From 83a512816189e506fd28c8b3b945a2575363cedc Mon Sep 17 00:00:00 2001 From: Naushir Patuck Date: Mon, 1 Nov 2021 09:15:08 +0000 Subject: pipeline: raspberrypi: Convert the pipeline handler to use media controller Switch the pipeline handler to use the new Unicam media controller based driver. With this change, we directly talk to the sensor device driver to set controls and set/get formats in the pipeline handler. This change requires the accompanying Raspberry Pi linux kernel change at https://github.com/raspberrypi/linux/pull/4645. If this kernel change is not present, the pipeline handler will fail to run with an error message informing the user to update the kernel build. Signed-off-by: Naushir Patuck Reviewed-by: Kieran Bingham Reviewed-by: Jacopo Mondi Signed-off-by: Kieran Bingham --- src/libcamera/pipeline/raspberrypi/raspberrypi.cpp | 173 ++++++++++++++------- 1 file changed, 115 insertions(+), 58 deletions(-) diff --git a/src/libcamera/pipeline/raspberrypi/raspberrypi.cpp b/src/libcamera/pipeline/raspberrypi/raspberrypi.cpp index e078b8b9..863516b9 100644 --- a/src/libcamera/pipeline/raspberrypi/raspberrypi.cpp +++ b/src/libcamera/pipeline/raspberrypi/raspberrypi.cpp @@ -26,6 +26,7 @@ #include #include +#include #include #include "libcamera/internal/bayer_format.h" @@ -48,6 +49,53 @@ LOG_DEFINE_CATEGORY(RPI) namespace { +/* Map of mbus codes to supported sizes reported by the sensor. */ +using SensorFormats = std::map>; + +SensorFormats populateSensorFormats(std::unique_ptr &sensor) +{ + SensorFormats formats; + + for (auto const mbusCode : sensor->mbusCodes()) + formats.emplace(mbusCode, sensor->sizes(mbusCode)); + + return formats; +} + +PixelFormat mbusCodeToPixelFormat(unsigned int mbus_code, + BayerFormat::Packing packingReq) +{ + BayerFormat bayer = BayerFormat::fromMbusCode(mbus_code); + + ASSERT(bayer.isValid()); + + bayer.packing = packingReq; + PixelFormat pix = bayer.toPixelFormat(); + + /* + * Not all formats (e.g. 8-bit or 16-bit Bayer formats) can have packed + * variants. So if the PixelFormat returns as invalid, use the non-packed + * conversion instead. + */ + if (!pix.isValid()) { + bayer.packing = BayerFormat::Packing::None; + pix = bayer.toPixelFormat(); + } + + return pix; +} + +V4L2DeviceFormat toV4L2DeviceFormat(const V4L2SubdeviceFormat &format, + BayerFormat::Packing packingReq) +{ + const PixelFormat pix = mbusCodeToPixelFormat(format.mbus_code, packingReq); + V4L2DeviceFormat deviceFormat; + + deviceFormat.fourcc = V4L2PixelFormat::fromPixelFormat(pix); + deviceFormat.size = format.size; + return deviceFormat; +} + bool isRaw(PixelFormat &pixFmt) { /* @@ -74,11 +122,10 @@ double scoreFormat(double desired, double actual) return score; } -V4L2DeviceFormat findBestMode(V4L2VideoDevice::Formats &formatsMap, - const Size &req) +V4L2SubdeviceFormat findBestFormat(const SensorFormats &formatsMap, const Size &req) { double bestScore = std::numeric_limits::max(), score; - V4L2DeviceFormat bestMode; + V4L2SubdeviceFormat bestFormat; #define PENALTY_AR 1500.0 #define PENALTY_8BIT 2000.0 @@ -88,19 +135,19 @@ V4L2DeviceFormat findBestMode(V4L2VideoDevice::Formats &formatsMap, /* Calculate the closest/best mode from the user requested size. */ for (const auto &iter : formatsMap) { - V4L2PixelFormat v4l2Format = iter.first; - const PixelFormatInfo &info = PixelFormatInfo::info(v4l2Format); + const unsigned int mbusCode = iter.first; + const PixelFormat format = mbusCodeToPixelFormat(mbusCode, + BayerFormat::Packing::None); + const PixelFormatInfo &info = PixelFormatInfo::info(format); - for (const SizeRange &sz : iter.second) { - double modeWidth = sz.contains(req) ? req.width : sz.max.width; - double modeHeight = sz.contains(req) ? req.height : sz.max.height; + for (const Size &size : iter.second) { double reqAr = static_cast(req.width) / req.height; - double modeAr = modeWidth / modeHeight; + double fmtAr = size.width / size.height; /* Score the dimensions for closeness. */ - score = scoreFormat(req.width, modeWidth); - score += scoreFormat(req.height, modeHeight); - score += PENALTY_AR * scoreFormat(reqAr, modeAr); + score = scoreFormat(req.width, size.width); + score += scoreFormat(req.height, size.height); + score += PENALTY_AR * scoreFormat(reqAr, fmtAr); /* Add any penalties... this is not an exact science! */ if (!info.packed) @@ -115,18 +162,18 @@ V4L2DeviceFormat findBestMode(V4L2VideoDevice::Formats &formatsMap, if (score <= bestScore) { bestScore = score; - bestMode.fourcc = v4l2Format; - bestMode.size = Size(modeWidth, modeHeight); + bestFormat.mbus_code = mbusCode; + bestFormat.size = size; } - LOG(RPI, Info) << "Mode: " << modeWidth << "x" << modeHeight - << " fmt " << v4l2Format.toString() + LOG(RPI, Info) << "Format: " << size.toString() + << " fmt " << format.toString() << " Score: " << score << " (best " << bestScore << ")"; } } - return bestMode; + return bestFormat; } enum class Unicam : unsigned int { Image, Embedded }; @@ -170,6 +217,7 @@ public: std::unique_ptr ipa_; std::unique_ptr sensor_; + SensorFormats sensorFormats_; /* Array of Unicam and ISP device streams and associated buffers/streams. */ RPi::Device unicam_; RPi::Device isp_; @@ -352,9 +400,10 @@ CameraConfiguration::Status RPiCameraConfiguration::validate() * Calculate the best sensor mode we can use based on * the user request. */ - V4L2VideoDevice::Formats fmts = data_->unicam_[Unicam::Image].dev()->formats(); - V4L2DeviceFormat sensorFormat = findBestMode(fmts, cfg.size); - int ret = data_->unicam_[Unicam::Image].dev()->tryFormat(&sensorFormat); + V4L2SubdeviceFormat sensorFormat = findBestFormat(data_->sensorFormats_, cfg.size); + V4L2DeviceFormat unicamFormat = toV4L2DeviceFormat(sensorFormat, + BayerFormat::Packing::CSI2); + int ret = data_->unicam_[Unicam::Image].dev()->tryFormat(&unicamFormat); if (ret) return Invalid; @@ -366,7 +415,7 @@ CameraConfiguration::Status RPiCameraConfiguration::validate() * fetch the "native" (i.e. untransformed) Bayer order, * because the sensor may currently be flipped! */ - V4L2PixelFormat fourcc = sensorFormat.fourcc; + V4L2PixelFormat fourcc = unicamFormat.fourcc; if (data_->flipsAlterBayerOrder_) { BayerFormat bayer = BayerFormat::fromV4L2PixelFormat(fourcc); bayer.order = data_->nativeBayerOrder_; @@ -374,16 +423,16 @@ CameraConfiguration::Status RPiCameraConfiguration::validate() fourcc = bayer.toV4L2PixelFormat(); } - PixelFormat sensorPixFormat = fourcc.toPixelFormat(); - if (cfg.size != sensorFormat.size || - cfg.pixelFormat != sensorPixFormat) { - cfg.size = sensorFormat.size; - cfg.pixelFormat = sensorPixFormat; + PixelFormat unicamPixFormat = fourcc.toPixelFormat(); + if (cfg.size != unicamFormat.size || + cfg.pixelFormat != unicamPixFormat) { + cfg.size = unicamFormat.size; + cfg.pixelFormat = unicamPixFormat; status = Adjusted; } - cfg.stride = sensorFormat.planes[0].bpl; - cfg.frameSize = sensorFormat.planes[0].size; + cfg.stride = unicamFormat.planes[0].bpl; + cfg.frameSize = unicamFormat.planes[0].size; rawCount++; } else { @@ -472,7 +521,7 @@ CameraConfiguration *PipelineHandlerRPi::generateConfiguration(Camera *camera, { RPiCameraData *data = cameraData(camera); CameraConfiguration *config = new RPiCameraConfiguration(data); - V4L2DeviceFormat sensorFormat; + V4L2SubdeviceFormat sensorFormat; unsigned int bufferCount; PixelFormat pixelFormat; V4L2VideoDevice::Formats fmts; @@ -487,9 +536,9 @@ CameraConfiguration *PipelineHandlerRPi::generateConfiguration(Camera *camera, switch (role) { case StreamRole::Raw: size = data->sensor_->resolution(); - fmts = data->unicam_[Unicam::Image].dev()->formats(); - sensorFormat = findBestMode(fmts, size); - pixelFormat = sensorFormat.fourcc.toPixelFormat(); + sensorFormat = findBestFormat(data->sensorFormats_, size); + pixelFormat = mbusCodeToPixelFormat(sensorFormat.mbus_code, + BayerFormat::Packing::CSI2); ASSERT(pixelFormat.isValid()); bufferCount = 2; rawCount++; @@ -572,6 +621,7 @@ int PipelineHandlerRPi::configure(Camera *camera, CameraConfiguration *config) for (auto const stream : data->streams_) stream->reset(); + BayerFormat::Packing packing = BayerFormat::Packing::CSI2; Size maxSize, sensorSize; unsigned int maxIndex = 0; bool rawStream = false; @@ -590,6 +640,8 @@ int PipelineHandlerRPi::configure(Camera *camera, CameraConfiguration *config) */ sensorSize = cfg.size; rawStream = true; + /* Check if the user has explicitly set an unpacked format. */ + packing = BayerFormat::fromPixelFormat(cfg.pixelFormat).packing; } else { if (cfg.size > maxSize) { maxSize = config->at(i).size; @@ -615,24 +667,21 @@ int PipelineHandlerRPi::configure(Camera *camera, CameraConfiguration *config) } /* First calculate the best sensor mode we can use based on the user request. */ - V4L2VideoDevice::Formats fmts = data->unicam_[Unicam::Image].dev()->formats(); - V4L2DeviceFormat sensorFormat = findBestMode(fmts, rawStream ? sensorSize : maxSize); - - ret = data->unicam_[Unicam::Image].dev()->setFormat(&sensorFormat); + V4L2SubdeviceFormat sensorFormat = findBestFormat(data->sensorFormats_, rawStream ? sensorSize : maxSize); + ret = data->sensor_->setFormat(&sensorFormat); if (ret) return ret; - /* - * The control ranges associated with the sensor may need updating - * after a format change. - * \todo Use the CameraSensor::setFormat API instead. - */ - data->sensor_->updateControlInfo(); + V4L2DeviceFormat unicamFormat = toV4L2DeviceFormat(sensorFormat, packing); + ret = data->unicam_[Unicam::Image].dev()->setFormat(&unicamFormat); + if (ret) + return ret; LOG(RPI, Info) << "Sensor: " << camera->id() - << " - Selected mode: " << sensorFormat.toString(); + << " - Selected sensor format: " << sensorFormat.toString() + << " - Selected unicam format: " << unicamFormat.toString(); - ret = data->isp_[Isp::Input].dev()->setFormat(&sensorFormat); + ret = data->isp_[Isp::Input].dev()->setFormat(&unicamFormat); if (ret) return ret; @@ -754,8 +803,8 @@ int PipelineHandlerRPi::configure(Camera *camera, CameraConfiguration *config) data->ispMinCropSize_ = testCrop.size(); /* Adjust aspect ratio by providing crops on the input image. */ - Size size = sensorFormat.size.boundedToAspectRatio(maxSize); - Rectangle crop = size.centeredTo(Rectangle(sensorFormat.size).center()); + Size size = unicamFormat.size.boundedToAspectRatio(maxSize); + Rectangle crop = size.centeredTo(Rectangle(unicamFormat.size).center()); data->ispCrop_ = crop; data->isp_[Isp::Input].dev()->setSelection(V4L2_SEL_TGT_CROP, &crop); @@ -769,8 +818,11 @@ int PipelineHandlerRPi::configure(Camera *camera, CameraConfiguration *config) * supports it. */ if (data->sensorMetadata_) { - format = {}; + V4L2SubdeviceFormat embeddedFormat; + + data->sensor_->device()->getFormat(1, &embeddedFormat); format.fourcc = V4L2PixelFormat(V4L2_META_FMT_SENSOR_DATA); + format.planes[0].size = embeddedFormat.size.width * embeddedFormat.size.height; LOG(RPI, Debug) << "Setting embedded data format."; ret = data->unicam_[Unicam::Embedded].dev()->setFormat(&format); @@ -1000,6 +1052,8 @@ bool PipelineHandlerRPi::match(DeviceEnumerator *enumerator) if (data->sensor_->init()) return false; + data->sensorFormats_ = populateSensorFormats(data->sensor_); + ipa::RPi::SensorConfig sensorConfig; if (data->loadIPA(&sensorConfig)) { LOG(RPI, Error) << "Failed to load a suitable IPA library"; @@ -1026,6 +1080,11 @@ bool PipelineHandlerRPi::match(DeviceEnumerator *enumerator) return false; } + if (!data->unicam_[Unicam::Image].dev()->caps().hasMediaController()) { + LOG(RPI, Error) << "Unicam driver does not use the MediaController, please update your kernel!"; + return false; + } + /* * Setup our delayed control writer with the sensor default * gain and exposure delays. Mark VBLANK for priority write. @@ -1035,7 +1094,7 @@ bool PipelineHandlerRPi::match(DeviceEnumerator *enumerator) { V4L2_CID_EXPOSURE, { sensorConfig.exposureDelay, false } }, { V4L2_CID_VBLANK, { sensorConfig.vblankDelay, true } } }; - data->delayedCtrls_ = std::make_unique(data->unicam_[Unicam::Image].dev(), params); + data->delayedCtrls_ = std::make_unique(data->sensor_->device(), params); data->sensorMetadata_ = sensorConfig.sensorMetadata; /* Register the controls that the Raspberry Pi IPA can handle. */ @@ -1062,15 +1121,14 @@ bool PipelineHandlerRPi::match(DeviceEnumerator *enumerator) * As part of answering the final question, we reset the camera to * no transform at all. */ - - V4L2VideoDevice *dev = data->unicam_[Unicam::Image].dev(); - const struct v4l2_query_ext_ctrl *hflipCtrl = dev->controlInfo(V4L2_CID_HFLIP); + const V4L2Subdevice *sensor = data->sensor_->device(); + const struct v4l2_query_ext_ctrl *hflipCtrl = sensor->controlInfo(V4L2_CID_HFLIP); if (hflipCtrl) { /* We assume it will support vflips too... */ data->supportsFlips_ = true; data->flipsAlterBayerOrder_ = hflipCtrl->flags & V4L2_CTRL_FLAG_MODIFY_LAYOUT; - ControlList ctrls(dev->controls()); + ControlList ctrls(data->sensor_->controls()); ctrls.set(V4L2_CID_HFLIP, 0); ctrls.set(V4L2_CID_VFLIP, 0); data->setSensorControls(ctrls); @@ -1078,9 +1136,8 @@ bool PipelineHandlerRPi::match(DeviceEnumerator *enumerator) /* Look for a valid Bayer format. */ BayerFormat bayerFormat; - for (const auto &iter : dev->formats()) { - V4L2PixelFormat v4l2Format = iter.first; - bayerFormat = BayerFormat::fromV4L2PixelFormat(v4l2Format); + for (const auto &iter : data->sensorFormats_) { + bayerFormat = BayerFormat::fromMbusCode(iter.first); if (bayerFormat.isValid()) break; } @@ -1263,7 +1320,7 @@ int RPiCameraData::configureIPA(const CameraConfiguration *config) } } - entityControls.emplace(0, unicam_[Unicam::Image].dev()->controls()); + entityControls.emplace(0, sensor_->controls()); entityControls.emplace(1, isp_[Isp::Input].dev()->controls()); /* Always send the user transform to the IPA. */ @@ -1387,10 +1444,10 @@ void RPiCameraData::setSensorControls(ControlList &controls) ControlList vblank_ctrl; vblank_ctrl.set(V4L2_CID_VBLANK, controls.get(V4L2_CID_VBLANK)); - unicam_[Unicam::Image].dev()->setControls(&vblank_ctrl); + sensor_->setControls(&vblank_ctrl); } - unicam_[Unicam::Image].dev()->setControls(&controls); + sensor_->setControls(&controls); } void RPiCameraData::unicamBufferDequeue(FrameBuffer *buffer) -- cgit v1.2.1