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/*
* Copyright (c) 2019, Alliance for Open Media. All rights reserved.
*
* This source code is subject to the terms of the BSD 2 Clause License and
* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
* was not distributed with this source code in the LICENSE file, you can
* obtain it at www.aomedia.org/license/software. If the Alliance for Open
* Media Patent License 1.0 was not distributed with this source code in the
* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
*/
#include <stdint.h>
#include "av1/common/blockd.h"
#include "config/aom_config.h"
#include "config/aom_scale_rtcd.h"
#include "aom/aom_codec.h"
#include "aom/aom_encoder.h"
#include "av1/common/av1_common_int.h"
#include "av1/encoder/encoder.h"
#include "av1/encoder/firstpass.h"
#include "av1/encoder/gop_structure.h"
#include "av1/encoder/pass2_strategy.h"
// This function sets gf_group->frame_parallel_level for LF_UPDATE frames based
// on the value of parallel_frame_count.
static void set_frame_parallel_level(int *frame_parallel_level,
int *parallel_frame_count,
int max_parallel_frames) {
assert(*parallel_frame_count > 0);
// parallel_frame_count > 1 indicates subsequent frame(s) in the current
// parallel encode set.
*frame_parallel_level = 1 + (*parallel_frame_count > 1);
// Update the count of no. of parallel frames.
(*parallel_frame_count)++;
if (*parallel_frame_count > max_parallel_frames) *parallel_frame_count = 1;
}
// This function sets gf_group->src_offset based on frame_parallel_level.
// Outputs are gf_group->src_offset and first_frame_index
static void set_src_offset(GF_GROUP *const gf_group, int *first_frame_index,
int cur_frame_idx, int frame_ind) {
if (gf_group->frame_parallel_level[frame_ind] > 0) {
if (gf_group->frame_parallel_level[frame_ind] == 1) {
*first_frame_index = cur_frame_idx;
}
// Obtain the offset of the frame at frame_ind in the lookahead queue by
// subtracting the display order hints of the current frame from the display
// order hint of the first frame in parallel encoding set (at
// first_frame_index).
gf_group->src_offset[frame_ind] =
(cur_frame_idx + gf_group->arf_src_offset[frame_ind]) -
*first_frame_index;
}
}
// Sets the GF_GROUP params for LF_UPDATE frames.
static inline void set_params_for_leaf_frames(
const TWO_PASS *twopass, const TWO_PASS_FRAME *twopass_frame,
const PRIMARY_RATE_CONTROL *p_rc, FRAME_INFO *frame_info,
GF_GROUP *const gf_group, int *cur_frame_idx, int *frame_ind,
int *parallel_frame_count, int max_parallel_frames,
int do_frame_parallel_encode, int *first_frame_index, int *cur_disp_index,
int layer_depth, int start, int end) {
gf_group->update_type[*frame_ind] = LF_UPDATE;
gf_group->arf_src_offset[*frame_ind] = 0;
gf_group->cur_frame_idx[*frame_ind] = *cur_frame_idx;
gf_group->layer_depth[*frame_ind] = MAX_ARF_LAYERS;
gf_group->frame_type[*frame_ind] = INTER_FRAME;
gf_group->refbuf_state[*frame_ind] = REFBUF_UPDATE;
gf_group->max_layer_depth = AOMMAX(gf_group->max_layer_depth, layer_depth);
gf_group->display_idx[*frame_ind] = (*cur_disp_index);
gf_group->arf_boost[*frame_ind] =
av1_calc_arf_boost(twopass, twopass_frame, p_rc, frame_info, start,
end - start, 0, NULL, NULL, 0);
++(*cur_disp_index);
// Set the level of parallelism for the LF_UPDATE frame.
if (do_frame_parallel_encode) {
set_frame_parallel_level(&gf_group->frame_parallel_level[*frame_ind],
parallel_frame_count, max_parallel_frames);
// Set LF_UPDATE frames as non-reference frames.
gf_group->is_frame_non_ref[*frame_ind] = true;
}
set_src_offset(gf_group, first_frame_index, *cur_frame_idx, *frame_ind);
++(*frame_ind);
++(*cur_frame_idx);
}
// Sets the GF_GROUP params for INTNL_OVERLAY_UPDATE frames.
static inline void set_params_for_intnl_overlay_frames(
GF_GROUP *const gf_group, int *cur_frame_idx, int *frame_ind,
int *first_frame_index, int *cur_disp_index, int layer_depth) {
gf_group->update_type[*frame_ind] = INTNL_OVERLAY_UPDATE;
gf_group->arf_src_offset[*frame_ind] = 0;
gf_group->cur_frame_idx[*frame_ind] = *cur_frame_idx;
gf_group->layer_depth[*frame_ind] = layer_depth;
gf_group->frame_type[*frame_ind] = INTER_FRAME;
gf_group->refbuf_state[*frame_ind] = REFBUF_UPDATE;
gf_group->display_idx[*frame_ind] = (*cur_disp_index);
++(*cur_disp_index);
set_src_offset(gf_group, first_frame_index, *cur_frame_idx, *frame_ind);
++(*frame_ind);
++(*cur_frame_idx);
}
// Sets the GF_GROUP params for INTNL_ARF_UPDATE frames.
static inline void set_params_for_internal_arfs(
const TWO_PASS *twopass, const TWO_PASS_FRAME *twopass_frame,
const PRIMARY_RATE_CONTROL *p_rc, FRAME_INFO *frame_info,
GF_GROUP *const gf_group, int *cur_frame_idx, int *frame_ind,
int *parallel_frame_count, int max_parallel_frames,
int do_frame_parallel_encode, int *first_frame_index, int depth_thr,
int *cur_disp_idx, int layer_depth, int arf_src_offset, int offset,
int f_frames, int b_frames) {
gf_group->update_type[*frame_ind] = INTNL_ARF_UPDATE;
gf_group->arf_src_offset[*frame_ind] = arf_src_offset;
gf_group->cur_frame_idx[*frame_ind] = *cur_frame_idx;
gf_group->layer_depth[*frame_ind] = layer_depth;
gf_group->frame_type[*frame_ind] = INTER_FRAME;
gf_group->refbuf_state[*frame_ind] = REFBUF_UPDATE;
gf_group->display_idx[*frame_ind] =
(*cur_disp_idx) + gf_group->arf_src_offset[*frame_ind];
gf_group->arf_boost[*frame_ind] =
av1_calc_arf_boost(twopass, twopass_frame, p_rc, frame_info, offset,
f_frames, b_frames, NULL, NULL, 0);
if (do_frame_parallel_encode) {
if (depth_thr != INT_MAX) {
assert(depth_thr == 3 || depth_thr == 4);
assert(IMPLIES(depth_thr == 3, layer_depth == 4));
assert(IMPLIES(depth_thr == 4, layer_depth == 5));
// Set frame_parallel_level of the first frame in the given layer to 1.
if (gf_group->layer_depth[(*frame_ind) - 1] != layer_depth) {
gf_group->frame_parallel_level[*frame_ind] = 1;
} else {
// Set frame_parallel_level of the consecutive frame in the same given
// layer to 2.
assert(gf_group->frame_parallel_level[(*frame_ind) - 1] == 1);
gf_group->frame_parallel_level[*frame_ind] = 2;
// Store the display order hints of the past 2 INTNL_ARF_UPDATE
// frames which would not have been displayed at the time of the encode
// of current frame.
gf_group->skip_frame_refresh[*frame_ind][0] =
gf_group->display_idx[(*frame_ind) - 1];
gf_group->skip_frame_refresh[*frame_ind][1] =
gf_group->display_idx[(*frame_ind) - 2];
// Set the display_idx of frame_parallel_level 1 frame in
// gf_group->skip_frame_as_ref.
gf_group->skip_frame_as_ref[*frame_ind] =
gf_group->display_idx[(*frame_ind) - 1];
}
}
// If max_parallel_frames is not exceeded and if the frame will not be
// temporally filtered, encode the next internal ARF frame in parallel.
if (*parallel_frame_count > 1 &&
*parallel_frame_count <= max_parallel_frames) {
if (gf_group->arf_src_offset[*frame_ind] < TF_LOOKAHEAD_IDX_THR)
gf_group->frame_parallel_level[*frame_ind] = 2;
*parallel_frame_count = 1;
}
}
set_src_offset(gf_group, first_frame_index, *cur_frame_idx, *frame_ind);
++(*frame_ind);
}
// Set parameters for frames between 'start' and 'end' (excluding both).
static void set_multi_layer_params_for_fp(
const TWO_PASS *twopass, const TWO_PASS_FRAME *twopass_frame,
GF_GROUP *const gf_group, const PRIMARY_RATE_CONTROL *p_rc,
RATE_CONTROL *rc, FRAME_INFO *frame_info, int start, int end,
int *cur_frame_idx, int *frame_ind, int *parallel_frame_count,
int max_parallel_frames, int do_frame_parallel_encode,
int *first_frame_index, int depth_thr, int *cur_disp_idx, int layer_depth) {
const int num_frames_to_process = end - start;
// Either we are at the last level of the pyramid, or we don't have enough
// frames between 'l' and 'r' to create one more level.
if (layer_depth > gf_group->max_layer_depth_allowed ||
num_frames_to_process < 3) {
// Leaf nodes.
while (start < end) {
set_params_for_leaf_frames(twopass, twopass_frame, p_rc, frame_info,
gf_group, cur_frame_idx, frame_ind,
parallel_frame_count, max_parallel_frames,
do_frame_parallel_encode, first_frame_index,
cur_disp_idx, layer_depth, start, end);
++start;
}
} else {
const int m = (start + end - 1) / 2;
// Internal ARF.
int arf_src_offset = m - start;
set_params_for_internal_arfs(
twopass, twopass_frame, p_rc, frame_info, gf_group, cur_frame_idx,
frame_ind, parallel_frame_count, max_parallel_frames,
do_frame_parallel_encode, first_frame_index, INT_MAX, cur_disp_idx,
layer_depth, arf_src_offset, m, end - m, m - start);
// If encode reordering is enabled, configure the multi-layers accordingly
// and return. For e.g., the encode order for gf-interval 16 after
// reordering would be 0-> 16-> 8-> 4-> 2-> 6-> 1-> 3-> 5-> 7-> 12-> 10->
// 14-> 9-> 11-> 13-> 15.
if (layer_depth >= depth_thr) {
int m1 = (m + start - 1) / 2;
int m2 = (m + 1 + end) / 2;
int arf_src_offsets[2] = { m1 - start, m2 - start };
// Parameters to compute arf_boost.
int offset[2] = { m1, m2 };
int f_frames[2] = { m - m1, end - m2 };
int b_frames[2] = { m1 - start, m2 - (m + 1) };
// Set GF_GROUP params for INTNL_ARF_UPDATE frames which are reordered.
for (int i = 0; i < 2; i++) {
set_params_for_internal_arfs(
twopass, twopass_frame, p_rc, frame_info, gf_group, cur_frame_idx,
frame_ind, parallel_frame_count, max_parallel_frames,
do_frame_parallel_encode, first_frame_index, depth_thr,
cur_disp_idx, layer_depth + 1, arf_src_offsets[i], offset[i],
f_frames[i], b_frames[i]);
}
// Initialize the start and end indices to configure LF_UPDATE frames.
int start_idx[4] = { start, m1 + 1, m + 1, end - 1 };
int end_idx[4] = { m1, m, m2, end };
int layer_depth_for_intnl_overlay[4] = { layer_depth + 1, layer_depth,
layer_depth + 1, INVALID_IDX };
// Set GF_GROUP params for the rest of LF_UPDATE and INTNL_OVERLAY_UPDATE
// frames after reordering.
for (int i = 0; i < 4; i++) {
set_multi_layer_params_for_fp(
twopass, twopass_frame, gf_group, p_rc, rc, frame_info,
start_idx[i], end_idx[i], cur_frame_idx, frame_ind,
parallel_frame_count, max_parallel_frames, do_frame_parallel_encode,
first_frame_index, depth_thr, cur_disp_idx, layer_depth + 2);
if (layer_depth_for_intnl_overlay[i] != INVALID_IDX)
set_params_for_intnl_overlay_frames(
gf_group, cur_frame_idx, frame_ind, first_frame_index,
cur_disp_idx, layer_depth_for_intnl_overlay[i]);
}
return;
}
// Frames displayed before this internal ARF.
set_multi_layer_params_for_fp(
twopass, twopass_frame, gf_group, p_rc, rc, frame_info, start, m,
cur_frame_idx, frame_ind, parallel_frame_count, max_parallel_frames,
do_frame_parallel_encode, first_frame_index, depth_thr, cur_disp_idx,
layer_depth + 1);
// Overlay for internal ARF.
set_params_for_intnl_overlay_frames(gf_group, cur_frame_idx, frame_ind,
first_frame_index, cur_disp_idx,
layer_depth);
// Frames displayed after this internal ARF.
set_multi_layer_params_for_fp(
twopass, twopass_frame, gf_group, p_rc, rc, frame_info, m + 1, end,
cur_frame_idx, frame_ind, parallel_frame_count, max_parallel_frames,
do_frame_parallel_encode, first_frame_index, depth_thr, cur_disp_idx,
layer_depth + 1);
}
}
// Structure for bookkeeping start, end and display indices to configure
// INTNL_ARF_UPDATE frames.
typedef struct {
int start;
int end;
int display_index;
} FRAME_REORDER_INFO;
// Updates the stats required to configure the GF_GROUP.
static inline void fill_arf_frame_stats(FRAME_REORDER_INFO *arf_frame_stats,
int arf_frame_index, int display_idx,
int start, int end) {
arf_frame_stats[arf_frame_index].start = start;
arf_frame_stats[arf_frame_index].end = end;
arf_frame_stats[arf_frame_index].display_index = display_idx;
}
// Sets GF_GROUP params for INTNL_ARF_UPDATE frames. Also populates
// doh_gf_index_map and arf_frame_stats.
static inline void set_params_for_internal_arfs_in_gf14(
GF_GROUP *const gf_group, FRAME_REORDER_INFO *arf_frame_stats,
int *cur_frame_idx, int *cur_disp_idx, int *frame_ind,
int *count_arf_frames, int *doh_gf_index_map, int start, int end,
int layer_depth, int layer_with_parallel_encodes) {
int index = (start + end - 1) / 2;
gf_group->update_type[*frame_ind] = INTNL_ARF_UPDATE;
gf_group->arf_src_offset[*frame_ind] = index - 1;
gf_group->cur_frame_idx[*frame_ind] = *cur_frame_idx;
gf_group->layer_depth[*frame_ind] = layer_depth;
gf_group->frame_type[*frame_ind] = INTER_FRAME;
gf_group->refbuf_state[*frame_ind] = REFBUF_UPDATE;
gf_group->display_idx[*frame_ind] =
(*cur_disp_idx) + gf_group->arf_src_offset[*frame_ind];
// Update the display index of the current frame with its gf index.
doh_gf_index_map[index] = *frame_ind;
if (layer_with_parallel_encodes) {
assert(layer_depth == 4);
// Set frame_parallel_level of the first frame in the given layer depth
// to 1.
if (gf_group->layer_depth[(*frame_ind) - 1] != layer_depth) {
gf_group->frame_parallel_level[*frame_ind] = 1;
} else {
// Set frame_parallel_level of the consecutive frame in the same given
// layer depth to 2.
assert(gf_group->frame_parallel_level[(*frame_ind) - 1] == 1);
gf_group->frame_parallel_level[*frame_ind] = 2;
// Set the display_idx of frame_parallel_level 1 frame in
// gf_group->skip_frame_as_ref.
gf_group->skip_frame_as_ref[*frame_ind] =
gf_group->display_idx[(*frame_ind) - 1];
}
}
++(*frame_ind);
// Update arf_frame_stats.
fill_arf_frame_stats(arf_frame_stats, *count_arf_frames, index, start, end);
++(*count_arf_frames);
}
// Sets GF_GROUP params for all INTNL_ARF_UPDATE frames in the given layer
// dpeth.
static inline void set_params_for_cur_layer_frames(
GF_GROUP *const gf_group, FRAME_REORDER_INFO *arf_frame_stats,
int *cur_frame_idx, int *cur_disp_idx, int *frame_ind,
int *count_arf_frames, int *doh_gf_index_map, int num_dir, int node_start,
int node_end, int layer_depth) {
assert(num_dir < 3);
int start, end;
// Iterate through the nodes in the previous layer depth.
for (int i = node_start; i < node_end; i++) {
// For each node, check if a frame can be coded as INTNL_ARF_UPDATE frame on
// either direction.
for (int dir = 0; dir < num_dir; dir++) {
// Checks for a frame to the left of current node.
if (dir == 0) {
start = arf_frame_stats[i].start;
end = arf_frame_stats[i].display_index;
} else {
// Checks for a frame to the right of current node.
start = arf_frame_stats[i].display_index + 1;
end = arf_frame_stats[i].end;
}
const int num_frames_to_process = end - start;
// Checks if a frame can be coded as INTNL_ARF_UPDATE frame. If
// num_frames_to_process is less than 3, then there are not enough frames
// between 'start' and 'end' to create another level.
if (num_frames_to_process >= 3) {
// Flag to indicate the lower layer depths for which parallel encoding
// is enabled. Currently enabled for layer 4 frames.
int layer_with_parallel_encodes = layer_depth == 4;
set_params_for_internal_arfs_in_gf14(
gf_group, arf_frame_stats, cur_frame_idx, cur_disp_idx, frame_ind,
count_arf_frames, doh_gf_index_map, start, end, layer_depth,
layer_with_parallel_encodes);
}
}
}
}
// Configures multi-layers of the GF_GROUP when consecutive encode of frames in
// the same layer depth is enbaled.
static inline void set_multi_layer_params_for_gf14(
const TWO_PASS *twopass, const TWO_PASS_FRAME *twopass_frame,
const PRIMARY_RATE_CONTROL *p_rc, FRAME_INFO *frame_info,
GF_GROUP *const gf_group, FRAME_REORDER_INFO *arf_frame_stats,
int *cur_frame_idx, int *frame_ind, int *count_arf_frames,
int *doh_gf_index_map, int *parallel_frame_count, int *first_frame_index,
int *cur_disp_index, int gf_interval, int layer_depth,
int max_parallel_frames) {
assert(layer_depth == 2);
assert(gf_group->max_layer_depth_allowed >= 4);
int layer, node_start, node_end = 0;
// Maximum layer depth excluding LF_UPDATE frames is 4 since applicable only
// for gf-interval 14.
const int max_layer_depth = 4;
// Iterate through each layer depth starting from 2 till 'max_layer_depth'.
for (layer = layer_depth; layer <= max_layer_depth; layer++) {
// 'node_start' and 'node_end' indicate the number of nodes from the
// previous layer depth to be considered. It also corresponds to the indices
// of arf_frame_stats.
node_start = node_end;
node_end = (*count_arf_frames);
// 'num_dir' indicates the number of directions to traverse w.r.t. a given
// node in order to choose an INTNL_ARF_UPDATE frame. Layer depth 2 would
// have only one frame and hence needs to traverse only in the left
// direction w.r.t the node in the previous layer.
int num_dir = layer == 2 ? 1 : 2;
set_params_for_cur_layer_frames(gf_group, arf_frame_stats, cur_frame_idx,
cur_disp_index, frame_ind, count_arf_frames,
doh_gf_index_map, num_dir, node_start,
node_end, layer);
}
for (int i = 1; i < gf_interval; i++) {
// Since doh_gf_index_map is already populated for all INTNL_ARF_UPDATE
// frames in the GF_GROUP, any frame with INVALID_IDX would correspond to an
// LF_UPDATE frame.
if (doh_gf_index_map[i] == INVALID_IDX) {
// LF_UPDATE frames.
// TODO(Remya): Correct start and end parameters passed to
// set_params_for_leaf_frames() once encode reordering for gf-interval 14
// is enbaled for parallel encode of lower layer frames.
set_params_for_leaf_frames(
twopass, twopass_frame, p_rc, frame_info, gf_group, cur_frame_idx,
frame_ind, parallel_frame_count, max_parallel_frames, 1,
first_frame_index, cur_disp_index, layer, 0, 0);
} else {
// In order to obtain the layer depths of INTNL_OVERLAY_UPDATE frames, get
// the gf index of corresponding INTNL_ARF_UPDATE frames.
int intnl_arf_index = doh_gf_index_map[i];
int ld = gf_group->layer_depth[intnl_arf_index];
set_params_for_intnl_overlay_frames(gf_group, cur_frame_idx, frame_ind,
first_frame_index, cur_disp_index,
ld);
}
}
}
// Set parameters for frames between 'start' and 'end' (excluding both).
static void set_multi_layer_params(
const TWO_PASS *twopass, const TWO_PASS_FRAME *twopass_frame,
GF_GROUP *const gf_group, const PRIMARY_RATE_CONTROL *p_rc,
RATE_CONTROL *rc, FRAME_INFO *frame_info, int start, int end,
int *cur_frame_idx, int *frame_ind, int *parallel_frame_count,
int max_parallel_frames, int do_frame_parallel_encode,
int *first_frame_index, int *cur_disp_idx, int layer_depth) {
const int num_frames_to_process = end - start;
// Either we are at the last level of the pyramid, or we don't have enough
// frames between 'l' and 'r' to create one more level.
if (layer_depth > gf_group->max_layer_depth_allowed ||
num_frames_to_process < 3) {
// Leaf nodes.
while (start < end) {
gf_group->update_type[*frame_ind] = LF_UPDATE;
gf_group->arf_src_offset[*frame_ind] = 0;
gf_group->cur_frame_idx[*frame_ind] = *cur_frame_idx;
gf_group->display_idx[*frame_ind] = *cur_disp_idx;
gf_group->layer_depth[*frame_ind] = MAX_ARF_LAYERS;
gf_group->arf_boost[*frame_ind] =
av1_calc_arf_boost(twopass, twopass_frame, p_rc, frame_info, start,
end - start, 0, NULL, NULL, 0);
gf_group->frame_type[*frame_ind] = INTER_FRAME;
gf_group->refbuf_state[*frame_ind] = REFBUF_UPDATE;
gf_group->max_layer_depth =
AOMMAX(gf_group->max_layer_depth, layer_depth);
// Set the level of parallelism for the LF_UPDATE frame.
if (do_frame_parallel_encode) {
set_frame_parallel_level(&gf_group->frame_parallel_level[*frame_ind],
parallel_frame_count, max_parallel_frames);
// Set LF_UPDATE frames as non-reference frames.
gf_group->is_frame_non_ref[*frame_ind] = true;
}
set_src_offset(gf_group, first_frame_index, *cur_frame_idx, *frame_ind);
++(*frame_ind);
++(*cur_frame_idx);
++(*cur_disp_idx);
++start;
}
} else {
const int m = (start + end - 1) / 2;
// Internal ARF.
gf_group->update_type[*frame_ind] = INTNL_ARF_UPDATE;
gf_group->arf_src_offset[*frame_ind] = m - start;
gf_group->cur_frame_idx[*frame_ind] = *cur_frame_idx;
gf_group->display_idx[*frame_ind] =
*cur_disp_idx + gf_group->arf_src_offset[*frame_ind];
gf_group->layer_depth[*frame_ind] = layer_depth;
gf_group->frame_type[*frame_ind] = INTER_FRAME;
gf_group->refbuf_state[*frame_ind] = REFBUF_UPDATE;
if (do_frame_parallel_encode) {
// If max_parallel_frames is not exceeded and if the frame will not be
// temporally filtered, encode the next internal ARF frame in parallel.
if (*parallel_frame_count > 1 &&
*parallel_frame_count <= max_parallel_frames) {
if (gf_group->arf_src_offset[*frame_ind] < TF_LOOKAHEAD_IDX_THR)
gf_group->frame_parallel_level[*frame_ind] = 2;
*parallel_frame_count = 1;
}
}
set_src_offset(gf_group, first_frame_index, *cur_frame_idx, *frame_ind);
// Get the boost factor for intermediate ARF frames.
gf_group->arf_boost[*frame_ind] =
av1_calc_arf_boost(twopass, twopass_frame, p_rc, frame_info, m, end - m,
m - start, NULL, NULL, 0);
++(*frame_ind);
// Frames displayed before this internal ARF.
set_multi_layer_params(twopass, twopass_frame, gf_group, p_rc, rc,
frame_info, start, m, cur_frame_idx, frame_ind,
parallel_frame_count, max_parallel_frames,
do_frame_parallel_encode, first_frame_index,
cur_disp_idx, layer_depth + 1);
// Overlay for internal ARF.
gf_group->update_type[*frame_ind] = INTNL_OVERLAY_UPDATE;
gf_group->arf_src_offset[*frame_ind] = 0;
gf_group->cur_frame_idx[*frame_ind] = *cur_frame_idx;
gf_group->display_idx[*frame_ind] = *cur_disp_idx;
gf_group->arf_boost[*frame_ind] = 0;
gf_group->layer_depth[*frame_ind] = layer_depth;
gf_group->frame_type[*frame_ind] = INTER_FRAME;
gf_group->refbuf_state[*frame_ind] = REFBUF_UPDATE;
set_src_offset(gf_group, first_frame_index, *cur_frame_idx, *frame_ind);
++(*frame_ind);
++(*cur_frame_idx);
++(*cur_disp_idx);
// Frames displayed after this internal ARF.
set_multi_layer_params(twopass, twopass_frame, gf_group, p_rc, rc,
frame_info, m + 1, end, cur_frame_idx, frame_ind,
parallel_frame_count, max_parallel_frames,
do_frame_parallel_encode, first_frame_index,
cur_disp_idx, layer_depth + 1);
}
}
static int construct_multi_layer_gf_structure(
AV1_COMP *cpi, TWO_PASS *twopass, GF_GROUP *const gf_group,
RATE_CONTROL *rc, FRAME_INFO *const frame_info, int baseline_gf_interval,
FRAME_UPDATE_TYPE first_frame_update_type) {
PRIMARY_RATE_CONTROL *const p_rc = &cpi->ppi->p_rc;
// TODO(angiebird): Why do we need "-1" here?
const int gf_interval = baseline_gf_interval - 1;
int frame_index = 0;
int cur_frame_index = 0;
// Set the display order hint for the first frame in the GF_GROUP.
int cur_disp_index = (first_frame_update_type == KF_UPDATE)
? 0
: cpi->common.current_frame.frame_number;
// Initialize gf_group->frame_parallel_level, gf_group->is_frame_non_ref,
// gf_group->src_offset and gf_group->is_frame_dropped with 0.
memset(gf_group->frame_parallel_level, 0,
sizeof(gf_group->frame_parallel_level));
memset(gf_group->is_frame_non_ref, 0, sizeof(gf_group->is_frame_non_ref));
memset(gf_group->src_offset, 0, sizeof(gf_group->src_offset));
memset(gf_group->is_frame_dropped, 0, sizeof(gf_group->is_frame_dropped));
// Initialize gf_group->skip_frame_refresh and gf_group->skip_frame_as_ref
// with INVALID_IDX.
memset(gf_group->skip_frame_refresh, INVALID_IDX,
sizeof(gf_group->skip_frame_refresh));
memset(gf_group->skip_frame_as_ref, INVALID_IDX,
sizeof(gf_group->skip_frame_as_ref));
int kf_decomp = cpi->oxcf.kf_cfg.enable_keyframe_filtering > 1;
// This is a patch that fixes https://crbug.com/aomedia/3163
// enable_keyframe_filtering > 1 will introduce an extra overlay frame at
// key frame location. However when
// baseline_gf_interval == MAX_STATIC_GF_GROUP_LENGTH, we can't
// afford to have an extra overlay frame. Otherwise, the gf_group->size will
// become MAX_STATIC_GF_GROUP_LENGTH + 1, which causes memory error.
// A cheap solution is to turn of kf_decomp here.
// TODO(angiebird): Find a systematic way to solve this issue.
if (baseline_gf_interval == MAX_STATIC_GF_GROUP_LENGTH) {
kf_decomp = 0;
}
if (first_frame_update_type == KF_UPDATE) {
gf_group->update_type[frame_index] = kf_decomp ? ARF_UPDATE : KF_UPDATE;
gf_group->arf_src_offset[frame_index] = 0;
gf_group->cur_frame_idx[frame_index] = cur_frame_index;
gf_group->layer_depth[frame_index] = 0;
gf_group->frame_type[frame_index] = KEY_FRAME;
gf_group->refbuf_state[frame_index] = REFBUF_RESET;
gf_group->max_layer_depth = 0;
gf_group->display_idx[frame_index] = cur_disp_index;
if (!kf_decomp) cur_disp_index++;
++frame_index;
if (kf_decomp) {
gf_group->update_type[frame_index] = OVERLAY_UPDATE;
gf_group->arf_src_offset[frame_index] = 0;
gf_group->cur_frame_idx[frame_index] = cur_frame_index;
gf_group->layer_depth[frame_index] = 0;
gf_group->frame_type[frame_index] = INTER_FRAME;
gf_group->refbuf_state[frame_index] = REFBUF_UPDATE;
gf_group->max_layer_depth = 0;
gf_group->display_idx[frame_index] = cur_disp_index;
cur_disp_index++;
++frame_index;
}
cur_frame_index++;
}
if (first_frame_update_type == GF_UPDATE) {
gf_group->update_type[frame_index] = GF_UPDATE;
gf_group->arf_src_offset[frame_index] = 0;
gf_group->cur_frame_idx[frame_index] = cur_frame_index;
gf_group->layer_depth[frame_index] = 0;
gf_group->frame_type[frame_index] = INTER_FRAME;
gf_group->refbuf_state[frame_index] = REFBUF_UPDATE;
gf_group->max_layer_depth = 0;
gf_group->display_idx[frame_index] = cur_disp_index;
cur_disp_index++;
++frame_index;
++cur_frame_index;
}
// ALTREF.
const int use_altref = gf_group->max_layer_depth_allowed > 0;
int is_fwd_kf = rc->frames_to_fwd_kf == gf_interval;
if (use_altref) {
gf_group->update_type[frame_index] = ARF_UPDATE;
gf_group->arf_src_offset[frame_index] = gf_interval - cur_frame_index;
gf_group->cur_frame_idx[frame_index] = cur_frame_index;
gf_group->layer_depth[frame_index] = 1;
gf_group->arf_boost[frame_index] = cpi->ppi->p_rc.gfu_boost;
gf_group->frame_type[frame_index] = is_fwd_kf ? KEY_FRAME : INTER_FRAME;
gf_group->refbuf_state[frame_index] = REFBUF_UPDATE;
gf_group->max_layer_depth = 1;
gf_group->arf_index = frame_index;
gf_group->display_idx[frame_index] =
cur_disp_index + gf_group->arf_src_offset[frame_index];
++frame_index;
} else {
gf_group->arf_index = -1;
}
// Flag to indicate if multi-layer configuration is complete.
int is_multi_layer_configured = 0;
// Running count of no. of frames that is part of a given parallel
// encode set in a gf_group. Value of 1 indicates no parallel encode.
int parallel_frame_count = 1;
// Enable parallel encode of frames if gf_group has a multi-layer pyramid
// structure with minimum 4 layers.
int do_frame_parallel_encode = (cpi->ppi->num_fp_contexts > 1 && use_altref &&
gf_group->max_layer_depth_allowed >= 4);
int first_frame_index = cur_frame_index;
if (do_frame_parallel_encode) {
// construct_multi_layer_gf_structure() takes the input parameter
// 'gf_interval' as p_rc->baseline_gf_interval - 1 . Below code computes the
// actual GF_GROUP length by compensating for this offset.
int actual_gf_length = ((first_frame_update_type == KF_UPDATE) ||
(first_frame_update_type == GF_UPDATE))
? gf_interval
: gf_interval + 1;
// In order to facilitate parallel encoding of frames in lower layer depths,
// encode reordering is done. Currently encode reordering is enabled only
// for gf-intervals 16 and 32. NOTE: Since the buffer holding the
// reference frames is of size 8 (ref_frame_map[REF_FRAMES]), there is a
// limitation on the number of hidden frames possible at any given point and
// hence the reordering is enabled only for gf-intervals 16 and 32.
// Disabling encode reordering for gf-interval 14 since some cross-frame
// dependencies related to temporal filtering for FPMT is currently not
// handled.
int disable_gf14_reorder = 1;
if (actual_gf_length == 14 && !disable_gf14_reorder) {
// This array holds the gf index of INTNL_ARF_UPDATE frames in the slot
// corresponding to their display order hint. This is used while
// configuring the LF_UPDATE frames and INTNL_OVERLAY_UPDATE frames.
int doh_gf_index_map[FIXED_GF_INTERVAL];
// Initialize doh_gf_index_map with INVALID_IDX.
memset(&doh_gf_index_map[0], INVALID_IDX,
(sizeof(doh_gf_index_map[0]) * FIXED_GF_INTERVAL));
FRAME_REORDER_INFO arf_frame_stats[REF_FRAMES - 1];
// Store the stats corresponding to layer 1 frame.
fill_arf_frame_stats(arf_frame_stats, 0, actual_gf_length, 1,
actual_gf_length);
int count_arf_frames = 1;
// Sets multi-layer params for gf-interval 14 to consecutively encode
// frames in the same layer depth, i.e., encode order would be 0-> 14->
// 7-> 3-> 10-> 5-> 12-> 1-> 2-> 4-> 6-> 8-> 9-> 11-> 13.
// TODO(Remya): Set GF_GROUP param 'arf_boost' for all frames.
set_multi_layer_params_for_gf14(
twopass, &cpi->twopass_frame, p_rc, frame_info, gf_group,
arf_frame_stats, &cur_frame_index, &frame_index, &count_arf_frames,
doh_gf_index_map, &parallel_frame_count, &first_frame_index,
&cur_disp_index, actual_gf_length, use_altref + 1,
cpi->ppi->num_fp_contexts);
// Set gf_group->skip_frame_refresh.
for (int i = 0; i < actual_gf_length; i++) {
int count = 0;
if (gf_group->update_type[i] == INTNL_ARF_UPDATE) {
for (int j = 0; j < i; j++) {
// Store the display order hint of the frames which would not
// have been displayed at the encode call of frame 'i'.
if ((gf_group->display_idx[j] < gf_group->display_idx[i]) &&
gf_group->update_type[j] == INTNL_ARF_UPDATE) {
gf_group->skip_frame_refresh[i][count++] =
gf_group->display_idx[j];
}
}
}
}
} else {
// Set layer depth threshold for reordering as per the gf length.
int depth_thr = (actual_gf_length == 16) ? 3
: (actual_gf_length == 32) ? 4
: INT_MAX;
set_multi_layer_params_for_fp(
twopass, &cpi->twopass_frame, gf_group, p_rc, rc, frame_info,
cur_frame_index, gf_interval, &cur_frame_index, &frame_index,
&parallel_frame_count, cpi->ppi->num_fp_contexts,
do_frame_parallel_encode, &first_frame_index, depth_thr,
&cur_disp_index, use_altref + 1);
}
is_multi_layer_configured = 1;
}
// Rest of the frames.
if (!is_multi_layer_configured)
set_multi_layer_params(twopass, &cpi->twopass_frame, gf_group, p_rc, rc,
frame_info, cur_frame_index, gf_interval,
&cur_frame_index, &frame_index,
&parallel_frame_count, cpi->ppi->num_fp_contexts,
do_frame_parallel_encode, &first_frame_index,
&cur_disp_index, use_altref + 1);
if (use_altref) {
gf_group->update_type[frame_index] = OVERLAY_UPDATE;
gf_group->arf_src_offset[frame_index] = 0;
gf_group->cur_frame_idx[frame_index] = cur_frame_index;
gf_group->layer_depth[frame_index] = MAX_ARF_LAYERS;
gf_group->arf_boost[frame_index] = NORMAL_BOOST;
gf_group->frame_type[frame_index] = INTER_FRAME;
gf_group->refbuf_state[frame_index] =
is_fwd_kf ? REFBUF_RESET : REFBUF_UPDATE;
gf_group->display_idx[frame_index] = cur_disp_index;
++frame_index;
} else {
for (; cur_frame_index <= gf_interval; ++cur_frame_index) {
gf_group->update_type[frame_index] = LF_UPDATE;
gf_group->arf_src_offset[frame_index] = 0;
gf_group->cur_frame_idx[frame_index] = cur_frame_index;
gf_group->layer_depth[frame_index] = MAX_ARF_LAYERS;
gf_group->arf_boost[frame_index] = NORMAL_BOOST;
gf_group->frame_type[frame_index] = INTER_FRAME;
gf_group->refbuf_state[frame_index] = REFBUF_UPDATE;
gf_group->max_layer_depth = AOMMAX(gf_group->max_layer_depth, 2);
set_src_offset(gf_group, &first_frame_index, cur_frame_index,
frame_index);
gf_group->display_idx[frame_index] = cur_disp_index;
cur_disp_index++;
++frame_index;
}
}
if (do_frame_parallel_encode) {
// Iterate through the gf_group and reset frame_parallel_level to 0 in case
// a frame is marked as frame_parallel_level 1 with no subsequent
// frame_parallel_level 2 frame(s).
int level1_frame_idx = INT_MAX;
int level2_frame_count = 0;
for (int frame_idx = 0; frame_idx < frame_index; frame_idx++) {
if (gf_group->frame_parallel_level[frame_idx] == 1) {
// Set frame_parallel_level to 0 if only one frame is present in a
// parallel encode set.
if (level1_frame_idx != INT_MAX && !level2_frame_count)
gf_group->frame_parallel_level[level1_frame_idx] = 0;
// Book-keep frame_idx of frame_parallel_level 1 frame and reset the
// count of frame_parallel_level 2 frames in the corresponding parallel
// encode set.
level1_frame_idx = frame_idx;
level2_frame_count = 0;
}
if (gf_group->frame_parallel_level[frame_idx] == 2) level2_frame_count++;
}
// If frame_parallel_level is set to 1 for the last LF_UPDATE
// frame in the gf_group, reset it to zero since there are no subsequent
// frames in the gf_group.
if (gf_group->frame_parallel_level[frame_index - 2] == 1) {
assert(gf_group->update_type[frame_index - 2] == LF_UPDATE);
gf_group->frame_parallel_level[frame_index - 2] = 0;
}
}
for (int gf_idx = frame_index; gf_idx < MAX_STATIC_GF_GROUP_LENGTH;
++gf_idx) {
gf_group->update_type[gf_idx] = LF_UPDATE;
gf_group->arf_src_offset[gf_idx] = 0;
gf_group->cur_frame_idx[gf_idx] = gf_idx;
gf_group->layer_depth[gf_idx] = MAX_ARF_LAYERS;
gf_group->arf_boost[gf_idx] = NORMAL_BOOST;
gf_group->frame_type[gf_idx] = INTER_FRAME;
gf_group->refbuf_state[gf_idx] = REFBUF_UPDATE;
gf_group->max_layer_depth = AOMMAX(gf_group->max_layer_depth, 2);
}
return frame_index;
}
static void set_ld_layer_depth(GF_GROUP *gf_group, int gop_length) {
int log_gop_length = 0;
while ((1 << log_gop_length) < gop_length) {
++log_gop_length;
}
for (int gf_index = 0; gf_index < gf_group->size; ++gf_index) {
int count = 0;
// Find the trailing zeros
for (; count < MAX_ARF_LAYERS; ++count) {
if ((gf_index >> count) & 0x01) break;
}
gf_group->layer_depth[gf_index] = AOMMAX(log_gop_length - count, 0);
}
gf_group->max_layer_depth = AOMMIN(log_gop_length, MAX_ARF_LAYERS);
}
void av1_gop_setup_structure(AV1_COMP *cpi) {
RATE_CONTROL *const rc = &cpi->rc;
PRIMARY_RATE_CONTROL *const p_rc = &cpi->ppi->p_rc;
GF_GROUP *const gf_group = &cpi->ppi->gf_group;
TWO_PASS *const twopass = &cpi->ppi->twopass;
FRAME_INFO *const frame_info = &cpi->frame_info;
const int key_frame = rc->frames_since_key == 0;
FRAME_UPDATE_TYPE first_frame_update_type = ARF_UPDATE;
if (key_frame) {
first_frame_update_type = KF_UPDATE;
if (cpi->oxcf.kf_max_pyr_height != -1) {
gf_group->max_layer_depth_allowed = AOMMIN(
cpi->oxcf.kf_max_pyr_height, gf_group->max_layer_depth_allowed);
}
} else if (!cpi->ppi->gf_state.arf_gf_boost_lst) {
first_frame_update_type = GF_UPDATE;
}
gf_group->size = construct_multi_layer_gf_structure(
cpi, twopass, gf_group, rc, frame_info, p_rc->baseline_gf_interval,
first_frame_update_type);
if (gf_group->max_layer_depth_allowed == 0)
set_ld_layer_depth(gf_group, p_rc->baseline_gf_interval);
}
int av1_gop_check_forward_keyframe(const GF_GROUP *gf_group,
int gf_frame_index) {
return gf_group->frame_type[gf_frame_index] == KEY_FRAME &&
gf_group->refbuf_state[gf_frame_index] == REFBUF_UPDATE;
}
int av1_gop_is_second_arf(const GF_GROUP *gf_group, int gf_frame_index) {
const int arf_src_offset = gf_group->arf_src_offset[gf_frame_index];
// TODO(angiebird): when gf_group->size == 32, it's possble to
// have "two" second arf. Check if this is acceptable.
if (gf_group->update_type[gf_frame_index] == INTNL_ARF_UPDATE &&
arf_src_offset >= TF_LOOKAHEAD_IDX_THR) {
return 1;
}
return 0;
}