acid-drop/lib/TFT_eSPI/examples/DMA test/boing_ball/boing_ball.ino

// 'Boing' ball demo

// STM32F767 55MHz SPI 170 fps without DMA
// STM32F767 55MHz SPI 227 fps with DMA
// STM32F446 55MHz SPI 110 fps without DMA
// STM32F446 55MHz SPI 187 fps with DMA
// STM32F401 55MHz SPI  56 fps without DMA
// STM32F401 55MHz SPI 120 fps with DMA

// STM32F767 27MHz SPI  99 fps without DMA
// STM32F767 27MHz SPI 120 fps with DMA
// STM32F446 27MHz SPI  73 fps without DMA
// STM32F446 27MHz SPI  97 fps with DMA
// STM32F401 27MHz SPI  51 fps without DMA
// STM32F401 27MHz SPI  90 fps with DMA

// Blue Pill - 36MHz SPI *no* DMA 36 fps
// Blue Pill - 36MHz SPI with DMA 67 fps
// Blue Pill overclocked to 128MHz *no* DMA - 32MHz SPI  64 fps
// Blue Pill overclocked to 128MHz with DMA - 32MHz SPI 116 fps

// ESP32     - 8 bit parallel     110 fps (no DMA)
// ESP32     - 40MHz SPI *no* DMA  93 fps
// ESP32     - 40MHz SPI with DMA 112 fps

#define SCREENWIDTH 320
#define SCREENHEIGHT 240

#include "graphic.h"

#include <TFT_eSPI.h> // Hardware-specific library

TFT_eSPI tft = TFT_eSPI();       // Invoke custom library

#define BGCOLOR    0xAD75
#define GRIDCOLOR  0xA815
#define BGSHADOW   0x5285
#define GRIDSHADOW 0x600C
#define RED        0xF800
#define WHITE      0xFFFF

#define YBOTTOM  123  // Ball Y coordinate at bottom
#define YBOUNCE -3.5  // Upward velocity on ball bounce

// Ball coordinates are stored floating-point because screen refresh
// is so quick, whole-pixel movements are just too fast!
float ballx     = 20.0, bally     = YBOTTOM, // Current ball position
      ballvx    =  0.8, ballvy    = YBOUNCE, // Ball velocity
      ballframe = 3;                         // Ball animation frame #
int   balloldx  = ballx, balloldy = bally;   // Prior ball position

// Working buffer for ball rendering...2 scan lines that alternate,
// one is rendered while the other is transferred via DMA.
uint16_t renderbuf[2][SCREENWIDTH];

uint16_t palette[16]; // Color table for ball rotation effect

uint32_t startTime, frame = 0; // For frames-per-second estimate

void setup() {
  Serial.begin(115200);
//  while(!Serial);

  tft.begin();
  tft.setRotation(3); // Landscape orientation, USB at bottom right
  tft.setSwapBytes(false);
  // Draw initial frame buffer contents:
  //tft.setBitmapColor(GRIDCOLOR, BGCOLOR);
  tft.fillScreen(BGCOLOR);

  tft.initDMA();

  tft.drawBitmap(0, 0, (const uint8_t *)background, SCREENWIDTH, SCREENHEIGHT, GRIDCOLOR);

  startTime = millis();
}

void loop() {

  balloldx = (int16_t)ballx; // Save prior position
  balloldy = (int16_t)bally;
  ballx   += ballvx;         // Update position
  bally   += ballvy;
  ballvy  += 0.06;          // Update Y velocity
  if((ballx <= 15) || (ballx >= SCREENWIDTH - BALLWIDTH))
    ballvx *= -1;            // Left/right bounce
  if(bally >= YBOTTOM) {     // Hit ground?
    bally  = YBOTTOM;        // Clip and
    ballvy = YBOUNCE;        // bounce up
  }

  // Determine screen area to update.  This is the bounds of the ball's
  // prior and current positions, so the old ball is fully erased and new
  // ball is fully drawn.
  int16_t minx, miny, maxx, maxy, width, height;
  // Determine bounds of prior and new positions
  minx = ballx;
  if(balloldx < minx)                    minx = balloldx;
  miny = bally;
  if(balloldy < miny)                    miny = balloldy;
  maxx = ballx + BALLWIDTH  - 1;
  if((balloldx + BALLWIDTH  - 1) > maxx) maxx = balloldx + BALLWIDTH  - 1;
  maxy = bally + BALLHEIGHT - 1;
  if((balloldy + BALLHEIGHT - 1) > maxy) maxy = balloldy + BALLHEIGHT - 1;

  width  = maxx - minx + 1;
  height = maxy - miny + 1;

  // Ball animation frame # is incremented opposite the ball's X velocity
  ballframe -= ballvx * 0.5;
  if(ballframe < 0)        ballframe += 14; // Constrain from 0 to 13
  else if(ballframe >= 14) ballframe -= 14;

  // Set 7 palette entries to white, 7 to red, based on frame number.
  // This makes the ball spin
  for(uint8_t i=0; i<14; i++) {
    palette[i+2] = ((((int)ballframe + i) % 14) < 7) ? WHITE : RED;
    // Palette entries 0 and 1 aren't used (clear and shadow, respectively)
  }

  // Only the changed rectangle is drawn into the 'renderbuf' array...
  uint16_t c, *destPtr;
  int16_t  bx  = minx - (int)ballx, // X relative to ball bitmap (can be negative)
           by  = miny - (int)bally, // Y relative to ball bitmap (can be negative)
           bgx = minx,              // X relative to background bitmap (>= 0)
           bgy = miny,              // Y relative to background bitmap (>= 0)
           x, y, bx1, bgx1;         // Loop counters and working vars
  uint8_t  p;                       // 'packed' value of 2 ball pixels
  int8_t bufIdx = 0;

  // Start SPI transaction and drop TFT_CS - avoids transaction overhead in loop
  tft.startWrite();

  // Set window area to pour pixels into
  tft.setAddrWindow(minx, miny, width, height);

  // Draw line by line loop
  for(y=0; y<height; y++) { // For each row...
    destPtr = &renderbuf[bufIdx][0];
    bx1  = bx;  // Need to keep the original bx and bgx values,
    bgx1 = bgx; // so copies of them are made here (and changed in loop below)
    for(x=0; x<width; x++) {
      if((bx1 >= 0) && (bx1 < BALLWIDTH) &&  // Is current pixel row/column
         (by  >= 0) && (by  < BALLHEIGHT)) { // inside the ball bitmap area?
        // Yes, do ball compositing math...
        p = ball[by][bx1 / 2];                // Get packed value (2 pixels)
        c = (bx1 & 1) ? (p & 0xF) : (p >> 4); // Unpack high or low nibble
        if(c == 0) { // Outside ball - just draw grid
          c = background[bgy][bgx1 / 8] & (0x80 >> (bgx1 & 7)) ? GRIDCOLOR : BGCOLOR;
        } else if(c > 1) { // In ball area...
          c = palette[c];
        } else { // In shadow area...
          c = background[bgy][bgx1 / 8] & (0x80 >> (bgx1 & 7)) ? GRIDSHADOW : BGSHADOW;
        }
      } else { // Outside ball bitmap, just draw background bitmap...
        c = background[bgy][bgx1 / 8] & (0x80 >> (bgx1 & 7)) ? GRIDCOLOR : BGCOLOR;
      }
      *destPtr++ = c<<8 | c>>8; // Store pixel colour
      bx1++;  // Increment bitmap position counters (X axis)
      bgx1++;
    }

    tft.pushPixelsDMA(&renderbuf[bufIdx][0], width); // Push line to screen

    // Push line to screen (swap bytes false for STM/ESP32)
    //tft.pushPixels(&renderbuf[bufIdx][0], width);

    bufIdx = 1 - bufIdx;
    by++; // Increment bitmap position counters (Y axis)
    bgy++;
  }
  //if (random(100) == 1) delay(2000);
  tft.endWrite();
  //delay(5);
  // Show approximate frame rate
  if(!(++frame & 255)) { // Every 256 frames...
    uint32_t elapsed = (millis() - startTime) / 1000; // Seconds
    if(elapsed) {
      Serial.print(frame / elapsed);
      Serial.println(" fps");
    }
  }
}
Initial commit 2024-05-23 18:42:03 -04:00			`// 'Boing' ball demo`

			`// STM32F767 55MHz SPI 170 fps without DMA`
			`// STM32F767 55MHz SPI 227 fps with DMA`
			`// STM32F446 55MHz SPI 110 fps without DMA`
			`// STM32F446 55MHz SPI 187 fps with DMA`
			`// STM32F401 55MHz SPI 56 fps without DMA`
			`// STM32F401 55MHz SPI 120 fps with DMA`

			`// STM32F767 27MHz SPI 99 fps without DMA`
			`// STM32F767 27MHz SPI 120 fps with DMA`
			`// STM32F446 27MHz SPI 73 fps without DMA`
			`// STM32F446 27MHz SPI 97 fps with DMA`
			`// STM32F401 27MHz SPI 51 fps without DMA`
			`// STM32F401 27MHz SPI 90 fps with DMA`

			`// Blue Pill - 36MHz SPI no DMA 36 fps`
			`// Blue Pill - 36MHz SPI with DMA 67 fps`
			`// Blue Pill overclocked to 128MHz no DMA - 32MHz SPI 64 fps`
			`// Blue Pill overclocked to 128MHz with DMA - 32MHz SPI 116 fps`

			`// ESP32 - 8 bit parallel 110 fps (no DMA)`
			`// ESP32 - 40MHz SPI no DMA 93 fps`
			`// ESP32 - 40MHz SPI with DMA 112 fps`

			`#define SCREENWIDTH 320`
			`#define SCREENHEIGHT 240`

			`#include "graphic.h"`

			`#include <TFT_eSPI.h> // Hardware-specific library`

			`TFT_eSPI tft = TFT_eSPI(); // Invoke custom library`

			`#define BGCOLOR 0xAD75`
			`#define GRIDCOLOR 0xA815`
			`#define BGSHADOW 0x5285`
			`#define GRIDSHADOW 0x600C`
			`#define RED 0xF800`
			`#define WHITE 0xFFFF`

			`#define YBOTTOM 123 // Ball Y coordinate at bottom`
			`#define YBOUNCE -3.5 // Upward velocity on ball bounce`

			`// Ball coordinates are stored floating-point because screen refresh`
			`// is so quick, whole-pixel movements are just too fast!`
			`float ballx = 20.0, bally = YBOTTOM, // Current ball position`
			`ballvx = 0.8, ballvy = YBOUNCE, // Ball velocity`
			`ballframe = 3; // Ball animation frame #`
			`int balloldx = ballx, balloldy = bally; // Prior ball position`

			`// Working buffer for ball rendering...2 scan lines that alternate,`
			`// one is rendered while the other is transferred via DMA.`
			`uint16_t renderbuf[2][SCREENWIDTH];`

			`uint16_t palette[16]; // Color table for ball rotation effect`

			`uint32_t startTime, frame = 0; // For frames-per-second estimate`

			`void setup() {`
			`Serial.begin(115200);`
			`// while(!Serial);`

			`tft.begin();`
			`tft.setRotation(3); // Landscape orientation, USB at bottom right`
			`tft.setSwapBytes(false);`
			`// Draw initial frame buffer contents:`
			`//tft.setBitmapColor(GRIDCOLOR, BGCOLOR);`
			`tft.fillScreen(BGCOLOR);`

			`tft.initDMA();`

			`tft.drawBitmap(0, 0, (const uint8_t *)background, SCREENWIDTH, SCREENHEIGHT, GRIDCOLOR);`

			`startTime = millis();`
			`}`

			`void loop() {`

			`balloldx = (int16_t)ballx; // Save prior position`
			`balloldy = (int16_t)bally;`
			`ballx += ballvx; // Update position`
			`bally += ballvy;`
			`ballvy += 0.06; // Update Y velocity`
			`if((ballx <= 15) \|\| (ballx >= SCREENWIDTH - BALLWIDTH))`
			`ballvx *= -1; // Left/right bounce`
			`if(bally >= YBOTTOM) { // Hit ground?`
			`bally = YBOTTOM; // Clip and`
			`ballvy = YBOUNCE; // bounce up`
			`}`

			`// Determine screen area to update. This is the bounds of the ball's`
			`// prior and current positions, so the old ball is fully erased and new`
			`// ball is fully drawn.`
			`int16_t minx, miny, maxx, maxy, width, height;`
			`// Determine bounds of prior and new positions`
			`minx = ballx;`
			`if(balloldx < minx) minx = balloldx;`
			`miny = bally;`
			`if(balloldy < miny) miny = balloldy;`
			`maxx = ballx + BALLWIDTH - 1;`
			`if((balloldx + BALLWIDTH - 1) > maxx) maxx = balloldx + BALLWIDTH - 1;`
			`maxy = bally + BALLHEIGHT - 1;`
			`if((balloldy + BALLHEIGHT - 1) > maxy) maxy = balloldy + BALLHEIGHT - 1;`

			`width = maxx - minx + 1;`
			`height = maxy - miny + 1;`

			`// Ball animation frame # is incremented opposite the ball's X velocity`
			`ballframe -= ballvx * 0.5;`
			`if(ballframe < 0) ballframe += 14; // Constrain from 0 to 13`
			`else if(ballframe >= 14) ballframe -= 14;`

			`// Set 7 palette entries to white, 7 to red, based on frame number.`
			`// This makes the ball spin`
			`for(uint8_t i=0; i<14; i++) {`
			`palette[i+2] = ((((int)ballframe + i) % 14) < 7) ? WHITE : RED;`
			`// Palette entries 0 and 1 aren't used (clear and shadow, respectively)`
			`}`

			`// Only the changed rectangle is drawn into the 'renderbuf' array...`
			`uint16_t c, *destPtr;`
			`int16_t bx = minx - (int)ballx, // X relative to ball bitmap (can be negative)`
			`by = miny - (int)bally, // Y relative to ball bitmap (can be negative)`
			`bgx = minx, // X relative to background bitmap (>= 0)`
			`bgy = miny, // Y relative to background bitmap (>= 0)`
			`x, y, bx1, bgx1; // Loop counters and working vars`
			`uint8_t p; // 'packed' value of 2 ball pixels`
			`int8_t bufIdx = 0;`

			`// Start SPI transaction and drop TFT_CS - avoids transaction overhead in loop`
			`tft.startWrite();`

			`// Set window area to pour pixels into`
			`tft.setAddrWindow(minx, miny, width, height);`

			`// Draw line by line loop`
			`for(y=0; y<height; y++) { // For each row...`
			`destPtr = &renderbuf[bufIdx][0];`
			`bx1 = bx; // Need to keep the original bx and bgx values,`
			`bgx1 = bgx; // so copies of them are made here (and changed in loop below)`
			`for(x=0; x<width; x++) {`
			`if((bx1 >= 0) && (bx1 < BALLWIDTH) && // Is current pixel row/column`
			`(by >= 0) && (by < BALLHEIGHT)) { // inside the ball bitmap area?`
			`// Yes, do ball compositing math...`
			`p = ball[by][bx1 / 2]; // Get packed value (2 pixels)`
			`c = (bx1 & 1) ? (p & 0xF) : (p >> 4); // Unpack high or low nibble`
			`if(c == 0) { // Outside ball - just draw grid`
			`c = background[bgy][bgx1 / 8] & (0x80 >> (bgx1 & 7)) ? GRIDCOLOR : BGCOLOR;`
			`} else if(c > 1) { // In ball area...`
			`c = palette[c];`
			`} else { // In shadow area...`
			`c = background[bgy][bgx1 / 8] & (0x80 >> (bgx1 & 7)) ? GRIDSHADOW : BGSHADOW;`
			`}`
			`} else { // Outside ball bitmap, just draw background bitmap...`
			`c = background[bgy][bgx1 / 8] & (0x80 >> (bgx1 & 7)) ? GRIDCOLOR : BGCOLOR;`
			`}`
			`*destPtr++ = c<<8 \| c>>8; // Store pixel colour`
			`bx1++; // Increment bitmap position counters (X axis)`
			`bgx1++;`
			`}`

			`tft.pushPixelsDMA(&renderbuf[bufIdx][0], width); // Push line to screen`

			`// Push line to screen (swap bytes false for STM/ESP32)`
			`//tft.pushPixels(&renderbuf[bufIdx][0], width);`

			`bufIdx = 1 - bufIdx;`
			`by++; // Increment bitmap position counters (Y axis)`
			`bgy++;`
			`}`
			`//if (random(100) == 1) delay(2000);`
			`tft.endWrite();`
			`//delay(5);`
			`// Show approximate frame rate`
			`if(!(++frame & 255)) { // Every 256 frames...`
			`uint32_t elapsed = (millis() - startTime) / 1000; // Seconds`
			`if(elapsed) {`
			`Serial.print(frame / elapsed);`
			`Serial.println(" fps");`
			`}`
			`}`
			`}`