docs/develop: Add documentation on how to build native .mpy modules.

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.. _cmodules:
MicroPython external C modules MicroPython external C modules
============================== ==============================
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This chapter describes how to compile such external modules into the This chapter describes how to compile such external modules into the
MicroPython executable or firmware image. MicroPython executable or firmware image.
An alternative approach is to use :ref:`natmod` which allows writing custom C
code that is placed in a .mpy file, which can be imported dynamically in to
a running MicroPython system without the need to recompile the main firmware.
Structure of an external C module Structure of an external C module
--------------------------------- ---------------------------------

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cmodules.rst cmodules.rst
qstr.rst qstr.rst
natmod.rst

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docs/develop/natmod.rst Normal file
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.. _natmod:
Native machine code in .mpy files
=================================
This section describes how to build and work with .mpy files that contain native
machine code from a language other than Python. This allows you to
write code in a language like C, compile and link it into a .mpy file, and then
import this file like a normal Python module. This can be used for implementing
functionality which is performance critical, or for including an existing
library written in another language.
One of the main advantages of using native .mpy files is that native machine code
can be imported by a script dynamically, without the need to rebuild the main
MicroPython firmware. This is in contrast to :ref:`cmodules` which also allows
defining custom modules in C but they must be compiled into the main firmware image.
The focus here is on using C to build native modules, but in principle any
language which can be compiled to stand-alone machine code can be put into a
.mpy file.
A native .mpy module is built using the ``mpy_ld.py`` tool, which is found in the
``tools/`` directory of the project. This tool takes a set of object files
(.o files) and links them together to create a native .mpy files.
Supported features and limitations
----------------------------------
A .mpy file can contain MicroPython bytecode and/or native machine code. If it
contains native machine code then the .mpy file has a specific architecture
associated with it. Current supported architectures are (these are the valid
options for the ``ARCH`` variable, see below):
* ``x86`` (32 bit)
* ``x64`` (64 bit x86)
* ``armv7m`` (ARM Thumb 2, eg Cortex-M3)
* ``armv7emsp`` (ARM Thumb 2, single precision float, eg Cortex-M4F, Cortex-M7)
* ``armv7emdp`` (ARM Thumb 2, double precision float, eg Cortex-M7)
* ``xtensa`` (non-windowed, eg ESP8266)
* ``xtensawin`` (windowed with window size 8, eg ESP32)
When compiling and linking the native .mpy file the architecture must be chosen
and the corresponding file can only be imported on that architecture. For more
details about .mpy files see :ref:`mpy_files`.
Native code must be compiled as position independent code (PIC) and use a global
offset table (GOT), although the details of this varies from architecture to
architecture. When importing .mpy files with native code the import machinery
is able to do some basic relocation of the native code. This includes
relocating text, rodata and BSS sections.
Supported features of the linker and dynamic loader are:
* executable code (text)
* read-only data (rodata), including strings and constant data (arrays, structs, etc)
* zeroed data (BSS)
* pointers in text to text, rodata and BSS
* pointers in rodata to text, rodata and BSS
The known limitations are:
* data sections are not supported; workaround: use BSS data and initialise the
data values explicitly
* static BSS variables are not supported; workaround: use global BSS variables
So, if your C code has writable data, make sure the data is defined globally,
without an initialiser, and only written to within functions.
Defining a native module
------------------------
A native .mpy module is defined by a set of files that are used to build the .mpy.
The filesystem layout consists of two main parts, the source files and the Makefile:
* In the simplest case only a single C source file is required, which contains all
the code that will be compiled into the .mpy module. This C source code must
include the ``py/dynruntime.h`` file to access the MicroPython dynamic API, and
must at least define a function called ``mpy_init``. This function will be the
entry point of the module, called when the module is imported.
The module can be split into multiple C source files if desired. Parts of the
module can also be implemented in Python. All source files should be listed in
the Makefile, by adding them to the ``SRC`` variable (see below). This includes
both C source files as well as any Python files which will be included in the
resulting .mpy file.
* The ``Makefile`` contains the build configuration for the module and list the
source files used to build the .mpy module. It should define ``MPY_DIR`` as the
location of the MicroPython repository (to find header files, the relevant Makefile
fragment, and the ``mpy_ld.py`` tool), ``MOD`` as the name of the module, ``SRC``
as the list of source files, optionally specify the machine architecture via ``ARCH``,
and then include ``py/dynruntime.mk``.
Minimal example
---------------
This section provides a fully working example of a simple module named ``factorial``.
This module provides a single function ``factorial.factorial(x)`` which computes the
factorial of the input and returns the result.
Directory layout::
factorial/
├── factorial.c
└── Makefile
The file ``factorial.c`` contains:
.. code-block:: c
// Include the header file to get access to the MicroPython API
#include "py/dynruntime.h"
// Helper function to compute factorial
STATIC mp_int_t factorial_helper(mp_int_t x) {
if (x == 0) {
return 1;
}
return x * factorial_helper(x - 1);
}
// This is the function which will be called from Python, as factorial(x)
STATIC mp_obj_t factorial(mp_obj_t x_obj) {
// Extract the integer from the MicroPython input object
mp_int_t x = mp_obj_get_int(x_obj);
// Calculate the factorial
mp_int_t result = factorial_helper(x);
// Convert the result to a MicroPython integer object and return it
return mp_obj_new_int(result);
}
// Define a Python reference to the function above
STATIC MP_DEFINE_CONST_FUN_OBJ_1(factorial_obj, factorial);
// This is the entry point and is called when the module is imported
mp_obj_t mpy_init(mp_obj_fun_bc_t *self, size_t n_args, size_t n_kw, mp_obj_t *args) {
// This must be first, it sets up the globals dict and other things
MP_DYNRUNTIME_INIT_ENTRY
// Make the function available in the module's namespace
mp_store_global(MP_QSTR_factorial, MP_OBJ_FROM_PTR(&factorial_obj));
// This must be last, it restores the globals dict
MP_DYNRUNTIME_INIT_EXIT
}
The file ``Makefile`` contains:
.. code-block:: make
# Location of top-level MicroPython directory
MPY_DIR = ../../..
# Name of module
MOD = features0
# Source files (.c or .py)
SRC = features0.c
# Architecture to build for (x86, x64, armv7m, xtensa, xtensawin)
ARCH = x64
# Include to get the rules for compiling and linking the module
include $(MPY_DIR)/py/dynruntime.mk
Compiling the module
--------------------
Be sure to select the correct ``ARCH`` for the target you are going to run on.
Then build with::
$ make
Without modifying the Makefile you can specify the target architecture via::
$ make ARCH=armv7m
Module usage in MicroPython
---------------------------
Once the module is built there should be a file called ``factorial.mpy``. Copy
this so it is accessible on the filesystem of your MicroPython system and can be
found in the import path. The module con now be accessed in Python just like any
other module, for example::
import factorial
print(factorial.factorial(10))
# should display 3628800
Further examples
----------------
See ``examples/natmod/`` for further examples which show many of the available
features of native .mpy modules. Such features include:
* using multiple C source files
* including Python code alongside C code
* rodata and BSS data
* memory allocation
* use of floating point
* exception handling
* including external C libraries