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rAKA akantu
grid_synchronizer.cc
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/**
* @file grid_synchronizer.cc
*
* @author Aurelia Isabel Cuba Ramos <aurelia.cubaramos@epfl.ch>
* @author Nicolas Richart <nicolas.richart@epfl.ch>
*
* @date creation: Mon Oct 03 2011
* @date last modification: Fri Jan 22 2016
*
* @brief implementation of the grid synchronizer
*
* @section LICENSE
*
* Copyright (©) 2010-2012, 2014, 2015 EPFL (Ecole Polytechnique Fédérale de
* Lausanne) Laboratory (LSMS - Laboratoire de Simulation en Mécanique des
* Solides)
*
* Akantu is free software: you can redistribute it and/or modify it under the
* terms of the GNU Lesser General Public License as published by the Free
* Software Foundation, either version 3 of the License, or (at your option) any
* later version.
*
* Akantu 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 Lesser General Public License for more
* details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with Akantu. If not, see <http://www.gnu.org/licenses/>.
*
*/
/* -------------------------------------------------------------------------- */
#include "grid_synchronizer.hh"
#include "aka_grid_dynamic.hh"
#include "mesh.hh"
#include "fe_engine.hh"
#include "integration_point.hh"
#include "static_communicator.hh"
#include "mesh_io.hh"
#include <iostream>
/* -------------------------------------------------------------------------- */
__BEGIN_AKANTU__
/* -------------------------------------------------------------------------- */
GridSynchronizer
::
GridSynchronizer
(
Mesh
&
mesh
,
const
ID
&
id
,
MemoryID
memory_id
,
const
bool
register_to_event_manager
)
:
ElementSynchronizer
(
mesh
,
id
,
memory_id
,
register_to_event_manager
)
{
AKANTU_DEBUG_IN
();
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
template
<
class
E
>
GridSynchronizer
*
GridSynchronizer
::
createGridSynchronizer
(
Mesh
&
mesh
,
const
SpatialGrid
<
E
>
&
grid
,
SynchronizerID
id
,
SynchronizerRegistry
*
synchronizer_registry
,
const
std
::
set
<
SynchronizationTag
>
&
tags_to_register
,
MemoryID
memory_id
,
const
bool
register_to_event_manager
)
{
AKANTU_DEBUG_IN
();
StaticCommunicator
&
comm
=
StaticCommunicator
::
getStaticCommunicator
();
UInt
nb_proc
=
comm
.
getNbProc
();
UInt
my_rank
=
comm
.
whoAmI
();
GridSynchronizer
&
communicator
=
*
(
new
GridSynchronizer
(
mesh
,
id
,
memory_id
,
register_to_event_manager
));
if
(
nb_proc
==
1
)
return
&
communicator
;
UInt
spatial_dimension
=
mesh
.
getSpatialDimension
();
Vector
<
Real
>
bounding_boxes
(
2
*
spatial_dimension
*
nb_proc
);
Vector
<
Real
>
my_bounding_box
(
bounding_boxes
.
storage
()
+
2
*
spatial_dimension
*
my_rank
,
2
*
spatial_dimension
);
// mesh.getLocalLowerBounds(my_bounding_box);
// mesh.getLocalUpperBounds(my_bounding_box + spatial_dimension);
const
Vector
<
Real
>
&
lower
=
grid
.
getLowerBounds
();
const
Vector
<
Real
>
&
upper
=
grid
.
getUpperBounds
();
const
Vector
<
Real
>
&
spacing
=
grid
.
getSpacing
();
for
(
UInt
i
=
0
;
i
<
spatial_dimension
;
++
i
)
{
my_bounding_box
[
i
]
=
lower
(
i
)
-
spacing
(
i
);
my_bounding_box
[
spatial_dimension
+
i
]
=
upper
(
i
)
+
spacing
(
i
);
}
AKANTU_DEBUG_INFO
(
"Exchange of bounding box to detect the overlapping regions."
);
comm
.
allGather
(
bounding_boxes
);
bool
*
intersects_proc
=
new
bool
[
nb_proc
];
std
::
fill_n
(
intersects_proc
,
nb_proc
,
true
);
Int
*
first_cells
=
new
Int
[
3
*
nb_proc
];
Int
*
last_cells
=
new
Int
[
3
*
nb_proc
];
std
::
fill_n
(
first_cells
,
3
*
nb_proc
,
0
);
std
::
fill_n
(
first_cells
,
3
*
nb_proc
,
0
);
ElementTypeMapArray
<
UInt
>
**
element_per_proc
=
new
ElementTypeMapArray
<
UInt
>
*
[
nb_proc
];
for
(
UInt
p
=
0
;
p
<
nb_proc
;
++
p
)
element_per_proc
[
p
]
=
NULL
;
// check the overlapping between my box and the one from other processors
for
(
UInt
p
=
0
;
p
<
nb_proc
;
++
p
)
{
if
(
p
==
my_rank
)
continue
;
Real
*
proc_bounding_box
=
bounding_boxes
.
storage
()
+
2
*
spatial_dimension
*
p
;
bool
intersects
=
false
;
Int
*
first_cell_p
=
first_cells
+
p
*
spatial_dimension
;
Int
*
last_cell_p
=
last_cells
+
p
*
spatial_dimension
;
for
(
UInt
s
=
0
;
s
<
spatial_dimension
;
++
s
)
{
// check overlapping of grid
intersects
=
Math
::
intersects
(
my_bounding_box
[
s
],
my_bounding_box
[
spatial_dimension
+
s
],
proc_bounding_box
[
s
],
proc_bounding_box
[
spatial_dimension
+
s
]);
intersects_proc
[
p
]
&=
intersects
;
if
(
intersects
)
{
AKANTU_DEBUG_INFO
(
"I intersects with processor "
<<
p
<<
" in direction "
<<
s
);
// is point 1 of proc p in the dimension s in the range ?
bool
point1
=
Math
::
is_in_range
(
proc_bounding_box
[
s
],
my_bounding_box
[
s
],
my_bounding_box
[
s
+
spatial_dimension
]);
// is point 2 of proc p in the dimension s in the range ?
bool
point2
=
Math
::
is_in_range
(
proc_bounding_box
[
s
+
spatial_dimension
],
my_bounding_box
[
s
],
my_bounding_box
[
s
+
spatial_dimension
]);
Real
start
=
0.
;
Real
end
=
0.
;
if
(
point1
&&
!
point2
)
{
/* |-----------| my_bounding_box(i)
* |-----------| proc_bounding_box(i)
* 1 2
*/
start
=
proc_bounding_box
[
s
];
end
=
my_bounding_box
[
s
+
spatial_dimension
];
AKANTU_DEBUG_INFO
(
"Intersection scheme 1 in direction "
<<
s
<<
" with processor "
<<
p
<<
" ["
<<
start
<<
", "
<<
end
<<
"]"
);
}
else
if
(
point1
&&
point2
)
{
/* |-----------------| my_bounding_box(i)
* |-----------| proc_bounding_box(i)
* 1 2
*/
start
=
proc_bounding_box
[
s
];
end
=
proc_bounding_box
[
s
+
spatial_dimension
];
AKANTU_DEBUG_INFO
(
"Intersection scheme 2 in direction "
<<
s
<<
" with processor "
<<
p
<<
" ["
<<
start
<<
", "
<<
end
<<
"]"
);
}
else
if
(
!
point1
&&
point2
)
{
/* |-----------| my_bounding_box(i)
* |-----------| proc_bounding_box(i)
* 1 2
*/
start
=
my_bounding_box
[
s
];
end
=
proc_bounding_box
[
s
+
spatial_dimension
];
AKANTU_DEBUG_INFO
(
"Intersection scheme 3 in direction "
<<
s
<<
" with processor "
<<
p
<<
" ["
<<
start
<<
", "
<<
end
<<
"]"
);
}
else
{
/* |-----------| my_bounding_box(i)
* |-----------------| proc_bounding_box(i)
* 1 2
*/
start
=
my_bounding_box
[
s
];
end
=
my_bounding_box
[
s
+
spatial_dimension
];
AKANTU_DEBUG_INFO
(
"Intersection scheme 4 in direction "
<<
s
<<
" with processor "
<<
p
<<
" ["
<<
start
<<
", "
<<
end
<<
"]"
);
}
first_cell_p
[
s
]
=
grid
.
getCellID
(
start
,
s
);
last_cell_p
[
s
]
=
grid
.
getCellID
(
end
,
s
);
}
}
// create the list of cells in the overlapping
typedef
typename
SpatialGrid
<
E
>::
CellID
CellID
;
std
::
vector
<
CellID
>
*
cell_ids
=
new
std
::
vector
<
CellID
>
;
if
(
intersects_proc
[
p
])
{
AKANTU_DEBUG_INFO
(
"I intersects with processor "
<<
p
);
CellID
cell_id
(
spatial_dimension
);
// for (UInt i = 0; i < spatial_dimension; ++i) {
// if(first_cell_p[i] != 0) --first_cell_p[i];
// if(last_cell_p[i] != 0) ++last_cell_p[i];
// }
for
(
Int
fd
=
first_cell_p
[
0
];
fd
<=
last_cell_p
[
0
];
++
fd
)
{
cell_id
.
setID
(
0
,
fd
);
if
(
spatial_dimension
==
1
)
{
cell_ids
->
push_back
(
cell_id
);
}
else
{
for
(
Int
sd
=
first_cell_p
[
1
];
sd
<=
last_cell_p
[
1
];
++
sd
)
{
cell_id
.
setID
(
1
,
sd
);
if
(
spatial_dimension
==
2
)
{
cell_ids
->
push_back
(
cell_id
);
}
else
{
for
(
Int
ld
=
first_cell_p
[
2
];
ld
<=
last_cell_p
[
2
];
++
ld
)
{
cell_id
.
setID
(
2
,
ld
);
cell_ids
->
push_back
(
cell_id
);
}
}
}
}
}
// get the list of elements in the cells of the overlapping
typename
std
::
vector
<
CellID
>::
iterator
cur_cell_id
=
cell_ids
->
begin
();
typename
std
::
vector
<
CellID
>::
iterator
last_cell_id
=
cell_ids
->
end
();
std
::
set
<
Element
>
*
to_send
=
new
std
::
set
<
Element
>
();
for
(;
cur_cell_id
!=
last_cell_id
;
++
cur_cell_id
)
{
typename
SpatialGrid
<
E
>::
Cell
::
const_iterator
cur_elem
=
grid
.
beginCell
(
*
cur_cell_id
);
typename
SpatialGrid
<
E
>::
Cell
::
const_iterator
last_elem
=
grid
.
endCell
(
*
cur_cell_id
);
for
(;
cur_elem
!=
last_elem
;
++
cur_elem
)
{
to_send
->
insert
(
*
cur_elem
);
}
}
AKANTU_DEBUG_INFO
(
"I have prepared "
<<
to_send
->
size
()
<<
" elements to send to processor "
<<
p
);
auto
&
scheme
=
communicator
.
getCommunications
().
createSendScheme
(
p
);
std
::
stringstream
sstr
;
sstr
<<
"element_per_proc_"
<<
p
;
element_per_proc
[
p
]
=
new
ElementTypeMapArray
<
UInt
>
(
sstr
.
str
(),
id
,
memory_id
);
ElementTypeMapArray
<
UInt
>
&
elempproc
=
*
(
element_per_proc
[
p
]);
typename
std
::
set
<
Element
>::
iterator
elem
=
to_send
->
begin
();
typename
std
::
set
<
Element
>::
iterator
last_elem
=
to_send
->
end
();
for
(;
elem
!=
last_elem
;
++
elem
)
{
ElementType
type
=
elem
->
type
;
UInt
nb_nodes_per_element
=
mesh
.
getNbNodesPerElement
(
type
);
// /!\ this part must be slow due to the access in the
// ElementTypeMapArray<UInt>
if
(
!
elempproc
.
exists
(
type
,
_not_ghost
))
elempproc
.
alloc
(
0
,
nb_nodes_per_element
,
type
,
_not_ghost
);
Vector
<
UInt
>
global_connect
(
nb_nodes_per_element
);
UInt
*
local_connect
=
mesh
.
getConnectivity
(
type
).
storage
()
+
elem
->
element
*
nb_nodes_per_element
;
for
(
UInt
i
=
0
;
i
<
nb_nodes_per_element
;
++
i
)
{
global_connect
(
i
)
=
mesh
.
getNodeGlobalId
(
local_connect
[
i
]);
AKANTU_DEBUG_ASSERT
(
global_connect
(
i
)
<
mesh
.
getNbGlobalNodes
(),
"This global node send in the connectivity does not seem correct "
<<
global_connect
(
i
)
<<
" corresponding to "
<<
local_connect
[
i
]
<<
" from element "
<<
elem
->
element
);
}
elempproc
(
type
).
push_back
(
global_connect
);
scheme
.
push_back
(
*
elem
);
}
delete
to_send
;
}
delete
cell_ids
;
}
delete
[]
first_cells
;
delete
[]
last_cells
;
AKANTU_DEBUG_INFO
(
"I have finished to compute intersection,"
<<
" no it's time to communicate with my neighbors"
);
/**
* Sending loop, sends the connectivity asynchronously to all concerned proc
*/
std
::
vector
<
CommunicationRequest
>
isend_requests
;
UInt
*
space
=
new
UInt
[
2
*
nb_proc
*
_max_element_type
];
UInt
offset
=
0
;
for
(
UInt
p
=
0
;
p
<
nb_proc
;
++
p
)
{
if
(
p
==
my_rank
)
continue
;
if
(
intersects_proc
[
p
])
{
ElementTypeMapArray
<
UInt
>
&
elempproc
=
*
(
element_per_proc
[
p
]);
ElementTypeMapArray
<
UInt
>::
type_iterator
it_type
=
elempproc
.
firstType
(
_all_dimensions
,
_not_ghost
);
ElementTypeMapArray
<
UInt
>::
type_iterator
last_type
=
elempproc
.
lastType
(
_all_dimensions
,
_not_ghost
);
UInt
count
=
0
;
for
(;
it_type
!=
last_type
;
++
it_type
)
{
Array
<
UInt
>
&
conn
=
elempproc
(
*
it_type
,
_not_ghost
);
Vector
<
UInt
>
info
(
space
+
offset
,
2
);
offset
+=
2
;
info
[
0
]
=
(
UInt
)
*
it_type
;
info
[
1
]
=
conn
.
getSize
()
*
conn
.
getNbComponent
();
AKANTU_DEBUG_INFO
(
"I have "
<<
conn
.
getSize
()
<<
" elements of type "
<<
*
it_type
<<
" to send to processor "
<<
p
<<
" (communication tag : "
<<
Tag
::
genTag
(
my_rank
,
count
,
DATA_TAG
)
<<
")"
);
isend_requests
.
push_back
(
comm
.
asyncSend
(
info
,
p
,
Tag
::
genTag
(
my_rank
,
count
,
SIZE_TAG
)));
if
(
info
[
1
]
!=
0
)
isend_requests
.
push_back
(
comm
.
asyncSend
<
UInt
>
(
conn
,
p
,
Tag
::
genTag
(
my_rank
,
count
,
DATA_TAG
)));
++
count
;
}
Vector
<
UInt
>
info
(
space
+
offset
,
2
);
offset
+=
2
;
info
[
0
]
=
(
UInt
)
_not_defined
;
info
[
1
]
=
0
;
isend_requests
.
push_back
(
comm
.
asyncSend
(
info
,
p
,
Tag
::
genTag
(
my_rank
,
count
,
SIZE_TAG
)));
}
}
/**
* Receives the connectivity and store them in the ghosts elements
*/
Array
<
UInt
>
&
global_nodes_ids
=
const_cast
<
Array
<
UInt
>
&>
(
mesh
.
getGlobalNodesIds
());
Array
<
NodeType
>
&
nodes_type
=
const_cast
<
Array
<
NodeType
>
&>
(
const_cast
<
const
Mesh
&>
(
mesh
).
getNodesType
());
std
::
vector
<
CommunicationRequest
>
isend_nodes_requests
;
Vector
<
UInt
>
nb_nodes_to_recv
(
nb_proc
);
UInt
nb_total_nodes_to_recv
=
0
;
UInt
nb_current_nodes
=
global_nodes_ids
.
getSize
();
NewNodesEvent
new_nodes
;
NewElementsEvent
new_elements
;
Array
<
UInt
>
*
ask_nodes_per_proc
=
new
Array
<
UInt
>
[
nb_proc
];
for
(
UInt
p
=
0
;
p
<
nb_proc
;
++
p
)
{
nb_nodes_to_recv
(
p
)
=
0
;
if
(
p
==
my_rank
)
continue
;
auto
&
scheme
=
communicator
.
getCommunications
().
createRecvScheme
(
p
);
Array
<
UInt
>
&
ask_nodes
=
ask_nodes_per_proc
[
p
];
UInt
count
=
0
;
if
(
intersects_proc
[
p
])
{
ElementType
type
=
_not_defined
;
do
{
Vector
<
UInt
>
info
(
2
);
comm
.
receive
(
info
,
p
,
Tag
::
genTag
(
p
,
count
,
SIZE_TAG
));
type
=
(
ElementType
)
info
[
0
];
if
(
type
!=
_not_defined
)
{
UInt
nb_nodes_per_element
=
mesh
.
getNbNodesPerElement
(
type
);
;
UInt
nb_element
=
info
[
1
]
/
nb_nodes_per_element
;
Array
<
UInt
>
tmp_conn
(
nb_element
,
nb_nodes_per_element
);
tmp_conn
.
clear
();
if
(
info
[
1
]
!=
0
)
comm
.
receive
<
UInt
>
(
tmp_conn
,
p
,
Tag
::
genTag
(
p
,
count
,
DATA_TAG
));
AKANTU_DEBUG_INFO
(
"I will receive "
<<
nb_element
<<
" elements of type "
<<
ElementType
(
info
[
0
])
<<
" from processor "
<<
p
<<
" (communication tag : "
<<
Tag
::
genTag
(
p
,
count
,
DATA_TAG
)
<<
")"
);
Array
<
UInt
>
&
ghost_connectivity
=
const_cast
<
Array
<
UInt
>
&>
(
mesh
.
getConnectivity
(
type
,
_ghost
));
UInt
nb_ghost_element
=
ghost_connectivity
.
getSize
();
Element
element
(
type
,
0
,
_ghost
);
Vector
<
UInt
>
conn
(
nb_nodes_per_element
);
for
(
UInt
el
=
0
;
el
<
nb_element
;
++
el
)
{
UInt
nb_node_to_ask_for_elem
=
0
;
for
(
UInt
n
=
0
;
n
<
nb_nodes_per_element
;
++
n
)
{
UInt
gn
=
tmp_conn
(
el
,
n
);
UInt
ln
=
global_nodes_ids
.
find
(
gn
);
AKANTU_DEBUG_ASSERT
(
gn
<
mesh
.
getNbGlobalNodes
(),
"This global node seems not correct "
<<
gn
<<
" from element "
<<
el
<<
" node "
<<
n
);
if
(
ln
==
UInt
(
-
1
))
{
global_nodes_ids
.
push_back
(
gn
);
nodes_type
.
push_back
(
_nt_pure_gost
);
// pure ghost node
ln
=
nb_current_nodes
;
new_nodes
.
getList
().
push_back
(
ln
);
++
nb_current_nodes
;
ask_nodes
.
push_back
(
gn
);
++
nb_node_to_ask_for_elem
;
}
conn
[
n
]
=
ln
;
}
// all the nodes are already known locally, the element should
// already exists
UInt
c
=
UInt
(
-
1
);
if
(
nb_node_to_ask_for_elem
==
0
)
{
c
=
ghost_connectivity
.
find
(
conn
);
element
.
element
=
c
;
}
if
(
c
==
UInt
(
-
1
))
{
element
.
element
=
nb_ghost_element
;
++
nb_ghost_element
;
ghost_connectivity
.
push_back
(
conn
);
new_elements
.
getList
().
push_back
(
element
);
}
scheme
.
push_back
(
element
);
}
}
count
++
;
}
while
(
type
!=
_not_defined
);
AKANTU_DEBUG_INFO
(
"I have "
<<
ask_nodes
.
getSize
()
<<
" missing nodes for elements coming from processor "
<<
p
<<
" (communication tag : "
<<
Tag
::
genTag
(
my_rank
,
0
,
ASK_NODES_TAG
)
<<
")"
);
ask_nodes
.
push_back
(
UInt
(
-
1
));
isend_nodes_requests
.
push_back
(
comm
.
asyncSend
(
ask_nodes
,
p
,
Tag
::
genTag
(
my_rank
,
0
,
ASK_NODES_TAG
)));
nb_nodes_to_recv
(
p
)
=
ask_nodes
.
getSize
()
-
1
;
nb_total_nodes_to_recv
+=
nb_nodes_to_recv
(
p
);
}
}
comm
.
waitAll
(
isend_requests
);
comm
.
freeCommunicationRequest
(
isend_requests
);
delete
[]
space
;
for
(
UInt
p
=
0
;
p
<
nb_proc
;
++
p
)
{
if
(
element_per_proc
[
p
])
delete
element_per_proc
[
p
];
}
delete
[]
element_per_proc
;
/**
* Sends requested nodes to proc
*/
Array
<
Real
>
&
nodes
=
const_cast
<
Array
<
Real
>
&>
(
mesh
.
getNodes
());
UInt
nb_nodes
=
nodes
.
getSize
();
std
::
vector
<
CommunicationRequest
>
isend_coordinates_requests
;
Array
<
Real
>
*
nodes_to_send_per_proc
=
new
Array
<
Real
>
[
nb_proc
];
for
(
UInt
p
=
0
;
p
<
nb_proc
;
++
p
)
{
if
(
p
==
my_rank
||
!
intersects_proc
[
p
])
continue
;
Array
<
UInt
>
asked_nodes
;
CommunicationStatus
status
;
AKANTU_DEBUG_INFO
(
"Waiting list of nodes to send to processor "
<<
p
<<
"(communication tag : "
<<
Tag
::
genTag
(
p
,
0
,
ASK_NODES_TAG
)
<<
")"
);
comm
.
probe
<
UInt
>
(
p
,
Tag
::
genTag
(
p
,
0
,
ASK_NODES_TAG
),
status
);
UInt
nb_nodes_to_send
=
status
.
getSize
();
asked_nodes
.
resize
(
nb_nodes_to_send
);
AKANTU_DEBUG_INFO
(
"I have "
<<
nb_nodes_to_send
-
1
<<
" nodes to send to processor "
<<
p
<<
" (communication tag : "
<<
Tag
::
genTag
(
p
,
0
,
ASK_NODES_TAG
)
<<
")"
);
AKANTU_DEBUG_INFO
(
"Getting list of nodes to send to processor "
<<
p
<<
" (communication tag : "
<<
Tag
::
genTag
(
p
,
0
,
ASK_NODES_TAG
)
<<
")"
);
comm
.
receive
(
asked_nodes
,
p
,
Tag
::
genTag
(
p
,
0
,
ASK_NODES_TAG
));
nb_nodes_to_send
--
;
asked_nodes
.
resize
(
nb_nodes_to_send
);
Array
<
Real
>
&
nodes_to_send
=
nodes_to_send_per_proc
[
p
];
nodes_to_send
.
extendComponentsInterlaced
(
spatial_dimension
,
1
);
auto
it
=
nodes
.
begin
(
spatial_dimension
);
for
(
UInt
n
=
0
;
n
<
nb_nodes_to_send
;
++
n
)
{
UInt
ln
=
global_nodes_ids
.
find
(
asked_nodes
(
n
));
AKANTU_DEBUG_ASSERT
(
ln
!=
UInt
(
-
1
),
"The node ["
<<
asked_nodes
(
n
)
<<
"] requested by proc "
<<
p
<<
" was not found locally!"
);
nodes_to_send
.
push_back
(
it
+
ln
);
}
if
(
nb_nodes_to_send
!=
0
)
{
AKANTU_DEBUG_INFO
(
"Sending the "
<<
nb_nodes_to_send
<<
" nodes to processor "
<<
p
<<
" (communication tag : "
<<
Tag
::
genTag
(
p
,
0
,
SEND_NODES_TAG
)
<<
")"
);
isend_coordinates_requests
.
push_back
(
comm
.
asyncSend
(
nodes_to_send
,
p
,
Tag
::
genTag
(
my_rank
,
0
,
SEND_NODES_TAG
)));
}
#if not defined(AKANTU_NDEBUG)
else
{
AKANTU_DEBUG_INFO
(
"No nodes to send to processor "
<<
p
);
}
#endif
}
comm
.
waitAll
(
isend_nodes_requests
);
comm
.
freeCommunicationRequest
(
isend_nodes_requests
);
delete
[]
ask_nodes_per_proc
;
nodes
.
resize
(
nb_total_nodes_to_recv
+
nb_nodes
);
for
(
UInt
p
=
0
;
p
<
nb_proc
;
++
p
)
{
if
((
p
!=
my_rank
)
&&
(
nb_nodes_to_recv
(
p
)
>
0
))
{
AKANTU_DEBUG_INFO
(
"Receiving the "
<<
nb_nodes_to_recv
(
p
)
<<
" nodes from processor "
<<
p
<<
" (communication tag : "
<<
Tag
::
genTag
(
p
,
0
,
SEND_NODES_TAG
)
<<
")"
);
Vector
<
Real
>
nodes_to_recv
(
nodes
.
storage
()
+
nb_nodes
*
spatial_dimension
,
nb_nodes_to_recv
(
p
)
*
spatial_dimension
);
comm
.
receive
(
nodes_to_recv
,
p
,
Tag
::
genTag
(
p
,
0
,
SEND_NODES_TAG
));
nb_nodes
+=
nb_nodes_to_recv
(
p
);
}
#if not defined(AKANTU_NDEBUG)
else
{
if
(
p
!=
my_rank
)
{
AKANTU_DEBUG_INFO
(
"No nodes to receive from processor "
<<
p
);
}
}
#endif
}
comm
.
waitAll
(
isend_coordinates_requests
);
comm
.
freeCommunicationRequest
(
isend_coordinates_requests
);
delete
[]
nodes_to_send_per_proc
;
// Register the tags if any
if
(
synchronizer_registry
)
{
std
::
set
<
SynchronizationTag
>::
const_iterator
it
=
tags_to_register
.
begin
();
std
::
set
<
SynchronizationTag
>::
const_iterator
end
=
tags_to_register
.
end
();
for
(;
it
!=
end
;
++
it
)
{
synchronizer_registry
->
registerSynchronizer
(
communicator
,
*
it
);
}
}
mesh
.
sendEvent
(
new_nodes
);
mesh
.
sendEvent
(
new_elements
);
delete
[]
intersects_proc
;
AKANTU_DEBUG_OUT
();
return
&
communicator
;
}
/* -------------------------------------------------------------------------- */
template
GridSynchronizer
*
GridSynchronizer
::
createGridSynchronizer
<
IntegrationPoint
>
(
Mesh
&
mesh
,
const
SpatialGrid
<
IntegrationPoint
>
&
grid
,
SynchronizerID
id
,
SynchronizerRegistry
*
synchronizer_registry
,
const
std
::
set
<
SynchronizationTag
>
&
tags_to_register
,
MemoryID
memory_id
,
const
bool
register_to_event_manager
);
template
GridSynchronizer
*
GridSynchronizer
::
createGridSynchronizer
<
Element
>
(
Mesh
&
mesh
,
const
SpatialGrid
<
Element
>
&
grid
,
SynchronizerID
id
,
SynchronizerRegistry
*
synchronizer_registry
,
const
std
::
set
<
SynchronizationTag
>
&
tags_to_register
,
MemoryID
memory_id
,
const
bool
register_to_event_manager
);
__END_AKANTU__
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