// ***************************************************************** -*- C++ -*- /* * Copyright (C) 2004 Andreas Huggel * * This program is part of the Exiv2 distribution. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /*! @file exif.hpp @brief Encoding and decoding of %Exif data @version $Name: $ $Revision: 1.10 $ @author Andreas Huggel (ahu) ahuggel@gmx.net @date 09-Jan-04, ahu: created */ #ifndef EXIF_HPP_ #define EXIF_HPP_ // ***************************************************************************** // included header files #include "tags.hpp" // + standard includes #include #include #include #include // ***************************************************************************** // namespace extensions //! Provides classes and functions to encode and decode %Exif data. namespace Exif { // ***************************************************************************** // class declarations class ExifData; // ***************************************************************************** // class definitions /*! @brief Helper class to access JPEG images Todo: define and implement write support */ class JpegImage { // Copying not allowed JpegImage(const JpegImage& rhs); // Assignment not allowed JpegImage& operator=(const JpegImage& rhs); public: //! Default constructor JpegImage(); //! Default destructor ~JpegImage(); /*! @brief Checks if the stream is the beginning of a JPEG image @param is Input stream to test @return true if the input stream starts the JPEG SOI marker. The stream is advanced by two characters in this case.
false if the input stream does not begin with the JPEG SOI marker. The stream is not advanced in this case.
false if reading the first two bytes from the stream fails. Consult the stream state for more information. In this case, the stream may or may not have been advanced by 1 or 2 characters. */ static bool isJpeg(std::istream& is); /*! @brief Reads the %Exif data from the file path into the internal data buffer. @param path Path to the file @return 0 if successful
-1 if the file cannot be opened or
the return code of readExifData(std::istream& is) if the call to this function fails */ int readExifData(const std::string& path); /*! @brief Reads the %Exif data from the stream into the internal data buffer. @param is Input stream to read from @return 0 if successful
1 if reading from the stream failed. Consult the stream state for more information.
2 if the stream does not contain a JPEG image
3 if the APP1 marker was not found
4 if the APP1 field does not contain %Exif data */ int readExifData(std::istream& is); //! @name Accessors //@{ //! Returns the size of the %Exif data buffer long sizeExifData() const { return sizeExifData_; } //! Returns the offset of the %Exif data buffer from SOI long offsetExifData() const { return offsetExifData_; } //! Returns a read-only pointer to the %Exif data buffer const char* exifData() const { return exifData_; } //@} private: static const uint16 soi_; // SOI marker static const uint16 app1_; // APP1 marker static const char exifId_[]; // Exif identifier long sizeExifData_; // Size of the Exif data buffer long offsetExifData_; // Offset from SOI char* exifData_; // Exif data buffer }; // class JpegImage //! Type to express the byte order (little or big endian) enum ByteOrder { littleEndian, bigEndian }; //! Helper class modelling the Tiff header structure. class TiffHeader { public: //! Default constructor. TiffHeader(); //! Read the Tiff header from a data buffer. Returns 0 if successful. int read(const char* buf); /*! @brief Write the Tiff header into buf as a data string, return number of bytes copied. */ long copy(char* buf) const; //! Return the lengths of the Tiff header in bytes. long size() const { return 8; } //! @name Accessors //@{ //! Return the byte order (little or big endian). ByteOrder byteOrder() const { return byteOrder_; } //! Return the tag value. uint16 tag() const { return tag_; } /*! @brief Return the offset to IFD0 from the start of the Tiff header. The offset is 0x00000008 if IFD0 begins immediately after the Tiff header. */ uint32 offset() const { return offset_; } //@} private: ByteOrder byteOrder_; uint16 tag_; uint32 offset_; }; // class TiffHeader /*! @brief Common interface for all values. The interface provides a uniform way to access values independent from their actual C++ type for simple tasks like reading the values from a string or data buffer. For other tasks, like modifying values you may need to downcast it to the actual subclass of %Value so that you can access the subclass specific interface. */ class Value { public: //! Constructor, taking a type id to initialize the base class with explicit Value(TypeId typeId) : type_(typeId) {} //! Virtual destructor. virtual ~Value() {} /*! @brief Read the value from a character buffer. @param buf Pointer to the data buffer to read from @param len Number of bytes in the data buffer @param byteOrder Applicable byte order (little or big endian). */ virtual void read(const char* buf, long len, ByteOrder byteOrder) =0; /*! @brief Set the value from a string buffer. The format of the string corresponds to that of the write() method, i.e., a string obtained through the write() method can be read by this function. @param buf The string to read from. */ virtual void read(const std::string& buf) =0; /*! @brief Write value to a character data buffer. The user must ensure that the buffer has enough memory. Otherwise the call results in undefined behaviour. @param buf Data buffer to write to. @param byteOrder Applicable byte order (little or big endian). @return Number of characters written. */ virtual long copy(char* buf, ByteOrder byteOrder) const =0; //! Return the number of components of the value virtual long count() const =0; //! Return the size of the value in bytes virtual long size() const =0; /*! @brief Return a pointer to a copy of itself (deep copy). The caller owns this copy and is responsible to delete it! */ virtual Value* clone() const =0; /*! @brief Write the value to an output stream. You do not usually have to use this function; it is used for the implementation of the output operator for %Value, operator<<(std::ostream &os, const Value &value). */ virtual std::ostream& write(std::ostream& os) const =0; /*! @brief Convert the n-th component of the value to a long. The behaviour of this method may be undefined if there is no n-th component. @return The converted value. */ virtual long toLong(long n =0) const =0; //! Return the type identifier (Exif data format type). TypeId typeId() const { return TypeId(type_); } /*! @brief A (simple) factory to create a Value type. @param typeId Type of the value. @return Pointer to the newly created Value. The caller owns this copy and is responsible to delete it! */ static Value* create(TypeId typeId); private: const uint16 type_; //!< Type of the data }; // class Value //! Output operator for Value types inline std::ostream& operator<<(std::ostream& os, const Value& value) { return value.write(os); } //! %Value for an undefined data type. class DataValue : public Value { public: //! Default constructor. DataValue(TypeId typeId =undefined) : Value(typeId) {} /*! @brief Read the value from a character buffer. The byte order is required by the interface but not used by this method. @param buf Pointer to the data buffer to read from @param len Number of bytes in the data buffer @param byteOrder Byte order. Not used. */ virtual void read(const char* buf, long len, ByteOrder byteOrder); //! Set the data from a string of integer values (e.g., "0 1 2 3") virtual void read(const std::string& buf); /*! @brief Write value to a character data buffer. The byte order is required by the interface but not used by this method. The user must ensure that the buffer has enough memory. Otherwise the call results in undefined behaviour. @param buf Data buffer to write to. @param byteOrder Byte order. Not used. @return Number of characters written. */ virtual long copy(char* buf, ByteOrder byteOrder) const; virtual long count() const { return size(); } virtual long size() const; virtual Value* clone() const; virtual std::ostream& write(std::ostream& os) const; virtual long toLong(long n =0) const { return value_[n]; } private: std::string value_; }; // class DataValue //! %Value for an Ascii string type. class AsciiValue : public Value { public: //! Default constructor. AsciiValue() : Value(asciiString) {} /*! @brief Read the value from a character buffer. The byte order is required by the interface but not used by this method. @param buf Pointer to the data buffer to read from @param len Number of bytes in the data buffer @param byteOrder Byte order. Not used. */ virtual void read(const char* buf, long len, ByteOrder byteOrder); /*! @brief Set the value to that of the string buf. A terminating '\\0' character is appended to the value if buf doesn't end with '\\0'. */ virtual void read(const std::string& buf); /*! @brief Write value to a character data buffer. The byte order is required by the interface but not used by this method. The user must ensure that the buffer has enough memory. Otherwise the call results in undefined behaviour. @param buf Data buffer to write to. @param byteOrder Byte order. Not used. @return Number of characters written. */ virtual long copy(char* buf, ByteOrder byteOrder) const; virtual long count() const { return size(); } virtual long size() const; virtual Value* clone() const; virtual std::ostream& write(std::ostream& os) const; virtual long toLong(long n =0) const { return value_[n]; } private: std::string value_; }; // class AsciiValue /*! @brief Template for a %Value of a basic type. This is used for unsigned and signed short, long and rationals. */ template class ValueType : public Value { public: //! Default constructor. ValueType() : Value(getType()) {} virtual void read(const char* buf, long len, ByteOrder byteOrder); /*! @brief Set the data from a string of values of type T (e.g., "0 1 2 3" or "1/2 1/3 1/4" depending on what T is). Generally, the accepted input format is the same as that produced by the write() method. */ virtual void read(const std::string& buf); virtual long copy(char* buf, ByteOrder byteOrder) const; virtual long count() const { return value_.size(); } virtual long size() const; virtual Value* clone() const; virtual std::ostream& write(std::ostream& os) const; virtual long toLong(long n =0) const; //! Container for values typedef std::vector ValueList; //! Iterator type defined for convenience. typedef typename std::vector::iterator iterator; //! Const iterator type defined for convenience. typedef typename std::vector::const_iterator const_iterator; /*! @brief The container for all values. In your application, if you know what subclass of Value you're dealing with (and possibly the T) then you can access this STL container through the usual standard library functions. */ ValueList value_; }; // class ValueType //! Unsigned short value type typedef ValueType UShortValue; //! Unsigned long value type typedef ValueType ULongValue; //! Unsigned rational value type typedef ValueType URationalValue; //! Signed short value type typedef ValueType ShortValue; //! Signed long value type typedef ValueType LongValue; //! Signed rational value type typedef ValueType RationalValue; /*! @brief Information related to one %Exif tag. */ class Metadatum { public: /*! @brief Constructor for tag data read from an IFD, when all information is available. %Metadatum copies (clones) the value if one is provided. */ Metadatum(uint16 tag, uint16 type, IfdId ifdId, int ifdIdx, Value* value =0); /*! @brief Constructor for new tags created by an application, which only needs to provide a key / value pair. %Metadatum copies (clones) the value if one is provided. Alternatively, a program can create an 'empty' metadatum with only a key and set the value later, using setValue(). @param key The key of the metadatum. @param value Pointer to a metadatum value. @throw Error ("Invalid key") if the key cannot be parsed and converted to a tag number and an IFD id or the section name does not match. */ explicit Metadatum(const std::string& key, Value* value =0); //! Destructor ~Metadatum(); //! Copy constructor Metadatum(const Metadatum& rhs); //! Assignment operator Metadatum& operator=(const Metadatum& rhs); /*! @brief Set the value. This method copies (clones) the value. */ void setValue(Value* value); /*! @brief Set the value to the string buf. Uses Value::read(const std::string& buf). If the metadatum does not have a value yet, then an AsciiValue is created. */ void setValue(const std::string& buf); //! Return the name of the tag const char* tagName() const { return ExifTags::tagName(tag_, ifdId_); } //! Return the name of the type const char* typeName() const { return ExifTags::typeName(typeId()); } //! Return the size in bytes of one component of this type long typeSize() const { return ExifTags::typeSize(typeId()); } //! Return the name of the IFD const char* ifdName() const { return ExifTags::ifdName(ifdId_); } //! Return the related image item (image or thumbnail) const char* ifdItem() const { return ExifTags::ifdItem(ifdId_); } //! Return the name of the section const char* sectionName() const { return ExifTags::sectionName(tag_, ifdId_); } //! @name Accessors //@{ //! Return the tag uint16 tag() const { return tag_; } //! Return the type id. TypeId typeId() const { return value_ == 0 ? invalid : value_->typeId(); } //! Return the number of components in the value long count() const { return value_ == 0 ? 0 : value_->count(); } //! Return the size of the value in bytes long size() const { return value_ == 0 ? 0 : value_->size(); } /*! @brief Return the n-th component of the value. The return value is -1 if the value of the Metadatum is not set and the behaviour of the method is undefined if there is no n-th component. */ long toLong(long n =0) const { return value_ == 0 ? -1 : value_->toLong(n); } //! Return the IFD id IfdId ifdId() const { return ifdId_; } //! Return the position in the IFD (-1: not set) int ifdIdx() const { return ifdIdx_; } /*! @brief Return a constant reference to the value. This method is provided mostly for convenient and versatile output of the value, for example @code ExifData::const_iterator i = exifData.findKey(key); if (i != exifData.end()) { std::cout << i->key() << " " << std::hex << i->value() << "\n"; } @endcode Do not attempt to write to the value through this reference. The behaviour of the method is undefined if value is not set. */ const Value& value() const { return *value_; } /*! @brief Return a unique key for the tag. The key is of the form 'ifdItem.sectionName.tagName'. */ std::string key() const { return key_; } //@} private: uint16 tag_; //!< Tag value IfdId ifdId_; //!< The IFD associated with this tag int ifdIdx_; //!< Position in the IFD (-1: not set) Value* value_; //!< Pointer to the value std::string key_; //!< Unique key }; // class Metadatum //! Container type to hold all metadata typedef std::vector Metadata; //! Unary predicate that matches a Metadatum with a given key class FindMetadatumByKey { public: //! Constructor, initializes the object with the tag to look for FindMetadatumByKey(const std::string& key) : key_(key) {} /*! @brief Returns true if the key of the argument metadatum is equal to that of the object. */ bool operator()(const Metadatum& metadatum) const { return key_ == metadatum.key(); } private: std::string key_; }; // class FindEntryByTag /*! @brief Models an IFD (Image File Directory) Todo: - make the data handling more intelligent */ class Ifd { public: //! Constructor. Allows to set the IFD identifier. explicit Ifd(IfdId ifdId =ifdIdNotSet); //! Data structure for one IFD directory entry struct Entry { Entry(); //!< Default constructor ~Entry(); //!< Destructor Entry(const Entry& rhs); //!< Copy constructor Entry& operator=(const Entry& rhs); //!< Assignment operator //! Return the size in bytes of one element of this type long typeSize() const { return ExifTags::typeSize(TypeId(type_)); } //! Return the name of the type const char* typeName() const { return ExifTags::typeName(TypeId(type_)); } //! Position in the IFD int ifdIdx_; //! Tag uint16 tag_; //! Type uint16 type_; //! Number of components uint32 count_; //! Offset from the start of the IFD uint32 offset_; //! Pointer to the data buffer char* data_; //! Size of the data buffer in bytes long size_; }; // struct Entry //! Container type to hold all IFD directory entries typedef std::vector Entries; //! Entries const iterator type typedef Entries::const_iterator const_iterator; //! Entries iterator type typedef Entries::iterator iterator; //! The first entry const_iterator begin() const { return entries_.begin(); } //! End of the entries const_iterator end() const { return entries_.end(); } //! The first entry iterator begin() { return entries_.begin(); } //! End of the entries iterator end() { return entries_.end(); } //! Unary predicate that matches an Entry with a given tag class FindEntryByTag { public: //! Constructor, initializes the object with the tag to look for FindEntryByTag(uint16 tag) : tag_(tag) {} /*! @brief Returns true if the tag of the argument entry is equal to that of the object. */ bool operator()(const Ifd::Entry& entry) const { return tag_ == entry.tag_; } private: uint16 tag_; }; // class FindEntryByTag /*! @brief Read a complete IFD and its data from a data buffer @param buf Pointer to the data to decode. The buffer must start with the IFD data (as opposed to readSubIfd). @param byteOrder Applicable byte order (little or big endian). @param offset (Optional) offset of the IFD from the start of the Tiff header, if known. If not given, the offset will be guessed using the assumption that the smallest offset of all IFD directory entries points to a data buffer immediately follwing the IFD. @return 0 if successful */ int read(const char* buf, ByteOrder byteOrder, long offset =0); /*! @brief Read a sub-IFD from the location pointed to by the directory entry with the given tag. @param dest References the destination IFD. @param buf The data buffer to read from. The buffer must contain all Exif data starting from the Tiff header (as opposed to read). @param byteOrder Applicable byte order (little or big endian). @param tag Tag to look for. @return 0 if successful */ int readSubIfd( Ifd& dest, const char* buf, ByteOrder byteOrder, uint16 tag ) const; /*! @brief Copy the IFD to a data array, returns a reference to the data buffer. The pointer to the next IFD will be adjusted to an offset from the start of the Tiff header to the position immediately following the converted IFD. @param buf Pointer to the data buffer. @param byteOrder Applicable byte order (little or big endian). @param offset Target offset from the start of the Tiff header of the data array. The IFD offsets will be adjusted as necessary. If not given, then it is assumed that the IFD will remain at its original position. @return Returns the number of characters written. */ long copy(char* buf, ByteOrder byteOrder, long offset =0) const; /*! @brief Print the IFD in human readable format to the given stream; begin each line with prefix. */ void print(std::ostream& os, const std::string& prefix ="") const; //! @name Accessors //@{ //! Ifd id of the IFD IfdId ifdId() const { return ifdId_; } //! Offset of the IFD from SOI long offset() const { return offset_; } //! Find an IFD entry by tag, return a const iterator into the entries list Entries::const_iterator findTag(uint16 tag) const; //! Find an IFD entry by tag, return an iterator into the entries list Entries::iterator findTag(uint16 tag); //! Get the offset to the next IFD from the start of the Tiff header long next() const { return next_; } //! Get the size of this IFD in bytes (IFD only, without data) long size() const { return size_; } //@} private: Entries entries_; // IFD entries IfdId ifdId_; // IFD Id long offset_; // offset of the IFD from the start of // Tiff header long next_; // offset of next IFD from the start of // the Tiff header long size_; // size of the IFD in bytes }; // class Ifd //! %Thumbnail data Todo: implement this properly class Thumbnail { public: //! Read the thumbnail from the data buffer, return 0 if successfull int read(const char* buf, const ExifData& exifData, ByteOrder byteOrder); //! Write thumbnail to file path, return 0 if successful int write(const std::string& path) const; private: std::string thumbnail_; }; // class Thumbnail /*! @brief A container for %Exif data Contains the %Exif data of a JPEG image - read and write access to all tags and data - iterators to access the %Exif data - decoding and encoding through the stream interface - human readable output - XML input and output - access to thumbnail (write, delete, re-calculate) Todo: - A constructor which creates a minimal valid set of %Exif data - Support to add, delete, edit, read data (maybe also in Metadata) */ class ExifData { public: /*! @brief Read the %Exif data from file path. @param path Path to the file @return 0 if successful
the return code of readExifData(std::istream& is) if the call to this function fails
the return code of read(const char* buf, long len) if the call to this function fails
*/ int read(const std::string& path); /*! @brief Read the %Exif data from a character buffer. Assumes that the original abs offset of the Exif data is set. @param buf Pointer to the data buffer to read from @param len Number of bytes in the data buffer @return 0 if successful */ int read(const char* buf, long len); //! Write %Exif data to a data buffer, return number of bytes written long copy(char* buf) const; //! Returns the size of all %Exif data (Tiff header plus metadata) long size() const; //! Returns the byte order as specified in the Tiff header ByteOrder byteOrder() const { return tiffHeader_.byteOrder(); } /*! @brief Add all entries of an IFD to the Exif metadata. Checks for duplicates: if a metadatum already exists, its value is overwritten. */ void add(const Ifd& ifd, ByteOrder byteOrder); /*! @brief Add a metadatum from the supplied key and value pair. This method copies (clones) the value. If a metadatum with the given key already exists, its value is overwritten and no new metadatum is added. */ void add(const std::string& key, Value* value); //! Metadata iterator type typedef Metadata::iterator iterator; //! Metadata const iterator type typedef Metadata::const_iterator const_iterator; //! Begin of the metadata const_iterator begin() const { return metadata_.begin(); } //! End of the metadata const_iterator end() const { return metadata_.end(); } //! Begin of the metadata iterator begin() { return metadata_.begin(); } //! End of the metadata iterator end() { return metadata_.end(); } //! Find a metadatum by its key, return an iterator to it iterator findKey(const std::string& key); //! Find a metadatum by its key, return a const iterator to it const_iterator findKey(const std::string& key) const; //! Delete the metadatum with a given key void erase(const std::string& key); //! Delete the metadatum at iterator position pos void erase(iterator pos); //! Write the thumbnail image to a file int writeThumbnail(const std::string& path) const { return thumbnail_.write(path); } private: /*! @brief Add metadatum src to the Exif metadata. No duplicate check is done. (That's why the method is private.) */ void add(const Metadatum& src); long offset_; // Original abs offset of the Exif data TiffHeader tiffHeader_; Metadata metadata_; Thumbnail thumbnail_; }; // class ExifData // ***************************************************************************** // free functions //! Read a 2 byte unsigned short value from the data buffer uint16 getUShort(const char* buf, ByteOrder byteOrder); //! Read a 4 byte unsigned long value from the data buffer uint32 getULong(const char* buf, ByteOrder byteOrder); //! Read an 8 byte unsigned rational value from the data buffer URational getURational(const char* buf, ByteOrder byteOrder); //! Read a 2 byte signed short value from the data buffer int16 getShort(const char* buf, ByteOrder byteOrder); //! Read a 4 byte signed long value from the data buffer int32 getLong(const char* buf, ByteOrder byteOrder); //! Read an 8 byte signed rational value from the data buffer Rational getRational(const char* buf, ByteOrder byteOrder); /*! @brief Convert an unsigned short to data, write the data to the buffer, return number of bytes written. */ long us2Data(char* buf, uint16 s, ByteOrder byteOrder); /*! @brief Convert an unsigned long to data, write the data to the buffer, return number of bytes written. */ long ul2Data(char* buf, uint32 l, ByteOrder byteOrder); /*! @brief Convert an unsigned rational to data, write the data to the buffer, return number of bytes written. */ long ur2Data(char* buf, URational l, ByteOrder byteOrder); /*! @brief Convert a signed short to data, write the data to the buffer, return number of bytes written. */ long s2Data(char* buf, int16 s, ByteOrder byteOrder); /*! @brief Convert a signed long to data, write the data to the buffer, return number of bytes written. */ long l2Data(char* buf, int32 l, ByteOrder byteOrder); /*! @brief Convert a signed rational to data, write the data to the buffer, return number of bytes written. */ long r2Data(char* buf, Rational l, ByteOrder byteOrder); //! Print len bytes from buf in hex and ASCII format to the given stream void hexdump(std::ostream& os, const char* buf, long len); // ***************************************************************************** // template and inline definitions /*! @brief Read a value of type T from the data buffer. We need this template function for the ValueType template classes. There are only specializations of this function available; no default implementation is provided. @param buf Pointer to the data buffer to read from. @param byteOrder Applicable byte order (little or big endian). @return A value of type T. */ template T getValue(const char* buf, ByteOrder byteOrder); // Specialization for a 2 byte unsigned short value. template<> inline uint16 getValue(const char* buf, ByteOrder byteOrder) { return getUShort(buf, byteOrder); } // Specialization for a 4 byte unsigned long value. template<> inline uint32 getValue(const char* buf, ByteOrder byteOrder) { return getULong(buf, byteOrder); } // Specialization for an 8 byte unsigned rational value. template<> inline URational getValue(const char* buf, ByteOrder byteOrder) { return getURational(buf, byteOrder); } // Specialization for a 2 byte signed short value. template<> inline int16 getValue(const char* buf, ByteOrder byteOrder) { return getShort(buf, byteOrder); } // Specialization for a 4 byte signed long value. template<> inline int32 getValue(const char* buf, ByteOrder byteOrder) { return getLong(buf, byteOrder); } // Specialization for an 8 byte signed rational value. template<> inline Rational getValue(const char* buf, ByteOrder byteOrder) { return getRational(buf, byteOrder); } /*! @brief Convert a value of type T to data, write the data to the data buffer. We need this template function for the ValueType template classes. There are only specializations of this function available; no default implementation is provided. @param buf Pointer to the data buffer to write to. @param t Value to be converted. @param byteOrder Applicable byte order (little or big endian). @return The number of bytes written to the buffer. */ template long toData(char* buf, T t, ByteOrder byteOrder); /*! @brief Specialization to write an unsigned short to the data buffer. Return the number of bytes written. */ template<> inline long toData(char* buf, uint16 t, ByteOrder byteOrder) { return us2Data(buf, t, byteOrder); } /*! @brief Specialization to write an unsigned long to the data buffer. Return the number of bytes written. */ template<> inline long toData(char* buf, uint32 t, ByteOrder byteOrder) { return ul2Data(buf, t, byteOrder); } /*! @brief Specialization to write an unsigned rational to the data buffer. Return the number of bytes written. */ template<> inline long toData(char* buf, URational t, ByteOrder byteOrder) { return ur2Data(buf, t, byteOrder); } /*! @brief Specialization to write a signed short to the data buffer. Return the number of bytes written. */ template<> inline long toData(char* buf, int16 t, ByteOrder byteOrder) { return s2Data(buf, t, byteOrder); } /*! @brief Specialization to write a signed long to the data buffer. Return the number of bytes written. */ template<> inline long toData(char* buf, int32 t, ByteOrder byteOrder) { return l2Data(buf, t, byteOrder); } /*! @brief Specialization to write a signed rational to the data buffer. Return the number of bytes written. */ template<> inline long toData(char* buf, Rational t, ByteOrder byteOrder) { return r2Data(buf, t, byteOrder); } template void ValueType::read(const char* buf, long len, ByteOrder byteOrder) { value_.clear(); for (long i = 0; i < len; i += ExifTags::typeSize(typeId())) { value_.push_back(getValue(buf + i, byteOrder)); } } template void ValueType::read(const std::string& buf) { std::istringstream is(buf); T tmp; value_.clear(); while (is >> tmp) { value_.push_back(tmp); } } template long ValueType::copy(char* buf, ByteOrder byteOrder) const { long offset = 0; typename ValueList::const_iterator end = value_.end(); for (typename ValueList::const_iterator i = value_.begin(); i != end; ++i) { offset += toData(buf + offset, *i, byteOrder); } return offset; } template long ValueType::size() const { return ExifTags::typeSize(typeId()) * value_.size(); } template Value* ValueType::clone() const { return new ValueType(*this); } template std::ostream& ValueType::write(std::ostream& os) const { typename ValueList::const_iterator end = value_.end(); typename ValueList::const_iterator i = value_.begin(); while (i != end) { os << *i; if (++i != end) os << " "; } return os; } // Default implementation template inline long ValueType::toLong(long n) const { return value_[n]; } // Specialization for rational template<> inline long ValueType::toLong(long n) const { return value_[n].first / value_[n].second; } // Specialization for unsigned rational template<> inline long ValueType::toLong(long n) const { return value_[n].first / value_[n].second; } } // namespace Exif #endif // #ifndef EXIF_HPP_