circuitpython/docs/library/machine.Signal.rst
Zenix27 e76c7466b6 docs: Change \* to * in argument lists.
Latest versions of Sphinx (at least 3.1.0) do not need the `*` escaped and
will render the `\` in the output if it is there, so remove it.

Fixes issue #6209.
2020-08-21 12:24:13 +10:00

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4.6 KiB
ReStructuredText

.. currentmodule:: machine
.. _machine.Signal:
class Signal -- control and sense external I/O devices
======================================================
The Signal class is a simple extension of the `Pin` class. Unlike Pin, which
can be only in "absolute" 0 and 1 states, a Signal can be in "asserted"
(on) or "deasserted" (off) states, while being inverted (active-low) or
not. In other words, it adds logical inversion support to Pin functionality.
While this may seem a simple addition, it is exactly what is needed to
support wide array of simple digital devices in a way portable across
different boards, which is one of the major MicroPython goals. Regardless
of whether different users have an active-high or active-low LED, a normally
open or normally closed relay - you can develop a single, nicely looking
application which works with each of them, and capture hardware
configuration differences in few lines in the config file of your app.
Example::
from machine import Pin, Signal
# Suppose you have an active-high LED on pin 0
led1_pin = Pin(0, Pin.OUT)
# ... and active-low LED on pin 1
led2_pin = Pin(1, Pin.OUT)
# Now to light up both of them using Pin class, you'll need to set
# them to different values
led1_pin.value(1)
led2_pin.value(0)
# Signal class allows to abstract away active-high/active-low
# difference
led1 = Signal(led1_pin, invert=False)
led2 = Signal(led2_pin, invert=True)
# Now lighting up them looks the same
led1.value(1)
led2.value(1)
# Even better:
led1.on()
led2.on()
Following is the guide when Signal vs Pin should be used:
* Use Signal: If you want to control a simple on/off (including software
PWM!) devices like LEDs, multi-segment indicators, relays, buzzers, or
read simple binary sensors, like normally open or normally closed buttons,
pulled high or low, Reed switches, moisture/flame detectors, etc. etc.
Summing up, if you have a real physical device/sensor requiring GPIO
access, you likely should use a Signal.
* Use Pin: If you implement a higher-level protocol or bus to communicate
with more complex devices.
The split between Pin and Signal come from the usecases above and the
architecture of MicroPython: Pin offers the lowest overhead, which may
be important when bit-banging protocols. But Signal adds additional
flexibility on top of Pin, at the cost of minor overhead (much smaller
than if you implemented active-high vs active-low device differences in
Python manually!). Also, Pin is a low-level object which needs to be
implemented for each support board, while Signal is a high-level object
which comes for free once Pin is implemented.
If in doubt, give the Signal a try! Once again, it is offered to save
developers from the need to handle unexciting differences like active-low
vs active-high signals, and allow other users to share and enjoy your
application, instead of being frustrated by the fact that it doesn't
work for them simply because their LEDs or relays are wired in a slightly
different way.
Constructors
------------
.. class:: Signal(pin_obj, invert=False)
Signal(pin_arguments..., *, invert=False)
Create a Signal object. There're two ways to create it:
* By wrapping existing Pin object - universal method which works for
any board.
* By passing required Pin parameters directly to Signal constructor,
skipping the need to create intermediate Pin object. Available on
many, but not all boards.
The arguments are:
- ``pin_obj`` is existing Pin object.
- ``pin_arguments`` are the same arguments as can be passed to Pin constructor.
- ``invert`` - if True, the signal will be inverted (active low).
Methods
-------
.. method:: Signal.value([x])
This method allows to set and get the value of the signal, depending on whether
the argument ``x`` is supplied or not.
If the argument is omitted then this method gets the signal level, 1 meaning
signal is asserted (active) and 0 - signal inactive.
If the argument is supplied then this method sets the signal level. The
argument ``x`` can be anything that converts to a boolean. If it converts
to ``True``, the signal is active, otherwise it is inactive.
Correspondence between signal being active and actual logic level on the
underlying pin depends on whether signal is inverted (active-low) or not.
For non-inverted signal, active status corresponds to logical 1, inactive -
to logical 0. For inverted/active-low signal, active status corresponds
to logical 0, while inactive - to logical 1.
.. method:: Signal.on()
Activate signal.
.. method:: Signal.off()
Deactivate signal.