/* TODO: this file should really be in a 'h264enc' package. DESCRIPTION cabacenc.go provides functionality for CABAC encoding. AUTHORS Saxon A. Nelson-Milton LICENSE Copyright (C) 2019 the Australian Ocean Lab (AusOcean). It is free software: you can redistribute it and/or modify them under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. It is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License in gpl.txt. If not, see http://www.gnu.org/licenses. */ package h264dec import ( "errors" "math" ) // Error used by unaryBinString. var errNegativeSyntaxVal = errors.New("cannot get unary binary string of negative value") // unaryBinString returns the unary binary string of a syntax element having // value v, as specified by setion 9.3.2.1 in the specifications. func unaryBinString(v int) ([]int, error) { if v < 0 { return nil, errNegativeSyntaxVal } r := make([]int, v+1) for i := 0; i <= v; i++ { if i < v { r[i] = 1 } } return r, nil } // Error used by truncUnaryBinString. var errInvalidSyntaxVal = errors.New("syntax value cannot be greater than cMax") // truncUnaryBinString returns the truncated unary binary string of a syntax // element v given a cMax as specified in section 9.3.2.2 of the specifications. func truncUnaryBinString(v, cMax int) ([]int, error) { if v < 0 { return nil, errNegativeSyntaxVal } if v > cMax { return nil, errInvalidSyntaxVal } if v == cMax { b, _ := unaryBinString(v) return b[:len(b)-1], nil } return unaryBinString(v) } // Error used by unaryExpGolombBinString. var errInvalidUCoff = errors.New("uCoff cannot be less than or equal to zero") // unaryExpGolombBinString returns the concatendated unary/k-th order // Exp-Golomb (UEGk) binary string of a syntax element using the process defined // in section 9.3.2.3 of the specifications. func unaryExpGolombBinString(v, uCoff, k int, signedValFlag bool) ([]int, error) { if uCoff <= 0 { return nil, errInvalidUCoff } prefix, err := truncUnaryBinString(mini(uCoff, absi(v)), uCoff) if err != nil { return nil, err } return append(prefix, suffix(v, uCoff, k, signedValFlag)...), nil } // suffix returns the suffix part of a unary k-th Exp-Golomb binar string // using the the algorithm as described by pseudo code 9-6 in section 9.3.2.3. // TODO: could probably reduce allocations. func suffix(v, uCoff, k int, signedValFlag bool) []int { var s []int if absi(v) >= uCoff { sufS := absi(v) - uCoff var stop bool for { if sufS >= (1 << uint(k)) { s = append(s, 1) sufS = sufS - (1 << uint(k)) k++ } else { s = append(s, 0) for k = k - 1; k >= 0; k-- { s = append(s, (sufS>>uint(k))&1) } stop = true } if stop { break } } } if signedValFlag && v != 0 { if v > 0 { s = append(s, 0) } else { s = append(s, 1) } } return s } // Error used by fixedLenBinString. var errNegativeValue = errors.New("cannot get fixed length binary string of negative value") // fixedLenBinString returns the fixed-length (FL) binary string of the syntax // element v, given cMax to determine bin length, as specified by section 9.3.2.4 // of the specifications. func fixedLenBinString(v, cMax int) ([]int, error) { if v < 0 { return nil, errNegativeValue } l := int(math.Ceil(math.Log2(float64(cMax + 1)))) r := make([]int, l) for i := l - 1; i >= 0; i-- { r[i] = v % 2 v = v / 2 } return r, nil } // Errors used by mbTypeBinString. var ( errBadMbType = errors.New("macroblock type outside of valid range") errBadMbSliceType = errors.New("bad slice type for macroblock") ) // mbTypeBinString returns the macroblock type binary string for the given // macroblock type value and slice type using the process defined in section // 9.3.2.5 of the specifications. func mbTypeBinString(v, slice int) ([]int, error) { switch slice { case sliceTypeI: if v < minIMbType || v > maxIMbType { return nil, errBadMbType } return binOfIMBTypes[v], nil case sliceTypeSI: if v < minSIMbType || v > maxSIMbType { return nil, errBadMbType } if v == sliceTypeSI { return []int{0}, nil } return append([]int{1}, binOfIMBTypes[v-1]...), nil case sliceTypeP, sliceTypeSP: if v < minPOrSPMbType || v > maxPOrSPMbType || v == P8x8ref0 { return nil, errBadMbType } if v < 5 { return binOfPOrSPMBTypes[v], nil } return append([]int{1}, binOfIMBTypes[v-5]...), nil case sliceTypeB: if v < minBMbType || v > maxBMbType { return nil, errBadMbType } if v < 23 { return binOfBMBTypes[v], nil } return append([]int{1, 1, 1, 1, 0, 1}, binOfIMBTypes[v-23]...), nil default: return nil, errBadMbSliceType } } // Error used by subMbTypeBinString. var errBadSubMbSliceType = errors.New("bad slice type for sub-macroblock") // subMbTypeBinString returns the binary string of a sub-macroblock type // given the slice in which it is in using the process defined in section // 9.3.2.5 of the specifications. func subMbTypeBinString(v, slice int) ([]int, error) { switch slice { case sliceTypeP, sliceTypeSP: if v < minPOrSPSubMbType || v > maxPOrSPSubMbType { return nil, errBadMbType } return binOfPOrSPSubMBTypes[v], nil case sliceTypeB: if v < minBSubMbType || v > maxBSubMbType { return nil, errBadMbType } return binOfBSubMBTypes[v], nil default: return nil, errBadSubMbSliceType } }