sutaburosu/recv_processing.ino

## recv_processing.ino
#include <FastLED.h>
#include <colorutils.h>
enum XY_matrix_config {LINEAR = 0, SERPENTINE = 1, COLUMNMAJOR = 0, ROWMAJOR = 2, FLIPMAJOR = 4, FLIPMINOR = 8};

#define BRIGHTNESS        32
#define LED_PIN           2
#define COLOR_ORDER       GRB
#define CHIPSET           WS2812B
#define kMatrixWidth      16
#define kMatrixHeight     16
#define XY_MATRIX         (SERPENTINE | ROWMAJOR | FLIPMINOR)

#define BAUD              1000000
#define AWAIT_TIMEOUT_MS  250
#define RECV_TIMEOUT_MS   3
#define NO_INPUT_AWAIT_MS 10
#define SCREENSAVER_MS    1250

#define NUM_LEDS          ((kMatrixWidth) * (kMatrixHeight))
CRGB leds[NUM_LEDS + 1];  // 1 extra for XY() to use when out-of-bounds

void setup() {
  FastLED.addLeds<CHIPSET, LED_PIN, COLOR_ORDER>(leds, NUM_LEDS);
  FastLED.setCorrection(UncorrectedColor);
  FastLED.setTemperature(UncorrectedTemperature);
  FastLED.setDither(DISABLE_DITHER);
  FastLED.setBrightness(BRIGHTNESS);
  Serial.begin(BAUD);
  Serial.setTimeout(RECV_TIMEOUT_MS);
  screensaver_setup();
}

void loop() {
  static uint32_t last_recvd_ms = 0;
  static bool no_input = true;
  uint32_t this_await_ms, ms = millis();
  if (no_input)
    this_await_ms = NO_INPUT_AWAIT_MS;
  else
    this_await_ms = AWAIT_TIMEOUT_MS;

  int in = -1;
  while (in <= 0 && millis() - ms < this_await_ms) {
    in = Serial.available();
  };
  if (in > 0) {
    in = Serial.readBytes((uint8_t *) &leds[0], NUM_LEDS * 3);
    if (in == NUM_LEDS * 3) {
      last_recvd_ms = millis();
      no_input = false;
    }
  } else {
    no_input = true;
    if (millis() - last_recvd_ms < SCREENSAVER_MS) {
      fadeToBlackBy(leds, NUM_LEDS, 8);
    } else {
      screensaver();
    }
  }
  FastLED.show();
}

////////////////////////////////////
// only screensaver stuff below here

#define NUM_LEAPERS       8
#define GRAVITY           10
#define SETTLED_THRESHOLD 72
#define WALL_FRICTION     248  // 255 is no friction
#define DRAG              240  // 255 is no wind resistance

uint16_t XY(uint8_t x, uint8_t y) {
  uint8_t major, minor, sz_major, sz_minor;
  if (x >= kMatrixWidth || y >= kMatrixHeight)
    return NUM_LEDS;
  if (XY_MATRIX & ROWMAJOR)
    major = x, minor = y, sz_major = kMatrixWidth,  sz_minor = kMatrixHeight;
  else
    major = y, minor = x, sz_major = kMatrixHeight, sz_minor = kMatrixWidth;
  if (((XY_MATRIX & FLIPMAJOR) != 0) ^ (minor & 1 && (XY_MATRIX & SERPENTINE)))
    major = sz_major - 1 - major;
  if (XY_MATRIX & FLIPMINOR)
    minor = sz_minor - 1 - minor;
  return (uint16_t) minor * sz_major + major;
}

CRGBPalette16 currentPalette = RainbowColors_p;
typedef struct {
  int16_t x, y, xd, yd;
} Leaper;
Leaper leapers[NUM_LEAPERS];
extern "C" {
  void restart_leaper(Leaper * lpr);
  void move_leaper(Leaper * lpr);
}

void screensaver_setup() {
  for (uint8_t lpr = 0; lpr < NUM_LEAPERS; lpr++)
    leapers[lpr].x = kMatrixWidth * 256 / 2 ;
}

void screensaver() {
  FastLED.clear();
  // fadeToBlackBy(leds, NUM_LEDS, 32);
  for (uint8_t lpr = 0; lpr < NUM_LEAPERS; lpr++) {
    move_leaper(&leapers[lpr]);
    CRGB rgb = ColorFromPalette(currentPalette, lpr * (255 / NUM_LEAPERS), 255, LINEARBLEND);
    wu_pixel(leapers[lpr].x, leapers[lpr].y, &rgb);
  }
}

void restart_leaper(Leaper * lpr) {
  // leap up and to the side with some random component
  lpr->xd = random8() + kMatrixWidth * 2;
  lpr->yd = random8() + kMatrixHeight * 16;

  // for variety, sometimes go 50% faster
  if (random8() < 12) {
    lpr->xd += lpr->xd >> 1;
    lpr->yd += lpr->yd >> 1;
  }

  // leap towards the centre of the screen
  if (lpr->x > (kMatrixWidth / 2 * 256)) {
    lpr->xd = -lpr->xd;
  }
}

void move_leaper(Leaper * lpr) {
  // add the X & Y velocities to the position
  lpr->x += lpr->xd;
  lpr->y += lpr->yd;

  // bounce off the floor and ceiling?
  if (lpr->y <= 0 || lpr->y >= ((kMatrixHeight - 1) << 8)) {
    lpr->xd = ((int32_t)  lpr->xd * WALL_FRICTION) >> 8;
    lpr->yd = ((int32_t) -lpr->yd * WALL_FRICTION) >> 8;
    if (lpr->y < 0) lpr->y = -lpr->y;
    // settled on the floor?
    if (lpr->y <= SETTLED_THRESHOLD && abs(lpr->yd) <= SETTLED_THRESHOLD) {
      restart_leaper(lpr);
    }
  }

  // bounce off the sides of the screen?
  if (lpr->x <= 0 || lpr->x >= (kMatrixWidth - 1) << 8) {
    lpr->xd = ((int32_t) -lpr->xd * WALL_FRICTION) >> 8;
    lpr->yd = ((int32_t)  lpr->yd * WALL_FRICTION) >> 8;
    if (lpr->x <= 0) {
      lpr->x = -lpr->x;
    } else {
      lpr->x = ((2 * kMatrixWidth - 1) << 8) - lpr->x;
    }
  }

  // gravity
  lpr->yd -= GRAVITY;

  // viscosity,  done badly
  // uint32_t speed2 = lpr->xd * lpr->xd + lpr->yd * lpr->yd;
  lpr->xd = ((int32_t) lpr->xd * DRAG) >> 8;
  lpr->yd = ((int32_t) lpr->yd * DRAG) >> 8;
}

// x and y are 24.8 fixed point
// Not Ray Wu. ;)  The idea came from Xiaolin Wu.
void wu_pixel(uint32_t x, uint32_t y, CRGB * col) {
  // extract the fractional parts and derive their inverses
  uint8_t xx = x & 0xff, yy = y & 0xff, ix = 255 - xx, iy = 255 - yy;
  // calculate the intensities for each affected pixel
  #define WU_WEIGHT(a,b) ((uint8_t) (((a)*(b)+(a)+(b))>>8))
  uint8_t wu[4] = {WU_WEIGHT(ix, iy), WU_WEIGHT(xx, iy),
                   WU_WEIGHT(ix, yy), WU_WEIGHT(xx, yy)};
  // multiply the intensities by the colour, and saturating-add them to the pixels
  for (uint8_t i = 0; i < 4; i++) {
    uint16_t xy = XY((x >> 8) + (i & 1), (y >> 8) + ((i >> 1) & 1));
    leds[xy].r = qadd8(leds[xy].r, col->r * wu[i] >> 8);
    leds[xy].g = qadd8(leds[xy].g, col->g * wu[i] >> 8);
    leds[xy].b = qadd8(leds[xy].b, col->b * wu[i] >> 8);
  }
}

## send_processing.pde
import processing.serial.*;
import processing.video.*;

// 1Mbit works very well on my Nano with CH340G USB<->serial
// giving ~50FPS for 256 LEDs. 2Mbit loses around half of the data.
int BAUD = 1000000;
String MoviePath = "H:\\LBRY\\art-020.mp4";
boolean playMovie = true;
boolean showCube = false;
int kMatrixWidth = 16;
int kMatrixHeight = 16;
// time to allow for FastLED.show(), e.g. around 8ms for 256 LEDs
// + 2.0ms to help with re-sync + 0.5ms to round correctly
int FRAME_TIME = (2500 + kMatrixWidth * kMatrixHeight * 30) / 1000;

int XY(int x, int y) {
  // this is for my serpentine row layout;  change it for your matrix
  if ((y & 1) == 1)
    x = kMatrixWidth - 1 - x;
  y = kMatrixHeight - 1 - y;
  return y*kMatrixWidth + x;
}

Serial myPort;
Movie myMovie;
float gamma = 2.0;
int[] gammatable = new int[256];
int last_frame_ms = 0;

void setup() {
  size(128, 128, P3D);
  printArray(Serial.list());
  myPort = new Serial(this, Serial.list()[0], BAUD);
  for (int i=0; i < 256; i++)
    gammatable[i] = (int)(pow((float)i / 255.0, gamma) * 255.0 + 0.5);
  if (playMovie) {
    myMovie = new Movie(this, MoviePath);
    myMovie.loop();
    delay(100); // allow the Movie to start playing
  }
}

void draw() {
  background(0);
  lights();

  if (playMovie) {
    int sx, sy, wx, wy;
    sx = myMovie.width / (32 / 9);
    sy = 0;
    wx = myMovie.width - sx * 2;
    wy = myMovie.height - sy;
    copy(myMovie, sx, sy, wx, wy, 0, 0, pixelWidth, pixelHeight);
  }

  if (showCube) {
    pushMatrix();
    translate(pixelWidth/2, pixelHeight/2, 0);
    rotateY(0.00250*millis());
    rotateX(-0.0009 * millis());
    noStroke();
    box(35+sin(millis()*0.004)*30);
    // box(64);
    popMatrix();
  }

  send_serial();
}

void send_serial() {
  // copy the main window and resize down to the dimensions of the matrix
  PImage ledImage = createImage(kMatrixWidth, kMatrixHeight, RGB);
  ledImage.copy(g, 0, 0, pixelWidth, pixelHeight, 0, 0, ledImage.width, ledImage.height);
  ledImage.loadPixels();
  // copy the pixels to a format for Serial and apply gamma correction
  byte[] bytes = new byte[3 * kMatrixWidth * kMatrixHeight];
  int index = 0;
  for (int y = 0; y < kMatrixHeight; y += 1) {
    for (int x = 0; x < kMatrixWidth; x += 1) {
      color c = ledImage.pixels[XY(x, y)];
      bytes[index++] = byte(gammatable[(c >> 16) & 0xff]);
      bytes[index++] = byte(gammatable[(c >> 8) & 0xff]);
      bytes[index++] = byte(gammatable[c & 0xff]);
    }
  }
  int pause = FRAME_TIME - (millis() - last_frame_ms);
  if (pause > 0)
    delay(pause);
  myPort.write(bytes);
  last_frame_ms = millis();
}

void movieEvent(Movie m) {
  m.read();
}
	#include <FastLED.h>
	#include <colorutils.h>
	enum XY_matrix_config {LINEAR = 0, SERPENTINE = 1, COLUMNMAJOR = 0, ROWMAJOR = 2, FLIPMAJOR = 4, FLIPMINOR = 8};

	#define BRIGHTNESS 32
	#define LED_PIN 2
	#define COLOR_ORDER GRB
	#define CHIPSET WS2812B
	#define kMatrixWidth 16
	#define kMatrixHeight 16
	#define XY_MATRIX (SERPENTINE \| ROWMAJOR \| FLIPMINOR)

	#define BAUD 1000000
	#define AWAIT_TIMEOUT_MS 250
	#define RECV_TIMEOUT_MS 3
	#define NO_INPUT_AWAIT_MS 10
	#define SCREENSAVER_MS 1250

	#define NUM_LEDS ((kMatrixWidth) * (kMatrixHeight))
	CRGB leds[NUM_LEDS + 1]; // 1 extra for XY() to use when out-of-bounds

	void setup() {
	FastLED.addLeds<CHIPSET, LED_PIN, COLOR_ORDER>(leds, NUM_LEDS);
	FastLED.setCorrection(UncorrectedColor);
	FastLED.setTemperature(UncorrectedTemperature);
	FastLED.setDither(DISABLE_DITHER);
	FastLED.setBrightness(BRIGHTNESS);
	Serial.begin(BAUD);
	Serial.setTimeout(RECV_TIMEOUT_MS);
	screensaver_setup();
	}

	void loop() {
	static uint32_t last_recvd_ms = 0;
	static bool no_input = true;
	uint32_t this_await_ms, ms = millis();
	if (no_input)
	this_await_ms = NO_INPUT_AWAIT_MS;
	else
	this_await_ms = AWAIT_TIMEOUT_MS;

	int in = -1;
	while (in <= 0 && millis() - ms < this_await_ms) {
	in = Serial.available();
	};
	if (in > 0) {
	in = Serial.readBytes((uint8_t ) &leds[0], NUM_LEDS 3);
	if (in == NUM_LEDS * 3) {
	last_recvd_ms = millis();
	no_input = false;
	}
	} else {
	no_input = true;
	if (millis() - last_recvd_ms < SCREENSAVER_MS) {
	fadeToBlackBy(leds, NUM_LEDS, 8);
	} else {
	screensaver();
	}
	}
	FastLED.show();
	}

	////////////////////////////////////
	// only screensaver stuff below here

	#define NUM_LEAPERS 8
	#define GRAVITY 10
	#define SETTLED_THRESHOLD 72
	#define WALL_FRICTION 248 // 255 is no friction
	#define DRAG 240 // 255 is no wind resistance

	uint16_t XY(uint8_t x, uint8_t y) {
	uint8_t major, minor, sz_major, sz_minor;
	if (x >= kMatrixWidth \|\| y >= kMatrixHeight)
	return NUM_LEDS;
	if (XY_MATRIX & ROWMAJOR)
	major = x, minor = y, sz_major = kMatrixWidth, sz_minor = kMatrixHeight;
	else
	major = y, minor = x, sz_major = kMatrixHeight, sz_minor = kMatrixWidth;
	if (((XY_MATRIX & FLIPMAJOR) != 0) ^ (minor & 1 && (XY_MATRIX & SERPENTINE)))
	major = sz_major - 1 - major;
	if (XY_MATRIX & FLIPMINOR)
	minor = sz_minor - 1 - minor;
	return (uint16_t) minor * sz_major + major;
	}

	CRGBPalette16 currentPalette = RainbowColors_p;
	typedef struct {
	int16_t x, y, xd, yd;
	} Leaper;
	Leaper leapers[NUM_LEAPERS];
	extern "C" {
	void restart_leaper(Leaper * lpr);
	void move_leaper(Leaper * lpr);
	}

	void screensaver_setup() {
	for (uint8_t lpr = 0; lpr < NUM_LEAPERS; lpr++)
	leapers[lpr].x = kMatrixWidth * 256 / 2 ;
	}

	void screensaver() {
	FastLED.clear();
	// fadeToBlackBy(leds, NUM_LEDS, 32);
	for (uint8_t lpr = 0; lpr < NUM_LEAPERS; lpr++) {
	move_leaper(&leapers[lpr]);
	CRGB rgb = ColorFromPalette(currentPalette, lpr * (255 / NUM_LEAPERS), 255, LINEARBLEND);
	wu_pixel(leapers[lpr].x, leapers[lpr].y, &rgb);
	}
	}

	void restart_leaper(Leaper * lpr) {
	// leap up and to the side with some random component
	lpr->xd = random8() + kMatrixWidth * 2;
	lpr->yd = random8() + kMatrixHeight * 16;

	// for variety, sometimes go 50% faster
	if (random8() < 12) {
	lpr->xd += lpr->xd >> 1;
	lpr->yd += lpr->yd >> 1;
	}

	// leap towards the centre of the screen
	if (lpr->x > (kMatrixWidth / 2 * 256)) {
	lpr->xd = -lpr->xd;
	}
	}

	void move_leaper(Leaper * lpr) {
	// add the X & Y velocities to the position
	lpr->x += lpr->xd;
	lpr->y += lpr->yd;

	// bounce off the floor and ceiling?
	if (lpr->y <= 0 \|\| lpr->y >= ((kMatrixHeight - 1) << 8)) {
	lpr->xd = ((int32_t) lpr->xd * WALL_FRICTION) >> 8;
	lpr->yd = ((int32_t) -lpr->yd * WALL_FRICTION) >> 8;
	if (lpr->y < 0) lpr->y = -lpr->y;
	// settled on the floor?
	if (lpr->y <= SETTLED_THRESHOLD && abs(lpr->yd) <= SETTLED_THRESHOLD) {
	restart_leaper(lpr);
	}
	}

	// bounce off the sides of the screen?
	if (lpr->x <= 0 \|\| lpr->x >= (kMatrixWidth - 1) << 8) {
	lpr->xd = ((int32_t) -lpr->xd * WALL_FRICTION) >> 8;
	lpr->yd = ((int32_t) lpr->yd * WALL_FRICTION) >> 8;
	if (lpr->x <= 0) {
	lpr->x = -lpr->x;
	} else {
	lpr->x = ((2 * kMatrixWidth - 1) << 8) - lpr->x;
	}
	}

	// gravity
	lpr->yd -= GRAVITY;

	// viscosity, done badly
	// uint32_t speed2 = lpr->xd * lpr->xd + lpr->yd * lpr->yd;
	lpr->xd = ((int32_t) lpr->xd * DRAG) >> 8;
	lpr->yd = ((int32_t) lpr->yd * DRAG) >> 8;
	}

	// x and y are 24.8 fixed point
	// Not Ray Wu. ;) The idea came from Xiaolin Wu.
	void wu_pixel(uint32_t x, uint32_t y, CRGB * col) {
	// extract the fractional parts and derive their inverses
	uint8_t xx = x & 0xff, yy = y & 0xff, ix = 255 - xx, iy = 255 - yy;
	// calculate the intensities for each affected pixel
	#define WU_WEIGHT(a,b) ((uint8_t) (((a)*(b)+(a)+(b))>>8))
	uint8_t wu[4] = {WU_WEIGHT(ix, iy), WU_WEIGHT(xx, iy),
	WU_WEIGHT(ix, yy), WU_WEIGHT(xx, yy)};
	// multiply the intensities by the colour, and saturating-add them to the pixels
	for (uint8_t i = 0; i < 4; i++) {
	uint16_t xy = XY((x >> 8) + (i & 1), (y >> 8) + ((i >> 1) & 1));
	leds[xy].r = qadd8(leds[xy].r, col->r * wu[i] >> 8);
	leds[xy].g = qadd8(leds[xy].g, col->g * wu[i] >> 8);
	leds[xy].b = qadd8(leds[xy].b, col->b * wu[i] >> 8);
	}
	}
	import processing.serial.*;
	import processing.video.*;

	// 1Mbit works very well on my Nano with CH340G USB<->serial
	// giving ~50FPS for 256 LEDs. 2Mbit loses around half of the data.
	int BAUD = 1000000;
	String MoviePath = "H:\\LBRY\\art-020.mp4";
	boolean playMovie = true;
	boolean showCube = false;
	int kMatrixWidth = 16;
	int kMatrixHeight = 16;
	// time to allow for FastLED.show(), e.g. around 8ms for 256 LEDs
	// + 2.0ms to help with re-sync + 0.5ms to round correctly
	int FRAME_TIME = (2500 + kMatrixWidth * kMatrixHeight * 30) / 1000;

	int XY(int x, int y) {
	// this is for my serpentine row layout; change it for your matrix
	if ((y & 1) == 1)
	x = kMatrixWidth - 1 - x;
	y = kMatrixHeight - 1 - y;
	return y*kMatrixWidth + x;
	}

	Serial myPort;
	Movie myMovie;
	float gamma = 2.0;
	int[] gammatable = new int[256];
	int last_frame_ms = 0;

	void setup() {
	size(128, 128, P3D);
	printArray(Serial.list());
	myPort = new Serial(this, Serial.list()[0], BAUD);
	for (int i=0; i < 256; i++)
	gammatable[i] = (int)(pow((float)i / 255.0, gamma) * 255.0 + 0.5);
	if (playMovie) {
	myMovie = new Movie(this, MoviePath);
	myMovie.loop();
	delay(100); // allow the Movie to start playing
	}
	}

	void draw() {
	background(0);
	lights();

	if (playMovie) {
	int sx, sy, wx, wy;
	sx = myMovie.width / (32 / 9);
	sy = 0;
	wx = myMovie.width - sx * 2;
	wy = myMovie.height - sy;
	copy(myMovie, sx, sy, wx, wy, 0, 0, pixelWidth, pixelHeight);
	}

	if (showCube) {
	pushMatrix();
	translate(pixelWidth/2, pixelHeight/2, 0);
	rotateY(0.00250*millis());
	rotateX(-0.0009 * millis());
	noStroke();
	box(35+sin(millis()0.004)30);
	// box(64);
	popMatrix();
	}

	send_serial();
	}

	void send_serial() {
	// copy the main window and resize down to the dimensions of the matrix
	PImage ledImage = createImage(kMatrixWidth, kMatrixHeight, RGB);
	ledImage.copy(g, 0, 0, pixelWidth, pixelHeight, 0, 0, ledImage.width, ledImage.height);
	ledImage.loadPixels();
	// copy the pixels to a format for Serial and apply gamma correction
	byte[] bytes = new byte[3 * kMatrixWidth * kMatrixHeight];
	int index = 0;
	for (int y = 0; y < kMatrixHeight; y += 1) {
	for (int x = 0; x < kMatrixWidth; x += 1) {
	color c = ledImage.pixels[XY(x, y)];
	bytes[index++] = byte(gammatable[(c >> 16) & 0xff]);
	bytes[index++] = byte(gammatable[(c >> 8) & 0xff]);
	bytes[index++] = byte(gammatable[c & 0xff]);
	}
	}
	int pause = FRAME_TIME - (millis() - last_frame_ms);
	if (pause > 0)
	delay(pause);
	myPort.write(bytes);
	last_frame_ms = millis();
	}

	void movieEvent(Movie m) {
	m.read();
	}