#include // Core graphics library #include #include #include #include "Adafruit_RA8875.h" #include #define sd_cs 6 // uding ethernet shield sd // Library only supports hardware SPI at this time // Connect SCLK to UNO Digital #13 (Hardware SPI clock) // Connect MISO to UNO Digital #12 (Hardware SPI MISO) // Connect MOSI to UNO Digital #11 (Hardware SPI MOSI) #define RA8875_INT 3 #define RA8875_CS 10 #define RA8875_RESET 9 Adafruit_RA8875 tft = Adafruit_RA8875(RA8875_CS, RA8875_RESET); void setup () { Serial.begin(9600); if (!SD.begin(sd_cs)) { Serial.println("initialization failed!"); return; } Serial.println("initialization done."); Serial.println("RA8875 start"); /* Initialise the display using 'RA8875_480x272' or 'RA8875_800x480' */ if (!tft.begin(RA8875_800x480)) { Serial.println("RA8875 Not Found!"); while (1); } Serial.println("Found RA8875"); tft.displayOn(true); tft.GPIOX(true); // Enable TFT - display enable tied to GPIOX tft.PWM1config(true, RA8875_PWM_CLK_DIV1024); // PWM output for backlight tft.PWM1out(255); Serial.print("("); Serial.print(tft.width()); Serial.print(", "); Serial.print(tft.height()); Serial.println(")"); tft.graphicsMode(); // go back to graphics mode tft.fillScreen(RA8875_BLACK); tft.graphicsMode(); bmpDraw("parrot.bmp", 0, 0); } void loop() { } // This function opens a Windows Bitmap (BMP) file and // displays it at the given coordinates. It's sped up // by reading many pixels worth of data at a time // (rather than pixel by pixel). Increasing the buffer // size takes more of the Arduino's precious RAM but // makes loading a little faster. 20 pixels seems a // good balance. #define BUFFPIXEL 20 void bmpDraw(char *filename, int x, int y) { File bmpFile; int bmpWidth, bmpHeight; // W+H in pixels uint8_t bmpDepth; // Bit depth (currently must be 24) uint32_t bmpImageoffset; // Start of image data in file uint32_t rowSize; // Not always = bmpWidth; may have padding uint8_t sdbuffer[3*BUFFPIXEL]; // pixel in buffer (R+G+B per pixel) uint16_t lcdbuffer[BUFFPIXEL]; // pixel out buffer (16-bit per pixel) uint8_t buffidx = sizeof(sdbuffer); // Current position in sdbuffer boolean goodBmp = false; // Set to true on valid header parse boolean flip = true; // BMP is stored bottom-to-top int w, h, row, col; uint8_t r, g, b; uint32_t pos = 0, startTime = millis(); uint8_t lcdidx = 0; boolean first = true; if((x >= tft.width()) || (y >= tft.height())) return; Serial.println(); Serial.print(F("Loading image '")); Serial.print(filename); Serial.println('\''); // Open requested file on SD card if ((bmpFile = SD.open(filename)) == NULL) { Serial.println(F("File not found")); return; } // Parse BMP header if(read16(bmpFile) == 0x4D42) { // BMP signature Serial.println(F("File size: ")); Serial.println(read32(bmpFile)); (void)read32(bmpFile); // Read & ignore creator bytes bmpImageoffset = read32(bmpFile); // Start of image data Serial.print(F("Image Offset: ")); Serial.println(bmpImageoffset, DEC); // Read DIB header Serial.print(F("Header size: ")); Serial.println(read32(bmpFile)); bmpWidth = read32(bmpFile); bmpHeight = read32(bmpFile); if(read16(bmpFile) == 1) { // # planes -- must be '1' bmpDepth = read16(bmpFile); // bits per pixel Serial.print(F("Bit Depth: ")); Serial.println(bmpDepth); if((bmpDepth == 24) && (read32(bmpFile) == 0)) { // 0 = uncompressed goodBmp = true; // Supported BMP format -- proceed! Serial.print(F("Image size: ")); Serial.print(bmpWidth); Serial.print('x'); Serial.println(bmpHeight); // BMP rows are padded (if needed) to 4-byte boundary rowSize = (bmpWidth * 3 + 3) & ~3; // If bmpHeight is negative, image is in top-down order. // This is not canon but has been observed in the wild. if(bmpHeight < 0) { bmpHeight = -bmpHeight; flip = false; } // Crop area to be loaded w = bmpWidth; h = bmpHeight; if((x+w-1) >= tft.width()) w = tft.width() - x; if((y+h-1) >= tft.height()) h = tft.height() - y; // Set TFT address window to clipped image bounds for (row=0; row= sizeof(sdbuffer)) { // Indeed // Push LCD buffer to the display first if(lcdidx > 0) { tft.drawPixel(col, row, lcdbuffer[lcdidx]); lcdidx = 0; first = false; } bmpFile.read(sdbuffer, sizeof(sdbuffer)); buffidx = 0; // Set index to beginning } // Convert pixel from BMP to TFT format b = sdbuffer[buffidx++]; g = sdbuffer[buffidx++]; r = sdbuffer[buffidx++]; lcdbuffer[lcdidx] = color565(r,g,b); tft.drawPixel(col, row, lcdbuffer[lcdidx]); } // end pixel } // end scanline // Write any remaining data to LCD if(lcdidx > 0) { tft.drawPixel(col, row, lcdbuffer[lcdidx]); } Serial.print(F("Loaded in ")); Serial.print(millis() - startTime); Serial.println(" ms"); } // end goodBmp } } bmpFile.close(); if(!goodBmp) Serial.println(F("BMP format not recognized.")); } // These read 16- and 32-bit types from the SD card file. // BMP data is stored little-endian, Arduino is little-endian too. // May need to reverse subscript order if porting elsewhere. uint16_t read16(File f) { uint16_t result; ((uint8_t *)&result)[0] = f.read(); // LSB ((uint8_t *)&result)[1] = f.read(); // MSB return result; } uint32_t read32(File f) { uint32_t result; ((uint8_t *)&result)[0] = f.read(); // LSB ((uint8_t *)&result)[1] = f.read(); ((uint8_t *)&result)[2] = f.read(); ((uint8_t *)&result)[3] = f.read(); // MSB return result; } uint16_t color565(uint8_t r, uint8_t g, uint8_t b) { return ((r & 0xF8) << 8) | ((g & 0xFC) << 3) | (b >> 3); } byte decToBcd(byte val){ // Convert normal decimal numbers to binary coded decimal return ( (val/10*16) + (val%10) ); }