/* -*- Mode: C; c-basic-offset:4 ; indent-tabs-mode:nil ; -*- */
/*
* (C) 2012 by Argonne National Laboratory.
* See COPYRIGHT in top-level directory.
*/
#include "mpiimpl.h"
/*
=== BEGIN_MPI_T_CVAR_INFO_BLOCK ===
cvars:
- name : MPIR_CVAR_NEIGHBOR_ALLTOALLW_INTRA_ALGORITHM
category : COLLECTIVE
type : string
default : auto
class : device
verbosity : MPI_T_VERBOSITY_USER_BASIC
scope : MPI_T_SCOPE_ALL_EQ
description : |-
Variable to select neighbor_alltoallw algorithm
auto - Internal algorithm selection
nb - Force nb algorithm
- name : MPIR_CVAR_NEIGHBOR_ALLTOALLW_INTER_ALGORITHM
category : COLLECTIVE
type : string
default : auto
class : device
verbosity : MPI_T_VERBOSITY_USER_BASIC
scope : MPI_T_SCOPE_ALL_EQ
description : |-
Variable to select neighbor_alltoallw algorithm
auto - Internal algorithm selection
nb - Force nb algorithm
- name : MPIR_CVAR_NEIGHBOR_ALLTOALLW_DEVICE_COLLECTIVE
category : COLLECTIVE
type : boolean
default : true
class : device
verbosity : MPI_T_VERBOSITY_USER_BASIC
scope : MPI_T_SCOPE_ALL_EQ
description : >-
If set to true, MPI_neighbor_alltoallw will allow the device to override the
MPIR-level collective algorithms. The device still has the
option to call the MPIR-level algorithms manually.
If set to false, the device-level neighbor_alltoallw function will not be
called.
=== END_MPI_T_CVAR_INFO_BLOCK ===
*/
/* -- Begin Profiling Symbol Block for routine MPI_Neighbor_alltoallw */
#if defined(HAVE_PRAGMA_WEAK)
#pragma weak MPI_Neighbor_alltoallw = PMPI_Neighbor_alltoallw
#elif defined(HAVE_PRAGMA_HP_SEC_DEF)
#pragma _HP_SECONDARY_DEF PMPI_Neighbor_alltoallw MPI_Neighbor_alltoallw
#elif defined(HAVE_PRAGMA_CRI_DUP)
#pragma _CRI duplicate MPI_Neighbor_alltoallw as PMPI_Neighbor_alltoallw
#elif defined(HAVE_WEAK_ATTRIBUTE)
int MPI_Neighbor_alltoallw(const void *sendbuf, const int sendcounts[], const MPI_Aint sdispls[],
const MPI_Datatype sendtypes[], void *recvbuf, const int recvcounts[],
const MPI_Aint rdispls[], const MPI_Datatype recvtypes[], MPI_Comm comm)
__attribute__ ((weak, alias("PMPI_Neighbor_alltoallw")));
#endif
/* -- End Profiling Symbol Block */
/* Define MPICH_MPI_FROM_PMPI if weak symbols are not supported to build
the MPI routines */
#ifndef MPICH_MPI_FROM_PMPI
#undef MPI_Neighbor_alltoallw
#define MPI_Neighbor_alltoallw PMPI_Neighbor_alltoallw
/* any non-MPI functions go here, especially non-static ones */
#undef FUNCNAME
#define FUNCNAME MPIR_Neighbor_alltoallw_intra_auto
#undef FCNAME
#define FCNAME MPL_QUOTE(FUNCNAME)
int MPIR_Neighbor_alltoallw_intra_auto(const void *sendbuf, const int sendcounts[],
const MPI_Aint sdispls[], const MPI_Datatype sendtypes[],
void *recvbuf, const int recvcounts[],
const MPI_Aint rdispls[], const MPI_Datatype recvtypes[],
MPIR_Comm * comm_ptr)
{
int mpi_errno = MPI_SUCCESS;
mpi_errno =
MPIR_Neighbor_alltoallw_allcomm_nb(sendbuf, sendcounts, sdispls, sendtypes, recvbuf,
recvcounts, rdispls, recvtypes, comm_ptr);
if (mpi_errno)
MPIR_ERR_POP(mpi_errno);
fn_exit:
return mpi_errno;
fn_fail:
goto fn_exit;
}
#undef FUNCNAME
#define FUNCNAME MPIR_Neighbor_alltoallw_inter_auto
#undef FCNAME
#define FCNAME MPL_QUOTE(FUNCNAME)
int MPIR_Neighbor_alltoallw_inter_auto(const void *sendbuf, const int sendcounts[],
const MPI_Aint sdispls[], const MPI_Datatype sendtypes[],
void *recvbuf, const int recvcounts[],
const MPI_Aint rdispls[], const MPI_Datatype recvtypes[],
MPIR_Comm * comm_ptr)
{
int mpi_errno = MPI_SUCCESS;
mpi_errno =
MPIR_Neighbor_alltoallw_allcomm_nb(sendbuf, sendcounts, sdispls, sendtypes, recvbuf,
recvcounts, rdispls, recvtypes, comm_ptr);
if (mpi_errno)
MPIR_ERR_POP(mpi_errno);
fn_exit:
return mpi_errno;
fn_fail:
goto fn_exit;
}
#undef FUNCNAME
#define FUNCNAME MPIR_Neighbor_alltoallw_impl
#undef FCNAME
#define FCNAME MPL_QUOTE(FUNCNAME)
int MPIR_Neighbor_alltoallw_impl(const void *sendbuf, const int sendcounts[],
const MPI_Aint sdispls[],
const MPI_Datatype sendtypes[], void *recvbuf,
const int recvcounts[],
const MPI_Aint rdispls[],
const MPI_Datatype recvtypes[], MPIR_Comm * comm_ptr)
{
int mpi_errno = MPI_SUCCESS;
if (comm_ptr->comm_kind == MPIR_COMM_KIND__INTRACOMM) {
switch (MPIR_Neighbor_alltoallw_intra_algo_choice) {
case MPIR_NEIGHBOR_ALLTOALLW_INTRA_ALGO_NB:
mpi_errno =
MPIR_Neighbor_alltoallw_allcomm_nb(sendbuf, sendcounts, sdispls, sendtypes,
recvbuf, recvcounts, rdispls, recvtypes,
comm_ptr);
break;
case MPIR_NEIGHBOR_ALLTOALLW_INTRA_ALGO_AUTO:
MPL_FALLTHROUGH;
default:
mpi_errno =
MPIR_Neighbor_alltoallw_intra_auto(sendbuf, sendcounts, sdispls, sendtypes,
recvbuf, recvcounts, rdispls, recvtypes,
comm_ptr);
break;
}
} else {
switch (MPIR_Neighbor_alltoallw_inter_algo_choice) {
case MPIR_NEIGHBOR_ALLTOALLW_INTER_ALGO_NB:
mpi_errno =
MPIR_Neighbor_alltoallw_allcomm_nb(sendbuf, sendcounts, sdispls, sendtypes,
recvbuf, recvcounts, rdispls, recvtypes,
comm_ptr);
break;
case MPIR_NEIGHBOR_ALLTOALLW_INTER_ALGO_AUTO:
MPL_FALLTHROUGH;
default:
mpi_errno =
MPIR_Neighbor_alltoallw_inter_auto(sendbuf, sendcounts, sdispls, sendtypes,
recvbuf, recvcounts, rdispls, recvtypes,
comm_ptr);
break;
}
}
if (mpi_errno)
MPIR_ERR_POP(mpi_errno);
fn_exit:
return mpi_errno;
fn_fail:
goto fn_exit;
}
#undef FUNCNAME
#define FUNCNAME MPIR_Neighbor_alltoallw
#undef FCNAME
#define FCNAME MPL_QUOTE(FUNCNAME)
int MPIR_Neighbor_alltoallw(const void *sendbuf, const int sendcounts[],
const MPI_Aint sdispls[],
const MPI_Datatype sendtypes[], void *recvbuf,
const int recvcounts[], const MPI_Aint rdispls[],
const MPI_Datatype recvtypes[], MPIR_Comm * comm_ptr)
{
int mpi_errno = MPI_SUCCESS;
if (MPIR_CVAR_BARRIER_DEVICE_COLLECTIVE && MPIR_CVAR_DEVICE_COLLECTIVES) {
mpi_errno = MPID_Neighbor_alltoallw(sendbuf, sendcounts, sdispls,
sendtypes, recvbuf, recvcounts,
rdispls, recvtypes, comm_ptr);
} else {
mpi_errno = MPIR_Neighbor_alltoallw_impl(sendbuf, sendcounts, sdispls,
sendtypes, recvbuf,
recvcounts, rdispls, recvtypes, comm_ptr);
}
return mpi_errno;
}
#endif /* MPICH_MPI_FROM_PMPI */
#undef FUNCNAME
#define FUNCNAME MPI_Neighbor_alltoallw
#undef FCNAME
#define FCNAME MPL_QUOTE(FUNCNAME)
/*@
MPI_Neighbor_alltoallw - Like MPI_Neighbor_alltoallv but it allows one to send
and receive with different types to and from each neighbor.
Input Parameters:
+ sendbuf - starting address of the send buffer (choice)
. sendcounts - non-negative integer array (of length outdegree) specifying the number of elements to send to each neighbor
. sdispls - integer array (of length outdegree). Entry j specifies the displacement in bytes (relative to sendbuf) from which to take the outgoing data destined for neighbor j (array of integers)
. sendtypes - array of datatypes (of length outdegree). Entry j specifies the type of data to send to neighbor j (array of handles)
. recvcounts - non-negative integer array (of length indegree) specifying the number of elements that are received from each neighbor
. rdispls - integer array (of length indegree). Entry i specifies the displacement in bytes (relative to recvbuf) at which to place the incoming data from neighbor i (array of integers).
. recvtypes - array of datatypes (of length indegree). Entry i specifies the type of data received from neighbor i (array of handles).
- comm - communicator with topology structure (handle)
Output Parameters:
. recvbuf - starting address of the receive buffer (choice)
.N ThreadSafe
.N Fortran
.N Errors
@*/
int MPI_Neighbor_alltoallw(const void *sendbuf, const int sendcounts[], const MPI_Aint sdispls[],
const MPI_Datatype sendtypes[], void *recvbuf, const int recvcounts[],
const MPI_Aint rdispls[], const MPI_Datatype recvtypes[], MPI_Comm comm)
{
int mpi_errno = MPI_SUCCESS;
MPIR_Comm *comm_ptr = NULL;
MPIR_FUNC_TERSE_STATE_DECL(MPID_STATE_MPI_NEIGHBOR_ALLTOALLW);
MPID_THREAD_CS_ENTER(GLOBAL, MPIR_THREAD_GLOBAL_ALLFUNC_MUTEX);
MPIR_FUNC_TERSE_ENTER(MPID_STATE_MPI_NEIGHBOR_ALLTOALLW);
/* Validate parameters, especially handles needing to be converted */
#ifdef HAVE_ERROR_CHECKING
{
MPID_BEGIN_ERROR_CHECKS;
{
MPIR_ERRTEST_COMM(comm, mpi_errno);
/* TODO more checks may be appropriate */
}
MPID_END_ERROR_CHECKS;
}
#endif /* HAVE_ERROR_CHECKING */
/* Convert MPI object handles to object pointers */
MPIR_Comm_get_ptr(comm, comm_ptr);
/* Validate parameters and objects (post conversion) */
#ifdef HAVE_ERROR_CHECKING
{
MPID_BEGIN_ERROR_CHECKS;
{
MPIR_Comm_valid_ptr(comm_ptr, mpi_errno, FALSE);
/* TODO more checks may be appropriate (counts, in_place, buffer aliasing, etc) */
if (mpi_errno != MPI_SUCCESS)
goto fn_fail;
}
MPID_END_ERROR_CHECKS;
}
#endif /* HAVE_ERROR_CHECKING */
/* ... body of routine ... */
mpi_errno = MPIR_Neighbor_alltoallw_impl(sendbuf, sendcounts, sdispls,
sendtypes, recvbuf, recvcounts,
rdispls, recvtypes, comm_ptr);
if (mpi_errno)
MPIR_ERR_POP(mpi_errno);
/* ... end of body of routine ... */
fn_exit:
MPIR_FUNC_TERSE_EXIT(MPID_STATE_MPI_NEIGHBOR_ALLTOALLW);
MPID_THREAD_CS_EXIT(GLOBAL, MPIR_THREAD_GLOBAL_ALLFUNC_MUTEX);
return mpi_errno;
fn_fail:
/* --BEGIN ERROR HANDLING-- */
#ifdef HAVE_ERROR_CHECKING
{
mpi_errno =
MPIR_Err_create_code(mpi_errno, MPIR_ERR_RECOVERABLE, FCNAME, __LINE__, MPI_ERR_OTHER,
"**mpi_neighbor_alltoallw",
"**mpi_neighbor_alltoallw %p %p %p %p %p %p %p %p %C", sendbuf,
sendcounts, sdispls, sendtypes, recvbuf, recvcounts, rdispls,
recvtypes, comm);
}
#endif
mpi_errno = MPIR_Err_return_comm(NULL, FCNAME, mpi_errno);
goto fn_exit;
/* --END ERROR HANDLING-- */
}