opencv/modules/imgcodecs/test/test_grfmt.cpp

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#include "test_precomp.hpp"
namespace opencv_test { namespace {
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typedef tuple<string, int> File_Mode;
typedef testing::TestWithParam<File_Mode> Imgcodecs_FileMode;
TEST_P(Imgcodecs_FileMode, regression)
{
const string root = cvtest::TS::ptr()->get_data_path();
const string filename = root + get<0>(GetParam());
const int mode = get<1>(GetParam());
const Mat single = imread(filename, mode);
ASSERT_FALSE(single.empty());
vector<Mat> pages;
ASSERT_TRUE(imreadmulti(filename, pages, mode));
ASSERT_FALSE(pages.empty());
const Mat page = pages[0];
ASSERT_FALSE(page.empty());
EXPECT_EQ(page.channels(), single.channels());
EXPECT_EQ(page.depth(), single.depth());
EXPECT_EQ(page.size().height, single.size().height);
EXPECT_EQ(page.size().width, single.size().width);
EXPECT_PRED_FORMAT2(cvtest::MatComparator(0, 0), page, single);
}
const string all_images[] =
{
Merge pull request #16494 from StefanBruens:jpeg2000_openjpeg_port Jpeg2000 OpenJPEG port * OpenJPEG based JPEG2000 decoder implementation Currently, the following input color spaces and depth conversions are supported: - 8 bit -> 8 bit - 16 bit -> 16 bit (IMREAD_UNCHANGED, IMREAD_ANYDEPTH) - RGB(a) -> BGR - RGBA -> BGRA (IMREAD_UNCHANGED) - Y(a) -> Y(a) (IMREAD_ANYCOLOR, IMREAD_GRAY, IMREAD_UNCHANGED)) - YCC -> Y (IMREAD_GRAY) * Check for OpenJPEG availability This enables OpenJPEG based JPEG2000 imread support by default, which can be disabled by -DWITH_OPENJPEG=OFF. In case OpenJPEG is enabled and found, any checks for Jasper are skipped. * Implement precision downscaling for precision > 8 without IMREAD_UNCHANGED With IMREAD_UNCHANGED, values are kept from the input image, without it components are downscaled to CV_8U range. * Enable Jpeg2K tests when OpenJPEG is available * Add support for some more color conversions Support IMREAD_GRAY when input color space is RGB or unspecified. Support YUV input color space for BGR output. * fix: problems with unmanaged memory * fix: CMake warning - HAVE_OPENJPEG is undefined Removed trailing whitespaces * fix: CMake find_package OpenJPEG add minimal version * Basic JPEG2K encoder Images with depth CV_8U and CV_16U are supported, with 1 to 4 channels. * feature: Improved code for OpenJPEG2000 encoder/decoder - Removed code duplication - Added error handlers - Extracted functions * feature: Update conversion openjpeg array from/to Mat * feature: Extend ChannelsIterator to fulfill RandomAccessIterator named requirements - Removed channels split in copyFromMatImpl. With ChannelsIterator no allocations are performed. - Split whole loop into 2 parts in copyToMat -> where std::copy and std::transforms are called. * fix: Applied review comments. - Changed `nullptr` in CV_LOG* functions to `NULL` - Added `falls through` comment in decoder color space `switch` - Added warning about unsupported parameters for the encoder * feature: Added decode from in-memory buffers. Co-authored-by: Vadim Levin <vadim.levin@xperience.ai>
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#if (defined(HAVE_JASPER) && defined(OPENCV_IMGCODECS_ENABLE_JASPER_TESTS)) \
|| defined(HAVE_OPENJPEG)
"readwrite/Rome.jp2",
"readwrite/Bretagne2.jp2",
"readwrite/Bretagne2.jp2",
"readwrite/Grey.jp2",
"readwrite/Grey.jp2",
"readwrite/balloon.j2c",
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#endif
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#ifdef HAVE_GDCM
"readwrite/int16-mono1.dcm",
"readwrite/uint8-mono2.dcm",
"readwrite/uint16-mono2.dcm",
"readwrite/uint8-rgb.dcm",
#endif
"readwrite/color_palette_alpha.png",
"readwrite/multipage.tif",
"readwrite/ordinary.bmp",
"readwrite/rle8.bmp",
"readwrite/test_1_c1.jpg",
#ifdef HAVE_IMGCODEC_HDR
"readwrite/rle.hdr"
#endif
};
const int basic_modes[] =
{
IMREAD_UNCHANGED,
IMREAD_GRAYSCALE,
IMREAD_COLOR,
IMREAD_ANYDEPTH,
IMREAD_ANYCOLOR
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};
INSTANTIATE_TEST_CASE_P(All, Imgcodecs_FileMode,
testing::Combine(
testing::ValuesIn(all_images),
testing::ValuesIn(basic_modes)));
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// GDAL does not support "hdr", "dcm" and has problems with JPEG2000 files (jp2, j2c)
struct notForGDAL {
bool operator()(const string &name) const {
const string &ext = name.substr(name.size() - 3, 3);
return ext == "hdr" || ext == "dcm" || ext == "jp2" || ext == "j2c" ||
name.find("rle8.bmp") != std::string::npos;
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}
};
inline vector<string> gdal_images()
{
vector<string> res;
std::back_insert_iterator< vector<string> > it(res);
std::remove_copy_if(all_images, all_images + sizeof(all_images)/sizeof(all_images[0]), it, notForGDAL());
return res;
}
INSTANTIATE_TEST_CASE_P(GDAL, Imgcodecs_FileMode,
testing::Combine(
testing::ValuesIn(gdal_images()),
testing::Values(IMREAD_LOAD_GDAL)));
//==================================================================================================
typedef tuple<string, Size> Ext_Size;
typedef testing::TestWithParam<Ext_Size> Imgcodecs_ExtSize;
TEST_P(Imgcodecs_ExtSize, write_imageseq)
{
const string ext = get<0>(GetParam());
const Size size = get<1>(GetParam());
const Point2i center = Point2i(size.width / 2, size.height / 2);
const int radius = std::min(size.height, size.width / 4);
for (int cn = 1; cn <= 4; cn++)
{
SCOPED_TRACE(format("channels %d", cn));
std::vector<int> parameters;
if (cn == 2)
continue;
if (cn == 4 && ext != ".tiff")
continue;
if (cn > 1 && (ext == ".pbm" || ext == ".pgm"))
continue;
if (cn != 3 && ext == ".ppm")
continue;
string filename = cv::tempfile(format("%d%s", cn, ext.c_str()).c_str());
Mat img_gt(size, CV_MAKETYPE(CV_8U, cn), Scalar::all(0));
circle(img_gt, center, radius, Scalar::all(255));
#if 1
if (ext == ".pbm" || ext == ".pgm" || ext == ".ppm")
{
parameters.push_back(IMWRITE_PXM_BINARY);
parameters.push_back(0);
}
#endif
ASSERT_TRUE(imwrite(filename, img_gt, parameters));
Mat img = imread(filename, IMREAD_UNCHANGED);
ASSERT_FALSE(img.empty());
EXPECT_EQ(img.size(), img.size());
EXPECT_EQ(img.type(), img.type());
EXPECT_EQ(cn, img.channels());
if (ext == ".jpg")
{
// JPEG format does not provide 100% accuracy
// using fuzzy image comparison
double n = cvtest::norm(img, img_gt, NORM_L1);
double expected = 0.07 * img.size().area();
EXPECT_LT(n, expected);
EXPECT_PRED_FORMAT2(cvtest::MatComparator(10, 0), img, img_gt);
}
else if (ext == ".pfm")
{
img_gt.convertTo(img_gt, CV_MAKETYPE(CV_32F, img.channels()));
double n = cvtest::norm(img, img_gt, NORM_L2);
EXPECT_LT(n, 1.);
EXPECT_PRED_FORMAT2(cvtest::MatComparator(0, 0), img, img_gt);
}
else
{
double n = cvtest::norm(img, img_gt, NORM_L2);
EXPECT_LT(n, 1.);
EXPECT_PRED_FORMAT2(cvtest::MatComparator(0, 0), img, img_gt);
}
#if 0
imshow("loaded", img);
waitKey(0);
#else
EXPECT_EQ(0, remove(filename.c_str()));
#endif
}
}
const string all_exts[] =
{
#if defined(HAVE_PNG) || defined(HAVE_SPNG)
".png",
#endif
#ifdef HAVE_TIFF
".tiff",
#endif
#ifdef HAVE_JPEG
".jpg",
#endif
".bmp",
#ifdef HAVE_IMGCODEC_PXM
".pam",
".ppm",
".pgm",
".pbm",
".pnm",
#endif
#ifdef HAVE_IMGCODEC_PFM
".pfm",
#endif
};
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vector<Size> all_sizes()
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{
vector<Size> res;
for (int k = 1; k <= 5; ++k)
res.push_back(Size(640 * k, 480 * k));
return res;
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}
INSTANTIATE_TEST_CASE_P(All, Imgcodecs_ExtSize,
testing::Combine(
testing::ValuesIn(all_exts),
testing::ValuesIn(all_sizes())));
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#ifdef HAVE_IMGCODEC_PXM
typedef testing::TestWithParam<bool> Imgcodecs_pbm;
TEST_P(Imgcodecs_pbm, write_read)
{
bool binary = GetParam();
const String ext = "pbm";
const string full_name = cv::tempfile(ext.c_str());
Size size(640, 480);
const Point2i center = Point2i(size.width / 2, size.height / 2);
const int radius = std::min(size.height, size.width / 4);
Mat image(size, CV_8UC1, Scalar::all(0));
circle(image, center, radius, Scalar::all(255));
vector<int> pbm_params;
pbm_params.push_back(IMWRITE_PXM_BINARY);
pbm_params.push_back(binary);
imwrite( full_name, image, pbm_params );
Mat loaded = imread(full_name, IMREAD_UNCHANGED);
ASSERT_FALSE(loaded.empty());
EXPECT_EQ(0, cvtest::norm(loaded, image, NORM_INF));
FILE *f = fopen(full_name.c_str(), "rb");
ASSERT_TRUE(f != NULL);
ASSERT_EQ('P', getc(f));
ASSERT_EQ('1' + (binary ? 3 : 0), getc(f));
fclose(f);
EXPECT_EQ(0, remove(full_name.c_str()));
}
INSTANTIATE_TEST_CASE_P(All, Imgcodecs_pbm, testing::Bool());
#endif
//==================================================================================================
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TEST(Imgcodecs_Bmp, read_rle8)
{
const string root = cvtest::TS::ptr()->get_data_path();
Mat rle = imread(root + "readwrite/rle8.bmp");
ASSERT_FALSE(rle.empty());
Mat ord = imread(root + "readwrite/ordinary.bmp");
ASSERT_FALSE(ord.empty());
EXPECT_LE(cvtest::norm(rle, ord, NORM_L2), 1.e-10);
EXPECT_PRED_FORMAT2(cvtest::MatComparator(0, 0), rle, ord);
}
TEST(Imgcodecs_Bmp, read_32bit_rgb)
{
const string root = cvtest::TS::ptr()->get_data_path();
const string filenameInput = root + "readwrite/test_32bit_rgb.bmp";
const Mat img = cv::imread(filenameInput, IMREAD_UNCHANGED);
ASSERT_FALSE(img.empty());
ASSERT_EQ(CV_8UC3, img.type());
}
TEST(Imgcodecs_Bmp, rgba_bit_mask)
{
const string root = cvtest::TS::ptr()->get_data_path();
const string filenameInput = root + "readwrite/test_rgba_mask.bmp";
const Mat img = cv::imread(filenameInput, IMREAD_UNCHANGED);
ASSERT_FALSE(img.empty());
ASSERT_EQ(CV_8UC4, img.type());
const uchar* data = img.ptr();
ASSERT_EQ(data[3], 255);
}
TEST(Imgcodecs_Bmp, read_32bit_xrgb)
{
const string root = cvtest::TS::ptr()->get_data_path();
const string filenameInput = root + "readwrite/test_32bit_xrgb.bmp";
const Mat img = cv::imread(filenameInput, IMREAD_UNCHANGED);
ASSERT_FALSE(img.empty());
ASSERT_EQ(CV_8UC4, img.type());
const uchar* data = img.ptr();
ASSERT_EQ(data[3], 255);
}
TEST(Imgcodecs_Bmp, rgba_scale)
{
const string root = cvtest::TS::ptr()->get_data_path();
const string filenameInput = root + "readwrite/test_rgba_scale.bmp";
Mat img = cv::imread(filenameInput, IMREAD_UNCHANGED);
ASSERT_FALSE(img.empty());
ASSERT_EQ(CV_8UC4, img.type());
uchar* data = img.ptr();
ASSERT_EQ(data[0], 255);
ASSERT_EQ(data[1], 255);
ASSERT_EQ(data[2], 255);
ASSERT_EQ(data[3], 255);
img = cv::imread(filenameInput, IMREAD_COLOR);
ASSERT_FALSE(img.empty());
ASSERT_EQ(CV_8UC3, img.type());
data = img.ptr();
ASSERT_EQ(data[0], 255);
ASSERT_EQ(data[1], 255);
ASSERT_EQ(data[2], 255);
img = cv::imread(filenameInput, IMREAD_GRAYSCALE);
ASSERT_FALSE(img.empty());
ASSERT_EQ(CV_8UC1, img.type());
data = img.ptr();
ASSERT_EQ(data[0], 255);
}
#ifdef HAVE_IMGCODEC_HDR
TEST(Imgcodecs_Hdr, regression)
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{
string folder = string(cvtest::TS::ptr()->get_data_path()) + "/readwrite/";
string name_rle = folder + "rle.hdr";
string name_no_rle = folder + "no_rle.hdr";
Mat img_rle = imread(name_rle, -1);
ASSERT_FALSE(img_rle.empty()) << "Could not open " << name_rle;
Mat img_no_rle = imread(name_no_rle, -1);
ASSERT_FALSE(img_no_rle.empty()) << "Could not open " << name_no_rle;
EXPECT_EQ(cvtest::norm(img_rle, img_no_rle, NORM_INF), 0.0);
string tmp_file_name = tempfile(".hdr");
vector<int> param(2);
param[0] = IMWRITE_HDR_COMPRESSION;
for(int i = 0; i < 2; i++) {
param[1] = i;
imwrite(tmp_file_name, img_rle, param);
Mat written_img = imread(tmp_file_name, -1);
EXPECT_EQ(cvtest::norm(written_img, img_rle, NORM_INF), 0.0);
}
remove(tmp_file_name.c_str());
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}
TEST(Imgcodecs_Hdr, regression_imencode)
{
string folder = string(cvtest::TS::ptr()->get_data_path()) + "/readwrite/";
string name = folder + "rle.hdr";
Mat img_ref = imread(name, -1);
ASSERT_FALSE(img_ref.empty()) << "Could not open " << name;
vector<int> params(2);
params[0] = IMWRITE_HDR_COMPRESSION;
{
vector<uchar> buf;
params[1] = IMWRITE_HDR_COMPRESSION_NONE;
imencode(".hdr", img_ref, buf, params);
Mat img = imdecode(buf, -1);
EXPECT_EQ(cvtest::norm(img_ref, img, NORM_INF), 0.0);
}
{
vector<uchar> buf;
params[1] = IMWRITE_HDR_COMPRESSION_RLE;
imencode(".hdr", img_ref, buf, params);
Mat img = imdecode(buf, -1);
EXPECT_EQ(cvtest::norm(img_ref, img, NORM_INF), 0.0);
}
}
#endif
#ifdef HAVE_IMGCODEC_PXM
TEST(Imgcodecs_Pam, read_write)
{
string folder = string(cvtest::TS::ptr()->get_data_path()) + "readwrite/";
string filepath = folder + "lena.pam";
cv::Mat img = cv::imread(filepath);
ASSERT_FALSE(img.empty());
std::vector<int> params;
params.push_back(IMWRITE_PAM_TUPLETYPE);
params.push_back(IMWRITE_PAM_FORMAT_RGB);
string writefile = cv::tempfile(".pam");
EXPECT_NO_THROW(cv::imwrite(writefile, img, params));
cv::Mat reread = cv::imread(writefile);
string writefile_no_param = cv::tempfile(".pam");
EXPECT_NO_THROW(cv::imwrite(writefile_no_param, img));
cv::Mat reread_no_param = cv::imread(writefile_no_param);
EXPECT_EQ(0, cvtest::norm(reread, reread_no_param, NORM_INF));
EXPECT_EQ(0, cvtest::norm(img, reread, NORM_INF));
remove(writefile.c_str());
remove(writefile_no_param.c_str());
}
#endif
#ifdef HAVE_IMGCODEC_PFM
TEST(Imgcodecs_Pfm, read_write)
{
Mat img = imread(findDataFile("readwrite/lena.pam"));
ASSERT_FALSE(img.empty());
img.convertTo(img, CV_32F, 1/255.0f);
std::vector<int> params;
string writefile = cv::tempfile(".pfm");
EXPECT_NO_THROW(cv::imwrite(writefile, img, params));
cv::Mat reread = cv::imread(writefile, IMREAD_UNCHANGED);
string writefile_no_param = cv::tempfile(".pfm");
EXPECT_NO_THROW(cv::imwrite(writefile_no_param, img));
cv::Mat reread_no_param = cv::imread(writefile_no_param, IMREAD_UNCHANGED);
EXPECT_EQ(0, cvtest::norm(reread, reread_no_param, NORM_INF));
EXPECT_EQ(0, cvtest::norm(img, reread, NORM_INF));
EXPECT_EQ(0, remove(writefile.c_str()));
EXPECT_EQ(0, remove(writefile_no_param.c_str()));
}
#endif
TEST(Imgcodecs, write_parameter_type)
{
cv::Mat m(10, 10, CV_8UC1, cv::Scalar::all(0));
cv::Mat1b m_type = cv::Mat1b::zeros(10, 10);
string tmp_file = cv::tempfile(".bmp");
EXPECT_NO_THROW(cv::imwrite(tmp_file, cv::Mat(m * 2))) << "* Failed with cv::Mat";
EXPECT_NO_THROW(cv::imwrite(tmp_file, m * 2)) << "* Failed with cv::MatExpr";
EXPECT_NO_THROW(cv::imwrite(tmp_file, m_type)) << "* Failed with cv::Mat_";
EXPECT_NO_THROW(cv::imwrite(tmp_file, m_type * 2)) << "* Failed with cv::MatExpr(Mat_)";
cv::Matx<uchar, 10, 10> matx;
EXPECT_NO_THROW(cv::imwrite(tmp_file, matx)) << "* Failed with cv::Matx";
EXPECT_EQ(0, remove(tmp_file.c_str()));
}
}} // namespace
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#if defined(HAVE_OPENEXR) && defined(OPENCV_IMGCODECS_ENABLE_OPENEXR_TESTS)
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#include "test_exr.impl.hpp"
#endif