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GCC Code Coverage Report

Directory:	./		Exec	Total	Coverage
File:	phylmd/rrtm/sucst.F90	Lines:	156	156	100.0 %
Date:	2023-06-30 12:56:34	Branches:	26	36	72.2 %


SUBROUTINE SUCST(KULOUT,KDAT,KSSS,KPRINTLEV)

!**** *SUCST * - Routine to initialize the constants of the model.

!     Purpose.
!     --------
!           Initialize and print the common YOMCST + initialize
!         date and time of YOMRIP.

!**   Interface.
!     ----------
!        *CALL* *SUCST (..)

!        Explicit arguments :
!        --------------------

!        KULOUT  - logical unit for the output
!        KDAT    - date in the form AAAAMMDD
!        KSSS    - number of seconds in the day
!        KPRINTLEV - printing level

!        Implicit arguments :
!        --------------------
!        COMMON YOMCST
!        COMMON YOMRIP

!     Method.
!     -------
!        See documentation

!     Externals.
!     ----------

!     Reference.
!     ----------
!        ECMWF Research Department documentation of the IFS

!     Author.
!     -------
!        Mats Hamrud and Philippe Courtier  *ECMWF*

!     Modifications.
!     --------------
!        Original : 87-10-15
!        Additions : 90-07-30 (J.-F. Geleyn)
!                    91-11-15 (M. Deque)
!                    96-08-12 M.Hamrud - Reduce printing
!        M.Hamrud      01-Oct-2003 CY28 Cleaning
!     ------------------------------------------------------------------

USE PARKIND1  ,ONLY : JPIM     ,JPRB
USE YOMHOOK   ,ONLY : LHOOK,   DR_HOOK

USE YOMCST   , ONLY : RPI      ,RCLUM    ,RHPLA    ,RKBOL    ,&
 & RNAVO    ,RDAY     ,REA      ,REPSM    ,RSIYEA   ,&
 & RSIDAY   ,ROMEGA   ,RA       ,RG       ,R1SA     ,&
 & RSIGMA   ,RI0      ,R        ,RMD      ,RMV      ,&
 & RMO3     ,RD       ,RV       ,RCPD     ,RCPV     ,&
 & RMCO2    ,RMCH4    ,RMN2O    ,RMCO     ,RMHCHO   ,&
 & RMSO2    ,RMNO2    ,RMSF6    ,RMRA     ,&
 & RCVD     ,RCVV     ,RKAPPA   ,RETV     ,RCW      ,&
 & RCS      ,RLVTT    ,RLSTT    ,RLVZER   ,RLSZER   ,&
 & RLMLT    ,RTT      ,RATM     ,RDT      ,RESTT    ,&
 & RALPW    ,RBETW    ,RGAMW    ,RALPS    ,RBETS    ,&
 & RGAMS    ,RALPD    ,RBETD    ,RGAMD
USE YOMRIP   , ONLY : RTIMST   ,RTIMTR

IMPLICIT NONE

INTEGER(KIND=JPIM),INTENT(IN)    :: KULOUT
INTEGER(KIND=JPIM),INTENT(IN)    :: KDAT
INTEGER(KIND=JPIM),INTENT(IN)    :: KSSS
INTEGER(KIND=JPIM),INTENT(IN)    :: KPRINTLEV
INTEGER(KIND=JPIM) :: IA, ID, IDAT, IM, ISSS, J

REAL(KIND=JPRB) :: ZDE, ZET, ZJU, ZRS, ZRSREL, ZTETA, ZTI
REAL(KIND=JPRB) :: ZHOOK_HANDLE

#include "fctast.h"
#include "fcttrm.h"
#include "fcttim.h"
!      -----------------------------------------------------------------

!*       1.    DEFINE FUNDAMENTAL CONSTANTS.
!              -----------------------------

print*,'DANS SUCST CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC'
IF (LHOOK) CALL DR_HOOK('SUCST',0,ZHOOK_HANDLE)
RPI=2.0_JPRB*ASIN(1.0_JPRB)
RCLUM=299792458._JPRB
RHPLA=6.6260755E-34_JPRB
RKBOL=1.380658E-23_JPRB
RNAVO=6.0221367E+23_JPRB

!     ------------------------------------------------------------------

!*       2.    DEFINE ASTRONOMICAL CONSTANTS.
!              ------------------------------

RDAY=86400._JPRB
REA=149597870000._JPRB
REPSM=0.409093_JPRB

RSIYEA=365.25_JPRB*RDAY*2.0_JPRB*RPI/6.283076_JPRB
RSIDAY=RDAY/(1.0_JPRB+RDAY/RSIYEA)
ROMEGA=2.0_JPRB*RPI/RSIDAY

IDAT=KDAT
ISSS=KSSS
ID=NDD(IDAT)
IM=NMM(IDAT)
IA=NCCAA(IDAT)
ZJU=RJUDAT(IA,IM,ID)
ZTI=RTIME(IA,IM,ID,ISSS)
RTIMST=ZTI
RTIMTR=ZTI
ZTETA=RTETA(ZTI)
ZRS=RRS(ZTETA)
ZDE=RDS(ZTETA)
ZET=RET(ZTETA)
ZRSREL=ZRS/REA

!     ------------------------------------------------------------------

!*       3.    DEFINE GEOIDE.
!              --------------

RG=9.80665_JPRB
RA=6371229._JPRB
R1SA=REAL(1.0_JPRB/REAL(RA,KIND(1.0_JPRB)),KIND(R1SA))

!     ------------------------------------------------------------------

!*       4.    DEFINE RADIATION CONSTANTS.
!              ---------------------------

RSIGMA=2.0_JPRB * RPI**5 * RKBOL**4 /(15._JPRB* RCLUM**2 * RHPLA**3)
RI0=1370._JPRB

!     ------------------------------------------------------------------

!*       5.    DEFINE THERMODYNAMIC CONSTANTS, GAS PHASE.
!              ------------------------------------------

R=RNAVO*RKBOL
RMD=28.9644_JPRB
RMV=18.0153_JPRB
RMO3=47.9942_JPRB
RD=1000._JPRB*R/RMD
RV=1000._JPRB*R/RMV
RCPD=3.5_JPRB*RD
RCVD=RCPD-RD
RCPV=4._JPRB *RV
RCVV=RCPV-RV
RKAPPA=RD/RCPD
RETV=RV/RD-1.0_JPRB
RMCO2=44.0095_JPRB
RMCH4=16.04_JPRB
RMN2O=44.013_JPRB
RMSF6=146.05_JPRB
RMRA=222._JPRB
RMCO=28.01_JPRB
RMHCHO=30.03_JPRB
RMNO2=46.01_JPRB
RMSO2=64.07_JPRB

!     ------------------------------------------------------------------

!*       6.    DEFINE THERMODYNAMIC CONSTANTS, LIQUID PHASE.
!              ---------------------------------------------

RCW=4218._JPRB

!     ------------------------------------------------------------------

!*       7.    DEFINE THERMODYNAMIC CONSTANTS, SOLID PHASE.
!              --------------------------------------------

RCS=2106._JPRB

!     ------------------------------------------------------------------

!*       8.    DEFINE THERMODYNAMIC CONSTANTS, TRANSITION OF PHASE.
!              ----------------------------------------------------

RTT=273.16_JPRB
RDT=11.82_JPRB
RLVTT=2.5008E+6_JPRB
RLSTT=2.8345E+6_JPRB
RLVZER=RLVTT+RTT*(RCW-RCPV)
RLSZER=RLSTT+RTT*(RCS-RCPV)
RLMLT=RLSTT-RLVTT
RATM=100000._JPRB

!     ------------------------------------------------------------------

!*       9.    SATURATED VAPOUR PRESSURE.
!              --------------------------

RESTT=611.14_JPRB
RGAMW=(RCW-RCPV)/RV
RBETW=RLVTT/RV+RGAMW*RTT
RALPW=LOG(RESTT)+RBETW/RTT+RGAMW*LOG(RTT)
print *,'SUCST: RESTT,RBETW,RTT,RGAMW',RESTT,RBETW,RTT,RGAMW
print *,'SUCST: RALPW',RALPW
RGAMS=(RCS-RCPV)/RV
RBETS=RLSTT/RV+RGAMS*RTT
RALPS=LOG(RESTT)+RBETS/RTT+RGAMS*LOG(RTT)
print *,'SUCST: RESTT,RBETS,RTT,RGAMS',RESTT,RBETS,RTT,RGAMS
print *,'SUCST: RALPS',RALPS
RGAMS=(RCS-RCPV)/RV
RGAMD=RGAMS-RGAMW
RBETD=RBETS-RBETW
RALPD=RALPS-RALPW

!     ------------------------------------------------------------------

!*      10.    PRINTS

print*,'KPRINTLEV ',KPRINTLEV
print*,'KULOUT ',KULOUT

IF (KPRINTLEV >= 1) THEN
  WRITE(KULOUT,'(''0*** Constants of the ICM   ***'')')
  WRITE(KULOUT,'('' *** Fundamental constants ***'')')
  WRITE(KULOUT,'(''           PI = '',E13.7,'' -'')')RPI
  WRITE(KULOUT,'(''            c = '',E13.7,''m s-1'')')RCLUM
  WRITE(KULOUT,'(''            h = '',E13.7,''J s'')')RHPLA
  WRITE(KULOUT,'(''            K = '',E13.7,''J K-1'')')RKBOL
  WRITE(KULOUT,'(''            N = '',E13.7,''mol-1'')')RNAVO
  WRITE(KULOUT,'('' *** Astronomical constants ***'')')
  WRITE(KULOUT,'(''          day = '',E13.7,'' s'')')RDAY
  WRITE(KULOUT,'('' half g. axis = '',E13.7,'' m'')')REA
  WRITE(KULOUT,'('' mean anomaly = '',E13.7,'' -'')')REPSM
  WRITE(KULOUT,'('' sideral year = '',E13.7,'' s'')')RSIYEA
  WRITE(KULOUT,'(''  sideral day = '',E13.7,'' s'')')RSIDAY
  WRITE(KULOUT,'(''        omega = '',E13.7,'' s-1'')')ROMEGA

  WRITE(KULOUT,'('' The initial date of the run is :'')')
  WRITE(KULOUT,'(1X,I8,1X,I5,5X,I4,1X,I2,1X,I2)')IDAT,ISSS,IA,IM,ID
  WRITE(KULOUT,'('' The Julian date is : '',F11.2)') ZJU
  WRITE(KULOUT,'('' Time of the model  : '',F15.2,'' s'')')ZTI
  WRITE(KULOUT,'('' Distance Earth-Sun : '',E13.7,'' m'')')ZRS
  WRITE(KULOUT,'('' Relative Dist. E-S : '',E13.7,'' m'')')ZRSREL
  WRITE(KULOUT,'('' Declination        : '',F12.5)') ZDE
  WRITE(KULOUT,'('' Eq. of time        : '',F12.5,'' s'')')ZET
  WRITE(KULOUT,'('' ***         Geoide         ***'')')
  WRITE(KULOUT,'(''      Gravity = '',E13.7,'' m s-2'')')RG
  WRITE(KULOUT,'('' Earth radius = '',E13.7,'' m'')')RA
  WRITE(KULOUT,'('' Inverse E.R. = '',E13.7,'' m'')')R1SA
  WRITE(KULOUT,'('' ***        Radiation       ***'')')
  WRITE(KULOUT,'('' Stefan-Bol.  = '',E13.7,'' W m-2 K-4'')')  RSIGMA
  WRITE(KULOUT,'('' Solar const. = '',E13.7,'' W m-2'')')RI0
  WRITE(KULOUT,'('' *** Thermodynamic, gas     ***'')')
  WRITE(KULOUT,'('' Perfect gas  = '',e13.7)') R
  WRITE(KULOUT,'('' Dry air mass = '',e13.7)') RMD
  WRITE(KULOUT,'('' Vapour  mass = '',e13.7)') RMV
  WRITE(KULOUT,'('' Ozone   mass = '',e13.7)') RMO3
  WRITE(KULOUT,'('' Dry air cst. = '',e13.7)') RD
  WRITE(KULOUT,'('' Vapour  cst. = '',e13.7)') RV
  WRITE(KULOUT,'(''         Cpd  = '',e13.7)') RCPD
  WRITE(KULOUT,'(''         Cvd  = '',e13.7)') RCVD
  WRITE(KULOUT,'(''         Cpv  = '',e13.7)') RCPV
  WRITE(KULOUT,'(''         Cvv  = '',e13.7)') RCVV
  WRITE(KULOUT,'(''      Rd/Cpd  = '',e13.7)') RKAPPA
  WRITE(KULOUT,'(''     Rv/Rd-1  = '',e13.7)') RETV
  WRITE(KULOUT,'('' *** Thermodynamic, liquid  ***'')')
  WRITE(KULOUT,'(''         Cw   = '',E13.7)') RCW
  WRITE(KULOUT,'('' *** thermodynamic, solid   ***'')')
  WRITE(KULOUT,'(''         Cs   = '',E13.7)') RCS
  WRITE(KULOUT,'('' *** Thermodynamic, trans.  ***'')')
  WRITE(KULOUT,'('' Fusion point  = '',E13.7)') RTT
  WRITE(KULOUT,'('' RTT-Tx(ew-ei) = '',E13.7)') RDT
  WRITE(KULOUT,'(''        RLvTt  = '',E13.7)') RLVTT
  WRITE(KULOUT,'(''        RLsTt  = '',E13.7)') RLSTT
  WRITE(KULOUT,'(''        RLv0   = '',E13.7)') RLVZER
  WRITE(KULOUT,'(''        RLs0   = '',E13.7)') RLSZER
  WRITE(KULOUT,'(''        RLMlt  = '',E13.7)') RLMLT
  WRITE(KULOUT,'('' Normal press. = '',E13.7)') RATM
  WRITE(KULOUT,'('' Latent heat :  '')')
  WRITE(KULOUT,'(10(1X,E10.4))') (10._JPRB*J,J=-4,4)
  WRITE(KULOUT,'(10(1X,E10.4))') (RLV(RTT+10._JPRB*J),J=-4,4)
  WRITE(KULOUT,'(10(1X,E10.4))') (RLS(RTT+10._JPRB*J),J=-4,4)
  WRITE(KULOUT,'('' *** Thermodynamic, satur.  ***'')')
  WRITE(KULOUT,'('' Fusion point = '',E13.7)') RTT
  WRITE(KULOUT,'(''      es(Tt)  = '',e13.7)') RESTT
  WRITE(KULOUT,'('' es(T) :  '')')
  WRITE(KULOUT,'(10(1X,E10.4))') (10._JPRB*J,J=-4,4)
  WRITE(KULOUT,'(10(1X,E10.4))') (ESW(RTT+10._JPRB*J),J=-4,4)
  WRITE(KULOUT,'(10(1X,E10.4))') (ESS(RTT+10._JPRB*J),J=-4,4)
!  call flush(0)       !!!!! A REVOIR (MPL) les 7 lignes qui suivent
   do j=1,9
     print*,'TEST J',j
     print*,'RTT...',RTT+10._JPRB*(J-5)
     print*,'ES(RTT...',ES(RTT+10._JPRB*(J-5))
   enddo
  call flush(0)

  WRITE(KULOUT,'(10(1X,E10.4))') (ES (RTT+10._JPRB*J),J=-4,4)
ENDIF

!     ------------------------------------------------------------------

IF (LHOOK) CALL DR_HOOK('SUCST',1,ZHOOK_HANDLE)
END SUBROUTINE SUCST



Generated by: GCOVR (Version 4.2)

Line	Branch	Exec	Source
1		1	SUBROUTINE SUCST(KULOUT,KDAT,KSSS,KPRINTLEV)
2
3			!**** SUCST - Routine to initialize the constants of the model.
4
5			! Purpose.
6			! --------
7			! Initialize and print the common YOMCST + initialize
8			! date and time of YOMRIP.
9
10			!** Interface.
11			! ----------
12			! CALL *SUCST (..)
13
14			! Explicit arguments :
15			! --------------------
16
17			! KULOUT - logical unit for the output
18			! KDAT - date in the form AAAAMMDD
19			! KSSS - number of seconds in the day
20			! KPRINTLEV - printing level
21
22			! Implicit arguments :
23			! --------------------
24			! COMMON YOMCST
25			! COMMON YOMRIP
26
27			! Method.
28			! -------
29			! See documentation
30
31			! Externals.
32			! ----------
33
34			! Reference.
35			! ----------
36			! ECMWF Research Department documentation of the IFS
37
38			! Author.
39			! -------
40			! Mats Hamrud and Philippe Courtier ECMWF
41
42			! Modifications.
43			! --------------
44			! Original : 87-10-15
45			! Additions : 90-07-30 (J.-F. Geleyn)
46			! 91-11-15 (M. Deque)
47			! 96-08-12 M.Hamrud - Reduce printing
48			! M.Hamrud 01-Oct-2003 CY28 Cleaning
49			! ------------------------------------------------------------------
50
51			USE PARKIND1 ,ONLY : JPIM ,JPRB
52			USE YOMHOOK ,ONLY : LHOOK, DR_HOOK
53
54			USE YOMCST , ONLY : RPI ,RCLUM ,RHPLA ,RKBOL ,&
55			& RNAVO ,RDAY ,REA ,REPSM ,RSIYEA ,&
56			& RSIDAY ,ROMEGA ,RA ,RG ,R1SA ,&
57			& RSIGMA ,RI0 ,R ,RMD ,RMV ,&
58			& RMO3 ,RD ,RV ,RCPD ,RCPV ,&
59			& RMCO2 ,RMCH4 ,RMN2O ,RMCO ,RMHCHO ,&
60			& RMSO2 ,RMNO2 ,RMSF6 ,RMRA ,&
61			& RCVD ,RCVV ,RKAPPA ,RETV ,RCW ,&
62			& RCS ,RLVTT ,RLSTT ,RLVZER ,RLSZER ,&
63			& RLMLT ,RTT ,RATM ,RDT ,RESTT ,&
64			& RALPW ,RBETW ,RGAMW ,RALPS ,RBETS ,&
65			& RGAMS ,RALPD ,RBETD ,RGAMD
66			USE YOMRIP , ONLY : RTIMST ,RTIMTR
67
68			IMPLICIT NONE
69
70			INTEGER(KIND=JPIM),INTENT(IN) :: KULOUT
71			INTEGER(KIND=JPIM),INTENT(IN) :: KDAT
72			INTEGER(KIND=JPIM),INTENT(IN) :: KSSS
73			INTEGER(KIND=JPIM),INTENT(IN) :: KPRINTLEV
74			INTEGER(KIND=JPIM) :: IA, ID, IDAT, IM, ISSS, J
75
76			REAL(KIND=JPRB) :: ZDE, ZET, ZJU, ZRS, ZRSREL, ZTETA, ZTI
77			REAL(KIND=JPRB) :: ZHOOK_HANDLE
78
79			#include "fctast.h"
80			#include "fcttrm.h"
81			#include "fcttim.h"
82			! -----------------------------------------------------------------
83
84			!* 1. DEFINE FUNDAMENTAL CONSTANTS.
85			! -----------------------------
86
87		1	print*,'DANS SUCST CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC'
88	✓✗	1	IF (LHOOK) CALL DR_HOOK('SUCST',0,ZHOOK_HANDLE)
89		1	RPI=2.0_JPRB*ASIN(1.0_JPRB)
90		1	RCLUM=299792458._JPRB
91		1	RHPLA=6.6260755E-34_JPRB
92		1	RKBOL=1.380658E-23_JPRB
93		1	RNAVO=6.0221367E+23_JPRB
94
95			! ------------------------------------------------------------------
96
97			!* 2. DEFINE ASTRONOMICAL CONSTANTS.
98			! ------------------------------
99
100		1	RDAY=86400._JPRB
101		1	REA=149597870000._JPRB
102		1	REPSM=0.409093_JPRB
103
104		1	RSIYEA=365.25_JPRBRDAY2.0_JPRB*RPI/6.283076_JPRB
105		1	RSIDAY=RDAY/(1.0_JPRB+RDAY/RSIYEA)
106		1	ROMEGA=2.0_JPRB*RPI/RSIDAY
107
108		1	IDAT=KDAT
109		1	ISSS=KSSS
110		1	ID=NDD(IDAT)
111		1	IM=NMM(IDAT)
112		1	IA=NCCAA(IDAT)
113		1	ZJU=RJUDAT(IA,IM,ID)
114		1	ZTI=RTIME(IA,IM,ID,ISSS)
115		1	RTIMST=ZTI
116		1	RTIMTR=ZTI
117		1	ZTETA=RTETA(ZTI)
118		1	ZRS=RRS(ZTETA)
119		1	ZDE=RDS(ZTETA)
120		1	ZET=RET(ZTETA)
121		1	ZRSREL=ZRS/REA
122
123			! ------------------------------------------------------------------
124
125			!* 3. DEFINE GEOIDE.
126			! --------------
127
128		1	RG=9.80665_JPRB
129		1	RA=6371229._JPRB
130		1	R1SA=REAL(1.0_JPRB/REAL(RA,KIND(1.0_JPRB)),KIND(R1SA))
131
132			! ------------------------------------------------------------------
133
134			!* 4. DEFINE RADIATION CONSTANTS.
135			! ---------------------------
136
137		1	RSIGMA=2.0_JPRB * RPI*5 RKBOL*4 /(15._JPRB RCLUM*2 RHPLA**3)
138		1	RI0=1370._JPRB
139
140			! ------------------------------------------------------------------
141
142			!* 5. DEFINE THERMODYNAMIC CONSTANTS, GAS PHASE.
143			! ------------------------------------------
144
145		1	R=RNAVO*RKBOL
146		1	RMD=28.9644_JPRB
147		1	RMV=18.0153_JPRB
148		1	RMO3=47.9942_JPRB
149		1	RD=1000._JPRB*R/RMD
150		1	RV=1000._JPRB*R/RMV
151		1	RCPD=3.5_JPRB*RD
152		1	RCVD=RCPD-RD
153		1	RCPV=4._JPRB *RV
154		1	RCVV=RCPV-RV
155		1	RKAPPA=RD/RCPD
156		1	RETV=RV/RD-1.0_JPRB
157		1	RMCO2=44.0095_JPRB
158		1	RMCH4=16.04_JPRB
159		1	RMN2O=44.013_JPRB
160		1	RMSF6=146.05_JPRB
161		1	RMRA=222._JPRB
162		1	RMCO=28.01_JPRB
163		1	RMHCHO=30.03_JPRB
164		1	RMNO2=46.01_JPRB
165		1	RMSO2=64.07_JPRB
166
167			! ------------------------------------------------------------------
168
169			!* 6. DEFINE THERMODYNAMIC CONSTANTS, LIQUID PHASE.
170			! ---------------------------------------------
171
172		1	RCW=4218._JPRB
173
174			! ------------------------------------------------------------------
175
176			!* 7. DEFINE THERMODYNAMIC CONSTANTS, SOLID PHASE.
177			! --------------------------------------------
178
179		1	RCS=2106._JPRB
180
181			! ------------------------------------------------------------------
182
183			!* 8. DEFINE THERMODYNAMIC CONSTANTS, TRANSITION OF PHASE.
184			! ----------------------------------------------------
185
186		1	RTT=273.16_JPRB
187		1	RDT=11.82_JPRB
188		1	RLVTT=2.5008E+6_JPRB
189		1	RLSTT=2.8345E+6_JPRB
190		1	RLVZER=RLVTT+RTT*(RCW-RCPV)
191		1	RLSZER=RLSTT+RTT*(RCS-RCPV)
192		1	RLMLT=RLSTT-RLVTT
193		1	RATM=100000._JPRB
194
195			! ------------------------------------------------------------------
196
197			!* 9. SATURATED VAPOUR PRESSURE.
198			! --------------------------
199
200		1	RESTT=611.14_JPRB
201		1	RGAMW=(RCW-RCPV)/RV
202		1	RBETW=RLVTT/RV+RGAMW*RTT
203		1	RALPW=LOG(RESTT)+RBETW/RTT+RGAMW*LOG(RTT)
204		1	print *,'SUCST: RESTT,RBETW,RTT,RGAMW',RESTT,RBETW,RTT,RGAMW
205		1	print *,'SUCST: RALPW',RALPW
206		1	RGAMS=(RCS-RCPV)/RV
207		1	RBETS=RLSTT/RV+RGAMS*RTT
208		1	RALPS=LOG(RESTT)+RBETS/RTT+RGAMS*LOG(RTT)
209		1	print *,'SUCST: RESTT,RBETS,RTT,RGAMS',RESTT,RBETS,RTT,RGAMS
210		1	print *,'SUCST: RALPS',RALPS
211		1	RGAMS=(RCS-RCPV)/RV
212		1	RGAMD=RGAMS-RGAMW
213		1	RBETD=RBETS-RBETW
214		1	RALPD=RALPS-RALPW
215
216			! ------------------------------------------------------------------
217
218			!* 10. PRINTS
219
220		1	print*,'KPRINTLEV ',KPRINTLEV
221		1	print*,'KULOUT ',KULOUT
222
223	✓✗	1	IF (KPRINTLEV >= 1) THEN
224		1	WRITE(KULOUT,'(''0* Constants of the ICM *'')')
225		1	WRITE(KULOUT,'('' * Fundamental constants *'')')
226		1	WRITE(KULOUT,'('' PI = '',E13.7,'' -'')')RPI
227		1	WRITE(KULOUT,'('' c = '',E13.7,''m s-1'')')RCLUM
228		1	WRITE(KULOUT,'('' h = '',E13.7,''J s'')')RHPLA
229		1	WRITE(KULOUT,'('' K = '',E13.7,''J K-1'')')RKBOL
230		1	WRITE(KULOUT,'('' N = '',E13.7,''mol-1'')')RNAVO
231		1	WRITE(KULOUT,'('' * Astronomical constants *'')')
232		1	WRITE(KULOUT,'('' day = '',E13.7,'' s'')')RDAY
233		1	WRITE(KULOUT,'('' half g. axis = '',E13.7,'' m'')')REA
234		1	WRITE(KULOUT,'('' mean anomaly = '',E13.7,'' -'')')REPSM
235		1	WRITE(KULOUT,'('' sideral year = '',E13.7,'' s'')')RSIYEA
236		1	WRITE(KULOUT,'('' sideral day = '',E13.7,'' s'')')RSIDAY
237		1	WRITE(KULOUT,'('' omega = '',E13.7,'' s-1'')')ROMEGA
238
239		1	WRITE(KULOUT,'('' The initial date of the run is :'')')
240		1	WRITE(KULOUT,'(1X,I8,1X,I5,5X,I4,1X,I2,1X,I2)')IDAT,ISSS,IA,IM,ID
241		1	WRITE(KULOUT,'('' The Julian date is : '',F11.2)') ZJU
242		1	WRITE(KULOUT,'('' Time of the model : '',F15.2,'' s'')')ZTI
243		1	WRITE(KULOUT,'('' Distance Earth-Sun : '',E13.7,'' m'')')ZRS
244		1	WRITE(KULOUT,'('' Relative Dist. E-S : '',E13.7,'' m'')')ZRSREL
245		1	WRITE(KULOUT,'('' Declination : '',F12.5)') ZDE
246		1	WRITE(KULOUT,'('' Eq. of time : '',F12.5,'' s'')')ZET
247		1	WRITE(KULOUT,'('' * Geoide *'')')
248		1	WRITE(KULOUT,'('' Gravity = '',E13.7,'' m s-2'')')RG
249		1	WRITE(KULOUT,'('' Earth radius = '',E13.7,'' m'')')RA
250		1	WRITE(KULOUT,'('' Inverse E.R. = '',E13.7,'' m'')')R1SA
251		1	WRITE(KULOUT,'('' * Radiation *'')')
252		1	WRITE(KULOUT,'('' Stefan-Bol. = '',E13.7,'' W m-2 K-4'')') RSIGMA
253		1	WRITE(KULOUT,'('' Solar const. = '',E13.7,'' W m-2'')')RI0
254		1	WRITE(KULOUT,'('' * Thermodynamic, gas *'')')
255		1	WRITE(KULOUT,'('' Perfect gas = '',e13.7)') R
256		1	WRITE(KULOUT,'('' Dry air mass = '',e13.7)') RMD
257		1	WRITE(KULOUT,'('' Vapour mass = '',e13.7)') RMV
258		1	WRITE(KULOUT,'('' Ozone mass = '',e13.7)') RMO3
259		1	WRITE(KULOUT,'('' Dry air cst. = '',e13.7)') RD
260		1	WRITE(KULOUT,'('' Vapour cst. = '',e13.7)') RV
261		1	WRITE(KULOUT,'('' Cpd = '',e13.7)') RCPD
262		1	WRITE(KULOUT,'('' Cvd = '',e13.7)') RCVD
263		1	WRITE(KULOUT,'('' Cpv = '',e13.7)') RCPV
264		1	WRITE(KULOUT,'('' Cvv = '',e13.7)') RCVV
265		1	WRITE(KULOUT,'('' Rd/Cpd = '',e13.7)') RKAPPA
266		1	WRITE(KULOUT,'('' Rv/Rd-1 = '',e13.7)') RETV
267		1	WRITE(KULOUT,'('' * Thermodynamic, liquid *'')')
268		1	WRITE(KULOUT,'('' Cw = '',E13.7)') RCW
269		1	WRITE(KULOUT,'('' * thermodynamic, solid *'')')
270		1	WRITE(KULOUT,'('' Cs = '',E13.7)') RCS
271		1	WRITE(KULOUT,'('' * Thermodynamic, trans. *'')')
272		1	WRITE(KULOUT,'('' Fusion point = '',E13.7)') RTT
273		1	WRITE(KULOUT,'('' RTT-Tx(ew-ei) = '',E13.7)') RDT
274		1	WRITE(KULOUT,'('' RLvTt = '',E13.7)') RLVTT
275		1	WRITE(KULOUT,'('' RLsTt = '',E13.7)') RLSTT
276		1	WRITE(KULOUT,'('' RLv0 = '',E13.7)') RLVZER
277		1	WRITE(KULOUT,'('' RLs0 = '',E13.7)') RLSZER
278		1	WRITE(KULOUT,'('' RLMlt = '',E13.7)') RLMLT
279		1	WRITE(KULOUT,'('' Normal press. = '',E13.7)') RATM
280		1	WRITE(KULOUT,'('' Latent heat : '')')
281	✓✗✓✓	10	WRITE(KULOUT,'(10(1X,E10.4))') (10._JPRB*J,J=-4,4)
282	✓✗✓✓	10	WRITE(KULOUT,'(10(1X,E10.4))') (RLV(RTT+10._JPRB*J),J=-4,4)
283	✓✗✓✓	10	WRITE(KULOUT,'(10(1X,E10.4))') (RLS(RTT+10._JPRB*J),J=-4,4)
284		1	WRITE(KULOUT,'('' * Thermodynamic, satur. *'')')
285		1	WRITE(KULOUT,'('' Fusion point = '',E13.7)') RTT
286		1	WRITE(KULOUT,'('' es(Tt) = '',e13.7)') RESTT
287		1	WRITE(KULOUT,'('' es(T) : '')')
288	✓✗✓✓	10	WRITE(KULOUT,'(10(1X,E10.4))') (10._JPRB*J,J=-4,4)
289	✓✗✓✓	10	WRITE(KULOUT,'(10(1X,E10.4))') (ESW(RTT+10._JPRB*J),J=-4,4)
290	✓✗✓✓	10	WRITE(KULOUT,'(10(1X,E10.4))') (ESS(RTT+10._JPRB*J),J=-4,4)
291			! call flush(0) !!!!! A REVOIR (MPL) les 7 lignes qui suivent
292	✓✓	10	do j=1,9
293		9	print*,'TEST J',j
294		9	print,'RTT...',RTT+10._JPRB(J-5)
295		10	print,'ES(RTT...',ES(RTT+10._JPRB(J-5))
296			enddo
297		1	call flush(0)
298
299	✓✗✓✓	10	WRITE(KULOUT,'(10(1X,E10.4))') (ES (RTT+10._JPRB*J),J=-4,4)
300			ENDIF
301
302			! ------------------------------------------------------------------
303
304	✓✗	1	IF (LHOOK) CALL DR_HOOK('SUCST',1,ZHOOK_HANDLE)
305		1	END SUBROUTINE SUCST
306