blob: bd99225224d4470a5a04aaae793c4d6d2030adad [file] [log] [blame]
// Copyright 2019 The Cobalt Authors. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "starboard/shared/libaom/aom_video_decoder.h"
#include "starboard/common/log.h"
#include "starboard/common/string.h"
#include "starboard/linux/shared/decode_target_internal.h"
#include "starboard/shared/libaom/aom_library_loader.h"
namespace starboard {
namespace shared {
namespace aom {
using starboard::player::JobThread;
VideoDecoder::VideoDecoder(SbMediaVideoCodec video_codec,
SbPlayerOutputMode output_mode,
SbDecodeTargetGraphicsContextProvider*
decode_target_graphics_context_provider)
: current_frame_width_(0),
current_frame_height_(0),
stream_ended_(false),
error_occured_(false),
output_mode_(output_mode),
decode_target_graphics_context_provider_(
decode_target_graphics_context_provider),
decode_target_(kSbDecodeTargetInvalid) {
#if SB_API_VERSION < 11
SB_DCHECK(video_codec == kSbMediaVideoCodecVp10);
#else // SB_API_VERSION < 11
SB_DCHECK(video_codec == kSbMediaVideoCodecAv1);
#endif // SB_API_VERSION < 11
SB_DCHECK(is_aom_supported());
}
VideoDecoder::~VideoDecoder() {
SB_DCHECK(BelongsToCurrentThread());
Reset();
}
void VideoDecoder::Initialize(const DecoderStatusCB& decoder_status_cb,
const ErrorCB& error_cb) {
SB_DCHECK(BelongsToCurrentThread());
SB_DCHECK(decoder_status_cb);
SB_DCHECK(!decoder_status_cb_);
SB_DCHECK(error_cb);
SB_DCHECK(!error_cb_);
decoder_status_cb_ = decoder_status_cb;
error_cb_ = error_cb;
}
void VideoDecoder::WriteInputBuffer(
const scoped_refptr<InputBuffer>& input_buffer) {
SB_DCHECK(BelongsToCurrentThread());
SB_DCHECK(input_buffer);
SB_DCHECK(decoder_status_cb_);
if (stream_ended_) {
SB_LOG(ERROR) << "WriteInputFrame() was called after WriteEndOfStream().";
return;
}
if (!decoder_thread_) {
decoder_thread_.reset(new JobThread("aom_video_decoder"));
SB_DCHECK(decoder_thread_);
}
decoder_thread_->job_queue()->Schedule(
std::bind(&VideoDecoder::DecodeOneBuffer, this, input_buffer));
}
void VideoDecoder::WriteEndOfStream() {
SB_DCHECK(BelongsToCurrentThread());
SB_DCHECK(decoder_status_cb_);
// We have to flush the decoder to decode the rest frames and to ensure that
// Decode() is not called when the stream is ended.
stream_ended_ = true;
if (!decoder_thread_) {
// In case there is no WriteInputBuffer() call before WriteEndOfStream(),
// don't create the decoder thread and send the EOS frame directly.
decoder_status_cb_(kBufferFull, VideoFrame::CreateEOSFrame());
return;
}
decoder_thread_->job_queue()->Schedule(
std::bind(&VideoDecoder::DecodeEndOfStream, this));
}
void VideoDecoder::Reset() {
SB_DCHECK(BelongsToCurrentThread());
if (decoder_thread_) {
decoder_thread_->job_queue()->Schedule(
std::bind(&VideoDecoder::TeardownCodec, this));
// Join the thread to ensure that all callbacks in process are finished.
decoder_thread_.reset();
}
error_occured_ = false;
stream_ended_ = false;
CancelPendingJobs();
ScopedLock lock(decode_target_mutex_);
frames_ = std::queue<scoped_refptr<CpuVideoFrame>>();
}
void VideoDecoder::UpdateDecodeTarget_Locked(
const scoped_refptr<CpuVideoFrame>& frame) {
SbDecodeTarget decode_target = DecodeTargetCreate(
decode_target_graphics_context_provider_, frame, decode_target_);
// Lock only after the post to the renderer thread, to prevent deadlock.
decode_target_ = decode_target;
if (!SbDecodeTargetIsValid(decode_target)) {
SB_LOG(ERROR) << "Could not acquire a decode target from provider.";
}
}
void VideoDecoder::ReportError(const std::string& error_message) {
SB_DCHECK(decoder_thread_->job_queue()->BelongsToCurrentThread());
error_occured_ = true;
Schedule(std::bind(error_cb_, kSbPlayerErrorDecode, error_message));
}
void VideoDecoder::InitializeCodec() {
SB_DCHECK(decoder_thread_->job_queue()->BelongsToCurrentThread());
aom_codec_dec_cfg_t aom_config = {0};
aom_config.threads = 8;
aom_config.allow_lowbitdepth = 1;
context_.reset(new aom_codec_ctx_t());
aom_codec_err_t status =
aom_codec_dec_init(context_.get(), aom_codec_av1_dx(), &aom_config, 0);
if (status != AOM_CODEC_OK) {
SB_LOG(ERROR) << "aom_codec_dec_init() failed with " << status;
ReportError(
FormatString("aom_codec_dec_init() failed with status %d.", status));
context_.reset();
}
}
void VideoDecoder::TeardownCodec() {
SB_DCHECK(decoder_thread_->job_queue()->BelongsToCurrentThread());
if (context_) {
aom_codec_destroy(context_.get());
context_.reset();
}
if (output_mode_ == kSbPlayerOutputModeDecodeToTexture) {
SbDecodeTarget decode_target_to_release;
{
ScopedLock lock(decode_target_mutex_);
decode_target_to_release = decode_target_;
decode_target_ = kSbDecodeTargetInvalid;
}
if (SbDecodeTargetIsValid(decode_target_to_release)) {
DecodeTargetRelease(decode_target_graphics_context_provider_,
decode_target_to_release);
}
}
}
void VideoDecoder::DecodeOneBuffer(
const scoped_refptr<InputBuffer>& input_buffer) {
SB_DCHECK(decoder_thread_->job_queue()->BelongsToCurrentThread());
SB_DCHECK(input_buffer);
const SbMediaVideoSampleInfo& sample_info = input_buffer->video_sample_info();
if (!context_ || sample_info.frame_width != current_frame_width_ ||
sample_info.frame_height != current_frame_height_) {
current_frame_width_ = sample_info.frame_width;
current_frame_height_ = sample_info.frame_height;
TeardownCodec();
InitializeCodec();
}
SB_DCHECK(context_);
SbTime timestamp = input_buffer->timestamp();
aom_codec_err_t status = aom_codec_decode(
context_.get(), input_buffer->data(), input_buffer->size(), &timestamp);
if (status != AOM_CODEC_OK) {
SB_DLOG(ERROR) << "aom_codec_decode() failed, status=" << status;
ReportError(
FormatString("aom_codec_decode() failed with status %d.", status));
return;
}
// Gets pointer to decoded data.
aom_codec_iter_t dummy = NULL;
const aom_image_t* aom_image = aom_codec_get_frame(context_.get(), &dummy);
if (!aom_image) {
return;
}
if (aom_image->user_priv != &timestamp) {
SB_DLOG(ERROR) << "Invalid output timestamp.";
ReportError("Invalid output timestamp.");
return;
}
if (aom_image->fmt != AOM_IMG_FMT_YV12) {
SB_DCHECK(aom_image->fmt == AOM_IMG_FMT_I420 ||
aom_image->fmt == AOM_IMG_FMT_I42016)
<< "Unsupported aom_image->fmt: " << aom_image->fmt;
if (aom_image->fmt != AOM_IMG_FMT_I420 &&
aom_image->fmt != AOM_IMG_FMT_I42016) {
ReportError(
FormatString("Unsupported aom_image->fmt: %d.", aom_image->fmt));
return;
}
}
if (aom_image->bit_depth != 8 && aom_image->bit_depth != 10 &&
aom_image->bit_depth != 12) {
SB_DLOG(ERROR) << "Unsupported bit depth " << aom_image->bit_depth;
ReportError(
FormatString("Unsupported bit depth %d.", aom_image->bit_depth));
return;
}
SB_DCHECK(aom_image->stride[AOM_PLANE_Y] ==
aom_image->stride[AOM_PLANE_U] * 2);
SB_DCHECK(aom_image->stride[AOM_PLANE_U] == aom_image->stride[AOM_PLANE_V]);
SB_DCHECK(aom_image->planes[AOM_PLANE_Y] < aom_image->planes[AOM_PLANE_U]);
SB_DCHECK(aom_image->planes[AOM_PLANE_U] < aom_image->planes[AOM_PLANE_V]);
if (aom_image->stride[AOM_PLANE_Y] != aom_image->stride[AOM_PLANE_U] * 2 ||
aom_image->stride[AOM_PLANE_U] != aom_image->stride[AOM_PLANE_V] ||
aom_image->planes[AOM_PLANE_Y] >= aom_image->planes[AOM_PLANE_U] ||
aom_image->planes[AOM_PLANE_U] >= aom_image->planes[AOM_PLANE_V]) {
ReportError("Unsupported yuv plane format.");
return;
}
// Create a VideoFrame from decoded frame data. The data is in YV12 format.
// Each component of a pixel takes one byte and they are in their own planes.
// UV planes have half resolution both vertically and horizontally.
scoped_refptr<CpuVideoFrame> frame = CpuVideoFrame::CreateYV12Frame(
aom_image->bit_depth, current_frame_width_, current_frame_height_,
aom_image->stride[AOM_PLANE_Y], timestamp, aom_image->planes[AOM_PLANE_Y],
aom_image->planes[AOM_PLANE_U], aom_image->planes[AOM_PLANE_V]);
if (output_mode_ == kSbPlayerOutputModeDecodeToTexture) {
ScopedLock lock(decode_target_mutex_);
frames_.push(frame);
}
Schedule(std::bind(decoder_status_cb_, kNeedMoreInput, frame));
}
void VideoDecoder::DecodeEndOfStream() {
SB_DCHECK(decoder_thread_->job_queue()->BelongsToCurrentThread());
// TODO: Flush the frames inside the decoder, though this is not required
// for vp9 in most cases.
Schedule(
std::bind(decoder_status_cb_, kBufferFull, VideoFrame::CreateEOSFrame()));
}
// When in decode-to-texture mode, this returns the current decoded video frame.
SbDecodeTarget VideoDecoder::GetCurrentDecodeTarget() {
SB_DCHECK(output_mode_ == kSbPlayerOutputModeDecodeToTexture);
// We must take a lock here since this function can be called from a
// separate thread.
ScopedLock lock(decode_target_mutex_);
while (frames_.size() > 1 && frames_.front()->HasOneRef()) {
frames_.pop();
}
if (!frames_.empty()) {
UpdateDecodeTarget_Locked(frames_.front());
}
if (SbDecodeTargetIsValid(decode_target_)) {
// Make a disposable copy, since the state is internally reused by this
// class (to avoid recreating GL objects).
return DecodeTargetCopy(decode_target_);
} else {
return kSbDecodeTargetInvalid;
}
}
} // namespace aom
} // namespace shared
} // namespace starboard