ipa: rkisp1: Use grey world algorithm from libipa
Now that libipa contains a grey world algorithm, use that. Signed-off-by: Stefan Klug <stefan.klug@ideasonboard.com> Reviewed-by: Paul Elder <paul.elder@ideasonboard.com> Reviewed-by: Daniel Scally <dan.scally@ideasonboard.com>
This commit is contained in:
Stefan Klug
parent
b60bd37b1a
commit
deb3f05137
2 changed files with 52 additions and 27 deletions
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@ -16,6 +16,7 @@
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#include <libcamera/ipa/core_ipa_interface.h>
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#include "libipa/awb_grey.h"
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#include "libipa/colours.h"
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/**
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@ -40,6 +41,30 @@ constexpr int32_t kDefaultColourTemperature = 5000;
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/* Minimum mean value below which AWB can't operate. */
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constexpr double kMeanMinThreshold = 2.0;
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class RkISP1AwbStats : public AwbStats
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{
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public:
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RkISP1AwbStats(const RGB<double> &rgbMeans)
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: rgbMeans_(rgbMeans)
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{
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}
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double computeColourError([[maybe_unused]] const RGB<double> &gains) const override
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{
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LOG(RkISP1Awb, Error)
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<< "RkISP1AwbStats::computeColourError is not implemented";
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return 0.0;
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}
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RGB<double> getRGBMeans() const override
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{
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return rgbMeans_;
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}
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private:
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RGB<double> rgbMeans_;
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};
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Awb::Awb()
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: rgbMode_(false)
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{
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@ -55,15 +80,12 @@ int Awb::init(IPAContext &context, const YamlObject &tuningData)
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kMaxColourTemperature,
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kDefaultColourTemperature);
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Interpolator<Vector<double, 2>> gainCurve;
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int ret = gainCurve.readYaml(tuningData["colourGains"], "ct", "gains");
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if (ret < 0)
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LOG(RkISP1Awb, Warning)
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<< "Failed to parse 'colourGains' "
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<< "parameter from tuning file; "
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<< "manual colour temperature will not work properly";
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else
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colourGainCurve_ = gainCurve;
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awbAlgo_ = std::make_unique<AwbGrey>();
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int ret = awbAlgo_->init(tuningData);
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if (ret) {
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LOG(RkISP1Awb, Error) << "Failed to init awb algorithm";
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return ret;
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}
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return 0;
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}
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@ -128,10 +150,10 @@ void Awb::queueRequest(IPAContext &context,
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* This will be fixed with the bayes AWB algorithm.
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*/
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update = true;
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} else if (colourTemperature && colourGainCurve_) {
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const auto &gains = colourGainCurve_->getInterpolated(*colourTemperature);
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awb.gains.manual.r() = gains[0];
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awb.gains.manual.b() = gains[1];
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} else if (colourTemperature) {
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const auto &gains = awbAlgo_->gainsFromColourTemperature(*colourTemperature);
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awb.gains.manual.r() = gains.r();
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awb.gains.manual.b() = gains.b();
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awb.temperatureK = *colourTemperature;
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update = true;
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}
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@ -251,33 +273,34 @@ void Awb::process(IPAContext &context,
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rgbMeans.b() < kMeanMinThreshold)
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return;
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activeState.awb.temperatureK = estimateCCT(rgbMeans);
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/*
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* \Todo: Hardcode lux to a fixed value, until an estimation is
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* implemented.
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*/
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int lux = 1000;
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RkISP1AwbStats awbStats{ rgbMeans };
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AwbResult awbResult = awbAlgo_->calculateAwb(awbStats, lux);
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activeState.awb.temperatureK = awbResult.colourTemperature;
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/* Metadata shall contain the up to date measurement */
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metadata.set(controls::ColourTemperature, activeState.awb.temperatureK);
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/*
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* Estimate the red and blue gains to apply in a grey world. The green
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* gain is hardcoded to 1.0. Avoid divisions by zero by clamping the
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* divisor to a minimum value of 1.0.
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*/
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RGB<double> gains({ rgbMeans.g() / std::max(rgbMeans.r(), 1.0),
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1.0,
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rgbMeans.g() / std::max(rgbMeans.b(), 1.0) });
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/*
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* Clamp the gain values to the hardware, which expresses gains as Q2.8
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* unsigned integer values. Set the minimum just above zero to avoid
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* divisions by zero when computing the raw means in subsequent
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* iterations.
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*/
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gains = gains.max(1.0 / 256).min(1023.0 / 256);
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awbResult.gains = awbResult.gains.max(1.0 / 256).min(1023.0 / 256);
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/* Filter the values to avoid oscillations. */
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double speed = 0.2;
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gains = gains * speed + activeState.awb.gains.automatic * (1 - speed);
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awbResult.gains = awbResult.gains * speed +
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activeState.awb.gains.automatic * (1 - speed);
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activeState.awb.gains.automatic = gains;
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activeState.awb.gains.automatic = awbResult.gains;
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LOG(RkISP1Awb, Debug)
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<< std::showpoint
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@ -11,6 +11,7 @@
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#include "libcamera/internal/vector.h"
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#include "libipa/awb.h"
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#include "libipa/interpolator.h"
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#include "algorithm.h"
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@ -42,7 +43,8 @@ private:
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RGB<double> calculateRgbMeans(const IPAFrameContext &frameContext,
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const rkisp1_cif_isp_awb_stat *awb) const;
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std::optional<Interpolator<Vector<double, 2>>> colourGainCurve_;
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std::unique_ptr<AwbAlgorithm> awbAlgo_;
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bool rgbMode_;
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};
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