/*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*/ #include "jpeg_exif.hpp" namespace { class ExifParsingError { }; } namespace cv { /** * @brief ExifReader constructor */ ExifReader::ExifReader(std::string filename) : m_filename(filename) { } /** * @brief ExifReader destructor */ ExifReader::~ExifReader() { } /** * @brief Parsing the jpeg file and prepare (internally) exif directory structure * @return true if parsing was successful and exif information exists in JpegReader object * false in case of unsuccessful parsing */ bool ExifReader::parse() { try { m_exif = getExif(); if( !m_exif.empty() ) { return true; } return false; } catch (ExifParsingError&) { return false; } } /** * @brief Get tag value by tag number * * @param [in] tag The tag number * * @return ExifEntru_t structure. Caller has to know what tag it calls in order to extract proper field from the structure ExifEntry_t * */ ExifEntry_t ExifReader::getTag(const ExifTagName tag) { ExifEntry_t entry; std::map::iterator it = m_exif.find(tag); if( it != m_exif.end() ) { entry = it->second; } return entry; } /** * @brief Get exif directory structure contained in jpeg file (if any) * This is internal function and is not exposed to client * * @return Map where key is tag number and value is ExifEntry_t structure */ std::map ExifReader::getExif() { const size_t markerSize = 2; const size_t offsetToTiffHeader = 6; //bytes from Exif size field to the first TIFF header unsigned char appMarker[markerSize]; m_exif.erase( m_exif.begin(), m_exif.end() ); size_t count; FILE* f = fopen( m_filename.c_str(), "rb" ); if( !f ) { return m_exif; //Until this moment the map is empty } bool exifFound = false; while( ( !feof( f ) ) && !exifFound ) { count = fread( appMarker, sizeof(unsigned char), markerSize, f ); if( count < markerSize ) { break; } unsigned char marker = appMarker[1]; size_t bytesToSkip; size_t exifSize; switch( marker ) { //For all the markers just skip bytes in file pointed by followed two bytes (field size) case SOF0: case SOF2: case DHT: case DQT: case DRI: case SOS: case RST0: case RST1: case RST2: case RST3: case RST4: case RST5: case RST6: case RST7: case APP0: case APP2: case APP3: case APP4: case APP5: case APP6: case APP7: case APP8: case APP9: case APP10: case APP11: case APP12: case APP13: case APP14: case APP15: case COM: bytesToSkip = getFieldSize( f ); fseek( f, static_cast( bytesToSkip - markerSize ), SEEK_CUR ); break; //SOI and EOI don't have the size field after the marker case SOI: case EOI: break; case APP1: //actual Exif Marker exifSize = getFieldSize(f); m_data.resize( exifSize - offsetToTiffHeader ); fseek(f, static_cast( offsetToTiffHeader ), SEEK_CUR); count = fread( &m_data[0], sizeof( unsigned char ), exifSize - offsetToTiffHeader, f ); exifFound = true; break; default: //No other markers are expected according to standard. May be a signal of error break; } } fclose(f); if( !exifFound ) { return m_exif; } parseExif(); return m_exif; } /** * @brief Get the size of exif field (required to properly ready whole exif from the file) * This is internal function and is not exposed to client * * @return size of exif field in the file */ size_t ExifReader::getFieldSize (FILE* f) const { unsigned char fieldSize[2]; size_t count = fread ( fieldSize, sizeof( char ), 2, f ); if (count < 2) { return 0; } return ( fieldSize[0] << 8 ) + fieldSize[1]; } /** * @brief Filling m_exif member with exif directory elements * This is internal function and is not exposed to client * * @return The function doesn't return any value. In case of unsiccessful parsing * the m_exif member is not filled up */ void ExifReader::parseExif() { m_format = getFormat(); if( !checkTagMark() ) { return; } uint32_t offset = getStartOffset(); size_t numEntry = getNumDirEntry(); offset += 2; //go to start of tag fields for( size_t entry = 0; entry < numEntry; entry++ ) { ExifEntry_t exifEntry = parseExifEntry( offset ); m_exif.insert( std::make_pair( exifEntry.tag, exifEntry ) ); offset += tiffFieldSize; } } /** * @brief Get endianness of exif information * This is internal function and is not exposed to client * * @return INTEL, MOTO or NONE */ Endianess_t ExifReader::getFormat() const { if( m_data[0] != m_data[1] ) { return NONE; } if( m_data[0] == 'I' ) { return INTEL; } if( m_data[0] == 'M' ) { return MOTO; } return NONE; } /** * @brief Checking whether Tag Mark (0x002A) correspond to one contained in the Jpeg file * This is internal function and is not exposed to client * * @return true if tag mark equals 0x002A, false otherwise */ bool ExifReader::checkTagMark() const { uint16_t tagMark = getU16( 2 ); if( tagMark != tagMarkRequired ) { return false; } return true; } /** * @brief The utility function for extracting actual offset exif IFD0 info is started from * This is internal function and is not exposed to client * * @return offset of IFD0 field */ uint32_t ExifReader::getStartOffset() const { return getU32( 4 ); } /** * @brief Get the number of Directory Entries in Jpeg file * * @return The number of directory entries */ size_t ExifReader::getNumDirEntry() const { return getU16( offsetNumDir ); } /** * @brief Parsing particular entry in exif directory * This is internal function and is not exposed to client * * Entries are divided into 12-bytes blocks each * Each block corresponds the following structure: * * +------+-------------+-------------------+------------------------+ * | Type | Data format | Num of components | Data or offset to data | * +======+=============+===================+========================+ * | TTTT | ffff | NNNNNNNN | DDDDDDDD | * +------+-------------+-------------------+------------------------+ * * Details can be found here: http://www.media.mit.edu/pia/Research/deepview/exif.html * * @param [in] offset Offset to entry in bytes inside raw exif data * @return ExifEntry_t structure which corresponds to particular entry * */ ExifEntry_t ExifReader::parseExifEntry(const size_t offset) { ExifEntry_t entry; uint16_t tagNum = getExifTag( offset ); entry.tag = tagNum; switch( tagNum ) { case IMAGE_DESCRIPTION: entry.field_str = getString( offset ); break; case MAKE: entry.field_str = getString( offset ); break; case MODEL: entry.field_str = getString( offset ); break; case ORIENTATION: entry.field_u16 = getOrientation( offset ); break; case XRESOLUTION: entry.field_u_rational = getResolution( offset ); break; case YRESOLUTION: entry.field_u_rational = getResolution( offset ); break; case RESOLUTION_UNIT: entry.field_u16 = getResolutionUnit( offset ); break; case SOFTWARE: entry.field_str = getString( offset ); break; case DATE_TIME: entry.field_str = getString( offset ); break; case WHITE_POINT: entry.field_u_rational = getWhitePoint( offset ); break; case PRIMARY_CHROMATICIES: entry.field_u_rational = getPrimaryChromaticies( offset ); break; case Y_CB_CR_COEFFICIENTS: entry.field_u_rational = getYCbCrCoeffs( offset ); break; case Y_CB_CR_POSITIONING: entry.field_u16 = getYCbCrPos( offset ); break; case REFERENCE_BLACK_WHITE: entry.field_u_rational = getRefBW( offset ); break; case COPYRIGHT: entry.field_str = getString( offset ); break; case EXIF_OFFSET: break; default: entry.tag = INVALID_TAG; break; } return entry; } /** * @brief Get tag number from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return tag number */ uint16_t ExifReader::getExifTag(const size_t offset) const { return getU16( offset ); } /** * @brief Get string information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return string value */ std::string ExifReader::getString(const size_t offset) const { size_t size = getU32( offset + 4 ); size_t dataOffset = 8; // position of data in the field if( size > maxDataSize ) { dataOffset = getU32( offset + 8 ); } std::vector::const_iterator it = m_data.begin() + dataOffset; std::string result( it, it + size ); //copy vector content into result return result; } /** * @brief Get unsigned short data from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return Unsigned short data */ uint16_t ExifReader::getU16(const size_t offset) const { if (offset + 1 >= m_data.size()) throw ExifParsingError(); if( m_format == INTEL ) { return m_data[offset] + ( m_data[offset + 1] << 8 ); } return ( m_data[offset] << 8 ) + m_data[offset + 1]; } /** * @brief Get unsigned 32-bit data from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return Unsigned 32-bit data */ uint32_t ExifReader::getU32(const size_t offset) const { if (offset + 3 >= m_data.size()) throw ExifParsingError(); if( m_format == INTEL ) { return m_data[offset] + ( m_data[offset + 1] << 8 ) + ( m_data[offset + 2] << 16 ) + ( m_data[offset + 3] << 24 ); } return ( m_data[offset] << 24 ) + ( m_data[offset + 1] << 16 ) + ( m_data[offset + 2] << 8 ) + m_data[offset + 3]; } /** * @brief Get unsigned rational data from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return Unsigned rational data * * "rational" means a fractional value, it contains 2 signed/unsigned long integer value, * and the first represents the numerator, the second, the denominator. */ u_rational_t ExifReader::getURational(const size_t offset) const { u_rational_t result; uint32_t numerator = getU32( offset ); uint32_t denominator = getU32( offset + 4 ); return std::make_pair( numerator, denominator ); } /** * @brief Get orientation information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return orientation number */ uint16_t ExifReader::getOrientation(const size_t offset) const { return getU16( offset + 8 ); } /** * @brief Get resolution information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return resolution value */ std::vector ExifReader::getResolution(const size_t offset) const { std::vector result; uint32_t rationalOffset = getU32( offset + 8 ); result.push_back( getURational( rationalOffset ) ); return result; } /** * @brief Get resolution unit from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return resolution unit value */ uint16_t ExifReader::getResolutionUnit(const size_t offset) const { return getU16( offset + 8 ); } /** * @brief Get White Point information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return White Point value * * If the image uses CIE Standard Illumination D65(known as international * standard of 'daylight'), the values are '3127/10000,3290/10000'. */ std::vector ExifReader::getWhitePoint(const size_t offset) const { std::vector result; uint32_t rationalOffset = getU32( offset + 8 ); result.push_back( getURational( rationalOffset ) ); result.push_back( getURational( rationalOffset + 8 ) ); return result; } /** * @brief Get Primary Chromaticies information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return vector with primary chromaticies values * */ std::vector ExifReader::getPrimaryChromaticies(const size_t offset) const { std::vector result; uint32_t rationalOffset = getU32( offset + 8 ); for( size_t i = 0; i < primaryChromaticiesComponents; i++ ) { result.push_back( getURational( rationalOffset ) ); rationalOffset += 8; } return result; } /** * @brief Get YCbCr Coefficients information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return vector with YCbCr coefficients values * */ std::vector ExifReader::getYCbCrCoeffs(const size_t offset) const { std::vector result; uint32_t rationalOffset = getU32( offset + 8 ); for( size_t i = 0; i < ycbcrCoeffs; i++ ) { result.push_back( getURational( rationalOffset ) ); rationalOffset += 8; } return result; } /** * @brief Get YCbCr Positioning information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return vector with YCbCr positioning value * */ uint16_t ExifReader::getYCbCrPos(const size_t offset) const { return getU16( offset + 8 ); } /** * @brief Get Reference Black&White point information from raw exif data * This is internal function and is not exposed to client * @param [in] offset Offset to entry in bytes inside raw exif data * @return vector with reference BW points * * In case of YCbCr format, first 2 show black/white of Y, next 2 are Cb, * last 2 are Cr. In case of RGB format, first 2 show black/white of R, * next 2 are G, last 2 are B. * */ std::vector ExifReader::getRefBW(const size_t offset) const { const size_t rationalFieldSize = 8; std::vector result; uint32_t rationalOffset = getU32( offset + rationalFieldSize ); for( size_t i = 0; i < refBWComponents; i++ ) { result.push_back( getURational( rationalOffset ) ); rationalOffset += rationalFieldSize; } return result; } } //namespace cv