External Builders and Launchers

Prior to Hyperledger Fabric 2.0, the process used to build and launch chaincode was part of the peer implementation and could not be easily customized. All chaincode installed on the peer would be “built” using language specific logic hard coded in the peer. This build process would generate a Docker container image that would be launched to execute chaincode that connected as a client to the peer.

This approach limited chaincode implementations to a handful of languages, required Docker to be part of the deployment environment, and prevented running chaincode as a long running server process.

Starting with Fabric 2.0, External Builders and Launchers address these limitations by enabling operators to extend the peer with programs that can build, launch, and discover chaincode. To leverage this capability you will need to create your own buildpack and then modify the peer core.yaml to include a new externalBuilder configuration element which lets the peer know an external builder is available. The following sections describe the details of this process.

Note that if no configured external builder claims a chaincode package, the peer will attempt to process the package as if it were created with the standard Fabric packaging tools such as the peer CLI or node SDK.

Note: This is an advanced feature which will likely require custom packaging of the peer image with everything your builders and launchers depend on unless your builders and launchers are simple enough, such as those used in the basic asset transfer external chaincode Fabric sample. For example, the following samples use go and bash, which are not included in the current official fabric-peer image.

External builder model

Hyperledger Fabric External Builders and Launchers are loosely based on Heroku Buildpacks. A buildpack implementation is simply a collection of programs or scripts that transform application artifacts into something that can run. The buildpack model has been adapted for chaincode packages and extended to support chaincode execution and discovery.

External builder and launcher API

An external builder and launcher consists of four programs or scripts:

  • bin/detect: Determine whether or not this buildpack should be used to build the chaincode package and launch it.

  • bin/build: Transform the chaincode package into executable chaincode.

  • bin/release (optional): Provide metadata to the peer about the chaincode.

  • bin/run (optional): Run the chaincode.

bin/detect

The bin/detect script is responsible for determining whether or not a buildpack should be used to build a chaincode package and launch it. The peer invokes detect with two arguments:

  1. bin/detect CHAINCODE_SOURCE_DIR CHAINCODE_METADATA_DIR

When detect is invoked, CHAINCODE_SOURCE_DIR contains the chaincode source and CHAINCODE_METADATA_DIR contains the metadata.json file from the chaincode package installed to the peer. The CHAINCODE_SOURCE_DIR and CHAINCODE_METADATA_DIR should be treated as read only inputs. If the buildpack should be applied to the chaincode source package, detect must return an exit code of 0; any other exit code will indicate that the buildpack should not be applied.

The following is an example of a simple detect script for go chaincode:

  1. #!/bin/bash
  2. CHAINCODE_METADATA_DIR="$2"
  3. # use jq to extract the chaincode type from metadata.json and exit with
  4. # success if the chaincode type is golang
  5. if [ "$(jq -r .type "$CHAINCODE_METADATA_DIR/metadata.json" | tr '[:upper:]' '[:lower:]')" = "golang" ]; then
  6. exit 0
  7. fi
  8. exit 1

bin/build

The bin/build script is responsible for building, compiling, or transforming the contents of a chaincode package into artifacts that can be used by release and run. The peer invokes build with three arguments:

  1. bin/build CHAINCODE_SOURCE_DIR CHAINCODE_METADATA_DIR BUILD_OUTPUT_DIR

When build is invoked, CHAINCODE_SOURCE_DIR contains the chaincode source and CHAINCODE_METADATA_DIR contains the metadata.json file from the chaincode package installed to the peer. BUILD_OUTPUT_DIR is the directory where build must place artifacts needed by release and run. The build script should treat the input directories CHAINCODE_SOURCE_DIR and CHAINCODE_METADATA_DIR as read only, but the BUILD_OUTPUT_DIR is writeable.

When build completes with an exit code of 0, the contents of BUILD_OUTPUT_DIR will be copied to the persistent storage maintained by the peer; any other exit code will be considered a failure.

The following is an example of a simple build script for go chaincode:

  1. #!/bin/bash
  2. CHAINCODE_SOURCE_DIR="$1"
  3. CHAINCODE_METADATA_DIR="$2"
  4. BUILD_OUTPUT_DIR="$3"
  5. # extract package path from metadata.json
  6. GO_PACKAGE_PATH="$(jq -r .path "$CHAINCODE_METADATA_DIR/metadata.json")"
  7. if [ -f "$CHAINCODE_SOURCE_DIR/src/go.mod" ]; then
  8. cd "$CHAINCODE_SOURCE_DIR/src"
  9. go build -v -mod=readonly -o "$BUILD_OUTPUT_DIR/chaincode" "$GO_PACKAGE_PATH"
  10. else
  11. GO111MODULE=off go build -v -o "$BUILD_OUTPUT_DIR/chaincode" "$GO_PACKAGE_PATH"
  12. fi
  13. # save statedb index metadata to provide at release
  14. if [ -d "$CHAINCODE_SOURCE_DIR/META-INF" ]; then
  15. cp -a "$CHAINCODE_SOURCE_DIR/META-INF" "$BUILD_OUTPUT_DIR/"
  16. fi

bin/release

The bin/release script is responsible for providing chaincode metadata to the peer. bin/release is optional. If it is not provided, this step is skipped. The peer invokes release with two arguments:

  1. bin/release BUILD_OUTPUT_DIR RELEASE_OUTPUT_DIR

When release is invoked, BUILD_OUTPUT_DIR contains the artifacts populated by the build program and should be treated as read only input. RELEASE_OUTPUT_DIR is the directory where release must place artifacts to be consumed by the peer.

When release completes, the peer will consume two types of metadata from RELEASE_OUTPUT_DIR:

  • state database index definitions for CouchDB

  • external chaincode server connection information (chaincode/server/connection.json)

If CouchDB index definitions are required for the chaincode, release is responsible for placing the indexes into the statedb/couchdb/indexes directory under RELEASE_OUTPUT_DIR. The indexes must have a .json extension. See the CouchDB indexes documentation for details.

In cases where a chaincode server implementation is used, release is responsible for populating chaincode/server/connection.json with the address of the chaincode server and any TLS assets required to communicate with the chaincode. When server connection information is provided to the peer, run will not be called.

The following is an example of a simple release script for go chaincode:

  1. #!/bin/bash
  2. BUILD_OUTPUT_DIR="$1"
  3. RELEASE_OUTPUT_DIR="$2"
  4. # copy indexes from META-INF/* to the output directory
  5. if [ -d "$BUILD_OUTPUT_DIR/META-INF" ] ; then
  6. cp -a "$BUILD_OUTPUT_DIR/META-INF/"* "$RELEASE_OUTPUT_DIR/"
  7. fi

bin/run

The bin/run script is responsible for running chaincode. The peer invokes run with two arguments:

  1. bin/run BUILD_OUTPUT_DIR RUN_METADATA_DIR

When run is called, BUILD_OUTPUT_DIR contains the artifacts populated by the build program and RUN_METADATA_DIR is populated with a file called chaincode.json that contains the information necessary for chaincode to connect and register with the peer. Note that the bin/run script should treat these BUILD_OUTPUT_DIR and RUN_METADATA_DIR directories as read only input. The keys included in chaincode.json are:

  • chaincode_id: The unique ID associated with the chaincode package.

  • peer_address: The address in host:port format of the ChaincodeSupport gRPC server endpoint hosted by the peer.

  • client_cert: The PEM encoded TLS client certificate generated by the peer that must be used when the chaincode establishes its connection to the peer.

  • client_key: The PEM encoded client key generated by the peer that must be used when the chaincode establishes its connection to the peer.

  • root_cert: The PEM encoded TLS root certificate for the ChaincodeSupport gRPC server endpoint hosted by the peer.

  • mspid: The local mspid of the peer.

When run terminates, the peer considers the chaincode terminated. If another request arrives for the chaincode, the peer will attempt to start another instance of the chaincode by invoking run again. The contents of chaincode.json must not be cached across invocations.

The following is an example of a simple run script for go chaincode:

  1. #!/bin/bash
  2. BUILD_OUTPUT_DIR="$1"
  3. RUN_METADATA_DIR="$2"
  4. # setup the environment expected by the go chaincode shim
  5. export CORE_CHAINCODE_ID_NAME="$(jq -r .chaincode_id "$RUN_METADATA_DIR/chaincode.json")"
  6. export CORE_PEER_TLS_ENABLED="true"
  7. export CORE_TLS_CLIENT_CERT_FILE="$RUN_METADATA_DIR/client.crt"
  8. export CORE_TLS_CLIENT_KEY_FILE="$RUN_METADATA_DIR/client.key"
  9. export CORE_PEER_TLS_ROOTCERT_FILE="$RUN_METADATA_DIR/root.crt"
  10. export CORE_PEER_LOCALMSPID="$(jq -r .mspid "$RUN_METADATA_DIR/chaincode.json")"
  11. # populate the key and certificate material used by the go chaincode shim
  12. jq -r .client_cert "$RUN_METADATA_DIR/chaincode.json" > "$CORE_TLS_CLIENT_CERT_FILE"
  13. jq -r .client_key "$RUN_METADATA_DIR/chaincode.json" > "$CORE_TLS_CLIENT_KEY_FILE"
  14. jq -r .root_cert "$RUN_METADATA_DIR/chaincode.json" > "$CORE_PEER_TLS_ROOTCERT_FILE"
  15. if [ -z "$(jq -r .client_cert "$RUN_METADATA_DIR/chaincode.json")" ]; then
  16. export CORE_PEER_TLS_ENABLED="false"
  17. fi
  18. # exec the chaincode to replace the script with the chaincode process
  19. exec "$BUILD_OUTPUT_DIR/chaincode" -peer.address="$(jq -r .peer_address "$ARTIFACTS/chaincode.json")"

Configuring external builders and launchers

Configuring the peer to use external builders involves adding an externalBuilder element under the chaincode configuration block in the core.yaml that defines external builders. Each external builder definition must include a name (used for logging) and the path to parent of the bin directory containing the builder scripts.

An optional list of environment variable names to propagate from the peer when invoking the external builder scripts can also be provided.

The following example defines two external builders:

  1. chaincode:
  2. externalBuilders:
  3. - name: my-golang-builder
  4. path: /builders/golang
  5. propagateEnvironment:
  6. - GOPROXY
  7. - GONOPROXY
  8. - GOSUMDB
  9. - GONOSUMDB
  10. - name: noop-builder
  11. path: /builders/binary

In this example, the implementation of “my-golang-builder” is contained within the /builders/golang directory and its build scripts are located in /builders/golang/bin. When the peer invokes any of the build scripts associated with “my-golang-builder”, it will propagate only the values of the environment variables in the propagateEnvironment.

Note: The following environment variables are always propagated to external builders:

  • LD_LIBRARY_PATH

  • LIBPATH

  • PATH

  • TMPDIR

When an externalBuilder configuration is present, the peer will iterate over the list of builders in the order provided, invoking bin/detect until one completes successfully. If no builder completes detect successfully, the peer will fallback to using the legacy Docker build process implemented within the peer. This means that external builders are completely optional.

In the example above, the peer will attempt to use “my-golang-builder”, followed by “noop-builder”, and finally the peer internal build process.

If you do not need to fallback to the legacy Docker build process for your chaincodes, you can remove the Docker endpoint from the peer core.yaml vm.endpoint configuration. This will also remove the Docker daemon health check.

Chaincode packages

As part of the new lifecycle introduced with Fabric 2.0, the chaincode package format changed from serialized protocol buffer messages to a gzip compressed POSIX tape archive. Chaincode packages created with peer lifecycle chaincode package use this new format.

Lifecycle chaincode package contents

A lifecycle chaincode package contains two files. The first file, code.tar.gz is a gzip compressed POSIX tape archive. This file includes the source artifacts for the chaincode. Packages created by the peer CLI will place the chaincode implementation source under the src directory and chaincode metadata (like CouchDB indexes) under the META-INF directory.

The second file, metadata.json is a JSON document with three keys:

  • type: the chaincode type (e.g. GOLANG, JAVA, NODE)

  • path: for go chaincode, the GOPATH or GOMOD relative path to the main chaincode package; undefined for other types

  • label: the chaincode label that is used to generate the package-id by which the package is identified within the new chaincode lifecycle process.

Note that the type and path fields are only utilized by docker platform builds.

Chaincode packages and external builders

When a chaincode package is installed to a peer, the contents of code.tar.gz and metadata.json are not processed prior to calling external builders, except for the label field that is used by the new lifecycle process to compute the package id. This affords users a great deal of flexibility in how they package source and metadata that will be processed by external builders and launchers.

For example, a custom chaincode package could be constructed that contains a pre-compiled, implementation of chaincode in code.tar.gz with a metadata.json that allows a binary buildpack to detect the custom package, validate the hash of the binary, and run the program as chaincode.

Another example would be a chaincode package that only contains state database index definitions and the data necessary for an external launcher to connect to a running chaincode server. In this case, the build process would simply extract the metadata from the process and release would present it to the peer.

The only requirements are that code.tar.gz can only contain regular file and directory entries, and that the entries cannot contain paths that would result in files being written outside of the logical root of the chaincode package.