package com.mbien.opencl.demos.fractal;
import com.mbien.opencl.CLBuffer;
import com.mbien.opencl.CLCommandQueue;
import com.mbien.opencl.CLDevice;
import com.mbien.opencl.CLEvent;
import com.mbien.opencl.CLEventList;
import com.mbien.opencl.CLException;
import com.mbien.opencl.gl.CLGLBuffer;
import com.mbien.opencl.gl.CLGLContext;
import com.mbien.opencl.CLKernel;
import com.mbien.opencl.CLPlatform;
import com.mbien.opencl.CLProgram;
import com.mbien.opencl.CLProgram.CompilerOptions;
import com.jogamp.opengl.util.awt.TextRenderer;
import java.awt.Color;
import java.awt.Dimension;
import java.awt.Font;
import java.awt.Point;
import java.awt.event.KeyAdapter;
import java.awt.event.KeyEvent;
import java.awt.event.MouseAdapter;
import java.awt.event.MouseEvent;
import java.awt.event.MouseWheelEvent;
import java.io.IOException;
import java.nio.IntBuffer;
import java.util.logging.Level;
import java.util.logging.Logger;
import javax.media.opengl.DebugGL2;
import javax.media.opengl.GL;
import javax.media.opengl.GL2;
import javax.media.opengl.GLAutoDrawable;
import javax.media.opengl.GLCapabilities;
import javax.media.opengl.GLContext;
import javax.media.opengl.GLEventListener;
import javax.media.opengl.GLProfile;
import javax.media.opengl.awt.GLCanvas;
import javax.swing.JFrame;
import javax.swing.SwingUtilities;
import static com.jogamp.common.nio.Buffers.*;
import static javax.media.opengl.GL2.*;
import static com.mbien.opencl.CLMemory.Mem.*;
import static com.mbien.opencl.CLEvent.ProfilingCommand.*;
import static com.mbien.opencl.CLCommandQueue.Mode.*;
import static com.mbien.opencl.CLDevice.Type.*;
import static java.lang.Math.*;
/**
* Computes the Mandelbrot set with OpenCL using multiple GPUs and renders the result with OpenGL.
* A shared PBO is used as storage for the fractal image.
* http://en.wikipedia.org/wiki/Mandelbrot_set
*
* controls:
* keys 1-9 control parallelism level
* space enables/disables slice seperator
* 'd' toggles between 32/64bit floatingpoint precision
* mouse/mousewheel to drag and zoom
*
* @author Michael Bien
*/
public class MultiDeviceFractal implements GLEventListener {
// max number of used GPUs
private static final int MAX_PARRALLELISM_LEVEL = 8;
// max per pixel iterations to compute the fractal
private static final int MAX_ITERATIONS = 500;
private GLCanvas canvas;
private CLGLContext clContext;
private CLCommandQueue[] queues;
private CLKernel[] kernels;
private CLProgram program;
private CLEventList probes;
private CLGLBuffer>[] pboBuffers;
private CLBuffer[] colorMap;
private int width = 0;
private int height = 0;
private double minX = -2f;
private double minY = -1.2f;
private double maxX = 0.6f;
private double maxY = 1.3f;
private int slices;
private boolean drawSeperator;
private boolean doublePrecision;
private boolean buffersInitialized;
private boolean rebuild;
private final TextRenderer textRenderer;
public MultiDeviceFractal(int width, int height) {
this.width = width;
this.height = height;
canvas = new GLCanvas(new GLCapabilities(GLProfile.get(GLProfile.GL2)));
canvas.addGLEventListener(this);
initSceneInteraction();
JFrame frame = new JFrame("JOCL Multi GPU Mandelbrot Set");
frame.setDefaultCloseOperation(JFrame.EXIT_ON_CLOSE);
canvas.setPreferredSize(new Dimension(width, height));
frame.add(canvas);
frame.pack();
frame.setVisible(true);
textRenderer = new TextRenderer(frame.getFont().deriveFont(Font.BOLD, 14), true, true, null, false);
}
public void init(GLAutoDrawable drawable) {
if(clContext == null) {
// enable GL error checking using the composable pipeline
drawable.setGL(new DebugGL2(drawable.getGL().getGL2()));
drawable.getGL().glFinish();
initCL(drawable.getContext());
GL2 gl = drawable.getGL().getGL2();
gl.setSwapInterval(0);
gl.glDisable(GL_DEPTH_TEST);
gl.glClearColor(0.0f, 0.0f, 0.0f, 1.0f);
initView(gl, drawable.getWidth(), drawable.getHeight());
initPBO(gl);
drawable.getGL().glFinish();
setKernelConstants();
}
}
private void initCL(GLContext glCtx){
try {
// create context managing all available GPUs
// clContext = CLGLContext.create(glCtx, GPU);
clContext = CLGLContext.create(glCtx, CLPlatform.getDefault().listCLDevices()[0]);
CLDevice[] devices = clContext.getDevices();
slices = min(devices.length, MAX_PARRALLELISM_LEVEL);
// create command queues for every GPU, setup colormap and init kernels
queues = new CLCommandQueue[slices];
kernels = new CLKernel[slices];
probes = new CLEventList(slices);
colorMap = new CLBuffer[slices];
for (int i = 0; i < slices; i++) {
colorMap[i] = clContext.createIntBuffer(32*2, READ_ONLY);
initColorMap(colorMap[i].getBuffer(), 32, Color.BLUE, Color.GREEN, Color.RED);
// create command queue and upload color map buffer on each used device
queues[i] = devices[i].createCommandQueue(PROFILING_MODE).putWriteBuffer(colorMap[i], true); // blocking upload
}
// load and build program
program = clContext.createProgram(getClass().getResourceAsStream("Mandelbrot.cl"));
buildProgram();
} catch (IOException ex) {
Logger.getLogger(getClass().getName()).log(Level.SEVERE, "can not find 'Mandelbrot.cl' in classpath.", ex);
} catch (CLException ex) {
Logger.getLogger(getClass().getName()).log(Level.SEVERE, "something went wrong, hopefully no one got hurt", ex);
}
}
private void initColorMap(IntBuffer colorMap, int stepSize, Color... colors) {
for (int n = 0; n < colors.length - 1; n++) {
Color color = colors[n];
int r0 = color.getRed();
int g0 = color.getGreen();
int b0 = color.getBlue();
color = colors[n + 1];
int r1 = color.getRed();
int g1 = color.getGreen();
int b1 = color.getBlue();
int deltaR = r1 - r0;
int deltaG = g1 - g0;
int deltaB = b1 - b0;
for (int step = 0; step < stepSize; step++) {
float alpha = (float) step / (stepSize - 1);
int r = (int) (r0 + alpha * deltaR);
int g = (int) (g0 + alpha * deltaG);
int b = (int) (b0 + alpha * deltaB);
colorMap.put((r << 16) | (g << 8) | (b << 0));
}
}
colorMap.rewind();
}
private void initView(GL2 gl, int width, int height) {
gl.glViewport(0, 0, width, height);
gl.glMatrixMode(GL_MODELVIEW);
gl.glLoadIdentity();
gl.glMatrixMode(GL_PROJECTION);
gl.glLoadIdentity();
gl.glOrtho(0.0, width, 0.0, height, 0.0, 1.0);
}
@SuppressWarnings("unchecked")
private void initPBO(GL gl) {
if(pboBuffers != null) {
int[] oldPbos = new int[pboBuffers.length];
for (int i = 0; i < pboBuffers.length; i++) {
CLGLBuffer> buffer = pboBuffers[i];
oldPbos[i] = buffer.GLID;
buffer.release();
}
gl.glDeleteBuffers(oldPbos.length, oldPbos, 0);
}
pboBuffers = new CLGLBuffer[slices];
int[] pbo = new int[slices];
gl.glGenBuffers(slices, pbo, 0);
// setup one empty PBO per slice
for (int i = 0; i < slices; i++) {
gl.glBindBuffer(GL_PIXEL_UNPACK_BUFFER, pbo[i]);
gl.glBufferData(GL_PIXEL_UNPACK_BUFFER, width*height * SIZEOF_INT / slices, null, GL_STREAM_DRAW);
gl.glBindBuffer(GL_PIXEL_UNPACK_BUFFER, 0);
pboBuffers[i] = clContext.createFromGLBuffer(pbo[i], WRITE_ONLY);
}
buffersInitialized = true;
}
private void buildProgram() {
/*
* workaround: The driver keeps using the old binaries for some reason.
* to solve this we simple create a new program and release the old.
* however rebuilding programs should be possible -> remove when drivers are fixed.
*/
if(program != null && rebuild) {
String source = program.getSource();
program.release();
program = clContext.createProgram(source);
}
// disable 64bit floating point math if not available
if(doublePrecision) {
for (CLDevice device : program.getCLDevices()) {
if(!device.isDoubleFPAvailable()) {
doublePrecision = false;
break;
}
}
}
if(doublePrecision) {
program.build(CompilerOptions.FAST_RELAXED_MATH, "-D DOUBLE_FP");
}else{
program.build(CompilerOptions.FAST_RELAXED_MATH);
}
rebuild = false;
for (int i = 0; i < kernels.length; i++) {
// init kernel with constants
kernels[i] = program.createCLKernel("mandelbrot");
}
}
// init kernels with constants
private void setKernelConstants() {
for (int i = 0; i < slices; i++) {
kernels[i].setForce32BitArgs(!doublePrecision)
.setArg(6, pboBuffers[i])
.setArg(7, colorMap[i])
.setArg(8, colorMap[i].getBuffer().capacity())
.setArg(9, MAX_ITERATIONS);
}
}
// rendering cycle
public void display(GLAutoDrawable drawable) {
GL gl = drawable.getGL();
// make sure GL does not use our objects before we start computeing
gl.glFinish();
if(!buffersInitialized) {
initPBO(gl);
setKernelConstants();
}
if(rebuild) {
buildProgram();
setKernelConstants();
}
compute();
render(gl.getGL2());
}
// OpenCL
private void compute() {
int sliceWidth = width / slices;
double rangeX = (maxX - minX) / slices;
double rangeY = (maxY - minY);
// release all old events, you can't reuse events in OpenCL
probes.release();
// start computation
for (int i = 0; i < slices; i++) {
kernels[i].putArg( sliceWidth).putArg(height)
.putArg(minX + rangeX*i).putArg( minY)
.putArg( rangeX ).putArg(rangeY)
.rewind();
// aquire GL objects, and enqueue a kernel with a probe from the list
queues[i].putAcquireGLObject(pboBuffers[i].ID)
.put2DRangeKernel(kernels[i], 0, 0, sliceWidth, height, 0, 0, probes)
.putReleaseGLObject(pboBuffers[i].ID);
}
// block until done (important: finish before doing further gl work)
for (int i = 0; i < slices; i++) {
queues[i].finish();
}
}
// OpenGL
private void render(GL2 gl) {
gl.glClear(GL_COLOR_BUFFER_BIT);
//draw slices
int sliceWidth = width / slices;
for (int i = 0; i < slices; i++) {
int seperatorOffset = drawSeperator?i:0;
gl.glBindBuffer(GL_PIXEL_UNPACK_BUFFER, pboBuffers[i].GLID);
gl.glRasterPos2i(sliceWidth*i + seperatorOffset, 0);
gl.glDrawPixels(sliceWidth, height, GL_BGRA, GL_UNSIGNED_BYTE, 0);
}
gl.glBindBuffer(GL_PIXEL_UNPACK_BUFFER, 0);
//draw info text
textRenderer.beginRendering(width, height, false);
textRenderer.draw("precision: "+ (doublePrecision?"64bit":"32bit"), 10, height-15);
for (int i = 0; i < slices; i++) {
CLEvent event = probes.getEvent(i);
long start = event.getProfilingInfo(START);
long end = event.getProfilingInfo(END);
textRenderer.draw("GPU"+i +" "+(int)((end-start)/1000000.0f)+"ms", 10, height-(20+16*(slices-i)));
}
textRenderer.endRendering();
}
public void reshape(GLAutoDrawable drawable, int x, int y, int width, int height) {
if(this.width == width && this.height == height)
return;
this.width = width;
this.height = height;
initPBO(drawable.getGL());
initView(drawable.getGL().getGL2(), drawable.getWidth(), drawable.getHeight());
}
private void initSceneInteraction() {
MouseAdapter mouseAdapter = new MouseAdapter() {
Point lastpos = new Point();
@Override
public void mouseDragged(MouseEvent e) {
double offsetX = (lastpos.x - e.getX()) * (maxX - minX) / width;
double offsetY = (lastpos.y - e.getY()) * (maxY - minY) / height;
minX += offsetX;
minY -= offsetY;
maxX += offsetX;
maxY -= offsetY;
lastpos = e.getPoint();
canvas.display();
}
@Override
public void mouseMoved(MouseEvent e) {
lastpos = e.getPoint();
}
@Override
public void mouseWheelMoved(MouseWheelEvent e) {
float rotation = e.getWheelRotation() / 25.0f;
double deltaX = rotation * (maxX - minX);
double deltaY = rotation * (maxY - minY);
// offset for "zoom to cursor"
double offsetX = (e.getX() / (float)width - 0.5f) * deltaX * 2;
double offsetY = (e.getY() / (float)height- 0.5f) * deltaY * 2;
minX += deltaX+offsetX;
minY += deltaY-offsetY;
maxX +=-deltaX+offsetX;
maxY +=-deltaY-offsetY;
canvas.display();
}
};
KeyAdapter keyAdapter = new KeyAdapter() {
@Override
public void keyPressed(KeyEvent e) {
if(e.getKeyCode() == KeyEvent.VK_SPACE) {
drawSeperator = !drawSeperator;
}else if(e.getKeyChar() > '0' && e.getKeyChar() < '9') {
int number = e.getKeyChar()-'0';
slices = min(number, min(queues.length, MAX_PARRALLELISM_LEVEL));
buffersInitialized = false;
}else if(e.getKeyCode() == KeyEvent.VK_D) {
doublePrecision = !doublePrecision;
rebuild = true;
}
canvas.display();
}
};
canvas.addMouseMotionListener(mouseAdapter);
canvas.addMouseWheelListener(mouseAdapter);
canvas.addKeyListener(keyAdapter);
}
public void dispose(GLAutoDrawable drawable) {
}
public static void main(String args[]) {
SwingUtilities.invokeLater(new Runnable() {
public void run() {
new MultiDeviceFractal(512, 512);
}
});
}
}