/[MITgcm]/MITgcm/pkg/seaice/seaice_jfnk.F

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-revision 1.16 by mlosch,
Thu Jan 17 08:51:15 2013 UTC
+revision 1.29 by mlosch,
Wed Jan 27 14:03:34 2016 UTC
 Line 2 
 C $Header$
  C $Name$
  #include "SEAICE_OPTIONS.h"
+ #ifdef ALLOW_AUTODIFF
+ # include "AUTODIFF_OPTIONS.h"
+ #endif
  C--  File seaice_jfnk.F: seaice jfnk dynamical solver S/R:
  C--   Contents
-Line 53 
 C     myThid :: my Thread Id. number
+Line 56 
 C     myThid :: my Thread Id. number
        INTEGER myIter
        INTEGER myThid
- #if ( (defined SEAICE_CGRID) && \
+ #ifdef SEAICE_ALLOW_JFNK
-       (defined SEAICE_ALLOW_JFNK) && \
-       (defined SEAICE_ALLOW_DYNAMICS) )
  C     !FUNCTIONS:
        LOGICAL  DIFFERENT_MULTIPLE
        EXTERNAL DIFFERENT_MULTIPLE
  C     !LOCAL VARIABLES:
  C     === Local variables ===
- C     i,j,bi,bj :: loop indices
+ C     i,j,k,bi,bj :: loop indices
-       INTEGER i,j,bi,bj
+       INTEGER i,j,k,bi,bj
  C     loop indices
        INTEGER newtonIter
        INTEGER krylovIter, krylovFails
        INTEGER totalKrylovItersLoc, totalNewtonItersLoc
+ C     FGMRES parameters
+ C     im      :: size of Krylov space
+ C     ifgmres :: interation counter
+       INTEGER im
+       PARAMETER ( im = 50 )
+       INTEGER ifgmres
  C     FGMRES flag that determines amount of output messages of fgmres
        INTEGER iOutFGMRES
  C     FGMRES flag that indicates what fgmres wants us to do next
-Line 75 
 C     FGMRES flag that indicates what fg
+Line 82 
 C     FGMRES flag that indicates what fg
        _RL     JFNKresidual
        _RL     JFNKresidualKm1
  C     parameters to compute convergence criterion
-       _RL     phi_e, alp_e, JFNKgamma_lin
+       _RL     JFNKgamma_lin
        _RL     FGMRESeps
        _RL     JFNKtol
- C
+ C     backward differences extrapolation factors
+       _RL bdfFac, bdfAlpha
+ C
        _RL     recip_deltaT
        LOGICAL JFNKconverged, krylovConverged
        LOGICAL writeNow
        CHARACTER*(MAX_LEN_MBUF) msgBuf
- C
  C     u/vIceRes :: residual of sea-ice momentum equations
        _RL uIceRes(1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
        _RL vIceRes(1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
- C     vector version of the residuals
+ C     extra time level required for backward difference time stepping
-       _RL resTmp (nVec,1,nSx,nSy)
+       _RL duIcNm1(1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
+       _RL dvIcNm1(1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
  C     du/vIce   :: ice velocity increment to be added to u/vIce
        _RL duIce  (1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
        _RL dvIce  (1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
  C     precomputed (= constant per Newton iteration) versions of
  C     zeta, eta, and DWATN, press
        _RL zetaPre (1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
+       _RL zetaZPre(1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
        _RL etaPre  (1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
        _RL etaZPre (1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
        _RL dwatPre (1-OLx:sNx+OLx,1-OLy:sNy+OLy,nSx,nSy)
+ C     work arrays
+       _RL rhs(nVec,nSx,nSy), sol(nVec,nSx,nSy)
+       _RL vv(nVec,im+1,nSx,nSy), w(nVec,im,nSx,nSy)
+       _RL wk1(nVec,nSx,nSy), wk2(nVec,nSx,nSy)
  CEOP
  C     Initialise
-Line 117 
 C     with iOutFgmres=1, seaice_fgmres p
+Line 132 
 C     with iOutFgmres=1, seaice_fgmres p
       &     DIFFERENT_MULTIPLE( SEAICE_monFreq, myTime, deltaTClock ) )
       &     iOutFGMRES=1
- C
+ C     backward difference extrapolation factors
+       bdfFac = 0. _d 0
+       IF ( SEAICEuseBDF2 ) THEN
+        IF ( myIter.EQ.nIter0 .AND. SEAICEmomStartBDF.EQ.0 ) THEN
+         bdfFac = 0. _d 0
+        ELSE
+         bdfFac = 0.5 _d 0
+        ENDIF
+       ENDIF
+       bdfAlpha = 1. _d 0 + bdfFac
        DO bj=myByLo(myThid),myByHi(myThid)
         DO bi=myBxLo(myThid),myBxHi(myThid)
-         DO J=1-Oly,sNy+Oly
+         DO J=1-OLy,sNy+OLy
-          DO I=1-Olx,sNx+Olx
+          DO I=1-OLx,sNx+OLx
            uIceRes(I,J,bi,bj) = 0. _d 0
            vIceRes(I,J,bi,bj) = 0. _d 0
            duIce  (I,J,bi,bj) = 0. _d 0
            dvIce  (I,J,bi,bj) = 0. _d 0
+          ENDDO
+         ENDDO
+ C     cycle ice velocities
+         DO J=1-OLy,sNy+OLy
+          DO I=1-OLx,sNx+OLx
+           duIcNm1(I,J,bi,bj) = uIce(I,J,bi,bj) * bdfAlpha
+      &         + ( uIce(I,J,bi,bj) - uIceNm1(I,J,bi,bj) ) * bdfFac
+           dvIcNm1(I,J,bi,bj) = vIce(I,J,bi,bj) * bdfAlpha
+      &         + ( vIce(I,J,bi,bj) - vIceNm1(I,J,bi,bj) ) * bdfFac
            uIceNm1(I,J,bi,bj) = uIce(I,J,bi,bj)
            vIceNm1(I,J,bi,bj) = vIce(I,J,bi,bj)
           ENDDO
          ENDDO
+ C     As long as IMEX is not properly implemented leave this commented out
+ CML        IF ( .NOT.SEAICEuseIMEX ) THEN
  C     Compute things that do no change during the Newton iteration:
  C     sea-surface tilt and wind stress:
- C     FORCEX/Y0 - mass*(u/vIceNm1)/deltaT
+ C     FORCEX/Y0 - mass*(1.5*u/vIceNm1+0.5*(u/vIceNm1-u/vIceNm2))/deltaT
-         DO J=1-Oly,sNy+Oly
+         DO J=1-OLy,sNy+OLy
-          DO I=1-Olx,sNx+Olx
+          DO I=1-OLx,sNx+OLx
            FORCEX(I,J,bi,bj) = FORCEX0(I,J,bi,bj)
-      &         + seaiceMassU(I,J,bi,bj)*uIceNm1(I,J,bi,bj)*recip_deltaT
+      &         + seaiceMassU(I,J,bi,bj)*duIcNm1(I,J,bi,bj)*recip_deltaT
            FORCEY(I,J,bi,bj) = FORCEY0(I,J,bi,bj)
-      &         + seaiceMassV(I,J,bi,bj)*vIceNm1(I,J,bi,bj)*recip_deltaT
+      &         + seaiceMassV(I,J,bi,bj)*dvIcNm1(I,J,bi,bj)*recip_deltaT
           ENDDO
          ENDDO
+ CML        ENDIF
         ENDDO
        ENDDO
  C     Start nonlinear Newton iteration: outer loop iteration
-Line 149 
 C     Start nonlinear Newton iteration:
+Line 186 
 C     Start nonlinear Newton iteration:
         newtonIter = newtonIter + 1
  C     Compute initial residual F(u), (includes computation of global
  C     variables DWATN, zeta, and eta)
         IF ( newtonIter .EQ. 1 ) CALL SEAICE_JFNK_UPDATE(
       I      duIce, dvIce,
       U      uIce, vIce, JFNKresidual,
       O      uIceRes, vIceRes,
       I      newtonIter, myTime, myIter, myThid )
-Line 158 
 C     local copies of precomputed coeffi
+Line 195 
 C     local copies of precomputed coeffi
  C     constant for the preconditioner
         DO bj=myByLo(myThid),myByHi(myThid)
          DO bi=myBxLo(myThid),myBxHi(myThid)
-          DO j=1-Oly,sNy+Oly
+          DO j=1-OLy,sNy+OLy
-           DO i=1-Olx,sNx+Olx
+           DO i=1-OLx,sNx+OLx
             zetaPre(I,J,bi,bj) =  zeta(I,J,bi,bj)
+            zetaZPre(I,J,bi,bj)= zetaZ(I,J,bi,bj)
              etaPre(I,J,bi,bj) =   eta(I,J,bi,bj)
             etaZPre(I,J,bi,bj) =  etaZ(I,J,bi,bj)
             dwatPre(I,J,bi,bj) = DWATN(I,J,bi,bj)
-Line 170 
 C     constant for the preconditioner
+Line 208 
 C     constant for the preconditioner
         ENDDO
  C     compute convergence criterion for linear preconditioned FGMRES
         JFNKgamma_lin = JFNKgamma_lin_max
-        IF ( newtonIter.GT.1.AND.newtonIter.LE.100
+        IF ( newtonIter.GT.1.AND.newtonIter.LE.SEAICE_JFNK_tolIter
       &      .AND.JFNKresidual.LT.JFNKres_t ) THEN
- C     Eisenstat, 1996, equ.(2.6)
+ C     Eisenstat and Walker (1996), eq.(2.6)
-         phi_e = 1. _d 0
+         JFNKgamma_lin = SEAICE_JFNKphi
-         alp_e = 1. _d 0
+      &       *( JFNKresidual/JFNKresidualKm1 )**SEAICE_JFNKalpha
-         JFNKgamma_lin = phi_e*( JFNKresidual/JFNKresidualKm1 )**alp_e
          JFNKgamma_lin = min(JFNKgamma_lin_max, JFNKgamma_lin)
          JFNKgamma_lin = max(JFNKgamma_lin_min, JFNKgamma_lin)
         ENDIF
  C     save the residual for the next iteration
         JFNKresidualKm1 = JFNKresidual
- C
  C     The Krylov iteration using FGMRES, the preconditioner is LSOR
  C     for now. The code is adapted from SEAICE_LSR, but heavily stripped
  C     down.
-Line 189 
 C     krylovIter is mapped into "its" in
+Line 226 
 C     krylovIter is mapped into "its" in
  C     in that routine
         krylovIter    = 0
         iCode         = 0
- C
         JFNKconverged = JFNKresidual.LT.JFNKtol
- C
  C     do Krylov loop only if convergence is not reached
- C
         IF ( .NOT.JFNKconverged ) THEN
- C
  C     start Krylov iteration (FGMRES)
- C
          krylovConverged = .FALSE.
          FGMRESeps = JFNKgamma_lin * JFNKresidual
-         DO WHILE ( .NOT.krylovConverged )
+ C     map first guess sol; it is zero because the solution is a correction
+        CALL SEAICE_MAP2VEC(nVec,duIce,dvIce,sol,.TRUE.,myThid)
+ C     map rhs and change its sign because we are solving J*u = -F
+         CALL SEAICE_MAP2VEC(nVec,-uIceRes,-vIceRes,rhs,.TRUE.,myThid)
+         DO WHILE ( .NOT.krylovConverged )
  C     solution vector sol = du/vIce
  C     residual vector (rhs) Fu = u/vIceRes
  C     output work vectors wk1, -> input work vector wk2
+ C     map preconditioner results or Jacobian times vector,
+ C     stored in du/vIce to wk2, for iCode=0, wk2 is set to zero,
+ C     because du/vIce = 0
+          CALL SEAICE_MAP2VEC(nVec,duIce,dvIce,wk2,.TRUE.,myThid)
+ C
+          CALL SEAICE_FGMRES (nVec,im,rhs,sol,ifgmres,krylovIter,
+      U        vv,w,wk1,wk2,
+      I        FGMRESeps,SEAICEkrylovIterMax,iOutFGMRES,
+      U        iCode,
+      I        myThid)
  C
-          CALL SEAICE_FGMRES_DRIVER(
+          IF ( iCode .EQ. 0 ) THEN
-      I        uIceRes, vIceRes,
+ C     map sol(ution) vector to du/vIce
-      U        duIce, dvIce, iCode,
+           CALL SEAICE_MAP2VEC(nVec,duIce,dvIce,sol,.FALSE.,myThid)
-      I        FGMRESeps, iOutFGMRES,
+          ELSE
-      I        newtonIter, krylovIter, myTime, myIter, myThid )
+ C     map work vector to du/vIce to either compute a preconditioner
+ C     solution (wk1=rhs) or a Jacobian times wk1
+           CALL SEAICE_MAP2VEC(nVec,duIce,dvIce,wk1,.FALSE.,myThid)
+          ENDIF
+ C     Fill overlaps in updated fields
+          CALL EXCH_UV_XY_RL( duIce, dvIce,.TRUE.,myThid)
  C     FGMRES returns iCode either asking for an new preconditioned vector
  C     or product of matrix (Jacobian) times vector. For iCode = 0, terminate
  C     iteration
           IF (iCode.EQ.1) THEN
  C     Call preconditioner
            IF ( SOLV_MAX_ITERS .GT. 0 )
       &         CALL SEAICE_PRECONDITIONER(
       U         duIce, dvIce,
-      I         zetaPre, etaPre, etaZpre, dwatPre,
+      I         zetaPre, etaPre, etaZpre, zetaZpre, dwatPre,
       I         newtonIter, krylovIter, myTime, myIter, myThid )
           ELSEIF (iCode.GE.2) THEN
  C     Compute Jacobian times vector
            CALL SEAICE_JACVEC(
       I         uIce, vIce, uIceRes, vIceRes,
       U         duIce, dvIce,
       I         newtonIter, krylovIter, myTime, myIter, myThid )
           ENDIF
           krylovConverged = iCode.EQ.0
-Line 234 
 C     End of Krylov iterate
+Line 291 
 C     End of Krylov iterate
  C     some output diagnostics
          IF ( debugLevel.GE.debLevA ) THEN
           _BEGIN_MASTER( myThid )
           totalNewtonItersLoc =
       &        SEAICEnewtonIterMax*(myIter-nIter0)+newtonIter
           WRITE(msgBuf,'(2A,2(1XI6),2E12.5)')
       &        ' S/R SEAICE_JFNK: Newton iterate / total, ',
       &        'JFNKgamma_lin, initial norm = ',
       &        newtonIter, totalNewtonItersLoc,
-Line 244 
 C     some output diagnostics
+Line 301 
 C     some output diagnostics
           CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &        SQUEEZE_RIGHT, myThid )
           WRITE(msgBuf,'(3(A,I6))')
       &        ' S/R SEAICE_JFNK: Newton iterate / total = ',newtonIter,
       &        ' / ', totalNewtonItersLoc,
       &        ', Nb. of FGMRES iterations = ', krylovIter
           CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
-Line 254 
 C     some output diagnostics
+Line 311 
 C     some output diagnostics
          IF ( krylovIter.EQ.SEAICEkrylovIterMax ) THEN
           krylovFails = krylovFails + 1
          ENDIF
- C     Set the stopping criterion for the Newton iteration
+ C     Set the stopping criterion for the Newton iteration and the
-         IF ( newtonIter .EQ. 1 ) JFNKtol=JFNKgamma_nonlin*JFNKresidual
+ C     criterion for the transition from accurate to approximate FGMRES
+         IF ( newtonIter .EQ. 1 ) THEN
+          JFNKtol=JFNKgamma_nonlin*JFNKresidual
+          IF ( JFNKres_tFac .NE. UNSET_RL )
+      &        JFNKres_t = JFNKresidual * JFNKres_tFac
+         ENDIF
  C     Update linear solution vector and return to Newton iteration
  C     Do a linesearch if necessary, and compute a new residual.
  C     Note that it should be possible to do the following operations
  C     at the beginning of the Newton iteration, thereby saving us from
  C     the extra call of seaice_jfnk_update, but unfortunately that
  C     changes the results, so we leave the stuff here for now.
          CALL SEAICE_JFNK_UPDATE(
       I       duIce, dvIce,
       U       uIce, vIce, JFNKresidual,
       O       uIceRes, vIceRes,
       I       newtonIter, myTime, myIter, myThid )
  C     reset du/vIce here instead of setting sol = 0 in seaice_fgmres_driver
          DO bj=myByLo(myThid),myByHi(myThid)
           DO bi=myBxLo(myThid),myBxHi(myThid)
-           DO J=1-Oly,sNy+Oly
+           DO J=1-OLy,sNy+OLy
-            DO I=1-Olx,sNx+Olx
+            DO I=1-OLx,sNx+OLx
              duIce(I,J,bi,bj)= 0. _d 0
              dvIce(I,J,bi,bj)= 0. _d 0
             ENDDO
-Line 281 
 C     reset du/vIce here instead of sett
+Line 343 
 C     reset du/vIce here instead of sett
         ENDIF
  C     end of Newton iterate
        ENDDO
- C
  C--   Output diagnostics
- C
        IF ( SEAICE_monFreq .GT. 0. _d 0 ) THEN
  C     Count iterations
         totalJFNKtimeSteps = totalJFNKtimeSteps + 1
-Line 292 
 C     Count iterations
+Line 354 
 C     Count iterations
  C     Record failure
         totalKrylovFails   = totalKrylovFails + krylovFails
         IF ( newtonIter .EQ. SEAICEnewtonIterMax ) THEN
          totalNewtonFails = totalNewtonFails + 1
         ENDIF
        ENDIF
  C     Decide whether it is time to dump and reset the counter
        writeNow = DIFFERENT_MULTIPLE(SEAICE_monFreq,
       &     myTime+deltaTClock, deltaTClock)
  #ifdef ALLOW_CAL
        IF ( useCAL ) THEN
         CALL CAL_TIME2DUMP(
       I      zeroRL, SEAICE_monFreq,  deltaTClock,
       U      writeNow,
       I      myTime+deltaTclock, myIter+1, myThid )
-Line 308 
 C     Decide whether it is time to dump
+Line 370 
 C     Decide whether it is time to dump
  #endif
        IF ( writeNow ) THEN
         _BEGIN_MASTER( myThid )
         WRITE(msgBuf,'(A)')
       &' // ======================================================='
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A)') ' // Begin JFNK statistics'
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A)')
       &' // ======================================================='
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A,I10)')
       &      ' %JFNK_MON: time step              = ', myIter+1
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A,I10)')
       &      ' %JFNK_MON: Nb. of time steps      = ', totalJFNKtimeSteps
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A,I10)')
       &      ' %JFNK_MON: Nb. of Newton steps    = ', totalNewtonIters
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A,I10)')
       &      ' %JFNK_MON: Nb. of Krylov steps    = ', totalKrylovIters
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A,I10)')
       &      ' %JFNK_MON: Nb. of Newton failures = ', totalNewtonFails
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A,I10)')
       &      ' %JFNK_MON: Nb. of Krylov failures = ', totalKrylovFails
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A)')
       &' // ======================================================='
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A)') ' // End JFNK statistics'
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
         WRITE(msgBuf,'(A)')
       &' // ======================================================='
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
       &      SQUEEZE_RIGHT, myThid )
-Line 367 
 C     Print more debugging information
+Line 429 
 C     Print more debugging information
        IF ( debugLevel.GE.debLevA ) THEN
         IF ( newtonIter .EQ. SEAICEnewtonIterMax ) THEN
          _BEGIN_MASTER( myThid )
          WRITE(msgBuf,'(A,I10)')
       &       ' S/R SEAICE_JFNK: JFNK did not converge in timestep ',
       &       myIter+1
          CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
-Line 376 
 C     Print more debugging information
+Line 438 
 C     Print more debugging information
         ENDIF
         IF ( krylovFails .GT. 0 ) THEN
          _BEGIN_MASTER( myThid )
          WRITE(msgBuf,'(A,I4,A,I10)')
       &       ' S/R SEAICE_JFNK: FGMRES did not converge ',
       &       krylovFails, ' times in timestep ', myIter+1
          CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
-Line 384 
 C     Print more debugging information
+Line 446 
 C     Print more debugging information
          _END_MASTER( myThid )
         ENDIF
         _BEGIN_MASTER( myThid )
         WRITE(msgBuf,'(A,I6,A,I10)')
       &      ' S/R SEAICE_JFNK: Total number FGMRES iterations = ',
       &      totalKrylovItersLoc, ' in timestep ', myIter+1
         CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
-Line 400 
 CBOP
+Line 462 
 CBOP
  C     !ROUTINE: SEAICE_JFNK_UPDATE
  C     !INTERFACE:
        SUBROUTINE SEAICE_JFNK_UPDATE(
       I     duIce, dvIce,
       U     uIce, vIce, JFNKresidual,
       O     uIceRes, vIceRes,
       I     newtonIter, myTime, myIter, myThid )
-Line 460 
 C     i,j,bi,bj :: loop indices
+Line 522 
 C     i,j,bi,bj :: loop indices
        _RL     resLoc, facLS
        LOGICAL doLineSearch
  C     nVec    :: size of the input vector(s)
- C     vector version of the residuals
+ C     resTmp  :: vector version of the residuals
        INTEGER nVec
        PARAMETER ( nVec  = 2*sNx*sNy )
        _RL resTmp (nVec,1,nSx,nSy)
- C
        CHARACTER*(MAX_LEN_MBUF) msgBuf
  CEOP
-Line 474 
 C     Initialise some local variables
+Line 536 
 C     Initialise some local variables
        facLS = 1. _d 0
        doLineSearch = .TRUE.
        DO WHILE ( doLineSearch )
- C     Determine, if we need more iterations
-        doLineSearch = resLoc .GE. JFNKresidual
- C     Limit the maximum number of iterations arbitrarily to four
-        doLineSearch = doLineSearch .AND. l .LE. 4
- C     For the first iteration du/vIce = 0 and there will be no
- C     improvement of the residual possible, so we do only the first
- C     iteration
-        IF ( newtonIter .EQ. 1 ) doLineSearch = .FALSE.
- C     Only start a linesearch after some Newton iterations
-        IF ( newtonIter .LE. SEAICE_JFNK_lsIter ) doLineSearch = .FALSE.
- C     Increment counter
-        l = l + 1
  C     Create update
         DO bj=myByLo(myThid),myByHi(myThid)
          DO bi=myBxLo(myThid),myBxHi(myThid)
-          DO J=1-Oly,sNy+Oly
+          DO J=1-OLy,sNy+OLy
-           DO I=1-Olx,sNx+Olx
+           DO I=1-OLx,sNx+OLx
             uIce(I,J,bi,bj) = uIce(I,J,bi,bj)+facLS*duIce(I,J,bi,bj)
             vIce(I,J,bi,bj) = vIce(I,J,bi,bj)+facLS*dvIce(I,J,bi,bj)
            ENDDO
-Line 499 
 C     Create update
+Line 549 
 C     Create update
         ENDDO
  C     Compute current residual F(u), (includes re-computation of global
  C     variables DWATN, zeta, and eta, i.e. they are different after this)
         CALL SEAICE_CALC_RESIDUAL(
       I      uIce, vIce,
       O      uIceRes, vIceRes,
       I      newtonIter, 0, myTime, myIter, myThid )
  C     Important: Compute the norm of the residual using the same scalar
  C     product that SEAICE_FGMRES does
         CALL SEAICE_MAP2VEC(nVec,uIceRes,vIceRes,resTmp,.TRUE.,myThid)
         CALL SEAICE_SCALPROD(nVec,1,1,1,resTmp,resTmp,resLoc,myThid)
         resLoc = SQRT(resLoc)
+ C     Determine, if we need more iterations
+        doLineSearch = resLoc .GE. JFNKresidual
+ C     Limit the maximum number of iterations arbitrarily to four
+        doLineSearch = doLineSearch .AND. l .LT. 4
+ C     For the first iteration du/vIce = 0 and there will be no
+ C     improvement of the residual possible, so we do only the first
+ C     iteration
+        IF ( newtonIter .EQ. 1 ) doLineSearch = .FALSE.
+ C     Only start a linesearch after some Newton iterations
+        IF ( newtonIter .LE. SEAICE_JFNK_lsIter ) doLineSearch = .FALSE.
+ C     Increment counter
+        l = l + 1
  C     some output diagnostics
         IF ( debugLevel.GE.debLevA .AND. doLineSearch ) THEN
          _BEGIN_MASTER( myThid )
          WRITE(msgBuf,'(2A,2(1XI6),3E12.5)')
       &       ' S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, ',
       &       'facLS, JFNKresidual, resLoc = ',
       &        newtonIter, l, facLS, JFNKresidual, resLoc
-Line 527 
 C     iterations, 0.25*du/vIce in the se
+Line 589 
 C     iterations, 0.25*du/vIce in the se
  C     This is the new residual
        JFNKresidual = resLoc
- #endif /* SEAICE_ALLOW_DYNAMICS and SEAICE_CGRID and SEAICE_ALLOW_JFNK */
+ #endif /* SEAICE_ALLOW_JFNK */
        RETURN
        END

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