.. _micropython:
===========
Micropython
===========
What is Micropython?
--------------------
`Micropython <http://micropython.org/>`__ is Python for
microcontrollers. Using Micropython, you can write Python3 code and run
it even on a bare metal architecture with limited resources.
Highlights of Micropython
~~~~~~~~~~~~~~~~~~~~~~~~~
- **Compact**: Fits and runs within just 256k of code space and 16k of RAM. No OS is needed, although you
can also run it with an OS, if you want.
- **Compatible**: Strives to be as compatible as possible with normal Python (known as CPython).
- **Versatile**: Supports many architectures (x86, x86-64, ARM, ARM Thumb, Xtensa).
- **Interactive**: No need for the compile-flash-boot cycle. With the REPL (interactive prompt) you can type
commands and execute them immediately, run scripts, etc.
- **Popular**: Many platforms are supported. The user base is growing bigger. Notable forks:
- `MicroPython <https://github.com/micropython/micropython>`__
- `CircuitPython <https://github.com/adafruit/circuitpython>`__
- `MicroPython_ESP32_psRAM_LoBo <https://github.com/loboris/MicroPython_ESP32_psRAM_LoBo>`__
- **Embedded Oriented**: Comes with modules specifically for embedded systems, such as the
`machine module <https://docs.micropython.org/en/latest/library/machine.html#classes>`__
for accessing low-level hardware (I/O pins, ADC, UART, SPI, I2C, RTC, Timers etc.)
--------------
Why Micropython + LVGL?
-----------------------
Micropython `does not have a good native high-level GUI library <https://forum.micropython.org/viewtopic.php?f=18&t=5543>`__.
LVGL is an `Object-Oriented Component Based <https://blog.lvgl.io/2018-12-13/extend-lvgl-objects>`__
high-level GUI library, which seems to be a natural candidate to map into a higher level language, such as Python.
LVGL is implemented in C and its APIs are in C.
Here are some advantages of using LVGL in Micropython:
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Develop GUI in Python, a very popular high level language. Use paradigms such as Object-Oriented Programming.
- Usually, GUI development requires multiple iterations to get things right. With C, each iteration consists of
**``Change code`` > ``Build`` > ``Flash`` > ``Run``**. In Micropython it's just
**``Change code`` > ``Run``** ! You can even run commands interactively using the
`REPL <https://en.wikipedia.org/wiki/Read%E2%80%93eval%E2%80%93print_loop>`__ (the interactive prompt)
Micropython + LVGL could be used for:
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Fast prototyping GUI.
- Shortening the cycle of changing and fine-tuning the GUI.
- Modelling the GUI in a more abstract way by defining reusable composite objects, taking advantage of Python's language features
such as Inheritance, Closures, List Comprehension, Generators, Exception Handling, Arbitrary Precision Integers and others.
- Make LVGL accessible to a larger audience. No need to know C to create a nice GUI on an embedded system. This goes well with
`CircuitPython vision <https://learn.adafruit.com/welcome-to-circuitpython/what-is-circuitpython>`__.
CircuitPython was designed with education in mind, to make it easier for new or inexperienced users to get started with
embedded development.
- Creating tools to work with LVGL at a higher level (e.g. drag-and-drop designer).
--------------
So what does it look like?
--------------------------
It's very much like the C API, but Object-Oriented for LVGL components.
Let's dive right into an example!
A simple example
~~~~~~~~~~~~~~~~
.. code:: python
# Initialize
import display_driver
import lvgl as lv
# Create a button with a label
scr = lv.obj()
btn = lv.button(scr)
btn.align(lv.ALIGN.CENTER, 0, 0)
label = lv.label(btn)
label.set_text('Hello World!')
lv.screen_load(scr)
How can I use it?
-----------------
Online Simulator
~~~~~~~~~~~~~~~~
If you want to experiment with LVGL + Micropython without downloading
anything - you can use our online simulator! It's a fully functional
LVGL + Micropython that runs entirely in the browser and allows you to
edit a python script and run it.
`Click here to experiment on the online simulator <https://sim.lvgl.io/>`__
Many `LVGL examples <https://docs.lvgl.io/master/examples.html>`__ are available also for Micropython. Just click the link!
PC Simulator
~~~~~~~~~~~~
Micropython is ported to many platforms. One notable port is "unix", which allows you to build and run Micropython
(+LVGL) on a Linux machine. (On a Windows machine you might need Virtual Box or WSL or MinGW or Cygwin etc.)
`Click here to know more information about building and running the unix port <https://github.com/lvgl/lv_micropython>`__
Embedded Platforms
~~~~~~~~~~~~~~~~~~
In the end, the goal is to run it all on an embedded platform. Both Micropython and LVGL can be used on many embedded
architectures. `lv_micropython <https://github.com/lvgl/lv_micropython>`__ is a fork of Micropython+LVGL and currently
supports Linux, ESP32, STM32 and RP2. It can be ported to any other platform supported by Micropython.
- You would also need display and input drivers. You can either use one of the existing drivers provided with lv_micropython,
or you can create your own input/display drivers for your specific hardware.
- Drivers can be implemented either in C as a Micropython module, or in pure Python!
lv_micropython already contains these drivers:
- Display drivers:
- SDL on Linux
- X11 on Linux
- ESP32 specific:
- ILI9341
- ILI9488
- GC9A01
- ST7789
- ST7735
- Generic (pure Python):
- ILI9341
- ST7789
- ST7735
- Input drivers:
- SDL
- X11
- XPT2046
- FT6X36
- ESP32 ADC with resistive touch
Where can I find more information?
----------------------------------
- ``lv_micropython`` `README <https://github.com/lvgl/lv_micropython>`__
- ``lv_binding_micropython`` `README <https://github.com/lvgl/lv_binding_micropython>`__
- The `LVGL micropython forum <https://forum.lvgl.io/c/micropython>`__ (Feel free to ask anything!)
- At Micropython: `docs <http://docs.micropython.org/en/latest/>`__ and `forum <https://forum.micropython.org/>`__
- `Blog Post <https://blog.lvgl.io/2019-02-20/micropython-bindings>`__, a little outdated.
The Micropython Binding is auto generated!
------------------------------------------
- LVGL is a git submodule inside `lv_micropython <https://github.com/lvgl/lv_micropython>`__
(LVGL is a git submodule of `lv_binding_micropython <https://github.com/lvgl/lv_binding_micropython>`__
which is itself a submodule of `lv_micropython <https://github.com/lvgl/lv_micropython>`__).
- When building lv_micropython, the public LVGL C API is scanned and Micropython API is auto-generated. That means that
lv_micropython provides LVGL API for **any** LVGL version, and generally does not require code changes as LVGL evolves.
LVGL C API Coding Conventions
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For a summary of coding conventions to follow see the `CODING STYLE <CODING_STYLE>`__.
.. _memory_management:
Memory Management
~~~~~~~~~~~~~~~~~
| When LVGL runs in Micropython, all dynamic memory allocations (:cpp:func:`lv_malloc`) are handled by Micropython's memory
manager which is `garbage-collected <https://en.wikipedia.org/wiki/Garbage_collection_(computer_science)>`__ (GC).
| To prevent GC from collecting memory prematurely, all dynamic allocated RAM must be reachable by GC.
| GC is aware of most allocations, except from pointers on the `Data Segment <https://en.wikipedia.org/wiki/Data_segment>`__:
- Pointers which are global variables
- Pointers which are static global variables
- Pointers which are static local variables
Such pointers need to be defined in a special way to make them reachable by GC
Identify The Problem
^^^^^^^^^^^^^^^^^^^^
Problem happens when an allocated memory's pointer (return value of :cpp:func:`lv_malloc`) is stored only in either **global**,
**static global** or **static local** pointer variable and not as part of a previously allocated ``struct`` or other variable.
Solve The Problem
^^^^^^^^^^^^^^^^^
- Replace the global/static local var with :cpp:expr:`(LV_GLOBAL_DEFAULT()->_var)`
- Include ``lv_global.h`` on files that use ``LV_GLOBAL_DEFAULT``
- Add ``_var`` to ``lv_global_t`` on ``lv_global.h``
Example
^^^^^^^
More Information
^^^^^^^^^^^^^^^^
- `In the README <https://github.com/lvgl/lv_binding_micropython#memory-management>`__
- `In the Blog <https://blog.lvgl.io/2019-02-20/micropython-bindings#i-need-to-allocate-a-littlevgl-struct-such-as-style-color-etc-how-can-i-do-that-how-do-i-allocatedeallocate-memory-for-it>`__
.. _callbacks:
Callbacks
~~~~~~~~~
In C a callback is just a function pointer. But in Micropython we need to register a *Micropython callable object* for each
callback. Therefore in the Micropython binding we need to register both a function pointer and a Micropython object for every callback.
Therefore we defined a **callback convention** for the LVGL C API that expects lvgl headers to be defined in a certain
way. Callbacks that are declared according to the convention would allow the binding to register a Micropython object
next to the function pointer when registering a callback, and access that object when the callback is called.
- The basic idea is that we have ``void * user_data`` field that is used automatically by the Micropython Binding
to save the *Micropython callable object* for a callback. This field must be provided when registering the function
pointer, and provided to the callback function itself.
- Although called "user_data", the user is not expected to read/write that field. Instead, the Micropython glue code uses
``user_data`` to automatically keep track of the Micropython callable object. The glue code updates it when the callback
is registered, and uses it when the callback is called in order to invoke a call to the original callable object.
There are a few options for defining a callback in LVGL C API:
- Option 1: ``user_data`` in a struct
- There's a struct that contains a field called ``void * user_data``
- A pointer to that struct is provided as the **first** argument of a callback registration function
- A pointer to that struct is provided as the **first** argument of the callback itself
- Option 2: ``user_data`` as a function argument
- A parameter called ``void * user_data`` is provided to the registration function as the **last** argument
- The callback itself receives ``void *`` as the **last** argument
- Option 3: both callback and ``user_data`` are struct fields
- The API exposes a struct with both function pointer member and ``user_data`` member
- The function pointer member receives the same struct as its **first** argument
In practice it's also possible to mix these options, for example provide a struct pointer when registering a callback
(option 1) and provide ``user_data`` argument when calling the callback (options 2),
**as long as the same ``user_data`` that was registered is passed to the callback when it's called**.
Examples
^^^^^^^^
- :cpp:type:`lv_anim_t` contains ``user_data`` field. :cpp:func:`lv_anim_set_path_cb`
registers `path_cb` callback. Both ``lv_anim_set_path_cb`` and :cpp:type:`lv_anim_path_cb_t`
receive :cpp:type:`lv_anim_t` as their first argument
- ``path_cb`` field can also be assigned directly in the Python code because it's a member
of :cpp:type:`lv_anim_t` which contains ``user_data`` field, and :cpp:type:`lv_anim_path_cb_t`
receive :cpp:type:`lv_anim_t` as its first argument.
- :cpp:func:`lv_imgfont_create` registers ``path_cb`` and receives ``user_data`` as the last
argument. The callback :cpp:type:`lv_imgfont_get_path_cb_t` also receives the ``user_data`` as the last argument.
.. _more-information-1:
More Information
^^^^^^^^^^^^^^^^
- In the `Blog <https://blog.lvgl.io/2019-08-05/micropython-pure-display-driver#using-callbacks>`__
and in the `README <https://github.com/lvgl/lv_binding_micropython#callbacks>`__
- `[v6.0] Callback conventions #1036 <https://github.com/lvgl/lvgl/issues/1036>`__
- Various discussions: `here <https://github.com/lvgl/lvgl/pull/3294#issuecomment-1184895335>`__
and `here <https://github.com/lvgl/lvgl/issues/1763#issuecomment-762247629>`__
and`here <https://github.com/lvgl/lvgl/issues/316#issuecomment-467221587>`__