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IFC: introduce new namespace fpr IFC-schema2x3

pull/1707/head
Kim Kulling 2018-01-13 10:27:45 +01:00
parent abb09cc1d8
commit cecab969c6
26 changed files with 24651 additions and 630 deletions
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36
code/CMakeLists.txt
View File

@ -457,24 +457,23 @@ ADD_ASSIMP_IMPORTER( BLEND
) )
ADD_ASSIMP_IMPORTER( IFC ADD_ASSIMP_IMPORTER( IFC
IFCLoader.cpp Importer/IFC/IFCLoader.cpp
IFCLoader.h Importer/IFC/IFCLoader.h
IFCReaderGen1.cpp Importer/IFC/IFCReaderGen1_2x3.cpp
IFCReaderGen2.cpp Importer/IFC/IFCReaderGen2_2x3.cpp
IFCReaderGen.h Importer/IFC/IFCReaderGen_2x3.h
IFCUtil.h Importer/IFC/IFCUtil.h
IFCUtil.cpp Importer/IFC/IFCUtil.cpp
IFCGeometry.cpp Importer/IFC/IFCGeometry.cpp
IFCMaterial.cpp Importer/IFC/IFCMaterial.cpp
IFCProfile.cpp Importer/IFC/IFCProfile.cpp
IFCCurve.cpp Importer/IFC/IFCCurve.cpp
IFCBoolean.cpp Importer/IFC/IFCBoolean.cpp
IFCOpenings.cpp Importer/IFC/IFCOpenings.cpp
STEPFile.h Importer/IFC/STEPFileReader.h
STEPFileReader.h Importer/IFC/STEPFileReader.cpp
STEPFileReader.cpp Importer/IFC/STEPFileEncoding.cpp
STEPFileEncoding.cpp Importer/IFC/STEPFileEncoding.h
STEPFileEncoding.h
) )
if (ASSIMP_BUILD_IFC_IMPORTER) if (ASSIMP_BUILD_IFC_IMPORTER)
if (MSVC) if (MSVC)
@ -695,6 +694,7 @@ ADD_ASSIMP_IMPORTER( MMD
) )
SET( Step_SRCS SET( Step_SRCS
STEPFile.h
StepExporter.h StepExporter.h
StepExporter.cpp StepExporter.cpp
) )

88
code/IFCBoolean.cpp → code/Importer/IFC/IFCBoolean.cpp
View File

@ -42,17 +42,15 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
* @brief Implements a subset of Ifc boolean operations * @brief Implements a subset of Ifc boolean operations
*/ */
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
#include "IFCUtil.h" #include "Code/Importer/IFC/IFCUtil.h"
#include "PolyTools.h" #include "code/PolyTools.h"
#include "ProcessHelper.h" #include "code/ProcessHelper.h"
#include <assimp/Defines.h> #include <assimp/Defines.h>
#include <iterator> #include <iterator>
#include <tuple> #include <tuple>
namespace Assimp { namespace Assimp {
namespace IFC { namespace IFC {
@ -131,20 +129,20 @@ void WritePolygon(std::vector<IfcVector3>& resultpoly, TempMesh& result)
if( resultpoly.size() > 2 ) if( resultpoly.size() > 2 )
{ {
result.verts.insert(result.verts.end(), resultpoly.begin(), resultpoly.end()); result.mVerts.insert(result.mVerts.end(), resultpoly.begin(), resultpoly.end());
result.vertcnt.push_back(static_cast<unsigned int>(resultpoly.size())); result.mVertcnt.push_back(static_cast<unsigned int>(resultpoly.size()));
} }
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessBooleanHalfSpaceDifference(const IfcHalfSpaceSolid* hs, TempMesh& result, void ProcessBooleanHalfSpaceDifference(const Schema_2x3::IfcHalfSpaceSolid* hs, TempMesh& result,
const TempMesh& first_operand, const TempMesh& first_operand,
ConversionData& /*conv*/) ConversionData& /*conv*/)
{ {
ai_assert(hs != NULL); ai_assert(hs != NULL);
const IfcPlane* const plane = hs->BaseSurface->ToPtr<IfcPlane>(); const Schema_2x3::IfcPlane* const plane = hs->BaseSurface->ToPtr<Schema_2x3::IfcPlane>();
if(!plane) { if(!plane) {
IFCImporter::LogError("expected IfcPlane as base surface for the IfcHalfSpaceSolid"); IFCImporter::LogError("expected IfcPlane as base surface for the IfcHalfSpaceSolid");
return; return;
@ -162,14 +160,14 @@ void ProcessBooleanHalfSpaceDifference(const IfcHalfSpaceSolid* hs, TempMesh& re
} }
// clip the current contents of `meshout` against the plane we obtained from the second operand // clip the current contents of `meshout` against the plane we obtained from the second operand
const std::vector<IfcVector3>& in = first_operand.verts; const std::vector<IfcVector3>& in = first_operand.mVerts;
std::vector<IfcVector3>& outvert = result.verts; std::vector<IfcVector3>& outvert = result.mVerts;
std::vector<unsigned int>::const_iterator begin = first_operand.vertcnt.begin(), std::vector<unsigned int>::const_iterator begin = first_operand.mVertcnt.begin(),
end = first_operand.vertcnt.end(), iit; end = first_operand.mVertcnt.end(), iit;
outvert.reserve(in.size()); outvert.reserve(in.size());
result.vertcnt.reserve(first_operand.vertcnt.size()); result.mVertcnt.reserve(first_operand.mVertcnt.size());
unsigned int vidx = 0; unsigned int vidx = 0;
for(iit = begin; iit != end; vidx += *iit++) { for(iit = begin; iit != end; vidx += *iit++) {
@ -229,10 +227,10 @@ void ProcessBooleanHalfSpaceDifference(const IfcHalfSpaceSolid* hs, TempMesh& re
--newcount; --newcount;
} }
if(newcount > 2) { if(newcount > 2) {
result.vertcnt.push_back(newcount); result.mVertcnt.push_back(newcount);
} }
else while(newcount-->0) { else while(newcount-->0) {
result.verts.pop_back(); result.mVerts.pop_back();
} }
} }
@ -386,13 +384,13 @@ bool PointInPoly(const IfcVector3& p, const std::vector<IfcVector3>& boundary)
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBoundedHalfSpace* hs, TempMesh& result, void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const Schema_2x3::IfcPolygonalBoundedHalfSpace* hs, TempMesh& result,
const TempMesh& first_operand, const TempMesh& first_operand,
ConversionData& conv) ConversionData& conv)
{ {
ai_assert(hs != NULL); ai_assert(hs != NULL);
const IfcPlane* const plane = hs->BaseSurface->ToPtr<IfcPlane>(); const Schema_2x3::IfcPlane* const plane = hs->BaseSurface->ToPtr<Schema_2x3::IfcPlane>();
if(!plane) { if(!plane) {
IFCImporter::LogError("expected IfcPlane as base surface for the IfcHalfSpaceSolid"); IFCImporter::LogError("expected IfcPlane as base surface for the IfcHalfSpaceSolid");
return; return;
@ -419,7 +417,7 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBounded
} }
// determine winding order by calculating the normal. // determine winding order by calculating the normal.
IfcVector3 profileNormal = TempMesh::ComputePolygonNormal(profile->verts.data(), profile->verts.size()); IfcVector3 profileNormal = TempMesh::ComputePolygonNormal(profile->mVerts.data(), profile->mVerts.size());
IfcMatrix4 proj_inv; IfcMatrix4 proj_inv;
ConvertAxisPlacement(proj_inv,hs->Position); ConvertAxisPlacement(proj_inv,hs->Position);
@ -430,16 +428,16 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBounded
proj.Inverse(); proj.Inverse();
// clip the current contents of `meshout` against the plane we obtained from the second operand // clip the current contents of `meshout` against the plane we obtained from the second operand
const std::vector<IfcVector3>& in = first_operand.verts; const std::vector<IfcVector3>& in = first_operand.mVerts;
std::vector<IfcVector3>& outvert = result.verts; std::vector<IfcVector3>& outvert = result.mVerts;
std::vector<unsigned int>& outvertcnt = result.vertcnt; std::vector<unsigned int>& outvertcnt = result.mVertcnt;
outvert.reserve(in.size()); outvert.reserve(in.size());
outvertcnt.reserve(first_operand.vertcnt.size()); outvertcnt.reserve(first_operand.mVertcnt.size());
unsigned int vidx = 0; unsigned int vidx = 0;
std::vector<unsigned int>::const_iterator begin = first_operand.vertcnt.begin(); std::vector<unsigned int>::const_iterator begin = first_operand.mVertcnt.begin();
std::vector<unsigned int>::const_iterator end = first_operand.vertcnt.end(); std::vector<unsigned int>::const_iterator end = first_operand.mVertcnt.end();
std::vector<unsigned int>::const_iterator iit; std::vector<unsigned int>::const_iterator iit;
for( iit = begin; iit != end; vidx += *iit++ ) for( iit = begin; iit != end; vidx += *iit++ )
{ {
@ -510,7 +508,7 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBounded
{ {
// poly edge index, intersection point, edge index in boundary poly // poly edge index, intersection point, edge index in boundary poly
std::vector<std::tuple<size_t, IfcVector3, size_t> > intersections; std::vector<std::tuple<size_t, IfcVector3, size_t> > intersections;
bool startedInside = PointInPoly(proj * blackside.front(), profile->verts); bool startedInside = PointInPoly(proj * blackside.front(), profile->mVerts);
bool isCurrentlyInside = startedInside; bool isCurrentlyInside = startedInside;
std::vector<std::pair<size_t, IfcVector3> > intersected_boundary; std::vector<std::pair<size_t, IfcVector3> > intersected_boundary;
@ -521,7 +519,7 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBounded
const IfcVector3 e1 = proj * blackside[(a + 1) % blackside.size()]; const IfcVector3 e1 = proj * blackside[(a + 1) % blackside.size()];
intersected_boundary.clear(); intersected_boundary.clear();
IntersectsBoundaryProfile(e0, e1, profile->verts, isCurrentlyInside, intersected_boundary); IntersectsBoundaryProfile(e0, e1, profile->mVerts, isCurrentlyInside, intersected_boundary);
// sort the hits by distance from e0 to get the correct in/out/in sequence. Manually :-( I miss you, C++11. // sort the hits by distance from e0 to get the correct in/out/in sequence. Manually :-( I miss you, C++11.
if( intersected_boundary.size() > 1 ) if( intersected_boundary.size() > 1 )
{ {
@ -634,17 +632,17 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBounded
// generate segments along the boundary polygon that lie in the poly's plane until we hit another intersection // generate segments along the boundary polygon that lie in the poly's plane until we hit another intersection
IfcVector3 startingPoint = proj * std::get<1>(nextintsec); IfcVector3 startingPoint = proj * std::get<1>(nextintsec);
size_t currentBoundaryEdgeIdx = (std::get<2>(nextintsec) + (marchBackwardsOnBoundary ? 1 : 0)) % profile->verts.size(); size_t currentBoundaryEdgeIdx = (std::get<2>(nextintsec) + (marchBackwardsOnBoundary ? 1 : 0)) % profile->mVerts.size();
size_t nextIntsecIdx = SIZE_MAX; size_t nextIntsecIdx = SIZE_MAX;
while( nextIntsecIdx == SIZE_MAX ) while( nextIntsecIdx == SIZE_MAX )
{ {
IfcFloat t = 1e10; IfcFloat t = 1e10;
size_t nextBoundaryEdgeIdx = marchBackwardsOnBoundary ? (currentBoundaryEdgeIdx + profile->verts.size() - 1) : currentBoundaryEdgeIdx + 1; size_t nextBoundaryEdgeIdx = marchBackwardsOnBoundary ? (currentBoundaryEdgeIdx + profile->mVerts.size() - 1) : currentBoundaryEdgeIdx + 1;
nextBoundaryEdgeIdx %= profile->verts.size(); nextBoundaryEdgeIdx %= profile->mVerts.size();
// vertices of the current boundary segments // vertices of the current boundary segments
IfcVector3 currBoundaryPoint = profile->verts[currentBoundaryEdgeIdx]; IfcVector3 currBoundaryPoint = profile->mVerts[currentBoundaryEdgeIdx];
IfcVector3 nextBoundaryPoint = profile->verts[nextBoundaryEdgeIdx]; IfcVector3 nextBoundaryPoint = profile->mVerts[nextBoundaryEdgeIdx];
// project the two onto the polygon // project the two onto the polygon
if( std::abs(polyNormal.z) > 1e-5 ) if( std::abs(polyNormal.z) > 1e-5 )
{ {
@ -693,7 +691,7 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBounded
} }
// quick endless loop check // quick endless loop check
if( resultpoly.size() > blackside.size() + profile->verts.size() ) if( resultpoly.size() > blackside.size() + profile->mVerts.size() )
{ {
IFCImporter::LogError("Encountered endless loop while clipping polygon against poly-bounded half space."); IFCImporter::LogError("Encountered endless loop while clipping polygon against poly-bounded half space.");
break; break;
@ -718,7 +716,7 @@ void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBounded
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessBooleanExtrudedAreaSolidDifference(const IfcExtrudedAreaSolid* as, TempMesh& result, void ProcessBooleanExtrudedAreaSolidDifference(const Schema_2x3::IfcExtrudedAreaSolid* as, TempMesh& result,
const TempMesh& first_operand, const TempMesh& first_operand,
ConversionData& conv) ConversionData& conv)
{ {
@ -738,12 +736,12 @@ void ProcessBooleanExtrudedAreaSolidDifference(const IfcExtrudedAreaSolid* as, T
TempMesh temp; TempMesh temp;
std::vector<IfcVector3>::const_iterator vit = first_operand.verts.begin(); std::vector<IfcVector3>::const_iterator vit = first_operand.mVerts.begin();
for(unsigned int pcount : first_operand.vertcnt) { for(unsigned int pcount : first_operand.mVertcnt) {
temp.Clear(); temp.Clear();
temp.verts.insert(temp.verts.end(), vit, vit + pcount); temp.mVerts.insert(temp.mVerts.end(), vit, vit + pcount);
temp.vertcnt.push_back(pcount); temp.mVertcnt.push_back(pcount);
// The algorithms used to generate mesh geometry sometimes // The algorithms used to generate mesh geometry sometimes
// spit out lines or other degenerates which must be // spit out lines or other degenerates which must be
@ -767,11 +765,11 @@ void ProcessBooleanExtrudedAreaSolidDifference(const IfcExtrudedAreaSolid* as, T
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessBoolean(const IfcBooleanResult& boolean, TempMesh& result, ConversionData& conv) void ProcessBoolean(const Schema_2x3::IfcBooleanResult& boolean, TempMesh& result, ConversionData& conv)
{ {
// supported CSG operations: // supported CSG operations:
// DIFFERENCE // DIFFERENCE
if(const IfcBooleanResult* const clip = boolean.ToPtr<IfcBooleanResult>()) { if(const Schema_2x3::IfcBooleanResult* const clip = boolean.ToPtr<Schema_2x3::IfcBooleanResult>()) {
if(clip->Operator != "DIFFERENCE") { if(clip->Operator != "DIFFERENCE") {
IFCImporter::LogWarn("encountered unsupported boolean operator: " + (std::string)clip->Operator); IFCImporter::LogWarn("encountered unsupported boolean operator: " + (std::string)clip->Operator);
return; return;
@ -786,18 +784,18 @@ void ProcessBoolean(const IfcBooleanResult& boolean, TempMesh& result, Conversio
// IfcExtrudedAreaSolid -- reduce to an instance of the quadrify() algorithm // IfcExtrudedAreaSolid -- reduce to an instance of the quadrify() algorithm
const IfcHalfSpaceSolid* const hs = clip->SecondOperand->ResolveSelectPtr<IfcHalfSpaceSolid>(conv.db); const Schema_2x3::IfcHalfSpaceSolid* const hs = clip->SecondOperand->ResolveSelectPtr<Schema_2x3::IfcHalfSpaceSolid>(conv.db);
const IfcExtrudedAreaSolid* const as = clip->SecondOperand->ResolveSelectPtr<IfcExtrudedAreaSolid>(conv.db); const Schema_2x3::IfcExtrudedAreaSolid* const as = clip->SecondOperand->ResolveSelectPtr<Schema_2x3::IfcExtrudedAreaSolid>(conv.db);
if(!hs && !as) { if(!hs && !as) {
IFCImporter::LogError("expected IfcHalfSpaceSolid or IfcExtrudedAreaSolid as second clipping operand"); IFCImporter::LogError("expected IfcHalfSpaceSolid or IfcExtrudedAreaSolid as second clipping operand");
return; return;
} }
TempMesh first_operand; TempMesh first_operand;
if(const IfcBooleanResult* const op0 = clip->FirstOperand->ResolveSelectPtr<IfcBooleanResult>(conv.db)) { if(const Schema_2x3::IfcBooleanResult* const op0 = clip->FirstOperand->ResolveSelectPtr<Schema_2x3::IfcBooleanResult>(conv.db)) {
ProcessBoolean(*op0,first_operand,conv); ProcessBoolean(*op0,first_operand,conv);
} }
else if (const IfcSweptAreaSolid* const swept = clip->FirstOperand->ResolveSelectPtr<IfcSweptAreaSolid>(conv.db)) { else if (const Schema_2x3::IfcSweptAreaSolid* const swept = clip->FirstOperand->ResolveSelectPtr<Schema_2x3::IfcSweptAreaSolid>(conv.db)) {
ProcessSweptAreaSolid(*swept,first_operand,conv); ProcessSweptAreaSolid(*swept,first_operand,conv);
} }
else { else {
@ -807,7 +805,7 @@ void ProcessBoolean(const IfcBooleanResult& boolean, TempMesh& result, Conversio
if(hs) { if(hs) {
const IfcPolygonalBoundedHalfSpace* const hs_bounded = clip->SecondOperand->ResolveSelectPtr<IfcPolygonalBoundedHalfSpace>(conv.db); const Schema_2x3::IfcPolygonalBoundedHalfSpace* const hs_bounded = clip->SecondOperand->ResolveSelectPtr<Schema_2x3::IfcPolygonalBoundedHalfSpace>(conv.db);
if (hs_bounded) { if (hs_bounded) {
ProcessPolygonalBoundedBooleanHalfSpaceDifference(hs_bounded, result, first_operand, conv); ProcessPolygonalBoundedBooleanHalfSpaceDifference(hs_bounded, result, first_operand, conv);
} }

69
code/IFCCurve.cpp → code/Importer/IFC/IFCCurve.cpp
View File

@ -57,7 +57,7 @@ namespace {
class Conic : public Curve { class Conic : public Curve {
public: public:
// -------------------------------------------------- // --------------------------------------------------
Conic(const IfcConic& entity, ConversionData& conv) Conic(const Schema_2x3::IfcConic& entity, ConversionData& conv)
: Curve(entity,conv) { : Curve(entity,conv) {
IfcMatrix4 trafo; IfcMatrix4 trafo;
ConvertAxisPlacement(trafo,*entity.Position,conv); ConvertAxisPlacement(trafo,*entity.Position,conv);
@ -103,7 +103,7 @@ protected:
class Circle : public Conic { class Circle : public Conic {
public: public:
// -------------------------------------------------- // --------------------------------------------------
Circle(const IfcCircle& entity, ConversionData& conv) Circle(const Schema_2x3::IfcCircle& entity, ConversionData& conv)
: Conic(entity,conv) : Conic(entity,conv)
, entity(entity) , entity(entity)
{ {
@ -117,17 +117,16 @@ public:
} }
private: private:
const IfcCircle& entity; const Schema_2x3::IfcCircle& entity;
}; };
// -------------------------------------------------------------------------------- // --------------------------------------------------------------------------------
// Ellipse // Ellipse
// -------------------------------------------------------------------------------- // --------------------------------------------------------------------------------
class Ellipse : public Conic { class Ellipse : public Conic {
public: public:
// -------------------------------------------------- // --------------------------------------------------
Ellipse(const IfcEllipse& entity, ConversionData& conv) Ellipse(const Schema_2x3::IfcEllipse& entity, ConversionData& conv)
: Conic(entity,conv) : Conic(entity,conv)
, entity(entity) { , entity(entity) {
// empty // empty
@ -141,7 +140,7 @@ public:
} }
private: private:
const IfcEllipse& entity; const Schema_2x3::IfcEllipse& entity;
}; };
// -------------------------------------------------------------------------------- // --------------------------------------------------------------------------------
@ -150,7 +149,7 @@ private:
class Line : public Curve { class Line : public Curve {
public: public:
// -------------------------------------------------- // --------------------------------------------------
Line(const IfcLine& entity, ConversionData& conv) Line(const Schema_2x3::IfcLine& entity, ConversionData& conv)
: Curve(entity,conv) { : Curve(entity,conv) {
ConvertCartesianPoint(p,entity.Pnt); ConvertCartesianPoint(p,entity.Pnt);
ConvertVector(v,entity.Dir); ConvertVector(v,entity.Dir);
@ -181,12 +180,12 @@ public:
ai_assert( InRange( b ) ); ai_assert( InRange( b ) );
if (a == b) { if (a == b) {
out.verts.push_back(Eval(a)); out.mVerts.push_back(Eval(a));
return; return;
} }
out.verts.reserve(out.verts.size()+2); out.mVerts.reserve(out.mVerts.size()+2);
out.verts.push_back(Eval(a)); out.mVerts.push_back(Eval(a));
out.verts.push_back(Eval(b)); out.mVerts.push_back(Eval(b));
} }
// -------------------------------------------------- // --------------------------------------------------
@ -208,11 +207,11 @@ class CompositeCurve : public BoundedCurve {
public: public:
// -------------------------------------------------- // --------------------------------------------------
CompositeCurve(const IfcCompositeCurve& entity, ConversionData& conv) CompositeCurve(const Schema_2x3::IfcCompositeCurve& entity, ConversionData& conv)
: BoundedCurve(entity,conv) : BoundedCurve(entity,conv)
, total() { , total() {
curves.reserve(entity.Segments.size()); curves.reserve(entity.Segments.size());
for(const IfcCompositeCurveSegment& curveSegment :entity.Segments) { for(const Schema_2x3::IfcCompositeCurveSegment& curveSegment :entity.Segments) {
// according to the specification, this must be a bounded curve // according to the specification, this must be a bounded curve
std::shared_ptr< Curve > cv(Curve::Convert(curveSegment.ParentCurve,conv)); std::shared_ptr< Curve > cv(Curve::Convert(curveSegment.ParentCurve,conv));
std::shared_ptr< BoundedCurve > bc = std::dynamic_pointer_cast<BoundedCurve>(cv); std::shared_ptr< BoundedCurve > bc = std::dynamic_pointer_cast<BoundedCurve>(cv);
@ -282,14 +281,14 @@ public:
ai_assert( InRange( b ) ); ai_assert( InRange( b ) );
const size_t cnt = EstimateSampleCount(a,b); const size_t cnt = EstimateSampleCount(a,b);
out.verts.reserve(out.verts.size() + cnt); out.mVerts.reserve(out.mVerts.size() + cnt);
for(const CurveEntry& entry : curves) { for(const CurveEntry& entry : curves) {
const size_t cnt = out.verts.size(); const size_t cnt = out.mVerts.size();
entry.first->SampleDiscrete(out); entry.first->SampleDiscrete(out);
if (!entry.second && cnt != out.verts.size()) { if (!entry.second && cnt != out.mVerts.size()) {
std::reverse(out.verts.begin()+cnt,out.verts.end()); std::reverse(out.mVerts.begin()+cnt,out.mVerts.end());
} }
} }
} }
@ -310,7 +309,7 @@ private:
class TrimmedCurve : public BoundedCurve { class TrimmedCurve : public BoundedCurve {
public: public:
// -------------------------------------------------- // --------------------------------------------------
TrimmedCurve(const IfcTrimmedCurve& entity, ConversionData& conv) TrimmedCurve(const Schema_2x3::IfcTrimmedCurve& entity, ConversionData& conv)
: BoundedCurve(entity,conv) : BoundedCurve(entity,conv)
{ {
base = std::shared_ptr<const Curve>(Curve::Convert(entity.BasisCurve,conv)); base = std::shared_ptr<const Curve>(Curve::Convert(entity.BasisCurve,conv));
@ -325,12 +324,12 @@ public:
bool have_param = false, have_point = false; bool have_param = false, have_point = false;
IfcVector3 point; IfcVector3 point;
for(const Entry sel :entity.Trim1) { for(const Entry sel :entity.Trim1) {
if (const EXPRESS::REAL* const r = sel->ToPtr<EXPRESS::REAL>()) { if (const ::Assimp::STEP::EXPRESS::REAL* const r = sel->ToPtr<::Assimp::STEP::EXPRESS::REAL>()) {
range.first = *r; range.first = *r;
have_param = true; have_param = true;
break; break;
} }
else if (const IfcCartesianPoint* const r = sel->ResolveSelectPtr<IfcCartesianPoint>(conv.db)) { else if (const Schema_2x3::IfcCartesianPoint* const r = sel->ResolveSelectPtr<Schema_2x3::IfcCartesianPoint>(conv.db)) {
ConvertCartesianPoint(point,*r); ConvertCartesianPoint(point,*r);
have_point = true; have_point = true;
} }
@ -342,12 +341,12 @@ public:
} }
have_param = false, have_point = false; have_param = false, have_point = false;
for(const Entry sel :entity.Trim2) { for(const Entry sel :entity.Trim2) {
if (const EXPRESS::REAL* const r = sel->ToPtr<EXPRESS::REAL>()) { if (const ::Assimp::STEP::EXPRESS::REAL* const r = sel->ToPtr<::Assimp::STEP::EXPRESS::REAL>()) {
range.second = *r; range.second = *r;
have_param = true; have_param = true;
break; break;
} }
else if (const IfcCartesianPoint* const r = sel->ResolveSelectPtr<IfcCartesianPoint>(conv.db)) { else if (const Schema_2x3::IfcCartesianPoint* const r = sel->ResolveSelectPtr<Schema_2x3::IfcCartesianPoint>(conv.db)) {
ConvertCartesianPoint(point,*r); ConvertCartesianPoint(point,*r);
have_point = true; have_point = true;
} }
@ -420,13 +419,13 @@ private:
class PolyLine : public BoundedCurve { class PolyLine : public BoundedCurve {
public: public:
// -------------------------------------------------- // --------------------------------------------------
PolyLine(const IfcPolyline& entity, ConversionData& conv) PolyLine(const Schema_2x3::IfcPolyline& entity, ConversionData& conv)
: BoundedCurve(entity,conv) : BoundedCurve(entity,conv)
{ {
points.reserve(entity.Points.size()); points.reserve(entity.Points.size());
IfcVector3 t; IfcVector3 t;
for(const IfcCartesianPoint& cp : entity.Points) { for(const Schema_2x3::IfcCartesianPoint& cp : entity.Points) {
ConvertCartesianPoint(t,cp); ConvertCartesianPoint(t,cp);
points.push_back(t); points.push_back(t);
} }
@ -463,29 +462,29 @@ private:
} // anon } // anon
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
Curve* Curve::Convert(const IFC::IfcCurve& curve,ConversionData& conv) { Curve* Curve::Convert(const IFC::Schema_2x3::IfcCurve& curve,ConversionData& conv) {
if(curve.ToPtr<IfcBoundedCurve>()) { if(curve.ToPtr<Schema_2x3::IfcBoundedCurve>()) {
if(const IfcPolyline* c = curve.ToPtr<IfcPolyline>()) { if(const Schema_2x3::IfcPolyline* c = curve.ToPtr<Schema_2x3::IfcPolyline>()) {
return new PolyLine(*c,conv); return new PolyLine(*c,conv);
} }
if(const IfcTrimmedCurve* c = curve.ToPtr<IfcTrimmedCurve>()) { if(const Schema_2x3::IfcTrimmedCurve* c = curve.ToPtr<Schema_2x3::IfcTrimmedCurve>()) {
return new TrimmedCurve(*c,conv); return new TrimmedCurve(*c,conv);
} }
if(const IfcCompositeCurve* c = curve.ToPtr<IfcCompositeCurve>()) { if(const Schema_2x3::IfcCompositeCurve* c = curve.ToPtr<Schema_2x3::IfcCompositeCurve>()) {
return new CompositeCurve(*c,conv); return new CompositeCurve(*c,conv);
} }
} }
if(curve.ToPtr<IfcConic>()) { if(curve.ToPtr<Schema_2x3::IfcConic>()) {
if(const IfcCircle* c = curve.ToPtr<IfcCircle>()) { if(const Schema_2x3::IfcCircle* c = curve.ToPtr<Schema_2x3::IfcCircle>()) {
return new Circle(*c,conv); return new Circle(*c,conv);
} }
if(const IfcEllipse* c = curve.ToPtr<IfcEllipse>()) { if(const Schema_2x3::IfcEllipse* c = curve.ToPtr<Schema_2x3::IfcEllipse>()) {
return new Ellipse(*c,conv); return new Ellipse(*c,conv);
} }
} }
if(const IfcLine* c = curve.ToPtr<IfcLine>()) { if(const Schema_2x3::IfcLine* c = curve.ToPtr<Schema_2x3::IfcLine>()) {
return new Line(*c,conv); return new Line(*c,conv);
} }
@ -589,11 +588,11 @@ void Curve::SampleDiscrete(TempMesh& out,IfcFloat a, IfcFloat b) const {
ai_assert( InRange( b ) ); ai_assert( InRange( b ) );
const size_t cnt = std::max(static_cast<size_t>(0),EstimateSampleCount(a,b)); const size_t cnt = std::max(static_cast<size_t>(0),EstimateSampleCount(a,b));
out.verts.reserve( out.verts.size() + cnt + 1); out.mVerts.reserve( out.mVerts.size() + cnt + 1);
IfcFloat p = a, delta = (b-a)/cnt; IfcFloat p = a, delta = (b-a)/cnt;
for(size_t i = 0; i <= cnt; ++i, p += delta) { for(size_t i = 0; i <= cnt; ++i, p += delta) {
out.verts.push_back(Eval(p)); out.mVerts.push_back(Eval(p));
} }
} }

186
code/IFCGeometry.cpp → code/Importer/IFC/IFCGeometry.cpp
View File

@ -46,8 +46,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
#include "IFCUtil.h" #include "IFCUtil.h"
#include "PolyTools.h" #include "code/PolyTools.h"
#include "ProcessHelper.h" #include "code/ProcessHelper.h"
#include "../contrib/poly2tri/poly2tri/poly2tri.h" #include "../contrib/poly2tri/poly2tri/poly2tri.h"
#include "../contrib/clipper/clipper.hpp" #include "../contrib/clipper/clipper.hpp"
@ -59,27 +59,27 @@ namespace Assimp {
namespace IFC { namespace IFC {
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool ProcessPolyloop(const IfcPolyLoop& loop, TempMesh& meshout, ConversionData& /*conv*/) bool ProcessPolyloop(const Schema_2x3::IfcPolyLoop& loop, TempMesh& meshout, ConversionData& /*conv*/)
{ {
size_t cnt = 0; size_t cnt = 0;
for(const IfcCartesianPoint& c : loop.Polygon) { for(const Schema_2x3::IfcCartesianPoint& c : loop.Polygon) {
IfcVector3 tmp; IfcVector3 tmp;
ConvertCartesianPoint(tmp,c); ConvertCartesianPoint(tmp,c);
meshout.verts.push_back(tmp); meshout.mVerts.push_back(tmp);
++cnt; ++cnt;
} }
meshout.vertcnt.push_back(static_cast<unsigned int>(cnt)); meshout.mVertcnt.push_back(static_cast<unsigned int>(cnt));
// zero- or one- vertex polyloops simply ignored // zero- or one- vertex polyloops simply ignored
if (meshout.vertcnt.back() > 1) { if (meshout.mVertcnt.back() > 1) {
return true; return true;
} }
if (meshout.vertcnt.back()==1) { if (meshout.mVertcnt.back()==1) {
meshout.vertcnt.pop_back(); meshout.mVertcnt.pop_back();
meshout.verts.pop_back(); meshout.mVerts.pop_back();
} }
return false; return false;
} }
@ -88,19 +88,19 @@ bool ProcessPolyloop(const IfcPolyLoop& loop, TempMesh& meshout, ConversionData&
void ProcessPolygonBoundaries(TempMesh& result, const TempMesh& inmesh, size_t master_bounds = (size_t)-1) void ProcessPolygonBoundaries(TempMesh& result, const TempMesh& inmesh, size_t master_bounds = (size_t)-1)
{ {
// handle all trivial cases // handle all trivial cases
if(inmesh.vertcnt.empty()) { if(inmesh.mVertcnt.empty()) {
return; return;
} }
if(inmesh.vertcnt.size() == 1) { if(inmesh.mVertcnt.size() == 1) {
result.Append(inmesh); result.Append(inmesh);
return; return;
} }
ai_assert(std::count(inmesh.vertcnt.begin(), inmesh.vertcnt.end(), 0) == 0); ai_assert(std::count(inmesh.mVertcnt.begin(), inmesh.mVertcnt.end(), 0) == 0);
typedef std::vector<unsigned int>::const_iterator face_iter; typedef std::vector<unsigned int>::const_iterator face_iter;
face_iter begin = inmesh.vertcnt.begin(), end = inmesh.vertcnt.end(), iit; face_iter begin = inmesh.mVertcnt.begin(), end = inmesh.mVertcnt.end(), iit;
std::vector<unsigned int>::const_iterator outer_polygon_it = end; std::vector<unsigned int>::const_iterator outer_polygon_it = end;
// major task here: given a list of nested polygon boundaries (one of which // major task here: given a list of nested polygon boundaries (one of which
@ -119,7 +119,7 @@ void ProcessPolygonBoundaries(TempMesh& result, const TempMesh& inmesh, size_t m
// shall be of the type IfcFaceOuterBound' // shall be of the type IfcFaceOuterBound'
IfcFloat area_outer_polygon = 1e-10f; IfcFloat area_outer_polygon = 1e-10f;
if (master_bounds != (size_t)-1) { if (master_bounds != (size_t)-1) {
ai_assert(master_bounds < inmesh.vertcnt.size()); ai_assert(master_bounds < inmesh.mVertcnt.size());
outer_polygon_it = begin + master_bounds; outer_polygon_it = begin + master_bounds;
} }
else { else {
@ -146,9 +146,9 @@ void ProcessPolygonBoundaries(TempMesh& result, const TempMesh& inmesh, size_t m
// this is the plane onto which the quadrulate algorithm will // this is the plane onto which the quadrulate algorithm will
// project the entire mesh. // project the entire mesh.
std::vector<TempOpening> fake_openings; std::vector<TempOpening> fake_openings;
fake_openings.reserve(inmesh.vertcnt.size()-1); fake_openings.reserve(inmesh.mVertcnt.size()-1);
std::vector<IfcVector3>::const_iterator vit = inmesh.verts.begin(), outer_vit; std::vector<IfcVector3>::const_iterator vit = inmesh.mVerts.begin(), outer_vit;
for(iit = begin; iit != end; vit += *iit++) { for(iit = begin; iit != end; vit += *iit++) {
if (iit == outer_polygon_it) { if (iit == outer_polygon_it) {
@ -171,32 +171,32 @@ void ProcessPolygonBoundaries(TempMesh& result, const TempMesh& inmesh, size_t m
opening.solid = NULL; opening.solid = NULL;
opening.profileMesh = std::make_shared<TempMesh>(); opening.profileMesh = std::make_shared<TempMesh>();
opening.profileMesh->verts.reserve(*iit); opening.profileMesh->mVerts.reserve(*iit);
opening.profileMesh->vertcnt.push_back(*iit); opening.profileMesh->mVertcnt.push_back(*iit);
std::copy(vit, vit + *iit, std::back_inserter(opening.profileMesh->verts)); std::copy(vit, vit + *iit, std::back_inserter(opening.profileMesh->mVerts));
} }
// fill a mesh with ONLY the main polygon // fill a mesh with ONLY the main polygon
TempMesh temp; TempMesh temp;
temp.verts.reserve(outer_polygon_size); temp.mVerts.reserve(outer_polygon_size);
temp.vertcnt.push_back(static_cast<unsigned int>(outer_polygon_size)); temp.mVertcnt.push_back(static_cast<unsigned int>(outer_polygon_size));
std::copy(outer_vit, outer_vit+outer_polygon_size, std::copy(outer_vit, outer_vit+outer_polygon_size,
std::back_inserter(temp.verts)); std::back_inserter(temp.mVerts));
GenerateOpenings(fake_openings, normals, temp, false, false); GenerateOpenings(fake_openings, normals, temp, false, false);
result.Append(temp); result.Append(temp);
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessConnectedFaceSet(const IfcConnectedFaceSet& fset, TempMesh& result, ConversionData& conv) void ProcessConnectedFaceSet(const Schema_2x3::IfcConnectedFaceSet& fset, TempMesh& result, ConversionData& conv)
{ {
for(const IfcFace& face : fset.CfsFaces) { for(const Schema_2x3::IfcFace& face : fset.CfsFaces) {
// size_t ob = -1, cnt = 0; // size_t ob = -1, cnt = 0;
TempMesh meshout; TempMesh meshout;
for(const IfcFaceBound& bound : face.Bounds) { for(const Schema_2x3::IfcFaceBound& bound : face.Bounds) {
if(const IfcPolyLoop* const polyloop = bound.Bound->ToPtr<IfcPolyLoop>()) { if(const Schema_2x3::IfcPolyLoop* const polyloop = bound.Bound->ToPtr<Schema_2x3::IfcPolyLoop>()) {
if(ProcessPolyloop(*polyloop, meshout,conv)) { if(ProcessPolyloop(*polyloop, meshout,conv)) {
// The outer boundary is better determined by checking which // The outer boundary is better determined by checking which
@ -230,12 +230,12 @@ void ProcessConnectedFaceSet(const IfcConnectedFaceSet& fset, TempMesh& result,
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessRevolvedAreaSolid(const IfcRevolvedAreaSolid& solid, TempMesh& result, ConversionData& conv) void ProcessRevolvedAreaSolid(const Schema_2x3::IfcRevolvedAreaSolid& solid, TempMesh& result, ConversionData& conv)
{ {
TempMesh meshout; TempMesh meshout;
// first read the profile description // first read the profile description
if(!ProcessProfile(*solid.SweptArea,meshout,conv) || meshout.verts.size()<=1) { if(!ProcessProfile(*solid.SweptArea,meshout,conv) || meshout.mVerts.size()<=1) {
return; return;
} }
@ -246,7 +246,7 @@ void ProcessRevolvedAreaSolid(const IfcRevolvedAreaSolid& solid, TempMesh& resul
IfcMatrix4::Translation(pos,tb0); IfcMatrix4::Translation(pos,tb0);
IfcMatrix4::Translation(-pos,tb1); IfcMatrix4::Translation(-pos,tb1);
const std::vector<IfcVector3>& in = meshout.verts; const std::vector<IfcVector3>& in = meshout.mVerts;
const size_t size=in.size(); const size_t size=in.size();
bool has_area = solid.SweptArea->ProfileType == "AREA" && size>2; bool has_area = solid.SweptArea->ProfileType == "AREA" && size>2;
@ -263,14 +263,14 @@ void ProcessRevolvedAreaSolid(const IfcRevolvedAreaSolid& solid, TempMesh& resul
has_area = has_area && std::fabs(max_angle) < AI_MATH_TWO_PI_F*0.99; has_area = has_area && std::fabs(max_angle) < AI_MATH_TWO_PI_F*0.99;
result.verts.reserve(size*((cnt_segments+1)*4+(has_area?2:0))); result.mVerts.reserve(size*((cnt_segments+1)*4+(has_area?2:0)));
result.vertcnt.reserve(size*cnt_segments+2); result.mVertcnt.reserve(size*cnt_segments+2);
IfcMatrix4 rot; IfcMatrix4 rot;
rot = tb0 * IfcMatrix4::Rotation(delta,axis,rot) * tb1; rot = tb0 * IfcMatrix4::Rotation(delta,axis,rot) * tb1;
size_t base = 0; size_t base = 0;
std::vector<IfcVector3>& out = result.verts; std::vector<IfcVector3>& out = result.mVerts;
// dummy data to simplify later processing // dummy data to simplify later processing
for(size_t i = 0; i < size; ++i) { for(size_t i = 0; i < size; ++i) {
@ -281,7 +281,7 @@ void ProcessRevolvedAreaSolid(const IfcRevolvedAreaSolid& solid, TempMesh& resul
for(size_t i = 0; i < size; ++i) { for(size_t i = 0; i < size; ++i) {
const size_t next = (i+1)%size; const size_t next = (i+1)%size;
result.vertcnt.push_back(4); result.mVertcnt.push_back(4);
const IfcVector3 base_0 = out[base+i*4+3],base_1 = out[base+next*4+3]; const IfcVector3 base_0 = out[base+i*4+3],base_1 = out[base+next*4+3];
out.push_back(base_0); out.push_back(base_0);
@ -305,8 +305,8 @@ void ProcessRevolvedAreaSolid(const IfcRevolvedAreaSolid& solid, TempMesh& resul
for(size_t i = 0; i < size; ++i ) { for(size_t i = 0; i < size; ++i ) {
out.push_back(out[i*4]); out.push_back(out[i*4]);
} }
result.vertcnt.push_back(static_cast<unsigned int>(size)); result.mVertcnt.push_back(static_cast<unsigned int>(size));
result.vertcnt.push_back(static_cast<unsigned int>(size)); result.mVertcnt.push_back(static_cast<unsigned int>(size));
} }
IfcMatrix4 trafo; IfcMatrix4 trafo;
@ -316,10 +316,8 @@ void ProcessRevolvedAreaSolid(const IfcRevolvedAreaSolid& solid, TempMesh& resul
IFCImporter::LogDebug("generate mesh procedurally by radial extrusion (IfcRevolvedAreaSolid)"); IFCImporter::LogDebug("generate mesh procedurally by radial extrusion (IfcRevolvedAreaSolid)");
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessSweptDiskSolid(const IfcSweptDiskSolid solid, TempMesh& result, ConversionData& conv) void ProcessSweptDiskSolid(const Schema_2x3::IfcSweptDiskSolid solid, TempMesh& result, ConversionData& conv)
{ {
const Curve* const curve = Curve::Convert(*solid.Directrix, conv); const Curve* const curve = Curve::Convert(*solid.Directrix, conv);
if(!curve) { if(!curve) {
@ -332,12 +330,12 @@ void ProcessSweptDiskSolid(const IfcSweptDiskSolid solid, TempMesh& result, Conv
TempMesh temp; TempMesh temp;
curve->SampleDiscrete(temp, solid.StartParam, solid.EndParam); curve->SampleDiscrete(temp, solid.StartParam, solid.EndParam);
const std::vector<IfcVector3>& curve_points = temp.verts; const std::vector<IfcVector3>& curve_points = temp.mVerts;
const size_t samples = curve_points.size(); const size_t samples = curve_points.size();
result.verts.reserve(cnt_segments * samples * 4); result.mVerts.reserve(cnt_segments * samples * 4);
result.vertcnt.reserve((cnt_segments - 1) * samples); result.mVertcnt.reserve((cnt_segments - 1) * samples);
std::vector<IfcVector3> points; std::vector<IfcVector3> points;
points.reserve(cnt_segments * samples); points.reserve(cnt_segments * samples);
@ -434,22 +432,22 @@ void ProcessSweptDiskSolid(const IfcSweptDiskSolid solid, TempMesh& result, Conv
for (unsigned int seg = 0; seg < cnt_segments; ++seg) { for (unsigned int seg = 0; seg < cnt_segments; ++seg) {
result.verts.push_back(points[ i * cnt_segments + (seg % cnt_segments)]); result.mVerts.push_back(points[ i * cnt_segments + (seg % cnt_segments)]);
result.verts.push_back(points[ i * cnt_segments + (seg + 1) % cnt_segments]); result.mVerts.push_back(points[ i * cnt_segments + (seg + 1) % cnt_segments]);
result.verts.push_back(points[ (i+1) * cnt_segments + ((seg + 1 + best_pair_offset) % cnt_segments)]); result.mVerts.push_back(points[ (i+1) * cnt_segments + ((seg + 1 + best_pair_offset) % cnt_segments)]);
result.verts.push_back(points[ (i+1) * cnt_segments + ((seg + best_pair_offset) % cnt_segments)]); result.mVerts.push_back(points[ (i+1) * cnt_segments + ((seg + best_pair_offset) % cnt_segments)]);
IfcVector3& v1 = *(result.verts.end()-1); IfcVector3& v1 = *(result.mVerts.end()-1);
IfcVector3& v2 = *(result.verts.end()-2); IfcVector3& v2 = *(result.mVerts.end()-2);
IfcVector3& v3 = *(result.verts.end()-3); IfcVector3& v3 = *(result.mVerts.end()-3);
IfcVector3& v4 = *(result.verts.end()-4); IfcVector3& v4 = *(result.mVerts.end()-4);
if (((v4-v3) ^ (v4-v1)) * (v4 - curve_points[i]) < 0.0f) { if (((v4-v3) ^ (v4-v1)) * (v4 - curve_points[i]) < 0.0f) {
std::swap(v4, v1); std::swap(v4, v1);
std::swap(v3, v2); std::swap(v3, v2);
} }
result.vertcnt.push_back(4); result.mVertcnt.push_back(4);
} }
} }
@ -459,14 +457,15 @@ void ProcessSweptDiskSolid(const IfcSweptDiskSolid solid, TempMesh& result, Conv
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
IfcMatrix3 DerivePlaneCoordinateSpace(const TempMesh& curmesh, bool& ok, IfcVector3& norOut) IfcMatrix3 DerivePlaneCoordinateSpace(const TempMesh& curmesh, bool& ok, IfcVector3& norOut)
{ {
const std::vector<IfcVector3>& out = curmesh.verts; const std::vector<IfcVector3>& out = curmesh.mVerts;
IfcMatrix3 m; IfcMatrix3 m;
ok = true; ok = true;
// The input "mesh" must be a single polygon // The input "mesh" must be a single polygon
const size_t s = out.size(); const size_t s = out.size();
assert(curmesh.vertcnt.size() == 1 && curmesh.vertcnt.back() == s); ai_assert( curmesh.mVertcnt.size() == 1 );
ai_assert( curmesh.mVertcnt.back() == s);
const IfcVector3 any_point = out[s-1]; const IfcVector3 any_point = out[s-1];
IfcVector3 nor; IfcVector3 nor;
@ -477,9 +476,10 @@ IfcMatrix3 DerivePlaneCoordinateSpace(const TempMesh& curmesh, bool& ok, IfcVect
// axis for the 2D coordinate space on the polygon plane, exploiting the // axis for the 2D coordinate space on the polygon plane, exploiting the
// fact that the input polygon is nearly always a quad. // fact that the input polygon is nearly always a quad.
bool done = false; bool done = false;
size_t i, j; size_t idx( 0 );
for (i = 0; !done && i < s-2; done || ++i) { for (size_t i = 0; !done && i < s-2; done || ++i) {
for (j = i+1; j < s-1; ++j) { idx = i;
for (size_t j = i+1; j < s-1; ++j) {
nor = -((out[i]-any_point)^(out[j]-any_point)); nor = -((out[i]-any_point)^(out[j]-any_point));
if(std::fabs(nor.Length()) > 1e-8f) { if(std::fabs(nor.Length()) > 1e-8f) {
done = true; done = true;
@ -496,7 +496,7 @@ IfcMatrix3 DerivePlaneCoordinateSpace(const TempMesh& curmesh, bool& ok, IfcVect
nor.Normalize(); nor.Normalize();
norOut = nor; norOut = nor;
IfcVector3 r = (out[i]-any_point); IfcVector3 r = (out[idx]-any_point);
r.Normalize(); r.Normalize();
//if(d) { //if(d) {
@ -524,12 +524,12 @@ IfcMatrix3 DerivePlaneCoordinateSpace(const TempMesh& curmesh, bool& ok, IfcVect
} }
// Extrudes the given polygon along the direction, converts it into an opening or applies all openings as necessary. // Extrudes the given polygon along the direction, converts it into an opening or applies all openings as necessary.
void ProcessExtrudedArea(const IfcExtrudedAreaSolid& solid, const TempMesh& curve, void ProcessExtrudedArea(const Schema_2x3::IfcExtrudedAreaSolid& solid, const TempMesh& curve,
const IfcVector3& extrusionDir, TempMesh& result, ConversionData &conv, bool collect_openings) const IfcVector3& extrusionDir, TempMesh& result, ConversionData &conv, bool collect_openings)
{ {
// Outline: 'curve' is now a list of vertex points forming the underlying profile, extrude along the given axis, // Outline: 'curve' is now a list of vertex points forming the underlying profile, extrude along the given axis,
// forming new triangles. // forming new triangles.
const bool has_area = solid.SweptArea->ProfileType == "AREA" && curve.verts.size() > 2; const bool has_area = solid.SweptArea->ProfileType == "AREA" && curve.mVerts.size() > 2;
if( solid.Depth < 1e-6 ) { if( solid.Depth < 1e-6 ) {
if( has_area ) { if( has_area ) {
result.Append(curve); result.Append(curve);
@ -537,9 +537,9 @@ void ProcessExtrudedArea(const IfcExtrudedAreaSolid& solid, const TempMesh& curv
return; return;
} }
result.verts.reserve(curve.verts.size()*(has_area ? 4 : 2)); result.mVerts.reserve(curve.mVerts.size()*(has_area ? 4 : 2));
result.vertcnt.reserve(curve.verts.size() + 2); result.mVertcnt.reserve(curve.mVerts.size() + 2);
std::vector<IfcVector3> in = curve.verts; std::vector<IfcVector3> in = curve.mVerts;
// First step: transform all vertices into the target coordinate space // First step: transform all vertices into the target coordinate space
IfcMatrix4 trafo; IfcMatrix4 trafo;
@ -582,24 +582,24 @@ void ProcessExtrudedArea(const IfcExtrudedAreaSolid& solid, const TempMesh& curv
for(TempOpening& t : *conv.apply_openings) { for(TempOpening& t : *conv.apply_openings) {
TempMesh& bounds = *t.profileMesh.get(); TempMesh& bounds = *t.profileMesh.get();
if( bounds.verts.size() <= 2 ) { if( bounds.mVerts.size() <= 2 ) {
nors.push_back(IfcVector3()); nors.push_back(IfcVector3());
continue; continue;
} }
nors.push_back(((bounds.verts[2] - bounds.verts[0]) ^ (bounds.verts[1] - bounds.verts[0])).Normalize()); nors.push_back(((bounds.mVerts[2] - bounds.mVerts[0]) ^ (bounds.mVerts[1] - bounds.mVerts[0])).Normalize());
} }
} }
TempMesh temp; TempMesh temp;
TempMesh& curmesh = openings ? temp : result; TempMesh& curmesh = openings ? temp : result;
std::vector<IfcVector3>& out = curmesh.verts; std::vector<IfcVector3>& out = curmesh.mVerts;
size_t sides_with_openings = 0; size_t sides_with_openings = 0;
for( size_t i = 0; i < in.size(); ++i ) { for( size_t i = 0; i < in.size(); ++i ) {
const size_t next = (i + 1) % in.size(); const size_t next = (i + 1) % in.size();
curmesh.vertcnt.push_back(4); curmesh.mVertcnt.push_back(4);
out.push_back(in[i]); out.push_back(in[i]);
out.push_back(in[next]); out.push_back(in[next]);
@ -638,7 +638,7 @@ void ProcessExtrudedArea(const IfcExtrudedAreaSolid& solid, const TempMesh& curv
out.push_back(in[i]); out.push_back(in[i]);
} }
curmesh.vertcnt.push_back(static_cast<unsigned int>(in.size())); curmesh.mVertcnt.push_back(static_cast<unsigned int>(in.size()));
if( openings && in.size() > 2 ) { if( openings && in.size() > 2 ) {
if( GenerateOpenings(*conv.apply_openings, nors, temp, true, true, dir) ) { if( GenerateOpenings(*conv.apply_openings, nors, temp, true, true, dir) ) {
++sides_with_v_openings; ++sides_with_v_openings;
@ -664,8 +664,8 @@ void ProcessExtrudedArea(const IfcExtrudedAreaSolid& solid, const TempMesh& curv
profile->Swap(result); profile->Swap(result);
std::shared_ptr<TempMesh> profile2D = std::shared_ptr<TempMesh>(new TempMesh()); std::shared_ptr<TempMesh> profile2D = std::shared_ptr<TempMesh>(new TempMesh());
profile2D->verts.insert(profile2D->verts.end(), in.begin(), in.end()); profile2D->mVerts.insert(profile2D->mVerts.end(), in.begin(), in.end());
profile2D->vertcnt.push_back(static_cast<unsigned int>(in.size())); profile2D->mVertcnt.push_back(static_cast<unsigned int>(in.size()));
conv.collect_openings->push_back(TempOpening(&solid, dir, profile, profile2D)); conv.collect_openings->push_back(TempOpening(&solid, dir, profile, profile2D));
ai_assert(result.IsEmpty()); ai_assert(result.IsEmpty());
@ -673,13 +673,13 @@ void ProcessExtrudedArea(const IfcExtrudedAreaSolid& solid, const TempMesh& curv
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessExtrudedAreaSolid(const IfcExtrudedAreaSolid& solid, TempMesh& result, void ProcessExtrudedAreaSolid(const Schema_2x3::IfcExtrudedAreaSolid& solid, TempMesh& result,
ConversionData& conv, bool collect_openings) ConversionData& conv, bool collect_openings)
{ {
TempMesh meshout; TempMesh meshout;
// First read the profile description. // First read the profile description.
if(!ProcessProfile(*solid.SweptArea,meshout,conv) || meshout.verts.size()<=1) { if(!ProcessProfile(*solid.SweptArea,meshout,conv) || meshout.mVerts.size()<=1) {
return; return;
} }
@ -691,13 +691,13 @@ void ProcessExtrudedAreaSolid(const IfcExtrudedAreaSolid& solid, TempMesh& resul
// and there's still so many corner cases uncovered - we really need a generic solution to all of this hole carving. // and there's still so many corner cases uncovered - we really need a generic solution to all of this hole carving.
std::vector<TempOpening> fisherPriceMyFirstOpenings; std::vector<TempOpening> fisherPriceMyFirstOpenings;
std::vector<TempOpening>* oldApplyOpenings = conv.apply_openings; std::vector<TempOpening>* oldApplyOpenings = conv.apply_openings;
if( const IfcArbitraryProfileDefWithVoids* const cprofile = solid.SweptArea->ToPtr<IfcArbitraryProfileDefWithVoids>() ) { if( const Schema_2x3::IfcArbitraryProfileDefWithVoids* const cprofile = solid.SweptArea->ToPtr<Schema_2x3::IfcArbitraryProfileDefWithVoids>() ) {
if( !cprofile->InnerCurves.empty() ) { if( !cprofile->InnerCurves.empty() ) {
// read all inner curves and extrude them to form proper openings. // read all inner curves and extrude them to form proper openings.
std::vector<TempOpening>* oldCollectOpenings = conv.collect_openings; std::vector<TempOpening>* oldCollectOpenings = conv.collect_openings;
conv.collect_openings = &fisherPriceMyFirstOpenings; conv.collect_openings = &fisherPriceMyFirstOpenings;
for(const IfcCurve* curve : cprofile->InnerCurves) { for (const Schema_2x3::IfcCurve* curve : cprofile->InnerCurves) {
TempMesh curveMesh, tempMesh; TempMesh curveMesh, tempMesh;
ProcessCurve(*curve, curveMesh, conv); ProcessCurve(*curve, curveMesh, conv);
ProcessExtrudedArea(solid, curveMesh, dir, tempMesh, conv, true); ProcessExtrudedArea(solid, curveMesh, dir, tempMesh, conv, true);
@ -713,13 +713,13 @@ void ProcessExtrudedAreaSolid(const IfcExtrudedAreaSolid& solid, TempMesh& resul
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessSweptAreaSolid(const IfcSweptAreaSolid& swept, TempMesh& meshout, void ProcessSweptAreaSolid(const Schema_2x3::IfcSweptAreaSolid& swept, TempMesh& meshout,
ConversionData& conv) ConversionData& conv)
{ {
if(const IfcExtrudedAreaSolid* const solid = swept.ToPtr<IfcExtrudedAreaSolid>()) { if(const Schema_2x3::IfcExtrudedAreaSolid* const solid = swept.ToPtr<Schema_2x3::IfcExtrudedAreaSolid>()) {
ProcessExtrudedAreaSolid(*solid,meshout,conv, !!conv.collect_openings); ProcessExtrudedAreaSolid(*solid,meshout,conv, !!conv.collect_openings);
} }
else if(const IfcRevolvedAreaSolid* const rev = swept.ToPtr<IfcRevolvedAreaSolid>()) { else if(const Schema_2x3::IfcRevolvedAreaSolid* const rev = swept.ToPtr<Schema_2x3::IfcRevolvedAreaSolid>()) {
ProcessRevolvedAreaSolid(*rev,meshout,conv); ProcessRevolvedAreaSolid(*rev,meshout,conv);
} }
else { else {
@ -728,16 +728,16 @@ void ProcessSweptAreaSolid(const IfcSweptAreaSolid& swept, TempMesh& meshout,
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool ProcessGeometricItem(const IfcRepresentationItem& geo, unsigned int matid, std::vector<unsigned int>& mesh_indices, bool ProcessGeometricItem(const Schema_2x3::IfcRepresentationItem& geo, unsigned int matid, std::vector<unsigned int>& mesh_indices,
ConversionData& conv) ConversionData& conv)
{ {
bool fix_orientation = false; bool fix_orientation = false;
std::shared_ptr< TempMesh > meshtmp = std::make_shared<TempMesh>(); std::shared_ptr< TempMesh > meshtmp = std::make_shared<TempMesh>();
if(const IfcShellBasedSurfaceModel* shellmod = geo.ToPtr<IfcShellBasedSurfaceModel>()) { if(const Schema_2x3::IfcShellBasedSurfaceModel* shellmod = geo.ToPtr<Schema_2x3::IfcShellBasedSurfaceModel>()) {
for(std::shared_ptr<const IfcShell> shell :shellmod->SbsmBoundary) { for(std::shared_ptr<const Schema_2x3::IfcShell> shell :shellmod->SbsmBoundary) {
try { try {
const EXPRESS::ENTITY& e = shell->To<ENTITY>(); const ::Assimp::STEP::EXPRESS::ENTITY& e = shell->To<::Assimp::STEP::EXPRESS::ENTITY>();
const IfcConnectedFaceSet& fs = conv.db.MustGetObject(e).To<IfcConnectedFaceSet>(); const Schema_2x3::IfcConnectedFaceSet& fs = conv.db.MustGetObject(e).To<Schema_2x3::IfcConnectedFaceSet>();
ProcessConnectedFaceSet(fs,*meshtmp.get(),conv); ProcessConnectedFaceSet(fs,*meshtmp.get(),conv);
} }
@ -747,30 +747,30 @@ bool ProcessGeometricItem(const IfcRepresentationItem& geo, unsigned int matid,
} }
fix_orientation = true; fix_orientation = true;
} }
else if(const IfcConnectedFaceSet* fset = geo.ToPtr<IfcConnectedFaceSet>()) { else if(const Schema_2x3::IfcConnectedFaceSet* fset = geo.ToPtr<Schema_2x3::IfcConnectedFaceSet>()) {
ProcessConnectedFaceSet(*fset,*meshtmp.get(),conv); ProcessConnectedFaceSet(*fset,*meshtmp.get(),conv);
fix_orientation = true; fix_orientation = true;
} }
else if(const IfcSweptAreaSolid* swept = geo.ToPtr<IfcSweptAreaSolid>()) { else if(const Schema_2x3::IfcSweptAreaSolid* swept = geo.ToPtr<Schema_2x3::IfcSweptAreaSolid>()) {
ProcessSweptAreaSolid(*swept,*meshtmp.get(),conv); ProcessSweptAreaSolid(*swept,*meshtmp.get(),conv);
} }
else if(const IfcSweptDiskSolid* disk = geo.ToPtr<IfcSweptDiskSolid>()) { else if(const Schema_2x3::IfcSweptDiskSolid* disk = geo.ToPtr<Schema_2x3::IfcSweptDiskSolid>()) {
ProcessSweptDiskSolid(*disk,*meshtmp.get(),conv); ProcessSweptDiskSolid(*disk,*meshtmp.get(),conv);
} }
else if(const IfcManifoldSolidBrep* brep = geo.ToPtr<IfcManifoldSolidBrep>()) { else if(const Schema_2x3::IfcManifoldSolidBrep* brep = geo.ToPtr<Schema_2x3::IfcManifoldSolidBrep>()) {
ProcessConnectedFaceSet(brep->Outer,*meshtmp.get(),conv); ProcessConnectedFaceSet(brep->Outer,*meshtmp.get(),conv);
fix_orientation = true; fix_orientation = true;
} }
else if(const IfcFaceBasedSurfaceModel* surf = geo.ToPtr<IfcFaceBasedSurfaceModel>()) { else if(const Schema_2x3::IfcFaceBasedSurfaceModel* surf = geo.ToPtr<Schema_2x3::IfcFaceBasedSurfaceModel>()) {
for(const IfcConnectedFaceSet& fc : surf->FbsmFaces) { for(const Schema_2x3::IfcConnectedFaceSet& fc : surf->FbsmFaces) {
ProcessConnectedFaceSet(fc,*meshtmp.get(),conv); ProcessConnectedFaceSet(fc,*meshtmp.get(),conv);
} }
fix_orientation = true; fix_orientation = true;
} }
else if(const IfcBooleanResult* boolean = geo.ToPtr<IfcBooleanResult>()) { else if(const Schema_2x3::IfcBooleanResult* boolean = geo.ToPtr<Schema_2x3::IfcBooleanResult>()) {
ProcessBoolean(*boolean,*meshtmp.get(),conv); ProcessBoolean(*boolean,*meshtmp.get(),conv);
} }
else if(geo.ToPtr<IfcBoundingBox>()) { else if(geo.ToPtr<Schema_2x3::IfcBoundingBox>()) {
// silently skip over bounding boxes // silently skip over bounding boxes
return false; return false;
} }
@ -788,7 +788,7 @@ bool ProcessGeometricItem(const IfcRepresentationItem& geo, unsigned int matid,
// which returns an empty mesh. // which returns an empty mesh.
if(conv.collect_openings) { if(conv.collect_openings) {
if (!meshtmp->IsEmpty()) { if (!meshtmp->IsEmpty()) {
conv.collect_openings->push_back(TempOpening(geo.ToPtr<IfcSolidModel>(), conv.collect_openings->push_back(TempOpening(geo.ToPtr<Schema_2x3::IfcSolidModel>(),
IfcVector3(0,0,0), IfcVector3(0,0,0),
meshtmp, meshtmp,
std::shared_ptr<TempMesh>())); std::shared_ptr<TempMesh>()));
@ -837,7 +837,7 @@ void AssignAddedMeshes(std::vector<unsigned int>& mesh_indices,aiNode* nd,
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool TryQueryMeshCache(const IfcRepresentationItem& item, bool TryQueryMeshCache(const Schema_2x3::IfcRepresentationItem& item,
std::vector<unsigned int>& mesh_indices, unsigned int mat_index, std::vector<unsigned int>& mesh_indices, unsigned int mat_index,
ConversionData& conv) ConversionData& conv)
{ {
@ -851,7 +851,7 @@ bool TryQueryMeshCache(const IfcRepresentationItem& item,
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void PopulateMeshCache(const IfcRepresentationItem& item, void PopulateMeshCache(const Schema_2x3::IfcRepresentationItem& item,
const std::vector<unsigned int>& mesh_indices, unsigned int mat_index, const std::vector<unsigned int>& mesh_indices, unsigned int mat_index,
ConversionData& conv) ConversionData& conv)
{ {
@ -860,7 +860,7 @@ void PopulateMeshCache(const IfcRepresentationItem& item,
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool ProcessRepresentationItem(const IfcRepresentationItem& item, unsigned int matid, bool ProcessRepresentationItem(const Schema_2x3::IfcRepresentationItem& item, unsigned int matid,
std::vector<unsigned int>& mesh_indices, std::vector<unsigned int>& mesh_indices,
ConversionData& conv) ConversionData& conv)
{ {

128
code/IFCLoader.cpp → code/Importer/IFC/IFCLoader.cpp
View File

@ -59,7 +59,7 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "IFCUtil.h" #include "IFCUtil.h"
#include "MemoryIOWrapper.h" #include "code/MemoryIOWrapper.h"
#include <assimp/scene.h> #include <assimp/scene.h>
#include <assimp/Importer.hpp> #include <assimp/Importer.hpp>
#include <assimp/importerdesc.h> #include <assimp/importerdesc.h>
@ -99,7 +99,7 @@ void SetUnits(ConversionData& conv);
void SetCoordinateSpace(ConversionData& conv); void SetCoordinateSpace(ConversionData& conv);
void ProcessSpatialStructures(ConversionData& conv); void ProcessSpatialStructures(ConversionData& conv);
void MakeTreeRelative(ConversionData& conv); void MakeTreeRelative(ConversionData& conv);
void ConvertUnit(const EXPRESS::DataType& dt,ConversionData& conv); void ConvertUnit(const ::Assimp::STEP::EXPRESS::DataType& dt,ConversionData& conv);
} // anon } // anon
@ -152,7 +152,6 @@ const aiImporterDesc* IFCImporter::GetInfo () const
return &desc; return &desc;
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
// Setup configuration properties for the loader // Setup configuration properties for the loader
void IFCImporter::SetupProperties(const Importer* pImp) void IFCImporter::SetupProperties(const Importer* pImp)
@ -167,8 +166,7 @@ void IFCImporter::SetupProperties(const Importer* pImp)
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
// Imports the given file into the given scene structure. // Imports the given file into the given scene structure.
void IFCImporter::InternReadFile( const std::string& pFile, void IFCImporter::InternReadFile( const std::string& pFile, aiScene* pScene, IOSystem* pIOHandler)
aiScene* pScene, IOSystem* pIOHandler)
{ {
std::shared_ptr<IOStream> stream(pIOHandler->Open(pFile)); std::shared_ptr<IOStream> stream(pIOHandler->Open(pFile));
if (!stream) { if (!stream) {
@ -253,8 +251,8 @@ void IFCImporter::InternReadFile( const std::string& pFile,
} }
// obtain a copy of the machine-generated IFC scheme // obtain a copy of the machine-generated IFC scheme
EXPRESS::ConversionSchema schema; ::Assimp::STEP::EXPRESS::ConversionSchema schema;
GetSchema(schema); Schema_2x3::GetSchema(schema);
// tell the reader which entity types to track with special care // tell the reader which entity types to track with special care
static const char* const types_to_track[] = { static const char* const types_to_track[] = {
@ -273,7 +271,7 @@ void IFCImporter::InternReadFile( const std::string& pFile,
ThrowException("missing IfcProject entity"); ThrowException("missing IfcProject entity");
} }
ConversionData conv(*db,proj->To<IfcProject>(),pScene,settings); ConversionData conv(*db,proj->To<Schema_2x3::IfcProject>(),pScene,settings);
SetUnits(conv); SetUnits(conv);
SetCoordinateSpace(conv); SetCoordinateSpace(conv);
ProcessSpatialStructures(conv); ProcessSpatialStructures(conv);
@ -323,10 +321,9 @@ namespace {
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertUnit(const IfcNamedUnit& unit,ConversionData& conv) void ConvertUnit(const Schema_2x3::IfcNamedUnit& unit,ConversionData& conv)
{ {
if(const IfcSIUnit* const si = unit.ToPtr<IfcSIUnit>()) { if(const Schema_2x3::IfcSIUnit* const si = unit.ToPtr<Schema_2x3::IfcSIUnit>()) {
if(si->UnitType == "LENGTHUNIT") { if(si->UnitType == "LENGTHUNIT") {
conv.len_scale = si->Prefix ? ConvertSIPrefix(si->Prefix) : 1.f; conv.len_scale = si->Prefix ? ConvertSIPrefix(si->Prefix) : 1.f;
IFCImporter::LogDebug("got units used for lengths"); IFCImporter::LogDebug("got units used for lengths");
@ -337,11 +334,10 @@ void ConvertUnit(const IfcNamedUnit& unit,ConversionData& conv)
} }
} }
} }
else if(const IfcConversionBasedUnit* const convu = unit.ToPtr<IfcConversionBasedUnit>()) { else if(const Schema_2x3::IfcConversionBasedUnit* const convu = unit.ToPtr<Schema_2x3::IfcConversionBasedUnit>()) {
if(convu->UnitType == "PLANEANGLEUNIT") { if(convu->UnitType == "PLANEANGLEUNIT") {
try { try {
conv.angle_scale = convu->ConversionFactor->ValueComponent->To<EXPRESS::REAL>(); conv.angle_scale = convu->ConversionFactor->ValueComponent->To<::Assimp::STEP::EXPRESS::REAL>();
ConvertUnit(*convu->ConversionFactor->UnitComponent,conv); ConvertUnit(*convu->ConversionFactor->UnitComponent,conv);
IFCImporter::LogDebug("got units used for angles"); IFCImporter::LogDebug("got units used for angles");
} }
@ -353,12 +349,12 @@ void ConvertUnit(const IfcNamedUnit& unit,ConversionData& conv)
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertUnit(const EXPRESS::DataType& dt,ConversionData& conv) void ConvertUnit(const ::Assimp::STEP::EXPRESS::DataType& dt,ConversionData& conv)
{ {
try { try {
const EXPRESS::ENTITY& e = dt.To<ENTITY>(); const ::Assimp::STEP::EXPRESS::ENTITY& e = dt.To<::Assimp::STEP::EXPRESS::ENTITY>();
const IfcNamedUnit& unit = e.ResolveSelect<IfcNamedUnit>(conv.db); const Schema_2x3::IfcNamedUnit& unit = e.ResolveSelect<Schema_2x3::IfcNamedUnit>(conv.db);
if(unit.UnitType != "LENGTHUNIT" && unit.UnitType != "PLANEANGLEUNIT") { if(unit.UnitType != "LENGTHUNIT" && unit.UnitType != "PLANEANGLEUNIT") {
return; return;
} }
@ -384,8 +380,8 @@ void SetUnits(ConversionData& conv)
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void SetCoordinateSpace(ConversionData& conv) void SetCoordinateSpace(ConversionData& conv)
{ {
const IfcRepresentationContext* fav = NULL; const Schema_2x3::IfcRepresentationContext* fav = NULL;
for(const IfcRepresentationContext& v : conv.proj.RepresentationContexts) { for(const Schema_2x3::IfcRepresentationContext& v : conv.proj.RepresentationContexts) {
fav = &v; fav = &v;
// Model should be the most suitable type of context, hence ignore the others // Model should be the most suitable type of context, hence ignore the others
if (v.ContextType && v.ContextType.Get() == "Model") { if (v.ContextType && v.ContextType.Get() == "Model") {
@ -393,7 +389,7 @@ void SetCoordinateSpace(ConversionData& conv)
} }
} }
if (fav) { if (fav) {
if(const IfcGeometricRepresentationContext* const geo = fav->ToPtr<IfcGeometricRepresentationContext>()) { if(const Schema_2x3::IfcGeometricRepresentationContext* const geo = fav->ToPtr<Schema_2x3::IfcGeometricRepresentationContext>()) {
ConvertAxisPlacement(conv.wcs, *geo->WorldCoordinateSystem, conv); ConvertAxisPlacement(conv.wcs, *geo->WorldCoordinateSystem, conv);
IFCImporter::LogDebug("got world coordinate system"); IFCImporter::LogDebug("got world coordinate system");
} }
@ -402,9 +398,9 @@ void SetCoordinateSpace(ConversionData& conv)
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ResolveObjectPlacement(aiMatrix4x4& m, const IfcObjectPlacement& place, ConversionData& conv) void ResolveObjectPlacement(aiMatrix4x4& m, const Schema_2x3::IfcObjectPlacement& place, ConversionData& conv)
{ {
if (const IfcLocalPlacement* const local = place.ToPtr<IfcLocalPlacement>()){ if (const Schema_2x3::IfcLocalPlacement* const local = place.ToPtr<Schema_2x3::IfcLocalPlacement>()){
IfcMatrix4 tmp; IfcMatrix4 tmp;
ConvertAxisPlacement(tmp, *local->RelativePlacement, conv); ConvertAxisPlacement(tmp, *local->RelativePlacement, conv);
@ -422,9 +418,9 @@ void ResolveObjectPlacement(aiMatrix4x4& m, const IfcObjectPlacement& place, Con
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool ProcessMappedItem(const IfcMappedItem& mapped, aiNode* nd_src, std::vector< aiNode* >& subnodes_src, unsigned int matid, ConversionData& conv) bool ProcessMappedItem(const Schema_2x3::IfcMappedItem& mapped, aiNode* nd_src, std::vector< aiNode* >& subnodes_src, unsigned int matid, ConversionData& conv)
{ {
// insert a custom node here, the cartesian transform operator is simply a conventional transformation matrix // insert a custom node here, the carthesian transform operator is simply a conventional transformation matrix
std::unique_ptr<aiNode> nd(new aiNode()); std::unique_ptr<aiNode> nd(new aiNode());
nd->mName.Set("IfcMappedItem"); nd->mName.Set("IfcMappedItem");
@ -448,10 +444,10 @@ bool ProcessMappedItem(const IfcMappedItem& mapped, aiNode* nd_src, std::vector<
} }
unsigned int localmatid = ProcessMaterials(mapped.GetID(),matid,conv,false); unsigned int localmatid = ProcessMaterials(mapped.GetID(),matid,conv,false);
const IfcRepresentation& repr = mapped.MappingSource->MappedRepresentation; const Schema_2x3::IfcRepresentation& repr = mapped.MappingSource->MappedRepresentation;
bool got = false; bool got = false;
for(const IfcRepresentationItem& item : repr.Items) { for(const Schema_2x3::IfcRepresentationItem& item : repr.Items) {
if(!ProcessRepresentationItem(item,localmatid,meshes,conv)) { if(!ProcessRepresentationItem(item,localmatid,meshes,conv)) {
IFCImporter::LogWarn("skipping mapped entity of type " + item.GetClassName() + ", no representations could be generated"); IFCImporter::LogWarn("skipping mapped entity of type " + item.GetClassName() + ", no representations could be generated");
} }
@ -483,8 +479,7 @@ bool ProcessMappedItem(const IfcMappedItem& mapped, aiNode* nd_src, std::vector<
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
struct RateRepresentationPredicate { struct RateRepresentationPredicate {
int Rate(const Schema_2x3::IfcRepresentation* r) const {
int Rate(const IfcRepresentation* r) const {
// the smaller, the better // the smaller, the better
if (! r->RepresentationIdentifier) { if (! r->RepresentationIdentifier) {
@ -497,7 +492,7 @@ struct RateRepresentationPredicate {
if (name == "MappedRepresentation") { if (name == "MappedRepresentation") {
if (!r->Items.empty()) { if (!r->Items.empty()) {
// take the first item and base our choice on it // take the first item and base our choice on it
const IfcMappedItem* const m = r->Items.front()->ToPtr<IfcMappedItem>(); const Schema_2x3::IfcMappedItem* const m = r->Items.front()->ToPtr<Schema_2x3::IfcMappedItem>();
if (m) { if (m) {
return Rate(m->MappingSource->MappedRepresentation); return Rate(m->MappingSource->MappedRepresentation);
} }
@ -509,8 +504,6 @@ struct RateRepresentationPredicate {
} }
int Rate(const std::string& r) const { int Rate(const std::string& r) const {
if (r == "SolidModel") { if (r == "SolidModel") {
return -3; return -3;
} }
@ -541,13 +534,13 @@ struct RateRepresentationPredicate {
return 0; return 0;
} }
bool operator() (const IfcRepresentation* a, const IfcRepresentation* b) const { bool operator() (const Schema_2x3::IfcRepresentation* a, const Schema_2x3::IfcRepresentation* b) const {
return Rate(a) < Rate(b); return Rate(a) < Rate(b);
} }
}; };
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessProductRepresentation(const IfcProduct& el, aiNode* nd, std::vector< aiNode* >& subnodes, ConversionData& conv) void ProcessProductRepresentation(const Schema_2x3::IfcProduct& el, aiNode* nd, std::vector< aiNode* >& subnodes, ConversionData& conv)
{ {
if(!el.Representation) { if(!el.Representation) {
return; return;
@ -562,14 +555,14 @@ void ProcessProductRepresentation(const IfcProduct& el, aiNode* nd, std::vector<
// representation is relatively generic and allows the concrete implementations // representation is relatively generic and allows the concrete implementations
// for the different representation types to make some sensible choices what // for the different representation types to make some sensible choices what
// to load and what not to load. // to load and what not to load.
const STEP::ListOf< STEP::Lazy< IfcRepresentation >, 1, 0 >& src = el.Representation.Get()->Representations; const STEP::ListOf< STEP::Lazy< Schema_2x3::IfcRepresentation >, 1, 0 >& src = el.Representation.Get()->Representations;
std::vector<const IfcRepresentation*> repr_ordered(src.size()); std::vector<const Schema_2x3::IfcRepresentation*> repr_ordered(src.size());
std::copy(src.begin(),src.end(),repr_ordered.begin()); std::copy(src.begin(),src.end(),repr_ordered.begin());
std::sort(repr_ordered.begin(),repr_ordered.end(),RateRepresentationPredicate()); std::sort(repr_ordered.begin(),repr_ordered.end(),RateRepresentationPredicate());
for(const IfcRepresentation* repr : repr_ordered) { for(const Schema_2x3::IfcRepresentation* repr : repr_ordered) {
bool res = false; bool res = false;
for(const IfcRepresentationItem& item : repr->Items) { for(const Schema_2x3::IfcRepresentationItem& item : repr->Items) {
if(const IfcMappedItem* const geo = item.ToPtr<IfcMappedItem>()) { if(const Schema_2x3::IfcMappedItem* const geo = item.ToPtr<Schema_2x3::IfcMappedItem>()) {
res = ProcessMappedItem(*geo,nd,subnodes,matid,conv) || res; res = ProcessMappedItem(*geo,nd,subnodes,matid,conv) || res;
} }
else { else {
@ -587,25 +580,25 @@ void ProcessProductRepresentation(const IfcProduct& el, aiNode* nd, std::vector<
typedef std::map<std::string, std::string> Metadata; typedef std::map<std::string, std::string> Metadata;
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessMetadata(const ListOf< Lazy< IfcProperty >, 1, 0 >& set, ConversionData& conv, Metadata& properties, void ProcessMetadata(const Schema_2x3::ListOf< Schema_2x3::Lazy< Schema_2x3::IfcProperty >, 1, 0 >& set, ConversionData& conv, Metadata& properties,
const std::string& prefix = "", const std::string& prefix = "",
unsigned int nest = 0) unsigned int nest = 0)
{ {
for(const IfcProperty& property : set) { for(const Schema_2x3::IfcProperty& property : set) {
const std::string& key = prefix.length() > 0 ? (prefix + "." + property.Name) : property.Name; const std::string& key = prefix.length() > 0 ? (prefix + "." + property.Name) : property.Name;
if (const IfcPropertySingleValue* const singleValue = property.ToPtr<IfcPropertySingleValue>()) { if (const Schema_2x3::IfcPropertySingleValue* const singleValue = property.ToPtr<Schema_2x3::IfcPropertySingleValue>()) {
if (singleValue->NominalValue) { if (singleValue->NominalValue) {
if (const EXPRESS::STRING* str = singleValue->NominalValue.Get()->ToPtr<EXPRESS::STRING>()) { if (const ::Assimp::STEP::EXPRESS::STRING* str = singleValue->NominalValue.Get()->ToPtr<::Assimp::STEP::EXPRESS::STRING>()) {
std::string value = static_cast<std::string>(*str); std::string value = static_cast<std::string>(*str);
properties[key]=value; properties[key]=value;
} }
else if (const EXPRESS::REAL* val = singleValue->NominalValue.Get()->ToPtr<EXPRESS::REAL>()) { else if (const ::Assimp::STEP::EXPRESS::REAL* val = singleValue->NominalValue.Get()->ToPtr<::Assimp::STEP::EXPRESS::REAL>()) {
float value = static_cast<float>(*val); float value = static_cast<float>(*val);
std::stringstream s; std::stringstream s;
s << value; s << value;
properties[key]=s.str(); properties[key]=s.str();
} }
else if (const EXPRESS::INTEGER* val = singleValue->NominalValue.Get()->ToPtr<EXPRESS::INTEGER>()) { else if (const ::Assimp::STEP::EXPRESS::INTEGER* val = singleValue->NominalValue.Get()->ToPtr<::Assimp::STEP::EXPRESS::INTEGER>()) {
int64_t value = static_cast<int64_t>(*val); int64_t value = static_cast<int64_t>(*val);
std::stringstream s; std::stringstream s;
s << value; s << value;
@ -613,21 +606,21 @@ void ProcessMetadata(const ListOf< Lazy< IfcProperty >, 1, 0 >& set, ConversionD
} }
} }
} }
else if (const IfcPropertyListValue* const listValue = property.ToPtr<IfcPropertyListValue>()) { else if (const Schema_2x3::IfcPropertyListValue* const listValue = property.ToPtr<Schema_2x3::IfcPropertyListValue>()) {
std::stringstream ss; std::stringstream ss;
ss << "["; ss << "[";
unsigned index=0; unsigned index=0;
for(const IfcValue::Out& v : listValue->ListValues) { for(const Schema_2x3::IfcValue::Out& v : listValue->ListValues) {
if (!v) continue; if (!v) continue;
if (const EXPRESS::STRING* str = v->ToPtr<EXPRESS::STRING>()) { if (const ::Assimp::STEP::EXPRESS::STRING* str = v->ToPtr<::Assimp::STEP::EXPRESS::STRING>()) {
std::string value = static_cast<std::string>(*str); std::string value = static_cast<std::string>(*str);
ss << "'" << value << "'"; ss << "'" << value << "'";
} }
else if (const EXPRESS::REAL* val = v->ToPtr<EXPRESS::REAL>()) { else if (const ::Assimp::STEP::EXPRESS::REAL* val = v->ToPtr<::Assimp::STEP::EXPRESS::REAL>()) {
float value = static_cast<float>(*val); float value = static_cast<float>(*val);
ss << value; ss << value;
} }
else if (const EXPRESS::INTEGER* val = v->ToPtr<EXPRESS::INTEGER>()) { else if (const ::Assimp::STEP::EXPRESS::INTEGER* val = v->ToPtr<::Assimp::STEP::EXPRESS::INTEGER>()) {
int64_t value = static_cast<int64_t>(*val); int64_t value = static_cast<int64_t>(*val);
ss << value; ss << value;
} }
@ -639,7 +632,7 @@ void ProcessMetadata(const ListOf< Lazy< IfcProperty >, 1, 0 >& set, ConversionD
ss << "]"; ss << "]";
properties[key]=ss.str(); properties[key]=ss.str();
} }
else if (const IfcComplexProperty* const complexProp = property.ToPtr<IfcComplexProperty>()) { else if (const Schema_2x3::IfcComplexProperty* const complexProp = property.ToPtr<Schema_2x3::IfcComplexProperty>()) {
if(nest > 2) { // mostly arbitrary limit to prevent stack overflow vulnerabilities if(nest > 2) { // mostly arbitrary limit to prevent stack overflow vulnerabilities
IFCImporter::LogError("maximum nesting level for IfcComplexProperty reached, skipping this property."); IFCImporter::LogError("maximum nesting level for IfcComplexProperty reached, skipping this property.");
} }
@ -657,29 +650,29 @@ void ProcessMetadata(const ListOf< Lazy< IfcProperty >, 1, 0 >& set, ConversionD
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessMetadata(uint64_t relDefinesByPropertiesID, ConversionData& conv, Metadata& properties) void ProcessMetadata(uint64_t relDefinesByPropertiesID, ConversionData& conv, Metadata& properties)
{ {
if (const IfcRelDefinesByProperties* const pset = conv.db.GetObject(relDefinesByPropertiesID)->ToPtr<IfcRelDefinesByProperties>()) { if (const Schema_2x3::IfcRelDefinesByProperties* const pset = conv.db.GetObject(relDefinesByPropertiesID)->ToPtr<Schema_2x3::IfcRelDefinesByProperties>()) {
if (const IfcPropertySet* const set = conv.db.GetObject(pset->RelatingPropertyDefinition->GetID())->ToPtr<IfcPropertySet>()) { if (const Schema_2x3::IfcPropertySet* const set = conv.db.GetObject(pset->RelatingPropertyDefinition->GetID())->ToPtr<Schema_2x3::IfcPropertySet>()) {
ProcessMetadata(set->HasProperties, conv, properties); ProcessMetadata(set->HasProperties, conv, properties);
} }
} }
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
aiNode* ProcessSpatialStructure(aiNode* parent, const IfcProduct& el, ConversionData& conv, std::vector<TempOpening>* collect_openings = NULL) aiNode* ProcessSpatialStructure(aiNode* parent, const Schema_2x3::IfcProduct& el, ConversionData& conv, std::vector<TempOpening>* collect_openings = NULL)
{ {
const STEP::DB::RefMap& refs = conv.db.GetRefs(); const STEP::DB::RefMap& refs = conv.db.GetRefs();
// skip over space and annotation nodes - usually, these have no meaning in Assimp's context // skip over space and annotation nodes - usually, these have no meaning in Assimp's context
bool skipGeometry = false; bool skipGeometry = false;
if(conv.settings.skipSpaceRepresentations) { if(conv.settings.skipSpaceRepresentations) {
if(el.ToPtr<IfcSpace>()) { if(el.ToPtr<Schema_2x3::IfcSpace>()) {
IFCImporter::LogDebug("skipping IfcSpace entity due to importer settings"); IFCImporter::LogDebug("skipping IfcSpace entity due to importer settings");
skipGeometry = true; skipGeometry = true;
} }
} }
if(conv.settings.skipAnnotations) { if(conv.settings.skipAnnotations) {
if(el.ToPtr<IfcAnnotation>()) { if(el.ToPtr<Schema_2x3::IfcAnnotation>()) {
IFCImporter::LogDebug("skipping IfcAnnotation entity due to importer settings"); IFCImporter::LogDebug("skipping IfcAnnotation entity due to importer settings");
return NULL; return NULL;
} }
@ -745,12 +738,12 @@ aiNode* ProcessSpatialStructure(aiNode* parent, const IfcProduct& el, Conversion
const STEP::LazyObject& obj = conv.db.MustGetObject((*range2.first).second); const STEP::LazyObject& obj = conv.db.MustGetObject((*range2.first).second);
// handle regularly-contained elements // handle regularly-contained elements
if(const IfcRelContainedInSpatialStructure* const cont = obj->ToPtr<IfcRelContainedInSpatialStructure>()) { if(const Schema_2x3::IfcRelContainedInSpatialStructure* const cont = obj->ToPtr<Schema_2x3::IfcRelContainedInSpatialStructure>()) {
if(cont->RelatingStructure->GetID() != el.GetID()) { if(cont->RelatingStructure->GetID() != el.GetID()) {
continue; continue;
} }
for(const IfcProduct& pro : cont->RelatedElements) { for(const Schema_2x3::IfcProduct& pro : cont->RelatedElements) {
if(pro.ToPtr<IfcOpeningElement>()) { if(pro.ToPtr<Schema_2x3::IfcOpeningElement>()) {
// IfcOpeningElement is handled below. Sadly we can't use it here as is: // IfcOpeningElement is handled below. Sadly we can't use it here as is:
// The docs say that opening elements are USUALLY attached to building storey, // The docs say that opening elements are USUALLY attached to building storey,
// but we want them for the building elements to which they belong. // but we want them for the building elements to which they belong.
@ -764,9 +757,9 @@ aiNode* ProcessSpatialStructure(aiNode* parent, const IfcProduct& el, Conversion
} }
} }
// handle openings, which we collect in a list rather than adding them to the node graph // handle openings, which we collect in a list rather than adding them to the node graph
else if(const IfcRelVoidsElement* const fills = obj->ToPtr<IfcRelVoidsElement>()) { else if(const Schema_2x3::IfcRelVoidsElement* const fills = obj->ToPtr<Schema_2x3::IfcRelVoidsElement>()) {
if(fills->RelatingBuildingElement->GetID() == el.GetID()) { if(fills->RelatingBuildingElement->GetID() == el.GetID()) {
const IfcFeatureElementSubtraction& open = fills->RelatedOpeningElement; const Schema_2x3::IfcFeatureElementSubtraction& open = fills->RelatedOpeningElement;
// move opening elements to a separate node since they are semantically different than elements that are just 'contained' // move opening elements to a separate node since they are semantically different than elements that are just 'contained'
std::unique_ptr<aiNode> nd_aggr(new aiNode()); std::unique_ptr<aiNode> nd_aggr(new aiNode());
@ -808,7 +801,7 @@ aiNode* ProcessSpatialStructure(aiNode* parent, const IfcProduct& el, Conversion
if (conv.already_processed.find((*range.first).second) != conv.already_processed.end()) { if (conv.already_processed.find((*range.first).second) != conv.already_processed.end()) {
continue; continue;
} }
if(const IfcRelAggregates* const aggr = conv.db.GetObject((*range.first).second)->ToPtr<IfcRelAggregates>()) { if(const Schema_2x3::IfcRelAggregates* const aggr = conv.db.GetObject((*range.first).second)->ToPtr<Schema_2x3::IfcRelAggregates>()) {
if(aggr->RelatingObject->GetID() != el.GetID()) { if(aggr->RelatingObject->GetID() != el.GetID()) {
continue; continue;
} }
@ -821,8 +814,8 @@ aiNode* ProcessSpatialStructure(aiNode* parent, const IfcProduct& el, Conversion
nd_aggr->mTransformation = nd->mTransformation; nd_aggr->mTransformation = nd->mTransformation;
nd_aggr->mChildren = new aiNode*[aggr->RelatedObjects.size()](); nd_aggr->mChildren = new aiNode*[aggr->RelatedObjects.size()]();
for(const IfcObjectDefinition& def : aggr->RelatedObjects) { for(const Schema_2x3::IfcObjectDefinition& def : aggr->RelatedObjects) {
if(const IfcProduct* const prod = def.ToPtr<IfcProduct>()) { if(const Schema_2x3::IfcProduct* const prod = def.ToPtr<Schema_2x3::IfcProduct>()) {
aiNode* const ndnew = ProcessSpatialStructure(nd_aggr.get(),*prod,conv,NULL); aiNode* const ndnew = ProcessSpatialStructure(nd_aggr.get(),*prod,conv,NULL);
if(ndnew) { if(ndnew) {
@ -889,7 +882,7 @@ void ProcessSpatialStructures(ConversionData& conv)
std::vector<aiNode*> nodes; std::vector<aiNode*> nodes;
for(const STEP::LazyObject* lz : *range) { for(const STEP::LazyObject* lz : *range) {
const IfcSpatialStructureElement* const prod = lz->ToPtr<IfcSpatialStructureElement>(); const Schema_2x3::IfcSpatialStructureElement* const prod = lz->ToPtr<Schema_2x3::IfcSpatialStructureElement>();
if(!prod) { if(!prod) {
continue; continue;
} }
@ -899,9 +892,9 @@ void ProcessSpatialStructures(ConversionData& conv)
const STEP::DB::RefMap& refs = conv.db.GetRefs(); const STEP::DB::RefMap& refs = conv.db.GetRefs();
STEP::DB::RefMapRange ref_range = refs.equal_range(conv.proj.GetID()); STEP::DB::RefMapRange ref_range = refs.equal_range(conv.proj.GetID());
for(; ref_range.first != ref_range.second; ++ref_range.first) { for(; ref_range.first != ref_range.second; ++ref_range.first) {
if(const IfcRelAggregates* const aggr = conv.db.GetObject((*ref_range.first).second)->ToPtr<IfcRelAggregates>()) { if(const Schema_2x3::IfcRelAggregates* const aggr = conv.db.GetObject((*ref_range.first).second)->ToPtr<Schema_2x3::IfcRelAggregates>()) {
for(const IfcObjectDefinition& def : aggr->RelatedObjects) { for(const Schema_2x3::IfcObjectDefinition& def : aggr->RelatedObjects) {
// comparing pointer values is not sufficient, we would need to cast them to the same type first // comparing pointer values is not sufficient, we would need to cast them to the same type first
// as there is multiple inheritance in the game. // as there is multiple inheritance in the game.
if (def.GetID() == prod->GetID()) { if (def.GetID() == prod->GetID()) {
@ -910,7 +903,6 @@ void ProcessSpatialStructures(ConversionData& conv)
nodes.push_back(ProcessSpatialStructure(NULL, *prod, conv, NULL)); nodes.push_back(ProcessSpatialStructure(NULL, *prod, conv, NULL));
} }
} }
} }
} }
} }
@ -920,7 +912,7 @@ void ProcessSpatialStructures(ConversionData& conv)
if (nb_nodes == 0) { if (nb_nodes == 0) {
IFCImporter::LogWarn("failed to determine primary site element, taking all the IfcSite"); IFCImporter::LogWarn("failed to determine primary site element, taking all the IfcSite");
for (const STEP::LazyObject* lz : *range) { for (const STEP::LazyObject* lz : *range) {
const IfcSpatialStructureElement* const prod = lz->ToPtr<IfcSpatialStructureElement>(); const Schema_2x3::IfcSpatialStructureElement* const prod = lz->ToPtr<Schema_2x3::IfcSpatialStructureElement>();
if (!prod) { if (!prod) {
continue; continue;
} }

4
code/IFCLoader.h → code/Importer/IFC/IFCLoader.h
View File

@ -45,8 +45,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef INCLUDED_AI_IFC_LOADER_H #ifndef INCLUDED_AI_IFC_LOADER_H
#define INCLUDED_AI_IFC_LOADER_H #define INCLUDED_AI_IFC_LOADER_H
#include "BaseImporter.h" #include "code/BaseImporter.h"
#include "LogAux.h" #include "code/LogAux.h"
namespace Assimp { namespace Assimp {

24
code/IFCMaterial.cpp → code/Importer/IFC/IFCMaterial.cpp
View File

@ -68,20 +68,20 @@ static int ConvertShadingMode(const std::string& name) {
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
static void FillMaterial(aiMaterial* mat,const IFC::IfcSurfaceStyle* surf,ConversionData& conv) { static void FillMaterial(aiMaterial* mat,const IFC::Schema_2x3::IfcSurfaceStyle* surf,ConversionData& conv) {
aiString name; aiString name;
name.Set((surf->Name? surf->Name.Get() : "IfcSurfaceStyle_Unnamed")); name.Set((surf->Name? surf->Name.Get() : "IfcSurfaceStyle_Unnamed"));
mat->AddProperty(&name,AI_MATKEY_NAME); mat->AddProperty(&name,AI_MATKEY_NAME);
// now see which kinds of surface information are present // now see which kinds of surface information are present
for(std::shared_ptr< const IFC::IfcSurfaceStyleElementSelect > sel2 : surf->Styles) { for(std::shared_ptr< const IFC::Schema_2x3::IfcSurfaceStyleElementSelect > sel2 : surf->Styles) {
if (const IFC::IfcSurfaceStyleShading* shade = sel2->ResolveSelectPtr<IFC::IfcSurfaceStyleShading>(conv.db)) { if (const IFC::Schema_2x3::IfcSurfaceStyleShading* shade = sel2->ResolveSelectPtr<IFC::Schema_2x3::IfcSurfaceStyleShading>(conv.db)) {
aiColor4D col_base,col; aiColor4D col_base,col;
ConvertColor(col_base, shade->SurfaceColour); ConvertColor(col_base, shade->SurfaceColour);
mat->AddProperty(&col_base,1, AI_MATKEY_COLOR_DIFFUSE); mat->AddProperty(&col_base,1, AI_MATKEY_COLOR_DIFFUSE);
if (const IFC::IfcSurfaceStyleRendering* ren = shade->ToPtr<IFC::IfcSurfaceStyleRendering>()) { if (const IFC::Schema_2x3::IfcSurfaceStyleRendering* ren = shade->ToPtr<IFC::Schema_2x3::IfcSurfaceStyleRendering>()) {
if (ren->Transparency) { if (ren->Transparency) {
const float t = 1.f-static_cast<float>(ren->Transparency.Get()); const float t = 1.f-static_cast<float>(ren->Transparency.Get());
@ -112,7 +112,7 @@ static void FillMaterial(aiMaterial* mat,const IFC::IfcSurfaceStyle* surf,Conver
mat->AddProperty(&shading,1, AI_MATKEY_SHADING_MODEL); mat->AddProperty(&shading,1, AI_MATKEY_SHADING_MODEL);
if (ren->SpecularHighlight) { if (ren->SpecularHighlight) {
if(const EXPRESS::REAL* rt = ren->SpecularHighlight.Get()->ToPtr<EXPRESS::REAL>()) { if(const ::Assimp::STEP::EXPRESS::REAL* rt = ren->SpecularHighlight.Get()->ToPtr<::Assimp::STEP::EXPRESS::REAL>()) {
// at this point we don't distinguish between the two distinct ways of // at this point we don't distinguish between the two distinct ways of
// specifying highlight intensities. leave this to the user. // specifying highlight intensities. leave this to the user.
const float e = static_cast<float>(*rt); const float e = static_cast<float>(*rt);
@ -123,23 +123,19 @@ static void FillMaterial(aiMaterial* mat,const IFC::IfcSurfaceStyle* surf,Conver
} }
} }
} }
} /*
else if (const IFC::IfcSurfaceStyleWithTextures* tex = sel2->ResolveSelectPtr<IFC::IfcSurfaceStyleWithTextures>(conv.db)) {
// XXX
} */
} }
}
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
unsigned int ProcessMaterials(uint64_t id, unsigned int prevMatId, ConversionData& conv, bool forceDefaultMat) { unsigned int ProcessMaterials(uint64_t id, unsigned int prevMatId, ConversionData& conv, bool forceDefaultMat) {
STEP::DB::RefMapRange range = conv.db.GetRefs().equal_range(id); STEP::DB::RefMapRange range = conv.db.GetRefs().equal_range(id);
for(;range.first != range.second; ++range.first) { for(;range.first != range.second; ++range.first) {
if(const IFC::IfcStyledItem* const styled = conv.db.GetObject((*range.first).second)->ToPtr<IFC::IfcStyledItem>()) { if(const IFC::Schema_2x3::IfcStyledItem* const styled = conv.db.GetObject((*range.first).second)->ToPtr<IFC::Schema_2x3::IfcStyledItem>()) {
for(const IFC::IfcPresentationStyleAssignment& as : styled->Styles) { for(const IFC::Schema_2x3::IfcPresentationStyleAssignment& as : styled->Styles) {
for(std::shared_ptr<const IFC::IfcPresentationStyleSelect> sel : as.Styles) { for(std::shared_ptr<const IFC::Schema_2x3::IfcPresentationStyleSelect> sel : as.Styles) {
if( const IFC::IfcSurfaceStyle* const surf = sel->ResolveSelectPtr<IFC::IfcSurfaceStyle>(conv.db) ) { if( const IFC::Schema_2x3::IfcSurfaceStyle* const surf = sel->ResolveSelectPtr<IFC::Schema_2x3::IfcSurfaceStyle>(conv.db) ) {
// try to satisfy from cache // try to satisfy from cache
ConversionData::MaterialCache::iterator mit = conv.cached_materials.find(surf); ConversionData::MaterialCache::iterator mit = conv.cached_materials.find(surf);
if( mit != conv.cached_materials.end() ) if( mit != conv.cached_materials.end() )

94
code/IFCOpenings.cpp → code/Importer/IFC/IFCOpenings.cpp
View File

@ -46,8 +46,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
#include "IFCUtil.h" #include "IFCUtil.h"
#include "PolyTools.h" #include "code/PolyTools.h"
#include "ProcessHelper.h" #include "code/ProcessHelper.h"
#include "../contrib/poly2tri/poly2tri/poly2tri.h" #include "../contrib/poly2tri/poly2tri/poly2tri.h"
#include "../contrib/clipper/clipper.hpp" #include "../contrib/clipper/clipper.hpp"
@ -323,7 +323,7 @@ void InsertWindowContours(const ContourVector& contours,
if (hit) { if (hit) {
if (last_hit != (size_t)-1) { if (last_hit != (size_t)-1) {
const size_t old = curmesh.verts.size(); const size_t old = curmesh.mVerts.size();
size_t cnt = last_hit > n ? size-(last_hit-n) : n-last_hit; size_t cnt = last_hit > n ? size-(last_hit-n) : n-last_hit;
for(size_t a = last_hit, e = 0; e <= cnt; a=(a+1)%size, ++e) { for(size_t a = last_hit, e = 0; e <= cnt; a=(a+1)%size, ++e) {
// hack: this is to fix cases where opening contours are self-intersecting. // hack: this is to fix cases where opening contours are self-intersecting.
@ -335,7 +335,7 @@ void InsertWindowContours(const ContourVector& contours,
if ((contour[a] - edge).SquareLength() > diag*diag*0.7) { if ((contour[a] - edge).SquareLength() > diag*diag*0.7) {
continue; continue;
} }
curmesh.verts.push_back(IfcVector3(contour[a].x, contour[a].y, 0.0f)); curmesh.mVerts.push_back(IfcVector3(contour[a].x, contour[a].y, 0.0f));
} }
if (edge != contour[last_hit]) { if (edge != contour[last_hit]) {
@ -356,16 +356,16 @@ void InsertWindowContours(const ContourVector& contours,
corner.y = bb.second.y; corner.y = bb.second.y;
} }
curmesh.verts.push_back(IfcVector3(corner.x, corner.y, 0.0f)); curmesh.mVerts.push_back(IfcVector3(corner.x, corner.y, 0.0f));
} }
else if (cnt == 1) { else if (cnt == 1) {
// avoid degenerate polygons (also known as lines or points) // avoid degenerate polygons (also known as lines or points)
curmesh.verts.erase(curmesh.verts.begin()+old,curmesh.verts.end()); curmesh.mVerts.erase(curmesh.mVerts.begin()+old,curmesh.mVerts.end());
} }
if (const size_t d = curmesh.verts.size()-old) { if (const size_t d = curmesh.mVerts.size()-old) {
curmesh.vertcnt.push_back(static_cast<unsigned int>(d)); curmesh.mVertcnt.push_back(static_cast<unsigned int>(d));
std::reverse(curmesh.verts.rbegin(),curmesh.verts.rbegin()+d); std::reverse(curmesh.mVerts.rbegin(),curmesh.mVerts.rbegin()+d);
} }
if (n == very_first_hit) { if (n == very_first_hit) {
break; break;
@ -504,8 +504,8 @@ void CleanupOuterContour(const std::vector<IfcVector2>& contour_flat, TempMesh&
std::vector<IfcVector3> vold; std::vector<IfcVector3> vold;
std::vector<unsigned int> iold; std::vector<unsigned int> iold;
vold.reserve(curmesh.verts.size()); vold.reserve(curmesh.mVerts.size());
iold.reserve(curmesh.vertcnt.size()); iold.reserve(curmesh.mVertcnt.size());
// Fix the outer contour using polyclipper // Fix the outer contour using polyclipper
try { try {
@ -530,9 +530,9 @@ void CleanupOuterContour(const std::vector<IfcVector2>& contour_flat, TempMesh&
subject.reserve(4); subject.reserve(4);
size_t index = 0; size_t index = 0;
size_t countdown = 0; size_t countdown = 0;
for(const IfcVector3& pip : curmesh.verts) { for(const IfcVector3& pip : curmesh.mVerts) {
if (!countdown) { if (!countdown) {
countdown = curmesh.vertcnt[index++]; countdown = curmesh.mVertcnt[index++];
if (!countdown) { if (!countdown) {
continue; continue;
} }
@ -572,8 +572,8 @@ void CleanupOuterContour(const std::vector<IfcVector2>& contour_flat, TempMesh&
} }
// swap data arrays // swap data arrays
std::swap(vold,curmesh.verts); std::swap(vold,curmesh.mVerts);
std::swap(iold,curmesh.vertcnt); std::swap(iold,curmesh.mVertcnt);
} }
typedef std::vector<TempOpening*> OpeningRefs; typedef std::vector<TempOpening*> OpeningRefs;
@ -898,14 +898,14 @@ size_t CloseWindows(ContourVector& contours,
SkipList::const_iterator skipbegin = (*it).skiplist.begin(); SkipList::const_iterator skipbegin = (*it).skiplist.begin();
curmesh.verts.reserve(curmesh.verts.size() + (*it).contour.size() * 4); curmesh.mVerts.reserve(curmesh.mVerts.size() + (*it).contour.size() * 4);
curmesh.vertcnt.reserve(curmesh.vertcnt.size() + (*it).contour.size()); curmesh.mVertcnt.reserve(curmesh.mVertcnt.size() + (*it).contour.size());
bool reverseCountourFaces = false; bool reverseCountourFaces = false;
// compare base poly normal and contour normal to detect if we need to reverse the face winding // compare base poly normal and contour normal to detect if we need to reverse the face winding
if(curmesh.vertcnt.size() > 0) { if(curmesh.mVertcnt.size() > 0) {
IfcVector3 basePolyNormal = TempMesh::ComputePolygonNormal(curmesh.verts.data(), curmesh.vertcnt.front()); IfcVector3 basePolyNormal = TempMesh::ComputePolygonNormal(curmesh.mVerts.data(), curmesh.mVertcnt.front());
std::vector<IfcVector3> worldSpaceContourVtx(it->contour.size()); std::vector<IfcVector3> worldSpaceContourVtx(it->contour.size());
@ -954,14 +954,14 @@ size_t CloseWindows(ContourVector& contours,
} }
if (drop_this_edge) { if (drop_this_edge) {
curmesh.verts.pop_back(); curmesh.mVerts.pop_back();
curmesh.verts.pop_back(); curmesh.mVerts.pop_back();
} }
else { else {
curmesh.verts.push_back(((cit == cbegin) != reverseCountourFaces) ? world_point : bestv); curmesh.mVerts.push_back(((cit == cbegin) != reverseCountourFaces) ? world_point : bestv);
curmesh.verts.push_back(((cit == cbegin) != reverseCountourFaces) ? bestv : world_point); curmesh.mVerts.push_back(((cit == cbegin) != reverseCountourFaces) ? bestv : world_point);
curmesh.vertcnt.push_back(4); curmesh.mVertcnt.push_back(4);
++closed; ++closed;
} }
@ -971,8 +971,8 @@ size_t CloseWindows(ContourVector& contours,
continue; continue;
} }
curmesh.verts.push_back(reverseCountourFaces ? bestv : world_point); curmesh.mVerts.push_back(reverseCountourFaces ? bestv : world_point);
curmesh.verts.push_back(reverseCountourFaces ? world_point : bestv); curmesh.mVerts.push_back(reverseCountourFaces ? world_point : bestv);
if (cit == cend - 1) { if (cit == cend - 1) {
drop_this_edge = *skipit; drop_this_edge = *skipit;
@ -981,13 +981,13 @@ size_t CloseWindows(ContourVector& contours,
// a border edge that needs to be dropped. // a border edge that needs to be dropped.
if (drop_this_edge) { if (drop_this_edge) {
--closed; --closed;
curmesh.vertcnt.pop_back(); curmesh.mVertcnt.pop_back();
curmesh.verts.pop_back(); curmesh.mVerts.pop_back();
curmesh.verts.pop_back(); curmesh.mVerts.pop_back();
} }
else { else {
curmesh.verts.push_back(reverseCountourFaces ? start0 : start1); curmesh.mVerts.push_back(reverseCountourFaces ? start0 : start1);
curmesh.verts.push_back(reverseCountourFaces ? start1 : start0); curmesh.mVerts.push_back(reverseCountourFaces ? start1 : start0);
} }
} }
} }
@ -1029,10 +1029,10 @@ void Quadrify(const std::vector< BoundingBox >& bbs, TempMesh& curmesh)
QuadrifyPart(IfcVector2(),one_vec,field,bbs,quads); QuadrifyPart(IfcVector2(),one_vec,field,bbs,quads);
ai_assert(!(quads.size() % 4)); ai_assert(!(quads.size() % 4));
curmesh.vertcnt.resize(quads.size()/4,4); curmesh.mVertcnt.resize(quads.size()/4,4);
curmesh.verts.reserve(quads.size()); curmesh.mVerts.reserve(quads.size());
for(const IfcVector2& v2 : quads) { for(const IfcVector2& v2 : quads) {
curmesh.verts.push_back(IfcVector3(v2.x, v2.y, static_cast<IfcFloat>(0.0))); curmesh.mVerts.push_back(IfcVector3(v2.x, v2.y, static_cast<IfcFloat>(0.0)));
} }
} }
@ -1053,7 +1053,7 @@ void Quadrify(const ContourVector& contours, TempMesh& curmesh)
IfcMatrix4 ProjectOntoPlane(std::vector<IfcVector2>& out_contour, const TempMesh& in_mesh, IfcMatrix4 ProjectOntoPlane(std::vector<IfcVector2>& out_contour, const TempMesh& in_mesh,
bool &ok, IfcVector3& nor_out) bool &ok, IfcVector3& nor_out)
{ {
const std::vector<IfcVector3>& in_verts = in_mesh.verts; const std::vector<IfcVector3>& in_verts = in_mesh.mVerts;
ok = true; ok = true;
IfcMatrix4 m = IfcMatrix4(DerivePlaneCoordinateSpace(in_mesh, ok, nor_out)); IfcMatrix4 m = IfcMatrix4(DerivePlaneCoordinateSpace(in_mesh, ok, nor_out));
@ -1200,8 +1200,8 @@ bool GenerateOpenings(std::vector<TempOpening>& openings,
} }
} }
} }
std::vector<IfcVector3> profile_verts = profile_data->verts; std::vector<IfcVector3> profile_verts = profile_data->mVerts;
std::vector<unsigned int> profile_vertcnts = profile_data->vertcnt; std::vector<unsigned int> profile_vertcnts = profile_data->mVertcnt;
if(profile_verts.size() <= 2) { if(profile_verts.size() <= 2) {
continue; continue;
} }
@ -1421,7 +1421,7 @@ bool GenerateOpenings(std::vector<TempOpening>& openings,
CleanupOuterContour(contour_flat, curmesh); CleanupOuterContour(contour_flat, curmesh);
// Undo the projection and get back to world (or local object) space // Undo the projection and get back to world (or local object) space
for(IfcVector3& v3 : curmesh.verts) { for(IfcVector3& v3 : curmesh.mVerts) {
v3 = minv * v3; v3 = minv * v3;
} }
@ -1438,7 +1438,7 @@ bool TryAddOpenings_Poly2Tri(const std::vector<TempOpening>& openings,const std:
TempMesh& curmesh) TempMesh& curmesh)
{ {
IFCImporter::LogWarn("forced to use poly2tri fallback method to generate wall openings"); IFCImporter::LogWarn("forced to use poly2tri fallback method to generate wall openings");
std::vector<IfcVector3>& out = curmesh.verts; std::vector<IfcVector3>& out = curmesh.mVerts;
bool result = false; bool result = false;
@ -1513,14 +1513,14 @@ bool TryAddOpenings_Poly2Tri(const std::vector<TempOpening>& openings,const std:
continue; continue;
} }
const std::vector<IfcVector3>& va = t.profileMesh->verts; const std::vector<IfcVector3>& va = t.profileMesh->mVerts;
if(va.size() <= 2) { if(va.size() <= 2) {
continue; continue;
} }
std::vector<IfcVector2> contour; std::vector<IfcVector2> contour;
for(const IfcVector3& xx : t.profileMesh->verts) { for(const IfcVector3& xx : t.profileMesh->mVerts) {
IfcVector3 vv = m * xx, vv_extr = m * (xx + t.extrusionDir); IfcVector3 vv = m * xx, vv_extr = m * (xx + t.extrusionDir);
const bool is_extruded_side = std::fabs(vv.z - coord) > std::fabs(vv_extr.z - coord); const bool is_extruded_side = std::fabs(vv.z - coord) > std::fabs(vv_extr.z - coord);
@ -1603,8 +1603,8 @@ bool TryAddOpenings_Poly2Tri(const std::vector<TempOpening>& openings,const std:
std::vector<IfcVector3> old_verts; std::vector<IfcVector3> old_verts;
std::vector<unsigned int> old_vertcnt; std::vector<unsigned int> old_vertcnt;
old_verts.swap(curmesh.verts); old_verts.swap(curmesh.mVerts);
old_vertcnt.swap(curmesh.vertcnt); old_vertcnt.swap(curmesh.mVertcnt);
std::vector< std::vector<p2t::Point*> > contours; std::vector< std::vector<p2t::Point*> > contours;
for(ClipperLib::ExPolygon& clip : clipped) { for(ClipperLib::ExPolygon& clip : clipped) {
@ -1669,9 +1669,9 @@ bool TryAddOpenings_Poly2Tri(const std::vector<TempOpening>& openings,const std:
ai_assert(v.x <= 1.0 && v.x >= 0.0 && v.y <= 1.0 && v.y >= 0.0); ai_assert(v.x <= 1.0 && v.x >= 0.0 && v.y <= 1.0 && v.y >= 0.0);
const IfcVector3 v3 = minv * IfcVector3(vmin.x + v.x * vmax.x, vmin.y + v.y * vmax.y,coord) ; const IfcVector3 v3 = minv * IfcVector3(vmin.x + v.x * vmax.x, vmin.y + v.y * vmax.y,coord) ;
curmesh.verts.push_back(v3); curmesh.mVerts.push_back(v3);
} }
curmesh.vertcnt.push_back(3); curmesh.mVertcnt.push_back(3);
} }
result = true; result = true;
@ -1679,8 +1679,8 @@ bool TryAddOpenings_Poly2Tri(const std::vector<TempOpening>& openings,const std:
if (!result) { if (!result) {
// revert -- it's a shame, but better than nothing // revert -- it's a shame, but better than nothing
curmesh.verts.insert(curmesh.verts.end(),old_verts.begin(), old_verts.end()); curmesh.mVerts.insert(curmesh.mVerts.end(),old_verts.begin(), old_verts.end());
curmesh.vertcnt.insert(curmesh.vertcnt.end(),old_vertcnt.begin(), old_vertcnt.end()); curmesh.mVertcnt.insert(curmesh.mVertcnt.end(),old_vertcnt.begin(), old_vertcnt.end());
IFCImporter::LogError("Ifc: revert, could not generate openings for this wall"); IFCImporter::LogError("Ifc: revert, could not generate openings for this wall");
} }

89
code/IFCProfile.cpp → code/Importer/IFC/IFCProfile.cpp
View File

@ -43,28 +43,27 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
* @brief Read profile and curves entities from IFC files * @brief Read profile and curves entities from IFC files
*/ */
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
#include "IFCUtil.h" #include "IFCUtil.h"
namespace Assimp { namespace Assimp {
namespace IFC { namespace IFC {
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessPolyLine(const IfcPolyline& def, TempMesh& meshout, ConversionData& /*conv*/) void ProcessPolyLine(const Schema_2x3::IfcPolyline& def, TempMesh& meshout, ConversionData& /*conv*/)
{ {
// this won't produce a valid mesh, it just spits out a list of vertices // this won't produce a valid mesh, it just spits out a list of vertices
IfcVector3 t; IfcVector3 t;
for(const IfcCartesianPoint& cp : def.Points) { for(const Schema_2x3::IfcCartesianPoint& cp : def.Points) {
ConvertCartesianPoint(t,cp); ConvertCartesianPoint(t,cp);
meshout.verts.push_back(t); meshout.mVerts.push_back(t);
} }
meshout.vertcnt.push_back(static_cast<unsigned int>(meshout.verts.size())); meshout.mVertcnt.push_back(static_cast<unsigned int>(meshout.mVerts.size()));
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool ProcessCurve(const IfcCurve& curve, TempMesh& meshout, ConversionData& conv) bool ProcessCurve(const Schema_2x3::IfcCurve& curve, TempMesh& meshout, ConversionData& conv)
{ {
std::unique_ptr<const Curve> cv(Curve::Convert(curve,conv)); std::unique_ptr<const Curve> cv(Curve::Convert(curve,conv));
if (!cv) { if (!cv) {
@ -78,10 +77,10 @@ bool ProcessCurve(const IfcCurve& curve, TempMesh& meshout, ConversionData& con
bc->SampleDiscrete(meshout); bc->SampleDiscrete(meshout);
} }
catch(const CurveError& cv) { catch(const CurveError& cv) {
IFCImporter::LogError(cv.s+ " (error occurred while processing curve)"); IFCImporter::LogError(cv.mStr + " (error occurred while processing curve)");
return false; return false;
} }
meshout.vertcnt.push_back(static_cast<unsigned int>(meshout.verts.size())); meshout.mVertcnt.push_back(static_cast<unsigned int>(meshout.mVerts.size()));
return true; return true;
} }
@ -90,66 +89,66 @@ bool ProcessCurve(const IfcCurve& curve, TempMesh& meshout, ConversionData& con
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessClosedProfile(const IfcArbitraryClosedProfileDef& def, TempMesh& meshout, ConversionData& conv) void ProcessClosedProfile(const Schema_2x3::IfcArbitraryClosedProfileDef& def, TempMesh& meshout, ConversionData& conv)
{ {
ProcessCurve(def.OuterCurve,meshout,conv); ProcessCurve(def.OuterCurve,meshout,conv);
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessOpenProfile(const IfcArbitraryOpenProfileDef& def, TempMesh& meshout, ConversionData& conv) void ProcessOpenProfile(const Schema_2x3::IfcArbitraryOpenProfileDef& def, TempMesh& meshout, ConversionData& conv)
{ {
ProcessCurve(def.Curve,meshout,conv); ProcessCurve(def.Curve,meshout,conv);
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ProcessParametrizedProfile(const IfcParameterizedProfileDef& def, TempMesh& meshout, ConversionData& conv) void ProcessParametrizedProfile(const Schema_2x3::IfcParameterizedProfileDef& def, TempMesh& meshout, ConversionData& conv)
{ {
if(const IfcRectangleProfileDef* const cprofile = def.ToPtr<IfcRectangleProfileDef>()) { if(const Schema_2x3::IfcRectangleProfileDef* const cprofile = def.ToPtr<Schema_2x3::IfcRectangleProfileDef>()) {
const IfcFloat x = cprofile->XDim*0.5f, y = cprofile->YDim*0.5f; const IfcFloat x = cprofile->XDim*0.5f, y = cprofile->YDim*0.5f;
meshout.verts.reserve(meshout.verts.size()+4); meshout.mVerts.reserve(meshout.mVerts.size()+4);
meshout.verts.push_back( IfcVector3( x, y, 0.f )); meshout.mVerts.push_back( IfcVector3( x, y, 0.f ));
meshout.verts.push_back( IfcVector3(-x, y, 0.f )); meshout.mVerts.push_back( IfcVector3(-x, y, 0.f ));
meshout.verts.push_back( IfcVector3(-x,-y, 0.f )); meshout.mVerts.push_back( IfcVector3(-x,-y, 0.f ));
meshout.verts.push_back( IfcVector3( x,-y, 0.f )); meshout.mVerts.push_back( IfcVector3( x,-y, 0.f ));
meshout.vertcnt.push_back(4); meshout.mVertcnt.push_back(4);
} }
else if( const IfcCircleProfileDef* const circle = def.ToPtr<IfcCircleProfileDef>()) { else if( const Schema_2x3::IfcCircleProfileDef* const circle = def.ToPtr<Schema_2x3::IfcCircleProfileDef>()) {
if(def.ToPtr<IfcCircleHollowProfileDef>()) { if(def.ToPtr<Schema_2x3::IfcCircleHollowProfileDef>()) {
// TODO // TODO
} }
const size_t segments = conv.settings.cylindricalTessellation; const size_t segments = conv.settings.cylindricalTessellation;
const IfcFloat delta = AI_MATH_TWO_PI_F/segments, radius = circle->Radius; const IfcFloat delta = AI_MATH_TWO_PI_F/segments, radius = circle->Radius;
meshout.verts.reserve(segments); meshout.mVerts.reserve(segments);
IfcFloat angle = 0.f; IfcFloat angle = 0.f;
for(size_t i = 0; i < segments; ++i, angle += delta) { for(size_t i = 0; i < segments; ++i, angle += delta) {
meshout.verts.push_back( IfcVector3( std::cos(angle)*radius, std::sin(angle)*radius, 0.f )); meshout.mVerts.push_back( IfcVector3( std::cos(angle)*radius, std::sin(angle)*radius, 0.f ));
} }
meshout.vertcnt.push_back(static_cast<unsigned int>(segments)); meshout.mVertcnt.push_back(static_cast<unsigned int>(segments));
} }
else if( const IfcIShapeProfileDef* const ishape = def.ToPtr<IfcIShapeProfileDef>()) { else if( const Schema_2x3::IfcIShapeProfileDef* const ishape = def.ToPtr<Schema_2x3::IfcIShapeProfileDef>()) {
// construct simplified IBeam shape // construct simplified IBeam shape
const IfcFloat offset = (ishape->OverallWidth - ishape->WebThickness) / 2; const IfcFloat offset = (ishape->OverallWidth - ishape->WebThickness) / 2;
const IfcFloat inner_height = ishape->OverallDepth - ishape->FlangeThickness * 2; const IfcFloat inner_height = ishape->OverallDepth - ishape->FlangeThickness * 2;
meshout.verts.reserve(12); meshout.mVerts.reserve(12);
meshout.verts.push_back(IfcVector3(0,0,0)); meshout.mVerts.push_back(IfcVector3(0,0,0));
meshout.verts.push_back(IfcVector3(0,ishape->FlangeThickness,0)); meshout.mVerts.push_back(IfcVector3(0,ishape->FlangeThickness,0));
meshout.verts.push_back(IfcVector3(offset,ishape->FlangeThickness,0)); meshout.mVerts.push_back(IfcVector3(offset,ishape->FlangeThickness,0));
meshout.verts.push_back(IfcVector3(offset,ishape->FlangeThickness + inner_height,0)); meshout.mVerts.push_back(IfcVector3(offset,ishape->FlangeThickness + inner_height,0));
meshout.verts.push_back(IfcVector3(0,ishape->FlangeThickness + inner_height,0)); meshout.mVerts.push_back(IfcVector3(0,ishape->FlangeThickness + inner_height,0));
meshout.verts.push_back(IfcVector3(0,ishape->OverallDepth,0)); meshout.mVerts.push_back(IfcVector3(0,ishape->OverallDepth,0));
meshout.verts.push_back(IfcVector3(ishape->OverallWidth,ishape->OverallDepth,0)); meshout.mVerts.push_back(IfcVector3(ishape->OverallWidth,ishape->OverallDepth,0));
meshout.verts.push_back(IfcVector3(ishape->OverallWidth,ishape->FlangeThickness + inner_height,0)); meshout.mVerts.push_back(IfcVector3(ishape->OverallWidth,ishape->FlangeThickness + inner_height,0));
meshout.verts.push_back(IfcVector3(offset+ishape->WebThickness,ishape->FlangeThickness + inner_height,0)); meshout.mVerts.push_back(IfcVector3(offset+ishape->WebThickness,ishape->FlangeThickness + inner_height,0));
meshout.verts.push_back(IfcVector3(offset+ishape->WebThickness,ishape->FlangeThickness,0)); meshout.mVerts.push_back(IfcVector3(offset+ishape->WebThickness,ishape->FlangeThickness,0));
meshout.verts.push_back(IfcVector3(ishape->OverallWidth,ishape->FlangeThickness,0)); meshout.mVerts.push_back(IfcVector3(ishape->OverallWidth,ishape->FlangeThickness,0));
meshout.verts.push_back(IfcVector3(ishape->OverallWidth,0,0)); meshout.mVerts.push_back(IfcVector3(ishape->OverallWidth,0,0));
meshout.vertcnt.push_back(12); meshout.mVertcnt.push_back(12);
} }
else { else {
IFCImporter::LogWarn("skipping unknown IfcParameterizedProfileDef entity, type is " + def.GetClassName()); IFCImporter::LogWarn("skipping unknown IfcParameterizedProfileDef entity, type is " + def.GetClassName());
@ -162,15 +161,15 @@ void ProcessParametrizedProfile(const IfcParameterizedProfileDef& def, TempMesh&
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool ProcessProfile(const IfcProfileDef& prof, TempMesh& meshout, ConversionData& conv) bool ProcessProfile(const Schema_2x3::IfcProfileDef& prof, TempMesh& meshout, ConversionData& conv)
{ {
if(const IfcArbitraryClosedProfileDef* const cprofile = prof.ToPtr<IfcArbitraryClosedProfileDef>()) { if(const Schema_2x3::IfcArbitraryClosedProfileDef* const cprofile = prof.ToPtr<Schema_2x3::IfcArbitraryClosedProfileDef>()) {
ProcessClosedProfile(*cprofile,meshout,conv); ProcessClosedProfile(*cprofile,meshout,conv);
} }
else if(const IfcArbitraryOpenProfileDef* const copen = prof.ToPtr<IfcArbitraryOpenProfileDef>()) { else if(const Schema_2x3::IfcArbitraryOpenProfileDef* const copen = prof.ToPtr<Schema_2x3::IfcArbitraryOpenProfileDef>()) {
ProcessOpenProfile(*copen,meshout,conv); ProcessOpenProfile(*copen,meshout,conv);
} }
else if(const IfcParameterizedProfileDef* const cparam = prof.ToPtr<IfcParameterizedProfileDef>()) { else if(const Schema_2x3::IfcParameterizedProfileDef* const cparam = prof.ToPtr<Schema_2x3::IfcParameterizedProfileDef>()) {
ProcessParametrizedProfile(*cparam,meshout,conv); ProcessParametrizedProfile(*cparam,meshout,conv);
} }
else { else {
@ -178,7 +177,7 @@ bool ProcessProfile(const IfcProfileDef& prof, TempMesh& meshout, ConversionData
return false; return false;
} }
meshout.RemoveAdjacentDuplicates(); meshout.RemoveAdjacentDuplicates();
if (!meshout.vertcnt.size() || meshout.vertcnt.front() <= 1) { if (!meshout.mVertcnt.size() || meshout.mVertcnt.front() <= 1) {
return false; return false;
} }
return true; return true;
@ -187,4 +186,4 @@ bool ProcessProfile(const IfcProfileDef& prof, TempMesh& meshout, ConversionData
} // ! IFC } // ! IFC
} // ! Assimp } // ! Assimp
#endif #endif // ASSIMP_BUILD_NO_IFC_IMPORTER

141
code/IFCReaderGen1.cpp → code/Importer/IFC/IFCReaderGen1_2x3.cpp
View File

@ -43,15 +43,17 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//#include "AssimpPCH.h" //#include "AssimpPCH.h"
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
#include "IFCReaderGen.h" #include "IFCReaderGen_2x3.h"
namespace Assimp { namespace Assimp {
using namespace IFC;
using namespace ::Assimp::IFC;
using namespace ::Assimp::IFC::Schema_2x3;
namespace { namespace {
typedef EXPRESS::ConversionSchema::SchemaEntry SchemaEntry; typedef EXPRESS::ConversionSchema::SchemaEntry SchemaEntry;
const SchemaEntry schema_raw[] = {
static const SchemaEntry schema_raw_2x3[] = {
SchemaEntry("ifcstairtypeenum",NULL ) SchemaEntry("ifcstairtypeenum",NULL )
, SchemaEntry("ifcspacetypeenum",NULL ) , SchemaEntry("ifcspacetypeenum",NULL )
, SchemaEntry("ifcwalltypeenum",NULL ) , SchemaEntry("ifcwalltypeenum",NULL )
@ -1037,9 +1039,8 @@ namespace {
} }
// ----------------------------------------------------------------------------------------------------------- // -----------------------------------------------------------------------------------------------------------
void IFC::GetSchema(EXPRESS::ConversionSchema& out) void IFC::Schema_2x3::GetSchema(EXPRESS::ConversionSchema& out) {
{ out = EXPRESS::ConversionSchema(schema_raw_2x3);
out = EXPRESS::ConversionSchema(schema_raw);
} }
namespace STEP { namespace STEP {
@ -1050,34 +1051,32 @@ template <> size_t GenericFill<NotImplemented>(const STEP::DB& /*db*/, const LIS
return 0; return 0;
} }
// ----------------------------------------------------------------------------------------------------------- // -----------------------------------------------------------------------------------------------------------
template <> size_t GenericFill<IfcRoot>(const DB& db, const LIST& params, IfcRoot* in) template <> size_t GenericFill<IfcRoot>(const DB& db, const LIST& params, IfcRoot* in)
{ {
size_t base = 0; size_t base = 0;
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcRoot"); } do { // convert the 'GlobalId' argument if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcRoot"); } do { // convert the 'GlobalId' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRoot,4>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->GlobalId, arg, db ); break; } try { GenericConvert( in->GlobalId, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRoot to be a `IfcGloballyUniqueId`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRoot to be a `IfcGloballyUniqueId`")); }
} while(0); } while(0);
do { // convert the 'OwnerHistory' argument do { // convert the 'OwnerHistory' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRoot,4>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->OwnerHistory, arg, db ); break; } try { GenericConvert( in->OwnerHistory, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRoot to be a `IfcOwnerHistory`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRoot to be a `IfcOwnerHistory`")); }
} while(0); } while(0);
do { // convert the 'Name' argument do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRoot,4>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[2]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; } try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcRoot to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcRoot to be a `IfcLabel`")); }
} while(0); } while(0);
do { // convert the 'Description' argument do { // convert the 'Description' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRoot,4>::aux_is_derived[3]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRoot,4>::aux_is_derived[3]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Description, arg, db ); break; } try { GenericConvert( in->Description, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRoot to be a `IfcText`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRoot to be a `IfcText`")); }
@ -1145,27 +1144,27 @@ template <> size_t GenericFill<IfcRepresentation>(const DB& db, const LIST& para
size_t base = 0; size_t base = 0;
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcRepresentation"); } do { // convert the 'ContextOfItems' argument if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcRepresentation"); } do { // convert the 'ContextOfItems' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRepresentation,4>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->ContextOfItems, arg, db ); break; } try { GenericConvert( in->ContextOfItems, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRepresentation to be a `IfcRepresentationContext`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRepresentation to be a `IfcRepresentationContext`")); }
} while(0); } while(0);
do { // convert the 'RepresentationIdentifier' argument do { // convert the 'RepresentationIdentifier' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRepresentation,4>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RepresentationIdentifier, arg, db ); break; } try { GenericConvert( in->RepresentationIdentifier, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRepresentation to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRepresentation to be a `IfcLabel`")); }
} while(0); } while(0);
do { // convert the 'RepresentationType' argument do { // convert the 'RepresentationType' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRepresentation,4>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[2]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->RepresentationType, arg, db ); break; } try { GenericConvert( in->RepresentationType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcRepresentation to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcRepresentation to be a `IfcLabel`")); }
} while(0); } while(0);
do { // convert the 'Items' argument do { // convert the 'Items' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRepresentation,4>::aux_is_derived[3]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentation,4>::aux_is_derived[3]=true; break; }
try { GenericConvert( in->Items, arg, db ); break; } try { GenericConvert( in->Items, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRepresentation to be a `SET [1:?] OF IfcRepresentationItem`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRepresentation to be a `SET [1:?] OF IfcRepresentationItem`")); }
} while(0); } while(0);
@ -1231,7 +1230,7 @@ template <> size_t GenericFill<IfcObject>(const DB& db, const LIST& params, IfcO
size_t base = GenericFill(db,params,static_cast<IfcObjectDefinition*>(in)); size_t base = GenericFill(db,params,static_cast<IfcObjectDefinition*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcObject"); } do { // convert the 'ObjectType' argument if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcObject"); } do { // convert the 'ObjectType' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcObject,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcObject,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ObjectType, arg, db ); break; } try { GenericConvert( in->ObjectType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcObject to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcObject to be a `IfcLabel`")); }
@ -1284,21 +1283,21 @@ template <> size_t GenericFill<IfcProductRepresentation>(const DB& db, const LIS
size_t base = 0; size_t base = 0;
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcProductRepresentation"); } do { // convert the 'Name' argument if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcProductRepresentation"); } do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProductRepresentation,3>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProductRepresentation,3>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; } try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProductRepresentation to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProductRepresentation to be a `IfcLabel`")); }
} while(0); } while(0);
do { // convert the 'Description' argument do { // convert the 'Description' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProductRepresentation,3>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProductRepresentation,3>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Description, arg, db ); break; } try { GenericConvert( in->Description, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProductRepresentation to be a `IfcText`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProductRepresentation to be a `IfcText`")); }
} while(0); } while(0);
do { // convert the 'Representations' argument do { // convert the 'Representations' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProductRepresentation,3>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProductRepresentation,3>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->Representations, arg, db ); break; } try { GenericConvert( in->Representations, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcProductRepresentation to be a `LIST [1:?] OF IfcRepresentation`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcProductRepresentation to be a `LIST [1:?] OF IfcRepresentation`")); }
} while(0); } while(0);
@ -1310,14 +1309,14 @@ template <> size_t GenericFill<IfcProduct>(const DB& db, const LIST& params, Ifc
size_t base = GenericFill(db,params,static_cast<IfcObject*>(in)); size_t base = GenericFill(db,params,static_cast<IfcObject*>(in));
if (params.GetSize() < 7) { throw STEP::TypeError("expected 7 arguments to IfcProduct"); } do { // convert the 'ObjectPlacement' argument if (params.GetSize() < 7) { throw STEP::TypeError("expected 7 arguments to IfcProduct"); } do { // convert the 'ObjectPlacement' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProduct,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProduct,2>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ObjectPlacement, arg, db ); break; } try { GenericConvert( in->ObjectPlacement, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcProduct to be a `IfcObjectPlacement`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcProduct to be a `IfcObjectPlacement`")); }
} while(0); } while(0);
do { // convert the 'Representation' argument do { // convert the 'Representation' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProduct,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProduct,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Representation, arg, db ); break; } try { GenericConvert( in->Representation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcProduct to be a `IfcProductRepresentation`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcProduct to be a `IfcProductRepresentation`")); }
@ -1330,7 +1329,7 @@ template <> size_t GenericFill<IfcElement>(const DB& db, const LIST& params, Ifc
size_t base = GenericFill(db,params,static_cast<IfcProduct*>(in)); size_t base = GenericFill(db,params,static_cast<IfcProduct*>(in));
if (params.GetSize() < 8) { throw STEP::TypeError("expected 8 arguments to IfcElement"); } do { // convert the 'Tag' argument if (params.GetSize() < 8) { throw STEP::TypeError("expected 8 arguments to IfcElement"); } do { // convert the 'Tag' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcElement,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcElement,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Tag, arg, db ); break; } try { GenericConvert( in->Tag, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcElement to be a `IfcIdentifier`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcElement to be a `IfcIdentifier`")); }
@ -1369,13 +1368,13 @@ template <> size_t GenericFill<IfcCompositeCurve>(const DB& db, const LIST& para
size_t base = GenericFill(db,params,static_cast<IfcBoundedCurve*>(in)); size_t base = GenericFill(db,params,static_cast<IfcBoundedCurve*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcCompositeCurve"); } do { // convert the 'Segments' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcCompositeCurve"); } do { // convert the 'Segments' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCompositeCurve,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCompositeCurve,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Segments, arg, db ); break; } try { GenericConvert( in->Segments, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCompositeCurve to be a `LIST [1:?] OF IfcCompositeCurveSegment`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCompositeCurve to be a `LIST [1:?] OF IfcCompositeCurveSegment`")); }
} while(0); } while(0);
do { // convert the 'SelfIntersect' argument do { // convert the 'SelfIntersect' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCompositeCurve,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCompositeCurve,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->SelfIntersect, arg, db ); break; } try { GenericConvert( in->SelfIntersect, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCompositeCurve to be a `LOGICAL`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCompositeCurve to be a `LOGICAL`")); }
} while(0); } while(0);
@ -1394,27 +1393,27 @@ template <> size_t GenericFill<IfcCartesianTransformationOperator>(const DB& db,
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcCartesianTransformationOperator"); } do { // convert the 'Axis1' argument if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcCartesianTransformationOperator"); } do { // convert the 'Axis1' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCartesianTransformationOperator,4>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis1, arg, db ); break; } try { GenericConvert( in->Axis1, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCartesianTransformationOperator to be a `IfcDirection`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcCartesianTransformationOperator to be a `IfcDirection`")); }
} while(0); } while(0);
do { // convert the 'Axis2' argument do { // convert the 'Axis2' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCartesianTransformationOperator,4>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis2, arg, db ); break; } try { GenericConvert( in->Axis2, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCartesianTransformationOperator to be a `IfcDirection`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcCartesianTransformationOperator to be a `IfcDirection`")); }
} while(0); } while(0);
do { // convert the 'LocalOrigin' argument do { // convert the 'LocalOrigin' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCartesianTransformationOperator,4>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->LocalOrigin, arg, db ); break; } try { GenericConvert( in->LocalOrigin, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcCartesianTransformationOperator to be a `IfcCartesianPoint`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcCartesianTransformationOperator to be a `IfcCartesianPoint`")); }
} while(0); } while(0);
do { // convert the 'Scale' argument do { // convert the 'Scale' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCartesianTransformationOperator,4>::aux_is_derived[3]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator,4>::aux_is_derived[3]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Scale, arg, db ); break; } try { GenericConvert( in->Scale, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcCartesianTransformationOperator to be a `REAL`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcCartesianTransformationOperator to be a `REAL`")); }
@ -1427,7 +1426,7 @@ template <> size_t GenericFill<IfcCartesianTransformationOperator3D>(const DB& d
size_t base = GenericFill(db,params,static_cast<IfcCartesianTransformationOperator*>(in)); size_t base = GenericFill(db,params,static_cast<IfcCartesianTransformationOperator*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcCartesianTransformationOperator3D"); } do { // convert the 'Axis3' argument if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcCartesianTransformationOperator3D"); } do { // convert the 'Axis3' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCartesianTransformationOperator3D,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCartesianTransformationOperator3D,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Axis3, arg, db ); break; } try { GenericConvert( in->Axis3, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcCartesianTransformationOperator3D to be a `IfcDirection`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcCartesianTransformationOperator3D to be a `IfcDirection`")); }
@ -1440,13 +1439,13 @@ template <> size_t GenericFill<IfcProperty>(const DB& db, const LIST& params, If
size_t base = 0; size_t base = 0;
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcProperty"); } do { // convert the 'Name' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcProperty"); } do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProperty,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProperty,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Name, arg, db ); break; } try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProperty to be a `IfcIdentifier`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProperty to be a `IfcIdentifier`")); }
} while(0); } while(0);
do { // convert the 'Description' argument do { // convert the 'Description' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProperty,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProperty,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Description, arg, db ); break; } try { GenericConvert( in->Description, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProperty to be a `IfcText`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProperty to be a `IfcText`")); }
@ -1492,7 +1491,7 @@ template <> size_t GenericFill<IfcElementarySurface>(const DB& db, const LIST& p
size_t base = GenericFill(db,params,static_cast<IfcSurface*>(in)); size_t base = GenericFill(db,params,static_cast<IfcSurface*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcElementarySurface"); } do { // convert the 'Position' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcElementarySurface"); } do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcElementarySurface,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcElementarySurface,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; } try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcElementarySurface to be a `IfcAxis2Placement3D`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcElementarySurface to be a `IfcAxis2Placement3D`")); }
} while(0); } while(0);
@ -1510,19 +1509,19 @@ template <> size_t GenericFill<IfcBooleanResult>(const DB& db, const LIST& param
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcBooleanResult"); } do { // convert the 'Operator' argument if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcBooleanResult"); } do { // convert the 'Operator' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBooleanResult,3>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBooleanResult,3>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Operator, arg, db ); break; } try { GenericConvert( in->Operator, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcBooleanResult to be a `IfcBooleanOperator`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcBooleanResult to be a `IfcBooleanOperator`")); }
} while(0); } while(0);
do { // convert the 'FirstOperand' argument do { // convert the 'FirstOperand' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBooleanResult,3>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBooleanResult,3>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->FirstOperand, arg, db ); break; } try { GenericConvert( in->FirstOperand, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcBooleanResult to be a `IfcBooleanOperand`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcBooleanResult to be a `IfcBooleanOperand`")); }
} while(0); } while(0);
do { // convert the 'SecondOperand' argument do { // convert the 'SecondOperand' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBooleanResult,3>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBooleanResult,3>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->SecondOperand, arg, db ); break; } try { GenericConvert( in->SecondOperand, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcBooleanResult to be a `IfcBooleanOperand`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcBooleanResult to be a `IfcBooleanOperand`")); }
} while(0); } while(0);
@ -1546,7 +1545,7 @@ template <> size_t GenericFill<IfcManifoldSolidBrep>(const DB& db, const LIST& p
size_t base = GenericFill(db,params,static_cast<IfcSolidModel*>(in)); size_t base = GenericFill(db,params,static_cast<IfcSolidModel*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcManifoldSolidBrep"); } do { // convert the 'Outer' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcManifoldSolidBrep"); } do { // convert the 'Outer' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcManifoldSolidBrep,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcManifoldSolidBrep,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Outer, arg, db ); break; } try { GenericConvert( in->Outer, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcManifoldSolidBrep to be a `IfcClosedShell`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcManifoldSolidBrep to be a `IfcClosedShell`")); }
} while(0); } while(0);
@ -1779,13 +1778,13 @@ template <> size_t GenericFill<IfcProfileDef>(const DB& db, const LIST& params,
size_t base = 0; size_t base = 0;
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcProfileDef"); } do { // convert the 'ProfileType' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcProfileDef"); } do { // convert the 'ProfileType' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProfileDef,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProfileDef,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->ProfileType, arg, db ); break; } try { GenericConvert( in->ProfileType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProfileDef to be a `IfcProfileTypeEnum`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcProfileDef to be a `IfcProfileTypeEnum`")); }
} while(0); } while(0);
do { // convert the 'ProfileName' argument do { // convert the 'ProfileName' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcProfileDef,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcProfileDef,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ProfileName, arg, db ); break; } try { GenericConvert( in->ProfileName, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProfileDef to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcProfileDef to be a `IfcLabel`")); }
@ -1798,7 +1797,7 @@ template <> size_t GenericFill<IfcParameterizedProfileDef>(const DB& db, const L
size_t base = GenericFill(db,params,static_cast<IfcProfileDef*>(in)); size_t base = GenericFill(db,params,static_cast<IfcProfileDef*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcParameterizedProfileDef"); } do { // convert the 'Position' argument if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcParameterizedProfileDef"); } do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcParameterizedProfileDef,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcParameterizedProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; } try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcParameterizedProfileDef to be a `IfcAxis2Placement2D`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcParameterizedProfileDef to be a `IfcAxis2Placement2D`")); }
} while(0); } while(0);
@ -1905,7 +1904,7 @@ template <> size_t GenericFill<IfcCircleProfileDef>(const DB& db, const LIST& pa
size_t base = GenericFill(db,params,static_cast<IfcParameterizedProfileDef*>(in)); size_t base = GenericFill(db,params,static_cast<IfcParameterizedProfileDef*>(in));
if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcCircleProfileDef"); } do { // convert the 'Radius' argument if (params.GetSize() < 4) { throw STEP::TypeError("expected 4 arguments to IfcCircleProfileDef"); } do { // convert the 'Radius' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcCircleProfileDef,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcCircleProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Radius, arg, db ); break; } try { GenericConvert( in->Radius, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcCircleProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcCircleProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0); } while(0);
@ -1928,7 +1927,7 @@ template <> size_t GenericFill<IfcPlacement>(const DB& db, const LIST& params, I
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPlacement"); } do { // convert the 'Location' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPlacement"); } do { // convert the 'Location' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcPlacement,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcPlacement,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Location, arg, db ); break; } try { GenericConvert( in->Location, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPlacement to be a `IfcCartesianPoint`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPlacement to be a `IfcCartesianPoint`")); }
} while(0); } while(0);
@ -1958,7 +1957,7 @@ template <> size_t GenericFill<IfcPresentationStyle>(const DB& db, const LIST& p
size_t base = 0; size_t base = 0;
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPresentationStyle"); } do { // convert the 'Name' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcPresentationStyle"); } do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcPresentationStyle,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcPresentationStyle,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; } try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPresentationStyle to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcPresentationStyle to be a `IfcLabel`")); }
@ -1999,13 +1998,13 @@ template <> size_t GenericFill<IfcRectangleProfileDef>(const DB& db, const LIST&
size_t base = GenericFill(db,params,static_cast<IfcParameterizedProfileDef*>(in)); size_t base = GenericFill(db,params,static_cast<IfcParameterizedProfileDef*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcRectangleProfileDef"); } do { // convert the 'XDim' argument if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcRectangleProfileDef"); } do { // convert the 'XDim' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRectangleProfileDef,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRectangleProfileDef,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->XDim, arg, db ); break; } try { GenericConvert( in->XDim, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRectangleProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcRectangleProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0); } while(0);
do { // convert the 'YDim' argument do { // convert the 'YDim' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRectangleProfileDef,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRectangleProfileDef,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->YDim, arg, db ); break; } try { GenericConvert( in->YDim, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRectangleProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRectangleProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0); } while(0);
@ -2118,13 +2117,13 @@ template <> size_t GenericFill<IfcSweptAreaSolid>(const DB& db, const LIST& para
size_t base = GenericFill(db,params,static_cast<IfcSolidModel*>(in)); size_t base = GenericFill(db,params,static_cast<IfcSolidModel*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcSweptAreaSolid"); } do { // convert the 'SweptArea' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcSweptAreaSolid"); } do { // convert the 'SweptArea' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcSweptAreaSolid,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSweptAreaSolid,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->SweptArea, arg, db ); break; } try { GenericConvert( in->SweptArea, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSweptAreaSolid to be a `IfcProfileDef`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSweptAreaSolid to be a `IfcProfileDef`")); }
} while(0); } while(0);
do { // convert the 'Position' argument do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcSweptAreaSolid,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSweptAreaSolid,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; } try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcSweptAreaSolid to be a `IfcAxis2Placement3D`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcSweptAreaSolid to be a `IfcAxis2Placement3D`")); }
} while(0); } while(0);
@ -2198,13 +2197,13 @@ template <> size_t GenericFill<IfcHalfSpaceSolid>(const DB& db, const LIST& para
size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcGeometricRepresentationItem*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcHalfSpaceSolid"); } do { // convert the 'BaseSurface' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcHalfSpaceSolid"); } do { // convert the 'BaseSurface' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcHalfSpaceSolid,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcHalfSpaceSolid,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->BaseSurface, arg, db ); break; } try { GenericConvert( in->BaseSurface, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcHalfSpaceSolid to be a `IfcSurface`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcHalfSpaceSolid to be a `IfcSurface`")); }
} while(0); } while(0);
do { // convert the 'AgreementFlag' argument do { // convert the 'AgreementFlag' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcHalfSpaceSolid,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcHalfSpaceSolid,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->AgreementFlag, arg, db ); break; } try { GenericConvert( in->AgreementFlag, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcHalfSpaceSolid to be a `BOOLEAN`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcHalfSpaceSolid to be a `BOOLEAN`")); }
} while(0); } while(0);
@ -2354,7 +2353,7 @@ template <> size_t GenericFill<IfcRelDefines>(const DB& db, const LIST& params,
size_t base = GenericFill(db,params,static_cast<IfcRelationship*>(in)); size_t base = GenericFill(db,params,static_cast<IfcRelationship*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcRelDefines"); } do { // convert the 'RelatedObjects' argument if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcRelDefines"); } do { // convert the 'RelatedObjects' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRelDefines,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDefines,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->RelatedObjects, arg, db ); break; } try { GenericConvert( in->RelatedObjects, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelDefines to be a `SET [1:?] OF IfcObject`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelDefines to be a `SET [1:?] OF IfcObject`")); }
} while(0); } while(0);
@ -2366,7 +2365,7 @@ template <> size_t GenericFill<IfcRelDefinesByProperties>(const DB& db, const LI
size_t base = GenericFill(db,params,static_cast<IfcRelDefines*>(in)); size_t base = GenericFill(db,params,static_cast<IfcRelDefines*>(in));
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelDefinesByProperties"); } do { // convert the 'RelatingPropertyDefinition' argument if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelDefinesByProperties"); } do { // convert the 'RelatingPropertyDefinition' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRelDefinesByProperties,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDefinesByProperties,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->RelatingPropertyDefinition, arg, db ); break; } try { GenericConvert( in->RelatingPropertyDefinition, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelDefinesByProperties to be a `IfcPropertySetDefinition`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelDefinesByProperties to be a `IfcPropertySetDefinition`")); }
} while(0); } while(0);
@ -2399,7 +2398,7 @@ template <> size_t GenericFill<IfcArbitraryOpenProfileDef>(const DB& db, const L
size_t base = GenericFill(db,params,static_cast<IfcProfileDef*>(in)); size_t base = GenericFill(db,params,static_cast<IfcProfileDef*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcArbitraryOpenProfileDef"); } do { // convert the 'Curve' argument if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcArbitraryOpenProfileDef"); } do { // convert the 'Curve' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcArbitraryOpenProfileDef,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcArbitraryOpenProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Curve, arg, db ); break; } try { GenericConvert( in->Curve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcArbitraryOpenProfileDef to be a `IfcBoundedCurve`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcArbitraryOpenProfileDef to be a `IfcBoundedCurve`")); }
} while(0); } while(0);
@ -2565,13 +2564,13 @@ template <> size_t GenericFill<IfcRelDecomposes>(const DB& db, const LIST& param
size_t base = GenericFill(db,params,static_cast<IfcRelationship*>(in)); size_t base = GenericFill(db,params,static_cast<IfcRelationship*>(in));
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelDecomposes"); } do { // convert the 'RelatingObject' argument if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcRelDecomposes"); } do { // convert the 'RelatingObject' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRelDecomposes,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDecomposes,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->RelatingObject, arg, db ); break; } try { GenericConvert( in->RelatingObject, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelDecomposes to be a `IfcObjectDefinition`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcRelDecomposes to be a `IfcObjectDefinition`")); }
} while(0); } while(0);
do { // convert the 'RelatedObjects' argument do { // convert the 'RelatedObjects' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRelDecomposes,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRelDecomposes,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->RelatedObjects, arg, db ); break; } try { GenericConvert( in->RelatedObjects, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelDecomposes to be a `SET [1:?] OF IfcObjectDefinition`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcRelDecomposes to be a `SET [1:?] OF IfcObjectDefinition`")); }
} while(0); } while(0);
@ -2653,13 +2652,13 @@ template <> size_t GenericFill<IfcNamedUnit>(const DB& db, const LIST& params, I
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcNamedUnit"); } do { // convert the 'Dimensions' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcNamedUnit"); } do { // convert the 'Dimensions' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcNamedUnit,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcNamedUnit,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Dimensions, arg, db ); break; } try { GenericConvert( in->Dimensions, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcNamedUnit to be a `IfcDimensionalExponents`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcNamedUnit to be a `IfcDimensionalExponents`")); }
} while(0); } while(0);
do { // convert the 'UnitType' argument do { // convert the 'UnitType' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcNamedUnit,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcNamedUnit,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->UnitType, arg, db ); break; } try { GenericConvert( in->UnitType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcNamedUnit to be a `IfcUnitEnum`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcNamedUnit to be a `IfcUnitEnum`")); }
} while(0); } while(0);
@ -2713,14 +2712,14 @@ template <> size_t GenericFill<IfcSpatialStructureElement>(const DB& db, const L
size_t base = GenericFill(db,params,static_cast<IfcProduct*>(in)); size_t base = GenericFill(db,params,static_cast<IfcProduct*>(in));
if (params.GetSize() < 9) { throw STEP::TypeError("expected 9 arguments to IfcSpatialStructureElement"); } do { // convert the 'LongName' argument if (params.GetSize() < 9) { throw STEP::TypeError("expected 9 arguments to IfcSpatialStructureElement"); } do { // convert the 'LongName' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcSpatialStructureElement,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSpatialStructureElement,2>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->LongName, arg, db ); break; } try { GenericConvert( in->LongName, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcSpatialStructureElement to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcSpatialStructureElement to be a `IfcLabel`")); }
} while(0); } while(0);
do { // convert the 'CompositionType' argument do { // convert the 'CompositionType' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcSpatialStructureElement,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSpatialStructureElement,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->CompositionType, arg, db ); break; } try { GenericConvert( in->CompositionType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 8 to IfcSpatialStructureElement to be a `IfcElementCompositionEnum`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 8 to IfcSpatialStructureElement to be a `IfcElementCompositionEnum`")); }
} while(0); } while(0);
@ -2756,7 +2755,7 @@ template <> size_t GenericFill<IfcConnectedFaceSet>(const DB& db, const LIST& pa
size_t base = GenericFill(db,params,static_cast<IfcTopologicalRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcTopologicalRepresentationItem*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcConnectedFaceSet"); } do { // convert the 'CfsFaces' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcConnectedFaceSet"); } do { // convert the 'CfsFaces' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcConnectedFaceSet,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcConnectedFaceSet,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->CfsFaces, arg, db ); break; } try { GenericConvert( in->CfsFaces, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcConnectedFaceSet to be a `SET [1:?] OF IfcFace`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcConnectedFaceSet to be a `SET [1:?] OF IfcFace`")); }
} while(0); } while(0);
@ -2782,7 +2781,7 @@ template <> size_t GenericFill<IfcConic>(const DB& db, const LIST& params, IfcCo
size_t base = GenericFill(db,params,static_cast<IfcCurve*>(in)); size_t base = GenericFill(db,params,static_cast<IfcCurve*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcConic"); } do { // convert the 'Position' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcConic"); } do { // convert the 'Position' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcConic,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcConic,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Position, arg, db ); break; } try { GenericConvert( in->Position, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcConic to be a `IfcAxis2Placement`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcConic to be a `IfcAxis2Placement`")); }
} while(0); } while(0);
@ -2829,31 +2828,31 @@ template <> size_t GenericFill<IfcIShapeProfileDef>(const DB& db, const LIST& pa
size_t base = GenericFill(db,params,static_cast<IfcParameterizedProfileDef*>(in)); size_t base = GenericFill(db,params,static_cast<IfcParameterizedProfileDef*>(in));
if (params.GetSize() < 8) { throw STEP::TypeError("expected 8 arguments to IfcIShapeProfileDef"); } do { // convert the 'OverallWidth' argument if (params.GetSize() < 8) { throw STEP::TypeError("expected 8 arguments to IfcIShapeProfileDef"); } do { // convert the 'OverallWidth' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcIShapeProfileDef,5>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->OverallWidth, arg, db ); break; } try { GenericConvert( in->OverallWidth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0); } while(0);
do { // convert the 'OverallDepth' argument do { // convert the 'OverallDepth' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcIShapeProfileDef,5>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->OverallDepth, arg, db ); break; } try { GenericConvert( in->OverallDepth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0); } while(0);
do { // convert the 'WebThickness' argument do { // convert the 'WebThickness' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcIShapeProfileDef,5>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->WebThickness, arg, db ); break; } try { GenericConvert( in->WebThickness, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0); } while(0);
do { // convert the 'FlangeThickness' argument do { // convert the 'FlangeThickness' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcIShapeProfileDef,5>::aux_is_derived[3]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[3]=true; break; }
try { GenericConvert( in->FlangeThickness, arg, db ); break; } try { GenericConvert( in->FlangeThickness, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 6 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
} while(0); } while(0);
do { // convert the 'FilletRadius' argument do { // convert the 'FilletRadius' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcIShapeProfileDef,5>::aux_is_derived[4]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcIShapeProfileDef,5>::aux_is_derived[4]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->FilletRadius, arg, db ); break; } try { GenericConvert( in->FilletRadius, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 7 to IfcIShapeProfileDef to be a `IfcPositiveLengthMeasure`")); }
@ -2978,20 +2977,20 @@ template <> size_t GenericFill<IfcStyledItem>(const DB& db, const LIST& params,
size_t base = GenericFill(db,params,static_cast<IfcRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcRepresentationItem*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcStyledItem"); } do { // convert the 'Item' argument if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcStyledItem"); } do { // convert the 'Item' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcStyledItem,3>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcStyledItem,3>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Item, arg, db ); break; } try { GenericConvert( in->Item, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcStyledItem to be a `IfcRepresentationItem`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcStyledItem to be a `IfcRepresentationItem`")); }
} while(0); } while(0);
do { // convert the 'Styles' argument do { // convert the 'Styles' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcStyledItem,3>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcStyledItem,3>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->Styles, arg, db ); break; } try { GenericConvert( in->Styles, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcStyledItem to be a `SET [1:?] OF IfcPresentationStyleAssignment`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcStyledItem to be a `SET [1:?] OF IfcPresentationStyleAssignment`")); }
} while(0); } while(0);
do { // convert the 'Name' argument do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcStyledItem,3>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcStyledItem,3>::aux_is_derived[2]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; } try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcStyledItem to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcStyledItem to be a `IfcLabel`")); }
@ -3018,7 +3017,7 @@ template <> size_t GenericFill<IfcArbitraryClosedProfileDef>(const DB& db, const
size_t base = GenericFill(db,params,static_cast<IfcProfileDef*>(in)); size_t base = GenericFill(db,params,static_cast<IfcProfileDef*>(in));
if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcArbitraryClosedProfileDef"); } do { // convert the 'OuterCurve' argument if (params.GetSize() < 3) { throw STEP::TypeError("expected 3 arguments to IfcArbitraryClosedProfileDef"); } do { // convert the 'OuterCurve' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcArbitraryClosedProfileDef,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcArbitraryClosedProfileDef,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->OuterCurve, arg, db ); break; } try { GenericConvert( in->OuterCurve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcArbitraryClosedProfileDef to be a `IfcCurve`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcArbitraryClosedProfileDef to be a `IfcCurve`")); }
} while(0); } while(0);
@ -3106,7 +3105,7 @@ template <> size_t GenericFill<IfcSurfaceStyleShading>(const DB& db, const LIST&
size_t base = 0; size_t base = 0;
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcSurfaceStyleShading"); } do { // convert the 'SurfaceColour' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcSurfaceStyleShading"); } do { // convert the 'SurfaceColour' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcSurfaceStyleShading,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcSurfaceStyleShading,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->SurfaceColour, arg, db ); break; } try { GenericConvert( in->SurfaceColour, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSurfaceStyleShading to be a `IfcColourRgb`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcSurfaceStyleShading to be a `IfcColourRgb`")); }
} while(0); } while(0);

33
code/IFCReaderGen2.cpp → code/Importer/IFC/IFCReaderGen2_2x3.cpp
View File

@ -41,10 +41,11 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//#include "AssimpPCH.h" //#include "AssimpPCH.h"
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
#include "IFCReaderGen.h" #include "IFCReaderGen_2x3.h"
namespace Assimp { namespace Assimp {
using namespace IFC; using namespace IFC;
using namespace ::Assimp::IFC::Schema_2x3;
namespace STEP { namespace STEP {
@ -111,7 +112,7 @@ template <> size_t GenericFill<IfcFace>(const DB& db, const LIST& params, IfcFac
size_t base = GenericFill(db,params,static_cast<IfcTopologicalRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcTopologicalRepresentationItem*>(in));
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcFace"); } do { // convert the 'Bounds' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcFace"); } do { // convert the 'Bounds' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcFace,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcFace,1>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Bounds, arg, db ); break; } try { GenericConvert( in->Bounds, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcFace to be a `SET [1:?] OF IfcFaceBound`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcFace to be a `SET [1:?] OF IfcFaceBound`")); }
} while(0); } while(0);
@ -165,7 +166,7 @@ template <> size_t GenericFill<IfcColourSpecification>(const DB& db, const LIST&
size_t base = 0; size_t base = 0;
if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcColourSpecification"); } do { // convert the 'Name' argument if (params.GetSize() < 1) { throw STEP::TypeError("expected 1 arguments to IfcColourSpecification"); } do { // convert the 'Name' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcColourSpecification,1>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcColourSpecification,1>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Name, arg, db ); break; } try { GenericConvert( in->Name, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcColourSpecification to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcColourSpecification to be a `IfcLabel`")); }
@ -405,31 +406,31 @@ template <> size_t GenericFill<IfcBSplineCurve>(const DB& db, const LIST& params
size_t base = GenericFill(db,params,static_cast<IfcBoundedCurve*>(in)); size_t base = GenericFill(db,params,static_cast<IfcBoundedCurve*>(in));
if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcBSplineCurve"); } do { // convert the 'Degree' argument if (params.GetSize() < 5) { throw STEP::TypeError("expected 5 arguments to IfcBSplineCurve"); } do { // convert the 'Degree' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBSplineCurve,5>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Degree, arg, db ); break; } try { GenericConvert( in->Degree, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcBSplineCurve to be a `INTEGER`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcBSplineCurve to be a `INTEGER`")); }
} while(0); } while(0);
do { // convert the 'ControlPointsList' argument do { // convert the 'ControlPointsList' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBSplineCurve,5>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->ControlPointsList, arg, db ); break; } try { GenericConvert( in->ControlPointsList, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcBSplineCurve to be a `LIST [2:?] OF IfcCartesianPoint`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcBSplineCurve to be a `LIST [2:?] OF IfcCartesianPoint`")); }
} while(0); } while(0);
do { // convert the 'CurveForm' argument do { // convert the 'CurveForm' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBSplineCurve,5>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->CurveForm, arg, db ); break; } try { GenericConvert( in->CurveForm, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcBSplineCurve to be a `IfcBSplineCurveForm`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcBSplineCurve to be a `IfcBSplineCurveForm`")); }
} while(0); } while(0);
do { // convert the 'ClosedCurve' argument do { // convert the 'ClosedCurve' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBSplineCurve,5>::aux_is_derived[3]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[3]=true; break; }
try { GenericConvert( in->ClosedCurve, arg, db ); break; } try { GenericConvert( in->ClosedCurve, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcBSplineCurve to be a `LOGICAL`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcBSplineCurve to be a `LOGICAL`")); }
} while(0); } while(0);
do { // convert the 'SelfIntersect' argument do { // convert the 'SelfIntersect' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcBSplineCurve,5>::aux_is_derived[4]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcBSplineCurve,5>::aux_is_derived[4]=true; break; }
try { GenericConvert( in->SelfIntersect, arg, db ); break; } try { GenericConvert( in->SelfIntersect, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcBSplineCurve to be a `LOGICAL`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcBSplineCurve to be a `LOGICAL`")); }
} while(0); } while(0);
@ -708,14 +709,14 @@ template <> size_t GenericFill<IfcRepresentationContext>(const DB& db, const LIS
size_t base = 0; size_t base = 0;
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcRepresentationContext"); } do { // convert the 'ContextIdentifier' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcRepresentationContext"); } do { // convert the 'ContextIdentifier' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRepresentationContext,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentationContext,2>::aux_is_derived[0]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ContextIdentifier, arg, db ); break; } try { GenericConvert( in->ContextIdentifier, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRepresentationContext to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcRepresentationContext to be a `IfcLabel`")); }
} while(0); } while(0);
do { // convert the 'ContextType' argument do { // convert the 'ContextType' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcRepresentationContext,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcRepresentationContext,2>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->ContextType, arg, db ); break; } try { GenericConvert( in->ContextType, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRepresentationContext to be a `IfcLabel`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcRepresentationContext to be a `IfcLabel`")); }
@ -728,26 +729,26 @@ template <> size_t GenericFill<IfcGeometricRepresentationContext>(const DB& db,
size_t base = GenericFill(db,params,static_cast<IfcRepresentationContext*>(in)); size_t base = GenericFill(db,params,static_cast<IfcRepresentationContext*>(in));
if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcGeometricRepresentationContext"); } do { // convert the 'CoordinateSpaceDimension' argument if (params.GetSize() < 6) { throw STEP::TypeError("expected 6 arguments to IfcGeometricRepresentationContext"); } do { // convert the 'CoordinateSpaceDimension' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcGeometricRepresentationContext,4>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->CoordinateSpaceDimension, arg, db ); break; } try { GenericConvert( in->CoordinateSpaceDimension, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcGeometricRepresentationContext to be a `IfcDimensionCount`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 2 to IfcGeometricRepresentationContext to be a `IfcDimensionCount`")); }
} while(0); } while(0);
do { // convert the 'Precision' argument do { // convert the 'Precision' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcGeometricRepresentationContext,4>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[1]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->Precision, arg, db ); break; } try { GenericConvert( in->Precision, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcGeometricRepresentationContext to be a `REAL`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 3 to IfcGeometricRepresentationContext to be a `REAL`")); }
} while(0); } while(0);
do { // convert the 'WorldCoordinateSystem' argument do { // convert the 'WorldCoordinateSystem' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcGeometricRepresentationContext,4>::aux_is_derived[2]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[2]=true; break; }
try { GenericConvert( in->WorldCoordinateSystem, arg, db ); break; } try { GenericConvert( in->WorldCoordinateSystem, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcGeometricRepresentationContext to be a `IfcAxis2Placement`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 4 to IfcGeometricRepresentationContext to be a `IfcAxis2Placement`")); }
} while(0); } while(0);
do { // convert the 'TrueNorth' argument do { // convert the 'TrueNorth' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcGeometricRepresentationContext,4>::aux_is_derived[3]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcGeometricRepresentationContext,4>::aux_is_derived[3]=true; break; }
if (dynamic_cast<const UNSET*>(&*arg)) break; if (dynamic_cast<const UNSET*>(&*arg)) break;
try { GenericConvert( in->TrueNorth, arg, db ); break; } try { GenericConvert( in->TrueNorth, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcGeometricRepresentationContext to be a `IfcDirection`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 5 to IfcGeometricRepresentationContext to be a `IfcDirection`")); }
@ -1165,13 +1166,13 @@ template <> size_t GenericFill<IfcFaceBound>(const DB& db, const LIST& params, I
size_t base = GenericFill(db,params,static_cast<IfcTopologicalRepresentationItem*>(in)); size_t base = GenericFill(db,params,static_cast<IfcTopologicalRepresentationItem*>(in));
if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcFaceBound"); } do { // convert the 'Bound' argument if (params.GetSize() < 2) { throw STEP::TypeError("expected 2 arguments to IfcFaceBound"); } do { // convert the 'Bound' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcFaceBound,2>::aux_is_derived[0]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcFaceBound,2>::aux_is_derived[0]=true; break; }
try { GenericConvert( in->Bound, arg, db ); break; } try { GenericConvert( in->Bound, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcFaceBound to be a `IfcLoop`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 0 to IfcFaceBound to be a `IfcLoop`")); }
} while(0); } while(0);
do { // convert the 'Orientation' argument do { // convert the 'Orientation' argument
std::shared_ptr<const DataType> arg = params[base++]; std::shared_ptr<const DataType> arg = params[base++];
if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::IfcFaceBound,2>::aux_is_derived[1]=true; break; } if (dynamic_cast<const ISDERIVED*>(&*arg)) { in->ObjectHelper<Assimp::IFC::Schema_2x3::IfcFaceBound,2>::aux_is_derived[1]=true; break; }
try { GenericConvert( in->Orientation, arg, db ); break; } try { GenericConvert( in->Orientation, arg, db ); break; }
catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcFaceBound to be a `BOOLEAN`")); } catch (const TypeError& t) { throw TypeError(t.what() + std::string(" - expected argument 1 to IfcFaceBound to be a `BOOLEAN`")); }
} while(0); } while(0);

9
code/IFCReaderGen.h → code/Importer/IFC/IFCReaderGen_2x3.h
View File

@ -43,10 +43,12 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef INCLUDED_IFC_READER_GEN_H #ifndef INCLUDED_IFC_READER_GEN_H
#define INCLUDED_IFC_READER_GEN_H #define INCLUDED_IFC_READER_GEN_H
#include "STEPFile.h" #include "code/STEPFile.h"
namespace Assimp { namespace Assimp {
namespace IFC { namespace IFC {
namespace Schema_2x3 {
using namespace STEP; using namespace STEP;
using namespace STEP::EXPRESS; using namespace STEP::EXPRESS;
@ -3912,15 +3914,16 @@ namespace IFC {
}; };
void GetSchema(EXPRESS::ConversionSchema& out); void GetSchema(EXPRESS::ConversionSchema& out);
} //! Schema_2x3
} //! IFC } //! IFC
namespace STEP { namespace STEP {
// ****************************************************************************** // ******************************************************************************
// Converter stubs // Converter stubs
// ****************************************************************************** // ******************************************************************************
#define DECL_CONV_STUB(type) template <> size_t GenericFill<IFC::type>(const STEP::DB& db, const EXPRESS::LIST& params, IFC::type* in) #define DECL_CONV_STUB(type) template <> size_t GenericFill<IFC::Schema_2x3::type>(const STEP::DB& db, const EXPRESS::LIST& params, IFC::Schema_2x3::type* in)
DECL_CONV_STUB(IfcRepresentationItem); DECL_CONV_STUB(IfcRepresentationItem);
DECL_CONV_STUB(IfcGeometricRepresentationItem); DECL_CONV_STUB(IfcGeometricRepresentationItem);

6206
code/Importer/IFC/IFCReaderGen_4.cpp 100644
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File diff suppressed because it is too large Load Diff

5449
code/Importer/IFC/IFCReaderGen_4.h 100644
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File diff suppressed because it is too large Load Diff

158
code/IFCUtil.cpp → code/Importer/IFC/IFCUtil.cpp
View File

@ -47,9 +47,9 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
#include "IFCUtil.h" #include "code/Importer/IFC/IFCUtil.h"
#include "PolyTools.h" #include "code/PolyTools.h"
#include "ProcessHelper.h" #include "code/ProcessHelper.h"
#include <assimp/Defines.h> #include <assimp/Defines.h>
namespace Assimp { namespace Assimp {
@ -70,31 +70,31 @@ void TempOpening::Transform(const IfcMatrix4& mat)
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
aiMesh* TempMesh::ToMesh() aiMesh* TempMesh::ToMesh()
{ {
ai_assert(verts.size() == std::accumulate(vertcnt.begin(),vertcnt.end(),size_t(0))); ai_assert(mVerts.size() == std::accumulate(mVertcnt.begin(),mVertcnt.end(),size_t(0)));
if (verts.empty()) { if (mVerts.empty()) {
return NULL; return NULL;
} }
std::unique_ptr<aiMesh> mesh(new aiMesh()); std::unique_ptr<aiMesh> mesh(new aiMesh());
// copy vertices // copy vertices
mesh->mNumVertices = static_cast<unsigned int>(verts.size()); mesh->mNumVertices = static_cast<unsigned int>(mVerts.size());
mesh->mVertices = new aiVector3D[mesh->mNumVertices]; mesh->mVertices = new aiVector3D[mesh->mNumVertices];
std::copy(verts.begin(),verts.end(),mesh->mVertices); std::copy(mVerts.begin(),mVerts.end(),mesh->mVertices);
// and build up faces // and build up faces
mesh->mNumFaces = static_cast<unsigned int>(vertcnt.size()); mesh->mNumFaces = static_cast<unsigned int>(mVertcnt.size());
mesh->mFaces = new aiFace[mesh->mNumFaces]; mesh->mFaces = new aiFace[mesh->mNumFaces];
for(unsigned int i = 0,n=0, acc = 0; i < mesh->mNumFaces; ++n) { for(unsigned int i = 0,n=0, acc = 0; i < mesh->mNumFaces; ++n) {
aiFace& f = mesh->mFaces[i]; aiFace& f = mesh->mFaces[i];
if (!vertcnt[n]) { if (!mVertcnt[n]) {
--mesh->mNumFaces; --mesh->mNumFaces;
continue; continue;
} }
f.mNumIndices = vertcnt[n]; f.mNumIndices = mVertcnt[n];
f.mIndices = new unsigned int[f.mNumIndices]; f.mIndices = new unsigned int[f.mNumIndices];
for(unsigned int a = 0; a < f.mNumIndices; ++a) { for(unsigned int a = 0; a < f.mNumIndices; ++a) {
f.mIndices[a] = acc++; f.mIndices[a] = acc++;
@ -109,14 +109,14 @@ aiMesh* TempMesh::ToMesh()
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void TempMesh::Clear() void TempMesh::Clear()
{ {
verts.clear(); mVerts.clear();
vertcnt.clear(); mVertcnt.clear();
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void TempMesh::Transform(const IfcMatrix4& mat) void TempMesh::Transform(const IfcMatrix4& mat)
{ {
for(IfcVector3& v : verts) { for(IfcVector3& v : mVerts) {
v *= mat; v *= mat;
} }
} }
@ -124,14 +124,14 @@ void TempMesh::Transform(const IfcMatrix4& mat)
// ------------------------------------------------------------------------------ // ------------------------------------------------------------------------------
IfcVector3 TempMesh::Center() const IfcVector3 TempMesh::Center() const
{ {
return (verts.size() == 0) ? IfcVector3(0.0f, 0.0f, 0.0f) : (std::accumulate(verts.begin(),verts.end(),IfcVector3()) / static_cast<IfcFloat>(verts.size())); return (mVerts.size() == 0) ? IfcVector3(0.0f, 0.0f, 0.0f) : (std::accumulate(mVerts.begin(),mVerts.end(),IfcVector3()) / static_cast<IfcFloat>(mVerts.size()));
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void TempMesh::Append(const TempMesh& other) void TempMesh::Append(const TempMesh& other)
{ {
verts.insert(verts.end(),other.verts.begin(),other.verts.end()); mVerts.insert(mVerts.end(),other.mVerts.begin(),other.mVerts.end());
vertcnt.insert(vertcnt.end(),other.vertcnt.begin(),other.vertcnt.end()); mVertcnt.insert(mVertcnt.end(),other.mVertcnt.begin(),other.mVertcnt.end());
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
@ -147,13 +147,13 @@ void TempMesh::RemoveDegenerates()
bool drop = false; bool drop = false;
size_t inor = 0; size_t inor = 0;
std::vector<IfcVector3>::iterator vit = verts.begin(); std::vector<IfcVector3>::iterator vit = mVerts.begin();
for (std::vector<unsigned int>::iterator it = vertcnt.begin(); it != vertcnt.end(); ++inor) { for (std::vector<unsigned int>::iterator it = mVertcnt.begin(); it != mVertcnt.end(); ++inor) {
const unsigned int pcount = *it; const unsigned int pcount = *it;
if (normals[inor].SquareLength() < 1e-10f) { if (normals[inor].SquareLength() < 1e-10f) {
it = vertcnt.erase(it); it = mVertcnt.erase(it);
vit = verts.erase(vit, vit + pcount); vit = mVerts.erase(vit, vit + pcount);
drop = true; drop = true;
continue; continue;
@ -191,24 +191,24 @@ void TempMesh::ComputePolygonNormals(std::vector<IfcVector3>& normals,
size_t ofs) const size_t ofs) const
{ {
size_t max_vcount = 0; size_t max_vcount = 0;
std::vector<unsigned int>::const_iterator begin = vertcnt.begin()+ofs, end = vertcnt.end(), iit; std::vector<unsigned int>::const_iterator begin = mVertcnt.begin()+ofs, end = mVertcnt.end(), iit;
for(iit = begin; iit != end; ++iit) { for(iit = begin; iit != end; ++iit) {
max_vcount = std::max(max_vcount,static_cast<size_t>(*iit)); max_vcount = std::max(max_vcount,static_cast<size_t>(*iit));
} }
std::vector<IfcFloat> temp((max_vcount+2)*4); std::vector<IfcFloat> temp((max_vcount+2)*4);
normals.reserve( normals.size() + vertcnt.size()-ofs ); normals.reserve( normals.size() + mVertcnt.size()-ofs );
// `NewellNormal()` currently has a relatively strange interface and need to // `NewellNormal()` currently has a relatively strange interface and need to
// re-structure things a bit to meet them. // re-structure things a bit to meet them.
size_t vidx = std::accumulate(vertcnt.begin(),begin,0); size_t vidx = std::accumulate(mVertcnt.begin(),begin,0);
for(iit = begin; iit != end; vidx += *iit++) { for(iit = begin; iit != end; vidx += *iit++) {
if (!*iit) { if (!*iit) {
normals.push_back(IfcVector3()); normals.push_back(IfcVector3());
continue; continue;
} }
for(size_t vofs = 0, cnt = 0; vofs < *iit; ++vofs) { for(size_t vofs = 0, cnt = 0; vofs < *iit; ++vofs) {
const IfcVector3& v = verts[vidx+vofs]; const IfcVector3& v = mVerts[vidx+vofs];
temp[cnt++] = v.x; temp[cnt++] = v.x;
temp[cnt++] = v.y; temp[cnt++] = v.y;
temp[cnt++] = v.z; temp[cnt++] = v.z;
@ -233,7 +233,7 @@ void TempMesh::ComputePolygonNormals(std::vector<IfcVector3>& normals,
// Compute the normal of the last polygon in the given mesh // Compute the normal of the last polygon in the given mesh
IfcVector3 TempMesh::ComputeLastPolygonNormal(bool normalize) const IfcVector3 TempMesh::ComputeLastPolygonNormal(bool normalize) const
{ {
return ComputePolygonNormal(&verts[verts.size() - vertcnt.back()], vertcnt.back(), normalize); return ComputePolygonNormal(&mVerts[mVerts.size() - mVertcnt.back()], mVertcnt.back(), normalize);
} }
struct CompareVector struct CompareVector
@ -258,27 +258,27 @@ void TempMesh::FixupFaceOrientation()
const IfcVector3 vavg = Center(); const IfcVector3 vavg = Center();
// create a list of start indices for all faces to allow random access to faces // create a list of start indices for all faces to allow random access to faces
std::vector<size_t> faceStartIndices(vertcnt.size()); std::vector<size_t> faceStartIndices(mVertcnt.size());
for( size_t i = 0, a = 0; a < vertcnt.size(); i += vertcnt[a], ++a ) for( size_t i = 0, a = 0; a < mVertcnt.size(); i += mVertcnt[a], ++a )
faceStartIndices[a] = i; faceStartIndices[a] = i;
// list all faces on a vertex // list all faces on a vertex
std::map<IfcVector3, std::vector<size_t>, CompareVector> facesByVertex; std::map<IfcVector3, std::vector<size_t>, CompareVector> facesByVertex;
for( size_t a = 0; a < vertcnt.size(); ++a ) for( size_t a = 0; a < mVertcnt.size(); ++a )
{ {
for( size_t b = 0; b < vertcnt[a]; ++b ) for( size_t b = 0; b < mVertcnt[a]; ++b )
facesByVertex[verts[faceStartIndices[a] + b]].push_back(a); facesByVertex[mVerts[faceStartIndices[a] + b]].push_back(a);
} }
// determine neighbourhood for all polys // determine neighbourhood for all polys
std::vector<size_t> neighbour(verts.size(), SIZE_MAX); std::vector<size_t> neighbour(mVerts.size(), SIZE_MAX);
std::vector<size_t> tempIntersect(10); std::vector<size_t> tempIntersect(10);
for( size_t a = 0; a < vertcnt.size(); ++a ) for( size_t a = 0; a < mVertcnt.size(); ++a )
{ {
for( size_t b = 0; b < vertcnt[a]; ++b ) for( size_t b = 0; b < mVertcnt[a]; ++b )
{ {
size_t ib = faceStartIndices[a] + b, nib = faceStartIndices[a] + (b + 1) % vertcnt[a]; size_t ib = faceStartIndices[a] + b, nib = faceStartIndices[a] + (b + 1) % mVertcnt[a];
const std::vector<size_t>& facesOnB = facesByVertex[verts[ib]]; const std::vector<size_t>& facesOnB = facesByVertex[mVerts[ib]];
const std::vector<size_t>& facesOnNB = facesByVertex[verts[nib]]; const std::vector<size_t>& facesOnNB = facesByVertex[mVerts[nib]];
// there should be exactly one or two faces which appear in both lists. Our face and the other side // there should be exactly one or two faces which appear in both lists. Our face and the other side
std::vector<size_t>::iterator sectstart = tempIntersect.begin(); std::vector<size_t>::iterator sectstart = tempIntersect.begin();
std::vector<size_t>::iterator sectend = std::set_intersection( std::vector<size_t>::iterator sectend = std::set_intersection(
@ -295,33 +295,33 @@ void TempMesh::FixupFaceOrientation()
// now we're getting started. We take the face which is the farthest away from the center. This face is most probably // now we're getting started. We take the face which is the farthest away from the center. This face is most probably
// facing outwards. So we reverse this face to point outwards in relation to the center. Then we adapt neighbouring // facing outwards. So we reverse this face to point outwards in relation to the center. Then we adapt neighbouring
// faces to have the same winding until all faces have been tested. // faces to have the same winding until all faces have been tested.
std::vector<bool> faceDone(vertcnt.size(), false); std::vector<bool> faceDone(mVertcnt.size(), false);
while( std::count(faceDone.begin(), faceDone.end(), false) != 0 ) while( std::count(faceDone.begin(), faceDone.end(), false) != 0 )
{ {
// find the farthest of the remaining faces // find the farthest of the remaining faces
size_t farthestIndex = SIZE_MAX; size_t farthestIndex = SIZE_MAX;
IfcFloat farthestDistance = -1.0; IfcFloat farthestDistance = -1.0;
for( size_t a = 0; a < vertcnt.size(); ++a ) for( size_t a = 0; a < mVertcnt.size(); ++a )
{ {
if( faceDone[a] ) if( faceDone[a] )
continue; continue;
IfcVector3 faceCenter = std::accumulate(verts.begin() + faceStartIndices[a], IfcVector3 faceCenter = std::accumulate(mVerts.begin() + faceStartIndices[a],
verts.begin() + faceStartIndices[a] + vertcnt[a], IfcVector3(0.0)) / IfcFloat(vertcnt[a]); mVerts.begin() + faceStartIndices[a] + mVertcnt[a], IfcVector3(0.0)) / IfcFloat(mVertcnt[a]);
IfcFloat dst = (faceCenter - vavg).SquareLength(); IfcFloat dst = (faceCenter - vavg).SquareLength();
if( dst > farthestDistance ) { farthestDistance = dst; farthestIndex = a; } if( dst > farthestDistance ) { farthestDistance = dst; farthestIndex = a; }
} }
// calculate its normal and reverse the poly if its facing towards the mesh center // calculate its normal and reverse the poly if its facing towards the mesh center
IfcVector3 farthestNormal = ComputePolygonNormal(verts.data() + faceStartIndices[farthestIndex], vertcnt[farthestIndex]); IfcVector3 farthestNormal = ComputePolygonNormal(mVerts.data() + faceStartIndices[farthestIndex], mVertcnt[farthestIndex]);
IfcVector3 farthestCenter = std::accumulate(verts.begin() + faceStartIndices[farthestIndex], IfcVector3 farthestCenter = std::accumulate(mVerts.begin() + faceStartIndices[farthestIndex],
verts.begin() + faceStartIndices[farthestIndex] + vertcnt[farthestIndex], IfcVector3(0.0)) mVerts.begin() + faceStartIndices[farthestIndex] + mVertcnt[farthestIndex], IfcVector3(0.0))
/ IfcFloat(vertcnt[farthestIndex]); / IfcFloat(mVertcnt[farthestIndex]);
// We accapt a bit of negative orientation without reversing. In case of doubt, prefer the orientation given in // We accapt a bit of negative orientation without reversing. In case of doubt, prefer the orientation given in
// the file. // the file.
if( (farthestNormal * (farthestCenter - vavg).Normalize()) < -0.4 ) if( (farthestNormal * (farthestCenter - vavg).Normalize()) < -0.4 )
{ {
size_t fsi = faceStartIndices[farthestIndex], fvc = vertcnt[farthestIndex]; size_t fsi = faceStartIndices[farthestIndex], fvc = mVertcnt[farthestIndex];
std::reverse(verts.begin() + fsi, verts.begin() + fsi + fvc); std::reverse(mVerts.begin() + fsi, mVerts.begin() + fsi + fvc);
std::reverse(neighbour.begin() + fsi, neighbour.begin() + fsi + fvc); std::reverse(neighbour.begin() + fsi, neighbour.begin() + fsi + fvc);
// because of the neighbour index belonging to the edge starting with the point at the same index, we need to // because of the neighbour index belonging to the edge starting with the point at the same index, we need to
// cycle the neighbours through to match the edges again. // cycle the neighbours through to match the edges again.
@ -339,7 +339,7 @@ void TempMesh::FixupFaceOrientation()
while( !todo.empty() ) while( !todo.empty() )
{ {
size_t tdf = todo.back(); size_t tdf = todo.back();
size_t vsi = faceStartIndices[tdf], vc = vertcnt[tdf]; size_t vsi = faceStartIndices[tdf], vc = mVertcnt[tdf];
todo.pop_back(); todo.pop_back();
// check its neighbours // check its neighbours
@ -350,19 +350,19 @@ void TempMesh::FixupFaceOrientation()
if( nbi == SIZE_MAX || faceDone[nbi] ) if( nbi == SIZE_MAX || faceDone[nbi] )
continue; continue;
const IfcVector3& vp = verts[vsi + a]; const IfcVector3& vp = mVerts[vsi + a];
size_t nbvsi = faceStartIndices[nbi], nbvc = vertcnt[nbi]; size_t nbvsi = faceStartIndices[nbi], nbvc = mVertcnt[nbi];
std::vector<IfcVector3>::iterator it = std::find_if(verts.begin() + nbvsi, verts.begin() + nbvsi + nbvc, FindVector(vp)); std::vector<IfcVector3>::iterator it = std::find_if(mVerts.begin() + nbvsi, mVerts.begin() + nbvsi + nbvc, FindVector(vp));
ai_assert(it != verts.begin() + nbvsi + nbvc); ai_assert(it != mVerts.begin() + nbvsi + nbvc);
size_t nb_vidx = std::distance(verts.begin() + nbvsi, it); size_t nb_vidx = std::distance(mVerts.begin() + nbvsi, it);
// two faces winded in the same direction should have a crossed edge, where one face has p0->p1 and the other // two faces winded in the same direction should have a crossed edge, where one face has p0->p1 and the other
// has p1'->p0'. If the next point on the neighbouring face is also the next on the current face, we need // has p1'->p0'. If the next point on the neighbouring face is also the next on the current face, we need
// to reverse the neighbour // to reverse the neighbour
nb_vidx = (nb_vidx + 1) % nbvc; nb_vidx = (nb_vidx + 1) % nbvc;
size_t oursideidx = (a + 1) % vc; size_t oursideidx = (a + 1) % vc;
if( FuzzyVectorCompare(1e-6)(verts[vsi + oursideidx], verts[nbvsi + nb_vidx]) ) if( FuzzyVectorCompare(1e-6)(mVerts[vsi + oursideidx], mVerts[nbvsi + nb_vidx]) )
{ {
std::reverse(verts.begin() + nbvsi, verts.begin() + nbvsi + nbvc); std::reverse(mVerts.begin() + nbvsi, mVerts.begin() + nbvsi + nbvc);
std::reverse(neighbour.begin() + nbvsi, neighbour.begin() + nbvsi + nbvc); std::reverse(neighbour.begin() + nbvsi, neighbour.begin() + nbvsi + nbvc);
for( size_t a = 0; a < nbvc - 1; ++a ) for( size_t a = 0; a < nbvc - 1; ++a )
std::swap(neighbour[nbvsi + a], neighbour[nbvsi + a + 1]); std::swap(neighbour[nbvsi + a], neighbour[nbvsi + a + 1]);
@ -379,12 +379,10 @@ void TempMesh::FixupFaceOrientation()
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void TempMesh::RemoveAdjacentDuplicates() void TempMesh::RemoveAdjacentDuplicates() {
{
bool drop = false; bool drop = false;
std::vector<IfcVector3>::iterator base = verts.begin(); std::vector<IfcVector3>::iterator base = mVerts.begin();
for(unsigned int& cnt : vertcnt) { for(unsigned int& cnt : mVertcnt) {
if (cnt < 2){ if (cnt < 2){
base += cnt; base += cnt;
continue; continue;
@ -425,13 +423,13 @@ void TempMesh::RemoveAdjacentDuplicates()
std::vector<IfcVector3>::iterator end = base+cnt, e = std::unique( base, end, fz ); std::vector<IfcVector3>::iterator end = base+cnt, e = std::unique( base, end, fz );
if (e != end) { if (e != end) {
cnt -= static_cast<unsigned int>(std::distance(e, end)); cnt -= static_cast<unsigned int>(std::distance(e, end));
verts.erase(e,end); mVerts.erase(e,end);
drop = true; drop = true;
} }
// check front and back vertices for this polygon // check front and back vertices for this polygon
if (cnt > 1 && fz(*base,*(base+cnt-1))) { if (cnt > 1 && fz(*base,*(base+cnt-1))) {
verts.erase(base+ --cnt); mVerts.erase(base+ --cnt);
drop = true; drop = true;
} }
@ -447,12 +445,12 @@ void TempMesh::RemoveAdjacentDuplicates()
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void TempMesh::Swap(TempMesh& other) void TempMesh::Swap(TempMesh& other)
{ {
vertcnt.swap(other.vertcnt); mVertcnt.swap(other.mVertcnt);
verts.swap(other.verts); mVerts.swap(other.mVerts);
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
bool IsTrue(const EXPRESS::BOOLEAN& in) bool IsTrue(const ::Assimp::STEP::EXPRESS::BOOLEAN& in)
{ {
return (std::string)in == "TRUE" || (std::string)in == "T"; return (std::string)in == "TRUE" || (std::string)in == "T";
} }
@ -515,7 +513,7 @@ IfcFloat ConvertSIPrefix(const std::string& prefix)
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertColor(aiColor4D& out, const IfcColourRgb& in) void ConvertColor(aiColor4D& out, const Schema_2x3::IfcColourRgb& in)
{ {
out.r = static_cast<float>( in.Red ); out.r = static_cast<float>( in.Red );
out.g = static_cast<float>( in.Green ); out.g = static_cast<float>( in.Green );
@ -524,9 +522,9 @@ void ConvertColor(aiColor4D& out, const IfcColourRgb& in)
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertColor(aiColor4D& out, const IfcColourOrFactor& in,ConversionData& conv,const aiColor4D* base) void ConvertColor(aiColor4D& out, const Schema_2x3::IfcColourOrFactor& in,ConversionData& conv,const aiColor4D* base)
{ {
if (const EXPRESS::REAL* const r = in.ToPtr<EXPRESS::REAL>()) { if (const ::Assimp::STEP::EXPRESS::REAL* const r = in.ToPtr<::Assimp::STEP::EXPRESS::REAL>()) {
out.r = out.g = out.b = static_cast<float>(*r); out.r = out.g = out.b = static_cast<float>(*r);
if(base) { if(base) {
out.r *= static_cast<float>( base->r ); out.r *= static_cast<float>( base->r );
@ -536,7 +534,7 @@ void ConvertColor(aiColor4D& out, const IfcColourOrFactor& in,ConversionData& co
} }
else out.a = 1.0; else out.a = 1.0;
} }
else if (const IfcColourRgb* const rgb = in.ResolveSelectPtr<IfcColourRgb>(conv.db)) { else if (const Schema_2x3::IfcColourRgb* const rgb = in.ResolveSelectPtr<Schema_2x3::IfcColourRgb>(conv.db)) {
ConvertColor(out,*rgb); ConvertColor(out,*rgb);
} }
else { else {
@ -545,7 +543,7 @@ void ConvertColor(aiColor4D& out, const IfcColourOrFactor& in,ConversionData& co
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertCartesianPoint(IfcVector3& out, const IfcCartesianPoint& in) void ConvertCartesianPoint(IfcVector3& out, const Schema_2x3::IfcCartesianPoint& in)
{ {
out = IfcVector3(); out = IfcVector3();
for(size_t i = 0; i < in.Coordinates.size(); ++i) { for(size_t i = 0; i < in.Coordinates.size(); ++i) {
@ -554,14 +552,14 @@ void ConvertCartesianPoint(IfcVector3& out, const IfcCartesianPoint& in)
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertVector(IfcVector3& out, const IfcVector& in) void ConvertVector(IfcVector3& out, const Schema_2x3::IfcVector& in)
{ {
ConvertDirection(out,in.Orientation); ConvertDirection(out,in.Orientation);
out *= in.Magnitude; out *= in.Magnitude;
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertDirection(IfcVector3& out, const IfcDirection& in) void ConvertDirection(IfcVector3& out, const Schema_2x3::IfcDirection& in)
{ {
out = IfcVector3(); out = IfcVector3();
for(size_t i = 0; i < in.DirectionRatios.size(); ++i) { for(size_t i = 0; i < in.DirectionRatios.size(); ++i) {
@ -592,7 +590,7 @@ void AssignMatrixAxes(IfcMatrix4& out, const IfcVector3& x, const IfcVector3& y,
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement3D& in) void ConvertAxisPlacement(IfcMatrix4& out, const Schema_2x3::IfcAxis2Placement3D& in)
{ {
IfcVector3 loc; IfcVector3 loc;
ConvertCartesianPoint(loc,in.Location); ConvertCartesianPoint(loc,in.Location);
@ -617,7 +615,7 @@ void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement3D& in)
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement2D& in) void ConvertAxisPlacement(IfcMatrix4& out, const Schema_2x3::IfcAxis2Placement2D& in)
{ {
IfcVector3 loc; IfcVector3 loc;
ConvertCartesianPoint(loc,in.Location); ConvertCartesianPoint(loc,in.Location);
@ -634,7 +632,7 @@ void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement2D& in)
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertAxisPlacement(IfcVector3& axis, IfcVector3& pos, const IfcAxis1Placement& in) void ConvertAxisPlacement(IfcVector3& axis, IfcVector3& pos, const Schema_2x3::IfcAxis1Placement& in)
{ {
ConvertCartesianPoint(pos,in.Location); ConvertCartesianPoint(pos,in.Location);
if (in.Axis) { if (in.Axis) {
@ -646,12 +644,12 @@ void ConvertAxisPlacement(IfcVector3& axis, IfcVector3& pos, const IfcAxis1Place
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement& in, ConversionData& conv) void ConvertAxisPlacement(IfcMatrix4& out, const Schema_2x3::IfcAxis2Placement& in, ConversionData& conv)
{ {
if(const IfcAxis2Placement3D* pl3 = in.ResolveSelectPtr<IfcAxis2Placement3D>(conv.db)) { if(const Schema_2x3::IfcAxis2Placement3D* pl3 = in.ResolveSelectPtr<Schema_2x3::IfcAxis2Placement3D>(conv.db)) {
ConvertAxisPlacement(out,*pl3); ConvertAxisPlacement(out,*pl3);
} }
else if(const IfcAxis2Placement2D* pl2 = in.ResolveSelectPtr<IfcAxis2Placement2D>(conv.db)) { else if(const Schema_2x3::IfcAxis2Placement2D* pl2 = in.ResolveSelectPtr<Schema_2x3::IfcAxis2Placement2D>(conv.db)) {
ConvertAxisPlacement(out,*pl2); ConvertAxisPlacement(out,*pl2);
} }
else { else {
@ -660,7 +658,7 @@ void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement& in, Conversi
} }
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
void ConvertTransformOperator(IfcMatrix4& out, const IfcCartesianTransformationOperator& op) void ConvertTransformOperator(IfcMatrix4& out, const Schema_2x3::IfcCartesianTransformationOperator& op)
{ {
IfcVector3 loc; IfcVector3 loc;
ConvertCartesianPoint(loc,op.LocalOrigin); ConvertCartesianPoint(loc,op.LocalOrigin);
@ -672,7 +670,7 @@ void ConvertTransformOperator(IfcMatrix4& out, const IfcCartesianTransformationO
if (op.Axis2) { if (op.Axis2) {
ConvertDirection(y,*op.Axis2.Get()); ConvertDirection(y,*op.Axis2.Get());
} }
if (const IfcCartesianTransformationOperator3D* op2 = op.ToPtr<IfcCartesianTransformationOperator3D>()) { if (const Schema_2x3::IfcCartesianTransformationOperator3D* op2 = op.ToPtr<Schema_2x3::IfcCartesianTransformationOperator3D>()) {
if(op2->Axis3) { if(op2->Axis3) {
ConvertDirection(z,*op2->Axis3.Get()); ConvertDirection(z,*op2->Axis3.Get());
} }
@ -684,7 +682,7 @@ void ConvertTransformOperator(IfcMatrix4& out, const IfcCartesianTransformationO
IfcVector3 vscale; IfcVector3 vscale;
if (const IfcCartesianTransformationOperator3DnonUniform* nuni = op.ToPtr<IfcCartesianTransformationOperator3DnonUniform>()) { if (const Schema_2x3::IfcCartesianTransformationOperator3DnonUniform* nuni = op.ToPtr<Schema_2x3::IfcCartesianTransformationOperator3DnonUniform>()) {
vscale.x = nuni->Scale?op.Scale.Get():1.f; vscale.x = nuni->Scale?op.Scale.Get():1.f;
vscale.y = nuni->Scale2?nuni->Scale2.Get():1.f; vscale.y = nuni->Scale2?nuni->Scale2.Get():1.f;
vscale.z = nuni->Scale3?nuni->Scale3.Get():1.f; vscale.z = nuni->Scale3?nuni->Scale3.Get():1.f;

123
code/IFCUtil.h → code/Importer/IFC/IFCUtil.h
View File

@ -46,9 +46,9 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef INCLUDED_IFCUTIL_H #ifndef INCLUDED_IFCUTIL_H
#define INCLUDED_IFCUTIL_H #define INCLUDED_IFCUTIL_H
#include "IFCReaderGen.h" #include "IFCReaderGen_2x3.h"
#include "IFCLoader.h" #include "IFCLoader.h"
#include "STEPFile.h" #include "code/STEPFile.h"
#include <assimp/mesh.h> #include <assimp/mesh.h>
#include <assimp/material.h> #include <assimp/material.h>
@ -71,8 +71,7 @@ namespace IFC {
// Helper for std::for_each to delete all heap-allocated items in a container // Helper for std::for_each to delete all heap-allocated items in a container
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
template<typename T> template<typename T>
struct delete_fun struct delete_fun {
{
void operator()(T* del) { void operator()(T* del) {
delete del; delete del;
} }
@ -83,10 +82,9 @@ struct delete_fun
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
// Helper used during mesh construction. Aids at creating aiMesh'es out of relatively few polygons. // Helper used during mesh construction. Aids at creating aiMesh'es out of relatively few polygons.
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
struct TempMesh struct TempMesh {
{ std::vector<IfcVector3> mVerts;
std::vector<IfcVector3> verts; std::vector<unsigned int> mVertcnt;
std::vector<unsigned int> vertcnt;
// utilities // utilities
aiMesh* ToMesh(); aiMesh* ToMesh();
@ -94,30 +92,28 @@ struct TempMesh
void Transform(const IfcMatrix4& mat); void Transform(const IfcMatrix4& mat);
IfcVector3 Center() const; IfcVector3 Center() const;
void Append(const TempMesh& other); void Append(const TempMesh& other);
bool IsEmpty() const;
bool IsEmpty() const {
return verts.empty() && vertcnt.empty();
}
void RemoveAdjacentDuplicates(); void RemoveAdjacentDuplicates();
void RemoveDegenerates(); void RemoveDegenerates();
void FixupFaceOrientation(); void FixupFaceOrientation();
static IfcVector3 ComputePolygonNormal(const IfcVector3* vtcs, size_t cnt, bool normalize = true); static IfcVector3 ComputePolygonNormal(const IfcVector3* vtcs, size_t cnt, bool normalize = true);
IfcVector3 ComputeLastPolygonNormal(bool normalize = true) const; IfcVector3 ComputeLastPolygonNormal(bool normalize = true) const;
void ComputePolygonNormals(std::vector<IfcVector3>& normals, bool normalize = true, size_t ofs = 0) const; void ComputePolygonNormals(std::vector<IfcVector3>& normals, bool normalize = true, size_t ofs = 0) const;
void Swap(TempMesh& other); void Swap(TempMesh& other);
}; };
inline
bool TempMesh::IsEmpty() const {
return mVerts.empty() && mVertcnt.empty();
}
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
// Temporary representation of an opening in a wall or a floor // Temporary representation of an opening in a wall or a floor
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
struct TempOpening struct TempOpening
{ {
const IFC::IfcSolidModel* solid; const IFC::Schema_2x3::IfcSolidModel *solid;
IfcVector3 extrusionDir; IfcVector3 extrusionDir;
std::shared_ptr<TempMesh> profileMesh; std::shared_ptr<TempMesh> profileMesh;
@ -139,7 +135,7 @@ struct TempOpening
} }
// ------------------------------------------------------------------------------ // ------------------------------------------------------------------------------
TempOpening(const IFC::IfcSolidModel* solid,IfcVector3 extrusionDir, TempOpening(const IFC::Schema_2x3::IfcSolidModel* solid,IfcVector3 extrusionDir,
std::shared_ptr<TempMesh> profileMesh, std::shared_ptr<TempMesh> profileMesh,
std::shared_ptr<TempMesh> profileMesh2D) std::shared_ptr<TempMesh> profileMesh2D)
: solid(solid) : solid(solid)
@ -174,7 +170,7 @@ struct TempOpening
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
struct ConversionData struct ConversionData
{ {
ConversionData(const STEP::DB& db, const IFC::IfcProject& proj, aiScene* out,const IFCImporter::Settings& settings) ConversionData(const STEP::DB& db, const IFC::Schema_2x3::IfcProject& proj, aiScene* out,const IFCImporter::Settings& settings)
: len_scale(1.0) : len_scale(1.0)
, angle_scale(-1.0) , angle_scale(-1.0)
, db(db) , db(db)
@ -194,7 +190,7 @@ struct ConversionData
bool plane_angle_in_radians; bool plane_angle_in_radians;
const STEP::DB& db; const STEP::DB& db;
const IFC::IfcProject& proj; const IFC::Schema_2x3::IfcProject& proj;
aiScene* out; aiScene* out;
IfcMatrix4 wcs; IfcMatrix4 wcs;
@ -202,16 +198,16 @@ struct ConversionData
std::vector<aiMaterial*> materials; std::vector<aiMaterial*> materials;
struct MeshCacheIndex { struct MeshCacheIndex {
const IFC::IfcRepresentationItem* item; unsigned int matindex; const IFC::Schema_2x3::IfcRepresentationItem* item; unsigned int matindex;
MeshCacheIndex() : item(NULL), matindex(0) { } MeshCacheIndex() : item(NULL), matindex(0) { }
MeshCacheIndex(const IFC::IfcRepresentationItem* i, unsigned int mi) : item(i), matindex(mi) { } MeshCacheIndex(const IFC::Schema_2x3::IfcRepresentationItem* i, unsigned int mi) : item(i), matindex(mi) { }
bool operator == (const MeshCacheIndex& o) const { return item == o.item && matindex == o.matindex; } bool operator == (const MeshCacheIndex& o) const { return item == o.item && matindex == o.matindex; }
bool operator < (const MeshCacheIndex& o) const { return item < o.item || (item == o.item && matindex < o.matindex); } bool operator < (const MeshCacheIndex& o) const { return item < o.item || (item == o.item && matindex < o.matindex); }
}; };
typedef std::map<MeshCacheIndex, std::vector<unsigned int> > MeshCache; typedef std::map<MeshCacheIndex, std::vector<unsigned int> > MeshCache;
MeshCache cached_meshes; MeshCache cached_meshes;
typedef std::map<const IFC::IfcSurfaceStyle*, unsigned int> MaterialCache; typedef std::map<const IFC::Schema_2x3::IfcSurfaceStyle*, unsigned int> MaterialCache;
MaterialCache cached_materials; MaterialCache cached_materials;
const IFCImporter::Settings& settings; const IFCImporter::Settings& settings;
@ -260,50 +256,50 @@ struct XYSorter {
// conversion routines for common IFC entities, implemented in IFCUtil.cpp // conversion routines for common IFC entities, implemented in IFCUtil.cpp
void ConvertColor(aiColor4D& out, const IfcColourRgb& in); void ConvertColor(aiColor4D& out, const Schema_2x3::IfcColourRgb& in);
void ConvertColor(aiColor4D& out, const IfcColourOrFactor& in,ConversionData& conv,const aiColor4D* base); void ConvertColor(aiColor4D& out, const Schema_2x3::IfcColourOrFactor& in,ConversionData& conv,const aiColor4D* base);
void ConvertCartesianPoint(IfcVector3& out, const IfcCartesianPoint& in); void ConvertCartesianPoint(IfcVector3& out, const Schema_2x3::IfcCartesianPoint& in);
void ConvertDirection(IfcVector3& out, const IfcDirection& in); void ConvertDirection(IfcVector3& out, const Schema_2x3::IfcDirection& in);
void ConvertVector(IfcVector3& out, const IfcVector& in); void ConvertVector(IfcVector3& out, const Schema_2x3::IfcVector& in);
void AssignMatrixAxes(IfcMatrix4& out, const IfcVector3& x, const IfcVector3& y, const IfcVector3& z); void AssignMatrixAxes(IfcMatrix4& out, const IfcVector3& x, const IfcVector3& y, const IfcVector3& z);
void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement3D& in); void ConvertAxisPlacement(IfcMatrix4& out, const Schema_2x3::IfcAxis2Placement3D& in);
void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement2D& in); void ConvertAxisPlacement(IfcMatrix4& out, const Schema_2x3::IfcAxis2Placement2D& in);
void ConvertAxisPlacement(IfcVector3& axis, IfcVector3& pos, const IFC::IfcAxis1Placement& in); void ConvertAxisPlacement(IfcVector3& axis, IfcVector3& pos, const IFC::Schema_2x3::IfcAxis1Placement& in);
void ConvertAxisPlacement(IfcMatrix4& out, const IfcAxis2Placement& in, ConversionData& conv); void ConvertAxisPlacement(IfcMatrix4& out, const Schema_2x3::IfcAxis2Placement& in, ConversionData& conv);
void ConvertTransformOperator(IfcMatrix4& out, const IfcCartesianTransformationOperator& op); void ConvertTransformOperator(IfcMatrix4& out, const Schema_2x3::IfcCartesianTransformationOperator& op);
bool IsTrue(const EXPRESS::BOOLEAN& in); bool IsTrue(const Assimp::STEP::EXPRESS::BOOLEAN& in);
IfcFloat ConvertSIPrefix(const std::string& prefix); IfcFloat ConvertSIPrefix(const std::string& prefix);
// IFCProfile.cpp // IFCProfile.cpp
bool ProcessProfile(const IfcProfileDef& prof, TempMesh& meshout, ConversionData& conv); bool ProcessProfile(const Schema_2x3::IfcProfileDef& prof, TempMesh& meshout, ConversionData& conv);
bool ProcessCurve(const IfcCurve& curve, TempMesh& meshout, ConversionData& conv); bool ProcessCurve(const Schema_2x3::IfcCurve& curve, TempMesh& meshout, ConversionData& conv);
// IFCMaterial.cpp // IFCMaterial.cpp
unsigned int ProcessMaterials(uint64_t id, unsigned int prevMatId, ConversionData& conv, bool forceDefaultMat); unsigned int ProcessMaterials(uint64_t id, unsigned int prevMatId, ConversionData& conv, bool forceDefaultMat);
// IFCGeometry.cpp // IFCGeometry.cpp
IfcMatrix3 DerivePlaneCoordinateSpace(const TempMesh& curmesh, bool& ok, IfcVector3& norOut); IfcMatrix3 DerivePlaneCoordinateSpace(const TempMesh& curmesh, bool& ok, IfcVector3& norOut);
bool ProcessRepresentationItem(const IfcRepresentationItem& item, unsigned int matid, std::vector<unsigned int>& mesh_indices, ConversionData& conv); bool ProcessRepresentationItem(const Schema_2x3::IfcRepresentationItem& item, unsigned int matid, std::vector<unsigned int>& mesh_indices, ConversionData& conv);
void AssignAddedMeshes(std::vector<unsigned int>& mesh_indices,aiNode* nd,ConversionData& /*conv*/); void AssignAddedMeshes(std::vector<unsigned int>& mesh_indices,aiNode* nd,ConversionData& /*conv*/);
void ProcessSweptAreaSolid(const IfcSweptAreaSolid& swept, TempMesh& meshout, void ProcessSweptAreaSolid(const Schema_2x3::IfcSweptAreaSolid& swept, TempMesh& meshout,
ConversionData& conv); ConversionData& conv);
void ProcessExtrudedAreaSolid(const IfcExtrudedAreaSolid& solid, TempMesh& result, void ProcessExtrudedAreaSolid(const Schema_2x3::IfcExtrudedAreaSolid& solid, TempMesh& result,
ConversionData& conv, bool collect_openings); ConversionData& conv, bool collect_openings);
// IFCBoolean.cpp // IFCBoolean.cpp
void ProcessBoolean(const IfcBooleanResult& boolean, TempMesh& result, ConversionData& conv); void ProcessBoolean(const Schema_2x3::IfcBooleanResult& boolean, TempMesh& result, ConversionData& conv);
void ProcessBooleanHalfSpaceDifference(const IfcHalfSpaceSolid* hs, TempMesh& result, void ProcessBooleanHalfSpaceDifference(const Schema_2x3::IfcHalfSpaceSolid* hs, TempMesh& result,
const TempMesh& first_operand, const TempMesh& first_operand,
ConversionData& conv); ConversionData& conv);
void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const IfcPolygonalBoundedHalfSpace* hs, TempMesh& result, void ProcessPolygonalBoundedBooleanHalfSpaceDifference(const Schema_2x3::IfcPolygonalBoundedHalfSpace* hs, TempMesh& result,
const TempMesh& first_operand, const TempMesh& first_operand,
ConversionData& conv); ConversionData& conv);
void ProcessBooleanExtrudedAreaSolidDifference(const IfcExtrudedAreaSolid* as, TempMesh& result, void ProcessBooleanExtrudedAreaSolidDifference(const Schema_2x3::IfcExtrudedAreaSolid* as, TempMesh& result,
const TempMesh& first_operand, const TempMesh& first_operand,
ConversionData& conv); ConversionData& conv);
@ -324,38 +320,31 @@ bool GenerateOpenings(std::vector<TempOpening>& openings,
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
// Custom exception for use by members of the Curve class // Custom exception for use by members of the Curve class
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
class CurveError class CurveError {
{
public: public:
CurveError(const std::string& s) CurveError(const std::string& s)
: s(s) : mStr(s) {
{ // empty
} }
std::string s; std::string mStr;
}; };
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
// Temporary representation for an arbitrary sub-class of IfcCurve. Used to sample the curves // Temporary representation for an arbitrary sub-class of IfcCurve. Used to sample the curves
// to obtain a list of line segments. // to obtain a list of line segments.
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
class Curve class Curve {
{
protected: protected:
Curve(const Schema_2x3::IfcCurve& base_entity, ConversionData& conv)
Curve(const IfcCurve& base_entity, ConversionData& conv)
: base_entity(base_entity) : base_entity(base_entity)
, conv(conv) , conv(conv) {
{} // empty
}
public: public:
typedef std::pair<IfcFloat, IfcFloat> ParamRange; typedef std::pair<IfcFloat, IfcFloat> ParamRange;
public:
virtual ~Curve() {} virtual ~Curve() {}
@ -386,14 +375,10 @@ public:
// check if a particular parameter value lies within the well-defined range // check if a particular parameter value lies within the well-defined range
bool InRange(IfcFloat) const; bool InRange(IfcFloat) const;
#endif #endif
static Curve* Convert(const IFC::Schema_2x3::IfcCurve&,ConversionData& conv);
public:
static Curve* Convert(const IFC::IfcCurve&,ConversionData& conv);
protected: protected:
const Schema_2x3::IfcCurve& base_entity;
const IfcCurve& base_entity;
ConversionData& conv; ConversionData& conv;
}; };
@ -402,11 +387,9 @@ protected:
// A BoundedCurve always holds the invariant that GetParametricRange() // A BoundedCurve always holds the invariant that GetParametricRange()
// never returns infinite values. // never returns infinite values.
// -------------------------------------------------------------------------------- // --------------------------------------------------------------------------------
class BoundedCurve : public Curve class BoundedCurve : public Curve {
{
public: public:
BoundedCurve(const Schema_2x3::IfcBoundedCurve& entity, ConversionData& conv)
BoundedCurve(const IfcBoundedCurve& entity, ConversionData& conv)
: Curve(entity,conv) : Curve(entity,conv)
{} {}
@ -422,7 +405,7 @@ public:
}; };
// IfcProfile.cpp // IfcProfile.cpp
bool ProcessCurve(const IfcCurve& curve, TempMesh& meshout, ConversionData& conv); bool ProcessCurve(const Schema_2x3::IfcCurve& curve, TempMesh& meshout, ConversionData& conv);
} }
} }

2
code/STEPFileEncoding.cpp → code/Importer/IFC/STEPFileEncoding.cpp
View File

@ -43,7 +43,7 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
* @brief STEP character handling, string un-escaping * @brief STEP character handling, string un-escaping
*/ */
#include "STEPFileEncoding.h" #include "STEPFileEncoding.h"
#include "fast_atof.h" #include "code/fast_atof.h"
#include <contrib/utf8cpp/source/utf8.h> #include <contrib/utf8cpp/source/utf8.h>
#include <memory> #include <memory>

0
code/STEPFileEncoding.h → code/Importer/IFC/STEPFileEncoding.h
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4
code/STEPFileReader.cpp → code/Importer/IFC/STEPFileReader.cpp
View File

@ -46,8 +46,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "STEPFileReader.h" #include "STEPFileReader.h"
#include "STEPFileEncoding.h" #include "STEPFileEncoding.h"
#include "TinyFormatter.h" #include "code/TinyFormatter.h"
#include "fast_atof.h" #include "code/fast_atof.h"
#include <memory> #include <memory>

2
code/STEPFileReader.h → code/Importer/IFC/STEPFileReader.h
View File

@ -42,7 +42,7 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef INCLUDED_AI_STEPFILEREADER_H #ifndef INCLUDED_AI_STEPFILEREADER_H
#define INCLUDED_AI_STEPFILEREADER_H #define INCLUDED_AI_STEPFILEREADER_H
#include "STEPFile.h" #include "code/STEPFile.h"
namespace Assimp { namespace Assimp {
namespace STEP { namespace STEP {

2
code/ImporterRegistry.cpp
View File

@ -169,7 +169,7 @@ corresponding preprocessor flag to selectively disable formats.
# include "NDOLoader.h" # include "NDOLoader.h"
#endif #endif
#ifndef ASSIMP_BUILD_NO_IFC_IMPORTER #ifndef ASSIMP_BUILD_NO_IFC_IMPORTER
# include "IFCLoader.h" # include "Importer/IFC/IFCLoader.h"
#endif #endif
#ifndef ASSIMP_BUILD_NO_XGL_IMPORTER #ifndef ASSIMP_BUILD_NO_XGL_IMPORTER
# include "XGLLoader.h" # include "XGLLoader.h"

5
code/LogAux.h
View File

@ -52,11 +52,8 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
namespace Assimp { namespace Assimp {
template<class TDeriving> template<class TDeriving>
class LogFunctions class LogFunctions {
{
public: public:
// ------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------
static void ThrowException(const std::string& msg) static void ThrowException(const std::string& msg)
{ {

15
code/STEPFile.h
View File

@ -364,17 +364,16 @@ namespace STEP {
// ------------------------------------------------------------------------------- // -------------------------------------------------------------------------------
class ConversionSchema class ConversionSchema
{ {
public: public:
struct SchemaEntry { struct SchemaEntry {
SchemaEntry( const char *name, ConvertObjectProc func ) SchemaEntry( const char *name, ConvertObjectProc func )
: name(name) : mName( name )
, func(func) , mFunc(func) {
{} // empty
}
const char* name; const char* mName;
ConvertObjectProc func; ConvertObjectProc mFunc;
}; };
typedef std::map<std::string,ConvertObjectProc> ConverterMap; typedef std::map<std::string,ConvertObjectProc> ConverterMap;
@ -410,7 +409,7 @@ namespace STEP {
const ConversionSchema& operator=( const SchemaEntry (& schemas)[N]) { const ConversionSchema& operator=( const SchemaEntry (& schemas)[N]) {
for(size_t i = 0; i < N; ++i ) { for(size_t i = 0; i < N; ++i ) {
const SchemaEntry& schema = schemas[i]; const SchemaEntry& schema = schemas[i];
converters[schema.name] = schema.func; converters[schema.mName] = schema.mFunc;
} }
return *this; return *this;
} }

1
scripts/IFCImporter/ExpressReader.py
View File

@ -96,6 +96,7 @@ class Type:
def read(filename, silent=False): def read(filename, silent=False):
schema = Schema() schema = Schema()
print( "Try to read EXPRESS schema file" + filename)
with open(filename,'rt') as inp: with open(filename,'rt') as inp:
contents = inp.read() contents = inp.read()
types = re.findall(re_match_type,contents) types = re.findall(re_match_type,contents)

0
scripts/IFCImporter/schema.exp → scripts/IFCImporter/schema_ifc2x3.exp
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12401
scripts/IFCImporter/schema_ifc4.exp 100644
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