/* eslint-disable camelcase */
// Copyright (c) 2020 Wayne Parrott. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Note: parameter api and function based on
// https://design.ros2.org/articles/ros_parameters.html
// https://github.com/ros2/rcl and
// https://github.com/ros2/rclpy
'use strict';
const IsClose = require('is-close');
const rclnodejs = require('bindings')('rclnodejs');
/**
* The plus/minus tolerance for determining number equivalence.
* @constant {number}
*
* @see [FloatingPointRange]{@link FloatingPointRange}
* @see [IntegerRange]{@link IntegerRange}
*/
const DEFAULT_NUMERIC_RANGE_TOLERANCE = 1e-6;
const PARAMETER_SEPARATOR = '.';
/**
* Enum for ParameterType
* @readonly
* @enum {number}
*/
const ParameterType = {
/** @member {number} */
PARAMETER_NOT_SET: 0,
/** @member {number} */
PARAMETER_BOOL: 1,
/** @member {number} */
PARAMETER_INTEGER: 2,
/** @member {number} */
PARAMETER_DOUBLE: 3,
/** @member {number} */
PARAMETER_STRING: 4,
/** @member {number} */
PARAMETER_BYTE_ARRAY: 5,
/** @member {number} */
PARAMETER_BOOL_ARRAY: 6,
/** @member {number} */
PARAMETER_INTEGER_ARRAY: 7,
/** @member {number} */
PARAMETER_DOUBLE_ARRAY: 8,
/** @member {number} */
PARAMETER_STRING_ARRAY: 9,
};
/**
* A node parameter.
* @class
*/
class Parameter {
/**
* Create a Parameter instance from an rlc_interfaces/msg/Parameter message.
* @constructs
* @param {rlc_interfaces/msg/Parameter} parameterMsg - The message to convert to a parameter.
* @return {Parameter} - The new instance.
*/
static fromParameterMessage(parameterMsg) {
const name = parameterMsg.name;
const type = parameterMsg.value.type;
let value;
switch (type) {
case ParameterType.PARAMETER_NOT_SET:
break;
case ParameterType.PARAMETER_BOOL:
value = parameterMsg.value.bool_value;
break;
case ParameterType.PARAMETER_BOOL_ARRAY:
value = parameterMsg.value.bool_array_value;
break;
case ParameterType.PARAMETER_BYTE_ARRAY:
value = parameterMsg.value.byte_array_value;
break;
case ParameterType.PARAMETER_DOUBLE:
value = parameterMsg.value.double_value;
break;
case ParameterType.PARAMETER_DOUBLE_ARRAY:
value = parameterMsg.value.double_array_value;
break;
case ParameterType.PARAMETER_INTEGER:
value = parameterMsg.value.integer_value;
break;
case ParameterType.PARAMETER_INTEGER_ARRAY:
value = parameterMsg.value.integer_array_value;
break;
case ParameterType.PARAMETER_STRING:
value = parameterMsg.value.string_value;
break;
case ParameterType.PARAMETER_STRING_ARRAY:
value = parameterMsg.value.string_array_value;
break;
}
return new Parameter(name, type, value);
}
/**
* Create new parameter instances.
* @constructor
*
* @param {string} name - The parameter name, must be a valid name.
* @param {ParameterType} type - The type identifier.
* @param {any} value - The parameter value.
*/
constructor(name, type, value) {
this._name = name;
this._type = type;
this._value = value;
this._isDirty = true;
this.validate();
}
/**
* Get name
*
* @return {string} - The parameter name.
*/
get name() {
return this._name;
}
/**
* Get type
*
* @return {ParameterType} - The parameter type.
*/
get type() {
return this._type;
}
/**
* Get value.
*
* @return {any} - The parameter value.
*/
get value() {
return this._value;
}
/**
* Set value.
* Value must be compatible with the type property.
* @param {any} newValue - The parameter name.
*/
set value(newValue) {
// no empty array value allowed
this._value =
Array.isArray(newValue) && newValue.length === 0 ? null : newValue;
this._dirty = true;
this.validate();
}
/**
* Check the state of this property.
* Throw TypeError on first property with invalid type.
* @return {undefined}
*/
validate() {
// validate name
if (
!this.name ||
typeof this.name !== 'string' ||
this.name.trim().length === 0
) {
throw new TypeError('Invalid name');
}
// validate type
if (!validType(this.type)) {
throw new TypeError('Invalid type');
}
// validate value
if (!validValue(this.value, this.type)) {
throw new TypeError('Incompatible value.');
}
this._dirty = false;
}
/**
* Create a rcl_interfaces.msg.Parameter from this instance.
*
* @return {rcl_interfaces.msg.Parameter} - The new instance.
*/
toParameterMessage() {
const msg = {
name: this.name,
value: this.toParameterValueMessage(),
};
return msg;
}
/**
* Create a rcl_interfaces.msg.ParameterValue from this instance.
*
* @return {rcl_interfaces.msg.ParameterValue} - The new instance.
*/
toParameterValueMessage() {
const msg = {};
msg.type = this.type;
switch (this.type) {
case ParameterType.PARAMETER_NOT_SET:
break;
case ParameterType.PARAMETER_BOOL:
msg.bool_value = this.value ? 'true' : 'false';
break;
case ParameterType.PARAMETER_BOOL_ARRAY:
msg.bool_array_value = this.value.map(val => (val ? 'true' : 'false'));
break;
case ParameterType.PARAMETER_BYTE_ARRAY:
msg.byte_array_value = this.value.map(val => Math.trunc(val));
break;
case ParameterType.PARAMETER_DOUBLE:
msg.double_value = this.value;
break;
case ParameterType.PARAMETER_DOUBLE_ARRAY:
msg.double_array_value = this.value;
break;
case ParameterType.PARAMETER_INTEGER:
msg.integer_value = Math.trunc(this.value);
break;
case ParameterType.PARAMETER_INTEGER_ARRAY:
msg.integer_array_value = this.value.map(val => Math.trunc(val));
break;
case ParameterType.PARAMETER_STRING:
msg.string_value = this.value;
break;
case ParameterType.PARAMETER_STRING_ARRAY:
msg.string_array_value = this.value;
break;
}
return msg;
}
}
/**
* A node parameter descriptor.
* @class
*/
class ParameterDescriptor {
/**
* Create a new instance from a parameter.
* @constructs
* @param {Parameter} parameter - The parameter from which new instance is constructed.
* @return {ParameterDescriptor} - The new instance.
*/
static fromParameter(parameter) {
const name = parameter.name;
const type = parameter.type;
const value = parameter.value;
return new ParameterDescriptor(name, type, 'Created from parameter.');
}
/**
* Create new instances.
* @constructor
* @param {string} name - The descriptor name, must be a valid name.
* @param {ParameterType} type - The type identifier.
* @param {string} [description] - A descriptive string.
* @param {boolean} [readOnly] - True indicates a parameter of this type can not be modified. Default = false.
* @param {Range} [range] - An optional IntegerRange or FloatingPointRange.
*/
constructor(
name,
type = ParameterType.PARAMETER_NOT_SET,
description = 'no description',
readOnly = false,
range = null
) {
this._name = name; // string
this._type = type; // ParameterType
this._description = description;
this._readOnly = readOnly;
this._additionalConstraints = '';
this._range = range;
this.validate();
}
/**
* Get name.
*
* @return {string} - The name property.
*/
get name() {
return this._name;
}
/**
* Get type.
*
* @return {ParameterType} - The type property.
*/
get type() {
return this._type;
}
/**
* Get description.
*
* @return {string} - A descriptive string property.
*/
get description() {
return this._description;
}
/**
* Get readOnly property.
*
* @return {boolean} - The readOnly property.
*/
get readOnly() {
return this._readOnly;
}
/**
* Get additionalConstraints property.
*
* @return {string} - The additionalConstraints property.
*/
get additionalConstraints() {
return this._additionalConstraints;
}
/**
* Set additionalConstraints property. .
*
* @param {string} constraintDescription - The new value.
*/
set additionalConstraints(constraintDescription) {
this._additionalConstraints = constraintDescription;
}
/**
* Determine if rangeConstraint property has been set.
*
* @return {boolean} - The rangeConstraint property.
*/
hasRange() {
return !!this._range;
}
/**
* Get range.
*
* @return {FloatingPointRange|IntegerRange} - The range property.
*/
get range() {
return this._range;
}
/**
* Set range.
* The range must be compatible with the type property.
* @param {FloatingPointRange|IntegerRange} range - The new range.
*/
set range(range) {
if (!range) {
this._range = null;
return;
}
if (!(range instanceof Range)) {
throw TypeException('Expected instance of Range.');
}
if (!range.isValidType(this.type)) {
throw TypeError('Incompatible Range');
}
this._range = range;
}
/**
* Check the state and ensure it is valid.
* Throw a TypeError if invalid state is detected.
*
* @return {undefined}
*/
validate() {
// validate name
if (
!this.name ||
typeof this.name !== 'string' ||
this.name.trim().length === 0
) {
throw new TypeError('Invalid name');
}
// validate type
if (!validType(this.type)) {
throw new TypeError('Invalid type');
}
// validate description
if (this.description && typeof this.description !== 'string') {
throw new TypeError('Invalid description');
}
// validate rangeConstraint
if (this.hasRange() && !this.range.isValidType(this.type)) {
throw new TypeError('Incompatible Range');
}
}
/**
* Check a parameter for consistency with this descriptor.
* Throw an Error if an inconsistent state is detected.
*
* @param {Parameter} parameter - The parameter to test for consistency.
* @return {undefined}
*/
validateParameter(parameter) {
if (!parameter) {
throw new TypeError('Parameter is undefined');
}
// ensure parameter is valid
try {
parameter.validate();
} catch (e) {
throw new TypeError('Parameter is invalid');
}
// ensure this descriptor is valid
try {
this.validate();
} catch (e) {
throw new Error('Descriptor is invalid.');
}
if (this.name !== parameter.name) throw new Error('Name mismatch');
if (this.type !== parameter.type) throw new Error('Type mismatch');
if (this.hasRange() && !this.range.inRange(parameter.value)) {
throw new RangeError('Parameter value is not in descriptor range');
}
}
/**
* Create a rcl_interfaces.msg.ParameterDescriptor from this descriptor.
*
* @return {rcl_interfaces.msg.ParameterDescriptor} - The new message.
*/
toMessage() {
const msg = {
name: this.name,
type: this.type,
description: this.description,
additional_constraints: this.additionalConstraints,
read_only: this.readOnly,
};
if (
(this._type === ParameterType.PARAMETER_INTEGER ||
this._type === ParameterType.PARAMETER_INTEGER_ARRAY) &&
this._rangeConstraint instanceof IntegerRange
) {
msg.integer_range = [this._rangeConstraint];
} else if (
(this._type === ParameterType.PARAMETER_DOUBLE ||
this._type === ParameterType.PARAMETER_DOUBLE_ARRAY) &&
this._rangeConstraint instanceof FloatingPointRange
) {
msg.floating_point_range = [this._rangeConstraint];
}
return msg;
}
}
/**
* An abstract class defining a range of numbers between 2 points inclusively
* divided by a step value.
* @class
*/
class Range {
/**
* Create a new instance.
* @constructor
* @param {number} fromValue - The lowest inclusive value in range
* @param {number} toValue - The highest inclusive value in range
* @param {number} step - The internal unit size.
*/
constructor(fromValue, toValue, step = 1) {
this._fromValue = fromValue;
this._toValue = toValue;
this._step = step;
}
/**
* Get fromValue.
*
* @return {number} - The lowest inclusive value in range.
*/
get fromValue() {
return this._fromValue;
}
/**
* Get toValue.
*
* @return {number} - The highest inclusive value in range.
*/
get toValue() {
return this._toValue;
}
/**
* Get step unit.
*
* @return {number} - The internal unit size.
*/
get step() {
return this._step;
}
/**
* Determine if a value is within this range.
* A TypeError is thrown when value is not a number.
* Subclasses should override and call this method for basic type checking.
*
* @param {number} value - The number to check.
* @return {boolean} - True if value satisfies the range; false otherwise.
*/
inRange(value) {
if (Array.isArray(value)) {
const valArr = value;
return valArr.reduce(
(inRange, val) => inRange && this.inRange(val),
true
);
} else if (typeof value !== 'number') {
throw new TypeError('Value must be a number');
}
return true;
}
/**
* Abstract method that determines if a ParameterType is compatible.
* Subclasses must implement this method.
*
* @param {ParameterType} parameterType - The parameter type to test.
* @return {boolean} - True if parameterType is compatible; otherwise return false.
*/
isValidType(parameterType) {
return false;
}
}
/**
* Defines a range for floating point values.
* @class
*/
class FloatingPointRange extends Range {
/**
* Create a new instance.
* @constructor
* @param {number} fromValue - The lowest inclusive value in range
* @param {number} toValue - The highest inclusive value in range
* @param {number} step - The internal unit size.
* @param {number} tolerance - The plus/minus tolerance for number equivalence.
*/
constructor(
fromValue,
toValue,
step = 1,
tolerance = DEFAULT_NUMERIC_RANGE_TOLERANCE
) {
super(fromValue, toValue, step);
this._tolerance = tolerance;
}
get tolerance() {
return this._tolerance;
}
/**
* Determine if a ParameterType is compatible.
*
* @param {ParameterType} parameterType - The parameter type to test.
* @return {boolean} - True if parameterType is compatible; otherwise return false.
*/
isValidType(parameterType) {
const result =
parameterType === ParameterType.PARAMETER_DOUBLE ||
parameterType === ParameterType.PARAMETER_DOUBLE_ARRAY;
return result;
}
/**
* Determine if a value is within this range.
* A TypeError is thrown when value is not a number.
*
* @param {number} value - The number to check.
* @return {boolean} - True if value satisfies the range; false otherwise.
*/
inRange(value) {
if (!super.inRange(value)) return false;
const min = Math.min(this.fromValue, this.toValue);
const max = Math.max(this.fromValue, this.toValue);
if (
IsClose.isClose(value, min, this.tolerance) ||
IsClose.isClose(value, max, this.tolerance)
) {
return true;
}
if (value < min || value > max) {
return false;
}
if (this.step != 0.0) {
const distanceInSteps = Math.round((value - min) / this.step);
if (
!IsClose.isClose(
min + distanceInSteps * this.step,
value,
this.tolerance
)
) {
return false;
}
}
return true;
}
}
/**
* Defines a range for integer values.
* @class
*/
class IntegerRange extends FloatingPointRange {
/**
* Create a new instance.
* @constructor
* @param {number} fromValue - The lowest inclusive value in range
* @param {number} toValue - The highest inclusive value in range
* @param {number} step - The internal unit size.
* @param {number} tolerance - The plus/minus tolerance for number equivalence.
*/
constructor(
fromValue,
toValue,
step = 1,
tolerance = DEFAULT_NUMERIC_RANGE_TOLERANCE
) {
super(
Math.trunc(fromValue),
Math.trunc(toValue),
Math.trunc(step),
tolerance
);
}
/**
* Determine if a ParameterType is compatible.
*
* @param {ParameterType} parameterType - The parameter type to test.
* @return {boolean} - True if parameterType is compatible; otherwise return false.
*/
isValidType(parameterType) {
const result =
parameterType === ParameterType.PARAMETER_BYTE ||
parameterType === ParameterType.PARAMETER_BYTE_ARRAY ||
parameterType === ParameterType.PARAMETER_INTEGER ||
parameterType === ParameterType.PARAMETER_INTEGER_ARRAY;
return result;
}
}
/**
* Infer a ParameterType for JS primitive types:
* string, boolean, number and arrays of these types.
* A TypeError is thrown for a value who's type is not one of
* the set listed.
* @param {any} value - The value to infer it's ParameterType
* @returns {ParameterType} - The ParameterType that best scribes the value.
*/
function parameterTypeFromValue(value) {
if (!value) return ParameterType.PARAMETER_NOT_SET;
if (typeof value === 'boolean') return ParameterType.PARAMETER_BOOL;
if (typeof value === 'string') return ParameterType.PARAMETER_STRING;
if (typeof value === 'number') return ParameterType.PARAMETER_DOUBLE;
if (Array.isArray(value)) {
if (value.length > 0) {
const elementType = parameterTypeFromValue(value[0]);
switch (elementType) {
case ParameterType.PARAMETER_BOOL:
return ParameterType.PARAMETER_BOOL_ARRAY;
case ParameterType.PARAMETER_DOUBLE:
return ParameterType.PARAMETER_DOUBLE_ARRAY;
case ParameterType.PARAMETER_STRING:
return ParameterType.PARAMETER_STRING_ARRAY;
}
}
return ParameterType.PARAMETER_NOT_SET;
}
// otherwise unrecognized value
throw new TypeError('Unrecognized parameter type.');
}
/**
* Determine if a number maps to is a valid ParameterType.
*
* @param {ParameterType} parameterType - The value to test.
* @return {boolean} - True if value is a valid ParameterType; false otherwise.
*/
function validType(parameterType) {
let result =
typeof parameterType === 'number' &&
ParameterType.PARAMETER_NOT_SET <=
parameterType <=
ParameterType.PARAMETER_STRING_ARRAY;
return result;
}
/**
* Test if value can be represented by a ParameterType.
*
* @param {number} value - The value to test.
* @param {ParameterType} type - The ParameterType to test value against.
* @return {boolean} - True if value can be represented by type.
*/
function validValue(value, type) {
if (value == null) {
return type === ParameterType.PARAMETER_NOT_SET;
}
let result = true;
switch (type) {
case ParameterType.PARAMETER_NOT_SET:
result = !value;
break;
case ParameterType.PARAMETER_BOOL:
result = typeof value === 'boolean';
break;
case ParameterType.PARAMETER_STRING:
result = typeof value === 'string';
break;
case ParameterType.PARAMETER_INTEGER:
case ParameterType.PARAMETER_DOUBLE:
result = typeof value === 'number';
break;
case ParameterType.PARAMETER_BOOL_ARRAY:
case ParameterType.PARAMETER_BYTE_ARRAY:
case ParameterType.PARAMETER_INTEGER_ARRAY:
case ParameterType.PARAMETER_DOUBLE_ARRAY:
const values = value;
result = _validArray(values, type);
break;
default:
result = false;
}
return result;
}
function _validArray(values, type) {
if (!Array.isArray(values)) return false;
let arrayElementType;
if (type === ParameterType.PARAMETER_BOOL_ARRAY) {
arrayElementType = ParameterType.PARAMETER_BOOL;
} else if (type === ParameterType.PARAMETER_BYTE_ARRAY) {
arrayElementType = ParameterType.PARAMETER_BYTE;
}
if (type === ParameterType.PARAMETER_INTEGER_ARRAY) {
arrayElementType = ParameterType.PARAMETER_INTEGER;
}
if (type === ParameterType.PARAMETER_DOUBLE_ARRAY) {
arrayElementType = ParameterType.PARAMETER_DOUBLE;
}
return values.reduce(
(compatible, val) =>
compatible &&
!_isArrayParameterType(arrayElementType) &&
validValue(val, arrayElementType),
true
);
}
function _isArrayParameterType(type) {
return (
type === ParameterType.PARAMETER_BOOL_ARRAY ||
type === ParameterType.PARAMETER_BYTE_ARRAY ||
type === ParameterType.PARAMETER_INTEGER_ARRAY ||
type === ParameterType.PARAMETER_DOUBLE_ARRAY
);
}
module.exports = {
ParameterType,
Parameter,
ParameterDescriptor,
PARAMETER_SEPARATOR,
Range,
FloatingPointRange,
IntegerRange,
DEFAULT_NUMERIC_RANGE_TOLERANCE,
};