// This file is part of OpenCV project. // It is subject to the license terms in the LICENSE file found in the top-level directory // of this distribution and at http://opencv.org/license.html #include "test_precomp.hpp" #include "test_common.hpp" namespace opencv_test { namespace { /* < , > */ typedef tuple< tuple, tuple > Imgcodecs_Resize_t; typedef testing::TestWithParam< Imgcodecs_Resize_t > Imgcodecs_Resize; /* resize_flag_and_dims = */ const tuple resize_flag_and_dims[] = { make_tuple(IMREAD_UNCHANGED, 1), make_tuple(IMREAD_REDUCED_GRAYSCALE_2, 2), make_tuple(IMREAD_REDUCED_GRAYSCALE_4, 4), make_tuple(IMREAD_REDUCED_GRAYSCALE_8, 8), make_tuple(IMREAD_REDUCED_COLOR_2, 2), make_tuple(IMREAD_REDUCED_COLOR_4, 4), make_tuple(IMREAD_REDUCED_COLOR_8, 8) }; const tuple images[] = { #ifdef HAVE_JPEG make_tuple("../cv/imgproc/stuff.jpg", Size(640, 480)), #endif #if defined(HAVE_PNG) || defined(HAVE_SPNG) make_tuple("../cv/shared/pic1.png", Size(400, 300)), #endif make_tuple("../highgui/readwrite/ordinary.bmp", Size(480, 272)), }; TEST_P(Imgcodecs_Resize, imread_reduce_flags) { const string file_name = findDataFile(get<0>(get<0>(GetParam()))); const Size imageSize = get<1>(get<0>(GetParam())); const int imread_flag = get<0>(get<1>(GetParam())); const int scale = get<1>(get<1>(GetParam())); const int cols = imageSize.width / scale; const int rows = imageSize.height / scale; { Mat img = imread(file_name, imread_flag); ASSERT_FALSE(img.empty()); EXPECT_EQ(cols, img.cols); EXPECT_EQ(rows, img.rows); } } //================================================================================================== TEST_P(Imgcodecs_Resize, imdecode_reduce_flags) { const string file_name = findDataFile(get<0>(get<0>(GetParam()))); const Size imageSize = get<1>(get<0>(GetParam())); const int imread_flag = get<0>(get<1>(GetParam())); const int scale = get<1>(get<1>(GetParam())); const int cols = imageSize.width / scale; const int rows = imageSize.height / scale; const std::ios::openmode mode = std::ios::in | std::ios::binary; std::ifstream ifs(file_name.c_str(), mode); ASSERT_TRUE(ifs.is_open()); ifs.seekg(0, std::ios::end); const size_t sz = static_cast(ifs.tellg()); ifs.seekg(0, std::ios::beg); std::vector content(sz); ifs.read((char*)content.data(), sz); ASSERT_FALSE(ifs.fail()); { Mat img = imdecode(Mat(content), imread_flag); ASSERT_FALSE(img.empty()); EXPECT_EQ(cols, img.cols); EXPECT_EQ(rows, img.rows); } } //================================================================================================== INSTANTIATE_TEST_CASE_P(/*nothing*/, Imgcodecs_Resize, testing::Combine( testing::ValuesIn(images), testing::ValuesIn(resize_flag_and_dims) ) ); //================================================================================================== TEST(Imgcodecs_Image, read_write_bmp) { const size_t IMAGE_COUNT = 10; const double thresDbell = 32; for (size_t i = 0; i < IMAGE_COUNT; ++i) { stringstream s; s << i; const string digit = s.str(); const string src_name = TS::ptr()->get_data_path() + "../python/images/QCIF_0" + digit + ".bmp"; const string dst_name = cv::tempfile((digit + ".bmp").c_str()); Mat image = imread(src_name); ASSERT_FALSE(image.empty()); resize(image, image, Size(968, 757), 0.0, 0.0, INTER_CUBIC); imwrite(dst_name, image); Mat loaded = imread(dst_name); ASSERT_FALSE(loaded.empty()); double psnr = cvtest::PSNR(loaded, image); EXPECT_GT(psnr, thresDbell); vector from_file; FILE *f = fopen(dst_name.c_str(), "rb"); fseek(f, 0, SEEK_END); long len = ftell(f); from_file.resize((size_t)len); fseek(f, 0, SEEK_SET); from_file.resize(fread(&from_file[0], 1, from_file.size(), f)); fclose(f); vector buf; imencode(".bmp", image, buf); ASSERT_EQ(buf, from_file); Mat buf_loaded = imdecode(Mat(buf), 1); ASSERT_FALSE(buf_loaded.empty()); psnr = cvtest::PSNR(buf_loaded, image); EXPECT_GT(psnr, thresDbell); EXPECT_EQ(0, remove(dst_name.c_str())); } } //================================================================================================== typedef string Ext; typedef testing::TestWithParam Imgcodecs_Image; const string exts[] = { #if defined(HAVE_PNG) || defined(HAVE_SPNG) "png", #endif #ifdef HAVE_TIFF "tiff", #endif #ifdef HAVE_JPEG "jpg", #endif #if (defined(HAVE_JASPER) && defined(OPENCV_IMGCODECS_ENABLE_JASPER_TESTS)) \ || defined(HAVE_OPENJPEG) "jp2", #endif #if 0 /*defined HAVE_OPENEXR && !defined __APPLE__*/ "exr", #endif "bmp", #ifdef HAVE_IMGCODEC_PXM "ppm", #endif #ifdef HAVE_IMGCODEC_SUNRASTER "ras", #endif }; static void test_image_io(const Mat& image, const std::string& fname, const std::string& ext, int imreadFlag, double psnrThreshold) { vector buf; ASSERT_NO_THROW(imencode("." + ext, image, buf)); ASSERT_NO_THROW(imwrite(fname, image)); FILE *f = fopen(fname.c_str(), "rb"); fseek(f, 0, SEEK_END); long len = ftell(f); cout << "File size: " << len << " bytes" << endl; EXPECT_GT(len, 1024) << "File is small. Test or implementation is broken"; fseek(f, 0, SEEK_SET); vector file_buf((size_t)len); EXPECT_EQ(len, (long)fread(&file_buf[0], 1, (size_t)len, f)); fclose(f); f = NULL; EXPECT_EQ(buf, file_buf) << "imwrite() / imencode() calls must provide the same output (bit-exact)"; Mat buf_loaded = imdecode(Mat(buf), imreadFlag); EXPECT_FALSE(buf_loaded.empty()); Mat loaded = imread(fname, imreadFlag); EXPECT_FALSE(loaded.empty()); EXPECT_EQ(0, cv::norm(loaded, buf_loaded, NORM_INF)) << "imread() and imdecode() calls must provide the same result (bit-exact)"; double psnr = cvtest::PSNR(loaded, image); EXPECT_GT(psnr, psnrThreshold); // not necessary due bitexact check above //double buf_psnr = cvtest::PSNR(buf_loaded, image); //EXPECT_GT(buf_psnr, psnrThreshold); #if 0 // debug if (psnr <= psnrThreshold /*|| buf_psnr <= thresDbell*/) { cout << "File: " << fname << endl; imshow("origin", image); imshow("imread", loaded); imshow("imdecode", buf_loaded); waitKey(); } #endif } TEST_P(Imgcodecs_Image, read_write_BGR) { const string ext = this->GetParam(); const string fname = cv::tempfile(ext.c_str()); double psnrThreshold = 100; if (ext == "jpg") psnrThreshold = 32; #if defined(HAVE_JASPER) if (ext == "jp2") psnrThreshold = 95; #elif defined(HAVE_OPENJPEG) if (ext == "jp2") psnrThreshold = 35; #endif Mat image = generateTestImageBGR(); EXPECT_NO_THROW(test_image_io(image, fname, ext, IMREAD_COLOR, psnrThreshold)); EXPECT_EQ(0, remove(fname.c_str())); } TEST_P(Imgcodecs_Image, read_write_GRAYSCALE) { const string ext = this->GetParam(); if (false || ext == "ppm" // grayscale is not implemented || ext == "ras" // broken (black result) ) throw SkipTestException("GRAYSCALE mode is not supported"); const string fname = cv::tempfile(ext.c_str()); double psnrThreshold = 100; if (ext == "jpg") psnrThreshold = 40; #if defined(HAVE_JASPER) if (ext == "jp2") psnrThreshold = 70; #elif defined(HAVE_OPENJPEG) if (ext == "jp2") psnrThreshold = 35; #endif Mat image = generateTestImageGrayscale(); EXPECT_NO_THROW(test_image_io(image, fname, ext, IMREAD_GRAYSCALE, psnrThreshold)); EXPECT_EQ(0, remove(fname.c_str())); } INSTANTIATE_TEST_CASE_P(imgcodecs, Imgcodecs_Image, testing::ValuesIn(exts)); TEST(Imgcodecs_Image, regression_9376) { String path = findDataFile("readwrite/regression_9376.bmp"); Mat m = imread(path); ASSERT_FALSE(m.empty()); EXPECT_EQ(32, m.cols); EXPECT_EQ(32, m.rows); } //================================================================================================== TEST(Imgcodecs_Image, write_umat) { const string src_name = TS::ptr()->get_data_path() + "../python/images/baboon.bmp"; const string dst_name = cv::tempfile(".bmp"); Mat image1 = imread(src_name); ASSERT_FALSE(image1.empty()); UMat image1_umat = image1.getUMat(ACCESS_RW); imwrite(dst_name, image1_umat); Mat image2 = imread(dst_name); ASSERT_FALSE(image2.empty()); EXPECT_PRED_FORMAT2(cvtest::MatComparator(0, 0), image1, image2); EXPECT_EQ(0, remove(dst_name.c_str())); } TEST(Imgcodecs_Image, multipage_collection_size) { const string root = cvtest::TS::ptr()->get_data_path(); const string filename = root + "readwrite/multipage.tif"; ImageCollection collection(filename, IMREAD_ANYCOLOR); EXPECT_EQ((std::size_t)6, collection.size()); } TEST(Imgcodecs_Image, multipage_collection_read_pages_iterator) { const string root = cvtest::TS::ptr()->get_data_path(); const string filename = root + "readwrite/multipage.tif"; const string page_files[] = { root + "readwrite/multipage_p1.tif", root + "readwrite/multipage_p2.tif", root + "readwrite/multipage_p3.tif", root + "readwrite/multipage_p4.tif", root + "readwrite/multipage_p5.tif", root + "readwrite/multipage_p6.tif" }; ImageCollection collection(filename, IMREAD_ANYCOLOR); auto collectionBegin = collection.begin(); for(size_t i = 0; i < collection.size(); ++i, ++collectionBegin) { double diff = cv::norm(collectionBegin.operator*(), imread(page_files[i]), NORM_INF); EXPECT_EQ(0., diff); } } TEST(Imgcodecs_Image, multipage_collection_two_iterator) { const string root = cvtest::TS::ptr()->get_data_path(); const string filename = root + "readwrite/multipage.tif"; const string page_files[] = { root + "readwrite/multipage_p1.tif", root + "readwrite/multipage_p2.tif", root + "readwrite/multipage_p3.tif", root + "readwrite/multipage_p4.tif", root + "readwrite/multipage_p5.tif", root + "readwrite/multipage_p6.tif" }; ImageCollection collection(filename, IMREAD_ANYCOLOR); auto firstIter = collection.begin(); auto secondIter = collection.begin(); // Decode all odd pages then decode even pages -> 1, 0, 3, 2 ... firstIter++; for(size_t i = 1; i < collection.size(); i += 2, ++firstIter, ++firstIter, ++secondIter, ++secondIter) { Mat mat = *firstIter; double diff = cv::norm(mat, imread(page_files[i]), NORM_INF); EXPECT_EQ(0., diff); Mat evenMat = *secondIter; diff = cv::norm(evenMat, imread(page_files[i-1]), NORM_INF); EXPECT_EQ(0., diff); } } TEST(Imgcodecs_Image, multipage_collection_operator_plusplus) { const string root = cvtest::TS::ptr()->get_data_path(); const string filename = root + "readwrite/multipage.tif"; // operator++ test ImageCollection collection(filename, IMREAD_ANYCOLOR); auto firstIter = collection.begin(); auto secondIter = firstIter++; // firstIter points to second page, secondIter points to first page double diff = cv::norm(*firstIter, *secondIter, NORM_INF); EXPECT_NE(diff, 0.); } TEST(Imgcodecs_Image, multipage_collection_backward_decoding) { const string root = cvtest::TS::ptr()->get_data_path(); const string filename = root + "readwrite/multipage.tif"; const string page_files[] = { root + "readwrite/multipage_p1.tif", root + "readwrite/multipage_p2.tif", root + "readwrite/multipage_p3.tif", root + "readwrite/multipage_p4.tif", root + "readwrite/multipage_p5.tif", root + "readwrite/multipage_p6.tif" }; ImageCollection collection(filename, IMREAD_ANYCOLOR); EXPECT_EQ((size_t)6, collection.size()); // backward decoding -> 5,4,3,2,1,0 for(int i = (int)collection.size() - 1; i >= 0; --i) { cv::Mat ithPage = imread(page_files[i]); EXPECT_FALSE(ithPage.empty()); double diff = cv::norm(collection[i], ithPage, NORM_INF); EXPECT_EQ(diff, 0.); } for(int i = 0; i < (int)collection.size(); ++i) { collection.releaseCache(i); } double diff = cv::norm(collection[2], imread(page_files[2]), NORM_INF); EXPECT_EQ(diff, 0.); } TEST(ImgCodecs, multipage_collection_decoding_range_based_for_loop_test) { const string root = cvtest::TS::ptr()->get_data_path(); const string filename = root + "readwrite/multipage.tif"; const string page_files[] = { root + "readwrite/multipage_p1.tif", root + "readwrite/multipage_p2.tif", root + "readwrite/multipage_p3.tif", root + "readwrite/multipage_p4.tif", root + "readwrite/multipage_p5.tif", root + "readwrite/multipage_p6.tif" }; ImageCollection collection(filename, IMREAD_ANYCOLOR); size_t index = 0; for(auto &i: collection) { cv::Mat ithPage = imread(page_files[index]); EXPECT_FALSE(ithPage.empty()); double diff = cv::norm(i, ithPage, NORM_INF); EXPECT_EQ(0., diff); ++index; } EXPECT_EQ(index, collection.size()); index = 0; for(auto &&i: collection) { cv::Mat ithPage = imread(page_files[index]); EXPECT_FALSE(ithPage.empty()); double diff = cv::norm(i, ithPage, NORM_INF); EXPECT_EQ(0., diff); ++index; } EXPECT_EQ(index, collection.size()); } TEST(ImgCodecs, multipage_collection_two_iterator_operatorpp) { const string root = cvtest::TS::ptr()->get_data_path(); const string filename = root + "readwrite/multipage.tif"; ImageCollection imcol(filename, IMREAD_ANYCOLOR); auto it0 = imcol.begin(), it1 = it0, it2 = it0; vector img(6); for (int i = 0; i < 6; i++) { img[i] = *it0; it0->release(); ++it0; } for (int i = 0; i < 3; i++) { ++it2; } for (int i = 0; i < 3; i++) { auto img2 = *it2; auto img1 = *it1; ++it2; ++it1; EXPECT_TRUE(cv::norm(img2, img[i+3], NORM_INF) == 0); EXPECT_TRUE(cv::norm(img1, img[i], NORM_INF) == 0); } } TEST(Imgcodecs_Params, imwrite_regression_22752) { const Mat img(16, 16, CV_8UC3, cv::Scalar::all(0)); vector params; params.push_back(IMWRITE_JPEG_QUALITY); // params.push_back(100)); // Forget it. EXPECT_ANY_THROW(cv::imwrite("test.jpg", img, params)); // parameters size or missing JPEG codec } TEST(Imgcodecs_Params, imencode_regression_22752) { const Mat img(16, 16, CV_8UC3, cv::Scalar::all(0)); vector params; params.push_back(IMWRITE_JPEG_QUALITY); // params.push_back(100)); // Forget it. vector buf; EXPECT_ANY_THROW(cv::imencode("test.jpg", img, buf, params)); // parameters size or missing JPEG codec } }} // namespace