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author | Andreas Rheinhardt <andreas.rheinhardt@outlook.com> | 2024-04-04 04:14:58 +0200 |
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committer | Andreas Rheinhardt <andreas.rheinhardt@outlook.com> | 2024-04-04 16:45:00 +0200 |
commit | db063212c8dde0d6082856935e2b2275230bc365 (patch) | |
tree | 69d3fa02629b16fd8150b04b6266b4b86a0e9087 /libavcodec/vvc/mvs.c | |
parent | 486a2b964ba4e496ecd821e189d495ad06585abe (diff) | |
download | ffmpeg-db063212c8dde0d6082856935e2b2275230bc365.tar.gz |
avcodec/vvc: Rename vvc_?foo->foo
A namespace is unnecessary here given that all these files
are already in the vvc subfolder.
Reviewed-by: Nuo Mi <nuomi2021@gmail.com>
Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@outlook.com>
Diffstat (limited to 'libavcodec/vvc/mvs.c')
-rw-r--r-- | libavcodec/vvc/mvs.c | 1928 |
1 files changed, 1928 insertions, 0 deletions
diff --git a/libavcodec/vvc/mvs.c b/libavcodec/vvc/mvs.c new file mode 100644 index 0000000000..fe7d923460 --- /dev/null +++ b/libavcodec/vvc/mvs.c @@ -0,0 +1,1928 @@ +/* + * VVC motion vector decoder + * + * Copyright (C) 2023 Nuo Mi + * Copyright (C) 2022 Xu Mu + * This file is part of FFmpeg. + * + * FFmpeg 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. + * + * FFmpeg 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 Lesser General Public + * License along with FFmpeg; if not, write to the Free Software + * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA + */ + +#include "ctu.h" +#include "data.h" +#include "refs.h" +#include "mvs.h" + +#define IS_SAME_MV(a, b) (AV_RN64A(a) == AV_RN64A(b)) + +//check if the two luma locations belong to the same motion estimation region +static av_always_inline int is_same_mer(const VVCFrameContext *fc, const int xN, const int yN, const int xP, const int yP) +{ + const uint8_t plevel = fc->ps.sps->log2_parallel_merge_level; + + return xN >> plevel == xP >> plevel && + yN >> plevel == yP >> plevel; +} + +//return true if we have same mvs and ref_idxs +static av_always_inline int compare_mv_ref_idx(const MvField *n, const MvField *o) +{ + if (!o || n->pred_flag != o->pred_flag) + return 0; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (n->pred_flag & mask) { + const int same_ref_idx = n->ref_idx[i] == o->ref_idx[i]; + const int same_mv = IS_SAME_MV(n->mv + i, o->mv + i); + if (!same_ref_idx || !same_mv) + return 0; + } + } + return 1; +} + +// 8.5.2.15 Temporal motion buffer compression process for collocated motion vectors +static av_always_inline void mv_compression(Mv *motion) +{ + int mv[2] = {motion->x, motion->y}; + for (int i = 0; i < 2; i++) { + const int s = mv[i] >> 17; + const int f = av_log2((mv[i] ^ s) | 31) - 4; + const int mask = (-1 * (1 << f)) >> 1; + const int round = (1 << f) >> 2; + mv[i] = (mv[i] + round) & mask; + } + motion->x = mv[0]; + motion->y = mv[1]; +} + +void ff_vvc_mv_scale(Mv *dst, const Mv *src, int td, int tb) +{ + int tx, scale_factor; + + td = av_clip_int8(td); + tb = av_clip_int8(tb); + tx = (0x4000 + (abs(td) >> 1)) / td; + scale_factor = av_clip_intp2((tb * tx + 32) >> 6, 12); + dst->x = av_clip_intp2((scale_factor * src->x + 127 + + (scale_factor * src->x < 0)) >> 8, 17); + dst->y = av_clip_intp2((scale_factor * src->y + 127 + + (scale_factor * src->y < 0)) >> 8, 17); +} + +//part of 8.5.2.12 Derivation process for collocated motion vectors +static int check_mvset(Mv *mvLXCol, Mv *mvCol, + int colPic, int poc, + const RefPicList *refPicList, int X, int refIdxLx, + const RefPicList *refPicList_col, int listCol, int refidxCol) +{ + int cur_lt = refPicList[X].isLongTerm[refIdxLx]; + int col_lt = refPicList_col[listCol].isLongTerm[refidxCol]; + int col_poc_diff, cur_poc_diff; + + if (cur_lt != col_lt) { + mvLXCol->x = 0; + mvLXCol->y = 0; + return 0; + } + + col_poc_diff = colPic - refPicList_col[listCol].list[refidxCol]; + cur_poc_diff = poc - refPicList[X].list[refIdxLx]; + + mv_compression(mvCol); + if (cur_lt || col_poc_diff == cur_poc_diff) { + mvLXCol->x = av_clip_intp2(mvCol->x, 17); + mvLXCol->y = av_clip_intp2(mvCol->y, 17); + } else { + ff_vvc_mv_scale(mvLXCol, mvCol, col_poc_diff, cur_poc_diff); + } + return 1; +} + +#define CHECK_MVSET(l) \ + check_mvset(mvLXCol, temp_col.mv + l, \ + colPic, fc->ps.ph.poc, \ + refPicList, X, refIdxLx, \ + refPicList_col, L ## l, temp_col.ref_idx[l]) + +//derive NoBackwardPredFlag +int ff_vvc_no_backward_pred_flag(const VVCLocalContext *lc) +{ + int check_diffpicount = 0; + int i, j; + const RefPicList *rpl = lc->sc->rpl; + + for (j = 0; j < 2; j++) { + for (i = 0; i < lc->sc->sh.r->num_ref_idx_active[j]; i++) { + if (rpl[j].list[i] > lc->fc->ps.ph.poc) { + check_diffpicount++; + break; + } + } + } + return !check_diffpicount; +} + +//8.5.2.12 Derivation process for collocated motion vectors +static int derive_temporal_colocated_mvs(const VVCLocalContext *lc, MvField temp_col, + int refIdxLx, Mv *mvLXCol, int X, + int colPic, const RefPicList *refPicList_col, int sb_flag) +{ + const VVCFrameContext *fc = lc->fc; + const SliceContext *sc = lc->sc; + RefPicList* refPicList = sc->rpl; + + if (temp_col.pred_flag == PF_INTRA) + return 0; + + if (sb_flag){ + if (X == 0) { + if (temp_col.pred_flag & PF_L0) + return CHECK_MVSET(0); + else if (ff_vvc_no_backward_pred_flag(lc) && (temp_col.pred_flag & PF_L1)) + return CHECK_MVSET(1); + } else { + if (temp_col.pred_flag & PF_L1) + return CHECK_MVSET(1); + else if (ff_vvc_no_backward_pred_flag(lc) && (temp_col.pred_flag & PF_L0)) + return CHECK_MVSET(0); + } + } else { + if (!(temp_col.pred_flag & PF_L0)) + return CHECK_MVSET(1); + else if (temp_col.pred_flag == PF_L0) + return CHECK_MVSET(0); + else if (temp_col.pred_flag == PF_BI) { + if (ff_vvc_no_backward_pred_flag(lc)) { + if (X == 0) + return CHECK_MVSET(0); + else + return CHECK_MVSET(1); + } else { + if (!lc->sc->sh.r->sh_collocated_from_l0_flag) + return CHECK_MVSET(0); + else + return CHECK_MVSET(1); + } + } + } + return 0; +} + +#define TAB_MVF(x, y) \ + tab_mvf[((y) >> MIN_PU_LOG2) * min_pu_width + ((x) >> MIN_PU_LOG2)] + +#define TAB_MVF_PU(v) \ + TAB_MVF(x ## v, y ## v) + +#define TAB_CP_MV(lx, x, y) \ + fc->tab.cp_mv[lx][((((y) >> min_cb_log2_size) * min_cb_width + ((x) >> min_cb_log2_size)) ) * MAX_CONTROL_POINTS] + + +#define DERIVE_TEMPORAL_COLOCATED_MVS(sb_flag) \ + derive_temporal_colocated_mvs(lc, temp_col, \ + refIdxLx, mvLXCol, X, colPic, \ + ff_vvc_get_ref_list(fc, ref, x, y), sb_flag) + +//8.5.2.11 Derivation process for temporal luma motion vector prediction +static int temporal_luma_motion_vector(const VVCLocalContext *lc, + const int refIdxLx, Mv *mvLXCol, const int X, int check_center, int sb_flag) +{ + const VVCFrameContext *fc = lc->fc; + const VVCSPS *sps = fc->ps.sps; + const VVCPPS *pps = fc->ps.pps; + const CodingUnit *cu = lc->cu; + const int subpic_idx = lc->sc->sh.r->curr_subpic_idx; + int x, y, x_end, y_end, colPic, availableFlagLXCol = 0; + int min_pu_width = fc->ps.pps->min_pu_width; + VVCFrame *ref = fc->ref->collocated_ref; + MvField *tab_mvf; + MvField temp_col; + + if (!ref) { + memset(mvLXCol, 0, sizeof(*mvLXCol)); + return 0; + } + + if (!fc->ps.ph.r->ph_temporal_mvp_enabled_flag || (cu->cb_width * cu->cb_height <= 32)) + return 0; + + tab_mvf = ref->tab_dmvr_mvf; + colPic = ref->poc; + + //bottom right collocated motion vector + x = cu->x0 + cu->cb_width; + y = cu->y0 + cu->cb_height; + + x_end = pps->subpic_x[subpic_idx] + pps->subpic_width[subpic_idx]; + y_end = pps->subpic_y[subpic_idx] + pps->subpic_height[subpic_idx]; + + if (tab_mvf && + (cu->y0 >> sps->ctb_log2_size_y) == (y >> sps->ctb_log2_size_y) && + x < x_end && y < y_end) { + x &= ~7; + y &= ~7; + temp_col = TAB_MVF(x, y); + availableFlagLXCol = DERIVE_TEMPORAL_COLOCATED_MVS(sb_flag); + } + if (check_center) { + // derive center collocated motion vector + if (tab_mvf && !availableFlagLXCol) { + x = cu->x0 + (cu->cb_width >> 1); + y = cu->y0 + (cu->cb_height >> 1); + x &= ~7; + y &= ~7; + temp_col = TAB_MVF(x, y); + availableFlagLXCol = DERIVE_TEMPORAL_COLOCATED_MVS(sb_flag); + } + } + return availableFlagLXCol; +} + +void ff_vvc_set_mvf(const VVCLocalContext *lc, const int x0, const int y0, const int w, const int h, const MvField *mvf) +{ + const VVCFrameContext *fc = lc->fc; + MvField *tab_mvf = fc->tab.mvf; + const int min_pu_width = fc->ps.pps->min_pu_width; + const int min_pu_size = 1 << MIN_PU_LOG2; + for (int dy = 0; dy < h; dy += min_pu_size) { + for (int dx = 0; dx < w; dx += min_pu_size) { + const int x = x0 + dx; + const int y = y0 + dy; + TAB_MVF(x, y) = *mvf; + } + } +} + +void ff_vvc_set_intra_mvf(const VVCLocalContext *lc, const int dmvr) +{ + const VVCFrameContext *fc = lc->fc; + const CodingUnit *cu = lc->cu; + MvField *tab_mvf = dmvr ? fc->ref->tab_dmvr_mvf : fc->tab.mvf; + const int min_pu_width = fc->ps.pps->min_pu_width; + const int min_pu_size = 1 << MIN_PU_LOG2; + for (int dy = 0; dy < cu->cb_height; dy += min_pu_size) { + for (int dx = 0; dx < cu->cb_width; dx += min_pu_size) { + const int x = cu->x0 + dx; + const int y = cu->y0 + dy; + TAB_MVF(x, y).pred_flag = PF_INTRA; + } + } +} + +//cbProfFlagLX from 8.5.5.9 Derivation process for motion vector arrays from affine control point motion vectors +static int derive_cb_prof_flag_lx(const VVCLocalContext *lc, const PredictionUnit* pu, int lx, int is_fallback) +{ + const MotionInfo* mi = &pu->mi; + const Mv* cp_mv = &mi->mv[lx][0]; + if (lc->fc->ps.ph.r->ph_prof_disabled_flag || is_fallback) + return 0; + if (mi->motion_model_idc == MOTION_4_PARAMS_AFFINE) { + if (IS_SAME_MV(cp_mv, cp_mv + 1)) + return 0; + } + if (mi->motion_model_idc == MOTION_6_PARAMS_AFFINE) { + if (IS_SAME_MV(cp_mv, cp_mv + 1) && IS_SAME_MV(cp_mv, cp_mv + 2)) + return 0; + } + //fixme: RprConstraintsActiveFlag + return 1; +} + +typedef struct SubblockParams { + int d_hor_x; + int d_ver_x; + int d_hor_y; + int d_ver_y; + int mv_scale_hor; + int mv_scale_ver; + int is_fallback; + + int cb_width; + int cb_height; +} SubblockParams; + +static int is_fallback_mode(const SubblockParams *sp, const PredFlag pred_flag) +{ + const int a = 4 * (2048 + sp->d_hor_x); + const int b = 4 * sp->d_hor_y; + const int c = 4 * (2048 + sp->d_ver_y); + const int d = 4 * sp->d_ver_x; + if (pred_flag == PF_BI) { + const int max_w4 = FFMAX(0, FFMAX(a, FFMAX(b, a + b))); + const int min_w4 = FFMIN(0, FFMIN(a, FFMIN(b, a + b))); + const int max_h4 = FFMAX(0, FFMAX(c, FFMAX(d, c + d))); + const int min_h4 = FFMIN(0, FFMIN(c, FFMIN(d, c + d))); + const int bx_wx4 = ((max_w4 - min_w4) >> 11) + 9; + const int bx_hx4 = ((max_h4 - min_h4) >> 11) + 9; + return bx_wx4 * bx_hx4 > 225; + } else { + const int bx_wxh = (FFABS(a) >> 11) + 9; + const int bx_hxh = (FFABS(d) >> 11) + 9; + const int bx_wxv = (FFABS(b) >> 11) + 9; + const int bx_hxv = (FFABS(c) >> 11) + 9; + if (bx_wxh * bx_hxh <= 165 && bx_wxv * bx_hxv <= 165) + return 0; + } + return 1; +} + +static void init_subblock_params(SubblockParams *sp, const MotionInfo* mi, + const int cb_width, const int cb_height, const int lx) +{ + const int log2_cbw = av_log2(cb_width); + const int log2_cbh = av_log2(cb_height); + const Mv* cp_mv = mi->mv[lx]; + const int num_cp_mv = mi->motion_model_idc + 1; + sp->d_hor_x = (cp_mv[1].x - cp_mv[0].x) * (1 << (MAX_CU_DEPTH - log2_cbw)); + sp->d_ver_x = (cp_mv[1].y - cp_mv[0].y) * (1 << (MAX_CU_DEPTH - log2_cbw)); + if (num_cp_mv == 3) { + sp->d_hor_y = (cp_mv[2].x - cp_mv[0].x) * (1 << (MAX_CU_DEPTH - log2_cbh)); + sp->d_ver_y = (cp_mv[2].y - cp_mv[0].y) * (1 << (MAX_CU_DEPTH - log2_cbh)); + } else { + sp->d_hor_y = -sp->d_ver_x; + sp->d_ver_y = sp->d_hor_x; + } + sp->mv_scale_hor = (cp_mv[0].x) * (1 << MAX_CU_DEPTH); + sp->mv_scale_ver = (cp_mv[0].y) * (1 << MAX_CU_DEPTH); + sp->cb_width = cb_width; + sp->cb_height = cb_height; + sp->is_fallback = is_fallback_mode(sp, mi->pred_flag); +} + +static void derive_subblock_diff_mvs(const VVCLocalContext *lc, PredictionUnit* pu, const SubblockParams* sp, const int lx) +{ + pu->cb_prof_flag[lx] = derive_cb_prof_flag_lx(lc, pu, lx, sp->is_fallback); + if (pu->cb_prof_flag[lx]) { + const int dmv_limit = 1 << 5; + const int pos_offset_x = 6 * (sp->d_hor_x + sp->d_hor_y); + const int pos_offset_y = 6 * (sp->d_ver_x + sp->d_ver_y); + for (int x = 0; x < AFFINE_MIN_BLOCK_SIZE; x++) { + for (int y = 0; y < AFFINE_MIN_BLOCK_SIZE; y++) { + LOCAL_ALIGNED_8(Mv, diff, [1]); + diff->x = x * (sp->d_hor_x * (1 << 2)) + y * (sp->d_hor_y * (1 << 2)) - pos_offset_x; + diff->y = x * (sp->d_ver_x * (1 << 2)) + y * (sp->d_ver_y * (1 << 2)) - pos_offset_y; + ff_vvc_round_mv(diff, 0, 8); + pu->diff_mv_x[lx][AFFINE_MIN_BLOCK_SIZE * y + x] = av_clip(diff->x, -dmv_limit + 1, dmv_limit - 1); + pu->diff_mv_y[lx][AFFINE_MIN_BLOCK_SIZE * y + x] = av_clip(diff->y, -dmv_limit + 1, dmv_limit - 1); + } + } + } +} + +static void store_cp_mv(const VVCLocalContext *lc, const MotionInfo *mi, const int lx) +{ + VVCFrameContext *fc = lc->fc; + const CodingUnit *cu = lc->cu; + const int log2_min_cb_size = fc->ps.sps->min_cb_log2_size_y; + const int min_cb_size = fc->ps.sps->min_cb_size_y; + const int min_cb_width = fc->ps.pps->min_cb_width; + const int num_cp_mv = mi->motion_model_idc + 1; + + for (int dy = 0; dy < cu->cb_height; dy += min_cb_size) { + for (int dx = 0; dx < cu->cb_width; dx += min_cb_size) { + const int x_cb = (cu->x0 + dx) >> log2_min_cb_size; + const int y_cb = (cu->y0 + dy) >> log2_min_cb_size; + const int offset = (y_cb * min_cb_width + x_cb) * MAX_CONTROL_POINTS; + + memcpy(&fc->tab.cp_mv[lx][offset], mi->mv[lx], sizeof(Mv) * num_cp_mv); + SAMPLE_CTB(fc->tab.mmi, x_cb, y_cb) = mi->motion_model_idc; + } + } +} + +//8.5.5.9 Derivation process for motion vector arrays from affine control point motion vectors +void ff_vvc_store_sb_mvs(const VVCLocalContext *lc, PredictionUnit *pu) +{ + const CodingUnit *cu = lc->cu; + const MotionInfo *mi = &pu->mi; + const int sbw = cu->cb_width / mi->num_sb_x; + const int sbh = cu->cb_height / mi->num_sb_y; + SubblockParams params[2]; + MvField mvf; + + mvf.pred_flag = mi->pred_flag; + mvf.bcw_idx = mi->bcw_idx; + mvf.hpel_if_idx = mi->hpel_if_idx; + mvf.ciip_flag = 0; + for (int i = 0; i < 2; i++) { + const PredFlag mask = i + 1; + if (mi->pred_flag & mask) { + store_cp_mv(lc, mi, i); + init_subblock_params(params + i, mi, cu->cb_width, cu->cb_height, i); + derive_subblock_diff_mvs(lc, pu, params + i, i); + mvf.ref_idx[i] = mi->ref_idx[i]; + } + } + + for (int sby = 0; sby < mi->num_sb_y; sby++) { + for (int sbx = 0; sbx < mi->num_sb_x; sbx++) { + const int x0 = cu->x0 + sbx * sbw; + const int y0 = cu->y0 + sby * sbh; + for (int i = 0; i < 2; i++) { + const PredFlag mask = i + 1; + if (mi->pred_flag & mask) { + const SubblockParams* sp = params + i; + const int x_pos_cb = sp->is_fallback ? (cu->cb_width >> 1) : (2 + (sbx << MIN_CU_LOG2)); + const int y_pos_cb = sp->is_fallback ? (cu->cb_height >> 1) : (2 + (sby << MIN_CU_LOG2)); + Mv *mv = mvf.mv + i; + + mv->x = sp->mv_scale_hor + sp->d_hor_x * x_pos_cb + sp->d_hor_y * y_pos_cb; + mv->y = sp->mv_scale_ver + sp->d_ver_x * x_pos_cb + sp->d_ver_y * y_pos_cb; + ff_vvc_round_mv(mv, 0, MAX_CU_DEPTH); + ff_vvc_clip_mv(mv); + } + } + ff_vvc_set_mvf(lc, x0, y0, sbw, sbh, &mvf); + } + } +} + +void ff_vvc_store_gpm_mvf(const VVCLocalContext *lc, const PredictionUnit *pu) +{ + const CodingUnit *cu = lc->cu; + const int angle_idx = ff_vvc_gpm_angle_idx[pu->gpm_partition_idx]; + const int distance_idx = ff_vvc_gpm_distance_idx[pu->gpm_partition_idx]; + const int displacement_x = ff_vvc_gpm_distance_lut[angle_idx]; + const int displacement_y = ff_vvc_gpm_distance_lut[(angle_idx + 8) % 32]; + const int is_flip = angle_idx >= 13 &&angle_idx <= 27; + const int shift_hor = (angle_idx % 16 == 8 || (angle_idx % 16 && cu->cb_height >= cu->cb_width)) ? 0 : 1; + const int sign = angle_idx < 16 ? 1 : -1; + const int block_size = 4; + int offset_x = (-cu->cb_width) >> 1; + int offset_y = (-cu->cb_height) >> 1; + + if (!shift_hor) + offset_y += sign * ((distance_idx * cu->cb_height) >> 3); + else + offset_x += sign * ((distance_idx * cu->cb_width) >> 3); + + for (int y = 0; y < cu->cb_height; y += block_size) { + for (int x = 0; x < cu->cb_width; x += block_size) { + const int motion_idx = (((x + offset_x) * (1 << 1)) + 5) * displacement_x + + (((y + offset_y) * (1 << 1)) + 5) * displacement_y; + const int s_type = FFABS(motion_idx) < 32 ? 2 : (motion_idx <= 0 ? (1 - is_flip) : is_flip); + const int pred_flag = pu->gpm_mv[0].pred_flag | pu->gpm_mv[1].pred_flag; + const int x0 = cu->x0 + x; + const int y0 = cu->y0 + y; + + if (!s_type) + ff_vvc_set_mvf(lc, x0, y0, block_size, block_size, pu->gpm_mv + 0); + else if (s_type == 1 || (s_type == 2 && pred_flag != PF_BI)) + ff_vvc_set_mvf(lc, x0, y0, block_size, block_size, pu->gpm_mv + 1); + else { + MvField mvf = pu->gpm_mv[0]; + const MvField *mv1 = &pu->gpm_mv[1]; + const int lx = mv1->pred_flag - PF_L0; + mvf.pred_flag = PF_BI; + mvf.ref_idx[lx] = mv1->ref_idx[lx]; + mvf.mv[lx] = mv1->mv[lx]; + ff_vvc_set_mvf(lc, x0, y0, block_size, block_size, &mvf); + } + } + } +} + +void ff_vvc_store_mvf(const VVCLocalContext *lc, const MvField *mvf) +{ + const CodingUnit *cu = lc->cu; + ff_vvc_set_mvf(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height, mvf); +} + +void ff_vvc_store_mv(const VVCLocalContext *lc, const MotionInfo *mi) +{ + const CodingUnit *cu = lc->cu; + MvField mvf; + + mvf.hpel_if_idx = mi->hpel_if_idx; + mvf.bcw_idx = mi->bcw_idx; + mvf.pred_flag = mi->pred_flag; + mvf.ciip_flag = 0; + + for (int i = 0; i < 2; i++) { + const PredFlag mask = i + 1; + if (mvf.pred_flag & mask) { + mvf.mv[i] = mi->mv[i][0]; + mvf.ref_idx[i] = mi->ref_idx[i]; + } + } + ff_vvc_set_mvf(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height, &mvf); +} + +typedef enum NeighbourIdx { + A0, + A1, + A2, + B0, + B1, + B2, + B3, + NUM_NBS, + NB_IDX_NONE = NUM_NBS, +} NeighbourIdx; + +typedef struct Neighbour { + int x; + int y; + + int checked; + int available; +} Neighbour; + +typedef struct NeighbourContext { + Neighbour neighbours[NUM_NBS]; + const VVCLocalContext *lc; +} NeighbourContext; + +static int is_a0_available(const VVCLocalContext *lc, const CodingUnit *cu) +{ + const VVCFrameContext *fc = lc->fc; + const VVCSPS *sps = fc->ps.sps; + const int x0b = av_mod_uintp2(cu->x0, sps->ctb_log2_size_y); + int cand_bottom_left; + + if (!x0b && !lc->ctb_left_flag) { + cand_bottom_left = 0; + } else { + const int log2_min_cb_size = sps->min_cb_log2_size_y; + const int min_cb_width = fc->ps.pps->min_cb_width; + const int x = (cu->x0 - 1) >> log2_min_cb_size; + const int y = (cu->y0 + cu->cb_height) >> log2_min_cb_size; + const int max_y = FFMIN(fc->ps.pps->height, ((cu->y0 >> sps->ctb_log2_size_y) + 1) << sps->ctb_log2_size_y); + if (cu->y0 + cu->cb_height >= max_y) + cand_bottom_left = 0; + else + cand_bottom_left = SAMPLE_CTB(fc->tab.cb_width[0], x, y) != 0; + } + return cand_bottom_left; +} + +static void init_neighbour_context(NeighbourContext *ctx, const VVCLocalContext *lc) +{ + const CodingUnit *cu = lc->cu; + const NeighbourAvailable *na = &lc->na; + const int x0 = cu->x0; + const int y0 = cu->y0; + const int cb_width = cu->cb_width; + const int cb_height = cu->cb_height; + const int a0_available = is_a0_available(lc, cu); + + Neighbour neighbours[NUM_NBS] = { + { x0 - 1, y0 + cb_height, !a0_available }, //A0 + { x0 - 1, y0 + cb_height - 1, !na->cand_left }, //A1 + { x0 - 1, y0, !na->cand_left }, //A2 + { x0 + cb_width, y0 - 1, !na->cand_up_right }, //B0 + { x0 + cb_width - 1, y0 - 1, !na->cand_up }, //B1 + { x0 - 1, y0 - 1, !na->cand_up_left }, //B2 + { x0, y0 - 1, !na->cand_up }, //B3 + }; + + memcpy(ctx->neighbours, neighbours, sizeof(neighbours)); + ctx->lc = lc; +} + +static av_always_inline PredMode pred_flag_to_mode(PredFlag pred) +{ + return pred == PF_IBC ? MODE_IBC : (pred == PF_INTRA ? MODE_INTRA : MODE_INTER); +} + +static int check_available(Neighbour *n, const VVCLocalContext *lc, const int check_mer) +{ + const VVCFrameContext *fc = lc->fc; + const VVCSPS *sps = fc->ps.sps; + const CodingUnit *cu = lc->cu; + const MvField *tab_mvf = fc->tab.mvf; + const int min_pu_width = fc->ps.pps->min_pu_width; + + if (!n->checked) { + n->checked = 1; + n->available = !sps->r->sps_entropy_coding_sync_enabled_flag || ((n->x >> sps->ctb_log2_size_y) <= (cu->x0 >> sps->ctb_log2_size_y)); + n->available &= cu->pred_mode == pred_flag_to_mode(TAB_MVF(n->x, n->y).pred_flag); + if (check_mer) + n->available &= !is_same_mer(fc, n->x, n->y, cu->x0, cu->y0); + } + return n->available; +} + +static const MvField *mv_merge_candidate(const VVCLocalContext *lc, const int x_cand, const int y_cand) +{ + const VVCFrameContext *fc = lc->fc; + const int min_pu_width = fc->ps.pps->min_pu_width; + const MvField* tab_mvf = fc->tab.mvf; + const MvField *mvf = &TAB_MVF(x_cand, y_cand); + + return mvf; +} + +static const MvField* mv_merge_from_nb(NeighbourContext *ctx, const NeighbourIdx nb) +{ + const VVCLocalContext *lc = ctx->lc; + Neighbour *n = &ctx->neighbours[nb]; + + if (check_available(n, lc, 1)) + return mv_merge_candidate(lc, n->x, n->y); + return 0; +} +#define MV_MERGE_FROM_NB(nb) mv_merge_from_nb(&nctx, nb) + +//8.5.2.3 Derivation process for spatial merging candidates +static int mv_merge_spatial_candidates(const VVCLocalContext *lc, const int merge_idx, + const MvField **nb_list, MvField *cand_list, int *nb_merge_cand) +{ + const MvField *cand; + int num_cands = 0; + NeighbourContext nctx; + + static NeighbourIdx nbs[][2] = { + {B1, NB_IDX_NONE }, + {A1, B1 }, + {B0, B1 }, + {A0, A1 }, + }; + + init_neighbour_context(&nctx, lc); + for (int i = 0; i < FF_ARRAY_ELEMS(nbs); i++) { + NeighbourIdx nb = nbs[i][0]; + NeighbourIdx old = nbs[i][1]; + cand = nb_list[nb] = MV_MERGE_FROM_NB(nb); + if (cand && !compare_mv_ref_idx(cand, nb_list[old])) { + cand_list[num_cands] = *cand; + if (merge_idx == num_cands) + return 1; + num_cands++; + } + } + if (num_cands != 4) { + cand = MV_MERGE_FROM_NB(B2); + if (cand && !compare_mv_ref_idx(cand, nb_list[A1]) + && !compare_mv_ref_idx(cand, nb_list[B1])) { + cand_list[num_cands] = *cand; + if (merge_idx == num_cands) + return 1; + num_cands++; + } + } + *nb_merge_cand = num_cands; + return 0; +} + +static int mv_merge_temporal_candidate(const VVCLocalContext *lc, MvField *cand) +{ + const VVCFrameContext *fc = lc->fc; + const CodingUnit *cu = lc->cu; + + memset(cand, 0, sizeof(*cand)); + if (fc->ps.ph.r->ph_temporal_mvp_enabled_flag && (cu->cb_width * cu->cb_height > 32)) { + int available_l0 = temporal_luma_motion_vector(lc, 0, cand->mv + 0, 0, 1, 0); + int available_l1 = IS_B(lc->sc->sh.r) ? + temporal_luma_motion_vector(lc, 0, cand->mv + 1, 1, 1, 0) : 0; + cand->pred_flag = available_l0 + (available_l1 << 1); + } + return cand->pred_flag; +} + +//8.5.2.6 Derivation process for history-based merging candidates +static int mv_merge_history_candidates(const VVCLocalContext *lc, const int merge_idx, + const MvField **nb_list, MvField *cand_list, int *num_cands) +{ + const VVCSPS *sps = lc->fc->ps.sps; + const EntryPoint* ep = lc->ep; + for (int i = 1; i <= ep->num_hmvp && (*num_cands < sps->max_num_merge_cand - 1); i++) { + const MvField *h = &ep->hmvp[ep->num_hmvp - i]; + const int same_motion = i <= 2 && (compare_mv_ref_idx(h, nb_list[A1]) || compare_mv_ref_idx(h, nb_list[B1])); + if (!same_motion) { + cand_list[*num_cands] = *h; + if (merge_idx == *num_cands) + return 1; + (*num_cands)++; + } + } + return 0; +} + +//8.5.2.4 Derivation process for pairwise average merging candidate +static int mv_merge_pairwise_candidate(MvField *cand_list, const int num_cands, const int is_b) +{ + if (num_cands > 1) { + const int num_ref_rists = is_b ? 2 : 1; + const MvField* p0 = cand_list + 0; + const MvField* p1 = cand_list + 1; + MvField* cand = cand_list + num_cands; + + cand->pred_flag = 0; + for (int i = 0; i < num_ref_rists; i++) { + PredFlag mask = i + 1; + if (p0->pred_flag & mask) { + cand->pred_flag |= mask; + cand->ref_idx[i] = p0->ref_idx[i]; + if (p1->pred_flag & mask) { + Mv *mv = cand->mv + i; + mv->x = p0->mv[i].x + p1->mv[i].x; + mv->y = p0->mv[i].y + p1->mv[i].y; + ff_vvc_round_mv(mv, 0, 1); + } else { + cand->mv[i] = p0->mv[i]; + } + } else if (p1->pred_flag & mask) { + cand->pred_flag |= mask; + cand->mv[i] = p1->mv[i]; + cand->ref_idx[i] = p1->ref_idx[i]; + } + } + if (cand->pred_flag) { + cand->hpel_if_idx = p0->hpel_if_idx == p1->hpel_if_idx ? p0->hpel_if_idx : 0; + cand->bcw_idx = 0; + cand->ciip_flag = 0; + return 1; + } + } + return 0; +} + +//8.5.2.5 Derivation process for zero motion vector merging candidates +static void mv_merge_zero_motion_candidate(const VVCLocalContext *lc, const int merge_idx, + MvField *cand_list, int num_cands) +{ + const VVCSPS *sps = lc->fc->ps.sps; + const H266RawSliceHeader *rsh = lc->sc->sh.r; + const int num_ref_idx = IS_P(rsh) ? + rsh->num_ref_idx_active[L0] : FFMIN(rsh->num_ref_idx_active[L0], rsh->num_ref_idx_active[L1]); + int zero_idx = 0; + + while (num_cands < sps->max_num_merge_cand) { + MvField *cand = cand_list + num_cands; + + cand->pred_flag = PF_L0 + (IS_B(rsh) << 1); + AV_ZERO64(cand->mv + 0); + AV_ZERO64(cand->mv + 1); + cand->ref_idx[0] = zero_idx < num_ref_idx ? zero_idx : 0; + cand->ref_idx[1] = zero_idx < num_ref_idx ? zero_idx : 0; + cand->bcw_idx = 0; + cand->hpel_if_idx = 0; + if (merge_idx == num_cands) + return; + num_cands++; + zero_idx++; + } +} + +static void mv_merge_mode(const VVCLocalContext *lc, const int merge_idx, MvField *cand_list) +{ + int num_cands = 0; + const MvField *nb_list[NUM_NBS + 1] = { NULL }; + + if (mv_merge_spatial_candidates(lc, merge_idx, nb_list, cand_list, &num_cands)) + return; + + if (mv_merge_temporal_candidate(lc, &cand_list[num_cands])) { + if (merge_idx == num_cands) + return; + num_cands++; + } + + if (mv_merge_history_candidates(lc, merge_idx, nb_list, cand_list, &num_cands)) + return; + + if (mv_merge_pairwise_candidate(cand_list, num_cands, IS_B(lc->sc->sh.r))) { + if (merge_idx == num_cands) + return; + num_cands++; + } + + mv_merge_zero_motion_candidate(lc, merge_idx, cand_list, num_cands); +} + +//8.5.2.2 Derivation process for luma motion vectors for merge mode +void ff_vvc_luma_mv_merge_mode(VVCLocalContext *lc, const int merge_idx, const int ciip_flag, MvField *mv) +{ + const CodingUnit *cu = lc->cu; + MvField cand_list[MRG_MAX_NUM_CANDS]; + + ff_vvc_set_neighbour_available(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height); + mv_merge_mode(lc, merge_idx, cand_list); + *mv = cand_list[merge_idx]; + //ciip flag in not inhritable + mv->ciip_flag = ciip_flag; +} + +//8.5.4.2 Derivation process for luma motion vectors for geometric partitioning merge mode +void ff_vvc_luma_mv_merge_gpm(VVCLocalContext *lc, const int merge_gpm_idx[2], MvField *mv) +{ + const CodingUnit *cu = lc->cu; + MvField cand_list[MRG_MAX_NUM_CANDS]; + + const int idx[] = { merge_gpm_idx[0], merge_gpm_idx[1] + (merge_gpm_idx[1] >= merge_gpm_idx[0]) }; + + ff_vvc_set_neighbour_available(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height); + mv_merge_mode(lc, FFMAX(idx[0], idx[1]), cand_list); + memset(mv, 0, 2 * sizeof(*mv)); + for (int i = 0; i < 2; i++) { + int lx = idx[i] & 1; + int mask = lx + PF_L0; + MvField *cand = cand_list + idx[i]; + if (!(cand->pred_flag & mask)) { + lx = !lx; + mask = lx + PF_L0; + } + mv[i].pred_flag = mask; + mv[i].ref_idx[lx] = cand->ref_idx[lx]; + mv[i].mv[lx] = cand->mv[lx]; + } + +} + +//8.5.5.5 Derivation process for luma affine control point motion vectors from a neighbouring block +static void affine_cps_from_nb(const VVCLocalContext *lc, + const int x_nb, int y_nb, const int nbw, const int nbh, const int lx, + Mv *cps, int num_cps) +{ + const VVCFrameContext *fc = lc->fc; + const CodingUnit *cu = lc->cu; + const int x0 = cu->x0; + const int y0 = cu->y0; + const int cb_width = cu->cb_width; + const int cb_height = cu->cb_height; + const MvField* tab_mvf = fc->tab.mvf; + const int min_cb_log2_size = fc->ps.sps->min_cb_log2_size_y; + const int min_cb_width = fc->ps.pps->min_cb_width; + + const int log2_nbw = ff_log2(nbw); + const int log2_nbh = ff_log2(nbh); + const int is_ctb_boundary = !((y_nb + nbh) % fc->ps.sps->ctb_size_y) && (y_nb + nbh == y0); + const Mv *l, *r; + int mv_scale_hor, mv_scale_ver, d_hor_x, d_ver_x, d_hor_y, d_ver_y, motion_model_idc_nb; + if (is_ctb_boundary) { + const int min_pu_width = fc->ps.pps->min_pu_width; + l = &TAB_MVF(x_nb, y_nb + nbh - 1).mv[lx]; + r = &TAB_MVF(x_nb + nbw - 1, y_nb + nbh - 1).mv[lx]; + } else { + const int x = x_nb >> min_cb_log2_size; + const int y = y_nb >> min_cb_log2_size; + motion_model_idc_nb = SAMPLE_CTB(fc->tab.mmi, x, y); + + l = &TAB_CP_MV(lx, x_nb, y_nb); + r = &TAB_CP_MV(lx, x_nb + nbw - 1, y_nb) + 1; + } + mv_scale_hor = l->x * (1 << 7); + mv_scale_ver = l->y * (1 << 7); + d_hor_x = (r->x - l->x) * (1 << (7 - log2_nbw)); + d_ver_x = (r->y - l->y) * (1 << (7 - log2_nbw)); + if (!is_ctb_boundary && motion_model_idc_nb == MOTION_6_PARAMS_AFFINE) { + const Mv* lb = &TAB_CP_MV(lx, x_nb, y_nb + nbh - 1) + 2; + d_hor_y = (lb->x - l->x) * (1 << (7 - log2_nbh)); + d_ver_y = (lb->y - l->y) * (1 << (7 - log2_nbh)); + } else { + d_hor_y = -d_ver_x; + d_ver_y = d_hor_x; + } + + if (is_ctb_boundary) { + y_nb = y0; + } + cps[0].x = mv_scale_hor + d_hor_x * (x0 - x_nb) + d_hor_y * (y0 - y_nb); + cps[0].y = mv_scale_ver + d_ver_x * (x0 - x_nb) + d_ver_y * (y0 - y_nb); + cps[1].x = mv_scale_hor + d_hor_x * (x0 + cb_width - x_nb) + d_hor_y * (y0 - y_nb); + cps[1].y = mv_scale_ver + d_ver_x * (x0 + cb_width - x_nb) + d_ver_y * (y0 - y_nb); + if (num_cps == 3) { + cps[2].x = mv_scale_hor + d_hor_x * (x0 - x_nb) + d_hor_y * (y0 + cb_height - y_nb); + cps[2].y = mv_scale_ver + d_ver_x * (x0 - x_nb) + d_ver_y * (y0 + cb_height - y_nb); + } + for (int i = 0; i < num_cps; i++) { + ff_vvc_round_mv(cps + i, 0, 7); + ff_vvc_clip_mv(cps + i); + } +} + +//derive affine neighbour's postion, width and height, +static int affine_neighbour_cb(const VVCFrameContext *fc, const int x_nb, const int y_nb, int *x_cb, int *y_cb, int *cbw, int *cbh) +{ + const int log2_min_cb_size = fc->ps.sps->min_cb_log2_size_y; + const int min_cb_width = fc->ps.pps->min_cb_width; + const int x = x_nb >> log2_min_cb_size; + const int y = y_nb >> log2_min_cb_size; + const int motion_model_idc = SAMPLE_CTB(fc->tab.mmi, x, y); + if (motion_model_idc) { + *x_cb = SAMPLE_CTB(fc->tab.cb_pos_x[0], x, y); + *y_cb = SAMPLE_CTB(fc->tab.cb_pos_y[0], x, y); + *cbw = SAMPLE_CTB(fc->tab.cb_width[0], x, y); + *cbh = SAMPLE_CTB(fc->tab.cb_height[0], x, y); + } + return motion_model_idc; +} + +//part of 8.5.5.2 Derivation process for motion vectors and reference indices in subblock merge mode +static int affine_merge_candidate(const VVCLocalContext *lc, const int x_cand, const int y_cand, MotionInfo* mi) +{ + const VVCFrameContext *fc = lc->fc; + int x, y, w, h, motion_model_idc; + + motion_model_idc = affine_neighbour_cb(fc, x_cand, y_cand, &x, &y, &w, &h); + if (motion_model_idc) { + const int min_pu_width = fc->ps.pps->min_pu_width; + const MvField* tab_mvf = fc->tab.mvf; + const MvField *mvf = &TAB_MVF(x, y); + + mi->bcw_idx = mvf->bcw_idx; + mi->pred_flag = mvf->pred_flag; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (mi->pred_flag & mask) { + affine_cps_from_nb(lc, x, y, w, h, i, &mi->mv[i][0], motion_model_idc + 1); + } + mi->ref_idx[i] = mvf->ref_idx[i]; + } + mi->motion_model_idc = motion_model_idc; + } + return motion_model_idc; +} + +static int affine_merge_from_nbs(NeighbourContext *ctx, const NeighbourIdx *nbs, const int num_nbs, MotionInfo* cand) +{ + const VVCLocalContext *lc = ctx->lc; + for (int i = 0; i < num_nbs; i++) { + Neighbour *n = &ctx->neighbours[nbs[i]]; + if (check_available(n, lc, 1) && affine_merge_candidate(lc, n->x, n->y, cand)) + return 1; + } + return 0; +} +#define AFFINE_MERGE_FROM_NBS(nbs) affine_merge_from_nbs(&nctx, nbs, FF_ARRAY_ELEMS(nbs), mi) + + +static const MvField* derive_corner_mvf(NeighbourContext *ctx, const NeighbourIdx *neighbour, const int num_neighbour) +{ + const VVCFrameContext *fc = ctx->lc->fc; + const MvField *tab_mvf = fc->tab.mvf; + const int min_pu_width = fc->ps.pps->min_pu_width; + for (int i = 0; i < num_neighbour; i++) { + Neighbour *n = &ctx->neighbours[neighbour[i]]; + if (check_available(n, ctx->lc, 1)) { + return &TAB_MVF(n->x, n->y); + } + } + return NULL; +} + +#define DERIVE_CORNER_MV(nbs) derive_corner_mvf(nctx, nbs, FF_ARRAY_ELEMS(nbs)) + +// check if the mv's and refidx are the same between A and B +static av_always_inline int compare_pf_ref_idx(const MvField *A, const struct MvField *B, const struct MvField *C, const int lx) +{ + + const PredFlag mask = (lx + 1) & A->pred_flag; + if (!(B->pred_flag & mask)) + return 0; + if (A->ref_idx[lx] != B->ref_idx[lx]) + return 0; + if (C) { + if (!(C->pred_flag & mask)) + return 0; + if (A->ref_idx[lx] != C->ref_idx[lx]) + return 0; + } + return 1; +} + +static av_always_inline void sb_clip_location(const VVCLocalContext *lc, + const int x_ctb, const int y_ctb, const Mv* temp_mv, int *x, int *y) +{ + const VVCFrameContext *fc = lc->fc; + const VVCPPS *pps = fc->ps.pps; + const int ctb_log2_size = fc->ps.sps->ctb_log2_size_y; + const int subpic_idx = lc->sc->sh.r->curr_subpic_idx; + const int x_end = pps->subpic_x[subpic_idx] + pps->subpic_width[subpic_idx]; + const int y_end = pps->subpic_y[subpic_idx] + pps->subpic_height[subpic_idx]; + + *x = av_clip(*x + temp_mv->x, x_ctb, FFMIN(x_end - 1, x_ctb + (1 << ctb_log2_size) + 3)) & ~7; + *y = av_clip(*y + temp_mv->y, y_ctb, FFMIN(y_end - 1, y_ctb + (1 << ctb_log2_size) - 1)) & ~7; +} + +static void sb_temproal_luma_motion(const VVCLocalContext *lc, + const int x_ctb, const int y_ctb, const Mv *temp_mv, + int x, int y, uint8_t *pred_flag, Mv *mv) +{ + MvField temp_col; + Mv* mvLXCol; + const int refIdxLx = 0; + const VVCFrameContext *fc = lc->fc; + const VVCSH *sh = &lc->sc->sh; + const int min_pu_width = fc->ps.pps->min_pu_width; + VVCFrame *ref = fc->ref->collocated_ref; + MvField *tab_mvf = ref->tab_dmvr_mvf; + int colPic = ref->poc; + int X = 0; + + sb_clip_location(lc, x_ctb, y_ctb, temp_mv, &x, &y); + + temp_col = TAB_MVF(x, y); + mvLXCol = mv + 0; + *pred_flag = DERIVE_TEMPORAL_COLOCATED_MVS(1); + if (IS_B(sh->r)) { + X = 1; + mvLXCol = mv + 1; + *pred_flag |= (DERIVE_TEMPORAL_COLOCATED_MVS(1)) << 1; + } +} + +//8.5.5.4 Derivation process for subblock-based temporal merging base motion data +static int sb_temporal_luma_motion_data(const VVCLocalContext *lc, const MvField *a1, + const int x_ctb, const int y_ctb, MvField *ctr_mvf, Mv *temp_mv) +{ + const VVCFrameContext *fc = lc->fc; + const RefPicList *rpl = lc->sc->rpl; + const CodingUnit *cu = lc->cu; + const int x = cu->x0 + cu->cb_width / 2; + const int y = cu->y0 + cu->cb_height / 2; + const VVCFrame *ref = fc->ref->collocated_ref; + + int colPic; + + memset(temp_mv, 0, sizeof(*temp_mv)); + + if (!ref) { + memset(ctr_mvf, 0, sizeof(*ctr_mvf)); + return 0; + } + + colPic = ref->poc; + + if (a1) { + if ((a1->pred_flag & PF_L0) && colPic == rpl[0].list[a1->ref_idx[0]]) + *temp_mv = a1->mv[0]; + else if ((a1->pred_flag & PF_L1) && colPic == rpl[1].list[a1->ref_idx[1]]) + *temp_mv = a1->mv[1]; + ff_vvc_round_mv(temp_mv, 0, 4); + } + sb_temproal_luma_motion(lc, x_ctb, y_ctb, temp_mv, x, y, &ctr_mvf->pred_flag , ctr_mvf->mv); + + return ctr_mvf->pred_flag; +} + + +//8.5.5.3 Derivation process for subblock-based temporal merging candidates +static int sb_temporal_merge_candidate(const VVCLocalContext* lc, NeighbourContext *nctx, PredictionUnit *pu) +{ + const VVCFrameContext *fc = lc->fc; + const CodingUnit *cu = lc->cu; + const VVCSPS *sps = fc->ps.sps; + const VVCPH *ph = &fc->ps.ph; + MotionInfo *mi = &pu->mi; + const int ctb_log2_size = sps->ctb_log2_size_y; + const int x0 = cu->x0; + const int y0 = cu->y0; + const NeighbourIdx n = A1; + const MvField *a1; + MvField ctr_mvf; + LOCAL_ALIGNED_8(Mv, temp_mv, [1]); + const int x_ctb = (x0 >> ctb_log2_size) << ctb_log2_size; + const int y_ctb = (y0 >> ctb_log2_size) << ctb_log2_size; + + + if (!ph->r->ph_temporal_mvp_enabled_flag || + !sps->r->sps_sbtmvp_enabled_flag || + (cu->cb_width < 8 && cu->cb_height < 8)) + return 0; + + mi->num_sb_x = cu->cb_width >> 3; + mi->num_sb_y = cu->cb_height >> 3; + + a1 = derive_corner_mvf(nctx, &n, 1); + if (sb_temporal_luma_motion_data(lc, a1, x_ctb, y_ctb, &ctr_mvf, temp_mv)) { + const int sbw = cu->cb_width / mi->num_sb_x; + const int sbh = cu->cb_height / mi->num_sb_y; + MvField mvf = {0}; + for (int sby = 0; sby < mi->num_sb_y; sby++) { + for (int sbx = 0; sbx < mi->num_sb_x; sbx++) { + int x = x0 + sbx * sbw; + int y = y0 + sby * sbh; + sb_temproal_luma_motion(lc, x_ctb, y_ctb, temp_mv, x + sbw / 2, y + sbh / 2, &mvf.pred_flag, mvf.mv); + if (!mvf.pred_flag) { + mvf.pred_flag = ctr_mvf.pred_flag; + memcpy(mvf.mv, ctr_mvf.mv, sizeof(mvf.mv)); + } + ff_vvc_set_mvf(lc, x, y, sbw, sbh, &mvf); + } + } + return 1; + } + return 0; +} + +static int affine_merge_const1(const MvField *c0, const MvField *c1, const MvField *c2, MotionInfo *mi) +{ + if (c0 && c1 && c2) { + mi->pred_flag = 0; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (compare_pf_ref_idx(c0, c1, c2, i)) { + mi->pred_flag |= mask; + mi->ref_idx[i] = c0->ref_idx[i]; + mi->mv[i][0] = c0->mv[i]; + mi->mv[i][1] = c1->mv[i]; + mi->mv[i][2] = c2->mv[i]; + } + } + if (mi->pred_flag) { + if (mi->pred_flag == PF_BI) + mi->bcw_idx = c0->bcw_idx; + mi->motion_model_idc = MOTION_6_PARAMS_AFFINE; + return 1; + } + } + return 0; +} + +static int affine_merge_const2(const MvField *c0, const MvField *c1, const MvField *c3, MotionInfo *mi) +{ + if (c0 && c1 && c3) { + mi->pred_flag = 0; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (compare_pf_ref_idx(c0, c1, c3, i)) { + mi->pred_flag |= mask; + mi->ref_idx[i] = c0->ref_idx[i]; + mi->mv[i][0] = c0->mv[i]; + mi->mv[i][1] = c1->mv[i]; + mi->mv[i][2].x = c3->mv[i].x + c0->mv[i].x - c1->mv[i].x; + mi->mv[i][2].y = c3->mv[i].y + c0->mv[i].y - c1->mv[i].y; + ff_vvc_clip_mv(&mi->mv[i][2]); + } + } + if (mi->pred_flag) { + mi->bcw_idx = mi->pred_flag == PF_BI ? c0->bcw_idx : 0; + mi->motion_model_idc = MOTION_6_PARAMS_AFFINE; + return 1; + } + } + return 0; +} + +static int affine_merge_const3(const MvField *c0, const MvField *c2, const MvField *c3, MotionInfo *mi) +{ + if (c0 && c2 && c3) { + mi->pred_flag = 0; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (compare_pf_ref_idx(c0, c2, c3, i)) { + mi->pred_flag |= mask; + mi->ref_idx[i] = c0->ref_idx[i]; + mi->mv[i][0] = c0->mv[i]; + mi->mv[i][1].x = c3->mv[i].x + c0->mv[i].x - c2->mv[i].x; + mi->mv[i][1].y = c3->mv[i].y + c0->mv[i].y - c2->mv[i].y; + ff_vvc_clip_mv(&mi->mv[i][1]); + mi->mv[i][2] = c2->mv[i]; + } + } + if (mi->pred_flag) { + mi->bcw_idx = mi->pred_flag == PF_BI ? c0->bcw_idx : 0; + mi->motion_model_idc = MOTION_6_PARAMS_AFFINE; + return 1; + } + } + return 0; +} + +static int affine_merge_const4(const MvField *c1, const MvField *c2, const MvField *c3, MotionInfo *mi) +{ + if (c1 && c2 && c3) { + mi->pred_flag = 0; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (compare_pf_ref_idx(c1, c2, c3, i)) { + mi->pred_flag |= mask; + mi->ref_idx[i] = c1->ref_idx[i]; + mi->mv[i][0].x = c1->mv[i].x + c2->mv[i].x - c3->mv[i].x; + mi->mv[i][0].y = c1->mv[i].y + c2->mv[i].y - c3->mv[i].y; + ff_vvc_clip_mv(&mi->mv[i][0]); + mi->mv[i][1] = c1->mv[i]; + mi->mv[i][2] = c2->mv[i]; + } + } + if (mi->pred_flag) { + mi->bcw_idx = mi->pred_flag == PF_BI ? c1->bcw_idx : 0; + mi->motion_model_idc = MOTION_6_PARAMS_AFFINE; + return 1; + } + } + return 0; +} + +static int affine_merge_const5(const MvField *c0, const MvField *c1, MotionInfo *mi) +{ + if (c0 && c1) { + mi->pred_flag = 0; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (compare_pf_ref_idx(c0, c1, NULL, i)) { + mi->pred_flag |= mask; + mi->ref_idx[i] = c0->ref_idx[i]; + mi->mv[i][0] = c0->mv[i]; + mi->mv[i][1] = c1->mv[i]; + } + } + if (mi->pred_flag) { + if (mi->pred_flag == PF_BI) + mi->bcw_idx = c0->bcw_idx; + mi->motion_model_idc = MOTION_4_PARAMS_AFFINE; + return 1; + } + } + return 0; +} + +static int affine_merge_const6(const MvField* c0, const MvField* c2, const int cb_width, const int cb_height, MotionInfo *mi) +{ + if (c0 && c2) { + const int shift = 7 + av_log2(cb_width) - av_log2(cb_height); + mi->pred_flag = 0; + for (int i = 0; i < 2; i++) { + PredFlag mask = i + 1; + if (compare_pf_ref_idx(c0, c2, NULL, i)) { + mi->pred_flag |= mask; + mi->ref_idx[i] = c0->ref_idx[i]; + mi->mv[i][0] = c0->mv[i]; + mi->mv[i][1].x = (c0->mv[i].x * (1 << 7)) + ((c2->mv[i].y - c0->mv[i].y) * (1 << shift)); + mi->mv[i][1].y = (c0->mv[i].y * (1 << 7)) - ((c2->mv[i].x - c0->mv[i].x) * (1 << shift)); + ff_vvc_round_mv(&mi->mv[i][1], 0, 7); + ff_vvc_clip_mv(&mi->mv[i][1]); + } + } + if (mi->pred_flag) { + if (mi->pred_flag == PF_BI) + mi->bcw_idx = c0->bcw_idx; + mi->motion_model_idc = MOTION_4_PARAMS_AFFINE; + return 1; + } + } + return 0; +} + +static void affine_merge_zero_motion(const VVCLocalContext *lc, MotionInfo *mi) +{ + const CodingUnit *cu = lc->cu; + + memset(mi, 0, sizeof(*mi)); + mi->pred_flag = PF_L0 + (IS_B(lc->sc->sh.r) << 1); + mi->motion_model_idc = MOTION_4_PARAMS_AFFINE; + mi->num_sb_x = cu->cb_width >> MIN_PU_LOG2; + mi->num_sb_y = cu->cb_height >> MIN_PU_LOG2; +} + +//8.5.5.6 Derivation process for constructed affine control point motion vector merging candidates +static int affine_merge_const_candidates(const VVCLocalContext *lc, MotionInfo *mi, + NeighbourContext *nctx, const int merge_subblock_idx, int num_cands) +{ + const VVCFrameContext *fc = lc->fc; + const CodingUnit *cu = lc->cu; + const NeighbourIdx tl[] = { B2, B3, A2 }; + const NeighbourIdx tr[] = { B1, B0}; + const NeighbourIdx bl[] = { A1, A0}; + const MvField *c0, *c1, *c2; + + c0 = DERIVE_CORNER_MV(tl); + c1 = DERIVE_CORNER_MV(tr); + c2 = DERIVE_CORNER_MV(bl); + + if (fc->ps.sps->r->sps_6param_affine_enabled_flag) { + MvField corner3, *c3 = NULL; + //Const1 + if (affine_merge_const1(c0, c1, c2, mi)) { + if (merge_subblock_idx == num_cands) + return 1; + num_cands++; + } + + memset(&corner3, 0, sizeof(corner3)); + if (fc->ps.ph.r->ph_temporal_mvp_enabled_flag){ + const int available_l0 = temporal_luma_motion_vector(lc, 0, corner3.mv + 0, 0, 0, 0); + const int available_l1 = (lc->sc->sh.r->sh_slice_type == VVC_SLICE_TYPE_B) ? + temporal_luma_motion_vector(lc, 0, corner3.mv + 1, 1, 0, 0) : 0; + + corner3.pred_flag = available_l0 + (available_l1 << 1); + if (corner3.pred_flag) + c3 = &corner3; + } + + //Const2 + if (affine_merge_const2(c0, c1, c3, mi)) { + if (merge_subblock_idx == num_cands) + return 1; + num_cands++; + } + + //Const3 + if (affine_merge_const3(c0, c2, c3, mi)) { + if (merge_subblock_idx == num_cands) + return 1; + num_cands++; + } + + //Const4 + if (affine_merge_const4(c1, c2, c3, mi)) { + if (merge_subblock_idx == num_cands) + return 1; + num_cands++; + } + } + + //Const5 + if (affine_merge_const5(c0, c1, mi)) { + if (merge_subblock_idx == num_cands) + return 1; + num_cands++; + } + + if (affine_merge_const6(c0, c2, cu->cb_width, cu->cb_height, mi)) { + if (merge_subblock_idx == num_cands) + return 1; + } + return 0; +} + +//8.5.5.2 Derivation process for motion vectors and reference indices in subblock merge mode +//return 1 if candidate is SbCol +static int sb_mv_merge_mode(const VVCLocalContext *lc, const int merge_subblock_idx, PredictionUnit *pu) +{ + const VVCSPS *sps = lc->fc->ps.sps; + const CodingUnit *cu = lc->cu; + MotionInfo *mi = &pu->mi; + int num_cands = 0; + NeighbourContext nctx; + + init_neighbour_context(&nctx, lc); + + //SbCol + if (sb_temporal_merge_candidate(lc, &nctx, pu)) { + if (merge_subblock_idx == num_cands) + return 1; + num_cands++; + } + + pu->inter_affine_flag = 1; + mi->num_sb_x = cu->cb_width >> MIN_PU_LOG2; + mi->num_sb_y = cu->cb_height >> MIN_PU_LOG2; + + if (sps->r->sps_affine_enabled_flag) { + const NeighbourIdx ak[] = { A0, A1 }; + const NeighbourIdx bk[] = { B0, B1, B2 }; + //A + if (AFFINE_MERGE_FROM_NBS(ak)) { + if (merge_subblock_idx == num_cands) + return 0; + num_cands++; + } + + //B + if (AFFINE_MERGE_FROM_NBS(bk)) { + if (merge_subblock_idx == num_cands) + return 0; + num_cands++; + } + + //Const1 to Const6 + if (affine_merge_const_candidates(lc, mi, &nctx, merge_subblock_idx, num_cands)) + return 0; + } + //Zero + affine_merge_zero_motion(lc, mi); + return 0; +} + +void ff_vvc_sb_mv_merge_mode(VVCLocalContext *lc, const int merge_subblock_idx, PredictionUnit *pu) +{ + const CodingUnit *cu = lc->cu; + ff_vvc_set_neighbour_available(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height); + if (!sb_mv_merge_mode(lc, merge_subblock_idx, pu)) { + ff_vvc_store_sb_mvs(lc, pu); + } +} + +static int mvp_candidate(const VVCLocalContext *lc, const int x_cand, const int y_cand, + const int lx, const int8_t *ref_idx, Mv *mv) +{ + const VVCFrameContext *fc = lc->fc; + const RefPicList *rpl = lc->sc->rpl; + const int min_pu_width = fc->ps.pps->min_pu_width; + const MvField* tab_mvf = fc->tab.mvf; + const MvField *mvf = &TAB_MVF(x_cand, y_cand); + const PredFlag maskx = lx + 1; + const int poc = rpl[lx].list[ref_idx[lx]]; + int available = 0; + + if ((mvf->pred_flag & maskx) && rpl[lx].list[mvf->ref_idx[lx]] == poc) { + available = 1; + *mv = mvf->mv[lx]; + } else { + const int ly = !lx; + const PredFlag masky = ly + 1; + if ((mvf->pred_flag & masky) && rpl[ly].list[mvf->ref_idx[ly]] == poc) { + available = 1; + *mv = mvf->mv[ly]; + } + } + + return available; +} + +static int affine_mvp_candidate(const VVCLocalContext *lc, + const int x_cand, const int y_cand, const int lx, const int8_t *ref_idx, + Mv *cps, const int num_cp) +{ + const VVCFrameContext *fc = lc->fc; + int x_nb, y_nb, nbw, nbh, motion_model_idc, available = 0; + + motion_model_idc = affine_neighbour_cb(fc, x_cand, y_cand, &x_nb, &y_nb, &nbw, &nbh); + if (motion_model_idc) { + const int min_pu_width = fc->ps.pps->min_pu_width; + const MvField* tab_mvf = fc->tab.mvf; + const MvField *mvf = &TAB_MVF(x_nb, y_nb); + RefPicList* rpl = lc->sc->rpl; + const PredFlag maskx = lx + 1; + const int poc = rpl[lx].list[ref_idx[lx]]; + + if ((mvf->pred_flag & maskx) && rpl[lx].list[mvf->ref_idx[lx]] == poc) { + available = 1; + affine_cps_from_nb(lc, x_nb, y_nb, nbw, nbh, lx, cps, num_cp); + } else { + const int ly = !lx; + const PredFlag masky = ly + 1; + if ((mvf->pred_flag & masky) && rpl[ly].list[mvf->ref_idx[ly]] == poc) { + available = 1; + affine_cps_from_nb(lc, x_nb, y_nb, nbw, nbh, ly, cps, num_cp); + } + } + + } + return available; +} + +static int mvp_from_nbs(NeighbourContext *ctx, + const NeighbourIdx *nbs, const int num_nbs, const int lx, const int8_t *ref_idx, const int amvr_shift, + Mv *cps, const int num_cps) +{ + const VVCLocalContext *lc = ctx->lc; + int available = 0; + + for (int i = 0; i < num_nbs; i++) { + Neighbour *n = &ctx->neighbours[nbs[i]]; + if (check_available(n, lc, 0)) { + if (num_cps > 1) + available = affine_mvp_candidate(lc, n->x, n->y, lx, ref_idx, cps, num_cps); + else + available = mvp_candidate(lc, n->x, n->y, lx, ref_idx, cps); + if (available) { + for (int c = 0; c < num_cps; c++) + ff_vvc_round_mv(cps + c, amvr_shift, amvr_shift); + return 1; + } + } + } + return 0; +} + +//get mvp from neighbours +#define AFFINE_MVP_FROM_NBS(nbs) \ + mvp_from_nbs(&nctx, nbs, FF_ARRAY_ELEMS(nbs), lx, ref_idx, amvr_shift, cps, num_cp) \ + +#define MVP_FROM_NBS(nbs) \ + mvp_from_nbs(&nctx, nbs, FF_ARRAY_ELEMS(nbs), lx, ref_idx, amvr_shift, mv, 1) \ + +static int mvp_spatial_candidates(const VVCLocalContext *lc, + const int mvp_lx_flag, const int lx, const int8_t* ref_idx, const int amvr_shift, + Mv* mv, int *nb_merge_cand) +{ + const NeighbourIdx ak[] = { A0, A1 }; + const NeighbourIdx bk[] = { B0, B1, B2 }; + NeighbourContext nctx; + int available_a, num_cands = 0; + LOCAL_ALIGNED_8(Mv, mv_a, [1]); + + init_neighbour_context(&nctx, lc); + + available_a = MVP_FROM_NBS(ak); + if (available_a) { + if (mvp_lx_flag == num_cands) + return 1; + num_cands++; + *mv_a = *mv; + } + if (MVP_FROM_NBS(bk)) { + if (!available_a || !IS_SAME_MV(mv_a, mv)) { + if (mvp_lx_flag == num_cands) + return 1; + num_cands++; + } + } + *nb_merge_cand = num_cands; + return 0; +} + +static int mvp_temporal_candidates(const VVCLocalContext* lc, + const int mvp_lx_flag, const int lx, const int8_t *ref_idx, const int amvr_shift, + Mv* mv, int *num_cands) +{ + if (temporal_luma_motion_vector(lc, ref_idx[lx], mv, lx, 1, 0)) { + if (mvp_lx_flag == *num_cands) { + ff_vvc_round_mv(mv, amvr_shift, amvr_shift); + return 1; + } + (*num_cands)++; + } + return 0; + +} + +static int mvp_history_candidates(const VVCLocalContext *lc, + const int mvp_lx_flag, const int lx, const int8_t ref_idx, const int amvr_shift, + Mv *mv, int num_cands) +{ + const EntryPoint* ep = lc->ep; + const RefPicList* rpl = lc->sc->rpl; + const int poc = rpl[lx].list[ref_idx]; + + if (ep->num_hmvp == 0) + return 0; + for (int i = 1; i <= FFMIN(4, ep->num_hmvp); i++) { + const MvField* h = &ep->hmvp[i - 1]; + for (int j = 0; j < 2; j++) { + const int ly = (j ? !lx : lx); + PredFlag mask = PF_L0 + ly; + if ((h->pred_flag & mask) && poc == rpl[ly].list[h->ref_idx[ly]]) { + if (mvp_lx_flag == num_cands) { + *mv = h->mv[ly]; + ff_vvc_round_mv(mv, amvr_shift, amvr_shift); + return 1; + } + num_cands++; + } + } + } + return 0; +} + +//8.5.2.8 Derivation process for luma motion vector prediction +static void mvp(const VVCLocalContext *lc, const int mvp_lx_flag, const int lx, + const int8_t *ref_idx, const int amvr_shift, Mv *mv) +{ + int num_cands; + + if (mvp_spatial_candidates(lc, mvp_lx_flag, lx, ref_idx, amvr_shift, mv, &num_cands)) + return; + + if (mvp_temporal_candidates(lc, mvp_lx_flag, lx, ref_idx, amvr_shift, mv, &num_cands)) + return; + + if (mvp_history_candidates(lc, mvp_lx_flag, lx, ref_idx[lx], amvr_shift, mv, num_cands)) + return; + + memset(mv, 0, sizeof(*mv)); +} + +void ff_vvc_mvp(VVCLocalContext *lc, const int *mvp_lx_flag, const int amvr_shift, MotionInfo *mi) +{ + const CodingUnit *cu = lc->cu; + mi->num_sb_x = 1; + mi->num_sb_y = 1; + + ff_vvc_set_neighbour_available(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height); + if (mi->pred_flag != PF_L1) + mvp(lc, mvp_lx_flag[L0], L0, mi->ref_idx, amvr_shift, &mi->mv[L0][0]); + if (mi->pred_flag != PF_L0) + mvp(lc, mvp_lx_flag[L1], L1, mi->ref_idx, amvr_shift, &mi->mv[L1][0]); +} + +static int ibc_spatial_candidates(const VVCLocalContext *lc, const int merge_idx, Mv *const cand_list, int *nb_merge_cand) +{ + const CodingUnit *cu = lc->cu; + const VVCFrameContext *fc = lc->fc; + const int min_pu_width = fc->ps.pps->min_pu_width; + const MvField *tab_mvf = fc->tab.mvf; + const int is_gt4by4 = (cu->cb_width * cu->cb_height) > 16; + int num_cands = 0; + + NeighbourContext nctx; + Neighbour *a1 = &nctx.neighbours[A1]; + Neighbour *b1 = &nctx.neighbours[B1]; + + if (!is_gt4by4) { + *nb_merge_cand = 0; + return 0; + } + + init_neighbour_context(&nctx, lc); + + if (check_available(a1, lc, 1)) { + cand_list[num_cands++] = TAB_MVF(a1->x, a1->y).mv[L0]; + if (num_cands > merge_idx) + return 1; + } + if (check_available(b1, lc, 1)) { + const MvField *mvf = &TAB_MVF(b1->x, b1->y); + if (!num_cands || !IS_SAME_MV(&cand_list[0], mvf->mv)) { + cand_list[num_cands++] = mvf->mv[L0]; + if (num_cands > merge_idx) + return 1; + } + } + + *nb_merge_cand = num_cands; + return 0; +} + +static int ibc_history_candidates(const VVCLocalContext *lc, + const int merge_idx, Mv *cand_list, int *nb_merge_cand) +{ + const CodingUnit *cu = lc->cu; + const EntryPoint *ep = lc->ep; + const int is_gt4by4 = (cu->cb_width * cu->cb_height) > 16; + int num_cands = *nb_merge_cand; + + for (int i = 1; i <= ep->num_hmvp_ibc; i++) { + int same_motion = 0; + const MvField *mvf = &ep->hmvp_ibc[ep->num_hmvp_ibc - i]; + for (int j = 0; j < *nb_merge_cand; j++) { + same_motion = is_gt4by4 && i == 1 && IS_SAME_MV(&mvf->mv[L0], &cand_list[j]); + if (same_motion) + break; + } + if (!same_motion) { + cand_list[num_cands++] = mvf->mv[L0]; + if (num_cands > merge_idx) + return 1; + } + } + + *nb_merge_cand = num_cands; + return 0; +} + +#define MV_BITS 18 +#define IBC_SHIFT(v) ((v) >= (1 << (MV_BITS - 1)) ? ((v) - (1 << MV_BITS)) : (v)) + +static inline void ibc_add_mvp(Mv *mv, Mv *mvp, const int amvr_shift) +{ + ff_vvc_round_mv(mv, amvr_shift, 0); + ff_vvc_round_mv(mvp, amvr_shift, amvr_shift); + mv->x = IBC_SHIFT(mv->x + mvp->x); + mv->y = IBC_SHIFT(mv->y + mvp->y); +} + +static void ibc_merge_candidates(VVCLocalContext *lc, const int merge_idx, Mv *mv) +{ + const CodingUnit *cu = lc->cu; + LOCAL_ALIGNED_8(Mv, cand_list, [MRG_MAX_NUM_CANDS]); + int nb_cands; + + ff_vvc_set_neighbour_available(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height); + if (ibc_spatial_candidates(lc, merge_idx, cand_list, &nb_cands) || + ibc_history_candidates(lc, merge_idx, cand_list, &nb_cands)) { + *mv = cand_list[merge_idx]; + return; + } + + //zero mv + memset(mv, 0, sizeof(*mv)); +} + +void ff_vvc_mvp_ibc(VVCLocalContext *lc, const int mvp_l0_flag, const int amvr_shift, Mv *mv) +{ + LOCAL_ALIGNED_8(Mv, mvp, [1]); + + ibc_merge_candidates(lc, mvp_l0_flag, mvp); + ibc_add_mvp(mv, mvp, amvr_shift); +} + +void ff_vvc_luma_mv_merge_ibc(VVCLocalContext *lc, const int merge_idx, Mv *mv) +{ + ibc_merge_candidates(lc, merge_idx, mv); +} + +static int affine_mvp_constructed_cp(NeighbourContext *ctx, + const NeighbourIdx *neighbour, const int num_neighbour, + const int lx, const int8_t ref_idx, const int amvr_shift, Mv *cp) +{ + const VVCLocalContext *lc = ctx->lc; + const VVCFrameContext *fc = lc->fc; + const MvField *tab_mvf = fc->tab.mvf; + const int min_pu_width = fc->ps.pps->min_pu_width; + const RefPicList* rpl = lc->sc->rpl; + int available = 0; + + for (int i = 0; i < num_neighbour; i++) { + Neighbour *n = &ctx->neighbours[neighbour[i]]; + if (check_available(n, ctx->lc, 0)) { + const PredFlag maskx = lx + 1; + const MvField* mvf = &TAB_MVF(n->x, n->y); + const int poc = rpl[lx].list[ref_idx]; + if ((mvf->pred_flag & maskx) && rpl[lx].list[mvf->ref_idx[lx]] == poc) { + available = 1; + *cp = mvf->mv[lx]; + } else { + const int ly = !lx; + const PredFlag masky = ly + 1; + if ((mvf->pred_flag & masky) && rpl[ly].list[mvf->ref_idx[ly]] == poc) { + available = 1; + *cp = mvf->mv[ly]; + } + } + if (available) { + ff_vvc_round_mv(cp, amvr_shift, amvr_shift); + return 1; + } + } + } + return 0; +} + +#define AFFINE_MVP_CONSTRUCTED_CP(cands, cp) \ + affine_mvp_constructed_cp(nctx, cands, FF_ARRAY_ELEMS(cands), lx, ref_idx, \ + amvr_shift, cp) + +//8.5.5.8 Derivation process for constructed affine control point motion vector prediction candidates +static int affine_mvp_const1(NeighbourContext* nctx, + const int lx, const int8_t ref_idx, const int amvr_shift, + Mv *cps, int *available) +{ + const NeighbourIdx tl[] = { B2, B3, A2 }; + const NeighbourIdx tr[] = { B1, B0 }; + const NeighbourIdx bl[] = { A1, A0 }; + + available[0] = AFFINE_MVP_CONSTRUCTED_CP(tl, cps + 0); + available[1] = AFFINE_MVP_CONSTRUCTED_CP(tr, cps + 1); + available[2] = AFFINE_MVP_CONSTRUCTED_CP(bl, cps + 2); + return available[0] && available[1]; +} + +//8.5.5.7 item 7 +static void affine_mvp_const2(const int idx, Mv *cps, const int num_cp) +{ + const Mv mv = cps[idx]; + for (int j = 0; j < num_cp; j++) + cps[j] = mv; +} + +//8.5.5.7 Derivation process for luma affine control point motion vector predictors +static void affine_mvp(const VVCLocalContext *lc, + const int mvp_lx_flag, const int lx, const int8_t *ref_idx, const int amvr_shift, + MotionModelIdc motion_model_idc, Mv *cps) +{ + const NeighbourIdx ak[] = { A0, A1 }; + const NeighbourIdx bk[] = { B0, B1, B2 }; + const int num_cp = motion_model_idc + 1; + NeighbourContext nctx; + int available[MAX_CONTROL_POINTS]; + int num_cands = 0; + + init_neighbour_context(&nctx, lc); + //Ak + if (AFFINE_MVP_FROM_NBS(ak)) { + if (mvp_lx_flag == num_cands) + return; + num_cands++; + } + //Bk + if (AFFINE_MVP_FROM_NBS(bk)) { + if (mvp_lx_flag == num_cands) + return; + num_cands++; + } + + //Const1 + if (affine_mvp_const1(&nctx, lx, ref_idx[lx], amvr_shift, cps, available)) { + if (available[2] || motion_model_idc == MOTION_4_PARAMS_AFFINE) { + if (mvp_lx_flag == num_cands) + return; + num_cands++; + } + } + + //Const2 + for (int i = 2; i >= 0; i--) { + if (available[i]) { + if (mvp_lx_flag == num_cands) { + affine_mvp_const2(i, cps, num_cp); + return; + } + num_cands++; + } + } + if (temporal_luma_motion_vector(lc, ref_idx[lx], cps, lx, 1, 0)) { + if (mvp_lx_flag == num_cands) { + ff_vvc_round_mv(cps, amvr_shift, amvr_shift); + for (int i = 1; i < num_cp; i++) + cps[i] = cps[0]; + return; + } + num_cands++; + } + + //Zero Mv + memset(cps, 0, num_cp * sizeof(Mv)); +} + +void ff_vvc_affine_mvp(VVCLocalContext *lc, const int *mvp_lx_flag, const int amvr_shift, MotionInfo *mi) +{ + const CodingUnit *cu = lc->cu; + + mi->num_sb_x = cu->cb_width >> MIN_PU_LOG2; + mi->num_sb_y = cu->cb_height >> MIN_PU_LOG2; + + ff_vvc_set_neighbour_available(lc, cu->x0, cu->y0, cu->cb_width, cu->cb_height); + if (mi->pred_flag != PF_L1) + affine_mvp(lc, mvp_lx_flag[L0], L0, mi->ref_idx, amvr_shift, mi->motion_model_idc, &mi->mv[L0][0]); + if (mi->pred_flag != PF_L0) + affine_mvp(lc, mvp_lx_flag[L1], L1, mi->ref_idx, amvr_shift, mi->motion_model_idc, &mi->mv[L1][0]); +} + +//8.5.2.14 Rounding process for motion vectors +void ff_vvc_round_mv(Mv *mv, const int lshift, const int rshift) +{ + if (rshift) { + const int offset = 1 << (rshift - 1); + mv->x = ((mv->x + offset - (mv->x >= 0)) >> rshift) * (1 << lshift); + mv->y = ((mv->y + offset - (mv->y >= 0)) >> rshift) * (1 << lshift); + } else { + mv->x = mv->x * (1 << lshift); + mv->y = mv->y * (1 << lshift); + } +} + +void ff_vvc_clip_mv(Mv *mv) +{ + mv->x = av_clip(mv->x, -(1 << 17), (1 << 17) - 1); + mv->y = av_clip(mv->y, -(1 << 17), (1 << 17) - 1); +} + +//8.5.2.1 Derivation process for motion vector components and reference indices +static av_always_inline int is_greater_mer(const VVCFrameContext *fc, const int x0, const int y0, const int x0_br, const int y0_br) +{ + const uint8_t plevel = fc->ps.sps->log2_parallel_merge_level; + + return x0_br >> plevel > x0 >> plevel && + y0_br >> plevel > y0 >> plevel; +} + +static void update_hmvp(MvField *hmvp, int *num_hmvp, const MvField *mvf, + int (*compare)(const MvField *n, const MvField *o)) +{ + int i; + for (i = 0; i < *num_hmvp; i++) { + if (compare(mvf, hmvp + i)) { + (*num_hmvp)--; + break; + } + } + if (i == MAX_NUM_HMVP_CANDS) { + (*num_hmvp)--; + i = 0; + } + + memmove(hmvp + i, hmvp + i + 1, (*num_hmvp - i) * sizeof(MvField)); + hmvp[(*num_hmvp)++] = *mvf; +} + +static int compare_l0_mv(const MvField *n, const MvField *o) +{ + return IS_SAME_MV(&n->mv[L0], &o->mv[L0]); +} + +//8.6.2.4 Derivation process for IBC history-based block vector candidates +//8.5.2.16 Updating process for the history-based motion vector predictor candidate list +void ff_vvc_update_hmvp(VVCLocalContext *lc, const MotionInfo *mi) +{ + const VVCFrameContext *fc = lc->fc; + const CodingUnit *cu = lc->cu; + const int min_pu_width = fc->ps.pps->min_pu_width; + const MvField *tab_mvf = fc->tab.mvf; + EntryPoint *ep = lc->ep; + + if (cu->pred_mode == MODE_IBC) { + if (cu->cb_width * cu->cb_height <= 16) + return; + update_hmvp(ep->hmvp_ibc, &ep->num_hmvp_ibc, &TAB_MVF(cu->x0, cu->y0), compare_l0_mv); + } else { + if (!is_greater_mer(fc, cu->x0, cu->y0, cu->x0 + cu->cb_width, cu->y0 + cu->cb_height)) + return; + update_hmvp(ep->hmvp, &ep->num_hmvp, &TAB_MVF(cu->x0, cu->y0), compare_mv_ref_idx); + } +} + +MvField* ff_vvc_get_mvf(const VVCFrameContext *fc, const int x0, const int y0) +{ + const int min_pu_width = fc->ps.pps->min_pu_width; + MvField* tab_mvf = fc->tab.mvf; + + return &TAB_MVF(x0, y0); +} |