model/src/config_summary.F

C $Header: /u/gcmpack/models/MITgcmUV/model/src/config_summary.F,v 1.17 1998/10/28 03:11:36 cnh Exp $

#include "CPP_OPTIONS.h"

CStartOfInterface
      SUBROUTINE CONFIG_SUMMARY( myThid )
C     /==========================================================\
C     | SUBROUTINE CONFIG_SUMMARY                                |
C     | o Summarize model prognostic variables.                  |
C     |==========================================================|
C     | This routine writes a tabulated summary of the model     |
C     | configuration.                                           |
C     | Note                                                     |
C     |  1. Under multi-process parallelism the summary          |
C     |     is only given for the per-process data.              |
C     |  2. Under multi-threading the summary is produced by     |
C     |     the master thread. This threads reads data managed by|
C     |     other threads.                                       |
C     \==========================================================/

C     === Global variables ===
#include "SIZE.h"
#include "EEPARAMS.h"
#include "PARAMS.h"
#include "GRID.h"
#include "DYNVARS.h"

C     == Routine arguments ==
C     myThid -  Number of this instance of CONFIG_SUMMARY
      INTEGER myThid
CEndOfInterface

C     == Local variables ==
      CHARACTER*(MAX_LEN_MBUF) msgBuf
      INTEGER                  I,J,K
      INTEGER                  bi, bj
      REAL                     xcoord(Nx)
      REAL                     ycoord(Ny)
      REAL                     rcoord(Nr)


      _BARRIER
      _BEGIN_MASTER(myThid)

      WRITE(msgBuf,'(A)')
     &'// ======================================================='
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') '// Model configuration'
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)')
     &'// ======================================================='
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
     &  SQUEEZE_RIGHT , 1)

      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') 
     & '// "Physical" paramters ( PARM01 in namelist ) '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      CALL WRITE_1D_R8( tRef, Nr, INDEX_K,'tRef =',
     &'   /* Reference temperature profile ( oC or oK ) */')
      CALL WRITE_1D_R8( sRef, Nr, INDEX_K,'sRef =',
     &'   /* Reference salinity profile ( ppt ) */')
      CALL WRITE_1D_R8( viscAh, 1, INDEX_NONE,'viscAh =',
     &'   /* Lateral eddy viscosity ( m^2/s ) */')
      CALL WRITE_1D_R8( viscA4, 1, INDEX_NONE,'viscAh =',
     &'   /* Lateral biharmonic viscosity ( m^4/s ) */')
      IF ( viscAz .NE. UNSET_RL ) THEN
       CALL WRITE_1D_R8( viscAz, 1, INDEX_NONE,'viscAz =',
     & '   /* Vertical eddy viscosity ( m^2/s ) */')
      ENDIF
      IF ( viscAp .NE. UNSET_RL ) THEN
       CALL WRITE_1D_R8( viscAp, 1, INDEX_NONE,'viscAp =',
     & '   /* Vertical eddy viscosity ( Pa^2/s ) */')
      ENDIF
      CALL WRITE_1D_R8( viscAr, 1, INDEX_NONE,'viscAr =',
     &'   /* Vertical eddy viscosity ( units of r^2/s ) */')
      CALL WRITE_1D_R8( diffKhT, 1, INDEX_NONE,'diffKhT =',
     &'   /* Laplacian diffusion of heat laterally ( m^2/s ) */')
      CALL WRITE_1D_R8( diffKzT, 1, INDEX_NONE,'diffKzT =',
     &'   /* Laplacian diffusion of heat vertically ( m^2/s ) */')
      CALL WRITE_1D_R8( diffK4T, 1, INDEX_NONE,'diffK4T =',
     &'   /* Bihaarmonic diffusion of heat laterally ( m^4/s ) */')
      CALL WRITE_1D_R8( diffKhS, 1, INDEX_NONE,'diffKhS =',
     &'   /* Laplacian diffusion of salt laterally ( m^2/s ) */')
      CALL WRITE_1D_R8( diffKzS, 1, INDEX_NONE,'diffKzS =',
     &'   /* Laplacian diffusion of salt vertically ( m^2/s ) */')
      CALL WRITE_1D_R8( diffK4S, 1, INDEX_NONE,'diffK4S =',
     &'   /* Bihaarmonic diffusion of salt laterally ( m^4/s ) */')
      CALL WRITE_1D_R8( tAlpha,1, INDEX_NONE,'tAlpha =',
     &'   /* Linear EOS thermal expansion coefficient ( 1/degree ) */')
      CALL WRITE_1D_R8( sBeta, 1, INDEX_NONE,'sBeta =',
     &'   /* Linear EOS haline contraction coefficient ( 1/ppt ) */')
      IF ( eosType .EQ. 'POLY3' ) THEN
        WRITE(msgBuf,'(A)') 
     &   '// Polynomial EQS parameters ( from POLY3.COEFFS ) '
        DO K = 1, Nr
         WRITE(msgBuf,'(I3,13F8.3)')
     &   K,eosRefT(K),eosRefS(K),eosSig0(K), (eosC(I,K),I=1,9)
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
        ENDDO
      ENDIF
      CALL WRITE_1D_R8( rhonil,1, INDEX_NONE,'rhonil =',
     &'   /* Reference density ( kg/m^3 ) */')
      CALL WRITE_1D_R8( gravity,1, INDEX_NONE,'gravity =',
     &'   /* Gravitational acceleration ( m/s^2 ) */')
      CALL WRITE_1D_R8( gBaro,1, INDEX_NONE,'gBaro =',
     &'   /* Barotropic gravity ( m/s^2 ) */')
      CALL WRITE_1D_R8( f0,1, INDEX_NONE,'f0 =',
     &'   /* Reference coriolis parameter ( 1/s ) */')
      CALL WRITE_1D_R8( beta,1, INDEX_NONE,'beta =',
     &'   /* Beta ( 1/(m.s) ) */')
      CALL WRITE_1D_R8( freeSurfFac,1, INDEX_NONE,'freeSurfFac =',
     &'   /* Implcit free surface factor */')
      CALL WRITE_1D_L( implicitFreeSurface,1, INDEX_NONE,
     &                 'implicitFreeSurface =',
     &'   /* Implicit free surface on/off flag */')
      CALL WRITE_1D_L( rigidLid,1, INDEX_NONE,
     &                 'rigidLid =',
     &'   /* Rigid lid on/off flag */')
      CALL WRITE_1D_L( momStepping,1, INDEX_NONE,
     & 'momStepping =', '  /* Momentum equation on/off flag */')
      CALL WRITE_1D_L( momAdvection,1, INDEX_NONE,
     & 'momAdvection =', '  /* Momentum advection on/off flag */')
      CALL WRITE_1D_L( momViscosity,1, INDEX_NONE,
     & 'momViscosity =', '  /* Momentum viscosity on/off flag */')
      CALL WRITE_1D_L( useCoriolis,1, INDEX_NONE,
     & 'useCoriolis =', '  /* Coriolis on/off flag */')
      CALL WRITE_1D_L( momForcing,1, INDEX_NONE,
     & 'momForcing =', '  /* Momentum forcing on/off flag */')
      CALL WRITE_1D_L( momPressureForcing,1, INDEX_NONE,
     & 'momPressureForcing =',  
     & '  /* Momentum pressure term on/off flag */')
      CALL WRITE_1D_L( tempStepping,1, INDEX_NONE,
     & 'tempStepping =', '  /* Temperature equation on/off flag */')
      CALL WRITE_1D_R8( GMMaxSlope,1, INDEX_NONE,'GMMaxSlope =',
     &'   /* Max. slope allowed in GM/Redi tensor */')
      CALL WRITE_1D_R8( GMLength,1, INDEX_NONE,'GMLength =',
     &'   /* Length to use in Visbeck et al. formula for K (m) */')
      CALL WRITE_1D_R8( GMAlpha,1, INDEX_NONE,'GMAlpha =',
     &'   /* alpha to use in Visbeck et al. formula for K */')
      CALL WRITE_1D_R8( GMdepth,1, INDEX_NONE,'GMdepth =',
     &'   /* Depth to integrate for Visbeck et. al Richardson # (m) */')
      CALL WRITE_1D_R8( GMkbackground,1, INDEX_NONE,'GMkbackground =',
     &'   /* background value of GM/Redi coefficient m^2/s */')
      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)

      WRITE(msgBuf,'(A)') 
     & '// Elliptic solver(s) paramters ( PARM02 in namelist ) '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      CALL WRITE_1D_I( cg2dMaxIters,1, INDEX_NONE,'cg2dMaxIters =',
     &'   /* Upper limit on 2d con. grad iterations  */')
      CALL WRITE_1D_I( cg2dChkResFreq,1, INDEX_NONE,'cg2dChkResFreq =',
     &'   /* 2d con. grad convergence test frequency */')
      CALL WRITE_1D_R8( cg2dTargetResidual,1, INDEX_NONE,
     & 'cg2dTargetResidual =',
     &'   /* 2d con. grad target residual  */')

      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') 
     & '// Time stepping paramters ( PARM03 in namelist ) '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      CALL WRITE_1D_I( nIter0,1, INDEX_NONE,'nIter0 =',
     &'   /* Base timestep number  */')
      CALL WRITE_1D_I( nTimeSteps,1, INDEX_NONE,'nTimeSteps =',
     &'   /* Number of timesteps */')
      CALL WRITE_1D_R8( deltaTmom,1, INDEX_NONE,'deltatTmom =',
     &'   /* Momentum equation timestep ( s ) */')
      CALL WRITE_1D_R8( deltaTtracer,1, INDEX_NONE,'deltatTtracer =',
     &'   /* Tracer equation timestep ( s ) */')
      CALL WRITE_1D_R8( deltaTClock ,1, INDEX_NONE,'deltatTClock  =',
     &'   /* Model clock timestep ( s ) */')
      CALL WRITE_1D_R8( cAdjFreq,1, INDEX_NONE,'cAdjFreq =',
     &'   /* Convective adjustment interval ( s ) */')
      CALL WRITE_1D_R8( abEps,1, INDEX_NONE,'abEps =',
     &'   /* Adams-Bashforth stabilizing weight */')
      CALL WRITE_1D_R8( tauCD,1, INDEX_NONE,'tauCD =',
     &'   /* CD coupling time-scale ( s ) */')
      CALL WRITE_1D_R8( rCD,1, INDEX_NONE,'rCD =',
     &'   /* Normalised CD coupling parameter */')
      CALL WRITE_1D_R8( startTime,1, INDEX_NONE,'startTime =',
     &'   /* Run start time ( s ). */')
      CALL WRITE_1D_R8( endTime,1, INDEX_NONE,'endTime =',
     &'   /* Integration ending time ( s ). */')
      CALL WRITE_1D_R8( pChkPtFreq,1, INDEX_NONE,'pChkPtFreq =',
     &'   /* Permanent restart/checkpoint file interval ( s ). */')
      CALL WRITE_1D_R8( chkPtFreq,1, INDEX_NONE,'chkPtFreq =',
     &'   /* Rolling restart/checkpoint file interval ( s ). */')
      CALL WRITE_1D_R8( dumpFreq,1, INDEX_NONE,'dumpFreq =',
     &'   /* Model state write out interval ( s ). */')

      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') 
     & '// Gridding paramters ( PARM04 in namelist ) '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      WRITE(msgBuf,'(A)') '//  '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, 
     &                    SQUEEZE_RIGHT , 1)
      CALL WRITE_1D_L( usingCartesianGrid,1, INDEX_NONE,
     & 'usingCartesianGrid =',
     &'   /* Cartesian coordinates flag ( True / False ) */')
      CALL WRITE_1D_L( usingSphericalPolarGrid,1, INDEX_NONE,
     & 'usingSphericalPolarGrid =',
     &'   /* Spherical coordinates flag ( True / False ) */')
      CALL WRITE_1D_R8( delZ,Nr, INDEX_K,'delZ = ',
     &'   /* W spacing ( m ) */')
      CALL WRITE_1D_R8( delP,Nr, INDEX_K,'delP = ',
     &'   /* W spacing ( Pa ) */')
      CALL WRITE_1D_R8( delR,Nr, INDEX_K,'delR = ',
     &'   /* W spacing ( units of r ) */')
      CALL WRITE_1D_R8( delX, Nx, INDEX_I,'delX = ',
     &'   /* U spacing ( m - cartesian, degrees - spherical ) */')
      CALL WRITE_1D_R8( delY, Ny, INDEX_J,'delY = ',
     &'   /* V spacing ( m - cartesian, degrees - spherical ) */')
      CALL WRITE_1D_R8( phiMin, 1, INDEX_NONE,'phiMin = ',
     &'   /* South edge (ignored - cartesian, degrees - spherical ) */')
      CALL WRITE_1D_R8( thetaMin, 1, INDEX_NONE,'thetaMin = ',
     &'   /* West edge ( ignored - cartesian, degrees - spherical ) */')
      CALL WRITE_1D_R8( rSphere, 1, INDEX_NONE,'rSphere = ',
     &'   /* Radius ( ignored - cartesian, m - spherical ) */')
      DO bi=1,nSx
       DO I=1,sNx
        xcoord((bi-1)*sNx+I) = xc(I,1,bi,1)
       ENDDO
      ENDDO
      CALL WRITE_1D_R8( xcoord, sNx*nSx, INDEX_I,'xcoord = ',
     &'   /* P-point X coord ( m - cartesian, degrees - spherical ) */')
      DO bj=1,nSy
       DO J=1,sNy
        ycoord((bj-1)*sNy+J) = yc(1,J,1,bj)
       ENDDO
      ENDDO
      CALL WRITE_1D_R8( ycoord, sNy*nSy, INDEX_J,'ycoord = ',
     &'   /* P-point Y coord ( m - cartesian, degrees - spherical ) */')
      DO K=1,Nr
       rcoord(K) = rc(K)
      ENDDO
      CALL WRITE_1D_R8( rcoord, Nr, INDEX_K,'rcoord = ',
     &'   /* P-point R coordinate (  units of r ) */')


      WRITE(msgBuf,'(A)') ' '
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
     &  SQUEEZE_RIGHT , 1)

      _END_MASTER(myThid)
      _BARRIER


      RETURN
  100 FORMAT(A,
     &' '
     &)
      END

1	C $Header: /u/gcmpack/models/MITgcmUV/model/src/config_summary.F,v 1.17 1998/10/28 03:11:36 cnh Exp $
2
3	#include "CPP_OPTIONS.h"
4
5	CStartOfInterface
6	SUBROUTINE CONFIG_SUMMARY( myThid )
7	C /==========================================================\
8	C \| SUBROUTINE CONFIG_SUMMARY \|
9	C \| o Summarize model prognostic variables. \|
10	C \|==========================================================\|
11	C \| This routine writes a tabulated summary of the model \|
12	C \| configuration. \|
13	C \| Note \|
14	C \| 1. Under multi-process parallelism the summary \|
15	C \| is only given for the per-process data. \|
16	C \| 2. Under multi-threading the summary is produced by \|
17	C \| the master thread. This threads reads data managed by\|
18	C \| other threads. \|
19	C \==========================================================/
20
21	C === Global variables ===
22	#include "SIZE.h"
23	#include "EEPARAMS.h"
24	#include "PARAMS.h"
25	#include "GRID.h"
26	#include "DYNVARS.h"
27
28	C == Routine arguments ==
29	C myThid - Number of this instance of CONFIG_SUMMARY
30	INTEGER myThid
31	CEndOfInterface
32
33	C == Local variables ==
34	CHARACTER*(MAX_LEN_MBUF) msgBuf
35	INTEGER I,J,K
36	INTEGER bi, bj
37	REAL xcoord(Nx)
38	REAL ycoord(Ny)
39	REAL rcoord(Nr)
40
41
42	_BARRIER
43	_BEGIN_MASTER(myThid)
44
45	WRITE(msgBuf,'(A)')
46	&'// ======================================================='
47	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
48	& SQUEEZE_RIGHT , 1)
49	WRITE(msgBuf,'(A)') '// Model configuration'
50	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
51	& SQUEEZE_RIGHT , 1)
52	WRITE(msgBuf,'(A)')
53	&'// ======================================================='
54	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
55	& SQUEEZE_RIGHT , 1)
56
57	WRITE(msgBuf,'(A)') '// '
58	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
59	& SQUEEZE_RIGHT , 1)
60	WRITE(msgBuf,'(A)')
61	& '// "Physical" paramters ( PARM01 in namelist ) '
62	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
63	& SQUEEZE_RIGHT , 1)
64	WRITE(msgBuf,'(A)') '// '
65	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
66	& SQUEEZE_RIGHT , 1)
67	CALL WRITE_1D_R8( tRef, Nr, INDEX_K,'tRef =',
68	&' /* Reference temperature profile ( oC or oK ) */')
69	CALL WRITE_1D_R8( sRef, Nr, INDEX_K,'sRef =',
70	&' /* Reference salinity profile ( ppt ) */')
71	CALL WRITE_1D_R8( viscAh, 1, INDEX_NONE,'viscAh =',
72	&' /* Lateral eddy viscosity ( m^2/s ) */')
73	CALL WRITE_1D_R8( viscA4, 1, INDEX_NONE,'viscAh =',
74	&' /* Lateral biharmonic viscosity ( m^4/s ) */')
75	IF ( viscAz .NE. UNSET_RL ) THEN
76	CALL WRITE_1D_R8( viscAz, 1, INDEX_NONE,'viscAz =',
77	& ' /* Vertical eddy viscosity ( m^2/s ) */')
78	ENDIF
79	IF ( viscAp .NE. UNSET_RL ) THEN
80	CALL WRITE_1D_R8( viscAp, 1, INDEX_NONE,'viscAp =',
81	& ' /* Vertical eddy viscosity ( Pa^2/s ) */')
82	ENDIF
83	CALL WRITE_1D_R8( viscAr, 1, INDEX_NONE,'viscAr =',
84	&' /* Vertical eddy viscosity ( units of r^2/s ) */')
85	CALL WRITE_1D_R8( diffKhT, 1, INDEX_NONE,'diffKhT =',
86	&' /* Laplacian diffusion of heat laterally ( m^2/s ) */')
87	CALL WRITE_1D_R8( diffKzT, 1, INDEX_NONE,'diffKzT =',
88	&' /* Laplacian diffusion of heat vertically ( m^2/s ) */')
89	CALL WRITE_1D_R8( diffK4T, 1, INDEX_NONE,'diffK4T =',
90	&' /* Bihaarmonic diffusion of heat laterally ( m^4/s ) */')
91	CALL WRITE_1D_R8( diffKhS, 1, INDEX_NONE,'diffKhS =',
92	&' /* Laplacian diffusion of salt laterally ( m^2/s ) */')
93	CALL WRITE_1D_R8( diffKzS, 1, INDEX_NONE,'diffKzS =',
94	&' /* Laplacian diffusion of salt vertically ( m^2/s ) */')
95	CALL WRITE_1D_R8( diffK4S, 1, INDEX_NONE,'diffK4S =',
96	&' /* Bihaarmonic diffusion of salt laterally ( m^4/s ) */')
97	CALL WRITE_1D_R8( tAlpha,1, INDEX_NONE,'tAlpha =',
98	&' /* Linear EOS thermal expansion coefficient ( 1/degree ) */')
99	CALL WRITE_1D_R8( sBeta, 1, INDEX_NONE,'sBeta =',
100	&' /* Linear EOS haline contraction coefficient ( 1/ppt ) */')
101	IF ( eosType .EQ. 'POLY3' ) THEN
102	WRITE(msgBuf,'(A)')
103	& '// Polynomial EQS parameters ( from POLY3.COEFFS ) '
104	DO K = 1, Nr
105	WRITE(msgBuf,'(I3,13F8.3)')
106	& K,eosRefT(K),eosRefS(K),eosSig0(K), (eosC(I,K),I=1,9)
107	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
108	& SQUEEZE_RIGHT , 1)
109	ENDDO
110	ENDIF
111	CALL WRITE_1D_R8( rhonil,1, INDEX_NONE,'rhonil =',
112	&' /* Reference density ( kg/m^3 ) */')
113	CALL WRITE_1D_R8( gravity,1, INDEX_NONE,'gravity =',
114	&' /* Gravitational acceleration ( m/s^2 ) */')
115	CALL WRITE_1D_R8( gBaro,1, INDEX_NONE,'gBaro =',
116	&' /* Barotropic gravity ( m/s^2 ) */')
117	CALL WRITE_1D_R8( f0,1, INDEX_NONE,'f0 =',
118	&' /* Reference coriolis parameter ( 1/s ) */')
119	CALL WRITE_1D_R8( beta,1, INDEX_NONE,'beta =',
120	&' /* Beta ( 1/(m.s) ) */')
121	CALL WRITE_1D_R8( freeSurfFac,1, INDEX_NONE,'freeSurfFac =',
122	&' /* Implcit free surface factor */')
123	CALL WRITE_1D_L( implicitFreeSurface,1, INDEX_NONE,
124	& 'implicitFreeSurface =',
125	&' /* Implicit free surface on/off flag */')
126	CALL WRITE_1D_L( rigidLid,1, INDEX_NONE,
127	& 'rigidLid =',
128	&' /* Rigid lid on/off flag */')
129	CALL WRITE_1D_L( momStepping,1, INDEX_NONE,
130	& 'momStepping =', ' /* Momentum equation on/off flag */')
131	CALL WRITE_1D_L( momAdvection,1, INDEX_NONE,
132	& 'momAdvection =', ' /* Momentum advection on/off flag */')
133	CALL WRITE_1D_L( momViscosity,1, INDEX_NONE,
134	& 'momViscosity =', ' /* Momentum viscosity on/off flag */')
135	CALL WRITE_1D_L( useCoriolis,1, INDEX_NONE,
136	& 'useCoriolis =', ' /* Coriolis on/off flag */')
137	CALL WRITE_1D_L( momForcing,1, INDEX_NONE,
138	& 'momForcing =', ' /* Momentum forcing on/off flag */')
139	CALL WRITE_1D_L( momPressureForcing,1, INDEX_NONE,
140	& 'momPressureForcing =',
141	& ' /* Momentum pressure term on/off flag */')
142	CALL WRITE_1D_L( tempStepping,1, INDEX_NONE,
143	& 'tempStepping =', ' /* Temperature equation on/off flag */')
144	CALL WRITE_1D_R8( GMMaxSlope,1, INDEX_NONE,'GMMaxSlope =',
145	&' /* Max. slope allowed in GM/Redi tensor */')
146	CALL WRITE_1D_R8( GMLength,1, INDEX_NONE,'GMLength =',
147	&' /* Length to use in Visbeck et al. formula for K (m) */')
148	CALL WRITE_1D_R8( GMAlpha,1, INDEX_NONE,'GMAlpha =',
149	&' /* alpha to use in Visbeck et al. formula for K */')
150	CALL WRITE_1D_R8( GMdepth,1, INDEX_NONE,'GMdepth =',
151	&' /* Depth to integrate for Visbeck et. al Richardson # (m) */')
152	CALL WRITE_1D_R8( GMkbackground,1, INDEX_NONE,'GMkbackground =',
153	&' /* background value of GM/Redi coefficient m^2/s */')
154	WRITE(msgBuf,'(A)') '// '
155	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
156	& SQUEEZE_RIGHT , 1)
157
158	WRITE(msgBuf,'(A)')
159	& '// Elliptic solver(s) paramters ( PARM02 in namelist ) '
160	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
161	& SQUEEZE_RIGHT , 1)
162	WRITE(msgBuf,'(A)') '// '
163	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
164	& SQUEEZE_RIGHT , 1)
165	CALL WRITE_1D_I( cg2dMaxIters,1, INDEX_NONE,'cg2dMaxIters =',
166	&' /* Upper limit on 2d con. grad iterations */')
167	CALL WRITE_1D_I( cg2dChkResFreq,1, INDEX_NONE,'cg2dChkResFreq =',
168	&' /* 2d con. grad convergence test frequency */')
169	CALL WRITE_1D_R8( cg2dTargetResidual,1, INDEX_NONE,
170	& 'cg2dTargetResidual =',
171	&' /* 2d con. grad target residual */')
172
173	WRITE(msgBuf,'(A)') '// '
174	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
175	& SQUEEZE_RIGHT , 1)
176	WRITE(msgBuf,'(A)')
177	& '// Time stepping paramters ( PARM03 in namelist ) '
178	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
179	& SQUEEZE_RIGHT , 1)
180	WRITE(msgBuf,'(A)') '// '
181	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
182	& SQUEEZE_RIGHT , 1)
183	CALL WRITE_1D_I( nIter0,1, INDEX_NONE,'nIter0 =',
184	&' /* Base timestep number */')
185	CALL WRITE_1D_I( nTimeSteps,1, INDEX_NONE,'nTimeSteps =',
186	&' /* Number of timesteps */')
187	CALL WRITE_1D_R8( deltaTmom,1, INDEX_NONE,'deltatTmom =',
188	&' /* Momentum equation timestep ( s ) */')
189	CALL WRITE_1D_R8( deltaTtracer,1, INDEX_NONE,'deltatTtracer =',
190	&' /* Tracer equation timestep ( s ) */')
191	CALL WRITE_1D_R8( deltaTClock ,1, INDEX_NONE,'deltatTClock =',
192	&' /* Model clock timestep ( s ) */')
193	CALL WRITE_1D_R8( cAdjFreq,1, INDEX_NONE,'cAdjFreq =',
194	&' /* Convective adjustment interval ( s ) */')
195	CALL WRITE_1D_R8( abEps,1, INDEX_NONE,'abEps =',
196	&' /* Adams-Bashforth stabilizing weight */')
197	CALL WRITE_1D_R8( tauCD,1, INDEX_NONE,'tauCD =',
198	&' /* CD coupling time-scale ( s ) */')
199	CALL WRITE_1D_R8( rCD,1, INDEX_NONE,'rCD =',
200	&' /* Normalised CD coupling parameter */')
201	CALL WRITE_1D_R8( startTime,1, INDEX_NONE,'startTime =',
202	&' /* Run start time ( s ). */')
203	CALL WRITE_1D_R8( endTime,1, INDEX_NONE,'endTime =',
204	&' /* Integration ending time ( s ). */')
205	CALL WRITE_1D_R8( pChkPtFreq,1, INDEX_NONE,'pChkPtFreq =',
206	&' /* Permanent restart/checkpoint file interval ( s ). */')
207	CALL WRITE_1D_R8( chkPtFreq,1, INDEX_NONE,'chkPtFreq =',
208	&' /* Rolling restart/checkpoint file interval ( s ). */')
209	CALL WRITE_1D_R8( dumpFreq,1, INDEX_NONE,'dumpFreq =',
210	&' /* Model state write out interval ( s ). */')
211
212	WRITE(msgBuf,'(A)') '// '
213	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
214	& SQUEEZE_RIGHT , 1)
215	WRITE(msgBuf,'(A)')
216	& '// Gridding paramters ( PARM04 in namelist ) '
217	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
218	& SQUEEZE_RIGHT , 1)
219	WRITE(msgBuf,'(A)') '// '
220	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
221	& SQUEEZE_RIGHT , 1)
222	CALL WRITE_1D_L( usingCartesianGrid,1, INDEX_NONE,
223	& 'usingCartesianGrid =',
224	&' /* Cartesian coordinates flag ( True / False ) */')
225	CALL WRITE_1D_L( usingSphericalPolarGrid,1, INDEX_NONE,
226	& 'usingSphericalPolarGrid =',
227	&' /* Spherical coordinates flag ( True / False ) */')
228	CALL WRITE_1D_R8( delZ,Nr, INDEX_K,'delZ = ',
229	&' /* W spacing ( m ) */')
230	CALL WRITE_1D_R8( delP,Nr, INDEX_K,'delP = ',
231	&' /* W spacing ( Pa ) */')
232	CALL WRITE_1D_R8( delR,Nr, INDEX_K,'delR = ',
233	&' /* W spacing ( units of r ) */')
234	CALL WRITE_1D_R8( delX, Nx, INDEX_I,'delX = ',
235	&' /* U spacing ( m - cartesian, degrees - spherical ) */')
236	CALL WRITE_1D_R8( delY, Ny, INDEX_J,'delY = ',
237	&' /* V spacing ( m - cartesian, degrees - spherical ) */')
238	CALL WRITE_1D_R8( phiMin, 1, INDEX_NONE,'phiMin = ',
239	&' /* South edge (ignored - cartesian, degrees - spherical ) */')
240	CALL WRITE_1D_R8( thetaMin, 1, INDEX_NONE,'thetaMin = ',
241	&' /* West edge ( ignored - cartesian, degrees - spherical ) */')
242	CALL WRITE_1D_R8( rSphere, 1, INDEX_NONE,'rSphere = ',
243	&' /* Radius ( ignored - cartesian, m - spherical ) */')
244	DO bi=1,nSx
245	DO I=1,sNx
246	xcoord((bi-1)*sNx+I) = xc(I,1,bi,1)
247	ENDDO
248	ENDDO
249	CALL WRITE_1D_R8( xcoord, sNx*nSx, INDEX_I,'xcoord = ',
250	&' /* P-point X coord ( m - cartesian, degrees - spherical ) */')
251	DO bj=1,nSy
252	DO J=1,sNy
253	ycoord((bj-1)*sNy+J) = yc(1,J,1,bj)
254	ENDDO
255	ENDDO
256	CALL WRITE_1D_R8( ycoord, sNy*nSy, INDEX_J,'ycoord = ',
257	&' /* P-point Y coord ( m - cartesian, degrees - spherical ) */')
258	DO K=1,Nr
259	rcoord(K) = rc(K)
260	ENDDO
261	CALL WRITE_1D_R8( rcoord, Nr, INDEX_K,'rcoord = ',
262	&' /* P-point R coordinate ( units of r ) */')
263
264
265
266	WRITE(msgBuf,'(A)') ' '
267	CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
268	& SQUEEZE_RIGHT , 1)
269
270	_END_MASTER(myThid)
271	_BARRIER
272
273
274	RETURN
275	100 FORMAT(A,
276	&' '
277	&)
278	END
279