uvg266/src/encoder.c

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/**
* HEVC Encoder
* - Marko Viitanen ( fador at iki.fi ), Tampere University of Technology, Department of Computer Systems.
*/
/*! \file encoder.c
\brief Encoding related functions
\author Marko Viitanen
\date 2012-06
Encoder main level
*/
/* Suppress some windows warnings */
#ifdef WIN32
#define _CRT_SECURE_NO_WARNINGS
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "global.h"
#include "config.h"
#include "encoder.h"
#include "cabac.h"
#include "picture.h"
#include "nal.h"
void init_encoder_control(encoder_control* control,bitstream* output)
{
control->stream = output;
}
void init_encoder_input(encoder_input* input,FILE* inputfile, uint32_t width, uint32_t height)
{
int i;
input->file = inputfile;
input->width = width;
input->height = height;
input->height_in_LCU = height / LCU_WIDTH;
input->width_in_LCU = width / LCU_WIDTH;
if(input->height_in_LCU * LCU_WIDTH < height)
input->height_in_LCU++;
if(input->width_in_LCU * LCU_WIDTH < width)
input->width_in_LCU++;
input->cur_pic.width = width;
input->cur_pic.height = height;
input->cur_pic.referenced = 0;
/* Allocate buffers */
input->cur_pic.yData = (uint8_t *)malloc(width*height);
input->cur_pic.uData = (uint8_t *)malloc((width*height)>>2);
input->cur_pic.vData = (uint8_t *)malloc((width*height)>>2);
/* Allocate memory for CU info */
input->cur_pic.CU = (CU_info*)malloc((MAX_DEPTH+1)*sizeof(CU_info*));
for(i=0; i < MAX_DEPTH+1; i++)
{
input->cur_pic.CU[i] = (CU_info*)malloc((input->height_in_LCU<<2)*(input->width_in_LCU<<2)*sizeof(CU_info));
memset(input->cur_pic.CU[i], 0, (input->height_in_LCU<<2)*(input->width_in_LCU<<2)*sizeof(CU_info));
}
}
void encode_one_frame(encoder_control* encoder)
{
/* output parameters before first frame */
if(encoder->frame == 0)
{
encode_seq_parameter_set(encoder);
bitstream_align(encoder->stream);
bitstream_flush(encoder->stream);
nal_write(encoder->output, encoder->stream->buffer, encoder->stream->buffer_pos, 1, NAL_SEQ_PARAMETER_SET, 1);
bitstream_clear_buffer(encoder->stream);
encode_pic_parameter_set(encoder);
bitstream_align(encoder->stream);
bitstream_flush(encoder->stream);
nal_write(encoder->output, encoder->stream->buffer, encoder->stream->buffer_pos, 1, NAL_PIC_PARAMETER_SET, 0);
bitstream_clear_buffer(encoder->stream);
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/* First slice is IDR */
cabac_start(&cabac);
encoder->in.cur_pic.type = NAL_IDR_SLICE;
encode_slice_header(encoder);
bitstream_align(encoder->stream);
encode_slice_data(encoder);
cabac_flush(&cabac);
bitstream_align(encoder->stream);
bitstream_flush(encoder->stream);
nal_write(encoder->output, encoder->stream->buffer, encoder->stream->buffer_pos, 0, NAL_IDR_SLICE, 0);
bitstream_clear_buffer(encoder->stream);
}
else if(encoder->frame < 3)
{
cabac_start(&cabac);
encoder->in.cur_pic.type = NAL_NONIDR_SLICE;
encode_slice_header(encoder);
bitstream_align(encoder->stream);
encode_slice_data(encoder);
cabac_flush(&cabac);
bitstream_align(encoder->stream);
bitstream_flush(encoder->stream);
nal_write(encoder->output, encoder->stream->buffer, encoder->stream->buffer_pos, 0, NAL_NONIDR_SLICE, 0);
bitstream_clear_buffer(encoder->stream);
}
}
void encode_pic_parameter_set(encoder_control* encoder)
{
#ifdef _DEBUG
printf("=========== Picture Parameter Set ID: 0 ===========\n");
#endif
WRITE_UE(encoder->stream, 0, "pic_parameter_set_id");
WRITE_UE(encoder->stream, 0, "seq_parameter_set_id");
WRITE_U(encoder->stream, 0, 1, "sign_data_hiding_flag");
WRITE_U(encoder->stream, 0, 1, "cabac_init_present_flag");
WRITE_U(encoder->stream, 0, 3, "num_ref_idx_l0_default_active_minus1");
WRITE_U(encoder->stream, 0, 3, "num_ref_idx_l1_default_active_minus1");
/*
//Should be this
WRITE_UE(encoder->stream, 0, "num_ref_idx_l0_default_active_minus1");
WRITE_UE(encoder->stream, 0, "num_ref_idx_l1_default_active_minus1");
*/
WRITE_SE(encoder->stream, encoder->QP-26, "pic_init_qp_minus26");
WRITE_U(encoder->stream, 0, 1, "constrained_intra_pred_flag");
WRITE_U(encoder->stream, 0, 1, "enable_temporal_mvp_flag");
WRITE_U(encoder->stream, 0, 2, "slice_granularity");
WRITE_UE(encoder->stream, 0, "max_cu_qp_delta_depth");
WRITE_SE(encoder->stream, 0, "cb_qp_offset");
WRITE_SE(encoder->stream, 0, "cr_qp_offset");
WRITE_U(encoder->stream, 0, 1, "weighted_pred_flag");
WRITE_U(encoder->stream, 0, 2, "weighted_bipred_idc");
WRITE_U(encoder->stream, 1, 1, "output_flag_present_flag");
WRITE_U(encoder->stream, 0, 1, "deblocking_filter_control_present_flag");
WRITE_UE(encoder->stream, 0, "log2_parallel_merge_level_minus2");
WRITE_U(encoder->stream, 0, 1, "pps_extension_flag");
}
void encode_seq_parameter_set(encoder_control* encoder)
{
#ifdef _DEBUG
printf("=========== Sequence Parameter Set ID: 0 ===========\n");
#endif
WRITE_U(encoder->stream, 0, 8, "profile_idc");
WRITE_U(encoder->stream, 0, 8, "reserved_zero_8bits");
WRITE_U(encoder->stream, 0, 8, "level_idc");
WRITE_UE(encoder->stream, 0, "seq_parameter_set_id");
WRITE_UE(encoder->stream, 1, "chroma_format_idc"); /* 0 = 4:0:0, 1 = 4:2:0, 2 = 4:2:2, 3 = 4:4:4 */
WRITE_U(encoder->stream, 0, 3, "max_temporal_layers_minus1");
WRITE_UE(encoder->stream, encoder->in.width, "pic_width_in_luma_samples");
WRITE_UE(encoder->stream, encoder->in.height, "pic_height_in_luma_samples");
WRITE_U(encoder->stream, 0, 1, "pic_cropping_flag");
WRITE_UE(encoder->stream, 0, "bit_depth_luma_minus8");
WRITE_UE(encoder->stream, 0, "bit_depth_chroma_minus8");
WRITE_U(encoder->stream, 1, 1, "pcm_enabled_flag");
WRITE_U(encoder->stream, 7, 4, "pcm_bit_depth_luma_minus1");
WRITE_U(encoder->stream, 7, 4, "pcm_bit_depth_chroma_minus1");
WRITE_U(encoder->stream, 0, 1, "qpprime_y_zero_transquant_bypass_flag");
WRITE_UE(encoder->stream, 4, "log2_max_pic_order_cnt_lsb_minus4");
WRITE_UE(encoder->stream, 0, "max_dec_pic_buffering");
WRITE_UE(encoder->stream, 0, "num_reorder_pics");
WRITE_UE(encoder->stream, 0, "max_latency_increase");
WRITE_U(encoder->stream, 0, 1, "restricted_ref_pic_lists_flag");
WRITE_UE(encoder->stream, 1, "log2_min_coding_block_size_minus3");
WRITE_UE(encoder->stream, 2, "log2_diff_max_min_coding_block_size");
WRITE_UE(encoder->stream, 0, "log2_min_transform_block_size_minus2");
WRITE_UE(encoder->stream, 3, "log2_diff_max_min_transform_block_size");
//If log2MinCUSize == 3
//WRITE_U(encoder->stream, 0, 1, "DisInter4x4");
//IF PCM
{
WRITE_UE(encoder->stream, 0, "log2_min_pcm_coding_block_size_minus3");
WRITE_UE(encoder->stream, 2, "log2_diff_max_min_pcm_coding_block_size");
}
WRITE_UE(encoder->stream, 2, "max_transform_hierarchy_depth_inter");
WRITE_UE(encoder->stream, 2, "max_transform_hierarchy_depth_intra");
WRITE_U(encoder->stream, 0, 1, "scaling_list_enable_flag");
WRITE_U(encoder->stream, 0, 1, "chroma_pred_from_luma_enabled_flag");
WRITE_U(encoder->stream, 0, 1, "transform_skip_enabled_flag");
WRITE_U(encoder->stream, 0, 1, "deblocking_filter_in_aps_enabled_flag");
WRITE_U(encoder->stream, 0, 1, "seq_loop_filter_across_slices_enabled_flag");
WRITE_U(encoder->stream, 0, 1, "asymmetric_motion_partitions_enabled_flag");
WRITE_U(encoder->stream, 0, 1, "nsrqt_enabled_flag");
WRITE_U(encoder->stream, 0, 1, "sample_adaptive_offset_enabled_flag");
WRITE_U(encoder->stream, 0, 1, "adaptive_loop_filter_enabled_flag");
//IF PCM
WRITE_U(encoder->stream, 1, 1, "pcm_loop_filter_disable_flag");
//endif
WRITE_U(encoder->stream, 0, 1, "temporal_id_nesting_flag");
WRITE_UE(encoder->stream, 0, "num_short_term_ref_pic_sets");
WRITE_U(encoder->stream, 0, 1, "long_term_ref_pics_present_flag");
WRITE_U(encoder->stream, 0, 2, "tiles_or_entropy_coding_sync_idc");
WRITE_U(encoder->stream, 0, 1, "sps_extension_flag");
//WRITE_U(encoder->stream, 0, 8, "stuffing");
}
void encode_slice_header(encoder_control* encoder)
{
#ifdef _DEBUG
printf("=========== Slice ===========\n");
#endif
WRITE_U(encoder->stream, 1, 1, "first_slice_in_pic_flag");
WRITE_UE(encoder->stream, SLICE_I, "slice_type");
WRITE_U(encoder->stream, 0, 1, "entropy_slice_flag");
// if !entropy_slice_flag
WRITE_UE(encoder->stream, 0, "pic_parameter_set_id");
//if output_flag_present_flag
WRITE_U(encoder->stream, 1, 1, "pic_output_flag");
//end if
//if( IdrPicFlag ) <- nal_unit_type == 5
if(encoder->in.cur_pic.type == NAL_IDR_SLICE)
{
WRITE_UE(encoder->stream, encoder->frame&3, "idr_pic_id");
WRITE_U(encoder->stream, 0, 1, "no_output_of_prior_pics_flag");
}
else
{
WRITE_U(encoder->stream, encoder->frame, 8, "pic_order_cnt_lsb");
WRITE_U(encoder->stream, 1, 1, "short_term_ref_pic_set_sps_flag");
WRITE_UE(encoder->stream, 0, "short_term_ref_pic_set_idx");
}
//end if
//end if
/*
Skip unpresent flags */
// if !entropy_slice_flag
WRITE_UE(encoder->stream, 0, "slice_qp_delta");
WRITE_UE(encoder->stream, 0, "5_minus_max_num_merge_cand");
}
cabac_ctx *SplitFlagSCModel;
cabac_ctx g_SplitFlagSCModel[3];
cabac_ctx PCMFlagSCModel;
cabac_ctx PartSizeSCModel;
void encode_slice_data(encoder_control* encoder)
{
uint16_t xCtb,yCtb;
/* Initialize contexts */
cxt_init(&g_SplitFlagSCModel[0], encoder->QP, INIT_SPLIT_FLAG[SLICE_I][0]);
cxt_init(&g_SplitFlagSCModel[1], encoder->QP, INIT_SPLIT_FLAG[SLICE_I][1]);
cxt_init(&g_SplitFlagSCModel[2], encoder->QP, INIT_SPLIT_FLAG[SLICE_I][2]);
cxt_init(&PartSizeSCModel, encoder->QP, 154);
//g_SplitFlagSCModel[1].ucState = 47;
//g_SplitFlagSCModel[2].ucState = 36;
for(yCtb = 0; yCtb < encoder->in.height_in_LCU; yCtb++)
{
uint8_t lastCUy = (yCtb == (encoder->in.height_in_LCU-1))?1:0;
for(xCtb = 0; xCtb < encoder->in.width_in_LCU; xCtb++)
{
uint8_t lastCUx = (xCtb == (encoder->in.width_in_LCU-1))?1:0;
uint8_t depth = 0;
encode_coding_tree(encoder, xCtb<<2,yCtb<<2, depth);
//Terminating bit
if(!lastCUx || !lastCUy)
{
cabac_encodeBinTrm(&cabac, 0);
}
else
{
cabac_encodeBinTrm(&cabac, 1);
}
}
}
}
void encode_coding_tree(encoder_control* encoder,uint16_t xCtb,uint16_t yCtb, uint8_t depth)
{
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int i,x,y;
uint8_t split_flag = (depth!=1)?1:0;
uint8_t split_model = 0;
//ToDo: GET REAL VALUE
if(xCtb > 0 && GET_SPLITDATA(&encoder->in.cur_pic.CU[depth][(xCtb>>(MAX_DEPTH-depth))-1+(yCtb>>(MAX_DEPTH-depth))*(encoder->in.width_in_LCU<<MAX_DEPTH)]) == 1)
{
split_model++;
}
if(yCtb > 0 && GET_SPLITDATA(&encoder->in.cur_pic.CU[depth][(xCtb>>(MAX_DEPTH-depth))+((yCtb>>(MAX_DEPTH-depth))-1)*(encoder->in.width_in_LCU<<MAX_DEPTH)]) == 1)
{
split_model++;
}
cabac.ctx = &g_SplitFlagSCModel[split_model];
if((yCtb > 0 && xCtb > 0))
{
SplitFlagSCModel = &g_SplitFlagSCModel[2];
printf("Model: 2\n");
}
else if(yCtb > 0 || xCtb > 0)
{
SplitFlagSCModel = &g_SplitFlagSCModel[1];
printf("Model: 1\n");
}
else
{
SplitFlagSCModel = &g_SplitFlagSCModel[0];
printf("Model: 0\n");
}
cabac.ctx = SplitFlagSCModel;//&g_SplitFlagSCModel[split_model];
if(depth == 1)
{
cabac.ctx = &g_SplitFlagSCModel[0];
}
/*
if((yCtb > 0 && xCtb > 0))
{
SplitFlagSCModel = &g_SplitFlagSCModel[2];
printf("Model: 2\n");
}
else if(yCtb > 0 || xCtb > 0)
{
SplitFlagSCModel = &g_SplitFlagSCModel[1];
printf("Model: 1\n");
}
else
{
SplitFlagSCModel = &g_SplitFlagSCModel[0];
printf("Model: 0\n");
}
cabac.ctx = SplitFlagSCModel;//&g_SplitFlagSCModel[split_model];
if(depth == 1)
{
cabac.ctx = &g_SplitFlagSCModel[0];
}
*/
if(depth != MAX_DEPTH)
{
SET_SPLITDATA(&encoder->in.cur_pic.CU[depth][xCtb>>(MAX_DEPTH-depth)+(yCtb>>(MAX_DEPTH-depth))*(encoder->in.width_in_LCU<<MAX_DEPTH)],split_flag);
CABAC_BIN(&cabac, split_flag, "SplitFlag");
if(split_flag)
{
uint8_t change = 1<<(MAX_DEPTH-1-depth);
encode_coding_tree(encoder,xCtb,yCtb,depth+1);
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encode_coding_tree(encoder,xCtb+change,yCtb,depth+1);
encode_coding_tree(encoder,xCtb,yCtb+change,depth+1);
encode_coding_tree(encoder,xCtb+change,yCtb+change,depth+1);
return;
}
}
/* coding_unit( x0, y0, log2CbSize ) */
/* prediction_unit 2Nx2N*/
//if !intra PREDMODE
/* if depth = MAX_DEPTH */
//PartSize
if(depth == 2)
{
cabac.ctx = &PartSizeSCModel;
CABAC_BIN(&cabac, 1, "PartSize");
}
/*end partsize*/
//If MODE_INTRA
//cabac.ctx = &PCMFlagSCModel;
cabac_encodeBinTrm(&cabac, 1);
printf("\tIPCMFlag = 1\n");
cabac_finish(&cabac);
WRITE_U(cabac.stream, 1, 1, "stop_bit");
WRITE_U(cabac.stream, 0, 1, "numSubseqIPCM_flag");
bitstream_align(cabac.stream);
/* PCM sample */
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{
uint8_t *base = &encoder->in.cur_pic.yData[xCtb*16 + (yCtb*16)*encoder->in.width];
uint8_t *baseCb = &encoder->in.cur_pic.uData[(xCtb*8 + (yCtb*8)*encoder->in.width/2)];
uint8_t *baseCr = &encoder->in.cur_pic.vData[(xCtb*8 + (yCtb*8)*encoder->in.width/2)];
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for(y = 0; y < 32; y++)
{
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for(x = 0; x < 32; x++)
{
bitstream_put(cabac.stream, base[x+y*encoder->in.width], 8);
}
}
//Cb
for(y = 0; y < 16; y++)
{
for(x = 0; x < 16; x++)
{
bitstream_put(cabac.stream, baseCb[x+y*(encoder->in.width>>1)], 8);
}
}
//Cr
for(y = 0; y < 16; y++)
{
for(x = 0; x < 16; x++)
{
bitstream_put(cabac.stream, baseCr[x+y*(encoder->in.width>>1)], 8);
}
}
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}
/* end PCM sample */
cabac_start(&cabac);
//endif
/* end prediction unit */
//cabac_encodeBin(&cabac, 0); //prev_intra_luma_pred_flag
//cabac_encodeBin(&cabac, 1); //rem_intra_luma_pred_mode
/* end coding_unit */
}