def test_setitem( self ):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW.create( "KW" , grid , EclTypeEnum.ECL_FLOAT_TYPE , default_value = 77)
with self.assertRaises(IndexError):
kw[1000]
with self.assertRaises(IndexError):
kw[0,10,100]
with self.assertRaises(ValueError):
kw[1,1]
with self.assertRaises(ValueError):
kw[1,1,1,1]
kw.assign(99)
self.assertEqual( kw[0,0,0] , 77 )
self.assertEqual( kw[0,0,1] , 99 )
with self.assertRaises(ValueError):
kw[0,0,0] = 88
kw[0,0,1] = 100
self.assertEqual( kw[0,0,1] , 100 )
def test_region_filter(self):
nx = 10
ny = 10
nz = 1
actnum = IntVector( initial_size = nx*ny*nz , default_value = 1 )
actnum[nx*ny - 1] = 0
grid = EclGrid.createRectangular( (nx,ny,nz) , (1,1,1) , actnum = actnum)
self.assertEqual( grid.getNumActive() , nx*ny*nz - 1 )
kw = Ecl3DKW.create( "REGIONS" , grid , EclTypeEnum.ECL_INT_TYPE , global_active = True )
kw.assign( 0 )
kw[0:nx*ny/2] = 1
kw[5,2,0] = 0
kw[0,9,0] = 2
kw.fixUninitialized( grid )
# Not assigned because they are in contact with a '2'; these
# two are problem cells.
self.assertEqual( kw[0,ny - 2,0] , 0)
self.assertEqual( kw[1,ny - 1,0] , 0)
# Not assigned because it is inactive
self.assertEqual( kw[nx - 1,ny - 1,0] , 0)
self.assertEqual( kw[5,2,0] , 1 )
for j in range(5,10):
self.assertEqual( kw[5,j,0] , 1 )
for i in range(10):
self.assertEqual( kw[i,7,0] , 1 )
def test_Load( self ):
kw = EclKW.read_grdecl(open(self.src_file, "r"), "PERMX")
self.assertTrue(kw)
grid = EclGrid( self.createTestPath("Statoil/ECLIPSE/Gurbat/ECLIPSE" ))
kw = Ecl3DKW.read_grdecl(grid , open(self.src_file, "r"), "PERMX")
self.assertTrue( isinstance( kw , Ecl3DKW ))
def __getitem__(self , index):
return_arg = super(Ecl3DFile, self).__getitem__( index )
if isinstance(return_arg,list):
kw_list = return_arg
else:
kw_list = [ return_arg ]
# Go through all the keywords and try inplace promotion to Ecl3DKW
for kw in kw_list:
try:
Ecl3DKW.castFromKW( kw , self.grid )
except ValueError:
pass
return return_arg
def test_setitem( self ):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW( "KW" , grid , EclTypeEnum.ECL_FLOAT_TYPE , default_value = 77)
with self.assertRaises(IndexError):
kw[1000]
with self.assertRaises(IndexError):
kw[0,10,100]
with self.assertRaises(ValueError):
kw[1,1]
with self.assertRaises(ValueError):
kw[1,1,1,1]
kw.assign(99)
self.assertEqual( kw[0,0,0] , 77 )
self.assertEqual( kw[0,0,1] , 99 )
with self.assertRaises(ValueError):
kw[0,0,0] = 88
kw[0,0,1] = 100
self.assertEqual( kw[0,0,1] , 100 )
def test_create( self ):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW( "KW" , grid , EclTypeEnum.ECL_FLOAT_TYPE )
self.assertEqual( len(kw) , grid.getNumActive())
self.assertEqual( (10,10,10) , kw.dims() )
def test_create( self ):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW.create( "KW" , grid , EclTypeEnum.ECL_FLOAT_TYPE )
self.assertEqual( len(kw) , grid.getNumActive())
self.assertEqual( (10,10,10) , kw.dims() )
def test_cast(self):
actnum = IntVector(default_value=1, initial_size=1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular((10, 10, 10), (1, 1, 1),
actnum=actnum)
kw_wrong_size = EclKW("KW", 27, EclDataType.ECL_FLOAT)
kw_global_size = EclKW("KW", grid.getGlobalSize(),
EclDataType.ECL_FLOAT)
kw_active_size = EclKW("KW", grid.getNumActive(),
EclDataType.ECL_FLOAT)
with self.assertRaises(ValueError):
Ecl3DKW.castFromKW(kw_wrong_size, grid)
Ecl3DKW.castFromKW(kw_global_size, grid)
self.assertTrue(isinstance(kw_global_size, Ecl3DKW))
Ecl3DKW.castFromKW(kw_active_size, grid, default_value=66)
self.assertTrue(isinstance(kw_active_size, Ecl3DKW))
self.assertEqual(kw_active_size[0, 0, 0], 66)
with self.assertRaises(ValueError):
kw_active_size[0, 0, 0] = 88
def test_create_global_size( self ):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW( "KW" , grid , EclTypeEnum.ECL_FLOAT_TYPE , global_active = True)
self.assertEqual( len(kw) , grid.getGlobalSize())
kw.assign(50)
self.assertEqual( kw[0,0,0] , 50 )
kw[0,0,0] = 45
self.assertEqual( kw[0,0,0] , 45 )
def test_create_global_size( self ):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW.create( "KW" , grid , EclTypeEnum.ECL_FLOAT_TYPE , global_active = True)
self.assertEqual( len(kw) , grid.getGlobalSize())
kw.assign(50)
self.assertEqual( kw[0,0,0] , 50 )
kw[0,0,0] = 45
self.assertEqual( kw[0,0,0] , 45 )
def test_fix_uninitialized(self):
nx = 10
ny = 11
nz = 12
grid = EclGrid.createRectangular( (nx,ny,nz) , (1,1,1) )
kw = Ecl3DKW.create("REGIONS" , grid , EclTypeEnum.ECL_INT_TYPE , global_active = True)
kw.assign(3)
self.assertEqual( 3 * nx*ny*nz , sum(kw))
kw[1,1,1] = 0
kw[3,3,3] = 0
kw[6,6,6] = 0
self.assertEqual( 3 * nx*ny*nz - 9 , sum(kw))
kw.fixUninitialized( grid )
self.assertEqual( 3 * nx*ny*nz , sum(kw))
def test_fix_uninitialized(self):
nx = 10
ny = 11
nz = 12
grid = EclGrid.createRectangular((nx, ny, nz), (1, 1, 1))
kw = Ecl3DKW("REGIONS", grid, EclDataType.ECL_INT, global_active=True)
kw.assign(3)
self.assertEqual(3 * nx * ny * nz, sum(kw))
kw[1, 1, 1] = 0
kw[3, 3, 3] = 0
kw[6, 6, 6] = 0
self.assertEqual(3 * nx * ny * nz - 9, sum(kw))
kw.fixUninitialized(grid)
self.assertEqual(3 * nx * ny * nz, sum(kw))
def test_compressed_copy(self):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(500):
actnum[2*i + 1] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW( "KW" , grid , EclTypeEnum.ECL_INT_TYPE , global_active = True)
for i in range(len(kw)):
kw[i] = i
kw_copy = kw.compressedCopy()
self.assertTrue( isinstance( kw_copy , EclKW ) )
self.assertEqual(len(kw_copy) , 500)
for i in range(len(kw_copy)):
self.assertEqual(kw_copy[i] , 2*i)
def test_compressed_copy(self):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(500):
actnum[2*i + 1] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw = Ecl3DKW.create( "KW" , grid , EclTypeEnum.ECL_INT_TYPE , global_active = True)
for i in range(len(kw)):
kw[i] = i
kw_copy = kw.compressedCopy()
self.assertTrue( isinstance( kw_copy , EclKW ) )
self.assertEqual(len(kw_copy) , 500)
for i in range(len(kw_copy)):
self.assertEqual(kw_copy[i] , 2*i)
def test_global_copy(self):
actnum = IntVector(default_value=1, initial_size=1000)
for i in range(500):
actnum[2 * i + 1] = 0
grid = EclGrid.createRectangular((10, 10, 10), (1, 1, 1),
actnum=actnum)
kw = Ecl3DKW("KW", grid, EclDataType.ECL_INT, global_active=False)
for i in range(len(kw)):
kw[i] = i
kw.setDefault(177)
kw_copy = kw.globalCopy()
self.assertTrue(isinstance(kw_copy, EclKW))
self.assertEqual(len(kw_copy), 1000)
for i in range(len(kw)):
self.assertEqual(kw_copy[2 * i], i)
self.assertEqual(kw_copy[2 * i + 1], kw.getDefault())
def test_cast(self):
actnum = IntVector(default_value = 1 , initial_size = 1000)
for i in range(100):
actnum[i] = 0
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1) , actnum = actnum)
kw_wrong_size = EclKW.create( "KW" , 27 , EclTypeEnum.ECL_FLOAT_TYPE )
kw_global_size = EclKW.create( "KW" , grid.getGlobalSize() , EclTypeEnum.ECL_FLOAT_TYPE )
kw_active_size = EclKW.create( "KW" , grid.getNumActive() , EclTypeEnum.ECL_FLOAT_TYPE )
with self.assertRaises(ValueError):
Ecl3DKW.castFromKW(kw_wrong_size , grid)
Ecl3DKW.castFromKW(kw_global_size , grid)
self.assertTrue( isinstance( kw_global_size , Ecl3DKW))
Ecl3DKW.castFromKW(kw_active_size , grid , default_value = 66)
self.assertTrue( isinstance( kw_active_size , Ecl3DKW))
self.assertEqual( kw_active_size[0,0,0] , 66)
with self.assertRaises(ValueError):
kw_active_size[0,0,0] = 88
def test_default(self):
grid = EclGrid.createRectangular((10, 10, 10), (1, 1, 1))
kw = Ecl3DKW("KW", grid, EclDataType.ECL_FLOAT)
kw.setDefault(55)
self.assertTrue(55, kw.getDefault())
print('Using Norne location %s' % norne)
rst = EclFile(join(norne, 'NORNE_ATW2013.UNRST'))
grd = EclGrid(join(norne, 'NORNE_ATW2013.EGRID'))
x = 10 # x in [0, grd.getNX())
y = 10 # y in [0, grd.getNY())
print(grd)
print('Plotting SGAS, SOIL, SWAT for x,y pillar (%d, %d)' % (x, y))
swat = rst.iget_named_kw('SWAT', 0)
sgas = rst.iget_named_kw('SGAS', 0)
swat3d = Ecl3DKW.castFromKW(swat, grd, default_value=0)
f_swat = lambda k: swat3d[x, y, k]
sgas3d = Ecl3DKW.castFromKW(sgas, grd, default_value=0)
f_sgas = lambda k: sgas3d[x, y, k]
f_soil = lambda k: max(0, 1 - (f_sgas(k) + f_swat(k)))
nz = grd.getNZ()
sgas = [f_sgas(k) for k in range(nz)]
soil = [f_soil(k) for k in range(nz)]
swat = [f_swat(k) for k in range(nz)]
import matplotlib.pyplot as plt
plt.plot(sgas, color='r', label='SGAS')
def test_default(self):
grid = EclGrid.createRectangular( (10,10,10) , (1,1,1))
kw = Ecl3DKW.create( "KW" , grid , EclTypeEnum.ECL_FLOAT_TYPE )
kw.setDefault(55)
self.assertTrue( 55 , kw.getDefault())
