void Regression::write(cv::InputArray array)
{
write() << "kind" << array.kind();
write() << "type" << array.type();
if (isVector(array))
{
int total = (int)array.total();
int idx = regRNG.uniform(0, total);
write() << "len" << total;
write() << "idx" << idx;
cv::Mat m = array.getMat(idx);
if (m.total() * m.channels() < 26) //5x5 or smaller
write() << "val" << m;
else
write(m);
}
else
{
if (array.total() * array.channels() < 26) //5x5 or smaller
write() << "val" << array.getMat();
else
write(array.getMat());
}
}
void illuminationChange(cv::InputArray _src,
cv::InputArray _mask,
cv::OutputArray _dst,
float a,
float b)
{
Mat src = _src.getMat();
Mat mask = _mask.getMat();
_dst.create(src.size(), src.type());
Mat blend = _dst.getMat();
float alpha = a;
float beta = b;
Mat gray = Mat::zeros(mask.size(), CV_8UC1);
if(mask.channels() == 3)
cvtColor(mask, gray, COLOR_BGR2GRAY);
else
gray = mask;
Mat cs_mask = Mat::zeros(src.size(), CV_8UC3);
src.copyTo(cs_mask, gray);
Cloning obj;
obj.illum_change(src, cs_mask, gray, blend, alpha, beta);
}
void stereo_disparity_normal(cv::InputArray left_image, cv::InputArray right_image, cv::OutputArray disp_,
int max_dis_level, int scale, float sigma) {
cv::Mat imL = left_image.getMat();
cv::Mat imR = right_image.getMat();
CV_Assert(imL.size() == imR.size());
CV_Assert(imL.type() == CV_8UC3 && imR.type() == CV_8UC3);
cv::Size imageSize = imL.size();
disp_.create(imageSize, CV_8U);
cv::Mat disp = disp_.getMat();
CDisparityHelper dispHelper;
//step 1: cost initialization
cv::Mat costVol = dispHelper.GetMatchingCost(imL, imR, max_dis_level);
//step 2: cost aggregation
CSegmentTree stree;
CColorWeight cWeight(imL);
stree.BuildSegmentTree(imL.size(), sigma, TAU, cWeight);
stree.Filter(costVol, max_dis_level);
//step 3: disparity computation
cv::Mat disparity = dispHelper.GetDisparity_WTA((float*)costVol.data,
imageSize.width, imageSize.height, max_dis_level);
MeanFilter(disparity, disparity, 3);
disparity *= scale;
disparity.copyTo(disp);
}
void colorChange(cv::InputArray _src,
cv::InputArray _mask,
cv::OutputArray _dst,
float r,
float g,
float b)
{
Mat src = _src.getMat();
Mat mask = _mask.getMat();
_dst.create(src.size(), src.type());
Mat blend = _dst.getMat();
float red = r;
float green = g;
float blue = b;
Mat gray = Mat::zeros(mask.size(), CV_8UC1);
if(mask.channels() == 3)
cvtColor(mask, gray, COLOR_BGR2GRAY);
else
gray = mask;
Mat cs_mask = Mat::zeros(src.size(), CV_8UC3);
src.copyTo(cs_mask, gray);
Cloning obj;
obj.local_color_change(src, cs_mask, gray, blend, red, green, blue);
}
void textureFlattening(cv::InputArray _src,
cv::InputArray _mask,
cv::OutputArray _dst,
double low_threshold,
double high_threshold,
int kernel_size)
{
Mat src = _src.getMat();
Mat mask = _mask.getMat();
_dst.create(src.size(), src.type());
Mat blend = _dst.getMat();
Mat gray = Mat::zeros(mask.size(), CV_8UC1);
if(mask.channels() == 3)
cvtColor(mask, gray, COLOR_BGR2GRAY);
else
gray = mask;
Mat cs_mask = Mat::zeros(src.size(), CV_8UC3);
src.copyTo(cs_mask, gray);
Cloning obj;
obj.texture_flatten(src, cs_mask, gray, low_threshold, high_threshold, kernel_size, blend);
}
void globalMatting(cv::InputArray _image, cv::InputArray _trimap, cv::OutputArray _foreground, cv::OutputArray _alpha, cv::OutputArray _conf)
{
cv::Mat image = _image.getMat();
cv::Mat trimap = _trimap.getMat();
if (image.empty())
CV_Error(CV_StsBadArg, "image is empty");
if (image.type() != CV_8UC3)
CV_Error(CV_StsBadArg, "image mush have CV_8UC3 type");
if (trimap.empty())
CV_Error(CV_StsBadArg, "trimap is empty");
if (trimap.type() != CV_8UC1)
CV_Error(CV_StsBadArg, "trimap mush have CV_8UC1 type");
if (image.size() != trimap.size())
CV_Error(CV_StsBadArg, "image and trimap mush have same size");
cv::Mat &foreground = _foreground.getMatRef();
cv::Mat &alpha = _alpha.getMatRef();
cv::Mat tempConf;
globalMattingHelper(image, trimap, foreground, alpha, tempConf);
if(_conf.needed())
tempConf.copyTo(_conf);
}
FilterCall::FilterCall(cv::InputArray in, cv::InputArray out,
impl::CallMetaData data, QString type,
QString description, QString requestedView)
: Call{ data, std::move(type),
std::move(description), std::move(requestedView) },
input_{ in.getMat().clone() }, output_{ out.getMat().clone() }
{
}
void sadTemplate(cv::InputArray tar, cv::InputArray tmp, cv::OutputArray res, int *minx, int *miny){
//引数の入力をMatとして受け取る
cv::Mat tarM = tar.getMat();
cv::Mat tmpM = tmp.getMat();
cv::Mat resM = res.getMat();
//sadが最小値のところがマッチングしたい箇所なので
int minsad = std::numeric_limits<int>::max();
int sad = 0; //各回のsadを格納
int diff; //sadに加算する前の作業変数
int tarx,tary; //目的のxy座標
for(int y=0;y<tarM.rows - tmpM.rows;y++){
for(int x=0;x<tarM.cols - tmpM.cols;x++){
sad = 0; //次の領域の計算の前に初期化
//探索
for(int yt = 0; yt < tmpM.rows; yt++){
for(int xt = 0; xt < tmpM.cols; xt++){
diff = (int)(tarM.at<uchar>(y+yt,x+xt) - tmpM.at<uchar>(yt,xt));
if(diff < 0){ //負なら正に変換
diff = -diff;
}
sad += diff;
////残差逐次検定法
if(sad > minsad){
yt = tmpM.rows;
break;
}
}
}
//探索結果:sadが今までで最小なら
if(sad < minsad){
minsad = sad; //最小値を更新
//目的のxyを格納
tarx = x;
tary = y;
}
}
}
//outputに出力
for(int y=0;y<resM.rows;y++){
for(int x=0;x<resM.cols;x++){
if(x==tarx && y==tary){
resM.at<uchar>(y,x) = (uchar)0;
}else{
resM.at<uchar>(y,x) = (uchar)255;
}
}
}
std::cout << "最小値=" << minsad << std::endl;
std::cout << "最小点=[" << tarx << ", " << tary << "]" << std::endl;
*minx = tarx;
*miny = tary;
}
void stereo::stereoMatching(cv::InputArray _recImage1, cv::InputArray _recIamge2, cv::OutputArray _disparityMap, int minDisparity, int numDisparities, int SADWindowSize, int P1, int P2)
{
Mat img1 = _recImage1.getMat();
Mat img2 = _recIamge2.getMat();
_disparityMap.create(img1.size(), CV_16S);
Mat dis = _disparityMap.getMat();
StereoSGBM matcher(minDisparity, numDisparities, SADWindowSize, P1, P2);
matcher(img1, img2, dis);
dis = dis / 16.0;
}
void testFunction(cv::InputArray ip, cv::InputArray op) {
cv::Mat img = ip.getMat();
cv::Mat obj = op.getMat();
printMatrix(img);
printMatrix(obj);
// std::cerr<<img.checkVector()<<std::endl;
}
void IPPE::PoseSolver::solveGeneric(cv::InputArray _objectPoints, cv::InputArray _normalizedInputPoints,
cv::OutputArray _Ma, cv::OutputArray _Mb)
{
//argument checking:
size_t n = _objectPoints.rows() * _objectPoints.cols(); //number of points
int objType = _objectPoints.type();
int type_input = _normalizedInputPoints.type();
assert((objType == CV_32FC3) | (objType == CV_64FC3));
assert((type_input == CV_32FC2) | (type_input == CV_64FC2));
assert((_objectPoints.rows() == 1) | (_objectPoints.cols() == 1));
assert((_objectPoints.rows() >= 4) | (_objectPoints.cols() >= 4));
assert((_normalizedInputPoints.rows() == 1) | (_normalizedInputPoints.cols() == 1));
assert(static_cast<size_t>(_objectPoints.rows() * _objectPoints.cols()) == n);
cv::Mat normalizedInputPoints;
if (type_input == CV_32FC2) {
_normalizedInputPoints.getMat().convertTo(normalizedInputPoints, CV_64FC2);
}
else {
normalizedInputPoints = _normalizedInputPoints.getMat();
}
cv::Mat objectInputPoints;
if (type_input == CV_32FC3) {
_objectPoints.getMat().convertTo(objectInputPoints, CV_64FC3);
}
else {
objectInputPoints = _objectPoints.getMat();
}
cv::Mat canonicalObjPoints;
cv::Mat MmodelPoints2Canonical;
//transform object points to the canonical position (zero centred and on the plane z=0):
makeCanonicalObjectPoints(objectInputPoints, canonicalObjPoints, MmodelPoints2Canonical);
//compute the homography mapping the model's points to normalizedInputPoints
cv::Mat H;
HomographyHO::homographyHO(canonicalObjPoints, _normalizedInputPoints, H);
//now solve
cv::Mat MaCanon, MbCanon;
solveCanonicalForm(canonicalObjPoints, normalizedInputPoints, H, MaCanon, MbCanon);
//transform computed poses to account for canonical transform:
cv::Mat Ma = MaCanon * MmodelPoints2Canonical;
cv::Mat Mb = MbCanon * MmodelPoints2Canonical;
//output poses:
Ma.copyTo(_Ma);
Mb.copyTo(_Mb);
}
void stereo::stereoRectify(cv::InputArray _K1, cv::InputArray _K2, cv::InputArray _R, cv::InputArray _T,
cv::OutputArray _R1, cv::OutputArray _R2, cv::OutputArray _P1, cv::OutputArray _P2)
{
Mat K1 = _K1.getMat(), K2 = _K2.getMat(), R = _R.getMat(), T = _T.getMat();
_R1.create(3, 3, CV_32F);
_R2.create(3, 3, CV_32F);
Mat R1 = _R1.getMat();
Mat R2 = _R2.getMat();
_P1.create(3, 4, CV_32F);
_P2.create(3, 4, CV_32F);
Mat P1 = _P1.getMat();
Mat P2 = _P2.getMat();
if(K1.type()!=CV_32F)
K1.convertTo(K1,CV_32F);
if(K2.type()!=CV_32F)
K2.convertTo(K2,CV_32F);
if(R.type()!=CV_32F)
R.convertTo(R,CV_32F);
if(T.type()!=CV_32F)
T.convertTo(T,CV_32F);
if(T.rows != 3)
T = T.t();
// R and T is the transformation from the first to the second camera
// Get the transformation from the second to the first camera
Mat R_inv = R.t();
Mat T_inv = -R.t()*T;
Mat e1, e2, e3;
e1 = T_inv.t() / norm(T_inv);
/*Mat z = (Mat_<float>(1, 3) << 0.0,0.0,-1.0);
e2 = e1.cross(z);
e2 = e2 / norm(e2);*/
e2 = (Mat_<float>(1,3) << T_inv.at<float>(1)*-1, T_inv.at<float>(0), 0.0 );
e2 = e2 / (sqrt(e2.at<float>(0)*e2.at<float>(0) + e2.at<float>(1)*e2.at<float>(1)));
e3 = e1.cross(e2);
e3 = e3 / norm(e3);
e1.copyTo(R1.row(0));
e2.copyTo(R1.row(1));
e3.copyTo(R1.row(2));
R2 = R_inv * R1;
P1.setTo(Scalar(0));
R1.copyTo(P1.colRange(0, 3));
P1 = K1 * P1;
P2.setTo(Scalar(0));
R2.copyTo(P2.colRange(0, 3));
P2 = K2 * P2;
}
cv::Mat flutter::estimate_rigid_transform(cv::InputArray src1, cv::InputArray src2,
double ransac_good_ratio, double ransac_threshold)
{
Mat M(2, 3, CV_64F), A = src1.getMat(), B = src2.getMat();
CvMat matA = A, matB = B, matM = M;
int err = estimate_rigid_transform_detail(&matA, &matB, &matM,
ransac_good_ratio, ransac_threshold);
if (err == 1) {
return M;
} else {
return Mat();
}
}
void StereoMatch::StereoMatching(cv::InputArray rec_image1, cv::InputArray rec_image2,
cv::OutputArray disparity_map, int min_disparity, int num_disparities, int SAD_window_size,
int P1, int P2)
{
cv::Mat img1 = rec_image1.getMat();
cv::Mat img2 = rec_image2.getMat();
disparity_map.create(img1.size(), CV_16S);
cv::Mat dis = disparity_map.getMat();
cv::StereoSGBM matcher(min_disparity, num_disparities, SAD_window_size, P1, P2);
matcher(img1, img2, dis);
dis = dis / 16.0;
}
void cv::SCascade::detect(cv::InputArray _image, cv::InputArray _rois, std::vector<Detection>& objects) const
{
// only color images are supperted
cv::Mat image = _image.getMat();
CV_Assert(image.type() == CV_8UC3);
Fields& fld = *fields;
fld.calcLevels(image.size(),(float) minScale, (float)maxScale, scales);
objects.clear();
if (_rois.empty())
return detectNoRoi(image, objects);
int shr = fld.shrinkage;
cv::Mat roi = _rois.getMat();
cv::Mat mask(image.rows / shr, image.cols / shr, CV_8UC1);
mask.setTo(cv::Scalar::all(0));
cv::Rect* r = roi.ptr<cv::Rect>(0);
for (int i = 0; i < (int)roi.cols; ++i)
cv::Mat(mask, cv::Rect(r[i].x / shr, r[i].y / shr, r[i].width / shr , r[i].height / shr)).setTo(cv::Scalar::all(1));
// create integrals
ChannelStorage storage(image, shr);
typedef std::vector<Level>::const_iterator lIt;
for (lIt it = fld.levels.begin(); it != fld.levels.end(); ++it)
{
const Level& level = *it;
// we train only 3 scales.
if (level.origScale > 2.5) break;
for (int dy = 0; dy < level.workRect.height; ++dy)
{
uchar* m = mask.ptr<uchar>(dy);
for (int dx = 0; dx < level.workRect.width; ++dx)
{
if (m[dx])
{
storage.offset = dy * storage.step + dx;
fld.detectAt(dx, dy, level, storage, objects);
}
}
}
}
if (rejCriteria != NO_REJECT) suppress(rejCriteria, objects);
}
void Picture::setAnimation(const AnimationEnum &animationEnum,
const cv::InputArray &startImg, const cv::InputArray &endImg)
{
delete animation;
Mat startImage = startImg.getMat();
Mat endImage = endImg.getMat();
if (!startImg.empty() && startImg.size() != this->size())
cv::resize(startImg, startImage, this->size());
if (!endImg.empty() && endImg.size() != this->size())
cv::resize(endImg, endImage, this->size());
animation = AnimationFactory::createAnimation(animationEnum, startImage, endImage);
}
void CV_HomographyTest::check_transform_quality(cv::InputArray src_points, cv::InputArray dst_points, const cv::Mat& H, const int norm_type)
{
Mat src, dst_original;
cv::transpose(src_points.getMat(), src); cv::transpose(dst_points.getMat(), dst_original);
cv::Mat src_3d(src.rows+1, src.cols, CV_32FC1);
src_3d(Rect(0, 0, src.rows, src.cols)) = src;
src_3d(Rect(src.rows, 0, 1, src.cols)) = Mat(1, src.cols, CV_32FC1, Scalar(1.0f));
cv::Mat dst_found, dst_found_3d;
cv::multiply(H, src_3d, dst_found_3d);
dst_found = dst_found_3d/dst_found_3d.row(dst_found_3d.rows-1);
double reprojection_error = cv::norm(dst_original, dst_found, norm_type);
CV_Assert ( reprojection_error > max_diff );
}
void printSmallMatrixCVChar(char *title, cv::InputArray inArr)
{
printf("%s\n", title);
printf("----------------------------------\n");
for (int rows = 0; rows < inArr.getMat().rows; rows++) {
printf("ROW: %02d ---> ", rows);
for (int cols = 0; cols < IMG_WIDTH; cols++) {
printf(" %04d ", inArr.getMat().at<unsigned char>(rows, cols));
}
printf("\n");
}
printf("\n");
}
void Tools::ReduceRowByMost(cv::InputArray _src, cv::OutputArray _dst, cv::InputArray _mask) {
cv::Mat src = _src.getMat();
_dst.create(1, src.cols, CV_8UC1);
cv::Mat dst = _dst.getMat();
cv::Mat mask = _mask.getMat();
if (src.depth() != CV_8U || mask.depth() != CV_8U) {
throw "TYPE DON'T SUPPORT";
}
int i, j, addr;
cv::Size size = src.size();
uchar *srcd = src.data;
uchar *dstd = dst.data;
uchar *maskd = mask.data;
std::map<uchar, int> m;
std::map<uchar, int>::iterator p;
uchar mostVal;
uchar rVal;
int r;
for (i = 0;i < size.width;++i) {
m.clear();
mostVal = 0;
for (j = 0;j < size.height;++j) {
addr = j*size.width + i;
if (!maskd[addr])
continue;
for (r = -2;r <= 2;++r) {
rVal = (uchar)(((int)srcd[addr] + r) % 180);
if (m.find(rVal) != m.end()) {
m[rVal]++;
}
else {
m[rVal] = 1;
}
}
}
if (m.size() == 0) {
dstd[i] = 0;
continue;
}
mostVal = m.begin()->first;
for (p = m.begin();p != m.end();++p) {
if (p->second > m[mostVal]) {
mostVal = p->first;
}
}
dstd[i] = mostVal;
}
}
void BackgroundSubtractorMedian::operator()(cv::InputArray _image, cv::OutputArray _fgmask, double learningRate)
{
framecount++;
cv::Mat image = _image.getMat();
if (image.channels() > 1) {
cvtColor(image,image,CV_BGR2GRAY);
}
if (image.cols == 0 || image.rows == 0) {
return;
}
_fgmask.create(image.size(), CV_8U);
cv::Mat fgmask = _fgmask.getMat();
if (!init)
{
init = true;
bgmodel = cv::Mat(image.size(), CV_8U);
}
//printf("(%d,%d)(%d) ",image.cols,image.rows,image.type());
//printf("(%d,%d)(%d)\n",bgmodel.cols,bgmodel.rows,bgmodel.type());
cv::Mat cmpArr = cv::Mat(image.size(),CV_8U);
cv::compare(image, bgmodel, cmpArr, CV_CMP_GT);
cv::bitwise_and(cmpArr, 1, cmpArr);
cv::add(bgmodel, cmpArr, bgmodel);
cmpArr = cv::Mat(image.size(),CV_8U);
cv::compare(image, bgmodel, cmpArr, CV_CMP_LT);
cv::bitwise_and(cmpArr, 1, cmpArr);
cv::subtract(bgmodel, cmpArr, bgmodel);
cv::absdiff(image, bgmodel,fgmask);
cv::threshold(fgmask,fgmask,fg_threshold,255,CV_THRESH_TOZERO);
cv::medianBlur(fgmask,fgmask,median_filter_level);
}
// Computes an Lidfaces model with images in src and corresponding labels
// in labels.
void Lidfaces::train(cv::InputArrayOfArrays src, cv::InputArray labels)
{
std::vector<std::vector<cv::KeyPoint> > allKeyPoints;
cv::Mat descriptors;
// Get SIFT keypoints and LID descriptors
detectKeypointsAndDescriptors(src, allKeyPoints, descriptors);
// kmeans function requires points to be CV_32F
descriptors.convertTo(descriptors, CV_32FC1);
// Do k-means clustering
const int CLUSTER_COUNT = params::lidFace::clustersAsPercentageOfKeypoints*descriptors.rows;
cv::Mat histogramLabels;
// This function populates histogram bin labels
// The nth element of histogramLabels is an integer which represents the cluster that the
// nth element of allKeyPoints is a member of.
kmeans(
descriptors, // The points we are clustering are the descriptors
CLUSTER_COUNT, // The number of clusters (K)
histogramLabels, // The label of the corresponding keypoint
params::kmeans::termCriteria,
params::kmeans::attempts,
params::kmeans::flags,
mCenters);
// Convert to single channel 32 bit float as the matrix needs to be in a form supported
// by calcHist
histogramLabels.convertTo(histogramLabels, CV_32FC1);
// We end up with a histogram for each image
const size_t NUM_IMAGES = getSize(src);
std::vector<cv::Mat> hists(NUM_IMAGES);
// mCodebook.resize(NUM_IMAGES);
// The histogramLabels vector contains ALL the points from EVERY image. We need to split
// it up into groups of points for each image.
// Because there are the same number of points in each image, and the points were put
// into the labels vector in order, we can simply divide the labels vector evenly to get
// the individual image's points.
std::vector<cv::Mat> separatedLabels;
for (unsigned int i = 0, startRow = 0; i < NUM_IMAGES; ++i)
{
separatedLabels.push_back(
histogramLabels.rowRange(
startRow,
startRow + allKeyPoints[i].size()));
startRow += allKeyPoints[i].size();
}
// Populate the hists vector
generateHistograms(hists, separatedLabels, CLUSTER_COUNT);
// Make the magnitude of each histogram equal to 1
normalizeHistograms(hists);
mCodebook = hists;
mLabels = labels.getMat();
}
void showWindow(const string &winName, cv::InputArray mat)
{
Mat temp(mat.size(), mat.type());
mat.getMat().copyTo(temp);
namedWindow(winName, WINDOW_NORMAL); // Create a window for display.
imshow(winName, temp); // Show our image inside it.
}
int boostColor(cv::InputArray src, cv::OutputArray dst, float intensity)
{
const int MAX_INTENSITY = 255;
Mat srcImg = src.getMat();
CV_Assert(srcImg.channels() == 3);
CV_Assert(intensity >= 0.0f && intensity <= 1.0f);
if (srcImg.type() != CV_8UC3)
{
srcImg.convertTo(srcImg, CV_8UC3);
}
Mat srcHls;
cvtColor(srcImg, srcHls, CV_BGR2HLS);
int intensityInt = intensity * MAX_INTENSITY;
srcHls += Scalar(0, 0, intensityInt);
cvtColor(srcHls, dst, CV_HLS2BGR);
dst.getMat().convertTo(dst, srcImg.type());
return 0;
}
void EdgeDetector_<ParallelUtils::eGLSL>::apply_async_glimpl(cv::InputArray _oNextImage, bool bRebindAll, double dThreshold) {
m_dCurrThreshold = dThreshold;
cv::Mat oNextInputImg = _oNextImage.getMat();
CV_Assert(oNextInputImg.size()==m_oFrameSize);
CV_Assert(oNextInputImg.isContinuous());
GLImageProcAlgo::apply_async(oNextInputImg,bRebindAll);
}
void IEdgeDetector_GLSL::apply_gl(cv::InputArray _oNextImage, bool bRebindAll, double dThreshold) {
lvAssert_(GLImageProcAlgo::m_bGLInitialized,"algo must be initialized first");
m_dCurrThreshold = dThreshold;
cv::Mat oNextInputImg = _oNextImage.getMat();
lvAssert_(oNextInputImg.size()==GLImageProcAlgo::m_oFrameSize,"input image size must match initialization size");
lvAssert_(oNextInputImg.isContinuous(),"input image must be continuous");
GLImageProcAlgo::apply_gl(oNextInputImg,bRebindAll);
}
void stereo::stereoMatching(cv::InputArray _recImage1, cv::InputArray _recIamge2, cv::OutputArray _disparityMap, int minDisparity, int numDisparities, int SADWindowSize, int P1, int P2)
{
Mat img1 = _recImage1.getMat();
Mat img2 = _recIamge2.getMat();
_disparityMap.create(img1.size(), CV_16S);
Mat dis = _disparityMap.getMat();
// create(int minDisparity, int numDisparities, int blockSize,)
Ptr<StereoSGBM> matcher = StereoSGBM::create(minDisparity, numDisparities, SADWindowSize);
matcher->setP1(P1);
matcher->setP2(P2);
matcher->compute(img1, img2, dis);
//StereoSGBM matcher(minDisparity, numDisparities, SADWindowSize, P1, P2);
//matcher(img1, img2, dis);
dis = dis / 16.0;
}
inline void normAssert(cv::InputArray ref, cv::InputArray test, const char *comment = "",
double l1 = 0.00001, double lInf = 0.0001)
{
double normL1 = cvtest::norm(ref, test, cv::NORM_L1) / ref.getMat().total();
EXPECT_LE(normL1, l1) << comment;
double normInf = cvtest::norm(ref, test, cv::NORM_INF);
EXPECT_LE(normInf, lInf) << comment;
}
void _SLICSegment2Vector3D_(cv::InputArray segment, cv::InputArray signal, T invalidValue, std::vector<std::vector<cv::Point3_<S>>>& segmentPoint)
{
Mat sig = signal.getMat();
Mat seg = segment.getMat();
for (int j = 0; j < seg.rows; ++j)
{
int* s = seg.ptr<int>(j);
T* value = sig.ptr<T>(j);
for (int i = 0; i < seg.cols; ++i)
{
if (value[i] != invalidValue)
{
segmentPoint[s[i]].push_back(Point3_<S>((S)i, (S)j, (S)value[i]));
}
}
}
}
void warmify(cv::InputArray src, cv::OutputArray dst, uchar delta)
{
CV_Assert(src.type() == CV_8UC3);
Mat imgSrc = src.getMat();
CV_Assert(imgSrc.data);
dst.create(src.size(), CV_8UC3);
Mat imgDst = dst.getMat();
imgDst = imgSrc + Scalar(0, delta, delta);
}
void IBackgroundSubtractor_GLSL::apply_gl(cv::InputArray _oNextImage, bool bRebindAll, double dLearningRate) {
glAssert(m_bInitialized && m_bModelInitialized);
m_dCurrLearningRate = dLearningRate;
cv::Mat oNextInputImg = _oNextImage.getMat();
CV_Assert(oNextInputImg.type()==m_nImgType && oNextInputImg.size()==m_oImgSize);
CV_Assert(oNextInputImg.isContinuous());
++m_nFrameIdx;
GLImageProcAlgo::apply_gl(oNextInputImg,bRebindAll);
oNextInputImg.copyTo(m_oLastColorFrame);
}