# -*- coding: iso-8859-1 -*-
-# Copyright (C) 2007-2015 CEA/DEN, EDF R&D
+# Copyright (C) 2007-2016 CEA/DEN, EDF R&D
#
# This library is free software; you can redistribute it and/or
# modify it under the terms of the GNU Lesser General Public
#
# See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
#
-# Author : Anthony Geay (CEA/DEN)
+# Author : Anthony Geay (EDF R&D)
from MEDLoader import *
import unittest
import platform
from math import pi,e,sqrt
from MEDLoaderDataForTest import MEDLoaderDataForTest
+from distutils.version import LooseVersion
-class MEDLoaderTest(unittest.TestCase):
+import sys
+if sys.version_info.major < 3:
+ import cPickle as pickle
+else:
+ import pickle
+
+class MEDLoaderTest3(unittest.TestCase):
def testMEDMesh1(self):
fileName="Pyfile18.med"
mname="ExampleOfMultiDimW"
self.assertRaises(InterpKernelException,MEDFileMesh.New,fileName,"")
self.assertEqual((0,-1),medmesh.getNonEmptyLevels())
m1_0=medmesh.getLevel0Mesh(True)
- m1_1=MEDLoader.ReadUMeshFromFile(fileName,mname,0)
+ m1_1=ReadUMeshFromFile(fileName,mname,0)
self.assertTrue(m1_0.isEqual(m1_1,1e-12));
m2_0=medmesh.getLevelM1Mesh(True)
- m2_1=MEDLoader.ReadUMeshFromFile(fileName,mname,-1)
+ m2_1=ReadUMeshFromFile(fileName,mname,-1)
self.assertTrue(m2_0.isEqual(m2_1,1e-12));
pass
medmesh=MEDFileUMesh.New(fileName,mname)
self.assertEqual((0,),medmesh.getNonEmptyLevels())
m1_0=medmesh.getLevel0Mesh(True)
- m1_1=MEDLoader.ReadUMeshFromFile(fileName,mname,0)
+ m1_1=ReadUMeshFromFile(fileName,mname,0)
self.assertTrue(m1_0.isEqual(m1_1,1e-12));
g1_0=medmesh.getGroup(0,"mesh2",True)
- g1_1=MEDLoader.ReadUMeshFromGroups(fileName,mname,0,["mesh2"]);
+ g1_1=ReadUMeshFromGroups(fileName,mname,0,["mesh2"]);
self.assertTrue(g1_0.isEqual(g1_1,1e-12));
g1_0=medmesh.getGroup(0,"mesh3",True)
- g1_1=MEDLoader.ReadUMeshFromGroups(fileName,mname,0,["mesh3"]);
+ g1_1=ReadUMeshFromGroups(fileName,mname,0,["mesh3"]);
self.assertTrue(g1_0.isEqual(g1_1,1e-12));
g1_0=medmesh.getGroups(0,["mesh3","mesh2"])
- g1_1=MEDLoader.ReadUMeshFromGroups(fileName,mname,0,["mesh3","mesh2"]);
+ g1_1=ReadUMeshFromGroups(fileName,mname,0,["mesh3","mesh2"]);
g1_1.setName(g1_0.getName())
self.assertTrue(g1_0.isEqual(g1_1,1e-12));
g1_0=medmesh.getFamily(0,"Family_-3",True)
- g1_1=MEDLoader.ReadUMeshFromFamilies(fileName,mname,0,["Family_-3"]);
+ g1_1=ReadUMeshFromFamilies(fileName,mname,0,["Family_-3"]);
self.assertTrue(g1_0.isEqual(g1_1,1e-12));
g1_0=medmesh.getFamilies(0,["Family_-3","Family_-5"],True)
- g1_1=MEDLoader.ReadUMeshFromFamilies(fileName,mname,0,["Family_-3","Family_-5"]);
+ g1_1=ReadUMeshFromFamilies(fileName,mname,0,["Family_-3","Family_-5"]);
g1_1.setName(g1_0.getName())
self.assertTrue(g1_0.isEqual(g1_1,1e-12));
self.assertTrue(g1_0.isEqual(g1_1,1e-12));
m.insertNextCell(NORM_POLYGON,4,targetConn[14:18])
m.finishInsertingCells();
m.setCoords(c)
- m.checkCoherency()
+ m.checkConsistencyLight()
m1=MEDCouplingUMesh.New();
m1.setMeshDimension(1);
m1.allocateCells(3);
m1.insertNextCell(NORM_SEG3,3,[2,8,5])
m1.finishInsertingCells();
m1.setCoords(c)
- m1.checkCoherency()
+ m1.checkConsistencyLight()
m2=MEDCouplingUMesh.New();
m2.setMeshDimension(0);
m2.allocateCells(4);
m2.insertNextCell(NORM_POINT1,1,[6])
m2.finishInsertingCells();
m2.setCoords(c)
- m2.checkCoherency()
+ m2.checkConsistencyLight()
#
mm=MEDFileUMesh.New()
self.assertTrue(mm.getUnivNameWrStatus())
g2_1.setName("G2")
mm.setGroupsAtLevel(-1,[g1_1,g2_1],False)
g1_N=DataArrayInt.New()
- g1_N.setValues(range(8),8,1)
+ g1_N.setValues(list(range(8)),8,1)
g1_N.setName("G1")
g2_N=DataArrayInt.New()
- g2_N.setValues(range(9),9,1)
+ g2_N.setValues(list(range(9)),9,1)
g2_N.setName("G2")
mm.setGroupsAtLevel(1,[g1_N,g2_N],False)
mm.createGroupOnAll(0,"GrpOnAllCell")
self.assertTrue(g2_N.isEqual(t));
self.assertTrue(mm.existsGroup("GrpOnAllCell"));
t=mm.getGroupArr(0,"GrpOnAllCell")
- self.assertTrue(t.getValues()==range(5))
+ self.assertTrue(t.getValues()==list(range(5)))
#
- mmCpy=mm.deepCpy()
+ mmCpy=mm.deepCopy()
self.assertTrue(mm.isEqual(mmCpy,1e-12)[0]) ; del mm
mmCpy.write(outFileName,2);
#
m.setName(mm.getName()) ; m.setDescription(mm.getDescription())
self.assertTrue(m.isEqual(mbis,1e-12));
#
- self.assertEqual(([[(3, 2), (4, 1), (5, 8)], [(1, 2), (2, 1)], [(0, 4)]], 2, 2, 9),MEDLoader.GetUMeshGlobalInfo(outFileName,"MyFirstMEDCouplingMEDmesh"))
+ self.assertEqual(([[(3, 2), (4, 1), (5, 8)], [(1, 2), (2, 1)], [(0, 4)]], 2, 2, 9),GetUMeshGlobalInfo(outFileName,"MyFirstMEDCouplingMEDmesh"))
pass
# this test is the testMEDMesh3 except that permutation is dealed here
m.insertNextCell(NORM_QUAD4,4,targetConn[14:18])
m.finishInsertingCells();
m.setCoords(c)
- m.checkCoherency()
+ m.checkConsistencyLight()
m1=MEDCouplingUMesh.New();
m1.setMeshDimension(1);
m1.allocateCells(3);
m1.insertNextCell(NORM_SEG2,2,[3,6])
m1.finishInsertingCells();
m1.setCoords(c)
- m1.checkCoherency()
+ m1.checkConsistencyLight()
m2=MEDCouplingUMesh.New();
m2.setMeshDimension(0);
m2.allocateCells(4);
m2.insertNextCell(NORM_POINT1,1,[6])
m2.finishInsertingCells();
m2.setCoords(c)
- m2.checkCoherency()
+ m2.checkConsistencyLight()
#
mm=MEDFileUMesh.New()
mm.setName("My2ndMEDCouplingMEDmesh")
self.assertTrue(not mm2.existsFamily("Family_-8"))
mm2.createGroupOnAll(-1,"GrpOnAllFace")
self.assertTrue(mm2.existsFamily("Family_-8"))
- self.assertEqual(range(3),mm2.getGroupArr(-1,"GrpOnAllFace").getValues())
+ self.assertEqual(list(range(3)),mm2.getGroupArr(-1,"GrpOnAllFace").getValues())
pass
#testing persistence of retrieved arrays
m.setRenumFieldArr(-1,n1)
m.setRenumFieldArr(-2,n0)
nbOfFams=len(fns)
- for i in xrange(nbOfFams):
+ for i in range(nbOfFams):
m.addFamily(fns[i],fids[i])
pass
nbOfGrps=len(grpns)
- for i in xrange(nbOfGrps):
+ for i in range(nbOfGrps):
m.setFamiliesIdsOnGroup(grpns[i],famIdsPerGrp[i])
pass
m.setName(m2.getName())
mm.write("Pyfile19_bis.med",2)
ff=MEDFileFieldMultiTS.New("Pyfile19.med")
ff.write("Pyfile19_bis.med",0)
- self.assertEqual([('tyty','mm'),('uiop','MW')],MEDLoader.GetComponentsNamesOfField("Pyfile19_bis.med","VFieldOnNodes"))
+ self.assertEqual([('tyty','mm'),('uiop','MW')],GetComponentsNamesOfField("Pyfile19_bis.med","VFieldOnNodes"))
pass
#gauss points
ff.write("Pyfile13_bis.med",0)
ff=MEDFileField1TS.New("Pyfile13.med","MyFirstFieldOnGaussPoint",1,5)
f=ff.getFieldAtLevel(ON_GAUSS_PT,0)
- f2=MEDLoader.ReadFieldGauss("Pyfile13.med",'2DMesh_2',0,'MyFirstFieldOnGaussPoint',1,5)
+ f2=ReadFieldGauss("Pyfile13.med",'2DMesh_2',0,'MyFirstFieldOnGaussPoint',1,5)
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
ff3=MEDFileField1TS.New("Pyfile13.med","MyFirstFieldOnGaussPoint")
f3=ff3.getFieldAtLevel(ON_GAUSS_PT,0)
ff.write("Pyfile14_bis.med",0)
ff=MEDFileField1TS.New("Pyfile14.med","MyFieldOnGaussNE",1,5)
f=ff.getFieldAtLevel(ON_GAUSS_NE,0)
- f2=MEDLoader.ReadFieldGaussNE("Pyfile14.med",'2DMesh_2',0,"MyFieldOnGaussNE",1,5)
+ f2=ReadFieldGaussNE("Pyfile14.med",'2DMesh_2',0,"MyFieldOnGaussNE",1,5)
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
pass
def testMEDField5(self):
ff=MEDFileField1TS.New("Pyfile17.med","MeasureOfMesh_Extruded",1,2)
f=ff.getFieldAtLevel(ON_CELLS,0)
- f2=MEDLoader.ReadFieldCell("Pyfile17.med","Extruded",0,"MeasureOfMesh_Extruded",1,2)
+ f2=ReadFieldCell("Pyfile17.med","Extruded",0,"MeasureOfMesh_Extruded",1,2)
self.assertTrue(f.getMesh().getCoords().isEqual(f2.getMesh().getCoords(),1e-12))
f.getMesh().tryToShareSameCoords(f2.getMesh(),1e-12)
f.changeUnderlyingMesh(f2.getMesh(),22,1e-12)
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
# no with renumbering
f=ff.getFieldAtLevel(ON_CELLS,0,1)
- f2=MEDLoader.ReadFieldCell("Pyfile17.med","Extruded",0,"MeasureOfMesh_Extruded",1,2)
+ f2=ReadFieldCell("Pyfile17.med","Extruded",0,"MeasureOfMesh_Extruded",1,2)
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
f=ff.getFieldAtLevel(ON_CELLS,0,3)
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
its=ff.getIterations()
self.assertRaises(InterpKernelException,ff.getFieldAtLevel,ON_CELLS,its[0][0],its[0][1],0)# request on cell and it is not on cells
f=ff.getFieldAtLevel(ON_NODES,its[0][0],its[0][1],0)
- f2=MEDLoader.ReadFieldNode("Pyfile7.med",'3DSurfMesh_1',0,"VectorFieldOnNodes",its[0][0],its[0][1])
+ f2=ReadFieldNode("Pyfile7.med",'3DSurfMesh_1',0,"VectorFieldOnNodes",its[0][0],its[0][1])
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
ff=MEDFileFieldMultiTS.New("Pyfile19.med","VFieldOnNodes")
its=ff.getIterations()
f=ff.getFieldAtLevel(ON_NODES,its[0][0],its[0][1],0)
- f2=MEDLoader.ReadFieldNode("Pyfile19.med",'2DMesh_1',0,"VFieldOnNodes",its[0][0],its[0][1])
+ f2=ReadFieldNode("Pyfile19.med",'2DMesh_1',0,"VFieldOnNodes",its[0][0],its[0][1])
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
self.assertRaises(InterpKernelException,ff.getFieldAtLevel,ON_CELLS,its[0][0],its[0][1],0)# request on cell and it is not on cells
self.assertRaises(InterpKernelException,ff.getFieldAtLevel,ON_NODES,its[0][0],its[0][1],0,1)#request renumber following mesh : it is on profile !
ff=MEDFileFieldMultiTS.New("Pyfile12.med","VectorFieldOnCells")
its=ff.getIterations()
f=ff.getFieldAtLevel(ON_CELLS,its[0][0],its[0][1],0)
- f2=MEDLoader.ReadFieldCell("Pyfile12.med",'3DMesh_1',0,"VectorFieldOnCells",its[0][0],its[0][1])
+ f2=ReadFieldCell("Pyfile12.med",'3DMesh_1',0,"VectorFieldOnCells",its[0][0],its[0][1])
self.assertTrue(f.isEqual(f2,1e-12,1e-12))
pass
ff1=MEDFileField1TS.New()
ff1.setFieldNoProfileSBT(f1)
ff1.write(fname,0)
- f2=MEDLoader.ReadFieldCell(fname,f1.getMesh().getName(),0,f1.getName(),f1.getTime()[1],f1.getTime()[2]);
+ f2=ReadFieldCell(fname,f1.getMesh().getName(),0,f1.getName(),f1.getTime()[1],f1.getTime()[2]);
itt,orr,ti=ff1.getTime()
self.assertEqual(0,itt); self.assertEqual(1,orr); self.assertAlmostEqual(2.,ti,14);
self.assertTrue(f1.isEqual(f2,1e-12,1e-12))
nv=1456.
da=ff1.getUndergroundDataArray().setIJ(0,0,nv)
ff1.write(fname,0)
- f2=MEDLoader.ReadFieldNode(fname,f1.getMesh().getName(),0,f1.getName(),f1.getTime()[1],f1.getTime()[2])
+ f2=ReadFieldNode(fname,f1.getMesh().getName(),0,f1.getName(),f1.getTime()[1],f1.getTime()[2])
self.assertTrue(not f1.isEqual(f2,1e-12,1e-12))
f1.getArray().setIJ(0,0,nv)
self.assertTrue(f1.isEqual(f2,1e-12,1e-12))
ff1=MEDFileField1TS.New()
ff1.setFieldNoProfileSBT(f1)
ff1.write(fname,0)
- f2=MEDLoader.ReadFieldGaussNE(fname,f1.getMesh().getName(),0,f1.getName(),f1.getTime()[1],f1.getTime()[2])
+ f2=ReadFieldGaussNE(fname,f1.getMesh().getName(),0,f1.getName(),f1.getTime()[1],f1.getTime()[2])
self.assertTrue(f1.isEqual(f2,1e-12,1e-12))
da,infos=ff1.getUndergroundDataArrayExt()
f2.getArray().setName(da.getName())#da has the same name than f2
#
fname="Pyfile28.med"
f1=MEDLoaderDataForTest.buildVecFieldOnGauss_2_Simpler();
- f1InvalidCpy=f1.deepCpy()
+ f1InvalidCpy=f1.deepCopy()
f1InvalidCpy.setDiscretization(MEDCouplingFieldDiscretizationGauss())
- f1InvalidCpy2=f1.deepCpy()
+ f1InvalidCpy2=f1.deepCopy()
f1InvalidCpy2.setDiscretization(MEDCouplingFieldDiscretizationGauss())
m1=f1.getMesh()
mm1=MEDFileUMesh.New()
f21=m2.getMeasureField(True) ; f21.setName("f21") ; f21=f21.buildNewTimeReprFromThis(ONE_TIME,False)
f21.getArray().setInfoOnComponent(0,"sta [mm]") ;
ff21.appendFieldNoProfileSBT(f21)
- f22=f21.deepCpy() ; f22.setName("f22") ; f22=f22.buildNewTimeReprFromThis(ONE_TIME,False) ;
+ f22=f21.deepCopy() ; f22.setName("f22") ; f22=f22.buildNewTimeReprFromThis(ONE_TIME,False) ;
f22.applyFunc(2,"3*x*IVec+2*x*JVec")
f22.getArray().setInfoOnComponent(0,"distance [km]") ; f22.getArray().setInfoOnComponent(1,"displacement [cm]")
ff22.appendFieldNoProfileSBT(f22)
#
ff1.setFieldProfile(f1,mm1,0,da)
ff1.changePflsNames([(["sup1_NORM_QUAD4"],"ForV650")])
- ff1=ff1.deepCpy()
+ ff1=ff1.deepCopy()
ff1.write(fname,0)
#
vals,pfl=ff1.getFieldWithProfile(ON_CELLS,0,mm1) ; vals.setName("")
ff1.appendFieldProfile(f1,mm1,0,da)
f1.setTime(1.2,1,2) ; e=d.applyFunc("2*x") ; e.copyStringInfoFrom(d) ; f1.setArray(e) ;
ff1.appendFieldProfile(f1,mm1,0,da)
- ff1=ff1.deepCpy()
+ ff1=ff1.deepCopy()
ff1.write(fname,0)
#
vals,pfl=ff1.getFieldWithProfile(ON_CELLS,1,2,0,mm1) ; vals.setName("")
m1=MEDLoaderDataForTest.build2DMesh_1()
m1.renumberCells([0,1,4,2,3,5],False)
tmp=m1.getName();
- m1=m1.buildPartOfMySelf(range(5),True) ; m1.setName(tmp) # suppression of last cell that is a polygon
+ m1=m1.buildPartOfMySelf(list(range(5)),True) ; m1.setName(tmp) # suppression of last cell that is a polygon
mm1=MEDFileUMesh.New() ; mm1.setCoords(m1.getCoords()) ; mm1.setMeshAtLevel(0,m1) ;
mm1.write(fname,2)
ff1=MEDFileField1TS.New()
m1=MEDLoaderDataForTest.build2DMesh_1()
m1.renumberCells([0,1,4,2,3,5],False)
tmp=m1.getName();
- m1=m1.buildPartOfMySelf(range(5),True) ; m1.setName(tmp) # suppression of last cell that is a polygon
+ m1=m1.buildPartOfMySelf(list(range(5)),True) ; m1.setName(tmp) # suppression of last cell that is a polygon
mm1=MEDFileUMesh.New() ; mm1.setCoords(m1.getCoords()) ; mm1.setMeshAtLevel(0,m1) ;
mm1.write(fname,2)
ff1=MEDFileFieldMultiTS.New()
da=DataArrayInt.New(); da.setValues([0,1,3,4,6],5,1) ; da.setName("sup1NodeElt")
#
ff1.setFieldProfile(f1,mm1,0,da)
- m1=m0.buildPartOfMySelf(range(5),True) ; m1.setName(tmp) ; mm1.setMeshAtLevel(0,m1) ;
+ m1=m0.buildPartOfMySelf(list(range(5)),True) ; m1.setName(tmp) ; mm1.setMeshAtLevel(0,m1) ;
mm1.write(fname,2)
ff1.write(fname,0)
f1=ff1.getFieldOnMeshAtLevel(ON_GAUSS_NE,m1,0)
f2,p1=ff1.getFieldWithProfile(ON_GAUSS_NE,0,mm1) ; f2.setName("")
- self.assertTrue(p1.isIdentity())
- self.assertEqual(5,p1.getNumberOfTuples())
+ self.assertTrue(p1.isIota(5))
self.assertTrue(f1.getArray().isEqual(f2,1e-12))
pass
# Test for getFieldAtTopLevel method
ff1.appendFieldProfile(f1,mm1,0,da)
ffs.resize(1)
ffs.setFieldAtPos(0,ff1)
- ffs=ffs.deepCpy()
+ ffs=ffs.deepCopy()
ffs.write(fname,0)
#
ffsr=MEDFileFields.New(fname)
ff1.setFieldNoProfileSBT(f1)
ff1.write(fname,0)
# writing mesh1 and field1, now creation of mesh2 and field2
- f2=f1.deepCpy()
+ f2=f1.deepCopy()
m2=f2.getMesh()
m2.translate([0.5,0.6,0.7])
m2.setName("3DSurfMesh_2")
ff2.setFieldNoProfileSBT(f2)
ff2.write(fname,0)
#
- f3=MEDLoader.ReadFieldCell(fname,"3DSurfMesh_1",0,"VectorFieldOnCells",0,1)
+ f3=ReadFieldCell(fname,"3DSurfMesh_1",0,"VectorFieldOnCells",0,1)
self.assertTrue(f3.isEqual(f1,1e-12,1e-12))
- f4=MEDLoader.ReadFieldCell(fname,"3DSurfMesh_2",0,"VectorFieldOnCells2",0,1)
+ f4=ReadFieldCell(fname,"3DSurfMesh_2",0,"VectorFieldOnCells2",0,1)
self.assertTrue(f4.isEqual(f2,1e-12,1e-12))
pass
da2.iota(7.)
da2.rearrange(len(compNames1))
da2.setInfoOnComponents(compNames1)
- f2=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f2.setName(FieldName1) ; f2.setArray(da2) ; f2.setMesh(m2) ; f2.checkCoherency()
+ f2=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f2.setName(FieldName1) ; f2.setArray(da2) ; f2.setMesh(m2) ; f2.checkConsistencyLight()
ff1.setFieldNoProfileSBT(f2)
self.assertEqual(ff1.getNonEmptyLevels(),(2, [0]))
da0=DataArrayDouble.New()
da0.iota(190.)
da0.rearrange(len(compNames1))
da0.setInfoOnComponents(compNames1)
- f0=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f0.setName(FieldName1) ; f0.setArray(da0) ; f0.setMesh(m0) ; f0.checkCoherency()
+ f0=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f0.setName(FieldName1) ; f0.setArray(da0) ; f0.setMesh(m0) ; f0.checkConsistencyLight()
ff1.setFieldNoProfileSBT(f0)
self.assertEqual(ff1.getNonEmptyLevels(),(2, [0,-2]))
da1=DataArrayDouble.New()
da1.iota(90.)
da1.rearrange(len(compNames1))
da1.setInfoOnComponents(compNames1)
- f1=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f1.setName(FieldName1) ; f1.setArray(da1) ; f1.setMesh(m1) ; f1.checkCoherency()
+ f1=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f1.setName(FieldName1) ; f1.setArray(da1) ; f1.setMesh(m1) ; f1.checkConsistencyLight()
ff1.setFieldNoProfileSBT(f1)
self.assertEqual(ff1.getNonEmptyLevels(),(2, [0,-1,-2]))
#
da0.iota(-190.)
da0.rearrange(2)
da0.setInfoOnComponents(compNames2)
- f0=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f0.setName(FieldName2) ; f0.setArray(da0) ; f0.setMesh(m0) ; f0.checkCoherency()
+ f0=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f0.setName(FieldName2) ; f0.setArray(da0) ; f0.setMesh(m0) ; f0.checkConsistencyLight()
ff2.setFieldNoProfileSBT(f0)
self.assertEqual(ff2.getNonEmptyLevels(),(0, [0]))
da1=DataArrayDouble.New()
da1.iota(-90.)
da1.rearrange(len(compNames2))
da1.setInfoOnComponents(compNames2)
- f1=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f1.setName(FieldName2) ; f1.setArray(da1) ; f1.setMesh(m1) ; f1.checkCoherency()
+ f1=MEDCouplingFieldDouble.New(ON_CELLS,ONE_TIME) ; f1.setName(FieldName2) ; f1.setArray(da1) ; f1.setMesh(m1) ; f1.checkConsistencyLight()
ff2.setFieldNoProfileSBT(f1)
self.assertEqual(ff2.getNonEmptyLevels(),(1, [0,-1]))
#
expected1=[1.,10.,100.,2.,20.,200.]
nodeCoordsWithValue1=[10.,2.5,0.]
nodeCoordsWithValue2=[10.,3.75,0.]
- for i in xrange(3):
+ for i in range(3):
self.assertAlmostEqual(nodeCoordsWithValue1[i],tes0.getMesh().getCoordinatesOfNode(0)[i],13);
self.assertAlmostEqual(nodeCoordsWithValue2[i],tes0.getMesh().getCoordinatesOfNode(1)[i],13);
pass
- for i in xrange(6):
+ for i in range(6):
self.assertAlmostEqual(expected1[i],tes0.getArray().getIJ(0,i),13);
pass
del tes0
self.assertEqual([0,2,4],tes1.getMesh().getNodalConnectivityIndex().getValues())
self.assertEqual(2,tes1.getArray().getNumberOfTuples())
self.assertEqual(3,tes1.getArray().getNumberOfComponents())
- for i in xrange(6):
+ for i in range(6):
self.assertAlmostEqual(expected1[i],tes1.getArray().getIJ(0,i),13);
pass
m.write(fname,2)
self.assertEqual(2,tes2.getArray().getNumberOfTuples())
self.assertEqual(3,tes2.getArray().getNumberOfComponents())
expected2=[2.,20.,200.,1.,10.,100.]
- for i in xrange(3):
+ for i in range(3):
self.assertAlmostEqual(nodeCoordsWithValue1[i],tes2.getMesh().getCoordinatesOfNode(0)[i],13);
self.assertAlmostEqual(nodeCoordsWithValue2[i],tes2.getMesh().getCoordinatesOfNode(1)[i],13);
pass
- for i in xrange(6):
+ for i in range(6):
self.assertAlmostEqual(expected2[i],tes2.getArray().getIJ(0,i),13);#compare tes2 and tes3
pass
#
self.assertEqual([0,2,4],tes3.getMesh().getNodalConnectivityIndex().getValues())
self.assertEqual(2,tes3.getArray().getNumberOfTuples())
self.assertEqual(3,tes3.getArray().getNumberOfComponents())
- for i in xrange(6):
+ for i in range(6):
self.assertAlmostEqual(expected1[i],tes3.getArray().getIJ(0,i),13);
pass
pass
- def testDuplicateNodesOnM1Group1(self):
+ def testBuildInnerBoundaryAlongM1Group1(self):
fname="Pyfile44.med"
m=MEDCouplingCMesh.New()
m.setCoordsAt(0,DataArrayDouble.New([0.,1.1,2.3,3.6,5.,6.5]))
self.assertEqual(ref0,mm.getMeshAtLevel(0)[[12,13,14]].getNodalConnectivity().getValues())
self.assertEqual(ref1,mm.getMeshAtLevel(0)[[7,8,9]].getNodalConnectivity().getValues())
#
- nodes,cells,cells2=mm.duplicateNodesOnM1Group("Grp")
+ nodes,cells,cells2=mm.buildInnerBoundaryAlongM1Group("Grp")
self.assertEqual([15,16,17],nodes.getValues());
self.assertEqual([7,8,9],cells.getValues());
self.assertEqual([12,13,14],cells2.getValues());
mm.write(fname,2)
pass
- def testDuplicateNodesOnM1Group2(self):
+ def testBuildInnerBoundaryAlongM1Group2(self):
fname="Pyfile45.med"
m=MEDCouplingCMesh.New()
m.setCoordsAt(0,DataArrayDouble.New([0.,1.1,2.3,3.6,5.,6.5]))
self.assertEqual(ref0,mm.getMeshAtLevel(0)[[12,13,14]].getNodalConnectivity().getValues())
self.assertEqual(ref1,mm.getMeshAtLevel(0)[[7,8]].getNodalConnectivity().getValues())
#
- nodes,cells,cells2=mm.duplicateNodesOnM1Group("Grp")
+ nodes,cells,cells2=mm.buildInnerBoundaryAlongM1Group("Grp")
self.assertEqual([15],nodes.getValues());
self.assertEqual([7,8],cells.getValues());
self.assertEqual([12,13],cells2.getValues());
mm.write(fname,2)
pass
- def testDuplicateNodesOnM1Group3(self):
- """ Test duplicateNodesOnM1Group() with *non-connex* cracks """
+ def testBuildInnerBoundaryAlongM1Group3(self):
+ """ Test buildInnerBoundaryAlongM1Group() with *non-connex* cracks """
fname = "Pyfile73.med"
m = MEDCouplingCMesh.New()
m.setCoordsAt(0, DataArrayDouble([0.0,1.1,2.3,3.6,5.0]))
m2.setName(m.getName())
# A crack in two non connected parts of the mesh:
- grpSeg = DataArrayInt([2,11]) ; grpSeg.setName("Grp")
+ grpSeg = DataArrayInt([3,19]) ; grpSeg.setName("Grp")
mm = MEDFileUMesh.New()
mm.setMeshAtLevel(0,m)
mm.setMeshAtLevel(-1,m2)
mm.setGroupsAtLevel(-1,[grpSeg])
- nodes, cellsMod, cellsNotMod = mm.duplicateNodesOnM1Group("Grp")
- self.assertEqual([5,9],nodes.getValues());
- self.assertEqual([0,3],cellsMod.getValues());
- self.assertEqual([4,7],cellsNotMod.getValues());
+ nodes, cellsMod, cellsNotMod = mm.buildInnerBoundaryAlongM1Group("Grp")
+ self.assertEqual([1,13],nodes.getValues());
+ self.assertEqual([0,6],cellsMod.getValues());
+ self.assertEqual([1,7],cellsNotMod.getValues());
self.assertEqual(17,mm.getNumberOfNodes())
- self.assertEqual([2,11],mm.getGroupArr(-1,"Grp").getValues())
+ self.assertEqual([3,19],mm.getGroupArr(-1,"Grp").getValues())
self.assertEqual([22,23],mm.getGroupArr(-1,"Grp_dup").getValues())
- ref0=[4, 1, 0, 15, 6, 4, 4, 3, 8, 16]
- ref1=[4, 6, 5, 10, 11, 4, 9, 8, 13, 14]
- self.assertEqual(ref0,mm.getMeshAtLevel(0)[[0,3]].getNodalConnectivity().getValues())
- self.assertEqual(ref1,mm.getMeshAtLevel(0)[[4,7]].getNodalConnectivity().getValues())
+ ref0=[4, 15, 0, 5, 6, 4, 8, 7, 12, 16]
+ ref1=[4, 2, 1, 6, 7, 4, 9, 8, 13, 14]
+ self.assertEqual(ref0,mm.getMeshAtLevel(0)[[0,6]].getNodalConnectivity().getValues())
+ self.assertEqual(ref1,mm.getMeshAtLevel(0)[[1,7]].getNodalConnectivity().getValues())
self.assertRaises(InterpKernelException,mm.getGroup(-1,"Grp_dup").checkGeoEquivalWith,mm.getGroup(-1,"Grp"),2,1e-12);# Grp_dup and Grp are not equal considering connectivity only
mm.getGroup(-1,"Grp_dup").checkGeoEquivalWith(mm.getGroup(-1,"Grp"),12,1e-12)# Grp_dup and Grp are equal considering connectivity and coordinates
refValues=DataArrayDouble([1.1, 1.2, 1.3, 1.4, 1.1, 1.2, 1.3, 1.4])
valsToTest=mm.getMeshAtLevel(0).getMeasureField(True).getArray() ; delta=(valsToTest-refValues) ; delta.abs()
- self.assertTrue(delta.getMaxValue()[0]<1e-12)
+ self.assertTrue(delta.getMaxValue()[0]<1e-10)
#
mm.getCoords()[-len(nodes):]+=[0.,-0.3]
self.assertRaises(InterpKernelException,mm.getGroup(-1,"Grp_dup").checkGeoEquivalWith,mm.getGroup(-1,"Grp"),12,1e-12);
- refValues2=refValues[:] ; refValues2[0] = 0.935; refValues2[3] = 1.19
- valsToTest=mm.getMeshAtLevel(0).getMeasureField(True).getArray() ; delta=(valsToTest-refValues2) ; delta.abs()
+ refValues2=refValues[:] ; refValues2[0] = 1.265; refValues2[6] = 1.105
+ valsToTest=mm.getMeshAtLevel(0).getMeasureField(True).getArray() ; delta=(valsToTest-refValues2) ; delta.abs()
self.assertTrue(delta.getMaxValue()[0]<1e-12)
mm.write(fname,2)
+ def testBuildInnerBoundaryAlongM1Group4(self):
+ """ Test case where cells touch the M1 group on some nodes only and not on full egdes (triangle mesh for ex)
+ """
+ coo = DataArrayDouble([0.,0., 1.,0., 2.,0., 3.,0.,
+ 0.,1., 1.,1., 2.,1., 3.,1.,
+ 0.,2., 1.,2., 2.,2., 3.,2.], 12, 2)
+ conn = [3,0,4,1, 3,1,4,5,
+ 3,5,9,10, 3,5,10,6,
+ 3,2,6,7, 3,2,7,3,
+ 3,4,8,9, 3,4,9,5,
+ 3,1,5,6, 3,1,6,2,
+ 3,6,10,11,3,6,11,7]
+ # Only TRI3:
+ connI = DataArrayInt()
+ connI.alloc(13, 1); connI.iota(); connI *= 4
+ m2 = MEDCouplingUMesh("2D", 2)
+ m2.setCoords(coo)
+ m2.setConnectivity(DataArrayInt(conn), connI)
+ m2.checkConsistency()
+ m1, _, _, _, _ = m2.buildDescendingConnectivity()
+ grpIds = DataArrayInt([9,11]); grpIds.setName("group")
+ grpIds2 = DataArrayInt([0,1]); grpIds2.setName("group2")
+ mfu = MEDFileUMesh()
+ mfu.setMeshAtLevel(0, m2)
+ mfu.setMeshAtLevel(-1, m1)
+ mfu.setGroupsAtLevel(-1, [grpIds, grpIds2])
+ nNod = m2.getNumberOfNodes()
+ nodesDup, cells1, cells2 = mfu.buildInnerBoundaryAlongM1Group("group")
+ m2_bis = mfu.getMeshAtLevel(0)
+ m2_bis.checkConsistency()
+ m1_bis = mfu.getMeshAtLevel(-1)
+ m1_bis.checkConsistency()
+ self.assertEqual(nNod+2, mfu.getNumberOfNodes())
+ self.assertEqual(nNod+2, m2_bis.getNumberOfNodes())
+ self.assertEqual(nNod+2, m1_bis.getNumberOfNodes())
+ self.assertEqual([6,7], nodesDup.getValues())
+ self.assertEqual([2.,1., 3.,1.], m2_bis.getCoords()[nNod:].getValues())
+ self.assertEqual(set([3,10,11]), set(cells1.getValues()))
+ self.assertEqual(set([8,9,4,5]), set(cells2.getValues()))
+ self.assertEqual([9,11],mfu.getGroupArr(-1,"group").getValues())
+ self.assertEqual([23,24],mfu.getGroupArr(-1,"group_dup").getValues())
+ self.assertEqual([0,1],mfu.getGroupArr(-1,"group2").getValues())
+# mfu.getMeshAtLevel(0).writeVTK("/tmp/mfu_M0.vtu")
+ ref0 =[3, 5, 10, 12, 3, 12, 10, 11, 3, 12, 11, 13]
+ ref1 =[3, 2, 6, 7, 3, 2, 7, 3, 3, 1, 5, 6, 3, 1, 6, 2]
+ self.assertEqual(ref0,mfu.getMeshAtLevel(0)[[3,10,11]].getNodalConnectivity().getValues())
+ self.assertEqual(ref1,mfu.getMeshAtLevel(0)[[4,5,8,9]].getNodalConnectivity().getValues())
+ self.assertRaises(InterpKernelException,mfu.getGroup(-1,"group_dup").checkGeoEquivalWith,mfu.getGroup(-1,"group"),2,1e-12) # Grp_dup and Grp are not equal considering connectivity only
+ mfu.getGroup(-1,"group_dup").checkGeoEquivalWith(mfu.getGroup(-1,"group"),12,1e-12)# Grp_dup and Grp are equal considering connectivity and coordinates
+ m_bis0 = mfu.getMeshAtLevel(-1)
+ m_desc, _, _, _, _ = m_bis0.buildDescendingConnectivity()
+ m_bis0.checkDeepEquivalOnSameNodesWith(mfu.getMeshAtLevel(-1), 2, 9.9999999)
+
+ def testBuildInnerBoundary5(self):
+ """ Full 3D test with tetras only. In this case a tri from the group is not duplicated because it is made only
+ of non duplicated nodes. The tri in question is hence not part of the final new "dup" group. """
+ coo = DataArrayDouble([200.0, 200.0, 0.0, 200.0, 200.0, 200.0, 200.0, 0.0, 200.0, 200.0, 0.0, 0.0, 0.0, 200.0, 0.0, 0.0, 200.0, 200.0, 0.0, 0.0, 0.0, 0.0, 0.0,
+ 200.0, 400.0, 200.0, 0.0, 400.0, 200.0, 200.0, 400.0, 0.0, 0.0, 400.0, 0.0, 200.0, 0.0, 100.00000000000016, 200.0, 63.15203310314546, 200.0, 200.0, 134.45205700643342,
+ 200.0, 200.0, 200.0, 100.00000000000016, 200.0, 63.15203310314546, 0.0, 200.0, 134.45205700643342, 0.0, 200.0, 0.0, 100.00000000000016, 0.0, 63.15203310314546,
+ 200.0, 0.0, 134.45205700643342, 200.0, 0.0, 200.0, 100.00000000000016, 0.0, 63.15203310314546, 0.0, 0.0, 134.45205700643342, 0.0, 0.0, 200.0, 200.0, 100.02130053568538,
+ 0.0, 200.0, 100.00938163175135, 200.0, 0.0, 100.02130053568538, 0.0, 0.0, 100.00938163175135, 299.3058739933347, 200.0, 200.0, 400.0, 98.68100542924483,
+ 200.0, 302.8923433403344, 0.0, 200.0, 302.8923433403344, 200.0, 0.0, 400.0, 100.00000000000016, 0.0, 302.8923433403344, 0.0, 0.0, 400.0, 200.0, 98.55126825835082,
+ 400.0, 0.0, 100.02162286181577, 99.31624553977466, 99.99999998882231, 200.0, 99.31624576683302, 100.00000010178034, 0.0, 99.31624560596512, 200.0, 100.0050761312483,
+ 99.31624560612883, 0.0, 100.00507613125338, 200.0, 99.99999995813045, 100.00950673487786, 0.0, 99.99999989928207, 100.0041870621175, 301.29063354383015,
+ 100.0000000093269, 0.0, 301.29063360689975, 0.0, 100.00957769061164, 140.52853868782435, 99.99999963972768, 100.00509135751312, 297.87779091770784,
+ 97.16750463405486, 97.18018457127863], 46, 3)
+ c0 = [14, 45, 31, 21, 42, 14, 37, 38, 20, 44, 14, 39, 36, 41, 44, 14, 5, 25, 12, 13, 14, 38, 36, 44, 41, 14, 21, 20, 24, 44, 14, 38, 25, 41, 19, 14, 37, 38, 44, 41, 14, 16, 27,
+ 39, 41, 14, 21, 45, 26, 40, 14, 39, 37, 44, 41, 14, 14, 15, 24, 44, 14, 25, 38, 41, 13, 14, 27, 18, 6, 22, 14, 38, 36, 41, 13, 14, 44, 14, 15, 36, 14, 44, 23, 39, 26, 14,
+ 21,26, 23, 44, 14, 38, 44, 14, 24, 14, 39, 37, 41, 22, 14, 21, 33, 45, 42, 14, 27, 22, 39, 41, 14, 23, 26, 21, 3, 14, 27, 18, 22, 41, 14, 39, 36, 44, 17, 14, 21, 26, 44, 40,
+ 14, 39, 37, 22, 23, 14, 37, 38, 41, 19, 14, 25, 12, 13, 41, 14, 30, 26, 43, 45, 14, 38, 36, 13, 14, 14, 12, 36, 13, 41, 14, 20, 44, 21, 37, 14, 16, 36, 12, 41, 14, 39, 36,
+ 17, 16, 14, 44, 20, 24, 38, 14, 27, 16, 12, 41, 14, 26, 15, 17, 44, 14, 19, 18, 41, 37, 14, 40, 45, 26, 15, 14, 37, 38, 19, 20, 14, 17, 15, 26, 2, 14, 39, 36, 16, 41, 14,
+ 24, 21, 44, 40, 14, 16, 7, 27, 12, 14, 22, 18, 37, 41, 14, 21, 31, 45, 24, 14, 44, 40, 15, 24, 14, 24, 45, 15, 28, 14, 44, 40, 26, 15, 14, 24, 20, 21, 0, 14, 38, 36, 14,
+ 44, 14, 39, 37, 23, 44, 14, 45, 31, 42, 32, 14, 25, 18, 19, 4, 14, 36, 44, 17, 15, 14, 25, 19, 18, 41, 14, 24, 15, 14, 1, 14, 45, 24, 34, 28, 14, 35, 45, 30, 43, 14, 17,
+ 44, 39, 26, 14, 44, 23, 21, 37, 14, 30, 45, 29, 15, 14, 45, 35, 33, 43, 14, 30, 15, 26, 45, 14, 31, 21, 0, 24, 14, 33, 35, 32, 10, 14, 29, 45, 34, 28, 14, 32, 45, 34,
+ 29, 14, 45, 31, 32, 34, 14, 33, 26, 45, 43, 14, 45, 31, 34, 24, 14, 33, 26, 21, 45, 14, 11, 30, 35, 29, 14, 33, 35, 45, 32, 14, 33, 45, 42, 32, 14, 32, 8, 34, 31, 14,
+ 21, 26, 33, 3, 14, 35, 45, 32, 29, 14, 29, 34, 9, 28, 14, 15, 45, 24, 40, 14, 29, 45, 28, 15, 14, 21, 24, 45, 40, 14, 24, 15, 1, 28, 14, 35, 45, 29, 30, 14, 26, 15,
+ 30, 2]
+ cI0 = [0, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165, 170, 175, 180, 185,
+ 190, 195, 200, 205, 210, 215, 220, 225, 230, 235, 240, 245, 250, 255, 260, 265, 270, 275, 280, 285, 290, 295, 300, 305, 310, 315, 320, 325, 330, 335, 340, 345, 350, 355,
+ 360, 365, 370, 375, 380, 385, 390, 395, 400, 405, 410, 415, 420, 425, 430]
+ m3 = MEDCouplingUMesh("3D", 3)
+ m3.setCoords(coo)
+ m3.setConnectivity(DataArrayInt(c0), DataArrayInt(cI0))
+ m3.checkConsistency()
+ m2, _, _, _, _ = m3.buildDescendingConnectivity()
+ grpIds = DataArrayInt([36,74]); grpIds.setName("group")
+ mfu = MEDFileUMesh()
+ mfu.setMeshAtLevel(0, m3)
+ mfu.setMeshAtLevel(-1, m2)
+ grpIds3D = DataArrayInt([0,1]); grpIds3D.setName("group_3d")
+ mfu.setGroupsAtLevel(0, [grpIds3D]) # just to check preservation of 3D group
+ mfu.setGroupsAtLevel(-1, [grpIds])
+ nNod = m3.getNumberOfNodes()
+ nodesDup, cells1, cells2 = mfu.buildInnerBoundaryAlongM1Group("group")
+ m3_bis = mfu.getMeshAtLevel(0)
+ m3_bis.checkConsistency()
+ m2_bis = mfu.getMeshAtLevel(-1)
+ m2_bis.checkConsistency()
+ self.assertEqual(nNod+1, mfu.getNumberOfNodes())
+ self.assertEqual(nNod+1, m3_bis.getNumberOfNodes())
+ self.assertEqual(nNod+1, m2_bis.getNumberOfNodes())
+ self.assertEqual([3], nodesDup.getValues())
+ self.assertEqual(m3_bis.getCoords()[3].getValues(), m3_bis.getCoords()[nNod:].getValues())
+ self.assertEqual(set([22]), set(cells1.getValues()))
+ self.assertEqual(set([77]), set(cells2.getValues()))
+ self.assertEqual([36,74],mfu.getGroupArr(-1,"group").getValues())
+ self.assertEqual([0,1],mfu.getGroupArr(0,"group_3d").getValues())
+ self.assertEqual([213],mfu.getGroupArr(-1,"group_dup").getValues()) # here only one cell has been duplicated
+ m_bis0 = mfu.getMeshAtLevel(-1)
+ m_desc, _, _, _, _ = m_bis0.buildDescendingConnectivity()
+ m_bis0.checkDeepEquivalOnSameNodesWith(mfu.getMeshAtLevel(-1), 2, 9.9999999)
+ pass
+
def testBasicConstructors(self):
fname="Pyfile18.med"
m=MEDFileMesh.New(fname)
fname="Pyfile46.med"
m=MEDLoaderDataForTest.build2DMesh_3()
m=m[:10] ; m.setName("mesh")
- f=m.getMeasureField(ON_CELLS)
+ f=m.getMeasureField(False)
f=f.buildNewTimeReprFromThis(ONE_TIME,False)
f.setTime(5.5,3,4)
f.setName("SemiPartialField")
fread=ff2.getFieldOnMeshAtLevel(ON_CELLS,0,mm)
fread2=ff2.getFieldAtLevel(ON_CELLS,0)
#
- fread.checkCoherency()
- fread2.checkCoherency()
+ fread.checkConsistencyLight()
+ fread2.checkConsistencyLight()
self.assertTrue(fread.isEqual(f1,1e-12,1e-12))
self.assertTrue(fread2.isEqual(f1,1e-12,1e-12))
pass
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.insertNextCell(NORM_QUAD8,list(range(8)))
mQ8.finishInsertingCells()
mQ4=MEDCouplingUMesh("",2) ; mQ4.setCoords(coords)
mQ4.allocateCells(1)
- mQ4.insertNextCell(NORM_QUAD4,range(4))
+ mQ4.insertNextCell(NORM_QUAD4,list(range(4)))
mQ4.finishInsertingCells()
mT3=MEDCouplingUMesh("",2) ; mT3.setCoords(coords)
mT3.allocateCells(1)
- mT3.insertNextCell(NORM_TRI3,range(3))
+ mT3.insertNextCell(NORM_TRI3,list(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)
+ ms[:]=(elt.deepCopy() for elt in ms)
for m,t in zip(ms,tr):
d=m.getCoords() ; d+= t
pass
da=DataArrayDouble(34) ; da.iota(3.)
f.setArray(da)
f.setName("fieldCellOnPflWithoutPfl")
- fInvalid=f.deepCpy()
+ fInvalid=f.deepCopy()
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()
+ f.checkConsistencyLight()
+ fInvalid2=fInvalid.deepCopy()
fInvalid2.getDiscretization().setArrayOfDiscIds(f.getDiscretization().getArrayOfDiscIds())
#
mm=MEDFileUMesh()
mm.write(fname,2)
#
f1ts=MEDFileField1TS.New()
- pfl=DataArrayInt(range(13)) ; pfl.setName("pfl")
+ pfl=DataArrayInt(list(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)
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()
+ f2_bis=ReadFieldGauss(fname,m.getName(),0,f.getName(),f.getTime()[1],f.getTime()[2])
+ f2_bis.checkConsistencyLight()
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])
+ WriteField(fname2,f,True)
+ f2_ter=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)
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()
+ f.checkConsistencyLight()
#
mm=MEDFileUMesh()
mm.setMeshAtLevel(0,m)
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=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])
+ WriteField(fname2,f,True)
+ f3_ter=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.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()
+ f.checkConsistencyLight()
mm=MEDFileUMesh()
mm.setMeshAtLevel(0,m)
f1ts=MEDFileField1TS.New()
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=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])
+ WriteField(fname2,f,True)
+ f3_ter=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
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):
+ for i in range(9):
m1.insertNextCell(NORM_SEG2,conn1[2*i:2*i+2])
pass
m1.finishInsertingCells()
## Reading from file
m=MEDFileMesh.New(fname)
m0=m.getMeshAtLevel(0)
- m00=m0.deepCpy() ; m00=m00[[0,2]] ; m00.setName(m.getName()) ; m00.zipCoords()
+ m00=m0.deepCopy() ; 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()
+ ff0_1.checkConsistencyLight()
self.assertTrue(ff0_1.isEqual(fieldNode0,1e-12,1e-12))
ff0_2=f0.getFieldAtLevel(ON_NODES,0)
- ff0_2.checkCoherency()
+ ff0_2.checkConsistencyLight()
self.assertTrue(ff0_2.isEqual(fieldNode0,1e-12,1e-12))
ff0_3=f0.getFieldOnMeshAtLevel(ON_NODES,0,m)
- ff0_3.checkCoherency()
+ ff0_3.checkConsistencyLight()
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()
+ ff0_4=ReadFieldNode(fname,m.getName(),0,fieldNode0.getName(),dt,it)
+ ff0_4.checkConsistencyLight()
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()
+ m10=m1.deepCopy() ; 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()
+ ff1_1.checkConsistencyLight()
self.assertTrue(ff1_1.isEqual(fieldNode1,1e-12,1e-12))
ff1_2=f1.getFieldAtLevel(ON_NODES,-1)
- ff1_2.checkCoherency()
+ ff1_2.checkConsistencyLight()
self.assertTrue(ff1_2.isEqual(fieldNode1,1e-12,1e-12))
ff1_3=f1.getFieldOnMeshAtLevel(ON_NODES,-1,m)
- ff1_3.checkCoherency()
+ ff1_3.checkConsistencyLight()
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()
+ ff1_4=ReadFieldNode(fname,m.getName(),-1,fieldNode1.getName(),dt,it)
+ ff1_4.checkConsistencyLight()
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]
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):
+ for i in range(9):
m1.insertNextCell(NORM_SEG2,conn1[2*i:2*i+2])
pass
m1.finishInsertingCells()
## Reading from file
m=MEDFileMesh.New(fname)
m0=m.getMeshAtLevel(0)
- m00=m0.deepCpy() ; m00=m00[pfl0] ; m00.setName(m.getName())
+ m00=m0.deepCopy() ; 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()
+ ff0_1.checkConsistencyLight()
self.assertTrue(ff0_1.isEqual(fieldCell0,1e-12,1e-12))
ff0_2=f0.getFieldAtLevel(ON_CELLS,0)
- ff0_2.checkCoherency()
+ ff0_2.checkConsistencyLight()
self.assertTrue(ff0_2.isEqual(fieldCell0,1e-12,1e-12))
ff0_3=f0.getFieldOnMeshAtLevel(ON_CELLS,0,m)
- ff0_3.checkCoherency()
+ ff0_3.checkConsistencyLight()
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()
+ ff0_4=ReadFieldCell(fname,m.getName(),0,fieldCell0.getName(),dt,it)
+ ff0_4.checkConsistencyLight()
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())
+ m10=m1.deepCopy() ; m10=m10[pfl1] ; m10.setName(m.getName())
fieldCell1.setMesh(m10)
ff1_1=f1.getFieldOnMeshAtLevel(ON_CELLS,m1)
- ff1_1.checkCoherency()
+ ff1_1.checkConsistencyLight()
self.assertTrue(ff1_1.isEqual(fieldCell1,1e-12,1e-12))
ff1_2=f1.getFieldAtLevel(ON_CELLS,-1)
- ff1_2.checkCoherency()
+ ff1_2.checkConsistencyLight()
self.assertTrue(ff1_2.isEqual(fieldCell1,1e-12,1e-12))
ff1_3=f1.getFieldOnMeshAtLevel(ON_CELLS,-1,m)
- ff1_3.checkCoherency()
+ ff1_3.checkConsistencyLight()
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()
+ ff1_4=ReadFieldCell(fname,m.getName(),-1,fieldCell1.getName(),dt,it)
+ ff1_4.checkConsistencyLight()
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]
m1.setCoords(coo) ; m.setMeshAtLevel(-1,m1)
m2.setCoords(coo) ; m.setMeshAtLevel(-2,m2)
#
- mm=m.deepCpy()
+ mm=m.deepCopy()
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)
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):
+ for i in range(7):
m0.insertNextCell(NORM_TRI3,[1,2,1])
pass
- for i in xrange(4):
+ for i in range(4):
m0.insertNextCell(NORM_QUAD4,[1,1,2,0])
pass
- for i in xrange(2):
+ for i in range(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])
m1.setCoords(coo) ; m.setMeshAtLevel(-1,m1)
m2.setCoords(coo) ; m.setMeshAtLevel(-2,m2)
#
- mm=m.deepCpy()
+ mm=m.deepCopy()
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)
m.setCoords(arr,arr)
m=m.buildUnstructured()
m.setName("mm")
- f=m.getMeasureField(ON_CELLS)
- self.assertIn(m.getHeapMemorySize(),xrange(3552-100,3552+100+4*strMulFac))
- self.assertIn(f.getHeapMemorySize(),xrange(4215-100,4215+100+8*strMulFac))
+ f=m.getMeasureField(False)
+ self.assertIn(m.getHeapMemorySize(), list(range(3552 - 100, 3552 + 100 + 4 * strMulFac)))
+ self.assertIn(f.getHeapMemorySize(), list(range(4215 - 100, 4215 + 100 + 8 * strMulFac)))
#
mm=MEDFileUMesh()
mm.setMeshAtLevel(0,m)
- self.assertIn(mm.getHeapMemorySize(),xrange(3889-100,3889+100+10*strMulFac))
+ self.assertIn(mm.getHeapMemorySize(), list(range(3889 - 100, 4225 + 100 + 10 * strMulFac)))
ff=MEDFileField1TS()
ff.setFieldNoProfileSBT(f)
- self.assertIn(ff.getHeapMemorySize(),xrange(771-40,771+21+(4+1)*strMulFac))
+ self.assertIn(ff.getHeapMemorySize(), list(range(771 - 40, 871 + 21 + (4 + 1) * strMulFac)))
#
fff=MEDFileFieldMultiTS()
fff.appendFieldNoProfileSBT(f)
- self.assertIn(fff.getHeapMemorySize(),xrange(815-50,815+30+(6+2)*strMulFac))
+ self.assertIn(fff.getHeapMemorySize(), list(range(815 - 50, 915 + 30 + (6 + 2) * strMulFac)))
f.setTime(1.,0,-1)
fff.appendFieldNoProfileSBT(f)
- self.assertIn(fff.getHeapMemorySize(),xrange(1594-90,1594+50+(10+1)*strMulFac))
- self.assertIn(fff[0,-1].getHeapMemorySize(),xrange(771-40,771+20+(4+1)*strMulFac))
+ self.assertIn(fff.getHeapMemorySize(), list(range(1594 - 90, 1794 + 50 + (10 + 1) * strMulFac)))
+ self.assertIn(fff[0, -1].getHeapMemorySize(), list(range(771 - 40, 871 + 20 + (4 + 1) * strMulFac)))
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(2348-130,2348+100+(10+2)*strMulFac))
- self.assertIn(fff.getProfile("pfl").getHeapMemorySize(),xrange(204-10,204+10+2*strMulFac))
- self.assertIn(fff[1,-1].getHeapMemorySize(),xrange(738-50,738+30+4*strMulFac))
+ self.assertIn(fff.getHeapMemorySize(), list(range(2348 - 130, 2608 + 100 + (10 + 2) * strMulFac)))
+ self.assertIn(fff.getProfile("pfl").getHeapMemorySize(), list(range(204 - 10, 204 + 10 + 2 * strMulFac)))
+ self.assertIn(fff[1, -1].getHeapMemorySize(), list(range(738 - 50, 838 + 30 + 4 * strMulFac)))
pass
def testCurveLinearMesh1(self):
a1.iota(7.) ; a1.rearrange(3);
mesh.setCoords(a1);
mesh.setNodeGridStructure([4,5]);
- mesh.checkCoherency();
+ mesh.checkConsistencyLight();
#
m=MEDFileCurveLinearMesh()
m.setMesh(mesh)
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")
+ pts2=pts.deepCopy() ; 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()
+ p3=p.deepCopy()
+ pts4=pts2.deepCopy()
+ pts3=pts2.deepCopy()
self.assertTrue(pts3.isEqual(pts2,1e-14)[0])
pts2.eraseTimeStepIds([0])
self.assertTrue(not pts3.isEqual(pts2,1e-14)[0])
mm.setMeshAtLevel(0,m)
mm.setMeshAtLevel(-1,m1)
namesCellL0=DataArrayAsciiChar(6,16)
- namesCellL0[:]=["CellL0#%.3d "%(i) for i in xrange(6)]
+ namesCellL0[:] = ["CellL0#%.3d " % (i) for i in range(6)]
mm.setNameFieldAtLevel(0,namesCellL0)
- namesCellL1=DataArrayAsciiChar.Aggregate([namesCellL0,namesCellL0,namesCellL0.substr(2)])
- namesCellL1[:]=["CellLM1#%.3d "%(i) for i in xrange(16)]
+ namesCellL1=DataArrayAsciiChar.Aggregate([namesCellL0,namesCellL0,namesCellL0.subArray(2)])
+ namesCellL1[:] = ["CellLM1#%.3d " % (i) for i in range(16)]
mm.setNameFieldAtLevel(-1,namesCellL1)
- namesNodes=namesCellL1.substr(4,16)
- namesNodes[:]=["Node#%.3d "%(i) for i in xrange(12)]
+ namesNodes=namesCellL1.subArray(4,16)
+ namesNodes[:] = ["Node#%.3d " % (i) for i in range(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.getNameFieldAtLevel(0).isEqual(DataArrayAsciiChar(["CellL0#%.3d " % (i) for i in range(6)])))
+ self.assertTrue(mm.getNameFieldAtLevel(-1).isEqual(DataArrayAsciiChar(["CellLM1#%.3d " % (i) for i in range(16)])))
+ self.assertTrue(mm.getNameFieldAtLevel(1).isEqual(DataArrayAsciiChar(["Node#%.3d " % (i) for i in range(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()
+ mmCpy=mm.deepCopy()
self.assertTrue(mm.isEqual(mmCpy,1e-12)[0])
# remove names on nodes
mmCpy.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.assertTrue(mmr.getNameFieldAtLevel(0).isEqual(DataArrayAsciiChar(["CellL0#%.3d " % (i) for i in range(6)])))
self.assertEqual(mmr.getNameFieldAtLevel(-1),None)
#
c=MEDCouplingCMesh()
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.setNameFieldAtLevel(0, DataArrayAsciiChar(["Cell#%.3d " % (i) for i in range(4)]))
+ cc.setNameFieldAtLevel(1, DataArrayAsciiChar(["Node#%.3d " % (i) for i in range(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(ccr.getNameFieldAtLevel(0).isEqual(DataArrayAsciiChar(["Cell#%.3d " % (i) for i in range(4)])))
+ self.assertTrue(ccr.getNameFieldAtLevel(1).isEqual(DataArrayAsciiChar(["Node#%.3d " % (i) for i in range(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()
+ ccCpy=cc.deepCopy()
self.assertTrue(cc.isEqual(ccCpy,1e-12)[0])
pass
c2.transformWithIndArr(whichGrp)
splitOfM1=len(grps)*[None]
for grpId,grp in enumerate(grps):
- tmp=c2.getIdsEqual(grpId)
+ tmp=c2.findIdsEqual(grpId)
splitOfM1[grpId]=tmp
pass
splitOfM1[0].isEqual(DataArrayInt([0,1,2,3,6,8,10,11,12,13]))
m.setFamilyFieldArr(-2,f0)
m.setFamilyFieldArr(1,p)
nbOfFams=len(fns)
- for i in xrange(nbOfFams):
+ for i in range(nbOfFams):
m.addFamily(fns[i],fids[i])
pass
nbOfGrps=len(grpns)
- for i in xrange(nbOfGrps):
+ for i in range(nbOfGrps):
m.setFamiliesIdsOnGroup(grpns[i],famIdsPerGrp[i])
pass
m.setName(m2.getName())
#
mm0=MEDFileMesh.New(fileName)
mm1=MEDFileMesh.New(fileName)
- groupNamesIni=MEDLoader.GetMeshGroupsNames(fileName,"ma")
+ groupNamesIni=GetMeshGroupsNames(fileName,"ma")
for name in groupNamesIni:
mm1.changeGroupName(name,name+'N')
pass
def testInt32InMEDFileFieldStar1(self):
fname="Pyfile63.med"
f1=MEDLoaderDataForTest.buildVecFieldOnCells_1();
- arr=f1.getArray().convertToIntArr()
- f1.setArray(None)
+ f1=f1.convertToIntField()
m1=f1.getMesh()
mm1=MEDFileUMesh.New()
mm1.setCoords(m1.getCoords())
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.setFieldNoProfileSBT(f1)
+ a=ff1.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertEqual(a.getArray().getInfoOnComponents(),['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ self.assertTrue(a.isEqual(f1,1e-12,0))
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))
+ a=ff1.getFieldOnMeshAtLevel(ON_CELLS,0,mm1)
+ self.assertEqual(a.getArray().getInfoOnComponents(),['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ self.assertTrue(a.isEqual(f1,1e-12,0))
ff2.setTime(1,2,3.)
c=ff2.getUndergroundDataArray() ; c*=2
ff2.write(fname,0) # 2 time steps in
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))
+ a=ffs1[2.].getFieldOnMeshAtLevel(ON_CELLS,0,mm1)
+ self.assertTrue(a.isEqual(f1,1e-12,0))
+ a=ffs1.getFieldOnMeshAtLevel(ON_CELLS,0,1,0,mm1)
+ self.assertTrue(a.isEqual(f1,1e-12,0))
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))
+ a=ff2bis.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertTrue(a.getArray().isEqual(2*f1.getArray()))
+ f1.setTime(3.,1,2) ; f1.getArray()[:]*=2
+ self.assertTrue(a.isEqual(f1,1e-12,0)) ; f1.getArray()[:]/=2
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
+ a=it.getFieldOnMeshAtLevel(ON_CELLS,0,mm1)
+ bc+=a.getArray()
pass
- self.assertTrue(bc.isEqual(3*arr))
- nf1=MEDCouplingFieldDouble(ON_NODES)
+ self.assertTrue(bc.isEqual(3*f1.getArray()))
+ nf1=MEDCouplingFieldInt(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")
+ narr=DataArrayInt(12,2) ; narr.setInfoOnComponents(["aa [u1]","bbbvv [ppp]"]) ; narr[:,0]=list(range(12)) ; narr[:,1]=2*narr[:,0]
+ nf1.setName("VectorFieldOnNodes") ; nf1.setArray(narr)
nff1=MEDFileIntField1TS.New()
- nff1.setFieldNoProfileSBT(nf1,narr)
+ nff1.setFieldNoProfileSBT(nf1)
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=MEDCouplingFieldInt(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())
+ narr2=DataArrayInt(8,2) ; narr.setInfoOnComponents(["aapfl [u1]","bbbvvpfl [ppp]"]) ; narr2[:,0]=list(range(8)) ; narr2[:,0]+=10 ; narr2[:,1]=3*narr2[:,0]
+ nf2.setName("VectorFieldOnNodesPfl") ; narr2.setName(nf2.getName()) ; nf2.setArray(narr2)
nff2=MEDFileIntField1TS.New()
npfl=DataArrayInt([1,2,4,5,6,7,10,11]) ; npfl.setName("npfl")
- nff2.setFieldProfile(nf2,narr2,mm1,0,npfl)
+ nff2.setFieldProfile(nf2,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(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["VectorFieldOnCells"][0].getUndergroundDataArray().isEqualWithoutConsideringStr(f1.getArray()))
+ self.assertTrue(fs["VectorFieldOnCells"][1,2].getUndergroundDataArray().isEqualWithoutConsideringStr(2*f1.getArray()))
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))
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]
+ arr=DataArrayDouble(12,2) ; arr.setInfoOnComponents(["aa [u1]","bbbvv [ppp]"]) ; arr[:,0]=list(range(12)) ; arr[:,1]=2*arr[:,0]
f1.setArray(arr)
f1.setName("Field1")
ff1=MEDFileField1TS.New()
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)]
+ tris = [tri.deepCopy() for i in range(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)]
+ quads = [quad.deepCopy() for i in range(5)]
for i,elt in enumerate(quads): elt.translate([5+i,0])
quads=MEDCouplingUMesh.MergeUMeshes(quads)
m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
fmts0_0=MEDFileFieldMultiTS()
fmts0_1=MEDFileFieldMultiTS()
# time steps
- for i in xrange(10):
+ for i in range(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)
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_2=fmts0_0.deepCopy()
+ fmts0_3=fmts0_0.deepCopy()
+ fmts0_4=fmts0_0.deepCopy()
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]
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)]
+ tris = [tri.deepCopy() for i in range(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)]
+ quads = [quad.deepCopy() for i in range(5)]
for i,elt in enumerate(quads): elt.translate([5+i,0])
quads=MEDCouplingUMesh.MergeUMeshes(quads)
m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
fmts0_0=MEDFileFieldMultiTS()
fmts0_1=MEDFileFieldMultiTS()
# time steps
- for i in xrange(10):
+ for i in range(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)
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()
+ fmts0_2=fmts0_0.deepCopy()
+ fmts0_3=fmts0_0.deepCopy()
+ fmts0_4=fmts0_0.deepCopy()
fs0=MEDFileFields()
fs0.pushField(fmts0_0)
fmts0_2.setName("2ndField") ; fs0.pushField(fmts0_2)
self.assertEqual(fs0.getPfls(),('pfl_NORM_QUAD4',))
#
fmts0_5=MEDFileFieldMultiTS()
- for i in xrange(7):
+ for i in range(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)
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)]
+ tris = [tri.deepCopy() for i in range(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)]
+ quads = [quad.deepCopy() for i in range(5)]
for i,elt in enumerate(quads): elt.translate([5+i,0])
quads=MEDCouplingUMesh.MergeUMeshes(quads)
m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
fmts0_1=MEDFileFieldMultiTS()
# time steps
infos1=['aa [bb]','ccc [ddd]',"ZZZZ [MW*s]"]
- for i in xrange(10):
+ for i in range(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)
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 i in range(10):
for j,fieldName in enumerate(['1stField_aa','1stField_ccc','1stField_ZZZZ']):
f1ts=fs1[fieldName][i]
f=f1ts.getFieldOnMeshAtLevel(ON_CELLS,0,mm)
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)]
+ tris = [tri.deepCopy() for i in range(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)]
+ quads = [quad.deepCopy() for i in range(5)]
for i,elt in enumerate(quads): elt.translate([5+i,0])
quads=MEDCouplingUMesh.MergeUMeshes(quads)
m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
#
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()
+ f0.checkConsistencyLight()
ff0.setFieldNoProfileSBT(f0)
#
fspExp=[(3,[(0,(0,4),'','')]),(4,[(0,(4,9),'','')])]
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()
+ f0.checkConsistencyLight()
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','')])]
## 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()
+ f0.checkConsistencyLight()
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()
+ f0.checkConsistencyLight()
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()
+ f0.checkConsistencyLight()
ff0.appendFieldProfile(f0,mm,0,pfl)
ff1=ff0.convertToInt()
self.assertTrue(isinstance(ff1,MEDFileIntFieldMultiTS))
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(30)]
+ tris = [tri.deepCopy() for i in range(30)]
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(40)]
+ quads = [quad.deepCopy() for i in range(40)]
for i,elt in enumerate(quads): elt.translate([40+i,0])
quads=MEDCouplingUMesh.MergeUMeshes(quads)
m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
#
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()
+ f0.checkConsistencyLight()
ff0.setFieldNoProfileSBT(f0)
ff0.write(fname,0)
#
# With profiles
ff0=MEDFileField1TS()
f0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f0.setMesh(m[:50]) ; arr=DataArrayDouble(50*2) ; arr.iota() ; arr.rearrange(2) ; arr.setInfoOnComponents(["XX [pm]","YYY [hm]"]) ; f0.setArray(arr) ; f0.setName("FieldCellPfl")
- f0.checkCoherency()
+ f0.checkConsistencyLight()
pfl=DataArrayInt.Range(0,50,1) ; pfl.setName("pfl")
ff0.setFieldProfile(f0,mm,0,pfl)
fspExp=[(3,[(0,(0,30),'','')]),(4,[(0,(30,50),'pfl_NORM_QUAD4','')])]
self.assertTrue(not ff0.getUndergroundDataArray().isAllocated())
self.assertEqual(ff0.getUndergroundDataArray().getInfoOnComponents(),['X [km]','YY [mm]'])
heap_memory_ref=ff0.getHeapMemorySize()
- self.assertIn(heap_memory_ref,xrange(182,298+2*strMulFac))
+ self.assertIn(heap_memory_ref, list(range(182, 540 + 2 * strMulFac)))
ff0.loadArrays() ##
arr=DataArrayDouble(140) ; arr.iota() ; arr.rearrange(2)
self.assertTrue(ff0.getUndergroundDataArray().isEqualWithoutConsideringStr(arr,1e-14))
ff0=MEDFileField1TS(fname,"FieldCellPfl",False)
self.assertEqual(ff0.getUndergroundDataArray().getInfoOnComponents(),["XX [pm]","YYY [hm]"])
heap_memory_ref=ff0.getHeapMemorySize()
- self.assertIn(heap_memory_ref,xrange(350,415+6*strMulFac))
+ self.assertIn(heap_memory_ref, list(range(350, 600 + 6 * strMulFac)))
ff0.loadArrays() ##
arr=DataArrayDouble(100) ; arr.iota() ; arr.rearrange(2)
self.assertTrue(ff0.getUndergroundDataArray().isEqualWithoutConsideringStr(arr,1e-14))
self.assertEqual(ff0.getUndergroundDataArray().getIJ(30,1),5.5)
self.assertTrue(not ff0.getUndergroundDataArray().isEqualWithoutConsideringStr(arr,1e-14))
heap_memory_ref=ff0.getHeapMemorySize()
- self.assertIn(heap_memory_ref,xrange(1100,1215+2*strMulFac))
+ self.assertIn(heap_memory_ref, list(range(1100, 1400 + 2 * strMulFac)))
ff0.unloadArrays()
hmd=ff0.getHeapMemorySize()-heap_memory_ref
self.assertEqual(hmd,-800) # -50*8*2
#
ff0=MEDFileField1TS(fname,"FieldCellPfl",-1,-1,False)
heap_memory_ref=ff0.getHeapMemorySize()
- self.assertIn(heap_memory_ref,xrange(299,415+6*strMulFac))
+ self.assertIn(heap_memory_ref, list(range(299, 620 + 6 * strMulFac)))
ff0.loadArrays() ##
self.assertTrue(ff0.getUndergroundDataArray().isEqualWithoutConsideringStr(arr,1e-14))
self.assertEqual(ff0.getHeapMemorySize()-heap_memory_ref,50*8*2)
#
fieldName="FieldCellMultiTS"
ff0=MEDFileFieldMultiTS()
- for t in xrange(20):
+ for t in range(20):
f0=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f0.setMesh(m) ; arr=DataArrayDouble(m.getNumberOfCells()*2) ; arr.iota(float(t+1000)) ; arr.rearrange(2) ; arr.setInfoOnComponents(["X [km]","YY [mm]"]) ; f0.setArray(arr) ; f0.setName(fieldName)
f0.setTime(float(t)+0.1,t,100+t)
- f0.checkCoherency()
+ f0.checkConsistencyLight()
ff0.appendFieldNoProfileSBT(f0)
pass
ff0.write(fname,0)
#
ff0=MEDFileAnyTypeFieldMultiTS.New(fname,fieldName,False)
heap_memory_ref=ff0.getHeapMemorySize()
- self.assertIn(heap_memory_ref,xrange(5536,5956+(80+26)*strMulFac))
+ self.assertIn(heap_memory_ref, list(range(5536, 9212 + (80 + 26 + 1) * strMulFac)))
ff0.loadArrays()
self.assertEqual(ff0.getHeapMemorySize()-heap_memory_ref,20*70*8*2)
del ff0
#
ffs=MEDFileFields(fname,False)
heap_memory_ref=ffs.getHeapMemorySize()
- self.assertIn(heap_memory_ref,xrange(5335,6687+(80+50)*strMulFac))
+ self.assertIn(heap_memory_ref, list(range(5335, 10031 + (80 + 50 + len(ffs)) * strMulFac)))
ffs.loadArrays()
self.assertEqual(ffs.getHeapMemorySize()-heap_memory_ref,20*70*8*2+70*8*2+50*8*2)
pass
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)]
+ tris = [tri.deepCopy() for i in range(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)]
+ quads = [quad.deepCopy() for i in range(5)]
for i,elt in enumerate(quads): elt.translate([5+i,0])
quads=MEDCouplingUMesh.MergeUMeshes(quads)
m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
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)]
+ tris = [tri.deepCopy() for i in range(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)]
+ quads = [quad.deepCopy() for i in range(5)]
for i,elt in enumerate(quads): elt.translate([5+i,0])
quads=MEDCouplingUMesh.MergeUMeshes(quads)
m=MEDCouplingUMesh.MergeUMeshes(tris,quads)
m00=MEDCouplingUMesh("mesh",1) ; m00.setCoords(m0.getCoords()) ; m00.allocateCells(0)
m=MEDFileUMesh()
m.setMeshAtLevel(0,m00)
- m.setRenumFieldArr(1,DataArrayInt(range(10,26)))
+ m.setRenumFieldArr(1,DataArrayInt(list(range(10,26))))
m.setFamilyFieldArr(1,DataArrayInt([-1,-1,-1,-1,-1,-2,-2,-2,-2,-2,-2,0,-1,-3,-3,-3]))
m.write(fname,2)
del m,a,c,m0,m00
m=MEDFileMesh.New(fname)
self.assertEqual((),m.getNonEmptyLevels())
self.assertTrue(m.getCoords().isEqual(DataArrayDouble([(0,0),(1,0),(2,0),(3,0),(0,1),(1,1),(2,1),(3,1),(0,2),(1,2),(2,2),(3,2),(0,3),(1,3),(2,3),(3,3)]),1e-12))
- self.assertTrue(m.getNumberFieldAtLevel(1).isEqual(DataArrayInt(range(10,26))))
+ self.assertTrue(m.getNumberFieldAtLevel(1).isEqual(DataArrayInt(list(range(10,26)))))
self.assertTrue(m.getFamilyFieldAtLevel(1).isEqual(DataArrayInt([-1,-1,-1,-1,-1,-2,-2,-2,-2,-2,-2,0,-1,-3,-3,-3])))
pass
m.insertNextCell([0,2,1,3])
m.setCoords(DataArrayDouble([0.,0.,1.,1.,1.,0.,0.,1.],4,2))
#
- ms=[m.deepCpy() for i in xrange(4)]
+ ms = [m.deepCopy() for i in range(4)]
for i,elt in enumerate(ms):
elt.translate([float(i)*1.5,0.])
pass
m0=MEDCoupling1SGTUMesh.Merge1SGTUMeshes(ms).buildUnstructured()
m0.convertAllToPoly()
#
- ms=[m.deepCpy() for i in xrange(5)]
+ ms = [m.deepCopy() for i in range(5)]
for i,elt in enumerate(ms):
elt.translate([float(i)*1.5,1.5])
pass
arr0=DataArrayDouble(9) ; arr0.iota()
arr1=DataArrayDouble(9) ; arr1.iota(100)
arr=DataArrayDouble.Meld(arr0,arr1) ; arr.setInfoOnComponents(["mm [kg]","sds [m]"])
- f.setArray(arr) ; f.checkCoherency()
+ f.setArray(arr) ; f.checkConsistencyLight()
f.setTime(5.6,1,2)
ff=MEDFileField1TS()
ff.setFieldNoProfileSBT(f)
for elt in [[0,1,2,3,4,5],[1,2,3,4,5,6],[2,3,4,5,6,7],[3,4,5,6,7,8]]:#4
m0.insertNextCell(NORM_PENTA6,elt)
pass
- m0.checkCoherency2()
+ m0.checkConsistency()
m1=MEDCouplingUMesh(); m1.setName("mesh")
m1.setMeshDimension(2);
m1.allocateCells(5);
#
fmts=MEDFileFieldMultiTS()
#
- for i in xrange(nbCells):
+ for i in range(nbCells):
t=(float(i)+0.1,i+1,-i-2)
f.setTime(*t)
arr2=DataArrayDouble(nbCells)
m.changeSpaceDimension(3,0.)
infos=["aa [b]","cc [de]","gg [klm]"]
m.getCoords().setInfoOnComponents(infos)
- m.checkCoherency2()
+ m.checkConsistency()
mm=MEDFileUMesh()
mm.setMeshAtLevel(0,m)
m1=MEDCouplingCMesh() ; m1.setCoords(arr) ; m1.setName("Mesh")
renum0=DataArrayInt([3,6,7,10,11,0,2,1,9,8,5,4,12,13,14,24,23,22,21,20,19,18,17,16,15])
famField0=DataArrayInt([-3,-6,-7,-10,-11,0,-2,-1,-9,-8,-5,-4,-12,-13,-14,-24,-23,-22,-21,-20,-19,-18,-17,-16,-15])
namesCellL0=DataArrayAsciiChar(25,16)
- namesCellL0[:]=["Cell#%.3d "%(i) for i in xrange(25)]
+ namesCellL0[:] = ["Cell#%.3d " % (i) for i in range(25)]
renumM1=DataArrayInt([3,4,0,2,1])
famFieldM1=DataArrayInt([-3,-4,0,-2,-1])
mm.setRenumFieldArr(0,renum0)
renum1=DataArrayInt([13,16,17,20,21,10,12,11,19,18,15,14,22,23,24,34,33,32,31,30,29,28,27,26,25,45,44,43,42,41,40,39,38,37,36,35])
famField1=DataArrayInt([-13,-16,-17,-20,-21,-10,-12,-11,-19,-18,-15,-14,-22,-23,-24,-34,-33,-32,-31,-30,-29,-28,-27,-26,-25,-45,-44,-43,-42,-41,-40,-39,-38,-37,-36,-35])
namesNodes=DataArrayAsciiChar(36,16)
- namesNodes[:]=["Node#%.3d "%(i) for i in xrange(36)]
+ namesNodes[:] = ["Node#%.3d " % (i) for i in range(36)]
mm.setRenumFieldArr(1,renum1)
mm.setFamilyFieldArr(1,famField1)
mm.setNameFieldAtLevel(1,namesNodes)
m.changeSpaceDimension(3,0.)
infos=["aa [b]","cc [de]","gg [klm]"]
m.getCoords().setInfoOnComponents(infos)
- m.checkCoherency2()
+ m.checkConsistency()
f=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f.setMesh(m)
f.setName("Field")
arr=DataArrayDouble(25,2) ; arr.setInfoOnComponents(compos)
- arr[:,0]=range(25)
- arr[:,1]=range(100,125)
+ arr[:,0]=list(range(25))
+ arr[:,1]=list(range(100,125))
f.setArray(arr)
- MEDLoader.WriteField(fileName,f,2)
+ WriteField(fileName,f,True)
f=MEDCouplingFieldDouble(ON_NODES,ONE_TIME) ; f.setMesh(m)
f.setName("FieldNode")
arr=DataArrayDouble(36,2) ; arr.setInfoOnComponents(compos)
- arr[:,0]=range(200,236)
- arr[:,1]=range(300,336)
+ arr[:,0]=list(range(200,236))
+ arr[:,1]=list(range(300,336))
f.setArray(arr)
- f.checkCoherency()
- MEDLoader.WriteFieldUsingAlreadyWrittenMesh(fileName,f)
+ f.checkConsistencyLight()
+ WriteFieldUsingAlreadyWrittenMesh(fileName,f)
#
ms=MEDFileMeshes()
mm=MEDFileUMesh.LoadPartOf(fileName,meshName,[NORM_QUAD4],[0,6,1])
mm=MEDFileUMesh.LoadPartOf(fileName,meshName,[NORM_QUAD4],[3,15,1])
ms.pushMesh(mm)
fs=MEDFileFields.LoadPartOf(fileName,False,ms)
- fs=fs.deepCpy()
+ fs=fs.deepCopy()
fs[0][0].loadArrays()
- arr=DataArrayDouble(12,2) ; arr[:,0]=range(3,15) ; arr[:,1]=range(103,115)
+ arr = DataArrayDouble(12, 2) ; arr[:, 0] = list(range(3, 15)) ; arr[:, 1] = list(range(103, 115))
arr.setInfoOnComponents(compos)
self.assertTrue(fs[0][0].getUndergroundDataArray().isEqual(arr,1e-12))
fs[1][0].loadArrays()
- arr=DataArrayDouble(21,2) ; arr[:,0]=range(203,224) ; arr[:,1]=range(303,324)
+ arr = DataArrayDouble(21, 2) ; arr[:, 0] = list(range(203, 224)) ; arr[:, 1] = list(range(303, 324))
arr.setInfoOnComponents(compos)
self.assertTrue(fs[1][0].getUndergroundDataArray().isEqual(arr,1e-12))
pass
m.changeSpaceDimension(3,0.)
infos=["aa [b]","cc [de]","gg [klm]"]
m.getCoords().setInfoOnComponents(infos)
- m.checkCoherency2()
+ m.checkConsistency()
f=MEDCouplingFieldDouble(ON_CELLS,ONE_TIME) ; f.setMesh(m)
f.setName("Field")
arr=DataArrayDouble(25,2) ; arr.setInfoOnComponents(compos)
- arr[:,0]=range(25)
- arr[:,1]=range(100,125)
+ arr[:,0]=list(range(25))
+ arr[:,1]=list(range(100,125))
f.setArray(arr)
- MEDLoader.WriteField(fileName,f,2)
+ WriteField(fileName,f,True)
f=MEDCouplingFieldDouble(ON_NODES,ONE_TIME) ; f.setMesh(m)
f.setName("FieldNode")
arr=DataArrayDouble(36,2) ; arr.setInfoOnComponents(compos)
- arr[:,0]=range(200,236)
- arr[:,1]=range(300,336)
+ arr[:,0]=list(range(200,236))
+ arr[:,1]=list(range(300,336))
f.setArray(arr)
- f.checkCoherency()
- MEDLoader.WriteFieldUsingAlreadyWrittenMesh(fileName,f)
+ f.checkConsistencyLight()
+ WriteFieldUsingAlreadyWrittenMesh(fileName,f)
#
ms=MEDFileMeshes()
mm=MEDFileUMesh.LoadPartOf(fileName,meshName,[NORM_QUAD4],[4,6,1])
m=MEDCouplingUMesh.MergeUMeshesOnSameCoords([m0,m1])
m.setName(meshName2D)
mMinus1,a,b,c,d=m.buildDescendingConnectivity()
- e=d.deltaShiftIndex().getIdsEqual(1)
+ e=d.deltaShiftIndex().findIdsEqual(1)
#
mm=MEDFileUMesh()
mm.setMeshAtLevel(0,m) ; mm.setMeshAtLevel(-1,mMinus1)
@unittest.skipUnless(MEDCouplingHasNumPyBindings(),"requires numpy")
def testMEDFileUMeshPickeling1(self):
- import cPickle
outFileName="Pyfile86.med"
c=DataArrayDouble([-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 ],9,2)
c.setInfoOnComponents(["aa","bbb"])
m.insertNextCell(NORM_POLYGON,4,targetConn[14:18])
m.finishInsertingCells();
m.setCoords(c)
- m.checkCoherency()
+ m.checkConsistencyLight()
m1=MEDCouplingUMesh.New();
m1.setMeshDimension(1);
m1.allocateCells(3);
m1.insertNextCell(NORM_SEG3,3,[2,8,5])
m1.finishInsertingCells();
m1.setCoords(c)
- m1.checkCoherency()
+ m1.checkConsistencyLight()
m2=MEDCouplingUMesh.New();
m2.setMeshDimension(0);
m2.allocateCells(4);
m2.insertNextCell(NORM_POINT1,1,[6])
m2.finishInsertingCells();
m2.setCoords(c)
- m2.checkCoherency()
+ m2.checkConsistencyLight()
#
mm=MEDFileUMesh.New()
self.assertTrue(mm.getUnivNameWrStatus())
g2_1.setName("G2")
mm.setGroupsAtLevel(-1,[g1_1,g2_1],False)
g1_N=DataArrayInt.New()
- g1_N.setValues(range(8),8,1)
+ g1_N.setValues(list(range(8)),8,1)
g1_N.setName("G1")
g2_N=DataArrayInt.New()
- g2_N.setValues(range(9),9,1)
+ g2_N.setValues(list(range(9)),9,1)
g2_N.setName("G2")
mm.setGroupsAtLevel(1,[g1_N,g2_N],False)
mm.createGroupOnAll(0,"GrpOnAllCell")
self.assertTrue(mm.existsGroup("GrpOnAllCell"));
t=mm.getGroupArr(0,"GrpOnAllCell")
#
- st=cPickle.dumps(mm,cPickle.HIGHEST_PROTOCOL)
- mm2=cPickle.loads(st)
+ st=pickle.dumps(mm,pickle.HIGHEST_PROTOCOL)
+ mm2=pickle.loads(st)
+ self.assertTrue(mm.isEqual(mm2,1e-12)[0])
+ self.assertEqual(mm.getAxisType(),AX_CART)
+ #
+ mm.setAxisType(AX_CYL)
+ st=pickle.dumps(mm,pickle.HIGHEST_PROTOCOL)
+ mm2=pickle.loads(st)
self.assertTrue(mm.isEqual(mm2,1e-12)[0])
+ self.assertEqual(mm2.getAxisType(),AX_CYL)
pass
def testMEDFileFieldsLoadSpecificEntities1(self):
m.setName(meshName)
#
fmts=MEDFileFieldMultiTS()
- for i in xrange(nbPdt):
+ for i in range(nbPdt):
f=MEDCouplingFieldDouble(ON_NODES)
f.setMesh(m)
arr=DataArrayDouble(nbNodes) ; arr.iota() ; arr*=i
fs2=MEDFileFields.LoadSpecificEntities(fileName,[(ON_NODES,NORM_ERROR)],False)
fs.loadArraysIfNecessary()
fs2.loadArraysIfNecessary()
- for i in xrange(nbPdt):
+ for i in range(nbPdt):
self.assertTrue(fs[fieldName][i].getUndergroundDataArray().isEqual(fs2[fieldName][i].getUndergroundDataArray(),1e-12))
pass
m1=MEDCouplingCMesh() ; m1.setCoords(DataArrayDouble([0,1,2,3]),DataArrayDouble([0,1])) ; m1=m1.buildUnstructured() ; m1.simplexize(0)
m2=MEDCouplingCMesh() ; m2.setCoords(DataArrayDouble([3,4,5]),DataArrayDouble([0,1])) ; m2=m2.buildUnstructured()
m3=MEDCouplingUMesh.MergeUMeshes(m1,m2) ; m3.setName(meshName)
fmts=MEDFileFieldMultiTS()
- for i in xrange(nbPdt):
+ for i in range(nbPdt):
f=MEDCouplingFieldDouble(ON_CELLS)
f.setMesh(m3)
arr=DataArrayDouble(8) ; arr.iota() ; arr*=i
fs2.loadArraysIfNecessary()
fs3.loadArraysIfNecessary()
fs4.loadArraysIfNecessary()
- for i in xrange(nbPdt):
+ for i in range(nbPdt):
self.assertTrue(fs[fieldName][i].getUndergroundDataArray()[:6].isEqual(fs2[fieldName][i].getUndergroundDataArray(),1e-12))
self.assertTrue(fs[fieldName][i].getUndergroundDataArray()[6:8].isEqual(fs3[i].getUndergroundDataArray(),1e-12))
self.assertTrue(fs[fieldName][i].getUndergroundDataArray().isEqual(fs4[fieldName][i].getUndergroundDataArray(),1e-12))
m=m.buildUnstructured()
m.setName(meshName)
#
- nbOfField=nbPdt/maxPdt
+ nbOfField=nbPdt//maxPdt
fs=MEDFileFields()
- for j in xrange(nbOfField):
+ for j in range(nbOfField):
fmts=MEDFileFieldMultiTS()
s=DataArray.GetSlice(slice(0,nbPdt,1),j,nbOfField)
- for i in xrange(s.start,s.stop,s.step):
+ for i in range(s.start, s.stop, s.step):
f=MEDCouplingFieldDouble(ON_NODES)
f.setMesh(m)
arr=DataArrayDouble(nbNodes) ; arr.iota() ; arr*=i
d[key]=[val]
pass
import re
- allFields=MEDLoader.GetAllFieldNames(fileName)
+ allFields=GetAllFieldNames(fileName)
allFieldsDict={}
pat=re.compile("([\d]+)([\s\S]+)$")
for st in allFields:
fmts2.reverse()
zeResu=fmts2.pop()
nbIter=len(fmts2)
- for ii in xrange(nbIter):
+ for ii in range(nbIter):
zeResu.pushBackTimeSteps(fmts2.pop())
pass
zeResu.setName(k)
fs2.pushField(zeResu)
pass
- self.assertEqual(fs2[0].getTimeSteps(),[(i,0,float(i)) for i in xrange(nbPdt)])
+ self.assertEqual(fs2[0].getTimeSteps(), [(i, 0, float(i)) for i in range(nbPdt)])
pass
def testMEDFileMeshRearrangeFamIds1(self):
field.setMesh(m)
field.setArray(DataArrayDouble([1.2,2.3,3.4,4.5]))
field.setName("Field")
- field.checkCoherency()
+ field.checkConsistencyLight()
pfl=DataArrayInt([0,1,2,3]) ; pfl.setName("TUTU") #<- false profile because defined on all cells !
ff.setFieldProfile(field,mm,0,pfl) # <- bug was revealed here !
self.assertEqual(ff.getPfls(),())
field.setMesh(m)
field.setArray(DataArrayDouble([1.2,2.3,3.4,4.5]))
field.setName("Field")
- field.checkCoherency()
+ field.checkConsistencyLight()
pfl=DataArrayInt([0,1,2,3]) ; pfl.setName("TUTU")
ff.setFieldProfile(field,mm,0,pfl)
self.assertEqual(ff.getPfls(),())
m3D=m.buildExtrudedMesh(m1D,0)
m3D.sortCellsInMEDFileFrmt()
m3D.setName(meshName)
- m2D=m ; m2D.setCoords(m3D.getCoords()) ; m2D.shiftNodeNumbersInConn(delta) ; m2D.setName(meshName) ; m2D.checkCoherency2()
+ m2D=m ; m2D.setCoords(m3D.getCoords()) ; m2D.shiftNodeNumbersInConn(delta) ; m2D.setName(meshName) ; m2D.checkConsistency()
m1D=m2D.computeSkin() ; m1D.setName(meshName)
+ m0D=MEDCouplingUMesh.Build0DMeshFromCoords(m3D.getCoords()) ; m0D.setName(meshName) ; m0D=m0D[[2,4,10]]
#
mm=MEDFileUMesh()
- mm[0]=m3D ; mm[-1]=m2D ; mm[-2]=m1D
+ mm[0]=m3D ; mm[-1]=m2D ; mm[-2]=m1D ; mm[-3]=m0D
grpEdge0=DataArrayInt([1,2,3,5]) ; grpEdge0.setName("East")
grpEdge1=DataArrayInt([0,1]) ; grpEdge1.setName("Corner1")
grpFaceSouth=DataArrayInt([0,1,8,9,10]) ; grpFaceSouth.setName("SouthFace")
self.assertEqual(mm.getGroupsNames(),('grp0','grp1','grp2','grp3'))
delta=12
for grp in [grp0,grp1,grp2,grp3]:
- grpNode=grp.deepCpy() ; grpNode+=delta ; grpNode.setName("%s_node"%grp.getName())
+ grpNode=grp.deepCopy() ; grpNode+=delta ; grpNode.setName("%s_node"%grp.getName())
mm.addGroup(1,grpNode)
self.assertEqual(mm.getGroupsNames(),('grp0','grp0_node','grp1','grp1_node','grp2','grp2_node','grp3','grp3_node'))
for grp in [grp0,grp1,grp2,grp3]:
def __del__(self):
import os,sys
sys.stderr=self.origPyVal
+ if sys.version_info.major >= 3:
+ self.fdOfSinkFile.close()
+ pass
#os.fsync(self.fdOfSinkFile)
os.fsync(2)
os.dup2(self.stdoutOld,2)
mm.setName("mesh")
mm.write(fname,2)
# third : change permissions to remove write access on created file
- os.chmod(fname,0444)
+ os.chmod(fname, 0o444)
# four : try to append data on file -> check that it raises Exception
f=MEDCouplingFieldDouble(ON_CELLS)
f.setName("field")
f.setMesh(m)
f.setArray(DataArrayDouble(100))
f.getArray()[:]=100.
- f.checkCoherency()
+ f.checkConsistencyLight()
f1ts=MEDFileField1TS()
f1ts.setFieldNoProfileSBT(f)
# redirect stderr
#
pass
+ def testUnivStatus1(self):
+ """ Non regression test to check the effectiveness of univ write status."""
+ fname="Pyfile95.med"
+ arr=DataArrayDouble(10) ; arr.iota()
+ m=MEDCouplingCMesh() ; m.setCoords(arr,arr) ; m.setName("mesh")
+ mm=MEDFileCMesh() ; mm.setMesh(m)
+ mm.setUnivNameWrStatus(False) # test is here
+ mm.write(fname,2)
+ mm=MEDFileCMesh(fname)
+ self.assertEqual(mm.getUnivName(),"")
+ mm.setUnivNameWrStatus(True)
+ mm.write(fname,2)
+ mm=MEDFileCMesh(fname)
+ self.assertTrue(mm.getUnivName()!="")
+ pass
+
+ def testEmptyMesh(self):
+ """ MEDLoader should be able to consistently write and read an empty mesh (coords array
+ with 0 tuples """
+ fname = "Pyfile96.med"
+ m = MEDCouplingUMesh('toto', 2)
+ m.setCoords(DataArrayDouble([], 0, 2))
+ m.setConnectivity(DataArrayInt([]), DataArrayInt([0]))
+ mfu = MEDFileUMesh()
+ mfu.setMeshAtLevel(0, m)
+ mfu.write(fname, 2)
+ mfu2 = MEDFileUMesh(fname)
+ self.assertEqual('toto', mfu2.getName())
+ lvl = mfu2.getNonEmptyLevels()
+ self.assertEqual((), lvl)
+
+ @unittest.skipUnless(MEDCouplingHasNumPyBindings(),"requires numpy")
+ def testMEDFileUMeshPickeling2(self):
+ """ Check that pickalization can be performed on a unpickalized instance. Non regression test."""
+ name="Mesh_1"
+ grpName1="HAUT"
+ grpName2="BASE"
+ hauteur=1.
+ nbOfNodesPerAxis=3
+ arr=DataArrayDouble(nbOfNodesPerAxis) ; arr.iota() ; arr/=(nbOfNodesPerAxis-1) ; arr*=hauteur
+ m=MEDCouplingCMesh() ; m.setCoords(arr,arr,arr) ; m=m.buildUnstructured() ; m.setName(name)
+ mesh=MEDFileUMesh() ; mesh[0]=m
+ m1=m.computeSkin() ; mesh[-1]=m1
+ #
+ bary1=m1.computeCellCenterOfMass()[:,2]
+ grp1=bary1.findIdsInRange(hauteur-1e-12,hauteur+1e-12) ; grp1.setName(grpName1)
+ grp2=bary1.findIdsInRange(0.-1e-12,0.+1e-12) ; grp2.setName(grpName2)
+ mesh.setGroupsAtLevel(-1,[grp1,grp2])
+
+ st=pickle.dumps(mesh,2)
+ mm=pickle.loads(st)
+ st2=pickle.dumps(mm,2)
+ mm2=pickle.loads(st2)
+ self.assertTrue(mesh.isEqual(mm2,1e-12)[0])
+ pass
+
+ def testMEDFileEquivalence1(self):
+ """ First check of equivalence implementation in MEDFileMesh"""
+ fileName="Pyfile97.med"
+ meshName="M_01"
+ mm=MEDFileUMesh()
+ coo=DataArrayDouble([(0,0,0),(6,0,0),(19,0,0),(36,0,0),(0,4,0),(6,4,0),(19,4,0),(36,4,0),(0,13,0),(6,13,0),(19,13,0),(36,13,0),(0,24,0),(6,24,0),(19,24,0),(36,24,0),(0,0,6),(6,0,6),(19,0,6),(36,0,6),(0,4,6),(6,4,6),(19,4,6),(36,4,6),(0,13,6),(6,13,6),(19,13,6),(36,13,6),(0,24,6),(6,24,6),(19,24,6),(36,24,6),(6,0,3),(6,2,0),(12.5,0,0),(19,0,3),(19,2,0),(6,4,3),(12.5,4,0),(19,4,3),(6,2,6),(12.5,0,6),(19,2,6),(12.5,4,6),(6,2,3),(12.5,0,3),(12.5,2,0),(19,2,3),(12.5,4,3),(12.5,2,6),(12.5,2,3)])
+ coo.setInfoOnComponents(["X [Sans_unite]","Y [Sans_unite]","Z [Sans_unite]"])
+ connQ4=DataArrayInt([1,17,21,5,2,18,22,6,21,5,6,22,1,32,44,33,17,40,44,32,21,37,44,40,5,33,44,37,2,35,47,36,18,42,47,35,22,39,47,42,6,36,47,39,21,37,48,43,5,38,48,37,6,39,48,38,22,43,48,39])
+ m1=MEDCoupling1SGTUMesh(meshName,NORM_QUAD4) ; m1.setCoords(coo) ; m1.setNodalConnectivity(connQ4) ; mm[-1]=m1
+ connH8=DataArrayInt([20,16,17,21,4,0,1,5,22,18,19,23,6,2,3,7,24,20,21,25,8,4,5,9,25,21,22,26,9,5,6,10,26,22,23,27,10,6,7,11,28,24,25,29,12,8,9,13,29,25,26,30,13,9,10,14,30,26,27,31,14,10,11,15,21,40,49,43,37,44,50,48,40,17,41,49,44,32,45,50,49,41,18,42,50,45,35,47,43,49,42,22,48,50,47,39,44,32,45,50,33,1,34,46,37,44,50,48,5,33,46,38,48,50,47,39,38,46,36,6,50,45,35,47,46,34,2,36])
+ m0=MEDCoupling1SGTUMesh(meshName,NORM_HEXA8) ; m0.setCoords(coo) ; m0.setNodalConnectivity(connH8) ; mm[0]=m0
+ mm.getFamilyFieldAtLevel(-1)[:]=-2
+ mm.getFamilyFieldAtLevel(0)[:]=0
+ mm.addFamily("HOMARD________-1",-1)
+ mm.addFamily("HOMARD________-2",-2)
+ mm.addFamily("HOMARD________-3",-3)
+ mm.setFamiliesIdsOnGroup("HOMARD",[-1,-2,-3])
+
+ eqName="MAILLES_A_RECOLLER_APRES_HOMARD"
+ descEq="Cette equivalence decrit les mailles a recoller. Dans chaque correspondance, le premier numero est celui de la maille coupee ; le second numero est celui d'une des petites mailles en regard."
+ mm.initializeEquivalences()
+ eqs=mm.getEquivalences()
+ eq0=eqs.appendEmptyEquivalenceWithName(eqName)
+ eq0.setDescription(descEq)
+ corr=DataArrayInt([(0,3),(0,4),(0,5),(0,6),(1,7),(1,8),(1,9),(1,10),(2,11),(2,12),(2,13),(2,14)])
+ eq0.setArray(-1,corr)
+ self.assertEqual(eq0.getCell().size(),1)
+ self.assertTrue(eq0.getCell().getArray(NORM_QUAD4).isEqual(corr))
+ eq0.getCell().clear()
+ self.assertEqual(eq0.getCell().size(),0)
+ eq0.getCell().setArrayForType(NORM_QUAD4,corr)
+ self.assertEqual(eq0.getCell().size(),1)
+ self.assertTrue(eq0.getCell().getArray(NORM_QUAD4).isEqual(corr))
+ mm.killEquivalences()
+ mm.initializeEquivalences()
+ eqs=mm.getEquivalences()
+ eq0=eqs.appendEmptyEquivalenceWithName(eqName)
+ eq0.setDescription(descEq)
+ c=eq0.initCell()
+ c.setArrayForType(NORM_QUAD4,corr)
+ self.assertEqual(eq0.getCell().size(),1)
+ self.assertTrue(eq0.getCell().getArray(NORM_QUAD4).isEqual(corr))
+ mm2=mm.deepCopy()
+ self.assertTrue(mm.isEqual(mm2,1e-12)[0])
+ self.assertEqual(mm2.getEquivalences().size(),1)
+ self.assertTrue(mm2.getEquivalences().getEquivalence(0).getCell().getArray(NORM_QUAD4).isEqual(corr))
+ mm2.getEquivalences().getEquivalence(0).getCell().getArray(NORM_QUAD4)[0,0]=2
+ self.assertTrue(not mm.isEqual(mm2,1e-12)[0])
+ mm2.getEquivalences().getEquivalence(0).getCell().getArray(NORM_QUAD4)[0,0]=0
+ self.assertTrue(mm.isEqual(mm2,1e-12)[0])
+ mm.write(fileName,2)
+ #
+ mm3=MEDFileMesh.New(fileName)
+ self.assertTrue(mm.isEqual(mm3,1e-12)[0])
+ pass
+
+ def testMEDFileForFamiliesPlayer1(self):
+ """Non regression bug EDF11911. For serial killers using same family name to store both cells and nodes ! Only sky is the limit."""
+ fileName="Pyfile98.med"
+ meshName="mesh"
+ magicSt="%s%%04i"%(MEDFileMesh.GetMagicFamilyStr())
+ arr=DataArrayDouble(4) ; arr.iota()
+ m=MEDCouplingCMesh() ; m.setCoords(arr,arr)
+ m=m.buildUnstructured()
+ mm=MEDFileUMesh()
+ mm[0]=m
+ mm.setName(meshName)
+ mm.setFamilyId("FAMILLE_ZERO",0)
+ mm.getFamilyFieldAtLevel(0)[-3:]=-4
+ mm.setFamilyId("RIDF%s"%(magicSt%0),-4)
+ mm.setGroupsOnFamily("RIDF%s"%(magicSt%0),["RID"])
+ d=DataArrayInt(16) ; d[:]=0 ; d[[1,2,4,5]]=3
+ mm.setFamilyFieldArr(1,d)
+ mm.setFamilyId("RIDF%s"%(magicSt%1),3)
+ mm.setGroupsOnFamily("RIDF%s"%(magicSt%1),["RID"])
+ self.assertEqual(mm.getFamiliesNames(),("FAMILLE_ZERO",'RIDF!/__\\!0000','RIDF!/__\\!0001'))
+ self.assertEqual(mm.getFamiliesNamesWithFilePointOfView(),("FAMILLE_ZERO","RIDF","RIDF")) # <- the aim of test is here !
+ self.assertEqual(mm.getFamiliesIdsOnGroup("RID"),(-4,3))
+ mm.write(fileName,2)
+ # now read such funny file !
+ mm2=MEDFileMesh.New(fileName) # <- normaly mdump of Pyfile98.med must contain only RID and FAMILLE_ZERO families.
+ self.assertTrue(mm.isEqual(mm2,1e-16))
+ self.assertEqual(mm2.getFamiliesNames(),("FAMILLE_ZERO",'RIDF!/__\\!0000','RIDF!/__\\!0001'))
+ self.assertEqual(mm2.getFamiliesNamesWithFilePointOfView(),("FAMILLE_ZERO","RIDF","RIDF"))
+ self.assertEqual(mm2.getFamiliesIdsOnGroup("RID"),(-4,3))# <- very important too !
+ pass
+
+ def testCartesianizer1(self):
+ """ This test is advanced to be sure that no unnecessary copies had been made during cartesianization process. """
+ # UMesh non cart
+ arr=DataArrayDouble(4) ; arr.iota() ; m=MEDCouplingCMesh() ; m.setCoords(arr,arr) ; m=m.buildUnstructured()
+ mm=MEDFileUMesh() ; mm[0]=m ; mm.forceComputationOfParts()
+ d0=DataArrayInt(16) ; d0[:]=0
+ d1=DataArrayInt(9) ; d1[:]=0
+ mm.setFamilyFieldArr(0,d1) ; mm.setFamilyFieldArr(1,d0)
+ mm.setName("a") ; mm.setDescription("b") ; mm.setTime(3,4,5.) ; mm.addFamily("c",-4) ; mm.setFamiliesOnGroup("d",["c"]) ; mm.setTimeUnit("ms")
+ ref0=mm.getCoords().getHiddenCppPointer()
+ ref1=mm[0].getNodalConnectivity().getHiddenCppPointer()
+ self.assertEqual(ref0,mm[0].getCoords().getHiddenCppPointer())
+ ref2=mm[0].getNodalConnectivityIndex().getHiddenCppPointer()
+ ref3=mm.getDirectUndergroundSingleGeoTypeMesh(NORM_QUAD4).getNodalConnectivity().getHiddenCppPointer()
+ self.assertEqual(ref0,mm.getDirectUndergroundSingleGeoTypeMesh(NORM_QUAD4).getCoords().getHiddenCppPointer())
+ mm.setAxisType(AX_CYL) #<- important
+ mm2=mm.cartesianize() # the trigger
+ self.assertEqual(mm2.getAxisType(),AX_CART)
+ mm.setAxisType(AX_CART) # this is here only to avoid complaints
+ self.assertTrue(isinstance(mm2,MEDFileUMesh))
+ self.assertTrue(mm.getHiddenCppPointer()!=mm2.getHiddenCppPointer())
+ self.assertTrue(ref0==mm.getCoords().getHiddenCppPointer()) # <- here important
+ self.assertTrue(ref0!=mm2.getCoords().getHiddenCppPointer()) # <- here important
+ self.assertEqual(mm2.getCoords().getHiddenCppPointer(),mm2[0].getCoords().getHiddenCppPointer())
+ self.assertEqual(mm2.getCoords().getHiddenCppPointer(),mm2.getDirectUndergroundSingleGeoTypeMesh(NORM_QUAD4).getCoords().getHiddenCppPointer())
+ self.assertEqual(mm2[0].getNodalConnectivity().getHiddenCppPointer(),ref1) # <- here very important
+ self.assertEqual(mm2[0].getNodalConnectivityIndex().getHiddenCppPointer(),ref2) # <- here very important
+ self.assertEqual(mm2.getDirectUndergroundSingleGeoTypeMesh(NORM_QUAD4).getNodalConnectivity().getHiddenCppPointer(),ref3) # <- here very important
+ self.assertEqual(mm2.getName(),mm.getName())
+ self.assertEqual(mm2.getDescription(),mm.getDescription())
+ self.assertEqual(mm2.getTime(),mm.getTime())
+ self.assertEqual(mm2.getTime(),mm.getTime())
+ self.assertEqual(mm2.getTimeUnit(),mm.getTimeUnit())
+ self.assertEqual(mm2.getGroupsNames(),mm.getGroupsNames())
+ self.assertEqual(mm2.getFamiliesNames(),mm.getFamiliesNames())
+ self.assertEqual([mm2.getFamilyId(elt) for elt in mm2.getFamiliesNames()],[mm.getFamilyId(elt2) for elt2 in mm.getFamiliesNames()])
+ self.assertEqual(mm.getFamilyFieldAtLevel(0).getHiddenCppPointer(),d1.getHiddenCppPointer())
+ self.assertEqual(mm2.getFamilyFieldAtLevel(0).getHiddenCppPointer(),d1.getHiddenCppPointer()) # <- here very important
+ self.assertEqual(mm.getFamilyFieldAtLevel(1).getHiddenCppPointer(),d0.getHiddenCppPointer())
+ self.assertEqual(mm2.getFamilyFieldAtLevel(1).getHiddenCppPointer(),d0.getHiddenCppPointer()) # <- here very important
+ # UMesh cart
+ mm.setAxisType(AX_CART)
+ mm2=mm.cartesianize() # the trigger
+ self.assertEqual(mm2.getAxisType(),AX_CART)
+ self.assertTrue(isinstance(mm2,MEDFileUMesh))
+ self.assertTrue(mm.getHiddenCppPointer()==mm2.getHiddenCppPointer()) # optimization
+ # CurveLinearMesh non cart
+ arr=DataArrayDouble(4) ; arr.iota() ; m=MEDCouplingCMesh() ; m.setCoords(arr,arr) ; m=m.buildCurveLinear()
+ mm=MEDFileCurveLinearMesh() ; mm.setMesh(m) ; mm.setAxisType(AX_CYL) #<- important
+ mm.setFamilyFieldArr(0,d1) ; mm.setFamilyFieldArr(1,d0)
+ mm.setName("a") ; mm.setDescription("b") ; mm.setTime(3,4,5.) ; mm.addFamily("c",-4) ; mm.setFamiliesOnGroup("d",["c"]) ; mm.setTimeUnit("ms")
+ ref0=mm.getMesh().getCoords().getHiddenCppPointer()
+ mm2=mm.cartesianize() # the trigger
+ self.assertEqual(mm2.getAxisType(),AX_CART)
+ self.assertTrue(isinstance(mm2,MEDFileCurveLinearMesh))
+ self.assertTrue(mm.getHiddenCppPointer()!=mm2.getHiddenCppPointer())
+ self.assertTrue(ref0==mm.getMesh().getCoords().getHiddenCppPointer()) # <- here important
+ self.assertTrue(ref0!=mm2.getMesh().getCoords().getHiddenCppPointer()) # <- here important
+ self.assertEqual(mm2.getMesh().getNodeGridStructure(),mm.getMesh().getNodeGridStructure())
+ self.assertEqual(mm2.getName(),mm.getName())
+ self.assertEqual(mm2.getDescription(),mm.getDescription())
+ self.assertEqual(mm2.getTime(),mm.getTime())
+ self.assertEqual(mm2.getTime(),mm.getTime())
+ self.assertEqual(mm2.getTimeUnit(),mm.getTimeUnit())
+ self.assertEqual(mm2.getGroupsNames(),mm.getGroupsNames())
+ self.assertEqual(mm2.getFamiliesNames(),mm.getFamiliesNames())
+ self.assertEqual([mm2.getFamilyId(elt) for elt in mm2.getFamiliesNames()],[mm.getFamilyId(elt2) for elt2 in mm.getFamiliesNames()])
+ self.assertEqual(mm.getFamilyFieldAtLevel(0).getHiddenCppPointer(),d1.getHiddenCppPointer())
+ self.assertEqual(mm2.getFamilyFieldAtLevel(0).getHiddenCppPointer(),d1.getHiddenCppPointer()) # <- here very important
+ self.assertEqual(mm.getFamilyFieldAtLevel(1).getHiddenCppPointer(),d0.getHiddenCppPointer())
+ self.assertEqual(mm2.getFamilyFieldAtLevel(1).getHiddenCppPointer(),d0.getHiddenCppPointer()) # <- here very important
+ # CurveLinearMesh cart
+ mm.setAxisType(AX_CART)
+ mm2=mm.cartesianize() # the trigger
+ self.assertEqual(mm2.getAxisType(),AX_CART)
+ self.assertTrue(isinstance(mm2,MEDFileCurveLinearMesh))
+ self.assertTrue(mm.getHiddenCppPointer()==mm2.getHiddenCppPointer()) # optimization
+ # CMesh non cart
+ arr=DataArrayDouble(4) ; arr.iota() ; m=MEDCouplingCMesh() ; m.setCoords(arr,arr)
+ mm=MEDFileCMesh() ; mm.setMesh(m) ; mm.setAxisType(AX_CYL) #<- important
+ mm.setFamilyFieldArr(0,d1) ; mm.setFamilyFieldArr(1,d0)
+ mm.setName("a") ; mm.setDescription("b") ; mm.setTime(3,4,5.) ; mm.addFamily("c",-4) ; mm.setFamiliesOnGroup("d",["c"]) ; mm.setTimeUnit("ms")
+ mm2=mm.cartesianize() # the trigger
+ self.assertEqual(mm2.getAxisType(),AX_CART)
+ self.assertTrue(isinstance(mm2,MEDFileCurveLinearMesh))
+ self.assertEqual(mm2.getMesh().getNodeGridStructure(),mm.getMesh().getNodeGridStructure())
+ self.assertEqual(mm2.getName(),mm.getName())
+ self.assertEqual(mm2.getDescription(),mm.getDescription())
+ self.assertEqual(mm2.getTime(),mm.getTime())
+ self.assertEqual(mm2.getTime(),mm.getTime())
+ self.assertEqual(mm2.getTimeUnit(),mm.getTimeUnit())
+ self.assertEqual(mm2.getGroupsNames(),mm.getGroupsNames())
+ self.assertEqual(mm2.getFamiliesNames(),mm.getFamiliesNames())
+ self.assertEqual([mm2.getFamilyId(elt) for elt in mm2.getFamiliesNames()],[mm.getFamilyId(elt2) for elt2 in mm.getFamiliesNames()])
+ self.assertEqual(mm.getFamilyFieldAtLevel(0).getHiddenCppPointer(),d1.getHiddenCppPointer())
+ self.assertEqual(mm2.getFamilyFieldAtLevel(0).getHiddenCppPointer(),d1.getHiddenCppPointer()) # <- here very important
+ self.assertEqual(mm.getFamilyFieldAtLevel(1).getHiddenCppPointer(),d0.getHiddenCppPointer())
+ self.assertEqual(mm2.getFamilyFieldAtLevel(1).getHiddenCppPointer(),d0.getHiddenCppPointer()) # <- here very important
+ # CMesh cart
+ mm.setAxisType(AX_CART)
+ mm2=mm.cartesianize() # the trigger
+ self.assertEqual(mm2.getAxisType(),AX_CART)
+ self.assertTrue(isinstance(mm2,MEDFileCMesh))
+ self.assertTrue(mm.getHiddenCppPointer()==mm2.getHiddenCppPointer()) # optimization
+ pass
+
+ def testCheckCoherency(self):
+ m2 = MEDCouplingUMesh("2d", 2)
+ m2.setCoords(DataArrayDouble([(0.0, 1.0)] * 4, 4,2)) # whatever
+ m2.setConnectivity(DataArrayInt([NORM_TRI3, 0,1,2,NORM_TRI3, 1,2,3]), DataArrayInt(([0,4,8])))
+ m1 , _, _ , _, _ = m2.buildDescendingConnectivity()
+ mum = MEDFileUMesh()
+ mum.setMeshAtLevel(0, m2)
+ mum.setMeshAtLevel(-1, m1)
+ mum.checkConsistency()
+ mum2 = mum.deepCopy()
+
+ # Nodes
+ arr = DataArrayInt([2]*4)
+ mum.setFamilyFieldArr(1, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayInt([2]*4)
+ mum.setRenumFieldArr(1, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ mum.setRenumFieldArr(1, DataArrayInt([2]*4))
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayAsciiChar(['tutu x']*4)
+ mum.setNameFieldAtLevel(1, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+
+ # 2D
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayInt([2]*2)
+ mum.setFamilyFieldArr(0, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayInt([2]*2)
+ mum.setRenumFieldArr(0, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ mum.setRenumFieldArr(0, DataArrayInt([2]*2))
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayAsciiChar(['tutu x']*2)
+ mum.setNameFieldAtLevel(0, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+
+ # 1D
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayInt([2]*5)
+ mum.setFamilyFieldArr(-1, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayInt([2]*5)
+ mum.setRenumFieldArr(-1, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ mum.setRenumFieldArr(-1, DataArrayInt([2]*5))
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+ mum=mum2; mum2=mum.deepCopy();
+ arr = DataArrayAsciiChar(['tutu x']*5)
+ mum.setNameFieldAtLevel(-1, arr); arr.reAlloc(35);
+ self.assertRaises(InterpKernelException, mum.checkConsistency)
+
+ def testCheckSMESHConsistency(self):
+ m2 = MEDCouplingUMesh("2d", 2)
+ m2.setCoords(DataArrayDouble([(0.0, 1.0)] * 4, 4,2)) # whatever
+ m2.setConnectivity(DataArrayInt([NORM_TRI3, 0,1,2,NORM_TRI3, 1,2,3]), DataArrayInt(([0,4,8])))
+ m1 , _, _ , _, _ = m2.buildDescendingConnectivity()
+ mum = MEDFileUMesh()
+ mum.setMeshAtLevel(0, m2)
+ mum.setMeshAtLevel(-1, m1)
+ mum.checkConsistency()
+ mum.checkSMESHConsistency()
+ n2 = DataArrayInt(m2.getNumberOfCells(), 1); n2.iota(1)
+ n1 = DataArrayInt(m1.getNumberOfCells(), 1); n1.iota(1)
+ mum.setRenumFieldArr(0, n2)
+ mum.setRenumFieldArr(-1, n1)
+ self.assertRaises(InterpKernelException, mum.checkSMESHConsistency)
+ mum.setRenumFieldArr(-1, n1+100)
+ mum.checkSMESHConsistency()
+ pass
+
+ def testClearNodeAndCellNumbers(self):
+ m2 = MEDCouplingUMesh("2d", 2)
+ m2.setCoords(DataArrayDouble([(0.0, 1.0)] * 4, 4,2)) # whatever
+ m2.setConnectivity(DataArrayInt([NORM_TRI3, 0,1,2,NORM_TRI3, 1,2,3]), DataArrayInt(([0,4,8])))
+ m1 , _, _ , _, _ = m2.buildDescendingConnectivity()
+ mum = MEDFileUMesh()
+ mum.setMeshAtLevel(0, m2)
+ mum.setMeshAtLevel(-1, m1)
+ mum.checkConsistency()
+ n2 = DataArrayInt(m2.getNumberOfCells(), 1); n2.iota(1)
+ n1 = DataArrayInt(m1.getNumberOfCells(), 1); n1.iota(1)
+ mum.setRenumFieldArr(0, n2)
+ mum.setRenumFieldArr(-1, n1)
+ mum.clearNodeAndCellNumbers()
+ mum.checkSMESHConsistency()
+ pass
+
+ def testCMeshSetFamilyFieldArrNull(self):
+ meshName="mesh"
+ fname="Pyfile99.med"
+ arrX=DataArrayDouble([0,1,2,3])
+ arrY=DataArrayDouble([0,1,2])
+ m=MEDCouplingCMesh() ; m.setCoords(arrX,arrY) ; m.setName(meshName)
+ mm=MEDFileCMesh() ; mm.setMesh(m)
+ famCellIds=DataArrayInt([0,-2,-2,-1,-2,0])
+ famNodeIds=DataArrayInt([0,0,0,3,4,1,2,7,2,1,0,0])
+ mm.setFamilyFieldArr(0,famCellIds)
+ mm.setFamilyFieldArr(1,famNodeIds)
+ mm.write(fname,2)
+ mm=MEDFileMesh.New(fname)
+ self.assertTrue(mm.getFamilyFieldAtLevel(0) is not None)
+ self.assertTrue(mm.getFamilyFieldAtLevel(1) is not None)
+ mm.setFamilyFieldArr(0,None)#<- bug was here
+ mm.setFamilyFieldArr(1,None)#<- bug was here
+ self.assertTrue(mm.getFamilyFieldAtLevel(0) is None)
+ self.assertTrue(mm.getFamilyFieldAtLevel(1) is None)
+ mm3=mm.deepCopy()
+ self.assertTrue(mm3.getFamilyFieldAtLevel(0) is None)
+ self.assertTrue(mm3.getFamilyFieldAtLevel(1) is None)
+ mm.write(fname,2)
+ mm2=MEDFileMesh.New(fname)
+ self.assertTrue(mm2.getFamilyFieldAtLevel(0) is None)
+ self.assertTrue(mm2.getFamilyFieldAtLevel(1) is None)
+ pass
+
+ def testAppendFieldProfileOnIntField(self):
+ fname="Pyfile100.med"
+ arrX=DataArrayDouble([0,1,2,3])
+ arrY=DataArrayDouble([0,1,2])
+ mesh=MEDCouplingCMesh() ; mesh.setCoords(arrX,arrY) ; mesh.setName("Mesh")
+ mm=MEDFileCMesh()
+ mm.setMesh(mesh)
+ #
+ fmts=MEDFileIntFieldMultiTS()
+ pflName="PFL"
+ pfl=DataArrayInt([1,3,5]) ; pfl.setName(pflName)
+ f=MEDCouplingFieldInt(ON_CELLS) ; f.setMesh(mesh)
+ fieldName="FieldOnCell"
+ f.setTime(1.2,1,1) ; f.setName(fieldName)
+ arr=DataArrayInt([101,102,103]) ; f.setArray(arr)
+ fmts.appendFieldProfile(f,mm,0,pfl)
+ #
+ mm.write(fname,2)
+ fmts.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname)
+ fmts=MEDFileAnyTypeFieldMultiTS.New(fname)
+ self.assertTrue(isinstance(fmts,MEDFileIntFieldMultiTS))
+ self.assertEqual(fmts.getName(),fieldName)
+ self.assertEqual(len(fmts),1)
+ f1ts=fmts[0]
+ ftest,pfltest=f1ts.getFieldWithProfile(ON_CELLS,0,mm)
+ self.assertEqual(pfltest.getName(),pflName)
+ self.assertEqual(ftest.getName(),fieldName)
+ self.assertTrue(ftest.isEqualWithoutConsideringStr(arr))
+ ftest2=f1ts.getFieldOnMeshAtLevel(ON_CELLS,0,mm)
+ self.assertTrue(ftest2.getArray().isEqualWithoutConsideringStr(arr))
+ self.assertEqual(ftest2.getTime(),f.getTime())
+ self.assertEqual(ftest2.getMesh().getNumberOfCells(),len(arr))
+ pass
+
+ def testMEDFileFieldEasyField1(self):
+ """Check for all spatial discretization of field (cells,nodes,elno,gauss) for double field that all is OK. Here no profile and only top level is considered."""
+ ## Basic test on cells on top level
+ fname="Pyfile101.med"
+ fieldName="field1"
+ mm=MEDFileUMesh()
+ coo=DataArrayDouble([(3,2,1),(8,7,6),(5,9,10)])
+ m=MEDCouplingUMesh("mesh",2) ; m.setCoords(coo)
+ m.allocateCells()
+ m.insertNextCell(NORM_TRI3,[0,1,2])
+ m.insertNextCell(NORM_TRI3,[3,4,5])
+ m.insertNextCell(NORM_TRI3,[6,7,8])
+ m.insertNextCell(NORM_TRI3,[9,10,11])
+ m.insertNextCell(NORM_QUAD4,[100,101,102,103])
+ m.insertNextCell(NORM_QUAD4,[104,105,106,107])
+ mm[0]=m
+ mm.write(fname,2)
+ arr0=DataArrayDouble([10,11,12,13,100,101])
+ f=MEDCouplingFieldDouble(ON_CELLS) ; f.setArray(arr0) ; f.setMesh(m)
+ f.setName(fieldName) ; f.setTime(2.,6,7)
+ f0=f.deepCopy()
+ ff=MEDFileFieldMultiTS() ; ff.appendFieldNoProfileSBT(f)
+ ff.write(fname,0)
+ arr2=arr0+1000 ; f.setArray(arr2)
+ f.setTime(3.,8,9) ; ff=MEDFileField1TS() ; ff.setFieldNoProfileSBT(f)
+ ff.write(fname,0)
+ f1=f.deepCopy()
+ ##
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileField1TS(fname,fieldName,6,7)
+ ftst0=f1ts.field(mm)
+ self.assertTrue(f0.isEqual(ftst0,1e-12,1e-12))
+ f1ts=MEDFileField1TS(fname,fieldName,8,9)
+ ftst1=f1ts.field(mm)
+ self.assertTrue(f1.isEqual(ftst1,1e-12,1e-12))
+ fmts=MEDFileFieldMultiTS(fname,fieldName)
+ self.assertTrue(f1.isEqual(fmts.field(8,9,mm),1e-12,1e-12))
+ ## Basic test on nodes on top level
+ f2=MEDCouplingFieldDouble(ON_NODES) ; arr2=DataArrayDouble([200,201,202]) ; arr2.setInfoOnComponent(0,"tutu") ; f2.setArray(arr2) ; f2.setMesh(m) ; f2.setTime(22.,23,24)
+ f2.setName(fieldName)
+ mm.write(fname,2)
+ ff=MEDFileField1TS() ; ff.setFieldNoProfileSBT(f2) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileField1TS(fname,fieldName,23,24)
+ self.assertTrue(f2.isEqual(f1ts.field(mm),1e-12,1e-12))
+ fmts=MEDFileFieldMultiTS(fname,fieldName)
+ self.assertTrue(f2.isEqual(fmts.field(23,24,mm),1e-12,1e-12))
+ ## Node on elements
+ f3=MEDCouplingFieldDouble(ON_GAUSS_NE) ; f3.setMesh(m) ; arr3=DataArrayDouble([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19]) ; f3.setArray(arr3) ; f3.setTime(0.5,2,3)
+ f3.setName(fieldName) ; f3.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileField1TS() ; ff.setFieldNoProfileSBT(f3) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileField1TS(fname,fieldName,2,3)
+ self.assertTrue(f3.isEqual(f1ts.field(mm),1e-12,1e-12))
+ ## Gauss
+ f4=MEDCouplingFieldDouble(ON_GAUSS_PT) ; f4.setMesh(m) ; f4.setName(fieldName)
+ f4.setGaussLocalizationOnType(NORM_TRI3,[0.,0.,1.,0.,1.,1.],[0.1,0.1, 0.2,0.2, 0.3,0.3, 0.4,0.4, 0.5,0.5],[0.2,0.3,0.1,0.05,0.35])
+ f4.setGaussLocalizationOnType(NORM_QUAD4,[0.,0.,1.,0.,1.,1.,0.,1.],[0.3,0.4, 0.6,0.7],[0.7,0.3]) ; f4.setTime(0.25,4,5)
+ arr4=DataArrayDouble([0,1,2,3,4 ,10,11,12,13,14, 20,21,22,23,24, 30,31,32,33,34, 45,46, 55,56]) ; arr4.setInfoOnComponent(0,"abc") ; f4.setArray(arr4)
+ f4.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileField1TS() ; ff.setFieldNoProfileSBT(f4) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileField1TS(fname,fieldName,4,5)
+ self.assertTrue(f4.isEqual(f1ts.field(mm),1e-12,1e-12))
+ pass
+
+ def testMEDFileFieldEasyField2(self):
+ """Same thantestMEDFileFieldEasyField1 except that here intfields are considered.
+ Check for all spatial discretization of field (cells,nodes,elno,gauss) for int field that all is OK. Here no profile and only top level is considered."""
+ ## Basic test on cells on top level
+ fname="Pyfile102.med"
+ fieldName="field1"
+ mm=MEDFileUMesh()
+ coo=DataArrayDouble([(3,2,1),(8,7,6),(5,9,10)])
+ m=MEDCouplingUMesh("mesh",2) ; m.setCoords(coo)
+ m.allocateCells()
+ m.insertNextCell(NORM_TRI3,[0,1,2])
+ m.insertNextCell(NORM_TRI3,[3,4,5])
+ m.insertNextCell(NORM_TRI3,[6,7,8])
+ m.insertNextCell(NORM_TRI3,[9,10,11])
+ m.insertNextCell(NORM_QUAD4,[100,101,102,103])
+ m.insertNextCell(NORM_QUAD4,[104,105,106,107])
+ mm[0]=m
+ mm.write(fname,2)
+ arr0=DataArrayInt([10,11,12,13,100,101])
+ f=MEDCouplingFieldInt(ON_CELLS) ; f.setArray(arr0) ; f.setMesh(m)
+ f.setName(fieldName) ; f.setTime(2.,6,7)
+ f0=f.deepCopy()
+ ff=MEDFileIntFieldMultiTS() ; ff.appendFieldNoProfileSBT(f)
+ ff.write(fname,0)
+ arr2=arr0+1000 ; f.setArray(arr2)
+ f.setTime(3.,8,9) ; ff=MEDFileIntField1TS() ; ff.setFieldNoProfileSBT(f)
+ ff.write(fname,0)
+ f1=f.deepCopy()
+ ##
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileIntField1TS(fname,fieldName,6,7)
+ ftst0=f1ts.field(mm)
+ self.assertTrue(f0.isEqual(ftst0,1e-12,0))
+ f1ts=MEDFileIntField1TS(fname,fieldName,8,9)
+ ftst1=f1ts.field(mm)
+ self.assertTrue(f1.isEqual(ftst1,1e-12,0))
+ fmts=MEDFileIntFieldMultiTS(fname,fieldName)
+ self.assertTrue(f1.isEqual(fmts.field(8,9,mm),1e-12,0))
+ ## Basic test on nodes on top level
+ f2=MEDCouplingFieldInt(ON_NODES) ; arr2=DataArrayInt([200,201,202]) ; arr2.setInfoOnComponent(0,"tutu") ; f2.setArray(arr2) ; f2.setMesh(m) ; f2.setTime(22.,23,24)
+ f2.setName(fieldName)
+ mm.write(fname,2)
+ ff=MEDFileIntField1TS() ; ff.setFieldNoProfileSBT(f2) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileIntField1TS(fname,fieldName,23,24)
+ self.assertTrue(f2.isEqual(f1ts.field(mm),1e-12,0))
+ fmts=MEDFileIntFieldMultiTS(fname,fieldName)
+ self.assertTrue(f2.isEqual(fmts.field(23,24,mm),1e-12,0))
+ ## Node on elements
+ f3=MEDCouplingFieldInt(ON_GAUSS_NE) ; f3.setMesh(m) ; arr3=DataArrayInt([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19]) ; f3.setArray(arr3) ; f3.setTime(0.5,2,3)
+ f3.setName(fieldName) ; f3.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileIntField1TS() ; ff.setFieldNoProfileSBT(f3) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileIntField1TS(fname,fieldName,2,3)
+ self.assertTrue(f3.isEqual(f1ts.field(mm),1e-12,0))
+ ## Gauss
+ f4=MEDCouplingFieldInt(ON_GAUSS_PT) ; f4.setMesh(m) ; f4.setName(fieldName)
+ f4.setGaussLocalizationOnType(NORM_TRI3,[0.,0.,1.,0.,1.,1.],[0.1,0.1, 0.2,0.2, 0.3,0.3, 0.4,0.4, 0.5,0.5],[0.2,0.3,0.1,0.05,0.35])
+ f4.setGaussLocalizationOnType(NORM_QUAD4,[0.,0.,1.,0.,1.,1.,0.,1.],[0.3,0.4, 0.6,0.7],[0.7,0.3]) ; f4.setTime(0.25,4,5)
+ arr4=DataArrayInt([0,1,2,3,4 ,10,11,12,13,14, 20,21,22,23,24, 30,31,32,33,34, 45,46, 55,56]) ; arr4.setInfoOnComponent(0,"abc") ; f4.setArray(arr4)
+ f4.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileIntField1TS() ; ff.setFieldNoProfileSBT(f4) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname)
+ f1ts=MEDFileIntField1TS(fname,fieldName,4,5)
+ self.assertTrue(f4.isEqual(f1ts.field(mm),1e-12,0))
+ pass
+
+ def testMEDFileFieldEasyField3(self):
+ """Here a multi level mesh. And field on cells lying on different level of this mesh. Show how "field" method deal with that. Here on field double are considered."""
+ fname="Pyfile103.med"
+ fieldName="field1"
+ mm=MEDFileUMesh()
+ coo=DataArrayDouble([(3,2,1),(8,7,6),(5,9,10)])
+ m=MEDCouplingUMesh("mesh",2) ; m.setCoords(coo)
+ m.allocateCells()
+ m.insertNextCell(NORM_TRI3,[0,1,2])
+ m.insertNextCell(NORM_TRI3,[3,4,5])
+ m.insertNextCell(NORM_TRI3,[6,7,8])
+ m.insertNextCell(NORM_TRI3,[9,10,11])
+ m.insertNextCell(NORM_QUAD4,[100,101,102,103])
+ m.insertNextCell(NORM_QUAD4,[104,105,106,107])
+ mm[-1]=m
+ m0=MEDCouplingUMesh("mesh",3) ; m0.setCoords(coo)
+ m0.allocateCells()
+ m0.insertNextCell(NORM_TETRA4,[3,2,5,0])
+ m0.insertNextCell(NORM_TETRA4,[7,6,3,2])
+ mm[0]=m0
+ mm.write(fname,2)
+ # start slowly
+ f1=MEDCouplingFieldDouble(ON_CELLS) ; f1.setName(fieldName) ; f1.setArray(DataArrayDouble([(0,100),(1,101)])) ; f1.setMesh(mm[0]) ; f1.setTime(4.,1,2)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldNoProfileSBT(f1) ; f1ts.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileField1TS(fname,fieldName,1,2)
+ self.assertTrue(f1.isEqual(f1ts.field(mm),1e-12,1e-12))
+ # here f1 lying on level -1 not 0 check if "field" method detect it !
+ f1=MEDCouplingFieldDouble(ON_CELLS) ; f1.setName(fieldName) ; f1.setArray(DataArrayDouble([(0,100),(1,101),(0,100),(1,101),(0,100),(1,101)]))
+ f1.setMesh(mm[-1]) # -1 is very important
+ f1.setTime(16.,3,4)
+ f1.checkConsistencyLight()
+ mm.write(fname,2)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldNoProfileSBT(f1) ; f1ts.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileField1TS(fname,fieldName,3,4)
+ self.assertTrue(f1.isEqual(f1ts.field(mm),1e-12,1e-12))
+ # nodes on elements
+ f3=MEDCouplingFieldDouble(ON_GAUSS_NE)
+ f3.setMesh(mm[-1]) # this line is important
+ arr3=DataArrayDouble([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19]) ; f3.setArray(arr3) ; f3.setTime(0.5,2,3)
+ f3.setName(fieldName) ; f3.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileField1TS() ; ff.setFieldNoProfileSBT(f3) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileField1TS(fname,fieldName,2,3)
+ self.assertTrue(f3.isEqual(f1ts.field(mm),1e-12,1e-12))
+ # gauss
+ f4=MEDCouplingFieldDouble(ON_GAUSS_PT)
+ f4.setMesh(mm[-1]) # this line is important
+ f4.setName(fieldName)
+ f4.setGaussLocalizationOnType(NORM_TRI3,[0.,0.,1.,0.,1.,1.],[0.1,0.1, 0.2,0.2, 0.3,0.3, 0.4,0.4, 0.5,0.5],[0.2,0.3,0.1,0.05,0.35])
+ f4.setGaussLocalizationOnType(NORM_QUAD4,[0.,0.,1.,0.,1.,1.,0.,1.],[0.3,0.4, 0.6,0.7],[0.7,0.3]) ; f4.setTime(0.25,4,5)
+ arr4=DataArrayDouble([0,1,2,3,4 ,10,11,12,13,14, 20,21,22,23,24, 30,31,32,33,34, 45,46, 55,56]) ; arr4.setInfoOnComponent(0,"abc") ; f4.setArray(arr4)
+ f4.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileField1TS() ; ff.setFieldNoProfileSBT(f4) ; ff.write(fname,0)
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileField1TS(fname,fieldName,4,5)
+ self.assertTrue(f4.isEqual(f1ts.field(mm),1e-12,1e-12))
+ pass
+
+ def testMEDFileFieldEasyField4(self):
+ """ Same than testMEDFileFieldEasyField3 but with integers"""
+ fname="Pyfile104.med"
+ fieldName="field1"
+ mm=MEDFileUMesh()
+ coo=DataArrayDouble([(3,2,1),(8,7,6),(5,9,10)])
+ m=MEDCouplingUMesh("mesh",2) ; m.setCoords(coo)
+ m.allocateCells()
+ m.insertNextCell(NORM_TRI3,[0,1,2])
+ m.insertNextCell(NORM_TRI3,[3,4,5])
+ m.insertNextCell(NORM_TRI3,[6,7,8])
+ m.insertNextCell(NORM_TRI3,[9,10,11])
+ m.insertNextCell(NORM_QUAD4,[100,101,102,103])
+ m.insertNextCell(NORM_QUAD4,[104,105,106,107])
+ mm[-1]=m
+ m0=MEDCouplingUMesh("mesh",3) ; m0.setCoords(coo)
+ m0.allocateCells()
+ m0.insertNextCell(NORM_TETRA4,[3,2,5,0])
+ m0.insertNextCell(NORM_TETRA4,[7,6,3,2])
+ mm[0]=m0
+ mm.write(fname,2)
+ # start slowly
+ f1=MEDCouplingFieldInt(ON_CELLS) ; f1.setName(fieldName) ; f1.setArray(DataArrayInt([(0,100),(1,101)])) ; f1.setMesh(mm[0]) ; f1.setTime(4.,1,2)
+ f1ts=MEDFileIntField1TS() ; f1ts.setFieldNoProfileSBT(f1) ; f1ts.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileIntField1TS(fname,fieldName,1,2)
+ self.assertTrue(f1.isEqual(f1ts.field(mm),1e-12,0))
+ # here f1 lying on level -1 not 0 check if "field" method detect it !
+ f1=MEDCouplingFieldInt(ON_CELLS) ; f1.setName(fieldName) ; f1.setArray(DataArrayInt([(0,100),(1,101),(0,100),(1,101),(0,100),(1,101)]))
+ f1.setMesh(mm[-1]) # -1 is very important
+ f1.setTime(16.,3,4)
+ f1.checkConsistencyLight()
+ mm.write(fname,2)
+ f1ts=MEDFileIntField1TS() ; f1ts.setFieldNoProfileSBT(f1) ; f1ts.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileIntField1TS(fname,fieldName,3,4)
+ self.assertTrue(f1.isEqual(f1ts.field(mm),1e-12,0))
+ # nodes on elements
+ f3=MEDCouplingFieldInt(ON_GAUSS_NE)
+ f3.setMesh(mm[-1]) # this line is important
+ arr3=DataArrayInt([0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19]) ; f3.setArray(arr3) ; f3.setTime(0.5,2,3)
+ f3.setName(fieldName) ; f3.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileIntField1TS() ; ff.setFieldNoProfileSBT(f3) ; ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileIntField1TS(fname,fieldName,2,3)
+ self.assertTrue(f3.isEqual(f1ts.field(mm),1e-12,0))
+ # gauss
+ f4=MEDCouplingFieldInt(ON_GAUSS_PT)
+ f4.setMesh(mm[-1]) # this line is important
+ f4.setName(fieldName)
+ f4.setGaussLocalizationOnType(NORM_TRI3,[0.,0.,1.,0.,1.,1.],[0.1,0.1, 0.2,0.2, 0.3,0.3, 0.4,0.4, 0.5,0.5],[0.2,0.3,0.1,0.05,0.35])
+ f4.setGaussLocalizationOnType(NORM_QUAD4,[0.,0.,1.,0.,1.,1.,0.,1.],[0.3,0.4, 0.6,0.7],[0.7,0.3]) ; f4.setTime(0.25,4,5)
+ arr4=DataArrayInt([0,1,2,3,4 ,10,11,12,13,14, 20,21,22,23,24, 30,31,32,33,34, 45,46, 55,56]) ; arr4.setInfoOnComponent(0,"abc") ; f4.setArray(arr4)
+ f4.checkConsistencyLight()
+ mm.write(fname,2) ; ff=MEDFileIntField1TS() ; ff.setFieldNoProfileSBT(f4) ; ff.write(fname,0)
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileIntField1TS(fname,fieldName,4,5)
+ self.assertTrue(f4.isEqual(f1ts.field(mm),1e-12,0))
+ pass
+
+ def testMEDFileFieldEasyField5(self):
+ """More and more difficult now look at how profiles are managed by "field" method."""
+ fname="Pyfile105.med"
+ fieldName="field1"
+ mm=MEDFileUMesh()
+ coo=DataArrayDouble([(3,2,1),(8,7,6),(5,9,10)])
+ m=MEDCouplingUMesh("mesh",2) ; m.setCoords(coo)
+ m.allocateCells()
+ m.insertNextCell(NORM_TRI3,[0,1,2])
+ m.insertNextCell(NORM_TRI3,[3,4,5])
+ m.insertNextCell(NORM_TRI3,[6,7,8])
+ m.insertNextCell(NORM_TRI3,[9,10,11])
+ m.insertNextCell(NORM_QUAD4,[100,101,102,103])
+ m.insertNextCell(NORM_QUAD4,[104,105,106,107])
+ mm[0]=m
+ mm.write(fname,2)
+ pfl=DataArrayInt([0,2,3,5]) ; pfl.setName("pfl")
+ m2=m.deepCopy()[pfl] ; m2.setName(m.getName())
+ #
+ arr0=DataArrayDouble([10,11,12,13])
+ f=MEDCouplingFieldDouble(ON_CELLS) ; f.setArray(arr0) ; f.setMesh(m2)
+ f.setName(fieldName) ; f.setTime(2.,6,7) ; f.checkConsistencyLight()
+ ff=MEDFileFieldMultiTS() ; ff.appendFieldProfile(f,mm,0,pfl) # ff is a field on profile
+ ff.write(fname,0)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileField1TS(fname,fieldName,6,7)
+ self.assertTrue(f.isEqual(f1ts.field(mm),1e-12,1e-12))
+ # more complicated -> multi level
+ m0=MEDCouplingUMesh("mesh",3) ; m0.setCoords(coo)
+ m0.allocateCells()
+ m0.insertNextCell(NORM_TETRA4,[3,2,5,0])
+ m0.insertNextCell(NORM_TETRA4,[7,6,3,2])
+ mm2=MEDFileUMesh()
+ mm2[0]=m0 ; mm2[-1]=m
+ #
+ ff=MEDFileField1TS() ; ff.setFieldProfile(f,mm2,-1,pfl)
+ #
+ mm=MEDFileMesh.New(fname) ; f1ts=MEDFileField1TS(fname,fieldName,6,7)
+ self.assertTrue(f.isEqual(f1ts.field(mm),1e-12,1e-12))
+ pass
+
+ def testExtractPart1(self):
+ coo=DataArrayDouble([(0,0),(1,0),(2,0),(3,0),(4,0),(0,1),(1,1),(2,1),(3,1),(4,1),(0,2),(1,2),(2,2),(3,2),(4,2)])
+ meshName="mesh"
+ m0=MEDCouplingUMesh(meshName,2) ; m0.setCoords(coo) ; m0.allocateCells()
+ m0.insertNextCell(NORM_TRI3,[8,4,3])
+ m0.insertNextCell(NORM_TRI3,[8,9,4])
+ m0.insertNextCell(NORM_TRI3,[7,13,8])
+ m0.insertNextCell(NORM_TRI3,[7,12,13])
+ m0.insertNextCell(NORM_TRI3,[0,6,1])
+ m0.insertNextCell(NORM_TRI3,[0,5,6])
+ m0.insertNextCell(NORM_QUAD4,[1,6,7,2])
+ m0.insertNextCell(NORM_QUAD4,[2,7,8,3])
+ m0.insertNextCell(NORM_QUAD4,[8,13,14,9])
+ m0.insertNextCell(NORM_QUAD4,[6,11,12,7])
+ m0.insertNextCell(NORM_QUAD4,[5,10,11,6])
+ #
+ m1=MEDCouplingUMesh(meshName,1) ; m1.setCoords(coo) ; m1.allocateCells()
+ m1.insertNextCell(NORM_SEG2,[10,5])
+ m1.insertNextCell(NORM_SEG2,[5,0])
+ m1.insertNextCell(NORM_SEG2,[0,1])
+ m1.insertNextCell(NORM_SEG2,[1,2])
+ m1.insertNextCell(NORM_SEG2,[2,3])
+ m1.insertNextCell(NORM_SEG2,[3,4])
+ m1.insertNextCell(NORM_SEG2,[4,9])
+ m1.insertNextCell(NORM_SEG2,[9,14])
+ m1.insertNextCell(NORM_SEG2,[14,13])
+ m1.insertNextCell(NORM_SEG2,[13,12])
+ m1.insertNextCell(NORM_SEG2,[12,11])
+ m1.insertNextCell(NORM_SEG2,[11,10])
+ mm=MEDFileUMesh()
+ mm[0]=m0 ; mm[-1]=m1
+ arr0=DataArrayInt([0,1,2,3,4,6,7,8,12,13])
+ tab={} #
+ tab[0]=DataArrayInt([0,2,3,4,6,7])
+ tab[-1]=DataArrayInt([2,3,4,5,9])
+ fs=MEDFileFields()
+ self.assertTrue(mm.deduceNodeSubPartFromCellSubPart(tab).isEqual(arr0))
+ tab[1]=arr0
+ #
+ fname0="Field0"
+ fmts=MEDFileFieldMultiTS() ; fs.pushField(fmts)
+ t0=(16.5,3,4)
+ ic=["toto [m]"]
+ arr0_0=DataArrayDouble([100,101,102,103,104,105,106,107,108,109,110]) ; arr0_0.setInfoOnComponents(ic)
+ f0=MEDCouplingFieldDouble(ON_CELLS) ; f0.setTime(*t0) ; f0.setArray(arr0_0)
+ f0.setMesh(m0) ; f0.setName(fname0)
+ f1=MEDCouplingFieldDouble(ON_CELLS) ; f1.setTime(*t0) ; f1.setArray(DataArrayDouble([200,201,202,203,204,205,206,207,208,209,210,211]))
+ f1.setMesh(m1) ; f1.setName(fname0) ; f1.getArray().setInfoOnComponents(ic)
+ f2=MEDCouplingFieldDouble(ON_NODES) ; f2.setTime(*t0) ; f2.setArray(DataArrayDouble([300,301,302,303,304,305,306,307,308,309,310,311,312,313,314]))
+ f2.setMesh(m0) ; f2.setName(fname0) ; f2.getArray().setInfoOnComponents(ic)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldNoProfileSBT(f0) ; f1ts.setFieldNoProfileSBT(f1) ; f1ts.setFieldNoProfileSBT(f2)
+ fmts.pushBackTimeStep(f1ts)
+ #
+ mmOut=mm.extractPart(tab)
+ #
+ fsPart0=fs.extractPart(tab,mm)
+ self.assertEqual(len(fsPart0),1)
+ fmtsP=fsPart0[0]
+ self.assertEqual(len(fmtsP),1)
+ f1ts=fmtsP[0]
+ self.assertRaises(InterpKernelException,f1ts.field,mmOut)
+ #
+ self.assertTrue(mmOut[0].computeCellCenterOfMass().isEqual(m0[tab[0]].computeCellCenterOfMass(),1e-12))
+ self.assertTrue(mmOut[-1].computeCellCenterOfMass().isEqual(m1[tab[-1]].computeCellCenterOfMass(),1e-12))
+ #
+ m0Part=m0.deepCopy()[tab[0]] ; m0Part.renumberNodes(tab[1].invertArrayN2O2O2N(mm.getNumberOfNodes()),len(tab[1])) ; m0Part.setName(m0.getName())
+ self.assertTrue(mmOut[0].isEqual(m0Part,1e-12))
+ m1Part=m1.deepCopy()[tab[-1]] ; m1Part.renumberNodes(tab[1].invertArrayN2O2O2N(mm.getNumberOfNodes()),len(tab[1])) ; m1Part.setName(m0.getName())
+ self.assertTrue(mmOut[0].isEqual(m0Part,1e-12))
+ self.assertTrue(mmOut[-1].isEqual(m1Part,1e-12))
+ #
+ f0Part=f1ts.getFieldOnMeshAtLevel(ON_CELLS,0,mmOut) ; f0Part.checkConsistencyLight()
+ self.assertEqual(f0Part.getTypeOfField(),ON_CELLS)
+ self.assertTrue(f0Part.getMesh().isEqual(m0Part,1e-12))
+ arr0Exp=DataArrayDouble([100,102,103,104,106,107]) ; arr0Exp.setInfoOnComponents(ic)
+ self.assertTrue(f0Part.getArray().isEqual(arr0Exp,1e-12)) ; self.assertEqual(f0Part.getTime(),list(t0))
+ f1Part=f1ts.getFieldOnMeshAtLevel(ON_CELLS,-1,mmOut) ; f1Part.checkConsistencyLight()
+ self.assertEqual(f1Part.getTypeOfField(),ON_CELLS)
+ self.assertTrue(f1Part.getMesh().isEqual(m1Part,1e-12))
+ arr1Exp=DataArrayDouble([202,203,204,205,209]) ; arr1Exp.setInfoOnComponents(ic)
+ self.assertTrue(f1Part.getArray().isEqual(arr1Exp,1e-12)) ; self.assertEqual(f1Part.getTime(),list(t0))
+ #
+ f2Part=f1ts.getFieldOnMeshAtLevel(ON_NODES,0,mmOut) ; f2Part.checkConsistencyLight()
+ arr2Exp=DataArrayDouble([300,301,302,303,304,306,307,308,312,313]) ; arr2Exp.setInfoOnComponents(ic)
+ self.assertTrue(f2Part.getArray().isEqual(arr2Exp,1e-12)) ; self.assertEqual(f2Part.getTime(),list(t0))
+ # multisteps
+ fs=MEDFileFields() ; fmts=MEDFileFieldMultiTS() ; fs.pushField(fmts)
+ tss=[(16.5,3,4),(17.5,4,5),(18.5,5,6)]
+ for i,tt in enumerate(tss):
+ f0=MEDCouplingFieldDouble(ON_CELLS) ; f0.setTime(*tt)
+ myarr=arr0_0+i*1000.
+ f0.setArray(myarr)
+ f0.setMesh(m0) ; f0.setName(fname0) ; f0.getArray().setInfoOnComponents(ic)
+ f1ts=MEDFileField1TS() ; f1ts.setFieldNoProfileSBT(f0) ; fmts.pushBackTimeStep(f1ts)
+ pass
+ fsPart1=fs.extractPart(tab,mm)
+ self.assertEqual(len(fsPart1),1)
+ fmtsP=fsPart1[0]
+ self.assertEqual(len(fmtsP),len(tss))
+ for i,(f1tsP,tt) in enumerate(zip(fmtsP,tss)):
+ fPart=f1tsP.field(mmOut) ; fPart.checkConsistencyLight()
+ self.assertEqual(fPart.getTypeOfField(),ON_CELLS)
+ arr0Exp=DataArrayDouble([100,102,103,104,106,107]) ; arr0Exp.setInfoOnComponents(ic) ; arr0Exp+=i*1000.
+ self.assertTrue(fPart.getMesh().isEqual(m0Part,1e-12))
+ self.assertTrue(fPart.getArray().isEqual(arr0Exp,1e-12))
+ self.assertEqual(fPart.getTime(),list(tt))
+ pass
+ pass
+
+ def testSymmetryPlusAggregationMFD1(self):
+ """ Testing of MEDFileData::Aggregate and MEDFileUMesh::Aggregate and MEDFileUMesh::getAllDistributionOfType """
+ fname1="Pyfile106_1.med"
+ fname2="Pyfile106_2.med"
+ fname3="Pyfile106_3.med"
+ meshName="mesh"
+ mm1=MEDFileUMesh()
+ da1=DataArrayDouble([1,2,10,3,4,11,5,6,12,7,8,13],4,3) ; da1.setInfoOnComponents(["aa [m]","bbb [kg]","cccc [MW]"])
+ mm1.setCoords(da1)
+ mm1_0=MEDCouplingUMesh(meshName,3) ; mm1_0.allocateCells()
+ mm1_0.setCoords(da1)
+ mm1_0.insertNextCell(NORM_TETRA4,[0,1,2,3])
+ mm1_0.insertNextCell(NORM_TETRA4,[4,5,6,7])
+ mm1_0.insertNextCell(NORM_PENTA6,[8,9,10,11,12,13])
+ mm1_0.insertNextCell(NORM_PENTA6,[14,15,16,17,18,19])
+ mm1_0.insertNextCell(NORM_PENTA6,[20,21,22,23,24,25])
+ mm1[0]=mm1_0
+ mm1.setFamilyFieldArr(0,DataArrayInt([1,2,3,4,5]))
+ mm1.setRenumFieldArr(0,DataArrayInt([11,12,13,14,15]))
+ #
+ mm1_1=MEDCouplingUMesh(meshName,2) ; mm1_1.allocateCells()
+ mm1_1.setCoords(da1)
+ mm1_1.insertNextCell(NORM_TRI3,[0,1,2])
+ mm1_1.insertNextCell(NORM_TRI3,[3,4,5])
+ mm1_1.insertNextCell(NORM_QUAD4,[6,7,8,9])
+ mm1_1.insertNextCell(NORM_QUAD4,[10,11,12,13])
+ mm1_1.insertNextCell(NORM_QUAD4,[14,15,16,17])
+ mm1_1.insertNextCell(NORM_QUAD4,[18,19,20,21])
+ mm1[-1]=mm1_1
+ mm1.setFamilyFieldArr(-1,DataArrayInt([6,7,8,9,10,11]))
+ mm1.setRenumFieldArr(-1,DataArrayInt([16,17,18,19,20,21]))
+ for i in range(1,10):
+ mm1.setFamilyId("F%d"%i,i)
+ mm1.setFamilyId("FAMILLE_ZERO",0)
+ mm1.setFamilyId("H1",100)
+ mm1.setFamiliesOnGroup("myGRP",["F2","F6"])
+ mm1.setFamiliesOnGroup("myGRP1",["F2","F6"])
+ mm1.setFamilyFieldArr(1,DataArrayInt([12,13,14,15]))
+ mm1.setRenumFieldArr(1,DataArrayInt([22,23,24,25]))
+ ##############
+ mm2=MEDFileUMesh()
+ da1=DataArrayDouble([9,10,30,11,12,31,13,14,32,15,16,33,17,18,34],5,3) ; da1.setInfoOnComponents(["aa [m]","bbb [kg]","cccc [MW]"])
+ mm2.setCoords(da1)
+ mm2_0=MEDCouplingUMesh(meshName,3) ; mm2_0.allocateCells()
+ mm2_0.setCoords(da1)
+ mm2_0.insertNextCell(NORM_TETRA4,[100,101,102,103])
+ mm2_0.insertNextCell(NORM_TETRA4,[104,105,106,107])
+ mm2_0.insertNextCell(NORM_TETRA4,[108,109,110,111])
+ mm2_0.insertNextCell(NORM_PENTA6,[112,113,114,115,116,117])
+ mm2[0]=mm2_0
+ mm2.setFamilyFieldArr(0,DataArrayInt([40,41,42,43]))
+ mm2.setRenumFieldArr(0,DataArrayInt([50,51,52,53]))
+ #
+ mm2_1=MEDCouplingUMesh(meshName,2) ; mm2_1.allocateCells()
+ mm2_1.setCoords(da1)
+ mm2_1.insertNextCell(NORM_TRI3,[100,101,102])
+ mm2_1.insertNextCell(NORM_TRI3,[103,104,105])
+ mm2_1.insertNextCell(NORM_TRI3,[106,107,108])
+ mm2_1.insertNextCell(NORM_QUAD4,[109,110,111,112])
+ mm2_1.insertNextCell(NORM_QUAD4,[113,114,115,116])
+ mm2_1.insertNextCell(NORM_QUAD4,[117,118,119,120])
+ mm2_1.insertNextCell(NORM_QUAD4,[121,122,123,124])
+ mm2_1.insertNextCell(NORM_QUAD4,[125,126,127,128])
+ mm2[-1]=mm2_1
+ mm2.setFamilyFieldArr(-1,DataArrayInt([200,201,202,203,204,205,206,207]))
+ mm2.setRenumFieldArr(-1,DataArrayInt([300,301,302,303,304,305,306,307]))
+ for i in range(1,12):
+ mm2.setFamilyId("G%d"%i,i+30)
+ mm2.setFamilyId("H1",100)
+ mm2.setFamilyId("FAMILLE_ZERO",0)
+ mm2.setFamiliesOnGroup("myGRP",["G2","G6"])
+ mm2.setFamiliesOnGroup("myGRP2",["G4","G7"])
+ mm2.setFamilyFieldArr(1,DataArrayInt([112,113,114,115,116]))
+ mm2.setRenumFieldArr(1,DataArrayInt([122,123,124,125,126]))
+ #
+ mm=MEDFileUMesh.Aggregate([mm1,mm2])
+ #######
+ def CheckMesh(tester,mm):
+ cooExp=DataArrayDouble([(1,2,10),(3,4,11),(5,6,12),(7,8,13),(9,10,30),(11,12,31),(13,14,32),(15,16,33),(17,18,34)]) ; cooExp.setInfoOnComponents(["aa [m]","bbb [kg]","cccc [MW]"])
+ tester.assertTrue(mm.getCoords().isEqual(cooExp,1e-12))
+ tester.assertTrue(mm[0].getNodalConnectivity().isEqual(DataArrayInt([14,0,1,2,3,14,4,5,6,7,14,104,105,106,107,14,108,109,110,111,14,112,113,114,115,16,8,9,10,11,12,13,16,14,15,16,17,18,19,16,20,21,22,23,24,25,16,116,117,118,119,120,121])))
+ tester.assertTrue(mm[0].getNodalConnectivityIndex().isEqual(DataArrayInt([0,5,10,15,20,25,32,39,46,53])))
+ tester.assertTrue(mm[-1].getNodalConnectivity().isEqual(DataArrayInt([3,0,1,2,3,3,4,5,3,104,105,106,3,107,108,109,3,110,111,112,4,6,7,8,9,4,10,11,12,13,4,14,15,16,17,4,18,19,20,21,4,113,114,115,116,4,117,118,119,120,4,121,122,123,124,4,125,126,127,128,4,129,130,131,132])))
+ tester.assertTrue(mm[-1].getNodalConnectivityIndex().isEqual(DataArrayInt([0,4,8,12,16,20,25,30,35,40,45,50,55,60,65])))
+ tester.assertTrue(mm.getFamilyFieldAtLevel(0).isEqual(DataArrayInt([1,2,40,41,42,3,4,5,43])))
+ tester.assertTrue(mm.getNumberFieldAtLevel(0).isEqual(DataArrayInt([11,12,50,51,52,13,14,15,53])))
+ tester.assertTrue(mm.getFamilyFieldAtLevel(-1).isEqual(DataArrayInt([6,7,200,201,202,8,9,10,11,203,204,205,206,207])))
+ tester.assertTrue(mm.getNumberFieldAtLevel(-1).isEqual(DataArrayInt([16,17,300,301,302,18,19,20,21,303,304,305,306,307])))
+ refFamIds=[("FAMILLE_ZERO",0),('F1',1),('F2',2),('F3',3),('F4',4),('F5',5),('F6',6),('F7',7),('F8',8),('F9',9),('G1',31),('G10',40),('G11',41),('G2',32),('G3',33),('G4',34),('G5',35),('G6',36),('G7',37),('G8',38),('G9',39),("H1",100)]
+ tester.assertEqual(set(mm.getFamiliesNames()),set([elt[0] for elt in refFamIds]))
+ tester.assertEqual(set([mm.getFamilyId(elt) for elt in mm.getFamiliesNames()]),set([elt[1] for elt in refFamIds]))
+ tester.assertEqual(mm.getGroupsNames(),('myGRP','myGRP1','myGRP2'))
+ tester.assertEqual(mm.getAllDistributionOfTypes(),[(NORM_TRI3,5),(NORM_QUAD4,9),(NORM_TETRA4,5),(NORM_PENTA6,4),(NORM_ERROR,9)])
+ pass
+ CheckMesh(self,mm)
+ ##
+ fieldName="zeField"
+ t1=(2.3,3,5)
+ t2=(5.6,7,12)
+ infoc=["dd [W]","eee [kA]"]
+ ##
+ fmts1=MEDFileFieldMultiTS()
+ f1ts1=MEDFileField1TS()
+ f1_1=MEDCouplingFieldDouble(ON_CELLS) ; f1_1.setMesh(mm1[0]) ; f1_1.setName(fieldName)
+ arr1=DataArrayDouble([(10,110),(11,111),(12,112),(13,113),(14,114)])
+ arr1.setInfoOnComponents(infoc)
+ f1_1.setArray(arr1) ; f1_1.setTime(*t1) ; f1_1.setTimeUnit("ms")
+ f1_1.checkConsistencyLight()
+ f1ts1.setFieldNoProfileSBT(f1_1)
+ #
+ f1_2=MEDCouplingFieldDouble(ON_CELLS) ; f1_2.setMesh(mm1[-1]) ; f1_2.setName(fieldName)
+ arr2=DataArrayDouble([(15,115),(16,116),(17,117),(18,118),(19,119),(20,120)])
+ arr2.setInfoOnComponents(infoc)
+ f1_2.setArray(arr2) ; f1_2.setTime(*t1) ; f1_2.setTimeUnit("ms")
+ f1_2.checkConsistencyLight()
+ f1ts1.setFieldNoProfileSBT(f1_2)
+ f1_3=MEDCouplingFieldDouble(ON_NODES) ; f1_3.setMesh(mm1[0]) ; f1_3.setName(fieldName)
+ arr3=DataArrayDouble([(21,121),(22,122),(23,123),(24,124)])
+ arr3.setInfoOnComponents(infoc)
+ f1_3.setArray(arr3) ; f1_3.setTime(*t1) ; f1_3.setTimeUnit("ms")
+ f1_3.checkConsistencyLight()
+ f1ts1.setFieldNoProfileSBT(f1_3)
+ fmts1.pushBackTimeStep(f1ts1)
+ #
+ f1ts2=f1ts1.deepCopy()
+ f1ts2.setTime(t2[1],t2[2],t2[0])
+ f1ts2.getUndergroundDataArray()[:]+=2000
+ fmts1.pushBackTimeStep(f1ts2)
+ ### fmts2
+ fmts2=MEDFileFieldMultiTS()
+ f1ts3=MEDFileField1TS()
+ f2_1=MEDCouplingFieldDouble(ON_CELLS) ; f2_1.setMesh(mm2[0]) ; f2_1.setName(fieldName)
+ arr4=DataArrayDouble([(50,150),(51,151),(52,152),(53,153)])
+ arr4.setInfoOnComponents(infoc)
+ f2_1.setArray(arr4) ; f2_1.setTime(*t1) ; f2_1.setTimeUnit("ms")
+ f2_1.checkConsistencyLight()
+ f1ts3.setFieldNoProfileSBT(f2_1)
+ f2_2=MEDCouplingFieldDouble(ON_CELLS) ; f2_2.setMesh(mm2[-1]) ; f2_2.setName(fieldName)
+ arr5=DataArrayDouble([(54,154),(55,155),(56,156),(57,157),(158,158),(59,159),(60,160),(61,161)])
+ arr5.setInfoOnComponents(infoc)
+ f2_2.setArray(arr5) ; f2_2.setTime(*t1) ; f2_2.setTimeUnit("ms")
+ f2_2.checkConsistencyLight()
+ f1ts3.setFieldNoProfileSBT(f2_2)
+ f2_3=MEDCouplingFieldDouble(ON_NODES) ; f2_3.setMesh(mm2[0]) ; f2_3.setName(fieldName)
+ arr6=DataArrayDouble([(62,162),(63,163),(64,164),(65,165),(66,166)])
+ arr6.setInfoOnComponents(infoc)
+ f2_3.setArray(arr6) ; f2_3.setTime(*t1) ; f2_3.setTimeUnit("ms")
+ f2_3.checkConsistencyLight()
+ f1ts3.setFieldNoProfileSBT(f2_3)
+ fmts2.pushBackTimeStep(f1ts3)
+ #
+ f1ts4=f1ts3.deepCopy()
+ f1ts4.setTime(t2[1],t2[2],t2[0])
+ f1ts4.getUndergroundDataArray()[:]+=2000
+ fmts2.pushBackTimeStep(f1ts4)
+ #
+ mfd1=MEDFileData()
+ mfd1.setMeshes(MEDFileMeshes())
+ mfd1.getMeshes().pushMesh(mm1)
+ mfd1.setFields(MEDFileFields())
+ mfd1.getFields().pushField(fmts1)
+ #
+ mfd2=MEDFileData()
+ mfd2.setMeshes(MEDFileMeshes())
+ mfd2.getMeshes().pushMesh(mm2)
+ mfd2.setFields(MEDFileFields())
+ mfd2.getFields().pushField(fmts2)
+ # ze Call !
+ mfd=MEDFileData.Aggregate([mfd1,mfd2])
+ def CheckMFD(tester,mfd):
+ tester.assertEqual(len(mfd.getMeshes()),1)
+ tester.assertEqual(len(mfd.getFields()),1)
+ CheckMesh(self,mfd.getMeshes()[0])
+ tester.assertEqual(len(mfd.getFields()[0]),2)
+ zeF1=mfd.getFields()[0][0]
+ zeF1_1=zeF1.getFieldOnMeshAtLevel(ON_CELLS,0,mfd.getMeshes()[0])
+ ref=MEDCouplingFieldDouble.MergeFields([f1_1,f2_1])
+ o2n=ref.getMesh().deepCopy().sortCellsInMEDFileFrmt()
+ ref.renumberCells(o2n)
+ tester.assertTrue(ref.isEqual(zeF1_1,1e-12,1e-12))
+ zeF1_2=zeF1.getFieldOnMeshAtLevel(ON_CELLS,-1,mfd.getMeshes()[0])
+ ref=MEDCouplingFieldDouble.MergeFields([f1_2,f2_2])
+ o2n=ref.getMesh().deepCopy().sortCellsInMEDFileFrmt()
+ ref.renumberCells(o2n)
+ tester.assertTrue(ref.isEqual(zeF1_2,1e-12,1e-12))
+ zeF1_3=zeF1.getFieldOnMeshAtLevel(ON_NODES,0,mfd.getMeshes()[0])
+ ref=MEDCouplingFieldDouble.MergeFields([f1_3,f2_3])
+ o2n=ref.getMesh().deepCopy().sortCellsInMEDFileFrmt()
+ ref.renumberCells(o2n)
+ tester.assertTrue(ref.isEqual(zeF1_3,1e-12,1e-12))
+ #
+ zeF2=mfd.getFields()[0][1]
+ zeF2_1=zeF2.getFieldOnMeshAtLevel(ON_CELLS,0,mfd.getMeshes()[0])
+ ref=MEDCouplingFieldDouble.MergeFields([f1_1,f2_1])
+ o2n=ref.getMesh().deepCopy().sortCellsInMEDFileFrmt()
+ ref.renumberCells(o2n)
+ ref.setTime(*t2) ; ref.getArray()[:]+=2000
+ tester.assertTrue(ref.isEqual(zeF2_1,1e-12,1e-12))
+ zeF2_2=zeF2.getFieldOnMeshAtLevel(ON_CELLS,-1,mfd.getMeshes()[0])
+ ref=MEDCouplingFieldDouble.MergeFields([f1_2,f2_2])
+ o2n=ref.getMesh().deepCopy().sortCellsInMEDFileFrmt()
+ ref.renumberCells(o2n)
+ ref.setTime(*t2) ; ref.getArray()[:]+=2000
+ tester.assertTrue(ref.isEqual(zeF2_2,1e-12,1e-12))
+ zeF2_3=zeF2.getFieldOnMeshAtLevel(ON_NODES,0,mfd.getMeshes()[0])
+ ref=MEDCouplingFieldDouble.MergeFields([f1_3,f2_3])
+ o2n=ref.getMesh().deepCopy().sortCellsInMEDFileFrmt()
+ ref.renumberCells(o2n)
+ ref.setTime(*t2) ; ref.getArray()[:]+=2000
+ tester.assertTrue(ref.isEqual(zeF2_3,1e-12,1e-12))
+ CheckMFD(self,mfd)
+ mfd1.write(fname1,2) ; mfd2.write(fname2,2)
+ mfd=MEDFileData.Aggregate([MEDFileData(fname1),MEDFileData(fname2)])
+ CheckMFD(self,mfd)
+ pass
+
+ def testExtrudedMesh1(self):
+ fname="Pyfile107.med"
+ arrX=DataArrayDouble([0,1,2,3]) ; arrY=DataArrayDouble([0,1,2,3,4]) ; arrZ=DataArrayDouble([0,1,2,3,4,5])
+ mesh3D=MEDCouplingCMesh() ; mesh3D.setCoords(arrX,arrY,arrZ) ; mesh3D.setName("mesh")
+ ex=MEDCouplingMappedExtrudedMesh(mesh3D)
+ mm=MEDFileUMesh(ex)
+ mm.write(fname,2)
+ ex2=mm.convertToExtrudedMesh()
+ mm2=MEDFileMesh.New(fname)
+ ex3=mm2.convertToExtrudedMesh()
+ self.assertTrue(ex.isEqual(ex2,1e-12))
+ self.assertTrue(ex.isEqual(ex3,1e-12))
+ pass
+
+ @unittest.skipUnless(LooseVersion(MEDFileVersionStr())>=LooseVersion('3.2.1'),"This test requires at least MEDFile version 3.2.1")
+ def testWriteInto30(self):
+ fname="Pyfile108.med"
+ fname2="Pyfile109.med"
+ m=MEDCouplingUMesh("mesh",1) ; m.setCoords(DataArrayDouble([0,0,1,1],2,2)) ; m.allocateCells() ; m.insertNextCell(NORM_SEG2,[1,0])
+ mm=MEDFileUMesh() ; mm[0]=m
+ mm.setFamilyId("FAMILLE_ZERO",0)
+ #
+ mm.write30(fname,2)
+ assert(LooseVersion(MEDFileVersionOfFileStr(fname)).version[:2]==[3,0]) # checks that just written MED file has a version == 3.0.x
+ mm2=MEDFileUMesh(fname)
+ self.assertTrue(mm.isEqual(mm2,1e-12))
+ #
+ mm.write(fname2,2)
+ assert(LooseVersion(MEDFileVersionOfFileStr(fname2)).version[:2]==list(MEDFileVersion()[:2])) # checks that MED file version of written mesh is thoose of the current MED file lib
+ pass
+
+ @unittest.skipUnless(MEDCouplingHasNumPyBindings(),"requires numpy")
+ def testPickelizationOfMEDFileObjects1(self):
+ fname="Pyfile110.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 range(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)
+ 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)
+ mfd=MEDFileData()
+ mfd.setMeshes(MEDFileMeshes()) ; mfd.setFields(MEDFileFields())
+ mfd.getMeshes().pushMesh(m)
+ fmts=MEDFileFieldMultiTS() ; fmts.pushBackTimeStep(f0)
+ mfd.getFields().pushField(fmts)
+ # first start gently
+ d=mfd.serialize()
+ mfd2=MEDFileData(d)
+ self.assertEqual(len(mfd2.getMeshes()),1)
+ self.assertEqual(len(mfd2.getFields()),1)
+ self.assertEqual(len(mfd2.getFields()[0]),1)
+ self.assertTrue(mfd2.getMeshes()[0].isEqual(mfd.getMeshes()[0],1e-12))
+ ff2=mfd2.getFields()[0][0].field(mfd2.getMeshes()[0])
+ ff =mfd.getFields()[0][0].field(mfd.getMeshes()[0])
+ self.assertTrue(ff2.isEqual(ff,1e-12,1e-12))
+ # OK now end of joke -> serialization of MEDFileData
+ st=pickle.dumps(mfd,pickle.HIGHEST_PROTOCOL)
+ mfd3=pickle.loads(st)
+ # check of object
+ self.assertEqual(len(mfd3.getMeshes()),1)
+ self.assertEqual(len(mfd3.getFields()),1)
+ self.assertEqual(len(mfd3.getFields()[0]),1)
+ self.assertTrue(mfd3.getMeshes()[0].isEqual(mfd.getMeshes()[0],1e-12))
+ ff3=mfd3.getFields()[0][0].field(mfd3.getMeshes()[0])
+ self.assertTrue(ff3.isEqual(ff,1e-12,1e-12))
+ # serialization of MEDFileFields
+ st=pickle.dumps(mfd.getFields(),pickle.HIGHEST_PROTOCOL)
+ fs4=pickle.loads(st)
+ ff4=fs4[0][0].field(mfd3.getMeshes()[0])
+ self.assertTrue(ff4.isEqual(ff,1e-12,1e-12))
+ # serialization of MEDFileFieldMulitTS
+ st=pickle.dumps(mfd.getFields()[0],pickle.HIGHEST_PROTOCOL)
+ fmts5=pickle.loads(st)
+ ff5=fmts5[0].field(mfd3.getMeshes()[0])
+ self.assertTrue(ff5.isEqual(ff,1e-12,1e-12))
+ # serialization of MEDFileField1TS
+ st=pickle.dumps(mfd.getFields()[0][0],pickle.HIGHEST_PROTOCOL)
+ f1ts6=pickle.loads(st)
+ ff6=f1ts6.field(mfd3.getMeshes()[0])
+ self.assertTrue(ff6.isEqual(ff,1e-12,1e-12))
+ # serialization of MEDFileMeshes
+ st=pickle.dumps(mfd.getMeshes(),pickle.HIGHEST_PROTOCOL)
+ ms7=pickle.loads(st)
+ self.assertEqual(len(ms7),1)
+ self.assertTrue(ms7[0].isEqual(mfd.getMeshes()[0],1e-12))
+ pass
+
+ @unittest.skipUnless(MEDCouplingHasNumPyBindings(),"requires numpy")
+ def testPickelizationOfMEDFileObjects2(self):
+ # CMesh
+ self.testMEDMesh6() # generates MEDFileMesh5.med file
+ mm=MEDFileMesh.New("MEDFileMesh5.med")
+ self.assertTrue(isinstance(mm,MEDFileCMesh))
+ st=pickle.dumps(mm,pickle.HIGHEST_PROTOCOL)
+ mm2=pickle.loads(st)
+ self.assertTrue(isinstance(mm2,MEDFileCMesh))
+ self.assertTrue(mm.getMesh().isEqual(mm2.getMesh(),1e-12))
+ # CurveLinear
+ self.testCurveLinearMesh1() # generates Pyfile55.med
+ mm=MEDFileMesh.New("Pyfile55.med")
+ self.assertTrue(isinstance(mm,MEDFileCurveLinearMesh))
+ st=pickle.dumps(mm,pickle.HIGHEST_PROTOCOL)
+ mm3=pickle.loads(st)
+ self.assertTrue(isinstance(mm3,MEDFileCurveLinearMesh))
+ self.assertTrue(mm.getMesh().isEqual(mm3.getMesh(),1e-12))
+ self.testInt32InMEDFileFieldStar1()# generates Pyfile63.med
+ # MEDFileIntFieldMultiTS
+ fs4=MEDFileFields("Pyfile63.med")
+ ms4=MEDFileMeshes("Pyfile63.med")
+ self.assertTrue(isinstance(fs4[0],MEDFileIntFieldMultiTS))
+ st=pickle.dumps(fs4[0],pickle.HIGHEST_PROTOCOL)
+ fmts5=pickle.loads(st)
+ self.assertEqual(len(fs4[0]),len(fmts5))
+ self.assertTrue(isinstance(fmts5,MEDFileIntFieldMultiTS))
+ self.assertTrue(fmts5[0].field(ms4[0]).isEqual((fs4[0][0]).field(ms4[0]),1e-12,0))
+ # MEDFileIntField1TS
+ st=pickle.dumps(fs4[0][0],pickle.HIGHEST_PROTOCOL)
+ f1ts6=pickle.loads(st)
+ self.assertTrue(isinstance(f1ts6,MEDFileIntField1TS))
+ self.assertTrue(f1ts6.field(ms4[0]).isEqual((fs4[0][0]).field(ms4[0]),1e-12,0))
+ # MEDFileParameters
+ self.testParameters1()# generates Pyfile56.med
+ params=MEDFileParameters("Pyfile56.med")
+ st=pickle.dumps(params,pickle.HIGHEST_PROTOCOL)
+ params7=pickle.loads(st)
+ self.assertEqual(len(params),len(params7))
+ for i in range(len(params)):
+ self.assertTrue(params[i].isEqual(params7[i],1e-12)[0])
+ pass
+ pass
+
+ def testGlobalNumOnNodes1(self):
+ """Test global number on nodes here. Used by partitionners."""
+ fname="Pyfile112.med"
+ arr=DataArrayDouble(5) ; arr.iota()
+ m=MEDCouplingUMesh.Build1DMeshFromCoords(arr)
+ m.setName("mesh")
+ mm=MEDFileUMesh()
+ mm[0]=m
+ self.assertTrue(not mm.getGlobalNumFieldAtLevel(1))
+ d=DataArrayInt([7,8,9,2,0])
+ dRef=d.deepCopy()
+ mm.setGlobalNumFieldAtLevel(1,d)
+ mm.checkConsistency()
+ self.assertRaises(InterpKernelException,mm.setGlobalNumFieldAtLevel,1,d[::2])
+ mm.checkConsistency()
+ self.assertEqual(d.getHiddenCppPointer(),mm.getGlobalNumFieldAtLevel(1).getHiddenCppPointer())
+ self.assertTrue(mm.getGlobalNumFieldAtLevel(1).isEqual(dRef))
+ mm.write(fname,2)
+ mm2=MEDFileMesh.New(fname)
+ self.assertTrue(mm.isEqual(mm2,1e-12)[0])
+ self.assertTrue(mm2.getGlobalNumFieldAtLevel(1).isEqual(dRef))
+ mm2.getGlobalNumFieldAtLevel(1).setIJ(0,0,10)
+ self.assertTrue(not mm.isEqual(mm2,1e-12)[0])
+ mm2.getGlobalNumFieldAtLevel(1).setIJ(0,0,7)
+ self.assertTrue(mm.isEqual(mm2,1e-12)[0])
+ pass
+
+ def testPartialReadOfEntities1(self):
+ """Test for advanced API on read to speed up read phase for users with "huge" number of time steps (more than 10 000)."""
+ fname="Pyfile113.med"
+ arr=DataArrayDouble(5) ; arr.iota()
+ m=MEDCouplingUMesh.Build1DMeshFromCoords(arr)
+ m.setName("mesh")
+ mm=MEDFileUMesh()
+ mm[0]=m
+ #
+ fieldName="Field"
+ ts1=(5.,1,2)
+ f1=MEDCouplingFieldDouble(ON_NODES) ; f1.setMesh(m) ; f1.setName(fieldName)
+ f1.setArray(DataArrayDouble([0.,0.1,0.2,0.3,0.4]))
+ f1.setTime(*ts1)
+ f2=MEDCouplingFieldDouble(ON_CELLS) ; f2.setMesh(m) ; f2.setName(fieldName)
+ f2.setArray(DataArrayDouble([1.,1.1,1.2,1.3]))
+ f2.setTime(*ts1)
+ f1ts=MEDFileField1TS()
+ f1ts.setFieldNoProfileSBT(f1)
+ f1ts.setFieldNoProfileSBT(f2)
+ self.assertEqual(set(f1ts.getTypesOfFieldAvailable()),set([ON_NODES,ON_CELLS]))
+ f1ts_2=f1ts.deepCopy()
+ f1ts_2.getUndergroundDataArray()[:]+=2
+ f1ts_2.setTime(3,4,6.)
+ fmts=MEDFileFieldMultiTS()
+ fmts.pushBackTimeStep(f1ts)
+ fmts.pushBackTimeStep(f1ts_2)
+ #
+ mm.write(fname,2)
+ fmts.write(fname,0)
+ #
+ ent=MEDFileEntities.BuildFrom([(ON_NODES,NORM_ERROR)])
+ mm=MEDFileMesh.New(fname)
+ fs=MEDFileFields(fname,False,ent) # the important line is here - We specify to MEDFileFields to read only nodes part to speed up read phase (by avoiding to scan all entities time geo types)
+ fs.loadArrays()
+ self.assertEqual(len(fs),1)
+ fmts=fs[0]
+ self.assertEqual(len(fmts),2)
+ ff0=fmts[0] ; ff1=fmts[1]
+ self.assertEqual(ff0.getTypesOfFieldAvailable(),[ON_NODES]) # only NODES have been loaded
+ self.assertTrue(ff0.field(mm).isEqual(f1,1e-12,1e-12))
+ f3=f1.deepCopy() ; f3+=2. ; f3.setTime(6.,3,4)
+ self.assertTrue(ff1.field(mm).isEqual(f3,1e-12,1e-12))
+ pass
+
+ def testFloat32InMEDFileFieldStar1(self):
+ """Like testInt32InMEDFileFieldStar1 but with float32 :)"""
+ fname="Pyfile114.med"
+ f1=MEDLoaderDataForTest.buildVecFieldOnCells_1();
+ f1=f1.convertToFloatField()
+ m1=f1.getMesh()
+ mm1=MEDFileUMesh.New()
+ mm1.setCoords(m1.getCoords())
+ mm1.setMeshAtLevel(0,m1)
+ mm1.setName(m1.getName())
+ mm1.write(fname,2)
+ ff1=MEDFileFloatField1TS()
+ ff1.setFieldNoProfileSBT(f1)
+ a=ff1.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertEqual(a.getArray().getInfoOnComponents(),['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ 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,MEDFileFloatField1TS))
+ a=ff1.getFieldOnMeshAtLevel(ON_CELLS,0,mm1)
+ self.assertEqual(a.getArray().getInfoOnComponents(),['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ 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,MEDFileFloatFieldMultiTS))
+ a=ffs1[2.].getFieldOnMeshAtLevel(ON_CELLS,0,mm1)
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12))
+ a=ffs1.getFieldOnMeshAtLevel(ON_CELLS,0,1,0,mm1)
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12))
+ it=ffs1.__iter__() ; it.next() ; ff2bis=it.next()
+ a=ff2bis.getFieldOnMeshAtLevel(0,ON_CELLS,mm1)
+ self.assertTrue(a.getArray().isEqual(2*f1.getArray(),1e-7))
+ f1.setTime(3.,1,2) ; f1.getArray()[:]*=2
+ self.assertTrue(a.isEqual(f1,1e-12,1e-12)) ; f1.getArray()[:]/=2
+ bc=DataArrayFloat(6,3) ; bc[:]=0 ; bc.setInfoOnComponents(['power [MW/m^3]','density [g/cm^3]','temperature [K]'])
+ for it in ffs1:
+ a=it.getFieldOnMeshAtLevel(ON_CELLS,0,mm1)
+ bc+=a.getArray()
+ pass
+ self.assertTrue(bc.isEqual(3*f1.getArray(),1e-7))
+ nf1=MEDCouplingFieldFloat(ON_NODES)
+ nf1.setTime(9.,10,-1)
+ nf1.setMesh(f1.getMesh())
+ narr=DataArrayFloat(12,2) ; narr.setInfoOnComponents(["aa [u1]","bbbvv [ppp]"]) ; narr[:,0]=list(range(12)) ; narr[:,1]=2*narr[:,0]
+ nf1.setName("VectorFieldOnNodes") ; nf1.setArray(narr)
+ nff1=MEDFileFloatField1TS.New()
+ nff1.setFieldNoProfileSBT(nf1)
+ self.assertEqual(nff1.getInfo(),('aa [u1]','bbbvv [ppp]'))
+ self.assertEqual(nff1.getTime(),[10,-1,9.0])
+ nff1.write(fname,0)
+ #
+ nf2=MEDCouplingFieldFloat(ON_NODES)
+ nf2.setTime(19.,20,-11)
+ nf2.setMesh(f1.getMesh())
+ narr2=DataArrayFloat(8,2) ; narr.setInfoOnComponents(["aapfl [u1]","bbbvvpfl [ppp]"]) ; narr2[:,0]=list(range(8)) ; narr2[:,0]+=10 ; narr2[:,1]=3*narr2[:,0]
+ nf2.setName("VectorFieldOnNodesPfl") ; narr2.setName(nf2.getName()) ; nf2.setArray(narr2)
+ nff2=MEDFileFloatField1TS.New()
+ npfl=DataArrayInt([1,2,4,5,6,7,10,11]) ; npfl.setName("npfl")
+ nff2.setFieldProfile(nf2,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(narr2,1e-7))
+ nff2.write(fname,0)
+ nff2bis=MEDFileFloatField1TS(fname,"VectorFieldOnNodesPfl")
+ a,b=nff2bis.getFieldWithProfile(ON_NODES,0,mm1) ; b.setName(npfl.getName())
+ self.assertTrue(b.isEqual(npfl))
+ self.assertTrue(a.isEqual(narr2,1e-7))
+ #
+ 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],MEDFileFloatFieldMultiTS))
+ self.assertTrue(isinstance(ffs[1],MEDFileFloatFieldMultiTS))
+ self.assertTrue(isinstance(ffs[2],MEDFileFieldMultiTS))
+ self.assertTrue(isinstance(ffs[3],MEDFileFloatFieldMultiTS))
+ #
+ self.assertTrue(fs["VectorFieldOnCells"][0].getUndergroundDataArray().isEqualWithoutConsideringStr(f1.getArray(),1e-7))
+ self.assertTrue(fs["VectorFieldOnCells"][1,2].getUndergroundDataArray().isEqualWithoutConsideringStr(2*f1.getArray(),1e-7))
+ self.assertTrue(fs["VectorFieldOnNodesPfl"][0].getUndergroundDataArray().isEqualWithoutConsideringStr(narr2,1e-7))
+ self.assertTrue(fs["VectorFieldOnNodes"][9.].getUndergroundDataArray().isEqualWithoutConsideringStr(narr,1e-7))
+ 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,MEDFileFloatFieldMultiTS.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,MEDFileFloatField1TS.New,fname,"VectorFieldOnNodesDouble",30,-21)# exception because trying to read a double field with int instance
+ MEDFileFloatField1TS.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
+
pass
if __name__ == "__main__":
- unittest.main()
+ unittest.main()
