/* The copyright in this software is being made available under the BSD
 * License, included below. This software may be subject to other third party
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 * granted under this license.
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 * Copyright (c) 2010-2023, ITU/ISO/IEC
 * All rights reserved.
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 * modification, are permitted provided that the following conditions are met:
 *
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 *    this list of conditions and the following disclaimer.
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 *    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
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 */

/** \file     Rom.h
    \brief    global variables & functions (header)
*/

#ifndef __ROM__
#define __ROM__

#include "CommonDef.h"
#include "Common.h"

#include <stdio.h>
#include <iostream>


//! \ingroup CommonLib
//! \{

// ====================================================================================================================
// Initialize / destroy functions
// ====================================================================================================================

void         initROM();
void         destroyROM();

// ====================================================================================================================
// Data structure related table & variable
// ====================================================================================================================


// flexible conversion from relative to absolute index
struct ScanElement
{
  uint32_t idx;
  uint16_t x;
  uint16_t y;
};

extern Size g_log2TxSubblockSize[MAX_CU_DEPTH + 1][MAX_CU_DEPTH + 1];

extern EnumArray<ScanElement *[MAX_CU_SIZE / 2 + 1][MAX_CU_SIZE / 2 + 1], CoeffScanType> g_scanOrder[SCAN_NUMBER_OF_GROUP_TYPES];
extern       ScanElement   g_coefTopLeftDiagScan8x8[ MAX_CU_SIZE / 2 + 1 ][ 64 ];

extern const int g_quantScales   [2/*0=4^n blocks, 1=2*4^n blocks*/][SCALING_LIST_REM_NUM];          // Q(QP%6)
extern const int g_invQuantScales[2/*0=4^n blocks, 1=2*4^n blocks*/][SCALING_LIST_REM_NUM];          // IQ(QP%6)

static constexpr int NUM_TRANSFORM_MATRIX_SIZES = 6;
#if RExt__HIGH_PRECISION_FORWARD_TRANSFORM
static const int g_transformMatrixShift[TRANSFORM_NUMBER_OF_DIRECTIONS] = { 14, 6 };
#else
static const int g_transformMatrixShift[TRANSFORM_NUMBER_OF_DIRECTIONS] = {  6, 6 };
#endif


// ====================================================================================================================
// Scanning order & context mapping table
// ====================================================================================================================
extern const std::array<TCoeff, 4> g_riceThreshold;

extern const std::array<uint8_t, g_riceThreshold.size() + 1> g_riceShift;

extern const uint32_t g_groupIdx[MAX_TB_SIZEY];
extern const uint32_t g_minInGroup[LAST_SIGNIFICANT_GROUPS];
extern const uint32_t g_goRiceParsCoeff[32];
inline uint32_t       g_goRicePosCoeff0(int st, uint32_t ricePar)
{
  return (st < 2 ? 1 : 2) << ricePar;
}

// ====================================================================================================================
// Intra prediction table
// ====================================================================================================================

extern const uint8_t g_intraModeNumFastUseMPM2D[7 - MIN_CU_LOG2 + 1][7 - MIN_CU_LOG2 + 1];

extern const uint8_t  g_chroma422IntraAngleMappingTable[NUM_INTRA_MODE];


// ====================================================================================================================
// Mode-Dependent DST Matrices
// ====================================================================================================================


extern const TMatrixCoeff g_trCoreDCT2P2  [TRANSFORM_NUMBER_OF_DIRECTIONS][  2][  2];
extern const TMatrixCoeff g_trCoreDCT2P4  [TRANSFORM_NUMBER_OF_DIRECTIONS][  4][  4];
extern const TMatrixCoeff g_trCoreDCT2P8  [TRANSFORM_NUMBER_OF_DIRECTIONS][  8][  8];
extern const TMatrixCoeff g_trCoreDCT2P16 [TRANSFORM_NUMBER_OF_DIRECTIONS][ 16][ 16];
extern const TMatrixCoeff g_trCoreDCT2P32 [TRANSFORM_NUMBER_OF_DIRECTIONS][ 32][ 32];
extern const TMatrixCoeff g_trCoreDCT2P64 [TRANSFORM_NUMBER_OF_DIRECTIONS][ 64][ 64];

extern const TMatrixCoeff g_trCoreDCT8P4  [TRANSFORM_NUMBER_OF_DIRECTIONS][  4][  4];
extern const TMatrixCoeff g_trCoreDCT8P8  [TRANSFORM_NUMBER_OF_DIRECTIONS][  8][  8];
extern const TMatrixCoeff g_trCoreDCT8P16 [TRANSFORM_NUMBER_OF_DIRECTIONS][ 16][ 16];
extern const TMatrixCoeff g_trCoreDCT8P32 [TRANSFORM_NUMBER_OF_DIRECTIONS][ 32][ 32];

extern const TMatrixCoeff g_trCoreDST7P4  [TRANSFORM_NUMBER_OF_DIRECTIONS][  4][  4];
extern const TMatrixCoeff g_trCoreDST7P8  [TRANSFORM_NUMBER_OF_DIRECTIONS][  8][  8];
extern const TMatrixCoeff g_trCoreDST7P16 [TRANSFORM_NUMBER_OF_DIRECTIONS][ 16][ 16];
extern const TMatrixCoeff g_trCoreDST7P32 [TRANSFORM_NUMBER_OF_DIRECTIONS][ 32][ 32];

extern const     int8_t   g_lfnst8x8[ 4 ][ 2 ][ 16 ][ 48 ];
extern const     int8_t   g_lfnst4x4[ 4 ][ 2 ][ 16 ][ 16 ];

extern const     uint8_t  g_lfnstLut[ NUM_INTRA_MODE + NUM_EXT_LUMA_MODE - 1 ];

// ====================================================================================================================
// Misc.
// ====================================================================================================================
extern SizeIndexInfo* gp_sizeIdxInfo;

extern const int       g_ictModes[2][4];

inline bool is34( const SizeType& size )
{
  return ( size & ( ( int64_t ) 1 << ( floorLog2(size) - 1 ) ) );
}

inline bool is58( const SizeType& size )
{
  return ( size & ( ( int64_t ) 1 << ( floorLog2(size) - 2 ) ) );
}

inline bool isNonLog2BlockSize( const Size& size )
{
  return ( ( 1 << floorLog2(size.width) ) != size.width ) || ( ( 1 << floorLog2(size.height) ) != size.height );
}

inline bool isNonLog2Size( const SizeType& size )
{
  return ( ( 1 << floorLog2(size) ) != size );
}

extern UnitScale     g_miScaling; // scaling object for motion scaling

/*! Sophisticated Trace-logging */
#if ENABLE_TRACING
#include "dtrace.h"
extern CDTrace* g_trace_ctx;
#endif

const char* nalUnitTypeToString(NalUnitType type);

extern const char *matrixType[SCALING_LIST_SIZE_NUM][SCALING_LIST_NUM];
extern const char *matrixTypeDc[SCALING_LIST_SIZE_NUM][SCALING_LIST_NUM];

extern const int g_quantTSDefault4x4   [4*4];
extern const int g_quantIntraDefault8x8[8*8];
extern const int g_quantInterDefault8x8[8*8];

extern const uint32_t g_scalingListSize [SCALING_LIST_SIZE_NUM];
extern const uint32_t g_scalingListSizeX[SCALING_LIST_SIZE_NUM];
extern const uint32_t g_scalingListId[SCALING_LIST_SIZE_NUM][SCALING_LIST_NUM];

extern MsgLevel g_verbosity;

extern const int8_t g_bcwLog2WeightBase;
extern const int8_t g_bcwWeightBase;
extern const int8_t g_BcwWeights[BCW_NUM];
extern const int8_t g_BcwSearchOrder[BCW_NUM];
extern       int8_t g_BcwCodingOrder[BCW_NUM];
extern       int8_t g_BcwParsingOrder[BCW_NUM];

class CodingStructure;
int8_t   getBcwWeight(uint8_t bcwIdx, uint8_t refFrameList);
void     resetBcwCodingOrder(bool runDecoding, const CodingStructure &cs);
uint32_t deriveWeightIdxBits(uint8_t bcwIdx);

//! \}


extern bool g_mctsDecCheckEnabled;

class  Mv;
extern RefSetArray<Mv> g_reusedUniMVs[MAX_CU_SIZE_IN_PARTS][MAX_CU_SIZE_IN_PARTS][MAX_NUM_SIZES][MAX_NUM_SIZES];
extern bool g_isReusedUniMVsFilled[MAX_CU_SIZE_IN_PARTS][MAX_CU_SIZE_IN_PARTS][MAX_NUM_SIZES][MAX_NUM_SIZES];

extern uint16_t g_paletteQuant[57];
extern uint8_t g_paletteRunTopLut[5];
extern uint8_t g_paletteRunLeftLut[5];

static constexpr int IBC_BUFFER_SIZE = 256 * 128;

void initGeoTemplate();

struct GeoParam
{
  uint8_t angleIdx : GEO_LOG2_NUM_ANGLES;
  uint8_t distanceIdx : GEO_LOG2_NUM_DISTANCES;
};

extern GeoParam g_geoParams[GEO_NUM_PARTITION_MODE];

extern int16_t*  g_globalGeoWeights   [GEO_NUM_PRESTORED_MASK];
extern Pel*      g_globalGeoEncSADmask[GEO_NUM_PRESTORED_MASK];
extern int16_t   g_weightOffset       [GEO_NUM_PARTITION_MODE][GEO_NUM_CU_SIZE][GEO_NUM_CU_SIZE][2];
extern int8_t    g_angle2mask         [GEO_NUM_ANGLES];
extern int8_t    g_dis[GEO_NUM_ANGLES];
extern int8_t    g_angle2mirror[GEO_NUM_ANGLES];
#endif  //__TCOMROM__