namespace sensors.internal { //% shim=pxt::unsafePollForChanges export function unsafePollForChanges( periodMs: number, query: () => number, changeHandler: (prev: number, curr: number) => void ) { // This is implemented in C++ without blocking the regular JS when query() is runnning // which is generally unsafe. Query should not update globally visible state, and cannot // call any yielding functions, like sleep(). // This is implementation for the simulator. control.runInParallel(() => { let prev = query() changeHandler(prev, prev) while (true) { pause(periodMs) let curr = query() if (prev !== curr) { changeHandler(prev, curr) prev = curr } } }) } export function bufferToString(buf: Buffer): string { let s = '' for (let i = 0; i < buf.length; i++) s += String.fromCharCode(buf[i]) return s } let analogMM: MMap let uartMM: MMap let IICMM: MMap let powerMM: MMap let devcon: Buffer let sensorInfos: SensorInfo[]; let batteryInfo: { CinCnt: number; CoutCnt: number; VinCnt: number; }; let batteryVMin: number; let batteryVMax: number; class SensorInfo { port: number sensor: Sensor sensors: Sensor[] connType: number devType: number iicid: string constructor(p: number) { this.port = p this.connType = DAL.CONN_NONE this.devType = DAL.DEVICE_TYPE_NONE this.iicid = '' this.sensors = [] } } function init() { if (sensorInfos) return sensorInfos = [] for (let i = 0; i < DAL.NUM_INPUTS; ++i) sensorInfos.push(new SensorInfo(i)) devcon = output.createBuffer(DevConOff.Size) analogMM = control.mmap("/dev/lms_analog", AnalogOff.Size, 0) if (!analogMM) control.fail("no analog sensor") uartMM = control.mmap("/dev/lms_uart", UartOff.Size, 0) if (!uartMM) control.fail("no uart sensor") IICMM = control.mmap("/dev/lms_iic", IICOff.Size, 0) if (!IICMM) control.fail("no iic sensor") powerMM = control.mmap("/dev/lms_power", 2, 0) unsafePollForChanges(500, () => { return hashDevices(); }, (prev, curr) => { detectDevices(); }); sensorInfos.forEach(info => { unsafePollForChanges(50, () => { if (info.sensor) return info.sensor._query() return 0 }, (prev, curr) => { if (info.sensor) info.sensor._update(prev, curr) }) }) } export function getActiveSensors(): Sensor[] { init(); return sensorInfos.filter(si => si.sensor && si.sensor.isActive()).map(si => si.sensor); } function readUartInfo(port: number, mode: number) { let buf = output.createBuffer(UartCtlOff.Size) buf[UartCtlOff.Port] = port buf[UartCtlOff.Mode] = mode uartMM.ioctl(IO.UART_READ_MODE_INFO, buf) return buf //let info = `t:${buf[TypesOff.Type]} c:${buf[TypesOff.Connection]} m:${buf[TypesOff.Mode]} n:${buf.slice(0, 12).toHex()}` //serial.writeLine("UART " + port + " / " + mode + " - " + info) } export function readIICID(port: number) { const buf = output.createBuffer(IICStr.Size) buf[IICStr.Port] = port IICMM.ioctl(IO.IIC_READ_TYPE_INFO, buf) const manufacturer = bufferToString(buf.slice(IICStr.Manufacturer, 8)) const sensorType = bufferToString(buf.slice(IICStr.SensorType, 8)) return manufacturer + sensorType; } const ADC_REF = 5000 //!< [mV] maximal value on ADC const ADC_RES = 4095 //!< [CNT] maximal count on ADC // see c_ui.c const SHUNT_IN = 0.11 // [Ohm] const AMP_CIN = 22.0 // [Times] const EP2_SHUNT_IN = 0.05 // [Ohm] const EP2_AMP_CIN = 15.0 // [Times] const SHUNT_OUT = 0.055 // [Ohm] const AMP_COUT = 19.0 // [Times] const VCE = 0.05 // [V] const AMP_VIN = 0.5 // [Times] const AVR_CIN = 300 const AVR_COUT = 30 const AVR_VIN = 30 // lms2012 const BATT_INDICATOR_HIGH = 7500 //!< Battery indicator high [mV] const BATT_INDICATOR_LOW = 6200 //!< Battery indicator low [mV] const ACCU_INDICATOR_HIGH = 7500 //!< Rechargeable battery indicator high [mV] const ACCU_INDICATOR_LOW = 7100 //!< Rechargeable battery indicator low [mV] function CNT_V(C: number) { return ((C * ADC_REF) / (ADC_RES * 1000.0)) } function updateBatteryInfo() { let CinCnt = analogMM.getNumber(NumberFormat.Int16LE, AnalogOff.BatteryCurrent); let CoutCnt = analogMM.getNumber(NumberFormat.Int16LE, AnalogOff.MotorCurrent); let VinCnt = analogMM.getNumber(NumberFormat.Int16LE, AnalogOff.Cell123456); if (!batteryInfo) { batteryVMin = BATT_INDICATOR_LOW; batteryVMax = BATT_INDICATOR_HIGH; if (powerMM) { const accu = powerMM.getNumber(NumberFormat.UInt8LE, 0); if (accu > 0) { control.dmesg("rechargeable battery") batteryVMin = ACCU_INDICATOR_LOW; batteryVMax = ACCU_INDICATOR_HIGH; } } batteryInfo = { CinCnt: CinCnt, CoutCnt: CoutCnt, VinCnt: VinCnt }; // update in background control.runInParallel(() => forever(updateBatteryInfo)); } else { CinCnt = batteryInfo.CinCnt = ((batteryInfo.CinCnt * (AVR_CIN - 1)) + CinCnt) / AVR_CIN; CoutCnt = batteryInfo.CoutCnt = ((batteryInfo.CoutCnt * (AVR_COUT - 1)) + CoutCnt) / AVR_COUT; VinCnt = batteryInfo.VinCnt = ((batteryInfo.VinCnt * (AVR_VIN - 1)) + VinCnt) / AVR_VIN; } } export function getBatteryInfo(): { level: number; Ibatt: number, Vbatt: number, Imotor: number } { init(); if (!batteryInfo) updateBatteryInfo(); const CinCnt = batteryInfo.CinCnt; const CoutCnt = batteryInfo.CoutCnt; const VinCnt = batteryInfo.VinCnt; /* void cUiUpdatePower(void) { #ifndef Linux_X86 DATAF CinV; DATAF CoutV; if ((UiInstance.Hw == FINAL) || (UiInstance.Hw == FINALB)) { CinV = CNT_V(UiInstance.CinCnt) / AMP_CIN; UiInstance.Vbatt = (CNT_V(UiInstance.VinCnt) / AMP_VIN) + CinV + VCE; UiInstance.Ibatt = CinV / SHUNT_IN; CoutV = CNT_V(UiInstance.CoutCnt) / AMP_COUT; UiInstance.Imotor = CoutV / SHUNT_OUT; } else { CinV = CNT_V(UiInstance.CinCnt) / EP2_AMP_CIN; UiInstance.Vbatt = (CNT_V(UiInstance.VinCnt) / AMP_VIN) + CinV + VCE; UiInstance.Ibatt = CinV / EP2_SHUNT_IN; UiInstance.Imotor = 0; } #endif #ifdef DEBUG_TEMP_SHUTDOWN UiInstance.Vbatt = 7.0; UiInstance.Ibatt = 5.0; #endif } */ const CinV = CNT_V(CinCnt) / AMP_CIN; const Vbatt = CNT_V(VinCnt) / AMP_VIN + CinV + VCE; const Ibatt = CinV / SHUNT_IN; const CoutV = CNT_V(CoutCnt) / AMP_COUT; const Imotor = CoutV / SHUNT_OUT; const level = Math.max(0, Math.min(100, Math.floor((Vbatt * 1000.0 - batteryVMin) / (batteryVMax - batteryVMin) * 100))); return { level: level, Vbatt: Vbatt, Ibatt: Ibatt, Imotor: Imotor }; } function hashDevices(): number { const conns = analogMM.slice(AnalogOff.InConn, DAL.NUM_INPUTS) let r = 0; for (let i = 0; i < conns.length; ++i) { r = (r << 8 | conns[i]); } return r; } let nonActivated = 0; function detectDevices() { //control.dmesg(`detect devices (${nonActivated} na)`) const conns = analogMM.slice(AnalogOff.InConn, DAL.NUM_INPUTS) let numChanged = 0; const uartSensors: SensorInfo[] = []; for (const sensorInfo of sensorInfos) { const newConn = conns[sensorInfo.port] if (newConn == sensorInfo.connType) { // control.dmesg(`connection unchanged ${newConn} at ${sensorInfo.port}`) continue; } numChanged++ sensorInfo.connType = newConn sensorInfo.devType = DAL.DEVICE_TYPE_NONE if (newConn == DAL.CONN_INPUT_UART) { control.dmesg(`new UART connection at ${sensorInfo.port}`) updateUartMode(sensorInfo.port, 0); uartSensors.push(sensorInfo); } else if (newConn == DAL.CONN_NXT_IIC) { control.dmesg(`new IIC connection at ${sensorInfo.port}`) sensorInfo.devType = DAL.DEVICE_TYPE_IIC_UNKNOWN sensorInfo.iicid = readIICID(sensorInfo.port) control.dmesg(`IIC ID ${sensorInfo.iicid.length}`) } else if (newConn == DAL.CONN_INPUT_DUMB) { control.dmesg(`new DUMB connection at ${sensorInfo.port}`) // TODO? for now assume touch sensorInfo.devType = DAL.DEVICE_TYPE_TOUCH } else if (newConn == DAL.CONN_NONE || newConn == 0) { control.dmesg(`disconnect at port ${sensorInfo.port}`) } else { control.dmesg(`unknown connection type: ${newConn} at ${sensorInfo.port}`) } } if (uartSensors.length > 0) { setUartModes(); for (const sensorInfo of uartSensors) { let uinfo = readUartInfo(sensorInfo.port, 0) sensorInfo.devType = uinfo[TypesOff.Type] control.dmesg(`UART type ${sensorInfo.devType}`) } } if (numChanged == 0 && nonActivated == 0) return control.dmesg(`updating sensor status`) nonActivated = 0; for (const sensorInfo of sensorInfos) { if (sensorInfo.devType == DAL.DEVICE_TYPE_IIC_UNKNOWN) { sensorInfo.sensor = sensorInfo.sensors.filter(s => s._IICId() == sensorInfo.iicid)[0] if (!sensorInfo.sensor) { control.dmesg(`sensor not found for iicid=${sensorInfo.iicid} at ${sensorInfo.port}`) nonActivated++; } else { control.dmesg(`sensor connected iicid=${sensorInfo.iicid} at ${sensorInfo.port}`) sensorInfo.sensor._activated() } } else if (sensorInfo.devType != DAL.DEVICE_TYPE_NONE) { sensorInfo.sensor = sensorInfo.sensors.filter(s => s._deviceType() == sensorInfo.devType)[0] if (!sensorInfo.sensor) { control.dmesg(`sensor not found for type=${sensorInfo.devType} at ${sensorInfo.port}`) nonActivated++; } else { control.dmesg(`sensor connected type=${sensorInfo.devType} at ${sensorInfo.port}`) sensorInfo.sensor._activated() } } } //control.dmesg(`detect devices done`) } export class Sensor extends control.Component { protected _port: number // this is 0-based constructor(port_: number) { super() if (!(1 <= port_ && port_ <= DAL.NUM_INPUTS)) control.panic(120) this._port = port_ - 1 init() sensorInfos[this._port].sensors.push(this) this.markUsed(); } markUsed() { sensors.__sensorUsed(this._port, this._deviceType()); } _activated() { } // 1-based port() { return this._port + 1 } isActive() { return sensorInfos[this._port].sensor == this } _query() { return 0 } _info(): string { return this._query().toString(); } _update(prev: number, curr: number) { } _deviceType() { return 0 } _IICId() { return '' } } export class AnalogSensor extends Sensor { constructor(port: number) { super(port) } _readPin6() { if (!this.isActive()) return 0 return analogMM.getNumber(NumberFormat.Int16LE, AnalogOff.InPin6 + 2 * this._port) } } export class UartSensor extends Sensor { protected mode: number // the mode user asked for protected realmode: number // the mode the hardware is in constructor(port: number) { super(port) this.mode = 0 this.realmode = 0 } _activated() { this.realmode = 0 this._setMode(this.mode) } protected _setMode(m: number) { //control.dmesg(`_setMode p=${this.port} m: ${this.realmode} -> ${m}`) let v = m | 0 this.mode = v if (!this.isActive()) return if (this.realmode != this.mode) { this.realmode = v setUartMode(this._port, v) } } getBytes(): Buffer { return getUartBytes(this.isActive() ? this._port : -1) } getNumber(fmt: NumberFormat, off: number) { if (!this.isActive()) return 0 return getUartNumber(fmt, off, this._port) } reset() { if (this.isActive()) uartReset(this._port); this.realmode = 0; } } export class IICSensor extends Sensor { protected mode: number // the mode user asked for protected realmode: number // the mode the hardware is in private readLength: number constructor(port: number) { super(port) this.mode = 0 this.realmode = 0 this.readLength = 1; } _activated() { this.realmode = 0 this._setMode(this.mode) } protected _setMode(m: number) { let v = m | 0 this.mode = v if (!this.isActive()) return if (this.realmode != this.mode) { this.realmode = v setIICMode(this._port, this._deviceType(), v) } } getBytes(): Buffer { return getIICBytes(this.isActive() ? this._port : -1, this.readLength) } getNumber(fmt: NumberFormat, off: number) { if (!this.isActive()) return 0 return getIICNumber(this.readLength, fmt, off, this._port) } transaction(deviceAddress: number, write: number[], read: number) { this.readLength = read; transactionIIC(this._port, deviceAddress, write, read) } _deviceType() { return DAL.DEVICE_TYPE_IIC_UNKNOWN } } export const iicsensor = new IICSensor(3) function uartReset(port: number) { if (port < 0) return control.dmesg(`UART reset at ${port}`) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Connection + port, DAL.CONN_NONE) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Type + port, 0) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Mode + port, 0) uartMM.ioctl(IO.UART_SET_CONN, devcon) } function getUartStatus(port: number) { if (port < 0) return 0 return uartMM.getNumber(NumberFormat.Int8LE, UartOff.Status + port) } function waitNonZeroUartStatus(port: number) { while (true) { if (port < 0) return 0 let s = getUartStatus(port) if (s) return s pause(25) } } function uartClearChange(port: number) { control.dmesg(`UART clear change`); const UART_DATA_READY = 8 const UART_PORT_CHANGED = 1 while (true) { let status = getUartStatus(port) if (port < 0) break if ((status & UART_DATA_READY) != 0 && (status & UART_PORT_CHANGED) == 0) break devcon.setNumber(NumberFormat.Int8LE, DevConOff.Connection + port, DAL.CONN_INPUT_UART) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Type + port, 0) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Mode + port, 0) uartMM.ioctl(IO.UART_CLEAR_CHANGED, devcon) uartMM.setNumber(NumberFormat.Int8LE, UartOff.Status + port, getUartStatus(port) & 0xfffe) pause(10) } } function setUartModes() { control.dmesg(`UART set modes`) uartMM.ioctl(IO.UART_SET_CONN, devcon) const ports: number[] = []; for (let port = 0; port < DAL.NUM_INPUTS; ++port) { if (devcon.getNumber(NumberFormat.Int8LE, DevConOff.Connection + port) == DAL.CONN_INPUT_UART) { ports.push(port); } } while (ports.length) { const port = ports.pop(); const status = waitNonZeroUartStatus(port) control.dmesg(`UART set mode ${status} at ${port}`); } } function updateUartMode(port: number, mode: number) { control.dmesg(`UART set mode to ${mode} at ${port}`) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Connection + port, DAL.CONN_INPUT_UART) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Type + port, 33) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Mode + port, mode) } function setUartMode(port: number, mode: number) { const UART_PORT_CHANGED = 1 while (true) { if (port < 0) return updateUartMode(port, mode); uartMM.ioctl(IO.UART_SET_CONN, devcon) let status = waitNonZeroUartStatus(port) if (status & UART_PORT_CHANGED) { control.dmesg(`UART clear changed at ${port}`) uartClearChange(port) } else { control.dmesg(`UART status ${status}`); break; } pause(10) } } function getUartBytes(port: number): Buffer { if (port < 0) return output.createBuffer(DAL.MAX_DEVICE_DATALENGTH) let index = uartMM.getNumber(NumberFormat.UInt16LE, UartOff.Actual + port * 2) return uartMM.slice( UartOff.Raw + DAL.MAX_DEVICE_DATALENGTH * 300 * port + DAL.MAX_DEVICE_DATALENGTH * index, DAL.MAX_DEVICE_DATALENGTH) } function getUartNumber(fmt: NumberFormat, off: number, port: number) { if (port < 0) return 0 let index = uartMM.getNumber(NumberFormat.UInt16LE, UartOff.Actual + port * 2) return uartMM.getNumber(fmt, UartOff.Raw + DAL.MAX_DEVICE_DATALENGTH * 300 * port + DAL.MAX_DEVICE_DATALENGTH * index + off) } export function setIICMode(port: number, type: number, mode: number) { if (port < 0) return; devcon.setNumber(NumberFormat.Int8LE, DevConOff.Connection + port, DAL.CONN_NXT_IIC) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Type + port, type) devcon.setNumber(NumberFormat.Int8LE, DevConOff.Mode + port, mode) IICMM.ioctl(IO.IIC_SET_CONN, devcon) } export function transactionIIC(port: number, deviceAddress: number, writeBuf: number[], readLen: number) { if (port < 0) return; let iicdata = output.createBuffer(IICDat.Size) iicdata.setNumber(NumberFormat.Int8LE, IICDat.Port, port) iicdata.setNumber(NumberFormat.Int8LE, IICDat.Repeat, 0) iicdata.setNumber(NumberFormat.Int16LE, IICDat.Time, 0) iicdata.setNumber(NumberFormat.Int8LE, IICDat.WrLng, writeBuf.length + 1) for (let i = 0; i < writeBuf.length; i++) iicdata.setNumber(NumberFormat.Int8LE, IICDat.WrData + i + 1, writeBuf[i]) iicdata.setNumber(NumberFormat.Int8LE, IICDat.WrData, deviceAddress) iicdata.setNumber(NumberFormat.Int8LE, IICDat.RdLng, readLen) IICMM.ioctl(IO.IIC_SETUP, iicdata) } export function getIICBytes(port: number, length: number) { if (port < 0) return output.createBuffer(length); let index = IICMM.getNumber(NumberFormat.UInt16LE, IICOff.Actual + port * 2); let buf = IICMM.slice( IICOff.Raw + DAL.MAX_DEVICE_DATALENGTH * 300 * port + DAL.MAX_DEVICE_DATALENGTH * index, length ); // Reverse for (let i = 0; i < length / 2; i++) { let c = buf[i] buf[i] = buf[length - i - 1] buf[length - i - 1] = c } return buf; } export function getIICNumber(length: number, format: NumberFormat, off: number, port: number) { return getIICBytes(port, length).getNumber(format, off) } const enum NxtColOff { Calibration = 0, // uint32[4][3] CalLimits = 48, // uint16[2] Crc = 52, // uint16 ADRaw = 54, // uint16[4] SensorRaw = 62, // uint16[4] Padding = 70, Size = 72 } const enum AnalogOff { InPin1 = 0, // int16[4] InPin6 = 8, // int16[4] OutPin5 = 16, // int16[4] BatteryTemp = 24, // int16 MotorCurrent = 26, // int16 BatteryCurrent = 28, // int16 Cell123456 = 30, // int16 Pin1 = 32, // int16[300][4] Pin6 = 2432, // int16[300][4] Actual = 4832, // uint16[4] LogIn = 4840, // uint16[4] LogOut = 4848, // uint16[4] NxtCol = 4856, // uint16[36][4] - NxtColor*4 OutPin5Low = 5144, // int16[4] Updated = 5152, // int8[4] InDcm = 5156, // int8[4] InConn = 5160, // int8[4] OutDcm = 5164, // int8[4] OutConn = 5168, // int8[4] Size = 5172 } const enum DevConOff { Connection = 0, // int8[4] Type = 4, // int8[4] Mode = 8, // int8[4] Size = 12 } const enum TypesOff { Name = 0, // int8[12] Type = 12, // int8 Connection = 13, // int8 Mode = 14, // int8 DataSets = 15, // int8 Format = 16, // int8 Figures = 17, // int8 Decimals = 18, // int8 Views = 19, // int8 RawMin = 20, // float32 RawMax = 24, // float32 PctMin = 28, // float32 PctMax = 32, // float32 SiMin = 36, // float32 SiMax = 40, // float32 InvalidTime = 44, // uint16 IdValue = 46, // uint16 Pins = 48, // int8 Symbol = 49, // int8[5] Align = 54, // uint16 Size = 56 } const enum UartOff { TypeData = 0, // Types[8][4] Repeat = 1792, // uint16[300][4] Raw = 4192, // int8[32][300][4] Actual = 42592, // uint16[4] LogIn = 42600, // uint16[4] Status = 42608, // int8[4] Output = 42612, // int8[32][4] OutputLength = 42740, // int8[4] Size = 42744 } const enum UartCtlOff { TypeData = 0, // Types Port = 56, // int8 Mode = 57, // int8 Size = 58 } const enum IICOff { TypeData = 0, // Types[8][4] Repeat = 1792, // uint16[300][4] Raw = 4192, // int8[32][300][4] Actual = 42592, // uint16[4] LogIn = 42600, // uint16[4] Status = 42608, // int8[4] Output = 42612, // int8[32][4] OutputLength = 42740, // int8[4] Size = 42744 } const enum IICCtlOff { TypeData = 0, // Types Port = 56, // int8 Mode = 57, // int8 Size = 58 } const enum IICDat { Result = 0, // result Port = 4, // int8 Repeat = 5, // int8 Time = 6, // int16 WrLng = 8, // int8 WrData = 9, // int8[32] RdLng = 41, // int8 RdData = 42, //int8[32] Size = 74, } const enum IICStr { Port = 0, // int8 Time = 2, // int16 Type = 4, // int8 Mode = 5, // int8 Manufacturer = 6, // int8[9] SensorType = 15, // int[9] SetupLng = 24, // int8 SetupString = 28, // ulong PollLng = 32, // int8 PollString = 36, // ulong ReadLng = 40, // int8 Size = 44 } const enum IO { UART_SET_CONN = 0xc00c7500, UART_READ_MODE_INFO = 0xc03c7501, UART_NACK_MODE_INFO = 0xc03c7502, UART_CLEAR_CHANGED = 0xc03c7503, IIC_SET_CONN = 0xc00c6902, IIC_READ_TYPE_INFO = 0xc03c6903, IIC_SETUP = 0xc04c6905, IIC_SET = 0xc02c6906, TST_PIN_ON = 0xc00b7401, TST_PIN_OFF = 0xc00b7402, TST_PIN_READ = 0xc00b7403, TST_PIN_WRITE = 0xc00b7404, TST_UART_ON = 0xc0487405, TST_UART_OFF = 0xc0487406, TST_UART_EN = 0xc0487407, TST_UART_DIS = 0xc0487408, TST_UART_READ = 0xc0487409, TST_UART_WRITE = 0xc048740a, } } namespace sensors { export enum ThresholdState { Normal = 1, High = 2, Low = 3, } export class ThresholdDetector { public id: number; public min: number; public max: number; public lowThreshold: number; public highThreshold: number; public level: number; public state: ThresholdState; constructor(id: number, min = 0, max = 100, lowThreshold = 20, highThreshold = 80) { this.id = id; this.min = min; this.max = max; this.lowThreshold = lowThreshold; this.highThreshold = highThreshold; this.level = Math.ceil((max - min) / 2); this.state = ThresholdState.Normal; } public setLevel(level: number) { if (this == null) return this.level = this.clampValue(level); if (this.level >= this.highThreshold) { this.setState(ThresholdState.High); } else if (this.level <= this.lowThreshold) { this.setState(ThresholdState.Low); } else { const interval = (this.highThreshold - this.lowThreshold) / 6; if ((this.state == ThresholdState.High && this.level < this.highThreshold - interval) || (this.state == ThresholdState.Low && this.level > this.lowThreshold + interval)) this.setState(ThresholdState.Normal); } } public threshold(t: ThresholdState): number { switch (t) { case ThresholdState.High: return this.highThreshold; case ThresholdState.Low: return this.lowThreshold; default: return (this.max - this.min) / 2; } } public setLowThreshold(value: number) { this.lowThreshold = this.clampValue(value); this.highThreshold = Math.max(this.lowThreshold + 1, this.highThreshold); } public setHighThreshold(value: number) { this.highThreshold = this.clampValue(value); this.lowThreshold = Math.min(this.highThreshold - 1, this.lowThreshold); } private clampValue(value: number) { if (value < this.min) { return this.min; } else if (value > this.max) { return this.max; } return value; } private setState(state: ThresholdState) { if (this.state == state) return; this.state = state; switch (state) { case ThresholdState.High: control.raiseEvent(this.id, ThresholdState.High); break; case ThresholdState.Low: control.raiseEvent(this.id, ThresholdState.Low); break; } } } }