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-rw-r--r--src/ipa/rkisp1/algorithms/agc.cpp231
-rw-r--r--src/ipa/rkisp1/algorithms/agc.h9
2 files changed, 14 insertions, 226 deletions
diff --git a/src/ipa/rkisp1/algorithms/agc.cpp b/src/ipa/rkisp1/algorithms/agc.cpp
index f8d1b9a3..3e98496b 100644
--- a/src/ipa/rkisp1/algorithms/agc.cpp
+++ b/src/ipa/rkisp1/algorithms/agc.cpp
@@ -36,30 +36,7 @@ namespace ipa::rkisp1::algorithms {
LOG_DEFINE_CATEGORY(RkISP1Agc)
-/* Minimum limit for analogue gain value */
-static constexpr double kMinAnalogueGain = 1.0;
-
-/* \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;
-
-/* Target value to reach for the top 2% of the histogram */
-static constexpr double kEvGainTarget = 0.5;
-
-/*
- * 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)
{
supportsRaw_ = true;
}
@@ -116,12 +93,6 @@ int Agc::configure(IPAContext &context, const IPACameraSensorInfo &configInfo)
context.configuration.agc.measureWindow.h_size = 3 * configInfo.outputSize.width / 4;
context.configuration.agc.measureWindow.v_size = 3 * configInfo.outputSize.height / 4;
- /*
- * \todo Use the upcoming per-frame context API that will provide a
- * frame index
- */
- frameCount_ = 0;
-
/* \todo Run this again when FrameDurationLimits is passed in */
setLimits(context.configuration.sensor.minShutterSpeed,
context.configuration.sensor.maxShutterSpeed,
@@ -223,122 +194,24 @@ void Agc::prepare(IPAContext &context, const uint32_t frame,
params->module_en_update |= RKISP1_CIF_ISP_MODULE_HST;
}
-/**
- * \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] context The shared IPA Context
- * \param[in] frameContext The FrameContext for this frame
- * \param[in] yGain The gain calculated on the current brightness level
- * \param[in] iqMeanGain The gain calculated based on the relative luminance target
- */
-void Agc::computeExposure(IPAContext &context, IPAFrameContext &frameContext,
- double yGain, double iqMeanGain)
+void Agc::fillMetadata(IPAContext &context, IPAFrameContext &frameContext,
+ ControlList &metadata)
{
- IPASessionConfiguration &configuration = context.configuration;
-
- /* Get the effective exposure and gain applied on the sensor. */
- uint32_t exposure = frameContext.sensor.exposure;
- double analogueGain = frameContext.sensor.gain;
-
- /* Use the highest of the two gain estimates. */
- double evGain = std::max(yGain, iqMeanGain);
-
- utils::Duration minShutterSpeed = configuration.sensor.minShutterSpeed;
- utils::Duration maxShutterSpeed = std::min(configuration.sensor.maxShutterSpeed,
- kMaxShutterSpeed);
-
- double minAnalogueGain = std::max(configuration.sensor.minAnalogueGain,
- kMinAnalogueGain);
- double maxAnalogueGain = configuration.sensor.maxAnalogueGain;
-
- /* Consider within 1% of the target as correctly exposed. */
- if (utils::abs_diff(evGain, 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 " << evGain;
-
- /*
- * Calculate the current exposure value for the scene as the latest
- * exposure value applied multiplied by the new estimated gain.
- */
- utils::Duration exposureValue = effectiveExposureValue * evGain;
-
- /* 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);
+ utils::Duration exposureTime = context.configuration.sensor.lineDuration
+ * frameContext.sensor.exposure;
+ metadata.set(controls::AnalogueGain, frameContext.sensor.gain);
+ metadata.set(controls::ExposureTime, exposureTime.get<std::micro>());
- /*
- * Push the shutter time up to the maximum first, and only then
- * increase the gain.
- */
- utils::Duration shutterTime = std::clamp<utils::Duration>(exposureValue / minAnalogueGain,
- minShutterSpeed, maxShutterSpeed);
- double stepGain = std::clamp(exposureValue / shutterTime,
- minAnalogueGain, maxAnalogueGain);
- LOG(RkISP1Agc, Debug) << "Divided up shutter and gain are "
- << shutterTime << " and "
- << stepGain;
+ /* \todo Use VBlank value calculated from each frame exposure. */
+ uint32_t vTotal = context.configuration.sensor.size.height
+ + context.configuration.sensor.defVBlank;
+ utils::Duration frameDuration = context.configuration.sensor.lineDuration
+ * vTotal;
+ metadata.set(controls::FrameDuration, frameDuration.get<std::micro>());
}
/**
* \brief Estimate the relative luminance of the frame with a given gain
- * \param[in] expMeans The mean luminance values, from the RkISP1 statistics
* \param[in] gain The gain to apply to the frame
*
* This function estimates the average relative luminance of the frame that
@@ -352,8 +225,6 @@ void Agc::computeExposure(IPAContext &context, IPAFrameContext &frameContext,
* 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.
*
@@ -362,47 +233,6 @@ void Agc::computeExposure(IPAContext &context, IPAFrameContext &frameContext,
*
* \return The relative luminance
*/
-double Agc::estimateLuminance(Span<const uint8_t> expMeans, double gain)
-{
- double ySum = 0.0;
-
- /* Sum the averages, saturated to 255. */
- for (uint8_t expMean : expMeans)
- ySum += std::min(expMean * gain, 255.0);
-
- /* \todo Weight with the AWB gains */
-
- return ySum / expMeans.size() / 255;
-}
-
-/**
- * \brief Estimate the mean value of the top 2% of the histogram
- * \param[in] hist The histogram statistics computed by the RkISP1
- * \return The mean value of the top 2% of the histogram
- */
-double Agc::measureBrightness(Span<const uint32_t> hist) const
-{
- Histogram histogram{ hist };
- /* Estimate the quantile mean of the top 2% of the histogram. */
- return histogram.interQuantileMean(0.98, 1.0);
-}
-
-void Agc::fillMetadata(IPAContext &context, IPAFrameContext &frameContext,
- ControlList &metadata)
-{
- utils::Duration exposureTime = context.configuration.sensor.lineDuration
- * frameContext.sensor.exposure;
- metadata.set(controls::AnalogueGain, frameContext.sensor.gain);
- metadata.set(controls::ExposureTime, exposureTime.get<std::micro>());
-
- /* \todo Use VBlank value calculated from each frame exposure. */
- uint32_t vTotal = context.configuration.sensor.size.height
- + context.configuration.sensor.defVBlank;
- utils::Duration frameDuration = context.configuration.sensor.lineDuration
- * vTotal;
- metadata.set(controls::FrameDuration, frameDuration.get<std::micro>());
-}
-
double Agc::estimateLuminance(double gain) const
{
double ySum = 0.0;
@@ -447,40 +277,7 @@ void Agc::process(IPAContext &context, [[maybe_unused]] const uint32_t frame,
const rkisp1_cif_isp_stat *params = &stats->params;
ASSERT(stats->meas_type & RKISP1_CIF_ISP_STAT_AUTOEXP);
- Span<const uint8_t> ae{ params->ae.exp_mean, context.hw->numAeCells };
- Span<const uint32_t> hist{
- params->hist.hist_bins,
- context.hw->numHistogramBins
- };
-
- double iqMean = measureBrightness(hist);
- double iqMeanGain = kEvGainTarget * hist.size() / iqMean;
-
- /*
- * 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, frameContext, yGain, iqMeanGain);
- frameCount_++;
-
+ Histogram hist({ params->hist.hist_bins, context.hw->numHistogramBins });
expMeans_ = { params->ae.exp_mean, context.hw->numAeCells };
/*
@@ -497,7 +294,7 @@ void Agc::process(IPAContext &context, [[maybe_unused]] const uint32_t frame,
std::tie(shutterTime, aGain, dGain) =
calculateNewEv(context.activeState.agc.constraintMode,
context.activeState.agc.exposureMode,
- Histogram(hist), effectiveExposureValue);
+ hist, effectiveExposureValue);
LOG(RkISP1Agc, Debug)
<< "Divided up shutter, analogue gain and digital gain are "
diff --git a/src/ipa/rkisp1/algorithms/agc.h b/src/ipa/rkisp1/algorithms/agc.h
index 34504459..f2f5b59d 100644
--- a/src/ipa/rkisp1/algorithms/agc.h
+++ b/src/ipa/rkisp1/algorithms/agc.h
@@ -44,19 +44,10 @@ public:
ControlList &metadata) override;
private:
- void computeExposure(IPAContext &Context, IPAFrameContext &frameContext,
- double yGain, double iqMeanGain);
- utils::Duration filterExposure(utils::Duration exposureValue);
- double estimateLuminance(Span<const uint8_t> expMeans, double gain);
- double measureBrightness(Span<const uint32_t> hist) const;
void fillMetadata(IPAContext &context, IPAFrameContext &frameContext,
ControlList &metadata);
double estimateLuminance(double gain) const override;
- uint64_t frameCount_;
-
- utils::Duration filteredExposure_;
-
Span<const uint8_t> expMeans_;
};