// © 2020 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html // Extra functions for MeasureUnit not needed for all clients. // Separate .o file so that it can be removed for modularity. #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING // Allow implicit conversion from char16_t* to UnicodeString for this file: // Helpful in toString methods and elsewhere. #define UNISTR_FROM_STRING_EXPLICIT #include #include "cstring.h" #include "measunit_impl.h" #include "uarrsort.h" #include "uassert.h" #include "ucln_in.h" #include "umutex.h" #include "unicode/errorcode.h" #include "unicode/localpointer.h" #include "unicode/measunit.h" #include "unicode/ucharstrie.h" #include "unicode/ucharstriebuilder.h" #include "cstr.h" U_NAMESPACE_BEGIN namespace { // TODO: Propose a new error code for this? constexpr UErrorCode kUnitIdentifierSyntaxError = U_ILLEGAL_ARGUMENT_ERROR; // Trie value offset for SI Prefixes. This is big enough to ensure we only // insert positive integers into the trie. constexpr int32_t kSIPrefixOffset = 64; // Trie value offset for compound parts, e.g. "-per-", "-", "-and-". constexpr int32_t kCompoundPartOffset = 128; enum CompoundPart { // Represents "-per-" COMPOUND_PART_PER = kCompoundPartOffset, // Represents "-" COMPOUND_PART_TIMES, // Represents "-and-" COMPOUND_PART_AND, }; // Trie value offset for "per-". constexpr int32_t kInitialCompoundPartOffset = 192; enum InitialCompoundPart { // Represents "per-", the only compound part that can appear at the start of // an identifier. INITIAL_COMPOUND_PART_PER = kInitialCompoundPartOffset, }; // Trie value offset for powers like "square-", "cubic-", "p2-" etc. constexpr int32_t kPowerPartOffset = 256; enum PowerPart { POWER_PART_P2 = kPowerPartOffset + 2, POWER_PART_P3, POWER_PART_P4, POWER_PART_P5, POWER_PART_P6, POWER_PART_P7, POWER_PART_P8, POWER_PART_P9, POWER_PART_P10, POWER_PART_P11, POWER_PART_P12, POWER_PART_P13, POWER_PART_P14, POWER_PART_P15, }; // Trie value offset for simple units, e.g. "gram", "nautical-mile", // "fluid-ounce-imperial". constexpr int32_t kSimpleUnitOffset = 512; const struct SIPrefixStrings { const char* const string; UMeasureSIPrefix value; } gSIPrefixStrings[] = { { "yotta", UMEASURE_SI_PREFIX_YOTTA }, { "zetta", UMEASURE_SI_PREFIX_ZETTA }, { "exa", UMEASURE_SI_PREFIX_EXA }, { "peta", UMEASURE_SI_PREFIX_PETA }, { "tera", UMEASURE_SI_PREFIX_TERA }, { "giga", UMEASURE_SI_PREFIX_GIGA }, { "mega", UMEASURE_SI_PREFIX_MEGA }, { "kilo", UMEASURE_SI_PREFIX_KILO }, { "hecto", UMEASURE_SI_PREFIX_HECTO }, { "deka", UMEASURE_SI_PREFIX_DEKA }, { "deci", UMEASURE_SI_PREFIX_DECI }, { "centi", UMEASURE_SI_PREFIX_CENTI }, { "milli", UMEASURE_SI_PREFIX_MILLI }, { "micro", UMEASURE_SI_PREFIX_MICRO }, { "nano", UMEASURE_SI_PREFIX_NANO }, { "pico", UMEASURE_SI_PREFIX_PICO }, { "femto", UMEASURE_SI_PREFIX_FEMTO }, { "atto", UMEASURE_SI_PREFIX_ATTO }, { "zepto", UMEASURE_SI_PREFIX_ZEPTO }, { "yocto", UMEASURE_SI_PREFIX_YOCTO }, }; // TODO(ICU-21059): Get this list from data const char16_t* const gSimpleUnits[] = { u"candela", u"carat", u"gram", u"ounce", u"ounce-troy", u"pound", u"kilogram", u"stone", u"ton", u"metric-ton", u"earth-mass", u"solar-mass", u"point", u"inch", u"foot", u"yard", u"meter", u"fathom", u"furlong", u"mile", u"nautical-mile", u"mile-scandinavian", u"100-kilometer", u"earth-radius", u"solar-radius", u"astronomical-unit", u"light-year", u"parsec", u"second", u"minute", u"hour", u"day", u"day-person", u"week", u"week-person", u"month", u"month-person", u"year", u"year-person", u"decade", u"century", u"ampere", u"fahrenheit", u"kelvin", u"celsius", u"arc-second", u"arc-minute", u"degree", u"radian", u"revolution", u"item", u"mole", u"permillion", u"permyriad", u"permille", u"percent", u"karat", u"portion", u"bit", u"byte", u"dot", u"pixel", u"em", u"hertz", u"newton", u"pound-force", u"pascal", u"bar", u"atmosphere", u"ofhg", u"electronvolt", u"dalton", u"joule", u"calorie", u"british-thermal-unit", u"foodcalorie", u"therm-us", u"watt", u"horsepower", u"solar-luminosity", u"volt", u"ohm", u"dunam", u"acre", u"hectare", u"teaspoon", u"tablespoon", u"fluid-ounce-imperial", u"fluid-ounce", u"cup", u"cup-metric", u"pint", u"pint-metric", u"quart", u"liter", u"gallon", u"gallon-imperial", u"bushel", u"barrel", u"knot", u"g-force", u"lux", }; icu::UInitOnce gUnitExtrasInitOnce = U_INITONCE_INITIALIZER; char16_t* kSerializedUnitExtrasStemTrie = nullptr; UBool U_CALLCONV cleanupUnitExtras() { uprv_free(kSerializedUnitExtrasStemTrie); kSerializedUnitExtrasStemTrie = nullptr; gUnitExtrasInitOnce.reset(); return TRUE; } void U_CALLCONV initUnitExtras(UErrorCode& status) { ucln_i18n_registerCleanup(UCLN_I18N_UNIT_EXTRAS, cleanupUnitExtras); UCharsTrieBuilder b(status); if (U_FAILURE(status)) { return; } // Add SI prefixes for (const auto& siPrefixInfo : gSIPrefixStrings) { UnicodeString uSIPrefix(siPrefixInfo.string, -1, US_INV); b.add(uSIPrefix, siPrefixInfo.value + kSIPrefixOffset, status); } if (U_FAILURE(status)) { return; } // Add syntax parts (compound, power prefixes) b.add(u"-per-", COMPOUND_PART_PER, status); b.add(u"-", COMPOUND_PART_TIMES, status); b.add(u"-and-", COMPOUND_PART_AND, status); b.add(u"per-", INITIAL_COMPOUND_PART_PER, status); b.add(u"square-", POWER_PART_P2, status); b.add(u"cubic-", POWER_PART_P3, status); b.add(u"p2-", POWER_PART_P2, status); b.add(u"p3-", POWER_PART_P3, status); b.add(u"p4-", POWER_PART_P4, status); b.add(u"p5-", POWER_PART_P5, status); b.add(u"p6-", POWER_PART_P6, status); b.add(u"p7-", POWER_PART_P7, status); b.add(u"p8-", POWER_PART_P8, status); b.add(u"p9-", POWER_PART_P9, status); b.add(u"p10-", POWER_PART_P10, status); b.add(u"p11-", POWER_PART_P11, status); b.add(u"p12-", POWER_PART_P12, status); b.add(u"p13-", POWER_PART_P13, status); b.add(u"p14-", POWER_PART_P14, status); b.add(u"p15-", POWER_PART_P15, status); if (U_FAILURE(status)) { return; } // Add sanctioned simple units by offset int32_t simpleUnitOffset = kSimpleUnitOffset; for (auto simpleUnit : gSimpleUnits) { b.add(simpleUnit, simpleUnitOffset++, status); } // Build the CharsTrie // TODO: Use SLOW or FAST here? UnicodeString result; b.buildUnicodeString(USTRINGTRIE_BUILD_FAST, result, status); if (U_FAILURE(status)) { return; } // Copy the result into the global constant pointer size_t numBytes = result.length() * sizeof(char16_t); kSerializedUnitExtrasStemTrie = static_cast(uprv_malloc(numBytes)); uprv_memcpy(kSerializedUnitExtrasStemTrie, result.getBuffer(), numBytes); } class Token { public: Token(int32_t match) : fMatch(match) {} enum Type { TYPE_UNDEFINED, TYPE_SI_PREFIX, // Token type for "-per-", "-", and "-and-". TYPE_COMPOUND_PART, // Token type for "per-". TYPE_INITIAL_COMPOUND_PART, TYPE_POWER_PART, TYPE_SIMPLE_UNIT, }; // Calling getType() is invalid, resulting in an assertion failure, if Token // value isn't positive. Type getType() const { U_ASSERT(fMatch > 0); if (fMatch < kCompoundPartOffset) { return TYPE_SI_PREFIX; } if (fMatch < kInitialCompoundPartOffset) { return TYPE_COMPOUND_PART; } if (fMatch < kPowerPartOffset) { return TYPE_INITIAL_COMPOUND_PART; } if (fMatch < kSimpleUnitOffset) { return TYPE_POWER_PART; } return TYPE_SIMPLE_UNIT; } UMeasureSIPrefix getSIPrefix() const { U_ASSERT(getType() == TYPE_SI_PREFIX); return static_cast(fMatch - kSIPrefixOffset); } // Valid only for tokens with type TYPE_COMPOUND_PART. int32_t getMatch() const { U_ASSERT(getType() == TYPE_COMPOUND_PART); return fMatch; } int32_t getInitialCompoundPart() const { // Even if there is only one InitialCompoundPart value, we have this // function for the simplicity of code consistency. U_ASSERT(getType() == TYPE_INITIAL_COMPOUND_PART); // Defensive: if this assert fails, code using this function also needs // to change. U_ASSERT(fMatch == INITIAL_COMPOUND_PART_PER); return fMatch; } int8_t getPower() const { U_ASSERT(getType() == TYPE_POWER_PART); return static_cast(fMatch - kPowerPartOffset); } int32_t getSimpleUnitIndex() const { U_ASSERT(getType() == TYPE_SIMPLE_UNIT); return fMatch - kSimpleUnitOffset; } private: int32_t fMatch; }; class Parser { public: /** * Factory function for parsing the given identifier. * * @param source The identifier to parse. This function does not make a copy * of source: the underlying string that source points at, must outlive the * parser. * @param status ICU error code. */ static Parser from(StringPiece source, UErrorCode& status) { if (U_FAILURE(status)) { return Parser(); } umtx_initOnce(gUnitExtrasInitOnce, &initUnitExtras, status); if (U_FAILURE(status)) { return Parser(); } return Parser(source); } MeasureUnitImpl parse(UErrorCode& status) { MeasureUnitImpl result; parseImpl(result, status); return result; } private: // Tracks parser progress: the offset into fSource. int32_t fIndex = 0; // Since we're not owning this memory, whatever is passed to the constructor // should live longer than this Parser - and the parser shouldn't return any // references to that string. StringPiece fSource; UCharsTrie fTrie; // Set to true when we've seen a "-per-" or a "per-", after which all units // are in the denominator. Until we find an "-and-", at which point the // identifier is invalid pending TODO(CLDR-13700). bool fAfterPer = false; Parser() : fSource(""), fTrie(u"") {} Parser(StringPiece source) : fSource(source), fTrie(kSerializedUnitExtrasStemTrie) {} inline bool hasNext() const { return fIndex < fSource.length(); } // Returns the next Token parsed from fSource, advancing fIndex to the end // of that token in fSource. In case of U_FAILURE(status), the token // returned will cause an abort if getType() is called on it. Token nextToken(UErrorCode& status) { fTrie.reset(); int32_t match = -1; // Saves the position in the fSource string for the end of the most // recent matching token. int32_t previ = -1; // Find the longest token that matches a value in the trie: while (fIndex < fSource.length()) { auto result = fTrie.next(fSource.data()[fIndex++]); if (result == USTRINGTRIE_NO_MATCH) { break; } else if (result == USTRINGTRIE_NO_VALUE) { continue; } U_ASSERT(USTRINGTRIE_HAS_VALUE(result)); match = fTrie.getValue(); previ = fIndex; if (result == USTRINGTRIE_FINAL_VALUE) { break; } U_ASSERT(result == USTRINGTRIE_INTERMEDIATE_VALUE); // continue; } if (match < 0) { status = kUnitIdentifierSyntaxError; } else { fIndex = previ; } return Token(match); } /** * Returns the next "single unit" via result. * * If a "-per-" was parsed, the result will have appropriate negative * dimensionality. * * Returns an error if we parse both compound units and "-and-", since mixed * compound units are not yet supported - TODO(CLDR-13700). * * @param result Will be overwritten by the result, if status shows success. * @param sawAnd If an "-and-" was parsed prior to finding the "single * unit", sawAnd is set to true. If not, it is left as is. * @param status ICU error code. */ void nextSingleUnit(SingleUnitImpl& result, bool& sawAnd, UErrorCode& status) { if (U_FAILURE(status)) { return; } // state: // 0 = no tokens seen yet (will accept power, SI prefix, or simple unit) // 1 = power token seen (will not accept another power token) // 2 = SI prefix token seen (will not accept a power or SI prefix token) int32_t state = 0; bool atStart = fIndex == 0; Token token = nextToken(status); if (U_FAILURE(status)) { return; } if (atStart) { // Identifiers optionally start with "per-". if (token.getType() == Token::TYPE_INITIAL_COMPOUND_PART) { U_ASSERT(token.getInitialCompoundPart() == INITIAL_COMPOUND_PART_PER); fAfterPer = true; result.dimensionality = -1; token = nextToken(status); if (U_FAILURE(status)) { return; } } } else { // All other SingleUnit's are separated from previous SingleUnit's // via a compound part: if (token.getType() != Token::TYPE_COMPOUND_PART) { status = kUnitIdentifierSyntaxError; return; } switch (token.getMatch()) { case COMPOUND_PART_PER: if (sawAnd) { // Mixed compound units not yet supported, // TODO(CLDR-13700). status = kUnitIdentifierSyntaxError; return; } fAfterPer = true; result.dimensionality = -1; break; case COMPOUND_PART_TIMES: if (fAfterPer) { result.dimensionality = -1; } break; case COMPOUND_PART_AND: if (fAfterPer) { // Can't start with "-and-", and mixed compound units // not yet supported, TODO(CLDR-13700). status = kUnitIdentifierSyntaxError; return; } sawAnd = true; break; } token = nextToken(status); if (U_FAILURE(status)) { return; } } // Read tokens until we have a complete SingleUnit or we reach the end. while (true) { switch (token.getType()) { case Token::TYPE_POWER_PART: if (state > 0) { status = kUnitIdentifierSyntaxError; return; } result.dimensionality *= token.getPower(); state = 1; break; case Token::TYPE_SI_PREFIX: if (state > 1) { status = kUnitIdentifierSyntaxError; return; } result.siPrefix = token.getSIPrefix(); state = 2; break; case Token::TYPE_SIMPLE_UNIT: result.index = token.getSimpleUnitIndex(); return; default: status = kUnitIdentifierSyntaxError; return; } if (!hasNext()) { // We ran out of tokens before finding a complete single unit. status = kUnitIdentifierSyntaxError; return; } token = nextToken(status); if (U_FAILURE(status)) { return; } } } /// @param result is modified, not overridden. Caller must pass in a /// default-constructed (empty) MeasureUnitImpl instance. void parseImpl(MeasureUnitImpl& result, UErrorCode& status) { if (U_FAILURE(status)) { return; } if (fSource.empty()) { // The dimenionless unit: nothing to parse. leave result as is. return; } int32_t unitNum = 0; while (hasNext()) { bool sawAnd = false; SingleUnitImpl singleUnit; nextSingleUnit(singleUnit, sawAnd, status); if (U_FAILURE(status)) { return; } U_ASSERT(!singleUnit.isDimensionless()); bool added = result.append(singleUnit, status); if (sawAnd && !added) { // Two similar units are not allowed in a mixed unit status = kUnitIdentifierSyntaxError; return; } if ((++unitNum) >= 2) { // nextSingleUnit fails appropriately for "per" and "and" in the // same identifier. It doesn't fail for other compound units // (COMPOUND_PART_TIMES). Consequently we take care of that // here. UMeasureUnitComplexity complexity = sawAnd ? UMEASURE_UNIT_MIXED : UMEASURE_UNIT_COMPOUND; if (unitNum == 2) { U_ASSERT(result.complexity == UMEASURE_UNIT_SINGLE); result.complexity = complexity; } else if (result.complexity != complexity) { // Can't have mixed compound units status = kUnitIdentifierSyntaxError; return; } } } } }; int32_t U_CALLCONV compareSingleUnits(const void* /*context*/, const void* left, const void* right) { auto realLeft = static_cast(left); auto realRight = static_cast(right); return (*realLeft)->compareTo(**realRight); } /** * Generate the identifier string for a single unit in place. * * Does not support the dimensionless SingleUnitImpl: calling serializeSingle * with the dimensionless unit results in an U_INTERNAL_PROGRAM_ERROR. * * @param first If singleUnit is part of a compound unit, and not its first * single unit, set this to false. Otherwise: set to true. */ void serializeSingle(const SingleUnitImpl& singleUnit, bool first, CharString& output, UErrorCode& status) { if (first && singleUnit.dimensionality < 0) { // Essentially the "unary per". For compound units with a numerator, the // caller takes care of the "binary per". output.append("per-", status); } if (singleUnit.isDimensionless()) { status = U_INTERNAL_PROGRAM_ERROR; return; } int8_t posPower = std::abs(singleUnit.dimensionality); if (posPower == 0) { status = U_INTERNAL_PROGRAM_ERROR; } else if (posPower == 1) { // no-op } else if (posPower == 2) { output.append("square-", status); } else if (posPower == 3) { output.append("cubic-", status); } else if (posPower < 10) { output.append('p', status); output.append(posPower + '0', status); output.append('-', status); } else if (posPower <= 15) { output.append("p1", status); output.append('0' + (posPower % 10), status); output.append('-', status); } else { status = kUnitIdentifierSyntaxError; } if (U_FAILURE(status)) { return; } if (singleUnit.siPrefix != UMEASURE_SI_PREFIX_ONE) { for (const auto& siPrefixInfo : gSIPrefixStrings) { if (siPrefixInfo.value == singleUnit.siPrefix) { output.append(siPrefixInfo.string, status); break; } } } if (U_FAILURE(status)) { return; } output.appendInvariantChars(gSimpleUnits[singleUnit.index], status); } /** * Normalize a MeasureUnitImpl and generate the identifier string in place. */ void serialize(MeasureUnitImpl& impl, UErrorCode& status) { if (U_FAILURE(status)) { return; } U_ASSERT(impl.identifier.isEmpty()); if (impl.units.length() == 0) { // Dimensionless, constructed by the default constructor: no appending // to impl.identifier, we wish it to contain the zero-length string. return; } if (impl.complexity == UMEASURE_UNIT_COMPOUND) { // Note: don't sort a MIXED unit uprv_sortArray( impl.units.getAlias(), impl.units.length(), sizeof(impl.units[0]), compareSingleUnits, nullptr, false, &status); if (U_FAILURE(status)) { return; } } serializeSingle(*impl.units[0], true, impl.identifier, status); if (impl.units.length() == 1) { return; } for (int32_t i = 1; i < impl.units.length(); i++) { const SingleUnitImpl& prev = *impl.units[i-1]; const SingleUnitImpl& curr = *impl.units[i]; if (impl.complexity == UMEASURE_UNIT_MIXED) { impl.identifier.append("-and-", status); serializeSingle(curr, true, impl.identifier, status); } else { if (prev.dimensionality > 0 && curr.dimensionality < 0) { impl.identifier.append("-per-", status); } else { impl.identifier.append('-', status); } serializeSingle(curr, false, impl.identifier, status); } } } /** * Appends a SingleUnitImpl to a MeasureUnitImpl. * * @return true if a new item was added. If unit is the dimensionless unit, it * is never added: the return value will always be false. */ bool appendImpl(MeasureUnitImpl& impl, const SingleUnitImpl& unit, UErrorCode& status) { if (unit.isDimensionless()) { // We don't append dimensionless units. return false; } // Find a similar unit that already exists, to attempt to coalesce SingleUnitImpl* oldUnit = nullptr; for (int32_t i = 0; i < impl.units.length(); i++) { auto* candidate = impl.units[i]; if (candidate->isCompatibleWith(unit)) { oldUnit = candidate; } } if (oldUnit) { // Both dimensionalities will be positive, or both will be negative, by // virtue of isCompatibleWith(). oldUnit->dimensionality += unit.dimensionality; } else { SingleUnitImpl* destination = impl.units.emplaceBack(); if (!destination) { status = U_MEMORY_ALLOCATION_ERROR; return false; } *destination = unit; } return (oldUnit == nullptr); } } // namespace SingleUnitImpl SingleUnitImpl::forMeasureUnit(const MeasureUnit& measureUnit, UErrorCode& status) { MeasureUnitImpl temp; const MeasureUnitImpl& impl = MeasureUnitImpl::forMeasureUnit(measureUnit, temp, status); if (U_FAILURE(status)) { return {}; } if (impl.units.length() == 0) { return {}; } if (impl.units.length() == 1) { return *impl.units[0]; } status = U_ILLEGAL_ARGUMENT_ERROR; return {}; } MeasureUnit SingleUnitImpl::build(UErrorCode& status) const { MeasureUnitImpl temp; temp.append(*this, status); return std::move(temp).build(status); } MeasureUnitImpl MeasureUnitImpl::forIdentifier(StringPiece identifier, UErrorCode& status) { return Parser::from(identifier, status).parse(status); } const MeasureUnitImpl& MeasureUnitImpl::forMeasureUnit( const MeasureUnit& measureUnit, MeasureUnitImpl& memory, UErrorCode& status) { if (measureUnit.fImpl) { return *measureUnit.fImpl; } else { memory = Parser::from(measureUnit.getIdentifier(), status).parse(status); return memory; } } MeasureUnitImpl MeasureUnitImpl::forMeasureUnitMaybeCopy( const MeasureUnit& measureUnit, UErrorCode& status) { if (measureUnit.fImpl) { return measureUnit.fImpl->copy(status); } else { return Parser::from(measureUnit.getIdentifier(), status).parse(status); } } void MeasureUnitImpl::takeReciprocal(UErrorCode& /*status*/) { identifier.clear(); for (int32_t i = 0; i < units.length(); i++) { units[i]->dimensionality *= -1; } } bool MeasureUnitImpl::append(const SingleUnitImpl& singleUnit, UErrorCode& status) { identifier.clear(); return appendImpl(*this, singleUnit, status); } MeasureUnit MeasureUnitImpl::build(UErrorCode& status) && { serialize(*this, status); return MeasureUnit(std::move(*this)); } MeasureUnit MeasureUnit::forIdentifier(StringPiece identifier, UErrorCode& status) { return Parser::from(identifier, status).parse(status).build(status); } UMeasureUnitComplexity MeasureUnit::getComplexity(UErrorCode& status) const { MeasureUnitImpl temp; return MeasureUnitImpl::forMeasureUnit(*this, temp, status).complexity; } UMeasureSIPrefix MeasureUnit::getSIPrefix(UErrorCode& status) const { return SingleUnitImpl::forMeasureUnit(*this, status).siPrefix; } MeasureUnit MeasureUnit::withSIPrefix(UMeasureSIPrefix prefix, UErrorCode& status) const { SingleUnitImpl singleUnit = SingleUnitImpl::forMeasureUnit(*this, status); singleUnit.siPrefix = prefix; return singleUnit.build(status); } int32_t MeasureUnit::getDimensionality(UErrorCode& status) const { SingleUnitImpl singleUnit = SingleUnitImpl::forMeasureUnit(*this, status); if (U_FAILURE(status)) { return 0; } if (singleUnit.isDimensionless()) { return 0; } return singleUnit.dimensionality; } MeasureUnit MeasureUnit::withDimensionality(int32_t dimensionality, UErrorCode& status) const { SingleUnitImpl singleUnit = SingleUnitImpl::forMeasureUnit(*this, status); singleUnit.dimensionality = dimensionality; return singleUnit.build(status); } MeasureUnit MeasureUnit::reciprocal(UErrorCode& status) const { MeasureUnitImpl impl = MeasureUnitImpl::forMeasureUnitMaybeCopy(*this, status); impl.takeReciprocal(status); return std::move(impl).build(status); } MeasureUnit MeasureUnit::product(const MeasureUnit& other, UErrorCode& status) const { MeasureUnitImpl impl = MeasureUnitImpl::forMeasureUnitMaybeCopy(*this, status); MeasureUnitImpl temp; const MeasureUnitImpl& otherImpl = MeasureUnitImpl::forMeasureUnit(other, temp, status); if (impl.complexity == UMEASURE_UNIT_MIXED || otherImpl.complexity == UMEASURE_UNIT_MIXED) { status = U_ILLEGAL_ARGUMENT_ERROR; return {}; } for (int32_t i = 0; i < otherImpl.units.length(); i++) { impl.append(*otherImpl.units[i], status); } if (impl.units.length() > 1) { impl.complexity = UMEASURE_UNIT_COMPOUND; } return std::move(impl).build(status); } LocalArray MeasureUnit::splitToSingleUnits(int32_t& outCount, UErrorCode& status) const { MeasureUnitImpl temp; const MeasureUnitImpl& impl = MeasureUnitImpl::forMeasureUnit(*this, temp, status); outCount = impl.units.length(); MeasureUnit* arr = new MeasureUnit[outCount]; for (int32_t i = 0; i < outCount; i++) { arr[i] = impl.units[i]->build(status); } return LocalArray(arr, status); } U_NAMESPACE_END #endif /* !UNCONFIG_NO_FORMATTING */