micropython-ili9341/xpt2046.py

"""XPT2046 Touch module."""
from time import sleep


class Touch(object):
    """Serial interface for XPT2046 Touch Screen Controller."""

    # Command constants from ILI9341 datasheet
    GET_X = const(0b11010000)  # X position
    GET_Y = const(0b10010000)  # Y position
    GET_Z1 = const(0b10110000)  # Z1 position
    GET_Z2 = const(0b11000000)  # Z2 position
    GET_TEMP0 = const(0b10000000)  # Temperature 0
    GET_TEMP1 = const(0b11110000)  # Temperature 1
    GET_BATTERY = const(0b10100000)  # Battery monitor
    GET_AUX = const(0b11100000)  # Auxiliary input to ADC

    def __init__(self, spi, cs, int_pin=None, int_handler=None,
                 width=240, height=320,
                 x_min=100, x_max=1962, y_min=100, y_max=1900):
        """Initialize touch screen controller.

        Args:
            spi (Class Spi):  SPI interface for OLED
            cs (Class Pin):  Chip select pin
            int_pin (Class Pin):  Touch controller interrupt pin
            int_handler (function): Handler for screen interrupt
            width (int): Width of LCD screen
            height (int): Height of LCD screen
            x_min (int): Minimum x coordinate
            x_max (int): Maximum x coordinate
            y_min (int): Minimum Y coordinate
            y_max (int): Maximum Y coordinate
        """
        self.spi = spi
        self.cs = cs
        self.cs.init(self.cs.OUT, value=1)
        self.rx_buf = bytearray(3)  # Receive buffer
        self.tx_buf = bytearray(3)  # Transmit buffer
        self.width = width
        self.height = height
        # Set calibration
        self.x_min = x_min
        self.x_max = x_max
        self.y_min = y_min
        self.y_max = y_max
        self.x_multiplier = width / (x_max - x_min)
        self.x_add = x_min * -self.x_multiplier
        self.y_multiplier = height / (y_max - y_min)
        self.y_add = y_min * -self.y_multiplier

        if int_pin is not None:
            self.int_pin = int_pin
            self.int_pin.init(int_pin.IN)
            self.int_handler = int_handler
            self.int_locked = False
            int_pin.irq(trigger=int_pin.IRQ_FALLING | int_pin.IRQ_RISING,
                        handler=self.int_press)

    def get_touch(self):
        """Take multiple samples to get accurate touch reading."""
        timeout = 2  # set timeout to 2 seconds
        confidence = 5
        buff = [[0, 0] for x in range(confidence)]
        buf_length = confidence  # Require a confidence of 5 good samples
        buffptr = 0  # Track current buffer position
        nsamples = 0  # Count samples
        while timeout > 0:
            if nsamples == buf_length:
                meanx = sum([c[0] for c in buff]) // buf_length
                meany = sum([c[1] for c in buff]) // buf_length
                dev = sum([(c[0] - meanx)**2 +
                          (c[1] - meany)**2 for c in buff]) / buf_length
                if dev <= 50:  # Deviation should be under margin of 50
                    return self.normalize(meanx, meany)
            # get a new value
            sample = self.raw_touch()  # get a touch
            if sample is None:
                nsamples = 0    # Invalidate buff
            else:
                buff[buffptr] = sample  # put in buff
                buffptr = (buffptr + 1) % buf_length  # Incr, until rollover
                nsamples = min(nsamples + 1, buf_length)  # Incr. until max

            sleep(.05)
            timeout -= .05
        return None
#

    def int_press(self, pin):
        """Send X,Y values to passed interrupt handler."""
        if not pin.value() and not self.int_locked:
            self.int_locked = True  # Lock Interrupt
            buff = self.raw_touch()

            if buff is not None:
                x, y = self.normalize(*buff)
                self.int_handler(x, y)
            sleep(.1)  # Debounce falling edge
        elif pin.value() and self.int_locked:
            sleep(.1)  # Debounce rising edge
            self.int_locked = False  # Unlock interrupt
            return

    def normalize(self, x, y):
        """Normalize mean X,Y values to match LCD screen."""
        x = int(self.x_multiplier * x + self.x_add)
        y = int(self.y_multiplier * y + self.y_add)
        return x, y

    def raw_touch(self):
        """Read raw X,Y touch values.

        Returns:
            tuple(int, int): X, Y
        """
        x = self.send_command(self.GET_X)
        y = self.send_command(self.GET_Y)
        if self.x_min <= x <= self.x_max and self.y_min <= y <= self.y_max:
            return (x, y)
        else:
            return None

    def send_command(self, command):
        """Write command to XT2046 (MicroPython).

        Args:
            command (byte): XT2046 command code.
        Returns:
            int: 12 bit response
        """
        self.tx_buf[0] = command
        self.cs(0)
        self.spi.write_readinto(self.tx_buf, self.rx_buf)
        self.cs(1)

        return (self.rx_buf[1] << 4) | (self.rx_buf[2] >> 4)
Initial commit 5 years ago			`"""XPT2046 Touch module."""`
			`from time import sleep`


			`class Touch(object):`
			`"""Serial interface for XPT2046 Touch Screen Controller."""`

			`# Command constants from ILI9341 datasheet`
			`GET_X = const(0b11010000) # X position`
			`GET_Y = const(0b10010000) # Y position`
			`GET_Z1 = const(0b10110000) # Z1 position`
			`GET_Z2 = const(0b11000000) # Z2 position`
			`GET_TEMP0 = const(0b10000000) # Temperature 0`
			`GET_TEMP1 = const(0b11110000) # Temperature 1`
			`GET_BATTERY = const(0b10100000) # Battery monitor`
			`GET_AUX = const(0b11100000) # Auxiliary input to ADC`

			`def __init__(self, spi, cs, int_pin=None, int_handler=None,`
			`width=240, height=320,`
			`x_min=100, x_max=1962, y_min=100, y_max=1900):`
			`"""Initialize touch screen controller.`

			`Args:`
			`spi (Class Spi): SPI interface for OLED`
			`cs (Class Pin): Chip select pin`
			`int_pin (Class Pin): Touch controller interrupt pin`
			`int_handler (function): Handler for screen interrupt`
			`width (int): Width of LCD screen`
			`height (int): Height of LCD screen`
			`x_min (int): Minimum x coordinate`
			`x_max (int): Maximum x coordinate`
			`y_min (int): Minimum Y coordinate`
			`y_max (int): Maximum Y coordinate`
			`"""`
			`self.spi = spi`
			`self.cs = cs`
			`self.cs.init(self.cs.OUT, value=1)`
			`self.rx_buf = bytearray(3) # Receive buffer`
			`self.tx_buf = bytearray(3) # Transmit buffer`
			`self.width = width`
			`self.height = height`
			`# Set calibration`
			`self.x_min = x_min`
			`self.x_max = x_max`
			`self.y_min = y_min`
			`self.y_max = y_max`
			`self.x_multiplier = width / (x_max - x_min)`
			`self.x_add = x_min * -self.x_multiplier`
			`self.y_multiplier = height / (y_max - y_min)`
			`self.y_add = y_min * -self.y_multiplier`

			`if int_pin is not None:`
			`self.int_pin = int_pin`
			`self.int_pin.init(int_pin.IN)`
			`self.int_handler = int_handler`
			`self.int_locked = False`
			`int_pin.irq(trigger=int_pin.IRQ_FALLING \| int_pin.IRQ_RISING,`
			`handler=self.int_press)`

			`def get_touch(self):`
			`"""Take multiple samples to get accurate touch reading."""`
			`timeout = 2 # set timeout to 2 seconds`
			`confidence = 5`
			`buff = [[0, 0] for x in range(confidence)]`
			`buf_length = confidence # Require a confidence of 5 good samples`
			`buffptr = 0 # Track current buffer position`
			`nsamples = 0 # Count samples`
			`while timeout > 0:`
			`if nsamples == buf_length:`
			`meanx = sum([c[0] for c in buff]) // buf_length`
			`meany = sum([c[1] for c in buff]) // buf_length`
			`dev = sum([(c[0] - meanx)**2 +`
			`(c[1] - meany)**2 for c in buff]) / buf_length`
			`if dev <= 50: # Deviation should be under margin of 50`
			`return self.normalize(meanx, meany)`
			`# get a new value`
			`sample = self.raw_touch() # get a touch`
			`if sample is None:`
			`nsamples = 0 # Invalidate buff`
			`else:`
			`buff[buffptr] = sample # put in buff`
			`buffptr = (buffptr + 1) % buf_length # Incr, until rollover`
			`nsamples = min(nsamples + 1, buf_length) # Incr. until max`

			`sleep(.05)`
			`timeout -= .05`
			`return None`
			`#`

			`def int_press(self, pin):`
			`"""Send X,Y values to passed interrupt handler."""`
			`if not pin.value() and not self.int_locked:`
			`self.int_locked = True # Lock Interrupt`
			`buff = self.raw_touch()`

			`if buff is not None:`
			`x, y = self.normalize(*buff)`
			`self.int_handler(x, y)`
			`sleep(.1) # Debounce falling edge`
			`elif pin.value() and self.int_locked:`
			`sleep(.1) # Debounce rising edge`
			`self.int_locked = False # Unlock interrupt`
			`return`

			`def normalize(self, x, y):`
			`"""Normalize mean X,Y values to match LCD screen."""`
			`x = int(self.x_multiplier * x + self.x_add)`
			`y = int(self.y_multiplier * y + self.y_add)`
			`return x, y`

			`def raw_touch(self):`
			`"""Read raw X,Y touch values.`

			`Returns:`
			`tuple(int, int): X, Y`
			`"""`
			`x = self.send_command(self.GET_X)`
			`y = self.send_command(self.GET_Y)`
			`if self.x_min <= x <= self.x_max and self.y_min <= y <= self.y_max:`
			`return (x, y)`
			`else:`
			`return None`

			`def send_command(self, command):`
			`"""Write command to XT2046 (MicroPython).`

			`Args:`
			`command (byte): XT2046 command code.`
			`Returns:`
			`int: 12 bit response`
			`"""`
			`self.tx_buf[0] = command`
			`self.cs(0)`
			`self.spi.write_readinto(self.tx_buf, self.rx_buf)`
			`self.cs(1)`

			`return (self.rx_buf[1] << 4) \| (self.rx_buf[2] >> 4)`