#include "perf_precomp.hpp" using namespace std; using namespace cv; using namespace perf; using namespace testing; using std::tr1::make_tuple; using std::tr1::get; enum{HALF_SIZE=0, UPSIDE_DOWN, REFLECTION_X, REFLECTION_BOTH}; CV_ENUM(BorderMode, BORDER_CONSTANT, BORDER_REPLICATE) CV_ENUM(InterType, INTER_NEAREST, INTER_LINEAR) CV_ENUM(RemapMode, HALF_SIZE, UPSIDE_DOWN, REFLECTION_X, REFLECTION_BOTH) typedef TestBaseWithParam< tr1::tuple > TestWarpAffine; typedef TestBaseWithParam< tr1::tuple > TestWarpPerspective; typedef TestBaseWithParam< tr1::tuple > TestWarpPerspectiveNear_t; typedef TestBaseWithParam< tr1::tuple > TestRemap; void update_map(const Mat& src, Mat& map_x, Mat& map_y, const int remapMode ); PERF_TEST_P( TestWarpAffine, WarpAffine, Combine( Values( szVGA, sz720p, sz1080p ), ValuesIn( InterType::all() ), ValuesIn( BorderMode::all() ) ) ) { Size sz; int borderMode, interType; sz = get<0>(GetParam()); borderMode = get<1>(GetParam()); interType = get<2>(GetParam()); Mat src, img = imread(getDataPath("cv/shared/fruits.png")); cvtColor(img, src, COLOR_BGR2RGBA, 4); Mat warpMat = getRotationMatrix2D(Point2f(src.cols/2.f, src.rows/2.f), 30., 2.2); Mat dst(sz, CV_8UC4); declare.in(src).out(dst); TEST_CYCLE() warpAffine( src, dst, warpMat, sz, interType, borderMode, Scalar::all(150) ); SANITY_CHECK(dst); } PERF_TEST_P( TestWarpPerspective, WarpPerspective, Combine( Values( szVGA, sz720p, sz1080p ), ValuesIn( InterType::all() ), ValuesIn( BorderMode::all() ) ) ) { Size sz; int borderMode, interType; sz = get<0>(GetParam()); borderMode = get<1>(GetParam()); interType = get<2>(GetParam()); Mat src, img = imread(getDataPath("cv/shared/fruits.png")); cvtColor(img, src, COLOR_BGR2RGBA, 4); Mat rotMat = getRotationMatrix2D(Point2f(src.cols/2.f, src.rows/2.f), 30., 2.2); Mat warpMat(3, 3, CV_64FC1); for(int r=0; r<2; r++) for(int c=0; c<3; c++) warpMat.at(r, c) = rotMat.at(r, c); warpMat.at(2, 0) = .3/sz.width; warpMat.at(2, 1) = .3/sz.height; warpMat.at(2, 2) = 1; Mat dst(sz, CV_8UC4); declare.in(src).out(dst); TEST_CYCLE() warpPerspective( src, dst, warpMat, sz, interType, borderMode, Scalar::all(150) ); SANITY_CHECK(dst); } PERF_TEST_P( TestWarpPerspectiveNear_t, WarpPerspectiveNear, Combine( Values( Size(176,144), Size(320,240), Size(352,288), Size(480,480), Size(640,480), Size(704,576), Size(720,408), Size(720,480), Size(720,576), Size(768,432), Size(800,448), Size(960,720), Size(1024,768), Size(1280,720), Size(1280,960), Size(1360,720), Size(1600,1200), Size(1920,1080), Size(2048,1536), Size(2592,1920), Size(2592,1944), Size(3264,2448), Size(4096,3072), Size(4208,3120) ), ValuesIn( InterType::all() ), ValuesIn( BorderMode::all() ), Values( CV_8UC1, CV_8UC4 ) ) ) { Size size; int borderMode, interType, type; size = get<0>(GetParam()); borderMode = get<1>(GetParam()); interType = get<2>(GetParam()); type = get<3>(GetParam()); Mat src, img = imread(getDataPath("cv/shared/5MP.png")); if( type == CV_8UC1 ) { cvtColor(img, src, COLOR_BGR2GRAY, 1); } else if( type == CV_8UC4 ) { cvtColor(img, src, COLOR_BGR2BGRA, 4); } else { FAIL(); } resize(src, src, size); int shift = src.cols*0.04; Mat srcVertices = (Mat_(1, 4) << Vec2f(0, 0), Vec2f(size.width-1, 0), Vec2f(size.width-1, size.height-1), Vec2f(0, size.height-1)); Mat dstVertices = (Mat_(1, 4) << Vec2f(0, shift), Vec2f(size.width-shift/2, 0), Vec2f(size.width-shift, size.height-shift), Vec2f(shift/2, size.height-1)); Mat warpMat = getPerspectiveTransform(srcVertices, dstVertices); Mat dst(size, type); declare.in(src).out(dst); TEST_CYCLE() { warpPerspective( src, dst, warpMat, size, interType, borderMode, Scalar::all(150) ); } SANITY_CHECK(dst); } PERF_TEST_P( TestRemap, remap, Combine( Values( TYPICAL_MAT_TYPES ), Values( szVGA, sz720p, sz1080p ), ValuesIn( InterType::all() ), ValuesIn( BorderMode::all() ), ValuesIn( RemapMode::all() ) ) ) { int type = get<0>(GetParam()); Size size = get<1>(GetParam()); int interpolationType = get<2>(GetParam()); int borderMode = get<3>(GetParam()); int remapMode = get<4>(GetParam()); unsigned int height = size.height; unsigned int width = size.width; Mat source(height, width, type); Mat destination; Mat map_x(height, width, CV_32F); Mat map_y(height, width, CV_32F); declare.in(source, WARMUP_RNG); update_map(source, map_x, map_y, remapMode); TEST_CYCLE() { remap(source, destination, map_x, map_y, interpolationType, borderMode); } SANITY_CHECK(destination, 1); } void update_map(const Mat& src, Mat& map_x, Mat& map_y, const int remapMode ) { for( int j = 0; j < src.rows; j++ ) { for( int i = 0; i < src.cols; i++ ) { switch( remapMode ) { case HALF_SIZE: if( i > src.cols*0.25 && i < src.cols*0.75 && j > src.rows*0.25 && j < src.rows*0.75 ) { map_x.at(j,i) = 2*( i - src.cols*0.25f ) + 0.5f ; map_y.at(j,i) = 2*( j - src.rows*0.25f ) + 0.5f ; } else { map_x.at(j,i) = 0 ; map_y.at(j,i) = 0 ; } break; case UPSIDE_DOWN: map_x.at(j,i) = static_cast(i) ; map_y.at(j,i) = static_cast(src.rows - j) ; break; case REFLECTION_X: map_x.at(j,i) = static_cast(src.cols - i) ; map_y.at(j,i) = static_cast(j) ; break; case REFLECTION_BOTH: map_x.at(j,i) = static_cast(src.cols - i) ; map_y.at(j,i) = static_cast(src.rows - j) ; break; } // end of switch } } } PERF_TEST(Transform, getPerspectiveTransform) { unsigned int size = 8; Mat source(1, size/2, CV_32FC2); Mat destination(1, size/2, CV_32FC2); Mat transformCoefficient; declare.in(source, destination, WARMUP_RNG); TEST_CYCLE() { transformCoefficient = getPerspectiveTransform(source, destination); } SANITY_CHECK(transformCoefficient, 1e-5); }