kmk_firmware/kmk/modules/split.py

'''Enables splitting keyboards wirelessly or wired'''
import busio
from micropython import const

from kmk.hid import HIDModes
from kmk.kmktime import ticks_diff, ticks_ms
from kmk.matrix import intify_coordinate
from kmk.modules import Module
from storage import getmount


class SplitSide:
    LEFT = const(1)
    RIGHT = const(2)


class SplitType:
    UART = const(1)
    I2C = const(2)  # unused
    ONEWIRE = const(3)  # unused
    BLE = const(4)


class Split(Module):
    '''Enables splitting keyboards wirelessly, or wired'''

    def __init__(
        self,
        split_flip=True,
        split_side=None,
        split_type=SplitType.UART,
        split_target_left=True,
        uart_interval=20,
        data_pin=None,
        data_pin2=None,
        target_left=True,
        uart_flip=True,
    ):
        self._is_target = True
        self._uart_buffer = []
        self.split_flip = split_flip
        self.split_side = split_side
        self.split_type = split_type
        self.split_target_left = split_target_left
        self.split_offset = None
        self.data_pin = data_pin
        self.data_pin2 = data_pin2
        self.target_left = target_left
        self.uart_flip = uart_flip
        self._is_target = True
        self._uart = None
        self._uart_interval = uart_interval
        self._debug_enabled = False
        if self.split_type == SplitType.BLE:
            try:
                from adafruit_ble import BLERadio
                from adafruit_ble.advertising.standard import (
                    ProvideServicesAdvertisement,
                )
                from adafruit_ble.services.nordic import UARTService

                self.ProvideServicesAdvertisement = ProvideServicesAdvertisement
                self.UARTService = UARTService
            except ImportError:
                pass  # BLE isn't supported on this platform
            self._ble = BLERadio()
            self._ble_last_scan = ticks_ms() - 5000
            self._connection_count = 0
            self._uart_connection = None
            self._advertisment = None
            self._advertising = False
            self._psave_enable = False

    def __repr__(self):
        return f'BLE_SPLIT({self._to_dict()})'

    def _to_dict(self):
        return {
            '_ble': self._ble,
            '_ble_last_scan': self._ble_last_scan,
            '_is_target': self._is_target,
            'uart_buffer': self._uart_buffer,
            '_split_flip': self.split_flip,
            '_split_side': self.split_side,
        }

    def during_bootup(self, keyboard):
        # Set up name for target side detection and BLE advertisment
        name = str(getmount('/').label)
        if self.split_type == SplitType.BLE:
            self._ble.name = name
        else:
            # Try to guess data pins if not supplied
            if not self.data_pin:
                self.data_pin = keyboard.data_pin

        # Detect split side from name
        if self.split_side is None:
            if name.endswith('L'):
                # If name ends in 'L' assume left and strip from name
                self._is_target = bool(self.split_target_left)
                self.split_side = SplitSide.LEFT
            elif name.endswith('R'):
                # If name ends in 'R' assume right and strip from name
                self._is_target = not bool(self.split_target_left)
                self.split_side = SplitSide.RIGHT

        # if split side was given, find master from split_side.
        elif self.split_side == SplitSide.LEFT:
            self._is_target = bool(self.split_target_left)
        elif self.split_side == SplitSide.RIGHT:
            self._is_target = not bool(self.split_target_left)

        # Flips the col pins if PCB is the same but flipped on right
        if self.split_flip and self.split_side == SplitSide.RIGHT:
            keyboard.col_pins = list(reversed(keyboard.col_pins))

        self.split_offset = len(keyboard.col_pins)

        if self.split_type == SplitType.UART and self.data_pin is not None:
            if self._is_target:
                self._uart = busio.UART(
                    tx=self.data_pin2, rx=self.data_pin, timeout=self._uart_interval
                )
            else:
                self._uart = busio.UART(
                    tx=self.data_pin, rx=self.data_pin2, timeout=self._uart_interval
                )

        # Attempt to sanely guess a coord_mapping if one is not provided.
        if not keyboard.coord_mapping:
            keyboard.coord_mapping = []

            rows_to_calc = len(keyboard.row_pins) * 2
            cols_to_calc = len(keyboard.col_pins) * 2

            for ridx in range(rows_to_calc):
                for cidx in range(cols_to_calc):
                    keyboard.coord_mapping.append(intify_coordinate(ridx, cidx))

    def before_matrix_scan(self, keyboard):
        if self.split_type == SplitType.BLE:
            self._check_all_connections(keyboard._hid_helper)
            self._receive_ble(keyboard)
        elif self.split_type == SplitType.UART:
            if self._is_target or self.data_pin2:
                self._receive_uart(keyboard)
        elif self.split_type == SplitType.ONEWIRE:
            pass  # Protocol needs written
        return

    def after_matrix_scan(self, keyboard):
        if keyboard.matrix_update:
            if self.split_type == SplitType.BLE:
                self._send_ble(keyboard.matrix_update)
            elif self.split_type == SplitType.UART and self.data_pin2:
                self._send_uart(keyboard.matrix_update)
            elif self.split_type == SplitType.ONEWIRE:
                pass  # Protocol needs written

        return

    def before_hid_send(self, keyboard):
        return

    def after_hid_send(self, keyboard):
        return

    def on_powersave_enable(self, keyboard):
        if self.split_type == SplitType.BLE:
            if self._uart_connection and not self._psave_enable:
                self._uart_connection.connection_interval = self._uart_interval
                self._psave_enable = True

    def on_powersave_disable(self, keyboard):
        if self.split_type == SplitType.BLE:
            if self._uart_connection and self._psave_enable:
                self._uart_connection.connection_interval = 11.25
                self._psave_enable = False

    def _check_all_connections(self, hid_type):
        '''Validates the correct number of BLE connections'''
        self._connection_count = len(self._ble.connections)
        if self._is_target and hid_type == HIDModes.BLE and self._connection_count < 2:
            self._target_advertise()
        elif not self._is_target and self._connection_count < 1:
            self._initiator_scan()

    def _initiator_scan(self):
        '''Scans for target device'''
        self._uart = None
        self._uart_connection = None
        # See if any existing connections are providing UARTService.
        self._connection_count = len(self._ble.connections)
        if self._connection_count > 0 and not self._uart:
            for connection in self._ble.connections:
                if self.UARTService in connection:
                    self._uart_connection = connection
                    self._uart_connection.connection_interval = 11.25
                    self._uart = self._uart_connection[self.UARTService]
                    break

        if not self._uart:
            if self._debug_enabled:
                print('Scanning')
            self._ble.stop_scan()
            for adv in self._ble.start_scan(
                self.ProvideServicesAdvertisement, timeout=20
            ):
                if self._debug_enabled:
                    print('Scanning')
                if self.UARTService in adv.services and adv.rssi > -70:
                    self._uart_connection = self._ble.connect(adv)
                    self._uart_connection.connection_interval = 11.25
                    self._uart = self._uart_connection[self.UARTService]
                    self._ble.stop_scan()
                    if self._debug_enabled:
                        print('Scan complete')
                    break
        self._ble.stop_scan()

    def _target_advertise(self):
        '''Advertises the target for the initiator to find'''
        self._ble.stop_advertising()
        if self._debug_enabled:
            print('Advertising')
        # Uart must not change on this connection if reconnecting
        if not self._uart:
            self._uart = self.UARTService()
        advertisement = self.ProvideServicesAdvertisement(self._uart)

        self._ble.start_advertising(advertisement)

        self.ble_time_reset()
        while not self.ble_rescan_timer():
            self._connection_count = len(self._ble.connections)
            if self._connection_count > 1:
                self.ble_time_reset()
                if self._debug_enabled:
                    print('Advertising complete')
                break
        self._ble.stop_advertising()

    def ble_rescan_timer(self):
        '''If true, the rescan timer is up'''
        return bool(ticks_diff(ticks_ms(), self._ble_last_scan) > 5000)

    def ble_time_reset(self):
        '''Resets the rescan timer'''
        self._ble_last_scan = ticks_ms()

    def _send_ble(self, update):
        if self._uart:
            try:
                if not self._is_target:
                    update[1] += self.split_offset
                self._uart.write(update)
            except OSError:
                try:
                    self._uart.disconnect()
                except:  # noqa: E722
                    if self._debug_enabled:
                        print('UART disconnect failed')

                if self._debug_enabled:
                    print('Connection error')
                self._uart_connection = None
                self._uart = None

    def _receive_ble(self, keyboard):
        if self._uart is not None and self._uart.in_waiting > 0 or self._uart_buffer:
            while self._uart.in_waiting >= 3:
                self._uart_buffer.append(self._uart.read(3))
            if self._uart_buffer:
                keyboard.secondary_matrix_update = bytearray(self._uart_buffer.pop(0))
                return

    def _send_uart(self, update):
        # Change offsets depending on where the data is going to match the correct
        # matrix location of the receiever
        if self._is_target:
            if self.split_target_left:
                update[1] += self.split_offset
            else:
                update[1] -= self.split_offset
        else:
            if self.split_target_left:
                update[1] -= self.split_offset
            else:
                update[1] += self.split_offset

        if self._uart is not None:
            self._uart.write(update)

    def _receive_uart(self, keyboard):
        if self._uart is not None and self._uart.in_waiting > 0 or self._uart_buffer:
            if self._uart.in_waiting >= 60:
                # This is a dirty hack to prevent crashes in unrealistic cases
                import microcontroller

                microcontroller.reset()

            while self._uart.in_waiting >= 3:
                self._uart_buffer.append(self._uart.read(3))
            if self._uart_buffer:
                keyboard.secondary_matrix_update = bytearray(self._uart_buffer.pop(0))

                return
feat(extensions): most of the extensions implementation, by kdb424 2020-10-21 21:19:42 +02:00			`'''Enables splitting keyboards wirelessly or wired'''`
			`import busio`
			`from micropython import const`

			`from kmk.hid import HIDModes`
			`from kmk.kmktime import ticks_diff, ticks_ms`
			`from kmk.matrix import intify_coordinate`
			`from kmk.modules import Module`
			`from storage import getmount`


			`class SplitSide:`
			`LEFT = const(1)`
			`RIGHT = const(2)`


			`class SplitType:`
			`UART = const(1)`
			`I2C = const(2) # unused`
			`ONEWIRE = const(3) # unused`
			`BLE = const(4)`


			`class Split(Module):`
			`'''Enables splitting keyboards wirelessly, or wired'''`

			`def __init__(`
			`self,`
			`split_flip=True,`
			`split_side=None,`
			`split_type=SplitType.UART,`
			`split_target_left=True,`
			`uart_interval=20,`
			`data_pin=None,`
			`data_pin2=None,`
			`target_left=True,`
			`uart_flip=True,`
			`):`
			`self._is_target = True`
			`self._uart_buffer = []`
			`self.split_flip = split_flip`
			`self.split_side = split_side`
			`self.split_type = split_type`
			`self.split_target_left = split_target_left`
			`self.split_offset = None`
			`self.data_pin = data_pin`
			`self.data_pin2 = data_pin2`
			`self.target_left = target_left`
			`self.uart_flip = uart_flip`
			`self._is_target = True`
			`self._uart = None`
			`self._uart_interval = uart_interval`
			`self._debug_enabled = False`
			`if self.split_type == SplitType.BLE:`
			`try:`
			`from adafruit_ble import BLERadio`
			`from adafruit_ble.advertising.standard import (`
			`ProvideServicesAdvertisement,`
			`)`
			`from adafruit_ble.services.nordic import UARTService`

			`self.ProvideServicesAdvertisement = ProvideServicesAdvertisement`
			`self.UARTService = UARTService`
			`except ImportError:`
			`pass # BLE isn't supported on this platform`
			`self._ble = BLERadio()`
			`self._ble_last_scan = ticks_ms() - 5000`
			`self._connection_count = 0`
			`self._uart_connection = None`
			`self._advertisment = None`
			`self._advertising = False`
			`self._psave_enable = False`

			`def __repr__(self):`
			`return f'BLE_SPLIT({self._to_dict()})'`

			`def _to_dict(self):`
			`return {`
			`'_ble': self._ble,`
			`'_ble_last_scan': self._ble_last_scan,`
			`'_is_target': self._is_target,`
			`'uart_buffer': self._uart_buffer,`
			`'_split_flip': self.split_flip,`
			`'_split_side': self.split_side,`
			`}`

			`def during_bootup(self, keyboard):`
			`# Set up name for target side detection and BLE advertisment`
			`name = str(getmount('/').label)`
			`if self.split_type == SplitType.BLE:`
			`self._ble.name = name`
			`else:`
			`# Try to guess data pins if not supplied`
			`if not self.data_pin:`
			`self.data_pin = keyboard.data_pin`

			`# Detect split side from name`
			`if self.split_side is None:`
			`if name.endswith('L'):`
			`# If name ends in 'L' assume left and strip from name`
			`self._is_target = bool(self.split_target_left)`
			`self.split_side = SplitSide.LEFT`
			`elif name.endswith('R'):`
			`# If name ends in 'R' assume right and strip from name`
			`self._is_target = not bool(self.split_target_left)`
			`self.split_side = SplitSide.RIGHT`

			`# if split side was given, find master from split_side.`
			`elif self.split_side == SplitSide.LEFT:`
			`self._is_target = bool(self.split_target_left)`
			`elif self.split_side == SplitSide.RIGHT:`
			`self._is_target = not bool(self.split_target_left)`

			`# Flips the col pins if PCB is the same but flipped on right`
			`if self.split_flip and self.split_side == SplitSide.RIGHT:`
			`keyboard.col_pins = list(reversed(keyboard.col_pins))`

			`self.split_offset = len(keyboard.col_pins)`

			`if self.split_type == SplitType.UART and self.data_pin is not None:`
			`if self._is_target:`
			`self._uart = busio.UART(`
			`tx=self.data_pin2, rx=self.data_pin, timeout=self._uart_interval`
			`)`
			`else:`
			`self._uart = busio.UART(`
			`tx=self.data_pin, rx=self.data_pin2, timeout=self._uart_interval`
			`)`

			`# Attempt to sanely guess a coord_mapping if one is not provided.`
			`if not keyboard.coord_mapping:`
			`keyboard.coord_mapping = []`

			`rows_to_calc = len(keyboard.row_pins) * 2`
			`cols_to_calc = len(keyboard.col_pins) * 2`

			`for ridx in range(rows_to_calc):`
			`for cidx in range(cols_to_calc):`
			`keyboard.coord_mapping.append(intify_coordinate(ridx, cidx))`

			`def before_matrix_scan(self, keyboard):`
			`if self.split_type == SplitType.BLE:`
			`self._check_all_connections(keyboard._hid_helper)`
			`self._receive_ble(keyboard)`
			`elif self.split_type == SplitType.UART:`
			`if self._is_target or self.data_pin2:`
			`self._receive_uart(keyboard)`
			`elif self.split_type == SplitType.ONEWIRE:`
			`pass # Protocol needs written`
			`return`

			`def after_matrix_scan(self, keyboard):`
			`if keyboard.matrix_update:`
			`if self.split_type == SplitType.BLE:`
			`self._send_ble(keyboard.matrix_update)`
			`elif self.split_type == SplitType.UART and self.data_pin2:`
			`self._send_uart(keyboard.matrix_update)`
			`elif self.split_type == SplitType.ONEWIRE:`
			`pass # Protocol needs written`

			`return`

			`def before_hid_send(self, keyboard):`
			`return`

			`def after_hid_send(self, keyboard):`
			`return`

			`def on_powersave_enable(self, keyboard):`
			`if self.split_type == SplitType.BLE:`
			`if self._uart_connection and not self._psave_enable:`
			`self._uart_connection.connection_interval = self._uart_interval`
			`self._psave_enable = True`

			`def on_powersave_disable(self, keyboard):`
			`if self.split_type == SplitType.BLE:`
			`if self._uart_connection and self._psave_enable:`
			`self._uart_connection.connection_interval = 11.25`
			`self._psave_enable = False`

			`def _check_all_connections(self, hid_type):`
			`'''Validates the correct number of BLE connections'''`
			`self._connection_count = len(self._ble.connections)`
			`if self._is_target and hid_type == HIDModes.BLE and self._connection_count < 2:`
			`self._target_advertise()`
			`elif not self._is_target and self._connection_count < 1:`
			`self._initiator_scan()`

			`def _initiator_scan(self):`
			`'''Scans for target device'''`
			`self._uart = None`
			`self._uart_connection = None`
			`# See if any existing connections are providing UARTService.`
			`self._connection_count = len(self._ble.connections)`
			`if self._connection_count > 0 and not self._uart:`
			`for connection in self._ble.connections:`
			`if self.UARTService in connection:`
			`self._uart_connection = connection`
			`self._uart_connection.connection_interval = 11.25`
			`self._uart = self._uart_connection[self.UARTService]`
			`break`

			`if not self._uart:`
			`if self._debug_enabled:`
			`print('Scanning')`
			`self._ble.stop_scan()`
			`for adv in self._ble.start_scan(`
			`self.ProvideServicesAdvertisement, timeout=20`
			`):`
			`if self._debug_enabled:`
			`print('Scanning')`
			`if self.UARTService in adv.services and adv.rssi > -70:`
			`self._uart_connection = self._ble.connect(adv)`
			`self._uart_connection.connection_interval = 11.25`
			`self._uart = self._uart_connection[self.UARTService]`
			`self._ble.stop_scan()`
			`if self._debug_enabled:`
			`print('Scan complete')`
			`break`
			`self._ble.stop_scan()`

			`def _target_advertise(self):`
			`'''Advertises the target for the initiator to find'''`
			`self._ble.stop_advertising()`
			`if self._debug_enabled:`
			`print('Advertising')`
			`# Uart must not change on this connection if reconnecting`
			`if not self._uart:`
			`self._uart = self.UARTService()`
			`advertisement = self.ProvideServicesAdvertisement(self._uart)`

			`self._ble.start_advertising(advertisement)`

			`self.ble_time_reset()`
			`while not self.ble_rescan_timer():`
			`self._connection_count = len(self._ble.connections)`
			`if self._connection_count > 1:`
			`self.ble_time_reset()`
			`if self._debug_enabled:`
			`print('Advertising complete')`
			`break`
			`self._ble.stop_advertising()`

			`def ble_rescan_timer(self):`
			`'''If true, the rescan timer is up'''`
			`return bool(ticks_diff(ticks_ms(), self._ble_last_scan) > 5000)`

			`def ble_time_reset(self):`
			`'''Resets the rescan timer'''`
			`self._ble_last_scan = ticks_ms()`

			`def _send_ble(self, update):`
			`if self._uart:`
			`try:`
			`if not self._is_target:`
			`update[1] += self.split_offset`
			`self._uart.write(update)`
			`except OSError:`
			`try:`
			`self._uart.disconnect()`
			`except: # noqa: E722`
			`if self._debug_enabled:`
			`print('UART disconnect failed')`

			`if self._debug_enabled:`
			`print('Connection error')`
			`self._uart_connection = None`
			`self._uart = None`

			`def _receive_ble(self, keyboard):`
			`if self._uart is not None and self._uart.in_waiting > 0 or self._uart_buffer:`
			`while self._uart.in_waiting >= 3:`
			`self._uart_buffer.append(self._uart.read(3))`
			`if self._uart_buffer:`
			`keyboard.secondary_matrix_update = bytearray(self._uart_buffer.pop(0))`
			`return`

			`def _send_uart(self, update):`
			`# Change offsets depending on where the data is going to match the correct`
			`# matrix location of the receiever`
			`if self._is_target:`
			`if self.split_target_left:`
			`update[1] += self.split_offset`
			`else:`
			`update[1] -= self.split_offset`
			`else:`
			`if self.split_target_left:`
			`update[1] -= self.split_offset`
			`else:`
			`update[1] += self.split_offset`

			`if self._uart is not None:`
			`self._uart.write(update)`

			`def _receive_uart(self, keyboard):`
			`if self._uart is not None and self._uart.in_waiting > 0 or self._uart_buffer:`
			`if self._uart.in_waiting >= 60:`
			`# This is a dirty hack to prevent crashes in unrealistic cases`
			`import microcontroller`

			`microcontroller.reset()`

			`while self._uart.in_waiting >= 3:`
			`self._uart_buffer.append(self._uart.read(3))`
			`if self._uart_buffer:`
			`keyboard.secondary_matrix_update = bytearray(self._uart_buffer.pop(0))`

			`return`