[rdoq] improve the cost calculations and clean up unused code

2024-12-18 11:14:05 +00:00 · 2021-02-26 16:41:54 +02:00 · 2021-02-26 16:41:54 +02:00 · 6544c25daf
parent d6379c02e0
commit 6544c25daf
4 changed files with 30 additions and 120 deletions
--- a/src/context.c
+++ b/src/context.c
@ -502,76 +502,6 @@ uint32_t kvz_context_get_sig_coeff_group( uint32_t *sig_coeff_group_flag,
 }
 /**
 * \brief Pattern decision for context derivation process of significant_coeff_flag
 * \param sig_coeff_group_flag pointer to prior coded significant coeff group
 * \param pos_x column of current coefficient group
 * \param pos_y row of current coefficient group
 * \param width width of the block
 * \returns pattern for current coefficient group
 */
 int32_t kvz_context_calc_pattern_sig_ctx(const uint32_t *sig_coeff_group_flag, uint32_t pos_x, uint32_t pos_y, int32_t width)
 {
  uint32_t sigRight = 0;
  uint32_t sigLower = 0;
  if (width == 4) return -1;
  width >>= 2;
  if (pos_x < (uint32_t)width - 1) sigRight = (sig_coeff_group_flag[pos_y * width + pos_x + 1] != 0);
  if (pos_y < (uint32_t)width - 1) sigLower = (sig_coeff_group_flag[(pos_y  + 1 ) * width + pos_x] != 0);
  return sigRight + (sigLower<<1);
 }
 /**
 * \brief Context derivation process of coeff_abs_significant_flag
 * \param pattern_sig_ctx pattern for current coefficient group
 * \param scan_idx pixel scan type in use
 * \param pos_x column of current scan position
 * \param pos_y row of current scan position
 * \param block_type log2 value of block size if square block, or 4 otherwise
 * \param width width of the block
 * \param texture_type texture type (TEXT_LUMA...)
 * \returns ctx_inc for current scan position
 */
 int32_t kvz_context_get_sig_ctx_inc(int32_t pattern_sig_ctx, uint32_t scan_idx, int32_t pos_x,
                                int32_t pos_y, int32_t block_type, int8_t texture_type)
 {
  const int32_t ctx_ind_map[16] =
  {
    0, 1, 4, 5,
    2, 3, 4, 5,
    6, 6, 8, 8,
    7, 7, 8, 8
  };
  int32_t cnt,offset,pos_x_in_subset,pos_y_in_subset;
  if (pos_x + pos_y == 0) return 0;
  if (block_type == 2) return ctx_ind_map[4 * pos_y + pos_x];
  offset = (block_type == 3) ? ((scan_idx == SCAN_DIAG) ? 9 : 15) : ((texture_type == 0) ? 21 : 12);
  pos_x_in_subset = pos_x - ((pos_x>>2)<<2);
  pos_y_in_subset = pos_y - ((pos_y>>2)<<2);
  if (pattern_sig_ctx == 0) {
    cnt = (pos_x_in_subset + pos_y_in_subset <= 2) ? ((pos_x_in_subset + pos_y_in_subset==0) ? 2 : 1) : 0;
  } else if (pattern_sig_ctx==1) {
    cnt = (pos_y_in_subset <= 1) ? ((pos_y_in_subset == 0) ? 2 : 1) : 0;
  } else if (pattern_sig_ctx==2) {
    cnt = (pos_x_in_subset <= 1) ? ((pos_x_in_subset == 0) ? 2 : 1) : 0;
  } else {
    cnt = 2;
  }
  return (( texture_type == 0 && ((pos_x>>2) + (pos_y>>2)) > 0 ) ? 3 : 0) + offset + cnt;
 }
 /**
 * \brief Context derivation process of coeff_abs_significant_flag
 * \param coeff     pointer to the current coefficient
--- a/src/context.h
+++ b/src/context.h
@ -36,14 +36,9 @@ void kvz_ctx_init(cabac_ctx_t* ctx, int32_t qp, int32_t init_value, uint8_t rate
 void kvz_init_contexts(encoder_state_t *state, int8_t QP, int8_t slice);
 void kvz_context_copy(encoder_state_t * target_state, const encoder_state_t * source_state);
 int32_t kvz_context_calc_pattern_sig_ctx( const uint32_t *sig_coeff_group_flag, uint32_t pos_x, uint32_t pos_y, int32_t width);
 uint32_t kvz_context_get_sig_coeff_group( uint32_t *sig_coeff_group_flag,uint32_t pos_x, uint32_t pos_y,int32_t width);
 int32_t kvz_context_get_sig_ctx_inc(int32_t pattern_sig_ctx,uint32_t scan_idx,int32_t pos_x,
                                int32_t pos_y,int32_t block_type, int8_t texture_type);
 uint32_t kvz_context_get_sig_ctx_idx_abs(const coeff_t* coeff, int32_t pos_x, int32_t pos_y,
                                         uint32_t height, uint32_t width, int8_t type, 
                                         int32_t* temp_diag, int32_t* temp_sum);
--- a/src/rdo.c
+++ b/src/rdo.c
@ -305,13 +305,12 @@ INLINE int32_t kvz_get_ic_rate(encoder_state_t * const state,
                    uint16_t ctx_num_gt2,
                    uint16_t ctx_num_par,
                    uint16_t abs_go_rice,
-                    uint32_t c1_idx,
+                    uint32_t reg_bins,
                    uint32_t c2_idx,
                    int8_t type)
 {
  cabac_data_t * const cabac = &state->cabac;
  int32_t rate = 1 << CTX_FRAC_BITS; // cost of sign bit
-  uint32_t base_level  =  (c1_idx < C1FLAG_NUMBER)? (2 + (c2_idx < C2FLAG_NUMBER)) : 1;
+  uint32_t base_level  =  4;
  cabac_ctx_t *base_par_ctx = (type == 0) ? &(cabac->ctx.cu_parity_flag_model_luma[0]) : &(cabac->ctx.cu_parity_flag_model_chroma[0]);
  cabac_ctx_t *base_gt1_ctx = (type == 0) ? &(cabac->ctx.cu_gtx_flag_model_luma[0][0]) : &(cabac->ctx.cu_gtx_flag_model_luma[0][0]);
  cabac_ctx_t* base_gt2_ctx = (type == 0) ? &(cabac->ctx.cu_gtx_flag_model_luma[1][0]) : &(cabac->ctx.cu_gtx_flag_model_luma[1][0]);
@ -383,7 +382,7 @@ INLINE uint32_t kvz_get_coded_level ( encoder_state_t * const state, double *cod
                           int32_t level_double, uint32_t max_abs_level,
                           uint16_t ctx_num_sig, uint16_t ctx_num_gt1, uint16_t ctx_num_gt2, uint16_t ctx_num_par,
                           uint16_t abs_go_rice,
-                           uint32_t c1_idx, uint32_t c2_idx,
+                           uint32_t reg_bins,
                           int32_t q_bits,double temp, int8_t last, int8_t type)
 {
  cabac_data_t * const cabac = &state->cabac;
@ -410,7 +409,7 @@ INLINE uint32_t kvz_get_coded_level ( encoder_state_t * const state, double *cod
    double err       = (double)(level_double - ( abs_level * (1 << q_bits) ) );
    double cur_cost  = err * err * temp + state->lambda *
                       kvz_get_ic_rate( state, abs_level, ctx_num_gt1, ctx_num_gt2, ctx_num_par,
-                                    abs_go_rice, c1_idx, c2_idx, type);
+                                    abs_go_rice, reg_bins, type);
    cur_cost        += cur_cost_sig;
    if( cur_cost < *coded_cost ) {
@ -640,6 +639,7 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
  uint32_t log2_tr_size      = kvz_g_convert_to_bit[ width ] + 2;
  int32_t  transform_shift   = MAX_TR_DYNAMIC_RANGE - encoder->bitdepth - log2_tr_size;  // Represents scaling through forward transform
  uint16_t go_rice_param     = 0;
  const uint32_t reg_bins = (width * height * 28) >> 4;
  const uint32_t log2_block_size   = kvz_g_convert_to_bit[ width ] + 2;
  int32_t  scalinglist_type= (block_type == CU_INTRA ? 0 : 3) + (int8_t)("\0\3\1\2"[type]);
@ -671,12 +671,10 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
  uint32_t sig_coeffgroup_flag[ 64 ];
  uint16_t    ctx_set    = 0;
  int16_t     c1         = 1;
  int16_t     c2         = 0;
  double      base_cost  = 0;
  int32_t temp_diag = -1;
  int32_t temp_sum = -1;
  uint32_t    c1_idx     = 0;
  uint32_t    c2_idx     = 0;
  int32_t     base_level;
  const uint32_t *scan = kvz_g_sig_last_scan[ scan_mode ][ log2_block_size - 1 ];
@ -722,7 +720,6 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
      if (max_abs_level > 0) {
        last_scanpos    = scanpos;        
        ctx_set         = (scanpos > 0 && type == 0) ? 2 : 0;
        cg_last_scanpos = cg_scanpos;
        sh_rates.sig_coeff_inc[blkpos] = 0;
        break;
@ -736,6 +733,7 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
    return;
  }
  for (; cg_scanpos >= 0; cg_scanpos--) cost_coeffgroup_sig[cg_scanpos] = 0;
  int32_t last_x_bits[32], last_y_bits[32];
@ -746,9 +744,6 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
    uint32_t cg_pos_y   = cg_blkpos / num_blk_side;
    uint32_t cg_pos_x   = cg_blkpos - (cg_pos_y * num_blk_side);
    int32_t pattern_sig_ctx = kvz_context_calc_pattern_sig_ctx(sig_coeffgroup_flag,
                                                           cg_pos_x, cg_pos_y, width);
    FILL(rd_stats, 0);
    for (int32_t scanpos_in_cg = cg_size - 1; scanpos_in_cg >= 0; scanpos_in_cg--)  {
      int32_t  scanpos = cg_scanpos*cg_size + scanpos_in_cg;
@ -765,22 +760,27 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
      block_uncoded_cost      += cost_coeff0[ scanpos ];
      //===== coefficient level estimation =====
      int32_t  level;
-      uint16_t  gt1_ctx = 4 * ctx_set + c1;
+
-      uint16_t  gt2_ctx = 4 * ctx_set + c1;
+      uint16_t  gt1_ctx = ctx_set;
-      uint16_t  par_ctx = ctx_set + c2;
+      uint16_t  gt2_ctx = ctx_set;
      uint16_t  par_ctx = ctx_set;
      if( scanpos == last_scanpos ) {
        level            = kvz_get_coded_level(state, &cost_coeff[ scanpos ], &cost_coeff0[ scanpos ], &cost_sig[ scanpos ],
                                             level_double, max_abs_level, 0, gt1_ctx, gt2_ctx, par_ctx, go_rice_param,
-                                             c1_idx, c2_idx, q_bits, temp, 1, type );
+                                             reg_bins, q_bits, temp, 1, type );
      } else {
        uint32_t  pos_y    = blkpos >> log2_block_size;
        uint32_t  pos_x    = blkpos - ( pos_y << log2_block_size );
-        uint16_t  ctx_sig  = (uint16_t)kvz_context_get_sig_ctx_inc(pattern_sig_ctx, scan_mode, pos_x, pos_y,
+        uint16_t ctx_sig = kvz_context_get_sig_ctx_idx_abs(coef, pos_x, pos_y, width, height, type, &temp_diag, &temp_sum);
-                                                     log2_block_size, type);
+        if (temp_diag != -1) {
          ctx_set = (MIN(temp_sum, 4) + 1) + (!temp_diag ? ((type == 0) ? 15 : 5) : (type == 0) ? temp_diag < 3 ? 10 : (temp_diag < 10 ? 5 : 0) : 0);
        }
        else ctx_set = 0;
        level              = kvz_get_coded_level(state, &cost_coeff[ scanpos ], &cost_coeff0[ scanpos ], &cost_sig[ scanpos ],
                                             level_double, max_abs_level, ctx_sig, gt1_ctx, gt2_ctx, par_ctx, go_rice_param,
-                                             c1_idx, c2_idx, q_bits, temp, 0, type );
+                                             reg_bins, q_bits, temp, 0, type );
        if (encoder->cfg.signhide_enable) {
          int greater_than_zero = CTX_ENTROPY_BITS(&baseCtx[ctx_sig], 1);
          int zero = CTX_ENTROPY_BITS(&baseCtx[ctx_sig], 0);
@ -788,12 +788,14 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
        }
      }
      if (encoder->cfg.signhide_enable) {
        sh_rates.quant_delta[blkpos] = (level_double - level * (1 << q_bits)) >> (q_bits - 8);
        if (level > 0) {
-          int32_t rate_now  = kvz_get_ic_rate(state, level, gt1_ctx, gt2_ctx, par_ctx, go_rice_param, c1_idx, c2_idx, type);
+          int32_t rate_now  = kvz_get_ic_rate(state, level, gt1_ctx, gt2_ctx, par_ctx, go_rice_param, reg_bins, type);
-          int32_t rate_up   = kvz_get_ic_rate(state, level + 1, gt1_ctx, gt2_ctx, par_ctx, go_rice_param, c1_idx, c2_idx, type);
+          int32_t rate_up   = kvz_get_ic_rate(state, level + 1, gt1_ctx, gt2_ctx, par_ctx, go_rice_param, reg_bins, type);
-          int32_t rate_down = kvz_get_ic_rate(state, level - 1, gt1_ctx, gt2_ctx, par_ctx, go_rice_param, c1_idx, c2_idx, type);
+          int32_t rate_down = kvz_get_ic_rate(state, level - 1, gt1_ctx, gt2_ctx, par_ctx, go_rice_param, reg_bins, type);
          sh_rates.inc[blkpos] = rate_up - rate_now;
          sh_rates.dec[blkpos] = rate_down - rate_now;
        } else { // level == 0
@ -803,35 +805,18 @@ void kvz_rdoq(encoder_state_t * const state, coeff_t *coef, coeff_t *dest_coeff,
      dest_coeff[blkpos] = (coeff_t)level;
      base_cost         += cost_coeff[scanpos];
-      base_level = (c1_idx < C1FLAG_NUMBER) ? (2 + (c2_idx < C2FLAG_NUMBER)) : 1;
+      base_level = 4;
      if (level >= base_level) {
        if(level  > 3*(1<<go_rice_param)) {
          go_rice_param = MIN(go_rice_param + 1, 4);
        }
      }
      if (level >= 1) c1_idx ++;
      //===== update bin model =====
      if (level > 1) {
        c1 = 0;
        c2 += (c2 < 2);
        c2_idx ++;
      } else if( (c1 < 3) && (c1 > 0) && level) {
        c1++;
      }
      //===== context set update =====
      if ((scanpos % SCAN_SET_SIZE == 0) && scanpos > 0) {
-        c2                = 0;
+
        go_rice_param     = 0;
        c1_idx   = 0;
        c2_idx   = 0;
        ctx_set = (scanpos == SCAN_SET_SIZE || type != 0) ? 0 : 2;
        if( c1 == 0 ) {
          ctx_set++;
        }
        c1 = 1;
      }
      rd_stats.sig_cost += cost_sig[scanpos];
--- a/src/rdo.h
+++ b/src/rdo.h
@ -46,12 +46,12 @@ uint32_t kvz_get_coeff_cost(const encoder_state_t * const state,
                            int8_t scan_mode);
 int32_t kvz_get_ic_rate(encoder_state_t *state, uint32_t abs_level, uint16_t ctx_num_gt1, uint16_t ctx_num_gt2, uint16_t ctx_num_par,
-                    uint16_t abs_go_rice, uint32_t c1_idx, uint32_t c2_idx, int8_t type);
+                    uint16_t abs_go_rice, uint32_t reg_bins, int8_t type);
 uint32_t kvz_get_coded_level(encoder_state_t * state, double* coded_cost, double* coded_cost0, double* coded_cost_sig,
                         int32_t level_double, uint32_t max_abs_level,
                         uint16_t ctx_num_sig, uint16_t ctx_num_gt1, uint16_t ctx_num_gt2, uint16_t ctx_num_par,
                         uint16_t abs_go_rice,
-                         uint32_t c1_idx, uint32_t c2_idx,
+                         uint32_t reg_bins,
                         int32_t q_bits,double temp, int8_t last, int8_t type);
 kvz_mvd_cost_func kvz_calc_mvd_cost_cabac;