1 |
C $Header: /u/gcmpack/MITgcm/model/src/config_summary.F,v 1.91 2006/07/13 02:58:03 jmc Exp $ |
2 |
C $Name: $ |
3 |
|
4 |
#include "PACKAGES_CONFIG.h" |
5 |
#include "CPP_OPTIONS.h" |
6 |
|
7 |
C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-|--+----| |
8 |
CBOP |
9 |
C !ROUTINE: CONFIG_SUMMARY |
10 |
|
11 |
C !INTERFACE: |
12 |
SUBROUTINE CONFIG_SUMMARY( myThid ) |
13 |
|
14 |
C !DESCRIPTION: |
15 |
C This routine summarizes the model parameter settings by writing a |
16 |
C tabulated list of the kernel model configuration variables. It |
17 |
C describes all the parameter settings in force and the meaning and |
18 |
C units of those parameters. Individal packages report a similar |
19 |
C table for each package using the same format as employed here. If |
20 |
C parameters are missing or incorrectly described or dimensioned |
21 |
C please contact <MITgcm-support@mitgcm.org> |
22 |
|
23 |
C !USES: |
24 |
IMPLICIT NONE |
25 |
#include "SIZE.h" |
26 |
#include "EEPARAMS.h" |
27 |
#include "PARAMS.h" |
28 |
#include "EOS.h" |
29 |
#include "GRID.h" |
30 |
#include "DYNVARS.h" |
31 |
#ifdef ALLOW_MNC |
32 |
#include "MNC_PARAMS.h" |
33 |
#endif |
34 |
|
35 |
C !INPUT/OUTPUT PARAMETERS: |
36 |
C myThid :: Number of this instance of CONFIG_SUMMARY |
37 |
INTEGER myThid |
38 |
CEOP |
39 |
|
40 |
C !LOCAL VARIABLES: |
41 |
C msgBuf :: Temp. for building output string. |
42 |
C I,J,K :: Loop counters. |
43 |
C bi,bj :: Tile loop counters. |
44 |
C xcoord :: Temps. for building lists of values for uni-dimensionally |
45 |
C ycoord :: varying parameters. |
46 |
C zcoord :: |
47 |
CHARACTER*(MAX_LEN_MBUF) msgBuf |
48 |
INTEGER I,J,K |
49 |
INTEGER bi, bj |
50 |
_RL xcoord(Nx) |
51 |
_RL ycoord(Ny) |
52 |
_RL rcoord(Nr+1) |
53 |
INTEGER coordLine |
54 |
INTEGER tileLine |
55 |
|
56 |
|
57 |
_BARRIER |
58 |
_BEGIN_MASTER(myThid) |
59 |
|
60 |
WRITE(msgBuf,'(A)') |
61 |
&'// =======================================================' |
62 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
63 |
& SQUEEZE_RIGHT, myThid ) |
64 |
WRITE(msgBuf,'(A)') '// Model configuration' |
65 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
66 |
& SQUEEZE_RIGHT, myThid ) |
67 |
WRITE(msgBuf,'(A)') |
68 |
&'// =======================================================' |
69 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
70 |
& SQUEEZE_RIGHT, myThid ) |
71 |
|
72 |
WRITE(msgBuf,'(A)') '// ' |
73 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
74 |
& SQUEEZE_RIGHT, myThid ) |
75 |
WRITE(msgBuf,'(A)') |
76 |
& '// "Physical" paramters ( PARM01 in namelist ) ' |
77 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
78 |
& SQUEEZE_RIGHT, myThid ) |
79 |
WRITE(msgBuf,'(A)') '// ' |
80 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
81 |
& SQUEEZE_RIGHT, myThid ) |
82 |
WRITE(msgBuf,'(A,A40)') 'buoyancyRelation = ', buoyancyRelation |
83 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
84 |
& SQUEEZE_RIGHT, myThid ) |
85 |
CALL WRITE_0D_L( fluidIsAir, INDEX_NONE, |
86 |
& 'fluidIsAir =', ' /* fluid major constituent is Air */') |
87 |
CALL WRITE_0D_L( fluidIsWater, INDEX_NONE, |
88 |
& 'fluidIsWater=', ' /* fuild major constituent is Water */') |
89 |
CALL WRITE_0D_L( usingPCoords, INDEX_NONE, |
90 |
& 'usingPCoords =', ' /* use p (or p*) vertical coordinate */') |
91 |
CALL WRITE_0D_L( usingZCoords, INDEX_NONE, |
92 |
& 'usingZCoords =', ' /* use z (or z*) vertical coordinate */') |
93 |
CALL WRITE_1D_R8( tRef, Nr, INDEX_K,'tRef =', |
94 |
&' /* Reference temperature profile ( oC or K ) */') |
95 |
CALL WRITE_1D_R8( sRef, Nr, INDEX_K,'sRef =', |
96 |
&' /* Reference salinity profile ( psu ) */') |
97 |
CALL WRITE_0D_R8( viscAh, INDEX_NONE,'viscAh =', |
98 |
&' /* Lateral eddy viscosity ( m^2/s ) */') |
99 |
IF ( viscAhD.NE.viscAh ) |
100 |
& CALL WRITE_0D_R8( viscAhD, INDEX_NONE,'viscAhD =', |
101 |
& ' /* Lateral eddy viscosity (Divergence)( m^2/s ) */') |
102 |
IF ( viscAhZ.NE.viscAh ) |
103 |
& CALL WRITE_0D_R8( viscAhZ, INDEX_NONE,'viscAhZ =', |
104 |
& ' /* Lateral eddy viscosity (Vorticity) ( m^2/s ) */') |
105 |
CALL WRITE_0D_R8( viscAhMax, INDEX_NONE,'viscAhMax =', |
106 |
&' /* Maximum lateral eddy viscosity ( m^2/s ) */') |
107 |
CALL WRITE_0D_R8( viscAhGrid, INDEX_NONE,'viscAhGrid =', |
108 |
&' /* Grid dependent lateral eddy viscosity ( non-dim. ) */') |
109 |
CALL WRITE_0D_L( useFullLeith, INDEX_NONE, |
110 |
&'useFullLeith =', |
111 |
&' /* Use Full Form of Leith Viscosity on/off flag*/') |
112 |
CALL WRITE_0D_L( useStrainTensionVisc, INDEX_NONE, |
113 |
&'useStrainTensionVisc =', |
114 |
&' /* Use StrainTension Form of Viscous Operator on/off flag*/') |
115 |
CALL WRITE_0D_L( useAreaViscLength, INDEX_NONE, |
116 |
&'useAreaViscLength =', |
117 |
&' /* Use area for visc length instead of geom. mean*/') |
118 |
CALL WRITE_0D_R8( viscC2leith, INDEX_NONE,'viscC2leith =', |
119 |
&' /* Leith harmonic visc. factor (on grad(vort),non-dim.) */') |
120 |
CALL WRITE_0D_R8( viscC2leithD, INDEX_NONE,'viscC2leithD =', |
121 |
&' /* Leith harmonic viscosity factor (on grad(div),non-dim.) */') |
122 |
CALL WRITE_0D_R8( viscC2smag, INDEX_NONE,'viscC2smag =', |
123 |
&' /* Smagorinsky harmonic viscosity factor (non-dim.) */') |
124 |
CALL WRITE_0D_R8( viscA4, INDEX_NONE,'viscA4 =', |
125 |
&' /* Lateral biharmonic viscosity ( m^4/s ) */') |
126 |
IF ( viscA4D.NE.viscA4 ) |
127 |
& CALL WRITE_0D_R8( viscA4D, INDEX_NONE,'viscA4D =', |
128 |
& ' /* Lateral biharmonic viscosity (Divergence)( m^4/s ) */') |
129 |
IF ( viscA4Z.NE.viscA4 ) |
130 |
& CALL WRITE_0D_R8( viscA4Z, INDEX_NONE,'viscA4Z =', |
131 |
& ' /* Lateral biharmonic viscosity (Vorticity) ( m^4/s ) */') |
132 |
CALL WRITE_0D_R8( viscA4Max, INDEX_NONE,'viscA4Max =', |
133 |
&' /* Maximum biharmonic viscosity ( m^2/s ) */') |
134 |
CALL WRITE_0D_R8( viscA4Grid, INDEX_NONE,'viscA4Grid =', |
135 |
&' /* Grid dependent biharmonic viscosity ( non-dim. ) */') |
136 |
CALL WRITE_0D_R8( viscC4leith, INDEX_NONE,'viscC4leith =', |
137 |
&' /* Leith biharm viscosity factor (on grad(vort), non-dim.) */') |
138 |
CALL WRITE_0D_R8( viscC4leithD, INDEX_NONE,'viscC4leithD =', |
139 |
&' /* Leith biharm viscosity factor (on grad(div), non-dim.) */') |
140 |
CALL WRITE_0D_R8( viscC4Smag, INDEX_NONE,'viscC4Smag =', |
141 |
&' /* Smagorinsky biharm viscosity factor (non-dim) */') |
142 |
CALL WRITE_0D_L( no_slip_sides, INDEX_NONE, |
143 |
& 'no_slip_sides =', ' /* Viscous BCs: No-slip sides */') |
144 |
CALL WRITE_0D_R8( sideDragFactor, INDEX_NONE, 'sideDragFactor =', |
145 |
& ' /* side-drag scaling factor (non-dim) */') |
146 |
CALL WRITE_0D_R8( viscAr, INDEX_NONE,'viscAr =', |
147 |
&' /* Vertical eddy viscosity ( units of r^2/s ) */') |
148 |
CALL WRITE_0D_L( no_slip_bottom, INDEX_NONE, |
149 |
& 'no_slip_bottom =', ' /* Viscous BCs: No-slip bottom */') |
150 |
CALL WRITE_0D_R8( bottomDragLinear, INDEX_NONE, |
151 |
& 'bottomDragLinear =', |
152 |
& ' /* linear bottom-drag coefficient ( 1/s ) */') |
153 |
CALL WRITE_0D_R8( bottomDragQuadratic, INDEX_NONE, |
154 |
& 'bottomDragQuadratic =', |
155 |
& ' /* quadratic bottom-drag coeff. ( 1/m ) */') |
156 |
CALL WRITE_0D_R8( diffKhT, INDEX_NONE,'diffKhT =', |
157 |
&' /* Laplacian diffusion of heat laterally ( m^2/s ) */') |
158 |
CALL WRITE_0D_R8( diffK4T, INDEX_NONE,'diffK4T =', |
159 |
&' /* Bihaarmonic diffusion of heat laterally ( m^4/s ) */') |
160 |
CALL WRITE_0D_R8( diffKhS, INDEX_NONE,'diffKhS =', |
161 |
&' /* Laplacian diffusion of salt laterally ( m^2/s ) */') |
162 |
CALL WRITE_0D_R8( diffK4S, INDEX_NONE,'diffK4S =', |
163 |
&' /* Bihaarmonic diffusion of salt laterally ( m^4/s ) */') |
164 |
CALL WRITE_1D_R8( diffKrNrT, Nr, INDEX_K,'diffKrNrT =', |
165 |
& ' /* vertical profile of vertical diffusion of Temp ( m^2/s )*/') |
166 |
CALL WRITE_1D_R8( diffKrNrS, Nr, INDEX_K,'diffKrNrS =', |
167 |
& ' /* vertical profile of vertical diffusion of Salt ( m^2/s )*/') |
168 |
CALL WRITE_0D_R8( diffKrBL79surf, INDEX_NONE,'diffKrBL79surf =', |
169 |
&' /* Surface diffusion for Bryan and Lewis 1979 ( m^2/s ) */') |
170 |
CALL WRITE_0D_R8( diffKrBL79deep, INDEX_NONE,'diffKrBL79deep =', |
171 |
&' /* Deep diffusion for Bryan and Lewis 1979 ( m^2/s ) */') |
172 |
CALL WRITE_0D_R8( diffKrBL79scl, INDEX_NONE,'diffKrBL79scl =', |
173 |
&' /* Depth scale for Bryan and Lewis 1979 ( m ) */') |
174 |
CALL WRITE_0D_R8( diffKrBL79Ho, INDEX_NONE,'diffKrBL79Ho =', |
175 |
&' /* Turning depth for Bryan and Lewis 1979 ( m ) */') |
176 |
c WRITE(msgBuf,'(2A)') ' Equation of State : eosType = ', eosType |
177 |
WRITE(msgBuf,'(4A)') 'Equation of State : ', |
178 |
& 'eosType = ', eosType, ' ;' |
179 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
180 |
& SQUEEZE_RIGHT, myThid ) |
181 |
CALL WRITE_0D_R8( tAlpha, INDEX_NONE,'tAlpha =', |
182 |
&' /* Linear EOS thermal expansion coefficient ( 1/oC ) */') |
183 |
CALL WRITE_0D_R8( sBeta, INDEX_NONE,'sBeta =', |
184 |
&' /* Linear EOS haline contraction coefficient ( 1/psu ) */') |
185 |
IF ( eosType .EQ. 'POLY3' ) THEN |
186 |
WRITE(msgBuf,'(A)') |
187 |
& '// Polynomial EQS parameters ( from POLY3.COEFFS ) ' |
188 |
DO K = 1, Nr |
189 |
WRITE(msgBuf,'(I3,13F8.3)') |
190 |
& K,eosRefT(K),eosRefS(K),eosSig0(K), (eosC(I,K),I=1,9) |
191 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
192 |
& SQUEEZE_RIGHT, myThid ) |
193 |
ENDDO |
194 |
ENDIF |
195 |
IF ( fluidIsAir ) THEN |
196 |
CALL WRITE_0D_R8( atm_Rd, INDEX_NONE, 'atm_Rd =', |
197 |
& ' /* gas constant for dry air ( J/kg/K ) */') |
198 |
CALL WRITE_0D_R8( atm_Cp, INDEX_NONE, 'atm_Cp =', |
199 |
& ' /* specific heat (Cp) of dry air ( J/kg/K ) */') |
200 |
CALL WRITE_0D_R8( atm_kappa, INDEX_NONE, 'atm_kappa =', |
201 |
& ' /* kappa (=Rd/Cp ) of dry air */') |
202 |
CALL WRITE_0D_R8( atm_Rq, INDEX_NONE, 'atm_Rq =', |
203 |
& ' /* water vap. specific vol. anomaly relative to dry air */') |
204 |
CALL WRITE_0D_R8( atm_Po, INDEX_NONE, 'atm_Po =', |
205 |
& ' /* standard reference pressure ( Pa ) */') |
206 |
CALL WRITE_0D_I( integr_GeoPot, INDEX_NONE, 'integr_GeoPot =', |
207 |
& ' /* select how the geopotential is integrated */') |
208 |
CALL WRITE_0D_I( selectFindRoSurf, INDEX_NONE, |
209 |
& 'selectFindRoSurf=', |
210 |
& ' /* select how Surf.Ref. pressure is defined */') |
211 |
ENDIF |
212 |
CALL WRITE_0D_R8( rhonil, INDEX_NONE,'rhonil =', |
213 |
&' /* Reference density ( kg/m^3 ) */') |
214 |
CALL WRITE_0D_R8( rhoConst, INDEX_NONE,'rhoConst =', |
215 |
&' /* Reference density ( kg/m^3 ) */') |
216 |
CALL WRITE_0D_R8( rhoConstFresh, INDEX_NONE,'rhoConstFresh =', |
217 |
&' /* Reference density ( kg/m^3 ) */') |
218 |
CALL WRITE_0D_R8( gravity, INDEX_NONE,'gravity =', |
219 |
&' /* Gravitational acceleration ( m/s^2 ) */') |
220 |
CALL WRITE_0D_R8( gBaro, INDEX_NONE,'gBaro =', |
221 |
&' /* Barotropic gravity ( m/s^2 ) */') |
222 |
CALL WRITE_0D_R8(rotationPeriod,INDEX_NONE,'rotationPeriod =', |
223 |
&' /* Rotation Period ( s ) */') |
224 |
CALL WRITE_0D_R8( omega, INDEX_NONE,'omega =', |
225 |
&' /* Angular velocity ( rad/s ) */') |
226 |
CALL WRITE_0D_R8( f0, INDEX_NONE,'f0 =', |
227 |
&' /* Reference coriolis parameter ( 1/s ) */') |
228 |
CALL WRITE_0D_R8( beta, INDEX_NONE,'beta =', |
229 |
&' /* Beta ( 1/(m.s) ) */') |
230 |
CALL WRITE_0D_R8( freeSurfFac, INDEX_NONE,'freeSurfFac =', |
231 |
&' /* Implicit free surface factor */') |
232 |
CALL WRITE_0D_L( implicitFreeSurface, INDEX_NONE, |
233 |
& 'implicitFreeSurface =', |
234 |
&' /* Implicit free surface on/off flag */') |
235 |
CALL WRITE_0D_L( rigidLid, INDEX_NONE, |
236 |
& 'rigidLid =', |
237 |
&' /* Rigid lid on/off flag */') |
238 |
CALL WRITE_0D_R8( implicSurfPress, INDEX_NONE, |
239 |
&'implicSurfPress =', |
240 |
&' /* Surface Pressure implicit factor (0-1)*/') |
241 |
CALL WRITE_0D_R8( implicDiv2Dflow, INDEX_NONE, |
242 |
&'implicDiv2Dflow =', |
243 |
&' /* Barot. Flow Div. implicit factor (0-1)*/') |
244 |
CALL WRITE_0D_L( exactConserv, INDEX_NONE, |
245 |
&'exactConserv =', |
246 |
&' /* Exact Volume Conservation on/off flag*/') |
247 |
CALL WRITE_0D_L( uniformLin_PhiSurf, INDEX_NONE, |
248 |
&'uniformLin_PhiSurf =', |
249 |
&' /* use uniform Bo_surf on/off flag*/') |
250 |
CALL WRITE_0D_I( nonlinFreeSurf, INDEX_NONE, |
251 |
&'nonlinFreeSurf =', |
252 |
&' /* Non-linear Free Surf. options (-1,0,1,2,3)*/') |
253 |
WRITE(msgBuf,'(2A)') ' -1,0= Off ; 1,2,3= On,', |
254 |
& ' 2=+rescale gU,gV, 3=+update cg2d solv.' |
255 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
256 |
& SQUEEZE_RIGHT, myThid ) |
257 |
CALL WRITE_0D_R8( hFacInf, INDEX_NONE, |
258 |
&'hFacInf =', |
259 |
&' /* lower threshold for hFac (nonlinFreeSurf only)*/') |
260 |
CALL WRITE_0D_R8( hFacSup, INDEX_NONE, |
261 |
&'hFacSup =', |
262 |
&' /* upper threshold for hFac (nonlinFreeSurf only)*/') |
263 |
CALL WRITE_0D_I( select_rStar, INDEX_NONE, |
264 |
&'select_rStar =', |
265 |
&' /* r* Coordinate options (not yet implemented)*/') |
266 |
CALL WRITE_0D_L( useRealFreshWaterFlux, INDEX_NONE, |
267 |
&'useRealFreshWaterFlux =', |
268 |
&' /* Real Fresh Water Flux on/off flag*/') |
269 |
IF (useRealFreshWaterFlux .AND. nonlinFreeSurf.GT.0) THEN |
270 |
CALL WRITE_0D_R8( temp_EvPrRn, INDEX_NONE, |
271 |
&'temp_EvPrRn =', |
272 |
&' /* Temp. of Evap/Prec/R (UNSET=use local T)(oC)*/') |
273 |
CALL WRITE_0D_R8( salt_EvPrRn, INDEX_NONE, |
274 |
&'salt_EvPrRn =', |
275 |
&' /* Salin. of Evap/Prec/R (UNSET=use local S)(ppt)*/') |
276 |
ELSE |
277 |
CALL WRITE_0D_R8( convertFW2Salt, INDEX_NONE, |
278 |
&'convertFW2Salt =', |
279 |
&' /* convert F.W. Flux to Salt Flux (-1=use local S)(ppt)*/') |
280 |
ENDIF |
281 |
|
282 |
CALL WRITE_0D_L( use3Dsolver, INDEX_NONE, |
283 |
& 'use3Dsolver =', ' /* use 3-D pressure solver on/off flag */') |
284 |
CALL WRITE_0D_L( nonHydrostatic, INDEX_NONE, |
285 |
& 'nonHydrostatic =', ' /* Non-Hydrostatic on/off flag */') |
286 |
CALL WRITE_0D_R8( nh_Am2, INDEX_NONE, 'nh_Am2 =', |
287 |
& ' /* Non-Hydrostatic terms scaling factor */') |
288 |
CALL WRITE_0D_L( quasiHydrostatic, INDEX_NONE, |
289 |
& 'quasiHydrostatic =', ' /* Quasi-Hydrostatic on/off flag */') |
290 |
CALL WRITE_0D_L( momStepping, INDEX_NONE, |
291 |
& 'momStepping =', ' /* Momentum equation on/off flag */') |
292 |
CALL WRITE_0D_L( vectorInvariantMomentum, INDEX_NONE, |
293 |
& 'vectorInvariantMomentum=', |
294 |
& ' /* Vector-Invariant Momentum on/off */') |
295 |
CALL WRITE_0D_L( momAdvection, INDEX_NONE, |
296 |
& 'momAdvection =', ' /* Momentum advection on/off flag */') |
297 |
CALL WRITE_0D_L( momViscosity, INDEX_NONE, |
298 |
& 'momViscosity =', ' /* Momentum viscosity on/off flag */') |
299 |
CALL WRITE_0D_L( momImplVertAdv, INDEX_NONE, 'momImplVertAdv =', |
300 |
& '/* Momentum implicit vert. advection on/off*/') |
301 |
CALL WRITE_0D_L( implicitViscosity, INDEX_NONE, |
302 |
& 'implicitViscosity =', ' /* Implicit viscosity on/off flag */') |
303 |
CALL WRITE_0D_L( metricTerms, INDEX_NONE, 'metricTerms =', |
304 |
& ' /* metric-Terms on/off flag */') |
305 |
CALL WRITE_0D_L( useNHMTerms, INDEX_NONE, 'useNHMTerms =', |
306 |
& ' /* Non-Hydrostatic Metric-Terms on/off */') |
307 |
CALL WRITE_0D_L( useConstantF, INDEX_NONE, |
308 |
& 'useConstantF =', ' /* use Constant f0 Coriolis flag */') |
309 |
CALL WRITE_0D_L( useBetaPlaneF, INDEX_NONE, |
310 |
& 'useBetaPlaneF =', ' /* use Beta-Plane Coriolis flag */') |
311 |
CALL WRITE_0D_L( useSphereF, INDEX_NONE, |
312 |
& 'useSphereF =', ' /* use Spherical Coriolis flag */') |
313 |
CALL WRITE_0D_L( use3dCoriolis, INDEX_NONE, |
314 |
& 'use3dCoriolis =', ' /* 3-D Coriolis on/off flag */') |
315 |
CALL WRITE_0D_L( useCoriolis, INDEX_NONE, |
316 |
& 'useCoriolis =', ' /* Coriolis on/off flag */') |
317 |
CALL WRITE_0D_L( useCDscheme, INDEX_NONE, |
318 |
& 'useCDscheme =', ' /* CD scheme on/off flag */') |
319 |
CALL WRITE_0D_L( useJamartWetPoints, INDEX_NONE, |
320 |
& 'useJamartWetPoints=',' /* Coriolis WetPoints method flag */') |
321 |
CALL WRITE_0D_L( useJamartMomAdv, INDEX_NONE, |
322 |
& 'useJamartMomAdv=',' /* V.I. Non-linear terms Jamart flag */') |
323 |
CALL WRITE_0D_L( SadournyCoriolis, INDEX_NONE, |
324 |
& 'SadournyCoriolis=',' /* Sadourny Coriolis discr. flag */') |
325 |
CALL WRITE_0D_L( upwindVorticity, INDEX_NONE, |
326 |
& 'upwindVorticity=',' /* Upwind bias vorticity flag */') |
327 |
CALL WRITE_0D_L( useAbsVorticity, INDEX_NONE, |
328 |
& 'useAbsVorticity=',' /* Work with f+zeta in Coriolis */') |
329 |
CALL WRITE_0D_L( highOrderVorticity, INDEX_NONE, |
330 |
& 'highOrderVorticity=',' /* High order interp. of vort. flag */') |
331 |
CALL WRITE_0D_L( upwindShear, INDEX_NONE, |
332 |
& 'upwindShear=', ' /* Upwind vertical Shear advection flag */') |
333 |
CALL WRITE_0D_I( selectKEscheme, INDEX_NONE, |
334 |
& 'selectKEscheme=', ' /* Kinetic Energy scheme selector */') |
335 |
CALL WRITE_0D_L( momForcing, INDEX_NONE, |
336 |
& 'momForcing =', ' /* Momentum forcing on/off flag */') |
337 |
CALL WRITE_0D_L( momPressureForcing, INDEX_NONE, |
338 |
& 'momPressureForcing =', |
339 |
& ' /* Momentum pressure term on/off flag */') |
340 |
CALL WRITE_0D_L( implicitIntGravWave, INDEX_NONE, |
341 |
& 'implicitIntGravWave=', |
342 |
& ' /* Implicit Internal Gravity Wave flag */') |
343 |
CALL WRITE_0D_L( staggerTimeStep, INDEX_NONE, |
344 |
& 'staggerTimeStep =', |
345 |
&' /* Stagger time stepping on/off flag */') |
346 |
CALL WRITE_0D_L( multiDimAdvection, INDEX_NONE, |
347 |
& 'multiDimAdvection =', |
348 |
&' /* enable/disable Multi-Dim Advection */') |
349 |
CALL WRITE_0D_L( useMultiDimAdvec, INDEX_NONE, |
350 |
& 'useMultiDimAdvec =', |
351 |
&' /* Multi-Dim Advection is/is-not used */') |
352 |
CALL WRITE_0D_L( implicitDiffusion, INDEX_NONE, |
353 |
& 'implicitDiffusion =','/* Implicit Diffusion on/off flag */') |
354 |
CALL WRITE_0D_L( tempStepping, INDEX_NONE, |
355 |
& 'tempStepping =', ' /* Temperature equation on/off flag */') |
356 |
CALL WRITE_0D_L( tempAdvection, INDEX_NONE, |
357 |
& 'tempAdvection=', ' /* Temperature advection on/off flag */') |
358 |
CALL WRITE_0D_L( tempImplVertAdv,INDEX_NONE,'tempImplVertAdv =', |
359 |
& '/* Temp. implicit vert. advection on/off */') |
360 |
CALL WRITE_0D_L( tempForcing, INDEX_NONE, |
361 |
& 'tempForcing =', ' /* Temperature forcing on/off flag */') |
362 |
CALL WRITE_0D_L( saltStepping, INDEX_NONE, |
363 |
& 'saltStepping =', ' /* Salinity equation on/off flag */') |
364 |
CALL WRITE_0D_L( saltAdvection, INDEX_NONE, |
365 |
& 'saltAdvection=', ' /* Salinity advection on/off flag */') |
366 |
CALL WRITE_0D_L( saltImplVertAdv,INDEX_NONE,'saltImplVertAdv =', |
367 |
& '/* Sali. implicit vert. advection on/off */') |
368 |
CALL WRITE_0D_L( saltForcing, INDEX_NONE, |
369 |
& 'saltForcing =', ' /* Salinity forcing on/off flag */') |
370 |
CALL WRITE_0D_I( readBinaryPrec, INDEX_NONE, ' readBinaryPrec =', |
371 |
& ' /* Precision used for reading binary files */') |
372 |
CALL WRITE_0D_I(writeBinaryPrec, INDEX_NONE, 'writeBinaryPrec =', |
373 |
& ' /* Precision used for writing binary files */') |
374 |
CALL WRITE_0D_L( globalFiles, INDEX_NONE, |
375 |
& ' globalFiles =',' /* write "global" (=not per tile) files */') |
376 |
CALL WRITE_0D_L( useSingleCpuIO, INDEX_NONE, |
377 |
& ' useSingleCpuIO =', ' /* only master MPI process does I/O */') |
378 |
CALL WRITE_0D_L( debugMode, INDEX_NONE, |
379 |
& ' debugMode =', ' /* Debug Mode on/off flag */') |
380 |
CALL WRITE_0D_I( debLevA, INDEX_NONE, |
381 |
& ' debLevA =', ' /* 1rst level of debugging */') |
382 |
CALL WRITE_0D_I( debLevB, INDEX_NONE, |
383 |
& ' debLevB =', ' /* 2nd level of debugging */') |
384 |
CALL WRITE_0D_I( debugLevel, INDEX_NONE, |
385 |
& ' debugLevel =', ' /* select debugging level */') |
386 |
WRITE(msgBuf,'(A)') '// ' |
387 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
388 |
& SQUEEZE_RIGHT, myThid ) |
389 |
|
390 |
WRITE(msgBuf,'(A)') |
391 |
& '// Elliptic solver(s) paramters ( PARM02 in namelist ) ' |
392 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
393 |
& SQUEEZE_RIGHT, myThid ) |
394 |
WRITE(msgBuf,'(A)') '// ' |
395 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
396 |
& SQUEEZE_RIGHT, myThid ) |
397 |
CALL WRITE_0D_I( cg2dMaxIters, INDEX_NONE,'cg2dMaxIters =', |
398 |
&' /* Upper limit on 2d con. grad iterations */') |
399 |
CALL WRITE_0D_I( cg2dChkResFreq, INDEX_NONE,'cg2dChkResFreq =', |
400 |
&' /* 2d con. grad convergence test frequency */') |
401 |
CALL WRITE_0D_R8( cg2dTargetResidual, INDEX_NONE, |
402 |
& 'cg2dTargetResidual =', |
403 |
&' /* 2d con. grad target residual */') |
404 |
CALL WRITE_0D_R8( cg2dTargetResWunit, INDEX_NONE, |
405 |
& 'cg2dTargetResWunit =', |
406 |
&' /* CG2d target residual [W units] */') |
407 |
CALL WRITE_0D_I( cg2dPreCondFreq, INDEX_NONE,'cg2dPreCondFreq =', |
408 |
&' /* Freq. for updating cg2d preconditioner */') |
409 |
|
410 |
WRITE(msgBuf,'(A)') '// ' |
411 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
412 |
& SQUEEZE_RIGHT, myThid ) |
413 |
WRITE(msgBuf,'(A)') |
414 |
& '// Time stepping paramters ( PARM03 in namelist ) ' |
415 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
416 |
& SQUEEZE_RIGHT, myThid ) |
417 |
WRITE(msgBuf,'(A)') '// ' |
418 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
419 |
& SQUEEZE_RIGHT, myThid ) |
420 |
CALL WRITE_0D_I( nIter0, INDEX_NONE,'nIter0 =', |
421 |
&' /* Run starting timestep number */') |
422 |
CALL WRITE_0D_I( nTimeSteps, INDEX_NONE,'nTimeSteps =', |
423 |
&' /* Number of timesteps */') |
424 |
CALL WRITE_0D_R8( deltaTmom, INDEX_NONE,'deltaTmom =', |
425 |
&' /* Momentum equation timestep ( s ) */') |
426 |
CALL WRITE_0D_R8( deltaTfreesurf,INDEX_NONE,'deltaTfreesurf =', |
427 |
&' /* FreeSurface equation timestep ( s ) */') |
428 |
CALL WRITE_1D_R8( dTtracerLev, Nr, INDEX_K, 'dTtracerLev =', |
429 |
&' /* Tracer equation timestep ( s ) */') |
430 |
CALL WRITE_0D_R8( deltaTClock, INDEX_NONE,'deltaTClock =', |
431 |
&' /* Model clock timestep ( s ) */') |
432 |
CALL WRITE_0D_R8( cAdjFreq, INDEX_NONE,'cAdjFreq =', |
433 |
&' /* Convective adjustment interval ( s ) */') |
434 |
CALL WRITE_0D_I( momForcingOutAB, INDEX_NONE, 'momForcingOutAB =', |
435 |
& ' /* =1: take Momentum Forcing out of Adams-Bash. stepping */') |
436 |
CALL WRITE_0D_I( tracForcingOutAB, INDEX_NONE, |
437 |
& 'tracForcingOutAB =', |
438 |
& ' /* =1: take T,S,pTr Forcing out of Adams-Bash. stepping */') |
439 |
CALL WRITE_0D_L( momDissip_In_AB,INDEX_NONE,'momDissip_In_AB =', |
440 |
& ' /* put Dissipation Tendency in Adams-Bash. stepping */') |
441 |
CALL WRITE_0D_L( doAB_onGtGs, INDEX_NONE, 'doAB_onGtGs =', |
442 |
& ' /* apply AB on Tendencies (rather than on T,S)*/') |
443 |
CALL WRITE_0D_R8( abEps, INDEX_NONE,'abEps =', |
444 |
&' /* Adams-Bashforth-2 stabilizing weight */') |
445 |
#ifdef ALLOW_ADAMSBASHFORTH_3 |
446 |
CALL WRITE_0D_R8( alph_AB, INDEX_NONE,'alph_AB =', |
447 |
&' /* Adams-Bashforth-3 primary factor */') |
448 |
CALL WRITE_0D_R8( beta_AB, INDEX_NONE,'beta_AB =', |
449 |
&' /* Adams-Bashforth-3 secondary factor */') |
450 |
CALL WRITE_0D_L( startFromPickupAB2, INDEX_NONE, |
451 |
& 'startFromPickupAB2=',' /* start from AB-2 pickup */') |
452 |
#endif |
453 |
IF (useCDscheme) THEN |
454 |
CALL WRITE_0D_R8( tauCD, INDEX_NONE,'tauCD =', |
455 |
&' /* CD coupling time-scale ( s ) */') |
456 |
CALL WRITE_0D_R8( rCD, INDEX_NONE,'rCD =', |
457 |
&' /* Normalised CD coupling parameter */') |
458 |
ENDIF |
459 |
CALL WRITE_0D_R8( baseTime, INDEX_NONE,'baseTime =', |
460 |
&' /* Model base time ( s ). */') |
461 |
CALL WRITE_0D_R8( startTime, INDEX_NONE,'startTime =', |
462 |
&' /* Run start time ( s ). */') |
463 |
CALL WRITE_0D_R8( endTime, INDEX_NONE,'endTime =', |
464 |
&' /* Integration ending time ( s ). */') |
465 |
CALL WRITE_0D_R8( pChkPtFreq, INDEX_NONE,'pChkPtFreq =', |
466 |
&' /* Permanent restart/checkpoint file interval ( s ). */') |
467 |
CALL WRITE_0D_R8( chkPtFreq, INDEX_NONE,'chkPtFreq =', |
468 |
&' /* Rolling restart/checkpoint file interval ( s ). */') |
469 |
CALL WRITE_0D_L(pickup_write_mdsio,INDEX_NONE, |
470 |
& 'pickup_write_mdsio =', ' /* Model IO flag. */') |
471 |
CALL WRITE_0D_L(pickup_read_mdsio,INDEX_NONE, |
472 |
& 'pickup_read_mdsio =', ' /* Model IO flag. */') |
473 |
#ifdef ALLOW_MNC |
474 |
CALL WRITE_0D_L(pickup_write_mnc,INDEX_NONE, |
475 |
& 'pickup_write_mnc =', ' /* Model IO flag. */') |
476 |
CALL WRITE_0D_L(pickup_read_mnc,INDEX_NONE, |
477 |
& 'pickup_read_mnc =', ' /* Model IO flag. */') |
478 |
#endif |
479 |
CALL WRITE_0D_L(pickup_write_immed,INDEX_NONE, |
480 |
& 'pickup_write_immed =',' /* Model IO flag. */') |
481 |
CALL WRITE_0D_R8( dumpFreq, INDEX_NONE,'dumpFreq =', |
482 |
&' /* Model state write out interval ( s ). */') |
483 |
CALL WRITE_0D_L(dumpInitAndLast,INDEX_NONE,'dumpInitAndLast=', |
484 |
& ' /* write out Initial & Last iter. model state */') |
485 |
CALL WRITE_0D_L(snapshot_mdsio,INDEX_NONE, |
486 |
& 'snapshot_mdsio =', ' /* Model IO flag. */') |
487 |
#ifdef ALLOW_MNC |
488 |
CALL WRITE_0D_L(snapshot_mnc,INDEX_NONE, |
489 |
& 'snapshot_mnc =', ' /* Model IO flag. */') |
490 |
#endif |
491 |
CALL WRITE_0D_R8( monitorFreq, INDEX_NONE,'monitorFreq =', |
492 |
&' /* Monitor output interval ( s ). */') |
493 |
CALL WRITE_0D_L(monitor_stdio,INDEX_NONE, |
494 |
& 'monitor_stdio =', ' /* Model IO flag. */') |
495 |
#ifdef ALLOW_MNC |
496 |
CALL WRITE_0D_L(monitor_mnc,INDEX_NONE, |
497 |
& 'monitor_mnc =', ' /* Model IO flag. */') |
498 |
#endif |
499 |
CALL WRITE_0D_R8( externForcingPeriod, INDEX_NONE, |
500 |
& 'externForcingPeriod =', ' /* forcing period (s) */') |
501 |
CALL WRITE_0D_R8( externForcingCycle, INDEX_NONE, |
502 |
& 'externForcingCycle =', ' /* period of the cyle (s). */') |
503 |
CALL WRITE_0D_R8( tauThetaClimRelax, INDEX_NONE, |
504 |
& 'tauThetaClimRelax =', ' /* relaxation time scale (s) */') |
505 |
CALL WRITE_0D_R8( tauSaltClimRelax, INDEX_NONE, |
506 |
& 'tauSaltClimRelax =', ' /* relaxation time scale (s) */') |
507 |
CALL WRITE_0D_R8( latBandClimRelax, INDEX_NONE, |
508 |
& 'latBandClimRelax =', ' /* max. Lat. where relaxation */') |
509 |
WRITE(msgBuf,'(A)') '// ' |
510 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
511 |
& SQUEEZE_RIGHT, myThid ) |
512 |
WRITE(msgBuf,'(A)') |
513 |
& '// Gridding paramters ( PARM04 in namelist ) ' |
514 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
515 |
& SQUEEZE_RIGHT, myThid ) |
516 |
WRITE(msgBuf,'(A)') '// ' |
517 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
518 |
& SQUEEZE_RIGHT, myThid ) |
519 |
CALL WRITE_0D_L( usingCartesianGrid, INDEX_NONE, |
520 |
& 'usingCartesianGrid =', |
521 |
&' /* Cartesian coordinates flag ( True / False ) */') |
522 |
CALL WRITE_0D_L( usingSphericalPolarGrid, INDEX_NONE, |
523 |
& 'usingSphericalPolarGrid =', |
524 |
&' /* Spherical coordinates flag ( True / False ) */') |
525 |
CALL WRITE_0D_L( usingCylindricalGrid, INDEX_NONE, |
526 |
& 'usingCylindricalGrid =', |
527 |
&' /* Spherical coordinates flag ( True / False ) */') |
528 |
CALL WRITE_0D_R8( Ro_SeaLevel, INDEX_NONE,'Ro_SeaLevel =', |
529 |
&' /* r(1) ( units of r ) */') |
530 |
CALL WRITE_0D_R8( rkSign, INDEX_NONE,'rkSign =', |
531 |
&' /* index orientation relative to vertical coordinate */') |
532 |
CALL WRITE_0D_R8( horiVertRatio, INDEX_NONE,'horiVertRatio =', |
533 |
&' /* Ratio on units : Horiz - Vertical */') |
534 |
c CALL WRITE_1D_R8( delZ,Nr, INDEX_K,'delZ = ', |
535 |
c &' /* W spacing ( m ) */') |
536 |
c CALL WRITE_1D_R8( delP,Nr, INDEX_K,'delP = ', |
537 |
c &' /* W spacing ( Pa ) */') |
538 |
c CALL WRITE_1D_R8( delR,Nr, INDEX_K,'delR = ', |
539 |
c &' /* W spacing ( units of r ) */') |
540 |
CALL WRITE_1D_R8( drC,Nr, INDEX_K,'drC = ', |
541 |
&' /* C spacing ( units of r ) */') |
542 |
CALL WRITE_1D_R8( drF,Nr, INDEX_K,'drF = ', |
543 |
&' /* W spacing ( units of r ) */') |
544 |
CALL WRITE_1D_R8( delX, Nx, INDEX_I,'delX = ', |
545 |
&' /* U spacing ( m - cartesian, degrees - spherical ) */') |
546 |
CALL WRITE_1D_R8( delY, Ny, INDEX_J,'delY = ', |
547 |
&' /* V spacing ( m - cartesian, degrees - spherical ) */') |
548 |
CALL WRITE_0D_R8( phiMin, INDEX_NONE,'phiMin = ', |
549 |
&' /* South edge (ignored - cartesian, degrees - spherical ) */') |
550 |
CALL WRITE_0D_R8( thetaMin, INDEX_NONE,'thetaMin = ', |
551 |
&' /* West edge ( ignored - cartesian, degrees - spherical ) */') |
552 |
CALL WRITE_0D_R8( rSphere, INDEX_NONE,'rSphere = ', |
553 |
&' /* Radius ( ignored - cartesian, m - spherical ) */') |
554 |
DO bi=1,nSx |
555 |
DO I=1,sNx |
556 |
xcoord((bi-1)*sNx+I) = xC(I,1,bi,1) |
557 |
ENDDO |
558 |
ENDDO |
559 |
CALL WRITE_1D_R8( xcoord, sNx*nSx, INDEX_I,'xcoord = ', |
560 |
&' /* P-point X coord ( m - cartesian, degrees - spherical ) */') |
561 |
DO bj=1,nSy |
562 |
DO J=1,sNy |
563 |
ycoord((bj-1)*sNy+J) = yC(1,J,1,bj) |
564 |
ENDDO |
565 |
ENDDO |
566 |
CALL WRITE_1D_R8( ycoord, sNy*nSy, INDEX_J,'ycoord = ', |
567 |
&' /* P-point Y coord ( m - cartesian, degrees - spherical ) */') |
568 |
DO K=1,Nr |
569 |
rcoord(K) = rC(K) |
570 |
ENDDO |
571 |
CALL WRITE_1D_R8( rcoord, Nr, INDEX_K,'rcoord = ', |
572 |
&' /* P-point R coordinate ( units of r ) */') |
573 |
DO K=1,Nr+1 |
574 |
rcoord(K) = rF(K) |
575 |
ENDDO |
576 |
CALL WRITE_1D_R8( rcoord, Nr+1, INDEX_K,'rF = ', |
577 |
&' /* W-Interf. R coordinate ( units of r ) */') |
578 |
CALL WRITE_1D_R8( dBdrRef, Nr, INDEX_K,'dBdrRef = ', |
579 |
& ' /* Vertical gradient of reference boyancy [(m/s/r)^2)] */') |
580 |
|
581 |
C Grid along selected grid lines |
582 |
coordLine = 1 |
583 |
tileLine = 1 |
584 |
CALL WRITE_XY_XLINE_RS( dxF, coordLine, tileLine, 'dxF', |
585 |
I '( units: m )' ) |
586 |
CALL WRITE_XY_YLINE_RS( dxF, coordLine, tileLine, 'dxF', |
587 |
I '( units: m )' ) |
588 |
CALL WRITE_XY_XLINE_RS( dyF, coordLine, tileLine, 'dyF', |
589 |
I '( units: m )' ) |
590 |
CALL WRITE_XY_YLINE_RS( dyF, coordLine, tileLine, 'dyF', |
591 |
I '( units: m )' ) |
592 |
CALL WRITE_XY_XLINE_RS( dxG, coordLine, tileLine, 'dxG', |
593 |
I '( units: m )' ) |
594 |
CALL WRITE_XY_YLINE_RS( dxG, coordLine, tileLine, 'dxG', |
595 |
I '( units: m )' ) |
596 |
CALL WRITE_XY_XLINE_RS( dyG, coordLine, tileLine, 'dyG', |
597 |
I '( units: m )' ) |
598 |
CALL WRITE_XY_YLINE_RS( dyG, coordLine, tileLine, 'dyG', |
599 |
I '( units: m )' ) |
600 |
CALL WRITE_XY_XLINE_RS( dxC, coordLine, tileLine, 'dxC', |
601 |
I '( units: m )' ) |
602 |
CALL WRITE_XY_YLINE_RS( dxC, coordLine, tileLine, 'dxC', |
603 |
I '( units: m )' ) |
604 |
CALL WRITE_XY_XLINE_RS( dyC, coordLine, tileLine, 'dyC', |
605 |
I '( units: m )' ) |
606 |
CALL WRITE_XY_YLINE_RS( dyC, coordLine, tileLine, 'dyC', |
607 |
I '( units: m )' ) |
608 |
CALL WRITE_XY_XLINE_RS( dxV, coordLine, tileLine, 'dxV', |
609 |
I '( units: m )' ) |
610 |
CALL WRITE_XY_YLINE_RS( dxV, coordLine, tileLine, 'dxV', |
611 |
I '( units: m )' ) |
612 |
CALL WRITE_XY_XLINE_RS( dyU, coordLine, tileLine, 'dyU', |
613 |
I '( units: m )' ) |
614 |
CALL WRITE_XY_YLINE_RS( dyU, coordLine, tileLine, 'dyU', |
615 |
I '( units: m )' ) |
616 |
CALL WRITE_XY_XLINE_RS( rA , coordLine, tileLine, 'rA ', |
617 |
I '( units: m^2 )' ) |
618 |
CALL WRITE_XY_YLINE_RS( rA , coordLine, tileLine, 'rA ', |
619 |
I '( units: m^2 )' ) |
620 |
CALL WRITE_XY_XLINE_RS( rAw, coordLine, tileLine, 'rAw', |
621 |
I '( units: m^2 )' ) |
622 |
CALL WRITE_XY_YLINE_RS( rAw, coordLine, tileLine, 'rAw', |
623 |
I '( units: m^2 )' ) |
624 |
CALL WRITE_XY_XLINE_RS( rAs, coordLine, tileLine, 'rAs', |
625 |
I '( units: m^2 )' ) |
626 |
CALL WRITE_XY_YLINE_RS( rAs, coordLine, tileLine, 'rAs', |
627 |
I '( units: m^2 )' ) |
628 |
|
629 |
CALL WRITE_0D_R8( globalArea, INDEX_NONE, 'globalArea =', |
630 |
& ' /* Integrated horizontal Area (m^2) */') |
631 |
|
632 |
WRITE(msgBuf,'(A)') |
633 |
&'// =======================================================' |
634 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
635 |
& SQUEEZE_RIGHT, myThid ) |
636 |
WRITE(msgBuf,'(A)') '// End of Model config. summary' |
637 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
638 |
& SQUEEZE_RIGHT, myThid ) |
639 |
WRITE(msgBuf,'(A)') |
640 |
&'// =======================================================' |
641 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
642 |
& SQUEEZE_RIGHT, myThid ) |
643 |
WRITE(msgBuf,'(A)') ' ' |
644 |
CALL PRINT_MESSAGE( msgBuf, standardMessageUnit, |
645 |
& SQUEEZE_RIGHT, myThid ) |
646 |
|
647 |
_END_MASTER(myThid) |
648 |
_BARRIER |
649 |
|
650 |
|
651 |
RETURN |
652 |
END |