docs/index.rst - pigweed/pigweed - Git at Google

 .. highlight:: sh

 .. toctree::
   :maxdepth: 1
   :hidden:

   Home <self>
   docs/getting_started
   Source Code <https://cs.opensource.google/pigweed/pigweed>
   Code Reviews <https://pigweed-review.googlesource.com>
   Mailing List <https://groups.google.com/forum/#!forum/pigweed>
   Chat Room <https://discord.gg/M9NSeTA>
   Issue Tracker <https://bugs.pigweed.dev/>
   docs/contributing
   docs/code_of_conduct
   docs/embedded_cpp_guide
   Style Guide <docs/style_guide>
   Automated Analysis <automated_analysis>
   docs/os_abstraction_layers
   targets
   Build System <build_system>
   docs/size_optimizations
   FAQ <docs/faq>
   docs/module_structure
   module_guides
   third_party_support

 =======
 Pigweed
 =======
 Pigweed is an open source collection of embedded-targeted libraries--or as we
 like to call them, modules. These modules are building blocks and
 infrastructure that enable faster and more reliable development on
 small-footprint MMU-less 32-bit microcontrollers like the STMicroelectronics
 STM32L452 or the Nordic nRF52832.

 .. attention::

   Pigweed is in **early access**; though many modules are shipping in
   production already. If you're interested in using Pigweed, please reach out
   in our `chat room <https://discord.gg/M9NSeTA>`_ or on the `mailing list
   <https://groups.google.com/forum/#!forum/pigweed>`_.

 Getting Started
 ---------------
 If you'd like to get set up with Pigweed, please visit the
 :ref:`docs-getting-started` guide.

 What does Pigweed offer?
 ------------------------
 There are many modules in Pigweed; this section showcases a selection that
 produce visual output. For more information about the different Pigweed module
 offerings, refer to :ref:`docs-module-guides` section.

 ``pw_watch`` - Build, flash, run, & test on save
 ------------------------------------------------
 In the web development space, file system watchers are prevalent. These
 watchers trigger a web server reload on source change, making development much
 faster. In the embedded space, file system watchers are less prevalent;
 however, they are no less useful! The Pigweed watcher module makes it easy to
 instantly compile, flash, and run tests upon save. Combined with the GN-based
 build which expresses the full dependency tree, only the exact tests affected
 by a file change are run on saves.

 The demo below shows :ref:`module-pw_watch` building for a STMicroelectronics
 STM32F429I-DISC1 development board, flashing the board with the affected test,
 and verifying the test runs as expected. Once this is set up, you can attach
 multiple devices to run tests in a distributed manner to reduce the time it
 takes to run tests.

 .. image:: docs/images/pw_watch_on_device_demo.gif
   :width: 800
   :alt: pw watch running on-device tests

 ``pw_presubmit`` - Vacuum lint on every commit
 ----------------------------------------------
 Presubmit checks are essential tools, but they take work to set up, and
 projects don’t always get around to it. The :ref:`module-pw_presubmit` module
 provides tools for setting up high quality presubmit checks for any project. We
 use this framework to run Pigweed’s presubmit on our workstations and in our
 automated building tools.

 The ``pw_presubmit`` module includes ``pw format``, a tool that provides a
 unified interface for automatically formatting code in a variety of languages.
 With ``pw format``, you can format C, C++, Python, GN, and Go code according to
 configurations defined by your project. ``pw format`` leverages existing tools
 like ``clang-format``, and it’s simple to add support for new languages.

 .. image:: pw_presubmit/docs/pw_presubmit_demo.gif
   :width: 800
   :alt: pw presubmit demo

 ``pw_env_setup`` - Cross platform embedded compiler setup
 ---------------------------------------------------------
 A classic problem in the embedded space is reducing the **time from git clone
 to having a binary executing on a device**. An entire suite of tools is needed
 for building non-trivial production embedded projects, and need to be
 installed. For example:

 - A C++ compiler for your target device, and also for your host
 - A build system or three; for example, GN, Ninja, CMake, Bazel
 - A code formatting program like clang-format
 - A debugger like OpenOCD to flash and debug your embedded device
 - A known Python version with known modules installed for scripting
 - A Go compiler for the Go-based command line tools
 - ... and so on

 In the server space, container solutions like Docker or Podman solve this;
 however, container solutions are a mixed bag for embedded systems development
 where one frequently needs access to native system resources like USB devices,
 or must operate on Windows.

 :ref:`module-pw_env_setup` is our compromise solution for this problem that
 works on Mac, Windows, and Linux. It leverages the Chrome Infrastructure
 Packaging Deployment system (CIPD) to bootstrap a Python installation, which in
 turn inflates a virtual environment. The tooling is installed into your
 workspace, and makes no changes to your system. This tooling is designed to be
 reused by any project.

 .. image:: docs/images/pw_env_setup_demo.gif
   :width: 800
   :alt: pw environment setup demo

 ``pw_unit_test`` - Embedded testing for MCUs
 --------------------------------------------
 Unit testing is important, and Pigweed offers a portable library that’s broadly
 compatible with `Google Test <https://github.com/google/googletest>`_. Unlike
 Google Test, :ref:`module-pw_unit_test` is built on top of embedded friendly
 primitives; for example, it does not use dynamic memory allocation.
 Additionally, it is easy to port to new target platforms by implementing the
 `test event handler interface <https://cs.opensource.google/pigweed/pigweed/+/main:pw_unit_test/public/pw_unit_test/event_handler.h>`_.

 Like other modules in Pigweed, ``pw_unit_test`` is designed for use in
 established codebases with their own build system, without the rest of Pigweed
 or the Pigweed integrated GN build. However, when combined with Pigweed's
 build, the result is a flexible and powerful setup that enables easily
 developing code on your desktop (with tests), then running the same tests
 on-device.

 .. image:: docs/images/pw_status_test.png
   :width: 800
   :alt: pw_status test run natively on host

 And more!
 ---------
 Here is a selection of interesting modules:

  - :ref:`module-pw_cpu_exception_cortex_m` - Robust low level hardware fault
    handler for ARM Cortex-M; the handler even has unit tests written in
    assembly to verify nested-hardware-fault handling!

  - :ref:`module-pw_polyfill` - Similar to JavaScript “polyfill” libraries, this
    module provides selected C++17 standard library components that are
    compatible with C++14.

  - :ref:`module-pw_tokenizer` - Replace string literals from log statements
    with 32-bit tokens, to reduce flash use, reduce logging bandwidth, and save
    formatting cycles from log statements at runtime.

  - :ref:`module-pw_kvs` - A key-value-store implementation for flash-backed
    persistent storage with integrated wear levelling. This is a lightweight
    alternative to a file system for embedded devices.

  - :ref:`module-pw_protobuf` - An early preview of our wire-format-oriented
    protocol buffer implementation. This protobuf compiler makes a different set
    of implementation tradeoffs than the most popular protocol buffer library in
    this space, nanopb.

 See the :ref:`docs-module-guides` for the complete list of modules and their
 documentation.
	.. highlight:: sh

	.. toctree::
	:maxdepth: 1
	:hidden:

	Home <self>
	docs/getting_started
	Source Code <https://cs.opensource.google/pigweed/pigweed>
	Code Reviews <https://pigweed-review.googlesource.com>
	Mailing List <https://groups.google.com/forum/#!forum/pigweed>
	Chat Room <https://discord.gg/M9NSeTA>
	Issue Tracker <https://bugs.pigweed.dev/>
	docs/contributing
	docs/code_of_conduct
	docs/embedded_cpp_guide
	Style Guide <docs/style_guide>
	Automated Analysis <automated_analysis>
	docs/os_abstraction_layers
	targets
	Build System <build_system>
	docs/size_optimizations
	FAQ <docs/faq>
	docs/module_structure
	module_guides
	third_party_support

	=======
	Pigweed
	=======
	Pigweed is an open source collection of embedded-targeted libraries--or as we
	like to call them, modules. These modules are building blocks and
	infrastructure that enable faster and more reliable development on
	small-footprint MMU-less 32-bit microcontrollers like the STMicroelectronics
	STM32L452 or the Nordic nRF52832.

	.. attention::

	Pigweed is in early access; though many modules are shipping in
	production already. If you're interested in using Pigweed, please reach out
	in our `chat room <https://discord.gg/M9NSeTA>`_ or on the `mailing list
	<https://groups.google.com/forum/#!forum/pigweed>`_.

	Getting Started
	---------------
	If you'd like to get set up with Pigweed, please visit the
	:ref:`docs-getting-started` guide.

	What does Pigweed offer?
	------------------------
	There are many modules in Pigweed; this section showcases a selection that
	produce visual output. For more information about the different Pigweed module
	offerings, refer to :ref:`docs-module-guides` section.

	``pw_watch`` - Build, flash, run, & test on save
	------------------------------------------------
	In the web development space, file system watchers are prevalent. These
	watchers trigger a web server reload on source change, making development much
	faster. In the embedded space, file system watchers are less prevalent;
	however, they are no less useful! The Pigweed watcher module makes it easy to
	instantly compile, flash, and run tests upon save. Combined with the GN-based
	build which expresses the full dependency tree, only the exact tests affected
	by a file change are run on saves.

	The demo below shows :ref:`module-pw_watch` building for a STMicroelectronics
	STM32F429I-DISC1 development board, flashing the board with the affected test,
	and verifying the test runs as expected. Once this is set up, you can attach
	multiple devices to run tests in a distributed manner to reduce the time it
	takes to run tests.

	.. image:: docs/images/pw_watch_on_device_demo.gif
	:width: 800
	:alt: pw watch running on-device tests

	``pw_presubmit`` - Vacuum lint on every commit
	----------------------------------------------
	Presubmit checks are essential tools, but they take work to set up, and
	projects don’t always get around to it. The :ref:`module-pw_presubmit` module
	provides tools for setting up high quality presubmit checks for any project. We
	use this framework to run Pigweed’s presubmit on our workstations and in our
	automated building tools.

	The ``pw_presubmit`` module includes ``pw format``, a tool that provides a
	unified interface for automatically formatting code in a variety of languages.
	With ``pw format``, you can format C, C++, Python, GN, and Go code according to
	configurations defined by your project. ``pw format`` leverages existing tools
	like ``clang-format``, and it’s simple to add support for new languages.

	.. image:: pw_presubmit/docs/pw_presubmit_demo.gif
	:width: 800
	:alt: pw presubmit demo

	``pw_env_setup`` - Cross platform embedded compiler setup
	---------------------------------------------------------
	A classic problem in the embedded space is reducing the **time from git clone
	to having a binary executing on a device**. An entire suite of tools is needed
	for building non-trivial production embedded projects, and need to be
	installed. For example:

	- A C++ compiler for your target device, and also for your host
	- A build system or three; for example, GN, Ninja, CMake, Bazel
	- A code formatting program like clang-format
	- A debugger like OpenOCD to flash and debug your embedded device
	- A known Python version with known modules installed for scripting
	- A Go compiler for the Go-based command line tools
	- ... and so on

	In the server space, container solutions like Docker or Podman solve this;
	however, container solutions are a mixed bag for embedded systems development
	where one frequently needs access to native system resources like USB devices,
	or must operate on Windows.

	:ref:`module-pw_env_setup` is our compromise solution for this problem that
	works on Mac, Windows, and Linux. It leverages the Chrome Infrastructure
	Packaging Deployment system (CIPD) to bootstrap a Python installation, which in
	turn inflates a virtual environment. The tooling is installed into your
	workspace, and makes no changes to your system. This tooling is designed to be
	reused by any project.

	.. image:: docs/images/pw_env_setup_demo.gif
	:width: 800
	:alt: pw environment setup demo

	``pw_unit_test`` - Embedded testing for MCUs
	--------------------------------------------
	Unit testing is important, and Pigweed offers a portable library that’s broadly
	compatible with `Google Test <https://github.com/google/googletest>`_. Unlike
	Google Test, :ref:`module-pw_unit_test` is built on top of embedded friendly
	primitives; for example, it does not use dynamic memory allocation.
	Additionally, it is easy to port to new target platforms by implementing the
	`test event handler interface <https://cs.opensource.google/pigweed/pigweed/+/main:pw_unit_test/public/pw_unit_test/event_handler.h>`_.

	Like other modules in Pigweed, ``pw_unit_test`` is designed for use in
	established codebases with their own build system, without the rest of Pigweed
	or the Pigweed integrated GN build. However, when combined with Pigweed's
	build, the result is a flexible and powerful setup that enables easily
	developing code on your desktop (with tests), then running the same tests
	on-device.

	.. image:: docs/images/pw_status_test.png
	:width: 800
	:alt: pw_status test run natively on host

	And more!
	---------
	Here is a selection of interesting modules:

	- :ref:`module-pw_cpu_exception_cortex_m` - Robust low level hardware fault
	handler for ARM Cortex-M; the handler even has unit tests written in
	assembly to verify nested-hardware-fault handling!

	- :ref:`module-pw_polyfill` - Similar to JavaScript “polyfill” libraries, this
	module provides selected C++17 standard library components that are
	compatible with C++14.

	- :ref:`module-pw_tokenizer` - Replace string literals from log statements
	with 32-bit tokens, to reduce flash use, reduce logging bandwidth, and save
	formatting cycles from log statements at runtime.

	- :ref:`module-pw_kvs` - A key-value-store implementation for flash-backed
	persistent storage with integrated wear levelling. This is a lightweight
	alternative to a file system for embedded devices.

	- :ref:`module-pw_protobuf` - An early preview of our wire-format-oriented
	protocol buffer implementation. This protobuf compiler makes a different set
	of implementation tradeoffs than the most popular protocol buffer library in
	this space, nanopb.

	See the :ref:`docs-module-guides` for the complete list of modules and their
	documentation.