services/audiopolicy/service/SpatializerPoseController.cpp

/*
 * Copyright 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 "SpatializerPoseController.h"

#define LOG_TAG "SpatializerPoseController"
//#define LOG_NDEBUG 0
#include <sensor/Sensor.h>
#include <utils/Log.h>
#include <utils/SystemClock.h>

namespace android {

using media::createHeadTrackingProcessor;
using media::HeadTrackingMode;
using media::HeadTrackingProcessor;
using media::Pose3f;
using media::SensorPoseProvider;
using media::Twist3f;

using namespace std::chrono_literals;

namespace {

// This is how fast, in m/s, we allow position to shift during rate-limiting.
constexpr auto kMaxTranslationalVelocity = 2;

// This is how fast, in rad/s, we allow rotation angle to shift during rate-limiting.
constexpr auto kMaxRotationalVelocity = 4 * M_PI;

// This should be set to the typical time scale that the translation sensors used drift in. This
// means, loosely, for how long we can trust the reading to be "accurate enough". This would
// determine the time constants used for high-pass filtering those readings. If the value is set
// too high, we may experience drift. If it is set too low, we may experience poses tending toward
// identity too fast.
constexpr auto kTranslationalDriftTimeConstant = 40s;

// This should be set to the typical time scale that the rotation sensors used drift in. This
// means, loosely, for how long we can trust the reading to be "accurate enough". This would
// determine the time constants used for high-pass filtering those readings. If the value is set
// too high, we may experience drift. If it is set too low, we may experience poses tending toward
// identity too fast.
constexpr auto kRotationalDriftTimeConstant = 40s;

// This is how far into the future we predict the head pose, using linear extrapolation based on
// twist (velocity). It should be set to a value that matches the characteristic durations of moving
// one's head. The higher we set this, the more latency we are able to reduce, but setting this too
// high will result in high prediction errors whenever the head accelerates (changes velocity).
constexpr auto kPredictionDuration = 10ms;

// After losing this many consecutive samples from either sensor, we would treat the measurement as
// stale;
constexpr auto kMaxLostSamples = 4;

// Auto-recenter kicks in after the head has been still for this long.
constexpr auto kAutoRecenterWindowDuration = 10s;

// Auto-recenter considers head not still if translated by this much (in meters, approx).
constexpr float kAutoRecenterTranslationThreshold = 0.1f;

// Auto-recenter considers head not still if rotated by this much (in radians, approx).
constexpr float kAutoRecenterRotationThreshold = 5.0f / 180 * M_PI;

// Time units for system clock ticks. This is what the Sensor Framework timestamps represent and
// what we use for pose filtering.
using Ticks = std::chrono::nanoseconds;

// How many ticks in a second.
constexpr auto kTicksPerSecond = Ticks::period::den;

}  // namespace

SpatializerPoseController::SpatializerPoseController(Listener* listener,
                                                     std::chrono::microseconds sensorPeriod,
                                                     std::chrono::microseconds maxUpdatePeriod)
    : mListener(listener),
      mSensorPeriod(sensorPeriod),
      mProcessor(createHeadTrackingProcessor(HeadTrackingProcessor::Options{
              .maxTranslationalVelocity = kMaxTranslationalVelocity / kTicksPerSecond,
              .maxRotationalVelocity = kMaxRotationalVelocity / kTicksPerSecond,
              .translationalDriftTimeConstant = Ticks(kTranslationalDriftTimeConstant).count(),
              .rotationalDriftTimeConstant = Ticks(kRotationalDriftTimeConstant).count(),
              .freshnessTimeout = Ticks(sensorPeriod * kMaxLostSamples).count(),
              .predictionDuration = Ticks(kPredictionDuration).count(),
              .autoRecenterWindowDuration = Ticks(kAutoRecenterWindowDuration).count(),
              .autoRecenterTranslationalThreshold = kAutoRecenterTranslationThreshold,
              .autoRecenterRotationalThreshold = kAutoRecenterRotationThreshold,
      })),
      mPoseProvider(SensorPoseProvider::create("headtracker", this)),
      mThread([this, maxUpdatePeriod] {
          while (true) {
              Pose3f headToStage;
              std::optional<HeadTrackingMode> modeIfChanged;
              {
                  std::unique_lock lock(mMutex);
                  mCondVar.wait_for(lock, maxUpdatePeriod,
                                    [this] { return mShouldExit || mShouldCalculate; });
                  if (mShouldExit) {
                      ALOGV("Exiting thread");
                      return;
                  }

                  // Calculate.
                  std::tie(headToStage, modeIfChanged) = calculate_l();
              }

              // Invoke the callbacks outside the lock.
              mListener->onHeadToStagePose(headToStage);
              if (modeIfChanged) {
                  mListener->onActualModeChange(modeIfChanged.value());
              }

              {
                  std::lock_guard lock(mMutex);
                  if (!mCalculated) {
                      mCalculated = true;
                      mCondVar.notify_all();
                  }
                  mShouldCalculate = false;
              }
          }
      }) {}

SpatializerPoseController::~SpatializerPoseController() {
    {
        std::unique_lock lock(mMutex);
        mShouldExit = true;
        mCondVar.notify_all();
    }
    mThread.join();
}

void SpatializerPoseController::setHeadSensor(int32_t sensor) {
    std::lock_guard lock(mMutex);
    // Stop current sensor, if valid and different from the other sensor.
    if (mHeadSensor != INVALID_SENSOR && mHeadSensor != mScreenSensor) {
        mPoseProvider->stopSensor(mHeadSensor);
    }

    if (sensor != INVALID_SENSOR) {
        if (sensor != mScreenSensor) {
            // Start new sensor.
            mHeadSensor =
                    mPoseProvider->startSensor(sensor, mSensorPeriod) ? sensor : INVALID_SENSOR;
        } else {
            // Sensor is already enabled.
            mHeadSensor = mScreenSensor;
        }
    } else {
        mHeadSensor = INVALID_SENSOR;
    }

    mProcessor->recenter(true, false);
}

void SpatializerPoseController::setScreenSensor(int32_t sensor) {
    std::lock_guard lock(mMutex);
    // Stop current sensor, if valid and different from the other sensor.
    if (mScreenSensor != INVALID_SENSOR && mScreenSensor != mHeadSensor) {
        mPoseProvider->stopSensor(mScreenSensor);
    }

    if (sensor != INVALID_SENSOR) {
        if (sensor != mHeadSensor) {
            // Start new sensor.
            mScreenSensor =
                    mPoseProvider->startSensor(sensor, mSensorPeriod) ? sensor : INVALID_SENSOR;
        } else {
            // Sensor is already enabled.
            mScreenSensor = mHeadSensor;
        }
    } else {
        mScreenSensor = INVALID_SENSOR;
    }

    mProcessor->recenter(false, true);
}

void SpatializerPoseController::setDesiredMode(HeadTrackingMode mode) {
    std::lock_guard lock(mMutex);
    mProcessor->setDesiredMode(mode);
}

void SpatializerPoseController::setScreenToStagePose(const Pose3f& screenToStage) {
    std::lock_guard lock(mMutex);
    mProcessor->setScreenToStagePose(screenToStage);
}

void SpatializerPoseController::setDisplayOrientation(float physicalToLogicalAngle) {
    std::lock_guard lock(mMutex);
    mProcessor->setDisplayOrientation(physicalToLogicalAngle);
}

void SpatializerPoseController::calculateAsync() {
    std::lock_guard lock(mMutex);
    mShouldCalculate = true;
    mCondVar.notify_all();
}

void SpatializerPoseController::waitUntilCalculated() {
    std::unique_lock lock(mMutex);
    mCondVar.wait(lock, [this] { return mCalculated; });
}

std::tuple<media::Pose3f, std::optional<media::HeadTrackingMode>>
SpatializerPoseController::calculate_l() {
    Pose3f headToStage;
    HeadTrackingMode mode;
    std::optional<media::HeadTrackingMode> modeIfChanged;

    mProcessor->calculate(elapsedRealtimeNano());
    headToStage = mProcessor->getHeadToStagePose();
    mode = mProcessor->getActualMode();
    if (!mActualMode.has_value() || mActualMode.value() != mode) {
        mActualMode = mode;
        modeIfChanged = mode;
    }
    return std::make_tuple(headToStage, modeIfChanged);
}

void SpatializerPoseController::recenter() {
    std::lock_guard lock(mMutex);
    mProcessor->recenter();
}

void SpatializerPoseController::onPose(int64_t timestamp, int32_t sensor, const Pose3f& pose,
                                       const std::optional<Twist3f>& twist, bool isNewReference) {
    std::lock_guard lock(mMutex);
    if (sensor == mHeadSensor) {
        mProcessor->setWorldToHeadPose(timestamp, pose, twist.value_or(Twist3f()));
        if (isNewReference) {
            mProcessor->recenter(true, false);
        }
    }
    if (sensor == mScreenSensor) {
        mProcessor->setWorldToScreenPose(timestamp, pose);
        if (isNewReference) {
            mProcessor->recenter(false, true);
        }
    }
}

}  // namespace android