diff options
Diffstat (limited to 'core')
-rw-r--r-- | core/exif.cpp | 1387 | ||||
-rw-r--r-- | core/exif.h | 198 | ||||
-rw-r--r-- | core/qthelper.cpp | 4 |
3 files changed, 958 insertions, 631 deletions
diff --git a/core/exif.cpp b/core/exif.cpp index 0b1cda2bc..b2423ba20 100644 --- a/core/exif.cpp +++ b/core/exif.cpp @@ -1,9 +1,8 @@ -#include <stdio.h> /************************************************************************** exif.cpp -- A simple ISO C++ library to parse basic EXIF - information from a JPEG file. + information from a JPEG file. - Copyright (c) 2010-2013 Mayank Lahiri + Copyright (c) 2010-2015 Mayank Lahiri mlahiri@gmail.com All rights reserved (BSD License). @@ -18,182 +17,455 @@ this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. - THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ``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 FREEBSD PROJECT 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. + THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ``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 FREEBSD PROJECT 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. */ +#include "exif.h" + #include <algorithm> +#include <cstdint> +#include <stdio.h> +#include <vector> #include "dive.h" -#include "exif.h" using std::string; namespace { - // IF Entry - struct IFEntry { - // Raw fields - unsigned short tag; - unsigned short format; - unsigned data; - unsigned length; - - // Parsed fields - string val_string; - unsigned short val_16; - unsigned val_32; - double val_rational; - unsigned char val_byte; - }; - - // Helper functions - unsigned int parse32(const unsigned char *buf, bool intel) - { - if (intel) - return ((unsigned)buf[3] << 24) | - ((unsigned)buf[2] << 16) | - ((unsigned)buf[1] << 8) | - buf[0]; - - return ((unsigned)buf[0] << 24) | - ((unsigned)buf[1] << 16) | - ((unsigned)buf[2] << 8) | - buf[3]; - } - - unsigned short parse16(const unsigned char *buf, bool intel) - { - if (intel) - return ((unsigned)buf[1] << 8) | buf[0]; - return ((unsigned)buf[0] << 8) | buf[1]; - } - - string parseEXIFString(const unsigned char *buf, - const unsigned num_components, - const unsigned data, - const unsigned base, - const unsigned len) - { - string value; - if (num_components <= 4) - value.assign((const char *)&data, num_components); - else { - if (base + data + num_components <= len) - value.assign((const char *)(buf + base + data), num_components); - } - return value; - } - - double parseEXIFRational(const unsigned char *buf, bool intel) - { - double numerator = 0; - double denominator = 1; - - numerator = (double)parse32(buf, intel); - denominator = (double)parse32(buf + 4, intel); - if (denominator < 1e-20) - return 0; - return numerator / denominator; - } - - IFEntry parseIFEntry(const unsigned char *buf, - const unsigned offs, - const bool alignIntel, - const unsigned base, - const unsigned len) - { - IFEntry result; - - // Each directory entry is composed of: - // 2 bytes: tag number (data field) - // 2 bytes: data format - // 4 bytes: number of components - // 4 bytes: data value or offset to data value - result.tag = parse16(buf + offs, alignIntel); - result.format = parse16(buf + offs + 2, alignIntel); - result.length = parse32(buf + offs + 4, alignIntel); - result.data = parse32(buf + offs + 8, alignIntel); - - // Parse value in specified format - switch (result.format) { - case 1: - result.val_byte = (unsigned char)*(buf + offs + 8); - break; - case 2: - result.val_string = parseEXIFString(buf, result.length, result.data, base, len); - break; - case 3: - result.val_16 = parse16((const unsigned char *)buf + offs + 8, alignIntel); - break; - case 4: - result.val_32 = result.data; - break; - case 5: - if (base + result.data + 8 <= len) - result.val_rational = parseEXIFRational(buf + base + result.data, alignIntel); - break; - case 7: - case 9: - case 10: - break; - default: - result.tag = 0xFF; - } - return result; - } + +struct Rational { + uint32_t numerator, denominator; + operator double() const { + if (denominator < 1e-20) { + return 0; + } + return static_cast<double>(numerator) / static_cast<double>(denominator); + } +}; + +// IF Entry +class IFEntry { + public: + using byte_vector = std::vector<uint8_t>; + using ascii_vector = std::string; + using short_vector = std::vector<uint16_t>; + using long_vector = std::vector<uint32_t>; + using rational_vector = std::vector<Rational>; + + IFEntry() + : tag_(0xFF), format_(0xFF), data_(0), length_(0), val_byte_(nullptr) {} + IFEntry(const IFEntry &) = delete; + IFEntry &operator=(const IFEntry &) = delete; + IFEntry(IFEntry &&other) + : tag_(other.tag_), + format_(other.format_), + data_(other.data_), + length_(other.length_), + val_byte_(other.val_byte_) { + other.tag_ = 0xFF; + other.format_ = 0xFF; + other.data_ = 0; + other.length_ = 0; + other.val_byte_ = nullptr; + } + ~IFEntry() { delete_union(); } + unsigned short tag() const { return tag_; } + void tag(unsigned short tag) { tag_ = tag; } + unsigned short format() const { return format_; } + bool format(unsigned short format) { + switch (format) { + case 0x01: + case 0x02: + case 0x03: + case 0x04: + case 0x05: + case 0x07: + case 0x09: + case 0x0a: + case 0xff: + break; + default: + return false; + } + delete_union(); + format_ = format; + new_union(); + return true; + } + unsigned data() const { return data_; } + void data(unsigned data) { data_ = data; } + unsigned length() const { return length_; } + void length(unsigned length) { length_ = length; } + + // functions to access the data + // + // !! it's CALLER responsibility to check that format !! + // !! is correct before accessing it's field !! + // + // - getters are use here to allow future addition + // of checks if format is correct + byte_vector &val_byte() { return *val_byte_; } + ascii_vector &val_string() { return *val_string_; } + short_vector &val_short() { return *val_short_; } + long_vector &val_long() { return *val_long_; } + rational_vector &val_rational() { return *val_rational_; } + + private: + // Raw fields + unsigned short tag_; + unsigned short format_; + unsigned data_; + unsigned length_; + + // Parsed fields + union { + byte_vector *val_byte_; + ascii_vector *val_string_; + short_vector *val_short_; + long_vector *val_long_; + rational_vector *val_rational_; + }; + + void delete_union() { + switch (format_) { + case 0x1: + delete val_byte_; + val_byte_ = nullptr; + break; + case 0x2: + delete val_string_; + val_string_ = nullptr; + break; + case 0x3: + delete val_short_; + val_short_ = nullptr; + break; + case 0x4: + delete val_long_; + val_long_ = nullptr; + break; + case 0x5: + delete val_rational_; + val_rational_ = nullptr; + break; + case 0xff: + break; + default: + // should not get here + // should I throw an exception or ...? + break; + } + } + void new_union() { + switch (format_) { + case 0x1: + val_byte_ = new byte_vector(); + break; + case 0x2: + val_string_ = new ascii_vector(); + break; + case 0x3: + val_short_ = new short_vector(); + break; + case 0x4: + val_long_ = new long_vector(); + break; + case 0x5: + val_rational_ = new rational_vector(); + break; + case 0xff: + break; + default: + // should not get here + // should I throw an exception or ...? + break; + } + } +}; + +// Helper functions +template <typename T, bool alignIntel> +T parse(const unsigned char *buf); + +template <> +uint8_t parse<uint8_t, false>(const unsigned char *buf) { + return *buf; +} + +template <> +uint8_t parse<uint8_t, true>(const unsigned char *buf) { + return *buf; +} + +template <> +uint16_t parse<uint16_t, false>(const unsigned char *buf) { + return (static_cast<uint16_t>(buf[0]) << 8) | buf[1]; +} + +template <> +uint16_t parse<uint16_t, true>(const unsigned char *buf) { + return (static_cast<uint16_t>(buf[1]) << 8) | buf[0]; +} + +template <> +uint32_t parse<uint32_t, false>(const unsigned char *buf) { + return (static_cast<uint32_t>(buf[0]) << 24) | + (static_cast<uint32_t>(buf[1]) << 16) | + (static_cast<uint32_t>(buf[2]) << 8) | buf[3]; +} + +template <> +uint32_t parse<uint32_t, true>(const unsigned char *buf) { + return (static_cast<uint32_t>(buf[3]) << 24) | + (static_cast<uint32_t>(buf[2]) << 16) | + (static_cast<uint32_t>(buf[1]) << 8) | buf[0]; +} + +template <> +Rational parse<Rational, true>(const unsigned char *buf) { + Rational r; + r.numerator = parse<uint32_t, true>(buf); + r.denominator = parse<uint32_t, true>(buf + 4); + return r; +} + +template <> +Rational parse<Rational, false>(const unsigned char *buf) { + Rational r; + r.numerator = parse<uint32_t, false>(buf); + r.denominator = parse<uint32_t, false>(buf + 4); + return r; +} + +/** + * Try to read entry.length() values for this entry. + * + * Returns: + * true - entry.length() values were read + * false - something went wrong, vec's content was not touched + */ +template <typename T, bool alignIntel, typename C> +bool extract_values(C &container, const unsigned char *buf, const unsigned base, + const unsigned len, const IFEntry &entry) { + const unsigned char *data; + uint32_t reversed_data; + // if data fits into 4 bytes, they are stored directly in + // the data field in IFEntry + if (sizeof(T) * entry.length() <= 4) { + if (alignIntel) { + reversed_data = entry.data(); + } else { + reversed_data = entry.data(); + // this reversing works, but is ugly + unsigned char *data = reinterpret_cast<unsigned char *>(&reversed_data); + unsigned char tmp; + tmp = data[0]; + data[0] = data[3]; + data[3] = tmp; + tmp = data[1]; + data[1] = data[2]; + data[2] = tmp; + } + data = reinterpret_cast<const unsigned char *>(&(reversed_data)); + } else { + data = buf + base + entry.data(); + if (data + sizeof(T) * entry.length() > buf + len) { + return false; + } + } + container.resize(entry.length()); + for (size_t i = 0; i < entry.length(); ++i) { + container[i] = parse<T, alignIntel>(data + sizeof(T) * i); + } + return true; +} + +template <bool alignIntel> +void parseIFEntryHeader(const unsigned char *buf, unsigned short &tag, + unsigned short &format, unsigned &length, + unsigned &data) { + // Each directory entry is composed of: + // 2 bytes: tag number (data field) + // 2 bytes: data format + // 4 bytes: number of components + // 4 bytes: data value or offset to data value + tag = parse<uint16_t, alignIntel>(buf); + format = parse<uint16_t, alignIntel>(buf + 2); + length = parse<uint32_t, alignIntel>(buf + 4); + data = parse<uint32_t, alignIntel>(buf + 8); +} + +template <bool alignIntel> +void parseIFEntryHeader(const unsigned char *buf, IFEntry &result) { + unsigned short tag; + unsigned short format; + unsigned length; + unsigned data; + + parseIFEntryHeader<alignIntel>(buf, tag, format, length, data); + + result.tag(tag); + result.format(format); + result.length(length); + result.data(data); +} + +template <bool alignIntel> +IFEntry parseIFEntry_temp(const unsigned char *buf, const unsigned offs, + const unsigned base, const unsigned len) { + IFEntry result; + + // check if there even is enough data for IFEntry in the buffer + if (buf + offs + 12 > buf + len) { + result.tag(0xFF); + return result; + } + + parseIFEntryHeader<alignIntel>(buf + offs, result); + + // Parse value in specified format + switch (result.format()) { + case 1: + if (!extract_values<uint8_t, alignIntel>(result.val_byte(), buf, base, + len, result)) { + result.tag(0xFF); + } + break; + case 2: + // string is basically sequence of uint8_t (well, according to EXIF even + // uint7_t, but + // we don't have that), so just read it as bytes + if (!extract_values<uint8_t, alignIntel>(result.val_string(), buf, base, + len, result)) { + result.tag(0xFF); + } + // and cut zero byte at the end, since we don't want that in the + // std::string + if (result.val_string()[result.val_string().length() - 1] == '\0') { + result.val_string().resize(result.val_string().length() - 1); + } + break; + case 3: + if (!extract_values<uint16_t, alignIntel>(result.val_short(), buf, base, + len, result)) { + result.tag(0xFF); + } + break; + case 4: + if (!extract_values<uint32_t, alignIntel>(result.val_long(), buf, base, + len, result)) { + result.tag(0xFF); + } + break; + case 5: + if (!extract_values<Rational, alignIntel>(result.val_rational(), buf, + base, len, result)) { + result.tag(0xFF); + } + break; + case 7: + case 9: + case 10: + break; + default: + result.tag(0xFF); + } + return result; +} + +// helper functions for convinience +template <typename T> +T parse_value(const unsigned char *buf, bool alignIntel) { + if (alignIntel) { + return parse<T, true>(buf); + } else { + return parse<T, false>(buf); + } +} + +void parseIFEntryHeader(const unsigned char *buf, bool alignIntel, + unsigned short &tag, unsigned short &format, + unsigned &length, unsigned &data) { + if (alignIntel) { + parseIFEntryHeader<true>(buf, tag, format, length, data); + } else { + parseIFEntryHeader<false>(buf, tag, format, length, data); + } +} + +IFEntry parseIFEntry(const unsigned char *buf, const unsigned offs, + const bool alignIntel, const unsigned base, + const unsigned len) { + if (alignIntel) { + return parseIFEntry_temp<true>(buf, offs, base, len); + } else { + return parseIFEntry_temp<false>(buf, offs, base, len); + } +} } // // Locates the EXIF segment and parses it using parseFromEXIFSegment // -int EXIFInfo::parseFrom(const unsigned char *buf, unsigned len) -{ - // Sanity check: all JPEG files start with 0xFFD8 and end with 0xFFD9 - // This check also ensures that the user has supplied a correct value for len. - if (!buf || len < 4) - return PARSE_EXIF_ERROR_NO_EXIF; - if (buf[0] != 0xFF || buf[1] != 0xD8) - return PARSE_EXIF_ERROR_NO_JPEG; - if (buf[len - 2] != 0xFF || buf[len - 1] != 0xD9) - return PARSE_EXIF_ERROR_NO_JPEG; - clear(); - - // Scan for EXIF header (bytes 0xFF 0xE1) and do a sanity check by - // looking for bytes "Exif\0\0". The marker length data is in Motorola - // byte order, which results in the 'false' parameter to parse16(). - // The marker has to contain at least the TIFF header, otherwise the - // EXIF data is corrupt. So the minimum length specified here has to be: - // 2 bytes: section size - // 6 bytes: "Exif\0\0" string - // 2 bytes: TIFF header (either "II" or "MM" string) - // 2 bytes: TIFF magic (short 0x2a00 in Motorola byte order) - // 4 bytes: Offset to first IFD - // ========= - // 16 bytes - unsigned offs = 0; // current offset into buffer - for (offs = 0; offs < len - 1; offs++) - if (buf[offs] == 0xFF && buf[offs + 1] == 0xE1) - break; - if (offs + 4 > len) - return PARSE_EXIF_ERROR_NO_EXIF; - offs += 2; - unsigned short section_length = parse16(buf + offs, false); - if (offs + section_length > len || section_length < 16) - return PARSE_EXIF_ERROR_CORRUPT; - offs += 2; - - return parseFromEXIFSegment(buf + offs, len - offs); +int easyexif::EXIFInfo::parseFrom(const unsigned char *buf, unsigned len) { + // Sanity check: all JPEG files start with 0xFFD8. + if (!buf || len < 4) return PARSE_EXIF_ERROR_NO_JPEG; + if (buf[0] != 0xFF || buf[1] != 0xD8) return PARSE_EXIF_ERROR_NO_JPEG; + + // Sanity check: some cameras pad the JPEG image with null bytes at the end. + // Normally, we should able to find the JPEG end marker 0xFFD9 at the end + // of the image, but not always. As long as there are null/0xFF bytes at the + // end of the image buffer, keep decrementing len until an 0xFFD9 is found, + // or some other bytes are. If the first non-zero/0xFF bytes from the end are + // not 0xFFD9, then we can be reasonably sure that the buffer is not a JPEG. + while (len > 2) { + if (buf[len - 1] == 0 || buf[len - 1] == 0xFF) { + len--; + } else { + if (buf[len - 1] != 0xD9 || buf[len - 2] != 0xFF) { + return PARSE_EXIF_ERROR_NO_JPEG; + } else { + break; + } + } + } + clear(); + + // Scan for EXIF header (bytes 0xFF 0xE1) and do a sanity check by + // looking for bytes "Exif\0\0". The marker length data is in Motorola + // byte order, which results in the 'false' parameter to parse16(). + // The marker has to contain at least the TIFF header, otherwise the + // EXIF data is corrupt. So the minimum length specified here has to be: + // 2 bytes: section size + // 6 bytes: "Exif\0\0" string + // 2 bytes: TIFF header (either "II" or "MM" string) + // 2 bytes: TIFF magic (short 0x2a00 in Motorola byte order) + // 4 bytes: Offset to first IFD + // ========= + // 16 bytes + unsigned offs = 0; // current offset into buffer + for (offs = 0; offs < len - 1; offs++) + if (buf[offs] == 0xFF && buf[offs + 1] == 0xE1) break; + if (offs + 4 > len) return PARSE_EXIF_ERROR_NO_EXIF; + offs += 2; + unsigned short section_length = parse_value<uint16_t>(buf + offs, false); + if (offs + section_length > len || section_length < 16) + return PARSE_EXIF_ERROR_CORRUPT; + offs += 2; + + return parseFromEXIFSegment(buf + offs, len - offs); } -int EXIFInfo::parseFrom(const string &data) -{ - return parseFrom((const unsigned char *)data.data(), data.length()); +int easyexif::EXIFInfo::parseFrom(const string &data) { + return parseFrom( + reinterpret_cast<const unsigned char *>(data.data()), static_cast<unsigned>(data.length())); } // @@ -202,373 +474,431 @@ int EXIFInfo::parseFrom(const string &data) // PARAM: 'buf' start of the EXIF TIFF, which must be the bytes "Exif\0\0". // PARAM: 'len' length of buffer // -int EXIFInfo::parseFromEXIFSegment(const unsigned char *buf, unsigned len) -{ - bool alignIntel = true; // byte alignment (defined in EXIF header) - unsigned offs = 0; // current offset into buffer - if (!buf || len < 6) - return PARSE_EXIF_ERROR_NO_EXIF; - - if (!std::equal(buf, buf + 6, "Exif\0\0")) - return PARSE_EXIF_ERROR_NO_EXIF; - offs += 6; - - // Now parsing the TIFF header. The first two bytes are either "II" or - // "MM" for Intel or Motorola byte alignment. Sanity check by parsing - // the unsigned short that follows, making sure it equals 0x2a. The - // last 4 bytes are an offset into the first IFD, which are added to - // the global offset counter. For this block, we expect the following - // minimum size: - // 2 bytes: 'II' or 'MM' - // 2 bytes: 0x002a - // 4 bytes: offset to first IDF - // ----------------------------- - // 8 bytes - if (offs + 8 > len) - return PARSE_EXIF_ERROR_CORRUPT; - unsigned tiff_header_start = offs; - if (buf[offs] == 'I' && buf[offs + 1] == 'I') - alignIntel = true; - else { - if (buf[offs] == 'M' && buf[offs + 1] == 'M') - alignIntel = false; - else - return PARSE_EXIF_ERROR_UNKNOWN_BYTEALIGN; - } - this->ByteAlign = alignIntel; - offs += 2; - if (0x2a != parse16(buf + offs, alignIntel)) - return PARSE_EXIF_ERROR_CORRUPT; - offs += 2; - unsigned first_ifd_offset = parse32(buf + offs, alignIntel); - offs += first_ifd_offset - 4; - if (offs >= len) - return PARSE_EXIF_ERROR_CORRUPT; - - // Now parsing the first Image File Directory (IFD0, for the main image). - // An IFD consists of a variable number of 12-byte directory entries. The - // first two bytes of the IFD section contain the number of directory - // entries in the section. The last 4 bytes of the IFD contain an offset - // to the next IFD, which means this IFD must contain exactly 6 + 12 * num - // bytes of data. - if (offs + 2 > len) - return PARSE_EXIF_ERROR_CORRUPT; - int num_entries = parse16(buf + offs, alignIntel); - if (offs + 6 + 12 * num_entries > len) - return PARSE_EXIF_ERROR_CORRUPT; - offs += 2; - unsigned exif_sub_ifd_offset = len; - unsigned gps_sub_ifd_offset = len; - while (--num_entries >= 0) { - IFEntry result = parseIFEntry(buf, offs, alignIntel, tiff_header_start, len); - offs += 12; - switch (result.tag) { - case 0x102: - // Bits per sample - if (result.format == 3) - this->BitsPerSample = result.val_16; - break; - - case 0x10E: - // Image description - if (result.format == 2) - this->ImageDescription = result.val_string; - break; - - case 0x10F: - // Digicam make - if (result.format == 2) - this->Make = result.val_string; - break; - - case 0x110: - // Digicam model - if (result.format == 2) - this->Model = result.val_string; - break; - - case 0x112: - // Orientation of image - if (result.format == 3) - this->Orientation = result.val_16; - break; - - case 0x131: - // Software used for image - if (result.format == 2) - this->Software = result.val_string; - break; - - case 0x132: - // EXIF/TIFF date/time of image modification - if (result.format == 2) - this->DateTime = result.val_string; - break; - - case 0x8298: - // Copyright information - if (result.format == 2) - this->Copyright = result.val_string; - break; - - case 0x8825: - // GPS IFS offset - gps_sub_ifd_offset = tiff_header_start + result.data; - break; - - case 0x8769: - // EXIF SubIFD offset - exif_sub_ifd_offset = tiff_header_start + result.data; - break; - } - } - - // Jump to the EXIF SubIFD if it exists and parse all the information - // there. Note that it's possible that the EXIF SubIFD doesn't exist. - // The EXIF SubIFD contains most of the interesting information that a - // typical user might want. - if (exif_sub_ifd_offset + 4 <= len) { - offs = exif_sub_ifd_offset; - int num_entries = parse16(buf + offs, alignIntel); - if (offs + 6 + 12 * num_entries > len) - return PARSE_EXIF_ERROR_CORRUPT; - offs += 2; - while (--num_entries >= 0) { - IFEntry result = parseIFEntry(buf, offs, alignIntel, tiff_header_start, len); - switch (result.tag) { - case 0x829a: - // Exposure time in seconds - if (result.format == 5) - this->ExposureTime = result.val_rational; - break; - - case 0x829d: - // FNumber - if (result.format == 5) - this->FNumber = result.val_rational; - break; - - case 0x8827: - // ISO Speed Rating - if (result.format == 3) - this->ISOSpeedRatings = result.val_16; - break; - - case 0x9003: - // Original date and time - if (result.format == 2) - this->DateTimeOriginal = result.val_string; - break; - - case 0x9004: - // Digitization date and time - if (result.format == 2) - this->DateTimeDigitized = result.val_string; - break; - - case 0x9201: - // Shutter speed value - if (result.format == 5) - this->ShutterSpeedValue = result.val_rational; - break; - - case 0x9204: - // Exposure bias value - if (result.format == 5) - this->ExposureBiasValue = result.val_rational; - break; - - case 0x9206: - // Subject distance - if (result.format == 5) - this->SubjectDistance = result.val_rational; - break; - - case 0x9209: - // Flash used - if (result.format == 3) - this->Flash = result.data ? 1 : 0; - break; - - case 0x920a: - // Focal length - if (result.format == 5) - this->FocalLength = result.val_rational; - break; - - case 0x9207: - // Metering mode - if (result.format == 3) - this->MeteringMode = result.val_16; - break; - - case 0x9291: - // Subsecond original time - if (result.format == 2) - this->SubSecTimeOriginal = result.val_string; - break; - - case 0xa002: - // EXIF Image width - if (result.format == 4) - this->ImageWidth = result.val_32; - if (result.format == 3) - this->ImageWidth = result.val_16; - break; - - case 0xa003: - // EXIF Image height - if (result.format == 4) - this->ImageHeight = result.val_32; - if (result.format == 3) - this->ImageHeight = result.val_16; - break; - - case 0xa405: - // Focal length in 35mm film - if (result.format == 3) - this->FocalLengthIn35mm = result.val_16; - break; - } - offs += 12; - } - } - - // Jump to the GPS SubIFD if it exists and parse all the information - // there. Note that it's possible that the GPS SubIFD doesn't exist. - if (gps_sub_ifd_offset + 4 <= len) { - offs = gps_sub_ifd_offset; - int num_entries = parse16(buf + offs, alignIntel); - if (offs + 6 + 12 * num_entries > len) - return PARSE_EXIF_ERROR_CORRUPT; - offs += 2; - while (--num_entries >= 0) { - unsigned short tag = parse16(buf + offs, alignIntel); - unsigned short format = parse16(buf + offs + 2, alignIntel); - unsigned length = parse32(buf + offs + 4, alignIntel); - unsigned data = parse32(buf + offs + 8, alignIntel); - switch (tag) { - case 1: - // GPS north or south - this->GeoLocation.LatComponents.direction = *(buf + offs + 8); - if ('S' == this->GeoLocation.LatComponents.direction) - this->GeoLocation.Latitude = -this->GeoLocation.Latitude; - break; - - case 2: - // GPS latitude - if (format == 5 && length == 3) { - this->GeoLocation.LatComponents.degrees = - parseEXIFRational(buf + data + tiff_header_start, alignIntel); - this->GeoLocation.LatComponents.minutes = - parseEXIFRational(buf + data + tiff_header_start + 8, alignIntel); - this->GeoLocation.LatComponents.seconds = - parseEXIFRational(buf + data + tiff_header_start + 16, alignIntel); - this->GeoLocation.Latitude = - this->GeoLocation.LatComponents.degrees + - this->GeoLocation.LatComponents.minutes / 60 + - this->GeoLocation.LatComponents.seconds / 3600; - if ('S' == this->GeoLocation.LatComponents.direction) - this->GeoLocation.Latitude = -this->GeoLocation.Latitude; - } - break; - - case 3: - // GPS east or west - this->GeoLocation.LonComponents.direction = *(buf + offs + 8); - if ('W' == this->GeoLocation.LonComponents.direction) - this->GeoLocation.Longitude = -this->GeoLocation.Longitude; - break; - - case 4: - // GPS longitude - if (format == 5 && length == 3) { - this->GeoLocation.LonComponents.degrees = - parseEXIFRational(buf + data + tiff_header_start, alignIntel); - this->GeoLocation.LonComponents.minutes = - parseEXIFRational(buf + data + tiff_header_start + 8, alignIntel); - this->GeoLocation.LonComponents.seconds = - parseEXIFRational(buf + data + tiff_header_start + 16, alignIntel); - this->GeoLocation.Longitude = - this->GeoLocation.LonComponents.degrees + - this->GeoLocation.LonComponents.minutes / 60 + - this->GeoLocation.LonComponents.seconds / 3600; - if ('W' == this->GeoLocation.LonComponents.direction) - this->GeoLocation.Longitude = -this->GeoLocation.Longitude; - } - break; - - case 5: - // GPS altitude reference (below or above sea level) - this->GeoLocation.AltitudeRef = *(buf + offs + 8); - if (1 == this->GeoLocation.AltitudeRef) - this->GeoLocation.Altitude = -this->GeoLocation.Altitude; - break; - - case 6: - // GPS altitude reference - if (format == 5) { - this->GeoLocation.Altitude = - parseEXIFRational(buf + data + tiff_header_start, alignIntel); - if (1 == this->GeoLocation.AltitudeRef) - this->GeoLocation.Altitude = -this->GeoLocation.Altitude; - } - break; - } - offs += 12; - } - } - - return PARSE_EXIF_SUCCESS; +int easyexif::EXIFInfo::parseFromEXIFSegment(const unsigned char *buf, + unsigned len) { + bool alignIntel = true; // byte alignment (defined in EXIF header) + unsigned offs = 0; // current offset into buffer + if (!buf || len < 6) return PARSE_EXIF_ERROR_NO_EXIF; + + if (!std::equal(buf, buf + 6, "Exif\0\0")) return PARSE_EXIF_ERROR_NO_EXIF; + offs += 6; + + // Now parsing the TIFF header. The first two bytes are either "II" or + // "MM" for Intel or Motorola byte alignment. Sanity check by parsing + // the unsigned short that follows, making sure it equals 0x2a. The + // last 4 bytes are an offset into the first IFD, which are added to + // the global offset counter. For this block, we expect the following + // minimum size: + // 2 bytes: 'II' or 'MM' + // 2 bytes: 0x002a + // 4 bytes: offset to first IDF + // ----------------------------- + // 8 bytes + if (offs + 8 > len) return PARSE_EXIF_ERROR_CORRUPT; + unsigned tiff_header_start = offs; + if (buf[offs] == 'I' && buf[offs + 1] == 'I') + alignIntel = true; + else { + if (buf[offs] == 'M' && buf[offs + 1] == 'M') + alignIntel = false; + else + return PARSE_EXIF_ERROR_UNKNOWN_BYTEALIGN; + } + this->ByteAlign = alignIntel; + offs += 2; + if (0x2a != parse_value<uint16_t>(buf + offs, alignIntel)) + return PARSE_EXIF_ERROR_CORRUPT; + offs += 2; + unsigned first_ifd_offset = parse_value<uint32_t>(buf + offs, alignIntel); + offs += first_ifd_offset - 4; + if (offs >= len) return PARSE_EXIF_ERROR_CORRUPT; + + // Now parsing the first Image File Directory (IFD0, for the main image). + // An IFD consists of a variable number of 12-byte directory entries. The + // first two bytes of the IFD section contain the number of directory + // entries in the section. The last 4 bytes of the IFD contain an offset + // to the next IFD, which means this IFD must contain exactly 6 + 12 * num + // bytes of data. + if (offs + 2 > len) return PARSE_EXIF_ERROR_CORRUPT; + int num_entries = parse_value<uint16_t>(buf + offs, alignIntel); + if (offs + 6 + 12 * num_entries > len) return PARSE_EXIF_ERROR_CORRUPT; + offs += 2; + unsigned exif_sub_ifd_offset = len; + unsigned gps_sub_ifd_offset = len; + while (--num_entries >= 0) { + IFEntry result = + parseIFEntry(buf, offs, alignIntel, tiff_header_start, len); + offs += 12; + switch (result.tag()) { + case 0x102: + // Bits per sample + if (result.format() == 3 && result.val_short().size()) + this->BitsPerSample = result.val_short().front(); + break; + + case 0x10E: + // Image description + if (result.format() == 2) this->ImageDescription = result.val_string(); + break; + + case 0x10F: + // Digicam make + if (result.format() == 2) this->Make = result.val_string(); + break; + + case 0x110: + // Digicam model + if (result.format() == 2) this->Model = result.val_string(); + break; + + case 0x112: + // Orientation of image + if (result.format() == 3 && result.val_short().size()) + this->Orientation = result.val_short().front(); + break; + + case 0x131: + // Software used for image + if (result.format() == 2) this->Software = result.val_string(); + break; + + case 0x132: + // EXIF/TIFF date/time of image modification + if (result.format() == 2) this->DateTime = result.val_string(); + break; + + case 0x8298: + // Copyright information + if (result.format() == 2) this->Copyright = result.val_string(); + break; + + case 0x8825: + // GPS IFS offset + gps_sub_ifd_offset = tiff_header_start + result.data(); + break; + + case 0x8769: + // EXIF SubIFD offset + exif_sub_ifd_offset = tiff_header_start + result.data(); + break; + } + } + + // Jump to the EXIF SubIFD if it exists and parse all the information + // there. Note that it's possible that the EXIF SubIFD doesn't exist. + // The EXIF SubIFD contains most of the interesting information that a + // typical user might want. + if (exif_sub_ifd_offset + 4 <= len) { + offs = exif_sub_ifd_offset; + int num_entries = parse_value<uint16_t>(buf + offs, alignIntel); + if (offs + 6 + 12 * num_entries > len) return PARSE_EXIF_ERROR_CORRUPT; + offs += 2; + while (--num_entries >= 0) { + IFEntry result = + parseIFEntry(buf, offs, alignIntel, tiff_header_start, len); + switch (result.tag()) { + case 0x829a: + // Exposure time in seconds + if (result.format() == 5 && result.val_rational().size()) + this->ExposureTime = result.val_rational().front(); + break; + + case 0x829d: + // FNumber + if (result.format() == 5 && result.val_rational().size()) + this->FNumber = result.val_rational().front(); + break; + + case 0x8827: + // ISO Speed Rating + if (result.format() == 3 && result.val_short().size()) + this->ISOSpeedRatings = result.val_short().front(); + break; + + case 0x9003: + // Original date and time + if (result.format() == 2) + this->DateTimeOriginal = result.val_string(); + break; + + case 0x9004: + // Digitization date and time + if (result.format() == 2) + this->DateTimeDigitized = result.val_string(); + break; + + case 0x9201: + // Shutter speed value + if (result.format() == 5 && result.val_rational().size()) + this->ShutterSpeedValue = result.val_rational().front(); + break; + + case 0x9204: + // Exposure bias value + if (result.format() == 5 && result.val_rational().size()) + this->ExposureBiasValue = result.val_rational().front(); + break; + + case 0x9206: + // Subject distance + if (result.format() == 5 && result.val_rational().size()) + this->SubjectDistance = result.val_rational().front(); + break; + + case 0x9209: + // Flash used + if (result.format() == 3) this->Flash = result.data() ? 1 : 0; + break; + + case 0x920a: + // Focal length + if (result.format() == 5 && result.val_rational().size()) + this->FocalLength = result.val_rational().front(); + break; + + case 0x9207: + // Metering mode + if (result.format() == 3 && result.val_short().size()) + this->MeteringMode = result.val_short().front(); + break; + + case 0x9291: + // Subsecond original time + if (result.format() == 2) + this->SubSecTimeOriginal = result.val_string(); + break; + + case 0xa002: + // EXIF Image width + if (result.format() == 4 && result.val_long().size()) + this->ImageWidth = result.val_long().front(); + if (result.format() == 3 && result.val_short().size()) + this->ImageWidth = result.val_short().front(); + break; + + case 0xa003: + // EXIF Image height + if (result.format() == 4 && result.val_long().size()) + this->ImageHeight = result.val_long().front(); + if (result.format() == 3 && result.val_short().size()) + this->ImageHeight = result.val_short().front(); + break; + + case 0xa20e: + // EXIF Focal plane X-resolution + if (result.format() == 5) { + this->LensInfo.FocalPlaneXResolution = result.val_rational()[0]; + } + break; + + case 0xa20f: + // EXIF Focal plane Y-resolution + if (result.format() == 5) { + this->LensInfo.FocalPlaneYResolution = result.val_rational()[0]; + } + break; + + case 0xa405: + // Focal length in 35mm film + if (result.format() == 3 && result.val_short().size()) + this->FocalLengthIn35mm = result.val_short().front(); + break; + + case 0xa432: + // Focal length and FStop. + if (result.format() == 5) { + int sz = static_cast<unsigned>(result.val_rational().size()); + if (sz) + this->LensInfo.FocalLengthMin = result.val_rational()[0]; + if (sz > 1) + this->LensInfo.FocalLengthMax = result.val_rational()[1]; + if (sz > 2) + this->LensInfo.FStopMin = result.val_rational()[2]; + if (sz > 3) + this->LensInfo.FStopMax = result.val_rational()[3]; + } + break; + + case 0xa433: + // Lens make. + if (result.format() == 2) { + this->LensInfo.Make = result.val_string(); + } + break; + + case 0xa434: + // Lens model. + if (result.format() == 2) { + this->LensInfo.Model = result.val_string(); + } + break; + } + offs += 12; + } + } + + // Jump to the GPS SubIFD if it exists and parse all the information + // there. Note that it's possible that the GPS SubIFD doesn't exist. + if (gps_sub_ifd_offset + 4 <= len) { + offs = gps_sub_ifd_offset; + int num_entries = parse_value<uint16_t>(buf + offs, alignIntel); + if (offs + 6 + 12 * num_entries > len) return PARSE_EXIF_ERROR_CORRUPT; + offs += 2; + while (--num_entries >= 0) { + unsigned short tag, format; + unsigned length, data; + parseIFEntryHeader(buf + offs, alignIntel, tag, format, length, data); + switch (tag) { + case 1: + // GPS north or south + this->GeoLocation.LatComponents.direction = *(buf + offs + 8); + if (this->GeoLocation.LatComponents.direction == 0) { + this->GeoLocation.LatComponents.direction = '?'; + } + if ('S' == this->GeoLocation.LatComponents.direction) { + this->GeoLocation.Latitude = -this->GeoLocation.Latitude; + } + break; + + case 2: + // GPS latitude + if ((format == 5 || format == 10) && length == 3) { + this->GeoLocation.LatComponents.degrees = parse_value<Rational>( + buf + data + tiff_header_start, alignIntel); + this->GeoLocation.LatComponents.minutes = parse_value<Rational>( + buf + data + tiff_header_start + 8, alignIntel); + this->GeoLocation.LatComponents.seconds = parse_value<Rational>( + buf + data + tiff_header_start + 16, alignIntel); + this->GeoLocation.Latitude = + this->GeoLocation.LatComponents.degrees + + this->GeoLocation.LatComponents.minutes / 60 + + this->GeoLocation.LatComponents.seconds / 3600; + if ('S' == this->GeoLocation.LatComponents.direction) { + this->GeoLocation.Latitude = -this->GeoLocation.Latitude; + } + } + break; + + case 3: + // GPS east or west + this->GeoLocation.LonComponents.direction = *(buf + offs + 8); + if (this->GeoLocation.LonComponents.direction == 0) { + this->GeoLocation.LonComponents.direction = '?'; + } + if ('W' == this->GeoLocation.LonComponents.direction) { + this->GeoLocation.Longitude = -this->GeoLocation.Longitude; + } + break; + + case 4: + // GPS longitude + if ((format == 5 || format == 10) && length == 3) { + this->GeoLocation.LonComponents.degrees = parse_value<Rational>( + buf + data + tiff_header_start, alignIntel); + this->GeoLocation.LonComponents.minutes = parse_value<Rational>( + buf + data + tiff_header_start + 8, alignIntel); + this->GeoLocation.LonComponents.seconds = parse_value<Rational>( + buf + data + tiff_header_start + 16, alignIntel); + this->GeoLocation.Longitude = + this->GeoLocation.LonComponents.degrees + + this->GeoLocation.LonComponents.minutes / 60 + + this->GeoLocation.LonComponents.seconds / 3600; + if ('W' == this->GeoLocation.LonComponents.direction) + this->GeoLocation.Longitude = -this->GeoLocation.Longitude; + } + break; + + case 5: + // GPS altitude reference (below or above sea level) + this->GeoLocation.AltitudeRef = *(buf + offs + 8); + if (1 == this->GeoLocation.AltitudeRef) { + this->GeoLocation.Altitude = -this->GeoLocation.Altitude; + } + break; + + case 6: + // GPS altitude + if ((format == 5 || format == 10)) { + this->GeoLocation.Altitude = parse_value<Rational>( + buf + data + tiff_header_start, alignIntel); + if (1 == this->GeoLocation.AltitudeRef) { + this->GeoLocation.Altitude = -this->GeoLocation.Altitude; + } + } + break; + + case 11: + // GPS degree of precision (DOP) + if ((format == 5 || format == 10)) { + this->GeoLocation.DOP = parse_value<Rational>( + buf + data + tiff_header_start, alignIntel); + } + break; + } + offs += 12; + } + } + + return PARSE_EXIF_SUCCESS; } -void EXIFInfo::clear() -{ - // Strings - ImageDescription.clear(); - Make.clear(); - Model.clear(); - Software.clear(); - DateTime.clear(); - DateTimeOriginal.clear(); - DateTimeDigitized.clear(); - SubSecTimeOriginal.clear(); - Copyright.clear(); - - // Shorts / unsigned / double - ByteAlign = 0; - Orientation = 0; - - BitsPerSample = 0; - ExposureTime = 0; - FNumber = 0; - ISOSpeedRatings = 0; - ShutterSpeedValue = 0; - ExposureBiasValue = 0; - SubjectDistance = 0; - FocalLength = 0; - FocalLengthIn35mm = 0; - Flash = 0; - MeteringMode = 0; - ImageWidth = 0; - ImageHeight = 0; - - // Geolocation - GeoLocation.Latitude = 0; - GeoLocation.Longitude = 0; - GeoLocation.Altitude = 0; - GeoLocation.AltitudeRef = 0; - GeoLocation.LatComponents.degrees = 0; - GeoLocation.LatComponents.minutes = 0; - GeoLocation.LatComponents.seconds = 0; - GeoLocation.LatComponents.direction = 0; - GeoLocation.LonComponents.degrees = 0; - GeoLocation.LonComponents.minutes = 0; - GeoLocation.LonComponents.seconds = 0; - GeoLocation.LonComponents.direction = 0; +void easyexif::EXIFInfo::clear() { + // Strings + ImageDescription = ""; + Make = ""; + Model = ""; + Software = ""; + DateTime = ""; + DateTimeOriginal = ""; + DateTimeDigitized = ""; + SubSecTimeOriginal = ""; + Copyright = ""; + + // Shorts / unsigned / double + ByteAlign = 0; + Orientation = 0; + + BitsPerSample = 0; + ExposureTime = 0; + FNumber = 0; + ISOSpeedRatings = 0; + ShutterSpeedValue = 0; + ExposureBiasValue = 0; + SubjectDistance = 0; + FocalLength = 0; + FocalLengthIn35mm = 0; + Flash = 0; + MeteringMode = 0; + ImageWidth = 0; + ImageHeight = 0; + + // Geolocation + GeoLocation.Latitude = 0; + GeoLocation.Longitude = 0; + GeoLocation.Altitude = 0; + GeoLocation.AltitudeRef = 0; + GeoLocation.DOP = 0; + GeoLocation.LatComponents.degrees = 0; + GeoLocation.LatComponents.minutes = 0; + GeoLocation.LatComponents.seconds = 0; + GeoLocation.LatComponents.direction = '?'; + GeoLocation.LonComponents.degrees = 0; + GeoLocation.LonComponents.minutes = 0; + GeoLocation.LonComponents.seconds = 0; + GeoLocation.LonComponents.direction = '?'; + + // LensInfo + LensInfo.FocalLengthMax = 0; + LensInfo.FocalLengthMin = 0; + LensInfo.FStopMax = 0; + LensInfo.FStopMin = 0; + LensInfo.FocalPlaneYResolution = 0; + LensInfo.FocalPlaneXResolution = 0; + LensInfo.Make = ""; + LensInfo.Model = ""; } -time_t EXIFInfo::epoch() +time_t easyexif::EXIFInfo::epoch() { struct tm tm; int year, month, day, hour, min, sec; @@ -585,3 +915,4 @@ time_t EXIFInfo::epoch() tm.tm_sec = sec; return (utc_mktime(&tm)); } + diff --git a/core/exif.h b/core/exif.h index 0fb3a7d4a..7c0ac5385 100644 --- a/core/exif.h +++ b/core/exif.h @@ -1,34 +1,16 @@ /************************************************************************** exif.h -- A simple ISO C++ library to parse basic EXIF - information from a JPEG file. + information from a JPEG file. Based on the description of the EXIF file format at: -- http://park2.wakwak.com/~tsuruzoh/Computer/Digicams/exif-e.html -- http://www.media.mit.edu/pia/Research/deepview/exif.html -- http://www.exif.org/Exif2-2.PDF - Copyright (c) 2010-2013 Mayank Lahiri + Copyright (c) 2010-2016 Mayank Lahiri mlahiri@gmail.com All rights reserved. - VERSION HISTORY: - ================ - - 2.1: Released July 2013 - -- fixed a bug where JPEGs without an EXIF SubIFD would not be parsed - -- fixed a bug in parsing GPS coordinate seconds - -- fixed makefile bug - -- added two pathological test images from Matt Galloway - http://www.galloway.me.uk/2012/01/uiimageorientation-exif-orientation-sample-images/ - -- split main parsing routine for easier integration into Firefox - - 2.0: Released February 2013 - -- complete rewrite - -- no new/delete - -- added GPS support - - 1.0: Released 2010 - Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: @@ -49,99 +31,113 @@ NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ -#ifndef EXIF_H -#define EXIF_H +#ifndef __EXIF_H +#define __EXIF_H #include <string> +namespace easyexif { + // // Class responsible for storing and parsing EXIF information from a JPEG blob // class EXIFInfo { -public: - // Parsing function for an entire JPEG image buffer. - // - // PARAM 'data': A pointer to a JPEG image. - // PARAM 'length': The length of the JPEG image. - // RETURN: PARSE_EXIF_SUCCESS (0) on succes with 'result' filled out - // error code otherwise, as defined by the PARSE_EXIF_ERROR_* macros - int parseFrom(const unsigned char *data, unsigned length); - int parseFrom(const std::string &data); - - // Parsing function for an EXIF segment. This is used internally by parseFrom() - // but can be called for special cases where only the EXIF section is - // available (i.e., a blob starting with the bytes "Exif\0\0"). - int parseFromEXIFSegment(const unsigned char *buf, unsigned len); - - // Set all data members to default values. - void clear(); - - // Data fields filled out by parseFrom() - char ByteAlign; // 0 = Motorola byte alignment, 1 = Intel - std::string ImageDescription; // Image description - std::string Make; // Camera manufacturer's name - std::string Model; // Camera model - unsigned short Orientation; // Image orientation, start of data corresponds to - // 0: unspecified in EXIF data - // 1: upper left of image - // 3: lower right of image - // 6: upper right of image - // 8: lower left of image - // 9: undefined - unsigned short BitsPerSample; // Number of bits per component - std::string Software; // Software used - std::string DateTime; // File change date and time - std::string DateTimeOriginal; // Original file date and time (may not exist) - std::string DateTimeDigitized; // Digitization date and time (may not exist) - std::string SubSecTimeOriginal; // Sub-second time that original picture was taken - std::string Copyright; // File copyright information - double ExposureTime; // Exposure time in seconds - double FNumber; // F/stop - unsigned short ISOSpeedRatings; // ISO speed - double ShutterSpeedValue; // Shutter speed (reciprocal of exposure time) - double ExposureBiasValue; // Exposure bias value in EV - double SubjectDistance; // Distance to focus point in meters - double FocalLength; // Focal length of lens in millimeters - unsigned short FocalLengthIn35mm; // Focal length in 35mm film - char Flash; // 0 = no flash, 1 = flash used - unsigned short MeteringMode; // Metering mode - // 1: average - // 2: center weighted average - // 3: spot - // 4: multi-spot - // 5: multi-segment - unsigned ImageWidth; // Image width reported in EXIF data - unsigned ImageHeight; // Image height reported in EXIF data - struct Geolocation_t - { // GPS information embedded in file - double Latitude; // Image latitude expressed as decimal - double Longitude; // Image longitude expressed as decimal - double Altitude; // Altitude in meters, relative to sea level - char AltitudeRef; // 0 = above sea level, -1 = below sea level - struct Coord_t { - double degrees; - double minutes; - double seconds; - char direction; - } LatComponents, LonComponents; // Latitude, Longitude expressed in deg/min/sec - } GeoLocation; - EXIFInfo() - { - clear(); - } - - time_t epoch(); + public: + // Parsing function for an entire JPEG image buffer. + // + // PARAM 'data': A pointer to a JPEG image. + // PARAM 'length': The length of the JPEG image. + // RETURN: PARSE_EXIF_SUCCESS (0) on succes with 'result' filled out + // error code otherwise, as defined by the PARSE_EXIF_ERROR_* macros + int parseFrom(const unsigned char *data, unsigned length); + int parseFrom(const std::string &data); + + // Parsing function for an EXIF segment. This is used internally by parseFrom() + // but can be called for special cases where only the EXIF section is + // available (i.e., a blob starting with the bytes "Exif\0\0"). + int parseFromEXIFSegment(const unsigned char *buf, unsigned len); + + // Set all data members to default values. + void clear(); + + // Data fields filled out by parseFrom() + char ByteAlign; // 0 = Motorola byte alignment, 1 = Intel + std::string ImageDescription; // Image description + std::string Make; // Camera manufacturer's name + std::string Model; // Camera model + unsigned short Orientation; // Image orientation, start of data corresponds to + // 0: unspecified in EXIF data + // 1: upper left of image + // 3: lower right of image + // 6: upper right of image + // 8: lower left of image + // 9: undefined + unsigned short BitsPerSample; // Number of bits per component + std::string Software; // Software used + std::string DateTime; // File change date and time + std::string DateTimeOriginal; // Original file date and time (may not exist) + std::string DateTimeDigitized; // Digitization date and time (may not exist) + std::string SubSecTimeOriginal; // Sub-second time that original picture was taken + std::string Copyright; // File copyright information + double ExposureTime; // Exposure time in seconds + double FNumber; // F/stop + unsigned short ISOSpeedRatings; // ISO speed + double ShutterSpeedValue; // Shutter speed (reciprocal of exposure time) + double ExposureBiasValue; // Exposure bias value in EV + double SubjectDistance; // Distance to focus point in meters + double FocalLength; // Focal length of lens in millimeters + unsigned short FocalLengthIn35mm; // Focal length in 35mm film + char Flash; // 0 = no flash, 1 = flash used + unsigned short MeteringMode; // Metering mode + // 1: average + // 2: center weighted average + // 3: spot + // 4: multi-spot + // 5: multi-segment + unsigned ImageWidth; // Image width reported in EXIF data + unsigned ImageHeight; // Image height reported in EXIF data + struct Geolocation_t { // GPS information embedded in file + double Latitude; // Image latitude expressed as decimal + double Longitude; // Image longitude expressed as decimal + double Altitude; // Altitude in meters, relative to sea level + char AltitudeRef; // 0 = above sea level, -1 = below sea level + double DOP; // GPS degree of precision (DOP) + struct Coord_t { + double degrees; + double minutes; + double seconds; + char direction; + } LatComponents, LonComponents; // Latitude, Longitude expressed in deg/min/sec + } GeoLocation; + struct LensInfo_t { // Lens information + double FStopMin; // Min aperture (f-stop) + double FStopMax; // Max aperture (f-stop) + double FocalLengthMin; // Min focal length (mm) + double FocalLengthMax; // Max focal length (mm) + double FocalPlaneXResolution; // Focal plane X-resolution + double FocalPlaneYResolution; // Focal plane Y-resolution + std::string Make; // Lens manufacturer + std::string Model; // Lens model + } LensInfo; + + + EXIFInfo() { + clear(); + } + time_t epoch(); }; +} + // Parse was successful -#define PARSE_EXIF_SUCCESS 0 +#define PARSE_EXIF_SUCCESS 0 // No JPEG markers found in buffer, possibly invalid JPEG file -#define PARSE_EXIF_ERROR_NO_JPEG 1982 +#define PARSE_EXIF_ERROR_NO_JPEG 1982 // No EXIF header found in JPEG file. -#define PARSE_EXIF_ERROR_NO_EXIF 1983 +#define PARSE_EXIF_ERROR_NO_EXIF 1983 // Byte alignment specified in EXIF file was unknown (not Motorola or Intel). -#define PARSE_EXIF_ERROR_UNKNOWN_BYTEALIGN 1984 +#define PARSE_EXIF_ERROR_UNKNOWN_BYTEALIGN 1984 // EXIF header was found, but data was corrupted. -#define PARSE_EXIF_ERROR_CORRUPT 1985 +#define PARSE_EXIF_ERROR_CORRUPT 1985 -#endif // EXIF_H +#endif diff --git a/core/qthelper.cpp b/core/qthelper.cpp index f9e504ece..39461c7eb 100644 --- a/core/qthelper.cpp +++ b/core/qthelper.cpp @@ -354,7 +354,7 @@ extern "C" xsltStylesheetPtr get_stylesheet(const char *name) extern "C" timestamp_t picture_get_timestamp(char *filename) { - EXIFInfo exif; + easyexif::EXIFInfo exif; memblock mem; int retval; @@ -1211,7 +1211,7 @@ extern "C" void savePictureLocal(struct picture *picture, const char *data, int extern "C" void picture_load_exif_data(struct picture *p) { - EXIFInfo exif; + easyexif::EXIFInfo exif; memblock mem; if (readfile(localFilePath(QString(p->filename)).toUtf8().data(), &mem) <= 0) |