third_party/icu/source/i18n/units_converter.cpp - cobalt - Git at Google

 // © 2020 and later: Unicode, Inc. and others.
 // License & terms of use: http://www.unicode.org/copyright.html

 #include "unicode/utypes.h"

 #if !UCONFIG_NO_FORMATTING

 #include "charstr.h"
 #include "cmemory.h"
 #include "double-conversion-string-to-double.h"
 #include "measunit_impl.h"
 #include "uassert.h"
 #include "unicode/errorcode.h"
 #include "unicode/localpointer.h"
 #include "unicode/stringpiece.h"
 #include "units_converter.h"
 #include <algorithm>
 #include <cmath>
 #include <stdlib.h>
 #include <utility>

 U_NAMESPACE_BEGIN
 namespace units {

 void U_I18N_API Factor::multiplyBy(const Factor &rhs) {
     factorNum *= rhs.factorNum;
     factorDen *= rhs.factorDen;
     for (int i = 0; i < CONSTANTS_COUNT; i++) {
         constants[i] += rhs.constants[i];
     }

     // NOTE
     //  We need the offset when the source and the target are simple units. e.g. the source is
     //  celsius and the target is Fahrenheit. Therefore, we just keep the value using `std::max`.
     offset = std::max(rhs.offset, offset);
 }

 void U_I18N_API Factor::divideBy(const Factor &rhs) {
     factorNum *= rhs.factorDen;
     factorDen *= rhs.factorNum;
     for (int i = 0; i < CONSTANTS_COUNT; i++) {
         constants[i] -= rhs.constants[i];
     }

     // NOTE
     //  We need the offset when the source and the target are simple units. e.g. the source is
     //  celsius and the target is Fahrenheit. Therefore, we just keep the value using `std::max`.
     offset = std::max(rhs.offset, offset);
 }

 void U_I18N_API Factor::power(int32_t power) {
     // multiply all the constant by the power.
     for (int i = 0; i < CONSTANTS_COUNT; i++) {
         constants[i] *= power;
     }

     bool shouldFlip = power < 0; // This means that after applying the absolute power, we should flip
                                  // the Numerator and Denominator.

     factorNum = std::pow(factorNum, std::abs(power));
     factorDen = std::pow(factorDen, std::abs(power));

     if (shouldFlip) {
         // Flip Numerator and Denominator.
         std::swap(factorNum, factorDen);
     }
 }

 void U_I18N_API Factor::flip() {
     std::swap(factorNum, factorDen);

     for (int i = 0; i < CONSTANTS_COUNT; i++) {
         constants[i] *= -1;
     }
 }

 void U_I18N_API Factor::applySiPrefix(UMeasureSIPrefix siPrefix) {
     if (siPrefix == UMeasureSIPrefix::UMEASURE_SI_PREFIX_ONE) return; // No need to do anything

     double siApplied = std::pow(10.0, std::abs(siPrefix));

     if (siPrefix < 0) {
         factorDen *= siApplied;
         return;
     }

     factorNum *= siApplied;
 }

 void U_I18N_API Factor::substituteConstants() {
     for (int i = 0; i < CONSTANTS_COUNT; i++) {
         if (this->constants[i] == 0) {
             continue;
         }

         auto absPower = std::abs(this->constants[i]);
         Signum powerSig = this->constants[i] < 0 ? Signum::NEGATIVE : Signum::POSITIVE;
         double absConstantValue = std::pow(constantsValues[i], absPower);

         if (powerSig == Signum::NEGATIVE) {
             this->factorDen *= absConstantValue;
         } else {
             this->factorNum *= absConstantValue;
         }

         this->constants[i] = 0;
     }
 }

 namespace {

 /* Helpers */

 using icu::double_conversion::StringToDoubleConverter;

 // TODO: Make this a shared-utility function.
 // Returns `double` from a scientific number(i.e. "1", "2.01" or "3.09E+4")
 double strToDouble(StringPiece strNum, UErrorCode &status) {
     // We are processing well-formed input, so we don't need any special options to
     // StringToDoubleConverter.
     StringToDoubleConverter converter(0, 0, 0, "", "");
     int32_t count;
     double result = converter.StringToDouble(strNum.data(), strNum.length(), &count);
     if (count != strNum.length()) {
         status = U_INVALID_FORMAT_ERROR;
     }

     return result;
 }

 // Returns `double` from a scientific number that could has a division sign (i.e. "1", "2.01", "3.09E+4"
 // or "2E+2/3")
 double strHasDivideSignToDouble(StringPiece strWithDivide, UErrorCode &status) {
     int divisionSignInd = -1;
     for (int i = 0, n = strWithDivide.length(); i < n; ++i) {
         if (strWithDivide.data()[i] == '/') {
             divisionSignInd = i;
             break;
         }
     }

     if (divisionSignInd >= 0) {
         return strToDouble(strWithDivide.substr(0, divisionSignInd), status) /
                strToDouble(strWithDivide.substr(divisionSignInd + 1), status);
     }

     return strToDouble(strWithDivide, status);
 }

 /*
   Adds single factor to a `Factor` object. Single factor means "23^2", "23.3333", "ft2m^3" ...etc.
   However, complex factor are not included, such as "ft2m^3*200/3"
 */
 void addFactorElement(Factor &factor, StringPiece elementStr, Signum signum, UErrorCode &status) {
     StringPiece baseStr;
     StringPiece powerStr;
     int32_t power =
         1; // In case the power is not written, then, the power is equal 1 ==> `ft2m^1` == `ft2m`

     // Search for the power part
     int32_t powerInd = -1;
     for (int32_t i = 0, n = elementStr.length(); i < n; ++i) {
         if (elementStr.data()[i] == '^') {
             powerInd = i;
             break;
         }
     }

     if (powerInd > -1) {
         // There is power
         baseStr = elementStr.substr(0, powerInd);
         powerStr = elementStr.substr(powerInd + 1);

         power = static_cast<int32_t>(strToDouble(powerStr, status));
     } else {
         baseStr = elementStr;
     }

     addSingleFactorConstant(baseStr, power, signum, factor, status);
 }

 /*
  * Extracts `Factor` from a complete string factor. e.g. "ft2m^3*1007/cup2m3*3"
  */
 Factor extractFactorConversions(StringPiece stringFactor, UErrorCode &status) {
     Factor result;
     Signum signum = Signum::POSITIVE;
     auto factorData = stringFactor.data();
     for (int32_t i = 0, start = 0, n = stringFactor.length(); i < n; i++) {
         if (factorData[i] == '*' || factorData[i] == '/') {
             StringPiece factorElement = stringFactor.substr(start, i - start);
             addFactorElement(result, factorElement, signum, status);

             start = i + 1; // Set `start` to point to the start of the new element.
         } else if (i == n - 1) {
             // Last element
             addFactorElement(result, stringFactor.substr(start, i + 1), signum, status);
         }

         if (factorData[i] == '/') {
             signum = Signum::NEGATIVE; // Change the signum because we reached the Denominator.
         }
     }

     return result;
 }

 // Load factor for a single source
 Factor loadSingleFactor(StringPiece source, const ConversionRates &ratesInfo, UErrorCode &status) {
     const auto conversionUnit = ratesInfo.extractConversionInfo(source, status);
     if (U_FAILURE(status)) return Factor();
     if (conversionUnit == nullptr) {
         status = U_INTERNAL_PROGRAM_ERROR;
         return Factor();
     }

     Factor result = extractFactorConversions(conversionUnit->factor.toStringPiece(), status);
     result.offset = strHasDivideSignToDouble(conversionUnit->offset.toStringPiece(), status);

     return result;
 }

 // Load Factor of a compound source unit.
 Factor loadCompoundFactor(const MeasureUnitImpl &source, const ConversionRates &ratesInfo,
                           UErrorCode &status) {

     Factor result;
     for (int32_t i = 0, n = source.units.length(); i < n; i++) {
         SingleUnitImpl singleUnit = *source.units[i];

         Factor singleFactor = loadSingleFactor(singleUnit.getSimpleUnitID(), ratesInfo, status);
         if (U_FAILURE(status)) return result;

         // Apply SiPrefix before the power, because the power may be will flip the factor.
         singleFactor.applySiPrefix(singleUnit.siPrefix);

         // Apply the power of the `dimensionality`
         singleFactor.power(singleUnit.dimensionality);

         result.multiplyBy(singleFactor);
     }

     return result;
 }

 /**
  * Checks if the source unit and the target unit are simple. For example celsius or fahrenheit. But not
  * square-celsius or square-fahrenheit.
  *
  * NOTE:
  *  Empty unit means simple unit.
  */
 UBool checkSimpleUnit(const MeasureUnitImpl &unit, UErrorCode &status) {
     if (U_FAILURE(status)) return false;

     if (unit.complexity != UMEASURE_UNIT_SINGLE) {
         return false;
     }
     if (unit.units.length() == 0) {
         // Empty units means simple unit.
         return true;
     }

     auto singleUnit = *(unit.units[0]);

     if (singleUnit.dimensionality != 1 || singleUnit.siPrefix != UMEASURE_SI_PREFIX_ONE) {
         return false;
     }

     return true;
 }

 /**
  *  Extract conversion rate from `source` to `target`
  */
 void loadConversionRate(ConversionRate &conversionRate, const MeasureUnitImpl &source,
                         const MeasureUnitImpl &target, Convertibility unitsState,
                         const ConversionRates &ratesInfo, UErrorCode &status) {
     // Represents the conversion factor from the source to the target.
     Factor finalFactor;

     // Represents the conversion factor from the source to the base unit that specified in the conversion
     // data which is considered as the root of the source and the target.
     Factor sourceToBase = loadCompoundFactor(source, ratesInfo, status);
     Factor targetToBase = loadCompoundFactor(target, ratesInfo, status);

     // Merger Factors
     finalFactor.multiplyBy(sourceToBase);
     if (unitsState == Convertibility::CONVERTIBLE) {
         finalFactor.divideBy(targetToBase);
     } else if (unitsState == Convertibility::RECIPROCAL) {
         finalFactor.multiplyBy(targetToBase);
     } else {
         status = UErrorCode::U_ARGUMENT_TYPE_MISMATCH;
         return;
     }

     finalFactor.substituteConstants();

     conversionRate.factorNum = finalFactor.factorNum;
     conversionRate.factorDen = finalFactor.factorDen;

     // In case of simple units (such as: celsius or fahrenheit), offsets are considered.
     if (checkSimpleUnit(source, status) && checkSimpleUnit(target, status)) {
         conversionRate.sourceOffset =
             sourceToBase.offset * sourceToBase.factorDen / sourceToBase.factorNum;
         conversionRate.targetOffset =
             targetToBase.offset * targetToBase.factorDen / targetToBase.factorNum;
     }

     conversionRate.reciprocal = unitsState == Convertibility::RECIPROCAL;
 }

 struct UnitIndexAndDimension : UMemory {
     int32_t index = 0;
     int32_t dimensionality = 0;

     UnitIndexAndDimension(const SingleUnitImpl &singleUnit, int32_t multiplier) {
         index = singleUnit.index;
         dimensionality = singleUnit.dimensionality * multiplier;
     }
 };

 void mergeSingleUnitWithDimension(MaybeStackVector<UnitIndexAndDimension> &unitIndicesWithDimension,
                                   const SingleUnitImpl &shouldBeMerged, int32_t multiplier) {
     for (int32_t i = 0; i < unitIndicesWithDimension.length(); i++) {
         auto &unitWithIndex = *unitIndicesWithDimension[i];
         if (unitWithIndex.index == shouldBeMerged.index) {
             unitWithIndex.dimensionality += shouldBeMerged.dimensionality * multiplier;
             return;
         }
     }

     unitIndicesWithDimension.emplaceBack(shouldBeMerged, multiplier);
 }

 void mergeUnitsAndDimensions(MaybeStackVector<UnitIndexAndDimension> &unitIndicesWithDimension,
                              const MeasureUnitImpl &shouldBeMerged, int32_t multiplier) {
     for (int32_t unit_i = 0; unit_i < shouldBeMerged.units.length(); unit_i++) {
         auto singleUnit = *shouldBeMerged.units[unit_i];
         mergeSingleUnitWithDimension(unitIndicesWithDimension, singleUnit, multiplier);
     }
 }

 UBool checkAllDimensionsAreZeros(const MaybeStackVector<UnitIndexAndDimension> &dimensionVector) {
     for (int32_t i = 0; i < dimensionVector.length(); i++) {
         if (dimensionVector[i]->dimensionality != 0) {
             return false;
         }
     }

     return true;
 }

 } // namespace

 // Conceptually, this modifies factor: factor *= baseStr^(signum*power).
 //
 // baseStr must be a known constant or a value that strToDouble() is able to
 // parse.
 void U_I18N_API addSingleFactorConstant(StringPiece baseStr, int32_t power, Signum signum,
                                         Factor &factor, UErrorCode &status) {
     if (baseStr == "ft_to_m") {
         factor.constants[CONSTANT_FT2M] += power * signum;
     } else if (baseStr == "ft2_to_m2") {
         factor.constants[CONSTANT_FT2M] += 2 * power * signum;
     } else if (baseStr == "ft3_to_m3") {
         factor.constants[CONSTANT_FT2M] += 3 * power * signum;
     } else if (baseStr == "in3_to_m3") {
         factor.constants[CONSTANT_FT2M] += 3 * power * signum;
         factor.factorDen *= 12 * 12 * 12;
     } else if (baseStr == "gal_to_m3") {
         factor.factorNum *= 231;
         factor.constants[CONSTANT_FT2M] += 3 * power * signum;
         factor.factorDen *= 12 * 12 * 12;
     } else if (baseStr == "gal_imp_to_m3") {
         factor.constants[CONSTANT_GAL_IMP2M3] += power * signum;
     } else if (baseStr == "G") {
         factor.constants[CONSTANT_G] += power * signum;
     } else if (baseStr == "gravity") {
         factor.constants[CONSTANT_GRAVITY] += power * signum;
     } else if (baseStr == "lb_to_kg") {
         factor.constants[CONSTANT_LB2KG] += power * signum;
     } else if (baseStr == "PI") {
         factor.constants[CONSTANT_PI] += power * signum;
     } else {
         if (signum == Signum::NEGATIVE) {
             factor.factorDen *= std::pow(strToDouble(baseStr, status), power);
         } else {
             factor.factorNum *= std::pow(strToDouble(baseStr, status), power);
         }
     }
 }

 /**
  * Extracts the compound base unit of a compound unit (`source`). For example, if the source unit is
  * `square-mile-per-hour`, the compound base unit will be `square-meter-per-second`
  */
 MeasureUnitImpl U_I18N_API extractCompoundBaseUnit(const MeasureUnitImpl &source,
                                                    const ConversionRates &conversionRates,
                                                    UErrorCode &status) {

     MeasureUnitImpl result;
     if (U_FAILURE(status)) return result;

     const auto &singleUnits = source.units;
     for (int i = 0, count = singleUnits.length(); i < count; ++i) {
         const auto &singleUnit = *singleUnits[i];
         // Extract `ConversionRateInfo` using the absolute unit. For example: in case of `square-meter`,
         // we will use `meter`
         const auto rateInfo =
             conversionRates.extractConversionInfo(singleUnit.getSimpleUnitID(), status);
         if (U_FAILURE(status)) {
             return result;
         }
         if (rateInfo == nullptr) {
             status = U_INTERNAL_PROGRAM_ERROR;
             return result;
         }

         // Multiply the power of the singleUnit by the power of the baseUnit. For example, square-hectare
         // must be pow4-meter. (NOTE: hectare --> square-meter)
         auto baseUnits =
             MeasureUnitImpl::forIdentifier(rateInfo->baseUnit.toStringPiece(), status).units;
         for (int32_t i = 0, baseUnitsCount = baseUnits.length(); i < baseUnitsCount; i++) {
             baseUnits[i]->dimensionality *= singleUnit.dimensionality;
             // TODO: Deal with SI-prefix
             result.append(*baseUnits[i], status);

             if (U_FAILURE(status)) {
                 return result;
             }
         }
     }

     return result;
 }

 /**
  * Determine the convertibility between `source` and `target`.
  * For example:
  *    `meter` and `foot` are `CONVERTIBLE`.
  *    `meter-per-second` and `second-per-meter` are `RECIPROCAL`.
  *    `meter` and `pound` are `UNCONVERTIBLE`.
  *
  * NOTE:
  *    Only works with SINGLE and COMPOUND units. If one of the units is a
  *    MIXED unit, an error will occur. For more information, see UMeasureUnitComplexity.
  */
 Convertibility U_I18N_API extractConvertibility(const MeasureUnitImpl &source,
                                                 const MeasureUnitImpl &target,
                                                 const ConversionRates &conversionRates,
                                                 UErrorCode &status) {

     if (source.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED ||
         target.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED) {
         status = U_INTERNAL_PROGRAM_ERROR;
         return UNCONVERTIBLE;
     }

     MeasureUnitImpl sourceBaseUnit = extractCompoundBaseUnit(source, conversionRates, status);
     MeasureUnitImpl targetBaseUnit = extractCompoundBaseUnit(target, conversionRates, status);
     if (U_FAILURE(status)) return UNCONVERTIBLE;

     MaybeStackVector<UnitIndexAndDimension> convertible;
     MaybeStackVector<UnitIndexAndDimension> reciprocal;

     mergeUnitsAndDimensions(convertible, sourceBaseUnit, 1);
     mergeUnitsAndDimensions(reciprocal, sourceBaseUnit, 1);

     mergeUnitsAndDimensions(convertible, targetBaseUnit, -1);
     mergeUnitsAndDimensions(reciprocal, targetBaseUnit, 1);

     if (checkAllDimensionsAreZeros(convertible)) {
         return CONVERTIBLE;
     }

     if (checkAllDimensionsAreZeros(reciprocal)) {
         return RECIPROCAL;
     }

     return UNCONVERTIBLE;
 }

 UnitConverter::UnitConverter(const MeasureUnitImpl &source, const MeasureUnitImpl &target,
                              const ConversionRates &ratesInfo, UErrorCode &status)
     : conversionRate_(source.copy(status), target.copy(status)) {
     if (source.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED ||
         target.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED) {
         status = U_INTERNAL_PROGRAM_ERROR;
         return;
     }

     Convertibility unitsState = extractConvertibility(source, target, ratesInfo, status);
     if (U_FAILURE(status)) return;
     if (unitsState == Convertibility::UNCONVERTIBLE) {
         status = U_INTERNAL_PROGRAM_ERROR;
         return;
     }

     loadConversionRate(conversionRate_, conversionRate_.source, conversionRate_.target, unitsState,
                        ratesInfo, status);
 }

 double UnitConverter::convert(double inputValue) const {
     double result =
         inputValue + conversionRate_.sourceOffset; // Reset the input to the target zero index.
     // Convert the quantity to from the source scale to the target scale.
     result *= conversionRate_.factorNum / conversionRate_.factorDen;

     result -= conversionRate_.targetOffset; // Set the result to its index.

     if (conversionRate_.reciprocal) {
         if (result == 0) {
             // TODO: demonstrate the resulting behaviour in tests... and figure
             // out desired behaviour. (Theoretical result should be infinity,
             // not 0.)
             return 0.0;
         }
         result = 1.0 / result;
     }

     return result;
 }

 double UnitConverter::convertInverse(double inputValue) const {
     double result = inputValue;
     if (conversionRate_.reciprocal) {
         if (result == 0) {
             // TODO: demonstrate the resulting behaviour in tests... and figure
             // out desired behaviour. (Theoretical result should be infinity,
             // not 0.)
             return 0.0;
         }
         result = 1.0 / result;
     }
     result += conversionRate_.targetOffset;
     result *= conversionRate_.factorDen / conversionRate_.factorNum;
     result -= conversionRate_.sourceOffset;
     return result;
 }

 } // namespace units
 U_NAMESPACE_END

 #endif /* #if !UCONFIG_NO_FORMATTING */
	// © 2020 and later: Unicode, Inc. and others.
	// License & terms of use: http://www.unicode.org/copyright.html

	#include "unicode/utypes.h"

	#if !UCONFIG_NO_FORMATTING

	#include "charstr.h"
	#include "cmemory.h"
	#include "double-conversion-string-to-double.h"
	#include "measunit_impl.h"
	#include "uassert.h"
	#include "unicode/errorcode.h"
	#include "unicode/localpointer.h"
	#include "unicode/stringpiece.h"
	#include "units_converter.h"
	#include <algorithm>
	#include <cmath>
	#include <stdlib.h>
	#include <utility>

	U_NAMESPACE_BEGIN
	namespace units {

	void U_I18N_API Factor::multiplyBy(const Factor &rhs) {
	factorNum *= rhs.factorNum;
	factorDen *= rhs.factorDen;
	for (int i = 0; i < CONSTANTS_COUNT; i++) {
	constants[i] += rhs.constants[i];
	}

	// NOTE
	// We need the offset when the source and the target are simple units. e.g. the source is
	// celsius and the target is Fahrenheit. Therefore, we just keep the value using `std::max`.
	offset = std::max(rhs.offset, offset);
	}

	void U_I18N_API Factor::divideBy(const Factor &rhs) {
	factorNum *= rhs.factorDen;
	factorDen *= rhs.factorNum;
	for (int i = 0; i < CONSTANTS_COUNT; i++) {
	constants[i] -= rhs.constants[i];
	}

	// NOTE
	// We need the offset when the source and the target are simple units. e.g. the source is
	// celsius and the target is Fahrenheit. Therefore, we just keep the value using `std::max`.
	offset = std::max(rhs.offset, offset);
	}

	void U_I18N_API Factor::power(int32_t power) {
	// multiply all the constant by the power.
	for (int i = 0; i < CONSTANTS_COUNT; i++) {
	constants[i] *= power;
	}

	bool shouldFlip = power < 0; // This means that after applying the absolute power, we should flip
	// the Numerator and Denominator.

	factorNum = std::pow(factorNum, std::abs(power));
	factorDen = std::pow(factorDen, std::abs(power));

	if (shouldFlip) {
	// Flip Numerator and Denominator.
	std::swap(factorNum, factorDen);
	}
	}

	void U_I18N_API Factor::flip() {
	std::swap(factorNum, factorDen);

	for (int i = 0; i < CONSTANTS_COUNT; i++) {
	constants[i] *= -1;
	}
	}

	void U_I18N_API Factor::applySiPrefix(UMeasureSIPrefix siPrefix) {
	if (siPrefix == UMeasureSIPrefix::UMEASURE_SI_PREFIX_ONE) return; // No need to do anything

	double siApplied = std::pow(10.0, std::abs(siPrefix));

	if (siPrefix < 0) {
	factorDen *= siApplied;
	return;
	}

	factorNum *= siApplied;
	}

	void U_I18N_API Factor::substituteConstants() {
	for (int i = 0; i < CONSTANTS_COUNT; i++) {
	if (this->constants[i] == 0) {
	continue;
	}

	auto absPower = std::abs(this->constants[i]);
	Signum powerSig = this->constants[i] < 0 ? Signum::NEGATIVE : Signum::POSITIVE;
	double absConstantValue = std::pow(constantsValues[i], absPower);

	if (powerSig == Signum::NEGATIVE) {
	this->factorDen *= absConstantValue;
	} else {
	this->factorNum *= absConstantValue;
	}

	this->constants[i] = 0;
	}
	}

	namespace {

	/* Helpers */

	using icu::double_conversion::StringToDoubleConverter;

	// TODO: Make this a shared-utility function.
	// Returns `double` from a scientific number(i.e. "1", "2.01" or "3.09E+4")
	double strToDouble(StringPiece strNum, UErrorCode &status) {
	// We are processing well-formed input, so we don't need any special options to
	// StringToDoubleConverter.
	StringToDoubleConverter converter(0, 0, 0, "", "");
	int32_t count;
	double result = converter.StringToDouble(strNum.data(), strNum.length(), &count);
	if (count != strNum.length()) {
	status = U_INVALID_FORMAT_ERROR;
	}

	return result;
	}

	// Returns `double` from a scientific number that could has a division sign (i.e. "1", "2.01", "3.09E+4"
	// or "2E+2/3")
	double strHasDivideSignToDouble(StringPiece strWithDivide, UErrorCode &status) {
	int divisionSignInd = -1;
	for (int i = 0, n = strWithDivide.length(); i < n; ++i) {
	if (strWithDivide.data()[i] == '/') {
	divisionSignInd = i;
	break;
	}
	}

	if (divisionSignInd >= 0) {
	return strToDouble(strWithDivide.substr(0, divisionSignInd), status) /
	strToDouble(strWithDivide.substr(divisionSignInd + 1), status);
	}

	return strToDouble(strWithDivide, status);
	}

	/*
	Adds single factor to a `Factor` object. Single factor means "23^2", "23.3333", "ft2m^3" ...etc.
	However, complex factor are not included, such as "ft2m^3*200/3"
	*/
	void addFactorElement(Factor &factor, StringPiece elementStr, Signum signum, UErrorCode &status) {
	StringPiece baseStr;
	StringPiece powerStr;
	int32_t power =
	1; // In case the power is not written, then, the power is equal 1 ==> `ft2m^1` == `ft2m`

	// Search for the power part
	int32_t powerInd = -1;
	for (int32_t i = 0, n = elementStr.length(); i < n; ++i) {
	if (elementStr.data()[i] == '^') {
	powerInd = i;
	break;
	}
	}

	if (powerInd > -1) {
	// There is power
	baseStr = elementStr.substr(0, powerInd);
	powerStr = elementStr.substr(powerInd + 1);

	power = static_cast<int32_t>(strToDouble(powerStr, status));
	} else {
	baseStr = elementStr;
	}

	addSingleFactorConstant(baseStr, power, signum, factor, status);
	}

	/*
	* Extracts `Factor` from a complete string factor. e.g. "ft2m^31007/cup2m33"
	*/
	Factor extractFactorConversions(StringPiece stringFactor, UErrorCode &status) {
	Factor result;
	Signum signum = Signum::POSITIVE;
	auto factorData = stringFactor.data();
	for (int32_t i = 0, start = 0, n = stringFactor.length(); i < n; i++) {
	if (factorData[i] == '*' \|\| factorData[i] == '/') {
	StringPiece factorElement = stringFactor.substr(start, i - start);
	addFactorElement(result, factorElement, signum, status);

	start = i + 1; // Set `start` to point to the start of the new element.
	} else if (i == n - 1) {
	// Last element
	addFactorElement(result, stringFactor.substr(start, i + 1), signum, status);
	}

	if (factorData[i] == '/') {
	signum = Signum::NEGATIVE; // Change the signum because we reached the Denominator.
	}
	}

	return result;
	}

	// Load factor for a single source
	Factor loadSingleFactor(StringPiece source, const ConversionRates &ratesInfo, UErrorCode &status) {
	const auto conversionUnit = ratesInfo.extractConversionInfo(source, status);
	if (U_FAILURE(status)) return Factor();
	if (conversionUnit == nullptr) {
	status = U_INTERNAL_PROGRAM_ERROR;
	return Factor();
	}

	Factor result = extractFactorConversions(conversionUnit->factor.toStringPiece(), status);
	result.offset = strHasDivideSignToDouble(conversionUnit->offset.toStringPiece(), status);

	return result;
	}

	// Load Factor of a compound source unit.
	Factor loadCompoundFactor(const MeasureUnitImpl &source, const ConversionRates &ratesInfo,
	UErrorCode &status) {

	Factor result;
	for (int32_t i = 0, n = source.units.length(); i < n; i++) {
	SingleUnitImpl singleUnit = *source.units[i];

	Factor singleFactor = loadSingleFactor(singleUnit.getSimpleUnitID(), ratesInfo, status);
	if (U_FAILURE(status)) return result;

	// Apply SiPrefix before the power, because the power may be will flip the factor.
	singleFactor.applySiPrefix(singleUnit.siPrefix);

	// Apply the power of the `dimensionality`
	singleFactor.power(singleUnit.dimensionality);

	result.multiplyBy(singleFactor);
	}

	return result;
	}

	/**
	* Checks if the source unit and the target unit are simple. For example celsius or fahrenheit. But not
	* square-celsius or square-fahrenheit.
	*
	* NOTE:
	* Empty unit means simple unit.
	*/
	UBool checkSimpleUnit(const MeasureUnitImpl &unit, UErrorCode &status) {
	if (U_FAILURE(status)) return false;

	if (unit.complexity != UMEASURE_UNIT_SINGLE) {
	return false;
	}
	if (unit.units.length() == 0) {
	// Empty units means simple unit.
	return true;
	}

	auto singleUnit = *(unit.units[0]);

	if (singleUnit.dimensionality != 1 \|\| singleUnit.siPrefix != UMEASURE_SI_PREFIX_ONE) {
	return false;
	}

	return true;
	}

	/**
	* Extract conversion rate from `source` to `target`
	*/
	void loadConversionRate(ConversionRate &conversionRate, const MeasureUnitImpl &source,
	const MeasureUnitImpl &target, Convertibility unitsState,
	const ConversionRates &ratesInfo, UErrorCode &status) {
	// Represents the conversion factor from the source to the target.
	Factor finalFactor;

	// Represents the conversion factor from the source to the base unit that specified in the conversion
	// data which is considered as the root of the source and the target.
	Factor sourceToBase = loadCompoundFactor(source, ratesInfo, status);
	Factor targetToBase = loadCompoundFactor(target, ratesInfo, status);

	// Merger Factors
	finalFactor.multiplyBy(sourceToBase);
	if (unitsState == Convertibility::CONVERTIBLE) {
	finalFactor.divideBy(targetToBase);
	} else if (unitsState == Convertibility::RECIPROCAL) {
	finalFactor.multiplyBy(targetToBase);
	} else {
	status = UErrorCode::U_ARGUMENT_TYPE_MISMATCH;
	return;
	}

	finalFactor.substituteConstants();

	conversionRate.factorNum = finalFactor.factorNum;
	conversionRate.factorDen = finalFactor.factorDen;

	// In case of simple units (such as: celsius or fahrenheit), offsets are considered.
	if (checkSimpleUnit(source, status) && checkSimpleUnit(target, status)) {
	conversionRate.sourceOffset =
	sourceToBase.offset * sourceToBase.factorDen / sourceToBase.factorNum;
	conversionRate.targetOffset =
	targetToBase.offset * targetToBase.factorDen / targetToBase.factorNum;
	}

	conversionRate.reciprocal = unitsState == Convertibility::RECIPROCAL;
	}

	struct UnitIndexAndDimension : UMemory {
	int32_t index = 0;
	int32_t dimensionality = 0;

	UnitIndexAndDimension(const SingleUnitImpl &singleUnit, int32_t multiplier) {
	index = singleUnit.index;
	dimensionality = singleUnit.dimensionality * multiplier;
	}
	};

	void mergeSingleUnitWithDimension(MaybeStackVector<UnitIndexAndDimension> &unitIndicesWithDimension,
	const SingleUnitImpl &shouldBeMerged, int32_t multiplier) {
	for (int32_t i = 0; i < unitIndicesWithDimension.length(); i++) {
	auto &unitWithIndex = *unitIndicesWithDimension[i];
	if (unitWithIndex.index == shouldBeMerged.index) {
	unitWithIndex.dimensionality += shouldBeMerged.dimensionality * multiplier;
	return;
	}
	}

	unitIndicesWithDimension.emplaceBack(shouldBeMerged, multiplier);
	}

	void mergeUnitsAndDimensions(MaybeStackVector<UnitIndexAndDimension> &unitIndicesWithDimension,
	const MeasureUnitImpl &shouldBeMerged, int32_t multiplier) {
	for (int32_t unit_i = 0; unit_i < shouldBeMerged.units.length(); unit_i++) {
	auto singleUnit = *shouldBeMerged.units[unit_i];
	mergeSingleUnitWithDimension(unitIndicesWithDimension, singleUnit, multiplier);
	}
	}

	UBool checkAllDimensionsAreZeros(const MaybeStackVector<UnitIndexAndDimension> &dimensionVector) {
	for (int32_t i = 0; i < dimensionVector.length(); i++) {
	if (dimensionVector[i]->dimensionality != 0) {
	return false;
	}
	}

	return true;
	}

	} // namespace

	// Conceptually, this modifies factor: factor = baseStr^(signumpower).
	//
	// baseStr must be a known constant or a value that strToDouble() is able to
	// parse.
	void U_I18N_API addSingleFactorConstant(StringPiece baseStr, int32_t power, Signum signum,
	Factor &factor, UErrorCode &status) {
	if (baseStr == "ft_to_m") {
	factor.constants[CONSTANT_FT2M] += power * signum;
	} else if (baseStr == "ft2_to_m2") {
	factor.constants[CONSTANT_FT2M] += 2 * power * signum;
	} else if (baseStr == "ft3_to_m3") {
	factor.constants[CONSTANT_FT2M] += 3 * power * signum;
	} else if (baseStr == "in3_to_m3") {
	factor.constants[CONSTANT_FT2M] += 3 * power * signum;
	factor.factorDen = 12 12 * 12;
	} else if (baseStr == "gal_to_m3") {
	factor.factorNum *= 231;
	factor.constants[CONSTANT_FT2M] += 3 * power * signum;
	factor.factorDen = 12 12 * 12;
	} else if (baseStr == "gal_imp_to_m3") {
	factor.constants[CONSTANT_GAL_IMP2M3] += power * signum;
	} else if (baseStr == "G") {
	factor.constants[CONSTANT_G] += power * signum;
	} else if (baseStr == "gravity") {
	factor.constants[CONSTANT_GRAVITY] += power * signum;
	} else if (baseStr == "lb_to_kg") {
	factor.constants[CONSTANT_LB2KG] += power * signum;
	} else if (baseStr == "PI") {
	factor.constants[CONSTANT_PI] += power * signum;
	} else {
	if (signum == Signum::NEGATIVE) {
	factor.factorDen *= std::pow(strToDouble(baseStr, status), power);
	} else {
	factor.factorNum *= std::pow(strToDouble(baseStr, status), power);
	}
	}
	}

	/**
	* Extracts the compound base unit of a compound unit (`source`). For example, if the source unit is
	* `square-mile-per-hour`, the compound base unit will be `square-meter-per-second`
	*/
	MeasureUnitImpl U_I18N_API extractCompoundBaseUnit(const MeasureUnitImpl &source,
	const ConversionRates &conversionRates,
	UErrorCode &status) {

	MeasureUnitImpl result;
	if (U_FAILURE(status)) return result;

	const auto &singleUnits = source.units;
	for (int i = 0, count = singleUnits.length(); i < count; ++i) {
	const auto &singleUnit = *singleUnits[i];
	// Extract `ConversionRateInfo` using the absolute unit. For example: in case of `square-meter`,
	// we will use `meter`
	const auto rateInfo =
	conversionRates.extractConversionInfo(singleUnit.getSimpleUnitID(), status);
	if (U_FAILURE(status)) {
	return result;
	}
	if (rateInfo == nullptr) {
	status = U_INTERNAL_PROGRAM_ERROR;
	return result;
	}

	// Multiply the power of the singleUnit by the power of the baseUnit. For example, square-hectare
	// must be pow4-meter. (NOTE: hectare --> square-meter)
	auto baseUnits =
	MeasureUnitImpl::forIdentifier(rateInfo->baseUnit.toStringPiece(), status).units;
	for (int32_t i = 0, baseUnitsCount = baseUnits.length(); i < baseUnitsCount; i++) {
	baseUnits[i]->dimensionality *= singleUnit.dimensionality;
	// TODO: Deal with SI-prefix
	result.append(*baseUnits[i], status);

	if (U_FAILURE(status)) {
	return result;
	}
	}
	}

	return result;
	}

	/**
	* Determine the convertibility between `source` and `target`.
	* For example:
	* `meter` and `foot` are `CONVERTIBLE`.
	* `meter-per-second` and `second-per-meter` are `RECIPROCAL`.
	* `meter` and `pound` are `UNCONVERTIBLE`.
	*
	* NOTE:
	* Only works with SINGLE and COMPOUND units. If one of the units is a
	* MIXED unit, an error will occur. For more information, see UMeasureUnitComplexity.
	*/
	Convertibility U_I18N_API extractConvertibility(const MeasureUnitImpl &source,
	const MeasureUnitImpl &target,
	const ConversionRates &conversionRates,
	UErrorCode &status) {

	if (source.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED \|\|
	target.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED) {
	status = U_INTERNAL_PROGRAM_ERROR;
	return UNCONVERTIBLE;
	}

	MeasureUnitImpl sourceBaseUnit = extractCompoundBaseUnit(source, conversionRates, status);
	MeasureUnitImpl targetBaseUnit = extractCompoundBaseUnit(target, conversionRates, status);
	if (U_FAILURE(status)) return UNCONVERTIBLE;

	MaybeStackVector<UnitIndexAndDimension> convertible;
	MaybeStackVector<UnitIndexAndDimension> reciprocal;

	mergeUnitsAndDimensions(convertible, sourceBaseUnit, 1);
	mergeUnitsAndDimensions(reciprocal, sourceBaseUnit, 1);

	mergeUnitsAndDimensions(convertible, targetBaseUnit, -1);
	mergeUnitsAndDimensions(reciprocal, targetBaseUnit, 1);

	if (checkAllDimensionsAreZeros(convertible)) {
	return CONVERTIBLE;
	}

	if (checkAllDimensionsAreZeros(reciprocal)) {
	return RECIPROCAL;
	}

	return UNCONVERTIBLE;
	}

	UnitConverter::UnitConverter(const MeasureUnitImpl &source, const MeasureUnitImpl &target,
	const ConversionRates &ratesInfo, UErrorCode &status)
	: conversionRate_(source.copy(status), target.copy(status)) {
	if (source.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED \|\|
	target.complexity == UMeasureUnitComplexity::UMEASURE_UNIT_MIXED) {
	status = U_INTERNAL_PROGRAM_ERROR;
	return;
	}

	Convertibility unitsState = extractConvertibility(source, target, ratesInfo, status);
	if (U_FAILURE(status)) return;
	if (unitsState == Convertibility::UNCONVERTIBLE) {
	status = U_INTERNAL_PROGRAM_ERROR;
	return;
	}

	loadConversionRate(conversionRate_, conversionRate_.source, conversionRate_.target, unitsState,
	ratesInfo, status);
	}

	double UnitConverter::convert(double inputValue) const {
	double result =
	inputValue + conversionRate_.sourceOffset; // Reset the input to the target zero index.
	// Convert the quantity to from the source scale to the target scale.
	result *= conversionRate_.factorNum / conversionRate_.factorDen;

	result -= conversionRate_.targetOffset; // Set the result to its index.

	if (conversionRate_.reciprocal) {
	if (result == 0) {
	// TODO: demonstrate the resulting behaviour in tests... and figure
	// out desired behaviour. (Theoretical result should be infinity,
	// not 0.)
	return 0.0;
	}
	result = 1.0 / result;
	}

	return result;
	}

	double UnitConverter::convertInverse(double inputValue) const {
	double result = inputValue;
	if (conversionRate_.reciprocal) {
	if (result == 0) {
	// TODO: demonstrate the resulting behaviour in tests... and figure
	// out desired behaviour. (Theoretical result should be infinity,
	// not 0.)
	return 0.0;
	}
	result = 1.0 / result;
	}
	result += conversionRate_.targetOffset;
	result *= conversionRate_.factorDen / conversionRate_.factorNum;
	result -= conversionRate_.sourceOffset;
	return result;
	}

	} // namespace units
	U_NAMESPACE_END

	#endif /* #if !UCONFIG_NO_FORMATTING */