44 |
C undef this option. |
C undef this option. |
45 |
#undef FMTFTN_IO_THREADSAFE |
#undef FMTFTN_IO_THREADSAFE |
46 |
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C Flag used to indicate which flavour of multi-threading |
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C compiler directives to use. Only set one of these. |
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C USE_SOLARIS_THREADING - Takes directives for SUN Workshop |
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C compiler. |
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C USE_KAP_THREADING - Takes directives for Kuck and |
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C Associates multi-threading compiler |
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C ( used on Digital platforms ). |
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C USE_IRIX_THREADING - Takes directives for SGI MIPS |
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C Pro Fortran compiler. |
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C USE_EXEMPLAR_THREADING - Takes directives for HP SPP series |
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C compiler. |
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C USE_C90_THREADING - Takes directives for CRAY/SGI C90 |
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C system F90 compiler. |
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#ifdef TARGET_SUN |
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#define USE_SOLARIS_THREADING |
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#endif |
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#ifdef TARGET_DEC |
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#define USE_KAP_THREADING |
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#endif |
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#ifdef TARGET_SGI |
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#define USE_IRIX_THREADING |
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#endif |
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#ifdef TARGET_HP |
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#define USE_EXEMPLAR_THREADING |
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#endif |
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#ifdef TARGET_CRAY_VECTOR |
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#define USE_C90_THREADING |
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#endif |
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C-- Define the mapping for the _BARRIER macro |
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C On some systems low-level hardware support can be accessed through |
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C compiler directives here. |
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#define _BARRIER CALL BARRIER(myThid) |
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C-- Define the mapping for the BEGIN_CRIT() and END_CRIT() macros. |
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C On some systems we simply execute this section only using the |
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C master thread i.e. its not really a critical section. We can |
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C do this because we do not use critical sections in any critical |
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|
C sections of our code! |
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#define _BEGIN_CRIT(a) _BEGIN_MASTER(a) |
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#define _END_CRIT(a) _END_MASTER(a) |
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C-- Define the mapping for the BEGIN_MASTER_SECTION() and |
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C END_MASTER_SECTION() macros. These are generally implemented by |
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C simply choosing a particular thread to be "the master" and have |
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C it alone execute the BEGIN_MASTER..., END_MASTER.. sections. |
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#define _BEGIN_MASTER(a) IF ( a .EQ. 1 ) THEN |
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#define _END_MASTER(a) ENDIF |
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|
47 |
C-- Control MPI based parallel processing |
C-- Control MPI based parallel processing |
48 |
#undef ALLOW_USE_MPI |
#undef ALLOW_USE_MPI |
49 |
#undef ALWAYS_USE_MPI |
#undef ALWAYS_USE_MPI |
63 |
C utilize the programmable aspect of Artic cards. |
C utilize the programmable aspect of Artic cards. |
64 |
#undef LETS_MAKE_JAM |
#undef LETS_MAKE_JAM |
65 |
#undef JAM_WITH_TWO_PROCS_PER_NODE |
#undef JAM_WITH_TWO_PROCS_PER_NODE |
|
#ifdef LETS_MAKE_JAM |
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|
#define _JAMEXT _jam |
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|
#else |
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|
#define _JAMEXT |
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|
#endif |
|
66 |
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|
67 |
C-- Control storage of floating point operands |
C-- Control storage of floating point operands |
68 |
C On many systems it improves performance only to use |
C On many systems it improves performance only to use |
74 |
C performance. |
C performance. |
75 |
#define REAL4_IS_SLOW |
#define REAL4_IS_SLOW |
76 |
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|
#ifdef REAL4_IS_SLOW |
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|
#define real Real*8 |
|
|
#define REAL Real*8 |
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|
#define _RS Real*8 |
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|
#define _RL Real*8 |
|
|
#define RS_IS_REAL8 |
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|
#define _EXCH_XY_R4(a,b) CALL EXCH_XY_R8 ( a, b ) |
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|
#define _EXCH_XYZ_R4(a,b) CALL EXCH_XYZ_R8 ( a, b ) |
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|
#define _GLOBAL_SUM_R4(a,b) CALL GLOBAL_SUM_R8( a, b ) |
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|
#define _GLOBAL_MAX_R4(a,b) CALL GLOBAL_MAX_R8( a, b ) |
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|
#endif |
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|
|
|
#ifndef REAL4_IS_SLOW |
|
|
#define real Real*4 |
|
|
#define REAL Real*8 |
|
|
#define _RS Real*4 |
|
|
#define _RL Real*8 |
|
|
#define RS_IS_REAL4 |
|
|
#define _EXCH_XY_R4(a,b) CALL EXCH_XY_R4 ( a, b ) |
|
|
#define _EXCH_XYZ_R4(a,b) CALL EXCH_XYZ_R4 ( a, b ) |
|
|
#define _GLOBAL_SUM_R4(a,b) CALL GLOBAL_SUM_R4( a, b ) |
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|
#define _GLOBAL_MAX_R4(a,b) CALL GLOBAL_MAX_R4( a, b ) |
|
|
#endif |
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|
|
|
#define _EXCH_XY_R8(a,b) CALL EXCH_XY_R8 ( a, b ) |
|
|
#define _EXCH_XYZ_R8(a,b) CALL EXCH_XYZ_R8 ( a, b ) |
|
|
#define _GLOBAL_SUM_R8(a,b) CALL GLOBAL_SUM_R8( a, b ) |
|
|
#define _GLOBAL_MAX_R8(a,b) CALL GLOBAL_MAX_R8( a, b ) |
|
|
|
|
77 |
C-- Control use of "double" precision constants. |
C-- Control use of "double" precision constants. |
78 |
C Use D0 where it means REAL*8 but not where it means REAL*16 |
C Use D0 where it means REAL*8 but not where it means REAL*16 |
79 |
#define D0 d0 |
#define D0 d0 |
|
#ifdef REAL_D0_IS_16BYTES |
|
|
#define D0 |
|
|
#endif |
|
80 |
|
|
81 |
C-- Control XY periodicity in processor to grid mappings |
C-- Control XY periodicity in processor to grid mappings |
82 |
C Note: Model code does not need to know whether a domain is |
C Note: Model code does not need to know whether a domain is |
88 |
#define CAN_PREVENT_X_PERIODICITY |
#define CAN_PREVENT_X_PERIODICITY |
89 |
#define CAN_PREVENT_Y_PERIODICITY |
#define CAN_PREVENT_Y_PERIODICITY |
90 |
|
|
|
C-- Substitue for 1.D variables |
|
|
C Sun compilers do not use 8-byte precision for literals |
|
|
C unless .Dnn is specified. CRAY vector machines use 16-byte |
|
|
C precision when they see .Dnn which runs very slowly! |
|
|
#ifdef REAL_D0_IS_16BYTES |
|
|
#define _d |
|
|
#define _F64( a ) a |
|
|
#endif |
|
|
#ifndef REAL_D0_IS_16BYTES |
|
|
#define _d D |
|
|
#define _F64( a ) DFLOAT( a ) |
|
|
#endif |
|
|
|
|
91 |
#endif /* _CPP_EEOPTIONS_H_ */ |
#endif /* _CPP_EEOPTIONS_H_ */ |
92 |
|
|
93 |
|
#include "CPP_EEMACROS.h" |