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vqats.cc
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vqats.cc
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/*
* Video Quality Assessment Tool using SSIM (VQATS).
* Written by Kah Keng Tay, kahkeng AT gmail DOT com, 2008.
*
* See header file for complete credits.
*/
#include <string>
#include <fstream>
#include <iostream>
#include <stdio.h>
#include "vqats.hh"
#ifdef SAMPLING_SIZE
#include <stdlib.h>
#include "cvmat.hh" // for modified CvScalar operators
#endif
// Macros from http://en.wikipedia.org/wiki/C_preprocessor to prevent side effects
#define min(a,b) \
({ typeof (a) _a = (a); \
typeof (b) _b = (b); \
_a < _b ? _a : _b; })
#define max(a,b) \
({ typeof (a) _a = (a); \
typeof (b) _b = (b); \
_a > _b ? _a : _b; })
FrameData::FrameData()
: _loaded(false), _index(0), _image(NULL)
{
#ifndef SAMPLING_SIZE
_image_sq = _mu = _mu_sq = _sigma_sq = NULL;
#endif
}
FrameData::~FrameData()
{
if (unload())
{
#ifdef DEBUG
std::cout << "Deleting frame " << _path << std::endl;
#endif
}
}
bool
FrameData::load()
{
if (!_loaded)
{
#ifdef DEBUG
std::cout << "Loading frame " << _path << std::endl;
#endif
_loaded = true;
_image = cvLoadImage(_path.c_str());
if (_image == NULL)
return false;
// precompute values that deal with only a single image
// convert the image to YCrCb color space, keeping the same depth as before (most likely IPL_DEPTH_8U)
_nChannels = _image->nChannels;
_size = cvSize(_image->width, _image->height);
IplImage* temp = cvCreateImage(_size, _image->depth, _nChannels);
cvCvtColor(_image, temp, CV_BGR2YCrCb);
cvReleaseImage(&_image);
// now convert it to IPL_DEPTH_32F to overcome the 0..255 range.
_depth = IPL_DEPTH_32F;
_image = cvCreateImage(_size, _depth, _nChannels);
cvConvert(temp, _image);
cvReleaseImage(&temp);
#ifndef SAMPLING_SIZE
_image_sq = cvCreateImage(_size, _depth, _nChannels);
cvPow(_image, _image_sq, 2);
_mu = cvCreateImage(_size, _depth, _nChannels);
_mu_sq = cvCreateImage(_size, _depth, _nChannels);
_sigma_sq = cvCreateImage(_size, _depth, _nChannels);
cvSmooth(_image, _mu, CV_GAUSSIAN, 11, 11, 1.5);
cvPow(_mu, _mu_sq, 2);
cvSmooth(_image_sq, _sigma_sq, CV_GAUSSIAN, 11, 11, 1.5);
cvAddWeighted(_sigma_sq, 1, _mu_sq, -1, 0, _sigma_sq);
#endif
}
return true;
}
bool
FrameData::unload()
{
if (_loaded)
{
#ifdef DEBUG
std::cout << "Unloading frame " << _path << std::endl;
#endif
_loaded = false;
if (_image != NULL) cvReleaseImage(&_image);
#ifndef SAMPLING_SIZE
if (_image_sq != NULL) cvReleaseImage(&_image_sq);
if (_mu != NULL) cvReleaseImage(&_mu);
if (_mu_sq != NULL) cvReleaseImage(&_mu_sq);
if (_sigma_sq != NULL) cvReleaseImage(&_sigma_sq);
#endif
return true;
}
return false;
}
VQATS::VQATS()
: _num_videos(0)
{
}
VQATS::~VQATS()
{
}
video_t
VQATS::load_video(std::string filename)
{
frame_t index = 0;
// read our ascii file and save image paths
std::fstream fs(filename.c_str(), std::fstream::in);
if (fs.fail())
{
std::cout << "Unable to load video file " << filename << std::endl;
return 0;
}
video_t id = ++_num_videos;
while (!fs.eof())
{
std::string s;
fs >> s;
if (s.length() > 0)
{
FrameData frame_data;
frame_data._path = s;
frame_data._index = index++;
_video_map[id]._frames.push_back(frame_data);
#ifdef DEBUG
std::cout << "Initialized frame " << s << " for sequence " << filename << std::endl;
#endif
}
}
fs.close();
return id;
}
bool
VQATS::load_video_frame(const video_t& video_index, const frame_t& frame_index)
{
VideoData& video = _video_map[video_index];
// we have a LRU cache replacement policy
// check if this frame is already in the cache
bool found = false;
VideoData::CacheList::iterator slot = video._cache.begin();
// if (video_index != 1) for (int i = 0; i < (int)video._cache.size() - 1; i++) slot++; // do MRU for videos other than first one
for (VideoData::CacheList::iterator it = video._cache.begin(); it != video._cache.end(); ++it)
{
if (*it == frame_index)
{
slot = it;
found = true;
break;
}
}
if (video._cache.size() >= CACHE_SIZE || found)
{
if (!found)
video._frames[*slot].unload();
video._cache.erase(slot);
}
video._cache.push_back(frame_index);
#ifdef DEBUG
// debug output for cache list
std::cout << "Cache List: ";
for (VideoData::CacheList::iterator it = video._cache.begin(); it != video._cache.end(); ++it)
std::cout << *it << " ";
std::cout << std::endl;
#endif
if (!found)
return video._frames[frame_index].load();
else
return true; // was already in cache
}
score_t
VQATS::compute_frame_score(const video_t& video1, const video_t& video2, const frame_t& index1, const frame_t& index2)
{
if (!load_video_frame(video1, index1)) return 0.0;
if (!load_video_frame(video2, index2)) return 0.0;
FrameData& frame1 = _video_map[video1]._frames[index1];
FrameData& frame2 = _video_map[video2]._frames[index2];
// assert some properties about the frames we are comparing
assert(frame1._size.width == frame2._size.width);
assert(frame1._size.height == frame2._size.height);
assert(frame1._depth == frame2._depth);
assert(frame1._nChannels == frame2._nChannels);
#ifdef SAMPLING_SIZE
// compute a random seed based on paths of frames. we try to make sure it is commutative.
unsigned int seed1 = 0, seed2 = 0, m = 30011; // just some prime
for (std::string::iterator it = frame1._path.begin(); it != frame1._path.end(); ++it)
seed1 = seed1 * m + *it;
for (std::string::iterator it = frame2._path.begin(); it != frame2._path.end(); ++it)
seed2 = seed2 * m + *it;
srand(seed1 + seed2); // initialize with this random seed
unsigned int sx = SAMPLING_WIN_X, sy = SAMPLING_WIN_Y, // window size
rangex = frame1._size.width - sx + 1, rangey = frame1._size.height - sy + 1; // range of valid x and y
CvMat *image1 = cvCreateMat(sx, sy, CV_32FC3), *image2 = cvCreateMat(sx, sy, CV_32FC3),
*image1_sq = cvCreateMat(sx, sy, CV_32FC3), *image2_sq = cvCreateMat(sx, sy, CV_32FC3),
*image_product = cvCreateMat(sx, sy, CV_32FC3);
CvScalar index_scalar = cvScalar(0.0, 0.0, 0.0, 0.0);
double total_weight = 0.0;
for (unsigned int i = 0; i < SAMPLING_SIZE; i++)
{
unsigned int rx = rand() % rangex, ry = rand() % rangey; // random sample position
image1 = cvGetSubRect(frame1._image, image1, cvRect(rx, ry, sx, sy));
image2 = cvGetSubRect(frame2._image, image2, cvRect(rx, ry, sx, sy));
cvPow(image1, image1_sq, 2);
cvPow(image2, image2_sq, 2);
CvScalar mu1 = cvAvg(image1), mu2 = cvAvg(image2),
mu1_sq = mu1 * mu1, mu2_sq = mu2 * mu2,
sigma1_sq = cvAvg(image1_sq) - mu1_sq, sigma2_sq = cvAvg(image2_sq) - mu2_sq;
cvMul(image1, image2, image_product, 1.0);
CvScalar mu_product = mu1 * mu2;
CvScalar sigma_cross = cvAvg(image_product) - mu_product;
CvScalar numerator = (2.0 * mu_product + C1) * (2.0 * sigma_cross + C2);
CvScalar denominator = (mu1_sq + mu2_sq + C1) * (sigma1_sq + sigma2_sq + C2);
CvScalar ssim = numerator / denominator;
#ifdef SAMPLING_LUMINANCE_WEIGHTING
double w = mu1.val[0] <= 40.1 ? 0.01 : // we want to avoid zero weights
mu1.val[0] >= 50 ? 1 :
(mu1.val[0] - 40) / 10;
index_scalar += ssim * w;
total_weight += w;
#else
index_scalar += ssim;
total_weight += 1;
#endif
}
index_scalar /= total_weight;
// clean up
cvReleaseMat(&image1);
cvReleaseMat(&image2);
cvReleaseMat(&image1_sq);
cvReleaseMat(&image2_sq);
cvReleaseMat(&image_product);
#else
// perform SSIM computation
IplImage *image_product = NULL,
*mu_product = NULL,
*sigma_cross = NULL,
*numerator = NULL,
*denominator = NULL,
*ssim_map = NULL,
*temp1 = NULL,
*temp2 = NULL;
CvSize size = frame1._size;
int depth = frame1._depth;
int nChannels = frame1._nChannels;
image_product = cvCreateImage(size, depth, nChannels);
mu_product = cvCreateImage(size, depth, nChannels);
sigma_cross = cvCreateImage(size, depth, nChannels);
temp1 = cvCreateImage(size, depth, nChannels);
temp2 = cvCreateImage(size, depth, nChannels);
numerator = cvCreateImage(size, depth, nChannels);
denominator = cvCreateImage(size, depth, nChannels);
ssim_map = cvCreateImage(size, depth, nChannels);
cvMul(frame1._image, frame2._image, image_product, 1);
cvMul(frame1._mu, frame2._mu, mu_product, 2); // scale by 2 to save one computation. note: mu_product is twice its actual value.
cvSmooth(image_product, sigma_cross, CV_GAUSSIAN, 11, 11, 1.5);
cvAddWeighted(sigma_cross, 2, mu_product, -1, C2, temp2); // scale by 2, add C2 to save two computations. note: mu_product is twice actual value, due to above.
cvAddS(mu_product, cvScalarAll(C1), temp1); // note: mu_product is twice actual value, due to above.
cvMul(temp1, temp2, numerator, 1);
cvAdd(frame1._mu_sq, frame2._mu_sq, temp1);
cvAddS(temp1, cvScalarAll(C1), temp1);
cvAdd(frame1._sigma_sq, frame2._sigma_sq, temp2);
cvAddS(temp2, cvScalarAll(C2), temp2);
cvMul(temp1, temp2, denominator, 1);
cvDiv(numerator, denominator, ssim_map, 1);
CvScalar index_scalar = cvAvg(ssim_map);
// cleanup
cvReleaseImage(&image_product);
cvReleaseImage(&mu_product);
cvReleaseImage(&sigma_cross);
cvReleaseImage(&numerator);
cvReleaseImage(&denominator);
cvReleaseImage(&ssim_map);
cvReleaseImage(&temp1);
cvReleaseImage(&temp2);
#endif
#ifdef DEBUG
std::cout << "Comparing " << frame1._path << " with " << frame2._path
<< ": (" << index_scalar.val[0]
<< "," << index_scalar.val[1]
<< "," << index_scalar.val[2] << ")" << std::endl;
#endif
return index_scalar.val[0] * W_Y + index_scalar.val[1] * W_Cr + index_scalar.val[2] * W_Cb;
}