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409 lines
13 KiB
Fortran
409 lines
13 KiB
Fortran
*DECK LSOD
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SUBROUTINE LSOD (F, NEQ, T, Y, TOUT, RTOL, ATOL, IDID, YPOUT, YH,
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+ YH1, EWT, SAVF, ACOR, WM, IWM, JAC, INTOUT, TSTOP, TOLFAC,
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+ DELSGN, RPAR, IPAR)
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C***BEGIN PROLOGUE LSOD
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C***SUBSIDIARY
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C***PURPOSE Subsidiary to DEBDF
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C***LIBRARY SLATEC
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C***TYPE SINGLE PRECISION (LSOD-S, DLSOD-D)
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C***AUTHOR (UNKNOWN)
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C***DESCRIPTION
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C
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C DEBDF merely allocates storage for LSOD to relieve the user of
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C the inconvenience of a long call list. Consequently LSOD is used
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C as described in the comments for DEBDF .
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C
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C***SEE ALSO DEBDF
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C***ROUTINES CALLED HSTART, INTYD, R1MACH, STOD, VNWRMS, XERMSG
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C***COMMON BLOCKS DEBDF1
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C***REVISION HISTORY (YYMMDD)
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C 800901 DATE WRITTEN
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C 890531 Changed all specific intrinsics to generic. (WRB)
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C 890831 Modified array declarations. (WRB)
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C 891214 Prologue converted to Version 4.0 format. (BAB)
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C 900328 Added TYPE section. (WRB)
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C 900510 Convert XERRWV calls to XERMSG calls. (RWC)
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C***END PROLOGUE LSOD
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C
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C
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LOGICAL INTOUT
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C
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DIMENSION Y(*),YPOUT(*),YH(NEQ,6),YH1(*),EWT(*),SAVF(*),
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1 ACOR(*),WM(*),IWM(*),RTOL(*),ATOL(*),RPAR(*),IPAR(*)
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CHARACTER*8 XERN1
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CHARACTER*16 XERN3, XERN4
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C
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COMMON /DEBDF1/ TOLD, ROWNS(210),
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1 EL0, H, HMIN, HMXI, HU, X, U,
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2 IQUIT, INIT, LYH, LEWT, LACOR, LSAVF, LWM, KSTEPS,
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3 IBEGIN, ITOL, IINTEG, ITSTOP, IJAC, IBAND, IOWNS(6),
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4 IER, JSTART, KFLAG, LDUM, METH, MITER, MAXORD, N, NQ, NST,
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5 NFE, NJE, NQU
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C
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EXTERNAL F, JAC
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C
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C.......................................................................
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C
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C THE EXPENSE OF SOLVING THE PROBLEM IS MONITORED BY COUNTING THE
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C NUMBER OF STEPS ATTEMPTED. WHEN THIS EXCEEDS MAXNUM, THE COUNTER
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C IS RESET TO ZERO AND THE USER IS INFORMED ABOUT POSSIBLE EXCESSIVE
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C WORK.
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C
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SAVE MAXNUM
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DATA MAXNUM/500/
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C
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C.......................................................................
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C
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C***FIRST EXECUTABLE STATEMENT LSOD
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IF (IBEGIN .EQ. 0) THEN
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C
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C ON THE FIRST CALL , PERFORM INITIALIZATION --
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C DEFINE THE MACHINE UNIT ROUNDOFF QUANTITY U BY CALLING THE
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C FUNCTION ROUTINE R1MACH. THE USER MUST MAKE SURE THAT THE
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C VALUES SET IN R1MACH ARE RELEVANT TO THE COMPUTER BEING USED.
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C
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U = R1MACH(4)
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C -- SET ASSOCIATED MACHINE DEPENDENT PARAMETER
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WM(1) = SQRT(U)
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C -- SET TERMINATION FLAG
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IQUIT = 0
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C -- SET INITIALIZATION INDICATOR
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INIT = 0
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C -- SET COUNTER FOR ATTEMPTED STEPS
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KSTEPS = 0
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C -- SET INDICATOR FOR INTERMEDIATE-OUTPUT
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INTOUT = .FALSE.
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C -- SET START INDICATOR FOR STOD CODE
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JSTART = 0
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C -- SET BDF METHOD INDICATOR
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METH = 2
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C -- SET MAXIMUM ORDER FOR BDF METHOD
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MAXORD = 5
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C -- SET ITERATION MATRIX INDICATOR
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C
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IF (IJAC .EQ. 0 .AND. IBAND .EQ. 0) MITER = 2
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IF (IJAC .EQ. 1 .AND. IBAND .EQ. 0) MITER = 1
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IF (IJAC .EQ. 0 .AND. IBAND .EQ. 1) MITER = 5
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IF (IJAC .EQ. 1 .AND. IBAND .EQ. 1) MITER = 4
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C
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C -- SET OTHER NECESSARY ITEMS IN COMMON BLOCK
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N = NEQ
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NST = 0
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NJE = 0
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HMXI = 0.
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NQ = 1
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H = 1.
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C -- RESET IBEGIN FOR SUBSEQUENT CALLS
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IBEGIN=1
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ENDIF
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C
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C.......................................................................
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C
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C CHECK VALIDITY OF INPUT PARAMETERS ON EACH ENTRY
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C
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IF (NEQ .LT. 1) THEN
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WRITE (XERN1, '(I8)') NEQ
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, THE NUMBER OF EQUATIONS MUST BE A POSITIVE ' //
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* 'INTEGER.$$YOU HAVE CALLED THE CODE WITH NEQ = ' // XERN1,
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* 6, 1)
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IDID=-33
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ENDIF
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C
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NRTOLP = 0
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NATOLP = 0
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DO 60 K = 1,NEQ
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IF (NRTOLP .LE. 0) THEN
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IF (RTOL(K) .LT. 0.) THEN
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WRITE (XERN1, '(I8)') K
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WRITE (XERN3, '(1PE15.6)') RTOL(K)
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, THE RELATIVE ERROR TOLERANCES MUST ' //
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* 'BE NON-NEGATIVE.$$YOU HAVE CALLED THE CODE WITH ' //
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* 'RTOL(' // XERN1 // ') = ' // XERN3 // '$$IN THE ' //
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* 'CASE OF VECTOR ERROR TOLERANCES, NO FURTHER ' //
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* 'CHECKING OF RTOL COMPONENTS IS DONE.', 7, 1)
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IDID = -33
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IF (NATOLP .GT. 0) GO TO 70
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NRTOLP = 1
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ELSEIF (NATOLP .GT. 0) THEN
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GO TO 50
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ENDIF
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ENDIF
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C
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IF (ATOL(K) .LT. 0.) THEN
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WRITE (XERN1, '(I8)') K
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WRITE (XERN3, '(1PE15.6)') ATOL(K)
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, THE ABSOLUTE ERROR ' //
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* 'TOLERANCES MUST BE NON-NEGATIVE.$$YOU HAVE CALLED ' //
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* 'THE CODE WITH ATOL(' // XERN1 // ') = ' // XERN3 //
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* '$$IN THE CASE OF VECTOR ERROR TOLERANCES, NO FURTHER '
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* // 'CHECKING OF ATOL COMPONENTS IS DONE.', 8, 1)
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IDID=-33
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IF (NRTOLP .GT. 0) GO TO 70
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NATOLP=1
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ENDIF
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50 IF (ITOL .EQ. 0) GO TO 70
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60 CONTINUE
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C
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70 IF (ITSTOP .EQ. 1) THEN
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IF (SIGN(1.,TOUT-T) .NE. SIGN(1.,TSTOP-T) .OR.
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1 ABS(TOUT-T) .GT. ABS(TSTOP-T)) THEN
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WRITE (XERN3, '(1PE15.6)') TOUT
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WRITE (XERN4, '(1PE15.6)') TSTOP
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, YOU HAVE CALLED THE ' //
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* 'CODE WITH TOUT = ' // XERN3 // '$$BUT YOU HAVE ' //
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* 'ALSO TOLD THE CODE NOT TO INTEGRATE PAST THE POINT ' //
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* 'TSTOP = ' // XERN4 // ' BY SETTING INFO(4) = 1. ' //
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* 'THESE INSTRUCTIONS CONFLICT.', 14, 1)
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IDID=-33
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ENDIF
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ENDIF
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C
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C CHECK SOME CONTINUATION POSSIBILITIES
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C
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IF (INIT .NE. 0) THEN
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IF (T .EQ. TOUT) THEN
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WRITE (XERN3, '(1PE15.6)') T
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, YOU HAVE CALLED THE CODE WITH T = TOUT = ' //
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* XERN3 // ' THIS IS NOT ALLOWED ON CONTINUATION CALLS.',
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* 9, 1)
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IDID=-33
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ENDIF
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C
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IF (T .NE. TOLD) THEN
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WRITE (XERN3, '(1PE15.6)') TOLD
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WRITE (XERN4, '(1PE15.6)') T
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, YOU HAVE CHANGED THE VALUE OF T FROM ' //
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* XERN3 // ' TO ' // XERN4 //
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* ' THIS IS NOT ALLOWED ON CONTINUATION CALLS.', 10, 1)
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IDID=-33
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ENDIF
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C
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IF (INIT .NE. 1) THEN
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IF (DELSGN*(TOUT-T) .LT. 0.) THEN
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WRITE (XERN3, '(1PE15.6)') TOUT
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, BY CALLING THE CODE WITH TOUT = ' //
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* XERN3 // ' YOU ARE ATTEMPTING TO CHANGE THE ' //
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* 'DIRECTION OF INTEGRATION.$$' //
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* 'THIS IS NOT ALLOWED WITHOUT RESTARTING.', 11, 1)
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IDID=-33
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ENDIF
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ENDIF
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ENDIF
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C
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IF (IDID .EQ. (-33)) THEN
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IF (IQUIT .NE. (-33)) THEN
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C INVALID INPUT DETECTED
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IQUIT=-33
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IBEGIN=-1
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ELSE
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CALL XERMSG ('SLATEC', 'LSOD',
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* 'IN DEBDF, INVALID INPUT WAS ' //
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* 'DETECTED ON SUCCESSIVE ENTRIES. IT IS IMPOSSIBLE ' //
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* 'TO PROCEED BECAUSE YOU HAVE NOT CORRECTED THE ' //
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* 'PROBLEM, SO EXECUTION IS BEING TERMINATED.', 12, 2)
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ENDIF
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RETURN
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ENDIF
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C
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C.......................................................................
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C
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C RTOL = ATOL = 0. IS ALLOWED AS VALID INPUT AND INTERPRETED AS
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C ASKING FOR THE MOST ACCURATE SOLUTION POSSIBLE. IN THIS CASE,
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C THE RELATIVE ERROR TOLERANCE RTOL IS RESET TO THE SMALLEST VALUE
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C 100*U WHICH IS LIKELY TO BE REASONABLE FOR THIS METHOD AND MACHINE
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C
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DO 170 K=1,NEQ
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IF (RTOL(K)+ATOL(K) .GT. 0.) GO TO 160
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RTOL(K)=100.*U
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IDID=-2
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160 IF (ITOL .EQ. 0) GO TO 180
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170 CONTINUE
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C
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180 IF (IDID .NE. (-2)) GO TO 190
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C RTOL=ATOL=0 ON INPUT, SO RTOL IS CHANGED TO A
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C SMALL POSITIVE VALUE
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IBEGIN=-1
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RETURN
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C
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C BRANCH ON STATUS OF INITIALIZATION INDICATOR
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C INIT=0 MEANS INITIAL DERIVATIVES AND NOMINAL STEP SIZE
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C AND DIRECTION NOT YET SET
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C INIT=1 MEANS NOMINAL STEP SIZE AND DIRECTION NOT YET SET
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C INIT=2 MEANS NO FURTHER INITIALIZATION REQUIRED
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C
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190 IF (INIT .EQ. 0) GO TO 200
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IF (INIT .EQ. 1) GO TO 220
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GO TO 240
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C
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C.......................................................................
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C
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C MORE INITIALIZATION --
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C -- EVALUATE INITIAL DERIVATIVES
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C
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200 INIT=1
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CALL F(T,Y,YH(1,2),RPAR,IPAR)
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NFE=1
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IF (T .NE. TOUT) GO TO 220
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IDID=2
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DO 210 L = 1,NEQ
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210 YPOUT(L) = YH(L,2)
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TOLD=T
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RETURN
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C
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C -- COMPUTE INITIAL STEP SIZE
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C -- SAVE SIGN OF INTEGRATION DIRECTION
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C -- SET INDEPENDENT AND DEPENDENT VARIABLES
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C X AND YH(*) FOR STOD
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C
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220 LTOL = 1
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DO 225 L=1,NEQ
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IF (ITOL .EQ. 1) LTOL = L
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TOL = RTOL(LTOL)*ABS(Y(L)) + ATOL(LTOL)
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IF (TOL .EQ. 0.) GO TO 380
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225 EWT(L) = TOL
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C
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BIG = SQRT(R1MACH(2))
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CALL HSTART (F,NEQ,T,TOUT,Y,YH(1,2),EWT,1,U,BIG,
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1 YH(1,3),YH(1,4),YH(1,5),YH(1,6),RPAR,IPAR,H)
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C
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DELSGN = SIGN(1.0,TOUT-T)
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X = T
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DO 230 L = 1,NEQ
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YH(L,1) = Y(L)
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230 YH(L,2) = H*YH(L,2)
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INIT = 2
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C
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C.......................................................................
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C
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C ON EACH CALL SET INFORMATION WHICH DETERMINES THE ALLOWED INTERVAL
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C OF INTEGRATION BEFORE RETURNING WITH AN ANSWER AT TOUT
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C
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240 DEL = TOUT - T
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ABSDEL = ABS(DEL)
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C
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C.......................................................................
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C
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C IF ALREADY PAST OUTPUT POINT, INTERPOLATE AND RETURN
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C
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250 IF (ABS(X-T) .LT. ABSDEL) GO TO 270
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CALL INTYD(TOUT,0,YH,NEQ,Y,INTFLG)
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CALL INTYD(TOUT,1,YH,NEQ,YPOUT,INTFLG)
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IDID = 3
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IF (X .NE. TOUT) GO TO 260
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IDID = 2
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INTOUT = .FALSE.
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260 T = TOUT
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TOLD = T
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RETURN
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C
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C IF CANNOT GO PAST TSTOP AND SUFFICIENTLY CLOSE,
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C EXTRAPOLATE AND RETURN
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C
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270 IF (ITSTOP .NE. 1) GO TO 290
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IF (ABS(TSTOP-X) .GE. 100.*U*ABS(X)) GO TO 290
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DT = TOUT - X
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DO 280 L = 1,NEQ
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280 Y(L) = YH(L,1) + (DT/H)*YH(L,2)
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CALL F(TOUT,Y,YPOUT,RPAR,IPAR)
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NFE = NFE + 1
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IDID = 3
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T = TOUT
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TOLD = T
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RETURN
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C
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290 IF (IINTEG .EQ. 0 .OR. .NOT.INTOUT) GO TO 300
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C
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C INTERMEDIATE-OUTPUT MODE
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C
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IDID = 1
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GO TO 500
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C
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C.......................................................................
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C
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C MONITOR NUMBER OF STEPS ATTEMPTED
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C
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300 IF (KSTEPS .LE. MAXNUM) GO TO 330
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C
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C A SIGNIFICANT AMOUNT OF WORK HAS BEEN EXPENDED
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IDID=-1
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KSTEPS=0
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IBEGIN = -1
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GO TO 500
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C
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C.......................................................................
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C
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C LIMIT STEP SIZE AND SET WEIGHT VECTOR
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C
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330 HMIN = 100.*U*ABS(X)
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HA = MAX(ABS(H),HMIN)
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IF (ITSTOP .NE. 1) GO TO 340
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HA = MIN(HA,ABS(TSTOP-X))
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340 H = SIGN(HA,H)
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LTOL = 1
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DO 350 L = 1,NEQ
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IF (ITOL .EQ. 1) LTOL = L
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EWT(L) = RTOL(LTOL)*ABS(YH(L,1)) + ATOL(LTOL)
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IF (EWT(L) .LE. 0.0) GO TO 380
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350 CONTINUE
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TOLFAC = U*VNWRMS(NEQ,YH,EWT)
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IF (TOLFAC .LE. 1.) GO TO 400
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C
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C TOLERANCES TOO SMALL
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IDID = -2
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TOLFAC = 2.*TOLFAC
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RTOL(1) = TOLFAC*RTOL(1)
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ATOL(1) = TOLFAC*ATOL(1)
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IF (ITOL .EQ. 0) GO TO 370
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DO 360 L = 2,NEQ
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RTOL(L) = TOLFAC*RTOL(L)
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360 ATOL(L) = TOLFAC*ATOL(L)
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370 IBEGIN = -1
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GO TO 500
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C
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C RELATIVE ERROR CRITERION INAPPROPRIATE
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380 IDID = -3
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IBEGIN = -1
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GO TO 500
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C
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C.......................................................................
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C
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C TAKE A STEP
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C
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400 CALL STOD(NEQ,Y,YH,NEQ,YH1,EWT,SAVF,ACOR,WM,IWM,F,JAC,RPAR,IPAR)
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C
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JSTART = -2
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INTOUT = .TRUE.
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IF (KFLAG .EQ. 0) GO TO 250
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C
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C.......................................................................
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C
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IF (KFLAG .EQ. -1) GO TO 450
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C
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C REPEATED CORRECTOR CONVERGENCE FAILURES
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IDID = -6
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IBEGIN = -1
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GO TO 500
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C
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C REPEATED ERROR TEST FAILURES
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450 IDID = -7
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IBEGIN = -1
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C
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C.......................................................................
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C
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C STORE VALUES BEFORE RETURNING TO DEBDF
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500 DO 555 L = 1,NEQ
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Y(L) = YH(L,1)
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555 YPOUT(L) = YH(L,2)/H
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T = X
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TOLD = T
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INTOUT = .FALSE.
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RETURN
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END
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