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LeafOS / LeafOS-Project / android_frameworks_av / 7c840b6ec8c491194a1bda61e95bae2027f1093a / . / media / codec2 / sfplugin / C2OMXNode.cpp
blob: bba022b4ac97fb26cd9d09a79c8111622aceba07 [file] [log] [blame]
/*
* Copyright 2018, The Android Open Source Project
*
* 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.
*/
#ifdef __LP64__
#define OMX_ANDROID_COMPILE_AS_32BIT_ON_64BIT_PLATFORMS
#endif
//#define LOG_NDEBUG 0
#define LOG_TAG "C2OMXNode"
#include <log/log.h>
#include <C2AllocatorGralloc.h>
#include <C2BlockInternal.h>
#include <C2Component.h>
#include <C2Config.h>
#include <C2PlatformSupport.h>
#include <OMX_Component.h>
#include <OMX_Index.h>
#include <OMX_IndexExt.h>
#include <android/fdsan.h>
#include <media/stagefright/foundation/ColorUtils.h>
#include <media/stagefright/omx/OMXUtils.h>
#include <media/stagefright/MediaErrors.h>
#include <ui/Fence.h>
#include <ui/GraphicBuffer.h>
#include <utils/Thread.h>
#include "utils/Codec2Mapper.h"
#include "C2OMXNode.h"
#include "Codec2Buffer.h"
namespace android {
namespace {
constexpr OMX_U32 kPortIndexInput = 0;
class Buffer2D : public C2Buffer {
public:
explicit Buffer2D(C2ConstGraphicBlock block) : C2Buffer({ block }) {}
};
} // namespace
class C2OMXNode::QueueThread : public Thread {
public:
QueueThread() : Thread(false) {}
~QueueThread() override = default;
void queue(
const std::shared_ptr<Codec2Client::Component> &comp,
int fenceFd,
std::unique_ptr<C2Work> &&work,
android::base::unique_fd &&fd0,
android::base::unique_fd &&fd1) {
Mutexed<Jobs>::Locked jobs(mJobs);
auto it = jobs->queues.try_emplace(comp, comp).first;
it->second.workList.emplace_back(
std::move(work), fenceFd, std::move(fd0), std::move(fd1));
jobs->cond.broadcast();
}
void setDataspace(android_dataspace dataspace) {
Mutexed<Jobs>::Locked jobs(mJobs);
ColorUtils::convertDataSpaceToV0(dataspace);
jobs->configUpdate.emplace_back(new C2StreamDataSpaceInfo::input(0u, dataspace));
int32_t standard;
int32_t transfer;
int32_t range;
ColorUtils::getColorConfigFromDataSpace(dataspace, &range, &standard, &transfer);
std::unique_ptr<C2StreamColorAspectsInfo::input> colorAspects =
std::make_unique<C2StreamColorAspectsInfo::input>(0u);
if (C2Mapper::map(standard, &colorAspects->primaries, &colorAspects->matrix)
&& C2Mapper::map(transfer, &colorAspects->transfer)
&& C2Mapper::map(range, &colorAspects->range)) {
jobs->configUpdate.push_back(std::move(colorAspects));
}
}
void setPriority(int priority) {
androidSetThreadPriority(getTid(), priority);
}
protected:
bool threadLoop() override {
constexpr nsecs_t kIntervalNs = nsecs_t(10) * 1000 * 1000; // 10ms
constexpr nsecs_t kWaitNs = kIntervalNs * 2;
for (int i = 0; i < 2; ++i) {
Mutexed<Jobs>::Locked jobs(mJobs);
nsecs_t nowNs = systemTime();
bool queued = false;
for (auto it = jobs->queues.begin(); it != jobs->queues.end(); ) {
Queue &queue = it->second;
if (queue.workList.empty()
|| (queue.lastQueuedTimestampNs != 0 &&
nowNs - queue.lastQueuedTimestampNs < kIntervalNs)) {
++it;
continue;
}
std::shared_ptr<Codec2Client::Component> comp = queue.component.lock();
if (!comp) {
it = jobs->queues.erase(it);
continue;
}
std::list<std::unique_ptr<C2Work>> items;
std::vector<int> fenceFds;
std::vector<android::base::unique_fd> uniqueFds;
while (!queue.workList.empty()) {
items.push_back(std::move(queue.workList.front().work));
fenceFds.push_back(queue.workList.front().fenceFd);
uniqueFds.push_back(std::move(queue.workList.front().fd0));
uniqueFds.push_back(std::move(queue.workList.front().fd1));
queue.workList.pop_front();
}
for (const std::unique_ptr<C2Param> &param : jobs->configUpdate) {
items.front()->input.configUpdate.emplace_back(C2Param::Copy(*param));
}
jobs.unlock();
for (int fenceFd : fenceFds) {
sp<Fence> fence(new Fence(fenceFd));
fence->waitForever(LOG_TAG);
}
queue.lastQueuedTimestampNs = nowNs;
comp->queue(&items);
for (android::base::unique_fd &ufd : uniqueFds) {
(void)ufd.release();
}
jobs.lock();
it = jobs->queues.upper_bound(comp);
queued = true;
}
if (queued) {
jobs->configUpdate.clear();
return true;
}
if (i == 0) {
jobs.waitForConditionRelative(jobs->cond, kWaitNs);
}
}
return true;
}
private:
struct WorkFence {
WorkFence(std::unique_ptr<C2Work> &&w, int fd) : work(std::move(w)), fenceFd(fd) {}
WorkFence(
std::unique_ptr<C2Work> &&w,
int fd,
android::base::unique_fd &&uniqueFd0,
android::base::unique_fd &&uniqueFd1)
: work(std::move(w)),
fenceFd(fd),
fd0(std::move(uniqueFd0)),
fd1(std::move(uniqueFd1)) {}
std::unique_ptr<C2Work> work;
int fenceFd;
android::base::unique_fd fd0;
android::base::unique_fd fd1;
};
struct Queue {
Queue(const std::shared_ptr<Codec2Client::Component> &comp)
: component(comp), lastQueuedTimestampNs(0) {}
Queue(const Queue &) = delete;
Queue &operator =(const Queue &) = delete;
std::weak_ptr<Codec2Client::Component> component;
std::list<WorkFence> workList;
nsecs_t lastQueuedTimestampNs;
};
struct Jobs {
std::map<std::weak_ptr<Codec2Client::Component>,
Queue,
std::owner_less<std::weak_ptr<Codec2Client::Component>>> queues;
std::vector<std::unique_ptr<C2Param>> configUpdate;
Condition cond;
};
Mutexed<Jobs> mJobs;
};
C2OMXNode::C2OMXNode(const std::shared_ptr<Codec2Client::Component> &comp)
: mComp(comp), mFrameIndex(0), mWidth(0), mHeight(0), mUsage(0),
mAdjustTimestampGapUs(0), mFirstInputFrame(true),
mQueueThread(new QueueThread) {
android_fdsan_set_error_level(ANDROID_FDSAN_ERROR_LEVEL_WARN_ALWAYS);
mQueueThread->run("C2OMXNode", PRIORITY_AUDIO);
android_dataspace ds = HAL_DATASPACE_UNKNOWN;
mDataspace.lock().set(ds);
uint32_t pf = PIXEL_FORMAT_UNKNOWN;
mPixelFormat.lock().set(pf);
}
status_t C2OMXNode::freeNode() {
mComp.reset();
android_fdsan_set_error_level(ANDROID_FDSAN_ERROR_LEVEL_WARN_ONCE);
return mQueueThread->requestExitAndWait();
}
status_t C2OMXNode::sendCommand(OMX_COMMANDTYPE cmd, OMX_S32 param) {
if (cmd == OMX_CommandStateSet && param == OMX_StateLoaded) {
// Reset first input frame so if C2OMXNode is recycled, the timestamp does not become
// negative. This is a workaround for HW codecs that do not handle timestamp rollover.
mFirstInputFrame = true;
}
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::getParameter(OMX_INDEXTYPE index, void *params, size_t size) {
status_t err = ERROR_UNSUPPORTED;
switch ((uint32_t)index) {
case OMX_IndexParamConsumerUsageBits: {
OMX_U32 *usage = (OMX_U32 *)params;
*usage = mUsage;
err = OK;
break;
}
case OMX_IndexParamConsumerUsageBits64: {
OMX_U64 *usage = (OMX_U64 *)params;
*usage = mUsage;
err = OK;
break;
}
case OMX_IndexParamPortDefinition: {
if (size < sizeof(OMX_PARAM_PORTDEFINITIONTYPE)) {
return BAD_VALUE;
}
OMX_PARAM_PORTDEFINITIONTYPE *pDef = (OMX_PARAM_PORTDEFINITIONTYPE *)params;
if (pDef->nPortIndex != kPortIndexInput) {
break;
}
pDef->nBufferCountActual = 16;
// WORKAROUND: having more slots improve performance while consuming
// more memory. This is a temporary workaround to reduce memory for
// larger-than-4K scenario.
if (mWidth * mHeight > 4096 * 2340) {
std::shared_ptr<Codec2Client::Component> comp = mComp.lock();
C2PortActualDelayTuning::input inputDelay(0);
C2ActualPipelineDelayTuning pipelineDelay(0);
c2_status_t c2err = C2_NOT_FOUND;
if (comp) {
c2err = comp->query(
{&inputDelay, &pipelineDelay}, {}, C2_DONT_BLOCK, nullptr);
}
if (c2err == C2_OK || c2err == C2_BAD_INDEX) {
pDef->nBufferCountActual = 4;
pDef->nBufferCountActual += (inputDelay ? inputDelay.value : 0u);
pDef->nBufferCountActual += (pipelineDelay ? pipelineDelay.value : 0u);
}
}
pDef->eDomain = OMX_PortDomainVideo;
pDef->format.video.nFrameWidth = mWidth;
pDef->format.video.nFrameHeight = mHeight;
pDef->format.video.eColorFormat = OMX_COLOR_FormatAndroidOpaque;
err = OK;
break;
}
default:
break;
}
return err;
}
status_t C2OMXNode::setParameter(OMX_INDEXTYPE index, const void *params, size_t size) {
if (params == NULL) {
return BAD_VALUE;
}
switch ((uint32_t)index) {
case OMX_IndexParamMaxFrameDurationForBitrateControl:
// handle max/fixed frame duration control
if (size != sizeof(OMX_PARAM_U32TYPE)) {
return BAD_VALUE;
}
// The incoming number is an int32_t contained in OMX_U32.
mAdjustTimestampGapUs = (int32_t)((OMX_PARAM_U32TYPE*)params)->nU32;
return OK;
case OMX_IndexParamConsumerUsageBits:
if (size != sizeof(OMX_U32)) {
return BAD_VALUE;
}
mUsage = *((OMX_U32 *)params);
return OK;
case OMX_IndexParamConsumerUsageBits64:
if (size != sizeof(OMX_U64)) {
return BAD_VALUE;
}
mUsage = *((OMX_U64 *)params);
return OK;
}
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::getConfig(OMX_INDEXTYPE index, void *config, size_t size) {
(void)index;
(void)config;
(void)size;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::setConfig(OMX_INDEXTYPE index, const void *config, size_t size) {
(void)index;
(void)config;
(void)size;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::setPortMode(OMX_U32 portIndex, IOMX::PortMode mode) {
(void)portIndex;
(void)mode;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::prepareForAdaptivePlayback(
OMX_U32 portIndex, OMX_BOOL enable,
OMX_U32 maxFrameWidth, OMX_U32 maxFrameHeight) {
(void)portIndex;
(void)enable;
(void)maxFrameWidth;
(void)maxFrameHeight;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::configureVideoTunnelMode(
OMX_U32 portIndex, OMX_BOOL tunneled,
OMX_U32 audioHwSync, native_handle_t **sidebandHandle) {
(void)portIndex;
(void)tunneled;
(void)audioHwSync;
*sidebandHandle = nullptr;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::getGraphicBufferUsage(OMX_U32 portIndex, OMX_U32* usage) {
(void)portIndex;
*usage = 0;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::setInputSurface(const sp<IOMXBufferSource> &bufferSource) {
c2_status_t err = GetCodec2PlatformAllocatorStore()->fetchAllocator(
C2PlatformAllocatorStore::GRALLOC,
&mAllocator);
if (err != OK) {
return UNKNOWN_ERROR;
}
mBufferSource = bufferSource;
return OK;
}
status_t C2OMXNode::allocateSecureBuffer(
OMX_U32 portIndex, size_t size, buffer_id *buffer,
void **bufferData, sp<NativeHandle> *nativeHandle) {
(void)portIndex;
(void)size;
(void)nativeHandle;
*buffer = 0;
*bufferData = nullptr;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::useBuffer(
OMX_U32 portIndex, const OMXBuffer &omxBuf, buffer_id *buffer) {
(void)portIndex;
(void)omxBuf;
*buffer = 0;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::freeBuffer(OMX_U32 portIndex, buffer_id buffer) {
(void)portIndex;
(void)buffer;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::fillBuffer(
buffer_id buffer, const OMXBuffer &omxBuf, int fenceFd) {
(void)buffer;
(void)omxBuf;
(void)fenceFd;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::emptyBuffer(
buffer_id buffer, const OMXBuffer &omxBuf,
OMX_U32 flags, OMX_TICKS timestamp, int fenceFd) {
std::shared_ptr<Codec2Client::Component> comp = mComp.lock();
if (!comp) {
return NO_INIT;
}
uint32_t c2Flags = (flags & OMX_BUFFERFLAG_EOS)
? C2FrameData::FLAG_END_OF_STREAM : 0;
std::shared_ptr<C2GraphicBlock> block;
android::base::unique_fd fd0, fd1;
C2Handle *handle = nullptr;
if (omxBuf.mBufferType == OMXBuffer::kBufferTypeANWBuffer
&& omxBuf.mGraphicBuffer != nullptr) {
std::shared_ptr<C2GraphicAllocation> alloc;
handle = WrapNativeCodec2GrallocHandle(
omxBuf.mGraphicBuffer->handle,
omxBuf.mGraphicBuffer->width,
omxBuf.mGraphicBuffer->height,
omxBuf.mGraphicBuffer->format,
omxBuf.mGraphicBuffer->usage,
omxBuf.mGraphicBuffer->stride);
if (handle != nullptr) {
// unique_fd takes ownership of the fds, we'll get warning if these
// fds get closed by somebody else. Onwership will be released before
// we return, so that the fds get closed as usually when this function
// goes out of scope (when both items and block are gone).
native_handle_t *nativeHandle = reinterpret_cast<native_handle_t*>(handle);
fd0.reset(nativeHandle->numFds > 0 ? nativeHandle->data[0] : -1);
fd1.reset(nativeHandle->numFds > 1 ? nativeHandle->data[1] : -1);
}
c2_status_t err = mAllocator->priorGraphicAllocation(handle, &alloc);
if (err != OK) {
(void)fd0.release();
(void)fd1.release();
native_handle_close(handle);
native_handle_delete(handle);
return UNKNOWN_ERROR;
}
block = _C2BlockFactory::CreateGraphicBlock(alloc);
} else if (!(flags & OMX_BUFFERFLAG_EOS)) {
return BAD_VALUE;
}
std::unique_ptr<C2Work> work(new C2Work);
work->input.flags = (C2FrameData::flags_t)c2Flags;
work->input.ordinal.timestamp = timestamp;
// WORKAROUND: adjust timestamp based on gapUs
{
work->input.ordinal.customOrdinal = timestamp; // save input timestamp
if (mFirstInputFrame) {
// grab timestamps on first frame
mPrevInputTimestamp = timestamp;
mPrevCodecTimestamp = timestamp;
mFirstInputFrame = false;
} else if (mAdjustTimestampGapUs > 0) {
work->input.ordinal.timestamp =
mPrevCodecTimestamp
+ c2_min((timestamp - mPrevInputTimestamp).peek(), mAdjustTimestampGapUs);
} else if (mAdjustTimestampGapUs < 0) {
work->input.ordinal.timestamp = mPrevCodecTimestamp - mAdjustTimestampGapUs;
}
mPrevInputTimestamp = work->input.ordinal.customOrdinal;
mPrevCodecTimestamp = work->input.ordinal.timestamp;
ALOGV("adjusting %lld to %lld (gap=%lld)",
work->input.ordinal.customOrdinal.peekll(),
work->input.ordinal.timestamp.peekll(),
(long long)mAdjustTimestampGapUs);
}
work->input.ordinal.frameIndex = mFrameIndex++;
work->input.buffers.clear();
if (block) {
std::shared_ptr<C2Buffer> c2Buffer(
new Buffer2D(block->share(
C2Rect(block->width(), block->height()), ::C2Fence())));
work->input.buffers.push_back(c2Buffer);
std::shared_ptr<C2StreamHdrStaticInfo::input> staticInfo;
std::shared_ptr<C2StreamHdrDynamicMetadataInfo::input> dynamicInfo;
GetHdrMetadataFromGralloc4Handle(
block->handle(),
&staticInfo,
&dynamicInfo);
if (staticInfo && *staticInfo) {
c2Buffer->setInfo(staticInfo);
}
if (dynamicInfo && *dynamicInfo) {
c2Buffer->setInfo(dynamicInfo);
}
}
work->worklets.clear();
work->worklets.emplace_back(new C2Worklet);
mBufferIdsInUse.lock()->emplace(work->input.ordinal.frameIndex.peeku(), buffer);
mQueueThread->queue(comp, fenceFd, std::move(work), std::move(fd0), std::move(fd1));
return OK;
}
status_t C2OMXNode::getExtensionIndex(
const char *parameterName, OMX_INDEXTYPE *index) {
(void)parameterName;
*index = OMX_IndexMax;
return ERROR_UNSUPPORTED;
}
status_t C2OMXNode::dispatchMessage(const omx_message& msg) {
if (msg.type != omx_message::EVENT) {
return ERROR_UNSUPPORTED;
}
if (msg.u.event_data.event != OMX_EventDataSpaceChanged) {
return ERROR_UNSUPPORTED;
}
android_dataspace dataSpace = (android_dataspace)msg.u.event_data.data1;
uint32_t pixelFormat = msg.u.event_data.data3;
ALOGD("dataspace changed to %#x pixel format: %#x", dataSpace, pixelFormat);
mQueueThread->setDataspace(dataSpace);
mDataspace.lock().set(dataSpace);
mPixelFormat.lock().set(pixelFormat);
return OK;
}
sp<IOMXBufferSource> C2OMXNode::getSource() {
return mBufferSource;
}
void C2OMXNode::setFrameSize(uint32_t width, uint32_t height) {
mWidth = width;
mHeight = height;
}
void C2OMXNode::onInputBufferDone(c2_cntr64_t index) {
if (!mBufferSource) {
ALOGD("Buffer source not set (index=%llu)", index.peekull());
return;
}
int32_t bufferId = 0;
{
decltype(mBufferIdsInUse)::Locked bufferIds(mBufferIdsInUse);
auto it = bufferIds->find(index.peeku());
if (it == bufferIds->end()) {
ALOGV("Untracked input index %llu (maybe already removed)", index.peekull());
return;
}
bufferId = it->second;
(void)bufferIds->erase(it);
}
(void)mBufferSource->onInputBufferEmptied(bufferId, -1);
}
android_dataspace C2OMXNode::getDataspace() {
return *mDataspace.lock();
}
uint32_t C2OMXNode::getPixelFormat() {
return *mPixelFormat.lock();
}
void C2OMXNode::setPriority(int priority) {
mQueueThread->setPriority(priority);
}
} // namespace android