:mod:`micropython` -- access and control MicroPython internals
.. module:: micropython :synopsis: access and control MicroPython internals
.. function:: const(expr)
Used to declare that the expression is a constant so that the compiler can
optimise it. The use of this function should be as follows::
from micropython import const
CONST_X = const(123)
CONST_Y = const(2 * CONST_X + 1)
Constants declared this way are still accessible as global variables from
outside the module they are declared in. On the other hand, if a constant
begins with an underscore then it is hidden, it is not available as a global
variable, and does not take up any memory during execution.
This `const` function is recognised directly by the MicroPython parser and is
provided as part of the :mod:`micropython` module mainly so that scripts can be
written which run under both CPython and MicroPython, by following the above
pattern.
.. function:: opt_level([level])
If *level* is given then this function sets the optimisation level for subsequent
compilation of scripts, and returns ``None``. Otherwise it returns the current
optimisation level.
The optimisation level controls the following compilation features:
- Assertions: at level 0 assertion statements are enabled and compiled into the
bytecode; at levels 1 and higher assertions are not compiled.
- Built-in ``__debug__`` variable: at level 0 this variable expands to ``True``;
at levels 1 and higher it expands to ``False``.
- Source-code line numbers: at levels 0, 1 and 2 source-code line number are
stored along with the bytecode so that exceptions can report the line number
they occurred at; at levels 3 and higher line numbers are not stored.
The default optimisation level is usually level 0.
.. function:: alloc_emergency_exception_buf(size) Allocate *size* bytes of RAM for the emergency exception buffer (a good size is around 100 bytes). The buffer is used to create exceptions in cases when normal RAM allocation would fail (eg within an interrupt handler) and therefore give useful traceback information in these situations. A good way to use this function is to put it at the start of your main script (eg ``boot.py`` or ``main.py``) and then the emergency exception buffer will be active for all the code following it.
.. function:: mem_info([verbose])
Print information about currently used memory. If the *verbose* argument
is given then extra information is printed.
The information that is printed is implementation dependent, but currently
includes the amount of stack and heap used. In verbose mode it prints out a
summary of the entire heap indicating which blocks are used and which are
free.
The exact output of verbose mode varies between ports, but in general each
letter represents a single 16 byte block of memory. Each line of
output represents 0x400 bytes or 1KiB of RAM.
The meaning of each letter:
====== =================
Symbol Meaning
====== =================
. free block
h head block
= tail block
m marked head block
T tuple
L list
D dict
F float
B byte code
M module
S string or bytes
A bytearray
====== =================
.. function:: qstr_info([verbose]) Print information about currently interned strings. If the *verbose* argument is given then extra information is printed. The information that is printed is implementation dependent, but currently includes the number of interned strings and the amount of RAM they use. In verbose mode it prints out the names of all RAM-interned strings.
.. function:: stack_use() Return an integer representing the current amount of stack that is being used. The absolute value of this is not particularly useful, rather it should be used to compute differences in stack usage at different points.
.. function:: heap_lock()
.. function:: heap_unlock()
.. function:: heap_locked() Lock or unlock the heap. When locked no memory allocation can occur and a `MemoryError` will be raised if any heap allocation is attempted. `heap_locked()` returns a true value if the heap is currently locked. These functions can be nested, ie `heap_lock()` can be called multiple times in a row and the lock-depth will increase, and then `heap_unlock()` must be called the same number of times to make the heap available again. Both `heap_unlock()` and `heap_locked()` return the current lock depth (after unlocking for the former) as a non-negative integer, with 0 meaning the heap is not locked. If the REPL becomes active with the heap locked then it will be forcefully unlocked. Note: `heap_locked()` is not enabled on most ports by default, requires ``MICROPY_PY_MICROPYTHON_HEAP_LOCKED``.
.. function:: kbd_intr(chr) Set the character that will raise a `KeyboardInterrupt` exception. By default this is set to 3 during script execution, corresponding to Ctrl-C. Passing -1 to this function will disable capture of Ctrl-C, and passing 3 will restore it. This function can be used to prevent the capturing of Ctrl-C on the incoming stream of characters that is usually used for the REPL, in case that stream is used for other purposes.
.. function:: schedule(func, arg)
Schedule the function *func* to be executed "very soon". The function
is passed the value *arg* as its single argument. "Very soon" means that
the MicroPython runtime will do its best to execute the function at the
earliest possible time, given that it is also trying to be efficient, and
that the following conditions hold:
- A scheduled function will never preempt another scheduled function.
- Scheduled functions are always executed "between opcodes" which means
that all fundamental Python operations (such as appending to a list)
are guaranteed to be atomic.
- A given port may define "critical regions" within which scheduled
functions will never be executed. Functions may be scheduled within
a critical region but they will not be executed until that region
is exited. An example of a critical region is a preempting interrupt
handler (an IRQ).
- Inside native code functions, scheduled functions are not called unless
the native code calls a function that specifically does so.
- Certain functions including ``poll.poll``, ``poll.ipoll``,
``time.sleep`` and ``time.sleep_ms`` (including zero-duration sleeps)
will call scheduled functions.
A use for this function is to schedule a callback from a preempting IRQ.
Such an IRQ puts restrictions on the code that runs in the IRQ (for example
the heap may be locked) and scheduling a function to call later will lift
those restrictions.
On multi-threaded ports, the scheduled function's behaviour depends on
whether the Global Interpreter Lock (GIL) is enabled for the specific port:
- If GIL is enabled, the function can preempt any thread and run in its
context.
- If GIL is disabled, the function will only preempt the main thread and run
in its context.
Note: If `schedule()` is called from a preempting IRQ, when memory
allocation is not allowed and the callback to be passed to `schedule()` is
a bound method, passing this directly will fail. This is because creating a
reference to a bound method causes memory allocation. A solution is to
create a reference to the method in the class constructor and to pass that
reference to `schedule()`. This is discussed in detail here
:ref:`reference documentation <isr_rules>` under "Creation of Python
objects".
There is a finite queue to hold the scheduled functions and `schedule()`
will raise a `RuntimeError` if the queue is full.
Provides a fixed-size ringbuffer for bytes with a stream interface. Can be considered like a fifo queue variant of io.BytesIO.
When created with integer size a suitable buffer will be allocated. Alternatively a bytearray or similar buffer protocol object can be provided to the constructor for in-place use.
The classic ringbuffer algorithm is used which allows for any size buffer
to be used however one byte will be consumed for tracking. If initialised
with an integer size this will be accounted for, for example RingIO(16)
will allocate a 17 byte buffer internally so it can hold 16 bytes of data.
When passing in a pre-allocated buffer however one byte less than its
original length will be available for storage, eg. RingIO(bytearray(16))
will only hold 15 bytes of data.
A RingIO instance can be IRQ / thread safe when used to pass data in a single direction eg. when written to in an IRQ and read from in a non-IRQ function (or vice versa). This does not hold if you try to eg. write to a single instance from both IRQ and non-IRQ code, this would often cause data corruption.
.. method:: RingIO.any() Returns an integer counting the number of characters that can be read... method:: RingIO.read([nbytes]) Read available characters. This is a non-blocking function. If ``nbytes`` is specified then read at most that many bytes, otherwise read as much data as possible. Return value: a bytes object containing the bytes read. Will be zero-length bytes object if no data is available... method:: RingIO.readline([nbytes]) Read a line, ending in a newline character or return if one exists in the buffer, else return available bytes in buffer. If ``nbytes`` is specified then read at most that many bytes. Return value: a bytes object containing the line read... method:: RingIO.readinto(buf[, nbytes]) Read available bytes into the provided ``buf``. If ``nbytes`` is specified then read at most that many bytes. Otherwise, read at most ``len(buf)`` bytes. Return value: Integer count of the number of bytes read into ``buf``... method:: RingIO.write(buf) Non-blocking write of bytes from ``buf`` into the ringbuffer, limited by the available space in the ringbuffer. Return value: Integer count of bytes written... method:: RingIO.close() No-op provided as part of standard `stream` interface. Has no effect on data in the ringbuffer.