md_highloss.c

压缩JM12.3d的完整的全部C语言的代码文档,用于嵌入式系统的压缩编解码

/*!
 ***************************************************************************
 * \file md_highloss.c
 *
 * \brief
 *    Main macroblock mode decision functions and helpers
 *
 **************************************************************************
 */

#include <stdlib.h>
#include <math.h>
#include <assert.h>
#include <limits.h>
#include <float.h>
#include <memory.h>
#include <string.h>

#include "global.h"
#include "rdopt_coding_state.h"
#include "mb_access.h"
#include "intrarefresh.h"
#include "image.h"
#include "transform8x8.h"
#include "ratectl.h"
#include "mode_decision.h"
#include "fmo.h"
#include "me_umhex.h"
#include "me_umhexsmp.h"
#include "macroblock.h"

/*!
*************************************************************************************
* \brief
*    Mode Decision for a macroblock with error resilience
*************************************************************************************
*/
void encode_one_macroblock_highloss ()
{
  int         max_index = 9;
  int         rerun, block, index, mode, i, j, ctr16x16;
  char        best_pdir;
  RD_PARAMS   enc_mb;
  double      min_rdcost = 1e30;
  double      min_dcost = 1e30;
  char        best_ref[2] = {0, -1};
  int         bmcost[5] = {INT_MAX};
  int         cost=0;
  int         min_cost = INT_MAX, cost_direct=0, have_direct=0, i16mode=0;
  int         intra1 = 0;
  int         cost8x8_direct = 0;
  int         mb_available_up;
  int         mb_available_left;
  int         mb_available_up_left;

  short       islice      = (short) (img->type==I_SLICE);
  short       bslice      = (short) (img->type==B_SLICE);
  short       pslice      = (short) ((img->type==P_SLICE) || (img->type==SP_SLICE));
  short       intra       = (short) (islice || (pslice && img->mb_y==img->mb_y_upd && img->mb_y_upd!=img->mb_y_intra));
  int         lambda_mf[3];
  short       runs        = (short) (input->RestrictRef==1 && (pslice  || (bslice && img->nal_reference_idc>0)) ? 2 : 1);

  Macroblock* currMB      = &img->mb_data[img->current_mb_nr];
  int         prev_mb_nr  = FmoGetPreviousMBNr(img->current_mb_nr);
  Macroblock* prevMB      = (prev_mb_nr >= 0) ? &img->mb_data[prev_mb_nr]:NULL ;

  short   min_chroma_pred_mode, max_chroma_pred_mode;

  short inter_skip = 0;
  double min_rate = 0;

  if(input->SearchMode == UM_HEX)
  {
    UMHEX_decide_intrabk_SAD();
  }
  else if (input->SearchMode == UM_HEX_SIMPLE)
  {
    smpUMHEX_decide_intrabk_SAD();
  }

  intra |= RandomIntra (img->current_mb_nr);    // Forced Pseudo-Random Intra

  //===== Setup Macroblock encoding parameters =====
  init_enc_mb_params(currMB, &enc_mb, intra, bslice);

  // Perform multiple encodings if rdopt with losses is enabled
  for (rerun=0; rerun<runs; rerun++)
  {
    if (runs==2)
      input->rdopt= (rerun==0) ? 1 : 3;

    // reset chroma intra predictor to default
    currMB->c_ipred_mode = DC_PRED_8;

    //=====   S T O R E   C O D I N G   S T A T E   =====
    //---------------------------------------------------
    store_coding_state (cs_cm);

    if (!intra)
    {
      //===== set direct motion vectors =====
      best_mode = 1;
      if (bslice)
      {
        Get_Direct_Motion_Vectors ();
      }

      if (input->CtxAdptLagrangeMult == 1)
      {
        get_initial_mb16x16_cost();
      }

      //===== MOTION ESTIMATION FOR 16x16, 16x8, 8x16 BLOCKS =====
      for (min_cost=INT_MAX, mode=1; mode<4; mode++)
      {
        bi_pred_me = 0;
        img->bi_pred_me[mode]=0;
        if (enc_mb.valid[mode])
        {
          for (cost=0, block=0; block<(mode==1?1:2); block++)
          {
            update_lambda_costs(&enc_mb, lambda_mf);
            PartitionMotionSearch (mode, block, lambda_mf);

            //--- set 4x4 block indizes (for getting MV) ---
            j = (block==1 && mode==2 ? 2 : 0);
            i = (block==1 && mode==3 ? 2 : 0);

            //--- get cost and reference frame for List 0 prediction ---
            bmcost[LIST_0] = INT_MAX;
            list_prediction_cost(LIST_0, block, mode, enc_mb, bmcost, best_ref);

            if (bslice)
            {
              //--- get cost and reference frame for List 1 prediction ---
              bmcost[LIST_1] = INT_MAX;
              list_prediction_cost(LIST_1, block, mode, enc_mb, bmcost, best_ref);

              // Compute bipredictive cost between best list 0 and best list 1 references
              list_prediction_cost(BI_PRED, block, mode, enc_mb, bmcost, best_ref);

              // Finally, if mode 16x16, compute cost for bipredictive ME vectore
              if (input->BiPredMotionEstimation && mode == 1)
              {
                list_prediction_cost(BI_PRED_L0, block, mode, enc_mb, bmcost, 0);
                list_prediction_cost(BI_PRED_L1, block, mode, enc_mb, bmcost, 0);
              }
              else
              {
                bmcost[BI_PRED_L0] = INT_MAX;
                bmcost[BI_PRED_L1] = INT_MAX;
              }

              // Determine prediction list based on mode cost
              determine_prediction_list(mode, bmcost, best_ref, &best_pdir, &cost, &bi_pred_me);
            }
            else // if (bslice)
            {
              best_pdir  = 0;
              cost      += bmcost[LIST_0];
            }

            assign_enc_picture_params(mode, best_pdir, block, enc_mb.list_offset[LIST_0], best_ref[LIST_0], best_ref[LIST_1], bslice);

            //----- set reference frame and direction parameters -----
            if (mode==3)
            {
              best8x8l0ref [3][block  ] = best8x8l0ref [3][  block+2] = best_ref[LIST_0];
              best8x8pdir  [3][block  ] = best8x8pdir  [3][  block+2] = best_pdir;
              best8x8l1ref [3][block  ] = best8x8l1ref [3][  block+2] = best_ref[LIST_1];
            }
            else if (mode==2)
            {
              best8x8l0ref [2][2*block] = best8x8l0ref [2][2*block+1] = best_ref[LIST_0];
              best8x8pdir  [2][2*block] = best8x8pdir  [2][2*block+1] = best_pdir;
              best8x8l1ref [2][2*block] = best8x8l1ref [2][2*block+1] = best_ref[LIST_1];
            }
            else
            {
              memset(&best8x8l0ref [1][0], best_ref[LIST_0], 4 * sizeof(char));
              memset(&best8x8l1ref [1][0], best_ref[LIST_1], 4 * sizeof(char));
              best8x8pdir  [1][0] = best8x8pdir  [1][1] = best8x8pdir  [1][2] = best8x8pdir  [1][3] = best_pdir;
            }

            //--- set reference frames and motion vectors ---
            if (mode>1 && block==0)
              SetRefAndMotionVectors (block, mode, best_pdir, best_ref[LIST_0], best_ref[LIST_1]);
          } // for (block=0; block<(mode==1?1:2); block++)

          if (cost < min_cost)
          {
            best_mode = (short) mode;
            min_cost  = cost;
            if (input->CtxAdptLagrangeMult == 1)
            {
              adjust_mb16x16_cost(cost);
            }
          }
        } // if (enc_mb.valid[mode])
      } // for (mode=1; mode<4; mode++)

    if (enc_mb.valid[P8x8])
      {
        giRDOpt_B8OnlyFlag = 1;

        tr8x8.cost8x8 = INT_MAX;
        tr4x4.cost8x8 = INT_MAX;
        //===== store coding state of macroblock =====
        store_coding_state (cs_mb);

        currMB->all_blk_8x8 = -1;

        if (input->Transform8x8Mode)
        {
          tr8x8.cost8x8 = 0;
          //===========================================================
          // Check 8x8 partition with transform size 8x8
          //===========================================================
          //=====  LOOP OVER 8x8 SUB-PARTITIONS  (Motion Estimation & Mode Decision) =====
          for (cost_direct=cbp8x8=cbp_blk8x8=cnt_nonz_8x8=0, block=0; block<4; block++)
          {
            submacroblock_mode_decision(enc_mb, &tr8x8, currMB, cofAC_8x8ts[block],
              &have_direct, bslice, block, &cost_direct, &cost, &cost8x8_direct, 1);
            best8x8mode       [block] = tr8x8.part8x8mode [block];
            best8x8pdir [P8x8][block] = tr8x8.part8x8pdir [block];
            best8x8l0ref[P8x8][block] = tr8x8.part8x8l0ref[block];
            best8x8l1ref[P8x8][block] = tr8x8.part8x8l1ref[block];
          }

          // following params could be added in RD_8x8DATA structure