public int getPixel(int x, int y, int[] inPixels, int width, int height) { float nx = m00 * x + m01 * y; float ny = m10 * x + m11 * y; nx /= scale; ny /= scale * stretch; nx += 1000; ny += 1000; // Reduce artifacts around 0,0 float f = turbulence == 1.0f ? evaluate(nx, ny) : turbulence2(nx, ny, turbulence); // Normalize to 0..1 // f = (f-min)/(max-min); f *= 2; f *= amount; int a = 0xff000000; int v; if (colormap != null) { v = colormap.getColor(f); if (useColor) { int srcx = ImageMath.clamp((int) ((results[0].x - 1000) * scale), 0, width - 1); int srcy = ImageMath.clamp((int) ((results[0].y - 1000) * scale), 0, height - 1); v = inPixels[srcy * width + srcx]; f = (results[1].distance - results[0].distance) / (results[1].distance + results[0].distance); f = ImageMath.smoothStep(coefficients[1], coefficients[0], f); v = ImageMath.mixColors(f, 0xff000000, v); } return v; } else { v = PixelUtils.clamp((int) (f * 255)); int r = v << 16; int g = v << 8; int b = v; return a | r | g | b; } }
protected int[] filterPixels(int width, int height, int[] inPixels, Rectangle transformedSpace) { int[] outPixels = new int[width * height]; randomGenerator.setSeed(seed); int w1 = width - 1; int h1 = height - 1; putPixel(0, 0, randomRGB(inPixels, 0, 0), outPixels, width); putPixel(w1, 0, randomRGB(inPixels, w1, 0), outPixels, width); putPixel(0, h1, randomRGB(inPixels, 0, h1), outPixels, width); putPixel(w1, h1, randomRGB(inPixels, w1, h1), outPixels, width); putPixel(w1 / 2, h1 / 2, randomRGB(inPixels, w1 / 2, h1 / 2), outPixels, width); putPixel(0, h1 / 2, randomRGB(inPixels, 0, h1 / 2), outPixels, width); putPixel(w1, h1 / 2, randomRGB(inPixels, w1, h1 / 2), outPixels, width); putPixel(w1 / 2, 0, randomRGB(inPixels, w1 / 2, 0), outPixels, width); putPixel(w1 / 2, h1, randomRGB(inPixels, w1 / 2, h1), outPixels, width); int depth = 1; while (doPixel(0, 0, width - 1, height - 1, outPixels, width, depth, 0)) depth++; if (useColormap && colormap != null) { int index = 0; for (int y = 0; y < height; y++) { for (int x = 0; x < width; x++) { outPixels[index] = colormap.getColor((outPixels[index] & 0xff) / 255.0f); index++; } } } return outPixels; }
public BufferedImage filter(BufferedImage src, BufferedImage dst) { if (dst == null) dst = createCompatibleDestImage(src, null); int width = src.getWidth(); int height = src.getHeight(); int numScratches = (int) (density * width * height / 100); ArrayList<Line2D> lines = new ArrayList<Line2D>(); { float l = length * width; Random random = new Random(seed); Graphics2D g = dst.createGraphics(); g.setRenderingHint(RenderingHints.KEY_ANTIALIASING, RenderingHints.VALUE_ANTIALIAS_ON); g.setColor(new Color(color)); g.setStroke(new BasicStroke(this.width)); for (int i = 0; i < numScratches; i++) { float x = width * random.nextFloat(); float y = height * random.nextFloat(); float a = angle + ImageMath.TWO_PI * (angleVariation * (random.nextFloat() - 0.5f)); float s = (float) Math.sin(a) * l; float c = (float) Math.cos(a) * l; float x1 = x - c; float y1 = y - s; float x2 = x + c; float y2 = y + s; g.drawLine((int) x1, (int) y1, (int) x2, (int) y2); lines.add(new Line2D.Float(x1, y1, x2, y2)); } g.dispose(); } if (false) { // int[] inPixels = getRGB( src, 0, 0, width, height, null ); int[] inPixels = new int[width * height]; int index = 0; for (int y = 0; y < height; y++) { for (int x = 0; x < width; x++) { float sx = x, sy = y; for (int i = 0; i < numScratches; i++) { Line2D.Float l = (Line2D.Float) lines.get(i); float dot = (l.x2 - l.x1) * (sx - l.x1) + (l.y2 - l.y1) * (sy - l.y1); if (dot > 0) inPixels[index] |= (1 << i); } index++; } } Colormap colormap = new LinearColormap(); index = 0; for (int y = 0; y < height; y++) { for (int x = 0; x < width; x++) { float f = (float) (inPixels[index] & 0x7fffffff) / 0x7fffffff; inPixels[index] = colormap.getColor(f); index++; } } setRGB(dst, 0, 0, width, height, inPixels); } return dst; }
protected int[] filterPixels(int width, int height, int[] inPixels, Rectangle transformedSpace) { int[] outPixels = new int[width * height]; int i = 0; int max = 0; float x = 0.1f; float y = 0.3f; for (int n = 0; n < 20; n++) { float mx = ImageMath.PI * x; float my = ImageMath.PI * y; float smx2 = (float) Math.sin(2 * mx); float smy2 = (float) Math.sin(2 * my); float x1 = (float) (a * smx2 + b * smx2 * Math.cos(2 * my) + c * Math.sin(4 * mx) + d * Math.sin(6 * mx) * Math.cos(4 * my) + k * x); x1 = x1 >= 0 ? x1 - (int) x1 : x1 - (int) x1 + 1; float y1 = (float) (a * smy2 + b * smy2 * Math.cos(2 * mx) + c * Math.sin(4 * my) + d * Math.sin(6 * my) * Math.cos(4 * mx) + k * y); y1 = y1 >= 0 ? y1 - (int) y1 : y1 - (int) y1 + 1; x = x1; y = y1; } for (int n = 0; n < iterations; n++) { float mx = ImageMath.PI * x; float my = ImageMath.PI * y; float x1 = (float) (a * Math.sin(2 * mx) + b * Math.sin(2 * mx) * Math.cos(2 * my) + c * Math.sin(4 * mx) + d * Math.sin(6 * mx) * Math.cos(4 * my) + k * x); x1 = x1 >= 0 ? x1 - (int) x1 : x1 - (int) x1 + 1; float y1 = (float) (a * Math.sin(2 * my) + b * Math.sin(2 * my) * Math.cos(2 * mx) + c * Math.sin(4 * my) + d * Math.sin(6 * my) * Math.cos(4 * mx) + k * y); y1 = y1 >= 0 ? y1 - (int) y1 : y1 - (int) y1 + 1; x = x1; y = y1; int ix = (int) (width * x); int iy = (int) (height * y); if (ix >= 0 && ix < width && iy >= 0 && iy < height) { int t = outPixels[width * iy + ix]++; if (t > max) max = t; } } if (colormap != null) { int index = 0; for (y = 0; y < height; y++) { for (x = 0; x < width; x++) { outPixels[index] = colormap.getColor(outPixels[index] / (float) max); index++; } } } return outPixels; }