Source code for gpiozero.devices

from __future__ import (
nstr = str
str = type('')

import atexit
import weakref
from collections import namedtuple
from itertools import chain
from types import FunctionType
from threading import RLock

from .threads import _threads_shutdown
from .mixins import (
from .exc import (

# Get a pin implementation to use as the default; we prefer RPi.GPIO's here
# as it supports PWM, and all Pi revisions. If no third-party libraries are
# available, however, we fall back to a pure Python implementation which
# supports platforms like PyPy
from .pins import _pins_shutdown
    from .pins.rpigpio import RPiGPIOPin
    DefaultPin = RPiGPIOPin
except ImportError:
        from .pins.rpio import RPIOPin
        DefaultPin = RPIOPin
    except ImportError:
            from .pins.pigipod import PiGPIOPin
            DefaultPin = PiGPIOPin
        except ImportError:
            from .pins.native import NativePin
            DefaultPin = NativePin

_PINS = set()
_PINS_LOCK = RLock() # Yes, this needs to be re-entrant

def _shutdown():
    with _PINS_LOCK:
        while _PINS:
    # Any cleanup routines registered by pins libraries must be called *after*
    # cleanup of pin objects used by devices


class GPIOMeta(type):
    # NOTE Yes, this is a metaclass. Don't be scared - it's a simple one.

    def __new__(mcls, name, bases, cls_dict):
        # Construct the class as normal
        cls = super(GPIOMeta, mcls).__new__(mcls, name, bases, cls_dict)
        # If there's a method in the class which has no docstring, search
        # the base classes recursively for a docstring to copy
        for attr_name, attr in cls_dict.items():
            if isinstance(attr, FunctionType) and not attr.__doc__:
                for base_cls in cls.__mro__:
                    if hasattr(base_cls, attr_name):
                        base_fn = getattr(base_cls, attr_name)
                        if base_fn.__doc__:
                            attr.__doc__ = base_fn.__doc__
        return cls

    def __call__(cls, *args, **kwargs):
        # Make sure cls has GPIOBase somewhere in its ancestry (otherwise
        # setting __attrs__ below will be rather pointless)
        assert issubclass(cls, GPIOBase)
        if issubclass(cls, SharedMixin):
            # If SharedMixin appears in the class' ancestry, convert the
            # constructor arguments to a key and check whether an instance
            # already exists. Only construct the instance if the key's new.
            key = cls._shared_key(*args, **kwargs)
                self = cls._INSTANCES[key]
                self._refs += 1
            except (KeyError, ReferenceError) as e:
                self = super(GPIOMeta, cls).__call__(*args, **kwargs)
                self._refs = 1
                # Replace the close method with one that merely decrements
                # the refs counter and calls the original close method when
                # it reaches zero
                old_close = self.close
                def close():
                    self._refs = max(0, self._refs - 1)
                    if not self._refs:
                                del cls._INSTANCES[key]
                            except KeyError:
                                # If the _refs go negative (too many closes)
                                # just ignore the resulting KeyError here -
                                # it's already gone
                self.close = close
                cls._INSTANCES[key] = weakref.proxy(self)
            # Construct the instance as normal
            self = super(GPIOMeta, cls).__call__(*args, **kwargs)
        # At this point __new__ and __init__ have all been run. We now fix the
        # set of attributes on the class by dir'ing the instance and creating a
        # frozenset of the result called __attrs__ (which is queried by
        # GPIOBase.__setattr__). An exception is made for SharedMixin devices
        # which can be constructed multiple times, returning the same instance
        if not issubclass(cls, SharedMixin) or self._refs == 1:
            self.__attrs__ = frozenset(dir(self))
        return self

# Cross-version compatible method of using a metaclass
class GPIOBase(GPIOMeta(nstr('GPIOBase'), (), {})):
    def __setattr__(self, name, value):
        # This overridden __setattr__ simply ensures that additional attributes
        # cannot be set on the class after construction (it manages this in
        # conjunction with the meta-class above). Traditionally, this is
        # managed with __slots__; however, this doesn't work with Python's
        # multiple inheritance system which we need to use in order to avoid
        # repeating the "source" and "values" property code in myriad places
        if hasattr(self, '__attrs__') and name not in self.__attrs__:
            raise AttributeError(
                "'%s' object has no attribute '%s'" % (
                self.__class__.__name__, name))
        return super(GPIOBase, self).__setattr__(name, value)

    def __del__(self):

    def close(self):
        Shut down the device and release all associated resources. This method
        can be called on an already closed device without raising an exception.

        This method is primarily intended for interactive use at the command
        line. It disables the device and releases its pin(s) for use by another

        You can attempt to do this simply by deleting an object, but unless
        you've cleaned up all references to the object this may not work (even
        if you've cleaned up all references, there's still no guarantee the
        garbage collector will actually delete the object at that point).  By
        contrast, the close method provides a means of ensuring that the object
        is shut down.

        For example, if you have a breadboard with a buzzer connected to pin
        16, but then wish to attach an LED instead:

            >>> from gpiozero import *
            >>> bz = Buzzer(16)
            >>> bz.on()
            >>> bz.close()
            >>> led = LED(16)
            >>> led.blink()

        :class:`Device` descendents can also be used as context managers using
        the :keyword:`with` statement. For example:

            >>> from gpiozero import *
            >>> with Buzzer(16) as bz:
            ...     bz.on()
            >>> with LED(16) as led:
            ...     led.on()
        # This is a placeholder which is simply here to ensure close() can be
        # safely called from subclasses without worrying whether super-class'
        # have it (which in turn is useful in conjunction with the SourceMixin
        # class).

    def closed(self):
        Returns ``True`` if the device is closed (see the :meth:`close`
        method). Once a device is closed you can no longer use any other
        methods or properties to control or query the device.
        raise NotImplementedError

    def _check_open(self):
        if self.closed:
            raise DeviceClosed(
                '%s is closed or uninitialized' % self.__class__.__name__)

    def __enter__(self):
        return self

    def __exit__(self, exc_type, exc_value, exc_tb):

[docs]class Device(ValuesMixin, GPIOBase): """ Represents a single device of any type; GPIO-based, SPI-based, I2C-based, etc. This is the base class of the device hierarchy. It defines the basic services applicable to all devices (specifically thhe :attr:`is_active` property, the :attr:`value` property, and the :meth:`close` method). """ def __repr__(self): return "<gpiozero.%s object>" % (self.__class__.__name__) @property def value(self): """ Returns a value representing the device's state. Frequently, this is a boolean value, or a number between 0 and 1 but some devices use larger ranges (e.g. -1 to +1) and composite devices usually use tuples to return the states of all their subordinate components. """ raise NotImplementedError @property def is_active(self): """ Returns ``True`` if the device is currently active and ``False`` otherwise. This property is usually derived from :attr:`value`. Unlike :attr:`value`, this is *always* a boolean. """ return bool(self.value)
[docs]class CompositeDevice(Device): """ Extends :class:`Device`. Represents a device composed of multiple devices like simple HATs, H-bridge motor controllers, robots composed of multiple motors, etc. The constructor accepts subordinate devices as positional or keyword arguments. Positional arguments form unnamed devices accessed via the :attr:`all` attribute, while keyword arguments are added to the device as named (read-only) attributes. :param list _order: If specified, this is the order of named items specified by keyword arguments (to ensure that the :attr:`value` tuple is constructed with a specific order). All keyword arguments *must* be included in the collection. If omitted, an alphabetically sorted order will be selected for keyword arguments. """ def __init__(self, *args, **kwargs): self._all = () self._named = {} self._namedtuple = None self._order = kwargs.pop('_order', None) if self._order is None: self._order = sorted(kwargs.keys()) self._order = tuple(self._order) for missing_name in set(kwargs.keys()) - set(self._order): raise CompositeDeviceBadOrder('%s missing from _order' % missing_name) super(CompositeDevice, self).__init__() for name in set(self._order) & set(dir(self)): raise CompositeDeviceBadName('%s is a reserved name' % name) self._all = args + tuple(kwargs[v] for v in self._order) for dev in self._all: if not isinstance(dev, Device): raise CompositeDeviceBadDevice("%s doesn't inherit from Device" % dev) self._named = kwargs self._namedtuple = namedtuple('%sValue' % self.__class__.__name__, chain( (str(i) for i in range(len(args))), self._order), rename=True) def __getattr__(self, name): # if _named doesn't exist yet, pretend it's an empty dict if name == '_named': return {} try: return self._named[name] except KeyError: raise AttributeError("no such attribute %s" % name) def __setattr__(self, name, value): # make named components read-only properties if name in self._named: raise AttributeError("can't set attribute %s" % name) return super(CompositeDevice, self).__setattr__(name, value) def __repr__(self): try: self._check_open() return "<gpiozero.%s object containing %d devices: %s and %d unnamed>" % ( self.__class__.__name__, len(self), ','.join(self._named), len(self) - len(self._named) ) except DeviceClosed: return "<gpiozero.%s object closed>" def __len__(self): return len(self._all) def __getitem__(self, index): return self._all[index] def __iter__(self): return iter(self._all) @property def all(self): # XXX Deprecate this in favour of using the instance as a container return self._all
[docs] def close(self): if self._all: for device in self._all: device.close()
@property def closed(self): return all(device.closed for device in self) @property def namedtuple(self): return self._namedtuple @property def value(self): return self.namedtuple(*(device.value for device in self)) @property def is_active(self): return any(self.value)
[docs]class GPIODevice(Device): """ Extends :class:`Device`. Represents a generic GPIO device and provides the services common to all single-pin GPIO devices (like ensuring two GPIO devices do no share a :attr:`pin`). :param int pin: The GPIO pin (in BCM numbering) that the device is connected to. If this is ``None``, :exc:`GPIOPinMissing` will be raised. If the pin is already in use by another device, :exc:`GPIOPinInUse` will be raised. """ def __init__(self, pin=None): super(GPIODevice, self).__init__() # self._pin must be set before any possible exceptions can be raised # because it's accessed in __del__. However, it mustn't be given the # value of pin until we've verified that it isn't already allocated self._pin = None if pin is None: raise GPIOPinMissing('No pin given') if isinstance(pin, int): pin = DefaultPin(pin) with _PINS_LOCK: if pin in _PINS: raise GPIOPinInUse( 'pin %r is already in use by another gpiozero object' % pin ) _PINS.add(pin) self._pin = pin self._active_state = True self._inactive_state = False def _read(self): try: return == self._active_state except (AttributeError, TypeError): self._check_open() raise
[docs] def close(self): super(GPIODevice, self).close() with _PINS_LOCK: pin = self._pin self._pin = None if pin in _PINS: _PINS.remove(pin) pin.close()
@property def closed(self): return self._pin is None def _check_open(self): try: super(GPIODevice, self)._check_open() except DeviceClosed as e: # For backwards compatibility; GPIODeviceClosed is deprecated raise GPIODeviceClosed(str(e)) @property def pin(self): """ The :class:`Pin` that the device is connected to. This will be ``None`` if the device has been closed (see the :meth:`close` method). When dealing with GPIO pins, query ``pin.number`` to discover the GPIO pin (in BCM numbering) that the device is connected to. """ return self._pin @property def value(self): return self._read() def __repr__(self): try: return "<gpiozero.%s object on pin %r, is_active=%s>" % ( self.__class__.__name__,, self.is_active) except DeviceClosed: return "<gpiozero.%s object closed>" % self.__class__.__name__