A system without a (full-fledged) operating system, for example an MCU-based system. When running on a baremetal system, MicroPython effectively functions like a small operating system, running user programs and providing a command interpreter (REPL).
- buffer protocol
Any Python object that can be automatically converted into bytes, such as
strobjects, which all implement the “buffer protocol”.
Typically this refers to a printed circuit board (PCB) containing a microcontroller and supporting components. MicroPython firmware is typically provided per-board, as the firmware contains both MCU-specific functionality but also board-level functionality such as drivers or pin names.
A compact representation of a Python program that generated by compiling the Python source code. This is what the VM actually executes. Bytecode is typically generated automatically at runtime and is invisible to the user. Note that while CPython and MicroPython both use bytecode, the format is different. You can also pre-compile source code offline using the cross-compiler.
- callee-owned tuple
This is a MicroPython-specific construct where, for efficiency reasons, some built-in functions or methods may re-use the same underlying tuple object to return data. This avoids having to allocate a new tuple for every call, and reduces heap fragmentation. Programs should not hold references to callee-owned tuples and instead only extract data from them (or make a copy).
A variant of MicroPython developed by Adafruit Industries.
CPython is the reference implementation of the Python programming language, and the most well-known one. It is, however, one of many implementations (including Jython, IronPython, PyPy, and MicroPython). While MicroPython’s implementation differs substantially from CPython, it aims to maintain as much compatibility as possible.
Also known as
mpy-cross. This tool runs on your PC and converts a .py file containing MicroPython code into a .mpy file containing MicroPython bytecode. This means it loads faster (the board doesn’t have to compile the code), and uses less space on flash (the bytecode is more space efficient).
A MicroPython library that implements support for a particular component, such as a sensor or display.
Acronym for Foreign Function Interface. A mechanism used by the MicroPython Unix port to access operating system functionality. This is not available on baremetal ports.
Most MicroPython ports and boards provide a filesystem stored in flash that is available to user code via the standard Python file APIs such as
open(). Some boards also make this internal filesystem accessible to the host via USB mass-storage.
- frozen module
A Python module that has been cross compiled and bundled into the firmware image. This reduces RAM requirements as the code is executed directly from flash.
- Garbage Collector
A background process that runs in Python (and MicroPython) to reclaim unused memory in the heap.
General-purpose input/output. The simplest means to control electrical signals (commonly referred to as “pins”) on a microcontroller. GPIO typically allows pins to be either input or output, and to set or get their digital value (logical “0” or “1”). MicroPython abstracts GPIO access using the
- GPIO port
A group of GPIO pins, usually based on hardware properties of these pins (e.g. controllable by the same register).
A region of RAM where MicroPython stores dynamic data. It is managed automatically by the Garbage Collector. Different MCUs and boards have vastly different amounts of RAM available for the heap, so this will affect how complex your program can be.
- interned string
An optimisation used by MicroPython to improve the efficiency of working with strings. An interned string is referenced by its (unique) identity rather than its address and can therefore be quickly compared just by its identifier. It also means that identical strings can be de-duplicated in memory. String interning is almost always invisible to the user.
Microcontroller. Microcontrollers usually have much less resources than a desktop, laptop, or phone, but are smaller, cheaper and require much less power. MicroPython is designed to be small and optimized enough to run on an average modern microcontroller.
- MicroPython port
MicroPython supports different boards, RTOSes, and OSes, and can be relatively easily adapted to new systems. MicroPython with support for a particular system is called a “port” to that system. Different ports may have widely different functionality. This documentation is intended to be a reference of the generic APIs available across different ports (“MicroPython core”). Note that some ports may still omit some APIs described here (e.g. due to resource constraints). Any such differences, and port-specific extensions beyond the MicroPython core functionality, would be described in the separate port-specific documentation.
- MicroPython Unix port
The unix port is one of the major MicroPython ports. It is intended to run on POSIX-compatible operating systems, like Linux, MacOS, FreeBSD, Solaris, etc. It also serves as the basis of Windows port. The Unix port is very useful for quick development and testing of the MicroPython language and machine-independent features. It can also function in a similar way to CPython’s
- .mpy file
The output of the cross-compiler. A compiled form of a .py file that contains MicroPython bytecode instead of Python source code.
Usually refers to “native code”, i.e. machine code for the target microcontroller (such as ARM Thumb, Xtensa, x86/x64). The
@nativedecorator can be applied to a MicroPython function to generate native code instead of bytecode for that function, which will likely be faster but use more RAM.
Usually short for MicroPython port, but could also refer to GPIO port.
- .py file
A file containing Python source code.
An acronym for “Read, Eval, Print, Loop”. This is the interactive Python prompt, useful for debugging or testing short snippets of code. Most MicroPython boards make a REPL available over a UART, and this is typically accessible on a host PC via USB.
Also known as a “file-like object”. An Python object which provides sequential read-write access to the underlying data. A stream object implements a corresponding interface, which consists of methods like
close(), etc. A stream is an important concept in MicroPython; many I/O objects implement the stream interface, and thus can be used consistently and interchangeably in different contexts. For more information on streams in MicroPython, see the
Acronym for “Universal Asynchronous Receiver/Transmitter”. This is a peripheral that sends data over a pair of pins (TX & RX). Many boards include a way to make at least one of the UARTs available to a host PC as a serial port over USB.