Cleanup

2023-04-02 13:12:53 +01:00 · 2023-04-02 13:12:53 +01:00 · 7c2d527dd8
commit 7c2d527dd8
parent b101ae6997
6 changed files with 40 additions and 460 deletions
--- a/examples/BouncingSquares/BouncingSquares.ino
+++ b/examples/BouncingSquares/BouncingSquares.ino
@ -1,3 +1,9 @@
 // Example uses the following configuration:  mxconfig.double_buff = true;
 // to enable double buffering, which means display->flipDMABuffer(); is required.
 // Bounce squares around the screen, doing the re-drawing in the background back-buffer.
 // Double buffering is not always required in reality.
 #include <ESP32-HUB75-MatrixPanel-I2S-DMA.h>
 MatrixPanel_I2S_DMA *display = nullptr;
@ -32,14 +38,14 @@ void setup()
  Serial.println("...Starting Display");
  HUB75_I2S_CFG mxconfig;
-  //mxconfig.double_buff = true; // Turn of double buffer
+  mxconfig.double_buff = true; // <------------- Turn on double buffer
-  mxconfig.clkphase = false;
+  //mxconfig.clkphase = false;
  // OK, now we can create our matrix object
  display = new MatrixPanel_I2S_DMA(mxconfig);
  display->begin();  // setup display with pins as pre-defined in the library
-  // Create some Squares
+  // Create some random squares
  for (int i = 0; i < numSquares; i++)
  {
    Squares[i].square_size = random(2,10);
@ -47,8 +53,6 @@ void setup()
    Squares[i].ypos = random(0, display->height() - Squares[i].square_size);
    Squares[i].velocityx = static_cast <float> (rand()) / static_cast <float> (RAND_MAX);
    Squares[i].velocityy = static_cast <float> (rand()) / static_cast <float> (RAND_MAX);
    //Squares[i].xdir = (random(2) == 1) ? true:false;
    //Squares[i].ydir = (random(2) == 1) ? true:false;
    int random_num = random(6);
    Squares[i].colour = colours[random_num];
@ -57,9 +61,11 @@ void setup()
 void loop()
 {
-  display->flipDMABuffer(); // not used if double buffering isn't enabled
+  
-  delay(25);
+  display->flipDMABuffer(); // Show the back buffer, set currently output buffer to the back (i.e. no longer being sent to LED panels)
-  display->clearScreen();
+  display->clearScreen();   // Now clear the back-buffer
  delay(16);  // <----------- Shouldn't see this clearscreen occur as it happens on the back buffer when double buffering is enabled.
  for (int i = 0; i < numSquares; i++)
  {
--- a/examples/4_HueValueSpectrumDemo/4_HueValueSpectrumDemo.ino
+++ b/examples/4_HueValueSpectrumDemo/4_HueValueSpectrumDemo.ino
@ -1,75 +0,0 @@
 #define PANEL_RES_X 64    // Number of pixels wide of each INDIVIDUAL panel module. 
 #define PANEL_RES_Y 32     // Number of pixels tall of each INDIVIDUAL panel module.
 #define PANEL_CHAIN 1      // Total number of panels chained one to another
 #include <ESP32-HUB75-MatrixPanel-I2S-DMA.h>
 MatrixPanel_I2S_DMA *dma_display = nullptr;
 void setup() {
  HUB75_I2S_CFG::i2s_pins _pins={
    25, //R1_PIN, 
    26, //G1_PIN, 
    27, //B1_PIN, 
    14, //R2_PIN, 
    12, //G2_PIN, 
    13, //B2_PIN, 
    23, //A_PIN, 
    19, //B_PIN, 
    5, //C_PIN, 
    17, //D_PIN, 
    18, //E_PIN,
    4, //LAT_PIN, 
    15, //OE_PIN, 
    16, //CLK_PIN
  };
  HUB75_I2S_CFG mxconfig(
    PANEL_RES_X, // Module width
    PANEL_RES_Y, // Module height
    PANEL_CHAIN, // chain length
    _pins // pin mapping
  );
  //mxconfig.clkphase = false;
  //mxconfig.driver = HUB75_I2S_CFG::FM6126A;
  // Display Setup
  dma_display = new MatrixPanel_I2S_DMA(mxconfig);
  dma_display->begin();
  dma_display->clearScreen();
 }
 void loop() {
  // Canvas loop
  float t = (float)(millis()%4000)/4000.f;
  float tt = (float)((millis()%16000)/16000.f;
  for(int x = 0; x < PANEL_RES_X*PANEL_CHAIN; x++){
    // calculate the overal shade
    float f = ((sin(tt-(float)x/PANEL_RES_Y/32.)*2.f*PI)+1)/2)*255;
    // calculate hue spectrum into rgb
    float r = max(min(cosf(2.f*PI*(t+((float)x/PANEL_RES_Y+0.f)/3.f))+0.5f,1.f),0.f);
    float g = max(min(cosf(2.f*PI*(t+((float)x/PANEL_RES_Y+1.f)/3.f))+0.5f,1.f),0.f);
    float b = max(min(cosf(2.f*PI*(t+((float)x/PANEL_RES_Y+2.f)/3.f))+0.5f,1.f),0.f);
    // iterate pixels for every row
    for(int y = 0; y < PANEL_RES_Y; y++){
      if(y*2 < PANEL_RES_Y){
        // top-middle part of screen, transition of value
        float t = (2.f*y+1)/PANEL_RES_Y;
        dma_display->drawPixelRGB888(x,y,
          (r*t)*f,
          (g*t)*f,
          (b*t)*f
        );
      }else{
        // middle to bottom of screen, transition of saturation
        float t = (2.f*(PANEL_RES_Y-y)-1)/PANEL_RES_Y;
        dma_display->drawPixelRGB888(x,y,
          (r*t+1-t)*f,
          (g*t+1-t)*f,
          (b*t+1-t)*f
        );
      }
    }
  }
 }
--- a/examples/4_OtherShiftDriverPanel/4_OtherShiftDriverPanel.ino
+++ b/examples/4_OtherShiftDriverPanel/4_OtherShiftDriverPanel.ino
@ -1,19 +1,30 @@
-// How to use this library with a FM6126 panel, thanks goes to:
+/**********************************************************************
-// https://github.com/hzeller/rpi-rgb-led-matrix/issues/746
+ * The library by default supports simple 'shift register' based panels
 * with A,B,C,D,E lines to select a specific row, but there are plenty
 * of examples of new chips coming on the market that work different.
 *
 * Please search through the project's issues. For some of these chips
 * (you will need to look at the back of your panel to identify), this
 * library has workarounds. This can be configured through using one of:
 	// mxconfig.driver = HUB75_I2S_CFG::FM6126A;     
 	//mxconfig.driver = HUB75_I2S_CFG::ICN2038S;
 	//mxconfig.driver = HUB75_I2S_CFG::FM6124;
 	//mxconfig.driver = HUB75_I2S_CFG::MBI5124;	
 */
 #include <Arduino.h>
 #include <ESP32-HUB75-MatrixPanel-I2S-DMA.h>
 #include <FastLED.h>
 ////////////////////////////////////////////////////////////////////
 // FM6126 support is still experimental
 // Output resolution and panel chain length configuration
 #define PANEL_RES_X 64 	   // Number of pixels wide of each INDIVIDUAL panel module. 
 #define PANEL_RES_Y 32 	   // Number of pixels tall of each INDIVIDUAL panel module.
 #define PANEL_CHAIN 1      // Total number of panels chained one to another
 // placeholder for the matrix object
 MatrixPanel_I2S_DMA *dma_display = nullptr;
@ -34,21 +45,18 @@ CRGB ColorFromCurrentPalette(uint8_t index = 0, uint8_t brightness = 255, TBlend
 void setup(){
 	/*
 		The configuration for MatrixPanel_I2S_DMA object is held in HUB75_I2S_CFG structure,
 		All options has it's predefined default values. So we can create a new structure and redefine only the options we need
 		Please refer to the '2_PatternPlasma.ino' example for detailed example of how to use the MatrixPanel_I2S_DMA configuration
 		if you need to change the pin mappings etc.
 	*/
 	HUB75_I2S_CFG mxconfig(
 				PANEL_RES_X,   // module width
 				PANEL_RES_Y,   // module height
 				PANEL_CHAIN    // Chain length
 	);
-	mxconfig.driver = HUB75_I2S_CFG::FM6126A;     // in case that we use panels based on FM6126A chip, we can set it here before creating MatrixPanel_I2S_DMA object
+	// in case that we use panels based on FM6126A chip, we can set it here before creating MatrixPanel_I2S_DMA object
 	mxconfig.driver = HUB75_I2S_CFG::FM6126A;     
 	//mxconfig.driver = HUB75_I2S_CFG::ICN2038S;
 	//mxconfig.driver = HUB75_I2S_CFG::FM6124;
 	//mxconfig.driver = HUB75_I2S_CFG::MBI5124;	
 	// OK, now we can create our matrix object
 	dma_display = new MatrixPanel_I2S_DMA(mxconfig);
@ -100,3 +108,7 @@ void loop(){
      fps = 0;
    }
 }
 // FM6126 panel , thanks goes to:
 // https://github.com/hzeller/rpi-rgb-led-matrix/issues/746
--- a/examples/4_OtherShiftDriverPanel/FM6126A.md
+++ b/examples/4_OtherShiftDriverPanel/FM6126A.md
--- a/examples/4_OtherShiftDriverPanel/README.md
+++ b/examples/4_OtherShiftDriverPanel/README.md
--- a/src/ESP32-VirtualMatrixPanel-I2S-DMA.h-old
+++ b/src/ESP32-VirtualMatrixPanel-I2S-DMA.h-old
@ -1,363 +0,0 @@
 #ifndef _ESP32_VIRTUAL_MATRIX_PANEL_I2S_DMA
 #define _ESP32_VIRTUAL_MATRIX_PANEL_I2S_DMA
 /*******************************************************************
    Class contributed by Brian Lough, and expanded by Faptastic.
    Originally designed to allow CHAINING of panels together to create
    a 'bigger' display of panels. i.e. Chaining 4 panels into a 2x2
    grid.
    However, the function of this class has expanded now to also manage
    the output for
 	1) TWO scan panels = Two rows updated in parallel. 
 		* 64px high panel =  sometimes referred to as 1/32 scan
 		* 32px high panel =  sometimes referred to as 1/16 scan
 		* 16px high panel =  sometimes referred to as 1/8 scan
 	2) FOUR scan panels = Four rows updated in parallel
 		* 32px high panel = sometimes referred to as 1/8 scan 
 		* 16px high panel = sometimes referred to as 1/4 scan 
    YouTube: https://www.youtube.com/brianlough
    Tindie: https://www.tindie.com/stores/brianlough/
    Twitter: https://twitter.com/witnessmenow
 *******************************************************************/
 #include "ESP32-HUB75-MatrixPanel-I2S-DMA.h"
 #ifndef NO_GFX
 #include <Fonts/FreeSansBold12pt7b.h>
 #endif
 struct VirtualCoords
 {
  int16_t x;
  int16_t y;
  int16_t virt_row; // chain of panels row
  int16_t virt_col; // chain of panels col
  VirtualCoords() : x(0), y(0)
  {
  }
 };
 enum PANEL_SCAN_RATE
 {
  NORMAL_TWO_SCAN, NORMAL_ONE_SIXTEEN, // treated as the same
  FOUR_SCAN_32PX_HIGH,
  FOUR_SCAN_16PX_HIGH
 };
 #ifdef USE_GFX_ROOT
 class VirtualMatrixPanel : public GFX
 #elif !defined NO_GFX
 class VirtualMatrixPanel : public Adafruit_GFX
 #else
 class VirtualMatrixPanel
 #endif
 {
 public:
  int16_t virtualResX;
  int16_t virtualResY;
  int16_t vmodule_rows;
  int16_t vmodule_cols;
  int16_t panelResX;
  int16_t panelResY;
  int16_t dmaResX; // The width of the chain in pixels (as the DMA engine sees it)
  MatrixPanel_I2S_DMA *display;
  VirtualMatrixPanel(MatrixPanel_I2S_DMA &disp, int _vmodule_rows, int _vmodule_cols, int _panelResX, int _panelResY, bool serpentine_chain = true, bool top_down_chain = false)
 #ifdef USE_GFX_ROOT
      : GFX(_vmodule_cols * _panelResX, _vmodule_rows * _panelResY)
 #elif !defined NO_GFX
      : Adafruit_GFX(_vmodule_cols * _panelResX, _vmodule_rows * _panelResY)
 #endif
  {
    this->display = &disp;
    panelResX = _panelResX;
    panelResY = _panelResY;
    vmodule_rows = _vmodule_rows;
    vmodule_cols = _vmodule_cols;
    virtualResX = vmodule_cols * _panelResX;
    virtualResY = vmodule_rows * _panelResY;
    dmaResX = panelResX * vmodule_rows * vmodule_cols;
    /* Virtual Display width() and height() will return a real-world value. For example:
     * Virtual Display width: 128
     * Virtual Display height: 64
     *
     * So, not values that at 0 to X-1
     */
    _s_chain_party = serpentine_chain; // serpentine, or 'S' chain?
    _chain_top_down = top_down_chain;
    coords.x = coords.y = -1; // By default use an invalid co-ordinates that will be rejected by updateMatrixDMABuffer
  }
  // equivalent methods of the matrix library so it can be just swapped out.
  virtual void drawPixel(int16_t x, int16_t y, uint16_t color);
  virtual void fillScreen(uint16_t color); // overwrite adafruit implementation
  virtual void fillScreenRGB888(uint8_t r, uint8_t g, uint8_t b);
  void clearScreen() { display->clearScreen(); }
  void drawPixelRGB888(int16_t x, int16_t y, uint8_t r, uint8_t g, uint8_t b);
 #ifdef USE_GFX_ROOT
  // 24bpp FASTLED CRGB colour struct support
  void fillScreen(CRGB color);
  void drawPixel(int16_t x, int16_t y, CRGB color);
 #endif
  uint16_t color444(uint8_t r, uint8_t g, uint8_t b) { return display->color444(r, g, b); }
  uint16_t color565(uint8_t r, uint8_t g, uint8_t b) { return display->color565(r, g, b); }
  uint16_t color333(uint8_t r, uint8_t g, uint8_t b) { return display->color333(r, g, b); }
  void flipDMABuffer() { display->flipDMABuffer(); }
  void drawDisplayTest();
  void setRotate(bool rotate);
  void setPhysicalPanelScanRate(PANEL_SCAN_RATE rate);
 protected:
  virtual VirtualCoords getCoords(int16_t &x, int16_t &y);
  VirtualCoords coords;
  bool _s_chain_party = true;   // Are we chained? Ain't no party like a...
  bool _chain_top_down = false; // is the ESP at the top or bottom of the matrix of devices?
  bool _rotate = false;
  PANEL_SCAN_RATE _panelScanRate = NORMAL_TWO_SCAN;
 }; // end Class header
 /**
 * Calculate virtual->real co-ordinate mapping to underlying single chain of panels connected to ESP32.
 * Updates the private class member variable 'coords', so no need to use the return value.
 * Not thread safe, but not a concern for ESP32 sketch anyway... I think.
 */
 inline VirtualCoords VirtualMatrixPanel::getCoords(int16_t &x, int16_t &y)
 {
  // Serial.println("Called Base.");
  coords.x = coords.y = -1; // By defalt use an invalid co-ordinates that will be rejected by updateMatrixDMABuffer
  // Do we want to rotate?
  if (_rotate)
  {
    int16_t temp_x = x;
    x = y;
    y = virtualResY - 1 - temp_x;
  }
  if (x < 0 || x >= virtualResX || y < 0 || y >= virtualResY)
  { // Co-ordinates go from 0 to X-1 remember! otherwise they are out of range!
    // Serial.printf("VirtualMatrixPanel::getCoords(): Invalid virtual display coordinate. x,y: %d, %d\r\n", x, y);
    return coords;
  }
  // Stupidity check
  if ((vmodule_rows == 1) && (vmodule_cols == 1)) // single panel...
  {
    coords.x = x;
    coords.y = y;
  }
  else
  {
    uint8_t row = (y / panelResY) + 1;                         // a non indexed 0 row number
    if ((_s_chain_party && !_chain_top_down && (row % 2 == 0)) // serpentine vertically stacked chain starting from bottom row (i.e. ESP closest to ground), upwards
        ||
        (_s_chain_party && _chain_top_down && (row % 2 != 0)) // serpentine vertically stacked chain starting from the sky downwards
    )
    {
      // First portion gets you to the correct offset for the row you need
      // Second portion inverts the x on the row
      coords.x = ((y / panelResY) * (virtualResX)) + (virtualResX - x) - 1;
      // inverts the y the row
      coords.y = panelResY - 1 - (y % panelResY);
    }
    else
    {
      // Normal chain pixel co-ordinate
      coords.x = x + ((y / panelResY) * (virtualResX));
      coords.y = y % panelResY;
    }
  }
  // Reverse co-ordinates if panel chain from ESP starts from the TOP RIGHT
  if (_chain_top_down)
  {
    /*
    const HUB75_I2S_CFG _cfg = this->display->getCfg();
    coords.x = (_cfg.mx_width * _cfg.chain_length - 1) - coords.x;
    coords.y = (_cfg.mx_height-1) - coords.y;
    */
    coords.x = (dmaResX - 1) - coords.x;
    coords.y = (panelResY - 1) - coords.y;
  }
  /* START: Pixel remapping AGAIN to convert TWO parallel scanline output that the
   *        the underlying hardware library is designed for (because
   *        there's only 2 x RGB pins... and convert this to 1/4 or something
   */
  if (_panelScanRate == FOUR_SCAN_32PX_HIGH)
  {
    /* Convert Real World 'VirtualMatrixPanel' co-ordinates (i.e. Real World pixel you're looking at
       on the panel or chain of panels, per the chaining configuration) to a 1/8 panels
       double 'stretched' and 'squished' coordinates which is what needs to be sent from the
       DMA buffer.
       Note: Look at the FourScanPanel example code and you'll see that the DMA buffer is setup
       as if the panel is 2 * W and 0.5 * H !
    */
    /*
      Serial.print("VirtualMatrixPanel Mapping ("); Serial.print(x, DEC); Serial.print(","); Serial.print(y, DEC); Serial.print(") ");
      // to
      Serial.print("to ("); Serial.print(coords.x, DEC);  Serial.print(",");  Serial.print(coords.y, DEC);   Serial.println(") ");
     */
    if ((y & 8) == 0)
    {
      coords.x += ((coords.x / panelResX) + 1) * panelResX; // 1st, 3rd 'block' of 8 rows of pixels, offset by panel width in DMA buffer
    }
    else
    {
      coords.x += (coords.x / panelResX) * panelResX; // 2nd, 4th 'block' of 8 rows of pixels, offset by panel width in DMA buffer
    }
    // http://cpp.sh/4ak5u
    // Real number of DMA y rows is half reality
    // coords.y = (y / 16)*8 + (y & 0b00000111);
    coords.y = (y >> 4) * 8 + (y & 0b00000111);
    /*
     Serial.print("OneEightScanPanel Mapping ("); Serial.print(x, DEC); Serial.print(","); Serial.print(y, DEC); Serial.print(") ");
     // to
     Serial.print("to ("); Serial.print(coords.x, DEC);  Serial.print(",");  Serial.print(coords.y, DEC);   Serial.println(") ");
    */
  }
  else if (_panelScanRate == FOUR_SCAN_16PX_HIGH)
  {
    if ((y & 8) == 0)
    {
      coords.x += (panelResX >> 2) * (((coords.x & 0xFFF0) >> 4) + 1); // 1st, 3rd 'block' of 8 rows of pixels, offset by panel width in DMA buffer
    }
    else
    {
      coords.x += (panelResX >> 2) * (((coords.x & 0xFFF0) >> 4)); // 2nd, 4th 'block' of 8 rows of pixels, offset by panel width in DMA buffer
    }
    if (y < 32)
      coords.y = (y >> 4) * 8 + (y & 0b00000111);
    else
    {
      coords.y = ((y - 32) >> 4) * 8 + (y & 0b00000111);
      coords.x += 256;
    }
  }
  // Serial.print("Mapping to x: "); Serial.print(coords.x, DEC);  Serial.print(", y: "); Serial.println(coords.y, DEC);
  return coords;
 }
 inline void VirtualMatrixPanel::drawPixel(int16_t x, int16_t y, uint16_t color)
 { // adafruit virtual void override
  getCoords(x, y);
  this->display->drawPixel(coords.x, coords.y, color);
 }
 inline void VirtualMatrixPanel::fillScreen(uint16_t color)
 { // adafruit virtual void override
  this->display->fillScreen(color);
 }
 inline void VirtualMatrixPanel::fillScreenRGB888(uint8_t r, uint8_t g, uint8_t b)
 {
  this->display->fillScreenRGB888(r, g, b);
 }
 inline void VirtualMatrixPanel::drawPixelRGB888(int16_t x, int16_t y, uint8_t r, uint8_t g, uint8_t b)
 {
  getCoords(x, y);
  this->display->drawPixelRGB888(coords.x, coords.y, r, g, b);
 }
 #ifdef USE_GFX_ROOT
 // Support for CRGB values provided via FastLED
 inline void VirtualMatrixPanel::drawPixel(int16_t x, int16_t y, CRGB color)
 {
  getCoords(x, y);
  this->display->drawPixel(coords.x, coords.y, color);
 }
 inline void VirtualMatrixPanel::fillScreen(CRGB color)
 {
  this->display->fillScreen(color);
 }
 #endif
 inline void VirtualMatrixPanel::setRotate(bool rotate)
 {
  _rotate = rotate;
 #ifndef NO_GFX
  // We don't support rotation by degrees.
  if (rotate)
  {
    setRotation(1);
  }
  else
  {
    setRotation(0);
  }
 #endif
 }
 inline void VirtualMatrixPanel::setPhysicalPanelScanRate(PANEL_SCAN_RATE rate)
 {
  _panelScanRate = rate;
 }
 #ifndef NO_GFX
 inline void VirtualMatrixPanel::drawDisplayTest()
 {
  this->display->setFont(&FreeSansBold12pt7b);
  this->display->setTextColor(this->display->color565(255, 255, 0));
  this->display->setTextSize(1);
  for (int panel = 0; panel < vmodule_cols * vmodule_rows; panel++)
  {
    int top_left_x = (panel == 0) ? 0 : (panel * panelResX);
    this->display->drawRect(top_left_x, 0, panelResX, panelResY, this->display->color565(0, 255, 0));
    this->display->setCursor(panel * panelResX, panelResY - 3);
    this->display->print((vmodule_cols * vmodule_rows) - panel);
  }
 }
 #endif
 /*
 // need to recreate this one, as it wouldn't work to just map where it starts.
 inline void VirtualMatrixPanel::drawIcon (int *ico, int16_t x, int16_t y, int16_t icon_cols, int16_t icon_rows) {
  int i, j;
  for (i = 0; i < icon_rows; i++) {
    for (j = 0; j < icon_cols; j++) {
      // This is a call to this libraries version of drawPixel
      // which will map each pixel, which is what we want.
      //drawPixelRGB565 (x + j, y + i, ico[i * module_cols + j]);
    drawPixel (x + j, y + i, ico[i * icon_cols + j]);
    }
  }
 }
 */
 #endif