IfcOpenShell/src/examples/IfcAlignment.cpp at ifc_cli · IfcOpenShell/IfcOpenShell

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/********************************************************************************

* *

* This file is part of IfcOpenShell. *

* *

* IfcOpenShell is free software: you can redistribute it and/or modify *

* it under the terms of the Lesser GNU General Public License as published by *

* the Free Software Foundation, either version 3.0 of the License, or *

* (at your option) any later version. *

* *

* IfcOpenShell is distributed in the hope that it will be useful, *

* but WITHOUT ANY WARRANTY; without even the implied warranty of *

* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *

* Lesser GNU General Public License for more details. *

* *

* You should have received a copy of the Lesser GNU General Public License *

* along with this program. If not, see <http://www.gnu.org/licenses/>. *

* *

********************************************************************************/

// This example illustrates the basic of building an alignment model.

// The alignment is based on "Bridge Geometry Manual", April 2022

// US Department of Transportation, Federal Highway Administration (FHWA)

// https://www.fhwa.dot.gov/bridge/pubs/hif22034.pdf

// Sections and page number for this document are cited in the code comments.

// This examples differs from IfcSimplifiedAlignment because it builds the

// alignment explicitly

// Disable warnings coming from IfcOpenShell

#pragma warning(disable : 4018 4267 4250 4984 4985)

#include "ifcparse/Ifc4x3_add2.h"

#include "ifcparse/IfcHierarchyHelper.h"

#include <boost/math/constants/constants.hpp>

#include <fstream>

const double PI = boost::math::constants::pi<double>();

double to_radian(double deg) { return PI * deg / 180; }

#define Schema Ifc4x3_add2

// performs basic project setup including created the IfcProject object

// and initializing the project units to FEET

Schema::IfcProject* setup_project(IfcHierarchyHelper<Schema>& file) {

std::vector<std::string> file_description;

file_description.push_back("ViewDefinition[Alignment-basedReferenceView]");

file.header().file_description()->setdescription(file_description);

auto project = file.addProject();

project->setName(std::string("FHWA Bridge Geometry Manual Example Alignment"));

project->setDescription(std::string("C++ Example"));

// set up project units for feet

// the call to file.addProject() sets up length units as millimeter.

auto units_in_context = project->UnitsInContext();

auto units = units_in_context->Units();

auto begin = units->begin();

auto iter = begin;

auto end = units->end();

for (; iter != end; iter++) {

auto unit = *iter;

if (unit->as<Schema::IfcSIUnit>() && unit->as<Schema::IfcSIUnit>()->UnitType() == Schema::IfcUnitEnum::IfcUnit_LENGTHUNIT) {

auto dimensions = new Schema::IfcDimensionalExponents(1, 0, 0, 0, 0, 0, 0);

file.addEntity(dimensions);

auto conversion_factor = new Schema::IfcMeasureWithUnit(new Schema::IfcLengthMeasure(304.80), unit->as<Schema::IfcSIUnit>());

file.addEntity(conversion_factor);

auto conversion_based_unit = new Schema::IfcConversionBasedUnit(dimensions, Schema::IfcUnitEnum::IfcUnit_LENGTHUNIT, "FEET", conversion_factor);

file.addEntity(conversion_based_unit);

units->remove(unit); // remove the millimeter unit

units->push(conversion_based_unit); // add the feet unit

units_in_context->setUnits(units); // update the UnitsInContext

break; // Done!, the length unit was found, so break out of the loop

}

return project;

}

// creates geometry and business logic segments for horizontal alignment tangent runs

std::pair<typename Schema::IfcCurveSegment*, typename Schema::IfcAlignmentSegment*> create_tangent(typename Schema::IfcCartesianPoint* p, double dir, double length) {

// geometry

auto parent_curve = new Schema::IfcLine(

new Schema::IfcCartesianPoint(std::vector<double>({0, 0})),

new Schema::IfcVector(new Schema::IfcDirection(std::vector<double>{1.0, 0.0}), 1.0));

auto curve_segment = new Schema::IfcCurveSegment(

Schema::IfcTransitionCode::IfcTransitionCode_CONTSAMEGRADIENT,

new Schema::IfcAxis2Placement2D(p, new Schema::IfcDirection(std::vector<double>{cos(dir), sin(dir)})),

new Schema::IfcLengthMeasure(0.0), // start

new Schema::IfcLengthMeasure(length),

parent_curve);

// business logic

auto design_parameters = new Schema::IfcAlignmentHorizontalSegment(

boost::none, boost::none, p, dir, 0.0, 0.0, length, boost::none, Schema::IfcAlignmentHorizontalSegmentTypeEnum::IfcAlignmentHorizontalSegmentType_LINE);

auto alignment_segment = new Schema::IfcAlignmentSegment(

IfcParse::IfcGlobalId(), nullptr, boost::none, boost::none, boost::none, nullptr, nullptr, design_parameters);

return {curve_segment, alignment_segment};

}

// creates geometry and business logic segments for horizontal alignment horizonal curves

std::pair<typename Schema::IfcCurveSegment*, typename Schema::IfcAlignmentSegment*> create_hcurve(typename Schema::IfcCartesianPoint* pc, double dir, double radius, double lc) {

// geometry

double sign = radius / fabs(radius);

auto parent_curve = new Schema::IfcCircle(

new Schema::IfcAxis2Placement2D(new Schema::IfcCartesianPoint(std::vector<double>({0, 0})), new Schema::IfcDirection(std::vector<double>{1, 0})),

fabs(radius));

auto curve_segment = new Schema::IfcCurveSegment(

Schema::IfcTransitionCode::IfcTransitionCode_CONTSAMEGRADIENT,

new Schema::IfcAxis2Placement2D(pc, new Schema::IfcDirection(std::vector<double>{cos(dir), sin(dir)})),

new Schema::IfcLengthMeasure(0.0),

new Schema::IfcLengthMeasure(sign * lc),

parent_curve);

// business logic

auto design_parameters = new Schema::IfcAlignmentHorizontalSegment(boost::none, boost::none, pc, dir, radius, radius, lc, boost::none, Schema::IfcAlignmentHorizontalSegmentTypeEnum::IfcAlignmentHorizontalSegmentType_CIRCULARARC);

auto alignment_segment = new Schema::IfcAlignmentSegment(IfcParse::IfcGlobalId(), nullptr, boost::none, boost::none, boost::none, nullptr, nullptr, design_parameters);

return {curve_segment, alignment_segment};

}

// creates geometry and business logic segments for vertical profile gradient runs

std::pair<typename Schema::IfcCurveSegment*, typename Schema::IfcAlignmentSegment*> create_gradient(typename Schema::IfcCartesianPoint* p, double slope, double length) {

// geometry

auto parent_curve = new Schema::IfcLine(

new Schema::IfcCartesianPoint(std::vector<double>({0, 0})),

new Schema::IfcVector(new Schema::IfcDirection(std::vector<double>{1, 0}), 1.0));

auto curve_segment = new Schema::IfcCurveSegment(

Schema::IfcTransitionCode::IfcTransitionCode_CONTSAMEGRADIENT,

new Schema::IfcAxis2Placement2D(p, new Schema::IfcDirection(std::vector<double>{sqrt(1 - slope * slope), slope})),

new Schema::IfcLengthMeasure(0.0), // start

new Schema::IfcLengthMeasure(length),

parent_curve);

// business logic

auto design_parameters = new Schema::IfcAlignmentVerticalSegment(boost::none, boost::none, p->Coordinates()[0], length, p->Coordinates()[1], slope, slope, boost::none, Schema::IfcAlignmentVerticalSegmentTypeEnum::IfcAlignmentVerticalSegmentType_CONSTANTGRADIENT);

auto alignment_segment = new Schema::IfcAlignmentSegment(IfcParse::IfcGlobalId(), nullptr, boost::none, boost::none, boost::none, nullptr, nullptr, design_parameters);

return {curve_segment, alignment_segment};

}

// creates geometry and business logic segments for vertical profile parabolic vertical curves

std::pair<typename Schema::IfcCurveSegment*, typename Schema::IfcAlignmentSegment*> create_vcurve(typename Schema::IfcCartesianPoint* p, double start_slope, double end_slope, double length) {

// geometry

double A = p->Coordinates()[1];

double B = start_slope;

double C = (end_slope - start_slope) / (2 * length);

auto parent_curve = new Schema::IfcPolynomialCurve(

new Schema::IfcAxis2Placement2D(new Schema::IfcCartesianPoint(std::vector<double>{0.0, 0.0}), new Schema::IfcDirection(std::vector<double>{1.0, 0.0})),

std::vector<double>{0.0, 1.0},

std::vector<double>{A, B, C},

boost::none);

auto curve_segment = new Schema::IfcCurveSegment(

Schema::IfcTransitionCode::IfcTransitionCode_CONTSAMEGRADIENT,

new Schema::IfcAxis2Placement2D(p, new Schema::IfcDirection(std::vector<double>{sqrt(1 - start_slope * start_slope), start_slope})),

new Schema::IfcLengthMeasure(0.0),

new Schema::IfcLengthMeasure(length),

parent_curve);

// business logic

double k = (end_slope - start_slope) / length;

auto design_parameters = new Schema::IfcAlignmentVerticalSegment(boost::none, boost::none, p->Coordinates()[0], length, p->Coordinates()[1], start_slope, end_slope, 1 / k, Schema::IfcAlignmentVerticalSegmentTypeEnum::IfcAlignmentVerticalSegmentType_PARABOLICARC);

auto alignment_segment = new Schema::IfcAlignmentSegment(IfcParse::IfcGlobalId(), nullptr, boost::none, boost::none, boost::none, nullptr, nullptr, design_parameters);

return {curve_segment, alignment_segment};

}

// creates representations for each IfcAlignmentSegment per CT 4.1.7.1.1.4

// https://standards.buildingsmart.org/IFC/RELEASE/IFC4_3/HTML/concepts/Product_Shape/Product_Geometric_Representation/Alignment_Geometry/Alignment_Geometry_-_Segments/content.html

void create_segment_representations(IfcHierarchyHelper<Schema>& file, Schema::IfcLocalPlacement* global_placement, Schema::IfcGeometricRepresentationSubContext* segment_axis_subcontext, typename aggregate_of<typename Schema::IfcSegment>::ptr curve_segments, typename aggregate_of<typename Schema::IfcObjectDefinition>::ptr segments) {

auto cs_iter = curve_segments->begin();

auto s_iter = segments->begin();

for (; cs_iter != curve_segments->end(); cs_iter++, s_iter++) {

auto curve_segment = *cs_iter;

auto alignment_segment = (*s_iter)->as<Schema::IfcAlignmentSegment>();

typename aggregate_of<typename Schema::IfcRepresentationItem>::ptr representation_items(new aggregate_of<typename Schema::IfcRepresentationItem>());

representation_items->push(curve_segment);

auto axis_representation = new Schema::IfcShapeRepresentation(segment_axis_subcontext, std::string("Axis"), std::string("Segment"), representation_items);

file.addEntity(axis_representation);

typename aggregate_of<typename Schema::IfcRepresentation>::ptr representations(new aggregate_of<typename Schema::IfcRepresentation>());

representations->push(axis_representation);

auto product = new Schema::IfcProductDefinitionShape(boost::none, boost::none, representations);

file.addEntity(product);

alignment_segment->setObjectPlacement(global_placement);

alignment_segment->setRepresentation(product);

}

int main() {

IfcHierarchyHelper<Schema> file;

auto project = setup_project(file);

auto geometric_representation_context = file.getRepresentationContext(std::string("Model")); // creates the representation context if it doesn't already exist

auto axis_model_representation_subcontext = new Schema::IfcGeometricRepresentationSubContext(std::string("Axis"), std::string("Model"), geometric_representation_context, boost::none, Schema::IfcGeometricProjectionEnum::IfcGeometricProjection_MODEL_VIEW, boost::none);

file.addEntity(axis_model_representation_subcontext);

auto global_placement = file.addLocalPlacement();

// Define horizontal alignment

// define key points

// B.1.4 pg 212

auto pob = file.addDoublet<Schema::IfcCartesianPoint>(500, 2500); // beginning

auto pc1 = file.addDoublet<Schema::IfcCartesianPoint>(2142.237995, 1436.014820); // Point of curve (PC), Curve #1

auto pt1 = file.addDoublet<Schema::IfcCartesianPoint>(3660.446123, 2050.736173); // Point of tangent (PT), Curve #1

auto pc2 = file.addDoublet<Schema::IfcCartesianPoint>(4084.115884, 3889.462938); // Point of curve (PC), Curve #2

auto pt2 = file.addDoublet<Schema::IfcCartesianPoint>(5469.395067, 4847.566310); // Point of tangent (PT), Curve #2

auto pc3 = file.addDoublet<Schema::IfcCartesianPoint>(7019.971367, 4638.286073); // Point of curve (PC), Curve #3

auto pt3 = file.addDoublet<Schema::IfcCartesianPoint>(7790.932128, 4006.730765); // Point of tangent (PT), Curve #3

auto poe = file.addDoublet<Schema::IfcCartesianPoint>(8480, 2010); // ending

// define tangent runs and curve lengths

double run_1 = 1956.785654;

double lc_1 = 1919.222667;

double run_2 = 1886.905454;

double lc_2 = 1848.115835;

double run_3 = 1564.635765;

double lc_3 = 1049.119737;

double run_4 = 2112.285084;

// define curve radii

double rc_1 = 1000;

double rc_2 = -1250; // negative radius for curves to the right

double rc_3 = -950;

// bearing of tangents

double angle_1 = to_radian(327.0613);

double angle_2 = to_radian(77.0247);

double angle_3 = to_radian(352.3133);

double angle_4 = to_radian(289.0395);

// create containers to store the curve segments

typename aggregate_of<typename Schema::IfcSegment>::ptr horizontal_curve_segments(new aggregate_of<typename Schema::IfcSegment>()); // geometry

typename aggregate_of<typename Schema::IfcObjectDefinition>::ptr horizontal_segments(new aggregate_of<typename Schema::IfcObjectDefinition>()); // business logic

// Build the horizontal alignment segments

// POB to PC1

auto curve_segment_1 = create_tangent(pob, angle_1, run_1);

horizontal_curve_segments->push(curve_segment_1.first);

horizontal_segments->push(curve_segment_1.second);

// Curve 1

auto curve_segment_2 = create_hcurve(pc1, angle_1, rc_1, lc_1);

horizontal_curve_segments->push(curve_segment_2.first);

horizontal_segments->push(curve_segment_2.second);

// PT1 to PC2

auto curve_segment_3 = create_tangent(pt1, angle_2, run_2);

horizontal_curve_segments->push(curve_segment_3.first);

horizontal_segments->push(curve_segment_3.second);

// Curve 2

auto curve_segment_4 = create_hcurve(pc2, angle_2, rc_2, lc_2);

horizontal_curve_segments->push(curve_segment_4.first);

horizontal_segments->push(curve_segment_4.second);

// PT2 to PC3

auto curve_segment_5 = create_tangent(pt2, angle_3, run_3);

horizontal_curve_segments->push(curve_segment_5.first);

horizontal_segments->push(curve_segment_5.second);

// Curve 3

auto curve_segment_6 = create_hcurve(pc3, angle_3, rc_3, lc_3);

horizontal_curve_segments->push(curve_segment_6.first);

horizontal_segments->push(curve_segment_6.second);

// PT3 to POE

auto curve_segment_7 = create_tangent(pt3, angle_4, run_4);

horizontal_curve_segments->push(curve_segment_7.first);

horizontal_segments->push(curve_segment_7.second);

// Zero-length terminator segment

auto terminator_segment = create_tangent(poe, angle_4, 0.0);

terminator_segment.first->setTransition(Schema::IfcTransitionCode::IfcTransitionCode_DISCONTINUOUS);

horizontal_curve_segments->push(terminator_segment.first);

horizontal_segments->push(terminator_segment.second);

// Create the horizontal alignment (IfcAlignmentHorizontal) and nest alignment segments

auto horizontal_alignment = new Schema::IfcAlignmentHorizontal(IfcParse::IfcGlobalId(), nullptr, std::string("Horizontal Alignment"), boost::none, boost::none, nullptr, nullptr);

file.addEntity(horizontal_alignment);

auto nests_horizontal_segments = new Schema::IfcRelNests(IfcParse::IfcGlobalId(), nullptr, boost::none, std::string("Nests horizontal alignment segments with horizontal alignment"), horizontal_alignment, horizontal_segments);

file.addEntity(nests_horizontal_segments);

// Create plan view footprint model representation for the horizontal alignment

// start by defining a composite curve composed of the horizonal curve segments

auto composite_curve = new Schema::IfcCompositeCurve(horizontal_curve_segments, false /*not self-intersecting*/);

file.addEntity(composite_curve);

// the composite curve is a representation item

typename aggregate_of<typename Schema::IfcRepresentationItem>::ptr alignment_representation_items(new aggregate_of<typename Schema::IfcRepresentationItem>());

alignment_representation_items->push(composite_curve);

// create the footprint representation

auto footprint_shape_representation = new Schema::IfcShapeRepresentation(axis_model_representation_subcontext, std::string("FootPrint"), std::string("Curve2D"), alignment_representation_items);

file.addEntity(footprint_shape_representation);

// Define vertical profile segments

// create containers to store the curve segments

typename aggregate_of<typename Schema::IfcSegment>::ptr vertical_curve_segments(new aggregate_of<typename Schema::IfcSegment>()); // geometry

typename aggregate_of<typename Schema::IfcObjectDefinition>::ptr vertical_segments(new aggregate_of<typename Schema::IfcObjectDefinition>()); // business logic

// define key profile points

auto vpob = file.addDoublet<Schema::IfcCartesianPoint>(0.0, 100.0); // beginning

auto vpc1 = file.addDoublet<Schema::IfcCartesianPoint>(1200.0, 121.0); // Vertical Curve Point (VPC), Vertical Curve #1

auto vpt1 = file.addDoublet<Schema::IfcCartesianPoint>(2800.0, 127.0); // Vertical Curve Tangent (VPT), Vertical Curve #1

auto vpc2 = file.addDoublet<Schema::IfcCartesianPoint>(4400.0, 111.0); // Vertical Curve Point (VPC), Vertical Curve #2

auto vpt2 = file.addDoublet<Schema::IfcCartesianPoint>(5600.0, 117.0); // Vertical Curve Tangent (VPT), Vertical Curve #2

auto vpc3 = file.addDoublet<Schema::IfcCartesianPoint>(6400.0, 133.0); // Vertical Curve Point (VPC), Vertical Curve #3

auto vpt3 = file.addDoublet<Schema::IfcCartesianPoint>(8400.0, 133.0); // Vertical Curve Tangent (VPT), Vertical Curve #3

auto vpc4 = file.addDoublet<Schema::IfcCartesianPoint>(9400.0, 113.0); // Vertical Curve Point (VPC), Vertical Curve #4

auto vpt4 = file.addDoublet<Schema::IfcCartesianPoint>(10200.0, 103.0); // Vertical Curve Tangent (VPT), Vertical Curve #4

auto vpoe = file.addDoublet<Schema::IfcCartesianPoint>(12800.0, 90.0); // ending

// Build the vertical alignment segments

// Grade start to VPC1

auto vertical_profile_segment_1 = create_gradient(vpob, 1.75 / 100, 1200);

vertical_curve_segments->push(vertical_profile_segment_1.first);

vertical_segments->push(vertical_profile_segment_1.second);

// Vertical Curve 1

auto vertical_profile_segment_2 = create_vcurve(vpc1, 1.75 / 100, -1.0 / 100, 1600);

vertical_curve_segments->push(vertical_profile_segment_2.first);

vertical_segments->push(vertical_profile_segment_2.second);

// Grade VPT1 to VPC2

auto vertical_profile_segment_3 = create_gradient(vpt1, -1.0 / 100, 1600);

vertical_curve_segments->push(vertical_profile_segment_3.first);

vertical_segments->push(vertical_profile_segment_3.second);

// Vertical Curve 2

auto vertical_profile_segment_4 = create_vcurve(vpc2, -1.0 / 100, 2.0 / 100, 1200);

vertical_curve_segments->push(vertical_profile_segment_4.first);

vertical_segments->push(vertical_profile_segment_4.second);

// Grade PVT2 to VPC3

auto vertical_profile_segment_5 = create_gradient(vpt2, 2.0 / 100, 800);

vertical_curve_segments->push(vertical_profile_segment_5.first);

vertical_segments->push(vertical_profile_segment_5.second);

// Vertical Curve 3

auto vertical_profile_segment_6 = create_vcurve(vpc3, 2.0 / 100, -2.0 / 100, 2000);

vertical_curve_segments->push(vertical_profile_segment_6.first);

vertical_segments->push(vertical_profile_segment_6.second);

// Grade PVT3 to VPC4

auto vertical_profile_segment_7 = create_gradient(vpt3, -2.0 / 100, 1000);

vertical_curve_segments->push(vertical_profile_segment_7.first);

vertical_segments->push(vertical_profile_segment_7.second);

// Vertical Curve 4

auto vertical_profile_segment_8 = create_vcurve(vpc4, -2.0 / 100, -0.5 / 100, 800);

vertical_curve_segments->push(vertical_profile_segment_8.first);

vertical_segments->push(vertical_profile_segment_8.second);

// Grade VPT4 to End

auto vertical_profile_segment_9 = create_gradient(vpt4, -0.5 / 100, 2600);

vertical_curve_segments->push(vertical_profile_segment_9.first);

vertical_segments->push(vertical_profile_segment_9.second);

// Zero-length terminator

auto vertical_terminator_segment = create_gradient(vpoe, -0.5 / 100, 0.0);

vertical_terminator_segment.first->setTransition(Schema::IfcTransitionCode::IfcTransitionCode_DISCONTINUOUS);

vertical_curve_segments->push(vertical_terminator_segment.first);

vertical_segments->push(vertical_terminator_segment.second);

// Create the vertical alignment (IfcAlignmentVertical) and nest alignment segments

auto vertical_profile = new Schema::IfcAlignmentVertical(IfcParse::IfcGlobalId(), nullptr, std::string("Vertical Alignment"), boost::none, boost::none, nullptr, nullptr);

file.addEntity(vertical_profile);

auto nests_vertical_segments = new Schema::IfcRelNests(IfcParse::IfcGlobalId(), nullptr, boost::none, std::string("Nests vertical alignment segments with vertical alignment"), vertical_profile, vertical_segments);

file.addEntity(nests_vertical_segments);

// Create profile view axis model representation for the vertical profile

// start by defining a gradient curve composed of the vertical curve segments and associated with the horizontal composite curve

auto gradient_curve = new Schema::IfcGradientCurve(vertical_curve_segments, false, composite_curve, nullptr);

file.addEntity(gradient_curve);

// the gradient curve is a representation item

typename aggregate_of<typename Schema::IfcRepresentationItem>::ptr profile_representation_items(new aggregate_of<typename Schema::IfcRepresentationItem>());

profile_representation_items->push(gradient_curve);

// create the axis representation

auto axis3d_shape_representation = new Schema::IfcShapeRepresentation(axis_model_representation_subcontext, std::string("Axis"), std::string("Curve3D"), profile_representation_items);

file.addEntity(axis3d_shape_representation);

// create axis representations for each segment

create_segment_representations(file, global_placement, axis_model_representation_subcontext, horizontal_curve_segments, horizontal_segments);

create_segment_representations(file, global_placement, axis_model_representation_subcontext, vertical_curve_segments, vertical_segments);

// Create the IfcAlignment

// the alignment has two representations, a plan view footprint and a 3d curve

typename aggregate_of<typename Schema::IfcRepresentation>::ptr alignment_representations(new aggregate_of<typename Schema::IfcRepresentation>());

alignment_representations->push(footprint_shape_representation); // 2D footprint

alignment_representations->push(axis3d_shape_representation); // 3D curve

// create the alignment product definition

auto alignment_product = new Schema::IfcProductDefinitionShape(std::string("Alignment Product Definition Shape"), boost::none, alignment_representations);

// create the alignment

auto alignment = new Schema::IfcAlignment(IfcParse::IfcGlobalId(), nullptr, std::string("Example Alignment"), boost::none, boost::none, global_placement, alignment_product, boost::none);

file.addEntity(alignment);

// Nest the IfcAlignmentHorizontal and IfcAlignmentVertical with the IfcAlignment to complete the business logic

// 4.1.4.4.1 Alignments nest horizontal and vertical layouts

// https://standards.buildingsmart.org/IFC/RELEASE/IFC4_3/HTML/concepts/Object_Composition/Nesting/Alignment_Layouts/content.html

typename aggregate_of<typename Schema::IfcObjectDefinition>::ptr alignment_layout_list(new aggregate_of<typename Schema::IfcObjectDefinition>());

alignment_layout_list->push(horizontal_alignment);

alignment_layout_list->push(vertical_profile);

auto nests_alignment_layouts = new Schema::IfcRelNests(IfcParse::IfcGlobalId(), nullptr, std::string("Nest horizontal and vertical alignment layouts with the alignment"), boost::none, alignment, alignment_layout_list);

file.addEntity(nests_alignment_layouts);

// Define the relationship with the project

// IFC 4.1.4.1.1 "Every IfcAlignment must be related to IfcProject using the IfcRelAggregates relationship"

// https://standards.buildingsmart.org/IFC/RELEASE/IFC4_3/HTML/concepts/Object_Composition/Aggregation/Alignment_Aggregation_To_Project/content.html

// IfcProject <-> IfcRelAggregates <-> IfcAlignment

typename aggregate_of<typename Schema::IfcObjectDefinition>::ptr list_of_alignments_in_project(new aggregate_of<typename Schema::IfcObjectDefinition>());

list_of_alignments_in_project->push(alignment);

auto aggregate_alignments_with_project = new Schema::IfcRelAggregates(IfcParse::IfcGlobalId(), nullptr, std::string("Alignments in project"), boost::none, project, list_of_alignments_in_project);

file.addEntity(aggregate_alignments_with_project);

// Define the spatial structure of the alignment with respect to the site

// IFC 4.1.5.1 alignment is referenced in spatial structure of an IfcSpatialElement. In this case IfcSite is the highest level IfcSpatialElement

// https://standards.buildingsmart.org/IFC/RELEASE/IFC4_3/HTML/concepts/Object_Connectivity/Alignment_Spatial_Reference/content.html

// IfcSite <-> IfcRelReferencedInSpatialStructure <-> IfcAlignment

// This means IfcAlignment is not part of the IfcSite (it is not an aggregate component) but instead IfcAlignment is used within

// the IfcSite by reference. This implies an IfcAlignment can traverse many IfcSite instances within an IfcProject

typename Schema::IfcSpatialReferenceSelect::list::ptr list_alignments_referenced_in_site(new Schema::IfcSpatialReferenceSelect::list);

list_alignments_referenced_in_site->push(alignment);

// this alignment traverse 3 bridge sites.

for (int i = 1; i <= 3; i++) {

std::ostringstream os;

os << "Site of Bridge " << i;

auto site = file.addSite(project, nullptr);

site->setName(os.str());

std::ostringstream description;

description << "Alignments referenced into the spatial structure of Bridge Site " << i;

auto rel_referenced_in_spatial_structure = new Schema::IfcRelReferencedInSpatialStructure(IfcParse::IfcGlobalId(), nullptr, boost::none, description.str(), list_alignments_referenced_in_site, site);

file.addEntity(rel_referenced_in_spatial_structure);

}

// That's it - save the model to a file

std::ofstream ofs("IfcAlignment.ifc");

ofs << file;

}

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