/* The copyright in this software is being made available under the BSD * License, included below. This software may be subject to other third party * and contributor rights, including patent rights, and no such rights are * granted under this license. * * Copyright (c) 2010-2012, ITU/ISO/IEC * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of the ITU/ISO/IEC nor the names of its contributors may * be used to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ /** \file TComRom.h \brief global variables & functions (header) */ #ifndef __TCOMROM__ #define __TCOMROM__ #include "CommonDef.h" #include #include #if HHI_DMM_WEDGE_INTRA || HHI_DMM_PRED_TEX #include "TComWedgelet.h" #endif //! \ingroup TLibCommon //! \{ // ==================================================================================================================== // Macros // ==================================================================================================================== #define MAX_CU_DEPTH 7 // log2(LCUSize) #define MAX_CU_SIZE (1<<(MAX_CU_DEPTH)) // maximum allowable size of CU #define MIN_PU_SIZE 4 #define MAX_NUM_SPU_W (MAX_CU_SIZE/MIN_PU_SIZE) // maximum number of SPU in horizontal line // ==================================================================================================================== // Initialize / destroy functions // ==================================================================================================================== Void initROM(); Void destroyROM(); Void initFrameScanXY( UInt* pBuff, UInt* pBuffX, UInt* pBuffY, Int iWidth, Int iHeight ); Void initSigLastScan(UInt* pBuffZ, UInt* pBuffH, UInt* pBuffV, UInt* pBuffD, Int iWidth, Int iHeight, Int iDepth); Void initNonSquareSigLastScan(UInt* pBuffZ, UInt uiWidth, UInt uiHeight); // ==================================================================================================================== // Data structure related table & variable // ==================================================================================================================== // flexible conversion from relative to absolute index extern UInt g_auiZscanToRaster[ MAX_NUM_SPU_W*MAX_NUM_SPU_W ]; extern UInt g_auiRasterToZscan[ MAX_NUM_SPU_W*MAX_NUM_SPU_W ]; extern UInt g_motionRefer[ MAX_NUM_SPU_W*MAX_NUM_SPU_W ]; Void initZscanToRaster ( Int iMaxDepth, Int iDepth, UInt uiStartVal, UInt*& rpuiCurrIdx ); Void initRasterToZscan ( UInt uiMaxCUWidth, UInt uiMaxCUHeight, UInt uiMaxDepth ); Void initMotionReferIdx ( UInt uiMaxCUWidth, UInt uiMaxCUHeight, UInt uiMaxDepth ); // conversion of partition index to picture pel position extern UInt g_auiRasterToPelX[ MAX_NUM_SPU_W*MAX_NUM_SPU_W ]; extern UInt g_auiRasterToPelY[ MAX_NUM_SPU_W*MAX_NUM_SPU_W ]; Void initRasterToPelXY ( UInt uiMaxCUWidth, UInt uiMaxCUHeight, UInt uiMaxDepth ); // global variable (LCU width/height, max. CU depth) extern UInt g_uiMaxCUWidth; extern UInt g_uiMaxCUHeight; extern UInt g_uiMaxCUDepth; extern UInt g_uiAddCUDepth; extern UInt g_auiPUOffset[8]; #define QUANT_IQUANT_SHIFT 20 // Q(QP%6) * IQ(QP%6) = 2^20 #define QUANT_SHIFT 14 // Q(4) = 2^14 #define SCALE_BITS 15 // Inherited from TMuC, pressumably for fractional bit estimates in RDOQ #define MAX_TR_DYNAMIC_RANGE 15 // Maximum transform dynamic range (excluding sign bit) #define SHIFT_INV_1ST 7 // Shift after first inverse transform stage #define SHIFT_INV_2ND 12 // Shift after second inverse transform stage extern Int g_quantScales[6]; // Q(QP%6) extern Int g_invQuantScales[6]; // IQ(QP%6) extern const short g_aiT4[4][4]; extern const short g_aiT8[8][8]; extern const short g_aiT16[16][16]; extern const short g_aiT32[32][32]; // ==================================================================================================================== // Luma QP to Chroma QP mapping // ==================================================================================================================== extern const UChar g_aucChromaScale [52]; // ==================================================================================================================== // Scanning order & context mapping table // ==================================================================================================================== extern UInt* g_auiFrameScanXY[ MAX_CU_DEPTH ]; // raster index from scanning index extern UInt* g_auiFrameScanX [ MAX_CU_DEPTH ]; // raster index (x) from scanning index extern UInt* g_auiFrameScanY [ MAX_CU_DEPTH ]; // raster index (y) from scanning index extern UInt* g_auiSigLastScan[4][ MAX_CU_DEPTH ]; // raster index from scanning index (zigzag, hor, ver, diag) extern UInt *g_sigScanNSQT[ 4 ]; // scan for non-square partitions extern UInt g_sigCGScanNSQT[ 4 ][ 16 ]; // coarse-grain scan for non-square partitions extern UInt* g_auiNonSquareSigLastScan[ 4 ]; // raster index from scanning index (zigzag) extern const UInt g_uiGroupIdx[ 32 ]; extern const UInt g_uiMinInGroup[ 10 ]; extern const UInt g_uiLastCtx[ 28 ]; extern const UInt g_auiGoRiceRange[5]; //!< maximum value coded with Rice codes extern const UInt g_auiGoRicePrefixLen[5]; //!< prefix length for each maximum value extern const UInt g_aauiGoRiceUpdate[5][24]; //!< parameter update rules for Rice codes extern const UInt g_sigLastScan8x8[ 4 ][ 4 ]; //!< coefficient group scan order for 8x8 TUs extern UInt g_sigLastScanCG32x32[ 64 ]; // ==================================================================================================================== // ADI table // ==================================================================================================================== extern const UChar g_aucIntraModeNumFast[7]; // ==================================================================================================================== // Angular Intra table // ==================================================================================================================== extern const UChar g_aucIntraModeNumAng[7]; extern const UChar g_aucIntraModeBitsAng[7]; extern const UChar g_aucAngIntraModeOrder[NUM_INTRA_MODE]; // ==================================================================================================================== // Bit-depth // ==================================================================================================================== extern UInt g_uiBitDepth; extern UInt g_uiBitIncrement; extern UInt g_uiIBDI_MAX; extern UInt g_uiBASE_MAX; extern UInt g_uiPCMBitDepthLuma; extern UInt g_uiPCMBitDepthChroma; // ==================================================================================================================== // Texture type to integer mapping // ==================================================================================================================== extern const UChar g_aucConvertTxtTypeToIdx[4]; // ==================================================================================================================== // Depth model modes // ==================================================================================================================== #if HHI_DMM_WEDGE_INTRA || HHI_DMM_PRED_TEX extern Int g_iDeltaDCsQuantOffset; extern const WedgeResolution g_aeWedgeResolutionList[5]; extern const UChar g_aucWedgeFullBitsListIdx[7]; #if LGE_DMM3_SIMP_C0044 extern const UChar g_aucWedgeTexPredBitsListIdx[7]; #endif extern const UChar g_aucIntraSizeIdxToWedgeSize[7]; extern std::vector< std::vector > g_aacWedgeLists; extern std::vector< std::vector > g_aacWedgeRefLists; #if HHIQC_DMMFASTSEARCH_B0039 extern std::vector< std::vector< std::vector > > g_aauiWdgLstM3; extern std::vector< std::vector > g_aacWedgeNodeLists; #endif #if RWTH_SDC_DLT_B0036 #if SAIT_SDC_C0096 #define RWTH_SDC_NUM_PRED_MODES 3 #else #define RWTH_SDC_NUM_PRED_MODES 4 #endif extern UInt g_auiSDCPredModes[RWTH_SDC_NUM_PRED_MODES]; #endif Void initWedgeLists(); Void createWedgeList( UInt uiWidth, UInt uiHeight, std::vector &racWedgeList, std::vector &racWedgeRefList, WedgeResolution eWedgeRes ); Void addWedgeletToList( TComWedgelet cWedgelet, std::vector &racWedgeList, std::vector &racWedgeRefList ); __inline Void mapDMMtoIntraMode( UInt& dirMode ) { dirMode = (dirMode >= NUM_INTRA_MODE) ? DC_IDX : dirMode; } __inline Void mapDMMtoIntraMode( Int& dirMode ) { dirMode = (dirMode >= NUM_INTRA_MODE) ? DC_IDX : dirMode; } #endif #if LGE_EDGE_INTRA_A0070 __inline Void mapEdgeIntratoDC( UChar& curDir ) { curDir = (curDir >= EDGE_INTRA_IDX) ? DC_IDX : curDir; } __inline Void mapEdgeIntratoDC( UInt& curDir ) { curDir = (curDir >= EDGE_INTRA_IDX) ? DC_IDX : curDir; } __inline Void mapEdgeIntratoDC( Int& curDir ) { curDir = (curDir >= EDGE_INTRA_IDX) ? DC_IDX : curDir; } #endif // ========================================== // Mode-Dependent DST Matrices extern const short g_as_DST_MAT_4 [4][4]; #if HHI_DMM_WEDGE_INTRA || HHI_DMM_PRED_TEX extern const UChar g_aucDCTDSTMode_Vert[NUM_INTRA_MODE+NUM_DMM_MODE]; extern const UChar g_aucDCTDSTMode_Hor [NUM_INTRA_MODE+NUM_DMM_MODE]; #else extern const UChar g_aucDCTDSTMode_Vert[NUM_INTRA_MODE]; extern const UChar g_aucDCTDSTMode_Hor[NUM_INTRA_MODE]; #endif // ========================================== // ==================================================================================================================== // Misc. // ==================================================================================================================== extern Char g_aucConvertToBit [ MAX_CU_SIZE+1 ]; // from width to log2(width)-2 #define ENC_DEC_TRACE 0 #if ENC_DEC_TRACE extern FILE* g_hTrace; extern Bool g_bJustDoIt; extern const Bool g_bEncDecTraceEnable; extern const Bool g_bEncDecTraceDisable; extern UInt64 g_nSymbolCounter; #define COUNTER_START 1 #define COUNTER_END 0 //( UInt64(1) << 63 ) #define DTRACE_CABAC_F(x) if ( ( g_nSymbolCounter >= COUNTER_START && g_nSymbolCounter <= COUNTER_END )|| g_bJustDoIt ) fprintf( g_hTrace, "%f", x ); #define DTRACE_CABAC_V(x) if ( ( g_nSymbolCounter >= COUNTER_START && g_nSymbolCounter <= COUNTER_END )|| g_bJustDoIt ) fprintf( g_hTrace, "%d", x ); #define DTRACE_CABAC_VL(x) if ( ( g_nSymbolCounter >= COUNTER_START && g_nSymbolCounter <= COUNTER_END )|| g_bJustDoIt ) fprintf( g_hTrace, "%lld", x ); #define DTRACE_CABAC_T(x) if ( ( g_nSymbolCounter >= COUNTER_START && g_nSymbolCounter <= COUNTER_END )|| g_bJustDoIt ) fprintf( g_hTrace, "%s", x ); #define DTRACE_CABAC_X(x) if ( ( g_nSymbolCounter >= COUNTER_START && g_nSymbolCounter <= COUNTER_END )|| g_bJustDoIt ) fprintf( g_hTrace, "%x", x ); #define DTRACE_CABAC_R( x,y ) if ( ( g_nSymbolCounter >= COUNTER_START && g_nSymbolCounter <= COUNTER_END )|| g_bJustDoIt ) fprintf( g_hTrace, x, y ); #define DTRACE_CABAC_N if ( ( g_nSymbolCounter >= COUNTER_START && g_nSymbolCounter <= COUNTER_END )|| g_bJustDoIt ) fprintf( g_hTrace, "\n" ); #else #define DTRACE_CABAC_F(x) #define DTRACE_CABAC_V(x) #define DTRACE_CABAC_VL(x) #define DTRACE_CABAC_T(x) #define DTRACE_CABAC_X(x) #define DTRACE_CABAC_R( x,y ) #define DTRACE_CABAC_N #endif #define SCALING_LIST_NUM 6 ///< list number for quantization matrix #define SCALING_LIST_NUM_32x32 2 ///< list number for quantization matrix 32x32 #define SCALING_LIST_REM_NUM 6 ///< remainder of QP/6 #define SCALING_LIST_START_VALUE 8 ///< start value for dpcm mode #define MAX_MATRIX_COEF_NUM 64 ///< max coefficient number for quantization matrix #define MAX_MATRIX_SIZE_NUM 8 ///< max size number for quantization matrix #define SCALING_LIST_DC 16 ///< default DC value enum ScalingListDIR { SCALING_LIST_SQT = 0, SCALING_LIST_VER, SCALING_LIST_HOR, SCALING_LIST_DIR_NUM }; enum ScalingListSize { SCALING_LIST_4x4 = 0, SCALING_LIST_8x8, SCALING_LIST_16x16, SCALING_LIST_32x32, SCALING_LIST_SIZE_NUM }; static const char MatrixType[4][6][20] = { { "INTRA4X4_LUMA", "INTRA4X4_CHROMAU", "INTRA4X4_CHROMAV", "INTER4X4_LUMA", "INTER4X4_CHROMAU", "INTER4X4_CHROMAV" }, { "INTRA8X8_LUMA", "INTRA8X8_CHROMAU", "INTRA8X8_CHROMAV", "INTER8X8_LUMA", "INTER8X8_CHROMAU", "INTER8X8_CHROMAV" }, { "INTRA16X16_LUMA", "INTRA16X16_CHROMAU", "INTRA16X16_CHROMAV", "INTER16X16_LUMA", "INTER16X16_CHROMAU", "INTER16X16_CHROMAV" }, { "INTRA32X32_LUMA", "INTER32X32_LUMA", }, }; static const char MatrixType_DC[4][12][22] = { { }, { }, { "INTRA16X16_LUMA_DC", "INTRA16X16_CHROMAU_DC", "INTRA16X16_CHROMAV_DC", "INTER16X16_LUMA_DC", "INTER16X16_CHROMAU_DC", "INTER16X16_CHROMAV_DC" }, { "INTRA32X32_LUMA_DC", "INTER32X32_LUMA_DC", }, }; extern Int g_quantIntraDefault4x4[16]; extern Int g_quantIntraDefault8x8[64]; extern Int g_quantIntraDefault16x16[256]; extern Int g_quantIntraDefault32x32[1024]; extern Int g_quantInterDefault4x4[16]; extern Int g_quantInterDefault8x8[64]; extern Int g_quantInterDefault16x16[256]; extern Int g_quantInterDefault32x32[1024]; extern UInt g_scalingListSize [SCALING_LIST_SIZE_NUM]; extern UInt g_scalingListSizeX[SCALING_LIST_SIZE_NUM]; extern UInt g_scalingListNum [SCALING_LIST_SIZE_NUM]; extern Int g_eTTable[4]; //! \} #endif //__TCOMROM__