.. _module-pw_build: -------- pw_build -------- Pigweed's modules aim to be easily integratable into both new and existing embedded projects. To that goal, the ``pw_build`` module provides support for multiple build systems. Our personal favorite is `GN`_/`Ninja`_, which is used by upstream developers for its speed and flexibility. `CMake`_ and `Bazel`_ build files are also provided by all modules, allowing Pigweed to be added to a project with minimal effort. .. _GN: https://gn.googlesource.com/gn/ .. _Ninja: https://ninja-build.org/ .. _CMake: https://cmake.org/ .. _Bazel: https://bazel.build/ Beyond just compiling code, Pigweed’s GN build system can also: * Generate HTML documentation, via our Sphinx integration (with ``pw_docgen``) * Display memory usage report cards (with ``pw_bloat``) * Incrementally run unit tests after code changes (with ``pw_target_runner``) * And more! These are only supported in the GN build, so we recommend using it if possible. GN / Ninja ========== The GN / Ninja build system is the primary build system used for upstream Pigweed development, and is the most tested and feature-rich build system Pigweed offers. This module's ``build.gn`` file contains a number of C/C++ ``config`` declarations that are used by upstream Pigweed to set some architecture-agnostic compiler defaults. (See Pigweed's ``//BUILDCONFIG.gn``) ``pw_build`` also provides several useful GN templates that are used throughout Pigweed. Build system philosophies ------------------------- While Pigweed's GN build is not hermetic, it strives to adhere to principles of `hermeticity `_. Some guidelines to move towards the ideal of hermeticity include: * Only rely on pre-compiled tools provided by CIPD (or some other versioned, pre-compiled binary distribution mechanism). This eliminates build artifact differences caused by different tool versions or variations (e.g. same tool version built with slightly different compilation flags). * Do not use absolute paths in Ninja commands. Typically, these appear when using ``rebase_path("//path/to/my_script.py")``. Most of the time, Ninja steps should be passed paths rebased relative to the build directory (i.e. ``rebase_path("//path/to/my_script.py", root_build_dir)``). This ensures build commands are the same across different machines. * Prevent produced artifacts from relying on or referencing system state. This includes time stamps, writing absolute paths to generated artifacts, or producing artifacts that reference system state in a way that prevents them from working the same way on a different machine. * Isolate build actions to the build directory. In general, the build system should not add or modify files outside of the build directory. This can cause confusion to users, and makes the concept of a clean build more ambiguous. Target types ------------ .. code-block:: import("$dir_pw_build/target_types.gni") pw_source_set("my_library") { sources = [ "lib.cc" ] } Pigweed defines wrappers around the four basic GN binary types ``source_set``, ``executable``, ``static_library``, and ``shared_library``. These templates do several things: #. **Add default configs/deps** Rather than binding the majority of compiler flags related to C++ standard, cross-compilation, warning/error policy, etc. directly to toolchain invocations, these flags are applied as configs to all ``pw_*`` C/C++ target types. The primary motivations for this are to allow some targets to modify the default set of flags when needed by specifying ``remove_configs``, and to reduce the complexity of building novel toolchains. Pigweed's global default configs are set in ``pw_build/default.gni``, and individual platform-specific toolchains extend the list by appending to the ``default_configs`` build argument. Default deps were added to support polyfill, which has since been deprecated. Default dependency functionality continues to exist for backwards compatibility. #. **Optionally add link-time binding** Some libraries like pw_assert and pw_log are borderline impossible to implement well without introducing circular dependencies. One solution for addressing this is to break apart the libraries into an interface with minimal dependencies, and an implementation with the bulk of the dependencies that would typically create dependency cycles. In order for the implementation to be linked in, it must be added to the dependency tree of linked artifacts (e.g. ``pw_executable``, ``pw_static_library``). Since there's no way for the libraries themselves to just happily pull in the implementation if someone depends on the interface, the implementation is instead late-bound by adding it as a direct dependency of the final linked artifact. This is all managed through ``pw_build_LINK_DEPS``, which is global for each toolchain and applied to every ``pw_executable``, ``pw_static_library``, and ``pw_shared_library``. #. **Apply a default visibility policy** Projects can globally control the default visibility of pw_* target types by specifying ``pw_build_DEFAULT_VISIBILITY``. This template applies that as the default visibility for any pw_* targets that do not explicitly specify a visibility. #. **Add source file names as metadata** All source file names are collected as `GN metadata `_. This list can be writen to a file at build time using ``generated_file``. The primary use case for this is to generate a token database containing all the source files. This allows PW_ASSERT to emit filename tokens even though it can't add them to the elf file because of the reasons described at :ref:`module-pw_assert-assert-api`. .. note:: ``pw_source_files``, if not rebased will default to outputing module relative paths from a ``generated_file`` target. This is likely not useful. Adding a ``rebase`` argument to ``generated_file`` such as ``rebase = root_build_dir`` will result in usable paths. For an example, see ``//pw_tokenizer/database.gni``'s ``pw_tokenizer_filename_database`` template. The ``pw_executable`` template provides additional functionality around building complete binaries. As Pigweed is a collection of libraries, it does not know how its final targets are built. ``pw_executable`` solves this by letting each user of Pigweed specify a global executable template for their target, and have Pigweed build against it. This is controlled by the build variable ``pw_executable_config.target_type``, specifying the name of the executable template for a project. In some uncommon cases, a project's ``pw_executable`` template definition may need to stamp out some ``pw_source_set``\s. Since a pw_executable template can't import ``$dir_pw_build/target_types.gni`` due to circular imports, it should import ``$dir_pw_build/cc_library.gni`` instead. .. tip:: Prefer to use ``pw_executable`` over plain ``executable`` targets to allow cleanly building the same code for multiple target configs. **Arguments** All of the ``pw_*`` target type overrides accept any arguments supported by the underlying native types, as they simply forward them through to the underlying target. Additionally, the following arguments are also supported: * **remove_configs**: (optional) A list of configs / config patterns to remove from the set of default configs specified by the current toolchain configuration. * **remove_public_deps**: (optional) A list of targets to remove from the set of default public_deps specified by the current toolchain configuration. .. _module-pw_build-link-deps: Link-only deps -------------- It may be necessary to specify additional link-time dependencies that may not be explicitly depended on elsewhere in the build. One example of this is a ``pw_assert`` backend, which may need to leave out dependencies to avoid circular dependencies. Its dependencies need to be linked for executables and libraries, even if they aren't pulled in elsewhere. The ``pw_build_LINK_DEPS`` build arg is a list of dependencies to add to all ``pw_executable``, ``pw_static_library``, and ``pw_shared_library`` targets. This should only be used as a last resort when dependencies cannot be properly expressed in the build. Python packages --------------- GN templates for :ref:`Python build automation ` are described in :ref:`module-pw_build-python`. .. toctree:: :hidden: python .. _module-pw_build-cc_blob_library: pw_cc_blob_library ------------------ The ``pw_cc_blob_library`` template is useful for embedding binary data into a program. The template takes in a mapping of symbol names to file paths, and generates a set of C++ source and header files that embed the contents of the passed-in files as arrays of ``std::byte``. The blob byte arrays are constant initialized and are safe to access at any time, including before ``main()``. ``pw_cc_blob_library`` is also available in the CMake build. It is provided by ``pw_build/cc_blob_library.cmake``. **Arguments** * ``blobs``: A list of GN scopes, where each scope corresponds to a binary blob to be transformed from file to byte array. This is a required field. Blob fields include: * ``symbol_name``: The C++ symbol for the byte array. * ``file_path``: The file path for the binary blob. * ``linker_section``: If present, places the byte array in the specified linker section. * ``alignas``: If present, uses the specified string or integer verbatim in the ``alignas()`` specifier for the byte array. * ``out_header``: The header file to generate. Users will include this file exactly as it is written here to reference the byte arrays. * ``namespace``: An optional (but highly recommended!) C++ namespace to place the generated blobs within. Example ^^^^^^^ **BUILD.gn** .. code-block:: pw_cc_blob_library("foo_bar_blobs") { blobs: [ { symbol_name: "kFooBlob" file_path: "${target_out_dir}/stuff/bin/foo.bin" }, { symbol_name: "kBarBlob" file_path: "//stuff/bin/bar.bin" linker_section: ".bar_section" }, ] out_header: "my/stuff/foo_bar_blobs.h" namespace: "my::stuff" deps = [ ":generate_foo_bin" ] } .. note:: If the binary blobs are generated as part of the build, be sure to list them as deps to the pw_cc_blob_library target. **Generated Header** .. code-block:: #pragma once #include #include namespace my::stuff { extern const std::array kFooBlob; extern const std::array kBarBlob; } // namespace my::stuff **Generated Source** .. code-block:: #include "my/stuff/foo_bar_blobs.h" #include #include #include "pw_preprocessor/compiler.h" namespace my::stuff { const std::array kFooBlob = { ... }; PW_PLACE_IN_SECTION(".bar_section") const std::array kBarBlob = { ... }; } // namespace my::stuff .. _module-pw_build-facade: pw_facade --------- In their simplest form, a :ref:`facade` is a GN build arg used to change a dependency at compile time. Pigweed targets configure these facades as needed. The ``pw_facade`` template bundles a ``pw_source_set`` with a facade build arg. This allows the facade to provide header files, compilation options or anything else a GN ``source_set`` provides. The ``pw_facade`` template declares two targets: * ``$target_name``: the public-facing ``pw_source_set``, with a ``public_dep`` on the backend * ``$target_name.facade``: target used by the backend to avoid circular dependencies .. code-block:: # Declares ":foo" and ":foo.facade" GN targets pw_facade("foo") { backend = pw_log_BACKEND public_configs = [ ":public_include_path" ] public = [ "public/pw_foo/foo.h" ] } Low-level facades like ``pw_assert`` cannot express all of their dependencies due to the potential for dependency cycles. Facades with this issue may require backends to place their implementations in a separate build target to be listed in ``pw_build_LINK_DEPS`` (see :ref:`module-pw_build-link-deps`). The ``require_link_deps`` variable in ``pw_facade`` asserts that all specified build targets are present in ``pw_build_LINK_DEPS`` if the facade's backend variable is set. .. _module-pw_build-python-action: pw_python_action ---------------- The ``pw_python_action`` template is a convenience wrapper around GN's `action function `_ for running Python scripts. The main benefit it provides is resolution of GN target labels to compiled binary files. This allows Python scripts to be written independently of GN, taking only filesystem paths as arguments. Another convenience provided by the template is to allow running scripts without any outputs. Sometimes scripts run in a build do not directly produce output files, but GN requires that all actions have an output. ``pw_python_action`` solves this by accepting a boolean ``stamp`` argument which tells it to create a placeholder output file for the action. **Arguments** ``pw_python_action`` accepts all of the arguments of a regular ``action`` target. Additionally, it has some of its own arguments: * ``module``: Run the specified Python module instead of a script. Either ``script`` or ``module`` must be specified, but not both. * ``capture_output``: Optional boolean. If true, script output is hidden unless the script fails with an error. Defaults to true. * ``stamp``: Optional variable indicating whether to automatically create a placeholder output file for the script. This allows running scripts without specifying ``outputs``. If ``stamp`` is true, a generic output file is used. If ``stamp`` is a file path, that file is used as a stamp file. Like any output file, ``stamp`` must be in the build directory. Defaults to false. * ``environment``: Optional list of strings. Environment variables to set, passed as NAME=VALUE strings. * ``working_directory``: Optional file path. When provided the current working directory will be set to this location before the Python module or script is run. * ``command_launcher``: Optional string. Arguments to prepend to the Python command, e.g. ``'/usr/bin/fakeroot --'`` will run the Python script within a fakeroot environment. * ``venv``: Optional gn target of the pw_python_venv that should be used to run this action. .. _module-pw_build-python-action-expressions: Expressions ^^^^^^^^^^^ ``pw_python_action`` evaluates expressions in ``args``, the arguments passed to the script. These expressions function similarly to generator expressions in CMake. Expressions may be passed as a standalone argument or as part of another argument. A single argument may contain multiple expressions. Generally, these expressions are used within templates rather than directly in BUILD.gn files. This allows build code to use GN labels without having to worry about converting them to files. .. note:: We intend to replace these expressions with native GN features when possible. See `b/234886742 `_. The following expressions are supported: .. describe:: Evaluates to the output file of the provided GN target. For example, the expression .. code-block:: "" might expand to .. code-block:: "/home/User/project_root/out/obj/foo/bar/static_lib.a" ``TARGET_FILE`` parses the ``.ninja`` file for the GN target, so it should always find the correct output file, regardless of the toolchain's or target's configuration. Some targets, such as ``source_set`` and ``group`` targets, do not have an output file, and attempting to use ``TARGET_FILE`` with them results in an error. ``TARGET_FILE`` only resolves GN target labels to their outputs. To resolve paths generally, use the standard GN approach of applying the ``rebase_path(path, root_build_dir)`` function. This function converts the provided GN path or list of paths to be relative to the build directory, from which all build commands and scripts are executed. .. describe:: ``TARGET_FILE_IF_EXISTS`` evaluates to the output file of the provided GN target, if the output file exists. If the output file does not exist, the entire argument that includes this expression is omitted, even if there is other text or another expression. For example, consider this expression: .. code-block:: "--database=" If the ``//alpha/bravo`` target file exists, this might expand to the following: .. code-block:: "--database=/home/User/project/out/obj/alpha/bravo/bravo.elf" If the ``//alpha/bravo`` target file does not exist, the entire ``--database=`` argument is omitted from the script arguments. .. describe:: Evaluates to the object files of the provided GN target. Expands to a separate argument for each object file. If the target has no object files, the argument is omitted entirely. Because it does not expand to a single expression, the ```` expression may not have leading or trailing text. For example, the expression .. code-block:: "" might expand to multiple separate arguments: .. code-block:: "/home/User/project_root/out/obj/foo/bar/a_source_set.file_a.cc.o" "/home/User/project_root/out/obj/foo/bar/a_source_set.file_b.cc.o" "/home/User/project_root/out/obj/foo/bar/a_source_set.file_c.cc.o" **Example** .. code-block:: import("$dir_pw_build/python_action.gni") pw_python_action("postprocess_main_image") { script = "py/postprocess_binary.py" args = [ "--database", rebase_path("my/database.csv", root_build_dir), "--binary=", ] stamp = true } .. _module-pw_build-evaluate-path-expressions: pw_evaluate_path_expressions ---------------------------- It is not always feasible to pass information to a script through command line arguments. If a script requires a large amount of input data, writing to a file is often more convenient. However, doing so bypasses ``pw_python_action``'s GN target label resolution, preventing such scripts from working with build artifacts in a build system-agnostic manner. ``pw_evaluate_path_expressions`` is designed to address this use case. It takes a list of input files and resolves target expressions within them, modifying the files in-place. Refer to ``pw_python_action``'s :ref:`module-pw_build-python-action-expressions` section for the list of supported expressions. .. note:: ``pw_evaluate_path_expressions`` is typically used as an intermediate sub-target of a larger template, rather than a standalone build target. **Arguments** * ``files``: A list of scopes, each containing a ``source`` file to process and a ``dest`` file to which to write the result. **Example** The following template defines an executable target which additionally outputs the list of object files from which it was compiled, making use of ``pw_evaluate_path_expressions`` to resolve their paths. .. code-block:: import("$dir_pw_build/evaluate_path_expressions.gni") template("executable_with_artifacts") { executable("${target_name}.exe") { sources = invoker.sources if defined(invoker.deps) { deps = invoker.deps } } _artifacts_input = "$target_gen_dir/${target_name}_artifacts.json.in" _artifacts_output = "$target_gen_dir/${target_name}_artifacts.json" _artifacts = { binary = "" objects = "" } write_file(_artifacts_input, _artifacts, "json") pw_evaluate_path_expressions("${target_name}.evaluate") { files = [ { source = _artifacts_input dest = _artifacts_output }, ] } group(target_name) { deps = [ ":${target_name}.exe", ":${target_name}.evaluate", ] } } .. _module-pw_build-pw_exec: pw_exec ------- ``pw_exec`` allows for execution of arbitrary programs. It is a wrapper around ``pw_python_action`` but allows for specifying the program to execute. .. note:: Prefer to use ``pw_python_action`` instead of calling out to shell scripts, as the python will be more portable. ``pw_exec`` should generally only be used for interacting with legacy/existing scripts. **Arguments** * ``program``: The program to run. Can be a full path or just a name (in which case $PATH is searched). * ``args``: Optional list of arguments to the program. * ``deps``: Dependencies for this target. * ``public_deps``: Public dependencies for this target. In addition to outputs from this target, outputs generated by public dependencies can be used as inputs from targets that depend on this one. This is not the case for private deps. * ``inputs``: Optional list of build inputs to the program. * ``outputs``: Optional list of artifacts produced by the program's execution. * ``env``: Optional list of key-value pairs defining environment variables for the program. * ``env_file``: Optional path to a file containing a list of newline-separated key-value pairs defining environment variables for the program. * ``args_file``: Optional path to a file containing additional positional arguments to the program. Each line of the file is appended to the invocation. Useful for specifying arguments from GN metadata. * ``skip_empty_args``: If args_file is provided, boolean indicating whether to skip running the program if the file is empty. Used to avoid running commands which error when called without arguments. * ``capture_output``: If true, output from the program is hidden unless the program exits with an error. Defaults to true. * ``working_directory``: The working directory to execute the subprocess with. If not specified it will not be set and the subprocess will have whatever the parent current working directory is. * ``visibility``: GN visibility to apply to the underlying target. **Example** .. code-block:: import("$dir_pw_build/exec.gni") pw_exec("hello_world") { program = "/bin/sh" args = [ "-c", "echo hello \$WORLD", ] env = [ "WORLD=world", ] } pw_input_group -------------- ``pw_input_group`` defines a group of input files which are not directly processed by the build but are still important dependencies of later build steps. This is commonly used alongside metadata to propagate file dependencies through the build graph and force rebuilds on file modifications. For example ``pw_docgen`` defines a ``pw_doc_group`` template which outputs metadata from a list of input files. The metadata file is not actually part of the build, and so changes to any of the input files do not trigger a rebuild. This is problematic, as targets that depend on the metadata should rebuild when the inputs are modified but GN cannot express this dependency. ``pw_input_group`` solves this problem by allowing a list of files to be listed in a target that does not output any build artifacts, causing all dependent targets to correctly rebuild. **Arguments** ``pw_input_group`` accepts all arguments that can be passed to a ``group`` target, as well as requiring one extra: * ``inputs``: List of input files. **Example** .. code-block:: import("$dir_pw_build/input_group.gni") pw_input_group("foo_metadata") { metadata = { files = [ "x.foo", "y.foo", "z.foo", ] } inputs = metadata.files } Targets depending on ``foo_metadata`` will rebuild when any of the ``.foo`` files are modified. pw_zip ------ ``pw_zip`` is a target that allows users to zip up a set of input files and directories into a single output ``.zip`` file—a simple automation of a potentially repetitive task. **Arguments** * ``inputs``: List of source files as well as the desired relative zip destination. See below for the input syntax. * ``dirs``: List of entire directories to be zipped as well as the desired relative zip destination. See below for the input syntax. * ``output``: Filename of output ``.zip`` file. * ``deps``: List of dependencies for the target. **Input Syntax** Inputs all need to follow the correct syntax: #. Path to source file or directory. Directories must end with a ``/``. #. The delimiter (defaults to ``>``). #. The desired destination of the contents within the ``.zip``. Must start with ``/`` to indicate the zip root. Any number of subdirectories are allowed. If the source is a file it can be put into any subdirectory of the root. If the source is a file, the zip copy can also be renamed by ending the zip destination with a filename (no trailing ``/``). Thus, it should look like the following: ``"[source file or dir] > /"``. **Example** Let's say we have the following structure for a ``//source/`` directory: .. code-block:: source/ ├── file1.txt ├── file2.txt ├── file3.txt └── some_dir/ ├── file4.txt └── some_other_dir/ └── file5.txt And we create the following build target: .. code-block:: import("$dir_pw_build/zip.gni") pw_zip("target_name") { inputs = [ "//source/file1.txt > /", # Copied to the zip root dir. "//source/file2.txt > /renamed.txt", # File renamed. "//source/file3.txt > /bar/", # File moved to the /bar/ dir. ] dirs = [ "//source/some_dir/ > /bar/some_dir/", # All /some_dir/ contents copied # as /bar/some_dir/. ] # Note on output: if the specific output directory isn't defined # (such as output = "zoo.zip") then the .zip will output to the # same directory as the BUILD.gn file that called the target. output = "//$target_out_dir/foo.zip" # Where the foo.zip will end up } This will result in a ``.zip`` file called ``foo.zip`` stored in ``//$target_out_dir`` with the following structure: .. code-block:: foo.zip ├── bar/ │ ├── file3.txt │ └── some_dir/ │ ├── file4.txt │ └── some_other_dir/ │ └── file5.txt ├── file1.txt └── renamed.txt .. _module-pw_build-relative-source-file-names: pw_relative_source_file_names ----------------------------- This template recursively walks the listed dependencies and collects the names of all the headers and source files required by the targets, and then transforms them such that they reflect the ``__FILE__`` when pw_build's ``relative_paths`` config is applied. This is primarily intended for side-band generation of pw_tokenizer tokens so file name tokens can be utilized in places where pw_tokenizer is unable to embed token information as part of C/C++ compilation. This template produces a JSON file containing an array of strings (file paths with ``-ffile-prefix-map``-like transformations applied) that can be used to :ref:`generate a token database `. **Arguments** * ``deps``: A required list of targets to recursively extract file names from. * ``outputs``: A required array with a single element: the path to write the final JSON file to. **Example** Let's say we have the following project structure: .. code-block:: project root ├── foo/ │ ├── foo.h │ └── foo.cc ├── bar/ │ ├── bar.h │ └── bar.cc ├── unused/ │ ├── unused.h │ └── unused.cc └── main.cc And a BUILD.gn at the root: .. code-block:: pw_source_set("bar") { public_configs = [ ":bar_headers" ] public = [ "bar/bar.h" ] sources = [ "bar/bar.cc" ] } pw_source_set("foo") { public_configs = [ ":foo_headers" ] public = [ "foo/foo.h" ] sources = [ "foo/foo.cc" ] deps = [ ":bar" ] } pw_source_set("unused") { public_configs = [ ":unused_headers" ] public = [ "unused/unused.h" ] sources = [ "unused/unused.cc" ] deps = [ ":bar" ] } pw_executable("main") { sources = [ "main.cc" ] deps = [ ":foo" ] } pw_relative_source_file_names("main_source_files") { deps = [ ":main" ] outputs = [ "$target_gen_dir/main_source_files.json" ] } The json file written to `out/gen/main_source_files.json` will contain: .. code-block:: [ "bar/bar.cc", "bar/bar.h", "foo/foo.cc", "foo/foo.h", "main.cc" ] Since ``unused`` isn't a transitive dependency of ``main``, its source files are not included. Similarly, even though ``bar`` is not a direct dependency of ``main``, its source files *are* included because ``foo`` brings in ``bar`` as a transitive dependency. Note how the file paths in this example are relative to the project root rather than being absolute paths (e.g. ``/home/user/ralph/coding/my_proj/main.cc``). This is a result of transformations applied to strip absolute pathing prefixes, matching the behavior of pw_build's ``$dir_pw_build:relative_paths`` config. Build time errors: pw_error and pw_build_assert ----------------------------------------------- In Pigweed's complex, multi-toolchain GN build it is not possible to build every target in every configuration. GN's ``assert`` statement is not ideal for enforcing the correct configuration because it may prevent the GN build files or targets from being referred to at all, even if they aren't used. The ``pw_error`` GN template results in an error if it is executed during the build. These error targets can exist in the build graph, but cannot be depended on without an error. ``pw_build_assert`` evaluates to a ``pw_error`` if a condition fails or nothing (an empty group) if the condition passes. Targets can add a dependency on a ``pw_build_assert`` to enforce a condition at build time. The templates for build time errors are defined in ``pw_build/error.gni``. Improved Ninja interface ------------------------ Ninja includes a basic progress display, showing in a single line the number of targets finished, the total number of targets, and the name of the most recent target it has either started or finished. For additional insight into the status of the build, Pigweed includes a Ninja wrapper, ``pw-wrap-ninja``, that displays additional real-time information about the progress of the build. The wrapper is invoked the same way you'd normally invoke Ninja: .. code-block:: sh pw-wrap-ninja -C out The script lists the progress of the build, as well as the list of targets that Ninja is currently building, along with a timer that measures how long each target has been building for: .. code-block:: [51.3s] Building [8924/10690] ... [10.4s] c++ pw_strict_host_clang_debug/obj/pw_string/string_test.lib.string_test.cc.o [ 9.5s] ACTION //pw_console/py:py.lint.mypy(//pw_build/python_toolchain:python) [ 9.4s] ACTION //pw_console/py:py.lint.pylint(//pw_build/python_toolchain:python) [ 6.1s] clang-tidy ../pw_log_rpc/log_service.cc [ 6.1s] clang-tidy ../pw_log_rpc/log_service_test.cc [ 6.1s] clang-tidy ../pw_log_rpc/rpc_log_drain.cc [ 6.1s] clang-tidy ../pw_log_rpc/rpc_log_drain_test.cc [ 5.4s] c++ pw_strict_host_clang_debug/obj/BUILD_DIR/pw_strict_host_clang_debug/gen/pw... ... and 109 more This allows you to, at a glance, know what Ninja's currently building, which targets are bottlenecking the rest of the build, and which targets are taking an unusually long time to complete. ``pw-wrap-ninja`` includes other useful functionality as well. The ``--write-trace`` option writes a build trace to the specified path, which can be viewed in the `Perfetto UI `_, or via Chrome's built-in ``chrome://tracing`` tool. CMake ===== Pigweed's `CMake`_ support is provided primarily for projects that have an existing CMake build and wish to integrate Pigweed without switching to a new build system. The following command generates Ninja build files for a host build in the ``out/cmake_host`` directory: .. code-block:: sh cmake -B out/cmake_host -S "$PW_ROOT" -G Ninja -DCMAKE_TOOLCHAIN_FILE=$PW_ROOT/pw_toolchain/host_clang/toolchain.cmake The ``PW_ROOT`` environment variable must point to the root of the Pigweed directory. This variable is set by Pigweed's environment setup. Tests can be executed with the ``pw_run_tests.GROUP`` targets. To run Pigweed module tests, execute ``pw_run_tests.modules``: .. code-block:: sh ninja -C out/cmake_host pw_run_tests.modules :ref:`module-pw_watch` supports CMake, so you can also run .. code-block:: sh pw watch -C out/cmake_host pw_run_tests.modules CMake functions --------------- CMake convenience functions are defined in ``pw_build/pigweed.cmake``. * ``pw_add_library_generic`` -- The base helper used to instantiate CMake libraries. This is meant for use in downstream projects as upstream Pigweed modules are expected to use ``pw_add_library``. * ``pw_add_library`` -- Add an upstream Pigweed library. * ``pw_add_facade_generic`` -- The base helper used to instantiate facade libraries. This is meant for use in downstream projects as upstream Pigweed modules are expected to use ``pw_add_facade``. * ``pw_add_facade`` -- Declare an upstream Pigweed facade. * ``pw_set_backend`` -- Set the backend library to use for a facade. * ``pw_add_test_generic`` -- The base helper used to instantiate test targets. This is meant for use in downstrema projects as upstream Pigweed modules are expected to use ``pw_add_test``. * ``pw_add_test`` -- Declare an upstream Pigweed test target. * ``pw_add_test_group`` -- Declare a target to group and bundle test targets. * ``pw_target_link_targets`` -- Helper wrapper around ``target_link_libraries`` which only supports CMake targets and detects when the target does not exist. Note that generator expressions are not supported. * ``pw_add_global_compile_options`` -- Applies compilation options to all targets in the build. This should only be used to add essential compilation options, such as those that affect the ABI. Use ``pw_add_library`` or ``target_compile_options`` to apply other compile options. * ``pw_add_error_target`` -- Declares target which reports a message and causes a build failure only when compiled. This is useful when ``FATAL_ERROR`` messages cannot be used to catch problems during the CMake configuration phase. * ``pw_parse_arguments`` -- Helper to parse CMake function arguments. See ``pw_build/pigweed.cmake`` for the complete documentation of these functions. Special libraries that do not fit well with these functions are created with the standard CMake functions, such as ``add_library`` and ``target_link_libraries``. Facades and backends -------------------- The CMake build uses CMake cache variables for configuring :ref:`facades` and backends. Cache variables are similar to GN's build args set with ``gn args``. Unlike GN, CMake does not support multi-toolchain builds, so these variables have a single global value per build directory. The ``pw_add_module_facade`` function declares a cache variable named ``_BACKEND`` for each facade. Cache variables can be awkward to work with, since their values only change when they're assigned, but then persist accross CMake invocations. These variables should be set in one of the following ways: * Prior to setting a backend, your application should include ``$ENV{PW_ROOT}/backends.cmake``. This file will setup all the backend targets such that any misspelling of a facade or backend will yield a warning. .. note:: Zephyr developers do not need to do this, backends can be set automatically by enabling the appropriate Kconfig options. * Call ``pw_set_backend`` to set backends appropriate for the target in the target's toolchain file. The toolchain file is provided to ``cmake`` with ``-DCMAKE_TOOLCHAIN_FILE=``. * Call ``pw_set_backend`` in the top-level ``CMakeLists.txt`` before other CMake code executes. * Set the backend variable at the command line with the ``-D`` option. .. code-block:: sh cmake -B out/cmake_host -S "$PW_ROOT" -G Ninja \ -DCMAKE_TOOLCHAIN_FILE=$PW_ROOT/pw_toolchain/host_clang/toolchain.cmake \ -Dpw_log_BACKEND=pw_log_basic * Temporarily override a backend by setting it interactively with ``ccmake`` or ``cmake-gui``. If the backend is set to a build target that does not exist, there will be an error message like the following: .. code-block:: CMake Error at pw_build/pigweed.cmake:257 (message): my_module.my_facade's INTERFACE dep "my_nonexistent_backend" is not a target. Call Stack (most recent call first): pw_build/pigweed.cmake:238:EVAL:1 (_pw_target_link_targets_deferred_check) CMakeLists.txt:DEFERRED Toolchain setup --------------- In CMake, the toolchain is configured by setting CMake variables, as described in the `CMake documentation `_. These variables are typically set in a toolchain CMake file passed to ``cmake`` with the ``-D`` option (``-DCMAKE_TOOLCHAIN_FILE=path/to/file.cmake``). For Pigweed embedded builds, set ``CMAKE_SYSTEM_NAME`` to the empty string (``""``). Toolchains may set the ``pw_build_WARNINGS`` variable to a list of ``INTERFACE`` libraries with compilation options for Pigweed's upstream libraries. This defaults to a strict set of warnings. Projects may need to use less strict compilation warnings to compile backends exposed to Pigweed code (such as ``pw_log``) that cannot compile with Pigweed's flags. If desired, Projects can access these warnings by depending on ``pw_build.warnings``. Third party libraries --------------------- The CMake build includes third-party libraries similarly to the GN build. A ``dir_pw_third_party_`` cache variable is defined for each third-party dependency. The variable must be set to the absolute path of the library in order to use it. If the variable is empty (``if("${dir_pw_third_party_}" STREQUAL "")``), the dependency is not available. Third-party dependencies are not automatically added to the build. They can be manually added with ``add_subdirectory`` or by setting the ``pw_third_party__ADD_SUBDIRECTORY`` option to ``ON``. Third party variables are set like any other cache global variable in CMake. It is recommended to set these in one of the following ways: * Set with the CMake ``set`` function in the toolchain file or a ``CMakeLists.txt`` before other CMake code executes. .. code-block:: cmake set(dir_pw_third_party_nanopb ${CMAKE_CURRENT_SOURCE_DIR}/external/nanopb CACHE PATH "" FORCE) * Set the variable at the command line with the ``-D`` option. .. code-block:: sh cmake -B out/cmake_host -S "$PW_ROOT" -G Ninja \ -DCMAKE_TOOLCHAIN_FILE=$PW_ROOT/pw_toolchain/host_clang/toolchain.cmake \ -Ddir_pw_third_party_nanopb=/path/to/nanopb * Set the variable interactively with ``ccmake`` or ``cmake-gui``. Use Pigweed from an existing CMake project ------------------------------------------ To use Pigweed libraries form a CMake-based project, simply include the Pigweed repository from a ``CMakeLists.txt``. .. code-block:: cmake add_subdirectory(path/to/pigweed pigweed) All module libraries will be available as ``module_name`` or ``module_name.sublibrary``. If desired, modules can be included individually. .. code-block:: cmake add_subdirectory(path/to/pigweed/pw_some_module pw_some_module) add_subdirectory(path/to/pigweed/pw_another_module pw_another_module) Bazel ===== Bazel is currently very experimental, and only builds for host and ARM Cortex-M microcontrollers. The common configuration for Bazel for all modules is in the ``pigweed.bzl`` file. The built-in Bazel rules ``cc_binary``, ``cc_library``, and ``cc_test`` are wrapped with ``pw_cc_binary``, ``pw_cc_library``, and ``pw_cc_test``. These wrappers add parameters to calls to the compiler and linker. In addition to wrapping the built-in rules, Pigweed also provides a custom rule for handling linker scripts with Bazel. e.g. .. code-block:: python pw_linker_script( name = "some_linker_script", linker_script = ":some_configurable_linker_script.ld", defines = [ "PW_BOOT_FLASH_BEGIN=0x08000200", "PW_BOOT_FLASH_SIZE=1024K", "PW_BOOT_HEAP_SIZE=112K", "PW_BOOT_MIN_STACK_SIZE=1K", "PW_BOOT_RAM_BEGIN=0x20000000", "PW_BOOT_RAM_SIZE=192K", "PW_BOOT_VECTOR_TABLE_BEGIN=0x08000000", "PW_BOOT_VECTOR_TABLE_SIZE=512", ], ) pw_cc_binary( name = "some_binary", srcs = ["some_source.c"], additional_linker_inputs = [":some_linker_script"], linkopts = ["-T $(location :some_linker_script)"], ) Currently Pigweed is making use of a set of `open source `_ toolchains. The host builds are only supported on Linux/Mac based systems. Additionally the host builds are not entirely hermetic, and will make use of system libraries and headers. This is close to the default configuration for Bazel, though slightly more hermetic. The host toolchain is based around clang-11 which has a system dependency on 'libtinfo.so.5' which is often included as part of the libncurses packages. On Debian based systems this can be installed using the command below: .. code-block:: sh sudo apt install libncurses5 The host toolchain does not currently support native Windows, though using WSL is a viable alternative. The ARM Cortex-M Bazel toolchains are based around gcc-arm-non-eabi and are entirely hermetic. You can target Cortex-M, by using the platforms command line option. This set of toolchains is supported from hosts; Windows, Mac and Linux. The platforms that are currently supported are listed below: .. code-block:: sh bazel build //:your_target --platforms=@pigweed//pw_build/platforms:cortex_m0 bazel build //:your_target --platforms=@pigweed//pw_build/platforms:cortex_m1 bazel build //:your_target --platforms=@pigweed//pw_build/platforms:cortex_m3 bazel build //:your_target --platforms=@pigweed//pw_build/platforms:cortex_m4 bazel build //:your_target --platforms=@pigweed//pw_build/platforms:cortex_m7 bazel build //:your_target \ --platforms=@pigweed//pw_build/platforms:cortex_m4_fpu bazel build //:your_target \ --platforms=@pigweed//pw_build/platforms:cortex_m7_fpu The above examples are cpu/fpu oriented platforms and can be used where applicable for your application. There some more specific platforms for the types of boards that are included as examples in Pigweed. It is strongly encouraged that you create your own set of platforms specific for your project, that implement the constraint_settings in this repository. e.g. New board constraint_value: .. code-block:: python #your_repo/build_settings/constraints/board/BUILD constraint_value( name = "nucleo_l432kc", constraint_setting = "@pigweed//pw_build/constraints/board", ) New chipset constraint_value: .. code-block:: python # your_repo/build_settings/constraints/chipset/BUILD constraint_value( name = "stm32l432kc", constraint_setting = "@pigweed//pw_build/constraints/chipset", ) New platforms for chipset and board: .. code-block:: python #your_repo/build_settings/platforms/BUILD # Works with all stm32l432kc platforms( name = "stm32l432kc", parents = ["@pigweed//pw_build/platforms:cortex_m4"], constraint_values = ["@your_repo//build_settings/constraints/chipset:stm32l432kc"], ) # Works with only the nucleo_l432kc platforms( name = "nucleo_l432kc", parents = [":stm32l432kc"], constraint_values = ["@your_repo//build_settings/constraints/board:nucleo_l432kc"], ) In the above example you can build your code with the command line: .. code-block:: python bazel build //:your_target_for_nucleo_l432kc \ --platforms=@your_repo//build_settings:nucleo_l432kc You can also specify that a specific target is only compatible with one platform: .. code-block:: python cc_library( name = "compatible_with_all_stm32l432kc", srcs = ["tomato_src.c"], target_compatible_with = ["@your_repo//build_settings/constraints/chipset:stm32l432kc"], ) cc_library( name = "compatible_with_only_nucleo_l432kc", srcs = ["bbq_src.c"], target_compatible_with = ["@your_repo//build_settings/constraints/board:nucleo_l432kc"], )