2017-12-10 17:06:38 -05:00
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Distribution packages, package management, and deploying applications
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=====================================================================
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Just as the "big" Python, MicroPython supports creation of "third party"
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packages, distributing them, and easily installing them in each user's
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environment. This chapter discusses how these actions are achieved.
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Some familiarity with Python packaging is recommended.
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Overview
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--------
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Steps below represent a high-level workflow when creating and consuming
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packages:
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1. Python modules and packages are turned into distribution package
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archives, and published at the Python Package Index (PyPI).
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2. `upip` package manager can be used to install a distribution package
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on a `MicroPython port` with networking capabilities (for example,
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on the Unix port).
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3. For ports without networking capabilities, an "installation image"
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can be prepared on the Unix port, and transferred to a device by
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suitable means.
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4. For low-memory ports, the installation image can be frozen as the
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bytecode into MicroPython executable, thus minimizing the memory
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storage overheads.
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The sections below describe this process in details.
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Distribution packages
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---------------------
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Python modules and packages can be packaged into archives suitable for
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transfer between systems, storing at the well-known location (PyPI),
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and downloading on demand for deployment. These archives are known as
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*distribution packages* (to differentiate them from Python packages
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(means to organize Python source code)).
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The MicroPython distribution package format is a well-known tar.gz
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format, with some adaptations however. The Gzip compressor, used as
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an external wrapper for TAR archives, by default uses 32KB dictionary
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size, which means that to uncompress a compressed stream, 32KB of
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contguous memory needs to be allocated. This requirement may be not
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satisfiable on low-memory devices, which may have total memory available
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less than that amount, and even if not, a contiguous block like that
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may be hard to allocate due to `memory fragmentation`. To accommodate
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these constraints, MicroPython distribution packages use Gzip compression
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with the dictionary size of 4K, which should be a suitable compromise
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with still achieving some compression while being able to uncompressed
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even by the smallest devices.
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Besides the small compression dictionary size, MicroPython distribution
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packages also have other optimizations, like removing any files from
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the archive which aren't used by the installation process. In particular,
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`upip` package manager doesn't execute ``setup.py`` during installation
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(see below), and thus that file is not included in the archive.
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At the same time, these optimizations make MicroPython distribution
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packages not compatible with `CPython`'s package manager, ``pip``.
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This isn't considered a big problem, because:
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1. Packages can be installed with `upip`, and then can be used with
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CPython (if they are compatible with it).
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2. In the other direction, majority of CPython packages would be
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incompatible with MicroPython by various reasons, first of all,
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the reliance on features not implemented by MicroPython.
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Summing up, the MicroPython distribution package archives are highly
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optimized for MicroPython's target environments, which are highly
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resource constrained devices.
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``upip`` package manager
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------------------------
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MicroPython distribution packages are intended to be installed using
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the `upip` package manager. `upip` is a Python application which is
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usually distributed (as frozen bytecode) with network-enabled
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`MicroPython ports <MicroPython port>`. At the very least,
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`upip` is available in the `MicroPython Unix port`.
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On any `MicroPython port` providing `upip`, it can be accessed as
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following::
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import upip
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upip.help()
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upip.install(package_or_package_list, [path])
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Where *package_or_package_list* is the name of a distribution
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package to install, or a list of such names to install multiple
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packages. Optional *path* parameter specifies filesystem
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location to install under and defaults to the standard library
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location (see below).
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An example of installing a specific package and then using it::
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>>> import upip
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>>> upip.install("micropython-pystone_lowmem")
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[...]
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>>> import pystone_lowmem
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>>> pystone_lowmem.main()
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Note that the name of Python package and the name of distribution
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package for it in general don't have to match, and oftentimes they
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don't. This is because PyPI provides a central package repository
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for all different Python implementations and versions, and thus
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distribution package names may need to be namespaced for a particular
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implementation. For example, all packages from `micropython-lib`
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follow this naming convention: for a Python module or package named
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``foo``, the distribution package name is ``micropython-foo``.
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For the ports which run MicroPython executable from the OS command
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prompts (like the Unix port), `upip` can be (and indeed, usually is)
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run from the command line instead of MicroPython's own REPL. The
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commands which corresponds to the example above are::
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micropython -m upip -h
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micropython -m upip install [-p <path>] <packages>...
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micropython -m upip install micropython-pystone_lowmem
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[TODO: Describe installation path.]
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Cross-installing packages
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-------------------------
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For `MicroPython ports <MicroPython port>` without native networking
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capabilities, the recommend process is "cross-installing" them into a
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"directory image" using the `MicroPython Unix port`, and then
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transferring this image to a device by suitable means.
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Installing to a directory image involves using ``-p`` switch to `upip`::
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2017-12-16 03:37:36 -05:00
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micropython -m upip install -p install_dir micropython-pystone_lowmem
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After this command, the package content (and contents of every depenency
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packages) will be available in the ``install_dir/`` subdirectory. You
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would need to transfer contents of this directory (without the
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``install_dir/`` prefix) to the device, at the suitable location, where
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it can be found by the Python ``import`` statement (see discussion of
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the `upip` installation path above).
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Cross-installing packages with freezing
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---------------------------------------
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For the low-memory `MicroPython ports <MicroPython port>`, the process
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described in the previous section does not provide the most efficient
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resource usage,because the packages are installed in the source form,
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so need to be compiled to the bytecome on each import. This compilation
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requires RAM, and the resulting bytecode is also stored in RAM, reducing
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its amount available for storing application data. Moreover, the process
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above requires presence of the filesystem on a device, and the most
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resource-constrained devices may not even have it.
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The bytecode freezing is a process which resolves all the issues
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mentioned above:
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* The source code is pre-compiled into bytecode and store as such.
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* The bytecode is stored in ROM, not RAM.
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* Filesystem is not required for frozen packages.
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Using frozen bytecode requires building the executable (firmware)
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for a given `MicroPython port` from the C source code. Consequently,
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the process is:
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1. Follow the instructions for a particular port on setting up a
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toolchain and building the port. For example, for ESP8266 port,
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study instructions in ``ports/esp8266/README.md`` and follow them.
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Make sure you can build the port and deploy the resulting
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executable/firmware successfully before proceeding to the next steps.
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2. Build `MicroPython Unix port` and make sure it is in your PATH and
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you can execute ``micropython``.
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3. Change to port's directory (e.g. ``ports/esp8266/`` for ESP8266).
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4. Run ``make clean-frozen``. This step cleans up any previous
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modules which were installed for freezing (consequently, you need
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to skip this step to add additional modules, instead of starting
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from scratch).
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5. Run ``micropython -m upip install -p modules <packages>...`` to
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install packages you want to freeze.
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6. Run ``make clean``.
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7. Run ``make``.
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After this, you should have the executable/firmware with modules as
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the bytecode inside, which you can deploy the usual way.
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Few notes:
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1. Step 5 in the sequence above assumes that the distribution package
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is available from PyPI. If that is not the case, you would need
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to copy Python source files manually to ``modules/`` subdirectory
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of the port port directory. (Note that upip does not support
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installing from e.g. version control repositories).
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2. The firmware for baremetal devices usually has size restrictions,
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so adding too many frozen modules may overflow it. Usually, you
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would get a linking error if this happens. However, in some cases,
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an image may be produced, which is not runnable on a device. Such
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cases are in general bugs, and should be reported and further
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investigated. If you face such a situation, as an initial step,
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you may want to decrease the amount of frozen modules included.
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2017-12-12 17:12:37 -05:00
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Creating distribution packages
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------------------------------
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Distribution packages for MicroPython are created in the same manner
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as for CPython or any other Python implementation, see references at
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the end of chapter. "Source distribution" (sdist) format is used for
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packaging. The post-processing discussed above, (and pre-processing
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discussed in the following section) is achieved by using custom
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"sdist" command for distutils/setuptools. Thus, packaging steps
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remain the same as for standard distutils/setuptools, the user just
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need to override "sdist" command implementation by passing the
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appropriate argument to ``setup()`` call::
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from setuptools import setup
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import sdist_upip
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setup(
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...,
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cmdclass={'sdist': sdist_upip.sdist}
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)
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The sdist_upip.py module as referenced above can be found in
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`micropython-lib`:
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https://github.com/micropython/micropython-lib/blob/master/sdist_upip.py
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2017-12-10 17:06:38 -05:00
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Application resources
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---------------------
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A complete application, besides the source code, oftentimes also consists
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of data files, e.g. web page templates, game images, etc. It's clear how
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to deal with those when application is installed manually - you just put
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those data files in the filesystem at some location and use the normal
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file access functions.
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The situation is different when deploying applications from packages - this
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is more advanced, streamlined and flexible way, but also requires more
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advanced approach to accessing data files. This approach is treating
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the data files as "resources", and abstracting away access to them.
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Python supports resource access using its "setuptools" library, using
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``pkg_resources`` module. MicroPython, following its usual approach,
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implements subset of the functionality of that module, specifically
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`pkg_resources.resource_stream(package, resource)` function.
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The idea is that an application calls this function, passing a
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resource identifier, which is a relative path to data file within
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the specified package (usually top-level application package). It
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returns a stream object which can be used to access resource contents.
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Thus, the ``resource_stream()`` emulates interface of the standard
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`open()` function.
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Implementation-wise, ``resource_stream()`` uses file operations
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underlyingly, if distribution package is install in the filesystem.
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However, it also supports functioning without the underlying filesystem,
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e.g. if the package is frozen as the bytecode. This however requires
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an extra intermediate step when packaging application - creation of
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"Python resource module".
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The idea of this module is to convert binary data to a Python bytes
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object, and put it into the dictionary, indexed by the resource name.
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This conversion is done automatically using overridden ``sdist`` command
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described in the previous section.
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Let's trace the complete process using the following example. Suppose
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your application has the following structure::
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my_app/
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__main__.py
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utils.py
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data/
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page.html
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image.png
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``__main__.py`` and ``utils.py`` should access resources using the
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following calls::
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import pkg_resources
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pkg_resources.resource_stream(__name__, "data/page.html")
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pkg_resources.resource_stream(__name__, "data/image.png")
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You can develop and debug using the `MicroPython Unix port` as usual.
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When time comes to make a distribution package out of it, just use
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overridden "sdist" command from sdist_upip.py module as described in
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the previous section.
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2017-12-14 11:28:10 -05:00
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This will create a Python resource module named ``R.py``, based on the
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files declared in ``MANIFEST`` or ``MANIFEST.in`` files (any non-``.py``
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file will be considered a resource and added to ``R.py``) - before
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proceeding with the normal packaging steps.
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Prepared like this, your application will work both when deployed to
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filesystem and as frozen bytecode.
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2017-12-14 11:28:10 -05:00
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If you would like to debug ``R.py`` creation, you can run::
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python3 setup.py sdist --manifest-only
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Alternatively, you can use tools/mpy_bin2res.py script from the
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MicroPython distribution, in which can you will need to pass paths
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to all resource files::
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mpy_bin2res.py data/page.html data/image.png
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2017-12-10 17:06:38 -05:00
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References
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----------
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* Python Packaging User Guide: https://packaging.python.org/
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* Setuptools documentation: https://setuptools.readthedocs.io/
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* Distutils documentation: https://docs.python.org/3/library/distutils.html
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