void ofxKinectTracking::update(){ bool newFrame; #ifndef NORMAL_CAMERA kinect->update(); newFrame = kinect->isFrameNew(); #else videoGrabber.update(); newFrame = videoGrabber.isFrameNew(); if(newFrame){ int pixelIndex = 0; for(int i=0; i<640; i++) { for(int j=0; j<480; j++) { int indexRGB = pixelIndex * 3; int indexL = pixelIndex; pixels[indexL] = videoGrabber.getPixels()[indexRGB+1 ]; pixelIndex++; } } // write the new pixel data into the OpenCL Image (and thus the OpenGL texture) clImage[0].write(pixels); } #endif if(newFrame){ cl_int2 spawnCoord = {int(ofRandom(0, 640)), int(ofRandom(0, 480))}; if(ofRandom(0, 1) < 0.500){ spawnCoord[0] = -1; spawnCoord[0] = -1; } MSA::OpenCLKernel *preKernel = openCL.kernel("preUpdate"); MSA::OpenCLKernel *updateKernel = openCL.kernel("update"); MSA::OpenCLKernel *postKernel = openCL.kernel("postUpdate"); //Prepare timetaking double totalTimeTmp; uint64_t mbeg, mend; openCL.finish(); mbeg = mach_absolute_time(); //Run pre update kernel preKernel->setArg(0, clImage[0].getCLMem()); preKernel->setArg(1, clAntsBuffer.getCLMem()); preKernel->run2D(640, 480); //Calculate time openCL.finish(); mend = mach_absolute_time(); killingTime.push_back(machcore(mend, mbeg)); totalTimeTmp = machcore(mend, mbeg); mbeg = mach_absolute_time(); //Run update kernel size_t shared_size = (1 * 64) * sizeof(int); updateKernel->setArg(0, clAntsBuffer.getCLMem()); updateKernel->setArg(1, clSharedBuffer.getCLMem()); updateKernel->setArg(2, spawnCoord); clSetKernelArg(updateKernel->getCLKernel(), 3, shared_size, NULL); for(int i=0;i<NUM_ITERATIONS;i++){ updateKernel->run2D(640, 480); } //Calculate time openCL.finish(); mend = mach_absolute_time(); spawningTime.push_back(machcore(mend, mbeg)); totalTimeTmp += machcore(mend, mbeg); mbeg = mach_absolute_time(); //Run post update kernel postKernel->setArg(0, clImage[0].getCLMem()); postKernel->setArg(1, clImage[1].getCLMem()); postKernel->setArg(2, clAntsBuffer.getCLMem()); postKernel->setArg(3, clSharedBuffer.getCLMem()); postKernel->setArg(4, spawnCoord); postKernel->run2D(640, 480); //Calculate time openCL.finish(); mend = mach_absolute_time(); updateTime.push_back(machcore(mend, mbeg)); totalTimeTmp += machcore(mend, mbeg); totalTime.push_back(totalTimeTmp); if(totalTime.size() > (640*2)/3){ totalTime.erase(totalTime.begin()); killingTime.erase(killingTime.begin()); spawningTime.erase(spawningTime.begin()); updateTime.erase(updateTime.begin()); } } }
//-------------------------------------------------------------- void testApp::setup(){ ofBackground(0, 0, 0); ofSetLogLevel(OF_LOG_VERBOSE); ofSetVerticalSync(false); #ifdef USE_OPENGL_CONTEXT opencl.setupFromOpenGL(); #else opencl.setup(CL_DEVICE_TYPE_CPU, 2); #endif for(int i=0; i<NUM_PARTICLES; i++) { Particle &p = particles[i]; p.vel.set(0, 0); p.mass = ofRandom(0.5, 1); particlesPos[i].set(ofRandomWidth(), ofRandomHeight()); } glGenBuffersARB(1, vbo); glBindBufferARB(GL_ARRAY_BUFFER_ARB, vbo[0]); glBufferDataARB(GL_ARRAY_BUFFER_ARB, sizeof(float2) * NUM_PARTICLES, particlesPos, GL_DYNAMIC_COPY_ARB); glBindBufferARB(GL_ARRAY_BUFFER_ARB, 0); opencl.loadProgramFromFile("MSAOpenCL/Particle.cl"); kernelUpdate = opencl.loadKernel("updateParticle"); clMemParticles.initBuffer(sizeof(Particle) * NUM_PARTICLES, CL_MEM_READ_WRITE, particles); #ifdef USE_OPENGL_CONTEXT clMemPosVBO.initFromGLObject(vbo[0]); #else clMemPosVBO.initBuffer(sizeof(Vec2) * NUM_PARTICLES, CL_MEM_READ_WRITE, particlesPos); #endif kernelUpdate->setArg(0, clMemParticles.getCLMem()); kernelUpdate->setArg(1, clMemPosVBO.getCLMem()); kernelUpdate->setArg(2, mousePos); kernelUpdate->setArg(3, dimensions); glPointSize(1); }