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/*M///////////////////////////////////////////////////////////////////////////////////////
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/*
OpenCV wrapper of reference implementation of
[1] Fast Explicit Diffusion for Accelerated Features in Nonlinear Scale Spaces.
Pablo F. Alcantarilla, J. Nuevo and Adrien Bartoli.
In British Machine Vision Conference (BMVC), Bristol, UK, September 2013
http://www.robesafe.com/personal/pablo.alcantarilla/papers/Alcantarilla13bmvc.pdf
@author Eugene Khvedchenya <ekhvedchenya@gmail.com>
*/
#include "precomp.hpp"
#include "kaze/AKAZEFeatures.h"
#include <iostream>
namespace cv
{
using namespace std;
class AKAZE_Impl : public AKAZE
{
public:
AKAZE_Impl(DescriptorType _descriptor_type, int _descriptor_size, int _descriptor_channels,
float _threshold, int _octaves, int _sublevels, KAZE::DiffusivityType _diffusivity, int _max_points)
: descriptor(_descriptor_type)
, descriptor_channels(_descriptor_channels)
, descriptor_size(_descriptor_size)
, threshold(_threshold)
, octaves(_octaves)
, sublevels(_sublevels)
, diffusivity(_diffusivity)
, max_points(_max_points)
{
}
virtual ~AKAZE_Impl() CV_OVERRIDE
{
}
void setDescriptorType(DescriptorType dtype) CV_OVERRIDE{ descriptor = dtype; }
DescriptorType getDescriptorType() const CV_OVERRIDE{ return descriptor; }
void setDescriptorSize(int dsize) CV_OVERRIDE { descriptor_size = dsize; }
int getDescriptorSize() const CV_OVERRIDE { return descriptor_size; }
void setDescriptorChannels(int dch) CV_OVERRIDE { descriptor_channels = dch; }
int getDescriptorChannels() const CV_OVERRIDE { return descriptor_channels; }
void setThreshold(double threshold_) CV_OVERRIDE { threshold = (float)threshold_; }
double getThreshold() const CV_OVERRIDE { return threshold; }
void setNOctaves(int octaves_) CV_OVERRIDE { octaves = octaves_; }
int getNOctaves() const CV_OVERRIDE { return octaves; }
void setNOctaveLayers(int octaveLayers_) CV_OVERRIDE { sublevels = octaveLayers_; }
int getNOctaveLayers() const CV_OVERRIDE { return sublevels; }
void setDiffusivity(KAZE::DiffusivityType diff_) CV_OVERRIDE{ diffusivity = diff_; }
KAZE::DiffusivityType getDiffusivity() const CV_OVERRIDE{ return diffusivity; }
void setMaxPoints(int max_points_) CV_OVERRIDE { max_points = max_points_; }
int getMaxPoints() const CV_OVERRIDE { return max_points; }
// returns the descriptor size in bytes
int descriptorSize() const CV_OVERRIDE
{
switch (descriptor)
{
case DESCRIPTOR_KAZE:
case DESCRIPTOR_KAZE_UPRIGHT:
return 64;
case DESCRIPTOR_MLDB:
case DESCRIPTOR_MLDB_UPRIGHT:
// We use the full length binary descriptor -> 486 bits
if (descriptor_size == 0)
{
int t = (6 + 36 + 120) * descriptor_channels;
return divUp(t, 8);
}
else
{
// We use the random bit selection length binary descriptor
return divUp(descriptor_size, 8);
}
default:
return -1;
}
}
// returns the descriptor type
int descriptorType() const CV_OVERRIDE
{
switch (descriptor)
{
case DESCRIPTOR_KAZE:
case DESCRIPTOR_KAZE_UPRIGHT:
return CV_32F;
case DESCRIPTOR_MLDB:
case DESCRIPTOR_MLDB_UPRIGHT:
return CV_8U;
default:
return -1;
}
}
// returns the default norm type
int defaultNorm() const CV_OVERRIDE
{
switch (descriptor)
{
case DESCRIPTOR_KAZE:
case DESCRIPTOR_KAZE_UPRIGHT:
return NORM_L2;
case DESCRIPTOR_MLDB:
case DESCRIPTOR_MLDB_UPRIGHT:
return NORM_HAMMING;
default:
return -1;
}
}
void detectAndCompute(InputArray image, InputArray mask,
std::vector<KeyPoint>& keypoints,
OutputArray descriptors,
bool useProvidedKeypoints) CV_OVERRIDE
{
CV_INSTRUMENT_REGION();
CV_Assert( ! image.empty() );
AKAZEOptions options;
options.descriptor = descriptor;
options.descriptor_channels = descriptor_channels;
options.descriptor_size = descriptor_size;
options.img_width = image.cols();
options.img_height = image.rows();
options.dthreshold = threshold;
options.omax = octaves;
options.nsublevels = sublevels;
options.diffusivity = diffusivity;
AKAZEFeatures impl(options);
impl.Create_Nonlinear_Scale_Space(image);
if (!useProvidedKeypoints)
{
impl.Feature_Detection(keypoints);
}
if (!mask.empty())
{
KeyPointsFilter::runByPixelsMask(keypoints, mask.getMat());
}
if (max_points > 0 && (int)keypoints.size() > max_points) {
std::partial_sort(keypoints.begin(), keypoints.begin() + max_points, keypoints.end(),
[](const cv::KeyPoint& k1, const cv::KeyPoint& k2) {return k1.response > k2.response;});
keypoints.erase(keypoints.begin() + max_points, keypoints.end());
}
if(descriptors.needed())
{
impl.Compute_Descriptors(keypoints, descriptors);
CV_Assert((descriptors.empty() || descriptors.cols() == descriptorSize()));
CV_Assert((descriptors.empty() || (descriptors.type() == descriptorType())));
}
}
void write(FileStorage& fs) const CV_OVERRIDE
{
writeFormat(fs);
fs << "name" << getDefaultName();
fs << "descriptor" << descriptor;
fs << "descriptor_channels" << descriptor_channels;
fs << "descriptor_size" << descriptor_size;
fs << "threshold" << threshold;
fs << "octaves" << octaves;
fs << "sublevels" << sublevels;
fs << "diffusivity" << diffusivity;
fs << "max_points" << max_points;
}
void read(const FileNode& fn) CV_OVERRIDE
{
// if node is empty, keep previous value
if (!fn["descriptor"].empty())
descriptor = static_cast<DescriptorType>((int)fn["descriptor"]);
if (!fn["descriptor_channels"].empty())
descriptor_channels = (int)fn["descriptor_channels"];
if (!fn["descriptor_size"].empty())
descriptor_size = (int)fn["descriptor_size"];
if (!fn["threshold"].empty())
threshold = (float)fn["threshold"];
if (!fn["octaves"].empty())
octaves = (int)fn["octaves"];
if (!fn["sublevels"].empty())
sublevels = (int)fn["sublevels"];
if (!fn["diffusivity"].empty())
diffusivity = static_cast<KAZE::DiffusivityType>((int)fn["diffusivity"]);
if (!fn["max_points"].empty())
max_points = (int)fn["max_points"];
}
DescriptorType descriptor;
int descriptor_channels;
int descriptor_size;
float threshold;
int octaves;
int sublevels;
KAZE::DiffusivityType diffusivity;
int max_points;
};
Ptr<AKAZE> AKAZE::create(DescriptorType descriptor_type,
int descriptor_size, int descriptor_channels,
float threshold, int octaves,
int sublevels, KAZE::DiffusivityType diffusivity, int max_points)
{
return makePtr<AKAZE_Impl>(descriptor_type, descriptor_size, descriptor_channels,
threshold, octaves, sublevels, diffusivity, max_points);
}
String AKAZE::getDefaultName() const
{
return (Feature2D::getDefaultName() + ".AKAZE");
}
}
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