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https://github.com/superseriousbusiness/gotosocial.git
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1a3f26fb5c
* media: add webp support Signed-off-by: Sigrid Solveig Haflínudóttir <sigrid@ftrv.se> * bump exif-terminator to v0.5.0 Signed-off-by: Sigrid Solveig Haflínudóttir <sigrid@ftrv.se> Signed-off-by: Sigrid Solveig Haflínudóttir <sigrid@ftrv.se>
403 lines
12 KiB
Go
403 lines
12 KiB
Go
// Copyright 2011 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Package vp8 implements a decoder for the VP8 lossy image format.
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//
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// The VP8 specification is RFC 6386.
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package vp8 // import "golang.org/x/image/vp8"
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// This file implements the top-level decoding algorithm.
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import (
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"errors"
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"image"
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"io"
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)
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// limitReader wraps an io.Reader to read at most n bytes from it.
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type limitReader struct {
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r io.Reader
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n int
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}
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// ReadFull reads exactly len(p) bytes into p.
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func (r *limitReader) ReadFull(p []byte) error {
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if len(p) > r.n {
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return io.ErrUnexpectedEOF
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}
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n, err := io.ReadFull(r.r, p)
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r.n -= n
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return err
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}
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// FrameHeader is a frame header, as specified in section 9.1.
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type FrameHeader struct {
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KeyFrame bool
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VersionNumber uint8
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ShowFrame bool
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FirstPartitionLen uint32
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Width int
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Height int
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XScale uint8
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YScale uint8
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}
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const (
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nSegment = 4
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nSegmentProb = 3
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)
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// segmentHeader holds segment-related header information.
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type segmentHeader struct {
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useSegment bool
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updateMap bool
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relativeDelta bool
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quantizer [nSegment]int8
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filterStrength [nSegment]int8
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prob [nSegmentProb]uint8
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}
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const (
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nRefLFDelta = 4
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nModeLFDelta = 4
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)
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// filterHeader holds filter-related header information.
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type filterHeader struct {
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simple bool
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level int8
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sharpness uint8
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useLFDelta bool
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refLFDelta [nRefLFDelta]int8
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modeLFDelta [nModeLFDelta]int8
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perSegmentLevel [nSegment]int8
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}
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// mb is the per-macroblock decode state. A decoder maintains mbw+1 of these
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// as it is decoding macroblocks left-to-right and top-to-bottom: mbw for the
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// macroblocks in the row above, and one for the macroblock to the left.
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type mb struct {
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// pred is the predictor mode for the 4 bottom or right 4x4 luma regions.
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pred [4]uint8
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// nzMask is a mask of 8 bits: 4 for the bottom or right 4x4 luma regions,
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// and 2 + 2 for the bottom or right 4x4 chroma regions. A 1 bit indicates
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// that region has non-zero coefficients.
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nzMask uint8
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// nzY16 is a 0/1 value that is 1 if the macroblock used Y16 prediction and
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// had non-zero coefficients.
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nzY16 uint8
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}
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// Decoder decodes VP8 bitstreams into frames. Decoding one frame consists of
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// calling Init, DecodeFrameHeader and then DecodeFrame in that order.
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// A Decoder can be re-used to decode multiple frames.
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type Decoder struct {
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// r is the input bitsream.
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r limitReader
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// scratch is a scratch buffer.
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scratch [8]byte
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// img is the YCbCr image to decode into.
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img *image.YCbCr
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// mbw and mbh are the number of 16x16 macroblocks wide and high the image is.
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mbw, mbh int
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// frameHeader is the frame header. When decoding multiple frames,
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// frames that aren't key frames will inherit the Width, Height,
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// XScale and YScale of the most recent key frame.
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frameHeader FrameHeader
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// Other headers.
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segmentHeader segmentHeader
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filterHeader filterHeader
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// The image data is divided into a number of independent partitions.
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// There is 1 "first partition" and between 1 and 8 "other partitions"
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// for coefficient data.
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fp partition
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op [8]partition
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nOP int
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// Quantization factors.
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quant [nSegment]quant
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// DCT/WHT coefficient decoding probabilities.
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tokenProb [nPlane][nBand][nContext][nProb]uint8
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useSkipProb bool
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skipProb uint8
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// Loop filter parameters.
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filterParams [nSegment][2]filterParam
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perMBFilterParams []filterParam
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// The eight fields below relate to the current macroblock being decoded.
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//
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// Segment-based adjustments.
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segment int
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// Per-macroblock state for the macroblock immediately left of and those
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// macroblocks immediately above the current macroblock.
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leftMB mb
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upMB []mb
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// Bitmasks for which 4x4 regions of coeff contain non-zero coefficients.
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nzDCMask, nzACMask uint32
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// Predictor modes.
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usePredY16 bool // The libwebp C code calls this !is_i4x4_.
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predY16 uint8
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predC8 uint8
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predY4 [4][4]uint8
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// The two fields below form a workspace for reconstructing a macroblock.
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// Their specific sizes are documented in reconstruct.go.
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coeff [1*16*16 + 2*8*8 + 1*4*4]int16
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ybr [1 + 16 + 1 + 8][32]uint8
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}
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// NewDecoder returns a new Decoder.
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func NewDecoder() *Decoder {
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return &Decoder{}
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}
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// Init initializes the decoder to read at most n bytes from r.
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func (d *Decoder) Init(r io.Reader, n int) {
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d.r = limitReader{r, n}
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}
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// DecodeFrameHeader decodes the frame header.
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func (d *Decoder) DecodeFrameHeader() (fh FrameHeader, err error) {
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// All frame headers are at least 3 bytes long.
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b := d.scratch[:3]
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if err = d.r.ReadFull(b); err != nil {
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return
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}
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d.frameHeader.KeyFrame = (b[0] & 1) == 0
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d.frameHeader.VersionNumber = (b[0] >> 1) & 7
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d.frameHeader.ShowFrame = (b[0]>>4)&1 == 1
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d.frameHeader.FirstPartitionLen = uint32(b[0])>>5 | uint32(b[1])<<3 | uint32(b[2])<<11
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if !d.frameHeader.KeyFrame {
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return d.frameHeader, nil
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}
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// Frame headers for key frames are an additional 7 bytes long.
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b = d.scratch[:7]
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if err = d.r.ReadFull(b); err != nil {
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return
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}
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// Check the magic sync code.
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if b[0] != 0x9d || b[1] != 0x01 || b[2] != 0x2a {
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err = errors.New("vp8: invalid format")
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return
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}
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d.frameHeader.Width = int(b[4]&0x3f)<<8 | int(b[3])
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d.frameHeader.Height = int(b[6]&0x3f)<<8 | int(b[5])
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d.frameHeader.XScale = b[4] >> 6
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d.frameHeader.YScale = b[6] >> 6
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d.mbw = (d.frameHeader.Width + 0x0f) >> 4
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d.mbh = (d.frameHeader.Height + 0x0f) >> 4
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d.segmentHeader = segmentHeader{
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prob: [3]uint8{0xff, 0xff, 0xff},
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}
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d.tokenProb = defaultTokenProb
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d.segment = 0
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return d.frameHeader, nil
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}
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// ensureImg ensures that d.img is large enough to hold the decoded frame.
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func (d *Decoder) ensureImg() {
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if d.img != nil {
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p0, p1 := d.img.Rect.Min, d.img.Rect.Max
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if p0.X == 0 && p0.Y == 0 && p1.X >= 16*d.mbw && p1.Y >= 16*d.mbh {
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return
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}
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}
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m := image.NewYCbCr(image.Rect(0, 0, 16*d.mbw, 16*d.mbh), image.YCbCrSubsampleRatio420)
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d.img = m.SubImage(image.Rect(0, 0, d.frameHeader.Width, d.frameHeader.Height)).(*image.YCbCr)
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d.perMBFilterParams = make([]filterParam, d.mbw*d.mbh)
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d.upMB = make([]mb, d.mbw)
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}
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// parseSegmentHeader parses the segment header, as specified in section 9.3.
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func (d *Decoder) parseSegmentHeader() {
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d.segmentHeader.useSegment = d.fp.readBit(uniformProb)
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if !d.segmentHeader.useSegment {
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d.segmentHeader.updateMap = false
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return
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}
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d.segmentHeader.updateMap = d.fp.readBit(uniformProb)
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if d.fp.readBit(uniformProb) {
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d.segmentHeader.relativeDelta = !d.fp.readBit(uniformProb)
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for i := range d.segmentHeader.quantizer {
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d.segmentHeader.quantizer[i] = int8(d.fp.readOptionalInt(uniformProb, 7))
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}
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for i := range d.segmentHeader.filterStrength {
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d.segmentHeader.filterStrength[i] = int8(d.fp.readOptionalInt(uniformProb, 6))
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}
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}
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if !d.segmentHeader.updateMap {
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return
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}
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for i := range d.segmentHeader.prob {
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if d.fp.readBit(uniformProb) {
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d.segmentHeader.prob[i] = uint8(d.fp.readUint(uniformProb, 8))
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} else {
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d.segmentHeader.prob[i] = 0xff
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}
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}
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}
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// parseFilterHeader parses the filter header, as specified in section 9.4.
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func (d *Decoder) parseFilterHeader() {
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d.filterHeader.simple = d.fp.readBit(uniformProb)
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d.filterHeader.level = int8(d.fp.readUint(uniformProb, 6))
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d.filterHeader.sharpness = uint8(d.fp.readUint(uniformProb, 3))
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d.filterHeader.useLFDelta = d.fp.readBit(uniformProb)
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if d.filterHeader.useLFDelta && d.fp.readBit(uniformProb) {
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for i := range d.filterHeader.refLFDelta {
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d.filterHeader.refLFDelta[i] = int8(d.fp.readOptionalInt(uniformProb, 6))
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}
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for i := range d.filterHeader.modeLFDelta {
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d.filterHeader.modeLFDelta[i] = int8(d.fp.readOptionalInt(uniformProb, 6))
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}
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}
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if d.filterHeader.level == 0 {
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return
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}
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if d.segmentHeader.useSegment {
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for i := range d.filterHeader.perSegmentLevel {
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strength := d.segmentHeader.filterStrength[i]
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if d.segmentHeader.relativeDelta {
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strength += d.filterHeader.level
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}
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d.filterHeader.perSegmentLevel[i] = strength
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}
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} else {
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d.filterHeader.perSegmentLevel[0] = d.filterHeader.level
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}
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d.computeFilterParams()
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}
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// parseOtherPartitions parses the other partitions, as specified in section 9.5.
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func (d *Decoder) parseOtherPartitions() error {
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const maxNOP = 1 << 3
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var partLens [maxNOP]int
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d.nOP = 1 << d.fp.readUint(uniformProb, 2)
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// The final partition length is implied by the remaining chunk data
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// (d.r.n) and the other d.nOP-1 partition lengths. Those d.nOP-1 partition
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// lengths are stored as 24-bit uints, i.e. up to 16 MiB per partition.
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n := 3 * (d.nOP - 1)
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partLens[d.nOP-1] = d.r.n - n
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if partLens[d.nOP-1] < 0 {
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return io.ErrUnexpectedEOF
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}
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if n > 0 {
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buf := make([]byte, n)
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if err := d.r.ReadFull(buf); err != nil {
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return err
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}
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for i := 0; i < d.nOP-1; i++ {
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pl := int(buf[3*i+0]) | int(buf[3*i+1])<<8 | int(buf[3*i+2])<<16
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if pl > partLens[d.nOP-1] {
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return io.ErrUnexpectedEOF
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}
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partLens[i] = pl
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partLens[d.nOP-1] -= pl
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}
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}
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// We check if the final partition length can also fit into a 24-bit uint.
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// Strictly speaking, this isn't part of the spec, but it guards against a
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// malicious WEBP image that is too large to ReadFull the encoded DCT
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// coefficients into memory, whether that's because the actual WEBP file is
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// too large, or whether its RIFF metadata lists too large a chunk.
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if 1<<24 <= partLens[d.nOP-1] {
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return errors.New("vp8: too much data to decode")
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}
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buf := make([]byte, d.r.n)
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if err := d.r.ReadFull(buf); err != nil {
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return err
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}
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for i, pl := range partLens {
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if i == d.nOP {
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break
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}
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d.op[i].init(buf[:pl])
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buf = buf[pl:]
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}
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return nil
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}
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// parseOtherHeaders parses header information other than the frame header.
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func (d *Decoder) parseOtherHeaders() error {
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// Initialize and parse the first partition.
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firstPartition := make([]byte, d.frameHeader.FirstPartitionLen)
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if err := d.r.ReadFull(firstPartition); err != nil {
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return err
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}
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d.fp.init(firstPartition)
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if d.frameHeader.KeyFrame {
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// Read and ignore the color space and pixel clamp values. They are
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// specified in section 9.2, but are unimplemented.
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d.fp.readBit(uniformProb)
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d.fp.readBit(uniformProb)
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}
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d.parseSegmentHeader()
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d.parseFilterHeader()
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if err := d.parseOtherPartitions(); err != nil {
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return err
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}
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d.parseQuant()
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if !d.frameHeader.KeyFrame {
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// Golden and AltRef frames are specified in section 9.7.
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// TODO(nigeltao): implement. Note that they are only used for video, not still images.
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return errors.New("vp8: Golden / AltRef frames are not implemented")
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}
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// Read and ignore the refreshLastFrameBuffer bit, specified in section 9.8.
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// It applies only to video, and not still images.
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d.fp.readBit(uniformProb)
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d.parseTokenProb()
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d.useSkipProb = d.fp.readBit(uniformProb)
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if d.useSkipProb {
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d.skipProb = uint8(d.fp.readUint(uniformProb, 8))
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}
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if d.fp.unexpectedEOF {
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return io.ErrUnexpectedEOF
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}
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return nil
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}
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// DecodeFrame decodes the frame and returns it as an YCbCr image.
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// The image's contents are valid up until the next call to Decoder.Init.
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func (d *Decoder) DecodeFrame() (*image.YCbCr, error) {
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d.ensureImg()
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if err := d.parseOtherHeaders(); err != nil {
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return nil, err
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}
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// Reconstruct the rows.
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for mbx := 0; mbx < d.mbw; mbx++ {
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d.upMB[mbx] = mb{}
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}
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for mby := 0; mby < d.mbh; mby++ {
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d.leftMB = mb{}
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for mbx := 0; mbx < d.mbw; mbx++ {
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skip := d.reconstruct(mbx, mby)
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fs := d.filterParams[d.segment][btou(!d.usePredY16)]
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fs.inner = fs.inner || !skip
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d.perMBFilterParams[d.mbw*mby+mbx] = fs
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}
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}
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if d.fp.unexpectedEOF {
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return nil, io.ErrUnexpectedEOF
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}
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for i := 0; i < d.nOP; i++ {
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if d.op[i].unexpectedEOF {
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return nil, io.ErrUnexpectedEOF
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}
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}
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// Apply the loop filter.
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//
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// Even if we are using per-segment levels, section 15 says that "loop
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// filtering must be skipped entirely if loop_filter_level at either the
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// frame header level or macroblock override level is 0".
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if d.filterHeader.level != 0 {
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if d.filterHeader.simple {
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d.simpleFilter()
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} else {
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d.normalFilter()
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}
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}
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return d.img, nil
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}
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