1 |
MODULE calendar |
MODULE calendar |
2 |
!$Header: /home/ioipsl/CVSROOT/IOIPSL/src/calendar.f90,v 2.0 2004/04/05 14:47:47 adm Exp $ |
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3 |
!- |
! From IOIPSL/src/calendar.f90, version 2.0 2004/04/05 14:47:47 |
4 |
!--------------------------------------------------------------------- |
|
5 |
!- This is the calendar which going to be used to do all |
! This is the calendar used to do all calculations on time. Three |
6 |
!- calculations on time. Three types of calendars are possible : |
! types of calendars are possible: |
7 |
!- - gregorian : The normal calendar. The time origin for the |
|
8 |
!- julian day in this case is 24 Nov -4713 |
! - Gregorian: |
9 |
!- - nolap : A 365 day year without leap years. |
! The normal calendar. The time origin for the julian day in this |
10 |
!- The origin for the julian days is in this case 1 Jan 0 |
! case is 24 Nov -4713. |
11 |
!- - xxxd : Year of xxx days with month of equal length. |
|
12 |
!- The origin for the julian days is then also 1 Jan 0 |
! - No leap: |
13 |
!- As one can see it is difficult to go from one calendar to the other. |
! A 365 day year without leap years. The origin for the julian days |
14 |
!- All operations involving julian days will be wrong. |
! is in this case 1 Jan 0. |
15 |
!- This calendar will lock as soon as possible |
|
16 |
!- the length of the year and forbid any further modification. |
! - xxxd: |
17 |
!- |
! Year of xxx days with months of equal length. The origin for the |
18 |
!- For the non leap-year calendar the method is still brute force. |
! julian days is then also 1 Jan 0. |
19 |
!- We need to find an Integer series which takes care of the length |
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20 |
!- of the various month. (Jan) |
! As one can see it is difficult to go from one calendar to the |
21 |
!- |
! other. All operations involving julian days will be wrong. This |
22 |
!- un_jour : one day in seconds |
! calendar will lock as soon as possible the length of the year and |
23 |
!- un_an : one year in days |
! forbid any further modification. |
24 |
!--------------------------------------------------------------------- |
|
25 |
USE strlowercase_m, ONLY : strlowercase |
! For the non leap-year calendar the method is still brute force. |
26 |
USE errioipsl, ONLY : histerr |
! We need to find an integer series which takes care of the length |
27 |
!- |
! of the various month. (Jan) |
28 |
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29 |
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USE strlowercase_m, ONLY: strlowercase |
30 |
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USE errioipsl, ONLY: histerr |
31 |
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32 |
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IMPLICIT NONE |
33 |
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34 |
PRIVATE |
PRIVATE |
35 |
PUBLIC :: ymds2ju,ju2ymds,isittime,ioconf_calendar, & |
PUBLIC ymds2ju, ju2ymds, isittime, ioconf_calendar, itau2date, lock_unan, & |
36 |
ioget_calendar,itau2date, ioconf_startdate |
calendar_used, un_an, un_jour |
37 |
!- |
|
38 |
INTERFACE ioget_calendar |
REAL, PARAMETER:: un_jour = 86400. ! one day in seconds |
39 |
MODULE PROCEDURE & |
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40 |
& ioget_calendar_real1,ioget_calendar_real2,ioget_calendar_str |
! Description of calendar |
41 |
END INTERFACE |
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42 |
!- |
CHARACTER(LEN=20):: calendar_used = "gregorian" |
43 |
REAL,PARAMETER :: un_jour = 86400.0 |
LOGICAL:: lock_unan = .FALSE. |
44 |
LOGICAL,SAVE :: lock_startdate = .FALSE. |
REAL:: un_an = 365.2425 ! one year in days |
45 |
!- |
INTEGER:: mon_len(12) = (/31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
46 |
CHARACTER(LEN=30),SAVE :: time_stamp='XXXXXXXXXXXXXXXX' |
|
47 |
!- |
CHARACTER(LEN=3), PARAMETER:: cal(12) = (/'JAN', 'FEB', 'MAR', 'APR', & |
48 |
!- Description of calendar |
'MAY', 'JUN', 'JUL', 'AUG', 'SEP', 'OCT', 'NOV', 'DEC'/) |
49 |
!- |
|
50 |
CHARACTER(LEN=20),SAVE :: calendar_used="gregorian" |
REAL, SAVE:: start_day, start_sec |
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LOGICAL,SAVE :: lock_unan = .FALSE. |
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REAL,SAVE :: un_an = 365.2425 |
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INTEGER,SAVE :: mon_len(12)=(/31,28,31,30,31,30,31,31,30,31,30,31/) |
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!- |
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!- |
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!- |
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CHARACTER(LEN=3),PARAMETER :: & |
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& cal(12) = (/'JAN','FEB','MAR','APR','MAY','JUN', & |
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& 'JUL','AUG','SEP','OCT','NOV','DEC'/) |
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!- |
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REAL,SAVE :: start_day,start_sec |
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51 |
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52 |
CONTAINS |
CONTAINS |
53 |
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54 |
SUBROUTINE ymds2ju (year,month,day,sec,julian) |
SUBROUTINE ymds2ju (year, month, day, sec, julian) |
55 |
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56 |
IMPLICIT NONE |
INTEGER, INTENT(IN):: year, month, day |
57 |
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REAL, INTENT(IN):: sec |
58 |
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REAL, INTENT(OUT):: julian |
59 |
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60 |
INTEGER,INTENT(IN) :: year,month,day |
INTEGER:: julian_day |
61 |
REAL,INTENT(IN) :: sec |
REAL:: julian_sec |
62 |
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|
63 |
REAL,INTENT(OUT) :: julian |
!-------------------------------------------------------------------- |
64 |
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|
65 |
INTEGER :: julian_day |
CALL ymds2ju_internal(year, month, day, sec, julian_day, julian_sec) |
66 |
REAL :: julian_sec |
julian = julian_day + julian_sec / un_jour |
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!--------------------------------------------------------------------- |
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CALL ymds2ju_internal (year,month,day,sec,julian_day,julian_sec) |
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67 |
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julian = julian_day+julian_sec / un_jour |
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!--------------------- |
|
68 |
END SUBROUTINE ymds2ju |
END SUBROUTINE ymds2ju |
69 |
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70 |
!=== |
!=== |
71 |
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72 |
SUBROUTINE ymds2ju_internal (year,month,day,sec,julian_day,julian_sec) |
SUBROUTINE ymds2ju_internal (year, month, day, sec, julian_day, julian_sec) |
|
!--------------------------------------------------------------------- |
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!- Converts year, month, day and seconds into a julian day |
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!- In 1968 in a letter to the editor of Communications of the ACM |
|
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!- (CACM, volume 11, number 10, October 1968, p.657) Henry F. Fliegel |
|
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!- and Thomas C. Van Flandern presented such an algorithm. |
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!- See also : http://www.magnet.ch/serendipity/hermetic/cal_stud/jdn.htm |
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!- In the case of the Gregorian calendar we have chosen to use |
|
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!- the Lilian day numbers. This is the day counter which starts |
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!- on the 15th October 1582. |
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!- This is the day at which Pope Gregory XIII introduced the |
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!- Gregorian calendar. |
|
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!- Compared to the true Julian calendar, which starts some |
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!- 7980 years ago, the Lilian days are smaler and are dealt with |
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!- easily on 32 bit machines. With the true Julian days you can only |
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!- the fraction of the day in the real part to a precision of |
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!- a 1/4 of a day with 32 bits. |
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!--------------------------------------------------------------------- |
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IMPLICIT NONE |
|
73 |
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|
74 |
INTEGER,INTENT(IN) :: year,month,day |
! Converts year, month, day and seconds into a julian day |
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REAL,INTENT(IN) :: sec |
|
75 |
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76 |
INTEGER,INTENT(OUT) :: julian_day |
! In 1968 in a letter to the editor of Communications of the ACM |
77 |
REAL,INTENT(OUT) :: julian_sec |
! (CACM, volume 11, number 10, October 1968, p.657) Henry F. Fliegel |
78 |
|
! and Thomas C. Van Flandern presented such an algorithm. |
79 |
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80 |
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! See also: http://www.magnet.ch/serendipity/hermetic/cal_stud/jdn.htm |
81 |
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82 |
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! In the case of the Gregorian calendar we have chosen to use |
83 |
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! the Lilian day numbers. This is the day counter which starts |
84 |
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! on the 15th October 1582. |
85 |
|
! This is the day at which Pope Gregory XIII introduced the |
86 |
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! Gregorian calendar. |
87 |
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! Compared to the true Julian calendar, which starts some |
88 |
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! 7980 years ago, the Lilian days are smaler and are dealt with |
89 |
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! easily on 32 bit machines. With the true Julian days you can only |
90 |
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! the fraction of the day in the real part to a precision of |
91 |
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! a 1/4 of a day with 32 bits. |
92 |
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93 |
INTEGER :: jd,m,y,d,ml |
INTEGER, INTENT(IN):: year, month, day |
94 |
!--------------------------------------------------------------------- |
REAL, INTENT(IN):: sec |
95 |
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96 |
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INTEGER, INTENT(OUT):: julian_day |
97 |
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REAL, INTENT(OUT):: julian_sec |
98 |
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99 |
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INTEGER:: jd, m, y, d, ml |
100 |
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!-------------------------------------------------------------------- |
101 |
lock_unan = .TRUE. |
lock_unan = .TRUE. |
102 |
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|
103 |
m = month |
m = month |
104 |
y = year |
y = year |
105 |
d = day |
d = day |
106 |
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|
107 |
!- We deduce the calendar from the length of the year as it |
! We deduce the calendar from the length of the year as it |
108 |
!- is faster than an INDEX on the calendar variable. |
! is faster than an INDEX on the calendar variable. |
109 |
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|
110 |
!- Gregorian |
! Gregorian |
111 |
IF ( (un_an > 365.0).AND.(un_an < 366.0) ) THEN |
IF ( (un_an > 365.0).AND.(un_an < 366.0) ) THEN |
112 |
jd = (1461*(y+4800+INT(( m-14 )/12)))/4 & |
jd = (1461*(y+4800+INT(( m-14 )/12)))/4 & |
113 |
& +(367*(m-2-12*(INT(( m-14 )/12))))/12 & |
& +(367*(m-2-12*(INT(( m-14 )/12))))/12 & |
114 |
& -(3*((y+4900+INT((m-14)/12))/100))/4 & |
& -(3*((y+4900+INT((m-14)/12))/100))/4 & |
115 |
& +d-32075 |
& +d-32075 |
116 |
jd = jd-2299160 |
jd = jd-2299160 |
117 |
!- No leap or All leap |
! No leap or All leap |
118 |
ELSE IF (ABS(un_an-365.0) <= EPSILON(un_an) .OR. & |
ELSE IF (ABS(un_an-365.0) <= EPSILON(un_an) .OR. & |
119 |
& ABS(un_an-366.0) <= EPSILON(un_an)) THEN |
& ABS(un_an-366.0) <= EPSILON(un_an)) THEN |
120 |
ml = SUM(mon_len(1:m-1)) |
ml = SUM(mon_len(1:m-1)) |
121 |
jd = y*INT(un_an)+ml+(d-1) |
jd = y*INT(un_an)+ml+(d-1) |
122 |
!- Calendar with regular month |
! Calendar with regular month |
123 |
ELSE |
ELSE |
124 |
ml = INT(un_an)/12 |
ml = INT(un_an)/12 |
125 |
jd = y*INT(un_an)+(m-1)*ml+(d-1) |
jd = y*INT(un_an)+(m-1)*ml+(d-1) |
127 |
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|
128 |
julian_day = jd |
julian_day = jd |
129 |
julian_sec = sec |
julian_sec = sec |
130 |
!------------------------------ |
|
131 |
END SUBROUTINE ymds2ju_internal |
END SUBROUTINE ymds2ju_internal |
132 |
!- |
|
133 |
!=== |
!=== |
134 |
!- |
|
135 |
SUBROUTINE ju2ymds (julian,year,month,day,sec) |
SUBROUTINE ju2ymds (julian, year, month, day, sec) |
136 |
!--------------------------------------------------------------------- |
|
137 |
IMPLICIT NONE |
REAL, INTENT(IN):: julian |
138 |
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|
139 |
REAL,INTENT(IN) :: julian |
INTEGER, INTENT(OUT):: year, month, day |
140 |
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REAL, INTENT(OUT):: sec |
141 |
INTEGER,INTENT(OUT) :: year,month,day |
|
142 |
REAL,INTENT(OUT) :: sec |
INTEGER:: julian_day |
143 |
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REAL:: julian_sec |
144 |
INTEGER :: julian_day |
!-------------------------------------------------------------------- |
|
REAL :: julian_sec |
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!--------------------------------------------------------------------- |
|
145 |
julian_day = INT(julian) |
julian_day = INT(julian) |
146 |
julian_sec = (julian-julian_day)*un_jour |
julian_sec = (julian-julian_day)*un_jour |
147 |
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148 |
CALL ju2ymds_internal(julian_day,julian_sec,year,month,day,sec) |
CALL ju2ymds_internal(julian_day, julian_sec, year, month, day, sec) |
149 |
!--------------------- |
|
150 |
END SUBROUTINE ju2ymds |
END SUBROUTINE ju2ymds |
151 |
!- |
|
152 |
!=== |
!=== |
153 |
!- |
|
154 |
SUBROUTINE ju2ymds_internal (julian_day,julian_sec,year,month,day,sec) |
SUBROUTINE ju2ymds_internal (julian_day, julian_sec, year, month, day, sec) |
155 |
!--------------------------------------------------------------------- |
|
156 |
!- This subroutine computes from the julian day the year, |
! This subroutine computes from the julian day the year, |
157 |
!- month, day and seconds |
! month, day and seconds |
158 |
|
|
159 |
!- In 1968 in a letter to the editor of Communications of the ACM |
! In 1968 in a letter to the editor of Communications of the ACM |
160 |
!- (CACM, volume 11, number 10, October 1968, p.657) Henry F. Fliegel |
! (CACM, volume 11, number 10, October 1968, p.657) Henry F. Fliegel |
161 |
!- and Thomas C. Van Flandern presented such an algorithm. |
! and Thomas C. Van Flandern presented such an algorithm. |
162 |
|
|
163 |
!- See also : http://www.magnet.ch/serendipity/hermetic/cal_stud/jdn.htm |
! See also: http://www.magnet.ch/serendipity/hermetic/cal_stud/jdn.htm |
164 |
|
|
165 |
!- In the case of the Gregorian calendar we have chosen to use |
! In the case of the Gregorian calendar we have chosen to use |
166 |
!- the Lilian day numbers. This is the day counter which starts |
! the Lilian day numbers. This is the day counter which starts |
167 |
!- on the 15th October 1582. This is the day at which Pope |
! on the 15th October 1582. This is the day at which Pope |
168 |
!- Gregory XIII introduced the Gregorian calendar. |
! Gregory XIII introduced the Gregorian calendar. |
169 |
!- Compared to the true Julian calendar, which starts some 7980 |
! Compared to the true Julian calendar, which starts some 7980 |
170 |
!- years ago, the Lilian days are smaler and are dealt with easily |
! years ago, the Lilian days are smaler and are dealt with easily |
171 |
!- on 32 bit machines. With the true Julian days you can only the |
! on 32 bit machines. With the true Julian days you can only the |
172 |
!- fraction of the day in the real part to a precision of a 1/4 of |
! fraction of the day in the real part to a precision of a 1/4 of |
173 |
!- a day with 32 bits. |
! a day with 32 bits. |
174 |
!--------------------------------------------------------------------- |
|
175 |
IMPLICIT NONE |
INTEGER, INTENT(IN):: julian_day |
176 |
|
REAL, INTENT(IN):: julian_sec |
177 |
INTEGER,INTENT(IN) :: julian_day |
|
178 |
REAL,INTENT(IN) :: julian_sec |
INTEGER, INTENT(OUT):: year, month, day |
179 |
|
REAL, INTENT(OUT):: sec |
180 |
INTEGER,INTENT(OUT) :: year,month,day |
|
181 |
REAL,INTENT(OUT) :: sec |
INTEGER:: l, n, i, jd, j, d, m, y, ml |
182 |
|
INTEGER:: add_day |
183 |
INTEGER :: l,n,i,jd,j,d,m,y,ml |
!-------------------------------------------------------------------- |
|
INTEGER :: add_day |
|
|
!--------------------------------------------------------------------- |
|
184 |
lock_unan = .TRUE. |
lock_unan = .TRUE. |
185 |
|
|
186 |
jd = julian_day |
jd = julian_day |
191 |
jd = jd+add_day |
jd = jd+add_day |
192 |
ENDIF |
ENDIF |
193 |
|
|
194 |
!- Gregorian |
! Gregorian |
195 |
IF ( (un_an > 365.0).AND.(un_an < 366.0) ) THEN |
IF ( (un_an > 365.0).AND.(un_an < 366.0) ) THEN |
196 |
jd = jd+2299160 |
jd = jd+2299160 |
197 |
|
|
205 |
l = j/11 |
l = j/11 |
206 |
m = j+2-(12*l) |
m = j+2-(12*l) |
207 |
y = 100*(n-49)+i+l |
y = 100*(n-49)+i+l |
208 |
!- No leap or All leap |
! No leap or All leap |
209 |
ELSE IF (ABS(un_an-365.0) <= EPSILON(un_an) .OR. & |
ELSE IF (ABS(un_an-365.0) <= EPSILON(un_an) .OR. & |
210 |
& ABS(un_an-366.0) <= EPSILON(un_an) ) THEN |
& ABS(un_an-366.0) <= EPSILON(un_an) ) THEN |
211 |
y = jd/INT(un_an) |
y = jd/INT(un_an) |
217 |
m = m+1 |
m = m+1 |
218 |
ENDDO |
ENDDO |
219 |
d = l-ml+1 |
d = l-ml+1 |
220 |
!- others |
! others |
221 |
ELSE |
ELSE |
222 |
ml = INT(un_an)/12 |
ml = INT(un_an)/12 |
223 |
y = jd/INT(un_an) |
y = jd/INT(un_an) |
229 |
day = d |
day = d |
230 |
month = m |
month = m |
231 |
year = y |
year = y |
232 |
!------------------------------ |
|
233 |
END SUBROUTINE ju2ymds_internal |
END SUBROUTINE ju2ymds_internal |
234 |
!- |
|
235 |
!=== |
!=== |
236 |
!- |
|
237 |
REAL FUNCTION itau2date (itau,date0,deltat) |
REAL FUNCTION itau2date (itau, date0, deltat) |
238 |
!--------------------------------------------------------------------- |
|
239 |
!- This function transforms itau into a date. The date whith which |
! This function transforms itau into a date. The date whith which |
240 |
!- the time axis is going to be labeled |
! the time axis is going to be labeled |
241 |
|
|
242 |
!- INPUT |
! INPUT |
243 |
!- itau : current time step |
! itau: current time step |
244 |
!- date0 : Date at which itau was equal to 0 |
! date0: Date at which itau was equal to 0 |
245 |
!- deltat : time step between itau s |
! deltat: time step between itau s |
246 |
|
|
247 |
!- OUTPUT |
! OUTPUT |
248 |
!- itau2date : Date for the given itau |
! itau2date: Date for the given itau |
249 |
!--------------------------------------------------------------------- |
|
250 |
IMPLICIT NONE |
INTEGER:: itau |
251 |
|
REAL:: date0, deltat |
252 |
INTEGER :: itau |
!-------------------------------------------------------------------- |
|
REAL :: date0,deltat |
|
|
!--------------------------------------------------------------------- |
|
253 |
itau2date = REAL(itau)*deltat/un_jour+date0 |
itau2date = REAL(itau)*deltat/un_jour+date0 |
254 |
!--------------------- |
|
255 |
END FUNCTION itau2date |
END FUNCTION itau2date |
256 |
!- |
|
257 |
!=== |
!=== |
258 |
!- |
|
259 |
SUBROUTINE isittime & |
SUBROUTINE isittime & |
260 |
& (itau,date0,dt,freq,last_action,last_check,do_action) |
& (itau, date0, dt, freq, last_action, last_check, do_action) |
261 |
!--------------------------------------------------------------------- |
|
262 |
!- This subroutine checks the time has come for a given action. |
! This subroutine checks the time has come for a given action. |
263 |
!- This is computed from the current time-step(itau). |
! This is computed from the current time-step(itau). |
264 |
!- Thus we need to have the time delta (dt), the frequency |
! Thus we need to have the time delta (dt), the frequency |
265 |
!- of the action (freq) and the last time it was done |
! of the action (freq) and the last time it was done |
266 |
!- (last_action in units of itau). |
! (last_action in units of itau). |
267 |
!- In order to extrapolate when will be the next check we need |
! In order to extrapolate when will be the next check we need |
268 |
!- the time step of the last call (last_check). |
! the time step of the last call (last_check). |
269 |
|
|
270 |
!- The test is done on the following condition : |
! The test is done on the following condition: |
271 |
!- the distance from the current time to the time for the next |
! the distance from the current time to the time for the next |
272 |
!- action is smaller than the one from the next expected |
! action is smaller than the one from the next expected |
273 |
!- check to the next action. |
! check to the next action. |
274 |
!- When the test is done on the time steps simplifactions make |
! When the test is done on the time steps simplifactions make |
275 |
!- it more difficult to read in the code. |
! it more difficult to read in the code. |
276 |
!- For the real time case it is easier to understand ! |
! For the real time case it is easier to understand ! |
277 |
!--------------------------------------------------------------------- |
|
278 |
IMPLICIT NONE |
INTEGER, INTENT(IN):: itau |
279 |
|
REAL, INTENT(IN):: dt, freq |
280 |
INTEGER,INTENT(IN) :: itau |
INTEGER, INTENT(IN):: last_action, last_check |
281 |
REAL,INTENT(IN) :: dt,freq |
REAL, INTENT(IN):: date0 |
282 |
INTEGER,INTENT(IN) :: last_action,last_check |
|
283 |
REAL,INTENT(IN) :: date0 |
LOGICAL, INTENT(OUT):: do_action |
284 |
|
|
285 |
LOGICAL,INTENT(OUT) :: do_action |
REAL:: dt_action, dt_check |
286 |
|
REAL:: date_last_act, date_next_check, date_next_act, & |
287 |
REAL :: dt_action,dt_check |
& date_now, date_mp1, date_mpf |
288 |
REAL :: date_last_act,date_next_check,date_next_act, & |
INTEGER:: year, month, monthp1, day, next_check_itau, next_act_itau |
289 |
& date_now,date_mp1,date_mpf |
INTEGER:: yearp, dayp |
290 |
INTEGER :: year,month,monthp1,day,next_check_itau,next_act_itau |
REAL:: sec, secp |
291 |
INTEGER :: yearp,dayp |
LOGICAL:: check = .FALSE. |
292 |
REAL :: sec,secp |
!-------------------------------------------------------------------- |
|
LOGICAL :: check = .FALSE. |
|
|
!--------------------------------------------------------------------- |
|
293 |
IF (check) THEN |
IF (check) THEN |
294 |
WRITE(*,*) & |
WRITE(*, *) & |
295 |
& "isittime 1.0 ",itau,date0,dt,freq,last_action,last_check |
& "isittime 1.0 ", itau, date0, dt, freq, last_action, last_check |
296 |
ENDIF |
ENDIF |
297 |
|
|
298 |
IF (last_check >= 0) THEN |
IF (last_check >= 0) THEN |
300 |
dt_check = (itau-last_check)*dt |
dt_check = (itau-last_check)*dt |
301 |
next_check_itau = itau+(itau-last_check) |
next_check_itau = itau+(itau-last_check) |
302 |
|
|
303 |
!-- We are dealing with frequencies in seconds and thus operation |
!- We are dealing with frequencies in seconds and thus operation |
304 |
!-- can be done on the time steps. |
!- can be done on the time steps. |
305 |
|
|
306 |
IF (freq > 0) THEN |
IF (freq > 0) THEN |
307 |
IF (ABS(dt_action-freq) <= ABS(dt_action+dt_check-freq)) THEN |
IF (ABS(dt_action-freq) <= ABS(dt_action+dt_check-freq)) THEN |
310 |
do_action = .FALSE. |
do_action = .FALSE. |
311 |
ENDIF |
ENDIF |
312 |
|
|
313 |
!---- Here we deal with frequencies in month and work on julian days. |
!--- Here we deal with frequencies in month and work on julian days. |
314 |
|
|
315 |
ELSE |
ELSE |
316 |
date_now = itau2date (itau,date0,dt) |
date_now = itau2date (itau, date0, dt) |
317 |
date_last_act = itau2date (last_action,date0,dt) |
date_last_act = itau2date (last_action, date0, dt) |
318 |
CALL ju2ymds (date_last_act,year,month,day,sec) |
CALL ju2ymds (date_last_act, year, month, day, sec) |
319 |
monthp1 = month-freq |
monthp1 = month - freq |
320 |
yearp = year |
yearp = year |
321 |
|
|
322 |
!---- Here we compute what logically should be the next month |
!--- Here we compute what logically should be the next month |
323 |
|
|
324 |
IF (month >= 13) THEN |
IF (month >= 13) THEN |
325 |
yearp = year+1 |
yearp = year+1 |
326 |
monthp1 = monthp1-12 |
monthp1 = monthp1-12 |
327 |
ENDIF |
ENDIF |
328 |
CALL ymds2ju (year,monthp1,day,sec,date_mpf) |
CALL ymds2ju (year, monthp1, day, sec, date_mpf) |
329 |
|
|
330 |
!---- But it could be that because of a shorter month or a bad |
!--- But it could be that because of a shorter month or a bad |
331 |
!---- starting date that we end up further than we should be. |
!--- starting date that we end up further than we should be. |
332 |
!---- Thus we compute the first day of the next month. |
!--- Thus we compute the first day of the next month. |
333 |
!---- We can not be beyond this date and if we are close |
!--- We can not be beyond this date and if we are close |
334 |
!---- then we will take it as it is better. |
!--- then we will take it as it is better. |
335 |
|
|
336 |
monthp1 = month+ABS(freq) |
monthp1 = month+ABS(freq) |
337 |
yearp=year |
yearp=year |
341 |
ENDIF |
ENDIF |
342 |
dayp = 1 |
dayp = 1 |
343 |
secp = 0.0 |
secp = 0.0 |
344 |
CALL ymds2ju (yearp,monthp1,dayp,secp,date_mp1) |
CALL ymds2ju (yearp, monthp1, dayp, secp, date_mp1) |
345 |
|
|
346 |
!---- If date_mp1 is smaller than date_mpf or only less than 4 days |
!--- If date_mp1 is smaller than date_mpf or only less than 4 days |
347 |
!---- larger then we take it. This needed to ensure that short month |
!--- larger then we take it. This needed to ensure that short month |
348 |
!---- like February do not mess up the thing ! |
!--- like February do not mess up the thing ! |
349 |
|
|
350 |
IF (date_mp1-date_mpf < 4.) THEN |
IF (date_mp1-date_mpf < 4.) THEN |
351 |
date_next_act = date_mp1 |
date_next_act = date_mp1 |
352 |
ELSE |
ELSE |
353 |
date_next_act = date_mpf |
date_next_act = date_mpf |
354 |
ENDIF |
ENDIF |
355 |
date_next_check = itau2date (next_check_itau,date0,dt) |
date_next_check = itau2date (next_check_itau, date0, dt) |
356 |
|
|
357 |
!---- Transform the dates into time-steps for the needed precisions. |
!--- Transform the dates into time-steps for the needed precisions. |
358 |
|
|
359 |
next_act_itau = & |
next_act_itau = & |
360 |
& last_action+INT((date_next_act-date_last_act)*(un_jour/dt)) |
& last_action+INT((date_next_act-date_last_act)*(un_jour/dt)) |
361 |
!----- |
|
362 |
IF ( ABS(itau-next_act_itau) & |
IF ( ABS(itau-next_act_itau) & |
363 |
& <= ABS( next_check_itau-next_act_itau)) THEN |
& <= ABS( next_check_itau-next_act_itau)) THEN |
364 |
do_action = .TRUE. |
do_action = .TRUE. |
365 |
IF (check) THEN |
IF (check) THEN |
366 |
WRITE(*,*) & |
WRITE(*, *) & |
367 |
& 'ACT-TIME : itau, next_act_itau, next_check_itau : ', & |
& 'ACT-TIME: itau, next_act_itau, next_check_itau: ', & |
368 |
& itau,next_act_itau,next_check_itau |
& itau, next_act_itau, next_check_itau |
369 |
CALL ju2ymds (date_now,year,month,day,sec) |
CALL ju2ymds (date_now, year, month, day, sec) |
370 |
WRITE(*,*) 'ACT-TIME : y, m, d, s : ',year,month,day,sec |
WRITE(*, *) 'ACT-TIME: y, m, d, s: ', year, month, day, sec |
371 |
WRITE(*,*) & |
WRITE(*, *) & |
372 |
& 'ACT-TIME : date_mp1, date_mpf : ',date_mp1,date_mpf |
& 'ACT-TIME: date_mp1, date_mpf: ', date_mp1, date_mpf |
373 |
ENDIF |
ENDIF |
374 |
ELSE |
ELSE |
375 |
do_action = .FALSE. |
do_action = .FALSE. |
377 |
ENDIF |
ENDIF |
378 |
|
|
379 |
IF (check) THEN |
IF (check) THEN |
380 |
WRITE(*,*) "isittime 2.0 ", & |
WRITE(*, *) "isittime 2.0 ", & |
381 |
& date_next_check,date_next_act,ABS(dt_action-freq), & |
& date_next_check, date_next_act, ABS(dt_action-freq), & |
382 |
& ABS(dt_action+dt_check-freq),dt_action,dt_check, & |
& ABS(dt_action+dt_check-freq), dt_action, dt_check, & |
383 |
& next_check_itau,do_action |
& next_check_itau, do_action |
384 |
ENDIF |
ENDIF |
385 |
ELSE |
ELSE |
386 |
do_action=.FALSE. |
do_action=.FALSE. |
387 |
ENDIF |
ENDIF |
388 |
!---------------------- |
|
389 |
END SUBROUTINE isittime |
END SUBROUTINE isittime |
390 |
!- |
|
391 |
!=== |
!=== |
392 |
!- |
|
393 |
SUBROUTINE ioconf_calendar (str) |
SUBROUTINE ioconf_calendar (str) |
394 |
!--------------------------------------------------------------------- |
|
395 |
!- This routine allows to configure the calendar to be used. |
! This routine allows to configure the calendar to be used. |
396 |
!- This operation is only allowed once and the first call to |
! This operation is only allowed once and the first call to |
397 |
!- ymds2ju or ju2ymsd will lock the current configuration. |
! ymds2ju or ju2ymsd will lock the current configuration. |
398 |
!- the argument to ioconf_calendar can be any of the following : |
! the argument to ioconf_calendar can be any of the following: |
399 |
!- - gregorian : This is the gregorian calendar (default here) |
! - gregorian: This is the gregorian calendar (default here) |
400 |
!- - noleap : A calendar without leap years = 365 days |
! - noleap: A calendar without leap years = 365 days |
401 |
!- - xxxd : A calendar of xxx days (has to be a modulo of 12) |
! - xxxd: A calendar of xxx days (has to be a modulo of 12) |
402 |
!- with 12 month of equal length |
! with 12 month of equal length |
403 |
!--------------------------------------------------------------------- |
|
404 |
IMPLICIT NONE |
CHARACTER(LEN=*), INTENT(IN):: str |
405 |
|
|
406 |
CHARACTER(LEN=*),INTENT(IN) :: str |
INTEGER:: leng, ipos |
407 |
|
CHARACTER(LEN=10):: str10 |
408 |
INTEGER :: leng,ipos |
!-------------------------------------------------------------------- |
|
CHARACTER(LEN=10) :: str10 |
|
|
!--------------------------------------------------------------------- |
|
409 |
|
|
410 |
! 1.0 Clean up the sring ! |
! 1.0 Clean up the sring ! |
411 |
|
|
412 |
CALL strlowercase (str) |
CALL strlowercase (str) |
413 |
|
|
414 |
IF (.NOT.lock_unan) THEN |
IF (.NOT.lock_unan) THEN |
415 |
!--- |
|
416 |
lock_unan=.TRUE. |
lock_unan=.TRUE. |
417 |
!--- |
|
418 |
SELECT CASE(str) |
SELECT CASE(str) |
419 |
CASE('gregorian') |
CASE('gregorian') |
420 |
calendar_used = 'gregorian' |
calendar_used = 'gregorian' |
421 |
un_an = 365.2425 |
un_an = 365.2425 |
422 |
mon_len(:)=(/31,28,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
423 |
CASE('standard') |
CASE('standard') |
424 |
calendar_used = 'gregorian' |
calendar_used = 'gregorian' |
425 |
un_an = 365.2425 |
un_an = 365.2425 |
426 |
mon_len(:)=(/31,28,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
427 |
CASE('proleptic_gregorian') |
CASE('proleptic_gregorian') |
428 |
calendar_used = 'gregorian' |
calendar_used = 'gregorian' |
429 |
un_an = 365.2425 |
un_an = 365.2425 |
430 |
mon_len(:)=(/31,28,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
431 |
CASE('noleap') |
CASE('noleap') |
432 |
calendar_used = 'noleap' |
calendar_used = 'noleap' |
433 |
un_an = 365.0 |
un_an = 365.0 |
434 |
mon_len(:)=(/31,28,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
435 |
CASE('365_day') |
CASE('365_day') |
436 |
calendar_used = 'noleap' |
calendar_used = 'noleap' |
437 |
un_an = 365.0 |
un_an = 365.0 |
438 |
mon_len(:)=(/31,28,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
439 |
CASE('365d') |
CASE('365d') |
440 |
calendar_used = 'noleap' |
calendar_used = 'noleap' |
441 |
un_an = 365.0 |
un_an = 365.0 |
442 |
mon_len(:)=(/31,28,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
443 |
CASE('all_leap') |
CASE('all_leap') |
444 |
calendar_used = 'all_leap' |
calendar_used = 'all_leap' |
445 |
un_an = 366.0 |
un_an = 366.0 |
446 |
mon_len(:)=(/31,29,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
447 |
CASE('366_day') |
CASE('366_day') |
448 |
calendar_used = 'all_leap' |
calendar_used = 'all_leap' |
449 |
un_an = 366.0 |
un_an = 366.0 |
450 |
mon_len(:)=(/31,29,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
451 |
CASE('366d') |
CASE('366d') |
452 |
calendar_used = 'all_leap' |
calendar_used = 'all_leap' |
453 |
un_an = 366.0 |
un_an = 366.0 |
454 |
mon_len(:)=(/31,29,31,30,31,30,31,31,30,31,30,31/) |
mon_len(:)=(/31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31/) |
455 |
CASE DEFAULT |
CASE DEFAULT |
456 |
ipos = INDEX(str,'d') |
ipos = INDEX(str, 'd') |
457 |
IF (ipos == 4) THEN |
IF (ipos == 4) THEN |
458 |
READ(str(1:3),'(I3)') leng |
READ(str(1:3), '(I3)') leng |
459 |
IF ( (MOD(leng,12) == 0).AND.(leng > 1) ) THEN |
IF ( (MOD(leng, 12) == 0).AND.(leng > 1) ) THEN |
460 |
calendar_used = str |
calendar_used = str |
461 |
un_an = leng |
un_an = leng |
462 |
mon_len(:) = leng |
mon_len(:) = leng |
463 |
ELSE |
ELSE |
464 |
CALL histerr (3,'ioconf_calendar', & |
CALL histerr (3, 'ioconf_calendar', & |
465 |
& 'The length of the year as to be a modulo of 12', & |
& 'The length of the year as to be a modulo of 12', & |
466 |
& 'so that it can be divided into 12 month of equal length', & |
& 'so that it can be divided into 12 month of equal length', & |
467 |
& str) |
& str) |
468 |
ENDIF |
ENDIF |
469 |
ELSE |
ELSE |
470 |
CALL histerr (3,'ioconf_calendar', & |
CALL histerr (3, 'ioconf_calendar', & |
471 |
& 'Unrecognized input, please ceck the man pages.',str,' ') |
& 'Unrecognized input, please ceck the man pages.', str, ' ') |
472 |
ENDIF |
ENDIF |
473 |
END SELECT |
END SELECT |
474 |
ELSE |
ELSE |
475 |
WRITE(str10,'(f10.4)') un_an |
WRITE(str10, '(f10.4)') un_an |
476 |
CALL histerr (2,'ioconf_calendar', & |
CALL histerr (2, 'ioconf_calendar', & |
477 |
& 'The calendar was already used or configured. You are not', & |
& 'The calendar was already used or configured. You are not', & |
478 |
& 'allowed to change it again. '// & |
& 'allowed to change it again. '// & |
479 |
& 'The following length of year is used :',str10) |
& 'The following length of year is used:', str10) |
480 |
ENDIF |
ENDIF |
|
!----------------------------- |
|
|
END SUBROUTINE ioconf_calendar |
|
|
!- |
|
|
!=== |
|
|
!- |
|
|
SUBROUTINE ioget_calendar_str (str) |
|
|
!--------------------------------------------------------------------- |
|
|
!- This subroutine returns the name of the calendar used here. |
|
|
!- Three options exist : |
|
|
!- - gregorian : This is the gregorian calendar (default here) |
|
|
!- - noleap : A calendar without leap years = 365 days |
|
|
!- - xxxd : A calendar of xxx days (has to be a modulo of 12) |
|
|
!- with 12 month of equal length |
|
|
|
|
|
!- This routine will lock the calendar. |
|
|
!- You do not want it to change after your inquiry. |
|
|
!--------------------------------------------------------------------- |
|
|
IMPLICIT NONE |
|
|
|
|
|
CHARACTER(LEN=*),INTENT(OUT) :: str |
|
|
!--------------------------------------------------------------------- |
|
|
lock_unan = .TRUE. |
|
|
|
|
|
str = calendar_used |
|
|
!-------------------------------- |
|
|
END SUBROUTINE ioget_calendar_str |
|
|
!- |
|
|
!=== |
|
|
!- |
|
|
SUBROUTINE ioget_calendar_real1 (long_an) |
|
|
!--------------------------------------------------------------------- |
|
|
!- This subroutine returns the name of the calendar used here. |
|
|
!- Three options exist : |
|
|
!- - gregorian : This is the gregorian calendar (default here) |
|
|
!- - noleap : A calendar without leap years = 365 days |
|
|
!- - xxxd : A calendar of xxx days (has to be a modulo of 12) |
|
|
!- with 12 month of equal length |
|
|
|
|
|
!- This routine will lock the calendar. |
|
|
!- You do not want it to change after your inquiry. |
|
|
!--------------------------------------------------------------------- |
|
|
IMPLICIT NONE |
|
481 |
|
|
482 |
REAL,INTENT(OUT) :: long_an |
END SUBROUTINE ioconf_calendar |
|
!--------------------------------------------------------------------- |
|
|
lock_unan = .TRUE. |
|
|
|
|
|
long_an = un_an |
|
|
!---------------------------------- |
|
|
END SUBROUTINE ioget_calendar_real1 |
|
|
!- |
|
|
!=== |
|
|
!- |
|
|
SUBROUTINE ioget_calendar_real2 (long_an,long_jour) |
|
|
!--------------------------------------------------------------------- |
|
|
!- This subroutine returns the name of the calendar used here. |
|
|
!- Three options exist : |
|
|
!- - gregorian : This is the gregorian calendar (default here) |
|
|
!- - noleap : A calendar without leap years = 365 days |
|
|
!- - xxxd : A calendar of xxx days (has to be a modulo of 12) |
|
|
!- with 12 month of equal length |
|
|
|
|
|
!- This routine will lock the calendar. |
|
|
!- You do not want it to change after your inquiry. |
|
|
!--------------------------------------------------------------------- |
|
|
IMPLICIT NONE |
|
|
|
|
|
REAL,INTENT(OUT) :: long_an,long_jour |
|
|
!--------------------------------------------------------------------- |
|
|
lock_unan = .TRUE. |
|
|
|
|
|
long_an = un_an |
|
|
long_jour = un_jour |
|
|
!---------------------------------- |
|
|
END SUBROUTINE ioget_calendar_real2 |
|
483 |
|
|
484 |
END MODULE calendar |
END MODULE calendar |