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rMUSPECTRE µSpectre
test_field_collections_1.cc
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/**
* @file test_field_collections_1.cc
*
* @author Till Junge <till.junge@epfl.ch>
*
* @date 20 Sep 2017
*
* @brief Test the FieldCollection classes which provide fast optimized iterators
* over run-time typed fields
*
* Copyright © 2017 Till Junge
*
* µSpectre is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation, either version 3, or (at
* your option) any later version.
*
* µSpectre is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with GNU Emacs; see the file COPYING. If not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
#include "test_field_collections.hh"
namespace
muSpectre
{
BOOST_AUTO_TEST_SUITE
(
field_collection_tests
);
BOOST_AUTO_TEST_CASE
(
simple
)
{
constexpr
Dim_t
sdim
=
2
;
using
FC_t
=
GlobalFieldCollection
<
sdim
>
;
FC_t
fc
;
BOOST_CHECK_EQUAL
(
FC_t
::
spatial_dim
(),
sdim
);
BOOST_CHECK_EQUAL
(
fc
.
get_spatial_dim
(),
sdim
);
}
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
Simple_construction_test
,
F
,
test_collections
,
F
)
{
BOOST_CHECK_EQUAL
(
F
::
FC_t
::
spatial_dim
(),
F
::
sdim
());
BOOST_CHECK_EQUAL
(
F
::
fc
.
get_spatial_dim
(),
F
::
sdim
());
}
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
get_field2_test
,
F
,
test_collections
,
F
)
{
const
auto
order
{
2
};
using
FC_t
=
typename
F
::
FC_t
;
using
TF_t
=
TensorField
<
FC_t
,
Real
,
order
,
F
::
mdim
()
>
;
auto
&&
myfield
=
make_field
<
TF_t
>
(
"TensorField real 2"
,
F
::
fc
);
using
TensorMap
=
TensorFieldMap
<
FC_t
,
Real
,
order
,
F
::
mdim
()
>
;
using
MatrixMap
=
MatrixFieldMap
<
FC_t
,
Real
,
F
::
mdim
(),
F
::
mdim
()
>
;
using
ArrayMap
=
ArrayFieldMap
<
FC_t
,
Real
,
F
::
mdim
(),
F
::
mdim
()
>
;
TensorMap
TFM
(
myfield
);
MatrixMap
MFM
(
myfield
);
ArrayMap
AFM
(
myfield
);
BOOST_CHECK_EQUAL
(
TFM
.
info_string
(),
"Tensor(d, "
+
std
::
to_string
(
order
)
+
"_o, "
+
std
::
to_string
(
F
::
mdim
())
+
"_d)"
);
BOOST_CHECK_EQUAL
(
MFM
.
info_string
(),
"Matrix(d, "
+
std
::
to_string
(
F
::
mdim
())
+
"x"
+
std
::
to_string
(
F
::
mdim
())
+
")"
);
BOOST_CHECK_EQUAL
(
AFM
.
info_string
(),
"Array(d, "
+
std
::
to_string
(
F
::
mdim
())
+
"x"
+
std
::
to_string
(
F
::
mdim
())
+
")"
);
}
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
multi_field_test
,
F
,
mult_collections
,
F
)
{
using
FC_t
=
typename
F
::
FC_t
;
// possible maptypes for Real tensor fields
using
T_type
=
Real
;
using
T_TFM1_t
=
TensorFieldMap
<
FC_t
,
T_type
,
order
,
F
::
mdim
()
>
;
using
T_TFM2_t
=
TensorFieldMap
<
FC_t
,
T_type
,
2
,
F
::
mdim
()
*
F
::
mdim
()
>
;
//! dangerous
using
T4_Map_t
=
T4MatrixFieldMap
<
FC_t
,
Real
,
F
::
mdim
()
>
;
// impossible maptypes for Real tensor fields
using
T_SFM_t
=
ScalarFieldMap
<
FC_t
,
T_type
>
;
using
T_MFM_t
=
MatrixFieldMap
<
FC_t
,
T_type
,
1
,
1
>
;
using
T_AFM_t
=
ArrayFieldMap
<
FC_t
,
T_type
,
1
,
1
>
;
using
T_MFMw1_t
=
MatrixFieldMap
<
FC_t
,
Int
,
1
,
2
>
;
using
T_MFMw2_t
=
MatrixFieldMap
<
FC_t
,
Real
,
1
,
2
>
;
using
T_MFMw3_t
=
MatrixFieldMap
<
FC_t
,
Complex
,
1
,
2
>
;
const
std
::
string
T_name
{
"Tensorfield Real o4"
};
const
std
::
string
T_name_w
{
"TensorField Real o4 wrongname"
};
BOOST_CHECK_THROW
(
T_SFM_t
(
F
::
fc
.
at
(
T_name
)),
FieldInterpretationError
);
BOOST_CHECK_NO_THROW
(
T_TFM1_t
(
F
::
fc
.
at
(
T_name
)));
BOOST_CHECK_NO_THROW
(
T_TFM2_t
(
F
::
fc
.
at
(
T_name
)));
BOOST_CHECK_NO_THROW
(
T4_Map_t
(
F
::
fc
.
at
(
T_name
)));
BOOST_CHECK_THROW
(
T4_Map_t
(
F
::
fc
.
at
(
T_name_w
)),
std
::
out_of_range
);
BOOST_CHECK_THROW
(
T_MFM_t
(
F
::
fc
.
at
(
T_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
T_AFM_t
(
F
::
fc
.
at
(
T_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
T_MFMw1_t
(
F
::
fc
.
at
(
T_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
T_MFMw2_t
(
F
::
fc
.
at
(
T_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
T_MFMw2_t
(
F
::
fc
.
at
(
T_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
T_MFMw3_t
(
F
::
fc
.
at
(
T_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
T_SFM_t
(
F
::
fc
.
at
(
T_name_w
)),
std
::
out_of_range
);
// possible maptypes for integer scalar fields
using
S_type
=
Int
;
using
S_SFM_t
=
ScalarFieldMap
<
FC_t
,
S_type
>
;
using
S_TFM1_t
=
TensorFieldMap
<
FC_t
,
S_type
,
1
,
1
>
;
using
S_TFM2_t
=
TensorFieldMap
<
FC_t
,
S_type
,
2
,
1
>
;
using
S_MFM_t
=
MatrixFieldMap
<
FC_t
,
S_type
,
1
,
1
>
;
using
S_AFM_t
=
ArrayFieldMap
<
FC_t
,
S_type
,
1
,
1
>
;
using
S4_Map_t
=
T4MatrixFieldMap
<
FC_t
,
S_type
,
1
>
;
// impossible maptypes for integer scalar fields
using
S_MFMw1_t
=
MatrixFieldMap
<
FC_t
,
Int
,
1
,
2
>
;
using
S_MFMw2_t
=
MatrixFieldMap
<
FC_t
,
Real
,
1
,
2
>
;
using
S_MFMw3_t
=
MatrixFieldMap
<
FC_t
,
Complex
,
1
,
2
>
;
const
std
::
string
S_name
{
"integer Scalar"
};
const
std
::
string
S_name_w
{
"integer Scalar wrongname"
};
BOOST_CHECK_NO_THROW
(
S_SFM_t
(
F
::
fc
.
at
(
S_name
)));
BOOST_CHECK_NO_THROW
(
S_TFM1_t
(
F
::
fc
.
at
(
S_name
)));
BOOST_CHECK_NO_THROW
(
S_TFM2_t
(
F
::
fc
.
at
(
S_name
)));
BOOST_CHECK_NO_THROW
(
S_MFM_t
(
F
::
fc
.
at
(
S_name
)));
BOOST_CHECK_NO_THROW
(
S_AFM_t
(
F
::
fc
.
at
(
S_name
)));
BOOST_CHECK_NO_THROW
(
S4_Map_t
(
F
::
fc
.
at
(
S_name
)));
BOOST_CHECK_THROW
(
S_MFMw1_t
(
F
::
fc
.
at
(
S_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
T4_Map_t
(
F
::
fc
.
at
(
S_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
S_MFMw2_t
(
F
::
fc
.
at
(
S_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
S_MFMw2_t
(
F
::
fc
.
at
(
S_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
S_MFMw3_t
(
F
::
fc
.
at
(
S_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
S_SFM_t
(
F
::
fc
.
at
(
S_name_w
)),
std
::
out_of_range
);
// possible maptypes for complex matrix fields
using
M_type
=
Complex
;
using
M_MFM_t
=
MatrixFieldMap
<
FC_t
,
M_type
,
F
::
sdim
(),
F
::
mdim
()
>
;
using
M_AFM_t
=
ArrayFieldMap
<
FC_t
,
M_type
,
F
::
sdim
(),
F
::
mdim
()
>
;
// impossible maptypes for complex matrix fields
using
M_SFM_t
=
ScalarFieldMap
<
FC_t
,
M_type
>
;
using
M_MFMw1_t
=
MatrixFieldMap
<
FC_t
,
Int
,
1
,
2
>
;
using
M_MFMw2_t
=
MatrixFieldMap
<
FC_t
,
Real
,
1
,
2
>
;
using
M_MFMw3_t
=
MatrixFieldMap
<
FC_t
,
Complex
,
1
,
2
>
;
const
std
::
string
M_name
{
"Matrixfield Complex sdim x mdim"
};
const
std
::
string
M_name_w
{
"Matrixfield Complex sdim x mdim wrongname"
};
BOOST_CHECK_THROW
(
M_SFM_t
(
F
::
fc
.
at
(
M_name
)),
FieldInterpretationError
);
BOOST_CHECK_NO_THROW
(
M_MFM_t
(
F
::
fc
.
at
(
M_name
)));
BOOST_CHECK_NO_THROW
(
M_AFM_t
(
F
::
fc
.
at
(
M_name
)));
BOOST_CHECK_THROW
(
M_MFMw1_t
(
F
::
fc
.
at
(
M_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
M_MFMw2_t
(
F
::
fc
.
at
(
M_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
M_MFMw2_t
(
F
::
fc
.
at
(
M_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
M_MFMw3_t
(
F
::
fc
.
at
(
M_name
)),
FieldInterpretationError
);
BOOST_CHECK_THROW
(
M_SFM_t
(
F
::
fc
.
at
(
M_name_w
)),
std
::
out_of_range
);
}
/* ---------------------------------------------------------------------- */
//! Check whether fields can be initialized
using
mult_collections_t
=
boost
::
mpl
::
list
<
FC_multi_fixture
<
2
,
2
,
true
>
,
FC_multi_fixture
<
2
,
3
,
true
>
,
FC_multi_fixture
<
3
,
3
,
true
>>
;
using
mult_collections_f
=
boost
::
mpl
::
list
<
FC_multi_fixture
<
2
,
2
,
false
>
,
FC_multi_fixture
<
2
,
3
,
false
>
,
FC_multi_fixture
<
3
,
3
,
false
>>
;
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
init_test_glob
,
F
,
mult_collections_t
,
F
)
{
Ccoord_t
<
F
::
sdim
()
>
size
;
Ccoord_t
<
F
::
sdim
()
>
loc
{};
for
(
auto
&&
s:
size
)
{
s
=
3
;
}
BOOST_CHECK_NO_THROW
(
F
::
fc
.
initialise
(
size
,
loc
));
}
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
init_test_loca
,
F
,
mult_collections_f
,
F
)
{
testGoodies
::
RandRange
<
Int
>
rng
;
for
(
int
i
=
0
;
i
<
7
;
++
i
)
{
Ccoord_t
<
F
::
sdim
()
>
pixel
;
for
(
auto
&&
s:
pixel
)
{
s
=
rng
.
randval
(
0
,
7
);
}
F
::
fc
.
add_pixel
(
pixel
);
}
BOOST_CHECK_NO_THROW
(
F
::
fc
.
initialise
());
}
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
init_test_loca_with_push_back
,
F
,
mult_collections_f
,
F
)
{
constexpr
auto
mdim
=
F
::
mdim
();
constexpr
int
nb_pix
=
7
;
testGoodies
::
RandRange
<
Int
>
rng
;
using
ftype
=
internal
::
TypedSizedFieldBase
<
decltype
(
F
::
fc
),
Real
,
mdim
*
mdim
*
mdim
*
mdim
>
;
using
stype
=
Eigen
::
Array
<
Real
,
mdim
*
mdim
*
mdim
*
mdim
,
1
>
;
auto
&
field
=
reinterpret_cast
<
ftype
&>
(
F
::
fc
[
"Tensorfield Real o4"
]);
field
.
push_back
(
stype
());
for
(
int
i
=
0
;
i
<
nb_pix
;
++
i
)
{
Ccoord_t
<
F
::
sdim
()
>
pixel
;
for
(
auto
&&
s:
pixel
)
{
s
=
rng
.
randval
(
0
,
7
);
}
F
::
fc
.
add_pixel
(
pixel
);
}
BOOST_CHECK_THROW
(
F
::
fc
.
initialise
(),
FieldCollectionError
);
for
(
int
i
=
0
;
i
<
nb_pix
-
1
;
++
i
)
{
field
.
push_back
(
stype
());
}
BOOST_CHECK_NO_THROW
(
F
::
fc
.
initialise
());
}
BOOST_AUTO_TEST_SUITE_END
();
}
// muSpectre
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