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/*
* Copyright (C) 2010 Apple Inc. All Rights Reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#import "config.h"
#import "WebCoreMotionManager.h"
#if PLATFORM(IOS_FAMILY) && ENABLE(DEVICE_ORIENTATION)
#import "WebCoreObjCExtras.h"
#import "WebCoreThreadRun.h"
#import <CoreLocation/CoreLocation.h>
#import <CoreMotion/CoreMotion.h>
#import <objc/objc-runtime.h>
#import <wtf/MathExtras.h>
#import <wtf/SoftLinking.h>
// Get CoreLocation classes
SOFT_LINK_FRAMEWORK(CoreLocation)
SOFT_LINK_CLASS(CoreLocation, CLLocationManager)
SOFT_LINK_CLASS(CoreLocation, CLHeading)
// Get CoreMotion classes
SOFT_LINK_FRAMEWORK(CoreMotion)
SOFT_LINK_CLASS(CoreMotion, CMMotionManager)
SOFT_LINK_CLASS(CoreMotion, CMAccelerometerData)
SOFT_LINK_CLASS(CoreMotion, CMDeviceMotion)
static const double kGravity = 9.80665;
@interface WebCoreMotionManager(Private)
- (void)initializeOnMainThread;
- (void)checkClientStatus;
- (void)update;
- (void)sendAccelerometerData:(CMAccelerometerData *)newAcceleration;
- (void)sendMotionData:(CMDeviceMotion *)newMotion withHeading:(CLHeading *)newHeading;
@end
@implementation WebCoreMotionManager
+ (WebCoreMotionManager *)sharedManager
{
static WebCoreMotionManager *sharedMotionManager = [[WebCoreMotionManager alloc] init];
return sharedMotionManager;
}
- (id)init
{
self = [super init];
if (self)
[self performSelectorOnMainThread:@selector(initializeOnMainThread) withObject:nil waitUntilDone:NO];
return self;
}
- (void)dealloc
{
if (WebCoreObjCScheduleDeallocateOnMainThread([WebCoreMotionManager class], self))
return;
ASSERT(!m_updateTimer);
if (m_headingAvailable)
[m_locationManager stopUpdatingHeading];
[m_locationManager release];
if (m_gyroAvailable)
[m_motionManager stopDeviceMotionUpdates];
else
[m_motionManager stopAccelerometerUpdates];
[m_motionManager release];
[super dealloc];
}
- (void)addMotionClient:(WebCore::DeviceMotionClientIOS *)client
{
m_deviceMotionClients.add(client);
if (m_initialized)
[self checkClientStatus];
}
- (void)removeMotionClient:(WebCore::DeviceMotionClientIOS *)client
{
m_deviceMotionClients.remove(client);
if (m_initialized)
[self checkClientStatus];
}
- (void)addOrientationClient:(WebCore::DeviceOrientationClientIOS *)client
{
m_deviceOrientationClients.add(client);
if (m_initialized)
[self checkClientStatus];
}
- (void)removeOrientationClient:(WebCore::DeviceOrientationClientIOS *)client
{
m_deviceOrientationClients.remove(client);
if (m_initialized)
[self checkClientStatus];
}
- (BOOL)gyroAvailable
{
return m_gyroAvailable;
}
- (BOOL)headingAvailable
{
return m_headingAvailable;
}
- (void)initializeOnMainThread
{
ASSERT(!WebThreadIsCurrent());
m_motionManager = [allocCMMotionManagerInstance() init];
m_gyroAvailable = m_motionManager.deviceMotionAvailable;
if (m_gyroAvailable)
m_motionManager.deviceMotionUpdateInterval = kMotionUpdateInterval;
else
m_motionManager.accelerometerUpdateInterval = kMotionUpdateInterval;
m_locationManager = [allocCLLocationManagerInstance() init];
m_headingAvailable = [getCLLocationManagerClass() headingAvailable];
m_initialized = YES;
[self checkClientStatus];
}
- (void)checkClientStatus
{
if (!pthread_main_np()) {
[self performSelectorOnMainThread:_cmd withObject:nil waitUntilDone:NO];
return;
}
// Since this method executes on the main thread, it should always be called
// after the initializeOnMainThread method has run, and hence there should
// be no chance that m_motionManager has not been created.
ASSERT(m_motionManager);
if (m_deviceMotionClients.size() || m_deviceOrientationClients.size()) {
if (m_gyroAvailable)
[m_motionManager startDeviceMotionUpdates];
else
[m_motionManager startAccelerometerUpdates];
if (m_headingAvailable)
[m_locationManager startUpdatingHeading];
if (!m_updateTimer) {
m_updateTimer = [[NSTimer scheduledTimerWithTimeInterval:kMotionUpdateInterval
target:self
selector:@selector(update)
userInfo:nil
repeats:YES] retain];
}
} else {
NSTimer *timer = m_updateTimer;
m_updateTimer = nil;
[timer invalidate];
[timer release];
if (m_gyroAvailable)
[m_motionManager stopDeviceMotionUpdates];
else
[m_motionManager stopAccelerometerUpdates];
if (m_headingAvailable)
[m_locationManager stopUpdatingHeading];
}
}
- (void)update
{
// It's extremely unlikely that an update happens without an active
// motion or location manager, but we should guard for this case just in case.
if (!m_motionManager || !m_locationManager)
return;
// We should, however, guard for the case where the managers return nil data.
CMDeviceMotion *deviceMotion = m_motionManager.deviceMotion;
if (m_gyroAvailable && deviceMotion)
[self sendMotionData:deviceMotion withHeading:m_locationManager.heading];
else {
if (CMAccelerometerData *accelerometerData = m_motionManager.accelerometerData)
[self sendAccelerometerData:accelerometerData];
}
}
- (void)sendAccelerometerData:(CMAccelerometerData *)newAcceleration
{
WebThreadRun(^{
CMAcceleration accel = newAcceleration.acceleration;
for (auto& client : copyToVector(m_deviceMotionClients))
client->motionChanged(0, 0, 0, accel.x * kGravity, accel.y * kGravity, accel.z * kGravity, 0, 0, 0);
});
}
- (void)sendMotionData:(CMDeviceMotion *)newMotion withHeading:(CLHeading *)newHeading
{
WebThreadRun(^{
// Acceleration is user + gravity
CMAcceleration userAccel = newMotion.userAcceleration;
CMAcceleration gravity = newMotion.gravity;
CMAcceleration totalAccel;
totalAccel.x = userAccel.x + gravity.x;
totalAccel.y = userAccel.y + gravity.y;
totalAccel.z = userAccel.z + gravity.z;
CMRotationRate rotationRate = newMotion.rotationRate;
for (auto& client : copyToVector(m_deviceMotionClients))
client->motionChanged(userAccel.x * kGravity, userAccel.y * kGravity, userAccel.z * kGravity, totalAccel.x * kGravity, totalAccel.y * kGravity, totalAccel.z * kGravity, rad2deg(rotationRate.x), rad2deg(rotationRate.y), rad2deg(rotationRate.z));
CMAttitude* attitude = newMotion.attitude;
auto orientationClients = copyToVector(m_deviceOrientationClients);
// Compose the raw motion data to an intermediate ZXY-based 3x3 rotation
// matrix (R) where [z=attitude.yaw, x=attitude.pitch, y=attitude.roll]
// in the form:
//
// / R[0] R[1] R[2] \
// | R[3] R[4] R[5] |
// \ R[6] R[7] R[8] /
double cX = cos(attitude.pitch);
double cY = cos(attitude.roll);
double cZ = cos(attitude.yaw);
double sX = sin(attitude.pitch);
double sY = sin(attitude.roll);
double sZ = sin(attitude.yaw);
double R[] = {
cZ * cY - sZ * sX * sY,
- cX * sZ,
cY * sZ * sX + cZ * sY,
cY * sZ + cZ * sX * sY,
cZ * cX,
sZ * sY - cZ * cY * sX,
- cX * sY,
sX,
cX * cY
};
// Compute correct, normalized values for DeviceOrientation from
// rotation matrix (R) according to the angle conventions defined in the
// W3C DeviceOrientation specification.
double zRot;
double xRot;
double yRot;
if (R[8] > 0) {
zRot = atan2(-R[1], R[4]);
xRot = asin(R[7]);
yRot = atan2(-R[6], R[8]);
} else if (R[8] < 0) {
zRot = atan2(R[1], -R[4]);
xRot = -asin(R[7]);
xRot += (xRot >= 0) ? -M_PI : M_PI;
yRot = atan2(R[6], -R[8]);
} else {
if (R[6] > 0) {
zRot = atan2(-R[1], R[4]);
xRot = asin(R[7]);
yRot = -M_PI_2;
} else if (R[6] < 0) {
zRot = atan2(R[1], -R[4]);
xRot = -asin(R[7]);
xRot += (xRot >= 0) ? -M_PI : M_PI;
yRot = -M_PI_2;
} else {
zRot = atan2(R[3], R[0]);
xRot = (R[7] > 0) ? M_PI_2 : -M_PI_2;
yRot = 0;
}
}
// Rotation around the Z axis (pointing up. normalized to [0, 360] deg).
double alpha = rad2deg(zRot > 0 ? zRot : (M_PI * 2 + zRot));
// Rotation around the X axis (top to bottom).
double beta = rad2deg(xRot);
// Rotation around the Y axis (side to side).
double gamma = rad2deg(yRot);
double heading = (m_headingAvailable && newHeading) ? newHeading.magneticHeading : 0;
double headingAccuracy = (m_headingAvailable && newHeading) ? newHeading.headingAccuracy : -1;
for (size_t i = 0; i < orientationClients.size(); ++i)
orientationClients[i]->orientationChanged(alpha, beta, gamma, heading, headingAccuracy);
});
}
@end
#endif