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5a79d28eba61aea39558a492fb4c0ff4fef427ba
platform-external-webrtc/sdk/android/src/jni/video_encoder_wrapper.cc
Jiwon Jung 5a79d28eba Require 16x16 alignment when using HardwareVideoEncoder for encoding. 
It seems the Android CTS tests only verify that 16x16 aligned resolutions
are supported.

This change checks the validity of input frame's size when initialing
or encoding processes are about to start using H/W MediaCodec.

This change has additional APIs to retrieve
|requested_resolution_alignment| and |apply_alignment_to_all_simulcast_layers|
from JAVA VideoEncoder class and its inherited classes. HardwareVideoEncoder
using MediaCodec has values of 16 and true for above variables.

Bug: webrtc:13089
Change-Id: I0c4ebf94eb36da29c2e384a3edf85b82e779b7f9
Reviewed-on: https://webrtc-review.googlesource.com/c/src/+/229460
Reviewed-by: Sergey Silkin <ssilkin@webrtc.org>
Reviewed-by: Åsa Persson <asapersson@webrtc.org>
Commit-Queue: Sergey Silkin <ssilkin@webrtc.org>
Cr-Commit-Position: refs/heads/main@{#35169}
2021-10-08 13:15:12 +00:00

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/*
* Copyright 2017 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "sdk/android/src/jni/video_encoder_wrapper.h"
#include <utility>
#include "common_video/h264/h264_common.h"
#include "modules/video_coding/include/video_codec_interface.h"
#include "modules/video_coding/include/video_error_codes.h"
#include "modules/video_coding/svc/scalable_video_controller_no_layering.h"
#include "modules/video_coding/utility/vp8_header_parser.h"
#include "modules/video_coding/utility/vp9_uncompressed_header_parser.h"
#include "rtc_base/logging.h"
#include "rtc_base/task_utils/to_queued_task.h"
#include "rtc_base/time_utils.h"
#include "sdk/android/generated_video_jni/VideoEncoderWrapper_jni.h"
#include "sdk/android/generated_video_jni/VideoEncoder_jni.h"
#include "sdk/android/native_api/jni/class_loader.h"
#include "sdk/android/native_api/jni/java_types.h"
#include "sdk/android/src/jni/encoded_image.h"
#include "sdk/android/src/jni/video_codec_status.h"
#include "sdk/android/src/jni/video_frame.h"
namespace webrtc {
namespace jni {
VideoEncoderWrapper::VideoEncoderWrapper(JNIEnv* jni,
const JavaRef<jobject>& j_encoder)
: encoder_(jni, j_encoder), int_array_class_(GetClass(jni, "[I")) {
initialized_ = false;
num_resets_ = 0;
// Fetch and update encoder info.
UpdateEncoderInfo(jni);
}
VideoEncoderWrapper::~VideoEncoderWrapper() = default;
int VideoEncoderWrapper::InitEncode(const VideoCodec* codec_settings,
const Settings& settings) {
JNIEnv* jni = AttachCurrentThreadIfNeeded();
codec_settings_ = *codec_settings;
capabilities_ = settings.capabilities;
number_of_cores_ = settings.number_of_cores;
num_resets_ = 0;
return InitEncodeInternal(jni);
}
int32_t VideoEncoderWrapper::InitEncodeInternal(JNIEnv* jni) {
bool automatic_resize_on;
switch (codec_settings_.codecType) {
case kVideoCodecVP8:
automatic_resize_on = codec_settings_.VP8()->automaticResizeOn;
break;
case kVideoCodecVP9:
automatic_resize_on = codec_settings_.VP9()->automaticResizeOn;
gof_.SetGofInfoVP9(TemporalStructureMode::kTemporalStructureMode1);
gof_idx_ = 0;
break;
default:
automatic_resize_on = true;
}
RTC_DCHECK(capabilities_);
ScopedJavaLocalRef<jobject> capabilities =
Java_Capabilities_Constructor(jni, capabilities_->loss_notification);
ScopedJavaLocalRef<jobject> settings = Java_Settings_Constructor(
jni, number_of_cores_, codec_settings_.width, codec_settings_.height,
static_cast<int>(codec_settings_.startBitrate),
static_cast<int>(codec_settings_.maxFramerate),
static_cast<int>(codec_settings_.numberOfSimulcastStreams),
automatic_resize_on, capabilities);
ScopedJavaLocalRef<jobject> callback =
Java_VideoEncoderWrapper_createEncoderCallback(jni,
jlongFromPointer(this));
int32_t status = JavaToNativeVideoCodecStatus(
jni, Java_VideoEncoder_initEncode(jni, encoder_, settings, callback));
RTC_LOG(LS_INFO) << "initEncode: " << status;
// Some encoder's properties depend on settings and may change after
// initialization.
UpdateEncoderInfo(jni);
if (status == WEBRTC_VIDEO_CODEC_OK) {
initialized_ = true;
}
return status;
}
void VideoEncoderWrapper::UpdateEncoderInfo(JNIEnv* jni) {
encoder_info_.supports_native_handle = true;
encoder_info_.has_internal_source = false;
encoder_info_.implementation_name = JavaToStdString(
jni, Java_VideoEncoder_getImplementationName(jni, encoder_));
encoder_info_.is_hardware_accelerated =
Java_VideoEncoder_isHardwareEncoder(jni, encoder_);
encoder_info_.scaling_settings = GetScalingSettingsInternal(jni);
encoder_info_.resolution_bitrate_limits = JavaToNativeResolutionBitrateLimits(
jni, Java_VideoEncoder_getResolutionBitrateLimits(jni, encoder_));
EncoderInfo info = GetEncoderInfoInternal(jni);
encoder_info_.requested_resolution_alignment =
info.requested_resolution_alignment;
encoder_info_.apply_alignment_to_all_simulcast_layers =
info.apply_alignment_to_all_simulcast_layers;
}
int32_t VideoEncoderWrapper::RegisterEncodeCompleteCallback(
EncodedImageCallback* callback) {
callback_ = callback;
return WEBRTC_VIDEO_CODEC_OK;
}
int32_t VideoEncoderWrapper::Release() {
JNIEnv* jni = AttachCurrentThreadIfNeeded();
int32_t status = JavaToNativeVideoCodecStatus(
jni, Java_VideoEncoder_release(jni, encoder_));
RTC_LOG(LS_INFO) << "release: " << status;
{
MutexLock lock(&frame_extra_infos_lock_);
frame_extra_infos_.clear();
}
initialized_ = false;
return status;
}
int32_t VideoEncoderWrapper::Encode(
const VideoFrame& frame,
const std::vector<VideoFrameType>* frame_types) {
if (!initialized_) {
// Most likely initializing the codec failed.
return WEBRTC_VIDEO_CODEC_FALLBACK_SOFTWARE;
}
JNIEnv* jni = AttachCurrentThreadIfNeeded();
// Construct encode info.
ScopedJavaLocalRef<jobjectArray> j_frame_types =
NativeToJavaFrameTypeArray(jni, *frame_types);
ScopedJavaLocalRef<jobject> encode_info =
Java_EncodeInfo_Constructor(jni, j_frame_types);
FrameExtraInfo info;
info.capture_time_ns = frame.timestamp_us() * rtc::kNumNanosecsPerMicrosec;
info.timestamp_rtp = frame.timestamp();
{
MutexLock lock(&frame_extra_infos_lock_);
frame_extra_infos_.push_back(info);
}
ScopedJavaLocalRef<jobject> j_frame = NativeToJavaVideoFrame(jni, frame);
ScopedJavaLocalRef<jobject> ret =
Java_VideoEncoder_encode(jni, encoder_, j_frame, encode_info);
ReleaseJavaVideoFrame(jni, j_frame);
return HandleReturnCode(jni, ret, "encode");
}
void VideoEncoderWrapper::SetRates(const RateControlParameters& rc_parameters) {
JNIEnv* jni = AttachCurrentThreadIfNeeded();
ScopedJavaLocalRef<jobject> j_rc_parameters =
ToJavaRateControlParameters(jni, rc_parameters);
ScopedJavaLocalRef<jobject> ret =
Java_VideoEncoder_setRates(jni, encoder_, j_rc_parameters);
HandleReturnCode(jni, ret, "setRates");
}
VideoEncoder::EncoderInfo VideoEncoderWrapper::GetEncoderInfo() const {
return encoder_info_;
}
VideoEncoderWrapper::ScalingSettings
VideoEncoderWrapper::GetScalingSettingsInternal(JNIEnv* jni) const {
ScopedJavaLocalRef<jobject> j_scaling_settings =
Java_VideoEncoder_getScalingSettings(jni, encoder_);
bool isOn =
Java_VideoEncoderWrapper_getScalingSettingsOn(jni, j_scaling_settings);
if (!isOn)
return ScalingSettings::kOff;
absl::optional<int> low = JavaToNativeOptionalInt(
jni,
Java_VideoEncoderWrapper_getScalingSettingsLow(jni, j_scaling_settings));
absl::optional<int> high = JavaToNativeOptionalInt(
jni,
Java_VideoEncoderWrapper_getScalingSettingsHigh(jni, j_scaling_settings));
if (low && high)
return ScalingSettings(*low, *high);
switch (codec_settings_.codecType) {
case kVideoCodecVP8: {
// Same as in vp8_impl.cc.
static const int kLowVp8QpThreshold = 29;
static const int kHighVp8QpThreshold = 95;
return ScalingSettings(low.value_or(kLowVp8QpThreshold),
high.value_or(kHighVp8QpThreshold));
}
case kVideoCodecVP9: {
// QP is obtained from VP9-bitstream, so the QP corresponds to the
// bitstream range of [0, 255] and not the user-level range of [0,63].
static const int kLowVp9QpThreshold = 96;
static const int kHighVp9QpThreshold = 185;
return VideoEncoder::ScalingSettings(kLowVp9QpThreshold,
kHighVp9QpThreshold);
}
case kVideoCodecH264: {
// Same as in h264_encoder_impl.cc.
static const int kLowH264QpThreshold = 24;
static const int kHighH264QpThreshold = 37;
return ScalingSettings(low.value_or(kLowH264QpThreshold),
high.value_or(kHighH264QpThreshold));
}
default:
return ScalingSettings::kOff;
}
}
VideoEncoder::EncoderInfo VideoEncoderWrapper::GetEncoderInfoInternal(
JNIEnv* jni) const {
ScopedJavaLocalRef<jobject> j_encoder_info =
Java_VideoEncoder_getEncoderInfo(jni, encoder_);
jint requested_resolution_alignment =
Java_EncoderInfo_getRequestedResolutionAlignment(jni, j_encoder_info);
jboolean apply_alignment_to_all_simulcast_layers =
Java_EncoderInfo_getApplyAlignmentToAllSimulcastLayers(jni,
j_encoder_info);
VideoEncoder::EncoderInfo info;
info.requested_resolution_alignment = requested_resolution_alignment;
info.apply_alignment_to_all_simulcast_layers =
apply_alignment_to_all_simulcast_layers;
return info;
}
void VideoEncoderWrapper::OnEncodedFrame(
JNIEnv* jni,
const JavaRef<jobject>& j_encoded_image) {
EncodedImage frame = JavaToNativeEncodedImage(jni, j_encoded_image);
int64_t capture_time_ns =
GetJavaEncodedImageCaptureTimeNs(jni, j_encoded_image);
// Encoded frames are delivered in the order received, but some of them
// may be dropped, so remove records of frames older than the current
// one.
//
// NOTE: if the current frame is associated with Encoder A, in the time
// since this frame was received, Encoder A could have been
// Release()'ed, Encoder B InitEncode()'ed (due to reuse of Encoder A),
// and frames received by Encoder B. Thus there may be frame_extra_infos
// entries that don't belong to us, and we need to be careful not to
// remove them. Removing only those entries older than the current frame
// provides this guarantee.
FrameExtraInfo frame_extra_info;
{
MutexLock lock(&frame_extra_infos_lock_);
while (!frame_extra_infos_.empty() &&
frame_extra_infos_.front().capture_time_ns < capture_time_ns) {
frame_extra_infos_.pop_front();
}
if (frame_extra_infos_.empty() ||
frame_extra_infos_.front().capture_time_ns != capture_time_ns) {
RTC_LOG(LS_WARNING)
<< "Java encoder produced an unexpected frame with timestamp: "
<< capture_time_ns;
return;
}
frame_extra_info = frame_extra_infos_.front();
frame_extra_infos_.pop_front();
}
// This is a bit subtle. The `frame` variable from the lambda capture is
// const. Which implies that (i) we need to make a copy to be able to
// write to the metadata, and (ii) we should avoid using the .data()
// method (including implicit conversion to ArrayView) on the non-const
// copy, since that would trigget a copy operation on the underlying
// CopyOnWriteBuffer.
EncodedImage frame_copy = frame;
frame_copy.SetTimestamp(frame_extra_info.timestamp_rtp);
frame_copy.capture_time_ms_ = capture_time_ns / rtc::kNumNanosecsPerMillisec;
if (frame_copy.qp_ < 0)
frame_copy.qp_ = ParseQp(frame);
CodecSpecificInfo info(ParseCodecSpecificInfo(frame));
callback_->OnEncodedImage(frame_copy, &info);
}
int32_t VideoEncoderWrapper::HandleReturnCode(JNIEnv* jni,
const JavaRef<jobject>& j_value,
const char* method_name) {
int32_t value = JavaToNativeVideoCodecStatus(jni, j_value);
if (value >= 0) { // OK or NO_OUTPUT
return value;
}
RTC_LOG(LS_WARNING) << method_name << ": " << value;
if (value == WEBRTC_VIDEO_CODEC_FALLBACK_SOFTWARE ||
value == WEBRTC_VIDEO_CODEC_UNINITIALIZED) { // Critical error.
RTC_LOG(LS_WARNING) << "Java encoder requested software fallback.";
return WEBRTC_VIDEO_CODEC_FALLBACK_SOFTWARE;
}
// Try resetting the codec.
if (Release() == WEBRTC_VIDEO_CODEC_OK &&
InitEncodeInternal(jni) == WEBRTC_VIDEO_CODEC_OK) {
RTC_LOG(LS_WARNING) << "Reset Java encoder.";
return WEBRTC_VIDEO_CODEC_ERROR;
}
RTC_LOG(LS_WARNING) << "Unable to reset Java encoder.";
return WEBRTC_VIDEO_CODEC_FALLBACK_SOFTWARE;
}
int VideoEncoderWrapper::ParseQp(rtc::ArrayView<const uint8_t> buffer) {
int qp;
bool success;
switch (codec_settings_.codecType) {
case kVideoCodecVP8:
success = vp8::GetQp(buffer.data(), buffer.size(), &qp);
break;
case kVideoCodecVP9:
success = vp9::GetQp(buffer.data(), buffer.size(), &qp);
break;
case kVideoCodecH264:
h264_bitstream_parser_.ParseBitstream(buffer);
qp = h264_bitstream_parser_.GetLastSliceQp().value_or(-1);
success = (qp >= 0);
break;
default: // Default is to not provide QP.
success = false;
break;
}
return success ? qp : -1; // -1 means unknown QP.
}
CodecSpecificInfo VideoEncoderWrapper::ParseCodecSpecificInfo(
const EncodedImage& frame) {
const bool key_frame = frame._frameType == VideoFrameType::kVideoFrameKey;
CodecSpecificInfo info;
// For stream with scalability, NextFrameConfig should be called before
// encoding and used to configure encoder, then passed here e.g. via
// FrameExtraInfo structure. But while this encoder wrapper uses only trivial
// scalability, NextFrameConfig can be called here.
auto layer_frames = svc_controller_.NextFrameConfig(/*reset=*/key_frame);
RTC_DCHECK_EQ(layer_frames.size(), 1);
info.generic_frame_info = svc_controller_.OnEncodeDone(layer_frames[0]);
if (key_frame) {
info.template_structure = svc_controller_.DependencyStructure();
info.template_structure->resolutions = {
RenderResolution(frame._encodedWidth, frame._encodedHeight)};
}
info.codecType = codec_settings_.codecType;
switch (codec_settings_.codecType) {
case kVideoCodecVP8:
info.codecSpecific.VP8.nonReference = false;
info.codecSpecific.VP8.temporalIdx = kNoTemporalIdx;
info.codecSpecific.VP8.layerSync = false;
info.codecSpecific.VP8.keyIdx = kNoKeyIdx;
break;
case kVideoCodecVP9:
if (key_frame) {
gof_idx_ = 0;
}
info.codecSpecific.VP9.inter_pic_predicted = key_frame ? false : true;
info.codecSpecific.VP9.flexible_mode = false;
info.codecSpecific.VP9.ss_data_available = key_frame ? true : false;
info.codecSpecific.VP9.temporal_idx = kNoTemporalIdx;
info.codecSpecific.VP9.temporal_up_switch = true;
info.codecSpecific.VP9.inter_layer_predicted = false;
info.codecSpecific.VP9.gof_idx =
static_cast<uint8_t>(gof_idx_++ % gof_.num_frames_in_gof);
info.codecSpecific.VP9.num_spatial_layers = 1;
info.codecSpecific.VP9.first_frame_in_picture = true;
info.codecSpecific.VP9.spatial_layer_resolution_present = false;
if (info.codecSpecific.VP9.ss_data_available) {
info.codecSpecific.VP9.spatial_layer_resolution_present = true;
info.codecSpecific.VP9.width[0] = frame._encodedWidth;
info.codecSpecific.VP9.height[0] = frame._encodedHeight;
info.codecSpecific.VP9.gof.CopyGofInfoVP9(gof_);
}
break;
default:
break;
}
return info;
}
ScopedJavaLocalRef<jobject> VideoEncoderWrapper::ToJavaBitrateAllocation(
JNIEnv* jni,
const VideoBitrateAllocation& allocation) {
ScopedJavaLocalRef<jobjectArray> j_allocation_array(
jni, jni->NewObjectArray(kMaxSpatialLayers, int_array_class_.obj(),
nullptr /* initial */));
for (int spatial_i = 0; spatial_i < kMaxSpatialLayers; ++spatial_i) {
std::array<int32_t, kMaxTemporalStreams> spatial_layer;
for (int temporal_i = 0; temporal_i < kMaxTemporalStreams; ++temporal_i) {
spatial_layer[temporal_i] = allocation.GetBitrate(spatial_i, temporal_i);
}
ScopedJavaLocalRef<jintArray> j_array_spatial_layer =
NativeToJavaIntArray(jni, spatial_layer);
jni->SetObjectArrayElement(j_allocation_array.obj(), spatial_i,
j_array_spatial_layer.obj());
}
return Java_BitrateAllocation_Constructor(jni, j_allocation_array);
}
ScopedJavaLocalRef<jobject> VideoEncoderWrapper::ToJavaRateControlParameters(
JNIEnv* jni,
const VideoEncoder::RateControlParameters& rc_parameters) {
ScopedJavaLocalRef<jobject> j_bitrate_allocation =
ToJavaBitrateAllocation(jni, rc_parameters.bitrate);
return Java_RateControlParameters_Constructor(jni, j_bitrate_allocation,
rc_parameters.framerate_fps);
}
std::unique_ptr<VideoEncoder> JavaToNativeVideoEncoder(
JNIEnv* jni,
const JavaRef<jobject>& j_encoder) {
const jlong native_encoder =
Java_VideoEncoder_createNativeVideoEncoder(jni, j_encoder);
VideoEncoder* encoder;
if (native_encoder == 0) {
encoder = new VideoEncoderWrapper(jni, j_encoder);
} else {
encoder = reinterpret_cast<VideoEncoder*>(native_encoder);
}
return std::unique_ptr<VideoEncoder>(encoder);
}
std::vector<VideoEncoder::ResolutionBitrateLimits>
JavaToNativeResolutionBitrateLimits(
JNIEnv* jni,
const JavaRef<jobjectArray>& j_bitrate_limits_array) {
std::vector<VideoEncoder::ResolutionBitrateLimits> resolution_bitrate_limits;
const jsize array_length = jni->GetArrayLength(j_bitrate_limits_array.obj());
for (int i = 0; i < array_length; ++i) {
ScopedJavaLocalRef<jobject> j_bitrate_limits = ScopedJavaLocalRef<jobject>(
jni, jni->GetObjectArrayElement(j_bitrate_limits_array.obj(), i));
jint frame_size_pixels =
Java_ResolutionBitrateLimits_getFrameSizePixels(jni, j_bitrate_limits);
jint min_start_bitrate_bps =
Java_ResolutionBitrateLimits_getMinStartBitrateBps(jni,
j_bitrate_limits);
jint min_bitrate_bps =
Java_ResolutionBitrateLimits_getMinBitrateBps(jni, j_bitrate_limits);
jint max_bitrate_bps =
Java_ResolutionBitrateLimits_getMaxBitrateBps(jni, j_bitrate_limits);
resolution_bitrate_limits.push_back(VideoEncoder::ResolutionBitrateLimits(
frame_size_pixels, min_start_bitrate_bps, min_bitrate_bps,
max_bitrate_bps));
}
return resolution_bitrate_limits;
}
} // namespace jni
} // namespace webrtc
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