from __future__ import ( unicode_literals, print_function, absolute_import, division, ) import warnings from time import sleep from threading import Lock from itertools import repeat from RPi import GPIO from .devices import ( GPIODeviceError, GPIODeviceClosed, GPIODevice, GPIOThread, CompositeDevice, SourceMixin, ) class OutputDeviceError(GPIODeviceError): pass class OutputDevice(SourceMixin, GPIODevice): """ Represents a generic GPIO output device. This class extends `GPIODevice` to add facilities common to GPIO output devices: an `on` method to switch the device on, and a corresponding `off` method. active_high: `True` If `True` (the default), the `on` method will set the GPIO to HIGH. If `False`, the `on` method will set the GPIO to LOW (the `off` method always does the opposite). """ def __init__(self, pin=None, active_high=True): self._active_high = active_high super(OutputDevice, self).__init__(pin) self._active_state = GPIO.HIGH if active_high else GPIO.LOW self._inactive_state = GPIO.LOW if active_high else GPIO.HIGH try: # NOTE: catch_warnings isn't thread-safe but hopefully no-one's # messing around with GPIO init within background threads... with warnings.catch_warnings(record=True) as w: GPIO.setup(pin, GPIO.OUT) # The only warning we want to squash is a RuntimeWarning that is # thrown when setting pins 2 or 3. Anything else should be replayed for warning in w: if warning.category != RuntimeWarning or pin not in (2, 3): warnings.showwarning( warning.message, warning.category, warning.filename, warning.lineno, warning.file, warning.line ) except: self.close() raise def _write(self, value): GPIO.output(self.pin, bool(value)) def on(self): """ Turns the device on. """ self._write(self._active_state) def off(self): """ Turns the device off. """ self._write(self._inactive_state) @property def value(self): return super(OutputDevice, self).value @value.setter def value(self, value): self._write(value) @property def active_high(self): return self._active_high def __repr__(self): try: return '' % ( self.__class__.__name__, self.pin, self.active_high, self.is_active) except: return super(OutputDevice, self).__repr__() class DigitalOutputDevice(OutputDevice): """ Represents a generic output device with typical on/off behaviour. This class extends `OutputDevice` with a `toggle` method to switch the device between its on and off states, and a `blink` method which uses an optional background thread to handle toggling the device state without further interaction. """ def __init__(self, pin=None, active_high=True): self._blink_thread = None super(DigitalOutputDevice, self).__init__(pin, active_high) self._lock = Lock() def close(self): self._stop_blink() super(DigitalOutputDevice, self).close() def on(self): """ Turns the device on. """ self._stop_blink() self._write(self._active_state) def off(self): """ Turns the device off. """ self._stop_blink() self._write(self._inactive_state) def toggle(self): """ Reverse the state of the device. If it's on, turn it off; if it's off, turn it on. """ with self._lock: if self.is_active: self.off() else: self.on() def blink(self, on_time=1, off_time=1, n=None, background=True): """ Make the device turn on and off repeatedly. on_time: `1` Number of seconds on off_time: `1` Number of seconds off n: `None` Number of times to blink; `None` means forever background: `True` If `True`, start a background thread to continue blinking and return immediately. If `False`, only return when the blink is finished (warning: the default value of n will result in this method never returning). """ self._stop_blink() self._blink_thread = GPIOThread( target=self._blink_led, args=(on_time, off_time, n) ) self._blink_thread.start() if not background: self._blink_thread.join() self._blink_thread = None def _stop_blink(self): if self._blink_thread: self._blink_thread.stop() self._blink_thread = None def _blink_led(self, on_time, off_time, n): iterable = repeat(0) if n is None else repeat(0, n) for i in iterable: self._write(self._active_state) if self._blink_thread.stopping.wait(on_time): break self._write(self._inactive_state) if self._blink_thread.stopping.wait(off_time): break class LED(DigitalOutputDevice): """ An LED (Light Emmitting Diode) component. A typical configuration of such a device is to connect a GPIO pin to the anode (long leg) of the LED, and the cathode (short leg) to ground, with an optional resistor to prevent the LED from burning out. """ pass LED.is_lit = LED.is_active class Buzzer(DigitalOutputDevice): """ A digital Buzzer component. A typical configuration of such a device is to connect a GPIO pin to the anode (long leg) of the buzzer, and the cathode (short leg) to ground. """ pass class PWMOutputDevice(DigitalOutputDevice): """ Generic Output device configured for PWM (Pulse-Width Modulation). """ def __init__(self, pin=None, frequency=100): self._pwm = None super(PWMOutputDevice, self).__init__(pin) try: self._pwm = GPIO.PWM(self.pin, frequency) self._pwm.start(0.0) self._frequency = frequency self._value = 0.0 except: self.close() raise def close(self): if self._pwm: # Ensure we wipe out the PWM object so that re-runs don't attempt # to re-stop the PWM thread (otherwise, the fact that close is # called from __del__ can easily result in us stopping the PWM # on *another* instance on the same pin) p = self._pwm self._pwm = None p.stop() super(PWMOutputDevice, self).close() def _read(self): return self._value def _write(self, value): if not 0 <= value <= 1: raise OutputDeviceError("PWM value must be between 0 and 1") self._pwm.ChangeDutyCycle(value * 100) self._value = value @property def value(self): """ The duty cycle of the PWM device. 0.0 is off, 1.0 is fully on. Values in between may be specified for varying levels of power in the device. """ return self._read() @value.setter def value(self, value): self._stop_blink() self._write(value) @property def is_active(self): """ Returns `True` if the device is currently active and `False` otherwise. """ return self.value > 0.0 @property def frequency(self): """ The frequency of the pulses used with the PWM device, in Hz. The default is 100. """ return self._frequency @frequency.setter def frequency(self, value): self._pwm.ChangeFrequency(value) self._frequency = value class PWMLED(PWMOutputDevice): """ An LED (Light Emmitting Diode) component with variable brightness. A typical configuration of such a device is to connect a GPIO pin to the anode (long leg) of the LED, and the cathode (short leg) to ground, with an optional resistor to prevent the LED from burning out. """ pass PWMLED.is_lit = PWMLED.is_active def _led_property(index, doc=None): return property( lambda self: getattr(self._leds[index], 'value'), lambda self, value: setattr(self._leds[index], 'value', value), doc ) class RGBLED(SourceMixin, CompositeDevice): """ Single LED with individually controllable red, green and blue components. red: `None` The GPIO pin that controls the red component of the RGB LED. green: `None` The GPIO pin that controls the green component of the RGB LED. blue: `None` The GPIO pin that controls the blue component of the RGB LED. """ def __init__(self, red=None, green=None, blue=None): if not all([red, green, blue]): raise OutputDeviceError('red, green, and blue pins must be provided') super(RGBLED, self).__init__() self._leds = tuple(PWMOutputDevice(pin) for pin in (red, green, blue)) red = _led_property(0) green = _led_property(1) blue = _led_property(2) @property def value(self): """ Represents the color of the LED as an RGB 3-tuple of `(red, green, blue)` where each value is between 0 and 1. For example, purple would be `(1, 0, 1)` and yellow would be `(1, 1, 0)`, while orange would be `(1, 0.5, 0)`. """ return (self.red, self.green, self.blue) @value.setter def value(self, value): self.red, self.green, self.blue = value @property def is_active(self): """ Returns `True` if the LED is currently active and `False` otherwise. """ return self.value != (0, 0, 0) color = value def on(self): """ Turn the device on. This equivalent to setting the device color to white `(1, 1, 1)`. """ self.value = (1, 1, 1) def off(self): """ Turn the device off. This is equivalent to setting the device color to black `(0, 0, 0)`. """ self.value = (0, 0, 0) def close(self): for led in self._leds: led.close() class Motor(SourceMixin, CompositeDevice): """ Generic bi-directional motor. """ def __init__(self, forward=None, backward=None): if not all([forward, backward]): raise OutputDeviceError('forward and back pins must be provided') super(Motor, self).__init__() self._forward = PWMOutputDevice(forward) self._backward = PWMOutputDevice(backward) @property def value(self): """ Represents the speed of the motor as a floating point value between -1 (full speed backward) and 1 (full speed forward). """ return self._forward.value - self._backward.value @value.setter def value(self, value): if not -1 <= value <= 1: raise OutputDeviceError("Motor value must be between -1 and 1") if value > 0: self.forward(value) elif value < 0: self.backward(-value) else: self.stop() @property def is_active(self): """ Returns `True` if the motor is currently active and `False` otherwise. """ return self.value != 0 def forward(self, speed=1): """ Drive the motor forwards """ self._backward.off() self._forward.value = speed def backward(self, speed=1): """ Drive the motor backwards """ self._forward.off() self._backward.value = speed def stop(self): """ Stop the motor """ self._forward.off() self._backward.off()