TIFF Metadata Format Specification and Usage Notes
Reading Images Writing ImagesNative Stream Metadata Format
Native Image Metadata Format
Reading Images
TIFF images are read by an ImageReader which may be controlled by its public interface as well as via a supplied TIFFImageReadParam.Color Conversion
If the source image data have photometric type CIE L*a*b* or YCbCr, and the destination color space type is RGB, then the source image data will be automatically converted to RGB using an internal color converter.
Color Spaces
The raw color space assigned by default, i.e., in the absence of a user-supplied ImageTypeSpecifier, will be the first among the following which applies:- A color space created from the ICC Profile metadata field if it is present and compatible with the image data layout.
- sRGB if the image is monochrome/bilevel (a two-level color map is created internally).
- sRGB if the image is palette-color.
- Linear RGB if the image has three samples per pixel, has photometric type CIE L*a*b*, or has photometric type YCbCr and is not JPEG-compressed.
- A default CMYK color space if the image has photometric type CMYK and four samples per pixel.
- Grayscale if the image has one or two samples per pixel and uniformly 1, 2, 4, 8, 16, or 32 bits per sample or is floating point.
- sRGB if the image has three or four samples per pixel and uniformly 1, 2, 4, 8, 16, or 32 bits per sample or is floating point.
- A fabricated, generic color space if the image has more than four samples per pixel and the number of bits per sample for all bands is the same and is a multiple of 8.
- Grayscale if the image has one or two samples per pixel regardless of the number of bits per sample.
- sRGB if the image has three or four samples per pixel regardless of the number of bits per sample.
- A fabricated, generic color space if the image has more than four samples per pixel regardless of the number of bits per sample.
The normalized color coordinate transformations used for the default CMYK color space are defined as follows:
- CMYK to linear RGB
R = (1 - K)*(1 - C) G = (1 - K)*(1 - M) B = (1 - K)*(1 - Y)
- Linear RGB to CMYK
K = min{1 - R, 1 - G, 1 - B} if(K != 1) { C = (1 - R - K)/(1 - K) M = (1 - G - K)/(1 - K) Y = (1 - B - K)/(1 - K) } else { C = M = Y = 0 }
The generic color space used when no other color space can be inferred is provided merely to enable the data to be loaded. It is not intended to provide accurate conversions of any kind.
If the data are known to be in a color space not correctly handled by the
foregoing, then an ImageTypeSpecifier
should be
supplied to the reader and should be derived from a color space which is correct
for the data in question.
ICC Profiles
If an ICC profile is contained in the image metadata ( BaselineTIFFTagSet.TAG_ICC_PROFILE, tag number 34675), an attempt will be made to use it to create the color space of the loaded image. It will be used if the data layout is of component type and the number of samples per pixel equals or is one greater than the number of components described by the ICC profile. If the ICC profile is not used then the color space will be inferred in one of the subsequent steps described above.If for some reason the embedded ICC profile is not used automatically, then it may be used manually by following this procedure:
- Obtain the image metadata from
ImageReader.getImageMetadata
- Extract the ICC profile field and its value.
- Create an
ICC_ColorSpace from an
ICC_Profile created from the ICC profile field data
using
ICC_Profile.getInstance(byte[])
. - Create an
ImageTypeSpecifier
from the new color space using one of its factory methods which accepts anICC_ColorSpace
. - Create a compatible ImageReadParam
and set the
ImageTypeSpecifier
usingImageReadParam.setDestinationType
. - Pass the parameter object to the appropriate
read
method.
If the inferred color space not based on the ICC Profile field is compatible
with the ICC profile-based color space, then a second
ImageTypeSpecifier
derived from this inferred color
space will be included in the
Iterator
returned by
ImageReader.getImageTypes
. If the iterator contains
more than one type, the first one will be based on the ICC profile and the
second on the inferred color space.
Metadata Issues
By default all recognized fields in the TIFF image file directory (IFD) are loaded into the native image metadata object. Which fields are loaded may be controlled by setting which TIFF tags the reader is allowed to recognize, whether to read fields with unrecognized tags, and whether to ignore all metadata. The reader is informed to disregard all metadata as usual via theignoreMetadata
parameter of
ImageReader.setInput(Object,boolean,boolean)
. It is
informed of which TIFFTags to
recognize or not to recognize via
TIFFImageReadParam.addAllowedTagSet(TIFFTagSet)
and
TIFFImageReadParam.removeAllowedTagSet(TIFFTagSet)
.
If ignoreMetadata
is true
, then only metadata
essential to reading the image will be loaded into the native image metadata
object. If ignoreMetadata
is false
, then the reader
will by default load into the native image metadata object only those fields
which are either essential to reading the image or have a TIFFTag
contained in the one of the allowed TIFFTagSet
s. Reading of
fields with tags not in the allowed TIFFTagSet
s may be forced
by passing in a TIFFImageReadParam
on which
TIFFImageReadParam.setReadUnknownTags(boolean)
has been
invoked with parameter true
.
Use of a TIFFDirectory
object may simplify gaining access to metadata values. An instance of
TIFFDirectory
may be created from the IIOMetadata
object returned by the TIFF reader using the
TIFFDirectory.createFromMetadata
method.
Mapping of TIFF Native Image Metadata to the Standard Metadata Format
The derivation of standard metadata format javax_imageio_1.0 elements from TIFF native image metadata is given in the following table.Standard Metadata Element | Derivation from TIFF Fields |
---|---|
/Chroma/ColorSpaceType@name | PhotometricInterpretation: WhiteIsZero, BlackIsZero, TransparencyMask = "GRAY"; RGB, PaletteColor => "RGB"; CMYK => "CMYK"; YCbCr => "YCbCr"; CIELab, ICCLab => "Lab". |
/Chroma/NumChannels@value | SamplesPerPixel |
/Chroma/BlackIsZero@value | "TRUE" <=> PhotometricInterpretation => WhiteIsZero |
/Chroma/Palette | ColorMap |
/Compression/CompressionTypeName@value | Compression: Uncompressed => "none"; CCITT 1D => "CCITT RLE"; Group 3 Fax => "CCITT T.4"; Group 4 Fax => "CCITT T.6"; LZW => "LZW"; JPEG => "Old JPEG"; New JPEG => "JPEG"; Zlib =>> "ZLib"; PackBits => "PackBits"; Deflate => "Deflate"; Exif JPEG => "JPEG". |
/Compression/Lossless@value | Compression: JPEG or New JPEG => "FALSE"; otherwise "TRUE". |
/Data/PlanarConfiguration@value | Chunky => "PixelInterleaved"; Planar => "PlaneInterleaved". |
/Data/SampleFormat@value | PhotometricInterpretation PaletteColor => "Index"; SampleFormat unsigned integer data => "UnsignedIntegral"; SampleFormat two's complement signed integer data => "SignedIntegral"; SampleFormat IEEE floating point data => "Real"; otherwise element not emitted. |
/Data/BitsPerSample@value | BitsPerSample as a space-separated list. |
/Data/SampleMSB@value | FillOrder: left-to-right => space-separated list of BitsPerSample-1; right-to-left => space-separated list of 0s. |
/Dimension/PixelAspectRatio@value | (1/XResolution)/(1/YResolution) |
/Dimension/ImageOrientation@value | Orientation |
/Dimension/HorizontalPixelSize@value | 1/XResolution in millimeters if ResolutionUnit is not None. |
/Dimension/VerticalPixelSize@value | 1/YResolution in millimeters if ResolutionUnit is not None. |
/Dimension/HorizontalPosition@value | XPosition in millimeters if ResolutionUnit is not None. |
/Dimension/VerticalPosition@value | YPosition in millimeters if ResolutionUnit is not None. |
/Document/FormatVersion@value | 6.0 |
/Document/SubimageInterpretation@value | NewSubFileType: transparency => "TransparencyMask"; reduced-resolution => "ReducedResolution"; single page => "SinglePage". |
/Document/ImageCreationTime@value | DateTime |
/Text/TextEntry | DocumentName, ImageDescription, Make, Model, PageName, Software,
Artist, HostComputer, InkNames, Copyright:
/Text/TextEntry@keyword = field name,
/Text/TextEntry@value = field value. Example: TIFF Software field => /Text/TextEntry@keyword = "Software", /Text/TextEntry@value = Name and version number of the software package(s) used to create the image. |
/Transparency/Alpha@value | ExtraSamples: associated alpha => "premultiplied"; unassociated alpha => "nonpremultiplied". |
Reading Exif Images
The TIFF reader may be used to read an uncompressed Exif image or the contents of theAPP1
marker segment of a compressed Exif image.
Reading Uncompressed Exif Images
An uncompressed Exif image is a one- or two-page uncompressed TIFF image with a specific ordering of its IFD and image data content. Each pixel has three 8-bit samples with photometric interpretation RGB or YCbCr. The image stream must contain a single primary image and may contain a single thumbnail which if present must also be uncompressed. The usualImageReader
methods may be used to read the image
data and metadata:
ImageInputStream input;
ImageReader tiffReader;
ImageReadParam tiffReadParam;
tiffReader.setInput(input);
// Read primary image and IFD.
BufferedImage image = tiffReader.read(0, tiffReadParam);
IIOMetadata primaryIFD = tiffReader.getImageMetadata(0);
// Read thumbnail if present.
BufferedImage thumbnail = null;
if (tiffReader.getNumImages(true) > 1) {
thumbnail = tiffReader.read(1, tiffReadParam);
}
Note that the Exif thumbnail is treated as a separate page in the TIFF
stream and not as a thumbnail, i.e.,
tiffReader.hasThumbnails(0)
will return false
.
Reading Compressed Exif Images
A compressed Exif image is a 3-band ISO/IEC 10918-1 baseline DCT JPEG stream with an insertedAPP1
marker segment. The parameters of the marker
segment after the length are the 6-byte sequence
{'E', 'x', 'i', 'f', 0x00, 0x00}
followed by a complete TIFF stream. The embedded TIFF stream contains a primary
IFD describing the JPEG image optionally followed by a thumbnail IFD and
compressed or uncompressed thumbnail image data. Note that the embedded TIFF
stream does not contain any image data associated with the primary IFD
nor any descriptive fields which duplicate information found in the JPEG
stream itself.
The parameter content of the APP1
marker segment may be obtained
from the user object of the associated Node
in a
javax_imageio_jpeg_image_1.0
native image metadata tree extracted
from the image metadata object returned by the JPEG reader. This APP1 Exif
node will be a child of the node named "markerSequence" and will
have name unknown
and an attribute named MarkerTag
with
integral value 0xE1
(String
value
"225"
). The user object of this node will be a byte array
which starts with the six bytes {'E', 'x', 'i', 'f', '0', '0'}
.
The primary IFD and the thumbnail IFD and image may be
read from the user object by the usual ImageReader
methods:
ImageReader jpegReader;
ImageReader tiffReader;
// Obtain the APP1 Exif marker data from the JPEG image metadata.
IIOMetadata jpegImageMetadata = jpegReader.getImageMetadata(0);
String nativeFormat = jpegImageMetadata.getNativeMetadataFormatName();
Node jpegImageMetadataTree = jpegImageMetadata.getAsTree(nativeFormat);
// getExifMarkerData() returns the byte array which is the user object
// of the APP1 Exif marker node.
byte[] app1Params = getExifMarkerData(jpegImageMetadataTree);
if (app1Params == null) {
throw new IIOException("APP1 Exif marker not found.");
}
// Set up input, skipping Exif ID 6-byte sequence.
MemoryCacheImageInputStream app1ExifInput
= new MemoryCacheImageInputStream
(new ByteArrayInputStream(app1Params, 6, app1Params.length - 6));
tiffReader.setInput(app1ExifInput);
// Read primary IFD.
IIOMetadata primaryIFD = tiffReader.getImageMetadata(0);
// Read thumbnail if present.
BufferedImage thumbnail = null;
if (tiffReader.getNumImages(true) > 1) {
thumbnail = tiffReader.read(1, tiffReadParam);
}
// Read the primary image.
BufferedImage image = jpegReader.read(0);
Note that tiffReader.getNumImages(true)
returns the number of
IFDs in the embedded TIFF stream including those corresponding to empty
images. Calling tiffReader.read(0, readParam)
will throw
an exception as the primary image in the embedded TIFF stream is always
empty; the primary image should be obtained using the JPEG reader itself.
Writing Images
TIFF images are written by a ImageWriter which may be controlled by its public interface as well as via a supplied ImageWriteParam. For anImageWriteParam
returned
by the getDefaultWriteParam()
method of the TIFF ImageWriter
,
the canWriteTiles()
and canWriteCompressed()
methods
will return true
; the canOffsetTiles()
and
canWriteProgressive()
methods will return false
.
The TIFF writer supports many optional capabilities including writing tiled
images, inserting images, writing or inserting empty images, and replacing image
data. Pixels may be replaced in either empty or non-empty images but if and
only if the data are not compressed.
If tiles are being written, then each of their dimensions will be rounded to the nearest multiple of 16 per the TIFF specification. If JPEG-in-TIFF compression is being used, and tiles are being written each tile dimension will be rounded to the nearest multiple of 8 times the JPEG minimum coded unit (MCU) in that dimension. If JPEG-in-TIFF compression is being used and strips are being written, the number of rows per strip is rounded to a multiple of 8 times the maximum MCU over both dimensions.
Compression
The compression type may be set via thesetCompressionType()
method of
the ImageWriteParam
after setting the compression mode to
MODE_EXPLICIT
. The set of innately
supported compression types is listed in the following table:
Compression Type | Description | Reference |
---|---|---|
CCITT RLE | Modified Huffman compression | TIFF 6.0 Specification, Section 10 |
CCITT T.4 | CCITT T.4 bilevel encoding/Group 3 facsimile compression | TIFF 6.0 Specification, Section 11 |
CCITT T.6 | CCITT T.6 bilevel encoding/Group 4 facsimile compression | TIFF 6.0 Specification, Section 11 |
LZW | LZW compression | TIFF 6.0 Specification, Section 13 |
JPEG | "New" JPEG-in-TIFF compression | TIFF Technical Note #2 |
ZLib | "Deflate/Inflate" compression (see note following this table) | Adobe Photoshop® TIFF Technical Notes |
PackBits | Byte-oriented, run length compression | TIFF 6.0 Specification, Section 9 |
Deflate | "Zip-in-TIFF" compression (see note following this table) | ZLIB Compressed Data Format Specification, DEFLATE Compressed Data Format Specification |
Exif JPEG | Exif-specific JPEG compression (see note following this table) | Exif 2.2 Specification (PDF), section 4.5.5, "Basic Structure of Thumbnail Data" |
Old-style JPEG compression as described in section 22 of the TIFF 6.0 Specification is not supported.
The CCITT compression types are applicable to bilevel (1-bit) images only. The JPEG compression type is applicable to byte grayscale (1-band) and RGB (3-band) images only.
ZLib and Deflate compression are identical except for the value of the TIFF Compression field: for ZLib the Compression field has value 8 whereas for Deflate it has value 32946 (0x80b2). In both cases each image segment (strip or tile) is written as a single complete zlib data stream.
"Exif JPEG" is a compression type used when writing the contents of an APP1 Exif marker segment for inclusion in a JPEG native image metadata tree. The contents appended to the output when this compression type is used are a function of whether an empty or non-empty image is written. If the image is empty, then a TIFF IFD adhering to the specification of a compressed Exif primary IFD is appended. If the image is non-empty, then a complete IFD and image adhering to the specification of a compressed Exif thumbnail IFD and image are appended. Note that the data of the empty image may not later be appended using the pixel replacement capability of the TIFF writer.
If ZLib/Deflate or JPEG compression is used, the compression quality
may be set. For ZLib/Deflate the supplied floating point quality value is
rescaled to the range [1, 9]
and truncated to an integer
to derive the Deflate compression level. For JPEG the floating point
quality value is passed directly to the JPEG writer plug-in which
interprets it in the usual way.
Color Conversion
If the source image data color space type is RGB, and the destination photometric type is CIE L*a*b* or YCbCr, then the source image data will be automatically converted from RGB using an internal color converter.
ICC Profiles
AnICC Profile
field will be written if either:
- one is present in the native image metadata IIOMetadata instance supplied to the writer, or
- the ColorSpace
of the destination
ImageTypeSpecifier
is an instance ofICC_ColorSpace
which is not one of the standard color spaces defined by theCS_*
constants in theColorSpace
class. The destination type is set viaImageWriteParam.setDestinationType(ImageTypeSpecifier)
and defaults to theImageTypeSpecifier
of the image being written.
Metadata Issues
Some behavior of the writer is affected by or may affect the contents of the image metadata which may be supplied by the user.For bilevel images, the FillOrder
, and T4Options
fields affect the output data. The data will be filled right-to-left if
FillOrder
is present with a value of 2
(BaselineTIFFTagSet.FILL_ORDER_RIGHT_TO_LEFT
)
and will be filled left-to-right otherwise. The value of T4Options
specifies whether the data should be 1D- or 2D-encoded and whether EOL
padding should be used.
For all images the value of the RowsPerStrip
field is used
to the set the number of rows per strip if the image is not tiled. The
default number of rows per strip is either 8 or the number of rows which
would fill no more than 8 kilobytes, whichever is larger.
For all images the tile dimensions may be set using the TileWidth
and TileLength
field values if the tiling mode is
ImageWriteParam.MODE_COPY_FROM_METADATA
. If this mode
is set but the fields are not, their respective default values are the image
width and height.
When using JPEG-in-TIFF compression, a JPEGTables
field will be
written to the IFD and abbreviated JPEG streams to each strip or tile if and
only if a JPEGTables
field is contained in the metadata object
provided to the writer. If the contents of the JPEGTables
field is
a valid tables-only JPEG stream, then it will be used; otherwise the contents
of the field will be replaced with default visually lossless tables. If no
such JPEGTables
field is present in the metadata, then no
JPEGTables
field will be written to the output and each strip or
tile will be written as a separate, self-contained JPEG stream.
When using Deflate/ZLib or LZW compression, if the image has 8 bits per
sample, a horizontal differencing predictor will be used if the
Predictor
field is present with a value of 2
(BaselineTIFFTagSet.PREDICTOR_HORIZONTAL_DIFFERENCING
).
If prediction is so requested but the image does not have
8 bits per sample the field will be reset to have the value 1
(BaselineTIFFTagSet.PREDICTOR_NONE
).
Some fields may be added or modified:
PhotometricInterpretation
if not present.PlanarConfiguration
if this field is present with valuePlanar
is is reset toChunky
.Compression
always.BitsPerSample
if the image is not bilevel.SamplesPerPixel
always.ExtraSamples
if an alpha channel is present.SampleFormat
if not present and the data are 16- or 32-bit integers or floating point.ColorMap
if thePhotometricInterpretation
isRGBPalette
.ImageWidth
andImageLength
always.TileWidth
,TileLength
,TileOffsets
, andTileByteCounts
if a tiled image is being written.RowsPerStrip
,StripOffsets
, andStripByteCounts
if a tiled image is not being written.XResolution
,YResolution
, andResolutionUnit
if none of these is present.YCbCrSubsampling
andYCbCrPositioning
if the photometric interpretation is YCbCr and the compression type is not JPEG (only [1, 1] subsampling and cosited positioning are supported for non-JPEG YCbCr output).YCbCrSubsampling
,YCbCrPositioning
, andReferenceBlackWhite
: if the compression type is JPEG and the color space is RGB these will be reset to [2, 2] centered subsampling with no headroom/footroom (0:255,128:255,128:255).
Some fields may be removed:
BitsPerSample
if the image is bilevel.ExtraSamples
if the image does not have an alpha channel.ColorMap
if the photometric interpretation is notRGBPalette
.TileWidth
,TileLength
,TileOffsets
, andTileByteCounts
if tiling is not being used.RowsPerStrip
,StripOffsets
, andStripByteCounts
if tiling is being used.YCbCrSubsampling
,YCbCrPositioning
, andReferenceBlackWhite
if the compression type is JPEG and the color space is grayscale.JPEGProc
,JPEGInterchangeFormat
,JPEGInterchangeFormatLength
,JPEGRestartInterval
,JPEGLosslessPredictors
,JPEGPointTransforms
,JPEGQTables
,JPEGDCTables
, andJPEGACTables
if the compression type is JPEG.
Other fields present in the supplied metadata are uninterpreted and will be written as supplied.
If an Exif image is being written, the set of fields present and their values will be modified such that the result is in accord with the Exif 2.2 specification.
Setting up the image metadata to write to a TIFF stream may be simplified
by using the TIFFDirectory
class
which represents a TIFF IFD. A field in a TIFF IFD is represented by an
instance of TIFFField. For each
field to be written a TIFFField
may be added to the
TIFFDirectory
and the latter converted to an
IIOMetadata
object by invoking
TIFFDirectory.getAsMetadata
. The
IIOMetadata
object so obtained may then be passed to the TIFF
writer.
Mapping of the Standard Metadata Format to TIFF Native Image Metadata
The derivation of TIFF native image metadata elements from the standard metadata format javax_imageio_1.0 is given in the following table.TIFF Field | Derivation from Standard Metadata Elements |
---|---|
PhotometricInterpretation | /Chroma/ColorSpaceType@name: "GRAY" and /Chroma/BlackIsZero@value = "FALSE" => WhiteIsZero; "GRAY" and /Document/SubimageInterpretation@value = "TransparencyMask" => TransparencyMask; "RGB" and /Chroma/Palette present => PaletteColor; "GRAY" => BlackIsZero; "RGB" => RGB; "YCbCr" => YCbCr; "CMYK" => CMYK; "Lab" => CIELab. |
SamplesPerPixel | /Chroma/NumChannels@value |
ColorMap | /Chroma/Palette |
Compression | /Compression/CompressionTypeName@value: "none" => Uncompressed; "CCITT RLE" => CCITT 1D; "CCITT T.4" => Group 3 Fax; "CCITT T.6" => Group 4 Fax; "LZW" => LZW; "Old JPEG" => JPEG; "JPEG" => New JPEG; "ZLib" => ZLib; "PackBits" => PackBits; "Deflate" => Deflate. |
PlanarConfiguration | /Data/PlanarConfiguration@value: "PixelInterleaved" => Chunky; "PlaneInterleaved" => Planar. |
SampleFormat | /Data/SampleFormat@value: "SignedIntegral" => two's complement signed integer data; "UnsignedIntegral" => unsigned integer data; "Real" => IEEE floating point data; "Index" => unsigned integer data. |
BitsPerSample | /Data/BitsPerSample@value: space-separated list parsed to char array. |
FillOrder | /Data/SampleMSB@value: if all values in space-separated list are 0s => right-to-left; otherwise => left-to-right. |
XResolution | (10 / /Dimension/HorizontalPixelSize@value) or (10 / (/Dimension/VerticalPixelSize@value * /Dimension/PixelAspectRatio@value)) |
YResolution | (10 / /Dimension/VerticalPixelSize@value) or (10 / (/Dimension/HorizontalPixelSize@value / /Dimension/PixelAspectRatio@value)) |
ResolutionUnit | Centimeter if XResolution or YResolution set; otherwise None. |
Orientation | /Dimension/ImageOrientation@value |
XPosition | /Dimension/HorizontalPosition@value / 10 |
YPosition | /Dimension/VerticalPosition@value / 10 |
NewSubFileType | /Document/SubimageInterpretation@value: "TransparencyMask" => transparency mask; "ReducedResolution" => reduced-resolution; "SinglePage" => single page. |
DateTime | /Document/ImageCreationTime@value |
DocumentName, ImageDescription, Make, Model, PageName, Software, Artist, HostComputer, InkNames, Copyright | /Text/TextEntry: if /Text/TextEntry@keyword is the name of any of the TIFF Fields, e.g., "Software", then the field is added with content /Text/TextEntry@value and count 1. |
ExtraSamples | /Transparency/Alpha@value: "premultiplied" => associated alpha, count 1; "nonpremultiplied" => unassociated alpha, count 1. |
Writing Exif Images
The TIFF writer may be used to write an uncompressed Exif image or the contents of theAPP1
marker segment of a compressed Exif image.
Writing Uncompressed Exif Images
When writing a sequence of images each image is normally recorded as {IFD, IFD Value, Image Data}. The Exif specification requires that an uncompressed Exif image be structured as follows:- Image File Header
- Primary IFD
- Primary IFD Value
- Thumbnail IFD
- Thumbnail IFD Value
- Thumbnail Image Data
- Primary Image Data
ImageWriter tiffWriter;
ImageWriteParam tiffWriteParam;
IIOMetadata tiffStreamMetadata;
IIOMetadata primaryIFD;
BufferedImage image;
BufferedImage thumbnail;
// Specify uncompressed output.
tiffWriteParam.setCompressionMode(ImageWriteParam.MODE_DISABLED);
if (thumbnail != null) {
// Write the TIFF header.
tiffWriter.prepareWriteSequence(tiffStreamMetadata);
// Append the primary IFD.
tiffWriter.prepareInsertEmpty(-1, // append
new ImageTypeSpecifier(image),
image.getWidth(),
image.getHeight(),
primaryIFD,
null, // thumbnails
tiffWriteParam);
tiffWriter.endInsertEmpty();
// Append the thumbnail image data.
tiffWriter.writeToSequence(new IIOImage(thumbnail, null, null),
tiffWriteParam);
// Insert the primary image data.
tiffWriter.prepareReplacePixels(0, new Rectangle(image.getWidth(),
image.getHeight()));
tiffWriter.replacePixels(image, tiffWriteParam);
tiffWriter.endReplacePixels();
// End writing.
tiffWriter.endWriteSequence();
} else {
// Write only the primary IFD and image data.
tiffWriter.write(tiffStreamMetadata,
new IIOImage(image, null, primaryIFD),
tiffWriteParam);
}
Writing Compressed Exif Images
The structure of the embedded TIFF stream in theAPP1
segment of a
compressed Exif image is identical to the
uncompressed Exif image structure except that there are no primary
image data, i.e., the primary IFD does not refer to any image data.
ImageWriter tiffWriter;
ImageWriteParam tiffWriteParam;
IIOMetadata tiffStreamMetadata;
BufferedImage image;
BufferedImage thumbnail;
IIOMetadata primaryIFD;
ImageOutputStream output;
// Set up an output to contain the APP1 Exif TIFF stream.
ByteArrayOutputStream baos = new ByteArrayOutputStream();
MemoryCacheImageOutputStream app1ExifOutput =
new MemoryCacheImageOutputStream(baos);
tiffWriter.setOutput(app1ExifOutput);
// Set compression for the thumbnail.
tiffWriteParam.setCompressionMode(ImageWriteParam.MODE_EXPLICIT);
tiffWriteParam.setCompressionType("Exif JPEG");
// Write the APP1 Exif TIFF stream.
if (thumbnail != null) {
// Write the TIFF header.
tiffWriter.prepareWriteSequence(tiffStreamMetadata);
// Append the primary IFD.
tiffWriter.prepareInsertEmpty(-1, // append
new ImageTypeSpecifier(image),
image.getWidth(),
image.getHeight(),
primaryIFD,
null, // thumbnails
tiffWriteParam);
tiffWriter.endInsertEmpty();
// Append the thumbnail IFD and image data.
tiffWriter.writeToSequence(new IIOImage(thumbnail, null,
null), tiffWriteParam);
// End writing.
tiffWriter.endWriteSequence();
} else {
// Write only the primary IFD.
tiffWriter.prepareWriteEmpty(tiffStreamMetadata,
new ImageTypeSpecifier(image),
image.getWidth(),
image.getHeight(),
primaryIFD,
null, // thumbnails
tiffWriteParam);
tiffWriter.endWriteEmpty();
}
// Flush data into byte stream.
app1ExifOutput.flush();
// Create APP1 parameter array.
byte[] app1Parameters = new byte[6 + baos.size()];
// Add APP1 Exif ID bytes.
app1Parameters[0] = (byte) 'E';
app1Parameters[1] = (byte) 'x';
app1Parameters[2] = (byte) 'i';
app1Parameters[3] = (byte) 'f';
app1Parameters[4] = app1Parameters[5] = (byte) 0;
// Append TIFF stream to APP1 parameters.
System.arraycopy(baos.toByteArray(), 0, app1Parameters, 6, baos.size());
// Create the APP1 Exif node to be added to native JPEG image metadata.
IIOMetadataNode app1Node = new IIOMetadataNode("unknown");
app1Node.setAttribute("MarkerTag", String.valueOf(0xE1));
app1Node.setUserObject(app1Parameters);
// Append the APP1 Exif marker to the "markerSequence" node.
IIOMetadata jpegImageMetadata =
jpegWriter.getDefaultImageMetadata(new ImageTypeSpecifier(image),
jpegWriteParam);
String nativeFormat = jpegImageMetadata.getNativeMetadataFormatName();
Node tree = jpegImageMetadata.getAsTree(nativeFormat);
NodeList children = tree.getChildNodes();
int numChildren = children.getLength();
for (int i = 0; i < numChildren; i++) {
Node child = children.item(i);
if (child.getNodeName().equals("markerSequence")) {
child.appendChild(app1Node);
break;
}
}
jpegImageMetadata.setFromTree(nativeFormat, tree);
// Write the JPEG image data including the APP1 Exif marker.
jpegWriter.setOutput(output);
jpegWriter.write(new IIOImage(image, null, jpegImageMetadata));
The "unknown"
node created above would be appended to the
"markerSequence"
node of the native JPEG image metadata
and written to the JPEG stream when the primary image is written using
the JPEG writer.
Stream Metadata
The DTD for the TIFF native stream metadata format is as follows:<!DOCTYPE "javax_imageio_tiff_stream_1.0" [ <!ELEMENT "javax_imageio_tiff_stream_1.0" (ByteOrder)> <!ELEMENT "ByteOrder" EMPTY> <!-- The stream byte order --> <!ATTLIST "ByteOrder" "value" #CDATA #REQUIRED> <!-- One of "BIG_ENDIAN" or "LITTLE_ENDIAN" --> <!-- Data type: String --> ]>
Image Metadata
The DTD for the TIFF native image metadata format is as follows:<!DOCTYPE "javax_imageio_tiff_image_1.0" [ <!ELEMENT "javax_imageio_tiff_image_1.0" (TIFFIFD)*> <!ELEMENT "TIFFIFD" (TIFFField | TIFFIFD)*> <!-- An IFD (directory) containing fields --> <!ATTLIST "TIFFIFD" "tagSets" #CDATA #REQUIRED> <!-- Data type: String --> <!ATTLIST "TIFFIFD" "parentTagNumber" #CDATA #IMPLIED> <!-- The tag number of the field pointing to this IFD --> <!-- Data type: Integer --> <!ATTLIST "TIFFIFD" "parentTagName" #CDATA #IMPLIED> <!-- A mnemonic name for the field pointing to this IFD, if known --> <!-- Data type: String --> <!ELEMENT "TIFFField" (TIFFBytes | TIFFAsciis | TIFFShorts | TIFFSShorts | TIFFLongs | TIFFSLongs | TIFFRationals | TIFFSRationals | TIFFFloats | TIFFDoubles | TIFFUndefined)> <!-- A field containing data --> <!ATTLIST "TIFFField" "number" #CDATA #REQUIRED> <!-- The tag number asociated with the field --> <!-- Data type: String --> <!ATTLIST "TIFFField" "name" #CDATA #IMPLIED> <!-- A mnemonic name associated with the field, if known --> <!-- Data type: String --> <!ELEMENT "TIFFBytes" (TIFFByte)*> <!-- A sequence of TIFFByte nodes --> <!ELEMENT "TIFFByte" EMPTY> <!-- An integral value between 0 and 255 --> <!ATTLIST "TIFFByte" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ATTLIST "TIFFByte" "description" #CDATA #IMPLIED> <!-- A description, if available --> <!-- Data type: String --> <!ELEMENT "TIFFAsciis" (TIFFAscii)*> <!-- A sequence of TIFFAscii nodes --> <!ELEMENT "TIFFAscii" EMPTY> <!-- A String value --> <!ATTLIST "TIFFAscii" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ELEMENT "TIFFShorts" (TIFFShort)*> <!-- A sequence of TIFFShort nodes --> <!ELEMENT "TIFFShort" EMPTY> <!-- An integral value between 0 and 65535 --> <!ATTLIST "TIFFShort" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ATTLIST "TIFFShort" "description" #CDATA #IMPLIED> <!-- A description, if available --> <!-- Data type: String --> <!ELEMENT "TIFFSShorts" (TIFFSShort)*> <!-- A sequence of TIFFSShort nodes --> <!ELEMENT "TIFFSShort" EMPTY> <!-- An integral value between -32768 and 32767 --> <!ATTLIST "TIFFSShort" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ATTLIST "TIFFSShort" "description" #CDATA #IMPLIED> <!-- A description, if available --> <!-- Data type: String --> <!ELEMENT "TIFFLongs" (TIFFLong)*> <!-- A sequence of TIFFLong nodes --> <!ELEMENT "TIFFLong" EMPTY> <!-- An integral value between 0 and 4294967295 --> <!ATTLIST "TIFFLong" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ATTLIST "TIFFLong" "description" #CDATA #IMPLIED> <!-- A description, if available --> <!-- Data type: String --> <!ELEMENT "TIFFSLongs" (TIFFSLong)*> <!-- A sequence of TIFFSLong nodes --> <!ELEMENT "TIFFSLong" EMPTY> <!-- An integral value between -2147483648 and 2147482647 --> <!ATTLIST "TIFFSLong" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ATTLIST "TIFFSLong" "description" #CDATA #IMPLIED> <!-- A description, if available --> <!-- Data type: String --> <!ELEMENT "TIFFRationals" (TIFFRational)*> <!-- A sequence of TIFFRational nodes --> <!ELEMENT "TIFFRational" EMPTY> <!-- A rational value consisting of an unsigned numerator and denominator --> <!ATTLIST "TIFFRational" "value" #CDATA #IMPLIED> <!-- The numerator and denominator, separated by a slash --> <!-- Data type: String --> <!ELEMENT "TIFFSRationals" (TIFFSRational)*> <!-- A sequence of TIFFSRational nodes --> <!ELEMENT "TIFFSRational" EMPTY> <!-- A rational value consisting of a signed numerator and denominator --> <!ATTLIST "TIFFSRational" "value" #CDATA #IMPLIED> <!-- The numerator and denominator, separated by a slash --> <!-- Data type: String --> <!ELEMENT "TIFFFloats" (TIFFFloat)*> <!-- A sequence of TIFFFloat nodes --> <!ELEMENT "TIFFFloat" EMPTY> <!-- A single-precision floating-point value --> <!ATTLIST "TIFFFloat" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ELEMENT "TIFFDoubles" (TIFFDouble)*> <!-- A sequence of TIFFDouble nodes --> <!ELEMENT "TIFFDouble" EMPTY> <!-- A double-precision floating-point value --> <!ATTLIST "TIFFDouble" "value" #CDATA #IMPLIED> <!-- The value --> <!-- Data type: String --> <!ELEMENT "TIFFUndefined" EMPTY> <!-- Uninterpreted byte data --> <!ATTLIST "TIFFUndefined" "value" #CDATA #IMPLIED> <!-- A list of comma-separated byte values --> <!-- Data type: String --> ]>
- Since:
- 9