#include "Model_SelectionNaming.h"
#include "Model_Document.h"
+#include "Model_Objects.h"
+#include "Model_Data.h"
#include <ModelAPI_Feature.h>
#include <Events_InfoMessage.h>
+#include <ModelAPI_Session.h>
+#include <ModelAPI_ResultPart.h>
+#include <ModelAPI_ResultConstruction.h>
+#include <ModelAPI_CompositeFeature.h>
+#include <ModelAPI_ResultBody.h>
+#include <GeomAPI_Wire.h>
#include <TopoDS_Iterator.hxx>
#include <TopoDS.hxx>
#include <TNaming_NamedShape.hxx>
#include <TNaming_Localizer.hxx>
#include <TDataStd_Name.hxx>
-#include <ModelAPI_ResultConstruction.h>
-#include <ModelAPI_CompositeFeature.h>
#include <TColStd_MapOfTransient.hxx>
-
+#include <algorithm>
+#include <stdexcept>
#ifdef DEB_NAMING
#include <BRepTools.hxx>
#endif
-/// added to the index in the packed map to signalize that the vertex of edge is selected
-/// (multiplied by the index of the edge)
-static const int kSTART_VERTEX_DELTA = 1000000;
-
Model_SelectionNaming::Model_SelectionNaming(TDF_Label theSelectionLab)
{
myLab = theSelectionLab;
}
-
std::string Model_SelectionNaming::getShapeName(
- std::shared_ptr<Model_Document> theDoc, const TopoDS_Shape& theShape)
+ std::shared_ptr<Model_Document> theDoc, const TopoDS_Shape& theShape,
+ ResultPtr& theContext, const bool theAnotherDoc, const bool theWholeContext)
{
std::string aName;
+ // add the result name to the name of the shape
+ // (it was in BodyBuilder, but did not work on Result rename)
+ bool isNeedContextName = theContext->shape().get() != NULL;
+ // && !theContext->shape()->isEqual(theSubSh);
// check if the subShape is already in DF
Handle(TNaming_NamedShape) aNS = TNaming_Tool::NamedShape(theShape, myLab);
Handle(TDataStd_Name) anAttr;
- if(!aNS.IsNull() && !aNS->IsEmpty()) { // in the document
+ if(!aNS.IsNull() && !aNS->IsEmpty()) { // in the document
if(aNS->Label().FindAttribute(TDataStd_Name::GetID(), anAttr)) {
- aName = TCollection_AsciiString(anAttr->Get()).ToCString();
- if(!aName.empty()) {
- const TDF_Label& aLabel = theDoc->findNamingName(aName);
- /* MPV: the same shape with the same name may be duplicated on different labels (selection of the same construction object)
- if(!aLabel.IsEqual(aNS->Label())) {
- //aName.erase(); //something is wrong, to be checked!!!
- aName += "_SomethingWrong";
- return aName;
- }*/
-
- static const std::string aPostFix("_");
- TNaming_Iterator anItL(aNS);
- for(int i = 1; anItL.More(); anItL.Next(), i++) {
- if(anItL.NewShape() == theShape) {
- aName += aPostFix;
- aName += TCollection_AsciiString (i).ToCString();
- break;
+ std::shared_ptr<Model_Data> aData =
+ std::dynamic_pointer_cast<Model_Data>(theContext->data());
+ if (isNeedContextName && aData && aData->label().IsEqual(aNS->Label())) {
+ // do nothing because this context name will be added later in this method
+ } else {
+ aName = TCollection_AsciiString(anAttr->Get()).ToCString();
+ // indexes are added to sub-shapes not primitives
+ // (primitives must not be located at the same label)
+ if(!aName.empty() && aNS->Evolution() != TNaming_PRIMITIVE && isNeedContextName) {
+ const TDF_Label& aLabel = aNS->Label();//theDoc->findNamingName(aName);
+ static const std::string aPostFix("_");
+ TNaming_Iterator anItL(aNS);
+ for(int i = 1; anItL.More(); anItL.Next(), i++) {
+ // in #1766 IsEqual produced no index of the face
+ if(anItL.NewShape().IsSame(theShape)) {
+ aName += aPostFix;
+ aName += TCollection_AsciiString (i).ToCString();
+ break;
+ }
}
}
- }
+ // if a shape is under another context, use this name, not theContext
+ std::shared_ptr<Model_Data> aContextData =
+ std::dynamic_pointer_cast<Model_Data>(theContext->data());
+ // for constructions the naming is in arguments and has no evolution, so, apply this only
+ // for bodies
+ if (isNeedContextName && theContext->groupName() == ModelAPI_ResultBody::group() &&
+ !aNS->Label().IsDescendant(aContextData->label())) {
+ isNeedContextName = false;
+ TDF_Label aNSDataLab = aNS->Label();
+ while(aNSDataLab.Depth() != 7 && aNSDataLab.Depth() > 5)
+ aNSDataLab = aNSDataLab.Father();
+ ObjectPtr aNewContext = theDoc->objects()->object(aNSDataLab);
+ if (!aNewContext.get() && aNSDataLab.Depth() == 7) {
+ aNSDataLab = aNSDataLab.Father().Father();
+ aNewContext = theDoc->objects()->object(aNSDataLab);
+ }
+ if (aNewContext.get()) {
+ aName = aNewContext->data()->name() + "/" + aName;
+ }
+ }
+ }
}
}
+
+ // Name is empty and this is full context, it just add the whole context name that must be added
+ bool isEmptyName = aName.empty();
+ if (isNeedContextName && (!isEmptyName || theWholeContext)) {
+ aName = theContext->data()->name() + (isEmptyName ? "" : ("/" + aName));
+ if (theAnotherDoc)
+ aName = theContext->document()->kind() + "/" + aName; // PartSet
+ }
return aName;
}
-
-
bool isTrivial (const TopTools_ListOfShape& theAncestors, TopTools_IndexedMapOfShape& theSMap)
{
// a trivial case: F1 & F2, aNumber = 1, i.e. intersection gives 1 edge.
}
std::string Model_SelectionNaming::namingName(ResultPtr& theContext,
- std::shared_ptr<GeomAPI_Shape> theSubSh, const std::string& theDefaultName)
+ std::shared_ptr<GeomAPI_Shape> theSubSh, const std::string& theDefaultName,
+ const bool theAnotherDoc)
{
std::string aName("Undefined name");
- if(!theContext.get() || theContext->shape()->isNull())
+ if(!theContext.get() || theContext->shape()->isNull())
return !theDefaultName.empty() ? theDefaultName : aName;
+
+ // if it is in result of another part
+ std::shared_ptr<Model_Document> aDoc =
+ std::dynamic_pointer_cast<Model_Document>(theContext->document());
+ if (theContext->groupName() == ModelAPI_ResultPart::group()) {
+ ResultPartPtr aPart = std::dynamic_pointer_cast<ModelAPI_ResultPart>(theContext);
+ int anIndex;
+ if (theSubSh.get())
+ return aPart->data()->name() + "/" + aPart->nameInPart(theSubSh, anIndex);
+ else
+ return aPart->data()->name();
+ }
+
if (!theSubSh.get() || theSubSh->isNull()) { // no subshape, so just the whole feature name
- return theContext->data()->name();
+ // but if it is in another Part, add this part name
+ std::string aPartName;
+ if (theAnotherDoc)
+ aPartName = theContext->document()->kind() + "/"; // PartSet
+ return aPartName + theContext->data()->name();
}
TopoDS_Shape aSubShape = theSubSh->impl<TopoDS_Shape>();
TopoDS_Shape aContext = theContext->shape()->impl<TopoDS_Shape>();
BRepTools::Write(aContext, "Context.brep");
}
#endif
- std::shared_ptr<Model_Document> aDoc =
- std::dynamic_pointer_cast<Model_Document>(theContext->document());
+ aName = getShapeName(aDoc, aSubShape, theContext, theAnotherDoc,
+ theContext->shape()->isEqual(theSubSh));
- // check if the subShape is already in DF
- aName = getShapeName(aDoc, aSubShape);
if(aName.empty() ) { // not in the document!
TopAbs_ShapeEnum aType = aSubShape.ShapeType();
switch (aType) {
case TopAbs_FACE:
- // the Face should be in DF. If it is not the case, it is an error ==> to be debugged
+ // the Face should be in DF. If it is not the case, it is an error ==> to be debugged
break;
case TopAbs_EDGE:
{
- // name structure: F1 & F2 [& F3 & F4], where F1 & F2 the faces which gives the Edge in trivial case
- // if it is not atrivial case we use localization by neighbours. F3 & F4 - neighbour faces
+ // name structure: F1 & F2 [& F3 & F4],
+ // where F1 & F2 the faces which gives the Edge in trivial case
+ // if it is not atrivial case we use localization by neighbours. F3 & F4 - neighbour faces
if (BRep_Tool::Degenerated(TopoDS::Edge(aSubShape))) {
aName = "Degenerated_Edge";
break;
- }
+ }
TopTools_IndexedDataMapOfShapeListOfShape aMap;
TopExp::MapShapesAndAncestors(aContext, TopAbs_EDGE, TopAbs_FACE, aMap);
TopTools_IndexedMapOfShape aSMap; // map for ancestors of the sub-shape
if(aMap.Contains(aSubShape)) {
const TopTools_ListOfShape& anAncestors = aMap.FindFromKey(aSubShape);
// check that it is not a trivial case (F1 & F2: aNumber = 1)
- isTrivialCase = isTrivial(anAncestors, aSMap);
- } else
+ isTrivialCase = isTrivial(anAncestors, aSMap);
+ } else
break;
TopTools_ListOfShape aListOfNbs;
if(!isTrivialCase) { // find Neighbors
// build name of the sub-shape Edge
for(int i=1; i <= aSMap.Extent(); i++) {
const TopoDS_Shape& aFace = aSMap.FindKey(i);
- std::string aFaceName = getShapeName(aDoc, aFace);
+ std::string aFaceName = getShapeName(aDoc, aFace, theContext, theAnotherDoc, false);
if(i == 1)
aName = aFaceName;
- else
+ else
aName += "&" + aFaceName;
}
TopTools_ListIteratorOfListOfShape itl(aListOfNbs);
for (;itl.More();itl.Next()) {
- std::string aFaceName = getShapeName(aDoc, itl.Value());
+ std::string aFaceName = getShapeName(aDoc, itl.Value(), theContext, theAnotherDoc, false);
aName += "&" + aFaceName;
- }
+ }
}
break;
case TopAbs_VERTEX:
- // name structure (Monifold Topology):
+ // name structure (Monifold Topology):
// 1) F1 | F2 | F3 - intersection of 3 faces defines a vertex - trivial case.
- // 2) F1 | F2 | F3 [|F4 [|Fn]] - redundant definition, but it should be kept as is to obtain safe recomputation
+ // 2) F1 | F2 | F3 [|F4 [|Fn]] - redundant definition,
+ // but it should be kept as is to obtain safe recomputation
// 2) F1 | F2 - intersection of 2 faces definses a vertex - applicable for case
// when 1 faces is cylindrical, conical, spherical or revolution and etc.
// 3) E1 | E2 | E3 - intersection of 3 edges defines a vertex - when we have case of a shell
// or compound of 2 open faces.
- // 4) E1 | E2 - intesection of 2 edges defines a vertex - when we have a case of
+ // 4) E1 | E2 - intesection of 2 edges defines a vertex - when we have a case of
// two independent edges (wire or compound)
// implemented 2 first cases
{
TopTools_IndexedDataMapOfShapeListOfShape aMap;
TopExp::MapShapesAndAncestors(aContext, TopAbs_VERTEX, TopAbs_FACE, aMap);
- const TopTools_ListOfShape& aList2 = aMap.FindFromKey(aSubShape);
TopTools_ListOfShape aList;
TopTools_MapOfShape aFMap;
- // fix is below
- TopTools_ListIteratorOfListOfShape itl2(aList2);
- for (int i = 1;itl2.More();itl2.Next(),i++) {
- if(aFMap.Add(itl2.Value()))
- aList.Append(itl2.Value());
- }
+ // simetimes when group is moved in history, naming may be badly updated, so
+ // avoid crash in FindFromKey (issue 1842)
+ if (aMap.Contains(aSubShape)) {
+ const TopTools_ListOfShape& aList2 = aMap.FindFromKey(aSubShape);
+ // fix is below
+ TopTools_ListIteratorOfListOfShape itl2(aList2);
+ for (int i = 1;itl2.More();itl2.Next(),i++) {
+ if(aFMap.Add(itl2.Value()))
+ aList.Append(itl2.Value());
+ }
+ } else
+ break;
int n = aList.Extent();
bool isByFaces = n >= 3;
if(!isByFaces) { // open topology case or Compound case => via edges
TopTools_ListIteratorOfListOfShape itl(aListE);
for (int i = 1;itl.More();itl.Next(),i++) {
const TopoDS_Shape& anEdge = itl.Value();
- std::string anEdgeName = getShapeName(aDoc, anEdge);
+ std::string anEdgeName = getShapeName(aDoc, anEdge, theContext, theAnotherDoc, false);
if (anEdgeName.empty()) { // edge is not in DS, trying by faces anyway
isByFaces = true;
aName.clear();
}
if(i == 1)
aName = anEdgeName;
- else
+ else
aName += "&" + anEdgeName;
}
}//reg
else { // dangle vertex: if(aList22.Extent() == 1)
//it should be already in DF
}
- }
+ }
if (isByFaces) {
TopTools_ListIteratorOfListOfShape itl(aList);
for (int i = 1;itl.More();itl.Next(),i++) {
const TopoDS_Shape& aFace = itl.Value();
- std::string aFaceName = getShapeName(aDoc, aFace);
+ std::string aFaceName = getShapeName(aDoc, aFace, theContext, theAnotherDoc, false);
if(i == 1)
aName = aFaceName;
- else
+ else
aName += "&" + aFaceName;
}
}
}
break;
}
- // register name
- // aDoc->addNamingName(selectionLabel(), aName);
- // the selected sub-shape will not be shared and as result it will not require registration
}
+
return aName;
}
}
if (aShapeTypes.find(theType) != aShapeTypes.end())
return aShapeTypes[theType];
- Events_InfoMessage("Model_SelectionNaming", "Shape type defined in XML is not implemented!").send();
+ Events_InfoMessage("Model_SelectionNaming",
+ "Shape type defined in XML is not implemented!").send();
return TopAbs_SHAPE;
}
const std::string& theSubShapeName, Handle(TNaming_NamedShape) theNS)
{
TopoDS_Shape aSelection;
- std::string::size_type n = theSubShapeName.rfind('/');
- if (n == std::string::npos) n = 0;
+ std::string::size_type n = theSubShapeName.rfind('/');
+ if (n == std::string::npos) n = -1;
std::string aSubString = theSubShapeName.substr(n + 1);
n = aSubString.rfind('_');
- if (n == std::string::npos) return aSelection;
- aSubString = aSubString.substr(n+1);
- int indx = atoi(aSubString.c_str());
+ int indx = 1;
+ if (n != std::string::npos) {// for primitives this is a first
+ // if we have here the same name as theSubShapeName, there is no index in compound, it is whole
+ Handle(TDataStd_Name) aName;
+ if (!theNS->Label().FindAttribute(TDataStd_Name::GetID(), aName) ||
+ aName->Get() != aSubString.c_str()) {
+ aSubString = aSubString.substr(n+1);
+ indx = atoi(aSubString.c_str());
+ }
+ }
TNaming_Iterator anItL(theNS);
for(int i = 1; anItL.More(); anItL.Next(), i++) {
return anItL.NewShape();
}
}
- return aSelection;
+ return aSelection;
}
const TopoDS_Shape findFaceByName(
const std::string& theSubShapeName, std::shared_ptr<Model_Document> theDoc)
{
TopoDS_Shape aFace;
- std::string::size_type n, nb = theSubShapeName.rfind('/');
- if (nb == std::string::npos) nb = 0;
- std::string aSubString = theSubShapeName.substr(nb + 1);
- n = aSubString.rfind('_');
- if (n != std::string::npos) {
- std::string aSubStr2 = aSubString.substr(0, n);
- aSubString = theSubShapeName.substr(0, nb + 1);
- aSubString = aSubString + aSubStr2;
- } else
- aSubString = theSubShapeName;
-
- const TDF_Label& aLabel = theDoc->findNamingName(aSubString);
+ //std::string::size_type n, nb = theSubShapeName.rfind('/');
+ //if (nb == std::string::npos) nb = 0;
+ //std::string aSubString = theSubShapeName.substr(nb + 1);
+ std::string aSubString = theSubShapeName;
+
+ TDF_Label aLabel = theDoc->findNamingName(aSubString);
+ if (aLabel.IsNull()) { // try to remove additional artificial suffix
+ std::string::size_type n = aSubString.rfind('_');
+ if (n != std::string::npos) {
+ aSubString = aSubString.substr(0, n);
+ aLabel = theDoc->findNamingName(aSubString);
+ }
+ }
if(aLabel.IsNull()) return aFace;
Handle(TNaming_NamedShape) aNS;
if(aLabel.FindAttribute(TNaming_NamedShape::GetID(), aNS)) {
size_t n1(0), n2(0); // n1 - start position, n2 - position of the delimiter
while ((n2 = aName.find('&', n1)) != std::string::npos) {
const std::string aName1 = aName.substr(n1, n2 - n1); //name of face
- theList.push_back(aName1);
+ theList.push_back(aName1);
n1 = n2 + 1;
aLastName = aName.substr(n1);
}
const TopoDS_Shape findCommonShape(
const TopAbs_ShapeEnum theType, const TopTools_ListOfShape& theList)
{
+ if(theList.IsEmpty() || theList.Extent() == 1) {
+ return TopoDS_Shape();
+ }
+
TopoDS_Shape aShape;
std::vector<TopTools_MapOfShape> aVec;
TopTools_MapOfShape aMap1, aMap2, aMap3, aMap4;
//fill maps
TopTools_ListIteratorOfListOfShape it(theList);
for(int i = 0;it.More();it.Next(),i++) {
- const TopoDS_Shape& aFace = it.Value();
+ const TopoDS_Shape& aFace = it.Value();
if(i < 2) {
TopExp_Explorer anExp (aFace, theType);
for(;anExp.More();anExp.Next()) {
aShape = it2.Key();
if(theList.Extent() == 2)
break;
- else
+ else
aList.Append(it2.Key());
}
}
- if(aList.Extent() && aVec.size() > 3) {// list of common edges ==> search ny neighbors
+ if(aList.Extent() && aVec.size() > 3) {// list of common edges ==> search ny neighbors
if(aVec[2].Extent() && aVec[3].Extent()) {
TopTools_ListIteratorOfListOfShape it(aList);
for(;it.More();it.Next()) {
std::string getContextName(const std::string& theSubShapeName)
{
std::string aName;
- std::string::size_type n = theSubShapeName.find('/');
- if (n == std::string::npos) return aName;
+ std::string::size_type n = theSubShapeName.find('/');
+ if (n == std::string::npos) return theSubShapeName;
aName = theSubShapeName.substr(0, n);
return aName;
}
-/// Parses naming name of sketch sub-elements: takes indices and orientation
-/// (if theOriented = true) from this name. Map theIDs constains indices ->
-/// orientations (true by default)
-bool parseSubIndices(const std::string& theName, const char* theShapeType,
- std::map<int, bool>& theIDs, const bool theOriented = false)
+/// Parses naming name of sketch sub-elements: takes indices and orientation
+/// (if theOriented = true) from this name. Map theIDs constains indices ->
+/// orientations and start/end vertices: negative is reversed, 2 - start, 3 - end
+bool parseSubIndices(CompositeFeaturePtr theComp, //< to iterate names
+ const std::string& theName, const char* theShapeType,
+ std::map<int, int>& theIDs, const bool theOriented = false)
{
// collect all IDs in the name
- std::set<int> anIDs;
+ std::map<std::string, int> aNames; // short name of sub -> ID of sub of theComp
+ const int aSubNum = theComp->numberOfSubs();
+ for(int a = 0; a < aSubNum; a++) {
+ FeaturePtr aSub = theComp->subFeature(a);
+ const std::list<std::shared_ptr<ModelAPI_Result> >& aResults = aSub->results();
+ std::list<std::shared_ptr<ModelAPI_Result> >::const_iterator aRes = aResults.cbegin();
+ // there may be many shapes (circle and center)
+ for(; aRes != aResults.cend(); aRes++) {
+ ResultConstructionPtr aConstr =
+ std::dynamic_pointer_cast<ModelAPI_ResultConstruction>(*aRes);
+ if (aConstr.get()) {
+ aNames[Model_SelectionNaming::shortName(aConstr)] = theComp->subFeatureId(a);
+ }
+ }
+ }
+
size_t aPrevPos = theName.find("/") + 1, aLastNamePos;
bool isShape = false; // anyway the first world must be 'Vertex'
do {
aLastNamePos = theName.find('-', aPrevPos);
- const std::string anID = theName.substr(aPrevPos, aLastNamePos - aPrevPos);
+ std::string anID = theName.substr(aPrevPos, aLastNamePos - aPrevPos);
if (!isShape) {
if (anID != theShapeType)
return false;
isShape = true;
} else {
- bool anOrientation = true; // default
+ int anOrientation = 1; // default
if (theOriented) { // here must be a symbol in the end of digit 'f' or 'r'
- const char aSymbol = theName.back();
- anOrientation = aSymbol == 'f';
+ std::string::iterator aSymbol = anID.end() - 1;
+ if (*aSymbol == 'r') anOrientation = -1;
+ anID.erase(aSymbol); // remove last symbol
+ }
+ // check start/end symbols
+ std::string::iterator aBack = anID.end() - 1;
+ if (*aBack == 's') {
+ anOrientation *= 2;
+ anID.erase(aBack); // remove last symbol
+ } else if (*aBack == 'e') {
+ anOrientation *= 3;
+ anID.erase(aBack); // remove last symbol
+ }
+
+ if (aNames.find(anID) != aNames.end()) {
+ theIDs[aNames[anID]] = anOrientation;
}
- int anInt = 0;
- try {
- anInt = std::stoi(anID, nullptr);
- } catch (const std::invalid_argument&) {}
- if (anInt != 0)
- theIDs[anInt] = anOrientation;
}
aPrevPos = aLastNamePos + 1;
} while (aLastNamePos != std::string::npos);
/// produces theEdge orientation relatively to theContext face
int Model_SelectionNaming::edgeOrientation(const TopoDS_Shape& theContext, TopoDS_Edge& theEdge)
{
- if (theContext.ShapeType() != TopAbs_FACE)
+ if (theContext.ShapeType() != TopAbs_FACE && theContext.ShapeType() != TopAbs_WIRE)
return 0;
- TopoDS_Face aContext = TopoDS::Face(theContext);
- if (theEdge.Orientation() == TopAbs_FORWARD)
+ if (theEdge.Orientation() == TopAbs_FORWARD)
return 1;
- if (theEdge.Orientation() == TopAbs_REVERSED)
+ if (theEdge.Orientation() == TopAbs_REVERSED)
return -1;
return 0; // unknown
}
std::shared_ptr<GeomAPI_Shape> Model_SelectionNaming::findAppropriateFace(
- std::shared_ptr<ModelAPI_Result>& theConstr,
- NCollection_DataMap<Handle(Geom_Curve), int>& theCurves)
+ std::shared_ptr<ModelAPI_Result>& theConstr,
+ NCollection_DataMap<Handle(Geom_Curve), int>& theCurves, const bool theIsWire)
{
int aBestFound = 0; // best number of found edges (not percentage: issue 1019)
int aBestOrient = 0; // for the equal "BestFound" additional parameter is orientation
std::shared_ptr<GeomAPI_Shape> aResult;
- ResultConstructionPtr aConstructionContext =
+ ResultConstructionPtr aConstructionContext =
std::dynamic_pointer_cast<ModelAPI_ResultConstruction>(theConstr);
if (!aConstructionContext.get())
return aResult;
for(int aFaceIndex = 0; aFaceIndex < aConstructionContext->facesNum(); aFaceIndex++) {
int aFound = 0, aNotFound = 0, aSameOrientation = 0;
- TopoDS_Face aFace =
+ TopoDS_Face aFace =
TopoDS::Face(aConstructionContext->face(aFaceIndex)->impl<TopoDS_Shape>());
- TopExp_Explorer anEdgesExp(aFace, TopAbs_EDGE);
- TColStd_MapOfTransient alreadyProcessed; // to avoid counting edges with same curved (841)
- for(; anEdgesExp.More(); anEdgesExp.Next()) {
- TopoDS_Edge anEdge = TopoDS::Edge(anEdgesExp.Current());
- if (!anEdge.IsNull()) {
- Standard_Real aFirst, aLast;
- Handle(Geom_Curve) aCurve = BRep_Tool::Curve(anEdge, aFirst, aLast);
- if (alreadyProcessed.Contains(aCurve))
- continue;
- alreadyProcessed.Add(aCurve);
- if (theCurves.IsBound(aCurve)) {
- aFound++;
- int anOrient = theCurves.Find(aCurve);
- if (anOrient != 0) { // extra comparision score is orientation
- if (edgeOrientation(aFace, anEdge) == anOrient)
- aSameOrientation++;
+ std::list<TopoDS_Shape> aFacesWires; // faces or wires to iterate
+ if (theIsWire) {
+ for(TopExp_Explorer aWires(aFace, TopAbs_WIRE); aWires.More(); aWires.Next()) {
+ aFacesWires.push_back(aWires.Current());
+ }
+ } else {
+ aFacesWires.push_back(aFace);
+ }
+ std::list<TopoDS_Shape>::iterator aFW = aFacesWires.begin();
+ for(; aFW != aFacesWires.end(); aFW++) {
+ TopExp_Explorer anEdgesExp(*aFW, TopAbs_EDGE);
+ TColStd_MapOfTransient alreadyProcessed; // to avoid counting edges with same curved (841)
+ for(; anEdgesExp.More(); anEdgesExp.Next()) {
+ TopoDS_Edge anEdge = TopoDS::Edge(anEdgesExp.Current());
+ if (!anEdge.IsNull()) {
+ Standard_Real aFirst, aLast;
+ Handle(Geom_Curve) aCurve = BRep_Tool::Curve(anEdge, aFirst, aLast);
+ if (alreadyProcessed.Contains(aCurve))
+ continue;
+ alreadyProcessed.Add(aCurve);
+ if (theCurves.IsBound(aCurve)) {
+ aFound++;
+ int anOrient = theCurves.Find(aCurve);
+ if (anOrient != 0) { // extra comparision score is orientation
+ if (edgeOrientation(aFace, anEdge) == anOrient)
+ aSameOrientation++;
+ }
+ } else {
+ aNotFound++;
}
- } else {
- aNotFound++;
}
}
- }
- if (aFound + aNotFound != 0) {
- if (aFound > aBestFound ||
- (aFound == aBestFound && aSameOrientation > aBestOrient)) {
- aBestFound = aFound;
- aBestOrient = aSameOrientation;
- aResult = aConstructionContext->face(aFaceIndex);
+ if (aFound + aNotFound != 0) {
+ if (aFound > aBestFound ||
+ (aFound == aBestFound && aSameOrientation > aBestOrient)) {
+ aBestFound = aFound;
+ aBestOrient = aSameOrientation;
+ if (theIsWire) {
+ std::shared_ptr<GeomAPI_Wire> aWire(new GeomAPI_Wire);
+ aWire->setImpl(new TopoDS_Shape(*aFW));
+ aResult = aWire;
+ } else {
+ aResult = aConstructionContext->face(aFaceIndex);
+ }
+ }
}
}
}
return aResult;
}
+std::string Model_SelectionNaming::shortName(
+ std::shared_ptr<ModelAPI_ResultConstruction>& theConstr, const int theEdgeVertexPos)
+{
+ std::string aName = theConstr->data()->name();
+ // remove "-", "/" and "&" command-symbols
+ aName.erase(std::remove(aName.begin(), aName.end(), '-'), aName.end());
+ aName.erase(std::remove(aName.begin(), aName.end(), '/'), aName.end());
+ aName.erase(std::remove(aName.begin(), aName.end(), '&'), aName.end());
+ // remove the last 's', 'e', 'f' and 'r' symbols:
+ // they are used as markers of start/end/forward/rewersed indicators
+ static const std::string aSyms("sefr");
+ std::string::iterator aSuffix = aName.end() - 1;
+ while(aSyms.find(*aSuffix) != std::string::npos) {
+ --aSuffix;
+ }
+ aName.erase(aSuffix + 1, aName.end());
+
+ if (theEdgeVertexPos == 1) {
+ aName += "s"; // start
+ } else if (theEdgeVertexPos == 2) {
+ aName += "e"; // end
+ }
+ return aName;
+}
+
// type ::= COMP | COMS | SOLD | SHEL | FACE | WIRE | EDGE | VERT
-bool Model_SelectionNaming::selectSubShape(const std::string& theType,
+bool Model_SelectionNaming::selectSubShape(const std::string& theType,
const std::string& theSubShapeName, std::shared_ptr<Model_Document> theDoc,
std::shared_ptr<GeomAPI_Shape>& theShapeToBeSelected, std::shared_ptr<ModelAPI_Result>& theCont)
{
if(theSubShapeName.empty() || theType.empty()) return false;
TopAbs_ShapeEnum aType = translateType(theType);
- std::string aContName = getContextName(theSubShapeName);
+
+ // check that it was selected in another document
+ size_t aSlash = theSubShapeName.find("/");
+ std::string aSubShapeName = theSubShapeName;
+ std::shared_ptr<Model_Document> aDoc = theDoc;
+ if (aSlash != std::string::npos) {
+ std::string aDocName = theSubShapeName.substr(0, aSlash);
+ ResultPartPtr aFoundPart;
+ DocumentPtr aRootDoc = ModelAPI_Session::get()->moduleDocument();
+ if (aDocName == aRootDoc->kind()) {
+ aDoc = std::dynamic_pointer_cast<Model_Document>(aRootDoc);
+ } else {
+ for (int a = aRootDoc->size(ModelAPI_ResultPart::group()) - 1; a >= 0; a--) {
+ ResultPartPtr aPart = std::dynamic_pointer_cast<ModelAPI_ResultPart>(
+ aRootDoc->object(ModelAPI_ResultPart::group(), a));
+ if (aPart.get() && aPart->isActivated() && aPart->data()->name() == aDocName) {
+ aDoc = std::dynamic_pointer_cast<Model_Document>(aPart->partDoc());
+ aFoundPart = aPart;
+ break;
+ }
+ }
+ }
+ if (aDoc != theDoc) {
+ // so, the first word is the document name => reduce the string for the next manips
+ aSubShapeName = theSubShapeName.substr(aSlash + 1);
+ if (aSubShapeName.empty() && aFoundPart.get()) { // the whole Part result
+ theCont = aFoundPart;
+ return true;
+ }
+ }
+ }
+
+ std::string aContName = getContextName(aSubShapeName);
if(aContName.empty()) return false;
- ResultPtr aCont = theDoc->findByName(aContName);
- //if(!aCont.get() || aCont->shape()->isNull()) return false;
- //TopoDS_Shape aContext = aCont->shape()->impl<TopoDS_Shape>();
- //TopAbs_ShapeEnum aContType = aContext.ShapeType();
- //if(aType <= aContType) return false; // not applicable
+ ResultPtr aCont = aDoc->findByName(aContName);
+ // possible this is body where postfix is added to distinguish several shapes on the same label
+ int aSubShapeId = -1; // -1 means sub shape not found
+ // for result body the name wihtout "_" has higher priority than with it: it is always added
+ if ((!aCont.get()/* || (aCont->groupName() == ModelAPI_ResultBody::group())*/) &&
+ aContName == aSubShapeName) {
+ size_t aPostIndex = aContName.rfind('_');
+ if (aPostIndex != std::string::npos) {
+ std::string aSubContName = aContName.substr(0, aPostIndex);
+ ResultPtr aSubCont = aDoc->findByName(aSubContName);
+ if (aSubCont.get()) {
+ try {
+ std::string aNum = aContName.substr(aPostIndex + 1);
+ aSubShapeId = std::stoi(aNum);
+ } catch (std::invalid_argument&) {
+ aSubShapeId = -1;
+ }
+ if (aSubShapeId > 0) {
+ aContName = aSubContName;
+ aCont = aSubCont;
+ }
+ }
+ }
+ }
TopoDS_Shape aSelection;
- switch (aType)
+ switch (aType)
{
case TopAbs_FACE:
+ case TopAbs_WIRE:
{
- aSelection = findFaceByName(theSubShapeName, theDoc);
+ aSelection = findFaceByName(aSubShapeName, aDoc);
}
break;
case TopAbs_EDGE:
- {
- const TDF_Label& aLabel = theDoc->findNamingName(theSubShapeName);
+ {
+ const TDF_Label& aLabel = aDoc->findNamingName(aSubShapeName);
if(!aLabel.IsNull()) {
Handle(TNaming_NamedShape) aNS;
if(aLabel.FindAttribute(TNaming_NamedShape::GetID(), aNS)) {
- aSelection = getShapeFromNS(theSubShapeName, aNS);
+ aSelection = getShapeFromNS(aSubShapeName, aNS);
}
}
}
break;
case TopAbs_VERTEX:
{
- const TDF_Label& aLabel = theDoc->findNamingName(theSubShapeName);
+ const TDF_Label& aLabel = aDoc->findNamingName(aSubShapeName);
if(!aLabel.IsNull()) {
Handle(TNaming_NamedShape) aNS;
if(aLabel.FindAttribute(TNaming_NamedShape::GetID(), aNS)) {
- aSelection = getShapeFromNS(theSubShapeName, aNS);
+ aSelection = getShapeFromNS(aSubShapeName, aNS);
}
}
}
case TopAbs_COMPSOLID:
case TopAbs_SOLID:
case TopAbs_SHELL:
- case TopAbs_WIRE:
- default: //TopAbs_SHAPE
+ default: {//TopAbs_SHAPE
+ /// case when the whole sketch is selected, so,
+ /// selection type is compound, but there is no value
+ if (aCont.get() && aCont->shape().get()) {
+ if (aCont->shape()->impl<TopoDS_Shape>().ShapeType() == aType) {
+ theCont = aCont;
+ return true;
+ } else if (aSubShapeId > 0) { // try to find sub-shape by the index
+ TopExp_Explorer anExp(aCont->shape()->impl<TopoDS_Shape>(), aType);
+ for(; aSubShapeId > 1 && anExp.More(); aSubShapeId--) {
+ anExp.Next();
+ }
+ if (anExp.More()) {
+ std::shared_ptr<GeomAPI_Shape> aShapeToBeSelected(new GeomAPI_Shape());
+ aShapeToBeSelected->setImpl(new TopoDS_Shape(anExp.Current()));
+ theShapeToBeSelected = aShapeToBeSelected;
+ theCont = aCont;
+ return true;
+ }
+ }
+ }
return false;
+ }
}
// another try to find edge or vertex by faces
std::list<std::string> aListofNames;
- size_t aN = aSelection.IsNull() ? ParseName(theSubShapeName, aListofNames) : 0;
+ size_t aN = aSelection.IsNull() ? ParseName(aSubShapeName, aListofNames) : 0;
if (aSelection.IsNull() && (aType == TopAbs_EDGE || aType == TopAbs_VERTEX)) {
if(aN > 1 && (aN < 4 || (aType == TopAbs_EDGE && aN < 5))) { // 2 || 3 or 4 for EDGE
TopTools_ListOfShape aList;
std::list<std::string>::iterator it = aListofNames.begin();
for(; it != aListofNames.end(); it++){
- const TopoDS_Shape aFace = findFaceByName(*it, theDoc);
+ const TopoDS_Shape aFace = findFaceByName(*it, aDoc);
if(!aFace.IsNull())
- aList.Append(aFace);
+ aList.Append(aFace);
}
aSelection = findCommonShape(aType, aList);
}
}
- if (!aSelection.IsNull()) {// Select it
- std::shared_ptr<GeomAPI_Shape> aShapeToBeSelected(new GeomAPI_Shape());
- aShapeToBeSelected->setImpl(new TopoDS_Shape(aSelection));
- theShapeToBeSelected = aShapeToBeSelected;
- theCont = aCont;
- return true;
- }
// in case of construction, there is no registered names for all sub-elements,
// even for the main element; so, trying to find them by name (without "&" intersections)
if (aN == 0) {
- size_t aConstrNamePos = theSubShapeName.find("/");
+ size_t aConstrNamePos = aSubShapeName.find("/");
bool isFullName = aConstrNamePos == std::string::npos;
- std::string aContrName =
- isFullName ? theSubShapeName : theSubShapeName.substr(0, aConstrNamePos);
- ResultPtr aConstr = theDoc->findByName(aContrName);
+ std::string aContrName = aContName;
+ ResultPtr aConstr = aDoc->findByName(aContrName);
if (aConstr.get() && aConstr->groupName() == ModelAPI_ResultConstruction::group()) {
theCont = aConstr;
if (isFullName) {
- theShapeToBeSelected = aConstr->shape();
+ // For the full construction selection shape must be empty.
+ //theShapeToBeSelected = aConstr->shape();
return true;
}
// for sketch sub-elements selected
- CompositeFeaturePtr aComposite =
- std::dynamic_pointer_cast<ModelAPI_CompositeFeature>(theDoc->feature(aConstr));
+ CompositeFeaturePtr aComposite =
+ std::dynamic_pointer_cast<ModelAPI_CompositeFeature>(aDoc->feature(aConstr));
if (aComposite.get()) {
if (aType == TopAbs_VERTEX || aType == TopAbs_EDGE) {
// collect all IDs in the name
- std::map<int, bool> anIDs;
- if (!parseSubIndices(theSubShapeName, aType == TopAbs_EDGE ? "Edge" : "Vertex", anIDs))
+ std::map<int, int> anIDs;
+ if (!parseSubIndices(aComposite, aSubShapeName,
+ aType == TopAbs_EDGE ? "Edge" : "Vertex", anIDs))
return false;
const int aSubNum = aComposite->numberOfSubs();
int aCompID = aComposite->subFeatureId(a);
if (anIDs.find(aCompID) != anIDs.end()) { // found the vertex/edge shape
FeaturePtr aSub = aComposite->subFeature(a);
- ResultConstructionPtr aV = std::dynamic_pointer_cast<ModelAPI_ResultConstruction>
- (*(aSub->results().begin()));
- if (aV) {
- theShapeToBeSelected = aV->shape();
- return true;
+ const std::list<std::shared_ptr<ModelAPI_Result> >& aResults = aSub->results();
+ std::list<std::shared_ptr<ModelAPI_Result> >::const_iterator aRIt = aResults.cbegin();
+ // there may be many shapes (circle and center)
+ for(; aRIt != aResults.cend(); aRIt++) {
+ ResultConstructionPtr aRes =
+ std::dynamic_pointer_cast<ModelAPI_ResultConstruction>(*aRIt);
+ if (aRes) {
+ int anOrientation = abs(anIDs[aCompID]);
+ TopoDS_Shape aShape = aRes->shape()->impl<TopoDS_Shape>();
+ if (anOrientation == 1) {
+ if (aType == aShape.ShapeType()) {
+ theShapeToBeSelected = aRes->shape();
+ return true;
+ }
+ } else { // take first or second vertex of the edge
+ TopoDS_Shape aShape = aRes->shape()->impl<TopoDS_Shape>();
+ TopExp_Explorer anExp(aShape, aType);
+ for(; anExp.More() && anOrientation != 2; anOrientation--)
+ anExp.Next();
+ if (anExp.More()) {
+ std::shared_ptr<GeomAPI_Shape> aShapeToBeSelected(new GeomAPI_Shape());
+ aShapeToBeSelected->setImpl(new TopoDS_Shape(anExp.Current()));
+ theShapeToBeSelected = aShapeToBeSelected;
+ return true;
+ }
+ }
+ }
}
- } else if (aType == TopAbs_VERTEX &&
- (anIDs.find(aCompID + kSTART_VERTEX_DELTA) != anIDs.end() ||
- anIDs.find(aCompID + 2 * kSTART_VERTEX_DELTA) != anIDs.end())) {
+ }
+ }
+ // sketch faces is identified by format "Sketch_1/Face-2f-8f-11r"
+ } else if (aType == TopAbs_FACE || aType == TopAbs_WIRE) {
+ std::map<int, int> anIDs;
+ if (!parseSubIndices(aComposite, aSubShapeName,
+ aType == TopAbs_FACE ? "Face" : "Wire", anIDs, true))
+ return false;
+
+ // curves and orientations of edges
+ NCollection_DataMap<Handle(Geom_Curve), int> allCurves;
+ const int aSubNum = aComposite->numberOfSubs();
+ for(int a = 0; a < aSubNum; a++) {
+ int aSubID = aComposite->subFeatureId(a);
+ if (anIDs.find(aSubID) != anIDs.end()) {
FeaturePtr aSub = aComposite->subFeature(a);
const std::list<std::shared_ptr<ModelAPI_Result> >& aResults = aSub->results();
- std::list<std::shared_ptr<ModelAPI_Result> >::const_iterator aRes = aResults.cbegin();
- // there may be many shapes (circle and center)
- for(; aRes != aResults.cend(); aRes++) {
- ResultConstructionPtr aE =
+ std::list<std::shared_ptr<ModelAPI_Result> >::const_iterator aRes;
+ for(aRes = aResults.cbegin(); aRes != aResults.cend(); aRes++) {
+ ResultConstructionPtr aConstr =
std::dynamic_pointer_cast<ModelAPI_ResultConstruction>(*aRes);
- if (aE && aE->shape()->isEdge()) {
- const TopoDS_Shape& anEdge = aE->shape()->impl<TopoDS_Shape>();
- TopExp_Explorer aVExp(anEdge, TopAbs_VERTEX); // first vertex
- if (anIDs.find(aCompID + kSTART_VERTEX_DELTA) == anIDs.end())
- aVExp.Next(); // second vertex
- std::shared_ptr<GeomAPI_Shape> aShapeToBeSelected(new GeomAPI_Shape());
- aShapeToBeSelected->setImpl(new TopoDS_Shape(aVExp.Current()));
- theShapeToBeSelected = aShapeToBeSelected;
- return true;
+ if (aConstr->shape() && aConstr->shape()->isEdge()) {
+ const TopoDS_Shape& aResShape = aConstr->shape()->impl<TopoDS_Shape>();
+ TopoDS_Edge anEdge = TopoDS::Edge(aResShape);
+ if (!anEdge.IsNull()) {
+ Standard_Real aFirst, aLast;
+ Handle(Geom_Curve) aCurve = BRep_Tool::Curve(anEdge, aFirst, aLast);
+ allCurves.Bind(aCurve, anIDs[aSubID] > 0 ? 1 : -1);
+ }
}
}
}
}
- } else if (aType == TopAbs_FACE) { // sketch faces is identified by format "Sketch_1/Face-2f-8f-11r"
- std::map<int, bool> anIDs;
- if (!parseSubIndices(theSubShapeName, "Face", anIDs, true))
+ std::shared_ptr<GeomAPI_Shape> aFoundFW =
+ findAppropriateFace(aConstr, allCurves, aType == TopAbs_WIRE);
+ if (aFoundFW.get()) {
+ theShapeToBeSelected = aFoundFW;
+ return true;
+ }
+ } else if (aType == TopAbs_WIRE) {
+ // sketch faces is identified by format "Sketch_1/Face-2f-8f-11r"
+ std::map<int, int> anIDs;
+ if (!parseSubIndices(aComposite, aSubShapeName, "Wire", anIDs))
return false;
- NCollection_DataMap<Handle(Geom_Curve), int> allCurves; // curves and orientations of edges
+ // curves and orientations of edges
+ NCollection_DataMap<Handle(Geom_Curve), int> allCurves;
const int aSubNum = aComposite->numberOfSubs();
for(int a = 0; a < aSubNum; a++) {
int aSubID = aComposite->subFeatureId(a);
const std::list<std::shared_ptr<ModelAPI_Result> >& aResults = aSub->results();
std::list<std::shared_ptr<ModelAPI_Result> >::const_iterator aRes;
for(aRes = aResults.cbegin(); aRes != aResults.cend(); aRes++) {
- ResultConstructionPtr aConstr =
+ ResultConstructionPtr aConstr =
std::dynamic_pointer_cast<ModelAPI_ResultConstruction>(*aRes);
if (aConstr->shape() && aConstr->shape()->isEdge()) {
const TopoDS_Shape& aResShape = aConstr->shape()->impl<TopoDS_Shape>();
if (!anEdge.IsNull()) {
Standard_Real aFirst, aLast;
Handle(Geom_Curve) aCurve = BRep_Tool::Curve(anEdge, aFirst, aLast);
- allCurves.Bind(aCurve, anIDs[aSubID] ? 1 : -1);
+ allCurves.Bind(aCurve, anIDs[aSubID] > 0 ? 1 : -1);
}
}
}
}
}
- std::shared_ptr<GeomAPI_Shape> aFoundFace = findAppropriateFace(aConstr, allCurves);
- if (aFoundFace.get()) {
- theShapeToBeSelected = aFoundFace;
+ std::shared_ptr<GeomAPI_Shape> aFoundFW =
+ findAppropriateFace(aConstr, allCurves, aType == TopAbs_WIRE);
+ if (aFoundFW.get()) {
+ theShapeToBeSelected = aFoundFW;
return true;
}
}
}
}
}
+ if (!aSelection.IsNull()) {
+ // Select it (must be after N=0 checking,
+ // since for simple constructions the shape must be null)
+ std::shared_ptr<GeomAPI_Shape> aShapeToBeSelected(new GeomAPI_Shape());
+ aShapeToBeSelected->setImpl(new TopoDS_Shape(aSelection));
+ theShapeToBeSelected = aShapeToBeSelected;
+ theCont = aCont;
+ return true;
+ }
+
return false;
}