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/* SPDX-License-Identifier: LGPL-2.1-or-later */
/*
* Copyright (C) 2020, Google Inc.
*
* camera_stream.cpp - Camera HAL stream
*/
#include "camera_stream.h"
#include <errno.h>
#include <string.h>
#include <sys/mman.h>
#include <sys/poll.h>
#include <unistd.h>
#include <libcamera/formats.h>
#include "jpeg/post_processor_jpeg.h"
#include "yuv/post_processor_yuv.h"
#include "camera_buffer.h"
#include "camera_capabilities.h"
#include "camera_device.h"
#include "camera_metadata.h"
#include "frame_buffer_allocator.h"
#include "post_processor.h"
using namespace libcamera;
LOG_DECLARE_CATEGORY(HAL)
/*
* \class CameraStream
* \brief Map a camera3_stream_t to a StreamConfiguration
*
* The CameraStream class maps a camera3_stream_t provided by Android
* camera framework to a libcamera::StreamConfiguration.
*
* The StreamConfiguration is represented by its index as recorded in the
* CameraConfiguration and not by pointer as StreamConfiguration is subject to
* relocation.
*
* A single StreamConfiguration may be used to deliver one or more streams to
* the Android framework. The mapping type between a camera3 stream to a
* StreamConfiguration is described by the CameraStream::Type.
*
* CameraStream handles all the aspects of producing a stream with the size
* and format requested by the camera3 stream from the data produced by
* the associated libcamera::Stream, including the creation of the encoder
* and buffer allocation.
*/
CameraStream::CameraStream(CameraDevice *const cameraDevice,
CameraConfiguration *config, Type type,
camera3_stream_t *camera3Stream,
CameraStream *const sourceStream, unsigned int index)
: cameraDevice_(cameraDevice), config_(config), type_(type),
camera3Stream_(camera3Stream), sourceStream_(sourceStream),
index_(index)
{
}
CameraStream::CameraStream(CameraStream &&other) = default;
CameraStream::~CameraStream()
{
/*
* Manually delete buffers and then the allocator to make sure buffers
* are released while the allocator is still valid.
*/
allocatedBuffers_.clear();
allocator_.reset();
}
const StreamConfiguration &CameraStream::configuration() const
{
return config_->at(index_);
}
Stream *CameraStream::stream() const
{
return configuration().stream();
}
int CameraStream::configure()
{
if (type_ == Type::Internal || type_ == Type::Mapped) {
const PixelFormat outFormat =
cameraDevice_->capabilities()->toPixelFormat(camera3Stream_->format);
StreamConfiguration output = configuration();
output.pixelFormat = outFormat;
output.size.width = camera3Stream_->width;
output.size.height = camera3Stream_->height;
switch (outFormat) {
case formats::NV12:
postProcessor_ = std::make_unique<PostProcessorYuv>();
break;
case formats::MJPEG:
postProcessor_ = std::make_unique<PostProcessorJpeg>(cameraDevice_);
break;
default:
LOG(HAL, Error) << "Unsupported format: " << outFormat;
return -EINVAL;
}
int ret = postProcessor_->configure(configuration(), output);
if (ret)
return ret;
worker_ = std::make_unique<PostProcessorWorker>(postProcessor_.get());
postProcessor_->processComplete.connect(
this, [&](Camera3RequestDescriptor::StreamBuffer *streamBuffer,
PostProcessor::Status status) {
Camera3RequestDescriptor::Status bufferStatus;
if (status == PostProcessor::Status::Success)
bufferStatus = Camera3RequestDescriptor::Status::Success;
else
bufferStatus = Camera3RequestDescriptor::Status::Error;
cameraDevice_->streamProcessingComplete(streamBuffer,
bufferStatus);
});
worker_->start();
}
allocator_ = std::make_unique<PlatformFrameBufferAllocator>(cameraDevice_);
mutex_ = std::make_unique<Mutex>();
camera3Stream_->max_buffers = configuration().bufferCount;
return 0;
}
int CameraStream::waitFence(int fence)
{
/*
* \todo The implementation here is copied from camera_worker.cpp
* and both should be removed once libcamera is instrumented to handle
* fences waiting in the core.
*
* \todo Better characterize the timeout. Currently equal to the one
* used by the Rockchip Camera HAL on ChromeOS.
*/
constexpr unsigned int timeoutMs = 300;
struct pollfd fds = { fence, POLLIN, 0 };
do {
int ret = poll(&fds, 1, timeoutMs);
if (ret == 0)
return -ETIME;
if (ret > 0) {
if (fds.revents & (POLLERR | POLLNVAL))
return -EINVAL;
return 0;
}
} while (errno == EINTR || errno == EAGAIN);
return -errno;
}
int CameraStream::process(Camera3RequestDescriptor::StreamBuffer *streamBuffer)
{
ASSERT(type_ != Type::Direct);
/* Handle waiting on fences on the destination buffer. */
if (streamBuffer->fence.isValid()) {
int ret = waitFence(streamBuffer->fence.get());
if (ret < 0) {
LOG(HAL, Error) << "Failed waiting for fence: "
<< streamBuffer->fence.get() << ": "
<< strerror(-ret);
return ret;
}
streamBuffer->fence.reset();
}
const StreamConfiguration &output = configuration();
streamBuffer->dstBuffer = std::make_unique<CameraBuffer>(
*streamBuffer->camera3Buffer, output.pixelFormat, output.size,
PROT_READ | PROT_WRITE);
if (!streamBuffer->dstBuffer->isValid()) {
LOG(HAL, Error) << "Failed to create destination buffer";
return -EINVAL;
}
worker_->queueRequest(streamBuffer);
return 0;
}
void CameraStream::flush()
{
if (!postProcessor_)
return;
worker_->flush();
}
FrameBuffer *CameraStream::getBuffer()
{
if (!allocator_)
return nullptr;
MutexLocker locker(*mutex_);
if (buffers_.empty()) {
/*
* Use HAL_PIXEL_FORMAT_YCBCR_420_888 unconditionally.
*
* YCBCR_420 is the source format for both the JPEG and the YUV
* post-processors.
*
* \todo Store a reference to the format of the source stream
* instead of hardcoding.
*/
auto frameBuffer = allocator_->allocate(HAL_PIXEL_FORMAT_YCBCR_420_888,
configuration().size,
camera3Stream_->usage);
allocatedBuffers_.push_back(std::move(frameBuffer));
buffers_.emplace_back(allocatedBuffers_.back().get());
}
FrameBuffer *buffer = buffers_.back();
buffers_.pop_back();
return buffer;
}
void CameraStream::putBuffer(FrameBuffer *buffer)
{
if (!allocator_)
return;
MutexLocker locker(*mutex_);
buffers_.push_back(buffer);
}
/**
* \class CameraStream::PostProcessorWorker
* \brief Post-process a CameraStream in an internal thread
*
* If the association between CameraStream and camera3_stream_t dictated by
* CameraStream::Type is internal or mapped, the stream is generated by post
* processing of a libcamera stream. Such a request is queued to a
* PostProcessorWorker in CameraStream::process(). A queue of post-processing
* requests is maintained by the PostProcessorWorker and it will run the
* post-processing on an internal thread as soon as any request is available on
* its queue.
*/
CameraStream::PostProcessorWorker::PostProcessorWorker(PostProcessor *postProcessor)
: postProcessor_(postProcessor)
{
}
CameraStream::PostProcessorWorker::~PostProcessorWorker()
{
{
MutexLocker lock(mutex_);
state_ = State::Stopped;
}
cv_.notify_one();
wait();
}
void CameraStream::PostProcessorWorker::start()
{
{
MutexLocker lock(mutex_);
ASSERT(state_ != State::Running);
state_ = State::Running;
}
Thread::start();
}
void CameraStream::PostProcessorWorker::queueRequest(Camera3RequestDescriptor::StreamBuffer *dest)
{
{
MutexLocker lock(mutex_);
ASSERT(state_ == State::Running);
requests_.push(dest);
}
cv_.notify_one();
}
void CameraStream::PostProcessorWorker::run()
{
MutexLocker locker(mutex_);
while (1) {
cv_.wait(locker, [&]() LIBCAMERA_TSA_REQUIRES(mutex_) {
return state_ != State::Running || !requests_.empty();
});
if (state_ != State::Running)
break;
Camera3RequestDescriptor::StreamBuffer *streamBuffer = requests_.front();
requests_.pop();
locker.unlock();
postProcessor_->process(streamBuffer);
locker.lock();
}
if (state_ == State::Flushing) {
std::queue<Camera3RequestDescriptor::StreamBuffer *> requests =
std::move(requests_);
locker.unlock();
while (!requests.empty()) {
postProcessor_->processComplete.emit(
requests.front(), PostProcessor::Status::Error);
requests.pop();
}
locker.lock();
state_ = State::Stopped;
}
}
void CameraStream::PostProcessorWorker::flush()
{
MutexLocker lock(mutex_);
state_ = State::Flushing;
lock.unlock();
cv_.notify_one();
}
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