haarobjectdetect.cl

//                           License Agreement
//                For Open Source Computer Vision Library
//
// Copyright (C) 2010-2012, Institute Of Software Chinese Academy Of Science, all rights reserved.
// Copyright (C) 2010-2012, Advanced Micro Devices, Inc., all rights reserved.
// Third party copyrights are property of their respective owners.
//
// @Authors
//    Niko Li, newlife20080214@gmail.com
//    Wang Weiyan, wangweiyanster@gmail.com
//    Jia Haipeng, jiahaipeng95@gmail.com
//    Nathan, liujun@multicorewareinc.com
// Redistribution and use in source and binary forms, with or without modification,
// are permitted provided that the following conditions are met:
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#pragma OPENCL EXTENSION cl_amd_printf : enable
#define CV_HAAR_FEATURE_MAX           3

#define calc_sum(rect,offset)        (sum[(rect).p0+offset] - sum[(rect).p1+offset] - sum[(rect).p2+offset] + sum[(rect).p3+offset])
#define calc_sum1(rect,offset,i)     (sum[(rect).p0[i]+offset] - sum[(rect).p1[i]+offset] - sum[(rect).p2[i]+offset] + sum[(rect).p3[i]+offset])

typedef int   sumtype;
typedef float sqsumtype;

typedef struct  __attribute__((aligned (128)))  GpuHidHaarFeature
{
    struct __attribute__((aligned (32)))
{
    int p0 __attribute__((aligned (4)));
    int p1 __attribute__((aligned (4)));
    int p2 __attribute__((aligned (4)));
    int p3 __attribute__((aligned (4)));
    float weight __attribute__((aligned (4)));
}
rect[CV_HAAR_FEATURE_MAX] __attribute__((aligned (32)));
}
GpuHidHaarFeature;


typedef struct __attribute__((aligned (128) )) GpuHidHaarTreeNode
{
    int p[CV_HAAR_FEATURE_MAX][4] __attribute__((aligned (64)));
    float weight[CV_HAAR_FEATURE_MAX] /*__attribute__((aligned (16)))*/;
    float threshold /*__attribute__((aligned (4)))*/;
    float alpha[2] __attribute__((aligned (8)));
    int left __attribute__((aligned (4)));
    int right __attribute__((aligned (4)));
}
GpuHidHaarTreeNode;


typedef struct __attribute__((aligned (32))) GpuHidHaarClassifier
{
    int count __attribute__((aligned (4)));
    GpuHidHaarTreeNode* node __attribute__((aligned (8)));
    float* alpha __attribute__((aligned (8)));
}
GpuHidHaarClassifier;


typedef struct __attribute__((aligned (64))) GpuHidHaarStageClassifier
{
    int  count __attribute__((aligned (4)));
    float threshold __attribute__((aligned (4)));
    int two_rects __attribute__((aligned (4)));
    int reserved0 __attribute__((aligned (8)));
    int reserved1 __attribute__((aligned (8)));
    int reserved2 __attribute__((aligned (8)));
    int reserved3 __attribute__((aligned (8)));
}
GpuHidHaarStageClassifier;


typedef struct __attribute__((aligned (64))) GpuHidHaarClassifierCascade
{
    int  count __attribute__((aligned (4)));
    int  is_stump_based __attribute__((aligned (4)));
    int  has_tilted_features __attribute__((aligned (4)));
    int  is_tree __attribute__((aligned (4)));
    int pq0 __attribute__((aligned (4)));
    int pq1 __attribute__((aligned (4)));
    int pq2 __attribute__((aligned (4)));
    int pq3 __attribute__((aligned (4)));
    int p0 __attribute__((aligned (4)));
    int p1 __attribute__((aligned (4)));
    int p2 __attribute__((aligned (4)));
    int p3 __attribute__((aligned (4)));
    float inv_window_area __attribute__((aligned (4)));
} GpuHidHaarClassifierCascade;


__kernel void __attribute__((reqd_work_group_size(8,8,1)))gpuRunHaarClassifierCascade(//constant GpuHidHaarClassifierCascade * cascade,
    global GpuHidHaarStageClassifier * stagecascadeptr,
    global int4 * info,
    global GpuHidHaarTreeNode * nodeptr,
    global const int * restrict sum1,
    global const float * restrict sqsum1,
    global int4 * candidate,
    const int pixelstep,
    const int loopcount,
    const int start_stage,
    const int split_stage,
    const int end_stage,
    const int startnode,
    const int splitnode,
    const int4 p,
    const int4 pq,
    const float correction
    //const int width,
    //const int height,
    //const int grpnumperline,
    //const int totalgrp
)
{
    int grpszx = get_local_size(0);
    int grpszy = get_local_size(1);
    int grpnumx = get_num_groups(0);
    int grpidx = get_group_id(0);
    int lclidx = get_local_id(0);
    int lclidy = get_local_id(1);

    int lcl_sz = mul24(grpszx,grpszy);
    int lcl_id = mad24(lclidy,grpszx,lclidx);

    //assume lcl_sz == 256 or 128 or 64
    //int lcl_sz_shift = (lcl_sz == 256) ? 8 : 7;
    //lcl_sz_shift = (lcl_sz == 64) ? 6 : lcl_sz_shift;
    __local int lclshare[1024];

#define OFF 0
    __local int* lcldata = lclshare + OFF;//for save win data
    __local int* glboutindex = lcldata + 28*28;//for save global out index
    __local int* lclcount = glboutindex + 1;//for save the numuber of temp pass pixel
    __local int* lcloutindex = lclcount + 1;//for save info of temp pass pixel
    __local float* partialsum = (__local float*)(lcloutindex + (lcl_sz<<1));
    glboutindex[0]=0;
    int outputoff = mul24(grpidx,256);

    //assume window size is 20X20
#define WINDOWSIZE 20+1
    //make sure readwidth is the multiple of 4
    //ystep =1, from host code
    int readwidth = ((grpszx-1 + WINDOWSIZE+3)>>2)<<2;
    int readheight = grpszy-1+WINDOWSIZE;
    int read_horiz_cnt = readwidth >> 2;//each read int4
    int total_read = mul24(read_horiz_cnt,readheight);
    int read_loop = (total_read + lcl_sz - 1) >> 6;
    candidate[outputoff+(lcl_id<<2)] = (int4)0;
    candidate[outputoff+(lcl_id<<2)+1] = (int4)0;
    candidate[outputoff+(lcl_id<<2)+2] = (int4)0;
    candidate[outputoff+(lcl_id<<2)+3] = (int4)0;
    for(int scalei = 0; scalei <loopcount; scalei++)
    {
        int4 scaleinfo1= info[scalei];
        int width = (scaleinfo1.x & 0xffff0000) >> 16;
        int height = scaleinfo1.x & 0xffff;
        int grpnumperline =(scaleinfo1.y & 0xffff0000) >> 16;
        int totalgrp = scaleinfo1.y & 0xffff;
        int imgoff = scaleinfo1.z;
        float factor = as_float(scaleinfo1.w);
        //int ystep =1;// factor > 2.0 ? 1 : 2;

        __global const int * sum = sum1 + imgoff;
        __global const float * sqsum = sqsum1 + imgoff;
        for(int grploop=grpidx; grploop<totalgrp; grploop+=grpnumx)
        {
            int grpidy = grploop / grpnumperline;
            int grpidx = grploop - mul24(grpidy, grpnumperline);
            int x = mad24(grpidx,grpszx,lclidx);
            int y = mad24(grpidy,grpszy,lclidy);
            //candidate_result.x = convert_int_rtn(x*factor);
            //candidate_result.y = convert_int_rtn(y*factor);
            int grpoffx = x-lclidx;
            int grpoffy = y-lclidy;

            for(int i=0; i<read_loop; i++)
            {
                int pos_id = mad24(i,lcl_sz,lcl_id);
                pos_id = pos_id < total_read ? pos_id : 0;

                int lcl_y = pos_id / read_horiz_cnt;
                int lcl_x = pos_id - mul24(lcl_y, read_horiz_cnt);

                int glb_x = grpoffx + (lcl_x<<2);
                int glb_y = grpoffy + lcl_y;

                int glb_off = mad24(glb_y,pixelstep,glb_x);
                int4 data = *(__global int4*)&sum[glb_off];
                int lcl_off = mad24(lcl_y, readwidth, lcl_x<<2);

                lcldata[lcl_off] = data.x;
                lcldata[lcl_off+1] = data.y;
                lcldata[lcl_off+2] = data.z;
                lcldata[lcl_off+3] = data.w;
            }

            lcloutindex[lcl_id] = 0;
            lclcount[0] = 0;
            int result = 1;
            int nodecounter= startnode;
            float mean, variance_norm_factor;
            barrier(CLK_LOCAL_MEM_FENCE);

            int lcl_off = mad24(lclidy,readwidth,lclidx);
            int4 cascadeinfo1, cascadeinfo2;
            cascadeinfo1 = p;
            cascadeinfo2 = pq;// + mad24(y, pixelstep, x);


            //if((x < width) && (y < height))
            {
                cascadeinfo1.x +=lcl_off;
                cascadeinfo1.z +=lcl_off;
                mean = (lcldata[mad24(cascadeinfo1.y,readwidth,cascadeinfo1.x)] - lcldata[mad24(cascadeinfo1.y,readwidth,cascadeinfo1.z)] -
                        lcldata[mad24(cascadeinfo1.w,readwidth,cascadeinfo1.x)] + lcldata[mad24(cascadeinfo1.w,readwidth,cascadeinfo1.z)])
                       *correction;

                int p_offset = mad24(y, pixelstep, x);

                cascadeinfo2.x +=p_offset;
                cascadeinfo2.z +=p_offset;
                variance_norm_factor =sqsum[mad24(cascadeinfo2.y, pixelstep, cascadeinfo2.x)] - sqsum[mad24(cascadeinfo2.y, pixelstep, cascadeinfo2.z)] -
                                      sqsum[mad24(cascadeinfo2.w, pixelstep, cascadeinfo2.x)] + sqsum[mad24(cascadeinfo2.w, pixelstep, cascadeinfo2.z)];

                variance_norm_factor = variance_norm_factor * correction - mean * mean;
                variance_norm_factor = variance_norm_factor >=0.f ? sqrt(variance_norm_factor) : 1.f;
                //if( cascade->is_stump_based )
                //{
                for(int stageloop = start_stage; (stageloop < split_stage)  && result; stageloop++ )
                {
                    float stage_sum = 0.f;
                    int2 stageinfo = *(global int2*)(stagecascadeptr+stageloop);
                    float stagethreshold = as_float(stageinfo.y);
                    for(int nodeloop = 0; nodeloop < stageinfo.x; nodeloop++ )
                    {
                        __global GpuHidHaarTreeNode* currentnodeptr = (nodeptr + nodecounter);

                        int4 info1 = *(__global int4*)(&(currentnodeptr->p[0][0]));
                        int4 info2 = *(__global int4*)(&(currentnodeptr->p[1][0]));
                        int4 info3 = *(__global int4*)(&(currentnodeptr->p[2][0]));
                        float4 w = *(__global float4*)(&(currentnodeptr->weight[0]));
                        float2 alpha2 = *(__global float2*)(&(currentnodeptr->alpha[0]));
                        float nodethreshold  = w.w * variance_norm_factor;

                        info1.x +=lcl_off;
                        info1.z +=lcl_off;
                        info2.x +=lcl_off;
                        info2.z +=lcl_off;

                        float classsum = (lcldata[mad24(info1.y,readwidth,info1.x)] - lcldata[mad24(info1.y,readwidth,info1.z)] -
                                          lcldata[mad24(info1.w,readwidth,info1.x)] + lcldata[mad24(info1.w,readwidth,info1.z)]) * w.x;


                        classsum += (lcldata[mad24(info2.y,readwidth,info2.x)] - lcldata[mad24(info2.y,readwidth,info2.z)] -
                                     lcldata[mad24(info2.w,readwidth,info2.x)] + lcldata[mad24(info2.w,readwidth,info2.z)]) * w.y;


                        //if((info3.z - info3.x) && (!stageinfo.z))
                        //{
                        info3.x +=lcl_off;
                        info3.z +=lcl_off;
                        classsum += (lcldata[mad24(info3.y,readwidth,info3.x)] - lcldata[mad24(info3.y,readwidth,info3.z)] -
                                     lcldata[mad24(info3.w,readwidth,info3.x)] + lcldata[mad24(info3.w,readwidth,info3.z)]) * w.z;
                        //}
                        stage_sum += classsum >= nodethreshold ? alpha2.y : alpha2.x;
                        nodecounter++;
                    }

                    result = (stage_sum >= stagethreshold);
                }

                if(result && (x < width) && (y < height))
                {
                    int queueindex = atomic_inc(lclcount);
                    lcloutindex[queueindex<<1] = (lclidy << 16) | lclidx;
                    lcloutindex[(queueindex<<1)+1] = as_int(variance_norm_factor);
                }
                barrier(CLK_LOCAL_MEM_FENCE);
                int queuecount  = lclcount[0];
                barrier(CLK_LOCAL_MEM_FENCE);
                nodecounter = splitnode;
                for(int stageloop = split_stage; stageloop< end_stage && queuecount>0; stageloop++)
                {
                    //barrier(CLK_LOCAL_MEM_FENCE);
                    //if(lcl_id == 0)
                    lclcount[0]=0;
                    barrier(CLK_LOCAL_MEM_FENCE);

                    int2 stageinfo = *(global int2*)(stagecascadeptr+stageloop);
                    float stagethreshold = as_float(stageinfo.y);

                    int perfscale = queuecount > 4 ? 3 : 2;
                    int queuecount_loop = (queuecount + (1<<perfscale)-1) >> perfscale;
                    int lcl_compute_win = lcl_sz >> perfscale;
                    int lcl_compute_win_id = (lcl_id >>(6-perfscale));
                    int lcl_loops = (stageinfo.x + lcl_compute_win -1) >> (6-perfscale);
                    int lcl_compute_id = lcl_id - (lcl_compute_win_id << (6-perfscale));
                    for(int queueloop=0; queueloop<queuecount_loop/* && lcl_compute_win_id < queuecount*/; queueloop++)
                    {
                        float stage_sum = 0.f;
                        int temp_coord = lcloutindex[lcl_compute_win_id<<1];
                        float variance_norm_factor = as_float(lcloutindex[(lcl_compute_win_id<<1)+1]);
                        int queue_pixel = mad24(((temp_coord  & (int)0xffff0000)>>16),readwidth,temp_coord & 0xffff);

                        //barrier(CLK_LOCAL_MEM_FENCE);
                        if(lcl_compute_win_id < queuecount)
                        {

                            int tempnodecounter = lcl_compute_id;
                            float part_sum = 0.f;
                            for(int lcl_loop=0; lcl_loop<lcl_loops && tempnodecounter<stageinfo.x; lcl_loop++)
                            {
                                __global GpuHidHaarTreeNode* currentnodeptr = (nodeptr + nodecounter + tempnodecounter);

                                int4 info1 = *(__global int4*)(&(currentnodeptr->p[0][0]));
                                int4 info2 = *(__global int4*)(&(currentnodeptr->p[1][0]));
                                int4 info3 = *(__global int4*)(&(currentnodeptr->p[2][0]));
                                float4 w = *(__global float4*)(&(currentnodeptr->weight[0]));
                                float2 alpha2 = *(__global float2*)(&(currentnodeptr->alpha[0]));
                                float nodethreshold  = w.w * variance_norm_factor;

                                info1.x +=queue_pixel;
                                info1.z +=queue_pixel;
                                info2.x +=queue_pixel;
                                info2.z +=queue_pixel;

                                float classsum = (lcldata[mad24(info1.y,readwidth,info1.x)] - lcldata[mad24(info1.y,readwidth,info1.z)] -
                                                  lcldata[mad24(info1.w,readwidth,info1.x)] + lcldata[mad24(info1.w,readwidth,info1.z)]) * w.x;


                                classsum += (lcldata[mad24(info2.y,readwidth,info2.x)] - lcldata[mad24(info2.y,readwidth,info2.z)] -
                                             lcldata[mad24(info2.w,readwidth,info2.x)] + lcldata[mad24(info2.w,readwidth,info2.z)]) * w.y;
                                //if((info3.z - info3.x) && (!stageinfo.z))
                                //{
                                info3.x +=queue_pixel;
                                info3.z +=queue_pixel;
                                classsum += (lcldata[mad24(info3.y,readwidth,info3.x)] - lcldata[mad24(info3.y,readwidth,info3.z)] -
                                             lcldata[mad24(info3.w,readwidth,info3.x)] + lcldata[mad24(info3.w,readwidth,info3.z)]) * w.z;
                                //}
                                part_sum += classsum >= nodethreshold ? alpha2.y : alpha2.x;
                                tempnodecounter +=lcl_compute_win;
                            }//end for(int lcl_loop=0;lcl_loop<lcl_loops;lcl_loop++)
                            partialsum[lcl_id]=part_sum;
                        }
                        barrier(CLK_LOCAL_MEM_FENCE);
                        if(lcl_compute_win_id < queuecount)
                        {
                            for(int i=0; i<lcl_compute_win && (lcl_compute_id==0); i++)
                            {
                                stage_sum += partialsum[lcl_id+i];
                            }
                            if(stage_sum >= stagethreshold && (lcl_compute_id==0))
                            {
                                int queueindex = atomic_inc(lclcount);
                                lcloutindex[queueindex<<1] = temp_coord;
                                lcloutindex[(queueindex<<1)+1] = as_int(variance_norm_factor);
                            }
                            lcl_compute_win_id +=(1<<perfscale);
                        }
                        barrier(CLK_LOCAL_MEM_FENCE);
                    }//end for(int queueloop=0;queueloop<queuecount_loop;queueloop++)
                    //barrier(CLK_LOCAL_MEM_FENCE);
                    queuecount = lclcount[0];
                    barrier(CLK_LOCAL_MEM_FENCE);
                    nodecounter += stageinfo.x;
                }//end for(int stageloop = splitstage; stageloop< endstage && queuecount>0;stageloop++)
                //barrier(CLK_LOCAL_MEM_FENCE);
                if(lcl_id<queuecount)
                {
                    int temp = lcloutindex[lcl_id<<1];
                    int x = mad24(grpidx,grpszx,temp & 0xffff);
                    int y = mad24(grpidy,grpszy,((temp & (int)0xffff0000) >> 16));
                    temp = glboutindex[0];
                    int4 candidate_result;
                    candidate_result.zw = (int2)convert_int_rtn(factor*20.f);
                    candidate_result.x = convert_int_rtn(x*factor);
                    candidate_result.y = convert_int_rtn(y*factor);
                    atomic_inc(glboutindex);
                    candidate[outputoff+temp+lcl_id] = candidate_result;
                }
                barrier(CLK_LOCAL_MEM_FENCE);
            }//end if((x < width) && (y < height))
        }//end for(int grploop=grpidx;grploop<totalgrp;grploop+=grpnumx)
        //outputoff +=mul24(width,height);
    }//end for(int scalei = 0; scalei <loopcount; scalei++)
}


















/*
if(stagecascade->two_rects)
{
    #pragma unroll
    for( n = 0; n < stagecascade->count; n++ )
    {
        t1 = *(node + counter);
        t = t1.threshold * variance_norm_factor;
        classsum = calc_sum1(t1,p_offset,0) * t1.weight[0];

        classsum  += calc_sum1(t1, p_offset,1) * t1.weight[1];
        stage_sum += classsum >= t ? t1.alpha[1]:t1.alpha[0];

        counter++;
    }
}
else
{
    #pragma unroll
    for( n = 0; n < stagecascade->count; n++ )
    {
        t = node[counter].threshold*variance_norm_factor;
        classsum = calc_sum1(node[counter],p_offset,0) * node[counter].weight[0];
        classsum += calc_sum1(node[counter],p_offset,1) * node[counter].weight[1];

        if( node[counter].p0[2] )
            classsum += calc_sum1(node[counter],p_offset,2) * node[counter].weight[2];

        stage_sum += classsum >= t ? node[counter].alpha[1]:node[counter].alpha[0];// modify

        counter++;
    }
}
*/
/*
__kernel void gpuRunHaarClassifierCascade_ScaleWindow(
                          constant GpuHidHaarClassifierCascade * _cascade,
                          global GpuHidHaarStageClassifier * stagecascadeptr,
                          //global GpuHidHaarClassifier * classifierptr,
                          global GpuHidHaarTreeNode * nodeptr,
                          global int * sum,
                          global float * sqsum,
                          global int * _candidate,
                          int pixel_step,
                          int cols,
                          int rows,
                          int start_stage,
                          int end_stage,
                          //int counts,
                          int nodenum,
                          int ystep,
                          int detect_width,
                          //int detect_height,
                          int loopcount,
                          int outputstep)
                          //float scalefactor)
{
unsigned int x1 = get_global_id(0);
unsigned int y1 = get_global_id(1);
int p_offset;
int m, n;
int result;
int counter;
float mean, variance_norm_factor;
for(int i=0;i<loopcount;i++)
{
constant GpuHidHaarClassifierCascade * cascade = _cascade + i;
global int * candidate = _candidate + i*outputstep;
int window_width = cascade->p1 - cascade->p0;
int window_height = window_width;
result = 1;
counter = 0;
unsigned int x = mul24(x1,ystep);
unsigned int y = mul24(y1,ystep);
if((x < cols - window_width - 1) && (y < rows - window_height -1))
{
global GpuHidHaarStageClassifier *stagecascade = stagecascadeptr +cascade->count*i+ start_stage;
//global GpuHidHaarClassifier      *classifier   = classifierptr;
global GpuHidHaarTreeNode        *node         = nodeptr + nodenum*i;

p_offset = mad24(y, pixel_step, x);// modify

mean = (*(sum + p_offset + (int)cascade->p0) - *(sum + p_offset + (int)cascade->p1) -
    *(sum + p_offset + (int)cascade->p2) + *(sum + p_offset + (int)cascade->p3))
    *cascade->inv_window_area;

variance_norm_factor = *(sqsum + p_offset + cascade->p0) - *(sqsum + cascade->p1 + p_offset) -
                    *(sqsum + p_offset + cascade->p2) + *(sqsum + cascade->p3 + p_offset);
variance_norm_factor = variance_norm_factor * cascade->inv_window_area - mean * mean;
variance_norm_factor = variance_norm_factor >=0.f ? sqrt(variance_norm_factor) : 1;//modify

// if( cascade->is_stump_based )
//{
for( m = start_stage; m < end_stage; m++ )
{
float stage_sum = 0.f;
float t,  classsum;
GpuHidHaarTreeNode t1;

//#pragma unroll
for( n = 0; n < stagecascade->count; n++ )
{
     t1 = *(node + counter);
     t  = t1.threshold * variance_norm_factor;
     classsum = calc_sum1(t1, p_offset ,0) * t1.weight[0] + calc_sum1(t1, p_offset ,1) * t1.weight[1];

     if((t1.p0[2]) && (!stagecascade->two_rects))
         classsum += calc_sum1(t1, p_offset, 2) * t1.weight[2];

     stage_sum += classsum >= t ? t1.alpha[1] : t1.alpha[0];// modify
     counter++;
}

if (stage_sum < stagecascade->threshold)
{
    result = 0;
    break;
}

stagecascade++;

}
if(result)
{
    candidate[4 * (y1 * detect_width + x1)]     = x;
    candidate[4 * (y1 * detect_width + x1) + 1] = y;
    candidate[4 * (y1 * detect_width + x1)+2]     = window_width;
    candidate[4 * (y1 * detect_width + x1) + 3] = window_height;
}
//}
}
}
}
*/