@openhps/web-sensors
Version:
Open Hybrid Positioning System - Web Sensors API
171 lines • 7.78 kB
JavaScript
/// <reference types="web" />
import { SourceNode, Acceleration, Orientation, Quaternion, DataFrame, LinearAccelerationSensor as LinearAccelerationSensorObject, AbsoluteOrientationSensor as AbsoluteOrientationSensorObject, RelativeOrientationSensor as RelativeOrientationSensorObject, Magnetometer as MagnetometerObject, Gyroscope as GyroscopeObject, Accelerometer as AccelerometerObject, AngularVelocity, AngularVelocityUnit, Magnetism, AccelerationUnit, MagnetismUnit, } from '@openhps/core';
/**
* Sensor source node using Web Sensor API.
*/
export class SensorSourceNode extends SourceNode {
constructor(options) {
super(options);
this._subscriptions = new Map();
this._values = new Map();
this._lastPush = 0;
this._running = false;
this.options.interval = this.options.interval || 100;
if (this.options.autoStart) {
this.once('build', this.start.bind(this));
}
this.once('destroy', this.stop.bind(this));
}
static checkPermissions(sensors) {
return this.requestPermissions(sensors);
}
static requestPermissions(sensors) {
return new Promise((resolve, reject) => {
if (navigator.permissions === undefined || sensors === undefined || sensors.length === 0) {
return resolve(true);
}
Promise.all(sensors
.map((sensor) => this.getPermissions(sensor).map((permission) => navigator.permissions.query({ name: permission })))
.reduce((a, b) => [...a, ...b]))
.then((results) => {
if (results.every((result) => result.state === 'granted')) {
resolve(true);
}
else {
resolve(false);
}
})
.catch(reject);
});
}
requestPermissions() {
return SensorSourceNode.requestPermissions(this.options.sensors);
}
start() {
return new Promise((resolve) => {
this._running = true;
if (this._subscriptions.size > 0) {
return resolve();
}
this.options.sensors.forEach((sensor) => {
const SensorType = this.findSensor(sensor);
if (SensorType === undefined) {
// Not supported
return;
}
const sensorInstance = new SensorType({
frequency: Math.round(1000 / this.options.interval),
});
sensorInstance.addEventListener('reading', (event) => {
if (!this._running)
return;
this._values.set(sensor, event.target);
if (this._isUpdated()) {
this._lastPush = event.timeStamp;
this.createFrame().catch((ex) => {
this.logger('error', 'Unable to create sensor data frame!', ex);
});
}
});
sensorInstance.start();
this._subscriptions.set(sensor, sensorInstance);
});
resolve();
});
}
_isUpdated() {
return (Array.from(this._values.values()).filter((sensor) => sensor.timestamp > this._lastPush).length ===
Array.from(this._subscriptions.values()).filter((sensor) => sensor.activated).length);
}
stop() {
return new Promise((resolve) => {
if (this.options.softStop) {
this._running = false;
}
else {
this._subscriptions.forEach((value) => value.stop());
this._subscriptions = new Map();
this._values = new Map();
}
resolve();
});
}
createFrame() {
return new Promise((resolve) => {
const dataFrame = new DataFrame();
dataFrame.source = this.source;
const acceleration = this._values.get(AccelerometerObject);
const linearAcceleration = this._values.get(LinearAccelerationSensorObject);
const gyroscope = this._values.get(GyroscopeObject);
const orientation = this._values.get(AbsoluteOrientationSensorObject);
const relativeOrientation = this._values.get(RelativeOrientationSensorObject);
const magnetometer = this._values.get(MagnetometerObject);
const sourceUID = this.source ? this.source.uid : this.uid;
const frequency = 1000 / this.options.interval;
if (acceleration) {
dataFrame.addSensor(new AccelerometerObject(sourceUID + '_accel', new Acceleration(acceleration.x, acceleration.y, acceleration.z, AccelerationUnit.METER_PER_SECOND_SQUARE), frequency));
}
if (linearAcceleration) {
dataFrame.addSensor(new LinearAccelerationSensorObject(sourceUID + '_linearaccel', new Acceleration(linearAcceleration.x, linearAcceleration.y, linearAcceleration.z, AccelerationUnit.METER_PER_SECOND_SQUARE), frequency));
}
if (gyroscope) {
dataFrame.addSensor(new GyroscopeObject(sourceUID + '_gyro', new AngularVelocity(gyroscope.x, gyroscope.y, gyroscope.z, AngularVelocityUnit.RADIAN_PER_SECOND), frequency));
}
if (orientation) {
dataFrame.addSensor(new AbsoluteOrientationSensorObject(sourceUID + '_absoluteorientation', Orientation.fromQuaternion(new Quaternion(...orientation.quaternion)), frequency));
}
if (relativeOrientation) {
dataFrame.addSensor(new RelativeOrientationSensorObject(sourceUID + '_relativeorientation', Orientation.fromQuaternion(new Quaternion(...relativeOrientation.quaternion)), frequency));
}
if (magnetometer) {
dataFrame.addSensor(new MagnetometerObject(sourceUID + '_mag', new Magnetism(magnetometer.x, magnetometer.y, magnetometer.z, MagnetismUnit.MICROTESLA), frequency));
}
this.push(dataFrame);
resolve();
});
}
onPull() {
return new Promise((resolve) => {
resolve(undefined);
});
}
findSensor(sensor) {
switch (sensor) {
case RelativeOrientationSensorObject:
return RelativeOrientationSensor;
case AbsoluteOrientationSensorObject:
return AbsoluteOrientationSensor;
case LinearAccelerationSensorObject:
return LinearAccelerationSensor;
// case SensorType.AMBIENT_LIGHT:
// return AmbientLightSensor;
case GyroscopeObject:
return Gyroscope;
case MagnetometerObject:
return window.Magnetometer; // Experimental
case AccelerometerObject:
return Accelerometer;
default:
return undefined;
}
}
static getPermissions(sensor) {
switch (sensor) {
// case SensorType.AMBIENT_LIGHT:
// return ["ambient-light-sensor"];
case RelativeOrientationSensorObject:
case AbsoluteOrientationSensorObject:
return ['gyroscope', 'accelerometer', 'magnetometer'];
case GyroscopeObject:
return ['gyroscope'];
case MagnetometerObject:
return ['magnetometer'];
case LinearAccelerationSensorObject:
case AccelerometerObject:
return ['accelerometer'];
default:
return undefined;
}
}
}
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