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srdjanmarjanovic/ILI9341_1.ino

Forked from calogerus/ILI9341_1.ino
Created December 3, 2020 13:41
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Arduino UNO + 2.4 TFT-LCD-Display-Shield-Touch-Panel-ILI9341-240x320-for-Arduino-UNO-MEGA
Raw
ILI9341_1.ino
void LCD_write(uint8_t d) {
// ILI9341 reads data pins when WR rises from LOW to HIGH (A1 pin on arduino)
PORTC = PORTC & B11111101; // WR 0
// data pins of ILI9341 connected to two arduino ports
PORTD = (PORTD & B00000011) | ((d) & B11111100);
PORTB = (PORTB & B11111100) | ((d) & B00000011);
PORTC = PORTC | B00000010; // WR 1
}
Raw
ILI9341_2.ino
void LCD_command_write(uint8_t d) {
PORTC = PORTC & B11111011; // LCD_RS = 0, arduino pin A2
// write data pins
LCD_write(d);
}
void LCD_data_write(uint8_t d) {
PORTC = PORTC | B00000100; // LCD_RS = 1, arduino pin A2
// write data pins
LCD_write(d);
}
Raw
ILI9341_3.ino
uint8_t LCD_read(void) {
// CS LOW, WR HIGH, RD HIGH->LOW>HIGH, RS(D/C) HIGH
PORTC = PORTC | B00000100; // RS 1
// LCD_RD - arduino pin A0
// After RD falls from HIGH to LOW ILI9341 outputs data until RD returns to HIGH
PORTC = PORTC & B11111110; // RD 0
BD_as_input(); // Set arduino pins as input
uint8_t pin72 = PIND & B11111100; // Read data pins 7-2
uint8_t pin10 = PINB & B00000011; // Read data pins 1-0
PORTC = PORTC | B00000001; // RD 1
BD_as_output(); // Re-Set arduino pins as output
return pin72 | pin10;
}
void BD_as_input(void) {
// Pins 7-2 as input, no change for pins 1,0 (RX TX)
DDRD = DDRD & B00000011;
// Pins 8-9 as input
DDRB = DDRB & B11111100;
}
void BD_as_output(void) {
// Pins 7-2 as output, no change for pins 1,0 (RX TX)
DDRD = DDRD | B11111100;
// Pins 8-9 as output
DDRB = DDRB | B00000011;
}
Raw
ILI9341_4.ino
void LCD_init(void) {
// LCD_RESET 1 - 0 - 1, arduino pin A4
PORTC = PORTC | B00010000; // 1
delay(10);
PORTC = PORTC & B11101111; // 0
delay(20);
PORTC = PORTC | B00010000; // 1
delay(20);
// CS HIGH, WR HIGH, RD HIGH, CS LOW
PORTC = PORTC | B00001000; // CS 1
PORTC = PORTC | B00000010; // WR 1
PORTC = PORTC | B00000001; // RD 1
PORTC = PORTC & B11110111; // CS 0
LCD_command_write(0xF7); // Pump ratio control
LCD_data_write(0x20); //
LCD_command_write(0x3A); // COLMOD: Pixel Format Set
LCD_data_write(0x55);
LCD_command_write(0x36); // Memory Access Control
// MY - Row Address Order (bit7)
// MX - Column Address Order
// MV - Row / Column Exchange
// ML - Vertical Refresh Order
// BGR - RGB-BGR Order
// MH - Horizontal Refresh ORDER(bit2)
LCD_data_write(B00001000);
LCD_command_write(0x11); // Sleep OUT
LCD_command_write(0x29); // Display ON
delay(50);
}
Raw
ILI9341_5.ino
// There is no output on the LCD SCREEN. Run and check Serial monitor if the ILI9341 commnunicates.
// Connect data pins LCD_D 0-7 to arduino UNO:
// LCD_D 0 -- D8
// LCD_D 1 -- D9
// LCD_D 2 -- D2
// LCD_D 3 -- D3
// LCD_D 4 -- D4
// LCD_D 5 -- D5
// LCD_D 6 -- D6
// LCD_D 7 -- D7
// Connect command pins:
// LCD_RST -- A4 1 -> 0 min 15 micros 0 -> 1
// LCD_CS -- A3 chip select, aktiv LOW
// LCD_RS -- A2 data/command select, 0 command, 1 data
// LCD_WR -- A1 0 -> 1, HIGH when not used
// LCD_RD -- A0 0 -> 1, HIGH when not used
// arduino UNO ports:
// B (digital pin 8 to 13)
// C (analog input pins)
// D (digital pins 0 to 7) 0 1 are RX TX, don't use
void LCD_write(uint8_t d) {
// ILI9341 reads data pins when WR rises from LOW to HIGH (A1 pin on arduino)
PORTC = PORTC & B11111101; // WR 0
// data pins of ILI9341 connected to two arduino ports
PORTD = (PORTD & B00000011) | ((d) & B11111100);
PORTB = (PORTB & B11111100) | ((d) & B00000011);
PORTC = PORTC | B00000010; // WR 1
}
void LCD_command_write(uint8_t d) {
PORTC = PORTC & B11111011; // LCD_RS = 0, arduino pin A2
// write data pins
LCD_write(d);
}
void LCD_data_write(uint8_t d) {
PORTC = PORTC | B00000100; // LCD_RS = 1, arduino pin A2
// write data pins
LCD_write(d);
}
uint8_t LCD_read(void) {
// CS LOW, WR HIGH, RD HIGH->LOW>HIGH, RS(D/C) HIGH
PORTC = PORTC | B00000100; // RS 1
// LCD_RD - arduino pin A0
// After RD falls from HIGH to LOW ILI9341 outputs data until RD returns to HIGH
PORTC = PORTC & B11111110; // RD 0
BD_as_input(); // Set arduino pins as input
uint8_t pin72 = PIND & B11111100; // Read data pins 7-2
uint8_t pin10 = PINB & B00000011; // Read data pins 1-0
PORTC = PORTC | B00000001; // RD 1
BD_as_output(); // Re-Set arduino pins as output
return pin72 | pin10;
}
void BD_as_input(void) {
// Pins 7-2 as input, no change for pins 1,0 (RX TX)
DDRD = DDRD & B00000011;
// Pins 8-9 as input
DDRB = DDRB & B11111100;
}
void BD_as_output(void) {
// Pins 7-2 as output, no change for pins 1,0 (RX TX)
DDRD = DDRD | B11111100;
// Pins 8-9 as output
DDRB = DDRB | B00000011;
}
void LCD_init(void) {
// LCD_RESET 1 - 0 - 1, arduino pin A4
PORTC = PORTC | B00010000; // 1
delay(10);
PORTC = PORTC & B11101111; // 0
delay(20);
PORTC = PORTC | B00010000; // 1
delay(20);
// CS HIGH, WR HIGH, RD HIGH, CS LOW
PORTC = PORTC | B00001000; // CS 1
PORTC = PORTC | B00000010; // WR 1
PORTC = PORTC | B00000001; // RD 1
PORTC = PORTC & B11110111; // CS 0
LCD_command_write(0xF7); // Pump ratio control
LCD_data_write(0x20); //
LCD_command_write(0x3A); // COLMOD: Pixel Format Set
LCD_data_write(0x55);
LCD_command_write(0x36); // Memory Access Control
// MY - Row Address Order (bit7)
// MX - Column Address Order
// MV - Row / Column Exchange
// ML - Vertical Refresh Order
// BGR - RGB-BGR Order
// MH - Horizontal Refresh ORDER(bit2)
LCD_data_write(B00001000);
LCD_command_write(0x11); // Sleep OUT
LCD_command_write(0x29); // Display ON
delay(50);
}
void setup()
{
Serial.begin(9600);
// Set pins 1-8 as output
BD_as_output();
// Set pins A0-A4 as output
DDRC = DDRC | B00011111;
LCD_init();
uint8_t r;
Serial.println("d3 Read ID4");
LCD_command_write(0xd3); // read ID4, should return 9341
//delay(50);
r = LCD_read(); //dummy
//delay(50);
r = LCD_read();
Serial.println(r,BIN);
//delay(50);
r = LCD_read();
Serial.println(r,BIN);
//delay(50);
r = LCD_read();
Serial.println(r,BIN);
Serial.println("");
Serial.println("09 Read Display Status");
LCD_command_write(0x09); // Read Display Status
r = LCD_read(); //dummy
r = LCD_read();
Serial.println(r,BIN);
r = LCD_read();
Serial.println(r,BIN);
r = LCD_read();
Serial.println(r,BIN);
r = LCD_read();
Serial.println(r,BIN);
Serial.println("");
Serial.println("0a Read Display Power Mode");
LCD_command_write(0x0a); // Read Display Power Mode
r = LCD_read(); //dummy
r = LCD_read();
Serial.println(r,BIN);
Serial.println("");
}
void loop()
{
}
Raw
ILI9341_6.ino
// There should be output on LCD screen. See the different ways of clearing the screen.
// Connect data pins LCD_D 0-7 to arduino UNO:
// LCD_D 0 -- D8
// LCD_D 1 -- D9
// LCD_D 2 -- D2
// LCD_D 3 -- D3
// LCD_D 4 -- D4
// LCD_D 5 -- D5
// LCD_D 6 -- D6
// LCD_D 7 -- D7
// Connect command pins:
// LCD_RST -- A4 1 -> 0 min 15 micros 0 -> 1
// LCD_CS -- A3 chip select, aktiv LOW
// LCD_RS -- A2 data/command select, 0 command, 1 data
// LCD_WR -- A1 0 -> 1, HIGH when not used
// LCD_RD -- A0 0 -> 1, HIGH when not used
// arduino UNO ports:
// B (digital pin 8 to 13)
// C (analog input pins)
// D (digital pins 0 to 7) 0 1 are RX TX, don't use
#define BLACK 0x0000
#define BLUE 0x001F
#define RED 0xF800
#define GREEN 0x07E0
#define CYAN 0x07FF
#define MAGENTA 0xF81F
#define YELLOW 0xFFE0
#define WHITE 0xFFFF
void LCD_write(uint8_t d) {
// ILI9341 reads data pins when WR rises from LOW to HIGH (A1 pin on arduino)
PORTC = PORTC & B11111101; // WR 0
// data pins of ILI9341 connected to two arduino ports
PORTD = (PORTD & B00000011) | ((d) & B11111100);
PORTB = (PORTB & B11111100) | ((d) & B00000011);
PORTC = PORTC | B00000010; // WR 1
}
void LCD_command_write(uint8_t d) {
PORTC = PORTC & B11111011; // LCD_RS = 0, arduino pin A2
// write data pins
LCD_write(d);
}
void LCD_data_write(uint8_t d) {
PORTC = PORTC | B00000100; // LCD_RS = 1, arduino pin A2
// write data pins
LCD_write(d);
}
uint8_t LCD_read(void) {
// CS LOW, WR HIGH, RD HIGH->LOW>HIGH, RS(D/C) HIGH
PORTC = PORTC | B00000100; // RS 1
// LCD_RD - arduino pin A0
// After RD falls from HIGH to LOW ILI9341 outputs data until RD returns to HIGH
PORTC = PORTC & B11111110; // RD 0
BD_as_input(); // Set arduino pins as input
uint8_t pin72 = PIND & B11111100; // Read data pins 7-2
uint8_t pin10 = PINB & B00000011; // Read data pins 1-0
PORTC = PORTC | B00000001; // RD 1
BD_as_output(); // Re-Set arduino pins as output
return pin72 | pin10;
}
void BD_as_input(void) {
// Pins 7-2 as input, no change for pins 1,0 (RX TX)
DDRD = DDRD & B00000011;
// Pins 8-9 as input
DDRB = DDRB & B11111100;
}
void BD_as_output(void) {
// Pins 7-2 as output, no change for pins 1,0 (RX TX)
DDRD = DDRD | B11111100;
// Pins 8-9 as output
DDRB = DDRB | B00000011;
}
void LCD_init(void) {
// LCD_RESET 1 - 0 - 1, arduino pin A4
PORTC = PORTC | B00010000; // 1
delay(10);
PORTC = PORTC & B11101111; // 0
delay(20);
PORTC = PORTC | B00010000; // 1
delay(20);
// CS HIGH, WR HIGH, RD HIGH, CS LOW
PORTC = PORTC | B00001000; // CS 1
PORTC = PORTC | B00000010; // WR 1
PORTC = PORTC | B00000001; // RD 1
PORTC = PORTC & B11110111; // CS 0
LCD_command_write(0xF7); // Pump ratio control
LCD_data_write(0x20); //
LCD_command_write(0x3A); // COLMOD: Pixel Format Set
LCD_data_write(0x55);
LCD_command_write(0x36); // Memory Access Control
// MY - Row Address Order (bit7)
// MX - Column Address Order
// MV - Row / Column Exchange
// ML - Vertical Refresh Order
// BGR - RGB-BGR Order
// MH - Horizontal Refresh ORDER(bit2)
LCD_data_write(B00001000);
LCD_command_write(0x11); // Sleep OUT
LCD_command_write(0x29); // Display ON
delay(50);
}
void LCD_rect(int16_t col,int16_t row, int16_t width, int16_t height, int16_t color) {
LCD_command_write(0x2a); // Column Address Set
LCD_data_write(row>>8);
LCD_data_write(row);
LCD_data_write((row+height-1)>>8);
LCD_data_write(row+height-1);
LCD_command_write(0x2b); // Page Address Set
LCD_data_write(col>>8);
LCD_data_write(col);
LCD_data_write((col+width-1)>>8);
LCD_data_write(col+width-1);
LCD_command_write(0x2c); // Memory Write
byte chigh=color >> 8;
byte clow=color;
int i,j;
for(i=0;i<width;i++)
for(j=0;j<height;j++)
{
LCD_data_write(chigh);
LCD_data_write(clow);
}
}
void LCD_clear(byte color) {
/*
Clear screen faster sacrifing color depth. Instead of writing
to data bits high and low byte of the color for each pixel, which takes more
than 300ms to fill the screen, set once data bits to 0's for black or
to 1's for white and start changing control bit WR from LOW to HIGH to
write the whole area. It takes cca 70 ms. In this way the colors of screen are
limited to those with the same high and low byte. For example setting color
to 0x0C fills the screen with color 0x0C0C.
Writing two pixels in one cycle lowering cycle count from 76800 (240x320) to
38400 clears screen in less then 30ms.
*/
LCD_command_write(0x2a);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(0xEC);
LCD_command_write(0x2b);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(1);
LCD_data_write(0x3F);
LCD_command_write(0x2c);
PORTC = PORTC | B00000100; // LCD_RS = 1 - DATA
PORTD = (PORTD & B00000011) | ((color) & B11111100);
PORTB = (PORTB & B11111100) | ((color) & B00000011);
uint16_t x;
x=38400; // 240*320/2
byte wr0=PORTC & B11111101; // set WR 0
byte wr1=PORTC | B00000010; // set WR 1
for(uint16_t y=0;y<x;y++)
{
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
}
}
void setup()
{
Serial.begin(9600);
// Set pins 1-8 as output
BD_as_output();
// Set pins A0-A4 as output
DDRC = DDRC | B00011111;
LCD_init();
}
void loop()
{
LCD_rect(0,0,320,240, WHITE); // clear whole screen, slow
delay(500);
LCD_rect(0,0,320,240, 0x0C0C);
delay(1000);
LCD_clear(0xFF); // clear whole screen, faster
delay(500);
LCD_clear(0x0C); ;
delay(1000);
LCD_rect(200,50,50,50, WHITE);
LCD_rect(50,50,50,50, BLACK);
delay(1000);
}
Raw
ILI9341_7.ino
// RUN to find values for TouchScreen calibration (lines 45-48)
// Connect data pins LCD_D 0-7 to arduino UNO:
// LCD_D 0 -- D8
// LCD_D 1 -- D9
// LCD_D 2 -- D2
// LCD_D 3 -- D3
// LCD_D 4 -- D4
// LCD_D 5 -- D5
// LCD_D 6 -- D6
// LCD_D 7 -- D7
// Connect command pins:
// LCD_RST -- A4 1 -> 0 min 15 micros 0 -> 1
// LCD_CS -- A3 chip select, aktiv LOW
// LCD_RS -- A2 data/command select, 0 command, 1 data
// LCD_WR -- A1 0 -> 1, HIGH when not used
// LCD_RD -- A0 0 -> 1, HIGH when not used
// arduino uno porty:
// B (digital pin 8 to 13)
// C (analog input pins)
// D (digital pins 0 to 7) 0 1 are RX TX, don't use
#define BLACK 0x0000
#define BLUE 0x001F
#define RED 0xF800
#define GREEN 0x07E0
#define CYAN 0x07FF
#define MAGENTA 0xF81F
#define YELLOW 0xFFE0
#define WHITE 0xFFFF
// Touchscreen connection:
#define Y1 A3 // need two analog inputs
#define X1 A2 //
#define Y2 9 //
#define X2 8 //
int16_t P_COL=0; // LCD cursor pointer
int16_t P_ROW=0;
int16_t T_COL=0; // TOUCHSCREEN(TS) detected value
int16_t T_ROW=0;
// TS calibration
uint16_t ROW_F=0; // TS first row
uint16_t ROW_L=0; // TS last row
uint16_t COL_F=0; // TS first column
uint16_t COL_L=0; // TS last column
uint8_t F_SIZE=2; // font size
uint16_t F_COLOR=WHITE; // foreground color
uint16_t B_COLOR=0x0C0C; // background color
void LCD_write(uint8_t d) {
// ILI9341 reads data pins when WR rises from LOW to HIGH (A1 pin on arduino)
PORTC = PORTC & B11111101; // WR 0
// data pins of ILI9341 connected to two arduino ports
PORTD = (PORTD & B00000011) | ((d) & B11111100);
PORTB = (PORTB & B11111100) | ((d) & B00000011);
PORTC = PORTC | B00000010; // WR 1
}
void LCD_command_write(uint8_t d) {
PORTC = PORTC & B11111011; // LCD_RS = 0, arduino pin A2
// write data pins
LCD_write(d);
}
void LCD_data_write(uint8_t d) {
PORTC = PORTC | B00000100; // LCD_RS = 1, arduino pin A2
// write data pins
LCD_write(d);
}
uint8_t LCD_read(void) {
// CS LOW, WR HIGH, RD HIGH->LOW>HIGH, RS(D/C) HIGH
PORTC = PORTC | B00000100; // RS 1
// LCD_RD - arduino pin A0
// After RD falls from HIGH to LOW ILI9341 outputs data until RD returns to HIGH
PORTC = PORTC & B11111110; // RD 0
BD_as_input(); // Set arduino pins as input
uint8_t pin72 = PIND & B11111100; // Read data pins 7-2
uint8_t pin10 = PINB & B00000011; // Read data pins 1-0
PORTC = PORTC | B00000001; // RD 1
BD_as_output(); // Re-Set arduino pins as output
return pin72 | pin10;
}
void BD_as_input(void) {
// Pins 7-2 as input, no change for pins 1,0 (RX TX)
DDRD = DDRD & B00000011;
// Pins 8-9 as input
DDRB = DDRB & B11111100;
}
void BD_as_output(void) {
// Pins 7-2 as output, no change for pins 1,0 (RX TX)
DDRD = DDRD | B11111100;
// Pins 8-9 as output
DDRB = DDRB | B00000011;
}
void LCD_init(void) {
// LCD_RESET 1 - 0 - 1, arduino pin A4
PORTC = PORTC | B00010000; // 1
delay(10);
PORTC = PORTC & B11101111; // 0
delay(20);
PORTC = PORTC | B00010000; // 1
delay(20);
// CS HIGH, WR HIGH, RD HIGH, CS LOW
PORTC = PORTC | B00001000; // CS 1
PORTC = PORTC | B00000010; // WR 1
PORTC = PORTC | B00000001; // RD 1
PORTC = PORTC & B11110111; // CS 0
LCD_command_write(0xF7); // Pump ratio control
LCD_data_write(0x20); //
LCD_command_write(0x3A); // COLMOD: Pixel Format Set
LCD_data_write(0x55);
LCD_command_write(0x36); // Memory Access Control
// MY - Row Address Order (bit7)
// MX - Column Address Order
// MV - Row / Column Exchange
// ML - Vertical Refresh Order
// BGR - RGB-BGR Order
// MH - Horizontal Refresh ORDER(bit2)
LCD_data_write(B00001000);
LCD_command_write(0x11); // Sleep OUT
LCD_command_write(0x29); // Display ON
delay(50);
}
void LCD_rect(int16_t col,int16_t row, int16_t width, int16_t height, int16_t color) {
LCD_command_write(0x2a); // Column Address Set
LCD_data_write(row>>8);
LCD_data_write(row);
LCD_data_write((row+height-1)>>8);
LCD_data_write(row+height-1);
LCD_command_write(0x2b); // Page Address Set
LCD_data_write(col>>8);
LCD_data_write(col);
LCD_data_write((col+width-1)>>8);
LCD_data_write(col+width-1);
LCD_command_write(0x2c); // Memory Write
byte chigh=color >> 8;
byte clow=color;
int i,j;
for(i=0;i<width;i++)
for(j=0;j<height;j++)
{
LCD_data_write(chigh);
LCD_data_write(clow);
}
}
void LCD_clear(byte color) {
/*
Accelerate screen clearing sacrifing color depth. Instead of writing
to data bits high and low byte of the color for each pixel, which takes more
than 300ms to fill the screen, set once data bits to 0's for black or
to 1's for white and start changing control bit WR from LOW to HIGH to
write whole area. It takes cca 70 ms. In this way the color of screen are
limited to those with the same high and low byte. For example setting color
to 0x0C fills the screen with color 0x0C0C.
Writing two pixels in one cycle lowering cycle count from 76800 (240x320) to
38400 clears screen in less then 30ms.
*/
LCD_command_write(0x2a);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(0xEC);
LCD_command_write(0x2b);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(1);
LCD_data_write(0x3F);
LCD_command_write(0x2c);
PORTC = PORTC | B00000100; // LCD_RS = 1 - DATA
PORTD = (PORTD & B00000011) | ((color) & B11111100);
PORTB = (PORTB & B11111100) | ((color) & B00000011);
uint16_t x;
x=38400; // 240*320/2
byte wr0=PORTC & B11111101; // set WR 0
byte wr1=PORTC | B00000010; // set WR 1
for(uint16_t y=0;y<x;y++)
{
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
}
}
void Display_integer(int16_t n) {
String str=String(n);
byte l=str.length();
char b[l+1]; // +1 for the null terminator
str.toCharArray(b,l+1);
for(int n=0; n<l; n++) {
Display_char(b[n]);
}
}
void Display_char(char znak) {
static const byte ASCII[][5] =
{
{0x00, 0x00, 0x00, 0x00, 0x00}, // 20
{0x00, 0x00, 0x5f, 0x00, 0x00}, // 21 !
{0x00, 0x07, 0x00, 0x07, 0x00}, // 22 "
{0x14, 0x7f, 0x14, 0x7f, 0x14}, // 23 #
{0x24, 0x2a, 0x7f, 0x2a, 0x12} ,// 24 $
{0x23, 0x13, 0x08, 0x64, 0x62}, // 25 %
{0x36, 0x49, 0x55, 0x22, 0x50}, // 26 &
{0x00, 0x00, 0x07, 0x05, 0x07}, // 27 '
{0x00, 0x1c, 0x22, 0x41, 0x00}, // 28 (
{0x00, 0x41, 0x22, 0x1c, 0x00}, // 29 )
{0x14, 0x08, 0x3e, 0x08, 0x14}, // 2a *
{0x08, 0x08, 0x3e, 0x08, 0x08}, // 2b +
{0x00, 0x50, 0x30, 0x00, 0x00}, // 2c ,
{0x08, 0x08, 0x08, 0x08, 0x08}, // 2d -
{0x00, 0x60, 0x60, 0x00, 0x00}, // 2e .
{0x20, 0x10, 0x08, 0x04, 0x02}, // 2f /
{0x3e, 0x51, 0x49, 0x45, 0x3e}, // 30 0
{0x00, 0x42, 0x7f, 0x40, 0x00}, // 31 1
{0x42, 0x61, 0x51, 0x49, 0x46}, // 32 2
{0x21, 0x41, 0x45, 0x4b, 0x31}, // 33 3
{0x18, 0x14, 0x12, 0x7f, 0x10}, // 34 4
{0x27, 0x45, 0x45, 0x45, 0x39}, // 35 5
{0x3c, 0x4a, 0x49, 0x49, 0x30}, // 36 6
{0x01, 0x71, 0x09, 0x05, 0x03}, // 37 7
{0x36, 0x49, 0x49, 0x49, 0x36}, // 38 8
{0x06, 0x49, 0x49, 0x29, 0x1e}, // 39 9
{0x00, 0x36, 0x36, 0x00, 0x00}, // 3a :
{0x00, 0x56, 0x36, 0x00, 0x00}, // 3b ;
{0x08, 0x14, 0x22, 0x41, 0x00}, // 3c <
{0x14, 0x14, 0x14, 0x14, 0x14}, // 3d =
{0x00, 0x41, 0x22, 0x14, 0x08}, // 3e >
{0x02, 0x01, 0x51, 0x09, 0x06}, // 3f ?
{0x32, 0x49, 0x79, 0x41, 0x3e}, // 40 @
{0x7e, 0x11, 0x11, 0x11, 0x7e}, // 41 A
{0x7f, 0x49, 0x49, 0x49, 0x36}, // 42 B
{0x3e, 0x41, 0x41, 0x41, 0x22}, // 43 C
{0x7f, 0x41, 0x41, 0x22, 0x1c}, // 44 D
{0x7f, 0x49, 0x49, 0x49, 0x41}, // 45 E
{0x7f, 0x09, 0x09, 0x09, 0x01}, // 46 F
{0x3e, 0x41, 0x49, 0x49, 0x7a}, // 47 G
{0x7f, 0x08, 0x08, 0x08, 0x7f}, // 48 H
{0x00, 0x41, 0x7f, 0x41, 0x00}, // 49 I
{0x20, 0x40, 0x41, 0x3f, 0x01}, // 4a J
{0x7f, 0x08, 0x14, 0x22, 0x41}, // 4b K
{0x7f, 0x40, 0x40, 0x40, 0x40}, // 4c L
{0x7f, 0x02, 0x0c, 0x02, 0x7f}, // 4d M
{0x7f, 0x04, 0x08, 0x10, 0x7f}, // 4e N
{0x3e, 0x41, 0x41, 0x41, 0x3e}, // 4f O
{0x7f, 0x09, 0x09, 0x09, 0x06}, // 50 P
{0x3e, 0x41, 0x51, 0x21, 0x5e}, // 51 Q
{0x7f, 0x09, 0x19, 0x29, 0x46}, // 52 R
{0x46, 0x49, 0x49, 0x49, 0x31}, // 53 S
{0x01, 0x01, 0x7f, 0x01, 0x01}, // 54 T
{0x3f, 0x40, 0x40, 0x40, 0x3f}, // 55 U
{0x1f, 0x20, 0x40, 0x20, 0x1f}, // 56 V
{0x3f, 0x40, 0x38, 0x40, 0x3f}, // 57 W
{0x63, 0x14, 0x08, 0x14, 0x63}, // 58 X
{0x07, 0x08, 0x70, 0x08, 0x07}, // 59 Y
{0x61, 0x51, 0x49, 0x45, 0x43}, // 5a Z
{0x00, 0x7f, 0x41, 0x41, 0x00}, // 5b [
{0x02, 0x04, 0x08, 0x10, 0x20}, // 5c Y
{0x00, 0x41, 0x41, 0x7f, 0x00}, // 5d ]
{0x04, 0x02, 0x01, 0x02, 0x04}, // 5e ^
{0x40, 0x40, 0x40, 0x40, 0x40}, // 5f _
{0x00, 0x01, 0x02, 0x04, 0x00}, // 60 `
{0x20, 0x54, 0x54, 0x54, 0x78}, // 61 a
{0x7f, 0x48, 0x44, 0x44, 0x38}, // 62 b
{0x38, 0x44, 0x44, 0x44, 0x20}, // 63 c
{0x38, 0x44, 0x44, 0x48, 0x7f}, // 64 d
{0x38, 0x54, 0x54, 0x54, 0x18}, // 65 e
{0x08, 0x7e, 0x09, 0x01, 0x02}, // 66 f
{0x0c, 0x52, 0x52, 0x52, 0x3e}, // 67 g
{0x7f, 0x08, 0x04, 0x04, 0x78}, // 68 h
{0x00, 0x44, 0x7d, 0x40, 0x00}, // 69 i
{0x20, 0x40, 0x44, 0x3d, 0x00}, // 6a j
{0x7f, 0x10, 0x28, 0x44, 0x00}, // 6b k
{0x00, 0x41, 0x7f, 0x40, 0x00}, // 6c l
{0x7c, 0x04, 0x18, 0x04, 0x78}, // 6d m
{0x7c, 0x08, 0x04, 0x04, 0x78}, // 6e n
{0x38, 0x44, 0x44, 0x44, 0x38}, // 6f o
{0x7c, 0x14, 0x14, 0x14, 0x08}, // 70 p
{0x08, 0x14, 0x14, 0x18, 0x7c}, // 71 q
{0x7c, 0x08, 0x04, 0x04, 0x08}, // 72 r
{0x48, 0x54, 0x54, 0x54, 0x20}, // 73 s
{0x04, 0x3f, 0x44, 0x40, 0x20}, // 74 t
{0x3c, 0x40, 0x40, 0x20, 0x7c}, // 75 u
{0x1c, 0x20, 0x40, 0x20, 0x1c}, // 76 v
{0x3c, 0x40, 0x30, 0x40, 0x3c}, // 77 w
{0x44, 0x28, 0x10, 0x28, 0x44}, // 78 x
{0x0c, 0x50, 0x50, 0x50, 0x3c}, // 79 y
{0x44, 0x64, 0x54, 0x4c, 0x44}, // 7a z
{0x00, 0x08, 0x36, 0x41, 0x00}, // 7b {
{0x00, 0x00, 0x7f, 0x00, 0x00}, // 7c |
{0x00, 0x41, 0x36, 0x08, 0x00}, // 7d }
{0x10, 0x08, 0x08, 0x10, 0x08}, // 7e ‹
{0x00, 0x06, 0x09, 0x09, 0x06} // 7f ›
};
int8_t size=F_SIZE;
int16_t color=F_COLOR;
int16_t bcolor=B_COLOR;
if( (P_COL+(size*6)) > 319) {
P_COL=0;
P_ROW+=size*(8+1);
}
LCD_command_write(0x2a); // ROWS
LCD_data_write(P_ROW>>8);
LCD_data_write(P_ROW);
LCD_data_write(((P_ROW+size*8)-1)>>8);
LCD_data_write((P_ROW+size*8)-1);
LCD_command_write(0x2b); // COLUMNS
LCD_data_write(P_COL>>8);
LCD_data_write(P_COL);
LCD_data_write((P_COL+(size*6))>>8);
LCD_data_write(P_COL+(size*6));
LCD_command_write(0x2c);
byte bchigh=bcolor >> 8;
byte bclow=bcolor;
byte fchigh=color >> 8;
byte fclow=color;
byte index, nbit, i, j;
for (index = 0; index < 5; index++) {
char col=ASCII[znak - 0x20][index];
for ( i=0; i<size; i++){
byte mask=B00000001;
for (nbit = 0; nbit < 8; nbit++) {
if (col & mask) {
for (j=0; j<size; j++){
LCD_data_write(fchigh);
LCD_data_write(fclow);
}
}
else {
for (j=0; j<size; j++){
LCD_data_write(bchigh);
LCD_data_write(bclow);
}
}
mask=mask<<1;
}
}
}
/*for ( i=0; i<size; i++){
for (nbit = 0; nbit < 8; nbit++) {
for (j=0; j<size; j++){
LCD_data_write(bchigh);
LCD_data_write(bclow);
}
}
}*/
P_COL+=size*6;
}
void Display_clear_char(byte n) {
// delete n chars
int8_t size=F_SIZE;
int16_t bcolor=B_COLOR;
LCD_command_write(0x2a); // ROWS
LCD_data_write(P_ROW>>8);
LCD_data_write(P_ROW);
LCD_data_write(((P_ROW+size*8)-1)>>8);
LCD_data_write((P_ROW+size*8)-1);
LCD_command_write(0x2b); // COLUMNS
LCD_data_write(P_COL>>8);
LCD_data_write(P_COL);
LCD_data_write((P_COL+(size*6*n))>>8);
LCD_data_write(P_COL+(size*6*n));
LCD_command_write(0x2c);
byte bchigh=bcolor >> 8;
byte bclow=bcolor;
int16_t cyc=size*8 * size*6*n;
for (int16_t i=0; i<cyc; i++) {
LCD_data_write(bchigh);
LCD_data_write(bclow);
}
}
byte ReadTouch(void) {
//Y1 A3
//X1 A2
//Y2 9
//X2 8
int16_t row, col;
int8_t touch, wait_touch, valid;
wait_touch=1;
valid=0;
while (wait_touch) {
pinMode(Y1, INPUT);
pinMode(Y2, INPUT_PULLUP);
pinMode(X1, OUTPUT);
pinMode(X2, OUTPUT);
digitalWrite(X1, LOW);
digitalWrite(X2, LOW);
touch = !digitalRead(Y1); // 0 - touched
if (touch) {
//delay(5);
digitalWrite(X1, HIGH); // X variant A
//digitalWrite(X2, HIGH); // X variant B
delay(1);
row = analogRead(Y1);
delay(4);
if (abs(analogRead(Y1)-row)>3) { return 0;}
delay(3);
if (abs(analogRead(Y1)-row)>3) { return 0;}
//if (analogRead(Y1)!=row) { return 0;}
pinMode(X1, INPUT);
pinMode(X2, INPUT_PULLUP);
pinMode(Y1, OUTPUT);
pinMode(Y2, OUTPUT);
//digitalWrite(Y1, HIGH); // Y variant A
//digitalWrite(Y2, LOW); // Y variant A
digitalWrite(Y1, LOW); // Y variant B
digitalWrite(Y2, HIGH); // Y variant B
delay(1);
col = analogRead(X1);
delay(4);
if (abs(analogRead(X1)-col)>3) { return 0;}
delay(3);
if (abs(analogRead(X1)-col)>3) { return 0;}
//if (analogRead(X1)!=col) { return 0;}
//digitalWrite(Y1, LOW); // Y variant A
digitalWrite(Y2, LOW); // Y variant B
//delay(5);
touch = !digitalRead(X1); // 0 - dotyk
if (touch) {
int16_t rows=ROW_L-ROW_F;
int16_t cols=COL_L-COL_F;
float row1=float(row-ROW_F)/rows*240;
float col1=float(col-COL_F)/cols*320;
T_ROW=int(row1);
T_COL=int(col1);
valid=1;
}
wait_touch=0;
}
}
// Re-Set A2 A3 8 9 for ILI9341
BD_as_output();
DDRC = DDRC | B00011111; // A0-A4 as outputs
// To find out values for calibration F_ROW, L_ROW, F_COL, F_COL
// /*
B_COLOR=0x0C0C;
F_SIZE=2;
P_COL=120;
P_ROW=100;
Display_integer(row);
P_COL=180;
P_ROW=100;
Display_integer(col);
// */
return valid;
}
uint16_t D_COL, D_ROW;
void setup()
{
Serial.begin(9600);
// Set pins 1-8 as output
BD_as_output();
// Set pins A0-A4 as output
DDRC = DDRC | B00011111;
LCD_init();
LCD_clear(0x0C);
}
void loop()
{
byte touch=ReadTouch() ;
}
Raw
ILI9341_8.ino
// Connect data pins LCD_D 0-7 to arduino UNO:
// LCD_D 0 -- D8
// LCD_D 1 -- D9
// LCD_D 2 -- D2
// LCD_D 3 -- D3
// LCD_D 4 -- D4
// LCD_D 5 -- D5
// LCD_D 6 -- D6
// LCD_D 7 -- D7
// Connect command pins:
// LCD_RST -- A4 1 -> 0 min 15 micros 0 -> 1
// LCD_CS -- A3 chip select, aktiv LOW
// LCD_RS -- A2 data/command select, 0 command, 1 data
// LCD_WR -- A1 0 -> 1, HIGH when not used
// LCD_RD -- A0 0 -> 1, HIGH when not used
// arduino uno porty:
// B (digital pin 8 to 13)
// C (analog input pins)
// D (digital pins 0 to 7) 0 1 are RX TX, don't use
#define BLACK 0x0000
#define BLUE 0x001F
#define RED 0xF800
#define GREEN 0x07E0
#define CYAN 0x07FF
#define MAGENTA 0xF81F
#define YELLOW 0xFFE0
#define WHITE 0xFFFF
// Touchscreen connection:
#define Y1 A3 // need two analog inputs
#define X1 A2 //
#define Y2 9 //
#define X2 8 //
int16_t P_COL=0; // LCD cursor pointer
int16_t P_ROW=0;
int16_t T_COL=0; // TOUCHSCREEN(TS) detected value
int16_t T_ROW=0;
// TS calibration
uint16_t ROW_F=110; // TS first row
uint16_t ROW_L=920; // TS last row
uint16_t COL_F=110; // TS first column
uint16_t COL_L=930; // TS last column
uint8_t F_SIZE=3; // font size
uint16_t F_COLOR=WHITE; // foreground color
uint16_t B_COLOR=0x0C0C; // background color
// draw keypad
String K_LABEL[] = {"1","2","3","4","5","6","7","8","9","0","<"};
uint16_t K_ROW[] = {150,150,150,100,100,100,50,50,50,200,200};
uint16_t K_COL[] = {10,50,90,10,50,90,10,50,90,50,90};
void LCD_write(uint8_t d) {
// ILI9341 reads data pins when WR rises from LOW to HIGH (A1 pin on arduino)
PORTC = PORTC & B11111101; // WR 0
// data pins of ILI9341 connected to two arduino ports
PORTD = (PORTD & B00000011) | ((d) & B11111100);
PORTB = (PORTB & B11111100) | ((d) & B00000011);
PORTC = PORTC | B00000010; // WR 1
}
void LCD_command_write(uint8_t d) {
PORTC = PORTC & B11111011; // LCD_RS = 0, arduino pin A2
// write data pins
LCD_write(d);
}
void LCD_data_write(uint8_t d) {
PORTC = PORTC | B00000100; // LCD_RS = 1, arduino pin A2
// write data pins
LCD_write(d);
}
uint8_t LCD_read(void) {
// CS LOW, WR HIGH, RD HIGH->LOW>HIGH, RS(D/C) HIGH
PORTC = PORTC | B00000100; // RS 1
// LCD_RD - arduino pin A0
// After RD falls from HIGH to LOW ILI9341 outputs data until RD returns to HIGH
PORTC = PORTC & B11111110; // RD 0
BD_as_input(); // Set arduino pins as input
uint8_t pin72 = PIND & B11111100; // Read data pins 7-2
uint8_t pin10 = PINB & B00000011; // Read data pins 1-0
PORTC = PORTC | B00000001; // RD 1
BD_as_output(); // Re-Set arduino pins as output
return pin72 | pin10;
}
void BD_as_input(void) {
// Pins 7-2 as input, no change for pins 1,0 (RX TX)
DDRD = DDRD & B00000011;
// Pins 8-9 as input
DDRB = DDRB & B11111100;
}
void BD_as_output(void) {
// Pins 7-2 as output, no change for pins 1,0 (RX TX)
DDRD = DDRD | B11111100;
// Pins 8-9 as output
DDRB = DDRB | B00000011;
}
void LCD_init(void) {
// LCD_RESET 1 - 0 - 1, arduino pin A4
PORTC = PORTC | B00010000; // 1
delay(10);
PORTC = PORTC & B11101111; // 0
delay(20);
PORTC = PORTC | B00010000; // 1
delay(20);
// CS HIGH, WR HIGH, RD HIGH, CS LOW
PORTC = PORTC | B00001000; // CS 1
PORTC = PORTC | B00000010; // WR 1
PORTC = PORTC | B00000001; // RD 1
PORTC = PORTC & B11110111; // CS 0
LCD_command_write(0xF7); // Pump ratio control
LCD_data_write(0x20); //
LCD_command_write(0x3A); // COLMOD: Pixel Format Set
LCD_data_write(0x55);
LCD_command_write(0x36); // Memory Access Control
// MY - Row Address Order (bit7)
// MX - Column Address Order
// MV - Row / Column Exchange
// ML - Vertical Refresh Order
// BGR - RGB-BGR Order
// MH - Horizontal Refresh ORDER(bit2)
LCD_data_write(B00001000);
LCD_command_write(0x11); // Sleep OUT
LCD_command_write(0x29); // Display ON
delay(50);
}
void LCD_rect(int16_t col,int16_t row, int16_t width, int16_t height, int16_t color) {
LCD_command_write(0x2a); // Column Address Set
LCD_data_write(row>>8);
LCD_data_write(row);
LCD_data_write((row+height-1)>>8);
LCD_data_write(row+height-1);
LCD_command_write(0x2b); // Page Address Set
LCD_data_write(col>>8);
LCD_data_write(col);
LCD_data_write((col+width-1)>>8);
LCD_data_write(col+width-1);
LCD_command_write(0x2c); // Memory Write
byte chigh=color >> 8;
byte clow=color;
int i,j;
for(i=0;i<width;i++)
for(j=0;j<height;j++)
{
LCD_data_write(chigh);
LCD_data_write(clow);
}
}
void LCD_clear(byte color) {
/*
Accelerate screen clearing sacrifing color depth. Instead of writing
to data bits high and low byte of the color for each pixel, which takes more
than 300ms to fill the screen, set once data bits to 0's for black or
to 1's for white and start changing control bit WR from LOW to HIGH to
write whole area. It takes cca 70 ms. In this way the color of screen are
limited to those with the same high and low byte. For example setting color
to 0x0C fills the screen with color 0x0C0C.
Writing two pixels in one cycle lowering cycle count from 76800 (240x320) to
38400 clears screen in less then 30ms.
*/
LCD_command_write(0x2a);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(0xEC);
LCD_command_write(0x2b);
LCD_data_write(0);
LCD_data_write(0);
LCD_data_write(1);
LCD_data_write(0x3F);
LCD_command_write(0x2c);
PORTC = PORTC | B00000100; // LCD_RS = 1 - DATA
PORTD = (PORTD & B00000011) | ((color) & B11111100);
PORTB = (PORTB & B11111100) | ((color) & B00000011);
uint16_t x;
x=38400; // 240*320/2
byte wr0=PORTC & B11111101; // set WR 0
byte wr1=PORTC | B00000010; // set WR 1
for(uint16_t y=0;y<x;y++)
{
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
PORTC = wr0;
PORTC = wr1;
}
}
void Display_integer(int16_t n) {
String str=String(n);
byte l=str.length();
char b[l+1]; // +1 for the null terminator
str.toCharArray(b,l+1);
for(int n=0; n<l; n++) {
Display_char(b[n]);
}
}
void Display_string(String str) {
byte l=str.length();
char b[l+1]; // +1 for the null terminator
str.toCharArray(b,l+1);
for(int n=0; n<l; n++) {
Display_char(b[n]);
}
}
void Display_char(char znak) {
static const byte ASCII[][5] =
{
{0x00, 0x00, 0x00, 0x00, 0x00}, // 20
{0x00, 0x00, 0x5f, 0x00, 0x00}, // 21 !
{0x00, 0x07, 0x00, 0x07, 0x00}, // 22 "
{0x14, 0x7f, 0x14, 0x7f, 0x14}, // 23 #
{0x24, 0x2a, 0x7f, 0x2a, 0x12} ,// 24 $
{0x23, 0x13, 0x08, 0x64, 0x62}, // 25 %
{0x36, 0x49, 0x55, 0x22, 0x50}, // 26 &
{0x00, 0x00, 0x07, 0x05, 0x07}, // 27 '
{0x00, 0x1c, 0x22, 0x41, 0x00}, // 28 (
{0x00, 0x41, 0x22, 0x1c, 0x00}, // 29 )
{0x14, 0x08, 0x3e, 0x08, 0x14}, // 2a *
{0x08, 0x08, 0x3e, 0x08, 0x08}, // 2b +
{0x00, 0x50, 0x30, 0x00, 0x00}, // 2c ,
{0x08, 0x08, 0x08, 0x08, 0x08}, // 2d -
{0x00, 0x60, 0x60, 0x00, 0x00}, // 2e .
{0x20, 0x10, 0x08, 0x04, 0x02}, // 2f /
{0x3e, 0x51, 0x49, 0x45, 0x3e}, // 30 0
{0x00, 0x42, 0x7f, 0x40, 0x00}, // 31 1
{0x42, 0x61, 0x51, 0x49, 0x46}, // 32 2
{0x21, 0x41, 0x45, 0x4b, 0x31}, // 33 3
{0x18, 0x14, 0x12, 0x7f, 0x10}, // 34 4
{0x27, 0x45, 0x45, 0x45, 0x39}, // 35 5
{0x3c, 0x4a, 0x49, 0x49, 0x30}, // 36 6
{0x01, 0x71, 0x09, 0x05, 0x03}, // 37 7
{0x36, 0x49, 0x49, 0x49, 0x36}, // 38 8
{0x06, 0x49, 0x49, 0x29, 0x1e}, // 39 9
{0x00, 0x36, 0x36, 0x00, 0x00}, // 3a :
{0x00, 0x56, 0x36, 0x00, 0x00}, // 3b ;
{0x08, 0x14, 0x22, 0x41, 0x00}, // 3c <
{0x14, 0x14, 0x14, 0x14, 0x14}, // 3d =
{0x00, 0x41, 0x22, 0x14, 0x08}, // 3e >
{0x02, 0x01, 0x51, 0x09, 0x06}, // 3f ?
{0x32, 0x49, 0x79, 0x41, 0x3e}, // 40 @
{0x7e, 0x11, 0x11, 0x11, 0x7e}, // 41 A
{0x7f, 0x49, 0x49, 0x49, 0x36}, // 42 B
{0x3e, 0x41, 0x41, 0x41, 0x22}, // 43 C
{0x7f, 0x41, 0x41, 0x22, 0x1c}, // 44 D
{0x7f, 0x49, 0x49, 0x49, 0x41}, // 45 E
{0x7f, 0x09, 0x09, 0x09, 0x01}, // 46 F
{0x3e, 0x41, 0x49, 0x49, 0x7a}, // 47 G
{0x7f, 0x08, 0x08, 0x08, 0x7f}, // 48 H
{0x00, 0x41, 0x7f, 0x41, 0x00}, // 49 I
{0x20, 0x40, 0x41, 0x3f, 0x01}, // 4a J
{0x7f, 0x08, 0x14, 0x22, 0x41}, // 4b K
{0x7f, 0x40, 0x40, 0x40, 0x40}, // 4c L
{0x7f, 0x02, 0x0c, 0x02, 0x7f}, // 4d M
{0x7f, 0x04, 0x08, 0x10, 0x7f}, // 4e N
{0x3e, 0x41, 0x41, 0x41, 0x3e}, // 4f O
{0x7f, 0x09, 0x09, 0x09, 0x06}, // 50 P
{0x3e, 0x41, 0x51, 0x21, 0x5e}, // 51 Q
{0x7f, 0x09, 0x19, 0x29, 0x46}, // 52 R
{0x46, 0x49, 0x49, 0x49, 0x31}, // 53 S
{0x01, 0x01, 0x7f, 0x01, 0x01}, // 54 T
{0x3f, 0x40, 0x40, 0x40, 0x3f}, // 55 U
{0x1f, 0x20, 0x40, 0x20, 0x1f}, // 56 V
{0x3f, 0x40, 0x38, 0x40, 0x3f}, // 57 W
{0x63, 0x14, 0x08, 0x14, 0x63}, // 58 X
{0x07, 0x08, 0x70, 0x08, 0x07}, // 59 Y
{0x61, 0x51, 0x49, 0x45, 0x43}, // 5a Z
{0x00, 0x7f, 0x41, 0x41, 0x00}, // 5b [
{0x02, 0x04, 0x08, 0x10, 0x20}, // 5c Y
{0x00, 0x41, 0x41, 0x7f, 0x00}, // 5d ]
{0x04, 0x02, 0x01, 0x02, 0x04}, // 5e ^
{0x40, 0x40, 0x40, 0x40, 0x40}, // 5f _
{0x00, 0x01, 0x02, 0x04, 0x00}, // 60 `
{0x20, 0x54, 0x54, 0x54, 0x78}, // 61 a
{0x7f, 0x48, 0x44, 0x44, 0x38}, // 62 b
{0x38, 0x44, 0x44, 0x44, 0x20}, // 63 c
{0x38, 0x44, 0x44, 0x48, 0x7f}, // 64 d
{0x38, 0x54, 0x54, 0x54, 0x18}, // 65 e
{0x08, 0x7e, 0x09, 0x01, 0x02}, // 66 f
{0x0c, 0x52, 0x52, 0x52, 0x3e}, // 67 g
{0x7f, 0x08, 0x04, 0x04, 0x78}, // 68 h
{0x00, 0x44, 0x7d, 0x40, 0x00}, // 69 i
{0x20, 0x40, 0x44, 0x3d, 0x00}, // 6a j
{0x7f, 0x10, 0x28, 0x44, 0x00}, // 6b k
{0x00, 0x41, 0x7f, 0x40, 0x00}, // 6c l
{0x7c, 0x04, 0x18, 0x04, 0x78}, // 6d m
{0x7c, 0x08, 0x04, 0x04, 0x78}, // 6e n
{0x38, 0x44, 0x44, 0x44, 0x38}, // 6f o
{0x7c, 0x14, 0x14, 0x14, 0x08}, // 70 p
{0x08, 0x14, 0x14, 0x18, 0x7c}, // 71 q
{0x7c, 0x08, 0x04, 0x04, 0x08}, // 72 r
{0x48, 0x54, 0x54, 0x54, 0x20}, // 73 s
{0x04, 0x3f, 0x44, 0x40, 0x20}, // 74 t
{0x3c, 0x40, 0x40, 0x20, 0x7c}, // 75 u
{0x1c, 0x20, 0x40, 0x20, 0x1c}, // 76 v
{0x3c, 0x40, 0x30, 0x40, 0x3c}, // 77 w
{0x44, 0x28, 0x10, 0x28, 0x44}, // 78 x
{0x0c, 0x50, 0x50, 0x50, 0x3c}, // 79 y
{0x44, 0x64, 0x54, 0x4c, 0x44}, // 7a z
{0x00, 0x08, 0x36, 0x41, 0x00}, // 7b {
{0x00, 0x00, 0x7f, 0x00, 0x00}, // 7c |
{0x00, 0x41, 0x36, 0x08, 0x00}, // 7d }
{0x10, 0x08, 0x08, 0x10, 0x08}, // 7e ‹
{0x00, 0x06, 0x09, 0x09, 0x06} // 7f ›
};
int8_t size=F_SIZE;
int16_t color=F_COLOR;
int16_t bcolor=B_COLOR;
if( (P_COL+(size*6)) > 319) {
P_COL=0;
P_ROW+=size*(8+1);
}
LCD_command_write(0x2a); // ROWS
LCD_data_write(P_ROW>>8);
LCD_data_write(P_ROW);
LCD_data_write(((P_ROW+size*8)-1)>>8);
LCD_data_write((P_ROW+size*8)-1);
LCD_command_write(0x2b); // COLUMNS
LCD_data_write(P_COL>>8);
LCD_data_write(P_COL);
LCD_data_write((P_COL+(size*6))>>8);
LCD_data_write(P_COL+(size*6));
LCD_command_write(0x2c);
byte bchigh=bcolor >> 8;
byte bclow=bcolor;
byte fchigh=color >> 8;
byte fclow=color;
byte index, nbit, i, j;
for (index = 0; index < 5; index++) {
char col=ASCII[znak - 0x20][index];
for ( i=0; i<size; i++){
byte mask=B00000001;
for (nbit = 0; nbit < 8; nbit++) {
if (col & mask) {
for (j=0; j<size; j++){
LCD_data_write(fchigh);
LCD_data_write(fclow);
}
}
else {
for (j=0; j<size; j++){
LCD_data_write(bchigh);
LCD_data_write(bclow);
}
}
mask=mask<<1;
}
}
}
/*for ( i=0; i<size; i++){
for (nbit = 0; nbit < 8; nbit++) {
for (j=0; j<size; j++){
LCD_data_write(bchigh);
LCD_data_write(bclow);
}
}
}*/
P_COL+=size*6;
}
void Display_clear_char(byte n) {
// delete n chars
int8_t size=F_SIZE;
int16_t bcolor=B_COLOR;
LCD_command_write(0x2a); // ROWS
LCD_data_write(P_ROW>>8);
LCD_data_write(P_ROW);
LCD_data_write(((P_ROW+size*8)-1)>>8);
LCD_data_write((P_ROW+size*8)-1);
LCD_command_write(0x2b); // COLUMNS
LCD_data_write(P_COL>>8);
LCD_data_write(P_COL);
LCD_data_write((P_COL+(size*6*n))>>8);
LCD_data_write(P_COL+(size*6*n));
LCD_command_write(0x2c);
byte bchigh=bcolor >> 8;
byte bclow=bcolor;
int16_t cyc=size*8 * size*6*n;
for (int16_t i=0; i<cyc; i++) {
LCD_data_write(bchigh);
LCD_data_write(bclow);
}
}
byte ReadTouch(void) {
//Y1 A3
//X1 A2
//Y2 9
//X2 8
int16_t row, col;
int8_t touch, wait_touch, valid;
wait_touch=1;
valid=0;
while (wait_touch) {
pinMode(Y1, INPUT);
pinMode(Y2, INPUT_PULLUP);
pinMode(X1, OUTPUT);
pinMode(X2, OUTPUT);
digitalWrite(X1, LOW);
digitalWrite(X2, LOW);
touch = !digitalRead(Y1); // 0 - touched
if (touch) {
//delay(5);
digitalWrite(X1, HIGH); // X variant A
//digitalWrite(X2, HIGH); // X variant B
delay(1);
row = analogRead(Y1);
delay(4);
if (abs(analogRead(Y1)-row)>3) { return 0;}
delay(3);
if (abs(analogRead(Y1)-row)>3) { return 0;}
//if (analogRead(Y1)!=row) { return 0;}
pinMode(X1, INPUT);
pinMode(X2, INPUT_PULLUP);
pinMode(Y1, OUTPUT);
pinMode(Y2, OUTPUT);
//digitalWrite(Y1, HIGH); // Y variant A
//digitalWrite(Y2, LOW); // Y variant A
digitalWrite(Y1, LOW); // Y variant B
digitalWrite(Y2, HIGH); // Y variant B
delay(1);
col = analogRead(X1);
delay(4);
if (abs(analogRead(X1)-col)>3) { return 0;}
delay(3);
if (abs(analogRead(X1)-col)>3) { return 0;}
//if (analogRead(X1)!=col) { return 0;}
//digitalWrite(Y1, LOW); // Y variant A
digitalWrite(Y2, LOW); // Y variant B
//delay(5);
touch = !digitalRead(X1); // 0 - dotyk
if (touch) {
int16_t rows=ROW_L-ROW_F;
int16_t cols=COL_L-COL_F;
float row1=float(row-ROW_F)/rows*240;
float col1=float(col-COL_F)/cols*320;
T_ROW=int(row1);
T_COL=int(col1);
valid=1;
}
wait_touch=0;
}
}
// Re-Set A2 A3 8 9 for ILI9341
BD_as_output();
DDRC = DDRC | B00011111; // A0-A4 as outputs
// To find out values for calibration F_ROW, L_ROW, F_COL, F_COL
// /*
B_COLOR=0x0C0C;
F_SIZE=2;
P_COL=230;
P_ROW=200;
Display_integer(row);
P_COL=280;
P_ROW=200;
Display_integer(col);
P_COL=230;
P_ROW=220;
Display_clear_char(3);
Display_integer(T_ROW);
P_COL=280;
P_ROW=220;
Display_clear_char(3);
Display_integer(T_COL);
B_COLOR=GREEN;
F_SIZE=3;
// */
// Draw a point where touched
LCD_rect(T_COL-1,T_ROW-1, 2, 2,F_COLOR);
return valid;
}
uint16_t D_COL, D_ROW;
void setup()
{
Serial.begin(9600);
// Set pins 1-8 as output
BD_as_output();
// Set pins A0-A4 as output
DDRC = DDRC | B00011111;
LCD_init();
LCD_clear(0x0C);
B_COLOR=GREEN;
F_COLOR=BLACK;
// draw a keypad
for (int i=0; i<11; i++) {
P_COL=K_COL[i];
P_ROW=K_ROW[i];
LCD_rect(P_COL,P_ROW, 30, 30, GREEN);
P_COL=K_COL[i]+8;
P_ROW=K_ROW[i]+4;
Display_string(K_LABEL[i]);
}
D_COL=10; // where to display number from keypad
D_ROW=10;
}
void loop()
{
byte touch=ReadTouch() ;
if(touch) {
for (int i=0; i<11; i++) {
if ( T_COL>K_COL[i] && T_COL<K_COL[i]+30 && T_ROW>K_ROW[i] && T_ROW<K_ROW[i]+30 ) {
P_COL=K_COL[i];
P_ROW=K_ROW[i];
LCD_rect(P_COL,P_ROW, 30, 30, RED);
P_COL=K_COL[i]+8;
P_ROW=K_ROW[i]+4;
B_COLOR=RED;
Display_string(K_LABEL[i]);
if (K_LABEL[i]=="<") {
if (D_COL>10){
D_COL-=F_SIZE*6;
P_COL=D_COL;
P_ROW=D_ROW;
B_COLOR=0x0C0C;
Display_clear_char(1);
}
}
else if( (D_COL+(F_SIZE*6)) < 320 ) {
P_COL=D_COL;
P_ROW=D_ROW;
B_COLOR=0x0C0C;
Display_string(K_LABEL[i]);
D_COL=P_COL;
D_ROW=P_ROW;
}
delay(100);
P_COL=K_COL[i];
P_ROW=K_ROW[i];
LCD_rect(P_COL,P_ROW, 30, 30, GREEN);
P_COL=K_COL[i]+8;
P_ROW=K_ROW[i]+4;
B_COLOR=GREEN;
Display_string(K_LABEL[i]);
}
}
}
}
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