riff/riff.go - image - Git at Google

 // Copyright 2014 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 riff implements the Resource Interchange File Format, used by media
 // formats such as AVI, WAVE and WEBP.
 //
 // A RIFF stream contains a sequence of chunks. Each chunk consists of an 8-byte
 // header (containing a 4-byte chunk type and a 4-byte chunk length), the chunk
 // data (presented as an io.Reader), and some padding bytes.
 //
 // A detailed description of the format is at
 // http://www.tactilemedia.com/info/MCI_Control_Info.html
 package riff // import "golang.org/x/image/riff"

 import (
 	"errors"
 	"io"
 	"io/ioutil"
 	"math"
 )

 var (
 	errMissingPaddingByte     = errors.New("riff: missing padding byte")
 	errMissingRIFFChunkHeader = errors.New("riff: missing RIFF chunk header")
 	errListSubchunkTooLong    = errors.New("riff: list subchunk too long")
 	errShortChunkData         = errors.New("riff: short chunk data")
 	errShortChunkHeader       = errors.New("riff: short chunk header")
 	errStaleReader            = errors.New("riff: stale reader")
 )

 // u32 decodes the first four bytes of b as a little-endian integer.
 func u32(b []byte) uint32 {
 	return uint32(b[0]) | uint32(b[1])<<8 | uint32(b[2])<<16 | uint32(b[3])<<24
 }

 const chunkHeaderSize = 8

 // FourCC is a four character code.
 type FourCC [4]byte

 // LIST is the "LIST" FourCC.
 var LIST = FourCC{'L', 'I', 'S', 'T'}

 // NewReader returns the RIFF stream's form type, such as "AVI " or "WAVE", and
 // its chunks as a *Reader.
 func NewReader(r io.Reader) (formType FourCC, data *Reader, err error) {
 	var buf [chunkHeaderSize]byte
 	if _, err := io.ReadFull(r, buf[:]); err != nil {
 		if err == io.EOF || err == io.ErrUnexpectedEOF {
 			err = errMissingRIFFChunkHeader
 		}
 		return FourCC{}, nil, err
 	}
 	if buf[0] != 'R' || buf[1] != 'I' || buf[2] != 'F' || buf[3] != 'F' {
 		return FourCC{}, nil, errMissingRIFFChunkHeader
 	}
 	return NewListReader(u32(buf[4:]), r)
 }

 // NewListReader returns a LIST chunk's list type, such as "movi" or "wavl",
 // and its chunks as a *Reader.
 func NewListReader(chunkLen uint32, chunkData io.Reader) (listType FourCC, data *Reader, err error) {
 	if chunkLen < 4 {
 		return FourCC{}, nil, errShortChunkData
 	}
 	z := &Reader{r: chunkData}
 	if _, err := io.ReadFull(chunkData, z.buf[:4]); err != nil {
 		if err == io.EOF || err == io.ErrUnexpectedEOF {
 			err = errShortChunkData
 		}
 		return FourCC{}, nil, err
 	}
 	z.totalLen = chunkLen - 4
 	return FourCC{z.buf[0], z.buf[1], z.buf[2], z.buf[3]}, z, nil
 }

 // Reader reads chunks from an underlying io.Reader.
 type Reader struct {
 	r   io.Reader
 	err error

 	totalLen uint32
 	chunkLen uint32

 	chunkReader *chunkReader
 	buf         [chunkHeaderSize]byte
 	padded      bool
 }

 // Next returns the next chunk's ID, length and data. It returns io.EOF if there
 // are no more chunks. The io.Reader returned becomes stale after the next Next
 // call, and should no longer be used.
 //
 // It is valid to call Next even if all of the previous chunk's data has not
 // been read.
 func (z *Reader) Next() (chunkID FourCC, chunkLen uint32, chunkData io.Reader, err error) {
 	if z.err != nil {
 		return FourCC{}, 0, nil, z.err
 	}

 	// Drain the rest of the previous chunk.
 	if z.chunkLen != 0 {
 		want := z.chunkLen
 		var got int64
 		got, z.err = io.Copy(ioutil.Discard, z.chunkReader)
 		if z.err == nil && uint32(got) != want {
 			z.err = errShortChunkData
 		}
 		if z.err != nil {
 			return FourCC{}, 0, nil, z.err
 		}
 	}
 	z.chunkReader = nil
 	if z.padded {
 		if z.totalLen == 0 {
 			z.err = errListSubchunkTooLong
 			return FourCC{}, 0, nil, z.err
 		}
 		z.totalLen--
 		_, z.err = io.ReadFull(z.r, z.buf[:1])
 		if z.err != nil {
 			if z.err == io.EOF {
 				z.err = errMissingPaddingByte
 			}
 			return FourCC{}, 0, nil, z.err
 		}
 	}

 	// We are done if we have no more data.
 	if z.totalLen == 0 {
 		z.err = io.EOF
 		return FourCC{}, 0, nil, z.err
 	}

 	// Read the next chunk header.
 	if z.totalLen < chunkHeaderSize {
 		z.err = errShortChunkHeader
 		return FourCC{}, 0, nil, z.err
 	}
 	z.totalLen -= chunkHeaderSize
 	if _, z.err = io.ReadFull(z.r, z.buf[:chunkHeaderSize]); z.err != nil {
 		if z.err == io.EOF || z.err == io.ErrUnexpectedEOF {
 			z.err = errShortChunkHeader
 		}
 		return FourCC{}, 0, nil, z.err
 	}
 	chunkID = FourCC{z.buf[0], z.buf[1], z.buf[2], z.buf[3]}
 	z.chunkLen = u32(z.buf[4:])
 	if z.chunkLen > z.totalLen {
 		z.err = errListSubchunkTooLong
 		return FourCC{}, 0, nil, z.err
 	}
 	z.padded = z.chunkLen&1 == 1
 	z.chunkReader = &chunkReader{z}
 	return chunkID, z.chunkLen, z.chunkReader, nil
 }

 type chunkReader struct {
 	z *Reader
 }

 func (c *chunkReader) Read(p []byte) (int, error) {
 	if c != c.z.chunkReader {
 		return 0, errStaleReader
 	}
 	z := c.z
 	if z.err != nil {
 		if z.err == io.EOF {
 			return 0, errStaleReader
 		}
 		return 0, z.err
 	}

 	n := int(z.chunkLen)
 	if n == 0 {
 		return 0, io.EOF
 	}
 	if n < 0 {
 		// Converting uint32 to int overflowed.
 		n = math.MaxInt32
 	}
 	if n > len(p) {
 		n = len(p)
 	}
 	n, err := z.r.Read(p[:n])
 	z.totalLen -= uint32(n)
 	z.chunkLen -= uint32(n)
 	if err != io.EOF {
 		z.err = err
 	}
 	return n, err
 }
	// Copyright 2014 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 riff implements the Resource Interchange File Format, used by media
	// formats such as AVI, WAVE and WEBP.
	//
	// A RIFF stream contains a sequence of chunks. Each chunk consists of an 8-byte
	// header (containing a 4-byte chunk type and a 4-byte chunk length), the chunk
	// data (presented as an io.Reader), and some padding bytes.
	//
	// A detailed description of the format is at
	// http://www.tactilemedia.com/info/MCI_Control_Info.html
	package riff // import "golang.org/x/image/riff"

	import (
	"errors"
	"io"
	"io/ioutil"
	"math"
	)

	var (
	errMissingPaddingByte = errors.New("riff: missing padding byte")
	errMissingRIFFChunkHeader = errors.New("riff: missing RIFF chunk header")
	errListSubchunkTooLong = errors.New("riff: list subchunk too long")
	errShortChunkData = errors.New("riff: short chunk data")
	errShortChunkHeader = errors.New("riff: short chunk header")
	errStaleReader = errors.New("riff: stale reader")
	)

	// u32 decodes the first four bytes of b as a little-endian integer.
	func u32(b []byte) uint32 {
	return uint32(b[0]) \| uint32(b[1])<<8 \| uint32(b[2])<<16 \| uint32(b[3])<<24
	}

	const chunkHeaderSize = 8

	// FourCC is a four character code.
	type FourCC [4]byte

	// LIST is the "LIST" FourCC.
	var LIST = FourCC{'L', 'I', 'S', 'T'}

	// NewReader returns the RIFF stream's form type, such as "AVI " or "WAVE", and
	// its chunks as a *Reader.
	func NewReader(r io.Reader) (formType FourCC, data *Reader, err error) {
	var buf [chunkHeaderSize]byte
	if _, err := io.ReadFull(r, buf[:]); err != nil {
	if err == io.EOF \|\| err == io.ErrUnexpectedEOF {
	err = errMissingRIFFChunkHeader
	}
	return FourCC{}, nil, err
	}
	if buf[0] != 'R' \|\| buf[1] != 'I' \|\| buf[2] != 'F' \|\| buf[3] != 'F' {
	return FourCC{}, nil, errMissingRIFFChunkHeader
	}
	return NewListReader(u32(buf[4:]), r)
	}

	// NewListReader returns a LIST chunk's list type, such as "movi" or "wavl",
	// and its chunks as a *Reader.
	func NewListReader(chunkLen uint32, chunkData io.Reader) (listType FourCC, data *Reader, err error) {
	if chunkLen < 4 {
	return FourCC{}, nil, errShortChunkData
	}
	z := &Reader{r: chunkData}
	if _, err := io.ReadFull(chunkData, z.buf[:4]); err != nil {
	if err == io.EOF \|\| err == io.ErrUnexpectedEOF {
	err = errShortChunkData
	}
	return FourCC{}, nil, err
	}
	z.totalLen = chunkLen - 4
	return FourCC{z.buf[0], z.buf[1], z.buf[2], z.buf[3]}, z, nil
	}

	// Reader reads chunks from an underlying io.Reader.
	type Reader struct {
	r io.Reader
	err error

	totalLen uint32
	chunkLen uint32

	chunkReader *chunkReader
	buf [chunkHeaderSize]byte
	padded bool
	}

	// Next returns the next chunk's ID, length and data. It returns io.EOF if there
	// are no more chunks. The io.Reader returned becomes stale after the next Next
	// call, and should no longer be used.
	//
	// It is valid to call Next even if all of the previous chunk's data has not
	// been read.
	func (z *Reader) Next() (chunkID FourCC, chunkLen uint32, chunkData io.Reader, err error) {
	if z.err != nil {
	return FourCC{}, 0, nil, z.err
	}

	// Drain the rest of the previous chunk.
	if z.chunkLen != 0 {
	want := z.chunkLen
	var got int64
	got, z.err = io.Copy(ioutil.Discard, z.chunkReader)
	if z.err == nil && uint32(got) != want {
	z.err = errShortChunkData
	}
	if z.err != nil {
	return FourCC{}, 0, nil, z.err
	}
	}
	z.chunkReader = nil
	if z.padded {
	if z.totalLen == 0 {
	z.err = errListSubchunkTooLong
	return FourCC{}, 0, nil, z.err
	}
	z.totalLen--
	_, z.err = io.ReadFull(z.r, z.buf[:1])
	if z.err != nil {
	if z.err == io.EOF {
	z.err = errMissingPaddingByte
	}
	return FourCC{}, 0, nil, z.err
	}
	}

	// We are done if we have no more data.
	if z.totalLen == 0 {
	z.err = io.EOF
	return FourCC{}, 0, nil, z.err
	}

	// Read the next chunk header.
	if z.totalLen < chunkHeaderSize {
	z.err = errShortChunkHeader
	return FourCC{}, 0, nil, z.err
	}
	z.totalLen -= chunkHeaderSize
	if _, z.err = io.ReadFull(z.r, z.buf[:chunkHeaderSize]); z.err != nil {
	if z.err == io.EOF \|\| z.err == io.ErrUnexpectedEOF {
	z.err = errShortChunkHeader
	}
	return FourCC{}, 0, nil, z.err
	}
	chunkID = FourCC{z.buf[0], z.buf[1], z.buf[2], z.buf[3]}
	z.chunkLen = u32(z.buf[4:])
	if z.chunkLen > z.totalLen {
	z.err = errListSubchunkTooLong
	return FourCC{}, 0, nil, z.err
	}
	z.padded = z.chunkLen&1 == 1
	z.chunkReader = &chunkReader{z}
	return chunkID, z.chunkLen, z.chunkReader, nil
	}

	type chunkReader struct {
	z *Reader
	}

	func (c *chunkReader) Read(p []byte) (int, error) {
	if c != c.z.chunkReader {
	return 0, errStaleReader
	}
	z := c.z
	if z.err != nil {
	if z.err == io.EOF {
	return 0, errStaleReader
	}
	return 0, z.err
	}

	n := int(z.chunkLen)
	if n == 0 {
	return 0, io.EOF
	}
	if n < 0 {
	// Converting uint32 to int overflowed.
	n = math.MaxInt32
	}
	if n > len(p) {
	n = len(p)
	}
	n, err := z.r.Read(p[:n])
	z.totalLen -= uint32(n)
	z.chunkLen -= uint32(n)
	if err != io.EOF {
	z.err = err
	}
	return n, err
	}