ports/openmpi
ports/openmpi
1
1
Форкнуть 0
Код Релизы Активность
openmpi/ompi/mca/op/base/op_base_functions.c
George Bosilca 5390fd6f33 Reshape the datatype engine. The basic types are built down in OPAL. MPI types are 
either direct link to these basic predefined types, or a combination of them.
Anyway, the first items in the datatype list belong to OPAL, the second round
are MPI datatypes created by composing basic OPAL datatypes, and the last
batch are mapped datatype (direct correspondance between an OMPI datatype and
an OPAL one such as int -> int32_t).

Modify the op to fit this new scheme.

This commit was SVN r24247.
2011-01-13 06:08:54 +00:00

1977 строки
71 KiB
C
Исходник Ответственный История

/*
* Copyright (c) 2004-2006 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2010 The University of Tennessee and The University
* of Tennessee Research Foundation. All rights
* reserved.
* Copyright (c) 2004-2007 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) 2006-2009 Cisco Systems, Inc. All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#include "ompi_config.h"
#ifdef HAVE_SYS_TYPES_H
#include <sys/types.h>
#endif
#include "ompi/mca/op/op.h"
#include "ompi/mca/op/base/functions.h"
/*
* Since all the functions in this file are essentially identical, we
* use a macro to substitute in names and types. The core operation
* in all functions that use this macro is the same.
*
* This macro is for (out op in).
*/
#define OP_FUNC(name, type_name, type, op) \
void ompi_op_base_##name##_##type_name(void *in, void *out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module) \
{ \
int i; \
type *a = (type *) in; \
type *b = (type *) out; \
for (i = 0; i < *count; ++i) { \
*(b++) op *(a++); \
} \
}
#define COMPLEX_OP_FUNC_SUM(type_name, type) \
void ompi_op_base_sum_##type_name(void *in, void *out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module)\
{ \
int i; \
type *a = (type *) in; \
type *b = (type *) out; \
for (i = 0; i < *count; ++i, ++b, ++a) { \
b->real += a->real; \
b->imag += a->imag; \
} \
}
#define COMPLEX_OP_FUNC_PROD(type_name, type) \
void ompi_op_base_prod_##type_name(void *in, void *out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module)\
{ \
int i; \
type *a = (type *) in; \
type *b = (type *) out; \
type temp; \
for (i = 0; i < *count; ++i, ++b, ++a) { \
temp.real = a->real * b->real - a->imag * b->imag; \
temp.imag = a->imag * b->real + a->real * b->imag; \
*b = temp; \
} \
}
/*
* Since all the functions in this file are essentially identical, we
* use a macro to substitute in names and types. The core operation
* in all functions that use this macro is the same.
*
* This macro is for (out = op(out, in))
*/
#define FUNC_FUNC(name, type_name, type) \
void ompi_op_base_##name##_##type_name(void *in, void *out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module)\
{ \
int i; \
type *a = (type *) in; \
type *b = (type *) out; \
for (i = 0; i < *count; ++i) { \
*(b) = current_func(*(b), *(a)); \
++b; \
++a; \
} \
}
/*
* Since all the functions in this file are essentially identical, we
* use a macro to substitute in names and types. The core operation
* in all functions that use this macro is the same.
*
* This macro is for minloc and maxloc
*/
#define LOC_STRUCT(type_name, type1, type2) \
typedef struct { \
type1 v; \
type2 k; \
} ompi_op_predefined_##type_name##_t;
#define LOC_FUNC(name, type_name, op) \
void ompi_op_base_##name##_##type_name(void *in, void *out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module)\
{ \
int i; \
ompi_op_predefined_##type_name##_t *a = (ompi_op_predefined_##type_name##_t*) in; \
ompi_op_predefined_##type_name##_t *b = (ompi_op_predefined_##type_name##_t*) out; \
for (i = 0; i < *count; ++i, ++a, ++b) { \
if (a->v op b->v) { \
b->v = a->v; \
b->k = a->k; \
} else if (a->v == b->v) { \
b->k = (b->k < a->k ? b->k : a->k); \
} \
} \
}
/*************************************************************************
* Max
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) > (b) ? (a) : (b))
/* C integer */
FUNC_FUNC(max, int8_t, int8_t)
FUNC_FUNC(max, uint8_t, uint8_t)
FUNC_FUNC(max, int16_t, int16_t)
FUNC_FUNC(max, uint16_t, uint16_t)
FUNC_FUNC(max, int32_t, int32_t)
FUNC_FUNC(max, uint32_t, uint32_t)
FUNC_FUNC(max, int64_t, int64_t)
FUNC_FUNC(max, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC(max, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC(max, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC(max, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC(max, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC(max, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC(max, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Floating point */
FUNC_FUNC(max, float, float)
FUNC_FUNC(max, double, double)
#if HAVE_LONG_DOUBLE
FUNC_FUNC(max, long_double, long double)
#endif
#if OMPI_HAVE_FORTRAN_REAL
FUNC_FUNC(max, fortran_real, ompi_fortran_real_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
FUNC_FUNC(max, fortran_double_precision, ompi_fortran_double_precision_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
FUNC_FUNC(max, fortran_real2, ompi_fortran_real2_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
FUNC_FUNC(max, fortran_real4, ompi_fortran_real4_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
FUNC_FUNC(max, fortran_real8, ompi_fortran_real8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
FUNC_FUNC(max, fortran_real16, ompi_fortran_real16_t)
#endif
/*************************************************************************
* Min
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) < (b) ? (a) : (b))
/* C integer */
FUNC_FUNC(min, int8_t, int8_t)
FUNC_FUNC(min, uint8_t, uint8_t)
FUNC_FUNC(min, int16_t, int16_t)
FUNC_FUNC(min, uint16_t, uint16_t)
FUNC_FUNC(min, int32_t, int32_t)
FUNC_FUNC(min, uint32_t, uint32_t)
FUNC_FUNC(min, int64_t, int64_t)
FUNC_FUNC(min, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC(min, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC(min, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC(min, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC(min, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC(min, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC(min, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Floating point */
FUNC_FUNC(min, float, float)
FUNC_FUNC(min, double, double)
#if HAVE_LONG_DOUBLE
FUNC_FUNC(min, long_double, long double)
#endif
#if OMPI_HAVE_FORTRAN_REAL
FUNC_FUNC(min, fortran_real, ompi_fortran_real_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
FUNC_FUNC(min, fortran_double_precision, ompi_fortran_double_precision_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
FUNC_FUNC(min, fortran_real2, ompi_fortran_real2_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
FUNC_FUNC(min, fortran_real4, ompi_fortran_real4_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
FUNC_FUNC(min, fortran_real8, ompi_fortran_real8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
FUNC_FUNC(min, fortran_real16, ompi_fortran_real16_t)
#endif
/*************************************************************************
* Sum
*************************************************************************/
/* C integer */
OP_FUNC(sum, int8_t, int8_t, +=)
OP_FUNC(sum, uint8_t, uint8_t, +=)
OP_FUNC(sum, int16_t, int16_t, +=)
OP_FUNC(sum, uint16_t, uint16_t, +=)
OP_FUNC(sum, int32_t, int32_t, +=)
OP_FUNC(sum, uint32_t, uint32_t, +=)
OP_FUNC(sum, int64_t, int64_t, +=)
OP_FUNC(sum, uint64_t, uint64_t, +=)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
OP_FUNC(sum, fortran_integer, ompi_fortran_integer_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
OP_FUNC(sum, fortran_integer1, ompi_fortran_integer1_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
OP_FUNC(sum, fortran_integer2, ompi_fortran_integer2_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
OP_FUNC(sum, fortran_integer4, ompi_fortran_integer4_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
OP_FUNC(sum, fortran_integer8, ompi_fortran_integer8_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
OP_FUNC(sum, fortran_integer16, ompi_fortran_integer16_t, +=)
#endif
/* Floating point */
OP_FUNC(sum, float, float, +=)
OP_FUNC(sum, double, double, +=)
#if HAVE_LONG_DOUBLE
OP_FUNC(sum, long_double, long double, +=)
#endif
#if OMPI_HAVE_FORTRAN_REAL
OP_FUNC(sum, fortran_real, ompi_fortran_real_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
OP_FUNC(sum, fortran_double_precision, ompi_fortran_double_precision_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
OP_FUNC(sum, fortran_real2, ompi_fortran_real2_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
OP_FUNC(sum, fortran_real4, ompi_fortran_real4_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
OP_FUNC(sum, fortran_real8, ompi_fortran_real8_t, +=)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
OP_FUNC(sum, fortran_real16, ompi_fortran_real16_t, +=)
#endif
/* Complex */
#if OMPI_HAVE_FORTRAN_REAL && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_SUM(fortran_complex, ompi_fortran_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_SUM(fortran_double_complex, ompi_fortran_double_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4 && OMPI_HAVE_FORTRAN_COMPLEX8
COMPLEX_OP_FUNC_SUM(fortran_complex8, ompi_fortran_complex8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8 && OMPI_HAVE_FORTRAN_COMPLEX16
COMPLEX_OP_FUNC_SUM(fortran_complex16, ompi_fortran_complex16_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16 && OMPI_HAVE_FORTRAN_COMPLEX32
COMPLEX_OP_FUNC_SUM(fortran_complex32, ompi_fortran_complex32_t)
#endif
/*************************************************************************
* Product
*************************************************************************/
/* C integer */
OP_FUNC(prod, int8_t, int8_t, *=)
OP_FUNC(prod, uint8_t, uint8_t, *=)
OP_FUNC(prod, int16_t, int16_t, *=)
OP_FUNC(prod, uint16_t, uint16_t, *=)
OP_FUNC(prod, int32_t, int32_t, *=)
OP_FUNC(prod, uint32_t, uint32_t, *=)
OP_FUNC(prod, int64_t, int64_t, *=)
OP_FUNC(prod, uint64_t, uint64_t, *=)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
OP_FUNC(prod, fortran_integer, ompi_fortran_integer_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
OP_FUNC(prod, fortran_integer1, ompi_fortran_integer1_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
OP_FUNC(prod, fortran_integer2, ompi_fortran_integer2_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
OP_FUNC(prod, fortran_integer4, ompi_fortran_integer4_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
OP_FUNC(prod, fortran_integer8, ompi_fortran_integer8_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
OP_FUNC(prod, fortran_integer16, ompi_fortran_integer16_t, *=)
#endif
/* Floating point */
OP_FUNC(prod, float, float, *=)
OP_FUNC(prod, double, double, *=)
#if HAVE_LONG_DOUBLE
OP_FUNC(prod, long_double, long double, *=)
#endif
#if OMPI_HAVE_FORTRAN_REAL
OP_FUNC(prod, fortran_real, ompi_fortran_real_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
OP_FUNC(prod, fortran_double_precision, ompi_fortran_double_precision_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
OP_FUNC(prod, fortran_real2, ompi_fortran_real2_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
OP_FUNC(prod, fortran_real4, ompi_fortran_real4_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
OP_FUNC(prod, fortran_real8, ompi_fortran_real8_t, *=)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
OP_FUNC(prod, fortran_real16, ompi_fortran_real16_t, *=)
#endif
/* Complex */
#if OMPI_HAVE_FORTRAN_REAL && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_PROD(fortran_complex, ompi_fortran_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_PROD(fortran_double_complex, ompi_fortran_double_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4 && OMPI_HAVE_FORTRAN_COMPLEX8
COMPLEX_OP_FUNC_PROD(fortran_complex8, ompi_fortran_complex8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8 && OMPI_HAVE_FORTRAN_COMPLEX16
COMPLEX_OP_FUNC_PROD(fortran_complex16, ompi_fortran_complex16_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16 && OMPI_HAVE_FORTRAN_COMPLEX32
COMPLEX_OP_FUNC_PROD(fortran_complex32, ompi_fortran_complex32_t)
#endif
/*************************************************************************
* Logical AND
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) && (b))
/* C integer */
FUNC_FUNC(land, int8_t, int8_t)
FUNC_FUNC(land, uint8_t, uint8_t)
FUNC_FUNC(land, int16_t, int16_t)
FUNC_FUNC(land, uint16_t, uint16_t)
FUNC_FUNC(land, int32_t, int32_t)
FUNC_FUNC(land, uint32_t, uint32_t)
FUNC_FUNC(land, int64_t, int64_t)
FUNC_FUNC(land, uint64_t, uint64_t)
/* Logical */
#if OMPI_HAVE_FORTRAN_LOGICAL
FUNC_FUNC(land, fortran_logical, ompi_fortran_logical_t)
#endif
/* C++ bool */
FUNC_FUNC(land, bool, bool)
/*************************************************************************
* Logical OR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) || (b))
/* C integer */
FUNC_FUNC(lor, int8_t, int8_t)
FUNC_FUNC(lor, uint8_t, uint8_t)
FUNC_FUNC(lor, int16_t, int16_t)
FUNC_FUNC(lor, uint16_t, uint16_t)
FUNC_FUNC(lor, int32_t, int32_t)
FUNC_FUNC(lor, uint32_t, uint32_t)
FUNC_FUNC(lor, int64_t, int64_t)
FUNC_FUNC(lor, uint64_t, uint64_t)
/* Logical */
#if OMPI_HAVE_FORTRAN_LOGICAL
FUNC_FUNC(lor, fortran_logical, ompi_fortran_logical_t)
#endif
/* C++ bool */
FUNC_FUNC(lor, bool, bool)
/*************************************************************************
* Logical XOR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a ? 1 : 0) ^ (b ? 1: 0))
/* C integer */
FUNC_FUNC(lxor, int8_t, int8_t)
FUNC_FUNC(lxor, uint8_t, uint8_t)
FUNC_FUNC(lxor, int16_t, int16_t)
FUNC_FUNC(lxor, uint16_t, uint16_t)
FUNC_FUNC(lxor, int32_t, int32_t)
FUNC_FUNC(lxor, uint32_t, uint32_t)
FUNC_FUNC(lxor, int64_t, int64_t)
FUNC_FUNC(lxor, uint64_t, uint64_t)
/* Logical */
#if OMPI_HAVE_FORTRAN_LOGICAL
FUNC_FUNC(lxor, fortran_logical, ompi_fortran_logical_t)
#endif
/* C++ bool */
FUNC_FUNC(lxor, bool, bool)
/*************************************************************************
* Bitwise AND
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) & (b))
/* C integer */
FUNC_FUNC(band, int8_t, int8_t)
FUNC_FUNC(band, uint8_t, uint8_t)
FUNC_FUNC(band, int16_t, int16_t)
FUNC_FUNC(band, uint16_t, uint16_t)
FUNC_FUNC(band, int32_t, int32_t)
FUNC_FUNC(band, uint32_t, uint32_t)
FUNC_FUNC(band, int64_t, int64_t)
FUNC_FUNC(band, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC(band, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC(band, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC(band, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC(band, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC(band, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC(band, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Byte */
FUNC_FUNC(band, byte, char)
/*************************************************************************
* Bitwise OR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) | (b))
/* C integer */
FUNC_FUNC(bor, int8_t, int8_t)
FUNC_FUNC(bor, uint8_t, uint8_t)
FUNC_FUNC(bor, int16_t, int16_t)
FUNC_FUNC(bor, uint16_t, uint16_t)
FUNC_FUNC(bor, int32_t, int32_t)
FUNC_FUNC(bor, uint32_t, uint32_t)
FUNC_FUNC(bor, int64_t, int64_t)
FUNC_FUNC(bor, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC(bor, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC(bor, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC(bor, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC(bor, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC(bor, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC(bor, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Byte */
FUNC_FUNC(bor, byte, char)
/*************************************************************************
* Bitwise XOR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) ^ (b))
/* C integer */
FUNC_FUNC(bxor, int8_t, int8_t)
FUNC_FUNC(bxor, uint8_t, uint8_t)
FUNC_FUNC(bxor, int16_t, int16_t)
FUNC_FUNC(bxor, uint16_t, uint16_t)
FUNC_FUNC(bxor, int32_t, int32_t)
FUNC_FUNC(bxor, uint32_t, uint32_t)
FUNC_FUNC(bxor, int64_t, int64_t)
FUNC_FUNC(bxor, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC(bxor, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC(bxor, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC(bxor, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC(bxor, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC(bxor, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC(bxor, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Byte */
FUNC_FUNC(bxor, byte, char)
/*************************************************************************
* Min and max location "pair" datatypes
*************************************************************************/
#if OMPI_HAVE_FORTRAN_REAL
LOC_STRUCT(2real, ompi_fortran_real_t, ompi_fortran_real_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
LOC_STRUCT(2double_precision, ompi_fortran_double_precision_t, ompi_fortran_double_precision_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER
LOC_STRUCT(2integer, ompi_fortran_integer_t, ompi_fortran_integer_t)
#endif
LOC_STRUCT(float_int, float, int)
LOC_STRUCT(double_int, double, int)
LOC_STRUCT(long_int, long, int)
LOC_STRUCT(2int, int, int)
LOC_STRUCT(short_int, short, int)
#if HAVE_LONG_DOUBLE
LOC_STRUCT(long_double_int, long double, int)
#endif
/*************************************************************************
* Max location
*************************************************************************/
#if OMPI_HAVE_FORTRAN_REAL
LOC_FUNC(maxloc, 2real, >)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
LOC_FUNC(maxloc, 2double_precision, >)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER
LOC_FUNC(maxloc, 2integer, >)
#endif
LOC_FUNC(maxloc, float_int, >)
LOC_FUNC(maxloc, double_int, >)
LOC_FUNC(maxloc, long_int, >)
LOC_FUNC(maxloc, 2int, >)
LOC_FUNC(maxloc, short_int, >)
#if HAVE_LONG_DOUBLE
LOC_FUNC(maxloc, long_double_int, >)
#endif
/*************************************************************************
* Min location
*************************************************************************/
#if OMPI_HAVE_FORTRAN_REAL
LOC_FUNC(minloc, 2real, <)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
LOC_FUNC(minloc, 2double_precision, <)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER
LOC_FUNC(minloc, 2integer, <)
#endif
LOC_FUNC(minloc, float_int, <)
LOC_FUNC(minloc, double_int, <)
LOC_FUNC(minloc, long_int, <)
LOC_FUNC(minloc, 2int, <)
LOC_FUNC(minloc, short_int, <)
#if HAVE_LONG_DOUBLE
LOC_FUNC(minloc, long_double_int, <)
#endif
/*
* This is a three buffer (2 input and 1 output) version of the reduction
* routines, needed for some optimizations.
*/
#define OP_FUNC_3BUF(name, type_name, type, op) \
void ompi_op_base_3buff_##name##_##type_name(void * restrict in1, \
void * restrict in2, void * restrict out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module) \
{ \
int i; \
type *a1 = (type *) in1; \
type *a2 = (type *) in2; \
type *b = (type *) out; \
for (i = 0; i < *count; ++i) { \
*(b++) = *(a1++) op *(a2++); \
} \
}
#define COMPLEX_OP_FUNC_SUM_3BUF(type_name, type) \
void ompi_op_base_3buff_sum_##type_name(void * restrict in1, \
void * restrict in2, void * restrict out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module) \
{ \
int i; \
type *a1 = (type *) in1; \
type *a2 = (type *) in2; \
type *b = (type *) out; \
for (i = 0; i < *count; ++i, ++b, ++a1, ++a2) { \
b->real = a1->real + a2->real; \
b->imag = a1->imag + a2->imag; \
} \
}
#define COMPLEX_OP_FUNC_PROD_3BUF(type_name, type) \
void ompi_op_base_3buff_prod_##type_name(void * restrict in1, \
void * restrict in2, void * restrict out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module) \
{ \
int i; \
type *a1 = (type *) in1; \
type *a2 = (type *) in2; \
type *b = (type *) out; \
for (i = 0; i < *count; ++i, ++b, ++a1, ++a2) { \
b->real = a1->real * a2->real - a1->imag * a2->imag; \
b->imag = a1->imag * a2->real + a1->real * a2->imag; \
} \
}
/*
* Since all the functions in this file are essentially identical, we
* use a macro to substitute in names and types. The core operation
* in all functions that use this macro is the same.
*
* This macro is for (out = op(in1, in2))
*/
#define FUNC_FUNC_3BUF(name, type_name, type) \
void ompi_op_base_3buff_##name##_##type_name(void * restrict in1, \
void * restrict in2, void * restrict out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module) \
{ \
int i; \
type *a1 = (type *) in1; \
type *a2 = (type *) in2; \
type *b = (type *) out; \
for (i = 0; i < *count; ++i) { \
*(b) = current_func(*(a1), *(a2)); \
++b; \
++a1; \
++a2; \
} \
}
/*
* Since all the functions in this file are essentially identical, we
* use a macro to substitute in names and types. The core operation
* in all functions that use this macro is the same.
*
* This macro is for minloc and maxloc
*/
/*
#define LOC_STRUCT(type_name, type1, type2) \
typedef struct { \
type1 v; \
type2 k; \
} ompi_op_predefined_##type_name##_t;
*/
#define LOC_FUNC_3BUF(name, type_name, op) \
void ompi_op_base_3buff_##name##_##type_name(void * restrict in1, \
void * restrict in2, void * restrict out, int *count, \
struct ompi_datatype_t **dtype, \
struct ompi_op_base_module_1_0_0_t *module) \
{ \
int i; \
ompi_op_predefined_##type_name##_t *a1 = (ompi_op_predefined_##type_name##_t*) in1; \
ompi_op_predefined_##type_name##_t *a2 = (ompi_op_predefined_##type_name##_t*) in2; \
ompi_op_predefined_##type_name##_t *b = (ompi_op_predefined_##type_name##_t*) out; \
for (i = 0; i < *count; ++i, ++a1, ++a2, ++b ) { \
if (a1->v op a2->v) { \
b->v = a1->v; \
b->k = a1->k; \
} else if (a1->v == a2->v) { \
b->v = a1->v; \
b->k = (a2->k < a1->k ? a2->k : a1->k); \
} else { \
b->v = a2->v; \
b->k = a2->k; \
} \
} \
}
/*************************************************************************
* Max
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) > (b) ? (a) : (b))
/* C integer */
FUNC_FUNC_3BUF(max, int8_t, int8_t)
FUNC_FUNC_3BUF(max, uint8_t, uint8_t)
FUNC_FUNC_3BUF(max, int16_t, int16_t)
FUNC_FUNC_3BUF(max, uint16_t, uint16_t)
FUNC_FUNC_3BUF(max, int32_t, int32_t)
FUNC_FUNC_3BUF(max, uint32_t, uint32_t)
FUNC_FUNC_3BUF(max, int64_t, int64_t)
FUNC_FUNC_3BUF(max, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC_3BUF(max, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC_3BUF(max, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC_3BUF(max, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC_3BUF(max, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC_3BUF(max, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC_3BUF(max, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Floating point */
FUNC_FUNC_3BUF(max, float, float)
FUNC_FUNC_3BUF(max, double, double)
#if HAVE_LONG_DOUBLE
FUNC_FUNC_3BUF(max, long_double, long double)
#endif
#if OMPI_HAVE_FORTRAN_REAL
FUNC_FUNC_3BUF(max, fortran_real, ompi_fortran_real_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
FUNC_FUNC_3BUF(max, fortran_double_precision, ompi_fortran_double_precision_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
FUNC_FUNC_3BUF(max, fortran_real2, ompi_fortran_real2_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
FUNC_FUNC_3BUF(max, fortran_real4, ompi_fortran_real4_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
FUNC_FUNC_3BUF(max, fortran_real8, ompi_fortran_real8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
FUNC_FUNC_3BUF(max, fortran_real16, ompi_fortran_real16_t)
#endif
/*************************************************************************
* Min
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) < (b) ? (a) : (b))
/* C integer */
FUNC_FUNC_3BUF(min, int8_t, int8_t)
FUNC_FUNC_3BUF(min, uint8_t, uint8_t)
FUNC_FUNC_3BUF(min, int16_t, int16_t)
FUNC_FUNC_3BUF(min, uint16_t, uint16_t)
FUNC_FUNC_3BUF(min, int32_t, int32_t)
FUNC_FUNC_3BUF(min, uint32_t, uint32_t)
FUNC_FUNC_3BUF(min, int64_t, int64_t)
FUNC_FUNC_3BUF(min, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC_3BUF(min, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC_3BUF(min, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC_3BUF(min, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC_3BUF(min, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC_3BUF(min, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC_3BUF(min, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Floating point */
FUNC_FUNC_3BUF(min, float, float)
FUNC_FUNC_3BUF(min, double, double)
#if HAVE_LONG_DOUBLE
FUNC_FUNC_3BUF(min, long_double, long double)
#endif
#if OMPI_HAVE_FORTRAN_REAL
FUNC_FUNC_3BUF(min, fortran_real, ompi_fortran_real_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
FUNC_FUNC_3BUF(min, fortran_double_precision, ompi_fortran_double_precision_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
FUNC_FUNC_3BUF(min, fortran_real2, ompi_fortran_real2_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
FUNC_FUNC_3BUF(min, fortran_real4, ompi_fortran_real4_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
FUNC_FUNC_3BUF(min, fortran_real8, ompi_fortran_real8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
FUNC_FUNC_3BUF(min, fortran_real16, ompi_fortran_real16_t)
#endif
/*************************************************************************
* Sum
*************************************************************************/
/* C integer */
OP_FUNC_3BUF(sum, int8_t, int8_t, +=)
OP_FUNC_3BUF(sum, uint8_t, uint8_t, +=)
OP_FUNC_3BUF(sum, int16_t, int16_t, +=)
OP_FUNC_3BUF(sum, uint16_t, uint16_t, +=)
OP_FUNC_3BUF(sum, int32_t, int32_t, +=)
OP_FUNC_3BUF(sum, uint32_t, uint32_t, +=)
OP_FUNC_3BUF(sum, int64_t, int64_t, +=)
OP_FUNC_3BUF(sum, uint64_t, uint64_t, +=)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
OP_FUNC_3BUF(sum, fortran_integer, ompi_fortran_integer_t, +)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
OP_FUNC_3BUF(sum, fortran_integer1, ompi_fortran_integer1_t, +)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
OP_FUNC_3BUF(sum, fortran_integer2, ompi_fortran_integer2_t, +)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
OP_FUNC_3BUF(sum, fortran_integer4, ompi_fortran_integer4_t, +)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
OP_FUNC_3BUF(sum, fortran_integer8, ompi_fortran_integer8_t, +)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
OP_FUNC_3BUF(sum, fortran_integer16, ompi_fortran_integer16_t, +)
#endif
/* Floating point */
OP_FUNC_3BUF(sum, float, float, +)
OP_FUNC_3BUF(sum, double, double, +)
#if HAVE_LONG_DOUBLE
OP_FUNC_3BUF(sum, long_double, long double, +)
#endif
#if OMPI_HAVE_FORTRAN_REAL
OP_FUNC_3BUF(sum, fortran_real, ompi_fortran_real_t, +)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
OP_FUNC_3BUF(sum, fortran_double_precision, ompi_fortran_double_precision_t, +)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
OP_FUNC_3BUF(sum, fortran_real2, ompi_fortran_real2_t, +)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
OP_FUNC_3BUF(sum, fortran_real4, ompi_fortran_real4_t, +)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
OP_FUNC_3BUF(sum, fortran_real8, ompi_fortran_real8_t, +)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
OP_FUNC_3BUF(sum, fortran_real16, ompi_fortran_real16_t, +)
#endif
/* Complex */
#if OMPI_HAVE_FORTRAN_REAL && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_SUM_3BUF(fortran_complex, ompi_fortran_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_SUM_3BUF(fortran_double_complex, ompi_fortran_double_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4 && OMPI_HAVE_FORTRAN_COMPLEX8
COMPLEX_OP_FUNC_SUM_3BUF(fortran_complex8, ompi_fortran_complex8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8 && OMPI_HAVE_FORTRAN_COMPLEX16
COMPLEX_OP_FUNC_SUM_3BUF(fortran_complex16, ompi_fortran_complex16_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16 && OMPI_HAVE_FORTRAN_COMPLEX32
COMPLEX_OP_FUNC_SUM_3BUF(fortran_complex32, ompi_fortran_complex32_t)
#endif
/*************************************************************************
* Product
*************************************************************************/
/* C integer */
OP_FUNC_3BUF(prod, int8_t, int8_t, *=)
OP_FUNC_3BUF(prod, uint8_t, uint8_t, *=)
OP_FUNC_3BUF(prod, int16_t, int16_t, *=)
OP_FUNC_3BUF(prod, uint16_t, uint16_t, *=)
OP_FUNC_3BUF(prod, int32_t, int32_t, *=)
OP_FUNC_3BUF(prod, uint32_t, uint32_t, *=)
OP_FUNC_3BUF(prod, int64_t, int64_t, *=)
OP_FUNC_3BUF(prod, uint64_t, uint64_t, *=)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
OP_FUNC_3BUF(prod, fortran_integer, ompi_fortran_integer_t, *)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
OP_FUNC_3BUF(prod, fortran_integer1, ompi_fortran_integer1_t, *)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
OP_FUNC_3BUF(prod, fortran_integer2, ompi_fortran_integer2_t, *)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
OP_FUNC_3BUF(prod, fortran_integer4, ompi_fortran_integer4_t, *)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
OP_FUNC_3BUF(prod, fortran_integer8, ompi_fortran_integer8_t, *)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
OP_FUNC_3BUF(prod, fortran_integer16, ompi_fortran_integer16_t, *)
#endif
/* Floating point */
OP_FUNC_3BUF(prod, float, float, *)
OP_FUNC_3BUF(prod, double, double, *)
#if HAVE_LONG_DOUBLE
OP_FUNC_3BUF(prod, long_double, long double, *)
#endif
#if OMPI_HAVE_FORTRAN_REAL
OP_FUNC_3BUF(prod, fortran_real, ompi_fortran_real_t, *)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
OP_FUNC_3BUF(prod, fortran_double_precision, ompi_fortran_double_precision_t, *)
#endif
#if OMPI_HAVE_FORTRAN_REAL2
OP_FUNC_3BUF(prod, fortran_real2, ompi_fortran_real2_t, *)
#endif
#if OMPI_HAVE_FORTRAN_REAL4
OP_FUNC_3BUF(prod, fortran_real4, ompi_fortran_real4_t, *)
#endif
#if OMPI_HAVE_FORTRAN_REAL8
OP_FUNC_3BUF(prod, fortran_real8, ompi_fortran_real8_t, *)
#endif
#if OMPI_HAVE_FORTRAN_REAL16
OP_FUNC_3BUF(prod, fortran_real16, ompi_fortran_real16_t, *)
#endif
/* Complex */
#if OMPI_HAVE_FORTRAN_REAL && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_PROD_3BUF(fortran_complex, ompi_fortran_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION && OMPI_HAVE_FORTRAN_COMPLEX
COMPLEX_OP_FUNC_PROD_3BUF(fortran_double_complex, ompi_fortran_double_complex_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL4 && OMPI_HAVE_FORTRAN_COMPLEX8
COMPLEX_OP_FUNC_PROD_3BUF(fortran_complex8, ompi_fortran_complex8_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL8 && OMPI_HAVE_FORTRAN_COMPLEX16
COMPLEX_OP_FUNC_PROD_3BUF(fortran_complex16, ompi_fortran_complex16_t)
#endif
#if OMPI_HAVE_FORTRAN_REAL16 && OMPI_HAVE_FORTRAN_COMPLEX32
COMPLEX_OP_FUNC_PROD_3BUF(fortran_complex32, ompi_fortran_complex32_t)
#endif
/*************************************************************************
* Logical AND
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) && (b))
/* C integer */
FUNC_FUNC_3BUF(land, int8_t, int8_t)
FUNC_FUNC_3BUF(land, uint8_t, uint8_t)
FUNC_FUNC_3BUF(land, int16_t, int16_t)
FUNC_FUNC_3BUF(land, uint16_t, uint16_t)
FUNC_FUNC_3BUF(land, int32_t, int32_t)
FUNC_FUNC_3BUF(land, uint32_t, uint32_t)
FUNC_FUNC_3BUF(land, int64_t, int64_t)
FUNC_FUNC_3BUF(land, uint64_t, uint64_t)
/* Logical */
#if OMPI_HAVE_FORTRAN_LOGICAL
FUNC_FUNC_3BUF(land, fortran_logical, ompi_fortran_logical_t)
#endif
/* C++ bool */
FUNC_FUNC_3BUF(land, bool, bool)
/*************************************************************************
* Logical OR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) || (b))
/* C integer */
FUNC_FUNC_3BUF(lor, int8_t, int8_t)
FUNC_FUNC_3BUF(lor, uint8_t, uint8_t)
FUNC_FUNC_3BUF(lor, int16_t, int16_t)
FUNC_FUNC_3BUF(lor, uint16_t, uint16_t)
FUNC_FUNC_3BUF(lor, int32_t, int32_t)
FUNC_FUNC_3BUF(lor, uint32_t, uint32_t)
FUNC_FUNC_3BUF(lor, int64_t, int64_t)
FUNC_FUNC_3BUF(lor, uint64_t, uint64_t)
/* Logical */
#if OMPI_HAVE_FORTRAN_LOGICAL
FUNC_FUNC_3BUF(lor, fortran_logical, ompi_fortran_logical_t)
#endif
/* C++ bool */
FUNC_FUNC_3BUF(lor, bool, bool)
/*************************************************************************
* Logical XOR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a ? 1 : 0) ^ (b ? 1: 0))
/* C integer */
FUNC_FUNC_3BUF(lxor, int8_t, int8_t)
FUNC_FUNC_3BUF(lxor, uint8_t, uint8_t)
FUNC_FUNC_3BUF(lxor, int16_t, int16_t)
FUNC_FUNC_3BUF(lxor, uint16_t, uint16_t)
FUNC_FUNC_3BUF(lxor, int32_t, int32_t)
FUNC_FUNC_3BUF(lxor, uint32_t, uint32_t)
FUNC_FUNC_3BUF(lxor, int64_t, int64_t)
FUNC_FUNC_3BUF(lxor, uint64_t, uint64_t)
/* Logical */
#if OMPI_HAVE_FORTRAN_LOGICAL
FUNC_FUNC_3BUF(lxor, fortran_logical, ompi_fortran_logical_t)
#endif
/* C++ bool */
FUNC_FUNC_3BUF(lxor, bool, bool)
/*************************************************************************
* Bitwise AND
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) & (b))
/* C integer */
FUNC_FUNC_3BUF(band, int8_t, int8_t)
FUNC_FUNC_3BUF(band, uint8_t, uint8_t)
FUNC_FUNC_3BUF(band, int16_t, int16_t)
FUNC_FUNC_3BUF(band, uint16_t, uint16_t)
FUNC_FUNC_3BUF(band, int32_t, int32_t)
FUNC_FUNC_3BUF(band, uint32_t, uint32_t)
FUNC_FUNC_3BUF(band, int64_t, int64_t)
FUNC_FUNC_3BUF(band, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC_3BUF(band, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC_3BUF(band, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC_3BUF(band, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC_3BUF(band, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC_3BUF(band, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC_3BUF(band, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Byte */
FUNC_FUNC_3BUF(band, byte, char)
/*************************************************************************
* Bitwise OR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) | (b))
/* C integer */
FUNC_FUNC_3BUF(bor, int8_t, int8_t)
FUNC_FUNC_3BUF(bor, uint8_t, uint8_t)
FUNC_FUNC_3BUF(bor, int16_t, int16_t)
FUNC_FUNC_3BUF(bor, uint16_t, uint16_t)
FUNC_FUNC_3BUF(bor, int32_t, int32_t)
FUNC_FUNC_3BUF(bor, uint32_t, uint32_t)
FUNC_FUNC_3BUF(bor, int64_t, int64_t)
FUNC_FUNC_3BUF(bor, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC_3BUF(bor, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC_3BUF(bor, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC_3BUF(bor, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC_3BUF(bor, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC_3BUF(bor, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC_3BUF(bor, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Byte */
FUNC_FUNC_3BUF(bor, byte, char)
/*************************************************************************
* Bitwise XOR
*************************************************************************/
#undef current_func
#define current_func(a, b) ((a) ^ (b))
/* C integer */
FUNC_FUNC_3BUF(bxor, int8_t, int8_t)
FUNC_FUNC_3BUF(bxor, uint8_t, uint8_t)
FUNC_FUNC_3BUF(bxor, int16_t, int16_t)
FUNC_FUNC_3BUF(bxor, uint16_t, uint16_t)
FUNC_FUNC_3BUF(bxor, int32_t, int32_t)
FUNC_FUNC_3BUF(bxor, uint32_t, uint32_t)
FUNC_FUNC_3BUF(bxor, int64_t, int64_t)
FUNC_FUNC_3BUF(bxor, uint64_t, uint64_t)
/* Fortran integer */
#if OMPI_HAVE_FORTRAN_INTEGER
FUNC_FUNC_3BUF(bxor, fortran_integer, ompi_fortran_integer_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
FUNC_FUNC_3BUF(bxor, fortran_integer1, ompi_fortran_integer1_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
FUNC_FUNC_3BUF(bxor, fortran_integer2, ompi_fortran_integer2_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
FUNC_FUNC_3BUF(bxor, fortran_integer4, ompi_fortran_integer4_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
FUNC_FUNC_3BUF(bxor, fortran_integer8, ompi_fortran_integer8_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
FUNC_FUNC_3BUF(bxor, fortran_integer16, ompi_fortran_integer16_t)
#endif
/* Byte */
FUNC_FUNC_3BUF(bxor, byte, char)
/*************************************************************************
* Min and max location "pair" datatypes
*************************************************************************/
/*
#if OMPI_HAVE_FORTRAN_REAL
LOC_STRUCT_3BUF(2real, ompi_fortran_real_t, ompi_fortran_real_t)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
LOC_STRUCT_3BUF(2double_precision, ompi_fortran_double_precision_t, ompi_fortran_double_precision_t)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER
LOC_STRUCT_3BUF(2integer, ompi_fortran_integer_t, ompi_fortran_integer_t)
#endif
LOC_STRUCT_3BUF(float_int, float, int)
LOC_STRUCT_3BUF(double_int, double, int)
LOC_STRUCT_3BUF(long_int, long, int)
LOC_STRUCT_3BUF(2int, int, int)
LOC_STRUCT_3BUF(short_int, short, int)
#if HAVE_LONG_DOUBLE
LOC_STRUCT_3BUF(long_double_int, long double, int)
#endif
*/
/*************************************************************************
* Max location
*************************************************************************/
#if OMPI_HAVE_FORTRAN_REAL
LOC_FUNC_3BUF(maxloc, 2real, >)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
LOC_FUNC_3BUF(maxloc, 2double_precision, >)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER
LOC_FUNC_3BUF(maxloc, 2integer, >)
#endif
LOC_FUNC_3BUF(maxloc, float_int, >)
LOC_FUNC_3BUF(maxloc, double_int, >)
LOC_FUNC_3BUF(maxloc, long_int, >)
LOC_FUNC_3BUF(maxloc, 2int, >)
LOC_FUNC_3BUF(maxloc, short_int, >)
#if HAVE_LONG_DOUBLE
LOC_FUNC_3BUF(maxloc, long_double_int, >)
#endif
/*************************************************************************
* Min location
*************************************************************************/
#if OMPI_HAVE_FORTRAN_REAL
LOC_FUNC_3BUF(minloc, 2real, <)
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
LOC_FUNC_3BUF(minloc, 2double_precision, <)
#endif
#if OMPI_HAVE_FORTRAN_INTEGER
LOC_FUNC_3BUF(minloc, 2integer, <)
#endif
LOC_FUNC_3BUF(minloc, float_int, <)
LOC_FUNC_3BUF(minloc, double_int, <)
LOC_FUNC_3BUF(minloc, long_int, <)
LOC_FUNC_3BUF(minloc, 2int, <)
LOC_FUNC_3BUF(minloc, short_int, <)
#if HAVE_LONG_DOUBLE
LOC_FUNC_3BUF(minloc, long_double_int, <)
#endif
/*
* Helpful defines, because there's soooo many names!
*
* **NOTE** These #define's are strictly ordered! A series of macros
* are built up to assemble a list of function names (or NULLs) that
* are put into the intrinsict ompi_op_t's in the middle of this file.
* The order of these function names is critical, and must be the same
* as the OMPI_OP_BASE_TYPE_* enums in ompi/mca/op/op.h (i.e., the
* enum's starting with OMPI_OP_BASE_TYPE_UNSIGNED_CHAR).
*/
/** C integer ***********************************************************/
#define C_INTEGER_NULL \
NULL, /* OMPI_OP_BASE_TYPE_UNSIGNED_CHAR */ \
NULL, /* OMPI_OP_BASE_TYPE_SIGNED_CHAR */ \
NULL, /* OMPI_OP_BASE_TYPE_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_LONG */ \
NULL, /* OMPI_OP_BASE_TYPE_SHORT */ \
NULL, /* OMPI_OP_BASE_TYPE_UNSIGNED_SHORT */ \
NULL, /* OMPI_OP_BASE_TYPE_UNSIGNED */ \
NULL /* OMPI_OP_BASE_TYPE_UNSIGNED_LONG */
#define C_INTEGER_NULL_3BUFF \
NULL, /* OMPI_OP_BASE_TYPE_UNSIGNED_CHAR */ \
NULL, /* OMPI_OP_BASE_TYPE_SIGNED_CHAR */ \
NULL, /* OMPI_OP_BASE_TYPE_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_LONG */ \
NULL, /* OMPI_OP_BASE_TYPE_SHORT */ \
NULL, /* OMPI_OP_BASE_TYPE_UNSIGNED_SHORT */ \
NULL, /* OMPI_OP_BASE_TYPE_UNSIGNED */ \
NULL /* OMPI_OP_BASE_TYPE_UNSIGNED_LONG */
#define C_INTEGER(name) \
ompi_op_base_##name##_int8_t, /* OMPI_OP_BASE_TYPE_UNSIGNED_CHAR */ \
ompi_op_base_##name##_uint8_t, /* OMPI_OP_BASE_TYPE_SIGNED_CHAR */ \
ompi_op_base_##name##_int16_t, /* OMPI_OP_BASE_TYPE_INT */ \
ompi_op_base_##name##_uint16_t, /* OMPI_OP_BASE_TYPE_LONG */ \
ompi_op_base_##name##_int32_t, /* OMPI_OP_BASE_TYPE_SHORT */ \
ompi_op_base_##name##_uint32_t, /* OMPI_OP_BASE_TYPE_UNSIGNED_SHORT */ \
ompi_op_base_##name##_int64_t, /* OMPI_OP_BASE_TYPE_UNSIGNED */ \
ompi_op_base_##name##_uint64_t /* OMPI_OP_BASE_TYPE_UNSIGNED_LONG */
#define C_INTEGER_3BUFF(name) \
ompi_op_base_3buff_##name##_int8_t, /* OMPI_OP_BASE_TYPE_UNSIGNED_CHAR */ \
ompi_op_base_3buff_##name##_uint8_t, /* OMPI_OP_BASE_TYPE_SIGNED_CHAR */ \
ompi_op_base_3buff_##name##_int16_t, /* OMPI_OP_BASE_TYPE_INT */ \
ompi_op_base_3buff_##name##_uint16_t, /* OMPI_OP_BASE_TYPE_LONG */ \
ompi_op_base_3buff_##name##_int32_t, /* OMPI_OP_BASE_TYPE_SHORT */ \
ompi_op_base_3buff_##name##_uint32_t, /* OMPI_OP_BASE_TYPE_UNSIGNED_SHORT */ \
ompi_op_base_3buff_##name##_int64_t, /* OMPI_OP_BASE_TYPE_UNSIGNED */ \
ompi_op_base_3buff_##name##_uint64_t /* OMPI_OP_BASE_TYPE_UNSIGNED_LONG */
/** All the Fortran integers ********************************************/
#if OMPI_HAVE_FORTRAN_INTEGER
#define FORTRAN_INTEGER_PLAIN(name) ompi_op_base_##name##_fortran_integer
#define FORTRAN_INTEGER_PLAIN_3BUFF(name) ompi_op_base_3buff_##name##_fortran_integer
#else
#define FORTRAN_INTEGER_PLAIN(name) NULL
#define FORTRAN_INTEGER_PLAIN_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_INTEGER1
#define FORTRAN_INTEGER1(name) ompi_op_base_##name##_fortran_integer1
#define FORTRAN_INTEGER1_3BUFF(name) ompi_op_base_3buff_##name##_fortran_integer1
#else
#define FORTRAN_INTEGER1(name) NULL
#define FORTRAN_INTEGER1_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_INTEGER2
#define FORTRAN_INTEGER2(name) ompi_op_base_##name##_fortran_integer2
#define FORTRAN_INTEGER2_3BUFF(name) ompi_op_base_3buff_##name##_fortran_integer2
#else
#define FORTRAN_INTEGER2(name) NULL
#define FORTRAN_INTEGER2_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_INTEGER4
#define FORTRAN_INTEGER4(name) ompi_op_base_##name##_fortran_integer4
#define FORTRAN_INTEGER4_3BUFF(name) ompi_op_base_3buff_##name##_fortran_integer4
#else
#define FORTRAN_INTEGER4(name) NULL
#define FORTRAN_INTEGER4_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_INTEGER8
#define FORTRAN_INTEGER8(name) ompi_op_base_##name##_fortran_integer8
#define FORTRAN_INTEGER8_3BUFF(name) ompi_op_base_3buff_##name##_fortran_integer8
#else
#define FORTRAN_INTEGER8(name) NULL
#define FORTRAN_INTEGER8_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_INTEGER16
#define FORTRAN_INTEGER16(name) ompi_op_base_##name##_fortran_integer16
#define FORTRAN_INTEGER16_3BUFF(name) ompi_op_base_3buff_##name##_fortran_integer16
#else
#define FORTRAN_INTEGER16(name) NULL
#define FORTRAN_INTEGER16_3BUFF(name) NULL
#endif
#define FORTRAN_INTEGER(name) \
FORTRAN_INTEGER_PLAIN(name), /* OMPI_OP_BASE_TYPE_INTEGER */ \
FORTRAN_INTEGER1(name), /* OMPI_OP_BASE_TYPE_INTEGER1 */ \
FORTRAN_INTEGER2(name), /* OMPI_OP_BASE_TYPE_INTEGER2 */ \
FORTRAN_INTEGER4(name), /* OMPI_OP_BASE_TYPE_INTEGER4 */ \
FORTRAN_INTEGER8(name), /* OMPI_OP_BASE_TYPE_INTEGER8 */ \
FORTRAN_INTEGER16(name) /* OMPI_OP_BASE_TYPE_INTEGER16 */
#define FORTRAN_INTEGER_3BUFF(name) \
FORTRAN_INTEGER_PLAIN_3BUFF(name), /* OMPI_OP_BASE_TYPE_INTEGER */ \
FORTRAN_INTEGER1_3BUFF(name), /* OMPI_OP_BASE_TYPE_INTEGER1 */ \
FORTRAN_INTEGER2_3BUFF(name), /* OMPI_OP_BASE_TYPE_INTEGER2 */ \
FORTRAN_INTEGER4_3BUFF(name), /* OMPI_OP_BASE_TYPE_INTEGER4 */ \
FORTRAN_INTEGER8_3BUFF(name), /* OMPI_OP_BASE_TYPE_INTEGER8 */ \
FORTRAN_INTEGER16_3BUFF(name) /* OMPI_OP_BASE_TYPE_INTEGER16 */
#define FORTRAN_INTEGER_NULL \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER1 */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER2 */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER4 */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER8 */ \
NULL /* OMPI_OP_BASE_TYPE_INTEGER16 */
#define FORTRAN_INTEGER_NULL_3BUFF \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER1 */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER2 */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER4 */ \
NULL, /* OMPI_OP_BASE_TYPE_INTEGER8 */ \
NULL /* OMPI_OP_BASE_TYPE_INTEGER16 */
/** All the Fortran reals ***********************************************/
#if OMPI_HAVE_FORTRAN_REAL
#define FLOATING_POINT_FORTRAN_REAL_PLAIN(name) ompi_op_base_##name##_fortran_real
#define FLOATING_POINT_FORTRAN_REAL_PLAIN_3BUFF(name) ompi_op_base_3buff_##name##_fortran_real
#else
#define FLOATING_POINT_FORTRAN_REAL_PLAIN(name) NULL
#define FLOATING_POINT_FORTRAN_REAL_PLAIN_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_REAL2
#define FLOATING_POINT_FORTRAN_REAL2(name) ompi_op_base_##name##_fortran_real2
#define FLOATING_POINT_FORTRAN_REAL2_3BUFF(name) ompi_op_base_3buff_##name##_fortran_real2
#else
#define FLOATING_POINT_FORTRAN_REAL2(name) NULL
#define FLOATING_POINT_FORTRAN_REAL2_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_REAL4
#define FLOATING_POINT_FORTRAN_REAL4(name) ompi_op_base_##name##_fortran_real4
#define FLOATING_POINT_FORTRAN_REAL4_3BUFF(name) ompi_op_base_3buff_##name##_fortran_real4
#else
#define FLOATING_POINT_FORTRAN_REAL4(name) NULL
#define FLOATING_POINT_FORTRAN_REAL4_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_REAL8
#define FLOATING_POINT_FORTRAN_REAL8(name) ompi_op_base_##name##_fortran_real8
#define FLOATING_POINT_FORTRAN_REAL8_3BUFF(name) ompi_op_base_3buff_##name##_fortran_real8
#else
#define FLOATING_POINT_FORTRAN_REAL8(name) NULL
#define FLOATING_POINT_FORTRAN_REAL8_3BUFF(name) NULL
#endif
/* If:
- we have fortran REAL*16, *and*
- fortran REAL*16 matches the bit representation of the
corresponding C type
Only then do we put in function pointers for REAL*16 reductions.
Otherwise, just put in NULL. */
#if OMPI_HAVE_FORTRAN_REAL16 && OMPI_REAL16_MATCHES_C
#define FLOATING_POINT_FORTRAN_REAL16(name) ompi_op_base_##name##_fortran_real16
#define FLOATING_POINT_FORTRAN_REAL16_3BUFF(name) ompi_op_base_3buff_##name##_fortran_real16
#else
#define FLOATING_POINT_FORTRAN_REAL16(name) NULL
#define FLOATING_POINT_FORTRAN_REAL16_3BUFF(name) NULL
#endif
#define FLOATING_POINT_FORTRAN_REAL(name) \
FLOATING_POINT_FORTRAN_REAL_PLAIN(name), /* OMPI_OP_BASE_TYPE_REAL */ \
FLOATING_POINT_FORTRAN_REAL2(name), /* OMPI_OP_BASE_TYPE_REAL2 */ \
FLOATING_POINT_FORTRAN_REAL4(name), /* OMPI_OP_BASE_TYPE_REAL4 */ \
FLOATING_POINT_FORTRAN_REAL8(name), /* OMPI_OP_BASE_TYPE_REAL8 */ \
FLOATING_POINT_FORTRAN_REAL16(name) /* OMPI_OP_BASE_TYPE_REAL16 */
#define FLOATING_POINT_FORTRAN_REAL_3BUFF(name) \
FLOATING_POINT_FORTRAN_REAL_PLAIN_3BUFF(name), /* OMPI_OP_BASE_TYPE_REAL */ \
FLOATING_POINT_FORTRAN_REAL2_3BUFF(name), /* OMPI_OP_BASE_TYPE_REAL2 */ \
FLOATING_POINT_FORTRAN_REAL4_3BUFF(name), /* OMPI_OP_BASE_TYPE_REAL4 */ \
FLOATING_POINT_FORTRAN_REAL8_3BUFF(name), /* OMPI_OP_BASE_TYPE_REAL8 */ \
FLOATING_POINT_FORTRAN_REAL16_3BUFF(name) /* OMPI_OP_BASE_TYPE_REAL16 */
/** Fortran double precision ********************************************/
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
#define FLOATING_POINT_FORTRAN_DOUBLE_PRECISION(name) \
ompi_op_base_##name##_fortran_double_precision
#define FLOATING_POINT_FORTRAN_DOUBLE_PRECISION_3BUFF(name) \
ompi_op_base_3buff_##name##_fortran_double_precision
#else
#define FLOATING_POINT_FORTRAN_DOUBLE_PRECISION(name) NULL
#define FLOATING_POINT_FORTRAN_DOUBLE_PRECISION_3BUFF(name) NULL
#endif
/** Floating point, including all the Fortran reals *********************/
#define FLOATING_POINT(name) \
ompi_op_base_##name##_float, /* OMPI_OP_BASE_TYPE_FLOAT */\
ompi_op_base_##name##_double, /* OMPI_OP_BASE_TYPE_DOUBLE */\
FLOATING_POINT_FORTRAN_REAL(name), /* OMPI_OP_BASE_TYPE_REAL */ \
FLOATING_POINT_FORTRAN_DOUBLE_PRECISION(name), /* OMPI_OP_BASE_TYPE_DOUBLE_PRECISION */ \
ompi_op_base_##name##_long_double /* OMPI_OP_BASE_TYPE_LONG_DOUBLE */
#define FLOATING_POINT_3BUFF(name) \
ompi_op_base_3buff_##name##_float, /* OMPI_OP_BASE_TYPE_FLOAT */\
ompi_op_base_3buff_##name##_double, /* OMPI_OP_BASE_TYPE_DOUBLE */\
FLOATING_POINT_FORTRAN_REAL_3BUFF(name), /* OMPI_OP_BASE_TYPE_REAL */ \
FLOATING_POINT_FORTRAN_DOUBLE_PRECISION_3BUFF(name), /* OMPI_OP_BASE_TYPE_DOUBLE_PRECISION */ \
ompi_op_base_3buff_##name##_long_double /* OMPI_OP_BASE_TYPE_LONG_DOUBLE */
#define FLOATING_POINT_NULL \
NULL, /* OMPI_OP_BASE_TYPE_FLOAT */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL2 */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL4 */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL8 */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL16 */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE_PRECISION */ \
NULL /* OMPI_OP_BASE_TYPE_LONG_DOUBLE */
#define FLOATING_POINT_NULL_3BUFF \
NULL, /* OMPI_OP_BASE_TYPE_FLOAT */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL2 */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL4 */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL8 */ \
NULL, /* OMPI_OP_BASE_TYPE_REAL16 */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE_PRECISION */ \
NULL /* OMPI_OP_BASE_TYPE_LONG_DOUBLE */
/** Fortran logical *****************************************************/
#if OMPI_HAVE_FORTRAN_LOGICAL
#define FORTRAN_LOGICAL(name) \
ompi_op_base_##name##_fortran_logical /* OMPI_OP_BASE_TYPE_LOGICAL */
#define FORTRAN_LOGICAL_3BUFF(name) \
ompi_op_base_3buff_##name##_fortran_logical /* OMPI_OP_BASE_TYPE_LOGICAL */
#else
#define FORTRAN_LOGICAL(name) NULL
#define FORTRAN_LOGICAL_3BUFF(name) NULL
#endif
#define LOGICAL(name) \
FORTRAN_LOGICAL(name), \
ompi_op_base_##name##_bool /* OMPI_OP_BASE_TYPE_BOOL */
#define LOGICAL_3BUFF(name) \
FORTRAN_LOGICAL_3BUFF(name), \
ompi_op_base_3buff_##name##_bool /* OMPI_OP_BASE_TYPE_BOOL */
#define LOGICAL_NULL \
NULL, /* OMPI_OP_BASE_TYPE_LOGICAL */ \
NULL /* OMPI_OP_BASE_TYPE_BOOL */
#define LOGICAL_NULL_3BUFF \
NULL, /* OMPI_OP_BASE_TYPE_LOGICAL */ \
NULL /* OMPI_OP_BASE_TYPE_BOOL */
/** Fortran complex *****************************************************/
#if OMPI_HAVE_FORTRAN_REAL && OMPI_HAVE_FORTRAN_COMPLEX
#define COMPLEX_PLAIN(name) ompi_op_base_##name##_fortran_complex
#define COMPLEX_PLAIN_3BUFF(name) ompi_op_base_3buff_##name##_fortran_complex
#else
#define COMPLEX_PLAIN(name) NULL
#define COMPLEX_PLAIN_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION && OMPI_HAVE_FORTRAN_COMPLEX
#define COMPLEX_DOUBLE(name) ompi_op_base_##name##_fortran_double_complex
#define COMPLEX_DOUBLE_3BUFF(name) ompi_op_base_3buff_##name##_fortran_double_complex
#else
#define COMPLEX_DOUBLE(name) NULL
#define COMPLEX_DOUBLE_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_REAL4 && OMPI_HAVE_FORTRAN_COMPLEX8
#define COMPLEX8(name) ompi_op_base_##name##_fortran_complex8
#define COMPLEX8_3BUFF(name) ompi_op_base_3buff_##name##_fortran_complex8
#else
#define COMPLEX8(name) NULL
#define COMPLEX8_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_REAL8 && OMPI_HAVE_FORTRAN_COMPLEX16
#define COMPLEX16(name) ompi_op_base_##name##_fortran_complex16
#define COMPLEX16_3BUFF(name) ompi_op_base_3buff_##name##_fortran_complex16
#else
#define COMPLEX16(name) NULL
#define COMPLEX16_3BUFF(name) NULL
#endif
/* If:
- we have fortran REAL*16, *and*
- fortran REAL*16 matches the bit representation of the
corresponding C type, *and*
- we have fortran COMPILEX*32
Only then do we put in function pointers for COMPLEX*32 reductions.
Otherwise, just put in NULL. */
#if OMPI_HAVE_FORTRAN_REAL16 && OMPI_REAL16_MATCHES_C && OMPI_HAVE_FORTRAN_COMPLEX32
#define COMPLEX32(name) ompi_op_base_##name##_fortran_complex32
#define COMPLEX32_3BUFF(name) ompi_op_base_3buff_##name##_fortran_complex32
#else
#define COMPLEX32(name) NULL
#define COMPLEX32_3BUFF(name) NULL
#endif
#define COMPLEX(name) \
COMPLEX_PLAIN(name), /* OMPI_OP_BASE_TYPE_COMPLEX */ \
COMPLEX_DOUBLE(name), /* OMPI_OP_BASE_TYPE_DOUBLE_COMPLEX */ \
COMPLEX8(name), /* OMPI_OP_BASE_TYPE_COMPLEX8 */ \
COMPLEX16(name), /* OMPI_OP_BASE_TYPE_COMPLEX16 */ \
COMPLEX32(name) /* OMPI_OP_BASE_TYPE_COMPLEX32 */
#define COMPLEX_3BUFF(name) \
COMPLEX_PLAIN_3BUFF(name), /* OMPI_OP_BASE_TYPE_COMPLEX */ \
COMPLEX_DOUBLE_3BUFF(name), /* OMPI_OP_BASE_TYPE_DOUBLE_COMPLEX */ \
COMPLEX8_3BUFF(name), /* OMPI_OP_BASE_TYPE_COMPLEX8 */ \
COMPLEX16_3BUFF(name), /* OMPI_OP_BASE_TYPE_COMPLEX16 */ \
COMPLEX32_3BUFF(name) /* OMPI_OP_BASE_TYPE_COMPLEX32 */
#define COMPLEX_NULL \
NULL, /* OMPI_OP_BASE_TYPE_COMPLEX */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE_COMPLEX */ \
NULL, /* OMPI_OP_BASE_TYPE_COMPLEX8 */ \
NULL, /* OMPI_OP_BASE_TYPE_COMPLEX16 */ \
NULL /* OMPI_OP_BASE_TYPE_COMPLEX32 */
#define COMPLEX_NULL_3BUFF \
NULL, /* OMPI_OP_BASE_TYPE_COMPLEX */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE_COMPLEX */ \
NULL, /* OMPI_OP_BASE_TYPE_COMPLEX8 */ \
NULL, /* OMPI_OP_BASE_TYPE_COMPLEX16 */ \
NULL /* OMPI_OP_BASE_TYPE_COMPLEX32 */
/** Byte ****************************************************************/
#define BYTE(name) \
ompi_op_base_##name##_byte /* OMPI_OP_BASE_TYPE_BYTE */
#define BYTE_3BUFF(name) \
ompi_op_base_3buff_##name##_byte /* OMPI_OP_BASE_TYPE_BYTE */
#define BYTE_NULL \
NULL /* OMPI_OP_BASE_TYPE_BYTE */
#define BYTE_NULL_3BUFF \
NULL /* OMPI_OP_BASE_TYPE_BYTE */
/** Fortran complex *****************************************************/
/** Fortran "2" types ***************************************************/
#if OMPI_HAVE_FORTRAN_REAL
#define TWOLOC_FORTRAN_2REAL(name) ompi_op_base_##name##_2real
#define TWOLOC_FORTRAN_2REAL_3BUFF(name) ompi_op_base_3buff_##name##_2real
#else
#define TWOLOC_FORTRAN_2REAL(name) NULL
#define TWOLOC_FORTRAN_2REAL_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_DOUBLE_PRECISION
#define TWOLOC_FORTRAN_2DOUBLE_PRECISION(name) ompi_op_base_##name##_2double_precision
#define TWOLOC_FORTRAN_2DOUBLE_PRECISION_3BUFF(name) ompi_op_base_3buff_##name##_2double_precision
#else
#define TWOLOC_FORTRAN_2DOUBLE_PRECISION(name) NULL
#define TWOLOC_FORTRAN_2DOUBLE_PRECISION_3BUFF(name) NULL
#endif
#if OMPI_HAVE_FORTRAN_INTEGER
#define TWOLOC_FORTRAN_2INTEGER(name) ompi_op_base_##name##_2integer
#define TWOLOC_FORTRAN_2INTEGER_3BUFF(name) ompi_op_base_3buff_##name##_2integer
#else
#define TWOLOC_FORTRAN_2INTEGER(name) NULL
#define TWOLOC_FORTRAN_2INTEGER_3BUFF(name) NULL
#endif
/** All "2" types *******************************************************/
#define TWOLOC(name) \
TWOLOC_FORTRAN_2REAL(name), /* OMPI_OP_BASE_TYPE_2REAL */ \
TWOLOC_FORTRAN_2DOUBLE_PRECISION(name), /* OMPI_OP_BASE_TYPE_2DOUBLE_PRECISION */ \
TWOLOC_FORTRAN_2INTEGER(name), /* OMPI_OP_BASE_TYPE_2INTEGER */ \
ompi_op_base_##name##_float_int, /* OMPI_OP_BASE_TYPE_FLOAT_INT */ \
ompi_op_base_##name##_double_int, /* OMPI_OP_BASE_TYPE_DOUBLE_INT */ \
ompi_op_base_##name##_long_int, /* OMPI_OP_BASE_TYPE_LONG_INT */ \
ompi_op_base_##name##_2int, /* OMPI_OP_BASE_TYPE_2INT */ \
ompi_op_base_##name##_short_int, /* OMPI_OP_BASE_TYPE_SHORT_INT */ \
ompi_op_base_##name##_long_double_int /* OMPI_OP_BASE_TYPE_LONG_DOUBLE_INT */
#define TWOLOC_3BUFF(name) \
TWOLOC_FORTRAN_2REAL_3BUFF(name), /* OMPI_OP_BASE_TYPE_2REAL */ \
TWOLOC_FORTRAN_2DOUBLE_PRECISION_3BUFF(name), /* OMPI_OP_BASE_TYPE_2DOUBLE_PRECISION */ \
TWOLOC_FORTRAN_2INTEGER_3BUFF(name), /* OMPI_OP_BASE_TYPE_2INTEGER */ \
ompi_op_base_3buff_##name##_float_int, /* OMPI_OP_BASE_TYPE_FLOAT_INT */ \
ompi_op_base_3buff_##name##_double_int, /* OMPI_OP_BASE_TYPE_DOUBLE_INT */ \
ompi_op_base_3buff_##name##_long_int, /* OMPI_OP_BASE_TYPE_LONG_INT */ \
ompi_op_base_3buff_##name##_2int, /* OMPI_OP_BASE_TYPE_2INT */ \
ompi_op_base_3buff_##name##_short_int, /* OMPI_OP_BASE_TYPE_SHORT_INT */ \
ompi_op_base_3buff_##name##_long_double_int /* OMPI_OP_BASE_TYPE_LONG_DOUBLE_INT */
#define TWOLOC_NULL \
NULL, /* OMPI_OP_BASE_TYPE_2REAL */\
NULL, /* OMPI_OP_BASE_TYPE_2DOUBLE_PRECISION */ \
NULL, /* OMPI_OP_BASE_TYPE_2INTEGER */ \
NULL, /* OMPI_OP_BASE_TYPE_FLOAT_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_LONG_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_2INT */ \
NULL, /* OMPI_OP_BASE_TYPE_SHORT_INT */ \
NULL /* OMPI_OP_BASE_TYPE_LONG_DOUBLE_INT */
#define TWOLOC_NULL_3BUFF \
NULL, /* OMPI_OP_BASE_TYPE_2REAL */\
NULL, /* OMPI_OP_BASE_TYPE_2DOUBLE_PRECISION */ \
NULL, /* OMPI_OP_BASE_TYPE_2INTEGER */ \
NULL, /* OMPI_OP_BASE_TYPE_FLOAT_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_DOUBLE_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_LONG_INT */ \
NULL, /* OMPI_OP_BASE_TYPE_2INT */ \
NULL, /* OMPI_OP_BASE_TYPE_SHORT_INT */ \
NULL /* OMPI_OP_BASE_TYPE_LONG_DOUBLE_INT */
/*
* MPI_OP_NULL
* All types
*/
#define FLAGS_NO_FLOAT \
(OMPI_OP_FLAGS_INTRINSIC | OMPI_OP_FLAGS_ASSOC | OMPI_OP_FLAGS_COMMUTE)
#define FLAGS \
(OMPI_OP_FLAGS_INTRINSIC | OMPI_OP_FLAGS_ASSOC | \
OMPI_OP_FLAGS_FLOAT_ASSOC | OMPI_OP_FLAGS_COMMUTE)
ompi_op_base_handler_fn_t ompi_op_base_functions[OMPI_OP_BASE_FORTRAN_OP_MAX][OMPI_OP_BASE_TYPE_MAX] =
{
/* Corresponds to MPI_OP_NULL */
{
/* Leaving this empty puts in NULL for all entries */
NULL,
},
/* Corresponds to MPI_MAX */
{
C_INTEGER(max),
FORTRAN_INTEGER(max),
FLOATING_POINT(max),
LOGICAL_NULL,
COMPLEX_NULL,
BYTE_NULL,
TWOLOC_NULL
},
/* Corresponds to MPI_MIN */
{
C_INTEGER(min),
FORTRAN_INTEGER(min),
FLOATING_POINT(min),
LOGICAL_NULL,
COMPLEX_NULL,
BYTE_NULL,
TWOLOC_NULL
},
/* Corresponds to MPI_SUM */
{
C_INTEGER(sum),
FORTRAN_INTEGER(sum),
FLOATING_POINT(sum),
LOGICAL_NULL,
COMPLEX(sum),
BYTE_NULL,
TWOLOC_NULL
},
/* Corresponds to MPI_PROD */
{
C_INTEGER(prod),
FORTRAN_INTEGER(prod),
FLOATING_POINT(prod),
LOGICAL_NULL,
COMPLEX(prod),
BYTE_NULL,
TWOLOC_NULL
},
/* Corresponds to MPI_LAND */
{
C_INTEGER(land),
FORTRAN_INTEGER_NULL,
FLOATING_POINT_NULL,
LOGICAL(land),
COMPLEX_NULL,
BYTE_NULL,
TWOLOC_NULL
},
/* Corresponds to MPI_BAND */
{
C_INTEGER(band),
FORTRAN_INTEGER(band),
FLOATING_POINT_NULL,
LOGICAL_NULL,
COMPLEX_NULL,
BYTE(band),
TWOLOC_NULL
},
/* Corresponds to MPI_LOR */
{
C_INTEGER(lor),
FORTRAN_INTEGER_NULL,
FLOATING_POINT_NULL,
LOGICAL(lor),
COMPLEX_NULL,
BYTE_NULL,
TWOLOC_NULL
},
/* Corresponds to MPI_BOR */
{
C_INTEGER(bor),
FORTRAN_INTEGER(bor),
FLOATING_POINT_NULL,
LOGICAL_NULL,
COMPLEX_NULL,
BYTE(bor),
TWOLOC_NULL
},
/* Corresponds to MPI_LXOR */
{
C_INTEGER(lxor),
FORTRAN_INTEGER_NULL,
FLOATING_POINT_NULL,
LOGICAL(lxor),
COMPLEX_NULL,
BYTE_NULL,
TWOLOC_NULL
},
/* Corresponds to MPI_BXOR */
{
C_INTEGER(bxor),
FORTRAN_INTEGER(bxor),
FLOATING_POINT_NULL,
LOGICAL_NULL,
COMPLEX_NULL,
BYTE(bxor),
TWOLOC_NULL
},
/* Corresponds to MPI_MAXLOC */
{
C_INTEGER_NULL,
FORTRAN_INTEGER_NULL,
FLOATING_POINT_NULL,
LOGICAL_NULL,
COMPLEX_NULL,
BYTE_NULL,
TWOLOC(maxloc),
},
/* Corresponds to MPI_MINLOC */
{
C_INTEGER_NULL,
FORTRAN_INTEGER_NULL,
FLOATING_POINT_NULL,
LOGICAL_NULL,
COMPLEX_NULL,
BYTE_NULL,
TWOLOC(minloc),
},
/* Corresponds to MPI_REPLACE */
{
/* (MPI_ACCUMULATE is handled differently than the other
reductions, so just zero out its function
impementations here to ensure that users don't invoke
MPI_REPLACE with any reduction operations other than
ACCUMULATE) */
NULL,
},
};
ompi_op_base_3buff_handler_fn_t ompi_op_base_3buff_functions[OMPI_OP_BASE_FORTRAN_OP_MAX][OMPI_OP_BASE_TYPE_MAX] =
{
/* Corresponds to MPI_OP_NULL */
{
/* Leaving this empty puts in NULL for all entries */
NULL,
},
/* Corresponds to MPI_MAX */
{
C_INTEGER_3BUFF(max),
FORTRAN_INTEGER_3BUFF(max),
FLOATING_POINT_3BUFF(max),
LOGICAL_NULL_3BUFF,
COMPLEX_NULL_3BUFF,
BYTE_NULL_3BUFF,
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_MIN */
{
C_INTEGER_3BUFF(min),
FORTRAN_INTEGER_3BUFF(min),
FLOATING_POINT_3BUFF(min),
LOGICAL_NULL_3BUFF,
COMPLEX_NULL_3BUFF,
BYTE_NULL_3BUFF,
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_SUM */
{
C_INTEGER_3BUFF(sum),
FORTRAN_INTEGER_3BUFF(sum),
FLOATING_POINT_3BUFF(sum),
LOGICAL_NULL_3BUFF,
COMPLEX_3BUFF(sum),
BYTE_NULL_3BUFF,
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_PROD */
{
C_INTEGER_3BUFF(prod),
FORTRAN_INTEGER_3BUFF(prod),
FLOATING_POINT_3BUFF(prod),
LOGICAL_NULL_3BUFF,
COMPLEX_3BUFF(prod),
BYTE_NULL_3BUFF,
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_LAND */
{
C_INTEGER_3BUFF(land),
FORTRAN_INTEGER_NULL_3BUFF,
FLOATING_POINT_NULL_3BUFF,
LOGICAL_3BUFF(land),
COMPLEX_NULL_3BUFF,
BYTE_NULL_3BUFF,
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_BAND */
{
C_INTEGER_3BUFF(band),
FORTRAN_INTEGER_3BUFF(band),
FLOATING_POINT_NULL_3BUFF,
LOGICAL_NULL_3BUFF,
COMPLEX_NULL_3BUFF,
BYTE_3BUFF(band),
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_LOR */
{
C_INTEGER_3BUFF(lor),
FORTRAN_INTEGER_NULL_3BUFF,
FLOATING_POINT_NULL_3BUFF,
LOGICAL_3BUFF(lor),
COMPLEX_NULL_3BUFF,
BYTE_NULL_3BUFF,
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_BOR */
{
C_INTEGER_3BUFF(bor),
FORTRAN_INTEGER_3BUFF(bor),
FLOATING_POINT_NULL_3BUFF,
LOGICAL_NULL_3BUFF,
COMPLEX_NULL_3BUFF,
BYTE_3BUFF(bor),
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_LXOR */
{
C_INTEGER_3BUFF(lxor),
FORTRAN_INTEGER_NULL_3BUFF,
FLOATING_POINT_NULL_3BUFF,
LOGICAL_3BUFF(lxor),
COMPLEX_NULL_3BUFF,
BYTE_NULL_3BUFF,
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_BXOR */
{
C_INTEGER_3BUFF(bxor),
FORTRAN_INTEGER_3BUFF(bxor),
FLOATING_POINT_NULL_3BUFF,
LOGICAL_NULL_3BUFF,
COMPLEX_NULL_3BUFF,
BYTE_3BUFF(bxor),
TWOLOC_NULL_3BUFF
},
/* Corresponds to MPI_MAXLOC */
{
C_INTEGER_NULL_3BUFF,
FORTRAN_INTEGER_NULL_3BUFF,
FLOATING_POINT_NULL_3BUFF,
LOGICAL_NULL_3BUFF,
COMPLEX_NULL_3BUFF,
BYTE_NULL_3BUFF,
TWOLOC_3BUFF(maxloc),
},
/* Corresponds to MPI_MINLOC */
{
C_INTEGER_NULL_3BUFF,
FORTRAN_INTEGER_NULL_3BUFF,
FLOATING_POINT_NULL_3BUFF,
LOGICAL_NULL_3BUFF,
COMPLEX_NULL_3BUFF,
BYTE_NULL_3BUFF,
TWOLOC_3BUFF(minloc),
},
/* Corresponds to MPI_REPLACE */
{
/* MPI_ACCUMULATE is handled differently than the other
reductions, so just zero out its function
impementations here to ensure that users don't invoke
MPI_REPLACE with any reduction operations other than
ACCUMULATE */
NULL,
},
};
Показать git blame Копировать постоянную ссылку