unitsnet-js/dist/gen-units/energydensity.g.js

A better way to hold unit variables and easily convert to the destination unit

"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.EnergyDensity = exports.EnergyDensityUnits = void 0;
const base_unit_1 = require("../base-unit");
/** EnergyDensityUnits enumeration */
var EnergyDensityUnits;
(function (EnergyDensityUnits) {
    /** */
    EnergyDensityUnits["JoulesPerCubicMeter"] = "JoulePerCubicMeter";
    /** */
    EnergyDensityUnits["WattHoursPerCubicMeter"] = "WattHourPerCubicMeter";
    /** */
    EnergyDensityUnits["KilojoulesPerCubicMeter"] = "KilojoulePerCubicMeter";
    /** */
    EnergyDensityUnits["MegajoulesPerCubicMeter"] = "MegajoulePerCubicMeter";
    /** */
    EnergyDensityUnits["GigajoulesPerCubicMeter"] = "GigajoulePerCubicMeter";
    /** */
    EnergyDensityUnits["TerajoulesPerCubicMeter"] = "TerajoulePerCubicMeter";
    /** */
    EnergyDensityUnits["PetajoulesPerCubicMeter"] = "PetajoulePerCubicMeter";
    /** */
    EnergyDensityUnits["KilowattHoursPerCubicMeter"] = "KilowattHourPerCubicMeter";
    /** */
    EnergyDensityUnits["MegawattHoursPerCubicMeter"] = "MegawattHourPerCubicMeter";
    /** */
    EnergyDensityUnits["GigawattHoursPerCubicMeter"] = "GigawattHourPerCubicMeter";
    /** */
    EnergyDensityUnits["TerawattHoursPerCubicMeter"] = "TerawattHourPerCubicMeter";
    /** */
    EnergyDensityUnits["PetawattHoursPerCubicMeter"] = "PetawattHourPerCubicMeter";
})(EnergyDensityUnits = exports.EnergyDensityUnits || (exports.EnergyDensityUnits = {}));
/** Energy density is the amount of energy stored in a substance per unit volume and is measured in J/m³. It is sometimes confused with energy per unit mass which is properly called specific energy. */
class EnergyDensity extends base_unit_1.BaseUnit {
    /**
     * Create a new EnergyDensity.
     * @param value The value.
     * @param fromUnit The ‘EnergyDensity’ unit to create from.
     * The default unit is JoulesPerCubicMeter
     */
    constructor(value, fromUnit = EnergyDensityUnits.JoulesPerCubicMeter) {
        super();
        this.joulespercubicmeterLazy = null;
        this.watthourspercubicmeterLazy = null;
        this.kilojoulespercubicmeterLazy = null;
        this.megajoulespercubicmeterLazy = null;
        this.gigajoulespercubicmeterLazy = null;
        this.terajoulespercubicmeterLazy = null;
        this.petajoulespercubicmeterLazy = null;
        this.kilowatthourspercubicmeterLazy = null;
        this.megawatthourspercubicmeterLazy = null;
        this.gigawatthourspercubicmeterLazy = null;
        this.terawatthourspercubicmeterLazy = null;
        this.petawatthourspercubicmeterLazy = null;
        if (value === undefined || value === null || Number.isNaN(value)) {
            throw new TypeError('invalid unit value ‘' + value + '’');
        }
        this.value = this.convertToBase(value, fromUnit);
    }
    /**
     * The base value of EnergyDensity is JoulesPerCubicMeter.
     * This accessor used when needs a value for calculations and it's better to use directly the base value
     */
    get BaseValue() {
        return this.value;
    }
    /** Gets the default unit used when creating instances of the unit or its DTO */
    get baseUnit() {
        return EnergyDensityUnits.JoulesPerCubicMeter;
    }
    /** */
    get JoulesPerCubicMeter() {
        if (this.joulespercubicmeterLazy !== null) {
            return this.joulespercubicmeterLazy;
        }
        return this.joulespercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.JoulesPerCubicMeter);
    }
    /** */
    get WattHoursPerCubicMeter() {
        if (this.watthourspercubicmeterLazy !== null) {
            return this.watthourspercubicmeterLazy;
        }
        return this.watthourspercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.WattHoursPerCubicMeter);
    }
    /** */
    get KilojoulesPerCubicMeter() {
        if (this.kilojoulespercubicmeterLazy !== null) {
            return this.kilojoulespercubicmeterLazy;
        }
        return this.kilojoulespercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.KilojoulesPerCubicMeter);
    }
    /** */
    get MegajoulesPerCubicMeter() {
        if (this.megajoulespercubicmeterLazy !== null) {
            return this.megajoulespercubicmeterLazy;
        }
        return this.megajoulespercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.MegajoulesPerCubicMeter);
    }
    /** */
    get GigajoulesPerCubicMeter() {
        if (this.gigajoulespercubicmeterLazy !== null) {
            return this.gigajoulespercubicmeterLazy;
        }
        return this.gigajoulespercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.GigajoulesPerCubicMeter);
    }
    /** */
    get TerajoulesPerCubicMeter() {
        if (this.terajoulespercubicmeterLazy !== null) {
            return this.terajoulespercubicmeterLazy;
        }
        return this.terajoulespercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.TerajoulesPerCubicMeter);
    }
    /** */
    get PetajoulesPerCubicMeter() {
        if (this.petajoulespercubicmeterLazy !== null) {
            return this.petajoulespercubicmeterLazy;
        }
        return this.petajoulespercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.PetajoulesPerCubicMeter);
    }
    /** */
    get KilowattHoursPerCubicMeter() {
        if (this.kilowatthourspercubicmeterLazy !== null) {
            return this.kilowatthourspercubicmeterLazy;
        }
        return this.kilowatthourspercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.KilowattHoursPerCubicMeter);
    }
    /** */
    get MegawattHoursPerCubicMeter() {
        if (this.megawatthourspercubicmeterLazy !== null) {
            return this.megawatthourspercubicmeterLazy;
        }
        return this.megawatthourspercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.MegawattHoursPerCubicMeter);
    }
    /** */
    get GigawattHoursPerCubicMeter() {
        if (this.gigawatthourspercubicmeterLazy !== null) {
            return this.gigawatthourspercubicmeterLazy;
        }
        return this.gigawatthourspercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.GigawattHoursPerCubicMeter);
    }
    /** */
    get TerawattHoursPerCubicMeter() {
        if (this.terawatthourspercubicmeterLazy !== null) {
            return this.terawatthourspercubicmeterLazy;
        }
        return this.terawatthourspercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.TerawattHoursPerCubicMeter);
    }
    /** */
    get PetawattHoursPerCubicMeter() {
        if (this.petawatthourspercubicmeterLazy !== null) {
            return this.petawatthourspercubicmeterLazy;
        }
        return this.petawatthourspercubicmeterLazy = this.convertFromBase(EnergyDensityUnits.PetawattHoursPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a JoulesPerCubicMeter
     *
     * @param value The unit as JoulesPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromJoulesPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.JoulesPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a WattHoursPerCubicMeter
     *
     * @param value The unit as WattHoursPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromWattHoursPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.WattHoursPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a KilojoulesPerCubicMeter
     *
     * @param value The unit as KilojoulesPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromKilojoulesPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.KilojoulesPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a MegajoulesPerCubicMeter
     *
     * @param value The unit as MegajoulesPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromMegajoulesPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.MegajoulesPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a GigajoulesPerCubicMeter
     *
     * @param value The unit as GigajoulesPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromGigajoulesPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.GigajoulesPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a TerajoulesPerCubicMeter
     *
     * @param value The unit as TerajoulesPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromTerajoulesPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.TerajoulesPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a PetajoulesPerCubicMeter
     *
     * @param value The unit as PetajoulesPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromPetajoulesPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.PetajoulesPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a KilowattHoursPerCubicMeter
     *
     * @param value The unit as KilowattHoursPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromKilowattHoursPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.KilowattHoursPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a MegawattHoursPerCubicMeter
     *
     * @param value The unit as MegawattHoursPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromMegawattHoursPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.MegawattHoursPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a GigawattHoursPerCubicMeter
     *
     * @param value The unit as GigawattHoursPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromGigawattHoursPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.GigawattHoursPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a TerawattHoursPerCubicMeter
     *
     * @param value The unit as TerawattHoursPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromTerawattHoursPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.TerawattHoursPerCubicMeter);
    }
    /**
     * Create a new EnergyDensity instance from a PetawattHoursPerCubicMeter
     *
     * @param value The unit as PetawattHoursPerCubicMeter to create a new EnergyDensity from.
     * @returns The new EnergyDensity instance.
     */
    static FromPetawattHoursPerCubicMeter(value) {
        return new EnergyDensity(value, EnergyDensityUnits.PetawattHoursPerCubicMeter);
    }
    /**
     * Gets the base unit enumeration associated with EnergyDensity
     * @returns The unit enumeration that can be used to interact with this type
     */
    static getUnitEnum() {
        return EnergyDensityUnits;
    }
    /**
     * Gets the default unit used when creating instances of the unit or its DTO
     * @returns The unit enumeration value used as a default parameter in constructor and DTO methods
     */
    static getBaseUnit() {
        return EnergyDensityUnits.JoulesPerCubicMeter;
    }
    /**
     * Create API DTO represent a EnergyDensity unit.
     * @param holdInUnit The specific EnergyDensity unit to be used in the unit representation at the DTO
     */
    toDto(holdInUnit = EnergyDensityUnits.JoulesPerCubicMeter) {
        return {
            value: this.convert(holdInUnit),
            unit: holdInUnit
        };
    }
    /**
     * Create a EnergyDensity unit from an API DTO representation.
     * @param dtoEnergyDensity The EnergyDensity API DTO representation
     */
    static FromDto(dtoEnergyDensity) {
        return new EnergyDensity(dtoEnergyDensity.value, dtoEnergyDensity.unit);
    }
    /**
     * Convert EnergyDensity to a specific unit value.
     * @param toUnit The specific unit to convert to
     * @returns The value of the specific unit provided.
     */
    convert(toUnit) {
        switch (toUnit) {
            case EnergyDensityUnits.JoulesPerCubicMeter: return this.JoulesPerCubicMeter;
            case EnergyDensityUnits.WattHoursPerCubicMeter: return this.WattHoursPerCubicMeter;
            case EnergyDensityUnits.KilojoulesPerCubicMeter: return this.KilojoulesPerCubicMeter;
            case EnergyDensityUnits.MegajoulesPerCubicMeter: return this.MegajoulesPerCubicMeter;
            case EnergyDensityUnits.GigajoulesPerCubicMeter: return this.GigajoulesPerCubicMeter;
            case EnergyDensityUnits.TerajoulesPerCubicMeter: return this.TerajoulesPerCubicMeter;
            case EnergyDensityUnits.PetajoulesPerCubicMeter: return this.PetajoulesPerCubicMeter;
            case EnergyDensityUnits.KilowattHoursPerCubicMeter: return this.KilowattHoursPerCubicMeter;
            case EnergyDensityUnits.MegawattHoursPerCubicMeter: return this.MegawattHoursPerCubicMeter;
            case EnergyDensityUnits.GigawattHoursPerCubicMeter: return this.GigawattHoursPerCubicMeter;
            case EnergyDensityUnits.TerawattHoursPerCubicMeter: return this.TerawattHoursPerCubicMeter;
            case EnergyDensityUnits.PetawattHoursPerCubicMeter: return this.PetawattHoursPerCubicMeter;
            default:
                break;
        }
        return Number.NaN;
    }
    convertFromBase(toUnit) {
        if (base_unit_1.areAnyOperatorsOverridden())
            switch (toUnit) {
                case EnergyDensityUnits.JoulesPerCubicMeter: return this.value;
                case EnergyDensityUnits.WattHoursPerCubicMeter: return super.internalDivide(this.value, 3.6e+3);
                case EnergyDensityUnits.KilojoulesPerCubicMeter: return super.internalDivide(this.value, 1000);
                case EnergyDensityUnits.MegajoulesPerCubicMeter: return super.internalDivide(this.value, 1000000);
                case EnergyDensityUnits.GigajoulesPerCubicMeter: return super.internalDivide(this.value, 1000000000);
                case EnergyDensityUnits.TerajoulesPerCubicMeter: return super.internalDivide(this.value, 1000000000000);
                case EnergyDensityUnits.PetajoulesPerCubicMeter: return super.internalDivide(this.value, 1000000000000000);
                case EnergyDensityUnits.KilowattHoursPerCubicMeter: {
                    const v3 = super.internalDivide(this.value, 3.6e+3);
                    return super.internalDivide(v3, 1000);
                }
                case EnergyDensityUnits.MegawattHoursPerCubicMeter: {
                    const v3 = super.internalDivide(this.value, 3.6e+3);
                    return super.internalDivide(v3, 1000000);
                }
                case EnergyDensityUnits.GigawattHoursPerCubicMeter: {
                    const v3 = super.internalDivide(this.value, 3.6e+3);
                    return super.internalDivide(v3, 1000000000);
                }
                case EnergyDensityUnits.TerawattHoursPerCubicMeter: {
                    const v3 = super.internalDivide(this.value, 3.6e+3);
                    return super.internalDivide(v3, 1000000000000);
                }
                case EnergyDensityUnits.PetawattHoursPerCubicMeter: {
                    const v3 = super.internalDivide(this.value, 3.6e+3);
                    return super.internalDivide(v3, 1000000000000000);
                }
                default: return Number.NaN;
            }
        switch (toUnit) {
            case EnergyDensityUnits.JoulesPerCubicMeter: return this.value;
            case EnergyDensityUnits.WattHoursPerCubicMeter: return this.value / 3.6e+3;
            case EnergyDensityUnits.KilojoulesPerCubicMeter: return (this.value) / 1000;
            case EnergyDensityUnits.MegajoulesPerCubicMeter: return (this.value) / 1000000;
            case EnergyDensityUnits.GigajoulesPerCubicMeter: return (this.value) / 1000000000;
            case EnergyDensityUnits.TerajoulesPerCubicMeter: return (this.value) / 1000000000000;
            case EnergyDensityUnits.PetajoulesPerCubicMeter: return (this.value) / 1000000000000000;
            case EnergyDensityUnits.KilowattHoursPerCubicMeter: return (this.value / 3.6e+3) / 1000;
            case EnergyDensityUnits.MegawattHoursPerCubicMeter: return (this.value / 3.6e+3) / 1000000;
            case EnergyDensityUnits.GigawattHoursPerCubicMeter: return (this.value / 3.6e+3) / 1000000000;
            case EnergyDensityUnits.TerawattHoursPerCubicMeter: return (this.value / 3.6e+3) / 1000000000000;
            case EnergyDensityUnits.PetawattHoursPerCubicMeter: return (this.value / 3.6e+3) / 1000000000000000;
            default: return Number.NaN;
        }
    }
    convertToBase(value, fromUnit) {
        if (base_unit_1.areAnyOperatorsOverridden())
            switch (fromUnit) {
                case EnergyDensityUnits.JoulesPerCubicMeter: return value;
                case EnergyDensityUnits.WattHoursPerCubicMeter: return super.internalMultiply(value, 3.6e+3);
                case EnergyDensityUnits.KilojoulesPerCubicMeter: return super.internalMultiply(value, 1000);
                case EnergyDensityUnits.MegajoulesPerCubicMeter: return super.internalMultiply(value, 1000000);
                case EnergyDensityUnits.GigajoulesPerCubicMeter: return super.internalMultiply(value, 1000000000);
                case EnergyDensityUnits.TerajoulesPerCubicMeter: return super.internalMultiply(value, 1000000000000);
                case EnergyDensityUnits.PetajoulesPerCubicMeter: return super.internalMultiply(value, 1000000000000000);
                case EnergyDensityUnits.KilowattHoursPerCubicMeter: {
                    const v3 = super.internalMultiply(value, 3.6e+3);
                    return super.internalMultiply(v3, 1000);
                }
                case EnergyDensityUnits.MegawattHoursPerCubicMeter: {
                    const v3 = super.internalMultiply(value, 3.6e+3);
                    return super.internalMultiply(v3, 1000000);
                }
                case EnergyDensityUnits.GigawattHoursPerCubicMeter: {
                    const v3 = super.internalMultiply(value, 3.6e+3);
                    return super.internalMultiply(v3, 1000000000);
                }
                case EnergyDensityUnits.TerawattHoursPerCubicMeter: {
                    const v3 = super.internalMultiply(value, 3.6e+3);
                    return super.internalMultiply(v3, 1000000000000);
                }
                case EnergyDensityUnits.PetawattHoursPerCubicMeter: {
                    const v3 = super.internalMultiply(value, 3.6e+3);
                    return super.internalMultiply(v3, 1000000000000000);
                }
                default: return Number.NaN;
            }
        switch (fromUnit) {
            case EnergyDensityUnits.JoulesPerCubicMeter: return value;
            case EnergyDensityUnits.WattHoursPerCubicMeter: return value * 3.6e+3;
            case EnergyDensityUnits.KilojoulesPerCubicMeter: return (value) * 1000;
            case EnergyDensityUnits.MegajoulesPerCubicMeter: return (value) * 1000000;
            case EnergyDensityUnits.GigajoulesPerCubicMeter: return (value) * 1000000000;
            case EnergyDensityUnits.TerajoulesPerCubicMeter: return (value) * 1000000000000;
            case EnergyDensityUnits.PetajoulesPerCubicMeter: return (value) * 1000000000000000;
            case EnergyDensityUnits.KilowattHoursPerCubicMeter: return (value * 3.6e+3) * 1000;
            case EnergyDensityUnits.MegawattHoursPerCubicMeter: return (value * 3.6e+3) * 1000000;
            case EnergyDensityUnits.GigawattHoursPerCubicMeter: return (value * 3.6e+3) * 1000000000;
            case EnergyDensityUnits.TerawattHoursPerCubicMeter: return (value * 3.6e+3) * 1000000000000;
            case EnergyDensityUnits.PetawattHoursPerCubicMeter: return (value * 3.6e+3) * 1000000000000000;
            default: return Number.NaN;
        }
    }
    /**
     * Format the EnergyDensity to string.
     * Note! the default format for EnergyDensity is JoulesPerCubicMeter.
     * To specify the unit format set the 'unit' parameter.
     * @param unit The unit to format the EnergyDensity.
     * @param options The ToString options, it also can be the number of fractional digits to keep that deprecated and moved to the options object. support in number will be dropped in the upcoming versions.
     * @returns The string format of the EnergyDensity.
     */
    toString(unit = EnergyDensityUnits.JoulesPerCubicMeter, options) {
        if (typeof options === 'number') {
            console.warn('The number parameter is deprecated and moved to the options object. support in number will be dropped in the upcoming versions.');
            options = { fractionalDigits: options };
        }
        switch (unit) {
            case EnergyDensityUnits.JoulesPerCubicMeter:
                return super.truncateFractionDigits(this.JoulesPerCubicMeter, options) + ` J/m³`;
            case EnergyDensityUnits.WattHoursPerCubicMeter:
                return super.truncateFractionDigits(this.WattHoursPerCubicMeter, options) + ` Wh/m³`;
            case EnergyDensityUnits.KilojoulesPerCubicMeter:
                return super.truncateFractionDigits(this.KilojoulesPerCubicMeter, options) + ` kJ/m³`;
            case EnergyDensityUnits.MegajoulesPerCubicMeter:
                return super.truncateFractionDigits(this.MegajoulesPerCubicMeter, options) + ` MJ/m³`;
            case EnergyDensityUnits.GigajoulesPerCubicMeter:
                return super.truncateFractionDigits(this.GigajoulesPerCubicMeter, options) + ` GJ/m³`;
            case EnergyDensityUnits.TerajoulesPerCubicMeter:
                return super.truncateFractionDigits(this.TerajoulesPerCubicMeter, options) + ` TJ/m³`;
            case EnergyDensityUnits.PetajoulesPerCubicMeter:
                return super.truncateFractionDigits(this.PetajoulesPerCubicMeter, options) + ` PJ/m³`;
            case EnergyDensityUnits.KilowattHoursPerCubicMeter:
                return super.truncateFractionDigits(this.KilowattHoursPerCubicMeter, options) + ` kWh/m³`;
            case EnergyDensityUnits.MegawattHoursPerCubicMeter:
                return super.truncateFractionDigits(this.MegawattHoursPerCubicMeter, options) + ` MWh/m³`;
            case EnergyDensityUnits.GigawattHoursPerCubicMeter:
                return super.truncateFractionDigits(this.GigawattHoursPerCubicMeter, options) + ` GWh/m³`;
            case EnergyDensityUnits.TerawattHoursPerCubicMeter:
                return super.truncateFractionDigits(this.TerawattHoursPerCubicMeter, options) + ` TWh/m³`;
            case EnergyDensityUnits.PetawattHoursPerCubicMeter:
                return super.truncateFractionDigits(this.PetawattHoursPerCubicMeter, options) + ` PWh/m³`;
            default:
                break;
        }
        return this.value.toString();
    }
    /**
     * Get EnergyDensity unit abbreviation.
     * Note! the default abbreviation for EnergyDensity is JoulesPerCubicMeter.
     * To specify the unit abbreviation set the 'unitAbbreviation' parameter.
     * @param unitAbbreviation The unit abbreviation of the EnergyDensity.
     * @returns The abbreviation string of EnergyDensity.
     */
    getUnitAbbreviation(unitAbbreviation = EnergyDensityUnits.JoulesPerCubicMeter) {
        switch (unitAbbreviation) {
            case EnergyDensityUnits.JoulesPerCubicMeter:
                return `J/m³`;
            case EnergyDensityUnits.WattHoursPerCubicMeter:
                return `Wh/m³`;
            case EnergyDensityUnits.KilojoulesPerCubicMeter:
                return `kJ/m³`;
            case EnergyDensityUnits.MegajoulesPerCubicMeter:
                return `MJ/m³`;
            case EnergyDensityUnits.GigajoulesPerCubicMeter:
                return `GJ/m³`;
            case EnergyDensityUnits.TerajoulesPerCubicMeter:
                return `TJ/m³`;
            case EnergyDensityUnits.PetajoulesPerCubicMeter:
                return `PJ/m³`;
            case EnergyDensityUnits.KilowattHoursPerCubicMeter:
                return `kWh/m³`;
            case EnergyDensityUnits.MegawattHoursPerCubicMeter:
                return `MWh/m³`;
            case EnergyDensityUnits.GigawattHoursPerCubicMeter:
                return `GWh/m³`;
            case EnergyDensityUnits.TerawattHoursPerCubicMeter:
                return `TWh/m³`;
            case EnergyDensityUnits.PetawattHoursPerCubicMeter:
                return `PWh/m³`;
            default:
                break;
        }
        return '';
    }
    /**
     * Check if the given EnergyDensity are equals to the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns True if the given EnergyDensity are equal to the current EnergyDensity.
     */
    equals(energyDensity) {
        return super.internalEquals(this.value, energyDensity.BaseValue);
    }
    /**
     * Compare the given EnergyDensity against the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns 0 if they are equal, -1 if the current EnergyDensity is less then other, 1 if the current EnergyDensity is greater then other.
     */
    compareTo(energyDensity) {
        return super.internalCompareTo(this.value, energyDensity.BaseValue);
    }
    /**
     * Add the given EnergyDensity with the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns A new EnergyDensity instance with the results.
     */
    add(energyDensity) {
        return new EnergyDensity(super.internalAdd(this.value, energyDensity.BaseValue));
    }
    /**
     * Subtract the given EnergyDensity with the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns A new EnergyDensity instance with the results.
     */
    subtract(energyDensity) {
        return new EnergyDensity(super.internalSubtract(this.value, energyDensity.BaseValue));
    }
    /**
     * Multiply the given EnergyDensity with the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns A new EnergyDensity instance with the results.
     */
    multiply(energyDensity) {
        return new EnergyDensity(super.internalMultiply(this.value, energyDensity.BaseValue));
    }
    /**
     * Divide the given EnergyDensity with the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns A new EnergyDensity instance with the results.
     */
    divide(energyDensity) {
        return new EnergyDensity(super.internalDivide(this.value, energyDensity.BaseValue));
    }
    /**
     * Modulo the given EnergyDensity with the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns A new EnergyDensity instance with the results.
     */
    modulo(energyDensity) {
        return new EnergyDensity(super.internalModulo(this.value, energyDensity.BaseValue));
    }
    /**
     * Pow the given EnergyDensity with the current EnergyDensity.
     * @param energyDensity The other EnergyDensity.
     * @returns A new EnergyDensity instance with the results.
     */
    pow(energyDensity) {
        return new EnergyDensity(super.internalPow(this.value, energyDensity.BaseValue));
    }
}
exports.EnergyDensity = EnergyDensity;