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image/tiff: implement a decoder.

The current iteration can decode 8-bit images in
grayscale, paletted, RGB, RGBA and NRGBA mode. LZW compression
is implemented but does not work on my test images.
Deflate (i.e. zlib) compression with or without a horizontal
predictor is supported.

R=nigeltao, nigeltao_gnome
CC=golang-dev, mpl
https://golang.org/cl/4240051
This commit is contained in:
Benny Siegert 2011-05-04 20:52:55 -07:00 committed by Nigel Tao
parent 737e96c7f3
commit d97b8a817b
7 changed files with 597 additions and 2 deletions

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@ -107,6 +107,7 @@ DIRS=\
image\ image\
image/jpeg\ image/jpeg\
image/png\ image/png\
image/tiff\
image/ycbcr\ image/ycbcr\
index/suffixarray\ index/suffixarray\
io\ io\

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@ -10,9 +10,10 @@ import (
"os" "os"
"testing" "testing"
// TODO(nigeltao): implement bmp, gif and tiff decoders. // TODO(nigeltao): implement bmp and gif decoders.
_ "image/jpeg" _ "image/jpeg"
_ "image/png" _ "image/png"
_ "image/tiff"
) )
const goldenFile = "testdata/video-001.png" const goldenFile = "testdata/video-001.png"
@ -30,7 +31,7 @@ var imageTests = []imageTest{
// JPEG is a lossy format and hence needs a non-zero tolerance. // JPEG is a lossy format and hence needs a non-zero tolerance.
{"testdata/video-001.jpeg", 8 << 8}, {"testdata/video-001.jpeg", 8 << 8},
{"testdata/video-001.png", 0}, {"testdata/video-001.png", 0},
//{"testdata/video-001.tiff", 0}, {"testdata/video-001.tiff", 0},
} }
func decode(filename string) (image.Image, string, os.Error) { func decode(filename string) (image.Image, string, os.Error) {

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@ -0,0 +1,13 @@
# Copyright 2011 The Go Authors. All rights reserved.
# Use of this source code is governed by a BSD-style
# license that can be found in the LICENSE file.
include ../../../Make.inc
TARG=image/tiff
GOFILES=\
buffer.go\
consts.go\
reader.go\
include ../../../Make.pkg

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@ -0,0 +1,57 @@
// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tiff
import (
"io"
"os"
)
// buffer buffers an io.Reader to satisfy io.ReaderAt.
type buffer struct {
r io.Reader
buf []byte
}
func (b *buffer) ReadAt(p []byte, off int64) (int, os.Error) {
o := int(off)
end := o + len(p)
if int64(end) != off+int64(len(p)) {
return 0, os.EINVAL
}
m := len(b.buf)
if end > m {
if end > cap(b.buf) {
newcap := 1024
for newcap < end {
newcap *= 2
}
newbuf := make([]byte, end, newcap)
copy(newbuf, b.buf)
b.buf = newbuf
} else {
b.buf = b.buf[:end]
}
if n, err := io.ReadFull(b.r, b.buf[m:end]); err != nil {
end = m + n
b.buf = b.buf[:end]
return copy(p, b.buf[o:end]), err
}
}
return copy(p, b.buf[o:end]), nil
}
// newReaderAt converts an io.Reader into an io.ReaderAt.
func newReaderAt(r io.Reader) io.ReaderAt {
if ra, ok := r.(io.ReaderAt); ok {
return ra
}
return &buffer{
r: r,
buf: make([]byte, 0, 1024),
}
}

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@ -0,0 +1,36 @@
// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tiff
import (
"os"
"strings"
"testing"
)
var readAtTests = []struct {
n int
off int64
s string
err os.Error
}{
{2, 0, "ab", nil},
{6, 0, "abcdef", nil},
{3, 3, "def", nil},
{3, 5, "f", os.EOF},
{3, 6, "", os.EOF},
}
func TestReadAt(t *testing.T) {
r := newReaderAt(strings.NewReader("abcdef"))
b := make([]byte, 10)
for _, test := range readAtTests {
n, err := r.ReadAt(b[:test.n], test.off)
s := string(b[:n])
if s != test.s || err != test.err {
t.Errorf("buffer.ReadAt(<%v bytes>, %v): got %v, %q; want %v, %q", test.n, test.off, err, s, test.err, test.s)
}
}
}

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@ -0,0 +1,102 @@
// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tiff
// A tiff image file contains one or more images. The metadata
// of each image is contained in an Image File Directory (IFD),
// which contains entries of 12 bytes each and is described
// on page 14-16 of the specification. An IFD entry consists of
//
// - a tag, which describes the signification of the entry,
// - the data type and length of the entry,
// - the data itself or a pointer to it if it is more than 4 bytes.
//
// The presence of a length means that each IFD is effectively an array.
const (
leHeader = "II\x2A\x00" // Header for little-endian files.
beHeader = "MM\x00\x2A" // Header for big-endian files.
ifdLen = 12 // Length of an IFD entry in bytes.
)
// Data types (p. 14-16 of the spec).
const (
dtByte = 1
dtASCII = 2
dtShort = 3
dtLong = 4
dtRational = 5
)
// The length of one instance of each data type in bytes.
var lengths = [...]uint32{0, 1, 1, 2, 4, 8}
// Tags (see p. 28-41 of the spec).
const (
tImageWidth = 256
tImageLength = 257
tBitsPerSample = 258
tCompression = 259
tPhotometricInterpretation = 262
tStripOffsets = 273
tSamplesPerPixel = 277
tRowsPerStrip = 278
tStripByteCounts = 279
tXResolution = 282
tYResolution = 283
tResolutionUnit = 296
tPredictor = 317
tColorMap = 320
tExtraSamples = 338
)
// Compression types (defined in various places in the spec and supplements).
const (
cNone = 1
cCCITT = 2
cG3 = 3 // Group 3 Fax.
cG4 = 4 // Group 4 Fax.
cLZW = 5
cJPEGOld = 6 // Superseded by cJPEG.
cJPEG = 7
cDeflate = 8 // zlib compression.
cPackBits = 32773
cDeflateOld = 32946 // Superseded by cDeflate.
)
// Photometric interpretation values (see p. 37 of the spec).
const (
pWhiteIsZero = 0
pBlackIsZero = 1
pRGB = 2
pPaletted = 3
pTransMask = 4 // transparency mask
pCMYK = 5
pYCbCr = 6
pCIELab = 8
)
// Values for the tPredictor tag (page 64-65 of the spec).
const (
prNone = 1
prHorizontal = 2
)
// imageMode represents the mode of the image.
type imageMode int
const (
mBilevel imageMode = iota
mPaletted
mGray
mGrayInvert
mRGB
mRGBA
mNRGBA
)

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@ -0,0 +1,385 @@
// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Package tiff implements a TIFF image decoder.
//
// The TIFF specification is at http://partners.adobe.com/public/developer/en/tiff/TIFF6.pdf
package tiff
import (
"compress/lzw"
"compress/zlib"
"encoding/binary"
"image"
"io"
"io/ioutil"
"os"
)
// A FormatError reports that the input is not a valid TIFF image.
type FormatError string
func (e FormatError) String() string {
return "tiff: invalid format: " + string(e)
}
// An UnsupportedError reports that the input uses a valid but
// unimplemented feature.
type UnsupportedError string
func (e UnsupportedError) String() string {
return "tiff: unsupported feature: " + string(e)
}
// An InternalError reports that an internal error was encountered.
type InternalError string
func (e InternalError) String() string {
return "tiff: internal error: " + string(e)
}
type decoder struct {
r io.ReaderAt
byteOrder binary.ByteOrder
config image.Config
mode imageMode
features map[int][]uint
palette []image.Color
}
// firstVal returns the first uint of the features entry with the given tag,
// or 0 if the tag does not exist.
func (d *decoder) firstVal(tag int) uint {
f := d.features[tag]
if len(f) == 0 {
return 0
}
return f[0]
}
// ifdUint decodes the IFD entry in p, which must be of the Byte, Short
// or Long type, and returns the decoded uint values.
func (d *decoder) ifdUint(p []byte) (u []uint, err os.Error) {
var raw []byte
datatype := d.byteOrder.Uint16(p[2:4])
count := d.byteOrder.Uint32(p[4:8])
if datalen := lengths[datatype] * count; datalen > 4 {
// The IFD contains a pointer to the real value.
raw = make([]byte, datalen)
_, err = d.r.ReadAt(raw, int64(d.byteOrder.Uint32(p[8:12])))
} else {
raw = p[8 : 8+datalen]
}
if err != nil {
return nil, err
}
u = make([]uint, count)
switch datatype {
case dtByte:
for i := uint32(0); i < count; i++ {
u[i] = uint(raw[i])
}
case dtShort:
for i := uint32(0); i < count; i++ {
u[i] = uint(d.byteOrder.Uint16(raw[2*i : 2*(i+1)]))
}
case dtLong:
for i := uint32(0); i < count; i++ {
u[i] = uint(d.byteOrder.Uint32(raw[4*i : 4*(i+1)]))
}
default:
return nil, UnsupportedError("data type")
}
return u, nil
}
// parseIFD decides whether the the IFD entry in p is "interesting" and
// stows away the data in the decoder.
func (d *decoder) parseIFD(p []byte) os.Error {
tag := d.byteOrder.Uint16(p[0:2])
switch tag {
case tBitsPerSample,
tExtraSamples,
tPhotometricInterpretation,
tCompression,
tPredictor,
tStripOffsets,
tStripByteCounts,
tRowsPerStrip,
tImageLength,
tImageWidth:
val, err := d.ifdUint(p)
if err != nil {
return err
}
d.features[int(tag)] = val
case tColorMap:
val, err := d.ifdUint(p)
if err != nil {
return err
}
numcolors := len(val) / 3
if len(val)%3 != 0 || numcolors <= 0 || numcolors > 256 {
return FormatError("bad ColorMap length")
}
d.palette = make([]image.Color, numcolors)
for i := 0; i < numcolors; i++ {
d.palette[i] = image.RGBA64Color{
uint16(val[i]),
uint16(val[i+numcolors]),
uint16(val[i+2*numcolors]),
0xffff,
}
}
}
return nil
}
// decode decodes the raw data of an image with 8 bits in each sample.
// It reads from p and writes the strip with ymin <= y < ymax into dst.
func (d *decoder) decode(dst image.Image, p []byte, ymin, ymax int) os.Error {
spp := len(d.features[tBitsPerSample]) // samples per pixel
off := 0
width := dst.Bounds().Dx()
if len(p) < spp*(ymax-ymin)*width {
return FormatError("short data strip")
}
// Apply horizontal predictor if necessary.
// In this case, p contains the color difference to the preceding pixel.
// See page 64-65 of the spec.
if d.firstVal(tPredictor) == prHorizontal {
for y := ymin; y < ymax; y++ {
off += spp
for x := 0; x < (width-1)*spp; x++ {
p[off] += p[off-spp]
off++
}
}
off = 0
}
switch d.mode {
case mGray:
img := dst.(*image.Gray)
for y := ymin; y < ymax; y++ {
for x := img.Rect.Min.X; x < img.Rect.Max.X; x++ {
img.Set(x, y, image.GrayColor{p[off]})
off += spp
}
}
case mGrayInvert:
img := dst.(*image.Gray)
for y := ymin; y < ymax; y++ {
for x := img.Rect.Min.X; x < img.Rect.Max.X; x++ {
img.Set(x, y, image.GrayColor{0xff - p[off]})
off += spp
}
}
case mPaletted:
img := dst.(*image.Paletted)
for y := ymin; y < ymax; y++ {
for x := img.Rect.Min.X; x < img.Rect.Max.X; x++ {
img.SetColorIndex(x, y, p[off])
off += spp
}
}
case mRGB:
img := dst.(*image.RGBA)
for y := ymin; y < ymax; y++ {
for x := img.Rect.Min.X; x < img.Rect.Max.X; x++ {
img.Set(x, y, image.RGBAColor{p[off], p[off+1], p[off+2], 0xff})
off += spp
}
}
case mNRGBA:
img := dst.(*image.NRGBA)
for y := ymin; y < ymax; y++ {
for x := img.Rect.Min.X; x < img.Rect.Max.X; x++ {
img.Set(x, y, image.NRGBAColor{p[off], p[off+1], p[off+2], p[off+3]})
off += spp
}
}
case mRGBA:
img := dst.(*image.RGBA)
for y := ymin; y < ymax; y++ {
for x := img.Rect.Min.X; x < img.Rect.Max.X; x++ {
img.Set(x, y, image.RGBAColor{p[off], p[off+1], p[off+2], p[off+3]})
off += spp
}
}
}
return nil
}
func newDecoder(r io.Reader) (*decoder, os.Error) {
d := &decoder{
r: newReaderAt(r),
features: make(map[int][]uint),
}
p := make([]byte, 8)
if _, err := d.r.ReadAt(p, 0); err != nil {
return nil, err
}
switch string(p[0:4]) {
case leHeader:
d.byteOrder = binary.LittleEndian
case beHeader:
d.byteOrder = binary.BigEndian
default:
return nil, FormatError("malformed header")
}
ifdOffset := int64(d.byteOrder.Uint32(p[4:8]))
// The first two bytes contain the number of entries (12 bytes each).
if _, err := d.r.ReadAt(p[0:2], ifdOffset); err != nil {
return nil, err
}
numItems := int(d.byteOrder.Uint16(p[0:2]))
// All IFD entries are read in one chunk.
p = make([]byte, ifdLen*numItems)
if _, err := d.r.ReadAt(p, ifdOffset+2); err != nil {
return nil, err
}
for i := 0; i < len(p); i += ifdLen {
if err := d.parseIFD(p[i : i+ifdLen]); err != nil {
return nil, err
}
}
d.config.Width = int(d.firstVal(tImageWidth))
d.config.Height = int(d.firstVal(tImageLength))
// Determine the image mode.
switch d.firstVal(tPhotometricInterpretation) {
case pRGB:
d.config.ColorModel = image.RGBAColorModel
// RGB images normally have 3 samples per pixel.
// If there are more, ExtraSamples (p. 31-32 of the spec)
// gives their meaning (usually an alpha channel).
switch len(d.features[tBitsPerSample]) {
case 3:
d.mode = mRGB
case 4:
switch d.firstVal(tExtraSamples) {
case 1:
d.mode = mRGBA
case 2:
d.mode = mNRGBA
d.config.ColorModel = image.NRGBAColorModel
default:
// The extra sample is discarded.
d.mode = mRGB
}
default:
return nil, FormatError("wrong number of samples for RGB")
}
case pPaletted:
d.mode = mPaletted
d.config.ColorModel = image.PalettedColorModel(d.palette)
case pWhiteIsZero:
d.mode = mGrayInvert
d.config.ColorModel = image.GrayColorModel
case pBlackIsZero:
d.mode = mGray
d.config.ColorModel = image.GrayColorModel
default:
return nil, UnsupportedError("color model")
}
if _, ok := d.features[tBitsPerSample]; !ok {
return nil, FormatError("BitsPerSample tag missing")
}
for _, b := range d.features[tBitsPerSample] {
if b != 8 {
return nil, UnsupportedError("not an 8-bit image")
}
}
return d, nil
}
// DecodeConfig returns the color model and dimensions of a TIFF image without
// decoding the entire image.
func DecodeConfig(r io.Reader) (image.Config, os.Error) {
d, err := newDecoder(r)
if err != nil {
return image.Config{}, err
}
return d.config, nil
}
// Decode reads a TIFF image from r and returns it as an image.Image.
// The type of Image returned depends on the contents of the TIFF.
func Decode(r io.Reader) (img image.Image, err os.Error) {
d, err := newDecoder(r)
if err != nil {
return
}
// Check if we have the right number of strips, offsets and counts.
rps := int(d.firstVal(tRowsPerStrip))
numStrips := (d.config.Height + rps - 1) / rps
if rps == 0 || len(d.features[tStripOffsets]) < numStrips || len(d.features[tStripByteCounts]) < numStrips {
return nil, FormatError("inconsistent header")
}
switch d.mode {
case mGray, mGrayInvert:
img = image.NewGray(d.config.Width, d.config.Height)
case mPaletted:
img = image.NewPaletted(d.config.Width, d.config.Height, d.palette)
case mNRGBA:
img = image.NewNRGBA(d.config.Width, d.config.Height)
case mRGB, mRGBA:
img = image.NewRGBA(d.config.Width, d.config.Height)
}
var p []byte
for i := 0; i < numStrips; i++ {
ymin := i * rps
// The last strip may be shorter.
if i == numStrips-1 && d.config.Height%rps != 0 {
rps = d.config.Height % rps
}
offset := int64(d.features[tStripOffsets][i])
n := int64(d.features[tStripByteCounts][i])
switch d.firstVal(tCompression) {
case cNone:
// TODO(bsiegert): Avoid copy if r is a tiff.buffer.
p = make([]byte, 0, n)
_, err = d.r.ReadAt(p, offset)
case cLZW:
r := lzw.NewReader(io.NewSectionReader(d.r, offset, n), lzw.MSB, 8)
p, err = ioutil.ReadAll(r)
r.Close()
case cDeflate, cDeflateOld:
r, err := zlib.NewReader(io.NewSectionReader(d.r, offset, n))
if err != nil {
return nil, err
}
p, err = ioutil.ReadAll(r)
r.Close()
default:
err = UnsupportedError("compression")
}
if err != nil {
return
}
err = d.decode(img, p, ymin, ymin+rps)
}
return
}
func init() {
image.RegisterFormat("tiff", leHeader, Decode, DecodeConfig)
image.RegisterFormat("tiff", beHeader, Decode, DecodeConfig)
}