blob: b6c2b6990bc9aea3b72be60e47921e7634f68990 [file] [log] [blame]
/*
* Copyright © 2018-2021, VideoLAN and dav1d authors
* Copyright © 2018, Two Orioles, LLC
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include <errno.h>
#include <limits.h>
#include <stdio.h>
#include "dav1d/data.h"
#include "common/frame.h"
#include "common/intops.h"
#include "src/decode.h"
#include "src/getbits.h"
#include "src/levels.h"
#include "src/log.h"
#include "src/obu.h"
#include "src/ref.h"
#include "src/thread_task.h"
static int parse_seq_hdr(Dav1dContext *const c, GetBits *const gb,
Dav1dSequenceHeader *const hdr)
{
#define DEBUG_SEQ_HDR 0
#if DEBUG_SEQ_HDR
const unsigned init_bit_pos = dav1d_get_bits_pos(gb);
#endif
memset(hdr, 0, sizeof(*hdr));
hdr->profile = dav1d_get_bits(gb, 3);
if (hdr->profile > 2) goto error;
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-profile: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
hdr->still_picture = dav1d_get_bit(gb);
hdr->reduced_still_picture_header = dav1d_get_bit(gb);
if (hdr->reduced_still_picture_header && !hdr->still_picture) goto error;
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-stillpicture_flags: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
if (hdr->reduced_still_picture_header) {
hdr->num_operating_points = 1;
hdr->operating_points[0].major_level = dav1d_get_bits(gb, 3);
hdr->operating_points[0].minor_level = dav1d_get_bits(gb, 2);
hdr->operating_points[0].initial_display_delay = 10;
} else {
hdr->timing_info_present = dav1d_get_bit(gb);
if (hdr->timing_info_present) {
hdr->num_units_in_tick = dav1d_get_bits(gb, 32);
hdr->time_scale = dav1d_get_bits(gb, 32);
hdr->equal_picture_interval = dav1d_get_bit(gb);
if (hdr->equal_picture_interval) {
const unsigned num_ticks_per_picture = dav1d_get_vlc(gb);
if (num_ticks_per_picture == 0xFFFFFFFFU)
goto error;
hdr->num_ticks_per_picture = num_ticks_per_picture + 1;
}
hdr->decoder_model_info_present = dav1d_get_bit(gb);
if (hdr->decoder_model_info_present) {
hdr->encoder_decoder_buffer_delay_length = dav1d_get_bits(gb, 5) + 1;
hdr->num_units_in_decoding_tick = dav1d_get_bits(gb, 32);
hdr->buffer_removal_delay_length = dav1d_get_bits(gb, 5) + 1;
hdr->frame_presentation_delay_length = dav1d_get_bits(gb, 5) + 1;
}
}
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-timinginfo: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
hdr->display_model_info_present = dav1d_get_bit(gb);
hdr->num_operating_points = dav1d_get_bits(gb, 5) + 1;
for (int i = 0; i < hdr->num_operating_points; i++) {
struct Dav1dSequenceHeaderOperatingPoint *const op =
&hdr->operating_points[i];
op->idc = dav1d_get_bits(gb, 12);
if (op->idc && (!(op->idc & 0xff) || !(op->idc & 0xf00)))
goto error;
op->major_level = 2 + dav1d_get_bits(gb, 3);
op->minor_level = dav1d_get_bits(gb, 2);
if (op->major_level > 3)
op->tier = dav1d_get_bit(gb);
if (hdr->decoder_model_info_present) {
op->decoder_model_param_present = dav1d_get_bit(gb);
if (op->decoder_model_param_present) {
struct Dav1dSequenceHeaderOperatingParameterInfo *const opi =
&hdr->operating_parameter_info[i];
opi->decoder_buffer_delay =
dav1d_get_bits(gb, hdr->encoder_decoder_buffer_delay_length);
opi->encoder_buffer_delay =
dav1d_get_bits(gb, hdr->encoder_decoder_buffer_delay_length);
opi->low_delay_mode = dav1d_get_bit(gb);
}
}
if (hdr->display_model_info_present)
op->display_model_param_present = dav1d_get_bit(gb);
op->initial_display_delay =
op->display_model_param_present ? dav1d_get_bits(gb, 4) + 1 : 10;
}
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-operating-points: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
}
const int op_idx =
c->operating_point < hdr->num_operating_points ? c->operating_point : 0;
c->operating_point_idc = hdr->operating_points[op_idx].idc;
const unsigned spatial_mask = c->operating_point_idc >> 8;
c->max_spatial_id = spatial_mask ? ulog2(spatial_mask) : 0;
hdr->width_n_bits = dav1d_get_bits(gb, 4) + 1;
hdr->height_n_bits = dav1d_get_bits(gb, 4) + 1;
hdr->max_width = dav1d_get_bits(gb, hdr->width_n_bits) + 1;
hdr->max_height = dav1d_get_bits(gb, hdr->height_n_bits) + 1;
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-size: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
if (!hdr->reduced_still_picture_header) {
hdr->frame_id_numbers_present = dav1d_get_bit(gb);
if (hdr->frame_id_numbers_present) {
hdr->delta_frame_id_n_bits = dav1d_get_bits(gb, 4) + 2;
hdr->frame_id_n_bits = dav1d_get_bits(gb, 3) + hdr->delta_frame_id_n_bits + 1;
}
}
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-frame-id-numbers-present: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
hdr->sb128 = dav1d_get_bit(gb);
hdr->filter_intra = dav1d_get_bit(gb);
hdr->intra_edge_filter = dav1d_get_bit(gb);
if (hdr->reduced_still_picture_header) {
hdr->screen_content_tools = DAV1D_ADAPTIVE;
hdr->force_integer_mv = DAV1D_ADAPTIVE;
} else {
hdr->inter_intra = dav1d_get_bit(gb);
hdr->masked_compound = dav1d_get_bit(gb);
hdr->warped_motion = dav1d_get_bit(gb);
hdr->dual_filter = dav1d_get_bit(gb);
hdr->order_hint = dav1d_get_bit(gb);
if (hdr->order_hint) {
hdr->jnt_comp = dav1d_get_bit(gb);
hdr->ref_frame_mvs = dav1d_get_bit(gb);
}
hdr->screen_content_tools = dav1d_get_bit(gb) ? DAV1D_ADAPTIVE : dav1d_get_bit(gb);
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-screentools: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
hdr->force_integer_mv = hdr->screen_content_tools ?
dav1d_get_bit(gb) ? DAV1D_ADAPTIVE : dav1d_get_bit(gb) : 2;
if (hdr->order_hint)
hdr->order_hint_n_bits = dav1d_get_bits(gb, 3) + 1;
}
hdr->super_res = dav1d_get_bit(gb);
hdr->cdef = dav1d_get_bit(gb);
hdr->restoration = dav1d_get_bit(gb);
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-featurebits: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
hdr->hbd = dav1d_get_bit(gb);
if (hdr->profile == 2 && hdr->hbd)
hdr->hbd += dav1d_get_bit(gb);
if (hdr->profile != 1)
hdr->monochrome = dav1d_get_bit(gb);
hdr->color_description_present = dav1d_get_bit(gb);
if (hdr->color_description_present) {
hdr->pri = dav1d_get_bits(gb, 8);
hdr->trc = dav1d_get_bits(gb, 8);
hdr->mtrx = dav1d_get_bits(gb, 8);
} else {
hdr->pri = DAV1D_COLOR_PRI_UNKNOWN;
hdr->trc = DAV1D_TRC_UNKNOWN;
hdr->mtrx = DAV1D_MC_UNKNOWN;
}
if (hdr->monochrome) {
hdr->color_range = dav1d_get_bit(gb);
hdr->layout = DAV1D_PIXEL_LAYOUT_I400;
hdr->ss_hor = hdr->ss_ver = 1;
hdr->chr = DAV1D_CHR_UNKNOWN;
} else if (hdr->pri == DAV1D_COLOR_PRI_BT709 &&
hdr->trc == DAV1D_TRC_SRGB &&
hdr->mtrx == DAV1D_MC_IDENTITY)
{
hdr->layout = DAV1D_PIXEL_LAYOUT_I444;
hdr->color_range = 1;
if (hdr->profile != 1 && !(hdr->profile == 2 && hdr->hbd == 2))
goto error;
} else {
hdr->color_range = dav1d_get_bit(gb);
switch (hdr->profile) {
case 0: hdr->layout = DAV1D_PIXEL_LAYOUT_I420;
hdr->ss_hor = hdr->ss_ver = 1;
break;
case 1: hdr->layout = DAV1D_PIXEL_LAYOUT_I444;
break;
case 2:
if (hdr->hbd == 2) {
hdr->ss_hor = dav1d_get_bit(gb);
if (hdr->ss_hor)
hdr->ss_ver = dav1d_get_bit(gb);
} else
hdr->ss_hor = 1;
hdr->layout = hdr->ss_hor ?
hdr->ss_ver ? DAV1D_PIXEL_LAYOUT_I420 :
DAV1D_PIXEL_LAYOUT_I422 :
DAV1D_PIXEL_LAYOUT_I444;
break;
}
hdr->chr = (hdr->ss_hor & hdr->ss_ver) ?
dav1d_get_bits(gb, 2) : DAV1D_CHR_UNKNOWN;
}
if (c->strict_std_compliance &&
hdr->mtrx == DAV1D_MC_IDENTITY && hdr->layout != DAV1D_PIXEL_LAYOUT_I444)
{
goto error;
}
if (!hdr->monochrome)
hdr->separate_uv_delta_q = dav1d_get_bit(gb);
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-colorinfo: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
hdr->film_grain_present = dav1d_get_bit(gb);
#if DEBUG_SEQ_HDR
printf("SEQHDR: post-filmgrain: off=%u\n",
dav1d_get_bits_pos(gb) - init_bit_pos);
#endif
dav1d_get_bit(gb); // dummy bit
// We needn't bother flushing the OBU here: we'll check we didn't
// overrun in the caller and will then discard gb, so there's no
// point in setting its position properly.
return 0;
error:
dav1d_log(c, "Error parsing sequence header\n");
return DAV1D_ERR(EINVAL);
}
static int read_frame_size(Dav1dContext *const c, GetBits *const gb,
const int use_ref)
{
const Dav1dSequenceHeader *const seqhdr = c->seq_hdr;
Dav1dFrameHeader *const hdr = c->frame_hdr;
if (use_ref) {
for (int i = 0; i < 7; i++) {
if (dav1d_get_bit(gb)) {
const Dav1dThreadPicture *const ref =
&c->refs[c->frame_hdr->refidx[i]].p;
if (!ref->p.frame_hdr) return -1;
hdr->width[1] = ref->p.frame_hdr->width[1];
hdr->height = ref->p.frame_hdr->height;
hdr->render_width = ref->p.frame_hdr->render_width;
hdr->render_height = ref->p.frame_hdr->render_height;
hdr->super_res.enabled = seqhdr->super_res && dav1d_get_bit(gb);
if (hdr->super_res.enabled) {
const int d = hdr->super_res.width_scale_denominator =
9 + dav1d_get_bits(gb, 3);
hdr->width[0] = imax((hdr->width[1] * 8 + (d >> 1)) / d,
imin(16, hdr->width[1]));
} else {
hdr->super_res.width_scale_denominator = 8;
hdr->width[0] = hdr->width[1];
}
return 0;
}
}
}
if (hdr->frame_size_override) {
hdr->width[1] = dav1d_get_bits(gb, seqhdr->width_n_bits) + 1;
hdr->height = dav1d_get_bits(gb, seqhdr->height_n_bits) + 1;
} else {
hdr->width[1] = seqhdr->max_width;
hdr->height = seqhdr->max_height;
}
hdr->super_res.enabled = seqhdr->super_res && dav1d_get_bit(gb);
if (hdr->super_res.enabled) {
const int d = hdr->super_res.width_scale_denominator = 9 + dav1d_get_bits(gb, 3);
hdr->width[0] = imax((hdr->width[1] * 8 + (d >> 1)) / d, imin(16, hdr->width[1]));
} else {
hdr->super_res.width_scale_denominator = 8;
hdr->width[0] = hdr->width[1];
}
hdr->have_render_size = dav1d_get_bit(gb);
if (hdr->have_render_size) {
hdr->render_width = dav1d_get_bits(gb, 16) + 1;
hdr->render_height = dav1d_get_bits(gb, 16) + 1;
} else {
hdr->render_width = hdr->width[1];
hdr->render_height = hdr->height;
}
return 0;
}
static inline int tile_log2(const int sz, const int tgt) {
int k;
for (k = 0; (sz << k) < tgt; k++) ;
return k;
}
static const Dav1dLoopfilterModeRefDeltas default_mode_ref_deltas = {
.mode_delta = { 0, 0 },
.ref_delta = { 1, 0, 0, 0, -1, 0, -1, -1 },
};
static int parse_frame_hdr(Dav1dContext *const c, GetBits *const gb) {
#define DEBUG_FRAME_HDR 0
#if DEBUG_FRAME_HDR
const uint8_t *const init_ptr = gb->ptr;
#endif
const Dav1dSequenceHeader *const seqhdr = c->seq_hdr;
Dav1dFrameHeader *const hdr = c->frame_hdr;
hdr->show_existing_frame =
!seqhdr->reduced_still_picture_header && dav1d_get_bit(gb);
#if DEBUG_FRAME_HDR
printf("HDR: post-show_existing_frame: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
if (hdr->show_existing_frame) {
hdr->existing_frame_idx = dav1d_get_bits(gb, 3);
if (seqhdr->decoder_model_info_present && !seqhdr->equal_picture_interval)
hdr->frame_presentation_delay = dav1d_get_bits(gb, seqhdr->frame_presentation_delay_length);
if (seqhdr->frame_id_numbers_present) {
hdr->frame_id = dav1d_get_bits(gb, seqhdr->frame_id_n_bits);
Dav1dFrameHeader *const ref_frame_hdr = c->refs[hdr->existing_frame_idx].p.p.frame_hdr;
if (!ref_frame_hdr || ref_frame_hdr->frame_id != hdr->frame_id) goto error;
}
return 0;
}
hdr->frame_type = seqhdr->reduced_still_picture_header ? DAV1D_FRAME_TYPE_KEY : dav1d_get_bits(gb, 2);
hdr->show_frame = seqhdr->reduced_still_picture_header || dav1d_get_bit(gb);
if (hdr->show_frame) {
if (seqhdr->decoder_model_info_present && !seqhdr->equal_picture_interval)
hdr->frame_presentation_delay = dav1d_get_bits(gb, seqhdr->frame_presentation_delay_length);
hdr->showable_frame = hdr->frame_type != DAV1D_FRAME_TYPE_KEY;
} else
hdr->showable_frame = dav1d_get_bit(gb);
hdr->error_resilient_mode =
(hdr->frame_type == DAV1D_FRAME_TYPE_KEY && hdr->show_frame) ||
hdr->frame_type == DAV1D_FRAME_TYPE_SWITCH ||
seqhdr->reduced_still_picture_header || dav1d_get_bit(gb);
#if DEBUG_FRAME_HDR
printf("HDR: post-frametype_bits: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->disable_cdf_update = dav1d_get_bit(gb);
hdr->allow_screen_content_tools = seqhdr->screen_content_tools == DAV1D_ADAPTIVE ?
dav1d_get_bit(gb) : seqhdr->screen_content_tools;
if (hdr->allow_screen_content_tools)
hdr->force_integer_mv = seqhdr->force_integer_mv == DAV1D_ADAPTIVE ?
dav1d_get_bit(gb) : seqhdr->force_integer_mv;
else
hdr->force_integer_mv = 0;
if (IS_KEY_OR_INTRA(hdr))
hdr->force_integer_mv = 1;
if (seqhdr->frame_id_numbers_present)
hdr->frame_id = dav1d_get_bits(gb, seqhdr->frame_id_n_bits);
hdr->frame_size_override = seqhdr->reduced_still_picture_header ? 0 :
hdr->frame_type == DAV1D_FRAME_TYPE_SWITCH ? 1 : dav1d_get_bit(gb);
#if DEBUG_FRAME_HDR
printf("HDR: post-frame_size_override_flag: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->frame_offset = seqhdr->order_hint ?
dav1d_get_bits(gb, seqhdr->order_hint_n_bits) : 0;
hdr->primary_ref_frame = !hdr->error_resilient_mode && IS_INTER_OR_SWITCH(hdr) ?
dav1d_get_bits(gb, 3) : DAV1D_PRIMARY_REF_NONE;
if (seqhdr->decoder_model_info_present) {
hdr->buffer_removal_time_present = dav1d_get_bit(gb);
if (hdr->buffer_removal_time_present) {
for (int i = 0; i < c->seq_hdr->num_operating_points; i++) {
const struct Dav1dSequenceHeaderOperatingPoint *const seqop = &seqhdr->operating_points[i];
struct Dav1dFrameHeaderOperatingPoint *const op = &hdr->operating_points[i];
if (seqop->decoder_model_param_present) {
int in_temporal_layer = (seqop->idc >> hdr->temporal_id) & 1;
int in_spatial_layer = (seqop->idc >> (hdr->spatial_id + 8)) & 1;
if (!seqop->idc || (in_temporal_layer && in_spatial_layer))
op->buffer_removal_time = dav1d_get_bits(gb, seqhdr->buffer_removal_delay_length);
}
}
}
}
if (IS_KEY_OR_INTRA(hdr)) {
hdr->refresh_frame_flags = (hdr->frame_type == DAV1D_FRAME_TYPE_KEY &&
hdr->show_frame) ? 0xff : dav1d_get_bits(gb, 8);
if (hdr->refresh_frame_flags != 0xff && hdr->error_resilient_mode && seqhdr->order_hint)
for (int i = 0; i < 8; i++)
dav1d_get_bits(gb, seqhdr->order_hint_n_bits);
if (c->strict_std_compliance &&
hdr->frame_type == DAV1D_FRAME_TYPE_INTRA && hdr->refresh_frame_flags == 0xff)
{
goto error;
}
if (read_frame_size(c, gb, 0) < 0) goto error;
hdr->allow_intrabc = hdr->allow_screen_content_tools &&
!hdr->super_res.enabled && dav1d_get_bit(gb);
hdr->use_ref_frame_mvs = 0;
} else {
hdr->allow_intrabc = 0;
hdr->refresh_frame_flags = hdr->frame_type == DAV1D_FRAME_TYPE_SWITCH ? 0xff :
dav1d_get_bits(gb, 8);
if (hdr->error_resilient_mode && seqhdr->order_hint)
for (int i = 0; i < 8; i++)
dav1d_get_bits(gb, seqhdr->order_hint_n_bits);
hdr->frame_ref_short_signaling =
seqhdr->order_hint && dav1d_get_bit(gb);
if (hdr->frame_ref_short_signaling) { // FIXME: Nearly verbatim copy from section 7.8
hdr->refidx[0] = dav1d_get_bits(gb, 3);
hdr->refidx[1] = hdr->refidx[2] = -1;
hdr->refidx[3] = dav1d_get_bits(gb, 3);
hdr->refidx[4] = hdr->refidx[5] = hdr->refidx[6] = -1;
int shifted_frame_offset[8];
const int current_frame_offset = 1 << (seqhdr->order_hint_n_bits - 1);
for (int i = 0; i < 8; i++) {
if (!c->refs[i].p.p.frame_hdr) goto error;
shifted_frame_offset[i] = current_frame_offset +
get_poc_diff(seqhdr->order_hint_n_bits,
c->refs[i].p.p.frame_hdr->frame_offset,
hdr->frame_offset);
}
int used_frame[8] = { 0 };
used_frame[hdr->refidx[0]] = 1;
used_frame[hdr->refidx[3]] = 1;
int latest_frame_offset = -1;
for (int i = 0; i < 8; i++) {
const int hint = shifted_frame_offset[i];
if (!used_frame[i] && hint >= current_frame_offset &&
hint >= latest_frame_offset)
{
hdr->refidx[6] = i;
latest_frame_offset = hint;
}
}
if (latest_frame_offset != -1)
used_frame[hdr->refidx[6]] = 1;
int earliest_frame_offset = INT_MAX;
for (int i = 0; i < 8; i++) {
const int hint = shifted_frame_offset[i];
if (!used_frame[i] && hint >= current_frame_offset &&
hint < earliest_frame_offset)
{
hdr->refidx[4] = i;
earliest_frame_offset = hint;
}
}
if (earliest_frame_offset != INT_MAX)
used_frame[hdr->refidx[4]] = 1;
earliest_frame_offset = INT_MAX;
for (int i = 0; i < 8; i++) {
const int hint = shifted_frame_offset[i];
if (!used_frame[i] && hint >= current_frame_offset &&
(hint < earliest_frame_offset))
{
hdr->refidx[5] = i;
earliest_frame_offset = hint;
}
}
if (earliest_frame_offset != INT_MAX)
used_frame[hdr->refidx[5]] = 1;
for (int i = 1; i < 7; i++) {
if (hdr->refidx[i] < 0) {
latest_frame_offset = -1;
for (int j = 0; j < 8; j++) {
const int hint = shifted_frame_offset[j];
if (!used_frame[j] && hint < current_frame_offset &&
hint >= latest_frame_offset)
{
hdr->refidx[i] = j;
latest_frame_offset = hint;
}
}
if (latest_frame_offset != -1)
used_frame[hdr->refidx[i]] = 1;
}
}
earliest_frame_offset = INT_MAX;
int ref = -1;
for (int i = 0; i < 8; i++) {
const int hint = shifted_frame_offset[i];
if (hint < earliest_frame_offset) {
ref = i;
earliest_frame_offset = hint;
}
}
for (int i = 0; i < 7; i++) {
if (hdr->refidx[i] < 0)
hdr->refidx[i] = ref;
}
}
for (int i = 0; i < 7; i++) {
if (!hdr->frame_ref_short_signaling)
hdr->refidx[i] = dav1d_get_bits(gb, 3);
if (seqhdr->frame_id_numbers_present) {
const int delta_ref_frame_id_minus_1 = dav1d_get_bits(gb, seqhdr->delta_frame_id_n_bits);
const int ref_frame_id = (hdr->frame_id + (1 << seqhdr->frame_id_n_bits) - delta_ref_frame_id_minus_1 - 1) & ((1 << seqhdr->frame_id_n_bits) - 1);
Dav1dFrameHeader *const ref_frame_hdr = c->refs[hdr->refidx[i]].p.p.frame_hdr;
if (!ref_frame_hdr || ref_frame_hdr->frame_id != ref_frame_id) goto error;
}
}
const int use_ref = !hdr->error_resilient_mode &&
hdr->frame_size_override;
if (read_frame_size(c, gb, use_ref) < 0) goto error;
hdr->hp = !hdr->force_integer_mv && dav1d_get_bit(gb);
hdr->subpel_filter_mode = dav1d_get_bit(gb) ? DAV1D_FILTER_SWITCHABLE :
dav1d_get_bits(gb, 2);
hdr->switchable_motion_mode = dav1d_get_bit(gb);
hdr->use_ref_frame_mvs = !hdr->error_resilient_mode &&
seqhdr->ref_frame_mvs && seqhdr->order_hint &&
IS_INTER_OR_SWITCH(hdr) && dav1d_get_bit(gb);
}
#if DEBUG_FRAME_HDR
printf("HDR: post-frametype-specific-bits: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->refresh_context = !seqhdr->reduced_still_picture_header &&
!hdr->disable_cdf_update && !dav1d_get_bit(gb);
#if DEBUG_FRAME_HDR
printf("HDR: post-refresh_context: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
// tile data
hdr->tiling.uniform = dav1d_get_bit(gb);
const int sbsz_min1 = (64 << seqhdr->sb128) - 1;
const int sbsz_log2 = 6 + seqhdr->sb128;
const int sbw = (hdr->width[0] + sbsz_min1) >> sbsz_log2;
const int sbh = (hdr->height + sbsz_min1) >> sbsz_log2;
const int max_tile_width_sb = 4096 >> sbsz_log2;
const int max_tile_area_sb = 4096 * 2304 >> (2 * sbsz_log2);
hdr->tiling.min_log2_cols = tile_log2(max_tile_width_sb, sbw);
hdr->tiling.max_log2_cols = tile_log2(1, imin(sbw, DAV1D_MAX_TILE_COLS));
hdr->tiling.max_log2_rows = tile_log2(1, imin(sbh, DAV1D_MAX_TILE_ROWS));
const int min_log2_tiles = imax(tile_log2(max_tile_area_sb, sbw * sbh),
hdr->tiling.min_log2_cols);
if (hdr->tiling.uniform) {
for (hdr->tiling.log2_cols = hdr->tiling.min_log2_cols;
hdr->tiling.log2_cols < hdr->tiling.max_log2_cols && dav1d_get_bit(gb);
hdr->tiling.log2_cols++) ;
const int tile_w = 1 + ((sbw - 1) >> hdr->tiling.log2_cols);
hdr->tiling.cols = 0;
for (int sbx = 0; sbx < sbw; sbx += tile_w, hdr->tiling.cols++)
hdr->tiling.col_start_sb[hdr->tiling.cols] = sbx;
hdr->tiling.min_log2_rows =
imax(min_log2_tiles - hdr->tiling.log2_cols, 0);
for (hdr->tiling.log2_rows = hdr->tiling.min_log2_rows;
hdr->tiling.log2_rows < hdr->tiling.max_log2_rows && dav1d_get_bit(gb);
hdr->tiling.log2_rows++) ;
const int tile_h = 1 + ((sbh - 1) >> hdr->tiling.log2_rows);
hdr->tiling.rows = 0;
for (int sby = 0; sby < sbh; sby += tile_h, hdr->tiling.rows++)
hdr->tiling.row_start_sb[hdr->tiling.rows] = sby;
} else {
hdr->tiling.cols = 0;
int widest_tile = 0, max_tile_area_sb = sbw * sbh;
for (int sbx = 0; sbx < sbw && hdr->tiling.cols < DAV1D_MAX_TILE_COLS; hdr->tiling.cols++) {
const int tile_width_sb = imin(sbw - sbx, max_tile_width_sb);
const int tile_w = (tile_width_sb > 1) ?
1 + dav1d_get_uniform(gb, tile_width_sb) :
1;
hdr->tiling.col_start_sb[hdr->tiling.cols] = sbx;
sbx += tile_w;
widest_tile = imax(widest_tile, tile_w);
}
hdr->tiling.log2_cols = tile_log2(1, hdr->tiling.cols);
if (min_log2_tiles) max_tile_area_sb >>= min_log2_tiles + 1;
const int max_tile_height_sb = imax(max_tile_area_sb / widest_tile, 1);
hdr->tiling.rows = 0;
for (int sby = 0; sby < sbh && hdr->tiling.rows < DAV1D_MAX_TILE_ROWS; hdr->tiling.rows++) {
const int tile_height_sb = imin(sbh - sby, max_tile_height_sb);
const int tile_h = (tile_height_sb > 1) ?
1 + dav1d_get_uniform(gb, tile_height_sb) :
1;
hdr->tiling.row_start_sb[hdr->tiling.rows] = sby;
sby += tile_h;
}
hdr->tiling.log2_rows = tile_log2(1, hdr->tiling.rows);
}
hdr->tiling.col_start_sb[hdr->tiling.cols] = sbw;
hdr->tiling.row_start_sb[hdr->tiling.rows] = sbh;
if (hdr->tiling.log2_cols || hdr->tiling.log2_rows) {
hdr->tiling.update = dav1d_get_bits(gb, hdr->tiling.log2_cols +
hdr->tiling.log2_rows);
if (hdr->tiling.update >= hdr->tiling.cols * hdr->tiling.rows)
goto error;
hdr->tiling.n_bytes = dav1d_get_bits(gb, 2) + 1;
} else {
hdr->tiling.n_bytes = hdr->tiling.update = 0;
}
#if DEBUG_FRAME_HDR
printf("HDR: post-tiling: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
// quant data
hdr->quant.yac = dav1d_get_bits(gb, 8);
hdr->quant.ydc_delta = dav1d_get_bit(gb) ? dav1d_get_sbits(gb, 7) : 0;
if (!seqhdr->monochrome) {
// If the sequence header says that delta_q might be different
// for U, V, we must check whether it actually is for this
// frame.
const int diff_uv_delta = seqhdr->separate_uv_delta_q ? dav1d_get_bit(gb) : 0;
hdr->quant.udc_delta = dav1d_get_bit(gb) ? dav1d_get_sbits(gb, 7) : 0;
hdr->quant.uac_delta = dav1d_get_bit(gb) ? dav1d_get_sbits(gb, 7) : 0;
if (diff_uv_delta) {
hdr->quant.vdc_delta = dav1d_get_bit(gb) ? dav1d_get_sbits(gb, 7) : 0;
hdr->quant.vac_delta = dav1d_get_bit(gb) ? dav1d_get_sbits(gb, 7) : 0;
} else {
hdr->quant.vdc_delta = hdr->quant.udc_delta;
hdr->quant.vac_delta = hdr->quant.uac_delta;
}
}
#if DEBUG_FRAME_HDR
printf("HDR: post-quant: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->quant.qm = dav1d_get_bit(gb);
if (hdr->quant.qm) {
hdr->quant.qm_y = dav1d_get_bits(gb, 4);
hdr->quant.qm_u = dav1d_get_bits(gb, 4);
hdr->quant.qm_v =
seqhdr->separate_uv_delta_q ? (int)dav1d_get_bits(gb, 4) :
hdr->quant.qm_u;
}
#if DEBUG_FRAME_HDR
printf("HDR: post-qm: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
// segmentation data
hdr->segmentation.enabled = dav1d_get_bit(gb);
if (hdr->segmentation.enabled) {
if (hdr->primary_ref_frame == DAV1D_PRIMARY_REF_NONE) {
hdr->segmentation.update_map = 1;
hdr->segmentation.temporal = 0;
hdr->segmentation.update_data = 1;
} else {
hdr->segmentation.update_map = dav1d_get_bit(gb);
hdr->segmentation.temporal =
hdr->segmentation.update_map ? dav1d_get_bit(gb) : 0;
hdr->segmentation.update_data = dav1d_get_bit(gb);
}
if (hdr->segmentation.update_data) {
hdr->segmentation.seg_data.preskip = 0;
hdr->segmentation.seg_data.last_active_segid = -1;
for (int i = 0; i < DAV1D_MAX_SEGMENTS; i++) {
Dav1dSegmentationData *const seg =
&hdr->segmentation.seg_data.d[i];
if (dav1d_get_bit(gb)) {
seg->delta_q = dav1d_get_sbits(gb, 9);
hdr->segmentation.seg_data.last_active_segid = i;
} else {
seg->delta_q = 0;
}
if (dav1d_get_bit(gb)) {
seg->delta_lf_y_v = dav1d_get_sbits(gb, 7);
hdr->segmentation.seg_data.last_active_segid = i;
} else {
seg->delta_lf_y_v = 0;
}
if (dav1d_get_bit(gb)) {
seg->delta_lf_y_h = dav1d_get_sbits(gb, 7);
hdr->segmentation.seg_data.last_active_segid = i;
} else {
seg->delta_lf_y_h = 0;
}
if (dav1d_get_bit(gb)) {
seg->delta_lf_u = dav1d_get_sbits(gb, 7);
hdr->segmentation.seg_data.last_active_segid = i;
} else {
seg->delta_lf_u = 0;
}
if (dav1d_get_bit(gb)) {
seg->delta_lf_v = dav1d_get_sbits(gb, 7);
hdr->segmentation.seg_data.last_active_segid = i;
} else {
seg->delta_lf_v = 0;
}
if (dav1d_get_bit(gb)) {
seg->ref = dav1d_get_bits(gb, 3);
hdr->segmentation.seg_data.last_active_segid = i;
hdr->segmentation.seg_data.preskip = 1;
} else {
seg->ref = -1;
}
if ((seg->skip = dav1d_get_bit(gb))) {
hdr->segmentation.seg_data.last_active_segid = i;
hdr->segmentation.seg_data.preskip = 1;
}
if ((seg->globalmv = dav1d_get_bit(gb))) {
hdr->segmentation.seg_data.last_active_segid = i;
hdr->segmentation.seg_data.preskip = 1;
}
}
} else {
// segmentation.update_data was false so we should copy
// segmentation data from the reference frame.
assert(hdr->primary_ref_frame != DAV1D_PRIMARY_REF_NONE);
const int pri_ref = hdr->refidx[hdr->primary_ref_frame];
if (!c->refs[pri_ref].p.p.frame_hdr) goto error;
hdr->segmentation.seg_data =
c->refs[pri_ref].p.p.frame_hdr->segmentation.seg_data;
}
} else {
memset(&hdr->segmentation.seg_data, 0, sizeof(Dav1dSegmentationDataSet));
for (int i = 0; i < DAV1D_MAX_SEGMENTS; i++)
hdr->segmentation.seg_data.d[i].ref = -1;
}
#if DEBUG_FRAME_HDR
printf("HDR: post-segmentation: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
// delta q
hdr->delta.q.present = hdr->quant.yac ? dav1d_get_bit(gb) : 0;
hdr->delta.q.res_log2 = hdr->delta.q.present ? dav1d_get_bits(gb, 2) : 0;
hdr->delta.lf.present = hdr->delta.q.present && !hdr->allow_intrabc &&
dav1d_get_bit(gb);
hdr->delta.lf.res_log2 = hdr->delta.lf.present ? dav1d_get_bits(gb, 2) : 0;
hdr->delta.lf.multi = hdr->delta.lf.present ? dav1d_get_bit(gb) : 0;
#if DEBUG_FRAME_HDR
printf("HDR: post-delta_q_lf_flags: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
// derive lossless flags
const int delta_lossless = !hdr->quant.ydc_delta && !hdr->quant.udc_delta &&
!hdr->quant.uac_delta && !hdr->quant.vdc_delta && !hdr->quant.vac_delta;
hdr->all_lossless = 1;
for (int i = 0; i < DAV1D_MAX_SEGMENTS; i++) {
hdr->segmentation.qidx[i] = hdr->segmentation.enabled ?
iclip_u8(hdr->quant.yac + hdr->segmentation.seg_data.d[i].delta_q) :
hdr->quant.yac;
hdr->segmentation.lossless[i] =
!hdr->segmentation.qidx[i] && delta_lossless;
hdr->all_lossless &= hdr->segmentation.lossless[i];
}
// loopfilter
if (hdr->all_lossless || hdr->allow_intrabc) {
hdr->loopfilter.level_y[0] = hdr->loopfilter.level_y[1] = 0;
hdr->loopfilter.level_u = hdr->loopfilter.level_v = 0;
hdr->loopfilter.sharpness = 0;
hdr->loopfilter.mode_ref_delta_enabled = 1;
hdr->loopfilter.mode_ref_delta_update = 1;
hdr->loopfilter.mode_ref_deltas = default_mode_ref_deltas;
} else {
hdr->loopfilter.level_y[0] = dav1d_get_bits(gb, 6);
hdr->loopfilter.level_y[1] = dav1d_get_bits(gb, 6);
if (!seqhdr->monochrome &&
(hdr->loopfilter.level_y[0] || hdr->loopfilter.level_y[1]))
{
hdr->loopfilter.level_u = dav1d_get_bits(gb, 6);
hdr->loopfilter.level_v = dav1d_get_bits(gb, 6);
}
hdr->loopfilter.sharpness = dav1d_get_bits(gb, 3);
if (hdr->primary_ref_frame == DAV1D_PRIMARY_REF_NONE) {
hdr->loopfilter.mode_ref_deltas = default_mode_ref_deltas;
} else {
const int ref = hdr->refidx[hdr->primary_ref_frame];
if (!c->refs[ref].p.p.frame_hdr) goto error;
hdr->loopfilter.mode_ref_deltas =
c->refs[ref].p.p.frame_hdr->loopfilter.mode_ref_deltas;
}
hdr->loopfilter.mode_ref_delta_enabled = dav1d_get_bit(gb);
if (hdr->loopfilter.mode_ref_delta_enabled) {
hdr->loopfilter.mode_ref_delta_update = dav1d_get_bit(gb);
if (hdr->loopfilter.mode_ref_delta_update) {
for (int i = 0; i < 8; i++)
if (dav1d_get_bit(gb))
hdr->loopfilter.mode_ref_deltas.ref_delta[i] =
dav1d_get_sbits(gb, 7);
for (int i = 0; i < 2; i++)
if (dav1d_get_bit(gb))
hdr->loopfilter.mode_ref_deltas.mode_delta[i] =
dav1d_get_sbits(gb, 7);
}
}
}
#if DEBUG_FRAME_HDR
printf("HDR: post-lpf: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
// cdef
if (!hdr->all_lossless && seqhdr->cdef && !hdr->allow_intrabc) {
hdr->cdef.damping = dav1d_get_bits(gb, 2) + 3;
hdr->cdef.n_bits = dav1d_get_bits(gb, 2);
for (int i = 0; i < (1 << hdr->cdef.n_bits); i++) {
hdr->cdef.y_strength[i] = dav1d_get_bits(gb, 6);
if (!seqhdr->monochrome)
hdr->cdef.uv_strength[i] = dav1d_get_bits(gb, 6);
}
} else {
hdr->cdef.n_bits = 0;
hdr->cdef.y_strength[0] = 0;
hdr->cdef.uv_strength[0] = 0;
}
#if DEBUG_FRAME_HDR
printf("HDR: post-cdef: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
// restoration
if ((!hdr->all_lossless || hdr->super_res.enabled) &&
seqhdr->restoration && !hdr->allow_intrabc)
{
hdr->restoration.type[0] = dav1d_get_bits(gb, 2);
if (!seqhdr->monochrome) {
hdr->restoration.type[1] = dav1d_get_bits(gb, 2);
hdr->restoration.type[2] = dav1d_get_bits(gb, 2);
} else {
hdr->restoration.type[1] =
hdr->restoration.type[2] = DAV1D_RESTORATION_NONE;
}
if (hdr->restoration.type[0] || hdr->restoration.type[1] ||
hdr->restoration.type[2])
{
// Log2 of the restoration unit size.
hdr->restoration.unit_size[0] = 6 + seqhdr->sb128;
if (dav1d_get_bit(gb)) {
hdr->restoration.unit_size[0]++;
if (!seqhdr->sb128)
hdr->restoration.unit_size[0] += dav1d_get_bit(gb);
}
hdr->restoration.unit_size[1] = hdr->restoration.unit_size[0];
if ((hdr->restoration.type[1] || hdr->restoration.type[2]) &&
seqhdr->ss_hor == 1 && seqhdr->ss_ver == 1)
{
hdr->restoration.unit_size[1] -= dav1d_get_bit(gb);
}
} else {
hdr->restoration.unit_size[0] = 8;
}
} else {
hdr->restoration.type[0] = DAV1D_RESTORATION_NONE;
hdr->restoration.type[1] = DAV1D_RESTORATION_NONE;
hdr->restoration.type[2] = DAV1D_RESTORATION_NONE;
}
#if DEBUG_FRAME_HDR
printf("HDR: post-restoration: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->txfm_mode = hdr->all_lossless ? DAV1D_TX_4X4_ONLY :
dav1d_get_bit(gb) ? DAV1D_TX_SWITCHABLE : DAV1D_TX_LARGEST;
#if DEBUG_FRAME_HDR
printf("HDR: post-txfmmode: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->switchable_comp_refs = IS_INTER_OR_SWITCH(hdr) ? dav1d_get_bit(gb) : 0;
#if DEBUG_FRAME_HDR
printf("HDR: post-refmode: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->skip_mode_allowed = 0;
if (hdr->switchable_comp_refs && IS_INTER_OR_SWITCH(hdr) && seqhdr->order_hint) {
const unsigned poc = hdr->frame_offset;
unsigned off_before = 0xFFFFFFFFU;
int off_after = -1;
int off_before_idx, off_after_idx;
for (int i = 0; i < 7; i++) {
if (!c->refs[hdr->refidx[i]].p.p.frame_hdr) goto error;
const unsigned refpoc = c->refs[hdr->refidx[i]].p.p.frame_hdr->frame_offset;
const int diff = get_poc_diff(seqhdr->order_hint_n_bits, refpoc, poc);
if (diff > 0) {
if (off_after == -1 || get_poc_diff(seqhdr->order_hint_n_bits,
off_after, refpoc) > 0)
{
off_after = refpoc;
off_after_idx = i;
}
} else if (diff < 0 && (off_before == 0xFFFFFFFFU ||
get_poc_diff(seqhdr->order_hint_n_bits,
refpoc, off_before) > 0))
{
off_before = refpoc;
off_before_idx = i;
}
}
if (off_before != 0xFFFFFFFFU && off_after != -1) {
hdr->skip_mode_refs[0] = imin(off_before_idx, off_after_idx);
hdr->skip_mode_refs[1] = imax(off_before_idx, off_after_idx);
hdr->skip_mode_allowed = 1;
} else if (off_before != 0xFFFFFFFFU) {
unsigned off_before2 = 0xFFFFFFFFU;
int off_before2_idx;
for (int i = 0; i < 7; i++) {
if (!c->refs[hdr->refidx[i]].p.p.frame_hdr) goto error;
const unsigned refpoc = c->refs[hdr->refidx[i]].p.p.frame_hdr->frame_offset;
if (get_poc_diff(seqhdr->order_hint_n_bits,
refpoc, off_before) < 0) {
if (off_before2 == 0xFFFFFFFFU ||
get_poc_diff(seqhdr->order_hint_n_bits,
refpoc, off_before2) > 0)
{
off_before2 = refpoc;
off_before2_idx = i;
}
}
}
if (off_before2 != 0xFFFFFFFFU) {
hdr->skip_mode_refs[0] = imin(off_before_idx, off_before2_idx);
hdr->skip_mode_refs[1] = imax(off_before_idx, off_before2_idx);
hdr->skip_mode_allowed = 1;
}
}
}
hdr->skip_mode_enabled = hdr->skip_mode_allowed ? dav1d_get_bit(gb) : 0;
#if DEBUG_FRAME_HDR
printf("HDR: post-extskip: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->warp_motion = !hdr->error_resilient_mode && IS_INTER_OR_SWITCH(hdr) &&
seqhdr->warped_motion && dav1d_get_bit(gb);
#if DEBUG_FRAME_HDR
printf("HDR: post-warpmotionbit: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->reduced_txtp_set = dav1d_get_bit(gb);
#if DEBUG_FRAME_HDR
printf("HDR: post-reducedtxtpset: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
for (int i = 0; i < 7; i++)
hdr->gmv[i] = dav1d_default_wm_params;
if (IS_INTER_OR_SWITCH(hdr)) {
for (int i = 0; i < 7; i++) {
hdr->gmv[i].type = !dav1d_get_bit(gb) ? DAV1D_WM_TYPE_IDENTITY :
dav1d_get_bit(gb) ? DAV1D_WM_TYPE_ROT_ZOOM :
dav1d_get_bit(gb) ? DAV1D_WM_TYPE_TRANSLATION :
DAV1D_WM_TYPE_AFFINE;
if (hdr->gmv[i].type == DAV1D_WM_TYPE_IDENTITY) continue;
const Dav1dWarpedMotionParams *ref_gmv;
if (hdr->primary_ref_frame == DAV1D_PRIMARY_REF_NONE) {
ref_gmv = &dav1d_default_wm_params;
} else {
const int pri_ref = hdr->refidx[hdr->primary_ref_frame];
if (!c->refs[pri_ref].p.p.frame_hdr) goto error;
ref_gmv = &c->refs[pri_ref].p.p.frame_hdr->gmv[i];
}
int32_t *const mat = hdr->gmv[i].matrix;
const int32_t *const ref_mat = ref_gmv->matrix;
int bits, shift;
if (hdr->gmv[i].type >= DAV1D_WM_TYPE_ROT_ZOOM) {
mat[2] = (1 << 16) + 2 *
dav1d_get_bits_subexp(gb, (ref_mat[2] - (1 << 16)) >> 1, 12);
mat[3] = 2 * dav1d_get_bits_subexp(gb, ref_mat[3] >> 1, 12);
bits = 12;
shift = 10;
} else {
bits = 9 - !hdr->hp;
shift = 13 + !hdr->hp;
}
if (hdr->gmv[i].type == DAV1D_WM_TYPE_AFFINE) {
mat[4] = 2 * dav1d_get_bits_subexp(gb, ref_mat[4] >> 1, 12);
mat[5] = (1 << 16) + 2 *
dav1d_get_bits_subexp(gb, (ref_mat[5] - (1 << 16)) >> 1, 12);
} else {
mat[4] = -mat[3];
mat[5] = mat[2];
}
mat[0] = dav1d_get_bits_subexp(gb, ref_mat[0] >> shift, bits) * (1 << shift);
mat[1] = dav1d_get_bits_subexp(gb, ref_mat[1] >> shift, bits) * (1 << shift);
}
}
#if DEBUG_FRAME_HDR
printf("HDR: post-gmv: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
hdr->film_grain.present = seqhdr->film_grain_present &&
(hdr->show_frame || hdr->showable_frame) &&
dav1d_get_bit(gb);
if (hdr->film_grain.present) {
const unsigned seed = dav1d_get_bits(gb, 16);
hdr->film_grain.update = hdr->frame_type != DAV1D_FRAME_TYPE_INTER || dav1d_get_bit(gb);
if (!hdr->film_grain.update) {
const int refidx = dav1d_get_bits(gb, 3);
int i;
for (i = 0; i < 7; i++)
if (hdr->refidx[i] == refidx)
break;
if (i == 7 || !c->refs[refidx].p.p.frame_hdr) goto error;
hdr->film_grain.data = c->refs[refidx].p.p.frame_hdr->film_grain.data;
hdr->film_grain.data.seed = seed;
} else {
Dav1dFilmGrainData *const fgd = &hdr->film_grain.data;
fgd->seed = seed;
fgd->num_y_points = dav1d_get_bits(gb, 4);
if (fgd->num_y_points > 14) goto error;
for (int i = 0; i < fgd->num_y_points; i++) {
fgd->y_points[i][0] = dav1d_get_bits(gb, 8);
if (i && fgd->y_points[i - 1][0] >= fgd->y_points[i][0])
goto error;
fgd->y_points[i][1] = dav1d_get_bits(gb, 8);
}
fgd->chroma_scaling_from_luma =
!seqhdr->monochrome && dav1d_get_bit(gb);
if (seqhdr->monochrome || fgd->chroma_scaling_from_luma ||
(seqhdr->ss_ver == 1 && seqhdr->ss_hor == 1 && !fgd->num_y_points))
{
fgd->num_uv_points[0] = fgd->num_uv_points[1] = 0;
} else for (int pl = 0; pl < 2; pl++) {
fgd->num_uv_points[pl] = dav1d_get_bits(gb, 4);
if (fgd->num_uv_points[pl] > 10) goto error;
for (int i = 0; i < fgd->num_uv_points[pl]; i++) {
fgd->uv_points[pl][i][0] = dav1d_get_bits(gb, 8);
if (i && fgd->uv_points[pl][i - 1][0] >= fgd->uv_points[pl][i][0])
goto error;
fgd->uv_points[pl][i][1] = dav1d_get_bits(gb, 8);
}
}
if (seqhdr->ss_hor == 1 && seqhdr->ss_ver == 1 &&
!!fgd->num_uv_points[0] != !!fgd->num_uv_points[1])
{
goto error;
}
fgd->scaling_shift = dav1d_get_bits(gb, 2) + 8;
fgd->ar_coeff_lag = dav1d_get_bits(gb, 2);
const int num_y_pos = 2 * fgd->ar_coeff_lag * (fgd->ar_coeff_lag + 1);
if (fgd->num_y_points)
for (int i = 0; i < num_y_pos; i++)
fgd->ar_coeffs_y[i] = dav1d_get_bits(gb, 8) - 128;
for (int pl = 0; pl < 2; pl++)
if (fgd->num_uv_points[pl] || fgd->chroma_scaling_from_luma) {
const int num_uv_pos = num_y_pos + !!fgd->num_y_points;
for (int i = 0; i < num_uv_pos; i++)
fgd->ar_coeffs_uv[pl][i] = dav1d_get_bits(gb, 8) - 128;
if (!fgd->num_y_points)
fgd->ar_coeffs_uv[pl][num_uv_pos] = 0;
}
fgd->ar_coeff_shift = dav1d_get_bits(gb, 2) + 6;
fgd->grain_scale_shift = dav1d_get_bits(gb, 2);
for (int pl = 0; pl < 2; pl++)
if (fgd->num_uv_points[pl]) {
fgd->uv_mult[pl] = dav1d_get_bits(gb, 8) - 128;
fgd->uv_luma_mult[pl] = dav1d_get_bits(gb, 8) - 128;
fgd->uv_offset[pl] = dav1d_get_bits(gb, 9) - 256;
}
fgd->overlap_flag = dav1d_get_bit(gb);
fgd->clip_to_restricted_range = dav1d_get_bit(gb);
}
} else {
memset(&hdr->film_grain.data, 0, sizeof(hdr->film_grain.data));
}
#if DEBUG_FRAME_HDR
printf("HDR: post-filmgrain: off=%td\n",
(gb->ptr - init_ptr) * 8 - gb->bits_left);
#endif
return 0;
error:
dav1d_log(c, "Error parsing frame header\n");
return DAV1D_ERR(EINVAL);
}
static void parse_tile_hdr(Dav1dContext *const c, GetBits *const gb) {
const int n_tiles = c->frame_hdr->tiling.cols * c->frame_hdr->tiling.rows;
const int have_tile_pos = n_tiles > 1 ? dav1d_get_bit(gb) : 0;
if (have_tile_pos) {
const int n_bits = c->frame_hdr->tiling.log2_cols +
c->frame_hdr->tiling.log2_rows;
c->tile[c->n_tile_data].start = dav1d_get_bits(gb, n_bits);
c->tile[c->n_tile_data].end = dav1d_get_bits(gb, n_bits);
} else {
c->tile[c->n_tile_data].start = 0;
c->tile[c->n_tile_data].end = n_tiles - 1;
}
}
// Check that we haven't read more than obu_len bytes from the buffer
// since init_bit_pos.
static int check_for_overrun(Dav1dContext *const c, GetBits *const gb,
const unsigned init_bit_pos,
const unsigned obu_len)
{
// Make sure we haven't actually read past the end of the gb buffer
if (gb->error) {
dav1d_log(c, "Overrun in OBU bit buffer\n");
return 1;
}
const unsigned pos = dav1d_get_bits_pos(gb);
// We assume that init_bit_pos was the bit position of the buffer
// at some point in the past, so cannot be smaller than pos.
assert (init_bit_pos <= pos);
if (pos - init_bit_pos > 8 * obu_len) {
dav1d_log(c, "Overrun in OBU bit buffer into next OBU\n");
return 1;
}
return 0;
}
int dav1d_parse_obus(Dav1dContext *const c, Dav1dData *const in, const int global) {
GetBits gb;
int res;
dav1d_init_get_bits(&gb, in->data, in->sz);
// obu header
dav1d_get_bit(&gb); // obu_forbidden_bit
const enum Dav1dObuType type = dav1d_get_bits(&gb, 4);
const int has_extension = dav1d_get_bit(&gb);
const int has_length_field = dav1d_get_bit(&gb);
dav1d_get_bit(&gb); // reserved
int temporal_id = 0, spatial_id = 0;
if (has_extension) {
temporal_id = dav1d_get_bits(&gb, 3);
spatial_id = dav1d_get_bits(&gb, 2);
dav1d_get_bits(&gb, 3); // reserved
}
// obu length field
const unsigned len = has_length_field ?
dav1d_get_uleb128(&gb) : (unsigned) in->sz - 1 - has_extension;
if (gb.error) goto error;
const unsigned init_bit_pos = dav1d_get_bits_pos(&gb);
const unsigned init_byte_pos = init_bit_pos >> 3;
// We must have read a whole number of bytes at this point (1 byte
// for the header and whole bytes at a time when reading the
// leb128 length field).
assert((init_bit_pos & 7) == 0);
// We also know that we haven't tried to read more than in->sz
// bytes yet (otherwise the error flag would have been set by the
// code in getbits.c)
assert(in->sz >= init_byte_pos);
// Make sure that there are enough bits left in the buffer for the
// rest of the OBU.
if (len > in->sz - init_byte_pos) goto error;
// skip obu not belonging to the selected temporal/spatial layer
if (type != DAV1D_OBU_SEQ_HDR && type != DAV1D_OBU_TD &&
has_extension && c->operating_point_idc != 0)
{
const int in_temporal_layer = (c->operating_point_idc >> temporal_id) & 1;
const int in_spatial_layer = (c->operating_point_idc >> (spatial_id + 8)) & 1;
if (!in_temporal_layer || !in_spatial_layer)
return len + init_byte_pos;
}
switch (type) {
case DAV1D_OBU_SEQ_HDR: {
Dav1dRef *ref = dav1d_ref_create_using_pool(c->seq_hdr_pool,
sizeof(Dav1dSequenceHeader));
if (!ref) return DAV1D_ERR(ENOMEM);
Dav1dSequenceHeader *seq_hdr = ref->data;
if ((res = parse_seq_hdr(c, &gb, seq_hdr)) < 0) {
dav1d_ref_dec(&ref);
goto error;
}
if (check_for_overrun(c, &gb, init_bit_pos, len)) {
dav1d_ref_dec(&ref);
goto error;
}
// If we have read a sequence header which is different from
// the old one, this is a new video sequence and can't use any
// previous state. Free that state.
if (!c->seq_hdr) {
c->frame_hdr = NULL;
c->frame_flags |= PICTURE_FLAG_NEW_SEQUENCE;
// see 7.5, operating_parameter_info is allowed to change in
// sequence headers of a single sequence
} else if (memcmp(seq_hdr, c->seq_hdr, offsetof(Dav1dSequenceHeader, operating_parameter_info))) {
c->frame_hdr = NULL;
c->mastering_display = NULL;
c->content_light = NULL;
dav1d_ref_dec(&c->mastering_display_ref);
dav1d_ref_dec(&c->content_light_ref);
for (int i = 0; i < 8; i++) {
if (c->refs[i].p.p.frame_hdr)
dav1d_thread_picture_unref(&c->refs[i].p);
dav1d_ref_dec(&c->refs[i].segmap);
dav1d_ref_dec(&c->refs[i].refmvs);
dav1d_cdf_thread_unref(&c->cdf[i]);
}
c->frame_flags |= PICTURE_FLAG_NEW_SEQUENCE;
// If operating_parameter_info changed, signal it
} else if (memcmp(seq_hdr->operating_parameter_info, c->seq_hdr->operating_parameter_info,
sizeof(seq_hdr->operating_parameter_info)))
{
c->frame_flags |= PICTURE_FLAG_NEW_OP_PARAMS_INFO;
}
dav1d_ref_dec(&c->seq_hdr_ref);
c->seq_hdr_ref = ref;
c->seq_hdr = seq_hdr;
break;
}
case DAV1D_OBU_REDUNDANT_FRAME_HDR:
if (c->frame_hdr) break;
// fall-through
case DAV1D_OBU_FRAME:
case DAV1D_OBU_FRAME_HDR:
if (global) break;
if (!c->seq_hdr) goto error;
if (!c->frame_hdr_ref) {
c->frame_hdr_ref = dav1d_ref_create_using_pool(c->frame_hdr_pool,
sizeof(Dav1dFrameHeader));
if (!c->frame_hdr_ref) return DAV1D_ERR(ENOMEM);
}
#ifndef NDEBUG
// ensure that the reference is writable
assert(dav1d_ref_is_writable(c->frame_hdr_ref));
#endif
c->frame_hdr = c->frame_hdr_ref->data;
memset(c->frame_hdr, 0, sizeof(*c->frame_hdr));
c->frame_hdr->temporal_id = temporal_id;
c->frame_hdr->spatial_id = spatial_id;
if ((res = parse_frame_hdr(c, &gb)) < 0) {
c->frame_hdr = NULL;
goto error;
}
for (int n = 0; n < c->n_tile_data; n++)
dav1d_data_unref_internal(&c->tile[n].data);
c->n_tile_data = 0;
c->n_tiles = 0;
if (type != DAV1D_OBU_FRAME) {
// This is actually a frame header OBU so read the
// trailing bit and check for overrun.
dav1d_get_bit(&gb);
if (check_for_overrun(c, &gb, init_bit_pos, len)) {
c->frame_hdr = NULL;
goto error;
}
}
if (c->frame_size_limit && (int64_t)c->frame_hdr->width[1] *
c->frame_hdr->height > c->frame_size_limit)
{
dav1d_log(c, "Frame size %dx%d exceeds limit %u\n", c->frame_hdr->width[1],
c->frame_hdr->height, c->frame_size_limit);
c->frame_hdr = NULL;
return DAV1D_ERR(ERANGE);
}
if (type != DAV1D_OBU_FRAME)
break;
// OBU_FRAMEs shouldn't be signaled with show_existing_frame
if (c->frame_hdr->show_existing_frame) {
c->frame_hdr = NULL;
goto error;
}
// This is the frame header at the start of a frame OBU.
// There's no trailing bit at the end to skip, but we do need
// to align to the next byte.
dav1d_bytealign_get_bits(&gb);
// fall-through
case DAV1D_OBU_TILE_GRP: {
if (global) break;
if (!c->frame_hdr) goto error;
if (c->n_tile_data_alloc < c->n_tile_data + 1) {
if ((c->n_tile_data + 1) > INT_MAX / (int)sizeof(*c->tile)) goto error;
struct Dav1dTileGroup *tile = realloc(c->tile, (c->n_tile_data + 1) * sizeof(*c->tile));
if (!tile) goto error;
c->tile = tile;
memset(c->tile + c->n_tile_data, 0, sizeof(*c->tile));
c->n_tile_data_alloc = c->n_tile_data + 1;
}
parse_tile_hdr(c, &gb);
// Align to the next byte boundary and check for overrun.
dav1d_bytealign_get_bits(&gb);
if (check_for_overrun(c, &gb, init_bit_pos, len))
goto error;
// The current bit position is a multiple of 8 (because we
// just aligned it) and less than 8*pkt_bytelen because
// otherwise the overrun check would have fired.
const unsigned pkt_bytelen = init_byte_pos + len;
const unsigned bit_pos = dav1d_get_bits_pos(&gb);
assert((bit_pos & 7) == 0);
assert(pkt_bytelen >= (bit_pos >> 3));
dav1d_data_ref(&c->tile[c->n_tile_data].data, in);
c->tile[c->n_tile_data].data.data += bit_pos >> 3;
c->tile[c->n_tile_data].data.sz = pkt_bytelen - (bit_pos >> 3);
// ensure tile groups are in order and sane, see 6.10.1
if (c->tile[c->n_tile_data].start > c->tile[c->n_tile_data].end ||
c->tile[c->n_tile_data].start != c->n_tiles)
{
for (int i = 0; i <= c->n_tile_data; i++)
dav1d_data_unref_internal(&c->tile[i].data);
c->n_tile_data = 0;
c->n_tiles = 0;
goto error;
}
c->n_tiles += 1 + c->tile[c->n_tile_data].end -
c->tile[c->n_tile_data].start;
c->n_tile_data++;
break;
}
case DAV1D_OBU_METADATA: {
#define DEBUG_OBU_METADATA 0
#if DEBUG_OBU_METADATA
const uint8_t *const init_ptr = gb.ptr;
#endif
// obu metadta type field
const enum ObuMetaType meta_type = dav1d_get_uleb128(&gb);
const int meta_type_len = (dav1d_get_bits_pos(&gb) - init_bit_pos) >> 3;
if (gb.error) goto error;
switch (meta_type) {
case OBU_META_HDR_CLL: {
Dav1dRef *ref = dav1d_ref_create(sizeof(Dav1dContentLightLevel));
if (!ref) return DAV1D_ERR(ENOMEM);
Dav1dContentLightLevel *const content_light = ref->data;
content_light->max_content_light_level = dav1d_get_bits(&gb, 16);
#if DEBUG_OBU_METADATA
printf("CLLOBU: max-content-light-level: %d [off=%td]\n",
content_light->max_content_light_level,
(gb.ptr - init_ptr) * 8 - gb.bits_left);
#endif
content_light->max_frame_average_light_level = dav1d_get_bits(&gb, 16);
#if DEBUG_OBU_METADATA
printf("CLLOBU: max-frame-average-light-level: %d [off=%td]\n",
content_light->max_frame_average_light_level,
(gb.ptr - init_ptr) * 8 - gb.bits_left);
#endif
// Skip the trailing bit, align to the next byte boundary and check for overrun.
dav1d_get_bit(&gb);
dav1d_bytealign_get_bits(&gb);
if (check_for_overrun(c, &gb, init_bit_pos, len)) {
dav1d_ref_dec(&ref);
goto error;
}
dav1d_ref_dec(&c->content_light_ref);
c->content_light = content_light;
c->content_light_ref = ref;
break;
}
case OBU_META_HDR_MDCV: {
Dav1dRef *ref = dav1d_ref_create(sizeof(Dav1dMasteringDisplay));
if (!ref) return DAV1D_ERR(ENOMEM);
Dav1dMasteringDisplay *const mastering_display = ref->data;
for (int i = 0; i < 3; i++) {
mastering_display->primaries[i][0] = dav1d_get_bits(&gb, 16);
mastering_display->primaries[i][1] = dav1d_get_bits(&gb, 16);
#if DEBUG_OBU_METADATA
printf("MDCVOBU: primaries[%d]: (%d, %d) [off=%td]\n", i,
mastering_display->primaries[i][0],
mastering_display->primaries[i][1],
(gb.ptr - init_ptr) * 8 - gb.bits_left);
#endif
}
mastering_display->white_point[0] = dav1d_get_bits(&gb, 16);
#if DEBUG_OBU_METADATA
printf("MDCVOBU: white-point-x: %d [off=%td]\n",
mastering_display->white_point[0],
(gb.ptr - init_ptr) * 8 - gb.bits_left);
#endif
mastering_display->white_point[1] = dav1d_get_bits(&gb, 16);
#if DEBUG_OBU_METADATA
printf("MDCVOBU: white-point-y: %d [off=%td]\n",
mastering_display->white_point[1],
(gb.ptr - init_ptr) * 8 - gb.bits_left);
#endif
mastering_display->max_luminance = dav1d_get_bits(&gb, 32);
#if DEBUG_OBU_METADATA
printf("MDCVOBU: max-luminance: %d [off=%td]\n",
mastering_display->max_luminance,
(gb.ptr - init_ptr) * 8 - gb.bits_left);
#endif
mastering_display->min_luminance = dav1d_get_bits(&gb, 32);
#if DEBUG_OBU_METADATA
printf("MDCVOBU: min-luminance: %d [off=%td]\n",
mastering_display->min_luminance,
(gb.ptr - init_ptr) * 8 - gb.bits_left);
#endif
// Skip the trailing bit, align to the next byte boundary and check for overrun.
dav1d_get_bit(&gb);
dav1d_bytealign_get_bits(&gb);
if (check_for_overrun(c, &gb, init_bit_pos, len)) {
dav1d_ref_dec(&ref);
goto error;
}
dav1d_ref_dec(&c->mastering_display_ref);
c->mastering_display = mastering_display;
c->mastering_display_ref = ref;
break;
}
case OBU_META_ITUT_T35: {
int payload_size = len;
// Don't take into account all the trailing bits for payload_size
while (payload_size > 0 && !in->data[init_byte_pos + payload_size - 1])
payload_size--; // trailing_zero_bit x 8
payload_size--; // trailing_one_bit + trailing_zero_bit x 7
// Don't take into account meta_type bytes
payload_size -= meta_type_len;
int country_code_extension_byte = 0;
const int country_code = dav1d_get_bits(&gb, 8);
payload_size--;
if (country_code == 0xFF) {
country_code_extension_byte = dav1d_get_bits(&gb, 8);
payload_size--;
}
if (payload_size <= 0) {
dav1d_log(c, "Malformed ITU-T T.35 metadata message format\n");
break;
}
Dav1dRef *ref = dav1d_ref_create(sizeof(Dav1dITUTT35) + payload_size * sizeof(uint8_t));
if (!ref) return DAV1D_ERR(ENOMEM);
Dav1dITUTT35 *const itut_t35_metadata = ref->data;
// We need our public headers to be C++ compatible, so payload can't be
// a flexible array member
itut_t35_metadata->payload = (uint8_t *) &itut_t35_metadata[1];
itut_t35_metadata->country_code = country_code;
itut_t35_metadata->country_code_extension_byte = country_code_extension_byte;
for (int i = 0; i < payload_size; i++)
itut_t35_metadata->payload[i] = dav1d_get_bits(&gb, 8);
itut_t35_metadata->payload_size = payload_size;
dav1d_ref_dec(&c->itut_t35_ref);
c->itut_t35 = itut_t35_metadata;
c->itut_t35_ref = ref;
break;
}
case OBU_META_SCALABILITY:
case OBU_META_TIMECODE:
// ignore metadata OBUs we don't care about
break;
default:
// print a warning but don't fail for unknown types
dav1d_log(c, "Unknown Metadata OBU type %d\n", meta_type);
break;
}
break;
}
case DAV1D_OBU_TD:
c->frame_flags |= PICTURE_FLAG_NEW_TEMPORAL_UNIT;
break;
case DAV1D_OBU_PADDING:
// ignore OBUs we don't care about
break;
default:
// print a warning but don't fail for unknown types
dav1d_log(c, "Unknown OBU type %d of size %u\n", type, len);
break;
}
if (c->seq_hdr && c->frame_hdr) {
if (c->frame_hdr->show_existing_frame) {
if (!c->refs[c->frame_hdr->existing_frame_idx].p.p.frame_hdr) goto error;
switch (c->refs[c->frame_hdr->existing_frame_idx].p.p.frame_hdr->frame_type) {
case DAV1D_FRAME_TYPE_INTER:
case DAV1D_FRAME_TYPE_SWITCH:
if (c->decode_frame_type > DAV1D_DECODEFRAMETYPE_REFERENCE)
goto skip;
break;
case DAV1D_FRAME_TYPE_INTRA:
if (c->decode_frame_type > DAV1D_DECODEFRAMETYPE_INTRA)
goto skip;
// fall-through
default:
break;
}
if (!c->refs[c->frame_hdr->existing_frame_idx].p.p.data[0]) goto error;
if (c->strict_std_compliance &&
!c->refs[c->frame_hdr->existing_frame_idx].p.showable)
{
goto error;
}
if (c->n_fc == 1) {
dav1d_thread_picture_ref(&c->out,
&c->refs[c->frame_hdr->existing_frame_idx].p);
dav1d_data_props_copy(&c->out.p.m, &in->m);
c->event_flags |= dav1d_picture_get_event_flags(&c->refs[c->frame_hdr->existing_frame_idx].p);
} else {
pthread_mutex_lock(&c->task_thread.lock);
// need to append this to the frame output queue
const unsigned next = c->frame_thread.next++;
if (c->frame_thread.next == c->n_fc)
c->frame_thread.next = 0;
Dav1dFrameContext *const f = &c->fc[next];
while (f->n_tile_data > 0)
pthread_cond_wait(&f->task_thread.cond,
&f->task_thread.ttd->lock);
Dav1dThreadPicture *const out_delayed =
&c->frame_thread.out_delayed[next];
if (out_delayed->p.data[0] || atomic_load(&f->task_thread.error)) {
unsigned first = atomic_load(&c->task_thread.first);
if (first + 1U < c->n_fc)
atomic_fetch_add(&c->task_thread.first, 1U);
else
atomic_store(&c->task_thread.first, 0);
atomic_compare_exchange_strong(&c->task_thread.reset_task_cur,
&first, UINT_MAX);
if (c->task_thread.cur && c->task_thread.cur < c->n_fc)
c->task_thread.cur--;
}
const int error = f->task_thread.retval;
if (error) {
c->cached_error = error;
f->task_thread.retval = 0;
dav1d_data_props_copy(&c->cached_error_props, &out_delayed->p.m);
dav1d_thread_picture_unref(out_delayed);
} else if (out_delayed->p.data[0]) {
const unsigned progress = atomic_load_explicit(&out_delayed->progress[1],
memory_order_relaxed);
if ((out_delayed->visible || c->output_invisible_frames) &&
progress != FRAME_ERROR)
{
dav1d_thread_picture_ref(&c->out, out_delayed);
c->event_flags |= dav1d_picture_get_event_flags(out_delayed);
}
dav1d_thread_picture_unref(out_delayed);
}
dav1d_thread_picture_ref(out_delayed,
&c->refs[c->frame_hdr->existing_frame_idx].p);
out_delayed->visible = 1;
dav1d_data_props_copy(&out_delayed->p.m, &in->m);
pthread_mutex_unlock(&c->task_thread.lock);
}
if (c->refs[c->frame_hdr->existing_frame_idx].p.p.frame_hdr->frame_type == DAV1D_FRAME_TYPE_KEY) {
const int r = c->frame_hdr->existing_frame_idx;
c->refs[r].p.showable = 0;
for (int i = 0; i < 8; i++) {
if (i == r) continue;
if (c->refs[i].p.p.frame_hdr)
dav1d_thread_picture_unref(&c->refs[i].p);
dav1d_thread_picture_ref(&c->refs[i].p, &c->refs[r].p);
dav1d_cdf_thread_unref(&c->cdf[i]);
dav1d_cdf_thread_ref(&c->cdf[i], &c->cdf[r]);
dav1d_ref_dec(&c->refs[i].segmap);
c->refs[i].segmap = c->refs[r].segmap;
if (c->refs[r].segmap)
dav1d_ref_inc(c->refs[r].segmap);
dav1d_ref_dec(&c->refs[i].refmvs);
}
}
c->frame_hdr = NULL;
} else if (c->n_tiles == c->frame_hdr->tiling.cols * c->frame_hdr->tiling.rows) {
switch (c->frame_hdr->frame_type) {
case DAV1D_FRAME_TYPE_INTER:
case DAV1D_FRAME_TYPE_SWITCH:
if (c->decode_frame_type > DAV1D_DECODEFRAMETYPE_REFERENCE ||
(c->decode_frame_type == DAV1D_DECODEFRAMETYPE_REFERENCE &&
!c->frame_hdr->refresh_frame_flags))
goto skip;
break;
case DAV1D_FRAME_TYPE_INTRA:
if (c->decode_frame_type > DAV1D_DECODEFRAMETYPE_INTRA ||
(c->decode_frame_type == DAV1D_DECODEFRAMETYPE_REFERENCE &&
!c->frame_hdr->refresh_frame_flags))
goto skip;
// fall-through
default:
break;
}
if (!c->n_tile_data)
goto error;
if ((res = dav1d_submit_frame(c)) < 0)
return res;
assert(!c->n_tile_data);
c->frame_hdr = NULL;
c->n_tiles = 0;
}
}
return len + init_byte_pos;
skip:
// update refs with only the headers in case we skip the frame
for (int i = 0; i < 8; i++) {
if (c->frame_hdr->refresh_frame_flags & (1 << i)) {
dav1d_thread_picture_unref(&c->refs[i].p);
c->refs[i].p.p.frame_hdr = c->frame_hdr;
c->refs[i].p.p.seq_hdr = c->seq_hdr;
c->refs[i].p.p.frame_hdr_ref = c->frame_hdr_ref;
c->refs[i].p.p.seq_hdr_ref = c->seq_hdr_ref;
dav1d_ref_inc(c->frame_hdr_ref);
dav1d_ref_inc(c->seq_hdr_ref);
}
}
dav1d_ref_dec(&c->frame_hdr_ref);
c->frame_hdr = NULL;
c->n_tiles = 0;
return len + init_byte_pos;
error:
dav1d_data_props_copy(&c->cached_error_props, &in->m);
dav1d_log(c, "Error parsing OBU data\n");
return DAV1D_ERR(EINVAL);
}