image.c

h.264官方测试软件

/*!
 *************************************************************************************
 * \file image.c
 *
 * \brief
 *    Code one image/slice
 *
 * \author
 *    Main contributors (see contributors.h for copyright, address and affiliation details)
 *     - Inge Lille-Langoy               <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>
 *     - Byeong-Moon Jeon                <jeonbm@lge.com>
 *     - Yoon-Seong Soh                  <yunsung@lge.com>
 *     - Thomas Stockhammer              <stockhammer@ei.tum.de>
 *     - Detlev Marpe                    <marpe@hhi.de>
 *     - Guido Heising                   <heising@hhi.de>
 *     - Thomas Wedi                     <wedi@tnt.uni-hannover.de>
 *     - Ragip Kurceren                  <ragip.kurceren@nokia.com>
 *     - Antti Hallapuro                 <antti.hallapuro@nokia.com>
 *     - Alexis Michael Tourapis         <alexismt@ieee.org> 
 *************************************************************************************
 */
#include "contributors.h"

#include <stdlib.h>
#include <math.h>
#include <time.h>
#include <sys/timeb.h>
#include <string.h>
#include <memory.h>
#include <assert.h>

#ifdef WIN32
#include <io.h>
#else
#include <unistd.h>
#endif

#include "global.h"

#include "refbuf.h"
#include "mbuffer.h"
#include "intrarefresh.h"
#include "fmo.h"
#include "sei.h"
#include "memalloc.h"
#include "nalu.h"
#include "ratectl.h"
#include "mb_access.h"
#include "output.h"
#include "cabac.h"

extern pic_parameter_set_rbsp_t *PicParSet[MAXPPS];

void code_a_picture(Picture *pic);
void frame_picture (Picture *frame, int method);
void field_picture(Picture *top, Picture *bottom);

static int  writeout_picture(Picture *pic);

static int  picture_structure_decision(Picture *frame, Picture *top, Picture *bot);
static void distortion_fld (float *dis_fld_y, float *dis_fld_u, float *dis_fld_v);
static void find_snr(void);
static void find_distortion(void);

static void field_mode_buffer(int bit_field, float snr_field_y, float snr_field_u, float snr_field_v);
static void frame_mode_buffer (int bit_frame, float snr_frame_y, float snr_frame_u, float snr_frame_v);

static void init_frame(void);
static void init_field(void);

static void put_buffer_frame(void);
static void put_buffer_top(void);
static void put_buffer_bot(void);

static void copy_motion_vectors_MB(void);

static void PaddAutoCropBorders (int org_size_x, int org_size_y, int img_size_x, int img_size_y,
                                 int org_size_x_cr, int org_size_y_cr, int img_size_x_cr, int img_size_y_cr);

static void ReadOneFrame (int FrameNoInFile, int HeaderSize, int xs, int ys, int xs_cr, int ys_cr);

static void writeUnit(Bitstream* currStream ,int partition);
static void rdPictureCoding(void);

#ifdef _ADAPT_LAST_GROUP_
int *last_P_no;
int *last_P_no_frm;
int *last_P_no_fld;
#endif

static void ReportFirstframe(int tmp_time, int me_time);
static void ReportIntra(int tmp_time, int me_time);
static void ReportSP(int tmp_time, int me_time);
static void ReportP(int tmp_time, int me_time);
static void ReportB(int tmp_time, int me_time);
static void ReportNALNonVLCBits(int tmp_time, int me_time);

static int CalculateFrameNumber(void);  // Calculates the next frame number

StorablePicture *enc_picture;
StorablePicture *enc_frame_picture;
StorablePicture *enc_frame_picture2;
StorablePicture *enc_frame_picture3;
StorablePicture *enc_top_picture;
StorablePicture *enc_bottom_picture;
//Rate control
int    QP;

const int ONE_FOURTH_TAP[3][2] =
{
  {20,20},
  {-5,-4},
  { 1, 0},
};


void MbAffPostProc(void)
{
  imgpel temp[32][16];

  imgpel ** imgY  = enc_picture->imgY;
  imgpel ***imgUV = enc_picture->imgUV;
  int i, y, x0, y0, uv;

  if (img->yuv_format != YUV400)
  {
    for (i=0; i<(int)img->PicSizeInMbs; i+=2)
    {
      if (enc_picture->mb_field[i])
      {
        get_mb_pos(i, &x0, &y0);
        for (y=0; y<(2*MB_BLOCK_SIZE);y++)
          memcpy(&temp[y],&imgY[y0+y][x0], MB_BLOCK_SIZE * sizeof(imgpel));

        for (y=0; y<MB_BLOCK_SIZE;y++)
        {
          memcpy(&imgY[y0+(2*y)][x0],temp[y], MB_BLOCK_SIZE * sizeof(imgpel));
          memcpy(&imgY[y0+(2*y + 1)][x0],temp[y+ MB_BLOCK_SIZE], MB_BLOCK_SIZE * sizeof(imgpel));
        }

        x0 = x0 / (16/img->mb_cr_size_x);
        y0 = y0 / (16/img->mb_cr_size_y);

        for (uv=0; uv<2; uv++)
        {
          for (y=0; y<(2*img->mb_cr_size_y);y++)    
            memcpy(&temp[y],&imgUV[uv][y0+y][x0], img->mb_cr_size_x * sizeof(imgpel));
          
          for (y=0; y<img->mb_cr_size_y;y++)
          {
            memcpy(&imgUV[uv][y0+(2*y)][x0],temp[y], img->mb_cr_size_x * sizeof(imgpel));
            memcpy(&imgUV[uv][y0+(2*y + 1)][x0],temp[y+ img->mb_cr_size_y], img->mb_cr_size_x * sizeof(imgpel));
            
          }
        }
      }
    }
  }
  else
  {
    for (i=0; i<(int)img->PicSizeInMbs; i+=2)
    {
      if (enc_picture->mb_field[i])
      {
        get_mb_pos(i, &x0, &y0);
        for (y=0; y<(2*MB_BLOCK_SIZE);y++)
          memcpy(&temp[y],&imgY[y0+y][x0], MB_BLOCK_SIZE * sizeof(imgpel));

        for (y=0; y<MB_BLOCK_SIZE;y++)
        {
          memcpy(&imgY[y0+(2*y)][x0],temp[y], MB_BLOCK_SIZE * sizeof(imgpel));
          memcpy(&imgY[y0+(2*y + 1)][x0],temp[y+ MB_BLOCK_SIZE], MB_BLOCK_SIZE * sizeof(imgpel));
        }
      }
    }
  }
}

/*!
 ************************************************************************
 * \brief
 *    Encodes a picture
 *
 *    This is the main picture coding loop.. It is called by all this
 *    frame and field coding stuff after the img-> elements have been
 *    set up.  Not sure whether it is useful for MB-adaptive frame/field
 *    coding
 ************************************************************************
 */
void code_a_picture(Picture *pic)
{
  unsigned int NumberOfCodedMBs = 0;
  int SliceGroup = 0;
  int j;

  img->currentPicture = pic;

  img->currentPicture->idr_flag = ((!IMG_NUMBER) && (!(img->structure==BOTTOM_FIELD))) || (input->idr_enable && (img->type == I_SLICE || img->type==SP_SLICE || img->type==SI_SLICE)&& (!(img->structure==BOTTOM_FIELD)));

  pic->no_slices = 0;
  pic->distortion_u = pic->distortion_v = pic->distortion_y = 0.0;

  RandomIntraNewPicture ();     //! Allocates forced INTRA MBs (even for fields!)

  // The slice_group_change_cycle can be changed here.
  // FmoInit() is called before coding each picture, frame or field
  img->slice_group_change_cycle=1;
  FmoInit(img, active_pps, active_sps);
  FmoStartPicture ();           //! picture level initialization of FMO

  CalculateQuantParam();
  CalculateOffsetParam();

  if(input->Transform8x8Mode)
  {
    CalculateQuant8Param();
    CalculateOffset8Param();
  }

  reset_pic_bin_count();
  img->bytes_in_picture = 0;

  while (NumberOfCodedMBs < img->PicSizeInMbs)       // loop over slices
  {
    // Encode one SLice Group
    while (!FmoSliceGroupCompletelyCoded (SliceGroup))
    {
      // Encode the current slice
      NumberOfCodedMBs += encode_one_slice (SliceGroup, pic, NumberOfCodedMBs);
      FmoSetLastMacroblockInSlice (img->current_mb_nr);
      // Proceed to next slice
      img->current_slice_nr++;
      stats->bit_slice = 0;
    }
    // Proceed to next SliceGroup
    SliceGroup++;
  }
  FmoEndPicture ();

  // Modified for Fast Mode Decision. Inchoon Choi, SungKyunKwan Univ.
  if (input->rdopt == 3 && (img->type != B_SLICE))
    for (j = 0; j < input->NoOfDecoders; j++)
      DeblockFrame (img, decs->decY_best[j], NULL);

  DeblockFrame (img, enc_picture->imgY, enc_picture->imgUV); //comment out to disable loop filter

  if (img->MbaffFrameFlag)
    MbAffPostProc();
}



/*!
 ************************************************************************
 * \brief
 *    Encodes one frame
 ************************************************************************
 */
int encode_one_frame (void)
{
  static int prev_frame_no = 0; // POC200301
  static int consecutive_non_reference_pictures = 0; // POC200301
  int        FrameNumberInFile;

#ifdef _LEAKYBUCKET_
  extern long Bit_Buffer[10000];
  extern unsigned long total_frame_buffer;
#endif

  time_t ltime1;
  time_t ltime2;

#ifdef WIN32
  struct _timeb tstruct1;
  struct _timeb tstruct2;
#else
  struct timeb tstruct1;
  struct timeb tstruct2;
#endif

  int tmp_time;
  int bits_frm = 0, bits_fld = 0;
  float dis_frm = 0.0, dis_frm_y = 0.0, dis_frm_u = 0.0, dis_frm_v = 0.0;
  float dis_fld = 0.0, dis_fld_y = 0.0, dis_fld_u = 0.0, dis_fld_v = 0.0;

  //Rate control
  int pic_type, bits = 0; 

  me_time=0;
  img->rd_pass = 0;
  enc_frame_picture  = NULL;
  enc_frame_picture2 = NULL;
  enc_frame_picture3 = NULL;

#ifdef WIN32
  _ftime (&tstruct1);           // start time ms
#else
  ftime (&tstruct1);
#endif
  time (&ltime1);               // start time s

  //Rate control 
  img->write_macroblock = 0;
/*
  //Shankar Regunathan (Oct 2002)
  //Prepare Panscanrect SEI payload
  UpdatePanScanRectInfo ();
  //Prepare Arbitrarydata SEI Payload
  UpdateUser_data_unregistered ();
  //Prepare Registered data SEI Payload
  UpdateUser_data_registered_itu_t_t35 ();
  //Prepare RandomAccess SEI Payload
  UpdateRandomAccess ();
*/

  if (input->ResendPPS && img->number !=0)
  {
    stats->bit_ctr_parametersets_n=write_PPS(0, 0);
    //stats->bit_slice += stats->bit_ctr_parametersets_n;
    stats->bit_ctr_parametersets += stats->bit_ctr_parametersets_n;
  }

  put_buffer_frame ();      // sets the pointers to the frame structures 
                            // (and not to one of the field structures)
  init_frame ();
  FrameNumberInFile = CalculateFrameNumber();

  ReadOneFrame (FrameNumberInFile, input->infile_header,
                input->img_width, input->img_height, input->img_width_cr, input->img_height_cr);

  PaddAutoCropBorders (input->img_width, input->img_height, img->width, img->height,
                       input->img_width_cr, input->img_height_cr, img->width_cr, img->height_cr);

  // set parameters for direct mode and deblocking filter
  img->direct_spatial_mv_pred_flag     = input->direct_spatial_mv_pred_flag;
  img->LFDisableIdc    = input->LFDisableIdc;
  img->LFAlphaC0Offset = input->LFAlphaC0Offset;
  img->LFBetaOffset    = input->LFBetaOffset;
  img->AdaptiveRounding = input->AdaptiveRounding;
  // Following code should consider optimal coding mode. Currently also does not support
  // multiple slices per frame.
  frame_ctr[img->type]++;
  snr->frame_ctr++;

  if(img->type == SP_SLICE)
  { 
    if(input->sp2_frame_indicator)
    { // switching SP frame encoding
      sp2_frame_indicator=1;
      read_SP_coefficients();
    }
  }
  else
  {
    sp2_frame_indicator=0;
  }

  if (input->PicInterlace == FIELD_CODING)
  {
    //Rate control
    img->FieldControl=1;

    img->field_picture = 1;  // we encode fields
    field_picture (top_pic, bottom_pic);
    img->fld_flag = 1;
  }
  else
  {
    //Rate control
    img->FieldControl=0;

    // For frame coding, turn MB level field/frame coding flag on
    if (input->MbInterlace)
      mb_adaptive = 1;

    img->field_picture = 0; // we encode a frame

    //Rate control
    if(input->RCEnable)
    { 
    /*update the number of MBs in the basic unit for MB adaptive 
      f/f coding*/
      if((input->MbInterlace)&&(input->basicunit<img->Frame_Total_Number_MB)\
        &&(img->type==P_SLICE)&&(img->IFLAG==0))
        img->BasicUnit=input->basicunit*2;
      else
        img->BasicUnit=input->basicunit;
      
      rc_init_pict(1,0,1); 
      img->qp  = updateQuantizationParameter(0); 
      
      
      pic_type = img->type;
      QP =0;
    }