Writing, Building, and Running Chaincode in a Development Environment

Chaincode developers need a way to test and debug their chaincode without having to set up a complete peer network. By default, when you want to interact with chaincode, you need to first Deploy it using the CLI, REST API, gRPC API, or SDK. Upon receiving this request, the peer node would typically spin up a Docker container with the relevant chaincode. This can make things rather complicated for debugging chaincode under development, because of the turnaround time with the launch chaincode - debug docker container - fix problem - launch chaincode - lather - rinse - repeat cycle. As such, the fabric peer has a --peer-chaincodedev flag that can be passed on start-up to instruct the peer node not to deploy the chaincode as a Docker container.

The following instructions apply to developing chaincode in Go or Java. They do not apply to running in a production environment. However, if developing chaincode in Java, please see the Java chaincode setup instructions first, to be sure your environment is properly configured.

Note: We have added support for System chaincode

Choices

Once again, you have the choice of using one of the following approaches:

  • Option 1 using Docker for Mac or Windows
  • Option 2 using Docker toolbox
  • Option 3 using the Vagrant development environment that is used for developing the fabric itself
A Docker approach provides several advantages, highlighted through its simplicity.
By using options 1 or 2, from above, you avoid having to build everything from scratch, and there’s no need to keep a synchronized clone of the Hyperledger fabric codebase. Instead, you can simply pull and run the fabric-peer and fabric-membersrvc images directly from DockerHub. There is no need to manually start the peer and member service nodes, rather a single docker-compose up command will spin up a live network on your machine. Additionally, you are able to operate from a single terminal, and you avoid the extra layer of abstraction and virtualization which arises when using the Vagrant environment.

For more information on using Docker Compose, and customizing your Docker environment, see the Docker Setup Guide If you are not familiar with Docker and/or chaincode development, it’s recommended to go through this section first.

Option 1 Docker for Mac or Windows

The Docker images for fabric-peer and fabric-membersrvc are continuously built and tested through the Hyperledger fabric CI (continuous integration). To run these fabric components on your Mac or Windows laptop/server using the Docker for Mac or Windows platform, follow these steps. If using Docker Toolbox, please skip to Option 2, below.

Pull images from DockerHub

You DO NOT need to manually pull the fabric-peer, fabric-membersrvc or fabric-baseimage images published by the Hyperledger Fabric project from DockerHub. These images are specified in the docker-compose.yaml and will be automatically downloaded and extracted when you run docker-compose up. However, you do need to ensure that the image tags correspond correctly to your platform.

Identify your platform and check the image tags. Use the Tags tab in the hyperledger/fabric-baseimage repository on DockerHub to browse the available images. For example, if you are running Docker natively on Linux or OSX then you will want:

hyperledger/fabric-baseimage:x86_64-0.2.0

Retrieve the docker-compose file

Now you need to retrieve a Docker Compose file to spin up your network. There are two standard Docker Compose files available. One is for a single node + CA network, and the second is for a four node + CA network. Identify or create a working directory where you want the Docker Compose file(s) to reside; this can be anywhere on your machine (the below directory is simply an example). Then execute a cURL to retrieve the .yaml file. For example, to retrieve the .yaml file for a single node + CA network:

mkdir -p $HOME/hyperledger/docker-compose
cd $HOME/hyperledger/docker-compose
curl https://raw.githubusercontent.com/hyperledger/fabric/v0.6/examples/docker-compose/single-peer-ca.yaml -o single-peer-ca.yaml 2>/dev/null

OR to retrieve the .yaml file for a four node + CA network:

mkdir -p $HOME/hyperledger/docker-compose
cd $HOME/hyperledger/docker-compose
curl https://raw.githubusercontent.com/hyperledger/fabric/v0.6/examples/docker-compose/four-peer-ca.yaml -o four-peer-ca.yaml 2>/dev/null

If you want to configure your network to use specific fabric-peer or fabric-membersrvc images from Hyperledger Docker Hub, use the Tags tab in the corresponding image repository to browse the available versions. Then add the tag in your Docker Compose .yaml file. For example, in the single-peer-ca.yaml you might alter the hyperledger/fabric-peer image from:

vp0:
    image: hyperledger/fabric-peer
    volumes:
      - /var/run/docker.sock:/var/run/docker.sock

to

vp0:
    image: hyperledger/fabric-peer:x86_64-0.6.1-preview
    volumes:
      - /var/run/docker.sock:/var/run/docker.sock

Running the Peer and CA

To run the fabric-peerand fabric-membersrvc images, you will use Docker Compose against one of your .yaml files. You specify the file after the -f argument on the command line. Therefore, to spin up the single node + CA network you first navigate to the working directory where your compose file(s) reside, and then execute docker-compose up from the command line:

cd $HOME/hyperledger/docker-compose
docker-compose -f single-peer-ca.yaml up

OR for a four node + CA network:

cd $HOME/hyperledger/docker-compose
docker-compose -f four-node-ca.yaml up

Now, you are ready to start running the chaincode.

Option 2 Docker Toolbox

If you are using Docker Toolbox, please follow these instructions.

Note: Docker will not run natively on older versions of macOS or any Windows versions prior to Windows 10. If either scenario describes your OS, you must use Docker Toolbox.

Docker Toolbox bundles Docker Engine, Docker Machine and Docker Compose, and by means of a VirtualBox, provides you with an environment to run Docker processes. You initialize the Docker host simply by launching the Docker Quick Start Terminal. Once the host is initialized, you can run all of the Docker commands and Docker Compose commands from the toolbox as if you were running them on the command line. Once you are in the toolbox, it is the same experience as if you were running on a Linux machine with Docker & Docker Compose installed.

Start up the default Docker host by clicking on the Docker Quick Start Terminal. It will open a new terminal window and initialize the Docker host. Once the startup process is complete, you will see the Docker whale together with the IP address of the Docker host, as shown below. In this example the IP address of the Docker host is 192.168.99.100. Take note of this IP address as you will need it later to connect to your Docker containers.

If you need to retrieve an IP address for one of your peers, use the docker inspect command. For more information on useful Docker commands, refer to the Docker documentation.

                        ##         .
                  ## ## ##        ==
               ## ## ## ## ##    ===
        /"""""""""""""""""\___/ ===
   ~~~ {~~ ~~~~ ~~~ ~~~~ ~~~ ~ /  ===- ~~~
        \______ o           __/
         \    \         __/
          \____\_______/

docker is configured to use the default machine with IP 192.168.99.100
For help getting started, check out the docs at https://docs.docker.com

Pull images from DockerHub

You DO NOT need to manually pull the fabric-peer, fabric-membersrvc or fabric-baseimage images published by the Hyperledger Fabric project from DockerHub.
These images are specified in the docker-compose.yaml and will be automatically downloaded and extracted when you run docker-compose up. However, you do need to ensure that the image tags correspond correctly to your platform.

Identify your platform and check the image tags. Use the Tags tab in the hyperledger/fabric-baseimage repository on DockerHub to browse the available images. If you are using Docker toolbox, then you will want:

hyperledger/fabric-baseimage:x86_64-0.2.0

Retrieve the docker-compose file

Now you need to retrieve a Docker Compose file to spin up your network. There are two standard Docker Compose files available. One is for a single node + CA network, and the second is for a four node + CA network. Identify or create a working directory where you want the Docker Compose file(s) to reside. Then execute a cURL to retrieve the .yaml file. For example, to retrieve the .yaml file for a single node + CA network:

mkdir -p $HOME/hyperledger/docker-compose
cd $HOME/hyperledger/docker-compose
curl https://raw.githubusercontent.com/hyperledger/fabric/master/examples/docker-compose/single-peer-ca.yaml -o single-peer-ca.yaml 2>/dev/null

OR to retrieve the .yaml file for a four node + CA network:

mkdir -p $HOME/hyperledger/docker-compose
cd $HOME/hyperledger/docker-compose
curl https://raw.githubusercontent.com/hyperledger/fabric/master/examples/docker-compose/four-peer-ca.yaml
-o four-peer-ca.yaml 2>dev/null

If you want to configure your network to use specific fabric-peer or fabric-membersrvc images from Hyperledger Docker Hub, use the Tags tab in the corresponding image repository to browse the available versions. Then add the tag in your Docker Compose .yaml file. For example, in the single-peer-ca.yaml you might alter the hyperledger/fabric-peer image from:

vp0:
    image: hyperledger/fabric-peer
    volumes:
      - /var/run/docker.sock:/var/run/docker.sock

to

vp0:
    image: hyperledger/fabric-peer:x86_64-0.6.1-preview
    volumes:
      - /var/run/docker.sock:/var/run/docker.sock

Running the Peer and CA

To run the fabric-peerand fabric-membersrvc images, you will use Docker Compose against one of your .yaml files. You specify the file through the -f argument on the command line. Therefore, to spin up the single node + CA network you first navigate to the working directory where your compose file(s) reside, and then execute docker-compose up from the command line:

cd $HOME/hyperledger/docker-compose
docker-compose -f single-peer-ca.yaml up

OR for a four node + CA network:

cd $HOME/hyperledger/docker-compose
docker-compose -f four-node-ca.yaml up

Now, you are ready to start running the chaincode.

Option 3 Vagrant development environment

You will need multiple terminal windows - essentially one for each component. One runs the validating peer; another runs the chaincode; the third runs the CLI or REST API commands to execute transactions. Finally, when running with security enabled, an additional fourth window is required to run the Certificate Authority (CA) server. Detailed instructions are provided in the sections below.

Note: Using the Vagrant environment results in a more complicated scenario due to an extra layer of virtualization and the need for multiple terminals.
Running Docker natively or using Docker Toolbox are the recommended approaches.

Security Setup (optional)

From the devenv subdirectory of your fabric workspace environment, ssh into Vagrant:

cd $GOPATH/src/github.com/hyperledger/fabric/devenv
vagrant ssh

To set up the local development environment with security enabled, you must first build and run the Certificate Authority (CA) server:

cd $GOPATH/src/github.com/hyperledger/fabric
make membersrvc && membersrvc

Running the above commands builds and runs the CA server with the default setup, which is defined in the membersrvc.yaml configuration file. The default configuration includes multiple users who are already registered with the CA; these users are listed in the eca.users section of the configuration file. To register additional users with the CA for testing, modify the eca.users section of the membersrvc.yaml file to include additional enrollmentID and enrollmentPW pairs. Note the integer that precedes the enrollmentPW. That integer indicates the role of the user, where 1 = client, 2 = non-validating peer, 4 = validating peer, and 8 = auditor.

Running the validating peer

Note: To run with security enabled, first modify the core.yaml configuration file to set the security.enabled value to true before building the peer executable. Alternatively, you can enable security by running the peer with the following environment variable: CORE_SECURITY_ENABLED=true. To enable privacy and confidentiality of transactions (which requires security to also be enabled), modify the core.yaml configuration file to set the security.privacy value to true as well. Alternatively, you can enable privacy by running the peer with the following environment variable: CORE_SECURITY_PRIVACY=true. If you are enabling security and privacy on the peer process with environment variables, it is important to include these environment variables in the command when executing all subsequent peer operations (e.g. deploy, invoke, or query).

In a new terminal window, from the devenv subdirectory of your fabric workspace environment, ssh into Vagrant:

cd $GOPATH/src/github.com/hyperledger/fabric/devenv
vagrant ssh

Build and run the peer process to enable security and privacy after setting security.enabled and security.privacy settings to true.

cd $GOPATH/src/github.com/hyperledger/fabric
make peer
peer node start --peer-chaincodedev

Alternatively, rather than tweaking the core.yaml and rebuilding, you can enable security and privacy on the peer with environment variables:

CORE_SECURITY_ENABLED=true CORE_SECURITY_PRIVACY=true peer node start --peer-chaincodedev

Now, you are ready to start running the chaincode.

Running the chaincode

Docker or Docker Toolbox

Start a new terminal window. If you ran spun up your Docker containers in detached mode - docker-compose up -d - you can remain in the same terminal.

If you are using either Option 1 or Option 2, you’ll need to download the sample chaincode. The chaincode project must be placed somewhere under the src directory in your local $GOPATH as shown below.

mkdir -p $GOPATH/src/github.com/chaincode_example02/
cd $GOPATH/src/github.com/chaincode_example02
curl GET https://raw.githubusercontent.com/hyperledger/fabric/master/examples/chaincode/go/chaincode_example02/chaincode_example02.go > chaincode_example02.go

Next, you’ll need to clone the Hyperledger fabric to your local $GOPATH, so that you can build your chaincode. Note: this is a temporary stop-gap until we can provide an independent package for the chaincode shim.

mkdir -p $GOPATH/src/github.com/hyperledger
cd $GOPATH/src/github.com/hyperledger
git clone http://gerrit.hyperledger.org/r/fabric

Now, you should be able to build your chaincode.

cd $GOPATH/src/github.com/chaincode_example02
go build

When you are ready to start creating your own Go chaincode, create a new subdirectory under $GOPATH/src. You can copy the chaincode_example02 file to the new directory and modify it.

Vagrant

Start a new terminal window.

If you are using Option 3, you’ll need to ssh to Vagrant.

cd $GOPATH/src/github.com/hyperledger/fabric/devenv
vagrant ssh

Next, we’ll build the chaincode_example02 code, which is provided in the Hyperledger fabric source code repository. If you are using Option 3, then you can do this from your clone of the fabric repository.

cd $GOPATH/src/github.com/hyperledger/fabric/examples/chaincode/go/chaincode_example02
go build

Starting and registering the chaincode

Run the following chaincode command to start and register the chaincode with the validating peer:

CORE_CHAINCODE_ID_NAME=mycc CORE_PEER_ADDRESS=0.0.0.0:7051 ./chaincode_example02

The chaincode console will display the message “Received REGISTERED, ready for invocations”, which indicates that the chaincode is ready to receive requests. Follow the steps below to send a chaincode deploy, invoke or query transaction. If the “Received REGISTERED” message is not displayed, then an error has occurred during the deployment; revisit the previous steps to resolve the issue.

Note: These instructions relate to writing, building, and running chaincode in “development” mode. This means that if you are using Docker, you will not see additional Docker containers after you have deployed your chaincode. Rather, the chaincode is directly registered with the peer as outlined in the above command.
See the Docker Setup Guide

Running the CLI or REST API

If you were running with security enabled, see Removing temporary files when security is enabled to learn how to clean up the temporary files.

See the logging control reference for information on controllinglogging output from the peer and chaincodes.

Terminal 3 (CLI or REST API)

Note on REST API port

The default REST interface port is 7050. It can be configured in core.yaml using the rest.address property. If using Vagrant, the REST port mapping is defined in Vagrantfile.

Note on security functionality

Current security implementation assumes that end user authentication takes place at the application layer and is not handled by the fabric. Authentication may be performed through any means considered appropriate for the target application. Upon successful user authentication, the application will perform user registration with the CA exactly once. If registration is attempted a second time for the same user, an error will result. During registration, the application sends a request to the certificate authority to verify the user registration and if successful, the CA responds with the user certificates and keys. The enrollment and transaction certificates received from the CA will be stored locally inside /var/hyperledger/production/crypto/client/ directory. This directory resides on a specific peer node which allows the user to transact only through this specific peer while using the stored crypto material. If the end user needs to perform transactions through more then one peer node, the application is responsible for replicating the crypto material to other peer nodes. This is necessary as registering a given user with the CA a second time will fail.

With security enabled, the CLI commands and REST payloads must be modified to include the enrollmentID of a registered user who is logged in; otherwise an error will result. A registered user can be logged in through the CLI or the REST API by following the instructions below. To log in through the CLI, issue the following commands, where username is one of the enrollmentID values listed in the eca.users section of the membersrvc.yaml file.

From your command line terminal, move to the devenv subdirectory of your workspace environment. Log into a Vagrant terminal by executing the following command:

vagrant ssh

Register the user though the CLI, substituting for <username> appropriately:

cd $GOPATH/src/github.com/hyperledger/fabric/peer
peer network login <username>

The command will prompt for a password, which must match the enrollmentPW listed for the target user in the eca.users section of the membersrvc.yaml file. If the password entered does not match the enrollmentPW, an error will result.

To log in through the REST API, send a POST request to the /registrar endpoint, containing the enrollmentID and enrollmentPW listed in the eca.users section of the membersrvc.yaml file.

REST Request:

POST localhost:7050/registrar

{
  "enrollId": "jim",
  "enrollSecret": "6avZQLwcUe9b"
}

REST Response:

200 OK
{
    "OK": "Login successful for user 'jim'."
}

chaincode deploy via CLI and REST

First, send a chaincode deploy transaction, only once, to the validating peer. The CLI connects to the validating peer using the properties defined in the core.yaml file. Note: The deploy transaction typically requires a path parameter to locate, build, and deploy the chaincode. However, because these instructions are specific to local development mode and the chaincode is deployed manually, the name parameter is used instead.

peer chaincode deploy -n mycc -c '{Args": ["init", "a","100", "b", "200"]}'

Alternatively, you can run the chaincode deploy transaction through the REST API.

REST Request:

POST <host:port>/chaincode

{
  "jsonrpc": "2.0",
  "method": "deploy",
  "params": {
    "type": 1,
    "chaincodeID":{
        "name": "mycc"
    },
    "ctorMsg": {
        "args":["init", "a", "100", "b", "200"]
    }
  },
  "id": 1
}

REST Response:

{
    "jsonrpc": "2.0",
    "result": {
        "status": "OK",
        "message": "mycc"
    },
    "id": 1
}

Note: When security is enabled, modify the CLI command and the REST API payload to pass the enrollmentID of a logged in user. To log in a registered user through the CLI or the REST API, follow the instructions in the note on security functionality. On the CLI, the enrollmentID is passed with the -u parameter; in the REST API, the enrollmentID is passed with the secureContext element. If you are enabling security and privacy on the peer process with environment variables, it is important to include these environment variables in the command when executing all subsequent peer operations (e.g. deploy, invoke, or query).

CORE_SECURITY_ENABLED=true CORE_SECURITY_PRIVACY=true peer chaincode deploy -u
jim -n mycc -c '{"Args": ["init", "a","100", "b", "200"]}'

REST Request:

POST <host:port>/chaincode

{
  "jsonrpc": "2.0",
  "method": "deploy",
  "params": {
    "type": 1,
    "chaincodeID":{
        "name": "mycc"
    },
    "ctorMsg": {
        "args":["init", "a", "100", "b", "200"]
    },
    "secureContext": "jim"
  },
  "id": 1
}

The deploy transaction initializes the chaincode by executing a target initializing function. Though the example shows “init”, the name could be arbitrarily chosen by the chaincode developer. You should see the following output in the chaincode window:

  <TIMESTAMP_SIGNATURE> Received INIT(uuid:005dea42-d57f-4983-803e-3232e551bf61),
initializing chaincode Aval = 100, Bval = 200

Chaincode invoke via CLI and REST

Run the chaincode invoking transaction on the CLI as many times as desired. The -n argument should match the value provided in the chaincode window (started in Vagrant terminal 2):

peer chaincode invoke -l golang -n mycc -c '{Args": ["invoke", "a", "b", "10"]}'

Alternatively, run the chaincode invoking transaction through the REST API.

REST Request:

POST <host:port>/chaincode

{
  "jsonrpc": "2.0",
  "method": "invoke",
  "params": {
      "type": 1,
      "chaincodeID":{
          "name":"mycc"
      },
      "ctorMsg": {
         "args":["invoke", "a", "b", "10"]
      }
  },
  "id": 3
}

REST Response:

{
    "jsonrpc": "2.0",
    "result": {
        "status": "OK",
        "message": "5a4540e5-902b-422d-a6ab-e70ab36a2e6d"
    },
    "id": 3
}

Note: When security is enabled, modify the CLI command and REST API payload to pass the enrollmentID of a logged in user. To log in a registered user through the CLI or the REST API, follow the instructions in the note on security functionality. On the CLI, the enrollmentID is passed with the -u parameter; in the REST API, the enrollmentID is passed with the secureContext element. If you are enabling security and privacy on the peer process with environment variables, it is important to include these environment variables in the command when executing all subsequent peer operations (e.g. deploy, invoke, or query).

  CORE_SECURITY_ENABLED=true CORE_SECURITY_PRIVACY=true peer chaincode invoke
-u jim -l golang -n mycc -c '{"Function": "invoke", "Args": ["a", "b", "10"]}'

REST Request:

POST <host:port>/chaincode

{
  "jsonrpc": "2.0",
  "method": "invoke",
  "params": {
      "type": 1,
      "chaincodeID":{
          "name":"mycc"
      },
      "ctorMsg": {
         "args":["invoke", "a", "b", "10"]
      },
      "secureContext": "jim"
  },
  "id": 3
}

The invoking transaction runs the specified chaincode function name “invoke” with the arguments. This transaction transfers 10 units from A to B. You should see the following output in the chaincode window:

  <TIMESTAMP_SIGNATURE> Received RESPONSE. Payload 200,
Uuid 075d72a4-4d1f-4a1d-a735-4f6f60d597a9 Aval = 90, Bval = 210

Chaincode query via CLI and REST

Run a query on the chaincode to retrieve the desired values. The -n argument should match the value provided in the chaincode window (started in Vagrant terminal 2):

peer chaincode query -l golang -n mycc -c '{"Args": ["query", "b"]}'

The response should be similar to the following:

{"Name":"b","Amount":"210"}

If a name other than “a” or “b” is provided in a query sent to chaincode_example02, you should see an error response similar to the following:

{"Error":"Nil amount for c"}

Alternatively, run the chaincode query transaction through the REST API.

REST Request:

POST <host:port>/chaincode

{
  "jsonrpc": "2.0",
  "method": "query",
  "params": {
      "type": 1,
      "chaincodeID":{
          "name":"mycc"
      },
      "ctorMsg": {
         "args":["query", "a"]
      }
  },
  "id": 5
}

REST Response:

{
    "jsonrpc": "2.0",
    "result": {
        "status": "OK",
        "message": "90"
    },
    "id": 5
}

Note: When security is enabled, modify the CLI command and REST API payload to pass the enrollmentID of a logged in user. To log in a registered user through the CLI or the REST API, follow the instructions in the note on security functionality. On the CLI, the enrollmentID is passed with the -u parameter; in the REST API, the enrollmentID is passed with the secureContext element. If you are enabling security and privacy on the peer process with environment variables, it is important to include these environment variables in the command when executing all subsequent peer operations (e.g. deploy, invoke, or query).

  CORE_SECURITY_ENABLED=true CORE_SECURITY_PRIVACY=true peer chaincode query
-u jim -l golang -n mycc -c '{Args": ["query", "b"]}'

REST Request:

POST <host:port>/chaincode

{
  "jsonrpc": "2.0",
  "method": "query",
  "params": {
      "type": 1,
      "chaincodeID":{
          "name":"mycc"
      },
      "ctorMsg": {
         "args":["query", "a"]
      },
      "secureContext": "jim"
  },
  "id": 5
}

Removing temporary files when security is enabled

Note: this step applies ONLY if you were using Option 1 above. For Option 2 or 3, the cleanup is handled by Docker.

After the completion of a chaincode test with security enabled, remove the temporary files that were created by the CA server process. To remove the client enrollment certificate, enrollment key, transaction certificate chain, etc., run the following commands. Note, that you must run these commands if you want to register a user who has already been registered previously.

From your command line terminal, ssh into Vagrant:

cd $GOPATH/src/github.com/hyperledger/fabric/devenv
vagrant ssh

And then run:

rm -rf /var/hyperledger/production