hence do not need to have smart contracts installed. Notice how peer9 should
not be used for anything other than endorsement, because those roles are
better served by MagnetoCorp peers.
Again, see how the peers are described according to their logical names and
their roles. Later in the profile, we’ll see the physical information for
these peers.

Line 97: organizations:
Details of all the organizations will follow, for all channels.  Note that
these organizations are for all channels, even though papernet is currently
the only one listed.  That’s because organizations can be in multiple
channels, and channels can have multiple organizations. Moreover, some
application operations relate to organizations rather than channels. For
example, an application can request notification from one or all peers within
its organization, or all organizations within the network – using connection
options.  For this, there needs to be an organization
to peer mapping, and this section provides it.

Line 101: MagnetoCorp:
All peers that are considered part of MagnetoCorp are listed: peer1,
peer2 and peer3. Likewise for Certificate Authorities. Again, note the
logical name usages, the same as the channels: section; physical information
will follow later in the profile.

Line 121: DigiBank:
Only peer9 is listed as part of DigiBank, and no Certificate Authorities.
That’s because these other peers and the DigiBank CA are not relevant for
users of this connection profile.

Line 134: orderers:
The physical information for orderers is now listed. As this connection
profile only mentioned one orderer for papernet, you see
orderer1.magnetocorp.example.com details listed. These include its IP
address and port, and gRPC options that can override the defaults used when
communicating with the orderer, if necessary. As with peers:, for high
availability, specifying more than one orderer is a good idea.

Line 152: peers:
The physical information for all previous peers is now listed.  This
connection profile has three peers for MagnetoCorp: peer1, peer2, and
peer3; for DigiBank, a single peer peer9 has its information listed. For
each peer, as with orderers, their IP address and port is listed, together
with gRPC options that can override the defaults used when communicating with
a particular peer, if necessary.

Line 194: certificateAuthorities:
The physical information for certificate authorities is now listed.  The
connection profile has a single CA listed for MagnetoCorp, ca1-magnetocorp,
and its physical information follows. As well as IP details, the registrar
information allows this CA to be used for Certificate Signing Requests (CSR).
These are used to request new certificates for locally generated
public/private key pairs.

Now you’ve understood a connection profile for MagnetoCorp, you might like to
look at a
corresponding
profile for DigiBank. Locate where the profile is the same as MagnetoCorp’s, see
where it’s similar, and finally where it’s different. Think about why these
differences make sense for DigiBank applications.
That’s everything you need to know about connection profiles. In summary, a
connection profile defines sufficient channels, organizations, peers, orderers
and certificate authorities for an application to configure a gateway. The
gateway allows the application to focus on business logic rather than the
details of the network topology.

Sample¶
This file is reproduced inline from the GitHub commercial paper
sample.
1: ---
2: #
3: # [Required]. A connection profile contains information about a set of network
4: # components. It is typically used to configure gateway, allowing applications
5: # interact with a network channel without worrying about the underlying
6: # topology. A connection profile is normally created by an administrator who
7: # understands this topology.
8: #
9: name: "papernet.magnetocorp.profile.sample"
10: #
11: # [Optional]. Analogous to HTTP, properties with an "x-" prefix are deemed
12: # "application-specific", and ignored by the gateway. For example, property
13: # "x-type" with value "hlfv1" was originally used to identify a connection
14: # profile for Fabric 1.x rather than 0.x.
15: #
16: x-type: "hlfv1"
17: #
18: # [Required]. A short description of the connection profile
19: #
20: description: "Sample connection profile for documentation topic"
21: #
22: # [Required]. Connection profile schema version. Used by the gateway to
23: # interpret these data.
24: #
25: version: "1.0"
26: #
27: # [Optional]. A logical description of each network channel; its peer and
28: # orderer names and their roles within the channel. The physical details of
29: # these components (e.g. peer IP addresses) will be specified later in the
30: # profile; we focus first on the logical, and then the physical.
31: #
32: channels:
33:   #
34:   # [Optional]. papernet is the only channel in this connection profile
35:   #
36:   papernet:
37:     #
38:     # [Optional]. Channel orderers for PaperNet. Details of how to connect to
39:     # them is specified later, under the physical "orderers:" section
40:     #
41:     orderers:
42:     #
43:     # [Required]. Orderer logical name
44:     #
45:       - orderer1.magnetocorp.example.com
46:     #
47:     # [Optional]. Peers and their roles
48:     #
49:     peers:
50:     #
51:     # [Required]. Peer logical name
52:     #
53:       peer1.magnetocorp.example.com:
54:         #
55:         # [Optional]. Is this an endorsing peer? (It must have chaincode
56:         # installed.) Default: true
57:         #
58:         endorsingPeer: true
59:         #
60:         # [Optional]. Is this peer used for query? (It must have chaincode
61:         # installed.) Default: true
62:         #
63:         chaincodeQuery: true
64:         #
65:         # [Optional]. Is this peer used for non-chaincode queries? All peers
66:         # support these types of queries, which include queryBlock(),
67:         # queryTransaction(), etc. Default: true
68:         #
69:         ledgerQuery: true
70:         #
71:         # [Optional]. Is this peer used as an event hub? All peers can produce
72:         # events. Default: true
73:         #
74:         eventSource: true
75:       #
76:       peer2.magnetocorp.example.com:
77:         endorsingPeer: true
78:         chaincodeQuery: true
79:         ledgerQuery: true
80:         eventSource: true
81:       #
82:       peer3.magnetocorp.example.com:
83:         endorsingPeer: false
84:         chaincodeQuery: false
85:         ledgerQuery: true
86:         eventSource: true
87:       #
88:       peer9.digibank.example.com:
89:         endorsingPeer: true
90:         chaincodeQuery: false
91:         ledgerQuery: false
92:         eventSource: false
93: #
94: # [Required]. List of organizations for all channels. At least one organization
95: # is required.
96: #
97: organizations:
98:    #
99:    # [Required]. Organizational information for MagnetoCorp
100:   #
101:   MagnetoCorp:
102:     #
103:     # [Required]. The MSPID used to identify MagnetoCorp
104:     #
105:     mspid: MagnetoCorpMSP
106:     #
107:     # [Required]. The MagnetoCorp peers
108:     #
109:     peers:
110:       - peer1.magnetocorp.example.com
111:       - peer2.magnetocorp.example.com
112:       - peer3.magnetocorp.example.com
113:     #
114:     # [Optional]. Fabric-CA Certificate Authorities.
115:     #
116:     certificateAuthorities:
117:       - ca-magnetocorp
118:   #
119:   # [Optional]. Organizational information for DigiBank
120:   #
121:   DigiBank:
122:     #
123:     # [Required]. The MSPID used to identify DigiBank
124:     #
125:     mspid: DigiBankMSP
126:     #
127:     # [Required]. The DigiBank peers
128:     #
129:     peers:
130:       - peer9.digibank.example.com
131: #
132: # [Optional]. Orderer physical information, by orderer name
133: #
134: orderers:
135:   #
136:   # [Required]. Name of MagnetoCorp orderer
137:   #
138:   orderer1.magnetocorp.example.com:
139:     #
140:     # [Required]. This orderer's IP address
141:     #
142:     url: grpc://localhost:7050
143:     #
144:     # [Optional]. gRPC connection properties used for communication
145:     #
146:     grpcOptions:
147:       ssl-target-name-override: orderer1.magnetocorp.example.com
148: #
149: # [Required]. Peer physical information, by peer name. At least one peer is
150: # required.
151: #
152: peers:
153:   #
154:   # [Required]. First MagetoCorp peer physical properties
155:   #
156:   peer1.magnetocorp.example.com:
157:     #
158:     # [Required]. Peer's IP address
159:     #
160:     url: grpc://localhost:7151
161:     #
162:     # [Optional]. gRPC connection properties used for communication
163:     #
164:     grpcOptions:
165:       ssl-target-name-override: peer1.magnetocorp.example.com
166:       request-timeout: 120001
167:   #
168:   # [Optional]. Other MagnetoCorp peers
169:   #
170:   peer2.magnetocorp.example.com:
171:     url: grpc://localhost:7251
172:     grpcOptions:
173:       ssl-target-name-override: peer2.magnetocorp.example.com
174:       request-timeout: 120001
175:   #
176:   peer3.magnetocorp.example.com:
177:     url: grpc://localhost:7351
178:     grpcOptions:
179:       ssl-target-name-override: peer3.magnetocorp.example.com
180:       request-timeout: 120001
181:   #
182:   # [Required]. Digibank peer physical properties
183:   #
184:   peer9.digibank.example.com:
185:     url: grpc://localhost:7951
186:     grpcOptions:
187:       ssl-target-name-override: peer9.digibank.example.com
188:       request-timeout: 120001
189: #
190: # [Optional]. Fabric-CA Certificate Authority physical information, by name.
191: # This information can be used to (e.g.) enroll new users. Communication is via
192: # REST, hence options relate to HTTP rather than gRPC.
193: #
194: certificateAuthorities:
195:   #
196:   # [Required]. MagnetoCorp CA
197:   #
198:   ca1-magnetocorp:
199:     #
200:     # [Required]. CA IP address
201:     #
202:     url: http://localhost:7054
203:     #
204:     # [Optioanl]. HTTP connection properties used for communication
205:     #
206:     httpOptions:
207:       verify: false
208:     #
209:     # [Optional]. Fabric-CA supports Certificate Signing Requests (CSRs). A
210:     # registrar is needed to enroll new users.
211:     #
212:     registrar:
213:       - enrollId: admin
214:         enrollSecret: adminpw
215:     #
216:     # [Optional]. The name of the CA.
217:     #
218:     caName: ca-magnetocorp

Connection Options¶
Audience: Architects, administrators, application and smart contract
developers
Connection options are used in conjunction with a connection profile to control
precisely how a gateway interacts with a network. Using a gateway allows an
application to focus on business logic rather than network topology.
In this topic, we’re going to cover:

Why connection options are important
How an application uses connection options
What each connection option does
When to use a particular connection option

Scenario¶
A connection option specifies a particular aspect of a gateway’s behaviour.
Gateways are important for many reasons, the primary being to
allow an application to focus on business logic and smart contracts, while it
manages interactions with the many components of a network.
 The different interaction points
where connection options control behaviour. These options are explained fully in
the text.
One example of a connection option might be to specify that the gateway used by
the issue application should use identity Isabella to submit transactions to
the papernet network. Another might be that a gateway should wait for all
three nodes from MagnetoCorp to confirm a transaction has been committed
returning control. Connection options allow applications to specify the precise
behaviour of a gateway’s interaction with the network. Without a gateway,
applications need to do a lot more work; gateways save you time, make your
application more readable, and less error prone.

Usage¶
We’ll describe the full set of connection options available to an
application in a moment; let’s first see how they are specified by the
sample MagnetoCorp issue application:
const userName = 'User1@org1.example.com';
const wallet = new FileSystemWallet('../identity/user/isabella/wallet');

const connectionOptions = {
  identity: userName,
  wallet: wallet,
  eventHandlerOptions: {
    commitTimeout: 100,
    strategy: EventStrategies.MSPID_SCOPE_ANYFORTX
    }
  };

await gateway.connect(connectionProfile, connectionOptions);

See how the identity and wallet options are simple properties of the
connectionOptions object. They have values userName and wallet
respectively, which were set earlier in the code. Contrast these options with
the eventHandlerOptions option which is an object in its own right. It has
two properties: commitTimeout: 100 (measured in seconds) and strategy: EventStrategies.MSPID_SCOPE_ANYFORTX.
See how connectionOptions is passed to a gateway as a complement to
connectionProfile; the network is identified by the connection profile and
the options specify precisely how the gateway should interact with it. Let’s now
look at the available options.

Options¶
Here’s a list of the available options and what they do.

wallet identifies the wallet that will be used by the gateway on behalf of
the application. See interaction 1; the wallet is specified by the
application, but it’s actually the gateway that retrieves identities from it.
A wallet must be specified; the most important decision is the
type of wallet to use, whether that’s file system,
in-memory, HSM or database.

identity is the user identity that the application will use from wallet.
See interaction 2a; the user identity is specified by the application and
represents the user of the application, Isabella, 2b. The identity is
actually retrieved by the gateway.
In our example, Isabella’s identity will be used by different MSPs (2c,
2d) to identify her as being from MagnetoCorp, and having a particular
role within it. These two facts will correspondingly determine her permission
over resources, such as being able to read and write the ledger, for example.
A user identity must be specified. As you can see, this identity is
fundamental to the idea that Hyperledger Fabric is a permissioned network –
all actors have an identity, including applications, peers and orderers, which
determines their control over resources. You can read more about this idea in the membership services topic.

clientTlsIdentity is the identity that is retrieved from a wallet (3a)
and used for secure communications (3b) between the gateway and different
channel components, such as peers and orderers.
Note that this identity is different to the user identity.  Even though
clientTlsIdentity is important for secure communications, it is not as
foundational as the user identity because its scope does not extend beyond
secure network communications.
clientTlsIdentity is optional. You are advised to set it in production
environments. You should always use a different clientTlsIdentity to
identity because these identities have very different meanings and
lifecycles. For example, if your clientTlsIdentity was compromised, then so
would your identity; it’s more secure to keep them separate.

eventHandlerOptions.commitTimeout is optional. It specifies, in seconds, the
maximum amount of time the gateway should wait for a transaction to be
committed by any peer (4a) before returning control to the application.
The set of peers to use for notification is determined by the
eventHandlerOptions.strategy option. If a commitTimeout is not
specified, the gateway will use a timeout of 300 seconds.

eventHandlerOptions.strategy is optional. It identifies the set of peers
that a gateway should use to listen for notification that a transaction has
been committed. For example, whether to listen for a single peer, or all
peers, from its organization. It can take one of the following values:

EventStrategies.MSPID_SCOPE_ANYFORTX Listen for any peer within the
user’s organization. In our example, see interaction points 4b; any of
peer 1, peer 2 or peer 3 from MagnetoCorp can notify the gateway.

EventStrategies.MSPID_SCOPE_ALLFORTX This is the default value. Listen
for all peers within the user’s organization. In our example peer, see
interaction point 4b. All peers from MagnetoCorp must all have notified
the gateway; peer 1, peer 2 and peer 3. Peers are only counted if they are
known/discovered and available; peers that are stopped or have failed are
not included.

EventStrategies.NETWORK_SCOPE_ANYFORTX Listen for any peer within the
entire network channel. In our example, see interaction points 4b and
4c; any of peer 1-3 from MagnetoCorp or peer 7-9 of DigiBank can notify
the gateway.

EventStrategies.NETWORK_SCOPE_ALLFORTX Listen for all peers within the
entire network channel. In our example, see interaction points 4b and
4c. All peers from MagnetoCorp and DigiBank must notify the gateway;
peers 1-3 and peers 7-9. Peers are only counted if they are known/discovered
and available; peers that are stopped or have failed are not included.

<PluginEventHandlerFunction> The name of a user-defined event handler.
This allows a user to define their own logic for event handling. See how to
define
a plugin event handler, and examine a sample
handler.
A user-defined event handler is only necessary if you have very specific
event handling requirements; in general, one of the built-in event
strategies will be sufficient. An example of a user-defined event handler
might be to wait for more than half the peers in an organization to confirm
a transaction has been committed.
If you do specify a user-defined event handler, it does not affect your
application logic; it is quite separate from it. The handler is called by
the SDK during processing; it decides when to call it, and uses its results
to select which peers to use for event notification. The application
receives control when the SDK has finished its processing.
If a user-defined event handler is not specified then the default values for
EventStrategies are used.

discovery.enabled is optional and has possible values true or false. The
default is true. It determines whether the gateway uses service
discovery to augment the network topology
specified in the connection profile. See interaction point 6; peer’s
gossip information used by the gateway.
This value will be overridden by the INITIALIIZE-WITH-DISCOVERY environment
variable, which can be set to true or false.

discovery.asLocalhost is optional and has possible values true or false.
The default is true. It determines whether IP addresses found during service
discovery are translated from the docker network to the local host.
Typically developers will write applications that use docker containers for
their network components such as peers, orderers and CAs, but that do not run
in docker containers themselves. This is why true is the default; in
production environments, applications will likely run in docker containers in
the same manner as network components and therefore address translation is not
required. In this case, applications should either explicitly specify false
or use the environment variable override.
This value will be overridden by the DISCOVERY-AS-LOCALHOST environment
variable, which can be set to true or false.

Considerations¶
The following list of considerations is helpful when deciding how to choose
connection options.

eventHandlerOptions.commitTimeout and eventHandlerOptions.strategy work
together. For example, commitTimeout: 100 and strategy: EventStrategies.MSPID_SCOPE_ANYFORTX means that the gateway will wait for up
to 100 seconds for any peer to confirm a transaction has been committed. In
contrast, specifying strategy: EventStrategies.NETWORK_SCOPE_ALLFORTX means
that the gateway will wait up to 100 seconds for all peers in all
organizations.

The default value of eventHandlerOptions.strategy: EventStrategies.MSPID_SCOPE_ALLFORTX will wait for all peers in the
application’s organization to commit the transaction. This is a good default
because applications can be sure that all their peers have an up-to-date copy
of the ledger, minimizing concurrency
issues 
However, as the number of peers in an organization grows, it becomes a little
unnecessary to wait for all peers, in which case using a pluggable event
handler can provide a more efficient strategy. For example the same set of
peers could be used to submit transactions and listen for notifications, on
the safe assumption that consensus will keep all ledgers synchronized.

Service discovery requires clientTlsIdentity to be set. That’s because the
peers exchanging information with an application need to be confident that
they are exchanging information with entities they trust. If
clientTlsIdentity is not set, then discovery will not be obeyed,
regardless of whether or not it is set.

Although applications can set connection options when they connect to the
gateway, it can be necessary for these options to be overridden by an
administrator. That’s because options relate to network interactions, which
can vary over time. For example, an administrator trying to understand the
effect of using service discovery on network performance.
A good approach is to define application overrides in a configuration file
which is read by the application when it configures its connection to the
gateway.
Because the discovery options enabled and asLocalHost are most frequently
required to be overridden by administrators, the environment variables
INITIALIIZE-WITH-DISCOVERY and DISCOVERY-AS-LOCALHOST are provided for
convenience. The administrator should set these in the production runtime
environment of the application, which will most likely be a docker container.

Wallet¶
Audience: Architects, application and smart contract developers
A wallet contains a set of user identities. An application run by a user selects
one of these identities when it connects to a channel. Access rights to channel
resources, such as the ledger, are determined using this identity in combination
with an MSP.
In this topic, we’re going to cover:

Why wallets are important
How wallets are organized
Different types of wallet
Wallet operations

Scenario¶
When an application connects to a network channel such as PaperNet, it selects a
user identity to do so, for example ID1. The channel MSPs associate ID1 with
a role within a particular organization, and this role will ultimately determine
the application’s rights over channel resources. For example, ID1 might
identify a user as a member of the MagnetoCorp organization who can read and
write to the ledger, whereas ID2 might identify an administrator in
MagnetoCorp who can add a new organization to a consortium.
 Two users, Isabella and Balaji
have wallets containing different identities they can use to connect to
different network channels, PaperNet and BondNet.
Consider the example of two users; Isabella from MagnetoCorp and Balaji from
DigiBank.  Isabella is going to use App 1 to invoke a smart contract in PaperNet
and a different smart contract in BondNet.  Similarly, Balaji is going to use
App 2 to invoke smart contracts, but only in PaperNet. (It’s very
easy for applications to access multiple
networks and multiple smart contracts within them.)
See how:

MagnetoCorp uses CA1 to issue identities and DigiBank uses CA2 to issue
identities. These identities are stored in user wallets.
Balaji’s wallet holds a single identity, ID4 issued by CA2. Isabella’s
wallet has many identities, ID1, ID2 and ID3, issued by CA1. Wallets
can hold multiple identities for a single user, and each identity can be
issued by a different CA.
Both Isabella and Balaji connect to PaperNet, and its MSPs determine that
Isabella is a member of the MagnetoCorp organization, and Balaji is a member
of the DigiBank organization, because of the respective CAs that issued their
identities. (It is
possible for an
organization to use multiple CAs, and for a single CA to support multiple
organizations.)
Isabella can use ID1 to connect to both PaperNet and BondNet. In both cases,
when Isabella uses this identity, she is recognized as a member of
MangetoCorp.
Isabella can use ID2 to connect to BondNet, in which case she is identified
as an administrator of MagnetoCorp. This gives Isabella two very different
privileges: ID1 identifies her as a simple member of MagnetoCorp who can
read and write to the BondNet ledger, whereas ID2 identities her as a
MagnetoCorp administrator who can add a new organization to BondNet.
Balaji cannot connect to BondNet with ID4. If he tried to connect, ID4
would not be recognized as belonging to DigiBank because CA2 is not known to
BondNet’s MSP.

Types¶
There are different types of wallets according to where they store their
identities:
 The three different types of wallet storage:
File system, In-memory and CouchDB.

File system: This is the most common place to store wallets; file systems
are pervasive, easy to understand, and can be network mounted. They are a good
default choice for wallets.
In-memory: A wallet in application storage. Use this type of wallet when
your application is running in a constrained environment without access to a
file system; typically a web browser. It’s worth remembering that this type of
wallet is volatile; identities will be lost after the application ends
normally or crashes.
CouchDB: A wallet stored in CouchDB. This is the rarest form of wallet
storage, but for those users who want to use the database back-up and restore
mechanisms, CouchDB wallets can provide a useful option to simplify disaster
recovery.

Use factory functions provided by the Wallets
class
to create wallets.

Hardware Security Module¶
A Hardware Security Module (HSM) is an ultra-secure, tamper-proof device that
stores digital identity information, particularly private keys. HSMs can be
locally attached to your computer or network accessible. Most HSMs provide the
ability to perform on-board encryption with private keys, such that the private
keys never leave the HSM.
An HSM can be used with any of the wallet types. In this case the certificate
for an identity will be stored in the wallet and the private key will be stored
in the HSM.
To enable the use of HSM-managed identities, an IdentityProvider must be
configured with the HSM connection information and registered with the wallet.
For further details, refer to the Using wallets to manage identities tutorial.

Structure¶
A single wallet can hold multiple identities, each issued by a particular
Certificate Authority. Each identity has a standard structure comprising a
descriptive label, an X.509 certificate containing a public key, a private key,
and some Fabric-specific metadata. Different wallet types map this
structure appropriately to their storage mechanism.
 A Fabric wallet can hold multiple
identities with certificates issued by a different Certificate Authority.
Identities comprise certificate, private key and Fabric metadata.
There’s a couple of key class methods that make it easy to manage wallets and
identities:
const identity: X509Identity = {
    credentials: {
        certificate: certificatePEM,
        privateKey: privateKeyPEM,
    },
    mspId: 'Org1MSP',
    type: 'X.509',
};
await wallet.put(identityLabel, identity);

See how an identity is created that has metadata Org1MSP, a certificate and
a privateKey. See how wallet.put() adds this identity to the wallet with a
particular identityLabel.
The Gateway class only requires the mspId and type metadata to be set for
an identity – Org1MSP and X.509 in the above example. It currently uses the
MSP ID value to identify particular peers from a connection profile,
for example when a specific notification strategy is
requested. In the DigiBank gateway file networkConnection.yaml, see how
Org1MSP notifications will be associated with peer0.org1.example.com:
organizations:
  Org1:
    mspid: Org1MSP

    peers:
      - peer0.org1.example.com

You really don’t need to worry about the internal structure of the different
wallet types, but if you’re interested, navigate to a user identity folder in
the commercial paper sample:
magnetocorp/identity/user/isabella/
                                  wallet/
                                        User1@org1.example.com.id

You can examine these files, but as discussed, it’s easier to use the SDK to
manipulate these data.

Operations¶
The different wallet types all implement a common
Wallet
interface which provides a standard set of APIs to manage identities. It means
that applications can be made independent of the underlying wallet storage
mechanism; for example, File system and HSM wallets are handled in a very
similar way.
 Wallets follow a
lifecycle: they can be created or opened, and identities can be read, added and
deleted.
An application can use a wallet according to a simple lifecycle. Wallets can be
opened or created, and subsequently identities can be added, updated, read and
deleted. Spend a little time on the different Wallet methods in the
JSDoc
to see how they work; the commercial paper tutorial provides a nice example in
addToWallet.js:
const wallet = await Wallets.newFileSystemWallet('../identity/user/isabella/wallet');

const cert = fs.readFileSync(path.join(credPath, '.../User1@org1.example.com-cert.pem')).toString();
const key = fs.readFileSync(path.join(credPath, '.../_sk')).toString();

const identityLabel = 'User1@org1.example.com';
const identity = {
    credentials: {
        certificate: cert,
        privateKey: key,
    },
    mspId: 'Org1MSP',
    type: 'X.509',
};

await wallet.put(identityLabel, identity);

Notice how:

When the program is first run, a wallet is created on the local file system at
.../isabella/wallet.
a certificate cert and private key are loaded from the file system.
a new X.509 identity is created with cert, key and Org1MSP.
the new identity is added to the wallet with wallet.put() with a label
User1@org1.example.com.

That’s everything you need to know about wallets. You’ve seen how they hold
identities that are used by applications on behalf of users to access Fabric
network resources. There are different types of wallets available depending on
your application and security needs, and a simple set of APIs to help
applications manage wallets and the identities within them.

Gateway¶
Audience: Architects, application and smart contract developers
A gateway manages the network interactions on behalf of an application, allowing
it to focus on business logic. Applications connect to a gateway and then all
subsequent interactions are managed using that gateway’s configuration.
In this topic, we’re going to cover:

Why gateways are important
How applications use a gateway
How to define a static gateway
How to define a dynamic gateway for service discovery
Using multiple gateways

Scenario¶
A Hyperledger Fabric network channel can constantly change.  The peer, orderer
and CA components, contributed by the different organizations in the network,
will come and go. Reasons for this include increased or reduced business demand,
and both planned and unplanned outages. A gateway relieves an application of
this burden, allowing it to focus on the business problem it is trying to solve.
 A MagnetoCorp and DigiBank
applications (issue and buy) delegate their respective network interactions to
their gateways. Each gateway understands the network channel topology comprising
the multiple peers and orderers of two organizations MagnetoCorp and DigiBank,
leaving applications to focus on business logic. Peers can talk to each other
both within and across organizations using the gossip protocol.
A gateway can be used by an application in two different ways:

Static: The gateway configuration is completely defined in a connection
profile. All the peers, orderers and CAs
available to an application are statically defined in the connection profile
used to configure the gateway. For peers, this includes their role as an
endorsing peer or event notification hub, for example. You can read more about
these roles in the connection profile topic.
The SDK will use this static topology, in conjunction with gateway
connection options, to manage the transaction
submission and notification processes. The connection profile must contain
enough of the network topology to allow a gateway to interact with the
network on behalf of the application; this includes the network channels,
organizations, orderers, peers and their roles.

Dynamic: The gateway configuration is minimally defined in a connection
profile. Typically, one or two peers from the application’s organization are
specified, and they use service discovery to
discover the available network topology. This includes peers, orderers,
channels, deployed smart contracts and their endorsement policies. (In
production environments, a gateway configuration should specify at least two
peers for availability.)
The SDK will use all of the static and discovered topology information, in
conjunction with gateway connection options, to manage the transaction
submission and notification processes. As part of this, it will also
intelligently use the discovered topology; for example, it will calculate
the minimum required endorsing peers using the discovered endorsement policy
for the smart contract.

You might ask yourself whether a static or dynamic gateway is better? The
trade-off is between predictability and responsiveness. Static networks will
always behave the same way, as they perceive the network as unchanging. In this
sense they are predictable – they will always use the same peers and orderers
if they are available. Dynamic networks are more responsive as they understand
how the network changes – they can use newly added peers and orderers, which
brings extra resilience and scalability, at potentially some cost in
predictability. In general it’s fine to use dynamic networks, and indeed this
the default mode for gateways.
Note that the same connection profile can be used statically or dynamically.
Clearly, if a profile is going to be used statically, it needs to be
comprehensive, whereas dynamic usage requires only sparse population.
Both styles of gateway are transparent to the application; the application
program design does not change whether static or dynamic gateways are used. This
also means that some applications may use service discovery, while others may
not. In general using dynamic discovery means less definition and more
intelligence by the SDK; it is the default.

Connect¶
When an application connects to a gateway, two options are provided. These are
used in subsequent SDK processing:
  await gateway.connect(connectionProfile, connectionOptions);

Connection profile: connectionProfile is the gateway configuration that
will be used for transaction processing by the SDK, whether statically or
dynamically. It can be specified in YAML or JSON, though it must be converted
to a JSON object when passed to the gateway:
let connectionProfile = yaml.safeLoad(fs.readFileSync('../gateway/paperNet.yaml', 'utf8'));

Read more about connection profiles and how
to configure them.

Connection options: connectionOptions allow an application to declare
rather than implement desired transaction processing behaviour. Connection
options are interpreted by the SDK to control interaction patterns with
network components, for example to select which identity to connect with, or
which peers to use for event notifications. These options significantly reduce
application complexity without compromising functionality. This is possible
because the SDK has implemented much of the low level logic that would
otherwise be required by applications; connection options control this logic
flow.
Read about the list of available connection options
and when to use them.

Static¶
Static gateways define a fixed view of a network. In the MagnetoCorp
scenario, a gateway might identify a single peer from MagnetoCorp,
a single peer from DigiBank, and a MagentoCorp orderer. Alternatively, a gateway
might define all peers and orderers from MagnetCorp and DigiBank. In both
cases, a gateway must define a view of the network sufficient to get commercial
paper transactions endorsed and distributed.
Applications can use a gateway statically by explicitly specifying the connect
option discovery: { enabled:false } on the gateway.connect() API.
Alternatively, the environment variable setting FABRIC_SDK_DISCOVERY=false
will always override the application choice.
Examine the connection
profile
used by the MagnetoCorp issue application. See how all the peers, orderers and
even CAs are specified in this file, including their roles.
It’s worth bearing in mind that a static gateway represents a view of a network
at a moment in time.  As networks change, it may be important to reflect this
in a change to the gateway file. Applications will automatically pick up these
changes when they re-load the gateway file.

Dynamic¶
Dynamic gateways define a small, fixed starting point for a network. In the
MagnetoCorp scenario, a dynamic gateway might identify just a
single peer from MagnetoCorp; everything else will be discovered! (To provide
resiliency, it might be better to define two such bootstrap peers.)
If service discovery is selected by an
application, the topology defined in the gateway file is augmented with that
produced by this process. Service discovery starts with the gateway definition,
and finds all the connected peers and orderers within the MagnetoCorp
organization using the gossip protocol. If anchor
peers have been defined for a channel, then
service discovery will use the gossip protocol across organizations to discover
components within the connected organization. This process will also discover
smart contracts installed on peers and their endorsement policies defined at a
channel level. As with static gateways, the discovered network must be
sufficient to get commercial paper transactions endorsed and distributed.
Dynamic gateways are the default setting for Fabric applications. They can be
explicitly specified using the connect option discovery: { enabled:true } on
the gateway.connect() API. Alternatively, the environment variable setting
FABRIC_SDK_DISCOVERY=true will always override the application choice.
A dynamic gateway represents an up-to-date view of a network. As networks
change, service discovery will ensure that the network view is an accurate
reflection of the topology visible to the application. Applications will
automatically pick up these changes; they do not even need to re-load the
gateway file.

Multiple gateways¶
Finally, it is straightforward for an application to define multiple gateways,
both for the same or different networks. Moreover, applications can use the name
gateway both statically and dynamically.
It can be helpful to have multiple gateways. Here are a few reasons:

Handling requests on behalf of different users.
Connecting to different networks simultaneously.
Testing a network configuration, by simultaneously comparing its behaviour
with an existing configuration.

This topic covers how to develop a client application and smart contract to
solve a business problem using Hyperledger Fabric. In a real world Commercial
Paper scenario, involving multiple organizations, you’ll learn about all the
concepts and tasks required to accomplish this goal. We assume that the
blockchain network is already available.
The topic is designed for multiple audiences:

Solution and application architect
Client application developer
Smart contract developer
Business professional

You can choose to read the topic in order, or you can select individual sections
as appropriate. Individual topic sections are marked according to reader
relevance, so whether you’re looking for business or technical information it’ll
be clear when a topic is for you.
The topic follows a typical software development lifecycle. It starts with
business requirements, and then covers all the major technical activities
required to develop an application and smart contract to meet these
requirements.
If you’d prefer, you can try out the commercial paper scenario immediately,
following an abbreviated explanation, by running the commercial paper tutorial. You can return to this topic when you
need fuller explanations of the concepts introduced in the tutorial.

Tutorials¶
Application developers can use the Fabric tutorials to get started building their
own solutions. Start working with Fabric by deploying the test network
on your local machine. You can then use the steps provided by the Deploying a smart contract to a channel
tutorial to deploy and test your smart contracts. The Writing Your First Application
tutorial provides an introduction to how to use the APIs provided by the Fabric
SDKs to invoke smart contracts from your client applications. For an in depth
overview of how Fabric applications and smart contracts work together, you
can visit the Developing Applications topic.
Network operators can use the Deploying a smart contract to a channel tutorial and the
Creating a channel tutorial series to learn
important aspects of administering a running network. Both network operators and
application developers can use the tutorials on
Private data and CouchDB
to explore important Fabric features. When you are ready to deploy Hyperledger
Fabric in production, see the guide for Deploying a production network.
There are two tutorials for updating a channel: Updating a channel configuration and
Updating the capability level of a channel, while Upgrading your components shows how
to upgrade components like peers, ordering nodes, SDKs, and more.
Finally, we provide an introduction to how to write a basic smart contract,
Chaincode for Developers.

Note
If you have questions not addressed by this documentation, or run into
issues with any of the tutorials, please visit the Still Have Questions?
page for some tips on where to find additional help.

Deploying a smart contract to a channel¶
End users interact with the blockchain ledger by invoking smart contracts. In Hyperledger Fabric, smart contracts are deployed in packages referred to as chaincode. Organizations that want to validate transactions or query the ledger need to install a chaincode on their peers. After a chaincode has been installed on the peers joined to a channel, channel members can deploy the chaincode to the channel and use the smart contracts in the chaincode to create or update assets on the channel ledger.
A chaincode is deployed to a channel using a process known as the Fabric chaincode lifecycle. The Fabric chaincode lifecycle allows multiple organizations to agree how a chaincode will be operated before it can be used to create transactions. For example, while an endorsement policy specifies which organizations need to execute a chaincode to validate a transaction, channel members need to use the Fabric chaincode lifecycle to agree on the chaincode endorsement policy. For a more in-depth overview about how to deploy and manage a chaincode on a channel, see Fabric chaincode lifecycle.
You can use this tutorial to learn how to use the peer lifecycle chaincode commands to deploy a chaincode to a channel of the Fabric test network. Once you have an understanding of the commands, you can use the steps in this tutorial to deploy your own chaincode to the test network, or to deploy chaincode to a production network. In this tutorial, you will deploy the Fabcar chaincode that is used by the Writing your first application tutorial.
Note: These instructions use the Fabric chaincode lifecycle introduced in the v2.0 release. If you would like to use the previous lifecycle to install and instantiate a chaincode, visit the v1.4 version of the Fabric documentation.

Start the network¶
We will start by deploying an instance of the Fabric test network. Before you begin, make sure that that you have installed the Prerequisites and Installed the Samples, Binaries and Docker Images. Use the following command to navigate to the test network directory within your local clone of the fabric-samples repository:
cd fabric-samples/test-network

For the sake of this tutorial, we want to operate from a known initial state. The following command will kill any active or stale docker containers and remove previously generated artifacts.
./network.sh down

You can then use the following command to start the test network:
./network.sh up createChannel

The createChannel command creates a channel named mychannel with two channel members, Org1 and Org2. The command also joins a peer that belongs to each organization to the channel. If the network and the channel are created successfully, you can see the following message printed in the logs:
========= Channel successfully joined ===========

We can now use the Peer CLI to deploy the Fabcar chaincode to the channel using the following steps:

Step one: Package the smart contract
Step two: Install the chaincode package
Step three: Approve a chaincode definition
Step four: Committing the chaincode definition to the channel

Setup Logspout (optional)¶
This step is not required but is extremely useful for troubleshooting chaincode. To monitor the logs of the smart contract, an administrator can view the aggregated output from a set of Docker containers using the logspout tool. The tool collects the output streams from different Docker containers into one place, making it easy to see what’s happening from a single window. This can help administrators debug problems when they install smart contracts or developers when they invoke smart contracts. Because some containers are created purely for the purposes of starting a smart contract and only exist for a short time, it is helpful to collect all of the logs from your network.
A script to install and configure Logspout, monitordocker.sh, is already included in the commercial-paper sample in the Fabric samples. We will use the same script in this tutorial as well. The Logspout tool will continuously stream logs to your terminal, so you will need to use a new terminal window. Open a new terminal and navigate to the test-network directory.
cd fabric-samples/test-network

You can run the monitordocker.sh script from any directory. For ease of use, we will copy the monitordocker.sh script from the commercial-paper sample to your working directory
cp ../commercial-paper/organization/digibank/configuration/cli/monitordocker.sh .
# if you're not sure where it is
find . -name monitordocker.sh

You can then start Logspout by running the following command:
./monitordocker.sh net_test

You should see output similar to the following:
Starting monitoring on all containers on the network net_basic
Unable to find image 'gliderlabs/logspout:latest' locally
latest: Pulling from gliderlabs/logspout
4fe2ade4980c: Pull complete
decca452f519: Pull complete
ad60f6b6c009: Pull complete
Digest: sha256:374e06b17b004bddc5445525796b5f7adb8234d64c5c5d663095fccafb6e4c26
Status: Downloaded newer image for gliderlabs/logspout:latest
1f99d130f15cf01706eda3e1f040496ec885036d485cb6bcc0da4a567ad84361

You will not see any logs at first, but this will change when we deploy our chaincode. It can be helpful to make this terminal window wide and the font small.

Package the smart contract¶
We need to package the chaincode before it can be installed on our peers. The steps are different if you want to install a smart contract written in Go, Java, or JavaScript.

Go¶
Before we package the chaincode, we need to install the chaincode dependences. Navigate to the folder that contains the Go version of the Fabcar chaincode.
cd fabric-samples/chaincode/fabcar/go

The sample uses a Go module to install the chaincode dependencies. The dependencies are listed in a go.mod file in the fabcar/go directory. You should take a moment to examine this file.
$ cat go.mod
module github.com/hyperledger/fabric-samples/chaincode/fabcar/go

go 1.13

require github.com/hyperledger/fabric-contract-api-go v1.1.0

The go.mod file imports the Fabric contract API into the smart contract package. You can open fabcar.go in a text editor to see how the contract API is used to define the SmartContract type at the beginning of the smart contract:
// SmartContract provides functions for managing a car
type SmartContract struct {
    contractapi.Contract
}

The SmartContract type is then used to create the transaction context for the functions defined within the smart contract that read and write data to the blockchain ledger.
// CreateCar adds a new car to the world state with given details
func (s *SmartContract) CreateCar(ctx contractapi.TransactionContextInterface, carNumber string, make string, model string, colour string, owner string) error {
    car := Car{
        Make:   make,
        Model:  model,
        Colour: colour,
        Owner:  owner,
    }

    carAsBytes, _ := json.Marshal(car)

    return ctx.GetStub().PutState(carNumber, carAsBytes)
}

You can learn more about the Go contract API by visiting the API documentation and the smart contract processing topic.
To install the smart contract dependencies, run the following command from the fabcar/go directory.
GO111MODULE=on go mod vendor

If the command is successful, the go packages will be installed inside a vendor folder.
Now that we that have our dependences, we can create the chaincode package. Navigate back to our working directory in the test-network folder so that we can package the chaincode together with our other network artifacts.
cd ../../../test-network

You can use the peer CLI to create a chaincode package in the required format. The peer binaries are located in the bin folder of the fabric-samples repository. Use the following command to add those binaries to your CLI Path:
export PATH=${PWD}/../bin:$PATH

You also need to set the FABRIC_CFG_PATH to point to the core.yaml file in the fabric-samples repository:
export FABRIC_CFG_PATH=$PWD/../config/

To confirm that you are able to use the peer CLI, check the version of the binaries. The binaries need to be version 2.0.0 or later to run this tutorial.
peer version

You can now create the chaincode package using the peer lifecycle chaincode package command:
peer lifecycle chaincode package fabcar.tar.gz --path ../chaincode/fabcar/go/ --lang golang --label fabcar_1

This command will create a package named fabcar.tar.gz in your current directory. The --lang flag is used to specify the chaincode language and the --path flag provides the location of your smart contract code. The --label flag is used to specify a chaincode label that will identity your chaincode after it is installed. It is recommended that your label include the chaincode name and version.
Now that we created the chaincode package, we can install the chaincode on the peers of the test network.

JavaScript¶
Before we package the chaincode, we need to install the chaincode dependences. Navigate to the folder that contains the JavaScript version of the Fabcar chaincode.
cd fabric-samples/chaincode/fabcar/javascript

The dependencies are listed in the package.json file in the fabcar/javascript directory. You should take a moment to examine this file. You can find the dependences section displayed below:
"dependencies": {
        "fabric-contract-api": "^2.0.0",
        "fabric-shim": "^2.0.0"

The package.json file imports the Fabric contract class into the smart contract package. You can open lib/fabcar.js in a text editor to see the contract class imported into the smart contract and used to create the FabCar class.
const { Contract } = require('fabric-contract-api');

class FabCar extends Contract {
    ...
}

The FabCar class provides the transaction context for the functions defined within the smart contract that read and write data to the blockchain ledger.
async createCar(ctx, carNumber, make, model, color, owner) {
    console.info('============= START : Create Car ===========');

    const car = {
        color,
        docType: 'car',
        make,
        model,
        owner,
    };

    await ctx.stub.putState(carNumber, Buffer.from(JSON.stringify(car)));
    console.info('============= END : Create Car ===========');
}

You can learn more about the JavaScript contract API by visiting the API documentation and the smart contract processing topic.
To install the smart contract dependencies, run the following command from the fabcar/javascript directory.
npm install

If the command is successful, the JavaScript packages will be installed inside a npm_modules folder.
Now that we that have our dependences, we can create the chaincode package. Navigate back to our working directory in the test-network folder so that we can package the chaincode together with our other network artifacts.
cd ../../../test-network

You can use the peer CLI to create a chaincode package in the required format. The peer binaries are located in the bin folder of the fabric-samples repository. Use the following command to add those binaries to your CLI Path:
export PATH=${PWD}/../bin:$PATH

You also need to set the FABRIC_CFG_PATH to point to the core.yaml file in the fabric-samples repository:
export FABRIC_CFG_PATH=$PWD/../config/

To confirm that you are able to use the peer CLI, check the version of the binaries. The binaries need to be version 2.0.0 or later to run this tutorial.
peer version

You can now create the chaincode package using the peer lifecycle chaincode package command:
peer lifecycle chaincode package fabcar.tar.gz --path ../chaincode/fabcar/javascript/ --lang node --label fabcar_1

This command will create a package named fabcar.tar.gz in your current directory. The --lang flag is used to specify the chaincode language and the --path flag provides the location of your smart contract code. The --label flag is used to specify a chaincode label that will identity your chaincode after it is installed. It is recommended that your label include the chaincode name and version.
Now that we created the chaincode package, we can install the chaincode on the peers of the test network.

Java¶
Before we package the chaincode, we need to install the chaincode dependences. Navigate to the folder that contains the Java version of the Fabcar chaincode.
cd fabric-samples/chaincode/fabcar/java

The sample uses Gradle to install the chaincode dependencies. The dependencies are listed in the build.gradle file in the fabcar/java directory. You should take a moment to examine this file. You can find the dependences section displayed below:
dependencies {
    compileOnly 'org.hyperledger.fabric-chaincode-java:fabric-chaincode-shim:2.0.+'
    implementation 'com.owlike:genson:1.5'
    testImplementation 'org.hyperledger.fabric-chaincode-java:fabric-chaincode-shim:2.0.+'
    testImplementation 'org.junit.jupiter:junit-jupiter:5.4.2'
    testImplementation 'org.assertj:assertj-core:3.11.1'
    testImplementation 'org.mockito:mockito-core:2.+'
}

The build.gradle file imports the Java chaincode shim into the smart contract package, which includes the contract class. You can find Fabcar smart contract in the src directory. You can navigate to the FabCar.java file and open it in a text editor to see how the contract class is used to create the transaction context for the functions defined that read and write data to the blockchain ledger.
You can learn more about the Java chaincode shim and the contract class by visiting the Java chaincode documentation and the smart contract processing topic.
To install the smart contract dependencies, run the following command from the fabcar/java directory.
./gradlew installDist

If the command is successful, you will be able to find the built smart contract in the build folder.
Now that we have installed the dependences and built the smart contract, we can create the chaincode package. Navigate back to our working directory in the test-network folder so that we can package the chaincode together with our other network artifacts.
cd ../../../test-network

You can use the peer CLI to create a chaincode package in the required format. The peer binaries are located in the bin folder of the fabric-samples repository. Use the following command to add those binaries to your CLI Path:
export PATH=${PWD}/../bin:$PATH

You also need to set the FABRIC_CFG_PATH to point to the core.yaml file in the fabric-samples repository:
export FABRIC_CFG_PATH=$PWD/../config/

To confirm that you are able to use the peer CLI, check the version of the binaries. The binaries need to be version 2.0.0 or later to run this tutorial.
peer version

You can now create the chaincode package using the peer lifecycle chaincode package command:
peer lifecycle chaincode package fabcar.tar.gz --path ../chaincode/fabcar/java/build/install/fabcar --lang java --label fabcar_1

This command will create a package named fabcar.tar.gz in your current directory. The --lang flag is used to specify the chaincode language and the --path flag provides the location of your smart contract code. The --label flag is used to specify a chaincode label that will identity your chaincode after it is installed. It is recommended that your label include the chaincode name and version.
Now that we created the chaincode package, we can install the chaincode on the peers of the test network.

Install the chaincode package¶
After we package the Fabcar smart contract, we can install the chaincode on our peers. The chaincode needs to be installed on every peer that will endorse a transaction. Because we are going to set the endorsement policy to require endorsements from both Org1 and Org2, we need to install the chaincode on the peers operated by both organizations:

peer0.org1.example.com
peer0.org2.example.com

Let’s install the chaincode on the Org1 peer first. Set the following environment variables to operate the peer CLI as the Org1 admin user. The CORE_PEER_ADDRESS will be set to point to the Org1 peer, peer0.org1.example.com.
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

Issue the peer lifecycle chaincode install command to install the chaincode on the peer:
peer lifecycle chaincode install fabcar.tar.gz

If the command is successful, the peer will generate and return the package identifier. This package ID will be used to approve the chaincode in the next step. You should see output similar to the following:
2020-02-12 11:40:02.923 EST [cli.lifecycle.chaincode] submitInstallProposal -> INFO 001 Installed remotely: response:<status:200 payload:"\nIfabcar_1:69de748301770f6ef64b42aa6bb6cb291df20aa39542c3ef94008615704007f3\022\010fabcar_1" >
2020-02-12 11:40:02.925 EST [cli.lifecycle.chaincode] submitInstallProposal -> INFO 002 Chaincode code package identifier: fabcar_1:69de748301770f6ef64b42aa6bb6cb291df20aa39542c3ef94008615704007f3

We can now install the chaincode on the Org2 peer. Set the following environment variables to operate as the Org2 admin and target target the Org2 peer, peer0.org2.example.com.
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

Issue the following command to install the chaincode:
peer lifecycle chaincode install fabcar.tar.gz

The chaincode is built by the peer when the chaincode is installed. The install command will return any build errors from the chaincode if there is a problem with the smart contract code.

Approve a chaincode definition¶
After you install the chaincode package, you need to approve a chaincode definition for your organization. The definition includes the important parameters of chaincode governance such as the name, version, and the chaincode endorsement policy.
The set of channel members who need to approve a chaincode before it can be deployed is governed by the Application/Channel/lifeycleEndorsement policy. By default, this policy requires that a majority of channel members need to approve a chaincode before it can used on a channel. Because we have only two organizations on the channel, and a majority of 2 is 2, we need approve a chaincode definition of Fabcar as Org1 and Org2.
If an organization has installed the chaincode on their peer, they need to include the packageID in the chaincode definition approved by their organization. The package ID is used to associate the chaincode installed on a peer with an approved chaincode definition, and allows an organization to use the chaincode to endorse transactions. You can find the package ID of a chaincode by using the peer lifecycle chaincode queryinstalled command to query your peer.
peer lifecycle chaincode queryinstalled

The package ID is the combination of the chaincode label and a hash of the chaincode binaries. Every peer will generate the same package ID. You should see output similar to the following:
Installed chaincodes on peer:
Package ID: fabcar_1:69de748301770f6ef64b42aa6bb6cb291df20aa39542c3ef94008615704007f3, Label: fabcar_1

We are going to use the package ID when we approve the chaincode, so let’s go ahead and save it as an environment variable. Paste the package ID returned by peer lifecycle chaincode queryinstalled into the command below. Note: The package ID will not be the same for all users, so you need to complete this step using the package ID returned from your command window in the previous step.
export CC_PACKAGE_ID=fabcar_1:69de748301770f6ef64b42aa6bb6cb291df20aa39542c3ef94008615704007f3

Because the environment variables have been set to operate the peer CLI as the Org2 admin, we can approve the chaincode definition of Fabcar as Org2. Chaincode is approved at the organization level, so the command only needs to target one peer. The approval is distributed to the other peers within the organization using gossip. Approve the chaincode definition using the peer lifecycle chaincode approveformyorg command:
peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name fabcar --version 1.0 --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

The command above uses the --package-id flag to include the package identifier in the chaincode definition. The --sequence parameter is an integer that keeps track of the number of times a chaincode has been defined or updated. Because the chaincode is being deployed to the channel for the first time, the sequence number is 1. When the Fabcar chaincode is upgraded, the sequence number will be incremented to 2. If you are using the low level APIs provided by the Fabric Chaincode Shim API, you could pass the --init-required flag to the command above to request the execution of the Init function to initialize the chaincode. The first invoke of the chaincode would need to target the Init function and include the --isInit flag before you could use the other functions in the chaincode to interact with the ledger.
We could have provided a --signature-policy or --channel-config-policy argument to the approveformyorg command to specify a chaincode endorsement policy. The endorsement policy specifies how many peers belonging to different channel members need to validate a transaction against a given chaincode. Because we did not set a policy, the definition of Fabcar will use the default endorsement policy, which requires that a transaction be endorsed by a majority of channel members present when the transaction is submitted. This implies that if new organizations are added or removed from the channel, the endorsement policy
is updated automatically to require more or fewer endorsements. In this tutorial, the default policy will require a majority of 2 out of 2 and transactions will need to be endorsed by a peer from Org1 and Org2. If you want to specify a custom endorsement policy, you can use the Endorsement Policies operations guide to learn about the policy syntax.
You need to approve a chaincode definition with an identity that has an admin role. As a result, the CORE_PEER_MSPCONFIGPATH variable needs to point to the MSP folder that contains an admin identity. You cannot approve a chaincode definition with a client user. The approval needs to be submitted to the ordering service, which will validate the admin signature and then distribute the approval to your peers.
We still need to approve the chaincode definition as Org1. Set the following environment variables to operate as the Org1 admin:
CORE_PEER_LOCALMSPID="Org1MSP"
CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
CORE_PEER_ADDRESS=localhost:7051

You can now approve the chaincode definition as Org1.
peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name fabcar --version 1.0 --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

We now have the majority we need to deploy the Fabcar the chaincode to the channel. While only a majority of organizations need to approve a chaincode definition (with the default policies), all organizations need to approve a chaincode definition to start the chaincode on their peers. If you commit the definition before a channel member has approved the chaincode, the organization will not be able to endorse transactions. As a result, it is recommended that all channel members approve a chaincode before committing the chaincode definition.

Committing the chaincode definition to the channel¶
After a sufficient number of organizations have approved a chaincode definition, one organization can commit the chaincode definition to the channel. If a majority of channel members have approved the definition, the commit transaction will be successful and the parameters agreed to in the chaincode definition will be implemented on the channel.
You can use the peer lifecycle chaincode checkcommitreadiness command to check whether channel members have approved the same chaincode definition. The flags used for the checkcommitreadiness command are identical to the flags used to approve a chaincode for your organization. However, you do not need to include the --package-id flag.
peer lifecycle chaincode checkcommitreadiness --channelID mychannel --name fabcar --version 1.0 --sequence 1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --output json

The command will produce a JSON map that displays if a channel member has approved the parameters that were specified in the checkcommitreadiness command:
    {
            "Approvals": {
                    "Org1MSP": true,
                    "Org2MSP": true
            }
    }

Since both organizations that are members of the channel have approved the same parameters, the chaincode definition is ready to be committed to the channel. You can use the peer lifecycle chaincode commit command to commit the chaincode definition to the channel. The commit command also needs to be submitted by an organization admin.
peer lifecycle chaincode commit -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name fabcar --version 1.0 --sequence 1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --peerAddresses localhost:7051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses localhost:9051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt

The transaction above uses the --peerAddresses flag to target peer0.org1.example.com from Org1 and peer0.org2.example.com from Org2. The commit transaction is submitted to the peers joined to the channel to query the chaincode definition that was approved by the organization that operates the peer. The command needs to target the peers from a sufficient number of organizations to satisfy the policy for deploying a chaincode. Because the approval is distributed within each organization, you can target any peer that belongs to a channel member.
The chaincode definition endorsements by channel members are submitted to the ordering service to be added to a block and distributed to the channel. The peers on the channel then validate whether a sufficient number of organizations have approved the chaincode definition. The peer lifecycle chaincode commit command will wait for the validations from the peer before returning a response.
You can use the peer lifecycle chaincode querycommitted command to confirm that the chaincode definition has been committed to the channel.
peer lifecycle chaincode querycommitted --channelID mychannel --name fabcar --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

If the chaincode was successful committed to the channel, the querycommitted command will return the sequence and version of the chaincode definition:
Committed chaincode definition for chaincode 'fabcar' on channel 'mychannel':
Version: 1, Sequence: 1, Endorsement Plugin: escc, Validation Plugin: vscc, Approvals: [Org1MSP: true, Org2MSP: true]

Invoking the chaincode¶
After the chaincode definition has been committed to a channel, the chaincode will start on the peers joined to the channel where the chaincode was installed. The Fabcar chaincode is now ready to be invoked by client applications. Use the following command create an initial set of cars on the ledger. Note that the invoke command needs target a sufficient number of peers to meet chaincode endorsement policy.
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n fabcar --peerAddresses localhost:7051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses localhost:9051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"function":"initLedger","Args":[]}'

If the command is successful, you should be able to a response similar to the following:
2020-02-12 18:22:20.576 EST [chaincodeCmd] chaincodeInvokeOrQuery -> INFO 001 Chaincode invoke successful. result: status:200

We can use a query function to read the set of cars that were created by the chaincode:
peer chaincode query -C mychannel -n fabcar -c '{"Args":["queryAllCars"]}'

The response to the query should be the following list of cars:
[{"Key":"CAR0","Record":{"make":"Toyota","model":"Prius","colour":"blue","owner":"Tomoko"}},
{"Key":"CAR1","Record":{"make":"Ford","model":"Mustang","colour":"red","owner":"Brad"}},
{"Key":"CAR2","Record":{"make":"Hyundai","model":"Tucson","colour":"green","owner":"Jin Soo"}},
{"Key":"CAR3","Record":{"make":"Volkswagen","model":"Passat","colour":"yellow","owner":"Max"}},
{"Key":"CAR4","Record":{"make":"Tesla","model":"S","colour":"black","owner":"Adriana"}},
{"Key":"CAR5","Record":{"make":"Peugeot","model":"205","colour":"purple","owner":"Michel"}},
{"Key":"CAR6","Record":{"make":"Chery","model":"S22L","colour":"white","owner":"Aarav"}},
{"Key":"CAR7","Record":{"make":"Fiat","model":"Punto","colour":"violet","owner":"Pari"}},
{"Key":"CAR8","Record":{"make":"Tata","model":"Nano","colour":"indigo","owner":"Valeria"}},
{"Key":"CAR9","Record":{"make":"Holden","model":"Barina","colour":"brown","owner":"Shotaro"}}]

Upgrading a smart contract¶
You can use the same Fabric chaincode lifecycle process to upgrade a chaincode that has already been deployed to a channel. Channel members can upgrade a chaincode by installing a new chaincode package and then approving a chaincode definition with the new package ID, a new chaincode version, and with the sequence number incremented by one. The new chaincode can be used after the chaincode definition is committed to the channel. This process allows channel members to coordinate on when a chaincode is upgraded, and ensure that a sufficient number of channel members are ready to use the new chaincode before it is deployed to the channel.
Channel members can also use the upgrade process to change the chaincode endorsement policy. By approving a chaincode definition with a new endorsement policy and committing the chaincode definition to the channel, channel members can change the endorsement policy governing a chaincode without installing a new chaincode package.
To provide a scenario for upgrading the Fabcar chaincode that we just deployed, let’s assume that Org1 and Org2 would like to install a version of the chaincode that is written in another language. They will use the Fabric chaincode lifecycle to update the chaincode version and ensure that both organizations have installed the new chaincode before it becomes active on the channel.
We are going to assume that Org1 and Org2 initially installed the GO version of the Fabcar chaincode, but would be more comfortable working with a chaincode written in JavaScript. The first step is to package the JavaScript version of the Fabcar chaincode. If you used the JavaScript instructions to package your chaincode when you went through the tutorial, you can install new chaincode binaries by following the steps for packaging a chaincode written in Go or Java.
Issue the following commands from the test-network directory to install the chaincode dependences.
cd ../chaincode/fabcar/javascript
npm install
cd ../../../test-network

You can then issue the following commands to package the JavaScript chaincode from the test-network directory. We will set the environment variables needed to use the peer CLI again in case you closed your terminal.
export PATH=${PWD}/../bin:$PATH
export FABRIC_CFG_PATH=$PWD/../config/
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
peer lifecycle chaincode package fabcar_2.tar.gz --path ../chaincode/fabcar/javascript/ --lang node --label fabcar_2

Run the following commands to operate the peer CLI as the Org1 admin:
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

We can now use the following command to install the new chaincode package on the Org1 peer.
peer lifecycle chaincode install fabcar_2.tar.gz

The new chaincode package will create a new package ID. We can find the new package ID by querying our peer.
peer lifecycle chaincode queryinstalled

The queryinstalled command will return a list of the chaincode that have been installed on your peer.
Installed chaincodes on peer:
Package ID: fabcar_1:69de748301770f6ef64b42aa6bb6cb291df20aa39542c3ef94008615704007f3, Label: fabcar_1
Package ID: fabcar_2:1d559f9fb3dd879601ee17047658c7e0c84eab732dca7c841102f20e42a9e7d4, Label: fabcar_2

You can use the package label to find the package ID of the new chaincode and save it as a new environment variable.
export NEW_CC_PACKAGE_ID=fabcar_2:1d559f9fb3dd879601ee17047658c7e0c84eab732dca7c841102f20e42a9e7d4

Org1 can now approve a new chaincode definition:
peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name fabcar --version 2.0 --package-id $NEW_CC_PACKAGE_ID --sequence 2 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

The new chaincode definition uses the package ID of the JavaScript chaincode package and updates the chaincode version. Because the sequence parameter is used by the Fabric chaincode lifecycle to keep track of chaincode upgrades, Org1 also needs to increment the sequence number from 1 to 2. You can use the peer lifecycle chaincode querycommitted command to find the sequence of the chaincode that was last committed to the channel.
We now need to install the chaincode package and approve the chaincode definition as Org2 in order to upgrade the chaincode. Run the following commands to operate the peer CLI as the Org2 admin:
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

We can now use the following command to install the new chaincode package on the Org2 peer.
peer lifecycle chaincode install fabcar_2.tar.gz

You can now approve the new chaincode definition for Org2.
peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name fabcar --version 2.0 --package-id $NEW_CC_PACKAGE_ID --sequence 2 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Use the peer lifecycle chaincode checkcommitreadiness command to check if the chaincode definition with sequence 2 is ready to be committed to the channel:
peer lifecycle chaincode checkcommitreadiness --channelID mychannel --name fabcar --version 2.0 --sequence 2 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --output json

The chaincode is ready to be upgraded if the command returns the following JSON:
    {
            "Approvals": {
                    "Org1MSP": true,
                    "Org2MSP": true
            }
    }

The chaincode will be upgraded on the channel after the new chaincode definition is committed. Until then, the previous chaincode will continue to run on the peers of both organizations. Org2 can use the following command to upgrade the chaincode:
peer lifecycle chaincode commit -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name fabcar --version 2.0 --sequence 2 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --peerAddresses localhost:7051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses localhost:9051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt

A successful commit transaction will start the new chaincode right away. If the chaincode definition changed the endorsement policy, the new policy would be put in effect.
You can use the docker ps command to verify that the new chaincode has started on your peers:
$docker ps
CONTAINER ID        IMAGE                                                                                                                                                                   COMMAND                  CREATED             STATUS              PORTS                              NAMES
197a4b70a392        dev-peer0.org1.example.com-fabcar_2-1d559f9fb3dd879601ee17047658c7e0c84eab732dca7c841102f20e42a9e7d4-d305a4e8b4f7c0bc9aedc84c4a3439daed03caedfbce6483058250915d64dd23   "docker-entrypoint.s…"   2 minutes ago       Up 2 minutes                                           dev-peer0.org1.example.com-fabcar_2-1d559f9fb3dd879601ee17047658c7e0c84eab732dca7c841102f20e42a9e7d4
b7e4dbfd4ea0        dev-peer0.org2.example.com-fabcar_2-1d559f9fb3dd879601ee17047658c7e0c84eab732dca7c841102f20e42a9e7d4-9de9cd456213232033c0cf8317cbf2d5abef5aee2529be9176fc0e980f0f7190   "docker-entrypoint.s…"   2 minutes ago       Up 2 minutes                                           dev-peer0.org2.example.com-fabcar_2-1d559f9fb3dd879601ee17047658c7e0c84eab732dca7c841102f20e42a9e7d4
8b6e9abaef8d        hyperledger/fabric-peer:latest                                                                                                                                          "peer node start"        About an hour ago   Up About an hour    0.0.0.0:7051->7051/tcp             peer0.org1.example.com
429dae4757ba        hyperledger/fabric-peer:latest                                                                                                                                          "peer node start"        About an hour ago   Up About an hour    7051/tcp, 0.0.0.0:9051->9051/tcp   peer0.org2.example.com
7de5d19400e6        hyperledger/fabric-orderer:latest                                                                                                                                       "orderer"                About an hour ago   Up About an hour    0.0.0.0:7050->7050/tcp             orderer.example.com

If you used the --init-required flag, you need to invoke the Init function before you can use the upgraded chaincode. Because we did not request the execution of Init, we can test our new JavaScript chaincode by creating a new car:
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n fabcar --peerAddresses localhost:7051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses localhost:9051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"function":"createCar","Args":["CAR11","Honda","Accord","Black","Tom"]}'

You can query all the cars on the ledger again to see the new car:
peer chaincode query -C mychannel -n fabcar -c '{"Args":["queryAllCars"]}'

You should see the following result from the JavaScript chaincode:
[{"Key":"CAR0","Record":{"make":"Toyota","model":"Prius","colour":"blue","owner":"Tomoko"}},
{"Key":"CAR1","Record":{"make":"Ford","model":"Mustang","colour":"red","owner":"Brad"}},
{"Key":"CAR11","Record":{"color":"Black","docType":"car","make":"Honda","model":"Accord","owner":"Tom"}},
{"Key":"CAR2","Record":{"make":"Hyundai","model":"Tucson","colour":"green","owner":"Jin Soo"}},
{"Key":"CAR3","Record":{"make":"Volkswagen","model":"Passat","colour":"yellow","owner":"Max"}},
{"Key":"CAR4","Record":{"make":"Tesla","model":"S","colour":"black","owner":"Adriana"}},
{"Key":"CAR5","Record":{"make":"Peugeot","model":"205","colour":"purple","owner":"Michel"}},
{"Key":"CAR6","Record":{"make":"Chery","model":"S22L","colour":"white","owner":"Aarav"}},
{"Key":"CAR7","Record":{"make":"Fiat","model":"Punto","colour":"violet","owner":"Pari"}},
{"Key":"CAR8","Record":{"make":"Tata","model":"Nano","colour":"indigo","owner":"Valeria"}},
{"Key":"CAR9","Record":{"make":"Holden","model":"Barina","colour":"brown","owner":"Shotaro"}}]

Clean up¶
When you are finished using the chaincode, you can also use the following commands to remove the Logspout tool.
docker stop logspout
docker rm logspout

You can then bring down the test network by issuing the following command from the test-network directory:
./network.sh down

Next steps¶
After you write your smart contract and deploy it to a channel, you can use the APIs provided by the Fabric SDKs to invoke the smart contracts from a client application. This allows end users to interact with the assets on the blockchain ledger. To get started with the Fabric SDKs, see the Writing Your first application tutorial.

troubleshooting¶

Chaincode not agreed to by this org¶
Problem: When I try to commit a new chaincode definition to the channel, the peer lifecycle chaincode commit command fails with the following error:
Error: failed to create signed transaction: proposal response was not successful, error code 500, msg failed to invoke backing implementation of 'CommitChaincodeDefinition': chaincode definition not agreed to by this org (Org1MSP)

Solution: You can try to resolve this error by using the peer lifecycle chaincode checkcommitreadiness command to check which channel members have approved the chaincode definition that you are trying to commit. If any organization used a different value for any parameter of the chaincode definition, the commit transaction will fail. The peer lifecycle chaincode checkcommitreadiness will reveal which organizations did not approve the chaincode definition you are trying to commit:
{
    "approvals": {
        "Org1MSP": false,
        "Org2MSP": true
    }
}

Invoke failure¶
Problem: The peer lifecycle chaincode commit transaction is successful, but when I try to invoke the chaincode for the first time, it fails with the following error:
Error: endorsement failure during invoke. response: status:500 message:"make sure the chaincode fabcar has been successfully defined on channel mychannel and try again: chaincode definition for 'fabcar' exists, but chaincode is not installed"

Solution: You may not have set the correct --package-id when you approved your chaincode definition. As a result, the chaincode definition that was committed to the channel was not associated with the chaincode package you installed and the chaincode was not started on your peers. If you are running a docker based network, you can use the docker ps command to check if your chaincode is running:
docker ps
CONTAINER ID        IMAGE                               COMMAND             CREATED             STATUS              PORTS                              NAMES
7fe1ae0a69fa        hyperledger/fabric-orderer:latest   "orderer"           5 minutes ago       Up 4 minutes        0.0.0.0:7050->7050/tcp             orderer.example.com
2b9c684bd07e        hyperledger/fabric-peer:latest      "peer node start"   5 minutes ago       Up 4 minutes        0.0.0.0:7051->7051/tcp             peer0.org1.example.com
39a3e41b2573        hyperledger/fabric-peer:latest      "peer node start"   5 minutes ago       Up 4 minutes        7051/tcp, 0.0.0.0:9051->9051/tcp   peer0.org2.example.com

If you do not see any chaincode containers listed, use the peer lifecycle chaincode approveformyorg command approve a chaincode definition with the correct package ID.

Endorsement policy failure¶
Problem: When I try to commit the chaincode definition to the channel, the transaction fails with the following error:
2020-04-07 20:08:23.306 EDT [chaincodeCmd] ClientWait -> INFO 001 txid [5f569e50ae58efa6261c4ad93180d49ac85ec29a07b58f576405b826a8213aeb] committed with status (ENDORSEMENT_POLICY_FAILURE) at localhost:7051
Error: transaction invalidated with status (ENDORSEMENT_POLICY_FAILURE)

Solution: This error is a result of the commit transaction not gathering enough endorsements to meet the Lifecycle endorsement policy. This problem could be a result of your transaction not targeting a sufficient number of peers to meet the policy. This could also be the result of some of the peer organizations not including the Endorsement: signature policy referenced by the default /Channel/Application/Endorsement policy in their configtx.yaml file:
Readers:
        Type: Signature
        Rule: "OR('Org2MSP.admin', 'Org2MSP.peer', 'Org2MSP.client')"
Writers:
        Type: Signature
        Rule: "OR('Org2MSP.admin', 'Org2MSP.client')"
Admins:
        Type: Signature
        Rule: "OR('Org2MSP.admin')"
Endorsement:
        Type: Signature
        Rule: "OR('Org2MSP.peer')"

When you enable the Fabric chaincode lifecycle, you also need to use the new Fabric 2.0 channel policies in addition to upgrading your channel to the V2_0 capabilitiy. Your channel needs to include the new /Channel/Application/LifecycleEndorsement and /Channel/Application/Endorsement policies:
Policies:
        Readers:
                Type: ImplicitMeta
                Rule: "ANY Readers"
        Writers:
                Type: ImplicitMeta
                Rule: "ANY Writers"
        Admins:
                Type: ImplicitMeta
                Rule: "MAJORITY Admins"
        LifecycleEndorsement:
                Type: ImplicitMeta
                Rule: "MAJORITY Endorsement"
        Endorsement:
                Type: ImplicitMeta
                Rule: "MAJORITY Endorsement"

If you do not include the new channel policies in the channel configuration, you will get the following error when you approve a chaincode definition for your organization:
Error: proposal failed with status: 500 - failed to invoke backing implementation of 'ApproveChaincodeDefinitionForMyOrg': could not set defaults for chaincode definition in channel mychannel: policy '/Channel/Application/Endorsement' must be defined for channel 'mychannel' before chaincode operations can be attempted

Writing Your First Application¶

Note
If you’re not yet familiar with the fundamental architecture of a
Fabric network, you may want to visit the Key Concepts section
prior to continuing.
It is also worth noting that this tutorial serves as an introduction
to Fabric applications and uses simple smart contracts and
applications. For a more in-depth look at Fabric applications and
smart contracts, check out our
Developing Applications section or the
Commercial paper tutorial.

This tutorial provides an introduction to how Fabric applications interact
with deployed blockchain networks. The tutorial uses sample programs built using the
Fabric SDKs – described in detail in the Application topic –
to invoke a smart contract which queries and updates the ledger with the smart
contract API – described in detail in Smart Contract Processing.
We will also use our sample programs and a deployed Certificate Authority to generate
the X.509 certificates that an application needs to interact with a permissioned
blockchain. The sample applications and the smart contract they invoke are
collectively known as FabCar.
We’ll go through three principle steps:

1. Setting up a development environment. Our application needs a network
to interact with, so we’ll deploy a basic network for our smart contracts and
application.

2. Explore a sample smart contract.
We’ll inspect the sample Fabcar smart contract to learn about the transactions within them,
and how they are used by applications to query and update the ledger.
3. Interact with the smart contract with a sample application. Our application will
use the FabCar smart contract to query and update car assets on the ledger.
We’ll get into the code of the apps and the transactions they create,
including querying a car, querying a range of cars, and creating a new car.

After completing this tutorial you should have a basic understanding of how Fabric
applications and smart contracts work together to manage data on the distributed
ledger of a blockchain network.

Before you begin¶
In addition to the standard Prerequisites for Fabric, this tutorial leverages the Hyperledger Fabric SDK for Node.js. See the Node.js SDK README for a up to date list of prerequisites.

If you are using macOS, complete the following steps:

Install Homebrew.
Check the Node SDK prerequisties to find out what level of Node to install.
Run brew install node to download the latest version of node or choose a specific version, for example: brew install node@10 according to what is supported in the prerequisites.
Run npm install.

If you are on Windows,  you can install the windows-build-tools with npm which installs all required compilers and tooling by running the following command:
npm install --global windows-build-tools

If you are on Linux, you need to install Python v2.7, make, and a C/C++ compiler toolchain such as GCC. You can run the following command to install the other tools:
sudo apt install build-essentials

Set up the blockchain network¶
If you’ve already run through Using the Fabric test network tutorial and have a network up
and running, this tutorial will bring down your running network before
bringing up a new one.

Launch the network¶

Note
This tutorial demonstrates the JavaScript versions of the FabCar
smart contract and application, but the fabric-samples repo also
contains Go, Java and TypeScript versions of this sample. To try the
Go, Java or TypeScript versions, change the javascript argument
for ./startFabric.sh below to either go, java or typescript
and follow the instructions written to the terminal.

Navigate to the fabcar subdirectory within your local clone of the
fabric-samples repo.
cd fabric-samples/fabcar

Launch your network using the startFabric.sh shell script.
./startFabric.sh javascript

This command will deploy the Fabric test network with two peers and an ordering
service. Instead of using the cryptogen tool, we will bring up the test network
using Certificate Authorities. We will use one of these CAs to create the certificates
and keys that will be used by our applications in a future step. The startFabric.sh
script will also deploy and initialize the JavaScript version of the FabCar smart
contract on the channel mychannel, and then invoke the smart contract to
put initial data on the ledger.

Install the application¶
From the fabcar directory inside fabric-samples, navigate to the
javascript folder.
cd javascript

This directory contains sample programs that were developed using the Fabric
SDK for Node.js. Run the following command to install the application dependencies.
It will take about a minute to complete:
npm install

This process is installing the key application dependencies defined in
package.json. The most important of which is the fabric-network class;
it enables an application to use identities, wallets, and gateways to connect to
channels, submit transactions, and wait for notifications. This tutorial also
uses the fabric-ca-client class to enroll users with their respective
certificate authorities, generating a valid identity which is then used by
fabric-network class methods.
Once npm install completes, everything is in place to run the application.
Let’s take a look at the sample JavaScript application files we will be using
in this tutorial:
ls

You should see the following:
enrollAdmin.js  node_modules       package.json  registerUser.js
invoke.js       package-lock.json  query.js      wallet

There are files for other program languages, for example in the
fabcar/java directory. You can read these once you’ve used the
JavaScript example – the principles are the same.

Enrolling the admin user¶

Note
The following two sections involve communication with the Certificate
Authority. You may find it useful to stream the CA logs when running
the upcoming programs by opening a new terminal shell and running
docker logs -f ca_org1.

When we created the network, an admin user — literally called admin —
was created as the registrar for the certificate authority (CA). Our first
step is to generate the private key, public key, and X.509 certificate for
admin using the enroll.js program. This process uses a Certificate
Signing Request (CSR) — the private and public key are first generated
locally and the public key is then sent to the CA which returns an encoded
certificate for use by the application. These credentials are then stored
in the wallet, allowing us to act as an administrator for the CA.
Let’s enroll user admin:
node enrollAdmin.js

This command stores the CA administrator’s credentials in the wallet directory.
You can find administrator’s certificate and private key in the wallet/admin.id
file.

Register and enroll an application user¶
Our admin is used to work with the CA. Now that we have the administrator’s
credentials in a wallet, we can create a new application user which will be used
to interact with the blockchain. Run the following command to register and enroll
a new user named appUser:
node registerUser.js

Similar to the admin enrollment, this program uses a CSR to enroll appUser and
store its credentials alongside those of admin in the wallet. We now have
identities for two separate users — admin and appUser — that can be
used by our application.

Querying the ledger¶
Each peer in a blockchain network hosts a copy of the ledger. An application
program can view the most recent data from the ledger using read only invocations of
a smart contract running on your peers called a query.
Here is a simplified representation of how a query works:

The most common queries involve the current values of data in the ledger – its
world state. The world state is
represented as a set of key-value pairs, and applications can query data for a
single key or multiple keys. Moreover, you can use complex queries to read the
data on the ledger when you use CouchDB as your state database and model your data in JSON.
This can be very helpful when looking for all assets that match certain keywords
with particular values; all cars with a particular owner, for example.
First, let’s run our query.js program to return a listing of all the cars on
the ledger. This program uses our second identity – appUser – to access the
ledger:
node query.js

The output should look like this:
Wallet path: ...fabric-samples/fabcar/javascript/wallet
Transaction has been evaluated, result is:
[{"Key":"CAR0","Record":{"color":"blue","docType":"car","make":"Toyota","model":"Prius","owner":"Tomoko"}},
{"Key":"CAR1","Record":{"color":"red","docType":"car","make":"Ford","model":"Mustang","owner":"Brad"}},
{"Key":"CAR2","Record":{"color":"green","docType":"car","make":"Hyundai","model":"Tucson","owner":"Jin Soo"}},
{"Key":"CAR3","Record":{"color":"yellow","docType":"car","make":"Volkswagen","model":"Passat","owner":"Max"}},
{"Key":"CAR4","Record":{"color":"black","docType":"car","make":"Tesla","model":"S","owner":"Adriana"}},
{"Key":"CAR5","Record":{"color":"purple","docType":"car","make":"Peugeot","model":"205","owner":"Michel"}},
{"Key":"CAR6","Record":{"color":"white","docType":"car","make":"Chery","model":"S22L","owner":"Aarav"}},
{"Key":"CAR7","Record":{"color":"violet","docType":"car","make":"Fiat","model":"Punto","owner":"Pari"}},
{"Key":"CAR8","Record":{"color":"indigo","docType":"car","make":"Tata","model":"Nano","owner":"Valeria"}},
{"Key":"CAR9","Record":{"color":"brown","docType":"car","make":"Holden","model":"Barina","owner":"Shotaro"}}]

Let’s take a closer look at how query.js program uses the APIs provided by the
Fabric Node SDK to
interact with our Fabric network. Use an editor (e.g. atom or visual studio) to
open query.js.
The application starts by bringing in scope two key classes from the
fabric-network module; Wallets and Gateway. These classes
will be used to locate the appUser identity in the wallet, and use it to
connect to the network:
const { Gateway, Wallets } = require('fabric-network');

First, the program uses the Wallet class to get our application user from our file system.
const identity = await wallet.get('appUser');

Once the program has an identity, it uses the Gateway class to connect to our network.
const gateway = new Gateway();
await gateway.connect(ccpPath, { wallet, identity: 'appUser', discovery: { enabled: true, asLocalhost: true } });

ccpPath describes the path to the connection profile that our application will use
to connect to our network. The connection profile was loaded from inside the
fabric-samples/test network directory and parsed as a JSON file:
const ccpPath = path.resolve(__dirname, '..', '..', 'test-network','organizations','peerOrganizations','org1.example.com', 'connection-org1.json');

If you’d like to understand more about the structure of a connection profile,
and how it defines the network, check out
the connection profile topic.
A network can be divided into multiple channels, and the next important line of
code connects the application to a particular channel within the network,
mychannel, where our smart contract was deployed:
const network = await gateway.getNetwork('mychannel');

Within this channel, we can access the FabCar smart contract to interact
with the ledger:
const contract = network.getContract('fabcar');

Within FabCar there are many different transactions, and our application
initially uses the queryAllCars transaction to access the ledger world state
data:
const result = await contract.evaluateTransaction('queryAllCars');

The evaluateTransaction method represents one of the simplest interactions
with a smart contract in blockchain network. It simply picks a peer defined in
the connection profile and sends the request to it, where it is evaluated. The
smart contract queries all the cars on the peer’s copy of the ledger and returns
the result to the application. This interaction does not result in an update the
ledger.

The FabCar smart contract¶
Let’s take a look at the transactions within the FabCar smart contract. Open a
new terminal and navigate to the JavaScript version of the FabCar Smart contract
inside the fabric-samples repository:
cd fabric-samples/chaincode/fabcar/javascript/lib

Open the fabcar.js file in a text editor editor.
See how our smart contract is defined using the Contract class:
class FabCar extends Contract {...

Within this class structure, you’ll see that we have the following
transactions defined: initLedger, queryCar, queryAllCars,
createCar, and changeCarOwner. For example:
async queryCar(ctx, carNumber) {...}
async queryAllCars(ctx) {...}

Let’s take a closer look at the queryAllCars transaction to see how it
interacts with the ledger.
async queryAllCars(ctx) {

  const startKey = 'CAR0';
  const endKey = 'CAR999';

  const iterator = await ctx.stub.getStateByRange(startKey, endKey);

This code defines the range of cars that queryAllCars will retrieve from the
ledger. Every car between CAR0 and CAR999 – 1,000 cars in all, assuming
every key has been tagged properly – will be returned by the query. The
remainder of the code iterates through the query results and packages them into
JSON for the application.
Below is a representation of how an application would call different
transactions in a smart contract. Each transaction uses a broad set of APIs such
as getStateByRange to interact with the ledger. You can read more about
these APIs in detail.

We can see our queryAllCars transaction, and another called createCar.
We will use this later in the tutorial to update the ledger, and add a new block
to the blockchain.
But first, go back to the query program and change the
evaluateTransaction request to query CAR4. The query program should
now look like this:
const result = await contract.evaluateTransaction('queryCar', 'CAR4');

Save the program and navigate back to your fabcar/javascript directory.
Now run the query program again:
node query.js

You should see the following:
Wallet path: ...fabric-samples/fabcar/javascript/wallet
Transaction has been evaluated, result is:
{"color":"black","docType":"car","make":"Tesla","model":"S","owner":"Adriana"}

If you go back and look at the result from when the transaction was
queryAllCars, you can see that CAR4 was Adriana’s black Tesla model S,
which is the result that was returned here.
We can use the queryCar transaction to query against any car, using its
key (e.g. CAR0) and get whatever make, model, color, and owner correspond to
that car.
Great. At this point you should be comfortable with the basic query transactions
in the smart contract and the handful of parameters in the query program.
Time to update the ledger…

Updating the ledger¶
Now that we’ve done a few ledger queries and added a bit of code, we’re ready to
update the ledger. There are a lot of potential updates we could make, but
let’s start by creating a new car.
From an application perspective, updating the ledger is simple. An application
submits a transaction to the blockchain network, and when it has been
validated and committed, the application receives a notification that
the transaction has been successful. Under the covers this involves the process
of consensus whereby the different components of the blockchain network work
together to ensure that every proposed update to the ledger is valid and
performed in an agreed and consistent order.

Above, you can see the major components that make this process work. As well as
the multiple peers which each host a copy of the ledger, and optionally a copy
of the smart contract, the network also contains an ordering service. The
ordering service coordinates transactions for a network; it creates blocks
containing transactions in a well-defined sequence originating from all the
different applications connected to the network.
Our first update to the ledger will create a new car. We have a separate program
called invoke.js that we will use to make updates to the ledger. Just as with
queries, use an editor to open the program and navigate to the code block where
we construct our transaction and submit it to the network:
await contract.submitTransaction('createCar', 'CAR12', 'Honda', 'Accord', 'Black', 'Tom');

See how the applications calls the smart contract transaction createCar to
create a black Honda Accord with an owner named Tom. We use CAR12 as the
identifying key here, just to show that we don’t need to use sequential keys.
Save it and run the program:
node invoke.js

If the invoke is successful, you will see output like this:
Wallet path: ...fabric-samples/fabcar/javascript/wallet
Transaction has been submitted

Notice how the invoke application interacted with the blockchain network
using the submitTransaction API, rather than evaluateTransaction.
await contract.submitTransaction('createCar', 'CAR12', 'Honda', 'Accord', 'Black', 'Tom');

submitTransaction is much more sophisticated than evaluateTransaction.
Rather than interacting with a single peer, the SDK will send the
submitTransaction proposal to every required organization’s peer in the
blockchain network. Each of these peers will execute the requested smart
contract using this proposal, to generate a transaction response which it signs
and returns to the SDK. The SDK collects all the signed transaction responses
into a single transaction, which it then sends to the orderer. The orderer
collects and sequences transactions from every application into a block of
transactions. It then distributes these blocks to every peer in the network,
where every transaction is validated and committed. Finally, the SDK is
notified, allowing it to return control to the application.

Note
submitTransaction also includes a listener that checks to make
sure the transaction has been validated and committed to the ledger.
Applications should either utilize a commit listener, or
leverage an API like submitTransaction that does this for you.
Without doing this, your transaction may not have been successfully
ordered, validated, and committed to the ledger.

submitTransaction does all this for the application! The process by which
the application, smart contract, peers and ordering service work together to
keep the ledger consistent across the network is called consensus, and it is
explained in detail in this section.
To see that this transaction has been written to the ledger, go back to
query.js and change the argument from CAR4 to CAR12.
In other words, change this:
const result = await contract.evaluateTransaction('queryCar', 'CAR4');

To this:
const result = await contract.evaluateTransaction('queryCar', 'CAR12');

Save once again, then query:
node query.js

Which should return this:
Wallet path: ...fabric-samples/fabcar/javascript/wallet
Transaction has been evaluated, result is:
{"color":"Black","docType":"car","make":"Honda","model":"Accord","owner":"Tom"}

Congratulations. You’ve created a car and verified that its recorded on the
ledger!
So now that we’ve done that, let’s say that Tom is feeling generous and he
wants to give his Honda Accord to someone named Dave.
To do this, go back to invoke.js and change the smart contract transaction
from createCar to changeCarOwner with a corresponding change in input
arguments:
await contract.submitTransaction('changeCarOwner', 'CAR12', 'Dave');

The first argument — CAR12 — identifies the car that will be changing
owners. The second argument — Dave — defines the new owner of the car.
Save and execute the program again:
node invoke.js

Now let’s query the ledger again and ensure that Dave is now associated with the
CAR12 key:
node query.js

It should return this result:
Wallet path: ...fabric-samples/fabcar/javascript/wallet
Transaction has been evaluated, result is:
{"color":"Black","docType":"car","make":"Honda","model":"Accord","owner":"Dave"}

The ownership of CAR12 has been changed from Tom to Dave.

Note
In a real world application the smart contract would likely have some
access control logic. For example, only certain authorized users may
create new cars, and only the car owner may transfer the car to
somebody else.

Clean up¶
When you are finished using the FabCar sample, you can bring down the test
network using networkDown.sh script.
./networkDown.sh

This command will bring down the CAs, peers, and ordering node of the network
that we created. It will also remove the admin and appUser crypto material stored
in the wallet directory. Note that all of the data on the ledger will be lost.
If you want to go through the tutorial again, you will start from a clean initial state.

Summary¶
Now that we’ve done a few queries and a few updates, you should have a pretty
good sense of how applications interact with a blockchain network using a smart
contract to query or update the ledger. You’ve seen the basics of the roles
smart contracts, APIs, and the SDK play in queries and updates and you should
have a feel for how different kinds of applications could be used to perform
other business tasks and operations.

Additional resources¶
As we said in the introduction, we have a whole section on
Developing Applications that includes in-depth information on
smart contracts, process and data design, a tutorial using a more in-depth
Commercial Paper tutorial and a large
amount of other material relating to the development of applications.

Commercial paper tutorial¶
Audience: Architects, application and smart contract developers,
administrators
This tutorial will show you how to install and use a commercial paper sample
application and smart contract. It is a task-oriented topic, so it emphasizes
procedures above concepts. When you’d like to understand the concepts in more
detail, you can read the
Developing Applications topic.
 In this tutorial
two organizations, MagnetoCorp and DigiBank, trade commercial paper with each
other using PaperNet, a Hyperledger Fabric blockchain network.
Once you’ve set up the test network, you’ll act as Isabella, an employee of
MagnetoCorp, who will issue a commercial paper on its behalf. You’ll then switch
roles to take the role of Balaji, an employee of DigiBank, who will buy this
commercial paper, hold it for a period of time, and then redeem it with
MagnetoCorp for a small profit.
You’ll act as an developer, end user, and administrator, each in different
organizations, performing the following steps designed to help you understand
what it’s like to collaborate as two different organizations working
independently, but according to mutually agreed rules in a Hyperledger Fabric
network.

Set up machine and download samples
Create the network
Examine the commercial paper smart contract
Deploy the smart contract to the channel
by approving the chaincode definition as MagnetoCorp and Digibank.
Understand the structure of a MagnetoCorp application,
including its dependencies
Configure and use a wallet and identities
Run a MagnetoCorp application to issue a commercial paper
Understand how DigiBank uses the smart contract in their applications
As Digibank, run applications that
buy and redeem commercial paper

This tutorial has been tested on MacOS and Ubuntu, and should work on other
Linux distributions. A Windows version is under development.

Prerequisites¶
Before you start, you must install some prerequisite technology required by the
tutorial. We’ve kept these to a minimum so that you can get going quickly.
You must have the following technologies installed:

Node
The Node.js SDK README contains the up to date list of prerequisites.

You will find it helpful to install the following technologies:

A source code editor, such as
Visual Studio Code version 1.28, or
higher. VS Code will help you develop and test your application and smart
contract. Install VS Code here.
Many excellent code editors are available including
Atom, Sublime Text and
Brackets.

You may find it helpful to install the following technologies as you become
more experienced with application and smart contract development. There’s no
requirement to install these when you first run the tutorial:

Node Version Manager. NVM helps you
easily switch between different versions of node – it can be really helpful
if you’re working on multiple projects at the same time. Install NVM
here.

Download samples¶
The commercial paper tutorial is one of the samples in the fabric-samples
directory. Before you begin this tutorial, ensure that you have followed the
instructions to install the Fabric Prerequisites and
Download the Samples, Binaries and Docker Images.
When you are finished, you will have cloned the fabric-samples repository that
contains the tutorial scripts, smart contract, and application files.
 Download the
fabric-samples GitHub repository to your local machine.
After downloading, feel free to examine the directory structure of fabric-samples:
$ cd fabric-samples
$ ls

CODEOWNERS            basic-network             first-network
CODE_OF_CONDUCT.md    chaincode                 high-throughput
CONTRIBUTING.md       chaincode-docker-devmode  interest_rate_swaps
Jenkinsfile           ci                        off_chain_data
LICENSE               ci.properties             scripts
MAINTAINERS.md        commercial-paper          test-network
README.md             docs
SECURITY.md           fabcar

Notice the commercial-paper directory – that’s where our sample is located!
You’ve now completed the first stage of the tutorial! As you proceed, you’ll
open multiple command windows for different users and components. For example:

To show peer, orderer and CA log output from your network.
To approve the chaincode as an administrator from MagnetoCorp and as an
administrator from DigiBank.
To run applications on behalf of Isabella and Balaji, who will use the smart
contract to trade commercial paper with each other.

We’ll make it clear when you should run a command from particular command
window; for example:
(isabella)$ ls

indicates that you should run the ls command from Isabella’s window.

Create the network¶
This tutorial will deploy a smart contract using the Fabric test network.
The test network consists of two peer organizations and an ordering organization.
The two peer organizations operate one peer each, while the ordering organization
operates a single node raft ordering service. We will also use the test network
to create a single channel named mychannel that both peer organizations will
be members of.

The Fabric test network is comprised of two peer organizations, Org1 and Org2,
each with one peer and its ledger database, an ordering node. Each of these
components runs as a Docker container.
The two peers, the peer ledgers, the
orderer and the CA each run in the their own Docker container. In production
environments, organizations typically use existing CAs that are shared with
other systems; they’re not dedicated to the Fabric network.
The two organizations of the test network allow us to interact with a blockchain
ledger as two organizations that operate separate peers. In this tutorial,
we will operate Org1 of the test network as DigiBank and Org2 as MagnetoCorp.
You can start the test network and create the channel with a script provided in
the commercial paper directory. Change to the commercial-paper directory in
the fabric-samples:
cd fabric-samples/commercial-paper

Then use the script to start the test network:
./network-starter.sh

If the command is successful, you will see the test network being created in your
logs. You can use the docker ps command to see the Fabric nodes running on your
local machine:
$ docker ps

CONTAINER ID        IMAGE                               COMMAND                  CREATED             STATUS              PORTS                                        NAMES
321cc489b10f        hyperledger/fabric-peer:latest      "peer node start"        2 minutes ago       Up 2 minutes        0.0.0.0:7051->7051/tcp                       peer0.org1.example.com
ad668671f95f        hyperledger/fabric-peer:latest      "peer node start"        2 minutes ago       Up 2 minutes        7051/tcp, 0.0.0.0:9051->9051/tcp             peer0.org2.example.com
caadbe4d8592        hyperledger/fabric-couchdb          "tini -- /docker-ent…"   2 minutes ago       Up 2 minutes        4369/tcp, 9100/tcp, 0.0.0.0:7984->5984/tcp   couchdb1
ebabe52903b8        hyperledger/fabric-couchdb          "tini -- /docker-ent…"   2 minutes ago       Up 2 minutes        4369/tcp, 9100/tcp, 0.0.0.0:5984->5984/tcp   couchdb0
7c72711c6e18        hyperledger/fabric-orderer:latest   "orderer"                2 minutes ago       Up 2 minutes        0.0.0.0:7050->7050/tcp                       orderer.example.com

See if you can map these containers to the nodes of the test network (you may
need to horizontally scroll to locate the information):

The Org1 peer, peer0.org1.example.com, is running in container 321cc489b10f
The Org2 peer, peer0.org2.example.com, is running in container ad668671f95f
The CouchDB database for the Org1 peer, couchdb0, is running in container ebabe52903b8
The CouchDB database for the Org2 peer, couchdb1, is running in container caadbe4d8592
The ordering node orderer.example.com is running in container 7c72711c6e18

These containers all form a Docker network
called net_test. You can view the network with the docker network command:
$ docker network inspect net_test

    {
          "Name": "net_test",
          "Id": "b77b99d29e37677fac48b7ecd78383bdebf09ebdd6b00e87e3d9444252b1ce31",
          "Created": "2020-01-30T23:04:39.6157465Z",
          "Containers": {
              "321cc489b10ff46554d0b215da307d38daf35b68bbea635ae0ae3176c3ae0945": {
                  "Name": "peer0.org1.example.com",
                  "IPv4Address": "192.168.224.5/20",
              },
              "7c72711c6e18caf7bff4cf78c27efc9ef3b2359a749c926c8aba1beacfdb0211": {
                  "Name": "orderer.example.com",
                  "IPv4Address": "192.168.224.4/20",
              },
              "ad668671f95f351f0119320198e1d1e19ebbb0d75766c6c8b9bb7bd36ba506af": {
                  "Name": "peer0.org2.example.com",
                  "IPv4Address": "192.168.224.6/20",
              },
              "caadbe4d8592aa558fe14d07a424a9e04365620ede1143b6ce5902ce038c0851": {
                  "Name": "couchdb1",
                  "IPv4Address": "192.168.224.2/20",
              },
              "ebabe52903b8597d016dbc0d0ca4373ef75162d3400efbe6416975abafd08a8f": {
                  "Name": "couchdb0",
                  "IPv4Address": "192.168.224.3/20",
              }
          },
          "Labels": {}
      }
  ]

See how the five containers use different IP addresses, while being part of a
single Docker network. (We’ve abbreviated the output for clarity.)
Because we are operating the test network as DigiBank and MagnetoCorp,
peer0.org1.example.com will belong to the DigiBank organization while
peer0.org2.example.com will be operated by MagnetoCorp. Now that the test
network is up and running, we can refer our network as PaperNet from this point
forward.
To recap: you’ve downloaded the Hyperledger Fabric samples repository from
GitHub and you’ve got the test network running on your local machine. Let’s now
start to play the role of MagnetoCorp, who wish to trade commercial paper.

Monitor the network as MagnetoCorp¶
The commercial paper tutorial allows you to act as two organizations by
providing two separate folders for DigiBank and MagnetoCorp. The two folders
contain the smart contracts and application files for each organization. Because
the two organizations have different roles in the trading of the commercial paper,
the application files are different for each organization. Open a new window in
the fabric-samples repository and use the following command to change into
the MagnetoCorp directory:
cd commercial-paper/organization/magnetocorp

The first thing we are going to do as MagnetoCorp is monitor the components
of PaperNet. An administrator can view the aggregated output from a set
of Docker containers using the logspout tool.
The tool collects the different output streams into one place, making it easy
to see what’s happening from a single window. This can be really helpful for
administrators when installing smart contracts or for developers when invoking
smart contracts, for example.
In the MagnetoCorp directory, run the following command to run the
monitordocker.sh  script and start the logspout tool for the containers
associated with PaperNet running on net_test:
(magnetocorp admin)$ ./configuration/cli/monitordocker.sh net_test
...
latest: Pulling from gliderlabs/logspout
4fe2ade4980c: Pull complete
decca452f519: Pull complete
(...)
Starting monitoring on all containers on the network net_test
b7f3586e5d0233de5a454df369b8eadab0613886fc9877529587345fc01a3582

Note that you can pass a port number to the above command if the default port in monitordocker.sh is already in use.
(magnetocorp admin)$ ./monitordocker.sh net_test <port_number>

This window will now show output from the Docker containers for the remainder of the
tutorial, so go ahead and open another command window. The next thing we will do is
examine the smart contract that MagnetoCorp will use to issue to the commercial
paper.

Examine the commercial paper smart contract¶
issue, buy and redeem are the three functions at the heart of the commercial
paper smart contract. It is used by applications to submit transactions which
correspondingly issue, buy and redeem commercial paper on the ledger. Our next
task is to examine this smart contract.
Open a new terminal in the fabric-samples directory and change into the
MagnetoCorp folder to act as the MagnetoCorp developer.
cd commercial-paper/organization/magnetocorp

You can then view the smart contract in the contract directory using your chosen
editor (VS Code in this tutorial):
(magnetocorp developer)$ code contract

In the lib directory of the folder, you’ll see papercontract.js file – this
contains the commercial paper smart contract!
 An
example code editor displaying the commercial paper smart contract in papercontract.js
papercontract.js is a JavaScript program designed to run in the Node.js
environment. Note the following key program lines:

const { Contract, Context } = require('fabric-contract-api');
This statement brings into scope two key Hyperledger Fabric classes that will
be used extensively by the smart contract  – Contract and Context. You
can learn more about these classes in the
fabric-shim JSDOCS.

class CommercialPaperContract extends Contract {
This defines the smart contract class CommercialPaperContract based on the
built-in Fabric Contract class.  The methods which implement the key
transactions to issue, buy and redeem commercial paper are defined
within this class.

async issue(ctx, issuer, paperNumber, issueDateTime, maturityDateTime...) {
This method defines the commercial paper issue transaction for PaperNet. The
parameters that are passed to this method will be used to create the new
commercial paper.
Locate and examine the buy and redeem transactions within the smart
contract.

let paper = CommercialPaper.createInstance(issuer, paperNumber, issueDateTime...);
Within the issue transaction, this statement creates a new commercial paper
in memory using the CommercialPaper class with the supplied transaction
inputs. Examine the buy and redeem transactions to see how they similarly
use this class.

await ctx.paperList.addPaper(paper);
This statement adds the new commercial paper to the ledger using
ctx.paperList, an instance of a PaperList class that was created when the
smart contract context CommercialPaperContext was initialized. Again,
examine the buy and redeem methods to see how they use this class.

return paper;
This statement returns a binary buffer as response from the issue
transaction for processing by the caller of the smart contract.

Feel free to examine other files in the contract directory to understand how
the smart contract works, and read in detail how papercontract.js is
designed in the smart contract topic.

Deploy the smart contract to the channel¶
Before papercontract can be invoked by applications, it must be installed onto
the appropriate peer nodes of the test network and then defined on the channel
using the Fabric chaincode lifecycle. The Fabric chaincode
lifecycle allows multiple organizations to agree to the parameters of a chaincode
before the chainocde is deployed to a channel. As a result, we need to install
and approve the chaincode as administrators of both MagnetoCorp and DigiBank.
  A MagnetoCorp
administrator installs a copy of the papercontract onto a MagnetoCorp peer.
Smart contracts are the focus of application development, and are contained
within a Hyperledger Fabric artifact called chaincode. One
or more smart contracts can be defined within a single chaincode, and installing
a chaincode will allow them to be consumed by the different organizations in
PaperNet. It means that only administrators need to worry about chaincode;
everyone else can think in terms of smart contracts.

Install and approve the smart contract as MagnetoCorp¶
We will first install and approve the smart contract as the MagnetoCorp admin. Make
sure that you are operating from the magnetocorp folder, or navigate back to that
folder using the following command:
cd commercial-paper/organization/magnetocorp

A MagnetoCorp administrator can interact with PaperNet using the peer CLI. However,
the administrator needs to set certain environment variables in their command
window to use the correct set of peer binaries, send commands to the address
of the MagnetoCorp peer, and sign requests with the correct crypto material.
You can use a script provided by the sample to set the environment variables in
your command window. Run the following command in the magnetocorp directory:
source magnetocorp.sh

You will see the full list of environment variables printed in your window. We
can now use this command window to interact with PaperNet as the MagnetoCorp
administrator.
The first step is to install the papercontract smart contract. The smart
contract can be packaged into a chaincode using the
peer lifecycle chaincode package command. In the MagnetoCorp administrator’s
command window, run the following command to create the chaincode package:
(magnetocorp admin)$ peer lifecycle chaincode package cp.tar.gz --lang node --path ./contract --label cp_0

The MagnetoCorp admin can now install the chaincode on the MagnetoCorp peer using
the peer lifecycle chaincode install command:
(magnetocorp admin)$ peer lifecycle chaincode install cp.tar.gz

If the command is successful, you will see messages similar to the following
printed in your terminal:
2020-01-30 18:32:33.762 EST [cli.lifecycle.chaincode] submitInstallProposal -> INFO 001 Installed remotely: response:<status:200 payload:"\nEcp_0:ffda93e26b183e231b7e9d5051e1ee7ca47fbf24f00a8376ec54120b1a2a335c\022\004cp_0" >
2020-01-30 18:32:33.762 EST [cli.lifecycle.chaincode] submitInstallProposal -> INFO 002 Chaincode code package identifier: cp_0:ffda93e26b183e231b7e9d5051e1ee7ca47fbf24f00a8376ec54120b1a2a335c

Because the MagnetoCorp admin has set CORE_PEER_ADDRESS=localhost:9051 to
target its commands to peer0.org2.example.com, the INFO 001 Installed remotely...
indicates that papercontract has been successfully installed on this peer.
After we install the smart contract, we need to approve the chaincode definition
for papercontract as MagnetoCorp. The first step is to find the packageID of
the chaincode we installed on our peer. We can query the packageID using the
peer lifecycle chaincode queryinstalled command:
peer lifecycle chaincode queryinstalled

The command will return the same package identifier as the install command. You
should see output similar to the following:
Installed chaincodes on peer:
Package ID: cp_0:ffda93e26b183e231b7e9d5051e1ee7ca47fbf24f00a8376ec54120b1a2a335c, Label: cp_0

We will need the package ID in the next step, so we will save it as an environment
variable. The package ID may not be the same for all users, so you need to
complete this step using the package ID returned from your command window.
export PACKAGE_ID=cp_0:ffda93e26b183e231b7e9d5051e1ee7ca47fbf24f00a8376ec54120b1a2a335c

The admin can now approve the chaincode definition for MagnetoCorp using the
peer lifecycle chaincode approveformyorg command:
(magnetocorp admin)$ peer lifecycle chaincode approveformyorg --orderer localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name papercontract -v 0 --package-id $PACKAGE_ID --sequence 1 --tls --cafile $ORDERER_CA

One of the most important chaincode parameters that channel members need to
agree to using the chaincode definition is the chaincode endorsement policy.
The endorsement policy describes the set of organizations that must endorse
(execute and sign) a transaction before it can be determined to be valid. By
approving the papercontract chaincode without the --policy flag, the
MagnetoCorp admin agrees to using the default endorsement policy, which requires a
majority of organizations on the channel to endorse a transaction. All transactions,
whether valid or invalid, will be recorded on the ledger blockchain,
but only valid transactions will update the world state.

Install and approve the smart contract as DigiBank¶
By default, the Fabric Chaincode lifecycle requires a majority of organizations
on the channel to successfully commit the chaincode definition to the channel.
This implies that we need to approve the papernet chaincode as both MagnetoCorp
and DigiBank to get the required majority of 2 out of 2. Open a new terminal
window in the fabric-samples and navigate to the older that contains the
DigiBank smart contract and application files:
(digibank admin)$ cd commercial-paper/organization/digibank/

Use the script in the DigiBank folder to set the environment variables that will
allow you to act as the DigiBank admin:
source digibank.sh

We can now install and approve papercontract as the DigiBank. Run the following
command to package the chaincode:
(digibank admin)$ peer lifecycle chaincode package cp.tar.gz --lang node --path ./contract --label cp_0

The admin can now install the chaincode on the DigiBank peer:
(digibank admin)$ peer lifecycle chaincode install cp.tar.gz

We then need to query and save the packageID of the chaincode that was just
installed:
(digibank admin)$ peer lifecycle chaincode queryinstalled

Save the package ID as an environment variable. Complete this step using the
package ID returned from your console.
export PACKAGE_ID=cp_0:ffda93e26b183e231b7e9d5051e1ee7ca47fbf24f00a8376ec54120b1a2a335c

The Digibank admin can now approve the chaincode definition of papercontract:
(digibank admin)$ peer lifecycle chaincode approveformyorg --orderer localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name papercontract -v 0 --package-id $PACKAGE_ID --sequence 1 --tls --cafile $ORDERER_CA

Commit the chaincode definition to the channel¶
Now that DigiBank and MagnetoCorp have both approved the papernet chaincode, we
have the majority we need (2 out of 2) to commit the chaincode definition to the
channel. Once the chaincode is successfully defined on the channel, the
CommercialPaper smart contract inside the papercontract chaincode can be
invoked by client applications on the channel. Since either organization can
commit the chaincode to the channel, we will continue operating as the
DigiBank admin:
  After the DigiBank administrator commits the definition of the papercontract chaincode to the channel, a new Docker chaincode container will be created to run papercontract on both PaperNet peers
The DigiBank administrator uses the peer lifecycle chaincode commit command
to commit the chaincode definition of papercontract to mychannel:
(digibank admin)$ peer lifecycle chaincode commit -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --peerAddresses localhost:7051 --tlsRootCertFiles ${PEER0_ORG1_CA} --peerAddresses localhost:9051 --tlsRootCertFiles ${PEER0_ORG2_CA} --channelID mychannel --name papercontract -v 0 --sequence 1 --tls --cafile $ORDERER_CA --waitForEvent

The chaincode container will start after the chaincode definition has been
committed to the channel. You can use the docker ps command to see
papercontract container starting on both peers.
(digibank admin)$ docker ps

CONTAINER ID        IMAGE                                                                                                                                                               COMMAND                  CREATED             STATUS              PORTS                                        NAMES
d4ba9dc9c55f        dev-peer0.org1.example.com-cp_0-ebef35e7f1f25eea1dcc6fcad5019477cd7f434c6a5dcaf4e81744e282903535-05cf67c20543ee1c24cf7dfe74abce99785374db15b3bc1de2da372700c25608   "docker-entrypoint.s…"   30 seconds ago      Up 28 seconds                                                    dev-peer0.org1.example.com-cp_0-ebef35e7f1f25eea1dcc6fcad5019477cd7f434c6a5dcaf4e81744e282903535
a944c0f8b6d6        dev-peer0.org2.example.com-cp_0-1487670371e56d107b5e980ce7f66172c89251ab21d484c7f988c02912ddeaec-1a147b6fd2a8bd2ae12db824fad8d08a811c30cc70bc5b6bc49a2cbebc2e71ee   "docker-entrypoint.s…"   31 seconds ago      Up 28 seconds                                                    dev-peer0.org2.example.com-cp_0-1487670371e56d107b5e980ce7f66172c89251ab21d484c7f988c02912ddeaec

Notice that the containers are named to indicate the peer that started it, and
the fact that it’s running papercontract version 0.
Now that we have deployed the papercontract chaincode to the channel, we can
use the MagnetoCorp application to issue the commercial paper. Let’s take a
moment to examine the application structure.

Application structure¶
The smart contract contained in papercontract is called by MagnetoCorp’s
application issue.js. Isabella uses this application to submit a transaction
to the ledger which issues commercial paper 00001. Let’s quickly examine how
the issue application works.
 A gateway
allows an application to focus on transaction generation, submission and
response. It coordinates transaction proposal, ordering and notification
processing between the different network components.
Because the issue application submits transactions on behalf of Isabella, it
starts by retrieving Isabella’s X.509 certificate from her
wallet, which might be stored on the local file
system or a Hardware Security Module
HSM. The issue
application is then able to utilize the gateway to submit transactions on the
channel. The Hyperledger Fabric SDK provides a
gateway abstraction so that applications can
focus on application logic while delegating network interaction to the
gateway. Gateways and wallets make it straightforward to write Hyperledger
Fabric applications.
So let’s examine the issue application that Isabella is going to use. Open a
separate terminal window for her, and in fabric-samples locate the MagnetoCorp
/application folder:
(isabella)$ cd commercial-paper/organization/magnetocorp/application/
(isabella)$ ls

addToWallet.js      issue.js        package.json

addToWallet.js is the program that Isabella is going to use to load her
identity into her wallet, and issue.js will use this identity to create
commercial paper 00001 on behalf of MagnetoCorp by invoking papercontract.
Change to the directory that contains MagnetoCorp’s copy of the application
issue.js, and use your code editor to examine it:
(isabella)$ cd commercial-paper/organization/magnetocorp/application
(isabella)$ code issue.js

Examine this directory; it contains the issue application and all its
dependencies.
 A code editor
displaying the contents of the commercial paper application directory.
Note the following key program lines in issue.js:

const { Wallets, Gateway } = require('fabric-network');
This statement brings two key Hyperledger Fabric SDK classes into scope –
Wallet and Gateway.

const wallet = await Wallets.newFileSystemWallet('../identity/user/isabella/wallet');
This statement identifies that the application will use isabella wallet when
it connects to the blockchain network channel. Because Isabella’s X.509 certificate
is in the local file system, the application creates a new FileSystemWallet. The
application will select a particular identity within isabella wallet.

await gateway.connect(connectionProfile, connectionOptions);
This line of code connects to the network using the gateway identified by
connectionProfile, using the identity referred to in ConnectionOptions.
See how ../gateway/networkConnection.yaml and User1@org1.example.com are
used for these values respectively.

const network = await gateway.getNetwork('mychannel');
This connects the application to the network channel mychannel, where the
papercontract was previously instantiated.

const contract = await network.getContract('papercontract');
This statement gives the application access to the papercontract chaincode.
Once an application has issued getContract, it can submit to any smart contract
transaction implemented within the chaincode.

const issueResponse = await contract.submitTransaction('issue', 'MagnetoCorp', '00001', ...);
This line of code submits the a transaction to the network using the issue
transaction defined within the smart contract. MagnetoCorp, 00001… are
the values to be used by the issue transaction to create a new commercial
paper.

let paper = CommercialPaper.fromBuffer(issueResponse);
This statement processes the response from the issue transaction. The
response needs to deserialized from a buffer into paper, a CommercialPaper
object which can interpreted correctly by the application.

Feel free to examine other files in the /application directory to understand
how issue.js works, and read in detail how it is implemented in the
application topic.

Application dependencies¶
The issue.js application is written in JavaScript and designed to run in the
Node.js environment that acts as a client to the PaperNet network.
As is common practice, MagnetoCorp’s application is built on many
external node packages — to improve quality and speed of development. Consider
how issue.js includes the js-yaml
package to process the YAML gateway
connection profile, or the fabric-network
package to access the Gateway
and Wallet classes:
const yaml = require('js-yaml');
const { Wallets, Gateway } = require('fabric-network');

These packages have to be downloaded from npm to the
local file system using the npm install command. By convention, packages must
be installed into an application-relative /node_modules directory for use at
runtime.
Examine the package.json file to see how issue.js identifies the packages to
download and their exact versions:
  "dependencies": {
    "fabric-network": "~1.4.0",
    "fabric-client": "~1.4.0",
    "js-yaml": "^3.12.0"
  },

npm versioning is very powerful; you can read more about it
here.
Let’s install these packages with the npm install command – this may take up
to a minute to complete:
(isabella)$ cd commercial-paper/organization/magnetocorp/application/
(isabella)$ npm install

(           ) extract:lodash: sill extract ansi-styles@3.2.1
(...)
added 738 packages in 46.701s

See how this command has updated the directory:
(isabella)$ ls

addToWallet.js      node_modules            package.json
issue.js            package-lock.json

Examine the node_modules directory to see the packages that have been
installed. There are lots, because js-yaml and fabric-network are themselves
built on other npm packages! Helpfully, the package-lock.json
file identifies the exact
versions installed, which can prove invaluable if you want to exactly reproduce
environments; to test, diagnose problems or deliver proven applications for
example.

Wallet¶
Isabella is almost ready to run issue.js to issue MagnetoCorp commercial paper
00001; there’s just one remaining task to perform! As issue.js acts on
behalf of Isabella, and therefore MagnetoCorp, it will use identity from her
wallet that reflects these facts. We now need to
perform this one-time activity of adding appropriate X.509 credentials to her
wallet.
In Isabella’s terminal window, run the addToWallet.js program to add identity
information to her wallet:
(isabella)$ node addToWallet.js

done

addToWallet.js is a simple file-copying program which you can examine at your
leisure. It moves an identity from the test network sample to Isabella’s
wallet. Let’s focus on the result of this program — the contents of
the wallet which will be used to submit transactions to PaperNet:
(isabella)$ ls ../identity/user/isabella/wallet/

isabella.id

Isabella can store multiple identities in her wallet, though in our example, she
only uses one. The wallet folder contains an isabella.id file that provides
the information that Isabella needs to connect to the network. Other identities
used by Isabella would have their own file. You can open this file to see the
identity information that issue.js will use on behalf of Isabella inside a JSON
file. The output has been formatted for clarity.
(isabella)$  cat ../identity/user/isabella/wallet/*

{
  "credentials": {
    "certificate": "-----BEGIN CERTIFICATE-----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\nXf0CSiTXIWOJIsswN4Jp+ZxkJfFVmXndqKqz+VM=\n-----END CERTIFICATE-----\n",
    "privateKey": "-----BEGIN PRIVATE KEY-----\nMIGHAgEAMBMGByqGSM49AgEGCCqGSM49AwEHBG0wawIBAQQggs55vQg2oXi8gNi8\nNidE8Fy5zenohArDq3FGJD8cKU2hRANCAAT4TnTblx0kgfqX+NN7F76Me33VTq3K\n2NUWZRreoJzq6bAuvdDR+iFvVPKXbdORnVvRSATcXsYlt20yU7n/53db\n-----END PRIVATE KEY-----\n"
  },
  "mspId": "Org2MSP",
  "type": "X.509",
  "version": 1
}

In the file you can notice the following:

a "privateKey": used to sign transactions on Isabella’s behalf, but not
distributed outside of her immediate control.
a "certificate": which contains Isabella’s public key and other X.509
attributes added by the Certificate Authority at certificate creation. This
certificate is distributed to the network so that different actors at different
times can cryptographically verify information created by Isabella’s private key.

You can Learn more about certificates here. In practice, the
certificate file also contains some Fabric-specific metadata such as
Isabella’s organization and role – read more in the wallet topic.

Issue application¶
Isabella can now use issue.js to submit a transaction that will issue
MagnetoCorp commercial paper 00001:
(isabella)$ node issue.js

Connect to Fabric gateway.
Use network channel: mychannel.
Use org.papernet.commercialpaper smart contract.
Submit commercial paper issue transaction.
Process issue transaction response.{"class":"org.papernet.commercialpaper","key":"\"MagnetoCorp\":\"00001\"","currentState":1,"issuer":"MagnetoCorp","paperNumber":"00001","issueDateTime":"2020-05-31","maturityDateTime":"2020-11-30","faceValue":"5000000","owner":"MagnetoCorp"}
MagnetoCorp commercial paper : 00001 successfully issued for value 5000000
Transaction complete.
Disconnect from Fabric gateway.
Issue program complete.

The node command initializes a Node.js environment, and runs issue.js. We
can see from the program output that MagnetoCorp commercial paper 00001 was
issued with a face value of 5M USD.
As you’ve seen, to achieve this, the application invokes the issue transaction
defined in the CommercialPaper smart contract within papercontract.js. This
had been installed and instantiated in the network by the MagnetoCorp
administrator. It’s the smart contract which interacts with the ledger via the
Fabric APIs, most notably putState() and getState(), to represent the new
commercial paper as a vector state within the world state. We’ll see how this
vector state is subsequently manipulated by the buy and redeem transactions
also defined within the smart contract.
All the time, the underlying Fabric SDK handles the transaction endorsement,
ordering and notification process, making the application’s logic
straightforward; the SDK uses a gateway to
abstract away network details and
connectionOptions to declare more advanced
processing strategies such as transaction retry.
Let’s now follow the lifecycle of MagnetoCorp 00001 by switching our emphasis
to an employee of DigiBank, Balaji, who will buy the commercial paper using a
DigiBank application.

Digibank applications¶
Balaji uses DigiBank’s buy application to submit a transaction to the ledger
which transfers ownership of commercial paper 00001 from MagnetoCorp to
DigiBank. The CommercialPaper smart contract is the same as that used by
MagnetoCorp’s application, however the transaction is different this time –
it’s buy rather than issue. Let’s examine how DigiBank’s application works.
Open a separate terminal window for Balaji. In fabric-samples, change to the
DigiBank application directory that contains the application, buy.js, and open
it with your editor:
(balaji)$ cd commercial-paper/organization/digibank/application/
(balaji)$ code buy.js

As you can see, this directory contains both the buy and redeem applications
that will be used by Balaji.
 DigiBank’s
commercial paper directory containing the buy.js and redeem.js
applications.
DigiBank’s buy.js application is very similar in structure to MagnetoCorp’s
issue.js with two important differences:

Identity: the user is a DigiBank user Balaji rather than MagnetoCorp’s
Isabella
const wallet = await Wallets.newFileSystemWallet('../identity/user/balaji/wallet');

See how the application uses the balaji wallet when it connects to the
PaperNet network channel. buy.js selects a particular identity within
balaji wallet.

Transaction: the invoked transaction is buy rather than issue
const buyResponse = await contract.submitTransaction('buy', 'MagnetoCorp', '00001', ...);

A buy transaction is submitted with the values MagnetoCorp, 00001, …,
that are used by the CommercialPaper smart contract class to transfer
ownership of commercial paper 00001 to DigiBank.

Feel free to examine other files in the application directory to understand
how the application works, and read in detail how buy.js is implemented in
the application topic.

Run as DigiBank¶
The DigiBank applications which buy and redeem commercial paper have a very
similar structure to MagnetoCorp’s issue application. Therefore, let’s install
their dependencies and set up Balaji’s wallet so that he can use these
applications to buy and redeem commercial paper.
Like MagnetoCorp, Digibank must the install the required application packages
using the npm install command, and again, this make take a short time to
complete.
In the DigiBank administrator window, install the application dependencies:
(digibank admin)$ cd commercial-paper/organization/digibank/application/
(digibank admin)$ npm install

(            ) extract:lodash: sill extract ansi-styles@3.2.1
(...)
added 738 packages in 46.701s

In Balaji’s command window, run the addToWallet.js program to add the identity
to his wallet:
(balaji)$ node addToWallet.js

done

The addToWallet.js program has added identity information for balaji, to his
wallet, which will be used by buy.js and redeem.js to submit transactions to
PaperNet.
Like Isabella, Balaji can store multiple identities in his wallet, though in our
example, he only uses one. His corresponding id file at
digibank/identity/user/balaji/wallet/balaji.id is very similar Isabella’s —
feel free to examine it.

Buy application¶
Balaji can now use buy.js to submit a transaction that will transfer ownership
of MagnetoCorp commercial paper 00001 to DigiBank.
Run the buy application in Balaji’s window:
(balaji)$ node buy.js

Connect to Fabric gateway.
Use network channel: mychannel.
Use org.papernet.commercialpaper smart contract.
Submit commercial paper buy transaction.
Process buy transaction response.
MagnetoCorp commercial paper : 00001 successfully purchased by DigiBank
Transaction complete.
Disconnect from Fabric gateway.
Buy program complete.

You can see the program output that MagnetoCorp commercial paper 00001 was
successfully purchased by Balaji on behalf of DigiBank. buy.js invoked the
buy transaction defined in the CommercialPaper smart contract which updated
commercial paper 00001 within the world state using the putState() and
getState() Fabric APIs. As you’ve seen, the application logic to buy and issue
commercial paper is very similar, as is the smart contract logic.

Redeem application¶
The final transaction in the lifecycle of commercial paper 00001 is for
DigiBank to redeem it with MagnetoCorp. Balaji uses redeem.js to submit a
transaction to perform the redeem logic within the smart contract.
Run the redeem transaction in Balaji’s window:
(balaji)$ node redeem.js

Connect to Fabric gateway.
Use network channel: mychannel.
Use org.papernet.commercialpaper smart contract.
Submit commercial paper redeem transaction.
Process redeem transaction response.
MagnetoCorp commercial paper : 00001 successfully redeemed with MagnetoCorp
Transaction complete.
Disconnect from Fabric gateway.
Redeem program complete.

Again, see how the commercial paper 00001 was successfully redeemed when
redeem.js invoked the redeem transaction defined in CommercialPaper.
Again, it updated commercial paper 00001 within the world state to reflect
that the ownership returned to MagnetoCorp, the issuer of the paper.

Clean up¶
When you are finished using the Commercial Paper tutorial, you can use a script
to clean up your environment. Use a command window to navigate back to the root
directory of the commercial paper sample:
cd fabric-samples/commercial-paper

You can then bring down the network with the following command:
./network-clean.sh

This command will bring down the peers, CouchDB containers, and ordering node of the network, in addition to the logspout tool. It will also remove the identities that we created for Isabella and Balaji. Note that all of the data on the ledger will be lost. If you want to go through the tutorial again, you will start from a clean initial state.

Further reading¶
To understand how applications and smart contracts shown in this tutorial work
in more detail, you’ll find it helpful to read
Developing Applications. This
topic will give you a fuller explanation of the commercial paper scenario, the
PaperNet business network, its actors, and how the applications and smart
contracts they use work in detail.
Also feel free to use this sample to start creating your own applications and
smart contracts!

Using Private Data in Fabric¶
This tutorial will demonstrate the use of collections to provide storage
and retrieval of private data on the blockchain network for authorized peers
of organizations.
The information in this tutorial assumes knowledge of private data
stores and their use cases. For more information, check out Private data.

Note
These instructions use the new Fabric chaincode lifecycle introduced
in the Fabric v2.0 release. If you would like to use the previous
lifecycle model to use private data with chaincode, visit the v1.4
version of the Using Private Data in Fabric tutorial.

The tutorial will take you through the following steps to practice defining,
configuring and using private data with Fabric:

Build a collection definition JSON file
Read and Write private data using chaincode APIs
Install and define a chaincode with a collection
Store private data
Query the private data as an authorized peer
Query the private data as an unauthorized peer
Purge Private Data
Using indexes with private data
Additional resources

This tutorial will deploy the marbles private data sample
to the Fabric test network to demonstrate how to create, deploy, and use a collection of
private data. You should have completed the task Install Samples, Binaries, and Docker Images.

Build a collection definition JSON file¶
The first step in privatizing data on a channel is to build a collection
definition which defines access to the private data.
The collection definition describes who can persist data, how many peers the
data is distributed to, how many peers are required to disseminate the private
data, and how long the private data is persisted in the private database. Later,
we will demonstrate how chaincode APIs PutPrivateData and GetPrivateData
are used to map the collection to the private data being secured.
A collection definition is composed of the following properties:

name: Name of the collection.
policy: Defines the organization peers allowed to persist the collection data.
requiredPeerCount: Number of peers required to disseminate the private data as
a condition of the endorsement of the chaincode
maxPeerCount: For data redundancy purposes, the number of other peers
that the current endorsing peer will attempt to distribute the data to.
If an endorsing peer goes down, these other peers are available at commit time
if there are requests to pull the private data.
blockToLive: For very sensitive information such as pricing or personal information,
this value represents how long the data should live on the private database in terms
of blocks. The data will live for this specified number of blocks on the private database
and after that it will get purged, making this data obsolete from the network.
To keep private data indefinitely, that is, to never purge private data, set
the blockToLive property to 0.
memberOnlyRead: a value of true indicates that peers automatically
enforce that only clients belonging to one of the collection member organizations
are allowed read access to private data.

To illustrate usage of private data, the marbles private data example contains
two private data collection definitions: collectionMarbles
and collectionMarblePrivateDetails. The policy property in the
collectionMarbles definition allows all members of  the channel (Org1 and
Org2) to have the private data in a private database. The
collectionMarblesPrivateDetails collection allows only members of Org1 to
have the private data in their private database.
For more information on building a policy definition refer to the Endorsement policies
topic.
// collections_config.json

[
  {
       "name": "collectionMarbles",
       "policy": "OR('Org1MSP.member', 'Org2MSP.member')",
       "requiredPeerCount": 0,
       "maxPeerCount": 3,
       "blockToLive":1000000,
       "memberOnlyRead": true
  },

  {
       "name": "collectionMarblePrivateDetails",
       "policy": "OR('Org1MSP.member')",
       "requiredPeerCount": 0,
       "maxPeerCount": 3,
       "blockToLive":3,
       "memberOnlyRead": true
  }
]

The data to be secured by these policies is mapped in chaincode and will be
shown later in the tutorial.
This collection definition file is deployed when the chaincode definition is
committed to the channel using the peer lifecycle chaincode commit command.
More details on this process are provided in Section 3 below.

Read and Write private data using chaincode APIs¶
The next step in understanding how to privatize data on a channel is to build
the data definition in the chaincode. The marbles private data sample divides
the private data into two separate data definitions according to how the data will
be accessed.
// Peers in Org1 and Org2 will have this private data in a side database
type marble struct {
  ObjectType string `json:"docType"`
  Name       string `json:"name"`
  Color      string `json:"color"`
  Size       int    `json:"size"`
  Owner      string `json:"owner"`
}

// Only peers in Org1 will have this private data in a side database
type marblePrivateDetails struct {
  ObjectType string `json:"docType"`
  Name       string `json:"name"`
  Price      int    `json:"price"`
}

Specifically access to the private data will be restricted as follows:

name, color, size, and owner will be visible to all members of the channel (Org1 and Org2)
price only visible to members of Org1

Thus two different sets of private data are defined in the marbles private data
sample. The mapping of this data to the collection policy which restricts its
access is controlled by chaincode APIs. Specifically, reading and writing
private data using a collection definition is performed by calling GetPrivateData()
and PutPrivateData(), which can be found here.
The following diagram illustrates the private data model used by the marbles
private data sample.

Reading collection data¶
Use the chaincode API GetPrivateData() to query private data in the
database.  GetPrivateData() takes two arguments, the collection name
and the data key. Recall the collection  collectionMarbles allows members of
Org1 and Org2 to have the private data in a side database, and the collection
collectionMarblePrivateDetails allows only members of Org1 to have the
private data in a side database. For implementation details refer to the
following two marbles private data functions:

readMarble for querying the values of the name, color, size and owner attributes
readMarblePrivateDetails for querying the values of the price attribute

When we issue the database queries using the peer commands later in this tutorial,
we will call these two functions.

Writing private data¶
Use the chaincode API PutPrivateData() to store the private data
into the private database. The API also requires the name of the collection.
Since the marbles private data sample includes two different collections, it is called
twice in the chaincode:

Write the private data name, color, size and owner using the
collection named collectionMarbles.
Write the private data price using the collection named
collectionMarblePrivateDetails.

For example, in the following snippet of the initMarble function,
PutPrivateData() is called twice, once for each set of private data.
// ==== Create marble object, marshal to JSON, and save to state ====
      marble := &marble{
              ObjectType: "marble",
              Name:       marbleInput.Name,
              Color:      marbleInput.Color,
              Size:       marbleInput.Size,
              Owner:      marbleInput.Owner,
      }
      marbleJSONasBytes, err := json.Marshal(marble)
      if err != nil {
              return shim.Error(err.Error())
      }

      // === Save marble to state ===
      err = stub.PutPrivateData("collectionMarbles", marbleInput.Name, marbleJSONasBytes)
      if err != nil {
              return shim.Error(err.Error())
      }

      // ==== Create marble private details object with price, marshal to JSON, and save to state ====
      marblePrivateDetails := &marblePrivateDetails{
              ObjectType: "marblePrivateDetails",
              Name:       marbleInput.Name,
              Price:      marbleInput.Price,
      }
      marblePrivateDetailsBytes, err := json.Marshal(marblePrivateDetails)
      if err != nil {
              return shim.Error(err.Error())
      }
      err = stub.PutPrivateData("collectionMarblePrivateDetails", marbleInput.Name, marblePrivateDetailsBytes)
      if err != nil {
              return shim.Error(err.Error())
      }

To summarize, the policy definition above for our collection.json
allows all peers in Org1 and Org2 to store and transact
with the marbles private data name, color, size, owner in their
private database. But only peers in Org1 can store and transact with
the price private data in its private database.
As an additional data privacy benefit, since a collection is being used,
only the private data hashes go through orderer, not the private data itself,
keeping private data confidential from orderer.

Start the network¶
Now we are ready to step through some commands which demonstrate how to use
private data.
Try it yourself
Before installing, defining, and using the marbles private data chaincode below,
we need to start the Fabric test network. For the sake of this tutorial, we want
to operate from a known initial state. The following command will kill any active
or stale Docker containers and remove previously generated artifacts.
Therefore let’s run the following command to clean up any previous
environments:
cd fabric-samples/test-network
./network.sh down

If you have not run through the tutorial before, you will need to vendor the
chaincode dependencies before we can deploy it to the network. Run the
following commands:
cd ../chaincode/marbles02_private/go
GO111MODULE=on go mod vendor
cd ../../../test-network

If you’ve already run through this tutorial, you’ll also want to delete the
underlying Docker containers for the marbles private data chaincode. Let’s run
the following commands to clean up previous environments:
docker rm -f $(docker ps -a | awk '($2 ~ /dev-peer.*.marblesp.*/) {print $1}')
docker rmi -f $(docker images | awk '($1 ~ /dev-peer.*.marblesp.*/) {print $3}')

From the test-network directory, you can use the following command to start
up the Fabric test network with CouchDB:
./network.sh up createChannel -s couchdb

This command will deploy a Fabric network consisting of a single channel named
mychannel with two organizations (each maintaining one peer node) and an
ordering service while using CouchDB as the state database. Either LevelDB or
CouchDB may be used with collections. CouchDB was chosen to demonstrate how to
use indexes with private data.

Note
For collections to work, it is important to have cross organizational
gossip configured correctly. Refer to our documentation on Gossip data dissemination protocol,
paying particular attention to the section on “anchor peers”. Our tutorial
does not focus on gossip given it is already configured in the test network,
but when configuring a channel, the gossip anchors peers are critical to
configure for collections to work properly.

Install and define a chaincode with a collection¶
Client applications interact with the blockchain ledger through chaincode.
Therefore we need to install a chaincode on every peer that will execute and
endorse our transactions. However, before we can interact with our chaincode,
the members of the channel need to agree on a chaincode definition that
establishes chaincode governance, including the private data collection
configuration. We are going to package, install, and then define the chaincode
on the channel using peer lifecycle chaincode.
The chaincode needs to be packaged before it can be installed on our peers.
We can use the peer lifecycle chaincode package command
to package the marbles chaincode.
The test network includes two organizations, Org1 and Org2, with one peer each.
Therefore, the chaincode package has to be installed on two peers:

peer0.org1.example.com
peer0.org2.example.com

After the chaincode is packaged, we can use the peer lifecycle chaincode install
command to install the Marbles chaincode on each peer.
Try it yourself
Assuming you have started the test network, copy and paste the following
environment variables in your CLI to interact with the network and operate as
the Org1 admin. Make sure that you are in the test-network directory.
export PATH=${PWD}/../bin:$PATH
export FABRIC_CFG_PATH=$PWD/../config/
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

Use the following command to package the marbles private data chaincode.

peer lifecycle chaincode package marblesp.tar.gz --path ../chaincode/marbles02_private/go/ --lang golang --label marblespv1

This command will create a chaincode package named marblesp.tar.gz.
2. Use the following command to install the chaincode package onto the peer
peer0.org1.example.com.
peer lifecycle chaincode install marblesp.tar.gz

A successful install command will return the chaincode identifier, similar to
the response below:
2019-04-22 19:09:04.336 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 001 Installed remotely: response:<status:200 payload:"\nKmarblespv1:57f5353b2568b79cb5384b5a8458519a47186efc4fcadb98280f5eae6d59c1cd\022\nmarblespv1" >
2019-04-22 19:09:04.336 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 002 Chaincode code package identifier: marblespv1:57f5353b2568b79cb5384b5a8458519a47186efc4fcadb98280f5eae6d59c1cd

3. Now use the CLI as the Org2 admin. Copy and paste the following block of
commands as a group and run them all at once:
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

Run the following command to install the chaincode on the Org2 peer:

peer lifecycle chaincode install marblesp.tar.gz

Approve the chaincode definition¶
Each channel member that wants to use the chaincode needs to approve a chaincode
definition for their organization. Since both organizations are going to use the
chaincode in this tutorial, we need to approve the chaincode definition for both
Org1 and Org2 using the peer lifecycle chaincode approveformyorg
command. The chaincode definition also includes the private data collection
definition that accompanies the marbles02_private sample. We will provide
the path to the collections JSON file using the --collections-config flag.
Try it yourself
Run the following commands from the test-network directory to approve a
definition for Org1 and Org2.
1. Use the following command to query your peer for the package ID of the
installed chaincode.
peer lifecycle chaincode queryinstalled

The command will return the same package identifier as the install command.
You should see output similar to the following:
Installed chaincodes on peer:
Package ID: marblespv1:f8c8e06bfc27771028c4bbc3564341887881e29b92a844c66c30bac0ff83966e, Label: marblespv1

2. Declare the package ID as an environment variable. Paste the package ID of
marblespv1 returned by the peer lifecycle chaincode queryinstalled into
the command below. The package ID may not be the same for all users, so you
need to complete this step using the package ID returned from your console.
export CC_PACKAGE_ID=marblespv1:f8c8e06bfc27771028c4bbc3564341887881e29b92a844c66c30bac0ff83966e

3. Make sure we are running the CLI as Org1. Copy and paste the following block
of commands as a group into the peer container and run them all at once:
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

4. Use the following command to approve a definition of the marbles private data
chaincode for Org1. This command includes a path to the collection definition
file.
export ORDERER_CA=${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem
peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marblesp --version 1.0 --collections-config ../chaincode/marbles02_private/collections_config.json --signature-policy "OR('Org1MSP.member','Org2MSP.member')" --init-required --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile $ORDERER_CA

When the command completes successfully you should see something similar to:
2020-01-03 17:26:55.022 EST [chaincodeCmd] ClientWait -> INFO 001 txid [06c9e86ca68422661e09c15b8e6c23004710ea280efda4bf54d501e655bafa9b] committed with status (VALID) at

5. Now use the CLI to switch to Org2. Copy and paste the following block of commands
as a group into the peer container and run them all at once.
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

You can now approve the chaincode definition for Org2:

peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marblesp --version 1.0 --collections-config ../chaincode/marbles02_private/collections_config.json --signature-policy "OR('Org1MSP.member','Org2MSP.member')" --init-required --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile $ORDERER_CA

Commit the chaincode definition¶
Once a sufficient number of organizations (in this case, a majority) have
approved a chaincode definition, one organization can commit the definition to
the channel.
Use the peer lifecycle chaincode commit
command to commit the chaincode definition. This command will also deploy the
collection definition to the channel.
We are ready to use the chaincode after the chaincode definition has been
committed to the channel. Because the marbles private data chaincode contains an
initiation function, we need to use the peer chaincode invoke command
to invoke Init() before we can use other functions in the chaincode.
Try it yourself
1. Run the following commands to commit the definition of the marbles private
data chaincode to the channel mychannel.
export ORDERER_CA=${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem
export ORG1_CA=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export ORG2_CA=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
peer lifecycle chaincode commit -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marblesp --version 1.0 --sequence 1 --collections-config ../chaincode/marbles02_private/collections_config.json --signature-policy "OR('Org1MSP.member','Org2MSP.member')" --init-required --tls --cafile $ORDERER_CA --peerAddresses localhost:7051 --tlsRootCertFiles $ORG1_CA --peerAddresses localhost:9051 --tlsRootCertFiles $ORG2_CA

When the commit transaction completes successfully you should see something
similar to:
2020-01-06 16:24:46.104 EST [chaincodeCmd] ClientWait -> INFO 001 txid [4a0d0f5da43eb64f7cbfd72ea8a8df18c328fb250cb346077d91166d86d62d46] committed with status (VALID) at localhost:9051
2020-01-06 16:24:46.184 EST [chaincodeCmd] ClientWait -> INFO 002 txid [4a0d0f5da43eb64f7cbfd72ea8a8df18c328fb250cb346077d91166d86d62d46] committed with status (VALID) at localhost:7051

2. Use the following command to invoke the Init function to initialize the
chaincode:
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marblesp --isInit --tls --cafile $ORDERER_CA --peerAddresses localhost:7051 --tlsRootCertFiles $ORG1_CA -c '{"Args":["Init"]}'

Store private data¶
Acting as a member of Org1, who is authorized to transact with all of the private data
in the marbles private data sample, switch back to an Org1 peer and
submit a request to add a marble:
Try it yourself
Copy and paste the following set of commands into your CLI in the test-network
directory:
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

Invoke the marbles initMarble function which
creates a marble with private data —  name marble1 owned by tom with a color
blue, size 35 and price of 99. Recall that private data price
will be stored separately from the private data name, owner, color, size.
For this reason, the initMarble function calls the PutPrivateData() API
twice to persist the private data, once for each collection. Also note that
the private data is passed using the --transient flag. Inputs passed
as transient data will not be persisted in the transaction in order to keep
the data private. Transient data is passed as binary data and therefore when
using CLI it must be base64 encoded. We use an environment variable
to capture the base64 encoded value, and use tr command to strip off the
problematic newline characters that linux base64 command adds.
export MARBLE=$(echo -n "{\"name\":\"marble1\",\"color\":\"blue\",\"size\":35,\"owner\":\"tom\",\"price\":99}" | base64 | tr -d \\n)
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marblesp -c '{"Args":["initMarble"]}' --transient "{\"marble\":\"$MARBLE\"}"

You should see results similar to:
[chaincodeCmd] chaincodeInvokeOrQuery->INFO 001 Chaincode invoke successful. result: status:200

Query the private data as an authorized peer¶
Our collection definition allows all members of Org1 and Org2
to have the name, color, size, owner private data in their side database,
but only peers in Org1 can have the price private data in their side
database. As an authorized peer in Org1, we will query both sets of private data.
The first query command calls the readMarble function which passes
collectionMarbles as an argument.
// ===============================================
// readMarble - read a marble from chaincode state
// ===============================================

func (t *SimpleChaincode) readMarble(stub shim.ChaincodeStubInterface, args []string) pb.Response {
     var name, jsonResp string
     var err error
     if len(args) != 1 {
             return shim.Error("Incorrect number of arguments. Expecting name of the marble to query")
     }

     name = args[0]
     valAsbytes, err := stub.GetPrivateData("collectionMarbles", name) //get the marble from chaincode state

     if err != nil {
             jsonResp = "{\"Error\":\"Failed to get state for " + name + "\"}"
             return shim.Error(jsonResp)
     } else if valAsbytes == nil {
             jsonResp = "{\"Error\":\"Marble does not exist: " + name + "\"}"
             return shim.Error(jsonResp)
     }

     return shim.Success(valAsbytes)
}

The second query command calls the readMarblePrivateDetails
function which passes collectionMarblePrivateDetails as an argument.
// ===============================================
// readMarblePrivateDetails - read a marble private details from chaincode state
// ===============================================

func (t *SimpleChaincode) readMarblePrivateDetails(stub shim.ChaincodeStubInterface, args []string) pb.Response {
     var name, jsonResp string
     var err error

     if len(args) != 1 {
             return shim.Error("Incorrect number of arguments. Expecting name of the marble to query")
     }

     name = args[0]
     valAsbytes, err := stub.GetPrivateData("collectionMarblePrivateDetails", name) //get the marble private details from chaincode state

     if err != nil {
             jsonResp = "{\"Error\":\"Failed to get private details for " + name + ": " + err.Error() + "\"}"
             return shim.Error(jsonResp)
     } else if valAsbytes == nil {
             jsonResp = "{\"Error\":\"Marble private details does not exist: " + name + "\"}"
             return shim.Error(jsonResp)
     }
     return shim.Success(valAsbytes)
}

Now Try it yourself
Query for the name, color, size and owner private data of marble1 as a member of Org1.
Note that since queries do not get recorded on the ledger, there is no need to pass
the marble name as a transient input.
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarble","marble1"]}'

You should see the following result:
{"color":"blue","docType":"marble","name":"marble1","owner":"tom","size":35}

Query for the price private data of marble1 as a member of Org1.
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarblePrivateDetails","marble1"]}'

You should see the following result:
{"docType":"marblePrivateDetails","name":"marble1","price":99}

Query the private data as an unauthorized peer¶
Now we will switch to a member of Org2. Org2 has the marbles private data
name, color, size, owner in its side database, but does not store the
marbles price data. We will query for both sets of private data.

Switch to a peer in Org2¶
Run the following commands to operate as the Org2 admin and query the Org2 peer.
Try it yourself
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

Query private data Org2 is authorized to¶
Peers in Org2 should have the first set of marbles private data (name,
color, size and owner) in their side database and can access it using the
readMarble() function which is called with the collectionMarbles
argument.
Try it yourself
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarble","marble1"]}'

You should see something similar to the following result:
{"docType":"marble","name":"marble1","color":"blue","size":35,"owner":"tom"}

Query private data Org2 is not authorized to¶
Peers in Org2 do not have the marbles price private data in their side database.
When they try to query for this data, they get back a hash of the key matching
the public state but will not have the private state.
Try it yourself
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarblePrivateDetails","marble1"]}'

You should see a result similar to:
Error: endorsement failure during query. response: status:500
message:"{\"Error\":\"Failed to get private details for marble1:
GET_STATE failed: transaction ID: d9c437d862de66755076aeebe79e7727791981606ae1cb685642c93f102b03e5:
tx creator does not have read access permission on privatedata in chaincodeName:marblesp collectionName: collectionMarblePrivateDetails\"}"

Members of Org2 will only be able to see the public hash of the private data.

Purge Private Data¶
For use cases where private data only needs to be on the ledger until it can be
replicated into an off-chain database, it is possible to “purge” the data after
a certain set number of blocks, leaving behind only hash of the data that serves
as immutable evidence of the transaction.
There may be private data including personal or confidential
information, such as the pricing data in our example, that the transacting
parties don’t want disclosed to other organizations on the channel. Thus, it
has a limited lifespan, and can be purged after existing unchanged on the
blockchain for a designated number of blocks using the blockToLive property
in the collection definition.
Our collectionMarblePrivateDetails definition has a blockToLive
property value of three meaning this data will live on the side database for
three blocks and then after that it will get purged. Tying all of the pieces
together, recall this collection definition  collectionMarblePrivateDetails
is associated with the price private data in the  initMarble() function
when it calls the PutPrivateData() API and passes the
collectionMarblePrivateDetails as an argument.
We will step through adding blocks to the chain, and then watch the price
information get purged by issuing four new transactions (Create a new marble,
followed by three marble transfers) which adds four new blocks to the chain.
After the fourth transaction (third marble transfer), we will verify that the
price private data is purged.
Try it yourself
Switch back to Org1 using the following commands. Copy and paste the following code
block and run it inside your peer container:
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

Open a new terminal window and view the private data logs for this peer by
running the following command. Note the highest block number.
docker logs peer0.org1.example.com 2>&1 | grep -i -a -E 'private|pvt|privdata'

Back in the peer container, query for the marble1 price data by running the
following command. (A Query does not create a new transaction on the ledger
since no data is transacted).
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarblePrivateDetails","marble1"]}'

You should see results similar to:
{"docType":"marblePrivateDetails","name":"marble1","price":99}

The price data is still in the private data ledger.
Create a new marble2 by issuing the following command. This transaction
creates a new block on the chain.
export MARBLE=$(echo -n "{\"name\":\"marble2\",\"color\":\"blue\",\"size\":35,\"owner\":\"tom\",\"price\":99}" | base64 | tr -d \\n)
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marblesp -c '{"Args":["initMarble"]}' --transient "{\"marble\":\"$MARBLE\"}"

Switch back to the Terminal window and view the private data logs for this peer
again. You should see the block height increase by 1.
docker logs peer0.org1.example.com 2>&1 | grep -i -a -E 'private|pvt|privdata'

Back in the peer container, query for the marble1 price data again by
running the following command:
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarblePrivateDetails","marble1"]}'

The private data has not been purged, therefore the results are unchanged from
previous query:
{"docType":"marblePrivateDetails","name":"marble1","price":99}

Transfer marble2 to “joe” by running the following command. This transaction
will add a second new block on the chain.
export MARBLE_OWNER=$(echo -n "{\"name\":\"marble2\",\"owner\":\"joe\"}" | base64 | tr -d \\n)
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marblesp -c '{"Args":["transferMarble"]}' --transient "{\"marble_owner\":\"$MARBLE_OWNER\"}"

Switch back to the Terminal window and view the private data logs for this peer
again. You should see the block height increase by 1.
docker logs peer0.org1.example.com 2>&1 | grep -i -a -E 'private|pvt|privdata'

Back in the peer container, query for the marble1 price data by running the
following command:
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarblePrivateDetails","marble1"]}'

You should still be able to see the price private data.
{"docType":"marblePrivateDetails","name":"marble1","price":99}

Transfer marble2 to “tom” by running the following command. This transaction
will create a third new block on the chain.
export MARBLE_OWNER=$(echo -n "{\"name\":\"marble2\",\"owner\":\"tom\"}" | base64 | tr -d \\n)
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marblesp -c '{"Args":["transferMarble"]}' --transient "{\"marble_owner\":\"$MARBLE_OWNER\"}"

Switch back to the Terminal window and view the private data logs for this peer
again. You should see the block height increase by 1.
docker logs peer0.org1.example.com 2>&1 | grep -i -a -E 'private|pvt|privdata'

Back in the peer container, query for the marble1 price data by running the
following command:
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarblePrivateDetails","marble1"]}'

You should still be able to see the price data.
{"docType":"marblePrivateDetails","name":"marble1","price":99}

Finally, transfer marble2 to “jerry” by running the following command. This
transaction will create a fourth new block on the chain. The price private
data should be purged after this transaction.
export MARBLE_OWNER=$(echo -n "{\"name\":\"marble2\",\"owner\":\"jerry\"}" | base64 | tr -d \\n)
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marblesp -c '{"Args":["transferMarble"]}' --transient "{\"marble_owner\":\"$MARBLE_OWNER\"}"

Switch back to the Terminal window and view the private data logs for this peer
again. You should see the block height increase by 1.
docker logs peer0.org1.example.com 2>&1 | grep -i -a -E 'private|pvt|privdata'

Back in the peer container, query for the marble1 price data by running the following command:
peer chaincode query -C mychannel -n marblesp -c '{"Args":["readMarblePrivateDetails","marble1"]}'

Because the price data has been purged, you should no longer be able to see it.
You should see something similar to:
Error: endorsement failure during query. response: status:500
message:"{\"Error\":\"Marble private details does not exist: marble1\"}"

Using indexes with private data¶
Indexes can also be applied to private data collections, by packaging indexes in
the META-INF/statedb/couchdb/collections/<collection_name>/indexes directory
alongside the chaincode. An example index is available here .
For deployment of chaincode to production environments, it is recommended
to define any indexes alongside chaincode so that the chaincode and supporting
indexes are deployed automatically as a unit, once the chaincode has been
installed on a peer and instantiated on a channel. The associated indexes are
automatically deployed upon chaincode instantiation on the channel when
the  --collections-config flag is specified pointing to the location of
the collection JSON file.

Additional resources¶
For additional private data education, a video tutorial has been created.

Note
The video uses the previous lifecycle model to install private data
collections with chaincode.

Using CouchDB¶
This tutorial will describe the steps required to use the CouchDB as the state
database with Hyperledger Fabric. By now, you should be familiar with Fabric
concepts and have explored some of the samples and tutorials.

Note
These instructions use the new Fabric chaincode lifecycle introduced
in the Fabric v2.0 release. If you would like to use the previous
lifecycle model to use indexes with chaincode, visit the v1.4
version of the Using CouchDB.

The tutorial will take you through the following steps:

Enable CouchDB in Hyperledger Fabric
Create an index
Add the index to your chaincode folder
Install and define the Chaincode
Query the CouchDB State Database
Use best practices for queries and indexes
Query the CouchDB State Database With Pagination
Update an Index
Delete an Index

For a deeper dive into CouchDB refer to CouchDB as the State Database
and for more information on the Fabric ledger refer to the Ledger
topic. Follow the tutorial below for details on how to leverage CouchDB in your
blockchain network.
Throughout this tutorial, we will use the Marbles sample
as our use case to demonstrate how to use CouchDB with Fabric and will deploy
Marbles to the Fabric test network. You should have completed the task
Install Samples, Binaries, and Docker Images.

Why CouchDB?¶
Fabric supports two types of peer databases. LevelDB is the default state
database embedded in the peer node. LevelDB stores chaincode data as simple
key-value pairs and only supports key, key range, and composite key queries.
CouchDB is an optional, alternate state database that allows you to model data
on the ledger as JSON and issue rich queries against data values rather than
the keys. CouchDB also allows you to deploy indexes with your chaincode to make
queries more efficient and enable you to query large datasets.
In order to leverage the benefits of CouchDB, namely content-based JSON
queries, your data must be modeled in JSON format. You must decide whether to use
LevelDB or CouchDB before setting up your network. Switching a peer from using
LevelDB to CouchDB is not supported due to data compatibility issues. All peers
on the network must use the same database type. If you have a mix of JSON and
binary data values, you can still use CouchDB, however the binary values can
only be queried based on key, key range, and composite key queries.

Enable CouchDB in Hyperledger Fabric¶
CouchDB runs as a separate database process alongside the peer. There
are additional considerations in terms of setup, management, and operations.
A Docker image of CouchDB
is available and we recommend that it be run on the same server as the
peer. You will need to setup one CouchDB container per peer
and update each peer container by changing the configuration found in
core.yaml to point to the CouchDB container. The core.yaml
file must be located in the directory specified by the environment variable
FABRIC_CFG_PATH:

For Docker deployments, core.yaml is pre-configured and located in the peer
container FABRIC_CFG_PATH folder. However, when using Docker environments,
you typically pass environment variables by editing the
docker-compose-couch.yaml  to override the core.yaml
For native binary deployments, core.yaml is included with the release artifact
distribution.

Edit the stateDatabase section of core.yaml. Specify CouchDB as the
stateDatabase and fill in the associated couchDBConfig properties. For
more information, see CouchDB configuration.

Create an index¶
Why are indexes important?
Indexes allow a database to be queried without having to examine every row
with every query, making them run faster and more efficiently. Normally,
indexes are built for frequently occurring query criteria allowing the data to
be queried more efficiently. To leverage the major benefit of CouchDB – the
ability to perform rich queries against JSON data – indexes are not required,
but they are strongly recommended for performance. Also, if sorting is required
in a query, CouchDB requires an index of the sorted fields.

Note
Rich queries that do not have an index will work but may throw a warning
in the CouchDB log that the index was not found. However, if a rich query
includes a sort specification, then an index on that field is required;
otherwise, the query will fail and an error will be thrown.

To demonstrate building an index, we will use the data from the Marbles
sample.
In this example, the Marbles data structure is defined as:
type marble struct {
         ObjectType string `json:"docType"` //docType is used to distinguish the various types of objects in state database
         Name       string `json:"name"`    //the field tags are needed to keep case from bouncing around
         Color      string `json:"color"`
         Size       int    `json:"size"`
         Owner      string `json:"owner"`
}

In this structure, the attributes (docType, name, color, size,
owner) define the ledger data associated with the asset. The attribute
docType is a pattern used in the chaincode to differentiate different data
types that may need to be queried separately. When using CouchDB, it
recommended to include this docType attribute to distinguish each type of
document in the chaincode namespace. (Each chaincode is represented as its own
CouchDB database, that is, each chaincode has its own namespace for keys.)
With respect to the Marbles data structure, docType is used to identify
that this document/asset is a marble asset. Potentially there could be other
documents/assets in the chaincode database. The documents in the database are
searchable against all of these attribute values.
When defining an index for use in chaincode queries, each one must be defined
in its own text file with the extension *.json and the index definition must
be formatted in the CouchDB index JSON format.
To define an index, three pieces of information are required:

fields: these are the frequently queried fields
name: name of the index
type: always json in this context

For example, a simple index named foo-index for a field named foo.
{
    "index": {
        "fields": ["foo"]
    },
    "name" : "foo-index",
    "type" : "json"
}

Optionally the design document  attribute ddoc can be specified on the index
definition. A design document is
CouchDB construct designed to contain indexes. Indexes can be grouped into
design documents for efficiency but CouchDB recommends one index per design
document.

Tip
When defining an index it is a good practice to include the ddoc
attribute and value along with the index name. It is important to
include this attribute to ensure that you can update the index later
if needed. Also it gives you the ability to explicitly specify which
index to use on a query.

Here is another example of an index definition from the Marbles sample with
the index name indexOwner using multiple fields docType and owner
and includes the ddoc attribute:
{
  "index":{
      "fields":["docType","owner"] // Names of the fields to be queried
  },
  "ddoc":"indexOwnerDoc", // (optional) Name of the design document in which the index will be created.
  "name":"indexOwner",
  "type":"json"
}

In the example above, if the design document indexOwnerDoc does not already
exist, it is automatically created when the index is deployed. An index can be
constructed with one or more attributes specified in the list of fields and
any combination of attributes can be specified. An attribute can exist in
multiple indexes for the same docType. In the following example, index1
only includes the attribute owner, index2 includes the attributes
owner and color and index3 includes the attributes owner, color and
size. Also, notice each index definition has its own ddoc value, following
the CouchDB recommended practice.
{
  "index":{
      "fields":["owner"] // Names of the fields to be queried
  },
  "ddoc":"index1Doc", // (optional) Name of the design document in which the index will be created.
  "name":"index1",
  "type":"json"
}

{
  "index":{
      "fields":["owner", "color"] // Names of the fields to be queried
  },
  "ddoc":"index2Doc", // (optional) Name of the design document in which the index will be created.
  "name":"index2",
  "type":"json"
}

{
  "index":{
      "fields":["owner", "color", "size"] // Names of the fields to be queried
  },
  "ddoc":"index3Doc", // (optional) Name of the design document in which the index will be created.
  "name":"index3",
  "type":"json"
}

In general, you should model index fields to match the fields that will be used
in query filters and sorts. For more details on building an index in JSON
format refer to the CouchDB documentation.
A final word on indexing, Fabric takes care of indexing the documents in the
database using a pattern called index warming. CouchDB does not typically
index new or updated documents until the next query. Fabric ensures that
indexes stay ‘warm’ by requesting an index update after every block of data is
committed.  This ensures queries are fast because they do not have to index
documents before running the query. This process keeps the index current
and refreshed every time new records are added to the state database.

Add the index to your chaincode folder¶
Once you finalize an index, you need to package it with your chaincode for
deployment by placing it in the appropriate metadata folder. You can install the
chaincode using the peer lifecycle chaincode command. The JSON index files
must be located under the path META-INF/statedb/couchdb/indexes which is
located inside the directory where the chaincode resides.
The Marbles sample  below illustrates how the index
is packaged with the chaincode.

This sample includes one index named indexOwnerDoc:
{"index":{"fields":["docType","owner"]},"ddoc":"indexOwnerDoc", "name":"indexOwner","type":"json"}

Start the network¶
Try it yourself
We will bring up the Fabric test network and use it to deploy the marbles
chainocde. Use the following command to navigate to the test-network directory
in the Fabric samples:
cd fabric-samples/test-network

For this tutorial, we want to operate from a known initial state. The following
command will kill any active or stale Docker containers and remove previously
generated artifacts:
./network.sh down

If you have not run through the tutorial before, you will need to vendor the
chaincode dependencies before we can deploy it to the network. Run the
following commands:
cd ../chaincode/marbles02/go
GO111MODULE=on go mod vendor
cd ../../../test-network

From the test-network directory, deploy the test network with CouchDB with the
following command:
./network.sh up createChannel -s couchdb

This will create two fabric peer nodes that use CouchDB as the state database.
It will also create one ordering node and a single channel named
mychannel.

Install and define the Chaincode¶
Client applications interact with the blockchain ledger through chaincode.
Therefore we need to install a chaincode on every peer that will execute and
endorse our transactions. However, before we can interact with our chaincode,
the members of the channel need to agree on a chaincode definition that
establishes chaincode governance. In the previous section, we demonstrated how
to add the index to the chaincode folder so that the index is deployed with
the chaincode.
The chaincode needs to be packaged before it can be installed on our peers.
We can use the peer lifecycle chaincode package command
to package the marbles chaincode.
Try it yourself
1. After you start the test network, copy and paste the following environment
variables in your CLI to interact with the network as the Org1 admin. Make sure
that you are in the test-network directory.
export PATH=${PWD}/../bin:$PATH
export FABRIC_CFG_PATH=${PWD}/../config/
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

Use the following command to package the marbles chaincode:

peer lifecycle chaincode package marbles.tar.gz --path ../chaincode/marbles02/go --lang golang --label marbles_1

This command will create a chaincode package named marbles.tar.gz.
3. Use the following command to install the chaincode package onto the peer
peer0.org1.example.com:
peer lifecycle chaincode install marbles.tar.gz

A successful install command will return the chaincode identifier, similar to
the response below:
2019-04-22 18:47:38.312 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 001 Installed remotely: response:<status:200 payload:"\nJmarbles_1:0907c1f3d3574afca69946e1b6132691d58c2f5c5703df7fc3b692861e92ecd3\022\tmarbles_1" >
2019-04-22 18:47:38.312 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 002 Chaincode code package identifier: marbles_1:0907c1f3d3574afca69946e1b6132691d58c2f5c5703df7fc3b692861e92ecd3

After installing the chaincode on peer0.org1.example.com, we need to approve
a chaincode definition for Org1.
4. Use the following command to query your peer for the package ID of the
installed chaincode.
peer lifecycle chaincode queryinstalled

The command will return the same package identifier as the install command.
You should see output similar to the following:
Installed chaincodes on peer:
Package ID: marbles_1:60ec9430b221140a45b96b4927d1c3af736c1451f8d432e2a869bdbf417f9787, Label: marbles_1

5. Declare the package ID as an environment variable. Paste the package ID of
marbles_1 returned by the peer lifecycle chaincode queryinstalled command
into the command below. The package ID may not be the same for all users, so
you need to complete this step using the package ID returned from your console.
export CC_PACKAGE_ID=marbles_1:60ec9430b221140a45b96b4927d1c3af736c1451f8d432e2a869bdbf417f9787

6. Use the following command to approve a definition of the marbles chaincode
for Org1.
export ORDERER_CA=${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem
peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marbles --version 1.0 --signature-policy "OR('Org1MSP.member','Org2MSP.member')" --init-required --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile $ORDERER_CA

When the command completes successfully you should see something similar to :
2020-01-07 16:24:20.886 EST [chaincodeCmd] ClientWait -> INFO 001 txid [560cb830efa1272c85d2f41a473483a25f3b12715d55e22a69d55abc46581415] committed with status (VALID) at

We need a majority of organizations to approve a chaincode definition before
it can be committed to the channel. This implies that we need Org2 to approve
the chaincode definition as well. Because we do not need Org2 to endorse the
chaincode and did not install the package on any Org2 peers, we do not need to
provide a packageID as part of the chaincode definition.
7. Use the CLI to operate as the Org2 admin. Copy and paste the following block
of commands as a group into the peer container and run them all at once.
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

Use the following command to approve the chaincode definition for Org2:

peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marbles --version 1.0 --signature-policy "OR('Org1MSP.member','Org2MSP.member')" --init-required --sequence 1 --tls --cafile $ORDERER_CA

9. We can now use the peer lifecycle chaincode commit command
to commit the chaincode definition to the channel:
export ORDERER_CA=${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem
export ORG1_CA=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export ORG2_CA=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
peer lifecycle chaincode commit -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marbles --version 1.0 --sequence 1 --signature-policy "OR('Org1MSP.member','Org2MSP.member')" --init-required --tls --cafile $ORDERER_CA --peerAddresses localhost:7051 --tlsRootCertFiles $ORG1_CA --peerAddresses localhost:9051 --tlsRootCertFiles $ORG2_CA

When the commit transaction completes successfully you should see something
similar to:
2019-04-22 18:57:34.274 UTC [chaincodeCmd] ClientWait -> INFO 001 txid [3da8b0bb8e128b5e1b6e4884359b5583dff823fce2624f975c69df6bce614614] committed with status (VALID) at peer0.org2.example.com:9051
2019-04-22 18:57:34.709 UTC [chaincodeCmd] ClientWait -> INFO 002 txid [3da8b0bb8e128b5e1b6e4884359b5583dff823fce2624f975c69df6bce614614] committed with status (VALID) at peer0.org1.example.com:7051

10. Because the marbles chaincode contains an initialization function, we need to
use the peer chaincode invoke command
to invoke Init() before we can use other functions in the chaincode:
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name marbles --isInit --tls --cafile $ORDERER_CA --peerAddresses localhost:7051 --tlsRootCertFiles $ORG1_CA -c '{"Args":["Init"]}'

Verify index was deployed¶
Indexes will be deployed to each peer’s CouchDB state database once the
chaincode has been installed on the peer and deployed to the channel. You can
verify that the CouchDB index was created successfully by examining the peer log
in the Docker container.
Try it yourself
To view the logs in the peer Docker container, open a new Terminal window and
run the following command to grep for message confirmation that the index was
created.
docker logs peer0.org1.example.com  2>&1 | grep "CouchDB index"

You should see a result that looks like the following:
[couchdb] CreateIndex -> INFO 0be Created CouchDB index [indexOwner] in state database [mychannel_marbles] using design document [_design/indexOwnerDoc]

Note
If you installed Marbles on a different peer than peer0.org1.example.com,
you may need to replace it with the name of a different peer where
Marbles was installed.

Query the CouchDB State Database¶
Now that the index has been defined in the JSON file and deployed alongside the
chaincode, chaincode functions can execute JSON queries against the CouchDB
state database, and thereby peer commands can invoke the chaincode functions.
Specifying an index name on a query is optional. If not specified, and an index
already exists for the fields being queried, the existing index will be
automatically used.

Tip
It is a good practice to explicitly include an index name on a
query using the use_index keyword. Without it, CouchDB may pick a
less optimal index. Also CouchDB may not use an index at all and you
may not realize it, at the low volumes during testing. Only upon
higher volumes you may realize slow performance because CouchDB is not
using an index and you assumed it was.

Build the query in chaincode¶
You can perform complex rich queries against the data on the ledger using
queries defined within your chaincode. The marbles02 sample
includes two rich query functions:

queryMarbles –

Example of an ad hoc rich query. This is a query
where a (selector) string can be passed into the function. This query
would be useful to client applications that need to dynamically build
their own selectors at runtime. For more information on selectors refer
to CouchDB selector syntax.

queryMarblesByOwner –

Example of a parameterized query where the
query logic is baked into the chaincode. In this case the function accepts
a single argument, the marble owner. It then queries the state database for
JSON documents matching the docType of “marble” and the owner id using the
JSON query syntax.

Run the query using the peer command¶
In absence of a client application, we can use the peer command to test the
queries defined in the chaincode. We will customize the peer chaincode query
command to use the Marbles index indexOwner and query for all marbles owned
by “tom” using the queryMarbles function.
Try it yourself
Before querying the database, we should add some data. Run the following
command as Org1 to create a marble owned by “tom”:
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marbles -c '{"Args":["initMarble","marble1","blue","35","tom"]}'

After an index has been deployed when the chaincode is initialized, it will
automatically be utilized by chaincode queries. CouchDB can determine which
index to use based on the fields being queried. If an index exists for the
query criteria it will be used. However the recommended approach is to
specify the use_index keyword on the query. The peer command below is an
example of how to specify the index explicitly in the selector syntax by
including the use_index keyword:
// Rich Query with index name explicitly specified:
peer chaincode query -C mychannel -n marbles -c '{"Args":["queryMarbles", "{\"selector\":{\"docType\":\"marble\",\"owner\":\"tom\"}, \"use_index\":[\"_design/indexOwnerDoc\", \"indexOwner\"]}"]}'

Delving into the query command above, there are three arguments of interest:

queryMarbles

Name of the function in the Marbles chaincode. Notice a shim
shim.ChaincodeStubInterface is used to access and modify the ledger. The
getQueryResultForQueryString() passes the queryString to the shim API getQueryResult().
func (t *SimpleChaincode) queryMarbles(stub shim.ChaincodeStubInterface, args []string) pb.Response {

        //   0
        // "queryString"
         if len(args) < 1 {
                 return shim.Error("Incorrect number of arguments. Expecting 1")
         }

         queryString := args[0]

         queryResults, err := getQueryResultForQueryString(stub, queryString)
         if err != nil {
               return shim.Error(err.Error())
         }
         return shim.Success(queryResults)
}

{"selector":{"docType":"marble","owner":"tom"}

This is an example of an ad hoc selector string which finds all documents
of type marble where the owner attribute has a value of tom.

"use_index":["_design/indexOwnerDoc", "indexOwner"]

Specifies both the design doc name  indexOwnerDoc and index name
indexOwner. In this example the selector query explicitly includes the
index name, specified by using the use_index keyword. Recalling the
index definition above Create an index, it contains a design doc,
"ddoc":"indexOwnerDoc". With CouchDB, if you plan to explicitly include
the index name on the query, then the index definition must include the
ddoc value, so it can be referenced with the use_index keyword.
The query runs successfully and the index is leveraged with the following results:
Query Result: [{"Key":"marble1", "Record":{"color":"blue","docType":"marble","name":"marble1","owner":"tom","size":35}}]

Use best practices for queries and indexes¶
Queries that use indexes will complete faster, without having to scan the full
database in couchDB. Understanding indexes will allow you to write your queries
for better performance and help your application handle larger amounts
of data or blocks on your network.
It is also important to plan the indexes you install with your chaincode. You
should install only a few indexes per chaincode that support most of your queries.
Adding too many indexes, or using an excessive number of fields in an index, will
degrade the performance of your network. This is because the indexes are updated
after each block is committed. The more indexes need to be updated through
“index warming”, the longer it will take for transactions to complete.
The examples in this section will help demonstrate how queries use indexes and
what type of queries will have the best performance. Remember the following
when writing your queries:

All fields in the index must also be in the selector or sort sections of your query
for the index to be used.
More complex queries will have a lower performance and will be less likely to
use an index.
You should try to avoid operators that will result in a full table scan or a
full index scan such as $or, $in and $regex.

In the previous section of this tutorial, you issued the following query against
the marbles chaincode:
// Example one: query fully supported by the index
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarbles", "{\"selector\":{\"docType\":\"marble\",\"owner\":\"tom\"}, \"use_index\":[\"indexOwnerDoc\", \"indexOwner\"]}"]}'

The marbles chaincode was installed with the indexOwnerDoc index:
{"index":{"fields":["docType","owner"]},"ddoc":"indexOwnerDoc", "name":"indexOwner","type":"json"}

Notice that both the fields in the query, docType and owner, are
included in the index, making it a fully supported query. As a result this
query will be able to use the data in the index, without having to search the
full database. Fully supported queries such as this one will return faster than
other queries from your chaincode.
If you add extra fields to the query above, it will still use the index.
However, the query will additionally have to scan the indexed data for the
extra fields, resulting in a longer response time. As an example, the query
below will still use the index, but will take a longer time to return than the
previous example.
// Example two: query fully supported by the index with additional data
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarbles", "{\"selector\":{\"docType\":\"marble\",\"owner\":\"tom\",\"color\":\"red\"}, \"use_index\":[\"/indexOwnerDoc\", \"indexOwner\"]}"]}'

A query that does not include all fields in the index will have to scan the full
database instead. For example, the query below searches for the owner, without
specifying the the type of item owned. Since the ownerIndexDoc contains both
the owner and docType fields, this query will not be able to use the
index.
// Example three: query not supported by the index
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarbles", "{\"selector\":{\"owner\":\"tom\"}, \"use_index\":[\"indexOwnerDoc\", \"indexOwner\"]}"]}'

In general, more complex queries will have a longer response time, and have a
lower chance of being supported by an index. Operators such as $or, $in,
and $regex will often cause the query to scan the full index or not use the
index at all.
As an example, the query below contains an $or term that will search for every
marble and every item owned by tom.
// Example four: query with $or supported by the index
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarbles", "{\"selector\":{"\$or\":[{\"docType\:\"marble\"},{\"owner\":\"tom\"}]}, \"use_index\":[\"indexOwnerDoc\", \"indexOwner\"]}"]}'

This query will still use the index because it searches for fields that are
included in indexOwnerDoc. However, the $or condition in the query
requires a scan of all the items in the index, resulting in a longer response
time.
Below is an example of a complex query that is not supported by the index.
// Example five: Query with $or not supported by the index
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarbles", "{\"selector\":{"\$or\":[{\"docType\":\"marble\",\"owner\":\"tom\"},{"\color\":"\yellow\"}]}, \"use_index\":[\"indexOwnerDoc\", \"indexOwner\"]}"]}'

The query searches for all marbles owned by tom or any other items that are
yellow. This query will not use the index because it will need to search the
entire table to meet the $or condition. Depending the amount of data on your
ledger, this query will take a long time to respond or may timeout.
While it is important to follow best practices with your queries, using indexes
is not a solution for collecting large amounts of data. The blockchain data
structure is optimized to validate and confirm transactions and is not suited
for data analytics or reporting. If you want to build a dashboard as part
of your application or analyze the data from your network, the best practice is
to query an off chain database that replicates the data from your peers. This
will allow you to understand the data on the blockchain without degrading the
performance of your network or disrupting transactions.
You can use block or chaincode events from your application to write transaction
data to an off-chain database or analytics engine. For each block received, the block
listener application would iterate through the block transactions and build a data
store using the key/value writes from each valid transaction’s rwset. The
Peer channel-based event services provide replayable events to ensure the integrity of
downstream data stores. For an example of how you can use an event listener to write
data to an external database, visit the Off chain data sample
in the Fabric Samples.

Query the CouchDB State Database With Pagination¶
When large result sets are returned by CouchDB queries, a set of APIs is
available which can be called by chaincode to paginate the list of results.
Pagination provides a mechanism to partition the result set by
specifying a pagesize and a start point – a bookmark which indicates
where to begin the result set. The client application iteratively invokes the
chaincode that executes the query until no more results are returned. For more information refer to
this topic on pagination with CouchDB.
We will use the Marbles sample
function queryMarblesWithPagination to  demonstrate how
pagination can be implemented in chaincode and the client application.

queryMarblesWithPagination –

Example of an ad hoc rich query with pagination. This is a query
where a (selector) string can be passed into the function similar to the
above example.  In this case, a pageSize is also included with the query as
well as a bookmark.

In order to demonstrate pagination, more data is required. This example assumes
that you have already added marble1 from above. Run the following commands in
the peer container to create four more marbles owned by “tom”, to create a
total of five marbles owned by “tom”:
Try it yourself
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile  ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marbles -c '{"Args":["initMarble","marble2","yellow","35","tom"]}'
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile  ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marbles -c '{"Args":["initMarble","marble3","green","20","tom"]}'
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile  ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marbles -c '{"Args":["initMarble","marble4","purple","20","tom"]}'
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile  ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n marbles -c '{"Args":["initMarble","marble5","blue","40","tom"]}'

In addition to the arguments for the query in the previous example,
queryMarblesWithPagination adds pagesize and bookmark. PageSize
specifies the number of records to return per query.  The bookmark is an
“anchor” telling couchDB where to begin the page. (Each page of results returns
a unique bookmark.)

queryMarblesWithPagination

Name of the function in the Marbles chaincode. Notice a shim
shim.ChaincodeStubInterface is used to access and modify the ledger. The
getQueryResultForQueryStringWithPagination() passes the queryString along
with the pagesize and bookmark to the shim API GetQueryResultWithPagination().
func (t *SimpleChaincode) queryMarblesWithPagination(stub shim.ChaincodeStubInterface, args []string) pb.Response {

      //   0
      // "queryString"
      if len(args) < 3 {
              return shim.Error("Incorrect number of arguments. Expecting 3")
      }

      queryString := args[0]
      //return type of ParseInt is int64
      pageSize, err := strconv.ParseInt(args[1], 10, 32)
      if err != nil {
              return shim.Error(err.Error())
      }
      bookmark := args[2]

      queryResults, err := getQueryResultForQueryStringWithPagination(stub, queryString, int32(pageSize), bookmark)
      if err != nil {
              return shim.Error(err.Error())
      }
      return shim.Success(queryResults)
}

The following example is a peer command which calls queryMarblesWithPagination
with a pageSize of 3 and no bookmark specified.

Tip
When no bookmark is specified, the query starts with the “first”
page of records.

Try it yourself
// Rich Query with index name explicitly specified and a page size of 3:
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarblesWithPagination", "{\"selector\":{\"docType\":\"marble\",\"owner\":\"tom\"}, \"use_index\":[\"_design/indexOwnerDoc\", \"indexOwner\"]}","3",""]}'

The following response is received (carriage returns added for clarity), three
of the five marbles are returned because the pagsize was set to 3:
[{"Key":"marble1", "Record":{"color":"blue","docType":"marble","name":"marble1","owner":"tom","size":35}},
 {"Key":"marble2", "Record":{"color":"yellow","docType":"marble","name":"marble2","owner":"tom","size":35}},
 {"Key":"marble3", "Record":{"color":"green","docType":"marble","name":"marble3","owner":"tom","size":20}}]
[{"ResponseMetadata":{"RecordsCount":"3",
"Bookmark":"g1AAAABLeJzLYWBgYMpgSmHgKy5JLCrJTq2MT8lPzkzJBYqz5yYWJeWkGoOkOWDSOSANIFk2iCyIyVySn5uVBQAGEhRz"}}]

Note
Bookmarks are uniquely generated by CouchDB for each query and
represent a placeholder in the result set. Pass the
returned bookmark on the subsequent iteration of the query to
retrieve the next set of results.

The following is a peer command to call queryMarblesWithPagination with a
pageSize of 3. Notice this time, the query includes the bookmark returned
from the previous query.
Try it yourself
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarblesWithPagination", "{\"selector\":{\"docType\":\"marble\",\"owner\":\"tom\"}, \"use_index\":[\"_design/indexOwnerDoc\", \"indexOwner\"]}","3","g1AAAABLeJzLYWBgYMpgSmHgKy5JLCrJTq2MT8lPzkzJBYqz5yYWJeWkGoOkOWDSOSANIFk2iCyIyVySn5uVBQAGEhRz"]}'

The following response is received (carriage returns added for clarity).  The
last two records are retrieved:
[{"Key":"marble4", "Record":{"color":"purple","docType":"marble","name":"marble4","owner":"tom","size":20}},
 {"Key":"marble5", "Record":{"color":"blue","docType":"marble","name":"marble5","owner":"tom","size":40}}]
[{"ResponseMetadata":{"RecordsCount":"2",
"Bookmark":"g1AAAABLeJzLYWBgYMpgSmHgKy5JLCrJTq2MT8lPzkzJBYqz5yYWJeWkmoKkOWDSOSANIFk2iCyIyVySn5uVBQAGYhR1"}}]

The final command is a peer command to call queryMarblesWithPagination with
a pageSize of 3 and with the bookmark from the previous query.
Try it yourself
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarblesWithPagination", "{\"selector\":{\"docType\":\"marble\",\"owner\":\"tom\"}, \"use_index\":[\"_design/indexOwnerDoc\", \"indexOwner\"]}","3","g1AAAABLeJzLYWBgYMpgSmHgKy5JLCrJTq2MT8lPzkzJBYqz5yYWJeWkmoKkOWDSOSANIFk2iCyIyVySn5uVBQAGYhR1"]}'

The following response is received (carriage returns added for clarity).
No records are returned, indicating that all pages have been retrieved:
[]
[{"ResponseMetadata":{"RecordsCount":"0",
"Bookmark":"g1AAAABLeJzLYWBgYMpgSmHgKy5JLCrJTq2MT8lPzkzJBYqz5yYWJeWkmoKkOWDSOSANIFk2iCyIyVySn5uVBQAGYhR1"}}]

For an example of how a client application can iterate over
the result sets using pagination, search for the getQueryResultForQueryStringWithPagination
function in the Marbles sample.

Update an Index¶
It may be necessary to update an index over time. The same index may exist in
subsequent versions of the chaincode that gets installed. In order for an index
to be updated, the original index definition must have included the design
document ddoc attribute and an index name. To update an index definition,
use the same index name but alter the index definition. Simply edit the index
JSON file and add or remove fields from the index. Fabric only supports the
index type JSON. Changing the index type is not supported. The updated
index definition gets redeployed to the peer’s state database when the chaincode
definition is committed to the channel. Changes to the index name or ddoc
attributes will result in a new index being created and the original index remains
unchanged in CouchDB until it is removed.

Note
If the state database has a significant volume of data, it will take
some time for the index to be re-built, during which time chaincode
invokes that issue queries may fail or timeout.

Iterating on your index definition¶
If you have access to your peer’s CouchDB state database in a development
environment, you can iteratively test various indexes in support of
your chaincode queries. Any changes to chaincode though would require
redeployment. Use the CouchDB Fauxton interface or a command
line curl utility to create and update indexes.

Note
The Fauxton interface is a web UI for the creation, update, and
deployment of indexes to CouchDB. If you want to try out this
interface, there is an example of the format of the Fauxton version
of the index in Marbles sample. If you have deployed the test network
with CouchDB, the Fauxton interface can be loaded by opening a browser
and navigating to http://localhost:5984/_utils.

Alternatively, if you prefer not use the Fauxton UI, the following is an example
of a curl command which can be used to create the index on the database
mychannel_marbles:
// Index for docType, owner.
// Example curl command line to define index in the CouchDB channel_chaincode database
 curl -i -X POST -H "Content-Type: application/json" -d
        "{\"index\":{\"fields\":[\"docType\",\"owner\"]},
          \"name\":\"indexOwner\",
          \"ddoc\":\"indexOwnerDoc\",
          \"type\":\"json\"}" http://hostname:port/mychannel_marbles/_index

Note
If you are using the test network configured with CouchDB, replace
hostname:port with localhost:5984.

Delete an Index¶
Index deletion is not managed by Fabric tooling. If you need to delete an index,
manually issue a curl command against the database or delete it using the
Fauxton interface.
The format of the curl command to delete an index would be:
curl -X DELETE http://localhost:5984/{database_name}/_index/{design_doc}/json/{index_name} -H  "accept: */*" -H  "Host: localhost:5984"

To delete the index used in this tutorial, the curl command would be:
curl -X DELETE http://localhost:5984/mychannel_marbles/_index/indexOwnerDoc/json/indexOwner -H  "accept: */*" -H  "Host: localhost:5984"

Creating a channel¶
In order to create and transfer assets on a Hyperledger Fabric network, an
organization needs to join a channel. Channels are a private layer of communication
between specific organizations and are invisible to other members of the network.
Each channel consists of a separate ledger that can only be read and written to
by channel members, who are allowed to join their peers to the channel and receive
new blocks of transactions from the ordering service. While the peers, nodes, and
Certificate Authorities form the physical infrastructure of the network, channels
are the process by which organizations connect with each other and interact.
Because of the fundamental role that channels play in the operation and governance
of Fabric, we provide a series of tutorials that will cover different aspects
of how channels are created. The Creating a new channel tutorial describes the
operational steps that need to be taken by a network administrator. The
Using configtx.yaml to build a channel configuration tutorial introduces the conceptual aspects of creating
a channel, followed by a separate discussion of Channel policies.

Creating a new channel¶
You can use this tutorial to learn how to create new channels using the configtxgen CLI tool and then use the peer channel commands to join a channel with your peers. While this tutorial will leverage the Fabric test network to create the new channel, the steps in this tutorial can also be used by network operators in a production environment.
In the process of creating the channel, this tutorial will take you through the following steps and concepts:

Setting up the configtxgen tool
Using the configtx.yaml file
The orderer system channel
Creating an application channel
Joining peers to the channel
Setting anchor peers

Setting up the configtxgen tool¶
Channels are created by building a channel creation transaction and submitting the transaction to the ordering service. The channel creation transaction specifies the initial configuration of the channel and is used by the ordering service to write the channel genesis block. While it is possible to build the channel creation transaction file manually, it is easier to use the configtxgen tool. The tool works by reading a configtx.yaml file that defines the configuration of your channel, and then writing the relevant information into the channel creation transaction. Before we discuss the configtx.yaml file in the next section, we can get started by downloading and setting up the configtxgen tool.
You can download the configtxgen binaries by following the steps to install the samples, binaries and Docker images. configtxgen will be downloaded to the bin folder of your local clone of the fabric-samples repository along with other Fabric tools.
For the purposes of this tutorial, we will want to operate from the test-network directory inside fabric-samples. Navigate to that directory using the following command:
cd fabric-samples/test-network

We will operate from the test-network directory for the remainder of the tutorial. Use the following command to add the configtxgen tool to your CLI path:
export PATH=${PWD}/../bin:$PATH

In order to use configtxgen, you need to the set the FABRIC_CFG_PATH environment variable to the path of the directory that contains your local copy of the configtx.yaml file. For this tutorial, we will reference the configtx.yaml used to setup the Fabric test network in the configtx folder:
export FABRIC_CFG_PATH=${PWD}/configtx

You can check that you can are able to use the tool by printing the configtxgen help text:
configtxgen --help

The configtx.yaml file¶
The configtx.yaml file specifies the channel configuration of new channels. The information that is required to build the channel configuration is specified in a readable and editable form in the configtx.yaml file. The configtxgen tool uses the channel profiles defined in the configtx.yaml file to create the channel configuration and write it to the protobuf format that can be read by Fabric.
You can find the configtx.yaml file that is used to deploy the test network in the configtx folder in the test-network directory. The file contains the following information that we will use to create our new channel:

Organizations: The organizations that can become members of your channel. Each organization has a reference to the cryptographic material that is used to build the channel MSP.

Ordering service: Which ordering nodes will form the ordering service of the network, and consensus method they will use to agree to a common order of transactions. The file also contains the organizations that will become the ordering service administrators.

Channel policies Different sections of the file work together to define the policies that will govern how organizations interact with the channel and which organizations need to approve channel updates. For the purposes of this tutorial, we will use the default policies used by Fabric.

Channel profiles Each channel profile references information from other sections of the configtx.yaml file to build a channel configuration. The profiles are used the create the genesis block of the orderer system channel and the channels that will be used by peer organizations. To distinguish them from the system channel, the channels used by peer organizations are often referred to as application channels.
The configtxgen tool uses configtx.yaml file to create a complete genesis block for the system channel. As a result, the system channel profile needs to specify the full system channel configuration. The channel profile used to create the channel creation transaction only needs to contain the additional configuration information required to create an application channel.

You can visit the Using configtx.yaml to create a channel genesis block tutorial to learn more about this file. For now, we will return to the operational aspects of creating the channel, though we will reference parts of this file in future steps.

Start the network¶
We will use a running instance of the Fabric test network to create the new channel. For the sake of this tutorial, we want to operate from a known initial state. The following command will kill any active containers and remove any previously generated artifacts. Make sure that you are still operating from the test-network directory of your local clone of fabric-samples.
./network.sh down

You can then use the following command to start the test network:
./network.sh up

This command will create a Fabric network with the two peer organizations and the single ordering organization defined in the configtx.yaml file. The peer organizations will operate one peer each, while the ordering service administrator will operate a single ordering node. When you run the command, the script will print out logs of the nodes being created:
Creating network "net_test" with the default driver
Creating volume "net_orderer.example.com" with default driver
Creating volume "net_peer0.org1.example.com" with default driver
Creating volume "net_peer0.org2.example.com" with default driver
Creating orderer.example.com    ... done
Creating peer0.org2.example.com ... done
Creating peer0.org1.example.com ... done
CONTAINER ID        IMAGE                               COMMAND             CREATED             STATUS                  PORTS                              NAMES
8d0c74b9d6af        hyperledger/fabric-orderer:latest   "orderer"           4 seconds ago       Up Less than a second   0.0.0.0:7050->7050/tcp             orderer.example.com
ea1cf82b5b99        hyperledger/fabric-peer:latest      "peer node start"   4 seconds ago       Up Less than a second   0.0.0.0:7051->7051/tcp             peer0.org1.example.com
cd8d9b23cb56        hyperledger/fabric-peer:latest      "peer node start"   4 seconds ago       Up 1 second             7051/tcp, 0.0.0.0:9051->9051/tcp   peer0.org2.example.com

Our instance of the test network was deployed without creating an application channel. However, the test network script creates the system channel when you issue the ./network.sh up command. Under the covers, the script uses the configtxgen tool and the configtx.yaml file to build the genesis block of the system channel.  Because the system channel is used to create other channels, we need to take some time to understand the orderer system channel before we can create an application channel.

The orderer system channel¶
The first channel that is created in a Fabric network is the system channel. The system channel defines the set of ordering nodes that form the ordering service and the set of organizations that serve as ordering service administrators.
The system channel also includes the organizations that are members of blockchain consortium.
The consortium is a set of peer organizations that belong to the system channel, but are not administrators of the ordering service. Consortium members have the ability to create new channels and include other consortium organizations as channel members.
The genesis block of the system channel is required to deploy a new ordering service. The test network script already created the system channel genesis block when you issued the ./network.sh up command. The genesis block was used to deploy the single ordering node, which used the block to create the system channel and form the ordering service of the network. If you examine the output of the ./network.sh script, you can find the command that created the genesis block in your logs:
configtxgen -profile TwoOrgsOrdererGenesis -channelID system-channel -outputBlock ./system-genesis-block/genesis.block

The configtxgen tool used the TwoOrgsOrdererGenesis channel profile from configtx.yaml to write the genesis block and store it in the system-genesis-block folder. You can see the TwoOrgsOrdererGenesis profile below:
TwoOrgsOrdererGenesis:
    <<: *ChannelDefaults
    Orderer:
        <<: *OrdererDefaults
        Organizations:
            - *OrdererOrg
        Capabilities:
            <<: *OrdererCapabilities
    Consortiums:
        SampleConsortium:
            Organizations:
                - *Org1
                - *Org2

The Orderer: section of the profile creates the single node Raft ordering service used by the test network, with the OrdererOrg as the ordering service administrator. The Consortiums section of the profile creates a consortium of peer organizations named SampleConsortium:. Both peer organizations, Org1 and Org2, are members of the consortium. As a result, we can include both organizations in new channels created by the test network. If we wanted to add another organization as a channel member without adding that organization to the consortium, we would first need to create the channel with Org1 and Org2, and then add the other organization by updating the channel configuration.

Creating an application channel¶
Now that we have deployed the nodes of the network and created the orderer system channel using the network.sh script, we can start the process of creating a new channel for our peer organizations. We have already set the environment variables that are required to use the configtxgen tool. Run the following command to create a channel creation transaction for channel1:
configtxgen -profile TwoOrgsChannel -outputCreateChannelTx ./channel-artifacts/channel1.tx -channelID channel1

The -channelID will be the name of the future channel. Channel names must be all lower case, less than 250 characters long and match the regular expression [a-z][a-z0-9.-]*. The command uses the uses the -profile flag to reference the TwoOrgsChannel: profile from configtx.yaml that is used by the test network to create application channels:
TwoOrgsChannel:
    Consortium: SampleConsortium
    <<: *ChannelDefaults
    Application:
        <<: *ApplicationDefaults
        Organizations:
            - *Org1
            - *Org2
        Capabilities:
            <<: *ApplicationCapabilities

The profile references the name of the SampleConsortium from the system channel, and includes both peer organizations from the consortium as channel members. Because the system channel is used as a template to create the application channel, the ordering nodes defined in the system channel become the default consenter set of the new channel, while the administrators of the ordering service become the orderer administrators of the channel. Ordering nodes and ordering organizations can be added or removed from the consenter set using channel updates.
If the command successful, you will see logs of configtxgen loading the configtx.yaml file and printing a channel creation transaction:
2020-03-11 16:37:12.695 EDT [common.tools.configtxgen] main -> INFO 001 Loading configuration
2020-03-11 16:37:12.738 EDT [common.tools.configtxgen.localconfig] Load -> INFO 002 Loaded configuration: /Usrs/fabric-samples/test-network/configtx/configtx.yaml
2020-03-11 16:37:12.740 EDT [common.tools.configtxgen] doOutputChannelCreateTx -> INFO 003 Generating new channel configtx
2020-03-11 16:37:12.789 EDT [common.tools.configtxgen] doOutputChannelCreateTx -> INFO 004 Writing new channel tx

We can use the peer CLI to submit the channel creation transaction to the ordering service. To use the peer CLI, we need to set the FABRIC_CFG_PATH to the core.yaml file located in the fabric-samples/config directory. Set the FABRIC_CFG_PATH environment variable by running the following command:
export FABRIC_CFG_PATH=$PWD/../config/

Before the ordering service creates the channel, the ordering service will check the permission of the identity that submitted the request. By default, only admin identities of organizations that belong to the system channel consortium can create a new channel. Issue the commands below to operate the peer CLI as the admin user from Org1:
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

You can now create the channel by using the following command:
peer channel create -o localhost:7050  --ordererTLSHostnameOverride orderer.example.com -c channel1 -f ./channel-artifacts/channel1.tx --outputBlock ./channel-artifacts/channel1.block --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

The command above provides the path to the channel creation transaction file using the -f flag and uses the -c flag to specify the channel name. The -o flag is used to select the ordering node that will be used to create the channel. The --cafile is the path to the TLS certificate of the ordering node. When you run the peer channel create command, the peer CLI will generate the following response:
2020-03-06 17:33:49.322 EST [channelCmd] InitCmdFactory -> INFO 00b Endorser and orderer connections initialized
2020-03-06 17:33:49.550 EST [cli.common] readBlock -> INFO 00c Received block: 0

Because we are using a Raft ordering service, you may get some status unavailable messages that you can safely ignore. The command will return the genesis block of the new channel to the location specified by the --outputBlock flag.

Join peers to the channel¶
After the channel has been created, we can join the channel with our peers. Organizations that are members of the channel can fetch the channel genesis block from the ordering service using the peer channel fetch command. The organization can then use the genesis block to join the peer to the channel using the peer channel join command. Once the peer is joined to the channel, the peer will build the blockchain ledger by retrieving the other blocks on the channel from the ordering service.
Since we are already operating the peer CLI as the Org1 admin, let’s join the Org1 peer to the channel. Since Org1 submitted the channel creation transaction, we already have the channel genesis block on our file system. Join the Org1 peer to the channel using the command below.
peer channel join -b ./channel-artifacts/channel1.block

The CORE_PEER_ADDRESS environment variable has been set to target peer0.org1.example.com. A successful command will generate a response from peer0.org1.example.com joining the channel:
2020-03-06 17:49:09.903 EST [channelCmd] InitCmdFactory -> INFO 001 Endorser and orderer connections initialized
2020-03-06 17:49:10.060 EST [channelCmd] executeJoin -> INFO 002 Successfully submitted proposal to join channel

You can verify that the peer has joined the chanel using the peer channel getinfo command:
peer channel getinfo -c channel1

The command will list the block height of the channel and the hash of the most recent block. Because the genesis block is the only block on the channel, the height of the channel will be 1:
2020-03-13 10:50:06.978 EDT [channelCmd] InitCmdFactory -> INFO 001 Endorser and orderer connections initialized
Blockchain info: {"height":1,"currentBlockHash":"kvtQYYEL2tz0kDCNttPFNC4e6HVUFOGMTIDxZ+DeNQM="}

We can now join the Org2 peer to the channel. Set the following environment variables to operate the peer CLI as the Org2 admin. The environment variables will also set the Org2 peer, peer0.org1.example.com, as the target peer.
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

While we still have the channel genesis block on our file system, in a more realistic scenario, Org2 would have the fetch the block from the ordering service. As an example, we will use the peer channel fetch command to get the genesis block for Org2:
peer channel fetch 0 ./channel-artifacts/channel_org2.block -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com -c channel1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

The command uses 0 to specify that it needs to fetch the genesis block that is required to join the channel. If the command is successful, you should see the following output:
2020-03-13 11:32:06.309 EDT [channelCmd] InitCmdFactory -> INFO 001 Endorser and orderer connections initialized
2020-03-13 11:32:06.336 EDT [cli.common] readBlock -> INFO 002 Received block: 0

The command returns the channel genesis block and names it channel_org2.block to distinguish it from the block pulled by org1. You can now use the block to join the Org2 peer to the channel:
peer channel join -b ./channel-artifacts/channel_org2.block

Set anchor peers¶
After an organizations has joined their peers to the channel, they should select at least one of their peers to become an anchor peer. Anchor peers are required in order to take advantage of features such as private data and service discovery. Each organization should set multiple anchor peers on a channel for redundancy. For more information about gossip and anchor peers, see the Gossip data dissemination protocol.
The endpoint information of the anchor peers of each organization is included in the channel configuration. Each channel member can specify their anchor peers by updating the channel. We will use the configtxlator tool to update the channel configuration and select an anchor peer for Org1 and Org2. The process for setting an anchor peer is similar to the steps that are required to make other channel updates and provides an introduction to how to use configtxlator to update a channel configuration. You will also need to install the jq tool on your local machine.
We will start by selecting an anchor peer as Org1. The first step is to pull the most recent channel configuration block using the peer channel fetch command. Set the following environment variables to operate the peer CLI as the Org1 admin:
export FABRIC_CFG_PATH=$PWD/../config/
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=localhost:7051

You can use the following command to fetch the channel configuration:
peer channel fetch config channel-artifacts/config_block.pb -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com -c channel1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Because the most recent channel configuration block is the channel genesis block, you will see the command return block 0 from the channel.
2020-04-15 20:41:56.595 EDT [channelCmd] InitCmdFactory -> INFO 001 Endorser and orderer connections initialized
2020-04-15 20:41:56.603 EDT [cli.common] readBlock -> INFO 002 Received block: 0
2020-04-15 20:41:56.603 EDT [channelCmd] fetch -> INFO 003 Retrieving last config block: 0
2020-04-15 20:41:56.608 EDT [cli.common] readBlock -> INFO 004 Received block: 0

The channel configuration block was stored in the channel-artifacts folder to keep the update process separate from other artifacts. Change into the  channel-artifacts folder to complete the next steps:
cd channel-artifacts

We can now start using the configtxlator tool to start working with the channel configuration. The first step is to decode the block from protobuf into a JSON object that can be read and edited. We also strip away the unnecessary block data, leaving only the channel configuration.
configtxlator proto_decode --input config_block.pb --type common.Block --output config_block.json
jq .data.data[0].payload.data.config config_block.json > config.json

These commands convert the channel configuration block into a streamlined JSON, config.json, that will serve as the baseline for our update. Because we don’t want to edit this file directly, we will make a copy that we can edit. We will use the original channel config in a future step.
cp config.json config_copy.json

You can use the jq tool to add the Org1 anchor peer to the channel configuration.
jq '.channel_group.groups.Application.groups.Org1MSP.values += {"AnchorPeers":{"mod_policy": "Admins","value":{"anchor_peers": [{"host": "peer0.org1.example.com","port": 7051}]},"version": "0"}}' config_copy.json > modified_config.json

After this step, we have an updated version of channel configuration in JSON format in the modified_config.json file. We can now convert both the original and modified channel configurations back into protobuf format and calculate the difference between them.
configtxlator proto_encode --input config.json --type common.Config --output config.pb
configtxlator proto_encode --input modified_config.json --type common.Config --output modified_config.pb
configtxlator compute_update --channel_id channel1 --original config.pb --updated modified_config.pb --output config_update.pb

The new protobuf named channel_update.pb contains the anchor peer update that we need to apply to the channel configuration. We can wrap the configuration update in a transaction envelope to create the channel configuration update transaction.
configtxlator proto_decode --input config_update.pb --type common.ConfigUpdate --output config_update.json
echo '{"payload":{"header":{"channel_header":{"channel_id":"channel1", "type":2}},"data":{"config_update":'$(cat config_update.json)'}}}' | jq . > config_update_in_envelope.json
configtxlator proto_encode --input config_update_in_envelope.json --type common.Envelope --output config_update_in_envelope.pb

We can now use the final artifact, config_update_in_envelope.pb, that can be used to update the channel. Navigate back to the test-network directory:
cd ..

We can add the anchor peer by providing the new channel configuration to the peer channel update command. Because we are updating a section of the channel configuration that only affects Org1, other channel members do not need to approve the channel update.
peer channel update -f channel-artifacts/config_update_in_envelope.pb -c channel1 -o localhost:7050  --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

When the channel update is successful, you should see the following response:
2020-01-09 21:30:45.791 UTC [channelCmd] update -> INFO 002 Successfully submitted channel update

We can set the anchor peers for Org2. Because we are going through the process a second time, we will go through the steps more quickly. Set the environment variables to operate the peer CLI as the Org2 admin:
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=localhost:9051

Pull the latest channel configuration block, which is now the second block on the channel:
peer channel fetch config channel-artifacts/config_block.pb -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com -c channel1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Navigate back to the channel-artifacts directory:
cd channel-artifacts

You can then decode and copy the configuration block.
configtxlator proto_decode --input config_block.pb --type common.Block --output config_block.json
jq .data.data[0].payload.data.config config_block.json > config.json
cp config.json config_copy.json

Add the Org2 peer that is joined to the channel as the anchor peer in the channel configuration:
jq '.channel_group.groups.Application.groups.Org2MSP.values += {"AnchorPeers":{"mod_policy": "Admins","value":{"anchor_peers": [{"host": "peer0.org2.example.com","port": 9051}]},"version": "0"}}' config_copy.json > modified_config.json

We can now convert both the original and updated channel configurations back into protobuf format and calculate the difference between them.
configtxlator proto_encode --input config.json --type common.Config --output config.pb
configtxlator proto_encode --input modified_config.json --type common.Config --output modified_config.pb
configtxlator compute_update --channel_id channel1 --original config.pb --updated modified_config.pb --output config_update.pb

Wrap the configuration update in a transaction envelope to create the channel configuration update transaction:
configtxlator proto_decode --input config_update.pb --type common.ConfigUpdate --output config_update.json
echo '{"payload":{"header":{"channel_header":{"channel_id":"channel1", "type":2}},"data":{"config_update":'$(cat config_update.json)'}}}' | jq . > config_update_in_envelope.json
configtxlator proto_encode --input config_update_in_envelope.json --type common.Envelope --output config_update_in_envelope.pb

Navigate back to the test-network directory.
cd ..

Update the channel and set the Org2 anchor peer by issuing the following command:
peer channel update -f channel-artifacts/config_update_in_envelope.pb -c channel1 -o localhost:7050  --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

You can confirm that the channel has been updated successfully by running the peer channel info command:
peer channel getinfo -c channel1

Now that the channel has been updated by adding two channel configuration blocks to the channel genesis block, the height of the channel will have grown to three:
Blockchain info: {"height":3,"currentBlockHash":"eBpwWKTNUgnXGpaY2ojF4xeP3bWdjlPHuxiPCTIMxTk=","previousBlockHash":"DpJ8Yvkg79XHXNfdgneDb0jjQlXLb/wxuNypbfHMjas="}

Deploy a chaincode to the new channel¶
We can confirm that the channel was created successfully by deploying a chaincode to the channel. We can use the network.sh script to deploy the Fabcar chaincode to any test network channel. Deploy a chaincode to our new channel using the following command:
./network.sh deployCC -c channel1

After you run the command, you should see the chaincode being deployed to the channel in your logs. The chaincode is invoked to add data to the channel ledger and then queried.
[{"Key":"CAR0","Record":{"make":"Toyota","model":"Prius","colour":"blue","owner":"Tomoko"}},
{"Key":"CAR1","Record":{"make":"Ford","model":"Mustang","colour":"red","owner":"Brad"}},
{"Key":"CAR2","Record":{"make":"Hyundai","model":"Tucson","colour":"green","owner":"Jin Soo"}},
{"Key":"CAR3","Record":{"make":"Volkswagen","model":"Passat","colour":"yellow","owner":"Max"}},
{"Key":"CAR4","Record":{"make":"Tesla","model":"S","colour":"black","owner":"Adriana"}},
{"Key":"CAR5","Record":{"make":"Peugeot","model":"205","colour":"purple","owner":"Michel"}},
{"Key":"CAR6","Record":{"make":"Chery","model":"S22L","colour":"white","owner":"Aarav"}},
{"Key":"CAR7","Record":{"make":"Fiat","model":"Punto","colour":"violet","owner":"Pari"}},
{"Key":"CAR8","Record":{"make":"Tata","model":"Nano","colour":"indigo","owner":"Valeria"}},
{"Key":"CAR9","Record":{"make":"Holden","model":"Barina","colour":"brown","owner":"Shotaro"}}]
===================== Query successful on peer0.org1 on channel 'channel1' =====================

Using configtx.yaml to build a channel configuration¶
A channel is created by building a channel creation transaction artifact that specifies the initial configuration of the channel. The channel configuration is stored on the ledger, and governs all the subsequent blocks that are added to the channel. The channel configuration specifies which organizations are channel members, the ordering nodes that can add new blocks on the channel, as well as the policies that govern channel updates. The initial channel configuration, stored in the channel genesis block, can be updated through channel configuration updates. If a sufficient number of organizations approve a channel update, a new channel config block will govern the channel after it is committed to the channel.
While it is possible to build the channel creation transaction file manually, it is easier to create a channel by using the configtx.yaml file and the configtxgen tool. The configtx.yaml file contains the information that is required to build the channel configuration in a format that can be easily read and edited by humans. The configtxgen tool reads the information in the configtx.yaml file and writes it to the protobuf format that can be read by Fabric.

Overview¶
You can use this tutorial to learn how to use the configtx.yaml file to build the initial channel configuration that is stored in the genesis block. The tutorial will discuss the portion of channel configuration that is built by each section of file.

Organizations
Capabilities
Application
Orderer
Channel
Profiles

Because different sections of the file work together to create the policies that govern the channel, we will discuss channel policies in their own tutorial.
Building off of the Creating a channel tutorial, we will use the configtx.yaml file that is used to deploy the Fabric test network as an example. Open a command terminal on your local machine and navigate to the test-network directory in your local clone of the Fabric samples:
cd fabric-samples/test-network

The configtx.yaml file used by the test network is located in the configtx folder. Open the file in a text editor. You can refer back to this file as the tutorial goes through each section. You can find a more detailed version of the configtx.yaml file in the Fabric sample configuration.

Organizations¶
The most important information contained in the channel configuration are the organizations that are channel members.  Each organization is identified by an MSP ID and a channel MSP. The channel MSP is stored in the channel configuration and contains the certificates that are used to the identify the nodes, applications, and administrators of an organization. The Organizations section of configtx.yaml file is used to create the channel MSP and accompanying MSP ID for each member of the channel.
The configtx.yaml file used by the test network contains three organizations. Two organizations are peer organizations, Org1 and Org2, that can be added to application channels. One organization, OrdererOrg, is the administrator of the ordering service. Because it is a best practice to use different certificate authorities to deploy peer nodes and ordering nodes, organizations are often referred to as peer organizations or ordering organizations, even if they are in fact run by the same company.
You can see the part of configtx.yaml that defines Org1 of the test network below:
- &Org1
    # DefaultOrg defines the organization which is used in the sampleconfig
    # of the fabric.git development environment
    Name: Org1MSP

    # ID to load the MSP definition as
    ID: Org1MSP

    MSPDir: ../organizations/peerOrganizations/org1.example.com/msp

    # Policies defines the set of policies at this level of the config tree
    # For organization policies, their canonical path is usually
    #   /Channel/<Application|Orderer>/<OrgName>/<PolicyName>
    Policies:
        Readers:
            Type: Signature
            Rule: "OR('Org1MSP.admin', 'Org1MSP.peer', 'Org1MSP.client')"
        Writers:
            Type: Signature
            Rule: "OR('Org1MSP.admin', 'Org1MSP.client')"
        Admins:
            Type: Signature
            Rule: "OR('Org1MSP.admin')"
        Endorsement:
            Type: Signature
            Rule: "OR('Org1MSP.peer')"

    # leave this flag set to true.
    AnchorPeers:
        # AnchorPeers defines the location of peers which can be used
        # for cross org gossip communication.  Note, this value is only
        # encoded in the genesis block in the Application section context
        - Host: peer0.org1.example.com
          Port: 7051

The Name field is an informal name used to identify the organization.

The ID field is the organization’s MSP ID. The MSP ID acts as a unique identifier for your organization, and is referred to by channel policies and is included in the transactions submitted to the channel.

The MSPDir is the path to an MSP folder that was created by the organization. The configtxgen tool will use this MSP folder to create the channel MSP. This MSP folder needs to contain the following information, which will be transferred to the channel MSP and stored in the channel configuration:

A CA root certificate that establishes the root of trust for the organization. The CA root cert is used to verify if an application, node, or administrator belongs to a channel member.
A root cert from the TLS CA that issued the TLS certificates of the peer or orderer nodes. The TLS root cert is used to identify the organization by the gossip protocol.
If Node OUs are enabled, the MSP folder needs to contain a config.yaml file that identifies the administrators, nodes, and clients based on the OUs of their x509 certificates.
If Node OUs are not enabled, the MSP needs to contain an admincerts folder that contains the signing certificates of the organizations administrator identities.

The MSP folder that is used to create the channel MSP only contains public certificates. As a result, you can build the MSP folder locally, and then send the MSP to the organization that is creating the channel.

The Policies section is used to define a set of signature policies that reference the channel member. We will discuss these policies in more detail when we discuss channel policies.

The AnchorPeers field lists the anchor peers for an organization. Anchor peers are required in order to take advantage of features such as private data and service discovery. It is recommended that organizations select at least one anchor peer. While an organization can select their anchor peers on the channel for the first time using the configtxgen tool, it is recommended that each organization set anchor peers by using the configtxlator tool to update the channel configuration. As a result, this field is not required.

Capabilities¶
Fabric channels can be joined by orderer and peer nodes that are running different versions of Hyperledger Fabric. Channel capabilities allow organizations that are running different Fabric binaries to participate on the same channel by only enabling certain features. For example, organizations that are running Fabric v1.4 and organizations that are running Fabric v2.x can join the same channel as long as the channel capabilities levels are set to V1_4_X or below. None of the channel members will be able to use the features introduced in Fabric v2.0.
If you examine the configtx.yaml file, you will see three capability groups:

Application capabilities govern the features that are used by peer nodes, such as the Fabric chaincode lifecycle, and set the minimum version of the Fabric binaries that can be run by peers joined to the channel.
Orderer capabilities govern the features that are used by orderer nodes, such as Raft consensus, and set the minimum version of the Fabric binaries that can be run by ordering nodes that belong to the channel consenter set.
Channel capabilities set the minimum version of the Fabric that can be run by peer and ordering nodes.

Because both of the peers and the ordering node of the Fabric test network run version v2.x, every capability group is set to V2_0. As a result, the test network cannot be joined by nodes that run a lower version of Fabric than v2.0. For more information, see the capabilities concept topic.

Application¶
The application section defines the policies that govern how peer organizations can interact with application channels. These policies govern the number of peer organizations that need to approve a chaincode definition or sign a request to update the channel configuration. These policies are also used to restrict access to channel resources, such as the ability to write to the channel ledger or to query channel events.
The test network uses the default application policies provided by Hyperledger Fabric. If you use the default policies, all peer organizations will be able to read and write data to the ledger. The default policies also require that a majority of channel members sign channel configuration updates and that a majority of channel members need to approve a chaincode definition before a chaincode can be deployed to a channel. The contents of this section are discussed in more detail in the channel policies tutorial.

Orderer¶
Each channel configuration includes the orderer nodes in the channel consenter set. The consenter set is the group of ordering nodes that have the ability to create new blocks and distribute them to the peers joined to the channel. The endpoint information of each ordering node that is a member of the consenter set is stored in the channel configuration.
The test network uses the Orderer section of the configtx.yaml file to create a single node Raft ordering service.

The OrdererType field is used to select Raft as the consensus type:
OrdererType: etcdraft

Raft ordering services are defined by the list of consenters that can participate in the consensus process. Because the test network only uses a single ordering node, the consenters list contains only one endpoint:
EtcdRaft:
    Consenters:
    - Host: orderer.example.com
      Port: 7050
      ClientTLSCert: ../organizations/ordererOrganizations/example.com/orderers/orderer.example.com/tls/server.crt
      ServerTLSCert: ../organizations/ordererOrganizations/example.com/orderers/orderer.example.com/tls/server.crt
    Addresses:
    - orderer.example.com:7050

Each ordering node in the list of consenters is identified by their endpoint address and their client and server TLS certificate. If you are deploying a multi-node ordering service, you would need to provide the hostname, port, and the path to the TLS certificates used by each node. You would also need to add the endpoint address of each ordering node to the list of Addresses.

You can use the BatchTimeout and BatchSize fields to tune the latency and throughput of the channel by changing the maximum size of each block and how often a new block is created.

The Policies section creates the policies that govern the channel consenter set. The test network uses the default policies provided by Fabric, which require that a majority of orderer administrators approve the addition or removal of ordering nodes, organizations, or an update to the block cutting parameters.

Because the test network is used for development and testing, it uses an ordering service that consists of a single ordering node. Networks that are deployed in production should use a multi-node ordering service for security and availability. To learn more, see Configuring and operating a Raft ordering service.

Channel¶
The channel section defines that policies that govern the highest level of the channel configuration. For an application channel, these policies govern the hashing algorithm, the data hashing structure used to create new blocks, and the channel capability level. In the system channel, these policies also govern the creation or removal of consortiums of peer organizations.
The test network uses the default policies provided by Fabric, which require that a majority of orderer service administrators would need to approve updates to these values in the system channel. In an application channel, changes would need to be approved by a majority of orderer organizations and a majority of channel members. Most users will not need to change these values.

Profiles¶
The configtxgen tool reads the channel profiles in the Profiles section to build a channel configuration. Each profile uses YAML syntax to gather data from other sections of the file. The configtxgen tool uses this configuration to create a channel creation transaction for an applications channel, or to write the channel genesis block for a system channel. To learn more about YAML syntax, Wikipedia provides a good place to get started.
The configtx.yaml used by the test network contains two channel profiles, TwoOrgsOrdererGenesis and TwoOrgsChannel:

TwoOrgsOrdererGenesis¶
The TwoOrgsOrdererGenesis profile is used to create the system channel genesis block:
TwoOrgsOrdererGenesis:
    <<: *ChannelDefaults
    Orderer:
        <<: *OrdererDefaults
        Organizations:
            - *OrdererOrg
        Capabilities:
            <<: *OrdererCapabilities
    Consortiums:
        SampleConsortium:
            Organizations:
                - *Org1
                - *Org2

The system channel defines the nodes of the ordering service and the set of organizations that are ordering service administrators. The system channel also includes a set of peer organizations that belong to the blockchain consortium. The channel MSP of each member of the consortium is included in the system channel, allowing them to create new application channels and add consortium members to the new channel.
The profile creates a consortium named SampleConsortium that contains the two peer organizations in the configtx.yaml file, Org1 and Org2. The Orderer section of the profile uses the single node Raft ordering service defined in the Orderer: section of the file. The OrdererOrg from the Organizations: section is made the only administrator of the ordering service. Because our only ordering node is running Fabric 2.x, we can set the orderer system channel capability to V2_0. The system channel uses default policies from the Channel section and enables V2_0 as the channel capability level.

TwoOrgsChannel¶
The TwoOrgsChannel profile is used by the test network to create application channels:
TwoOrgsChannel:
    Consortium: SampleConsortium
    <<: *ChannelDefaults
    Application:
        <<: *ApplicationDefaults
        Organizations:
            - *Org1
            - *Org2
        Capabilities:
            <<: *ApplicationCapabilities

The system channel is used by the ordering service as a template to create application channels. The nodes of the ordering service that are defined in the system channel become the default consenter set of new channels, while the administrators of the ordering service become the orderer administrators of the channel. The channel MSPs of channel members are transferred to the new channel from the system channel. After the channel is created, ordering nodes can be added or removed from the channel by updating the channel configuration. You can also update the channel configuration to add other organizations as channel members.
The TwoOrgsChannel provides the name of the consortium, SampleConsortium, hosted by the test network system channel. As a result, the ordering service defined in the TwoOrgsOrdererGenesis profile becomes channel consenter set. In the Application section, both organizations from the consortium, Org1 and Org2, are included as channel members. The channel uses V2_0 as the application capabilities, and uses the default policies from the Application section to govern how peer organizations will interact with the channel. The application channel also uses the default policies from the Channel section and enables V2_0 as the channel capability level.

Channel policies¶
Channels are a private method of communication between organizations. As a result, most changes to the channel configuration need to be agreed to by other members of the channel. A channel would not be useful if an organization could join the channel and read the data on the ledger without getting the approval of other organizations. Any changes to the channel structure need to be approved by a set of organizations that can satisfy the channel policies.
Policies also govern the processes of how users interact with the channel, such as the set of organizations that need to approve a chaincode before it can be deployed to a channel or which actions need to be completed by channel administrators.
Channel policies are important enough that they need to be discussed in their own topic. Unlike other parts of the channel configuration, the policies that govern the channel are determined by how different sections of the configtx.yaml file work together. While channel policies can be configured for any use case with few constraints, this topic will focus on how to use the default policies provided by Hyperledger Fabric. If you use the default policies used by the Fabric test network or the Fabric sample configuration, each channel you create will use a combination of signature policies, ImplicitMeta policies, and Access Control Lists to determine how organizations interact with the channel and agree to update the channel structure. You can learn more about the role of policies in Hyperledger Fabric by visiting the Policies concept topic.

Signature policies¶
By default, each channel member defines a set of signature policies that references their organization. When a proposal is submitted to a peer, or a transaction is submitted to the ordering nodes, the nodes read the signatures attached to the transaction and evaluate them against the signature policies defined in the channel configuration. Every signature policy has rule that specifies the set of organizations and identities whose signatures can satisfy the policy. You can see the signature policies defined by Org1 in the Organizations section of configtx.yaml below:
- &Org1

  ...

  Policies:
      Readers:
          Type: Signature
          Rule: "OR('Org1MSP.admin', 'Org1MSP.peer', 'Org1MSP.client')"
      Writers:
          Type: Signature
          Rule: "OR('Org1MSP.admin', 'Org1MSP.client')"
      Admins:
          Type: Signature
          Rule: "OR('Org1MSP.admin')"
      Endorsement:
          Type: Signature
          Rule: "OR('Org1MSP.peer')"

All the policies above can be satisfied by signatures from Org1. However, each policy lists a different set of roles from within the organization that are able to satisfy the policy. The Admins policy can only be satisfied by transactions submitted by an identity with an admin role, while only identities with a peer role can satisfy the Endorsement policy. A set of signatures attached to a single transaction can satisfy multiple signature policies. For example, if the endorsements attached to a transaction were provided by both Org1 and Org2, then this signature set would satisfy the Endorsement policy of Org1 and Org2.

ImplicitMeta Policies¶
If your channel uses the default policies, the signature policies for each organization are evaluated by ImplicitMeta policies at higher levels of the channel configuration. Instead of directly evaluating the signatures that are submitted to the channel, ImplicitMeta policies have rules specify a set of other policies in the channel configuration that can satisfy the policy. A transaction can satisfy an ImplicitMeta policy if it can satisfy the underlying set of signature policies that are referenced by the policy.
You can see the ImplicitMeta policies defined in the Application section of configtx.yaml file below:
Policies:
    Readers:
        Type: ImplicitMeta
        Rule: "ANY Readers"
    Writers:
        Type: ImplicitMeta
        Rule: "ANY Writers"
    Admins:
        Type: ImplicitMeta
        Rule: "MAJORITY Admins"
    LifecycleEndorsement:
        Type: ImplicitMeta
        Rule: "MAJORITY Endorsement"
    Endorsement:
        Type: ImplicitMeta
        Rule: "MAJORITY Endorsement"

The ImplicitMeta policies in the Application section govern how peer organizations interact with the channel. Each policy references the signature policies associated with each channel member. You see the relationship between the policies in the Application section and the policies in the Organization section below:

Figure 1: The Admins ImplicitMeta policy can be satisfied by a majority of the Admins signature policies that are defined by each organization.
Each policy is referred to its path in the channel configuration. Because the policies in the Application section are located in the application group, which is located inside the channel group, they are referred to as Channel/Application policies. Since most places in the Fabric documentation refer to policies by their path, we will refer to policies by their path for the rest of the tutorial.
The Rule in each ImplicitMeta references the name of the signature policies that can satisfy the policy. For example, the Channel/Application/Admins ImplicitMeta policy references the Admins signature policies for each organization. Each Rule also contains the number of signature policies that are required to satisfy the ImplicitMeta policy. For example, the Channel/Application/Admins policy requires that a majority of the Admins signature policies be satisfied.

Figure 2: A channel update request submitted to the channel contains signatures from Org1, Org2, and Org3, satisfying the signature policies for each organization. As a result, the request satisfies the Channel/Application/Admins policy. The Org3 check is in light green because the signature was not required to reach to a majority.
To provide another example, the Channel/Application/Endorsement policy can be satisfied by a majority of organization Endorsement policies, which require signatures from the peers of each organization. This policy is used by the Fabric chaincode lifecycle as the default chaincode endorsement policy. Unless you commit a chaincode definition with a different endorsement policy, transactions that invoke a chaincode need to be endorsed by a majority of channel members.

Figure 3: A transaction from a client application invoked a chaincode on the peers of Org1 and Org2. The chaincode invoke was successful, and the application received an endorsement from the peers of both organizations. Because this transaction satisfies the Channel/Application/Endorsement policy, the transaction meets the default endorsement policy and can be added to the channel ledger.
The advantage of using ImplicitMeta policies and signature policies together is that you can set the rules for governance at the channel level, while allowing each channel member to select the identities that are required to sign for their organization. For example, a channel can specify that a majority of organization admins are required to sign a channel configuration update. However, each organization can use their signature policies to select which identities from their organization are admins, or even require that multiple identities from their organization need to sign in order to approve a channel update.
Another advantage of ImplicitMeta policies is that they do not need to be updated when an organization is added or removed from the channel. Using Figure 3 as an example, if two new organizations are added to the channel, the Channel/Application/Endorsement would require an endorsement from three organizations in order to validate a transaction.
A disadvantage of ImplicitMeta policies is that they do not explicitly read the signature policies used by the channel members (which is why they are called implicit policies). Instead, they assume that users have the required signature policies based on the configuration of the channel. The rule of the Channel/Application/Endorsement policy is based on the number of peer organizations in the channel. If two of the three organizations in Figure 3 do not possess the Endorsement signature polices, no transaction would be able to get the majority required to meet the Channel/Application/Endorsement ImplicitMeta policy.

Channel modification policies¶
The channel structure is governed by modification policies within the channel configuration. Each component of the channel configuration has a modification policy that needs to be satisfied in order to be updated by channel members. For example, the policies and channel MSP defined by each organization, the application group that contains the members of the channel, and the components of the configuration that define the channel consenter set each have a different modification policy.
Each modification policy can reference an ImplicitMeta policy or a signature policy. For example, if you use the default policies, the values that define each organization reference the Admins signature policy associated with that organization. As a result, an organization can update their channel MSP or set an anchor peer without approval from other channel members. The modification policy of the application group that defines the set of channel members is the Channel/Application/Admins ImplicitMeta policy. As a result, the default policy is that a majority of organizations need to approve the addition or removal of a channel member.

Channel policies and Access Control Lists¶
The policies within the channel configuration are also referenced by Access Control Lists (ACLs) that are used to restrict access to Fabric resources used by the channel. The ACLs extend the policies within the channel configuration to govern the processes of the channel. You can see the default ACLs in the sample configtx.yaml file. Each ACL refers to a channel policy using the path. For example, the following ACL restricts who can invoke a chaincode based on the /Channel/Application/Writers policy:
# ACL policy for invoking chaincodes on peer
peer/Propose: /Channel/Application/Writers

Most of the default ACLs point to the ImplicitMeta policies in the application section of the channel configuration. To extend the example above, an organization can invoke a chaincode if they can satisfy the /Channel/Application/Writers policy.

Figure 4: The peer/Propose ACL is satisfied by the /Channel/Application/Writers policy. This policy can be satisfied by a transaction submitted by a client application from any organization with the writers signature policy.

Orderer policies¶
The ImplicitMeta policies in the Orderer section of configtx.yaml govern the ordering nodes of a channel in a similar way as the Application section governs the peer organizations. The ImplicitMeta policies point to the signature policies associated with the organizations that are ordering service administrators.

Figure 5: The Channel/Orderer/Admins policy points to the Admins signature policies associated with the administrators of the ordering service.
If you use the default policies, a majority of orderer organizations are required to approve the addition or removal of an ordering node.

Figure 6: A request submitted to remove an ordering node from the channel contains signatures from the three ordering organizations in the network, satisfying the Channel/Orderer/Admins policy. The Org3 check is in light green because the signature was not required to reach to a majority.
The Channel/Orderer/BlockValidation policy is used by peers to confirm that new blocks being added to the channel were generated by an ordering node that is part of the channel consenter set, and that the block was not tampered with or created by another peer organization. By default, any orderer organization with a Writers signature policy can create and validate blocks for the channel.

Adding an Org to a Channel¶

Note
Ensure that you have downloaded the appropriate images and binaries
as outlined in Install Samples, Binaries, and Docker Images and Prerequisites that conform to the
version of this documentation (which can be found at the bottom of the
table of contents to the left).

This tutorial extends the Fabric test network by adding a new organization
– Org3 – to an application channel.
While we will focus on adding a new organization to the channel, you can use a
similar process to make other channel configuration updates (updating modification
policies or altering batch size, for example). To learn more about the process
and possibilities of channel config updates in general, check out Updating a channel configuration).
It’s also worth noting that channel configuration updates like the one
demonstrated here will usually be the responsibility of an organization admin
(rather than a chaincode or application developer).

Setup the Environment¶
We will be operating from the root of the test-network subdirectory within
your local clone of fabric-samples. Change into that directory now.
cd fabric-samples/test-network

First, use the network.sh script to tidy up. This command will kill any active
or stale Docker containers and remove previously generated artifacts. It is by no
means necessary to bring down a Fabric network in order to perform channel
configuration update tasks. However, for the sake of this tutorial, we want to operate
from a known initial state. Therefore let’s run the following command to clean up any
previous environments:
./network.sh down

You can now use the script to bring up the test network with one channel named
mychannel:
./network.sh up createChannel

If the command was successful, you can see the following message printed in your
logs:
========= Channel successfully joined ===========

Now that you have a clean version of the test network running on your machine, we
can start the process of adding a new org to the channel we created. First, we are
going use a script to add Org3 to the channel to confirm that the process works.
Then, we will go through the step by step process of adding Org3 by updating the
channel configuration.

Bring Org3 into the Channel with the Script¶
You should be in the test-network directory. To use the script, simply issue
the following commands:
cd addOrg3
./addOrg3.sh up

The output here is well worth reading. You’ll see the Org3 crypto material being
generated, the Org3 organization definition being created, and then the channel
configuration being updated, signed, and then submitted to the channel.
If everything goes well, you’ll get this message:
========= Finished adding Org3 to your test network! =========

Now that we have confirmed we can add Org3 to our channel, we can go through the
steps to update the channel configuration that the script completed behind the
scenes.

Bring Org3 into the Channel Manually¶
If you just used the addOrg3.sh script, you’ll need to bring your network down.
The following command will bring down all running components and remove the crypto
material for all organizations:
./addOrg3.sh down

After the network is brought down, bring it back up again:
cd ..
./network.sh up createChannel

This will bring your network back to the same state it was in before you executed
the addOrg3.sh script.
Now we’re ready to add Org3 to the channel manually. As a first step, we’ll need
to generate Org3’s crypto material.

Generate the Org3 Crypto Material¶
In another terminal, change into the addOrg3 subdirectory from
test-network.
cd addOrg3

First, we are going to create the certificates and keys for the Org3 peer, along
with an application and admin user. Because we are updating an example channel,
we are going to use the cryptogen tool instead of using a Certificate Authority.
The following command uses cryptogen  to read the org3-crypto.yaml file
and generate the Org3 crypto material in a new org3.example.com folder:
../../bin/cryptogen generate --config=org3-crypto.yaml --output="../organizations"

You can find the generated Org3 crypto material alongside the certificates and
keys for Org1 and Org2 in the test-network/organizations/peerOrganizations
directory.
Once we have created the Org3 crypto material, we can use the configtxgen
tool to print out the Org3 organization definition. We will preface the command
by telling the tool to look in the current directory for the configtx.yaml
file that it needs to ingest.
export FABRIC_CFG_PATH=$PWD
../../bin/configtxgen -printOrg Org3MSP > ../organizations/peerOrganizations/org3.example.com/org3.json

The above command creates a JSON file – org3.json – and writes it to the
test-network/organizations/peerOrganizations/org3.example.com folder. The
organization definition contains the policy definitions for Org3, as well as three
important certificates encoded in base64 format:

a CA root cert, used to establish the organizations root of trust
a TLS root cert, used by the gossip protocol to identify Org3 for block dissemination and service discovery
The admin user certificate (which will be needed to act as the admin of Org3 later on)

We will add Org3 to the channel by appending this organization definition to
the channel configuration.

Bring up Org3 components¶
After we have created the Org3 certificate material, we can now bring up the
Org3 peer. From the addOrg3 directory, issue the following command:
docker-compose -f docker/docker-compose-org3.yaml up -d

If the command is successful, you will see the the creation of the Org3 peer and
an instance of the Fabric tools container named Org3CLI:
Creating peer0.org3.example.com ... done
Creating Org3cli                ... done

This Docker Compose file has been configured to bridge across our initial network,
so that the Org3 peer and Org3CLI resolve with the existing peers and ordering
node of the test network. We will use the Org3CLI container to communicate with
the network and issue the peer commands that will add Org3 to the channel.

Prepare the CLI Environment¶
The update process makes use of the configuration translator tool – configtxlator.
This tool provides a stateless REST API independent of the SDK. Additionally it
provides a CLI tool that can be used to simplify configuration tasks in Fabric
networks. The tool allows for the easy conversion between different equivalent
data representations/formats (in this case, between protobufs and JSON).
Additionally, the tool can compute a configuration update transaction based on
the differences between two channel configurations.
Use the following command to exec into the Org3CLI container:
docker exec -it Org3cli bash

This container has been mounted with the organizations folder, giving us
access to the crypto material and TLS certificates for all organizations and the
Orderer Org. We can use environment variables to operate the Org3CLI container
as the admin of Org1, Org2, or Org3. First, we need to set the environment
variables for the orderer TLS certificate and the channel name:
export ORDERER_CA=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem
export CHANNEL_NAME=mychannel

Check to make sure the variables have been properly set:
echo $ORDERER_CA && echo $CHANNEL_NAME

Note
If for any reason you need to restart the Org3CLI container, you will also need to
re-export the two environment variables – ORDERER_CA and CHANNEL_NAME.

Fetch the Configuration¶
Now we have the Org3CLI container with our two key environment variables – ORDERER_CA
and CHANNEL_NAME exported.  Let’s go fetch the most recent config block for the
channel – mychannel.
The reason why we have to pull the latest version of the config is because channel
config elements are versioned. Versioning is important for several reasons. It prevents
config changes from being repeated or replayed (for instance, reverting to a channel config
with old CRLs would represent a security risk). Also it helps ensure concurrency (if you
want to remove an Org from your channel, for example, after a new Org has been added,
versioning will help prevent you from removing both Orgs, instead of just the Org you want
to remove).
Because Org3 is not yet a member of the channel, we need to operate as the admin
of another organization to fetch the channel config. Because Org1 is a member of the channel, the
Org1 admin has permission to fetch the channel config from the ordering service.
Issue the following commands to operate as the Org1 admin.
# you can issue all of these commands at once

export CORE_PEER_LOCALMSPID="Org1MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
export CORE_PEER_ADDRESS=peer0.org1.example.com:7051

We can now issue the command to fetch the latest config block:
peer channel fetch config config_block.pb -o orderer.example.com:7050 -c $CHANNEL_NAME --tls --cafile $ORDERER_CA

This command saves the binary protobuf channel configuration block to
config_block.pb. Note that the choice of name and file extension is arbitrary.
However, following a convention which identifies both the type of object being
represented and its encoding (protobuf or JSON) is recommended.
When you issued the peer channel fetch command, the following output is
displayed in your logs:
2017-11-07 17:17:57.383 UTC [channelCmd] readBlock -> DEBU 011 Received block: 2

This is telling us that the most recent configuration block for mychannel is
actually block 2, NOT the genesis block. By default, the peer channel fetch config
command returns the most recent configuration block for the targeted channel, which
in this case is the third block. This is because the test network script, network.sh, defined anchor
peers for our two organizations – Org1 and Org2 – in two separate channel update
transactions. As a result, we have the following configuration sequence:

block 0: genesis block
block 1: Org1 anchor peer update
block 2: Org2 anchor peer update

Convert the Configuration to JSON and Trim It Down¶
Now we will make use of the configtxlator tool to decode this channel
configuration block into JSON format (which can be read and modified by humans).
We also must strip away all of the headers, metadata, creator signatures, and
so on that are irrelevant to the change we want to make. We accomplish this by
means of the jq tool:
configtxlator proto_decode --input config_block.pb --type common.Block | jq .data.data[0].payload.data.config > config.json

This command leaves us with a trimmed down JSON object – config.json – which
will serve as the baseline for our config update.
Take a moment to open this file inside your text editor of choice (or in your
browser). Even after you’re done with this tutorial, it will be worth studying it
as it reveals the underlying configuration structure and the other kind of channel
updates that can be made. We discuss them in more detail in Updating a channel configuration.

Add the Org3 Crypto Material¶

Note
The steps you’ve taken up to this point will be nearly identical no matter
what kind of config update you’re trying to make. We’ve chosen to add an
org with this tutorial because it’s one of the most complex channel
configuration updates you can attempt.

We’ll use the jq tool once more to append the Org3 configuration definition
– org3.json – to the channel’s application groups field, and name the output
– modified_config.json.
jq -s '.[0] * {"channel_group":{"groups":{"Application":{"groups": {"Org3MSP":.[1]}}}}}' config.json ./organizations/peerOrganizations/org3.example.com/org3.json > modified_config.json

Now, within the Org3CLI container we have two JSON files of interest – config.json
and modified_config.json. The initial file contains only Org1 and Org2 material,
whereas the “modified” file contains all three Orgs. At this point it’s simply
a matter of re-encoding these two JSON files and calculating the delta.
First, translate config.json back into a protobuf called config.pb:
configtxlator proto_encode --input config.json --type common.Config --output config.pb

Next, encode modified_config.json to modified_config.pb:
configtxlator proto_encode --input modified_config.json --type common.Config --output modified_config.pb

Now use configtxlator to calculate the delta between these two config
protobufs. This command will output a new protobuf binary named org3_update.pb:
configtxlator compute_update --channel_id $CHANNEL_NAME --original config.pb --updated modified_config.pb --output org3_update.pb

This new proto – org3_update.pb – contains the Org3 definitions and high
level pointers to the Org1 and Org2 material. We are able to forgo the extensive
MSP material and modification policy information for Org1 and Org2 because this
data is already present within the channel’s genesis block. As such, we only need
the delta between the two configurations.
Before submitting the channel update, we need to perform a few final steps. First,
let’s decode this object into editable JSON format and call it org3_update.json:
configtxlator proto_decode --input org3_update.pb --type common.ConfigUpdate | jq . > org3_update.json

Now, we have a decoded update file – org3_update.json – that we need to wrap
in an envelope message. This step will give us back the header field that we stripped away
earlier. We’ll name this file org3_update_in_envelope.json:
echo '{"payload":{"header":{"channel_header":{"channel_id":"'$CHANNEL_NAME'", "type":2}},"data":{"config_update":'$(cat org3_update.json)'}}}' | jq . > org3_update_in_envelope.json

Using our properly formed JSON – org3_update_in_envelope.json – we will
leverage the configtxlator tool one last time and convert it into the
fully fledged protobuf format that Fabric requires. We’ll name our final update
object org3_update_in_envelope.pb:
configtxlator proto_encode --input org3_update_in_envelope.json --type common.Envelope --output org3_update_in_envelope.pb

Sign and Submit the Config Update¶
Almost done!
We now have a protobuf binary – org3_update_in_envelope.pb – within the
Org3CLI container. However, we need signatures from the requisite Admin users
before the config can be written to the ledger. The modification policy (mod_policy)
for our channel Application group is set to the default of “MAJORITY”, which means that
we need a majority of existing org admins to sign it. Because we have only two orgs –
Org1 and Org2 – and the majority of two is two, we need both of them to sign. Without
both signatures, the ordering service will reject the transaction for failing to
fulfill the policy.
First, let’s sign this update proto as Org1. Remember that we exported the
necessary environment variables to operate the Org3CLI container as the Org1 admin.
As a result, the following peer channel signconfigtx command will sign the update as Org1.
peer channel signconfigtx -f org3_update_in_envelope.pb

The final step is to switch the container’s identity to reflect the Org2 Admin
user. We do this by exporting four environment variables specific to the Org2 MSP.

Note
Switching between organizations to sign a config transaction (or to do anything
else) is not reflective of a real-world Fabric operation. A single container
would never be mounted with an entire network’s crypto material. Rather, the
config update would need to be securely passed out-of-band to an Org2
Admin for inspection and approval.

Export the Org2 environment variables:
# you can issue all of these commands at once

export CORE_PEER_LOCALMSPID="Org2MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
export CORE_PEER_ADDRESS=peer0.org2.example.com:9051

Lastly, we will issue the peer channel update command. The Org2 Admin signature
will be attached to this call so there is no need to manually sign the protobuf a
second time:

Note
The upcoming update call to the ordering service will undergo a series
of systematic signature and policy checks. As such you may find it
useful to stream and inspect the ordering node’s logs. You can issue a
docker logs -f orderer.example.com command from a terminal outside
the Org3CLI container to display them.

Send the update call:
peer channel update -f org3_update_in_envelope.pb -c $CHANNEL_NAME -o orderer.example.com:7050 --tls --cafile $ORDERER_CA

You should see a message similar to the following if your update has been submitted successfully:
2020-01-09 21:30:45.791 UTC [channelCmd] update -> INFO 002 Successfully submitted channel update

The successful channel update call returns a new block – block 3 – to all of the
peers on the channel. If you remember, blocks 0-2 are the initial channel
configurations. Block 3 serves as the most recent channel configuration with
Org3 now defined on the channel.
You can inspect the logs for peer0.org1.example.com by navigating to a terminal
outside the Org3CLI container and issuing the following command:
docker logs -f peer0.org1.example.com

Join Org3 to the Channel¶
At this point, the channel configuration has been updated to include our new
organization – Org3 – meaning that peers attached to it can now join mychannel.
Inside the Org3CLI container, export the following environment variables to operate
as the Org3 Admin:
# you can issue all of these commands at once

export CORE_PEER_LOCALMSPID="Org3MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org3.example.com/peers/peer0.org3.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org3.example.com/users/Admin@org3.example.com/msp
export CORE_PEER_ADDRESS=peer0.org3.example.com:11051

Now let’s send a call to the ordering service asking for the genesis block of
mychannel. As a result of the successful channel update, the ordering service
will verify that Org3 can pull the genesis block and join the channel. If Org3 had not
been successfully appended to the channel config, the ordering service would
reject this request.

Note
Again, you may find it useful to stream the ordering node’s logs
to reveal the sign/verify logic and policy checks.

Use the peer channel fetch command to retrieve this block:
peer channel fetch 0 mychannel.block -o orderer.example.com:7050 -c $CHANNEL_NAME --tls --cafile $ORDERER_CA

Notice, that we are passing a 0 to indicate that we want the first block on
the channel’s ledger; the genesis block. If we simply passed the
peer channel fetch config command, then we would have received block 3 – the
updated config with Org3 defined. However, we can’t begin our ledger with a
downstream block – we must start with block 0.
If successful, the command returned the genesis block to a file named mychannel.block.
We can now use this block to join the peer to the channel. Issue the
peer channel join command and pass in the genesis block to join the Org3
peer to the channel:
peer channel join -b mychannel.block

Configuring Leader Election¶

Note
This section is included as a general reference for understanding
the leader election settings when adding organizations to a network
after the initial channel configuration has completed. This sample
defaults to dynamic leader election, which is set for all peers in the
network.

Newly joining peers are bootstrapped with the genesis block, which does not
contain information about the organization that is being added in the channel
configuration update. Therefore new peers are not able to utilize gossip as
they cannot verify blocks forwarded by other peers from their own organization
until they get the configuration transaction which added the organization to the
channel. Newly added peers must therefore have one of the following
configurations so that they receive blocks from the ordering service:
1. To utilize static leader mode, configure the peer to be an organization
leader:
CORE_PEER_GOSSIP_USELEADERELECTION=false
CORE_PEER_GOSSIP_ORGLEADER=true

Note
This configuration must be the same for all new peers added to the
channel.

2. To utilize dynamic leader election, configure the peer to use leader
election:
CORE_PEER_GOSSIP_USELEADERELECTION=true
CORE_PEER_GOSSIP_ORGLEADER=false

Note
Because peers of the newly added organization won’t be able to form
membership view, this option will be similar to the static
configuration, as each peer will start proclaiming itself to be a
leader. However, once they get updated with the configuration
transaction that adds the organization to the channel, there will be
only one active leader for the organization. Therefore, it is
recommended to leverage this option if you eventually want the
organization’s peers to utilize leader election.

Install, define, and invoke chaincode¶
We can confirm that Org3 is a member of mychannel by installing and invoking
a chaincode on the channel. If the existing channel members have already committed
a chaincode definition to the channel, a new organization can start using the
chaincode by approving the chaincode definition.

Note
These instructions use the Fabric chaincode lifecycle introduced in
the v2.0 release. If you would like to use the previous lifecycle to
install and instantiate a chaincode, visit the v1.4 version of the
Adding an org to a channel tutorial.

Before we install a chaincode as Org3, we can use the ./network.sh script to
deploy the Fabcar chaincode on the channel. Open a new terminal outside the
Org3CLI container and navigate to the test-network directory. You can then use
use the test-network script to deploy the Fabcar chaincode:
cd fabric-samples/test-network
./network.sh deployCC

The script will install the Fabcar chaincode on the Org1 and Org2 peers, approve
the chaincode definition for Org1 and Org2, and then commit the chaincode
definition to the channel. Once the chaincode definition has been committed to
the channel, the Fabcar chaincode is initialized and invoked to put initial data
on the ledger. The commands below assume that we are still using the channel
mychannel.
After the chaincode has been to deployed we can use the following steps to use
invoke Fabcar chaincode as Org3. These steps can be completed from the
test-network directory, without having to exec into Org3CLI container. Copy
and paste the following environment variables in your terminal in order to interact
with the network as the Org3 admin:
export PATH=${PWD}/../bin:$PATH
export FABRIC_CFG_PATH=$PWD/../config/
export CORE_PEER_TLS_ENABLED=true
export CORE_PEER_LOCALMSPID="Org3MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org3.example.com/peers/peer0.org3.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org3.example.com/users/Admin@org3.example.com/msp
export CORE_PEER_ADDRESS=localhost:11051

The first step is to package the Fabcar chaincode:
peer lifecycle chaincode package fabcar.tar.gz --path ../chaincode/fabcar/go/ --lang golang --label fabcar_1

This command will create a chaincode package named fabcar.tar.gz, which we can
install on the Org3 peer. Modify the command accordingly if the channel is running a
chaincode written in Java or Node.js. Issue the following command to install the
chaincode package peer0.org3.example.com:
peer lifecycle chaincode install fabcar.tar.gz

The next step is to approve the chaincode definition of Fabcar as Org3. Org3
needs to approve the same definition that Org1 and Org2 approved and committed
to the channel. In order to invoke the chaincode, Org3 needs to include the
package identifier in the chaincode definition. You can find the package
identifier by querying your peer:
peer lifecycle chaincode queryinstalled

You should see output similar to the following:
Get installed chaincodes on peer:
Package ID: fabcar_1:25f28c212da84a8eca44d14cf12549d8f7b674a0d8288245561246fa90f7ab03, Label: fabcar_1

We are going to need the package ID in a future command, so lets go ahead and
save it as an environment variable. Paste the package ID returned by the
peer lifecycle chaincode queryinstalled command into the command below. The
package ID may not be the same for all users, so you need to complete this step
using the package ID returned from your console.
export CC_PACKAGE_ID=fabcar_1:25f28c212da84a8eca44d14cf12549d8f7b674a0d8288245561246fa90f7ab03

Use the following command to approve a definition of the Fabcar chaincode
for Org3:
# use the --package-id flag to provide the package identifier
# use the --init-required flag to request the ``Init`` function be invoked to initialize the chaincode
peer lifecycle chaincode approveformyorg -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --channelID mychannel --name fabcar --version 1 --init-required --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

You can use the peer lifecycle chaincode querycommitted command to check if
the chaincode definition you have approved has already been committed to the
channel.
# use the --name flag to select the chaincode whose definition you want to query
peer lifecycle chaincode querycommitted --channelID mychannel --name fabcar --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

A successful command will return information about the committed definition:
Committed chaincode definition for chaincode 'fabcar' on channel 'mychannel':
Version: 1, Sequence: 1, Endorsement Plugin: escc, Validation Plugin: vscc, Approvals: [Org1MSP: true, Org2MSP: true, Org3MSP: true]

Org3 can use the Fabcar chaincode after it approves the chaincode definition
that was committed to the channel. The chaincode definition uses the default endorsement
policy, which requires a majority of organizations on the channel endorse a transaction.
This implies that if an organization is added to or removed from the channel, the
endorsement policy will be updated automatically. We previously needed endorsements
from Org1 and Org2 (2 out of 2). Now we need endorsements from two organizations
out of Org1, Org2, and Org3 (2 out of 3).
You can query the chaincode to ensure that it has started on the Org3 peer. Note
that you may need to wait for the chaincode container to start.
peer chaincode query -C mychannel -n fabcar -c '{"Args":["queryAllCars"]}'

You should see the initial list of cars that were added to the ledger as a
response.
Now, invoke the chaincode to add a new car to the ledger. In the command below,
we target a peer in Org1 and Org3 to collect a sufficient number of endorsements.
peer chaincode invoke -o localhost:7050 --ordererTLSHostnameOverride orderer.example.com --tls --cafile ${PWD}/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C mychannel -n fabcar --peerAddresses localhost:7051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses localhost:11051 --tlsRootCertFiles ${PWD}/organizations/peerOrganizations/org3.example.com/peers/peer0.org3.example.com/tls/ca.crt -c '{"function":"createCar","Args":["CAR11","Honda","Accord","Black","Tom"]}'

We can query again to see the new car, “CAR11” on the our the ledger:
peer chaincode query -C mychannel -n fabcar -c '{"Args":["queryCar","CAR11"]}'

Conclusion¶
The channel configuration update process is indeed quite involved, but there is a
logical method to the various steps. The endgame is to form a delta transaction object
represented in protobuf binary format and then acquire the requisite number of admin
signatures such that the channel configuration update transaction fulfills the channel’s
modification policy.
The configtxlator and jq tools, along with the peer channel
commands, provide us with the functionality to accomplish this task.

Updating the Channel Config to include an Org3 Anchor Peer (Optional)¶
The Org3 peers were able to establish gossip connection to the Org1 and Org2
peers since Org1 and Org2 had anchor peers defined in the channel configuration.
Likewise newly added organizations like Org3 should also define their anchor peers
in the channel configuration so that any new peers from other organizations can
directly discover an Org3 peer. In this section, we will make a channel
configuration update to define an Org3 anchor peer. The process will be similar
to the previous configuration update, therefore we’ll go faster this time.
If you don’t have it open, exec back into the Org3CLI container:
docker exec -it Org3cli bash

Export the $ORDERER_CA and $CHANNEL_NAME variables if they are not already set:
export ORDERER_CA=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem
export CHANNEL_NAME=mychannel

As before, we will fetch the latest channel configuration to get started.
Inside the Org3CLI container, fetch the most recent config block for the channel,
using the peer channel fetch command.
peer channel fetch config config_block.pb -o orderer.example.com:7050 -c $CHANNEL_NAME --tls --cafile $ORDERER_CA

After fetching the config block we will want to convert it into JSON format. To do
this we will use the configtxlator tool, as done previously when adding Org3 to the
channel. When converting it we need to remove all the headers, metadata, and signatures
that are not required to update Org3 to include an anchor peer by using the jq
tool. This information will be reincorporated later before we proceed to update the
channel configuration.
configtxlator proto_decode --input config_block.pb --type common.Block | jq .data.data[0].payload.data.config > config.json

The config.json is the now trimmed JSON representing the latest channel configuration
that we will update.
Using the jq tool again, we will update the configuration JSON with the Org3 anchor peer we
want to add.
jq '.channel_group.groups.Application.groups.Org3MSP.values += {"AnchorPeers":{"mod_policy": "Admins","value":{"anchor_peers": [{"host": "peer0.org3.example.com","port": 11051}]},"version": "0"}}' config.json > modified_anchor_config.json

We now have two JSON files, one for the current channel configuration,
config.json, and one for the desired channel configuration modified_anchor_config.json.
Next we convert each of these back into protobuf format and calculate the delta between the two.
Translate config.json back into protobuf format as config.pb
configtxlator proto_encode --input config.json --type common.Config --output config.pb

Translate the modified_anchor_config.json into protobuf format as modified_anchor_config.pb
configtxlator proto_encode --input modified_anchor_config.json --type common.Config --output modified_anchor_config.pb

Calculate the delta between the two protobuf formatted configurations.
configtxlator compute_update --channel_id $CHANNEL_NAME --original config.pb --updated modified_anchor_config.pb --output anchor_update.pb

Now that we have the desired update to the channel we must wrap it in an envelope
message so that it can be properly read. To do this we must first convert the protobuf
back into a JSON that can be wrapped.
We will use the configtxlator command again to convert anchor_update.pb into anchor_update.json
configtxlator proto_decode --input anchor_update.pb --type common.ConfigUpdate | jq . > anchor_update.json

Next we will wrap the update in an envelope message, restoring the previously
stripped away header, outputting it to anchor_update_in_envelope.json
echo '{"payload":{"header":{"channel_header":{"channel_id":"'$CHANNEL_NAME'", "type":2}},"data":{"config_update":'$(cat anchor_update.json)'}}}' | jq . > anchor_update_in_envelope.json

Now that we have reincorporated the envelope we need to convert it
to a protobuf so it can be properly signed and submitted to the orderer for the update.
configtxlator proto_encode --input anchor_update_in_envelope.json --type common.Envelope --output anchor_update_in_envelope.pb

Now that the update has been properly formatted it is time to sign off and submit it. Since this
is only an update to Org3 we only need to have Org3 sign off on the update. Run the following
commands to make sure that we are operating as the Org3 admin:
# you can issue all of these commands at once

export CORE_PEER_LOCALMSPID="Org3MSP"
export CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org3.example.com/peers/peer0.org3.example.com/tls/ca.crt
export CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/organizations/peerOrganizations/org3.example.com/users/Admin@org3.example.com/msp
export CORE_PEER_ADDRESS=peer0.org3.example.com:11051

We can now just use the peer channel update command to sign the update as the
Org3 admin before submitting it to the orderer.
peer channel update -f anchor_update_in_envelope.pb -c $CHANNEL_NAME -o orderer.example.com:7050 --tls --cafile $ORDERER_CA

The orderer receives the config update request and cuts a block with the updated configuration.
As peers receive the block, they will process the configuration updates.
Inspect the logs for one of the peers. While processing the configuration transaction from the new block,
you will see gossip re-establish connections using the new anchor peer for Org3. This is proof
that the configuration update has been successfully applied!
docker logs -f peer0.org1.example.com

2019-06-12 17:08:57.924 UTC [gossip.gossip] learnAnchorPeers -> INFO 89a Learning about the configured anchor peers of Org1MSP for channel mychannel : [{peer0.org1.example.com 7051}]
2019-06-12 17:08:57.926 UTC [gossip.gossip] learnAnchorPeers -> INFO 89b Learning about the configured anchor peers of Org2MSP for channel mychannel : [{peer0.org2.example.com 9051}]
2019-06-12 17:08:57.926 UTC [gossip.gossip] learnAnchorPeers -> INFO 89c Learning about the configured anchor peers of Org3MSP for channel mychannel : [{peer0.org3.example.com 11051}]

Congratulations, you have now made two configuration updates — one to add Org3 to the channel,
and a second to define an anchor peer for Org3.

Updating a channel configuration¶
Audience: network administrators, node administrators

What is a channel configuration?¶
Like many complex systems, Hyperledger Fabric networks are comprised of both structure and a number related of processes.

Structure: encompassing users (like admins), organizations, peers, ordering nodes, CAs, smart contracts, and applications.
Process: the way these structures interact. Most important of these are Policies, the rules that govern which users can do what, and under what conditions.

Information identifying the structure of blockchain networks and the processes governing how structures interact are contained in channel configurations. These configurations are collectively decided upon by the members of channels and are contained in blocks that are committed to the ledger of a channel. Channel configurations can be built using a tool called configtxgen, which uses a configtx.yaml file as its input. You can look at a sample configtx.yaml file here.
Because configurations are contained in blocks (the first of these is known as the genesis block with the latest representing the current configuration of the channel), the process for updating a channel configuration (changing the structure by adding members, for example, or processes by modifying channel policies) is known as a configuration update transaction.
In production networks, these configuration update transactions will normally be proposed by a single channel admin after an out of band discussion, just as the initial configuration of the channel will be decided on out of band by the initial members of the channel.
In this topic, we’ll:

Show a full sample configuration of an application channel.
Discuss many of the channel parameters that can be edited.
Show the process for updating a channel configuration, including the commands necessary to pull, translate, and scope a configuration into something that humans can read.
Discuss the methods that can be used to edit a channel configuration.
Show the process used to reformat a configuration and get the signatures necessary for it to be approved.

Channel parameters that can be updated¶
Channels are highly configurable, but not infinitely so. Once certain things about a channel (for example, the name of the channel) have been specified, they cannot be changed. And changing one of the parameters we’ll talk about in this topic requires satisfying the relevant policy as specified in the channel configuration.
In this section, we’ll look a sample channel configuration and show the configuration parameters that can be updated.

Sample channel configuration¶
To see what the configuration file of an application channel looks like after it has been pulled and scoped, click Click here to see the config below. For ease of readability, it might be helpful to put this config into a viewer that supports JSON folding, like atom or Visual Studio.
Note: for simplicity, we are only showing an application channel configuration here. The configuration of the orderer system channel is very similar, but not identical, to the configuration of an application channel. However, the same basic rules and structure apply, as do the commands to pull and edit a configuration, as you can see in our topic on Updating the capability level of a channel.

Click here to see the config. Note that this is the configuration of an application channel, not the orderer system channel.

{
  "channel_group": {
    "groups": {
      "Application": {
        "groups": {
          "Org1MSP": {
            "groups": {},
            "mod_policy": "Admins",
            "policies": {
              "Admins": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org1MSP",
                          "role": "ADMIN"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Endorsement": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org1MSP",
                          "role": "PEER"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Readers": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org1MSP",
                          "role": "ADMIN"
                        },
                        "principal_classification": "ROLE"
                      },
                      {
                        "principal": {
                          "msp_identifier": "Org1MSP",
                          "role": "PEER"
                        },
                        "principal_classification": "ROLE"
                      },
                      {
                        "principal": {
                          "msp_identifier": "Org1MSP",
                          "role": "CLIENT"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          },
                          {
                            "signed_by": 1
                          },
                          {
                            "signed_by": 2
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Writers": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org1MSP",
                          "role": "ADMIN"
                        },
                        "principal_classification": "ROLE"
                      },
                      {
                        "principal": {
                          "msp_identifier": "Org1MSP",
                          "role": "CLIENT"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          },
                          {
                            "signed_by": 1
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              }
            },
            "values": {
              "AnchorPeers": {
                "mod_policy": "Admins",
                "value": {
                  "anchor_peers": [
                    {
                      "host": "peer0.org1.example.com",
                      "port": 7051
                    }
                  ]
                },
                "version": "0"
              },
              "MSP": {
                "mod_policy": "Admins",
                "value": {
                  "config": {
                    "admins": [],
                    "crypto_config": {
                      "identity_identifier_hash_function": "SHA256",
                      "signature_hash_family": "SHA2"
                    },
                    "fabric_node_ous": {
                      "admin_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "admin"
                      },
                      "client_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "client"
                      },
                      "enable": true,
                      "orderer_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "orderer"
                      },
                      "peer_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "peer"
                      }
                    },
                    "intermediate_certs": [],
                    "name": "Org1MSP",
                    "organizational_unit_identifiers": [],
                    "revocation_list": [],
                    "root_certs": [
                      "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"
                    ],
                    "signing_identity": null,
                    "tls_intermediate_certs": [],
                    "tls_root_certs": [
                      "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"
                    ]
                  },
                  "type": 0
                },
                "version": "0"
              }
            },
            "version": "1"
          },
          "Org2MSP": {
            "groups": {},
            "mod_policy": "Admins",
            "policies": {
              "Admins": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org2MSP",
                          "role": "ADMIN"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Endorsement": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org2MSP",
                          "role": "PEER"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Readers": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org2MSP",
                          "role": "ADMIN"
                        },
                        "principal_classification": "ROLE"
                      },
                      {
                        "principal": {
                          "msp_identifier": "Org2MSP",
                          "role": "PEER"
                        },
                        "principal_classification": "ROLE"
                      },
                      {
                        "principal": {
                          "msp_identifier": "Org2MSP",
                          "role": "CLIENT"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          },
                          {
                            "signed_by": 1
                          },
                          {
                            "signed_by": 2
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Writers": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "Org2MSP",
                          "role": "ADMIN"
                        },
                        "principal_classification": "ROLE"
                      },
                      {
                        "principal": {
                          "msp_identifier": "Org2MSP",
                          "role": "CLIENT"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          },
                          {
                            "signed_by": 1
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              }
            },
            "values": {
              "AnchorPeers": {
                "mod_policy": "Admins",
                "value": {
                  "anchor_peers": [
                    {
                      "host": "peer0.org2.example.com",
                      "port": 9051
                    }
                  ]
                },
                "version": "0"
              },
              "MSP": {
                "mod_policy": "Admins",
                "value": {
                  "config": {
                    "admins": [],
                    "crypto_config": {
                      "identity_identifier_hash_function": "SHA256",
                      "signature_hash_family": "SHA2"
                    },
                    "fabric_node_ous": {
                      "admin_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "admin"
                      },
                      "client_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "client"
                      },
                      "enable": true,
                      "orderer_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "orderer"
                      },
                      "peer_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "peer"
                      }
                    },
                    "intermediate_certs": [],
                    "name": "Org2MSP",
                    "organizational_unit_identifiers": [],
                    "revocation_list": [],
                    "root_certs": [
                      "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"
                    ],
                    "signing_identity": null,
                    "tls_intermediate_certs": [],
                    "tls_root_certs": [
                      "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"
                    ]
                  },
                  "type": 0
                },
                "version": "0"
              }
            },
            "version": "1"
          }
        },
        "mod_policy": "Admins",
        "policies": {
          "Admins": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "MAJORITY",
                "sub_policy": "Admins"
              }
            },
            "version": "0"
          },
          "Endorsement": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "MAJORITY",
                "sub_policy": "Endorsement"
              }
            },
            "version": "0"
          },
          "LifecycleEndorsement": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "MAJORITY",
                "sub_policy": "Endorsement"
              }
            },
            "version": "0"
          },
          "Readers": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "ANY",
                "sub_policy": "Readers"
              }
            },
            "version": "0"
          },
          "Writers": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "ANY",
                "sub_policy": "Writers"
              }
            },
            "version": "0"
          }
        },
        "values": {
          "Capabilities": {
            "mod_policy": "Admins",
            "value": {
              "capabilities": {
                "V2_0": {}
              }
            },
            "version": "0"
          }
        },
        "version": "1"
      },
      "Orderer": {
        "groups": {
          "OrdererOrg": {
            "groups": {},
            "mod_policy": "Admins",
            "policies": {
              "Admins": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "OrdererMSP",
                          "role": "ADMIN"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Readers": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "OrdererMSP",
                          "role": "MEMBER"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              },
              "Writers": {
                "mod_policy": "Admins",
                "policy": {
                  "type": 1,
                  "value": {
                    "identities": [
                      {
                        "principal": {
                          "msp_identifier": "OrdererMSP",
                          "role": "MEMBER"
                        },
                        "principal_classification": "ROLE"
                      }
                    ],
                    "rule": {
                      "n_out_of": {
                        "n": 1,
                        "rules": [
                          {
                            "signed_by": 0
                          }
                        ]
                      }
                    },
                    "version": 0
                  }
                },
                "version": "0"
              }
            },
            "values": {
              "MSP": {
                "mod_policy": "Admins",
                "value": {
                  "config": {
                    "admins": [],
                    "crypto_config": {
                      "identity_identifier_hash_function": "SHA256",
                      "signature_hash_family": "SHA2"
                    },
                    "fabric_node_ous": {
                      "admin_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "admin"
                      },
                      "client_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "client"
                      },
                      "enable": true,
                      "orderer_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "orderer"
                      },
                      "peer_ou_identifier": {
                        "certificate": "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",
                        "organizational_unit_identifier": "peer"
                      }
                    },
                    "intermediate_certs": [],
                    "name": "OrdererMSP",
                    "organizational_unit_identifiers": [],
                    "revocation_list": [],
                    "root_certs": [
                      "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"
                    ],
                    "signing_identity": null,
                    "tls_intermediate_certs": [],
                    "tls_root_certs": [
                      "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"
                    ]
                  },
                  "type": 0
                },
                "version": "0"
              }
            },
            "version": "0"
          }
        },
        "mod_policy": "Admins",
        "policies": {
          "Admins": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "MAJORITY",
                "sub_policy": "Admins"
              }
            },
            "version": "0"
          },
          "BlockValidation": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "ANY",
                "sub_policy": "Writers"
              }
            },
            "version": "0"
          },
          "Readers": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "ANY",
                "sub_policy": "Readers"
              }
            },
            "version": "0"
          },
          "Writers": {
            "mod_policy": "Admins",
            "policy": {
              "type": 3,
              "value": {
                "rule": "ANY",
                "sub_policy": "Writers"
              }
            },
            "version": "0"
          }
        },
        "values": {
          "BatchSize": {
            "mod_policy": "Admins",
            "value": {
              "absolute_max_bytes": 103809024,
              "max_message_count": 10,
              "preferred_max_bytes": 524288
            },
            "version": "0"
          },
          "BatchTimeout": {
            "mod_policy": "Admins",
            "value": {
              "timeout": "2s"
            },
            "version": "0"
          },
          "Capabilities": {
            "mod_policy": "Admins",
            "value": {
              "capabilities": {
                "V2_0": {}
              }
            },
            "version": "0"
          },
          "ChannelRestrictions": {
            "mod_policy": "Admins",
            "value": null,
            "version": "0"
          },
          "ConsensusType": {
            "mod_policy": "Admins",
            "value": {
              "metadata": {
                "consenters": [
                  {
                    "client_tls_cert": "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",
                    "host": "orderer.example.com",
                    "port": 7050,
                    "server_tls_cert": "LS0tLS1CRUdJTiBDRVJUSUZJQ0FURS0tLS0tCk1JSUN3akNDQW1pZ0F3SUJBZ0lVZG9JbmpzaW5vVnZua0llbE5WUU8wbDRMbEdrd0NnWUlLb1pJemowRUF3SXcKWWpFTE1Ba0dBMVVFQmhNQ1ZWTXhFVEFQQmdOVkJBZ1RDRTVsZHlCWmIzSnJNUkV3RHdZRFZRUUhFd2hPWlhjZwpXVzl5YXpFVU1CSUdBMVVFQ2hNTFpYaGhiWEJzWlM1amIyMHhGekFWQmdOVkJBTVREbU5oTG1WNFlXMXdiR1V1ClkyOXRNQjRYRFRJd01ETXlOREl3TVRnd01Gb1hEVEl4TURNeU5ESXdNak13TUZvd1lERUxNQWtHQTFVRUJoTUMKVlZNeEZ6QVZCZ05WQkFnVERrNXZjblJvSUVOaGNtOXNhVzVoTVJRd0VnWURWUVFLRXd0SWVYQmxjbXhsWkdkbApjakVRTUE0R0ExVUVDeE1IYjNKa1pYSmxjakVRTUE0R0ExVUVBeE1IYjNKa1pYSmxjakJaTUJNR0J5cUdTTTQ5CkFnRUdDQ3FHU000OUF3RUhBMElBQkdGaFd3SllGbHR3clBVellIQ3loNTMvU3VpVU1ZYnVJakdGTWRQMW9FRzMKSkcrUlRSOFR4NUNYTXdpV05sZ285dU00a1NGTzBINURZUWZPQU5MU0o5NmpnZjB3Z2Zvd0RnWURWUjBQQVFILwpCQVFEQWdPb01CMEdBMVVkSlFRV01CUUdDQ3NHQVFVRkJ3TUJCZ2dyQmdFRkJRY0RBakFNQmdOVkhSTUJBZjhFCkFqQUFNQjBHQTFVZERnUVdCQlJ2M3lNUmh5cHc0Qi9Cc1NHTlVJL0VpU1lNN2pBZkJnTlZIU01FR0RBV2dCUzYKSFYyWEl1VE9rS213azVsNE1rcGpHVzFSbHpBZUJnTlZIUkVFRnpBVmdoTnZjbVJsY21WeUxtVjRZVzF3YkdVdQpZMjl0TUZzR0NDb0RCQVVHQndnQkJFOTdJbUYwZEhKeklqcDdJbWhtTGtGbVptbHNhV0YwYVc5dUlqb2lJaXdpCmFHWXVSVzV5YjJ4c2JXVnVkRWxFSWpvaWIzSmtaWEpsY2lJc0ltaG1MbFI1Y0dVaU9pSnZjbVJsY21WeUluMTkKTUFvR0NDcUdTTTQ5QkFNQ0EwZ0FNRVVDSVFESHNrWUR5clNqeWpkTVVVWDNaT05McXJUNkdCcVNUdmZXN0dXMwpqVTg2cEFJZ0VIZkloVWxVV0VpN1hTb2Y4K2toaW9PYW5PWG80TWxQbGhlT0xjTGlqUzA9Ci0tLS0tRU5EIENFUlRJRklDQVRFLS0tLS0K"
                  }
                ],
                "options": {
                  "election_tick": 10,
                  "heartbeat_tick": 1,
                  "max_inflight_blocks": 5,
                  "snapshot_interval_size": 16777216,
                  "tick_interval": "500ms"
                }
              },
              "state": "STATE_NORMAL",
              "type": "etcdraft"
            },
            "version": "0"
          }
        },
        "version": "0"
      }
    },
    "mod_policy": "Admins",
    "policies": {
      "Admins": {
        "mod_policy": "Admins",
        "policy": {
          "type": 3,
          "value": {
            "rule": "MAJORITY",
            "sub_policy": "Admins"
          }
        },
        "version": "0"
      },
      "Readers": {
        "mod_policy": "Admins",
        "policy": {
          "type": 3,
          "value": {
            "rule": "ANY",
            "sub_policy": "Readers"
          }
        },
        "version": "0"
      },
      "Writers": {
        "mod_policy": "Admins",
        "policy": {
          "type": 3,
          "value": {
            "rule": "ANY",
            "sub_policy": "Writers"
          }
        },
        "version": "0"
      }
    },
    "values": {
      "BlockDataHashingStructure": {
        "mod_policy": "Admins",
        "value": {
          "width": 4294967295
        },
        "version": "0"
      },
      "Capabilities": {
        "mod_policy": "Admins",
        "value": {
          "capabilities": {
            "V2_0": {}
          }
        },
        "version": "0"
      },
      "Consortium": {
        "mod_policy": "Admins",
        "value": {
          "name": "SampleConsortium"
        },
        "version": "0"
      },
      "HashingAlgorithm": {
        "mod_policy": "Admins",
        "value": {
          "name": "SHA256"
        },
        "version": "0"
      },
      "OrdererAddresses": {
        "mod_policy": "/Channel/Orderer/Admins",
        "value": {
          "addresses": [
            "orderer.example.com:7050"
          ]
        },
        "version": "0"
      }
    },
    "version": "0"
  },
  "sequence": "3"
}

A config might look intimidating in this form, but once you study it you’ll see that it has a logical structure.
For example, let’s take a look at the config with a few of the tabs closed.
Note that this is the configuration of an application channel, not the orderer system channel.

The structure of the config should now be more obvious. You can see the config groupings: Channel, Application, and Orderer, and the configuration parameters related to each config grouping (we’ll talk more about these in the next section), but also where the MSPs representing organizations are. Note that the Channel config grouping is below the Orderer group config values.

More about these parameters¶
In this section, we’ll take a deeper look at the configurable values in the context of where they sit in the configuration.
First, there are config parameters that occur in multiple parts of the configuration:

Policies. Policies are not just a configuration value (which can be updated as defined in a mod_policy), they define the circumstances under which all parameters can be changed. For more information, check out Policies.
Capabilities. Ensures that networks and channels process things in the same way, creating deterministic results for things like channel configuration updates and chaincode invocations. Without deterministic results, one peer on a channel might invalidate a transaction while another peer may validate it. For more information, check out Capabilities.

Channel/Application¶
Governs the configuration parameters unique to application channels (for example, adding or removing channel members). By default, changing these parameters requires the signature of a majority of the application organization admins.

Add orgs to a channel. To add an organization to a channel, their MSP and other organization parameters must be generated and added here (under Channel/Application/groups).
Organization-related parameters. Any parameters specific to an organization, (identifying an anchor peer, for example, or the certificates of org admins), can be changed. Note that changing these values will by default not require the majority of application organization admins but only an admin of the organization itself.

Channel/Orderer¶
Governs configuration parameters unique to the ordering service or the orderer system channel, requires a majority of the ordering organizations’ admins (by default there is only one ordering organization, though more can be added, for example when multiple organizations contribute nodes to the ordering service).

Batch size. These parameters dictate the number and size of transactions in a block. No block will appear larger than absolute_max_bytes large or with more than max_message_count transactions inside the block. If it is possible to construct a block under preferred_max_bytes, then a block will be cut prematurely, and transactions larger than this size will appear in their own block.
Batch timeout. The amount of time to wait after the first transaction arrives for additional transactions before cutting a block. Decreasing this value will improve latency, but decreasing it too much may decrease throughput by not allowing the block to fill to its maximum capacity.
Block validation. This policy specifies the signature requirements for a block to be considered valid. By default, it requires a signature from some member of the ordering org.
Consensus type. To enable the migration of Kafka based ordering services to Raft based ordering services, it is possible to change the consensus type of a channel. For more information, check out Migrating from Kafka to Raft.
Raft ordering service parameters. For a look at the parameters unique to a Raft ordering service, check out Raft configuration.
Kafka brokers (where applicable). When ConsensusType is set to kafka, the brokers list enumerates some subset (or preferably all) of the Kafka brokers for the orderer to initially connect to at startup.

Channel¶
Governs configuration parameters that both the peer orgs and the ordering service orgs need to consent to, requires both the agreement of a majority of application organization admins and orderer organization admins.

Orderer addresses. A list of addresses where clients may invoke the orderer Broadcast and Deliver functions. The peer randomly chooses among these addresses and fails over between them for retrieving blocks.
Hashing structure. The block data is an array of byte arrays. The hash of the block data is computed as a Merkle tree. This value specifies the width of that Merkle tree. For the time being, this value is fixed to 4294967295 which corresponds to a simple flat hash of the concatenation of the block data bytes.
Hashing algorithm. The algorithm used for computing the hash values encoded into the blocks of the blockchain. In particular, this affects the data hash, and the previous block hash fields of the block. Note, this field currently only has one valid value (SHA256) and should not be changed.

System channel configuration parameters¶
Certain configuration values are unique to the orderer system channel.

Channel creation policy. Defines the policy value which will be set as the mod_policy for the Application group of new channels for the consortium it is defined in. The signature set attached to the channel creation request will be checked against the instantiation of this policy in the new channel to ensure that the channel creation is authorized. Note that this config value is only set in the orderer system channel.
Channel restrictions. Only editable in the orderer system channel. The total number of channels the orderer is willing to allocate may be specified as max_count. This is primarily useful in pre-production environments with weak consortium ChannelCreation policies.

Editing a config¶
Updating a channel configuration is a three step operation that’s conceptually simple:

Get the latest channel config
Create a modified channel config
Create a config update transaction

However, as you’ll see, this conceptual simplicity is wrapped in a somewhat convoluted process. As a result, some users might choose to script the process of pulling, translating, and scoping a config update. Users also have the option of how to modify the channel configuration itself, either manually or by using a tool like jq.
We have two tutorials that deal specifically with editing a channel configuration to achieve a specific end:

Adding an Org to a Channel: shows the process for adding an additional organization to an existing channel.
Updating channel capabilities: shows how to update channel capabilities.

In this topic, we’ll show the process of editing a channel configuration independent of the end goal of the configuration update.

Set environment variables for your config update¶
Before you attempt to use the sample commands, make sure to export the following environment variables, which will depend on the way you have structured your deployment. Note that the channel name, CH_NAME will have to be set for every channel being updated, as channel configuration updates only apply to the configuration of the channel being updated (with the exception of the ordering system channel, whose configuration is copied into the configuration of application channels by default).

CH_NAME: the name of the channel being updated.
TLS_ROOT_CA: the path to the root CA cert of the TLS CA of the organization proposing the update.
CORE_PEER_LOCALMSPID: the name of your MSP.
CORE_PEER_MSPCONFIGPATH: the absolute path to the MSP of your organization.
ORDERER_CONTAINER: the name of an ordering node container. Note that when targeting the ordering service, you can target any active node in the ordering service. Your requests will be forwarded to the leader automatically.

Note: this topic will provide default names for the various JSON and protobuf files being pulled and modified (config_block.pb, config_block.json, etc). You are free to use whatever names you want. However, be aware that unless you go back and erase these files at the end of each config update, you will have to select different when making an additional update.

Step 1: Pull and translate the config¶
The first step in updating a channel configuration is getting the latest config block. This is a three step process. First, we’ll pull the channel configuration in protobuf format, creating a file called config_block.pb.
Make sure you are in the peer container.
Now issue:
peer channel fetch config config_block.pb -o $ORDERER_CONTAINER -c $CH_NAME --tls --cafile $TLS_ROOT_CA

Next, we’ll convert the protobuf version of the channel config into a JSON version called config_block.json (JSON files are easier for humans to read and understand):
configtxlator proto_decode --input config_block.pb --type common.Block --output config_block.json

Finally, we’ll scope out all of the unnecessary metadata from the config, which makes it easier to read. You are free to call this file whatever you want, but in this example we’ll call it config.json.
jq .data.data[0].payload.data.config config_block.json > config.json

Now let’s make a copy of config.json called modified_config.json. Do not edit config.json directly, as we will be using it to compute the difference between config.json and modified_config.json in a later step.
cp config.json modified_config.json

Step 2: Modify the config¶
At this point, you have two options of how you want to modify the config.

Open modified_config.json using the text editor of your choice and make edits. Online tutorials exist that describe how to copy a file from a container that does not have an editor, edit it, and add it back to the container.
Use jq to apply edits to the config.

Whether you choose to edit the config manually or using jq depends on your use case. Because jq is concise and scriptable (an advantage when the same configuration update will be made to multiple channels), it’s the recommend method for performing a channel update. For an example on how jq can be used, check out Updating channel capabilities, which shows multiple jq commands leveraging a capabilities config file called capabilities.json. If you are updating something other than the capabilities in your channel, you will have to modify your jq command and JSON file accordingly.
For more information about the content and structure of a channel configuration, check out our sample channel config above.

Step 3: Re-encode and submit the config¶
Whether you make your config updates manually or using a tool like jq, you now have to run the process you ran to pull and scope the config in reverse, along with a step to calculate the difference between the old config and the new one, before submitting the config update to the other administrators on the channel to be approved.
First, we’ll turn our config.json file back to protobuf format, creating a file called config.pb. Then we’ll do the same with our modified_config.json file. Afterwards, we’ll compute the difference between the two files, creating a file called config_update.pb.
configtxlator proto_encode --input config.json --type common.Config --output config.pb

configtxlator proto_encode --input modified_config.json --type common.Config --output modified_config.pb

configtxlator compute_update --channel_id $CH_NAME --original config.pb --updated modified_config.pb --output config_update.pb

Now that we have calculated the difference between the old config and the new one, we can apply the changes to the config.
configtxlator proto_decode --input config_update.pb --type common.ConfigUpdate --output config_update.json

echo '{"payload":{"header":{"channel_header":{"channel_id":"'$CH_NAME'", "type":2}},"data":{"config_update":'$(cat config_update.json)'}}}' | jq . > config_update_in_envelope.json

configtxlator proto_encode --input config_update_in_envelope.json --type common.Envelope --output config_update_in_envelope.pb

Submit the config update transaction:
peer channel update -f config_update_in_envelope.pb -c $CH_NAME -o $ORDERER_CONTAINER --tls --cafile $TLS_ROOT_CA

Our config update transaction represents the difference between the original config and the modified one, but the ordering service will translate this into a full channel config.

Get the Necessary Signatures¶
Once you’ve successfully generated the new configuration protobuf file, it will need to satisfy the relevant policy for whatever it is you’re trying to change, typically (though not always) by requiring signatures from other organizations.
Note: you may be able to script the signature collection, dependent on your application. In general, you may always collect more signatures than are required.
The actual process of getting these signatures will depend on how you’ve set up your system, but there are two main implementations. Currently, the Fabric command line defaults to a “pass it along” system. That is, the Admin of the Org proposing a config update sends the update to someone else (another Admin, typically) who needs to sign it. This Admin signs it (or doesn’t) and passes it along to the next Admin, and so on, until there are enough signatures for the config to be submitted.
This has the virtue of simplicity — when there are enough signatures, the last admin can simply submit the config transaction (in Fabric, the peer channel update command includes a signature by default). However, this process will only be practical in smaller channels, since the “pass it along” method can be time consuming.
The other option is to submit the update to every Admin on a channel and wait for enough signatures to come back. These signatures can then be stitched together and submitted. This makes life a bit more difficult for the Admin who created the config update (forcing them to deal with a file per signer) but is the recommended workflow for users which are developing Fabric management applications.
Once the config has been added to the ledger, it will be a best practice to pull it and convert it to JSON to check to make sure everything was added correctly. This will also serve as a useful copy of the latest config.

Chaincode for Developers¶

What is Chaincode?¶
Chaincode is a program, written in Go, Node.js,
or Java that implements a prescribed interface.
Chaincode runs in a separate process from the peer and initializes and manages
the ledger state through transactions submitted by applications.
A chaincode typically handles business logic agreed to by members of the
network, so it similar to a “smart contract”. A chaincode can be invoked to update or query
the ledger in a proposal transaction. Given the appropriate permission, a chaincode
may invoke another chaincode, either in the same channel or in different channels, to access its state.
Note that, if the called chaincode is on a different channel from the calling chaincode,
only read query is allowed. That is, the called chaincode on a different channel is only a Query,
which does not participate in state validation checks in subsequent commit phase.
In the following sections, we will explore chaincode through the eyes of an
application developer. We’ll present a simple chaincode sample application
and walk through the purpose of each method in the Chaincode Shim API. If you
are a network operator who is deploying a chaincode to running network,
visit the Deploying a smart contract to a channel tutorial and the Fabric chaincode lifecycle
concept topic.
This tutorial provides an overview of the low level APIs provided by the Fabric
Chaincode Shim API. You can also use the higher level APIs provided by the
Fabric Contract API. To learn more about developing smart contracts
using the Fabric contract API, visit the Smart Contract Processing topic.

Chaincode API¶
Every chaincode program must implement the Chaincode interface whose methods
are called in response to received transactions. You can find the reference
documentation of the Chaincode Shim API for different languages below:

Go
Node.js
Java

In each language, the Invoke method is called by clients to submit transaction
proposals. This method allows you to use the chaincode to read and write data on
the channel ledger.
You also need to include an Init method in your chaincode that will serve as
the initialization function. This function is required by the chaincode interface,
but does not necessarily need to invoked by your applications. You can use the
Fabric chaincode lifecycle process to specify whether the Init function must
be called prior to Invokes. For more information, refer to the initialization
parameter in the Approving a chaincode definition
step of the Fabric chaincode lifecycle documentation.
The other interface in the chaincode “shim” APIs is the ChaincodeStubInterface:

Go
Node.js
Java

which is used to access and modify the ledger, and to make invocations between
chaincodes.
In this tutorial using Go chaincode, we will demonstrate the use of these APIs
by implementing a simple chaincode application that manages simple “assets”.

Simple Asset Chaincode¶
Our application is a basic sample chaincode to create assets
(key-value pairs) on the ledger.

Choosing a Location for the Code¶
If you haven’t been doing programming in Go, you may want to make sure that
you have Go installed and your system properly configured.
Now, you will want to create a directory for your chaincode application as a
child directory of $GOPATH/src/.
To keep things simple, let’s use the following command:
mkdir -p $GOPATH/src/sacc && cd $GOPATH/src/sacc

Now, let’s create the source file that we’ll fill in with code:
touch sacc.go

Housekeeping¶
First, let’s start with some housekeeping. As with every chaincode, it implements the
Chaincode interface
in particular, Init and Invoke functions. So, let’s add the Go import
statements for the necessary dependencies for our chaincode. We’ll import the
chaincode shim package and the
peer protobuf package.
Next, let’s add a struct SimpleAsset as a receiver for Chaincode shim functions.
package main

import (
    "fmt"

    "github.com/hyperledger/fabric-chaincode-go/shim"
    "github.com/hyperledger/fabric-protos-go/peer"
)

// SimpleAsset implements a simple chaincode to manage an asset
type SimpleAsset struct {
}

Initializing the Chaincode¶
Next, we’ll implement the Init function.
// Init is called during chaincode instantiation to initialize any data.
func (t *SimpleAsset) Init(stub shim.ChaincodeStubInterface) peer.Response {

}

Note
Note that chaincode upgrade also calls this function. When writing a
chaincode that will upgrade an existing one, make sure to modify the Init
function appropriately. In particular, provide an empty “Init” method if there’s
no “migration” or nothing to be initialized as part of the upgrade.

Next, we’ll retrieve the arguments to the Init call using the
ChaincodeStubInterface.GetStringArgs
function and check for validity. In our case, we are expecting a key-value pair.

// Init is called during chaincode instantiation to initialize any
// data. Note that chaincode upgrade also calls this function to reset
// or to migrate data, so be careful to avoid a scenario where you
// inadvertently clobber your ledger's data!
func (t *SimpleAsset) Init(stub shim.ChaincodeStubInterface) peer.Response {
  // Get the args from the transaction proposal
  args := stub.GetStringArgs()
  if len(args) != 2 {
    return shim.Error("Incorrect arguments. Expecting a key and a value")
  }
}

Next, now that we have established that the call is valid, we’ll store the
initial state in the ledger. To do this, we will call
ChaincodeStubInterface.PutState
with the key and value passed in as the arguments. Assuming all went well,
return a peer.Response object that indicates the initialization was a success.
// Init is called during chaincode instantiation to initialize any
// data. Note that chaincode upgrade also calls this function to reset
// or to migrate data, so be careful to avoid a scenario where you
// inadvertently clobber your ledger's data!
func (t *SimpleAsset) Init(stub shim.ChaincodeStubInterface) peer.Response {
  // Get the args from the transaction proposal
  args := stub.GetStringArgs()
  if len(args) != 2 {
    return shim.Error("Incorrect arguments. Expecting a key and a value")
  }

  // Set up any variables or assets here by calling stub.PutState()

  // We store the key and the value on the ledger
  err := stub.PutState(args[0], []byte(args[1]))
  if err != nil {
    return shim.Error(fmt.Sprintf("Failed to create asset: %s", args[0]))
  }
  return shim.Success(nil)
}

Invoking the Chaincode¶
First, let’s add the Invoke function’s signature.
// Invoke is called per transaction on the chaincode. Each transaction is
// either a 'get' or a 'set' on the asset created by Init function. The 'set'
// method may create a new asset by specifying a new key-value pair.
func (t *SimpleAsset) Invoke(stub shim.ChaincodeStubInterface) peer.Response {

}

As with the Init function above, we need to extract the arguments from the
ChaincodeStubInterface. The Invoke function’s arguments will be the
name of the chaincode application function to invoke. In our case, our application
will simply have two functions: set and get, that allow the value of an
asset to be set or its current state to be retrieved. We first call
ChaincodeStubInterface.GetFunctionAndParameters
to extract the function name and the parameters to that chaincode application
function.
// Invoke is called per transaction on the chaincode. Each transaction is
// either a 'get' or a 'set' on the asset created by Init function. The Set
// method may create a new asset by specifying a new key-value pair.
func (t *SimpleAsset) Invoke(stub shim.ChaincodeStubInterface) peer.Response {
    // Extract the function and args from the transaction proposal
    fn, args := stub.GetFunctionAndParameters()

}

Next, we’ll validate the function name as being either set or get, and
invoke those chaincode application functions, returning an appropriate
response via the shim.Success or shim.Error functions that will
serialize the response into a gRPC protobuf message.
// Invoke is called per transaction on the chaincode. Each transaction is
// either a 'get' or a 'set' on the asset created by Init function. The Set
// method may create a new asset by specifying a new key-value pair.
func (t *SimpleAsset) Invoke(stub shim.ChaincodeStubInterface) peer.Response {
    // Extract the function and args from the transaction proposal
    fn, args := stub.GetFunctionAndParameters()

    var result string
    var err error
    if fn == "set" {
            result, err = set(stub, args)
    } else {
            result, err = get(stub, args)
    }
    if err != nil {
            return shim.Error(err.Error())
    }

    // Return the result as success payload
    return shim.Success([]byte(result))
}

Implementing the Chaincode Application¶
As noted, our chaincode application implements two functions that can be
invoked via the Invoke function. Let’s implement those functions now.
Note that as we mentioned above, to access the ledger’s state, we will leverage
the ChaincodeStubInterface.PutState
and ChaincodeStubInterface.GetState
functions of the chaincode shim API.
// Set stores the asset (both key and value) on the ledger. If the key exists,
// it will override the value with the new one
func set(stub shim.ChaincodeStubInterface, args []string) (string, error) {
    if len(args) != 2 {
            return "", fmt.Errorf("Incorrect arguments. Expecting a key and a value")
    }

    err := stub.PutState(args[0], []byte(args[1]))
    if err != nil {
            return "", fmt.Errorf("Failed to set asset: %s", args[0])
    }
    return args[1], nil
}

// Get returns the value of the specified asset key
func get(stub shim.ChaincodeStubInterface, args []string) (string, error) {
    if len(args) != 1 {
            return "", fmt.Errorf("Incorrect arguments. Expecting a key")
    }

    value, err := stub.GetState(args[0])
    if err != nil {
            return "", fmt.Errorf("Failed to get asset: %s with error: %s", args[0], err)
    }
    if value == nil {
            return "", fmt.Errorf("Asset not found: %s", args[0])
    }
    return string(value), nil
}

Pulling it All Together¶
Finally, we need to add the main function, which will call the
shim.Start
function. Here’s the whole chaincode program source.
package main

import (
    "fmt"

    "github.com/hyperledger/fabric-chaincode-go/shim"
    "github.com/hyperledger/fabric-protos-go/peer"
)

// SimpleAsset implements a simple chaincode to manage an asset
type SimpleAsset struct {
}

// Init is called during chaincode instantiation to initialize any
// data. Note that chaincode upgrade also calls this function to reset
// or to migrate data.
func (t *SimpleAsset) Init(stub shim.ChaincodeStubInterface) peer.Response {
    // Get the args from the transaction proposal
    args := stub.GetStringArgs()
    if len(args) != 2 {
            return shim.Error("Incorrect arguments. Expecting a key and a value")
    }

    // Set up any variables or assets here by calling stub.PutState()

    // We store the key and the value on the ledger
    err := stub.PutState(args[0], []byte(args[1]))
    if err != nil {
            return shim.Error(fmt.Sprintf("Failed to create asset: %s", args[0]))
    }
    return shim.Success(nil)
}

// Invoke is called per transaction on the chaincode. Each transaction is
// either a 'get' or a 'set' on the asset created by Init function. The Set
// method may create a new asset by specifying a new key-value pair.
func (t *SimpleAsset) Invoke(stub shim.ChaincodeStubInterface) peer.Response {
    // Extract the function and args from the transaction proposal
    fn, args := stub.GetFunctionAndParameters()

    var result string
    var err error
    if fn == "set" {
            result, err = set(stub, args)
    } else { // assume 'get' even if fn is nil
            result, err = get(stub, args)
    }
    if err != nil {
            return shim.Error(err.Error())
    }

    // Return the result as success payload
    return shim.Success([]byte(result))
}

// Set stores the asset (both key and value) on the ledger. If the key exists,
// it will override the value with the new one
func set(stub shim.ChaincodeStubInterface, args []string) (string, error) {
    if len(args) != 2 {
            return "", fmt.Errorf("Incorrect arguments. Expecting a key and a value")
    }

    err := stub.PutState(args[0], []byte(args[1]))
    if err != nil {
            return "", fmt.Errorf("Failed to set asset: %s", args[0])
    }
    return args[1], nil
}

// Get returns the value of the specified asset key
func get(stub shim.ChaincodeStubInterface, args []string) (string, error) {
    if len(args) != 1 {
            return "", fmt.Errorf("Incorrect arguments. Expecting a key")
    }

    value, err := stub.GetState(args[0])
    if err != nil {
            return "", fmt.Errorf("Failed to get asset: %s with error: %s", args[0], err)
    }
    if value == nil {
            return "", fmt.Errorf("Asset not found: %s", args[0])
    }
    return string(value), nil
}

// main function starts up the chaincode in the container during instantiate
func main() {
    if err := shim.Start(new(SimpleAsset)); err != nil {
            fmt.Printf("Error starting SimpleAsset chaincode: %s", err)
    }
}

Chaincode access control¶
Chaincode can utilize the client (submitter) certificate for access
control decisions by calling the GetCreator() function. Additionally
the Go shim provides extension APIs that extract client identity
from the submitter’s certificate that can be used for access control decisions,
whether that is based on client identity itself, or the org identity,
or on a client identity attribute.
For example an asset that is represented as a key/value may include the
client’s identity as part of the value (for example as a JSON attribute
indicating that asset owner), and only this client may be authorized
to make updates to the key/value in the future. The client identity
library extension APIs can be used within chaincode to retrieve this
submitter information to make such access control decisions.
See the client identity (CID) library documentation
for more details.
To add the client identity shim extension to your chaincode as a dependency, see Managing external dependencies for chaincode written in Go.

Managing external dependencies for chaincode written in Go¶
Your Go chaincode requires packages (like the chaincode shim) that are not part
of the Go standard library. These packages must be included in your chaincode
package.
There are many tools available
for managing (or “vendoring”) these dependencies.  The following demonstrates how to use
govendor:
govendor init
govendor add +external  // Add all external package, or
govendor add github.com/external/pkg // Add specific external package

This imports the external dependencies into a local vendor directory.
If you are vendoring the Fabric shim or shim extensions, clone the
Fabric repository to your $GOPATH/src/github.com/hyperledger directory,
before executing the govendor commands.
Once dependencies are vendored in your chaincode directory, peer chaincode package
and peer chaincode install operations will then include code associated with the
dependencies into the chaincode package.

Building Your First Network¶

Note
The Build your first network (BYFN) tutorial has been deprecated. If
you are getting started with Hyperledger Fabric and would like to deploy
a basic network, see Using the Fabric test network. If you are deploying Fabric
in production, see the guide for Deploying a production network.

The build your first network (BYFN) scenario provisions a sample Hyperledger
Fabric network consisting of two organizations, each maintaining two peer
nodes. It also will deploy a Raft ordering service by default.

Install prerequisites¶
Before we begin, if you haven’t already done so, you may wish to check that
you have all the Prerequisites installed on the platform(s) on which you’ll be
developing blockchain applications and/or operating Hyperledger Fabric.
You will also need to Install Samples, Binaries, and Docker Images. You will notice that there are a number of
samples included in the fabric-samples repository. We will be using the
first-network sample. Let’s open that sub-directory now.
cd fabric-samples/first-network

Note
The supplied commands in this documentation MUST be run from your
first-network sub-directory of the fabric-samples repository
clone.  If you elect to run the commands from a different location,
the various provided scripts will be unable to find the binaries.

Want to run it now?¶
We provide a fully annotated script — byfn.sh — that leverages these Docker
images to quickly bootstrap a Hyperledger Fabric network that by default is
comprised of four peers representing two different organizations, and a Raft ordering
service. It will also launch a container to run a scripted execution that will join
peers to a channel, deploy a chaincode and drive execution of transactions
against the deployed chaincode.
Here’s the help text for the byfn.sh script:
Usage:
byfn.sh <mode> [-c <channel name>] [-t <timeout>] [-d <delay>] [-f <docker-compose-file>] [-s <dbtype>] [-l <language>] [-o <consensus-type>] [-i <imagetag>] [-v]"
  <mode> - one of 'up', 'down', 'restart', 'generate' or 'upgrade'"
    - 'up' - bring up the network with docker-compose up"
    - 'down' - clear the network with docker-compose down"
    - 'restart' - restart the network"
    - 'generate' - generate required certificates and genesis block"
    - 'upgrade'  - upgrade the network from version 1.3.x to 1.4.0"
  -c <channel name> - channel name to use (defaults to \"mychannel\")"
  -t <timeout> - CLI timeout duration in seconds (defaults to 10)"
  -d <delay> - delay duration in seconds (defaults to 3)"
  -f <docker-compose-file> - specify which docker-compose file use (defaults to docker-compose-cli.yaml)"
  -s <dbtype> - the database backend to use: goleveldb (default) or couchdb"
  -l <language> - the chaincode language: golang (default), javascript, or java"
  -a - launch certificate authorities (no certificate authorities are launched by default)
  -n - do not deploy chaincode (abstore chaincode is deployed by default)
  -i <imagetag> - the tag to be used to launch the network (defaults to \"latest\")"
  -v - verbose mode"
byfn.sh -h (print this message)"

Typically, one would first generate the required certificates and
genesis block, then bring up the network. e.g.:"

  byfn.sh generate -c mychannel"
  byfn.sh up -c mychannel -s couchdb"
  byfn.sh up -c mychannel -s couchdb -i 1.4.0"
  byfn.sh up -l javascript"
  byfn.sh down -c mychannel"
  byfn.sh upgrade -c mychannel"

Taking all defaults:"
      byfn.sh generate"
      byfn.sh up"
      byfn.sh down"

If you choose not to supply a flag, the script will use default values.

Generate Network Artifacts¶
Ready to give it a go? Okay then! Execute the following command:
./byfn.sh generate

You will see a brief description as to what will occur, along with a yes/no command line
prompt. Respond with a y or hit the return key to execute the described action.
Generating certs and genesis block for channel 'mychannel' with CLI timeout of '10' seconds and CLI delay of '3' seconds
Continue? [Y/n] y
proceeding ...
/Users/xxx/dev/fabric-samples/bin/cryptogen

##########################################################
##### Generate certificates using cryptogen tool #########
##########################################################
org1.example.com
2017-06-12 21:01:37.334 EDT [bccsp] GetDefault -> WARN 001 Before using BCCSP, please call InitFactories(). Falling back to bootBCCSP.
...

/Users/xxx/dev/fabric-samples/bin/configtxgen
##########################################################
#########  Generating Orderer Genesis block ##############
##########################################################
2017-06-12 21:01:37.558 EDT [common/configtx/tool] main -> INFO 001 Loading configuration
2017-06-12 21:01:37.562 EDT [msp] getMspConfig -> INFO 002 intermediate certs folder not found at [/Users/xxx/dev/byfn/crypto-config/ordererOrganizations/example.com/msp/intermediatecerts]. Skipping.: [stat /Users/xxx/dev/byfn/crypto-config/ordererOrganizations/example.com/msp/intermediatecerts: no such file or directory]
...
2017-06-12 21:01:37.588 EDT [common/configtx/tool] doOutputBlock -> INFO 00b Generating genesis block
2017-06-12 21:01:37.590 EDT [common/configtx/tool] doOutputBlock -> INFO 00c Writing genesis block

#################################################################
### Generating channel configuration transaction 'channel.tx' ###
#################################################################
2017-06-12 21:01:37.634 EDT [common/configtx/tool] main -> INFO 001 Loading configuration
2017-06-12 21:01:37.644 EDT [common/configtx/tool] doOutputChannelCreateTx -> INFO 002 Generating new channel configtx
2017-06-12 21:01:37.645 EDT [common/configtx/tool] doOutputChannelCreateTx -> INFO 003 Writing new channel tx

#################################################################
#######    Generating anchor peer update for Org1MSP   ##########
#################################################################
2017-06-12 21:01:37.674 EDT [common/configtx/tool] main -> INFO 001 Loading configuration
2017-06-12 21:01:37.678 EDT [common/configtx/tool] doOutputAnchorPeersUpdate -> INFO 002 Generating anchor peer update
2017-06-12 21:01:37.679 EDT [common/configtx/tool] doOutputAnchorPeersUpdate -> INFO 003 Writing anchor peer update

#################################################################
#######    Generating anchor peer update for Org2MSP   ##########
#################################################################
2017-06-12 21:01:37.700 EDT [common/configtx/tool] main -> INFO 001 Loading configuration
2017-06-12 21:01:37.704 EDT [common/configtx/tool] doOutputAnchorPeersUpdate -> INFO 002 Generating anchor peer update
2017-06-12 21:01:37.704 EDT [common/configtx/tool] doOutputAnchorPeersUpdate -> INFO 003 Writing anchor peer update

This first step generates all of the certificates and keys for our various
network entities, the genesis block used to bootstrap the ordering service,
and a collection of configuration transactions required to configure a
Channel.

Bring Up the Network¶
Next, you can bring the network up with one of the following commands:
./byfn.sh up

The above command will compile Go chaincode images and spin up the corresponding
containers. Go is the default chaincode language, however there is also support
for Node.js and Java
chaincode. If you’d like to run through this tutorial with node chaincode, pass
the following command instead:
# we use the -l flag to specify the chaincode language
# forgoing the -l flag will default to "golang"

./byfn.sh up -l javascript

Note
For more information on the Node.js shim, please refer to its
documentation.

Note
For more information on the Java shim, please refer to its
documentation.

Тo make the sample run with Java chaincode, you have to specify -l java as follows:
./byfn.sh up -l java

Note
Do not run both of these commands. Only one language can be tried unless
you bring down and recreate the network between.

You will be prompted as to whether you wish to continue or abort.
Respond with a y or hit the return key:
Starting for channel 'mychannel' with CLI timeout of '10' seconds and CLI delay of '3' seconds
Continue? [Y/n]
proceeding ...
Creating network "net_byfn" with the default driver
Creating peer0.org1.example.com
Creating peer1.org1.example.com
Creating peer0.org2.example.com
Creating orderer.example.com
Creating peer1.org2.example.com
Creating cli

 ____    _____      _      ____    _____
/ ___|  |_   _|    / \    |  _ \  |_   _|
\___ \    | |     / _ \   | |_) |   | |
 ___) |   | |    / ___ \  |  _ <    | |
|____/    |_|   /_/   \_\ |_| \_\   |_|

Channel name : mychannel
Creating channel...

The logs will continue from there. This will launch all of the containers, and
then drive a complete end-to-end application scenario. Upon successful
completion, it should report the following in your terminal window:
Query Result: 90
2017-05-16 17:08:15.158 UTC [main] main -> INFO 008 Exiting.....
===================== Query successful on peer1.org2 on channel 'mychannel' =====================

===================== All GOOD, BYFN execution completed =====================

 _____   _   _   ____
| ____| | \ | | |  _ \
|  _|   |  \| | | | | |
| |___  | |\  | | |_| |
|_____| |_| \_| |____/

You can scroll through these logs to see the various transactions. If you don’t
get this result, then jump down to the Troubleshooting section and let’s see
whether we can help you discover what went wrong.

Bring Down the Network¶
Finally, let’s bring it all down so we can explore the network setup one step
at a time. The following will kill your containers, remove the crypto material
and four artifacts, and delete the chaincode images from your Docker Registry:
./byfn.sh down

Once again, you will be prompted to continue, respond with a y or hit the return key:
Stopping with channel 'mychannel' and CLI timeout of '10'
Continue? [Y/n] y
proceeding ...
WARNING: The CHANNEL_NAME variable is not set. Defaulting to a blank string.
WARNING: The TIMEOUT variable is not set. Defaulting to a blank string.
Removing network net_byfn
468aaa6201ed
...
Untagged: dev-peer1.org2.example.com-mycc-1.0:latest
Deleted: sha256:ed3230614e64e1c83e510c0c282e982d2b06d148b1c498bbdcc429e2b2531e91
...

If you’d like to learn more about the underlying tooling and bootstrap mechanics,
continue reading.  In these next sections we’ll walk through the various steps
and requirements to build a fully-functional Hyperledger Fabric network.

Note
The manual steps outlined below assume that the FABRIC_LOGGING_SPEC in
the cli container is set to DEBUG. You can set this by modifying
the docker-compose-cli.yaml file in the first-network directory.
e.g.
cli:
  container_name: cli
  image: hyperledger/fabric-tools:$IMAGE_TAG
  tty: true
  stdin_open: true
  environment:
    - GOPATH=/opt/gopath
    - CORE_VM_ENDPOINT=unix:///host/var/run/docker.sock
    - FABRIC_LOGGING_SPEC=DEBUG
    #- FABRIC_LOGGING_SPEC=INFO

Crypto Generator¶
We will use the cryptogen tool to generate the cryptographic material
(x509 certs and signing keys) for our various network entities.  These certificates are
representative of identities, and they allow for sign/verify authentication to
take place as our entities communicate and transact.

How does it work?¶
Cryptogen consumes a file — crypto-config.yaml — that contains the network
topology and allows us to generate a set of certificates and keys for both the
Organizations and the components that belong to those Organizations.  Each
Organization is provisioned a unique root certificate (ca-cert) that binds
specific components (peers and orderers) to that Org.  By assigning each
Organization a unique CA certificate, we are mimicking a typical network where
a participating Member would use its own Certificate Authority.
Transactions and communications within Hyperledger Fabric are signed by an
entity’s private key (keystore), and then verified by means of a public
key (signcerts).
You will notice a count variable within this file. We use this to specify
the number of peers per Organization; in our case there are two peers per Org.
We won’t delve into the minutiae of x.509 certificates and public key
infrastructure
right now. If you’re interested, you can peruse these topics on your own time.
After we run the cryptogen tool, the generated certificates and keys will be
saved to a folder titled crypto-config. Note that the crypto-config.yaml
file lists five orderers as being tied to the orderer organization. While the
cryptogen tool will create certificates for all five of these orderers. These orderers
will be used in a etcdraft ordering service implementation and be used to create the
system channel and mychannel.

Configuration Transaction Generator¶
The configtxgen tool is used to create four configuration artifacts:

orderer genesis block,
channel configuration transaction,
and two anchor peer transactions - one for each Peer Org.

Please see configtxgen for a complete description of this tool’s functionality.
The orderer block is the Genesis Block for the ordering service, and the
channel configuration transaction file is broadcast to the orderer at Channel creation
time.  The anchor peer transactions, as the name might suggest, specify each
Org’s Anchor Peer on this channel.

How does it work?¶
Configtxgen consumes a file - configtx.yaml - that contains the definitions
for the sample network. There are three members - one Orderer Org (OrdererOrg)
and two Peer Orgs (Org1 & Org2) each managing and maintaining two peer nodes.
This file also specifies a consortium - SampleConsortium - consisting of our
two Peer Orgs.  Pay specific attention to the “Profiles” section at the bottom of
this file. You will notice that we have several unique profiles. A few are worth
noting:

SampleMultiNodeEtcdRaft: generates the genesis block for a Raft ordering
service. Only used if you issue the -o flag and specify etcdraft.
TwoOrgsChannel: generates the genesis block for our channel, mychannel.

These headers are important, as we will pass them in as arguments when we create
our artifacts.

Note
Notice that our SampleConsortium is defined in
the system-level profile and then referenced by
our channel-level profile.  Channels exist within
the purview of a consortium, and all consortia
must be defined in the scope of the network at
large.

This file also contains two additional specifications that are worth
noting. Firstly, we specify the anchor peers for each Peer Org
(peer0.org1.example.com & peer0.org2.example.com).  Secondly, we point to
the location of the MSP directory for each member, in turn allowing us to store the
root certificates for each Org in the orderer genesis block.  This is a critical
concept. Now any network entity communicating with the ordering service can have
its digital signature verified.

Run the tools¶
You can manually generate the certificates/keys and the various configuration
artifacts using the configtxgen and cryptogen commands. Alternately,
you could try to adapt the byfn.sh script to accomplish your objectives.

Manually generate the artifacts¶
You can refer to the generateCerts function in the byfn.sh script for the
commands necessary to generate the certificates that will be used for your
network configuration as defined in the crypto-config.yaml file. However,
for the sake of convenience, we will also provide a reference here.
First let’s run the cryptogen tool.  Our binary is in the bin
directory, so we need to provide the relative path to where the tool resides.
../bin/cryptogen generate --config=./crypto-config.yaml

You should see the following in your terminal:
org1.example.com
org2.example.com

The certs and keys (i.e. the MSP material) will be output into a directory - crypto-config -
at the root of the first-network directory.
Next, we need to tell the configtxgen tool where to look for the
configtx.yaml file that it needs to ingest.  We will tell it look in our
present working directory:
export FABRIC_CFG_PATH=$PWD

Then, we’ll invoke the configtxgen tool to create the orderer genesis block:
../bin/configtxgen -profile SampleMultiNodeEtcdRaft -channelID byfn-sys-channel -outputBlock ./channel-artifacts/genesis.block

Note
The orderer genesis block and the subsequent artifacts we are about to create
will be output into the channel-artifacts directory at the root of the
first-network directory. The channelID in the above command is the
name of the system channel.

Create a Channel Configuration Transaction¶
Next, we need to create the channel transaction artifact. Be sure to replace $CHANNEL_NAME or
set CHANNEL_NAME as an environment variable that can be used throughout these instructions:
# The channel.tx artifact contains the definitions for our sample channel

export CHANNEL_NAME=mychannel  && ../bin/configtxgen -profile TwoOrgsChannel -outputCreateChannelTx ./channel-artifacts/channel.tx -channelID $CHANNEL_NAME

Note that the TwoOrgsChannel profile will use the ordering service
configuration you specified when creating the genesis block for the network.
You should see an output similar to the following in your terminal:
2017-10-26 19:24:05.324 EDT [common/tools/configtxgen] main -> INFO 001 Loading configuration
2017-10-26 19:24:05.329 EDT [common/tools/configtxgen] doOutputChannelCreateTx -> INFO 002 Generating new channel configtx
2017-10-26 19:24:05.329 EDT [common/tools/configtxgen] doOutputChannelCreateTx -> INFO 003 Writing new channel tx

Next, we will define the anchor peer for Org1 on the channel that we are
constructing. Again, be sure to replace $CHANNEL_NAME or set the environment
variable for the following commands.  The terminal output will mimic that of the
channel transaction artifact:
../bin/configtxgen -profile TwoOrgsChannel -outputAnchorPeersUpdate ./channel-artifacts/Org1MSPanchors.tx -channelID $CHANNEL_NAME -asOrg Org1MSP

Now, we will define the anchor peer for Org2 on the same channel:
../bin/configtxgen -profile TwoOrgsChannel -outputAnchorPeersUpdate ./channel-artifacts/Org2MSPanchors.tx -channelID $CHANNEL_NAME -asOrg Org2MSP

Start the network¶

Note
If you ran the byfn.sh example above previously, be sure that you
have brought down the test network before you proceed (see
Bring Down the Network).

We will leverage a script to spin up our network. The
docker-compose file references the images that we have previously downloaded,
and bootstraps the orderer with our previously generated genesis.block.
We want to go through the commands manually in order to expose the
syntax and functionality of each call.
First let’s start our network:
docker-compose -f docker-compose-cli.yaml -f docker-compose-etcdraft2.yaml up -d

If you want to see the realtime logs for your network, then do not supply the -d flag.
If you let the logs stream, then you will need to open a second terminal to execute the CLI calls.

Create & Join Channel¶
Recall that we created the channel configuration transaction using the
configtxgen tool in the Create a Channel Configuration Transaction section, above. You can
repeat that process to create additional channel configuration transactions,
using the same or different profiles in the configtx.yaml that you pass
to the configtxgen tool. Then you can repeat the process defined in this
section to establish those other channels in your network.
We will enter the CLI container using the docker exec command:
docker exec -it cli bash

If successful you should see the following:
bash-5.0#

For the following CLI commands against peer0.org1.example.com to work, we need
to preface our commands with the four environment variables given below.  These
variables for peer0.org1.example.com are baked into the CLI container,
therefore we can operate without passing them. HOWEVER, if you want to send
calls to other peers or the orderer, keep the CLI container defaults targeting
peer0.org1.example.com, but override the environment variables as seen in the
example below when you make any CLI calls:
# Environment variables for PEER0

CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
CORE_PEER_ADDRESS=peer0.org1.example.com:7051
CORE_PEER_LOCALMSPID="Org1MSP"
CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt

Next, we are going to pass in the generated channel configuration transaction
artifact that we created in the Create a Channel Configuration Transaction section (we called
it channel.tx) to the orderer as part of the create channel request.
We specify our channel name with the -c flag and our channel configuration
transaction with the -f flag. In this case it is channel.tx, however
you can mount your own configuration transaction with a different name.  Once again
we will set the CHANNEL_NAME environment variable within our CLI container so that
we don’t have to explicitly pass this argument. Channel names must be all lower
case, less than 250 characters long and match the regular expression
[a-z][a-z0-9.-]*.
export CHANNEL_NAME=mychannel

# the channel.tx file is mounted in the channel-artifacts directory within your CLI container
# as a result, we pass the full path for the file
# we also pass the path for the orderer ca-cert in order to verify the TLS handshake
# be sure to export or replace the $CHANNEL_NAME variable appropriately

peer channel create -o orderer.example.com:7050 -c $CHANNEL_NAME -f ./channel-artifacts/channel.tx --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Note
Notice the --cafile that we pass as part of this command.  It is
the local path to the orderer’s root cert, allowing us to verify the
TLS handshake.

This command returns a genesis block - <CHANNEL_NAME.block> - which we will use to join the channel.
It contains the configuration information specified in channel.tx  If you have not
made any modifications to the default channel name, then the command will return you a
proto titled mychannel.block.

Note
You will remain in the CLI container for the remainder of
these manual commands. You must also remember to preface all commands
with the corresponding environment variables when targeting a peer other than
peer0.org1.example.com.

Now let’s join peer0.org1.example.com to the channel.
# By default, this joins ``peer0.org1.example.com`` only
# the <CHANNEL_NAME.block> was returned by the previous command
# if you have not modified the channel name, you will join with mychannel.block
# if you have created a different channel name, then pass in the appropriately named block

 peer channel join -b mychannel.block

You can make other peers join the channel as necessary by making appropriate
changes in the four environment variables we used in the Create & Join Channel
section, above.
Rather than join every peer, we will simply join peer0.org2.example.com so that
we can properly update the anchor peer definitions in our channel.  Since we are
overriding the default environment variables baked into the CLI container, this full
command will be the following:
CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp CORE_PEER_ADDRESS=peer0.org2.example.com:9051 CORE_PEER_LOCALMSPID="Org2MSP" CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt peer channel join -b mychannel.block

Alternatively, you could choose to set these environment variables individually
rather than passing in the entire string.  Once they’ve been set, you simply need
to issue the peer channel join command again and the CLI container will act
on behalf of peer0.org2.example.com.

Update the anchor peers¶
The following commands are channel updates and they will propagate to the definition
of the channel.  In essence, we adding additional configuration information on top
of the channel’s genesis block.  Note that we are not modifying the genesis block, but
simply adding deltas into the chain that will define the anchor peers.
Update the channel definition to define the anchor peer for Org1 as peer0.org1.example.com:
peer channel update -o orderer.example.com:7050 -c $CHANNEL_NAME -f ./channel-artifacts/Org1MSPanchors.tx --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Now update the channel definition to define the anchor peer for Org2 as peer0.org2.example.com.
Identically to the peer channel join command for the Org2 peer, we will need to
preface this call with the appropriate environment variables.
CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp CORE_PEER_ADDRESS=peer0.org2.example.com:9051 CORE_PEER_LOCALMSPID="Org2MSP" CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt peer channel update -o orderer.example.com:7050 -c $CHANNEL_NAME -f ./channel-artifacts/Org2MSPanchors.tx --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Install and define a chaincode¶

Note
We will utilize a simple existing chaincode. To learn how to write
your own chaincode, see the Chaincode for Developers tutorial.

Note
These instructions use the Fabric chaincode lifecycle introduced in
the v2.0 release. If you would like to use the previous lifecycle to
install and instantiate a chaincode, visit the v1.4 version of the
Building your first network tutorial.

Applications interact with the blockchain ledger through chaincode.
Therefore we need to install a chaincode on every peer that will execute and
endorse our transactions. However, before we can interact with our chaincode,
the members of the channel need to agree on a chaincode definition that
establishes chaincode governance.
We need to package the chaincode before it can be installed on our peers. For
each package you create, you need to provide a chaincode package label as a
description of the chaincode. Use the following commands to package a sample
Go, Node.js or Java chaincode.
Go
# before packaging Go chaincode, vendoring Go dependencies is required like the following commands.
cd /opt/gopath/src/github.com/hyperledger/fabric-samples/chaincode/abstore/go
GO111MODULE=on go mod vendor
cd -

# this packages a Go chaincode.
# make note of the --lang flag to indicate "golang" chaincode
# for Go chaincode --path takes the relative path from $GOPATH/src
# The --label flag is used to create the package label
peer lifecycle chaincode package mycc.tar.gz --path github.com/hyperledger/fabric-samples/chaincode/abstore/go/ --lang golang --label mycc_1

Node.js
# this packages a Node.js chaincode
# make note of the --lang flag to indicate "node" chaincode
# for node chaincode --path takes the absolute path to the Node.js chaincode
# The --label flag is used to create the package label
peer lifecycle chaincode package mycc.tar.gz --path /opt/gopath/src/github.com/hyperledger/fabric-samples/chaincode/abstore/javascript/ --lang node --label mycc_1

Java
# this packages a java chaincode
# make note of the --lang flag to indicate "java" chaincode
# for java chaincode --path takes the absolute path to the Java chaincode
# The --label flag is used to create the package label
peer lifecycle chaincode package mycc.tar.gz --path /opt/gopath/src/github.com/hyperledger/fabric-samples/chaincode/abstore/java/ --lang java --label mycc_1

Each of the above commands will create a chaincode package named mycc.tar.gz,
which we can use to install the chaincode on our peers. Issue the following
command to install the package on peer0 of Org1.
# this command installs a chaincode package on your peer
peer lifecycle chaincode install mycc.tar.gz

A successful install command will return a chaincode package identifier. You
should see output similar to the following:
2019-03-13 13:48:53.691 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 001 Installed remotely: response:<status:200 payload:"\nEmycc_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173" >
2019-03-13 13:48:53.691 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 002 Chaincode code package identifier: mycc_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173

You can also find the chaincode package identifier by querying your peer for
information about the packages you have installed.
# this returns the details of the chaincode packages installed on your peers
peer lifecycle chaincode queryinstalled

The command above will return the same package identifier as the install command.
You should see output similar to the following:
Get installed chaincodes on peer:
Package ID: mycc_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173, Label: mycc_1

We are going to need the package ID for future commands, so let’s go ahead and
save it as an environment variable. Paste the package ID returned by the
peer lifecycle chaincode queryinstalled command into the command below. The
package ID may not be the same for all users, so you need to complete this step
using the package ID returned from your console.
# Save the package ID as an environment variable.

CC_PACKAGE_ID=mycc_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173

The endorsement policy of mycc will be set to require endorsements from a
peer in both Org1 and Org2. Therefore, we also need to install the chaincode on
a peer in Org2.
Modify the following four environment variables to issue the install command
as Org2:
# Environment variables for PEER0 in Org2

CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
CORE_PEER_ADDRESS=peer0.org2.example.com:9051
CORE_PEER_LOCALMSPID="Org2MSP"
CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt

Now install the chaincode package onto peer0 of Org2. The following command
will install the chaincode and return same identifier as the install command we
issued as Org1.
# this installs a chaincode package on your peer
peer lifecycle chaincode install mycc.tar.gz

After you install the package, you need to approve a chaincode definition
for your organization. The chaincode definition includes the important
parameters of chaincode governance, including the chaincode name and version.
The definition also includes the package identifier used to associate the
chaincode package installed on your peers with a chaincode definition approved
by your organization.
Because we set the environment variables to operate as Org2, we can use the
following command to approve a definition of the mycc chaincode for
Org2. The approval is distributed to peers within each organization, so
the command does not need to target every peer within an organization.
# this approves a chaincode definition for your org
# make note of the --package-id flag that provides the package ID
# use the --init-required flag to request the ``Init`` function be invoked to initialize the chaincode
peer lifecycle chaincode approveformyorg --channelID $CHANNEL_NAME --name mycc --version 1.0 --init-required --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

We could have provided a --signature-policy or --channel-config-policy
argument to the command above to set the chaincode endorsement policy. The
endorsement policy specifies how many peers belonging to different channel
members need to validate a transaction against a given chaincode. Because we did
not set a policy, the definition of mycc will use the default endorsement
policy, which requires that a transaction be endorsed by a majority of channel
members present when the transaction is submitted. This implies that if new
organizations are added to or removed from the channel, the endorsement policy
is updated automatically to require more or fewer endorsements. In this tutorial,
the default policy will require an endorsement from a peer belonging to Org1
AND Org2 (i.e. two endorsements). See the Endorsement policies
documentation for more details on policy implementation.
All organizations need to agree on the definition before they can use the
chaincode. Modify the following four environment variables to operate as Org1:
# Environment variables for PEER0

CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
CORE_PEER_ADDRESS=peer0.org1.example.com:7051
CORE_PEER_LOCALMSPID="Org1MSP"
CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt

You can now approve a definition for the mycc chaincode as Org1. Chaincode is
approved at the organization level. You can issue the command once even if you
have multiple peers.
# this defines a chaincode for your org
# make note of the --package-id flag that provides the package ID
# use the --init-required flag to request the Init function be invoked to initialize the chaincode
peer lifecycle chaincode approveformyorg --channelID $CHANNEL_NAME --name mycc --version 1.0 --init-required --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Once a sufficient number of channel members have approved a chaincode definition,
one member can commit the definition to the channel. By default a majority of
channel members need to approve a definition before it can be committed. It is
possible to check whether the chaincode definition is ready to be committed and
view the current approvals by organization by issuing the following query:
# the flags used for this command are identical to those used for approveformyorg
# except for --package-id which is not required since it is not stored as part of
# the definition
peer lifecycle chaincode checkcommitreadiness --channelID $CHANNEL_NAME --name mycc --version 1.0 --init-required --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --output json

The command will produce as output a JSON map showing if the organizations in the
channel have approved the chaincode definition provided in the checkcommitreadiness
command. In this case, given that both organizations have approved, we obtain:
{
        "Approvals": {
                "Org1MSP": true,
                "Org2MSP": true
        }
}

Since both channel members have approved the definition, we can now commit it to
the channel using the following command. You can issue this command as either
Org1 or Org2. Note that the transaction targets peers in Org1 and Org2 to
collect endorsements.
# this commits the chaincode definition to the channel
peer lifecycle chaincode commit -o orderer.example.com:7050 --channelID $CHANNEL_NAME --name mycc --version 1.0 --sequence 1 --init-required --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt

Invoking the chaincode¶
After a chaincode definition has been committed to a channel, we are ready to
invoke the chaincode and start interacting with the ledger. We requested the
execution of the Init function in the chaincode definition using the
--init-required flag. As a result, we need to pass the --isInit flag to
its first invocation and supply the arguments to the Init function. Issue the
following command to initialize the chaincode and put the initial data on the
ledger.
# be sure to set the -C and -n flags appropriately
# use the --isInit flag if you are invoking an Init function
peer chaincode invoke -o orderer.example.com:7050 --isInit --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n mycc --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["Init","a","100","b","100"]}' --waitForEvent

The first invoke will start the chaincode container. We may need to wait for the
container to start. Node.js images will take longer.

Query¶
Let’s query the chaincode to make sure that the container was properly started
and the state DB was populated. The syntax for query is as follows:
# be sure to set the -C and -n flags appropriately

peer chaincode query -C $CHANNEL_NAME -n mycc -c '{"Args":["query","a"]}'

Invoke¶
Now let’s move 10 from a to b. This transaction will cut a new block
and update the state DB. The syntax for invoke is as follows:
# be sure to set the -C and -n flags appropriately
peer chaincode invoke -o orderer.example.com:7050 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n mycc --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["invoke","a","b","10"]}' --waitForEvent

Query¶
Let’s confirm that our previous invocation executed properly. We initialized the
key a with a value of 100 and just removed 10 with our previous
invocation. Therefore, a query against a should return 90. The syntax
for query is as follows.
# be sure to set the -C and -n flags appropriately

peer chaincode query -C $CHANNEL_NAME -n mycc -c '{"Args":["query","a"]}'

We should see the following:
Query Result: 90

Install the chaincode on an additional peer¶
If you want additional peers to interact with the ledger, then you will need to
join them to the channel and install the same chaincode package on the peers.
You only need to approve the chaincode definition once from your organization.
A chaincode container will be launched for each peer as soon as they try to
interact with that specific chaincode. Again, be cognizant of the fact that the
Node.js images will be slower to build and start upon the first invoke.
We will install the chaincode on a third peer, peer1 in Org2. Modify the
following four environment variables to issue the install command against peer1
in Org2:
# Environment variables for PEER1 in Org2

CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
CORE_PEER_ADDRESS=peer1.org2.example.com:10051
CORE_PEER_LOCALMSPID="Org2MSP"
CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer1.org2.example.com/tls/ca.crt

Now install the mycc package on peer1 of Org2:
# this command installs a chaincode package on your peer
peer lifecycle chaincode install mycc.tar.gz

Query¶
Let’s confirm that we can issue the query to Peer1 in Org2. We initialized the
key a with a value of 100 and just removed 10 with our previous
invocation. Therefore, a query against a should still return 90.
Peer1 in Org2 must first join the channel before it can respond to queries. The
channel can be joined by issuing the following command:
CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp CORE_PEER_ADDRESS=peer1.org2.example.com:10051 CORE_PEER_LOCALMSPID="Org2MSP" CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer1.org2.example.com/tls/ca.crt peer channel join -b mychannel.block

After the join command returns, the query can be issued. The syntax for query is
as follows.
# be sure to set the -C and -n flags appropriately

peer chaincode query -C $CHANNEL_NAME -n mycc -c '{"Args":["query","a"]}'

We should see the following:
Query Result: 90

If you received an error, it may be because it takes a few seconds for the
peer to join and catch up to the current blockchain height. You may
re-query as needed. Feel free to perform additional invokes as well.

What’s happening behind the scenes?¶

Note
These steps describe the scenario in which
script.sh is run by ‘./byfn.sh up’.  Clean your network
with ./byfn.sh down and ensure
this command is active.  Then use the same
docker-compose prompt to launch your network again

A script - script.sh - is baked inside the CLI container. The
script drives the createChannel command against the supplied channel name
and uses the channel.tx file for channel configuration.
The output of createChannel is a genesis block -
<your_channel_name>.block - which gets stored on the peers’ file systems and contains
the channel configuration specified from channel.tx.
The joinChannel command is exercised for all four peers, which takes as
input the previously generated genesis block.  This command instructs the
peers to join <your_channel_name> and create a chain starting with <your_channel_name>.block.
Now we have a channel consisting of four peers, and two
organizations.  This is our TwoOrgsChannel profile.
peer0.org1.example.com and peer1.org1.example.com belong to Org1;
peer0.org2.example.com and peer1.org2.example.com belong to Org2
These relationships are defined through the crypto-config.yaml and
the MSP path is specified in our docker compose.
The anchor peers for Org1MSP (peer0.org1.example.com) and
Org2MSP (peer0.org2.example.com) are then updated.  We do this by passing
the Org1MSPanchors.tx and Org2MSPanchors.tx artifacts to the ordering
service along with the name of our channel.
A chaincode - abstore - is packaged and installed on peer0.org1.example.com
and peer0.org2.example.com
The chaincode is then separately approved by Org1 and Org2, and then committed
on the channel. Since an endorsement policy was not specified, the channel’s
default endorsement policy of a majority of organizations will get utilized,
meaning that any transaction must be endorsed by a peer tied to Org1 and Org2.
The chaincode Init is then called which starts the container for the target peer,
and initializes the key value pairs associated with the chaincode.  The initial
values for this example are [“a”,”100” “b”,”200”]. This first invoke results
in a container by the name of dev-peer0.org2.example.com-mycc-1.0 starting.
A query against the value of “a” is issued to peer0.org2.example.com.
A container for Org2 peer0 by the name of dev-peer0.org2.example.com-mycc-1.0
was started when the chaincode was initialized. The result of the query is
returned. No write operations have occurred, so a query against “a” will
still return a value of “100”.
An invoke is sent to peer0.org1.example.com and peer0.org2.example.com
to move “10” from “a” to “b”
A query is sent to peer0.org2.example.com for the value of “a”. A
value of 90 is returned, correctly reflecting the previous
transaction during which the value for key “a” was modified by 10.
The chaincode - abstore - is installed on peer1.org2.example.com
A query is sent to peer1.org2.example.com for the value of “a”. This starts a
third chaincode container by the name of dev-peer1.org2.example.com-mycc-1.0. A
value of 90 is returned, correctly reflecting the previous
transaction during which the value for key “a” was modified by 10.

What does this demonstrate?¶
Chaincode MUST be installed on a peer in order for it to
successfully perform read/write operations against the ledger.
Furthermore, a chaincode container is not started for a peer until an init or
traditional transaction - read/write - is performed against that chaincode (e.g. query for
the value of “a”). The transaction causes the container to start. Also,
all peers in a channel maintain an exact copy of the ledger which
comprises the blockchain to store the immutable, sequenced record in
blocks, as well as a state database to maintain a snapshot of the current state.
This includes those peers that do not have chaincode installed on them
(like peer1.org1.example.com in the above example) . Finally, the chaincode is accessible
after it is installed (like peer1.org2.example.com in the above example) because its
definition has already been committed on the channel.

How do I see these transactions?¶
Check the logs for the CLI Docker container.
docker logs -f cli

You should see the following output:
2017-05-16 17:08:01.366 UTC [msp] GetLocalMSP -> DEBU 004 Returning existing local MSP
2017-05-16 17:08:01.366 UTC [msp] GetDefaultSigningIdentity -> DEBU 005 Obtaining default signing identity
2017-05-16 17:08:01.366 UTC [msp/identity] Sign -> DEBU 006 Sign: plaintext: 0AB1070A6708031A0C08F1E3ECC80510...6D7963631A0A0A0571756572790A0161
2017-05-16 17:08:01.367 UTC [msp/identity] Sign -> DEBU 007 Sign: digest: E61DB37F4E8B0D32C9FE10E3936BA9B8CD278FAA1F3320B08712164248285C54
Query Result: 90
2017-05-16 17:08:15.158 UTC [main] main -> INFO 008 Exiting.....
===================== Query successful on peer1.org2 on channel 'mychannel' =====================

===================== All GOOD, BYFN execution completed =====================

 _____   _   _   ____
| ____| | \ | | |  _ \
|  _|   |  \| | | | | |
| |___  | |\  | | |_| |
|_____| |_| \_| |____/

You can scroll through these logs to see the various transactions.

How can I see the chaincode logs?¶
You can inspect the individual chaincode containers to see the separate
transactions executed against each container. Use the following command to find
the list of running containers to find your chaincode containers:
$ docker ps -a
CONTAINER ID        IMAGE                                                                                                                                                                 COMMAND                  CREATED              STATUS              PORTS                                NAMES
7aa7d9e199f5        dev-peer1.org2.example.com-mycc_1-27ef99cb3cbd1b545063f018f3670eddc0d54f40b2660b8f853ad2854c49a0d8-2eba360c66609a3ba78327c2c86bc3abf041c78f5a35553191a1acf1efdd5a0d   "chaincode -peer.add…"   About a minute ago   Up About a minute                                        dev-peer1.org2.example.com-mycc_1-27ef99cb3cbd1b545063f018f3670eddc0d54f40b2660b8f853ad2854c49a0d8
82ce129c0fe6        dev-peer0.org2.example.com-mycc_1-27ef99cb3cbd1b545063f018f3670eddc0d54f40b2660b8f853ad2854c49a0d8-1297906045aa77086daba21aba47e8eef359f9498b7cb2b010dff3e2a354565a   "chaincode -peer.add…"   About a minute ago   Up About a minute                                        dev-peer0.org2.example.com-mycc_1-27ef99cb3cbd1b545063f018f3670eddc0d54f40b2660b8f853ad2854c49a0d8
eaef1a8f7acf        dev-peer0.org1.example.com-mycc_1-27ef99cb3cbd1b545063f018f3670eddc0d54f40b2660b8f853ad2854c49a0d8-00d8dbefd85a4aeb9428b7df95df9744be1325b2a60900ac7a81796e67e4280a   "chaincode -peer.add…"   2 minutes ago        Up 2 minutes                                             dev-peer0.org1.example.com-mycc_1-27ef99cb3cbd1b545063f018f3670eddc0d54f40b2660b8f853ad2854c49a0d8
da403175b785        hyperledger/fabric-tools:latest                                                                                                                                       "/bin/bash"              4 minutes ago        Up 4 minutes                                             cli
c62a8d03818f        hyperledger/fabric-peer:latest                                                                                                                                        "peer node start"        4 minutes ago        Up 4 minutes        7051/tcp, 0.0.0.0:9051->9051/tcp     peer0.org2.example.com
06593c4f3e53        hyperledger/fabric-peer:latest                                                                                                                                        "peer node start"        4 minutes ago        Up 4 minutes        0.0.0.0:7051->7051/tcp               peer0.org1.example.com
4ddc928ebffe        hyperledger/fabric-orderer:latest                                                                                                                                     "orderer"                4 minutes ago        Up 4 minutes        0.0.0.0:7050->7050/tcp               orderer.example.com
6d79e95ec059        hyperledger/fabric-peer:latest                                                                                                                                        "peer node start"        4 minutes ago        Up 4 minutes        7051/tcp, 0.0.0.0:10051->10051/tcp   peer1.org2.example.com
6aad6b40fd30        hyperledger/fabric-peer:latest                                                                                                                                        "peer node start"        4 minutes ago        Up 4 minutes        7051/tcp, 0.0.0.0:8051->8051/tcp     peer1.org1.example.com

The chaincode containers are the images starting with dev-peer. You can then
use the container ID to find the logs from each chaincode container.
$ docker logs 7aa7d9e199f5
ABstore Init
Aval = 100, Bval = 100
ABstore Invoke
Aval = 90, Bval = 110

$ docker logs eaef1a8f7acf
ABstore Init
Aval = 100, Bval = 100
ABstore Invoke
Query Response:{"Name":"a","Amount":"100"}
ABstore Invoke
Aval = 90, Bval = 110
ABstore Invoke
Query Response:{"Name":"a","Amount":"90"}

You can also see the peer logs to view chaincode invoke messages
and block commit messages:
$ docker logs peer0.org1.example.com

Understanding the Docker Compose topology¶
The BYFN sample offers us two flavors of Docker Compose files, both of which
are extended from the docker-compose-base.yaml (located in the base
folder).  Our first flavor, docker-compose-cli.yaml, provides us with a
CLI container, along with an orderer, four peers.  We use this file
for the entirety of the instructions on this page.

Note
the remainder of this section covers a docker-compose file designed for the
SDK.  Refer to the Node SDK
repo for details on running these tests.

The second flavor, docker-compose-e2e.yaml, is constructed to run end-to-end tests
using the Node.js SDK.  Aside from functioning with the SDK, its primary differentiation
is that there are containers for the fabric-ca servers.  As a result, we are able
to send REST calls to the organizational CAs for user registration and enrollment.
If you want to use the docker-compose-e2e.yaml without first running the
byfn.sh script, then we will need to make four slight modifications.
We need to point to the private keys for our Organization’s CA’s.  You can locate
these values in your crypto-config folder.  For example, to locate the private
key for Org1 we would follow this path - crypto-config/peerOrganizations/org1.example.com/ca/.
The private key is a long hash value followed by _sk.  The path for Org2
would be - crypto-config/peerOrganizations/org2.example.com/ca/.
In the docker-compose-e2e.yaml update the FABRIC_CA_SERVER_TLS_KEYFILE variable
for ca0 and ca1.  You also need to edit the path that is provided in the command
to start the ca server.  You are providing the same private key twice for each
CA container.

Using CouchDB¶
The state database can be switched from the default (goleveldb) to CouchDB.
The same chaincode functions are available with CouchDB, however, there is the
added ability to perform rich and complex queries against the state database
data content contingent upon the chaincode data being modeled as JSON.
To use CouchDB instead of the default database (goleveldb), follow the same
procedures outlined earlier for generating the artifacts, except when starting
the network pass docker-compose-couch.yaml as well:
docker-compose -f docker-compose-cli.yaml -f docker-compose-couch.yaml -f docker-compose-etcdraft2.yaml up -d

abstore should now work using CouchDB underneath.

Note
If you choose to implement mapping of the fabric-couchdb container
port to a host port, please make sure you are aware of the security
implications. Mapping of the port in a development environment makes the
CouchDB REST API available, and allows the
visualization of the database via the CouchDB web interface (Fauxton).
Production environments would likely refrain from implementing port mapping in
order to restrict outside access to the CouchDB containers.

You can use abstore chaincode against the CouchDB state database
using the steps outlined above, however in order to exercise the CouchDB query
capabilities you will need to use a chaincode that has data modeled as JSON.
The sample chaincode marbles02 has been written to demostrate the queries
you can issue from your chaincode if you are using a CouchDB database. You can
locate the marbles02 chaincode in the fabric/examples/chaincode/go
directory.
We will follow the same process to create and join the channel as outlined in the
Create & Join Channel section above.  Once you have joined your peer(s) to the
channel, use the following steps to interact with the marbles02 chaincode:

Package and install the chaincode on peer0.org1.example.com:

# before packaging Go chaincode, vendoring dependencies is required.
cd /opt/gopath/src/github.com/hyperledger/fabric-samples/chaincode/marbles02/go
GO111MODULE=on go mod vendor
cd -

# package and install the Go chaincode
peer lifecycle chaincode package marbles.tar.gz --path github.com/hyperledger/fabric-samples/chaincode/marbles02/go/ --lang golang --label marbles_1
peer lifecycle chaincode install marbles.tar.gz

The install command will return a chaincode packageID that you will use to
approve a chaincode definition.
2019-04-08 20:10:32.568 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 001 Installed remotely: response:<status:200 payload:"\nJmarbles_1:cfb623954827aef3f35868764991cc7571b445a45cfd3325f7002f14156d61ae\022\tmarbles_1" >
2019-04-08 20:10:32.568 UTC [cli.lifecycle.chaincode] submitInstallProposal -> INFO 002 Chaincode code package identifier: marbles_1:cfb623954827aef3f35868764991cc7571b445a45cfd3325f7002f14156d61ae

Save the packageID as an environment variable so you can pass it to future
commands:
CC_PACKAGE_ID=marbles_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173

Approve a chaincode definition as Org1:

# be sure to modify the $CHANNEL_NAME variable accordingly for the command

peer lifecycle chaincode approveformyorg --channelID $CHANNEL_NAME --name marbles --version 1.0 --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem

Install the chaincode on peer0.org2.example.com:

CORE_PEER_MSPCONFIGPATH=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/users/Admin@org2.example.com/msp
CORE_PEER_ADDRESS=peer0.org2.example.com:9051
CORE_PEER_LOCALMSPID="Org2MSP"
CORE_PEER_TLS_ROOTCERT_FILE=/opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt
peer lifecycle chaincode install marbles.tar.gz

Approve a chaincode definition as Org2, and then commit the definition to the
channel:

# be sure to modify the $CHANNEL_NAME variable accordingly for the command

peer lifecycle chaincode approveformyorg --channelID $CHANNEL_NAME --name marbles --version 1.0 --package-id $CC_PACKAGE_ID --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem
peer lifecycle chaincode commit -o orderer.example.com:7050 --channelID $CHANNEL_NAME --name marbles --version 1.0 --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt

We can now create some marbles. The first invoke of the chaincode will start
the chaincode container. You may need to wait for the container to start.

# be sure to modify the $CHANNEL_NAME variable accordingly

peer chaincode invoke -o orderer.example.com:7050 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n marbles --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["initMarble","marble1","blue","35","tom"]}'

Once the container has started, you can issue additional commands to create
some marbles and move them around:
# be sure to modify the $CHANNEL_NAME variable accordingly

peer chaincode invoke -o orderer.example.com:7050 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n marbles --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["initMarble","marble2","red","50","tom"]}'
peer chaincode invoke -o orderer.example.com:7050 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n marbles --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["initMarble","marble3","blue","70","tom"]}'
peer chaincode invoke -o orderer.example.com:7050 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n marbles --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["transferMarble","marble2","jerry"]}'
peer chaincode invoke -o orderer.example.com:7050 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n marbles --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["transferMarblesBasedOnColor","blue","jerry"]}'
peer chaincode invoke -o orderer.example.com:7050 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem -C $CHANNEL_NAME -n marbles --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt -c '{"Args":["delete","marble1"]}'

If you chose to map the CouchDB ports in docker-compose, you can now view
the state database through the CouchDB web interface (Fauxton) by opening
a browser and navigating to the following URL:
http://localhost:5984/_utils

You should see a database named mychannel (or your unique channel name) and
the documents inside it.

Note
For the below commands, be sure to update the $CHANNEL_NAME variable appropriately.

You can run regular queries from the CLI (e.g. reading marble2):
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["readMarble","marble2"]}'

The output should display the details of marble2:
Query Result: {"color":"red","docType":"marble","name":"marble2","owner":"jerry","size":50}

You can retrieve the history of a specific marble - e.g. marble1:
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["getHistoryForMarble","marble1"]}'

The output should display the transactions on marble1:
Query Result: [{"TxId":"1c3d3caf124c89f91a4c0f353723ac736c58155325f02890adebaa15e16e6464", "Value":{"docType":"marble","name":"marble1","color":"blue","size":35,"owner":"tom"}},{"TxId":"755d55c281889eaeebf405586f9e25d71d36eb3d35420af833a20a2f53a3eefd", "Value":{"docType":"marble","name":"marble1","color":"blue","size":35,"owner":"jerry"}},{"TxId":"819451032d813dde6247f85e56a89262555e04f14788ee33e28b232eef36d98f", "Value":}]

You can also perform rich queries on the data content, such as querying marble fields by owner jerry:
peer chaincode query -C $CHANNEL_NAME -n marbles -c '{"Args":["queryMarblesByOwner","jerry"]}'

The output should display the two marbles owned by jerry:
Query Result: [{"Key":"marble2", "Record":{"color":"red","docType":"marble","name":"marble2","owner":"jerry","size":50}},{"Key":"marble3", "Record":{"color":"blue","docType":"marble","name":"marble3","owner":"jerry","size":70}}]

Why CouchDB¶
CouchDB is a kind of NoSQL solution. It is a document-oriented database where document fields are stored as key-value maps. Fields can be either a simple key-value pair, list, or map.
In addition to keyed/composite-key/key-range queries which are supported by LevelDB, CouchDB also supports full data rich queries capability, such as non-key queries against the whole blockchain data,
since its data content is stored in JSON format and fully queryable. Therefore, CouchDB can meet chaincode, auditing, reporting requirements for many use cases that not supported by LevelDB.
CouchDB can also enhance the security for compliance and data protection in the blockchain. As it is able to implement field-level security through the filtering and masking of individual attributes within a transaction, and only authorizing the read-only permission if needed.

A Note on Data Persistence¶
If data persistence is desired on the peer container or the CouchDB container,
one option is to mount a directory in the docker-host into a relevant directory
in the container. For example, you may add the following two lines in
the peer container specification in the docker-compose-base.yaml file:
volumes:
 - /var/hyperledger/peer0:/var/hyperledger/production

For the CouchDB container, you may add the following two lines in the CouchDB
container specification:
volumes:
 - /var/hyperledger/couchdb0:/opt/couchdb/data

Troubleshooting¶

Always start your network fresh.  Use the following command
to remove artifacts, crypto, containers and chaincode images:
./byfn.sh down

Note
You will see errors if you do not remove old containers
and images.

If you see Docker errors, first check your docker version (Prerequisites),
and then try restarting your Docker process.  Problems with Docker are
oftentimes not immediately recognizable.  For example, you may see errors
resulting from an inability to access crypto material mounted within a
container.
If they persist remove your images and start from scratch:
docker rm -f $(docker ps -aq)
docker rmi -f $(docker images -q)

If you see errors on your create, approve, commit, invoke or query commands,
make sure you have properly updated the channel name and chaincode name.
There are placeholder values in the supplied sample commands.

If you see the below error:
Error: Error endorsing chaincode: rpc error: code = 2 desc = Error installing chaincode code mycc:1.0(chaincode /var/hyperledger/production/chaincodes/mycc.1.0 exits)

You likely have chaincode images (e.g. dev-peer1.org2.example.com-mycc-1.0 or
dev-peer0.org1.example.com-mycc-1.0) from prior runs. Remove them and try
again.
docker rmi -f $(docker images | grep dev-peer[0-9] | awk '{print $3}')

If you see something similar to the following:
Error connecting: rpc error: code = 14 desc = grpc: RPC failed fast due to transport failure
Error: rpc error: code = 14 desc = grpc: RPC failed fast due to transport failure

Make sure you are running your network against the “1.0.0” images that have
been retagged as “latest”.

If you see the below error:
[configtx/tool/localconfig] Load -> CRIT 002 Error reading configuration: Unsupported Config Type ""
panic: Error reading configuration: Unsupported Config Type ""

Then you did not set the FABRIC_CFG_PATH environment variable properly.  The
configtxgen tool needs this variable in order to locate the configtx.yaml.  Go
back and execute an export FABRIC_CFG_PATH=$PWD, then recreate your
channel artifacts.

To cleanup the network, use the down option:
./byfn.sh down

If you see an error stating that you still have “active endpoints”, then prune
your Docker networks.  This will wipe your previous networks and start you with a
fresh environment:
docker network prune

You will see the following message:
WARNING! This will remove all networks not used by at least one container.
Are you sure you want to continue? [y/N]

Select y.

If you see an error similar to the following:
/bin/bash: ./scripts/script.sh: /bin/bash^M: bad interpreter: No such file or directory

Ensure that the file in question (script.sh in this example) is encoded
in the Unix format. This was most likely caused by not setting
core.autocrlf to false in your Git configuration (see
Windows extras). There are several ways of fixing this. If you have
access to the vim editor for instance, open the file:
vim ./fabric-samples/first-network/scripts/script.sh

Then change its format by executing the following vim command:
:set ff=unix

Note
If you continue to see errors, share your logs on the
fabric-questions channel on
Hyperledger Rocket Chat
or on StackOverflow.

Videos¶
Refer to the Hyperledger Fabric channel on YouTube

This collection contains developers demonstrating various v1 features and
components such as: ledger, channels, gossip, SDK, chaincode, MSP, and
more…

Deploying a production network¶
This deployment guide is a high level overview of the proper sequence for setting up production Fabric network components, in addition to best practices and a few of the many considerations to keep in mind when deploying. Note that this topic will discuss “setting up the network” as a holistic process from the perspective of a single individual. More likely than not, real world production networks will not be set up by a single individual but as a collaborative effort directed by several individuals (a collection of banks each setting up their own components, for example) instead.
The process for deploying a Fabric network is complex and presumes an understanding of Public Key Infrastructure and managing distributed systems. If you are a smart contract or application developer, you should not need this level of expertise in deploying a production level Fabric network. However, you might need to be aware of how networks are deployed in order to develop effective smart contracts and applications.
If all you need is a development environment to test chaincode, smart contracts, and applications against, check out Using the Fabric test network. It includes two organizations, each owning one peer, and a single ordering service organization that owns a single ordering node. This test network is not meant to provide a blueprint for deploying production components, and should not be used as such, as it makes assumptions and decisions that production deployments will not make.
The guide will give you an overview of the steps of setting up production components and a production network:

Step one: Decide on your network configuration

Step two: Set up a cluster for your resources

Step three: Set up your CAs

Step four: Use the CA to create identities and MSPs

Step five: Deploy nodes

Create a peer
Create an ordering node

Step one: Decide on your network configuration¶
The structure of a blockchain network must be dictated by the use case. These fundamental business decisions will vary according to your use case, but let’s consider a few scenarios.
In contrast to development environments or proofs of concept, security, resource management, and high availability become a priority when operating in production. How many nodes do you need to satisfy high availability, and in what data centers do you wish to deploy them in to satisfy both the needs of disaster recovery and data residency? How will you ensure that your private keys and roots of trust remain secure?
In addition to the above, here is a sampling of the decisions you will need to make before deploying components:

Certificate Authority configuration.
As part of the overall decisions you have to make about your peers (how many, how many on each channel, and so on) and about your ordering service (how many nodes, who will own them), you also have to decide on how the CAs for your organization will be deployed. Production networks should be using Transport Layer Security (TLS), which will require setting up a TLS CA and using it to generate TLS certficates. This TLS CA will need to be deployed before your enrollment CA. We’ll discuss this more in Step three: Set up your CAs.
Use Organizational Units or not?
Some organizations might find it necessary to establish Organizational Units to create a separation between certain identities and MSPs created by a single CA.
Database type.
Some channels in a network might require all data to be modeled in a way CouchDB as the State Database can understand, while other networks, prioritizing speed, might decide that all peers will use LevelDB. Note that channels should not have peers that use both CouchDB and LevelDB on them, as the two database types model data slightly differently.
Channels and private data.
Some networks might decide that Channels are the best way to ensure privacy and isolation for certain transactions. Others might decide that a single channel, along with Private data, better serves their need for privacy.
Container orchestration.
Different users might also make different decisions about their container orchestration, creating separate containers for their peer process, logging for the peer, CouchDB, gRPC communications, and chaincode, while other users might decide to combine some of these processes.
Chaincode deployment method.
Users now have the option to deploy their chaincode using either the built in build and run support, a customized build and run using the External Builders and Launchers, or using an Chaincode as an external service.
Using firewalls.
In a production deployment, components belonging to one organization might need access to components from other organizations, necessitating the use of firewalls and advanced networking configuration. For example, applications using the Fabric SDK require access to all endorsing peers from all organizations and the ordering services for all channels. Similarly, peers need access to the ordering service on the channels that they are receiving new blocks from.

However and wherever your components are deployed, you will need a high degree of expertise in your management system of choice (such as Kubernetes) in order to efficiently operate your network. Similarly, the structure of the network must be designed to fit the business use case and any relevant laws and regulations government of the industry in which the network will be designed to function.
This deployment guide will not go through every iteration and potential network configuration, but does give common guidelines and rules to consider.

Step two: Set up a cluster for your resources¶
Generally speaking, Fabric is agnostic to the method used to deploy and manage it. It is possible, for example, to deploy and manage a peer from a laptop. For a number of reasons, this is likely to be unadvisable, but there is nothing in Fabric that prohibits it.
As long as you have the ability to deploy containers, whether locally (or behind a firewall), or in a cloud, it should be possible to stand up components and connect them to each other. However, Kubernetes features a number of helpful tools that have made it a popular container management platform for deploying and managing Fabric networks. For more information about Kubernetes, check out the Kubernetes documentation. This topic will mostly limit its scope to the binaries and provide instructions that can be applied when using a Docker deployment or Kubernetes.
However and wherever you choose to deploy your components, you will need to make sure you have enough resources for the components to run effectively. The sizes you need will largely depend on your use case. If you plan to join a single peer to several high volume channels, it will need much more CPU and memory than a peer a user plans to join to a single channel. As a rough estimate, plan to dedicate approximately three times the resources to a peer as you plan to allocate to a single ordering node (as you will see below, it is recommended to deploy at least three and optimally five nodes in an ordering service). Similarly, you should need approximately a tenth of the resources for a CA as you will for a peer. You will also need to add storage to your cluster (some cloud providers may provide storage) as you cannot configure Persistent Volumes and Persistent Volume Claims without storage being set up with your cloud provider first.
By deploying a proof of concept network and testing it under load, you will have a better sense of the resources you will require.

Managing your infrastructure¶
The exact methods and tools you use to manage your backend will depend on the backend you choose. However, here are some considerations worth noting.

Using secret objects to securely store important configuration files in your cluster. For information about Kubernetes secrets, check out Kubernetes secrets. You also have the option to use Hardened Security Modules (HSMs) or encrypted Persistent Volumes (PVs). Along similar lines, after deploying Fabric components, you will likely want to connect to a container on your own backend, for example using a private repo in a service like Docker Hub. In that case, you will need to code the login information in the form of a Kubernetes secret and include it in the YAML file when deploying components.
Cluster considerations and node sizing. In step 2 above, we discussed a general outline for how to think about the sizings of nodes. Your use case, as well as a robust period of development, is the only way you will truly know how how large your peers, ordering nodes, and CAs will need to be.
How you choose to mount your volumes. It is a best practice to mount the volumes relevant to your nodes external to the place where your nodes are deployed. This will allow you to reference these volumes later on (for example, restarting a node or a container that has crashed) without having to redeploy or regenerate your crypto material.
How you will monitor your resources. It is critical that you establish a strategy and method for monitoring the resources used by your individual nodes and the resources deployed to your cluster generally. As you join your peers to more channels, you will need likely need to increase its CPU and memory allocation. Similarly, you will need to make sure you have enough storage space for your state database and blockchain.

Step three: Set up your CAs¶
The first component that must be deployed in a Fabric network is a CA. This is because the certificates associated with a node (not just for the node itself but also the certificates identifying who can administer the node) must be created before the node itself can be deployed. While it is not necessary to use the Fabric CA to create these certificates, the Fabric CA also creates MSP structures that are needed for components and organizations to be properly defined. If a user chooses to use a CA other than the Fabric CA, they will have to create the MSP folders themselves.

One CA (or more, if you are using intermediate CAs — more on intermediate CAs below) is used to generate (through a process called “enrollment”) the certificates of the admin of an organization, the MSP of that organization, and any nodes owned by that organization. This CA will also generate the certificates for any additional users. Because of its role in “enrolling” identities, this CA is sometimes called the “enrollment CA” or the “ecert CA”.
The other CA generates the certificates used to secure communications on Transport Layer Security (TLS). For this reason, this CA is often referred to as a “TLS CA”. These TLS certificates are attached to actions as a way of preventing “man in the middle” attacks. Note that the TLS CA is only used for issuing certificates for nodes and can be shut down when that activity is completed. Users have the option to use one way (client only) TLS as well as two way (server and client) TLS, with the latter also known as “mutual TLS”. Because specifying that your network will be using TLS (which is recommended) should be decided before deploying the “enrollment” CA (the YAML file specifying the configuration of this CA has a field for enabling TLS), you should deploy your TLS CA first and use its root certificate when bootstrapping your enrollment CA. This TLS certificate will also be used by the fabric-ca client when connecting to the enrollment CA to enroll identities for users and nodes.

While all of the non-TLS certificates associated with an organization can be created by a single “root” CA (that is, a CA that is its own root of trust), for added security organizations can decide to use “intermediate” CAs whose certificates are created by a root CA (or another intermediate CA that eventually leads back to a root CA). Because a compromise in the root CA leads to a collapse for its entire trust domain (the certs for the admins, nodes, and any CAs it has generated certificates for), intermediate CAs are a useful way to limit the exposure of the root CA. Whether you choose to use intermediate CAs will depend on the needs of your use case. They are not mandatory. Note that it is also possible to configure a Lightweight Directory Access Protocol (LDAP) to manage identities on a Fabric network for those enterprises that already have this implementation and do not want to add a layer of identity management to their existing infrastructure. The LDAP effectively pre registers all of the members of the directory and allows them to enroll based on the criteria given.
In a production network, it is recommended to deploy at least one CA per organization for enrollment purposes and another for TLS. For example, if you deploy three peers that are associated with one organization and an ordering node that is associated with an ordering organization, you will need at least four CAs. Two of the CAs will be for the peer organization (generating the enrollment and TLS certificates for the peer, admins, communications, and the folder structure of the MSP representing the organization) and the other two will be for the orderer organization. Note that users will generally only register and enroll with the enrollment CA, while nodes will register and enroll with both the enrollment CA (where the node will get its signing certificates that identify it when it attempts to sign its actions) and with the TLS CA (where it will get the TLS certificates it uses to authenticate its communications).
For an example of how to setup an organization CA and a TLS CA and enroll their admin identity, check out the Fabric CA Deployment Guide.  The deploy guide uses the Fabric CA client to register and enroll the identities that are required when setting up CAs.

Step four: Use the CA to create identities and MSPs¶
After you have created your CAs, you can use them to create the certificates for the identities and components related to your organization (which is represented by an MSP). For each organization, you will need to, at a minimum:

Register and enroll an admin identity and create an MSP. After the CA that will be associated with an organization has been created, it can be used to first register an identity and then enroll it. In the first step, a username and password for the identity is assigned by the admin of the CA. Attributes and affiliations can also be given to the identity (for example, a role of admin, which is necessary for organization admins). After the identity has been registered, it can be enrolled by using the username and password. The CA will generate two certificates for this identity — a public certificate (also known as a signcert) known to the other members of the network, and the private key (stored in the keystore folder) used to sign actions taken by the identity. The CA will also generate an MSP file containing the public certificate of the CA issuing the certificate and the root of trust for the CA (this may or may not be the same CA). This MSP can be thought of as defining the organization associated with the identity of the admin. For an example of how this process looks, check out the this example of how an admin is enrolled. In cases where the admin of the org will also be an admin of a node (which will be typical), you must create the org admin identity before creating the local MSP of a node, since the certificate of the node admin must be used when creating the local MSP.
Register and enroll node identities. Just as an org admin identity is registered and enrolled, the identity of a node must be registered and enrolled with both an enrollment CA and the TLS CA. For this reason, it can be useful for your enrollment CA and TLS to share a database (which allows the node identity to only be registered once and enrolled by each CA server separately), though this is an optional configuration option. Instead of giving a node a role of admin or user when registering it with the enrollment CA, give it a role of peer or orderer. As with the admin, attributes and affiliations for this identity can also be assigned. The MSP structure for a node is known as a “local MSP”, since the permissions assigned to the identities are only relevant at the local (node) level. This MSP is created when the node identity is created, and is used when bootstrapping the node. You will use the TLS root certificate generated when enrolling with the TLS CA when joining your organization to the channel (this certificate must be added to the org MSP that was created when you enrolled your admin) and when using the peer binary as a CLI client to make calls to other peers (as in peer chaincode invoke) or ordering nodes (as in peer channel fetch) because there is no orderer CLI. It is not necessary to add the TLS root certificates to the local MSP of a node because these certificates are contained in the channel configuration.

For more conceptual information about identities and permissions in a Fabric-based blockchain network, see Identity and Membership Service Provider (MSP).
For a look at how to use a CA to generate an admin identity and MSP, check out Enroll Org1’s Admin.
To see how to use the enrollment CA to and the TLS CA to generate the certificates for a node, check out Setup Org1’s Peers.

Step five: Deploy nodes¶
Once you have gathered all of the certificates and MSPs you need, you’re almost ready to create a node. As discussed above, there are a number of valid ways to deploy nodes.

Create a peer¶
Before you can create a peer, you will need to customize the configuration file for the peer. In Fabric, this file is called core.yaml. You can find a sample core.yaml configuration file in the sampleconfig directory of Hyperledger Fabric.
As you can see in the file, there are quite a number of parameters you either have the option to set or will need to set for your node to work properly. In general, if you do not have the need to change a tuning value, leave it alone. You will, however, likely need to adjust the various addresses, specify the database type you want to use, as well as to specify where the MSP for the node is located.
You have two main options for tuning your configuration.

Edit the YAML file bundled with the binaries.
Use environment variable overrides when deploying.
Specify flags on CLI commands.

Option 1 has the advantage of persisting your changes whenever you bring down and bring back up the node. The downside is that you will have to port the options you customized to the new YAML when upgrading to a new binary version (you should use the latest YAML when upgrading to a new version).
Either way, here are some values in core.yaml you must review.

peer.localMspID: this is the name of the local MSP of your peer organization. This MSP is where your peer organization admins will be listed as well as the peer organization’s root CA and TLS CA certificates.
peer.mspConfigPath: the place where the local MSP for the peer is located. Note that it is a best practice to mount this volume external to your container. This ensures that even if the container is stopped (for example, during a maintenance cycle) that the MSPs are not lost and have to be recreated.
peer.address: represents the endpoint to other peers in the same organization, an important consideration when establishing gossip communication within an organization.
peer.tls: When you set the enabled value to true (as should be done in a production network), you will have to specify the locations of the relevant TLS certificates. Note that all of the nodes in a network (both the peers and the ordering nodes) must either all have TLS enabled or not enabled. For production networks, it is highly recommended to enable TLS. As with your MSP, it is a best practice to mount this volume external to your container.
ledger: users have a number of decisions to make about their ledger, including the state database type (LevelDB or CouchDB, for example), and its location (specified in fileSystemPath). Note that for CouchDB, it is a best practice to operate your state database external to the peer (for example, in a separate container), as you will be better able to allocate specific resources to the database this way. For latency and security reasons, it is a best practice to have the CouchDB container on the same server as the peer. Access to the CouchDB container should be restricted to only the peer container.
gossip: there are a number of configuration options to think about when setting up Gossip data dissemination protocol, including the externalEndpoint (which makes peers discoverable to peers owned by other organizations) as well as the bootstrap address (which identifies a peer in the peer’s own organization).
chaincode.externalBuilders: this field is important to set when using Chaincode as an external service.

When you’re comfortable with how your peer has been configured, how your volumes are mounted, and your backend configuration, you can run the command to launch the peer (this command will depend on your backend configuration).

Create an ordering node¶
Unlike the creation of a peer, you will need to create a genesis block (or reference a block that has already been created, if adding an ordering node to an existing ordering service) and specify the path to it before launching the ordering node.
In Fabric, this configuration file for ordering nodes is called orderer.yaml. You can find a sample orderer.yaml configuration file in the sampleconfig directory of Hyperledger Fabric. Note that orderer.yaml is different than the “genesis block” of an ordering service. This block, which includes the initial configuration of the orderer system channel, must be created before an ordering node is created because it is used to bootstrap the node.
As with the peer, you will see that there are quite a number of parameters you either have the option to set or will need to set for your node to work properly. In general, if you do not have the need to change a tuning value, leave it alone.
You have two main options for tuning your configuration.

Edit the YAML file bundled with the binaries.
Use environment variable overrides when deploying.
Specify flags on CLI commands.

Option 1 has the advantage of persisting your changes whenever you bring down and bring back up the node. The downside is that you will have to port the options you customized to the new YAML when upgrading to a new binary version (you should use the latest YAML when upgrading to a new version).
Either way, here are some values in orderer.yaml you must review. You will notice that some of these fields are the same as those in core.yaml only with different names.

General.LocalMSPID: this is the name of the local MSP, generated by your CA, of your orderer organization.
General.LocalMSPDir: the place where the local MSP for the ordering node is located. Note that it is a best practice to mount this volume external to your container.
General.ListenAddress and General.ListenPort: represents the endpoint to other ordering nodes in the same organization.
FileLedger: although ordering nodes do not have a state database, they still all carry copies of the blockchain, as this allows them to verify permissions using the latest config block. Therefore the ledger fields should be customized with the correct file path.
Cluster: these values are important for ordering service nodes that communicate with other ordering nodes, such as in a Raft based ordering service.
General.BootstrapFile: this is the name of the configuration block used to bootstrap an ordering node. If this node is the first node generated in an ordering service, this file will have to be generated and is known as the “genesis block”.
General.BootstrapMethod: the method by which the bootstrap block is given. For now, this can only be file, in which the file in the BootstrapFile is specified. Starting in 2.0, you can specify none to simply start the orderer without bootstrapping.
Consensus: determines the key/value pairs allowed by the consensus plugin (Raft ordering services are supported and recommended) for the Write Ahead Logs (WALDir) and Snapshots (SnapDir).

When you’re comfortable with how your ordering node has been configured, how your volumes are mounted, and your backend configuration, you can run the command to launch the ordering node (this command will depend on your backend configuration).

Next steps¶
Blockchain networks are all about connection, so once you’ve deployed nodes, you’ll obviously want to connect them to other nodes! If you have a peer organization and a peer, you’ll want to join your organization to a consortium and join or Channels. If you have an ordering node, you will want to add peer organizations to your consortium. You’ll also want to learn how to develop chaincode, which you can learn about in the topics The scenario and chaincode4noah.
Part of the process of connecting nodes and creating channels will involve modifying policies to fit the use cases of business networks. For more information about policies, check out Policies.
One of the common tasks in a Fabric will be the editing of existing channels. For a tutorial about that process, check out Updating a channel configuration. One popular channel update is to add an org to an existing channel. For a tutorial about that specific process, check out Adding an Org to a Channel. For information about upgrading nodes after they have been deployed, check out Upgrading your components.

Operations Guides¶

Setting up an ordering node¶
In this topic, we’ll describe the process for bootstrapping an ordering node.
If you want more information about the different ordering service implementations
and their relative strengths and weaknesses, check out our
conceptual documentation about ordering.
Broadly, this topic will involve a few interrelated steps:

Creating the organization your ordering node belongs to (if you have not already
done so)
Configuring your node (using orderer.yaml)
Creating the genesis block for the orderer system channel
Bootstrapping the orderer

Note: this topic assumes you have already pulled the Hyperledger Fabric orderer
images from docker hub.

Create an organization definition¶
Like peers, all orderers must belong to an organization that must be created
before the orderer itself is created. This organization has a definition
encapsulated by a Membership Service Provider
(MSP) that is created by a Certificate Authority (CA) dedicated to creating the
certificates and MSP for the organization.
For information about creating a CA and using it to create users and an MSP,
check out the Fabric CA user’s guide.

Configure your node¶
The configuration of the orderer is handled through a yaml file called
orderer.yaml. The FABRIC_CFG_PATH environment variable is used to point to
an orderer.yaml file you’ve configured, which will extract a series of files
and certificates on your file system.
To look at a sample orderer.yaml, check out the fabric-samples github repo, which should be read and studied closely before proceeding.
Note in particular a few values:

LocalMSPID — this is the name of the MSP, generated by your CA, of your
orderer organization. This is where your orderer organization admins will be
listed.
LocalMSPDir — the place in your file system where the local MSP is located.
# TLS enabled, Enabled: false. This is where you specify whether you want
to enable TLS. If you set this value to true, you will have
to specify the locations of the relevant TLS certificates. Note that this is
mandatory for Raft nodes.
BootstrapFile — this is the name of the genesis block you will generate for
this ordering service.
BootstrapMethod — the method by which the bootstrap block is given. For now,
this can only be file, in which the file in the BootstrapFile is specified.

If you are deploying this node as part of a cluster (for example, as part of a
cluster of Raft nodes), make note of the Cluster and Consensus sections.
If you plan to deploy a Kafka based ordering service, you will need to complete
the Kafka section.

Generate the genesis block of the orderer¶
The first block of a newly created channel is known as a “genesis block”. If
this genesis block is being created as part of the creation of a new network
(in other words, if the orderer being created will not be joined to an existing
cluster of orderers), then this genesis block will be the first block of the “orderer
system channel” (also known as the “ordering system channel”), a special channel
managed by the orderer admins which includes a list of the organizations permitted
to create channels. The genesis block of the orderer system channel is special:
it must be created and included in the configuration of the node before the node
can be started.
To learn how to create a genesis block using the configtxgen tool, check out
Channel Configuration (configtx).

Bootstrap the ordering node¶
Once you have built the images, created the MSP, configured your orderer.yaml,
and created the genesis block, you’re ready to start your orderer using a
command that will look similar to:
docker-compose -f docker-compose-cli.yaml up -d --no-deps orderer.example.com

With the address of your orderer replacing orderer.example.com.

Membership Service Providers (MSP)¶
The document serves to provide details on the setup and best practices for MSPs.
Membership Service Provider (MSP) is a Hyperledger Fabric component that offers
an abstraction of membership operations.
In particular, an MSP abstracts away all cryptographic mechanisms and protocols
behind issuing certificates, validating certificates, and user authentication.
An MSP may define its own notion of identity, and the rules by which those
identities are governed (identity validation) and authenticated (signature
generation and verification).
A Hyperledger Fabric blockchain network can be governed by one or more MSPs.
This provides modularity of membership operations, and interoperability
across different membership standards and architectures.
In the rest of this document we elaborate on the setup of the MSP
implementation supported by Hyperledger Fabric, and discuss best practices
concerning its use.

MSP Configuration¶
To setup an instance of the MSP, its configuration needs to be specified
locally at each peer and orderer (to enable peer and orderer signing),
and on the channels to enable peer, orderer, client identity validation, and
respective signature verification (authentication) by and for all channel
members.
Firstly, for each MSP a name needs to be specified in order to reference that MSP
in the network (e.g. msp1, org2, and org3.divA). This is the name under
which membership rules of an MSP representing a consortium, organization or
organization division is to be referenced in a channel. This is also referred
to as the MSP Identifier or MSP ID. MSP Identifiers are required to be unique per MSP
instance. For example, shall two MSP instances with the same identifier be
detected at the system channel genesis, orderer setup will fail.
In the case of the default MSP implementation, a set of parameters need to be
specified to allow for identity (certificate) validation and signature
verification. These parameters are deduced by
RFC5280, and include:

A list of self-signed (X.509) CA certificates to constitute the root of
trust
A list of X.509 certificates to represent intermediate CAs this provider
considers for certificate validation; these certificates ought to be
certified by exactly one of the certificates in the root of trust;
intermediate CAs are optional parameters
A list of X.509 certificates representing the administrators of this MSP with a
verifiable certificate path to exactly one of the CA certificates of the
root of trust; owners of these certificates are authorized to request changes
to this MSP configuration (e.g. root CAs, intermediate CAs)
A list of Organizational Units that valid members of this MSP should
include in their X.509 certificate; this is an optional configuration
parameter, used when, e.g., multiple organizations leverage the same
root of trust, and intermediate CAs, and have reserved an OU field for
their members
A list of certificate revocation lists (CRLs) each corresponding to
exactly one of the listed (intermediate or root) MSP Certificate
Authorities; this is an optional parameter
A list of self-signed (X.509) certificates to constitute the TLS root of
trust for TLS certificates.
A list of X.509 certificates to represent intermediate TLS CAs this provider
considers; these certificates ought to be
certified by exactly one of the certificates in the TLS root of trust;
intermediate CAs are optional parameters.

Valid  identities for this MSP instance are required to satisfy the following conditions:

They are in the form of X.509 certificates with a verifiable certificate path to
exactly one of the root of trust certificates;
They are not included in any CRL;
And they list one or more of the Organizational Units of the MSP configuration
in the OU field of their X.509 certificate structure.

For more information on the validity of identities in the current MSP implementation,
we refer the reader to MSP Identity Validity Rules.
In addition to verification related parameters, for the MSP to enable
the node on which it is instantiated to sign or authenticate, one needs to
specify:

The signing key used for signing by the node (currently only ECDSA keys are
supported), and
The node’s X.509 certificate, that is a valid identity under the
verification parameters of this MSP.

It is important to note that MSP identities never expire; they can only be revoked
by adding them to the appropriate CRLs. Additionally, there is currently no
support for enforcing revocation of TLS certificates.

How to generate MSP certificates and their signing keys?¶
Openssl can be used to generate X.509
certificates and keys. Please note that Hyperledger Fabric does not support
RSA key and certificates.
Alternatively, the cryptogen tool can be used as described in
Getting Started.
Hyperledger Fabric CA
can also be used to generate the keys and certificates needed to configure an MSP.

MSP setup on the peer & orderer side¶
To set up a local MSP (for either a peer or an orderer), the administrator
should create a folder (e.g. $MY_PATH/mspconfig) that contains six subfolders
and a file:

a folder admincerts to include PEM files each corresponding to an
administrator certificate
a folder cacerts to include PEM files each corresponding to a root
CA’s certificate
(optional) a folder intermediatecerts to include PEM files each
corresponding to an intermediate CA’s certificate
(optional) a file config.yaml to configure the supported Organizational Units
and identity classifications (see respective sections below).
(optional) a folder crls to include the considered CRLs
a folder keystore to include a PEM file with the node’s signing key;
we emphasise that currently RSA keys are not supported
a folder signcerts to include a PEM file with the node’s X.509
certificate
(optional) a folder tlscacerts to include PEM files each corresponding to a TLS root
CA’s certificate
(optional) a folder tlsintermediatecerts to include PEM files each
corresponding to an intermediate TLS CA’s certificate

In the configuration file of the node (core.yaml file for the peer, and
orderer.yaml for the orderer), one needs to specify the path to the
mspconfig folder, and the MSP Identifier of the node’s MSP. The path to the
mspconfig folder is expected to be relative to FABRIC_CFG_PATH and is provided
as the value of parameter mspConfigPath for the peer, and LocalMSPDir
for the orderer. The identifier of the node’s MSP is provided as a value of
parameter localMspId for the peer and LocalMSPID for the orderer.
These variables can be overridden via the environment using the CORE prefix for
peer (e.g. CORE_PEER_LOCALMSPID) and the ORDERER prefix for the orderer (e.g.
ORDERER_GENERAL_LOCALMSPID). Notice that for the orderer setup, one needs to
generate, and provide to the orderer the genesis block of the system channel.
The MSP configuration needs of this block are detailed in the next section.
Reconfiguration of a “local” MSP is only possible manually, and requires that
the peer or orderer process is restarted. In subsequent releases we aim to
offer online/dynamic reconfiguration (i.e. without requiring to stop the node
by using a node managed system chaincode).

Organizational Units¶
In order to configure the list of Organizational Units that valid members of this MSP should
include in their X.509 certificate, the config.yaml file
needs to specify the organizational unit (OU, for short) identifiers. You can find an example
below:
OrganizationalUnitIdentifiers:
  - Certificate: "cacerts/cacert1.pem"
    OrganizationalUnitIdentifier: "commercial"
  - Certificate: "cacerts/cacert2.pem"
    OrganizationalUnitIdentifier: "administrators"

The above example declares two organizational unit identifiers: commercial and administrators.
An MSP identity is valid if it carries at least one of these organizational unit identifiers.
The Certificate field refers to the CA or intermediate CA certificate path
under which identities, having that specific OU, should be validated.
The path is relative to the MSP root folder and cannot be empty.

Identity Classification¶
The default MSP implementation allows organizations to further classify identities into clients,
admins, peers, and orderers based on the OUs of their x509 certificates.

An identity should be classified as a client if it transacts on the network.
An identity should be classified as an admin if it handles administrative tasks such as
joining a peer to a channel or signing a channel configuration update transaction.
An identity should be classified as a peer if it endorses or commits transactions.
An identity should be classified as an orderer if belongs to an ordering node.

In order to define the clients, admins, peers, and orderers of a given MSP, the config.yaml file
needs to be set appropriately. You can find an example NodeOU section of the config.yaml file
below:
NodeOUs:
  Enable: true
  # For each identity classification that you would like to utilize, specify
  # an OU identifier.
  # You can optionally configure that the OU identifier must be issued by a specific CA
  # or intermediate certificate from your organization. However, it is typical to NOT
  # configure a specific Certificate. By not configuring a specific Certificate, you will be
  # able to add other CA or intermediate certs later, without having to reissue all credentials.
  # For this reason, the sample below comments out the Certificate field.
  ClientOUIdentifier:
    # Certificate: "cacerts/cacert.pem"
    OrganizationalUnitIdentifier: "client"
  AdminOUIdentifier:
    # Certificate: "cacerts/cacert.pem"
    OrganizationalUnitIdentifier: "admin"
  PeerOUIdentifier:
    # Certificate: "cacerts/cacert.pem"
    OrganizationalUnitIdentifier: "peer"
  OrdererOUIdentifier:
    # Certificate: "cacerts/cacert.pem"
    OrganizationalUnitIdentifier: "orderer"

Identity classification is enabled when NodeOUs.Enable is set to true. Then the client
(admin, peer, orderer) organizational unit identifier is defined by setting the properties of
the NodeOUs.ClientOUIdentifier (NodeOUs.AdminOUIdentifier, NodeOUs.PeerOUIdentifier,
NodeOUs.OrdererOUIdentifier) key:

OrganizationalUnitIdentifier: Is the OU value that the x509 certificate needs to contain
to be considered a client (admin, peer, orderer respectively). If this field is empty, then the classification
is not applied.
Certificate: (Optional) Set this to the path of the CA or intermediate CA certificate
under which client (peer, admin or orderer) identities should be validated.
The field is relative to the MSP root folder. Only a single Certificate can be specified.
If you do not set this field, then the identities are validated under any CA defined in
the organization’s MSP configuration, which could be desirable in the future if you need
to add other CA or intermediate certificates.

Notice that if the NodeOUs.ClientOUIdentifier section (NodeOUs.AdminOUIdentifier,
NodeOUs.PeerOUIdentifier, NodeOUs.OrdererOUIdentifier) is missing, then the classification
is not applied. If NodeOUs.Enable is set to true and no classification keys are defined,
then identity classification is assumed to be disabled.
Identities can use organizational units to be classified as either a client, an admin, a peer, or an
orderer. The four classifications are mutually exclusive.
The 1.1 channel capability needs to be enabled before identities can be classified as clients
or peers. The 1.4.3 channel capability needs to be enabled for identities to be classified as an
admin or orderer.
Classification allows identities to be classified as admins (and conduct administrator actions)
without the certificate being stored in the admincerts folder of the MSP. Instead, the
admincerts folder can remain empty and administrators can be created by enrolling identities
with the admin OU. Certificates in the admincerts folder will still grant the role of
administrator to their bearer, provided that they possess the client or admin OU.

Channel MSP setup¶
At the genesis of the system, verification parameters of all the MSPs that
appear in the network need to be specified, and included in the system
channel’s genesis block. Recall that MSP verification parameters consist of
the MSP identifier, the root of trust certificates, intermediate CA and admin
certificates, as well as OU specifications and CRLs.
The system genesis block is provided to the orderers at their setup phase,
and allows them to authenticate channel creation requests. Orderers would
reject the system genesis block, if the latter includes two MSPs with the same
identifier, and consequently the bootstrapping of the network would fail.
For application channels, the verification components of only the MSPs that
govern a channel need to reside in the channel’s genesis block. We emphasize
that it is the responsibility of the application to ensure that correct
MSP configuration information is included in the genesis blocks (or the
most recent configuration block) of a channel prior to instructing one or
more of their peers to join the channel.
When bootstrapping a channel with the help of the configtxgen tool, one can
configure the channel MSPs by including the verification parameters of MSP
in the mspconfig folder, and setting that path in the relevant section in
configtx.yaml.
Reconfiguration of an MSP on the channel, including announcements of the
certificate revocation lists associated to the CAs of that MSP is achieved
through the creation of a config_update object by the owner of one of the
administrator certificates of the MSP. The client application managed by the
admin would then announce this update to the channels in which this MSP appears.

Best Practices¶
In this section we elaborate on best practices for MSP
configuration in commonly met scenarios.
1) Mapping between organizations/corporations and MSPs
We recommend that there is a one-to-one mapping between organizations and MSPs.
If a different type of mapping is chosen, the following needs to be to
considered:

One organization employing various MSPs. This corresponds to the
case of an organization including a variety of divisions each represented
by its MSP, either for management independence reasons, or for privacy reasons.
In this case a peer can only be owned by a single MSP, and will not recognize
peers with identities from other MSPs as peers of the same organization. The
implication of this is that peers may share through gossip organization-scoped
data with a set of peers that are members of the same subdivision, and NOT with
the full set of providers constituting the actual organization.
Multiple organizations using a single MSP. This corresponds to a
case of a consortium of organizations that are governed by similar
membership architecture. One needs to know here that peers would propagate
organization-scoped messages to the peers that have an identity under the
same MSP regardless of whether they belong to the same actual organization.
This is a limitation of the granularity of MSP definition, and/or of the peer’s
configuration.

2) One organization has different divisions (say organizational units), to
which it wants to grant access to different channels.
Two ways to handle this:

Define one MSP to accommodate membership for all organization’s members.
Configuration of that MSP would consist of a list of root CAs,
intermediate CAs and admin certificates; and membership identities would
include the organizational unit (OU) a member belongs to. Policies can then
be defined to capture members of a specific role (should be one of: peer, admin,
client, orderer, member), and these policies may constitute the read/write policies
of a channel or endorsement policies of a chaincode. Specifying custom OUs in
the profile section of configtx.yaml is currently not configured.
A limitation of this approach is that gossip peers would
consider peers with membership identities under their local MSP as
members of the same organization, and would consequently gossip
with them organization-scoped data (e.g. their status).
Defining one MSP to represent each division.  This would involve specifying for each
division, a set of certificates for root CAs, intermediate CAs, and admin
Certs, such that there is no overlapping certification path across MSPs.
This would mean that, for example, a different intermediate CA per subdivision
is employed. Here the disadvantage is the management of more than one
MSPs instead of one, but this circumvents the issue present in the previous
approach.  One could also define one MSP for each division by leveraging an OU
extension of the MSP configuration.

3) Separating clients from peers of the same organization.
In many cases it is required that the “type” of an identity is retrievable
from the identity itself (e.g. it may be needed that endorsements are
guaranteed to have derived by peers, and not clients or nodes acting solely
as orderers).
There is limited support for such requirements.
One way to allow for this separation is to create a separate intermediate
CA for each node type - one for clients and one for peers/orderers; and
configure two different MSPs - one for clients and one for peers/orderers.
Channels this organization should be accessing would need to include
both MSPs, while endorsement policies will leverage only the MSP that
refers to the peers. This would ultimately result in the organization
being mapped to two MSP instances, and would have certain consequences
on the way peers and clients interact.
Gossip would not be drastically impacted as all peers of the same organization
would still belong to one MSP. Peers can restrict the execution of certain
system chaincodes to local MSP based policies. For
example, peers would only execute “joinChannel” request if the request is
signed by the admin of their local MSP who can only be a client (end-user
should be sitting at the origin of that request). We can go around this
inconsistency if we accept that the only clients to be members of a
peer/orderer MSP would be the administrators of that MSP.
Another point to be considered with this approach is that peers
authorize event registration requests based on membership of request
originator within their local MSP. Clearly, since the originator of the
request is a client, the request originator is always deemed to belong
to a different MSP than the requested peer and the peer would reject the
request.
4) Admin and CA certificates.
It is important to set MSP admin certificates to be different than any of the
certificates considered by the MSP for root of trust, or intermediate CAs.
This is a common (security) practice to separate the duties of management of
membership components from the issuing of new certificates, and/or validation of existing ones.
5) Blacklisting an intermediate CA.
As mentioned in previous sections, reconfiguration of an MSP is achieved by
reconfiguration mechanisms (manual reconfiguration for the local MSP instances,
and via properly constructed config_update messages for MSP instances of a channel).
Clearly, there are two ways to ensure an intermediate CA considered in an MSP is no longer
considered for that MSP’s identity validation:

Reconfigure the MSP to no longer include the certificate of that
intermediate CA in the list of trusted intermediate CA certs. For the
locally configured MSP, this would mean that the certificate of this CA is
removed from the intermediatecerts folder.
Reconfigure the MSP to include a CRL produced by the root of trust
which denounces the mentioned intermediate CA’s certificate.

In the current MSP implementation we only support method (1) as it is simpler
and does not require blacklisting the no longer considered intermediate CA.
6) CAs and TLS CAs
MSP identities’ root CAs and MSP TLS certificates’ root CAs (and relative intermediate CAs)
need to be declared in different folders. This is to avoid confusion between
different classes of certificates. It is not forbidden to reuse the same
CAs for both MSP identities and TLS certificates but best practices suggest
to avoid this in production.

Using a Hardware Security Module (HSM)¶
The cryptographic operations performed by Fabric nodes can be delegated to
a Hardware Security Module (HSM).  An HSM protects your private keys and
handles cryptographic operations, allowing your peers and orderer nodes to
sign and endorse transactions without exposing their private keys.  If you
require compliance with government standards such as FIPS 140-2, there are
multiple certified HSMs from which to choose.
Fabric currently leverages the PKCS11 standard to communicate with an HSM.

Configuring an HSM¶
To use an HSM with your Fabric node, you need to update the bccsp (Crypto Service
Provider) section of the node configuration file such as core.yaml or
orderer.yaml. In the bccsp section, you need to select PKCS11 as the provider and
enter the path to the PKCS11 library that you would like to use. You also need
to provide the Label and PIN of the token that you created for your cryptographic
operations. You can use one token to generate and store multiple keys.
The prebuilt Hyperledger Fabric Docker images are not enabled to use PKCS11. If
you are deploying Fabric using docker, you need to build your own images and
enable PKCS11 using the following command:
make docker GO_TAGS=pkcs11

You also need to ensure that the PKCS11 library is available to be used by the
node by installing it or mounting it inside the container.

Example¶
The following example demonstrates how to configure a Fabric node to use an HSM.
First, you will need to install an implementation of the PKCS11 interface. This
example uses the softhsm open source
implementation. After downloading and configuring softhsm, you will need to set
the SOFTHSM2_CONF environment variable to point to the softhsm2 configuration
file.
You can then use softhsm to create the token that will handle the cryptographic
operations of your Fabric node inside an HSM slot. In this example, we create a
token labelled “fabric” and set the pin to “71811222”. After you have created
the token, update the configuration file to use PKCS11 and your token as the
crypto service provider. You can find an example bccsp section below:
#############################################################################
# BCCSP (BlockChain Crypto Service Provider) section is used to select which
# crypto library implementation to use
#############################################################################
bccsp:
  default: PKCS11
  pkcs11:
    Library: /etc/hyperledger/fabric/libsofthsm2.so
    Pin: 71811222
    Label: fabric
    hash: SHA2
    security: 256
    Immutable: false

By default, when private keys are generated using the HSM, the private key is mutable, meaning PKCS11 private key  attributes can be changed after the key is generated. Setting Immutable to true means that the private key attributes cannot be altered after key generation. Before you configure immutability by setting Immutable: true, ensure that PKCS11 object copy is supported by the HSM.
You can also use environment variables to override the relevant fields of the configuration file. If you are connecting to softhsm2 using the Fabric CA server, you could set the following environment variables or directly set the corresponding values in the CA server config file:
FABRIC_CA_SERVER_BCCSP_DEFAULT=PKCS11
FABRIC_CA_SERVER_BCCSP_PKCS11_LIBRARY=/etc/hyperledger/fabric/libsofthsm2.so
FABRIC_CA_SERVER_BCCSP_PKCS11_PIN=71811222
FABRIC_CA_SERVER_BCCSP_PKCS11_LABEL=fabric

If you are connecting to softhsm2 using the Fabric peer, you could set the following environment variables or directly set the corresponding values in the peer config file:
CORE_PEER_BCCSP_DEFAULT=PKCS11
CORE_PEER_BCCSP_PKCS11_LIBRARY=/etc/hyperledger/fabric/libsofthsm2.so
CORE_PEER_BCCSP_PKCS11_PIN=71811222
CORE_PEER_BCCSP_PKCS11_LABEL=fabric

If you are connecting to softhsm2 using the Fabric orderer, you could set the following environment variables or directly set the corresponding values in the orderer config file:
ORDERER_GENERAL_BCCSP_DEFAULT=PKCS11
ORDERER_GENERAL_BCCSP_PKCS11_LIBRARY=/etc/hyperledger/fabric/libsofthsm2.so
ORDERER_GENERAL_BCCSP_PKCS11_PIN=71811222
ORDERER_GENERAL_BCCSP_PKCS11_LABEL=fabric

If you are deploying your nodes using docker compose, after building your own
images, you can update your docker compose files to mount the softhsm library
and configuration file inside the container using volumes. As an example, you
would add the following environment and volumes variables to your docker compose
file:
  environment:
     - SOFTHSM2_CONF=/etc/hyperledger/fabric/config.file
  volumes:
     - /home/softhsm/config.file:/etc/hyperledger/fabric/config.file
     - /usr/local/Cellar/softhsm/2.1.0/lib/softhsm/libsofthsm2.so:/etc/hyperledger/fabric/libsofthsm2.so

Setting up a network using HSM¶
If you are deploying Fabric nodes using an HSM, your private keys need to be
generated and stored inside the HSM rather than inside the keystore folder of the node’s
local MSP folder. The keystore folder of the MSP will remain empty. Instead,
the Fabric node will use the subject key identifier of the signing certificate
in the signcerts folder to retrieve the private key from inside the HSM.
The process for creating the node MSP folder differs depending on whether you
are using a Fabric Certificate Authority (CA) your own CA.

Before you begin¶
Before configuring a Fabric node to use an HSM, you should have completed the following steps:

Created a partition on your HSM Server and recorded the Label and PIN of the partition.
Followed instructions in the documentation from your HSM provider to configure an HSM Client that communicates with your HSM server.

Using an HSM with a Fabric CA¶
You can set up a Fabric CA to use an HSM by making the same edits to the CA server configuration file as you would make to a peer or ordering node. Because you can use the Fabric CA to generate keys inside an HSM, the process of creating the local MSP folders is straightforward. Use the following steps:

Modify the bccsp section of the Fabric CA server configuration file and point to the Label and PIN that you created for your HSM. When the Fabric CA server starts, the private key is generated and stored in the HSM. If you are not concerned about exposing your CA signing certificate, you can skip this step and only configure an HSM for your peer or ordering nodes, described in the next steps.
Use the Fabric CA client to register the peer or ordering node identities with your CA.
Before you deploy a peer or ordering node with HSM support, you need to enroll the node identity by storing its private key in the HSM. Edit the bccsp section of the Fabric CA client config file or use the associated environment variables to point to the HSM configuration for your peer or ordering node. In the Fabric CA Client configuration file, replace the default SW configuration with the PKCS11 configuration and provide the values for your own HSM:

bccsp:
  default: PKCS11
  pkcs11:
    Library: /etc/hyperledger/fabric/libsofthsm2.so
    Pin: 71811222
    Label: fabric
    hash: SHA2
    security: 256
    Immutable: false

Then for each node, use the Fabric CA client to generate the peer or ordering node’s MSP folder by enrolling against the node identity that you registered in step 2. Instead of storing the private key in the keystore folder of the associated MSP, the enroll command uses the node’s HSM to generate and store the private key for the peer or ordering node. The keystore folder remains empty.

To configure a peer or ordering node to use the HSM, similarly update the bccsp section of the peer or orderer configuration file to use PKCS11 and provide the Label and PIN. Also, edit the value of the mspConfigPath (for a peer node) or the LocalMSPDir (for an ordering node) to point to the MSP folder that was generated in the previous step using the Fabric CA client. Now that the peer or ordering node is configured to use HSM, when you start the node it will be able sign and endorse transactions with the private key protected by the HSM.

Using an HSM with your own CA¶
If you are using your own Certificate Authority to deploy Fabric components, you
can use an HSM using the following steps:

Configure your CA to communicate with an HSM using PKCS11 and create a Label and PIN.
Then use your CA to generate the private key and signing certificate for each
node, with the private key generated inside the HSM.
Use your CA to build the peer or ordering node MSP folder. Place the signing certificate that you generated in step 1 inside the signcerts folder. You can leave the keystore folder empty.
To configure a peer or ordering node to use the HSM, similarly update the bccsp section of the peer or orderer configuration file to use PKCS11 andand provide the Label and PIN. Edit the value of the mspConfigPath (for a peer node) or the LocalMSPDir (for an ordering node) to point to the MSP folder that was generated in the previous step using the Fabric CA client. Now that the peer or ordering node is configured to use HSM, when you start the node it will be able sign and endorse transactions with the private key protected by the HSM.

Channel Configuration (configtx)¶
Shared configuration for a Hyperledger Fabric blockchain network is
stored in a collection configuration transactions, one per channel. Each
configuration transaction is usually referred to by the shorter name
configtx.
Channel configuration has the following important properties:

Versioned: All elements of the configuration have an associated
version which is advanced with every modification. Further, every
committed configuration receives a sequence number.
Permissioned: Each element of the configuration has an associated
policy which governs whether or not modification to that element is
permitted. Anyone with a copy of the previous configtx (and no
additional info) may verify the validity of a new config based on
these policies.
Hierarchical: A root configuration group contains sub-groups, and
each group of the hierarchy has associated values and policies. These
policies can take advantage of the hierarchy to derive policies at
one level from policies of lower levels.

Anatomy of a configuration¶
Configuration is stored as a transaction of type HeaderType_CONFIG
in a block with no other transactions. These blocks are referred to as
Configuration Blocks, the first of which is referred to as the
Genesis Block.
The proto structures for configuration are stored in
fabric-protos/common/configtx.proto. The Envelope of type
HeaderType_CONFIG encodes a ConfigEnvelope message as the
Payload data field. The proto for ConfigEnvelope is defined
as follows:
message ConfigEnvelope {
    Config config = 1;
    Envelope last_update = 2;
}

The last_update field is defined below in the Updates to
configuration section, but is only necessary when validating the
configuration, not reading it. Instead, the currently committed
configuration is stored in the config field, containing a Config
message.
message Config {
    uint64 sequence = 1;
    ConfigGroup channel_group = 2;
}

The sequence number is incremented by one for each committed
configuration. The channel_group field is the root group which
contains the configuration. The ConfigGroup structure is recursively
defined, and builds a tree of groups, each of which contains values and
policies. It is defined as follows:
message ConfigGroup {
    uint64 version = 1;
    map<string,ConfigGroup> groups = 2;
    map<string,ConfigValue> values = 3;
    map<string,ConfigPolicy> policies = 4;
    string mod_policy = 5;
}

Because ConfigGroup is a recursive structure, it has hierarchical
arrangement. The following example is expressed for clarity in Go
syntax.
// Assume the following groups are defined
var root, child1, child2, grandChild1, grandChild2, grandChild3 *ConfigGroup

// Set the following values
root.Groups["child1"] = child1
root.Groups["child2"] = child2
child1.Groups["grandChild1"] = grandChild1
child2.Groups["grandChild2"] = grandChild2
child2.Groups["grandChild3"] = grandChild3

// The resulting config structure of groups looks like:
// root:
//     child1:
//         grandChild1
//     child2:
//         grandChild2
//         grandChild3

Each group defines a level in the config hierarchy, and each group has
an associated set of values (indexed by string key) and policies (also
indexed by string key).
Values are defined by:
message ConfigValue {
    uint64 version = 1;
    bytes value = 2;
    string mod_policy = 3;
}

Policies are defined by:
message ConfigPolicy {
    uint64 version = 1;
    Policy policy = 2;
    string mod_policy = 3;
}

Note that Values, Policies, and Groups all have a version and a
mod_policy. The version of an element is incremented each time
that element is modified. The mod_policy is used to govern the
required signatures to modify that element. For Groups, modification is
adding or removing elements to the Values, Policies, or Groups maps (or
changing the mod_policy). For Values and Policies, modification is
changing the Value and Policy fields respectively (or changing the
mod_policy). Each element’s mod_policy is evaluated in the
context of the current level of the config. Consider the following
example mod policies defined at Channel.Groups["Application"] (Here,
we use the Go map reference syntax, so
Channel.Groups["Application"].Policies["policy1"] refers to the base
Channel group’s Application group’s Policies map’s
policy1 policy.)

policy1 maps to Channel.Groups["Application"].Policies["policy1"]
Org1/policy2 maps to
Channel.Groups["Application"].Groups["Org1"].Policies["policy2"]
/Channel/policy3 maps to Channel.Policies["policy3"]

Note that if a mod_policy references a policy which does not exist,
the item cannot be modified.

Configuration updates¶
Configuration updates are submitted as an Envelope message of type
HeaderType_CONFIG_UPDATE. The Payload data of the
transaction is a marshaled ConfigUpdateEnvelope. The ConfigUpdateEnvelope
is defined as follows:
message ConfigUpdateEnvelope {
    bytes config_update = 1;
    repeated ConfigSignature signatures = 2;
}

The signatures field contains the set of signatures which authorizes
the config update. Its message definition is:
message ConfigSignature {
    bytes signature_header = 1;
    bytes signature = 2;
}

The signature_header is as defined for standard transactions, while
the signature is over the concatenation of the signature_header
bytes and the config_update bytes from the ConfigUpdateEnvelope
message.
The ConfigUpdateEnvelope config_update bytes are a marshaled
ConfigUpdate message which is defined as follows:
message ConfigUpdate {
    string channel_id = 1;
    ConfigGroup read_set = 2;
    ConfigGroup write_set = 3;
}

The channel_id is the channel ID the update is bound for, this is
necessary to scope the signatures which support this reconfiguration.
The read_set specifies a subset of the existing configuration,
specified sparsely where only the version field is set and no other
fields must be populated. The particular ConfigValue value or
ConfigPolicy policy fields should never be set in the
read_set. The ConfigGroup may have a subset of its map fields
populated, so as to reference an element deeper in the config tree. For
instance, to include the Application group in the read_set, its
parent (the Channel group) must also be included in the read set,
but, the Channel group does not need to populate all of the keys,
such as the Orderer group key, or any of the values or
policies keys.
The write_set specifies the pieces of configuration which are
modified. Because of the hierarchical nature of the configuration, a
write to an element deep in the hierarchy must contain the higher level
elements in its write_set as well. However, for any element in the
write_set which is also specified in the read_set at the same
version, the element should be specified sparsely, just as in the
read_set.
For example, given the configuration:
Channel: (version 0)
    Orderer (version 0)
    Application (version 3)
       Org1 (version 2)

To submit a configuration update which modifies Org1, the
read_set would be:
Channel: (version 0)
    Application: (version 3)

and the write_set would be
Channel: (version 0)
    Application: (version 3)
        Org1 (version 3)

When the CONFIG_UPDATE is received, the orderer computes the
resulting CONFIG by doing the following:

Verifies the channel_id and read_set. All elements in the
read_set must exist at the given versions.
Computes the update set by collecting all elements in the
write_set which do not appear at the same version in the
read_set.
Verifies that each element in the update set increments the version
number of the element update by exactly 1.
Verifies that the signature set attached to the
ConfigUpdateEnvelope satisfies the mod_policy for each
element in the update set.
Computes a new complete version of the config by applying the update
set to the current config.
Writes the new config into a ConfigEnvelope which includes the
CONFIG_UPDATE as the last_update field and the new config
encoded in the config field, along with the incremented
sequence value.
Writes the new ConfigEnvelope into a Envelope of type
CONFIG, and ultimately writes this as the sole transaction in a
new configuration block.

When the peer (or any other receiver for Deliver) receives this
configuration block, it should verify that the config was appropriately
validated by applying the last_update message to the current config
and verifying that the orderer-computed config field contains the
correct new configuration.

Permitted configuration groups and values¶
Any valid configuration is a subset of the following configuration. Here
we use the notation peer.<MSG> to define a ConfigValue whose
value field is a marshaled proto message of name <MSG> defined
in fabric-protos/peer/configuration.proto. The notations
common.<MSG>, msp.<MSG>, and orderer.<MSG> correspond
similarly, but with their messages defined in
fabric-protos/common/configuration.proto,
fabric-protos/msp/mspconfig.proto, and
fabric-protos/orderer/configuration.proto respectively.
Note, that the keys {{org_name}} and {{consortium_name}}
represent arbitrary names, and indicate an element which may be repeated
with different names.
&ConfigGroup{
    Groups: map<string, *ConfigGroup> {
        "Application":&ConfigGroup{
            Groups:map<String, *ConfigGroup> {
                {{org_name}}:&ConfigGroup{
                    Values:map<string, *ConfigValue>{
                        "MSP":msp.MSPConfig,
                        "AnchorPeers":peer.AnchorPeers,
                    },
                },
            },
        },
        "Orderer":&ConfigGroup{
            Groups:map<String, *ConfigGroup> {
                {{org_name}}:&ConfigGroup{
                    Values:map<string, *ConfigValue>{
                        "MSP":msp.MSPConfig,
                    },
                },
            },

            Values:map<string, *ConfigValue> {
                "ConsensusType":orderer.ConsensusType,
                "BatchSize":orderer.BatchSize,
                "BatchTimeout":orderer.BatchTimeout,
                "KafkaBrokers":orderer.KafkaBrokers,
            },
        },
        "Consortiums":&ConfigGroup{
            Groups:map<String, *ConfigGroup> {
                {{consortium_name}}:&ConfigGroup{
                    Groups:map<string, *ConfigGroup> {
                        {{org_name}}:&ConfigGroup{
                            Values:map<string, *ConfigValue>{
                                "MSP":msp.MSPConfig,
                            },
                        },
                    },
                    Values:map<string, *ConfigValue> {
                        "ChannelCreationPolicy":common.Policy,
                    }
                },
            },
        },
    },

    Values: map<string, *ConfigValue> {
        "HashingAlgorithm":common.HashingAlgorithm,
        "BlockHashingDataStructure":common.BlockDataHashingStructure,
        "Consortium":common.Consortium,
        "OrdererAddresses":common.OrdererAddresses,
    },
}

Orderer system channel configuration¶
The ordering system channel needs to define ordering parameters, and
consortiums for creating channels. There must be exactly one ordering
system channel for an ordering service, and it is the first channel to
be created (or more accurately bootstrapped). It is recommended never to
define an Application section inside of the ordering system channel
genesis configuration, but may be done for testing. Note that any member
with read access to the ordering system channel may see all channel
creations, so this channel’s access should be restricted.
The ordering parameters are defined as the following subset of config:
&ConfigGroup{
    Groups: map<string, *ConfigGroup> {
        "Orderer":&ConfigGroup{
            Groups:map<String, *ConfigGroup> {
                {{org_name}}:&ConfigGroup{
                    Values:map<string, *ConfigValue>{
                        "MSP":msp.MSPConfig,
                    },
                },
            },

            Values:map<string, *ConfigValue> {
                "ConsensusType":orderer.ConsensusType,
                "BatchSize":orderer.BatchSize,
                "BatchTimeout":orderer.BatchTimeout,
                "KafkaBrokers":orderer.KafkaBrokers,
            },
        },
    },

Each organization participating in ordering has a group element under
the Orderer group. This group defines a single parameter MSP
which contains the cryptographic identity information for that
organization. The Values of the Orderer group determine how the
ordering nodes function. They exist per channel, so
orderer.BatchTimeout for instance may be specified differently on
one channel than another.
At startup, the orderer is faced with a filesystem which contains
information for many channels. The orderer identifies the system channel
by identifying the channel with the consortiums group defined. The
consortiums group has the following structure.
&ConfigGroup{
    Groups: map<string, *ConfigGroup> {
        "Consortiums":&ConfigGroup{
            Groups:map<String, *ConfigGroup> {
                {{consortium_name}}:&ConfigGroup{
                    Groups:map<string, *ConfigGroup> {
                        {{org_name}}:&ConfigGroup{
                            Values:map<string, *ConfigValue>{
                                "MSP":msp.MSPConfig,
                            },
                        },
                    },
                    Values:map<string, *ConfigValue> {
                        "ChannelCreationPolicy":common.Policy,
                    }
                },
            },
        },
    },
},

Note that each consortium defines a set of members, just like the
organizational members for the ordering orgs. Each consortium also
defines a ChannelCreationPolicy. This is a policy which is applied
to authorize channel creation requests. Typically, this value will be
set to an ImplicitMetaPolicy requiring that the new members of the
channel sign to authorize the channel creation. More details about
channel creation follow later in this document.

Application channel configuration¶
Application configuration is for channels which are designed for
application type transactions. It is defined as follows:
&ConfigGroup{
    Groups: map<string, *ConfigGroup> {
        "Application":&ConfigGroup{
            Groups:map<String, *ConfigGroup> {
                {{org_name}}:&ConfigGroup{
                    Values:map<string, *ConfigValue>{
                        "MSP":msp.MSPConfig,
                        "AnchorPeers":peer.AnchorPeers,
                    },
                },
            },
        },
    },
}

Just like with the Orderer section, each organization is encoded as
a group. However, instead of only encoding the MSP identity
information, each org additionally encodes a list of AnchorPeers.
This list allows the peers of different organizations to contact each
other for peer gossip networking.
The application channel encodes a copy of the orderer orgs and consensus
options to allow for deterministic updating of these parameters, so the
same Orderer section from the orderer system channel configuration
is included. However from an application perspective this may be largely
ignored.

Channel creation¶
When the orderer receives a CONFIG_UPDATE for a channel which does
not exist, the orderer assumes that this must be a channel creation
request and performs the following.

The orderer identifies the consortium which the channel creation
request is to be performed for. It does this by looking at the
Consortium value of the top level group.
The orderer verifies that the organizations included in the
Application group are a subset of the organizations included in
the corresponding consortium and that the ApplicationGroup is set
to version 1.
The orderer verifies that if the consortium has members, that the new
channel also has application members (creation consortiums and
channels with no members is useful for testing only).
The orderer creates a template configuration by taking the
Orderer group from the ordering system channel, and creating an
Application group with the newly specified members and specifying
its mod_policy to be the ChannelCreationPolicy as specified
in the consortium config. Note that the policy is evaluated in the
context of the new configuration, so a policy requiring ALL
members, would require signatures from all the new channel members,
not all the members of the consortium.
The orderer then applies the CONFIG_UPDATE as an update to this
template configuration. Because the CONFIG_UPDATE applies
modifications to the Application group (its version is
1), the config code validates these updates against the
ChannelCreationPolicy. If the channel creation contains any other
modifications, such as to an individual org’s anchor peers, the
corresponding mod policy for the element will be invoked.
The new CONFIG transaction with the new channel config is wrapped
and sent for ordering on the ordering system channel. After ordering,
the channel is created.

Endorsement policies¶
Every chaincode has an endorsement policy which specifies the set of peers on
a channel that must execute chaincode and endorse the execution results in
order for the transaction to be considered valid. These endorsement policies
define the organizations (through their peers) who must “endorse” (i.e., approve
of) the execution of a proposal.

Note
Recall that state, represented by key-value pairs, is separate
from blockchain data. For more on this, check out our Ledger
documentation.

As part of the transaction validation step performed by the peers, each validating
peer checks to make sure that the transaction contains the appropriate number
of endorsements and that they are from the expected sources (both of these are
specified in the endorsement policy). The endorsements are also checked to make
sure they’re valid (i.e., that they are valid signatures from valid certificates).

Multiple ways to require endorsement¶
By default, endorsement policies are specified in the chaincode definition,
which is agreed to by channel members and then committed to a channel (that is,
one endorsement policy covers all of the state associated with a chaincode).
For private data collections, you can also specify an endorsement policy
at the private data collection level, which would override the chaincode
level endorsement policy for any keys in the private data collection, thereby
further restricting which organizations can write to a private data collection.
Finally, there are cases where it may be necessary for a particular public
channel state or private data collection state (a particular key-value pair,
in other words) to have a different endorsement policy.
This state-based endorsement allows the chaincode-level or collection-level
endorsement policies to be overridden by a different policy for the specified keys.
To illustrate the circumstances in which the various types of endorsement policies
might be used, consider a channel on which cars are being exchanged. The “creation”
— also known as “issuance” – of a car as an asset that can be traded (putting
the key-value pair that represents it into the world state, in other words) would
have to satisfy the chaincode-level endorsement policy. To see how to set a
chaincode-level endorsement policy, check out the section below.
If the key representing the car requires a specific endorsement policy, it can be
defined either when the car is created or afterwards. There are a number of reasons
why it might be necessary or preferable to set a state-specific endorsement policy. The
car might have historical importance or value that makes it necessary to have the
endorsement of a licensed appraiser. Also, the owner of the car (if they’re a
member of the channel) might also want to ensure that their peer signs off on a
transaction. In both cases, an endorsement policy is required for a particular
asset that is different from the default endorsement policies for the other
assets associated with that chaincode.
We’ll show you how to define a state-based endorsement policy in a subsequent
section. But first, let’s see how we set a chaincode-level endorsement policy.

Setting chaincode-level endorsement policies¶
Chaincode-level endorsement policies are agreed to by channel members when they
approve a chaincode definition for their organization. A sufficient number of
channel members need to approve a chaincode definition to meet the
Channel/Application/LifecycleEndorsement policy, which by default is set to
a majority of channel members, before the definition can be committed to the
channel. Once the definition has been committed, the chaincode is ready to use.
Any invoke of the chaincode that writes data to the ledger will need to be
validated by enough channel members to meet the endorsement policy.
You can specify an endorsement policy for a chainocode using the Fabric SDKs.
For an example, visit the How to install and start your chaincode
in the Node.js SDK documentation. You can also create an endorsement policy from
your CLI when you approve and commit a chaincode definition with the Fabric peer
binaries by using the --signature-policy flag.

Note
Don’t worry about the policy syntax ('Org1.member', et all) right
now. We’ll talk more about the syntax in the next section.

For example:
peer lifecycle chaincode approveformyorg --channelID mychannel --signature-policy "AND('Org1.member', 'Org2.member')" --name mycc --version 1.0 --package-id mycc_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173 --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --waitForEvent

The above command approves the chaincode definition of mycc with the policy
AND('Org1.member', 'Org2.member') which would require that a member of both
Org1 and Org2 sign the transaction. After a sufficient number of channel members
approve a chaincode definition for mycc, the definition and endorsement
policy can be committed to the channel using the command below:
peer lifecycle chaincode commit -o orderer.example.com:7050 --channelID mychannel --signature-policy "AND('Org1.member', 'Org2.member')" --name mycc --version 1.0 --sequence 1 --init-required --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --waitForEvent --peerAddresses peer0.org1.example.com:7051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org1.example.com/peers/peer0.org1.example.com/tls/ca.crt --peerAddresses peer0.org2.example.com:9051 --tlsRootCertFiles /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/peerOrganizations/org2.example.com/peers/peer0.org2.example.com/tls/ca.crt

Notice that, if the identity classification is enabled (see Membership Service Providers (MSP)), one can
use the PEER role to restrict endorsement to only peers.
For example:
peer lifecycle chaincode approveformyorg --channelID mychannel --signature-policy "AND('Org1.peer', 'Org2.peer')" --name mycc --version 1.0 --package-id mycc_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173 --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --waitForEvent

In addition to the specifying an endorsement policy from the CLI or SDK, a
chaincode can also use policies in the channel configuration as endorsement
policies. You can use the ``–channel-config-policy``flag to select a channel policy with
format used by the channel configuration and by ACLs.
For example:
peer lifecycle chaincode approveformyorg --channelID mychannel --channel-config-policy Channel/Application/Admins --name mycc --version 1.0 --package-id mycc_1:3a8c52d70c36313cfebbaf09d8616e7a6318ababa01c7cbe40603c373bcfe173 --sequence 1 --tls --cafile /opt/gopath/src/github.com/hyperledger/fabric/peer/crypto/ordererOrganizations/example.com/orderers/orderer.example.com/msp/tlscacerts/tlsca.example.com-cert.pem --waitForEvent

If you do not specify a policy, the chaincode definition will use the
Channel/Application/Endorsement policy by default, which requires that a
transaction be validated by a majority of channel members. This policy depends on
the membership of the channel, so it will be updated automatically when organizations
are added or removed from a channel. One advantage of using channel policies is
that they can be written to be updated automatically with channel membership.
If you specify an endorsement policy using the --signature-policy flag or
the SDK, you will need to update the policy when organizations join or leave the
channel. A new organization added to the channel after the chaincode has been defined
will be able to query a chaincode (provided the query has appropriate authorization as
defined by channel policies and any application level checks enforced by the
chaincode) but will not be able to execute or endorse the chaincode. Only
organizations listed in the endorsement policy syntax will be able sign
transactions.

Endorsement policy syntax¶
As you can see above, policies are expressed in terms of principals
(“principals” are identities matched to a role). Principals are described as
'MSP.ROLE', where MSP represents the required MSP ID and ROLE
represents one of the four accepted roles: member, admin, client, and
peer.
Here are a few examples of valid principals:

'Org0.admin': any administrator of the Org0 MSP
'Org1.member': any member of the Org1 MSP
'Org1.client': any client of the Org1 MSP
'Org1.peer': any peer of the Org1 MSP

The syntax of the language is:
EXPR(E[, E...])
Where EXPR is either AND, OR, or OutOf, and E is either a
principal (with the syntax described above) or another nested call to EXPR.

For example:

AND('Org1.member', 'Org2.member', 'Org3.member') requests one signature
from each of the three principals.
OR('Org1.member', 'Org2.member') requests one signature from either one
of the two principals.
OR('Org1.member', AND('Org2.member', 'Org3.member')) requests either one
signature from a member of the Org1 MSP or one signature from a member
of the Org2 MSP and one signature from a member of the Org3 MSP.
OutOf(1, 'Org1.member', 'Org2.member'), which resolves to the same thing
as OR('Org1.member', 'Org2.member').
Similarly, OutOf(2, 'Org1.member', 'Org2.member') is equivalent to
AND('Org1.member', 'Org2.member'), and OutOf(2, 'Org1.member',
'Org2.member', 'Org3.member') is equivalent to OR(AND('Org1.member',
'Org2.member'), AND('Org1.member', 'Org3.member'), AND('Org2.member',
'Org3.member')).

Setting collection-level endorsement policies¶
Similar to chaincode-level endorsement policies, when you approve and commit
a chaincode definition, you can also specify the chaincode’s private data collections
and corresponding collection-level endorsement policies. If a collection-level
endorsement policy is set, transactions that write to a private data collection
key will require that the specified organization peers have endorsed the transaction.
You can use collection-level endorsement policies to restrict which organization
peers can write to the private data collection key namespace, for example to
ensure that non-authorized organizations cannot write to a collection, and to
have confidence that any state in a private data collection has been endorsed
by the required collection organization(s).
The collection-level endorsement policy may be less restrictive or more restrictive
than the chaincode-level endorsement policy and the collection’s private data
distribution policy.  For example a majority of organizations may be required
to endorse a chaincode transaction, but a specific organization may be required
to endorse a transaction that includes a key in a specific collection.
The syntax for collection-level endorsement policies exactly matches the syntax
for chaincode-level endorsement policies — in the collection configuration
you can specify an endorsementPolicy with either a signaturePolicy or
channelConfigPolicy. For more details see Private Data.

Setting key-level endorsement policies¶
Setting regular chaincode-level or collection-level endorsement policies is tied to
the lifecycle of the corresponding chaincode. They can only be set or modified when
defining the chaincode on a channel.
In contrast, key-level endorsement policies can be set and modified in a more
granular fashion from within a chaincode. The modification is part of the
read-write set of a regular transaction.
The shim API provides the following functions to set and retrieve an endorsement
policy for/from a regular key.

Note
ep below stands for the “endorsement policy”, which can be expressed
either by using the same syntax described above or by using the
convenience function described below. Either method will generate a
binary version of the endorsement policy that can be consumed by the
basic shim API.

SetStateValidationParameter(key string, ep []byte) error
GetStateValidationParameter(key string) ([]byte, error)

For keys that are part of Private data in a collection the
following functions apply:
SetPrivateDataValidationParameter(collection, key string, ep []byte) error
GetPrivateDataValidationParameter(collection, key string) ([]byte, error)

To help set endorsement policies and marshal them into validation
parameter byte arrays, the Go shim provides an extension with convenience
functions that allow the chaincode developer to deal with endorsement policies
in terms of the MSP identifiers of organizations, see KeyEndorsementPolicy:
type KeyEndorsementPolicy interface {
    // Policy returns the endorsement policy as bytes
    Policy() ([]byte, error)

    // AddOrgs adds the specified orgs to the list of orgs that are required
    // to endorse
    AddOrgs(roleType RoleType, organizations ...string) error

    // DelOrgs delete the specified channel orgs from the existing key-level endorsement
    // policy for this KVS key. If any org is not present, an error will be returned.
    DelOrgs(organizations ...string) error

    // ListOrgs returns an array of channel orgs that are required to endorse changes
    ListOrgs() ([]string)
}

For example, to set an endorsement policy for a key where two specific orgs are
required to endorse the key change, pass both org MSPIDs to AddOrgs(),
and then call Policy() to construct the endorsement policy byte array that
can be passed to SetStateValidationParameter().
To add the shim extension to your chaincode as a dependency, see Managing external dependencies for chaincode written in Go.

Validation¶
At commit time, setting a value of a key is no different from setting the
endorsement policy of a key — both update the state of the key and are
validated based on the same rules.

Validation
no validation parameter set
validation parameter set

modify value
check chaincode or collection ep
check key-level ep

modify key-level ep
check chaincode or collection ep
check key-level ep

As we discussed above, if a key is modified and no key-level endorsement policy
is present, the chaincode-level or collection-level endorsement policy applies by default.
This is also true when a key-level endorsement policy is set for a key for the first time
— the new key-level endorsement policy must first be endorsed according to the
pre-existing chaincode-level or collection-level endorsement policy.
If a key is modified and a key-level endorsement policy is present, the key-level
endorsement policy overrides the chaincode-level or collection-level endorsement policy.
In practice, this means that the key-level endorsement policy can be either less restrictive
or more restrictive than the chaincode-level or collection-level endorsement policies.
Because the chaincode-level or collection-level endorsement policy must be satisfied in order
to set a key-level endorsement policy for the first time, no trust assumptions have been violated.
If a key’s endorsement policy is removed (set to nil), the chaincode-level
or collection-level endorsement policy becomes the default again.
If a transaction modifies multiple keys with different associated key-level
endorsement policies, all of these policies need to be satisfied in order
for the transaction to be valid.

Pluggable transaction endorsement and validation¶

Motivation¶
When a transaction is validated at time of commit, the peer performs various
checks before applying the state changes that come with the transaction itself:

Validating the identities that signed the transaction.
Verifying the signatures of the endorsers on the transaction.
Ensuring the transaction satisfies the endorsement policies of the namespaces
of the corresponding chaincodes.

There are use cases which demand custom transaction validation rules different
from the default Fabric validation rules, such as:

UTXO (Unspent Transaction Output): When the validation takes into account
whether the transaction doesn’t double spend its inputs.
Anonymous transactions: When the endorsement doesn’t contain the identity
of the peer, but a signature and a public key are shared that can’t be linked
to the peer’s identity.

Pluggable endorsement and validation logic¶
Fabric allows for the implementation and deployment of custom endorsement and
validation logic into the peer to be associated with chaincode handling in a
pluggable manner. This logic can be either compiled into the peer as built in
selectable logic, or compiled and deployed alongside the peer as a
Go plugin.
By default, A chaincode will use the built in endorsement and validation logic.
However, users have the option of selecting custom endorsement and validation
plugins as part of the chaincode definition. An administrator can extend the
endorsement/validation logic available to the peer by customizing the peer’s
local configuration.

Configuration¶
Each peer has a local configuration (core.yaml) that declares a mapping
between the endorsement/validation logic name and the implementation that is to
be run.
The default logic are called ESCC (with the “E” standing for endorsement) and
VSCC (validation), and they can be found in the peer local configuration in
the handlers section:
handlers:
    endorsers:
      escc:
        name: DefaultEndorsement
    validators:
      vscc:
        name: DefaultValidation

When the endorsement or validation implementation is compiled into the peer, the
name property represents the initialization function that is to be run in order
to obtain the factory that creates instances of the endorsement/validation logic.
The function is an instance method of the HandlerLibrary construct under
core/handlers/library/library.go and in order for custom endorsement or
validation logic to be added, this construct needs to be extended with any
additional methods.
Since this is cumbersome and poses a deployment challenge, one can also deploy
custom endorsement and validation as a Go plugin by adding another property
under the name called library.
For example, if we have custom endorsement and validation logic which is
implemented as a plugin, we would have the following entries in the configuration
in core.yaml:
handlers:
    endorsers:
      escc:
        name: DefaultEndorsement
      custom:
        name: customEndorsement
        library: /etc/hyperledger/fabric/plugins/customEndorsement.so
    validators:
      vscc:
        name: DefaultValidation
      custom:
        name: customValidation
        library: /etc/hyperledger/fabric/plugins/customValidation.so

And we’d have to place the .so plugin files in the peer’s local file system.
The name of the custom plugin needs to be referenced by the chaincode definition
to be used by the chaincode. If you are using the peer CLI to approve the
chaincode definition, use the --escc and --vscc flag to select the name
of the custom endorsement or validation library. If you are using the
Fabric SDK for Node.js, visit How to install and start your chaincode.
For more information, see Fabric chaincode lifecycle.

Note
Hereafter, custom endorsement or validation logic implementation is
going to be referred to as “plugins”, even if they are compiled into
the peer.

Endorsement plugin implementation¶
To implement an endorsement plugin, one must implement the Plugin interface
found in core/handlers/endorsement/api/endorsement.go:
// Plugin endorses a proposal response
type Plugin interface {
    // Endorse signs the given payload(ProposalResponsePayload bytes), and optionally mutates it.
    // Returns:
    // The Endorsement: A signature over the payload, and an identity that is used to verify the signature
    // The payload that was given as input (could be modified within this function)
    // Or error on failure
    Endorse(payload []byte, sp *peer.SignedProposal) (*peer.Endorsement, []byte, error)

    // Init injects dependencies into the instance of the Plugin
    Init(dependencies ...Dependency) error
}

An endorsement plugin instance of a given plugin type (identified either by the
method name as an instance method of the HandlerLibrary or by the plugin .so
file path) is created for each channel by having the peer invoke the New
method in the PluginFactory interface which is also expected to be implemented
by the plugin developer:
// PluginFactory creates a new instance of a Plugin
type PluginFactory interface {
    New() Plugin
}

The Init method is expected to receive as input all the dependencies declared
under core/handlers/endorsement/api/, identified as embedding the Dependency
interface.
After the creation of the Plugin instance, the Init method is invoked on
it by the peer with the dependencies passed as parameters.
Currently Fabric comes with the following dependencies for endorsement plugins:

SigningIdentityFetcher: Returns an instance of SigningIdentity based
on a given signed proposal:

// SigningIdentity signs messages and serializes its public identity to bytes
type SigningIdentity interface {
    // Serialize returns a byte representation of this identity which is used to verify
    // messages signed by this SigningIdentity
    Serialize() ([]byte, error)

    // Sign signs the given payload and returns a signature
    Sign([]byte) ([]byte, error)
}

StateFetcher: Fetches a State object which interacts with the world
state:

// State defines interaction with the world state
type State interface {
    // GetPrivateDataMultipleKeys gets the values for the multiple private data items in a single call
    GetPrivateDataMultipleKeys(namespace, collection string, keys []string) ([][]byte, error)

    // GetStateMultipleKeys gets the values for multiple keys in a single call
    GetStateMultipleKeys(namespace string, keys []string) ([][]byte, error)

    // GetTransientByTXID gets the values private data associated with the given txID
    GetTransientByTXID(txID string) ([]*rwset.TxPvtReadWriteSet, error)

    // Done releases resources occupied by the State
    Done()
 }

Validation plugin implementation¶
To implement a validation plugin, one must implement the Plugin interface
found in core/handlers/validation/api/validation.go:
// Plugin validates transactions
type Plugin interface {
    // Validate returns nil if the action at the given position inside the transaction
    // at the given position in the given block is valid, or an error if not.
    Validate(block *common.Block, namespace string, txPosition int, actionPosition int, contextData ...ContextDatum) error

    // Init injects dependencies into the instance of the Plugin
    Init(dependencies ...Dependency) error
}

Each ContextDatum is additional runtime-derived metadata that is passed by
the peer to the validation plugin. Currently, the only ContextDatum that is
passed is one that represents the endorsement policy of the chaincode:
 // SerializedPolicy defines a serialized policy
type SerializedPolicy interface {
      validation.ContextDatum

      // Bytes returns the bytes of the SerializedPolicy
      Bytes() []byte
 }

A validation plugin instance of a given plugin type (identified either by the
method name as an instance method of the HandlerLibrary or by the plugin .so
file path) is created for each channel by having the peer invoke the New
method in the PluginFactory interface which is also expected to be implemented
by the plugin developer:
// PluginFactory creates a new instance of a Plugin
type PluginFactory interface {
    New() Plugin
}

The Init method is expected to receive as input all the dependencies declared
under core/handlers/validation/api/, identified as embedding the Dependency
interface.
After the creation of the Plugin instance, the Init method is invoked on
it by the peer with the dependencies passed as parameters.
Currently Fabric comes with the following dependencies for validation plugins:

IdentityDeserializer: Converts byte representation of identities into
Identity objects that can be used to verify signatures signed by them, be
validated themselves against their corresponding MSP, and see whether they
satisfy a given MSP Principal. The full specification can be found in
core/handlers/validation/api/identities/identities.go.
PolicyEvaluator: Evaluates whether a given policy is satisfied:

// PolicyEvaluator evaluates policies
type PolicyEvaluator interface {
    validation.Dependency

    // Evaluate takes a set of SignedData and evaluates whether this set of signatures satisfies
    // the policy with the given bytes
    Evaluate(policyBytes []byte, signatureSet []*common.SignedData) error
}

StateFetcher: Fetches a State object which interacts with the world state:

// State defines interaction with the world state
type State interface {
    // GetStateMultipleKeys gets the values for multiple keys in a single call
    GetStateMultipleKeys(namespace string, keys []string) ([][]byte, error)

    // GetStateRangeScanIterator returns an iterator that contains all the key-values between given key ranges.
    // startKey is included in the results and endKey is excluded. An empty startKey refers to the first available key
    // and an empty endKey refers to the last available key. For scanning all the keys, both the startKey and the endKey
    // can be supplied as empty strings. However, a full scan should be used judiciously for performance reasons.
    // The returned ResultsIterator contains results of type *KV which is defined in fabric-protos/ledger/queryresult.
    GetStateRangeScanIterator(namespace string, startKey string, endKey string) (ResultsIterator, error)

    // GetStateMetadata returns the metadata for given namespace and key
    GetStateMetadata(namespace, key string) (map[string][]byte, error)

    // GetPrivateDataMetadata gets the metadata of a private data item identified by a tuple <namespace, collection, key>
    GetPrivateDataMetadata(namespace, collection, key string) (map[string][]byte, error)

    // Done releases resources occupied by the State
    Done()
}

Important notes¶

Validation plugin consistency across peers: In future releases, the Fabric
channel infrastructure would guarantee that the same validation logic is used
for a given chaincode by all peers in the channel at any given blockchain
height in order to eliminate the chance of mis-configuration which would might
lead to state divergence among peers that accidentally run different
implementations. However, for now it is the sole responsibility of the system
operators and administrators to ensure this doesn’t happen.
Validation plugin error handling: Whenever a validation plugin can’t
determine whether a given transaction is valid or not, because of some transient
execution problem like inability to access the database, it should return an
error of type ExecutionFailureError that is defined in core/handlers/validation/api/validation.go.
Any other error that is returned, is treated as an endorsement policy error
and marks the transaction as invalidated by the validation logic. However,
if an ExecutionFailureError is returned, the chain processing halts instead
of marking the transaction as invalid. This is to prevent state divergence
between different peers.
Error handling for private metadata retrieval: In case a plugin retrieves
metadata for private data by making use of the StateFetcher interface,
it is important that errors are handled as follows: CollConfigNotDefinedError
and InvalidCollNameError, signalling that the specified collection does
not exist, should be handled as deterministic errors and should not lead the
plugin to return an ExecutionFailureError.
Importing Fabric code into the plugin: Importing code that belongs to Fabric
other than protobufs as part of the plugin is highly discouraged, and can lead
to issues when the Fabric code changes between releases, or can cause inoperability
issues when running mixed peer versions. Ideally, the plugin code should only
use the dependencies given to it, and should import the bare minimum other
than protobufs.

Access Control Lists (ACL)¶

What is an Access Control List?¶
Note: This topic deals with access control and policies on a channel
administration level. To learn about access control within a chaincode, check out
our chaincode for developers tutorial.
Fabric uses access control lists (ACLs) to manage access to resources by associating
a Policy with a resource. Fabric contains a number of default ACLs. In this
document, we’ll talk about how they’re formatted and how the defaults can be overridden.
But before we can do that, it’s necessary to understand a little about resources
and policies.

Resources¶
Users interact with Fabric by targeting a user chaincode,
or an events stream source, or system chaincode that
are called in the background. As such, these endpoints are considered “resources”
on which access control should be exercised.
Application developers need to be aware of these resources and the default
policies associated with them. The complete list of these resources are found in
configtx.yaml. You can look at a sample configtx.yaml file here.
The resources named in configtx.yaml is an exhaustive list of all internal resources
currently defined by Fabric. The loose convention adopted there is <component>/<resource>.
So cscc/GetConfigBlock is the resource for the GetConfigBlock call in the CSCC
component.

Policies¶
Policies are fundamental to the way Fabric works because they allow the identity
(or set of identities) associated with a request to be checked against the policy
associated with the resource needed to fulfill the request. Endorsement policies
are used to determine whether a transaction has been appropriately endorsed. The
policies defined in the channel configuration are referenced as modification policies
as well as for access control, and are defined in the channel configuration itself.
Policies can be structured in one of two ways: as Signature policies or as an
ImplicitMeta policy.

Signature policies¶
These policies identify specific users who must sign in order for a policy
to be satisfied. For example:
Policies:
  MyPolicy:
    Type: Signature
    Rule: “Org1.Peer OR Org2.Peer”

This policy construct can be interpreted as: the policy named MyPolicy can
only be satisfied by the signature of an identity with role of “a peer from
Org1” or “a peer from Org2”.
Signature policies support arbitrary combinations of AND, OR, and NOutOf,
allowing the construction of extremely powerful rules like: “An admin of org A
and two other admins, or 11 of 20 org admins”.

ImplicitMeta policies¶
ImplicitMeta policies aggregate the result of policies deeper in the
configuration hierarchy that are ultimately defined by Signature policies. They
support default rules like “A majority of the organization admins”. These policies
use a different but still very simple syntax as compared to Signature policies:
<ALL|ANY|MAJORITY> <sub_policy>.
For example: ANY Readers or MAJORITY Admins.
Note that in the default policy configuration Admins have an operational role.
Policies that specify that only Admins — or some subset of Admins — have access
to a resource will tend to be for sensitive or operational aspects of the network
(such as instantiating chaincode on a channel). Writers will tend to be able to
propose ledger updates, such as a transaction, but will not typically have
administrative permissions. Readers have a passive role. They can access
information but do not have the permission to propose ledger updates nor do can
they perform administrative tasks. These default policies can be added to,
edited, or supplemented, for example by the new peer and client roles (if you
have NodeOU support).
Here’s an example of an ImplicitMeta policy structure:
Policies:
  AnotherPolicy:
    Type: ImplicitMeta
    Rule: "MAJORITY Admins"

Here, the policy AnotherPolicy can be satisfied by the MAJORITY of Admins,
where Admins is eventually being specified by lower level Signature policy.

Where is access control specified?¶
Access control defaults exist inside configtx.yaml, the file that configtxgen
uses to build channel configurations.
Access control can be updated in one of two ways, either by editing configtx.yaml
itself, which will be used when creating new channel configurations, or by updating
access control in the channel configuration of an existing channel.

How ACLs are formatted in configtx.yaml¶
ACLs are formatted as a key-value pair consisting of a resource function name
followed by a string. To see what this looks like, reference this sample configtx.yaml file.
Two excerpts from this sample:
# ACL policy for invoking chaincodes on peer
peer/Propose: /Channel/Application/Writers

# ACL policy for sending block events
event/Block: /Channel/Application/Readers

These ACLs define that access to peer/Propose and event/Block resources
is restricted to identities satisfying the policy defined at the canonical path
/Channel/Application/Writers and /Channel/Application/Readers, respectively.

Updating ACL defaults in configtx.yaml¶
In cases where it will be necessary to override ACL defaults when bootstrapping
a network, or to change the ACLs before a channel has been bootstrapped, the
best practice will be to update configtx.yaml.
Let’s say you want to modify the peer/Propose ACL default — which specifies
the policy for invoking chaincodes on a peer – from /Channel/Application/Writers
to a policy called MyPolicy.
This is done by adding a policy called MyPolicy (it could be called anything,
but for this example we’ll call it MyPolicy). The policy is defined in the
Application.Policies section inside configtx.yaml and specifies a rule to be
checked to grant or deny access to a user. For this example, we’ll be creating a
Signature policy identifying SampleOrg.admin.
Policies: &ApplicationDefaultPolicies
    Readers:
        Type: ImplicitMeta
        Rule: "ANY Readers"
    Writers:
        Type: ImplicitMeta
        Rule: "ANY Writers"
    Admins:
        Type: ImplicitMeta
        Rule: "MAJORITY Admins"
    MyPolicy:
        Type: Signature
        Rule: "OR('SampleOrg.admin')"

Then, edit the Application: ACLs section inside configtx.yaml to change
peer/Propose from this:
peer/Propose: /Channel/Application/Writers
To this:
peer/Propose: /Channel/Application/MyPolicy
Once these fields have been changed in configtx.yaml, the configtxgen tool
will use the policies and ACLs defined when creating a channel creation
transaction. When appropriately signed and submitted by one of the admins of the
consortium members, a new channel with the defined ACLs and policies is created.
Once MyPolicy has been bootstrapped into the channel configuration, it can also
be referenced to override other ACL defaults. For example:
SampleSingleMSPChannel:
    Consortium: SampleConsortium
    Application:
        <<: *ApplicationDefaults
        ACLs:
            <<: *ACLsDefault
            event/Block: /Channel/Application/MyPolicy

This would restrict the ability to subscribe to block events to SampleOrg.admin.
If channels have already been created that want to use this ACL, they’ll have
to update their channel configurations one at a time using the following flow:

Updating ACL defaults in the channel config¶
If channels have already been created that want to use MyPolicy to restrict
access to peer/Propose — or if they want to create ACLs they don’t want
other channels to know about — they’ll have to update their channel
configurations one at a time through config update transactions.
Note: Channel configuration transactions are an involved process we won’t
delve into here. If you want to read more about them check out our document on
channel configuration updates and our “Adding an Org to a Channel” tutorial.
After pulling, translating, and stripping the configuration block of its metadata,
you would edit the configuration by adding MyPolicy under Application: policies,
where the Admins, Writers, and Readers policies already live.
"MyPolicy": {
  "mod_policy": "Admins",
  "policy": {
    "type": 1,
    "value": {
      "identities": [
        {
          "principal": {
            "msp_identifier": "SampleOrg",
            "role": "ADMIN"
          },
          "principal_classification": "ROLE"
        }
      ],
      "rule": {
        "n_out_of": {
          "n": 1,
          "rules": [
            {
              "signed_by": 0
            }
          ]
        }
      },
      "version": 0
    }
  },
  "version": "0"
},

Note in particular the msp_identifer and role here.
Then, in the ACLs section of the config, change the peer/Propose ACL from
this:
"peer/Propose": {
  "policy_ref": "/Channel/Application/Writers"

To this:
"peer/Propose": {
  "policy_ref": "/Channel/Application/MyPolicy"

Note: If you do not have ACLs defined in your channel configuration, you will
have to add the entire ACL structure.
Once the configuration has been updated, it will need to be submitted by the
usual channel update process.

Satisfying an ACL that requires access to multiple resources¶
If a member makes a request that calls multiple system chaincodes, all of the ACLs
for those system chaincodes must be satisfied.
For example, peer/Propose refers to any proposal request on a channel. If the
particular proposal requires access to two system chaincodes that requires an
identity satisfying Writers and one system chaincode that requires an identity
satisfying MyPolicy, then the member submitting the proposal must have an identity
that evaluates to “true” for both Writers and MyPolicy.
In the default configuration, Writers is a signature policy whose rule is
SampleOrg.member. In other words, “any member of my organization”. MyPolicy,
listed above, has a rule of SampleOrg.admin, or “any admin of my organization”.
To satisfy these ACLs, the member would have to be both an administrator and a
member of SampleOrg. By default, all administrators are members (though not all
administrators are members), but it is possible to overwrite these policies to
whatever you want them to be. As a result, it’s important to keep track of these
policies to ensure that the ACLs for peer proposals are not impossible to satisfy
(unless that is the intention).

MSP Implementation with Identity Mixer¶

What is Idemix?¶
Idemix is a cryptographic protocol suite, which provides strong authentication as
well as privacy-preserving features such as anonymity, the ability to transact
without revealing the identity of the transactor, and unlinkability, the
ability of a single identity to send multiple transactions without revealing
that the transactions were sent by the same identity.
There are three actors involved in an Idemix flow: user, issuer, and
verifier.

An issuer certifies a set of user’s attributes are issued in the form of a
digital certificate, hereafter called “credential”.
The user later generates a “zero-knowledge proof”
of possession of the credential and also selectively discloses only the
attributes the user chooses to reveal. The proof, because it is zero-knowledge,
reveals no additional information to the verifier, issuer, or anyone else.

As an example, suppose “Alice” needs to prove to Bob (a store clerk) that she has
a driver’s license issued to her by the DMV.
In this scenario, Alice is the user, the DMV is the issuer, and Bob is the
verifier. In order to prove to Bob that Alice has a driver’s license, she could
show it to him. However, Bob would then be able to see Alice’s name, address,
exact age, etc. — much more information than Bob needs to know.
Instead, Alice can use Idemix to generate a “zero-knowledge proof” for Bob, which
only reveals that she has a valid driver’s license and nothing else.
So from the proof:

Bob does not learn any additional information about Alice other than the fact
that she has a valid license (anonymity).
If Alice visits the store multiple times and generates a proof each time for Bob,
Bob would not be able to tell from the proof that it was the same person
(unlinkability).

Idemix authentication technology provides the trust model and security
guarantees that are similar to what is ensured by standard X.509 certificates but
with underlying cryptographic algorithms that efficiently provide advanced
privacy features including the ones described above. We’ll compare Idemix and
X.509 technologies in detail in the technical section below.

How to use Idemix¶
To understand how to use Idemix with Hyperledger Fabric, we need to see which
Fabric components correspond to the user, issuer, and verifier in Idemix.

The Fabric Java SDK is the API for the user. In the future, other Fabric
SDKs will also support Idemix.

Fabric provides two possible Idemix issuers:

Fabric CA for production environments or development, and
the idemixgen tool for development environments.

The verifier is an Idemix MSP in Fabric.

In order to use Idemix in Hyperledger Fabric, the following three basic steps
are required:

Compare the roles in this image to the ones above.

Consider the issuer.
Fabric CA (version 1.3 or later) has been enhanced to automatically function
as an Idemix issuer. When fabric-ca-server is started (or initialized via
the fabric-ca-server init command), the following two files are
automatically created in the home directory of the fabric-ca-server:
IssuerPublicKey and IssuerRevocationPublicKey. These files are
required in step 2.
For a development environment and if you are not using Fabric CA, you may use
idemixgen to create these files.

Consider the verifier.
You need to create an Idemix MSP using the IssuerPublicKey and
IssuerRevocationPublicKey from step 1.
For example, consider the following excerpt from
configtx.yaml in the Hyperledger Java SDK sample:
- &Org1Idemix
    # defaultorg defines the organization which is used in the sampleconfig
    # of the fabric.git development environment
    name: idemixMSP1

    # id to load the msp definition as
    id: idemixMSPID1

    msptype: idemix
    mspdir: crypto-config/peerOrganizations/org3.example.com

The msptype is set to idemix and the contents of the mspdir
directory (crypto-config/peerOrganizations/org3.example.com/msp in this
example) contains the IssuerPublicKey and IssuerRevocationPublicKey
files.
Note that in this example, Org1Idemix represents the Idemix MSP for Org1
(not shown), which would also have an X509 MSP.

Consider the user. Recall that the Java SDK is the API for the user.
There is only a single additional API call required in order to use Idemix
with the Java SDK: the idemixEnroll method of the
org.hyperledger.fabric_ca.sdk.HFCAClient class. For example, assume
hfcaClient is your HFCAClient object and x509Enrollment is your
org.hyperledger.fabric.sdk.Enrollment associated with your X509 certificate.
The following call will return an org.hyperledger.fabric.sdk.Enrollment
object associated with your Idemix credential.
IdemixEnrollment idemixEnrollment = hfcaClient.idemixEnroll(x509enrollment, "idemixMSPID1");

Note also that IdemixEnrollment implements the org.hyperledger.fabric.sdk.Enrollment
interface and can, therefore, be used in the same way that one uses the X509
enrollment object, except, of course, that this automatically provides the
privacy enhancing features of Idemix.

Idemix and chaincode¶
From a verifier perspective, there is one more actor to consider: chaincode.
What can chaincode learn about the transactor when an Idemix credential is used?
The cid (Client Identity) library
(for Go only) has been extended to support the GetAttributeValue function
when an Idemix credential is used. However, as mentioned in the “Current
limitations” section below, there are only two attributes which are disclosed in
the Idemix case: ou and role.
If Fabric CA is the credential issuer:

the value of the ou attribute is the identity’s affiliation (e.g.
“org1.department1”);
the value of the role attribute will be either ‘member’ or ‘admin’. A
value of ‘admin’ means that the identity is an MSP administrator. By default,
identities created by Fabric CA will return the ‘member’ role. In order to
create an ‘admin’ identity, register the identity with the role attribute
and a value of 2.

For an example of setting an affiliation in the Java SDK see this sample.
For an example of using the CID library in go chaincode to retrieve attributes,
see this go chaincode.
Idemix organizations cannot be used to endorse a chaincode or approve a chaincode
definition. This needs to be taken into account when you set the
LifecycleEndorsement and Endorsement policies on your channels. For more
information, see the limitations section below.

Current limitations¶
The current version of Idemix does have a few limitations.

Idemix organizations and endorsement policies
Idemix organizations cannot be used to endorse a chaincode transaction or
approve a chaincode definition. By default, the
Channel/Application/LifecycleEndorsement and
Channel/Application/Endorsement policies will require signatures from a
majority of organizations active on the channel. This implies that a channel
that contains a large number of Idemix organizations may not be able to
reach the majority needed to fulfill the default policy. For example, if a
channel has two MSP Organizations and two Idemix organizations, the channel
policy will require that three out of four organizations approve a chaincode
definition to commit that definition to the channel. Because Idemix
organizations cannot approve a chaincode definition, the policy will only be
able to validate two out of four signatures.
If your channel contains a sufficient number of Idemix organizations to affect
the endorsement policy, you can use a signature policy to explicitly specify
the required MSP organizations.

Fixed set of attributes
It not yet possible to issue or use an Idemix credential with custom attributes.
Custom attributes will be supported in a future release.
The following four attributes are currently supported:

Organizational Unit attribute (“ou”):

Usage: same as X.509
Type: String
Revealed: always

Role attribute (“role”):

Usage: same as X.509
Type: integer
Revealed: always

Enrollment ID attribute

Usage: uniquely identify a user — same in all enrollment credentials that
belong to the same user (will be used for auditing in the future releases)
Type: BIG
Revealed: never in the signature, only when generating an authentication token for Fabric CA

Revocation Handle attribute

Usage: uniquely identify a credential (will be used for revocation in future releases)
Type: integer
Revealed: never

Revocation is not yet supported

Although much of the revocation framework is in place as can be seen by the
presence of a revocation handle attribute mentioned above, revocation of an
Idemix credential is not yet supported.

Peers do not use Idemix for endorsement

Currently, Idemix MSP is used by the peers only for signature verification.
Signing with Idemix is only done via Client SDK. More roles (including a
‘peer’ role) will be supported by Idemix MSP.

Technical summary¶

Comparing Idemix credentials to X.509 certificates¶
The certificate/credential concept and the issuance process are very similar in
Idemix and X.509 certs: a set of attributes is digitally signed with a signature
that cannot be forged and there is a secret key to which a credential is
cryptographically bound.
The main difference between a standard X.509 certificate and an Identity Mixer
credential is the signature scheme that is used to certify the attributes. The
signatures underlying the Identity Mixer system allow for efficient proofs of the
possession of a signature and the corresponding attributes without revealing the
signature and (selected) attribute values themselves. We use zero-knowledge proofs
to ensure that such “knowledge” or “information” is not revealed while ensuring
that the signature over some attributes is valid and the user is in possession
of the corresponding credential secret key.
Such proofs, like X.509 certificates, can be verified with the public key of
the authority that originally signed the credential and cannot be successfully
forged. Only the user who knows the credential secret key can generate the proofs
about the credential and its attributes.
With regard to unlinkability, when an X.509 certificate is presented, all attributes
have to be revealed to verify the certificate signature. This implies that all
certificate usages for signing transactions are linkable.
To avoid such linkability, fresh X.509 certificates need to be used every time,
which results in complex key management and communication and storage overhead.
Furthermore, there are cases where it is important that not even the CA issuing
the certificates is able to link all the transactions to the user.
Idemix helps to avoid linkability with respect to both the CA and verifiers,
since even the CA is not able to link proofs to the original credential. Neither
the issuer nor a verifier can tell whether two proofs were derived from the same
credential (or from two different ones).
More details on the concepts and features of the Identity Mixer technology are
described in the paper Concepts and Languages for Privacy-Preserving Attribute-Based Authentication.

Topology Information¶
Given the above limitations, it is recommended to have only one Idemix-based MSP
per channel or, at the extreme, per network. Indeed, for example, having multiple Idemix-based MSPs
per channel would allow a party, reading the ledger of that channel, to tell apart
transactions signed by parties belonging to different Idemix-based MSPs. This is because,
each transaction leak the MSP-ID of the signer.
In other words, Idemix currently provides only anonymity of clients among the same organization (MSP).
In the future, Idemix could be extended to support anonymous hierarchies of Idemix-based
Certification Authorities whose certified credentials can be verified by using a unique public-key,
therefore achieving anonymity across organizations (MSPs).
This would allow multiple Idemix-based MSPs to coexist in the same channel.
In principal, a channel can be configured to have a single Idemix-based MSP and multiple
X.509-based MSPs. Of course, the interaction between these MSP can potential
leak information. An assessment of the leaked information need to be done case by case.wq

Underlying cryptographic protocols¶
Idemix technology is built from a blind signature scheme that supports multiple
messages and efficient zero-knowledge proofs of signature possession. All of the
cryptographic building blocks for Idemix were published at the top conferences
and journals and verified by the scientific community.
This particular Idemix implementation for Fabric uses a pairing-based
signature scheme that was briefly proposed by Camenisch and Lysyanskaya
and described in detail by Au et al..
The ability to prove knowledge of a signature in a zero-knowledge proof
Camenisch et al. was used.

Identity Mixer MSP configuration generator (idemixgen)¶
This document describes the usage for the idemixgen utility, which can be
used to create configuration files for the identity mixer based MSP.
Two commands are available, one for creating a fresh CA key pair, and one
for creating an MSP config using a previously generated CA key.

Directory Structure¶
The idemixgen tool will create directories with the following structure:
- /ca/
    IssuerSecretKey
    IssuerPublicKey
    RevocationKey
- /msp/
    IssuerPublicKey
    RevocationPublicKey
- /user/
    SignerConfig

The ca directory contains the issuer secret key (including the revocation key) and should only be present
for a CA. The msp directory contains the information required to set up an
MSP verifying idemix signatures. The user directory specifies a default
signer.

CA Key Generation¶
CA (issuer) keys suitable for identity mixer can be created using command
idemixgen ca-keygen. This will create directories ca and msp in the
working directory.

Adding a Default Signer¶
After generating the ca and msp directories with
idemixgen ca-keygen, a default signer specified in the user directory
can be added to the config with idemixgen signerconfig.
$ idemixgen signerconfig -h
usage: idemixgen signerconfig [<flags>]

Generate a default signer for this Idemix MSP

Flags:
    -h, --help               Show context-sensitive help (also try --help-long and --help-man).
    -u, --org-unit=ORG-UNIT  The Organizational Unit of the default signer
    -a, --admin              Make the default signer admin
    -e, --enrollment-id=ENROLLMENT-ID
                             The enrollment id of the default signer
    -r, --revocation-handle=REVOCATION-HANDLE
                             The handle used to revoke this signer

For example, we can create a default signer that is a member of organizational
unit “OrgUnit1”, with enrollment identity “johndoe”, revocation handle “1234”,
and that is an admin, with the following command:
idemixgen signerconfig -u OrgUnit1 --admin -e "johndoe" -r 1234

The Operations Service¶
The peer and the orderer host an HTTP server that offers a RESTful “operations”
API. This API is unrelated to the Fabric network services and is intended to be
used by operators, not administrators or “users” of the network.
The API exposes the following capabilities:

Log level management
Health checks
Prometheus target for operational metrics (when configured)

Configuring the Operations Service¶
The operations service requires two basic pieces of configuration:

The address and port to listen on.
The TLS certificates and keys to use for authentication and encryption.
Note, these certificates should be generated by a separate and dedicated CA.
Do not use a CA that has generated certificates for any organizations
in any channels.

Peer¶
For each peer, the operations server can be configured in the operations
section of core.yaml:
operations:
  # host and port for the operations server
  listenAddress: 127.0.0.1:9443

  # TLS configuration for the operations endpoint
  tls:
    # TLS enabled
    enabled: true

    # path to PEM encoded server certificate for the operations server
    cert:
      file: tls/server.crt

    # path to PEM encoded server key for the operations server
    key:
      file: tls/server.key

    # most operations service endpoints require client authentication when TLS
    # is enabled. clientAuthRequired requires client certificate authentication
    # at the TLS layer to access all resources.
    clientAuthRequired: false

    # paths to PEM encoded ca certificates to trust for client authentication
    clientRootCAs:
      files: []

The listenAddress key defines the host and port that the operation server
will listen on. If the server should listen on all addresses, the host portion
can be omitted.
The tls section is used to indicate whether or not TLS is enabled for the
operations service, the location of the service’s certificate and private key,
and the locations of certificate authority root certificates that should be
trusted for client authentication. When enabled is true, most of the operations
service endpoints require client authentication, therefore
clientRootCAs.files must be set. When clientAuthRequired is true,
the TLS layer will require clients to provide a certificate for authentication
on every request. See Operations Security section below for more details.

Orderer¶
For each orderer, the operations server can be configured in the Operations
section of orderer.yaml:
Operations:
  # host and port for the operations server
  ListenAddress: 127.0.0.1:8443

  # TLS configuration for the operations endpoint
  TLS:
    # TLS enabled
    Enabled: true

    # PrivateKey: PEM-encoded tls key for the operations endpoint
    PrivateKey: tls/server.key

    # Certificate governs the file location of the server TLS certificate.
    Certificate: tls/server.crt

    # Paths to PEM encoded ca certificates to trust for client authentication
    ClientRootCAs: []

    # Most operations service endpoints require client authentication when TLS
    # is enabled. ClientAuthRequired requires client certificate authentication
    # at the TLS layer to access all resources.
    ClientAuthRequired: false

The ListenAddress key defines the host and port that the operations server
will listen on. If the server should listen on all addresses, the host portion
can be omitted.
The TLS section is used to indicate whether or not TLS is enabled for the
operations service, the location of the service’s certificate and private key,
and the locations of certificate authority root certificates that should be
trusted for client authentication.   When Enabled is true, most of the operations
service endpoints require client authentication, therefore
RootCAs must be set. When ClientAuthRequired is true,
the TLS layer will require clients to provide a certificate for authentication
on every request. See Operations Security section below for more details.

Operations Security¶
As the operations service is focused on operations and intentionally unrelated
to the Fabric network, it does not use the Membership Services Provider for
access control. Instead, the operations service relies entirely on mutual TLS with
client certificate authentication.
When TLS is disabled, authorization is bypassed and any client that can
connect to the operations endpoint will be able to use the API.
When TLS is enabled, a valid client certificate must be provided in order to
access all resources unless explicitly noted otherwise below.
When clientAuthRequired is also enabled, the TLS layer will require
a valid client certificate regardless of the resource being accessed.

Log Level Management¶
The operations service provides a /logspec resource that operators can use to
manage the active logging spec for a peer or orderer. The resource is a
conventional REST resource and supports GET and PUT requests.
When a GET /logspec request is received by the operations service, it will
respond with a JSON payload that contains the current logging specification:
{"spec":"info"}

When a PUT /logspec request is received by the operations service, it will
read the body as a JSON payload. The payload must consist of a single attribute
named spec.
{"spec":"chaincode=debug:info"}

If the spec is activated successfully, the service will respond with a 204 "No Content"
response. If an error occurs, the service will respond with a 400 "Bad Request"
and an error payload:
{"error":"error message"}

Health Checks¶
The operations service provides a /healthz resource that operators can use to
help determine the liveness and health of peers and orderers. The resource is
a conventional REST resource that supports GET requests. The implementation is
intended to be compatible with the liveness probe model used by Kubernetes but
can be used in other contexts.
When a GET /healthz request is received, the operations service will call all
registered health checkers for the process. When all of the health checkers
return successfully, the operations service will respond with a 200 "OK" and a
JSON body:
{
  "status": "OK",
  "time": "2009-11-10T23:00:00Z"
}

If one or more of the health checkers returns an error, the operations service
will respond with a 503 "Service Unavailable" and a JSON body that includes
information about which health checker failed:
{
  "status": "Service Unavailable",
  "time": "2009-11-10T23:00:00Z",
  "failed_checks": [
    {
      "component": "docker",
      "reason": "failed to connect to Docker daemon: invalid endpoint"
    }
  ]
}

In the current version, the only health check that is registered is for Docker.
Future versions will be enhanced to add additional health checks.
When TLS is enabled, a valid client certificate is not required to use this
service unless clientAuthRequired is set to true.

Metrics¶
Some components of the Fabric peer and orderer expose metrics that can help
provide insight into the behavior of the system. Operators and administrators
can use this information to better understand how the system is performing
over time.

Configuring Metrics¶
Fabric provides two ways to expose metrics: a pull model based on Prometheus
and a push model based on StatsD.

Prometheus¶
A typical Prometheus deployment scrapes metrics by requesting them from an HTTP
endpoint exposed by instrumented targets. As Prometheus is responsible for
requesting the metrics, it is considered a pull system.
When configured, a Fabric peer or orderer will present a /metrics resource
on the operations service.

Peer¶
A peer can be configured to expose a /metrics endpoint for Prometheus to
scrape by setting the metrics provider to prometheus in the metrics section
of core.yaml.
metrics:
  provider: prometheus

Orderer¶
An orderer can be configured to expose a /metrics endpoint for Prometheus to
scrape by setting the metrics provider to prometheus in the Metrics
section of orderer.yaml.
Metrics:
  Provider: prometheus

StatsD¶
StatsD is a simple statistics aggregation daemon. Metrics are sent to a
statsd daemon where they are collected, aggregated, and pushed to a backend
for visualization and alerting. As this model requires instrumented processes
to send metrics data to StatsD, this is considered a push system.

Peer¶
A peer can be configured to send metrics to StatsD by setting the metrics
provider to statsd in the metrics section of core.yaml. The statsd
subsection must also be configured with the address of the StatsD daemon, the
network type to use (tcp or udp), and how often to send the metrics. An
optional prefix may be specified to help differentiate the source of the
metrics — for example, differentiating metrics coming from separate peers —
that would be prepended to all generated metrics.
metrics:
  provider: statsd
  statsd:
    network: udp
    address: 127.0.0.1:8125
    writeInterval: 10s
    prefix: peer-0

Orderer¶
An orderer can be configured to send metrics to StatsD by setting the metrics
provider to statsd in the Metrics section of orderer.yaml. The Statsd
subsection must also be configured with the address of the StatsD daemon, the
network type to use (tcp or udp), and how often to send the metrics. An
optional prefix may be specified to help differentiate the source of the
metrics.
Metrics:
    Provider: statsd
    Statsd:
      Network: udp
      Address: 127.0.0.1:8125
      WriteInterval: 30s
      Prefix: org-orderer

For a look at the different metrics that are generated, check out
Metrics Reference.

Metrics Reference¶

Orderer Metrics¶

Prometheus¶
The following orderer metrics are exported for consumption by Prometheus.

Name
Type
Description
Labels

blockcutter_block_fill_duration
histogram
The time from first transaction enqueing to the block
being cut in seconds.
channel

broadcast_enqueue_duration
histogram
The time to enqueue a transaction in seconds.
channel

type

status

broadcast_processed_count
counter
The number of transactions processed.
channel

type

status

broadcast_validate_duration
histogram
The time to validate a transaction in seconds.
channel

type

status

cluster_comm_egress_queue_capacity
gauge
Capacity of the egress queue.
host

msg_type

channel

cluster_comm_egress_queue_length
gauge
Length of the egress queue.
host

msg_type

channel

cluster_comm_egress_queue_workers
gauge
Count of egress queue workers.
channel

cluster_comm_egress_stream_count
gauge
Count of streams to other nodes.
channel

cluster_comm_egress_tls_connection_count
gauge
Count of TLS connections to other nodes.

cluster_comm_ingress_stream_count
gauge
Count of streams from other nodes.

cluster_comm_msg_dropped_count
counter
Count of messages dropped.
host

channel

cluster_comm_msg_send_time
histogram
The time it takes to send a message in seconds.
host

channel

consensus_etcdraft_active_nodes
gauge
Number of active nodes in this channel.
channel

consensus_etcdraft_cluster_size
gauge
Number of nodes in this channel.
channel

consensus_etcdraft_committed_block_number
gauge
The block number of the latest block committed.
channel

consensus_etcdraft_config_proposals_received
counter
The total number of proposals received for config type
transactions.
channel

consensus_etcdraft_data_persist_duration
histogram
The time taken for etcd/raft data to be persisted in
storage (in seconds).
channel

consensus_etcdraft_is_leader
gauge
The leadership status of the current node: 1 if it is the
leader else 0.
channel

consensus_etcdraft_leader_changes
counter
The number of leader changes since process start.
channel

consensus_etcdraft_normal_proposals_received
counter
The total number of proposals received for normal type
transactions.
channel

consensus_etcdraft_proposal_failures
counter
The number of proposal failures.
channel

consensus_etcdraft_snapshot_block_number
gauge
The block number of the latest snapshot.
channel

consensus_kafka_batch_size
gauge
The mean batch size in bytes sent to topics.
topic

consensus_kafka_compression_ratio
gauge
The mean compression ratio (as percentage) for topics.
topic

consensus_kafka_incoming_byte_rate
gauge
Bytes/second read off brokers.
broker_id

consensus_kafka_last_offset_persisted
gauge
The offset specified in the block metadata of the most
recently committed block.
channel

consensus_kafka_outgoing_byte_rate
gauge
Bytes/second written to brokers.
broker_id

consensus_kafka_record_send_rate
gauge
The number of records per second sent to topics.
topic

consensus_kafka_records_per_request
gauge
The mean number of records sent per request to topics.
topic

consensus_kafka_request_latency
gauge
The mean request latency in ms to brokers.
broker_id

consensus_kafka_request_rate
gauge
Requests/second sent to brokers.
broker_id

consensus_kafka_request_size
gauge
The mean request size in bytes to brokers.
broker_id

consensus_kafka_response_rate
gauge
Requests/second sent to brokers.
broker_id

consensus_kafka_response_size
gauge
The mean response size in bytes from brokers.
broker_id

couchdb_processing_time
histogram
Time taken in seconds for the function to complete request
to CouchDB
database

function_name

result

deliver_blocks_sent
counter
The number of blocks sent by the deliver service.
channel

filtered

data_type

deliver_requests_completed
counter
The number of deliver requests that have been completed.
channel

filtered

data_type

success

deliver_requests_received
counter
The number of deliver requests that have been received.
channel

filtered

data_type

deliver_streams_closed
counter
The number of GRPC streams that have been closed for the
deliver service.

deliver_streams_opened
counter
The number of GRPC streams that have been opened for the
deliver service.

fabric_version
gauge
The active version of Fabric.
version

grpc_comm_conn_closed
counter
gRPC connections closed. Open minus closed is the active
number of connections.

grpc_comm_conn_opened
counter
gRPC connections opened. Open minus closed is the active
number of connections.

grpc_server_stream_messages_received
counter
The number of stream messages received.
service

method

grpc_server_stream_messages_sent
counter
The number of stream messages sent.
service

method

grpc_server_stream_request_duration
histogram
The time to complete a stream request.
service

method

code

grpc_server_stream_requests_completed
counter
The number of stream requests completed.
service

method

code

grpc_server_stream_requests_received
counter
The number of stream requests received.
service

method

grpc_server_unary_request_duration
histogram
The time to complete a unary request.
service

method

code

grpc_server_unary_requests_completed
counter
The number of unary requests completed.
service

method

code

grpc_server_unary_requests_received
counter
The number of unary requests received.
service

method

ledger_blockchain_height
gauge
Height of the chain in blocks.
channel

ledger_blockstorage_commit_time
histogram
Time taken in seconds for committing the block to storage.
channel

logging_entries_checked
counter
Number of log entries checked against the active logging
level
level

logging_entries_written
counter
Number of log entries that are written
level

StatsD¶
The following orderer metrics are emitted for consumption by StatsD. The
%{variable_name} nomenclature represents segments that vary based on
context.
For example, %{channel} will be replaced with the name of the channel
associated with the metric.

Bucket
Type
Description

blockcutter.block_fill_duration.%{channel}
histogram
The time from first transaction enqueing to the block
being cut in seconds.

broadcast.enqueue_duration.%{channel}.%{type}.%{status}
histogram
The time to enqueue a transaction in seconds.

broadcast.processed_count.%{channel}.%{type}.%{status}
counter
The number of transactions processed.

broadcast.validate_duration.%{channel}.%{type}.%{status}
histogram
The time to validate a transaction in seconds.

cluster.comm.egress_queue_capacity.%{host}.%{msg_type}.%{channel}
gauge
Capacity of the egress queue.

cluster.comm.egress_queue_length.%{host}.%{msg_type}.%{channel}
gauge
Length of the egress queue.

cluster.comm.egress_queue_workers.%{channel}
gauge
Count of egress queue workers.

cluster.comm.egress_stream_count.%{channel}
gauge
Count of streams to other nodes.

cluster.comm.egress_tls_connection_count
gauge
Count of TLS connections to other nodes.

cluster.comm.ingress_stream_count
gauge
Count of streams from other nodes.

cluster.comm.msg_dropped_count.%{host}.%{channel}
counter
Count of messages dropped.

cluster.comm.msg_send_time.%{host}.%{channel}
histogram
The time it takes to send a message in seconds.

consensus.etcdraft.active_nodes.%{channel}
gauge
Number of active nodes in this channel.

consensus.etcdraft.cluster_size.%{channel}
gauge
Number of nodes in this channel.

consensus.etcdraft.committed_block_number.%{channel}
gauge
The block number of the latest block committed.

consensus.etcdraft.config_proposals_received.%{channel}
counter
The total number of proposals received for config type
transactions.

consensus.etcdraft.data_persist_duration.%{channel}
histogram
The time taken for etcd/raft data to be persisted in
storage (in seconds).

consensus.etcdraft.is_leader.%{channel}
gauge
The leadership status of the current node: 1 if it is the
leader else 0.

consensus.etcdraft.leader_changes.%{channel}
counter
The number of leader changes since process start.

consensus.etcdraft.normal_proposals_received.%{channel}
counter
The total number of proposals received for normal type
transactions.

consensus.etcdraft.proposal_failures.%{channel}
counter
The number of proposal failures.

consensus.etcdraft.snapshot_block_number.%{channel}
gauge
The block number of the latest snapshot.

consensus.kafka.batch_size.%{topic}
gauge
The mean batch size in bytes sent to topics.

consensus.kafka.compression_ratio.%{topic}
gauge
The mean compression ratio (as percentage) for topics.

consensus.kafka.incoming_byte_rate.%{broker_id}
gauge
Bytes/second read off brokers.

consensus.kafka.last_offset_persisted.%{channel}
gauge
The offset specified in the block metadata of the most
recently committed block.

consensus.kafka.outgoing_byte_rate.%{broker_id}
gauge
Bytes/second written to brokers.

consensus.kafka.record_send_rate.%{topic}
gauge
The number of records per second sent to topics.

consensus.kafka.records_per_request.%{topic}
gauge
The mean number of records sent per request to topics.

consensus.kafka.request_latency.%{broker_id}
gauge
The mean request latency in ms to brokers.

consensus.kafka.request_rate.%{broker_id}
gauge
Requests/second sent to brokers.

consensus.kafka.request_size.%{broker_id}
gauge
The mean request size in bytes to brokers.

consensus.kafka.response_rate.%{broker_id}
gauge
Requests/second sent to brokers.

consensus.kafka.response_size.%{broker_id}
gauge
The mean response size in bytes from brokers.

couchdb.processing_time.%{database}.%{function_name}.%{result}
histogram
Time taken in seconds for the function to complete request
to CouchDB

deliver.blocks_sent.%{channel}.%{filtered}.%{data_type}
counter
The number of blocks sent by the deliver service.

deliver.requests_completed.%{channel}.%{filtered}.%{data_type}.%{success}
counter
The number of deliver requests that have been completed.

deliver.requests_received.%{channel}.%{filtered}.%{data_type}
counter
The number of deliver requests that have been received.

deliver.streams_closed
counter
The number of GRPC streams that have been closed for the
deliver service.

deliver.streams_opened
counter
The number of GRPC streams that have been opened for the
deliver service.

fabric_version.%{version}
gauge
The active version of Fabric.

grpc.comm.conn_closed
counter
gRPC connections closed. Open minus closed is the active
number of connections.

grpc.comm.conn_opened
counter
gRPC connections opened. Open minus closed is the active
number of connections.

grpc.server.stream_messages_received.%{service}.%{method}
counter
The number of stream messages received.

grpc.server.stream_messages_sent.%{service}.%{method}
counter
The number of stream messages sent.

grpc.server.stream_request_duration.%{service}.%{method}.%{code}
histogram
The time to complete a stream request.

grpc.server.stream_requests_completed.%{service}.%{method}.%{code}
counter
The number of stream requests completed.

grpc.server.stream_requests_received.%{service}.%{method}
counter
The number of stream requests received.

grpc.server.unary_request_duration.%{service}.%{method}.%{code}
histogram
The time to complete a unary request.

grpc.server.unary_requests_completed.%{service}.%{method}.%{code}
counter
The number of unary requests completed.

grpc.server.unary_requests_received.%{service}.%{method}
counter
The number of unary requests received.

ledger.blockchain_height.%{channel}
gauge
Height of the chain in blocks.

ledger.blockstorage_commit_time.%{channel}
histogram
Time taken in seconds for committing the block to storage.

logging.entries_checked.%{level}
counter
Number of log entries checked against the active logging
level

logging.entries_written.%{level}
counter
Number of log entries that are written

Peer Metrics¶

Prometheus¶
The following peer metrics are exported for consumption by Prometheus.

Name
Type
Description
Labels

chaincode_execute_timeouts
counter
The number of chaincode executions (Init or Invoke) that
have timed out.
chaincode

chaincode_launch_duration
histogram
The time to launch a chaincode.
chaincode

success

chaincode_launch_failures
counter
The number of chaincode launches that have failed.
chaincode

chaincode_launch_timeouts
counter
The number of chaincode launches that have timed out.
chaincode

chaincode_shim_request_duration
histogram
The time to complete chaincode shim requests.
type

channel

chaincode

success

chaincode_shim_requests_completed
counter
The number of chaincode shim requests completed.
type

channel

chaincode

success

chaincode_shim_requests_received
counter
The number of chaincode shim requests received.
type

channel

chaincode

couchdb_processing_time
histogram
Time taken in seconds for the function to complete request
to CouchDB
database

function_name

result

deliver_blocks_sent
counter
The number of blocks sent by the deliver service.
channel

filtered

data_type

deliver_requests_completed
counter
The number of deliver requests that have been completed.
channel

filtered

data_type

success

deliver_requests_received
counter
The number of deliver requests that have been received.
channel

filtered

data_type

deliver_streams_closed
counter
The number of GRPC streams that have been closed for the
deliver service.

deliver_streams_opened
counter
The number of GRPC streams that have been opened for the
deliver service.

dockercontroller_chaincode_container_build_duration
histogram
The time to build a chaincode image in seconds.
chaincode

success

endorser_chaincode_instantiation_failures
counter
The number of chaincode instantiations or upgrade that
have failed.
channel

chaincode

endorser_duplicate_transaction_failures
counter
The number of failed proposals due to duplicate
transaction ID.
channel

chaincode

endorser_endorsement_failures
counter
The number of failed endorsements.
channel

chaincode

chaincodeerror

endorser_proposal_acl_failures
counter
The number of proposals that failed ACL checks.
channel

chaincode

endorser_proposal_duration
histogram
The time to complete a proposal.
channel

chaincode

success

endorser_proposal_simulation_failures
counter
The number of failed proposal simulations
channel

chaincode

endorser_proposal_validation_failures
counter
The number of proposals that have failed initial
validation.

endorser_proposals_received
counter
The number of proposals received.

endorser_successful_proposals
counter
The number of successful proposals.

fabric_version
gauge
The active version of Fabric.
version

gossip_comm_messages_received
counter
Number of messages received

gossip_comm_messages_sent
counter
Number of messages sent

gossip_comm_overflow_count
counter
Number of outgoing queue buffer overflows

gossip_leader_election_leader
gauge
Peer is leader (1) or follower (0)
channel

gossip_membership_total_peers_known
gauge
Total known peers
channel

gossip_payload_buffer_size
gauge
Size of the payload buffer
channel

gossip_privdata_commit_block_duration
histogram
Time it takes to commit private data and the corresponding
block (in seconds)
channel

gossip_privdata_fetch_duration
histogram
Time it takes to fetch missing private data from peers (in
seconds)
channel

gossip_privdata_list_missing_duration
histogram
Time it takes to list the missing private data (in
seconds)
channel

gossip_privdata_pull_duration
histogram
Time it takes to pull a missing private data element (in
seconds)
channel

gossip_privdata_purge_duration
histogram
Time it takes to purge private data (in seconds)
channel

gossip_privdata_reconciliation_duration
histogram
Time it takes for reconciliation to complete (in seconds)
channel

gossip_privdata_retrieve_duration
histogram
Time it takes to retrieve missing private data elements
from the ledger (in seconds)
channel

gossip_privdata_send_duration
histogram
Time it takes to send a missing private data element (in
seconds)
channel

gossip_privdata_validation_duration
histogram
Time it takes to validate a block (in seconds)
channel

gossip_state_commit_duration
histogram
Time it takes to commit a block in seconds
channel

gossip_state_height
gauge
Current ledger height
channel

grpc_comm_conn_closed
counter
gRPC connections closed. Open minus closed is the active
number of connections.

grpc_comm_conn_opened
counter
gRPC connections opened. Open minus closed is the active
number of connections.

grpc_server_stream_messages_received
counter
The number of stream messages received.
service

method

grpc_server_stream_messages_sent
counter
The number of stream messages sent.
service

method

grpc_server_stream_request_duration
histogram
The time to complete a stream request.
service

method

code

grpc_server_stream_requests_completed
counter
The number of stream requests completed.
service

method

code

grpc_server_stream_requests_received
counter
The number of stream requests received.
service

method

grpc_server_unary_request_duration
histogram
The time to complete a unary request.
service

method

code

grpc_server_unary_requests_completed
counter
The number of unary requests completed.
service

method

code

grpc_server_unary_requests_received
counter
The number of unary requests received.
service

method

ledger_block_processing_time
histogram
Time taken in seconds for ledger block processing.
channel

ledger_blockchain_height
gauge
Height of the chain in blocks.
channel

ledger_blockstorage_and_pvtdata_commit_time
histogram
Time taken in seconds for committing the block and private
data to storage.
channel

ledger_blockstorage_commit_time
histogram
Time taken in seconds for committing the block to storage.
channel

ledger_statedb_commit_time
histogram
Time taken in seconds for committing block changes to
state db.
channel

ledger_transaction_count
counter
Number of transactions processed.
channel

transaction_type

chaincode

validation_code

logging_entries_checked
counter
Number of log entries checked against the active logging
level
level

logging_entries_written
counter
Number of log entries that are written
level

StatsD¶
The following peer metrics are emitted for consumption by StatsD. The
%{variable_name} nomenclature represents segments that vary based on
context.
For example, %{channel} will be replaced with the name of the channel
associated with the metric.

Bucket
Type
Description

chaincode.execute_timeouts.%{chaincode}
counter
The number of chaincode executions (Init or Invoke) that
have timed out.

chaincode.launch_duration.%{chaincode}.%{success}
histogram
The time to launch a chaincode.

chaincode.launch_failures.%{chaincode}
counter
The number of chaincode launches that have failed.

chaincode.launch_timeouts.%{chaincode}
counter
The number of chaincode launches that have timed out.

chaincode.shim_request_duration.%{type}.%{channel}.%{chaincode}.%{success}
histogram
The time to complete chaincode shim requests.

chaincode.shim_requests_completed.%{type}.%{channel}.%{chaincode}.%{success}
counter
The number of chaincode shim requests completed.

chaincode.shim_requests_received.%{type}.%{channel}.%{chaincode}
counter
The number of chaincode shim requests received.

couchdb.processing_time.%{database}.%{function_name}.%{result}
histogram
Time taken in seconds for the function to complete request
to CouchDB

deliver.blocks_sent.%{channel}.%{filtered}.%{data_type}
counter
The number of blocks sent by the deliver service.

deliver.requests_completed.%{channel}.%{filtered}.%{data_type}.%{success}
counter
The number of deliver requests that have been completed.

deliver.requests_received.%{channel}.%{filtered}.%{data_type}
counter
The number of deliver requests that have been received.

deliver.streams_closed
counter
The number of GRPC streams that have been closed for the
deliver service.

deliver.streams_opened
counter
The number of GRPC streams that have been opened for the
deliver service.

dockercontroller.chaincode_container_build_duration.%{chaincode}.%{success}
histogram
The time to build a chaincode image in seconds.

endorser.chaincode_instantiation_failures.%{channel}.%{chaincode}
counter
The number of chaincode instantiations or upgrade that
have failed.

endorser.duplicate_transaction_failures.%{channel}.%{chaincode}
counter
The number of failed proposals due to duplicate
transaction ID.

endorser.endorsement_failures.%{channel}.%{chaincode}.%{chaincodeerror}
counter
The number of failed endorsements.

endorser.proposal_acl_failures.%{channel}.%{chaincode}
counter
The number of proposals that failed ACL checks.

endorser.proposal_duration.%{channel}.%{chaincode}.%{success}
histogram
The time to complete a proposal.

endorser.proposal_simulation_failures.%{channel}.%{chaincode}
counter
The number of failed proposal simulations

endorser.proposal_validation_failures
counter
The number of proposals that have failed initial
validation.

endorser.proposals_received
counter
The number of proposals received.

endorser.successful_proposals
counter
The number of successful proposals.

fabric_version.%{version}
gauge
The active version of Fabric.

gossip.comm.messages_received
counter
Number of messages received

gossip.comm.messages_sent
counter
Number of messages sent

gossip.comm.overflow_count
counter
Number of outgoing queue buffer overflows

gossip.leader_election.leader.%{channel}
gauge
Peer is leader (1) or follower (0)

gossip.membership.total_peers_known.%{channel}
gauge
Total known peers

gossip.payload_buffer.size.%{channel}
gauge
Size of the payload buffer

gossip.privdata.commit_block_duration.%{channel}
histogram
Time it takes to commit private data and the corresponding
block (in seconds)

gossip.privdata.fetch_duration.%{channel}
histogram
Time it takes to fetch missing private data from peers (in
seconds)

gossip.privdata.list_missing_duration.%{channel}
histogram
Time it takes to list the missing private data (in
seconds)

gossip.privdata.pull_duration.%{channel}
histogram
Time it takes to pull a missing private data element (in
seconds)

gossip.privdata.purge_duration.%{channel}
histogram
Time it takes to purge private data (in seconds)

gossip.privdata.reconciliation_duration.%{channel}
histogram
Time it takes for reconciliation to complete (in seconds)

gossip.privdata.retrieve_duration.%{channel}
histogram
Time it takes to retrieve missing private data elements
from the ledger (in seconds)

gossip.privdata.send_duration.%{channel}
histogram
Time it takes to send a missing private data element (in
seconds)

gossip.privdata.validation_duration.%{channel}
histogram
Time it takes to validate a block (in seconds)

gossip.state.commit_duration.%{channel}
histogram
Time it takes to commit a block in seconds

gossip.state.height.%{channel}
gauge
Current ledger height