/******************************************************************************
*
* Copyright (C) 2012 Ittiam Systems Pvt Ltd, Bangalore
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
******************************************************************************/
/**
*******************************************************************************
* @file
* ihevc_boundary_strength.c
*
* @brief
* Contains functions for computing boundary strength
*
* @author
* Harish
*
* @par List of Functions:
*
* @remarks
* None
*
*******************************************************************************
*/
/*****************************************************************************/
/* File Includes */
/*****************************************************************************/
#include <stdio.h>
#include <stddef.h>
#include <stdlib.h>
#include <string.h>
#include "ihevc_typedefs.h"
#include "iv.h"
#include "ivd.h"
#include "ihevcd_cxa.h"
#include "ithread.h"
#include "ihevc_defs.h"
#include "ihevc_debug.h"
#include "ihevc_defs.h"
#include "ihevc_structs.h"
#include "ihevc_macros.h"
#include "ihevc_platform_macros.h"
#include "ihevc_cabac_tables.h"
#include "ihevc_error.h"
#include "ihevc_common_tables.h"
#include "ihevcd_trace.h"
#include "ihevcd_defs.h"
#include "ihevcd_function_selector.h"
#include "ihevcd_structs.h"
#include "ihevcd_error.h"
#include "ihevcd_nal.h"
#include "ihevcd_bitstream.h"
#include "ihevcd_job_queue.h"
#include "ihevcd_utils.h"
#include "ihevcd_profile.h"
/*****************************************************************************/
/* Function Prototypes */
/*****************************************************************************/
#define SET_NGBHR_ALL_AVAIL(avail) avail = 0x1F;
#define SET_NGBHR_BOTLEFT_NOTAVAIL(avail) avail &= ~0x10;
#define SET_NGBHR_LEFT_NOTAVAIL(avail) avail &= ~0x8;
#define SET_NGBHR_TOPLEFT_NOTAVAIL(avail) avail &= ~0x4;
#define SET_NGBHR_TOP_NOTAVAIL(avail) avail &= ~0x2;
#define SET_NGBHR_TOPRIGHT_NOTAVAIL(avail) avail &= ~0x1;
WORD32 ihevcd_pu_boundary_strength(pu_t *ps_pu,
pu_t *ps_ngbr_pu)
{
WORD32 i4_bs;
UWORD32 l0_ref_pic_buf_id, l1_ref_pic_buf_id;
UWORD32 ngbr_l0_ref_pic_buf_id, ngbr_l1_ref_pic_buf_id;
WORD16 i2_mv_x0, i2_mv_y0, i2_mv_x1, i2_mv_y1;
WORD16 i2_ngbr_mv_x0, i2_ngbr_mv_y0, i2_ngbr_mv_x1, i2_ngbr_mv_y1;
WORD32 num_mv, ngbr_num_mv;
num_mv = (PRED_BI == ps_pu->b2_pred_mode) ? 2 : 1;
ngbr_num_mv = (PRED_BI == ps_ngbr_pu->b2_pred_mode) ? 2 : 1;
l0_ref_pic_buf_id = ps_pu->mv.i1_l0_ref_pic_buf_id;
l1_ref_pic_buf_id = ps_pu->mv.i1_l1_ref_pic_buf_id;
ngbr_l0_ref_pic_buf_id = ps_ngbr_pu->mv.i1_l0_ref_pic_buf_id;
ngbr_l1_ref_pic_buf_id = ps_ngbr_pu->mv.i1_l1_ref_pic_buf_id;
i2_mv_x0 = ps_pu->mv.s_l0_mv.i2_mvx;
i2_mv_y0 = ps_pu->mv.s_l0_mv.i2_mvy;
i2_mv_x1 = ps_pu->mv.s_l1_mv.i2_mvx;
i2_mv_y1 = ps_pu->mv.s_l1_mv.i2_mvy;
i2_ngbr_mv_x0 = ps_ngbr_pu->mv.s_l0_mv.i2_mvx;
i2_ngbr_mv_y0 = ps_ngbr_pu->mv.s_l0_mv.i2_mvy;
i2_ngbr_mv_x1 = ps_ngbr_pu->mv.s_l1_mv.i2_mvx;
i2_ngbr_mv_y1 = ps_ngbr_pu->mv.s_l1_mv.i2_mvy;
/* If two motion vectors are used */
if((2 == num_mv) &&
(2 == ngbr_num_mv))
{
if((l0_ref_pic_buf_id == ngbr_l0_ref_pic_buf_id && l1_ref_pic_buf_id == ngbr_l1_ref_pic_buf_id) ||
(l0_ref_pic_buf_id == ngbr_l1_ref_pic_buf_id && l1_ref_pic_buf_id == ngbr_l0_ref_pic_buf_id))
{
if(l0_ref_pic_buf_id != l1_ref_pic_buf_id) /* Different L0 and L1 */
{
if(l0_ref_pic_buf_id == ngbr_l0_ref_pic_buf_id)
{
i4_bs = (ABS(i2_mv_x0 - i2_ngbr_mv_x0) < 4) &&
(ABS(i2_mv_y0 - i2_ngbr_mv_y0) < 4) &&
(ABS(i2_mv_x1 - i2_ngbr_mv_x1) < 4) &&
(ABS(i2_mv_y1 - i2_ngbr_mv_y1) < 4) ? 0 : 1;
}
else
{
i4_bs = (ABS(i2_mv_x0 - i2_ngbr_mv_x1) < 4) &&
(ABS(i2_mv_y0 - i2_ngbr_mv_y1) < 4) &&
(ABS(i2_mv_x1 - i2_ngbr_mv_x0) < 4) &&
(ABS(i2_mv_y1 - i2_ngbr_mv_y0) < 4) ? 0 : 1;
}
}
else /* Same L0 and L1 */
{
i4_bs = ((ABS(i2_mv_x0 - i2_ngbr_mv_x0) >= 4) ||
(ABS(i2_mv_y0 - i2_ngbr_mv_y0) >= 4) ||
(ABS(i2_mv_x1 - i2_ngbr_mv_x1) >= 4) ||
(ABS(i2_mv_y1 - i2_ngbr_mv_y1) >= 4)) &&
((ABS(i2_mv_x0 - i2_ngbr_mv_x1) >= 4) ||
(ABS(i2_mv_y0 - i2_ngbr_mv_y1) >= 4) ||
(ABS(i2_mv_x1 - i2_ngbr_mv_x0) >= 4) ||
(ABS(i2_mv_y1 - i2_ngbr_mv_y0) >= 4)) ? 1 : 0;
}
}
else /* If the reference pictures used are different */
{
i4_bs = 1;
}
}
/* If one motion vector is used in both PUs */
else if((1 == num_mv) &&
(1 == ngbr_num_mv))
{
WORD16 i2_mv_x, i2_mv_y;
WORD16 i2_ngbr_mv_x, i2_ngbr_mv_y;
UWORD32 ref_pic_buf_id, ngbr_ref_pic_buf_id;
if(PRED_L0 == ps_pu->b2_pred_mode)
{
i2_mv_x = i2_mv_x0;
i2_mv_y = i2_mv_y0;
ref_pic_buf_id = l0_ref_pic_buf_id;
}
else
{
i2_mv_x = i2_mv_x1;
i2_mv_y = i2_mv_y1;
ref_pic_buf_id = l1_ref_pic_buf_id;
}
if(PRED_L0 == ps_ngbr_pu->b2_pred_mode)
{
i2_ngbr_mv_x = i2_ngbr_mv_x0;
i2_ngbr_mv_y = i2_ngbr_mv_y0;
ngbr_ref_pic_buf_id = ngbr_l0_ref_pic_buf_id;
}
else
{
i2_ngbr_mv_x = i2_ngbr_mv_x1;
i2_ngbr_mv_y = i2_ngbr_mv_y1;
ngbr_ref_pic_buf_id = ngbr_l1_ref_pic_buf_id;
}
i4_bs = (ref_pic_buf_id == ngbr_ref_pic_buf_id) &&
(ABS(i2_mv_x - i2_ngbr_mv_x) < 4) &&
(ABS(i2_mv_y - i2_ngbr_mv_y) < 4) ? 0 : 1;
}
/* If the no. of motion vectors is not the same */
else
{
i4_bs = 1;
}
return i4_bs;
}
/* QP is also populated in the same function */
WORD32 ihevcd_ctb_boundary_strength_islice(bs_ctxt_t *ps_bs_ctxt)
{
pps_t *ps_pps;
sps_t *ps_sps;
tu_t *ps_tu;
UWORD32 *pu4_vert_bs;
UWORD32 *pu4_horz_bs;
WORD32 bs_strd;
WORD32 vert_bs0_tmp;
WORD32 horz_bs0_tmp;
UWORD8 *pu1_qp;
WORD32 qp_strd;
UWORD32 u4_qp_const_in_ctb;
WORD32 ctb_indx;
WORD32 i4_tu_cnt;
WORD32 log2_ctb_size;
WORD32 ctb_size;
WORD8 i1_loop_filter_across_tiles_enabled_flag;
WORD8 i1_loop_filter_across_slices_enabled_flag;
WORD32 i;
PROFILE_DISABLE_BOUNDARY_STRENGTH();
ps_pps = ps_bs_ctxt->ps_pps;
ps_sps = ps_bs_ctxt->ps_sps;
i1_loop_filter_across_tiles_enabled_flag = ps_pps->i1_loop_filter_across_tiles_enabled_flag;
i1_loop_filter_across_slices_enabled_flag = ps_bs_ctxt->ps_slice_hdr->i1_slice_loop_filter_across_slices_enabled_flag;
i4_tu_cnt = ps_bs_ctxt->i4_ctb_tu_cnt;
log2_ctb_size = ps_sps->i1_log2_ctb_size;
ctb_size = (1 << log2_ctb_size);
/* strides are in units of number of bytes */
/* ctb_size * ctb_size / 8 / 16 is the number of bytes needed per CTB */
bs_strd = (ps_sps->i2_pic_wd_in_ctb + 1) << (2 * log2_ctb_size - 7);
pu4_vert_bs = (UWORD32 *)((UWORD8 *)ps_bs_ctxt->pu4_pic_vert_bs +
(ps_bs_ctxt->i4_ctb_x << (2 * log2_ctb_size - 7)) +
ps_bs_ctxt->i4_ctb_y * bs_strd);
pu4_horz_bs = (UWORD32 *)((UWORD8 *)ps_bs_ctxt->pu4_pic_horz_bs +
(ps_bs_ctxt->i4_ctb_x << (2 * log2_ctb_size - 7)) +
ps_bs_ctxt->i4_ctb_y * bs_strd);
/* ctb_size/8 elements per CTB */
qp_strd = ps_sps->i2_pic_wd_in_ctb << (log2_ctb_size - 3);
pu1_qp = ps_bs_ctxt->pu1_pic_qp + ((ps_bs_ctxt->i4_ctb_x + ps_bs_ctxt->i4_ctb_y * qp_strd) << (log2_ctb_size - 3));
ctb_indx = ps_bs_ctxt->i4_ctb_x + ps_sps->i2_pic_wd_in_ctb * ps_bs_ctxt->i4_ctb_y;
u4_qp_const_in_ctb = ps_bs_ctxt->pu1_pic_qp_const_in_ctb[ctb_indx >> 3] & (1 << (ctb_indx & 7));
vert_bs0_tmp = pu4_vert_bs[0] & (0xFFFFFFFF >> (sizeof(UWORD32) * 8 - ctb_size / 2));
horz_bs0_tmp = pu4_horz_bs[0] & (0xFFFFFFFF >> (sizeof(UWORD32) * 8 - ctb_size / 2));
/* ctb_size/8 is the number of edges per CTB
* ctb_size/4 is the number of BS values needed per edge
* divided by 8 for the number of bytes
* 2 is the number of bits needed for each BS value */
/*
memset(pu4_vert_bs, 0, (ctb_size / 8 + 1) * (ctb_size / 4) / 8 * 2 );
memset(pu4_horz_bs, 0, (ctb_size / 8) * (ctb_size / 4) / 8 * 2 );
*/
memset(pu4_vert_bs, 0, (1 << (2 * log2_ctb_size - 7)) + ((ctb_size >> 5) << 1));
memset(pu4_horz_bs, 0, (1 << (2 * log2_ctb_size - 7)));
/* pu4_vert_bs[0] has information about the left CTB which is not required when ctb_x = 0 */
if(0 != ps_bs_ctxt->i4_ctb_x)
{
pu4_vert_bs[0] |= vert_bs0_tmp;
}
/* pu4_horz_bs[0] has information about the top CTB which is not required when ctb_y = 0 */
if(0 != ps_bs_ctxt->i4_ctb_y)
{
pu4_horz_bs[0] |= horz_bs0_tmp;
}
ps_tu = ps_bs_ctxt->ps_tu;
/* Populating the QP array - if const_qp_in_ctb flag is one, set only the first element */
if(u4_qp_const_in_ctb)
pu1_qp[0] = ps_tu->b7_qp;
for(i = 0; i < i4_tu_cnt; i++)
{
WORD32 start_pos_x;
WORD32 start_pos_y;
WORD32 tu_size;
UWORD32 u4_bs;
ps_tu = ps_bs_ctxt->ps_tu + i;
/* start_pos_x and start_pos_y are in units of min TU size (4x4) */
start_pos_x = ps_tu->b4_pos_x;
start_pos_y = ps_tu->b4_pos_y;
tu_size = 1 << (ps_tu->b3_size + 2);
tu_size >>= 2; /* TU size divided by 4 */
u4_bs = DUP_LSB_10(tu_size);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_x & 1))
{
WORD32 shift;
shift = start_pos_y * 2;
/* shift += (((start_pos_x >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_x & 2) << (log2_ctb_size - 2));
pu4_vert_bs[start_pos_x >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_y & 1))
{
WORD32 shift;
shift = start_pos_x * 2;
/* shift += (((start_pos_y >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_y & 2) << (log2_ctb_size - 2));
pu4_horz_bs[start_pos_y >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
/* Populating the QP array */
if(0 == u4_qp_const_in_ctb)
{
if(0 == (start_pos_x & 1) && 0 == (start_pos_y & 1))
{
WORD32 row, col;
for(row = start_pos_y; row < start_pos_y + tu_size; row += 2)
{
for(col = start_pos_x; col < start_pos_x + tu_size; col += 2)
{
pu1_qp[(row >> 1) * qp_strd + (col >> 1)] = ps_tu->b7_qp;
}
}
}
}
}
{
/*Determine if the slice is dependent, and is its left neighbor belongs to the same slice, in a different tile*/
UWORD32 ctb_addr;
WORD32 slice_idx, left_slice_idx = -1, top_slice_idx = -1;
/* If left neighbor is not available, then set BS for entire first column to zero */
if(!ps_pps->i1_tiles_enabled_flag)
{
if((0 == i1_loop_filter_across_tiles_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_tile_x) ||
(0 == i1_loop_filter_across_slices_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_slice_x && 0 == ps_bs_ctxt->i4_ctb_slice_y) ||
(0 == ps_bs_ctxt->i4_ctb_x))
{
pu4_vert_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
}
else
{
//If across-tiles is disabled
if((0 == i1_loop_filter_across_tiles_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_tile_x))
{
pu4_vert_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
else
{
ctb_addr = ps_bs_ctxt->i4_ctb_x + (ps_bs_ctxt->i4_ctb_y * ps_sps->i2_pic_wd_in_ctb);
slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
if(ps_bs_ctxt->i4_ctb_x)
{
ctb_addr = (ps_bs_ctxt->i4_ctb_x - 1) + (ps_bs_ctxt->i4_ctb_y * ps_sps->i2_pic_wd_in_ctb);
left_slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
}
/*If the 1st slice in a new tile is a dependent slice*/
if(!((ps_bs_ctxt->ps_slice_hdr->i1_dependent_slice_flag == 1) && (slice_idx == left_slice_idx)))
{
if((0 == i1_loop_filter_across_slices_enabled_flag && (
(0 == ps_bs_ctxt->i4_ctb_slice_x && 0 == ps_bs_ctxt->i4_ctb_slice_y) || (0 == ps_bs_ctxt->i4_ctb_slice_x && 0 == ps_bs_ctxt->i4_ctb_tile_x) ||
((0 == ps_bs_ctxt->i4_ctb_tile_x) && (slice_idx != left_slice_idx)))) ||
(0 == ps_bs_ctxt->i4_ctb_x))
{
pu4_vert_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
}
}
}
ctb_addr = ps_bs_ctxt->i4_ctb_x + (ps_bs_ctxt->i4_ctb_y * ps_sps->i2_pic_wd_in_ctb);
slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
if(ps_bs_ctxt->i4_ctb_y)
{
ctb_addr = (ps_bs_ctxt->i4_ctb_x) + ((ps_bs_ctxt->i4_ctb_y - 1) * ps_sps->i2_pic_wd_in_ctb);
top_slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
}
/* If top neighbor is not available, then set BS for entire first row to zero */
if((0 == i1_loop_filter_across_tiles_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_tile_y)
|| (0 == i1_loop_filter_across_slices_enabled_flag && ((0 == ps_bs_ctxt->i4_ctb_slice_y) || (slice_idx != top_slice_idx)))
|| (0 == ps_bs_ctxt->i4_ctb_y))
{
pu4_horz_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
}
/**
* Set BS of bottom and right frame boundaries to zero if it is an incomplete CTB
* (They might have been set to non zero values because of CBF of the current CTB)
* This block might not be needed for I slices*/
{
WORD32 num_rows_remaining = (ps_sps->i2_pic_height_in_luma_samples - (ps_bs_ctxt->i4_ctb_y << log2_ctb_size)) >> 3;
WORD32 num_cols_remaining = (ps_sps->i2_pic_width_in_luma_samples - (ps_bs_ctxt->i4_ctb_x << log2_ctb_size)) >> 3;
if(num_rows_remaining < (ctb_size >> 3))
{
/* WORD32 offset = (((num_rows_remaining >> 3) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 4));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
WORD32 offset;
offset = (num_rows_remaining >> (6 - log2_ctb_size)) << 2;
if(6 != log2_ctb_size)
offset += (num_rows_remaining & 1) << (log2_ctb_size - 4);
memset(((UWORD8 *)pu4_horz_bs) + offset, 0, 1 << (log2_ctb_size - 4));
}
if(num_cols_remaining < (ctb_size >> 3))
{
/* WORD32 offset = (((num_cols_remaining >> 3) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 4));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
WORD32 offset;
offset = (num_cols_remaining >> (6 - log2_ctb_size)) << 2;
if(6 != log2_ctb_size)
offset += (num_cols_remaining & 1) << (log2_ctb_size - 4);
memset(((UWORD8 *)pu4_vert_bs) + offset, 0, 1 << (log2_ctb_size - 4));
}
}
return 0;
}
WORD32 ihevcd_ctb_boundary_strength_pbslice(bs_ctxt_t *ps_bs_ctxt)
{
sps_t *ps_sps;
pps_t *ps_pps;
WORD32 cur_ctb_idx, next_ctb_idx = 0;
WORD32 i4_tu_cnt;
WORD32 i4_pu_cnt;
tu_t *ps_tu;
UWORD32 *pu4_vert_bs;
UWORD32 *pu4_horz_bs;
WORD32 bs_strd;
WORD32 vert_bs0_tmp;
WORD32 horz_bs0_tmp;
UWORD8 *pu1_qp;
WORD32 qp_strd;
UWORD32 u4_qp_const_in_ctb;
WORD32 ctb_indx;
WORD32 log2_ctb_size;
WORD32 ctb_size;
WORD32 i;
WORD8 i1_loop_filter_across_tiles_enabled_flag;
WORD8 i1_loop_filter_across_slices_enabled_flag;
PROFILE_DISABLE_BOUNDARY_STRENGTH();
ps_sps = ps_bs_ctxt->ps_sps;
ps_pps = ps_bs_ctxt->ps_pps;
log2_ctb_size = ps_sps->i1_log2_ctb_size;
ctb_size = (1 << log2_ctb_size);
/* strides are in units of number of bytes */
/* ctb_size * ctb_size / 8 / 16 is the number of bytes needed per CTB */
bs_strd = (ps_sps->i2_pic_wd_in_ctb + 1) << (2 * log2_ctb_size - 7);
pu4_vert_bs = (UWORD32 *)((UWORD8 *)ps_bs_ctxt->pu4_pic_vert_bs +
(ps_bs_ctxt->i4_ctb_x << (2 * log2_ctb_size - 7)) +
ps_bs_ctxt->i4_ctb_y * bs_strd);
pu4_horz_bs = (UWORD32 *)((UWORD8 *)ps_bs_ctxt->pu4_pic_horz_bs +
(ps_bs_ctxt->i4_ctb_x << (2 * log2_ctb_size - 7)) +
ps_bs_ctxt->i4_ctb_y * bs_strd);
vert_bs0_tmp = pu4_vert_bs[0] & (0xFFFFFFFF >> (sizeof(UWORD32) * 8 - ctb_size / 2));
horz_bs0_tmp = pu4_horz_bs[0] & (0xFFFFFFFF >> (sizeof(UWORD32) * 8 - ctb_size / 2));
ps_tu = ps_bs_ctxt->ps_tu;
/* ctb_size/8 elements per CTB */
qp_strd = ps_sps->i2_pic_wd_in_ctb << (log2_ctb_size - 3);
pu1_qp = ps_bs_ctxt->pu1_pic_qp + ((ps_bs_ctxt->i4_ctb_x + ps_bs_ctxt->i4_ctb_y * qp_strd) << (log2_ctb_size - 3));
ctb_indx = ps_bs_ctxt->i4_ctb_x + ps_sps->i2_pic_wd_in_ctb * ps_bs_ctxt->i4_ctb_y;
u4_qp_const_in_ctb = ps_bs_ctxt->pu1_pic_qp_const_in_ctb[ctb_indx >> 3] & (1 << (ctb_indx & 7));
i1_loop_filter_across_tiles_enabled_flag = ps_pps->i1_loop_filter_across_tiles_enabled_flag;
i1_loop_filter_across_slices_enabled_flag = ps_bs_ctxt->ps_slice_hdr->i1_slice_loop_filter_across_slices_enabled_flag;
/* ctb_size/8 is the number of edges per CTB
* ctb_size/4 is the number of BS values needed per edge
* divided by 8 for the number of bytes
* 2 is the number of bits needed for each BS value */
/*
memset(pu4_vert_bs, 0, (ctb_size / 8 + 1) * (ctb_size / 4) * 2 / 8 );
memset(pu4_horz_bs, 0, (ctb_size / 8) * (ctb_size / 4) * 2 / 8 );
*/
memset(pu4_vert_bs, 0, (1 << (2 * log2_ctb_size - 7)) + (ctb_size >> 4));
memset(pu4_horz_bs, 0, (1 << (2 * log2_ctb_size - 7)));
/* pu4_vert_bs[0] has information about the left CTB which is not required when ctb_x = 0 */
if(0 != ps_bs_ctxt->i4_ctb_x)
{
pu4_vert_bs[0] |= vert_bs0_tmp;
}
/* pu4_horz_bs[0] has information about the top CTB which is not required when ctb_y = 0 */
if(0 != ps_bs_ctxt->i4_ctb_y)
{
pu4_horz_bs[0] |= horz_bs0_tmp;
}
/* pu4_horz_bs[bs_strd / 4] corresponds to pu4_horz_bs[0] of the bottom CTB */
*(UWORD32 *)((UWORD8 *)pu4_horz_bs + bs_strd) = 0;
cur_ctb_idx = ps_bs_ctxt->i4_ctb_x
+ ps_bs_ctxt->i4_ctb_y * (ps_sps->i2_pic_wd_in_ctb);
next_ctb_idx = ps_bs_ctxt->i4_next_tu_ctb_cnt;
if(1 == ps_bs_ctxt->ps_codec->i4_num_cores)
{
i4_tu_cnt = ps_bs_ctxt->pu4_pic_tu_idx[next_ctb_idx] - ps_bs_ctxt->pu4_pic_tu_idx[cur_ctb_idx % RESET_TU_BUF_NCTB];
}
else
{
i4_tu_cnt = ps_bs_ctxt->pu4_pic_tu_idx[next_ctb_idx] - ps_bs_ctxt->pu4_pic_tu_idx[cur_ctb_idx];
}
ps_tu = ps_bs_ctxt->ps_tu;
if(u4_qp_const_in_ctb)
pu1_qp[0] = ps_tu->b7_qp;
/* For all TUs in the CTB For left and top edges, check if there are coded coefficients on either sides of the edge */
for(i = 0; i < i4_tu_cnt; i++)
{
WORD32 start_pos_x;
WORD32 start_pos_y;
WORD32 end_pos_x;
WORD32 end_pos_y;
WORD32 tu_size;
UWORD32 u4_bs;
WORD32 intra_flag;
UWORD8 *pu1_pic_intra_flag;
ps_tu = ps_bs_ctxt->ps_tu + i;
start_pos_x = ps_tu->b4_pos_x;
start_pos_y = ps_tu->b4_pos_y;
tu_size = 1 << (ps_tu->b3_size + 2);
tu_size >>= 2;
end_pos_x = start_pos_x + tu_size;
end_pos_y = start_pos_y + tu_size;
{
WORD32 tu_abs_x = (ps_bs_ctxt->i4_ctb_x << log2_ctb_size) + (start_pos_x << 2);
WORD32 tu_abs_y = (ps_bs_ctxt->i4_ctb_y << log2_ctb_size) + (start_pos_y << 2);
WORD32 numbytes_row = (ps_sps->i2_pic_width_in_luma_samples + 63) / 64;
pu1_pic_intra_flag = ps_bs_ctxt->ps_codec->pu1_pic_intra_flag;
pu1_pic_intra_flag += (tu_abs_y >> 3) * numbytes_row;
pu1_pic_intra_flag += (tu_abs_x >> 6);
intra_flag = *pu1_pic_intra_flag;
intra_flag &= (1 << ((tu_abs_x >> 3) % 8));
}
if(intra_flag)
{
u4_bs = DUP_LSB_10(tu_size);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_x & 1))
{
WORD32 shift;
shift = start_pos_y * 2;
/* shift += (((start_pos_x >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_x & 2) << (log2_ctb_size - 2));
pu4_vert_bs[start_pos_x >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_y & 1))
{
WORD32 shift;
shift = start_pos_x * 2;
/* shift += (((start_pos_y >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_y & 2) << (log2_ctb_size - 2));
pu4_horz_bs[start_pos_y >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
/* If the current TU is coded then set both top edge and left edge BS to 1 and go to next TU */
if(ps_tu->b1_y_cbf)
{
u4_bs = DUP_LSB_01(tu_size);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_x & 1))
{
WORD32 shift;
shift = start_pos_y * 2;
/* shift += (((start_pos_x >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_x & 2) << (log2_ctb_size - 2));
pu4_vert_bs[start_pos_x >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_y & 1))
{
WORD32 shift;
shift = start_pos_x * 2;
/* shift += (((start_pos_y >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_y & 2) << (log2_ctb_size - 2));
pu4_horz_bs[start_pos_y >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (end_pos_x & 1))
{
if(!(ctb_size / 8 == (end_pos_x >> 1) && ps_bs_ctxt->i4_ctb_x == ps_sps->i2_pic_wd_in_ctb - 1))
{
WORD32 shift;
shift = start_pos_y * 2;
shift += (((end_pos_x >> 1) & ((MAX_CTB_SIZE >> log2_ctb_size) - 1)) << (log2_ctb_size - 1));
pu4_vert_bs[end_pos_x >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (end_pos_y & 1))
{
/* If end_pos_y corresponds to the bottom of the CTB, write to pu4_horz_bs[0] of the bottom CTB */
if(ctb_size / 8 == (end_pos_y >> 1))
{
*(UWORD32 *)((UWORD8 *)pu4_horz_bs + bs_strd) |= (u4_bs << (start_pos_x * 2));
}
else
{
WORD32 shift;
shift = start_pos_x * 2;
shift += (((end_pos_y >> 1) & ((MAX_CTB_SIZE >> log2_ctb_size) - 1)) << (log2_ctb_size - 1));
pu4_horz_bs[end_pos_y >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
}
if(0 == u4_qp_const_in_ctb)
{
if(0 == (start_pos_x & 1) && 0 == (start_pos_y & 1))
{
WORD32 row, col;
for(row = start_pos_y; row < start_pos_y + tu_size; row += 2)
{
for(col = start_pos_x; col < start_pos_x + tu_size; col += 2)
{
pu1_qp[(row >> 1) * qp_strd + (col >> 1)] = ps_tu->b7_qp;
}
}
}
}
}
/* For all PUs in the CTB,
For left and top edges, compute BS */
cur_ctb_idx = ps_bs_ctxt->i4_ctb_x
+ ps_bs_ctxt->i4_ctb_y * (ps_sps->i2_pic_wd_in_ctb);
{
WORD32 next_ctb_idx;
next_ctb_idx = ps_bs_ctxt->i4_next_pu_ctb_cnt;
i4_pu_cnt = ps_bs_ctxt->pu4_pic_pu_idx[next_ctb_idx] - ps_bs_ctxt->pu4_pic_pu_idx[cur_ctb_idx];
}
for(i = 0; i < i4_pu_cnt; i++)
{
WORD32 start_pos_x;
WORD32 start_pos_y;
WORD32 end_pos_x;
WORD32 end_pos_y;
WORD32 pu_wd, pu_ht;
UWORD32 u4_bs;
pu_t *ps_pu = ps_bs_ctxt->ps_pu + i;
pu_t *ps_ngbr_pu;
UWORD32 u4_ngbr_pu_indx;
start_pos_x = ps_pu->b4_pos_x;
start_pos_y = ps_pu->b4_pos_y;
pu_wd = (ps_pu->b4_wd + 1);
pu_ht = (ps_pu->b4_ht + 1);
end_pos_x = start_pos_x + pu_wd;
end_pos_y = start_pos_y + pu_ht;
/* If the current PU is intra, set Boundary strength as 2 for both top and left edge */
/* Need not mask the BS to zero even if it was set to 1 already since BS 2 and 3 are assumed to be the same in leaf level functions */
if(ps_pu->b1_intra_flag)
{
u4_bs = DUP_LSB_10(pu_ht);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_x & 1))
{
WORD32 shift;
shift = start_pos_y * 2;
/* shift += (((start_pos_x >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_x & 2) << (log2_ctb_size - 2));
pu4_vert_bs[start_pos_x >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
u4_bs = DUP_LSB_10(pu_wd);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_y & 1))
{
WORD32 shift;
shift = start_pos_x * 2;
/* shift += (((start_pos_y >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_y & 2) << (log2_ctb_size - 2));
pu4_horz_bs[start_pos_y >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
else
{
/* Vertical edge */
/* Process only if the edge is not a frame edge */
if(0 != ps_bs_ctxt->i4_ctb_x + start_pos_x)
{
do
{
WORD32 pu_ngbr_ht;
WORD32 min_pu_ht;
WORD32 ngbr_end_pos_y;
UWORD32 ngbr_pu_idx_strd;
ngbr_pu_idx_strd = MAX_CTB_SIZE / MIN_PU_SIZE + 2;
u4_ngbr_pu_indx = ps_bs_ctxt->pu4_pic_pu_idx_map[(start_pos_y + 1) * ngbr_pu_idx_strd + (start_pos_x)];
ps_ngbr_pu = ps_bs_ctxt->ps_pic_pu + u4_ngbr_pu_indx;
pu_ngbr_ht = ps_ngbr_pu->b4_ht + 1;
ngbr_end_pos_y = ps_ngbr_pu->b4_pos_y + pu_ngbr_ht;
min_pu_ht = MIN(ngbr_end_pos_y, end_pos_y) - start_pos_y;
if(ps_ngbr_pu->b1_intra_flag)
{
u4_bs = DUP_LSB_10(min_pu_ht);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_x & 1))
{
WORD32 shift;
shift = start_pos_y * 2;
/* shift += (((start_pos_x >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_x & 2) << (log2_ctb_size - 2));
pu4_vert_bs[start_pos_x >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
else
{
u4_bs = ihevcd_pu_boundary_strength(ps_pu, ps_ngbr_pu);
if(u4_bs)
{
u4_bs = DUP_LSB_01(min_pu_ht);
if(0 == (start_pos_x & 1))
{
WORD32 shift;
shift = start_pos_y * 2;
/* shift += (((start_pos_x >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_x & 2) << (log2_ctb_size - 2));
pu4_vert_bs[start_pos_x >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
}
pu_ht -= min_pu_ht;
start_pos_y += min_pu_ht;
}while(pu_ht > 0);
/* Reinitialising since the values are updated in the previous loop */
pu_ht = ps_pu->b4_ht + 1;
start_pos_y = ps_pu->b4_pos_y;
}
/* Horizontal edge */
/* Process only if the edge is not a frame edge */
if(0 != ps_bs_ctxt->i4_ctb_y + start_pos_y)
{
do
{
WORD32 pu_ngbr_wd;
WORD32 min_pu_wd;
WORD32 ngbr_end_pos_x;
UWORD32 ngbr_pu_idx_strd = MAX_CTB_SIZE / MIN_PU_SIZE + 2;
u4_ngbr_pu_indx = ps_bs_ctxt->pu4_pic_pu_idx_map[(start_pos_y)*ngbr_pu_idx_strd + (start_pos_x + 1)];
ps_ngbr_pu = ps_bs_ctxt->ps_pic_pu + u4_ngbr_pu_indx;
pu_ngbr_wd = ps_ngbr_pu->b4_wd + 1;
ngbr_end_pos_x = ps_ngbr_pu->b4_pos_x + pu_ngbr_wd;
min_pu_wd = MIN(ngbr_end_pos_x, end_pos_x) - start_pos_x;
if(ps_ngbr_pu->b1_intra_flag)
{
u4_bs = DUP_LSB_10(min_pu_wd);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_y & 1))
{
WORD32 shift;
shift = start_pos_x * 2;
/* shift += (((start_pos_y >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_y & 2) << (log2_ctb_size - 2));
pu4_horz_bs[start_pos_y >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
else
{
u4_bs = ihevcd_pu_boundary_strength(ps_pu, ps_ngbr_pu);
if(u4_bs)
{
u4_bs = DUP_LSB_01(min_pu_wd);
/* Only if the current edge falls on 8 pixel grid set BS */
if(0 == (start_pos_y & 1))
{
WORD32 shift;
shift = start_pos_x * 2;
/* shift += (((start_pos_y >> 1) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 1));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
if(6 != log2_ctb_size)
shift += ((start_pos_y & 2) << (log2_ctb_size - 2));
pu4_horz_bs[start_pos_y >> (7 - log2_ctb_size)] |= (u4_bs << shift);
}
}
}
pu_wd -= min_pu_wd;
start_pos_x += min_pu_wd;
}while(pu_wd > 0);
/* Reinitialising since the values are updated in the previous loop */
pu_wd = ps_pu->b4_wd + 1;
start_pos_x = ps_pu->b4_pos_x;
}
}
}
{
/* If left neighbor is not available, then set BS for entire first column to zero */
UWORD32 ctb_addr;
WORD32 slice_idx, left_slice_idx = -1, top_slice_idx = -1;
if(!ps_pps->i1_tiles_enabled_flag)
{
if((0 == i1_loop_filter_across_tiles_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_tile_x) ||
(0 == i1_loop_filter_across_slices_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_slice_x && 0 == ps_bs_ctxt->i4_ctb_slice_y) ||
(0 == ps_bs_ctxt->i4_ctb_x))
{
pu4_vert_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
}
else
{
if((0 == i1_loop_filter_across_tiles_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_tile_x))
{
pu4_vert_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
else
{
ctb_addr = ps_bs_ctxt->i4_ctb_x + (ps_bs_ctxt->i4_ctb_y * ps_sps->i2_pic_wd_in_ctb);
slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
if(ps_bs_ctxt->i4_ctb_x)
{
ctb_addr = (ps_bs_ctxt->i4_ctb_x - 1) + (ps_bs_ctxt->i4_ctb_y * ps_sps->i2_pic_wd_in_ctb);
left_slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
}
if(!((ps_bs_ctxt->ps_slice_hdr->i1_dependent_slice_flag == 1) && (slice_idx == left_slice_idx)))
{
if((0 == i1_loop_filter_across_slices_enabled_flag && (
(0 == ps_bs_ctxt->i4_ctb_slice_x && 0 == ps_bs_ctxt->i4_ctb_slice_y) || (0 == ps_bs_ctxt->i4_ctb_slice_x && 0 == ps_bs_ctxt->i4_ctb_tile_x)
|| ((0 == ps_bs_ctxt->i4_ctb_tile_x) && (slice_idx != left_slice_idx)))) || (0 == ps_bs_ctxt->i4_ctb_x))
{
pu4_vert_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
}
}
}
ctb_addr = ps_bs_ctxt->i4_ctb_x + (ps_bs_ctxt->i4_ctb_y * ps_sps->i2_pic_wd_in_ctb);
slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
if(ps_bs_ctxt->i4_ctb_y)
{
ctb_addr = (ps_bs_ctxt->i4_ctb_x) + ((ps_bs_ctxt->i4_ctb_y - 1) * ps_sps->i2_pic_wd_in_ctb);
top_slice_idx = ps_bs_ctxt->pu1_slice_idx[ctb_addr];
}
/* If top neighbor is not available, then set BS for entire first row to zero */
if((0 == i1_loop_filter_across_tiles_enabled_flag && 0 == ps_bs_ctxt->i4_ctb_tile_y)
|| (0 == i1_loop_filter_across_slices_enabled_flag && ((0 == ps_bs_ctxt->i4_ctb_slice_y) || (slice_idx != top_slice_idx)))
|| (0 == ps_bs_ctxt->i4_ctb_y))
{
pu4_horz_bs[0] &= (64 == ctb_size) ? 0 : ((UWORD32)0xFFFFFFFF) << (ctb_size / 2);
}
}
/**
* Set BS of bottom and right frame boundaries to zero if it is an incomplete CTB
* (They might have set to non zero values because of CBF of the current CTB)*/
{
WORD32 num_rows_remaining = (ps_sps->i2_pic_height_in_luma_samples - (ps_bs_ctxt->i4_ctb_y << log2_ctb_size)) >> 3;
WORD32 num_cols_remaining = (ps_sps->i2_pic_width_in_luma_samples - (ps_bs_ctxt->i4_ctb_x << log2_ctb_size)) >> 3;
if(num_rows_remaining < (ctb_size >> 3))
{
/* WORD32 offset = (((num_rows_remaining >> 3) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 4));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
WORD32 offset;
offset = (num_rows_remaining >> (6 - log2_ctb_size)) << 2;
if(6 != log2_ctb_size)
offset += (num_rows_remaining & 1) << (log2_ctb_size - 4);
memset(((UWORD8 *)pu4_horz_bs) + offset, 0, 1 << (log2_ctb_size - 4));
}
if(num_cols_remaining < (ctb_size >> 3))
{
/* WORD32 offset = (((num_cols_remaining >> 3) & (MAX_CTB_SIZE / ctb_size - 1)) << (log2_ctb_size - 4));
* will reduce to the following assuming ctb size is one of 16, 32 and 64
* and deblocking is done on 8x8 grid
*/
WORD32 offset;
offset = (num_cols_remaining >> (6 - log2_ctb_size)) << 2;
if(6 != log2_ctb_size)
offset += (num_cols_remaining & 1) << (log2_ctb_size - 4);
memset(((UWORD8 *)pu4_vert_bs) + offset, 0, 1 << (log2_ctb_size - 4));
}
}
return 0;
}