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aomedia / avm / refs/heads/fg8/CT3-coeff-v2 / . / av1 / decoder / decodetxb.c
blob: 17506d280fe8372c6f335d41858db1b264cd248b [file] [log] [blame] [edit]
/*
* Copyright (c) 2021, Alliance for Open Media. All rights reserved
*
* This source code is subject to the terms of the BSD 3-Clause Clear License
* and the Alliance for Open Media Patent License 1.0. If the BSD 3-Clause Clear
* License was not distributed with this source code in the LICENSE file, you
* can obtain it at aomedia.org/license/software-license/bsd-3-c-c/. If the
* Alliance for Open Media Patent License 1.0 was not distributed with this
* source code in the PATENTS file, you can obtain it at
* aomedia.org/license/patent-license/.
*/
#include "av1/decoder/decodetxb.h"
#include "aom_ports/mem.h"
#include "av1/common/hr_coding.h"
#include "av1/common/idct.h"
#include "av1/common/pred_common.h"
#include "av1/common/reconintra.h"
#include "av1/common/scan.h"
#include "av1/common/txb_common.h"
#include "av1/decoder/decodemv.h"
#if CONFIG_PARAKIT_COLLECT_DATA
#include "av1/common/cost.h"
#endif
#if CONFIG_PARAKIT_COLLECT_DATA
static int get_q_ctx(int q) {
if (q <= 90) return 0;
if (q <= 140) return 1;
if (q <= 190) return 2;
return 3;
}
#endif
/*!\brief Read and decode from bitstream an integer value following Exp-Golomb
* coding with order k
*
* \ingroup coefficient_coding
*
* This function reads and decodes from the bitstream r an integer value which
* was coded in Exp-Golomb with order k
*
* \param[in] xd Pointer to structure holding the data for the
* current macroblockd
* \param[in] r Pointer to the bitstream reader
* \param[in] k Order of Exp-Golomb coding
*
*/
static int read_exp_golomb(MACROBLOCKD *xd, aom_reader *r, int k) {
#if CONFIG_BYPASS_IMPROVEMENT
int length = aom_read_unary(r, 21, ACCT_INFO("hr"));
if (length > 20) {
aom_internal_error(xd->error_info, AOM_CODEC_CORRUPT_FRAME,
"Invalid length in read_exp_golomb");
}
length += k;
int x = 1 << length;
x += aom_read_literal(r, length, ACCT_INFO("hr"));
#else
int x = 1;
int length = 0;
int i = 0;
while (!i) {
i = aom_read_bit(r, ACCT_INFO("hr"));
++length;
if (length > 20) {
aom_internal_error(xd->error_info, AOM_CODEC_CORRUPT_FRAME,
"Invalid length in read_exp_golomb");
break;
}
}
length += k;
for (i = 0; i < length - 1; ++i) {
x <<= 1;
x += aom_read_bit(r, ACCT_INFO("hr"));
}
#endif // CONFIG_BYPASS_IMPROVEMENT
return x - (1 << k);
}
#if CONFIG_COEFF_HR_ADAPTIVE
/*!\brief Read and decode from the bitstream a Truncated-Rice coded integer
* value.
*
* \ingroup coefficient_coding
*
* This function reads and decodes from the bitstream a Truncated-Rice coded
* integer value, with Rice parameter m. It first reads and decodes the unary
* prefix q from the input bitstream r. Given a shorter prefix (q < cmax), it
* decodes the remaining offset of the integer using Golomb-Rice coding;
* otherwise (i.e., when q == cmax) it shifts to use Exp-Golomb to decode the
* remainder value.
*
* \param[in] xd Pointer to structure holding the data for the
* current macroblockd
* \param[in] r Pointer to the reader of the bitstream
* \param[in] m Parameter of the Rice distribution
* \param[in] k Order of the Exp-Golomb code
* \param[in] cmax Maximum unary prefix length above which Exp-Golomb
* is used instead of Golomb-Rice coding
*
*/
static int read_truncated_rice(MACROBLOCKD *xd, aom_reader *r, int m, int k,
int cmax) {
#if CONFIG_BYPASS_IMPROVEMENT
int q = aom_read_unary(r, cmax, ACCT_INFO("hr"));
#else
int q = 0;
int i = 0;
while (!i) {
i = aom_read_bit(r, ACCT_INFO("hr"));
++q;
if (q > cmax - 1) {
aom_internal_error(xd->error_info, AOM_CODEC_CORRUPT_FRAME,
"Invalid length in read_truncated_rice");
break;
}
}
#endif // CONFIG_BYPASS_IMPROVEMENT
int rem = (q == cmax) ? read_exp_golomb(xd, r, k)
: aom_read_literal(r, m, ACCT_INFO("hr"));
return rem + (q << m);
}
/*!\brief Read and decode from the bitstream the high range (HR) value of
* the coefficient level using adaptive Truncated-Rice coding.
*
* \ingroup coefficient_coding
*
* This function reads and decodes from the bitstream the high range (HR)
* value of the coefficient level following adaptive Truncated-Rice coding.
* It first derives the Rice parameter m from the input context value ctx.
* It then invokes the read_truncated_rice function to decode the HR
* coefficient value using Rice parameter m, Exp-Golomb order k = m + 1,
* and maximum unary prefix lenght cmax = AOMMIN(m + 4, 6).
*
* \param[in] xd Pointer to structure holding the data for the
* current macroblockd
* \param[in] r Pointer to the reader of the bitstream
* \param[in] ctx Context value
*
*/
static int read_adaptive_hr(MACROBLOCKD *xd, aom_reader *r, int ctx) {
int m = get_adaptive_param(ctx);
return read_truncated_rice(xd, r, m, m + 1, AOMMIN(m + 4, 6));
}
#endif // CONFIG_COEFF_HR_ADAPTIVE
// Read high range part of coeff
static INLINE int read_high_range(MACROBLOCKD *xd, aom_reader *r, int tcq_mode,
int level, int lf
#if CONFIG_COEFF_HR_ADAPTIVE
,
int *hr_avg
#endif
#if CONFIG_COEFF_BR_LF_UV_BYPASS
,
int plane
#endif
) {
#if CONFIG_COEFF_BR_LF_UV_BYPASS // code_hr_t
int max_br = lf ? (plane == 0 ? LF_MAX_BASE_BR_RANGE // 8
: LF_NUM_BASE_LEVELS + 1)
: MAX_BASE_BR_RANGE;
#else
int max_br = lf ? LF_MAX_BASE_BR_RANGE : MAX_BASE_BR_RANGE;
#endif
int use_tcq_hr = tcq_mode && (level >= max_br - 1);
#if CONFIG_COEFF_HR_ADAPTIVE
int hr_level_avg = *hr_avg;
int use_hr = use_tcq_hr || level >= max_br;
if (use_hr) {
int hr = read_adaptive_hr(xd, r, hr_level_avg);
level += hr << (tcq_mode ? 1 : 0);
*hr_avg = (hr_level_avg + hr) >> 1;
}
#else
int use_hr = use_tcq_hr || level >= max_br;
int hr = use_hr ? read_exp_golomb(xd, r, 0) : 0;
level += (1 << use_tcq_hr) * hr;
#endif
return level;
}
static INLINE int rec_eob_pos(const int eob_token, const int extra) {
int eob = av1_eob_group_start[eob_token];
if (eob > 2) {
eob += extra;
}
return eob;
}
static INLINE int get_dqv(const int32_t *dequant, int coeff_idx,
const qm_val_t *iqmatrix) {
int dqv = dequant[!!coeff_idx];
if (iqmatrix != NULL)
dqv =
((iqmatrix[coeff_idx] * dqv) + (1 << (AOM_QM_BITS - 1))) >> AOM_QM_BITS;
return dqv;
}
static int read_low_range(aom_reader *r, aom_cdf_prob *cdf) {
int br_level = 0;
for (int idx = 0; idx < COEFF_BASE_RANGE; idx += BR_CDF_SIZE - 1) {
const int k =
aom_read_symbol(r, cdf, BR_CDF_SIZE, ACCT_INFO("k", "br_lf_uv_cdf"));
br_level += k;
if (k < BR_CDF_SIZE - 1) break;
}
return br_level;
}
static INLINE void read_coeffs_reverse_2d(
aom_reader *r, int start_si, int end_si, const int16_t *scan, int bwl,
uint8_t *levels, base_lf_cdf_arr base_lf_cdf, br_cdf_arr br_lf_cdf,
int plane, base_cdf_arr base_cdf, br_cdf_arr br_cdf,
base_lf_cdf_arr base_lf_uv_cdf,
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
br_cdf_arr br_lf_uv_cdf,
#endif
base_cdf_arr base_uv_cdf, br_cdf_arr br_uv_cdf
#if CONFIG_TCQ
,
int *state
#endif // CONFIG_TCQ
) {
for (int c = end_si; c >= start_si; --c) {
const int pos = scan[c];
int level = 0;
const int row = pos >> bwl;
const int col = pos - (row << bwl);
int limits = get_lf_limits(row, col, 0, plane);
#if CONFIG_TCQ
int q_i = tcq_quant(*state);
#endif // CONFIG_TCQ
if (plane > 0) {
if (limits) {
const int coeff_ctx =
get_lower_levels_ctx_lf_2d_chroma(levels, pos, bwl, plane);
#if CONFIG_TCQ
level +=
aom_read_symbol(r, base_lf_uv_cdf[coeff_ctx][q_i], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_uv_cdf"));
#else
level += aom_read_symbol(r, base_lf_uv_cdf[coeff_ctx], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_uv_cdf"));
#endif // CONFIG_TCQ
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
if (level > LF_NUM_BASE_LEVELS) {
const int br_ctx = get_br_lf_ctx_2d_chroma(levels, pos, bwl);
aom_cdf_prob *cdf = br_lf_uv_cdf[br_ctx];
level += read_low_range(r, cdf);
}
#endif
} else {
const int coeff_ctx =
get_lower_levels_ctx_2d_chroma(levels, pos, bwl, plane);
#if CONFIG_TCQ
level += aom_read_symbol(r, base_uv_cdf[coeff_ctx][q_i], 4,
ACCT_INFO("level", "base_uv_cdf"));
#else
level += aom_read_symbol(r, base_uv_cdf[coeff_ctx], 4,
ACCT_INFO("level", "base_uv_cdf"));
#endif // CONFIG_TCQ
if (level > NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx_2d_chroma(levels, pos, bwl);
aom_cdf_prob *cdf = br_uv_cdf[br_ctx];
level += read_low_range(r, cdf);
}
}
} else {
if (limits) {
const int coeff_ctx = get_lower_levels_ctx_lf_2d(levels, pos, bwl);
#if CONFIG_TCQ
level +=
aom_read_symbol(r, base_lf_cdf[coeff_ctx][q_i], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_cdf"));
#else
level += aom_read_symbol(r, base_lf_cdf[coeff_ctx], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_cdf"));
#endif // CONFIG_TCQ
if (level > LF_NUM_BASE_LEVELS) {
const int br_ctx = get_br_lf_ctx_2d(levels, pos, bwl);
aom_cdf_prob *cdf = br_lf_cdf[br_ctx];
level += read_low_range(r, cdf);
}
} else {
const int coeff_ctx = get_lower_levels_ctx_2d(levels, pos, bwl, plane);
#if CONFIG_TCQ
level += aom_read_symbol(r, base_cdf[coeff_ctx][q_i], 4,
ACCT_INFO("level", "base_cdf"));
#else
level += aom_read_symbol(r, base_cdf[coeff_ctx], 4,
ACCT_INFO("level", "base_cdf"));
#endif // CONFIG_TCQ
if (level > NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx_2d(levels, pos, bwl);
aom_cdf_prob *cdf = br_cdf[br_ctx];
level += read_low_range(r, cdf);
}
}
}
levels[get_padded_idx(pos, bwl)] = level;
#if CONFIG_TCQ
*state = tcq_next_state(*state, level);
#endif // CONFIG_TCQ
}
}
static INLINE void read_coeffs_reverse(
aom_reader *r, TX_CLASS tx_class, int start_si, int end_si,
const int16_t *scan, int bwl, uint8_t *levels, base_lf_cdf_arr base_lf_cdf,
br_cdf_arr br_lf_cdf, int plane, base_cdf_arr base_cdf, br_cdf_arr br_cdf,
base_lf_cdf_arr base_lf_uv_cdf,
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
br_cdf_arr br_lf_uv_cdf,
#endif
base_cdf_arr base_uv_cdf, br_cdf_arr br_uv_cdf
#if CONFIG_TCQ
,
int *state
#endif // CONFIG_TCQ
) {
for (int c = end_si; c >= start_si; --c) {
const int pos = scan[c];
int level = 0;
#if CONFIG_TCQ
int q_i = tcq_quant(*state);
#endif // CONFIG_TCQ
const int row = pos >> bwl;
const int col = pos - (row << bwl);
int limits = get_lf_limits(row, col, tx_class, plane);
if (plane > 0) {
if (limits) {
const int coeff_ctx =
get_lower_levels_lf_ctx_chroma(levels, pos, bwl, tx_class, plane);
#if CONFIG_TCQ
level +=
aom_read_symbol(r, base_lf_uv_cdf[coeff_ctx][q_i], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_uv_cdf"));
#else
level += aom_read_symbol(r, base_lf_uv_cdf[coeff_ctx], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_uv_cdf"));
#endif // CONFIG_TCQ
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
if (level > LF_NUM_BASE_LEVELS) {
const int br_ctx = get_br_lf_ctx_chroma(levels, pos, bwl, tx_class);
aom_cdf_prob *cdf = br_lf_uv_cdf[br_ctx];
level += read_low_range(r, cdf);
}
#endif
} else {
const int coeff_ctx =
get_lower_levels_ctx_chroma(levels, pos, bwl, tx_class, plane);
#if CONFIG_TCQ
level += aom_read_symbol(r, base_uv_cdf[coeff_ctx][q_i], 4,
ACCT_INFO("level", "base_uv_cdf"));
#else
level += aom_read_symbol(r, base_uv_cdf[coeff_ctx], 4,
ACCT_INFO("level", "base_uv_cdf"));
#endif // CONFIG_TCQ
if (level > NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx_chroma(levels, pos, bwl, tx_class);
aom_cdf_prob *cdf = br_uv_cdf[br_ctx];
level += read_low_range(r, cdf);
}
}
} else {
if (limits) {
const int coeff_ctx =
get_lower_levels_lf_ctx(levels, pos, bwl, tx_class);
#if CONFIG_TCQ
level +=
aom_read_symbol(r, base_lf_cdf[coeff_ctx][q_i], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_cdf"));
#else
level += aom_read_symbol(r, base_lf_cdf[coeff_ctx], LF_BASE_SYMBOLS,
ACCT_INFO("level", "base_lf_cdf"));
#endif // CONFIG_TCQ
if (level > LF_NUM_BASE_LEVELS) {
const int br_ctx = get_br_lf_ctx(levels, pos, bwl, tx_class);
aom_cdf_prob *cdf = br_lf_cdf[br_ctx];
level += read_low_range(r, cdf);
}
} else {
const int coeff_ctx =
get_lower_levels_ctx(levels, pos, bwl, tx_class, plane);
#if CONFIG_TCQ
level += aom_read_symbol(r, base_cdf[coeff_ctx][q_i], 4,
ACCT_INFO("level", "base_cdf"));
#else
level += aom_read_symbol(r, base_cdf[coeff_ctx], 4,
ACCT_INFO("level", "base_cdf"));
#endif // CONFIG_TCQ
if (level > NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx(levels, pos, bwl, tx_class);
aom_cdf_prob *cdf = br_cdf[br_ctx];
level += read_low_range(r, cdf);
}
}
}
levels[get_padded_idx(pos, bwl)] = level;
#if CONFIG_TCQ
*state = tcq_next_state(*state, level);
#endif // CONFIG_TCQ
}
}
static INLINE void read_coeffs_forward_2d(aom_reader *r, int start_si,
int end_si, const int16_t *scan,
int bwl, uint8_t *levels,
base_fsc_cdf_arr base_cdf,
br_cdf_arr br_cdf) {
for (int c = start_si; c <= end_si; c++) {
const int pos = scan[c];
const int coeff_ctx = get_upper_levels_ctx_2d(levels, pos, bwl);
const int nsymbs = 4;
int level = aom_read_symbol(r, base_cdf[coeff_ctx], nsymbs,
ACCT_INFO("level", "base_cdf"));
if (level > NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx_skip(levels, pos, bwl);
aom_cdf_prob *cdf = br_cdf[br_ctx];
level += read_low_range(r, cdf);
}
levels[get_padded_idx_left(pos, bwl)] = level;
}
}
// Decode the end-of-block syntax.
static INLINE void decode_eob(DecoderCodingBlock *dcb, aom_reader *const r,
const int plane, const TX_SIZE tx_size
#if CONFIG_PARAKIT_COLLECT_DATA
,
const AV1_COMMON *const cm
#endif
) {
MACROBLOCKD *const xd = &dcb->xd;
#if !CONFIG_EOB_PT_CTX_REDUCTION
const PLANE_TYPE plane_type = get_plane_type(plane);
#endif
FRAME_CONTEXT *const ec_ctx = xd->tile_ctx;
#if CONFIG_EOB_POS_LUMA
const int is_inter = is_inter_block(xd->mi[0], xd->tree_type);
const int pl_ctx = get_eob_plane_ctx(plane, is_inter);
#else
const int pl_ctx = plane_type;
#endif // CONFIG_EOB_POS_LUMA
#if !CONFIG_EOB_PT_CTX_REDUCTION
const TX_SIZE txs_ctx = get_txsize_entropy_ctx(tx_size);
#endif
eob_info *eob_data = dcb->eob_data[plane] + dcb->txb_offset[plane];
uint16_t *const eob = &(eob_data->eob);
eob_info *bob_data = dcb->bob_data[plane] + dcb->txb_offset[plane];
uint16_t *const bob = &(bob_data->eob);
int eob_extra = 0;
int eob_pt = 1;
const int eob_multi_size = txsize_log2_minus4[tx_size];
#if CONFIG_PARAKIT_COLLECT_DATA
const int qp_index = get_q_ctx(cm->quant_params.base_qindex);
int idxlist[MAX_CTX_DIM];
idxlist[0] = qp_index;
idxlist[1] = pl_ctx;
idxlist[2] = -1;
idxlist[3] = -1;
#endif
switch (eob_multi_size) {
case 0:
#if CONFIG_PARAKIT_COLLECT_DATA
{
eob_pt =
aom_read_symbol_probdata(r, ec_ctx->eob_flag_cdf16[pl_ctx], idxlist,
cm->prob_models[EOB_FLAG_CDF16]) +
1;
break;
}
#else
eob_pt =
aom_read_symbol(r, ec_ctx->eob_flag_cdf16[pl_ctx], EOB_MAX_SYMS - 6,
ACCT_INFO("eob_pt", "eob_multi_size:0")) +
1;
break;
#endif
case 1:
#if CONFIG_PARAKIT_COLLECT_DATA
{
eob_pt =
aom_read_symbol_probdata(r, ec_ctx->eob_flag_cdf32[pl_ctx], idxlist,
cm->prob_models[EOB_FLAG_CDF32]) +
1;
break;
}
#else
eob_pt =
aom_read_symbol(r, ec_ctx->eob_flag_cdf32[pl_ctx], EOB_MAX_SYMS - 5,
ACCT_INFO("eob_pt", "eob_multi_size:1")) +
1;
break;
#endif
case 2:
eob_pt =
aom_read_symbol(r, ec_ctx->eob_flag_cdf64[pl_ctx], EOB_MAX_SYMS - 4,
ACCT_INFO("eob_pt", "eob_multi_size:2")) +
1;
break;
case 3:
eob_pt =
aom_read_symbol(r, ec_ctx->eob_flag_cdf128[pl_ctx], EOB_MAX_SYMS - 3,
ACCT_INFO("eob_pt", "eob_multi_size:3")) +
1;
break;
case 4:
eob_pt =
aom_read_symbol(r, ec_ctx->eob_flag_cdf256[pl_ctx], EOB_MAX_SYMS - 2,
ACCT_INFO("eob_pt", "eob_multi_size:4")) +
1;
break;
case 5:
eob_pt =
aom_read_symbol(r, ec_ctx->eob_flag_cdf512[pl_ctx], EOB_MAX_SYMS - 1,
ACCT_INFO("eob_pt", "eob_multi_size:5")) +
1;
break;
case 6:
default:
eob_pt =
aom_read_symbol(r, ec_ctx->eob_flag_cdf1024[pl_ctx], EOB_MAX_SYMS,
ACCT_INFO("eob_pt", "eob_multi_size:6")) +
1;
break;
}
const int eob_offset_bits = av1_eob_offset_bits[eob_pt];
if (eob_offset_bits > 0) {
#if !CONFIG_EOB_PT_CTX_REDUCTION
const int eob_ctx = eob_pt - 3;
#endif
int bit =
#if CONFIG_EOB_PT_CTX_REDUCTION
aom_read_symbol(r, ec_ctx->eob_extra_cdf, 2,
ACCT_INFO("eob_extra_cdf"));
#else
aom_read_symbol(r, ec_ctx->eob_extra_cdf[txs_ctx][plane_type][eob_ctx],
2, ACCT_INFO("eob_extra_cdf"));
#endif
if (bit) {
eob_extra += (1 << (eob_offset_bits - 1));
}
#if CONFIG_BYPASS_IMPROVEMENT
eob_extra +=
aom_read_literal(r, eob_offset_bits - 1, ACCT_INFO("eob_extra"));
#else
for (int i = 1; i < eob_offset_bits; i++) {
bit = aom_read_bit(r, ACCT_INFO("eob_offset_bits"));
if (bit) {
eob_extra += (1 << (eob_offset_bits - 1 - i));
}
}
#endif // CONFIG_BYPASS_IMPROVEMENT
}
*eob = rec_eob_pos(eob_pt, eob_extra);
*bob = *eob; // escape character
#if CONFIG_CONTEXT_DERIVATION
if (plane == AOM_PLANE_U) {
xd->eob_u = *eob;
}
#endif // CONFIG_CONTEXT_DERIVATION
}
uint8_t av1_read_sig_txtype(const AV1_COMMON *const cm, DecoderCodingBlock *dcb,
aom_reader *const r, const int blk_row,
const int blk_col, const int plane,
const TXB_CTX *const txb_ctx,
const TX_SIZE tx_size) {
MACROBLOCKD *const xd = &dcb->xd;
FRAME_CONTEXT *const ec_ctx = xd->tile_ctx;
const TX_SIZE txs_ctx = get_txsize_entropy_ctx(tx_size);
const int is_inter = is_inter_block(xd->mi[0], xd->tree_type);
eob_info *eob_data = dcb->eob_data[plane] + dcb->txb_offset[plane];
uint16_t *const eob = &(eob_data->eob);
uint16_t *const max_scan_line = &(eob_data->max_scan_line);
*max_scan_line = 0;
*eob = 0;
#if CCTX_C2_DROPPED
if (plane == AOM_PLANE_V && is_cctx_allowed(cm, xd)) {
CctxType cctx_type = av1_get_cctx_type(xd, blk_row, blk_col);
if (!keep_chroma_c2(cctx_type)) return 0;
}
#endif // CCTX_C2_DROPPED
#if CONFIG_CONTEXT_DERIVATION
if (plane == AOM_PLANE_U) {
xd->eob_u = 0;
}
int txb_skip_ctx = txb_ctx->txb_skip_ctx;
int all_zero;
if (plane == AOM_PLANE_Y || plane == AOM_PLANE_U) {
#if CONFIG_TX_SKIP_FLAG_MODE_DEP_CTX
MB_MODE_INFO *const mbmi = xd->mi[0];
const int pred_mode_ctx =
(is_inter || mbmi->fsc_mode[xd->tree_type == CHROMA_PART]) ? 1 : 0;
all_zero = aom_read_symbol(
r, ec_ctx->txb_skip_cdf[pred_mode_ctx][txs_ctx][txb_skip_ctx], 2,
ACCT_INFO("all_zero", "plane_y_or_u"));
#else
all_zero = aom_read_symbol(r, ec_ctx->txb_skip_cdf[txs_ctx][txb_skip_ctx],
2, ACCT_INFO("all_zero", "plane_y_or_u"));
#endif // CONFIG_TX_SKIP_FLAG_MODE_DEP_CTX
} else {
txb_skip_ctx += (xd->eob_u_flag ? V_TXB_SKIP_CONTEXT_OFFSET : 0);
all_zero = aom_read_symbol(r, ec_ctx->v_txb_skip_cdf[txb_skip_ctx], 2,
ACCT_INFO("all_zero", "plane_v"));
}
#else
const int all_zero =
aom_read_symbol(r, ec_ctx->txb_skip_cdf[txs_ctx][txb_ctx->txb_skip_ctx],
2, ACCT_INFO("all_zero"));
#endif // CONFIG_CONTEXT_DERIVATION
#if CONFIG_INSPECTION
MB_MODE_INFO *const mbmi = xd->mi[0];
if (plane == 0) {
const int txk_type_idx =
av1_get_txk_type_index(mbmi->sb_type[0], blk_row, blk_col);
mbmi->tx_skip[txk_type_idx] = all_zero;
}
#endif // CONFIG_INSPECTION
#if CONFIG_CONTEXT_DERIVATION
if (plane == AOM_PLANE_U) {
xd->eob_u_flag = all_zero ? 0 : 1;
}
#endif // CONFIG_CONTEXT_DERIVATION
#if CONFIG_WAIP
#if !CONFIG_INSPECTION
MB_MODE_INFO *mbmi = xd->mi[0];
#endif // !CONFIG_INSPECTION
if (is_inter_block(mbmi, xd->tree_type)) {
#if CONFIG_NEW_TX_PARTITION
const int txb_idx = get_tx_partition_idx(mbmi, plane);
mbmi->is_wide_angle[plane > 0][txb_idx] = 0;
mbmi->mapped_intra_mode[plane > 0][txb_idx] = DC_PRED;
#else
mbmi->is_wide_angle[plane > 0] = 0;
mbmi->mapped_intra_mode[plane > 0] = DC_PRED;
#endif // CONFIG_NEW_TX_PARTITION
} else {
PREDICTION_MODE mode = (plane == PLANE_TYPE_Y ? mbmi->mode : mbmi->uv_mode);
const int angle_delta =
mbmi->angle_delta[plane != AOM_PLANE_Y] * ANGLE_STEP;
wide_angle_mapping(mbmi, angle_delta, tx_size, mode, plane);
}
#endif // CONFIG_WAIP
if (all_zero) {
*max_scan_line = 0;
if (plane == 0) {
xd->tx_type_map[blk_row * xd->tx_type_map_stride + blk_col] = DCT_DCT;
}
return 0;
}
decode_eob(dcb, r, plane, tx_size
#if CONFIG_PARAKIT_COLLECT_DATA
,
cm
#endif
);
av1_read_tx_type(cm, xd, blk_row, blk_col, tx_size, r, plane, *eob,
is_inter ? 0 : *eob);
if (plane == AOM_PLANE_U && is_cctx_allowed(cm, xd)) {
const int skip_cctx = is_inter ? 0 : (*eob == 1);
if (!all_zero && !skip_cctx) {
av1_read_cctx_type(cm, xd, blk_row, blk_col, tx_size, r);
} else {
int row_offset, col_offset;
get_chroma_mi_offsets(xd, &row_offset, &col_offset);
update_cctx_array(xd, blk_row, blk_col, row_offset, col_offset, tx_size,
CCTX_NONE);
}
}
return 1;
}
uint8_t av1_read_coeffs_txb_skip(const AV1_COMMON *const cm,
DecoderCodingBlock *dcb, aom_reader *const r,
const int blk_row, const int blk_col,
const int plane, const TX_SIZE tx_size) {
MACROBLOCKD *const xd = &dcb->xd;
MB_MODE_INFO *const mbmi = xd->mi[0];
FRAME_CONTEXT *const ec_ctx = xd->tile_ctx;
struct macroblockd_plane *const pd = &xd->plane[plane];
const PLANE_TYPE plane_type = get_plane_type(plane);
const int32_t max_value = (1 << (7 + xd->bd)) - 1;
const int32_t min_value = -(1 << (7 + xd->bd));
const int32_t *const dequant = pd->seg_dequant_QTX[mbmi->segment_id];
tran_low_t *const tcoeffs = dcb->dqcoeff_block[plane] + dcb->cb_offset[plane];
const int shift = av1_get_tx_scale(tx_size);
const int bwl = get_txb_bwl(tx_size);
const int width = get_txb_wide(tx_size);
const int height = get_txb_high(tx_size);
#if CONFIG_INSPECTION
tran_low_t *const tcoeffs_copy =
dcb->dqcoeff_block_copy[plane] + dcb->cb_offset[plane];
tran_low_t *const quant_coeffs =
dcb->qcoeff_block[plane] + dcb->cb_offset[plane];
tran_low_t *const dequant_values =
dcb->dequant_values[plane] + dcb->cb_offset[plane];
// For TX sizes > 32x32, all coeffs are zero except for top-left 32x32.
const int coeff_width = AOMMIN(width, 32);
const int coeff_height = AOMMIN(height, 32);
memset(tcoeffs_copy, 0, sizeof(tran_low_t) * coeff_width * coeff_height);
memset(quant_coeffs, 0, sizeof(tran_low_t) * coeff_width * coeff_height);
memset(dequant_values, 0, sizeof(tran_low_t) * coeff_width * coeff_height);
#endif // CONFIG_INSPECTION
int cul_level = 0;
int dc_val = 0;
uint8_t levels_buf[TX_PAD_2D];
uint8_t *const levels = set_levels(levels_buf, width);
int8_t signs_buf[TX_PAD_2D];
int8_t *const signs = set_signs(signs_buf, width);
eob_info *eob_data = dcb->eob_data[plane] + dcb->txb_offset[plane];
eob_data->max_scan_line = 0;
eob_data->eob = av1_get_max_eob(tx_size);
eob_info *bob_data = dcb->bob_data[plane] + dcb->txb_offset[plane];
bob_data->max_scan_line = 0;
const TX_TYPE tx_type =
av1_get_tx_type(xd, plane_type, blk_row, blk_col, tx_size,
is_reduced_tx_set_used(cm, plane_type));
const qm_val_t *iqmatrix =
av1_get_iqmatrix(&cm->quant_params, xd, plane, tx_size, tx_type);
#if CONFIG_INSPECTION
for (int c = 0; c < width * height; c++) {
dequant_values[c] = get_dqv(dequant, c, iqmatrix);
}
#endif // CONFIG_INSPECTION
const SCAN_ORDER *const scan_order = get_scan(tx_size, tx_type);
const int16_t *const scan = scan_order->scan;
const TX_SIZE txs_ctx = get_txsize_entropy_ctx(tx_size);
const int size_ctx = AOMMIN(txs_ctx, TX_16X16);
if (eob_data->eob > 1) {
memset(levels_buf, 0, sizeof(*levels_buf) * TX_PAD_2D);
memset(signs_buf, 0, sizeof(*signs_buf) * TX_PAD_2D);
base_fsc_cdf_arr base_cdf = ec_ctx->coeff_base_cdf_idtx[size_ctx];
br_cdf_arr br_cdf = ec_ctx->coeff_br_cdf_idtx[size_ctx];
const int bob = av1_get_max_eob(tx_size) - bob_data->eob;
{
const int pos = scan[bob];
const int coeff_ctx_bob = get_lower_levels_ctx_bob(bwl, height, bob);
const int nsymbs_bob = 3;
aom_cdf_prob *cdf_bob =
ec_ctx->coeff_base_bob_cdf[size_ctx][coeff_ctx_bob];
int level = aom_read_symbol(r, cdf_bob, nsymbs_bob,
ACCT_INFO("level", "cdf_bob")) +
1;
if (level > NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx_skip(levels, pos, bwl);
aom_cdf_prob *cdf = br_cdf[br_ctx];
level += read_low_range(r, cdf);
}
levels[get_padded_idx_left(pos, bwl)] = level;
}
read_coeffs_forward_2d(r, bob + 1, eob_data->eob - 1, scan, bwl, levels,
base_cdf, br_cdf);
}
const int bob = av1_get_max_eob(tx_size) - bob_data->eob;
#if CONFIG_COEFF_HR_ADAPTIVE
int hr_level_avg = 0;
#endif // CONFIG_COEFF_HR_ADAPTIVE
for (int c = bob; c < eob_data->eob; c++) {
const int pos = scan[c];
const int sign_idx = get_padded_idx_left(pos, bwl);
uint8_t sign;
tran_low_t level = levels[get_padded_idx_left(pos, bwl)];
if (level) {
eob_data->max_scan_line = AOMMAX(eob_data->max_scan_line, pos);
int idtx_sign_ctx = get_sign_ctx_skip(signs, levels, pos, bwl);
sign = aom_read_symbol(r, ec_ctx->idtx_sign_cdf[size_ctx][idtx_sign_ctx],
2, ACCT_INFO("sign"));
signs[sign_idx] = sign > 0 ? -1 : 1;
#if 0 /* !CONFIG_TCQ read_high_level() to use HR_ADAPTIVEK */
if (level >= MAX_BASE_BR_RANGE) {
#if CONFIG_COEFF_HR_ADAPTIVE
int hr_level = read_adaptive_hr(xd, r, hr_level_avg);
level += hr_level;
hr_level_avg = (hr_level + hr_level_avg) >> 1;
#else
level += read_exp_golomb(xd, r, 0);
#endif // CONFIG_COEFF_HR_ADAPTIVE
}
#else
level = read_high_range(xd, r, 0, level, 0
#if CONFIG_COEFF_HR_ADAPTIVE
,
&hr_level_avg
#endif
#if CONFIG_COEFF_BR_LF_UV_BYPASS
,
plane
#endif
);
#endif
if (c == 0) dc_val = sign ? -level : level;
// Bitmasking to clamp level to valid range:
// The valid range for 8/10/12 bit video is at most 14/16/18 bit
level &= 0xfffff;
cul_level += level;
tran_low_t dq_coeff;
// Bitmasking to clamp dq_coeff to valid range:
// The valid range for 8/10/12 bit video is at most 17/19/21 bits
const int64_t dq_coeff_hp =
(int64_t)level * get_dqv(dequant, scan[c], iqmatrix) & 0xffffff;
dq_coeff =
(tran_low_t)(ROUND_POWER_OF_TWO_64(dq_coeff_hp, QUANT_TABLE_BITS));
dq_coeff = dq_coeff >> shift;
if (sign) {
dq_coeff = -dq_coeff;
}
tcoeffs[pos] = clamp(dq_coeff, min_value, max_value);
#if CONFIG_INSPECTION
tcoeffs_copy[pos] = tcoeffs[pos];
quant_coeffs[pos] = sign ? -level : level;
#endif // CONFIG_INSPECTION
}
}
cul_level = AOMMIN(COEFF_CONTEXT_MASK, cul_level);
set_dc_sign(&cul_level, dc_val);
return cul_level;
}
// This function returns the partial absolute level of the coefficient
// with hidden parity.
static INLINE tran_low_t read_coeff_hidden(aom_reader *r, TX_CLASS tx_class,
const int16_t *scan, int bwl,
uint8_t *levels, int parity,
base_ph_cdf_arr base_cdf_ph
#if !CONFIG_COEFF_BR_PH_BYPASS
,
br_cdf_arr br_cdf_ph
#endif
) {
int q_index;
const int pos = scan[0];
int ctx_idx = get_base_ctx_ph(levels, pos, bwl, tx_class);
q_index = aom_read_symbol(r, base_cdf_ph[ctx_idx], 4, ACCT_INFO("q_index"));
#if !CONFIG_COEFF_BR_PH_BYPASS
if (q_index > NUM_BASE_LEVELS) {
ctx_idx = get_par_br_ctx(levels, pos, bwl, tx_class);
aom_cdf_prob *cdf_br = br_cdf_ph[ctx_idx];
q_index += read_low_range(r, cdf_br);
}
#endif
assert(q_index <= MAX_BASE_BR_RANGE);
uint8_t level = (q_index << 1) + parity;
levels[get_padded_idx(pos, bwl)] = level;
return level;
}
uint8_t av1_read_coeffs_txb(const AV1_COMMON *const cm, DecoderCodingBlock *dcb,
aom_reader *const r, const int blk_row,
const int blk_col, const int plane,
const TXB_CTX *const txb_ctx,
const TX_SIZE tx_size) {
MACROBLOCKD *const xd = &dcb->xd;
FRAME_CONTEXT *const ec_ctx = xd->tile_ctx;
const int32_t max_value = (1 << (7 + xd->bd)) - 1;
const int32_t min_value = -(1 << (7 + xd->bd));
const TX_SIZE txs_ctx = get_txsize_entropy_ctx(tx_size);
const PLANE_TYPE plane_type = get_plane_type(plane);
MB_MODE_INFO *const mbmi = xd->mi[0];
struct macroblockd_plane *const pd = &xd->plane[plane];
const int32_t *const dequant = pd->seg_dequant_QTX[mbmi->segment_id];
tran_low_t *const tcoeffs = dcb->dqcoeff_block[plane] + dcb->cb_offset[plane];
const int shift = av1_get_tx_scale(tx_size);
const int bwl = get_txb_bwl(tx_size);
const int width = get_txb_wide(tx_size);
const int height = get_txb_high(tx_size);
#if CONFIG_INSPECTION
tran_low_t *const tcoeffs_copy =
dcb->dqcoeff_block_copy[plane] + dcb->cb_offset[plane];
tran_low_t *const quant_coeffs =
dcb->qcoeff_block[plane] + dcb->cb_offset[plane];
tran_low_t *const dequant_values =
dcb->dequant_values[plane] + dcb->cb_offset[plane];
// For TX sizes > 32x32, all coeffs are zero except for top-left 32x32.
const int coeff_width = AOMMIN(width, 32);
const int coeff_height = AOMMIN(height, 32);
memset(tcoeffs_copy, 0, sizeof(tran_low_t) * coeff_width * coeff_height);
memset(quant_coeffs, 0, sizeof(tran_low_t) * coeff_width * coeff_height);
memset(dequant_values, 0, sizeof(tran_low_t) * coeff_width * coeff_height);
#endif // CONFIG_INSPECTION
int cul_level = 0;
int dc_val = 0;
uint8_t levels_buf[TX_PAD_2D];
uint8_t *const levels = set_levels(levels_buf, width);
eob_info *eob_data = dcb->eob_data[plane] + dcb->txb_offset[plane];
uint16_t *const eob = &(eob_data->eob);
uint16_t *const max_scan_line = &(eob_data->max_scan_line);
#if DEBUG_EXTQUANT
fprintf(cm->fDecCoeffLog,
"\nmi_row = %d, mi_col = %d, blk_row = %d,"
" blk_col = %d, plane = %d, tx_size = %d ",
xd->mi_row, xd->mi_col, blk_row, blk_col, plane, tx_size);
#endif
const TX_TYPE tx_type =
av1_get_tx_type(xd, plane_type, blk_row, blk_col, tx_size,
is_reduced_tx_set_used(cm, plane_type));
const TX_CLASS tx_class = tx_type_to_class[get_primary_tx_type(tx_type)];
const qm_val_t *iqmatrix =
av1_get_iqmatrix(&cm->quant_params, xd, plane, tx_size, tx_type);
#if CONFIG_INSPECTION
for (int c = 0; c < width * height; c++) {
dequant_values[c] = get_dqv(dequant, c, iqmatrix);
}
#endif // CONFIG_INSPECTION
const SCAN_ORDER *const scan_order = get_scan(tx_size, tx_type);
const int16_t *const scan = scan_order->scan;
// read sec_tx_type here
// Only y plane's sec_tx_type is transmitted
if ((plane == AOM_PLANE_Y) &&
(is_inter_block(mbmi, xd->tree_type)
? (*eob > 3 && cm->seq_params.enable_inter_ist)
: (*eob != 1 && cm->seq_params.enable_ist))) {
av1_read_sec_tx_type(cm, xd, blk_row, blk_col, tx_size, eob, r);
}
if (*eob > 1) {
memset(levels_buf, 0, sizeof(*levels_buf) * TX_PAD_2D);
}
#if DEBUG_EXTQUANT
fprintf(cm->fDecCoeffLog, "tx_type = %d, eob = %d\n", tx_type, *eob);
#endif
#if CONFIG_TCQ
int tcq_mode = tcq_enable(cm->features.tcq_mode, plane, tx_class);
int state = tcq_init_state(tcq_mode);
#endif // CONFIG_TCQ
{
// Read the non-zero coefficient with scan index eob-1
// TODO(angiebird): Put this into a function
const int c = *eob - 1;
const int pos = scan[c];
const int coeff_ctx = get_lower_levels_ctx_eob(bwl, height, c);
int level = 0;
const int row = pos >> bwl;
const int col = pos - (row << bwl);
int limits = get_lf_limits(row, col, tx_class, plane);
if (plane > 0) {
if (limits) {
aom_cdf_prob *cdf = ec_ctx->coeff_base_lf_eob_uv_cdf[coeff_ctx];
level +=
aom_read_symbol(r, cdf, LF_BASE_SYMBOLS - 1,
ACCT_INFO("level", "coeff_base_lf_eob_uv_cdf")) +
1;
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
if (level > LF_NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx_lf_eob_chroma(pos, tx_class);
cdf = ec_ctx->coeff_br_lf_uv_cdf[br_ctx];
level += read_low_range(r, cdf);
}
#endif
} else {
aom_cdf_prob *cdf = ec_ctx->coeff_base_eob_uv_cdf[coeff_ctx];
level += aom_read_symbol(r, cdf, 3,
ACCT_INFO("level", "coeff_base_eob_uv_cdf")) +
1;
if (level > NUM_BASE_LEVELS) {
const int br_ctx = 0; /* get_lf_ctx_eob */
cdf = ec_ctx->coeff_br_uv_cdf[br_ctx];
level += read_low_range(r, cdf);
}
}
} else {
if (limits) {
aom_cdf_prob *cdf = ec_ctx->coeff_base_lf_eob_cdf[txs_ctx][coeff_ctx];
level += aom_read_symbol(r, cdf, LF_BASE_SYMBOLS - 1,
ACCT_INFO("level", "coeff_base_lf_eob_cdf")) +
1;
if (level > LF_NUM_BASE_LEVELS) {
const int br_ctx = get_br_ctx_lf_eob(pos, tx_class);
cdf = ec_ctx->coeff_br_lf_cdf[br_ctx];
level += read_low_range(r, cdf);
}
} else {
aom_cdf_prob *cdf = ec_ctx->coeff_base_eob_cdf[txs_ctx][coeff_ctx];
level += aom_read_symbol(r, cdf, 3,
ACCT_INFO("level", "coeff_base_eob_cdf")) +
1;
if (level > NUM_BASE_LEVELS) {
const int br_ctx = 0; /* get_lf_ctx_eob */
cdf = ec_ctx->coeff_br_cdf[br_ctx];
level += read_low_range(r, cdf);
}
}
}
levels[get_padded_idx(pos, bwl)] = level;
#if CONFIG_TCQ
state = tcq_next_state(state, level);
#endif // CONFIG_TCQ
}
bool enable_parity_hiding =
cm->features.allow_parity_hiding && !xd->lossless[mbmi->segment_id] &&
plane == PLANE_TYPE_Y &&
ph_allowed_tx_types[get_primary_tx_type(tx_type)] && (*eob > PHTHRESH);
int num_nz = 0, sum_abs1 = 0;
bool is_hidden = false;
if (*eob > 1) {
base_lf_cdf_arr base_lf_cdf = ec_ctx->coeff_base_lf_cdf[txs_ctx];
br_cdf_arr br_lf_cdf = ec_ctx->coeff_br_lf_cdf;
base_cdf_arr base_cdf = ec_ctx->coeff_base_cdf[txs_ctx];
br_cdf_arr br_cdf = ec_ctx->coeff_br_cdf;
base_lf_cdf_arr base_lf_uv_cdf = ec_ctx->coeff_base_lf_uv_cdf;
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
br_cdf_arr br_lf_uv_cdf = ec_ctx->coeff_br_lf_uv_cdf;
#endif
base_cdf_arr base_uv_cdf = ec_ctx->coeff_base_uv_cdf;
br_cdf_arr br_uv_cdf = ec_ctx->coeff_br_uv_cdf;
if (tx_class == TX_CLASS_2D) {
read_coeffs_reverse_2d(r, 1, *eob - 2, scan, bwl, levels, base_lf_cdf,
br_lf_cdf, plane, base_cdf, br_cdf, base_lf_uv_cdf,
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
br_lf_uv_cdf,
#endif
base_uv_cdf, br_uv_cdf
#if CONFIG_TCQ
,
&state
#endif // CONFIG_TCQ
);
if (enable_parity_hiding) {
for (int si = *eob - 1; si > 0; --si) {
int pos = scan[si];
int level =
AOMMIN(levels[get_padded_idx(pos, bwl)], MAX_BASE_BR_RANGE);
if (level) {
++num_nz;
sum_abs1 += level;
}
}
is_hidden = num_nz >= PHTHRESH;
}
if (is_hidden) {
read_coeff_hidden(r, tx_class, scan, bwl, levels, (sum_abs1 & 1),
ec_ctx->coeff_base_ph_cdf
#if !CONFIG_COEFF_BR_PH_BYPASS
,
ec_ctx->coeff_br_ph_cdf
#endif
);
} else {
read_coeffs_reverse(r, tx_class, 0, 0, scan, bwl, levels, base_lf_cdf,
br_lf_cdf, plane, base_cdf, br_cdf, base_lf_uv_cdf,
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
br_lf_uv_cdf,
#endif
base_uv_cdf, br_uv_cdf
#if CONFIG_TCQ
,
&state
#endif // CONFIG_TCQ
);
}
} else {
read_coeffs_reverse(r, tx_class, 1, *eob - 2, scan, bwl, levels,
base_lf_cdf, br_lf_cdf, plane, base_cdf, br_cdf,
base_lf_uv_cdf,
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
br_lf_uv_cdf,
#endif
base_uv_cdf, br_uv_cdf
#if CONFIG_TCQ
,
&state
#endif // CONFIG_TCQ
);
if (enable_parity_hiding) {
for (int si = *eob - 1; si > 0; --si) {
int pos = scan[si];
int level =
AOMMIN(levels[get_padded_idx(pos, bwl)], MAX_BASE_BR_RANGE);
if (level) {
++num_nz;
sum_abs1 += level;
}
}
is_hidden = num_nz >= PHTHRESH;
}
if (is_hidden) {
read_coeff_hidden(r, tx_class, scan, bwl, levels, (sum_abs1 & 1),
ec_ctx->coeff_base_ph_cdf
#if !CONFIG_COEFF_BR_PH_BYPASS
,
ec_ctx->coeff_br_ph_cdf
#endif
);
} else {
read_coeffs_reverse(r, tx_class, 0, 0, scan, bwl, levels, base_lf_cdf,
br_lf_cdf, plane, base_cdf, br_cdf, base_lf_uv_cdf,
#if !CONFIG_COEFF_BR_LF_UV_BYPASS
br_lf_uv_cdf,
#endif
base_uv_cdf, br_uv_cdf
#if CONFIG_TCQ
,
&state
#endif // CONFIG_TCQ
);
}
}
}
#if CONFIG_COEFF_HR_ADAPTIVE
int hr_level_avg = 0;
#endif // CONFIG_COEFF_HR_ADAPTIVE
for (int c = *eob - 1; c >= 0; --c) {
const int pos = scan[c];
uint8_t sign;
tran_low_t level = levels[get_padded_idx(pos, bwl)];
const int tmp_sign_idx = pos;
#if CONFIG_CONTEXT_DERIVATION
if (plane == AOM_PLANE_U) {
xd->tmp_sign[pos] = 0;
}
#endif // CONFIG_CONTEXT_DERIVATION
if (level) {
*max_scan_line = AOMMAX(*max_scan_line, pos);
const int row = pos >> bwl;
const int col = pos - (row << bwl);
const bool dc_2dtx = (c == 0);
const bool dc_hor = (col == 0) && tx_class == TX_CLASS_HORIZ;
const bool dc_ver = (row == 0) && tx_class == TX_CLASS_VERT;
if (dc_2dtx || dc_hor || dc_ver) {
const int dc_sign_ctx = dc_2dtx ? txb_ctx->dc_sign_ctx : 0;
#if CONFIG_CONTEXT_DERIVATION
if (plane == AOM_PLANE_Y || plane == AOM_PLANE_U) {
#if CONFIG_CTX_BYPASS_DC_SIGN
#if CONFIG_CTX_BYPASS_CB_DC_SIGN
if (plane == AOM_PLANE_Y) {
sign = aom_read_symbol(
r,
ec_ctx->dc_sign_cdf[plane_type][is_hidden ? 1 : 0][dc_sign_ctx],
2, ACCT_INFO("sign", "dc_sign_cdf", "plane_y_or_u"));
} else
#endif
sign = aom_read_literal(
r, 1, ACCT_INFO("sign", "dc_sign_cdf", "plane_y_or_u"));
#else
sign = aom_read_symbol(
r,
ec_ctx->dc_sign_cdf[plane_type][is_hidden ? 1 : 0][dc_sign_ctx],
2, ACCT_INFO("sign", "dc_sign_cdf", "plane_y_or_u"));
#endif
} else {
#if CONFIG_BY_PASS_V_SIGN
sign = aom_read_literal(
r, 1, ACCT_INFO("sign", "v_dc_sign_cdf", "plane_v"));
#else
int32_t tmp_sign = 0;
if (c < xd->eob_u) tmp_sign = xd->tmp_sign[tmp_sign_idx];
sign =
aom_read_symbol(r, ec_ctx->v_dc_sign_cdf[tmp_sign][dc_sign_ctx],
2, ACCT_INFO("sign", "v_dc_sign_cdf", "plane_v"));
#endif
}
if (plane == AOM_PLANE_U) xd->tmp_sign[tmp_sign_idx] = (sign ? 2 : 1);
#else
sign = aom_read_symbol(r, ec_ctx->dc_sign_cdf[plane_type][dc_sign_ctx],
2, ACCT_INFO("sign", "dc_sign_cdf"));
#endif // CONFIG_CONTEXT_DERIVATION
} else {
#if CONFIG_CONTEXT_DERIVATION && !CONFIG_CTX_V_AC_SIGN
if (plane == AOM_PLANE_Y || plane == AOM_PLANE_U)
sign = aom_read_bit(r, ACCT_INFO("sign", "plane_y_or_u"));
else {
int32_t tmp_sign = 0;
if (c < xd->eob_u) tmp_sign = xd->tmp_sign[pos];
sign = aom_read_symbol(r, ec_ctx->v_ac_sign_cdf[tmp_sign], 2,
ACCT_INFO("sign", "v_ac_sign_cdf", "plane_v"));
}
if (plane == AOM_PLANE_U) xd->tmp_sign[pos] = (sign ? 2 : 1);
#else
sign = aom_read_bit(r, ACCT_INFO("sign"));
#endif // CONFIG_CONTEXT_DERIVATION && !CONFIG_CTX_V_AC_SIGN
}
if (is_hidden && c == 0) {
#if CONFIG_COEFF_BR_PH_BYPASS
if (level >= ((NUM_BASE_LEVELS + 1) << 1)) {
int hr_level = (read_adaptive_hr(xd, r, hr_level_avg >> 1) << 1);
level += hr_level;
hr_level_avg = (hr_level_avg + hr_level) >> 1;
}
#else
if (level >= (MAX_BASE_BR_RANGE << 1)) {
#if CONFIG_COEFF_HR_ADAPTIVE
int hr_level = (read_adaptive_hr(xd, r, hr_level_avg >> 1) << 1);
level += hr_level;
hr_level_avg = (hr_level_avg + hr_level) >> 1;
#else
level += (read_exp_golomb(xd, r, 0) << 1);
#endif // CONFIG_COEFF_HR_ADAPTIVE
}
#endif
} else {
int limits = get_lf_limits(row, col, tx_class, plane);
#if !CONFIG_TCQ /* read_high_range / hr_adap */
if (limits) {
if (level >= LF_MAX_BASE_BR_RANGE) {
#if CONFIG_COEFF_HR_ADAPTIVE
int hr_level = read_adaptive_hr(xd, r, hr_level_avg);
level += hr_level;
hr_level_avg = (hr_level_avg + hr_level) >> 1;
#else
level += read_exp_golomb(xd, r, 0);
#endif // CONFIG_COEFF_HR_ADAPTIVE
}
} else {
if (level >= MAX_BASE_BR_RANGE) {
#if CONFIG_COEFF_HR_ADAPTIVE
int hr_level = read_adaptive_hr(xd, r, hr_level_avg);
level += hr_level;
hr_level_avg = (hr_level_avg + hr_level) >> 1;
#else
level += read_exp_golomb(xd, r, 0);
#endif // CONFIG_COEFF_HR_ADAPTIVE
}
}
#else
level = read_high_range(xd, r, tcq_mode, level, limits
#if CONFIG_COEFF_HR_ADAPTIVE
,
&hr_level_avg
#endif
#if CONFIG_COEFF_BR_LF_UV_BYPASS
,
plane
#endif
);
#endif
}
if (c == 0) dc_val = sign ? -level : level;
// Bitmasking to clamp level to valid range:
// The valid range for 8/10/12 bit vdieo is at most 14/16/18 bit
level &= 0xfffff;
cul_level += level;
#if CONFIG_TCQ
if (!xd->lossless[mbmi->segment_id] && tcq_mode) {
tcoeffs[pos] = sign ? -level : level;
} else {
tran_low_t dq_coeff;
// Bitmasking to clamp dq_coeff to valid range:
// The valid range for 8/10/12 bit video is at most 17/19/21 bit
const int64_t dq_coeff_hp =
(int64_t)level * get_dqv(dequant, scan[c], iqmatrix) & 0xffffff;
dq_coeff =
(tran_low_t)(ROUND_POWER_OF_TWO_64(dq_coeff_hp, QUANT_TABLE_BITS));
dq_coeff = dq_coeff >> shift;
if (sign) {
dq_coeff = -dq_coeff;
}
tcoeffs[pos] = clamp(dq_coeff, min_value, max_value);
#if CONFIG_INSPECTION
tcoeffs_copy[pos] = tcoeffs[pos];
quant_coeffs[pos] = sign ? -level : level;
#endif // CONFIG_INSPECTION
}
#else
tran_low_t dq_coeff;
// Bitmasking to clamp dq_coeff to valid range:
// The valid range for 8/10/12 bit video is at most 17/19/21 bit
const int64_t dq_coeff_hp =
(int64_t)level * get_dqv(dequant, scan[c], iqmatrix) & 0xffffff;
dq_coeff =
(tran_low_t)(ROUND_POWER_OF_TWO_64(dq_coeff_hp, QUANT_TABLE_BITS));
dq_coeff = dq_coeff >> shift;
if (sign) {
dq_coeff = -dq_coeff;
}
tcoeffs[pos] = clamp(dq_coeff, min_value, max_value);
#if CONFIG_INSPECTION
tcoeffs_copy[pos] = tcoeffs[pos];
quant_coeffs[pos] = sign ? -level : level;
#endif // CONFIG_INSPECTION
#endif // CONFIG_TCQ
}
}
#if CONFIG_TCQ
if (!xd->lossless[mbmi->segment_id] && tcq_mode) {
state = tcq_init_state(tcq_mode);
for (int c = *eob - 1; c >= 0; --c) {
const int pos = scan[c];
int Qx = tcq_quant(state);
int level = abs(tcoeffs[pos]);
if (abs(tcoeffs[pos])) {
tran_low_t dq_coeff;
tran_low_t qIdx = AOMMAX(0, (abs(tcoeffs[pos]) << 1) - Qx);
// Bitmasking to clamp dq_coeff to valid range:
// The valid range for 8/10/12 bit video is at most 17/19/21 bit
int tempdqv = get_dqv(dequant, scan[c], iqmatrix);
const int64_t dq_coeff_hp = (int64_t)qIdx * tempdqv & 0xffffff;
dq_coeff =
(tran_low_t)(ROUND_POWER_OF_TWO_64(dq_coeff_hp, QUANT_TABLE_BITS));
dq_coeff = dq_coeff >> (shift + 1);
// dq_coeff = dq_coeff >> (shift);
// dq_coeff = (tran_low_t)ROUND_POWER_OF_TWO_64((tran_high_t)qIdx *
// get_dqv(dequant, scan[c], iqmatrix), QUANT_TABLE_BITS) >> (shift +
// 1);
if (tcoeffs[pos] < 0) {
dq_coeff = -dq_coeff;
}
tcoeffs[pos] = clamp(dq_coeff, min_value, max_value);
}
// state transition
state = tcq_next_state(state, level);
}
}
#endif // CONFIG_TCQ
#if DEBUG_EXTQUANT
for (int c = 0; c < tx_size_wide[tx_size] * tx_size_high[tx_size]; c++) {
fprintf(cm->fDecCoeffLog, "%d ", tcoeffs[c]);
}
fprintf(cm->fDecCoeffLog, "\n\n");
#endif
cul_level = AOMMIN(COEFF_CONTEXT_MASK, cul_level);
// DC value
set_dc_sign(&cul_level, dc_val);
return cul_level;
}
void av1_read_coeffs_txb_facade(const AV1_COMMON *const cm,
DecoderCodingBlock *dcb, aom_reader *const r,
const int plane, const int row, const int col,
const TX_SIZE tx_size) {
#if TXCOEFF_TIMER
struct aom_usec_timer timer;
aom_usec_timer_start(&timer);
#endif
MACROBLOCKD *const xd = &dcb->xd;
MB_MODE_INFO *const mbmi = xd->mi[0];
struct macroblockd_plane *const pd = &xd->plane[plane];
const BLOCK_SIZE plane_bsize = get_mb_plane_block_size(
xd, mbmi, plane, pd->subsampling_x, pd->subsampling_y);
TXB_CTX txb_ctx;
get_txb_ctx(plane_bsize, tx_size, plane, pd->above_entropy_context + col,
pd->left_entropy_context + row, &txb_ctx,
mbmi->fsc_mode[xd->tree_type == CHROMA_PART]);
const uint8_t decode_rest =
av1_read_sig_txtype(cm, dcb, r, row, col, plane, &txb_ctx, tx_size);
const PLANE_TYPE plane_type = get_plane_type(plane);
const TX_TYPE tx_type =
av1_get_tx_type(xd, plane_type, row, col, tx_size,
is_reduced_tx_set_used(cm, plane_type));
const int is_inter = is_inter_block(mbmi, xd->tree_type);
uint8_t cul_level = 0;
if (decode_rest) {
if ((mbmi->fsc_mode[xd->tree_type == CHROMA_PART] &&
get_primary_tx_type(tx_type) == IDTX && plane == PLANE_TYPE_Y) ||
use_inter_fsc(cm, plane, tx_type, is_inter)) {
cul_level =
av1_read_coeffs_txb_skip(cm, dcb, r, row, col, plane, tx_size);
} else {
cul_level =
av1_read_coeffs_txb(cm, dcb, r, row, col, plane, &txb_ctx, tx_size);
}
} else {
av1_update_txk_skip_array(cm, xd->mi_row, xd->mi_col, xd->tree_type,
&mbmi->chroma_ref_info, plane, row, col, tx_size);
}
av1_set_entropy_contexts(xd, pd, plane, plane_bsize, tx_size, cul_level, col,
row);
if (is_inter_block(mbmi, xd->tree_type) && (plane == 0)) {
const TX_TYPE tx_type_inter =
av1_get_tx_type(xd, plane_type, row, col, tx_size,
is_reduced_tx_set_used(cm, plane_type));
update_txk_array(xd, row, col, tx_size, tx_type_inter);
}
#if TXCOEFF_TIMER
aom_usec_timer_mark(&timer);
const int64_t elapsed_time = aom_usec_timer_elapsed(&timer);
cm->txcoeff_timer += elapsed_time;
++cm->txb_count;
#endif
}