libs/input/MotionPredictorMetricsManager.cpp - platform/frameworks/native - Git at Google

 /*
  * Copyright 2023 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #define LOG_TAG "MotionPredictorMetricsManager"

 #include <input/MotionPredictorMetricsManager.h>

 #include <algorithm>

 #include <android-base/logging.h>

 #include "Eigen/Core"
 #include "Eigen/Geometry"

 #ifdef __ANDROID__
 #include <statslog_libinput.h>
 #endif

 namespace android {
 namespace {

 inline constexpr int NANOS_PER_SECOND = 1'000'000'000; // nanoseconds per second
 inline constexpr int NANOS_PER_MILLIS = 1'000'000;     // nanoseconds per millisecond

 // Velocity threshold at which we report "high-velocity" metrics, in pixels per second.
 // This value was selected from manual experimentation, as a threshold that separates "fast"
 // (semi-sloppy) handwriting from more careful medium to slow handwriting.
 inline constexpr float HIGH_VELOCITY_THRESHOLD = 1100.0;

 // Small value to add to the path length when computing scale-invariant error to avoid division by
 // zero.
 inline constexpr float PATH_LENGTH_EPSILON = 0.001;

 } // namespace

 void MotionPredictorMetricsManager::defaultReportAtomFunction(
         const MotionPredictorMetricsManager::AtomFields& atomFields) {
     // Call stats_write logging function only on Android targets (not supported on host).
 #ifdef __ANDROID__
     android::stats::libinput::
             stats_write(android::stats::libinput::STYLUS_PREDICTION_METRICS_REPORTED,
                             /*stylus_vendor_id=*/0,
                             /*stylus_product_id=*/0,
                             atomFields.deltaTimeBucketMilliseconds,
                             atomFields.alongTrajectoryErrorMeanMillipixels,
                             atomFields.alongTrajectoryErrorStdMillipixels,
                             atomFields.offTrajectoryRmseMillipixels,
                             atomFields.pressureRmseMilliunits,
                             atomFields.highVelocityAlongTrajectoryRmse,
                             atomFields.highVelocityOffTrajectoryRmse,
                             atomFields.scaleInvariantAlongTrajectoryRmse,
                             atomFields.scaleInvariantOffTrajectoryRmse);
 #endif
 }

 MotionPredictorMetricsManager::MotionPredictorMetricsManager(
         nsecs_t predictionInterval,
         size_t maxNumPredictions,
         ReportAtomFunction reportAtomFunction)
       : mPredictionInterval(predictionInterval),
         mMaxNumPredictions(maxNumPredictions),
         mRecentGroundTruthPoints(maxNumPredictions + 1),
         mAggregatedMetrics(maxNumPredictions),
         mAtomFields(maxNumPredictions),
         mReportAtomFunction(reportAtomFunction ? reportAtomFunction : defaultReportAtomFunction) {}

 void MotionPredictorMetricsManager::onRecord(const MotionEvent& inputEvent) {
     // Convert MotionEvent to GroundTruthPoint.
     const PointerCoords* coords = inputEvent.getRawPointerCoords(/*pointerIndex=*/0);
     LOG_ALWAYS_FATAL_IF(coords == nullptr);
     const GroundTruthPoint groundTruthPoint{{.position = Eigen::Vector2f{coords->getY(),
                                                                          coords->getX()},
                                              .pressure =
                                                      inputEvent.getPressure(/*pointerIndex=*/0)},
                                             .timestamp = inputEvent.getEventTime()};

     // Handle event based on action type.
     switch (inputEvent.getActionMasked()) {
         case AMOTION_EVENT_ACTION_DOWN: {
             clearStrokeData();
             incorporateNewGroundTruth(groundTruthPoint);
             break;
         }
         case AMOTION_EVENT_ACTION_MOVE: {
             incorporateNewGroundTruth(groundTruthPoint);
             break;
         }
         case AMOTION_EVENT_ACTION_UP:
         case AMOTION_EVENT_ACTION_CANCEL: {
             // Only expect meaningful predictions when given at least two input points.
             if (mRecentGroundTruthPoints.size() >= 2) {
                 computeAtomFields();
                 reportMetrics();
             }
             break;
         }
     }
 }

 // Adds new predictions to mRecentPredictions and maintains the invariant that elements are
 // sorted in ascending order of targetTimestamp.
 void MotionPredictorMetricsManager::onPredict(const MotionEvent& predictionEvent) {
     for (size_t i = 0; i < predictionEvent.getHistorySize() + 1; ++i) {
         // Convert MotionEvent to PredictionPoint.
         const PointerCoords* coords =
                 predictionEvent.getHistoricalRawPointerCoords(/*pointerIndex=*/0, i);
         LOG_ALWAYS_FATAL_IF(coords == nullptr);
         const nsecs_t targetTimestamp = predictionEvent.getHistoricalEventTime(i);
         mRecentPredictions.push_back(
                 PredictionPoint{{.position = Eigen::Vector2f{coords->getY(), coords->getX()},
                                  .pressure =
                                          predictionEvent.getHistoricalPressure(/*pointerIndex=*/0,
                                                                                i)},
                                 .originTimestamp = mRecentGroundTruthPoints.back().timestamp,
                                 .targetTimestamp = targetTimestamp});
     }

     std::sort(mRecentPredictions.begin(), mRecentPredictions.end());
 }

 void MotionPredictorMetricsManager::clearStrokeData() {
     mRecentGroundTruthPoints.clear();
     mRecentPredictions.clear();
     std::fill(mAggregatedMetrics.begin(), mAggregatedMetrics.end(), AggregatedStrokeMetrics{});
     std::fill(mAtomFields.begin(), mAtomFields.end(), AtomFields{});
 }

 void MotionPredictorMetricsManager::incorporateNewGroundTruth(
         const GroundTruthPoint& groundTruthPoint) {
     // Note: this removes the oldest point if `mRecentGroundTruthPoints` is already at capacity.
     mRecentGroundTruthPoints.pushBack(groundTruthPoint);

     // Remove outdated predictions – those that can never be matched with the current or any future
     // ground truth points. We use fuzzy association for the timestamps here, because ground truth
     // and prediction timestamps may not be perfectly synchronized.
     const nsecs_t fuzzy_association_time_delta = mPredictionInterval / 4;
     const auto firstCurrentIt =
             std::find_if(mRecentPredictions.begin(), mRecentPredictions.end(),
                          [&groundTruthPoint,
                           fuzzy_association_time_delta](const PredictionPoint& prediction) {
                              return prediction.targetTimestamp >
                                      groundTruthPoint.timestamp - fuzzy_association_time_delta;
                          });
     mRecentPredictions.erase(mRecentPredictions.begin(), firstCurrentIt);

     // Fuzzily match the new ground truth's timestamp to recent predictions' targetTimestamp and
     // update the corresponding metrics.
     for (const PredictionPoint& prediction : mRecentPredictions) {
         if ((prediction.targetTimestamp >
              groundTruthPoint.timestamp - fuzzy_association_time_delta) &&
             (prediction.targetTimestamp <
              groundTruthPoint.timestamp + fuzzy_association_time_delta)) {
             updateAggregatedMetrics(prediction);
         }
     }
 }

 void MotionPredictorMetricsManager::updateAggregatedMetrics(
         const PredictionPoint& predictionPoint) {
     if (mRecentGroundTruthPoints.size() < 2) {
         return;
     }

     const GroundTruthPoint& latestGroundTruthPoint = mRecentGroundTruthPoints.back();
     const GroundTruthPoint& previousGroundTruthPoint =
             mRecentGroundTruthPoints[mRecentGroundTruthPoints.size() - 2];
     // Calculate prediction error vector.
     const Eigen::Vector2f groundTruthTrajectory =
             latestGroundTruthPoint.position - previousGroundTruthPoint.position;
     const Eigen::Vector2f predictionTrajectory =
             predictionPoint.position - previousGroundTruthPoint.position;
     const Eigen::Vector2f predictionError = predictionTrajectory - groundTruthTrajectory;

     // By default, prediction error counts fully as both off-trajectory and along-trajectory error.
     // This serves as the fallback when the two most recent ground truth points are equal.
     const float predictionErrorNorm = predictionError.norm();
     float alongTrajectoryError = predictionErrorNorm;
     float offTrajectoryError = predictionErrorNorm;
     if (groundTruthTrajectory.squaredNorm() > 0) {
         // Rotate the prediction error vector by the angle of the ground truth trajectory vector.
         // This yields a vector whose first component is the along-trajectory error and whose
         // second component is the off-trajectory error.
         const float theta = std::atan2(groundTruthTrajectory[1], groundTruthTrajectory[0]);
         const Eigen::Vector2f rotatedPredictionError = Eigen::Rotation2Df(-theta) * predictionError;
         alongTrajectoryError = rotatedPredictionError[0];
         offTrajectoryError = rotatedPredictionError[1];
     }

     // Compute the multiple of mPredictionInterval nearest to the amount of time into the
     // future being predicted. This serves as the time bucket index into mAggregatedMetrics.
     const float timestampDeltaFloat =
             static_cast<float>(predictionPoint.targetTimestamp - predictionPoint.originTimestamp);
     const size_t tIndex =
             static_cast<size_t>(std::round(timestampDeltaFloat / mPredictionInterval - 1));

     // Aggregate values into "general errors".
     mAggregatedMetrics[tIndex].alongTrajectoryErrorSum += alongTrajectoryError;
     mAggregatedMetrics[tIndex].alongTrajectorySumSquaredErrors +=
             alongTrajectoryError * alongTrajectoryError;
     mAggregatedMetrics[tIndex].offTrajectorySumSquaredErrors +=
             offTrajectoryError * offTrajectoryError;
     const float pressureError = predictionPoint.pressure - latestGroundTruthPoint.pressure;
     mAggregatedMetrics[tIndex].pressureSumSquaredErrors += pressureError * pressureError;
     ++mAggregatedMetrics[tIndex].generalErrorsCount;

     // Aggregate values into high-velocity metrics, if we are in one of the last two time buckets
     // and the velocity is above the threshold. Velocity here is measured in pixels per second.
     const float velocity = groundTruthTrajectory.norm() /
             (static_cast<float>(latestGroundTruthPoint.timestamp -
                                 previousGroundTruthPoint.timestamp) /
              NANOS_PER_SECOND);
     if ((tIndex + 2 >= mMaxNumPredictions) && (velocity > HIGH_VELOCITY_THRESHOLD)) {
         mAggregatedMetrics[tIndex].highVelocityAlongTrajectorySse +=
                 alongTrajectoryError * alongTrajectoryError;
         mAggregatedMetrics[tIndex].highVelocityOffTrajectorySse +=
                 offTrajectoryError * offTrajectoryError;
         ++mAggregatedMetrics[tIndex].highVelocityErrorsCount;
     }

     // Compute path length for scale-invariant errors.
     float pathLength = 0;
     for (size_t i = 1; i < mRecentGroundTruthPoints.size(); ++i) {
         pathLength +=
                 (mRecentGroundTruthPoints[i].position - mRecentGroundTruthPoints[i - 1].position)
                         .norm();
     }
     // Avoid overweighting errors at the beginning of a stroke: compute the path length as if there
     // were a full ground truth history by filling in missing segments with the average length.
     // Note: the "- 1" is needed to translate from number of endpoints to number of segments.
     pathLength *= static_cast<float>(mRecentGroundTruthPoints.capacity() - 1) /
             (mRecentGroundTruthPoints.size() - 1);
     pathLength += PATH_LENGTH_EPSILON; // Ensure path length is nonzero (>= PATH_LENGTH_EPSILON).

     // Compute and aggregate scale-invariant errors.
     const float scaleInvariantAlongTrajectoryError = alongTrajectoryError / pathLength;
     const float scaleInvariantOffTrajectoryError = offTrajectoryError / pathLength;
     mAggregatedMetrics[tIndex].scaleInvariantAlongTrajectorySse +=
             scaleInvariantAlongTrajectoryError * scaleInvariantAlongTrajectoryError;
     mAggregatedMetrics[tIndex].scaleInvariantOffTrajectorySse +=
             scaleInvariantOffTrajectoryError * scaleInvariantOffTrajectoryError;
     ++mAggregatedMetrics[tIndex].scaleInvariantErrorsCount;
 }

 void MotionPredictorMetricsManager::computeAtomFields() {
     for (size_t i = 0; i < mAggregatedMetrics.size(); ++i) {
         if (mAggregatedMetrics[i].generalErrorsCount == 0) {
             // We have not received data corresponding to metrics for this time bucket.
             continue;
         }

         mAtomFields[i].deltaTimeBucketMilliseconds =
                 static_cast<int>(mPredictionInterval / NANOS_PER_MILLIS * (i + 1));

         // Note: we need the "* 1000"s below because we report values in integral milli-units.

         { // General errors: reported for every time bucket.
             const float alongTrajectoryErrorMean = mAggregatedMetrics[i].alongTrajectoryErrorSum /
                     mAggregatedMetrics[i].generalErrorsCount;
             mAtomFields[i].alongTrajectoryErrorMeanMillipixels =
                     static_cast<int>(alongTrajectoryErrorMean * 1000);

             const float alongTrajectoryMse = mAggregatedMetrics[i].alongTrajectorySumSquaredErrors /
                     mAggregatedMetrics[i].generalErrorsCount;
             // Take the max with 0 to avoid negative values caused by numerical instability.
             const float alongTrajectoryErrorVariance =
                     std::max(0.0f,
                              alongTrajectoryMse -
                                      alongTrajectoryErrorMean * alongTrajectoryErrorMean);
             const float alongTrajectoryErrorStd = std::sqrt(alongTrajectoryErrorVariance);
             mAtomFields[i].alongTrajectoryErrorStdMillipixels =
                     static_cast<int>(alongTrajectoryErrorStd * 1000);

             LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].offTrajectorySumSquaredErrors < 0,
                                 "mAggregatedMetrics[%zu].offTrajectorySumSquaredErrors = %f should "
                                 "not be negative",
                                 i, mAggregatedMetrics[i].offTrajectorySumSquaredErrors);
             const float offTrajectoryRmse =
                     std::sqrt(mAggregatedMetrics[i].offTrajectorySumSquaredErrors /
                               mAggregatedMetrics[i].generalErrorsCount);
             mAtomFields[i].offTrajectoryRmseMillipixels =
                     static_cast<int>(offTrajectoryRmse * 1000);

             LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].pressureSumSquaredErrors < 0,
                                 "mAggregatedMetrics[%zu].pressureSumSquaredErrors = %f should not "
                                 "be negative",
                                 i, mAggregatedMetrics[i].pressureSumSquaredErrors);
             const float pressureRmse = std::sqrt(mAggregatedMetrics[i].pressureSumSquaredErrors /
                                                  mAggregatedMetrics[i].generalErrorsCount);
             mAtomFields[i].pressureRmseMilliunits = static_cast<int>(pressureRmse * 1000);
         }

         // High-velocity errors: reported only for last two time buckets.
         // Check if we are in one of the last two time buckets, and there is high-velocity data.
         if ((i + 2 >= mMaxNumPredictions) && (mAggregatedMetrics[i].highVelocityErrorsCount > 0)) {
             LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].highVelocityAlongTrajectorySse < 0,
                                 "mAggregatedMetrics[%zu].highVelocityAlongTrajectorySse = %f "
                                 "should not be negative",
                                 i, mAggregatedMetrics[i].highVelocityAlongTrajectorySse);
             const float alongTrajectoryRmse =
                     std::sqrt(mAggregatedMetrics[i].highVelocityAlongTrajectorySse /
                               mAggregatedMetrics[i].highVelocityErrorsCount);
             mAtomFields[i].highVelocityAlongTrajectoryRmse =
                     static_cast<int>(alongTrajectoryRmse * 1000);

             LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].highVelocityOffTrajectorySse < 0,
                                 "mAggregatedMetrics[%zu].highVelocityOffTrajectorySse = %f should "
                                 "not be negative",
                                 i, mAggregatedMetrics[i].highVelocityOffTrajectorySse);
             const float offTrajectoryRmse =
                     std::sqrt(mAggregatedMetrics[i].highVelocityOffTrajectorySse /
                               mAggregatedMetrics[i].highVelocityErrorsCount);
             mAtomFields[i].highVelocityOffTrajectoryRmse =
                     static_cast<int>(offTrajectoryRmse * 1000);
         }

         // Scale-invariant errors: reported only for the last time bucket, where the values
         // represent an average across all time buckets.
         if (i + 1 == mMaxNumPredictions) {
             // Compute error averages.
             float alongTrajectoryRmseSum = 0;
             float offTrajectoryRmseSum = 0;
             for (size_t j = 0; j < mAggregatedMetrics.size(); ++j) {
                 // If we have general errors (checked above), we should always also have
                 // scale-invariant errors.
                 LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[j].scaleInvariantErrorsCount == 0,
                                     "mAggregatedMetrics[%zu].scaleInvariantErrorsCount is 0", j);

                 LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[j].scaleInvariantAlongTrajectorySse < 0,
                                     "mAggregatedMetrics[%zu].scaleInvariantAlongTrajectorySse = %f "
                                     "should not be negative",
                                     j, mAggregatedMetrics[j].scaleInvariantAlongTrajectorySse);
                 alongTrajectoryRmseSum +=
                         std::sqrt(mAggregatedMetrics[j].scaleInvariantAlongTrajectorySse /
                                   mAggregatedMetrics[j].scaleInvariantErrorsCount);

                 LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[j].scaleInvariantOffTrajectorySse < 0,
                                     "mAggregatedMetrics[%zu].scaleInvariantOffTrajectorySse = %f "
                                     "should not be negative",
                                     j, mAggregatedMetrics[j].scaleInvariantOffTrajectorySse);
                 offTrajectoryRmseSum +=
                         std::sqrt(mAggregatedMetrics[j].scaleInvariantOffTrajectorySse /
                                   mAggregatedMetrics[j].scaleInvariantErrorsCount);
             }

             const float averageAlongTrajectoryRmse =
                     alongTrajectoryRmseSum / mAggregatedMetrics.size();
             mAtomFields.back().scaleInvariantAlongTrajectoryRmse =
                     static_cast<int>(averageAlongTrajectoryRmse * 1000);

             const float averageOffTrajectoryRmse = offTrajectoryRmseSum / mAggregatedMetrics.size();
             mAtomFields.back().scaleInvariantOffTrajectoryRmse =
                     static_cast<int>(averageOffTrajectoryRmse * 1000);
         }
     }
 }

 void MotionPredictorMetricsManager::reportMetrics() {
     LOG_ALWAYS_FATAL_IF(!mReportAtomFunction);
     // Report one atom for each prediction time bucket.
     for (size_t i = 0; i < mAtomFields.size(); ++i) {
         mReportAtomFunction(mAtomFields[i]);
     }
 }

 } // namespace android
	/*
	* Copyright 2023 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#define LOG_TAG "MotionPredictorMetricsManager"

	#include <input/MotionPredictorMetricsManager.h>

	#include <algorithm>

	#include <android-base/logging.h>

	#include "Eigen/Core"
	#include "Eigen/Geometry"

	#ifdef __ANDROID__
	#include <statslog_libinput.h>
	#endif

	namespace android {
	namespace {

	inline constexpr int NANOS_PER_SECOND = 1'000'000'000; // nanoseconds per second
	inline constexpr int NANOS_PER_MILLIS = 1'000'000; // nanoseconds per millisecond

	// Velocity threshold at which we report "high-velocity" metrics, in pixels per second.
	// This value was selected from manual experimentation, as a threshold that separates "fast"
	// (semi-sloppy) handwriting from more careful medium to slow handwriting.
	inline constexpr float HIGH_VELOCITY_THRESHOLD = 1100.0;

	// Small value to add to the path length when computing scale-invariant error to avoid division by
	// zero.
	inline constexpr float PATH_LENGTH_EPSILON = 0.001;

	} // namespace

	void MotionPredictorMetricsManager::defaultReportAtomFunction(
	const MotionPredictorMetricsManager::AtomFields& atomFields) {
	// Call stats_write logging function only on Android targets (not supported on host).
	#ifdef __ANDROID__
	android::stats::libinput::
	stats_write(android::stats::libinput::STYLUS_PREDICTION_METRICS_REPORTED,
	/stylus_vendor_id=/0,
	/stylus_product_id=/0,
	atomFields.deltaTimeBucketMilliseconds,
	atomFields.alongTrajectoryErrorMeanMillipixels,
	atomFields.alongTrajectoryErrorStdMillipixels,
	atomFields.offTrajectoryRmseMillipixels,
	atomFields.pressureRmseMilliunits,
	atomFields.highVelocityAlongTrajectoryRmse,
	atomFields.highVelocityOffTrajectoryRmse,
	atomFields.scaleInvariantAlongTrajectoryRmse,
	atomFields.scaleInvariantOffTrajectoryRmse);
	#endif
	}

	MotionPredictorMetricsManager::MotionPredictorMetricsManager(
	nsecs_t predictionInterval,
	size_t maxNumPredictions,
	ReportAtomFunction reportAtomFunction)
	: mPredictionInterval(predictionInterval),
	mMaxNumPredictions(maxNumPredictions),
	mRecentGroundTruthPoints(maxNumPredictions + 1),
	mAggregatedMetrics(maxNumPredictions),
	mAtomFields(maxNumPredictions),
	mReportAtomFunction(reportAtomFunction ? reportAtomFunction : defaultReportAtomFunction) {}

	void MotionPredictorMetricsManager::onRecord(const MotionEvent& inputEvent) {
	// Convert MotionEvent to GroundTruthPoint.
	const PointerCoords* coords = inputEvent.getRawPointerCoords(/pointerIndex=/0);
	LOG_ALWAYS_FATAL_IF(coords == nullptr);
	const GroundTruthPoint groundTruthPoint{{.position = Eigen::Vector2f{coords->getY(),
	coords->getX()},
	.pressure =
	inputEvent.getPressure(/pointerIndex=/0)},
	.timestamp = inputEvent.getEventTime()};

	// Handle event based on action type.
	switch (inputEvent.getActionMasked()) {
	case AMOTION_EVENT_ACTION_DOWN: {
	clearStrokeData();
	incorporateNewGroundTruth(groundTruthPoint);
	break;
	}
	case AMOTION_EVENT_ACTION_MOVE: {
	incorporateNewGroundTruth(groundTruthPoint);
	break;
	}
	case AMOTION_EVENT_ACTION_UP:
	case AMOTION_EVENT_ACTION_CANCEL: {
	// Only expect meaningful predictions when given at least two input points.
	if (mRecentGroundTruthPoints.size() >= 2) {
	computeAtomFields();
	reportMetrics();
	}
	break;
	}
	}
	}

	// Adds new predictions to mRecentPredictions and maintains the invariant that elements are
	// sorted in ascending order of targetTimestamp.
	void MotionPredictorMetricsManager::onPredict(const MotionEvent& predictionEvent) {
	for (size_t i = 0; i < predictionEvent.getHistorySize() + 1; ++i) {
	// Convert MotionEvent to PredictionPoint.
	const PointerCoords* coords =
	predictionEvent.getHistoricalRawPointerCoords(/pointerIndex=/0, i);
	LOG_ALWAYS_FATAL_IF(coords == nullptr);
	const nsecs_t targetTimestamp = predictionEvent.getHistoricalEventTime(i);
	mRecentPredictions.push_back(
	PredictionPoint{{.position = Eigen::Vector2f{coords->getY(), coords->getX()},
	.pressure =
	predictionEvent.getHistoricalPressure(/pointerIndex=/0,
	i)},
	.originTimestamp = mRecentGroundTruthPoints.back().timestamp,
	.targetTimestamp = targetTimestamp});
	}

	std::sort(mRecentPredictions.begin(), mRecentPredictions.end());
	}

	void MotionPredictorMetricsManager::clearStrokeData() {
	mRecentGroundTruthPoints.clear();
	mRecentPredictions.clear();
	std::fill(mAggregatedMetrics.begin(), mAggregatedMetrics.end(), AggregatedStrokeMetrics{});
	std::fill(mAtomFields.begin(), mAtomFields.end(), AtomFields{});
	}

	void MotionPredictorMetricsManager::incorporateNewGroundTruth(
	const GroundTruthPoint& groundTruthPoint) {
	// Note: this removes the oldest point if `mRecentGroundTruthPoints` is already at capacity.
	mRecentGroundTruthPoints.pushBack(groundTruthPoint);

	// Remove outdated predictions – those that can never be matched with the current or any future
	// ground truth points. We use fuzzy association for the timestamps here, because ground truth
	// and prediction timestamps may not be perfectly synchronized.
	const nsecs_t fuzzy_association_time_delta = mPredictionInterval / 4;
	const auto firstCurrentIt =
	std::find_if(mRecentPredictions.begin(), mRecentPredictions.end(),
	[&groundTruthPoint,
	fuzzy_association_time_delta](const PredictionPoint& prediction) {
	return prediction.targetTimestamp >
	groundTruthPoint.timestamp - fuzzy_association_time_delta;
	});
	mRecentPredictions.erase(mRecentPredictions.begin(), firstCurrentIt);

	// Fuzzily match the new ground truth's timestamp to recent predictions' targetTimestamp and
	// update the corresponding metrics.
	for (const PredictionPoint& prediction : mRecentPredictions) {
	if ((prediction.targetTimestamp >
	groundTruthPoint.timestamp - fuzzy_association_time_delta) &&
	(prediction.targetTimestamp <
	groundTruthPoint.timestamp + fuzzy_association_time_delta)) {
	updateAggregatedMetrics(prediction);
	}
	}
	}

	void MotionPredictorMetricsManager::updateAggregatedMetrics(
	const PredictionPoint& predictionPoint) {
	if (mRecentGroundTruthPoints.size() < 2) {
	return;
	}

	const GroundTruthPoint& latestGroundTruthPoint = mRecentGroundTruthPoints.back();
	const GroundTruthPoint& previousGroundTruthPoint =
	mRecentGroundTruthPoints[mRecentGroundTruthPoints.size() - 2];
	// Calculate prediction error vector.
	const Eigen::Vector2f groundTruthTrajectory =
	latestGroundTruthPoint.position - previousGroundTruthPoint.position;
	const Eigen::Vector2f predictionTrajectory =
	predictionPoint.position - previousGroundTruthPoint.position;
	const Eigen::Vector2f predictionError = predictionTrajectory - groundTruthTrajectory;

	// By default, prediction error counts fully as both off-trajectory and along-trajectory error.
	// This serves as the fallback when the two most recent ground truth points are equal.
	const float predictionErrorNorm = predictionError.norm();
	float alongTrajectoryError = predictionErrorNorm;
	float offTrajectoryError = predictionErrorNorm;
	if (groundTruthTrajectory.squaredNorm() > 0) {
	// Rotate the prediction error vector by the angle of the ground truth trajectory vector.
	// This yields a vector whose first component is the along-trajectory error and whose
	// second component is the off-trajectory error.
	const float theta = std::atan2(groundTruthTrajectory[1], groundTruthTrajectory[0]);
	const Eigen::Vector2f rotatedPredictionError = Eigen::Rotation2Df(-theta) * predictionError;
	alongTrajectoryError = rotatedPredictionError[0];
	offTrajectoryError = rotatedPredictionError[1];
	}

	// Compute the multiple of mPredictionInterval nearest to the amount of time into the
	// future being predicted. This serves as the time bucket index into mAggregatedMetrics.
	const float timestampDeltaFloat =
	static_cast<float>(predictionPoint.targetTimestamp - predictionPoint.originTimestamp);
	const size_t tIndex =
	static_cast<size_t>(std::round(timestampDeltaFloat / mPredictionInterval - 1));

	// Aggregate values into "general errors".
	mAggregatedMetrics[tIndex].alongTrajectoryErrorSum += alongTrajectoryError;
	mAggregatedMetrics[tIndex].alongTrajectorySumSquaredErrors +=
	alongTrajectoryError * alongTrajectoryError;
	mAggregatedMetrics[tIndex].offTrajectorySumSquaredErrors +=
	offTrajectoryError * offTrajectoryError;
	const float pressureError = predictionPoint.pressure - latestGroundTruthPoint.pressure;
	mAggregatedMetrics[tIndex].pressureSumSquaredErrors += pressureError * pressureError;
	++mAggregatedMetrics[tIndex].generalErrorsCount;

	// Aggregate values into high-velocity metrics, if we are in one of the last two time buckets
	// and the velocity is above the threshold. Velocity here is measured in pixels per second.
	const float velocity = groundTruthTrajectory.norm() /
	(static_cast<float>(latestGroundTruthPoint.timestamp -
	previousGroundTruthPoint.timestamp) /
	NANOS_PER_SECOND);
	if ((tIndex + 2 >= mMaxNumPredictions) && (velocity > HIGH_VELOCITY_THRESHOLD)) {
	mAggregatedMetrics[tIndex].highVelocityAlongTrajectorySse +=
	alongTrajectoryError * alongTrajectoryError;
	mAggregatedMetrics[tIndex].highVelocityOffTrajectorySse +=
	offTrajectoryError * offTrajectoryError;
	++mAggregatedMetrics[tIndex].highVelocityErrorsCount;
	}

	// Compute path length for scale-invariant errors.
	float pathLength = 0;
	for (size_t i = 1; i < mRecentGroundTruthPoints.size(); ++i) {
	pathLength +=
	(mRecentGroundTruthPoints[i].position - mRecentGroundTruthPoints[i - 1].position)
	.norm();
	}
	// Avoid overweighting errors at the beginning of a stroke: compute the path length as if there
	// were a full ground truth history by filling in missing segments with the average length.
	// Note: the "- 1" is needed to translate from number of endpoints to number of segments.
	pathLength *= static_cast<float>(mRecentGroundTruthPoints.capacity() - 1) /
	(mRecentGroundTruthPoints.size() - 1);
	pathLength += PATH_LENGTH_EPSILON; // Ensure path length is nonzero (>= PATH_LENGTH_EPSILON).

	// Compute and aggregate scale-invariant errors.
	const float scaleInvariantAlongTrajectoryError = alongTrajectoryError / pathLength;
	const float scaleInvariantOffTrajectoryError = offTrajectoryError / pathLength;
	mAggregatedMetrics[tIndex].scaleInvariantAlongTrajectorySse +=
	scaleInvariantAlongTrajectoryError * scaleInvariantAlongTrajectoryError;
	mAggregatedMetrics[tIndex].scaleInvariantOffTrajectorySse +=
	scaleInvariantOffTrajectoryError * scaleInvariantOffTrajectoryError;
	++mAggregatedMetrics[tIndex].scaleInvariantErrorsCount;
	}

	void MotionPredictorMetricsManager::computeAtomFields() {
	for (size_t i = 0; i < mAggregatedMetrics.size(); ++i) {
	if (mAggregatedMetrics[i].generalErrorsCount == 0) {
	// We have not received data corresponding to metrics for this time bucket.
	continue;
	}

	mAtomFields[i].deltaTimeBucketMilliseconds =
	static_cast<int>(mPredictionInterval / NANOS_PER_MILLIS * (i + 1));

	// Note: we need the "* 1000"s below because we report values in integral milli-units.

	{ // General errors: reported for every time bucket.
	const float alongTrajectoryErrorMean = mAggregatedMetrics[i].alongTrajectoryErrorSum /
	mAggregatedMetrics[i].generalErrorsCount;
	mAtomFields[i].alongTrajectoryErrorMeanMillipixels =
	static_cast<int>(alongTrajectoryErrorMean * 1000);

	const float alongTrajectoryMse = mAggregatedMetrics[i].alongTrajectorySumSquaredErrors /
	mAggregatedMetrics[i].generalErrorsCount;
	// Take the max with 0 to avoid negative values caused by numerical instability.
	const float alongTrajectoryErrorVariance =
	std::max(0.0f,
	alongTrajectoryMse -
	alongTrajectoryErrorMean * alongTrajectoryErrorMean);
	const float alongTrajectoryErrorStd = std::sqrt(alongTrajectoryErrorVariance);
	mAtomFields[i].alongTrajectoryErrorStdMillipixels =
	static_cast<int>(alongTrajectoryErrorStd * 1000);

	LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].offTrajectorySumSquaredErrors < 0,
	"mAggregatedMetrics[%zu].offTrajectorySumSquaredErrors = %f should "
	"not be negative",
	i, mAggregatedMetrics[i].offTrajectorySumSquaredErrors);
	const float offTrajectoryRmse =
	std::sqrt(mAggregatedMetrics[i].offTrajectorySumSquaredErrors /
	mAggregatedMetrics[i].generalErrorsCount);
	mAtomFields[i].offTrajectoryRmseMillipixels =
	static_cast<int>(offTrajectoryRmse * 1000);

	LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].pressureSumSquaredErrors < 0,
	"mAggregatedMetrics[%zu].pressureSumSquaredErrors = %f should not "
	"be negative",
	i, mAggregatedMetrics[i].pressureSumSquaredErrors);
	const float pressureRmse = std::sqrt(mAggregatedMetrics[i].pressureSumSquaredErrors /
	mAggregatedMetrics[i].generalErrorsCount);
	mAtomFields[i].pressureRmseMilliunits = static_cast<int>(pressureRmse * 1000);
	}

	// High-velocity errors: reported only for last two time buckets.
	// Check if we are in one of the last two time buckets, and there is high-velocity data.
	if ((i + 2 >= mMaxNumPredictions) && (mAggregatedMetrics[i].highVelocityErrorsCount > 0)) {
	LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].highVelocityAlongTrajectorySse < 0,
	"mAggregatedMetrics[%zu].highVelocityAlongTrajectorySse = %f "
	"should not be negative",
	i, mAggregatedMetrics[i].highVelocityAlongTrajectorySse);
	const float alongTrajectoryRmse =
	std::sqrt(mAggregatedMetrics[i].highVelocityAlongTrajectorySse /
	mAggregatedMetrics[i].highVelocityErrorsCount);
	mAtomFields[i].highVelocityAlongTrajectoryRmse =
	static_cast<int>(alongTrajectoryRmse * 1000);

	LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[i].highVelocityOffTrajectorySse < 0,
	"mAggregatedMetrics[%zu].highVelocityOffTrajectorySse = %f should "
	"not be negative",
	i, mAggregatedMetrics[i].highVelocityOffTrajectorySse);
	const float offTrajectoryRmse =
	std::sqrt(mAggregatedMetrics[i].highVelocityOffTrajectorySse /
	mAggregatedMetrics[i].highVelocityErrorsCount);
	mAtomFields[i].highVelocityOffTrajectoryRmse =
	static_cast<int>(offTrajectoryRmse * 1000);
	}

	// Scale-invariant errors: reported only for the last time bucket, where the values
	// represent an average across all time buckets.
	if (i + 1 == mMaxNumPredictions) {
	// Compute error averages.
	float alongTrajectoryRmseSum = 0;
	float offTrajectoryRmseSum = 0;
	for (size_t j = 0; j < mAggregatedMetrics.size(); ++j) {
	// If we have general errors (checked above), we should always also have
	// scale-invariant errors.
	LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[j].scaleInvariantErrorsCount == 0,
	"mAggregatedMetrics[%zu].scaleInvariantErrorsCount is 0", j);

	LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[j].scaleInvariantAlongTrajectorySse < 0,
	"mAggregatedMetrics[%zu].scaleInvariantAlongTrajectorySse = %f "
	"should not be negative",
	j, mAggregatedMetrics[j].scaleInvariantAlongTrajectorySse);
	alongTrajectoryRmseSum +=
	std::sqrt(mAggregatedMetrics[j].scaleInvariantAlongTrajectorySse /
	mAggregatedMetrics[j].scaleInvariantErrorsCount);

	LOG_ALWAYS_FATAL_IF(mAggregatedMetrics[j].scaleInvariantOffTrajectorySse < 0,
	"mAggregatedMetrics[%zu].scaleInvariantOffTrajectorySse = %f "
	"should not be negative",
	j, mAggregatedMetrics[j].scaleInvariantOffTrajectorySse);
	offTrajectoryRmseSum +=
	std::sqrt(mAggregatedMetrics[j].scaleInvariantOffTrajectorySse /
	mAggregatedMetrics[j].scaleInvariantErrorsCount);
	}

	const float averageAlongTrajectoryRmse =
	alongTrajectoryRmseSum / mAggregatedMetrics.size();
	mAtomFields.back().scaleInvariantAlongTrajectoryRmse =
	static_cast<int>(averageAlongTrajectoryRmse * 1000);

	const float averageOffTrajectoryRmse = offTrajectoryRmseSum / mAggregatedMetrics.size();
	mAtomFields.back().scaleInvariantOffTrajectoryRmse =
	static_cast<int>(averageOffTrajectoryRmse * 1000);
	}
	}
	}

	void MotionPredictorMetricsManager::reportMetrics() {
	LOG_ALWAYS_FATAL_IF(!mReportAtomFunction);
	// Report one atom for each prediction time bucket.
	for (size_t i = 0; i < mAtomFields.size(); ++i) {
	mReportAtomFunction(mAtomFields[i]);
	}
	}

	} // namespace android