1
1
openmpi/ompi/mca/op/op.h

422 строки
14 KiB
C
Исходник Обычный вид История

Two major things in this commit: * New "op" MPI layer framework * Addition of the MPI_REDUCE_LOCAL proposed function (for MPI-2.2) = Op framework = Add new "op" framework in the ompi layer. This framework replaces the hard-coded MPI_Op back-end functions for (MPI_Op, MPI_Datatype) tuples for pre-defined MPI_Ops, allowing components and modules to provide the back-end functions. The intent is that components can be written to take advantage of hardware acceleration (GPU, FPGA, specialized CPU instructions, etc.). Similar to other frameworks, components are intended to be able to discover at run-time if they can be used, and if so, elect themselves to be selected (or disqualify themselves from selection if they cannot run). If specialized hardware is not available, there is a default set of functions that will automatically be used. This framework is ''not'' used for user-defined MPI_Ops. The new op framework is similar to the existing coll framework, in that the final set of function pointers that are used on any given intrinsic MPI_Op can be a mixed bag of function pointers, potentially coming from multiple different op modules. This allows for hardware that only supports some of the operations, not all of them (e.g., a GPU that only supports single-precision operations). All the hard-coded back-end MPI_Op functions for (MPI_Op, MPI_Datatype) tuples still exist, but unlike coll, they're in the framework base (vs. being in a separate "basic" component) and are automatically used if no component is found at runtime that provides a module with the necessary function pointers. There is an "example" op component that will hopefully be useful to those writing meaningful op components. It is currently .ompi_ignore'd so that it doesn't impinge on other developers (it's somewhat chatty in terms of opal_output() so that you can tell when its functions have been invoked). See the README file in the example op component directory. Developers of new op components are encouraged to look at the following wiki pages: https://svn.open-mpi.org/trac/ompi/wiki/devel/Autogen https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateComponent https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateFramework = MPI_REDUCE_LOCAL = Part of the MPI-2.2 proposal listed here: https://svn.mpi-forum.org/trac/mpi-forum-web/ticket/24 is to add a new function named MPI_REDUCE_LOCAL. It is very easy to implement, so I added it (also because it makes testing the op framework pretty easy -- you can do it in serial rather than via parallel reductions). There's even a man page! This commit was SVN r20280.
2009-01-15 02:44:31 +03:00
/*
* Copyright (c) 2004-2007 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2008 The University of Tennessee and The University
* of Tennessee Research Foundation. All rights
* reserved.
* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
* University of Stuttgart. All rights reserved.
* Copyright (c) 2004-2005 The Regents of the University of California.
* All rights reserved.
* Copyright (c) 2006-2007 Los Alamos National Security, LLC. All rights
* reserved.
* Copyright (c) 2007-2008 UT-Battelle, LLC
* Copyright (c) 2007-2009 Cisco Systems, Inc. All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
/**
* @file
*
* MPI_Op back-end operation framework. This framework allows
* component-izing the back-end operations of MPI_Op in order to use
* specialized hardware (e.g., mathematical accelerators). In short:
* each MPI_Op contains a table of function pointers; one for
* implementing the operation on each predefined datatype.
*
* The MPI interface provides error checking and error handler
* invocation, but the op components provide all other functionality.
*
* Component selection is done on a per-MPI_Op basis when each MPI_Op
* is created. All MPI_Ops go through the selection process, even
* user-defined MPI_Ops -- although it is expected that most (all?)
* op components will only be able to handle the predefined MPI_Ops.
*
* The general sequence of usage for the op framework is:
*
* 1. ompi_op_base_open() is invoked during MPI_INIT to find/open all
* op components.
*
* 2. ompi_op_base_find_available() is invoked during MPI_INIT to call
* each successfully opened op component's opc_init_query() function.
* All op components that return OMPI_SUCCESS are kept; all others are
* closed and removed from the process.
*
* 3. ompi_op_base_op_select() is invoked during MPI_INIT for each
* predefined MPI_Op (e.g., MPI_SUM). This function will call each
* available op component's opc_op_query() function to see if this
* component wants to provide a module for one or more of the function
* pointers on this MPI_Op. Priorities are used to rank returned
* modules; the module with the highest priority has its function
* pointers set in the MPI_Op function table.
*
* Note that a module may only have *some* non-NULL function pointers
* (i.e., for the functions that it can support). For example, some
* modules may only support operations on single-precision floating
* point datatypes. These modules would provide function pointers for
* these datatypes and NULL for all the rest. The op framework will
* mix-n-match function pointers between modules to obtain a full set
* of non-NULL function pointers for a given MPI_Op (note that the op
* base provides a complete set of functions for the MPI_Op, usually a
* simple C loop around the operation, such as "+=" -- so even if
* there is no specialized op component available, there will *always*
* be a full set of MPI_Op function pointers). The op framework will
* OBJ_RETAIN an op module once for each function pointer where it is
* used on a given MPI_Op.
*
* Note that this scheme can result in up to N different modules being
* used for a single MPI_Op, one per needed datatype function.
*
* 5. Finally, during MPI_FINALIZE, ompi_op_base_close() is invoked to
* close all available op components.
*/
#ifndef MCA_OP_H
#define MCA_OP_H
Preparation work for another commit (after RFC): - This patch solely _adds_ required headers and is rather localized The next patch (after RFC) heavily removes headers (based on script) - ompi/communicator/communicator.h: For sources that use ompi_mpi_comm_world, don't require them to include "mpi.h" - ompi/debuggers/ompi_common_dll.c: mca_topo_base_comm_1_0_0_t needs #include "ompi/mca/topo/topo.h" - ompi/errhandler/errhandler_predefined.h: ompi/communicator/communicator.h depends on this header file! To prevent recursion just have fwd declarations. #include "ompi/types.h" for fwd declarations of the main structs. - ompi/mca/btl/btl.h: #include "opal/types.h" for ompi_ptr_t - ompi/mca/mpool/base/mpool_base_tree.c: We use ompi_free_list_t and ompi_rb_tree_t, so have the proper classes - ompi/mca/op/op.h: Op is pretty self-contained: Nobody up to now has done #include "opal/class/opal_object.h" - ompi/mca/osc/pt2pt/osc_pt2pt_replyreq.h: #include "opal/types.h" for ompi_ptr_t - ompi/mca/pml/base/base.h: We use opal_lists - ompi/mca/pml/dr/pml_dr_vfrag.h: #include "opal/types.h" for ompi_ptr_t - ompi/mca/pml/ob1/pml_ob1_hdr.h: #include "ompi/mca/btl/btl.h" for mca_btl_base_segment_t - opal/dss/dss_unpack.c: #include "opal/types.h" - opal/mca/base/base.h: #include "opal/util/cmd_line.h" for opal_cmd_line_t - orte/mca/oob/tcp/oob_tcp.c: #include "opal/types.h" for opal_socklen_t - orte/mca/oob/tcp/oob_tcp.h: #include "opal/threads/threads.h" for opal_thread_t - orte/mca/oob/tcp/oob_tcp_msg.c: #include "opal/types.h" - orte/mca/oob/tcp/oob_tcp_peer.c: #include "opal/types.h" for opal_socklen_t - orte/mca/oob/tcp/oob_tcp_send.c: #include "opal/types.h" - orte/mca/plm/base/plm_base_proxy.c: #include "orte/util/name_fns.h" for ORTE_NAME_PRINT - orte/mca/rml/base/rml_base_receive.c: #include "opal/util/output.h" for OPAL_OUTPUT_VERBOSE - orte/mca/rml/oob/rml_oob_recv.c: #include "opal/types.h" for ompi_iov_base_ptr_t - orte/mca/rml/oob/rml_oob_send.c: #include "opal/types.h" for ompi_iov_base_ptr_t - orte/runtime/orte_data_server.c #include "opal/util/output.h" for OPAL_OUTPUT_VERBOSE - orte/runtime/orte_globals.h: #include "orte/util/name_fns.h" for ORTE_NAME_PRINT Tested on Linux/x86-64 This commit was SVN r20817.
2009-03-18 00:34:30 +03:00
#include "ompi_config.h"
#include "opal/class/opal_object.h"
#include "opal/mca/mca.h"
Two major things in this commit: * New "op" MPI layer framework * Addition of the MPI_REDUCE_LOCAL proposed function (for MPI-2.2) = Op framework = Add new "op" framework in the ompi layer. This framework replaces the hard-coded MPI_Op back-end functions for (MPI_Op, MPI_Datatype) tuples for pre-defined MPI_Ops, allowing components and modules to provide the back-end functions. The intent is that components can be written to take advantage of hardware acceleration (GPU, FPGA, specialized CPU instructions, etc.). Similar to other frameworks, components are intended to be able to discover at run-time if they can be used, and if so, elect themselves to be selected (or disqualify themselves from selection if they cannot run). If specialized hardware is not available, there is a default set of functions that will automatically be used. This framework is ''not'' used for user-defined MPI_Ops. The new op framework is similar to the existing coll framework, in that the final set of function pointers that are used on any given intrinsic MPI_Op can be a mixed bag of function pointers, potentially coming from multiple different op modules. This allows for hardware that only supports some of the operations, not all of them (e.g., a GPU that only supports single-precision operations). All the hard-coded back-end MPI_Op functions for (MPI_Op, MPI_Datatype) tuples still exist, but unlike coll, they're in the framework base (vs. being in a separate "basic" component) and are automatically used if no component is found at runtime that provides a module with the necessary function pointers. There is an "example" op component that will hopefully be useful to those writing meaningful op components. It is currently .ompi_ignore'd so that it doesn't impinge on other developers (it's somewhat chatty in terms of opal_output() so that you can tell when its functions have been invoked). See the README file in the example op component directory. Developers of new op components are encouraged to look at the following wiki pages: https://svn.open-mpi.org/trac/ompi/wiki/devel/Autogen https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateComponent https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateFramework = MPI_REDUCE_LOCAL = Part of the MPI-2.2 proposal listed here: https://svn.mpi-forum.org/trac/mpi-forum-web/ticket/24 is to add a new function named MPI_REDUCE_LOCAL. It is very easy to implement, so I added it (also because it makes testing the op framework pretty easy -- you can do it in serial rather than via parallel reductions). There's even a man page! This commit was SVN r20280.
2009-01-15 02:44:31 +03:00
/*
* This file includes some basic struct declarations (but not
* definitions) just so that we can avoid including files like op/op.h
* and datatype/datatype.h, which would create #include file loops.
*/
#include "ompi/types.h"
BEGIN_C_DECLS
/**
* Corresponding to the types that we can reduce over. See
* MPI-1:4.9.2, p114-115 and
* MPI-2:4.15, p76-77
*/
enum {
/** C integer: unsigned char */
OMPI_OP_BASE_TYPE_UNSIGNED_CHAR,
/** C integer: signed char */
OMPI_OP_BASE_TYPE_SIGNED_CHAR,
/** C integer: int */
OMPI_OP_BASE_TYPE_INT,
/** C integer: long */
OMPI_OP_BASE_TYPE_LONG,
/** C integer: short */
OMPI_OP_BASE_TYPE_SHORT,
/** C integer: unsigned short */
OMPI_OP_BASE_TYPE_UNSIGNED_SHORT,
/** C integer: unsigned */
OMPI_OP_BASE_TYPE_UNSIGNED,
/** C integer: unsigned long */
OMPI_OP_BASE_TYPE_UNSIGNED_LONG,
/** C integer: long long int (optional) */
OMPI_OP_BASE_TYPE_LONG_LONG_INT,
/** C integer: unsigned long long (optional) */
OMPI_OP_BASE_TYPE_UNSIGNED_LONG_LONG,
/** Fortran integer */
OMPI_OP_BASE_TYPE_INTEGER,
/** Fortran integer*1 */
OMPI_OP_BASE_TYPE_INTEGER1,
/** Fortran integer*2 */
OMPI_OP_BASE_TYPE_INTEGER2,
/** Fortran integer*4 */
OMPI_OP_BASE_TYPE_INTEGER4,
/** Fortran integer*8 */
OMPI_OP_BASE_TYPE_INTEGER8,
/** Fortran integer*16 */
OMPI_OP_BASE_TYPE_INTEGER16,
/** Floating point: float */
OMPI_OP_BASE_TYPE_FLOAT,
/** Floating point: double */
OMPI_OP_BASE_TYPE_DOUBLE,
/** Floating point: real */
OMPI_OP_BASE_TYPE_REAL,
/** Floating point: real*2 */
OMPI_OP_BASE_TYPE_REAL2,
/** Floating point: real*4 */
OMPI_OP_BASE_TYPE_REAL4,
/** Floating point: real*8 */
OMPI_OP_BASE_TYPE_REAL8,
/** Floating point: real*16 */
OMPI_OP_BASE_TYPE_REAL16,
/** Floating point: double precision */
OMPI_OP_BASE_TYPE_DOUBLE_PRECISION,
/** Floating point: long double */
OMPI_OP_BASE_TYPE_LONG_DOUBLE,
/** Logical */
OMPI_OP_BASE_TYPE_LOGICAL,
/** Bool */
OMPI_OP_BASE_TYPE_BOOL,
/** Complex */
OMPI_OP_BASE_TYPE_COMPLEX,
/** Double complex */
OMPI_OP_BASE_TYPE_DOUBLE_COMPLEX,
/** Complex8 */
OMPI_OP_BASE_TYPE_COMPLEX8,
/** Complex16 */
OMPI_OP_BASE_TYPE_COMPLEX16,
/** Complex32 */
OMPI_OP_BASE_TYPE_COMPLEX32,
/** Byte */
OMPI_OP_BASE_TYPE_BYTE,
/** 2 location Fortran: 2 real */
OMPI_OP_BASE_TYPE_2REAL,
/** 2 location Fortran: 2 double precision */
OMPI_OP_BASE_TYPE_2DOUBLE_PRECISION,
/** 2 location Fortran: 2 integer */
OMPI_OP_BASE_TYPE_2INTEGER,
/** 2 location C: float int */
OMPI_OP_BASE_TYPE_FLOAT_INT,
/** 2 location C: double int */
OMPI_OP_BASE_TYPE_DOUBLE_INT,
/** 2 location C: long int */
OMPI_OP_BASE_TYPE_LONG_INT,
/** 2 location C: int int */
OMPI_OP_BASE_TYPE_2INT,
/** 2 location C: short int */
OMPI_OP_BASE_TYPE_SHORT_INT,
/** 2 location C: long double int */
OMPI_OP_BASE_TYPE_LONG_DOUBLE_INT,
/** 2 location C: wchar_t */
OMPI_OP_BASE_TYPE_WCHAR,
/** Maximum type */
OMPI_OP_BASE_TYPE_MAX
};
/**
* Fortran handles; must be [manually set to be] equivalent to the
* values in mpif.h.
*/
enum {
/** Corresponds to Fortran MPI_OP_NULL */
OMPI_OP_BASE_FORTRAN_NULL = 0,
/** Corresponds to Fortran MPI_MAX */
OMPI_OP_BASE_FORTRAN_MAX,
/** Corresponds to Fortran MPI_MIN */
OMPI_OP_BASE_FORTRAN_MIN,
/** Corresponds to Fortran MPI_SUM */
OMPI_OP_BASE_FORTRAN_SUM,
/** Corresponds to Fortran MPI_PROD */
OMPI_OP_BASE_FORTRAN_PROD,
/** Corresponds to Fortran MPI_LAND */
OMPI_OP_BASE_FORTRAN_LAND,
/** Corresponds to Fortran MPI_BAND */
OMPI_OP_BASE_FORTRAN_BAND,
/** Corresponds to Fortran MPI_LOR */
OMPI_OP_BASE_FORTRAN_LOR,
/** Corresponds to Fortran MPI_BOR */
OMPI_OP_BASE_FORTRAN_BOR,
/** Corresponds to Fortran MPI_LXOR */
OMPI_OP_BASE_FORTRAN_LXOR,
/** Corresponds to Fortran MPI_BXOR */
OMPI_OP_BASE_FORTRAN_BXOR,
/** Corresponds to Fortran MPI_MAXLOC */
OMPI_OP_BASE_FORTRAN_MAXLOC,
/** Corresponds to Fortran MPI_MINLOC */
OMPI_OP_BASE_FORTRAN_MINLOC,
/** Corresponds to Fortran MPI_REPLACE */
OMPI_OP_BASE_FORTRAN_REPLACE,
/** Maximum value */
OMPI_OP_BASE_FORTRAN_OP_MAX
};
/**
* Pre-declare this so that we can pass it as an argument to the
* typedef'ed functions.
*/
struct ompi_op_base_module_1_0_0_t;
typedef struct ompi_op_base_module_1_0_0_t ompi_op_base_module_t;
/**
* Typedef for 2-buffer op functions.
*
* We don't use MPI_User_function because this would create a
* confusing dependency loop between this file and mpi.h. So this is
* repeated code, but it's better this way (and this typedef will
* never change, so there's not much of a maintenance worry).
*/
typedef void (*ompi_op_base_handler_fn_1_0_0_t)(void *, void *, int *,
struct ompi_datatype_t **,
struct ompi_op_base_module_1_0_0_t *);
typedef ompi_op_base_handler_fn_1_0_0_t ompi_op_base_handler_fn_t;
/*
* Typedef for 3-buffer (two input and one output) op functions.
*/
typedef void (*ompi_op_base_3buff_handler_fn_1_0_0_t)(void *,
void *,
void *, int *,
Two major things in this commit: * New "op" MPI layer framework * Addition of the MPI_REDUCE_LOCAL proposed function (for MPI-2.2) = Op framework = Add new "op" framework in the ompi layer. This framework replaces the hard-coded MPI_Op back-end functions for (MPI_Op, MPI_Datatype) tuples for pre-defined MPI_Ops, allowing components and modules to provide the back-end functions. The intent is that components can be written to take advantage of hardware acceleration (GPU, FPGA, specialized CPU instructions, etc.). Similar to other frameworks, components are intended to be able to discover at run-time if they can be used, and if so, elect themselves to be selected (or disqualify themselves from selection if they cannot run). If specialized hardware is not available, there is a default set of functions that will automatically be used. This framework is ''not'' used for user-defined MPI_Ops. The new op framework is similar to the existing coll framework, in that the final set of function pointers that are used on any given intrinsic MPI_Op can be a mixed bag of function pointers, potentially coming from multiple different op modules. This allows for hardware that only supports some of the operations, not all of them (e.g., a GPU that only supports single-precision operations). All the hard-coded back-end MPI_Op functions for (MPI_Op, MPI_Datatype) tuples still exist, but unlike coll, they're in the framework base (vs. being in a separate "basic" component) and are automatically used if no component is found at runtime that provides a module with the necessary function pointers. There is an "example" op component that will hopefully be useful to those writing meaningful op components. It is currently .ompi_ignore'd so that it doesn't impinge on other developers (it's somewhat chatty in terms of opal_output() so that you can tell when its functions have been invoked). See the README file in the example op component directory. Developers of new op components are encouraged to look at the following wiki pages: https://svn.open-mpi.org/trac/ompi/wiki/devel/Autogen https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateComponent https://svn.open-mpi.org/trac/ompi/wiki/devel/CreateFramework = MPI_REDUCE_LOCAL = Part of the MPI-2.2 proposal listed here: https://svn.mpi-forum.org/trac/mpi-forum-web/ticket/24 is to add a new function named MPI_REDUCE_LOCAL. It is very easy to implement, so I added it (also because it makes testing the op framework pretty easy -- you can do it in serial rather than via parallel reductions). There's even a man page! This commit was SVN r20280.
2009-01-15 02:44:31 +03:00
struct ompi_datatype_t **,
struct ompi_op_base_module_1_0_0_t *);
typedef ompi_op_base_3buff_handler_fn_1_0_0_t ompi_op_base_3buff_handler_fn_t;
/**
* Op component initialization
*
* Initialize the given op component. This function should initialize
* any component-level. data. It will be called exactly once during
* MPI_INIT.
*
* @note The component framework is not lazily opened, so attempts
* should be made to minimze the amount of memory allocated during
* this function.
*
* @param[in] enable_progress_threads True if the component needs to
* support progress threads
* @param[in] enable_mpi_threads True if the component needs to
* support MPI_THREAD_MULTIPLE
*
* @retval OMPI_SUCCESS Component successfully initialized
* @retval OMPI_ERROR An unspecified error occurred
*/
typedef int (*ompi_op_base_component_init_query_fn_t)
(bool enable_progress_threads, bool enable_mpi_threads);
/**
* Query whether a component is available for a specific MPI_Op.
*
* If the component is available, an object should be allocated and
* returned (with refcount at 1). The module will not be used for
* reduction operations until module_enable() is called on the module,
* but may be destroyed (via OBJ_RELEASE) either before or after
* module_enable() is called. If the module needs to release
* resources obtained during query(), it should do so in the module
* destructor.
*
* A component may provide NULL to this function to indicate it does
* not wish to run or return an error during module_enable().
*
* @param[in] op The MPI_Op being created
* @param[out] priority Priority setting for component on
* this op
*
* @returns An initialized module structure if the component can
* provide a module with the requested functionality or NULL if the
* component should not be used on the given communicator.
*/
typedef struct ompi_op_base_module_1_0_0_t *
(*ompi_op_base_component_op_query_1_0_0_fn_t)
(struct ompi_op_t *op, int *priority);
/**
* Op component interface.
*
* Component interface for the op framework. A public instance of
* this structure, called mca_op_[component_name]_component, must
* exist in any op component.
*/
typedef struct ompi_op_base_component_1_0_0_t {
/** Base component description */
mca_base_component_t opc_version;
/** Base component data block */
mca_base_component_data_t opc_data;
/** Component initialization function */
ompi_op_base_component_init_query_fn_t opc_init_query;
/** Query whether component is useable for given op */
ompi_op_base_component_op_query_1_0_0_fn_t opc_op_query;
} ompi_op_base_component_1_0_0_t;
/** Per guidence in mca.h, use the unversioned struct name if you just
want to always keep up with the most recent version of the
interace. */
typedef struct ompi_op_base_component_1_0_0_t ompi_op_base_component_t;
/**
* Module initialization function. Should return OPAL_SUCCESS if
* everything goes ok. This function can be NULL in the module struct
* if the module doesn't need to do anything between the component
* query function and being invoked for MPI_Op operations.
*/
typedef int (*ompi_op_base_module_enable_1_0_0_fn_t)
(struct ompi_op_base_module_1_0_0_t *module,
struct ompi_op_t *op);
/**
* Module struct
*/
typedef struct ompi_op_base_module_1_0_0_t {
/** Op modules all inherit from opal_object */
opal_object_t super;
/** Enable function called when an op module is (possibly) going
to be used for the given MPI_Op */
ompi_op_base_module_enable_1_0_0_fn_t opm_enable;
/** Just for reference -- a pointer to the MPI_Op that this module
is being used for */
struct ompi_op_t *opm_op;
/** Function pointers for all the different datatypes to be used
with the MPI_Op that this module is used with */
ompi_op_base_handler_fn_1_0_0_t opm_fns[OMPI_OP_BASE_TYPE_MAX];
ompi_op_base_3buff_handler_fn_1_0_0_t opm_3buff_fns[OMPI_OP_BASE_TYPE_MAX];
} ompi_op_base_module_1_0_0_t;
/**
* Declare the module as a class, unversioned
*/
OMPI_DECLSPEC OBJ_CLASS_DECLARATION(ompi_op_base_module_t);
/**
* Declare the module as a class, unversioned
*/
OMPI_DECLSPEC OBJ_CLASS_DECLARATION(ompi_op_base_module_1_0_0_t);
/**
* Struct that is used in op.h to hold all the function pointers and
* pointers to the corresopnding modules (so that we can properly
* RETAIN/RELEASE them)
*/
typedef struct ompi_op_base_op_fns_1_0_0_t {
ompi_op_base_handler_fn_1_0_0_t fns[OMPI_OP_BASE_TYPE_MAX];
ompi_op_base_module_t *modules[OMPI_OP_BASE_TYPE_MAX];
} ompi_op_base_op_fns_1_0_0_t;
typedef ompi_op_base_op_fns_1_0_0_t ompi_op_base_op_fns_t;
/**
* Struct that is used in op.h to hold all the function pointers and
* pointers to the corresopnding modules (so that we can properly
* RETAIN/RELEASE them)
*/
typedef struct ompi_op_base_op_3buff_fns_1_0_0_t {
ompi_op_base_3buff_handler_fn_1_0_0_t fns[OMPI_OP_BASE_TYPE_MAX];
ompi_op_base_module_t *modules[OMPI_OP_BASE_TYPE_MAX];
} ompi_op_base_op_3buff_fns_1_0_0_t;
typedef ompi_op_base_op_3buff_fns_1_0_0_t ompi_op_base_op_3buff_fns_t;
/*
* Macro for use in modules that are of type op v2.0.0
*/
#define OMPI_OP_BASE_VERSION_1_0_0 \
MCA_BASE_VERSION_2_0_0, \
"op", 1, 0, 0
END_C_DECLS
#endif /* OMPI_MCA_OP_H */