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incyclist-ant-plus

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Incyclist library for ANT+ - originally forked from longhorn/ant-plus

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"use strict"; var __awaiter = (this && this.__awaiter) || function (thisArg, _arguments, P, generator) { function adopt(value) { return value instanceof P ? value : new P(function (resolve) { resolve(value); }); } return new (P || (P = Promise))(function (resolve, reject) { function fulfilled(value) { try { step(generator.next(value)); } catch (e) { reject(e); } } function rejected(value) { try { step(generator["throw"](value)); } catch (e) { reject(e); } } function step(result) { result.done ? resolve(result.value) : adopt(result.value).then(fulfilled, rejected); } step((generator = generator.apply(thisArg, _arguments || [])).next()); }); }; Object.defineProperty(exports, "__esModule", { value: true }); exports.SpeedCadenceScanner = exports.SpeedCadenceSensor = void 0; const Ant = require("./ant"); const consts_1 = require("./consts"); const messages_1 = require("./messages"); class SpeedCadenceSensorState { constructor(deviceID) { this.DeviceID = deviceID; } } class SpeedCadenceScanState extends SpeedCadenceSensorState { } class SpeedCadenceSensor extends Ant.AntPlusSensor { constructor(stick) { super(stick); this.wheelCircumference = 2.118; this.decodeDataCbk = this.decodeData.bind(this); } setWheelCircumference(wheelCircumference) { this.wheelCircumference = wheelCircumference; } attach(channel, deviceID) { const _super = Object.create(null, { attach: { get: () => super.attach } }); return __awaiter(this, void 0, void 0, function* () { _super.attach.call(this, channel, 'receive', deviceID, SpeedCadenceSensor.deviceType, 0, 255, 8086); this.state = new SpeedCadenceSensorState(deviceID); }); } decodeData(data) { if (data.readUInt8(messages_1.Messages.BUFFER_INDEX_CHANNEL_NUM) !== this.channel) { return; } switch (data.readUInt8(messages_1.Messages.BUFFER_INDEX_MSG_TYPE)) { case consts_1.Constants.MESSAGE_CHANNEL_BROADCAST_DATA: case consts_1.Constants.MESSAGE_CHANNEL_ACKNOWLEDGED_DATA: case consts_1.Constants.MESSAGE_CHANNEL_BURST_DATA: if (this.deviceID === 0) { this.write(messages_1.Messages.requestMessage(this.channel, consts_1.Constants.MESSAGE_CHANNEL_ID)); } updateState(this, this.state, data); break; case consts_1.Constants.MESSAGE_CHANNEL_ID: this.deviceID = data.readUInt16LE(messages_1.Messages.BUFFER_INDEX_MSG_DATA); this.transmissionType = data.readUInt8(messages_1.Messages.BUFFER_INDEX_MSG_DATA + 3); this.state.DeviceID = this.deviceID; break; default: break; } } } exports.SpeedCadenceSensor = SpeedCadenceSensor; SpeedCadenceSensor.deviceType = 0x79; class SpeedCadenceScanner extends Ant.AntPlusScanner { constructor(stick) { super(stick); this.wheelCircumference = 2.118; this.states = {}; this.decodeDataCbk = this.decodeData.bind(this); } setWheelCircumference(wheelCircumference) { this.wheelCircumference = wheelCircumference; } scan() { const _super = Object.create(null, { scan: { get: () => super.scan } }); return __awaiter(this, void 0, void 0, function* () { _super.scan.call(this, 'receive'); }); } decodeData(data) { if (data.length <= (messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN + 3) || !(data.readUInt8(messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN) & 0x80)) { console.log('wrong message format', data.toString('hex')); return; } const deviceId = data.readUInt16LE(messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN + 1); const deviceType = data.readUInt8(messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN + 3); if (deviceType !== SpeedCadenceScanner.deviceType) { return; } if (!this.states[deviceId]) { this.states[deviceId] = new SpeedCadenceScanState(deviceId); } if (data.readUInt8(messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN) & 0x40) { if (data.readUInt8(messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN + 5) === 0x20) { this.states[deviceId].Rssi = data.readInt8(messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN + 6); this.states[deviceId].Threshold = data.readInt8(messages_1.Messages.BUFFER_INDEX_EXT_MSG_BEGIN + 7); } } switch (data.readUInt8(messages_1.Messages.BUFFER_INDEX_MSG_TYPE)) { case consts_1.Constants.MESSAGE_CHANNEL_BROADCAST_DATA: case consts_1.Constants.MESSAGE_CHANNEL_ACKNOWLEDGED_DATA: case consts_1.Constants.MESSAGE_CHANNEL_BURST_DATA: updateState(this, this.states[deviceId], data); break; default: break; } } } exports.SpeedCadenceScanner = SpeedCadenceScanner; SpeedCadenceScanner.deviceType = 0x79; function updateState(sensor, state, data) { const oldCadenceTime = state.CadenceEventTime; const oldCadenceCount = state.CumulativeCadenceRevolutionCount; const oldSpeedTime = state.SpeedEventTime; const oldSpeedCount = state.CumulativeSpeedRevolutionCount; let cadenceTime = data.readUInt16LE(messages_1.Messages.BUFFER_INDEX_MSG_DATA); const cadenceCount = data.readUInt16LE(messages_1.Messages.BUFFER_INDEX_MSG_DATA + 2); let speedEventTime = data.readUInt16LE(messages_1.Messages.BUFFER_INDEX_MSG_DATA + 4); const speedRevolutionCount = data.readUInt16LE(messages_1.Messages.BUFFER_INDEX_MSG_DATA + 6); if (cadenceTime !== oldCadenceTime) { state.CadenceEventTime = cadenceTime; state.CumulativeCadenceRevolutionCount = cadenceCount; if (oldCadenceTime > cadenceTime) { cadenceTime += (1024 * 64); } const cadence = ((60 * (cadenceCount - oldCadenceCount) * 1024) / (cadenceTime - oldCadenceTime)); if (!isNaN(cadence)) { state.CalculatedCadence = cadence; sensor.emit('cadenceData', state); } } if (speedEventTime !== oldSpeedTime) { state.SpeedEventTime = speedEventTime; state.CumulativeSpeedRevolutionCount = speedRevolutionCount; if (oldSpeedTime > speedEventTime) { speedEventTime += (1024 * 64); } const distance = sensor.wheelCircumference * (speedRevolutionCount - oldSpeedCount); state.CalculatedDistance = distance; const speed = (distance * 1024) / (speedEventTime - oldSpeedTime); if (!isNaN(speed)) { state.CalculatedSpeed = speed; sensor.emit('speedData', state); } } }