00001 #ifdef DWIN
00002 #include "stdafx.h"
00003 #include <windows.h>
00004 #endif
00005
00006 #include "CRForestEstimator.h"
00007 #include <vector>
00008 #include <iostream>
00009 #include <opencv2/highgui/highgui.hpp>
00010 #include <opencv2/imgproc/imgproc.hpp>
00011
00012 using namespace std;
00013 using namespace cv;
00014
00015 bool CRForestEstimator::loadForest(const char* treespath, int ntrees){
00016
00017
00018 crForest = new CRForest( ntrees );
00019
00020 if( !crForest->loadForest( treespath ) )
00021 return false;
00022
00023 return true;
00024 }
00025
00026 Rect CRForestEstimator::getBoundingBox(const Mat& im3D){
00027
00028 Rect bbox;
00029 int min_x = im3D.cols;
00030 int min_y = im3D.rows;
00031 int max_x = 0;
00032 int max_y = 0;
00033 int p_width = crForest->getPatchWidth();
00034 int p_height = crForest->getPatchHeight();
00035
00036 for(int y = 0; y < im3D.rows; y++)
00037 {
00038 const Vec3f* Mi = im3D.ptr<Vec3f>(y);
00039 for(int x = 0; x < im3D.cols; x++){
00040
00041 if( Mi[x][2] > 0) {
00042
00043 min_x = MIN(min_x,x); min_y = MIN(min_y,y);
00044 max_x = MAX(max_x,x); max_y = MAX(max_y,y);
00045 }
00046
00047 }
00048 }
00049
00050 int new_w = max_x - min_x + p_width;
00051 int new_h = max_y - min_y + p_height;
00052
00053 bbox.x = MIN( im3D.cols-1, MAX( 0 , min_x - p_width/2 ) );
00054 bbox.y = MIN( im3D.rows-1, MAX( 0 , min_y - p_height/2) );
00055
00056 bbox.width = MAX(0, MIN( new_w, im3D.cols-bbox.x));
00057 bbox.height = MAX(0, MIN( new_h, im3D.rows-bbox.y));
00058
00059 return bbox;
00060
00061 }
00062
00063 void CRForestEstimator::estimate( const Mat & im3D,
00064 std::vector< cv::Vec<float,6> >& means,
00065 std::vector< std::vector< Vote > >& clusters,
00066 std::vector< Vote >& votes,
00067 int stride,
00068 float max_variance,
00069 float prob_th,
00070 float larger_radius_ratio,
00071 float smaller_radius_ratio,
00072 bool verbose , int threshold ){
00073
00074 unsigned int max_clusters = 20;
00075 int max_ms_iterations = 10;
00076
00077 int p_width = crForest->getPatchWidth();
00078 int p_height = crForest->getPatchHeight();
00079
00080
00081 Rect bbox = getBoundingBox(im3D);
00082
00083 vector<Mat> channels;
00084 split(im3D, channels);
00085
00086 int rows = im3D.rows;
00087 int cols = im3D.cols;
00088
00089
00090 Mat depthInt( rows+1, cols+1, CV_64FC1);
00091 integral( channels[2], depthInt );
00092
00093
00094 std::vector< cv::Mat > featureChans;
00095 featureChans.push_back(depthInt);
00096
00097
00098 Mat mask( rows, cols, CV_32FC1); mask.setTo(0);
00099 cv::threshold( channels[2], mask, 10, 1, THRESH_BINARY);
00100
00101
00102 Mat maskIntegral( rows+1, cols+1, CV_64FC1); maskIntegral.setTo(0);
00103 integral( mask, maskIntegral );
00104
00105
00106 Rect roi = Rect(0,0,p_width,p_height);
00107
00108 int min_no_pixels = p_width*p_height/10;
00109 int half_w = roi.width/2;
00110 int half_h = roi.height/2;
00111
00112
00113 for(roi.y=bbox.y; roi.y<bbox.y+bbox.height-p_height; roi.y+=stride) {
00114
00115 float* rowX = channels[0].ptr<float>(roi.y + half_h);
00116 float* rowY = channels[1].ptr<float>(roi.y + half_h);
00117 float* rowZ = channels[2].ptr<float>(roi.y + half_h);
00118
00119 double* maskIntY1 = maskIntegral.ptr<double>(roi.y);
00120 double* maskIntY2 = maskIntegral.ptr<double>(roi.y + roi.height);
00121
00122 for(roi.x=bbox.x; roi.x<bbox.x+bbox.width-p_width; roi.x+=stride) {
00123
00124
00125 if( rowZ[roi.x + half_w] <= 0.f )
00126 continue;
00127
00128
00129 if( (maskIntY1[roi.x] + maskIntY2[roi.x + roi.width] - maskIntY1[roi.x + roi.width] - maskIntY2[roi.x]) <= min_no_pixels )
00130 continue;
00131
00132
00133 std::vector< const LeafNode* > leaves = crForest->regressionIntegral( featureChans, maskIntegral, roi );
00134
00135
00136 for(unsigned int t=0;t<leaves.size();++t){
00137
00138
00139 if ( leaves[t]->pfg < prob_th || leaves[t]->trace > max_variance )
00140 continue;
00141
00142 Vote v;
00143
00144
00145 v.vote[0] = leaves[t]->mean.at<float>(0) + rowX[roi.x + half_w];
00146 v.vote[1] = leaves[t]->mean.at<float>(1) + rowY[roi.x + half_w];
00147 v.vote[2] = leaves[t]->mean.at<float>(2) + rowZ[roi.x + half_w];
00148
00149
00150 v.vote[3] = leaves[t]->mean.at<float>(3);
00151 v.vote[4] = leaves[t]->mean.at<float>(4);
00152 v.vote[5] = leaves[t]->mean.at<float>(5);
00153
00154 v.trace = &(leaves[t]->trace);
00155 v.conf = &(leaves[t]->pfg);
00156
00157 votes.push_back(v);
00158 }
00159
00160 }
00161
00162 }
00163
00164 if(verbose)
00165 cout << endl << "votes : " << votes.size() << endl;
00166
00167
00168 Vec<float,POSE_SIZE> temp_mean;
00169 vector< vector< Vote* > > temp_clusters;
00170 vector< Vec<float,POSE_SIZE> > cluster_means;
00171
00172
00173 float large_radius = AVG_FACE_DIAMETER2/(larger_radius_ratio*larger_radius_ratio);
00174
00175
00176 for(unsigned int l=0;l<votes.size();++l){
00177
00178 bool found = false;
00179 float best_dist = FLT_MAX;
00180 unsigned int best_cluster = 0;
00181
00182
00183 for(unsigned int c=0; ( c<cluster_means.size() && found==false ); ++c){
00184
00185 float norm = 0;
00186 for(int n=0;n<3;++n)
00187 norm += (votes[l].vote[n]-cluster_means[c][n])*(votes[l].vote[n]-cluster_means[c][n]);
00188
00189
00190 if( norm < large_radius ){
00191
00192 best_cluster = c;
00193 found = true;
00194
00195
00196 temp_clusters[best_cluster].push_back( &(votes[l]) );
00197
00198
00199 ((cluster_means[best_cluster])) = 0;
00200 if ( temp_clusters[best_cluster].size() > 0 ){
00201
00202 for(unsigned int i=0;i < temp_clusters[best_cluster].size(); ++i)
00203 ((cluster_means[best_cluster])) = ((cluster_means[best_cluster])) + temp_clusters[best_cluster][i]->vote;
00204
00205 float div = float(MAX(1,temp_clusters[best_cluster].size()));
00206 for(int n=0;n<POSE_SIZE;++n)
00207 cluster_means[best_cluster][n] /= div;
00208 }
00209
00210 }
00211
00212 }
00213
00214
00215 if( !found && temp_clusters.size() < max_clusters ){
00216
00217 vector< Vote* > new_cluster;
00218 new_cluster.push_back( &(votes[l]) );
00219 temp_clusters.push_back( new_cluster );
00220
00221 Vec<float,POSE_SIZE> vote( votes[l].vote );
00222 cluster_means.push_back( vote );
00223
00224 }
00225
00226 }
00227
00228 if(verbose){
00229 cout << cluster_means.size() << " CLUSTERS ";
00230 for(unsigned int c = 0 ; c<cluster_means.size(); ++c)
00231 cout << temp_clusters[c].size() << " ";
00232 cout << endl;
00233 }
00234
00235 std::vector< std::vector< Vote* > > new_clusters;
00236 vector< Vec<float,POSE_SIZE> > new_means;
00237
00238 int count = 0;
00239 float ms_radius2 = AVG_FACE_DIAMETER*AVG_FACE_DIAMETER/(smaller_radius_ratio*smaller_radius_ratio);
00240
00241
00242
00243 int th = cvRound((double)threshold*crForest->getSize()/(double)(stride*stride));
00244
00245
00246 for(unsigned int c=0;c<cluster_means.size();++c){
00247
00248 if(verbose){
00249 cout << endl << "MS cluster " << c << " : ";
00250 for(int n=0;n<3;++n)
00251 cout << cluster_means[c][n] << " ";
00252 cout << endl;
00253 }
00254
00255 if ( temp_clusters[c].size() <= th ){
00256 if(verbose)
00257 cout << "skipping cluster " << endl;
00258 continue;
00259 }
00260
00261
00262 vector< Vote* > new_cluster;
00263
00264 for(unsigned int it=0; it<max_ms_iterations; ++it){
00265
00266 count = 0;
00267 temp_mean = 0;
00268 new_cluster.clear();
00269
00270
00271 for(unsigned int idx=0; idx < temp_clusters[c].size() ;++idx){
00272
00273 float norm = 0;
00274 for(int n=0;n<3;++n)
00275 norm += (temp_clusters[c][idx]->vote[n]-cluster_means[c][n])*(temp_clusters[c][idx]->vote[n]-cluster_means[c][n]);
00276
00277 if( norm < ms_radius2 ){
00278
00279 temp_mean = temp_mean + temp_clusters[c][idx]->vote;
00280 new_cluster.push_back( temp_clusters[c][idx] );
00281 count++;
00282
00283 }
00284
00285 }
00286
00287 for(int n=0;n<POSE_SIZE;++n)
00288 temp_mean[n] /= (float)MAX(1,count);
00289
00290 float distance_to_previous_mean2 = 0;
00291 for(int n=0;n<3;++n){
00292 distance_to_previous_mean2 += (temp_mean[n]-cluster_means[c][n])*(temp_mean[n]-cluster_means[c][n]);
00293 }
00294
00295
00296
00297
00298 cluster_means[c] = temp_mean;
00299
00300 if( distance_to_previous_mean2 < 1 )
00301 break;
00302
00303 }
00304
00305 new_clusters.push_back( new_cluster );
00306 new_means.push_back( cluster_means[c] );
00307
00308 }
00309
00310 for(unsigned int c=0; c < new_clusters.size() ;++c){
00311
00312 if( new_clusters[c].size() < th )
00313 continue;
00314
00315 vector< Vote > cluster;
00316 cluster_means[c] = 0;
00317
00318
00319 for(unsigned int k=0; k < new_clusters[c].size(); k++ ){
00320
00321 cluster_means[c] = cluster_means[c] + new_clusters[c][k]->vote;
00322 cluster.push_back( *(new_clusters[c][k]) );
00323
00324 }
00325
00326 float div = (float)MAX(1,new_clusters[c].size());
00327 for(int n=0;n<POSE_SIZE;++n)
00328 cluster_means[c][n] /= div;
00329
00330 means.push_back( cluster_means[c] );
00331 clusters.push_back( cluster );
00332
00333 }
00334
00335 }