313 lines
9.9 KiB
Python
313 lines
9.9 KiB
Python
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# See docs/encoder.md for how to use
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import busio
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import digitalio
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from supervisor import ticks_ms
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from kmk.modules import Module
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# NB : not using rotaryio as it requires the pins to be consecutive
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class BaseEncoder:
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VELOCITY_MODE = True
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def __init__(self, is_inverted=False, divisor=4):
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self.is_inverted = is_inverted
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self.divisor = divisor
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self._state = None
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self._start_state = None
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self._direction = None
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self._pos = 0
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self._button_state = True
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self._button_held = None
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self._velocity = 0
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self._movement = 0
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self._timestamp = ticks_ms()
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# callback functions on events. Need to be defined externally
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self.on_move_do = None
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self.on_button_do = None
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def get_state(self):
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return {
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'direction': self.is_inverted and -self._direction or self._direction,
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'position': self.is_inverted and -self._pos or self._pos,
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'is_pressed': not self._button_state,
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'velocity': self._velocity,
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}
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# Called in a loop to refresh encoder state
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def update_state(self):
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# Rotation events
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new_state = (self.pin_a.get_value(), self.pin_b.get_value())
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if new_state != self._state:
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# encoder moved
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self._movement += 1
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# false / false and true / true are common half steps
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# looking on the step just before helps determining
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# the direction
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if new_state[0] == new_state[1] and self._state[0] != self._state[1]:
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if new_state[1] == self._state[0]:
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self._direction = 1
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else:
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self._direction = -1
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# when the encoder settles on a position (every 2 steps)
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if new_state[0] == new_state[1]:
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# an encoder returned to the previous
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# position halfway, cancel rotation
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if (
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self._start_state[0] == new_state[0]
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and self._start_state[1] == new_state[1]
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and self._movement <= 2
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):
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self._movement = 0
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self._direction = 0
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# when the encoder made a full loop according to its divisor
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elif self._movement >= self.divisor - 1:
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# 1 full step is 4 movements (2 for high-resolution encoder),
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# however, when rotated quickly, some steps may be missed.
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# This makes it behave more naturally
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real_movement = self._movement // self.divisor
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self._pos += self._direction * real_movement
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if self.on_move_do is not None:
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for i in range(real_movement):
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self.on_move_do(self.get_state())
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# Rotation finished, reset to identify new movement
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self._movement = 0
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self._direction = 0
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self._start_state = new_state
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self._state = new_state
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# Velocity
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self.velocity_event()
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# Button event
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self.button_event()
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def velocity_event(self):
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if self.VELOCITY_MODE:
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new_timestamp = ticks_ms()
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self._velocity = new_timestamp - self._timestamp
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self._timestamp = new_timestamp
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def button_event(self):
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raise NotImplementedError('subclasses must override button_event()!')
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# return knob velocity as milliseconds between position changes (detents)
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# for backwards compatibility
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def vel_report(self):
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# print(self._velocity)
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return self._velocity
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class GPIOEncoder(BaseEncoder):
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def __init__(self, pin_a, pin_b, pin_button=None, is_inverted=False, divisor=None):
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super().__init__(is_inverted)
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# Divisor can be 4 or 2 depending on whether the detent
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# on the encoder is defined by 2 or 4 pulses
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self.divisor = divisor
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self.pin_a = EncoderPin(pin_a)
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self.pin_b = EncoderPin(pin_b)
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self.pin_button = (
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EncoderPin(pin_button, button_type=True) if pin_button is not None else None
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)
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self._state = (self.pin_a.get_value(), self.pin_b.get_value())
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self._start_state = self._state
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def button_event(self):
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if self.pin_button:
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new_button_state = self.pin_button.get_value()
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if new_button_state != self._button_state:
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self._button_state = new_button_state
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if self.on_button_do is not None:
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self.on_button_do(self.get_state())
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class EncoderPin:
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def __init__(self, pin, button_type=False):
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self.pin = pin
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self.button_type = button_type
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self.prepare_pin()
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def prepare_pin(self):
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if self.pin is not None:
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self.io = digitalio.DigitalInOut(self.pin)
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self.io.direction = digitalio.Direction.INPUT
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self.io.pull = digitalio.Pull.UP
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else:
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self.io = None
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def get_value(self):
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return self.io.value
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class I2CEncoder(BaseEncoder):
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def __init__(self, i2c, address, is_inverted=False):
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try:
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from adafruit_seesaw import digitalio, neopixel, rotaryio, seesaw
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except ImportError:
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print('seesaw missing')
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return
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super().__init__(is_inverted)
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self.seesaw = seesaw.Seesaw(i2c, address)
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# Check for correct product
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seesaw_product = (self.seesaw.get_version() >> 16) & 0xFFFF
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if seesaw_product != 4991:
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print('Wrong firmware loaded? Expected 4991')
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self.encoder = rotaryio.IncrementalEncoder(self.seesaw)
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self.seesaw.pin_mode(24, self.seesaw.INPUT_PULLUP)
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self.switch = digitalio.DigitalIO(self.seesaw, 24)
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self.pixel = neopixel.NeoPixel(self.seesaw, 6, 1)
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self._state = self.encoder.position
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def update_state(self):
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# Rotation events
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new_state = self.encoder.position
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if new_state != self._state:
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# it moves !
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self._movement += 1
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# false / false and true / true are common half steps
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# looking on the step just before helps determining
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# the direction
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if self.encoder.position > self._state:
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self._direction = 1
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else:
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self._direction = -1
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self._state = new_state
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self.on_move_do(self.get_state())
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# Velocity
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self.velocity_event()
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# Button events
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self.button_event()
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def button_event(self):
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if not self.switch.value and not self._button_held:
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# Pressed
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self._button_held = True
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if self.on_button_do is not None:
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self.on_button_do(self.get_state())
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if self.switch.value and self._button_held:
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# Released
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self._button_held = False
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def get_state(self):
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return {
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'direction': self.is_inverted and -self._direction or self._direction,
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'position': self._state,
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'is_pressed': not self.switch.value,
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'is_held': self._button_held,
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'velocity': self._velocity,
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}
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class EncoderHandler(Module):
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def __init__(self):
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self.encoders = []
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self.pins = None
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self.map = None
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self.divisor = 4
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def on_runtime_enable(self, keyboard):
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return
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def on_runtime_disable(self, keyboard):
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return
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def during_bootup(self, keyboard):
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if self.pins and self.map:
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for idx, pins in enumerate(self.pins):
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try:
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# Check for busio.I2C
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if isinstance(pins[0], busio.I2C):
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new_encoder = I2CEncoder(*pins)
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# Else fall back to GPIO
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else:
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new_encoder = GPIOEncoder(*pins)
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# Set default divisor if unset
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if new_encoder.divisor is None:
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new_encoder.divisor = self.divisor
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# In our case, we need to define keybord and encoder_id for callbacks
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new_encoder.on_move_do = lambda x, bound_idx=idx: self.on_move_do(
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keyboard, bound_idx, x
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)
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new_encoder.on_button_do = (
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lambda x, bound_idx=idx: self.on_button_do(
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keyboard, bound_idx, x
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)
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)
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self.encoders.append(new_encoder)
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except Exception as e:
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print(e)
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return
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def on_move_do(self, keyboard, encoder_id, state):
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if self.map:
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layer_id = keyboard.active_layers[0]
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# if Left, key index 0 else key index 1
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if state['direction'] == -1:
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key_index = 0
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else:
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key_index = 1
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key = self.map[layer_id][encoder_id][key_index]
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keyboard.tap_key(key)
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def on_button_do(self, keyboard, encoder_id, state):
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if state['is_pressed'] is True:
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layer_id = keyboard.active_layers[0]
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key = self.map[layer_id][encoder_id][2]
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keyboard.tap_key(key)
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def before_matrix_scan(self, keyboard):
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'''
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Return value will be injected as an extra matrix update
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'''
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for encoder in self.encoders:
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encoder.update_state()
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return keyboard
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def after_matrix_scan(self, keyboard):
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'''
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Return value will be replace matrix update if supplied
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'''
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return
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def before_hid_send(self, keyboard):
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return
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def after_hid_send(self, keyboard):
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return
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def on_powersave_enable(self, keyboard):
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return
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def on_powersave_disable(self, keyboard):
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return
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