/* * This file is part of FFmpeg. * * FFmpeg is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * FFmpeg is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with FFmpeg; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ /** * @file * Frame multithreading support functions * @see doc/multithreading.txt */ #include #include "avcodec.h" #include "avcodec_internal.h" #include "codec_desc.h" #include "codec_internal.h" #include "decode.h" #include "hwaccel_internal.h" #include "hwconfig.h" #include "internal.h" #include "packet_internal.h" #include "pthread_internal.h" #include "refstruct.h" #include "thread.h" #include "threadframe.h" #include "version_major.h" #include "libavutil/avassert.h" #include "libavutil/buffer.h" #include "libavutil/common.h" #include "libavutil/cpu.h" #include "libavutil/frame.h" #include "libavutil/internal.h" #include "libavutil/log.h" #include "libavutil/mem.h" #include "libavutil/opt.h" #include "libavutil/thread.h" enum { /// Set when the thread is awaiting a packet. STATE_INPUT_READY, /// Set before the codec has called ff_thread_finish_setup(). STATE_SETTING_UP, /// Set after the codec has called ff_thread_finish_setup(). STATE_SETUP_FINISHED, }; enum { UNINITIALIZED, ///< Thread has not been created, AVCodec->close mustn't be called NEEDS_CLOSE, ///< FFCodec->close needs to be called INITIALIZED, ///< Thread has been properly set up }; typedef struct DecodedFrames { AVFrame **f; size_t nb_f; size_t nb_f_allocated; } DecodedFrames; typedef struct ThreadFrameProgress { atomic_int progress[2]; } ThreadFrameProgress; /** * Context used by codec threads and stored in their AVCodecInternal thread_ctx. */ typedef struct PerThreadContext { struct FrameThreadContext *parent; pthread_t thread; int thread_init; unsigned pthread_init_cnt;///< Number of successfully initialized mutexes/conditions pthread_cond_t input_cond; ///< Used to wait for a new packet from the main thread. pthread_cond_t progress_cond; ///< Used by child threads to wait for progress to change. pthread_cond_t output_cond; ///< Used by the main thread to wait for frames to finish. pthread_mutex_t mutex; ///< Mutex used to protect the contents of the PerThreadContext. pthread_mutex_t progress_mutex; ///< Mutex used to protect frame progress values and progress_cond. AVCodecContext *avctx; ///< Context used to decode packets passed to this thread. AVPacket *avpkt; ///< Input packet (for decoding) or output (for encoding). /** * Decoded frames from a single decode iteration. */ DecodedFrames df; int result; ///< The result of the last codec decode/encode() call. atomic_int state; int die; ///< Set when the thread should exit. int hwaccel_serializing; int async_serializing; // set to 1 in ff_thread_finish_setup() when a threadsafe hwaccel is used; // cannot check hwaccel caps directly, because // worked threads clear hwaccel state for thread-unsafe hwaccels // after each decode call int hwaccel_threadsafe; atomic_int debug_threads; ///< Set if the FF_DEBUG_THREADS option is set. /// The following two fields have the same semantics as the DecodeContext field int intra_only_flag; enum AVPictureType initial_pict_type; } PerThreadContext; /** * Context stored in the client AVCodecInternal thread_ctx. */ typedef struct FrameThreadContext { PerThreadContext *threads; ///< The contexts for each thread. PerThreadContext *prev_thread; ///< The last thread submit_packet() was called on. unsigned pthread_init_cnt; ///< Number of successfully initialized mutexes/conditions pthread_mutex_t buffer_mutex; ///< Mutex used to protect get/release_buffer(). /** * This lock is used for ensuring threads run in serial when thread-unsafe * hwaccel is used. */ pthread_mutex_t hwaccel_mutex; pthread_mutex_t async_mutex; pthread_cond_t async_cond; int async_lock; DecodedFrames df; int result; /** * Packet to be submitted to the next thread for decoding. */ AVPacket *next_pkt; int next_decoding; ///< The next context to submit a packet to. int next_finished; ///< The next context to return output from. /* hwaccel state for thread-unsafe hwaccels is temporarily stored here in * order to transfer its ownership to the next decoding thread without the * need for extra synchronization */ const AVHWAccel *stash_hwaccel; void *stash_hwaccel_context; void *stash_hwaccel_priv; } FrameThreadContext; static int hwaccel_serial(const AVCodecContext *avctx) { return avctx->hwaccel && !(ffhwaccel(avctx->hwaccel)->caps_internal & HWACCEL_CAP_THREAD_SAFE); } static void async_lock(FrameThreadContext *fctx) { pthread_mutex_lock(&fctx->async_mutex); while (fctx->async_lock) pthread_cond_wait(&fctx->async_cond, &fctx->async_mutex); fctx->async_lock = 1; pthread_mutex_unlock(&fctx->async_mutex); } static void async_unlock(FrameThreadContext *fctx) { pthread_mutex_lock(&fctx->async_mutex); av_assert0(fctx->async_lock); fctx->async_lock = 0; pthread_cond_broadcast(&fctx->async_cond); pthread_mutex_unlock(&fctx->async_mutex); } static void thread_set_name(PerThreadContext *p) { AVCodecContext *avctx = p->avctx; int idx = p - p->parent->threads; char name[16]; snprintf(name, sizeof(name), "av:%.7s:df%d", avctx->codec->name, idx); ff_thread_setname(name); } // get a free frame to decode into static AVFrame *decoded_frames_get_free(DecodedFrames *df) { if (df->nb_f == df->nb_f_allocated) { AVFrame **tmp = av_realloc_array(df->f, df->nb_f + 1, sizeof(*df->f)); if (!tmp) return NULL; df->f = tmp; df->f[df->nb_f] = av_frame_alloc(); if (!df->f[df->nb_f]) return NULL; df->nb_f_allocated++; } av_assert0(!df->f[df->nb_f]->buf[0]); return df->f[df->nb_f]; } static void decoded_frames_pop(DecodedFrames *df, AVFrame *dst) { AVFrame *tmp_frame = df->f[0]; av_frame_move_ref(dst, tmp_frame); memmove(df->f, df->f + 1, (df->nb_f - 1) * sizeof(*df->f)); df->f[--df->nb_f] = tmp_frame; } static void decoded_frames_flush(DecodedFrames *df) { for (size_t i = 0; i < df->nb_f; i++) av_frame_unref(df->f[i]); df->nb_f = 0; } static void decoded_frames_free(DecodedFrames *df) { for (size_t i = 0; i < df->nb_f_allocated; i++) av_frame_free(&df->f[i]); av_freep(&df->f); df->nb_f = 0; df->nb_f_allocated = 0; } /** * Codec worker thread. * * Automatically calls ff_thread_finish_setup() if the codec does * not provide an update_thread_context method, or if the codec returns * before calling it. */ static attribute_align_arg void *frame_worker_thread(void *arg) { PerThreadContext *p = arg; AVCodecContext *avctx = p->avctx; const FFCodec *codec = ffcodec(avctx->codec); thread_set_name(p); pthread_mutex_lock(&p->mutex); while (1) { int ret; while (atomic_load(&p->state) == STATE_INPUT_READY && !p->die) pthread_cond_wait(&p->input_cond, &p->mutex); if (p->die) break; if (!codec->update_thread_context) ff_thread_finish_setup(avctx); /* If a decoder supports hwaccel, then it must call ff_get_format(). * Since that call must happen before ff_thread_finish_setup(), the * decoder is required to implement update_thread_context() and call * ff_thread_finish_setup() manually. Therefore the above * ff_thread_finish_setup() call did not happen and hwaccel_serializing * cannot be true here. */ av_assert0(!p->hwaccel_serializing); /* if the previous thread uses thread-unsafe hwaccel then we take the * lock to ensure the threads don't run concurrently */ if (hwaccel_serial(avctx)) { pthread_mutex_lock(&p->parent->hwaccel_mutex); p->hwaccel_serializing = 1; } ret = 0; while (ret >= 0) { AVFrame *frame; /* get the frame which will store the output */ frame = decoded_frames_get_free(&p->df); if (!frame) { p->result = AVERROR(ENOMEM); goto alloc_fail; } /* do the actual decoding */ ret = ff_decode_receive_frame_internal(avctx, frame); if (ret == 0) p->df.nb_f++; else if (ret < 0 && frame->buf[0]) av_frame_unref(frame); p->result = (ret == AVERROR(EAGAIN)) ? 0 : ret; } if (atomic_load(&p->state) == STATE_SETTING_UP) ff_thread_finish_setup(avctx); alloc_fail: if (p->hwaccel_serializing) { /* wipe hwaccel state for thread-unsafe hwaccels to avoid stale * pointers lying around; * the state was transferred to FrameThreadContext in * ff_thread_finish_setup(), so nothing is leaked */ avctx->hwaccel = NULL; avctx->hwaccel_context = NULL; avctx->internal->hwaccel_priv_data = NULL; p->hwaccel_serializing = 0; pthread_mutex_unlock(&p->parent->hwaccel_mutex); } av_assert0(!avctx->hwaccel || (ffhwaccel(avctx->hwaccel)->caps_internal & HWACCEL_CAP_THREAD_SAFE)); if (p->async_serializing) { p->async_serializing = 0; async_unlock(p->parent); } pthread_mutex_lock(&p->progress_mutex); atomic_store(&p->state, STATE_INPUT_READY); pthread_cond_broadcast(&p->progress_cond); pthread_cond_signal(&p->output_cond); pthread_mutex_unlock(&p->progress_mutex); } pthread_mutex_unlock(&p->mutex); return NULL; } /** * Update the next thread's AVCodecContext with values from the reference thread's context. * * @param dst The destination context. * @param src The source context. * @param for_user 0 if the destination is a codec thread, 1 if the destination is the user's thread * @return 0 on success, negative error code on failure */ static int update_context_from_thread(AVCodecContext *dst, const AVCodecContext *src, int for_user) { const FFCodec *const codec = ffcodec(dst->codec); int err = 0; if (dst != src && (for_user || codec->update_thread_context)) { dst->time_base = src->time_base; dst->framerate = src->framerate; dst->width = src->width; dst->height = src->height; dst->pix_fmt = src->pix_fmt; dst->sw_pix_fmt = src->sw_pix_fmt; dst->coded_width = src->coded_width; dst->coded_height = src->coded_height; dst->has_b_frames = src->has_b_frames; dst->idct_algo = src->idct_algo; dst->properties = src->properties; dst->bits_per_coded_sample = src->bits_per_coded_sample; dst->sample_aspect_ratio = src->sample_aspect_ratio; dst->profile = src->profile; dst->level = src->level; dst->bits_per_raw_sample = src->bits_per_raw_sample; #if FF_API_TICKS_PER_FRAME FF_DISABLE_DEPRECATION_WARNINGS dst->ticks_per_frame = src->ticks_per_frame; FF_ENABLE_DEPRECATION_WARNINGS #endif dst->color_primaries = src->color_primaries; dst->color_trc = src->color_trc; dst->colorspace = src->colorspace; dst->color_range = src->color_range; dst->chroma_sample_location = src->chroma_sample_location; dst->sample_rate = src->sample_rate; dst->sample_fmt = src->sample_fmt; err = av_channel_layout_copy(&dst->ch_layout, &src->ch_layout); if (err < 0) return err; if (!!dst->hw_frames_ctx != !!src->hw_frames_ctx || (dst->hw_frames_ctx && dst->hw_frames_ctx->data != src->hw_frames_ctx->data)) { av_buffer_unref(&dst->hw_frames_ctx); if (src->hw_frames_ctx) { dst->hw_frames_ctx = av_buffer_ref(src->hw_frames_ctx); if (!dst->hw_frames_ctx) return AVERROR(ENOMEM); } } dst->hwaccel_flags = src->hwaccel_flags; ff_refstruct_replace(&dst->internal->pool, src->internal->pool); ff_decode_internal_sync(dst, src); } if (for_user) { if (codec->update_thread_context_for_user) err = codec->update_thread_context_for_user(dst, src); } else { const PerThreadContext *p_src = src->internal->thread_ctx; PerThreadContext *p_dst = dst->internal->thread_ctx; if (codec->update_thread_context) { err = codec->update_thread_context(dst, src); if (err < 0) return err; } // reset dst hwaccel state if needed av_assert0(p_dst->hwaccel_threadsafe || (!dst->hwaccel && !dst->internal->hwaccel_priv_data)); if (p_dst->hwaccel_threadsafe && (!p_src->hwaccel_threadsafe || dst->hwaccel != src->hwaccel)) { ff_hwaccel_uninit(dst); p_dst->hwaccel_threadsafe = 0; } // propagate hwaccel state for threadsafe hwaccels if (p_src->hwaccel_threadsafe) { const FFHWAccel *hwaccel = ffhwaccel(src->hwaccel); if (!dst->hwaccel) { if (hwaccel->priv_data_size) { av_assert0(hwaccel->update_thread_context); dst->internal->hwaccel_priv_data = av_mallocz(hwaccel->priv_data_size); if (!dst->internal->hwaccel_priv_data) return AVERROR(ENOMEM); } dst->hwaccel = src->hwaccel; } av_assert0(dst->hwaccel == src->hwaccel); if (hwaccel->update_thread_context) { err = hwaccel->update_thread_context(dst, src); if (err < 0) { av_log(dst, AV_LOG_ERROR, "Error propagating hwaccel state\n"); ff_hwaccel_uninit(dst); return err; } } p_dst->hwaccel_threadsafe = 1; } } return err; } /** * Update the next thread's AVCodecContext with values set by the user. * * @param dst The destination context. * @param src The source context. * @return 0 on success, negative error code on failure */ static int update_context_from_user(AVCodecContext *dst, const AVCodecContext *src) { int err; dst->flags = src->flags; dst->draw_horiz_band= src->draw_horiz_band; dst->get_buffer2 = src->get_buffer2; dst->opaque = src->opaque; dst->debug = src->debug; dst->slice_flags = src->slice_flags; dst->flags2 = src->flags2; dst->export_side_data = src->export_side_data; dst->skip_loop_filter = src->skip_loop_filter; dst->skip_idct = src->skip_idct; dst->skip_frame = src->skip_frame; dst->frame_num = src->frame_num; av_packet_unref(dst->internal->last_pkt_props); err = av_packet_copy_props(dst->internal->last_pkt_props, src->internal->last_pkt_props); if (err < 0) return err; return 0; } static int submit_packet(PerThreadContext *p, AVCodecContext *user_avctx, AVPacket *in_pkt) { FrameThreadContext *fctx = p->parent; PerThreadContext *prev_thread = fctx->prev_thread; const AVCodec *codec = p->avctx->codec; int ret; pthread_mutex_lock(&p->mutex); av_packet_unref(p->avpkt); av_packet_move_ref(p->avpkt, in_pkt); if (AVPACKET_IS_EMPTY(p->avpkt)) p->avctx->internal->draining = 1; ret = update_context_from_user(p->avctx, user_avctx); if (ret) { pthread_mutex_unlock(&p->mutex); return ret; } atomic_store_explicit(&p->debug_threads, (p->avctx->debug & FF_DEBUG_THREADS) != 0, memory_order_relaxed); if (prev_thread) { if (atomic_load(&prev_thread->state) == STATE_SETTING_UP) { pthread_mutex_lock(&prev_thread->progress_mutex); while (atomic_load(&prev_thread->state) == STATE_SETTING_UP) pthread_cond_wait(&prev_thread->progress_cond, &prev_thread->progress_mutex); pthread_mutex_unlock(&prev_thread->progress_mutex); } /* codecs without delay might not be prepared to be called repeatedly here during * flushing (vp3/theora), and also don't need to be, since from this point on, they * will always return EOF anyway */ if (!p->avctx->internal->draining || (codec->capabilities & AV_CODEC_CAP_DELAY)) { ret = update_context_from_thread(p->avctx, prev_thread->avctx, 0); if (ret) { pthread_mutex_unlock(&p->mutex); return ret; } } } /* transfer the stashed hwaccel state, if any */ av_assert0(!p->avctx->hwaccel || p->hwaccel_threadsafe); if (!p->hwaccel_threadsafe) { FFSWAP(const AVHWAccel*, p->avctx->hwaccel, fctx->stash_hwaccel); FFSWAP(void*, p->avctx->hwaccel_context, fctx->stash_hwaccel_context); FFSWAP(void*, p->avctx->internal->hwaccel_priv_data, fctx->stash_hwaccel_priv); } atomic_store(&p->state, STATE_SETTING_UP); pthread_cond_signal(&p->input_cond); pthread_mutex_unlock(&p->mutex); fctx->prev_thread = p; fctx->next_decoding = (fctx->next_decoding + 1) % p->avctx->thread_count; return 0; } int ff_thread_receive_frame(AVCodecContext *avctx, AVFrame *frame) { FrameThreadContext *fctx = avctx->internal->thread_ctx; int ret = 0; /* release the async lock, permitting blocked hwaccel threads to * go forward while we are in this function */ async_unlock(fctx); /* submit packets to threads while there are no buffered results to return */ while (!fctx->df.nb_f && !fctx->result) { PerThreadContext *p; /* get a packet to be submitted to the next thread */ av_packet_unref(fctx->next_pkt); ret = ff_decode_get_packet(avctx, fctx->next_pkt); if (ret < 0 && ret != AVERROR_EOF) goto finish; ret = submit_packet(&fctx->threads[fctx->next_decoding], avctx, fctx->next_pkt); if (ret < 0) goto finish; /* do not return any frames until all threads have something to do */ if (fctx->next_decoding != fctx->next_finished && !avctx->internal->draining) continue; p = &fctx->threads[fctx->next_finished]; fctx->next_finished = (fctx->next_finished + 1) % avctx->thread_count; if (atomic_load(&p->state) != STATE_INPUT_READY) { pthread_mutex_lock(&p->progress_mutex); while (atomic_load_explicit(&p->state, memory_order_relaxed) != STATE_INPUT_READY) pthread_cond_wait(&p->output_cond, &p->progress_mutex); pthread_mutex_unlock(&p->progress_mutex); } update_context_from_thread(avctx, p->avctx, 1); fctx->result = p->result; p->result = 0; if (p->df.nb_f) FFSWAP(DecodedFrames, fctx->df, p->df); } /* a thread may return multiple frames AND an error * we first return all the frames, then the error */ if (fctx->df.nb_f) { decoded_frames_pop(&fctx->df, frame); ret = 0; } else { ret = fctx->result; fctx->result = 0; } finish: async_lock(fctx); return ret; } void ff_thread_report_progress(ThreadFrame *f, int n, int field) { PerThreadContext *p; atomic_int *progress = f->progress ? f->progress->progress : NULL; if (!progress || atomic_load_explicit(&progress[field], memory_order_relaxed) >= n) return; p = f->owner[field]->internal->thread_ctx; if (atomic_load_explicit(&p->debug_threads, memory_order_relaxed)) av_log(f->owner[field], AV_LOG_DEBUG, "%p finished %d field %d\n", progress, n, field); pthread_mutex_lock(&p->progress_mutex); atomic_store_explicit(&progress[field], n, memory_order_release); pthread_cond_broadcast(&p->progress_cond); pthread_mutex_unlock(&p->progress_mutex); } void ff_thread_await_progress(const ThreadFrame *f, int n, int field) { PerThreadContext *p; atomic_int *progress = f->progress ? f->progress->progress : NULL; if (!progress || atomic_load_explicit(&progress[field], memory_order_acquire) >= n) return; p = f->owner[field]->internal->thread_ctx; if (atomic_load_explicit(&p->debug_threads, memory_order_relaxed)) av_log(f->owner[field], AV_LOG_DEBUG, "thread awaiting %d field %d from %p\n", n, field, progress); pthread_mutex_lock(&p->progress_mutex); while (atomic_load_explicit(&progress[field], memory_order_relaxed) < n) pthread_cond_wait(&p->progress_cond, &p->progress_mutex); pthread_mutex_unlock(&p->progress_mutex); } void ff_thread_finish_setup(AVCodecContext *avctx) { PerThreadContext *p; if (!(avctx->active_thread_type&FF_THREAD_FRAME)) return; p = avctx->internal->thread_ctx; p->hwaccel_threadsafe = avctx->hwaccel && (ffhwaccel(avctx->hwaccel)->caps_internal & HWACCEL_CAP_THREAD_SAFE); if (hwaccel_serial(avctx) && !p->hwaccel_serializing) { pthread_mutex_lock(&p->parent->hwaccel_mutex); p->hwaccel_serializing = 1; } /* this assumes that no hwaccel calls happen before ff_thread_finish_setup() */ if (avctx->hwaccel && !(ffhwaccel(avctx->hwaccel)->caps_internal & HWACCEL_CAP_ASYNC_SAFE)) { p->async_serializing = 1; async_lock(p->parent); } /* thread-unsafe hwaccels share a single private data instance, so we * save hwaccel state for passing to the next thread; * this is done here so that this worker thread can wipe its own hwaccel * state after decoding, without requiring synchronization */ av_assert0(!p->parent->stash_hwaccel); if (hwaccel_serial(avctx)) { p->parent->stash_hwaccel = avctx->hwaccel; p->parent->stash_hwaccel_context = avctx->hwaccel_context; p->parent->stash_hwaccel_priv = avctx->internal->hwaccel_priv_data; } pthread_mutex_lock(&p->progress_mutex); if(atomic_load(&p->state) == STATE_SETUP_FINISHED){ av_log(avctx, AV_LOG_WARNING, "Multiple ff_thread_finish_setup() calls\n"); } atomic_store(&p->state, STATE_SETUP_FINISHED); pthread_cond_broadcast(&p->progress_cond); pthread_mutex_unlock(&p->progress_mutex); } /// Waits for all threads to finish. static void park_frame_worker_threads(FrameThreadContext *fctx, int thread_count) { int i; async_unlock(fctx); for (i = 0; i < thread_count; i++) { PerThreadContext *p = &fctx->threads[i]; if (atomic_load(&p->state) != STATE_INPUT_READY) { pthread_mutex_lock(&p->progress_mutex); while (atomic_load(&p->state) != STATE_INPUT_READY) pthread_cond_wait(&p->output_cond, &p->progress_mutex); pthread_mutex_unlock(&p->progress_mutex); } } async_lock(fctx); } #define OFF(member) offsetof(FrameThreadContext, member) DEFINE_OFFSET_ARRAY(FrameThreadContext, thread_ctx, pthread_init_cnt, (OFF(buffer_mutex), OFF(hwaccel_mutex), OFF(async_mutex)), (OFF(async_cond))); #undef OFF #define OFF(member) offsetof(PerThreadContext, member) DEFINE_OFFSET_ARRAY(PerThreadContext, per_thread, pthread_init_cnt, (OFF(progress_mutex), OFF(mutex)), (OFF(input_cond), OFF(progress_cond), OFF(output_cond))); #undef OFF void ff_frame_thread_free(AVCodecContext *avctx, int thread_count) { FrameThreadContext *fctx = avctx->internal->thread_ctx; const FFCodec *codec = ffcodec(avctx->codec); int i; park_frame_worker_threads(fctx, thread_count); for (i = 0; i < thread_count; i++) { PerThreadContext *p = &fctx->threads[i]; AVCodecContext *ctx = p->avctx; if (ctx->internal) { if (p->thread_init == INITIALIZED) { pthread_mutex_lock(&p->mutex); p->die = 1; pthread_cond_signal(&p->input_cond); pthread_mutex_unlock(&p->mutex); pthread_join(p->thread, NULL); } if (codec->close && p->thread_init != UNINITIALIZED) codec->close(ctx); /* When using a threadsafe hwaccel, this is where * each thread's context is uninit'd and freed. */ ff_hwaccel_uninit(ctx); if (ctx->priv_data) { if (codec->p.priv_class) av_opt_free(ctx->priv_data); av_freep(&ctx->priv_data); } ff_refstruct_unref(&ctx->internal->pool); av_packet_free(&ctx->internal->in_pkt); av_packet_free(&ctx->internal->last_pkt_props); ff_decode_internal_uninit(ctx); av_freep(&ctx->internal); av_buffer_unref(&ctx->hw_frames_ctx); av_frame_side_data_free(&ctx->decoded_side_data, &ctx->nb_decoded_side_data); } decoded_frames_free(&p->df); ff_pthread_free(p, per_thread_offsets); av_packet_free(&p->avpkt); av_freep(&p->avctx); } decoded_frames_free(&fctx->df); av_packet_free(&fctx->next_pkt); av_freep(&fctx->threads); ff_pthread_free(fctx, thread_ctx_offsets); /* if we have stashed hwaccel state, move it to the user-facing context, * so it will be freed in ff_codec_close() */ av_assert0(!avctx->hwaccel); FFSWAP(const AVHWAccel*, avctx->hwaccel, fctx->stash_hwaccel); FFSWAP(void*, avctx->hwaccel_context, fctx->stash_hwaccel_context); FFSWAP(void*, avctx->internal->hwaccel_priv_data, fctx->stash_hwaccel_priv); av_freep(&avctx->internal->thread_ctx); } static av_cold int init_thread(PerThreadContext *p, int *threads_to_free, FrameThreadContext *fctx, AVCodecContext *avctx, const FFCodec *codec, int first) { AVCodecContext *copy; int err; p->initial_pict_type = AV_PICTURE_TYPE_NONE; if (avctx->codec_descriptor->props & AV_CODEC_PROP_INTRA_ONLY) { p->intra_only_flag = AV_FRAME_FLAG_KEY; if (avctx->codec_type == AVMEDIA_TYPE_VIDEO) p->initial_pict_type = AV_PICTURE_TYPE_I; } atomic_init(&p->state, STATE_INPUT_READY); copy = av_memdup(avctx, sizeof(*avctx)); if (!copy) return AVERROR(ENOMEM); copy->priv_data = NULL; copy->decoded_side_data = NULL; copy->nb_decoded_side_data = 0; /* From now on, this PerThreadContext will be cleaned up by * ff_frame_thread_free in case of errors. */ (*threads_to_free)++; p->parent = fctx; p->avctx = copy; copy->internal = ff_decode_internal_alloc(); if (!copy->internal) return AVERROR(ENOMEM); ff_decode_internal_sync(copy, avctx); copy->internal->thread_ctx = p; copy->internal->progress_frame_pool = avctx->internal->progress_frame_pool; copy->delay = avctx->delay; if (codec->priv_data_size) { copy->priv_data = av_mallocz(codec->priv_data_size); if (!copy->priv_data) return AVERROR(ENOMEM); if (codec->p.priv_class) { *(const AVClass **)copy->priv_data = codec->p.priv_class; err = av_opt_copy(copy->priv_data, avctx->priv_data); if (err < 0) return err; } } err = ff_pthread_init(p, per_thread_offsets); if (err < 0) return err; if (!(p->avpkt = av_packet_alloc())) return AVERROR(ENOMEM); copy->internal->is_frame_mt = 1; if (!first) copy->internal->is_copy = 1; copy->internal->in_pkt = av_packet_alloc(); if (!copy->internal->in_pkt) return AVERROR(ENOMEM); copy->internal->last_pkt_props = av_packet_alloc(); if (!copy->internal->last_pkt_props) return AVERROR(ENOMEM); if (codec->init) { err = codec->init(copy); if (err < 0) { if (codec->caps_internal & FF_CODEC_CAP_INIT_CLEANUP) p->thread_init = NEEDS_CLOSE; return err; } } p->thread_init = NEEDS_CLOSE; if (first) { update_context_from_thread(avctx, copy, 1); av_frame_side_data_free(&avctx->decoded_side_data, &avctx->nb_decoded_side_data); for (int i = 0; i < copy->nb_decoded_side_data; i++) { err = av_frame_side_data_clone(&avctx->decoded_side_data, &avctx->nb_decoded_side_data, copy->decoded_side_data[i], 0); if (err < 0) return err; } } atomic_init(&p->debug_threads, (copy->debug & FF_DEBUG_THREADS) != 0); err = AVERROR(pthread_create(&p->thread, NULL, frame_worker_thread, p)); if (err < 0) return err; p->thread_init = INITIALIZED; return 0; } int ff_frame_thread_init(AVCodecContext *avctx) { int thread_count = avctx->thread_count; const FFCodec *codec = ffcodec(avctx->codec); FrameThreadContext *fctx; int err, i = 0; if (!thread_count) { int nb_cpus = av_cpu_count(); // use number of cores + 1 as thread count if there is more than one if (nb_cpus > 1) thread_count = avctx->thread_count = FFMIN(nb_cpus + 1, MAX_AUTO_THREADS); else thread_count = avctx->thread_count = 1; } if (thread_count <= 1) { avctx->active_thread_type = 0; return 0; } avctx->internal->thread_ctx = fctx = av_mallocz(sizeof(FrameThreadContext)); if (!fctx) return AVERROR(ENOMEM); err = ff_pthread_init(fctx, thread_ctx_offsets); if (err < 0) { ff_pthread_free(fctx, thread_ctx_offsets); av_freep(&avctx->internal->thread_ctx); return err; } fctx->next_pkt = av_packet_alloc(); if (!fctx->next_pkt) return AVERROR(ENOMEM); fctx->async_lock = 1; if (codec->p.type == AVMEDIA_TYPE_VIDEO) avctx->delay = avctx->thread_count - 1; fctx->threads = av_calloc(thread_count, sizeof(*fctx->threads)); if (!fctx->threads) { err = AVERROR(ENOMEM); goto error; } for (; i < thread_count; ) { PerThreadContext *p = &fctx->threads[i]; int first = !i; err = init_thread(p, &i, fctx, avctx, codec, first); if (err < 0) goto error; } return 0; error: ff_frame_thread_free(avctx, i); return err; } void ff_thread_flush(AVCodecContext *avctx) { int i; FrameThreadContext *fctx = avctx->internal->thread_ctx; if (!fctx) return; park_frame_worker_threads(fctx, avctx->thread_count); if (fctx->prev_thread) { if (fctx->prev_thread != &fctx->threads[0]) update_context_from_thread(fctx->threads[0].avctx, fctx->prev_thread->avctx, 0); } fctx->next_decoding = fctx->next_finished = 0; fctx->prev_thread = NULL; decoded_frames_flush(&fctx->df); fctx->result = 0; for (i = 0; i < avctx->thread_count; i++) { PerThreadContext *p = &fctx->threads[i]; decoded_frames_flush(&p->df); p->result = 0; avcodec_flush_buffers(p->avctx); } } int ff_thread_can_start_frame(AVCodecContext *avctx) { if ((avctx->active_thread_type & FF_THREAD_FRAME) && ffcodec(avctx->codec)->update_thread_context) { PerThreadContext *p = avctx->internal->thread_ctx; if (atomic_load(&p->state) != STATE_SETTING_UP) return 0; } return 1; } static int thread_get_buffer_internal(AVCodecContext *avctx, AVFrame *f, int flags) { PerThreadContext *p; int err; if (!(avctx->active_thread_type & FF_THREAD_FRAME)) return ff_get_buffer(avctx, f, flags); p = avctx->internal->thread_ctx; if (atomic_load(&p->state) != STATE_SETTING_UP && ffcodec(avctx->codec)->update_thread_context) { av_log(avctx, AV_LOG_ERROR, "get_buffer() cannot be called after ff_thread_finish_setup()\n"); return -1; } pthread_mutex_lock(&p->parent->buffer_mutex); err = ff_get_buffer(avctx, f, flags); pthread_mutex_unlock(&p->parent->buffer_mutex); return err; } int ff_thread_get_buffer(AVCodecContext *avctx, AVFrame *f, int flags) { int ret = thread_get_buffer_internal(avctx, f, flags); if (ret < 0) av_log(avctx, AV_LOG_ERROR, "thread_get_buffer() failed\n"); return ret; } int ff_thread_get_ext_buffer(AVCodecContext *avctx, ThreadFrame *f, int flags) { int ret; f->owner[0] = f->owner[1] = avctx; if (!(avctx->active_thread_type & FF_THREAD_FRAME)) return ff_get_buffer(avctx, f->f, flags); f->progress = ff_refstruct_allocz(sizeof(*f->progress)); if (!f->progress) return AVERROR(ENOMEM); atomic_init(&f->progress->progress[0], -1); atomic_init(&f->progress->progress[1], -1); ret = ff_thread_get_buffer(avctx, f->f, flags); if (ret) ff_refstruct_unref(&f->progress); return ret; } void ff_thread_release_ext_buffer(ThreadFrame *f) { ff_refstruct_unref(&f->progress); f->owner[0] = f->owner[1] = NULL; if (f->f) av_frame_unref(f->f); } enum ThreadingStatus ff_thread_sync_ref(AVCodecContext *avctx, size_t offset) { PerThreadContext *p; const void *ref; if (!avctx->internal->is_copy) return avctx->active_thread_type & FF_THREAD_FRAME ? FF_THREAD_IS_FIRST_THREAD : FF_THREAD_NO_FRAME_THREADING; p = avctx->internal->thread_ctx; av_assert1(memcpy(&ref, (char*)avctx->priv_data + offset, sizeof(ref)) && ref == NULL); memcpy(&ref, (const char*)p->parent->threads[0].avctx->priv_data + offset, sizeof(ref)); av_assert1(ref); ff_refstruct_replace((char*)avctx->priv_data + offset, ref); return FF_THREAD_IS_COPY; } int ff_thread_get_packet(AVCodecContext *avctx, AVPacket *pkt) { PerThreadContext *p = avctx->internal->thread_ctx; if (!AVPACKET_IS_EMPTY(p->avpkt)) { av_packet_move_ref(pkt, p->avpkt); return 0; } return avctx->internal->draining ? AVERROR_EOF : AVERROR(EAGAIN); }