/*****************************************************************************
* This file is part of Kvazaar HEVC encoder.
*
* Copyright (C) 2013-2015 Tampere University of Technology and others (see
* COPYING file).
*
* Kvazaar is free software: you can redistribute it and/or modify it under
* the terms of the GNU Lesser General Public License as published by the
* Free Software Foundation; either version 2.1 of the License, or (at your
* option) any later version.
*
* Kvazaar is distributed in the hope that it will be useful, but WITHOUT ANY
* WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
* FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License along
* with Kvazaar. If not, see .
****************************************************************************/
/*
* \file
*/
#include "search_inter.h"
#include
#include "inter.h"
#include "strategies/strategies-picture.h"
#include "strategies/strategies-ipol.h"
#include "rdo.h"
// Temporarily for debugging.
#define SEARCH_MV_FULL_RADIUS 0
static uint32_t get_ep_ex_golomb_bitcost(uint32_t symbol, uint32_t count)
{
int32_t num_bins = 0;
while (symbol >= (uint32_t)(1 << count)) {
++num_bins;
symbol -= 1 << count;
++count;
}
num_bins ++;
return num_bins;
}
static uint32_t get_mvd_coding_cost(vector2d_t *mvd, cabac_data_t* cabac)
{
uint32_t bitcost = 0;
const int32_t mvd_hor = mvd->x;
const int32_t mvd_ver = mvd->y;
const int8_t hor_abs_gr0 = mvd_hor != 0;
const int8_t ver_abs_gr0 = mvd_ver != 0;
const uint32_t mvd_hor_abs = abs(mvd_hor);
const uint32_t mvd_ver_abs = abs(mvd_ver);
// Greater than 0 for x/y
bitcost += 2;
if (hor_abs_gr0) {
if (mvd_hor_abs > 1) {
bitcost += get_ep_ex_golomb_bitcost(mvd_hor_abs-2, 1) - 2; // TODO: tune the costs
}
// Greater than 1 + sign
bitcost += 2;
}
if (ver_abs_gr0) {
if (mvd_ver_abs > 1) {
bitcost += get_ep_ex_golomb_bitcost(mvd_ver_abs-2, 1) - 2; // TODO: tune the costs
}
// Greater than 1 + sign
bitcost += 2;
}
return bitcost;
}
static int calc_mvd_cost(const encoder_state_t * const state, int x, int y, int mv_shift,
int16_t mv_cand[2][2], inter_merge_cand_t merge_cand[MRG_MAX_NUM_CANDS],
int16_t num_cand,int32_t ref_idx, uint32_t *bitcost)
{
uint32_t temp_bitcost = 0;
uint32_t merge_idx;
int cand1_cost,cand2_cost;
vector2d_t mvd_temp1, mvd_temp2;
int8_t merged = 0;
int8_t cur_mv_cand = 0;
x <<= mv_shift;
y <<= mv_shift;
// Check every candidate to find a match
for(merge_idx = 0; merge_idx < (uint32_t)num_cand; merge_idx++) {
if (merge_cand[merge_idx].dir == 3) continue;
if (merge_cand[merge_idx].mv[merge_cand[merge_idx].dir - 1][0] == x &&
merge_cand[merge_idx].mv[merge_cand[merge_idx].dir - 1][1] == y &&
merge_cand[merge_idx].ref[merge_cand[merge_idx].dir - 1] == ref_idx) {
temp_bitcost += merge_idx;
merged = 1;
break;
}
}
// Check mvd cost only if mv is not merged
if(!merged) {
mvd_temp1.x = x - mv_cand[0][0];
mvd_temp1.y = y - mv_cand[0][1];
cand1_cost = get_mvd_coding_cost(&mvd_temp1, NULL);
mvd_temp2.x = x - mv_cand[1][0];
mvd_temp2.y = y - mv_cand[1][1];
cand2_cost = get_mvd_coding_cost(&mvd_temp2, NULL);
// Select candidate 1 if it has lower cost
if (cand2_cost < cand1_cost) {
cur_mv_cand = 1;
}
temp_bitcost += cur_mv_cand ? cand2_cost : cand1_cost;
}
*bitcost = temp_bitcost;
return temp_bitcost*(int32_t)(state->global->cur_lambda_cost_sqrt+0.5);
}
unsigned kvz_tz_pattern_search(const encoder_state_t * const state, const kvz_picture *pic, const kvz_picture *ref, unsigned pattern_type,
const vector2d_t *orig, const int iDist, vector2d_t *mv, unsigned best_cost, int *best_dist,
int16_t mv_cand[2][2], inter_merge_cand_t merge_cand[MRG_MAX_NUM_CANDS], int16_t num_cand, int32_t ref_idx, uint32_t *best_bitcost,
int block_width, int max_lcu_below)
{
int n_points;
int best_index = -1;
int i;
vector2d_t mv_best = { 0, 0 };
int(*calc_mvd)(const encoder_state_t * const, int, int, int,
int16_t[2][2], inter_merge_cand_t[MRG_MAX_NUM_CANDS],
int16_t, int32_t, uint32_t *) = calc_mvd_cost;
if (state->encoder_control->cfg->mv_rdo) {
calc_mvd = kvz_calc_mvd_cost_cabac;
}
assert(pattern_type < 4);
//implemented search patterns
vector2d_t pattern[4][8] = {
//diamond (8 points)
//[ ][ ][ ][ ][1][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][8][ ][ ][ ][5][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[4][ ][ ][ ][o][ ][ ][ ][2]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][7][ ][ ][ ][6][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][3][ ][ ][ ][ ]
{
{ 0, iDist }, { iDist, 0 }, { 0, -iDist }, { -iDist, 0 },
{ iDist / 2, iDist / 2 }, { iDist / 2, -iDist / 2 }, { -iDist / 2, -iDist / 2 }, { -iDist / 2, iDist / 2 }
},
//square (8 points)
//[8][ ][ ][ ][1][ ][ ][ ][2]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[7][ ][ ][ ][o][ ][ ][ ][3]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[6][ ][ ][ ][5][ ][ ][ ][4]
{
{ 0, iDist }, { iDist, iDist }, { iDist, 0 }, { iDist, -iDist }, { 0, -iDist },
{ -iDist, -iDist }, { -iDist, 0 }, { -iDist, iDist }
},
//octagon (8 points)
//[ ][ ][5][ ][ ][ ][1][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][2]
//[4][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][o][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[8][ ][ ][ ][ ][ ][ ][ ][6]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][7][ ][ ][ ][3][ ][ ]
{
{ iDist / 2, iDist }, { iDist, iDist / 2 }, { iDist / 2, -iDist }, { -iDist, iDist / 2 },
{ -iDist / 2, iDist }, { iDist, -iDist / 2 }, { -iDist / 2, -iDist }, { -iDist, -iDist / 2 }
},
//hexagon (6 points)
//[ ][ ][5][ ][ ][ ][1][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[4][ ][ ][ ][o][ ][ ][ ][2]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][ ][ ][ ][ ][ ][ ][ ]
//[ ][ ][6][ ][ ][ ][3][ ][ ]
{
{ iDist / 2, iDist }, { iDist, 0 }, { iDist / 2, -iDist }, { -iDist, 0 },
{ iDist / 2, iDist }, { -iDist / 2, -iDist }, { 0, 0 }, { 0, 0 }
}
};
//set the number of points to be checked
if (iDist == 1)
{
switch (pattern_type)
{
case 0:
n_points = 4;
break;
case 2:
n_points = 4;
break;
case 3:
n_points = 4;
break;
default:
n_points = 8;
break;
};
}
else
{
switch (pattern_type)
{
case 3:
n_points = 6;
break;
default:
n_points = 8;
break;
};
}
//compute SAD values for all chosen points
for (i = 0; i < n_points; i++)
{
vector2d_t *current = &pattern[pattern_type][i];
unsigned cost;
uint32_t bitcost;
{
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv->x + current->x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv->y + current->y,
block_width, block_width, max_lcu_below);
cost += calc_mvd(state, mv->x + current->x, mv->y + current->y, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv->x + current->x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv->x + current->x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv->y + current->y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv->y + current->y + block_width);
}
if (cost < best_cost)
{
best_cost = cost;
*best_bitcost = bitcost;
best_index = i;
}
}
if (best_index >= 0)
{
mv_best = pattern[pattern_type][best_index];
*best_dist = iDist;
}
mv->x += mv_best.x;
mv->y += mv_best.y;
return best_cost;
}
unsigned kvz_tz_raster_search(const encoder_state_t * const state, const kvz_picture *pic, const kvz_picture *ref,
const vector2d_t *orig, vector2d_t *mv, unsigned best_cost,
int16_t mv_cand[2][2], inter_merge_cand_t merge_cand[MRG_MAX_NUM_CANDS], int16_t num_cand, int32_t ref_idx, uint32_t *best_bitcost,
int block_width, int iSearchRange, int iRaster, int max_lcu_below)
{
int i;
int k;
vector2d_t mv_best = { 0, 0 };
int(*calc_mvd)(const encoder_state_t * const, int, int, int,
int16_t[2][2], inter_merge_cand_t[MRG_MAX_NUM_CANDS],
int16_t, int32_t, uint32_t *) = calc_mvd_cost;
if (state->encoder_control->cfg->mv_rdo) {
calc_mvd = kvz_calc_mvd_cost_cabac;
}
//compute SAD values for every point in the iRaster downsampled version of the current search area
for (i = iSearchRange; i >= -iSearchRange; i -= iRaster)
{
for (k = -iSearchRange; k <= iSearchRange; k += iRaster)
{
vector2d_t current = { k, i };
unsigned cost;
uint32_t bitcost;
{
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv->x + k,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv->y + i,
block_width, block_width, max_lcu_below);
cost += calc_mvd(state, mv->x + k, mv->y + i, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv->x + k,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv->x + k + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv->y + i,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv->y + i + block_width);
}
if (cost < best_cost)
{
best_cost = cost;
*best_bitcost = bitcost;
mv_best = current;
}
}
}
mv->x += mv_best.x;
mv->y += mv_best.y;
return best_cost;
}
static unsigned tz_search(const encoder_state_t * const state, unsigned depth,
const kvz_picture *pic, const kvz_picture *ref,
const vector2d_t *orig, vector2d_t *mv_in_out,
int16_t mv_cand[2][2], inter_merge_cand_t merge_cand[MRG_MAX_NUM_CANDS],
int16_t num_cand, int32_t ref_idx, uint32_t *bitcost_out)
{
//TZ parameters
const int iSearchRange = 96; // search range for each stage
const int iRaster = 5; // search distance limit and downsampling factor for step 3
const unsigned step2_type = 0; // search patterns for steps 2 and 4
const unsigned step4_type = 0;
const bool bRasterRefinementEnable = true; // enable step 4 mode 1
const bool bStarRefinementEnable = false; // enable step 4 mode 2 (only one mode will be executed)
const int block_width = CU_WIDTH_FROM_DEPTH(depth);
vector2d_t mv = { mv_in_out->x >> 2, mv_in_out->y >> 2 };
unsigned best_cost = UINT32_MAX;
uint32_t best_bitcost = 0;
int iDist;
int best_dist = 0;
unsigned best_index = num_cand;
int max_lcu_below = -1;
int(*calc_mvd)(const encoder_state_t * const, int, int, int,
int16_t[2][2], inter_merge_cand_t[MRG_MAX_NUM_CANDS],
int16_t, int32_t, uint32_t *) = calc_mvd_cost;
if (state->encoder_control->cfg->mv_rdo) {
calc_mvd = kvz_calc_mvd_cost_cabac;
}
if (state->encoder_control->owf) {
max_lcu_below = 1;
}
//step 1, compare (0,0) vector to predicted vectors
// Check whatever input vector we got, unless its (0, 0) which will be checked later.
if (mv.x || mv.y)
{
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
best_cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
block_width, block_width, max_lcu_below);
best_cost += calc_mvd(state, mv.x, mv.y, 2, mv_cand, merge_cand, num_cand, ref_idx, &best_bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + block_width);
}
int i;
// Select starting point from among merge candidates. These should include
// both mv_cand vectors and (0, 0).
for (i = 0; i < num_cand; ++i)
{
if (merge_cand[i].dir == 3) continue;
mv.x = merge_cand[i].mv[merge_cand[i].dir - 1][0] >> 2;
mv.y = merge_cand[i].mv[merge_cand[i].dir - 1][1] >> 2;
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
uint32_t bitcost;
unsigned cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
block_width, block_width, max_lcu_below);
cost += calc_mvd(state, mv.x, mv.y, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + block_width);
if (cost < best_cost) {
best_cost = cost;
best_index = i;
best_bitcost = bitcost;
}
}
if (best_index < (unsigned)num_cand) {
mv.x = merge_cand[best_index].mv[merge_cand[best_index].dir - 1][0] >> 2;
mv.y = merge_cand[best_index].mv[merge_cand[best_index].dir - 1][1] >> 2;
} else {
mv.x = mv_in_out->x >> 2;
mv.y = mv_in_out->y >> 2;
}
//step 2, grid search
for (iDist = 1; iDist <= iSearchRange; iDist *= 2)
{
best_cost = kvz_tz_pattern_search(state, pic, ref, step2_type, orig, iDist, &mv, best_cost, &best_dist,
mv_cand, merge_cand, num_cand, ref_idx, &best_bitcost, block_width, max_lcu_below);
}
//step 3, raster scan
if (best_dist > iRaster)
{
best_dist = iRaster;
best_cost = kvz_tz_raster_search(state, pic, ref, orig, &mv, best_cost, mv_cand, merge_cand,
num_cand, ref_idx, &best_bitcost, block_width, iSearchRange, iRaster, max_lcu_below);
}
//step 4
//raster refinement
if (bRasterRefinementEnable && best_dist > 0)
{
iDist = best_dist >> 1;
while (iDist > 0)
{
best_cost = kvz_tz_pattern_search(state, pic, ref, step4_type, orig, iDist, &mv, best_cost, &best_dist,
mv_cand, merge_cand, num_cand, ref_idx, &best_bitcost, block_width, max_lcu_below);
iDist = iDist >> 1;
}
}
//star refinement (repeat step 2 for the current starting point)
if (bStarRefinementEnable && best_dist > 0)
{
for (iDist = 1; iDist <= iSearchRange; iDist *= 2)
{
best_cost = kvz_tz_pattern_search(state, pic, ref, step4_type, orig, iDist, &mv, best_cost, &best_dist,
mv_cand, merge_cand, num_cand, ref_idx, &best_bitcost, block_width, max_lcu_below);
}
}
mv.x = mv.x << 2;
mv.y = mv.y << 2;
*mv_in_out = mv;
*bitcost_out = best_bitcost;
return best_cost;
}
/**
* \brief Do motion search using the HEXBS algorithm.
*
* \param depth log2 depth of the search
* \param pic Picture motion vector is searched for.
* \param ref Picture motion vector is searched from.
* \param orig Top left corner of the searched for block.
* \param mv_in_out Predicted mv in and best out. Quarter pixel precision.
*
* \returns Cost of the motion vector.
*
* Motion vector is searched by first searching iteratively with the large
* hexagon pattern until the best match is at the center of the hexagon.
* As a final step a smaller hexagon is used to check the adjacent pixels.
*
* If a non 0,0 predicted motion vector predictor is given as mv_in_out,
* the 0,0 vector is also tried. This is hoped to help in the case where
* the predicted motion vector is way off. In the future even more additional
* points like 0,0 might be used, such as vectors from top or left.
*/
static unsigned hexagon_search(const encoder_state_t * const state, unsigned depth,
const kvz_picture *pic, const kvz_picture *ref,
const vector2d_t *orig, vector2d_t *mv_in_out,
int16_t mv_cand[2][2], inter_merge_cand_t merge_cand[MRG_MAX_NUM_CANDS],
int16_t num_cand, int32_t ref_idx, uint32_t *bitcost_out)
{
// The start of the hexagonal pattern has been repeated at the end so that
// the indices between 1-6 can be used as the start of a 3-point list of new
// points to search.
// 6--1,7
// / \ =)
// 5 0 2,8
// \ /
// 4---3
static const vector2d_t large_hexbs[10] = {
{ 0, 0 },
{ 1, -2 }, { 2, 0 }, { 1, 2 }, { -1, 2 }, { -2, 0 }, { -1, -2 },
{ 1, -2 }, { 2, 0 }
};
// This is used as the last step of the hexagon search.
// 1
// 2 0 3
// 4
static const vector2d_t small_hexbs[5] = {
{ 0, 0 },
{ 0, -1 }, { -1, 0 }, { 1, 0 }, { 0, 1 }
};
vector2d_t mv = { mv_in_out->x >> 2, mv_in_out->y >> 2 };
int block_width = CU_WIDTH_FROM_DEPTH(depth);
unsigned best_cost = UINT32_MAX;
uint32_t best_bitcost = 0, bitcost;
unsigned i;
unsigned best_index = 0; // Index of large_hexbs or finally small_hexbs.
int max_lcu_below = -1;
int (*calc_mvd)(const encoder_state_t * const, int, int, int,
int16_t[2][2], inter_merge_cand_t[MRG_MAX_NUM_CANDS],
int16_t, int32_t, uint32_t *) = calc_mvd_cost;
if (state->encoder_control->cfg->mv_rdo) {
calc_mvd = kvz_calc_mvd_cost_cabac;
}
if (state->encoder_control->owf) {
max_lcu_below = 1;
}
// Check mv_in, if it's not in merge candidates.
bool mv_in_merge_cand = false;
for (int i = 0; i < num_cand; ++i) {
if (merge_cand[i].dir == 3) continue;
if (merge_cand[i].mv[merge_cand[i].dir - 1][0] >> 2 == mv.x &&
merge_cand[i].mv[merge_cand[i].dir - 1][1] >> 2 == mv.y) {
mv_in_merge_cand = true;
break;
}
}
if (!mv_in_merge_cand) {
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
best_cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
block_width, block_width, max_lcu_below);
best_cost += calc_mvd(state, mv.x, mv.y, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
best_bitcost = bitcost;
best_index = num_cand;
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + block_width);
}
// Select starting point from among merge candidates. These should include
// both mv_cand vectors and (0, 0).
for (i = 0; i < num_cand; ++i) {
if (merge_cand[i].dir == 3) continue;
mv.x = merge_cand[i].mv[merge_cand[i].dir - 1][0] >> 2;
mv.y = merge_cand[i].mv[merge_cand[i].dir - 1][1] >> 2;
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
unsigned cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
block_width, block_width, max_lcu_below);
cost += calc_mvd(state, mv.x, mv.y, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + block_width);
if (cost < best_cost) {
best_cost = cost;
best_index = i;
best_bitcost = bitcost;
}
}
if (best_index < num_cand) {
mv.x = merge_cand[best_index].mv[merge_cand[best_index].dir - 1][0] >> 2;
mv.y = merge_cand[best_index].mv[merge_cand[best_index].dir - 1][1] >> 2;
} else {
mv.x = mv_in_out->x >> 2;
mv.y = mv_in_out->y >> 2;
}
// Search the initial 7 points of the hexagon.
best_index = 0;
for (i = 0; i < 7; ++i) {
const vector2d_t *pattern = &large_hexbs[i];
unsigned cost;
{
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + pattern->x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + pattern->y,
block_width, block_width, max_lcu_below);
cost += calc_mvd(state, mv.x + pattern->x, mv.y + pattern->y, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + pattern->x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + pattern->x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + pattern->y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + pattern->y + block_width);
}
if (cost < best_cost) {
best_cost = cost;
best_index = i;
best_bitcost = bitcost;
}
}
// Iteratively search the 3 new points around the best match, until the best
// match is in the center.
while (best_index != 0) {
unsigned start; // Starting point of the 3 offsets to be searched.
if (best_index == 1) {
start = 6;
} else if (best_index == 8) {
start = 1;
} else {
start = best_index - 1;
}
// Move the center to the best match.
mv.x += large_hexbs[best_index].x;
mv.y += large_hexbs[best_index].y;
best_index = 0;
// Iterate through the next 3 points.
for (i = 0; i < 3; ++i) {
const vector2d_t *offset = &large_hexbs[start + i];
unsigned cost;
{
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + offset->x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + offset->y,
block_width, block_width, max_lcu_below);
cost += calc_mvd(state, mv.x + offset->x, mv.y + offset->y, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=large_hexbs_iterative,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + offset->x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + offset->x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + offset->y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + offset->y + block_width);
}
if (cost < best_cost) {
best_cost = cost;
best_index = start + i;
best_bitcost = bitcost;
}
++offset;
}
}
// Move the center to the best match.
mv.x += large_hexbs[best_index].x;
mv.y += large_hexbs[best_index].y;
best_index = 0;
// Do the final step of the search with a small pattern.
for (i = 1; i < 5; ++i) {
const vector2d_t *offset = &small_hexbs[i];
unsigned cost;
{
PERFORMANCE_MEASURE_START(KVZ_PERF_SEARCHPX);
cost = kvz_image_calc_sad(pic, ref, orig->x, orig->y,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + offset->x,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + offset->y,
block_width, block_width, max_lcu_below);
cost += calc_mvd(state, mv.x + offset->x, mv.y + offset->y, 2, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
PERFORMANCE_MEASURE_END(KVZ_PERF_SEARCHPX, state->encoder_control->threadqueue, "type=sad,step=small_hexbs,frame=%d,tile=%d,px_x=%d-%d,px_y=%d-%d,ref_px_x=%d-%d,ref_px_y=%d-%d", state->global->frame, state->tile->id, orig->x, orig->x + block_width, orig->y, orig->y + block_width,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + offset->x,
(state->tile->lcu_offset_x * LCU_WIDTH) + orig->x + mv.x + offset->x + block_width,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + offset->y,
(state->tile->lcu_offset_y * LCU_WIDTH) + orig->y + mv.y + offset->y + block_width);
}
if (cost > 0 && cost < best_cost) {
best_cost = cost;
best_index = i;
best_bitcost = bitcost;
}
}
// Adjust the movement vector according to the final best match.
mv.x += small_hexbs[best_index].x;
mv.y += small_hexbs[best_index].y;
// Return final movement vector in quarter-pixel precision.
mv_in_out->x = mv.x << 2;
mv_in_out->y = mv.y << 2;
*bitcost_out = best_bitcost;
return best_cost;
}
#if SEARCH_MV_FULL_RADIUS
static unsigned search_mv_full(unsigned depth,
const picture *pic, const picture *ref,
const vector2d *orig, vector2d *mv_in_out,
int16_t mv_cand[2][2], int16_t merge_cand[MRG_MAX_NUM_CANDS][3],
int16_t num_cand, int32_t ref_idx, uint32_t *bitcost_out)
{
vector2d mv = { mv_in_out->x >> 2, mv_in_out->y >> 2 };
int block_width = CU_WIDTH_FROM_DEPTH(depth);
unsigned best_cost = UINT32_MAX;
int x, y;
uint32_t best_bitcost = 0, bitcost;
vector2d min_mv, max_mv;
/*if (abs(mv.x) > SEARCH_MV_FULL_RADIUS || abs(mv.y) > SEARCH_MV_FULL_RADIUS) {
best_cost = calc_sad(pic, ref, orig->x, orig->y,
orig->x, orig->y,
block_width, block_width);
mv.x = 0;
mv.y = 0;
}*/
min_mv.x = mv.x - SEARCH_MV_FULL_RADIUS;
min_mv.y = mv.y - SEARCH_MV_FULL_RADIUS;
max_mv.x = mv.x + SEARCH_MV_FULL_RADIUS;
max_mv.y = mv.y + SEARCH_MV_FULL_RADIUS;
for (y = min_mv.y; y < max_mv.y; ++y) {
for (x = min_mv.x; x < max_mv.x; ++x) {
unsigned cost = calc_sad(pic, ref, orig->x, orig->y,
orig->x + x,
orig->y + y,
block_width, block_width);
cost += calc_mvd_cost(x, y, mv_cand,merge_cand,num_cand,ref_idx, &bitcost);
if (cost < best_cost) {
best_cost = cost;
best_bitcost = bitcost;
mv.x = x;
mv.y = y;
}
}
}
mv_in_out->x = mv.x << 2;
mv_in_out->y = mv.y << 2;
*bitcost_out = best_bitcost;
return best_cost;
}
#endif
/**
* \brief Do fractional motion estimation
*
* \param depth log2 depth of the search
* \param pic Picture motion vector is searched for.
* \param ref Picture motion vector is searched from.
* \param orig Top left corner of the searched for block.
* \param mv_in_out Predicted mv in and best out. Quarter pixel precision.
*
* \returns Cost of the motion vector.
*
* Algoritm first searches 1/2-pel positions around integer mv and after best match is found,
* refines the search by searching best 1/4-pel postion around best 1/2-pel position.
*/
static unsigned search_frac(const encoder_state_t * const state,
unsigned depth,
const kvz_picture *pic, const kvz_picture *ref,
const vector2d_t *orig, vector2d_t *mv_in_out,
int16_t mv_cand[2][2], inter_merge_cand_t merge_cand[MRG_MAX_NUM_CANDS],
int16_t num_cand, int32_t ref_idx, uint32_t *bitcost_out)
{
// Map indexes to relative coordinates in the following way:
// 6 7 8
// 3 4 5
// 0 1 2
static const vector2d_t square[9] = {
{ -1, 1 }, { 0, 1 }, { 1, 1 },
{ -1, 0 }, { 0, 0 }, { 1, 0 },
{ -1, -1 }, { 0, -1 }, { 1, -1 }
};
//Set mv to halfpel precision
vector2d_t mv = { mv_in_out->x >> 2, mv_in_out->y >> 2 };
int block_width = CU_WIDTH_FROM_DEPTH(depth);
unsigned best_cost = UINT32_MAX;
uint32_t best_bitcost = 0, bitcost;
unsigned i;
unsigned best_index = 0; // Index of large_hexbs or finally small_hexbs.
unsigned cost = 0;
cost_pixel_nxn_func *satd = kvz_pixels_get_satd_func(block_width);
vector2d_t halfpel_offset;
#define FILTER_SIZE 8
#define HALF_FILTER (FILTER_SIZE>>1)
kvz_extended_block src = { 0, 0, 0 };
//destination buffer for interpolation
int dst_stride = (block_width+1)*4;
kvz_pixel dst[(LCU_WIDTH+1) * (LCU_WIDTH+1) * 16];
kvz_pixel* dst_off = &dst[dst_stride*4+4];
int(*calc_mvd)(const encoder_state_t * const, int, int, int,
int16_t[2][2], inter_merge_cand_t[MRG_MAX_NUM_CANDS],
int16_t, int32_t, uint32_t *) = calc_mvd_cost;
if (state->encoder_control->cfg->mv_rdo) {
calc_mvd = kvz_calc_mvd_cost_cabac;
}
kvz_get_extended_block(orig->x, orig->y, mv.x-1, mv.y-1,
state->tile->lcu_offset_x * LCU_WIDTH,
state->tile->lcu_offset_y * LCU_WIDTH,
ref->y, ref->width, ref->height, FILTER_SIZE, block_width+1, block_width+1, &src);
kvz_filter_inter_quarterpel_luma(state->encoder_control, src.orig_topleft, src.stride, block_width+1,
block_width+1, dst, dst_stride, 1, 1);
if (src.malloc_used) free(src.buffer);
//Set mv to half-pixel precision
mv.x <<= 1;
mv.y <<= 1;
kvz_pixel tmp_filtered[LCU_WIDTH*LCU_WIDTH];
kvz_pixel tmp_pic[LCU_WIDTH*LCU_WIDTH];
kvz_pixels_blit(pic->y + orig->y*pic->width + orig->x, tmp_pic, block_width, block_width, pic->stride, block_width);
// Search halfpel positions around best integer mv
for (i = 0; i < 9; ++i) {
const vector2d_t *pattern = &square[i];
int y,x;
for(y = 0; y < block_width; ++y) {
int dst_y = y*4+pattern->y*2;
for(x = 0; x < block_width; ++x) {
int dst_x = x*4+pattern->x*2;
tmp_filtered[y*block_width+x] = dst_off[dst_y*dst_stride+dst_x];
}
}
cost = satd(tmp_pic,tmp_filtered);
cost += calc_mvd(state, mv.x + pattern->x, mv.y + pattern->y, 1, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
if (cost < best_cost) {
best_cost = cost;
best_index = i;
best_bitcost = bitcost;
}
}
//Set mv to best match
mv.x += square[best_index].x;
mv.y += square[best_index].y;
halfpel_offset.x = square[best_index].x*2;
halfpel_offset.y = square[best_index].y*2;
//Set mv to quarterpel precision
mv.x <<= 1;
mv.y <<= 1;
//Search quarterpel points around best halfpel mv
for (i = 0; i < 9; ++i) {
const vector2d_t *pattern = &square[i];
int y,x;
for(y = 0; y < block_width; ++y) {
int dst_y = y*4+halfpel_offset.y+pattern->y;
for(x = 0; x < block_width; ++x) {
int dst_x = x*4+halfpel_offset.x+pattern->x;
tmp_filtered[y*block_width+x] = dst_off[dst_y*dst_stride+dst_x];
}
}
cost = satd(tmp_pic,tmp_filtered);
cost += calc_mvd(state, mv.x + pattern->x, mv.y + pattern->y, 0, mv_cand, merge_cand, num_cand, ref_idx, &bitcost);
if (cost < best_cost) {
best_cost = cost;
best_index = i;
best_bitcost = bitcost;
}
}
//Set mv to best final best match
mv.x += square[best_index].x;
mv.y += square[best_index].y;
mv_in_out->x = mv.x;
mv_in_out->y = mv.y;
*bitcost_out = best_bitcost;
return best_cost;
}
/**
* Update lcu to have best modes at this depth.
* \return Cost of best mode.
*/
int kvz_search_cu_inter(const encoder_state_t * const state, int x, int y, int depth, lcu_t *lcu)
{
const videoframe_t * const frame = state->tile->frame;
uint32_t ref_idx = 0;
int x_local = SUB_SCU(x);
int y_local = SUB_SCU(y);
int x_cu = x>>3;
int y_cu = y>>3;
cu_info_t *cur_cu = LCU_GET_CU(lcu, x_local >> 3, y_local >> 3);
int16_t mv_cand[2][2];
// Search for merge mode candidate
inter_merge_cand_t merge_cand[MRG_MAX_NUM_CANDS];
// Get list of candidates
int16_t num_cand = kvz_inter_get_merge_cand(state, x, y, depth, merge_cand, lcu);
uint32_t(*get_mvd_cost)(vector2d_t *, cabac_data_t*) = get_mvd_coding_cost;
if (state->encoder_control->cfg->mv_rdo) {
get_mvd_cost = kvz_get_mvd_coding_cost_cabac;
}
int max_lcu_below = -1;
if (state->encoder_control->owf) {
max_lcu_below = 1;
}
// Default to candidate 0
cur_cu->inter.mv_cand[0] = 0;
cur_cu->inter.mv_cand[1] = 0;
cur_cu->inter.cost = UINT_MAX;
for (ref_idx = 0; ref_idx < state->global->ref->used_size; ref_idx++) {
kvz_picture *ref_image = state->global->ref->images[ref_idx];
uint32_t temp_bitcost = 0;
uint32_t temp_cost = 0;
vector2d_t orig, mvd;
int32_t merged = 0;
uint8_t cu_mv_cand = 0;
int8_t merge_idx = 0;
int8_t ref_list = state->global->refmap[ref_idx].list-1;
int8_t temp_ref_idx = cur_cu->inter.mv_ref[ref_list];
orig.x = x_cu * CU_MIN_SIZE_PIXELS;
orig.y = y_cu * CU_MIN_SIZE_PIXELS;
// Get MV candidates
cur_cu->inter.mv_ref[ref_list] = ref_idx;
kvz_inter_get_mv_cand(state, x, y, depth, mv_cand, cur_cu, lcu, ref_list);
cur_cu->inter.mv_ref[ref_list] = temp_ref_idx;
vector2d_t mv = { 0, 0 };
{
// Take starting point for MV search from previous frame.
// When temporal motion vector candidates are added, there is probably
// no point to this anymore, but for now it helps.
int mid_x_cu = (x + (LCU_WIDTH >> (depth+1))) / 8;
int mid_y_cu = (y + (LCU_WIDTH >> (depth+1))) / 8;
cu_info_t *ref_cu = &state->global->ref->cu_arrays[ref_idx]->data[mid_x_cu + mid_y_cu * (frame->width_in_lcu << MAX_DEPTH)];
if (ref_cu->type == CU_INTER) {
if (ref_cu->inter.mv_dir & 1) {
mv.x = ref_cu->inter.mv[0][0];
mv.y = ref_cu->inter.mv[0][1];
} else {
mv.x = ref_cu->inter.mv[1][0];
mv.y = ref_cu->inter.mv[1][1];
}
}
}
#if SEARCH_MV_FULL_RADIUS
temp_cost += search_mv_full(depth, frame, ref_pic, &orig, &mv, mv_cand, merge_cand, num_cand, ref_idx, &temp_bitcost);
#else
switch (state->encoder_control->cfg->ime_algorithm) {
case KVZ_IME_TZ:
temp_cost += tz_search(state, depth, frame->source, ref_image, &orig, &mv, mv_cand, merge_cand, num_cand, ref_idx, &temp_bitcost);
break;
default:
temp_cost += hexagon_search(state, depth, frame->source, ref_image, &orig, &mv, mv_cand, merge_cand, num_cand, ref_idx, &temp_bitcost);
break;
}
#endif
if (state->encoder_control->cfg->fme_level > 0) {
temp_cost = search_frac(state, depth, frame->source, ref_image, &orig, &mv, mv_cand, merge_cand, num_cand, ref_idx, &temp_bitcost);
}
merged = 0;
// Check every candidate to find a match
for(merge_idx = 0; merge_idx < num_cand; merge_idx++) {
if (merge_cand[merge_idx].dir != 3 &&
merge_cand[merge_idx].mv[merge_cand[merge_idx].dir - 1][0] == mv.x &&
merge_cand[merge_idx].mv[merge_cand[merge_idx].dir - 1][1] == mv.y &&
(uint32_t)merge_cand[merge_idx].ref[merge_cand[merge_idx].dir - 1] == ref_idx) {
merged = 1;
break;
}
}
// Only check when candidates are different
if (!merged && (mv_cand[0][0] != mv_cand[1][0] || mv_cand[0][1] != mv_cand[1][1])) {
vector2d_t mvd_temp1, mvd_temp2;
int cand1_cost,cand2_cost;
mvd_temp1.x = mv.x - mv_cand[0][0];
mvd_temp1.y = mv.y - mv_cand[0][1];
cand1_cost = get_mvd_cost(&mvd_temp1, (cabac_data_t*)&state->cabac);
mvd_temp2.x = mv.x - mv_cand[1][0];
mvd_temp2.y = mv.y - mv_cand[1][1];
cand2_cost = get_mvd_cost(&mvd_temp2, (cabac_data_t*)&state->cabac);
// Select candidate 1 if it has lower cost
if (cand2_cost < cand1_cost) {
cu_mv_cand = 1;
}
}
mvd.x = mv.x - mv_cand[cu_mv_cand][0];
mvd.y = mv.y - mv_cand[cu_mv_cand][1];
if(temp_cost < cur_cu->inter.cost) {
// Map reference index to L0/L1 pictures
cur_cu->inter.mv_dir = ref_list+1;
cur_cu->inter.mv_ref_coded[ref_list] = state->global->refmap[ref_idx].idx;
cur_cu->merged = merged;
cur_cu->merge_idx = merge_idx;
cur_cu->inter.mv_ref[ref_list] = ref_idx;
cur_cu->inter.mv[ref_list][0] = (int16_t)mv.x;
cur_cu->inter.mv[ref_list][1] = (int16_t)mv.y;
cur_cu->inter.mvd[ref_list][0] = (int16_t)mvd.x;
cur_cu->inter.mvd[ref_list][1] = (int16_t)mvd.y;
cur_cu->inter.cost = temp_cost;
cur_cu->inter.bitcost = temp_bitcost + cur_cu->inter.mv_dir - 1 + cur_cu->inter.mv_ref_coded[ref_list];
cur_cu->inter.mv_cand[ref_list] = cu_mv_cand;
}
}
// Search bi-pred positions
if (state->global->slicetype == KVZ_SLICE_B && state->encoder_control->cfg->bipred) {
lcu_t *templcu = MALLOC(lcu_t, 1);
cost_pixel_nxn_func *satd = kvz_pixels_get_satd_func(LCU_WIDTH >> depth);
#define NUM_PRIORITY_LIST 12;
static const uint8_t priorityList0[] = { 0, 1, 0, 2, 1, 2, 0, 3, 1, 3, 2, 3 };
static const uint8_t priorityList1[] = { 1, 0, 2, 0, 2, 1, 3, 0, 3, 1, 3, 2 };
uint8_t cutoff = num_cand;
int(*calc_mvd)(const encoder_state_t * const, int, int, int,
int16_t[2][2], inter_merge_cand_t[MRG_MAX_NUM_CANDS],
int16_t, int32_t, uint32_t *) = calc_mvd_cost;
if (state->encoder_control->cfg->mv_rdo) {
calc_mvd = kvz_calc_mvd_cost_cabac;
}
for (int32_t idx = 0; idx= num_cand || j >= num_cand) break;
// Find one L0 and L1 candidate according to the priority list
if ((merge_cand[i].dir & 0x1) && (merge_cand[j].dir & 0x2)) {
if (merge_cand[i].ref[0] != merge_cand[j].ref[1] ||
merge_cand[i].mv[0][0] != merge_cand[j].mv[1][0] ||
merge_cand[i].mv[0][1] != merge_cand[j].mv[1][1]) {
uint32_t bitcost[2];
uint32_t cost = 0;
int8_t cu_mv_cand = 0;
int16_t mv[2][2];
kvz_pixel tmp_block[64 * 64];
kvz_pixel tmp_pic[64 * 64];
// Force L0 and L1 references
if (state->global->refmap[merge_cand[i].ref[0]].list == 2 || state->global->refmap[merge_cand[j].ref[1]].list == 1) continue;
mv[0][0] = merge_cand[i].mv[0][0];
mv[0][1] = merge_cand[i].mv[0][1];
mv[1][0] = merge_cand[j].mv[1][0];
mv[1][1] = merge_cand[j].mv[1][1];
// Check boundaries when using owf to process multiple frames at the same time
if (max_lcu_below >= 0) {
// When SAO is off, row is considered reconstructed when the last LCU
// is done, although the bottom 2 pixels might still need deblocking.
// To work around this, add 2 luma pixels to the reach of the mv
// in order to avoid referencing those possibly non-deblocked pixels.
int mv_lcu_row_reach_1 = ((y+(mv[0][1]>>2)) + (LCU_WIDTH >> depth) - 1 + 2) / LCU_WIDTH;
int mv_lcu_row_reach_2 = ((y+(mv[1][1]>>2)) + (LCU_WIDTH >> depth) - 1 + 2) / LCU_WIDTH;
int cur_lcu_row = y / LCU_WIDTH;
if (mv_lcu_row_reach_1 > cur_lcu_row + max_lcu_below || mv_lcu_row_reach_2 > cur_lcu_row + max_lcu_below) {
continue;
}
}
kvz_inter_recon_lcu_bipred(state, state->global->ref->images[merge_cand[i].ref[0]], state->global->ref->images[merge_cand[j].ref[1]], x, y, LCU_WIDTH >> depth, mv, templcu);
for (int ypos = 0; ypos < LCU_WIDTH >> depth; ++ypos) {
int dst_y = ypos*(LCU_WIDTH >> depth);
for (int xpos = 0; xpos < (LCU_WIDTH >> depth); ++xpos) {
tmp_block[dst_y + xpos] = templcu->rec.y[
SUB_SCU(y + ypos) * LCU_WIDTH + SUB_SCU(x + xpos)];
tmp_pic[dst_y + xpos] = frame->source->y[x + xpos + (y + ypos)*frame->source->width];
}
}
cost = satd(tmp_pic, tmp_block);
cost += calc_mvd(state, merge_cand[i].mv[0][0], merge_cand[i].mv[0][1], 0, mv_cand, merge_cand, 0, ref_idx, &bitcost[0]);
cost += calc_mvd(state, merge_cand[i].mv[1][0], merge_cand[i].mv[1][1], 0, mv_cand, merge_cand, 0, ref_idx, &bitcost[1]);
if (cost < cur_cu->inter.cost) {
cur_cu->inter.mv_dir = 3;
cur_cu->inter.mv_ref_coded[0] = state->global->refmap[merge_cand[i].ref[0]].idx;
cur_cu->inter.mv_ref_coded[1] = state->global->refmap[merge_cand[j].ref[1]].idx;
cur_cu->inter.mv_ref[0] = merge_cand[i].ref[0];
cur_cu->inter.mv_ref[1] = merge_cand[j].ref[1];
cur_cu->inter.mv[0][0] = merge_cand[i].mv[0][0];
cur_cu->inter.mv[0][1] = merge_cand[i].mv[0][1];
cur_cu->inter.mv[1][0] = merge_cand[j].mv[1][0];
cur_cu->inter.mv[1][1] = merge_cand[j].mv[1][1];
cur_cu->merged = 0;
// Check every candidate to find a match
for(int merge_idx = 0; merge_idx < num_cand; merge_idx++) {
if (
merge_cand[merge_idx].mv[0][0] == cur_cu->inter.mv[0][0] &&
merge_cand[merge_idx].mv[0][1] == cur_cu->inter.mv[0][1] &&
merge_cand[merge_idx].mv[1][0] == cur_cu->inter.mv[1][0] &&
merge_cand[merge_idx].mv[1][1] == cur_cu->inter.mv[1][1] &&
merge_cand[merge_idx].ref[0] == cur_cu->inter.mv_ref[0] &&
merge_cand[merge_idx].ref[1] == cur_cu->inter.mv_ref[1]) {
cur_cu->merged = 1;
cur_cu->merge_idx = merge_idx;
break;
}
}
// Each motion vector has its own candidate
for (int reflist = 0; reflist < 2; reflist++) {
cu_mv_cand = 0;
kvz_inter_get_mv_cand(state, x, y, depth, mv_cand, cur_cu, lcu, reflist);
if ((mv_cand[0][0] != mv_cand[1][0] || mv_cand[0][1] != mv_cand[1][1])) {
vector2d_t mvd_temp1, mvd_temp2;
int cand1_cost, cand2_cost;
mvd_temp1.x = cur_cu->inter.mv[reflist][0] - mv_cand[0][0];
mvd_temp1.y = cur_cu->inter.mv[reflist][1] - mv_cand[0][1];
cand1_cost = get_mvd_cost(&mvd_temp1, (cabac_data_t*)&state->cabac);
mvd_temp2.x = cur_cu->inter.mv[reflist][0] - mv_cand[1][0];
mvd_temp2.y = cur_cu->inter.mv[reflist][1] - mv_cand[1][1];
cand2_cost = get_mvd_cost(&mvd_temp2, (cabac_data_t*)&state->cabac);
// Select candidate 1 if it has lower cost
if (cand2_cost < cand1_cost) {
cu_mv_cand = 1;
}
}
cur_cu->inter.mvd[reflist][0] = cur_cu->inter.mv[reflist][0] - mv_cand[cu_mv_cand][0];
cur_cu->inter.mvd[reflist][1] = cur_cu->inter.mv[reflist][1] - mv_cand[cu_mv_cand][1];
cur_cu->inter.mv_cand[reflist] = cu_mv_cand;
}
cur_cu->inter.cost = cost;
cur_cu->inter.bitcost = bitcost[0] + bitcost[1] + cur_cu->inter.mv_dir - 1 + cur_cu->inter.mv_ref_coded[0] + cur_cu->inter.mv_ref_coded[1];
}
}
}
}
FREE_POINTER(templcu);
}
return cur_cu->inter.cost;
}