Running External Chaincode Builders

Fabric v2.4.1 external chaincode builders provide a practical approach to running smart contracts by enabling the peer to run external (to itself) commands to manage chaincode. By comparison, the earlier deploying a smart contract to a channel method required the peer to orchestrate the complete lifecycle of the chaincode. This required the peer to have access to the Docker Daemon to create images and to start containers. Java, Node.js and Go chaincode frameworks were explicitly known to the peer, including how they should be built and started.

As a result, the traditional chaincode deployment method made it challenging to deploy chaincode into Kubernetes (K8s), or other environments where access to the Docker Daemon is restricted, and to run chaincode in any form of debug mode. Additionally, the code was usually rebuilt by the peer, requiring an external internet connection and introducing some uncertainty about which dependencies had been installed.

The chaincode as a service method does require an administrator to orchestrate the chaincode build and deployment phase. Although this creates an additional step, it provides administrators with control over the process. The peer still requires a ‘chaincode package’ to be installed, but with no code - only information about where the chaincode is hosted is installed (such as hostname, port, and TLS configuration).

Fabric v2.4.1 Improvements

The test network uses the latest Fabric release (v2.4.1), which facilitates using chaincode as a service:

  • The Docker image for the peer contains a preconfigured builder for chaincode-as-a-service, named ‘ccaasbuilder’. This removes the prior requirement to build your own external builder and repackage and configure the peer.

  • The ccaasbuilder applications are included in the binary tgz archive download for use in other circumstances. The sampleconfig/core.yaml is updated to refer to ‘ccaasbuilder’.

  • The Fabric v2.4.1 Java chaincode removes the requirement to write a custom bootstrap main class (as implemented in the Node.js chaincode and planned for the go chaincode).

NOTE: This core functionality is also available in earlier releases, but with the requirements of writing the external chaincode code builder binaries and configuring the core.yaml correctly.

End-to-end with the test-network

The test-network and some of the chaincodes have been updated to support running chaincode-as-a-service. The commands below require the latest fabric-samples, along with the latest Fabric Docker images.

Begin by opening two terminal windows, one for starting the Fabric test-network, and another for monitoring the Docker containers. In the ‘monitoring’ window, run the following bash scripts to watch activity from the Docker containers on the fabric_test network; this will monitor all Docker containers that are added to the fabric-test network.

The test-network is typically created by running the ./network.sh up command, so delay running the bash scripts until the network is created. (Note the network can be created in advance using docker network create fabric-test.)

  1. # from the fabric-samples repo
  2. ./test-network/monitordocker.sh

In the ‘Fabric Network’ window, start the test network:

  1. cd test-network
  2. ./network.sh up createChannel

Variants of the next command, such as to use CouchDB or CAs, can be used without affecting the chaincode-as-a-service feature. The three keys steps are as follows, in no required order:

  1. Build a Docker image of the chaincode package, which contains information for determining where the chaincode containers (hosting one or more contracts) are running. Both /asset-transfer-basic/chaincode-typescript and /asset-transfer-basic/chaincode-java have been updated with Docker files.

  2. Install, approve, and commit a chaincode definition; these commands are run regardless of whether external chaincode builders are used. The chaincode package contains connection information (hostname, port, TLS certificates) only, with no code.

  3. Start the Docker container(s) containing the contract.

The containers must be running before the first transaction is committed by the peer. This could be on the commit if the initRequired flag is set.

This sequence can be run as follows:

  1. ./network.sh deployCCAAS -ccn basicts -ccp ../asset-transfer-basic/chaincode-typescript

This is similar to the deployCC command in that it specifies the name and path. Because each container is on the fabric-test network, changing the port can avoid collisions with other chaincode containers. If you run multiple services, the ports will need to change.

If successful to this point, the smart contract (chaincode) should be starting in the monitoring window. There should be two containers running, one for org1 and one for org2. The container names contain the organization, peer, and chaincode name.

As a test, run the ‘Contract Metadata’ function as shown below. (For details on testing as different organizations, see Interacting with the network.

  1. # Environment variables for Org1
  2. export CORE_PEER_TLS_ENABLED=true
  3. export CORE_PEER_LOCALMSPID="Org1MSP"
  4. export CORE_PEER_TLS_ROOTCERT_FILE=${PWD}/organizations/peerOrganizations/org1.example.com/tlsca/tlsca.org1.example.com-cert.pem
  5. export CORE_PEER_MSPCONFIGPATH=${PWD}/organizations/peerOrganizations/org1.example.com/users/Admin@org1.example.com/msp
  6. export CORE_PEER_ADDRESS=localhost:7051
  7. export PATH=${PWD}/../bin:$PATH
  8. export FABRIC_CFG_PATH=${PWD}/../config
  9. # invoke the function
  10. peer chaincode query -C mychannel -n basicts -c '{"Args":["org.hyperledger.fabric:GetMetadata"]}' | jq

Note that | jq can be omitted if jq is not installed. However, the metadata shows details of the deployed contract in JSON, so jq provides legibility. To confirm that the smart contract is working, repeat the prior commands for org2.

To run the Java example, change the deployCCAAS command as follows, which will create two new containers:

  1. ./network.sh deployCCAAS -ccn basicj -ccp ../asset-transfer-basic/chaincode-java

Troubleshooting

If a passed JSON structure is not well-formatted, the peer log will include the following error:

  1. ::Error: Failed to unmarshal json: cannot unmarshal string into Go value of type map[string]interface {} command=build

How to configure each language

Each language can function in the ‘-as-a-service’ mode. The following approaches are based on the latest libraries at the time of publication. When starting the image, any TLS options or additional logging options for the respective chaincode libraries can be specified.

Java

With the Fabric v2.4.1 Java chaincode libraries, there are no code changes or build changes to implement. The ‘-as-a-service’ mode will be used if the environment variable CHAINCODE_SERVER_ADDRESS is set.

The following sample Docker run command shows the two required variables, CHAINCODE_SERVER_ADDRESS and CORE_CHAICODE_ID_NAME:

  1. docker run --rm -d --name peer0org1_assettx_ccaas \
  2. --network fabric_test \
  3. -e CHAINCODE_SERVER_ADDRESS=0.0.0.0:9999 \
  4. -e CORE_CHAINCODE_ID_NAME=<use package id here> \
  5. assettx_ccaas_image:latest

Node.js

For Node.js (JavaScript or TypeScript) chaincode, package.json typically has fabric-chaincode-node start as the main start command. To run in the ‘-as-a-service’ mode change this start command to fabric-chaincode-node server --chaincode-address=$CHAINCODE_SERVER_ADDRESS --chaincode-id=$CHAINCODE_ID.

Debugging the Chaincode

Running in ‘-as-a-service’ mode provides options, similar to Fabric ‘dev’ mode for debugging code. The restrictions of ‘dev’ mode do not apply to ‘-as-a-service’.

The -ccaasdocker false option can be provided with the deployCCAAS command to not build the Docker image or start a Docker container. The option outputs the commands that would have run.

Command output is similar to the following example:

  1. ./network.sh deployCCAAS -ccn basicj -ccp ../asset-transfer-basic/chaincode-java -ccaasdocker false
  2. #....
  3. Not building docker image; this the command we would have run
  4. docker build -f ../asset-transfer-basic/chaincode-java/Dockerfile -t basicj_ccaas_image:latest --build-arg CC_SERVER_PORT=9999 ../asset-transfer-basic/chaincode-java
  5. #....
  6. Not starting docker containers; these are the commands we would have run
  7. docker run --rm -d --name peer0org1_basicj_ccaas --network fabric_test -e CHAINCODE_SERVER_ADDRESS=0.0.0.0:9999 -e CHAINCODE_ID=basicj_1.0:59dcd73a14e2db8eab7f7683343ce27ac242b93b4e8075605a460d63a0438405 -e CORE_CHAINCODE_ID_NAME=basicj_1.0:59dcd73a14e2db8eab7f7683343ce27ac242b93b4e8075605a460d63a0438405 basicj_ccaas_image:latest

Note: The previous commands may require adjustments depending on the directory location or debugging requirements.

Building the Docker image

The first requirement for debugging chaincode is building the Docker image. As long as the peer can connect to the hostname:port specified in connection.json the actual packaging of the chaincode is not important to the peer. The Docker files specified below can be relocated.

Manually build the Docker image for asset-transfer-basic/chaincode-java:

  1. docker build -f ../asset-transfer-basic/chaincode-java/Dockerfile -t basicj_ccaas_image:latest --build-arg CC_SERVER_PORT=9999 ../asset-transfer-basic/chaincode-java

Starting the Docker container

Next, the Docker container must be started. In Node.js, for example, the container could be started as follows:

  1. docker run --rm -it -p 9229:9229 --name peer0org2_basic_ccaas --network fabric_test -e DEBUG=true -e CHAINCODE_SERVER_ADDRESS=0.0.0.0:9999 -e CHAINCODE_ID=basic_1.0:7c7dff5cdc43c77ccea028c422b3348c3c1fb5a26ace0077cf3cc627bd355ef0 -e CORE_CHAINCODE_ID_NAME=basic_1.0:7c7dff5cdc43c77ccea028c422b3348c3c1fb5a26ace0077cf3cc627bd355ef0 basic_ccaas_image:latest

In Java, for example, the Docker container could be started as follows:

  1. docker run --rm -it --name peer0org1_basicj_ccaas -p 8000:8000 --network fabric_test -e DEBUG=true -e CHAINCODE_SERVER_ADDRESS=0.0.0.0:9999 -e CHAINCODE_ID=basicj_1.0:b014a03d8eb1898535e25b4dfeeb3f8244c9f07d91a06aec03e2d19174c45e4f -e CORE_CHAINCODE_ID_NAME=basicj_1.0:b014a03d8e
  2. b1898535e25b4dfeeb3f8244c9f07d91a06aec03e2d19174c45e4f basicj_ccaas_image:latest

Debugging Prerequisites

The following prerequisites apply to debugging all languages:

  • The container name must match the name in the peer’s connection.json.

  • The peer is connecting to the chaincode container via the Docker network. Therefore, port 9999 does not need to be forwarded to the host.

  • Single stepping in a debugger is likely to trigger the default Fabric transaction timeout value of 30 seconds. Increase the time that the chaincode has to complete transactions, to 300 seconds, by adding CORE_CHAINCODE_EXECUTETIMEOUT=300s to the environment options for each peer in the test-network/docker/docker-composer-test-net.yml file.

  • In the docker run command in the previous section, the test-network -d default option has been replaced with -it. This change runs the Docker container in the foreground and not in detached mode.

The following prerequisites apply to debugging Node.js:

  • Port 9229 is forwarded. However, this is the debug port used by Node.js.

  • -e DEBUG=true will trigger the node runtime to be started in debug mode. This is encoded in the docker/docker-entrypoint.sh script, which for security purposes, should be considered for removal from production images.

  • If you are using TypeScript, ensure that the TypeScript has been compiled with sourcemaps; otherwise, a debugger will have difficulty matching up the source code.

The following prerequisites apply to debugging Java:

  • Port 8000 is forwarded, which is the debug port for the JVM.

  • -e DEBUG=true will trigger the node runtime to be started in debug mode. This is an example encoded in the docker/docker-entrypoint.sh script, which for security purposes, should be considered for removal from production images.

  • The java command option to start the debugger is java -agentlib:jdwp=transport=dt_socket,server=y,suspend=n,address=0.0.0.0:8000 -jar /chaincode.jar. Note 0.0.0.0, as the debug port, must be bound to all network adapters so the debugger can be attached from outside the container.

Running with multiple peers

In the earlier method, each peer that the chaincode is approved on will have a container running the chaincode. The ‘-as-a-service’ approach requires achieving the same architecture.

The connection.json contains the address of the running chaincode container, so it can be updated to ensure that each peer connects to a different container. However, as with the connection.json in the chaincode package, Fabric mandates that the package ID be consistent across all peers in an organization. To achieve this, the external builder supports a template capability. The context from this template is taken from the environment variable CHAINCODE_AS_A_SERVICE_BUILDER_CONFIG set on each peer.

Define the address to be a template in connection.json as follows:

  1. {
  2. "address": "{{.peername}}_assettransfer_ccaas:9999",
  3. "dial_timeout": "10s",
  4. "tls_required": false
  5. }

In the peer’s environment configuration, set the following variable for org1’s peer1:

  1. CHAINCODE_AS_A_SERVICE_BUILDER_CONFIG="{\"peername\":\"org1peer1\"}"

The external builder will then resolve this address to be org1peer1_assettransfer_ccaas:9999 for the peer to use.

Each peer can have its own separate configuration, and therefore a unique address. The JSON string that is set can have any structure, as long as the templates (in golang template syntax) match.

Any value in connection.json can be templated, but only the values and not the keys.