JPEG Metadata
Abbreviated Streams
Sources of Tables
Colorspace Transformations and Conventional Markers
Thumbnail Images
Progressive Encoding
Native Metadata Format Tree Structure and Editing
Image Metadata DTD
Stream Metadata DTD
dispose()
on the JPEG reader and writer objects when they are no longer needed, as they consume significant native resources which are not adequately recovered by garbage collection. Both reader and writer call dispose()
in their finalizers, but those finalizers may not be called before the native code has exhausted native memory.
The JPEG writer does not support replacing pixels.
SOI
marker and the
EOI
marker for that image. The image metadata object passed into a write determines the contents of the stream between the
SOI
marker and the
EOI
marker for that image, subject to the controls in any
ImageWriteParam
.
Stream metadata is used only for tables-only images found (or to be placed) at the beginning of a stream containing abbreviated images. Tables-only images are not treated as images and do not consume an image index. The stream metadata object returned from a read describes the contents of the marker segments between the SOI
marker and the EOI
marker for the single tables-only image at the beginning of the stream, if one is present. If no tables-only image is present at the front of the stream, the getStreamMetadata
method of ImageReader
returns null
. If stream metadata is provided to the writer, a single tables-only image containing the tables from the stream metadata object will be written at the beginning of the stream. If the stream metadata object contains no tables, default tables will be written. As the sole purpose of stream metadata is for specifying tables-only images at the front of abbreviated streams, the stream metadata argument is useful only on the ImageWriter.prepareWriteSequence
method. It is ignored on all other methods.
The ImageWriter.getDefaultStreamMetadata
method returns an object containing the tables from the ImageWriteParam
argument, if it is a JPEGImageWriteParam
and contains tables. Otherwise, the returned object will contain default tables.
The ImageWriter.getDefaultImageMetadata
method returns a metadata object containing
ImageWriteParam
argument contains tables. Otherwise the returned metadata object will contain default visually lossless tables. Of course, only a JPEGImageWriteParam
may contain tables.
If ignoreMetadata
is set to true
when the input is set on the reader, stream metadata will not be available, but image metadata will.
IllegalArgumentException
is thrown.Note that once a tables-only image has been read, it's contents is available as stream metadata from the reader until either another tables-only image is read from another stream or the reader is reset. Changing the input does not reset the stream metadata. This is useful for reading the tables from one file, then changing the input to read an abbreviated stream containing a sequence of images. The tables will be used automatically, and will remain available as "stream" metadata.
Abbreviated streams are written using the sequence methods of ImageWriter
. Stream metadata is used to write a tables-only image at the beginning of the stream, and the tables are set up for use, using ImageWriter.prepareWriteSequence
. If no stream metadata is supplied to ImageWriter.prepareWriteSequence
, then no tables-only image is written. If stream metadata containing no tables is supplied to ImageWriter.prepareWriteSequence
, then a tables-only image containing default visually lossless tables is written.
Images are written with tables if tables are present in their metadata objects or without them if no tables are present in their metadata objects. If no metadata object is present then the tables are written. The tables used for compression are taken from one of the following sources, which are consulted in order:
ImageWriteParam
and the compression mode is set to EXPLICIT
, default tables constructed using the quality setting are used. They are written only if the metadata contains tables or if there is no metadata, but they replace the tables in the metadata.ImageWriteParam
and the compression mode is set to DEFAULT
, default visually lossles tables are used. They are written only if the metadata contains tables or if there is no metadata, but they replace the tables in the metadata.ImageWriteParam
must be MODE_COPY_FROM_METADATA
, in which case the following are used:
JPEGImageWriteParam
, if presentJPEGImageWriteParam
s only as a means of specifying tables when no other source is available, and this can occur only when writing to an abbreviated stream without tables using known non-standard tables for compression.
When reading, tables in a JPEGImageReadParam
are consulted only if tables have not been set by any previous read. Tables set from a JPEGImageReadParam
are overridden by any tables present in the stream being read.
Note that if no image metadata object is specified for a particular image, a default object is used, which includes default tables.
Raster
s are read, no colorspace transformation is performed, and any destination type is ignored. A warning is sent to any listeners if a destination type is specified in this case. When
Raster
s are written, any destination type is used to interpret the bands. This might result in a JFIF or Adobe header being written, or different component ids being written to the frame and scan headers. If values present in a metadata object do not match the destination type, the destination type is used and a warning is sent to any listeners.
Optional ColorSpace support: Handling of PhotoYCC (YCC), PhotoYCCA (YCCA), RGBA and YCbCrA color spaces by the standard plugin, as described below, is dependent on capabilities of the libraries used to interpret the JPEG data. Thus all consequential behaviors are optional. If the support is not available when decoding, the color space will be treated as unrecognized and the appropriate default color space for the specified number of component channels may be used. When writing, an Exception may be thrown if no suitable conversion can be applied before encoding. But where the support for these color spaces is available, the behavior must be as documented.
When reading, the contents of the stream are interpreted by the usual JPEG conventions, as follows:
APP0
marker segment is present, the colorspace is known to be either grayscale or YCbCr. If an APP2
marker segment containing an embedded ICC profile is also present, then the YCbCr is converted to RGB according to the formulas given in the JFIF spec, and the ICC profile is assumed to refer to the resulting RGB space.
APP14
marker segment is present, the colorspace is determined by consulting the transform
flag. The transform
flag takes one of three values:
RGB
RGBA
YCC (as 'Y','C','c'), assumed to be PhotoYCC
YCCA (as 'Y','C','c','A'), assumed to be PhotoYCCA
Otherwise, 3-channel subsampled images are assumed to be YCbCr, 3-channel non-subsampled images are assumed to be RGB, 4-channel subsampled images are assumed to be YCCK, and 4-channel, non-subsampled images are assumed to be CMYK.
BufferedImage
. Such an image may be read only as a Raster
. If an image is interpretable but there is no Java ColorSpace
available corresponding to the encoded colorspace (
ImageReader.getRawImageType
will return null
. ColorSpace
or a custom RGB ColorSpace
object based on an embedded ICC profile is used to create the output ColorModel
. PhotoYCC and PhotoYCCA images are not converted. CMYK and YCCK images are currently not supported.BufferedImage
(
Raster
s. If an image colorspace is unsupported or uninterpretable, then ImageReader.getImageTypes
will return an empty Iterator
. If a subset of the raw bands are required, a Raster
must be obtained first and the bands obtained from that. For writing, the color transformation to apply is determined as follows:
If a subset of the source bands is to be written, no color conversion is performed. Any destination, if set, must match the number of bands that will be written, and serves as an interpretation of the selected bands, rather than a conversion request. This behavior is identical to that for Raster
s. If all the bands are to be written and an image (as opposed to a Raster
) is being written, any destination type is ignored and a warning is sent to any listeners.
If a destination type is used and any aspect of the metadata object, if there is one, is not compatible with that type, the destination type is used, the metadata written is modified from that provided, and a warning is sent to listeners. This includes the app0JFIF
and app14Adobe
nodes. The component ids in the sof
and sos
nodes are not modified, however, as unless a app0JFIF
node is present, any values may be used.
When a full image is written, a destination colorspace will be chosen based on the image contents and the metadata settings, according to the following algorithm:
If no metadata object is specified, then the following defaults apply:
APP0
marker segment. Grayscale images with alpha are written with no special marker. As required by JFIF, the component ids in the frame and scan header is set to 1. APP0
marker segment. If the ColorSpace
of the image is based on an ICCProfile
(it is an instance of ICC_ColorSpace
, but is not one of the standard built-in ColorSpaces
), then that profile is embedded in an APP2
marker segment. As required by JFIF, the component ids in the frame and scan headers are set to 1, 2, and 3. APP14
marker segment and 'Y','C', and 'c' (and 'A' if an alpha channel is present) as component ids in the frame and scan headers. If a metadata object is specified, then the number of channels in the frame and scan headers must always match the number of bands to be written, or an exception is thrown. app0JFIF
and app14Adobe
nodes may appear in the same metadata object only if the app14Adobe
node indicates YCbCr, and the component ids are JFIF compatible (0-2). The various image types are processed in the following ways:
(All multi-channel images are subsampled according to the sampling factors in the frame header node of the metadata object, regardless of color space.)
app0JFIF
node is present in the metadata object, a JFIF APP0
marker segment is written. app14Adobe
node is present in the metadata object, it is checked for validity (transform
must be UNKNOWN
) and written. app0JFIF
node is present in the metadata object, it is ignored and a warning is sent to listeners, as JFIF does not support 2-channel images. app14Adobe
node is present in the metadata object, it is checked for validity (transform
must be UNKNOWN
) and written. If transform
is not UNKNOWN
, a warning is sent to listeners and the correct transform is written. app0JFIF
node is present in the metadata object, the image is converted to YCbCr and written with a JFIF APP0
marker segment. If the ColorSpace
of the image is based on a non-standard ICC Profile, then that profile is embedded in an APP2
marker segment. If the ColorSpace
is not based on a non-standard ICC Profile, but an app2ICC
node appears in the metadata, then an APP2
marker segment is written with the appropriate standard profile. Note that the profile must specify an RGB color space, as the file must be JFIF compliant. app14Adobe
node is present in the metadata object, the image is converted according to the color transform setting and written with an Adobe APP14
marker segment. Component ids are written just as they appear in the frame and scan headers. The color transform must be either YCbCr or UNKNOWN
. If it is UNKNOWN
, the image is not color converted. app0JFIF
node is present in the metadata object, it is ignored and a warning is sent to listeners, as JFIF does not support 4-channel images. app14Adobe
node is present in the metadata object, the image is written with an Adobe APP14
marker segment. No colorspace conversion is performed. Component ids are written just as they appear in the frame and scan headers. The color transform must be UNKNOWN
. If it is not, a warning is sent to listeners. app14Adobe
node is present, the component ids in the frame header are consulted. If these indicate a colorspace as described above, then the image is converted to that colorspace if possible. If the component ids do not indicate a colorspace, then the sampling factors are consulted. If the image is to be subsampled, it is converted to YCbCrA. If the image is not to be subsampled, then no conversion is applied. No special marker segments are written. app0JFIF
node is present in the metadata object, the image is converted to sRGB, and then to YCbCr during encoding, and a JFIF APP0
marker segment is written. app14Adobe
node is present in the metadata object, no conversion is applied, and an Adobe APP14
marker segment is written. The color transform must be YCC. If it is not, a warning is sent to listeners. app0JFIF
node is present in the metadata object, it is ignored and a warning is sent to listeners, as JFIF does not support 4-channel images. app14Adobe
node is present in the metadata object, no conversion is applied, and an Adobe APP14
marker segment is written. The color transform must be UNKNOWN
. If it is not, a warning is sent to listeners.
app0JFIF
and
app0JFXX
nodes present in the metadata do not contain any thumbnail pixel data. However, the kinds of thumbnails written depend on the contents of the metadata object, as follows. Any thumbnail which is to be written as an indexed or RGB image and which is larger than 255 by 255 will be clipped, not scaled, to 255 by 255. Thumbnails written as JPEG images may be any size. A warning is sent to any listeners whenever a thumbnail is clipped.
app0JFXX
node is present in the metadata, or the first app0JFXX
node present in the metadata contains a JFIFthumbPalette
element, a palette thumbnail is written in a JFXX APP0
marker segment. app0JFXX
node present in the metadata contains another thumbnail form (RGB or JPEG), the palette image is expanded to RGB and the indicated thumbnail form is written. app0JFXX
node is present in the metadata, the thumbnail is written as part of the JFIF APP0
marker segment. app0JFXX
node present in the metadata contains a JFIFthumbRGB
element, an RGB thumbnail is written in a JFXX APP0
marker segment. app0JFXX
node present in the metadata contains a JFIFthumbJPEG
element, a JPEG thumbnail is written in a JFXX APP0
marker segment. app0JFXX
node present in the metadata contains a JFIFthumbPalette
element, an RGB thumbnail is written in a JFXX APP0
marker segment and a warning is sent to any listeners. app0JFXX
node is present in the metadata, the thumbnail is expanded to RGB and written as part of the JFIF APP0
marker segment. app0JFXX
node present in the metadata contains a JFIFthumbRGB
element, the thumbnail is expanded to RGB and written in a separate JFXX
RGB marker segment. app0JFXX
node present in the metadata contains a JFIFthumbJPEG
element, a JPEG thumbnail is written in a JFXX APP0
marker segment. app0JFXX
node present in the metadata contains a JFIFthumbPalette
element, a JPEG thumbnail is written in a JFXX APP0
marker segment and a warning is sent to any listeners. APP0
segment, and the app0JFXX
node consulted for each thumbnail is the app0JFXX
node from the metadata that occurs in the same sequence as the thumbnail.
app0JFXX
node applies to the first thumbnail, the second node to the second thumbnail, and so on. If there are fewer app0JFXX
nodes in the metadata than thumbnails, then those thumbnails are considered to have no matching app0JFXX
node. An RGB thumbnail with no matching app0JFXX
node is written in a JFXX APP0
marker segment. A grayscale thumbnail with no matching app0JFXX
node is written as a JPEG image to a JFXX APP0
marker segment. Note that as the only mechanism for storing thumbnails is via the JFIF or JFIF extension marker segments, only grayscale or RGB images may have thumbnails. If thumbnails are present when writing any other type of image, the thumbnails are ignored and a warning is sent to any warning listeners.
ImageWriteParam
passed in to a write operation, or the image will be written sequentially, regardless of the scan headers included in the metadata object. If progressive encoding is enabled and set to copy from metadata, then the sequence of scan headers from the metadata is used to write the image. If progressive encoding is enabled and set to use a default, then the scans in the metadata are ignored and a default set of scans is used. Progressive encoding always forces optimized Huffman tables to be used. Any Huffman tables present in the metadata will be ignored, and a warning will be sent to any warning listeners. If Huffman-table optimization is requested on the
ImageWriteParam
, all Huffman tables in the metadata or in the
ImageWriteParam
itself are ignored, and a warning will be sent to any warning listeners if any such tables are present.
IIOMetadata
object. They do not include nodes corresponding to
SOI
,
EOI
, or
RST
markers, as these parsing delimiters do not carry any meaningful metadata.
The first node is always a JPEGvariety
node. In the javax_imageio_jpeg_image_1.0
version of the JPEG metadata format, this node may have one child, an app0JFIF
node, indicating that the JPEG stream contains a JFIF marker segment and related data, or no children, indicating that the stream contains no JFIF marker. In future versions of the JPEG metadata format, other varieties of JPEG metadata may be supported (e.g. Exif) by defining other types of nodes which may appear as a child of the JPEGvariety
node.
(Note that an application wishing to interpret Exif metadata given a metadata tree structure in the javax_imageio_jpeg_image_1.0
format must check for an unknown
marker segment with a tag indicating an APP1
marker and containing data identifying it as an Exif marker segment. Then it may use application-specific code to interpret the data in the marker segment. If such an application were to encounter a metadata tree formatted according to a future version of the JPEG metadata format, the Exif marker segment might not be unknown
in that format - it might be structured as a child node of the JPEGvariety
node. Thus, it is important for an application to specify which version to use by passing the string identifying the version to the method/constructor used to obtain an IIOMetadata
object.)
On reading, JFXX
and app2ICC
nodes occur as children of an app0JFIF
node. This is true regardless of where the JFXX APP0
and APP2
marker segments actually occur in the stream. The ordering of nodes within the markerSequence
node corresponds to the ordering of marker segments found in the JPEG stream.
On writing, any JFXX
and app2ICC
nodes must occur as children of an app0JFIF
node, itself a child of a JPEGvariety
node, which must always be the first node. (If the stream is not to be JFIF compliant, no app0JFIF
node should be provided, and the JPEGvariety
node should have no children.) Any JFIF APP0
, JFXX APP0
, and APP2
marker segments are written first, followed by all Adobe APP14
, APPn
, COM
and unknown segments in the order in which their corresponding nodes appear in the markerSequence
node, followed by DQT
(and DHT
for non-progressive writes) marker segments, followed by the SOF
and SOS
marker segments. For progressive writes using metadata to control progression, the SOS
segments are used in the order in which their corresponding nodes occur in the markerSequence
node.
The reset
, mergeTree
and setFromTree
operations have the following semantics for the JPEG plug-in metadata object:
reset
- A call to reset
will restore the metadata object to the same state it had immediately after creation, whether this came about from reading a stream or by obtaining a default object from the ImageWriter
. This is true regardless of how many times the metadata object has been modified since creation.
mergeTree
- Native Format
The mergeTree
operation accepts valid trees conforming to the DTD below, and merges the nodes using the following ordering rules. In all cases, only data present in the new node is changed in a corresponding existing node, if any. This means that nodes cannot be removed using mergeTree
. To remove nodes, use setFromTree
. The tree must consist of IIOMetadataNode
s.
app0JFIF
app0JFIF
node already exists, the contents of the new one modify the existing one. dqt
dqt
nodes in the sequence, then each table in the node replaces the first table, in any dqt
node, with the same table id. dqt
nodes contain a table with the same id, then the table is added to the last existing dqt
node. dqt
nodes, then a new one is created and added as follows:
dht
nodes, the new dqt
node is inserted before the first one. dht
nodes, the new dqt
node is inserted before an sof
node, if there is one. sof
node, the new dqt
node is inserted before the first sos
node, if there is one. sos
node, the new dqt
node is added to the end of the sequence. dht
dht
nodes in the sequence, then each table in the node replaces the first table, in any dht
node, with the same table class and table id. dht
nodes contain a table with the same class and id, then the table is added to the last existing dht
node. dht
nodes, then a new one is created and added as follows:
dqt
nodes, the new dht
node is inserted immediately following the last dqt
node. dqt
nodes, the new dht
node is inserted before an sof
node, if there is one. sof
node, the new dht
node is inserted before the first sos
node, if there is one. sos
node, the new dht
node is added to the end of the sequence. dri
dri
node, the restart interval value is updated. dri
node, then a new one is created and added as follows:
sof
node, the new dri
node is inserted before it. sof
node, the new dri
node is inserted before the first sos
node, if there is one. sos
node, the new dri
node is added to the end of the sequence. com
com
node is created and inserted as follows:
com
nodes, the new one is inserted after the last one. com
nodes, the new com
node is inserted after the app14Adobe
node, if there is one. app14Adobe
node, the new com
node is inserted at the beginning of the sequence. app14Adobe
app14Adobe
node, then its attributes are updated from the node. app14Adobe
node, then a new one is created and added as follows:
app14Adobe
node is inserted after the last unknown
node, if there are any. unknown
nodes, the new app14Adobe
node is inserted at the beginning of the sequence. unknown
unknown
node is created and added to the sequence as follows:
unknown
marker nodes, the new one is inserted after the last one. unknown
nodes, the new unknown
node is inserted before the app14Adobe
node, if there is one. app14Adobe
node, the new unknown
node is inserted at the beginning of the sequence. sof
sof
node in the sequence, then its values are updated from the node. sof
node, then a new one is created and added as follows:
sos
nodes, the new sof
node is inserted before the first one. sos
node, the new sof
node is added to the end of the sequence. sos
sos
node, then the values are updated from the node. sos
nodes, then an IIOInvalidTreeException
is thrown, as sos
nodes cannot be merged into a set of progressive scans. sos
nodes, a new one is created and added to the end of the sequence. mergeTree
- Standard Format
The mergeTree
operation, when given a tree in the standard format, will modify the native tree in the following ways:
Chroma
- The ColorSpaceType
subnode of a Chroma
node may change the target colorspace of the compressed image. The selection of a new colorspace can cause a number of changes, in keeping with the algorithms described above: app0JFIF
and app14Adobe
nodes may be added or removed, subsampling may be added or removed, component ids may be changed, and sof
and sos
nodes will be updated accordingly. If necessary, additional quantization and huffman tables are added. In the case of quantization tables, the default will be scaled to match the quality level of any existing tables. No tables are added to metadata that does not already contain tables. If the existing metadata specifies progressive encoding, then the number of channels must not change. Any Transparency
node is also taken into account, as an explicit value of none
for the Alpha
subnode can cause the removal of an alpha channel, and anything other than none
can cause the addition of an alpha channel. Dimension
- A PixelAspectRatio
specification can cause the contents of an app0JFIF
node to change, if there is one present, or the addition of an app0JFIF
node containing appropriate values, if there can be one. An appropriate pair of integers is computed from the floating-point ratio for inclusion in the node. Text
- Each uncompressed text item is converted to a com
node and inserted according to the rules above for merging com
nodes. setFromTree
- Native Format
The setFromTree
operation, when given a tree in the native format described below, will simply replace the existing tree in its entirety with the new one. The tree must consist of IIOMetadataNode
s.
setFromTree
- Standard Format
The setFromTree
operation, when given a tree in the standard format, performs a reset
followed by a merge of the new tree.
<!DOCTYPE "javax_imageio_jpeg_image_1.0" [ <!ELEMENT "javax_imageio_jpeg_image_1.0" (JPEGvariety, markerSequence)> <!ELEMENT "JPEGvariety" (app0JFIF)> <!-- A node grouping all marker segments specific to the variety of stream being read/written (e.g. JFIF) - may be empty --> <!ELEMENT "app0JFIF" (JFXX?, app2ICC?)> <!ATTLIST "app0JFIF" "majorVersion" #CDATA "1"> <!-- The major JFIF version number --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "app0JFIF" "minorVersion" #CDATA "2"> <!-- The minor JFIF version number --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "app0JFIF" "resUnits" ("0" | "1" | "2") "0"> <!-- The resolution units for Xdensisty and Ydensity (0 = no units, just aspect ratio; 1 = dots/inch; 2 = dots/cm) --> <!ATTLIST "app0JFIF" "Xdensity" #CDATA "1"> <!-- The horizontal density or aspect ratio numerator --> <!-- Data type: Integer --> <!-- Min value: 1 (inclusive) --> <!-- Max value: 65535 (inclusive) --> <!ATTLIST "app0JFIF" "Ydensity" #CDATA "1"> <!-- The vertical density or aspect ratio denominator --> <!-- Data type: Integer --> <!-- Min value: 1 (inclusive) --> <!-- Max value: 65535 (inclusive) --> <!ATTLIST "app0JFIF" "thumbWidth" #CDATA "0"> <!-- The width of the thumbnail, or 0 if there isn't one --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "app0JFIF" "thumbHeight" #CDATA "0"> <!-- The height of the thumbnail, or 0 if there isn't one --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ELEMENT "JFXX" (app0JFXX)*> <!-- Min children: 1 --> <!ELEMENT "app0JFXX" (JFIFthumbJPEG | JFIFthumbPalette | JFIFthumbRGB)> <!-- A JFIF extension marker segment --> <!ATTLIST "app0JFXX" "extensionCode" ("16" | "17" | "19") #IMPLIED> <!-- The JFXX extension code identifying thumbnail type: (16 = JPEG, 17 = indexed, 19 = RGB --> <!ELEMENT "JFIFthumbJPEG" (markerSequence?)> <!-- A JFIF thumbnail in JPEG format (no JFIF segments permitted) --> <!ELEMENT "JFIFthumbPalette" EMPTY> <!-- A JFIF thumbnail as an RGB indexed image --> <!ATTLIST "JFIFthumbPalette" "thumbWidth" #CDATA #IMPLIED> <!-- The width of the thumbnail --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "JFIFthumbPalette" "thumbHeight" #CDATA #IMPLIED> <!-- The height of the thumbnail --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ELEMENT "JFIFthumbRGB" EMPTY> <!-- A JFIF thumbnail as an RGB image --> <!ATTLIST "JFIFthumbRGB" "thumbWidth" #CDATA #IMPLIED> <!-- The width of the thumbnail --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "JFIFthumbRGB" "thumbHeight" #CDATA #IMPLIED> <!-- The height of the thumbnail --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ELEMENT "app2ICC" EMPTY> <!-- An ICC profile APP2 marker segment --> <!-- Optional User object: java.awt.color.ICC_Profile --> <!ELEMENT "markerSequence" (dqt | dht | dri | com | unknown | app14Adobe | sof | sos)*> <!-- A node grouping all non-jfif marker segments --> <!ELEMENT "dqt" (dqtable)*> <!-- A Define Quantization Table(s) marker segment --> <!-- Min children: 1 --> <!-- Max children: 4 --> <!ELEMENT "dqtable" EMPTY> <!-- A single quantization table --> <!-- User object: javax.imageio.plugins.jpeg.JPEGQTable --> <!ATTLIST "dqtable" "elementPrecision" #CDATA "0"> <!-- The number of bits in each table element (0 = 8, 1 = 16) --> <!-- Data type: Integer --> <!ATTLIST "dqtable" "qtableId" ("0" | "1" | "2" | "3") #REQUIRED> <!ELEMENT "dht" (dhtable)*> <!-- A Define Huffman Table(s) marker segment --> <!-- Min children: 1 --> <!-- Max children: 4 --> <!ELEMENT "dhtable" EMPTY> <!-- A single Huffman table --> <!-- User object: javax.imageio.plugins.jpeg.JPEGHuffmanTable --> <!ATTLIST "dhtable" "class" ("0" | "1") #REQUIRED> <!-- Indicates whether this is a DC (0) or an AC (1) table --> <!ATTLIST "dhtable" "htableId" ("0" | "1" | "2" | "3") #REQUIRED> <!-- The table id --> <!ELEMENT "dri" EMPTY> <!-- A Define Restart Interval marker segment --> <!ATTLIST "dri" "interval" #CDATA #REQUIRED> <!-- The restart interval in MCUs --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 65535 (inclusive) --> <!ELEMENT "com" EMPTY> <!-- A Comment marker segment. The user object contains the actual bytes. --> <!-- User object: array of [B --> <!-- Min length: 1 --> <!-- Max length: 65533 --> <!ATTLIST "com" "comment" #CDATA #IMPLIED> <!-- The comment as a string (used only if user object is null) --> <!-- Data type: String --> <!ELEMENT "unknown" EMPTY> <!-- An unrecognized marker segment. The user object contains the data not including length. --> <!-- User object: array of [B --> <!-- Min length: 1 --> <!-- Max length: 65533 --> <!ATTLIST "unknown" "MarkerTag" #CDATA #REQUIRED> <!-- The tag identifying this marker segment --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ELEMENT "app14Adobe" EMPTY> <!-- An Adobe APP14 marker segment --> <!ATTLIST "app14Adobe" "version" #CDATA "100"> <!-- The version of Adobe APP14 marker segment --> <!-- Data type: Integer --> <!-- Min value: 100 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "app14Adobe" "flags0" #CDATA "0"> <!-- The flags0 variable of an APP14 marker segment --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 65535 (inclusive) --> <!ATTLIST "app14Adobe" "flags1" #CDATA "0"> <!-- The flags1 variable of an APP14 marker segment --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 65535 (inclusive) --> <!ATTLIST "app14Adobe" "transform" ("0" | "1" | "2") #REQUIRED> <!-- The color transform applied to the image (0 = Unknown, 1 = YCbCr, 2 = YCCK) --> <!ELEMENT "sof" (componentSpec)*> <!-- A Start Of Frame marker segment --> <!-- Min children: 1 --> <!-- Max children: 4 --> <!ATTLIST "sof" "process" ("0" | "1" | "2") #IMPLIED> <!-- The JPEG process (0 = Baseline sequential, 1 = Extended sequential, 2 = Progressive) --> <!ATTLIST "sof" "samplePrecision" #CDATA "8"> <!-- The number of bits per sample --> <!-- Data type: Integer --> <!ATTLIST "sof" "numLines" #CDATA #IMPLIED> <!-- The number of lines in the image --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 65535 (inclusive) --> <!ATTLIST "sof" "samplesPerLine" #CDATA #IMPLIED> <!-- The number of samples per line --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 65535 (inclusive) --> <!ATTLIST "sof" "numFrameComponents" ("1" | "2" | "3" | "4") #IMPLIED> <!-- The number of components in the image --> <!ELEMENT "componentSpec" EMPTY> <!-- A component specification for a frame --> <!ATTLIST "componentSpec" "componentId" #CDATA #REQUIRED> <!-- The id for this component --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "componentSpec" "HsamplingFactor" #CDATA #REQUIRED> <!-- The horizontal sampling factor for this component --> <!-- Data type: Integer --> <!-- Min value: 1 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "componentSpec" "VsamplingFactor" #CDATA #REQUIRED> <!-- The vertical sampling factor for this component --> <!-- Data type: Integer --> <!-- Min value: 1 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "componentSpec" "QtableSelector" ("0" | "1" | "2" | "3") #REQUIRED> <!-- The quantization table to use for this component --> <!ELEMENT "sos" (scanComponentSpec)*> <!-- A Start Of Scan marker segment --> <!-- Min children: 1 --> <!-- Max children: 4 --> <!ATTLIST "sos" "numScanComponents" ("1" | "2" | "3" | "4") #REQUIRED> <!-- The number of components in the scan --> <!ATTLIST "sos" "startSpectralSelection" #CDATA "0"> <!-- The first spectral band included in this scan --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 63 (inclusive) --> <!ATTLIST "sos" "endSpectralSelection" #CDATA "63"> <!-- The last spectral band included in this scan --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 63 (inclusive) --> <!ATTLIST "sos" "approxHigh" #CDATA "0"> <!-- The highest bit position included in this scan --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 15 (inclusive) --> <!ATTLIST "sos" "approxLow" #CDATA "0"> <!-- The lowest bit position included in this scan --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 15 (inclusive) --> <!ELEMENT "scanComponentSpec" EMPTY> <!-- A component specification for a scan --> <!ATTLIST "scanComponentSpec" "componentSelector" #CDATA #REQUIRED> <!-- The id of this component --> <!-- Data type: Integer --> <!-- Min value: 0 (inclusive) --> <!-- Max value: 255 (inclusive) --> <!ATTLIST "scanComponentSpec" "dcHuffTable" ("0" | "1" | "2" | "3") #REQUIRED> <!-- The huffman table to use for encoding DC coefficients --> <!ATTLIST "scanComponentSpec" "acHuffTable" ("0" | "1" | "2" | "3") #REQUIRED> <!-- The huffman table to use for encoding AC coefficients --> ]>
<!DOCTYPE "javax_imageio_jpeg_stream_1.0" [ <!ELEMENT "javax_imageio_jpeg_stream_1.0" (dqt | dht | dri | com | unknown)*> <!-- All elements are as defined above for image metadata --> ]>