TEST_F(UnitsFixture,IddUnits_Grams) {
IddUnitString iddString("g/m-s-K");
EXPECT_EQ("mkg/m*s*K",iddString.toStandardUnitString());
OptionalUnit unit = createUnit(iddString.toStandardUnitString());
ASSERT_TRUE(unit);
EXPECT_TRUE(unit->system() == UnitSystem::SI);
EXPECT_EQ(-3,unit->scale().exponent);
}
boost::optional<Unit> UnitFactorySingleton::createUnit(const std::string& unitString,
UnitSystem system) const
{
if (m_callbackMaps.size() == 0) {
LOG(Warn,"UnitFactorySingleton::createUnit called, but the maps appear to be empty.");
}
if (!unitString.empty() && !isUnit(unitString)) {
LOG(Error,unitString << " is not properly formatted.");
return boost::none;
}
OptionalUnit result = createUnitSimple(unitString,system);
if (result) {
return *result;
}
// no luck--start parsing
std::string wUnitString(unitString);
ScaleConstant scale = ScaleFactory::instance().createScale(0);
if (isScaledUnit(wUnitString)) {
std::pair<std::string,std::string> scaleAndUnit = decomposeScaledUnitString(wUnitString);
scale = ScaleFactory::instance().createScale(scaleAndUnit.first);
if (scale().value == 0.0) {
LOG(Error,"Scaled unit string " << wUnitString << " uses invalid scale abbreviation "
<< scaleAndUnit.first << ".");
return boost::none;
}
wUnitString = scaleAndUnit.second;
}
// wUnitString should now be compound unit
std::pair< std::vector<std::string>,std::vector<std::string> > atomicUnits =
decomposeCompoundUnitString(wUnitString);
// loop through numerator
std::vector<std::string>::const_iterator atomicUnitIter;
std::vector<std::string>::const_iterator vectorEnd = atomicUnits.first.end();
std::pair<std::string,int> atomicUnit;
for (atomicUnitIter = atomicUnits.first.begin(); atomicUnitIter != vectorEnd; ++atomicUnitIter) {
// decompose into baseUnit and exponent
atomicUnit = decomposeAtomicUnitString(*atomicUnitIter);
// look for baseUnit
OptionalUnit baseUnit = createUnitSimple(atomicUnit.first,system);
if (!baseUnit) {
// decompose into scale, baseUnit
std::pair<std::string,std::string> scaleAndBaseUnit = extractScaleAbbreviation(atomicUnit.first);
if (!scaleAndBaseUnit.first.empty()) {
baseUnit = createUnitSimple(scaleAndBaseUnit.second,system);
if (!baseUnit) {
baseUnit = Unit();
baseUnit->setBaseUnitExponent(scaleAndBaseUnit.second,1);
}
baseUnit->setScale(scaleAndBaseUnit.first);
}
else {
baseUnit = Unit();
baseUnit->setBaseUnitExponent(atomicUnit.first,1);
}
}
baseUnit->pow(atomicUnit.second);
if (!result) {
result = baseUnit;
}
else {
result = (*result) * (*baseUnit);
}
}
// loop through denominator
vectorEnd = atomicUnits.second.end();
for (atomicUnitIter = atomicUnits.second.begin(); atomicUnitIter != vectorEnd; ++atomicUnitIter) {
// decompose into baseUnit and exponent
atomicUnit = decomposeAtomicUnitString(*atomicUnitIter);
// look for baseUnit
OptionalUnit baseUnit = createUnitSimple(atomicUnit.first,system);
if (!baseUnit) {
// decompose into scale, baseUnit
std::pair<std::string,std::string> scaleAndBaseUnit = extractScaleAbbreviation(atomicUnit.first);
if (!scaleAndBaseUnit.first.empty()) {
baseUnit = createUnitSimple(scaleAndBaseUnit.second,system);
if (!baseUnit) {
LOG(Info,scaleAndBaseUnit.second << " is not a registered baseUnit (in the selected system). "
<< "Returning it as-is in a mixed Unit (not SI, IP, etc.).");
baseUnit = Unit();
baseUnit->setBaseUnitExponent(scaleAndBaseUnit.second,1);
}
baseUnit->setScale(scaleAndBaseUnit.first);
}
else {
LOG(Info,scaleAndBaseUnit.second << " is not a registered baseUnit (in the selected system). "
<< "Returning it as-is in a mixed Unit (not SI, IP, etc.).");
baseUnit = Unit();
baseUnit->setBaseUnitExponent(atomicUnit.first,1);
}
}
baseUnit->pow(atomicUnit.second);
if (!result) {
baseUnit->pow(-1);
result = baseUnit;
}
else {
result = (*result) / (*baseUnit);
}
}
BOOST_ASSERT(result);
// impose overall scale
if (scale().exponent != 0) {
ScaleOpReturnType resultScale = scale()*result->scale();
result->setScale(resultScale.first().exponent);
}
return result;
}
