+
+ def testGaussWriteOnPfl1(self):
+ fname="Pyfile49.med"
+ fname2="Pyfile50.med"
+ coords=DataArrayDouble([0.,0.,0.,1.,1.,1.,1.,0.,0.,0.5,0.5,1.,1.,0.5,0.5,0.],8,2)
+ mQ8=MEDCouplingUMesh("",2) ; mQ8.setCoords(coords)
+ mQ8.allocateCells(1)
+ mQ8.insertNextCell(NORM_QUAD8,range(8))
+ mQ8.finishInsertingCells()
+ mQ4=MEDCouplingUMesh("",2) ; mQ4.setCoords(coords)
+ mQ4.allocateCells(1)
+ mQ4.insertNextCell(NORM_QUAD4,range(4))
+ mQ4.finishInsertingCells()
+ mT3=MEDCouplingUMesh("",2) ; mT3.setCoords(coords)
+ mT3.allocateCells(1)
+ mT3.insertNextCell(NORM_TRI3,range(3))
+ mT3.finishInsertingCells()
+
+ tr=[[0.,4.],[2.,4.],[4.,4.],[6.,4.],[8.,4.],[10.,4.],[12.,4.],[14.,4.],[16.,4.],[18.,4.],[20.,4.],[0.,0.],[2.,0.], [0.,2.],[2.,2.],[4.,2.],[6.,2.],[8.,2.],[10.,2.],[12.,2.]]
+ ms=11*[mT3]+2*[mQ4]+7*[mQ8]
+ ms[:]=(elt.deepCpy() for elt in ms)
+ for m,t in zip(ms,tr):
+ d=m.getCoords() ; d+= t
+ pass
+ m=MEDCouplingUMesh.MergeUMeshes(ms)
+ m.setName("mesh")
+ m2=m[:13] ; m2.setName(m.getName())
+ ### Use case 1 : Pfl on all tri3 and on all quad4. If we were on CELLS or GAUSS_NE no pfl were needed. But here 2 discs in tri3.
+ ### So here 2 pfls will be created (pfl_TRI3_loc_0 and pfl_TRI3_loc_1)
+ f=MEDCouplingFieldDouble.New(ON_GAUSS_PT,ONE_TIME)
+ f.setMesh(m2)
+ f.setTime(4.5,1,2)
+ da=DataArrayDouble(34) ; da.iota(3.)
+ f.setArray(da)
+ f.setName("fieldCellOnPflWithoutPfl")
+ fInvalid=f.deepCpy()
+ f.setGaussLocalizationOnCells([0,1,2,3,4,5,6,7,8],[0.,0.,1.,0.,1.,1.],[0.3,0.3,0.7,0.7],[0.8,0.2])
+ f.setGaussLocalizationOnCells([9,10],[0.,0.,1.,0.,1.,1.],[0.3,0.3,0.7,0.7,0.8,0.8],[0.8,0.07,0.13])
+ f.setGaussLocalizationOnCells([11,12],[0.,0.,1.,0.,1.,1.,0.,1.],[0.3,0.3,0.7,0.7,0.8,0.8,0.8,0.8,0.8,0.8],[0.8,0.07,0.1,0.01,0.02])
+ f.checkCoherency()
+ fInvalid2=fInvalid.deepCpy()
+ fInvalid2.getDiscretization().setArrayOfDiscIds(f.getDiscretization().getArrayOfDiscIds())
+ #
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ mm.write(fname,2)
+ #
+ f1ts=MEDFileField1TS.New()
+ pfl=DataArrayInt(range(13)) ; pfl.setName("pfl")
+ self.assertRaises(InterpKernelException,f1ts.setFieldProfile,fInvalid,mm,0,pfl) # fails because no Gauss localization per cell set !
+ self.assertRaises(InterpKernelException,f1ts.setFieldProfile,fInvalid2,mm,0,pfl) # fails because no Gauss localization set whereas gauss locid per cell given !
+ f1ts.setFieldProfile(f,mm,0,pfl)
+ f1ts.write(fname,0)
+ #
+ self.assertEqual(f1ts.getPfls(),('pfl_NORM_TRI3_loc_0', 'pfl_NORM_TRI3_loc_1'))
+ self.assertEqual(f1ts.getPflsReallyUsed(),('pfl_NORM_TRI3_loc_0', 'pfl_NORM_TRI3_loc_1'))
+ da1=DataArrayInt([0,1,2,3,4,5,6,7,8]) ; da1.setName("pfl_NORM_TRI3_loc_0")
+ self.assertTrue(f1ts.getProfile("pfl_NORM_TRI3_loc_0").isEqual(da1))
+ da1=DataArrayInt([9,10]) ; da1.setName("pfl_NORM_TRI3_loc_1")
+ self.assertTrue(f1ts.getProfile("pfl_NORM_TRI3_loc_1").isEqual(da1))
+ self.assertEqual(f1ts.getLocs(),('Loc_fieldCellOnPflWithoutPfl_NORM_TRI3_0', 'Loc_fieldCellOnPflWithoutPfl_NORM_TRI3_1', 'Loc_fieldCellOnPflWithoutPfl_NORM_QUAD4_2'))
+ self.assertEqual(f1ts.getLocsReallyUsed(),('Loc_fieldCellOnPflWithoutPfl_NORM_TRI3_0', 'Loc_fieldCellOnPflWithoutPfl_NORM_TRI3_1', 'Loc_fieldCellOnPflWithoutPfl_NORM_QUAD4_2'))
+ #
+ dataRead=MEDFileData.New(fname)
+ mRead=dataRead.getMeshes()[0]
+ f1tsRead=dataRead.getFields()[0][0]
+ f1tsRead.getFieldOnMeshAtLevel(ON_GAUSS_PT,0,mRead)
+ f2=f1tsRead.getFieldOnMeshAtLevel(ON_GAUSS_PT,0,mRead)
+ self.assertTrue(f.isEqual(f2,1e-12,1e-12))
+ f2_bis=MEDLoader.ReadFieldGauss(fname,m.getName(),0,f.getName(),f.getTime()[1],f.getTime()[2])
+ f2_bis.checkCoherency()
+ self.assertTrue(f.isEqual(f2_bis,1e-12,1e-12))
+ #
+ MEDLoader.WriteField(fname2,f,True)
+ f2_ter=MEDLoader.ReadFieldGauss(fname2,m.getName(),0,f.getName(),f.getTime()[1],f.getTime()[2])
+ self.assertTrue(f.isEqual(f2_ter,1e-12,1e-12))
+ ## Use case 2 : Pfl on part tri3 with 2 disc and on part quad8 with 1 disc
+ f=MEDCouplingFieldDouble.New(ON_GAUSS_PT,ONE_TIME)
+ pfl=DataArrayInt([1,2,5,6,8,9,15,16,17,18]) ; pfl.setName("pfl2")
+ m2=m[pfl] ; m2.setName(m.getName())
+ f.setMesh(m2)
+ f.setTime(4.5,1,2)
+ da=DataArrayDouble(35) ; da.iota(3.)
+ f.setArray(da)
+ f.setName("fieldCellOnPflWithoutPfl2")
+ f.setGaussLocalizationOnCells([0,1,3],[0.,0.,1.,0.,1.,1.],[0.3,0.3,0.7,0.7],[0.8,0.2])
+ f.setGaussLocalizationOnCells([2,4,5],[0.,0.,1.,0.,1.,1.],[0.3,0.3,0.7,0.7,0.8,0.8],[0.8,0.07,0.13])
+ f.setGaussLocalizationOnCells([6,7,8,9],[0.,0.,1.,0.,1.,1.,0.,1.,0.5,0.,1.,0.5,0.5,1.,0.,0.5],[0.3,0.3,0.7,0.7,0.8,0.8,0.8,0.8,0.8,0.8],[0.8,0.07,0.1,0.01,0.02])
+ f.checkCoherency()
+ #
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ mm.write(fname,2)
+ f1ts=MEDFileField1TS.New()
+ f1ts.setFieldProfile(f,mm,0,pfl)
+ self.assertEqual(f1ts.getPfls(),('pfl2_NORM_TRI3_loc_0','pfl2_NORM_TRI3_loc_1','pfl2_NORM_QUAD8_loc_2'))
+ self.assertEqual(f1ts.getProfile("pfl2_NORM_TRI3_loc_0").getValues(),[1,2,6])
+ self.assertEqual(f1ts.getProfile("pfl2_NORM_TRI3_loc_1").getValues(),[5,8,9])
+ self.assertEqual(f1ts.getProfile("pfl2_NORM_QUAD8_loc_2").getValues(),[2,3,4,5])
+ f1ts.write(fname,0)
+ dataRead=MEDFileData.New(fname)
+ mRead=dataRead.getMeshes()[0]
+ f1tsRead=dataRead.getFields()[0][0]
+ f1tsRead.getFieldOnMeshAtLevel(ON_GAUSS_PT,0,mRead)
+ f3=f1tsRead.getFieldOnMeshAtLevel(ON_GAUSS_PT,0,mRead)
+ f3.renumberCells([0,1,3,2,4,5,6,7,8,9])
+ self.assertTrue(f.isEqual(f3,1e-12,1e-12))
+ f3_bis=MEDLoader.ReadFieldGauss(fname,m.getName(),0,f.getName(),f.getTime()[1],f.getTime()[2])
+ f3_bis.renumberCells([0,1,3,2,4,5,6,7,8,9])
+ self.assertTrue(f.isEqual(f3_bis,1e-12,1e-12))
+ #
+ MEDLoader.WriteField(fname2,f,True)
+ f3_ter=MEDLoader.ReadFieldGauss(fname2,m.getName(),0,f.getName(),f.getTime()[1],f.getTime()[2])
+ f3_ter.renumberCells([0,1,3,2,4,5,6,7,8,9])
+ self.assertTrue(f.isEqual(f3_ter,1e-12,1e-12))
+ ## Use case 3 : no pfl but creation of pfls due to gauss pts
+ f=MEDCouplingFieldDouble.New(ON_GAUSS_PT,ONE_TIME)
+ f.setMesh(m)
+ f.setTime(4.5,1,2)
+ da=DataArrayDouble(60) ; da.iota(3.)
+ f.setArray(da)
+ f.setName("fieldCellWithoutPfl")
+ f.setGaussLocalizationOnCells([0,1,2,3,4,5,6,7,8],[0.,0.,1.,0.,1.,1.],[0.3,0.3,0.7,0.7],[0.8,0.2])
+ f.setGaussLocalizationOnCells([9,10],[0.,0.,1.,0.,1.,1.],[0.3,0.3,0.7,0.7,0.8,0.8],[0.8,0.07,0.13])
+ f.setGaussLocalizationOnCells([11,12],[0.,0.,1.,0.,1.,1.,0.,1.],[0.3,0.3,0.7,0.7,0.8,0.8,0.8,0.8,0.8,0.8],[0.8,0.07,0.1,0.01,0.02])
+ f.setGaussLocalizationOnCells([13,14,15,17,18],[0.,0.,1.,0.,1.,1.,0.,1.,0.5,0.,1.,0.5,0.5,1.,0.,0.5],[0.3,0.3,0.7,0.7,0.8,0.8,0.8,0.8],[0.8,0.1,0.03,0.07])
+ f.setGaussLocalizationOnCells([16,19],[0.,0.,1.,0.,1.,1.,0.,1.,0.5,0.,1.,0.5,0.5,1.,0.,0.5],[0.3,0.3,0.7,0.7,0.8,0.8],[0.8,0.1,0.1])
+ f.checkCoherency()
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ f1ts=MEDFileField1TS.New()
+ f1ts.setFieldNoProfileSBT(f)
+ self.assertEqual(f1ts.getPfls(),('Pfl_fieldCellWithoutPfl_NORM_TRI3_0','Pfl_fieldCellWithoutPfl_NORM_TRI3_1','Pfl_fieldCellWithoutPfl_NORM_QUAD8_3','Pfl_fieldCellWithoutPfl_NORM_QUAD8_4'))
+ self.assertEqual(f1ts.getProfile("Pfl_fieldCellWithoutPfl_NORM_TRI3_0").getValues(),[0,1,2,3,4,5,6,7,8])
+ self.assertEqual(f1ts.getProfile("Pfl_fieldCellWithoutPfl_NORM_TRI3_1").getValues(),[9,10])
+ self.assertEqual(f1ts.getProfile("Pfl_fieldCellWithoutPfl_NORM_QUAD8_3").getValues(),[0,1,2,4,5])
+ self.assertEqual(f1ts.getProfile("Pfl_fieldCellWithoutPfl_NORM_QUAD8_4").getValues(),[3,6])
+ mm.write(fname,2)
+ f1ts.write(fname,0)
+ #
+ dataRead=MEDFileData.New(fname)
+ mRead=dataRead.getMeshes()[0]
+ f1tsRead=dataRead.getFields()[0][0]
+ f3=f1tsRead.getFieldOnMeshAtLevel(ON_GAUSS_PT,0,mRead)
+ f3.renumberCells([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,17,18,16,19])
+ self.assertTrue(f.isEqual(f3,1e-12,1e-12))
+ f3_bis=MEDLoader.ReadFieldGauss(fname,m.getName(),0,f.getName(),f.getTime()[1],f.getTime()[2])
+ f3_bis.renumberCells([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,17,18,16,19])
+ self.assertTrue(f.isEqual(f3_bis,1e-12,1e-12))
+ #
+ MEDLoader.WriteField(fname2,f,True)
+ f3_ter=MEDLoader.ReadFieldGauss(fname2,m.getName(),0,f.getName(),f.getTime()[1],f.getTime()[2])
+ f3_ter.renumberCells([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,17,18,16,19])
+ self.assertTrue(f.isEqual(f3_ter,1e-12,1e-12))
+ pass
+
+ # Testing profile on nodes when the profile is identity but not on all nodes.
+ def testMEDFieldPflOnNode1(self):
+ fname="Pyfile51.med"
+ coo=DataArrayDouble([0.,0.,0.5,0.,1.,0.,0.,0.5,0.5,0.5,1.,0.5,0.,1.,0.5,1.,1.,1.],9,2)
+ m0=MEDCouplingUMesh("Mesh",2)
+ m0.allocateCells(5)
+ m0.insertNextCell(NORM_TRI3,[1,4,2])
+ m0.insertNextCell(NORM_TRI3,[4,5,2])
+ m0.insertNextCell(NORM_QUAD4,[0,3,4,1])
+ m0.insertNextCell(NORM_QUAD4,[3,6,7,4])
+ m0.insertNextCell(NORM_QUAD4,[4,7,8,5])
+ m0.finishInsertingCells()
+ m0.setCoords(coo)
+ m1=MEDCouplingUMesh(m0.getName(),1)
+ m1.allocateCells(9)
+ conn1=[0,1,0,3,3,4,4,1,5,4,2,4,1,2,3,6,5,8]
+ for i in xrange(9):
+ m1.insertNextCell(NORM_SEG2,conn1[2*i:2*i+2])
+ pass
+ m1.finishInsertingCells()
+ m1.setCoords(coo)
+ #
+ m=MEDFileUMesh()
+ m.setMeshAtLevel(0,m0)
+ m.setMeshAtLevel(-1,m1)
+ #
+ dt=3 ; it=2 ; tim=4.5
+ fieldNode0=MEDCouplingFieldDouble(ON_NODES,ONE_TIME)
+ fieldNode0.setName("fieldNode0")
+ fieldNode0.setTime(tim,dt,it)
+ pfl0=DataArrayInt([0,1,2,3,4]) ; pfl0.setName("PflIdentity0") # important to keep like that
+ arr=DataArrayDouble([10,11,12,13,14])
+ fieldNode0.setArray(arr)
+ f0=MEDFileField1TS()
+ f0.setFieldProfile(fieldNode0,m,0,pfl0)
+ m.write(fname,2) ; f0.write(fname,0)
+ fieldNode1=MEDCouplingFieldDouble(ON_NODES,ONE_TIME)
+ fieldNode1.setName("fieldNode1")
+ fieldNode1.setTime(tim,dt,it)
+ pfl1=DataArrayInt([0,1,2,3,4,5,6]) ; pfl1.setName("PflIdentity1")
+ arr1=DataArrayDouble([20,21,22,23,24,25,26])
+ fieldNode1.setArray(arr1)
+ f1=MEDFileField1TS()
+ f1.setFieldProfile(fieldNode1,m,-1,pfl1)
+ f1.write(fname,0)
+ del m,f0,m0,m1,f1
+ ## Reading from file
+ m=MEDFileMesh.New(fname)
+ m0=m.getMeshAtLevel(0)
+ m00=m0.deepCpy() ; m00=m00[[0,2]] ; m00.setName(m.getName()) ; m00.zipCoords()
+ fieldNode0.setMesh(m00)
+ f0=MEDFileField1TS.New(fname,fieldNode0.getName(),dt,it)
+ ff0_1=f0.getFieldOnMeshAtLevel(ON_NODES,m0)
+ ff0_1.checkCoherency()
+ self.assertTrue(ff0_1.isEqual(fieldNode0,1e-12,1e-12))
+ ff0_2=f0.getFieldAtLevel(ON_NODES,0)
+ ff0_2.checkCoherency()
+ self.assertTrue(ff0_2.isEqual(fieldNode0,1e-12,1e-12))
+ ff0_3=f0.getFieldOnMeshAtLevel(ON_NODES,0,m)
+ ff0_3.checkCoherency()
+ self.assertTrue(ff0_3.isEqual(fieldNode0,1e-12,1e-12))
+ ff0_4=MEDLoader.ReadFieldNode(fname,m.getName(),0,fieldNode0.getName(),dt,it)
+ ff0_4.checkCoherency()
+ self.assertTrue(ff0_4.isEqual(fieldNode0,1e-12,1e-12))
+ f1=MEDFileField1TS.New(fname,fieldNode1.getName(),dt,it)
+ m1=m.getMeshAtLevel(-1)
+ m10=m1.deepCpy() ; m10=m10[[0,1,2,3,4,5,6,7]] ; m10.setName(m.getName()) ; m10.zipCoords()
+ fieldNode1.setMesh(m10)
+ ff1_1=f1.getFieldOnMeshAtLevel(ON_NODES,m1)
+ ff1_1.checkCoherency()
+ self.assertTrue(ff1_1.isEqual(fieldNode1,1e-12,1e-12))
+ ff1_2=f1.getFieldAtLevel(ON_NODES,-1)
+ ff1_2.checkCoherency()
+ self.assertTrue(ff1_2.isEqual(fieldNode1,1e-12,1e-12))
+ ff1_3=f1.getFieldOnMeshAtLevel(ON_NODES,-1,m)
+ ff1_3.checkCoherency()
+ self.assertTrue(ff1_3.isEqual(fieldNode1,1e-12,1e-12))
+ ff1_4=MEDLoader.ReadFieldNode(fname,m.getName(),-1,fieldNode1.getName(),dt,it)
+ ff1_4.checkCoherency()
+ self.assertTrue(ff1_4.getMesh().isEqual(m10,1e-12))
+ self.assertRaises(InterpKernelException,f1.getFieldOnMeshAtLevel,ON_NODES,m0) # error because impossible to build a sub mesh at level 0 lying on nodes [0,1,2,3,4,5,6]
+ self.assertRaises(InterpKernelException,f1.getFieldAtLevel,ON_NODES,0) # error because impossible to build a sub mesh at level 0 lying on nodes [0,1,2,3,4,5,6]
+ self.assertRaises(InterpKernelException,f1.getFieldOnMeshAtLevel,ON_NODES,0,m) # error because impossible to build a sub mesh at level 0 lying on nodes [0,1,2,3,4,5,6]
+ arr_r,pfl1_r=f1.getFieldWithProfile(ON_NODES,-1,m)
+ arr_r.setName(fieldNode1.getArray().getName())
+ self.assertTrue(arr_r.isEqual(fieldNode1.getArray(),1e-12))
+ pfl1_r.setName(pfl1.getName())
+ self.assertTrue(pfl1_r.isEqual(pfl1))
+ pass
+
+ # Testing profile on nodes when the profile is identity but not on all nodes.
+ def testMEDFieldPflOnCell1(self):
+ fname="Pyfile52.med"
+ coo=DataArrayDouble([0.,0.,0.5,0.,1.,0.,0.,0.5,0.5,0.5,1.,0.5,0.,1.,0.5,1.,1.,1.],9,2)
+ m0=MEDCouplingUMesh("Mesh",2)
+ m0.allocateCells(5)
+ m0.insertNextCell(NORM_TRI3,[1,4,2])
+ m0.insertNextCell(NORM_TRI3,[4,5,2])
+ m0.insertNextCell(NORM_QUAD4,[0,3,4,1])
+ m0.insertNextCell(NORM_QUAD4,[3,6,7,4])
+ m0.insertNextCell(NORM_QUAD4,[4,7,8,5])
+ m0.finishInsertingCells()
+ m0.setCoords(coo)
+ m1=MEDCouplingUMesh(m0.getName(),1)
+ m1.allocateCells(9)
+ conn1=[0,1,0,3,3,4,4,1,5,4,2,4,1,2,3,6,5,8]
+ for i in xrange(9):
+ m1.insertNextCell(NORM_SEG2,conn1[2*i:2*i+2])
+ pass
+ m1.finishInsertingCells()
+ m1.setCoords(coo)
+ #
+ m=MEDFileUMesh()
+ m.setMeshAtLevel(0,m0)
+ m.setMeshAtLevel(-1,m1)
+ #
+ dt=3 ; it=2 ; tim=4.5
+ fieldCell0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME)
+ fieldCell0.setName("fieldCell0")
+ fieldCell0.setTime(tim,dt,it)
+ pfl0=DataArrayInt([0,1,2]) ; pfl0.setName("PflIdentity0") # important to keep like that
+ arr=DataArrayDouble([10,11,12])
+ fieldCell0.setArray(arr)
+ f0=MEDFileField1TS()
+ f0.setFieldProfile(fieldCell0,m,0,pfl0)
+ m.write(fname,2) ; f0.write(fname,0)
+ fieldCell1=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME)
+ fieldCell1.setName("fieldCell1")
+ fieldCell1.setTime(tim,dt,it)
+ pfl1=DataArrayInt([0,1,2,3,4,5,6]) ; pfl1.setName("PflIdentity1")
+ arr1=DataArrayDouble([20,21,22,23,24,25,26])
+ fieldCell1.setArray(arr1)
+ f1=MEDFileField1TS()
+ f1.setFieldProfile(fieldCell1,m,-1,pfl1)
+ f1.write(fname,0)
+ del m,f0,m0,m1,f1
+ ## Reading from file
+ m=MEDFileMesh.New(fname)
+ m0=m.getMeshAtLevel(0)
+ m00=m0.deepCpy() ; m00=m00[pfl0] ; m00.setName(m.getName())
+ fieldCell0.setMesh(m00)
+ f0=MEDFileField1TS.New(fname,fieldCell0.getName(),dt,it)
+ ff0_1=f0.getFieldOnMeshAtLevel(ON_CELLS,m0)
+ ff0_1.checkCoherency()
+ self.assertTrue(ff0_1.isEqual(fieldCell0,1e-12,1e-12))
+ ff0_2=f0.getFieldAtLevel(ON_CELLS,0)
+ ff0_2.checkCoherency()
+ self.assertTrue(ff0_2.isEqual(fieldCell0,1e-12,1e-12))
+ ff0_3=f0.getFieldOnMeshAtLevel(ON_CELLS,0,m)
+ ff0_3.checkCoherency()
+ self.assertTrue(ff0_3.isEqual(fieldCell0,1e-12,1e-12))
+ ff0_4=MEDLoader.ReadFieldCell(fname,m.getName(),0,fieldCell0.getName(),dt,it)
+ ff0_4.checkCoherency()
+ self.assertTrue(ff0_4.isEqual(fieldCell0,1e-12,1e-12))
+ f1=MEDFileField1TS.New(fname,fieldCell1.getName(),dt,it)
+ m1=m.getMeshAtLevel(-1)
+ m10=m1.deepCpy() ; m10=m10[pfl1] ; m10.setName(m.getName())
+ fieldCell1.setMesh(m10)
+ ff1_1=f1.getFieldOnMeshAtLevel(ON_CELLS,m1)
+ ff1_1.checkCoherency()
+ self.assertTrue(ff1_1.isEqual(fieldCell1,1e-12,1e-12))
+ ff1_2=f1.getFieldAtLevel(ON_CELLS,-1)
+ ff1_2.checkCoherency()
+ self.assertTrue(ff1_2.isEqual(fieldCell1,1e-12,1e-12))
+ ff1_3=f1.getFieldOnMeshAtLevel(ON_CELLS,-1,m)
+ ff1_3.checkCoherency()
+ self.assertTrue(ff1_3.isEqual(fieldCell1,1e-12,1e-12))
+ ff1_4=MEDLoader.ReadFieldCell(fname,m.getName(),-1,fieldCell1.getName(),dt,it)
+ ff1_4.checkCoherency()
+ self.assertTrue(ff1_4.getMesh().isEqual(m10,1e-12))
+ self.assertRaises(InterpKernelException,f1.getFieldOnMeshAtLevel,ON_CELLS,m0) # error because impossible to build a sub mesh at level 0 lying on cells [0,1,2,3,4,5,6]
+ self.assertRaises(InterpKernelException,f1.getFieldAtLevel,ON_CELLS,0) # error because impossible to build a sub mesh at level 0 lying on cells [0,1,2,3,4,5,6]
+ self.assertRaises(InterpKernelException,f1.getFieldOnMeshAtLevel,ON_CELLS,0,m) # error because impossible to build a sub mesh at level 0 lying on cells [0,1,2,3,4,5,6]
+ arr_r,pfl1_r=f1.getFieldWithProfile(ON_CELLS,-1,m)
+ arr_r.setName(fieldCell1.getArray().getName())
+ self.assertTrue(arr_r.isEqual(fieldCell1.getArray(),1e-12))
+ pfl1_r.setName(pfl1.getName())
+ self.assertTrue(pfl1_r.isEqual(pfl1))
+ pass
+
+ def testMEDFileUMeshZipCoords1(self):
+ m=MEDFileUMesh()
+ coo=DataArrayDouble(30) ; coo.iota(1.) ; coo.rearrange(3) ; coo.setInfoOnComponents(["aaa [b]","cc [dd]", "e [fff]"])
+ m0=MEDCouplingUMesh("toto",2) ; m0.allocateCells(0) ; m0.insertNextCell(NORM_TRI3,[1,2,3]) ; m0.insertNextCell(NORM_QUAD4,[2,4,3,4]) ; m0.insertNextCell(NORM_POLYGON,[1,6,6,6,2])
+ m1=MEDCouplingUMesh("toto",1) ; m1.allocateCells(0) ; m1.insertNextCell(NORM_SEG2,[1,6]) ; m1.insertNextCell(NORM_SEG2,[7,3])
+ m2=MEDCouplingUMesh("toto",0) ; m2.allocateCells(0) ; m2.insertNextCell(NORM_POINT1,[2]) ; m2.insertNextCell(NORM_POINT1,[6]) ; m2.insertNextCell(NORM_POINT1,[8])
+ m0.setCoords(coo) ; m.setMeshAtLevel(0,m0)
+ m1.setCoords(coo) ; m.setMeshAtLevel(-1,m1)
+ m2.setCoords(coo) ; m.setMeshAtLevel(-2,m2)
+ numCoo=DataArrayInt(10) ; numCoo.iota(3) ; m.setRenumFieldArr(1,numCoo)
+ famCoo=DataArrayInt(10) ; famCoo.iota(4) ; m.setFamilyFieldArr(1,famCoo)
+ da=DataArrayInt([20,30,40]) ; m.setRenumFieldArr(0,da) ; da=DataArrayInt([200,300,400]) ; m.setFamilyFieldArr(0,da)
+ da=DataArrayInt([50,60]) ; m.setRenumFieldArr(-1,da) ; da=DataArrayInt([500,600]) ; m.setFamilyFieldArr(-1,da)
+ da=DataArrayInt([70,80,90]) ; m.setRenumFieldArr(-2,da) ; da=DataArrayInt([700,800,900]) ; m.setFamilyFieldArr(-2,da)
+ o2n=m.zipCoords()
+ self.assertTrue(o2n.isEqual(DataArrayInt([-1,0,1,2,3,-1,4,5,6,-1])))
+ self.assertTrue(m.getNumberFieldAtLevel(1).isEqual(DataArrayInt([4,5,6,7,9,10,11])))
+ self.assertTrue(m.getFamilyFieldAtLevel(1).isEqual(DataArrayInt([5,6,7,8,10,11,12])))
+ self.assertTrue(m.getMeshAtLevel(0).getNodalConnectivity().isEqual(DataArrayInt([3,0,1,2,4,1,3,2,3,5,0,4,4,4,1])))
+ self.assertTrue(m.getMeshAtLevel(0).getNodalConnectivityIndex().isEqual(DataArrayInt([0,4,9,15])))
+ self.assertTrue(m.getMeshAtLevel(-1).getNodalConnectivity().isEqual(DataArrayInt([1,0,4,1,5,2])))
+ self.assertTrue(m.getMeshAtLevel(-1).getNodalConnectivityIndex().isEqual(DataArrayInt([0,3,6])))
+ self.assertTrue(m.getMeshAtLevel(-2).getNodalConnectivity().isEqual(DataArrayInt([0,1,0,4,0,6])))
+ self.assertTrue(m.getMeshAtLevel(-2).getNodalConnectivityIndex().isEqual(DataArrayInt([0,2,4,6])))
+ pass
+
+ def testMEDUMeshAddNodeGroup1(self):
+ fname="Pyfile53.med"
+ m=MEDFileUMesh()
+ coo=DataArrayDouble(39) ; coo.iota(1.) ; coo.rearrange(3) ; coo.setInfoOnComponents(["aaa [b]","cc [dd]", "e [fff]"])
+ m0=MEDCouplingUMesh("toto",2) ; m0.allocateCells(0) ; m0.insertNextCell(NORM_TRI3,[1,2,3]) ; m0.insertNextCell(NORM_QUAD4,[2,4,3,4]) ; m0.insertNextCell(NORM_POLYGON,[1,6,6,6,2])
+ m1=MEDCouplingUMesh("toto",1) ; m1.allocateCells(0) ; m1.insertNextCell(NORM_SEG2,[1,6]) ; m1.insertNextCell(NORM_SEG2,[7,3])
+ m2=MEDCouplingUMesh("toto",0) ; m2.allocateCells(0) ; m2.insertNextCell(NORM_POINT1,[2]) ; m2.insertNextCell(NORM_POINT1,[6]) ; m2.insertNextCell(NORM_POINT1,[8])
+ m0.setCoords(coo) ; m.setMeshAtLevel(0,m0)
+ m1.setCoords(coo) ; m.setMeshAtLevel(-1,m1)
+ m2.setCoords(coo) ; m.setMeshAtLevel(-2,m2)
+ #
+ mm=m.deepCpy()
+ famCoo=DataArrayInt([0,2,0,3,2,0,-1,0,0,0,0,-1,3]) ; mm.setFamilyFieldArr(1,famCoo)
+ da0=DataArrayInt([0,0,0]) ; mm.setFamilyFieldArr(0,da0)
+ da1=DataArrayInt([0,3]) ; mm.setFamilyFieldArr(-1,da1)
+ da2=DataArrayInt([0,0,0]) ; mm.setFamilyFieldArr(-2,da2)
+ mm.setFamilyId("MyFam",2)
+ mm.setFamilyId("MyOtherFam",3)
+ mm.setFamilyId("MyOther-1",-1)
+ mm.setFamiliesOnGroup("grp0",["MyOtherFam"])
+ mm.setFamiliesOnGroup("grpA",["MyOther-1"])
+ #
+ daTest=DataArrayInt([1,3,4,6,9,10,12]) ; daTest.setName("grp1")
+ mm.addNodeGroup(daTest)
+ self.assertTrue(mm.getGroupArr(1,daTest.getName()).isEqual(daTest))
+ self.assertTrue(mm.getFamilyFieldAtLevel(1).isEqual(DataArrayInt([6,2,6,8,2,6,5,6,6,7,7,4,8])))
+ for lev,arr in [(0,da0),(-1,da1),(-2,da2)]:
+ self.assertTrue(mm.getFamilyFieldAtLevel(lev).isEqual(arr))
+ pass
+ self.assertEqual(mm.getFamiliesNames(),('Family_4','Family_5','Family_7','Family_8','MyFam','MyOther-1','MyOtherFam'))
+ self.assertEqual(mm.getGroupsNames(),('grp0','grp1','grpA'))
+ self.assertEqual(mm.getFamilyNameGivenId(3),'MyOtherFam')
+ self.assertEqual(mm.getFamilyNameGivenId(2),'MyFam')
+ for famName,famId in [('Family_4',4),('Family_5',5),('Family_7',7),('Family_8',8)]:
+ self.assertEqual(mm.getFamilyNameGivenId(famId),famName)
+ pass
+ self.assertEqual(mm.getFamiliesOnGroup("grp0"),('MyOtherFam','Family_8'))
+ da=DataArrayInt([3,12]) ; da.setName("grp0")
+ self.assertTrue(mm.getGroupArr(1,"grp0").isEqual(da))
+ da.setValues([1])
+ self.assertTrue(mm.getGroupArr(-1,"grp0").isEqual(da))
+ mm.write(fname,2)
+ mm=MEDFileMesh.New(fname)
+ self.assertTrue(mm.getGroupArr(1,daTest.getName()).isEqual(daTest))
+ self.assertTrue(mm.getFamilyFieldAtLevel(1).isEqual(DataArrayInt([6,2,6,8,2,6,5,6,6,7,7,4,8])))
+ for lev,arr in [(0,da0),(-1,da1),(-2,da2)]:
+ self.assertTrue(mm.getFamilyFieldAtLevel(lev).isEqual(arr))
+ pass
+ self.assertEqual(mm.getFamiliesNames(),('FAMILLE_ZERO','Family_4','Family_5','Family_7','Family_8','MyFam','MyOther-1','MyOtherFam'))
+ self.assertEqual(mm.getGroupsNames(),('grp0','grp1','grpA'))
+ self.assertEqual(mm.getFamilyNameGivenId(3),'MyOtherFam')
+ self.assertEqual(mm.getFamilyNameGivenId(2),'MyFam')
+ for famName,famId in [('Family_4',4),('Family_5',5),('Family_7',7),('Family_8',8)]:
+ self.assertEqual(mm.getFamilyNameGivenId(famId),famName)
+ pass
+ self.assertEqual(mm.getFamiliesOnGroup("grp0"),('Family_8','MyOtherFam'))
+ da=DataArrayInt([3,12]) ; da.setName("grp0")
+ self.assertTrue(mm.getGroupArr(1,"grp0").isEqual(da))
+ da.setValues([1])
+ self.assertTrue(mm.getGroupArr(-1,"grp0").isEqual(da))
+ pass
+
+ def testMEDUMeshAddGroup1(self):
+ fname="Pyfile54.med"
+ m=MEDFileUMesh()
+ coo=DataArrayDouble(9) ; coo.iota(1.) ; coo.rearrange(3) ; coo.setInfoOnComponents(["aaa [b]","cc [dd]", "e [fff]"])
+ m0=MEDCouplingUMesh("toto",2) ; m0.allocateCells(0)
+ for i in xrange(7):
+ m0.insertNextCell(NORM_TRI3,[1,2,1])
+ pass
+ for i in xrange(4):
+ m0.insertNextCell(NORM_QUAD4,[1,1,2,0])
+ pass
+ for i in xrange(2):
+ m0.insertNextCell(NORM_POLYGON,[0,0,1,1,2,2])
+ pass
+ m1=MEDCouplingUMesh("toto",1) ; m1.allocateCells(0) ; m1.insertNextCell(NORM_SEG2,[1,6]) ; m1.insertNextCell(NORM_SEG2,[7,3])
+ m2=MEDCouplingUMesh("toto",0) ; m2.allocateCells(0) ; m2.insertNextCell(NORM_POINT1,[2]) ; m2.insertNextCell(NORM_POINT1,[6]) ; m2.insertNextCell(NORM_POINT1,[8])
+ m0.setCoords(coo) ; m.setMeshAtLevel(0,m0)
+ m1.setCoords(coo) ; m.setMeshAtLevel(-1,m1)
+ m2.setCoords(coo) ; m.setMeshAtLevel(-2,m2)
+ #
+ mm=m.deepCpy()
+ famCoo=DataArrayInt([0,2,0,3,2,0,-1,0,0,0,0,-1,3]) ; mm.setFamilyFieldArr(0,famCoo)
+ da0=DataArrayInt([0,0,0]) ; mm.setFamilyFieldArr(1,da0)
+ da1=DataArrayInt([0,3]) ; mm.setFamilyFieldArr(-1,da1)
+ da2=DataArrayInt([0,0,0]) ; mm.setFamilyFieldArr(-2,da2)
+ mm.setFamilyId("MyFam",2)
+ mm.setFamilyId("MyOtherFam",3)
+ mm.setFamilyId("MyOther-1",-1)
+ mm.setFamiliesOnGroup("grp0",["MyOtherFam"])
+ mm.setFamiliesOnGroup("grpA",["MyOther-1"])
+ #
+ daTest=DataArrayInt([1,3,4,6,9,10,12]) ; daTest.setName("grp1")
+ mm.addGroup(0,daTest)
+ self.assertTrue(mm.getGroupArr(0,daTest.getName()).isEqual(daTest))
+ self.assertTrue(mm.getFamilyFieldAtLevel(0).isEqual(DataArrayInt([-6,2,-6,-8,2,-6,-5,-6,-6,-7,-7,-4,-8])))
+ for lev,arr in [(1,da0),(-1,da1),(-2,da2)]:
+ self.assertTrue(mm.getFamilyFieldAtLevel(lev).isEqual(arr))
+ pass
+ self.assertEqual(mm.getFamiliesNames(),('Family_-4','Family_-5','Family_-7','Family_-8','MyFam','MyOther-1','MyOtherFam'))
+ self.assertEqual(mm.getGroupsNames(),('grp0','grp1','grpA'))
+ self.assertEqual(mm.getFamilyNameGivenId(3),'MyOtherFam')
+ self.assertEqual(mm.getFamilyNameGivenId(2),'MyFam')
+ for famName,famId in [('Family_-4',-4),('Family_-5',-5),('Family_-7',-7),('Family_-8',-8)]:
+ self.assertEqual(mm.getFamilyNameGivenId(famId),famName)
+ pass
+ self.assertEqual(mm.getFamiliesOnGroup("grp0"),('MyOtherFam','Family_-8'))
+ da=DataArrayInt([3,12]) ; da.setName("grp0")
+ self.assertTrue(mm.getGroupArr(0,"grp0").isEqual(da))
+ da.setValues([1])
+ self.assertTrue(mm.getGroupArr(-1,"grp0").isEqual(da))
+ mm.write(fname,2)
+ mm=MEDFileMesh.New(fname)
+ self.assertTrue(mm.getGroupArr(0,daTest.getName()).isEqual(daTest))
+ self.assertTrue(mm.getFamilyFieldAtLevel(0).isEqual(DataArrayInt([-6,2,-6,-8,2,-6,-5,-6,-6,-7,-7,-4,-8])))
+ for lev,arr in [(1,da0),(-1,da1),(-2,da2)]:
+ self.assertTrue(mm.getFamilyFieldAtLevel(lev).isEqual(arr))
+ pass
+ self.assertEqual(mm.getFamiliesNames(),('FAMILLE_ZERO','Family_-4','Family_-5','Family_-7','Family_-8','MyFam','MyOther-1','MyOtherFam'))
+ self.assertEqual(mm.getGroupsNames(),('grp0','grp1','grpA'))
+ self.assertEqual(mm.getFamilyNameGivenId(3),'MyOtherFam')
+ self.assertEqual(mm.getFamilyNameGivenId(2),'MyFam')
+ for famName,famId in [('Family_-4',-4),('Family_-5',-5),('Family_-7',-7),('Family_-8',-8)]:
+ self.assertEqual(mm.getFamilyNameGivenId(famId),famName)
+ pass
+ self.assertEqual(mm.getFamiliesOnGroup("grp0"),('Family_-8','MyOtherFam'))
+ da=DataArrayInt([3,12]) ; da.setName("grp0")
+ self.assertTrue(mm.getGroupArr(0,"grp0").isEqual(da))
+ da.setValues([1])
+ self.assertTrue(mm.getGroupArr(-1,"grp0").isEqual(da))
+ pass
+
+ def testHeapMem1(self):
+ m=MEDCouplingCMesh()
+ arr=DataArrayDouble(10,1) ; arr.iota(0)
+ m.setCoords(arr,arr)
+ m=m.buildUnstructured()
+ m.setName("mm")
+ f=m.getMeasureField(ON_CELLS)
+ self.assertIn(m.getHeapMemorySize(),xrange(3552-100,3552+100))
+ self.assertIn(f.getHeapMemorySize(),xrange(4215-100,4215+100))
+ #
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ self.assertIn(mm.getHeapMemorySize(),xrange(3889-100,3889+100))
+ ff=MEDFileField1TS()
+ ff.setFieldNoProfileSBT(f)
+ self.assertIn(ff.getHeapMemorySize(),xrange(711-20,711+20))
+ #
+ fff=MEDFileFieldMultiTS()
+ fff.appendFieldNoProfileSBT(f)
+ self.assertIn(fff.getHeapMemorySize(),xrange(743-30,743+30))
+ f.setTime(1.,0,-1)
+ fff.appendFieldNoProfileSBT(f)
+ self.assertIn(fff.getHeapMemorySize(),xrange(1462-50,1462+50))
+ self.assertIn(fff[0,-1].getHeapMemorySize(),xrange(711-20,711+20))
+ f2=f[:50]
+ f2.setTime(2.,1,-1)
+ pfl=DataArrayInt.Range(0,50,1) ; pfl.setName("pfl")
+ fff.appendFieldProfile(f2,mm,0,pfl)
+ self.assertIn(fff.getHeapMemorySize(),xrange(2178-100,2178+100))
+ self.assertIn(fff.getProfile("pfl_NORM_QUAD4").getHeapMemorySize(),xrange(215-10,215+10))
+ self.assertIn(fff[1,-1].getHeapMemorySize(),xrange(700-30,700+30))
+ pass
+
+ def testCurveLinearMesh1(self):
+ fname="Pyfile55.med"
+ mesh=MEDCouplingCurveLinearMesh();
+ mesh.setTime(2.3,4,5);
+ mesh.setTimeUnit("us");
+ mesh.setName("Example of Cuve linear mesh");
+ mesh.setDescription("buildCLMesh");
+ a1=DataArrayDouble(3*20,1);
+ a1.iota(7.) ; a1.rearrange(3);
+ mesh.setCoords(a1);
+ mesh.setNodeGridStructure([4,5]);
+ mesh.checkCoherency();
+ #
+ m=MEDFileCurveLinearMesh()
+ m.setMesh(mesh)
+ d=DataArrayInt(20) ; d.iota(4)
+ m.setFamilyFieldArr(1,d)
+ d3=DataArrayInt(20) ; d3.iota(400)
+ m.setRenumFieldArr(1,d3)
+ d2=DataArrayInt(12) ; d2.iota(40)
+ m.setFamilyFieldArr(0,d2)
+ d4=DataArrayInt(21) ; d4.iota(4000)
+ self.assertRaises(InterpKernelException,m.setRenumFieldArr,1,d4)
+ d4.popBackSilent()
+ m.setRenumFieldArr(1,d4)
+ m.write(fname,2)
+ #
+ m1=MEDFileCurveLinearMesh(fname)
+ mm=m1.getMesh()
+ self.assertTrue(mm.isEqual(mesh,1e-12))
+ #
+ m1=MEDFileMesh.New(fname)
+ self.assertTrue(isinstance(m1,MEDFileCurveLinearMesh))
+ self.assertTrue(isinstance(m1.getUnivName(),str))
+ self.assertTrue(len(m1.getUnivName())!=0)
+ self.assertTrue(m1.getMesh().isEqual(mesh,1e-12))
+ pass
+
+ def testParameters1(self):
+ fname="Pyfile56.med"
+ m=MEDCouplingCMesh() ; arr=DataArrayDouble([0.,1.2,3.5]) ; m.setCoords(arr,arr) ; m.setName("mesh")
+ mm=MEDFileCMesh() ; mm.setMesh(m)
+ ms=MEDFileMeshes() ; ms.pushMesh(mm)
+ data=MEDFileData()
+ p=MEDFileParameters()
+ data.setParams(p) ; data.setMeshes(ms)
+ pts=MEDFileParameterMultiTS()
+ pts.setName("A") ; pts.setDescription("An example of parameter") ; pts.setTimeUnit("ms")
+ pts.appendValue(1,2,3.4,567.89)
+ pts.appendValue(2,3,5.6,999.123)
+ pts2=pts.deepCpy() ; pts2.setName("B") ; pts2.setDescription("A second example")
+ p.pushParam(pts) ; p.pushParam(pts2)
+ data.write(fname,2)
+ p2=MEDFileParameters(fname)
+ self.assertTrue(p.isEqual(p2,1e-14)[0])
+ self.assertAlmostEqual(p[1][1,2].getValue(),567.89,13)
+ p3=p.deepCpy()
+ pts4=pts2.deepCpy()
+ pts3=pts2.deepCpy()
+ self.assertTrue(pts3.isEqual(pts2,1e-14)[0])
+ pts2.eraseTimeStepIds([0])
+ self.assertTrue(not pts3.isEqual(pts2,1e-14)[0])
+ del pts3[[3.4]]
+ self.assertTrue(pts3.isEqual(pts2,1e-14)[0])
+ self.assertRaises(InterpKernelException,p[1].__getitem__,(1,2))
+ self.assertRaises(InterpKernelException,p["B"].__getitem__,(1,2))
+ self.assertAlmostEqual(p[0][1,2].getValue(),567.89,13)
+ self.assertAlmostEqual(p["A"][1,2].getValue(),567.89,13)
+ p=p3
+ self.assertTrue(p.isEqual(p2,1e-14)[0])
+ self.assertTrue(p2["B"].isEqual(pts,1e-14)[0])
+ self.assertTrue(not p2["B"].isEqual(pts2,1e-14)[0])
+ self.assertAlmostEqual(p2[0][1,2].getValue(),567.89,13)
+ self.assertEqual(p.getParamsNames(),('A','B'))
+ ptsr=MEDFileParameterMultiTS(fname,"B")
+ self.assertTrue(ptsr.isEqual(pts4,1e-14)[0])
+ ptsr=MEDFileParameterMultiTS(fname)
+ self.assertTrue(ptsr.isEqual(pts,1e-14)[0])
+ p1tsr=MEDFileParameterDouble1TS(fname)
+ self.assertEqual(p1tsr.getName(),"A")
+ self.assertAlmostEqual(p1tsr.getValue(),567.89,13)
+ p1tsr=MEDFileParameterDouble1TS(fname,"B")
+ self.assertEqual(p1tsr.getName(),"B")
+ self.assertAlmostEqual(p1tsr.getValue(),567.89,13)
+ p1tsr=MEDFileParameterDouble1TS(fname,"B",2,3)
+ self.assertEqual(p1tsr.getName(),"B")
+ self.assertAlmostEqual(p1tsr.getValue(),999.123,13)
+ data2=MEDFileData(fname)
+ self.assertEqual(2,data2.getNumberOfParams())
+ self.assertAlmostEqual(data2.getParams()["B"][1,2].getValue(),567.89,13)
+ pass
+
+ def testNamesOnCellAndNodesInMeshes1(self):
+ fname="Pyfile58.med"
+ fname2="Pyfile59.med"
+ m=MEDLoaderDataForTest.build3DSurfMesh_1()
+ m1=m.buildDescendingConnectivity()[0]
+ m1.sortCellsInMEDFileFrmt()
+ #
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ mm.setMeshAtLevel(-1,m1)
+ namesCellL0=DataArrayAsciiChar(6,16)
+ namesCellL0[:]=["CellL0#%.3d "%(i) for i in xrange(6)]
+ mm.setNameFieldAtLevel(0,namesCellL0)
+ namesCellL1=DataArrayAsciiChar.Aggregate([namesCellL0,namesCellL0,namesCellL0.substr(2)])
+ namesCellL1[:]=["CellLM1#%.3d "%(i) for i in xrange(16)]
+ mm.setNameFieldAtLevel(-1,namesCellL1)
+ namesNodes=namesCellL1.substr(4,16)
+ namesNodes[:]=["Node#%.3d "%(i) for i in xrange(12)]
+ mm.setNameFieldAtLevel(1,namesNodes)
+ mm.write(fname,2)
+ #
+ mmr=MEDFileMesh.New(fname)
+ self.assertTrue(mm.getNameFieldAtLevel(0).isEqual(DataArrayAsciiChar(["CellL0#%.3d "%(i) for i in xrange(6)])))
+ self.assertTrue(mm.getNameFieldAtLevel(-1).isEqual(DataArrayAsciiChar(["CellLM1#%.3d "%(i) for i in xrange(16)])))
+ self.assertTrue(mm.getNameFieldAtLevel(1).isEqual(DataArrayAsciiChar(["Node#%.3d "%(i) for i in xrange(12)])))
+ self.assertTrue(mm.isEqual(mmr,1e-12)[0])
+ mmr.getNameFieldAtLevel(1).setIJ(0,0,'M')
+ self.assertTrue(not mm.isEqual(mmr,1e-12)[0])
+ mmr.getNameFieldAtLevel(1).setIJ(0,0,'N')
+ self.assertTrue(mm.isEqual(mmr,1e-12)[0])
+ mmCpy=mm.deepCpy()
+ self.assertTrue(mm.isEqual(mmCpy,1e-12)[0])
+ # remove names on nodes
+ mmCpy.setNameFieldAtLevel(1,None)
+ self.assertTrue(not mm.isEqual(mmCpy,1e-12)[0])
+ mm.setNameFieldAtLevel(1,None)
+ self.assertTrue(mm.isEqual(mmCpy,1e-12)[0])
+ mm.setNameFieldAtLevel(-1,None)
+ mm.write(fname,2)
+ mmr=MEDFileMesh.New(fname)
+ self.assertEqual(mmr.getNameFieldAtLevel(1),None)
+ self.assertTrue(mmr.getNameFieldAtLevel(0).isEqual(DataArrayAsciiChar(["CellL0#%.3d "%(i) for i in xrange(6)])))
+ self.assertEqual(mmr.getNameFieldAtLevel(-1),None)
+ #
+ c=MEDCouplingCMesh()
+ arr=DataArrayDouble([0.,1.1,2.3])
+ c.setCoords(arr,arr)
+ c.setName("cmesh")
+ cc=MEDFileCMesh()
+ cc.setMesh(c)
+ cc.setNameFieldAtLevel(0,DataArrayAsciiChar(["Cell#%.3d "%(i) for i in xrange(4)]))
+ cc.setNameFieldAtLevel(1,DataArrayAsciiChar(["Node#%.3d "%(i) for i in xrange(9)]))
+ cc.write(fname2,2)
+ ccr=MEDFileMesh.New(fname2)
+ self.assertTrue(ccr.getNameFieldAtLevel(0).isEqual(DataArrayAsciiChar(["Cell#%.3d "%(i) for i in xrange(4)])))
+ self.assertTrue(ccr.getNameFieldAtLevel(1).isEqual(DataArrayAsciiChar(["Node#%.3d "%(i) for i in xrange(9)])))
+ self.assertTrue(cc.isEqual(ccr,1e-12)[0])
+ ccr.getNameFieldAtLevel(1).setIJ(0,0,'M')
+ self.assertTrue(not cc.isEqual(ccr,1e-12)[0])
+ ccr.getNameFieldAtLevel(1).setIJ(0,0,'N')
+ self.assertTrue(cc.isEqual(ccr,1e-12)[0])
+ ccCpy=cc.deepCpy()
+ self.assertTrue(cc.isEqual(ccCpy,1e-12)[0])
+ pass
+
+ def testToExportInExamples1(self):
+ m=MEDCouplingCMesh()
+ arr=DataArrayDouble([0.,1.,2.,3.,4.])
+ m.setCoords(arr,arr)
+ m=m.buildUnstructured() ; m.setName("mesh")
+ grp1=DataArrayInt([0,1,2,4,5,6,8,9,10,12,13,14]) ; grp1.setName("grp1")
+ grp2=DataArrayInt([3,7,11,15]) ; grp2.setName("grp2")
+ m2=m.computeSkin()
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ mm.setMeshAtLevel(-1,m2)
+ mm.setGroupsAtLevel(0,[grp1,grp2])
+ mm.write("example.med",2)
+ #
+ m0=mm.getMeshAtLevel(0)
+ m1=mm.getMeshAtLevel(-1)
+ grp1=mm.getGroupArr(0,"grp1")
+ grp2=mm.getGroupArr(0,"grp2")
+ grps=[grp1,grp2]
+ whichGrp=DataArrayInt(m0.getNumberOfCells())
+ whichGrp.fillWithValue(-1)
+ for grpId,grp in enumerate(grps):
+ whichGrp[grp]=grpId
+ pass
+ a,b,bI,c,cI=m0.buildDescendingConnectivity()
+ e,f=a.areCellsIncludedIn(m1,2)
+ self.assertTrue(e)
+ c2,c2I=MEDCouplingUMesh.ExtractFromIndexedArrays(f,c,cI)
+ self.assertTrue(c2I.deltaShiftIndex().isUniform(1))
+ c2.transformWithIndArr(whichGrp)
+ splitOfM1=len(grps)*[None]
+ for grpId,grp in enumerate(grps):
+ tmp=c2.getIdsEqual(grpId)
+ splitOfM1[grpId]=tmp
+ pass
+ splitOfM1[0].isEqual(DataArrayInt([0,1,2,3,6,8,10,11,12,13]))
+ splitOfM1[1].isEqual(DataArrayInt([4,5,7,9,14,15]))
+ pass
+
+ def testBugCorrection1(self):
+ fs=MEDFileFields()
+ fs.resize(3)
+ self.assertEqual(fs[0],None)
+ self.assertEqual(3,len(fs))
+ pass
+
+ def testCompareMEDFilesContainingOnlyFieldsOnCell1(self):
+ f1Name="Pyfile60.med"
+ f2Name="Pyfile61.med"
+ d1=MEDLoaderDataForTest.buildACompleteMEDDataStructureWithFieldsOnCells_1()
+ d1.write(f1Name,2)
+ d2=MEDLoaderDataForTest.buildACompleteMEDDataStructureWithFieldsOnCells_1()
+ d2.write(f2Name,2)
+ # reading and compare
+ d1=MEDFileData(f1Name) ; d2=MEDFileData(f2Name)
+ for mn in d1.getMeshes().getMeshesNames():
+ m1=d1.getMeshes()[mn]
+ m2=d2.getMeshes()[mn]
+ for lev in m1.getNonEmptyLevels():
+ grpsNames=m1.getGroupsOnSpecifiedLev(lev)
+ for grpName in grpsNames:
+ self.assertTrue(m1.getGroupArr(lev,grpName).isEqual(m2.getGroupArr(lev,grpName))) # compare groups
+ pass
+ pass
+ pass
+ for fieldn in d1.getFields().getFieldsNames():
+ f1=d1.getFields()[fieldn]
+ f2=d2.getFields()[fieldn]
+ for it,order,tim in f1.getTimeSteps():
+ f1t=f1[it,order]
+ f2t=f2[it,order]
+ if len(f1t.getPflsReallyUsed())!=0:
+ # profile case
+ for lev in f1t.getNonEmptyLevels()[1]:
+ arr1,pfl1=f1t.getFieldWithProfile(ON_CELLS,lev,m1)
+ arr2,pfl2=f2t.getFieldWithProfile(ON_CELLS,lev,m2)
+ self.assertTrue(pfl1.isEqual(pfl2))
+ self.assertTrue(arr1.isEqual(arr2,1e-10))
+ pass
+ pass
+ else:
+ # no profile case
+ for lev in f1t.getNonEmptyLevels()[1]:
+ f1mc=f1t.getFieldOnMeshAtLevel(ON_CELLS,lev,m1)
+ f2mc=f2t.getFieldOnMeshAtLevel(ON_CELLS,lev,m2)
+ self.assertTrue(f1mc.isEqual(f2mc,1e-10,1e-10))
+ pass
+ pass
+ pass
+ pass
+ pass
+
+ def testNonRegBugNormalizeFamIdsMEDFile1(self):
+ m=MEDCouplingCMesh()
+ arr=DataArrayDouble([0.,1.,2.,3.,4.])
+ m.setCoords(arr,arr,arr)
+ m=m.buildUnstructured()
+ m2=m.buildDescendingConnectivity()[0]
+ m.setName("mesh")
+ g1=DataArrayInt([0,1,2,3]) ; g1.setName("g1")
+ g2=DataArrayInt([2,3,5,6]) ; g2.setName("g2")
+ g1Face=DataArrayInt([20,21,22,23]) ; g1Face.setName("g1Face")
+ g2Face=DataArrayInt([22,23,25,26]) ; g2Face.setName("g2Face")
+ g1Node=DataArrayInt([10,11,12,13]) ; g1Node.setName("g1Node")
+ g2Node=DataArrayInt([12,13,15,16]) ; g2Node.setName("g2Node")
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ mm.setGroupsAtLevel(0,[g1,g2])
+ s1=set(mm.getFamiliesOnGroup("g1")) ; s2=set(mm.getFamiliesOnGroup("g2"))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2"),(0,))
+ mm.normalizeFamIdsMEDFile()
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2"),(0,))
+ self.assertTrue(mm.getGroupArr(0,"g1").isEqual(g1))
+ self.assertTrue(mm.getGroupArr(0,"g2").isEqual(g2))
+ self.assertEqual(s1,set(mm.getFamiliesOnGroup("g1")))
+ self.assertEqual(s2,set(mm.getFamiliesOnGroup("g2")))
+ for g in mm.getGroupsOnSpecifiedLev(0):
+ for f in mm.getFamiliesIdsOnGroup(g):
+ self.assertTrue(f<0)
+ pass
+ pass
+ #
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ mm.setMeshAtLevel(-1,m2)
+ mm.setGroupsAtLevel(0,[g1,g2])
+ mm.setGroupsAtLevel(-1,[g1Face,g2Face])
+ s1=set(mm.getFamiliesOnGroup("g1")) ; s2=set(mm.getFamiliesOnGroup("g2"))
+ s3=set(mm.getFamiliesOnGroup("g1Face")) ; s4=set(mm.getFamiliesOnGroup("g2Face"))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1Face"),(-1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2Face"),(-1,))
+ mm.normalizeFamIdsMEDFile()
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1Face"),(-1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2Face"),(-1,))
+ self.assertTrue(mm.getGroupArr(0,"g1").isEqual(g1))
+ self.assertTrue(mm.getGroupArr(0,"g2").isEqual(g2))
+ self.assertTrue(mm.getGroupArr(-1,"g1Face").isEqual(g1Face))
+ self.assertTrue(mm.getGroupArr(-1,"g2Face").isEqual(g2Face))
+ self.assertEqual(s1,set(mm.getFamiliesOnGroup("g1")))
+ self.assertEqual(s2,set(mm.getFamiliesOnGroup("g2")))
+ self.assertEqual(s3,set(mm.getFamiliesOnGroup("g1Face")))
+ self.assertEqual(s4,set(mm.getFamiliesOnGroup("g2Face")))
+ for lev in [0,-1]:
+ for g in mm.getGroupsOnSpecifiedLev(lev):
+ for f in mm.getFamiliesIdsOnGroup(g):
+ self.assertTrue(f<0)
+ pass
+ pass
+ pass
+ #
+ mm=MEDFileUMesh()
+ mm.setMeshAtLevel(0,m)
+ mm.setMeshAtLevel(-1,m2)
+ mm.setGroupsAtLevel(0,[g1,g2])
+ mm.setGroupsAtLevel(-1,[g1Face,g2Face])
+ mm.setGroupsAtLevel(1,[g1Node,g2Node])
+ s1=set(mm.getFamiliesOnGroup("g1")) ; s2=set(mm.getFamiliesOnGroup("g2"))
+ s3=set(mm.getFamiliesOnGroup("g1Face")) ; s4=set(mm.getFamiliesOnGroup("g2Face"))
+ s5=set(mm.getFamiliesOnGroup("g1Node")) ; s6=set(mm.getFamiliesOnGroup("g2Node"))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1Face"),(-1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2Face"),(-1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1Node"),(1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2Node"),(1,))
+ mm.normalizeFamIdsMEDFile()
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2"),(0,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1Face"),(-1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2Face"),(-1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g1Node"),(1,))
+ self.assertEqual(mm.getGrpNonEmptyLevelsExt("g2Node"),(1,))
+ self.assertTrue(mm.getGroupArr(0,"g1").isEqual(g1))
+ self.assertTrue(mm.getGroupArr(0,"g2").isEqual(g2))
+ self.assertTrue(mm.getGroupArr(-1,"g1Face").isEqual(g1Face))
+ self.assertTrue(mm.getGroupArr(-1,"g2Face").isEqual(g2Face))
+ self.assertTrue(mm.getGroupArr(1,"g1Node").isEqual(g1Node))
+ self.assertTrue(mm.getGroupArr(1,"g2Node").isEqual(g2Node))
+ self.assertEqual(s1,set(mm.getFamiliesOnGroup("g1")))
+ self.assertEqual(s2,set(mm.getFamiliesOnGroup("g2")))
+ self.assertEqual(s3,set(mm.getFamiliesOnGroup("g1Face")))
+ self.assertEqual(s4,set(mm.getFamiliesOnGroup("g2Face")))
+ self.assertEqual(s5,set(mm.getFamiliesOnGroup("g1Node")))
+ self.assertEqual(s6,set(mm.getFamiliesOnGroup("g2Node")))
+ for lev in [0,-1]:
+ for g in mm.getGroupsOnSpecifiedLev(lev):
+ for f in mm.getFamiliesIdsOnGroup(g):
+ self.assertTrue(f<0)
+ pass
+ pass
+ pass
+ for g in mm.getGroupsOnSpecifiedLev(1):
+ for f in mm.getFamiliesIdsOnGroup(g):
+ self.assertTrue(f>0)
+ pass
+ pass
+ pass
+
+ def testNonRegressionMantis22212ChangeGrpName(self):
+ fileName="Pyfile62.med"
+ m2,m1,m0,f2,f1,f0,p,n2,n1,n0,fns,fids,grpns,famIdsPerGrp=MEDLoaderDataForTest.buildMultiLevelMesh_1()
+ m=MEDFileUMesh.New()
+ m.setCoords(m2.getCoords())
+ m.setMeshAtLevel(0,m2)
+ m.setMeshAtLevel(-1,m1)
+ m.setMeshAtLevel(-2,m0)
+ m.setFamilyFieldArr(0,f2)
+ m.setFamilyFieldArr(-1,f1)
+ m.setFamilyFieldArr(-2,f0)
+ m.setFamilyFieldArr(1,p)
+ nbOfFams=len(fns)
+ for i in xrange(nbOfFams):
+ m.addFamily(fns[i],fids[i])
+ pass
+ nbOfGrps=len(grpns)
+ for i in xrange(nbOfGrps):
+ m.setFamiliesIdsOnGroup(grpns[i],famIdsPerGrp[i])
+ pass
+ m.setName(m2.getName())
+ m.setDescription(m2.getDescription())
+ m.write(fileName,2)
+ #
+ mm0=MEDFileMesh.New(fileName)
+ mm1=MEDFileMesh.New(fileName)
+ groupNamesIni=MEDLoader.GetMeshGroupsNames(fileName,"ma")
+ for name in groupNamesIni:
+ mm1.changeGroupName(name,name+'N')
+ pass
+ mm1.write(fileName,2)
+ del mm1
+ #
+ mm2=MEDFileMesh.New(fileName)
+ for name in groupNamesIni:
+ for lev in mm0.getGrpNonEmptyLevelsExt(name):
+ arr0=mm0.getGroupArr(lev,name)
+ arr2=mm2.getGroupArr(lev,name+'N')
+ arr0.setName(name+'N')
+ self.assertTrue(arr0.isEqual(arr2))
+ pass
+ pass
+ pass
+
+ def testInt32InMEDFileFieldStar1(self):
+ fname="Pyfile63.med"
+ f1=MEDLoaderDataForTest.buildVecFieldOnCells_1();
+ arr=f1.getArray().convertToIntArr()
+ f1.setArray(None)
+ m1=f1.getMesh()
+ mm1=MEDFileUMesh.New()
+ mm1.setCoords(m1.getCoords())
+ mm1.setMeshAtLevel(0,m1)
+ mm1.setName(m1.getName())
+ mm1.write(fname,2)
+ ff1=MEDFileIntField1TS()
+ ff1.setFieldNoProfileSBT(f1,arr)
+ a,b=ff1.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertEqual(b.getInfoOnComponents(),['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ self.assertTrue(b.isEqual(arr))
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12))
+ ff1.write(fname,0)
+ ff2=MEDFileAnyTypeField1TS.New(fname)
+ self.assertEqual(ff2.getName(),"VectorFieldOnCells")
+ self.assertEqual(ff2.getTime(),[0,1,2.0])
+ self.assertTrue(isinstance(ff2,MEDFileIntField1TS))
+ a,b=ff1.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertEqual(b.getInfoOnComponents(),['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ self.assertTrue(b.isEqual(arr))
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12))
+ ff2.setTime(1,2,3.)
+ c=ff2.getUndergroundDataArray() ; c*=2
+ ff2.write(fname,0) # 2 time steps in
+ ffs1=MEDFileAnyTypeFieldMultiTS.New(fname,"VectorFieldOnCells")
+ self.assertEqual(ffs1.getTimeSteps(),[(0, 1, 2.0), (1, 2, 3.0)])
+ self.assertEqual(len(ffs1),2)
+ self.assertTrue(isinstance(ffs1,MEDFileIntFieldMultiTS))
+ a,b=ffs1[2.].getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertTrue(b.isEqual(arr))
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12))
+ a,b=ffs1[2.].getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertTrue(b.isEqual(arr))
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12))
+ it=ffs1.__iter__() ; it.next() ; ff2bis=it.next()
+ a,b=ff2bis.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertTrue(b.isEqual(2*arr))
+ f1.setTime(3.,1,2)
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12))
+ bc=DataArrayInt(6,3) ; bc[:]=0 ; bc.setInfoOnComponents(['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ for it in ffs1:
+ a,b=it.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ bc+=b
+ pass
+ self.assertTrue(bc.isEqual(3*arr))
+ nf1=MEDCouplingFieldDouble(ON_NODES)
+ nf1.setTime(9.,10,-1)
+ nf1.setMesh(f1.getMesh())
+ narr=DataArrayInt(12,2) ; narr.setInfoOnComponents(["aa [u1]","bbbvv [ppp]"]) ; narr[:,0]=range(12) ; narr[:,1]=2*narr[:,0]
+ nf1.setName("VectorFieldOnNodes")
+ nff1=MEDFileIntField1TS.New()
+ nff1.setFieldNoProfileSBT(nf1,narr)
+ self.assertEqual(nff1.getInfo(),('aa [u1]','bbbvv [ppp]'))
+ self.assertEqual(nff1.getTime(),[10,-1,9.0])
+ nff1.write(fname,0)
+ #
+ nf2=MEDCouplingFieldDouble(ON_NODES)
+ nf2.setTime(19.,20,-11)
+ nf2.setMesh(f1.getMesh())
+ narr2=DataArrayInt(8,2) ; narr.setInfoOnComponents(["aapfl [u1]","bbbvvpfl [ppp]"]) ; narr2[:,0]=range(8) ; narr2[:,0]+=10 ; narr2[:,1]=3*narr2[:,0]
+ nf2.setName("VectorFieldOnNodesPfl") ; narr2.setName(nf2.getName())
+ nff2=MEDFileIntField1TS.New()
+ npfl=DataArrayInt([1,2,4,5,6,7,10,11]) ; npfl.setName("npfl")
+ nff2.setFieldProfile(nf2,narr2,mm1,0,npfl)
+ nff2.getFieldWithProfile(ON_NODES,0,mm1)
+ a,b=nff2.getFieldWithProfile(ON_NODES,0,mm1) ; b.setName(npfl.getName())
+ self.assertTrue(b.isEqual(npfl))
+ self.assertTrue(a.isEqual(narr2))
+ nff2.write(fname,0)
+ nff2bis=MEDFileIntField1TS(fname,"VectorFieldOnNodesPfl")
+ a,b=nff2bis.getFieldWithProfile(ON_NODES,0,mm1) ; b.setName(npfl.getName())
+ self.assertTrue(b.isEqual(npfl))
+ self.assertTrue(a.isEqual(narr2))
+ #
+ nf3=MEDCouplingFieldDouble(ON_NODES)
+ nf3.setName("VectorFieldOnNodesDouble")
+ nf3.setTime(29.,30,-21)
+ nf3.setMesh(f1.getMesh())
+ nf3.setArray(f1.getMesh().getCoords())
+ nff3=MEDFileField1TS.New()
+ nff3.setFieldNoProfileSBT(nf3)
+ nff3.write(fname,0)
+ fs=MEDFileFields(fname)
+ self.assertEqual(len(fs),4)
+ ffs=[it for it in fs]
+ self.assertTrue(isinstance(ffs[0],MEDFileIntFieldMultiTS))
+ self.assertTrue(isinstance(ffs[1],MEDFileIntFieldMultiTS))
+ self.assertTrue(isinstance(ffs[2],MEDFileFieldMultiTS))
+ self.assertTrue(isinstance(ffs[3],MEDFileIntFieldMultiTS))
+ #
+ self.assertTrue(fs["VectorFieldOnCells"][0].getUndergroundDataArray().isEqualWithoutConsideringStr(arr))
+ self.assertTrue(fs["VectorFieldOnCells"][1,2].getUndergroundDataArray().isEqualWithoutConsideringStr(2*arr))
+ self.assertTrue(fs["VectorFieldOnNodesPfl"][0].getUndergroundDataArray().isEqualWithoutConsideringStr(narr2))
+ self.assertTrue(fs["VectorFieldOnNodes"][9.].getUndergroundDataArray().isEqualWithoutConsideringStr(narr))
+ self.assertTrue(fs["VectorFieldOnNodesDouble"][29.].getUndergroundDataArray().isEqualWithoutConsideringStr(f1.getMesh().getCoords(),1e-12))
+ #
+ nf3_read=MEDFileFieldMultiTS(fname,"VectorFieldOnNodesDouble")
+ self.assertTrue(nf3_read[29.].getUndergroundDataArray().isEqualWithoutConsideringStr(f1.getMesh().getCoords(),1e-12))
+ self.assertRaises(InterpKernelException,MEDFileIntFieldMultiTS.New,fname,"VectorFieldOnNodesDouble")# exception because trying to read a double field with int instance
+ self.assertRaises(InterpKernelException,MEDFileFieldMultiTS.New,fname,"VectorFieldOnNodes")# exception because trying to read a int field with double instance
+ MEDFileField1TS.New(fname,"VectorFieldOnNodesDouble",30,-21)
+ self.assertRaises(InterpKernelException,MEDFileIntField1TS.New,fname,"VectorFieldOnNodesDouble",30,-21)# exception because trying to read a double field with int instance
+ MEDFileIntField1TS.New(fname,"VectorFieldOnNodes",10,-1)
+ self.assertRaises(InterpKernelException,MEDFileField1TS.New,fname,"VectorFieldOnNodes",10,-1)# exception because trying to read a double field with int instance
+ #
+ self.assertEqual(fs.getMeshesNames(),('3DSurfMesh_1','3DSurfMesh_1','3DSurfMesh_1','3DSurfMesh_1'))
+ self.assertTrue(fs.changeMeshNames([('3DSurfMesh_1','3DSurfMesh')]))
+ self.assertEqual(fs.getMeshesNames(),('3DSurfMesh','3DSurfMesh','3DSurfMesh','3DSurfMesh'))
+ self.assertTrue(not fs.changeMeshNames([('3DSurfMesh_1','3DSurfMesh')]))
+ pass
+
+ def testMEDFileFields1(self):
+ fname="Pyfile64.med"
+ f1=MEDCouplingFieldDouble(ON_NODES)
+ f1.setTime(0.001,0,-1) ; f1.setTimeUnit("us")
+ c=DataArrayDouble(12) ; c.iota(); m=MEDCouplingCMesh() ; m.setCoordsAt(0,c) ; m.setName("mesh")
+ mm=MEDFileCMesh() ; mm.setMesh(m) ; mm.write(fname,2)
+ f1.setMesh(m)
+ arr=DataArrayDouble(12,2) ; arr.setInfoOnComponents(["aa [u1]","bbbvv [ppp]"]) ; arr[:,0]=range(12) ; arr[:,1]=2*arr[:,0]
+ f1.setArray(arr)
+ f1.setName("Field1")
+ ff1=MEDFileField1TS.New()
+ ff1.setFieldNoProfileSBT(f1)
+ self.assertEqual(ff1.getDtUnit(),"us")
+ ff1.write(fname,0)
+ f1.setTime(1.001,1,-1) ; ff1=MEDFileField1TS.New() ; ff1.setFieldNoProfileSBT(f1) ; ff1.write(fname,0)
+ f1.setTime(2.001,2,-1) ; ff1=MEDFileField1TS.New() ; ff1.setFieldNoProfileSBT(f1) ; ff1.write(fname,0)
+ #
+ self.assertEqual(MEDFileFields(fname).getCommonIterations(),([(0,-1),(1,-1),(2,-1)],False))
+ ff1s=MEDFileFieldMultiTS(fname,"Field1")
+ ff1s.setName("Field2")
+ ff1s.write(fname,0)
+ self.assertEqual(MEDFileFields(fname).getCommonIterations(),([(0,-1),(1,-1),(2,-1)],False))
+ f1.setTime(3.001,3,-1) ; ff1=MEDFileField1TS.New() ; ff1.setFieldNoProfileSBT(f1) ; ff1.write(fname,0)
+ self.assertEqual(MEDFileFields(fname).getCommonIterations(),([(0,-1),(1,-1),(2,-1)],True))
+ self.assertEqual(MEDFileFields(fname).partOfThisLyingOnSpecifiedTimeSteps([(1,-1)]).getCommonIterations(),([(1,-1)],False))
+ self.assertEqual(MEDFileFields(fname).partOfThisNotLyingOnSpecifiedTimeSteps([(1,-1)]).getCommonIterations(),([(0,-1),(2,-1)],True))
+ f1.setName("Field2") ; f1.setTime(3.001,3,-1) ; ff1=MEDFileField1TS.New() ; ff1.setFieldNoProfileSBT(f1) ; ff1.write(fname,0)
+ self.assertEqual(MEDFileFields(fname).getCommonIterations(),([(0,-1),(1,-1),(2,-1),(3,-1)],False))
+ self.assertEqual(MEDFileFields(fname)[1].getDtUnit(),"us")
+ pass
+
+ # Multi time steps and multi fields management without Globals (profiles, locs) aspects
+ def testMEDFileFields2(self):
+ fname="Pyfile65.med"
+ # to check that all is initialize
+ MEDFileField1TS().__str__()
+ MEDFileFieldMultiTS().__str__()
+ # building a mesh containing 4 tri3 + 5 quad4
+ tri=MEDCouplingUMesh("tri",2)
+ tri.allocateCells() ; tri.insertNextCell(NORM_TRI3,[0,1,2])
+ tri.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,0.)]))
+ tris=[tri.deepCpy() for i in xrange(4)]
+ for i,elt in enumerate(tris): elt.translate([i,0])
+ tris=MEDCouplingUMesh.MergeUMeshes(tris)
+ quad=MEDCouplingUMesh("quad",2)
+ quad.allocateCells() ; quad.insertNextCell(NORM_QUAD4,[0,1,2,3])
+ quad.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,1.),(1.,0.)]))
+ quads=[quad.deepCpy() for i in xrange(5)]
+ for i,elt in enumerate(quads): elt.translate([5+i,0])
+ quads=MEDCouplingUMesh.MergeUMeshes(quads)
+ m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
+ m.setName("mesh") ; m.getCoords().setInfoOnComponents(["XX [m]","YYY [km]"])
+ #
+ fmts0_0=MEDFileFieldMultiTS()
+ fmts0_1=MEDFileFieldMultiTS()
+ # time steps
+ for i in xrange(10):
+ infos1=["aa [bb]","ccc [ddd]"] ; name1="1stField"
+ d=DataArrayDouble(18) ; d.iota(i*10) ; d.rearrange(2) ; d.setInfoOnComponents(infos1)
+ f=MEDCouplingFieldDouble(ON_CELLS) ; f.setName(name1) ; f.setArray(d) ; f.setMesh(m)
+ f.setTime(float(i+1)+0.1,i+1,-i-1)
+ fmts0_0.appendFieldNoProfileSBT(f)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldNoProfileSBT(f) ; fmts0_1.pushBackTimeStep(f1ts)
+ self.assertEqual(fmts0_1.getName(),name1)
+ self.assertEqual(fmts0_0.getInfo(),('aa [bb]','ccc [ddd]'))
+ self.assertEqual(fmts0_1.getInfo(),('aa [bb]','ccc [ddd]'))
+ if i>1:
+ # components names have been modified to generate errors
+ d.setInfoOnComponents(['aa [bb]','eee [dd]'])
+ self.assertRaises(InterpKernelException,fmts0_0.appendFieldNoProfileSBT,f)
+ self.assertRaises(InterpKernelException,f1ts.setInfo,['aa [bb]'])#throw because mismatch of number of components
+ f1ts.setInfo(['aa [bb]','eee [dd]'])
+ self.assertRaises(InterpKernelException,fmts0_1.pushBackTimeStep,f1ts)
+ pass
+ # add a mismatch of nb of compos
+ pass
+ fmts0_2=fmts0_0.deepCpy()
+ fmts0_3=fmts0_0.deepCpy()
+ fmts0_4=fmts0_0.deepCpy()
+ fmts0_5=fmts0_0.shallowCpy()
+ self.assertTrue(len(fmts0_0)==10 and len(fmts0_1)==10 and len(fmts0_2)==10 and len(fmts0_3)==10 and len(fmts0_4)==10 and len(fmts0_5)==10)
+ del fmts0_2[::2]
+ self.assertTrue(len(fmts0_2)==5 and fmts0_2.getIterations()==[(2,-2),(4,-4),(6,-6),(8,-8),(10,-10)])
+ del fmts0_3[[1.1,(6,-6),9]]
+ self.assertTrue(len(fmts0_3)==7 and fmts0_3.getIterations()==[(2,-2),(3,-3),(4,-4),(5,-5),(7,-7),(8,-8),(9,-9)])
+ fmts0_6=fmts0_4[[1.1,(6,-6),8]]
+ self.assertTrue(isinstance(fmts0_6,MEDFileFieldMultiTS))
+ self.assertTrue(len(fmts0_6)==3 and fmts0_6.getIterations()==[(1,-1),(6,-6),(9,-9)])
+ fmts0_7=fmts0_4[::-3]
+ self.assertTrue(isinstance(fmts0_7,MEDFileFieldMultiTS))
+ self.assertTrue(len(fmts0_7)==4 and fmts0_7.getIterations()==[(10,-10),(7,-7),(4,-4),(1,-1)])
+ #
+ fs0=MEDFileFields()
+ fs0.pushField(fmts0_0)
+ fmts0_2.setName("2ndField") ; fs0.pushField(fmts0_2)
+ fmts0_3.setName("3rdField") ; fs0.pushField(fmts0_3)
+ fmts0_4.setName("4thField") ; fs0.pushField(fmts0_4)
+ self.assertTrue(len(fs0)==4 and fs0.getFieldsNames()==('1stField','2ndField','3rdField','4thField'))
+ fs0.write(fname,2)
+ fs0=MEDFileFields(fname)
+ self.assertEqual(fs0.getCommonIterations(),([(2,-2),(4,-4),(8,-8)],True))
+ fs1=fs0.partOfThisLyingOnSpecifiedTimeSteps(fs0.getCommonIterations()[0])
+ self.assertTrue(fs1.getFieldsNames()==('1stField','2ndField','3rdField','4thField') and fs1.getCommonIterations()==([(2,-2),(4,-4),(8,-8)],False))
+ del fs1[["2ndField",3]]
+ self.assertTrue(fs1.getFieldsNames()==('1stField','3rdField') and fs1.getCommonIterations()==([(2,-2),(4,-4),(8,-8)],False))
+ fs2=fs0[[0,"4thField"]]
+ self.assertTrue(isinstance(fs2,MEDFileFields))
+ self.assertEqual(fs2.getFieldsNames(),('1stField','4thField'))
+ #
+ mm=MEDFileUMesh() ; mm.setMeshAtLevel(0,m) ; mm.write(fname,0)
+ pass
+
+ # Multi time steps and multi fields management with Globals (profiles, locs) aspects
+ def testMEDFileFields3(self):
+ fname="Pyfile66.med"
+ # building a mesh containing 4 tri3 + 5 quad4
+ tri=MEDCouplingUMesh("tri",2)
+ tri.allocateCells() ; tri.insertNextCell(NORM_TRI3,[0,1,2])
+ tri.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,0.)]))
+ tris=[tri.deepCpy() for i in xrange(4)]
+ for i,elt in enumerate(tris): elt.translate([i,0])
+ tris=MEDCouplingUMesh.MergeUMeshes(tris)
+ quad=MEDCouplingUMesh("quad",2)
+ quad.allocateCells() ; quad.insertNextCell(NORM_QUAD4,[0,1,2,3])
+ quad.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,1.),(1.,0.)]))
+ quads=[quad.deepCpy() for i in xrange(5)]
+ for i,elt in enumerate(quads): elt.translate([5+i,0])
+ quads=MEDCouplingUMesh.MergeUMeshes(quads)
+ m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
+ m.setName("mesh") ; m.getCoords().setInfoOnComponents(["XX [m]","YYY [km]"])
+ #
+ mm=MEDFileUMesh() ; mm.setMeshAtLevel(0,m) ; mm.write(fname,2)
+ #
+ pfl=DataArrayInt([0,1,2,3,4,5,6]) ; pfl.setName("pfl")
+ pfl2=DataArrayInt([0,1,2,3,4,5,6,8]) ; pfl2.setName("pfl2")
+ fmts0_0=MEDFileFieldMultiTS()
+ fmts0_1=MEDFileFieldMultiTS()
+ # time steps
+ for i in xrange(10):
+ infos1=["aa [bb]","ccc [ddd]"] ; name1="1stField"
+ d=DataArrayDouble(14) ; d.iota(i*10) ; d.rearrange(2) ; d.setInfoOnComponents(infos1)
+ f=MEDCouplingFieldDouble(ON_CELLS) ; f.setName(name1) ; f.setArray(d) ; f.setMesh(m)
+ f.setTime(float(i+1)+0.1,i+1,-i-1)
+ fmts0_0.appendFieldProfile(f,mm,0,pfl)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldProfile(f,mm,0,pfl) ; fmts0_1.pushBackTimeStep(f1ts)
+ self.assertEqual(fmts0_0.getInfo(),('aa [bb]','ccc [ddd]'))
+ self.assertEqual(fmts0_1.getInfo(),('aa [bb]','ccc [ddd]'))
+ pass
+ #
+ self.assertEqual(fmts0_0.getPfls(),10*('pfl_NORM_QUAD4',))
+ self.assertEqual(fmts0_1.getPfls(),('pfl_NORM_QUAD4',))
+ fmts0_0.zipPflsNames()
+ self.assertEqual(fmts0_0.getPfls(),('pfl_NORM_QUAD4',))
+ self.assertTrue(fmts0_1.getProfile("pfl_NORM_QUAD4").isEqual(fmts0_0.getProfile("pfl_NORM_QUAD4")))
+ fmts0_2=fmts0_0.deepCpy()
+ fmts0_3=fmts0_0.deepCpy()
+ fmts0_4=fmts0_0.deepCpy()
+ fs0=MEDFileFields()
+ fs0.pushField(fmts0_0)
+ fmts0_2.setName("2ndField") ; fs0.pushField(fmts0_2)
+ fmts0_3.setName("3rdField") ; fs0.pushField(fmts0_3)
+ fmts0_4.setName("4thField") ; fs0.pushField(fmts0_4)
+ self.assertEqual(fs0.getPfls(),('pfl_NORM_QUAD4',))
+ #
+ fmts0_5=MEDFileFieldMultiTS()
+ for i in xrange(7):
+ infos1=["aa [bb]","ccc [ddd]"] ; name1="1stField"
+ d=DataArrayDouble(16) ; d.iota(i*10) ; d.rearrange(2) ; d.setInfoOnComponents(infos1)
+ f=MEDCouplingFieldDouble(ON_CELLS) ; f.setName(name1) ; f.setArray(d) ; f.setMesh(m)
+ f.setTime(float(i+1)+0.1,i+1,-i-1)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldProfile(f,mm,0,pfl2) ; fmts0_5.pushBackTimeStep(f1ts)
+ pass
+ fmts0_5.setName("5thField") ; fs0.pushField(fmts0_5)
+ self.assertEqual(fs0.getPfls(),('pfl_NORM_QUAD4','pfl2_NORM_QUAD4'))
+ fs0.checkGlobsCoherency()
+ fs0.write(fname,0)
+ pass
+
+ def testSplitComponents1(self):
+ fname="Pyfile67.med"
+ # building a mesh containing 4 tri3 + 5 quad4
+ tri=MEDCouplingUMesh("tri",2)
+ tri.allocateCells() ; tri.insertNextCell(NORM_TRI3,[0,1,2])
+ tri.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,0.)]))
+ tris=[tri.deepCpy() for i in xrange(4)]
+ for i,elt in enumerate(tris): elt.translate([i,0])
+ tris=MEDCouplingUMesh.MergeUMeshes(tris)
+ quad=MEDCouplingUMesh("quad",2)
+ quad.allocateCells() ; quad.insertNextCell(NORM_QUAD4,[0,1,2,3])
+ quad.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,1.),(1.,0.)]))
+ quads=[quad.deepCpy() for i in xrange(5)]
+ for i,elt in enumerate(quads): elt.translate([5+i,0])
+ quads=MEDCouplingUMesh.MergeUMeshes(quads)
+ m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
+ m.setName("mesh") ; m.getCoords().setInfoOnComponents(["XX [m]","YYY [km]"])
+ #
+ mm=MEDFileUMesh() ; mm.setMeshAtLevel(0,m) ; mm.write(fname,2)
+ #
+ pfl=DataArrayInt([0,1,2,3,4,5,6]) ; pfl.setName("pfl")
+ pfl2=DataArrayInt([0,1,2,3,4,5,6,8]) ; pfl2.setName("pfl2")
+ fs=MEDFileFields()
+ fmts0_1=MEDFileFieldMultiTS()
+ # time steps
+ infos1=['aa [bb]','ccc [ddd]',"ZZZZ [MW*s]"]
+ for i in xrange(10):
+ name1="1stField"
+ d=DataArrayDouble(21) ; d.iota(i*10) ; d.rearrange(3) ; d.setInfoOnComponents(infos1)
+ f=MEDCouplingFieldDouble(ON_CELLS) ; f.setName(name1) ; f.setArray(d) ; f.setMesh(m)
+ f.setTime(float(i+1)+0.1,i+1,-i-1)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldProfile(f,mm,0,pfl) ; fmts0_1.pushBackTimeStep(f1ts)
+ self.assertEqual(fmts0_1.getInfo(),tuple(infos1))
+ pass
+ fs.pushField(fmts0_1)
+ self.assertEqual(1,len(fs))
+ l=fmts0_1.splitComponents()
+ self.assertEqual(3,len(l))
+ for elt in l: self.assertEqual(10,len(elt))
+ for elt in l: self.assertTrue(isinstance(elt,MEDFileFieldMultiTS))
+ for elt in l:
+ elt.setName("%s_%s"%(elt.getName(),DataArray.GetVarNameFromInfo(elt.getInfo()[0])))
+ pass
+ fs.pushFields(l)
+ self.assertEqual(4,len(fs))
+ for elt in fs: self.assertEqual(10,len(elt))
+ self.assertEqual(fs.getPfls(),('pfl_NORM_QUAD4',))
+ self.assertEqual(fs.getPflsReallyUsed(),('pfl_NORM_QUAD4',))
+ #
+ fs.write(fname,0) ; del fs
+ #
+ fs1=MEDFileFields(fname)
+ self.assertEqual(fs1.getPfls(),('pfl_NORM_QUAD4',))
+ self.assertEqual(fs1.getPflsReallyUsed(),('pfl_NORM_QUAD4',))
+ self.assertEqual(4,len(fs1))
+ for i in xrange(10):
+ for j,fieldName in enumerate(['1stField_aa','1stField_ccc','1stField_ZZZZ']):
+ f1ts=fs1[fieldName][i]
+ f=f1ts.getFieldOnMeshAtLevel(ON_CELLS,0,mm)
+ d=DataArrayDouble(21) ; d.iota(i*10) ; d.rearrange(3) ; d=d[:,j] ; d.setInfoOnComponent(0,infos1[j])
+ self.assertTrue(d.isEqual(f.getArray(),1e-13))
+ pass
+ f1ts=fs1["1stField"][i]
+ f=f1ts.getFieldOnMeshAtLevel(ON_CELLS,0,mm)
+ d=DataArrayDouble(21) ; d.iota(i*10) ; d.rearrange(3) ; d.setInfoOnComponents(infos1)
+ self.assertTrue(d.isEqual(f.getArray(),1e-13))
+ pass
+ pass
+
+ def testMEDFileFieldConvertTo1(self):
+ fname="Pyfile68.med"
+ # building a mesh containing 4 tri3 + 5 quad4
+ tri=MEDCouplingUMesh("tri",2)
+ tri.allocateCells() ; tri.insertNextCell(NORM_TRI3,[0,1,2])
+ tri.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,0.)]))
+ tris=[tri.deepCpy() for i in xrange(4)]
+ for i,elt in enumerate(tris): elt.translate([i,0])
+ tris=MEDCouplingUMesh.MergeUMeshes(tris)
+ quad=MEDCouplingUMesh("quad",2)
+ quad.allocateCells() ; quad.insertNextCell(NORM_QUAD4,[0,1,2,3])
+ quad.setCoords(DataArrayDouble([(0.,0.),(0.,1.),(1.,1.),(1.,0.)]))
+ quads=[quad.deepCpy() for i in xrange(5)]
+ for i,elt in enumerate(quads): elt.translate([5+i,0])
+ quads=MEDCouplingUMesh.MergeUMeshes(quads)
+ m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
+ m.setName("mesh") ; m.getCoords().setInfoOnComponents(["XX [m]","YYY [km]"])
+ mm=MEDFileUMesh() ; mm.setMeshAtLevel(0,m)
+ #
+ ff0=MEDFileField1TS()
+ f0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f0.setMesh(m) ; arr=DataArrayDouble(m.getNumberOfCells()*2) ; arr.iota() ; arr.rearrange(2) ; arr.setInfoOnComponents(["X [km]","YY [mm]"]) ; f0.setArray(arr) ; f0.setName("FieldCell")
+ f0.checkCoherency()
+ ff0.setFieldNoProfileSBT(f0)
+ #
+ fspExp=[(3,[(0,(0,4),'','')]),(4,[(0,(4,9),'','')])]
+ self.assertEqual(ff0.getFieldSplitedByType(),fspExp)
+ #
+ ff0i=ff0.convertToInt()
+ self.assertEqual(ff0i.getFieldSplitedByType(),fspExp)
+ self.assertTrue(arr.convertToIntArr().isEqual(ff0i.getUndergroundDataArray()))
+ #
+ ff1=ff0i.convertToDouble()
+ self.assertTrue(ff1.getUndergroundDataArray().isEqual(ff0.getUndergroundDataArray(),1e-13))
+ self.assertEqual(ff1.getFieldSplitedByType(),fspExp)
+ # With profiles
+ del arr,f0,ff0,ff1,ff0i,fspExp
+ ff0=MEDFileField1TS()
+ f0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f0.setMesh(m[:7]) ; arr=DataArrayDouble(7*2) ; arr.iota() ; arr.rearrange(2) ; arr.setInfoOnComponents(["XX [pm]","YYY [hm]"]) ; f0.setArray(arr) ; f0.setName("FieldCellPfl")
+ f0.checkCoherency()
+ pfl=DataArrayInt.Range(0,7,1) ; pfl.setName("pfl")
+ ff0.setFieldProfile(f0,mm,0,pfl)
+ fspExp=[(3,[(0,(0,4),'','')]),(4,[(0,(4,7),'pfl_NORM_QUAD4','')])]
+ self.assertEqual(ff0.getFieldSplitedByType(),fspExp)
+ #
+ ff0i=ff0.convertToInt()
+ self.assertTrue(isinstance(ff0i,MEDFileIntField1TS))
+ self.assertEqual(ff0i.getFieldSplitedByType(),fspExp)
+ self.assertTrue(arr.convertToIntArr().isEqual(ff0i.getUndergroundDataArray()))
+ #
+ ff1=ff0i.convertToDouble()
+ self.assertTrue(isinstance(ff1,MEDFileField1TS))
+ self.assertTrue(ff1.getUndergroundDataArray().isEqual(ff0.getUndergroundDataArray(),1e-13))
+ self.assertEqual(ff1.getFieldSplitedByType(),fspExp)
+ ## MultiTimeSteps
+ ff0=MEDFileFieldMultiTS()
+ f0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f0.setMesh(m[:7]) ; arr=DataArrayDouble(7*2) ; arr.iota() ; arr.rearrange(2) ; arr.setInfoOnComponents(["X [km]","YY [mm]"]) ; f0.setArray(arr) ; f0.setName("FieldCellMTime") ; f0.setTime(0.1,0,10)
+ f0.checkCoherency()
+ ff0.appendFieldProfile(f0,mm,0,pfl)
+ f0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f0.setMesh(m[:7]) ; arr=DataArrayDouble(7*2) ; arr.iota(100) ; arr.rearrange(2) ; arr.setInfoOnComponents(["X [km]","YY [mm]"]) ; f0.setArray(arr) ; f0.setName("FieldCellMTime") ; f0.setTime(1.1,1,11)
+ f0.checkCoherency()
+ ff0.appendFieldProfile(f0,mm,0,pfl)
+ f0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f0.setMesh(m[:7]) ; arr=DataArrayDouble(7*2) ; arr.iota(200) ; arr.rearrange(2) ; arr.setInfoOnComponents(["X [km]","YY [mm]"]) ; f0.setArray(arr) ; f0.setName("FieldCellMTime") ; f0.setTime(2.1,2,12)
+ f0.checkCoherency()
+ ff0.appendFieldProfile(f0,mm,0,pfl)
+ ff1=ff0.convertToInt()
+ self.assertTrue(isinstance(ff1,MEDFileIntFieldMultiTS))
+ self.assertEqual(ff1.getTimeSteps(),[(0,10,0.1),(1,11,1.1),(2,12,2.1)])
+ for delt,(dt,it,t) in zip([0,100,200],ff1.getTimeSteps()):
+ self.assertEqual(ff1.getFieldSplitedByType(dt,it),fspExp)
+ arr=ff1.getUndergroundDataArray(dt,it)
+ arr.isEqualWithoutConsideringStr(DataArrayInt.Range(delt,delt+7,1))
+ pass
+ self.assertEqual(ff1.getPfls(),('pfl_NORM_QUAD4', 'pfl_NORM_QUAD4', 'pfl_NORM_QUAD4'))
+ #
+ mm.write(fname,2)
+ ff1.write(fname,0)
+ #
+ ff1=ff1.convertToDouble()
+ self.assertTrue(isinstance(ff1,MEDFileFieldMultiTS))
+ self.assertEqual(ff1.getTimeSteps(),[(0,10,0.1),(1,11,1.1),(2,12,2.1)])
+ for delt,(dt,it,t) in zip([0,100,200],ff1.getTimeSteps()):
+ self.assertEqual(ff1.getFieldSplitedByType(dt,it),fspExp)
+ arr=ff1.getUndergroundDataArray(dt,it)
+ arr.isEqualWithoutConsideringStr(DataArrayInt.Range(delt,delt+7,1).convertToDblArr(),1e-14)
+ pass
+ self.assertEqual(ff1.getPfls(),('pfl_NORM_QUAD4', 'pfl_NORM_QUAD4', 'pfl_NORM_QUAD4'))
+ #
+ ff1=MEDFileAnyTypeFieldMultiTS.New(fname,"FieldCellMTime")
+ self.assertTrue(isinstance(ff1,MEDFileIntFieldMultiTS))
+ self.assertEqual(ff1.getTimeSteps(),[(0,10,0.1),(1,11,1.1),(2,12,2.1)])
+ for delt,(dt,it,t) in zip([0,100,200],ff1.getTimeSteps()):
+ self.assertTrue(ff1.getFieldSplitedByType(dt,it),fspExp)
+ arr=ff1.getUndergroundDataArray(dt,it)
+ arr.isEqualWithoutConsideringStr(DataArrayInt.Range(delt,delt+7,1))
+ pass
+ self.assertEqual(ff1.getPfls(),('pfl_NORM_QUAD4',))
+ pass