cc=MEDCouplingCMesh()
cc.setCoords(c,c,c)
um=cc.buildUnstructured()
- f=um.getMeasureField(ON_CELLS)
+ f=um.getMeasureField(False)
#
n2o=um.simplexize(PLANAR_FACE_5)
f.setArray(f.getArray()[n2o])
pt_c = coo.deepCopy(); pt_c[:,0] = 1.0; pt_c[:,1] = 0.0
# P = x*C+y*A + xy(B-A-C) + ORIGIN
coo2 = coo[:,0]*pt_c + coo[:, 1]*pt_a + coo[:, 0]*coo[:, 1]*(pt_b - pt_a - pt_c) + orig
-
+
tgt.setCoords(coo2)
-
+
sCoo = DataArrayDouble([0.0,0.0, -0.3,1.0, 2.0,3.0, 1.0,0.0],4,2)
- sCoo[:,0] += 10.0; sCoo[:,1] += 15.0;
+ sCoo[:,0] += 10.0; sCoo[:,1] += 15.0;
sConn = DataArrayInt([0,1,2,3])
s = MEDCoupling1SGTUMesh("source",NORM_QUAD4) ; s.setCoords(sCoo)
s.setNodalConnectivity(sConn)
srcField.setMesh(s); srcField.setName("field")
srcField.setArray(DataArrayDouble([1.0,2.0,3.0,4.0]))
tgtF = aRemapper.transferField(srcField, 1e+300)
- ref = [1.0, 1.75, 2.5, 3.25, 4.0, 1.25, 1.875, 2.5, 3.125, 3.75, 1.5, 2.0, 2.5, 3.0, 3.5, 1.75,
+ ref = [1.0, 1.75, 2.5, 3.25, 4.0, 1.25, 1.875, 2.5, 3.125, 3.75, 1.5, 2.0, 2.5, 3.0, 3.5, 1.75,
2.125, 2.5, 2.875, 3.25, 2.0, 2.25, 2.5, 2.75, 3.0]
val = tgtF.getArray().getValues()
for i, ref_v in enumerate(ref):
- self.assertAlmostEqual(ref_v, val[i])
+ self.assertAlmostEqual(ref_v, val[i])
pass
def testSwig2MappedBarycentricP1P13_1(self):
pt_1 = coo.deepCopy(); pt_1[:,0] = 0.0; pt_1[:,1] = 0.0; pt_1[:,2] = 1.0
pt_2 = coo.deepCopy(); pt_2[:,0] = 1.0; pt_2[:,1] = 0.0; pt_2[:,2] = 1.0
pt_3 = coo.deepCopy(); pt_3[:,0] = 2.0; pt_3[:,1] = 3.0; pt_3[:,2] = 1.0
-
+
pt_4 = coo.deepCopy(); pt_4[:,0] = -0.3; pt_4[:,1] = 1.0; pt_4[:,2] = 0.0
orig = coo.deepCopy(); orig[:,0] = 10.0; orig[:,1] = 15.0; orig[:,2] = 20.0
- pt_6 = coo.deepCopy(); pt_6[:,0] = 1.0; pt_6[:,1] = 0.0; pt_6[:,2] = 0.0
+ pt_6 = coo.deepCopy(); pt_6[:,0] = 1.0; pt_6[:,1] = 0.0; pt_6[:,2] = 0.0
pt_7 = coo.deepCopy(); pt_7[:,0] = 2.0; pt_7[:,1] = 3.0; pt_7[:,2] = 0.0
# P = x*p6 + y*p4 + z*p1 + xy*(p7-p6-p4) + xz*(p2-p1-p6) + yz*(p0-p4-p1) + xyz(p3-p7-p2-p0+p1+p6+p4)
x,y,z = coo[:,0],coo[:,1],coo[:,2]
x*y*(pt_7 - pt_6 - pt_4) + x*z*(pt_2 - pt_1 - pt_6) + y*z*(pt_0 - pt_4 - pt_1) + \
x*y*z*(pt_3 - pt_7 - pt_2 - pt_0 + pt_6 + pt_1 + pt_4) + orig
tgt.setCoords(coo2)
-
- sCoo = DataArrayDouble([-0.3,1.0,1.0, 0.0,0.0,1.0, 1.0,0.0,1.0, 2.0,3.0,1.0,
+
+ sCoo = DataArrayDouble([-0.3,1.0,1.0, 0.0,0.0,1.0, 1.0,0.0,1.0, 2.0,3.0,1.0,
-0.3,1.0,0.0, 0.0,0.0,0.0, 1.0,0.0,0.0, 2.0,3.0,0.0,],8,3)
- sCoo[:, 0] += 10.0; sCoo[:, 1] += 15.0; sCoo[:, 2] += 20.0;
+ sCoo[:, 0] += 10.0; sCoo[:, 1] += 15.0; sCoo[:, 2] += 20.0;
sConn = DataArrayInt([0,1,2,3,4, 5,6,7])
s = MEDCoupling1SGTUMesh("source",NORM_HEXA8) ; s.setCoords(sCoo)
s.setNodalConnectivity(sConn)
srcField.setArray(DataArrayDouble([1.0,2.0,3.0,4.0,5.0,6.0,7.0,8.0]))
tgtF = aRemapper.transferField(srcField, 1e+300)
# print tgtF.getArray().getValues()
- ref = [6.0, 6.251802698104413, 6.502397834044702, 6.7517940736426665, 7.0, 5.740554726834594,
- 6.1761835575796935, 6.6052985689637564, 7.009392769824465, 7.383488834310164,
- 5.487562931129931, 6.140664596972973, 6.720290674177548, 7.220534970454015, 7.651092836860121,
- 5.2407867837524345, 6.125759809889516, 6.82853486793175, 7.390880823876876, 7.848445254819061,
- 5.0, 6.12211344611157, 6.925740671133115, 7.529623182840827, 8.0, 5.0, 5.251802698104413,
- 5.502397834044702, 5.751794073642667, 6.0, 4.740554726834594, 5.1761835575796935,
+ ref = [6.0, 6.251802698104413, 6.502397834044702, 6.7517940736426665, 7.0, 5.740554726834594,
+ 6.1761835575796935, 6.6052985689637564, 7.009392769824465, 7.383488834310164,
+ 5.487562931129931, 6.140664596972973, 6.720290674177548, 7.220534970454015, 7.651092836860121,
+ 5.2407867837524345, 6.125759809889516, 6.82853486793175, 7.390880823876876, 7.848445254819061,
+ 5.0, 6.12211344611157, 6.925740671133115, 7.529623182840827, 8.0, 5.0, 5.251802698104413,
+ 5.502397834044702, 5.751794073642667, 6.0, 4.740554726834594, 5.1761835575796935,
5.6052985689637564, 6.009392769824465, 6.383488834310163, 4.487562931129931, 5.140664596972973,
- 5.720290674177548, 6.220534970454015, 6.651092836860121, 4.2407867837524345, 5.125759809889516,
- 5.828534867931749, 6.390880823876876, 6.848445254819061, 4.0, 5.122113446111569, 5.925740671133115,
- 6.529623182840827, 7.0, 4.0, 4.251802698104413, 4.502397834044702, 4.751794073642667, 5.0, 3.740554726834594,
- 4.176183557579693, 4.6052985689637564, 5.009392769824464, 5.383488834310164, 3.487562931129931,
- 4.140664596972973, 4.720290674177548, 5.220534970454015, 5.651092836860121, 3.240786783752434, 4.125759809889516, 4.82853486793175,
- 5.390880823876876, 5.848445254819061, 3.0, 4.122113446111569, 4.925740671133115, 5.529623182840827, 6.0, 3.0,
- 3.2518026981044135, 3.502397834044702, 3.7517940736426674, 4.0, 2.7405547268345933, 3.176183557579693,
- 3.6052985689637564, 4.009392769824465, 4.383488834310164, 2.487562931129931, 3.140664596972973, 3.7202906741775474, 4.220534970454015, 4.65109283686012, 2.2407867837524345, 3.1257598098895154, 3.828534867931749,
- 4.390880823876876, 4.848445254819061, 2.0, 3.1221134461115687, 3.9257406711331146, 4.529623182840826, 5.0, 2.0, 2.2518026981044135, 2.502397834044702, 2.7517940736426674, 3.0, 1.7405547268345936, 2.176183557579693, 2.6052985689637564,
- 3.0093927698244642, 3.3834888343101635, 1.4875629311299305, 2.1406645969729734, 2.720290674177548,
+ 5.720290674177548, 6.220534970454015, 6.651092836860121, 4.2407867837524345, 5.125759809889516,
+ 5.828534867931749, 6.390880823876876, 6.848445254819061, 4.0, 5.122113446111569, 5.925740671133115,
+ 6.529623182840827, 7.0, 4.0, 4.251802698104413, 4.502397834044702, 4.751794073642667, 5.0, 3.740554726834594,
+ 4.176183557579693, 4.6052985689637564, 5.009392769824464, 5.383488834310164, 3.487562931129931,
+ 4.140664596972973, 4.720290674177548, 5.220534970454015, 5.651092836860121, 3.240786783752434, 4.125759809889516, 4.82853486793175,
+ 5.390880823876876, 5.848445254819061, 3.0, 4.122113446111569, 4.925740671133115, 5.529623182840827, 6.0, 3.0,
+ 3.2518026981044135, 3.502397834044702, 3.7517940736426674, 4.0, 2.7405547268345933, 3.176183557579693,
+ 3.6052985689637564, 4.009392769824465, 4.383488834310164, 2.487562931129931, 3.140664596972973, 3.7202906741775474, 4.220534970454015, 4.65109283686012, 2.2407867837524345, 3.1257598098895154, 3.828534867931749,
+ 4.390880823876876, 4.848445254819061, 2.0, 3.1221134461115687, 3.9257406711331146, 4.529623182840826, 5.0, 2.0, 2.2518026981044135, 2.502397834044702, 2.7517940736426674, 3.0, 1.7405547268345936, 2.176183557579693, 2.6052985689637564,
+ 3.0093927698244642, 3.3834888343101635, 1.4875629311299305, 2.1406645969729734, 2.720290674177548,
3.2205349704540143, 3.6510928368601205, 1.2407867837524345, 2.125759809889516, 2.8285348679317495, 3.390880823876876, 3.848445254819061, 1.0, 2.1221134461115687, 2.9257406711331146, 3.529623182840827, 4.0]
val = tgtF.getArray().getValues()
for i, ref_v in enumerate(ref):
- self.assertAlmostEqual(ref_v, val[i])
+ self.assertAlmostEqual(ref_v, val[i])
pass
@unittest.skipUnless(MEDCouplingHasNumPyBindings() and MEDCouplingHasSciPyBindings(),"requires numpy AND scipy")
self.assertAlmostEqual(m_1[2,3],0.3,12)
self.assertEqual(m_1.getnnz(),7)
pass
-
+
@unittest.skipUnless(MEDCouplingHasNumPyBindings() and MEDCouplingHasSciPyBindings(),"requires numpy AND scipy")
def testP0P1Bary_1(self):
a=MEDCouplingUMesh("a",2)
#
rem=MEDCouplingRemapper()
rem.setMaxDistance3DSurfIntersect(1e-12)
- rem.setMinDotBtwPlane3DSurfIntersect(0.99)# this line is important it is to tell to remapper to select only cells with very close orientation
+ rem.setMinDotBtwPlane3DSurfIntersect(0.99)# this line is important it is to tell to remapper to select only cells with very close orientation
rem.prepare(skinAndNonConformCells,skinAndNonConformCells,"P0P0")
mat=rem.getCrudeCSRMatrix()
indptr=DataArrayInt(mat.indptr)
#
self.assertTrue(coarse.isEqual(trgField.getArray(),1e-12))
pass
-
+
@unittest.skipUnless(MEDCouplingHasNumPyBindings() and MEDCouplingHasSciPyBindings(),"requires numpy AND scipy")
def test1DPointLocator1(self):
"""This test focuses on PointLocator for P1P1 in 1D and 2DCurve."""
diff=abs(m-mExp0)
self.assertAlmostEqual(diff.sum(),0.,14)
pass
-
+
def test3D2Dand2D3DPointLocator1(self):
""" Non regression test solving SIGSEGV when using 3D<->3Dsurf pointlocator."""
arrX=DataArrayDouble([0,1,2])
rem.prepare(mt,ms,"P0P0")
self.assertEqual(rem.getCrudeMatrix(),[{0:1.},{1:1.}])
pass
-
+
+ def test3D1DPointLocatorBBoxAdjusted(self):
+ """ In case a 1D segment lies exactly on the interface between two 2D (or 3D) faces, the default
+ bounding box logic will make it non-intersecting with the surrounding 2D (or 3D) faces.
+ Test bounding box adjustment allowing to widen the BB to capture this.
+ """
+ m = MEDCouplingCMesh("source")
+ di, dd = DataArrayInt, DataArrayDouble
+ m.setCoordsAt(0, dd([0.0, 1.0, 2.0]))
+ m.setCoordsAt(1, dd([0.0, 1.0]))
+ m.setCoordsAt(2, dd([0.0, 1.0]))
+ m3d = m.buildUnstructured()
+ m1d = MEDCouplingUMesh("target", 1)
+ m1d.setCoords(dd([1.0,0.5,0.2 , 1.0,0.5,0.8], 2,3))
+ m1d.setConnectivity(di([NORM_SEG2, 0, 1]), di([0,3]))
+
+ rem = MEDCouplingRemapper()
+ rem.setPrecision(1e-12)
+ rem.setIntersectionType(PointLocator)
+ rem.prepare(m3d, m1d,"P0P1")
+ self.assertEqual(rem.getCrudeMatrix(), [{0: 1.0, 1: 1.0}, {0: 1.0, 1: 1.0}])
+
+ rem = MEDCouplingRemapper()
+ rem.setPrecision(1e-12)
+ rem.setIntersectionType(PointLocator)
+ rem.setBoundingBoxAdjustment(0.0)
+ rem.setBoundingBoxAdjustmentAbs(0.0)
+ rem.prepare(m3d, m1d,"P0P1")
+ self.assertEqual(rem.getCrudeMatrix(), [{}, {}])
+ pass
+
+ def testPointLocator3DTo2D(self):
+ """Target mesh has spaceDim==3 and meshDim==2. Source has spaceDim==3 and meshDim==3. Here we are on pointlocator alg.
+ The test evaluates on each nodes of target mesh the bary coor into source mesh."""
+ src=MEDCouplingCMesh()
+ arr=DataArrayDouble([0,1,2])
+ src.setCoords(arr,arr,arr)
+ src=src.buildUnstructured()
+ src.simplexize(PLANAR_FACE_5)
+ fsrc=MEDCouplingFieldDouble(ON_NODES) ; fsrc.setMesh(src)
+ fsrc.setArray(DataArrayDouble([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26]))
+ #
+ trg=MEDCouplingCMesh()
+ arr=DataArrayDouble([0,1])
+ trg.setCoords(arr,arr)
+ trg=trg.buildUnstructured()
+ trg.changeSpaceDimension(3,0.)
+ trg.translate([0.5,0.5,0.5])
+ #
+ arrTrg=fsrc.getValueOnMulti(trg.getCoords())
+ ftrg=MEDCouplingFieldDouble(ON_NODES)
+ ftrg.setMesh(trg)
+ ftrg.setArray(arrTrg)
+ ftrg.checkConsistencyLight()
+ ftrg.setNature(IntensiveMaximum)
+ #
+ fsrc.setNature(IntensiveMaximum)
+ remap=MEDCouplingRemapper()
+ remap.setIntersectionType(PointLocator)
+ self.assertEqual(remap.prepare(src,trg,"P1P1"),1)
+ ftrg2=remap.transferField(fsrc,1e300)
+ self.assertTrue(ftrg.isEqual(ftrg2,1e-12,1e-12))
+ pass
+
def testExtrudedOnDiffZLev1(self):
"""Non regression bug : This test is base on P0P0 ExtrudedExtruded. This test checks that if the input meshes are not based on a same plane // OXY the interpolation works"""
arrX=DataArrayDouble([0,1]) ; arrY=DataArrayDouble([0,1]) ; arrZ=DataArrayDouble([0,1,2])
self.checkMatrix(rem2.getCrudeMatrix(),[{0:0.125,1:0.25}],src.getNumberOfCells(),1e-12)
pass
+ def testP0P0WithHEXGP12(self):
+ """ Test that HEXGP12 are correclty remapped (elements with polygonal faces were not properly handled) """
+ # From Astrid, two disjoint hexagonal prisms:
+ coo1 = [-4.991193077144312, 8.644999999999998, 0.0, -9.982386154288623, 6.112246755425186e-16, 0.0, -4.991193077144315, -8.644999999999998, 0.0, 4.991193077144309, -8.645000000000005, 0.0, 9.982386154288626, 1.1651321638577316e-15, 0.0, 4.991193077144314, 8.645, 0.0, -4.991193077144312, 8.644999999999998, 7.561799999999991, -9.982386154288623, 6.112246755425186e-16, 7.561799999999991, -4.991193077144315, -8.644999999999998, 7.561799999999991, 4.991193077144309, -8.645000000000005, 7.561799999999991, 9.982386154288626, 1.1651321638577316e-15, 7.561799999999991, 4.991193077144314, 8.645, 7.561799999999991]
+ coo2 = [-4.991193077144313, -8.645, 0.0, -9.982386154288626, -1.3992140779350848e-15, 0.0, -19.964772308577256, 0.0, 0.0, -24.95596538572157, -8.644999999999998, 0.0, -19.96477230857726, -17.289999999999996, 0.0, -9.982386154288626, -17.289999999999996, 0.0, -4.991193077144313, -8.645, 5.041200000000004, -9.982386154288626, -1.3992140779350848e-15, 5.041200000000004, -19.964772308577256, 0.0, 5.041200000000004, -24.95596538572157, -8.644999999999998, 5.041200000000004, -19.96477230857726, -17.289999999999996, 5.041200000000004, -9.982386154288626, -17.289999999999996, 5.041200000000004]
+ conn1 = [31, 0, 5, 4, 3, 2, 1, -1, 11, 6, 7, 8, 9, 10, -1, 1, 7, 6, 0, -1, 2, 8, 7, 1, -1, 3, 9, 8, 2, -1, 4, 10, 9, 3, -1, 5, 11, 10, 4, -1, 0, 6, 11, 5]
+ cI1 = [0, 44]
+ conn2 = [31, 0, 5, 4, 3, 2, 1, -1, 6, 7, 8, 9, 10, 11, -1, 0, 1, 7, 6, -1, 1, 2, 8, 7, -1, 2, 3, 9, 8, -1, 3, 4, 10, 9, -1, 4, 5, 11, 10, -1, 5, 0, 6, 11]
+ cI2 = [0, 44]
+ mTgt = MEDCouplingUMesh("target", 3)
+ mSrc = MEDCouplingUMesh("src", 3)
+ mTgt.setCoords(DataArrayDouble(coo1, len(coo1)/3, 3))
+ mSrc.setCoords(DataArrayDouble(coo2, len(coo2)/3, 3))
+ mTgt.setConnectivity(DataArrayInt(conn1), DataArrayInt(cI1))
+ mSrc.setConnectivity(DataArrayInt(conn2), DataArrayInt(cI2))
+
+ # Recognize the HEXGP12:
+ mTgt.unPolyze()
+ mSrc.unPolyze()
+
+ rmp = MEDCouplingRemapper()
+ rmp.setIntersectionType(Triangulation)
+ rmp.prepare(mSrc, mTgt, "P0P0")
+ mat = rmp.getCrudeMatrix()
+ self.assertEqual(len(mat[0]), 0)
+ self.assertEqual(len(mat), 1)
+ pass
+
def checkMatrix(self,mat1,mat2,nbCols,eps):
self.assertEqual(len(mat1),len(mat2))
for i in xrange(len(mat1)):
pass
pass
pass
-
+
def build2DSourceMesh_1(self):
sourceCoords=[-0.3,-0.3, 0.7,-0.3, -0.3,0.7, 0.7,0.7]
sourceConn=[0,3,1,0,2,3]
myCoords.setValues(sourceCoords,4,2);
sourceMesh.setCoords(myCoords);
return sourceMesh;
-
+
def build2DTargetMesh_1(self):
targetCoords=[-0.3,-0.3, 0.2,-0.3, 0.7,-0.3, -0.3,0.2, 0.2,0.2, 0.7,0.2, -0.3,0.7, 0.2,0.7, 0.7,0.7 ]
targetConn=[0,3,4,1, 1,4,2, 4,5,2, 6,7,4,3, 7,8,5,4]
targetMesh.setCoords(myCoords);
return targetMesh;
pass
-
+
def setUp(self):
pass
pass