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[DepQuant] WIP: easy part done
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630
src/dep_quant.c
630
src/dep_quant.c
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@ -47,7 +47,22 @@
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#define sm_maxNumSigCtx 12
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#define sm_maxNumGtxCtx 21
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#define SCALE_BITS 15
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#define RICEMAX 32
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static const int32_t g_goRiceBits[4][RICEMAX] = {
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{ 32768, 65536, 98304, 131072, 163840, 196608, 262144, 262144, 327680, 327680, 327680, 327680, 393216, 393216, 393216, 393216, 393216, 393216, 393216, 393216, 458752, 458752, 458752, 458752, 458752, 458752, 458752, 458752, 458752, 458752, 458752, 458752},
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{ 65536, 65536, 98304, 98304, 131072, 131072, 163840, 163840, 196608, 196608, 229376, 229376, 294912, 294912, 294912, 294912, 360448, 360448, 360448, 360448, 360448, 360448, 360448, 360448, 425984, 425984, 425984, 425984, 425984, 425984, 425984, 425984},
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{ 98304, 98304, 98304, 98304, 131072, 131072, 131072, 131072, 163840, 163840, 163840, 163840, 196608, 196608, 196608, 196608, 229376, 229376, 229376, 229376, 262144, 262144, 262144, 262144, 327680, 327680, 327680, 327680, 327680, 327680, 327680, 327680},
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{131072, 131072, 131072, 131072, 131072, 131072, 131072, 131072, 163840, 163840, 163840, 163840, 163840, 163840, 163840, 163840, 196608, 196608, 196608, 196608, 196608, 196608, 196608, 196608, 229376, 229376, 229376, 229376, 229376, 229376, 229376, 229376},
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};
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static const int g_riceT[4] = { 32,128, 512, 2048 };
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static const int g_riceShift[5] = { 0, 2, 4, 6, 8 };
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static const uint32_t g_goRiceParsCoeff[32] = { 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 2, 2,
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2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 3, 3, 3, 3 };
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enum ScanPosType { SCAN_ISCSBB = 0, SCAN_SOCSBB = 1, SCAN_EOCSBB = 2 };
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typedef struct {
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int m_QShift;
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@ -79,6 +94,21 @@ typedef struct {
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uint8_t* levels;
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} SbbCtx;
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typedef struct
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{
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coeff_t absLevel;
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int64_t deltaDist;
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}PQData;
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typedef struct {
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int64_t rdCost;
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coeff_t absLevel;
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int prevId;
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} Decision;
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typedef struct {
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const NbInfoOut* m_nbInfo;
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uint32_t m_sbbFlagBits[2][2];
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@ -114,7 +144,7 @@ typedef struct {
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int8_t m_stateId;
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const uint32_t* m_sigFracBitsArray;
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const uint32_t* m_gtxFracBitsArray;
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common_context* m_commonCtx;
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struct common_context* m_commonCtx;
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unsigned effWidth;
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unsigned effHeight;
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@ -317,12 +347,557 @@ static void depquant_state_init(depquant_state* state, uint32_t sig_frac_bits[2]
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state->m_goRiceZero = 0;
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}
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static INLINE void checkRdCostSkipSbbZeroOut(Decision *decision, const depquant_state * const state)
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{
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int64_t rdCost = state->m_rdCost + state->m_sbbFracBits[0];
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decision->rdCost = rdCost;
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decision->absLevel = 0;
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decision->prevId = 4 + state->m_stateId;
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}
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static void checkRdCosts(const depquant_state * const state, const enum ScanPosType spt, const PQData *pqDataA, const PQData *pqDataB, Decision *decisionA, Decision *decisionB)
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{
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const int32_t* goRiceTab = g_goRiceBits[state->m_goRicePar];
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int64_t rdCostA = state->m_rdCost + pqDataA->deltaDist;
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int64_t rdCostB = state->m_rdCost + pqDataB->deltaDist;
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int64_t rdCostZ = state->m_rdCost;
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if (state->m_remRegBins >= 4)
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{
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if (pqDataA->absLevel < 4)
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{
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rdCostA += state->m_coeffFracBits[pqDataA->absLevel];
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}
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else
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{
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const coeff_t value = (pqDataA->absLevel - 4) >> 1;
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rdCostA +=
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state->m_coeffFracBits[pqDataA->absLevel - (value << 1)] + goRiceTab[value < RICEMAX ? value : RICEMAX - 1];
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}
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if (pqDataB->absLevel < 4)
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{
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rdCostB += state->m_coeffFracBits[pqDataB->absLevel];
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}
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else
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{
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const coeff_t value = (pqDataB->absLevel - 4) >> 1;
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rdCostB +=
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state->m_coeffFracBits[pqDataB->absLevel - (value << 1)] + goRiceTab[value < RICEMAX ? value : RICEMAX - 1];
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}
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if (spt == SCAN_ISCSBB)
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{
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rdCostA += state->m_sigFracBits[1];
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rdCostB += state->m_sigFracBits[1];
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rdCostZ += state->m_sigFracBits[0];
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}
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else if (spt == SCAN_SOCSBB)
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{
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rdCostA += state->m_sbbFracBits[1] + state->m_sigFracBits[1];
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rdCostB += state->m_sbbFracBits[1] + state->m_sigFracBits[1];
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rdCostZ += state->m_sbbFracBits[1] + state->m_sigFracBits[0];
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}
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else if (state->m_numSigSbb)
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{
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rdCostA += state->m_sigFracBits[1];
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rdCostB += state->m_sigFracBits[1];
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rdCostZ += state->m_sigFracBits[0];
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}
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else
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{
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rdCostZ = decisionA->rdCost;
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}
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}
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else
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{
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rdCostA +=
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(1 << SCALE_BITS)
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+ goRiceTab[pqDataA->absLevel <= state->m_goRiceZero ? pqDataA->absLevel - 1
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: (pqDataA->absLevel < RICEMAX ? pqDataA->absLevel : RICEMAX - 1)];
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rdCostB +=
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(1 << SCALE_BITS)
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+ goRiceTab[pqDataB->absLevel <= state->m_goRiceZero ? pqDataB->absLevel - 1
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: (pqDataB->absLevel < RICEMAX ? pqDataB->absLevel : RICEMAX - 1)];
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rdCostZ += goRiceTab[state->m_goRiceZero];
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}
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if (rdCostA < decisionA->rdCost)
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{
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decisionA->rdCost = rdCostA;
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decisionA->absLevel = pqDataA->absLevel;
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decisionA->prevId = state->m_stateId;
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}
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if (rdCostZ < decisionA->rdCost)
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{
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decisionA->rdCost = rdCostZ;
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decisionA->absLevel = 0;
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decisionA->prevId = state->m_stateId;
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}
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if (rdCostB < decisionB->rdCost)
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{
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decisionB->rdCost = rdCostB;
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decisionB->absLevel = pqDataB->absLevel;
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decisionB->prevId = state->m_stateId;
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}
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}
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static INLINE void checkRdCostSkipSbb(const depquant_state* const state, Decision *decision)
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{
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int64_t rdCost = state->m_rdCost + state->m_sbbFracBits[0];
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if (rdCost < decision->rdCost)
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{
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decision->rdCost = rdCost;
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decision->absLevel = 0;
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decision->prevId = 4 + state->m_stateId;
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}
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}
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static INLINE void checkRdCostStart(const depquant_state* const state, int32_t lastOffset, const PQData *pqData, Decision *decision)
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{
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int64_t rdCost = pqData->deltaDist + lastOffset;
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if (pqData->absLevel < 4)
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{
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rdCost += state->m_coeffFracBits[pqData->absLevel];
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}
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else
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{
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const coeff_t value = (pqData->absLevel - 4) >> 1;
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rdCost += state->m_coeffFracBits[pqData->absLevel - (value << 1)] + g_goRiceBits[state->m_goRicePar][value < RICEMAX ? value : RICEMAX - 1];
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}
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if (rdCost < decision->rdCost)
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{
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decision->rdCost = rdCost;
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decision->absLevel = pqData->absLevel;
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decision->prevId = -1;
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}
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}
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static INLINE void preQuantCoeff(const quant_block * const qp, const coeff_t absCoeff, PQData* pqData, coeff_t quanCoeff)
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{
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int64_t scaledOrg = (int64_t)(absCoeff) * quanCoeff;
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coeff_t qIdx = MAX(1, MIN(qp->m_maxQIdx, (coeff_t)((scaledOrg + qp->m_QAdd) >> qp->m_QShift)));
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int64_t scaledAdd = qIdx * qp->m_DistStepAdd - scaledOrg * qp->m_DistOrgFact;
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PQData *pq_a = &pqData[qIdx & 3];
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pq_a->deltaDist = (scaledAdd * qIdx + qp->m_DistAdd) >> qp->m_DistShift;
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pq_a->absLevel = (++qIdx) >> 1;
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scaledAdd += qp->m_DistStepAdd;
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PQData *pq_b = &pqData[qIdx & 3];
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pq_b->deltaDist = (scaledAdd * qIdx + qp->m_DistAdd) >> qp->m_DistShift;
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pq_b->absLevel = (++qIdx) >> 1;
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scaledAdd += qp->m_DistStepAdd;
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PQData *pq_c = &pqData[qIdx & 3];
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pq_c->deltaDist = (scaledAdd * qIdx + qp->m_DistAdd) >> qp->m_DistShift;
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pq_c->absLevel = (++qIdx) >> 1;
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scaledAdd += qp->m_DistStepAdd;
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PQData *pq_d = &pqData[qIdx & 3];
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pq_d->deltaDist = (scaledAdd * qIdx + qp->m_DistAdd) >> qp->m_DistShift;
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pq_d->absLevel = (++qIdx) >> 1;
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}
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#define DINIT(l,p) {INT64_MAX>>2,(l),(p)}
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static const Decision startDec[8] = { DINIT(-1,-2),DINIT(-1,-2),DINIT(-1,-2),DINIT(-1,-2),DINIT(0,4),DINIT(0,5),DINIT(0,6),DINIT(0,7) };
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#undef DINIT
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static void xDecide(
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depquant_state* const m_skipStates,
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depquant_state* const m_prevStates,
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depquant_state* const m_startState,
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quant_block *qp,
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const enum ScanPosType spt,
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const coeff_t absCoeff,
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const int lastOffset,
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Decision* decisions,
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bool zeroOut,
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coeff_t quanCoeff)
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{
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memcpy(decisions, startDec, 8 * sizeof(Decision));
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if (zeroOut)
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{
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if (spt == SCAN_EOCSBB)
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{
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checkRdCostSkipSbbZeroOut(&decisions[0], &m_skipStates[0]);
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checkRdCostSkipSbbZeroOut(&decisions[1], &m_skipStates[1]);
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checkRdCostSkipSbbZeroOut(&decisions[2], &m_skipStates[2]);
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checkRdCostSkipSbbZeroOut(&decisions[3], &m_skipStates[3]);
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}
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return;
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}
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PQData pqData[4];
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preQuantCoeff(qp, absCoeff, pqData, quanCoeff);
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checkRdCosts(&m_prevStates[0], spt, &pqData[0], &pqData[2], &decisions[0], &decisions[2]);
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checkRdCosts(&m_prevStates[1], spt, &pqData[0], &pqData[2], &decisions[2], &decisions[0]);
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checkRdCosts(&m_prevStates[2], spt, &pqData[3], &pqData[1], &decisions[1], &decisions[3]);
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checkRdCosts(&m_prevStates[3], spt, &pqData[3], &pqData[1], &decisions[3], &decisions[1]);
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if (spt == SCAN_EOCSBB)
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{
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checkRdCostSkipSbb(&m_skipStates[0], &decisions[0]);
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checkRdCostSkipSbb(&m_skipStates[1], &decisions[1]);
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checkRdCostSkipSbb(&m_skipStates[2], &decisions[2]);
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checkRdCostSkipSbb(&m_skipStates[3], &decisions[3]);
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}
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checkRdCostStart(m_startState, lastOffset, &pqData[0], &decisions[0]);
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checkRdCostStart(m_startState, lastOffset, &pqData[2], &decisions[2]);
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}
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unsigned templateAbsCompare(coeff_t sum)
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{
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int rangeIdx = 0;
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if (sum < g_riceT[0])
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{
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rangeIdx = 0;
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}
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else if (sum < g_riceT[1])
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{
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rangeIdx = 1;
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}
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else if (sum < g_riceT[2])
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{
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rangeIdx = 2;
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}
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else if (sum < g_riceT[3])
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{
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rangeIdx = 3;
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}
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else
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{
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rangeIdx = 4;
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}
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return g_riceShift[rangeIdx];
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}
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static INLINE void update_common_context(common_context * cc, const ScanInfo *scanInfo, const depquant_state* prevState, depquant_state *currState)
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{
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uint8_t* sbbFlags = cc->m_currSbbCtx[currState->m_stateId].sbbFlags;
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uint8_t* levels = cc->m_currSbbCtx[currState->m_stateId].levels;
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size_t setCpSize = cc->m_nbInfo[scanInfo.scanIdx - 1].maxDist * sizeof(uint8_t);
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if (prevState && prevState->m_refSbbCtxId >= 0)
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{
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memcpy(sbbFlags, cc->m_prevSbbCtx[prevState->m_refSbbCtxId].sbbFlags, scanInfo.numSbb * sizeof(uint8_t));
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memcpy(levels + scanInfo.scanIdx, cc->m_prevSbbCtx[prevState->m_refSbbCtxId].levels + scanInfo.scanIdx, setCpSize);
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}
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else
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{
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memset(sbbFlags, 0, scanInfo.numSbb * sizeof(uint8_t));
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memset(levels + scanInfo.scanIdx, 0, setCpSize);
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}
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sbbFlags[scanInfo.sbbPos] = !!currState->m_numSigSbb;
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memcpy(levels + scanInfo.scanIdx, currState->m_absLevelsAndCtxInit, scanInfo.sbbSize * sizeof(uint8_t));
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const int sigNSbb = ((scanInfo.nextSbbRight ? sbbFlags[scanInfo.nextSbbRight] : false) || (scanInfo.nextSbbBelow ? sbbFlags[scanInfo.nextSbbBelow] : false) ? 1 : 0);
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currState->m_numSigSbb = 0;
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if (prevState)
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{
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currState->m_remRegBins = prevState->m_remRegBins;
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}
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else
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{
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int ctxBinSampleRatio = 28; // (scanInfo.chType == COLOR_Y) ? MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_LUMA : MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_CHROMA;
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currState->m_remRegBins = (currState->effWidth * currState->effHeight * ctxBinSampleRatio) / 16;
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}
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currState->m_goRicePar = 0;
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currState->m_refSbbCtxId = currState->m_stateId;
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currState->m_sbbFracBits[0] = cc->m_sbbFlagBits[sigNSbb][0];
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currState->m_sbbFracBits[1] = cc->m_sbbFlagBits[sigNSbb][1];
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uint16_t templateCtxInit[16];
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const int scanBeg = scanInfo.scanIdx - scanInfo.sbbSize;
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const NbInfoOut* nbOut = cc->m_nbInfo + scanBeg;
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const uint8_t* absLevels = levels + scanBeg;
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for (int id = 0; id < scanInfo.sbbSize; id++, nbOut++)
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{
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if (nbOut->num)
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{
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coeff_t sumAbs = 0, sumAbs1 = 0, sumNum = 0;
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#define UPDATE(k) {coeff_t t=absLevels[nbOut->outPos[k]]; sumAbs+=t; sumAbs1+=MIN(4+(t&1),t); sumNum+=!!t; }
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UPDATE(0);
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if (nbOut->num > 1)
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{
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UPDATE(1);
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if (nbOut->num > 2)
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{
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UPDATE(2);
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if (nbOut->num > 3)
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{
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UPDATE(3);
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if (nbOut->num > 4)
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{
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UPDATE(4);
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}
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}
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}
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}
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#undef UPDATE
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templateCtxInit[id] = (uint16_t)(sumNum) + ((uint16_t)(sumAbs1) << 3) + ((uint16_t)MIN(127, sumAbs) << 8);
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}
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else
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{
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templateCtxInit[id] = 0;
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}
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}
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memset(currState->m_absLevelsAndCtxInit, 0, 16 * sizeof(uint8_t));
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memcpy(currState->m_absLevelsAndCtxInit + 8, templateCtxInit, 16 * sizeof(uint16_t));
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}
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static INLINE void updateStateEOS(depquant_state * state, const ScanInfo *scanInfo, const depquant_state* prevStates, const depquant_state* skipStates,
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const Decision *decision)
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{
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state->m_rdCost = decision->rdCost;
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if (decision->prevId > -2)
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{
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const depquant_state* prvState = 0;
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if (decision->prevId >= 4)
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{
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prvState = skipStates + (decision->prevId - 4);
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state->m_numSigSbb = 0;
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memset(state->m_absLevelsAndCtxInit, 0, 16 * sizeof(uint8_t));
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}
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else if (decision->prevId >= 0)
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{
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prvState = prevStates + decision->prevId;
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state->m_numSigSbb = prvState->m_numSigSbb + !!decision->absLevel;
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memcpy(state->m_absLevelsAndCtxInit, prvState->m_absLevelsAndCtxInit, 16 * sizeof(uint8_t));
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}
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else
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{
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state->m_numSigSbb = 1;
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memset(state->m_absLevelsAndCtxInit, 0, 16 * sizeof(uint8_t));
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}
|
||||
reinterpret_cast<uint8_t*>(m_absLevelsAndCtxInit)[scanInfo.insidePos] = (uint8_t)MIN(255, decision->absLevel);
|
||||
|
||||
update_common_context(state->m_commonCtx, scanInfo, prvState, state);
|
||||
|
||||
coeff_t tinit = state->m_absLevelsAndCtxInit[8 + scanInfo.nextInsidePos];
|
||||
coeff_t sumNum = tinit & 7;
|
||||
coeff_t sumAbs1 = (tinit >> 3) & 31;
|
||||
coeff_t sumGt1 = sumAbs1 - sumNum;
|
||||
state->m_sigFracBits = state->m_sigFracBitsArray[scanInfo.sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)];
|
||||
state->m_coeffFracBits = state->m_gtxFracBitsArray[scanInfo.gtxCtxOffsetNext + (sumGt1 < 4 ? sumGt1 : 4)];
|
||||
}
|
||||
}
|
||||
|
||||
static INLINE void updateState(depquant_state* state, int numIPos, const ScanInfo scanInfo, const depquant_state *prevStates, const Decision *decision, const int baseLevel, const bool extRiceFlag)
|
||||
{
|
||||
state->m_rdCost = decision->rdCost;
|
||||
if (decision->prevId > -2)
|
||||
{
|
||||
if (decision->prevId >= 0)
|
||||
{
|
||||
const depquant_state* prvState = prevStates + decision->prevId;
|
||||
state->m_numSigSbb = prvState->m_numSigSbb + !!decision->absLevel;
|
||||
state->m_refSbbCtxId = prvState->m_refSbbCtxId;
|
||||
state->m_sbbFracBits[0] = prvState->m_sbbFracBits[0];
|
||||
state->m_sbbFracBits[1] = prvState->m_sbbFracBits[1];
|
||||
state->m_remRegBins = prvState->m_remRegBins - 1;
|
||||
state->m_goRicePar = prvState->m_goRicePar;
|
||||
if (state->m_remRegBins >= 4)
|
||||
{
|
||||
state->m_remRegBins -= (decision->absLevel < 2 ? (unsigned)decision->absLevel : 3);
|
||||
}
|
||||
memcpy(state->m_absLevelsAndCtxInit, prvState->m_absLevelsAndCtxInit, 48 * sizeof(uint8_t));
|
||||
}
|
||||
else
|
||||
{
|
||||
state->m_numSigSbb = 1;
|
||||
state->m_refSbbCtxId = -1;
|
||||
int ctxBinSampleRatio = 28; //(scanInfo.chType == CHANNEL_TYPE_LUMA) ? MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_LUMA : MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_CHROMA;
|
||||
state->m_remRegBins = (state->effWidth * state->effHeight * ctxBinSampleRatio) / 16 - (decision->absLevel < 2 ? (unsigned)decision->absLevel : 3);
|
||||
memset(state->m_absLevelsAndCtxInit, 0, 48 * sizeof(uint8_t));
|
||||
}
|
||||
|
||||
uint8_t* levels = (uint8_t*)(state->m_absLevelsAndCtxInit);
|
||||
levels[scanInfo.insidePos] = (uint8_t)MIN(255, decision->absLevel);
|
||||
|
||||
if (state->m_remRegBins >= 4)
|
||||
{
|
||||
coeff_t tinit = state->m_absLevelsAndCtxInit[8 + scanInfo.nextInsidePos];
|
||||
coeff_t sumAbs1 = (tinit >> 3) & 31;
|
||||
coeff_t sumNum = tinit & 7;
|
||||
#define UPDATE(k) {coeff_t t=levels[scanInfo.nextNbInfoSbb.inPos[k]]; sumAbs1+=MIN(4+(t&1),t); sumNum+=!!t; }
|
||||
if (numIPos == 1)
|
||||
{
|
||||
UPDATE(0);
|
||||
}
|
||||
else if (numIPos == 2)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
}
|
||||
else if (numIPos == 3)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
}
|
||||
else if (numIPos == 4)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
UPDATE(3);
|
||||
}
|
||||
else if (numIPos == 5)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
UPDATE(3);
|
||||
UPDATE(4);
|
||||
}
|
||||
#undef UPDATE
|
||||
coeff_t sumGt1 = sumAbs1 - sumNum;
|
||||
state->m_sigFracBits[0] = state->m_sigFracBitsArray[scanInfo.sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][0];
|
||||
state->m_sigFracBits[1] = state->m_sigFracBitsArray[scanInfo.sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][1];
|
||||
memcpy(state->m_coeffFracBits, &state->m_gtxFracBitsArray[scanInfo.gtxCtxOffsetNext + (sumGt1 < 4 ? sumGt1 : 4)], sizeof(state->m_coeffFracBits));
|
||||
|
||||
|
||||
coeff_t sumAbs = state->m_absLevelsAndCtxInit[8 + scanInfo.nextInsidePos] >> 8;
|
||||
#define UPDATE(k) {coeff_t t=levels[scanInfo.nextNbInfoSbb.inPos[k]]; sumAbs+=t; }
|
||||
if (numIPos == 1)
|
||||
{
|
||||
UPDATE(0);
|
||||
}
|
||||
else if (numIPos == 2)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
}
|
||||
else if (numIPos == 3)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
}
|
||||
else if (numIPos == 4)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
UPDATE(3);
|
||||
}
|
||||
else if (numIPos == 5)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
UPDATE(3);
|
||||
UPDATE(4);
|
||||
}
|
||||
#undef UPDATE
|
||||
if (extRiceFlag)
|
||||
{
|
||||
unsigned currentShift = templateAbsCompare(sumAbs);
|
||||
sumAbs = sumAbs >> currentShift;
|
||||
int sumAll = MAX(MIN(31, (int)sumAbs - (int)baseLevel), 0);
|
||||
state->m_goRicePar = g_goRiceParsCoeff[sumAll];
|
||||
state->m_goRicePar += currentShift;
|
||||
}
|
||||
else
|
||||
{
|
||||
int sumAll = MAX(MIN(31, (int)sumAbs - 4 * 5), 0);
|
||||
state->m_goRicePar = g_goRiceParsCoeff[sumAll];
|
||||
}
|
||||
}
|
||||
else
|
||||
{
|
||||
coeff_t sumAbs = state->m_absLevelsAndCtxInit[8 + scanInfo.nextInsidePos] >> 8;
|
||||
#define UPDATE(k) {coeff_t t=levels[scanInfo.nextNbInfoSbb.inPos[k]]; sumAbs+=t; }
|
||||
if (numIPos == 1)
|
||||
{
|
||||
UPDATE(0);
|
||||
}
|
||||
else if (numIPos == 2)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
}
|
||||
else if (numIPos == 3)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
}
|
||||
else if (numIPos == 4)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
UPDATE(3);
|
||||
}
|
||||
else if (numIPos == 5)
|
||||
{
|
||||
UPDATE(0);
|
||||
UPDATE(1);
|
||||
UPDATE(2);
|
||||
UPDATE(3);
|
||||
UPDATE(4);
|
||||
}
|
||||
#undef UPDATE
|
||||
if (extRiceFlag)
|
||||
{
|
||||
unsigned currentShift = templateAbsCompare(sumAbs);
|
||||
sumAbs = sumAbs >> currentShift;
|
||||
sumAbs = MIN(31, sumAbs);
|
||||
state->m_goRicePar = g_goRiceParsCoeff[sumAbs];
|
||||
state->m_goRicePar += currentShift;
|
||||
}
|
||||
else
|
||||
{
|
||||
sumAbs = MIN(31, sumAbs);
|
||||
state->m_goRicePar = g_goRiceParsCoeff[sumAbs];
|
||||
}
|
||||
state->m_goRiceZero = (state->m_stateId < 2 ? 1 : 2) << state->m_goRicePar;
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
static void xDecideAndUpdate(
|
||||
const coeff_t absCoeff,
|
||||
const ScanInfo scanInfo,
|
||||
bool zeroOut,
|
||||
coeff_t quantCoeff,
|
||||
int effWidth,
|
||||
int effHeight,
|
||||
bool reverseLast,
|
||||
Decision* decisions)
|
||||
{
|
||||
std::swap(m_prevStates, m_currStates);
|
||||
|
||||
xDecide(scanInfo.spt, absCoeff, lastOffset(scanInfo.scanIdx, effWidth, effHeight, reverseLast), decisions, zeroOut, quantCoeff);
|
||||
|
||||
if (scanInfo.scanIdx) {
|
||||
if (scanInfo.eosbb) {
|
||||
m_commonCtx.swap();
|
||||
updateStateEOS(&m_currStates[0], scanInfo, m_prevStates, m_skipStates, &decisions[0]);
|
||||
updateStateEOS(&m_currStates[1], scanInfo, m_prevStates, m_skipStates, &decisions[1]);
|
||||
updateStateEOS(&m_currStates[2], scanInfo, m_prevStates, m_skipStates, &decisions[2]);
|
||||
updateStateEOS(&m_currStates[3], scanInfo, m_prevStates, m_skipStates, &decisions[3]);
|
||||
memcpy(decisions + 4, decisions, 4 * sizeof(Decision));
|
||||
} else if (!zeroOut) {
|
||||
|
||||
updateState(&m_currStates[0], scanInfo.nextNbInfoSbb.num, scanInfo, m_prevStates, decisions[0], m_baseLevel, m_extRiceRRCFlag);
|
||||
updateState(&m_currStates[1], scanInfo.nextNbInfoSbb.num, scanInfo, m_prevStates, decisions[1], m_baseLevel, m_extRiceRRCFlag);
|
||||
updateState(&m_currStates[2], scanInfo.nextNbInfoSbb.num, scanInfo, m_prevStates, decisions[2], m_baseLevel, m_extRiceRRCFlag);
|
||||
updateState(&m_currStates[3], scanInfo.nextNbInfoSbb.num, scanInfo, m_prevStates, decisions[3], m_baseLevel, m_extRiceRRCFlag);
|
||||
}
|
||||
|
||||
if (scanInfo.spt == SCAN_SOCSBB) {
|
||||
std::swap(m_prevStates, m_skipStates);
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
uint8_t uvg_dep_quant(
|
||||
const encoder_state_t* const state,
|
||||
const cu_info_t* const cur_tu,
|
||||
const cu_loc_t* const cu_loc,
|
||||
const coeff_t* srcCoeff,
|
||||
const coeff_t* coeff_out,
|
||||
coeff_t* coeff_out,
|
||||
const color_t compID,
|
||||
enum uvg_tree_type tree_type,
|
||||
const double lambda,
|
||||
|
@ -365,6 +940,7 @@ uint8_t uvg_dep_quant(
|
|||
quant_block quant_block;
|
||||
init_quant_block(state, &quant_block, cur_tu, log2_tr_width, log2_tr_height, compID, needs_block_size_trafo_scale, -1);
|
||||
|
||||
Decision trellis[TR_MAX_WIDTH * TR_MAX_WIDTH][8];
|
||||
//===== scaling matrix ====
|
||||
//const int qpDQ = cQP.Qp + 1;
|
||||
//const int qpPer = qpDQ / 6;
|
||||
|
@ -389,14 +965,13 @@ uint8_t uvg_dep_quant(
|
|||
if (
|
||||
lfnstIdx > 0 && !is_ts && width >= 4 &&
|
||||
height >= 4) {
|
||||
firstTestPos =
|
||||
((width == 4 && height == 4) || (width == 8 && height == 8)) ? 7 : 15;
|
||||
firstTestPos =((width == 4 && height == 4) || (width == 8 && height == 8)) ? 7 : 15;
|
||||
}
|
||||
const int32_t default_quant_coeff = uvg_g_quant_scales[needs_block_size_trafo_scale][qp_scaled % 6];
|
||||
const coeff_t thres = 4 << q_bits;
|
||||
for (; firstTestPos >= 0; firstTestPos--) {
|
||||
coeff_t thresTmp = (enableScalingLists) ? (thres / (4 * q_coeff[firstTestPos])) :(thres / (4 * default_quant_coeff));
|
||||
if (abs(srcCoeff[firstTestPos]) > thresTmp) {
|
||||
coeff_t thresTmp = (enableScalingLists) ? (thres / (4 * q_coeff[scan[firstTestPos]])) :(thres / (4 * default_quant_coeff));
|
||||
if (abs(srcCoeff[scan[firstTestPos]]) > thresTmp) {
|
||||
break;
|
||||
}
|
||||
}
|
||||
|
@ -414,50 +989,48 @@ uint8_t uvg_dep_quant(
|
|||
depquant_state start_state;
|
||||
|
||||
|
||||
int effectHeight = MIN(32, effHeight);
|
||||
int effectWidth = MIN(32, effWidth);
|
||||
for (int k = 0; k < 12; k++) {
|
||||
depquant_state_init(&all_state[k], rate_estimator.m_sigFracBits[0][0], rate_estimator.m_gtxFracBits[0]);
|
||||
all_state[k].effHeight = MIN(32, effHeight);
|
||||
all_state[k].effWidth = MIN(32, effWidth);
|
||||
all_state[k].effHeight = effectHeight;
|
||||
all_state[k].effWidth = effectWidth;
|
||||
}
|
||||
depquant_state_init(&start_state, rate_estimator.m_sigFracBits[0][0], rate_estimator.m_gtxFracBits[0]);
|
||||
start_state.effHeight = MIN(32, effHeight);
|
||||
start_state.effWidth = MIN(32, effWidth);
|
||||
start_state.effHeight = effectHeight;
|
||||
start_state.effWidth = effectWidth;
|
||||
|
||||
//===== populate trellis =====
|
||||
for (int scanIdx = firstTestPos; scanIdx >= 0; scanIdx--) {
|
||||
const ScanInfo& scanInfo = tuPars.m_scanInfo[scanIdx];
|
||||
uint32_t scan_pos = scan[scanIdx];
|
||||
if (enableScalingLists) {
|
||||
m_quant.initQuantBlock(
|
||||
tu,
|
||||
compID,
|
||||
cQP,
|
||||
lambda,
|
||||
quantCoeff[scanInfo.rasterPos]);
|
||||
init_quant_block(state, &quant_block, cur_tu, log2_tr_width, log2_tr_height, compID, needs_block_size_trafo_scale, q_coeff[scan_pos]);
|
||||
|
||||
xDecideAndUpdate(
|
||||
abs(tCoeff[scanInfo.rasterPos]),
|
||||
abs(srcCoeff[scan_pos]),
|
||||
scanInfo,
|
||||
(zeroOut && (scanInfo.posX >= effWidth || scanInfo.posY >= effHeight)),
|
||||
quantCoeff[scanInfo.rasterPos],
|
||||
q_coeff[scan_pos],
|
||||
effectWidth,
|
||||
effectHeight,
|
||||
tu.cu->slice->getReverseLastSigCoeffFlag());
|
||||
false); //tu.cu->slice->getReverseLastSigCoeffFlag());
|
||||
} else {
|
||||
xDecideAndUpdate(
|
||||
abs(tCoeff[scanInfo.rasterPos]),
|
||||
abs(srcCoeff[scan_pos]),
|
||||
scanInfo,
|
||||
(zeroOut && (scanInfo.posX >= effWidth || scanInfo.posY >= effHeight)),
|
||||
default_quant_coeff,
|
||||
effectWidth,
|
||||
effectHeight,
|
||||
tu.cu->slice->getReverseLastSigCoeffFlag());
|
||||
}
|
||||
false); //tu.cu->slice->getReverseLastSigCoeffFlag());
|
||||
}
|
||||
}
|
||||
|
||||
//===== find best path =====
|
||||
Decision decision = {std::numeric_limits<int64_t>::max(), -1, -2};
|
||||
Decision decision = {INT64_MAX, -1, -2};
|
||||
int64_t minPathCost = 0;
|
||||
for (int8_t stateId = 0; stateId < 4; stateId++) {
|
||||
int64_t pathCost = m_trellis[0][stateId].rdCost;
|
||||
int64_t pathCost = trellis[0][stateId].rdCost;
|
||||
if (pathCost < minPathCost) {
|
||||
decision.prevId = stateId;
|
||||
minPathCost = pathCost;
|
||||
|
@ -467,10 +1040,9 @@ uint8_t uvg_dep_quant(
|
|||
//===== backward scanning =====
|
||||
int scanIdx = 0;
|
||||
for (; decision.prevId >= 0; scanIdx++) {
|
||||
decision = m_trellis[scanIdx][decision.prevId];
|
||||
int32_t blkpos = tuPars.m_scanId2BlkPos[scanIdx].idx;
|
||||
q_coeff[blkpos] =
|
||||
(tCoeff[blkpos] < 0 ? -decision.absLevel : decision.absLevel);
|
||||
decision = trellis[scanIdx][decision.prevId];
|
||||
int32_t blkpos = scan[scanIdx];
|
||||
coeff_out[blkpos] = (srcCoeff[blkpos] < 0 ? -decision.absLevel : decision.absLevel);
|
||||
absSum += decision.absLevel;
|
||||
}
|
||||
}
|
||||
|
|
Loading…
Reference in a new issue