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287 lines
11 KiB
287 lines
11 KiB
.. _cmodules:
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MicroPython external C modules
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==============================
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When developing modules for use with MicroPython you may find you run into
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limitations with the Python environment, often due to an inability to access
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certain hardware resources or Python speed limitations.
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If your limitations can't be resolved with suggestions in :ref:`speed_python`,
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writing some or all of your module in C (and/or C++ if implemented for your port)
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is a viable option.
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If your module is designed to access or work with commonly available
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hardware or libraries please consider implementing it inside the MicroPython
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source tree alongside similar modules and submitting it as a pull request.
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If however you're targeting obscure or proprietary systems it may make
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more sense to keep this external to the main MicroPython repository.
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This chapter describes how to compile such external modules into the
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MicroPython executable or firmware image. Both Make and CMake build
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tools are supported, and when writing an external module it's a good idea to
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add the build files for both of these tools so the module can be used on all
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ports. But when compiling a particular port you will only need to use one
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method of building, either Make or CMake.
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An alternative approach is to use :ref:`natmod` which allows writing custom C
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code that is placed in a .mpy file, which can be imported dynamically in to
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a running MicroPython system without the need to recompile the main firmware.
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Structure of an external C module
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---------------------------------
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A MicroPython user C module is a directory with the following files:
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* ``*.c`` / ``*.cpp`` / ``*.h`` source code files for your module.
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These will typically include the low level functionality being implemented and
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the MicroPython binding functions to expose the functions and module(s).
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Currently the best reference for writing these functions/modules is
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to find similar modules within the MicroPython tree and use them as examples.
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* ``micropython.mk`` contains the Makefile fragment for this module.
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``$(USERMOD_DIR)`` is available in ``micropython.mk`` as the path to your
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module directory. As it's redefined for each c module, is should be expanded
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in your ``micropython.mk`` to a local make variable,
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eg ``EXAMPLE_MOD_DIR := $(USERMOD_DIR)``
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Your ``micropython.mk`` must add your modules source files to the
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``SRC_USERMOD_C`` or ``SRC_USERMOD_LIB_C`` variables. The former will be
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processed for ``MP_QSTR_`` and ``MP_REGISTER_MODULE`` definitions, the latter
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will not (e.g. helpers and library code that isn't MicroPython-specific).
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These paths should include your expanded copy of ``$(USERMOD_DIR)``, e.g.::
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SRC_USERMOD_C += $(EXAMPLE_MOD_DIR)/modexample.c
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SRC_USERMOD_LIB_C += $(EXAMPLE_MOD_DIR)/utils/algorithm.c
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Similarly, use ``SRC_USERMOD_CXX`` and ``SRC_USERMOD_LIB_CXX`` for C++
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source files.
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If you have custom compiler options (like ``-I`` to add directories to search
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for header files), these should be added to ``CFLAGS_USERMOD`` for C code
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and to ``CXXFLAGS_USERMOD`` for C++ code.
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* ``micropython.cmake`` contains the CMake configuration for this module.
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In ``micropython.cmake``, you may use ``${CMAKE_CURRENT_LIST_DIR}`` as the path to
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the current module.
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Your ``micropython.cmake`` should define an ``INTERFACE`` library and associate
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your source files, compile definitions and include directories with it.
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The library should then be linked to the ``usermod`` target.
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.. code-block:: cmake
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add_library(usermod_cexample INTERFACE)
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target_sources(usermod_cexample INTERFACE
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${CMAKE_CURRENT_LIST_DIR}/examplemodule.c
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)
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target_include_directories(usermod_cexample INTERFACE
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${CMAKE_CURRENT_LIST_DIR}
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)
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target_link_libraries(usermod INTERFACE usermod_cexample)
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See below for full usage example.
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Basic example
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-------------
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The ``cexample`` module provides examples for a function and a class. The
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``cexample.add_ints(a, b)`` function adds two integer args together and returns
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the result. The ``cexample.Timer()`` type creates timers that can be used to
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measure the elapsed time since the object is instantiated.
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The module can be found in the MicroPython source tree
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`in the examples directory <https://github.com/micropython/micropython/tree/master/examples/usercmodule/cexample>`_
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and has a source file and a Makefile fragment with content as described above::
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micropython/
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└──examples/
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└──usercmodule/
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└──cexample/
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├── examplemodule.c
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├── micropython.mk
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└── micropython.cmake
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Refer to the comments in these files for additional explanation.
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Next to the ``cexample`` module there's also ``cppexample`` which
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works in the same way but shows one way of mixing C and C++ code
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in MicroPython.
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Compiling the cmodule into MicroPython
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--------------------------------------
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To build such a module, compile MicroPython (see `getting started
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<https://github.com/micropython/micropython/wiki/Getting-Started>`_),
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applying 2 modifications:
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1. Set the build-time flag ``USER_C_MODULES`` to point to the modules
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you want to include. For ports that use Make this variable should be a
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directory which is searched automatically for modules. For ports that
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use CMake this variable should be a file which includes the modules to
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build. See below for details.
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2. Enable the modules by setting the corresponding C preprocessor macro to
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1. This is only needed if the modules you are building are not
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automatically enabled.
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For building the example modules which come with MicroPython,
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set ``USER_C_MODULES`` to the ``examples/usercmodule`` directory for Make,
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or to ``examples/usercmodule/micropython.cmake`` for CMake.
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For example, here's how the to build the unix port with the example modules:
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.. code-block:: bash
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cd micropython/ports/unix
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make USER_C_MODULES=../../examples/usercmodule
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You may need to run ``make clean`` once at the start when including new
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user modules in the build. The build output will show the modules found::
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...
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Including User C Module from ../../examples/usercmodule/cexample
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Including User C Module from ../../examples/usercmodule/cppexample
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...
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For a CMake-based port such as rp2, this will look a little different (note
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that CMake is actually invoked by ``make``):
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.. code-block:: bash
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cd micropython/ports/rp2
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make USER_C_MODULES=../../examples/usercmodule/micropython.cmake
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Again, you may need to run ``make clean`` first for CMake to pick up the
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user modules. The CMake build output lists the modules by name::
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...
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Including User C Module(s) from ../../examples/usercmodule/micropython.cmake
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Found User C Module(s): usermod_cexample, usermod_cppexample
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...
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The contents of the top-level ``micropython.cmake`` can be used to control which
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modules are enabled.
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For your own projects it's more convenient to keep custom code out of the main
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MicroPython source tree, so a typical project directory structure will look
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like this::
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my_project/
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├── modules/
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│ ├── example1/
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│ │ ├── example1.c
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│ │ ├── micropython.mk
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│ │ └── micropython.cmake
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│ ├── example2/
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│ │ ├── example2.c
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│ │ ├── micropython.mk
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│ │ └── micropython.cmake
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│ └── micropython.cmake
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└── micropython/
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├──ports/
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... ├──stm32/
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...
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When building with Make set ``USER_C_MODULES`` to the ``my_project/modules``
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directory. For example, building the stm32 port:
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.. code-block:: bash
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cd my_project/micropython/ports/stm32
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make USER_C_MODULES=../../../modules
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When building with CMake the top level ``micropython.cmake`` -- found directly
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in the ``my_project/modules`` directory -- should ``include`` all of the modules
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you want to have available:
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.. code-block:: cmake
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include(${CMAKE_CURRENT_LIST_DIR}/example1/micropython.cmake)
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include(${CMAKE_CURRENT_LIST_DIR}/example2/micropython.cmake)
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Then build with:
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.. code-block:: bash
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cd my_project/micropython/ports/esp32
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make USER_C_MODULES=../../../../modules/micropython.cmake
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Note that the esp32 port needs the extra ``..`` for relative paths due to the
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location of its main ``CMakeLists.txt`` file. You can also specify absolute
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paths to ``USER_C_MODULES``.
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All modules specified by the ``USER_C_MODULES`` variable (either found in this
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directory when using Make, or added via ``include`` when using CMake) will be
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compiled, but only those which are enabled will be available for importing.
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User modules are usually enabled by default (this is decided by the developer
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of the module), in which case there is nothing more to do than set ``USER_C_MODULES``
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as described above.
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If a module is not enabled by default then the corresponding C preprocessor macro
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must be enabled. This macro name can be found by searching for the ``MP_REGISTER_MODULE``
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line in the module's source code (it usually appears at the end of the main source file).
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This macro should be surrounded by a ``#if X`` / ``#endif`` pair, and the configuration
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option ``X`` must be set to 1 using ``CFLAGS_EXTRA`` to make the module available. If
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there is no ``#if X`` / ``#endif`` pair then the module is enabled by default.
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For example, the ``examples/usercmodule/cexample`` module is enabled by default so
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has the following line in its source code:
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.. code-block:: c
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MP_REGISTER_MODULE(MP_QSTR_cexample, example_user_cmodule);
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Alternatively, to make this module disabled by default but selectable through
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a preprocessor configuration option, it would be:
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.. code-block:: c
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#if MODULE_CEXAMPLE_ENABLED
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MP_REGISTER_MODULE(MP_QSTR_cexample, example_user_cmodule);
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#endif
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In this case the module is enabled by adding ``CFLAGS_EXTRA=-DMODULE_CEXAMPLE_ENABLED=1``
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to the ``make`` command, or editing ``mpconfigport.h`` or ``mpconfigboard.h`` to add
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.. code-block:: c
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#define MODULE_CEXAMPLE_ENABLED (1)
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Note that the exact method depends on the port as they have different
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structures. If not done correctly it will compile but importing will
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fail to find the module.
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Module usage in MicroPython
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---------------------------
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Once built into your copy of MicroPython, the module
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can now be accessed in Python just like any other builtin module, e.g.
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.. code-block:: python
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import cexample
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print(cexample.add_ints(1, 3))
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# should display 4
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.. code-block:: python
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from cexample import Timer
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from time import sleep_ms
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watch = Timer()
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sleep_ms(1000)
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print(watch.time())
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# should display approximately 1000
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