H264参数语法文档: SPS、PPS、IDR

H.264码流第一个 NALU 是 SPS(序列参数集Sequence Parameter Set)
对应H264标准文档 7.3.2.1 序列参数集的语法进行解析

SPS参数解析// fill sps with content of p

   
   
   
   
int InterpretSPS (VideoParameters *p_Vid, DataPartition *p, seq_parameter_set_rbsp_t *sps)  
  1. {  
  2.   unsigned i;  
  3.   unsigned n_ScalingList;  
  4.   int reserved_zero;  
  5.   Bitstream *s = p->bitstream;  
  6.   
  7.   assert (p != NULL);  
  8.   assert (p->bitstream != NULL);  
  9.   assert (p->bitstream->streamBuffer != 0);  
  10.   assert (sps != NULL);  
  11.   
  12.   p_Dec->UsedBits = 0;  
  13.   
  14.   sps->profile_idc                            = u_v  (8, "SPS: profile_idc"                           , s);  
  15.   
  16.   if ((sps->profile_idc!=BASELINE       ) &&  
  17.       (sps->profile_idc!=MAIN           ) &&  
  18.       (sps->profile_idc!=EXTENDED       ) &&  
  19.       (sps->profile_idc!=FREXT_HP       ) &&  
  20.       (sps->profile_idc!=FREXT_Hi10P    ) &&  
  21.       (sps->profile_idc!=FREXT_Hi422    ) &&  
  22.       (sps->profile_idc!=FREXT_Hi444    ) &&  
  23.       (sps->profile_idc!=FREXT_CAVLC444 )  
  24. #if (MVC_EXTENSION_ENABLE)   
  25.       && (sps->profile_idc!=MVC_HIGH)  
  26.       && (sps->profile_idc!=STEREO_HIGH)  
  27. #endif   
  28.       )  
  29.   {  
  30.     printf("Invalid Profile IDC (%d) encountered. /n", sps->profile_idc);  
  31.     return p_Dec->UsedBits;  
  32.   }  
  33.   
  34.   sps->constrained_set0_flag                  = u_1  (   "SPS: constrained_set0_flag"                 , s);  
  35.   sps->constrained_set1_flag                  = u_1  (   "SPS: constrained_set1_flag"                 , s);  
  36.   sps->constrained_set2_flag                  = u_1  (   "SPS: constrained_set2_flag"                 , s);  
  37.   sps->constrained_set3_flag                  = u_1  (   "SPS: constrained_set3_flag"                 , s);  
  38. #if (MVC_EXTENSION_ENABLE)   
  39.   sps->constrained_set4_flag                  = u_1  (   "SPS: constrained_set4_flag"                 , s);  
  40.   reserved_zero                               = u_v  (3, "SPS: reserved_zero_3bits"                   , s);  
  41. #else   
  42.   reserved_zero                               = u_v  (4, "SPS: reserved_zero_4bits"                   , s);  
  43. #endif   
  44.   assert (reserved_zero==0);  
  45.   
  46.   sps->level_idc                              = u_v  (8, "SPS: level_idc"                             , s);  
  47.   
  48.   sps->seq_parameter_set_id                   = ue_v ("SPS: seq_parameter_set_id"                     , s);  
  49.   
  50.   // Fidelity Range Extensions stuff   
  51.   sps->chroma_format_idc = 1;  
  52.   sps->bit_depth_luma_minus8   = 0;  
  53.   sps->bit_depth_chroma_minus8 = 0;  
  54.   p_Vid->lossless_qpprime_flag   = 0;  
  55.   sps->separate_colour_plane_flag = 0;  
  56.   
  57.   if((sps->profile_idc==FREXT_HP   ) ||  
  58.      (sps->profile_idc==FREXT_Hi10P) ||  
  59.      (sps->profile_idc==FREXT_Hi422) ||  
  60.      (sps->profile_idc==FREXT_Hi444) ||  
  61.      (sps->profile_idc==FREXT_CAVLC444)  
  62. #if (MVC_EXTENSION_ENABLE)   
  63.      || (sps->profile_idc==MVC_HIGH)  
  64.      || (sps->profile_idc==STEREO_HIGH)  
  65. #endif   
  66.      )  
  67.   {  
  68.     sps->chroma_format_idc                      = ue_v ("SPS: chroma_format_idc"                       , s);  
  69.   
  70.     if(sps->chroma_format_idc == YUV444)  
  71.     {  
  72.       sps->separate_colour_plane_flag           = u_1  ("SPS: separate_colour_plane_flag"              , s);  
  73.     }  
  74.   
  75.     sps->bit_depth_luma_minus8                  = ue_v ("SPS: bit_depth_luma_minus8"                   , s);  
  76.     sps->bit_depth_chroma_minus8                = ue_v ("SPS: bit_depth_chroma_minus8"                 , s);  
  77.     //checking;   
  78.     if((sps->bit_depth_luma_minus8+8 > sizeof(imgpel)*8) || (sps->bit_depth_chroma_minus8+8> sizeof(imgpel)*8))  
  79.       error ("Source picture has higher bit depth than imgpel data type. /nPlease recompile with larger data type for imgpel.", 500);  
  80.   
  81.     p_Vid->lossless_qpprime_flag                  = u_1  ("SPS: lossless_qpprime_y_zero_flag"            , s);  
  82.   
  83.     sps->seq_scaling_matrix_present_flag        = u_1  (   "SPS: seq_scaling_matrix_present_flag"       , s);  
  84.       
  85.     if(sps->seq_scaling_matrix_present_flag)  
  86.     {  
  87.       n_ScalingList = (sps->chroma_format_idc != YUV444) ? 8 : 12;  
  88.       for(i=0; iseq_scaling_list_present_flag[i]   = u_1  (   "SPS: seq_scaling_list_present_flag"         , s);  
  89.         if(sps->seq_scaling_list_present_flag[i])  
  90.         {  
  91.           if(i<6) scaling_list="">ScalingList4x4[i], 16, &sps->UseDefaultScalingMatrix4x4Flag[i], s);  
  92.           else  
  93.             Scaling_List(sps->ScalingList8x8[i-6], 64, &sps->UseDefaultScalingMatrix8x8Flag[i-6], s);  
  94.         }  
  95.       }  
  96.     }  
  97.   }  
  98.   
  99.   sps->log2_max_frame_num_minus4              = ue_v ("SPS: log2_max_frame_num_minus4"                , s);  
  100.   sps->pic_order_cnt_type                     = ue_v ("SPS: pic_order_cnt_type"                       , s);  
  101.   
  102.   if (sps->pic_order_cnt_type == 0)  
  103.     sps->log2_max_pic_order_cnt_lsb_minus4 = ue_v ("SPS: log2_max_pic_order_cnt_lsb_minus4"           , s);  
  104.   else if (sps->pic_order_cnt_type == 1)  
  105.   {  
  106.     sps->delta_pic_order_always_zero_flag      = u_1  ("SPS: delta_pic_order_always_zero_flag"       , s);  
  107.     sps->offset_for_non_ref_pic                = se_v ("SPS: offset_for_non_ref_pic"                 , s);  
  108.     sps->offset_for_top_to_bottom_field        = se_v ("SPS: offset_for_top_to_bottom_field"         , s);  
  109.     sps->num_ref_frames_in_pic_order_cnt_cycle = ue_v ("SPS: num_ref_frames_in_pic_order_cnt_cycle"  , s);  
  110.     for(i=0; inum_ref_frames_in_pic_order_cnt_cycle; i++)  
  111.       sps->offset_for_ref_frame[i]               = se_v ("SPS: offset_for_ref_frame[i]"              , s);  
  112.   }  
  113.   sps->num_ref_frames                        = ue_v ("SPS: num_ref_frames"                         , s);  
  114.   sps->gaps_in_frame_num_value_allowed_flag  = u_1  ("SPS: gaps_in_frame_num_value_allowed_flag"   , s);  
  115.   sps->pic_width_in_mbs_minus1               = ue_v ("SPS: pic_width_in_mbs_minus1"                , s);  
  116.   sps->pic_height_in_map_units_minus1        = ue_v ("SPS: pic_height_in_map_units_minus1"         , s);  
  117.   sps->frame_mbs_only_flag                   = u_1  ("SPS: frame_mbs_only_flag"                    , s);  
  118.   if (!sps->frame_mbs_only_flag)  
  119.   {  
  120.     sps->mb_adaptive_frame_field_flag        = u_1  ("SPS: mb_adaptive_frame_field_flag"           , s);  
  121.   }  
  122.   sps->direct_8x8_inference_flag             = u_1  ("SPS: direct_8x8_inference_flag"              , s);  
  123.   sps->frame_cropping_flag                   = u_1  ("SPS: frame_cropping_flag"                    , s);  
  124.   
  125.   if (sps->frame_cropping_flag)  
  126.   {  
  127.     sps->frame_cropping_rect_left_offset      = ue_v ("SPS: frame_cropping_rect_left_offset"           , s);  
  128.     sps->frame_cropping_rect_right_offset     = ue_v ("SPS: frame_cropping_rect_right_offset"          , s);  
  129.     sps->frame_cropping_rect_top_offset       = ue_v ("SPS: frame_cropping_rect_top_offset"            , s);  
  130.     sps->frame_cropping_rect_bottom_offset    = ue_v ("SPS: frame_cropping_rect_bottom_offset"         , s);  
  131.   }  
  132.   sps->vui_parameters_present_flag           = (Boolean) u_1  ("SPS: vui_parameters_present_flag"      , s);  
  133.   
  134.   InitVUI(sps);  
  135.   ReadVUI(p, sps);  
  136.   
  137.   sps->Valid = TRUE;  
  138.   return p_Dec->UsedBits;  
  139. }  

 

H.264码流第二个 NALU 是 PPS(图像参数集Picture Parameter Set)
对应H264标准文档 7.3.2.2 序列参数集的语法进行解析

PPS参数解析
   
   
   
   
int InterpretPPS (VideoParameters *p_Vid, DataPartition *p, pic_parameter_set_rbsp_t *pps)  
  1. {  
  2.   unsigned i;  
  3.   unsigned n_ScalingList;  
  4.   int chroma_format_idc;  
  5.   int NumberBitsPerSliceGroupId;  
  6.   Bitstream *s = p->bitstream;  
  7.   
  8.   assert (p != NULL);  
  9.   assert (p->bitstream != NULL);  
  10.   assert (p->bitstream->streamBuffer != 0);  
  11.   assert (pps != NULL);  
  12.   
  13.   p_Dec->UsedBits = 0;  
  14.   
  15.   pps->pic_parameter_set_id                  = ue_v ("PPS: pic_parameter_set_id"                   , s);  
  16.   pps->seq_parameter_set_id                  = ue_v ("PPS: seq_parameter_set_id"                   , s);  
  17.   pps->entropy_coding_mode_flag              = u_1  ("PPS: entropy_coding_mode_flag"               , s);  
  18.   
  19.   //! Note: as per JVT-F078 the following bit is unconditional.  If F078 is not accepted, then   
  20.   //! one has to fetch the correct SPS to check whether the bit is present (hopefully there is   
  21.   //! no consistency problem :-(   
  22.   //! The current encoder code handles this in the same way.  When you change this, don't forget   
  23.   //! the encoder!  StW, 12/8/02   
  24.   pps->bottom_field_pic_order_in_frame_present_flag                = u_1  ("PPS: bottom_field_pic_order_in_frame_present_flag"                 , s);  
  25.   
  26.   pps->num_slice_groups_minus1               = ue_v ("PPS: num_slice_groups_minus1"                , s);  
  27.   
  28.   // FMO stuff begins here   
  29.   if (pps->num_slice_groups_minus1 > 0)  
  30.   {  
  31.     pps->slice_group_map_type               = ue_v ("PPS: slice_group_map_type"                , s);  
  32.     if (pps->slice_group_map_type == 0)  
  33.     {  
  34.       for (i=0; i<=pps->num_slice_groups_minus1; i++)  
  35.         pps->run_length_minus1 [i]                  = ue_v ("PPS: run_length_minus1 [i]"              , s);  
  36.     }  
  37.     else if (pps->slice_group_map_type == 2)  
  38.     {  
  39.       for (i=0; inum_slice_groups_minus1; i++)  
  40.       {  
  41.         //! JVT-F078: avoid reference of SPS by using ue(v) instead of u(v)   
  42.         pps->top_left [i]                          = ue_v ("PPS: top_left [i]"                        , s);  
  43.         pps->bottom_right [i]                      = ue_v ("PPS: bottom_right [i]"                    , s);  
  44.       }  
  45.     }  
  46.     else if (pps->slice_group_map_type == 3 ||  
  47.              pps->slice_group_map_type == 4 ||  
  48.              pps->slice_group_map_type == 5)  
  49.     {  
  50.       pps->slice_group_change_direction_flag     = u_1  ("PPS: slice_group_change_direction_flag"      , s);  
  51.       pps->slice_group_change_rate_minus1        = ue_v ("PPS: slice_group_change_rate_minus1"         , s);  
  52.     }  
  53.     else if (pps->slice_group_map_type == 6)  
  54.     {  
  55.       if (pps->num_slice_groups_minus1+1 >4)  
  56.         NumberBitsPerSliceGroupId = 3;  
  57.       else if (pps->num_slice_groups_minus1+1 > 2)  
  58.         NumberBitsPerSliceGroupId = 2;  
  59.       else  
  60.         NumberBitsPerSliceGroupId = 1;  
  61.       pps->pic_size_in_map_units_minus1      = ue_v ("PPS: pic_size_in_map_units_minus1"               , s);  
  62.       if ((pps->slice_group_id = calloc (pps->pic_size_in_map_units_minus1+1, 1)) == NULL)  
  63.         no_mem_exit ("InterpretPPS: slice_group_id");  
  64.       for (i=0; i<=pps->pic_size_in_map_units_minus1; i++)  
  65.         pps->slice_group_id[i] = (byte) u_v (NumberBitsPerSliceGroupId, "slice_group_id[i]", s);  
  66.     }  
  67.   }  
  68.   
  69.   // End of FMO stuff   
  70.   
  71.   pps->num_ref_idx_l0_active_minus1          = ue_v ("PPS: num_ref_idx_l0_active_minus1"           , s);  
  72.   pps->num_ref_idx_l1_active_minus1          = ue_v ("PPS: num_ref_idx_l1_active_minus1"           , s);  
  73.   pps->weighted_pred_flag                    = u_1  ("PPS: weighted_pred_flag"                     , s);  
  74.   pps->weighted_bipred_idc                   = u_v  ( 2, "PPS: weighted_bipred_idc"                , s);  
  75.   pps->pic_init_qp_minus26                   = se_v ("PPS: pic_init_qp_minus26"                    , s);  
  76.   pps->pic_init_qs_minus26                   = se_v ("PPS: pic_init_qs_minus26"                    , s);  
  77.   
  78.   pps->chroma_qp_index_offset                = se_v ("PPS: chroma_qp_index_offset"                 , s);  
  79.   
  80.   pps->deblocking_filter_control_present_flag = u_1 ("PPS: deblocking_filter_control_present_flag" , s);  
  81.   pps->constrained_intra_pred_flag           = u_1  ("PPS: constrained_intra_pred_flag"            , s);  
  82.   pps->redundant_pic_cnt_present_flag        = u_1  ("PPS: redundant_pic_cnt_present_flag"         , s);  
  83.   
  84.   if(more_rbsp_data(s->streamBuffer, s->frame_bitoffset,s->bitstream_length)) // more_data_in_rbsp()   
  85.   {  
  86.     //Fidelity Range Extensions Stuff   
  87.     pps->transform_8x8_mode_flag           = u_1  ("PPS: transform_8x8_mode_flag"                , s);  
  88.     pps->pic_scaling_matrix_present_flag   =  u_1  ("PPS: pic_scaling_matrix_present_flag"        , s);  
  89.   
  90.     if(pps->pic_scaling_matrix_present_flag)  
  91.     {  
  92.       chroma_format_idc = p_Vid->SeqParSet[pps->seq_parameter_set_id].chroma_format_idc;  
  93.       n_ScalingList = 6 + ((chroma_format_idc != YUV444) ? 2 : 6) * pps->transform_8x8_mode_flag;  
  94.       for(i=0; ipic_scaling_list_present_flag[i]= u_1  ("PPS: pic_scaling_list_present_flag"          , s);  
  95.   
  96.         if(pps->pic_scaling_list_present_flag[i])  
  97.         {  
  98.           if(i<6) scaling_list="">ScalingList4x4[i], 16, &pps->UseDefaultScalingMatrix4x4Flag[i], s);  
  99.           else  
  100.             Scaling_List(pps->ScalingList8x8[i-6], 64, &pps->UseDefaultScalingMatrix8x8Flag[i-6], s);  
  101.         }  
  102.       }  
  103.     }  
  104.     pps->second_chroma_qp_index_offset      = se_v ("PPS: second_chroma_qp_index_offset"          , s);  
  105.   }  
  106.   else  
  107.   {  
  108.     pps->second_chroma_qp_index_offset      = pps->chroma_qp_index_offset;  
  109.   }  
  110.   
  111.   pps->Valid = TRUE;  
  112.   return p_Dec->UsedBits;  
  113. }  

 

H.264码流第三个 NALU 是 IDR(即时解码器刷新)
对应H264标准文档 7.3.3 序列参数集的语法进行解析

IDR参数解析

   
   
   
   
[cpp] view plain copy print ?
  1. case NALU_TYPE_IDR:  
  2.         img->idr_flag = (nalu->nal_unit_type == NALU_TYPE_IDR);  
  3.         img->nal_reference_idc = nalu->nal_reference_idc;  
  4.         img->disposable_flag = (nalu->nal_reference_idc == NALU_PRIORITY_DISPOSABLE);  
  5.         currSlice->dp_mode = PAR_DP_1;   //++ dp_mode:数据分割模式;PAR_DP_1=0:没有数据分割   
  6.         currSlice->max_part_nr = 1;  
  7.         currSlice->ei_flag = 0;  //++ 该处赋值直接影响decode_slice()函数中对decode_one_slice()函数的调用   
  8.                                     //++ 该值不为0,表明当前片出错,解码程序将忽略当前片的解码过程,而使用错误隐藏   
  9.         currStream = currSlice->partArr[0].bitstream;  
  10.         currStream->ei_flag = 0; //++ 此处的赋值为最终赋值,以后不再改变。该值将对每个宏块的ei_flag产生影响   
  11.                                     //++ 参见macroblock.c文件read_one_macroblock()函数的如下语句:   
  12.                                     //++        :if(!dP->bitstream->ei_flag)      :currMB->ei_flag = 0;   
  13.                                     //++ 该值还在macroblock.c文件if(IS_INTRA (currMB) && dP->bitstream->ei_flag && img->number)中用到   
  14.         currStream->frame_bitoffset = currStream->read_len = 0;  
  15.         memcpy (currStream->streamBuffer, &nalu->buf[1], nalu->len-1);  
  16.         currStream->code_len = currStream->bitstream_length = RBSPtoSODB(currStream->streamBuffer, nalu->len-1);  
  17.   
  18.         // Some syntax of the Slice Header depends on the parameter set, which depends on   
  19.         // the parameter set ID of the SLice header.  Hence, read the pic_parameter_set_id   
  20.         // of the slice header first, then setup the active parameter sets, and then read   
  21.         // the rest of the slice header   
  22.         BitsUsedByHeader = FirstPartOfSliceHeader();    //++ 参见标准7.3.3   
  23.         UseParameterSet (currSlice->pic_parameter_set_id);  
  24.         BitsUsedByHeader+= RestOfSliceHeader ();    //++ 参见标准7.3.3   
  25.         //++ BitsUsedByHeader在程序中没有实际用处,而且BitsUsedByHeader+= RestOfSliceHeader ()   
  26.         //++ 重复计算了FirstPartOfSliceHeader()所用到的比特数。因为在FirstPartOfSliceHeader()   
  27.         //++ 之后,变量UsedBits值并未被置零就代入RestOfSliceHeader()运算,从而RestOfSliceHeader ()   
  28.         //++ 在返回时,BitsUsedByHeader+= RestOfSliceHeader()多加了一个BitsUsedByHeader值   
  29.   
  30.         FmoInit (active_pps, active_sps);  
  31.   
  32.         if(is_new_picture())  
  33.         {  
  34.           init_picture(img, input);  
  35.             
  36.           current_header = SOP;  
  37.           //check zero_byte if it is also the first NAL unit in the access unit   
  38.           CheckZeroByteVCL(nalu, &ret);  
  39.         }  
  40.         else  
  41.           current_header = SOS;  
  42.     
  43.         init_lists(img->type, img->currentSlice->structure);  
  44.         reorder_lists (img->type, img->currentSlice);  
  45.   
  46.         if (img->structure==FRAME)  
  47.         {  
  48.           init_mbaff_lists();  
  49.         }  
  50.   
  51. /*        if (img->frame_num==1) // write a reference list 
  52.         { 
  53.           count ++; 
  54.           if (count==1) 
  55.             for (i=0; i 
  56.  
  57.         // From here on, active_sps, active_pps and the slice header are valid 
  58.         if (img->MbaffFrameFlag) 
  59.           img->current_mb_nr = currSlice->start_mb_nr << 1="" style="color: #0000ff">else 
  60.           img->current_mb_nr = currSlice->start_mb_nr; 
  61.  
  62.         if (active_pps->entropy_coding_mode_flag) 
  63.         { 
  64.           int ByteStartPosition = currStream->frame_bitoffset/8; 
  65.           if (currStream->frame_bitoffset%8 != 0)  
  66.           { 
  67.             ByteStartPosition++; 
  68.           } 
  69.           arideco_start_decoding (&currSlice->partArr[0].de_cabac, currStream->streamBuffer, ByteStartPosition, &currStream->read_len, img->type); 
  70.         } 
  71. // printf ("read_new_slice: returning %s/n", current_header == SOP?"SOP":"SOS"); 
  72.         FreeNALU(nalu); 
  73.         return current_header; 
  74.         break; 
  75.       case NALU_TYPE_DPA: 
  76.         //! The state machine here should follow the same ideas as the old readSliceRTP() 
  77.         //! basically: 
  78.         //! work on DPA (as above) 
  79.         //! read and process all following SEI/SPS/PPS/PD/Filler NALUs 
  80.         //! if next video NALU is dpB,  
  81.         //!   then read and check whether it belongs to DPA, if yes, use it 
  82.         //! else 
  83.         //!   ;   // nothing 
  84.         //! read and process all following SEI/SPS/PPS/PD/Filler NALUs 
  85.         //! if next video NALU is dpC 
  86.         //!   then read and check whether it belongs to DPA (and DPB, if present), if yes, use it, done 
  87.         //! else 
  88.         //!   use the DPA (and the DPB if present) 
  89.  
  90.         /*  
  91.             LC: inserting the code related to DP processing, mainly copying some of the parts 
  92.             related to NALU_TYPE_SLICE, NALU_TYPE_IDR. 
  93.         */  
  94.   
  95.         if(expected_slice_type != NALU_TYPE_DPA)  
  96.         {  
  97.           /* oops... we found the next slice, go back! */  
  98.           fseek(bits, ftell_position, SEEK_SET);  
  99.           FreeNALU(nalu);  
  100.           return current_header;  
  101.         }  
  102.   
  103.         img->idr_flag          = (nalu->nal_unit_type == NALU_TYPE_IDR);  
  104.         img->nal_reference_idc = nalu->nal_reference_idc;  
  105.         img->disposable_flag   = (nalu->nal_reference_idc == NALU_PRIORITY_DISPOSABLE);  
  106.         currSlice->dp_mode     = PAR_DP_3;  
  107.         currSlice->max_part_nr = 3;  
  108.         currSlice->ei_flag     = 0;  
  109.         currStream             = currSlice->partArr[0].bitstream;  
  110.         currStream->ei_flag    = 0;  
  111.         currStream->frame_bitoffset = currStream->read_len = 0;  
  112.         memcpy (currStream->streamBuffer, &nalu->buf[1], nalu->len-1);  
  113.         currStream->code_len = currStream->bitstream_length = RBSPtoSODB(currStream->streamBuffer, nalu->len-1);    //++ 剔除停止比特和填充比特   
  114.           
  115.         BitsUsedByHeader     = FirstPartOfSliceHeader();  
  116.         UseParameterSet (currSlice->pic_parameter_set_id);  
  117.         BitsUsedByHeader    += RestOfSliceHeader ();  
  118.           
  119.         FmoInit (active_pps, active_sps);  
  120.   
  121.         if(is_new_picture())  
  122.         {  
  123.           init_picture(img, input);  
  124.           current_header = SOP;  
  125.           CheckZeroByteVCL(nalu, &ret);  
  126.         }  
  127.         else  
  128.           current_header = SOS;  
  129.   
  130.           
  131.         init_lists(img->type, img->currentSlice->structure);  
  132.         reorder_lists (img->type, img->currentSlice);  
  133.           
  134.         if (img->structure==FRAME)  
  135.         {  
  136.           init_mbaff_lists();  
  137.         }  
  138.   
  139.         // From here on, active_sps, active_pps and the slice header are valid   
  140.         if (img->MbaffFrameFlag)  
  141.           img->current_mb_nr = currSlice->start_mb_nr << 1="" style="color: #0000ff">else  
  142.    
  143.          img->current_mb_nr = currSlice->start_mb_nr;  
  144.   
  145.   
  146.         /*  
  147.            LC: 
  148.               Now I need to read the slice ID, which depends on the value of  
  149.               redundant_pic_cnt_present_flag (pag.49).  
  150.         */  
  151.   
  152.         slice_id_a  = ue_v("NALU:SLICE_A slice_idr", currStream);  
  153.         if (active_pps->entropy_coding_mode_flag)  
  154.         {  
  155.           int ByteStartPosition = currStream->frame_bitoffset/8;  
  156.           if (currStream->frame_bitoffset%8 != 0)   
  157.           {  
  158.             ByteStartPosition++;  
  159.           }  
  160.           arideco_start_decoding (&currSlice->partArr[0].de_cabac, currStream->streamBuffer, ByteStartPosition, &currStream->read_len, img->type);  
  161.         }  
  162. // printf ("read_new_slice: returning %s/n", current_header == SOP?"SOP":"SOS");   
  163.         break;  
  164.       case NALU_TYPE_DPB:  
  165.         /* LC: inserting the code related to DP processing */  
  166.   
  167.         currStream             = currSlice->partArr[1].bitstream;  
  168.         currStream->ei_flag    = 0;  
  169.         currStream->frame_bitoffset = currStream->read_len = 0;  
  170.         memcpy (currStream->streamBuffer, &nalu->buf[1], nalu->len-1);  
  171.         currStream->code_len = currStream->bitstream_length = RBSPtoSODB(currStream->streamBuffer, nalu->len-1);  
  172.   
  173.         slice_id_b  = ue_v("NALU:SLICE_B slice_idr", currStream);  
  174.         if (active_pps->redundant_pic_cnt_present_flag)  
  175.           redundant_pic_cnt_b = ue_v("NALU:SLICE_B redudand_pic_cnt", currStream);  
  176.         else  
  177.           redundant_pic_cnt_b = 0;  
  178.           
  179.         /*  LC: Initializing CABAC for the current data stream. */  
  180.   
  181.         if (active_pps->entropy_coding_mode_flag)  
  182.         {  
  183.           int ByteStartPosition = currStream->frame_bitoffset/8;  
  184.           if (currStream->frame_bitoffset % 8 != 0)   
  185.             ByteStartPosition++;  
  186.             
  187.           arideco_start_decoding (&currSlice->partArr[1].de_cabac, currStream->streamBuffer,   
  188.             ByteStartPosition, &currStream->read_len, img->type);  
  189.             
  190.         }  
  191.   
  192.         /* LC: resilience code to be inserted */  
  193.         /*         FreeNALU(nalu); */  
  194.         /*         return current_header; */  
  195.   
  196.         break;  
case NALU_TYPE_IDR: img->idr_flag = (nalu->nal_unit_type == NALU_TYPE_IDR); img->nal_reference_idc = nalu->nal_reference_idc; img->disposable_flag = (nalu->nal_reference_idc == NALU_PRIORITY_DISPOSABLE); currSlice->dp_mode = PAR_DP_1; //++ dp_mode:数据分割模式;PAR_DP_1=0:没有数据分割 currSlice->max_part_nr = 1; currSlice->ei_flag = 0; //++ 该处赋值直接影响decode_slice()函数中对decode_one_slice()函数的调用 //++ 该值不为0,表明当前片出错,解码程序将忽略当前片的解码过程,而使用错误隐藏 currStream = currSlice->partArr[0].bitstream; currStream->ei_flag = 0; //++ 此处的赋值为最终赋值,以后不再改变。该值将对每个宏块的ei_flag产生影响 //++ 参见macroblock.c文件read_one_macroblock()函数的如下语句: //++ :if(!dP->bitstream->ei_flag) :currMB->ei_flag = 0; //++ 该值还在macroblock.c文件if(IS_INTRA (currMB) && dP->bitstream->ei_flag && img->number)中用到 currStream->frame_bitoffset = currStream->read_len = 0; memcpy (currStream->streamBuffer, &nalu->buf[1], nalu->len-1); currStream->code_len = currStream->bitstream_length = RBSPtoSODB(currStream->streamBuffer, nalu->len-1); // Some syntax of the Slice Header depends on the parameter set, which depends on // the parameter set ID of the SLice header. Hence, read the pic_parameter_set_id // of the slice header first, then setup the active parameter sets, and then read // the rest of the slice header BitsUsedByHeader = FirstPartOfSliceHeader(); //++ 参见标准7.3.3 UseParameterSet (currSlice->pic_parameter_set_id); BitsUsedByHeader+= RestOfSliceHeader (); //++ 参见标准7.3.3 //++ BitsUsedByHeader在程序中没有实际用处,而且BitsUsedByHeader+= RestOfSliceHeader () //++ 重复计算了FirstPartOfSliceHeader()所用到的比特数。因为在FirstPartOfSliceHeader() //++ 之后,变量UsedBits值并未被置零就代入RestOfSliceHeader()运算,从而RestOfSliceHeader () //++ 在返回时,BitsUsedByHeader+= RestOfSliceHeader()多加了一个BitsUsedByHeader值 FmoInit (active_pps, active_sps); if(is_new_picture()) { init_picture(img, input); current_header = SOP; //check zero_byte if it is also the first NAL unit in the access unit CheckZeroByteVCL(nalu, &ret); } else current_header = SOS; init_lists(img->type, img->currentSlice->structure); reorder_lists (img->type, img->currentSlice); if (img->structure==FRAME) { init_mbaff_lists(); } /* if (img->frame_num==1) // write a reference list { count ++; if (count==1) for (i=0; i // From here on, active_sps, active_pps and the slice header are valid if (img->MbaffFrameFlag) img->current_mb_nr = currSlice->start_mb_nr << 1="" style="color: #0000ff">else img->current_mb_nr = currSlice->start_mb_nr; if (active_pps->entropy_coding_mode_flag) { int ByteStartPosition = currStream->frame_bitoffset/8; if (currStream->frame_bitoffset%8 != 0) { ByteStartPosition++; } arideco_start_decoding (&currSlice->partArr[0].de_cabac, currStream->streamBuffer, ByteStartPosition, &currStream->read_len, img->type); } // printf ("read_new_slice: returning %s/n", current_header == SOP?"SOP":"SOS"); FreeNALU(nalu); return current_header; break; case NALU_TYPE_DPA: //! The state machine here should follow the same ideas as the old readSliceRTP() //! basically: //! work on DPA (as above) //! read and process all following SEI/SPS/PPS/PD/Filler NALUs //! if next video NALU is dpB, //! then read and check whether it belongs to DPA, if yes, use it //! else //! ; // nothing //! read and process all following SEI/SPS/PPS/PD/Filler NALUs //! if next video NALU is dpC //! then read and check whether it belongs to DPA (and DPB, if present), if yes, use it, done //! else //! use the DPA (and the DPB if present) /* LC: inserting the code related to DP processing, mainly copying some of the parts related to NALU_TYPE_SLICE, NALU_TYPE_IDR. */ if(expected_slice_type != NALU_TYPE_DPA) { /* oops... we found the next slice, go back! */ fseek(bits, ftell_position, SEEK_SET); FreeNALU(nalu); return current_header; } img->idr_flag = (nalu->nal_unit_type == NALU_TYPE_IDR); img->nal_reference_idc = nalu->nal_reference_idc; img->disposable_flag = (nalu->nal_reference_idc == NALU_PRIORITY_DISPOSABLE); currSlice->dp_mode = PAR_DP_3; currSlice->max_part_nr = 3; currSlice->ei_flag = 0; currStream = currSlice->partArr[0].bitstream; currStream->ei_flag = 0; currStream->frame_bitoffset = currStream->read_len = 0; memcpy (currStream->streamBuffer, &nalu->buf[1], nalu->len-1); currStream->code_len = currStream->bitstream_length = RBSPtoSODB(currStream->streamBuffer, nalu->len-1); //++ 剔除停止比特和填充比特 BitsUsedByHeader = FirstPartOfSliceHeader(); UseParameterSet (currSlice->pic_parameter_set_id); BitsUsedByHeader += RestOfSliceHeader (); FmoInit (active_pps, active_sps); if(is_new_picture()) { init_picture(img, input); current_header = SOP; CheckZeroByteVCL(nalu, &ret); } else current_header = SOS; init_lists(img->type, img->currentSlice->structure); reorder_lists (img->type, img->currentSlice); if (img->structure==FRAME) { init_mbaff_lists(); } // From here on, active_sps, active_pps and the slice header are valid if (img->MbaffFrameFlag) img->current_mb_nr = currSlice->start_mb_nr << 1="" style="color: #0000ff">else img->current_mb_nr = currSlice->start_mb_nr; /* LC: Now I need to read the slice ID, which depends on the value of redundant_pic_cnt_present_flag (pag.49). */ slice_id_a = ue_v("NALU:SLICE_A slice_idr", currStream); if (active_pps->entropy_coding_mode_flag) { int ByteStartPosition = currStream->frame_bitoffset/8; if (currStream->frame_bitoffset%8 != 0) { ByteStartPosition++; } arideco_start_decoding (&currSlice->partArr[0].de_cabac, currStream->streamBuffer, ByteStartPosition, &currStream->read_len, img->type); } // printf ("read_new_slice: returning %s/n", current_header == SOP?"SOP":"SOS"); break; case NALU_TYPE_DPB: /* LC: inserting the code related to DP processing */ currStream = currSlice->partArr[1].bitstream; currStream->ei_flag = 0; currStream->frame_bitoffset = currStream->read_len = 0; memcpy (currStream->streamBuffer, &nalu->buf[1], nalu->len-1); currStream->code_len = currStream->bitstream_length = RBSPtoSODB(currStream->streamBuffer, nalu->len-1); slice_id_b = ue_v("NALU:SLICE_B slice_idr", currStream); if (active_pps->redundant_pic_cnt_present_flag) redundant_pic_cnt_b = ue_v("NALU:SLICE_B redudand_pic_cnt", currStream); else redundant_pic_cnt_b = 0; /* LC: Initializing CABAC for the current data stream. */ if (active_pps->entropy_coding_mode_flag) { int ByteStartPosition = currStream->frame_bitoffset/8; if (currStream->frame_bitoffset % 8 != 0) ByteStartPosition++; arideco_start_decoding (&currSlice->partArr[1].de_cabac, currStream->streamBuffer, ByteStartPosition, &currStream->read_len, img->type); } /* LC: resilience code to be inserted */ /* FreeNALU(nalu); */ /* return current_header; */ break;
IDR参数解析/*! 
   
   
   
   
[cpp] view plain copy print ?
  1. <pre name="code" class="cpp"> ************************************************************************  
  2.  * /brief  
  3.  *    read the first part of the header (only the pic_parameter_set_id)  
  4.  * /return  
  5.  *    Length of the first part of the slice header (in bits)  
  6.  ************************************************************************  
  7.  */  
  8. //++ 参见标准7.3.3   
  9. int FirstPartOfSliceHeader()  
  10. {  
  11.   Slice *currSlice = img->currentSlice;  
  12.   int dP_nr = assignSE2partition[currSlice->dp_mode][SE_HEADER];  
  13.   DataPartition *partition = &(currSlice->partArr[dP_nr]);  
  14.   Bitstream *currStream = partition->bitstream;  
  15.   int tmp;  
  16.   
  17.   UsedBits= partition->bitstream->frame_bitoffset; // was hardcoded to 31 for previous start-code. This is better.   
  18.   
  19.   // Get first_mb_in_slice   
  20.   currSlice->start_mb_nr = ue_v ("SH: first_mb_in_slice", currStream);  
  21.   
  22.   tmp = ue_v ("SH: slice_type", currStream);  
  23.     
  24.   if (tmp>4) tmp -=5;  
  25.   
  26.   img->type = currSlice->picture_type = (SliceType) tmp;  
  27.   
  28.   currSlice->pic_parameter_set_id = ue_v ("SH: pic_parameter_set_id", currStream);  
  29.     
  30.   return UsedBits;  
  31. }  

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