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520 lines
19 KiB
C++
520 lines
19 KiB
C++
/*
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* Copyright (c) 2013, Linux Foundation. All rights reserved
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*
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* Copyright (C) 2008 The Android Open Source Project
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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#include "base/basictypes.h"
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#include "mozilla/Hal.h"
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#include "mozilla/unused.h"
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#include "nsIScreen.h"
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#include "nsIScreenManager.h"
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#include "OrientationObserver.h"
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#include "ProcessOrientation.h"
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#include "mozilla/HalSensor.h"
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#include "math.h"
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#include "limits.h"
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#include "android/log.h"
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#if 0
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#define LOGD(args...) __android_log_print(ANDROID_LOG_DEBUG, "ProcessOrientation" , ## args)
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#else
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#define LOGD(args...)
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#endif
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namespace mozilla {
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// We work with all angles in degrees in this class.
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#define RADIANS_TO_DEGREES (180/M_PI)
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// Number of nanoseconds per millisecond.
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#define NANOS_PER_MS 1000000
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// Indices into SensorEvent.values for the accelerometer sensor.
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#define ACCELEROMETER_DATA_X 0
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#define ACCELEROMETER_DATA_Y 1
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#define ACCELEROMETER_DATA_Z 2
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// The minimum amount of time that a predicted rotation must be stable before
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// it is accepted as a valid rotation proposal. This value can be quite small
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// because the low-pass filter already suppresses most of the noise so we're
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// really just looking for quick confirmation that the last few samples are in
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// agreement as to the desired orientation.
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#define PROPOSAL_SETTLE_TIME_NANOS (40*NANOS_PER_MS)
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// The minimum amount of time that must have elapsed since the device last
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// exited the flat state (time since it was picked up) before the proposed
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// rotation can change.
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#define PROPOSAL_MIN_TIME_SINCE_FLAT_ENDED_NANOS (500*NANOS_PER_MS)
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// The minimum amount of time that must have elapsed since the device stopped
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// swinging (time since device appeared to be in the process of being put down
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// or put away into a pocket) before the proposed rotation can change.
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#define PROPOSAL_MIN_TIME_SINCE_SWING_ENDED_NANOS (300*NANOS_PER_MS)
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// The minimum amount of time that must have elapsed since the device stopped
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// undergoing external acceleration before the proposed rotation can change.
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#define PROPOSAL_MIN_TIME_SINCE_ACCELERATION_ENDED_NANOS (500*NANOS_PER_MS)
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// If the tilt angle remains greater than the specified angle for a minimum of
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// the specified time, then the device is deemed to be lying flat
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// (just chillin' on a table).
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#define FLAT_ANGLE 75
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#define FLAT_TIME_NANOS (1000*NANOS_PER_MS)
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// If the tilt angle has increased by at least delta degrees within the
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// specified amount of time, then the device is deemed to be swinging away
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// from the user down towards flat (tilt = 90).
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#define SWING_AWAY_ANGLE_DELTA 20
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#define SWING_TIME_NANOS (300*NANOS_PER_MS)
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// The maximum sample inter-arrival time in milliseconds. If the acceleration
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// samples are further apart than this amount in time, we reset the state of
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// the low-pass filter and orientation properties. This helps to handle
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// boundary conditions when the device is turned on, wakes from suspend or
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// there is a significant gap in samples.
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#define MAX_FILTER_DELTA_TIME_NANOS (1000*NANOS_PER_MS)
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// The acceleration filter time constant.
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//
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// This time constant is used to tune the acceleration filter such that
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// impulses and vibrational noise (think car dock) is suppressed before we try
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// to calculate the tilt and orientation angles.
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//
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// The filter time constant is related to the filter cutoff frequency, which
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// is the frequency at which signals are attenuated by 3dB (half the passband
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// power). Each successive octave beyond this frequency is attenuated by an
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// additional 6dB.
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//
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// Given a time constant t in seconds, the filter cutoff frequency Fc in Hertz
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// is given by Fc = 1 / (2pi * t).
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//
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// The higher the time constant, the lower the cutoff frequency, so more noise
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// will be suppressed.
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//
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// Filtering adds latency proportional the time constant (inversely
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// proportional to the cutoff frequency) so we don't want to make the time
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// constant too large or we can lose responsiveness. Likewise we don't want
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// to make it too small or we do a poor job suppressing acceleration spikes.
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// Empirically, 100ms seems to be too small and 500ms is too large. Android
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// default is 200.
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#define FILTER_TIME_CONSTANT_MS 200.0f
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// State for orientation detection. Thresholds for minimum and maximum
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// allowable deviation from gravity.
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//
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// If the device is undergoing external acceleration (being bumped, in a car
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// that is turning around a corner or a plane taking off) then the magnitude
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// may be substantially more or less than gravity. This can skew our
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// orientation detection by making us think that up is pointed in a different
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// direction.
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//
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// Conversely, if the device is in freefall, then there will be no gravity to
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// measure at all. This is problematic because we cannot detect the orientation
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// without gravity to tell us which way is up. A magnitude near 0 produces
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// singularities in the tilt and orientation calculations.
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//
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// In both cases, we postpone choosing an orientation.
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//
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// However, we need to tolerate some acceleration because the angular momentum
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// of turning the device can skew the observed acceleration for a short period
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// of time.
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#define NEAR_ZERO_MAGNITUDE 1 // m/s^2
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#define ACCELERATION_TOLERANCE 4 // m/s^2
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#define STANDARD_GRAVITY 9.80665f
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#define MIN_ACCELERATION_MAGNITUDE (STANDARD_GRAVITY-ACCELERATION_TOLERANCE)
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#define MAX_ACCELERATION_MAGNITUDE (STANDARD_GRAVITY+ACCELERATION_TOLERANCE)
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// Maximum absolute tilt angle at which to consider orientation data. Beyond
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// this (i.e. when screen is facing the sky or ground), we completely ignore
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// orientation data.
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#define MAX_TILT 75
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// The gap angle in degrees between adjacent orientation angles for
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// hysteresis.This creates a "dead zone" between the current orientation and a
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// proposed adjacent orientation. No orientation proposal is made when the
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// orientation angle is within the gap between the current orientation and the
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// adjacent orientation.
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#define ADJACENT_ORIENTATION_ANGLE_GAP 45
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const int
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ProcessOrientation::tiltTolerance[][4] = {
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{-25, 70}, // ROTATION_0
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{-25, 65}, // ROTATION_90
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{-25, 60}, // ROTATION_180
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{-25, 65} // ROTATION_270
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};
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int
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ProcessOrientation::GetProposedRotation()
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{
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return mProposedRotation;
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}
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int
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ProcessOrientation::OnSensorChanged(const SensorData& event,
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int deviceCurrentRotation)
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{
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// The vector given in the SensorEvent points straight up (towards the sky)
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// under ideal conditions (the phone is not accelerating). I'll call this up
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// vector elsewhere.
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const InfallibleTArray<float>& values = event.values();
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float x = values[ACCELEROMETER_DATA_X];
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float y = values[ACCELEROMETER_DATA_Y];
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float z = values[ACCELEROMETER_DATA_Z];
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LOGD
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("ProcessOrientation: Raw acceleration vector: x = %f, y = %f, z = %f,"
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"magnitude = %f\n", x, y, z, sqrt(x * x + y * y + z * z));
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// Apply a low-pass filter to the acceleration up vector in cartesian space.
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// Reset the orientation listener state if the samples are too far apart in
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// time or when we see values of (0, 0, 0) which indicates that we polled the
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// accelerometer too soon after turning it on and we don't have any data yet.
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const int64_t now = (int64_t) event.timestamp();
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const int64_t then = mLastFilteredTimestampNanos;
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const float timeDeltaMS = (now - then) * 0.000001f;
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bool skipSample = false;
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if (now < then
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|| now > then + MAX_FILTER_DELTA_TIME_NANOS
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|| (x == 0 && y == 0 && z == 0)) {
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LOGD
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("ProcessOrientation: Resetting orientation listener.");
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Reset();
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skipSample = true;
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} else {
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const float alpha = timeDeltaMS / (FILTER_TIME_CONSTANT_MS + timeDeltaMS);
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x = alpha * (x - mLastFilteredX) + mLastFilteredX;
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y = alpha * (y - mLastFilteredY) + mLastFilteredY;
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z = alpha * (z - mLastFilteredZ) + mLastFilteredZ;
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LOGD
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("ProcessOrientation: Filtered acceleration vector: x=%f, y=%f, z=%f,"
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"magnitude=%f", z, y, z, sqrt(x * x + y * y + z * z));
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skipSample = false;
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}
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mLastFilteredTimestampNanos = now;
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mLastFilteredX = x;
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mLastFilteredY = y;
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mLastFilteredZ = z;
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bool isAccelerating = false;
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bool isFlat = false;
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bool isSwinging = false;
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if (skipSample) {
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return -1;
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}
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// Calculate the magnitude of the acceleration vector.
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const float magnitude = sqrt(x * x + y * y + z * z);
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if (magnitude < NEAR_ZERO_MAGNITUDE) {
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LOGD
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("ProcessOrientation: Ignoring sensor data, magnitude too close to"
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" zero.");
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ClearPredictedRotation();
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} else {
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// Determine whether the device appears to be undergoing external
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// acceleration.
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if (this->IsAccelerating(magnitude)) {
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isAccelerating = true;
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mAccelerationTimestampNanos = now;
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}
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// Calculate the tilt angle. This is the angle between the up vector and
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// the x-y plane (the plane of the screen) in a range of [-90, 90]
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// degrees.
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// -90 degrees: screen horizontal and facing the ground (overhead)
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// 0 degrees: screen vertical
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// 90 degrees: screen horizontal and facing the sky (on table)
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const int tiltAngle =
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static_cast<int>(roundf(asin(z / magnitude) * RADIANS_TO_DEGREES));
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AddTiltHistoryEntry(now, tiltAngle);
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// Determine whether the device appears to be flat or swinging.
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if (this->IsFlat(now)) {
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isFlat = true;
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mFlatTimestampNanos = now;
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}
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if (this->IsSwinging(now, tiltAngle)) {
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isSwinging = true;
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mSwingTimestampNanos = now;
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}
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// If the tilt angle is too close to horizontal then we cannot determine
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// the orientation angle of the screen.
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if (abs(tiltAngle) > MAX_TILT) {
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LOGD
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("ProcessOrientation: Ignoring sensor data, tilt angle too high:"
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" tiltAngle=%d", tiltAngle);
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ClearPredictedRotation();
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} else {
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// Calculate the orientation angle.
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// This is the angle between the x-y projection of the up vector onto
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// the +y-axis, increasing clockwise in a range of [0, 360] degrees.
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int orientationAngle =
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static_cast<int>(roundf(-atan2f(-x, y) * RADIANS_TO_DEGREES));
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if (orientationAngle < 0) {
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// atan2 returns [-180, 180]; normalize to [0, 360]
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orientationAngle += 360;
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}
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// Find the nearest rotation.
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int nearestRotation = (orientationAngle + 45) / 90;
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if (nearestRotation == 4) {
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nearestRotation = 0;
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}
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// Determine the predicted orientation.
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if (IsTiltAngleAcceptable(nearestRotation, tiltAngle)
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&&
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IsOrientationAngleAcceptable
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(nearestRotation, orientationAngle, deviceCurrentRotation)) {
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UpdatePredictedRotation(now, nearestRotation);
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LOGD
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("ProcessOrientation: Predicted: tiltAngle=%d, orientationAngle=%d,"
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" predictedRotation=%d, predictedRotationAgeMS=%f",
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tiltAngle,
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orientationAngle,
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mPredictedRotation,
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((now - mPredictedRotationTimestampNanos) * 0.000001f));
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} else {
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LOGD
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("ProcessOrientation: Ignoring sensor data, no predicted rotation:"
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" tiltAngle=%d, orientationAngle=%d",
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tiltAngle,
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orientationAngle);
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ClearPredictedRotation();
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}
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}
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}
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// Determine new proposed rotation.
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const int oldProposedRotation = mProposedRotation;
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if (mPredictedRotation < 0 || IsPredictedRotationAcceptable(now)) {
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mProposedRotation = mPredictedRotation;
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}
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// Write final statistics about where we are in the orientation detection
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// process.
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LOGD
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("ProcessOrientation: Result: oldProposedRotation=%d,currentRotation=%d, "
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"proposedRotation=%d, predictedRotation=%d, timeDeltaMS=%f, "
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"isAccelerating=%d, isFlat=%d, isSwinging=%d, timeUntilSettledMS=%f, "
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"timeUntilAccelerationDelayExpiredMS=%f, timeUntilFlatDelayExpiredMS=%f, "
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"timeUntilSwingDelayExpiredMS=%f",
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oldProposedRotation,
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deviceCurrentRotation, mProposedRotation,
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mPredictedRotation, timeDeltaMS, isAccelerating, isFlat,
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isSwinging, RemainingMS(now,
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mPredictedRotationTimestampNanos +
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PROPOSAL_SETTLE_TIME_NANOS),
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RemainingMS(now,
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mAccelerationTimestampNanos +
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PROPOSAL_MIN_TIME_SINCE_ACCELERATION_ENDED_NANOS),
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RemainingMS(now,
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mFlatTimestampNanos +
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PROPOSAL_MIN_TIME_SINCE_FLAT_ENDED_NANOS),
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RemainingMS(now,
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mSwingTimestampNanos +
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PROPOSAL_MIN_TIME_SINCE_SWING_ENDED_NANOS));
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// Avoid unused-but-set compile warnings for these variables, when LOGD is
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// a no-op, as it is by default:
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Unused << isAccelerating;
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Unused << isFlat;
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Unused << isSwinging;
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// Tell the listener.
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if (mProposedRotation != oldProposedRotation && mProposedRotation >= 0) {
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LOGD
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("ProcessOrientation: Proposed rotation changed! proposedRotation=%d, "
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"oldProposedRotation=%d",
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mProposedRotation,
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oldProposedRotation);
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return mProposedRotation;
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}
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// Don't rotate screen
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return -1;
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}
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bool
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ProcessOrientation::IsTiltAngleAcceptable(int rotation, int tiltAngle)
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{
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return (tiltAngle >= tiltTolerance[rotation][0]
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&& tiltAngle <= tiltTolerance[rotation][1]);
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}
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bool
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ProcessOrientation::IsOrientationAngleAcceptable(int rotation,
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int orientationAngle,
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int currentRotation)
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{
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// If there is no current rotation, then there is no gap.
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// The gap is used only to introduce hysteresis among advertised orientation
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// changes to avoid flapping.
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if (currentRotation < 0) {
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return true;
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}
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// If the specified rotation is the same or is counter-clockwise adjacent
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// to the current rotation, then we set a lower bound on the orientation
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// angle. For example, if currentRotation is ROTATION_0 and proposed is
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// ROTATION_90, then we want to check orientationAngle > 45 + GAP / 2.
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if (rotation == currentRotation || rotation == (currentRotation + 1) % 4) {
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int lowerBound = rotation * 90 - 45 + ADJACENT_ORIENTATION_ANGLE_GAP / 2;
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if (rotation == 0) {
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if (orientationAngle >= 315 && orientationAngle < lowerBound + 360) {
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return false;
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}
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} else {
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if (orientationAngle < lowerBound) {
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return false;
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}
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}
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}
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// If the specified rotation is the same or is clockwise adjacent, then we
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// set an upper bound on the orientation angle. For example, if
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// currentRotation is ROTATION_0 and rotation is ROTATION_270, then we want
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// to check orientationAngle < 315 - GAP / 2.
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if (rotation == currentRotation || rotation == (currentRotation + 3) % 4) {
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int upperBound = rotation * 90 + 45 - ADJACENT_ORIENTATION_ANGLE_GAP / 2;
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if (rotation == 0) {
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if (orientationAngle <= 45 && orientationAngle > upperBound) {
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return false;
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}
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} else {
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if (orientationAngle > upperBound) {
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return false;
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}
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}
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}
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return true;
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}
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bool
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ProcessOrientation::IsPredictedRotationAcceptable(int64_t now)
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{
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// The predicted rotation must have settled long enough.
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if (now < mPredictedRotationTimestampNanos + PROPOSAL_SETTLE_TIME_NANOS) {
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return false;
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}
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// The last flat state (time since picked up) must have been sufficiently long
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// ago.
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if (now < mFlatTimestampNanos + PROPOSAL_MIN_TIME_SINCE_FLAT_ENDED_NANOS) {
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return false;
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}
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// The last swing state (time since last movement to put down) must have been
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// sufficiently long ago.
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if (now < mSwingTimestampNanos + PROPOSAL_MIN_TIME_SINCE_SWING_ENDED_NANOS) {
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return false;
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}
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// The last acceleration state must have been sufficiently long ago.
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if (now < mAccelerationTimestampNanos
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+ PROPOSAL_MIN_TIME_SINCE_ACCELERATION_ENDED_NANOS) {
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return false;
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}
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// Looks good!
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return true;
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}
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int
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ProcessOrientation::Reset()
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{
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mLastFilteredTimestampNanos = std::numeric_limits<int64_t>::min();
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mProposedRotation = -1;
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mFlatTimestampNanos = std::numeric_limits<int64_t>::min();
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mSwingTimestampNanos = std::numeric_limits<int64_t>::min();
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mAccelerationTimestampNanos = std::numeric_limits<int64_t>::min();
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ClearPredictedRotation();
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ClearTiltHistory();
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return -1;
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}
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void
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ProcessOrientation::ClearPredictedRotation()
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{
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mPredictedRotation = -1;
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mPredictedRotationTimestampNanos = std::numeric_limits<int64_t>::min();
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}
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void
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ProcessOrientation::UpdatePredictedRotation(int64_t now, int rotation)
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{
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if (mPredictedRotation != rotation) {
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mPredictedRotation = rotation;
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mPredictedRotationTimestampNanos = now;
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}
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}
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bool
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ProcessOrientation::IsAccelerating(float magnitude)
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{
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return magnitude < MIN_ACCELERATION_MAGNITUDE
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|| magnitude > MAX_ACCELERATION_MAGNITUDE;
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}
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void
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ProcessOrientation::ClearTiltHistory()
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{
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mTiltHistory.history[0].timestampNanos = std::numeric_limits<int64_t>::min();
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mTiltHistory.index = 1;
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}
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void
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ProcessOrientation::AddTiltHistoryEntry(int64_t now, float tilt)
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{
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mTiltHistory.history[mTiltHistory.index].tiltAngle = tilt;
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mTiltHistory.history[mTiltHistory.index].timestampNanos = now;
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mTiltHistory.index = (mTiltHistory.index + 1) % TILT_HISTORY_SIZE;
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mTiltHistory.history[mTiltHistory.index].timestampNanos = std::numeric_limits<int64_t>::min();
|
|
}
|
|
|
|
bool
|
|
ProcessOrientation::IsFlat(int64_t now)
|
|
{
|
|
for (int i = mTiltHistory.index; (i = NextTiltHistoryIndex(i)) >= 0;) {
|
|
if (mTiltHistory.history[i].tiltAngle < FLAT_ANGLE) {
|
|
break;
|
|
}
|
|
if (mTiltHistory.history[i].timestampNanos + FLAT_TIME_NANOS <= now) {
|
|
// Tilt has remained greater than FLAT_TILT_ANGLE for FLAT_TIME_NANOS.
|
|
return true;
|
|
}
|
|
}
|
|
return false;
|
|
}
|
|
|
|
bool
|
|
ProcessOrientation::IsSwinging(int64_t now, float tilt)
|
|
{
|
|
for (int i = mTiltHistory.index; (i = NextTiltHistoryIndex(i)) >= 0;) {
|
|
if (mTiltHistory.history[i].timestampNanos + SWING_TIME_NANOS < now) {
|
|
break;
|
|
}
|
|
if (mTiltHistory.history[i].tiltAngle + SWING_AWAY_ANGLE_DELTA <= tilt) {
|
|
// Tilted away by SWING_AWAY_ANGLE_DELTA within SWING_TIME_NANOS.
|
|
return true;
|
|
}
|
|
}
|
|
return false;
|
|
}
|
|
|
|
int
|
|
ProcessOrientation::NextTiltHistoryIndex(int index)
|
|
{
|
|
index = (index == 0 ? TILT_HISTORY_SIZE : index) - 1;
|
|
return mTiltHistory.history[index].timestampNanos != std::numeric_limits<int64_t>::min() ? index : -1;
|
|
}
|
|
|
|
float
|
|
ProcessOrientation::RemainingMS(int64_t now, int64_t until)
|
|
{
|
|
return now >= until ? 0 : (until - now) * 0.000001f;
|
|
}
|
|
|
|
} // namespace mozilla
|