/[MITgcm]/MITgcm/model/src/config_summary.F
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Contents of /MITgcm/model/src/config_summary.F

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Revision 1.39 - (show annotations) (download)
Wed Feb 26 03:21:08 2003 UTC (21 years, 3 months ago) by jmc
Branch: MAIN
CVS Tags: checkpoint48i_post, checkpoint50, checkpoint48h_post, checkpoint49
Changes since 1.38: +1 -3 lines 
minor cleaning.
1 C $Header: /u/gcmpack/MITgcm/model/src/config_summary.F,v 1.38 2003/01/24 18:26:53 jmc Exp $
2 C $Name: $
3
4 #include "CPP_OPTIONS.h"
5
6 CBOP
7 C !ROUTINE: CONFIG_SUMMARY
8 C !INTERFACE:
9 SUBROUTINE CONFIG_SUMMARY( myThid )
10 C !DESCRIPTION: \bv
11 C *=========================================================*
12 C | SUBROUTINE CONFIG_SUMMARY
13 C | o Summarize model parameter settings.
14 C *=========================================================*
15 C | This routine writes a tabulated summary of the kernel
16 C | model configuration. Information describes all the
17 C | parameter setting in force and the meaning and units of
18 C | those parameters. Individal packages report a similar
19 C | table for each package using the same format as employed
20 C | here. If parameters are missing or incorrectly described
21 C | or dimensioned please contact support@mitgcm.org
22 C *=========================================================*
23 C \ev
24
25 C !USES:
26 IMPLICIT NONE
27 C === Global variables ===
28 #include "SIZE.h"
29 #include "EEPARAMS.h"
30 #include "PARAMS.h"
31 #include "EOS.h"
32 #include "GRID.h"
33 #include "DYNVARS.h"
34
35 C !INPUT/OUTPUT PARAMETERS:
36 C == Routine arguments ==
37 C myThid - Number of this instance of CONFIG_SUMMARY
38 INTEGER myThid
39 CEndOfInterface
40
41 C !LOCAL VARIABLES:
42 C == Local variables ==
43 C msgBuf :: Temp. for building output string.
44 C I,J,K :: Loop counters.
45 C bi,bj :: Tile loop counters.
46 C xcoord :: Temps. for building lists of values for uni-dimensionally
47 C ycoord :: varying parameters.
48 C zcoord ::
49 CHARACTER*(MAX_LEN_MBUF) msgBuf
50 INTEGER I,J,K
51 INTEGER bi, bj
52 _RL xcoord(Nx)
53 _RL ycoord(Ny)
54 _RL rcoord(Nr+1)
55 INTEGER coordLine
56 INTEGER tileLine
57 CEOP
58
59
60 _BARRIER
61 _BEGIN_MASTER(myThid)
62
63 WRITE(msgBuf,'(A)')
64 &'// ======================================================='
65 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
66 & SQUEEZE_RIGHT , 1)
67 WRITE(msgBuf,'(A)') '// Model configuration'
68 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
69 & SQUEEZE_RIGHT , 1)
70 WRITE(msgBuf,'(A)')
71 &'// ======================================================='
72 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
73 & SQUEEZE_RIGHT , 1)
74
75 WRITE(msgBuf,'(A)') '// '
76 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
77 & SQUEEZE_RIGHT , 1)
78 WRITE(msgBuf,'(A)')
79 & '// "Physical" paramters ( PARM01 in namelist ) '
80 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
81 & SQUEEZE_RIGHT , 1)
82 WRITE(msgBuf,'(A)') '// '
83 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
84 & SQUEEZE_RIGHT , 1)
85 WRITE(msgBuf,'(A,A40)') 'buoyancyRelation = ', buoyancyRelation
86 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
87 & SQUEEZE_RIGHT , 1)
88 CALL WRITE_1D_R8( tRef, Nr, INDEX_K,'tRef =',
89 &' /* Reference temperature profile ( oC or oK ) */')
90 CALL WRITE_1D_R8( sRef, Nr, INDEX_K,'sRef =',
91 &' /* Reference salinity profile ( ppt ) */')
92 CALL WRITE_0D_R8( viscAh, INDEX_NONE,'viscAh =',
93 &' /* Lateral eddy viscosity ( m^2/s ) */')
94 CALL WRITE_0D_R8( viscA4, INDEX_NONE,'viscAh =',
95 &' /* Lateral biharmonic viscosity ( m^4/s ) */')
96 CALL WRITE_0D_L( no_slip_sides, INDEX_NONE,
97 & 'no_slip_sides =', ' /* Viscous BCs: No-slip sides */')
98 IF ( viscAz .NE. UNSET_RL ) THEN
99 CALL WRITE_0D_R8( viscAz, INDEX_NONE,'viscAz =',
100 & ' /* Vertical eddy viscosity ( m^2/s ) */')
101 ENDIF
102 IF ( viscAp .NE. UNSET_RL ) THEN
103 CALL WRITE_0D_R8( viscAp, INDEX_NONE,'viscAp =',
104 & ' /* Vertical eddy viscosity ( Pa^2/s ) */')
105 ENDIF
106 CALL WRITE_0D_R8( viscAr, INDEX_NONE,'viscAr =',
107 &' /* Vertical eddy viscosity ( units of r^2/s ) */')
108 CALL WRITE_0D_R8( diffKhT, INDEX_NONE,'diffKhT =',
109 &' /* Laplacian diffusion of heat laterally ( m^2/s ) */')
110 CALL WRITE_0D_R8( diffK4T, INDEX_NONE,'diffK4T =',
111 &' /* Bihaarmonic diffusion of heat laterally ( m^4/s ) */')
112 CALL WRITE_0D_R8( diffKzT, INDEX_NONE,'diffKzT =',
113 &' /* Laplacian diffusion of heat vertically ( m^2/s ) */')
114 CALL WRITE_0D_R8( diffKrT, INDEX_NONE,'diffKrT =',
115 &' /* Laplacian diffusion of heat vertically ( m^2/s ) */')
116 CALL WRITE_0D_R8( diffKhS, INDEX_NONE,'diffKhS =',
117 &' /* Laplacian diffusion of salt laterally ( m^2/s ) */')
118 CALL WRITE_0D_R8( diffK4S, INDEX_NONE,'diffK4S =',
119 &' /* Bihaarmonic diffusion of salt laterally ( m^4/s ) */')
120 CALL WRITE_0D_R8( diffKzS, INDEX_NONE,'diffKzS =',
121 &' /* Laplacian diffusion of salt vertically ( m^2/s ) */')
122 CALL WRITE_0D_R8( diffKrS, INDEX_NONE,'diffKrS =',
123 &' /* Laplacian diffusion of salt vertically ( m^2/s ) */')
124 WRITE(msgBuf,'(2A)') ' Equation of State : eosType = ', eosType
125 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
126 & SQUEEZE_RIGHT , 1)
127 CALL WRITE_0D_R8( tAlpha, INDEX_NONE,'tAlpha =',
128 &' /* Linear EOS thermal expansion coefficient ( 1/degree ) */')
129 CALL WRITE_0D_R8( sBeta, INDEX_NONE,'sBeta =',
130 &' /* Linear EOS haline contraction coefficient ( 1/ppt ) */')
131 IF ( eosType .EQ. 'POLY3' ) THEN
132 WRITE(msgBuf,'(A)')
133 & '// Polynomial EQS parameters ( from POLY3.COEFFS ) '
134 DO K = 1, Nr
135 WRITE(msgBuf,'(I3,13F8.3)')
136 & K,eosRefT(K),eosRefS(K),eosSig0(K), (eosC(I,K),I=1,9)
137 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
138 & SQUEEZE_RIGHT , 1)
139 ENDDO
140 ENDIF
141 IF ( buoyancyRelation .eq. 'ATMOSPHERIC' ) THEN
142 CALL WRITE_0D_R8( atm_Rd, INDEX_NONE, 'atm_Rd =',
143 & ' /* gas constant for dry air ( J/kg/K ) */')
144 CALL WRITE_0D_R8( atm_Cp, INDEX_NONE, 'atm_Cp =',
145 & ' /* specific heat (Cp) of dry air ( J/kg/K ) */')
146 CALL WRITE_0D_R8( atm_kappa, INDEX_NONE, 'atm_kappa =',
147 & ' /* kappa (=Rd/Cp ) of dry air */')
148 CALL WRITE_0D_R8( atm_Po, INDEX_NONE, 'atm_Po =',
149 & ' /* standard reference pressure ( Pa ) */')
150 CALL WRITE_0D_I( integr_GeoPot, INDEX_NONE, 'integr_GeoPot =',
151 & ' /* select how the geopotential is integrated */')
152 CALL WRITE_0D_I( selectFindRoSurf, INDEX_NONE,
153 & 'selectFindRoSurf=',
154 & ' /* select how Surf.Ref. pressure is defined */')
155 ENDIF
156 CALL WRITE_0D_R8( rhonil, INDEX_NONE,'rhonil =',
157 &' /* Reference density ( kg/m^3 ) */')
158 CALL WRITE_0D_R8( rhoConst, INDEX_NONE,'rhoConst =',
159 &' /* Reference density ( kg/m^3 ) */')
160 CALL WRITE_0D_R8( rhoConstFresh, INDEX_NONE,'rhoConstFresh =',
161 &' /* Reference density ( kg/m^3 ) */')
162 CALL WRITE_0D_R8( gravity, INDEX_NONE,'gravity =',
163 &' /* Gravitational acceleration ( m/s^2 ) */')
164 CALL WRITE_0D_R8( gBaro, INDEX_NONE,'gBaro =',
165 &' /* Barotropic gravity ( m/s^2 ) */')
166 CALL WRITE_0D_R8( f0, INDEX_NONE,'f0 =',
167 &' /* Reference coriolis parameter ( 1/s ) */')
168 CALL WRITE_0D_R8( beta, INDEX_NONE,'beta =',
169 &' /* Beta ( 1/(m.s) ) */')
170
171 CALL WRITE_0D_R8( freeSurfFac, INDEX_NONE,'freeSurfFac =',
172 &' /* Implicit free surface factor */')
173 CALL WRITE_0D_L( implicitFreeSurface, INDEX_NONE,
174 & 'implicitFreeSurface =',
175 &' /* Implicit free surface on/off flag */')
176 CALL WRITE_0D_L( rigidLid, INDEX_NONE,
177 & 'rigidLid =',
178 &' /* Rigid lid on/off flag */')
179 CALL WRITE_0D_R8( implicSurfPress, INDEX_NONE,
180 &'implicSurfPress =',
181 &' /* Surface Pressure implicit factor (0-1)*/')
182 CALL WRITE_0D_R8( implicDiv2Dflow, INDEX_NONE,
183 &'implicDiv2Dflow =',
184 &' /* Barot. Flow Div. implicit factor (0-1)*/')
185 CALL WRITE_0D_L( exactConserv, INDEX_NONE,
186 &'exactConserv =',
187 &' /* Exact Volume Conservation on/off flag*/')
188 CALL WRITE_0D_L( uniformLin_PhiSurf, INDEX_NONE,
189 &'uniformLin_PhiSurf =',
190 &' /* use uniform Bo_surf on/off flag*/')
191 CALL WRITE_0D_I( nonlinFreeSurf, INDEX_NONE,
192 &'nonlinFreeSurf =',
193 &' /* Non-linear Free Surf. options (-1,0,1,2,3)*/')
194 WRITE(msgBuf,'(2A)') ' -1,0= Off ; 1,2,3= On,',
195 & ' 2=+rescale gU,gV, 3=+update cg2d solv.'
196 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
197 & SQUEEZE_RIGHT , 1)
198 CALL WRITE_0D_R8( hFacInf, INDEX_NONE,
199 &'hFacInf =',
200 &' /* lower threshold for hFac (nonlinFreeSurf only)*/')
201 CALL WRITE_0D_R8( hFacSup, INDEX_NONE,
202 &'hFacSup =',
203 &' /* upper threshold for hFac (nonlinFreeSurf only)*/')
204 CALL WRITE_0D_I( select_rStar, INDEX_NONE,
205 &'select_rStar =',
206 &' /* r* Coordinate options (not yet implemented)*/')
207 CALL WRITE_0D_L( useRealFreshWaterFlux, INDEX_NONE,
208 &'useRealFreshWaterFlux =',
209 &' /* Real Fresh Water Flux on/off flag*/')
210 IF (useRealFreshWaterFlux .AND. nonlinFreeSurf.GT.0) THEN
211 CALL WRITE_0D_R8( temp_EvPrRn, INDEX_NONE,
212 &'temp_EvPrRn =',
213 &' /* Temp. of Evap/Prec/R (UNSET=use local T)(oC)*/')
214 CALL WRITE_0D_R8( salt_EvPrRn, INDEX_NONE,
215 &'salt_EvPrRn =',
216 &' /* Salin. of Evap/Prec/R (UNSET=use local S)(ppt)*/')
217 CALL WRITE_0D_R8( trac_EvPrRn, INDEX_NONE,
218 &'trac_EvPrRn =',
219 &' /* Tracer in Evap/Prec/R (UNSET=use local Tr)*/')
220 ELSE
221 CALL WRITE_0D_R8( convertFW2Salt, INDEX_NONE,
222 &'convertFW2Salt =',
223 &' /* convert F.W. Flux to Salt Flux (-1=use local S)(ppt)*/')
224 ENDIF
225
226 CALL WRITE_0D_L( multiDimAdvection, INDEX_NONE,
227 & 'multiDimAdvection =',
228 &' /* enable/disable Multi-Dim Advection */')
229 CALL WRITE_0D_L( staggerTimeStep, INDEX_NONE,
230 & 'staggerTimeStep =',
231 &' /* Stagger time stepping on/off flag */')
232 CALL WRITE_0D_L( momStepping, INDEX_NONE,
233 & 'momStepping =', ' /* Momentum equation on/off flag */')
234 CALL WRITE_0D_L( momAdvection, INDEX_NONE,
235 & 'momAdvection =', ' /* Momentum advection on/off flag */')
236 CALL WRITE_0D_L( momViscosity, INDEX_NONE,
237 & 'momViscosity =', ' /* Momentum viscosity on/off flag */')
238 CALL WRITE_0D_L( useCoriolis, INDEX_NONE,
239 & 'useCoriolis =', ' /* Coriolis on/off flag */')
240 CALL WRITE_0D_L( momForcing, INDEX_NONE,
241 & 'momForcing =', ' /* Momentum forcing on/off flag */')
242 CALL WRITE_0D_L( momPressureForcing, INDEX_NONE,
243 & 'momPressureForcing =',
244 & ' /* Momentum pressure term on/off flag */')
245 CALL WRITE_0D_L( tempStepping, INDEX_NONE,
246 & 'tempStepping =', ' /* Temperature equation on/off flag */')
247 CALL WRITE_0D_L( tempAdvection, INDEX_NONE,
248 & 'tempAdvection=', ' /* Temperature advection on/off flag */')
249 CALL WRITE_0D_L( tempForcing, INDEX_NONE,
250 & 'tempForcing =', ' /* Temperature forcing on/off flag */')
251 CALL WRITE_0D_L( saltStepping, INDEX_NONE,
252 & 'saltStepping =', ' /* Salinity equation on/off flag */')
253 CALL WRITE_0D_L( saltAdvection, INDEX_NONE,
254 & 'saltAdvection=', ' /* Salinity advection on/off flag */')
255 CALL WRITE_0D_L( saltForcing, INDEX_NONE,
256 & 'saltForcing =', ' /* Salinity forcing on/off flag */')
257 CALL WRITE_0D_L( nonHydrostatic, INDEX_NONE,
258 & 'nonHydrostatic =', ' /* Non-Hydrostatic on/off flag */')
259 WRITE(msgBuf,'(A)') '// '
260 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
261 & SQUEEZE_RIGHT , 1)
262
263 WRITE(msgBuf,'(A)')
264 & '// Elliptic solver(s) paramters ( PARM02 in namelist ) '
265 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
266 & SQUEEZE_RIGHT , 1)
267 WRITE(msgBuf,'(A)') '// '
268 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
269 & SQUEEZE_RIGHT , 1)
270 CALL WRITE_0D_I( cg2dMaxIters, INDEX_NONE,'cg2dMaxIters =',
271 &' /* Upper limit on 2d con. grad iterations */')
272 CALL WRITE_0D_I( cg2dChkResFreq, INDEX_NONE,'cg2dChkResFreq =',
273 &' /* 2d con. grad convergence test frequency */')
274 CALL WRITE_0D_R8( cg2dTargetResidual, INDEX_NONE,
275 & 'cg2dTargetResidual =',
276 &' /* 2d con. grad target residual */')
277
278 WRITE(msgBuf,'(A)') '// '
279 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
280 & SQUEEZE_RIGHT , 1)
281 WRITE(msgBuf,'(A)')
282 & '// Time stepping paramters ( PARM03 in namelist ) '
283 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
284 & SQUEEZE_RIGHT , 1)
285 WRITE(msgBuf,'(A)') '// '
286 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
287 & SQUEEZE_RIGHT , 1)
288 CALL WRITE_0D_I( nIter0, INDEX_NONE,'nIter0 =',
289 &' /* Base timestep number */')
290 CALL WRITE_0D_I( nTimeSteps, INDEX_NONE,'nTimeSteps =',
291 &' /* Number of timesteps */')
292 CALL WRITE_0D_R8( deltaTmom, INDEX_NONE,'deltatTmom =',
293 &' /* Momentum equation timestep ( s ) */')
294 CALL WRITE_0D_R8( deltaTfreesurf,INDEX_NONE,'deltaTfreesurf =',
295 &' /* FreeSurface equation timestep ( s ) */')
296 CALL WRITE_0D_R8( deltaTtracer, INDEX_NONE,'deltatTtracer =',
297 &' /* Tracer equation timestep ( s ) */')
298 CALL WRITE_0D_R8( deltaTClock, INDEX_NONE,'deltatTClock =',
299 &' /* Model clock timestep ( s ) */')
300 CALL WRITE_0D_R8( cAdjFreq, INDEX_NONE,'cAdjFreq =',
301 &' /* Convective adjustment interval ( s ) */')
302 CALL WRITE_0D_L( forcing_In_AB,INDEX_NONE,'forcing_In_AB =',
303 &' /* put T,S Forcing in Adams-Bash. stepping */')
304 CALL WRITE_0D_R8( abeps, INDEX_NONE,'abeps =',
305 &' /* Adams-Bashforth stabilizing weight */')
306 CALL WRITE_0D_R8( tauCD, INDEX_NONE,'tauCD =',
307 &' /* CD coupling time-scale ( s ) */')
308 CALL WRITE_0D_R8( rCD, INDEX_NONE,'rCD =',
309 &' /* Normalised CD coupling parameter */')
310 CALL WRITE_0D_R8( startTime, INDEX_NONE,'startTime =',
311 &' /* Run start time ( s ). */')
312 CALL WRITE_0D_R8( endTime, INDEX_NONE,'endTime =',
313 &' /* Integration ending time ( s ). */')
314 CALL WRITE_0D_R8( pChkPtFreq, INDEX_NONE,'pChkPtFreq =',
315 &' /* Permanent restart/checkpoint file interval ( s ). */')
316 CALL WRITE_0D_R8( chkPtFreq, INDEX_NONE,'chkPtFreq =',
317 &' /* Rolling restart/checkpoint file interval ( s ). */')
318 CALL WRITE_0D_R8( dumpFreq, INDEX_NONE,'dumpFreq =',
319 &' /* Model state write out interval ( s ). */')
320
321 WRITE(msgBuf,'(A)') '// '
322 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
323 & SQUEEZE_RIGHT , 1)
324 WRITE(msgBuf,'(A)')
325 & '// Gridding paramters ( PARM04 in namelist ) '
326 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
327 & SQUEEZE_RIGHT , 1)
328 WRITE(msgBuf,'(A)') '// '
329 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
330 & SQUEEZE_RIGHT , 1)
331 CALL WRITE_0D_L( usingCartesianGrid, INDEX_NONE,
332 & 'usingCartesianGrid =',
333 &' /* Cartesian coordinates flag ( True / False ) */')
334 CALL WRITE_0D_L( usingSphericalPolarGrid, INDEX_NONE,
335 & 'usingSphericalPolarGrid =',
336 &' /* Spherical coordinates flag ( True / False ) */')
337 CALL WRITE_0D_L( groundAtK1, INDEX_NONE, 'groundAtK1 =',
338 &' /* Lower Boundary (ground) at the surface(k=1) ( T / F ) */')
339 CALL WRITE_0D_R8( Ro_SeaLevel, INDEX_NONE,'Ro_SeaLevel =',
340 &' /* r(1) ( units of r ) */')
341 CALL WRITE_0D_R8( rkFac, INDEX_NONE,'rkFac =',
342 &' /* minus Vertical index orientation */')
343 CALL WRITE_0D_R8( horiVertRatio, INDEX_NONE,'horiVertRatio =',
344 &' /* Ratio on units : Horiz - Vertical */')
345 c CALL WRITE_1D_R8( delZ,Nr, INDEX_K,'delZ = ',
346 c &' /* W spacing ( m ) */')
347 c CALL WRITE_1D_R8( delP,Nr, INDEX_K,'delP = ',
348 c &' /* W spacing ( Pa ) */')
349 c CALL WRITE_1D_R8( delR,Nr, INDEX_K,'delR = ',
350 c &' /* W spacing ( units of r ) */')
351 CALL WRITE_1D_R8( drC,Nr, INDEX_K,'drC = ',
352 &' /* C spacing ( units of r ) */')
353 CALL WRITE_1D_R8( drF,Nr, INDEX_K,'drF = ',
354 &' /* W spacing ( units of r ) */')
355 CALL WRITE_1D_R8( delX, Nx, INDEX_I,'delX = ',
356 &' /* U spacing ( m - cartesian, degrees - spherical ) */')
357 CALL WRITE_1D_R8( delY, Ny, INDEX_J,'delY = ',
358 &' /* V spacing ( m - cartesian, degrees - spherical ) */')
359 CALL WRITE_0D_R8( phiMin, INDEX_NONE,'phiMin = ',
360 &' /* South edge (ignored - cartesian, degrees - spherical ) */')
361 CALL WRITE_0D_R8( thetaMin, INDEX_NONE,'thetaMin = ',
362 &' /* West edge ( ignored - cartesian, degrees - spherical ) */')
363 CALL WRITE_0D_R8( rSphere, INDEX_NONE,'rSphere = ',
364 &' /* Radius ( ignored - cartesian, m - spherical ) */')
365 DO bi=1,nSx
366 DO I=1,sNx
367 xcoord((bi-1)*sNx+I) = xC(I,1,bi,1)
368 ENDDO
369 ENDDO
370 CALL WRITE_1D_R8( xcoord, sNx*nSx, INDEX_I,'xcoord = ',
371 &' /* P-point X coord ( m - cartesian, degrees - spherical ) */')
372 DO bj=1,nSy
373 DO J=1,sNy
374 ycoord((bj-1)*sNy+J) = yC(1,J,1,bj)
375 ENDDO
376 ENDDO
377 CALL WRITE_1D_R8( ycoord, sNy*nSy, INDEX_J,'ycoord = ',
378 &' /* P-point Y coord ( m - cartesian, degrees - spherical ) */')
379 DO K=1,Nr
380 rcoord(K) = rC(K)
381 ENDDO
382 CALL WRITE_1D_R8( rcoord, Nr, INDEX_K,'rcoord = ',
383 &' /* P-point R coordinate ( units of r ) */')
384 DO K=1,Nr+1
385 rcoord(K) = rF(K)
386 ENDDO
387 CALL WRITE_1D_R8( rcoord, Nr+1, INDEX_K,'rF = ',
388 &' /* W-Interf. R coordinate ( units of r ) */')
389
390 C Grid along selected grid lines
391 coordLine = 1
392 tileLine = 1
393 CALL WRITE_XY_XLINE_RS( dxF, coordLine, tileLine,
394 I 'dxF','( m - cartesian, degrees - spherical )')
395 CALL WRITE_XY_YLINE_RS( dxF, coordLine, tileLine,
396 I 'dxF','( m - cartesian, degrees - spherical )')
397 CALL WRITE_XY_XLINE_RS( dyF, coordLine, tileLine,
398 I 'dyF','( m - cartesian, degrees - spherical )')
399 CALL WRITE_XY_YLINE_RS( dyF, coordLine, tileLine,
400 I 'dyF','( m - cartesian, degrees - spherical )')
401 CALL WRITE_XY_XLINE_RS( dxG, coordLine, tileLine,
402 I 'dxG','( m - cartesian, degrees - spherical )')
403 CALL WRITE_XY_YLINE_RS( dxG, coordLine, tileLine,
404 I 'dxG','( m - cartesian, degrees - spherical )')
405 CALL WRITE_XY_XLINE_RS( dyG, coordLine, tileLine,
406 I 'dyG','( m - cartesian, degrees - spherical )')
407 CALL WRITE_XY_YLINE_RS( dyG, coordLine, tileLine,
408 I 'dyG','( m - cartesian, degrees - spherical )')
409 CALL WRITE_XY_XLINE_RS( dxC, coordLine, tileLine,
410 I 'dxC','( m - cartesian, degrees - spherical )')
411 CALL WRITE_XY_YLINE_RS( dxC, coordLine, tileLine,
412 I 'dxC','( m - cartesian, degrees - spherical )')
413 CALL WRITE_XY_XLINE_RS( dyC, coordLine, tileLine,
414 I 'dyC','( m - cartesian, degrees - spherical )')
415 CALL WRITE_XY_YLINE_RS( dyC, coordLine, tileLine,
416 I 'dyC','( m - cartesian, degrees - spherical )')
417 CALL WRITE_XY_XLINE_RS( dxV, coordLine, tileLine,
418 I 'dxV','( m - cartesian, degrees - spherical )')
419 CALL WRITE_XY_YLINE_RS( dxV, coordLine, tileLine,
420 I 'dxV','( m - cartesian, degrees - spherical )')
421 CALL WRITE_XY_XLINE_RS( dyU, coordLine, tileLine,
422 I 'dyU','( m - cartesian, degrees - spherical )')
423 CALL WRITE_XY_YLINE_RS( dyU, coordLine, tileLine,
424 I 'dyU','( m - cartesian, degrees - spherical )')
425 CALL WRITE_XY_XLINE_RS( rA, coordLine, tileLine,
426 I 'rA','( m - cartesian, degrees - spherical )')
427 CALL WRITE_XY_YLINE_RS( rA, coordLine, tileLine,
428 I 'rA','( m - cartesian, degrees - spherical )')
429 CALL WRITE_XY_XLINE_RS( rAw, coordLine, tileLine,
430 I 'rAw','( m - cartesian, degrees - spherical )')
431 CALL WRITE_XY_YLINE_RS( rAw, coordLine, tileLine,
432 I 'rAw','( m - cartesian, degrees - spherical )')
433 CALL WRITE_XY_XLINE_RS( rAs, coordLine, tileLine,
434 I 'rAs','( m - cartesian, degrees - spherical )')
435 CALL WRITE_XY_YLINE_RS( rAs, coordLine, tileLine,
436 I 'rAs','( m - cartesian, degrees - spherical )')
437
438 WRITE(msgBuf,'(A)') ' '
439 CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
440 & SQUEEZE_RIGHT , 1)
441
442 _END_MASTER(myThid)
443 _BARRIER
444
445
446 RETURN
447 100 FORMAT(A,
448 &' '
449 &)
450 END
451
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