|FormatType (bitmask 0xf0):||
0x00 - other (or unknown) data 0x10 - MIE group 0x20 - text string 0x30 - list of null-separated text strings 0x40 - integer 0x50 - rational 0x60 - fixed point 0x70 - floating point 0x80 - free space
|TypeModifier (bitmask 0x08):||
Modifies the meaning of certain FormatTypes (0x00-0x60):
|Compressed (bitmask 0x04):||If this bit is set, the data block is compressed using Zlib deflate. An entire MIE group may be compressed, with the exception of file-level groups.|
|FormatSize (bitmask 0x03):||
Gives the byte size of each data element:
The number of bytes in a single value for this format is given by 2**FormatSize (or 1 << FormatSize). The number of values is the data length divided by this number of bytes. It is an error if the data length is not an even multiple of the format size in bytes.
0x00 - other data (insensitive to MIE group byte order) (1)
0x01 - other 16-bit data (may be byte swapped)
0x02 - other 32-bit data (may be byte swapped)
0x03 - other 64-bit data (may be byte swapped)
0x08 - other data (sensitive to MIE group byte order) (1)
0x10 - MIE group with big-endian values (1)
0x18 - MIE group with little-endian values (1)
0x20 - ASCII (ISO 8859-1) string (2,3)
0x28 - UTF-8 string (2,3,4)
0x29 - UTF-16 string (2,3,4)
0x2a - UTF-32 string (2,3,4)
0x30 - ASCII (ISO 8859-1) string list (3,5)
0x38 - UTF-8 string list (3,4,5)
0x39 - UTF-16 string list (3,4,5)
0x3a - UTF-32 string list (3,4,5)
0x40 - unsigned 8-bit integer
0x41 - unsigned 16-bit integer
0x42 - unsigned 32-bit integer
0x43 - unsigned 64-bit integer (6)
0x48 - signed 8-bit integer
0x49 - signed 16-bit integer
0x4a - signed 32-bit integer
0x4b - signed 64-bit integer (6)
0x52 - unsigned 32-bit rational (16-bit numerator then denominator) (7)
0x53 - unsigned 64-bit rational (32-bit numerator then denominator) (7)
0x5a - signed 32-bit rational (denominator is unsigned) (7)
0x5b - signed 64-bit rational (denominator is unsigned) (7)
0x61 - unsigned 16-bit fixed-point (high 8 bits is integer part) (8)
0x62 - unsigned 32-bit fixed-point (high 16 bits is integer part) (8)
0x69 - signed 16-bit fixed-point (high 8 bits is signed integer) (8)
0x6a - signed 32-bit fixed-point (high 16 bits is signed integer) (8)
0x72 - 32-bit IEEE float (not recommended for portability reasons)
0x73 - 64-bit IEEE double (not recommended for portability reasons) (6)
0x80 - free space (value data does not contain useful information)
The byte ordering specified by the MIE group TypeModifier applies to the MIE
group element as well as all elements within the group. Data for all
FormatCodes except 0x08 (other data, sensitive to byte order) may be
transferred between MIE groups with different byte order by byte swapping
the uncompressed data according to the specified data format. The following
list illustrates the byte-swapping pattern, based on FormatSize, for all
format types except rational (FormatType 0x50).
Rational values consist of two integers, so they are swapped as the next lower FormatSize. For example, a 32-bit rational (FormatSize 0x02, and FormatCode 0x52 or 0x5a) is swapped as two 16-bit values (ie. as if it had FormatSize 0x01).
|2.||The TagName of a string element may have an 6-character suffix to indicate a specific locale. (eg. Title-en_US, or Keywords-de_DE).|
|3.||Text strings are not normally null terminated, however they may be padded with one or more null characters to the end of the data block to allow strings to be edited within fixed-length data blocks. Newlines in the text are indicated by a single LF (0x0a) character.|
|4.||UTF strings must not begin with a byte order mark (BOM) since the byte order and byte size are specified by the MIE format. If a BOM is found, it should be treated as a zero-width non-breaking space.|
|5.||A list of text strings separated by null characters. These lists must not be null padded or null terminated, since this would be interpreted as additional zero-length strings. For ASCII and UTF-8 strings, the null character is a single zero (0x00) byte. For UTF-16 or UTF-32 strings, the null character is 2 or 4 zero bytes respectively.|
|6.||64-bit integers and doubles are subject to the specified byte ordering for both 32-bit words and bytes within these words. For instance, the high order byte is always the first byte if big-endian, and the eighth byte if little-endian. This means that some swapping is always necessary for these values on systems where the byte order differs from the word order (eg. some ARM systems), regardless of the endian-ness of the stored values.|
|7.||Rational values are treated as two separate integers. The numerator always comes first regardless of the byte ordering. In a signed rational value, only the numerator is signed. The denominator of all rational values is unsigned (eg. a signed 64-bit rational of 0x80000000/0x80000000 evaluates to -1, not +1).|
|8.||32-bit fixed point values are converted to floating point by treating them as an integer and dividing by an appropriate value. eg)|
Gives the length of the TagName string. Any value between 0 and 255 is valid, but the TagLength of 0 is valid only for the MIE group terminator.
DataLength is an unsigned byte that gives the number of bytes in the data block. A value between 0 and 252 gives the data length directly, and numbers from 253 to 255 are reserved for extended DataLength codes. Codes of 255, 254 and 253 indicate that the element contains an additional 2, 4 or 8 byte unsigned integer representing the data length.
0-252 - length of data block
255 (0xff) - use DataLength2
254 (0xfe) - use DataLength4
253 (0xfd) - use DataLength8
A DataLength of zero is valid for any element except a compressed MIE group. A zero DataLength for an uncompressed MIE group indicates that the group length is unknown. For other elements, a zero length indicates there is no associated data. A terminator element must have a DataLength of 0, 6 or 10, and may not use an extended DataLength.
The TagName string is 0 to 255 bytes long, and is composed of the ASCII characters A-Z, a-z, 0-9 and underline (_). Also, a dash (-) is used to separate the language/country code in the TagName of a localized text string, and a units string (possibly containing other ASCII characters) may be appear in brackets at the end of the TagName. The TagName string is NOT null terminated. A MIE element with a tag string of zero length is reserved for the group terminator.
MIE elements are sorted alphabetically by TagName within each group. Multiple elements with the same TagName are allowed, even within the same group.
TagNames should be meaningful. Case is significant. Words should be lowercase with an uppercase first character, and acronyms should be all upper case. The underline (_) is provided to allow separation of two acronyms or two numbers, but it shouldnt be used unless necessary. No separation is necessary between an acronym and a word (eg. ISOSetting).
All TagNames should start with an uppercase letter. An exception to this rule allows tags to begin with a digit (0-9) if they must come before other tags in the sort order, or a lowercase letter (a-z) if they must come after. For instance, the 0Type element begins with a digit so it comes before, and the data element begins with a lowercase letter so that it comes after meta information tags in the main 0MIE group.
Tag names for localized text strings have an 6-character suffix with the following format: The first character is a dash (-), followed by a 2-character lower case ISO 639-1 language code, then an underline (_), and ending with a 2-character upper case ISO 3166-1 alpha 2 country code. (eg. -en_US, -en_GB, -de_DE or -fr_FR. Note that GB, and not UK is the code for Great Britain, although UK should be recognized for compatibility reasons.) The suffix is included when sorting the tags alphabetically, so the default locale (with no tag-name suffix) always comes first. If the country is unknown or not applicable, a country code of XX should be used.
Tags with numerical values may allow units of measurement to be specified. The units string is stored in brackets at the end of the tag name, and is composed of zero or more ASCII characters in the range 0x21 to 0x7d, excluding the bracket characters 0x28 and 0x29. (eg. Resolution(/cm) or SpecificHeat(J/kg.K).) See Image::ExifTool::MIEUnits for details. Unit strings are not localized, and may not be used in combination with localized text strings.
Sets of tags which would require a common prefix should be added in a separate MIE group instead of adding the prefix to all tag names. For example, instead of these TagNames:
one would instead designate a separate ExternalFlash MIE group to contain the following elements:
These extended DataLength fields exist only if DataLength is 255, 254 or 253, and are respectively 2, 4 or 8 byte unsigned integers giving the data block length. One of these values must be used if the data block is larger than 252 bytes, but they may be used if desired for smaller blocks too (although this may add a few unnecessary bytes to the MIE element).
The data value for the MIE element. The format of the data is given by the FormatCode. For MIE group elements, the data includes all contained elements and the group terminator.
All MIE data elements must be contained within a group. A group begins with a MIE group element, and ends with a group terminator. Groups may be nested in a hierarchy to arbitrary depth.
A MIE group element is identified by a format code of 0x10 (big endian byte ordering) or 0x18 (little endian). The group terminator is distinguished by a zero TagLength (it is the only element allowed to have a zero TagLength), and has a FormatCode of 0x00.
The MIE group element is permitted to have a zero DataLength only if the data is uncompressed. This special value indicates that the group length is unknown (otherwise the minimum value for DataLength is 4, corresponding the the minimum group size which includes a terminator of at least 4 bytes). If DataLength is zero, all elements in the group must be parsed until the group terminator is found. If non-zero, DataLength includes the length of all elements contained within the group, including the group terminator. Use of a non-zero DataLength is encouraged because it allows readers quickly skip over entire MIE groups. For compressed groups DataLength must be non-zero, and is the length of the compressed group data (which includes the compressed group terminator).
The group terminator has a FormatCode and TagLength of zero. The terminator DataLength must be 0, 6 or 10 bytes, and extended DataLength codes may not be used. With a zero DataLength, the byte sequence for a terminator is 7e 00 00 00 (hex). With a DataLength of 6 or 10 bytes, the terminator data block contains information about the length and byte ordering of the preceding group. This additional information is recommended for file-level groups, and is used in multi-document MIE files and MIE trailers to allow the file to be scanned backwards from the end. (This may also allow some documents to be recovered if part of the file is corrupted.) The structure of this optional terminator data block is as follows:
The ByteOrder and GroupLengthSize values give the byte ordering and size of the GroupLength integer. The GroupLength value is the total length of the entire MIE group ending with this terminator, including the opening MIE group element and the terminator itself.
File-level MIE groups
File-level MIE groups may NOT be compressed.
All elements in a MIE file are contained within a special group with a TagName of 0MIE. The purpose of the OMIE group is to provide a unique signature at the start of the file, and to encapsulate information allowing files to be easily combined. The 0MIE group must be terminated like any other group, but it is recommended that the terminator of a file-level group include the optional data block (defined above) to provide information about the group length and byte order.
It is valid to have more than one 0MIE group at the file level, allowing multiple documents in a single MIE file. Furthermore, the MIE structure enables multi-document files to be generated by simply concatenating two or more MIE files.
The steps below give an algorithm to quickly locate the last document in a MIE file:
This algorithm may be repeated again beginning at this point in the file to locate the next-to-last document, etc.
1. Read the last 10 bytes of the file. (Note that a valid MIE file may be as short as 12 bytes long, but a file this length contains only an an empty MIE group.) 2. If the last byte of the file is zero, then it is not possible to scan backward through the file, so the file must be scanned from the beginning. Otherwise, proceed to the next step. 3. If the last byte is 4 or 8, the terminator contains information about the byte ordering and length of the group. Otherwise, stop here because this isnt a valid MIE file. 4. The next-to-last byte must be either 0x10 indicating big-endian byte ordering or 0x18 for little-endian ordering, otherwise this isnt a valid MIE file. 5. The value of the preceding 4 or 8 bytes gives the length of the complete file-level MIE group (GroupLength). This length includes both the leading MIE group element and the terminator element itself. The value is an unsigned integer with a byte length given in step 3), and a byte order from step 4). From the current file position (at the end of the data read in step 1), seek backward by this number of bytes to find the start of the MIE group element for this document.
The table below lists all 5 valid patterns for the last 14 bytes of a file-level MIE group, with all numbers in hex. The comments indicate the length and byte ordering of GroupLength (xx) if available:
?? ?? ?? ?? ?? ?? ?? ?? ?? ?? 7e 00 00 00 - (no GroupLength) ?? ?? ?? ?? 7e 00 00 06 xx xx xx xx 10 04 - 4 bytes, big endian ?? ?? ?? ?? 7e 00 00 06 xx xx xx xx 18 04 - 4 bytes, little endian 7e 00 00 0a xx xx xx xx xx xx xx xx 10 08 - 8 bytes, big endian 7e 00 00 0a xx xx xx xx xx xx xx xx 18 08 - 8 bytes, little endian
The MIE format may be used for trailer information appended to other types of files. When this is done, a signature must appear at the end of the main MIE group to uniquely identify the MIE format trailer. To achieve this, a zmie trailer signature is written as the last element in the main 0MIE group. This element has a FormatCode of 0, a TagLength of 4, a DataLength of 0, and a TagName of zmie. With this signature, the hex byte sequence 7e 00 04 00 7a 6d 69 65 appears immediately before the final group terminator, and the last 22 bytes of the trailer correspond to one of the following 4 patterns (where the trailer length is given by xx, as above):
?? ?? ?? ?? 7e 00 04 00 7a 6d 69 65 7e 00 00 06 xx xx xx xx 10 04 ?? ?? ?? ?? 7e 00 04 00 7a 6d 69 65 7e 00 00 06 xx xx xx xx 18 04 7e 00 04 00 7a 6d 69 65 7e 00 00 0a xx xx xx xx xx xx xx xx 10 08 7e 00 04 00 7a 6d 69 65 7e 00 00 0a xx xx xx xx xx xx xx xx 18 08
Note that the zero-DataLength terminator may not be used here because the trailer length must be known for seeking backwards from the end of the file.
Multiple trailers may be appended to the same file using this technique.
MIE data values for a given tag are usually not restricted to a specific FormatCode. Any value may be represented in any appropriate format, including numbers represented in string (ASCII or UTF) form.
It is preferred that closely related values with the same format are written to a single tag instead of using multiple tags. This improves localization of like values and decreases MIE element overhead. For instance, instead of separate ImageWidth and ImageHeight tags, a single ImageSize tag is defined.
Tags which may take on a discrete set of values should have meaningful values if possible. This improves the extensibility of the format and allows a more reasonable interpretation of unrecognized values.
Integer and floating point numbers may be represented in binary or string form. In string form, integers are a series of digits with an optional leading sign (eg. [+|-]DDDDDD), and multiple values are separated by a single space character (eg. 23 128 -32). Floating point numbers are similar but may also contain a decimal point and/or a signed exponent with a leading e character (eg. [+|-]DD[.DDDDDD][e(+|-)EEE]). The string inf is used to represent infinity. One advantage of numerical strings is that they can have an arbitrarily high precision because the possible number of significant digits is virtually unlimited.
Note that numerical values may have associated units of measurement which are specified in the TagName string.
All MIE dates are strings in the form YYYY:mm:dd HH:MM:SS.ss+HH:MM. The fractional seconds (.ss) are optional, and if included may contain any number of significant digits (unlike all other fields which are a fixed number of digits and must be padded with leading zeros if necessary). The timezone (+HH:MM or -HH:MM) is recommended but not required. If not given, the local system timezone is assumed.
The basic MIME type for a MIE file is application/x-mie, however the specific MIME type depends on the type of subfile, and is obtained by adding x-mie- to the MIME type of the subfile. For example, with a subfile of type image/jpeg, the MIE file MIME type is image/x-mie-jpeg. But note that the x- is not duplicated if the subfile MIME type already starts with x-. So a subfile with MIME type image/x-raw is contained within a MIE file of type image/x-mie-raw, not image/x-mie-x-raw. In the case of multiple documents in a MIE file, the MIME type is taken from the first document. Regardless of the subfile type, all MIE-format files should have a filename extension of .MIE.
Basic MIE reader/writer applications may choose not to provide support for some advanced features of the MIE format. Features which may not be supported by all software are:
Compression Software not supporting compression must ignore compressed elements and groups, but should be able to process the remaining information. Large data lengths Some software may limit the maximum size of a MIE group or element. Historically, a limit of 2GB may be imposed by some systems. However, 8-byte data lengths should be supported by all applications provided the value doesnt exceed the system limit. (eg. For systems with a 2GB limit, 8-byte data lengths should be supported if the upper 17 bits are all zero.) If a data length above the system limit is encountered, it may be necessary for the application to stop processing if it can not seek to the next element in the file.
This section gives examples for working with MIE information using ExifTool.
The following command encapsulates any file recognized by ExifTool inside a MIE file, and initializes MIE tags from information within the file:
where FILE is the name of the file.
For unrecognized files, this command may be used:
exiftool -o new.mie -subfilename=FILE -subfiletype=TYPE \ -subfilemimetype=MIME -subfiledata<=FILE
where TYPE and MIME represent the source file type and MIME type respectively.
The MIE format may also be used to store information in a trailer appended to another type of file. Beware that trailers may not be compatible with all file formats, but JPEG and TIFF are two formats where additional trailer information doesnt create any problems for normal parsing of the file. Also note that this technique has the disadvantage that trailer information is commonly lost if the file is subsequently edited by other software.
Creating a MIE trailer with ExifTool is a two-step process since ExifTool cant currently be used to add a MIE trailer directly. The example below illustrates the steps for adding a MIE trailer with a small preview image (small.jpg) to a destination JPEG image (dst.jpg).
Step 1) Create a MIE file with a TrailerSignature containing the desired information:
exiftool -o new.mie -trailersignature=1 -tagsfromfile small.jpg \ -previewimagetype<filetype -previewimagesize<imagesize \ -previewimagename<filename -previewimage<=small.jpg
Step 2) Append the MIE information to another file. In Unix, this can be done with the cat command:
cat new.mie >> dst.jpg
Once added, ExifTool may be used to edit or delete a MIE trailer in a JPEG or TIFF image.
The MIE specification allows multiple MIE documents (or trailers) to exist in a single file. A file like this may be created by simply concatenating MIE documents. ExifTool may be used to access information in a specific document by adding a copy number to the MIE group name. For example:
Some MIE tags allow values to be specified in different units of measurement. In the MIE file format these units are combined with the tag name, but when using ExifTool they are specified in brackets after the value:
exiftool -mie:gpsaltitude=7500(ft) test.mie
If no units are provided, the default units are written.
Localized text values are accessed by adding a language/country code to the tag name. For example:
exiftool -comment-en_us=this is a comment test.mie
2010-04-05 - Fixed "Format Size" Note 7 to give the correct number of bits in the example rational value 2007-01-21 - Specified LF character (0x0a) for text newline sequence 2007-01-19 - Specified ISO 8859-1 character set for extended ASCII codes 2007-01-01 - Improved wording of Step 5 for scanning backwards in MIE file 2006-12-30 - Added EXAMPLES section and note about UTF BOM 2006-12-20 - MIE 1.1: Changed meaning of TypeModifier bit (0x08) for unknown data (FormatType 0x00), and documented byte swapping 2006-12-14 - MIE 1.0: Added Data Values and Numerical Representations sections, and added ability to specify units in tag names 2006-11-09 - Added Levels of Support section 2006-11-03 - Added Trailer Signature 2005-11-18 - Original specification created
Copyright 2003-2016, Phil Harvey (phil at owl.phy.queensu.ca)
This library is free software; you can redistribute it and/or modify it under the same terms as Perl itself. The MIE format itself is also copyright Phil Harvey, and is covered by the same free-use license.
MIE Tags in Image::ExifTool::TagNames, Image::ExifTool::MIEUnits, Image::ExifTool(3pm)
|perl v5.20.3||IMAGE::EXIFTOOL::MIE (3)||2016-01-04|