From: abn Date: Mon, 12 Jun 2023 19:49:45 +0000 (+0200) Subject: Bug fix: isColinear3D() was using wrongly dimensionned epsilon X-Git-Tag: V9_12_0a1~8 X-Git-Url: http://git.salome-platform.org/gitweb/?a=commitdiff_plain;h=6bde562a2144cf019c745c4d44068f1074acede0;p=tools%2Fmedcoupling.git Bug fix: isColinear3D() was using wrongly dimensionned epsilon --- diff --git a/src/INTERP_KERNEL/VectorUtils.hxx b/src/INTERP_KERNEL/VectorUtils.hxx index 47be64cd3..fb6955739 100644 --- a/src/INTERP_KERNEL/VectorUtils.hxx +++ b/src/INTERP_KERNEL/VectorUtils.hxx @@ -159,6 +159,16 @@ namespace INTERP_KERNEL return epsilonEqual(dot(cros, cros), 0.0, eps); } + /** + * Caracteristic vector size (its biggest component, in absolute) + */ + inline double caracteristicDimVector(const double *v) + { + double ret = 0; + for (int i = 0; i < 3; i++) + ret = std::max(ret, std::fabs(v[i])); + return ret; + } /** * Compares doubles using a relative tolerance diff --git a/src/MEDCoupling/MEDCouplingUMesh_intersection.cxx b/src/MEDCoupling/MEDCouplingUMesh_intersection.cxx index 16677a3d4..4d5915580 100644 --- a/src/MEDCoupling/MEDCouplingUMesh_intersection.cxx +++ b/src/MEDCoupling/MEDCouplingUMesh_intersection.cxx @@ -2339,7 +2339,7 @@ void MEDCouplingUMesh::ReplaceEdgeInFace(const mcIdType * sIdxConn, const mcIdTy * \b WARNING this method only works for 'partition-like' non-conformities. When joining adjacent faces, the set of all small faces must fit exactly into the * neighboring bigger face. No real face intersection is actually computed. * - * \param [in] eps the relative error to detect merged edges. + * \param [in] eps the absolute (geometric) error to detect merged edges. * \return DataArrayIdType * - The list of cellIds in \a this that have been subdivided. If empty, nothing changed in \a this (as if it were a const method). The array is a newly allocated array * that the user is expected to deal with. * @@ -2363,6 +2363,7 @@ DataArrayIdType *MEDCouplingUMesh::conformize3D(double eps) MCAuto connSla(MEDCouplingSkyLineArray::BuildFromPolyhedronConn(getNodalConnectivity(), getNodalConnectivityIndex())); const double * coo(_coords->begin()); MCAuto ret(DataArrayIdType::New()); ret->alloc(0,1); + const double carMeshSz = getCaracteristicDimension(); { /************************* @@ -2409,14 +2410,14 @@ DataArrayIdType *MEDCouplingUMesh::conformize3D(double eps) // Keep only candidates whose normal matches the normal of current face for(vector::const_iterator it2=candidates.begin();it2!=candidates.end();it2++) { - bool col = INTERP_KERNEL::isColinear3D(normalsP + faceIdx*SPACEDIM, normalsP + *(it2)*SPACEDIM, eps); + bool col = INTERP_KERNEL::isColinear3D(normalsP + faceIdx*SPACEDIM, normalsP + *(it2)*SPACEDIM, eps/carMeshSz); // using rough relative epsilon if (*it2 != faceIdx && col) cands2.push_back(*it2); } if (!cands2.size()) continue; - // Now rotate, and match barycenters -- this is where we will bring Intersect2DMeshes later + // Now rotate, and match barycenters -- this is where we will bring Intersect2DMeshes one day INTERP_KERNEL::TranslationRotationMatrix rotation; INTERP_KERNEL::TranslationRotationMatrix::Rotate3DTriangle(coo+SPACEDIM*(cDesc[cIDesc[faceIdx]+1]), coo+SPACEDIM*(cDesc[cIDesc[faceIdx]+2]), @@ -2579,13 +2580,17 @@ DataArrayIdType *MEDCouplingUMesh::conformize3D(double eps) mcIdType start = cDesc2[cIDesc2[eIdx]+1], end = cDesc2[cIDesc2[eIdx]+2]; for (mcIdType i3=0; i3 < 3; i3++) // TODO: use fillSonCellNodalConnectivity2 or similar? vCurr[i3] = coo[start*SPACEDIM+i3] - coo[end*SPACEDIM+i3]; + double carSz = INTERP_KERNEL::caracteristicDimVector(vCurr), eps2 = eps*carSz*carSz*carSz; for(vector::const_iterator it2=candidates.begin();it2!=candidates.end();it2++) { double vOther[3]; mcIdType start2 = cDesc2[cIDesc2[*it2]+1], end2 = cDesc2[cIDesc2[*it2]+2]; for (mcIdType i3=0; i3 < 3; i3++) vOther[i3] = coo[start2*SPACEDIM+i3] - coo[end2*SPACEDIM+i3]; - bool col = INTERP_KERNEL::isColinear3D(vCurr, vOther, eps); + // isColinear() expect unit vecotr, and relative (non geometrical) precision. + // relative prec means going from eps -> eps/curSz + // normalizing vCurr and vOther means multiplying by v^4, knowing that inside isColinear3D() the square (^2) of a dot product (^2) is computed + bool col = INTERP_KERNEL::isColinear3D(vCurr, vOther, eps2); // Warning: different from faces: we need to keep eIdx in the final list of candidates because we need // to have its nodes inside the sub mesh mPartCand below (needed in OrderPointsAlongLine()) if (col) @@ -2600,7 +2605,7 @@ DataArrayIdType *MEDCouplingUMesh::conformize3D(double eps) INTERP_KERNEL::TranslationRotationMatrix rotation; INTERP_KERNEL::TranslationRotationMatrix::Rotate3DBipoint(coo+SPACEDIM*startNode, coo+SPACEDIM*endNode, rotation); MCAuto mPartRef(mDesc2->buildPartOfMySelfSlice(eIdx, eIdx+1,1,false)); // false=zipCoords is called - MCAuto mPartCand(mDesc2->buildPartOfMySelf(&cands2[0], &cands2[0]+cands2.size(), true)); // true=zipCoords is called + MCAuto mPartCand(mDesc2->buildPartOfMySelf(&cands2[0], &cands2[0]+cands2.size(), true)); // true=zipCoords is NOT called MCAuto nodeMap(mPartCand->zipCoordsTraducer()); mcIdType nbElemsNotM1; { @@ -2615,8 +2620,7 @@ DataArrayIdType *MEDCouplingUMesh::conformize3D(double eps) for (mcIdType ii = 0; ii < mPartCand->_coords->getNumberOfTuples(); ii++) rotation.transform_vector(cooPartCand+SPACEDIM*ii); - - // Eliminate all edges for which y or z is not null + // Eliminate all edges for which y or z is not null - those are colinear edges which are simply parallels, but not on the same line MCAuto baryPart = mPartCand->computeCellCenterOfMass(); vector compo; compo.push_back(1); MCAuto baryPartY = baryPart->keepSelectedComponents(compo);