macroblock.c

G729、h263、h264、MPEG4四种最流行的音频和视频标准的压缩和解压算法的源代码.rar

/*!
 *************************************************************************************
 * \file macroblock.c
 *
 * \brief
 *    Process one macroblock
 *
 * \author
 *    Main contributors (see contributors.h for copyright, address and affiliation details)
 *    - Inge Lille-Lang鴜               <inge.lille-langoy@telenor.com>
 *    - Rickard Sjoberg                 <rickard.sjoberg@era.ericsson.se>
 *    - Jani Lainema                    <jani.lainema@nokia.com>
 *    - Sebastian Purreiter             <sebastian.purreiter@mch.siemens.de>
 *    - Detlev Marpe                    <marpe@hhi.de>
 *    - Thomas Wedi                     <wedi@tnt.uni-hannover.de>
 *    - Ragip Kurceren                  <ragip.kurceren@nokia.com>
 *************************************************************************************
 */
#include "contributors.h"

#include <math.h>
#include <stdlib.h>
#include <assert.h>

#include "elements.h"
#include "macroblock.h"
#include "refbuf.h"
#include "fmo.h"
#include "vlc.h"
#include "image.h"
#include "mb_access.h"
#include "ratectl.h"              // head file for rate control
#include "cabac.h"

//Rate control
int predict_error,dq;
extern int DELTA_QP,DELTA_QP2;
extern int QP,QP2;

 /*!
 ************************************************************************
 * \brief
 *    updates the coordinates for the next macroblock to be processed
 *
 * \param mb_addr
 *    MB address in scan order
 ************************************************************************
 */

void set_MB_parameters (int mb_addr)
{
  img->current_mb_nr = mb_addr;
  
  get_mb_block_pos(mb_addr, &img->mb_x, &img->mb_y);
  
  img->block_x = img->mb_x << 2;
  img->block_y = img->mb_y << 2;

  img->pix_x   = img->block_x << 2;
  img->pix_y   = img->block_y << 2;

  img->opix_x   = img->pix_x;

  if (img->MbaffFrameFlag)
  {
    if (img->mb_data[mb_addr].mb_field)
    {

      imgY_org  = (mb_addr % 2) ? imgY_org_bot  : imgY_org_top;
      imgUV_org = (mb_addr % 2) ? imgUV_org_bot : imgUV_org_top;
      img->opix_y   = (img->mb_y >> 1 ) << 4;
    }
    else
    {
      imgY_org  = imgY_org_frm;
      imgUV_org = imgUV_org_frm;
      img->opix_y   = img->block_y << 2;
    }
  }
  else
  {
    img->opix_y   = img->block_y << 2;
  }

  img->pix_c_x = img->pix_x >> 1;
  img->pix_c_y = img->pix_y >> 1;

  img->opix_c_x = img->opix_x >> 1;
  img->opix_c_y = img->opix_y >> 1;

//  printf ("set_MB_parameters: mb %d,  mb_x %d,  mb_y %d\n", mb_addr, img->mb_x, img->mb_y);
}


int clip1a(int a)
{
  return ((a)>255?255:((a)<0?0:(a)));
}

/*!
 ************************************************************************
 * \brief
 *    updates the coordinates and statistics parameter for the
 *    next macroblock
 ************************************************************************
 */
void proceed2nextMacroblock()
{
#if TRACE
  int i;
  int use_bitstream_backing = (input->slice_mode == FIXED_RATE || input->slice_mode == CALLBACK);
#endif
  Macroblock *currMB = &img->mb_data[img->current_mb_nr];
  int*        bitCount = currMB->bitcounter;

#if TRACE

  if (p_trace)
  {
    fprintf(p_trace, "\n*********** Pic: %i (I/P) MB: %i Slice: %i **********\n\n", frame_no, img->current_mb_nr, img->current_slice_nr);
    if(use_bitstream_backing)
      fprintf(p_trace, "\n*********** Pic: %i (I/P) MB: %i Slice: %i **********\n\n", frame_no, img->current_mb_nr, img->current_slice_nr);
   // Write out the tracestring for each symbol
    for (i=0; i<currMB->currSEnr; i++)
      trace2out(&(img->MB_SyntaxElements[i]));
  }
#endif

  // Update the statistics
  stat->bit_use_mb_type    [img->type]  += bitCount[BITS_MB_MODE];
  stat->bit_use_coeffY     [img->type]  += bitCount[BITS_COEFF_Y_MB] ;
  stat->tmp_bit_use_cbp    [img->type]  += bitCount[BITS_CBP_MB];
  stat->bit_use_coeffC     [img->type]  += bitCount[BITS_COEFF_UV_MB];
  stat->bit_use_delta_quant[img->type]  += bitCount[BITS_DELTA_QUANT_MB];

  ++stat->mode_use[img->type][currMB->mb_type];
  stat->bit_use_mode[img->type][currMB->mb_type]+= bitCount[BITS_INTER_MB];

  // Statistics
  if ((img->type == P_SLICE)||(img->type==SP_SLICE) )
  {
    ++stat->quant0;
    stat->quant1 += currMB->qp;      // to find average quant for inter frames
  }
}

/*!
 ************************************************************************
 * \brief
 *    initializes the current macroblock
 ************************************************************************
 */
void start_macroblock(int mb_addr, int mb_field)
{
  int i,j,k,l;
  int use_bitstream_backing = (input->slice_mode == FIXED_RATE || input->slice_mode == CALLBACK);
  Macroblock *currMB = &img->mb_data[mb_addr];
  Slice *curr_slice = img->currentSlice;
  DataPartition *dataPart;
  Bitstream *currStream;
  EncodingEnvironmentPtr eep;

  currMB->mb_field = mb_field;
  
  enc_picture->mb_field[mb_addr] = mb_field;

  set_MB_parameters (mb_addr);

  if(use_bitstream_backing)
  {
    // Keep the current state of the bitstreams
    if(!img->cod_counter)
      for (i=0; i<curr_slice->max_part_nr; i++)
      {
        dataPart = &(curr_slice->partArr[i]);
        currStream = dataPart->bitstream;
        currStream->stored_bits_to_go   = currStream->bits_to_go;
        currStream->stored_byte_pos   = currStream->byte_pos;
        currStream->stored_byte_buf   = currStream->byte_buf;

        if (input->symbol_mode ==CABAC)
        {
          eep = &(dataPart->ee_cabac);
          eep->ElowS            = eep->Elow;
          eep->ErangeS           = eep->Erange;
          eep->EbufferS         = eep->Ebuffer;
          eep->Ebits_to_goS     = eep->Ebits_to_go;
          eep->Ebits_to_followS = eep->Ebits_to_follow;
          eep->EcodestrmS       = eep->Ecodestrm;
          eep->Ecodestrm_lenS   = eep->Ecodestrm_len;
          eep->CS               = eep->C;
          eep->BS               = eep->B;
          eep->ES               = eep->E;
        }
      }
  }

  // Save the slice number of this macroblock. When the macroblock below
  // is coded it will use this to decide if prediction for above is possible
  currMB->slice_nr = img->current_slice_nr;

  // Initialize delta qp change from last macroblock. Feature may be used for future rate control
  // Rate control
  currMB->qpsp       = img->qpsp;
  if(input->RCEnable)
  {
    if (img->current_mb_nr==0)
    {
      currMB->prev_qp = img->qp;
      currMB->prev_delta_qp = 0;
    }
    else
    {    
      currMB->prev_qp = img->mb_data[img->current_mb_nr-1].qp;
      currMB->prev_delta_qp = img->mb_data[img->current_mb_nr-1].delta_qp;
    }
    /*frame layer rate control*/
    if(input->basicunit==img->Frame_Total_Number_MB)
    {
      currMB->delta_qp = 0;
      currMB->qp       = img->qp;
    }
/*basic unit layer rate control*/
    else
    {
/*each I or B frame has only one QP*/
     if((img->type==I_SLICE)||(img->type==B_SLICE))
     {
       currMB->delta_qp = 0;
       currMB->qp       = img->qp;
     }
     else if(img->type==P_SLICE)
     {

       if (!img->write_macroblock) //write macroblock
       {
         if (!currMB->mb_field)  //frame macroblock
         {
           if (img->current_mb_nr == 0) //first macroblock
           {
// Initialize delta qp change from last macroblock. Feature may be used for future rate control
             currMB->delta_qp = 0;
             currMB->qp       = img->qp;
             DELTA_QP = DELTA_QP2 = currMB->delta_qp;
             QP = QP2 = currMB->qp;
           }
           else
           {
             if (!((input->MbInterlace) && img->bot_MB)) //top macroblock
             {
               if (img->mb_data[img->current_mb_nr-1].prev_cbp == 1)
               {
                 currMB->delta_qp = 0;
                 currMB->qp       = img->qp;
               }
               else
               {
                 currMB->qp = img->mb_data[img->current_mb_nr-1].prev_qp;
                 currMB->delta_qp = currMB->qp - img->mb_data[img->current_mb_nr-1].qp;
                 img->qp = currMB->qp;
               }
               DELTA_QP = DELTA_QP2 = currMB->delta_qp;
               QP = QP2 = currMB->qp;
             }
             else //bottom macroblock
             {
// Initialize delta qp change from last macroblock. Feature may be used for future rate control
               currMB->delta_qp = 0;
               currMB->qp       = img->qp;       // needed in loop filter (even if constant QP is used)
             }
           }
         }
         else  //field macroblock
         {
           if (!img->bot_MB) //top macroblock 
           {
             currMB->delta_qp = DELTA_QP2;
             currMB->qp   = img->qp    = QP2;
           }
           else//bottom macroblock
           {
             currMB->qp = img->qp;
             currMB->delta_qp = 0;
           }
           
         }
         
       }
       else 
       {
         if (!img->bot_MB) //write top macroblock
         {
           if (img->write_macroblock_frame)
           {
             currMB->delta_qp = DELTA_QP;
             img->qp = currMB->qp = QP;
           }
           else
           {
             currMB->delta_qp = DELTA_QP2;
             img->qp = currMB->qp = QP2;
           }
         }
         else //write bottom macroblock
         {
           currMB->delta_qp = 0;
           currMB->qp = img->qp;
         }
       }

       /*compute the quantization parameter for each basic unit of P frame*/

       if(!((input->MbInterlace)&&img->bot_MB))
       {
         if(!currMB->mb_field)
         {
           
           if((img->NumberofCodedMacroBlocks>0)\
             &&(img->NumberofCodedMacroBlocks%img->BasicUnit==0))
           {
             
             /*frame coding*/
             if(active_sps->frame_mbs_only_flag)
             {
               updateRCModel();
               img->BasicUnitQP=updateQuantizationParameter(img->TopFieldFlag);
             }
             /*adaptive field/frame coding*/
             else if((input->PicInterlace==ADAPTIVE_CODING)&&(!input->MbInterlace)&&(img->IFLAG==0))
             {
               updateRCModel();
               img->BasicUnitQP=updateQuantizationParameter(img->TopFieldFlag);
             }
             /*field coding*/
             else if((input->PicInterlace==FIELD_CODING)&&(!input->MbInterlace)&&(img->IFLAG==0))
             {
               updateRCModel();
               img->BasicUnitQP=updateQuantizationParameter(img->TopFieldFlag);
             }
             /*mb adaptive f/f coding, field coding*/
             else if((input->MbInterlace)&&(img->IFLAG==0)&&(img->FieldControl==1))
             {
               updateRCModel();
               img->BasicUnitQP=updateQuantizationParameter(img->TopFieldFlag);
             }
             /*mb adaptive f/f coding, frame coding*/
             else if((input->MbInterlace)&&(img->IFLAG==0)&&(img->FieldControl==0))
             {
               updateRCModel();
               img->BasicUnitQP=updateQuantizationParameter(img->TopFieldFlag);
             } 
             
             
           }
           
           
           if(img->current_mb_nr==0)
             img->BasicUnitQP=img->qp;

           currMB->predict_qp=img->BasicUnitQP;
           
           if(currMB->predict_qp>currMB->qp+25)
             currMB->predict_qp=currMB->qp+25;
           else if(currMB->predict_qp<currMB->qp-26)
             currMB->predict_qp=currMB->qp-26; 
           
           currMB->prev_qp = currMB->predict_qp;
           
           dq = currMB->delta_qp + currMB->predict_qp-currMB->qp;
           if(dq < -26) 
           {
             dq = -26;
             predict_error = dq-currMB->delta_qp;
             img->qp = img->qp+predict_error;
             currMB->delta_qp = -26;
           }
           else if(dq > 25)
           {
             dq = 25;
             predict_error = dq - currMB->delta_qp;
             img->qp = img->qp + predict_error;
             currMB->delta_qp = 25;
           }
           else
           {
             currMB->delta_qp = dq;
             predict_error=currMB->predict_qp-currMB->qp;