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VectorPartitioned.hpp
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rGOOSEFEM GooseFEM
VectorPartitioned.hpp
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/**
Implementation of VectorPartitioned.h
\file VectorPartitioned.hpp
\copyright Copyright 2017. Tom de Geus. All rights reserved.
\license This project is released under the GNU Public License (GPLv3).
*/
#ifndef GOOSEFEM_VECTORPARTITIONED_HPP
#define GOOSEFEM_VECTORPARTITIONED_HPP
#include "Mesh.h"
#include "VectorPartitioned.h"
namespace
GooseFEM
{
inline
VectorPartitioned
::
VectorPartitioned
(
const
xt
::
xtensor
<
size_t
,
2
>&
conn
,
const
xt
::
xtensor
<
size_t
,
2
>&
dofs
,
const
xt
::
xtensor
<
size_t
,
1
>&
iip
)
:
Vector
(
conn
,
dofs
),
m_iip
(
iip
)
{
m_iiu
=
xt
::
setdiff1d
(
m_dofs
,
m_iip
);
m_nnp
=
m_iip
.
size
();
m_nnu
=
m_iiu
.
size
();
m_part
=
Mesh
::
Reorder
({
m_iiu
,
m_iip
}).
apply
(
m_dofs
);
GOOSEFEM_ASSERT
(
xt
::
amax
(
m_iip
)()
<=
xt
::
amax
(
m_dofs
)());
}
inline
size_t
VectorPartitioned
::
nnu
()
const
{
return
m_nnu
;
}
inline
size_t
VectorPartitioned
::
nnp
()
const
{
return
m_nnp
;
}
inline
xt
::
xtensor
<
size_t
,
1
>
VectorPartitioned
::
iiu
()
const
{
return
m_iiu
;
}
inline
xt
::
xtensor
<
size_t
,
1
>
VectorPartitioned
::
iip
()
const
{
return
m_iip
;
}
inline
xt
::
xtensor
<
bool
,
2
>
VectorPartitioned
::
dofs_is_u
()
const
{
xt
::
xtensor
<
bool
,
2
>
ret
=
xt
::
zeros
<
bool
>
(
this
->
shape_nodevec
());
#pragma omp parallel for
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
<
m_nnu
)
{
ret
(
m
,
i
)
=
true
;
}
}
}
return
ret
;
}
inline
xt
::
xtensor
<
bool
,
2
>
VectorPartitioned
::
dofs_is_p
()
const
{
xt
::
xtensor
<
bool
,
2
>
ret
=
xt
::
zeros
<
bool
>
(
this
->
shape_nodevec
());
#pragma omp parallel for
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
>=
m_nnu
)
{
ret
(
m
,
i
)
=
true
;
}
}
}
return
ret
;
}
inline
void
VectorPartitioned
::
copy_u
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec_src
,
xt
::
xtensor
<
double
,
2
>&
nodevec_dest
)
const
{
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec_src
,
{
m_nnode
,
m_ndim
}));
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec_dest
,
{
m_nnode
,
m_ndim
}));
#pragma omp parallel for
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
<
m_nnu
)
{
nodevec_dest
(
m
,
i
)
=
nodevec_src
(
m
,
i
);
}
}
}
}
inline
void
VectorPartitioned
::
copy_p
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec_src
,
xt
::
xtensor
<
double
,
2
>&
nodevec_dest
)
const
{
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec_src
,
{
m_nnode
,
m_ndim
}));
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec_dest
,
{
m_nnode
,
m_ndim
}));
#pragma omp parallel for
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
>=
m_nnu
)
{
nodevec_dest
(
m
,
i
)
=
nodevec_src
(
m
,
i
);
}
}
}
}
inline
void
VectorPartitioned
::
dofsFromParitioned
(
const
xt
::
xtensor
<
double
,
1
>&
dofval_u
,
const
xt
::
xtensor
<
double
,
1
>&
dofval_p
,
xt
::
xtensor
<
double
,
1
>&
dofval
)
const
{
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
GOOSEFEM_ASSERT
(
dofval
.
size
()
==
m_ndof
);
dofval
.
fill
(
0.0
);
#pragma omp parallel for
for
(
size_t
d
=
0
;
d
<
m_nnu
;
++
d
)
{
dofval
(
m_iiu
(
d
))
=
dofval_u
(
d
);
}
#pragma omp parallel for
for
(
size_t
d
=
0
;
d
<
m_nnp
;
++
d
)
{
dofval
(
m_iip
(
d
))
=
dofval_p
(
d
);
}
}
inline
void
VectorPartitioned
::
asDofs_u
(
const
xt
::
xtensor
<
double
,
1
>&
dofval
,
xt
::
xtensor
<
double
,
1
>&
dofval_u
)
const
{
GOOSEFEM_ASSERT
(
dofval
.
size
()
==
m_ndof
);
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
#pragma omp parallel for
for
(
size_t
d
=
0
;
d
<
m_nnu
;
++
d
)
{
dofval_u
(
d
)
=
dofval
(
m_iiu
(
d
));
}
}
inline
void
VectorPartitioned
::
asDofs_u
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
,
xt
::
xtensor
<
double
,
1
>&
dofval_u
)
const
{
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec
,
{
m_nnode
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
dofval_u
.
fill
(
0.0
);
#pragma omp parallel for
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
<
m_nnu
)
{
dofval_u
(
m_part
(
m
,
i
))
=
nodevec
(
m
,
i
);
}
}
}
}
inline
void
VectorPartitioned
::
asDofs_p
(
const
xt
::
xtensor
<
double
,
1
>&
dofval
,
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
GOOSEFEM_ASSERT
(
dofval
.
size
()
==
m_ndof
);
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
#pragma omp parallel for
for
(
size_t
d
=
0
;
d
<
m_nnp
;
++
d
)
{
dofval_p
(
d
)
=
dofval
(
m_iip
(
d
));
}
}
inline
void
VectorPartitioned
::
asDofs_p
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
,
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec
,
{
m_nnode
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
dofval_p
.
fill
(
0.0
);
#pragma omp parallel for
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
>=
m_nnu
)
{
dofval_p
(
m_part
(
m
,
i
)
-
m_nnu
)
=
nodevec
(
m
,
i
);
}
}
}
}
inline
void
VectorPartitioned
::
asDofs_u
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
,
xt
::
xtensor
<
double
,
1
>&
dofval_u
)
const
{
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
elemvec
,
{
m_nelem
,
m_nne
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
dofval_u
.
fill
(
0.0
);
#pragma omp parallel for
for
(
size_t
e
=
0
;
e
<
m_nelem
;
++
e
)
{
for
(
size_t
m
=
0
;
m
<
m_nne
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m_conn
(
e
,
m
),
i
)
<
m_nnu
)
{
dofval_u
(
m_part
(
m_conn
(
e
,
m
),
i
))
=
elemvec
(
e
,
m
,
i
);
}
}
}
}
}
inline
void
VectorPartitioned
::
asDofs_p
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
,
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
elemvec
,
{
m_nelem
,
m_nne
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
dofval_p
.
fill
(
0.0
);
#pragma omp parallel for
for
(
size_t
e
=
0
;
e
<
m_nelem
;
++
e
)
{
for
(
size_t
m
=
0
;
m
<
m_nne
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m_conn
(
e
,
m
),
i
)
>=
m_nnu
)
{
dofval_p
(
m_part
(
m_conn
(
e
,
m
),
i
)
-
m_nnu
)
=
elemvec
(
e
,
m
,
i
);
}
}
}
}
}
inline
void
VectorPartitioned
::
nodeFromPartitioned
(
const
xt
::
xtensor
<
double
,
1
>&
dofval_u
,
const
xt
::
xtensor
<
double
,
1
>&
dofval_p
,
xt
::
xtensor
<
double
,
2
>&
nodevec
)
const
{
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec
,
{
m_nnode
,
m_ndim
}));
#pragma omp parallel for
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
<
m_nnu
)
{
nodevec
(
m
,
i
)
=
dofval_u
(
m_part
(
m
,
i
));
}
else
{
nodevec
(
m
,
i
)
=
dofval_p
(
m_part
(
m
,
i
)
-
m_nnu
);
}
}
}
}
inline
void
VectorPartitioned
::
elementFromPartitioned
(
const
xt
::
xtensor
<
double
,
1
>&
dofval_u
,
const
xt
::
xtensor
<
double
,
1
>&
dofval_p
,
xt
::
xtensor
<
double
,
3
>&
elemvec
)
const
{
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
elemvec
,
{
m_nelem
,
m_nne
,
m_ndim
}));
#pragma omp parallel for
for
(
size_t
e
=
0
;
e
<
m_nelem
;
++
e
)
{
for
(
size_t
m
=
0
;
m
<
m_nne
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m_conn
(
e
,
m
),
i
)
<
m_nnu
)
{
elemvec
(
e
,
m
,
i
)
=
dofval_u
(
m_part
(
m_conn
(
e
,
m
),
i
));
}
else
{
elemvec
(
e
,
m
,
i
)
=
dofval_p
(
m_part
(
m_conn
(
e
,
m
),
i
)
-
m_nnu
);
}
}
}
}
}
/**
\cond
*/
inline
void
VectorPartitioned
::
assembleDofs_u
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
,
xt
::
xtensor
<
double
,
1
>&
dofval_u
)
const
{
GOOSEFEM_WARNING
(
"assembleDofs_u is deprecated and will not be replaced"
);
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec
,
{
m_nnode
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
dofval_u
.
fill
(
0.0
);
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
<
m_nnu
)
{
dofval_u
(
m_part
(
m
,
i
))
+=
nodevec
(
m
,
i
);
}
}
}
}
inline
void
VectorPartitioned
::
assembleDofs_p
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
,
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
GOOSEFEM_WARNING
(
"assembleDofs_p is deprecated and will not be replaced"
);
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
nodevec
,
{
m_nnode
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
dofval_p
.
fill
(
0.0
);
for
(
size_t
m
=
0
;
m
<
m_nnode
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m
,
i
)
>=
m_nnu
)
{
dofval_p
(
m_part
(
m
,
i
)
-
m_nnu
)
+=
nodevec
(
m
,
i
);
}
}
}
}
inline
void
VectorPartitioned
::
assembleDofs_u
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
,
xt
::
xtensor
<
double
,
1
>&
dofval_u
)
const
{
GOOSEFEM_WARNING
(
"assembleDofs_u is deprecated and will not be replaced"
);
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
elemvec
,
{
m_nelem
,
m_nne
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_u
.
size
()
==
m_nnu
);
dofval_u
.
fill
(
0.0
);
for
(
size_t
e
=
0
;
e
<
m_nelem
;
++
e
)
{
for
(
size_t
m
=
0
;
m
<
m_nne
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m_conn
(
e
,
m
),
i
)
<
m_nnu
)
{
dofval_u
(
m_part
(
m_conn
(
e
,
m
),
i
))
+=
elemvec
(
e
,
m
,
i
);
}
}
}
}
}
inline
void
VectorPartitioned
::
assembleDofs_p
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
,
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
GOOSEFEM_WARNING
(
"assembleDofs_p is deprecated and will not be replaced"
);
GOOSEFEM_ASSERT
(
xt
::
has_shape
(
elemvec
,
{
m_nelem
,
m_nne
,
m_ndim
}));
GOOSEFEM_ASSERT
(
dofval_p
.
size
()
==
m_nnp
);
dofval_p
.
fill
(
0.0
);
for
(
size_t
e
=
0
;
e
<
m_nelem
;
++
e
)
{
for
(
size_t
m
=
0
;
m
<
m_nne
;
++
m
)
{
for
(
size_t
i
=
0
;
i
<
m_ndim
;
++
i
)
{
if
(
m_part
(
m_conn
(
e
,
m
),
i
)
>=
m_nnu
)
{
dofval_p
(
m_part
(
m_conn
(
e
,
m
),
i
)
-
m_nnu
)
+=
elemvec
(
e
,
m
,
i
);
}
}
}
}
}
/**
\endcond
*/
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
DofsFromParitioned
(
const
xt
::
xtensor
<
double
,
1
>&
dofval_u
,
const
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval
=
xt
::
empty
<
double
>
({
m_ndof
});
this
->
dofsFromParitioned
(
dofval_u
,
dofval_p
,
dofval
);
return
dofval
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AsDofs_u
(
const
xt
::
xtensor
<
double
,
1
>&
dofval
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_u
=
xt
::
empty
<
double
>
({
m_nnu
});
this
->
asDofs_u
(
dofval
,
dofval_u
);
return
dofval_u
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AsDofs_u
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_u
=
xt
::
empty
<
double
>
({
m_nnu
});
this
->
asDofs_u
(
nodevec
,
dofval_u
);
return
dofval_u
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AsDofs_p
(
const
xt
::
xtensor
<
double
,
1
>&
dofval
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_p
=
xt
::
empty
<
double
>
({
m_nnp
});
this
->
asDofs_p
(
dofval
,
dofval_p
);
return
dofval_p
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AsDofs_p
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_p
=
xt
::
empty
<
double
>
({
m_nnp
});
this
->
asDofs_p
(
nodevec
,
dofval_p
);
return
dofval_p
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AsDofs_u
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_u
=
xt
::
empty
<
double
>
({
m_nnu
});
this
->
asDofs_u
(
elemvec
,
dofval_u
);
return
dofval_u
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AsDofs_p
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_p
=
xt
::
empty
<
double
>
({
m_nnp
});
this
->
asDofs_p
(
elemvec
,
dofval_p
);
return
dofval_p
;
}
inline
xt
::
xtensor
<
double
,
2
>
VectorPartitioned
::
NodeFromPartitioned
(
const
xt
::
xtensor
<
double
,
1
>&
dofval_u
,
const
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
xt
::
xtensor
<
double
,
2
>
nodevec
=
xt
::
empty
<
double
>
({
m_nnode
,
m_ndim
});
this
->
nodeFromPartitioned
(
dofval_u
,
dofval_p
,
nodevec
);
return
nodevec
;
}
inline
xt
::
xtensor
<
double
,
3
>
VectorPartitioned
::
ElementFromPartitioned
(
const
xt
::
xtensor
<
double
,
1
>&
dofval_u
,
const
xt
::
xtensor
<
double
,
1
>&
dofval_p
)
const
{
xt
::
xtensor
<
double
,
3
>
elemvec
=
xt
::
empty
<
double
>
({
m_nelem
,
m_nne
,
m_ndim
});
this
->
elementFromPartitioned
(
dofval_u
,
dofval_p
,
elemvec
);
return
elemvec
;
}
/**
\cond
*/
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AssembleDofs_u
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_u
=
xt
::
empty
<
double
>
({
m_nnu
});
this
->
assembleDofs_u
(
nodevec
,
dofval_u
);
return
dofval_u
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AssembleDofs_p
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_p
=
xt
::
empty
<
double
>
({
m_nnp
});
this
->
assembleDofs_p
(
nodevec
,
dofval_p
);
return
dofval_p
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AssembleDofs_u
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_u
=
xt
::
empty
<
double
>
({
m_nnu
});
this
->
assembleDofs_u
(
elemvec
,
dofval_u
);
return
dofval_u
;
}
inline
xt
::
xtensor
<
double
,
1
>
VectorPartitioned
::
AssembleDofs_p
(
const
xt
::
xtensor
<
double
,
3
>&
elemvec
)
const
{
xt
::
xtensor
<
double
,
1
>
dofval_p
=
xt
::
empty
<
double
>
({
m_nnp
});
this
->
assembleDofs_p
(
elemvec
,
dofval_p
);
return
dofval_p
;
}
/**
\endcond
*/
inline
xt
::
xtensor
<
double
,
2
>
VectorPartitioned
::
Copy_u
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec_src
,
const
xt
::
xtensor
<
double
,
2
>&
nodevec_dest
)
const
{
xt
::
xtensor
<
double
,
2
>
ret
=
nodevec_dest
;
this
->
copy_u
(
nodevec_src
,
ret
);
return
ret
;
}
inline
xt
::
xtensor
<
double
,
2
>
VectorPartitioned
::
Copy_p
(
const
xt
::
xtensor
<
double
,
2
>&
nodevec_src
,
const
xt
::
xtensor
<
double
,
2
>&
nodevec_dest
)
const
{
xt
::
xtensor
<
double
,
2
>
ret
=
nodevec_dest
;
this
->
copy_p
(
nodevec_src
,
ret
);
return
ret
;
}
}
// namespace GooseFEM
#endif
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