/// <summary>
/// Processes an IFC unit in the property.
/// </summary>
/// <param name="ifcSimpleProperty">The simple property.</param>
/// <param name="simplePropertyHandle">The simple property handle.</param>
static protected void ProcessIFCSimplePropertyUnit(IFCSimpleProperty ifcSimpleProperty, IFCAnyHandle simplePropertyHandle)
{
IFCAnyHandle ifcUnitHandle = IFCImportHandleUtil.GetOptionalInstanceAttribute(simplePropertyHandle, "Unit");
IFCUnit ifcUnit = (ifcUnitHandle != null) ? IFCUnit.ProcessIFCUnit(ifcUnitHandle) : null;
if (ifcUnit == null)
{
if (ifcSimpleProperty.IFCPropertyValues.Count > 0)
{
IFCPropertyValue propertyValue = ifcSimpleProperty.IFCPropertyValues[0];
if (propertyValue != null && propertyValue.HasValue() &&
(propertyValue.Type == IFCDataPrimitiveType.Integer) || (propertyValue.Type == IFCDataPrimitiveType.Double))
{
string unitTypeName;
UnitType unitType = IFCDataUtil.GetUnitTypeFromData(propertyValue.Value, UnitType.UT_Undefined, out unitTypeName);
if (unitType != UnitType.UT_Undefined)
{
ifcUnit = IFCImportFile.TheFile.IFCUnits.GetIFCProjectUnit(unitType);
}
else
{
Importer.TheLog.LogWarning(simplePropertyHandle.StepId, "Unhandled unit type: " + unitTypeName, true);
}
}
}
}
ifcSimpleProperty.m_IFCUnit = ifcUnit;
}
/// <summary>
/// Processes an IFC physical simple quantity.
/// </summary>
/// <param name="ifcPhysicalQuantity">The IfcPhysicalSimpleQuantity object.</param>
/// <returns>The IFCPhysicalSimpleQuantity object.</returns>
override protected void Process(IFCAnyHandle ifcPhysicalSimpleQuantity)
{
base.Process(ifcPhysicalSimpleQuantity);
IFCAnyHandle unit = IFCImportHandleUtil.GetOptionalInstanceAttribute(ifcPhysicalSimpleQuantity, "Unit");
if (!IFCAnyHandleUtil.IsNullOrHasNoValue(unit))
{
IFCUnit = IFCUnit.ProcessIFCUnit(unit);
}
// Process subtypes of IfcPhysicalSimpleQuantity here.
string attributeName = ifcPhysicalSimpleQuantity.TypeName.Substring(11) + "Value";
Value = ifcPhysicalSimpleQuantity.GetAttribute(attributeName);
BaseUnitType = IFCDataUtil.GetUnitTypeFromData(Value, UnitType.UT_Undefined);
if (BaseUnitType == UnitType.UT_Undefined)
{
// Determine it from the attributeName.
if (string.Compare(attributeName, "LengthValue", true) == 0)
{
BaseUnitType = UnitType.UT_Length;
}
else if (string.Compare(attributeName, "AreaValue", true) == 0)
{
BaseUnitType = UnitType.UT_Area;
}
else if (string.Compare(attributeName, "VolumeValue", true) == 0)
{
BaseUnitType = UnitType.UT_Volume;
}
else if (string.Compare(attributeName, "CountValue", true) == 0)
{
BaseUnitType = UnitType.UT_Number;
}
else if (string.Compare(attributeName, "WeightValue", true) == 0)
{
BaseUnitType = UnitType.UT_Mass;
}
else if (string.Compare(attributeName, "TimeValue", true) == 0)
{
BaseUnitType = UnitType.UT_Number; // No time unit type in Revit.
}
else
{
Importer.TheLog.LogWarning(Id, "Can't determine unit type for IfcPhysicalSimpleQuantity of type: " + attributeName, true);
BaseUnitType = UnitType.UT_Number;
}
}
if (IFCUnit == null)
{
IFCUnit = IFCImportFile.TheFile.IFCUnits.GetIFCProjectUnit(BaseUnitType);
}
}
/// <summary>
/// Processes a project unit.
/// </summary>
/// <param name="unitHnd">The unit handle.</param>
/// <returns>The Unit object.</returns>
public IFCUnit ProcessIFCProjectUnit(IFCAnyHandle unitHnd)
{
IFCUnit unit = IFCUnit.ProcessIFCUnit(unitHnd);
if (unit != null)
{
m_ProjectUnitsDictionary[unit.Spec] = unit;
}
return(unit);
}
/// <summary>
/// Processes a conversion based unit.
/// </summary>
/// <param name="convUnitHnd">The unit handle.</param>
void ProcessIFCConversionBasedUnit(IFCAnyHandle convUnitHnd)
{
IFCAnyHandle measureWithUnitHnd = IFCAnyHandleUtil.GetInstanceAttribute(convUnitHnd, "ConversionFactor");
if (IFCAnyHandleUtil.IsNullOrHasNoValue(measureWithUnitHnd))
{
throw new InvalidOperationException("#" + convUnitHnd.StepId + ": Missing required attribute ConversionFactor.");
}
IFCUnit measureWithUnit = IFCUnit.ProcessIFCUnit(measureWithUnitHnd);
if (measureWithUnit == null)
{
throw new InvalidOperationException("#" + convUnitHnd.StepId + ": Invalid base ConversionFactor, aborting.");
}
CopyUnit(measureWithUnit);
// For some common cases, get the units correct.
string unitType = IFCAnyHandleUtil.GetEnumerationAttribute(convUnitHnd, "UnitType");
if (string.Compare(unitType, "LENGTHUNIT", true) == 0)
{
UnitType = UnitType.UT_Length;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "FOOT", true) == 0 ||
string.Compare(name, "FEET", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
UnitName = UnitName.DUT_FEET_FRACTIONAL_INCHES;
UnitSymbol = UnitSymbolType.UST_NONE;
}
else if (string.Compare(name, "INCH", true) == 0 ||
string.Compare(name, "INCHES", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
UnitName = UnitName.DUT_FRACTIONAL_INCHES;
UnitSymbol = UnitSymbolType.UST_NONE;
}
}
else if (string.Compare(unitType, "PLANEANGLEUNIT", true) == 0)
{
UnitType = UnitType.UT_Angle;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "GRAD", true) == 0 ||
string.Compare(name, "GRADIAN", true) == 0 ||
string.Compare(name, "GRADS", true) == 0 ||
string.Compare(name, "GRADIANS", true) == 0)
{
UnitSystem = UnitSystem.Metric;
UnitName = UnitName.DUT_GRADS;
UnitSymbol = UnitSymbolType.UST_GRAD;
}
else if (string.Compare(name, "DEGREE", true) == 0 ||
string.Compare(name, "DEGREES", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
UnitName = UnitName.DUT_DECIMAL_DEGREES;
UnitSymbol = UnitSymbolType.UST_DEGREE_SYMBOL;
}
}
else if (string.Compare(unitType, "AREAUNIT", true) == 0)
{
UnitType = UnitType.UT_Area;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "SQUARE FOOT", true) == 0 ||
string.Compare(name, "SQUARE_FOOT", true) == 0 ||
string.Compare(name, "SQUARE FEET", true) == 0 ||
string.Compare(name, "SQUARE_FEET", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
UnitName = UnitName.DUT_SQUARE_FEET;
UnitSymbol = UnitSymbolType.UST_FT_SUP_2;
}
}
else if (string.Compare(unitType, "VOLUMEUNIT", true) == 0)
{
UnitType = UnitType.UT_Volume;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "CUBIC FOOT", true) == 0 ||
string.Compare(name, "CUBIC_FOOT", true) == 0 ||
string.Compare(name, "CUBIC FEET", true) == 0 ||
string.Compare(name, "CUBIC_FEET", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
UnitName = UnitName.DUT_CUBIC_FEET;
UnitSymbol = UnitSymbolType.UST_FT_SUP_3;
}
}
else if (string.Compare(unitType, "THERMODYNAMICMEASUREUNIT", true) == 0)
{
UnitType = UnitType.UT_HVAC_Temperature;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if ((string.Compare(name, "F", true) == 0) ||
(string.Compare(name, "FAHRENHEIT", true) == 0))
{
UnitSystem = UnitSystem.Imperial;
UnitName = UnitName.DUT_FAHRENHEIT;
UnitSymbol = UnitSymbolType.UST_DEGREE_F;
}
else if ((string.Compare(name, "R", true) == 0) ||
(string.Compare(name, "RANKINE", true) == 0))
{
UnitSystem = UnitSystem.Imperial;
UnitName = UnitName.DUT_RANKINE;
UnitSymbol = UnitSymbolType.UST_DEGREE_R;
}
}
}
/// <summary>
/// Processes an IfcDerivedUnit.
/// </summary>
/// <param name="unitHnd">The unit handle.</param>
void ProcessIFCDerivedUnit(IFCAnyHandle unitHnd)
{
List <IFCAnyHandle> elements =
IFCAnyHandleUtil.GetAggregateInstanceAttribute <List <IFCAnyHandle> >(unitHnd, "Elements");
IList <KeyValuePair <IFCUnit, int> > derivedElementUnitHnds = new List <KeyValuePair <IFCUnit, int> >();
foreach (IFCAnyHandle subElement in elements)
{
IFCAnyHandle derivedElementUnitHnd = IFCImportHandleUtil.GetRequiredInstanceAttribute(subElement, "Unit", false);
IFCUnit subUnit = IFCAnyHandleUtil.IsNullOrHasNoValue(derivedElementUnitHnd) ? null : IFCUnit.ProcessIFCUnit(derivedElementUnitHnd);
if (subUnit != null)
{
bool found;
int exponent = IFCImportHandleUtil.GetRequiredIntegerAttribute(subElement, "Exponent", out found);
if (found)
{
derivedElementUnitHnds.Add(new KeyValuePair <IFCUnit, int>(subUnit, exponent));
}
}
}
// the DerivedUnitExpectedTypes object is a description of one possible set of base units for a particular derived unit.
// The IList allows for possible different interpretations. For example, Volumetric Flow Rate could be defined by m^3/s (length ^ 3 / time) or L/s (volume / time).
IList <DerivedUnitExpectedTypes> expectedTypesList = new List <DerivedUnitExpectedTypes>();
string unitType = IFCAnyHandleUtil.GetEnumerationAttribute(unitHnd, "UnitType");
if (string.Compare(unitType, "LINEARVELOCITYUNIT", true) == 0)
{
UnitType = UnitType.UT_HVAC_Velocity;
UnitSystem = UnitSystem.Metric;
// Support only m / s.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitName.DUT_METERS_PER_SECOND, UnitSymbolType.UST_M_PER_S);
expectedTypes.AddExpectedType(1, UnitType.UT_Length);
expectedTypes.AddCustomExpectedType(-1, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "THERMALTRANSMITTANCEUNIT", true) == 0)
{
UnitType = UnitType.UT_HVAC_CoefficientOfHeatTransfer;
UnitSystem = UnitSystem.Metric;
// Support W / (K * m^2) or kg / (K * s^3)
DerivedUnitExpectedTypes expectedTypesWinvKinvM2 = new DerivedUnitExpectedTypes(UnitName.DUT_WATTS_PER_SQUARE_METER_KELVIN, UnitSymbolType.UST_WATT_PER_SQ_M_K);
expectedTypesWinvKinvM2.AddExpectedType(1, UnitType.UT_HVAC_Power); // UT_Electrical_Wattage is similar, but UT_HVAC_Power is the one we map to.
expectedTypesWinvKinvM2.AddExpectedType(-1, UnitType.UT_HVAC_Temperature);
expectedTypesWinvKinvM2.AddExpectedType(-2, UnitType.UT_Length);
expectedTypesList.Add(expectedTypesWinvKinvM2);
DerivedUnitExpectedTypes expectedTypesWinvKinvArea = new DerivedUnitExpectedTypes(UnitName.DUT_WATTS_PER_SQUARE_METER_KELVIN, UnitSymbolType.UST_WATT_PER_SQ_M_K);
expectedTypesWinvKinvArea.AddExpectedType(1, UnitType.UT_HVAC_Power); // UT_Electrical_Wattage is similar, but UT_HVAC_Power is the one we map to.
expectedTypesWinvKinvArea.AddExpectedType(-1, UnitType.UT_HVAC_Temperature);
expectedTypesWinvKinvArea.AddExpectedType(-1, UnitType.UT_Area);
expectedTypesList.Add(expectedTypesWinvKinvArea);
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitName.DUT_WATTS_PER_SQUARE_METER_KELVIN, UnitSymbolType.UST_WATT_PER_SQ_M_K);
expectedTypes.AddExpectedType(1, UnitType.UT_Mass);
expectedTypes.AddExpectedType(-1, UnitType.UT_HVAC_Temperature);
expectedTypes.AddCustomExpectedType(-3, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "VOLUMETRICFLOWRATEUNIT", true) == 0)
{
UnitType = UnitType.UT_HVAC_Airflow;
UnitSystem = UnitSystem.Metric;
// Support L / s or m^3 / s in the IFC file.
// L / s
DerivedUnitExpectedTypes expectedTypesLPerS = new DerivedUnitExpectedTypes(UnitName.DUT_LITERS_PER_SECOND, UnitSymbolType.UST_L_PER_S);
expectedTypesLPerS.AddExpectedType(1, UnitType.UT_Volume);
expectedTypesLPerS.AddCustomExpectedType(-1, "TIMEUNIT");
expectedTypesList.Add(expectedTypesLPerS);
// m^3 / s.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitName.DUT_CUBIC_METERS_PER_SECOND, UnitSymbolType.UST_CU_M_PER_S);
expectedTypes.AddExpectedType(3, UnitType.UT_Length);
expectedTypes.AddCustomExpectedType(-1, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "MASSDENSITYUNIT", true) == 0)
{
UnitType = UnitType.UT_MassDensity;
UnitSystem = UnitSystem.Metric;
// Support kg / m^3 in the IFC file.
// kg / m^3.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitName.DUT_KILOGRAMS_PER_CUBIC_METER, UnitSymbolType.UST_KG_PER_CU_M);
expectedTypes.AddExpectedType(1, UnitType.UT_Mass);
expectedTypes.AddExpectedType(-3, UnitType.UT_Length);
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "USERDEFINED", true) == 0)
{
// Look at the sub-types to see what we support.
string userDefinedType = IFCImportHandleUtil.GetOptionalStringAttribute(unitHnd, "UserDefinedType", null);
if (!string.IsNullOrWhiteSpace(userDefinedType))
{
if (string.Compare(userDefinedType, "Luminous Efficacy", true) == 0)
{
UnitType = UnitType.UT_Electrical_Efficacy;
UnitSystem = UnitSystem.Metric;
// Support only lm / W.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitName.DUT_LUMENS_PER_WATT, UnitSymbolType.UST_LM_PER_W);
expectedTypes.AddExpectedType(-1, UnitType.UT_Mass);
expectedTypes.AddExpectedType(-2, UnitType.UT_Length);
expectedTypes.AddCustomExpectedType(3, "TIMEUNIT");
expectedTypes.AddExpectedType(1, UnitType.UT_Electrical_Luminous_Flux);
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(userDefinedType, "Friction Loss", true) == 0)
{
UnitType = UnitType.UT_HVAC_Friction;
UnitSystem = UnitSystem.Metric;
// Support only Pa / m.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitName.DUT_PASCALS_PER_METER, UnitSymbolType.UST_PASCAL_PER_M);
expectedTypes.AddExpectedType(-2, UnitType.UT_Length);
expectedTypes.AddExpectedType(1, UnitType.UT_Mass);
expectedTypes.AddCustomExpectedType(-2, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
}
}
foreach (DerivedUnitExpectedTypes derivedUnitExpectedTypes in expectedTypesList)
{
double scaleFactor = 1.0;
if (derivedUnitExpectedTypes.Matches(derivedElementUnitHnds, out scaleFactor))
{
// Found a match.
UnitName = derivedUnitExpectedTypes.UnitName;
UnitSymbol = derivedUnitExpectedTypes.UnitSymbol;
ScaleFactor = scaleFactor;
return;
}
}
Importer.TheLog.LogUnhandledUnitTypeError(unitHnd, unitType);
}
/// <summary>
/// Processes a conversion based unit.
/// </summary>
/// <param name="convUnitHnd">The unit handle.</param>
void ProcessIFCConversionBasedUnit(IFCAnyHandle convUnitHnd)
{
IFCAnyHandle measureWithUnitHnd = IFCAnyHandleUtil.GetInstanceAttribute(convUnitHnd, "ConversionFactor");
if (IFCAnyHandleUtil.IsNullOrHasNoValue(measureWithUnitHnd))
{
throw new InvalidOperationException("#" + convUnitHnd.StepId + ": Missing required attribute ConversionFactor.");
}
IFCUnit measureWithUnit = IFCUnit.ProcessIFCUnit(measureWithUnitHnd);
if (measureWithUnit == null)
{
throw new InvalidOperationException("#" + convUnitHnd.StepId + ": Invalid base ConversionFactor, aborting.");
}
CopyUnit(measureWithUnit);
// For some common cases, get the units correct.
string unitType = IFCAnyHandleUtil.GetEnumerationAttribute(convUnitHnd, "UnitType");
if (string.Compare(unitType, "LENGTHUNIT", true) == 0)
{
Spec = SpecTypeId.Length;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "FOOT", true) == 0 ||
string.Compare(name, "FEET", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
Unit = UnitTypeId.FeetFractionalInches;
Symbol = new ForgeTypeId();
}
else if (string.Compare(name, "INCH", true) == 0 ||
string.Compare(name, "INCHES", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
Unit = UnitTypeId.FractionalInches;
Symbol = new ForgeTypeId();
}
}
else if (string.Compare(unitType, "PLANEANGLEUNIT", true) == 0)
{
Spec = SpecTypeId.Angle;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "GRAD", true) == 0 ||
string.Compare(name, "GRADIAN", true) == 0 ||
string.Compare(name, "GRADS", true) == 0 ||
string.Compare(name, "GRADIANS", true) == 0)
{
UnitSystem = UnitSystem.Metric;
Unit = UnitTypeId.Gradians;
Symbol = SymbolTypeId.Grad;
}
else if (string.Compare(name, "DEGREE", true) == 0 ||
string.Compare(name, "DEGREES", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
Unit = UnitTypeId.Degrees;
Symbol = SymbolTypeId.Degree;
}
}
else if (string.Compare(unitType, "AREAUNIT", true) == 0)
{
Spec = SpecTypeId.Area;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "SQUARE FOOT", true) == 0 ||
string.Compare(name, "SQUARE_FOOT", true) == 0 ||
string.Compare(name, "SQUARE FEET", true) == 0 ||
string.Compare(name, "SQUARE_FEET", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
Unit = UnitTypeId.SquareFeet;
Symbol = SymbolTypeId.FtSup2;
}
}
else if (string.Compare(unitType, "VOLUMEUNIT", true) == 0)
{
Spec = SpecTypeId.Volume;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if (string.Compare(name, "CUBIC FOOT", true) == 0 ||
string.Compare(name, "CUBIC_FOOT", true) == 0 ||
string.Compare(name, "CUBIC FEET", true) == 0 ||
string.Compare(name, "CUBIC_FEET", true) == 0)
{
UnitSystem = UnitSystem.Imperial;
Unit = UnitTypeId.CubicFeet;
Symbol = SymbolTypeId.FtSup3;
}
}
else if (string.Compare(unitType, "THERMODYNAMICMEASUREUNIT", true) == 0)
{
Spec = SpecTypeId.HvacTemperature;
string name = IFCAnyHandleUtil.GetStringAttribute(convUnitHnd, "Name");
if ((string.Compare(name, "F", true) == 0) ||
(string.Compare(name, "FAHRENHEIT", true) == 0))
{
UnitSystem = UnitSystem.Imperial;
Unit = UnitTypeId.Fahrenheit;
Symbol = SymbolTypeId.DegreeF;
}
else if ((string.Compare(name, "R", true) == 0) ||
(string.Compare(name, "RANKINE", true) == 0))
{
UnitSystem = UnitSystem.Imperial;
Unit = UnitTypeId.Rankine;
Symbol = SymbolTypeId.DegreeR;
}
}
}
/// <summary>
/// Processes an IfcDerivedUnit.
/// </summary>
/// <param name="unitHnd">The unit handle.</param>
void ProcessIFCDerivedUnit(IFCAnyHandle unitHnd)
{
List <IFCAnyHandle> elements =
IFCAnyHandleUtil.GetAggregateInstanceAttribute <List <IFCAnyHandle> >(unitHnd, "Elements");
IList <KeyValuePair <IFCUnit, int> > derivedElementUnitHnds = new List <KeyValuePair <IFCUnit, int> >();
foreach (IFCAnyHandle subElement in elements)
{
IFCAnyHandle derivedElementUnitHnd = IFCImportHandleUtil.GetRequiredInstanceAttribute(subElement, "Unit", false);
IFCUnit subUnit = IFCAnyHandleUtil.IsNullOrHasNoValue(derivedElementUnitHnd) ? null : IFCUnit.ProcessIFCUnit(derivedElementUnitHnd);
if (subUnit != null)
{
bool found;
int exponent = IFCImportHandleUtil.GetRequiredIntegerAttribute(subElement, "Exponent", out found);
if (found)
{
derivedElementUnitHnds.Add(new KeyValuePair <IFCUnit, int>(subUnit, exponent));
}
}
}
// the DerivedUnitExpectedTypes object is a description of one possible set of base units for a particular derived unit.
// The IList allows for possible different interpretations. For example, Volumetric Flow Rate could be defined by m^3/s (length ^ 3 / time) or L/s (volume / time).
IList <DerivedUnitExpectedTypes> expectedTypesList = new List <DerivedUnitExpectedTypes>();
string unitType = IFCAnyHandleUtil.GetEnumerationAttribute(unitHnd, "UnitType");
if (string.Compare(unitType, "LINEARVELOCITYUNIT", true) == 0)
{
Spec = SpecTypeId.HvacVelocity;
UnitSystem = UnitSystem.Metric;
// Support only m / s.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.MetersPerSecond, SymbolTypeId.MPerS);
expectedTypes.AddExpectedType(1, SpecTypeId.Length);
expectedTypes.AddCustomExpectedType(-1, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "THERMALTRANSMITTANCEUNIT", true) == 0)
{
Spec = SpecTypeId.HeatTransferCoefficient;
UnitSystem = UnitSystem.Metric;
// Support W / (K * m^2) or kg / (K * s^3)
DerivedUnitExpectedTypes expectedTypesWinvKinvM2 = new DerivedUnitExpectedTypes(UnitTypeId.WattsPerSquareMeterKelvin, SymbolTypeId.WPerMSup2K);
expectedTypesWinvKinvM2.AddExpectedType(1, SpecTypeId.HvacPower); // UT_Electrical_Wattage is similar, but UT_HVAC_Power is the one we map to.
expectedTypesWinvKinvM2.AddExpectedType(-1, SpecTypeId.HvacTemperature);
expectedTypesWinvKinvM2.AddExpectedType(-2, SpecTypeId.Length);
expectedTypesList.Add(expectedTypesWinvKinvM2);
DerivedUnitExpectedTypes expectedTypesWinvKinvArea = new DerivedUnitExpectedTypes(UnitTypeId.WattsPerSquareMeterKelvin, SymbolTypeId.WPerMSup2K);
expectedTypesWinvKinvArea.AddExpectedType(1, SpecTypeId.HvacPower); // UT_Electrical_Wattage is similar, but UT_HVAC_Power is the one we map to.
expectedTypesWinvKinvArea.AddExpectedType(-1, SpecTypeId.HvacTemperature);
expectedTypesWinvKinvArea.AddExpectedType(-1, SpecTypeId.Area);
expectedTypesList.Add(expectedTypesWinvKinvArea);
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.WattsPerSquareMeterKelvin, SymbolTypeId.WPerMSup2K);
expectedTypes.AddExpectedType(1, SpecTypeId.Mass);
expectedTypes.AddExpectedType(-1, SpecTypeId.HvacTemperature);
expectedTypes.AddCustomExpectedType(-3, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "VOLUMETRICFLOWRATEUNIT", true) == 0)
{
Spec = SpecTypeId.AirFlow;
UnitSystem = UnitSystem.Metric;
// Support L / s or m^3 / s in the IFC file.
// L / s
DerivedUnitExpectedTypes expectedTypesLPerS = new DerivedUnitExpectedTypes(UnitTypeId.LitersPerSecond, SymbolTypeId.LPerS);
expectedTypesLPerS.AddExpectedType(1, SpecTypeId.Volume);
expectedTypesLPerS.AddCustomExpectedType(-1, "TIMEUNIT");
expectedTypesList.Add(expectedTypesLPerS);
// m^3 / s.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.CubicMetersPerSecond, SymbolTypeId.MSup3PerS);
expectedTypes.AddExpectedType(3, SpecTypeId.Length);
expectedTypes.AddCustomExpectedType(-1, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "MASSDENSITYUNIT", true) == 0)
{
Spec = SpecTypeId.MassDensity;
UnitSystem = UnitSystem.Metric;
// Support kg / m^3 in the IFC file.
// kg / m^3.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.KilogramsPerCubicMeter, SymbolTypeId.KgPerMSup3);
expectedTypes.AddExpectedType(1, SpecTypeId.Mass);
expectedTypes.AddExpectedType(-3, SpecTypeId.Length);
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(unitType, "LINEARFORCEUNIT", true) == 0)
{
Spec = SpecTypeId.LinearForce;
UnitSystem = UnitSystem.Metric;
// Support N / m in the IFC file.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.NewtonsPerMeter, SymbolTypeId.NPerM);
expectedTypes.AddExpectedType(1, SpecTypeId.LinearForce);
expectedTypesList.Add(expectedTypes);
// Support N / m in basic units
DerivedUnitExpectedTypes expectedTypes2 = new DerivedUnitExpectedTypes(UnitTypeId.NewtonsPerMeter, SymbolTypeId.NPerM);
expectedTypes2.AddExpectedType(1, SpecTypeId.Mass);
expectedTypes2.AddExpectedType(1, SpecTypeId.Length);
expectedTypes2.AddCustomExpectedType(-2, "TIMEUNIT");
expectedTypes2.AddExpectedType(-1, SpecTypeId.Length);
expectedTypesList.Add(expectedTypes2);
}
else if (string.Compare(unitType, "PLANARFORCEUNIT", true) == 0)
{
Spec = SpecTypeId.AreaForce;
UnitSystem = UnitSystem.Metric;
// Support N / m^2 in the IFC file.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.NewtonsPerSquareMeter, SymbolTypeId.NPerMSup2);
expectedTypes.AddExpectedType(1, SpecTypeId.AreaForce);
expectedTypesList.Add(expectedTypes);
// Support N / m in basic units
DerivedUnitExpectedTypes expectedTypes2 = new DerivedUnitExpectedTypes(UnitTypeId.NewtonsPerSquareMeter, SymbolTypeId.NPerMSup2);
expectedTypes2.AddExpectedType(1, SpecTypeId.Mass);
expectedTypes2.AddExpectedType(1, SpecTypeId.Length);
expectedTypes2.AddCustomExpectedType(-2, "TIMEUNIT");
expectedTypes2.AddExpectedType(-2, SpecTypeId.Length);
expectedTypesList.Add(expectedTypes2);
}
else if (string.Compare(unitType, "USERDEFINED", true) == 0)
{
// Look at the sub-types to see what we support.
string userDefinedType = IFCImportHandleUtil.GetOptionalStringAttribute(unitHnd, "UserDefinedType", null);
if (!string.IsNullOrWhiteSpace(userDefinedType))
{
if (string.Compare(userDefinedType, "Luminous Efficacy", true) == 0)
{
Spec = SpecTypeId.Efficacy;
UnitSystem = UnitSystem.Metric;
// Support only lm / W.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.LumensPerWatt, SymbolTypeId.LmPerW);
expectedTypes.AddExpectedType(-1, SpecTypeId.Mass);
expectedTypes.AddExpectedType(-2, SpecTypeId.Length);
expectedTypes.AddCustomExpectedType(3, "TIMEUNIT");
expectedTypes.AddExpectedType(1, SpecTypeId.LuminousFlux);
expectedTypesList.Add(expectedTypes);
}
else if (string.Compare(userDefinedType, "Friction Loss", true) == 0)
{
Spec = SpecTypeId.HvacFriction;
UnitSystem = UnitSystem.Metric;
// Support only Pa / m.
DerivedUnitExpectedTypes expectedTypes = new DerivedUnitExpectedTypes(UnitTypeId.PascalsPerMeter, SymbolTypeId.PaPerM);
expectedTypes.AddExpectedType(-2, SpecTypeId.Length);
expectedTypes.AddExpectedType(1, SpecTypeId.Mass);
expectedTypes.AddCustomExpectedType(-2, "TIMEUNIT");
expectedTypesList.Add(expectedTypes);
}
}
}
foreach (DerivedUnitExpectedTypes derivedUnitExpectedTypes in expectedTypesList)
{
double scaleFactor = 1.0;
if (derivedUnitExpectedTypes.Matches(derivedElementUnitHnds, out scaleFactor))
{
// Found a match.
Unit = derivedUnitExpectedTypes.Unit;
Symbol = derivedUnitExpectedTypes.Symbol;
ScaleFactor = scaleFactor;
return;
}
}
Importer.TheLog.LogUnhandledUnitTypeError(unitHnd, unitType);
}
/// <summary>
/// Processes an IfcDerivedUnit.
/// </summary>
/// <param name="unitHnd">The unit handle.</param>
void ProcessIFCDerivedUnit(IFCAnyHandle unitHnd)
{
List <IFCAnyHandle> elements =
IFCAnyHandleUtil.GetAggregateInstanceAttribute <List <IFCAnyHandle> >(unitHnd, "Elements");
IList <KeyValuePair <IFCUnit, int> > derivedElementUnitHnds = new List <KeyValuePair <IFCUnit, int> >();
foreach (IFCAnyHandle subElement in elements)
{
IFCAnyHandle derivedElementUnitHnd = IFCImportHandleUtil.GetRequiredInstanceAttribute(subElement, "Unit", false);
IFCUnit subUnit = IFCAnyHandleUtil.IsNullOrHasNoValue(derivedElementUnitHnd) ? null : IFCUnit.ProcessIFCUnit(derivedElementUnitHnd);
if (subUnit != null)
{
bool found;
int exponent = IFCImportHandleUtil.GetRequiredIntegerAttribute(subElement, "Exponent", out found);
if (found)
{
derivedElementUnitHnds.Add(new KeyValuePair <IFCUnit, int>(subUnit, exponent));
}
}
}
ISet <Tuple <int, UnitType, string> > expectedTypes = new HashSet <Tuple <int, UnitType, string> >();
string unitType = IFCAnyHandleUtil.GetEnumerationAttribute(unitHnd, "UnitType");
if (string.Compare(unitType, "THERMALTRANSMITTANCEUNIT", true) == 0)
{
UnitType = UnitType.UT_HVAC_CoefficientOfHeatTransfer;
UnitSystem = UnitSystem.Metric;
UnitName = UnitName.DUT_WATTS_PER_SQUARE_METER_KELVIN;
// Support only kg / (K * s^3).
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(1, UnitType.UT_Mass, null));
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(-1, UnitType.UT_HVAC_Temperature, null));
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(-3, UnitType.UT_Custom, "TIMEUNIT"));
}
else if (string.Compare(unitType, "VOLUMETRICFLOWRATEUNIT", true) == 0)
{
UnitType = UnitType.UT_HVAC_Airflow;
UnitSystem = UnitSystem.Metric;
UnitName = UnitName.DUT_CUBIC_METERS_PER_SECOND;
// Support only m^3 / s.
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(3, UnitType.UT_Length, null));
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(-1, UnitType.UT_Custom, "TIMEUNIT"));
}
else if (string.Compare(unitType, "USERDEFINED", true) == 0)
{
// Look at the sub-types to see what we support.
string userDefinedType = IFCImportHandleUtil.GetOptionalStringAttribute(unitHnd, "UserDefinedType", null);
if (!string.IsNullOrWhiteSpace(userDefinedType))
{
if (string.Compare(userDefinedType, "Luminous Efficacy", true) == 0)
{
UnitType = UnitType.UT_Electrical_Efficacy;
UnitSystem = UnitSystem.Metric;
UnitName = UnitName.DUT_LUMENS_PER_WATT;
// Support only lm / W.
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(-1, UnitType.UT_Mass, null));
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(-2, UnitType.UT_Length, null));
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(3, UnitType.UT_Custom, "TIMEUNIT"));
expectedTypes.Add(new Tuple <int, Autodesk.Revit.DB.UnitType, string>(1, UnitType.UT_Electrical_Luminous_Flux, null));
}
}
}
double scaleFactor = 1.0;
if (derivedElementUnitHnds.Count == expectedTypes.Count)
{
foreach (KeyValuePair <IFCUnit, int> derivedElementUnitHnd in derivedElementUnitHnds)
{
int dimensionality = derivedElementUnitHnd.Value;
Tuple <int, UnitType, string> currKey = new Tuple <int, UnitType, string>(dimensionality, derivedElementUnitHnd.Key.UnitType, derivedElementUnitHnd.Key.CustomUnitType);
if (expectedTypes.Contains(currKey))
{
expectedTypes.Remove(currKey);
scaleFactor *= Math.Pow(derivedElementUnitHnd.Key.ScaleFactor, dimensionality);
}
else
{
break;
}
}
// Found all supported units.
if (expectedTypes.Count == 0)
{
ScaleFactor = scaleFactor;
return;
}
}
IFCImportFile.TheLog.LogUnhandledUnitTypeError(unitHnd, unitType);
}
/// <summary>
/// Processes IfcProject attributes.
/// </summary>
/// <param name="ifcProjectHandle">The IfcProject handle.</param>
protected override void Process(IFCAnyHandle ifcProjectHandle)
{
IFCAnyHandle unitsInContext = IFCImportHandleUtil.GetRequiredInstanceAttribute(ifcProjectHandle, "UnitsInContext", false);
if (!IFCAnyHandleUtil.IsNullOrHasNoValue(unitsInContext))
{
IList <IFCAnyHandle> units = IFCAnyHandleUtil.GetAggregateInstanceAttribute <List <IFCAnyHandle> >(unitsInContext, "Units");
if (units != null)
{
m_UnitsInContext = new HashSet <IFCUnit>();
foreach (IFCAnyHandle unit in units)
{
IFCUnit ifcUnit = IFCImportFile.TheFile.IFCUnits.ProcessIFCProjectUnit(unit);
if (!IFCUnit.IsNullOrInvalid(ifcUnit))
{
m_UnitsInContext.Add(ifcUnit);
}
}
}
else
{
Importer.TheLog.LogMissingRequiredAttributeError(unitsInContext, "Units", false);
}
}
var application = IFCImportFile.TheFile.Document.Application;
var projectUnits = IFCImportFile.TheFile.IFCUnits.GetIFCProjectUnit(SpecTypeId.Length);
IFCImportFile.TheFile.VertexTolerance = application.VertexTolerance;
IFCImportFile.TheFile.ShortCurveTolerance = application.ShortCurveTolerance;
Importer.TheProcessor.PostProcessProject(projectUnits?.ScaleFactor, projectUnits?.Unit);
// We need to process the units before we process the rest of the file, since we will scale values as we go along.
base.Process(ifcProjectHandle);
// process true north - take the first valid representation context that has a true north value.
HashSet <IFCAnyHandle> repContexts = IFCAnyHandleUtil.GetAggregateInstanceAttribute <HashSet <IFCAnyHandle> >(ifcProjectHandle, "RepresentationContexts");
bool hasMapConv = false;
XYZ geoRef = XYZ.Zero;
string geoRefName = null;
double trueNorth = 0.0;
if (repContexts != null)
{
foreach (IFCAnyHandle geomRepContextHandle in repContexts)
{
if (!IFCAnyHandleUtil.IsNullOrHasNoValue(geomRepContextHandle) &&
IFCAnyHandleUtil.IsSubTypeOf(geomRepContextHandle, IFCEntityType.IfcGeometricRepresentationContext))
{
IFCRepresentationContext context = IFCRepresentationContext.ProcessIFCRepresentationContext(geomRepContextHandle);
if (TrueNorthDirection == null && context.TrueNorth != null)
{
// TODO: Verify that we don't have inconsistent true norths. If we do, warn.
TrueNorthDirection = new UV(context.TrueNorth.X, context.TrueNorth.Y);
}
if (WorldCoordinateSystem == null && context.WorldCoordinateSystem != null && !context.WorldCoordinateSystem.IsIdentity)
{
WorldCoordinateSystem = context.WorldCoordinateSystem;
}
// Process Map Conversion if any
HashSet <IFCAnyHandle> coordOperation = IFCAnyHandleUtil.GetAggregateInstanceAttribute <HashSet <IFCAnyHandle> >(geomRepContextHandle, "HasCoordinateOperation");
if (coordOperation != null)
{
if (coordOperation.Count > 0)
{
if (IFCAnyHandleUtil.IsSubTypeOf(coordOperation.FirstOrDefault(), IFCEntityType.IfcMapConversion))
{
hasMapConv = true;
IFCAnyHandle mapConv = coordOperation.FirstOrDefault();
bool found = false;
double eastings = IFCImportHandleUtil.GetRequiredScaledLengthAttribute(mapConv, "Eastings", out found);
if (!found)
{
eastings = 0.0;
}
double northings = IFCImportHandleUtil.GetRequiredScaledLengthAttribute(mapConv, "Northings", out found);
if (!found)
{
northings = 0.0;
}
double orthogonalHeight = IFCImportHandleUtil.GetRequiredScaledLengthAttribute(mapConv, "OrthogonalHeight", out found);
if (!found)
{
orthogonalHeight = 0.0;
}
double xAxisAbs = IFCImportHandleUtil.GetOptionalRealAttribute(mapConv, "XAxisAbscissa", 1.0);
double xAxisOrd = IFCImportHandleUtil.GetOptionalRealAttribute(mapConv, "XAxisOrdinate", 0.0);
trueNorth = Math.Atan2(xAxisOrd, xAxisAbs);
//angleToNorth = -((xAxisAngle > -Math.PI / 2.0) ? xAxisAngle - Math.PI / 2.0 : xAxisAngle + Math.PI * 1.5);
double scale = IFCImportHandleUtil.GetOptionalRealAttribute(mapConv, "Scale", 1.0);
geoRef = new XYZ(scale * eastings, scale * northings, scale * orthogonalHeight);
// Process the IfcProjectedCRS
IFCAnyHandle projCRS = IFCAnyHandleUtil.GetInstanceAttribute(mapConv, "TargetCRS");
if (projCRS != null && IFCAnyHandleUtil.IsSubTypeOf(projCRS, IFCEntityType.IfcProjectedCRS))
{
geoRefName = IFCImportHandleUtil.GetRequiredStringAttribute(projCRS, "Name", false);
string desc = IFCImportHandleUtil.GetOptionalStringAttribute(projCRS, "Description", null);
string geodeticDatum = IFCImportHandleUtil.GetOptionalStringAttribute(projCRS, "GeodeticDatum", null);
string verticalDatum = IFCImportHandleUtil.GetOptionalStringAttribute(projCRS, "VerticalDatum", null);
string mapProj = IFCImportHandleUtil.GetOptionalStringAttribute(projCRS, "MapProjection", null);
string mapZone = IFCImportHandleUtil.GetOptionalStringAttribute(projCRS, "MapZone", null);
IFCAnyHandle mapUnit = IFCImportHandleUtil.GetOptionalInstanceAttribute(projCRS, "MapUnit");
Document doc = IFCImportFile.TheFile.Document;
ProjectInfo projectInfo = doc.ProjectInformation;
// We add this here because we want to make sure that external processors (e.g., Navisworks)
// get a chance to add a container for the parameters that get added below. In general,
// we should probably augment Processor.AddParameter to ensure that CreateOrUpdateElement
// is called before anything is attempted to be added. This is a special case, though,
// as in Revit we don't actually create an element for the IfcProject.
Importer.TheProcessor.CreateOrUpdateElement(Id, GlobalId, EntityType.ToString(), CategoryId.IntegerValue, null);
Category category = IFCPropertySet.GetCategoryForParameterIfValid(projectInfo, Id);
IFCPropertySet.AddParameterString(doc, projectInfo, category, this, "IfcProjectedCRS.Name", geoRefName, Id);
if (!string.IsNullOrEmpty(desc))
{
IFCPropertySet.AddParameterString(doc, projectInfo, category, this, "IfcProjectedCRS.Description", desc, Id);
}
if (!string.IsNullOrEmpty(geodeticDatum))
{
IFCPropertySet.AddParameterString(doc, projectInfo, category, this, "IfcProjectedCRS.GeodeticDatum", geodeticDatum, Id);
}
if (!string.IsNullOrEmpty(verticalDatum))
{
IFCPropertySet.AddParameterString(doc, projectInfo, category, this, "IfcProjectedCRS.VerticalDatum", verticalDatum, Id);
}
if (!string.IsNullOrEmpty(mapProj))
{
IFCPropertySet.AddParameterString(doc, projectInfo, category, this, "IfcProjectedCRS.MapProjection", mapProj, Id);
}
if (!string.IsNullOrEmpty(mapZone))
{
IFCPropertySet.AddParameterString(doc, projectInfo, category, this, "IfcProjectedCRS.MapZone", mapZone, Id);
}
if (!IFCAnyHandleUtil.IsNullOrHasNoValue(mapUnit))
{
IFCUnit mapUnitIfc = IFCUnit.ProcessIFCUnit(mapUnit);
string unitStr = UnitUtils.GetTypeCatalogStringForUnit(mapUnitIfc.Unit);
IFCPropertySet.AddParameterString(doc, projectInfo, category, this, "IfcProjectedCRS.MapUnit", unitStr, Id);
double convFactor = UnitUtils.Convert(1.0, mapUnitIfc.Unit, IFCImportFile.TheFile.IFCUnits.GetIFCProjectUnit(SpecTypeId.Length).Unit);
eastings = convFactor * eastings;
northings = convFactor * northings;
orthogonalHeight = convFactor * orthogonalHeight;
geoRef = new XYZ(eastings, northings, orthogonalHeight);
}
}
}
}
}
}
}
ProjectLocation projectLocation = IFCImportFile.TheFile.Document.ActiveProjectLocation;
ProjectPosition projectPosition;
if (projectLocation != null)
{
if (hasMapConv)
{
projectPosition = new ProjectPosition(geoRef.X, geoRef.Y, geoRef.Z, trueNorth);
projectLocation.SetProjectPosition(XYZ.Zero, projectPosition);
if (!string.IsNullOrEmpty(geoRefName))
{
IFCImportFile.TheFile.Document.SiteLocation.SetGeoCoordinateSystem(geoRefName);
}
}
else
{
// Set initial project location based on the information above.
// This may be further modified by the site.
trueNorth = 0.0;
if (TrueNorthDirection != null)
{
trueNorth = -Math.Atan2(-TrueNorthDirection.U, TrueNorthDirection.V);
}
// TODO: Extend this to work properly if the world coordinate system
// isn't a simple translation.
XYZ origin = XYZ.Zero;
if (WorldCoordinateSystem != null)
{
geoRef = WorldCoordinateSystem.Origin;
double angleRot = Math.Atan2(WorldCoordinateSystem.BasisX.Y, WorldCoordinateSystem.BasisX.X);
// If it is translation only, or if the WCS rotation is equal to trueNorth, we assume they are the same
if (WorldCoordinateSystem.IsTranslation ||
MathUtil.IsAlmostEqual(angleRot, trueNorth))
{
WorldCoordinateSystem = null;
}
else
{
// If the trueNorth is not set (=0), set the trueNorth by the rotation of the WCS, otherwise add the angle
if (MathUtil.IsAlmostZero(trueNorth))
{
trueNorth = angleRot;
}
else
{
trueNorth += angleRot;
}
WorldCoordinateSystem = null;
}
}
projectPosition = new ProjectPosition(geoRef.X, geoRef.Y, geoRef.Z, trueNorth);
projectLocation.SetProjectPosition(XYZ.Zero, projectPosition);
}
}
}
}