libcamera/jmondi/libcamera.git - Jacopo Mondi's clone of libcamera

Age	Commit message (Expand)	Author
2021-03-28	meson: Summarize which applications and adaptation layers are built	Laurent Pinchart
2021-02-23	libcamera: Enable vimc pipeline handler when tests are enabled	Laurent Pinchart
2021-02-04	subprojects: Add libyuv and built if -Dandroid=enabled	Hirokazu Honda
2021-01-20	libcamera: Use meson summary() function to summarize configuration	Laurent Pinchart
2020-12-30	meson: test: Simplify top level meson	Kieran Bingham
2020-11-03	libcamera: tracing: Implement tracing infrastructure	Paul Elder
2020-10-21	meson: Enable shadowed variable warning	Kieran Bingham
2020-10-20	meson: Enable -Wextra-semi for clang	Hirokazu Honda
2020-10-12	meson: Enable -Wno-psabi for gcc 9+	Tomi Valkeinen
2020-09-24	meson: Define python3 and python3-yaml required dependencies	Ezequiel Garcia
2020-09-24	meson: Bump meson version to 0.51	Ricardo Ribalda
2020-09-24	Documentation: Move all dependencies into features	Ricardo Ribalda
2020-09-24	meson: Process utils first	Kieran Bingham
2020-09-15	qcam: Add ViewFinderGL class to accelerate the format conversion	Show Liu
2020-09-07	meson: Provide build configuration summary	Kieran Bingham
2020-08-25	meson: Remove -Wno-unused-parameter	Laurent Pinchart
2020-08-25	meson: Switch to C++17	Laurent Pinchart
2020-06-15	meson: detect kernel version	Stéphane Cerveau
2020-05-13	licenses: License all meson files under CC0-1.0	Laurent Pinchart
2020-05-10	pkgconfig: Fix include directory path	Nicolas Dufresne
2020-05-01	libcamera: Set -Wno-psabi on gcc 7 and 8 for arm	Laurent Pinchart
2020-04-28	libcamera: utils: Add a function to retrieve the libcamera source tree	Laurent Pinchart
2020-02-13	meson.build: Silence the C99 designators warning	Laurent Pinchart
2020-01-17	meson: Bump required version to 0.47	Nicolas Dufresne
2020-01-14	meson.build: Switch to C++14	Laurent Pinchart
2019-11-26	libcamera: Print backtrace on fatal errors	Laurent Pinchart
2019-11-21	meson: Really define _FORTIFY_SOURCE for optimised builds	Laurent Pinchart
2019-08-22	meson: Rename 'tests' option to 'test'	Laurent Pinchart
2019-08-22	meson: Define _FORTIFY_SOURCE for optimised builds	Laurent Pinchart
2019-07-11	libcamera: skip auto version generation when building for Chromium OS	Paul Elder
2019-07-09	libcamera: Rework automatic version generation to avoid rebuilds	Laurent Pinchart
2019-07-04	libcamera: Auto generate version information	Kieran Bingham
2019-06-19	meson: Link against libc++ with compiling with clang	Laurent Pinchart
2019-05-23	meson: Fix coding style in meson.build files	Laurent Pinchart
2019-04-27	libcamera: Make libudev optional	Laurent Pinchart
2019-04-26	meson: check if secure_getenv() is present	Giulio Benetti
2019-04-03	meson: Re-order the optional components	Kieran Bingham
2019-03-20	meson: Provide options to disable test/docs	Kieran Bingham
2019-01-15	meson: Utilise default compiler options	Kieran Bingham
2019-01-01	meson: Shorten project description	Kieran Bingham
2018-12-13	build: Add 'std=c++11' cpp compiler flag	Jacopo Mondi
2018-12-12	Documentation: Generate source code documentation using Doxygen	Laurent Pinchart
2018-12-06	Overhaul the directory structure	Laurent Pinchart
2018-11-30	meson: Describe minimum meson version requirements	Kieran Bingham
2018-11-28	Documentation: Introduce sphinx documentation	Kieran Bingham
2018-11-27	build: Add project arguments	Kieran Bingham
2018-11-27	include: Install include files	Kieran Bingham
2018-11-20	utils: ipu3: Add IPU3 raw capture unpack utility	Laurent Pinchart
2018-10-24	build: Provide initial meson infrastructure	Kieran Bingham

/* SPDX-License-Identifier: LGPL-2.1-or-later */ /* * Copyright (C) 2019, Google Inc. * * ipu3.cpp - Pipeline handler for Intel IPU3 */ #include <algorithm> #include <iomanip> #include <memory> #include <queue> #include <vector> #include <linux/media-bus-format.h> #include <libcamera/camera.h> #include <libcamera/formats.h> #include <libcamera/request.h> #include <libcamera/stream.h> #include "libcamera/internal/camera_sensor.h" #include "libcamera/internal/device_enumerator.h" #include "libcamera/internal/log.h" #include "libcamera/internal/media_device.h" #include "libcamera/internal/pipeline_handler.h" #include "libcamera/internal/utils.h" #include "libcamera/internal/v4l2_controls.h" #include "libcamera/internal/v4l2_subdevice.h" #include "libcamera/internal/v4l2_videodevice.h" #include "cio2.h" namespace libcamera { LOG_DEFINE_CATEGORY(IPU3) class IPU3CameraData; class ImgUDevice { public: static constexpr unsigned int PAD_INPUT = 0; static constexpr unsigned int PAD_OUTPUT = 2; static constexpr unsigned int PAD_VF = 3; static constexpr unsigned int PAD_STAT = 4; /* ImgU output descriptor: group data specific to an ImgU output. */ struct ImgUOutput { V4L2VideoDevice *dev; unsigned int pad; std::string name; std::vector<std::unique_ptr<FrameBuffer>> buffers; }; ImgUDevice() : imgu_(nullptr), input_(nullptr) { output_.dev = nullptr; viewfinder_.dev = nullptr; stat_.dev = nullptr; } ~ImgUDevice() { delete imgu_; delete input_; delete output_.dev; delete viewfinder_.dev; delete stat_.dev; } int init(MediaDevice *media, unsigned int index); int configureInput(const Size &size, V4L2DeviceFormat *inputFormat); int configureOutput(ImgUOutput *output, const StreamConfiguration &cfg, V4L2DeviceFormat *outputFormat); int allocateBuffers(IPU3CameraData *data, unsigned int bufferCount); void freeBuffers(IPU3CameraData *data); int start(); int stop(); int linkSetup(const std::string &source, unsigned int sourcePad, const std::string &sink, unsigned int sinkPad, bool enable); int enableLinks(bool enable); unsigned int index_; std::string name_; MediaDevice *media_; V4L2Subdevice *imgu_; V4L2VideoDevice *input_; ImgUOutput output_; ImgUOutput viewfinder_; ImgUOutput stat_; /* \todo Add param video device for 3A tuning */ }; class IPU3Stream : public Stream { public: IPU3Stream() : active_(false), raw_(false), device_(nullptr) { } bool active_; bool raw_; std::string name_; ImgUDevice::ImgUOutput *device_; }; class IPU3CameraData : public CameraData { public: IPU3CameraData(PipelineHandler *pipe) : CameraData(pipe) { } void imguOutputBufferReady(FrameBuffer *buffer); void imguInputBufferReady(FrameBuffer *buffer); void cio2BufferReady(FrameBuffer *buffer); CIO2Device cio2_; ImgUDevice *imgu_; IPU3Stream outStream_; IPU3Stream vfStream_; IPU3Stream rawStream_; }; class IPU3CameraConfiguration : public CameraConfiguration { public: IPU3CameraConfiguration(Camera *camera, IPU3CameraData *data); Status validate() override; const StreamConfiguration &cio2Format() const { return cio2Configuration_; }; const std::vector<const IPU3Stream *> &streams() { return streams_; } private: static constexpr unsigned int IPU3_BUFFER_COUNT = 4; static constexpr unsigned int IPU3_MAX_STREAMS = 3; void assignStreams(); void adjustStream(StreamConfiguration &cfg, bool scale); /* * The IPU3CameraData instance is guaranteed to be valid as long as the * corresponding Camera instance is valid. In order to borrow a * reference to the camera data, store a new reference to the camera. */ std::shared_ptr<Camera> camera_; const IPU3CameraData *data_; StreamConfiguration cio2Configuration_; std::vector<const IPU3Stream *> streams_; }; class PipelineHandlerIPU3 : public PipelineHandler { public: static constexpr unsigned int V4L2_CID_IPU3_PIPE_MODE = 0x009819c1; enum IPU3PipeModes { IPU3PipeModeVideo = 0, IPU3PipeModeStillCapture = 1, }; PipelineHandlerIPU3(CameraManager *manager); CameraConfiguration *generateConfiguration(Camera *camera, const StreamRoles &roles) override; int configure(Camera *camera, CameraConfiguration *config) override; int exportFrameBuffers(Camera *camera, Stream *stream, std::vector<std::unique_ptr<FrameBuffer>> *buffers) override; int start(Camera *camera) override; void stop(Camera *camera) override; int queueRequestDevice(Camera *camera, Request *request) override; bool match(DeviceEnumerator *enumerator) override; private: IPU3CameraData *cameraData(const Camera *camera) { return static_cast<IPU3CameraData *>( PipelineHandler::cameraData(camera)); } int registerCameras(); int allocateBuffers(Camera *camera); int freeBuffers(Camera *camera); ImgUDevice imgu0_; ImgUDevice imgu1_; MediaDevice *cio2MediaDev_; MediaDevice *imguMediaDev_; }; IPU3CameraConfiguration::IPU3CameraConfiguration(Camera *camera, IPU3CameraData *data) : CameraConfiguration() { camera_ = camera->shared_from_this(); data_ = data; } void IPU3CameraConfiguration::assignStreams() { /* * Verify and update all configuration entries, and assign a stream to * each of them. The viewfinder stream can scale, while the output * stream can crop only, so select the output stream when the requested * resolution is equal to the sensor resolution, and the viewfinder * stream otherwise. */ std::set<const IPU3Stream *> availableStreams = { &data_->outStream_, &data_->vfStream_, &data_->rawStream_, }; /* * The caller is responsible to limit the number of requested streams * to a number supported by the pipeline before calling this function. */ ASSERT(availableStreams.size() >= config_.size()); streams_.clear(); streams_.reserve(config_.size()); for (const StreamConfiguration &cfg : config_) { const PixelFormatInfo &info = PixelFormatInfo::info(cfg.pixelFormat); const IPU3Stream *stream; if (info.colourEncoding == PixelFormatInfo::ColourEncodingRAW) stream = &data_->rawStream_; else if (cfg.size == cio2Configuration_.size) stream = &data_->outStream_; else stream = &data_->vfStream_; if (availableStreams.find(stream) == availableStreams.end()) stream = *availableStreams.begin(); streams_.push_back(stream); availableStreams.erase(stream); } } void IPU3CameraConfiguration::adjustStream(StreamConfiguration &cfg, bool scale) { /* The only pixel format the driver supports is NV12. */ cfg.pixelFormat = formats::NV12; if (scale) { /* * Provide a suitable default that matches the sensor aspect * ratio. */ if (!cfg.size.width || !cfg.size.height) { cfg.size.width = 1280; cfg.size.height = 1280 * cio2Configuration_.size.height / cio2Configuration_.size.width; } /* * \todo: Clamp the size to the hardware bounds when we will * figure them out. * * \todo: Handle the scaler (BDS) restrictions. The BDS can * only scale with the same factor in both directions, and the * scaling factor is limited to a multiple of 1/32. At the * moment the ImgU driver hides these constraints by applying * additional cropping, this should be fixed on the driver * side, and cropping should be exposed to us. */ } else { /* * \todo: Properly support cropping when the ImgU driver * interface will be cleaned up. */ cfg.size = cio2Configuration_.size; } /* * Clamp the size to match the ImgU alignment constraints. The width * shall be a multiple of 8 pixels and the height a multiple of 4 * pixels. */ if (cfg.size.width % 8 || cfg.size.height % 4) { cfg.size.width &= ~7; cfg.size.height &= ~3; } } CameraConfiguration::Status IPU3CameraConfiguration::validate() { Status status = Valid; if (config_.empty()) return Invalid; /* Cap the number of entries to the available streams. */ if (config_.size() > IPU3_MAX_STREAMS) { config_.resize(IPU3_MAX_STREAMS); status = Adjusted; } /* * Select the sensor format by collecting the maximum width and height * and picking the closest larger match, as the IPU3 can downscale * only. If no resolution is requested for any stream, or if no sensor * resolution is large enough, pick the largest one. */ Size size = {}; for (const StreamConfiguration &cfg : config_) { if (cfg.size.width > size.width) size.width = cfg.size.width; if (cfg.size.height > size.height) size.height = cfg.size.height; } /* Generate raw configuration from CIO2. */ cio2Configuration_ = data_->cio2_.generateConfiguration(size); if (!cio2Configuration_.pixelFormat.isValid()) return Invalid; /* Assign streams to each configuration entry. */ assignStreams(); /* Verify and adjust configuration if needed. */ for (unsigned int i = 0; i < config_.size(); ++i) { StreamConfiguration &cfg = config_[i]; const StreamConfiguration oldCfg = cfg; const IPU3Stream *stream = streams_[i]; if (stream->raw_) { cfg = cio2Configuration_; } else { bool scale = stream == &data_->vfStream_; adjustStream(config_[i], scale); cfg.bufferCount = IPU3_BUFFER_COUNT; } if (cfg.pixelFormat != oldCfg.pixelFormat || cfg.size != oldCfg.size) { LOG(IPU3, Debug) << "Stream " << i << " configuration adjusted to " << cfg.toString(); status = Adjusted; } } return status; } PipelineHandlerIPU3::PipelineHandlerIPU3(CameraManager *manager) : PipelineHandler(manager), cio2MediaDev_(nullptr), imguMediaDev_(nullptr) { } CameraConfiguration *PipelineHandlerIPU3::generateConfiguration(Camera *camera, const StreamRoles &roles) { IPU3CameraData *data = cameraData(camera); IPU3CameraConfiguration *config; std::set<IPU3Stream *> streams = { &data->outStream_, &data->vfStream_, &data->rawStream_, }; config = new IPU3CameraConfiguration(camera, data); for (const StreamRole role : roles) { StreamConfiguration cfg = {}; IPU3Stream *stream = nullptr; cfg.pixelFormat = formats::NV12; switch (role) { case StreamRole::StillCapture: /* * Pick the output stream by default as the Viewfinder * and VideoRecording roles are not allowed on * the output stream. */ if (streams.find(&data->outStream_) != streams.end()) { stream = &data->outStream_; } else if (streams.find(&data->vfStream_) != streams.end()) { stream = &data->vfStream_; } else { LOG(IPU3, Error) << "No stream available for requested role " << role; break; } /* * FIXME: Soraka: the maximum resolution reported by * both sensors (2592x1944 for ov5670 and 4224x3136 for * ov13858) are returned as default configurations but * they're not correctly processed by the ImgU. * Resolutions up tp 2560x1920 have been validated. * * \todo Clarify ImgU alignment requirements. */ cfg.size = { 2560, 1920 }; break; case StreamRole::StillCaptureRaw: { if (streams.find(&data->rawStream_) == streams.end()) { LOG(IPU3, Error) << "No stream available for requested role " << role; break; } stream = &data->rawStream_; cfg.size = data->cio2_.sensor_->resolution(); cfg = data->cio2_.generateConfiguration(cfg.size); break; } case StreamRole::Viewfinder: case StreamRole::VideoRecording: { /* * We can't use the 'output' stream for viewfinder or * video capture roles. * * \todo This is an artificial limitation until we * figure out the exact capabilities of the hardware. */ if (streams.find(&data->vfStream_) == streams.end()) { LOG(IPU3, Error) << "No stream available for requested role " << role; break; } stream = &data->vfStream_; /* * Align the default viewfinder size to the maximum * available sensor resolution and to the IPU3 * alignment constraints. */ const Size &res = data->cio2_.sensor_->resolution(); unsigned int width = std::min(1280U, res.width); unsigned int height = std::min(720U, res.height); cfg.size = { width & ~7, height & ~3 }; break; } default: LOG(IPU3, Error) << "Requested stream role not supported: " << role; break; } if (!stream) { delete config; return nullptr; } streams.erase(stream); config->addConfiguration(cfg); } config->validate(); return config; } int PipelineHandlerIPU3::configure(Camera *camera, CameraConfiguration *c) { IPU3CameraConfiguration *config = static_cast<IPU3CameraConfiguration *>(c); IPU3CameraData *data = cameraData(camera); IPU3Stream *outStream = &data->outStream_; IPU3Stream *vfStream = &data->vfStream_; CIO2Device *cio2 = &data->cio2_; ImgUDevice *imgu = data->imgu_; V4L2DeviceFormat outputFormat; int ret; /* * FIXME: enabled links in one ImgU pipe interfere with capture * operations on the other one. This can be easily triggered by * capturing from one camera and then trying to capture from the other * one right after, without disabling media links on the first used * pipe. * * The tricky part here is where to disable links on the ImgU instance * which is currently not in use: * 1) Link enable/disable cannot be done at start()/stop() time as video * devices needs to be linked first before format can be configured on * them. * 2) As link enable has to be done at the least in configure(), * before configuring formats, the only place where to disable links * would be 'stop()', but the Camera class state machine allows * start()<->stop() sequences without any configure() in between. * * As of now, disable all links in the ImgU media graph before * configuring the device, to allow alternate the usage of the two * ImgU pipes. * * As a consequence, a Camera using an ImgU shall be configured before * any start()/stop() sequence. An application that wants to * pre-configure all the camera and then start/stop them alternatively * without going through any re-configuration (a sequence that is * allowed by the Camera state machine) would now fail on the IPU3. */ ret = imguMediaDev_->disableLinks(); if (ret) return ret; /* * \todo: Enable links selectively based on the requested streams. * As of now, enable all links unconditionally. * \todo Don't configure the ImgU at all if we only have a single * stream which is for raw capture, in which case no buffers will * ever be queued to the ImgU. */ ret = data->imgu_->enableLinks(true); if (ret) return ret; /* * Pass the requested stream size to the CIO2 unit and get back the * adjusted format to be propagated to the ImgU output devices. */ const Size &sensorSize = config->cio2Format().size; V4L2DeviceFormat cio2Format = {}; ret = cio2->configure(sensorSize, &cio2Format); if (ret) return ret; ret = imgu->configureInput(sensorSize, &cio2Format); if (ret) return ret; /* Apply the format to the configured streams output devices. */ outStream->active_ = false; vfStream->active_ = false; for (unsigned int i = 0; i < config->size(); ++i) { /* * Use a const_cast<> here instead of storing a mutable stream * pointer in the configuration to let the compiler catch * unwanted modifications of camera data in the configuration * validate() implementation. */ IPU3Stream *stream = const_cast<IPU3Stream *>(config->streams()[i]); StreamConfiguration &cfg = (*config)[i]; stream->active_ = true; cfg.setStream(stream); /* * The RAW still capture stream just copies buffers from the * internal queue and doesn't need any specific configuration. */ if (stream->raw_) { cfg.stride = cio2Format.planes[0].bpl; } else { ret = imgu->configureOutput(stream->device_, cfg, &outputFormat); if (ret) return ret; cfg.stride = outputFormat.planes[0].bpl; } } /* * As we need to set format also on the non-active streams, use * the configuration of the active one for that purpose (there should * be at least one active stream in the configuration request). */ if (!outStream->active_) { ret = imgu->configureOutput(outStream->device_, config->at(0), &outputFormat); if (ret) return ret; } if (!vfStream->active_) { ret = imgu->configureOutput(vfStream->device_, config->at(0), &outputFormat); if (ret) return ret; } /* * Apply the largest available format to the stat node. * \todo Revise this when we'll actually use the stat node. */ StreamConfiguration statCfg = {}; statCfg.size = cio2Format.size; ret = imgu->configureOutput(&imgu->stat_, statCfg, &outputFormat); if (ret) return ret; /* Apply the "pipe_mode" control to the ImgU subdevice. */ ControlList ctrls(imgu->imgu_->controls()); ctrls.set(V4L2_CID_IPU3_PIPE_MODE, static_cast<int32_t>(vfStream->active_ ? IPU3PipeModeVideo : IPU3PipeModeStillCapture)); ret = imgu->imgu_->setControls(&ctrls); if (ret) { LOG(IPU3, Error) << "Unable to set pipe_mode control"; return ret; } return 0; } int PipelineHandlerIPU3::exportFrameBuffers(Camera *camera, Stream *stream, std::vector<std::unique_ptr<FrameBuffer>> *buffers) { IPU3CameraData *data = cameraData(camera); IPU3Stream *ipu3stream = static_cast<IPU3Stream *>(stream); unsigned int count = stream->configuration().bufferCount; V4L2VideoDevice *video; if (ipu3stream->raw_) video = data->cio2_.output_; else video = ipu3stream->device_->dev; return video->exportBuffers(count, buffers); } /** * \todo Clarify if 'viewfinder' and 'stat' nodes have to be set up and * started even if not in use. As of now, if not properly configured and * enabled, the ImgU processing pipeline stalls. * * In order to be able to start the 'viewfinder' and 'stat' nodes, we need * memory to be reserved. */ int PipelineHandlerIPU3::allocateBuffers(Camera *camera) { IPU3CameraData *data = cameraData(camera); CIO2Device *cio2 = &data->cio2_; ImgUDevice *imgu = data->imgu_; unsigned int bufferCount; int ret; ret = cio2->allocateBuffers(); if (ret < 0) return ret; bufferCount = std::max({ data->outStream_.configuration().bufferCount, data->vfStream_.configuration().bufferCount, data->rawStream_.configuration().bufferCount, }); ret = imgu->allocateBuffers(data, bufferCount); if (ret < 0) { cio2->freeBuffers(); return ret; } return 0; } int PipelineHandlerIPU3::freeBuffers(Camera *camera) { IPU3CameraData *data = cameraData(camera); data->cio2_.freeBuffers(); data->imgu_->freeBuffers(data); return 0; } int PipelineHandlerIPU3::start(Camera *camera) { IPU3CameraData *data = cameraData(camera); CIO2Device *cio2 = &data->cio2_; ImgUDevice *imgu = data->imgu_; int ret; /* Allocate buffers for internal pipeline usage. */ ret = allocateBuffers(camera); if (ret) return ret; /* * Start the ImgU video devices, buffers will be queued to the * ImgU output and viewfinder when requests will be queued. */ ret = cio2->start(); if (ret) goto error; ret = imgu->start(); if (ret) { imgu->stop(); cio2->stop(); goto error; } return 0; error: freeBuffers(camera); LOG(IPU3, Error) << "Failed to start camera " << camera->name(); return ret; } void PipelineHandlerIPU3::stop(Camera *camera) { IPU3CameraData *data = cameraData(camera); int ret; ret = data->cio2_.stop(); ret |= data->imgu_->stop(); if (ret) LOG(IPU3, Warning) << "Failed to stop camera " << camera->name(); freeBuffers(camera); } int PipelineHandlerIPU3::queueRequestDevice(Camera *camera, Request *request) { IPU3CameraData *data = cameraData(camera); FrameBuffer *buffer; int error = 0; /* Get a CIO2 buffer, associate it with the request and queue it. */ buffer = data->cio2_.getBuffer(); if (!buffer) return -EINVAL; buffer->setRequest(request); data->cio2_.output_->queueBuffer(buffer); for (auto it : request->buffers()) { IPU3Stream *stream = static_cast<IPU3Stream *>(it.first); buffer = it.second; /* Skip raw streams, they are copied from the CIO2 buffer. */ if (stream->raw_) continue; int ret = stream->device_->dev->queueBuffer(buffer); if (ret < 0) error = ret; } return error; } bool PipelineHandlerIPU3::match(DeviceEnumerator *enumerator) { int ret; DeviceMatch cio2_dm("ipu3-cio2"); cio2_dm.add("ipu3-csi2 0"); cio2_dm.add("ipu3-cio2 0"); cio2_dm.add("ipu3-csi2 1"); cio2_dm.add("ipu3-cio2 1"); cio2_dm.add("ipu3-csi2 2"); cio2_dm.add("ipu3-cio2 2"); cio2_dm.add("ipu3-csi2 3"); cio2_dm.add("ipu3-cio2 3"); DeviceMatch imgu_dm("ipu3-imgu"); imgu_dm.add("ipu3-imgu 0"); imgu_dm.add("ipu3-imgu 0 input"); imgu_dm.add("ipu3-imgu 0 parameters"); imgu_dm.add("ipu3-imgu 0 output"); imgu_dm.add("ipu3-imgu 0 viewfinder"); imgu_dm.add("ipu3-imgu 0 3a stat"); imgu_dm.add("ipu3-imgu 1"); imgu_dm.add("ipu3-imgu 1 input"); imgu_dm.add("ipu3-imgu 1 parameters"); imgu_dm.add("ipu3-imgu 1 output"); imgu_dm.add("ipu3-imgu 1 viewfinder"); imgu_dm.add("ipu3-imgu 1 3a stat"); cio2MediaDev_ = acquireMediaDevice(enumerator, cio2_dm); if (!cio2MediaDev_) return false; imguMediaDev_ = acquireMediaDevice(enumerator, imgu_dm); if (!imguMediaDev_) return false; /* * Disable all links that are enabled by default on CIO2, as camera * creation enables all valid links it finds. */ if (cio2MediaDev_->disableLinks()) return false; ret = imguMediaDev_->disableLinks(); if (ret) return ret; ret = registerCameras(); return ret == 0; } /** * \brief Initialise ImgU and CIO2 devices associated with cameras * * Initialise the two ImgU instances and create cameras with an associated * CIO2 device instance. * * \return 0 on success or a negative error code for error or if no camera * has been created * \retval -ENODEV no camera has been created */ int PipelineHandlerIPU3::registerCameras() { int ret; ret = imgu0_.init(imguMediaDev_, 0); if (ret) return ret; ret = imgu1_.init(imguMediaDev_, 1); if (ret) return ret; /* * For each CSI-2 receiver on the IPU3, create a Camera if an * image sensor is connected to it and the sensor can produce images * in a compatible format. */ unsigned int numCameras = 0; for (unsigned int id = 0; id < 4 && numCameras < 2; ++id) { std::unique_ptr<IPU3CameraData> data = std::make_unique<IPU3CameraData>(this); std::set<Stream *> streams = { &data->outStream_, &data->vfStream_, &data->rawStream_, }; CIO2Device *cio2 = &data->cio2_; ret = cio2->init(cio2MediaDev_, id); if (ret) continue; /* Initialize the camera properties. */ data->properties_ = cio2->sensor_->properties(); /** * \todo Dynamically assign ImgU and output devices to each * stream and camera; as of now, limit support to two cameras * only, and assign imgu0 to the first one and imgu1 to the * second. */ data->imgu_ = numCameras ? &imgu1_ : &imgu0_; data->outStream_.device_ = &data->imgu_->output_; data->outStream_.name_ = "output"; data->vfStream_.device_ = &data->imgu_->viewfinder_; data->vfStream_.name_ = "viewfinder"; data->rawStream_.raw_ = true; data->rawStream_.name_ = "raw"; /* * Connect video devices' 'bufferReady' signals to their * slot to implement the image processing pipeline. * * Frames produced by the CIO2 unit are passed to the * associated ImgU input where they get processed and * returned through the ImgU main and secondary outputs. */ data->cio2_.output_->bufferReady.connect(data.get(), &IPU3CameraData::cio2BufferReady); data->imgu_->input_->bufferReady.connect(data.get(), &IPU3CameraData::imguInputBufferReady); data->imgu_->output_.dev->bufferReady.connect(data.get(), &IPU3CameraData::imguOutputBufferReady); data->imgu_->viewfinder_.dev->bufferReady.connect(data.get(), &IPU3CameraData::imguOutputBufferReady); /* Create and register the Camera instance. */ std::string cameraName = cio2->sensor_->entity()->name(); std::shared_ptr<Camera> camera = Camera::create(this, cameraName, streams); registerCamera(std::move(camera), std::move(data)); LOG(IPU3, Info) << "Registered Camera[" << numCameras << "] \"" << cameraName << "\"" << " connected to CSI-2 receiver " << id; numCameras++; } return numCameras ? 0 : -ENODEV; } /* ----------------------------------------------------------------------------- * Buffer Ready slots */ /** * \brief Handle buffers completion at the ImgU input * \param[in] buffer The completed buffer * * Buffers completed from the ImgU input are immediately queued back to the * CIO2 unit to continue frame capture. */ void IPU3CameraData::imguInputBufferReady(FrameBuffer *buffer) { /* \todo Handle buffer failures when state is set to BufferError. */ if (buffer->metadata().status == FrameMetadata::FrameCancelled) return; cio2_.putBuffer(buffer); } /** * \brief Handle buffers completion at the ImgU output * \param[in] buffer The completed buffer * * Buffers completed from the ImgU output are directed to the application. */ void IPU3CameraData::imguOutputBufferReady(FrameBuffer *buffer) { Request *request = buffer->request(); if (!pipe_->completeBuffer(camera_, request, buffer)) /* Request not completed yet, return here. */ return; /* Mark the request as complete. */ pipe_->completeRequest(camera_, request); } /** * \brief Handle buffers completion at the CIO2 output * \param[in] buffer The completed buffer * * Buffers completed from the CIO2 are immediately queued to the ImgU unit * for further processing. */ void IPU3CameraData::cio2BufferReady(FrameBuffer *buffer) { /* \todo Handle buffer failures when state is set to BufferError. */ if (buffer->metadata().status == FrameMetadata::FrameCancelled) return; Request *request = buffer->request(); FrameBuffer *raw = request->findBuffer(&rawStream_); if (!raw) { /* No RAW buffers present, just queue to IMGU. */ imgu_->input_->queueBuffer(buffer); return; } /* RAW buffers present, special care is needed. */ if (request->buffers().size() > 1) imgu_->input_->queueBuffer(buffer); if (raw->copyFrom(buffer)) LOG(IPU3, Debug) << "Copy of FrameBuffer failed"; pipe_->completeBuffer(camera_, request, raw); if (request->buffers().size() == 1) { cio2_.putBuffer(buffer); pipe_->completeRequest(camera_, request); } } /* ----------------------------------------------------------------------------- * ImgU Device */ /** * \brief Initialize components of the ImgU instance * \param[in] mediaDevice The ImgU instance media device * \param[in] index The ImgU instance index * * Create and open the V4L2 devices and subdevices of the ImgU instance * with \a index. * * In case of errors the created V4L2VideoDevice and V4L2Subdevice instances * are destroyed at pipeline handler delete time. * * \return 0 on success or a negative error code otherwise */ int ImgUDevice::init(MediaDevice *media, unsigned int index) { int ret; index_ = index; name_ = "ipu3-imgu " + std::to_string(index_); media_ = media; /* * The media entities presence in the media device has been verified * by the match() function: no need to check for newly created * video devices and subdevice validity here. */ imgu_ = V4L2Subdevice::fromEntityName(media, name_); ret = imgu_->open(); if (ret) return ret; input_ = V4L2VideoDevice::fromEntityName(media, name_ + " input"); ret = input_->open(); if (ret) return ret; output_.dev = V4L2VideoDevice::fromEntityName(media, name_ + " output"); ret = output_.dev->open(); if (ret) return ret; output_.pad = PAD_OUTPUT; output_.name = "output"; viewfinder_.dev = V4L2VideoDevice::fromEntityName(media, name_ + " viewfinder"); ret = viewfinder_.dev->open(); if (ret) return ret; viewfinder_.pad = PAD_VF; viewfinder_.name = "viewfinder"; stat_.dev = V4L2VideoDevice::fromEntityName(media, name_ + " 3a stat"); ret = stat_.dev->open(); if (ret) return ret; stat_.pad = PAD_STAT; stat_.name = "stat"; return 0; } /** * \brief Configure the ImgU unit input * \param[in] size The ImgU input frame size * \param[in] inputFormat The format to be applied to ImgU input * \return 0 on success or a negative error code otherwise */ int ImgUDevice::configureInput(const Size &size, V4L2DeviceFormat *inputFormat) { /* Configure the ImgU input video device with the requested sizes. */ int ret = input_->setFormat(inputFormat); if (ret) return ret; LOG(IPU3, Debug) << "ImgU input format = " << inputFormat->toString(); /* * \todo The IPU3 driver implementation shall be changed to use the * input sizes as 'ImgU Input' subdevice sizes, and use the desired * GDC output sizes to configure the crop/compose rectangles. * * The current IPU3 driver implementation uses GDC sizes as the * 'ImgU Input' subdevice sizes, and the input video device sizes * to configure the crop/compose rectangles, contradicting the * V4L2 specification. */ Rectangle rect = { .x = 0, .y = 0, .width = inputFormat->size.width, .height = inputFormat->size.height, }; ret = imgu_->setSelection(PAD_INPUT, V4L2_SEL_TGT_CROP, &rect); if (ret) return ret; ret = imgu_->setSelection(PAD_INPUT, V4L2_SEL_TGT_COMPOSE, &rect); if (ret) return ret; LOG(IPU3, Debug) << "ImgU input feeder and BDS rectangle = " << rect.toString(); V4L2SubdeviceFormat imguFormat = {}; imguFormat.mbus_code = MEDIA_BUS_FMT_FIXED; imguFormat.size = size; ret = imgu_->setFormat(PAD_INPUT, &imguFormat); if (ret) return ret; LOG(IPU3, Debug) << "ImgU GDC format = " << imguFormat.toString(); return 0; } /** * \brief Configure the ImgU unit \a id video output * \param[in] output The ImgU output device to configure * \param[in] cfg The requested configuration * \return 0 on success or a negative error code otherwise */ int ImgUDevice::configureOutput(ImgUOutput *output, const StreamConfiguration &cfg, V4L2DeviceFormat *outputFormat) { V4L2VideoDevice *dev = output->dev; unsigned int pad = output->pad; V4L2SubdeviceFormat imguFormat = {}; imguFormat.mbus_code = MEDIA_BUS_FMT_FIXED; imguFormat.size = cfg.size; int ret = imgu_->setFormat(pad, &imguFormat); if (ret) return ret; /* No need to apply format to the stat node. */ if (output == &stat_) return 0; *outputFormat = {}; outputFormat->fourcc = dev->toV4L2PixelFormat(formats::NV12); outputFormat->size = cfg.size; outputFormat->planesCount = 2; ret = dev->setFormat(outputFormat); if (ret) return ret; LOG(IPU3, Debug) << "ImgU " << output->name << " format = " << outputFormat->toString(); return 0; } /** * \brief Allocate buffers for all the ImgU video devices */ int ImgUDevice::allocateBuffers(IPU3CameraData *data, unsigned int bufferCount) { IPU3Stream *outStream = &data->outStream_; IPU3Stream *vfStream = &data->vfStream_; /* Share buffers between CIO2 output and ImgU input. */ int ret = input_->importBuffers(bufferCount); if (ret) { LOG(IPU3, Error) << "Failed to import ImgU input buffers"; return ret; } /* * Use for the stat's internal pool the same number of buffers as for * the input pool. * \todo To be revised when we'll actually use the stat node. */ ret = stat_.dev->allocateBuffers(bufferCount, &stat_.buffers); if (ret < 0) { LOG(IPU3, Error) << "Failed to allocate ImgU stat buffers"; goto error; } /* * Allocate buffers for both outputs. If an output is active, prepare * for buffer import, otherwise allocate internal buffers. Use the same * number of buffers in either case. */ if (outStream->active_) ret = output_.dev->importBuffers(bufferCount); else ret = output_.dev->allocateBuffers(bufferCount, &output_.buffers); if (ret < 0) { LOG(IPU3, Error) << "Failed to allocate ImgU output buffers"; goto error; } if (vfStream->active_) ret = viewfinder_.dev->importBuffers(bufferCount); else ret = viewfinder_.dev->allocateBuffers(bufferCount, &viewfinder_.buffers); if (ret < 0) { LOG(IPU3, Error) << "Failed to allocate ImgU viewfinder buffers"; goto error; } return 0; error: freeBuffers(data); return ret; } /** * \brief Release buffers for all the ImgU video devices */ void ImgUDevice::freeBuffers(IPU3CameraData *data) { int ret; ret = output_.dev->releaseBuffers(); if (ret) LOG(IPU3, Error) << "Failed to release ImgU output buffers"; ret = stat_.dev->releaseBuffers(); if (ret) LOG(IPU3, Error) << "Failed to release ImgU stat buffers"; ret = viewfinder_.dev->releaseBuffers(); if (ret) LOG(IPU3, Error) << "Failed to release ImgU viewfinder buffers"; ret = input_->releaseBuffers(); if (ret) LOG(IPU3, Error) << "Failed to release ImgU input buffers"; } int ImgUDevice::start() { int ret; /* Start the ImgU video devices. */ ret = output_.dev->streamOn(); if (ret) { LOG(IPU3, Error) << "Failed to start ImgU output"; return ret; } ret = viewfinder_.dev->streamOn(); if (ret) { LOG(IPU3, Error) << "Failed to start ImgU viewfinder"; return ret; } ret = stat_.dev->streamOn(); if (ret) { LOG(IPU3, Error) << "Failed to start ImgU stat"; return ret; } ret = input_->streamOn(); if (ret) { LOG(IPU3, Error) << "Failed to start ImgU input"; return ret; } return 0; } int ImgUDevice::stop() { int ret; ret = output_.dev->streamOff(); ret |= viewfinder_.dev->streamOff(); ret |= stat_.dev->streamOff(); ret |= input_->streamOff(); return ret; } /** * \brief Enable or disable a single link on the ImgU instance * * This method assumes the media device associated with the ImgU instance * is open. * * \return 0 on success or a negative error code otherwise */ int ImgUDevice::linkSetup(const std::string &source, unsigned int sourcePad, const std::string &sink, unsigned int sinkPad, bool enable) { MediaLink *link = media_->link(source, sourcePad, sink, sinkPad); if (!link) { LOG(IPU3, Error) << "Failed to get link: '" << source << "':" << sourcePad << " -> '" << sink << "':" << sinkPad; return -ENODEV; } return link->setEnabled(enable); } /** * \brief Enable or disable all media links in the ImgU instance to prepare * for capture operations * * \todo This method will probably be removed or changed once links will be * enabled or disabled selectively. * * \return 0 on success or a negative error code otherwise */ int ImgUDevice::enableLinks(bool enable) { std::string viewfinderName = name_ + " viewfinder"; std::string outputName = name_ + " output"; std::string statName = name_ + " 3a stat"; std::string inputName = name_ + " input"; int ret; ret = linkSetup(inputName, 0, name_, PAD_INPUT, enable); if (ret) return ret; ret = linkSetup(name_, PAD_OUTPUT, outputName, 0, enable); if (ret) return ret; ret = linkSetup(name_, PAD_VF, viewfinderName, 0, enable); if (ret) return ret; return linkSetup(name_, PAD_STAT, statName, 0, enable); } REGISTER_PIPELINE_HANDLER(PipelineHandlerIPU3); } /* namespace libcamera */