Code generation
Contents
Code generation#
Code generation inputs (*.zap
files)#
Matter code relies on code generation for cluster-specific data types and callbacks. Generally this is split into:
Data serialization for structures/lists/commands. This applies to both client-side and server-side structures and objects
Callback setup using the Ember-based framework. This generally applies to server-side processing and the code generation defines what processing needs to be done when a specific command is received or an attribute is read and what memory should be allocated for storing cluster attributes
Code generation depends on the clusters that are needed by an application. Every
application configures the specific set of endpoints and clusters it needs based
on the device type it supports. The selection of the supported clusters and
attributes (as optional attributes may be omitted to save memory) is generally
stored in *.zap
files.
The selection of enabled clusters and files is done using
ZAP. You can download a recent release of
zap from its releases page. It
is recommended to download a release that is in sync with the currently in use
version by the SDK (see integrations/docker/images/chip-build/Dockerfile
and
check the ZAP_VERSION
setting).
Beyond basic zap file selection, there are also .json
zap settings that define
additional cluster info: source XML files, sdk-access methods and data types.
There are only two such files currently in use:
src/app/zap-templates/zcl/zcl.json
is the default onesrc/app/zap-templates/zcl/zcl-with-test-extensions.json
is used byall-clusters-app
to show how a cluster extension may be configured with minimal changes fromzcl.json
(but it is different)
Installing zap and environment variables#
Matter scripts may need to invoke zap-cli
(for code generation) or zap
(to
start the UI tool). For this, scrips need to know where to find the commands. In
the following order, the scripts process these environment variables:
if
$ZAP_DEVELOPMENT_PATH
is set, code assumes you are running zap from source. Use this if you develop zap. Zap has to be bootstrapped (generallynpm ci
but check zap documentation for this. Some scripts have a--run-bootstrap
command line argument to do this for you)if
$ZAP_INSTALL_PATH
is set, code assumes thatzap
orzap-cli
is available in the given path. This is generally an unpacked release.otherwise, scripts will assume
zap
/zap-cli
is in$PATH
Using a UI to edit .zap
files#
Generally you need to invoke zap with appropriate zcl and generate arguments.
Most of code generation is app specific, so you generally want something of the
form
--gen src/app/zap-templates/app-templates.json --zcl $ZCL_JSON_FILE $ZAP_FILE_TO_EDIT
Since this is tedious to type, the SDK provides a
scripts/tools/zap/run_zaptool.sh
script to automate this:
# Ensure zap is in $PATH or set $ZAP_INSTALL_PATH or $ZAP_DEVELOPMENT_PATH
./scripts/tools/zap/run_zaptool.sh examples/lighting-app/lighting-common/lighting-app.zap
Human-readable code generation inputs (*.matter
)#
.zap
files are large json files that are generally not human readable. As a
result, the Matter SDK also keeps an equivalent *.matter
file along side
.zap
files that contain the same data as .zap
files, targeted specifically
for matter:
They are designed to be human readable, looking like a IDL (think protobuf or android
aidl
, thrift idl etc.)We strive to make them contain only Matter-specific data (
.zap
files contain more generic data and is designed to be ZigBee backwards compatible)
Currently .matter
files are generated from .zap
files during the application
specific codegen.
*.matter
parsing and codegen#
*.matter
files are both human and machine readable. Code that can process
these files is available at scripts/py_matter_idl
and scripts/codegen.py
.
You can read the
scripts/py_matter_idl/matter_idl/README.md
for details of how things work.
scripts/codegen.py
can generate various outputs based on an input *.matter
file.
The split between .zap
and .matter
currently exists as an experiment of code
generation technologies. Currently .matter
-based Python code generation:
has fewer third party dependencies than
zap
, which installs a significant number ofnpm
packages.runs significantly faster than zap
offers more flexible code generation (can generate multiple files per cluster for example, without which some compiles would run out of RAM on large compilations)
has a more flexible templating language
has human readable (and potentially editable) input
is more easily provable deterministic (
zap
uses an underlying sqlite database and some legacy assumptions from zigbee have historically caused non-determinism)uses a synchronous processing model which is potentially easier to develop for
has lower complexity, is unit tested and uses typing extensively
Ideally, the project would be to have a single code generation method in the long term that has all the benefits and none of the drawbacks. We are not there yet, however we likely want:
Flexible codegen (we will need to split output by clusters or other rules)
Human-readable inputs that enable code reviews and audits
Rules that a script can validate based on CSA data model (ensure mandatory attribute settings are followed, ensure proper device type adherence, ensure correct cluster and data type definitions)
Easy to maintain and develop for chosen languages/templates/codegen in general
Code generation outputs and templates#
Code that is generated:
Application-specific:
ZAP generation is based on
.zap
files inexamples/
and generates server-side processing data: what cluster callbacks to set up, what RAM to reserve for attribute storage etc.Codegen.py
will also generate a subset of application-specific files
Automated tests: embedded client-side tools (
chip-tool
anddarwin-framework-tool
) generate test-definition data. Each use their ownexamples/${TOOL}/templates/tests/templates.json
to drive what gets generated.Controller clusters target: the file
src/controller/data_model/controller-clusters.zap
contains a set of cluster selections to which all applications would potentially have access. These are generally used asall clusters selection
and the intent is to allow any application to access any cluster as aclient side
.Client/controllers will codegen based on this, like tools, tests, java, python etc.
Running codegen#
ZAP file generation#
Generating all possible code (all categories above) using zap tool can be done via:
./scripts/tools/zap_regen_all.py
This can be slow (several minutes). The regen tool allows selection of only tests so that yaml test development goes faster.
./scripts/tools/zap_regen_all.py --type tests
./scripts/tools/zap_regen_all.py --type tests --tests chip-tool
Additionally, individual code regeneration can be done using
./scripts/tools/zap/generate.py
:
/scripts/tools/zap/generate.py \
examples/bridge-app/bridge-common/bridge-app.zap \
-o zzz_generated/bridge-app/zap-generated
*.matter
code generation#
*.matter
code generation can be done either at compile time or it can use
pre-generated output.
Rules for how codegen.py
is invoked and how includes/sources are set are
defined at:
src/app/chip_data_model.cmake
src/app/chip_data_model.gni
Additionally, build/chip/esp32/esp32_codegen.cmake
adds processing support for
the 2-pass cmake builds used by the Espressif idf.py
build system.
Pre-generation#
Code pre-generation can be used:
when compile-time code generation is not desirable. This may be for importing into build systems that do not have the pre-requisites to run code generation at build time or to save the code generation time at the expense of running code generation for every possible zap/generation type
To check changes in generated code across versions, beyond the comparisons of golden image tests in
scripts/py_matter_idl/matter_idl/tests
The script to trigger code pre-generation is scripts/code_pregenerate.py
and
requires the pre-generation output directory as an argument
scripts/code_pregenerate.py ${OUTPUT_DIRECTORY:-./zzz_pregenerated/}