/************************************************************************* * Arduino Text & Bitmap Display Library for color LCDs * Distributed under GPL v2.0 * Developed by Stanley Huang * For more information, please visit http://arduinodev.com *************************************************************************/ #include #include "MultiLCD.h" /********************************************** Define zone **********************************************/ #if defined(__AVR_ATmega2560__) || defined(__AVR_ATmega1280__) #define RS 59 #define WR 58 #define CS 57 #define RST 56 #define T_CLK 55 #define T_CS 60 #define T_DIN 54 #define T_DOUT 8 #define T_IRQ 9 #define X_CONST 240 #define Y_CONST 320 #define PREC_TOUCH_CONST 10 #define PixSizeX 13.78 #define PixOffsX 411 #define PixSizeY 11.01 #define PixOffsY 378 #define WINDOW_XADDR_START 0x0050 // Horizontal Start Address Set #define WINDOW_XADDR_END 0x0051 // Horizontal End Address Set #define WINDOW_YADDR_START 0x0052 // Vertical Start Address Set #define WINDOW_YADDR_END 0x0053 // Vertical End Address Set #define GRAM_XADDR 0x0020 // GRAM Horizontal Address Set #define GRAM_YADDR 0x0021 // GRAM Vertical Address Set #define GRAMWR 0x0022 // memory write /* LCD color */ #define White 0xFFFF #define Black 0x0000 #define Blue 0x001F #define Blue2 0x051F #define Red 0xF800 #define Magenta 0xF81F #define Green 0x07E0 #define Cyan 0x7FFF #define Yellow 0xFFE0 /********************************************** Standard C functions zone **********************************************/ void LCD_ILI9325D::Enable() { digitalWrite(CS,LOW); } void LCD_ILI9325D::Disable() { digitalWrite(CS,HIGH); } void LCD_ILI9325D::SetCommandMode() { digitalWrite(CS,HIGH); digitalWrite(RS, LOW); digitalWrite(CS,LOW); } void LCD_ILI9325D::SetDataMode() { digitalWrite(CS,HIGH); digitalWrite(RS, HIGH); digitalWrite(CS,LOW); } void LCD_ILI9325D::WriteData(byte l, byte h) { if (h != lastData) { PORTE = (h & 0x3) | ((h & 0xC) << 2) | ((h & 0x20) >> 2); PORTG = (h & 0x10) << 1; PORTH = (h & 0xC0) >> 3; lastData = h; } digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; if (l != lastData) { PORTE = (l & 0x3) | ((l & 0xC) << 2) | ((l & 0x20) >> 2); PORTG = (l & 0x10) << 1; PORTH = (l & 0xC0) >> 3; lastData = l; } digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; } void LCD_ILI9325D::WriteData(uint16_t c) { byte value = *((unsigned char*)&c + 1); if (value != lastData) { PORTE = (value & 0x3) | ((value & 0xC) << 2) | ((value & 0x20) >> 2); PORTG = (value & 0x10) << 1; PORTH = (value & 0xC0) >> 3; lastData = value; } digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; value = (unsigned char)c; if (value != lastData) { PORTE = (value & 0x3) | ((value & 0xC) << 2) | ((value & 0x20) >> 2); PORTG = (value & 0x10) << 1; PORTH = (value & 0xC0) >> 3; lastData = value; } digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; } void LCD_ILI9325D::WriteCommandData(uint16_t cmd,uint16_t dat) { SetCommandMode(); WriteData(cmd); SetDataMode(); WriteData(dat); } void LCD_ILI9325D::begin() { pinMode(RS,OUTPUT); pinMode(WR,OUTPUT); pinMode(CS,OUTPUT); pinMode(RST,OUTPUT); //DDRD = 0xFF; for(int a=0;a < 8;a++) { pinMode(a,OUTPUT); digitalWrite(a, LOW); } digitalWrite(RST,HIGH); delay(5); digitalWrite(RST,LOW); delay(5); digitalWrite(RST,HIGH); digitalWrite(CS,HIGH); digitalWrite(WR,HIGH); delay(50); PORTE = 0; PORTG = 0; PORTH = 0; lastData = 0; WriteCommandData(0x00E5, 0x78F0); // set SRAM internal timing WriteCommandData(0x0001, 0x0100); // set Driver Output Control WriteCommandData(0x0002, 0x0200); // set 1 line inversion WriteCommandData(0x0003, 0x1030); // set GRAM write direction and BGR=1. WriteCommandData(0x0004, 0x0000); // Resize register WriteCommandData(0x0008, 0x0207); // set the back porch and front porch WriteCommandData(0x0009, 0x0000); // set non-display area refresh cycle ISC[3:0] WriteCommandData(0x000A, 0x0000); // FMARK function WriteCommandData(0x000C, 0x0000); // RGB interface setting WriteCommandData(0x000D, 0x0000); // Frame marker Position WriteCommandData(0x000F, 0x0000); // RGB interface polarity //*************Power 00On sequence ****************// WriteCommandData(0x0010, 0x0000); // SAP, BT[3:0], AP, DSTB, SLP, STB WriteCommandData(0x0011, 0x0007); // DC1[2:0], DC0[2:0], VC[2:0] WriteCommandData(0x0012, 0x0000); // VREG1OUT voltage WriteCommandData(0x0013, 0x0000); // VDV[4:0] for VCOM amplitude WriteCommandData(0x0007, 0x0001); delay(200); // Dis-ch00arge capacitor power voltage WriteCommandData(0x0010, 0x1690); // SAP, BT[3:0], AP, DSTB, SLP, STB WriteCommandData(0x0011, 0x0227); // Set DC1[2:0], DC0[2:0], VC[2:0] delay(50); // Delay 50ms WriteCommandData(0x0012, 0x000D); // 0012 delay(50); // Delay 50ms WriteCommandData(0x0013, 0x1200); // VDV[4:0] for VCOM amplitude WriteCommandData(0x0029, 0x000A); // 04 VCM[5:0] for VCOMH WriteCommandData(0x002B, 0x000D); // Set Frame Rate delay(50); // Delay 50ms WriteCommandData(0x0020, 0x0000); // GRAM horizontal Address WriteCommandData(0x0021, 0x0000); // GRAM Vertical Address // ----------- Adjust00 the Gamma Curve ----------// WriteCommandData(0x0030, 0x0000); WriteCommandData(0x0031, 0x0404); WriteCommandData(0x0032, 0x0003); WriteCommandData(0x0035, 0x0405); WriteCommandData(0x0036, 0x0808); WriteCommandData(0x0037, 0x0407); WriteCommandData(0x0038, 0x0303); WriteCommandData(0x0039, 0x0707); WriteCommandData(0x003C, 0x0504); WriteCommandData(0x003D, 0x0808); //------------------ 00Set GRAM area ---------------// WriteCommandData(0x0050, 0x0000); // Horizontal GRAM Start Address WriteCommandData(0x0051, 0x00EF); // Horizontal GRAM End Address WriteCommandData(0x0052, 0x0000); // Vertical GRAM Start Address WriteCommandData(0x0053, 0x013F); // Vertical GRAM Start Address WriteCommandData(0x0060, 0xA700); // Gate Scan Line WriteCommandData(0x0061, 0x0001); // NDL,VLE, REV WriteCommandData(0x006A, 0x0000); // set scrolling line //-------------- Part00ial Display Control ---------// WriteCommandData(0x0080, 0x0000); WriteCommandData(0x0081, 0x0000); WriteCommandData(0x0082, 0x0000); WriteCommandData(0x0083, 0x0000); WriteCommandData(0x0084, 0x0000); WriteCommandData(0x0085, 0x0000); //-------------- Pane00l Control -------------------// WriteCommandData(0x0090, 0x0010); WriteCommandData(0x0092, 0x0000); WriteCommandData(0x0007, 0x0133); Disable(); m_color[0] = 0; m_color[1] = 0xffff; clear(); } void LCD_ILI9325D::setXY(uint16_t x0,uint16_t x1,uint16_t y1,uint16_t y0) { y1 = 319 - y1; y0 = 319 - y0; WriteCommandData(WINDOW_XADDR_START,x0); WriteCommandData(WINDOW_XADDR_END,x1); WriteCommandData(WINDOW_YADDR_START,y0); WriteCommandData(WINDOW_YADDR_END,y1); WriteCommandData(GRAM_XADDR,x0); WriteCommandData(GRAM_YADDR,y0); SetCommandMode(); WriteData(0x0022);//LCD_WriteCMD(GRAMWR); SetDataMode(); } void LCD_ILI9325D::clearPixels(uint16_t pixels) { digitalWrite(RS,HIGH);//LCD_RS=0; digitalWrite(CS,LOW);//LCD_CS =0; PORTE = 0; PORTG = 0; PORTH = 0; lastData = 0; do { digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; } while (--pixels); digitalWrite(CS,HIGH);//LCD_CS =0; } void LCD_ILI9325D::clear(uint16_t x, uint16_t y, uint16_t width, uint16_t height) { unsigned long count = (unsigned long)width * height; setXY(y, y + height - 1, x, x + width - 1); digitalWrite(RS,HIGH);//LCD_RS=0; digitalWrite(CS,LOW);//LCD_CS =0; PORTE = 0; PORTG = 0; PORTH = 0; lastData = 0; do { digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; digitalWrite(WR,LOW);//LCD_WR=0; digitalWrite(WR,HIGH);//LCD_WR=1; } while (--count); digitalWrite(CS,HIGH);//LCD_CS =0; m_x = x; m_y = y; } size_t LCD_ILI9325D::write(uint8_t c) { if (c == '\n') { m_x += (m_font + 1) << 3; return 0; } else if (c == '\r') { setXY(m_x, m_x + 7, m_y, 319); clearPixels((320 - m_y) * 8); m_y = 0; return 0; } if (m_font == FONT_SIZE_SMALL) { setXY(m_x, m_x + 7, m_y, m_y + 4); m_y += 6; if (m_y >= 320) { m_x += (m_font + 1) << 3; m_y = 0; if (m_x >= 240) { m_x = 0; } } if (c > 0x20 && c < 0x7f) { byte pgm_buffer[5]; memcpy_P(pgm_buffer, &font5x8[c - 0x21], 5); byte i = 4; do { unsigned char d = pgm_buffer[i]; for (byte j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } } while (i--); } else { clearPixels(5 * 8); } } else { setXY(m_x, m_x + 15, m_y, m_y + 7); m_y += 9; if (m_y >= 320) { m_x += (m_font + 1) << 3; m_y = 0; if (m_x >= 240) { m_x = 0; } } if (c > 0x20 && c < 0x7f) { byte pgm_buffer[16]; memcpy_P(pgm_buffer, &font8x16_terminal[c - 0x21], 16); for (byte i = 0; i < 16; i += 2) { unsigned char d = pgm_buffer[14 - i]; for (byte j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } d = pgm_buffer[15 - i]; for (byte j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } } } else { clearPixels(8 * 16); } } } void LCD_ILI9325D::writeDigit(byte n) { if (m_font == FONT_SIZE_LARGE) { setXY(m_x, m_x + 15, m_y, m_y + 15); m_y += 16; if (n <= 9) { byte pgm_buffer[32]; memcpy_P(pgm_buffer, &digits16x16[n], sizeof(pgm_buffer)); for (byte i = 0; i < 16; i++) { unsigned char d = pgm_buffer[15 - i]; for (byte j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } d = pgm_buffer[31 - i]; for (byte j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } } } else { clearPixels(16 * 16); } } else if (m_font == FONT_SIZE_XLARGE) { setXY(m_x, m_x + 23, m_y, m_y + 15); m_y += 18; if (n <= 9) { byte pgm_buffer[48]; memcpy_P(pgm_buffer, &digits16x24[n], sizeof(pgm_buffer)); for (int i = 0; i < 48; i += 3) { unsigned char d = pgm_buffer[45 - i]; for (int j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } d = pgm_buffer[46 - i]; for (int j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } d = pgm_buffer[47 - i]; for (int j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } } } else { clearPixels(16 * 24); } } else { write(n <= 9 ? ('0' + n) : ' '); } } void LCD_ILI9325D::draw(const byte* buffer, uint16_t width, uint16_t height) { byte rows = height >> 3; setXY(m_x, m_x + height - 1, m_y, m_y + width - 1); uint16_t i = width - 1; do { for (uint8_t h = 0; h < rows; h++) { byte d = pgm_read_byte_far(buffer + i + width * h); for (byte j = 0; j < 8; j++, d >>= 1) { WriteData(m_color[d & 1]); } } } while (i--); m_y += width; } void LCD_ILI9325D::draw(const byte* buffer, uint16_t width, uint16_t height, byte scaleX, byte scaleY) { byte rows = height >> 3; if (scaleY == 0) scaleY = scaleX; setXY(m_x, m_x + height - 1, m_y, m_y + width - 1); uint16_t i = width - 1; do { for (byte n = 0; n < scaleX; n++) { for (uint8_t h = 0; h < rows; h++) { byte d = pgm_read_byte_far(buffer + i + width * h); for (byte j = 0; j < 8; j++, d >>= 1) { for (byte m = 0; m < scaleY; m++) { WriteData(m_color[d & 1]); } } } } } while (i--); m_y += width * scaleX; } void LCD_ILI9325D::draw4bpp(const byte* buffer, uint16_t width, uint16_t height) { char buf[240]; setXY(m_x, m_x + height * 2 - 1, m_y, m_y + width * 2- 1); uint16_t i = width - 1; do { memcpy_P(buf, buffer + i * height * 2, height * 2); for (byte j = 0; j < height * 2; j += 2) { WriteData(buf[j], buf[j + 1]); WriteData(buf[j], buf[j + 1]); } for (byte j = 0; j < height * 2; j += 2) { WriteData(buf[j], buf[j + 1]); WriteData(buf[j], buf[j + 1]); } } while (i--); m_y += width * 2; } #endif