/*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) 2000-2008, Intel Corporation, all rights reserved. // Copyright (C) 2009, Willow Garage 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 Intel Corporation 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*/ #ifndef OPENCV_IMGCODECS_HPP #define OPENCV_IMGCODECS_HPP #include "opencv2/core.hpp" /** @defgroup imgcodecs Image file reading and writing @{ @defgroup imgcodecs_flags Flags used for image file reading and writing @defgroup imgcodecs_ios iOS glue @defgroup imgcodecs_macosx MacOS(OSX) glue @} */ //////////////////////////////// image codec //////////////////////////////// namespace cv { //! @addtogroup imgcodecs //! @{ //! @addtogroup imgcodecs_flags //! @{ //! Imread flags enum ImreadModes { IMREAD_UNCHANGED = -1, //!< If set, return the loaded image as is (with alpha channel, otherwise it gets cropped). Ignore EXIF orientation. IMREAD_GRAYSCALE = 0, //!< If set, always convert image to the single channel grayscale image (codec internal conversion). IMREAD_COLOR_BGR = 1, //!< If set, always convert image to the 3 channel BGR color image. IMREAD_COLOR = 1, //!< Same as IMREAD_COLOR_BGR. IMREAD_ANYDEPTH = 2, //!< If set, return 16-bit/32-bit image when the input has the corresponding depth, otherwise convert it to 8-bit. IMREAD_ANYCOLOR = 4, //!< If set, the image is read in any possible color format. IMREAD_LOAD_GDAL = 8, //!< If set, use the gdal driver for loading the image. IMREAD_REDUCED_GRAYSCALE_2 = 16, //!< If set, always convert image to the single channel grayscale image and the image size reduced 1/2. IMREAD_REDUCED_COLOR_2 = 17, //!< If set, always convert image to the 3 channel BGR color image and the image size reduced 1/2. IMREAD_REDUCED_GRAYSCALE_4 = 32, //!< If set, always convert image to the single channel grayscale image and the image size reduced 1/4. IMREAD_REDUCED_COLOR_4 = 33, //!< If set, always convert image to the 3 channel BGR color image and the image size reduced 1/4. IMREAD_REDUCED_GRAYSCALE_8 = 64, //!< If set, always convert image to the single channel grayscale image and the image size reduced 1/8. IMREAD_REDUCED_COLOR_8 = 65, //!< If set, always convert image to the 3 channel BGR color image and the image size reduced 1/8. IMREAD_IGNORE_ORIENTATION = 128, //!< If set, do not rotate the image according to EXIF's orientation flag. IMREAD_COLOR_RGB = 256, //!< If set, always convert image to the 3 channel RGB color image. }; //! Imwrite flags enum ImwriteFlags { IMWRITE_JPEG_QUALITY = 1, //!< For JPEG, it can be a quality from 0 to 100 (the higher is the better). Default value is 95. IMWRITE_JPEG_PROGRESSIVE = 2, //!< Enable JPEG features, 0 or 1, default is False. IMWRITE_JPEG_OPTIMIZE = 3, //!< Enable JPEG features, 0 or 1, default is False. IMWRITE_JPEG_RST_INTERVAL = 4, //!< JPEG restart interval, 0 - 65535, default is 0 - no restart. IMWRITE_JPEG_LUMA_QUALITY = 5, //!< Separate luma quality level, 0 - 100, default is -1 - don't use. If JPEG_LIB_VERSION < 70, Not supported. IMWRITE_JPEG_CHROMA_QUALITY = 6, //!< Separate chroma quality level, 0 - 100, default is -1 - don't use. If JPEG_LIB_VERSION < 70, Not supported. IMWRITE_JPEG_SAMPLING_FACTOR = 7, //!< For JPEG, set sampling factor. See cv::ImwriteJPEGSamplingFactorParams. IMWRITE_PNG_COMPRESSION = 16, //!< For PNG, it can be the compression level from 0 to 9. A higher value means a smaller size and longer compression time. If specified, strategy is changed to IMWRITE_PNG_STRATEGY_DEFAULT (Z_DEFAULT_STRATEGY). Default value is 1 (best speed setting). IMWRITE_PNG_STRATEGY = 17, //!< One of cv::ImwritePNGFlags, default is IMWRITE_PNG_STRATEGY_RLE. IMWRITE_PNG_BILEVEL = 18, //!< Binary level PNG, 0 or 1, default is 0. IMWRITE_PXM_BINARY = 32, //!< For PPM, PGM, or PBM, it can be a binary format flag, 0 or 1. Default value is 1. IMWRITE_EXR_TYPE = (3 << 4) + 0 /* 48 */, //!< override EXR storage type (FLOAT (FP32) is default) IMWRITE_EXR_COMPRESSION = (3 << 4) + 1 /* 49 */, //!< override EXR compression type (ZIP_COMPRESSION = 3 is default) IMWRITE_EXR_DWA_COMPRESSION_LEVEL = (3 << 4) + 2 /* 50 */, //!< override EXR DWA compression level (45 is default) IMWRITE_WEBP_QUALITY = 64, //!< For WEBP, it can be a quality from 1 to 100 (the higher is the better). By default (without any parameter) and for quality above 100 the lossless compression is used. IMWRITE_HDR_COMPRESSION = (5 << 4) + 0 /* 80 */, //!< specify HDR compression IMWRITE_PAM_TUPLETYPE = 128,//!< For PAM, sets the TUPLETYPE field to the corresponding string value that is defined for the format IMWRITE_TIFF_RESUNIT = 256,//!< For TIFF, use to specify which DPI resolution unit to set; see libtiff documentation for valid values IMWRITE_TIFF_XDPI = 257,//!< For TIFF, use to specify the X direction DPI IMWRITE_TIFF_YDPI = 258,//!< For TIFF, use to specify the Y direction DPI IMWRITE_TIFF_COMPRESSION = 259,//!< For TIFF, use to specify the image compression scheme. See cv::ImwriteTiffCompressionFlags. Note, for images whose depth is CV_32F, only libtiff's SGILOG compression scheme is used. For other supported depths, the compression scheme can be specified by this flag; LZW compression is the default. IMWRITE_TIFF_ROWSPERSTRIP = 278,//!< For TIFF, use to specify the number of rows per strip. IMWRITE_TIFF_PREDICTOR = 317,//!< For TIFF, use to specify predictor. See cv::ImwriteTiffPredictorFlags. IMWRITE_JPEG2000_COMPRESSION_X1000 = 272,//!< For JPEG2000, use to specify the target compression rate (multiplied by 1000). The value can be from 0 to 1000. Default is 1000. IMWRITE_AVIF_QUALITY = 512,//!< For AVIF, it can be a quality between 0 and 100 (the higher the better). Default is 95. IMWRITE_AVIF_DEPTH = 513,//!< For AVIF, it can be 8, 10 or 12. If >8, it is stored/read as CV_32F. Default is 8. IMWRITE_AVIF_SPEED = 514 //!< For AVIF, it is between 0 (slowest) and (fastest). Default is 9. }; enum ImwriteJPEGSamplingFactorParams { IMWRITE_JPEG_SAMPLING_FACTOR_411 = 0x411111, //!< 4x1,1x1,1x1 IMWRITE_JPEG_SAMPLING_FACTOR_420 = 0x221111, //!< 2x2,1x1,1x1(Default) IMWRITE_JPEG_SAMPLING_FACTOR_422 = 0x211111, //!< 2x1,1x1,1x1 IMWRITE_JPEG_SAMPLING_FACTOR_440 = 0x121111, //!< 1x2,1x1,1x1 IMWRITE_JPEG_SAMPLING_FACTOR_444 = 0x111111 //!< 1x1,1x1,1x1(No subsampling) }; enum ImwriteTiffCompressionFlags { IMWRITE_TIFF_COMPRESSION_NONE = 1, //!< dump mode IMWRITE_TIFF_COMPRESSION_CCITTRLE = 2, //!< CCITT modified Huffman RLE IMWRITE_TIFF_COMPRESSION_CCITTFAX3 = 3, //!< CCITT Group 3 fax encoding IMWRITE_TIFF_COMPRESSION_CCITT_T4 = 3, //!< CCITT T.4 (TIFF 6 name) IMWRITE_TIFF_COMPRESSION_CCITTFAX4 = 4, //!< CCITT Group 4 fax encoding IMWRITE_TIFF_COMPRESSION_CCITT_T6 = 4, //!< CCITT T.6 (TIFF 6 name) IMWRITE_TIFF_COMPRESSION_LZW = 5, //!< Lempel-Ziv & Welch IMWRITE_TIFF_COMPRESSION_OJPEG = 6, //!< !6.0 JPEG IMWRITE_TIFF_COMPRESSION_JPEG = 7, //!< %JPEG DCT compression IMWRITE_TIFF_COMPRESSION_T85 = 9, //!< !TIFF/FX T.85 JBIG compression IMWRITE_TIFF_COMPRESSION_T43 = 10, //!< !TIFF/FX T.43 colour by layered JBIG compression IMWRITE_TIFF_COMPRESSION_NEXT = 32766, //!< NeXT 2-bit RLE IMWRITE_TIFF_COMPRESSION_CCITTRLEW = 32771, //!< #1 w/ word alignment IMWRITE_TIFF_COMPRESSION_PACKBITS = 32773, //!< Macintosh RLE IMWRITE_TIFF_COMPRESSION_THUNDERSCAN = 32809, //!< ThunderScan RLE IMWRITE_TIFF_COMPRESSION_IT8CTPAD = 32895, //!< IT8 CT w/padding IMWRITE_TIFF_COMPRESSION_IT8LW = 32896, //!< IT8 Linework RLE IMWRITE_TIFF_COMPRESSION_IT8MP = 32897, //!< IT8 Monochrome picture IMWRITE_TIFF_COMPRESSION_IT8BL = 32898, //!< IT8 Binary line art IMWRITE_TIFF_COMPRESSION_PIXARFILM = 32908, //!< Pixar companded 10bit LZW IMWRITE_TIFF_COMPRESSION_PIXARLOG = 32909, //!< Pixar companded 11bit ZIP IMWRITE_TIFF_COMPRESSION_DEFLATE = 32946, //!< Deflate compression, legacy tag IMWRITE_TIFF_COMPRESSION_ADOBE_DEFLATE = 8, //!< Deflate compression, as recognized by Adobe IMWRITE_TIFF_COMPRESSION_DCS = 32947, //!< Kodak DCS encoding IMWRITE_TIFF_COMPRESSION_JBIG = 34661, //!< ISO JBIG IMWRITE_TIFF_COMPRESSION_SGILOG = 34676, //!< SGI Log Luminance RLE IMWRITE_TIFF_COMPRESSION_SGILOG24 = 34677, //!< SGI Log 24-bit packed IMWRITE_TIFF_COMPRESSION_JP2000 = 34712, //!< Leadtools JPEG2000 IMWRITE_TIFF_COMPRESSION_LERC = 34887, //!< ESRI Lerc codec: https://github.com/Esri/lerc IMWRITE_TIFF_COMPRESSION_LZMA = 34925, //!< LZMA2 IMWRITE_TIFF_COMPRESSION_ZSTD = 50000, //!< ZSTD: WARNING not registered in Adobe-maintained registry IMWRITE_TIFF_COMPRESSION_WEBP = 50001, //!< WEBP: WARNING not registered in Adobe-maintained registry IMWRITE_TIFF_COMPRESSION_JXL = 50002 //!< JPEGXL: WARNING not registered in Adobe-maintained registry }; enum ImwriteTiffPredictorFlags { IMWRITE_TIFF_PREDICTOR_NONE = 1, //!< no prediction scheme used IMWRITE_TIFF_PREDICTOR_HORIZONTAL = 2, //!< horizontal differencing IMWRITE_TIFF_PREDICTOR_FLOATINGPOINT = 3 //!< floating point predictor }; enum ImwriteEXRTypeFlags { /*IMWRITE_EXR_TYPE_UNIT = 0, //!< not supported */ IMWRITE_EXR_TYPE_HALF = 1, //!< store as HALF (FP16) IMWRITE_EXR_TYPE_FLOAT = 2 //!< store as FP32 (default) }; enum ImwriteEXRCompressionFlags { IMWRITE_EXR_COMPRESSION_NO = 0, //!< no compression IMWRITE_EXR_COMPRESSION_RLE = 1, //!< run length encoding IMWRITE_EXR_COMPRESSION_ZIPS = 2, //!< zlib compression, one scan line at a time IMWRITE_EXR_COMPRESSION_ZIP = 3, //!< zlib compression, in blocks of 16 scan lines IMWRITE_EXR_COMPRESSION_PIZ = 4, //!< piz-based wavelet compression IMWRITE_EXR_COMPRESSION_PXR24 = 5, //!< lossy 24-bit float compression IMWRITE_EXR_COMPRESSION_B44 = 6, //!< lossy 4-by-4 pixel block compression, fixed compression rate IMWRITE_EXR_COMPRESSION_B44A = 7, //!< lossy 4-by-4 pixel block compression, flat fields are compressed more IMWRITE_EXR_COMPRESSION_DWAA = 8, //!< lossy DCT based compression, in blocks of 32 scanlines. More efficient for partial buffer access. Supported since OpenEXR 2.2.0. IMWRITE_EXR_COMPRESSION_DWAB = 9, //!< lossy DCT based compression, in blocks of 256 scanlines. More efficient space wise and faster to decode full frames than DWAA_COMPRESSION. Supported since OpenEXR 2.2.0. }; //! Imwrite PNG specific flags used to tune the compression algorithm. /** These flags will be modify the way of PNG image compression and will be passed to the underlying zlib processing stage. - The effect of IMWRITE_PNG_STRATEGY_FILTERED is to force more Huffman coding and less string matching; it is somewhat intermediate between IMWRITE_PNG_STRATEGY_DEFAULT and IMWRITE_PNG_STRATEGY_HUFFMAN_ONLY. - IMWRITE_PNG_STRATEGY_RLE is designed to be almost as fast as IMWRITE_PNG_STRATEGY_HUFFMAN_ONLY, but give better compression for PNG image data. - The strategy parameter only affects the compression ratio but not the correctness of the compressed output even if it is not set appropriately. - IMWRITE_PNG_STRATEGY_FIXED prevents the use of dynamic Huffman codes, allowing for a simpler decoder for special applications. */ enum ImwritePNGFlags { IMWRITE_PNG_STRATEGY_DEFAULT = 0, //!< Use this value for normal data. IMWRITE_PNG_STRATEGY_FILTERED = 1, //!< Use this value for data produced by a filter (or predictor).Filtered data consists mostly of small values with a somewhat random distribution. In this case, the compression algorithm is tuned to compress them better. IMWRITE_PNG_STRATEGY_HUFFMAN_ONLY = 2, //!< Use this value to force Huffman encoding only (no string match). IMWRITE_PNG_STRATEGY_RLE = 3, //!< Use this value to limit match distances to one (run-length encoding). IMWRITE_PNG_STRATEGY_FIXED = 4 //!< Using this value prevents the use of dynamic Huffman codes, allowing for a simpler decoder for special applications. }; //! Imwrite PAM specific tupletype flags used to define the 'TUPLETYPE' field of a PAM file. enum ImwritePAMFlags { IMWRITE_PAM_FORMAT_NULL = 0, IMWRITE_PAM_FORMAT_BLACKANDWHITE = 1, IMWRITE_PAM_FORMAT_GRAYSCALE = 2, IMWRITE_PAM_FORMAT_GRAYSCALE_ALPHA = 3, IMWRITE_PAM_FORMAT_RGB = 4, IMWRITE_PAM_FORMAT_RGB_ALPHA = 5 }; //! Imwrite HDR specific values for IMWRITE_HDR_COMPRESSION parameter key enum ImwriteHDRCompressionFlags { IMWRITE_HDR_COMPRESSION_NONE = 0, IMWRITE_HDR_COMPRESSION_RLE = 1 }; //! @} imgcodecs_flags /** @brief Loads an image from a file. @anchor imread The function imread loads an image from the specified file and returns it. If the image cannot be read (because of missing file, improper permissions, unsupported or invalid format), the function returns an empty matrix ( Mat::data==NULL ). Currently, the following file formats are supported: - Windows bitmaps - \*.bmp, \*.dib (always supported) - JPEG files - \*.jpeg, \*.jpg, \*.jpe (see the *Note* section) - JPEG 2000 files - \*.jp2 (see the *Note* section) - Portable Network Graphics - \*.png (see the *Note* section) - WebP - \*.webp (see the *Note* section) - AVIF - \*.avif (see the *Note* section) - Portable image format - \*.pbm, \*.pgm, \*.ppm \*.pxm, \*.pnm (always supported) - PFM files - \*.pfm (see the *Note* section) - Sun rasters - \*.sr, \*.ras (always supported) - TIFF files - \*.tiff, \*.tif (see the *Note* section) - OpenEXR Image files - \*.exr (see the *Note* section) - Radiance HDR - \*.hdr, \*.pic (always supported) - Raster and Vector geospatial data supported by GDAL (see the *Note* section) @note - The function determines the type of an image by the content, not by the file extension. - In the case of color images, the decoded images will have the channels stored in **B G R** order. - When using IMREAD_GRAYSCALE, the codec's internal grayscale conversion will be used, if available. Results may differ to the output of cvtColor() - On Microsoft Windows\* OS and MacOSX\*, the codecs shipped with an OpenCV image (libjpeg, libpng, libtiff, and libjasper) are used by default. So, OpenCV can always read JPEGs, PNGs, and TIFFs. On MacOSX, there is also an option to use native MacOSX image readers. But beware that currently these native image loaders give images with different pixel values because of the color management embedded into MacOSX. - On Linux\*, BSD flavors and other Unix-like open-source operating systems, OpenCV looks for codecs supplied with an OS image. Install the relevant packages (do not forget the development files, for example, "libjpeg-dev", in Debian\* and Ubuntu\*) to get the codec support or turn on the OPENCV_BUILD_3RDPARTY_LIBS flag in CMake. - In the case you set *WITH_GDAL* flag to true in CMake and @ref IMREAD_LOAD_GDAL to load the image, then the [GDAL](http://www.gdal.org) driver will be used in order to decode the image, supporting the following formats: [Raster](http://www.gdal.org/formats_list.html), [Vector](http://www.gdal.org/ogr_formats.html). - If EXIF information is embedded in the image file, the EXIF orientation will be taken into account and thus the image will be rotated accordingly except if the flags @ref IMREAD_IGNORE_ORIENTATION or @ref IMREAD_UNCHANGED are passed. - Use the IMREAD_UNCHANGED flag to keep the floating point values from PFM image. - By default number of pixels must be less than 2^30. Limit can be set using system variable OPENCV_IO_MAX_IMAGE_PIXELS @param filename Name of file to be loaded. @param flags Flag that can take values of cv::ImreadModes */ CV_EXPORTS_W Mat imread( const String& filename, int flags = IMREAD_COLOR_BGR ); /** @brief Loads an image from a file. This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts and the return value. @param filename Name of file to be loaded. @param dst object in which the image will be loaded. @param flags Flag that can take values of cv::ImreadModes @note The image passing through the img parameter can be pre-allocated. The memory is reused if the shape and the type match with the load image. */ CV_EXPORTS_W void imread( const String& filename, OutputArray dst, int flags = IMREAD_COLOR_BGR ); /** @brief Loads a multi-page image from a file. The function imreadmulti loads a multi-page image from the specified file into a vector of Mat objects. @param filename Name of file to be loaded. @param mats A vector of Mat objects holding each page. @param flags Flag that can take values of cv::ImreadModes, default with cv::IMREAD_ANYCOLOR. @sa cv::imread */ CV_EXPORTS_W bool imreadmulti(const String& filename, CV_OUT std::vector& mats, int flags = IMREAD_ANYCOLOR); /** @brief Loads images of a multi-page image from a file. The function imreadmulti loads a specified range from a multi-page image from the specified file into a vector of Mat objects. @param filename Name of file to be loaded. @param mats A vector of Mat objects holding each page. @param start Start index of the image to load @param count Count number of images to load @param flags Flag that can take values of cv::ImreadModes, default with cv::IMREAD_ANYCOLOR. @sa cv::imread */ CV_EXPORTS_W bool imreadmulti(const String& filename, CV_OUT std::vector& mats, int start, int count, int flags = IMREAD_ANYCOLOR); /** @brief Returns the number of images inside the given file The function imcount will return the number of pages in a multi-page image, or 1 for single-page images @param filename Name of file to be loaded. @param flags Flag that can take values of cv::ImreadModes, default with cv::IMREAD_ANYCOLOR. */ CV_EXPORTS_W size_t imcount(const String& filename, int flags = IMREAD_ANYCOLOR); /** @brief Saves an image to a specified file. The function imwrite saves the image to the specified file. The image format is chosen based on the filename extension (see cv::imread for the list of extensions). In general, only 8-bit unsigned (CV_8U) single-channel or 3-channel (with 'BGR' channel order) images can be saved using this function, with these exceptions: - With OpenEXR encoder, only 32-bit float (CV_32F) images can be saved. - 8-bit unsigned (CV_8U) images are not supported. - With Radiance HDR encoder, non 64-bit float (CV_64F) images can be saved. - All images will be converted to 32-bit float (CV_32F). - With JPEG 2000 encoder, 8-bit unsigned (CV_8U) and 16-bit unsigned (CV_16U) images can be saved. - With PAM encoder, 8-bit unsigned (CV_8U) and 16-bit unsigned (CV_16U) images can be saved. - With PNG encoder, 8-bit unsigned (CV_8U) and 16-bit unsigned (CV_16U) images can be saved. - PNG images with an alpha channel can be saved using this function. To do this, create 8-bit (or 16-bit) 4-channel image BGRA, where the alpha channel goes last. Fully transparent pixels should have alpha set to 0, fully opaque pixels should have alpha set to 255/65535 (see the code sample below). - With PGM/PPM encoder, 8-bit unsigned (CV_8U) and 16-bit unsigned (CV_16U) images can be saved. - With TIFF encoder, 8-bit unsigned (CV_8U), 16-bit unsigned (CV_16U), 32-bit float (CV_32F) and 64-bit float (CV_64F) images can be saved. - Multiple images (vector of Mat) can be saved in TIFF format (see the code sample below). - 32-bit float 3-channel (CV_32FC3) TIFF images will be saved using the LogLuv high dynamic range encoding (4 bytes per pixel) If the image format is not supported, the image will be converted to 8-bit unsigned (CV_8U) and saved that way. If the format, depth or channel order is different, use Mat::convertTo and cv::cvtColor to convert it before saving. Or, use the universal FileStorage I/O functions to save the image to XML or YAML format. The sample below shows how to create a BGRA image, how to set custom compression parameters and save it to a PNG file. It also demonstrates how to save multiple images in a TIFF file: @include snippets/imgcodecs_imwrite.cpp @param filename Name of the file. @param img (Mat or vector of Mat) Image or Images to be saved. @param params Format-specific parameters encoded as pairs (paramId_1, paramValue_1, paramId_2, paramValue_2, ... .) see cv::ImwriteFlags */ CV_EXPORTS_W bool imwrite( const String& filename, InputArray img, const std::vector& params = std::vector()); //! @brief multi-image overload for bindings CV_WRAP static inline bool imwritemulti(const String& filename, InputArrayOfArrays img, const std::vector& params = std::vector()) { return imwrite(filename, img, params); } /** @brief Reads an image from a buffer in memory. The function imdecode reads an image from the specified buffer in the memory. If the buffer is too short or contains invalid data, the function returns an empty matrix ( Mat::data==NULL ). See cv::imread for the list of supported formats and flags description. @note In the case of color images, the decoded images will have the channels stored in **B G R** order. @param buf Input array or vector of bytes. @param flags The same flags as in cv::imread, see cv::ImreadModes. */ CV_EXPORTS_W Mat imdecode( InputArray buf, int flags ); /** @overload @param buf Input array or vector of bytes. @param flags The same flags as in cv::imread, see cv::ImreadModes. @param dst The optional output placeholder for the decoded matrix. It can save the image reallocations when the function is called repeatedly for images of the same size. In case of decoder failure the function returns empty cv::Mat object, but does not release user-provided dst buffer. */ CV_EXPORTS Mat imdecode( InputArray buf, int flags, Mat* dst); /** @brief Reads a multi-page image from a buffer in memory. The function imdecodemulti reads a multi-page image from the specified buffer in the memory. If the buffer is too short or contains invalid data, the function returns false. See cv::imreadmulti for the list of supported formats and flags description. @note In the case of color images, the decoded images will have the channels stored in **B G R** order. @param buf Input array or vector of bytes. @param flags The same flags as in cv::imread, see cv::ImreadModes. @param mats A vector of Mat objects holding each page, if more than one. @param range A continuous selection of pages. */ CV_EXPORTS_W bool imdecodemulti(InputArray buf, int flags, CV_OUT std::vector& mats, const cv::Range& range = Range::all()); /** @brief Encodes an image into a memory buffer. The function imencode compresses the image and stores it in the memory buffer that is resized to fit the result. See cv::imwrite for the list of supported formats and flags description. @param ext File extension that defines the output format. Must include a leading period. @param img Image to be written. @param buf Output buffer resized to fit the compressed image. @param params Format-specific parameters. See cv::imwrite and cv::ImwriteFlags. */ CV_EXPORTS_W bool imencode( const String& ext, InputArray img, CV_OUT std::vector& buf, const std::vector& params = std::vector()); /** @brief Checks if the specified image file can be decoded by OpenCV. The function haveImageReader checks if OpenCV is capable of reading the specified file. This can be useful for verifying support for a given image format before attempting to load an image. @param filename The name of the file to be checked. @return true if an image reader for the specified file is available and the file can be opened, false otherwise. @note The function checks the availability of image codecs that are either built into OpenCV or dynamically loaded. It does not check for the actual existence of the file but rather the ability to read the specified file type. If the file cannot be opened or the format is unsupported, the function will return false. @sa cv::haveImageWriter, cv::imread, cv::imdecode */ CV_EXPORTS_W bool haveImageReader( const String& filename ); /** @brief Checks if the specified image file or specified file extension can be encoded by OpenCV. The function haveImageWriter checks if OpenCV is capable of writing images with the specified file extension. This can be useful for verifying support for a given image format before attempting to save an image. @param filename The name of the file or the file extension (e.g., ".jpg", ".png"). It is recommended to provide the file extension rather than the full file name. @return true if an image writer for the specified extension is available, false otherwise. @note The function checks the availability of image codecs that are either built into OpenCV or dynamically loaded. It does not check for the actual existence of the file but rather the ability to write files of the given type. @sa cv::haveImageReader, cv::imwrite, cv::imencode */ CV_EXPORTS_W bool haveImageWriter( const String& filename ); /** @brief To read multi-page images on demand The ImageCollection class provides iterator API to read multi-page images on demand. Create iterator to the collection of the images and iterate over the collection. Decode the necessary page with operator*. The performance of page decoding is O(1) if collection is increment sequentially. If the user wants to access random page, then the time Complexity is O(n) because the collection has to be reinitialized every time in order to go to the correct page. However, the intermediate pages are not decoded during the process, so typically it's quite fast. This is required because multi-page codecs does not support going backwards. After decoding the one page, it is stored inside the collection cache. Hence, trying to get Mat object from already decoded page is O(1). If you need memory, you can use .releaseCache() method to release cached index. The space complexity is O(n) if all pages are decoded into memory. The user is able to decode and release images on demand. */ class CV_EXPORTS ImageCollection { public: struct CV_EXPORTS iterator { iterator(ImageCollection* col); iterator(ImageCollection* col, int end); Mat& operator*(); Mat* operator->(); iterator& operator++(); iterator operator++(int); friend bool operator== (const iterator& a, const iterator& b) { return a.m_curr == b.m_curr; } friend bool operator!= (const iterator& a, const iterator& b) { return a.m_curr != b.m_curr; } private: ImageCollection* m_pCollection; int m_curr; }; ImageCollection(); ImageCollection(const String& filename, int flags); void init(const String& img, int flags); size_t size() const; const Mat& at(int index); const Mat& operator[](int index); void releaseCache(int index); iterator begin(); iterator end(); class Impl; Ptr getImpl(); protected: Ptr pImpl; }; //! @} imgcodecs } // cv #endif //OPENCV_IMGCODECS_HPP