eesupp/inc/CPP_EEOPTIONS.h

C $Header: /u/gcmpack/models/MITgcmUV/eesupp/inc/CPP_EEOPTIONS.h,v 1.12 1999/05/21 21:57:44 adcroft Exp $
C
C     /==========================================================\
C     | CPP_EEOPTIONS.h                                          |
C     |==========================================================|
C     | C preprocessor "execution environment" supporting        |
C     | flags. Use this file to set flags controlling the        |
C     | execution environment in which a model runs - as opposed |
C     | to the dynamical problem the model solves.               |
C     | Note: Many options are implemented with both compile time|
C     |       and run-time switches. This allows options to be   |
C     |       removed altogether, made optional at run-time or   |
C     |       to be permanently enabled. This convention helps   |
C     |       with the data-dependence analysis performed by the |
C     |       adjoint model compiler. This data dependency       |
C     |       analysis can be upset by runtime switches that it  |
C     |       is unable to recoginise as being fixed for the     |
C     |       duration of an integration.                        |
C     |       A reasonable way to use these flags is to          |
C     |       set all options as selectable at runtime but then  |
C     |       once an experimental configuration has been        |
C     |       identified, rebuild the code with the appropriate  |
C     |       options set at compile time.                       |
C     \==========================================================/

#ifndef _CPP_EEOPTIONS_H_
#define _CPP_EEOPTIONS_H_

C     In general the following convention applies:
C     ALLOW  - indicates an feature will be included but it may
C     CAN      have a run-time flag to allow it to be switched
C              on and off.
C              If ALLOW or CAN directives are "undef'd" this generally
C              means that the feature will not be available i.e. it
C              will not be included in the compiled code and so no
C              run-time option to use the feature will be available.
C
C     ALWAYS - indicates the choice will be fixed at compile time
C              so no run-time option will be present

C     Flag used to indicate whether Fortran formatted write
C     and read are threadsafe. On SGI the routines can be thread
C     safe, on Sun it is not possible - if you are unsure then
C     undef this option.
#undef  FMTFTN_IO_THREADSAFE

C     Flag used to indicate which flavour of multi-threading
C     compiler directives to use. Only set one of these.
C     USE_SOLARIS_THREADING  - Takes directives for SUN Workshop
C                              compiler.
C     USE_KAP_THREADING      - Takes directives for Kuck and 
C                              Associates multi-threading compiler
C                              ( used on Digital platforms ).
C     USE_IRIX_THREADING     - Takes directives for SGI MIPS
C                              Pro Fortran compiler.
C     USE_EXEMPLAR_THREADING - Takes directives for HP SPP series
C                              compiler.
C     USE_C90_THREADING      - Takes directives for CRAY/SGI C90
C                              system F90 compiler.
#ifdef TARGET_SUN
#define USE_SOLARIS_THREADING
#endif

#ifdef TARGET_DEC
#define USE_KAP_THREADING
#endif

#ifdef TARGET_SGI
#define USE_IRIX_THREADING
#endif

#ifdef TARGET_HP
#define USE_EXEMPLAR_THREADING
#endif

#ifdef TARGET_CRAY_VECTOR
#define USE_C90_THREADING
#endif

C--   Define the mapping for the _BARRIER macro
C     On some systems low-level hardware support can be accessed through
C     compiler directives here.
#define _BARRIER CALL BARRIER(myThid)

C--   Define the mapping for the BEGIN_CRIT() and  END_CRIT() macros. 
C     On some systems we simply execute this section only using the
C     master thread i.e. its not really a critical section. We can
C     do this because we do not use critical sections in any critical
C     sections of our code!
#define _BEGIN_CRIT(a) _BEGIN_MASTER(a)
#define _END_CRIT(a)   _END_MASTER(a)

C--   Define the mapping for the BEGIN_MASTER_SECTION() and
C     END_MASTER_SECTION() macros. These are generally implemented by
C     simply choosing a particular thread to be "the master" and have
C     it alone execute the BEGIN_MASTER..., END_MASTER.. sections.
#define _BEGIN_MASTER(a)  IF ( a .EQ. 1 ) THEN
#define _END_MASTER(a)    ENDIF

C--   Control MPI based parallel processing
#undef  ALLOW_USE_MPI
#undef  ALWAYS_USE_MPI
 
C--   Control use of communication that might overlap computation.
C     Under MPI selects/deselects "non-blocking" sends and receives.
#define ALLOW_ASYNC_COMMUNICATION
#undef  ALLOW_ASYNC_COMMUNICATION
#undef  ALWAYS_USE_ASYNC_COMMUNICATION
C--   Control use of communication that is atomic to computation.
C     Under MPI selects/deselects "blocking" sends and receives.
#define ALLOW_SYNC_COMMUNICATION
#undef  ALWAYS_USE_SYNC_COMMUNICATION

C--   Control use of JAM routines for Artic network
C     These invoke optimized versions of "exchange" and "sum" that
C     utilize the programmable aspect of Artic cards.
#undef  LETS_MAKE_JAM
#undef  JAM_WITH_TWO_PROCS_PER_NODE
#ifdef LETS_MAKE_JAM
#define _JAMEXT _jam
#else
#define _JAMEXT
#endif

C--   Control storage of floating point operands
C     On many systems it improves performance only to use
C     8-byte precision for time stepped variables.
C     Constant in time terms ( geometric factors etc.. )
C     can use 4-byte precision, reducing memory utilisation and
C     boosting performance because of a smaller working
C     set size. However, on vector CRAY systems this degrades
C     performance.
#define REAL4_IS_SLOW
 
#ifdef REAL4_IS_SLOW
#define real Real*8
#define REAL Real*8
#define _RS  Real*8
#define _RL  Real*8
#define RS_IS_REAL8
#define _EXCH_XY_R4(a,b)       CALL EXCH_XY_R8 ( a, b )
#define _EXCH_XYZ_R4(a,b)      CALL EXCH_XYZ_R8 ( a, b )
#define _GLOBAL_SUM_R4(a,b)    CALL GLOBAL_SUM_R8( a, b )
#define _GLOBAL_MAX_R4(a,b)    CALL GLOBAL_MAX_R8( a, b )
#endif

#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 )
#define _GLOBAL_MAX_R4(a,b)    CALL GLOBAL_MAX_R4( a, b )
#endif
 
#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 )
 
C--   Control use of "double" precision constants.
C     Use D0 where it means REAL*8 but not where it means REAL*16
#define D0 d0
#ifdef REAL_D0_IS_16BYTES
#define D0
#endif

C--   Control XY periodicity in processor to grid mappings
C     Note: Model code does not need to know whether a domain is 
C           periodic because it has overlap regions for every box.
C           Model assume that these values have been
C           filled in some way.
#undef  ALWAYS_PREVENT_X_PERIODICITY
#undef  ALWAYS_PREVENT_Y_PERIODICITY
#define CAN_PREVENT_X_PERIODICITY
#define CAN_PREVENT_Y_PERIODICITY

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

#endif /* _CPP_EEOPTIONS_H_ */
1	adcroft	1.13	C $Header: /u/gcmpack/models/MITgcmUV/eesupp/inc/CPP_EEOPTIONS.h,v 1.12 1999/05/21 21:57:44 adcroft Exp $
2	cnh	1.1	C
3			C /==========================================================\
4			C \| CPP_EEOPTIONS.h \|
5			C \|==========================================================\|
6			C \| C preprocessor "execution environment" supporting \|
7			C \| flags. Use this file to set flags controlling the \|
8			C \| execution environment in which a model runs - as opposed \|
9			C \| to the dynamical problem the model solves. \|
10			C \| Note: Many options are implemented with both compile time\|
11			C \| and run-time switches. This allows options to be \|
12			C \| removed altogether, made optional at run-time or \|
13			C \| to be permanently enabled. This convention helps \|
14			C \| with the data-dependence analysis performed by the \|
15			C \| adjoint model compiler. This data dependency \|
16			C \| analysis can be upset by runtime switches that it \|
17			C \| is unable to recoginise as being fixed for the \|
18			C \| duration of an integration. \|
19			C \| A reasonable way to use these flags is to \|
20			C \| set all options as selectable at runtime but then \|
21			C \| once an experimental configuration has been \|
22			C \| identified, rebuild the code with the appropriate \|
23			C \| options set at compile time. \|
24			C \==========================================================/
25
26	adcroft	1.4	#ifndef _CPP_EEOPTIONS_H_
27			#define _CPP_EEOPTIONS_H_
28
29	cnh	1.1	C In general the following convention applies:
30			C ALLOW - indicates an feature will be included but it may
31			C CAN have a run-time flag to allow it to be switched
32			C on and off.
33			C If ALLOW or CAN directives are "undef'd" this generally
34			C means that the feature will not be available i.e. it
35			C will not be included in the compiled code and so no
36			C run-time option to use the feature will be available.
37			C
38			C ALWAYS - indicates the choice will be fixed at compile time
39			C so no run-time option will be present
40
41			C Flag used to indicate whether Fortran formatted write
42			C and read are threadsafe. On SGI the routines can be thread
43			C safe, on Sun it is not possible - if you are unsure then
44			C undef this option.
45			#undef FMTFTN_IO_THREADSAFE
46
47			C Flag used to indicate which flavour of multi-threading
48			C compiler directives to use. Only set one of these.
49			C USE_SOLARIS_THREADING - Takes directives for SUN Workshop
50			C compiler.
51			C USE_KAP_THREADING - Takes directives for Kuck and
52			C Associates multi-threading compiler
53			C ( used on Digital platforms ).
54			C USE_IRIX_THREADING - Takes directives for SGI MIPS
55			C Pro Fortran compiler.
56			C USE_EXEMPLAR_THREADING - Takes directives for HP SPP series
57			C compiler.
58			C USE_C90_THREADING - Takes directives for CRAY/SGI C90
59			C system F90 compiler.
60			#ifdef TARGET_SUN
61			#define USE_SOLARIS_THREADING
62			#endif
63
64			#ifdef TARGET_DEC
65	cnh	1.9	#define USE_KAP_THREADING
66	cnh	1.1	#endif
67
68			#ifdef TARGET_SGI
69			#define USE_IRIX_THREADING
70			#endif
71
72			#ifdef TARGET_HP
73			#define USE_EXEMPLAR_THREADING
74			#endif
75
76			#ifdef TARGET_CRAY_VECTOR
77			#define USE_C90_THREADING
78			#endif
79
80			C-- Define the mapping for the _BARRIER macro
81			C On some systems low-level hardware support can be accessed through
82			C compiler directives here.
83			#define _BARRIER CALL BARRIER(myThid)
84
85			C-- Define the mapping for the BEGIN_CRIT() and END_CRIT() macros.
86			C On some systems we simply execute this section only using the
87			C master thread i.e. its not really a critical section. We can
88	cnh	1.10	C do this because we do not use critical sections in any critical
89	cnh	1.1	C sections of our code!
90			#define _BEGIN_CRIT(a) _BEGIN_MASTER(a)
91			#define _END_CRIT(a) _END_MASTER(a)
92
93			C-- Define the mapping for the BEGIN_MASTER_SECTION() and
94			C END_MASTER_SECTION() macros. These are generally implemented by
95			C simply choosing a particular thread to be "the master" and have
96			C it alone execute the BEGIN_MASTER..., END_MASTER.. sections.
97			#define _BEGIN_MASTER(a) IF ( a .EQ. 1 ) THEN
98			#define _END_MASTER(a) ENDIF
99
100			C-- Control MPI based parallel processing
101	cnh	1.8	#undef ALLOW_USE_MPI
102			#undef ALWAYS_USE_MPI
103	cnh	1.1
104			C-- Control use of communication that might overlap computation.
105			C Under MPI selects/deselects "non-blocking" sends and receives.
106			#define ALLOW_ASYNC_COMMUNICATION
107			#undef ALLOW_ASYNC_COMMUNICATION
108			#undef ALWAYS_USE_ASYNC_COMMUNICATION
109			C-- Control use of communication that is atomic to computation.
110			C Under MPI selects/deselects "blocking" sends and receives.
111			#define ALLOW_SYNC_COMMUNICATION
112			#undef ALWAYS_USE_SYNC_COMMUNICATION
113	adcroft	1.13
114			C-- Control use of JAM routines for Artic network
115			C These invoke optimized versions of "exchange" and "sum" that
116			C utilize the programmable aspect of Artic cards.
117			#undef LETS_MAKE_JAM
118			#undef JAM_WITH_TWO_PROCS_PER_NODE
119			#ifdef LETS_MAKE_JAM
120			#define _JAMEXT _jam
121			#else
122			#define _JAMEXT
123			#endif
124	cnh	1.1
125			C-- Control storage of floating point operands
126			C On many systems it improves performance only to use
127			C 8-byte precision for time stepped variables.
128			C Constant in time terms ( geometric factors etc.. )
129			C can use 4-byte precision, reducing memory utilisation and
130			C boosting performance because of a smaller working
131			C set size. However, on vector CRAY systems this degrades
132			C performance.
133	cnh	1.8	#define REAL4_IS_SLOW
134	cnh	1.1
135			#ifdef REAL4_IS_SLOW
136			#define real Real*8
137			#define REAL Real*8
138			#define _RS Real*8
139			#define _RL Real*8
140	cnh	1.9	#define RS_IS_REAL8
141	cnh	1.1	#define _EXCH_XY_R4(a,b) CALL EXCH_XY_R8 ( a, b )
142			#define _EXCH_XYZ_R4(a,b) CALL EXCH_XYZ_R8 ( a, b )
143	adcroft	1.12	#define _GLOBAL_SUM_R4(a,b) CALL GLOBAL_SUM_R8( a, b )
144			#define _GLOBAL_MAX_R4(a,b) CALL GLOBAL_MAX_R8( a, b )
145	cnh	1.1	#endif
146
147			#ifndef REAL4_IS_SLOW
148			#define real Real*4
149			#define REAL Real*8
150			#define _RS Real*4
151			#define _RL Real*8
152	cnh	1.9	#define RS_IS_REAL4
153	cnh	1.1	#define _EXCH_XY_R4(a,b) CALL EXCH_XY_R4 ( a, b )
154			#define _EXCH_XYZ_R4(a,b) CALL EXCH_XYZ_R4 ( a, b )
155	adcroft	1.12	#define _GLOBAL_SUM_R4(a,b) CALL GLOBAL_SUM_R4( a, b )
156			#define _GLOBAL_MAX_R4(a,b) CALL GLOBAL_MAX_R4( a, b )
157	cnh	1.1	#endif
158
159			#define _EXCH_XY_R8(a,b) CALL EXCH_XY_R8 ( a, b )
160			#define _EXCH_XYZ_R8(a,b) CALL EXCH_XYZ_R8 ( a, b )
161	adcroft	1.12	#define _GLOBAL_SUM_R8(a,b) CALL GLOBAL_SUM_R8( a, b )
162			#define _GLOBAL_MAX_R8(a,b) CALL GLOBAL_MAX_R8( a, b )
163	cnh	1.1
164			C-- Control use of "double" precision constants.
165			C Use D0 where it means REAL8 but not where it means REAL16
166			#define D0 d0
167			#ifdef REAL_D0_IS_16BYTES
168			#define D0
169			#endif
170
171			C-- Control XY periodicity in processor to grid mappings
172			C Note: Model code does not need to know whether a domain is
173			C periodic because it has overlap regions for every box.
174	cnh	1.10	C Model assume that these values have been
175	cnh	1.1	C filled in some way.
176			#undef ALWAYS_PREVENT_X_PERIODICITY
177			#undef ALWAYS_PREVENT_Y_PERIODICITY
178			#define CAN_PREVENT_X_PERIODICITY
179			#define CAN_PREVENT_Y_PERIODICITY
180
181			C-- Substitue for 1.D variables
182	cnh	1.10	C Sun compilers do not use 8-byte precision for literals
183	cnh	1.1	C unless .Dnn is specified. CRAY vector machines use 16-byte
184			C precision when they see .Dnn which runs very slowly!
185			#ifdef REAL_D0_IS_16BYTES
186			#define _d
187	cnh	1.8	#define _F64( a ) a
188	cnh	1.1	#endif
189			#ifndef REAL_D0_IS_16BYTES
190			#define _d D
191	cnh	1.8	#define _F64( a ) DFLOAT( a )
192	cnh	1.1	#endif
193	cnh	1.3
194	adcroft	1.4	#endif /* _CPP_EEOPTIONS_H_ */