remove extra calculations from haar to be consistent with native implementation
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@ -866,16 +866,17 @@ CvSeq *cv::ocl::OclCascadeClassifier::oclHaarDetectObjects( oclMat &gimg, CvMemS
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if(gcascade->is_stump_based && gsum.clCxt->supportsFeature(FEATURE_CL_INTEL_DEVICE))
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{
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//setup local group size
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localThreads[0] = 8;
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localThreads[1] = 16;
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//setup local group size for "pixel step" = 1
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localThreads[0] = 16;
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localThreads[1] = 32;
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localThreads[2] = 1;
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//init maximal number of workgroups
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//calc maximal number of workgroups
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int WGNumX = 1+(sizev[0].width /(localThreads[0]));
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int WGNumY = 1+(sizev[0].height/(localThreads[1]));
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int WGNumZ = loopcount;
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int WGNum = 0; //accurate number of non -empty workgroups
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int WGNumTotal = 0; //accurate number of non-empty workgroups
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int WGNumSampled = 0; //accurate number of workgroups processed only 1/4 part of all pixels. it is made for large images with scale <= 2
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oclMat oclWGInfo(1,sizeof(cl_int4) * WGNumX*WGNumY*WGNumZ,CV_8U);
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{
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cl_int4* pWGInfo = (cl_int4*)clEnqueueMapBuffer(getClCommandQueue(oclWGInfo.clCxt),(cl_mem)oclWGInfo.datastart,true,CL_MAP_WRITE, 0, oclWGInfo.step, 0,0,0,&status);
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@ -895,12 +896,16 @@ CvSeq *cv::ocl::OclCascadeClassifier::oclHaarDetectObjects( oclMat &gimg, CvMemS
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if(gx>=(Width-cascade->orig_window_size.width))
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continue; // no data to process
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if(scaleinfo[z].factor<=2)
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{
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WGNumSampled++;
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}
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// save no-empty workgroup info into array
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pWGInfo[WGNum].s[0] = scaleinfo[z].width_height;
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pWGInfo[WGNum].s[1] = (gx << 16) | gy;
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pWGInfo[WGNum].s[2] = scaleinfo[z].imgoff;
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memcpy(&(pWGInfo[WGNum].s[3]),&(scaleinfo[z].factor),sizeof(float));
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WGNum++;
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pWGInfo[WGNumTotal].s[0] = scaleinfo[z].width_height;
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pWGInfo[WGNumTotal].s[1] = (gx << 16) | gy;
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pWGInfo[WGNumTotal].s[2] = scaleinfo[z].imgoff;
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memcpy(&(pWGInfo[WGNumTotal].s[3]),&(scaleinfo[z].factor),sizeof(float));
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WGNumTotal++;
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}
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}
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}
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@ -908,13 +913,8 @@ CvSeq *cv::ocl::OclCascadeClassifier::oclHaarDetectObjects( oclMat &gimg, CvMemS
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pWGInfo = NULL;
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}
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// setup global sizes to have linear array of workgroups with WGNum size
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globalThreads[0] = localThreads[0]*WGNum;
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globalThreads[1] = localThreads[1];
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globalThreads[2] = 1;
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#define NODE_SIZE 12
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// pack node info to have less memory loads
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// pack node info to have less memory loads on the device side
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oclMat oclNodesPK(1,sizeof(cl_int) * NODE_SIZE * nodenum,CV_8U);
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{
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cl_int status;
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@ -963,8 +963,6 @@ CvSeq *cv::ocl::OclCascadeClassifier::oclHaarDetectObjects( oclMat &gimg, CvMemS
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options += format(" -D WND_SIZE_X=%d",cascade->orig_window_size.width);
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options += format(" -D WND_SIZE_Y=%d",cascade->orig_window_size.height);
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options += format(" -D STUMP_BASED=%d",gcascade->is_stump_based);
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options += format(" -D LSx=%d",localThreads[0]);
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options += format(" -D LSy=%d",localThreads[1]);
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options += format(" -D SPLITNODE=%d",splitnode);
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options += format(" -D SPLITSTAGE=%d",splitstage);
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options += format(" -D OUTPUTSZ=%d",outputsz);
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@ -972,8 +970,39 @@ CvSeq *cv::ocl::OclCascadeClassifier::oclHaarDetectObjects( oclMat &gimg, CvMemS
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// init candiate global count by 0
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int pattern = 0;
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openCLSafeCall(clEnqueueWriteBuffer(qu, candidatebuffer, 1, 0, 1 * sizeof(pattern),&pattern, 0, NULL, NULL));
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// execute face detector
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openCLExecuteKernel(gsum.clCxt, &haarobjectdetect, "gpuRunHaarClassifierCascadePacked", globalThreads, localThreads, args, -1, -1, options.c_str());
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if(WGNumTotal>WGNumSampled)
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{// small images and each pixel is processed
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// setup global sizes to have linear array of workgroups with WGNum size
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int pixelstep = 1;
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size_t LS[3]={localThreads[0]/pixelstep,localThreads[1]/pixelstep,1};
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globalThreads[0] = LS[0]*(WGNumTotal-WGNumSampled);
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globalThreads[1] = LS[1];
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globalThreads[2] = 1;
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string options1 = options;
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options1 += format(" -D PIXEL_STEP=%d",pixelstep);
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options1 += format(" -D WGSTART=%d",WGNumSampled);
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options1 += format(" -D LSx=%d",LS[0]);
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options1 += format(" -D LSy=%d",LS[1]);
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// execute face detector
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openCLExecuteKernel(gsum.clCxt, &haarobjectdetect, "gpuRunHaarClassifierCascadePacked", globalThreads, LS, args, -1, -1, options1.c_str());
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}
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if(WGNumSampled>0)
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{// large images each 4th pixel is processed
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// setup global sizes to have linear array of workgroups with WGNum size
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int pixelstep = 2;
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size_t LS[3]={localThreads[0]/pixelstep,localThreads[1]/pixelstep,1};
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globalThreads[0] = LS[0]*WGNumSampled;
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globalThreads[1] = LS[1];
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globalThreads[2] = 1;
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string options2 = options;
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options2 += format(" -D PIXEL_STEP=%d",pixelstep);
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options2 += format(" -D WGSTART=%d",0);
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options2 += format(" -D LSx=%d",LS[0]);
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options2 += format(" -D LSy=%d",LS[1]);
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// execute face detector
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openCLExecuteKernel(gsum.clCxt, &haarobjectdetect, "gpuRunHaarClassifierCascadePacked", globalThreads, LS, args, -1, -1, options2.c_str());
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}
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//read candidate buffer back and put it into host list
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openCLReadBuffer( gsum.clCxt, candidatebuffer, candidate, 4 * sizeof(int)*outputsz );
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assert(candidate[0]<outputsz);
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@ -126,13 +126,11 @@ __kernel void gpuRunHaarClassifierCascadePacked(
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)
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{
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// this version used information provided for each workgroup
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// no empty WG
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int gid = (int)get_group_id(0);
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int lid_x = (int)get_local_id(0);
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int lid_y = (int)get_local_id(1);
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int lid = lid_y*LSx+lid_x;
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int4 WGInfo = pWGInfo[gid];
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int4 WGInfo = pWGInfo[WGSTART+gid];
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int GroupX = (WGInfo.y >> 16)&0xFFFF;
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int GroupY = (WGInfo.y >> 0 )& 0xFFFF;
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int Width = (WGInfo.x >> 16)&0xFFFF;
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@ -140,8 +138,8 @@ __kernel void gpuRunHaarClassifierCascadePacked(
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int ImgOffset = WGInfo.z;
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float ScaleFactor = as_float(WGInfo.w);
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#define DATA_SIZE_X (LSx+WND_SIZE_X)
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#define DATA_SIZE_Y (LSy+WND_SIZE_Y)
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#define DATA_SIZE_X (PIXEL_STEP*LSx+WND_SIZE_X)
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#define DATA_SIZE_Y (PIXEL_STEP*LSy+WND_SIZE_Y)
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#define DATA_SIZE (DATA_SIZE_X*DATA_SIZE_Y)
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local int SumL[DATA_SIZE];
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@ -165,9 +163,11 @@ __kernel void gpuRunHaarClassifierCascadePacked(
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int4 info1 = p;
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int4 info2 = pq;
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{
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int xl = lid_x;
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int yl = lid_y;
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// calc processed ROI coordinate in local mem
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int xl = lid_x*PIXEL_STEP;
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int yl = lid_y*PIXEL_STEP;
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{// calc variance_norm_factor for all stages
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int OffsetLocal = yl * DATA_SIZE_X + xl;
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int OffsetGlobal = (GroupY+yl)* pixelstep + (GroupX+xl);
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@ -194,13 +194,13 @@ __kernel void gpuRunHaarClassifierCascadePacked(
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int result = (1.0f>0.0f);
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for(int stageloop = start_stage; (stageloop < end_stage) && result; stageloop++ )
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{// iterate until candidate is exist
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{// iterate until candidate is valid
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float stage_sum = 0.0f;
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__global GpuHidHaarStageClassifier* stageinfo = (__global GpuHidHaarStageClassifier*)
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((__global uchar*)stagecascadeptr+stageloop*sizeof(GpuHidHaarStageClassifier));
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int lcl_off = (yl*DATA_SIZE_X)+(xl);
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int stagecount = stageinfo->count;
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float stagethreshold = stageinfo->threshold;
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int lcl_off = (lid_y*DATA_SIZE_X)+(lid_x);
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for(int nodeloop = 0; nodeloop < stagecount; nodecounter++,nodeloop++ )
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{
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// simple macro to extract shorts from int
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@ -212,7 +212,7 @@ __kernel void gpuRunHaarClassifierCascadePacked(
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int4 n1 = pN[1];
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int4 n2 = pN[2];
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float nodethreshold = as_float(n2.y) * variance_norm_factor;
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// calc sum of intensity pixels according to node information
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// calc sum of intensity pixels according to classifier node information
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float classsum =
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(SumL[M0(n0.x)+lcl_off] - SumL[M1(n0.x)+lcl_off] - SumL[M0(n0.y)+lcl_off] + SumL[M1(n0.y)+lcl_off]) * as_float(n1.z) +
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(SumL[M0(n0.z)+lcl_off] - SumL[M1(n0.z)+lcl_off] - SumL[M0(n0.w)+lcl_off] + SumL[M1(n0.w)+lcl_off]) * as_float(n1.w) +
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@ -228,8 +228,8 @@ __kernel void gpuRunHaarClassifierCascadePacked(
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int index = 1+atomic_inc((volatile global int*)candidate); //get index to write global data with face info
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if(index<OUTPUTSZ)
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{
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int x = GroupX+lid_x;
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int y = GroupY+lid_y;
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int x = GroupX+xl;
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int y = GroupY+yl;
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int4 candidate_result;
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candidate_result.x = convert_int_rtn(x*ScaleFactor);
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candidate_result.y = convert_int_rtn(y*ScaleFactor);
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