/* * Copyright © 2018, 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 "vcs_version.h" #include #include #if defined(__linux__) && defined(HAVE_DLSYM) #include #endif #include "dav1d/dav1d.h" #include "dav1d/data.h" #include "common/validate.h" #include "src/cpu.h" #include "src/fg_apply.h" #include "src/internal.h" #include "src/log.h" #include "src/obu.h" #include "src/qm.h" #include "src/ref.h" #include "src/thread_task.h" #include "src/wedge.h" static COLD void init_internal(void) { dav1d_init_cpu(); dav1d_init_interintra_masks(); dav1d_init_qm_tables(); dav1d_init_thread(); dav1d_init_wedge_masks(); } COLD const char *dav1d_version(void) { return DAV1D_VERSION; } COLD void dav1d_default_settings(Dav1dSettings *const s) { s->n_threads = 0; s->max_frame_delay = 0; s->apply_grain = 1; s->allocator.cookie = NULL; s->allocator.alloc_picture_callback = dav1d_default_picture_alloc; s->allocator.release_picture_callback = dav1d_default_picture_release; s->logger.cookie = NULL; s->logger.callback = dav1d_log_default_callback; s->operating_point = 0; s->all_layers = 1; // just until the tests are adjusted s->frame_size_limit = 0; s->strict_std_compliance = 0; s->output_invisible_frames = 0; s->inloop_filters = DAV1D_INLOOPFILTER_ALL; } static void close_internal(Dav1dContext **const c_out, int flush); NO_SANITIZE("cfi-icall") // CFI is broken with dlsym() static COLD size_t get_stack_size_internal(const pthread_attr_t *const thread_attr) { #if defined(__linux__) && defined(HAVE_DLSYM) && defined(__GLIBC__) /* glibc has an issue where the size of the TLS is subtracted from the stack * size instead of allocated separately. As a result the specified stack * size may be insufficient when used in an application with large amounts * of TLS data. The following is a workaround to compensate for that. * See https://sourceware.org/bugzilla/show_bug.cgi?id=11787 */ size_t (*const get_minstack)(const pthread_attr_t*) = dlsym(RTLD_DEFAULT, "__pthread_get_minstack"); if (get_minstack) return get_minstack(thread_attr) - PTHREAD_STACK_MIN; #endif return 0; } static COLD void get_num_threads(Dav1dContext *const c, const Dav1dSettings *const s, unsigned *n_tc, unsigned *n_fc) { /* ceil(sqrt(n)) */ static const uint8_t fc_lut[49] = { 1, /* 1 */ 2, 2, 2, /* 2- 4 */ 3, 3, 3, 3, 3, /* 5- 9 */ 4, 4, 4, 4, 4, 4, 4, /* 10-16 */ 5, 5, 5, 5, 5, 5, 5, 5, 5, /* 17-25 */ 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, /* 26-36 */ 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, /* 37-49 */ }; *n_tc = s->n_threads ? s->n_threads : iclip(dav1d_num_logical_processors(c), 1, DAV1D_MAX_THREADS); *n_fc = s->max_frame_delay ? umin(s->max_frame_delay, *n_tc) : *n_tc < 50 ? fc_lut[*n_tc - 1] : 8; // min(8, ceil(sqrt(n))) } COLD int dav1d_get_frame_delay(const Dav1dSettings *const s) { unsigned n_tc, n_fc; validate_input_or_ret(s != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(s->n_threads >= 0 && s->n_threads <= DAV1D_MAX_THREADS, DAV1D_ERR(EINVAL)); validate_input_or_ret(s->max_frame_delay >= 0 && s->max_frame_delay <= DAV1D_MAX_FRAME_DELAY, DAV1D_ERR(EINVAL)); get_num_threads(NULL, s, &n_tc, &n_fc); return n_fc; } COLD int dav1d_open(Dav1dContext **const c_out, const Dav1dSettings *const s) { static pthread_once_t initted = PTHREAD_ONCE_INIT; pthread_once(&initted, init_internal); validate_input_or_ret(c_out != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(s != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(s->n_threads >= 0 && s->n_threads <= DAV1D_MAX_THREADS, DAV1D_ERR(EINVAL)); validate_input_or_ret(s->max_frame_delay >= 0 && s->max_frame_delay <= DAV1D_MAX_FRAME_DELAY, DAV1D_ERR(EINVAL)); validate_input_or_ret(s->allocator.alloc_picture_callback != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(s->allocator.release_picture_callback != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(s->operating_point >= 0 && s->operating_point <= 31, DAV1D_ERR(EINVAL)); pthread_attr_t thread_attr; if (pthread_attr_init(&thread_attr)) return DAV1D_ERR(ENOMEM); size_t stack_size = 1024 * 1024 + get_stack_size_internal(&thread_attr); pthread_attr_setstacksize(&thread_attr, stack_size); Dav1dContext *const c = *c_out = dav1d_alloc_aligned(sizeof(*c), 64); if (!c) goto error; memset(c, 0, sizeof(*c)); c->allocator = s->allocator; c->logger = s->logger; c->apply_grain = s->apply_grain; c->operating_point = s->operating_point; c->all_layers = s->all_layers; c->frame_size_limit = s->frame_size_limit; c->strict_std_compliance = s->strict_std_compliance; c->output_invisible_frames = s->output_invisible_frames; c->inloop_filters = s->inloop_filters; dav1d_data_props_set_defaults(&c->cached_error_props); if (dav1d_mem_pool_init(&c->seq_hdr_pool) || dav1d_mem_pool_init(&c->frame_hdr_pool) || dav1d_mem_pool_init(&c->segmap_pool) || dav1d_mem_pool_init(&c->refmvs_pool) || dav1d_mem_pool_init(&c->cdf_pool)) { goto error; } if (c->allocator.alloc_picture_callback == dav1d_default_picture_alloc && c->allocator.release_picture_callback == dav1d_default_picture_release) { if (c->allocator.cookie) goto error; if (dav1d_mem_pool_init(&c->picture_pool)) goto error; c->allocator.cookie = c->picture_pool; } else if (c->allocator.alloc_picture_callback == dav1d_default_picture_alloc || c->allocator.release_picture_callback == dav1d_default_picture_release) { goto error; } /* On 32-bit systems extremely large frame sizes can cause overflows in * dav1d_decode_frame() malloc size calculations. Prevent that from occuring * by enforcing a maximum frame size limit, chosen to roughly correspond to * the largest size possible to decode without exhausting virtual memory. */ if (sizeof(size_t) < 8 && s->frame_size_limit - 1 >= 8192 * 8192) { c->frame_size_limit = 8192 * 8192; if (s->frame_size_limit) dav1d_log(c, "Frame size limit reduced from %u to %u.\n", s->frame_size_limit, c->frame_size_limit); } c->flush = &c->flush_mem; atomic_init(c->flush, 0); get_num_threads(c, s, &c->n_tc, &c->n_fc); c->fc = dav1d_alloc_aligned(sizeof(*c->fc) * c->n_fc, 32); if (!c->fc) goto error; memset(c->fc, 0, sizeof(*c->fc) * c->n_fc); c->tc = dav1d_alloc_aligned(sizeof(*c->tc) * c->n_tc, 64); if (!c->tc) goto error; memset(c->tc, 0, sizeof(*c->tc) * c->n_tc); if (c->n_tc > 1) { if (pthread_mutex_init(&c->task_thread.lock, NULL)) goto error; if (pthread_cond_init(&c->task_thread.cond, NULL)) { pthread_mutex_destroy(&c->task_thread.lock); goto error; } if (pthread_cond_init(&c->task_thread.delayed_fg.cond, NULL)) { pthread_cond_destroy(&c->task_thread.cond); pthread_mutex_destroy(&c->task_thread.lock); goto error; } c->task_thread.cur = c->n_fc; atomic_init(&c->task_thread.reset_task_cur, UINT_MAX); atomic_init(&c->task_thread.cond_signaled, 0); c->task_thread.inited = 1; } if (c->n_fc > 1) { c->frame_thread.out_delayed = calloc(c->n_fc, sizeof(*c->frame_thread.out_delayed)); if (!c->frame_thread.out_delayed) goto error; } for (unsigned n = 0; n < c->n_fc; n++) { Dav1dFrameContext *const f = &c->fc[n]; if (c->n_tc > 1) { if (pthread_mutex_init(&f->task_thread.lock, NULL)) goto error; if (pthread_cond_init(&f->task_thread.cond, NULL)) { pthread_mutex_destroy(&f->task_thread.lock); goto error; } if (pthread_mutex_init(&f->task_thread.pending_tasks.lock, NULL)) { pthread_cond_destroy(&f->task_thread.cond); pthread_mutex_destroy(&f->task_thread.lock); goto error; } } f->c = c; f->task_thread.ttd = &c->task_thread; f->lf.last_sharpness = -1; dav1d_refmvs_init(&f->rf); } for (unsigned m = 0; m < c->n_tc; m++) { Dav1dTaskContext *const t = &c->tc[m]; t->f = &c->fc[0]; t->task_thread.ttd = &c->task_thread; t->c = c; memset(t->cf_16bpc, 0, sizeof(t->cf_16bpc)); if (c->n_tc > 1) { if (pthread_mutex_init(&t->task_thread.td.lock, NULL)) goto error; if (pthread_cond_init(&t->task_thread.td.cond, NULL)) { pthread_mutex_destroy(&t->task_thread.td.lock); goto error; } if (pthread_create(&t->task_thread.td.thread, &thread_attr, dav1d_worker_task, t)) { pthread_cond_destroy(&t->task_thread.td.cond); pthread_mutex_destroy(&t->task_thread.td.lock); goto error; } t->task_thread.td.inited = 1; } } dav1d_refmvs_dsp_init(&c->refmvs_dsp); // intra edge tree c->intra_edge.root[BL_128X128] = &c->intra_edge.branch_sb128[0].node; dav1d_init_mode_tree(c->intra_edge.root[BL_128X128], c->intra_edge.tip_sb128, 1); c->intra_edge.root[BL_64X64] = &c->intra_edge.branch_sb64[0].node; dav1d_init_mode_tree(c->intra_edge.root[BL_64X64], c->intra_edge.tip_sb64, 0); pthread_attr_destroy(&thread_attr); return 0; error: if (c) close_internal(c_out, 0); pthread_attr_destroy(&thread_attr); return DAV1D_ERR(ENOMEM); } static void dummy_free(const uint8_t *const data, void *const user_data) { assert(data && !user_data); } int dav1d_parse_sequence_header(Dav1dSequenceHeader *const out, const uint8_t *const ptr, const size_t sz) { Dav1dData buf = { 0 }; int res; validate_input_or_ret(out != NULL, DAV1D_ERR(EINVAL)); Dav1dSettings s; dav1d_default_settings(&s); s.n_threads = 1; s.logger.callback = NULL; Dav1dContext *c; res = dav1d_open(&c, &s); if (res < 0) return res; if (ptr) { res = dav1d_data_wrap_internal(&buf, ptr, sz, dummy_free, NULL); if (res < 0) goto error; } while (buf.sz > 0) { res = dav1d_parse_obus(c, &buf, 1); if (res < 0) goto error; assert((size_t)res <= buf.sz); buf.sz -= res; buf.data += res; } if (!c->seq_hdr) { res = DAV1D_ERR(ENOENT); goto error; } memcpy(out, c->seq_hdr, sizeof(*out)); res = 0; error: dav1d_data_unref_internal(&buf); dav1d_close(&c); return res; } static int has_grain(const Dav1dPicture *const pic) { const Dav1dFilmGrainData *fgdata = &pic->frame_hdr->film_grain.data; return fgdata->num_y_points || fgdata->num_uv_points[0] || fgdata->num_uv_points[1] || (fgdata->clip_to_restricted_range && fgdata->chroma_scaling_from_luma); } static int output_image(Dav1dContext *const c, Dav1dPicture *const out) { int res = 0; Dav1dThreadPicture *const in = (c->all_layers || !c->max_spatial_id) ? &c->out : &c->cache; if (!c->apply_grain || !has_grain(&in->p)) { dav1d_picture_move_ref(out, &in->p); dav1d_thread_picture_unref(in); goto end; } res = dav1d_apply_grain(c, out, &in->p); dav1d_thread_picture_unref(in); end: if (!c->all_layers && c->max_spatial_id && c->out.p.data[0]) { dav1d_thread_picture_move_ref(in, &c->out); } return res; } static int output_picture_ready(Dav1dContext *const c, const int drain) { if (c->cached_error) return 1; if (!c->all_layers && c->max_spatial_id) { if (c->out.p.data[0] && c->cache.p.data[0]) { if (c->max_spatial_id == c->cache.p.frame_hdr->spatial_id || c->out.flags & PICTURE_FLAG_NEW_TEMPORAL_UNIT) return 1; dav1d_thread_picture_unref(&c->cache); dav1d_thread_picture_move_ref(&c->cache, &c->out); return 0; } else if (c->cache.p.data[0] && drain) { return 1; } else if (c->out.p.data[0]) { dav1d_thread_picture_move_ref(&c->cache, &c->out); return 0; } } return !!c->out.p.data[0]; } static int drain_picture(Dav1dContext *const c, Dav1dPicture *const out) { unsigned drain_count = 0; do { const unsigned next = c->frame_thread.next; Dav1dFrameContext *const f = &c->fc[next]; pthread_mutex_lock(&c->task_thread.lock); 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--; } if (++c->frame_thread.next == c->n_fc) c->frame_thread.next = 0; pthread_mutex_unlock(&c->task_thread.lock); const int error = f->task_thread.retval; if (error) { f->task_thread.retval = 0; dav1d_data_props_copy(&c->cached_error_props, &out_delayed->p.m); dav1d_thread_picture_unref(out_delayed); return error; } 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); if (output_picture_ready(c, 0)) return output_image(c, out); } } while (++drain_count < c->n_fc); if (output_picture_ready(c, 1)) return output_image(c, out); return DAV1D_ERR(EAGAIN); } static int gen_picture(Dav1dContext *const c) { int res; Dav1dData *const in = &c->in; if (output_picture_ready(c, 0)) return 0; while (in->sz > 0) { res = dav1d_parse_obus(c, in, 0); if (res < 0) { dav1d_data_unref_internal(in); } else { assert((size_t)res <= in->sz); in->sz -= res; in->data += res; if (!in->sz) dav1d_data_unref_internal(in); } if (output_picture_ready(c, 0)) break; if (res < 0) return res; } return 0; } int dav1d_send_data(Dav1dContext *const c, Dav1dData *const in) { validate_input_or_ret(c != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(in != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(in->data == NULL || in->sz, DAV1D_ERR(EINVAL)); if (in->data) c->drain = 0; if (c->in.data) return DAV1D_ERR(EAGAIN); dav1d_data_ref(&c->in, in); int res = gen_picture(c); if (!res) dav1d_data_unref_internal(in); return res; } int dav1d_get_picture(Dav1dContext *const c, Dav1dPicture *const out) { validate_input_or_ret(c != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(out != NULL, DAV1D_ERR(EINVAL)); const int drain = c->drain; c->drain = 1; int res = gen_picture(c); if (res < 0) return res; if (c->cached_error) { const int res = c->cached_error; c->cached_error = 0; return res; } if (output_picture_ready(c, c->n_fc == 1)) return output_image(c, out); if (c->n_fc > 1 && drain) return drain_picture(c, out); return DAV1D_ERR(EAGAIN); } int dav1d_apply_grain(Dav1dContext *const c, Dav1dPicture *const out, const Dav1dPicture *const in) { validate_input_or_ret(c != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(out != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(in != NULL, DAV1D_ERR(EINVAL)); if (!has_grain(in)) { dav1d_picture_ref(out, in); return 0; } int res = dav1d_picture_alloc_copy(c, out, in->p.w, in); if (res < 0) goto error; if (c->n_tc > 1) { dav1d_task_delayed_fg(c, out, in); } else { switch (out->p.bpc) { #if CONFIG_8BPC case 8: dav1d_apply_grain_8bpc(&c->dsp[0].fg, out, in); break; #endif #if CONFIG_16BPC case 10: case 12: dav1d_apply_grain_16bpc(&c->dsp[(out->p.bpc >> 1) - 4].fg, out, in); break; #endif default: abort(); } } return 0; error: dav1d_picture_unref_internal(out); return res; } void dav1d_flush(Dav1dContext *const c) { dav1d_data_unref_internal(&c->in); if (c->out.p.data[0]) dav1d_thread_picture_unref(&c->out); if (c->cache.p.data[0]) dav1d_thread_picture_unref(&c->cache); c->drain = 0; c->cached_error = 0; for (int i = 0; i < 8; i++) { if (c->refs[i].p.p.data[0]) 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_hdr = NULL; c->seq_hdr = NULL; dav1d_ref_dec(&c->seq_hdr_ref); c->mastering_display = NULL; c->content_light = NULL; c->itut_t35 = NULL; dav1d_ref_dec(&c->mastering_display_ref); dav1d_ref_dec(&c->content_light_ref); dav1d_ref_dec(&c->itut_t35_ref); dav1d_data_props_unref_internal(&c->cached_error_props); if (c->n_fc == 1 && c->n_tc == 1) return; atomic_store(c->flush, 1); // stop running tasks in worker threads if (c->n_tc > 1) { pthread_mutex_lock(&c->task_thread.lock); for (unsigned i = 0; i < c->n_tc; i++) { Dav1dTaskContext *const tc = &c->tc[i]; while (!tc->task_thread.flushed) { pthread_cond_wait(&tc->task_thread.td.cond, &c->task_thread.lock); } } for (unsigned i = 0; i < c->n_fc; i++) { c->fc[i].task_thread.task_head = NULL; c->fc[i].task_thread.task_tail = NULL; c->fc[i].task_thread.task_cur_prev = NULL; c->fc[i].task_thread.pending_tasks.head = NULL; c->fc[i].task_thread.pending_tasks.tail = NULL; atomic_init(&c->fc[i].task_thread.pending_tasks.merge, 0); } atomic_init(&c->task_thread.first, 0); c->task_thread.cur = c->n_fc; atomic_store(&c->task_thread.reset_task_cur, UINT_MAX); atomic_store(&c->task_thread.cond_signaled, 0); pthread_mutex_unlock(&c->task_thread.lock); } // wait for threads to complete flushing if (c->n_fc > 1) { for (unsigned n = 0, next = c->frame_thread.next; n < c->n_fc; n++, next++) { if (next == c->n_fc) next = 0; Dav1dFrameContext *const f = &c->fc[next]; dav1d_decode_frame_exit(f, -1); f->n_tile_data = 0; f->task_thread.retval = 0; Dav1dThreadPicture *out_delayed = &c->frame_thread.out_delayed[next]; if (out_delayed->p.data[0]) { dav1d_thread_picture_unref(out_delayed); } } c->frame_thread.next = 0; } atomic_store(c->flush, 0); } COLD void dav1d_close(Dav1dContext **const c_out) { validate_input(c_out != NULL); close_internal(c_out, 1); } static COLD void close_internal(Dav1dContext **const c_out, int flush) { Dav1dContext *const c = *c_out; if (!c) return; if (flush) dav1d_flush(c); if (c->tc) { struct TaskThreadData *ttd = &c->task_thread; if (ttd->inited) { pthread_mutex_lock(&ttd->lock); for (unsigned n = 0; n < c->n_tc && c->tc[n].task_thread.td.inited; n++) c->tc[n].task_thread.die = 1; pthread_cond_broadcast(&ttd->cond); pthread_mutex_unlock(&ttd->lock); for (unsigned n = 0; n < c->n_tc; n++) { Dav1dTaskContext *const pf = &c->tc[n]; if (!pf->task_thread.td.inited) break; pthread_join(pf->task_thread.td.thread, NULL); pthread_cond_destroy(&pf->task_thread.td.cond); pthread_mutex_destroy(&pf->task_thread.td.lock); } pthread_cond_destroy(&ttd->delayed_fg.cond); pthread_cond_destroy(&ttd->cond); pthread_mutex_destroy(&ttd->lock); } dav1d_free_aligned(c->tc); } for (unsigned n = 0; c->fc && n < c->n_fc; n++) { Dav1dFrameContext *const f = &c->fc[n]; // clean-up threading stuff if (c->n_fc > 1) { freep(&f->tile_thread.lowest_pixel_mem); freep(&f->frame_thread.b); dav1d_freep_aligned(&f->frame_thread.pal_idx); dav1d_freep_aligned(&f->frame_thread.cf); freep(&f->frame_thread.tile_start_off); dav1d_freep_aligned(&f->frame_thread.pal); freep(&f->frame_thread.cbi); } if (c->n_tc > 1) { pthread_mutex_destroy(&f->task_thread.pending_tasks.lock); pthread_cond_destroy(&f->task_thread.cond); pthread_mutex_destroy(&f->task_thread.lock); } freep(&f->frame_thread.frame_progress); freep(&f->task_thread.tasks); freep(&f->task_thread.tile_tasks[0]); dav1d_free_aligned(f->ts); dav1d_free_aligned(f->ipred_edge[0]); free(f->a); free(f->tile); free(f->lf.mask); free(f->lf.lr_mask); free(f->lf.level); free(f->lf.tx_lpf_right_edge[0]); free(f->lf.start_of_tile_row); dav1d_refmvs_clear(&f->rf); dav1d_free_aligned(f->lf.cdef_line_buf); dav1d_free_aligned(f->lf.lr_line_buf); } dav1d_free_aligned(c->fc); if (c->n_fc > 1 && c->frame_thread.out_delayed) { for (unsigned n = 0; n < c->n_fc; n++) if (c->frame_thread.out_delayed[n].p.data[0]) dav1d_thread_picture_unref(&c->frame_thread.out_delayed[n]); free(c->frame_thread.out_delayed); } for (int n = 0; n < c->n_tile_data; n++) dav1d_data_unref_internal(&c->tile[n].data); free(c->tile); for (int n = 0; n < 8; n++) { dav1d_cdf_thread_unref(&c->cdf[n]); if (c->refs[n].p.p.data[0]) dav1d_thread_picture_unref(&c->refs[n].p); dav1d_ref_dec(&c->refs[n].refmvs); dav1d_ref_dec(&c->refs[n].segmap); } dav1d_ref_dec(&c->seq_hdr_ref); dav1d_ref_dec(&c->frame_hdr_ref); dav1d_ref_dec(&c->mastering_display_ref); dav1d_ref_dec(&c->content_light_ref); dav1d_ref_dec(&c->itut_t35_ref); dav1d_mem_pool_end(c->seq_hdr_pool); dav1d_mem_pool_end(c->frame_hdr_pool); dav1d_mem_pool_end(c->segmap_pool); dav1d_mem_pool_end(c->refmvs_pool); dav1d_mem_pool_end(c->cdf_pool); dav1d_mem_pool_end(c->picture_pool); dav1d_freep_aligned(c_out); } int dav1d_get_event_flags(Dav1dContext *const c, enum Dav1dEventFlags *const flags) { validate_input_or_ret(c != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(flags != NULL, DAV1D_ERR(EINVAL)); *flags = c->event_flags; c->event_flags = 0; return 0; } int dav1d_get_decode_error_data_props(Dav1dContext *const c, Dav1dDataProps *const out) { validate_input_or_ret(c != NULL, DAV1D_ERR(EINVAL)); validate_input_or_ret(out != NULL, DAV1D_ERR(EINVAL)); dav1d_data_props_unref_internal(out); *out = c->cached_error_props; dav1d_data_props_set_defaults(&c->cached_error_props); return 0; } void dav1d_picture_unref(Dav1dPicture *const p) { dav1d_picture_unref_internal(p); } uint8_t *dav1d_data_create(Dav1dData *const buf, const size_t sz) { return dav1d_data_create_internal(buf, sz); } int dav1d_data_wrap(Dav1dData *const buf, const uint8_t *const ptr, const size_t sz, void (*const free_callback)(const uint8_t *data, void *user_data), void *const user_data) { return dav1d_data_wrap_internal(buf, ptr, sz, free_callback, user_data); } int dav1d_data_wrap_user_data(Dav1dData *const buf, const uint8_t *const user_data, void (*const free_callback)(const uint8_t *user_data, void *cookie), void *const cookie) { return dav1d_data_wrap_user_data_internal(buf, user_data, free_callback, cookie); } void dav1d_data_unref(Dav1dData *const buf) { dav1d_data_unref_internal(buf); } void dav1d_data_props_unref(Dav1dDataProps *const props) { dav1d_data_props_unref_internal(props); }