From fea85f84c2ac940f1e149d1382216ab3da0b7703 Mon Sep 17 00:00:00 2001 From: Jean-Michel Hautbois Date: Fri, 19 Nov 2021 07:56:12 +0100 Subject: ipa: rkisp1: Introduce AGC Now that we have IPAContext and Algorithm, we can implement a simple AGC based on the IPU3 one. It is very similar, except that there is no histogram used for an inter quantile mean. The RkISP1 is returning a 5x5 array (for V10) of luminance means. Estimating the relative luminance is thus a simple mean of all the blocks already calculated by the ISP. Signed-off-by: Jean-Michel Hautbois Reviewed-by: Laurent Pinchart Reviewed-by: Kieran Bingham --- src/ipa/rkisp1/algorithms/agc.cpp | 285 ++++++++++++++++++++++++++++++++++ src/ipa/rkisp1/algorithms/agc.h | 46 ++++++ src/ipa/rkisp1/algorithms/meson.build | 1 + src/ipa/rkisp1/ipa_context.cpp | 50 ++++++ src/ipa/rkisp1/ipa_context.h | 22 +++ src/ipa/rkisp1/rkisp1.cpp | 83 +++++----- 6 files changed, 443 insertions(+), 44 deletions(-) create mode 100644 src/ipa/rkisp1/algorithms/agc.cpp create mode 100644 src/ipa/rkisp1/algorithms/agc.h (limited to 'src') diff --git a/src/ipa/rkisp1/algorithms/agc.cpp b/src/ipa/rkisp1/algorithms/agc.cpp new file mode 100644 index 00000000..2c222a4e --- /dev/null +++ b/src/ipa/rkisp1/algorithms/agc.cpp @@ -0,0 +1,285 @@ +/* SPDX-License-Identifier: LGPL-2.1-or-later */ +/* + * Copyright (C) 2021, Ideas On Board + * + * agc.cpp - AGC/AEC mean-based control algorithm + */ + +#include "agc.h" + +#include +#include +#include + +#include + +#include + +/** + * \file agc.h + */ + +namespace libcamera { + +using namespace std::literals::chrono_literals; + +namespace ipa::rkisp1::algorithms { + +/** + * \class Agc + * \brief A mean-based auto-exposure algorithm + */ + +LOG_DEFINE_CATEGORY(RkISP1Agc) + +/* Limits for analogue gain values */ +static constexpr double kMinAnalogueGain = 1.0; +static constexpr double kMaxAnalogueGain = 8.0; + +/* \todo Honour the FrameDurationLimits control instead of hardcoding a limit */ +static constexpr utils::Duration kMaxShutterSpeed = 60ms; + +/* Number of frames to wait before calculating stats on minimum exposure */ +static constexpr uint32_t kNumStartupFrames = 10; + +/* + * Relative luminance target. + * + * It's a number that's chosen so that, when the camera points at a grey + * target, the resulting image brightness is considered right. + * + * \todo Why is the value different between IPU3 and RkISP1 ? + */ +static constexpr double kRelativeLuminanceTarget = 0.4; + +Agc::Agc() + : frameCount_(0), filteredExposure_(0s) +{ +} + +/** + * \brief Configure the AGC given a configInfo + * \param[in] context The shared IPA context + * \param[in] configInfo The IPA configuration data + * + * \return 0 + */ +int Agc::configure(IPAContext &context, + [[maybe_unused]] const IPACameraSensorInfo &configInfo) +{ + /* Configure the default exposure and gain. */ + context.frameContext.agc.gain = std::max(context.configuration.agc.minAnalogueGain, kMinAnalogueGain); + context.frameContext.agc.exposure = 10ms / context.configuration.sensor.lineDuration; + + /* + * According to the RkISP1 documentation: + * - versions < V12 have RKISP1_CIF_ISP_AE_MEAN_MAX_V10 entries, + * - versions >= V12 have RKISP1_CIF_ISP_AE_MEAN_MAX_V12 entries. + */ + if (context.configuration.hw.revision < RKISP1_V12) + numCells_ = RKISP1_CIF_ISP_AE_MEAN_MAX_V10; + else + numCells_ = RKISP1_CIF_ISP_AE_MEAN_MAX_V12; + + /* \todo Use actual frame index by populating it in the frameContext. */ + frameCount_ = 0; + return 0; +} + +/** + * \brief Apply a filter on the exposure value to limit the speed of changes + * \param[in] exposureValue The target exposure from the AGC algorithm + * + * The speed of the filter is adaptive, and will produce the target quicker + * during startup, or when the target exposure is within 20% of the most recent + * filter output. + * + * \return The filtered exposure + */ +utils::Duration Agc::filterExposure(utils::Duration exposureValue) +{ + double speed = 0.2; + + /* Adapt instantly if we are in startup phase. */ + if (frameCount_ < kNumStartupFrames) + speed = 1.0; + + /* + * If we are close to the desired result, go faster to avoid making + * multiple micro-adjustments. + * \todo Make this customisable? + */ + if (filteredExposure_ < 1.2 * exposureValue && + filteredExposure_ > 0.8 * exposureValue) + speed = sqrt(speed); + + filteredExposure_ = speed * exposureValue + + filteredExposure_ * (1.0 - speed); + + LOG(RkISP1Agc, Debug) << "After filtering, exposure " << filteredExposure_; + + return filteredExposure_; +} + +/** + * \brief Estimate the new exposure and gain values + * \param[inout] frameContext The shared IPA frame Context + * \param[in] yGain The gain calculated on the current brightness level + */ +void Agc::computeExposure(IPAContext &context, double yGain) +{ + IPASessionConfiguration &configuration = context.configuration; + IPAFrameContext &frameContext = context.frameContext; + + /* Get the effective exposure and gain applied on the sensor. */ + uint32_t exposure = frameContext.sensor.exposure; + double analogueGain = frameContext.sensor.gain; + + utils::Duration minShutterSpeed = configuration.agc.minShutterSpeed; + utils::Duration maxShutterSpeed = std::min(configuration.agc.maxShutterSpeed, + kMaxShutterSpeed); + + double minAnalogueGain = std::max(configuration.agc.minAnalogueGain, + kMinAnalogueGain); + double maxAnalogueGain = std::min(configuration.agc.maxAnalogueGain, + kMaxAnalogueGain); + + /* Consider within 1% of the target as correctly exposed. */ + if (std::abs(yGain - 1.0) < 0.01) + return; + + /* extracted from Rpi::Agc::computeTargetExposure. */ + + /* Calculate the shutter time in seconds. */ + utils::Duration currentShutter = exposure * configuration.sensor.lineDuration; + + /* + * Update the exposure value for the next computation using the values + * of exposure and gain really used by the sensor. + */ + utils::Duration effectiveExposureValue = currentShutter * analogueGain; + + LOG(RkISP1Agc, Debug) << "Actual total exposure " << currentShutter * analogueGain + << " Shutter speed " << currentShutter + << " Gain " << analogueGain + << " Needed ev gain " << yGain; + + /* + * Calculate the current exposure value for the scene as the latest + * exposure value applied multiplied by the new estimated gain. + */ + utils::Duration exposureValue = effectiveExposureValue * yGain; + + /* Clamp the exposure value to the min and max authorized. */ + utils::Duration maxTotalExposure = maxShutterSpeed * maxAnalogueGain; + exposureValue = std::min(exposureValue, maxTotalExposure); + LOG(RkISP1Agc, Debug) << "Target total exposure " << exposureValue + << ", maximum is " << maxTotalExposure; + + /* + * Divide the exposure value as new exposure and gain values. + * \todo estimate if we need to desaturate + */ + exposureValue = filterExposure(exposureValue); + + /* + * Push the shutter time up to the maximum first, and only then + * increase the gain. + */ + utils::Duration shutterTime = std::clamp(exposureValue / minAnalogueGain, + minShutterSpeed, maxShutterSpeed); + double stepGain = std::clamp(exposureValue / shutterTime, + minAnalogueGain, maxAnalogueGain); + LOG(RkISP1Agc, Debug) << "Divided up shutter and gain are " + << shutterTime << " and " + << stepGain; + + /* Update the estimated exposure and gain. */ + frameContext.agc.exposure = shutterTime / configuration.sensor.lineDuration; + frameContext.agc.gain = stepGain; +} + +/** + * \brief Estimate the relative luminance of the frame with a given gain + * \param[in] ae The RkISP1 statistics and ISP results + * \param[in] gain The gain to apply to the frame + * + * This function estimates the average relative luminance of the frame that + * would be output by the sensor if an additional \a gain was applied. + * + * The estimation is based on the AE statistics for the current frame. Y + * averages for all cells are first multiplied by the gain, and then saturated + * to approximate the sensor behaviour at high brightness values. The + * approximation is quite rough, as it doesn't take into account non-linearities + * when approaching saturation. In this case, saturating after the conversion to + * YUV doesn't take into account the fact that the R, G and B components + * contribute differently to the relative luminance. + * + * \todo Have a dedicated YUV algorithm ? + * + * The values are normalized to the [0.0, 1.0] range, where 1.0 corresponds to a + * theoretical perfect reflector of 100% reference white. + * + * More detailed information can be found in: + * https://en.wikipedia.org/wiki/Relative_luminance + * + * \return The relative luminance + */ +double Agc::estimateLuminance(const rkisp1_cif_isp_ae_stat *ae, + double gain) +{ + double ySum = 0.0; + + /* Sum the averages, saturated to 255. */ + for (unsigned int aeCell = 0; aeCell < numCells_; aeCell++) + ySum += std::min(ae->exp_mean[aeCell] * gain, 255.0); + + /* \todo Weight with the AWB gains */ + + return ySum / numCells_ / 255; +} + +/** + * \brief Process RkISP1 statistics, and run AGC operations + * \param[in] context The shared IPA context + * \param[in] stats The RKISP1 statistics and ISP results + * + * Identify the current image brightness, and use that to estimate the optimal + * new exposure and gain for the scene. + */ +void Agc::process(IPAContext &context, const rkisp1_stat_buffer *stats) +{ + const rkisp1_cif_isp_stat *params = &stats->params; + ASSERT(stats->meas_type & RKISP1_CIF_ISP_STAT_AUTOEXP); + + const rkisp1_cif_isp_ae_stat *ae = ¶ms->ae; + + /* + * Estimate the gain needed to achieve a relative luminance target. To + * account for non-linearity caused by saturation, the value needs to be + * estimated in an iterative process, as multiplying by a gain will not + * increase the relative luminance by the same factor if some image + * regions are saturated. + */ + double yGain = 1.0; + double yTarget = kRelativeLuminanceTarget; + + for (unsigned int i = 0; i < 8; i++) { + double yValue = estimateLuminance(ae, yGain); + double extra_gain = std::min(10.0, yTarget / (yValue + .001)); + + yGain *= extra_gain; + LOG(RkISP1Agc, Debug) << "Y value: " << yValue + << ", Y target: " << yTarget + << ", gives gain " << yGain; + if (extra_gain < 1.01) + break; + } + + computeExposure(context, yGain); + frameCount_++; +} + +} /* namespace ipa::rkisp1::algorithms */ + +} /* namespace libcamera */ diff --git a/src/ipa/rkisp1/algorithms/agc.h b/src/ipa/rkisp1/algorithms/agc.h new file mode 100644 index 00000000..07b9ea37 --- /dev/null +++ b/src/ipa/rkisp1/algorithms/agc.h @@ -0,0 +1,46 @@ +/* SPDX-License-Identifier: LGPL-2.1-or-later */ +/* + * Copyright (C) 2021, Ideas On Board + * + * agc.h - RkISP1 AGC/AEC mean-based control algorithm + */ + +#pragma once + +#include + +#include + +#include + +#include "algorithm.h" + +namespace libcamera { + +struct IPACameraSensorInfo; + +namespace ipa::rkisp1::algorithms { + +class Agc : public Algorithm +{ +public: + Agc(); + ~Agc() = default; + + int configure(IPAContext &context, const IPACameraSensorInfo &configInfo) override; + void process(IPAContext &context, const rkisp1_stat_buffer *stats) override; + +private: + void computeExposure(IPAContext &Context, double yGain); + utils::Duration filterExposure(utils::Duration exposureValue); + double estimateLuminance(const rkisp1_cif_isp_ae_stat *ae, double gain); + + uint64_t frameCount_; + + uint32_t numCells_; + + utils::Duration filteredExposure_; +}; + +} /* namespace ipa::rkisp1::algorithms */ +} /* namespace libcamera */ diff --git a/src/ipa/rkisp1/algorithms/meson.build b/src/ipa/rkisp1/algorithms/meson.build index 1c6c59cf..a19c1a4f 100644 --- a/src/ipa/rkisp1/algorithms/meson.build +++ b/src/ipa/rkisp1/algorithms/meson.build @@ -1,4 +1,5 @@ # SPDX-License-Identifier: CC0-1.0 rkisp1_ipa_algorithms = files([ + 'agc.cpp', ]) diff --git a/src/ipa/rkisp1/ipa_context.cpp b/src/ipa/rkisp1/ipa_context.cpp index 6b53dfdf..9cb2a9fd 100644 --- a/src/ipa/rkisp1/ipa_context.cpp +++ b/src/ipa/rkisp1/ipa_context.cpp @@ -56,6 +56,21 @@ namespace libcamera::ipa::rkisp1 { */ /** + * \var IPASessionConfiguration::agc + * \brief AGC parameters configuration of the IPA + * + * \var IPASessionConfiguration::agc.minShutterSpeed + * \brief Minimum shutter speed supported with the configured sensor + * + * \var IPASessionConfiguration::agc.maxShutterSpeed + * \brief Maximum shutter speed supported with the configured sensor + * + * \var IPASessionConfiguration::agc.minAnalogueGain + * \brief Minimum analogue gain supported with the configured sensor + * + * \var IPASessionConfiguration::agc.maxAnalogueGain + * \brief Maximum analogue gain supported with the configured sensor + * * \var IPASessionConfiguration::hw * \brief RkISP1-specific hardware information * @@ -63,4 +78,39 @@ namespace libcamera::ipa::rkisp1 { * \brief Hardware revision of the ISP */ +/** + * \var IPASessionConfiguration::sensor + * \brief Sensor-specific configuration of the IPA + * + * \var IPASessionConfiguration::sensor.lineDuration + * \brief Line duration in microseconds + */ + +/** + * \var IPAFrameContext::agc + * \brief Context for the Automatic Gain Control algorithm + * + * The exposure and gain determined are expected to be applied to the sensor + * at the earliest opportunity. + * + * \var IPAFrameContext::agc.exposure + * \brief Exposure time expressed as a number of lines + * + * \var IPAFrameContext::agc.gain + * \brief Analogue gain multiplier + * + * The gain should be adapted to the sensor specific gain code before applying. + */ + +/** + * \var IPAFrameContext::sensor + * \brief Effective sensor values + * + * \var IPAFrameContext::sensor.exposure + * \brief Exposure time expressed as a number of lines + * + * \var IPAFrameContext::sensor.gain + * \brief Analogue gain multiplier + */ + } /* namespace libcamera::ipa::rkisp1 */ diff --git a/src/ipa/rkisp1/ipa_context.h b/src/ipa/rkisp1/ipa_context.h index 9342025b..b94ade0c 100644 --- a/src/ipa/rkisp1/ipa_context.h +++ b/src/ipa/rkisp1/ipa_context.h @@ -10,17 +10,39 @@ #include +#include + namespace libcamera { namespace ipa::rkisp1 { struct IPASessionConfiguration { + struct { + utils::Duration minShutterSpeed; + utils::Duration maxShutterSpeed; + double minAnalogueGain; + double maxAnalogueGain; + } agc; + + struct { + utils::Duration lineDuration; + } sensor; + struct { rkisp1_cif_isp_version revision; } hw; }; struct IPAFrameContext { + struct { + uint32_t exposure; + double gain; + } agc; + + struct { + uint32_t exposure; + double gain; + } sensor; }; struct IPAContext { diff --git a/src/ipa/rkisp1/rkisp1.cpp b/src/ipa/rkisp1/rkisp1.cpp index 59676a70..38917fb7 100644 --- a/src/ipa/rkisp1/rkisp1.cpp +++ b/src/ipa/rkisp1/rkisp1.cpp @@ -25,6 +25,7 @@ #include +#include "algorithms/agc.h" #include "algorithms/algorithm.h" #include "libipa/camera_sensor_helper.h" @@ -34,6 +35,8 @@ namespace libcamera { LOG_DEFINE_CATEGORY(IPARkISP1) +using namespace std::literals::chrono_literals; + namespace ipa::rkisp1 { class IPARkISP1 : public IPARkISP1Interface @@ -66,16 +69,13 @@ private: /* Camera sensor controls. */ bool autoExposure_; - uint32_t exposure_; uint32_t minExposure_; uint32_t maxExposure_; - uint32_t gain_; uint32_t minGain_; uint32_t maxGain_; /* revision-specific data */ rkisp1_cif_isp_version hwRevision_; - unsigned int hwAeMeanMax_; unsigned int hwHistBinNMax_; unsigned int hwGammaOutMaxSamples_; unsigned int hwHistogramWeightGridsSize_; @@ -95,13 +95,11 @@ int IPARkISP1::init(const IPASettings &settings, unsigned int hwRevision) /* \todo Add support for other revisions */ switch (hwRevision) { case RKISP1_V10: - hwAeMeanMax_ = RKISP1_CIF_ISP_AE_MEAN_MAX_V10; hwHistBinNMax_ = RKISP1_CIF_ISP_HIST_BIN_N_MAX_V10; hwGammaOutMaxSamples_ = RKISP1_CIF_ISP_GAMMA_OUT_MAX_SAMPLES_V10; hwHistogramWeightGridsSize_ = RKISP1_CIF_ISP_HISTOGRAM_WEIGHT_GRIDS_SIZE_V10; break; case RKISP1_V12: - hwAeMeanMax_ = RKISP1_CIF_ISP_AE_MEAN_MAX_V12; hwHistBinNMax_ = RKISP1_CIF_ISP_HIST_BIN_N_MAX_V12; hwGammaOutMaxSamples_ = RKISP1_CIF_ISP_GAMMA_OUT_MAX_SAMPLES_V12; hwHistogramWeightGridsSize_ = RKISP1_CIF_ISP_HISTOGRAM_WEIGHT_GRIDS_SIZE_V12; @@ -126,6 +124,9 @@ int IPARkISP1::init(const IPASettings &settings, unsigned int hwRevision) return -ENODEV; } + /* Construct our Algorithms */ + algorithms_.push_back(std::make_unique()); + return 0; } @@ -167,11 +168,9 @@ int IPARkISP1::configure([[maybe_unused]] const IPACameraSensorInfo &info, minExposure_ = itExp->second.min().get(); maxExposure_ = itExp->second.max().get(); - exposure_ = minExposure_; minGain_ = itGain->second.min().get(); maxGain_ = itGain->second.max().get(); - gain_ = minGain_; LOG(IPARkISP1, Info) << "Exposure: " << minExposure_ << "-" << maxExposure_ @@ -183,6 +182,26 @@ int IPARkISP1::configure([[maybe_unused]] const IPACameraSensorInfo &info, /* Set the hardware revision for the algorithms. */ context_.configuration.hw.revision = hwRevision_; + context_.configuration.sensor.lineDuration = info.lineLength * 1.0s / info.pixelRate; + + /* + * When the AGC computes the new exposure values for a frame, it needs + * to know the limits for shutter speed and analogue gain. + * As it depends on the sensor, update it with the controls. + * + * \todo take VBLANK into account for maximum shutter speed + */ + context_.configuration.agc.minShutterSpeed = minExposure_ * context_.configuration.sensor.lineDuration; + context_.configuration.agc.maxShutterSpeed = maxExposure_ * context_.configuration.sensor.lineDuration; + context_.configuration.agc.minAnalogueGain = camHelper_->gain(minGain_); + context_.configuration.agc.maxAnalogueGain = camHelper_->gain(maxGain_); + + for (auto const &algo : algorithms_) { + int ret = algo->configure(context_, info); + if (ret) + return ret; + } + return 0; } @@ -227,6 +246,11 @@ void IPARkISP1::processEvent(const RkISP1Event &event) reinterpret_cast( mappedBuffers_.at(bufferId).planes()[0].data()); + context_.frameContext.sensor.exposure = + event.sensorControls.get(V4L2_CID_EXPOSURE).get(); + context_.frameContext.sensor.gain = + camHelper_->gain(event.sensorControls.get(V4L2_CID_ANALOGUE_GAIN).get()); + updateStatistics(frame, stats); break; } @@ -271,44 +295,12 @@ void IPARkISP1::queueRequest(unsigned int frame, rkisp1_params_cfg *params, void IPARkISP1::updateStatistics(unsigned int frame, const rkisp1_stat_buffer *stats) { - const rkisp1_cif_isp_stat *params = &stats->params; unsigned int aeState = 0; - if (stats->meas_type & RKISP1_CIF_ISP_STAT_AUTOEXP) { - const rkisp1_cif_isp_ae_stat *ae = ¶ms->ae; - - const unsigned int target = 60; - - unsigned int value = 0; - unsigned int num = 0; - for (unsigned int i = 0; i < hwAeMeanMax_; i++) { - if (ae->exp_mean[i] <= 15) - continue; - - value += ae->exp_mean[i]; - num++; - } - value /= num; + for (auto const &algo : algorithms_) + algo->process(context_, stats); - double factor = (double)target / value; - - if (frame % 3 == 0) { - double exposure; - - exposure = factor * exposure_ * gain_ / minGain_; - exposure_ = std::clamp((uint64_t)exposure, - minExposure_, - maxExposure_); - - exposure = exposure / exposure_ * minGain_; - gain_ = std::clamp((uint64_t)exposure, - minGain_, maxGain_); - - setControls(frame + 1); - } - - aeState = fabs(factor - 1.0f) < 0.05f ? 2 : 1; - } + setControls(frame); metadataReady(frame, aeState); } @@ -318,9 +310,12 @@ void IPARkISP1::setControls(unsigned int frame) RkISP1Action op; op.op = ActionV4L2Set; + uint32_t exposure = context_.frameContext.agc.exposure; + uint32_t gain = camHelper_->gainCode(context_.frameContext.agc.gain); + ControlList ctrls(ctrls_); - ctrls.set(V4L2_CID_EXPOSURE, static_cast(exposure_)); - ctrls.set(V4L2_CID_ANALOGUE_GAIN, static_cast(gain_)); + ctrls.set(V4L2_CID_EXPOSURE, static_cast(exposure)); + ctrls.set(V4L2_CID_ANALOGUE_GAIN, static_cast(gain)); op.sensorControls = ctrls; queueFrameAction.emit(frame, op); -- cgit v1.2.1