SPI Library for 240x320 TFT LCD with ILI9320, ILI9325 and ILI9328 chip
Dependents: KL25Z_ILI9320_Demo Mini-DK
Other LCD drivers
05-30-2014
Device initialization for ILI9325 and ILI9328 has been added to the library.
The library will auto-detect what driver chip is connected (ILI9320, ILI9325 or ILI9328) and use the appropriate init sequence.
Please use the Issues tab to report any problems.
SPI TFT library for LPC1768, LPC11U24 and KL25Z
Loading fonts
When using this libary, don't forget to load the TFT_FONTS library from Peter Drescher at http://mbed.org/users/dreschpe/code/TFT_fonts/
KL25Z : limitations
The filetoflash function (see below) is not available.
Writing to the LCD is a little slower as the KL25Z only supports 8-bit SPI communication.
LPC1768 and LPC11U24 : filetoflash (SD to CPU flash)
This library contains a function to copy an image from the SD card to the CPU flash memory.
It allows you to use an image as background without speed loss when writing other text and graphics.
By default, this option is enabled.
It can be disabled by adding following instruction BEFORE you load the library:
#define NO_FLASH_BUFFER
Since the flash memory has limited write endurance, DO NOT use this feature when you intend to read multiple images from the SD card (eg: when used as a photo frame).
Sample code
#include "mbed.h" // SPI TFT demo // NOTES // - Connect the LCD reset pin to the reset pin of the CPU board or connect a // separate reset circuit to the LCD reset pin (pull-up 10k to 3v3 + 100nf capacitor to GND). // - When using the mbed LPC1768 board, following hardware modifications are needed: // Connect the LCD reset pin to the nR input. // Connect a 100nF capacitor between the nR input and GND. // Connect a pushbutton parallel to the 100nF capacitor. // Use the new pushbutton as the reset button (instead of the LPC1768 on-board reset button). #define NO_FLASH_BUFFER // Do not use CPU flash for storing bitmaps #include "SPI_TFT_ILI9320.h" #include "Arial12x12.h" #include "Arial24x23.h" #include "Arial28x28.h" #include "font_big.h" SPI_TFT TFT(p11, p12, p13, p14,"TFT"); //mosi, miso, clk, cs int main (void) { TFT.claim(stdout); // send stdout to the TFT display // Disable stdout buffering, allows us to omit \n with printf. // More info at http://www.cplusplus.com/reference/cstdio/setvbuf/ setvbuf ( stdout , NULL , _IONBF , NULL ); TFT.background(Black); // set background to black TFT.foreground(White); // set chars to white TFT.cls(); // clear the screen TFT.set_font((unsigned char*) Arial12x12); // select the font TFT.locate(0,0); printf("ILI9320 SPI TFT library\n"); printf("Simple demo\n"); }
Demo code LPC1768 (Mini-DK board)
Import programLPC1768_Mini-DK
LPC1768 Mini-DK board with 2.8" SPI TFT and SPI touch
Demo code FRDM-KL25Z board
Import programKL25Z_ILI9320_Demo
KL25Z driving an ILI9320 LCD board with touch panel (HY28A-LCDB SPI)
SPI_TFT_ILI9320.cpp
- Committer:
- frankvnk
- Date:
- 2013-05-22
- Revision:
- 2:45a3c5aa99c3
- Parent:
- 0:630b4da97968
- Child:
- 3:a016fe71ed72
File content as of revision 2:45a3c5aa99c3:
/************************************************************************************************** ***** ***** ***** Name: SPI_TFT.cpp ***** ***** Ver.: 1.0 ***** ***** Date: 04/01/2013 ***** ***** Auth: Frank Vannieuwkerke ***** ***** Erik Olieman ***** ***** Func: library for 240*320 pixel TFT with ILI9320 LCD Controller ***** ***** ***** ***** Rewrite from Peter Drescher code - http://mbed.org/cookbook/SPI-driven-QVGA-TFT ***** ***** ***** **************************************************************************************************/ #include "SPI_TFT_ILI9320.h" #include "mbed.h" #define BPP 16 // Bits per pixel SPI_TFT::SPI_TFT(PinName mosi, PinName miso, PinName sclk, PinName cs, const char *name) : GraphicsDisplay(name), _spi(mosi, miso, sclk), _cs(cs) { char_x = 0; tft_reset(); set_orientation(0); backgroundimage = false; #ifndef NO_FLASH_BUFFER backgroundOrientation = 0; #endif } int SPI_TFT::width() { if (orientation == 0 || orientation == 2) return 240; else return 320; } int SPI_TFT::height() { if (orientation == 0 || orientation == 2) return 320; else return 240; } void SPI_TFT::set_orientation(unsigned int o) { orientation = o; WindowMax(); } void SPI_TFT::mod_orientation(void) { switch (orientation) { case 0: wr_reg(0x03, 0x10b0); // ID1 = 1, ID0 = 1, AM = 0 - Portrait break; case 1: wr_reg(0x03, 0x10a8); // ID1 = 1, ID0 = 0, AM = 0 - Landscape break; case 2: wr_reg(0x03, 0x1080); // ID1 = 0, ID0 = 0, AM = 1 - Portrait upside down break; case 3: wr_reg(0x03, 0x1098); // ID1 = 0, ID0 = 1, AM = 1 - Landscape upside down break; } } void SPI_TFT::wr_cmd(unsigned char cmd) { _cs = 0; _spi.write(0x70); _spi.write(0x00); _spi.write(cmd); _cs = 1; } void SPI_TFT::wr_dat(unsigned short dat) { unsigned char u,l; u = (dat >> 0x08); l = (dat & 0xff); _cs = 0; _spi.write(0x72); _spi.write(u); _spi.write(l); _cs = 1; } void SPI_TFT::wr_dat_start(void) { _spi.write(0x72); } unsigned short SPI_TFT::rd_dat(void) // IMPORTANT : SPI frequency needs to be lowered when reading { unsigned short val = 0; _cs = 0; _spi.frequency(SPI_F_LO); _spi.write(0x73); _spi.write(0x00); val = _spi.write(0x00); // Dummy read val = _spi.write(0x00); // Read D8..D15 val <<= 8; val |= _spi.write(0x00); // Read D0..D7 _cs = 1; _spi.frequency(SPI_F_HI); return (val); } void SPI_TFT::wr_reg(unsigned char reg, unsigned short val) { wr_cmd(reg); wr_dat(val); } unsigned short SPI_TFT::rd_reg(unsigned char reg) { wr_cmd(reg); return(rd_dat()); } unsigned short SPI_TFT::Read_ID(void) // IMPORTANT : SPI frequency needs to be lowered when reading { unsigned short val = 0; _cs = 0; _spi.write(0x70); _spi.write(0x00); _spi.write(0x00); _cs = 1; _spi.frequency(SPI_F_LO); _cs = 0; _spi.write(0x73); val = _spi.write(0x00); // Dummy read val = _spi.write(0x00); // Read D8..D15 val <<= 8; val |= _spi.write(0x00); // Read D0..D7 _cs = 1; _spi.frequency(SPI_F_HI); return (val); } void SPI_TFT::SetCursor( unsigned short Xpos, unsigned short Ypos ) { wr_reg(0x20, Xpos ); wr_reg(0x21, Ypos ); } void SPI_TFT::tft_reset() { _spi.format(8,3); // 8 bit spi mode 3 _spi.frequency(SPI_F_HI); // 48 Mhz SPI clock wr_reg(0x00,0x0000); wr_reg(0x01,0x0100); // Driver Output Control wr_reg(0x02,0x0700); // LCD Driver Waveform Control wr_reg(0x03,0x1030); // Set the scan mode wr_reg(0x04,0x0000); // Scaling Control wr_reg(0x08,0x0202); // Display Control 2 wr_reg(0x09,0x0000); // Display Control 3 wr_reg(0x0a,0x0000); // Frame Cycle Contal wr_reg(0x0c,(1<<0)); // Extern Display Interface Control 1 wr_reg(0x0d,0x0000); // Frame Maker Position wr_reg(0x0f,0x0000); // Extern Display Interface Control 2 wait_ms(50); wr_reg(0x07,0x0101); // Display Control wait_ms(50); wr_reg(0x10,(1<<12)|(0<<8)|(1<<7)|(1<<6)|(0<<4)); // Power Control 1 wr_reg(0x11,0x0007); // Power Control 2 wr_reg(0x12,(1<<8)|(1<<4)|(0<<0)); // Power Control 3 wr_reg(0x13,0x0b00); // Power Control 4 wr_reg(0x29,0x0000); // Power Control 7 wr_reg(0x2b,(1<<14)|(1<<4)); wr_reg(0x50,0); // Set X Start wr_reg(0x51,239); // Set X End wr_reg(0x52,0); // Set Y Start wr_reg(0x53,319); // Set Y End wait_ms(50); wr_reg(0x60,0x2700); // Driver Output Control wr_reg(0x61,0x0001); // Driver Output Control wr_reg(0x6a,0x0000); // Vertical Srcoll Control wr_reg(0x80,0x0000); // Display Position Partial Display 1 wr_reg(0x81,0x0000); // RAM Address Start Partial Display 1 wr_reg(0x82,0x0000); // RAM Address End-Partial Display 1 wr_reg(0x83,0x0000); // Displsy Position Partial Display 2 wr_reg(0x84,0x0000); // RAM Address Start Partial Display 2 wr_reg(0x85,0x0000); // RAM Address End Partial Display 2 wr_reg(0x90,(0<<7)|(16<<0)); // Frame Cycle Control wr_reg(0x92,0x0000); // Panel Interface Control 2 wr_reg(0x93,0x0001); // Panel Interface Control 3 wr_reg(0x95,0x0110); // Frame Cycle Control wr_reg(0x97,(0<<8)); wr_reg(0x98,0x0000); // Frame Cycle Control wr_reg(0x07,0x0133); wait_ms(100); WindowMax(); } void SPI_TFT::pixel(int x, int y, int color) { switch (orientation) { case 0: wr_reg(0x20, x); wr_reg(0x21, y); break; case 1: wr_reg(0x20, 239-y); wr_reg(0x21, x); break; case 2: wr_reg(0x20, 239-x); wr_reg(0x21, 319-y); break; case 3: wr_reg(0x20, y); wr_reg(0x21, 319-x); break; } wr_cmd(0x22); wr_dat(color); } void SPI_TFT::window(int x, int y, int w, int h) { unsigned int xw1, yh1; xw1 = x + w - 1; yh1 = y + h - 1; wr_reg(0x20, x); wr_reg(0x21, y); switch (orientation) { case 0: wr_reg(0x50, x); wr_reg(0x51, xw1); wr_reg(0x52, y); wr_reg(0x53, yh1); break; case 1: wr_reg(0x50, 239 - yh1); wr_reg(0x51, 239 - y); wr_reg(0x52, x); wr_reg(0x53, xw1); break; case 2: wr_reg(0x50, 239 - xw1); wr_reg(0x51, 239 - x); wr_reg(0x52, 319 - yh1); wr_reg(0x53, 319 - y); break; case 3: wr_reg(0x50, y); wr_reg(0x51, yh1); wr_reg(0x52, 319 - xw1); wr_reg(0x53, 319 - x); break; } } void SPI_TFT::WindowMax(void) { window(0, 0, width(), height()); } void SPI_TFT::cls (void) { if (backgroundimage == false) { unsigned long int index=0; wr_reg(0x03, 0x1030); WindowMax(); SetCursor(0,0); wr_cmd(0x22); _cs = 0; wr_dat_start(); _spi.format(16,3); int num = width()*height(); for( index = 0; index<num; index++ ) { _spi.fastWrite(_background); } _spi.clearRX(); _spi.format(8,3); _cs = 1; } #ifndef NO_FLASH_BUFFER else { int _orientation=orientation; set_orientation(backgroundOrientation); Bitmap(0,0,width(),height(),(unsigned char*) sector_start_adress[ 25 ]); set_orientation(_orientation); } #endif } void SPI_TFT::hline(int x0, int x1, int y, int color) { unsigned int index=0; int w; w = x1 - x0 + 1; mod_orientation(); window(x0,y,w,1); wr_cmd(0x22); _cs = 0; wr_dat_start(); _spi.format(16,3); int num = x1-x0; for( index = 0; index<num; index++ ) { _spi.fastWrite(color); } _spi.clearRX(); _spi.format(8,3); _cs = 1; return; } void SPI_TFT::vline(int x, int y0, int y1, int color) { unsigned int index=0; int h; h = y1 - y0 + 1; mod_orientation(); window(x,y0,1,h); wr_cmd(0x22); _cs = 0; wr_dat_start(); _spi.format(16,3); int num = y1-y0; for( index = 0; index<num; index++ ) { _spi.fastWrite(color); } _spi.clearRX(); _spi.format(8,3); _cs = 1; return; } void SPI_TFT::line(int x0, int y0, int x1, int y1, int color) { wr_reg(0x03, 0x1030); WindowMax(); int dx = 0, dy = 0; int dx_sym = 0, dy_sym = 0; int dx_x2 = 0, dy_x2 = 0; int di = 0; dx = x1-x0; dy = y1-y0; if (dx == 0) { // vertical line if (y1 > y0) vline(x0,y0,y1,color); else vline(x0,y1,y0,color); return; } if (dx > 0) { dx_sym = 1; } else { dx_sym = -1; } if (dy == 0) { // horizontal line if (x1 > x0) hline(x0,x1,y0,color); else hline(x1,x0,y0,color); return; } if (dy > 0) { dy_sym = 1; } else { dy_sym = -1; } dx = dx_sym*dx; dy = dy_sym*dy; dx_x2 = dx*2; dy_x2 = dy*2; if (dx >= dy) { di = dy_x2 - dx; while (x0 != x1) { pixel(x0, y0, color); x0 += dx_sym; if (di<0) { di += dy_x2; } else { di += dy_x2 - dx_x2; y0 += dy_sym; } } pixel(x0, y0, color); } else { di = dx_x2 - dy; while (y0 != y1) { pixel(x0, y0, color); y0 += dy_sym; if (di < 0) { di += dx_x2; } else { di += dx_x2 - dy_x2; x0 += dx_sym; } } pixel(x0, y0, color); } return; } void SPI_TFT::rect(int x0, int y0, int w, int h, int color) { hline(x0,x0+w,y0,color); vline(x0,y0,y0+h,color); hline(x0,x0+w,y0+h,color); vline(x0+w,y0,y0+h,color); return; } void SPI_TFT::fillrect(int x0, int y0, int w, int h, int color) { unsigned long int index=0; if (w < 0) { x0 = x0 + w; w = -w; } if (h < 0) { y0 = y0 + h; h = -h; } mod_orientation(); window(x0,y0,w,h); wr_cmd(0x22); _cs = 0; wr_dat_start(); _spi.format(16,3); int num = h*w; for( index = 0; index<num; index++ ) { _spi.fastWrite(color); } _spi.clearRX(); _spi.format(8,3); _cs = 1; return; } void SPI_TFT::draw_ellipse(int xc, int yc, int a, int b, unsigned int color) { /* e(x,y) = b^2*x^2 + a^2*y^2 - a^2*b^2 */ wr_reg(0x03, 0x1030); WindowMax(); int x = 0, y = b; long a2 = (long)a*a, b2 = (long)b*b; long crit1 = -(a2/4 + a%2 + b2); long crit2 = -(b2/4 + b%2 + a2); long crit3 = -(b2/4 + b%2); long t = -a2*y; // e(x+1/2,y-1/2) - (a^2+b^2)/4 long dxt = 2*b2*x, dyt = -2*a2*y; long d2xt = 2*b2, d2yt = 2*a2; while (y>=0 && x<=a) { pixel(xc+x, yc+y, color); if (x!=0 || y!=0) pixel(xc-x, yc-y, color); if (x!=0 && y!=0) { pixel(xc+x, yc-y, color); pixel(xc-x, yc+y, color); } if (t + b2*x <= crit1 || // e(x+1,y-1/2) <= 0 t + a2*y <= crit3) // e(x+1/2,y) <= 0 incx(); else if (t - a2*y > crit2) // e(x+1/2,y-1) > 0 incy(); else { incx(); incy(); } } } void SPI_TFT::fill_ellipse(int xc, int yc, int a, int b, unsigned int color) { /* e(x,y) = b^2*x^2 + a^2*y^2 - a^2*b^2 */ int x = 0, y = b; int rx = x, ry = y; unsigned int width = 1; unsigned int height = 1; long a2 = (long)a*a, b2 = (long)b*b; long crit1 = -(a2/4 + a%2 + b2); long crit2 = -(b2/4 + b%2 + a2); long crit3 = -(b2/4 + b%2); long t = -a2*y; // e(x+1/2,y-1/2) - (a^2+b^2)/4 long dxt = 2*b2*x, dyt = -2*a2*y; long d2xt = 2*b2, d2yt = 2*a2; if (b == 0) { fillrect(xc-a, yc, 2*a+1, 1, color); return; } while (y>=0 && x<=a) { if (t + b2*x <= crit1 || // e(x+1,y-1/2) <= 0 t + a2*y <= crit3) { // e(x+1/2,y) <= 0 if (height == 1) ; // draw nothing else if (ry*2+1 > (height-1)*2) { fillrect(xc-rx, yc-ry, width, height-1, color); fillrect(xc-rx, yc+ry+1, width, 1-height, color); ry -= height-1; height = 1; } else { fillrect(xc-rx, yc-ry, width, ry*2+1, color); ry -= ry; height = 1; } incx(); rx++; width += 2; } else if (t - a2*y > crit2) { // e(x+1/2,y-1) > 0 incy(); height++; } else { if (ry*2+1 > height*2) { fillrect(xc-rx, yc-ry, width, height, color); fillrect(xc-rx, yc+ry+1, width, -height, color); } else { fillrect(xc-rx, yc-ry, width, ry*2+1, color); } incx(); incy(); rx++; width += 2; ry -= height; height = 1; } } if (ry > height) { fillrect(xc-rx, yc-ry, width, height, color); fillrect(xc-rx, yc+ry+1, width, -height, color); } else { fillrect(xc-rx, yc-ry, width, ry*2+1, color); } } void SPI_TFT::locate(int x, int y) { char_x = x; char_y = y; } int SPI_TFT::columns() { return width() / font[1]; } int SPI_TFT::rows() { return height() / font[2]; } int SPI_TFT::_putc(int value) { if (value == '\n') { // new line char_x = 0; char_y = char_y + font[2]; if (char_y >= height() - font[2]) { char_y = 0; } } else { character(char_x, char_y, value); } return value; } void SPI_TFT::character(int x, int y, int c) { unsigned int hor,vert,offset,bpl,j,i,b; unsigned char* bitmap_char; unsigned char z,w; if ((c < 31) || (c > 127)) return; // test char range // read font parameter from start of array offset = font[0]; // bytes / char hor = font[1]; // get hor size of font vert = font[2]; // get vert size of font bpl = font[3]; // bytes per line if (char_x + hor > width()) { char_x = 0; char_y = char_y + vert; if (char_y >= height() - font[2]) { char_y = 0; } } mod_orientation(); bitmap_char = &font[((c -32) * offset) + 4]; // start of char bitmap w = bitmap_char[0]; // width of actual char window(char_x, char_y,hor,vert); // char box wr_cmd(0x22); _cs = 0; wr_dat_start(); _spi.format(16,3); for (j=0; j<vert; j++) { // vert line for (i=0; i<hor; i++) { // horz line z = bitmap_char[bpl * i + ((j & 0xF8) >> 3)+1]; b = 1 << (j & 0x07); if (( z & b ) == 0x00) { #ifndef NO_FLASH_BUFFER if (backgroundimage==false) #endif _spi.fastWrite(_background); #ifndef NO_FLASH_BUFFER else { unsigned short *bitmap_ptr = (unsigned short *)sector_start_adress[ 25 ]; int angle = (orientation - backgroundOrientation)%4; //Get the difference in orientation between background and current switch (angle) { case 0: //Same orientation bitmap_ptr += width() * (height()-(y+j+1))+x+i; break; case 1: //Rotated 1 (don't ask me which direction) bitmap_ptr += height() * (width()-(x+i+1))+height()-(y+j + 1); break; case 2: //Upside down bitmap_ptr += width() * (y+j)+width() - (x+i + 1); break; case 3: //Rotated 3 bitmap_ptr += height() * (x+i)+y+j; break; default: break; } _spi.fastWrite(*bitmap_ptr); } #endif } else { _spi.fastWrite(_foreground); } } } _spi.clearRX(); _spi.format(8,3); _cs = 1; if ((w + 2) < hor) { // x offset to next char char_x += w + 2; } else char_x += hor; } void SPI_TFT::set_font(unsigned char* f) { font = f; } void SPI_TFT::Bitmap(unsigned int x, unsigned int y, unsigned int w, unsigned int h,unsigned char *bitmap) { unsigned int i,j; unsigned short *bitmap_ptr = (unsigned short *)bitmap; mod_orientation(); window(x, y, w, h); wr_cmd(0x22); _cs = 0; wr_dat_start(); _spi.format(16,3); bitmap_ptr += ((h - 1)*w); for (j = 0; j < h; j++) { //Lines for (i = 0; i < w; i++) { // copy pixel data to TFT _spi.fastWrite(*bitmap_ptr); // one line bitmap_ptr++; } bitmap_ptr -= 2*w; } _spi.clearRX(); _spi.format(8,3); _cs = 1; } int SPI_TFT::Bitmap(unsigned int x, unsigned int y, const char *Name_BMP) { #define RGB565CONVERT(red, green, blue) (uint16_t)( (( red >> 3 ) << 11 ) | (( green >> 2 ) << 5 ) | ( blue >> 3 )) mod_orientation(); bitmapData bmp = getBitmapData(Name_BMP); if (bmp.return_code != 1) return bmp.return_code; unsigned char *line = (unsigned char *) malloc (bmp.bits/8 * bmp.width); // we need a buffer for a line unsigned short *line_short = (unsigned short*) (line); // Same one, addressed as short if ((bmp.height > height()+y) || (bmp.width > width()+x)) return -3; //Size mismatch if (line == NULL) return(-4); // error no memory for (int j = bmp.height-1; j >= 0; j--) { //Lines bottom up int off = j * (bmp.width * bmp.bits/8 + bmp.pad) + bmp.start_data; // start of line fseek(bmp.file, off ,SEEK_SET); fread(line,1,bmp.width * bmp.bits/8,bmp.file); // read a line - slow ! //If 24 bit format, convert to 565 if (bmp.bits == 24) { for (int i = 0; i<bmp.width; i++) { line_short[i] = RGB565CONVERT(line[3*i+2], line[3*i+1], line[3*i]); } } window(x, y+bmp.height - 1 - j,bmp.width ,1); wr_cmd(0x22); _cs = 0; wr_dat_start(); _spi.format(16, 3); _spi.setFormat(); for (int i = 0; i < bmp.width; i++) { // copy pixel data to TFT _spi.fastWrite(line_short[i]); // one line } _spi.clearRX(); _spi.format(8,3); _cs = 1; } free (line); fclose(bmp.file); WindowMax(); return(1); } #ifndef NO_FLASH_BUFFER int SPI_TFT::fileToFlash(const char *Name_BMP) { #define RGB565CONVERT(red, green, blue) (uint16_t)( (( red >> 3 ) << 11 ) | (( green >> 2 ) << 5 ) | ( blue >> 3 )) mod_orientation(); bitmapData bmp = getBitmapData(Name_BMP); if (bmp.return_code != 1) return bmp.return_code; unsigned char *line = (unsigned char *) malloc (bmp.bits/8 * bmp.width); // we need a buffer for a line unsigned short *line_short = (unsigned short*) (line); // Same one, addressed as short unsigned short *flashSector = (unsigned short *) malloc (256); //And one to send to flash if ((bmp.height != height()) || (bmp.width != width())) return -3; //Size mismatch if ((line == NULL) || (flashSector == NULL)) return(-4); // error no memory int flashPointer = 0, flashWrites = 0; //Erase Flash that will be used: if ( iap.blank_check( 25, 29 ) == SECTOR_NOT_BLANK ) { iap.prepare( 25, 29 ); iap.erase( 25, 29 ); } for (int j = 0; j < bmp.height; j++) { //Lines bottom up int off = j * (bmp.width * bmp.bits/8 + bmp.pad) + bmp.start_data; // start of line fseek(bmp.file, off ,SEEK_SET); fread(line,1,bmp.width * bmp.bits/8,bmp.file); // read a line - slow ! //If 24 bit format, do some processing if (bmp.bits == 24) { for (int i = 0; i<bmp.width; i++) { line_short[i] = RGB565CONVERT(line[3*i+2], line[3*i+1], line[3*i]); } } for (int i = 0; i < bmp.width; i++) { // copy pixel data to TFT flashSector[flashPointer] = line_short[i]; // one line flashPointer++; //If flashpointer reached the end, write to flash if (flashPointer == 128) { iap.prepare( 25, 29 ); iap.write((char *)flashSector, sector_start_adress[ 25 ] + 256 * flashWrites, 256); flashPointer = 0; flashWrites++; if (flashWrites == 1000) error("Too many flashwrites"); } } } //write remaining data if (flashPointer!=0) { iap.prepare( 25, 29 ); iap.write((char*)flashSector, sector_start_adress[ 25 ] + 256 * flashWrites, 256); flashPointer = 0; flashWrites++; if (flashWrites == 1000) error("Too many flashwrites"); } free (line); fclose(bmp.file); backgroundImage(true); backgroundOrientation = orientation; return(1); } void SPI_TFT::backgroundImage( bool active) { backgroundimage = active; } #endif SPI_TFT::bitmapData SPI_TFT::getBitmapData(const char *Name_BMP){ #define OffsetPixelWidth 18 #define OffsetPixelHeigh 22 #define OffsetFileSize 34 #define OffsetPixData 10 #define OffsetBPP 28 bitmapData retval; retval.return_code = 1; unsigned char BMP_Header[54]; retval.file = fopen(Name_BMP, "rb"); // open the bmp file if (!retval.file) { retval.return_code = 0; return(retval); // error file not found ! } fread(&BMP_Header[0],1,54,retval.file); // get the BMP Header if (BMP_Header[0] != 0x42 || BMP_Header[1] != 0x4D) { // check magic byte fclose(retval.file); retval.return_code = -1; return(retval); // error not a BMP file } int BPP_t = BMP_Header[OffsetBPP] + (BMP_Header[OffsetBPP + 1] << 8); if (BPP_t == 0x0010) retval.bits = 16; else if (BPP_t == 0x0018) retval.bits = 24; else { fclose(retval.file); retval.return_code = -2; return(retval); // error no 16/24 bit BMP } retval.height = BMP_Header[OffsetPixelHeigh] + (BMP_Header[OffsetPixelHeigh + 1] << 8) + (BMP_Header[OffsetPixelHeigh + 2] << 16) + (BMP_Header[OffsetPixelHeigh + 3] << 24); retval.width = BMP_Header[OffsetPixelWidth] + (BMP_Header[OffsetPixelWidth + 1] << 8) + (BMP_Header[OffsetPixelWidth + 2] << 16) + (BMP_Header[OffsetPixelWidth + 3] << 24); if (retval.height > height()|| retval.width > width()) { fclose(retval.file); retval.return_code = -3; return(retval); // too big } retval.start_data = BMP_Header[OffsetPixData] + (BMP_Header[OffsetPixData + 1] << 8) + (BMP_Header[OffsetPixData + 2] << 16) + (BMP_Header[OffsetPixData + 3] << 24); // the bmp lines are padded to multiple of 4 bytes retval.pad = -1; do { retval.pad ++; } while ((retval.width * retval.bits/8 + retval.pad)%4 != 0); return retval; }