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flood_fill.cpp
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rTAMAAS tamaas
flood_fill.cpp
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/**
* @file
* LICENSE
*
* Copyright (©) 2016-2021 EPFL (École Polytechnique Fédérale de Lausanne),
* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as published
* by the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program 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 Affero General Public License for more details.
*
* You should have received a copy of the GNU Affero General Public License
* along with this program. If not, see <https://www.gnu.org/licenses/>.
*
*/
/* -------------------------------------------------------------------------- */
#include "flood_fill.hh"
#include "partitioner.hh"
#include <algorithm>
#include <limits>
#include <stack>
/* -------------------------------------------------------------------------- */
namespace
tamaas
{
Int
unsigned_modulo
(
Int
i
,
UInt
n
)
{
return
(
i
%
n
+
n
)
%
n
;
}
template
<
std
::
size_t
dim
>
std
::
array
<
UInt
,
dim
>
unsigned_modulo
(
const
std
::
array
<
Int
,
dim
>&
t
,
const
std
::
array
<
UInt
,
dim
>&
n
)
{
std
::
array
<
UInt
,
dim
>
index
;
for
(
UInt
i
=
0
;
i
<
dim
;
++
i
)
index
[
i
]
=
unsigned_modulo
(
t
[
i
],
n
[
i
]);
return
index
;
}
template
<
std
::
size_t
dim
>
std
::
array
<
Int
,
dim
>
cast_int
(
const
std
::
array
<
UInt
,
dim
>&
a
)
{
std
::
array
<
Int
,
dim
>
r
;
for
(
UInt
i
=
0
;
i
<
dim
;
++
i
)
r
[
i
]
=
(
Int
)
a
[
i
];
return
r
;
}
template
<
UInt
dim
>
Cluster
<
dim
>::
Cluster
(
const
Cluster
&
other
)
:
points
(
other
.
points
),
perimeter
(
other
.
perimeter
)
{}
template
<>
auto
Cluster
<
1
>::
getNextNeighbors
(
const
std
::
array
<
UInt
,
1
>&
p
)
{
std
::
vector
<
Point
>
neighbors
(
2
);
Int
i
=
p
[
0
];
neighbors
[
0
]
=
{
i
-
1
};
neighbors
[
1
]
=
{
i
+
1
};
return
neighbors
;
}
template
<>
auto
Cluster
<
1
>::
getDiagonalNeighbors
(
const
std
::
array
<
UInt
,
1
>&
)
{
return
std
::
vector
<
Point
>
();
}
template
<>
auto
Cluster
<
2
>::
getNextNeighbors
(
const
std
::
array
<
UInt
,
2
>&
p
)
{
std
::
vector
<
Point
>
neighbors
(
4
);
Int
i
=
p
[
0
],
j
=
p
[
1
];
neighbors
[
0
]
=
{
i
+
1
,
j
};
neighbors
[
1
]
=
{
i
-
1
,
j
};
neighbors
[
2
]
=
{
i
,
j
-
1
};
neighbors
[
3
]
=
{
i
,
j
+
1
};
return
neighbors
;
}
template
<>
auto
Cluster
<
2
>::
getDiagonalNeighbors
(
const
std
::
array
<
UInt
,
2
>&
p
)
{
std
::
vector
<
Point
>
neighbors
(
4
);
Int
i
=
p
[
0
],
j
=
p
[
1
];
neighbors
[
0
]
=
{
i
+
1
,
j
+
1
};
neighbors
[
1
]
=
{
i
-
1
,
j
-
1
};
neighbors
[
2
]
=
{
i
-
1
,
j
+
1
};
neighbors
[
3
]
=
{
i
+
1
,
j
-
1
};
return
neighbors
;
}
template
<>
auto
Cluster
<
3
>::
getNextNeighbors
(
const
std
::
array
<
UInt
,
3
>&
p
)
{
std
::
vector
<
Point
>
neighbors
(
6
);
Int
i
=
p
[
0
],
j
=
p
[
1
],
k
=
p
[
2
];
neighbors
[
0
]
=
{
i
+
1
,
j
,
k
};
neighbors
[
1
]
=
{
i
-
1
,
j
,
k
};
neighbors
[
2
]
=
{
i
,
j
-
1
,
k
};
neighbors
[
3
]
=
{
i
,
j
+
1
,
k
};
neighbors
[
4
]
=
{
i
,
j
,
k
-
1
};
neighbors
[
5
]
=
{
i
,
j
,
k
+
1
};
return
neighbors
;
}
template
<>
auto
Cluster
<
3
>::
getDiagonalNeighbors
(
const
std
::
array
<
UInt
,
3
>&
p
)
{
std
::
vector
<
Point
>
neighbors
(
20
);
Int
i
=
p
[
0
],
j
=
p
[
1
],
k
=
p
[
2
];
// 8 corners
neighbors
[
0
]
=
{
i
+
1
,
j
+
1
,
k
+
1
};
neighbors
[
1
]
=
{
i
+
1
,
j
+
1
,
k
-
1
};
neighbors
[
2
]
=
{
i
+
1
,
j
-
1
,
k
+
1
};
neighbors
[
3
]
=
{
i
+
1
,
j
-
1
,
k
-
1
};
neighbors
[
4
]
=
{
i
-
1
,
j
+
1
,
k
+
1
};
neighbors
[
5
]
=
{
i
-
1
,
j
+
1
,
k
-
1
};
neighbors
[
6
]
=
{
i
-
1
,
j
-
1
,
k
+
1
};
neighbors
[
7
]
=
{
i
-
1
,
j
-
1
,
k
-
1
};
// 4 diagonals in i = 0
neighbors
[
8
]
=
{
i
,
j
+
1
,
k
+
1
};
neighbors
[
9
]
=
{
i
,
j
+
1
,
k
-
1
};
neighbors
[
10
]
=
{
i
,
j
-
1
,
k
+
1
};
neighbors
[
11
]
=
{
i
,
j
-
1
,
k
-
1
};
// 4 diagonals in j = 0
neighbors
[
12
]
=
{
i
+
1
,
j
,
k
+
1
};
neighbors
[
13
]
=
{
i
+
1
,
j
,
k
-
1
};
neighbors
[
14
]
=
{
i
-
1
,
j
,
k
+
1
};
neighbors
[
15
]
=
{
i
-
1
,
j
,
k
-
1
};
// 4 diagonals in k = 0
neighbors
[
16
]
=
{
i
+
1
,
j
+
1
,
k
};
neighbors
[
17
]
=
{
i
+
1
,
j
-
1
,
k
};
neighbors
[
18
]
=
{
i
-
1
,
j
+
1
,
k
};
neighbors
[
19
]
=
{
i
-
1
,
j
-
1
,
k
};
return
neighbors
;
}
template
<
UInt
dim
>
std
::
pair
<
std
::
array
<
Int
,
dim
>
,
std
::
array
<
Int
,
dim
>>
Cluster
<
dim
>::
boundingBox
()
const
{
// TODO make sure periodic boundaries are correctly unwrapped
std
::
array
<
Int
,
dim
>
mins
,
maxs
;
mins
.
fill
(
std
::
numeric_limits
<
Int
>::
max
());
maxs
.
fill
(
std
::
numeric_limits
<
Int
>::
min
());
for
(
const
auto
&
p
:
points
)
for
(
UInt
i
=
0
;
i
<
dim
;
++
i
)
{
mins
[
i
]
=
std
::
min
(
mins
[
i
],
p
[
i
]);
maxs
[
i
]
=
std
::
max
(
maxs
[
i
],
p
[
i
]);
}
return
std
::
make_pair
(
mins
,
maxs
);
}
template
<
UInt
dim
>
Cluster
<
dim
>::
Cluster
(
Point
start
,
const
Grid
<
bool
,
dim
>&
contact
,
Grid
<
bool
,
dim
>&
visited
,
bool
diagonal
)
{
// Visiting stack
std
::
stack
<
Point
,
std
::
vector
<
Point
>>
visiting
;
visiting
.
push
(
start
);
// Contact sizes
const
auto
&
n
=
contact
.
sizes
();
while
(
not
visiting
.
empty
())
{
auto
p
=
unsigned_modulo
(
visiting
.
top
(),
n
);
if
(
visited
(
p
))
{
visiting
.
pop
();
continue
;
}
visited
(
p
)
=
true
;
points
.
push_back
(
visiting
.
top
());
visiting
.
pop
();
auto
process
=
[
&
](
const
std
::
vector
<
Point
>&
neighbors
,
const
bool
do_perimeter
)
{
for
(
auto
&
p
:
neighbors
)
{
auto
index
=
unsigned_modulo
(
p
,
n
);
if
(
not
visited
(
index
)
and
contact
(
index
))
{
visiting
.
push
(
cast_int
(
index
));
}
if
(
do_perimeter
and
(
not
contact
(
index
)))
++
perimeter
;
}
};
process
(
getNextNeighbors
(
p
),
true
);
if
(
diagonal
)
{
process
(
getDiagonalNeighbors
(
p
),
false
);
}
}
}
std
::
list
<
Cluster
<
1
>>
FloodFill
::
getSegments
(
const
Grid
<
bool
,
1
>&
contact
)
{
auto
n
=
contact
.
sizes
();
Grid
<
bool
,
1
>
visited
(
n
,
1
);
visited
=
false
;
std
::
list
<
Cluster
<
1
>>
clusters
;
for
(
UInt
i
=
0
;
i
<
n
[
0
];
++
i
)
{
if
(
contact
(
i
)
&&
!
visited
(
i
))
{
clusters
.
emplace_back
(
std
::
array
<
Int
,
1
>
{(
Int
)
i
},
contact
,
visited
,
false
);
}
}
return
clusters
;
}
std
::
list
<
Cluster
<
2
>>
FloodFill
::
getClusters
(
const
Grid
<
bool
,
2
>&
contact
,
bool
diagonal
)
{
auto
global_contact
=
Partitioner
<
2
>::
gather
(
contact
);
auto
n
=
global_contact
.
sizes
();
Grid
<
bool
,
2
>
visited
(
n
,
1
);
visited
=
false
;
std
::
list
<
Cluster
<
2
>>
clusters
;
if
(
mpi
::
rank
()
==
0
)
for
(
UInt
i
=
0
;
i
<
n
[
0
];
++
i
)
{
for
(
UInt
j
=
0
;
j
<
n
[
1
];
++
j
)
{
if
(
global_contact
(
i
,
j
)
&&
!
visited
(
i
,
j
))
{
clusters
.
emplace_back
(
std
::
array
<
Int
,
2
>
{(
Int
)
i
,
(
Int
)
j
},
global_contact
,
visited
,
diagonal
);
}
}
}
return
clusters
;
}
std
::
list
<
Cluster
<
3
>>
FloodFill
::
getVolumes
(
const
Grid
<
bool
,
3
>&
contact
,
bool
diagonal
)
{
auto
n
=
contact
.
sizes
();
Grid
<
bool
,
3
>
visited
(
n
,
1
);
visited
=
false
;
std
::
list
<
Cluster
<
3
>>
clusters
;
for
(
UInt
i
=
0
;
i
<
n
[
0
];
++
i
)
{
for
(
UInt
j
=
0
;
j
<
n
[
1
];
++
j
)
{
for
(
UInt
k
=
0
;
k
<
n
[
2
];
++
k
)
{
if
(
contact
(
i
,
j
,
k
)
&&
!
visited
(
i
,
j
,
k
))
{
clusters
.
emplace_back
(
std
::
array
<
Int
,
3
>
{(
Int
)
i
,
(
Int
)
j
,
(
Int
)
k
},
contact
,
visited
,
diagonal
);
}
}
}
}
return
clusters
;
}
template
class
Cluster
<
1
>
;
template
class
Cluster
<
2
>
;
template
class
Cluster
<
3
>
;
}
// namespace tamaas
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