dupeguru/core_pe/exif.py

# Created By: Virgil Dupras
# Created On: 2011-04-20
# Copyright 2012 Hardcoded Software (http://www.hardcoded.net)
# 
# This software is licensed under the "BSD" License as described in the "LICENSE" file, 
# which should be included with this package. The terms are also available at 
# http://www.hardcoded.net/licenses/bsd_license

# Heavily based on http://topo.math.u-psud.fr/~bousch/exifdump.py by Thierry Bousch (Public Domain)

import logging

EXIF_TAGS = {
    0x0100: "ImageWidth",
    0x0101: "ImageLength",
    0x0102: "BitsPerSample",
    0x0103: "Compression",
    0x0106: "PhotometricInterpretation",
    0x010A: "FillOrder",
    0x010D: "DocumentName",
    0x010E: "ImageDescription",
    0x010F: "Make",
    0x0110: "Model",
    0x0111: "StripOffsets",
    0x0112: "Orientation",
    0x0115: "SamplesPerPixel",
    0x0116: "RowsPerStrip",
    0x0117: "StripByteCounts",
    0x011A: "XResolution",
    0x011B: "YResolution",
    0x011C: "PlanarConfiguration",
    0x0128: "ResolutionUnit",
    0x012D: "TransferFunction",
    0x0131: "Software",
    0x0132: "DateTime",
    0x013B: "Artist",
    0x013E: "WhitePoint",
    0x013F: "PrimaryChromaticities",
    0x0156: "TransferRange",
    0x0200: "JPEGProc",
    0x0201: "JPEGInterchangeFormat",
    0x0202: "JPEGInterchangeFormatLength",
    0x0211: "YCbCrCoefficients",
    0x0212: "YCbCrSubSampling",
    0x0213: "YCbCrPositioning",
    0x0214: "ReferenceBlackWhite",
    0x828F: "BatteryLevel",
    0x8298: "Copyright",
    0x829A: "ExposureTime",
    0x829D: "FNumber",
    0x83BB: "IPTC/NAA",
    0x8769: "ExifIFDPointer",
    0x8773: "InterColorProfile",
    0x8822: "ExposureProgram",
    0x8824: "SpectralSensitivity",
    0x8825: "GPSInfoIFDPointer",
    0x8827: "ISOSpeedRatings",
    0x8828: "OECF",
    0x9000: "ExifVersion",
    0x9003: "DateTimeOriginal",
    0x9004: "DateTimeDigitized",
    0x9101: "ComponentsConfiguration",
    0x9102: "CompressedBitsPerPixel",
    0x9201: "ShutterSpeedValue",
    0x9202: "ApertureValue",
    0x9203: "BrightnessValue",
    0x9204: "ExposureBiasValue",
    0x9205: "MaxApertureValue",
    0x9206: "SubjectDistance",
    0x9207: "MeteringMode",
    0x9208: "LightSource",
    0x9209: "Flash",
    0x920A: "FocalLength",
    0x9214: "SubjectArea",
    0x927C: "MakerNote",
    0x9286: "UserComment",
    0x9290: "SubSecTime",
    0x9291: "SubSecTimeOriginal",
    0x9292: "SubSecTimeDigitized",
    0xA000: "FlashPixVersion",
    0xA001: "ColorSpace",
    0xA002: "PixelXDimension",
    0xA003: "PixelYDimension",
    0xA004: "RelatedSoundFile",
    0xA005: "InteroperabilityIFDPointer",
    0xA20B: "FlashEnergy",          # 0x920B in TIFF/EP
    0xA20C: "SpatialFrequencyResponse", # 0x920C    -  -
    0xA20E: "FocalPlaneXResolution",    # 0x920E    -  -
    0xA20F: "FocalPlaneYResolution",    # 0x920F    -  -
    0xA210: "FocalPlaneResolutionUnit", # 0x9210    -  -
    0xA214: "SubjectLocation",      # 0x9214    -  -
    0xA215: "ExposureIndex",        # 0x9215    -  -
    0xA217: "SensingMethod",        # 0x9217    -  -
    0xA300: "FileSource",
    0xA301: "SceneType",
    0xA302: "CFAPattern",           # 0x828E in TIFF/EP
    0xA401: "CustomRendered",
    0xA402: "ExposureMode",
    0xA403: "WhiteBalance",
    0xA404: "DigitalZoomRatio",
    0xA405: "FocalLengthIn35mmFilm",
    0xA406: "SceneCaptureType",
    0xA407: "GainControl",
    0xA408: "Contrast",
    0xA409: "Saturation",
    0xA40A: "Sharpness",
    0xA40B: "DeviceSettingDescription",
    0xA40C: "SubjectDistanceRange",
    0xA420: "ImageUniqueID",
}

INTR_TAGS = {
    0x0001: "InteroperabilityIndex",
    0x0002: "InteroperabilityVersion",
    0x1000: "RelatedImageFileFormat",
    0x1001: "RelatedImageWidth",
    0x1002: "RelatedImageLength",
}

GPS_TA0GS = {
    0x00: "GPSVersionID",
    0x01: "GPSLatitudeRef",
    0x02: "GPSLatitude",
    0x03: "GPSLongitudeRef",
    0x04: "GPSLongitude",
    0x05: "GPSAltitudeRef",
    0x06: "GPSAltitude",
    0x07: "GPSTimeStamp",
    0x08: "GPSSatellites",
    0x09: "GPSStatus",
    0x0A: "GPSMeasureMode",
    0x0B: "GPSDOP",
    0x0C: "GPSSpeedRef",
    0x0D: "GPSSpeed",
    0x0E: "GPSTrackRef",
    0x0F: "GPSTrack",
    0x10: "GPSImgDirectionRef",
    0x11: "GPSImgDirection",
    0x12: "GPSMapDatum",
    0x13: "GPSDestLatitudeRef",
    0x14: "GPSDestLatitude",
    0x15: "GPSDestLongitudeRef",
    0x16: "GPSDestLongitude",
    0x17: "GPSDestBearingRef",
    0x18: "GPSDestBearing",
    0x19: "GPSDestDistanceRef",
    0x1A: "GPSDestDistance",
    0x1B: "GPSProcessingMethod",
    0x1C: "GPSAreaInformation",
    0x1D: "GPSDateStamp",
    0x1E: "GPSDifferential"
}

INTEL_ENDIAN = ord('I')
MOTOROLA_ENDIAN = ord('M')

# About MAX_COUNT: It's possible to have corrupted exif tags where the entry count is way too high
# and thus makes us loop, not endlessly, but for heck of a long time for nothing. Therefore, we put
# an arbitrary limit on the entry count we'll allow ourselves to read and any IFD reporting more
# entries than that will be considered corrupt.
MAX_COUNT = 0xffff

def s2n_motorola(bytes):
    x = 0
    for c in bytes:
        x = (x << 8) | c
    return x

def s2n_intel(bytes):
    x = 0
    y = 0
    for c in bytes:
        x = x | (c << y)
        y = y + 8
    return x

class Fraction:
    def __init__(self, num, den):
        self.num = num
        self.den = den

    def __repr__(self):
        return '%d/%d' % (self.num, self.den)
    

class TIFF_file:
    def __init__(self, data):
        self.data = data
        self.endian = data[0]
        self.s2nfunc = s2n_intel if self.endian == INTEL_ENDIAN else s2n_motorola

    def s2n(self, offset, length, signed=0, debug=False):
        slice = self.data[offset:offset+length]
        val = self.s2nfunc(slice)
        # Sign extension ?
        if signed:
            msb = 1 << (8*length - 1)
            if val & msb:
                val = val - (msb << 1)
        if debug:
            logging.debug(self.endian)
            logging.debug("Slice for offset %d length %d: %r and value: %d", offset, length, slice, val)
        return val
    
    def first_IFD(self):
        return self.s2n(4, 4)
    
    def next_IFD(self, ifd):
        entries = self.s2n(ifd, 2)
        return self.s2n(ifd + 2 + 12 * entries, 4)
    
    def list_IFDs(self):
        i = self.first_IFD()
        a = []
        while i:
            a.append(i)
            i = self.next_IFD(i)
        return a
    
    def dump_IFD(self, ifd):
        entries = self.s2n(ifd, 2)
        logging.debug("Entries for IFD %d: %d", ifd, entries)
        if entries > MAX_COUNT:
            logging.debug("Probably corrupt. Aborting.")
            return []
        a = []
        for i in range(entries):
            entry = ifd + 2 + 12*i
            tag = self.s2n(entry, 2)
            type = self.s2n(entry+2, 2)
            if not 1 <= type <= 10:
                continue # not handled
            typelen = [ 1, 1, 2, 4, 8, 1, 1, 2, 4, 8 ] [type-1]
            count = self.s2n(entry+4, 4)
            if count > MAX_COUNT:
                logging.debug("Probably corrupt. Aborting.")
                return []
            offset = entry+8
            if count*typelen > 4:
                offset = self.s2n(offset, 4)
            if type == 2:
                # Special case: nul-terminated ASCII string
                values = str(self.data[offset:offset+count-1], encoding='latin-1')
            else:
                values = []
                signed = (type == 6 or type >= 8)
                for j in range(count):
                    if type in {5, 10}:
                        # The type is either 5 or 10
                        value_j = Fraction(self.s2n(offset,   4, signed),
                                           self.s2n(offset+4, 4, signed))
                    else:
                        # Not a fraction
                        value_j = self.s2n(offset, typelen, signed)
                    values.append(value_j)
                    offset = offset + typelen
            # Now "values" is either a string or an array
            a.append((tag,type,values))
        return a

def read_exif_header(fp):
    # If `fp`'s first bytes are not exif, it tries to find it in the next 4kb
    def isexif(data):
        return data[0:4] == b'\377\330\377\341' and data[6:10] == b'Exif'
    data = fp.read(12)
    if isexif(data):
        return data
    # ok, not exif, try to find it
    large_data = fp.read(4096)
    try:
        index = large_data.index(b'Exif')
        data = large_data[index-6:index+6]
        # large_data omits the first 12 bytes, and the index is at the middle of the header, so we
        # must seek index + 18
        fp.seek(index+18)
        return data
    except ValueError:
        raise ValueError("Not an Exif file")

def get_fields(fp):
    data = read_exif_header(fp)
    length = data[4] * 256 + data[5]
    logging.debug("Exif header length: %d bytes", length)
    data = fp.read(length-8)
    data_format = data[0]
    logging.debug("%s format", {INTEL_ENDIAN:'Intel', MOTOROLA_ENDIAN:'Motorola'}[data_format])
    T = TIFF_file(data)
    # There may be more than one IFD per file, but we only read the first one because others are
    # most likely thumbnails.
    main_IFD_offset = T.first_IFD()
    result = {}
    
    def add_tag_to_result(tag, values):
        try:
            stag = EXIF_TAGS[tag]
        except KeyError:
            stag = '0x%04X' % tag
        if stag in result:
            return # don't overwrite data
        result[stag] = values
    
    logging.debug("IFD at offset %d", main_IFD_offset)
    IFD = T.dump_IFD(main_IFD_offset)
    exif_off = gps_off = 0
    for tag, type, values in IFD:
        if tag == 0x8769:
            exif_off = values[0]
            continue
        if tag == 0x8825:
            gps_off = values[0]
            continue
        add_tag_to_result(tag, values)
    if exif_off:
        logging.debug("Exif SubIFD at offset %d:", exif_off)
        IFD = T.dump_IFD(exif_off)
        # Recent digital cameras have a little subdirectory
        # here, pointed to by tag 0xA005. Apparently, it's the
        # "Interoperability IFD", defined in Exif 2.1 and DCF.
        intr_off = 0
        for tag, type, values in IFD:
            if tag == 0xA005:
                intr_off = values[0]
                continue
            add_tag_to_result(tag, values)
        if intr_off:
            logging.debug("Exif Interoperability SubSubIFD at offset %d:", intr_off)
            IFD = T.dump_IFD(intr_off)
            for tag, type, values in IFD:
                add_tag_to_result(tag, values)
    if gps_off:
        logging.debug("GPS SubIFD at offset %d:", gps_off)
        IFD = T.dump_IFD(gps_off)
        for tag, type, values in IFD:
            add_tag_to_result(tag, values)
    return result
Added core_pe.exif to read exif data from pictures 2011-04-20 13:19:12 +00:00			`# Created By: Virgil Dupras`
			`# Created On: 2011-04-20`
Changed copyright year to 2012 2012-03-15 18:28:40 +00:00			`# Copyright 2012 Hardcoded Software (http://www.hardcoded.net)`
Added core_pe.exif to read exif data from pictures 2011-04-20 13:19:12 +00:00			`#`
			`# This software is licensed under the "BSD" License as described in the "LICENSE" file,`
			`# which should be included with this package. The terms are also available at`
			`# http://www.hardcoded.net/licenses/bsd_license`

			`# Heavily based on http://topo.math.u-psud.fr/~bousch/exifdump.py by Thierry Bousch (Public Domain)`

			`import logging`

			`EXIF_TAGS = {`
			`0x0100: "ImageWidth",`
			`0x0101: "ImageLength",`
			`0x0102: "BitsPerSample",`
			`0x0103: "Compression",`
			`0x0106: "PhotometricInterpretation",`
			`0x010A: "FillOrder",`
			`0x010D: "DocumentName",`
			`0x010E: "ImageDescription",`
			`0x010F: "Make",`
			`0x0110: "Model",`
			`0x0111: "StripOffsets",`
			`0x0112: "Orientation",`
			`0x0115: "SamplesPerPixel",`
			`0x0116: "RowsPerStrip",`
			`0x0117: "StripByteCounts",`
			`0x011A: "XResolution",`
			`0x011B: "YResolution",`
			`0x011C: "PlanarConfiguration",`
			`0x0128: "ResolutionUnit",`
			`0x012D: "TransferFunction",`
			`0x0131: "Software",`
			`0x0132: "DateTime",`
			`0x013B: "Artist",`
			`0x013E: "WhitePoint",`
			`0x013F: "PrimaryChromaticities",`
			`0x0156: "TransferRange",`
			`0x0200: "JPEGProc",`
			`0x0201: "JPEGInterchangeFormat",`
			`0x0202: "JPEGInterchangeFormatLength",`
			`0x0211: "YCbCrCoefficients",`
			`0x0212: "YCbCrSubSampling",`
			`0x0213: "YCbCrPositioning",`
			`0x0214: "ReferenceBlackWhite",`
			`0x828F: "BatteryLevel",`
			`0x8298: "Copyright",`
			`0x829A: "ExposureTime",`
			`0x829D: "FNumber",`
			`0x83BB: "IPTC/NAA",`
			`0x8769: "ExifIFDPointer",`
			`0x8773: "InterColorProfile",`
			`0x8822: "ExposureProgram",`
			`0x8824: "SpectralSensitivity",`
			`0x8825: "GPSInfoIFDPointer",`
			`0x8827: "ISOSpeedRatings",`
			`0x8828: "OECF",`
			`0x9000: "ExifVersion",`
			`0x9003: "DateTimeOriginal",`
			`0x9004: "DateTimeDigitized",`
			`0x9101: "ComponentsConfiguration",`
			`0x9102: "CompressedBitsPerPixel",`
			`0x9201: "ShutterSpeedValue",`
			`0x9202: "ApertureValue",`
			`0x9203: "BrightnessValue",`
			`0x9204: "ExposureBiasValue",`
			`0x9205: "MaxApertureValue",`
			`0x9206: "SubjectDistance",`
			`0x9207: "MeteringMode",`
			`0x9208: "LightSource",`
			`0x9209: "Flash",`
			`0x920A: "FocalLength",`
			`0x9214: "SubjectArea",`
			`0x927C: "MakerNote",`
			`0x9286: "UserComment",`
			`0x9290: "SubSecTime",`
			`0x9291: "SubSecTimeOriginal",`
			`0x9292: "SubSecTimeDigitized",`
			`0xA000: "FlashPixVersion",`
			`0xA001: "ColorSpace",`
			`0xA002: "PixelXDimension",`
			`0xA003: "PixelYDimension",`
			`0xA004: "RelatedSoundFile",`
			`0xA005: "InteroperabilityIFDPointer",`
			`0xA20B: "FlashEnergy", # 0x920B in TIFF/EP`
			`0xA20C: "SpatialFrequencyResponse", # 0x920C - -`
			`0xA20E: "FocalPlaneXResolution", # 0x920E - -`
			`0xA20F: "FocalPlaneYResolution", # 0x920F - -`
			`0xA210: "FocalPlaneResolutionUnit", # 0x9210 - -`
			`0xA214: "SubjectLocation", # 0x9214 - -`
			`0xA215: "ExposureIndex", # 0x9215 - -`
			`0xA217: "SensingMethod", # 0x9217 - -`
			`0xA300: "FileSource",`
			`0xA301: "SceneType",`
			`0xA302: "CFAPattern", # 0x828E in TIFF/EP`
			`0xA401: "CustomRendered",`
			`0xA402: "ExposureMode",`
			`0xA403: "WhiteBalance",`
			`0xA404: "DigitalZoomRatio",`
			`0xA405: "FocalLengthIn35mmFilm",`
			`0xA406: "SceneCaptureType",`
			`0xA407: "GainControl",`
			`0xA408: "Contrast",`
			`0xA409: "Saturation",`
			`0xA40A: "Sharpness",`
			`0xA40B: "DeviceSettingDescription",`
			`0xA40C: "SubjectDistanceRange",`
			`0xA420: "ImageUniqueID",`
			`}`

			`INTR_TAGS = {`
			`0x0001: "InteroperabilityIndex",`
			`0x0002: "InteroperabilityVersion",`
			`0x1000: "RelatedImageFileFormat",`
			`0x1001: "RelatedImageWidth",`
			`0x1002: "RelatedImageLength",`
			`}`

			`GPS_TA0GS = {`
			`0x00: "GPSVersionID",`
			`0x01: "GPSLatitudeRef",`
			`0x02: "GPSLatitude",`
			`0x03: "GPSLongitudeRef",`
			`0x04: "GPSLongitude",`
			`0x05: "GPSAltitudeRef",`
			`0x06: "GPSAltitude",`
			`0x07: "GPSTimeStamp",`
			`0x08: "GPSSatellites",`
			`0x09: "GPSStatus",`
			`0x0A: "GPSMeasureMode",`
			`0x0B: "GPSDOP",`
			`0x0C: "GPSSpeedRef",`
			`0x0D: "GPSSpeed",`
			`0x0E: "GPSTrackRef",`
			`0x0F: "GPSTrack",`
			`0x10: "GPSImgDirectionRef",`
			`0x11: "GPSImgDirection",`
			`0x12: "GPSMapDatum",`
			`0x13: "GPSDestLatitudeRef",`
			`0x14: "GPSDestLatitude",`
			`0x15: "GPSDestLongitudeRef",`
			`0x16: "GPSDestLongitude",`
			`0x17: "GPSDestBearingRef",`
			`0x18: "GPSDestBearing",`
			`0x19: "GPSDestDistanceRef",`
			`0x1A: "GPSDestDistance",`
			`0x1B: "GPSProcessingMethod",`
			`0x1C: "GPSAreaInformation",`
			`0x1D: "GPSDateStamp",`
			`0x1E: "GPSDifferential"`
			`}`

			`INTEL_ENDIAN = ord('I')`
			`MOTOROLA_ENDIAN = ord('M')`

Fixed a bug where corrupt exif tags would make the analysis process stall. 2011-06-14 19:05:33 +00:00			`# About MAX_COUNT: It's possible to have corrupted exif tags where the entry count is way too high`
			`# and thus makes us loop, not endlessly, but for heck of a long time for nothing. Therefore, we put`
			`# an arbitrary limit on the entry count we'll allow ourselves to read and any IFD reporting more`
			`# entries than that will be considered corrupt.`
			`MAX_COUNT = 0xffff`

Added core_pe.exif to read exif data from pictures 2011-04-20 13:19:12 +00:00			`def s2n_motorola(bytes):`
			`x = 0`
			`for c in bytes:`
			`x = (x << 8) \| c`
			`return x`

			`def s2n_intel(bytes):`
			`x = 0`
			`y = 0`
			`for c in bytes:`
			`x = x \| (c << y)`
			`y = y + 8`
			`return x`

			`class Fraction:`
			`def __init__(self, num, den):`
			`self.num = num`
			`self.den = den`

			`def __repr__(self):`
			`return '%d/%d' % (self.num, self.den)`


			`class TIFF_file:`
			`def __init__(self, data):`
			`self.data = data`
			`self.endian = data[0]`
			`self.s2nfunc = s2n_intel if self.endian == INTEL_ENDIAN else s2n_motorola`

			`def s2n(self, offset, length, signed=0, debug=False):`
			`slice = self.data[offset:offset+length]`
			`val = self.s2nfunc(slice)`
			`# Sign extension ?`
			`if signed:`
			`msb = 1 << (8*length - 1)`
			`if val & msb:`
			`val = val - (msb << 1)`
			`if debug:`
			`logging.debug(self.endian)`
			`logging.debug("Slice for offset %d length %d: %r and value: %d", offset, length, slice, val)`
			`return val`

			`def first_IFD(self):`
			`return self.s2n(4, 4)`

			`def next_IFD(self, ifd):`
			`entries = self.s2n(ifd, 2)`
			`return self.s2n(ifd + 2 + 12 * entries, 4)`

			`def list_IFDs(self):`
			`i = self.first_IFD()`
			`a = []`
			`while i:`
			`a.append(i)`
			`i = self.next_IFD(i)`
			`return a`

			`def dump_IFD(self, ifd):`
			`entries = self.s2n(ifd, 2)`
			`logging.debug("Entries for IFD %d: %d", ifd, entries)`
Fixed a bug where corrupt exif tags would make the analysis process stall. 2011-06-14 19:05:33 +00:00			`if entries > MAX_COUNT:`
			`logging.debug("Probably corrupt. Aborting.")`
			`return []`
Added core_pe.exif to read exif data from pictures 2011-04-20 13:19:12 +00:00			`a = []`
			`for i in range(entries):`
			`entry = ifd + 2 + 12*i`
			`tag = self.s2n(entry, 2)`
			`type = self.s2n(entry+2, 2)`
			`if not 1 <= type <= 10:`
			`continue # not handled`
			`typelen = [ 1, 1, 2, 4, 8, 1, 1, 2, 4, 8 ] [type-1]`
			`count = self.s2n(entry+4, 4)`
Fixed a bug where corrupt exif tags would make the analysis process stall. 2011-06-14 19:05:33 +00:00			`if count > MAX_COUNT:`
			`logging.debug("Probably corrupt. Aborting.")`
			`return []`
Added core_pe.exif to read exif data from pictures 2011-04-20 13:19:12 +00:00			`offset = entry+8`
			`if count*typelen > 4:`
			`offset = self.s2n(offset, 4)`
			`if type == 2:`
			`# Special case: nul-terminated ASCII string`
			`values = str(self.data[offset:offset+count-1], encoding='latin-1')`
			`else:`
			`values = []`
			`signed = (type == 6 or type >= 8)`
			`for j in range(count):`
			`if type in {5, 10}:`
			`# The type is either 5 or 10`
			`value_j = Fraction(self.s2n(offset, 4, signed),`
			`self.s2n(offset+4, 4, signed))`
			`else:`
			`# Not a fraction`
			`value_j = self.s2n(offset, typelen, signed)`
			`values.append(value_j)`
			`offset = offset + typelen`
			`# Now "values" is either a string or an array`
			`a.append((tag,type,values))`
			`return a`

			`def read_exif_header(fp):`
			# If `fp`'s first bytes are not exif, it tries to find it in the next 4kb
			`def isexif(data):`
			`return data[0:4] == b'\377\330\377\341' and data[6:10] == b'Exif'`
			`data = fp.read(12)`
			`if isexif(data):`
			`return data`
			`# ok, not exif, try to find it`
			`large_data = fp.read(4096)`
			`try:`
			`index = large_data.index(b'Exif')`
			`data = large_data[index-6:index+6]`
			`# large_data omits the first 12 bytes, and the index is at the middle of the header, so we`
			`# must seek index + 18`
			`fp.seek(index+18)`
			`return data`
			`except ValueError:`
			`raise ValueError("Not an Exif file")`

			`def get_fields(fp):`
			`data = read_exif_header(fp)`
			`length = data[4] * 256 + data[5]`
			`logging.debug("Exif header length: %d bytes", length)`
			`data = fp.read(length-8)`
			`data_format = data[0]`
			`logging.debug("%s format", {INTEL_ENDIAN:'Intel', MOTOROLA_ENDIAN:'Motorola'}[data_format])`
			`T = TIFF_file(data)`
			`# There may be more than one IFD per file, but we only read the first one because others are`
			`# most likely thumbnails.`
			`main_IFD_offset = T.first_IFD()`
			`result = {}`

			`def add_tag_to_result(tag, values):`
			`try:`
			`stag = EXIF_TAGS[tag]`
			`except KeyError:`
			`stag = '0x%04X' % tag`
			`if stag in result:`
			`return # don't overwrite data`
			`result[stag] = values`

			`logging.debug("IFD at offset %d", main_IFD_offset)`
			`IFD = T.dump_IFD(main_IFD_offset)`
			`exif_off = gps_off = 0`
			`for tag, type, values in IFD:`
			`if tag == 0x8769:`
			`exif_off = values[0]`
			`continue`
			`if tag == 0x8825:`
			`gps_off = values[0]`
			`continue`
			`add_tag_to_result(tag, values)`
			`if exif_off:`
			`logging.debug("Exif SubIFD at offset %d:", exif_off)`
			`IFD = T.dump_IFD(exif_off)`
			`# Recent digital cameras have a little subdirectory`
			`# here, pointed to by tag 0xA005. Apparently, it's the`
			`# "Interoperability IFD", defined in Exif 2.1 and DCF.`
			`intr_off = 0`
			`for tag, type, values in IFD:`
			`if tag == 0xA005:`
			`intr_off = values[0]`
			`continue`
			`add_tag_to_result(tag, values)`
			`if intr_off:`
			`logging.debug("Exif Interoperability SubSubIFD at offset %d:", intr_off)`
			`IFD = T.dump_IFD(intr_off)`
			`for tag, type, values in IFD:`
			`add_tag_to_result(tag, values)`
			`if gps_off:`
			`logging.debug("GPS SubIFD at offset %d:", gps_off)`
			`IFD = T.dump_IFD(gps_off)`
			`for tag, type, values in IFD:`
			`add_tag_to_result(tag, values)`
			`return result`