keybow2040/keybow2040.py

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# SPDX-FileCopyrightText: 2021 Sandy Macdonald
#
# SPDX-License-Identifier: MIT
"""
`Keybow 2040 CircuitPython library`
====================================================
CircuitPython driver for the Pimoroni Keybow 2040.
Drop the keybow2040.py file into your `lib` folder on your `CIRCUITPY` drive.
* Author: Sandy Macdonald
Notes
--------------------
**Hardware:**
* Pimoroni Keybow 2040
<https://shop.pimoroni.com/products/keybow-2040>_
**Software and Dependencies:**
* Adafruit CircuitPython firmware for Keybow 2040:
<https://circuitpython.org/board/pimoroni_keybow2040/>_
* Adafruit CircuitPython IS31FL3731 library:
<https://github.com/adafruit/Adafruit_CircuitPython_IS31FL3731>_
"""
import time
import board
from adafruit_is31fl3731.keybow2040 import Keybow2040 as Display
from digitalio import DigitalInOut, Direction, Pull
# These are the 16 switches on Keybow, with their board-defined names.
_PINS = [board.SW0,
board.SW1,
board.SW2,
board.SW3,
board.SW4,
board.SW5,
board.SW6,
board.SW7,
board.SW8,
board.SW9,
board.SW10,
board.SW11,
board.SW12,
board.SW13,
board.SW14,
board.SW15]
NUM_KEYS = 16
class Keybow2040(object):
"""
Represents a Keybow 2040 and hence a set of Key instances with
associated LEDs and key behaviours.
:param i2c: the I2C bus for Keybow 2040
"""
def __init__(self, i2c):
self.pins = _PINS
self.display = Display(i2c)
self.keys = []
self.time_of_last_press = time.monotonic()
self.time_since_last_press = None
self.led_sleep_enabled = False
self.led_sleep_time = 60
self.sleeping = False
self.was_asleep = False
self.last_led_states = None
# self.rotation = 0
for i in range(len(self.pins)):
_key = Key(i, self.pins[i], self.display)
self.keys.append(_key)
def update(self):
# Call this in each iteration of your while loop to update
# to update everything's state, e.g. `keybow.update()`
for _key in self.keys:
_key.update()
# Used to work out the sleep behaviour, by keeping track
# of the time of the last key press.
if self.any_pressed():
self.time_of_last_press = time.monotonic()
self.sleeping = False
self.time_since_last_press = time.monotonic() - self.time_of_last_press
# If LED sleep is enabled, but not engaged, check if enough time
# has elapsed to engage sleep. If engaged, record the state of the
# LEDs, so it can be restored on wake.
if self.led_sleep_enabled and not self.sleeping:
if time.monotonic() - self.time_of_last_press > self.led_sleep_time:
self.sleeping = True
self.last_led_states = [k.rgb if k.lit else [0, 0, 0] for k in self.keys]
self.set_all(0, 0, 0)
self.was_asleep = True
# If it was sleeping, but is no longer, then restore LED states.
if not self.sleeping and self.was_asleep:
for k in range(len(self.keys)):
self.keys[k].set_led(*self.last_led_states[k])
self.was_asleep = False
def set_led(self, number, r, g, b):
# Set an individual key's LED to an RGB value by its number.
self.keys[number].set_led(r, g, b)
def set_all(self, r, g, b):
# Set all of Keybow's LEDs to an RGB value.
if not self.sleeping:
for _key in self.keys:
_key.set_led(r, g, b)
else:
for _key in self.keys:
_key.led_off()
def get_states(self):
# Returns a Boolean list of Keybow's key states
# (0=not pressed, 1=pressed).
_states = [_key.state for _key in self.keys]
return _states
def get_pressed(self):
# Returns a list of key numbers currently pressed.
_pressed = [_key.number for _key in self.keys if _key.state == True]
return _pressed
def any_pressed(self):
# Returns True if any key is pressed, False if none are pressed.
if any(self.get_states()):
return True
else:
return False
def none_pressed(self):
# Returns True if none of the keys are pressed, False is any key
# is pressed.
if not any(self.get_states()):
return True
else:
return False
def on_press(self, _key, handler=None):
# Attaches a press function to a key, via a decorator. This is stored as
# `key.press_function` in the key's attributes, and run if necessary
# as part of the key's update function (and hence Keybow's update
# function). It can be attached as follows:
# @keybow.on_press(key)
# def press_handler(key, pressed):
# if pressed:
# do something
# else:
# do something else
if _key is None:
return
def attach_handler(handler):
_key.press_function = handler
if handler is not None:
attach_handler(handler)
else:
return attach_handler
def on_release(self, _key, handler=None):
# Attaches a release function to a key, via a decorator. This is stored
# as `key.release_function` in the key's attributes, and run if
# necessary as part of the key's update function (and hence Keybow's
# update function). It can be attached as follows:
# @keybow.on_release(key)
# def release_handler(key):
# do something
if _key is None:
return
def attach_handler(handler):
_key.release_function = handler
if handler is not None:
attach_handler(handler)
else:
return attach_handler
def on_hold(self, _key, handler=None):
# Attaches a hold unction to a key, via a decorator. This is stored as
# `key.hold_function` in the key's attributes, and run if necessary
# as part of the key's update function (and hence Keybow's update
# function). It can be attached as follows:
# @keybow.on_hold(key)
# def hold_handler(key):
# do something
if _key is None:
return
def attach_handler(handler):
_key.hold_function = handler
if handler is not None:
attach_handler(handler)
else:
return attach_handler
# def rotate(self, degrees):
# # Rotates all of Keybow's keys by a number of degrees, clamped to
# # the closest multiple of 90 degrees. Because it shuffles the order
# # of the Key instances, all of the associated attributes of the key
# # are retained. The x/y coordinate of the keys are rotated also. It
# # also handles negative degrees, e.g. -90 to rotate 90 degrees anti-
# # clockwise.
# # Rotate as follows: `keybow.rotate(270)`
# self.rotation = degrees
# num_rotations = degrees // 90
# if num_rotations == 0:
# return
# if num_rotations < 1:
# num_rotations = 4 + num_rotations
# matrix = [[(x * 4) + y for y in range(4)] for x in range(4)]
# for r in range(num_rotations):
# matrix = zip(*matrix[::-1])
# matrix = [list(x) for x in list(matrix)]
# flat_matrix = [x for y in matrix for x in y]
# for i in range(len(self.keys)):
# self.keys[i].number = flat_matrix[i]
# self.keys = sorted(self.keys, key=lambda x:x.number)
class Key:
"""
Represents a key on Keybow 2040, with associated switch and
LED behaviours.
:param number: the key number (0-15) to associate with the key
:param pin: the pin object for the key, e.g. board.SW0
:param display: the IS31FL3731 matrix instance for the LEDs
"""
def __init__(self, number, pin, display):
self.pin = pin
self.number = number
self.switch = DigitalInOut(self.pin)
self.switch.direction = Direction.INPUT
self.switch.pull = Pull.UP
self.state = 0
self.pressed = 0
self.last_state = None
self.time_of_last_press = time.monotonic()
self.time_since_last_press = None
self.time_held_for = 0
self.held = False
self.hold_time = 0.75
self.modifier = False
self.rgb = [0, 0, 0]
self.lit = False
self.xy = self.get_xy()
self.x, self.y = self.xy
self.display = display
self.led_off()
self.press_function = None
self.release_function = None
self.hold_function = None
self.press_func_fired = False
self.hold_func_fired = False
self.debounce = 0.125
self.key_locked = False
def get_state(self):
# Returns the state of the key (0=not pressed, 1=pressed).
return int(not self.switch.value)
def update(self):
# Updates the state of the key and updates all of its
# attributes.
self.time_since_last_press = time.monotonic() - self.time_of_last_press
# Keys get locked during the debounce time.
if self.time_since_last_press < self.debounce:
self.key_locked = True
else:
self.key_locked = False
self.state = self.get_state()
self.pressed = self.state
update_time = time.monotonic()
# If there's a `press_function` attached, then call it,
# returning the key object and the pressed state.
if self.press_function is not None and self.pressed and not self.press_func_fired and not self.key_locked:
self.press_function(self)
self.press_func_fired = True
# time.sleep(0.05) # A little debounce
# If the key has been pressed and releases, then call
# the `release_function`, if one is attached.
if not self.pressed and self.last_state == True:
if self.release_function is not None:
self.release_function(self)
self.last_state = False
self.press_func_fired = False
if not self.pressed:
self.time_held_for = 0
self.last_state = False
# If the key has just been pressed, then record the
# `time_of_last_press`, and update last_state.
elif self.pressed and self.last_state == False:
self.time_of_last_press = update_time
self.last_state = True
# If the key is pressed and held, then update the
# `time_held_for` variable.
elif self.pressed and self.last_state == True:
self.time_held_for = update_time - self.time_of_last_press
self.last_state = True
# If the `hold_time` theshold is crossed, then call the
# `hold_function` if one is attached. The `hold_func_fired`
# ensures that the function is only called once.
if self.time_held_for > self.hold_time:
self.held = True
if self.hold_function is not None and not self.hold_func_fired:
self.hold_function(self)
self.hold_func_fired = True
else:
self.held = False
self.hold_func_fired = False
def get_xy(self):
# Returns the x/y coordinate of a key from 0,0 to 3,3.
return number_to_xy(self.number)
def get_number(self):
# Returns the key number, from 0 to 15.
return xy_to_number(self.x, self.y)
def is_modifier(self):
# Designates a modifier key, so you can hold the modifier
# and tap another key to trigger additional behaviours.
if self.modifier:
return True
else:
return False
def set_led(self, r, g, b):
# Set this key's LED to an RGB value.
if [r, g, b] == [0, 0, 0]:
self.lit = False
else:
self.lit = True
self.rgb = [r, g, b]
self.display.pixelrgb(self.x, self.y, r, g, b)
def led_on(self):
# Turn the LED on, using its current RGB value.
r, g, b = self.rgb
self.set_led(r, g, b)
def led_off(self):
# Turn the LED off.
self.set_led(0, 0, 0)
def led_state(self, state):
# Set the LED's state (0=off, 1=on)
state = int(state)
if state == 0:
self.led_off()
elif state == 1:
self.led_on()
else:
return
def toggle_led(self, rgb=None):
# Toggle the LED's state, retaining its RGB value for when it's toggled
# back on. Can also be passed an RGB tuple to set the colour as part of
# the toggle.
if rgb is not None:
self.rgb = rgb
if self.lit:
self.led_off()
else:
self.led_on()
def __str__(self):
# When printed, show the key's state (0 or 1).
return self.state
def xy_to_number(x, y):
# Convert an x/y coordinate to key number.
return x + (y * 4)
def number_to_xy(number):
# Convert a number to an x/y coordinate.
x = number % 4
y = number // 4
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return (x, y)
def hsv_to_rgb(h, s, v):
# Convert an HSV (0.0-1.0) colour to RGB (0-255)
if s == 0.0:
rgb = [v, v, v]
i = int(h * 6.0)
f = (h*6.)-i; p,q,t = v*(1.-s), v*(1.-s*f), v*(1.-s*(1.-f)); i%=6
if i == 0:
rgb = [v, t, p]
if i == 1:
rgb = [q, v, p]
if i == 2:
rgb = [p, v, t]
if i == 3:
rgb = [p, q, v]
if i == 4:
rgb = [t, p, v]
if i == 5:
rgb = [v, p, q]
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rgb = tuple(int(c * 255) for c in rgb)
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return rgb