[depquant] AoS -> SoA all states

This commit is contained in:
Joose Sainio 2023-04-06 15:12:29 +03:00
parent 73442f1bba
commit 2f1e9c4020

View file

@ -143,13 +143,34 @@ typedef struct
unsigned effHeight; unsigned effHeight;
} depquant_state; } depquant_state;
typedef struct
{
int64_t m_rdCost[12];
uint16_t m_absLevelsAndCtxInit[12][24]; // 16x8bit for abs levels + 16x16bit for ctx init id
int8_t m_numSigSbb[12];
int m_remRegBins[12];
int8_t m_refSbbCtxId[12];
uint32_t m_sbbFracBits[12][2];
uint32_t m_sigFracBits[12][2];
int32_t m_coeffFracBits[12][6];
int8_t m_goRicePar[12];
int8_t m_goRiceZero[12];
int8_t m_stateId[12];
uint32_t *m_sigFracBitsArray[12][12];
int32_t *m_gtxFracBitsArray[21];
common_context* m_commonCtx;
unsigned effWidth;
unsigned effHeight;
} all_depquant_states;
typedef struct typedef struct
{ {
common_context m_common_context; common_context m_common_context;
depquant_state m_allStates[12]; all_depquant_states m_allStates;
depquant_state* m_currStates; int m_curr_state_offset;
depquant_state* m_prevStates; int m_prev_state_offset;
depquant_state* m_skipStates; int m_skip_state_offset;
depquant_state m_startState; depquant_state m_startState;
quant_block m_quant; quant_block m_quant;
Decision m_trellis[TR_MAX_WIDTH * TR_MAX_WIDTH]; Decision m_trellis[TR_MAX_WIDTH * TR_MAX_WIDTH];
@ -526,66 +547,66 @@ static void depquant_state_init(depquant_state* state, uint32_t sig_frac_bits[2]
state->m_sbbFracBits[1] = 0; state->m_sbbFracBits[1] = 0;
} }
static INLINE void checkRdCostSkipSbbZeroOut(Decision * decision, const depquant_state * const state, int decision_id) static INLINE void checkRdCostSkipSbbZeroOut(Decision * decision, const all_depquant_states * const state, int decision_id, int skip_offset) {
{ int64_t rdCost = state->m_rdCost[decision_id + skip_offset] + state->m_sbbFracBits[decision_id + skip_offset][0];
int64_t rdCost = state->m_rdCost + state->m_sbbFracBits[0]; decision->rdCost[decision_id] = rdCost;
decision->rdCost[decision_id] = rdCost;
decision->absLevel[decision_id] = 0; decision->absLevel[decision_id] = 0;
decision->prevId[decision_id] = 4 + state->m_stateId; decision->prevId[decision_id] = 4 + state->m_stateId[decision_id + skip_offset];
} }
static void checkRdCosts( static void checkRdCosts(
const depquant_state * const state, const all_depquant_states * const state,
const enum ScanPosType spt, const enum ScanPosType spt,
const PQData *pqDataA, const PQData * pqDataA,
const PQData *pqDataB, const PQData * pqDataB,
Decision *decisions, Decision * decisions,
int decisionA, const int decisionA,
int decisionB) const int decisionB,
const int state_offset)
{ {
const int32_t* goRiceTab = g_goRiceBits[state->m_goRicePar]; const int32_t* goRiceTab = g_goRiceBits[state->m_goRicePar[state_offset]];
int64_t rdCostA = state->m_rdCost + pqDataA->deltaDist; int64_t rdCostA = state->m_rdCost[state_offset] + pqDataA->deltaDist;
int64_t rdCostB = state->m_rdCost + pqDataB->deltaDist; int64_t rdCostB = state->m_rdCost[state_offset] + pqDataB->deltaDist;
int64_t rdCostZ = state->m_rdCost; int64_t rdCostZ = state->m_rdCost[state_offset];
if (state->m_remRegBins >= 4) if (state->m_remRegBins[state_offset] >= 4)
{ {
if (pqDataA->absLevel < 4) if (pqDataA->absLevel < 4)
{ {
rdCostA += state->m_coeffFracBits[pqDataA->absLevel]; rdCostA += state->m_coeffFracBits[state_offset][pqDataA->absLevel];
} }
else else
{ {
const coeff_t value = (pqDataA->absLevel - 4) >> 1; const coeff_t value = (pqDataA->absLevel - 4) >> 1;
rdCostA += rdCostA +=
state->m_coeffFracBits[pqDataA->absLevel - (value << 1)] + goRiceTab[value < RICEMAX ? value : RICEMAX - 1]; state->m_coeffFracBits[state_offset][pqDataA->absLevel - (value << 1)] + goRiceTab[value < RICEMAX ? value : RICEMAX - 1];
} }
if (pqDataB->absLevel < 4) if (pqDataB->absLevel < 4)
{ {
rdCostB += state->m_coeffFracBits[pqDataB->absLevel]; rdCostB += state->m_coeffFracBits[state_offset][pqDataB->absLevel];
} }
else else
{ {
const coeff_t value = (pqDataB->absLevel - 4) >> 1; const coeff_t value = (pqDataB->absLevel - 4) >> 1;
rdCostB += rdCostB +=
state->m_coeffFracBits[pqDataB->absLevel - (value << 1)] + goRiceTab[value < RICEMAX ? value : RICEMAX - 1]; state->m_coeffFracBits[state_offset][pqDataB->absLevel - (value << 1)] + goRiceTab[value < RICEMAX ? value : RICEMAX - 1];
} }
if (spt == SCAN_ISCSBB) if (spt == SCAN_ISCSBB)
{ {
rdCostA += state->m_sigFracBits[1]; rdCostA += state->m_sigFracBits[state_offset][1];
rdCostB += state->m_sigFracBits[1]; rdCostB += state->m_sigFracBits[state_offset][1];
rdCostZ += state->m_sigFracBits[0]; rdCostZ += state->m_sigFracBits[state_offset][0];
} }
else if (spt == SCAN_SOCSBB) else if (spt == SCAN_SOCSBB)
{ {
rdCostA += state->m_sbbFracBits[1] + state->m_sigFracBits[1]; rdCostA += state->m_sbbFracBits[state_offset][1] + state->m_sigFracBits[state_offset][1];
rdCostB += state->m_sbbFracBits[1] + state->m_sigFracBits[1]; rdCostB += state->m_sbbFracBits[state_offset][1] + state->m_sigFracBits[state_offset][1];
rdCostZ += state->m_sbbFracBits[1] + state->m_sigFracBits[0]; rdCostZ += state->m_sbbFracBits[state_offset][1] + state->m_sigFracBits[state_offset][0];
} }
else if (state->m_numSigSbb) else if (state->m_numSigSbb[state_offset])
{ {
rdCostA += state->m_sigFracBits[1]; rdCostA += state->m_sigFracBits[state_offset][1];
rdCostB += state->m_sigFracBits[1]; rdCostB += state->m_sigFracBits[state_offset][1];
rdCostZ += state->m_sigFracBits[0]; rdCostZ += state->m_sigFracBits[state_offset][0];
} }
else else
{ {
@ -595,43 +616,43 @@ static void checkRdCosts(
else else
{ {
rdCostA += rdCostA +=
(1 << SCALE_BITS) (1 << SCALE_BITS) + goRiceTab[pqDataA->absLevel <= state->m_goRiceZero[state_offset]
+ goRiceTab[pqDataA->absLevel <= state->m_goRiceZero ? pqDataA->absLevel - 1 ? pqDataA->absLevel - 1
: (pqDataA->absLevel < RICEMAX ? pqDataA->absLevel : RICEMAX - 1)]; : (pqDataA->absLevel < RICEMAX ? pqDataA->absLevel : RICEMAX - 1)];
rdCostB += rdCostB +=
(1 << SCALE_BITS) (1 << SCALE_BITS) + goRiceTab[pqDataB->absLevel <= state->m_goRiceZero[state_offset]
+ goRiceTab[pqDataB->absLevel <= state->m_goRiceZero ? pqDataB->absLevel - 1 ? pqDataB->absLevel - 1
: (pqDataB->absLevel < RICEMAX ? pqDataB->absLevel : RICEMAX - 1)]; : (pqDataB->absLevel < RICEMAX ? pqDataB->absLevel : RICEMAX - 1)];
rdCostZ += goRiceTab[state->m_goRiceZero]; rdCostZ += goRiceTab[state->m_goRiceZero[state_offset]];
} }
if (rdCostA < decisions->rdCost[decisionA]) if (rdCostA < decisions->rdCost[decisionA])
{ {
decisions->rdCost[decisionA] = rdCostA; decisions->rdCost[decisionA] = rdCostA;
decisions->absLevel[decisionA] = pqDataA->absLevel; decisions->absLevel[decisionA] = pqDataA->absLevel;
decisions->prevId[decisionA] = state->m_stateId; decisions->prevId[decisionA] = state->m_stateId[state_offset];
} }
if (rdCostZ < decisions->rdCost[decisionA]) if (rdCostZ < decisions->rdCost[decisionA])
{ {
decisions->rdCost[decisionA] = rdCostZ; decisions->rdCost[decisionA] = rdCostZ;
decisions->absLevel[decisionA] = 0; decisions->absLevel[decisionA] = 0;
decisions->prevId[decisionA] = state->m_stateId; decisions->prevId[decisionA] = state->m_stateId[state_offset];
} }
if (rdCostB < decisions->rdCost[decisionB]) if (rdCostB < decisions->rdCost[decisionB])
{ {
decisions->rdCost[decisionB] = rdCostB; decisions->rdCost[decisionB] = rdCostB;
decisions->absLevel[decisionB] = pqDataB->absLevel; decisions->absLevel[decisionB] = pqDataB->absLevel;
decisions->prevId[decisionB] = state->m_stateId; decisions->prevId[decisionB] = state->m_stateId[state_offset];
} }
} }
static INLINE void checkRdCostSkipSbb(const depquant_state* const state, Decision * decisions, int decision_id) static INLINE void checkRdCostSkipSbb(const all_depquant_states* const state, Decision * decisions, int decision_id, int skip_offset)
{ {
int64_t rdCost = state->m_rdCost + state->m_sbbFracBits[0]; int64_t rdCost = state->m_rdCost[skip_offset + decision_id] + state->m_sbbFracBits[skip_offset + decision_id][0];
if (rdCost < decisions->rdCost[decision_id]) if (rdCost < decisions->rdCost[decision_id])
{ {
decisions->rdCost[decision_id] = rdCost; decisions->rdCost[decision_id] = rdCost;
decisions->absLevel[decision_id] = 0; decisions->absLevel[decision_id] = 0;
decisions->prevId[decision_id] = 4 + state->m_stateId; decisions->prevId[decision_id] = 4 + state->m_stateId[skip_offset + decision_id];
} }
} }
@ -685,16 +706,17 @@ static const Decision startDec = { .rdCost = {INT64_MAX >> 2, INT64_MAX >> 2, IN
static void xDecide( static void xDecide(
depquant_state* const m_skipStates, all_depquant_states* const all_states,
depquant_state* const m_prevStates, depquant_state* const m_startState,
depquant_state* const m_startState, quant_block * qp,
quant_block *qp, const enum ScanPosType spt,
const enum ScanPosType spt, const coeff_t absCoeff,
const coeff_t absCoeff, const int lastOffset,
const int lastOffset, Decision* decisions,
Decision* decisions, bool zeroOut,
bool zeroOut, coeff_t quanCoeff,
coeff_t quanCoeff) const int skip_offset,
const int prev_offset)
{ {
memcpy(decisions, &startDec, sizeof(Decision)); memcpy(decisions, &startDec, sizeof(Decision));
@ -702,26 +724,26 @@ static void xDecide(
{ {
if (spt == SCAN_EOCSBB) if (spt == SCAN_EOCSBB)
{ {
checkRdCostSkipSbbZeroOut(decisions, &m_skipStates[0], 0); checkRdCostSkipSbbZeroOut(decisions, all_states, 0, skip_offset);
checkRdCostSkipSbbZeroOut(decisions, &m_skipStates[1], 1); checkRdCostSkipSbbZeroOut(decisions, all_states, 1, skip_offset);
checkRdCostSkipSbbZeroOut(decisions, &m_skipStates[2],2); checkRdCostSkipSbbZeroOut(decisions, all_states,2, skip_offset);
checkRdCostSkipSbbZeroOut(decisions, &m_skipStates[3],3); checkRdCostSkipSbbZeroOut(decisions, all_states,3, skip_offset);
} }
return; return;
} }
PQData pqData[4]; PQData pqData[4];
preQuantCoeff(qp, absCoeff, pqData, quanCoeff); preQuantCoeff(qp, absCoeff, pqData, quanCoeff);
checkRdCosts(&m_prevStates[0], spt, &pqData[0], &pqData[2], decisions, 0, 2); checkRdCosts(all_states, spt, &pqData[0], &pqData[2], decisions, 0, 2, prev_offset + 0);
checkRdCosts(&m_prevStates[1], spt, &pqData[0], &pqData[2], decisions,2, 0); checkRdCosts(all_states, spt, &pqData[0], &pqData[2], decisions, 2, 0, prev_offset + 1);
checkRdCosts(&m_prevStates[2], spt, &pqData[3], &pqData[1], decisions, 1,3); checkRdCosts(all_states, spt, &pqData[3], &pqData[1], decisions, 1, 3, prev_offset + 2);
checkRdCosts(&m_prevStates[3], spt, &pqData[3], &pqData[1], decisions, 3,1); checkRdCosts(all_states, spt, &pqData[3], &pqData[1], decisions, 3, 1, prev_offset + 3);
if (spt == SCAN_EOCSBB) if (spt == SCAN_EOCSBB)
{ {
checkRdCostSkipSbb(&m_skipStates[0], decisions, 0); checkRdCostSkipSbb(all_states, decisions, 0, skip_offset);
checkRdCostSkipSbb(&m_skipStates[1], decisions, 1); checkRdCostSkipSbb(all_states, decisions, 1, skip_offset);
checkRdCostSkipSbb(&m_skipStates[2], decisions,2); checkRdCostSkipSbb(all_states, decisions,2, skip_offset);
checkRdCostSkipSbb(&m_skipStates[3], decisions,3); checkRdCostSkipSbb(all_states, decisions,3, skip_offset);
} }
checkRdCostStart(m_startState, lastOffset, &pqData[0], decisions, 0); checkRdCostStart(m_startState, lastOffset, &pqData[0], decisions, 0);
@ -756,45 +778,46 @@ static INLINE unsigned templateAbsCompare(coeff_t sum)
} }
static INLINE void update_common_context( static INLINE void update_common_context(
context_store* ctxs,
common_context * cc, common_context * cc,
const uint32_t scan_pos, const uint32_t scan_pos,
const uint32_t cg_pos, const uint32_t cg_pos,
const uint32_t width_in_sbb, const uint32_t width_in_sbb,
const uint32_t height_in_sbb, const uint32_t height_in_sbb,
const uint32_t next_sbb_right, const uint32_t next_sbb_right,
const uint32_t next_sbb_below, const uint32_t next_sbb_below,
const depquant_state* prevState, const int prev_state,
depquant_state *currState) const int curr_state)
{ {
const uint32_t numSbb = width_in_sbb * height_in_sbb; const uint32_t numSbb = width_in_sbb * height_in_sbb;
uint8_t* sbbFlags = cc->m_currSbbCtx[currState->m_stateId].sbbFlags; uint8_t* sbbFlags = cc->m_currSbbCtx[curr_state & 3].sbbFlags;
uint8_t* levels = cc->m_currSbbCtx[currState->m_stateId].levels; uint8_t* levels = cc->m_currSbbCtx[curr_state & 3].levels;
size_t setCpSize = cc->m_nbInfo[scan_pos - 1].maxDist * sizeof(uint8_t); size_t setCpSize = cc->m_nbInfo[scan_pos - 1].maxDist * sizeof(uint8_t);
if (prevState && prevState->m_refSbbCtxId >= 0) { if (prev_state != -1 && ctxs->m_allStates.m_refSbbCtxId[prev_state] >= 0) {
memcpy(sbbFlags, cc->m_prevSbbCtx[prevState->m_refSbbCtxId].sbbFlags, numSbb * sizeof(uint8_t)); memcpy(sbbFlags, cc->m_prevSbbCtx[ctxs->m_allStates.m_refSbbCtxId[prev_state]].sbbFlags, numSbb * sizeof(uint8_t));
memcpy(levels + scan_pos, cc->m_prevSbbCtx[prevState->m_refSbbCtxId].levels + scan_pos, setCpSize); memcpy(levels + scan_pos, cc->m_prevSbbCtx[ctxs->m_allStates.m_refSbbCtxId[prev_state]].levels + scan_pos, setCpSize);
} }
else { else {
memset(sbbFlags, 0, numSbb * sizeof(uint8_t)); memset(sbbFlags, 0, numSbb * sizeof(uint8_t));
memset(levels + scan_pos, 0, setCpSize); memset(levels + scan_pos, 0, setCpSize);
} }
sbbFlags[cg_pos] = !!currState->m_numSigSbb; sbbFlags[cg_pos] = !!ctxs->m_allStates.m_numSigSbb[curr_state];
memcpy(levels + scan_pos, currState->m_absLevelsAndCtxInit, 16 * sizeof(uint8_t)); memcpy(levels + scan_pos, ctxs->m_allStates.m_absLevelsAndCtxInit[curr_state], 16 * sizeof(uint8_t));
const int sigNSbb = ((next_sbb_right ? sbbFlags[next_sbb_right] : false) || (next_sbb_below ? sbbFlags[next_sbb_below] : false) ? 1 : 0); const int sigNSbb = ((next_sbb_right ? sbbFlags[next_sbb_right] : false) || (next_sbb_below ? sbbFlags[next_sbb_below] : false) ? 1 : 0);
currState->m_numSigSbb = 0; ctxs->m_allStates.m_numSigSbb[curr_state] = 0;
if (prevState) { if (prev_state != -1) {
currState->m_remRegBins = prevState->m_remRegBins; ctxs->m_allStates.m_remRegBins[curr_state] = ctxs->m_allStates.m_remRegBins[prev_state];
} }
else { else {
int ctxBinSampleRatio = 28; int ctxBinSampleRatio = 28;
// (scanInfo.chType == COLOR_Y) ? MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_LUMA : MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_CHROMA; // (scanInfo.chType == COLOR_Y) ? MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_LUMA : MAX_TU_LEVEL_CTX_CODED_BIN_CONSTRAINT_CHROMA;
currState->m_remRegBins = (currState->effWidth * currState->effHeight * ctxBinSampleRatio) / 16; ctxs->m_allStates.m_remRegBins[curr_state] = (ctxs->m_allStates.effWidth * ctxs->m_allStates.effHeight * ctxBinSampleRatio) / 16;
} }
currState->m_goRicePar = 0; ctxs->m_allStates.m_goRicePar[curr_state] = 0;
currState->m_refSbbCtxId = currState->m_stateId; ctxs->m_allStates.m_refSbbCtxId[curr_state] = curr_state & 3;
currState->m_sbbFracBits[0] = cc->m_sbbFlagBits[sigNSbb][0]; ctxs->m_allStates.m_sbbFracBits[curr_state][0] = cc->m_sbbFlagBits[sigNSbb][0];
currState->m_sbbFracBits[1] = cc->m_sbbFlagBits[sigNSbb][1]; ctxs->m_allStates.m_sbbFracBits[curr_state][1] = cc->m_sbbFlagBits[sigNSbb][1];
uint16_t templateCtxInit[16]; uint16_t templateCtxInit[16];
const int scanBeg = scan_pos - 16; const int scanBeg = scan_pos - 16;
@ -824,108 +847,109 @@ static INLINE void update_common_context(
templateCtxInit[id] = 0; templateCtxInit[id] = 0;
} }
} }
memset(currState->m_absLevelsAndCtxInit, 0, 16 * sizeof(uint8_t)); memset(ctxs->m_allStates.m_absLevelsAndCtxInit[curr_state], 0, 16 * sizeof(uint8_t));
memcpy(currState->m_absLevelsAndCtxInit + 8, templateCtxInit, 16 * sizeof(uint16_t)); memcpy(ctxs->m_allStates.m_absLevelsAndCtxInit[curr_state] + 8, templateCtxInit, 16 * sizeof(uint16_t));
} }
static INLINE void updateStateEOS( static INLINE void updateStateEOS(
depquant_state * state, context_store* ctxs,
const uint32_t scan_pos, const uint32_t scan_pos,
const uint32_t cg_pos, const uint32_t cg_pos,
const uint32_t sigCtxOffsetNext, const uint32_t sigCtxOffsetNext,
const uint32_t gtxCtxOffsetNext, const uint32_t gtxCtxOffsetNext,
const uint32_t width_in_sbb, const uint32_t width_in_sbb,
const uint32_t height_in_sbb, const uint32_t height_in_sbb,
const uint32_t next_sbb_right, const uint32_t next_sbb_right,
const uint32_t next_sbb_below, const uint32_t next_sbb_below,
const depquant_state* prevStates, const Decision * decisions,
const depquant_state* skipStates, int decision_id)
const Decision * decisions,
int decision_id)
{ {
state->m_rdCost = decisions->rdCost[decision_id]; all_depquant_states* state = &ctxs->m_allStates;
int curr_state_offset = ctxs->m_curr_state_offset + decision_id;
state->m_rdCost[curr_state_offset] = decisions->rdCost[decision_id];
if (decisions->prevId[decision_id] > -2) if (decisions->prevId[decision_id] > -2)
{ {
const depquant_state* prvState = 0; int prvState = -1;
if (decisions->prevId[decision_id] >= 4) if (decisions->prevId[decision_id] >= 4)
{ {
prvState = skipStates + (decisions->prevId[decision_id] - 4); prvState = ctxs->m_skip_state_offset + (decisions->prevId[decision_id] - 4);
state->m_numSigSbb = 0; state->m_numSigSbb[curr_state_offset] = 0;
memset(state->m_absLevelsAndCtxInit, 0, 16 * sizeof(uint8_t)); memset(state->m_absLevelsAndCtxInit[curr_state_offset], 0, 16 * sizeof(uint8_t));
} }
else if (decisions->prevId[decision_id] >= 0) else if (decisions->prevId[decision_id] >= 0)
{ {
prvState = prevStates + decisions->prevId[decision_id]; prvState = ctxs->m_prev_state_offset + decisions->prevId[decision_id];
state->m_numSigSbb = prvState->m_numSigSbb + !!decisions->absLevel[decision_id]; state->m_numSigSbb[curr_state_offset] = state->m_numSigSbb[prvState] + !!decisions->absLevel[decision_id];
memcpy(state->m_absLevelsAndCtxInit, prvState->m_absLevelsAndCtxInit, 16 * sizeof(uint8_t)); memcpy(state->m_absLevelsAndCtxInit[curr_state_offset], state->m_absLevelsAndCtxInit[prvState], 16 * sizeof(uint8_t));
} }
else else
{ {
state->m_numSigSbb = 1; state->m_numSigSbb[curr_state_offset] = 1;
memset(state->m_absLevelsAndCtxInit, 0, 16 * sizeof(uint8_t)); memset(state->m_absLevelsAndCtxInit[curr_state_offset], 0, 16 * sizeof(uint8_t));
} }
uint8_t* temp = (uint8_t*)(&state->m_absLevelsAndCtxInit[scan_pos & 15]); uint8_t* temp = (uint8_t*)(&state->m_absLevelsAndCtxInit[curr_state_offset][scan_pos & 15]);
*temp = (uint8_t)MIN(255, decisions->absLevel[decision_id]); *temp = (uint8_t)MIN(255, decisions->absLevel[decision_id]);
update_common_context(state->m_commonCtx, scan_pos, cg_pos, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below,prvState, state); update_common_context(ctxs, state->m_commonCtx, scan_pos, cg_pos, width_in_sbb, height_in_sbb, next_sbb_right,next_sbb_below, prvState, ctxs->m_curr_state_offset + decision_id);
coeff_t tinit = state->m_absLevelsAndCtxInit[8 + ((scan_pos - 1) & 15)]; coeff_t tinit = state->m_absLevelsAndCtxInit[curr_state_offset][8 + ((scan_pos - 1) & 15)];
coeff_t sumNum = tinit & 7; coeff_t sumNum = tinit & 7;
coeff_t sumAbs1 = (tinit >> 3) & 31; coeff_t sumAbs1 = (tinit >> 3) & 31;
coeff_t sumGt1 = sumAbs1 - sumNum; coeff_t sumGt1 = sumAbs1 - sumNum;
state->m_sigFracBits[0] = state->m_sigFracBitsArray[sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][0]; state->m_sigFracBits[curr_state_offset][0] = state->m_sigFracBitsArray[curr_state_offset][sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][0];
state->m_sigFracBits[1] = state->m_sigFracBitsArray[sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][1]; state->m_sigFracBits[curr_state_offset][1] = state->m_sigFracBitsArray[curr_state_offset][sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][1];
memcpy(state->m_coeffFracBits, state->m_gtxFracBitsArray[gtxCtxOffsetNext + (sumGt1 < 4 ? sumGt1 : 4)], sizeof(state->m_coeffFracBits)); memcpy(state->m_coeffFracBits[curr_state_offset], state->m_gtxFracBitsArray[gtxCtxOffsetNext + (sumGt1 < 4 ? sumGt1 : 4)], sizeof(state->m_coeffFracBits[0]));
} }
} }
static INLINE void updateState( static INLINE void updateState(
depquant_state* state, context_store * ctxs,
int numIPos, int numIPos,
const uint32_t scan_pos, const uint32_t scan_pos,
const depquant_state* prevStates, const Decision* decisions,
const Decision* decisions, const uint32_t sigCtxOffsetNext,
const uint32_t sigCtxOffsetNext, const uint32_t gtxCtxOffsetNext,
const uint32_t gtxCtxOffsetNext, const NbInfoSbb next_nb_info_ssb,
const NbInfoSbb next_nb_info_ssb, const int baseLevel,
const int baseLevel, const bool extRiceFlag,
const bool extRiceFlag, int decision_id) {
int decision_id) { all_depquant_states* state = &ctxs->m_allStates;
state->m_rdCost = decisions->rdCost[decision_id]; int state_id = ctxs->m_curr_state_offset + decision_id;
state->m_rdCost[state_id] = decisions->rdCost[decision_id];
if (decisions->prevId[decision_id] > -2) if (decisions->prevId[decision_id] > -2)
{ {
if (decisions->prevId[decision_id] >= 0) if (decisions->prevId[decision_id] >= 0)
{ {
const depquant_state* prvState = prevStates + decisions->prevId[decision_id]; const int prvState = ctxs->m_prev_state_offset + decisions->prevId[decision_id];
state->m_numSigSbb = prvState->m_numSigSbb + !!decisions->absLevel[decision_id]; state->m_numSigSbb[state_id] = (state->m_numSigSbb[prvState]) + !!decisions->absLevel[decision_id];
state->m_refSbbCtxId = prvState->m_refSbbCtxId; state->m_refSbbCtxId[state_id] = state->m_refSbbCtxId[prvState];
state->m_sbbFracBits[0] = prvState->m_sbbFracBits[0]; state->m_sbbFracBits[state_id][0] = state->m_sbbFracBits[prvState][0];
state->m_sbbFracBits[1] = prvState->m_sbbFracBits[1]; state->m_sbbFracBits[state_id][1] = state->m_sbbFracBits[prvState][1];
state->m_remRegBins = prvState->m_remRegBins - 1; state->m_remRegBins[state_id] = state->m_remRegBins[prvState] - 1;
state->m_goRicePar = prvState->m_goRicePar; state->m_goRicePar[state_id] = state->m_goRicePar[prvState];
if (state->m_remRegBins >= 4) if (state->m_remRegBins[state_id] >= 4)
{ {
state->m_remRegBins -= (decisions->absLevel[decision_id] < 2 ? (unsigned)decisions->absLevel[decision_id] : 3); state->m_remRegBins[state_id] -= (decisions->absLevel[decision_id] < 2 ? (unsigned)decisions->absLevel[decision_id] : 3);
} }
memcpy(state->m_absLevelsAndCtxInit, prvState->m_absLevelsAndCtxInit, 48 * sizeof(uint8_t)); memcpy(state->m_absLevelsAndCtxInit[state_id], state->m_absLevelsAndCtxInit[prvState], 48 * sizeof(uint8_t));
} }
else else
{ {
state->m_numSigSbb = 1; state->m_numSigSbb[state_id] = 1;
state->m_refSbbCtxId = -1; state->m_refSbbCtxId[state_id] = -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; 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 - (decisions->absLevel[decision_id] < 2 ? (unsigned)decisions->absLevel[decision_id] : 3); state->m_remRegBins[state_id] = (state->effWidth * state->effHeight * ctxBinSampleRatio) / 16 - (decisions->absLevel[decision_id] < 2 ? (unsigned)decisions->absLevel[decision_id] : 3);
memset(state->m_absLevelsAndCtxInit, 0, 48 * sizeof(uint8_t)); memset(state->m_absLevelsAndCtxInit[state_id], 0, 48 * sizeof(uint8_t));
} }
uint8_t* levels = (uint8_t*)(state->m_absLevelsAndCtxInit); uint8_t* levels = (uint8_t*)(state->m_absLevelsAndCtxInit[state_id]);
levels[scan_pos & 15] = (uint8_t)MIN(255, decisions->absLevel[decision_id]); levels[scan_pos & 15] = (uint8_t)MIN(255, decisions->absLevel[decision_id]);
if (state->m_remRegBins >= 4) if (state->m_remRegBins[state_id] >= 4)
{ {
coeff_t tinit = state->m_absLevelsAndCtxInit[8 + ((scan_pos - 1) & 15)]; coeff_t tinit = state->m_absLevelsAndCtxInit[state_id][8 + ((scan_pos - 1) & 15)];
coeff_t sumAbs1 = (tinit >> 3) & 31; coeff_t sumAbs1 = (tinit >> 3) & 31;
coeff_t sumNum = tinit & 7; coeff_t sumNum = tinit & 7;
#define UPDATE(k) {coeff_t t=levels[next_nb_info_ssb.inPos[k]]; sumAbs1+=MIN(4+(t&1),t); sumNum+=!!t; } #define UPDATE(k) {coeff_t t=levels[next_nb_info_ssb.inPos[k]]; sumAbs1+=MIN(4+(t&1),t); sumNum+=!!t; }
@ -961,12 +985,12 @@ static INLINE void updateState(
} }
#undef UPDATE #undef UPDATE
coeff_t sumGt1 = sumAbs1 - sumNum; coeff_t sumGt1 = sumAbs1 - sumNum;
state->m_sigFracBits[0] = state->m_sigFracBitsArray[sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][0]; state->m_sigFracBits[state_id][0] = state->m_sigFracBitsArray[state_id][sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][0];
state->m_sigFracBits[1] = state->m_sigFracBitsArray[sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][1]; state->m_sigFracBits[state_id][1] = state->m_sigFracBitsArray[state_id][sigCtxOffsetNext + MIN((sumAbs1 + 1) >> 1, 3)][1];
memcpy(state->m_coeffFracBits, state->m_gtxFracBitsArray[gtxCtxOffsetNext + (sumGt1 < 4 ? sumGt1 : 4)], sizeof(state->m_coeffFracBits)); memcpy(state->m_coeffFracBits[state_id], state->m_gtxFracBitsArray[gtxCtxOffsetNext + (sumGt1 < 4 ? sumGt1 : 4)], sizeof(state->m_coeffFracBits[0]));
coeff_t sumAbs = state->m_absLevelsAndCtxInit[8 + ((scan_pos - 1) & 15)] >> 8; coeff_t sumAbs = state->m_absLevelsAndCtxInit[state_id][8 + ((scan_pos - 1) & 15)] >> 8;
#define UPDATE(k) {coeff_t t=levels[next_nb_info_ssb.inPos[k]]; sumAbs+=t; } #define UPDATE(k) {coeff_t t=levels[next_nb_info_ssb.inPos[k]]; sumAbs+=t; }
if (numIPos == 1) if (numIPos == 1)
{ {
@ -1004,18 +1028,18 @@ static INLINE void updateState(
unsigned currentShift = templateAbsCompare(sumAbs); unsigned currentShift = templateAbsCompare(sumAbs);
sumAbs = sumAbs >> currentShift; sumAbs = sumAbs >> currentShift;
int sumAll = MAX(MIN(31, (int)sumAbs - (int)baseLevel), 0); int sumAll = MAX(MIN(31, (int)sumAbs - (int)baseLevel), 0);
state->m_goRicePar = g_goRiceParsCoeff[sumAll]; state->m_goRicePar[state_id] = g_goRiceParsCoeff[sumAll];
state->m_goRicePar += currentShift; state->m_goRicePar[state_id] += currentShift;
} }
else else
{ {
int sumAll = MAX(MIN(31, (int)sumAbs - 4 * 5), 0); int sumAll = MAX(MIN(31, (int)sumAbs - 4 * 5), 0);
state->m_goRicePar = g_goRiceParsCoeff[sumAll]; state->m_goRicePar[state_id] = g_goRiceParsCoeff[sumAll];
} }
} }
else else
{ {
coeff_t sumAbs = state->m_absLevelsAndCtxInit[8 + ((scan_pos - 1) & 15)] >> 8; coeff_t sumAbs = (state->m_absLevelsAndCtxInit[state_id][8 + ((scan_pos - 1) & 15)]) >> 8;
#define UPDATE(k) {coeff_t t=levels[next_nb_info_ssb.inPos[k]]; sumAbs+=t; } #define UPDATE(k) {coeff_t t=levels[next_nb_info_ssb.inPos[k]]; sumAbs+=t; }
if (numIPos == 1) if (numIPos == 1)
{ {
@ -1053,19 +1077,20 @@ static INLINE void updateState(
unsigned currentShift = templateAbsCompare(sumAbs); unsigned currentShift = templateAbsCompare(sumAbs);
sumAbs = sumAbs >> currentShift; sumAbs = sumAbs >> currentShift;
sumAbs = MIN(31, sumAbs); sumAbs = MIN(31, sumAbs);
state->m_goRicePar = g_goRiceParsCoeff[sumAbs]; state->m_goRicePar[state_id] = g_goRiceParsCoeff[sumAbs];
state->m_goRicePar += currentShift; state->m_goRicePar[state_id] += currentShift;
} }
else else
{ {
sumAbs = MIN(31, sumAbs); sumAbs = MIN(31, sumAbs);
state->m_goRicePar = g_goRiceParsCoeff[sumAbs]; state->m_goRicePar[state_id] = g_goRiceParsCoeff[sumAbs];
} }
state->m_goRiceZero = (state->m_stateId < 2 ? 1 : 2) << state->m_goRicePar; state->m_goRiceZero[state_id] = ((state_id & 3) < 2 ? 1 : 2) << state->m_goRicePar[state_id];
} }
} }
} }
static bool same[13];
static void xDecideAndUpdate( static void xDecideAndUpdate(
rate_estimator* re, rate_estimator* re,
context_store* ctxs, context_store* ctxs,
@ -1087,7 +1112,7 @@ static void xDecideAndUpdate(
int effHeight) int effHeight)
{ {
Decision* decisions = &ctxs->m_trellis[scan_pos]; Decision* decisions = &ctxs->m_trellis[scan_pos];
SWAP(ctxs->m_currStates, ctxs->m_prevStates, depquant_state*); SWAP(ctxs->m_curr_state_offset, ctxs->m_prev_state_offset, int);
enum ScanPosType spt = 0; enum ScanPosType spt = 0;
if ((scan_pos & 15) == 15 && scan_pos > 16 && scan_pos < effHeight * effWidth - 1) if ((scan_pos & 15) == 15 && scan_pos > 16 && scan_pos < effHeight * effWidth - 1)
@ -1099,28 +1124,28 @@ static void xDecideAndUpdate(
spt = SCAN_EOCSBB; spt = SCAN_EOCSBB;
} }
xDecide(ctxs->m_skipStates, ctxs->m_prevStates, &ctxs->m_startState, &ctxs->m_quant, spt, absCoeff, re->m_lastBitsX[pos_x] + re->m_lastBitsY[pos_y], decisions, zeroOut, quantCoeff); xDecide(&ctxs->m_allStates, &ctxs->m_startState, &ctxs->m_quant, spt, absCoeff, re->m_lastBitsX[pos_x] + re->m_lastBitsY[pos_y], decisions, zeroOut, quantCoeff,ctxs->m_skip_state_offset, ctxs->m_prev_state_offset);
if (scan_pos) { if (scan_pos) {
if (!(scan_pos & 15)) { if (!(scan_pos & 15)) {
SWAP(ctxs->m_common_context.m_currSbbCtx, ctxs->m_common_context.m_prevSbbCtx, SbbCtx*); SWAP(ctxs->m_common_context.m_currSbbCtx, ctxs->m_common_context.m_prevSbbCtx, SbbCtx*);
updateStateEOS(&ctxs->m_currStates[0], scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, ctxs->m_prevStates, ctxs->m_skipStates, decisions,0); updateStateEOS(ctxs, scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, decisions, 0);
updateStateEOS(&ctxs->m_currStates[1], scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, ctxs->m_prevStates, ctxs->m_skipStates, decisions,1); updateStateEOS(ctxs, scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, decisions, 1);
updateStateEOS(&ctxs->m_currStates[2], scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, ctxs->m_prevStates, ctxs->m_skipStates, decisions,2); updateStateEOS(ctxs, scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, decisions, 2);
updateStateEOS(&ctxs->m_currStates[3], scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, ctxs->m_prevStates, ctxs->m_skipStates, decisions,3); updateStateEOS(ctxs, scan_pos, cg_pos, sigCtxOffsetNext, gtxCtxOffsetNext, width_in_sbb, height_in_sbb, next_sbb_right, next_sbb_below, decisions, 3);
memcpy(decisions->prevId + 4, decisions->prevId, 4 * sizeof(int)); memcpy(decisions->prevId + 4, decisions->prevId, 4 * sizeof(int));
memcpy(decisions->absLevel + 4, decisions->absLevel, 4 * sizeof(coeff_t)); memcpy(decisions->absLevel + 4, decisions->absLevel, 4 * sizeof(coeff_t));
memcpy(decisions->rdCost + 4, decisions->rdCost, 4 * sizeof(int64_t)); memcpy(decisions->rdCost + 4, decisions->rdCost, 4 * sizeof(int64_t));
} else if (!zeroOut) { } else if (!zeroOut) {
updateState(&ctxs->m_currStates[0], next_nb_info_ssb.num, scan_pos, ctxs->m_prevStates, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 0); updateState(ctxs, next_nb_info_ssb.num, scan_pos, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 0);
updateState(&ctxs->m_currStates[1], next_nb_info_ssb.num, scan_pos, ctxs->m_prevStates, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 1); updateState(ctxs, next_nb_info_ssb.num, scan_pos, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 1);
updateState(&ctxs->m_currStates[2], next_nb_info_ssb.num, scan_pos, ctxs->m_prevStates, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 2); updateState(ctxs, next_nb_info_ssb.num, scan_pos, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 2);
updateState(&ctxs->m_currStates[3], next_nb_info_ssb.num, scan_pos, ctxs->m_prevStates, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 3); updateState(ctxs, next_nb_info_ssb.num, scan_pos, decisions, sigCtxOffsetNext, gtxCtxOffsetNext, next_nb_info_ssb, 4, false, 3);
} }
if (spt == SCAN_SOCSBB) { if (spt == SCAN_SOCSBB) {
SWAP(ctxs->m_skipStates, ctxs->m_prevStates, depquant_state*); SWAP(ctxs->m_skip_state_offset, ctxs->m_prev_state_offset, int);
} }
} }
} }
@ -1142,9 +1167,9 @@ int uvg_dep_quant(
//===== reset / pre-init ===== //===== reset / pre-init =====
const int baseLevel = 4; const int baseLevel = 4;
context_store dep_quant_context; context_store dep_quant_context;
dep_quant_context.m_currStates = &dep_quant_context.m_allStates[0]; dep_quant_context.m_curr_state_offset = 0;
dep_quant_context.m_prevStates = &dep_quant_context.m_allStates[4]; dep_quant_context.m_prev_state_offset = 4;
dep_quant_context.m_skipStates = &dep_quant_context.m_allStates[8]; dep_quant_context.m_skip_state_offset = 8;
const uint32_t lfnstIdx = tree_type != UVG_CHROMA_T || compID == COLOR_Y ? const uint32_t lfnstIdx = tree_type != UVG_CHROMA_T || compID == COLOR_Y ?
cur_tu->lfnst_idx : cur_tu->lfnst_idx :
@ -1226,18 +1251,32 @@ int uvg_dep_quant(
int effectHeight = MIN(32, effHeight); int effectHeight = MIN(32, effHeight);
int effectWidth = MIN(32, effWidth); int effectWidth = MIN(32, effWidth);
for (int k = 0; k < 12; k++) { for (int k = 0; k < 12; k++) {
depquant_state_init(&dep_quant_context.m_allStates[k], rate_estimator.m_sigFracBits[0][0], rate_estimator.m_gtxFracBits[0]); dep_quant_context.m_allStates.m_rdCost[k] = INT64_MAX >> 1;
dep_quant_context.m_allStates[k].effHeight = effectHeight; dep_quant_context.m_allStates.m_numSigSbb[k] = 0;
dep_quant_context.m_allStates[k].effWidth = effectWidth; dep_quant_context.m_allStates.m_remRegBins[k] = 4; // just large enough for last scan pos
dep_quant_context.m_allStates[k].m_commonCtx = &dep_quant_context.m_common_context; dep_quant_context.m_allStates.m_refSbbCtxId[k] = -1;
dep_quant_context.m_allStates[k].m_stateId = k & 3; dep_quant_context.m_allStates.m_sigFracBits[k][0] = rate_estimator.m_sigFracBits[0][0][0];
dep_quant_context.m_allStates.m_sigFracBits[k][1] = rate_estimator.m_sigFracBits[0][0][1];
memcpy(dep_quant_context.m_allStates.m_coeffFracBits[k], rate_estimator.m_gtxFracBits[0], sizeof(dep_quant_context.m_allStates.m_coeffFracBits[k]));
dep_quant_context.m_allStates.m_goRicePar[k] = 0;
dep_quant_context.m_allStates.m_goRiceZero[k] = 0;
dep_quant_context.m_allStates.m_sbbFracBits[k][0] = 0;
dep_quant_context.m_allStates.m_sbbFracBits[k][1] = 0;
dep_quant_context.m_allStates.m_stateId[k] = k & 3;
for (int i = 0; i < (compID == COLOR_Y ? 12 : 8); ++i) { for (int i = 0; i < (compID == COLOR_Y ? 12 : 8); ++i) {
dep_quant_context.m_allStates[k].m_sigFracBitsArray[i] = rate_estimator.m_sigFracBits[(k & 3 ? (k & 3) - 1 : 0)][i]; dep_quant_context.m_allStates.m_sigFracBitsArray[k][i] = rate_estimator.m_sigFracBits[(k & 3 ? (k & 3) - 1 : 0)][i];
}
for (int i = 0; i < (compID == COLOR_Y ? 21 : 11); ++i) {
dep_quant_context.m_allStates[k].m_gtxFracBitsArray[i] = rate_estimator.m_gtxFracBits[i];
} }
} }
dep_quant_context.m_allStates.effHeight = effectHeight;
dep_quant_context.m_allStates.effWidth = effectWidth;
dep_quant_context.m_allStates.m_commonCtx = &dep_quant_context.m_common_context;
for (int i = 0; i < (compID == COLOR_Y ? 21 : 11); ++i) {
dep_quant_context.m_allStates.m_gtxFracBitsArray[i] = rate_estimator.m_gtxFracBits[i];
}
depquant_state_init(&dep_quant_context.m_startState, rate_estimator.m_sigFracBits[0][0], rate_estimator.m_gtxFracBits[0]); depquant_state_init(&dep_quant_context.m_startState, rate_estimator.m_sigFracBits[0][0], rate_estimator.m_gtxFracBits[0]);
dep_quant_context.m_startState.effHeight = effectHeight; dep_quant_context.m_startState.effHeight = effectHeight;
dep_quant_context.m_startState.effWidth = effectWidth; dep_quant_context.m_startState.effWidth = effectWidth;
@ -1250,7 +1289,6 @@ int uvg_dep_quant(
dep_quant_context.m_startState.m_gtxFracBitsArray[i] = rate_estimator.m_gtxFracBits[i]; dep_quant_context.m_startState.m_gtxFracBitsArray[i] = rate_estimator.m_gtxFracBits[i];
} }
const uint32_t height_in_sbb = MAX(height >> 2, 1); const uint32_t height_in_sbb = MAX(height >> 2, 1);
const uint32_t width_in_sbb = MAX(width >> 2, 1); const uint32_t width_in_sbb = MAX(width >> 2, 1);
//===== populate trellis ===== //===== populate trellis =====
@ -1320,11 +1358,13 @@ int uvg_dep_quant(
width, width,
height); //tu.cu->slice->getReverseLastSigCoeffFlag()); height); //tu.cu->slice->getReverseLastSigCoeffFlag());
} }
//printf("%d\n", scanIdx); if(0){
//for(int i = 0; i < 4; i++) { printf("%d\n", scanIdx);
// printf("%lld %hu %d\n", ctxs->m_trellis[scanIdx].rdCost[i], ctxs->m_trellis[scanIdx].absLevel[i], ctxs->m_trellis[scanIdx].prevId[i]); for (int i = 0; i < 4; i++) {
//} printf("%lld %hu %d\n", ctxs->m_trellis[scanIdx].rdCost[i], ctxs->m_trellis[scanIdx].absLevel[i], ctxs->m_trellis[scanIdx].prevId[i]);
//printf("\n"); }
printf("\n");
}
} }
//===== find best path ===== //===== find best path =====
@ -1340,6 +1380,12 @@ int uvg_dep_quant(
//===== backward scanning ===== //===== backward scanning =====
int scanIdx = 0; int scanIdx = 0;
context_store* ctxs = &dep_quant_context;
// printf("%d\n", scanIdx);
//for (int i = 0; i < 4; i++) {
// printf("%lld %hu %d\n", ctxs->m_trellis[scanIdx].rdCost[i], ctxs->m_trellis[scanIdx].absLevel[i], ctxs->m_trellis[scanIdx].prevId[i]);
//}
//printf("\n");
for (; prev_id >= 0; scanIdx++) { for (; prev_id >= 0; scanIdx++) {
Decision temp = dep_quant_context.m_trellis[scanIdx]; Decision temp = dep_quant_context.m_trellis[scanIdx];
int32_t blkpos = scan[scanIdx]; int32_t blkpos = scan[scanIdx];