/* SPDX-License-Identifier: LGPL-2.1-or-later */ /* * Copyright (C) 2023, Linaro Ltd * * Simple Software Image Processing Algorithm module */ #include #include #include #include #include #include #include #include #include #include #include #include "libcamera/internal/software_isp/debayer_params.h" #include "libcamera/internal/software_isp/swisp_stats.h" #include "libcamera/internal/yaml_parser.h" #include "libipa/camera_sensor_helper.h" #include "module.h" namespace libcamera { LOG_DEFINE_CATEGORY(IPASoft) namespace ipa::soft { /* Maximum number of frame contexts to be held */ static constexpr uint32_t kMaxFrameContexts = 16; class IPASoftSimple : public ipa::soft::IPASoftInterface, public Module { public: IPASoftSimple() : context_({ {}, {}, { kMaxFrameContexts } }) { } ~IPASoftSimple(); int init(const IPASettings &settings, const SharedFD &fdStats, const SharedFD &fdParams, const ControlInfoMap &sensorInfoMap) override; int configure(const IPAConfigInfo &configInfo) override; int start() override; void stop() override; void queueRequest(const uint32_t frame, const ControlList &controls) override; void fillParamsBuffer(const uint32_t frame) override; void processStats(const uint32_t frame, const uint32_t bufferId, const ControlList &sensorControls) override; protected: std::string logPrefix() const override; private: void updateExposure(double exposureMSV); DebayerParams *params_; SwIspStats *stats_; std::unique_ptr camHelper_; ControlInfoMap sensorInfoMap_; /* Local parameter storage */ struct IPAContext context_; }; IPASoftSimple::~IPASoftSimple() { if (stats_) munmap(stats_, sizeof(SwIspStats)); if (params_) munmap(params_, sizeof(DebayerParams)); } int IPASoftSimple::init(const IPASettings &settings, const SharedFD &fdStats, const SharedFD &fdParams, const ControlInfoMap &sensorInfoMap) { camHelper_ = CameraSensorHelperFactoryBase::create(settings.sensorModel); if (!camHelper_) { LOG(IPASoft, Warning) << "Failed to create camera sensor helper for " << settings.sensorModel; } /* Load the tuning data file */ File file(settings.configurationFile); if (!file.open(File::OpenModeFlag::ReadOnly)) { int ret = file.error(); LOG(IPASoft, Error) << "Failed to open configuration file " << settings.configurationFile << ": " << strerror(-ret); return ret; } std::unique_ptr data = YamlParser::parse(file); if (!data) return -EINVAL; /* \todo Use the IPA configuration file for real. */ unsigned int version = (*data)["version"].get(0); LOG(IPASoft, Debug) << "Tuning file version " << version; if (!data->contains("algorithms")) { LOG(IPASoft, Error) << "Tuning file doesn't contain algorithms"; return -EINVAL; } int ret = createAlgorithms(context_, (*data)["algorithms"]); if (ret) return ret; params_ = nullptr; stats_ = nullptr; if (!fdStats.isValid()) { LOG(IPASoft, Error) << "Invalid Statistics handle"; return -ENODEV; } if (!fdParams.isValid()) { LOG(IPASoft, Error) << "Invalid Parameters handle"; return -ENODEV; } { void *mem = mmap(nullptr, sizeof(DebayerParams), PROT_WRITE, MAP_SHARED, fdParams.get(), 0); if (mem == MAP_FAILED) { LOG(IPASoft, Error) << "Unable to map Parameters"; return -errno; } params_ = static_cast(mem); } { void *mem = mmap(nullptr, sizeof(SwIspStats), PROT_READ, MAP_SHARED, fdStats.get(), 0); if (mem == MAP_FAILED) { LOG(IPASoft, Error) << "Unable to map Statistics"; return -errno; } stats_ = static_cast(mem); } /* * Check if the sensor driver supports the controls required by the * Soft IPA. * Don't save the min and max control values yet, as e.g. the limits * for V4L2_CID_EXPOSURE depend on the configured sensor resolution. */ if (sensorInfoMap.find(V4L2_CID_EXPOSURE) == sensorInfoMap.end()) { LOG(IPASoft, Error) << "Don't have exposure control"; return -EINVAL; } if (sensorInfoMap.find(V4L2_CID_ANALOGUE_GAIN) == sensorInfoMap.end()) { LOG(IPASoft, Error) << "Don't have gain control"; return -EINVAL; } return 0; } int IPASoftSimple::configure(const IPAConfigInfo &configInfo) { sensorInfoMap_ = configInfo.sensorControls; const ControlInfo &exposureInfo = sensorInfoMap_.find(V4L2_CID_EXPOSURE)->second; const ControlInfo &gainInfo = sensorInfoMap_.find(V4L2_CID_ANALOGUE_GAIN)->second; context_.configuration.agc.exposureMin = exposureInfo.min().get(); context_.configuration.agc.exposureMax = exposureInfo.max().get(); if (!context_.configuration.agc.exposureMin) { LOG(IPASoft, Warning) << "Minimum exposure is zero, that can't be linear"; context_.configuration.agc.exposureMin = 1; } int32_t againMin = gainInfo.min().get(); int32_t againMax = gainInfo.max().get(); if (camHelper_) { context_.configuration.agc.againMin = camHelper_->gain(againMin); context_.configuration.agc.againMax = camHelper_->gain(againMax); context_.configuration.agc.againMinStep = (context_.configuration.agc.againMax - context_.configuration.agc.againMin) / 100.0; } else { /* * The camera sensor gain (g) is usually not equal to the value written * into the gain register (x). But the way how the AGC algorithm changes * the gain value to make the total exposure closer to the optimum * assumes that g(x) is not too far from linear function. If the minimal * gain is 0, the g(x) is likely to be far from the linear, like * g(x) = a / (b * x + c). To avoid unexpected changes to the gain by * the AGC algorithm (abrupt near one edge, and very small near the * other) we limit the range of the gain values used. */ context_.configuration.agc.againMax = againMax; if (!againMin) { LOG(IPASoft, Warning) << "Minimum gain is zero, that can't be linear"; context_.configuration.agc.againMin = std::min(100, againMin / 2 + againMax / 2); } context_.configuration.agc.againMinStep = 1.0; } for (auto const &algo : algorithms()) { int ret = algo->configure(context_, configInfo); if (ret) return ret; } LOG(IPASoft, Info) << "Exposure " << context_.configuration.agc.exposureMin << "-" << context_.configuration.agc.exposureMax << ", gain " << context_.configuration.agc.againMin << "-" << context_.configuration.agc.againMax << " (" << context_.configuration.agc.againMinStep << ")"; return 0; } int IPASoftSimple::start() { return 0; } void IPASoftSimple::stop() { } void IPASoftSimple::queueRequest(const uint32_t frame, const ControlList &controls) { IPAFrameContext &frameContext = context_.frameContexts.alloc(frame); for (auto const &algo : algorithms()) algo->queueRequest(context_, frame, frameContext, controls); } void IPASoftSimple::fillParamsBuffer(const uint32_t frame) { IPAFrameContext &frameContext = context_.frameContexts.get(frame); for (auto const &algo : algorithms()) algo->prepare(context_, frame, frameContext, params_); setIspParams.emit(); } void IPASoftSimple::processStats(const uint32_t frame, [[maybe_unused]] const uint32_t bufferId, const ControlList &sensorControls) { IPAFrameContext &frameContext = context_.frameContexts.get(frame); frameContext.sensor.exposure = sensorControls.get(V4L2_CID_EXPOSURE).get(); int32_t again = sensorControls.get(V4L2_CID_ANALOGUE_GAIN).get(); frameContext.sensor.gain = camHelper_ ? camHelper_->gain(again) : again; /* * Software ISP currently does not produce any metadata. Use an empty * ControlList for now. * * \todo Implement proper metadata handling */ ControlList metadata(controls::controls); for (auto const &algo : algorithms()) algo->process(context_, frame, frameContext, stats_, metadata); /* Sanity check */ if (!sensorControls.contains(V4L2_CID_EXPOSURE) || !sensorControls.contains(V4L2_CID_ANALOGUE_GAIN)) { LOG(IPASoft, Error) << "Control(s) missing"; return; } ControlList ctrls(sensorInfoMap_); auto &againNew = context_.activeState.agc.again; ctrls.set(V4L2_CID_EXPOSURE, context_.activeState.agc.exposure); ctrls.set(V4L2_CID_ANALOGUE_GAIN, static_cast(camHelper_ ? camHelper_->gainCode(againNew) : againNew)); setSensorControls.emit(ctrls); } std::string IPASoftSimple::logPrefix() const { return "IPASoft"; } } /* namespace ipa::soft */ /* * External IPA module interface */ extern "C" { const struct IPAModuleInfo ipaModuleInfo = { IPA_MODULE_API_VERSION, 0, "simple", "simple", }; IPAInterface *ipaCreate() { return new ipa::soft::IPASoftSimple(); } } /* extern "C" */ } /* namespace libcamera */