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International Component for Unicode for Java (ICU4J) is a mature, widely used Java library providing Unicode and Globalization support

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// © 2020 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
package com.ibm.icu.impl.units;

import static java.math.MathContext.DECIMAL128;

import java.math.BigDecimal;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.HashMap;
import java.util.regex.Pattern;

import com.ibm.icu.impl.IllegalIcuArgumentException;
import com.ibm.icu.util.MeasureUnit;

// TODO ICU-22683: Consider splitting handling of special mappings into separate (possibly internal) class
public class UnitsConverter {
    private BigDecimal conversionRate;
    private boolean reciprocal;
    private BigDecimal offset;
    private String specialSource;
    private String specialTarget;

    /**
     * Constructor of UnitsConverter.
     * NOTE:
     * - source and target must be under the same category
     * - e.g. meter to mile --> both of them are length units.
     * 

* NOTE: * This constructor creates an instance of UnitsConverter internally. * * @param sourceIdentifier represents the source unit identifier. * @param targetIdentifier represents the target unit identifier. */ public UnitsConverter(String sourceIdentifier, String targetIdentifier) { this( MeasureUnitImpl.forIdentifier(sourceIdentifier), MeasureUnitImpl.forIdentifier(targetIdentifier), new ConversionRates() ); } /** * Constructor of UnitsConverter. * NOTE: * - source and target must be under the same category * - e.g. meter to mile --> both of them are length units. * This converts from source to base to target (one of those may be a no-op). * * @param source represents the source unit. * @param target represents the target unit. * @param conversionRates contains all the needed conversion rates. */ public UnitsConverter(MeasureUnitImpl source, MeasureUnitImpl target, ConversionRates conversionRates) { Convertibility convertibility = extractConvertibility(source, target, conversionRates); if (convertibility != Convertibility.CONVERTIBLE && convertibility != Convertibility.RECIPROCAL) { throw new IllegalIcuArgumentException("input units must be convertible or reciprocal"); } this.specialSource = conversionRates.getSpecialMappingName(source); this.specialTarget = conversionRates.getSpecialMappingName(target); if (this.specialSource == null && this.specialTarget == null) { Factor sourceToBase = conversionRates.getFactorToBase(source); Factor targetToBase = conversionRates.getFactorToBase(target); if (convertibility == Convertibility.CONVERTIBLE) { this.conversionRate = sourceToBase.divide(targetToBase).getConversionRate(); } else { assert convertibility == Convertibility.RECIPROCAL; this.conversionRate = sourceToBase.multiply(targetToBase).getConversionRate(); } this.reciprocal = convertibility == Convertibility.RECIPROCAL; // calculate the offset this.offset = conversionRates.getOffset(source, target, sourceToBase, targetToBase, convertibility); // We should see no offsets for reciprocal conversions - they don't make sense: assert convertibility != Convertibility.RECIPROCAL || this.offset == BigDecimal.ZERO; } else { this.reciprocal = false; this.offset = BigDecimal.ZERO; if (this.specialSource == null) { // conversionRate is for source to base only this.conversionRate = conversionRates.getFactorToBase(source).getConversionRate(); } else if (this.specialTarget == null) { // conversionRate is for base to target only this.conversionRate = conversionRates.getFactorToBase(target).getConversionRate(); } else { this.conversionRate = BigDecimal.ONE; } } } static public Convertibility extractConvertibility(MeasureUnitImpl source, MeasureUnitImpl target, ConversionRates conversionRates) { ArrayList sourceSingleUnits = conversionRates.extractBaseUnits(source); ArrayList targetSingleUnits = conversionRates.extractBaseUnits(target); HashMap dimensionMap = new HashMap<>(); insertInMap(dimensionMap, sourceSingleUnits, 1); insertInMap(dimensionMap, targetSingleUnits, -1); if (areDimensionsZeroes(dimensionMap)) return Convertibility.CONVERTIBLE; insertInMap(dimensionMap, targetSingleUnits, 2); if (areDimensionsZeroes(dimensionMap)) return Convertibility.RECIPROCAL; return Convertibility.UNCONVERTIBLE; } /** * Helpers */ private static void insertInMap(HashMap dimensionMap, ArrayList singleUnits, int multiplier) { for (SingleUnitImpl singleUnit : singleUnits) { if (dimensionMap.containsKey(singleUnit.getSimpleUnitID())) { dimensionMap.put(singleUnit.getSimpleUnitID(), dimensionMap.get(singleUnit.getSimpleUnitID()) + singleUnit.getDimensionality() * multiplier); } else { dimensionMap.put(singleUnit.getSimpleUnitID(), singleUnit.getDimensionality() * multiplier); } } } private static boolean areDimensionsZeroes(HashMap dimensionMap) { for (Integer value : dimensionMap.values()) { if (!value.equals(0)) return false; } return true; } // Convert inputValue (source) to base then to target public BigDecimal convert(BigDecimal inputValue) { BigDecimal result = inputValue; if (this.specialSource != null || this.specialTarget != null) { BigDecimal base = inputValue; // convert input (=source) to base if (this.specialSource != null) { // We have a special mapping from source to base (not using factor, offset). // Currently the only supported mapping is a scale-based mapping for beaufort. base = (this.specialSource.equals("beaufort"))? scaleToBase(inputValue, minMetersPerSecForBeaufort): inputValue; } else { // Standard mapping (using factor, offset) from source to base. base = inputValue.multiply(this.conversionRate); } // convert base to result (=target) if (this.specialTarget != null) { // We have a special mapping from base to target (not using factor, offset). // Currently the only supported mapping is a scale-based mapping for beaufort. result = (this.specialTarget.equals("beaufort"))? baseToScale(base, minMetersPerSecForBeaufort): base; } else { // Standard mapping (using factor, offset) from base to target. result = base.divide(this.conversionRate, DECIMAL128); } return result; } result = inputValue.multiply(this.conversionRate).add(offset); if (this.reciprocal) { // We should see no offsets for reciprocal conversions - they don't make sense: assert offset == BigDecimal.ZERO; if (result.compareTo(BigDecimal.ZERO) == 0) { // TODO(ICU-21988): determine desirable behaviour return BigDecimal.ZERO; } result = BigDecimal.ONE.divide(result, DECIMAL128); } return result; } // Convert inputValue (target) to base then to source public BigDecimal convertInverse(BigDecimal inputValue) { BigDecimal result = inputValue; if (this.specialSource != null || this.specialTarget != null) { BigDecimal base = inputValue; // convert input (=target) to base if (this.specialTarget != null) { // We have a special mapping from target to base (not using factor, offset). // Currently the only supported mapping is a scale-based mapping for beaufort. base = (this.specialTarget.equals("beaufort"))? scaleToBase(inputValue, minMetersPerSecForBeaufort): inputValue; } else { // Standard mapping (using factor, offset) from target to base. base = inputValue.multiply(this.conversionRate); } // convert base to result (=source) if (this.specialSource != null) { // We have a special mapping from base to source (not using factor, offset). // Currently the only supported mapping is a scale-based mapping for beaufort. result = (this.specialSource.equals("beaufort"))? baseToScale(base, minMetersPerSecForBeaufort): base; } else { // Standard mapping (using factor, offset) from base to source. result = base.divide(this.conversionRate, DECIMAL128); } return result; } if (this.reciprocal) { // We should see no offsets for reciprocal conversions - they don't make sense: assert offset == BigDecimal.ZERO; if (result.compareTo(BigDecimal.ZERO) == 0) { // TODO(ICU-21988): determine desirable behaviour return BigDecimal.ZERO; } result = BigDecimal.ONE.divide(result, DECIMAL128); } result = result.subtract(offset).divide(this.conversionRate, DECIMAL128); return result; } // TODO per CLDR-17421 and ICU-22683: consider getting the data below from CLDR private static final BigDecimal[] minMetersPerSecForBeaufort = { // Minimum m/s (base) values for each Bft value, plus an extra artificial value; // when converting from Bft to m/s, the middle of the range will be used // (Values from table in Wikipedia, except for artificial value). // Since this is 0 based, max Beaufort value is thus array dimension minus 2. BigDecimal.valueOf(0.0), // 0 Bft BigDecimal.valueOf(0.3), // 1 BigDecimal.valueOf(1.6), // 2 BigDecimal.valueOf(3.4), // 3 BigDecimal.valueOf(5.5), // 4 BigDecimal.valueOf(8.0), // 5 BigDecimal.valueOf(10.8), // 6 BigDecimal.valueOf(13.9), // 7 BigDecimal.valueOf(17.2), // 8 BigDecimal.valueOf(20.8), // 9 BigDecimal.valueOf(24.5), // 10 BigDecimal.valueOf(28.5), // 11 BigDecimal.valueOf(32.7), // 12 BigDecimal.valueOf(36.9), // 13 BigDecimal.valueOf(41.4), // 14 BigDecimal.valueOf(46.1), // 15 BigDecimal.valueOf(51.1), // 16 BigDecimal.valueOf(55.8), // 17 BigDecimal.valueOf(61.4), // artificial end of range 17 to give reasonable midpoint }; // Convert from what should be discrete scale values for a particular unit like beaufort // to a corresponding value in the base unit (which can have any decimal value, like meters/sec). // First we round the scale value to the nearest integer (in case it is specified with a fractional value), // then we map that to a value in middle of the range of corresponding base values. // This can handle different scales, specified by minBaseForScaleValues[]. private BigDecimal scaleToBase(BigDecimal scaleValue, BigDecimal[] minBaseForScaleValues) { BigDecimal pointFive = BigDecimal.valueOf(0.5); BigDecimal scaleAdjust = scaleValue.abs().add(pointFive); // adjust up for later truncation BigDecimal scaleAdjustCapped = scaleAdjust.min(BigDecimal.valueOf(minBaseForScaleValues.length - 2)); int scaleIndex = scaleAdjustCapped.intValue(); // Return midpont of range (the final range uses an articial end to produce reasonable midpoint) return minBaseForScaleValues[scaleIndex].add(minBaseForScaleValues[scaleIndex + 1]).multiply(pointFive); } // Convert from a value in the base unit (which can have any decimal value, like meters/sec) to a corresponding // discrete value in a scale (like beaufort), where each scale value represents a range of base values. // We binary-search the ranges to find the one that contains the specified base value, and return its index. // This can handle different scales, specified by minBaseForScaleValues[]. private BigDecimal baseToScale(BigDecimal baseValue, BigDecimal[] minBaseForScaleValues) { int scaleIndex = Arrays.binarySearch(minBaseForScaleValues, baseValue.abs()); if (scaleIndex < 0) { // since our first array entry is 0, this value will always be -2 or less scaleIndex = -scaleIndex - 2; } int scaleMax = minBaseForScaleValues.length - 2; if (scaleIndex > scaleMax) { scaleIndex = scaleMax; } return BigDecimal.valueOf(scaleIndex); } public enum Convertibility { CONVERTIBLE, RECIPROCAL, UNCONVERTIBLE, } public ConversionInfo getConversionInfo() { ConversionInfo result = new ConversionInfo(); result.conversionRate = this.conversionRate; result.offset = this.offset; result.reciprocal = this.reciprocal; return result; } public static class ConversionInfo { public BigDecimal conversionRate; public BigDecimal offset; public boolean reciprocal; } /** * Responsible for all the Factor operation * NOTE: * This class is immutable */ static class Factor { private BigDecimal factorNum; private BigDecimal factorDen; // The exponents below correspond to ICU4C's Factor::exponents[]. /** Exponent for the ft_to_m constant */ private int exponentFtToM = 0; /** Exponent for PI */ private int exponentPi = 0; /** Exponent for gravity (gravity-of-earth, "g") */ private int exponentGravity = 0; /** Exponent for Newtonian constant of gravitation "G". */ private int exponentG = 0; /** Exponent for the imperial-gallon to cubic-meter conversion rate constant */ private int exponentGalImpToM3 = 0; /** Exponent for the pound to kilogram conversion rate constant */ private int exponentLbToKg = 0; /** Exponent for the glucose molar mass conversion rate constant */ private int exponentGlucoseMolarMass = 0; /** Exponent for the item per mole conversion rate constant */ private int exponentItemPerMole = 0; /** Exponent for the meters per AU conversion rate constant */ private int exponentMetersPerAU = 0; /** Exponent for the sec per julian year conversion rate constant */ private int exponentSecPerJulianYear = 0; /** Exponent for the speed of light meters per second" conversion rate constant */ private int exponentSpeedOfLightMetersPerSecond = 0; /** Exponent for https://en.wikipedia.org/wiki/Japanese_units_of_measurement */ private int exponentShoToM3 = 0; /** Exponent for https://en.wikipedia.org/wiki/Japanese_units_of_measurement */ private int exponentTsuboToM2 = 0; /** Exponent for https://en.wikipedia.org/wiki/Japanese_units_of_measurement */ private int exponentShakuToM = 0; /** Exponent for Atomic Mass Unit */ private int exponentAMU = 0; /** * Creates Empty Factor */ public Factor() { this.factorNum = BigDecimal.valueOf(1); this.factorDen = BigDecimal.valueOf(1); } public static Factor processFactor(String factor) { assert (!factor.isEmpty()); // Remove all spaces in the factor factor = factor.replaceAll("\\s+", ""); String[] fractions = factor.split("/"); assert (fractions.length == 1 || fractions.length == 2); if (fractions.length == 1) { return processFactorWithoutDivision(fractions[0]); } Factor num = processFactorWithoutDivision(fractions[0]); Factor den = processFactorWithoutDivision(fractions[1]); return num.divide(den); } private static Factor processFactorWithoutDivision(String factorWithoutDivision) { Factor result = new Factor(); for (String poweredEntity : factorWithoutDivision.split(Pattern.quote("*"))) { result.addPoweredEntity(poweredEntity); } return result; } /** * Copy this Factor. */ protected Factor copy() { Factor result = new Factor(); result.factorNum = this.factorNum; result.factorDen = this.factorDen; result.exponentFtToM = this.exponentFtToM; result.exponentPi = this.exponentPi; result.exponentGravity = this.exponentGravity; result.exponentG = this.exponentG; result.exponentGalImpToM3 = this.exponentGalImpToM3; result.exponentLbToKg = this.exponentLbToKg; result.exponentGlucoseMolarMass = this.exponentGlucoseMolarMass; result.exponentItemPerMole = this.exponentItemPerMole; result.exponentMetersPerAU = this.exponentMetersPerAU; result.exponentSecPerJulianYear = this.exponentSecPerJulianYear; result.exponentSpeedOfLightMetersPerSecond = this.exponentSpeedOfLightMetersPerSecond; result.exponentShoToM3 = this.exponentShoToM3; result.exponentTsuboToM2 = this.exponentTsuboToM2; result.exponentShakuToM = this.exponentShakuToM; result.exponentAMU = this.exponentAMU; return result; } /** * Returns a single {@code BigDecimal} that represent the conversion rate after substituting all the constants. * * In ICU4C, see Factor::substituteConstants(). */ public BigDecimal getConversionRate() { // TODO: this copies all the exponents then doesn't use them at all. Factor resultCollector = this.copy(); // TODO(icu-units#92): port C++ unit tests to Java. // These values are a hard-coded subset of unitConstants in the // units resources file. A unit test should check that all constants // in the resource file are at least recognised by the code. // In ICU4C, these constants live in constantsValues[]. resultCollector.multiply(new BigDecimal("0.3048"), this.exponentFtToM); // TODO: this recalculates this division every time this is called. resultCollector.multiply(new BigDecimal("411557987.0").divide(new BigDecimal("131002976.0"), DECIMAL128), this.exponentPi); resultCollector.multiply(new BigDecimal("9.80665"), this.exponentGravity); resultCollector.multiply(new BigDecimal("6.67408E-11"), this.exponentG); resultCollector.multiply(new BigDecimal("0.00454609"), this.exponentGalImpToM3); resultCollector.multiply(new BigDecimal("0.45359237"), this.exponentLbToKg); resultCollector.multiply(new BigDecimal("180.1557"), this.exponentGlucoseMolarMass); resultCollector.multiply(new BigDecimal("6.02214076E+23"), this.exponentItemPerMole); resultCollector.multiply(new BigDecimal("149597870700"), this.exponentMetersPerAU); resultCollector.multiply(new BigDecimal("31557600"), this.exponentSecPerJulianYear); resultCollector.multiply(new BigDecimal("299792458"), this.exponentSpeedOfLightMetersPerSecond); resultCollector.multiply(new BigDecimal("0.001803906836964688204"), this.exponentShoToM3); // 2401/(1331*1000) resultCollector.multiply(new BigDecimal("3.305785123966942"), this.exponentTsuboToM2); // 400/121 resultCollector.multiply(new BigDecimal("0.033057851239669"), this.exponentShakuToM); // 4/121 resultCollector.multiply(new BigDecimal("1.66053878283E-27"), this.exponentAMU); return resultCollector.factorNum.divide(resultCollector.factorDen, DECIMAL128); } /** Multiplies the Factor instance by value^power. */ private void multiply(BigDecimal value, int power) { if (power == 0) return; BigDecimal absPoweredValue = value.pow(Math.abs(power), DECIMAL128); if (power > 0) { this.factorNum = this.factorNum.multiply(absPoweredValue); } else { this.factorDen = this.factorDen.multiply(absPoweredValue); } } /** Apply SI or binary prefix to the Factor. */ public Factor applyPrefix(MeasureUnit.MeasurePrefix unitPrefix) { Factor result = this.copy(); if (unitPrefix == MeasureUnit.MeasurePrefix.ONE) { return result; } int base = unitPrefix.getBase(); int power = unitPrefix.getPower(); BigDecimal absFactor = BigDecimal.valueOf(base).pow(Math.abs(power), DECIMAL128); if (power < 0) { result.factorDen = this.factorDen.multiply(absFactor); return result; } result.factorNum = this.factorNum.multiply(absFactor); return result; } public Factor power(int power) { Factor result = new Factor(); if (power == 0) return result; if (power > 0) { result.factorNum = this.factorNum.pow(power); result.factorDen = this.factorDen.pow(power); } else { result.factorNum = this.factorDen.pow(power * -1); result.factorDen = this.factorNum.pow(power * -1); } result.exponentFtToM = this.exponentFtToM * power; result.exponentPi = this.exponentPi * power; result.exponentGravity = this.exponentGravity * power; result.exponentG = this.exponentG * power; result.exponentGalImpToM3 = this.exponentGalImpToM3 * power; result.exponentLbToKg = this.exponentLbToKg * power; result.exponentGlucoseMolarMass = this.exponentGlucoseMolarMass * power; result.exponentItemPerMole = this.exponentItemPerMole * power; result.exponentMetersPerAU = this.exponentMetersPerAU * power; result.exponentSecPerJulianYear = this.exponentSecPerJulianYear * power; result.exponentSpeedOfLightMetersPerSecond = this.exponentSpeedOfLightMetersPerSecond * power; result.exponentShoToM3 = this.exponentShoToM3 * power; result.exponentTsuboToM2 = this.exponentTsuboToM2 * power; result.exponentShakuToM = this.exponentShakuToM * power; result.exponentAMU = this.exponentAMU * power; return result; } public Factor divide(Factor other) { Factor result = new Factor(); result.factorNum = this.factorNum.multiply(other.factorDen); result.factorDen = this.factorDen.multiply(other.factorNum); result.exponentFtToM = this.exponentFtToM - other.exponentFtToM; result.exponentPi = this.exponentPi - other.exponentPi; result.exponentGravity = this.exponentGravity - other.exponentGravity; result.exponentG = this.exponentG - other.exponentG; result.exponentGalImpToM3 = this.exponentGalImpToM3 - other.exponentGalImpToM3; result.exponentLbToKg = this.exponentLbToKg - other.exponentLbToKg; result.exponentGlucoseMolarMass = this.exponentGlucoseMolarMass - other.exponentGlucoseMolarMass; result.exponentItemPerMole = this.exponentItemPerMole - other.exponentItemPerMole; result.exponentMetersPerAU = this.exponentMetersPerAU - other.exponentMetersPerAU; result.exponentSecPerJulianYear = this.exponentSecPerJulianYear - other.exponentSecPerJulianYear; result.exponentSpeedOfLightMetersPerSecond = this.exponentSpeedOfLightMetersPerSecond - other.exponentSpeedOfLightMetersPerSecond; result.exponentShoToM3 = this.exponentShoToM3 - other.exponentShoToM3; result.exponentTsuboToM2 = this.exponentTsuboToM2 - other.exponentTsuboToM2; result.exponentShakuToM = this.exponentShakuToM - other.exponentShakuToM; result.exponentAMU = this.exponentAMU - other.exponentAMU; return result; } public Factor multiply(Factor other) { Factor result = new Factor(); result.factorNum = this.factorNum.multiply(other.factorNum); result.factorDen = this.factorDen.multiply(other.factorDen); result.exponentFtToM = this.exponentFtToM + other.exponentFtToM; result.exponentPi = this.exponentPi + other.exponentPi; result.exponentGravity = this.exponentGravity + other.exponentGravity; result.exponentG = this.exponentG + other.exponentG; result.exponentGalImpToM3 = this.exponentGalImpToM3 + other.exponentGalImpToM3; result.exponentLbToKg = this.exponentLbToKg + other.exponentLbToKg; result.exponentGlucoseMolarMass = this.exponentGlucoseMolarMass + other.exponentGlucoseMolarMass; result.exponentItemPerMole = this.exponentItemPerMole + other.exponentItemPerMole; result.exponentMetersPerAU = this.exponentMetersPerAU + other.exponentMetersPerAU; result.exponentSecPerJulianYear = this.exponentSecPerJulianYear + other.exponentSecPerJulianYear; result.exponentSpeedOfLightMetersPerSecond = this.exponentSpeedOfLightMetersPerSecond + other.exponentSpeedOfLightMetersPerSecond; result.exponentShoToM3 = this.exponentShoToM3 + other.exponentShoToM3; result.exponentTsuboToM2 = this.exponentTsuboToM2 + other.exponentTsuboToM2; result.exponentShakuToM = this.exponentShakuToM + other.exponentShakuToM; result.exponentAMU = this.exponentAMU + other.exponentAMU; return result; } /** * Adds Entity with power or not. For example, {@code 12 ^ 3} or {@code 12}. * * @param poweredEntity */ private void addPoweredEntity(String poweredEntity) { String[] entities = poweredEntity.split(Pattern.quote("^")); assert (entities.length == 1 || entities.length == 2); int power = entities.length == 2 ? Integer.parseInt(entities[1]) : 1; this.addEntity(entities[0], power); } private void addEntity(String entity, int power) { if ("ft_to_m".equals(entity)) { this.exponentFtToM += power; } else if ("ft2_to_m2".equals(entity)) { this.exponentFtToM += 2 * power; } else if ("ft3_to_m3".equals(entity)) { this.exponentFtToM += 3 * power; } else if ("in3_to_m3".equals(entity)) { this.exponentFtToM += 3 * power; this.factorDen = this.factorDen.multiply(BigDecimal.valueOf(Math.pow(12, 3))); } else if ("gal_to_m3".equals(entity)) { this.factorNum = this.factorNum.multiply(BigDecimal.valueOf(231)); this.exponentFtToM += 3 * power; this.factorDen = this.factorDen.multiply(BigDecimal.valueOf(12 * 12 * 12)); } else if ("gal_imp_to_m3".equals(entity)) { this.exponentGalImpToM3 += power; } else if ("G".equals(entity)) { this.exponentG += power; } else if ("gravity".equals(entity)) { this.exponentGravity += power; } else if ("lb_to_kg".equals(entity)) { this.exponentLbToKg += power; } else if ("glucose_molar_mass".equals(entity)) { this.exponentGlucoseMolarMass += power; } else if ("item_per_mole".equals(entity)) { this.exponentItemPerMole += power; } else if ("meters_per_AU".equals(entity)) { this.exponentMetersPerAU += power; } else if ("PI".equals(entity)) { this.exponentPi += power; } else if ("sec_per_julian_year".equals(entity)) { this.exponentSecPerJulianYear += power; } else if ("speed_of_light_meters_per_second".equals(entity)) { this.exponentSpeedOfLightMetersPerSecond += power; } else if ("sho_to_m3".equals(entity)) { this.exponentShoToM3 += power; } else if ("tsubo_to_m2".equals(entity)) { this.exponentTsuboToM2 += power; } else if ("shaku_to_m".equals(entity)) { this.exponentShakuToM += power; } else if ("AMU".equals(entity)) { this.exponentAMU += power; } else { BigDecimal decimalEntity = new BigDecimal(entity).pow(power, DECIMAL128); this.factorNum = this.factorNum.multiply(decimalEntity); } } } @Override public String toString() { return "UnitsConverter [conversionRate=" + conversionRate + ", offset=" + offset + "]"; } }





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