replacing outdated driver files with latest ones

modules/inkycal_drivers.py

@@ -1,344 +0,0 @@
-#!/usr/bin/python3
-# -*- coding: utf-8 -*-
-"""
-Drivers file for Inky-Calendar software.
-Handles E-Paper display related tasks
-"""
-
-from PIL import Image
-import RPi.GPIO as GPIO
-from settings import display_type
-import numpy
-import spidev
-import RPi.GPIO as GPIO
-from time import sleep
-
-RST_PIN = 17
-DC_PIN = 25
-CS_PIN = 8
-BUSY_PIN = 24
-
-EPD_WIDTH = 640
-EPD_HEIGHT = 384
-
-SPI = spidev.SpiDev(0, 0)
-
-def epd_digital_write(pin, value):
-  GPIO.output(pin, value)
-
-def epd_digital_read(pin):
-  return GPIO.input(BUSY_PIN)
-
-def epd_delay_ms(delaytime):
-  sleep(delaytime / 1000.0)
-
-def spi_transfer(data):
-  SPI.writebytes(data)
-
-def epd_init():
-  GPIO.setmode(GPIO.BCM)
-  GPIO.setwarnings(False)
-  GPIO.setup(RST_PIN, GPIO.OUT)
-  GPIO.setup(DC_PIN, GPIO.OUT)
-  GPIO.setup(CS_PIN, GPIO.OUT)
-  GPIO.setup(BUSY_PIN, GPIO.IN)
-  SPI.max_speed_hz = 4000000
-  SPI.mode = 0b00
-  return 0;
-
-# EPD7IN5 commands
-PANEL_SETTING                               = 0x00
-POWER_SETTING                               = 0x01
-POWER_OFF                                   = 0x02
-POWER_OFF_SEQUENCE_SETTING                  = 0x03
-POWER_ON                                    = 0x04
-POWER_ON_MEASURE                            = 0x05
-BOOSTER_SOFT_START                          = 0x06
-DEEP_SLEEP                                  = 0x07
-DATA_START_TRANSMISSION_1                   = 0x10
-DATA_STOP                                   = 0x11
-DISPLAY_REFRESH                             = 0x12
-IMAGE_PROCESS                               = 0x13
-LUT_FOR_VCOM                                = 0x20
-LUT_BLUE                                    = 0x21
-LUT_WHITE                                   = 0x22
-LUT_GRAY_1                                  = 0x23
-LUT_GRAY_2                                  = 0x24
-LUT_RED_0                                   = 0x25
-LUT_RED_1                                   = 0x26
-LUT_RED_2                                   = 0x27
-LUT_RED_3                                   = 0x28
-LUT_XON                                     = 0x29
-PLL_CONTROL                                 = 0x30
-TEMPERATURE_SENSOR_COMMAND                  = 0x40
-TEMPERATURE_CALIBRATION                     = 0x41
-TEMPERATURE_SENSOR_WRITE                    = 0x42
-TEMPERATURE_SENSOR_READ                     = 0x43
-VCOM_AND_DATA_INTERVAL_SETTING              = 0x50
-LOW_POWER_DETECTION                         = 0x51
-TCON_SETTING                                = 0x60
-TCON_RESOLUTION                             = 0x61
-SPI_FLASH_CONTROL                           = 0x65
-REVISION                                    = 0x70
-GET_STATUS                                  = 0x71
-AUTO_MEASUREMENT_VCOM                       = 0x80
-READ_VCOM_VALUE                             = 0x81
-VCM_DC_SETTING                              = 0x82
-
-class EPD:
-  def __init__(self):
-    self.reset_pin = RST_PIN
-    self.dc_pin = DC_PIN
-    self.busy_pin = BUSY_PIN
-    self.width = EPD_WIDTH
-    self.height = EPD_HEIGHT
-
-  def digital_write(self, pin, value):
-    epd_digital_write(pin, value)
-
-  def digital_read(self, pin):
-    return epd_digital_read(pin)
-
-  def delay_ms(self, delaytime):
-    epd_delay_ms(delaytime)
-
-  def send_command(self, command):
-    self.digital_write(self.dc_pin, GPIO.LOW)
-    spi_transfer([command])
-
-  def send_data(self, data):
-    self.digital_write(self.dc_pin, GPIO.HIGH)
-    spi_transfer([data])
-
-  def init(self):
-    if (epd_init() != 0):
-        return -1
-    self.reset()
-    self.send_command(POWER_SETTING)
-    self.send_data(0x37)
-    self.send_data(0x00)
-    self.send_command(PANEL_SETTING)
-    self.send_data(0xCF)
-    self.send_data(0x08)
-    self.send_command(BOOSTER_SOFT_START)
-    self.send_data(0xc7)
-    self.send_data(0xcc)
-    self.send_data(0x28)
-    self.send_command(POWER_ON)
-    self.wait_until_idle()
-    self.send_command(PLL_CONTROL)
-    self.send_data(0x3c)
-    self.send_command(TEMPERATURE_CALIBRATION)
-    self.send_data(0x00)
-    self.send_command(VCOM_AND_DATA_INTERVAL_SETTING)
-    self.send_data(0x77)
-    self.send_command(TCON_SETTING)
-    self.send_data(0x22)
-    self.send_command(TCON_RESOLUTION)
-    self.send_data(0x02)     #source 640
-    self.send_data(0x80)
-    self.send_data(0x01)     #gate 384
-    self.send_data(0x80)
-    self.send_command(VCM_DC_SETTING)
-    self.send_data(0x1E)      #decide by LUT file
-    self.send_command(0xe5)           #FLASH MODE
-    self.send_data(0x03)
-
-  def wait_until_idle(self):
-    while(self.digital_read(self.busy_pin) == 0):      # 0: busy, 1: idle
-      self.delay_ms(100)
-
-  def reset(self):
-    self.digital_write(self.reset_pin, GPIO.LOW)         # module reset
-    self.delay_ms(200)
-    self.digital_write(self.reset_pin, GPIO.HIGH)
-    self.delay_ms(200)
-
-  def calibrate_display(self, no_of_cycles):
-    """Function for Calibration"""
-    
-    if display_type == 'colour':
-      packets = int(self.width / 2 * self.height)
-    if display_type == 'black_and_white':
-      packets = int(self.width / 4 * self.height)
-    
-    white, red, black = 0x33, 0x04, 0x00
-    
-    self.init()
-    print('----------Started calibration of E-Paper display----------')
-    for _ in range(no_of_cycles):
-      self.send_command(DATA_START_TRANSMISSION_1)
-      print('Calibrating black...')
-      [self.send_data(black) for i in range(packets)]
-      self.send_command(DISPLAY_REFRESH)
-      self.wait_until_idle()
-      
-      if display_type == 'colour':
-        print('Calibrating red...')
-        self.send_command(DATA_START_TRANSMISSION_1)
-        [self.send_data(red) for i in range(packets)]
-        self.send_command(DISPLAY_REFRESH)
-        self.wait_until_idle()
-
-      print('Calibrating white...')
-      self.send_command(DATA_START_TRANSMISSION_1)
-      [self.send_data(white) for i in range(packets)]
-      self.send_command(DISPLAY_REFRESH)
-      self.wait_until_idle()
-
-      print('Cycle {0} of {1} complete'.format(_+1, no_of_cycles))
-      
-    print('-----------Calibration complete----------')
-    self.sleep()
-
-  def reduce_colours(self, image):
-    buffer = numpy.array(image)
-    r,g,b = buffer[:,:,0], buffer[:,:,1], buffer[:,:,2]
-
-    if display_type == "colour":
-      buffer[numpy.logical_and(r <= 180, r == g)] = [0,0,0] #black
-      buffer[numpy.logical_and(r >= 150, g >= 150)] = [255,255,255] #white
-      buffer[numpy.logical_and(r >= 150, g <= 90)] = [255,0,0] #red
-
-    image = Image.fromarray(buffer)
-    return image
-
-  def clear(self, colour='white'):
-    if display_type == 'colour':
-      packets = int(self.width / 2 * self.height)
-    if display_type == 'black_and_white':
-      packets = int(self.width / 4 * self.height)
-    
-    if colour == 'white': data = 0x33
-    if colour == 'red': data = 0x04
-    if colour == 'black': data = 0x00
-
-    self.init()
-    self.send_command(DATA_START_TRANSMISSION_1)
-    [self.send_data(data) for _ in range(packets)]
-    self.send_command(DISPLAY_REFRESH)
-    print('waiting until E-Paper is not busy')
-    self.delay_ms(100)
-    self.wait_until_idle()
-    print('E-Paper free')
-    self.sleep()
-
-  def get_frame_buffer(self, image):
-    imwidth, imheight = image.size
-    if imwidth == self.height and imheight == self.width:
-      image = image.rotate(270, expand = True)
-      print('Rotated image by 270 degrees...', end= '')
-    elif imwidth != self.width or imheight != self.height:
-      raise ValueError('Image must be same dimensions as display \
-      ({0}x{1}).' .format(self.width, self.height))
-    else:
-      print('Image size OK')
-    imwidth, imheight = image.size
-
-    if display_type == 'colour':
-      buf = [0x00] * int(self.width * self.height / 4)
-      image_grayscale = image.convert('L')
-      pixels = image_grayscale.load()
-
-      for y in range(self.height):
-        for x in range(self.width):
-          # Set the bits for the column of pixels at the current position.
-          if pixels[x, y] == 0: # black
-            buf[int((x + y * self.width) / 4)] &= ~(0xC0 >> (x % 4 * 2))
-          elif pixels[x, y] == 76: # convert gray to red
-            buf[int((x + y * self.width) / 4)] &= ~(0xC0 >> (x % 4 * 2))
-            buf[int((x + y * self.width) / 4)] |= 0x40 >> (x % 4 * 2)
-          else:                           # white
-            buf[int((x + y * self.width) / 4)] |= 0xC0 >> (x % 4 * 2)
-
-    if display_type == 'black_and_white':
-      buf = [0x00] * int(self.width * self.height / 8)
-      image_monocolor = image.convert('1', dither = True)
-
-      pixels = image_monocolor.load()
-      for y in range(self.height):
-        for x in range(self.width):
-            # Set the bits for the column of pixels at the current position.
-          if pixels[x, y] != 0:
-            buf[int((x + y * self.width) / 8)] |= 0x80 >> (x % 8)
-
-    return buf
-
-  def display_frame(self, frame_buffer):
-    self.send_command(DATA_START_TRANSMISSION_1)
-    if display_type == 'colour':
-      for i in range(0, int(self.width / 4 * self.height)):
-        temp1 = frame_buffer[i]
-        j = 0
-        while (j < 4):
-          if ((temp1 & 0xC0) == 0xC0):
-            temp2 = 0x03 #white
-          elif ((temp1 & 0xC0) == 0x00):
-            temp2 = 0x00 #black
-          else:
-            temp2 = 0x04 #red
-          temp2 = (temp2 << 4) & 0xFF
-          temp1 = (temp1 << 2) & 0xFF
-          j += 1
-          if((temp1 & 0xC0) == 0xC0):
-            temp2 |= 0x03 #white
-          elif ((temp1 & 0xC0) == 0x00):
-            temp2 |= 0x00 #black
-          else:
-            temp2 |= 0x04 #red
-          temp1 = (temp1 << 2) & 0xFF
-          self.send_data(temp2)
-          j += 1
-
-    if display_type == 'black_and_white':
-      for i in range(0, 30720):
-        temp1 = frame_buffer[i]
-        j = 0
-        while (j < 8):
-          if(temp1 & 0x80):
-            temp2 = 0x03 #white
-          else:
-            temp2 = 0x00 #black
-          temp2 = (temp2 << 4) & 0xFF
-          temp1 = (temp1 << 1) & 0xFF
-          j += 1
-          if(temp1 & 0x80):
-            temp2 |= 0x03 #white
-          else:
-            temp2 |= 0x00 #black
-          temp1 = (temp1 << 1) & 0xFF
-          self.send_data(temp2)
-          j += 1
-
-    self.send_command(DISPLAY_REFRESH)
-    self.delay_ms(100)
-    self.wait_until_idle()
-
-  def show_image(self, image, reduce_colours = True):
-    print('Initialising E-Paper Display...', end='')
-    self.init()
-    sleep(5)
-    print('Done')
-    
-    if reduce_colours == True:
-      print('Optimising Image for E-Paper displays...', end = '')
-      image = self.reduce_colours(image)
-      print('Done')
-    else:
-      print('No colour optimisation done on image')
-
-    print('Creating image buffer and sending it to E-Paper display...', end='')
-    data = self.get_frame_buffer(image)
-    print('Done')
-    print('Refreshing display...', end = '')
-    self.display_frame(data)
-    print('Done')
-    print('Sending E-Paper to deep sleep mode...',end='')
-    self.sleep()
-    print('Done')
-
-  def sleep(self):
-    self.send_command(POWER_OFF)
-    self.wait_until_idle()
-    self.send_command(DEEP_SLEEP)
-    self.send_data(0xa5)