/*M/////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2010-2013, Advanced Micro Devices, Inc., all rights reserved. // Third party copyrights are property of their respective owners. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // // * The name of the copyright holders may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors "as is" and // any express or implied warranties, including, but not limited to, the implied // warranties of merchantability and fitness for a particular purpose are disclaimed. // In no event shall the OpenCV Foundation or contributors be liable for any direct, // indirect, incidental, special, exemplary, or consequential damages // (including, but not limited to, procurement of substitute goods or services; // loss of use, data, or profits; or business interruption) however caused // and on any theory of liability, whether in contract, strict liability, // or tort (including negligence or otherwise) arising in any way out of // the use of this software, even if advised of the possibility of such damage. // //M*/ #include "perf_precomp.hpp" #include "opencv2/ts/ocl_perf.hpp" #ifdef HAVE_OPENCL namespace cvtest { namespace ocl { ///////////// Lut //////////////////////// typedef Size_MatType LUTFixture; OCL_PERF_TEST_P(LUTFixture, LUT, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params), cn = CV_MAT_CN(type); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, CV_8UC(cn)), lut(1, 256, type); int dstType = CV_MAKETYPE(lut.depth(), src.channels()); UMat dst(srcSize, dstType); declare.in(src, lut, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::LUT(src, lut, dst); SANITY_CHECK(dst); } ///////////// Exp //////////////////////// typedef Size_MatType ExpFixture; OCL_PERF_TEST_P(ExpFixture, Exp, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); declare.in(src).out(dst); randu(src, 5, 16); OCL_TEST_CYCLE() cv::exp(src, dst); SANITY_CHECK(dst, 1e-6, ERROR_RELATIVE); } ///////////// Log //////////////////////// typedef Size_MatType LogFixture; OCL_PERF_TEST_P(LogFixture, Log, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); randu(src, 1, 10000); declare.in(src).out(dst); OCL_TEST_CYCLE() cv::log(src, dst); SANITY_CHECK(dst, 1e-6, ERROR_RELATIVE); } ///////////// Add //////////////////////// typedef Size_MatType AddFixture; OCL_PERF_TEST_P(AddFixture, Add, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size srcSize = GET_PARAM(0); const int type = GET_PARAM(1); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::add(src1, src2, dst); SANITY_CHECK(dst); } ///////////// Subtract //////////////////////// typedef Size_MatType SubtractFixture; OCL_PERF_TEST_P(SubtractFixture, Subtract, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::subtract(src1, src2, dst); SANITY_CHECK(dst); } ///////////// Mul //////////////////////// typedef Size_MatType MulFixture; OCL_PERF_TEST_P(MulFixture, Multiply, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::multiply(src1, src2, dst); SANITY_CHECK(dst); } ///////////// Div //////////////////////// typedef Size_MatType DivFixture; OCL_PERF_TEST_P(DivFixture, Divide, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::divide(src1, src2, dst); SANITY_CHECK(dst, 1e-6, ERROR_RELATIVE); } ///////////// Absdiff //////////////////////// typedef Size_MatType AbsDiffFixture; OCL_PERF_TEST_P(AbsDiffFixture, Absdiff, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).in(dst); OCL_TEST_CYCLE() cv::absdiff(src1, src2, dst); SANITY_CHECK(dst); } ///////////// CartToPolar //////////////////////// typedef Size_MatType CartToPolarFixture; OCL_PERF_TEST_P(CartToPolarFixture, CartToPolar, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst1(srcSize, type), dst2(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst1, dst2); OCL_TEST_CYCLE() cv::cartToPolar(src1, src2, dst1, dst2); SANITY_CHECK(dst1, 8e-3); SANITY_CHECK(dst2, 8e-3); } ///////////// PolarToCart //////////////////////// typedef Size_MatType PolarToCartFixture; OCL_PERF_TEST_P(PolarToCartFixture, PolarToCart, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst1(srcSize, type), dst2(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst1, dst2); OCL_TEST_CYCLE() cv::polarToCart(src1, src2, dst1, dst2); SANITY_CHECK(dst1, 5e-5); SANITY_CHECK(dst2, 5e-5); } ///////////// Magnitude //////////////////////// typedef Size_MatType MagnitudeFixture; OCL_PERF_TEST_P(MagnitudeFixture, Magnitude, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::magnitude(src1, src2, dst); SANITY_CHECK(dst, 1e-6); } ///////////// Transpose //////////////////////// typedef Size_MatType TransposeFixture; OCL_PERF_TEST_P(TransposeFixture, Transpose, ::testing::Combine( OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::transpose(src, dst); SANITY_CHECK(dst); } ///////////// Flip //////////////////////// enum { FLIP_BOTH = 0, FLIP_ROWS, FLIP_COLS }; CV_ENUM(FlipType, FLIP_BOTH, FLIP_ROWS, FLIP_COLS) typedef std::tr1::tuple FlipParams; typedef TestBaseWithParam FlipFixture; OCL_PERF_TEST_P(FlipFixture, Flip, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES, FlipType::all())) { const FlipParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const int flipType = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::flip(src, dst, flipType - 1); SANITY_CHECK(dst); } ///////////// minMaxLoc //////////////////////// typedef Size_MatType MinMaxLocFixture; OCL_PERF_TEST_P(MinMaxLocFixture, MinMaxLoc, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); bool onecn = CV_MAT_CN(type) == 1; checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type);; declare.in(src, WARMUP_RNG); double min_val = 0.0, max_val = 0.0; Point min_loc, max_loc; OCL_TEST_CYCLE() cv::minMaxLoc(src, &min_val, &max_val, onecn ? &min_loc : NULL, onecn ? &max_loc : NULL); ASSERT_GE(max_val, min_val); SANITY_CHECK(min_val); SANITY_CHECK(max_val); int min_loc_x = min_loc.x, min_loc_y = min_loc.y, max_loc_x = max_loc.x, max_loc_y = max_loc.y; SANITY_CHECK(min_loc_x); SANITY_CHECK(min_loc_y); SANITY_CHECK(max_loc_x); SANITY_CHECK(max_loc_y); } ///////////// Sum //////////////////////// typedef Size_MatType SumFixture; OCL_PERF_TEST_P(SumFixture, Sum, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params), depth = CV_MAT_DEPTH(type); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type); Scalar result; randu(src, 0, 60); declare.in(src); OCL_TEST_CYCLE() result = cv::sum(src); if (depth >= CV_32F) SANITY_CHECK(result, 1e-6, ERROR_RELATIVE); else SANITY_CHECK(result); } ///////////// countNonZero //////////////////////// typedef Size_MatType CountNonZeroFixture; OCL_PERF_TEST_P(CountNonZeroFixture, CountNonZero, ::testing::Combine(OCL_TEST_SIZES, OCL_PERF_ENUM(CV_8UC1, CV_32FC1))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type); int result = 0; randu(src, 0, 10); declare.in(src); OCL_TEST_CYCLE() result = cv::countNonZero(src); SANITY_CHECK(result); } ///////////// Phase //////////////////////// typedef Size_MatType PhaseFixture; OCL_PERF_TEST_P(PhaseFixture, Phase, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::phase(src1, src2, dst, 1); SANITY_CHECK(dst, 1e-2); } ///////////// bitwise_and //////////////////////// typedef Size_MatType BitwiseAndFixture; OCL_PERF_TEST_P(BitwiseAndFixture, Bitwise_and, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::bitwise_and(src1, src2, dst); SANITY_CHECK(dst); } ///////////// bitwise_xor //////////////////////// typedef Size_MatType BitwiseXorFixture; OCL_PERF_TEST_P(BitwiseXorFixture, Bitwise_xor, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::bitwise_xor(src1, src2, dst); SANITY_CHECK(dst); } ///////////// bitwise_or //////////////////////// typedef Size_MatType BitwiseOrFixture; OCL_PERF_TEST_P(BitwiseOrFixture, Bitwise_or, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::bitwise_or(src1, src2, dst); SANITY_CHECK(dst); } ///////////// bitwise_not //////////////////////// typedef Size_MatType BitwiseNotFixture; OCL_PERF_TEST_P(BitwiseNotFixture, Bitwise_not, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::bitwise_not(src, dst); SANITY_CHECK(dst); } ///////////// compare //////////////////////// CV_ENUM(CmpCode, CMP_LT, CMP_LE, CMP_EQ, CMP_NE, CMP_GE, CMP_GT) typedef std::tr1::tuple CompareParams; typedef TestBaseWithParam CompareFixture; OCL_PERF_TEST_P(CompareFixture, Compare, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134, CmpCode::all())) { const CompareParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const int cmpCode = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, CV_8UC(CV_MAT_CN(type))); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::compare(src1, src2, dst, cmpCode); SANITY_CHECK(dst); } OCL_PERF_TEST_P(CompareFixture, CompareScalar, ::testing::Combine(OCL_TEST_SIZES, OCL_PERF_ENUM((MatType)CV_32FC1), // TODO: OCL_TEST_TYPES_134 CmpCode::all())) { const CompareParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const int cmpCode = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), dst(srcSize, CV_8UC(CV_MAT_CN(type))); declare.in(src1, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::compare(src1, 32, dst, cmpCode); SANITY_CHECK(dst); } ///////////// pow //////////////////////// typedef Size_MatType PowFixture; OCL_PERF_TEST_P(PowFixture, Pow, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); randu(src, 0, 100); declare.in(src).out(dst); OCL_TEST_CYCLE() cv::pow(src, 2.17, dst); SANITY_CHECK(dst, 1.5e-6, ERROR_RELATIVE); } ///////////// AddWeighted//////////////////////// typedef Size_MatType AddWeightedFixture; OCL_PERF_TEST_P(AddWeightedFixture, AddWeighted, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params), depth = CV_MAT_DEPTH(type); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); double alpha = 2.0, beta = 1.0, gama = 3.0; OCL_TEST_CYCLE() cv::addWeighted(src1, alpha, src2, beta, gama, dst); if (depth >= CV_32F) SANITY_CHECK(dst, 1e-6, ERROR_RELATIVE); else SANITY_CHECK(dst); } ///////////// Sqrt /////////////////////// typedef Size_MatType SqrtFixture; OCL_PERF_TEST_P(SqrtFixture, Sqrt, ::testing::Combine( OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); randu(src, 0, 1000); declare.in(src).out(dst); OCL_TEST_CYCLE() cv::sqrt(src, dst); SANITY_CHECK(dst, 1e-6, ERROR_RELATIVE); } ///////////// SetIdentity //////////////////////// typedef Size_MatType SetIdentityFixture; OCL_PERF_TEST_P(SetIdentityFixture, SetIdentity, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat dst(srcSize, type); declare.out(dst); OCL_TEST_CYCLE() cv::setIdentity(dst, cv::Scalar::all(181)); SANITY_CHECK(dst); } ///////////// MeanStdDev //////////////////////// typedef Size_MatType MeanStdDevFixture; OCL_PERF_TEST_P(MeanStdDevFixture, MeanStdDev, ::testing::Combine(OCL_PERF_ENUM(OCL_SIZE_1, OCL_SIZE_2, OCL_SIZE_3), OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const double eps = 2e-5; checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type); Scalar mean, stddev; declare.in(src, WARMUP_RNG); OCL_TEST_CYCLE() cv::meanStdDev(src, mean, stddev); double mean0 = mean[0], mean1 = mean[1], mean2 = mean[2], mean3 = mean[3]; double stddev0 = stddev[0], stddev1 = stddev[1], stddev2 = stddev[2], stddev3 = stddev[3]; SANITY_CHECK(mean0, eps, ERROR_RELATIVE); SANITY_CHECK(mean1, eps, ERROR_RELATIVE); SANITY_CHECK(mean2, eps, ERROR_RELATIVE); SANITY_CHECK(mean3, eps, ERROR_RELATIVE); SANITY_CHECK(stddev0, eps, ERROR_RELATIVE); SANITY_CHECK(stddev1, eps, ERROR_RELATIVE); SANITY_CHECK(stddev2, eps, ERROR_RELATIVE); SANITY_CHECK(stddev3, eps, ERROR_RELATIVE); } OCL_PERF_TEST_P(MeanStdDevFixture, MeanStdDevWithMask, ::testing::Combine(OCL_PERF_ENUM(OCL_SIZE_1, OCL_SIZE_2, OCL_SIZE_3), OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const double eps = 2e-5; checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), mask(srcSize, CV_8UC1); Scalar mean, stddev; declare.in(src, mask, WARMUP_RNG); OCL_TEST_CYCLE() cv::meanStdDev(src, mean, stddev, mask); double mean0 = mean[0], mean1 = mean[1], mean2 = mean[2], mean3 = mean[3]; double stddev0 = stddev[0], stddev1 = stddev[1], stddev2 = stddev[2], stddev3 = stddev[3]; SANITY_CHECK(mean0, eps, ERROR_RELATIVE); SANITY_CHECK(mean1, eps, ERROR_RELATIVE); SANITY_CHECK(mean2, eps, ERROR_RELATIVE); SANITY_CHECK(mean3, eps, ERROR_RELATIVE); SANITY_CHECK(stddev0, eps, ERROR_RELATIVE); SANITY_CHECK(stddev1, eps, ERROR_RELATIVE); SANITY_CHECK(stddev2, eps, ERROR_RELATIVE); SANITY_CHECK(stddev3, eps, ERROR_RELATIVE); } ///////////// Norm //////////////////////// CV_ENUM(NormType, NORM_INF, NORM_L1, NORM_L2) typedef std::tr1::tuple NormParams; typedef TestBaseWithParam NormFixture; OCL_PERF_TEST_P(NormFixture, Norm1Arg, ::testing::Combine(OCL_PERF_ENUM(OCL_SIZE_1, OCL_SIZE_2, OCL_SIZE_3), OCL_TEST_TYPES_134, NormType::all())) { const NormParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const int normType = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type); double res; declare.in(src1, WARMUP_RNG); OCL_TEST_CYCLE() res = cv::norm(src1, normType); SANITY_CHECK(res, 1e-5, ERROR_RELATIVE); } OCL_PERF_TEST_P(NormFixture, Norm, ::testing::Combine(OCL_PERF_ENUM(OCL_SIZE_1, OCL_SIZE_2, OCL_SIZE_3), OCL_TEST_TYPES_134, NormType::all())) { const NormParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const int normType = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type); double res; declare.in(src1, src2, WARMUP_RNG); OCL_TEST_CYCLE() res = cv::norm(src1, src2, normType); SANITY_CHECK(res, 1e-5, ERROR_RELATIVE); } OCL_PERF_TEST_P(NormFixture, NormRel, ::testing::Combine(OCL_PERF_ENUM(OCL_SIZE_1, OCL_SIZE_2, OCL_SIZE_3), OCL_TEST_TYPES_134, NormType::all())) { const NormParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); const int normType = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type); double res; declare.in(src1, src2, WARMUP_RNG); OCL_TEST_CYCLE() res = cv::norm(src1, src2, normType | cv::NORM_RELATIVE); SANITY_CHECK(res, 1e-5, ERROR_RELATIVE); } ///////////// UMat::dot //////////////////////// typedef Size_MatType UMatDotFixture; OCL_PERF_TEST_P(UMatDotFixture, UMatDot, ::testing::Combine(OCL_PERF_ENUM(OCL_SIZE_1, OCL_SIZE_2, OCL_SIZE_3), OCL_TEST_TYPES_134)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); double r = 0.0; checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type); declare.in(src1, src2, WARMUP_RNG); OCL_TEST_CYCLE() r = src1.dot(src2); SANITY_CHECK(r, 1e-5, ERROR_RELATIVE); } ///////////// Repeat //////////////////////// typedef Size_MatType RepeatFixture; OCL_PERF_TEST_P(RepeatFixture, Repeat, ::testing::Combine(OCL_PERF_ENUM(OCL_SIZE_1, OCL_SIZE_2, OCL_SIZE_3), OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params), nx = 2, ny = 2; checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(Size(srcSize.width * nx, srcSize.height * ny), type); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::repeat(src, nx, ny, dst); SANITY_CHECK(dst); } ///////////// Min //////////////////////// typedef Size_MatType MinFixture; OCL_PERF_TEST_P(MinFixture, Min, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::min(src1, src2, dst); SANITY_CHECK(dst); } ///////////// Max //////////////////////// typedef Size_MatType MaxFixture; OCL_PERF_TEST_P(MaxFixture, Max, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::max(src1, src2, dst); SANITY_CHECK(dst); } ///////////// InRange //////////////////////// typedef Size_MatType InRangeFixture; OCL_PERF_TEST_P(InRangeFixture, InRange, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), lb(srcSize, type), ub(srcSize, type), dst(srcSize, CV_8UC1); declare.in(src, lb, ub, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::inRange(src, lb, ub, dst); SANITY_CHECK(dst); } ///////////// Normalize //////////////////////// CV_ENUM(NormalizeModes, CV_MINMAX, CV_L2, CV_L1, CV_C) typedef tuple NormalizeParams; typedef TestBaseWithParam NormalizeFixture; OCL_PERF_TEST_P(NormalizeFixture, Normalize, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES_134, NormalizeModes::all())) { const NormalizeParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params), mode = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, type); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::normalize(src, dst, 10, 110, mode); SANITY_CHECK(dst, 5e-2); } OCL_PERF_TEST_P(NormalizeFixture, NormalizeWithMask, ::testing::Combine(OCL_TEST_SIZES, OCL_PERF_ENUM(CV_8UC1, CV_32FC1), NormalizeModes::all())) { const NormalizeParams params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params), mode = get<2>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), mask(srcSize, CV_8UC1), dst(srcSize, type); declare.in(src, mask, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::normalize(src, dst, 10, 110, mode, -1, mask); SANITY_CHECK(dst, 5e-2); } ///////////// ConvertScaleAbs //////////////////////// typedef Size_MatType ConvertScaleAbsFixture; OCL_PERF_TEST_P(ConvertScaleAbsFixture, ConvertScaleAbs, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params), cn = CV_MAT_CN(type); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type), dst(srcSize, CV_8UC(cn)); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::convertScaleAbs(src, dst, 0.5, 2); SANITY_CHECK(dst); } ///////////// PatchNaNs //////////////////////// typedef Size_MatType PatchNaNsFixture; OCL_PERF_TEST_P(PatchNaNsFixture, PatchNaNs, ::testing::Combine(OCL_TEST_SIZES, OCL_PERF_ENUM(CV_32FC1, CV_32FC4))) { const Size_MatType_t params = GetParam(); Size srcSize = get<0>(params); const int type = get<1>(params), cn = CV_MAT_CN(type); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src(srcSize, type); declare.in(src, WARMUP_RNG).out(src); // generating NaNs { Mat src_ = src.getMat(ACCESS_RW); srcSize.width *= cn; for (int y = 0; y < srcSize.height; ++y) { float * const ptr = src_.ptr(y); for (int x = 0; x < srcSize.width; ++x) ptr[x] = (x + y) % 2 == 0 ? std::numeric_limits::quiet_NaN() : ptr[x]; } } OCL_TEST_CYCLE() cv::patchNaNs(src, 17.7); SANITY_CHECK(src); } ///////////// ScaleAdd //////////////////////// typedef Size_MatType ScaleAddFixture; OCL_PERF_TEST_P(ScaleAddFixture, ScaleAdd, ::testing::Combine(OCL_TEST_SIZES, OCL_TEST_TYPES)) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); UMat src1(srcSize, type), src2(srcSize, type), dst(srcSize, type); declare.in(src1, src2, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::scaleAdd(src1, 0.6, src2, dst); SANITY_CHECK(dst, 1e-6); } ///////////// PSNR //////////////////////// typedef Size_MatType PSNRFixture; OCL_PERF_TEST_P(PSNRFixture, PSNR, ::testing::Combine(OCL_TEST_SIZES, OCL_PERF_ENUM(CV_8UC1, CV_8UC4))) { const Size_MatType_t params = GetParam(); const Size srcSize = get<0>(params); const int type = get<1>(params); checkDeviceMaxMemoryAllocSize(srcSize, type); double psnr = 0; UMat src1(srcSize, type), src2(srcSize, type); declare.in(src1, src2, WARMUP_RNG); OCL_TEST_CYCLE() psnr = cv::PSNR(src1, src2); SANITY_CHECK(psnr, 1e-4, ERROR_RELATIVE); } ///////////// Reduce //////////////////////// CV_ENUM(ReduceMinMaxOp, CV_REDUCE_MIN, CV_REDUCE_MAX) typedef tuple, int, ReduceMinMaxOp> ReduceMinMaxParams; typedef TestBaseWithParam ReduceMinMaxFixture; OCL_PERF_TEST_P(ReduceMinMaxFixture, Reduce, ::testing::Combine(OCL_TEST_SIZES, OCL_PERF_ENUM(std::make_pair(CV_8UC1, CV_8UC1), std::make_pair(CV_32FC4, CV_32FC4)), OCL_PERF_ENUM(0, 1), ReduceMinMaxOp::all())) { const ReduceMinMaxParams params = GetParam(); const std::pair types = get<1>(params); const int stype = types.first, dtype = types.second, dim = get<2>(params), op = get<3>(params); const Size srcSize = get<0>(params), dstSize(dim == 0 ? srcSize.width : 1, dim == 0 ? 1 : srcSize.height); const double eps = CV_MAT_DEPTH(dtype) <= CV_32S ? 1 : 1e-5; checkDeviceMaxMemoryAllocSize(srcSize, stype); checkDeviceMaxMemoryAllocSize(srcSize, dtype); UMat src(srcSize, stype), dst(dstSize, dtype); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::reduce(src, dst, dim, op, dtype); SANITY_CHECK(dst, eps); } CV_ENUM(ReduceAccOp, CV_REDUCE_SUM, CV_REDUCE_AVG) typedef tuple, int, ReduceAccOp> ReduceAccParams; typedef TestBaseWithParam ReduceAccFixture; OCL_PERF_TEST_P(ReduceAccFixture, Reduce, ::testing::Combine(OCL_TEST_SIZES, OCL_PERF_ENUM(std::make_pair(CV_8UC4, CV_32SC4), std::make_pair(CV_32FC1, CV_32FC1)), OCL_PERF_ENUM(0, 1), ReduceAccOp::all())) { const ReduceAccParams params = GetParam(); const std::pair types = get<1>(params); const int stype = types.first, dtype = types.second, dim = get<2>(params), op = get<3>(params); const Size srcSize = get<0>(params), dstSize(dim == 0 ? srcSize.width : 1, dim == 0 ? 1 : srcSize.height); const double eps = CV_MAT_DEPTH(dtype) <= CV_32S ? 1 : 3e-4; checkDeviceMaxMemoryAllocSize(srcSize, stype); checkDeviceMaxMemoryAllocSize(srcSize, dtype); UMat src(srcSize, stype), dst(dstSize, dtype); declare.in(src, WARMUP_RNG).out(dst); OCL_TEST_CYCLE() cv::reduce(src, dst, dim, op, dtype); SANITY_CHECK(dst, eps); } } } // namespace cvtest::ocl #endif // HAVE_OPENCL