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|
##############################################################################
#
# Copyright (c) 2003-2018 by The University of Queensland
# http://www.uq.edu.au
#
# Primary Business: Queensland, Australia
# Licensed under the Apache License, version 2.0
# http://www.apache.org/licenses/LICENSE-2.0
#
# Development until 2012 by Earth Systems Science Computational Center (ESSCC)
# Development 2012-2013 by School of Earth Sciences
# Development from 2014 by Centre for Geoscience Computing (GeoComp)
#
##############################################################################
from __future__ import print_function, division
__copyright__="""Copyright (c) 2003-2018 by The University of Queensland
http://www.uq.edu.au
Primary Business: Queensland, Australia"""
__license__="""Licensed under the Apache License, version 2.0
http://www.apache.org/licenses/LICENSE-2.0"""
__url__="https://launchpad.net/escript-finley"
import os
import sys
import esys.escriptcore.utestselect as unittest
from esys.escriptcore.testing import *
from esys.escript import *
from esys.finley import Rectangle, Brick, ReadMesh, ReadGmsh
from test_objects import Test_Dump, Test_SetDataPointValue, Test_saveCSV, \
Test_TableInterpolation, Test_Domain, Test_Lazy, Test_tagMap
from test_shared import Test_Shared
try:
FINLEY_WORKDIR=os.environ['FINLEY_WORKDIR']
except KeyError:
FINLEY_WORKDIR='.'
try:
FINLEY_TEST_DATA=os.environ['FINLEY_TEST_DATA']
except KeyError:
FINLEY_TEST_DATA='.'
FINLEY_TEST_MESH_PATH=os.path.join(FINLEY_TEST_DATA,"data_meshes")
mpisize=getMPISizeWorld()
NE=4 # number of elements, must be even
class Test_SharedOnFinley(Test_Shared):
def setUp(self):
self.domain=Rectangle(NE,NE)
self.tol=0.001
def tearDown(self):
del self.domain
del self.tol
class Test_DomainOnFinley(Test_Domain):
def setUp(self):
self.boundary_tag_list = [1, 2, 10, 20]
self.domain =Rectangle(NE,NE+1,2)
self.rdomain=self.domain
def tearDown(self):
del self.domain
del self.rdomain
del self.boundary_tag_list
def test_setXError(self):
domain=Rectangle(NE,NE)
x=domain.getX()
z=interpolate(x, Function(domain))
self.assertRaises(ValueError, domain.setX, z)
del x
del z
del domain
def test_tagsContinuousFunction(self):
ref_tags=[0]
tags=ContinuousFunction(self.domain).getListOfTags()
self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in ref_tags: self.assertTrue(i in tags,"tag %s is missing."%i)
def test_tagsFunction(self):
ref_tags=[0]
tags=Function(self.domain).getListOfTags()
self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in ref_tags: self.assertTrue(i in tags,"tag %s is missing."%i)
def test_tagsReducedFunction(self):
ref_tags=[0]
tags=ReducedFunction(self.domain).getListOfTags()
self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in ref_tags: self.assertTrue(i in tags,"tag %s is missing."%i)
def test_tagsFunctionOnBoundary(self):
ref_tags=[1, 2, 10, 20]
tags=FunctionOnBoundary(self.domain).getListOfTags()
# For an MPI-distributed domain some tags may be missing
if getMPISizeWorld() == 1: self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in tags: self.assertTrue(i in ref_tags,"tag %s is missing."%i)
def test_tagsReducedFunctionOnBoundary(self):
ref_tags=[1, 2, 10, 20]
tags=ReducedFunctionOnBoundary(self.domain).getListOfTags()
# For an MPI-distributed domain some tags may be missing
if getMPISizeWorld() == 1: self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in tags: self.assertTrue(i in ref_tags,"tag %s is missing."%i)
def test_tagsFunctionOnContactOne(self):
ref_tags=[]
tags=FunctionOnContactOne(self.domain).getListOfTags()
self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in ref_tags: self.assertTrue(i in tags,"tag %s is missing."%i)
def test_tagsFunctionOnContactZero(self):
ref_tags=[]
tags=FunctionOnContactZero(self.domain).getListOfTags()
self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in ref_tags: self.assertTrue(i in tags,"tag %s is missing."%i)
def test_tagsReducedFunctionOnContactOne(self):
ref_tags=[]
tags=ReducedFunctionOnContactOne(self.domain).getListOfTags()
self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in ref_tags: self.assertTrue(i in tags,"tag %s is missing."%i)
def test_tagsReducedFunctionOnContactZero(self):
ref_tags=[]
tags=ReducedFunctionOnContactZero(self.domain).getListOfTags()
self.assertTrue(len(tags)==len(ref_tags), "tags list has wrong length.")
for i in ref_tags: self.assertTrue(i in tags,"tag %s is missing."%i)
class Test_DumpOnFinley(Test_Dump):
def setUp(self):
self.domain = Rectangle(NE, NE+1, 2)
self.domain_with_different_number_of_samples =Rectangle(2*NE,NE+1,2)
self.domain_with_different_number_of_data_points_per_sample =Rectangle(2*NE,NE+1,2,integrationOrder=2)
self.domain_with_different_sample_ordering =Rectangle(NE,NE+1,2, optimize=True)
self.filename_base=FINLEY_WORKDIR
def tearDown(self):
del self.domain
del self.domain_with_different_number_of_samples
del self.domain_with_different_number_of_data_points_per_sample
del self.domain_with_different_sample_ordering
class Test_SetDataPointValueOnFinley(Test_SetDataPointValue):
def setUp(self):
self.domain = Rectangle(NE, NE+1, 2)
def tearDown(self):
del self.domain
class Test_LazyOnFinley(Test_Lazy):
def setUp(self):
self.domain = Rectangle(NE,NE+1,2)
self.mainfs = Function(self.domain)
self.otherfs = Solution(self.domain)
def tearDown(self):
del self.domain
del self.mainfs
del self.otherfs
class Test_tagMapOnFinley(Test_tagMap):
def setUp(self):
self.domain=Brick(2,2,2)
self.functionspaces=[ContinuousFunction(self.domain), Function(self.domain), ReducedFunction(self.domain),
FunctionOnBoundary(self.domain), ReducedFunctionOnBoundary(self.domain),
FunctionOnContactZero(self.domain), FunctionOnContactOne(self.domain),
ReducedFunctionOnContactZero(self.domain), ReducedFunctionOnContactOne(self.domain)]
def tearDown(self):
del self.domain
del self.functionspaces
class Test_TableInterpolationOnFinley(Test_TableInterpolation):
def setUp(self):
self.domain=Brick(4,4,4)
self.functionspaces=[ContinuousFunction(self.domain), Function(self.domain), ReducedFunction(self.domain),
FunctionOnBoundary(self.domain), ReducedFunctionOnBoundary(self.domain),
FunctionOnContactZero(self.domain), FunctionOnContactOne(self.domain),
ReducedFunctionOnContactZero(self.domain), ReducedFunctionOnContactOne(self.domain)]
#We aren't testing DiracDeltaFunctions
self.xn=3 # number of grids on x axis
self.yn=3 # number of grids on y axis
self.zn=3 # number of grids on z axis
def tearDown(self):
del self.domain
del self.functionspaces
# This functionality is only tested on Finley.
# It is not finley specific but it does need a known set of input points
# so I've chosen to put it here
class Test_OtherInterpolationOnFinley(unittest.TestCase):
def setUp(self):
self.r=Rectangle(4,1).getX()[0]+2
self.z=Data(2)
def tearDown(self):
del self.z
del self.r
def test_nonuniformint(self):
self.assertRaises(RuntimeError, self.z.nonuniformInterpolate, [0,1], [5,6], True)
self.assertRaises(RuntimeError, self.z.nonuniformInterpolate, [3,4], [5,6], True)
self.assertTrue(Lsup(self.z.nonuniformInterpolate([0,1], [5,6], False)-6)<0.00001, "RHS edge not fitted")
self.assertTrue(Lsup(self.z.nonuniformInterpolate([3,4], [5,6], False)-5)<0.00001, "LHS edge not fitted")
tmp=self.r.nonuniformInterpolate([2.125, 2.4, 2.5, 2.8], [1, -1, 2, 4], False)
self.assertTrue(Lsup(sup(tmp)-4)<0.0001, "RHS edge not fitted for Rect")
self.assertTrue(Lsup(inf(tmp)-0.090909)<0.00001, "Internal interpolate failed")
tmp=self.r.nonuniformInterpolate([2.125, 2.4, 2.5, 3.2], [1, -1, 2, 4], False)
self.assertTrue(Lsup(sup(tmp)-3.42857)<0.00001, "Internal interpolate failed")
def test_nonuniformSlope(self):
self.assertRaises(RuntimeError, self.z.nonuniformSlope, [0,1], [5,6], True)
self.assertRaises(RuntimeError, self.z.nonuniformSlope, [3,4], [5,6], True)
self.assertTrue(Lsup(self.z.nonuniformSlope([0,1], [5,6], False))<0.00001, "RHS edge not fitted")
self.assertTrue(Lsup(self.z.nonuniformSlope([3,4], [5,6], False))<0.00001, "LHS edge not fitted")
tmp=self.r.nonuniformSlope([2.125, 2.4, 2.5, 3.2], [1, -1, 2, 4], False)
self.assertTrue(Lsup(sup(tmp)-30)<0.00001, "Internal interpolate failed")
self.assertTrue(Lsup(inf(tmp)+7.27273)<0.00001, "Internal interpolate failed")
class Test_CSVOnFinley(Test_saveCSV):
def setUp(self):
try:
self.workdir=os.environ['FINLEY_WORKDIR']
except KeyError:
self.workdir='.'
NE0=NE
NE1=NE+1
self.domain = Rectangle(NE0, NE1, order=2)
self.functionspaces = [ ContinuousFunction ]
# number of total data points for each function space
self.linecounts=[ (2*NE0+1)*(2*NE1+1)-NE0*NE1+1 ]
# number of masked points, i.e. where X[0] is non-zero
self.linecounts_masked=[ (2*NE0+1)*(2*NE1+1)-(2+NE0)*NE1 ]
# expected values in first line of masked data = [ X[:], X[0] ]
self.firstline=[ [1./(2*NE0), 0., 1./(2*NE0)] ]
if getMPISizeWorld() == 1:
self.functionspaces += [ ReducedContinuousFunction, Function,
ReducedFunction, FunctionOnBoundary, ReducedFunctionOnBoundary ]
self.linecounts += [ 31, 181, 81, 55, 37 ]
self.linecounts_masked += [ 25, 181, 81, 40, 27 ]
self.firstline += [ [.25, 0., .25],
[.02817541634481463,.02254033307585171,.02817541634481463],
[.05283121635129676,.04226497308103741,.05283121635129676],
[.02817541634481463,0.,.02817541634481463],
[.05283121635129676,0.,.05283121635129676]
]
else:
print("Skipping some CSV tests on finley since MPI size > 1")
def tearDown(self):
del self.domain
@unittest.skipIf(mpisize > 1, "more than 1 MPI rank")
def test_csv_multiFS(self):
fname=os.path.join(self.workdir, "test_multifs.csv")
sol=Data(8,Solution(self.domain))
ctsfn=Data(9,ContinuousFunction(self.domain))
#test line 0
dirac=Data(-1,DiracDeltaFunctions(self.domain))
saveDataCSV(fname, A=sol, B=ctsfn, C=dirac)
#test line 1
fun=Data(5,Function(self.domain))
rfun=Data(3,ReducedFunction(self.domain))
saveDataCSV(fname, A=sol,B=ctsfn,C=fun, D=rfun)
#test line 2
bound=Data(1,FunctionOnBoundary(self.domain))
rbound=Data(3,ReducedFunctionOnBoundary(self.domain))
saveDataCSV(fname,A=sol,B=ctsfn,C=bound, D=rbound)
#test line 3
conzz=Data(7,FunctionOnContactZero(self.domain))
rconz=Data(8,ReducedFunctionOnContactZero(self.domain))
saveDataCSV(fname,A=sol,B=ctsfn, C=conzz, D=rconz)
#check for cross line exceptions
self.assertRaises(RuntimeError, saveDataCSV, fname, A=dirac, B=rfun)
self.assertRaises(RuntimeError, saveDataCSV, fname, A=bound, B=conzz)
class Test_DiracOnFinley(unittest.TestCase):
def test_rectconstr(self):
self.assertRaises(ValueError, Rectangle, 4,4, diracPoints=[(0,0)])
self.assertRaises(ValueError, Rectangle, 4,4, diracPoints=[(0,0), (1,1)], diracTags=[40])
self.assertRaises(ValueError, Rectangle, 4,4, diracPoints=[(0,0), (1,1)], diracTags=[40])
self.assertRaises(ValueError, Rectangle, 4,4, diracPoints=[(0,0), (1,1)], diracTags=["cows"])
self.assertRaises(ValueError, Rectangle, 4,4, diracPoints=[(0,)], diracTags=["test"])
z=Rectangle(4,4, diracPoints=[(0,0), (0.25,0.25)], diracTags=[40,51])
z=Rectangle(4,4, diracPoints=[(0.125,0.625), (0.5,1), (0.75, 0.25), (0.89, 0.875)], diracTags=["A", "B", "A", "C"])
v=interpolate(z.getX(), DiracDeltaFunctions(z))
if mpisize==1:
self.assertEqual(v.toListOfTuples(),[(0.0, 0.5), (0.5, 1.0), (0.75, 0.25), (1.0, 0.75)])
self.assertEqual(v.getNumberOfDataPoints(), 4)
self.assertEqual(inf(v[0]), 0)
self.assertEqual(inf(v[1]), 0.25)
self.assertEqual(Lsup(v[0]), 1)
self.assertEqual(Lsup(v[1]), 1)
v.setTaggedValue("A",(-10,0.5))
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
v.setTaggedValue(500,(-100,-100)) # non-existant tag
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
self.assertEqual(z.showTagNames(), 'A, B, C, bottom, left, right, top')
self.assertEqual(z.getTag("C"), 42)
def test_brickconstr(self):
self.assertRaises(ValueError, Brick, 4,4, diracPoints=[(0,0,0)])
self.assertRaises(ValueError, Brick, 4,4, diracPoints=[(0,0,0), (1,1,1)], diracTags=[40])
self.assertRaises(ValueError, Brick, 4,4, diracPoints=[(0,0,0), (1,1,1)], diracTags=[40])
self.assertRaises(ValueError, Brick, 4,4, diracPoints=[(0,0,0), (1,1,1)], diracTags=["cows"])
self.assertRaises(ValueError, Brick, 4,4, diracPoints=[(0,0)], diracTags=["test"])
z=Brick(4,4, diracPoints=[(0,0,0), (0.25,0.25, 0.25)], diracTags=[40,51])
z=Brick(4,4, diracPoints=[(0.125,0.625,0), (0.5,1,0), (0.75, 0.25, 0.51), (0.89, 0.875,1)], diracTags=["A", "B", "A", "C"])
v=interpolate(z.getX(), DiracDeltaFunctions(z))
if mpisize==1:
self.assertEqual(v.toListOfTuples(),[(0.0, 0.5, 0.0), (0.5, 1.0, 0.0), (0.75, 0.25, 1), (1.0, 0.75, 1.0)])
self.assertEqual(v.getNumberOfDataPoints(), 4)
self.assertEqual(inf(v[0]), 0)
self.assertEqual(inf(v[1]), 0.25)
self.assertEqual(Lsup(v[0]), 1)
self.assertEqual(Lsup(v[1]), 1)
v.setTaggedValue("A",(-10,0.5,-500))
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
self.assertEqual(inf(v[2]),-500)
v.setTaggedValue(500,(-100,-100, -100)) # non-existant tag
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
self.assertEqual(z.showTagNames(), 'A, B, C, back, bottom, front, left, right, top')
self.assertEqual(z.getTag("C"), 42)
def test_rectReadMesh(self):
fname=os.path.join(FINLEY_TEST_MESH_PATH,'rect_4x4.fly')
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,)])
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,0)])
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,0), (1,1)], diracTags=[40])
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,0), (1,1)], diracTags=["cows"])
z=ReadMesh(fname, diracPoints=[(0,0), (0.25,0.25)], diracTags=[40,51])
z=ReadMesh(fname, diracPoints=[(0.125,0.625), (0.5,1), (0.75, 0.25), (0.89, 0.875)], diracTags=["A", "B", "A", "C"])
v=interpolate(z.getX(), DiracDeltaFunctions(z))
if mpisize==1:
self.assertEqual(v.toListOfTuples(),[(0.0, 0.5), (0.5, 1.0), (0.75, 0.25), (1.0, 0.75)])
self.assertEqual(v.getNumberOfDataPoints(), 4)
self.assertEqual(inf(v[0]), 0)
self.assertEqual(inf(v[1]), 0.25)
self.assertEqual(Lsup(v[0]), 1)
self.assertEqual(Lsup(v[1]), 1)
v.setTaggedValue("A",(-10,0.5))
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
v.setTaggedValue(500,(-100,-100)) # non-existant tag
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
self.assertEqual(z.showTagNames(), 'A, B, C, bottom, left, right, top')
self.assertEqual(z.getTag("C"), 42)
def test_brickReadMesh(self):
fname=os.path.join(FINLEY_TEST_MESH_PATH,'brick_4x4x4.fly')
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,0)])
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,0,0)])
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,0,0), (1,1,1)], diracTags=[40])
self.assertRaises(ValueError, ReadMesh, fname, diracPoints=[(0,0,0), (1,1,1)], diracTags=["cows"])
z=ReadMesh(fname, diracPoints=[(0,0,1), (0.25,0.25, 0.25)], diracTags=[40,51])
z=ReadMesh(fname, diracPoints=[(0.125,0.625,0), (0.5,1,1), (0.75, 0.25,0), (0.89, 0.875, 0.5)], diracTags=["A", "B", "A", "C"])
v=interpolate(z.getX(), DiracDeltaFunctions(z))
if mpisize==1:
self.assertEqual(v.toListOfTuples(),[(0.0, 0.5, 0.0), (0.5, 1.0, 1.0), (0.75, 0.25, 0.0), (1.0, 0.75, 0.5)])
self.assertEqual(v.getNumberOfDataPoints(), 4)
self.assertEqual(inf(v[0]), 0)
self.assertEqual(inf(v[1]), 0.25)
self.assertEqual(Lsup(v[0]), 1)
self.assertEqual(Lsup(v[1]), 1)
v.setTaggedValue("A",(-10,0.5,-0.5))
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
self.assertEqual(inf(v[2]), -0.5)
v.setTaggedValue(500,(-100,-100, -100)) # non-existant tag
if mpisize==1:
self.assertEqual(inf(v[0]), -10)
self.assertEqual(inf(v[1]), 0.5)
self.assertEqual(inf(v[2]), -0.5)
self.assertEqual(z.showTagNames(), 'A, B, C, back, bottom, front, left, right, top')
self.assertEqual(z.getTag("C"), 203)
def test_rectReadGmsh(self):
fname=os.path.join(FINLEY_TEST_MESH_PATH, 'rect_test.msh')
self.assertRaises(ValueError, ReadGmsh, fname, 2, diracPoints=[(0,0)])
self.assertRaises(ValueError, ReadGmsh, fname, 2, diracPoints=[(0,0), (1,1)], diracTags=[40])
self.assertRaises(ValueError, ReadGmsh, fname, 2, diracPoints=[(0,0), (1,1)], diracTags=["cows"])
z=ReadGmsh(fname, 2, diracPoints=[(0,0), (1,1)], diracTags=[40,51])
z=ReadGmsh(fname, 2, diracPoints=[(0,0),(0,1),(1,0),(1,1)], diracTags=["A", "B", "A", "C"])
v=interpolate(z.getX(), DiracDeltaFunctions(z))
if mpisize==1:
self.assertEqual(v.toListOfTuples(),[(0,0), (0,1), (1,0), (1,1)])
self.assertEqual(v.getNumberOfDataPoints(), 4)
v.setTaggedValue("A",(-10,99))
self.assertEqual(inf(v[0]), -10)
self.assertEqual(Lsup(v[1]), 99)
v.setTaggedValue(500,(-100,-100)) # non-existant tag
self.assertEqual(inf(v[0]), -10)
self.assertEqual(Lsup(v[1]), 99)
self.assertEqual(z.showTagNames(), 'A, B, C')
self.assertEqual(z.getTag("C"), 42)
def test_brickReadGmsh(self):
fname=os.path.join(FINLEY_TEST_MESH_PATH, 'brick_test.msh')
self.assertRaises(ValueError, ReadGmsh, fname, 3, diracPoints=[(0,0)])
self.assertRaises(ValueError, ReadGmsh, fname, 3, diracPoints=[(0,0,0)])
self.assertRaises(ValueError, ReadGmsh, fname, 3, diracPoints=[(0,0,0), (1,1,1)], diracTags=[40])
self.assertRaises(ValueError, ReadGmsh, fname, 3, diracPoints=[(0,0,0), (1,1,1)], diracTags=["cows"])
z=ReadGmsh(fname, 3, diracPoints=[(0,0,0), (1,1,1)], diracTags=[40,51])
z=ReadGmsh(fname, 3, diracPoints=[(0,0,0),(0,1,0),(1,0,1),(1,1,1)], diracTags=["A", "B", "A", "C"])
v=interpolate(z.getX(), DiracDeltaFunctions(z))
if mpisize==1:
self.assertEqual(v.toListOfTuples(),[(0,0,0), (0,1,0), (1,0,1), (1,1,1)])
self.assertEqual(v.getNumberOfDataPoints(), 4)
v.setTaggedValue("A",(-10,99,-98))
self.assertEqual(inf(v[0]), -10)
self.assertEqual(Lsup(v[1]), 99)
self.assertEqual(inf(v[2]), -98)
v.setTaggedValue(500,(-100,-100,-100)) # non-existant tag
self.assertEqual(inf(v[0]), -10)
self.assertEqual(Lsup(v[1]), 99)
self.assertEqual(z.showTagNames(), 'A, B, C')
self.assertEqual(z.getTag("C"), 42)
if __name__ == '__main__':
run_tests(__name__, exit_on_failure=True)
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