723 lines
26 KiB
JavaScript
723 lines
26 KiB
JavaScript
'use strict';
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// Run a set of tests for a given |sensorName|.
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// |readingData| is an object with 3 keys, all of which are arrays of arrays:
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// 1. "readings". Each value corresponds to one raw reading that will be
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// processed by a sensor.
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// 2. "expectedReadings". Each value corresponds to the processed value a
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// sensor will make available to users (i.e. a capped or rounded value).
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// Its length must match |readings|'.
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// 3. "expectedRemappedReadings" (optional). Similar to |expectedReadings|, but
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// used only by spatial sensors, whose reference frame can change the values
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// returned by a sensor.
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// Its length should match |readings|'.
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// |verificationFunction| is called to verify that a given reading matches a
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// value in |expectedReadings|.
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// |featurePolicies| represents |sensorName|'s associated sensor feature name.
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function runGenericSensorTests(sensorData, readingData) {
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validate_sensor_data(sensorData);
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validate_reading_data(readingData);
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const {sensorName, permissionName, testDriverName, featurePolicyNames} =
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sensorData;
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const sensorType = self[sensorName];
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function sensor_test(func, name, properties) {
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promise_test(async t => {
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assert_implements(sensorName in self, `${sensorName} is not supported.`);
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const readings = new RingBuffer(readingData.readings);
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const expectedReadings = new RingBuffer(readingData.expectedReadings);
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const expectedRemappedReadings = readingData.expectedRemappedReadings ?
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new RingBuffer(readingData.expectedRemappedReadings) :
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undefined;
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return func(t, readings, expectedReadings, expectedRemappedReadings);
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}, name, properties);
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}
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promise_setup(async () => {
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// Ensure window's document has focus so that the global under test can
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// receive data.
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await test_driver.click(document.documentElement);
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});
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'denied'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType;
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['reading', 'error']);
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sensor.start();
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const event = await sensorWatcher.wait_for('error');
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assert_false(sensor.activated);
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assert_equals(event.error.name, 'NotAllowedError');
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}, `${sensorName}: Test that onerror is sent when permissions are not\
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granted.`);
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName, {connected: false});
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const sensor = new sensorType;
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['reading', 'error']);
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sensor.start();
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const event = await sensorWatcher.wait_for('error');
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assert_false(sensor.activated);
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assert_equals(event.error.name, 'NotReadableError');
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}, `${sensorName}: Test that onerror is send when start() call has failed.`);
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType({frequency: 560});
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['activate', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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const mockSensorInfo =
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await test_driver.get_virtual_sensor_information(testDriverName);
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assert_less_than_equal(mockSensorInfo.requestedSamplingFrequency, 60);
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}, `${sensorName}: Test that frequency is capped to allowed maximum.`);
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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const maxSupportedFrequency = 5;
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await test_driver.create_virtual_sensor(
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testDriverName, {maxSamplingFrequency: maxSupportedFrequency});
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const sensor = new sensorType({frequency: 50});
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['activate', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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const mockSensorInfo =
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await test_driver.get_virtual_sensor_information(testDriverName);
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assert_equals(
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mockSensorInfo.requestedSamplingFrequency, maxSupportedFrequency);
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}, `${sensorName}: Test that frequency is capped to the maximum supported\
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frequency.`);
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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const minSupportedFrequency = 2;
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await test_driver.create_virtual_sensor(
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testDriverName, {minSamplingFrequency: minSupportedFrequency});
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const sensor = new sensorType({frequency: -1});
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['activate', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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const mockSensorInfo =
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await test_driver.get_virtual_sensor_information(testDriverName);
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assert_equals(
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mockSensorInfo.requestedSamplingFrequency, minSupportedFrequency);
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}, `${sensorName}: Test that frequency is limited to the minimum supported\
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frequency.`);
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sensor_test(async t => {
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const iframe = document.createElement('iframe');
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iframe.allow = featurePolicyNames.join(' \'none\'; ') + ' \'none\';';
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iframe.srcdoc = '<script>' +
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' window.onmessage = message => {' +
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' if (message.data === "LOADED") {' +
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' try {' +
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' new ' + sensorName + '();' +
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' parent.postMessage("FAIL", "*");' +
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' } catch (e) {' +
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' parent.postMessage(`PASS: got ${e.name}`, "*");' +
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' }' +
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' }' +
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' };' +
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'<\/script>';
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const iframeWatcher = new EventWatcher(t, iframe, 'load');
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document.body.appendChild(iframe);
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await iframeWatcher.wait_for('load');
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iframe.contentWindow.postMessage('LOADED', '*');
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const windowWatcher = new EventWatcher(t, window, 'message');
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const message = await windowWatcher.wait_for('message');
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assert_equals(message.data, 'PASS: got SecurityError');
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}, `${sensorName}: Test that sensor cannot be constructed within iframe\
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disallowed to use feature policy.`);
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sensor_test(async t => {
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const iframe = document.createElement('iframe');
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iframe.allow = featurePolicyNames.join(';') + ';';
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iframe.srcdoc = '<script>' +
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' window.onmessage = message => {' +
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' if (message.data === "LOADED") {' +
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' try {' +
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' new ' + sensorName + '();' +
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' parent.postMessage("PASS", "*");' +
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' } catch (e) {' +
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' parent.postMessage("FAIL", "*");' +
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' }' +
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' }' +
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' };' +
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'<\/script>';
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const iframeWatcher = new EventWatcher(t, iframe, 'load');
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document.body.appendChild(iframe);
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await iframeWatcher.wait_for('load');
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iframe.contentWindow.postMessage('LOADED', '*');
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const windowWatcher = new EventWatcher(t, window, 'message');
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const message = await windowWatcher.wait_for('message');
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assert_equals(message.data, 'PASS');
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}, `${sensorName}: Test that sensor can be constructed within an iframe\
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allowed to use feature policy.`);
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sensor_test(async (t, readings, expectedReadings) => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType;
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher =
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new EventWatcher(t, sensor, ['activate', 'reading', 'error']);
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sensor.start();
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assert_false(sensor.hasReading);
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await sensorWatcher.wait_for('activate');
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await Promise.all([
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test_driver.update_virtual_sensor(testDriverName, readings.next().value),
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sensorWatcher.wait_for('reading')
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]);
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assert_sensor_reading_equals(sensor, expectedReadings.next().value);
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assert_true(sensor.hasReading);
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sensor.stop();
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assert_sensor_reading_is_null(sensor);
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assert_false(sensor.hasReading);
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}, `${sensorName}: Test that 'onreading' is called and sensor reading is\
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valid.`);
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sensor_test(async (t, readings, expectedReadings) => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor1 = new sensorType();
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const sensor2 = new sensorType();
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t.add_cleanup(async () => {
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sensor1.stop();
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sensor2.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher1 =
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new EventWatcher(t, sensor1, ['activate', 'reading', 'error']);
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const sensorWatcher2 =
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new EventWatcher(t, sensor2, ['activate', 'reading', 'error']);
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sensor1.start();
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sensor2.start();
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await Promise.all([
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sensorWatcher1.wait_for('activate'), sensorWatcher2.wait_for('activate')
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]);
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await Promise.all([
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test_driver.update_virtual_sensor(testDriverName, readings.next().value),
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sensorWatcher1.wait_for('reading'), sensorWatcher2.wait_for('reading')
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]);
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// Reading values are correct for both sensors.
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const expected = expectedReadings.next().value;
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assert_sensor_reading_equals(sensor1, expected);
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assert_sensor_reading_equals(sensor2, expected);
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// After first sensor stops its reading values are null,
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// reading values for the second sensor sensor remain.
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sensor1.stop();
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assert_sensor_reading_is_null(sensor1);
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assert_sensor_reading_equals(sensor2, expected);
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sensor2.stop();
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assert_sensor_reading_is_null(sensor2);
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}, `${sensorName}: sensor reading is correct.`);
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// Tests that readings maps to expectedReadings correctly. Due to threshold
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// check and rounding some values might be discarded or changed.
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sensor_test(async (t, readings, expectedReadings) => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType();
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher =
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new EventWatcher(t, sensor, ['activate', 'reading', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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const sensorInfo =
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await test_driver.get_virtual_sensor_information(testDriverName);
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const sensorPeriodInMs = (1 / sensorInfo.requestedSamplingFrequency) * 1000;
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for (let expectedReading of expectedReadings.data) {
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await update_virtual_sensor_until_reading(
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t, readings, sensorWatcher.wait_for('reading'), testDriverName,
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sensorPeriodInMs * 3);
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assert_true(sensor.hasReading, 'hasReading');
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assert_sensor_reading_equals(sensor, expectedReading);
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}
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}, `${sensorName}: Test that readings are all mapped to expectedReadings\
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correctly.`);
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sensor_test(async (t, readings) => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType();
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher =
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new EventWatcher(t, sensor, ['activate', 'reading', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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const sensorInfo =
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await test_driver.get_virtual_sensor_information(testDriverName);
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const sensorPeriodInMs = (1 / sensorInfo.requestedSamplingFrequency) * 1000;
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await Promise.all([
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test_driver.update_virtual_sensor(testDriverName, readings.next().value),
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sensorWatcher.wait_for('reading')
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]);
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const cachedTimeStamp1 = sensor.timestamp;
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await update_virtual_sensor_until_reading(
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t, readings, sensorWatcher.wait_for('reading'), testDriverName,
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sensorPeriodInMs * 3);
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const cachedTimeStamp2 = sensor.timestamp;
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assert_greater_than(cachedTimeStamp2, cachedTimeStamp1);
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}, `${sensorName}: sensor timestamp is updated when time passes.`);
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType();
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['activate', 'error']);
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assert_false(sensor.activated);
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sensor.start();
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assert_false(sensor.activated);
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await sensorWatcher.wait_for('activate');
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assert_true(sensor.activated);
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sensor.stop();
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assert_false(sensor.activated);
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}, `${sensorName}: Test that sensor can be successfully created and its\
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states are correct.`);
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType();
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['activate', 'error']);
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sensor.start();
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sensor.start();
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await sensorWatcher.wait_for('activate');
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assert_true(sensor.activated);
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}, `${sensorName}: no exception is thrown when calling start() on already\
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started sensor.`);
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sensor_test(async t => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType();
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['activate', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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sensor.stop();
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sensor.stop();
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assert_false(sensor.activated);
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}, `${sensorName}: no exception is thrown when calling stop() on already\
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stopped sensor.`);
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sensor_test(async (t, readings, expectedReadings) => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType();
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher =
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new EventWatcher(t, sensor, ['activate', 'reading', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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await Promise.all([
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test_driver.update_virtual_sensor(testDriverName, readings.next().value),
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sensorWatcher.wait_for('reading')
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]);
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assert_true(sensor.hasReading);
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const expected = expectedReadings.next().value;
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assert_sensor_reading_equals(sensor, expected);
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const timestamp = sensor.timestamp;
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sensor.stop();
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assert_false(sensor.hasReading);
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assert_false(sensor.activated);
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readings.reset();
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await test_driver.update_virtual_sensor(
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testDriverName, readings.next().value);
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sensor.start();
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// Starting |sensor| again will cause the backing virtual sensor to report
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// the previous reading automatically.
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await sensorWatcher.wait_for('activate');
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await sensorWatcher.wait_for('reading');
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assert_sensor_reading_equals(sensor, expected);
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// Make sure that 'timestamp' is already initialized.
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assert_greater_than(timestamp, 0);
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// Check that the reading is updated.
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assert_greater_than(sensor.timestamp, timestamp);
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}, `${sensorName}: Test that fresh reading is fetched on start().`);
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sensor_test(async (t, readings, expectedReadings) => {
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await test_driver.bidi.permissions.set_permission(
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{descriptor: {name: permissionName}, state: 'granted'});
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await test_driver.create_virtual_sensor(testDriverName);
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const sensor = new sensorType();
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t.add_cleanup(async () => {
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sensor.stop();
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await test_driver.remove_virtual_sensor(testDriverName);
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});
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const sensorWatcher = new EventWatcher(t, sensor, ['activate', 'error']);
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sensor.start();
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await sensorWatcher.wait_for('activate');
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assert_false(sensor.hasReading);
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assert_sensor_reading_is_null(sensor);
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const {minimize, restore} = window_state_context(t);
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await minimize();
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assert_true(document.hidden);
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assert_true(sensor.activated);
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assert_false(sensor.hasReading);
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assert_sensor_reading_is_null(sensor);
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const hiddenEventPromise = new Promise(resolve => {
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sensor.addEventListener('reading', t.step_func((event) => {
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assert_false(document.hidden);
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resolve(event);
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|
}, {once: true}));
|
|
});
|
|
|
|
const reading = readings.next().value;
|
|
await test_driver.update_virtual_sensor(testDriverName, reading);
|
|
|
|
const visibilityChangeEventPromise =
|
|
new EventWatcher(t, document, 'visibilitychange')
|
|
.wait_for('visibilitychange');
|
|
|
|
const preRestoreTimestamp = performance.now();
|
|
await restore();
|
|
|
|
const readingEvent = await hiddenEventPromise;
|
|
|
|
assert_false(document.hidden);
|
|
assert_true(sensor.activated);
|
|
assert_true(sensor.hasReading);
|
|
assert_sensor_reading_equals(sensor, expectedReadings.next().value);
|
|
|
|
// Check that a reading sent while the page is hidden is stashed and
|
|
// triggers an update only when it is visible again: the original timestamp
|
|
// remains, but the event is emitted only after the "visibilitychange"
|
|
// event is fired.
|
|
assert_less_than(
|
|
sensor.timestamp, preRestoreTimestamp,
|
|
'Original sensor timestamp is used even if the update is delayed');
|
|
assert_greater_than(
|
|
readingEvent.timeStamp, (await visibilityChangeEventPromise).timeStamp,
|
|
'Sensor "reading" event is always emitted after page visibility is restored');
|
|
}, `${sensorName}: Readings are not delivered when the page has no visibility`);
|
|
|
|
sensor_test(async t => {
|
|
await test_driver.bidi.permissions.set_permission(
|
|
{descriptor: {name: permissionName}, state: 'granted'});
|
|
|
|
await test_driver.create_virtual_sensor(testDriverName);
|
|
|
|
const fastSensor = new sensorType({frequency: 60});
|
|
t.add_cleanup(() => {
|
|
fastSensor.stop();
|
|
});
|
|
let eventWatcher = new EventWatcher(t, fastSensor, ['activate']);
|
|
fastSensor.start();
|
|
|
|
// Wait for |fastSensor| to be activated so that the call to
|
|
// getSamplingFrequency() below works.
|
|
await eventWatcher.wait_for('activate');
|
|
|
|
let mockSensorInfo =
|
|
await test_driver.get_virtual_sensor_information(testDriverName);
|
|
|
|
// We need |fastSensorFrequency| because 60Hz might be higher than a sensor
|
|
// type's maximum allowed frequency.
|
|
const fastSensorFrequency = mockSensorInfo.requestedSamplingFrequency;
|
|
const slowSensorFrequency = fastSensorFrequency * 0.25;
|
|
|
|
const slowSensor = new sensorType({frequency: slowSensorFrequency});
|
|
t.add_cleanup(() => {
|
|
slowSensor.stop();
|
|
});
|
|
t.add_cleanup(async () => {
|
|
// Remove the virtual sensor only after calling stop() on both sensors.
|
|
await test_driver.remove_virtual_sensor(testDriverName);
|
|
});
|
|
eventWatcher = new EventWatcher(t, slowSensor, 'activate');
|
|
slowSensor.start();
|
|
|
|
// Wait for |slowSensor| to be activated before we check if the mock
|
|
// platform sensor's sampling frequency has changed.
|
|
await eventWatcher.wait_for('activate');
|
|
mockSensorInfo =
|
|
await test_driver.get_virtual_sensor_information(testDriverName);
|
|
assert_equals(
|
|
mockSensorInfo.requestedSamplingFrequency, fastSensorFrequency);
|
|
|
|
// Now stop |fastSensor| and verify that the sampling frequency has dropped
|
|
// to the one |slowSensor| had requested.
|
|
fastSensor.stop();
|
|
await wait_for_virtual_sensor_state(testDriverName, (info) => {
|
|
return info.requestedSamplingFrequency === slowSensorFrequency;
|
|
});
|
|
}, `${sensorName}: frequency hint works.`);
|
|
|
|
sensor_test(async (t, readings, expectedReadings) => {
|
|
await test_driver.bidi.permissions.set_permission(
|
|
{descriptor: {name: permissionName}, state: 'granted'});
|
|
|
|
await test_driver.create_virtual_sensor(testDriverName);
|
|
|
|
const sensor1 = new sensorType();
|
|
const sensor2 = new sensorType();
|
|
|
|
t.add_cleanup(async () => {
|
|
sensor1.stop();
|
|
sensor2.stop();
|
|
await test_driver.remove_virtual_sensor(testDriverName);
|
|
});
|
|
|
|
return new Promise(async (resolve, reject) => {
|
|
sensor1.addEventListener('reading', () => {
|
|
sensor2.addEventListener('activate', () => {
|
|
try {
|
|
assert_true(sensor1.activated);
|
|
assert_true(sensor1.hasReading);
|
|
|
|
const expected = expectedReadings.next().value;
|
|
assert_sensor_reading_equals(sensor1, expected);
|
|
|
|
assert_true(sensor2.activated);
|
|
assert_sensor_reading_equals(sensor2, expected);
|
|
} catch (e) {
|
|
reject(e);
|
|
}
|
|
}, {once: true});
|
|
sensor2.addEventListener('reading', () => {
|
|
try {
|
|
assert_true(sensor2.activated);
|
|
assert_true(sensor2.hasReading);
|
|
assert_sensor_reading_equals(sensor1, sensor2);
|
|
assert_equals(sensor1.timestamp, sensor2.timestamp);
|
|
resolve();
|
|
} catch (e) {
|
|
reject(e);
|
|
}
|
|
}, {once: true});
|
|
sensor2.start();
|
|
}, {once: true});
|
|
|
|
const eventWatcher = new EventWatcher(t, sensor1, ['activate']);
|
|
sensor1.start();
|
|
await eventWatcher.wait_for('activate');
|
|
await test_driver.update_virtual_sensor(
|
|
testDriverName, readings.next().value);
|
|
});
|
|
}, `${sensorName}: Readings delivered by shared platform sensor are\
|
|
immediately accessible to all sensors.`);
|
|
|
|
// Re-enable after https://github.com/w3c/sensors/issues/361 is fixed.
|
|
// promise_test(async () => {
|
|
// assert_throws_dom("NotSupportedError",
|
|
// () => { new sensorType({invalid: 1}) });
|
|
// assert_throws_dom("NotSupportedError",
|
|
// () => { new sensorType({frequency: 60, invalid: 1}) });
|
|
// if (!expectedRemappedReadings) {
|
|
// assert_throws_dom("NotSupportedError",
|
|
// () => { new sensorType({referenceFrame: "screen"}) });
|
|
// }
|
|
// }, `${sensorName}: throw 'NotSupportedError' for an unsupported sensor\
|
|
// option.`);
|
|
|
|
promise_test(async () => {
|
|
const invalidFreqs = ['invalid', NaN, Infinity, -Infinity, {}];
|
|
invalidFreqs.map(freq => {
|
|
assert_throws_js(
|
|
TypeError, () => {new sensorType({frequency: freq})},
|
|
`when freq is ${freq}`);
|
|
});
|
|
}, `${sensorName}: throw 'TypeError' if frequency is invalid.`);
|
|
|
|
if (!readingData.expectedRemappedReadings) {
|
|
// The sensorType does not represent a spatial sensor.
|
|
return;
|
|
}
|
|
|
|
// TODO(https://github.com/web-platform-tests/wpt/issues/42724): Re-enable
|
|
// when there is a cross-platform way to set an orientation angle.
|
|
// sensor_test(
|
|
// async (t, readings, expectedReadings, expectedRemappedReadings) => {
|
|
// assert_implements_optional(screen.orientation.angle == 270,
|
|
// 'Remapped values expect a specific screen rotation.');
|
|
// await test_driver.bidi.permissions.set_permission({descriptor: {name:
|
|
// permissionName}, state: 'granted'});
|
|
|
|
// await test_driver.create_virtual_sensor(testDriverName);
|
|
|
|
// const sensor1 = new sensorType({frequency: 60});
|
|
// const sensor2 =
|
|
// new sensorType({frequency: 60, referenceFrame: 'screen'});
|
|
// t.add_cleanup(async () => {
|
|
// sensor1.stop();
|
|
// sensor2.stop();
|
|
// await test_driver.remove_virtual_sensor(testDriverName);
|
|
// });
|
|
// const sensorWatcher1 =
|
|
// new EventWatcher(t, sensor1, ['activate', 'reading', 'error']);
|
|
// const sensorWatcher2 =
|
|
// new EventWatcher(t, sensor1, ['activate', 'reading', 'error']);
|
|
|
|
// sensor1.start();
|
|
// sensor2.start();
|
|
|
|
// await Promise.all([
|
|
// sensorWatcher1.wait_for('activate'),
|
|
// sensorWatcher2.wait_for('activate')
|
|
// ]);
|
|
|
|
// await Promise.all([
|
|
// test_driver.update_virtual_sensor(testDriverName,
|
|
// readings.next().value), sensorWatcher1.wait_for('reading'),
|
|
// sensorWatcher2.wait_for('reading')
|
|
// ]);
|
|
|
|
// const expected = expectedReadings.next().value;
|
|
// const expectedRemapped = expectedRemappedReadings.next().value;
|
|
// assert_sensor_reading_equals(sensor1, expected);
|
|
// assert_sensor_reading_equals(sensor2, expectedRemapped);
|
|
|
|
// sensor1.stop();
|
|
// assert_sensor_reading_is_null(sensor1);
|
|
// assert_sensor_reading_equals(sensor2, expectedRemapped);
|
|
|
|
// sensor2.stop();
|
|
// assert_sensor_reading_is_null(sensor2);
|
|
// },
|
|
// `${sensorName}: sensor reading is correct when options.referenceFrame\
|
|
// is 'screen'.`);
|
|
}
|
|
|
|
function runGenericSensorInsecureContext(sensorName) {
|
|
test(() => {
|
|
assert_false(sensorName in window, `${sensorName} must not be exposed`);
|
|
}, `${sensorName} is not exposed in an insecure context.`);
|
|
}
|