opencv/modules/contrib/src/selfsimilarity.cpp

260 lines
9.6 KiB
C++

// This is based on Rainer Lienhart contribution. Below is the original copyright:
//
/*M///////////////////////////////////////////////////////////////////////////////////////
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// For Open Source MultiMedia Computing (MMC) Library
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// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
// Author: Rainer Lienhart
// email: Rainer.Lienhart@informatik.uni-augsburg.de
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
// Please cite the following two papers:
// 1. Shechtman, E., Irani, M.:
// Matching local self-similarities across images and videos.
// CVPR, (2007)
// 2. Eva Horster, Thomas Greif, Rainer Lienhart, Malcolm Slaney.
// Comparing Local Feature Descriptors in pLSA-Based Image Models.
// 30th Annual Symposium of the German Association for
// Pattern Recognition (DAGM) 2008, Munich, Germany, June 2008.
#include "precomp.hpp"
namespace cv
{
SelfSimDescriptor::SelfSimDescriptor()
{
smallSize = DEFAULT_SMALL_SIZE;
largeSize = DEFAULT_LARGE_SIZE;
numberOfAngles = DEFAULT_NUM_ANGLES;
startDistanceBucket = DEFAULT_START_DISTANCE_BUCKET;
numberOfDistanceBuckets = DEFAULT_NUM_DISTANCE_BUCKETS;
}
SelfSimDescriptor::SelfSimDescriptor(int _ssize, int _lsize,
int _startDistanceBucket,
int _numberOfDistanceBuckets, int _numberOfAngles)
{
smallSize = _ssize;
largeSize = _lsize;
startDistanceBucket = _startDistanceBucket;
numberOfDistanceBuckets = _numberOfDistanceBuckets;
numberOfAngles = _numberOfAngles;
}
SelfSimDescriptor::SelfSimDescriptor(const SelfSimDescriptor& ss)
{
smallSize = ss.smallSize;
largeSize = ss.largeSize;
startDistanceBucket = ss.startDistanceBucket;
numberOfDistanceBuckets = ss.numberOfDistanceBuckets;
numberOfAngles = ss.numberOfAngles;
}
SelfSimDescriptor::~SelfSimDescriptor()
{
}
SelfSimDescriptor& SelfSimDescriptor::operator = (const SelfSimDescriptor& ss)
{
if( this != &ss )
{
smallSize = ss.smallSize;
largeSize = ss.largeSize;
startDistanceBucket = ss.startDistanceBucket;
numberOfDistanceBuckets = ss.numberOfDistanceBuckets;
numberOfAngles = ss.numberOfAngles;
}
return *this;
}
size_t SelfSimDescriptor::getDescriptorSize() const
{
return numberOfAngles*(numberOfDistanceBuckets - startDistanceBucket);
}
Size SelfSimDescriptor::getGridSize( Size imgSize, Size winStride ) const
{
winStride.width = std::max(winStride.width, 1);
winStride.height = std::max(winStride.height, 1);
int border = largeSize/2 + smallSize/2;
return Size(std::max(imgSize.width - border*2 + winStride.width - 1, 0)/winStride.width,
std::max(imgSize.height - border*2 + winStride.height - 1, 0)/winStride.height);
}
// TODO: optimized with SSE2
void SelfSimDescriptor::SSD(const Mat& img, Point pt, Mat& ssd) const
{
int x, y, dx, dy, r0 = largeSize/2, r1 = smallSize/2;
int step = (int)img.step;
for( y = -r0; y <= r0; y++ )
{
float* sptr = ssd.ptr<float>(y+r0) + r0;
for( x = -r0; x <= r0; x++ )
{
int sum = 0;
const uchar* src0 = img.ptr<uchar>(y + pt.y - r1) + x + pt.x;
const uchar* src1 = img.ptr<uchar>(pt.y - r1) + pt.x;
for( dy = -r1; dy <= r1; dy++, src0 += step, src1 += step )
for( dx = -r1; dx <= r1; dx++ )
{
int t = src0[dx] - src1[dx];
sum += t*t;
}
sptr[x] = (float)sum;
}
}
}
void SelfSimDescriptor::compute(const Mat& img, vector<float>& descriptors, Size winStride,
const vector<Point>& locations) const
{
CV_Assert( img.depth() == CV_8U );
winStride.width = std::max(winStride.width, 1);
winStride.height = std::max(winStride.height, 1);
Size gridSize = getGridSize(img.size(), winStride);
int i, nwindows = locations.empty() ? gridSize.width*gridSize.height : (int)locations.size();
int border = largeSize/2 + smallSize/2;
int fsize = (int)getDescriptorSize();
vector<float> tempFeature(fsize+1);
descriptors.resize(fsize*nwindows + 1);
Mat ssd(largeSize, largeSize, CV_32F), mappingMask;
computeLogPolarMapping(mappingMask);
#if 0 //def _OPENMP
int nthreads = cvGetNumThreads();
#pragma omp parallel for num_threads(nthreads)
#endif
for( i = 0; i < nwindows; i++ )
{
Point pt;
float* feature0 = &descriptors[fsize*i];
float* feature = &tempFeature[0];
int x, y, j;
if( !locations.empty() )
{
pt = locations[i];
if( pt.x < border || pt.x >= img.cols - border ||
pt.y < border || pt.y >= img.rows - border )
{
for( j = 0; j < fsize; j++ )
feature0[j] = 0.f;
continue;
}
}
else
pt = Point((i % gridSize.width)*winStride.width + border,
(i / gridSize.width)*winStride.height + border);
SSD(img, pt, ssd);
// Determine in the local neighborhood the largest difference and use for normalization
float var_noise = 1000.f;
for( y = -1; y <= 1 ; y++ )
for( x = -1 ; x <= 1 ; x++ )
var_noise = std::max(var_noise, ssd.at<float>(largeSize/2+y, largeSize/2+x));
for( j = 0; j <= fsize; j++ )
feature[j] = FLT_MAX;
// Derive feature vector before exp(-x) computation
// Idea: for all x,a >= 0, a=const. we have:
// max [ exp( -x / a) ] = exp ( -min(x) / a )
// Thus, determine min(ssd) and store in feature[...]
for( y = 0; y < ssd.rows; y++ )
{
const schar *mappingMaskPtr = mappingMask.ptr<schar>(y);
const float *ssdPtr = ssd.ptr<float>(y);
for( x = 0 ; x < ssd.cols; x++ )
{
int index = mappingMaskPtr[x];
feature[index] = std::min(feature[index], ssdPtr[x]);
}
}
var_noise = -1.f/var_noise;
for( j = 0; j < fsize; j++ )
feature0[j] = feature[j]*var_noise;
Mat _f(1, fsize, CV_32F, feature0);
cv::exp(_f, _f);
}
}
void SelfSimDescriptor::computeLogPolarMapping(Mat& mappingMask) const
{
mappingMask.create(largeSize, largeSize, CV_8S);
// What we want is
// log_m (radius) = numberOfDistanceBuckets
// <==> log_10 (radius) / log_10 (m) = numberOfDistanceBuckets
// <==> log_10 (radius) / numberOfDistanceBuckets = log_10 (m)
// <==> m = 10 ^ log_10(m) = 10 ^ [log_10 (radius) / numberOfDistanceBuckets]
//
int radius = largeSize/2, angleBucketSize = 360 / numberOfAngles;
int fsize = (int)getDescriptorSize();
double inv_log10m = (double)numberOfDistanceBuckets/log10((double)radius);
for (int y=-radius ; y<=radius ; y++)
{
schar* mrow = mappingMask.ptr<schar>(y+radius);
for (int x=-radius ; x<=radius ; x++)
{
int index = fsize;
float dist = (float)std::sqrt((float)x*x + (float)y*y);
int distNo = dist > 0 ? cvRound(log10(dist)*inv_log10m) : 0;
if( startDistanceBucket <= distNo && distNo < numberOfDistanceBuckets )
{
float angle = std::atan2( (float)y, (float)x ) / (float)CV_PI * 180.0f;
if (angle < 0) angle += 360.0f;
int angleInt = (cvRound(angle) + angleBucketSize/2) % 360;
int angleIndex = angleInt / angleBucketSize;
index = (distNo-startDistanceBucket)*numberOfAngles + angleIndex;
}
mrow[x + radius] = saturate_cast<schar>(index);
}
}
}
}