av/codec/h264/h264dec/slice.go

1421 lines
45 KiB
Go

package h264dec
import (
"bytes"
"fmt"
"math"
"bitbucket.org/ausocean/av/codec/h264/h264dec/bits"
"github.com/pkg/errors"
)
// Chroma formats as defined in section 6.2, tab 6-1.
const (
chromaMonochrome = iota
chroma420
chroma422
chroma444
)
type VideoStream struct {
SPS *SPS
PPS *PPS
Slices []*SliceContext
}
type SliceContext struct {
*NalUnit
*SPS
*PPS
*Slice
}
type Slice struct {
Header *SliceHeader
Data *SliceData
}
// RefPicListModification provides elements of a ref_pic_list_modification syntax
// (defined in 7.3.3.1 of specifications) and a ref_pic_list_mvc_modification
// (defined in H.7.3.3.1.1 of specifications).
type RefPicListModification struct {
RefPicListModificationFlagL0 bool
ModificationOfPicNums int
AbsDiffPicNumMinus1 int
LongTermPicNum int
RefPicListModificationFlagL1 bool
}
// TODO: need to complete this.
// NewRefPicListMVCModification parses elements of a ref_pic_list_mvc_modification
// following the syntax structure defined in section H.7.3.3.1.1, and returns as
// a new RefPicListModification.
func NewRefPicListMVCModifiation(br *bits.BitReader) (*RefPicListModification, error) {
return nil, nil
}
// NewRefPicListModification parses elements of a ref_pic_list_modification
// following the syntax structure defined in section 7.3.3.1, and returns as
// a new RefPicListModification.
func NewRefPicListModification(br *bits.BitReader, h *SliceHeader) (*RefPicListModification, error) {
r := &RefPicListModification{}
// 7.3.3.1
if h.SliceType%5 != 2 && h.SliceType%5 != 4 {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read RefPicListModificationFlagL0")
}
r.RefPicListModificationFlagL0 = b == 1
if r.RefPicListModificationFlagL0 {
for r.ModificationOfPicNums != 3 {
r.ModificationOfPicNums, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse ModificationOfPicNums")
}
if r.ModificationOfPicNums == 0 || r.ModificationOfPicNums == 1 {
r.AbsDiffPicNumMinus1, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse AbsDiffPicNumMinus1")
}
} else if r.ModificationOfPicNums == 2 {
r.LongTermPicNum, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LongTermPicNum")
}
}
}
}
}
if h.SliceType%5 == 1 {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read RefPicListModificationFlagL1")
}
r.RefPicListModificationFlagL1 = b == 1
if r.RefPicListModificationFlagL1 {
for r.ModificationOfPicNums != 3 {
r.ModificationOfPicNums, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse ModificationOfPicNums")
}
if r.ModificationOfPicNums == 0 || r.ModificationOfPicNums == 1 {
r.AbsDiffPicNumMinus1, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse AbsDiffPicNumMinus1")
}
} else if r.ModificationOfPicNums == 2 {
r.LongTermPicNum, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LongTermPicNum")
}
}
}
}
}
// refPicListModification()
return nil, nil
}
// PredWeightTable provides elements of a pred_weight_table syntax structure
// as defined in section 7.3.3.2 of the specifications.
type PredWeightTable struct {
LumaLog2WeightDenom int
ChromaLog2WeightDenom int
ChromaArrayType int
LumaWeightL0Flag bool
LumaWeightL0 []int
LumaOffsetL0 []int
ChromaWeightL0Flag bool
ChromaWeightL0 [][]int
ChromaOffsetL0 [][]int
LumaWeightL1Flag bool
LumaWeightL1 []int
LumaOffsetL1 []int
ChromaWeightL1Flag bool
ChromaWeightL1 [][]int
ChromaOffsetL1 [][]int
}
// NewPredWeightTable parses elements of a pred_weight_table following the
// syntax structure defined in section 7.3.3.2, and returns as a new
// PredWeightTable.
func NewPredWeightTable(br *bits.BitReader, h *SliceHeader) (*PredWeightTable, error) {
p := &PredWeightTable{}
var err error
p.LumaLog2WeightDenom, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LumaLog2WeightDenom")
}
if p.ChromaArrayType != 0 {
p.ChromaLog2WeightDenom, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse ChromaLog2WeightDenom")
}
}
for i := 0; i <= h.NumRefIdxL0ActiveMinus1; i++ {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read LumaWeightL0Flag")
}
p.LumaWeightL0Flag = b == 1
if p.LumaWeightL0Flag {
se, err := readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LumaWeightL0")
}
p.LumaWeightL0 = append(p.LumaWeightL0, se)
se, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LumaOffsetL0")
}
p.LumaOffsetL0 = append(p.LumaOffsetL0, se)
}
if p.ChromaArrayType != 0 {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read ChromaWeightL0Flag")
}
p.ChromaWeightL0Flag = b == 1
if p.ChromaWeightL0Flag {
p.ChromaWeightL0 = append(p.ChromaWeightL0, []int{})
p.ChromaOffsetL0 = append(p.ChromaOffsetL0, []int{})
for j := 0; j < 2; j++ {
se, err := readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse ChromaWeightL0")
}
p.ChromaWeightL0[i] = append(p.ChromaWeightL0[i], se)
se, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse ChromaOffsetL0")
}
p.ChromaOffsetL0[i] = append(p.ChromaOffsetL0[i], se)
}
}
}
}
if h.SliceType%5 == 1 {
for i := 0; i <= h.NumRefIdxL1ActiveMinus1; i++ {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read LumaWeightL1Flag")
}
p.LumaWeightL1Flag = b == 1
if p.LumaWeightL1Flag {
se, err := readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LumaWeightL1")
}
p.LumaWeightL1 = append(p.LumaWeightL1, se)
se, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LumaOffsetL1")
}
p.LumaOffsetL1 = append(p.LumaOffsetL1, se)
}
if p.ChromaArrayType != 0 {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read ChromaWeightL1Flag")
}
p.ChromaWeightL1Flag = b == 1
if p.ChromaWeightL1Flag {
p.ChromaWeightL1 = append(p.ChromaWeightL1, []int{})
p.ChromaOffsetL1 = append(p.ChromaOffsetL1, []int{})
for j := 0; j < 2; j++ {
se, err := readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse ChromaWeightL1")
}
p.ChromaWeightL1[i] = append(p.ChromaWeightL1[i], se)
se, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse ChromaOffsetL1")
}
p.ChromaOffsetL1[i] = append(p.ChromaOffsetL1[i], se)
}
}
}
}
}
return p, nil
}
type SliceHeader struct {
FirstMbInSlice int
SliceType int
PPSID int
ColorPlaneID int
FrameNum int
FieldPic bool
BottomField bool
IDRPicID int
PicOrderCntLsb int
DeltaPicOrderCntBottom int
DeltaPicOrderCnt []int
RedundantPicCnt int
DirectSpatialMvPred bool
NumRefIdxActiveOverride bool
NumRefIdxL0ActiveMinus1 int
NumRefIdxL1ActiveMinus1 int
*RefPicListModification
*PredWeightTable
// dec_ref_pic_marking
NoOutputOfPriorPicsFlag bool
LongTermReferenceFlag bool
AdaptiveRefPicMarkingModeFlag bool
MemoryManagementControlOperation int
DifferenceOfPicNumsMinus1 int
LongTermFrameIdx int
MaxLongTermFrameIdxPlus1 int
CabacInit int
SliceQpDelta int
SpForSwitch bool
SliceQsDelta int
DisableDeblockingFilter int
SliceAlphaC0OffsetDiv2 int
SliceBetaOffsetDiv2 int
SliceGroupChangeCycle int
}
type SliceData struct {
BitReader *bits.BitReader
CabacAlignmentOneBit int
MbSkipRun int
MbSkipFlag bool
MbFieldDecodingFlag bool
EndOfSliceFlag bool
MbType int
MbTypeName string
SliceTypeName string
PcmAlignmentZeroBit int
PcmSampleLuma []int
PcmSampleChroma []int
TransformSize8x8Flag bool
CodedBlockPattern int
MbQpDelta int
PrevIntra4x4PredModeFlag []int
RemIntra4x4PredMode []int
PrevIntra8x8PredModeFlag []int
RemIntra8x8PredMode []int
IntraChromaPredMode int
RefIdxL0 []int
RefIdxL1 []int
MvdL0 [][][]int
MvdL1 [][][]int
}
// Table 7-6
var sliceTypeMap = map[int]string{
0: "P",
1: "B",
2: "I",
3: "SP",
4: "SI",
5: "P",
6: "B",
7: "I",
8: "SP",
9: "SI",
}
func flagVal(b bool) int {
if b {
return 1
}
return 0
}
// context-adaptive arithmetic entropy-coded element (CABAC)
// 9.3
// When parsing the slice date of a slice (7.3.4) the initialization is 9.3.1
func (d SliceData) ae(v int) int {
// 9.3.1.1 : CABAC context initialization ctxIdx
return 0
}
// 8.2.2
func MbToSliceGroupMap(sps *SPS, pps *PPS, header *SliceHeader) []int {
mbaffFrameFlag := 0
if sps.MBAdaptiveFrameField && !header.FieldPic {
mbaffFrameFlag = 1
}
mapUnitToSliceGroupMap := MapUnitToSliceGroupMap(sps, pps, header)
mbToSliceGroupMap := []int{}
for i := 0; i <= PicSizeInMbs(sps, header)-1; i++ {
if sps.FrameMbsOnly || header.FieldPic {
mbToSliceGroupMap = append(mbToSliceGroupMap, mapUnitToSliceGroupMap[i])
continue
}
if mbaffFrameFlag == 1 {
mbToSliceGroupMap = append(mbToSliceGroupMap, mapUnitToSliceGroupMap[i/2])
continue
}
if !sps.FrameMbsOnly && !sps.MBAdaptiveFrameField && !header.FieldPic {
mbToSliceGroupMap = append(
mbToSliceGroupMap,
mapUnitToSliceGroupMap[(i/(2*PicWidthInMbs(sps)))*PicWidthInMbs(sps)+(i%PicWidthInMbs(sps))])
}
}
return mbToSliceGroupMap
}
func PicWidthInMbs(sps *SPS) int {
return sps.PicWidthInMbsMinus1 + 1
}
func PicHeightInMapUnits(sps *SPS) int {
return sps.PicHeightInMapUnitsMinus1 + 1
}
func PicSizeInMapUnits(sps *SPS) int {
return PicWidthInMbs(sps) * PicHeightInMapUnits(sps)
}
func FrameHeightInMbs(sps *SPS) int {
return (2 - flagVal(sps.FrameMbsOnly)) * PicHeightInMapUnits(sps)
}
func PicHeightInMbs(sps *SPS, header *SliceHeader) int {
return FrameHeightInMbs(sps) / (1 + flagVal(header.FieldPic))
}
func PicSizeInMbs(sps *SPS, header *SliceHeader) int {
return PicWidthInMbs(sps) * PicHeightInMbs(sps, header)
}
// table 6-1
func SubWidthC(sps *SPS) int {
n := 17
if sps.UseSeparateColorPlane {
if sps.ChromaFormat == chroma444 {
return n
}
}
switch sps.ChromaFormat {
case chromaMonochrome:
return n
case chroma420:
n = 2
case chroma422:
n = 2
case chroma444:
n = 1
}
return n
}
func SubHeightC(sps *SPS) int {
n := 17
if sps.UseSeparateColorPlane {
if sps.ChromaFormat == chroma444 {
return n
}
}
switch sps.ChromaFormat {
case chromaMonochrome:
return n
case chroma420:
n = 2
case chroma422:
n = 1
case chroma444:
n = 1
}
return n
}
// 7-36
func CodedBlockPatternLuma(data *SliceData) int {
return data.CodedBlockPattern % 16
}
func CodedBlockPatternChroma(data *SliceData) int {
return data.CodedBlockPattern / 16
}
// dependencyId see Annex G.8.8.1
// Also G7.3.1.1 nal_unit_header_svc_extension
func DQId(nalUnit *NalUnit) int {
return (nalUnit.DependencyId << 4) + nalUnit.QualityId
}
// Annex G p527
func NumMbPart(nalUnit *NalUnit, sps *SPS, header *SliceHeader, data *SliceData) int {
sliceType := sliceTypeMap[header.SliceType]
numMbPart := 0
if MbTypeName(sliceType, CurrMbAddr(sps, header)) == "B_SKIP" || MbTypeName(sliceType, CurrMbAddr(sps, header)) == "B_Direct_16x16" {
if DQId(nalUnit) == 0 && nalUnit.Type != 20 {
numMbPart = 4
} else if DQId(nalUnit) > 0 && nalUnit.Type == 20 {
numMbPart = 1
}
} else if MbTypeName(sliceType, CurrMbAddr(sps, header)) != "B_SKIP" && MbTypeName(sliceType, CurrMbAddr(sps, header)) != "B_Direct_16x16" {
numMbPart = CurrMbAddr(sps, header)
}
return numMbPart
}
func MbPred(sliceContext *SliceContext, br *bits.BitReader, rbsp []byte) error {
var cabac *CABAC
sliceType := sliceTypeMap[sliceContext.Slice.Header.SliceType]
mbPartPredMode, err := MbPartPredMode(sliceContext.Slice.Data, sliceType, sliceContext.Slice.Data.MbType, 0)
if err != nil {
return errors.Wrap(err, "could not get mbPartPredMode")
}
if mbPartPredMode == intra4x4 || mbPartPredMode == intra8x8 || mbPartPredMode == intra16x16 {
if mbPartPredMode == intra4x4 {
for luma4x4BlkIdx := 0; luma4x4BlkIdx < 16; luma4x4BlkIdx++ {
var v int
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: 1 bit or ae(v)
binarization := NewBinarization(
"PrevIntra4x4PredModeFlag",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
cabac = initCabac(binarization, sliceContext)
_ = cabac
logger.Printf("TODO: ae for PevIntra4x4PredModeFlag[%d]\n", luma4x4BlkIdx)
} else {
b, err := br.ReadBits(1)
if err != nil {
return errors.Wrap(err, "could not read PrevIntra4x4PredModeFlag")
}
v = int(b)
}
sliceContext.Slice.Data.PrevIntra4x4PredModeFlag = append(
sliceContext.Slice.Data.PrevIntra4x4PredModeFlag,
v)
if sliceContext.Slice.Data.PrevIntra4x4PredModeFlag[luma4x4BlkIdx] == 0 {
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: 3 bits or ae(v)
binarization := NewBinarization(
"RemIntra4x4PredMode",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
logger.Printf("TODO: ae for RemIntra4x4PredMode[%d]\n", luma4x4BlkIdx)
} else {
b, err := br.ReadBits(3)
if err != nil {
return errors.Wrap(err, "could not read RemIntra4x4PredMode")
}
v = int(b)
}
if len(sliceContext.Slice.Data.RemIntra4x4PredMode) < luma4x4BlkIdx {
sliceContext.Slice.Data.RemIntra4x4PredMode = append(
sliceContext.Slice.Data.RemIntra4x4PredMode,
make([]int, luma4x4BlkIdx-len(sliceContext.Slice.Data.RemIntra4x4PredMode)+1)...)
}
sliceContext.Slice.Data.RemIntra4x4PredMode[luma4x4BlkIdx] = v
}
}
}
if mbPartPredMode == intra8x8 {
for luma8x8BlkIdx := 0; luma8x8BlkIdx < 4; luma8x8BlkIdx++ {
sliceContext.Update(sliceContext.Slice.Header, sliceContext.Slice.Data)
var v int
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: 1 bit or ae(v)
binarization := NewBinarization("PrevIntra8x8PredModeFlag", sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
logger.Printf("TODO: ae for PrevIntra8x8PredModeFlag[%d]\n", luma8x8BlkIdx)
} else {
b, err := br.ReadBits(1)
if err != nil {
return errors.Wrap(err, "could not read PrevIntra8x8PredModeFlag")
}
v = int(b)
}
sliceContext.Slice.Data.PrevIntra8x8PredModeFlag = append(
sliceContext.Slice.Data.PrevIntra8x8PredModeFlag, v)
if sliceContext.Slice.Data.PrevIntra8x8PredModeFlag[luma8x8BlkIdx] == 0 {
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: 3 bits or ae(v)
binarization := NewBinarization(
"RemIntra8x8PredMode",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
logger.Printf("TODO: ae for RemIntra8x8PredMode[%d]\n", luma8x8BlkIdx)
} else {
b, err := br.ReadBits(3)
if err != nil {
return errors.Wrap(err, "could not read RemIntra8x8PredMode")
}
v = int(b)
}
if len(sliceContext.Slice.Data.RemIntra8x8PredMode) < luma8x8BlkIdx {
sliceContext.Slice.Data.RemIntra8x8PredMode = append(
sliceContext.Slice.Data.RemIntra8x8PredMode,
make([]int, luma8x8BlkIdx-len(sliceContext.Slice.Data.RemIntra8x8PredMode)+1)...)
}
sliceContext.Slice.Data.RemIntra8x8PredMode[luma8x8BlkIdx] = v
}
}
}
if sliceContext.Slice.Header.ChromaArrayType == 1 || sliceContext.Slice.Header.ChromaArrayType == 2 {
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: ue(v) or ae(v)
binarization := NewBinarization(
"IntraChromaPredMode",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
logger.Printf("TODO: ae for IntraChromaPredMode\n")
} else {
var err error
sliceContext.Slice.Data.IntraChromaPredMode, err = readUe(br)
if err != nil {
return errors.Wrap(err, "could not parse IntraChromaPredMode")
}
}
}
} else if mbPartPredMode != direct {
for mbPartIdx := 0; mbPartIdx < NumMbPart(sliceContext.NalUnit, sliceContext.SPS, sliceContext.Slice.Header, sliceContext.Slice.Data); mbPartIdx++ {
sliceContext.Update(sliceContext.Slice.Header, sliceContext.Slice.Data)
m, err := MbPartPredMode(sliceContext.Slice.Data, sliceType, sliceContext.Slice.Data.MbType, mbPartIdx)
if err != nil {
return errors.Wrap(err, fmt.Sprintf("could not get mbPartPredMode for loop 1 mbPartIdx: %d", mbPartIdx))
}
if (sliceContext.Slice.Header.NumRefIdxL0ActiveMinus1 > 0 || sliceContext.Slice.Data.MbFieldDecodingFlag != sliceContext.Slice.Header.FieldPic) && m != predL1 {
logger.Printf("\tTODO: refIdxL0[%d] te or ae(v)\n", mbPartIdx)
if len(sliceContext.Slice.Data.RefIdxL0) < mbPartIdx {
sliceContext.Slice.Data.RefIdxL0 = append(
sliceContext.Slice.Data.RefIdxL0, make([]int, mbPartIdx-len(sliceContext.Slice.Data.RefIdxL0)+1)...)
}
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: te(v) or ae(v)
binarization := NewBinarization(
"RefIdxL0",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
logger.Printf("TODO: ae for RefIdxL0[%d]\n", mbPartIdx)
} else {
// TODO: Only one reference picture is used for inter-prediction,
// then the value should be 0
if MbaffFrameFlag(sliceContext.SPS, sliceContext.Slice.Header) == 0 || !sliceContext.Slice.Data.MbFieldDecodingFlag {
sliceContext.Slice.Data.RefIdxL0[mbPartIdx], _ = readTe(
br,
uint(sliceContext.Slice.Header.NumRefIdxL0ActiveMinus1))
} else {
rangeMax := 2*sliceContext.Slice.Header.NumRefIdxL0ActiveMinus1 + 1
sliceContext.Slice.Data.RefIdxL0[mbPartIdx], _ = readTe(
br,
uint(rangeMax))
}
}
}
}
for mbPartIdx := 0; mbPartIdx < NumMbPart(sliceContext.NalUnit, sliceContext.SPS, sliceContext.Slice.Header, sliceContext.Slice.Data); mbPartIdx++ {
m, err := MbPartPredMode(sliceContext.Slice.Data, sliceType, sliceContext.Slice.Data.MbType, mbPartIdx)
if err != nil {
return errors.Wrap(err, fmt.Sprintf("could not get mbPartPredMode for loop 2 mbPartIdx: %d", mbPartIdx))
}
if m != predL1 {
for compIdx := 0; compIdx < 2; compIdx++ {
if len(sliceContext.Slice.Data.MvdL0) < mbPartIdx {
sliceContext.Slice.Data.MvdL0 = append(
sliceContext.Slice.Data.MvdL0,
make([][][]int, mbPartIdx-len(sliceContext.Slice.Data.MvdL0)+1)...)
}
if len(sliceContext.Slice.Data.MvdL0[mbPartIdx][0]) < compIdx {
sliceContext.Slice.Data.MvdL0[mbPartIdx][0] = append(
sliceContext.Slice.Data.MvdL0[mbPartIdx][0],
make([]int, compIdx-len(sliceContext.Slice.Data.MvdL0[mbPartIdx][0])+1)...)
}
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: se(v) or ae(v)
if compIdx == 0 {
binarization := NewBinarization(
"MvdLnEnd0",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
} else if compIdx == 1 {
binarization := NewBinarization(
"MvdLnEnd1",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
}
logger.Printf("TODO: ae for MvdL0[%d][0][%d]\n", mbPartIdx, compIdx)
} else {
sliceContext.Slice.Data.MvdL0[mbPartIdx][0][compIdx], _ = readSe(br)
}
}
}
}
for mbPartIdx := 0; mbPartIdx < NumMbPart(sliceContext.NalUnit, sliceContext.SPS, sliceContext.Slice.Header, sliceContext.Slice.Data); mbPartIdx++ {
sliceContext.Update(sliceContext.Slice.Header, sliceContext.Slice.Data)
m, err := MbPartPredMode(sliceContext.Slice.Data, sliceType, sliceContext.Slice.Data.MbType, mbPartIdx)
if err != nil {
return errors.Wrap(err, fmt.Sprintf("could not get mbPartPredMode for loop 3 mbPartIdx: %d", mbPartIdx))
}
if m != predL0 {
for compIdx := 0; compIdx < 2; compIdx++ {
if len(sliceContext.Slice.Data.MvdL1) < mbPartIdx {
sliceContext.Slice.Data.MvdL1 = append(
sliceContext.Slice.Data.MvdL1,
make([][][]int, mbPartIdx-len(sliceContext.Slice.Data.MvdL1)+1)...)
}
if len(sliceContext.Slice.Data.MvdL1[mbPartIdx][0]) < compIdx {
sliceContext.Slice.Data.MvdL1[mbPartIdx][0] = append(
sliceContext.Slice.Data.MvdL0[mbPartIdx][0],
make([]int, compIdx-len(sliceContext.Slice.Data.MvdL1[mbPartIdx][0])+1)...)
}
if sliceContext.PPS.EntropyCodingMode == 1 {
if compIdx == 0 {
binarization := NewBinarization(
"MvdLnEnd0",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
} else if compIdx == 1 {
binarization := NewBinarization(
"MvdLnEnd1",
sliceContext.Slice.Data)
binarization.Decode(sliceContext, br, rbsp)
}
// TODO: se(v) or ae(v)
logger.Printf("TODO: ae for MvdL1[%d][0][%d]\n", mbPartIdx, compIdx)
} else {
sliceContext.Slice.Data.MvdL1[mbPartIdx][0][compIdx], _ = readSe(br)
}
}
}
}
}
return nil
}
// 8.2.2.1
func MapUnitToSliceGroupMap(sps *SPS, pps *PPS, header *SliceHeader) []int {
mapUnitToSliceGroupMap := []int{}
picSizeInMapUnits := PicSizeInMapUnits(sps)
if pps.NumSliceGroupsMinus1 == 0 {
// 0 to PicSizeInMapUnits -1 inclusive
for i := 0; i <= picSizeInMapUnits-1; i++ {
mapUnitToSliceGroupMap = append(mapUnitToSliceGroupMap, 0)
}
} else {
switch pps.SliceGroupMapType {
case 0:
// 8.2.2.1
i := 0
for i < picSizeInMapUnits {
// iGroup should be incremented in the pps.RunLengthMinus1 index operation. There may be a bug here
for iGroup := 0; iGroup <= pps.NumSliceGroupsMinus1 && i < picSizeInMapUnits; i += pps.RunLengthMinus1[iGroup+1] + 1 {
for j := 0; j < pps.RunLengthMinus1[iGroup] && i+j < picSizeInMapUnits; j++ {
if len(mapUnitToSliceGroupMap) < i+j {
mapUnitToSliceGroupMap = append(
mapUnitToSliceGroupMap,
make([]int, (i+j)-len(mapUnitToSliceGroupMap)+1)...)
}
mapUnitToSliceGroupMap[i+j] = iGroup
}
}
}
case 1:
// 8.2.2.2
for i := 0; i < picSizeInMapUnits; i++ {
v := ((i % PicWidthInMbs(sps)) + (((i / PicWidthInMbs(sps)) * (pps.NumSliceGroupsMinus1 + 1)) / 2)) % (pps.NumSliceGroupsMinus1 + 1)
mapUnitToSliceGroupMap = append(mapUnitToSliceGroupMap, v)
}
case 2:
// 8.2.2.3
for i := 0; i < picSizeInMapUnits; i++ {
mapUnitToSliceGroupMap = append(mapUnitToSliceGroupMap, pps.NumSliceGroupsMinus1)
}
for iGroup := pps.NumSliceGroupsMinus1 - 1; iGroup >= 0; iGroup-- {
yTopLeft := pps.TopLeft[iGroup] / PicWidthInMbs(sps)
xTopLeft := pps.TopLeft[iGroup] % PicWidthInMbs(sps)
yBottomRight := pps.BottomRight[iGroup] / PicWidthInMbs(sps)
xBottomRight := pps.BottomRight[iGroup] % PicWidthInMbs(sps)
for y := yTopLeft; y <= yBottomRight; y++ {
for x := xTopLeft; x <= xBottomRight; x++ {
idx := y*PicWidthInMbs(sps) + x
if len(mapUnitToSliceGroupMap) < idx {
mapUnitToSliceGroupMap = append(
mapUnitToSliceGroupMap,
make([]int, idx-len(mapUnitToSliceGroupMap)+1)...)
mapUnitToSliceGroupMap[idx] = iGroup
}
}
}
}
case 3:
// 8.2.2.4
// TODO
case 4:
// 8.2.2.5
// TODO
case 5:
// 8.2.2.6
// TODO
case 6:
// 8.2.2.7
// TODO
}
}
// 8.2.2.8
// Convert mapUnitToSliceGroupMap to MbToSliceGroupMap
return mapUnitToSliceGroupMap
}
func nextMbAddress(n int, sps *SPS, pps *PPS, header *SliceHeader) int {
i := n + 1
// picSizeInMbs is the number of macroblocks in picture 0
// 7-13
// PicWidthInMbs = sps.PicWidthInMbsMinus1 + 1
// PicHeightInMapUnits = sps.PicHeightInMapUnitsMinus1 + 1
// 7-29
// picSizeInMbs = PicWidthInMbs * PicHeightInMbs
// 7-26
// PicHeightInMbs = FrameHeightInMbs / (1 + header.fieldPicFlag)
// 7-18
// FrameHeightInMbs = (2 - ps.FrameMbsOnly) * PicHeightInMapUnits
picWidthInMbs := sps.PicWidthInMbsMinus1 + 1
picHeightInMapUnits := sps.PicHeightInMapUnitsMinus1 + 1
frameHeightInMbs := (2 - flagVal(sps.FrameMbsOnly)) * picHeightInMapUnits
picHeightInMbs := frameHeightInMbs / (1 + flagVal(header.FieldPic))
picSizeInMbs := picWidthInMbs * picHeightInMbs
mbToSliceGroupMap := MbToSliceGroupMap(sps, pps, header)
for i < picSizeInMbs && mbToSliceGroupMap[i] != mbToSliceGroupMap[i] {
i++
}
return i
}
func CurrMbAddr(sps *SPS, header *SliceHeader) int {
mbaffFrameFlag := 0
if sps.MBAdaptiveFrameField && !header.FieldPic {
mbaffFrameFlag = 1
}
return header.FirstMbInSlice * (1 * mbaffFrameFlag)
}
func MbaffFrameFlag(sps *SPS, header *SliceHeader) int {
if sps.MBAdaptiveFrameField && !header.FieldPic {
return 1
}
return 0
}
func NewSliceData(sliceContext *SliceContext, br *bits.BitReader) (*SliceData, error) {
var cabac *CABAC
var err error
sliceContext.Slice.Data = &SliceData{BitReader: br}
// TODO: Why is this being initialized here?
// initCabac(sliceContext)
if sliceContext.PPS.EntropyCodingMode == 1 {
for !br.ByteAligned() {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read CabacAlignmentOneBit")
}
sliceContext.Slice.Data.CabacAlignmentOneBit = int(b)
}
}
mbaffFrameFlag := 0
if sliceContext.SPS.MBAdaptiveFrameField && !sliceContext.Slice.Header.FieldPic {
mbaffFrameFlag = 1
}
currMbAddr := sliceContext.Slice.Header.FirstMbInSlice * (1 * mbaffFrameFlag)
moreDataFlag := true
prevMbSkipped := 0
sliceContext.Slice.Data.SliceTypeName = sliceTypeMap[sliceContext.Slice.Header.SliceType]
sliceContext.Slice.Data.MbTypeName = MbTypeName(sliceContext.Slice.Data.SliceTypeName, sliceContext.Slice.Data.MbType)
logger.Printf("debug: \tSliceData: Processing moreData: %v\n", moreDataFlag)
for moreDataFlag {
logger.Printf("debug: \tLooking for more sliceContext.Slice.Data in slice type %s\n", sliceContext.Slice.Data.SliceTypeName)
if sliceContext.Slice.Data.SliceTypeName != "I" && sliceContext.Slice.Data.SliceTypeName != "SI" {
logger.Printf("debug: \tNonI/SI slice, processing moreData\n")
if sliceContext.PPS.EntropyCodingMode == 0 {
sliceContext.Slice.Data.MbSkipRun, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse MbSkipRun")
}
if sliceContext.Slice.Data.MbSkipRun > 0 {
prevMbSkipped = 1
}
for i := 0; i < sliceContext.Slice.Data.MbSkipRun; i++ {
// nextMbAddress(currMbAdd
currMbAddr = nextMbAddress(currMbAddr, sliceContext.SPS, sliceContext.PPS, sliceContext.Slice.Header)
}
if sliceContext.Slice.Data.MbSkipRun > 0 {
moreDataFlag = moreRBSPData(br)
}
} else {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read MbSkipFlag")
}
sliceContext.Slice.Data.MbSkipFlag = b == 1
moreDataFlag = !sliceContext.Slice.Data.MbSkipFlag
}
}
if moreDataFlag {
if mbaffFrameFlag == 1 && (currMbAddr%2 == 0 || (currMbAddr%2 == 1 && prevMbSkipped == 1)) {
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: ae implementation
binarization := NewBinarization("MbFieldDecodingFlag", sliceContext.Slice.Data)
// TODO: this should take a BitReader where the nil is.
binarization.Decode(sliceContext, br, nil)
logger.Printf("TODO: ae for MbFieldDecodingFlag\n")
} else {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read MbFieldDecodingFlag")
}
sliceContext.Slice.Data.MbFieldDecodingFlag = b == 1
}
}
// BEGIN: macroblockLayer()
if sliceContext.PPS.EntropyCodingMode == 1 {
// TODO: ae implementation
binarization := NewBinarization("MbType", sliceContext.Slice.Data)
cabac = initCabac(binarization, sliceContext)
_ = cabac
// TODO: remove bytes parameter from this function.
binarization.Decode(sliceContext, br, nil)
if binarization.PrefixSuffix {
logger.Printf("debug: MBType binarization has prefix and suffix\n")
}
bits := []int{}
for binIdx := 0; binarization.IsBinStringMatch(bits); binIdx++ {
newBit, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read bit")
}
if binarization.UseDecodeBypass == 1 {
// DecodeBypass
logger.Printf("TODO: decodeBypass is set: 9.3.3.2.3")
codIRange, codIOffset, err := initDecodingEngine(sliceContext.Slice.Data.BitReader)
if err != nil {
return nil, errors.Wrap(err, "could not initialise decoding engine")
}
// Initialize the decoder
// TODO: When should the suffix of MaxBinIdxCtx be used and when just the prefix?
// TODO: When should the suffix of CtxIdxOffset be used?
arithmeticDecoder, err := NewArithmeticDecoding(
sliceContext,
binarization,
CtxIdx(
binarization.binIdx,
binarization.MaxBinIdxCtx.Prefix,
binarization.CtxIdxOffset.Prefix,
),
codIRange,
codIOffset,
)
if err != nil {
return nil, errors.Wrap(err, "error from NewArithmeticDecoding")
}
// Bypass decoding
codIOffset, _, err = arithmeticDecoder.DecodeBypass(
sliceContext.Slice.Data,
codIRange,
codIOffset,
)
if err != nil {
return nil, errors.Wrap(err, "could not DecodeBypass")
}
// End DecodeBypass
} else {
// DO 9.3.3.1
ctxIdx := CtxIdx(
binIdx,
binarization.MaxBinIdxCtx.Prefix,
binarization.CtxIdxOffset.Prefix)
if binarization.MaxBinIdxCtx.IsPrefixSuffix {
logger.Printf("TODO: Handle PrefixSuffix binarization\n")
}
logger.Printf("debug: MBType ctxIdx for %d is %d\n", binIdx, ctxIdx)
// Then 9.3.3.2
codIRange, codIOffset, err := initDecodingEngine(br)
if err != nil {
return nil, errors.Wrap(err, "error from initDecodingEngine")
}
logger.Printf("debug: coding engine initialized: %d/%d\n", codIRange, codIOffset)
}
bits = append(bits, int(newBit))
}
logger.Printf("TODO: ae for MBType\n")
} else {
sliceContext.Slice.Data.MbType, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse MbType")
}
}
if sliceContext.Slice.Data.MbTypeName == "I_PCM" {
for !br.ByteAligned() {
_, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read PCMAlignmentZeroBit")
}
}
// 7-3 p95
bitDepthY := 8 + sliceContext.SPS.BitDepthLumaMinus8
for i := 0; i < 256; i++ {
s, err := br.ReadBits(bitDepthY)
if err != nil {
return nil, errors.Wrap(err, fmt.Sprintf("could not read PcmSampleLuma[%d]", i))
}
sliceContext.Slice.Data.PcmSampleLuma = append(
sliceContext.Slice.Data.PcmSampleLuma,
int(s))
}
// 9.3.1 p 246
// cabac = initCabac(binarization, sliceContext)
// 6-1 p 47
mbWidthC := 16 / SubWidthC(sliceContext.SPS)
mbHeightC := 16 / SubHeightC(sliceContext.SPS)
// if monochrome
if sliceContext.SPS.ChromaFormat == chromaMonochrome || sliceContext.SPS.UseSeparateColorPlane {
mbWidthC = 0
mbHeightC = 0
}
bitDepthC := 8 + sliceContext.SPS.BitDepthChromaMinus8
for i := 0; i < 2*mbWidthC*mbHeightC; i++ {
s, err := br.ReadBits(bitDepthC)
if err != nil {
return nil, errors.Wrap(err, fmt.Sprintf("could not read PcmSampleChroma[%d]", i))
}
sliceContext.Slice.Data.PcmSampleChroma = append(
sliceContext.Slice.Data.PcmSampleChroma,
int(s))
}
// 9.3.1 p 246
// cabac = initCabac(binarization, sliceContext)
} else {
noSubMbPartSizeLessThan8x8Flag := 1
m, err := MbPartPredMode(sliceContext.Slice.Data, sliceContext.Slice.Data.SliceTypeName, sliceContext.Slice.Data.MbType, 0)
if err != nil {
return nil, errors.Wrap(err, "could not get mbPartPredMode")
}
if sliceContext.Slice.Data.MbTypeName == "I_NxN" && m != intra16x16 && NumMbPart(sliceContext.NalUnit, sliceContext.SPS, sliceContext.Slice.Header, sliceContext.Slice.Data) == 4 {
logger.Printf("\tTODO: subMbPred\n")
/*
subMbType := SubMbPred(sliceContext.Slice.Data.MbType)
for mbPartIdx := 0; mbPartIdx < 4; mbPartIdx++ {
if subMbType[mbPartIdx] != "B_Direct_8x8" {
if NumbSubMbPart(subMbType[mbPartIdx]) > 1 {
noSubMbPartSizeLessThan8x8Flag = 0
}
} else if !sliceContext.SPS.Direct8x8Inference {
noSubMbPartSizeLessThan8x8Flag = 0
}
}
*/
} else {
if sliceContext.PPS.Transform8x8Mode == 1 && sliceContext.Slice.Data.MbTypeName == "I_NxN" {
// TODO
// 1 bit or ae(v)
// If sliceContext.PPS.EntropyCodingMode == 1, use ae(v)
if sliceContext.PPS.EntropyCodingMode == 1 {
binarization := NewBinarization("TransformSize8x8Flag", sliceContext.Slice.Data)
cabac = initCabac(binarization, sliceContext)
binarization.Decode(sliceContext, br, nil)
logger.Println("TODO: ae(v) for TransformSize8x8Flag")
} else {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read TransformSize8x8Flag")
}
sliceContext.Slice.Data.TransformSize8x8Flag = b == 1
}
}
// TODO: fix nil argument for.
MbPred(sliceContext, br, nil)
}
m, err = MbPartPredMode(sliceContext.Slice.Data, sliceContext.Slice.Data.SliceTypeName, sliceContext.Slice.Data.MbType, 0)
if err != nil {
return nil, errors.Wrap(err, "could not get mbPartPredMode")
}
if m != intra16x16 {
// TODO: me, ae
logger.Printf("TODO: CodedBlockPattern pending me/ae implementation\n")
if sliceContext.PPS.EntropyCodingMode == 1 {
binarization := NewBinarization("CodedBlockPattern", sliceContext.Slice.Data)
cabac = initCabac(binarization, sliceContext)
// TODO: fix nil argument.
binarization.Decode(sliceContext, br, nil)
logger.Printf("TODO: ae for CodedBlockPattern\n")
} else {
me, _ := readMe(
br,
uint(sliceContext.Slice.Header.ChromaArrayType),
// TODO: fix this
//MbPartPredMode(sliceContext.Slice.Data, sliceContext.Slice.Data.SliceTypeName, sliceContext.Slice.Data.MbType, 0)))
0)
sliceContext.Slice.Data.CodedBlockPattern = int(me)
}
// sliceContext.Slice.Data.CodedBlockPattern = me(v) | ae(v)
if CodedBlockPatternLuma(sliceContext.Slice.Data) > 0 && sliceContext.PPS.Transform8x8Mode == 1 && sliceContext.Slice.Data.MbTypeName != "I_NxN" && noSubMbPartSizeLessThan8x8Flag == 1 && (sliceContext.Slice.Data.MbTypeName != "B_Direct_16x16" || sliceContext.SPS.Direct8x8Inference) {
// TODO: 1 bit or ae(v)
if sliceContext.PPS.EntropyCodingMode == 1 {
binarization := NewBinarization("Transform8x8Flag", sliceContext.Slice.Data)
cabac = initCabac(binarization, sliceContext)
// TODO: fix nil argument.
binarization.Decode(sliceContext, br, nil)
logger.Printf("TODO: ae for TranformSize8x8Flag\n")
} else {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "coult not read TransformSize8x8Flag")
}
sliceContext.Slice.Data.TransformSize8x8Flag = b == 1
}
}
}
m, err = MbPartPredMode(sliceContext.Slice.Data, sliceContext.Slice.Data.SliceTypeName, sliceContext.Slice.Data.MbType, 0)
if err != nil {
return nil, errors.Wrap(err, "could not get mbPartPredMode")
}
if CodedBlockPatternLuma(sliceContext.Slice.Data) > 0 || CodedBlockPatternChroma(sliceContext.Slice.Data) > 0 || m == intra16x16 {
// TODO: se or ae(v)
if sliceContext.PPS.EntropyCodingMode == 1 {
binarization := NewBinarization("MbQpDelta", sliceContext.Slice.Data)
cabac = initCabac(binarization, sliceContext)
// TODO; fix nil argument
binarization.Decode(sliceContext, br, nil)
logger.Printf("TODO: ae for MbQpDelta\n")
} else {
sliceContext.Slice.Data.MbQpDelta, _ = readSe(br)
}
}
}
} // END MacroblockLayer
if sliceContext.PPS.EntropyCodingMode == 0 {
moreDataFlag = moreRBSPData(br)
} else {
if sliceContext.Slice.Data.SliceTypeName != "I" && sliceContext.Slice.Data.SliceTypeName != "SI" {
if sliceContext.Slice.Data.MbSkipFlag {
prevMbSkipped = 1
} else {
prevMbSkipped = 0
}
}
if mbaffFrameFlag == 1 && currMbAddr%2 == 0 {
moreDataFlag = true
} else {
// TODO: ae implementation
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read EndOfSliceFlag")
}
sliceContext.Slice.Data.EndOfSliceFlag = b == 1
moreDataFlag = !sliceContext.Slice.Data.EndOfSliceFlag
}
}
currMbAddr = nextMbAddress(currMbAddr, sliceContext.SPS, sliceContext.PPS, sliceContext.Slice.Header)
} // END while moreDataFlag
return sliceContext.Slice.Data, nil
}
func (c *SliceContext) Update(header *SliceHeader, data *SliceData) {
c.Slice = &Slice{Header: header, Data: data}
}
func NewSliceContext(videoStream *VideoStream, nalUnit *NalUnit, rbsp []byte, showPacket bool) (*SliceContext, error) {
var err error
sps := videoStream.SPS
pps := videoStream.PPS
logger.Printf("debug: %s RBSP %d bytes %d bits == \n", NALUnitType[nalUnit.Type], len(rbsp), len(rbsp)*8)
logger.Printf("debug: \t%#v\n", rbsp[0:8])
var idrPic bool
if nalUnit.Type == 5 {
idrPic = true
}
header := SliceHeader{}
if sps.UseSeparateColorPlane {
header.ChromaArrayType = 0
} else {
header.ChromaArrayType = sps.ChromaFormat
}
br := bits.NewBitReader(bytes.NewReader(rbsp))
header.FirstMbInSlice, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse FirstMbInSlice")
}
header.SliceType, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse SliceType")
}
sliceType := sliceTypeMap[header.SliceType]
logger.Printf("debug: %s (%s) slice of %d bytes\n", NALUnitType[nalUnit.Type], sliceType, len(rbsp))
header.PPSID, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse PPSID")
}
if sps.UseSeparateColorPlane {
b, err := br.ReadBits(2)
if err != nil {
return nil, errors.Wrap(err, "could not read ColorPlaneID")
}
header.ColorPlaneID = int(b)
}
// TODO: See 7.4.3
// header.FrameNum = b.NextField("FrameNum", 0)
if !sps.FrameMbsOnly {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read FieldPic")
}
header.FieldPic = b == 1
if header.FieldPic {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read BottomField")
}
header.BottomField = b == 1
}
}
if idrPic {
header.IDRPicID, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse IDRPicID")
}
}
if sps.PicOrderCountType == 0 {
b, err := br.ReadBits(sps.Log2MaxPicOrderCntLSBMin4 + 4)
if err != nil {
return nil, errors.Wrap(err, "could not read PicOrderCntLsb")
}
header.PicOrderCntLsb = int(b)
if pps.BottomFieldPicOrderInFramePresent && !header.FieldPic {
header.DeltaPicOrderCntBottom, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse DeltaPicOrderCntBottom")
}
}
}
if sps.PicOrderCountType == 1 && !sps.DeltaPicOrderAlwaysZero {
header.DeltaPicOrderCnt[0], err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse DeltaPicOrderCnt")
}
if pps.BottomFieldPicOrderInFramePresent && !header.FieldPic {
header.DeltaPicOrderCnt[1], err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse DeltaPicOrderCnt")
}
}
}
if pps.RedundantPicCntPresent {
header.RedundantPicCnt, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse RedundantPicCnt")
}
}
if sliceType == "B" {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read DirectSpatialMvPred")
}
header.DirectSpatialMvPred = b == 1
}
if sliceType == "B" || sliceType == "SP" {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read NumRefIdxActiveOverride")
}
header.NumRefIdxActiveOverride = b == 1
if header.NumRefIdxActiveOverride {
header.NumRefIdxL0ActiveMinus1, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse NumRefIdxL0ActiveMinus1")
}
if sliceType == "B" {
header.NumRefIdxL1ActiveMinus1, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse NumRefIdxL1ActiveMinus1")
}
}
}
}
if nalUnit.Type == 20 || nalUnit.Type == 21 {
// Annex H
// H.7.3.3.1.1
// refPicListMvcModifications()
} else {
header.RefPicListModification, err = NewRefPicListModification(br, &header)
if err != nil {
return nil, errors.Wrap(err, "could not parse RefPicListModification")
}
}
if (pps.WeightedPred && (sliceType == "P" || sliceType == "SP")) || (pps.WeightedBipred == 1 && sliceType == "B") {
header.PredWeightTable, err = NewPredWeightTable(br, &header)
if err != nil {
return nil, errors.Wrap(err, "could not parse PredWeightTable")
}
}
if nalUnit.RefIdc != 0 {
// devRefPicMarking()
if idrPic {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read NoOutputOfPriorPicsFlag")
}
header.NoOutputOfPriorPicsFlag = b == 1
b, err = br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read LongTermReferenceFlag")
}
header.LongTermReferenceFlag = b == 1
} else {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read AdaptiveRefPicMarkingModeFlag")
}
header.AdaptiveRefPicMarkingModeFlag = b == 1
if header.AdaptiveRefPicMarkingModeFlag {
header.MemoryManagementControlOperation, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse MemoryManagementControlOperation")
}
for header.MemoryManagementControlOperation != 0 {
if header.MemoryManagementControlOperation == 1 || header.MemoryManagementControlOperation == 3 {
header.DifferenceOfPicNumsMinus1, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse MemoryManagementControlOperation")
}
}
if header.MemoryManagementControlOperation == 2 {
header.RefPicListModification.LongTermPicNum, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LongTermPicNum")
}
}
if header.MemoryManagementControlOperation == 3 || header.MemoryManagementControlOperation == 6 {
header.LongTermFrameIdx, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse LongTermFrameIdx")
}
}
if header.MemoryManagementControlOperation == 4 {
header.MaxLongTermFrameIdxPlus1, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse MaxLongTermFrameIdxPlus1")
}
}
}
}
} // end decRefPicMarking
}
if pps.EntropyCodingMode == 1 && sliceType != "I" && sliceType != "SI" {
header.CabacInit, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse CabacInit")
}
}
header.SliceQpDelta, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse SliceQpDelta")
}
if sliceType == "SP" || sliceType == "SI" {
if sliceType == "SP" {
b, err := br.ReadBits(1)
if err != nil {
return nil, errors.Wrap(err, "could not read SpForSwitch")
}
header.SpForSwitch = b == 1
}
header.SliceQsDelta, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse SliceQsDelta")
}
}
if pps.DeblockingFilterControlPresent {
header.DisableDeblockingFilter, err = readUe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse DisableDeblockingFilter")
}
if header.DisableDeblockingFilter != 1 {
header.SliceAlphaC0OffsetDiv2, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse SliceAlphaC0OffsetDiv2")
}
header.SliceBetaOffsetDiv2, err = readSe(br)
if err != nil {
return nil, errors.Wrap(err, "could not parse SliceBetaOffsetDiv2")
}
}
}
if pps.NumSliceGroupsMinus1 > 0 && pps.SliceGroupMapType >= 3 && pps.SliceGroupMapType <= 5 {
b, err := br.ReadBits(int(math.Ceil(math.Log2(float64(pps.PicSizeInMapUnitsMinus1/pps.SliceGroupChangeRateMinus1 + 1)))))
if err != nil {
return nil, errors.Wrap(err, "could not read SliceGruopChangeCycle")
}
header.SliceGroupChangeCycle = int(b)
}
sliceContext := &SliceContext{
NalUnit: nalUnit,
SPS: sps,
PPS: pps,
Slice: &Slice{
Header: &header,
},
}
sliceContext.Slice.Data, err = NewSliceData(sliceContext, br)
if err != nil {
return nil, errors.Wrap(err, "could not create slice data")
}
if showPacket {
debugPacket("debug: Header", sliceContext.Slice.Header)
debugPacket("debug: Data", sliceContext.Slice.Data)
}
return sliceContext, nil
}