media/libheadtracking/StillnessDetector.cpp - third_party/android/platform/frameworks/av - Git at Google

 /*
  * Copyright (C) 2021 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.
  */

 #include "StillnessDetector.h"

 namespace android {
 namespace media {

 StillnessDetector::StillnessDetector(const Options& options)
     : mOptions(options), mCosHalfRotationalThreshold(cos(mOptions.rotationalThreshold / 2)) {}

 void StillnessDetector::reset() {
     mFifo.clear();
     mWindowFull = false;
     mSuppressionDeadline.reset();
     // A "true" state indicates stillness is detected (default = true)
     mCurrentState = true;
     mPreviousState = true;
 }

 void StillnessDetector::setInput(int64_t timestamp, const Pose3f& input) {
     mFifo.push_back(TimestampedPose{timestamp, input});
     discardOld(timestamp);
 }

 bool StillnessDetector::getPreviousState() const {
     return mPreviousState;
 }

 bool StillnessDetector::calculate(int64_t timestamp) {
     // Move the current stillness state to the previous state.
     // This allows us to detect transitions into and out of stillness.
     mPreviousState = mCurrentState;

     discardOld(timestamp);

     // Check whether all the poses in the queue are in the proximity of the new one. We want to do
     // this before checking the overriding conditions below, in order to update the suppression
     // deadline correctly. We always go from end to start, to find the most recent pose that
     // violated stillness and update the suppression deadline if it has not been set or if the new
     // one ends after the current one.
     bool moved = false;

     if (!mFifo.empty()) {
         for (auto iter = mFifo.rbegin() + 1; iter != mFifo.rend(); ++iter) {
             const auto& event = *iter;
             if (!areNear(event.pose, mFifo.back().pose)) {
                 // Enable suppression for the duration of the window.
                 int64_t deadline = event.timestamp + mOptions.windowDuration;
                 if (!mSuppressionDeadline.has_value() || mSuppressionDeadline.value() < deadline) {
                     mSuppressionDeadline = deadline;
                 }
                 moved = true;
                 break;
             }
         }
     }

     // If the window has not been full, return the default value.
     if (!mWindowFull) {
         mCurrentState = mOptions.defaultValue;
     }
     // Force "in motion" while the suppression deadline is active.
     else if (mSuppressionDeadline.has_value()) {
         mCurrentState = false;
     }
     else {
         mCurrentState = !moved;
     }

     return mCurrentState;
 }

 void StillnessDetector::discardOld(int64_t timestamp) {
     // Handle the special case of the window duration being zero (always considered full).
     if (mOptions.windowDuration == 0) {
         mFifo.clear();
         mWindowFull = true;
     }

     // Remove any events from the queue that are older than the window. If there were any such
     // events we consider the window full.
     const int64_t windowStart = timestamp - mOptions.windowDuration;
     while (!mFifo.empty() && mFifo.front().timestamp <= windowStart) {
         mWindowFull = true;
         mFifo.pop_front();
     }

     // Expire the suppression deadline.
     if (mSuppressionDeadline.has_value() && mSuppressionDeadline <= timestamp) {
         mSuppressionDeadline.reset();
     }
 }

 bool StillnessDetector::areNear(const Pose3f& pose1, const Pose3f& pose2) const {
     // Check translation. We use the L1 norm to reduce computational load on expense of accuracy.
     // The L1 norm is an upper bound for the actual (L2) norm, so this approach will err on the side
     // of "not near".
     if ((pose1.translation() - pose2.translation()).lpNorm<1>() > mOptions.translationalThreshold) {
         return false;
     }

     // Check orientation.
     // The angle x between the quaternions is greater than that threshold iff
     // cos(x/2) < cos(threshold/2).
     // cos(x/2) can be efficiently calculated as the dot product of both quaternions.
     if (pose1.rotation().dot(pose2.rotation()) < mCosHalfRotationalThreshold) {
         return false;
     }

     return true;
 }

 }  // namespace media
 }  // namespace android
	/*
	* Copyright (C) 2021 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.
	*/

	#include "StillnessDetector.h"

	namespace android {
	namespace media {

	StillnessDetector::StillnessDetector(const Options& options)
	: mOptions(options), mCosHalfRotationalThreshold(cos(mOptions.rotationalThreshold / 2)) {}

	void StillnessDetector::reset() {
	mFifo.clear();
	mWindowFull = false;
	mSuppressionDeadline.reset();
	// A "true" state indicates stillness is detected (default = true)
	mCurrentState = true;
	mPreviousState = true;
	}

	void StillnessDetector::setInput(int64_t timestamp, const Pose3f& input) {
	mFifo.push_back(TimestampedPose{timestamp, input});
	discardOld(timestamp);
	}

	bool StillnessDetector::getPreviousState() const {
	return mPreviousState;
	}

	bool StillnessDetector::calculate(int64_t timestamp) {
	// Move the current stillness state to the previous state.
	// This allows us to detect transitions into and out of stillness.
	mPreviousState = mCurrentState;

	discardOld(timestamp);

	// Check whether all the poses in the queue are in the proximity of the new one. We want to do
	// this before checking the overriding conditions below, in order to update the suppression
	// deadline correctly. We always go from end to start, to find the most recent pose that
	// violated stillness and update the suppression deadline if it has not been set or if the new
	// one ends after the current one.
	bool moved = false;

	if (!mFifo.empty()) {
	for (auto iter = mFifo.rbegin() + 1; iter != mFifo.rend(); ++iter) {
	const auto& event = *iter;
	if (!areNear(event.pose, mFifo.back().pose)) {
	// Enable suppression for the duration of the window.
	int64_t deadline = event.timestamp + mOptions.windowDuration;
	if (!mSuppressionDeadline.has_value() \|\| mSuppressionDeadline.value() < deadline) {
	mSuppressionDeadline = deadline;
	}
	moved = true;
	break;
	}
	}
	}

	// If the window has not been full, return the default value.
	if (!mWindowFull) {
	mCurrentState = mOptions.defaultValue;
	}
	// Force "in motion" while the suppression deadline is active.
	else if (mSuppressionDeadline.has_value()) {
	mCurrentState = false;
	}
	else {
	mCurrentState = !moved;
	}

	return mCurrentState;
	}

	void StillnessDetector::discardOld(int64_t timestamp) {
	// Handle the special case of the window duration being zero (always considered full).
	if (mOptions.windowDuration == 0) {
	mFifo.clear();
	mWindowFull = true;
	}

	// Remove any events from the queue that are older than the window. If there were any such
	// events we consider the window full.
	const int64_t windowStart = timestamp - mOptions.windowDuration;
	while (!mFifo.empty() && mFifo.front().timestamp <= windowStart) {
	mWindowFull = true;
	mFifo.pop_front();
	}

	// Expire the suppression deadline.
	if (mSuppressionDeadline.has_value() && mSuppressionDeadline <= timestamp) {
	mSuppressionDeadline.reset();
	}
	}

	bool StillnessDetector::areNear(const Pose3f& pose1, const Pose3f& pose2) const {
	// Check translation. We use the L1 norm to reduce computational load on expense of accuracy.
	// The L1 norm is an upper bound for the actual (L2) norm, so this approach will err on the side
	// of "not near".
	if ((pose1.translation() - pose2.translation()).lpNorm<1>() > mOptions.translationalThreshold) {
	return false;
	}

	// Check orientation.
	// The angle x between the quaternions is greater than that threshold iff
	// cos(x/2) < cos(threshold/2).
	// cos(x/2) can be efficiently calculated as the dot product of both quaternions.
	if (pose1.rotation().dot(pose2.rotation()) < mCosHalfRotationalThreshold) {
	return false;
	}

	return true;
	}

	} // namespace media
	} // namespace android