/////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2002-2025, Open Design Alliance (the "Alliance"). // All rights reserved. // // This software and its documentation and related materials are owned by // the Alliance. The software may only be incorporated into application // programs owned by members of the Alliance, subject to a signed // Membership Agreement and Supplemental Software License Agreement with the // Alliance. The structure and organization of this software are the valuable // trade secrets of the Alliance and its suppliers. The software is also // protected by copyright law and international treaty provisions. Application // programs incorporating this software must include the following statement // with their copyright notices: // // This application incorporates Open Design Alliance software pursuant to a license // agreement with Open Design Alliance. // Open Design Alliance Copyright (C) 2002-2025 by Open Design Alliance. // All rights reserved. // // By use of this software, its documentation or related materials, you // acknowledge and accept the above terms. /////////////////////////////////////////////////////////////////////////////// // This file is generated automatically. #ifndef _IFC4X4_IFCMEMBER_AUTO_IMPL_H #define _IFC4X4_IFCMEMBER_AUTO_IMPL_H #include "IfcBuiltElementAutoImpl.h" #include "TD_PackPush.h" /** \details The namespace contains schema-dependent classes, definitions and sub routines for work with IFC4X4 express schema definitions. */ namespace OdIfc4x4 { /** \details An IfcMember is a structural member designed to carry loads between or beyond points of support. It is not required to be load bearing. The orientation of the member (being horizontal, vertical or sloped) is not relevant to its definition (in contrary to IfcBeam and IfcColumn). An IfcMember represents a linear structural element from an architectural or structural modeling point of view and is used if it cannot be expressed more specifically as either an IfcBeam or an IfcColumn. There are two main representations for member occurrences: * IfcMember with IfcMaterialProfileSetUsage is used for all occurrences of members, that have a profile defined that is swept along a directrix. The profile might be changed uniformly by a taper definition along the directrix. The profile parameter and its cardinal point of insertion can be fully described by the IfcMaterialProfileSetUsage. These members are always represented geometrically by an 'Axis' and a 'SweptSolid' or 'AdvancedSweptSolid' shape representation (or by a 'Clipping' geometry based on the swept solid), if a 3D geometric representation is assigned * IfcMember without IfcMaterialProfileSetUsage is used for all other occurrences of members, particularly for members with changing profile sizes along the extrusion, or members defined by non-linear extrusion, or members having only 'Brep', or 'SurfaceModel' geometry, or if a more parametric representation is not intended - Axis 3D Geometry - The axis representation can be used to represent the fundamental orientation and extents of a member's body. The image below illustrates that the axis representation can be used to represent the system length of a member that can extend past the body length of the member. As shown on the image below, the axis representation must be positioned at the IfcMaterialProfileSetUsage.CardinalPoint, and parallel to the IfcExtrudedAreaSolid.ExtrudedDirection. This offset between the axis line and the IfcExtrudedAreaSolid.Position must correlate with the chosen IfcMaterialProfileSetUsage.CardinalPoint. - Body AdvancedSweptSolid Geometry - * IfcSurfaceCurveSweptAreaSolid, IfcFixedReferenceSweptAreaSolid, IfcExtrudedAreaSolidTapered, IfcRevolvedAreaSolidTapered is supported * All subtypes of (IfcProfileDef) (with exception of IfcArbitraryOpenProfileDef) are supported - Body Clipping Geometry - * IfcExtrudedAreaSolid, IfcRevolvedAreaSolid is supported * All subtypes of (IfcProfileDef) (with exception of IfcArbitraryOpenProfileDef) are supported * All extrusion directions are supported * The IfcBooleanClippingResult is supported, allowing for Boolean differences between the swept solid (here IfcExtrudedAreaSolid) and one or several IfcHalfSpaceSolid (or its subtypes) instances The image below illustrates a 'Clipping' geometric representation with use of IfcBooleanClippingResult between an IfcExtrudedAreaSolid and an IfcHalfSpaceSolid to create a clipped body. When an IfcMaterialProfileSetUsage is applied, the image below illustrates an advanced geometric representation with use of IfcBooleanClippingResult between an IfcExtrudedAreaSolid and an IfcHalfSpaceSolid to create a clipped body, with cardinal point applied as 4 (mid-depth left). - Body SweptSolid Geometry - * IfcExtrudedAreaSolid, IfcRevolvedAreaSolid is supported * All subtypes of (IfcProfileDef) (with exception of IfcArbitraryOpenProfileDef) are supported * All extrusion directions are supported When an (IfcMaterialProfileSetUsage) is assigned to the IfcMember: * For all single profiles, the IfcParameterizedProfileDef.Position is NIL, or having Location = 0.,0. and RefDirection = 1.,0 * The extrusion is perpendicular to the profile direction * The y-axis of the profile, as determined by IfcSweptAreaSolid.Position.P[2] points to the Z-Axis. It indicates the "role" of the column, a role=0° means y-axis of profile = Z-axis of reference coordinate system. In the exception of a vertical member, the y-axis points to the Y-axis The image below illustrates a 'SweptSolid' geometric representation with cardinal point applied as 1 (bottom left). If parametric profiles are used, the parameters can be interpreted to be the dimensions of the beam: * IfcRectangleProfileDef.YDim interpreted as member width * IfcRectangleProfileDef.XDim interpreted as member depth * IfcCircleProfileDef.Radius interpreted as member radius - Material Profile Set Usage - The image below illustrates assignment of IfcMaterialProfileSetUsage and IfcMaterialProfileSet to the IfcMemberType and the IfcMember occurrence. Both the IfcMaterialProfileSet and IfcProfileDef is shared between all occurrences. Te image below illustrates assignment of a composite profile by using IfcCompositeProfileDef for geometric representation and several IfcMaterialProfile entities within the IfcMaterialProfileSet. - Material Set - This concept can be applied to the following resources: * LoadBearing - Object Typing - This concept can be applied to the following resources: * IfcMemberType - Product Assignment - This concept can be applied to the following resources: * IfcStructuralCurveMember - An idealized structural member corresponding to the member * IfcTask - A task for operating on the member - Property Sets for Objects - This concept can be applied to the following resources: * Pset_ConcreteElementGeneral * Pset_PrecastConcreteElementFabrication * Pset_PrecastConcreteElementGeneral * Pset_MemberCommon * Pset_MemberTypeAnchoringBar (only applies to BRACE) * Pset_MemberTypeOCSRigidSupport (only applies to MEMBER) * Pset_MemberTypePost (only applies to POST) * Pset_MemberTypeCatenaryStay (only applies to STAY_CABLE) * Pset_MemberTypeTieBar (only applies to TIEBAR) - Quantity Sets - This concept can be applied to the following resources: * Qto_MemberBaseQuantities - Spatial Containment - The IfcMember, as any subtype of IfcBuildingElement, can participate alternatively in one of the two different containment relationships: * the Spatial Containment (defined here) * the Element Composition \changes * IFC4X3_RC1 changes: Supertype changed from "IfcBuildingElement" to "IfcBuiltElement" */ class IFC4X4_EXPORT IfcMember : public IfcBuiltElement { //DOM-IGNORE-BEGIN OD_EXP_DECLARE_MEMBERS(OdIfc4x4::IfcMember); //DOM-IGNORE-END public: // // OdDAI early binding accessors // /** \details Returns the value of PredefinedType attribute. This attribute represents predefined generic type for a member that is specified in an enumeration. There can be a property set specified for the predefined types. \returns Returns the value of PredefinedType attribute. \remarks The PredefinedType is only used if no IfcMemberType is assigned, providing its own IfcMemberType.PredefinedType. */ IfcMemberTypeEnum getPredefinedType() const; /** \details Sets the value of PredefinedType attribute. This attribute represents predefined generic type for a member that is specified in an enumeration. There can be a property set specified for the predefined types. \param PredefinedType [in] Predefined type to set. \remarks The PredefinedType is only used if no IfcMemberType is assigned, providing its own IfcMemberType.PredefinedType. */ void setPredefinedType(IfcMemberTypeEnum PredefinedType); public: /** \details Default constructor for the IfcMember class. */ IfcMember(); /** \details Reads object's data from the specified filer. \param rdFiler [in] Pointer to a filer from which to read the data. \returns A value of OdResult type that contains the result of the method execution. */ virtual OdResult inFields(OdDAI::OdSpfFilerBase* rdFiler) override; /** \details Writes object's data the the specified filer. \param wrFiler [in] Pointer to a filer to which to write the data. \returns A value of OdResult type that contains the result of the method execution. */ virtual OdResult outFields(OdDAI::OdSpfFilerBase* wrFiler) override; /** \details Returns a type of a class instance. \returns Pointer to the OdDAI::Entity type that determines an entity definition within a schema. */ virtual OdDAI::Entity* getInstanceType() const override; /** \details Returns an attribute value for the specified attribute name. \param attrName [in] Name of an attribute to query. \returns OdRxValue object that represents a generic variant type value. */ virtual OdRxValue getAttr(const char * attrName) const override; /** \details Early-bound version of instances comparison. \param pOther [in] Other application instance. \param ordering [out] Receives the ordering (comparison) status. \returns true if comparison was performed, false if method has no implementation, so late-bound version could be applied. \remarks If the method returns true, the ordering parameter can receive one of the following statuses: Name Value Description _kLessThan_ -1 This object < Other Object. _kEqual_ 0 This object = Other Object. _kGreaterThan_ 1 This object > Other Object. _kNotOrderable_ 2 This class is not orderable.
*/ virtual bool comparedToEarlyImpl(const OdDAI::ApplicationInstance *pOther, OdRx::Ordering &ordering) const override; /** \details Resets a value for the specified attribute. \param explicitAttrName [in] Explicit name of the attribute to reset. */ virtual void unsetAttr(const char * explicitAttrName) override; /** \details Checks whether the specified attribute is set. \param explicitAttrName [in] Explicit name of the attribute to test. \returns true if the specified attribute is set, false otherwise. */ virtual bool testAttr(const char * explicitAttrName) const override; /** \details Sets the specified attribute with a given value. \param explicitAttrName [in] Explicit name of the attribute to set. \param val [in] Value to set. \returns true if the value is successfully set for the specified attribute, false otherwise. */ virtual bool putAttr(const char * explicitAttrName, const OdRxValue &val) override; /** \details Checks whether the specified instance is the object derived from or belongs to this class. \param entityType [in] Entity to check. \returns true if the specified instance is the object derived from or belongs to this class, false otherwise. */ virtual bool isKindOf(OdIfc::OdIfcEntityType entityType) const override; /** \details Returns the type of this entity. \returns A value of the OdIfc::OdIfcEntityType type that represents type of this entity. */ virtual OdIfc::OdIfcEntityType type() const override; /** \details Returns an attribute value for the specified attribute definition. \param attrDef [in] Attribute definition to query. \returns OdRxValue object that represents a generic variant type value. */ virtual OdRxValue getAttr(const OdIfc::OdIfcAttribute attrDef) const override; /** \details Resets a value for the specified attribute. \param explicitAttrDef [in] Explicit definition that represents an attribute to reset. */ virtual void unsetAttr(const OdIfc::OdIfcAttribute explicitAttrDef) override; /** \details Checks whether the specified attribute is set. \param explicitAttrDef [in] Attribute definition to test. \returns true if the specified attribute is set, false otherwise. */ virtual bool testAttr(const OdIfc::OdIfcAttribute explicitAttrDef) const override; /** \details Sets the specified attribute with a given value. \param explicitAttrDef [in] Explicit attribute definition to set. \param val [in] Value to set. \returns true if the value is successfully set for the specified attribute, false otherwise. */ virtual bool putAttr(const OdIfc::OdIfcAttribute explicitAttrDef, const OdRxValue &val) override; protected: // Fields declaration: OdDAI::Enum m_PredefinedType; // IfcMemberTypeEnum [optional] }; /** \details A data type that represents a smart pointer to a IfcMember object. */ typedef OdSmartPtr IfcMemberPtr; } // namespace #include "TD_PackPop.h" #endif // _IFC4X4_IFCMEMBER_AUTO_IMPL_H