! ! SWAN/COMPU file 1 of 5 ! ! ! PROGRAM SWANCOM1.FOR ! ! This subroutine SWANCOM1 of the main program SWAN ! includes the next subroutines : ! ! SWCOMP (main subroutine for the computational module) 31.02 ! SWOMPU (carries out computation for one grid point) 31.02 ! SWPRSET (print all the settings used in SWAN run) 40.80 ! SACCUR (calculate the accuracy and check if the iteration process ! can be terminated) ! INSAC (initialize the values for the calculation of accuracy) 40.00 ! ACTION (fill the arrays with the derivatives of the action eq.) ! SINTGRL (calculate some general wave (integral) parameters) 40.02 ! SOLPRE (preparation before solving the system) ! SOLMAT (solve tri-diagonal system in absence of a current) ! SOLMT1 (solve tri-diagonal system in presence of a current; ! almost identical to SOLMAT, however, space in theta can ! be periodic) ! SOURCE (fill the array with the source terms) ! PHILIM (limit the change in action density between two iterations) ! HJLIM (limit the change in action density between two iterations 40.61 ! based on Hersbach and Janssen limiter) 40.61 ! RESCALE (remove negative values from action density) ! SWSIP (solve penta-diagonal system in spectral space by means 40.23 ! of Stone's SIP solver) 40.23 ! SWSOR (solve penta-diagonal system in spectral space by means 40.41 ! of point SOR method) 40.41 ! SWMTLB (compute bounds of thread loop) 40.31 ! SWSTPC (calculate the accuracy and check if the iteration process 40.41 ! can be terminated based on curvature of Hs) 40.41 ! SETUPP (compute the wave-induced setup for a one-dimensional and a 32.01 ! two-dimensional run. Note that the one-dimensional mode of 32.01 ! SWAN has been coded in this project (H3268)) 32.01 ! SETUP2D (computation of the change of waterlevel by waves, 31.03 ! a 2D Poisson equation in general coordinates is solved) 31.03 ! !****************************************************************** ! SUBROUTINE SWCOMP (AC1 ,AC2 , 40.22 & COMPDA , 40.22 & SPCDIR ,SPCSIG , 30.72 & XYTST , & IT ,KGRPNT , & XCGRID ,YCGRID , 30.72 & CROSS ) 40.31 40.30 ! !****************************************************************** USE TIMECOMM 40.41 USE OCPCOMM1 40.41 USE OCPCOMM2 40.41 USE OCPCOMM3 40.41 USE OCPCOMM4 40.41 USE SWCOMM1 40.41 USE SWCOMM2 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE M_PARALL 40.31 USE m_constants 40.41 USE m_xnldata 40.41 USE m_fileio 40.41 !ESMF USE M_GENARR, ONLY: SAVE_SINBAC, SINBAC ! IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.70: Nico Booij ! 30.72: IJsbrand Haagsma ! 30.74: IJsbrand Haagsma (Include version) ! 30.75: IJsbrand Haagsma (Bug fix) ! 30.81: Annette Kieftenburg ! 30.82: IJsbrand Haagsma ! 30.90: IJsbrand Haagsma (Equivalence version) ! 31.03: Annette Kieftenburg ! 32.02: Roeland Ris & Cor van der Schelde (1D-version) ! 33.08: W. Erick Rogers (some S&L scheme-related changes) ! 33.10: Nico Booij and Erick Rogers ! 34.01: Jeroen Adema ! 40.00: Nico Booij ! 40.02: IJsbrand Haagsma ! 40.03, 40.13: Nico Booij ! 40.17: IJsbrand Haagsma ! 40.21: Agnieszka Herman ! 40.22: John Cazes and Tim Campbell ! 40.23: Marcel Zijlema ! 40.30: Marcel Zijlema ! 40.31: Tim Campbell and John Cazes ! 40.31: Andre van der Westhuysen ! 40.41: Andre van der Westhuysen ! 40.41: Marcel Zijlema ! 40.41: Andre van der Westhuysen ! 40.59: W. Erick Rogers ! ! 1. Updates ! ! 30.72, Nov. 97: Declaration of MSC4MI, MSC4MA, MDC4MI, MDC4MA and ! ISTAT removed because they are common and already ! declared in the INCLUDE file ! 30.72, Nov. 97: ITERMX can be chosen freely with NUM ACCUR also in dynamic ! mode. Default ITERMX=6. Needs extensive testing ! 30.74, Nov. 97: Prepared for version with INCLUDE statements ! 32.02, Jan. 98: Introduced 1D-version ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 30.70, Feb. 98: call WINDP0 removed, function taken over by WINDP1 ! 30.72, Mar. 98: Current switched off for the first iteration, when ! preconditining is required ! 30.72, Mar. 98: Writes the result of the iteration step to the PRINT ! file ! 30.75, Mar. 98: Renamed SLOW to SIGLOW, because SLOW was used only locally ! 31.03, Feb. 98: Call SETUPP added, initialisation of array SETPDA ! 30.90, Oct. 98: Introduced EQUIVALENCE POOL-arrays ! 30.82, Oct. 98: Updated description of several variables ! 30.81, Jan. 99: Replaced variable STATUS by IERR (because STATUS is a ! reserved word) ! 34.01, Feb. 99: Introducing STPNOW ! 33.08, July 98: some S&L scheme-related changes ! 30.82, July 99: Corrected argumentlist SETUPP ! 40.00, July 99: argument KQUAD removed from call PLTSRC ! 30.82, Sep. 99: Modified messages in case of non-convergence ! 33.10, Jan. 00: minor changes re: the SORDUP scheme ! 40.03, Mar. 00: Ursell number is now array (value for each grid point) ! 40.02, Oct. 00: Avoided real/int conflict by introducing replacing ! RWAREA for WAREA in FAC4WW and SETUPP ! 40.13, Mar. 01: comments changed; ! order of calling SWAPAR and SPROXY changed ! message concerning lack of convergence only to print file ! in nonstationary cases ! 40.21, Aug. 01: implementation of diffraction ! 40.22, Sep. 01: WAREA, LWAREA, and RWAREA structures removed 40.22 ! and replaced with allocated arrays to ease 40.22 ! OpenMP implementation. 40.22 ! 40.22, Sep. 01: OpenMP directives were added to parallelize the 40.22 ! outer Y loop for the call to SWOMPU in the sweep 40.22 ! across the computational grid. 40.22 ! 40.22, Sep. 01: Added logical array LLOCK for thread management 40.22 ! during parallel operation. It will not affect 40.22 ! serial execution. 40.22 ! 40.22, Sep. 01: Changed array definitions to use the parameter 40.22 ! MICMAX instead of ICMAX. 40.22 ! 40.17, Dec. 01: Implemented Multiple DIA ! 40.23, Aug. 02: Print of CPU times added ! 40.23, Aug. 02: Print of use of limiter and rescaling ! 40.30, Mar. 03: introduction distributed-memory approach using MPI ! 40.31, Jul. 03: some improvements and corrections w.r.t. OpenMP ! 40.31, Sep. 03: Under-relaxation parameter is set to zero in first ! iteration because of the first guess ! 40.41, May 04: Implemented XNL (Webb-Resio-Tracy) method for ! quadruplet interactions ! 40.41, Jun. 04: Implementation of curvature-based convergence check ! 40.41, Aug. 04: some code optimization ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! 40.59, Aug. 07: stencil modification ! ! 2. Purpose ! ! The aim of this model is to simulate the wave energy in ! shallow water areas. In the subroutine SWCOMP the main processes ! taking place in the shallow water zone are determined in ! several subroutines. ! The input for this subroutine comes from SWANPRE1 and SWANPRE2. ! The output is send to the subroutines SWANOUT1 and SWANOUT2. ! The output consist of some characteristic ! wave parameters and the wave action density. The equations are ! all based on the action density N which is a function of the ! spatial position (x,y), the relative frequency (s) and the ! spectral direction (d). ! ! 3. Method ! ! Keywords: ! Action density, propagation terms, refraction, reflection, ! white capping, wave breaking, bottom friction, nonlinear ! and nonhomogeneous wind- and current-fields, wave blocking, ! fully spectral description, nonlinear wave-wave interaction, ! higher order upwind schemes, flux limiting, SIP solver ! ! 4. Argument variables ! ! i SPCDIR: (*,1); spectral directions (radians) 30.82 ! (*,2); cosine of spectral directions 30.82 ! (*,3); sine of spectral directions 30.82 ! (*,4); cosine^2 of spectral directions 30.82 ! (*,5); cosine*sine of spectral directions 30.82 ! (*,6); sine^2 of spectral directions 30.82 ! i SPCSIG: Relative frequencies in computational domain in sigma-space 30.72 ! i XCGRID: Coordinates of computational grid in x-direction 30.72 ! i YCGRID: Coordinates of computational grid in y-direction 30.72 ! REAL SPCDIR(MDC,6) 30.82 REAL SPCSIG(MSC) 30.72 REAL XCGRID(MXC,MYC), YCGRID(MXC,MYC) 30.72 ! ! ! INTEGERS: ! -------------------------------------------------------------- ! IC Dummy variable: ICode gridpoint: ! IC = 1 Top or Bottom gridpoint ! IC = 2 Left or Right gridpoint ! IC = 3 Central gridpoint ! Whether which value IC has, depends of the sweep ! If necessary, IC can be enlarged by increasing ! the array size of ICMAX ! ITER Counter of iterations per 4 sweeps for accuracy ! ITERMX Maximum number of iterations in model ! IX Counter of gridpoints in x-direction ! IY Counter of gridpoints in y-direction ! IS Counter of relative frequency band ! IT Counter in time space ! ID Counter of directional distribution ! IBOT Indicator for bottom friction ! IBOT = 0 no bottom friction dissipation ! IBOT = 1 Jonswap bottom dissipation model ! IBOT = 2 Dingemans bottom dissipation model ! IBOT = 3 Madsen bottom dissipation model ! IBOT = 5 bottom dissipation due to ripples ! ICUR Indicator for current ! ISURF Indicator for wave breaking ! ITRIAD Indicator for nonlinear triad interactions ! IQUAD Indicator for nonlinear quadruplet interactions ! IWCAP Indicator for white capping ! IWIND Indicator for which wind generation model is used ! IWIND = 1 first generation wind growth model ! IWIND = 2 second generation wind growth model ! IWIND = 3 third generation wind growth model ! IREFR indicator for refraction (can be tuned off) ! ITFRE indicator for transport of action in frequency ! space ! ICMAX Maximum array size for the points in the molecule ! KSX input Dummy variable to get the right sign in the ! numerical difference scheme in X-direction ! depending on the sweep direction ! KSY input Dummy variable to get the right sign in the ! numerical difference scheme in Y-direction ! depending on the sweep direction ! MXC Maximum counter of gridppoints in x-direction in ! computational model: (XLEN/DX + 1 ) ! MYC Maximum counter of gridppoints in y-direction in ! computational model: (YLEN/DY + 1 ) ! MSC Maximum counter of relative frequency in ! computational model ! MDC Maximum counter of directional distribution in ! computational model (2PI / DDIR + 1) ! MTC Maximum counter of the time, i.e.: ! (total time in proto type) / (time step) ! MBOT Maximum array size for PBOT ! MSURF Maximum array size for PSSURF ! MTRIAD Maximum array size for PTRIAD ! MWCAP Maximum array size for PWCAP ! MWIND Maximum array size for PWIND ! MNISL Minimum sigma-index occured in applying limiter ! MXNFL Maximum number of use of limiter in a spectral ! space ! MXNFR Maximum number of use of rescaling in a spectral ! space ! NPFL Number of geographical points in which limiter ! is used ! NPFR Number of geographical points in which rescaling ! is used ! NWETP Total number of wet gridpoints ! IDEBUG Level of debug output: ! 0 = no output ! 1 = print of statistics w.r.t. use of limiter ! and rescaling ! I1GRD Lower index for thread loop over spatial grid 40.31 ! I2GRD Upper index for thread loop over spatial grid 40.31 ! I1MYC Lower index for thread loop over y-grid row 40.31 ! I2MYC Upper index for thread loop over y-grid row 40.31 ! ! REALS: ! -------------------------------------------------------------- ! ! ALEN Part of side length of an angle side ! BETA Angle between DX end DY ! BLEN Part of side length of an angle side ! DIR Spectral direction (i.e., ID*DDIR) ! DX input Length of spatial cell in X-direction ! DY input Length of spatial cell in Y-direction ! DS input Width of frequency band (is not constant because ! of the logarithmic distribution of the frequency ! DDIR input Width of directional band ! DT input Time step ! DDX input Same as DX but with correct sign depending of the ! direction of the sweep (+1. OR -1. ) no input ! DDY input Same as DY but with correct sign depending of the ! direction of the sweep (+1. OR -1. ) no input ! FAC_A Factor representing the influence of the action- ! density depening of the propagation velocity ! FAC_B Factor representing the influence of the action- ! density depending of the propagation velocity ! GAMMA PI - alpha - beta ! HM Maximum waveheight (breaking source term) ! GRAV input Gravitational acceleration ! FRAC Fraction of total wet points ! ! one and more dimensional arrays: ! --------------------------------- ! ! AC1 4D Action density as function of D,S,X,Y at time T ! AC2 4D (Nonstationary case) action density as function ! of D,S,X,Y at time T+DT ! CGO 2D Group velocity as function of IC and IS in the ! direction of wave propagation in absence of currents ! CAX 3D Wave transport velocity in X-direction, function of ! (ID,IS,IC) ! CAY 3D Wave transport velocity in Y-direction, function of ! (ID,IS,IC) ! CAS 3D Wave transport velocity in S-direction, function of ! (ID,IS,IC) ! CAD 3D Wave transport velocity in D-dirction, function of ! (ID,IS,IC) ! COMPDA 3D array containing depth and other arrays of (IX,IY) 20.39 ! JDP1 Depth as function of X and Y at time T ! JDP2 (Nonstationary case) depth as function of X and Y ! at time T+DT ! JVX1 X-component of current velocity of X and Y ! at time T ! JVX2 (Nonstationary case) X-component of current ! velocity in (X,Y) at time T+DT ! JVY1 Y-component of current velocity in (X,Y) ! at time T ! JVY2 (Nonstationary case) Y-component of current ! velocity in (X,Y) at time T+DT ! JWX2 X-component of wind velocity in (X,Y) 40.00 ! at time T+DT (nonstationary case) 40.00 ! JWY2 Y-component of wind velocity in (X,Y) 40.00 ! at time T+DT (nonstationary case) 40.00 ! JUBOT Absolute orbital velocity in a gridpoint (IX,IY) ! SWTSDA 4D intermediate data computed for the test points; ! there are MTSVAR subarrays: ! JPWNDD wind input term (implicit part) ! JPWNDS wind input term (explicit part) ! JPWCAP whitecapping source term ! JPBTFR bottom friction ! JPVEGT vegetation dissipation ! JPTURB turbulent dissipation ! JPMUD fluid mud-induced wave dissipation ! JPICE dissipation by sea ice ! JPWBRK surf breaking ! JPSWEL swell dissipation ! JP4S quadruplet interactions ! JP4D quadruplet interactions ! JPTRI triad interactions ! ALIMW 1D Maximum energy by wind growth. This dummy array is ! used because the maximum value has to be checked ! direct after the solver of the tri-diagonal matrix ! see the subroutine SOLMAT ! GROWW 1D Check for a certain frequency if the waves are ! growing or not in a spectral direction (LOGICAL) ! HSAC0 2D Represent the significant wave height at iter-2 ! HSAC1 2D Represent the significant wave height at iter-1 ! HSAC2 2D Represent the significant wave height at iter ! HSDIFC 2D Represent Hs(iter) - Hs(iter-2) meant for ! computation of curvature of Hs ! IMATDA 2D Coefficients of main diagonal of matrix ! IMATLA 2D Coefficients of lower diagonal of matrix in theta-space ! IMATUA 2D Coefficients of upper diagonal of matrix in theta-space ! IMAT5L 2D Coefficients of lower diagonal of matrix in sigma-space ! IMAT6U 2D Coefficients of upper diagonal of matrix in sigma-space ! IMATRA 2D Coefficients of right hand side ! KWAVE 2D wavenumber as function of the relative frequency S ! and position IC(ix,iy) ! DMW 2D mud dissipation rate as function of IC and IS ! PBOT 1D Coefficient for the bottom friction models ! PSURF 1D Coefficient for the wave breaking model ! PTRIAD 1D Coefficient for the triad interaction model ! PWCAP 1D Coefficient for the white capping model ! PWIND 1D Coefficient for the wind growth model ! SACC0 2D Represents the mean wave frequency at iter-2 ! SACC1 2D Represents the mean wave frequency at iter-1 ! SACC2 2D Represents the mean wave frequency at iter ! TMDIFC 2D Represent Tm(iter) - Tm(iter-2) meant for ! computation of curvature of Tm ! PWTAIL 1D coefficients for tail of spectrum ! IDCMIN 1D frequency dependent counter in directional space ! no current <---> current ! IDCMAX 1D frequency dependent counter in directional space ! no current <---> current ! ISCMIN 1D frequency dependent counter in frequency space ! no current <---> current ! ISCMAX 1D frequency dependent counter in frequency space ! no current <---> current ! ANYBIN 2D Set for a particular bin TRUE or FALSE depending on ! propagation velocities within a sweep ! WWINT 1D Counters for 4 wave-wave interactions ! WWAWG 1D Weight coefficients for the 4 wave-wave interactions ! WWSWG 1D Weights coefficients for the 4 wave-wave interactions ! for the semi-implicit computation ! ISLMIN 1D Lowest sigma-index occured in applying limiter ! NFLIM 1D Number of frequency use of limiter in each ! geographical point ! NRSCAL 1D Number of frequency use of rescaling in each ! geographical point ! AC2LOC 2D help array containing action density for ! sending/receiving with MPI ! IARR 1D help array of type integer for MPI communication ! ARR 1D help array of type real for MPI communication ! REFLSO 2D contribution to the source term due to reflection ! ! Coefficients for the arrays: ! ----------------------------- ! default ! value: ! ! PBOT(1) = CFC 0.005 (Collins equation) ! PBOT(2) = CFW 0.01 (Collins equation) ! PBOT(3) = GAMJNS 0.038 (Jonswap formulation) ! note: this lower friction value combined with second order polynomial wind drag ! PBOT(4) = MF -0.08 (Madsen equation) ! PBOT(5) = KN 0.05 (bottom roughness) ! ! ISURF 1 (Constant breaking coefficient) ! 2 (variable breaking coefficient ! according to Nelson (1994)) ! PSURF(1) = ALFA 1.0 (Battjes Janssen) ! PSURF(2) = GAMMA 0.73 (breaking criterium) ! ! PWCAP(1) = ALFAWC 2.36e-5 (Empirical coefficient) ! PWCAP(2) = ALFAPM 3.02E-3 (Alpha of Pierson Moskowitz frequency) ! ! PWIND(1) = CF10 188.0 (second generation wind growth model) ! PWIND(2) = CF20 0.59 (second generation wind growth model) ! PWIND(3) = CF30 0.12 (second generation wind growth model) ! PWIND(4) = CF40 250.0 (second generation wind growth model) ! PWIND(5) = CF50 0.0023 (second generation wind growth model) ! PWIND(6) = CF60 -0.2233 (second generation wind growth model) ! PWIND(7) = CF70 0. (second generation wind growth model) ! PWIND(8) = CF80 -0.56 (second generation wind growth model) ! PWIND(9) = RHOAW 0.00125 (density air / density water) ! PWIND(10) = EDMLPM 0.0036 (limit energy Pierson Moskowitz) ! PWIND(11) = CDRAG 0.0012 (drag coefficient) ! PWIND(12) = UMIN 1.0 (minimum wind velocity) ! PWIND(13) = PMLM 0.13 ( ) ! ! PNUMS(1) = DREL relative error in Hs and Tm ! PNUMS(2) = DHABS absolute error in Hs ! PNUMS(3) = DTABS absolute error in Tm ! PNUMS(4) = NPNTS number of points were accuracy is reached ! ! PNUMS(5) = NOT USED ! PNUMS(6) = CDD blending parameter for finite differences ! in theta space ! PNUMS(7) = CSS blending parameter for finite differences ! in sigma space ! PNUMS(8) = NUMFRE numerical scheme in frequency space : ! 1) implicit scheme ! 2) explicit scheme CFL limited ! 3) explicit scheme filter after iteration ! PNUMS(9) = DIFFC if explicit scheme is used, then numerical ! diffusion coefficient can be chosen ! PNUMS(12) = EPS2 termination criterion in relative sense for a ! penta-diagonal solver ! PNUMS(13) = OUTP request for output for a penta-diagonal solver ! PNUMS(14) = NITER maximum number of iterations for a penta-diagonal ! solver ! PNUMS(15) = DHOVAL global error in Hs ! = CURVAT curvature of Hs meant for convergence check ! PNUMS(16) = DTOVAL global error in Tm01 ! PNUMS(17) = CDLIM coefficient of limitation of Ctheta ! PNUMS(18) = FROUDMAX maximum Froude number for reduction of currents ! PNUMS(19) = CFL CFL criterion for option explicit scheme ! in frequency space (see PNUMS(8)) ! PNUMS(20) = GRWMX maximum growth in spectral bin ! ! PNUMS(21) = STOPC type of stopping criterion: ! 0: standard SWAN based on relative and global ! errors of Hs and Tm01, ! 1: based on absolute, relative and curvature ! errors of Hs ! ! PNUMS(30) = ALFA relaxation parameter for under-relaxation method ! ! arrays for the 4-wave interactions: ! ! WWINT ( 1 = IDP WWAWG ( = AGW1 WWSWG ( = SWG1 ! 2 = IDP1 = AWG2 = SWG2 ! 3 = IDM = AWG3 = SWG3 ! 4 = IDM1 = AWG4 = SWG4 ! 5 = ISP = AWG5 = SWG5 ! 6 = ISP1 = AWG6 = SWG6 ! 7 = ISM = AWG7 = SWG7 ! 8 = ISM1 = AWG8 ) = SWG8 ) ! 9 = ISLOW ! 10= ISHGH ! 11= ISCLW ! 12= ISCHG ! 13= IDLOW ! 14= IDHGH ! 15= MSC4MI ! 16= MSC4MA ! 17= MDC4MI ! 18= MDC4MA ! 19= MSCMAX ! 20= MDCMAX ! 21= IDPP ! 22= IDMM ! 23= ISPP ! 24= ISMM ) ! ! ! 6. Local variables ! ! SIGLOW: recommended lowest frequency when TRIADS are activated ! REAL SIGLOW ! ! 7. Common blocks used ! ! ! 8. Subroutines used ! ! INSAC ! SWOMPU ! PLTSRC ! SETUPP ! SACCUR ! SWSTPC !TIMG! SWTSTA 40.23 !TIMG! SWTSTO 40.23 ! SWREDUCE 40.30 !JAC! SWEXCHG 40.30 !WFR! SWRECVAC 40.30 !WFR! SWSENDAC 40.30 !JAC! SWSYNC 40.30 ! MSGERR : Handles error messages according to severity 40.41 ! NUMSTR : Converts integer/real to string 40.41 ! TXPBLA : Removes leading and trailing blanks in string 40.41 !MPI! STPNOW : Logical indicating whether program must !MPI! terminated or not ! !MPI LOGICAL STPNOW 34.01 ! ! 9. Subroutines calling ! ! SWANPREn, SWANOUTn ! ! 10. Error messages ! ! --- ! ! 11. Remarks ! ! SWCOMP is the main subroutine is and called of the main program SWAN. ! The main program SWAN is build of three main subroutines: ! ! 1. SWREAD (preparation of the computation (reading parameters)) ! 2. SWCOMP (computation of the action densities (discussed below)) ! 3. SWOUTP (output of the computation) ! ! In this part the subroutine SWCOMP is discussed: ! ! SWCOMP ! ====== ! | ! |------+ INSAC determine initial values for ! | accuracy check ! | ! | ! Begin parallel region over threads 40.22 ! | ! |-------+ SWOMPU ! | | ! | |--------+ SWAPAR determ. of waveparameters ! | | ! | |--------+ SPROXY comp. of propagation ! | | velocities of energy: ! | | CAX, CAY ! | | ! | |--------+ SPROSD comp. of propagation ! | | velocities of energy: ! | | CAS, CAD ! | | ! | |--------+ WINDP1 compute absolute wind, FPM ! | | mean wind direction, min. and ! | | max. counters for the wind, ! | | wind friction velocity ! | | ! | |--------+ CNTAIL Compute contributions to ! | | spectrum due to high frequency ! | | tail ! | | ! | |--------+ SPREDT predict energy density in ! | | gridpoints for first ! | | iteration ! | | ! | |--------+ SINTGRL comp. Ub, Etot, Hmax, Qb, 40.02 ! | | | SME, SMA, SMESPC , SMASPC ! | | | ! | | +-------+ FRABRE comp. of fraction of 30.77 ! | | breaking waves ! | | ! | |--------+ SOURCE comp. of source terms ! | | | ! | | +-------+ SBOT bottom friction ! | | | ! | | +-------+ SVEG dissipation due to vegetation ! | | | ! | | +-------+ STURBV dissipation due to turbulence ! | | | ! | | +-------+ SMUD fluid mud-induced wave dissipation ! | | | ! | | +-------+ SICE dissipation by sea ice ! | | | ! | | +-------+ SWCAP white capping ! | | | ! | | +-------+ SSURF wave breaking ! | | | ! | | +-------+ SWLTA nonlinear triad interactions based on LTA ! | | | ! | | +-------+ SWSNL? nonlinear quadruplet interactions ! | | | ! | | +-------+ SWIND1 first generation wind model ! | | | ! | | + -- WINDP2 compute total wind sea energy o ! | | | SWIND2 second generation wind model ! | | | ! | | + SWIND3 third generation wind model ! | | ! | |--------+ ACTION comp. of ACTION balance eq. ! | | | ( @ CAn/@n ) ! | | | ! | | +-------+ STIME comp. of (@AC2/@t) ! | | | ! | | +-------+ STRSX @[CAX AC2]/@X ! | | | ! | | +-------+ STRSY @[CAY AC2]/@Y ! | | | ! | | +-------+ STRSS @[CAS AC2]/@S ! | | | ! | | +-------+ STRSD @[CAD AC2]/@D ! | | ! | |--------+ SOLMAT solve the matrix which is ! | | filled in SOURCE and ACTION ! | | ! | |--------+ FILIMP filter the frequency spectrum ! | | | in presence of a current using ! | | | a diffusion model (important for ! | | | wave blocking) -->IMPLICIT SCHEME ! | | | ! | | |----+ DIFSOL The matrix filled in FILIMP is ! | | solved for each direction separately ! | | ! | |--------+ WINDP3 Limit the energy spectrum ! | for first and second ! | generation wind model ! | ! | ! End parallel region over threads 40.22 ! | ! |-------+ PLTSRC write sourceterm after an ! | iteration to a file SOURCE ! | ! |-------+ SACCUR / SWSTPC check accuracy of the comp. ! | ! END SWCOMP ! ! ! 12. Structure ! ! The numerical procedure in SWAN is based on the four-direction ! point Gauss-Seidel technique with the following ! ! {**************************************************************} ! { definition of the sweep directions } ! { } ! { \ N / } ! { swp_NW = 4 _\| | |/_ swp_EN = 3 } ! { | } ! { | } ! { W --------------------------- E (0 degrees,id=1)} ! { | } ! { __. | .__ } ! { swp_WS = 1 /| | |\ swp_SE = 2 } ! { / S \ } ! { } ! {**************************************************************} ! { } ! { swp_NW: * ksy=+1 swp_EN: * ksy=+1 } ! { | | } ! { | -dy -dy | } ! { dx | | -dx } ! { *---------o IX,IY IX,IY o--------* } ! { ksx=-1 ksx=+1 } ! { } ! { } ! { swp_WS: dx swp_SE: -dx } ! { *---------o IX,IY IX,IY o--------* } ! { ksx=-1 | | ksx=+1 } ! { | dy dy | } ! { | | } ! { * ksy=-1 * ksy=-1 } ! {**************************************************************} ! ! ---------------------------------------------------------- ! Call INSAC to give values to HSACC and SACC meant for accuracy check ! ---------------------------------------------------------- ! For IT = 1 to end of computation time (MTC), do, ! ! If accuracy <= given tolerance, then do iteration, ! ! ----------------------------------------------------- ! give argument for sweep : swpdir = 1 ! KSX = -1 DDX = +DX. ! KSY = -1 DDY = +DY. ! give number of direction a start and an end value: ! For IY=2 to MYC and IX=2 to MXC, do, ! Call SWOMPU to compute the wave field ! ----------------------------------------------------- ! give argument for sweep : swpdir = 2 ! KSX = +1 DDX = -DX. ! KSY = -1 DDY = +DY. ! give number of direction a start and an end value: ! For IX=MXC-1 to 1 and IY=2 to MYC, do, ! Call SWOMPU to compute the wave field ! ----------------------------------------------------- ! give argument for sweep : swpdir = 3 ! KSX = +1. DDX = -DX. ! KSY = +1. DDY = -DY. ! give number of direction a start and an end value: ! For IY=MYC-1 to 1 and IX=MXC-1 to 1, do, ! Call SWOMPU to compute the wave field ! ----------------------------------------------------- ! give argument for sweep : swpdir = 4 ! KSX = -1 DDX = +DX. ! KSY = +1 DDY = -DY. ! give number of direction a start and an end value: ! For IX=2 to MXC and IY=MYC-1 to 1, do, ! Call SWOMPU to compute the wave field ! ---------------------------------------------------- ! CALL PLTSRC to write the source term to a file ! ---------------------------------------------------- ! CALL SACCUR / SWSTPC to check the accuracy of the computation ! -------------------------------------------------------- ! End of SWCOMP ! -------------------------------------------------------- ! ! 13. Source text ! ! ************************************************************************ ! * * ! * MAIN SUBROUTINE OF COMPUTATIONAL PART * ! * * ! * -- SWCOMP -- * ! * * ! * Definition of variables in main program * ! * * ! ************************************************************************ ! INTEGER :: ITER ,IX ,IY ,IS ,IT 30.72 INTEGER :: IP, IDC, ISC 40.31 INTEGER :: KSX ,KSY ,SWPDIR INTEGER :: INOCNV 30.72 INTEGER :: INOCNT 40.31 ! REAL :: DDX ,DDY ,ACCUR ,XIS ,SNLC1 ,DAL1 ,DAL2 ,DAL3 30.74 ! LOGICAL :: PRECOR ! INTEGER :: MNISL, MXNFL, MXNFR, NPFL, NPFR, NWETP, IDEBUG 40.23 REAL :: FRAC 40.23 PARAMETER (IDEBUG=0) 40.23 ! INTEGER ISTAT, IF1, IL1 40.41 CHARACTER*20 NUMSTR, CHARS(1) 40.41 CHARACTER*80 MSGSTR 40.41 ! INTEGER IARR(10) 40.30 REAL ARR(10) 40.30 !WFR INTEGER JDUM, JS, JE, JWFRS, JWFRE, INCJ, JJ, JNODE, 40.30 !WFR & JSD, JED, IE, INCI, III, LSTCP 40.31 !WFR !JAC INTEGER ISWP !JAC INTEGER II, IX1, IX2, IY1, IY2 40.31 ! ! Add variables for the XNL interface (quadruplet interaction) 40.41 INTEGER :: IXGRID, IXQUAD, IQERR 40.41 ! INTEGER :: XYTST(2*NPTST) 30.21 INTEGER :: KGRPNT(MXC,MYC) 30.21 INTEGER :: CROSS(2,MCGRD) ! REAL AC2(MDC,MSC,MCGRD) , 30.21 & AC1(MDC,MSC,MCGRD) , 30.21 & COMPDA(MCGRD,MCMVAR) 40.31 REAL WWAWG(8), WWSWG(8) 40.22 INTEGER, DIMENSION(:), ALLOCATABLE :: IDCMIN, IDCMAX, 40.22 & ISCMIN, ISCMAX 40.22 INTEGER WWINT(24) 40.41 40.22 REAL, DIMENSION(:,:,:), ALLOCATABLE :: CAX,CAY,CAX1,CAY1, 40.41 40.22 & CAS,CAD 40.22 REAL, DIMENSION(:,:), ALLOCATABLE :: CGO,KWAVE,DMW 40.59 40.22 REAL, DIMENSION(:,:), ALLOCATABLE :: ALIMW 40.22 REAL, DIMENSION(:,:), ALLOCATABLE :: UE,SA1,SA2,SFNL 40.22 REAL, DIMENSION(:,:), ALLOCATABLE :: DA1C,DA1P,DA1M, 40.22 & DA2C,DA2P,DA2M,DSNL 40.22 REAL, DIMENSION(:,:,:), ALLOCATABLE :: MEMNL4 40.22 REAL, DIMENSION(:,:,:), ALLOCATABLE :: MEMSINA 40.88 REAL, DIMENSION(:,:,:), ALLOCATABLE :: MEMSINB 40.88 REAL, DIMENSION(:,:,:), ALLOCATABLE :: OBREDF 40.22 REAL, DIMENSION(:,:), ALLOCATABLE :: REFLSO 40.41 REAL, DIMENSION(:), ALLOCATABLE :: HSAC1,HSAC2,SACC1,SACC2 40.22 REAL, DIMENSION(:), ALLOCATABLE :: HSAC0,HSDIFC 40.41 REAL, DIMENSION(:), ALLOCATABLE :: SACC0,TMDIFC 40.93 REAL, DIMENSION(:,:), ALLOCATABLE :: SETPDA 40.41 40.22 LOGICAL, DIMENSION(:), ALLOCATABLE :: GROWW 40.22 LOGICAL, DIMENSION(:), ALLOCATABLE :: ANYWND 40.22 REAL, ALLOCATABLE :: SWTSDA(:,:,:,:) 40.31 ! SWMATR and LSWMAT replace the single array SWMATR 40.22 ! that is equivalenced to the logical array LSWMATR 40.22 ! in the subroutine SWOMPU. 40.22 REAL, DIMENSION(:,:,:), ALLOCATABLE :: SWMATR 40.22 LOGICAL, DIMENSION(:,:,:), ALLOCATABLE :: LSWMAT 40.22 !$ LOGICAL, ALLOCATABLE :: LLOCK(:,:) 40.31 40.22 INTEGER, ALLOCATABLE :: ISLMIN(:), NFLIM(:), NRSCAL(:) 40.23 !MPI REAL, ALLOCATABLE :: AC2LOC(:) 40.30 ! Add variables for OMP thread parameters. 40.31 !$ INTEGER, EXTERNAL :: OMP_GET_NUM_THREADS, OMP_GET_THREAD_NUM 40.31 INTEGER I1GRD,I2GRD,I1MYC,I2MYC 40.31 ! INTEGER IENT, MSTPDA, KWIND, KWCAP, KQUAD, IYSTEP, J, IJ, IK, ID REAL ALFAT, GRWOLD ! !----------------------------------------------------------------------- ! End of variable definition !----------------------------------------------------------------------- ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SWCOMP') ! IF (IT .EQ. 1 .AND. ITEST.GE.1) CALL SWPRSET (SPCSIG) 40.80 ! ! *** print test points *** ! IF (NPTST.GT.0) THEN DO 121 II = 1, NPTST WRITE(PRINTF,1001) II, XYTST(2*II-1)+MXF-2, XYTST(2*II)+MYF-2 40.30 1001 FORMAT(' Test points :',3I5) 121 CONTINUE ENDIF ! ! *** prepare ranges of spectral space, constants and *** 40.41 ! *** weight factors for nonlinear 4 wave interactions *** 40.41 ! 40.41 !TIMG CALL SWTSTA(135) 40.41 IF ( IQUAD.GE.1 ) 40.41 & CALL FAC4WW (XIS ,SNLC1 , 40.41 & DAL1 ,DAL2 ,DAL3 ,SPCSIG, 40.41 & WWINT ,WWAWG ,WWSWG ) 40.41 !TIMG CALL SWTSTO(135) 40.41 ! 40.22 ! *** Indexing and bounds for SWMAT arrays 40.22 ! 40.22 JMATD = 1 40.22 JMATR = 2 40.22 JMATL = 3 40.22 JMATU = 4 40.22 JMAT5 = 5 40.22 JMAT6 = 6 40.22 JDIS0 = 7 40.22 JDIS1 = JDIS0+MDISP 40.67 40.22 JGEN0 = JDIS1+MDISP 40.85 JGEN1 = JGEN0+MGENR 40.85 JRED0 = JGEN1+MGENR 40.85 JRED1 = JRED0+MREDS 40.85 JTRA0 = JRED1+MREDS 40.85 JTRA1 = JTRA0+MTRNP 40.85 JAOLD = JTRA1+MTRNP 40.85 40.67 40.22 JLEK1 = JAOLD+1 40.67 40.22 MSWMATR = JLEK1 40.85 40.67 40.61 40.22 JABIN = 1 40.22 JABLK = 2 40.22 MLSWMAT = 2 40.22 ! *** Stencil size 40.22 IF (PROPSC.EQ.3) THEN 33.09 ICMAX = 13 !WFR LSTCP = 3 40.31 ELSE IF (PROPSC.EQ.2) THEN 33.10 ICMAX = 7 40.59 33.10 !WFR LSTCP = 2 40.31 ELSE ICMAX = 5 40.59 33.10 !WFR LSTCP = 1 40.31 ENDIF 33.08 !TIMG CALL SWTSTA(101) 40.23 !---------------------------------------------------------------------- 40.22 ! Begin allocate shared arrays. 40.22 !---------------------------------------------------------------------- 40.22 ! ALLOCATE(HSAC1(MCGRD)) 40.22 ALLOCATE(HSAC2(MCGRD)) 40.22 ALLOCATE(SACC1(MCGRD)) 40.22 ALLOCATE(SACC2(MCGRD)) 40.22 ALLOCATE(HSAC0(MCGRD)) 40.41 ALLOCATE(HSDIFC(MCGRD)) 40.41 ALLOCATE(SACC0(MCGRD)) 40.93 ALLOCATE(TMDIFC(MCGRD)) 40.93 ! ALLOCATE(ISLMIN(MCGRD)) 40.23 ALLOCATE(NFLIM(MCGRD)) 40.23 ALLOCATE(NRSCAL(MCGRD)) 40.23 ! IF ( IQUAD .GE. 1) THEN ! *** quadruplets *** IF ( IQUAD .GE. 3 ) THEN 40.10 ! *** prior to every iteration full directional domain *** ALLOCATE(MEMNL4(MDC,MSC,MCGRD),STAT=ISTAT) 40.41 40.22 IF ( ISTAT.NE.0 ) THEN 40.41 CHARS(1) = NUMSTR(ISTAT,RNAN,'(I6)') 40.41 CALL TXPBLA(CHARS(1),IF1,IL1) 40.41 MSGSTR = 40.41 & 'Allocation problem: array MEMNL4 and return code is '// 40.41 & CHARS(1)(IF1:IL1) 40.41 CALL MSGERR ( 4, MSGSTR ) 40.41 RETURN 40.41 END IF 40.41 ELSE 40.22 ! *** iquad < 3 *** 40.22 ALLOCATE(MEMNL4(0,0,0)) 40.22 END IF ELSE ! *** no quadruplets *** ALLOCATE(MEMNL4(0,0,0)) 40.22 ENDIF ! IF ( IWIND.EQ.8 ) THEN 40.88 ! *** prior to every iteration full directional domain *** ISTAT=0 ALLOCATE(MEMSINA(MDC,MSC,MCGRD),STAT=ISTAT) IF (ISTAT.EQ.0) ALLOCATE(MEMSINB(MDC,MSC,MCGRD),STAT=ISTAT) IF ( ISTAT.NE.0 ) THEN 40.88 CHARS(1) = NUMSTR(ISTAT,RNAN,'(I6)') 40.88 CALL TXPBLA(CHARS(1),IF1,IL1) 40.88 MSGSTR = 40.88 & 'Allocation problem: array MEMSIN and return code is '// 40.88 & CHARS(1)(IF1:IL1) 40.88 CALL MSGERR ( 4, MSGSTR ) 40.88 RETURN 40.88 END IF 40.88 ELSE 40.88 ALLOCATE(MEMSINA(0,0,0)) 40.88 ALLOCATE(MEMSINB(0,0,0)) 40.88 END IF ! ! *** Lock array for thread management 40.22 !$ ALLOCATE(LLOCK(MXC,MYC)) 40.31 40.22 !MPI ALLOCATE(AC2LOC(MCGRD)) 40.30 !MPI ALLOCATE(SWTSDA(MDC,MSC,NPTSTA,MTSVAR)) 40.31 SWTSDA = 0. 40.41 ! ! *** In case of SETUP expand array for setup data *** 32.02 ! IF (LSETUP.GT.0) THEN 31.04 MSTPDA = 23 31.04 ALLOCATE(SETPDA(MCGRD,MSTPDA)) 40.41 40.22 ELSE 40.22 ALLOCATE(SETPDA(0,0)) 40.41 40.22 END IF !---------------------------------------------------------------------- 40.22 ! End allocate shared arrays. 40.22 !---------------------------------------------------------------------- 40.22 !---------------------------------------------------------------------- 40.31 ! Begin initialization of shared arrays. 40.31 !---------------------------------------------------------------------- 40.31 HSAC1 = 0. 40.31 HSAC2 = 0. 40.31 SACC1 = 0. 40.31 SACC2 = 0. 40.31 HSAC0 = 0. 40.41 HSDIFC= 0. 40.41 SACC0 = 0. 40.93 TMDIFC= 0. 40.93 IF ( IQUAD.GE.3 ) MEMNL4 = 0. 40.41 40.31 IF ( IWIND.EQ.8 ) MEMSINA = 0. 40.88 IF ( IWIND.EQ.8 ) MEMSINB = 0. 40.88 IF ( LSETUP.GT.0 ) SETPDA = 0. 40.31 !---------------------------------------------------------------------- 40.31 ! End initialization shared arrays. 40.31 !---------------------------------------------------------------------- 40.31 !TIMG !TIMG CALL SWTSTO(101) 40.23 !---------------------------------------------------------------------- 40.22 ! Begin parallel region. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP PARALLEL DEFAULT(SHARED) 40.22 !$OMP+PRIVATE(ITER, SWPDIR, IX, IY, II, IJ, IK) 40.41 40.22 !$OMP+PRIVATE(CAX, CAY, CAX1, CAY1, CAS, CAD, CGO, KWAVE, DMW) 40.59 40.22 !$OMP+PRIVATE(SWMATR, LSWMAT, ALIMW, GROWW, IDCMIN, IDCMAX) 40.22 !$OMP+PRIVATE(ISCMIN, ISCMAX, UE, SA1, SA2, SFNL) 40.41 40.22 !$OMP+PRIVATE(DA1C, DA1P, DA1M, DA2C, DA2P, DA2M, DSNL) 40.22 !$OMP+PRIVATE(ANYWND, OBREDF) 40.41 40.22 !$OMP+PRIVATE(REFLSO, INOCNT) 40.41 40.31 !$OMP+PRIVATE(IP,IDC,ISC) 40.31 !$OMP+PRIVATE(I1GRD,I2GRD,I1MYC,I2MYC) 40.31 !$OMP+PRIVATE(JDUM,JJ,III) 40.31 !$OMP+PRIVATE(IS,IE,INCI,JS,JE,INCJ,JSD,JED,JNODE,JWFRS,JWFRE) 40.31 !$OMP+COPYIN(ICMAX,CSETUP) !$OMP+COPYIN(COSLAT,PROPSL) !$OMP+COPYIN(IPTST,TESTFL) !$OMP+COPYIN(RDFSIN) ! !$OMP MASTER 40.22 ! Print number of threads set by environment 40.22 !$ IF ( IT.EQ.1 ) 41.10 !$ +WRITE(SCREEN,'(a,i2/)') 41.10 40.22 !$ + ' Number of threads during execution of parallel region = ', 41.10 40.22 !$ + OMP_GET_NUM_THREADS() 41.10 40.22 !$OMP END MASTER 40.22 !TIMG !TIMG CALL SWTSTA(101) 40.23 !---------------------------------------------------------------------- 40.22 ! Begin allocate private arrays. 40.22 !---------------------------------------------------------------------- 40.22 ALLOCATE(CAX(MDC,MSC,MICMAX)) 40.22 ALLOCATE(CAY(MDC,MSC,MICMAX)) 40.22 ALLOCATE(CAX1(MDC,MSC,MICMAX)) 40.22 ALLOCATE(CAY1(MDC,MSC,MICMAX)) 40.22 ALLOCATE(CAS(MDC,MSC,MICMAX)) 40.22 ALLOCATE(CAD(MDC,MSC,MICMAX)) 40.22 ALLOCATE(CGO(MSC,MICMAX)) 40.22 ALLOCATE(KWAVE(MSC,MICMAX)) 40.22 ALLOCATE(DMW(MSC,MICMAX)) 40.59 ! Since SWMATR has been broken up into a real array(SWMATR) and a 40.22 ! logical array(LSWMAT), the size of each array has been adjusted 40.22 ! to MSWMATR(x-2) and MLSWMAT(2) instead of the original equivalenced 40.22 ! array with a size of MSWMAT(x). 40.22 ALLOCATE(SWMATR(MDC,MSC,MSWMATR)) 40.22 ALLOCATE(LSWMAT(MDC,MSC,MLSWMAT)) 40.22 ALLOCATE(ALIMW(MDC,MSC)) 40.22 ALLOCATE(GROWW(MDC*MSC)) 40.22 ALLOCATE(IDCMIN(MSC)) 40.22 ALLOCATE(IDCMAX(MSC)) 40.22 ALLOCATE(ISCMIN(MDC)) 40.22 ALLOCATE(ISCMAX(MDC)) 40.22 ! *** quadruplets *** IF ( IQUAD .GE. 1) THEN ALLOCATE(UE(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(SA1(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(SA2(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(SFNL(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 IF ( IQUAD .EQ. 1 ) THEN ! *** semi-implicit calculation *** ALLOCATE(DA1C(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(DA1P(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(DA1M(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(DA2C(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(DA2P(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(DA2M(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ALLOCATE(DSNL(MSC4MI:MSC4MA,MDC4MI:MDC4MA)) 40.22 ELSE 40.22 ! *** iquad > 1 *** 40.22 ALLOCATE(DA1C(0,0)) 40.22 ALLOCATE(DA1P(0,0)) 40.22 ALLOCATE(DA1M(0,0)) 40.22 ALLOCATE(DA2C(0,0)) 40.22 ALLOCATE(DA2P(0,0)) 40.22 ALLOCATE(DA2M(0,0)) 40.22 ALLOCATE(DSNL(0,0)) 40.22 END IF 40.22 ELSE ! *** no quadruplets *** ALLOCATE(UE(0,0)) 40.22 ALLOCATE(SA1(0,0)) 40.22 ALLOCATE(SA2(0,0)) 40.22 ALLOCATE(SFNL(0,0)) 40.22 ALLOCATE(DA1C(0,0)) 40.22 ALLOCATE(DA1P(0,0)) 40.22 ALLOCATE(DA1M(0,0)) 40.22 ALLOCATE(DA2C(0,0)) 40.22 ALLOCATE(DA2P(0,0)) 40.22 ALLOCATE(DA2M(0,0)) 40.22 ALLOCATE(DSNL(0,0)) 40.22 END IF ! ! *** for wind, indicating a bin inside the wind region *** ! ALLOCATE(ANYWND(MDC)) 40.22 ! ! *** for obstacles, to store the transmission coefficients *** ! *** and contribution to the source terms *** ! ALLOCATE(OBREDF(MDC,MSC,2)) 40.22 ALLOCATE(REFLSO(MDC,MSC)) 40.41 !---------------------------------------------------------------------- 40.22 ! End allocate private arrays. 40.22 !---------------------------------------------------------------------- 40.22 !---------------------------------------------------------------------- 40.31 ! Begin initialization of private arrays. 40.31 !---------------------------------------------------------------------- 40.31 CAX = 0. 40.31 CAY = 0. 40.31 CAX1 = 0. 40.31 CAY1 = 0. 40.31 CAS = 0. 40.31 CAD = 0. 40.31 CGO = 0. 40.31 KWAVE = 0. 40.31 DMW = 0. 40.59 SWMATR = 0. 40.31 ALIMW = 0. 40.31 IF ( IQUAD.GE.1 ) THEN 40.31 UE = 0. 40.31 SA1 = 0. 40.31 SA2 = 0. 40.31 SFNL = 0. 40.31 IF ( IQUAD.EQ.1 ) THEN 40.31 DA1C = 0. 40.31 DA1P = 0. 40.31 DA1M = 0. 40.31 DA2C = 0. 40.31 DA2P = 0. 40.31 DA2M = 0. 40.31 DSNL = 0. 40.31 END IF 40.31 END IF 40.31 !---------------------------------------------------------------------- 40.31 ! End initialization private arrays. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP BARRIER 40.31 !TIMG !TIMG CALL SWTSTO(101) 40.23 ! Each thread compute its own spatial grid loop bounds for MCGRD 40.31 CALL SWMTLB(1,MCGRD,I1GRD,I2GRD) 40.31 ! Each thread compute its own spatial grid loop bounds for MYC 40.31 CALL SWMTLB(1,MYC,I1MYC,I2MYC) 40.31 ! ! *** initialise values for determining the accuracy that *** ! *** has been reached *** ! *** This is done in parallel within OpenMP environment *** 40.31 ! !TIMG CALL SWTSTA(102) 40.23 CALL INSAC (AC2 ,SPCSIG ,COMPDA(1,JDP2) , 40.22 & HSAC2 ,SACC2 ,KGRPNT , 40.31 40.30 40.22 & I1MYC ,I2MYC ) 40.31 !TIMG CALL SWTSTO(102) 40.23 ! ! *** To obtain a first estimate of energy density in a *** ! *** gridpoint considered we run the SWAN model (in case *** ! *** of active wind) in a second generation mode first. *** ! *** After 1st iteration, the options, as defined by the *** ! *** user, are re-activated. *** ! *** This first guess is not used in nonstationary *** ! *** computations (NSTATC>0), or if a restart file was *** ! *** used (ICOND=4) *** ! !$OMP MASTER 40.31 IF ( IWIND.GE.3 .AND. NSTATC.EQ.0 .AND. ICOND.NE.4 ) THEN 40.41 ! --- first guess will be used PRECOR = .TRUE. ELSE PRECOR = .FALSE. END IF !$OMP END MASTER 40.31 ! ! *** call initialization procedure of XNL to create *.BQF *** 40.41 ! *** interaction files *** 40.41 ! 40.41 !TIMG CALL SWTSTA(135) 40.41 !$OMP MASTER IF (IQUAD.EQ.51.OR.IQUAD.EQ.52.OR.IQUAD.EQ.53) THEN 40.41 CALL init_constants 40.41 IXQUAD = IQUAD - 50 40.41 IF (IAMMASTER) THEN 40.95 40.41 WRITE(SCREEN,*) 'GurboQuad initialization' 40.41 WRITE(SCREEN,*) 'gravity :', GRAV 40.41 WRITE(SCREEN,*) 'pftail :', PWTAIL(1) 40.41 WRITE(SCREEN,*) 'number of sigma values:', MSC 40.41 WRITE(SCREEN,*) 'number of directions :', MDC 40.41 WRITE(SCREEN,*) 'IQ_QUAD :', IXQUAD 40.41 END IF 40.41 ! 40.41 IXGRID = 3 40.41 CALL xnl_init(SPCSIG , SPCDIR(:,1)*180./PI , MSC , MDC , 40.41 & -PWTAIL(1), GRAV , COMPDA(2,JDP2) , 40.41 & MCGRD-1 , IXQUAD , IXGRID ,INODE,IQERR ) 40.41 END IF 40.41 !$OMP END MASTER !TIMG CALL SWTSTO(135) 40.41 ! !TIMG CALL SWTSTA(103) 40.23 DO 450 ITER = 1, ITERMX 30.00 ! initialise local (thread private) counter for SIP solver 40.31 INOCNT = 0 40.31 ! ! initialise propagation, generation, dissipation, redistribution, 40.85 ! leak and radiation stress for each iteration ! this is done in parallel within OpenMP environment 40.31 ! DO IP = I1GRD,I2GRD 40.31 COMPDA(IP,JDISS) = 0. COMPDA(IP,JLEAK) = 0. COMPDA(IP,JDSXB) = 0. 40.61 COMPDA(IP,JDSXS) = 0. 40.61 COMPDA(IP,JDSXW) = 0. 40.61 COMPDA(IP,JDSXM) = 0. 40.61 COMPDA(IP,JDSXV) = 0. 40.61 COMPDA(IP,JDSXI) = 0. 41.75 COMPDA(IP,JDSXT) = 0. 40.35 COMPDA(IP,JDSXL) = 0. 40.88 COMPDA(IP,JGENR) = 0. 40.85 COMPDA(IP,JGSXW) = 0. 40.85 COMPDA(IP,JREDS) = 0. 40.85 COMPDA(IP,JRSXQ) = 0. 40.85 COMPDA(IP,JRSXT) = 0. 40.85 COMPDA(IP,JTRAN) = 0. 40.85 COMPDA(IP,JTSXG) = 0. 40.85 COMPDA(IP,JTSXT) = 0. 40.85 COMPDA(IP,JTSXS) = 0. 40.85 COMPDA(IP,JRADS) = 0. 40.85 COMPDA(IP,JQB ) = 0. 40.67 !ESMF IF (SAVE_SINBAC) SINBAC(:,:,IP) = 0. ENDDO ! ! initialise Ursell number to 0 for each iteration 40.03 ! this is done in parallel within OpenMP environment 40.31 ! IF (ITRIAD.GT.0 & ) THEN DO IP = I1GRD,I2GRD 40.31 COMPDA(IP,JURSEL) = 0. ENDDO ENDIF ! 40.31 ! *** IQUAD = 3: the nonlinear wave interactions are *** 40.31 ! *** calculated just once for an iteration. First, *** 40.31 ! *** set the auxiliary array equal zero before a *** 40.31 ! *** new iteration *** 40.31 ! *** This is done in parallel within OpenMP environment *** 40.31 ! 40.31 IF ( IQUAD .GE. 3 ) THEN 40.31 DO IP = I1GRD,I2GRD 40.31 DO ISC = 1,MSC 40.31 DO IDC = 1,MDC 40.31 MEMNL4(IDC,ISC,IP)=0. 40.31 END DO 40.31 END DO 40.31 END DO 40.31 END IF 40.31 ! 40.88 IF ( IWIND .EQ. 8 ) THEN 40.88 DO IP = I1GRD,I2GRD 40.88 DO ISC = 1,MSC 40.88 DO IDC = 1,MDC 40.88 MEMSINA(IDC,ISC,IP)=0. 40.88 MEMSINB(IDC,ISC,IP)=0. 40.88 END DO 40.88 END DO 40.88 END DO 40.88 END IF 40.88 ! 40.31 !---------------------------------------------------------------------- 40.31 ! Begin master thread region. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP MASTER 40.31 ! 40.31 ! *** If a current is present and a penta-diagonal solver *** 40.31 ! *** is employed, it is possible that the solver does *** 40.31 ! *** not converged. For this, the counter INOCNV represents *** 40.31 ! *** the number of geographical points in which the solver *** 40.31 ! *** did not converged *** 40.31 ! 40.31 INOCNV = 0 40.31 ! IF ( ITEST.GE.30 .OR. IDEBUG.EQ.1 ) THEN ISLMIN(:) = 9999 40.23 NFLIM (:) = 0 40.23 NRSCAL(:) = 0 40.23 IARR = 0 40.30 ARR = 0. 40.30 END IF ! IF ( PRECOR ) THEN 40.41 ! *** third generation wave input *** IF ( ITER .EQ. 1 )THEN ! *** save settings of 3rd generation model *** 40.13 ! *** bottom friction, surf breaking and triads may *** ! *** still active *** KWIND = IWIND KWCAP = IWCAP KQUAD = IQUAD ! *** save maximum change per bin and under-relaxation *** 40.41 40.13 GRWOLD = PNUMS(20) ALFAT = PNUMS(30) 40.31 ! first guess settings 40.13 ! if 1st generation is to be used as first guess, replace 40.13 ! the next statement by IWIND = 1 40.13 IWIND = 2 IWCAP = 0 IQUAD = 0 PNUMS(20) = 1.E22 ! *** under-relaxation parameter is PNUMS(30) and 40.31 ! temporarily set to zero 40.31 PNUMS(30) = 0. 40.31 ELSE IF ( ITER .EQ. 2 ) THEN IWIND = KWIND IWCAP = KWCAP IQUAD = KQUAD PNUMS(20) = GRWOLD PNUMS(30) = ALFAT 40.31 ENDIF ! ENDIF IF ( PRECOR .AND. ITER .LE. 2 ) THEN 40.41 WRITE(PRINTF,*)' -----------------------------------------', & '----------------------' IF ( ITER .EQ. 1 ) THEN WRITE(PRINTF,*) ' First guess by 2nd generation model', & ' flags for first iteration:' ELSE IF ( ITER .EQ. 2 ) THEN WRITE(PRINTF,*) ' Options given by user are activated', & ' for proceeding calculation:' ENDIF WRITE(PRINTF,2001) ITER, PNUMS(20), PNUMS(30) 2001 FORMAT(' ITER ',I4,' GRWMX ',E12.4,' ALFA ', & E12.4) WRITE(PRINTF,2002) IWIND, IWCAP, IQUAD 2002 FORMAT(' IWIND ',I4,' IWCAP ',I4,' IQUAD ',I4) WRITE(PRINTF,2003) ITRIAD, IBOT , ISURF 2003 FORMAT(' ITRIAD ',I4,' IBOT ',I4,' ISURF ',I4) WRITE(PRINTF,2005) IVEG, ITURBV, IMUD 40.59 40.35 40.55 2005 FORMAT(' IVEG ',I4,' ITURBV ',I4,' IMUD ',I4) 40.59 40.35 40.55 WRITE(PRINTF,2006) IICE, ICEWIND 41.75 2006 FORMAT(' IICE ',I4,' ICEWIND ',F5.2) 41.75 WRITE(PRINTF,*)' -----------------------------------------', & '----------------------' ENDIF ! --- calculate diffraction parameter and its derivatives 40.21 !TIMG CALL SWTSTA(137) 40.41 IF ( IDIFFR.GT.0 ) 40.21 & CALL DIFPAR( AC2 , SPCSIG, KGRPNT, COMPDA(1,JDP2), 40.21 & CROSS , XCGRID, YCGRID, XYTST ) 40.21 !TIMG CALL SWTSTO(137) 40.41 !---------------------------------------------------------------------- 40.22 ! End master thread region. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP END MASTER 40.22 !---------------------------------------------------------------------- 40.22 ! Synchronize threads before loop over sweep directions. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP BARRIER 40.22 ! ! *** START ITERATION PROCESS WITH 4 SWEEPS *** ! ! *** loop over sweep directions *** ! !WFR DO 410 SWPDIR = 1, 4 !JAC DO 410 ISWP = 0, 3 !JAC !JAC! ====================================================================== 40.30 !JAC! !JAC! Determine sequence of sweeps depending on 40.30 !JAC! color of subdomain 40.30 !JAC! !JAC! ====================================================================== 40.30 !JAC !JAC IF ( IBCOL.EQ.IRED ) THEN 40.30 !JAC SWPDIR = MOD(ISWP ,4)+1 40.30 !JAC ELSE IF ( IBCOL.EQ.IYELOW ) THEN 40.30 !JAC SWPDIR = MOD(ISWP+1,4)+1 40.30 !JAC ELSE IF ( IBCOL.EQ.IGREEN ) THEN 40.30 !JAC SWPDIR = MOD(ISWP+2,4)+1 40.30 !JAC ELSE 40.30 !JAC SWPDIR = MOD(ISWP+3,4)+1 40.30 !JAC END IF 40.30 ! Initialize LLOCK in parallel 40.31 ! Make .FALSE. at grid points where depth is negative 40.31 !$ DO IY = I1MYC,I2MYC 40.31 !$ DO IX = 1, MXC 40.31 !$ IF (COMPDA(KGRPNT(IX,IY),JDP2).GE.DEPMIN) THEN 40.31 !$ LLOCK(IX,IY) = .TRUE. 40.31 !$ ELSE 40.31 !$ LLOCK(IX,IY) = .FALSE. 40.31 !$ ENDIF 40.31 !$ ENDDO 40.31 !$ ENDDO 40.31 !---------------------------------------------------------------------- 40.31 ! Synchronize threads before setting LLOCK for boundary. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP BARRIER 40.31 !---------------------------------------------------------------------- 40.31 ! Begin master thread region. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP MASTER 40.31 ! make LLOCK False for points on boundary 40.22 IF (SWPDIR.EQ.1) THEN KSX = -1 KSY = -1 DDX = +DX DDY = +DY IF (KREPTX.EQ.0) THEN IX1 = 2 IF (.NOT.LMXF) IX1 = IX1-1+IHALOX 40.41 40.31 !$ LLOCK(IX1-1,:) = .FALSE. 40.31 40.22 ELSE IX1 = 1 ENDIF IX2 = MXC IY1 = 2 IY2 = MYC IF (.NOT.LMXL) IX2 = IX2-IHALOX 40.41 40.31 IF (.NOT.LMYF) IY1 = IY1-1+IHALOY 40.41 40.31 IF (.NOT.LMYL) IY2 = IY2-IHALOY 40.41 40.31 !$ LLOCK(:,IY1-1) = .FALSE. 40.31 40.22 ELSE IF (SWPDIR.EQ.2) THEN KSX = +1 KSY = -1 DDX = -DX DDY = +DY IF (KREPTX.EQ.0) THEN IX1 = MXC-1 IF (.NOT.LMXL) IX1 = IX1+1-IHALOX 40.41 40.31 !$ LLOCK(IX1+1,:) = .FALSE. 40.31 40.22 ELSE IX1 = MXC ENDIF IX2 = 1 IY1 = 2 IY2 = MYC IF (.NOT.LMXF) IX2 = IX2+IHALOX 40.41 40.31 IF (.NOT.LMYF) IY1 = IY1-1+IHALOY 40.41 40.31 IF (.NOT.LMYL) IY2 = IY2-IHALOY 40.41 40.31 !$ LLOCK(:,IY1-1) = .FALSE. 40.31 40.22 ELSE IF (SWPDIR.EQ.3) THEN KSX = +1 KSY = +1 DDX = -DX DDY = -DY IF (KREPTX.EQ.0) THEN IX1 = MXC-1 IF (.NOT.LMXL) IX1 = IX1+1-IHALOX 40.41 40.31 !$ LLOCK(IX1+1,:) = .FALSE. 40.31 40.22 ELSE IX1 = MXC ENDIF IX2 = 1 IY1 = MYC-1 IY2 = 1 IF (.NOT.LMXF) IX2 = IX2+IHALOX 40.41 40.31 IF (.NOT.LMYL) IY1 = IY1+1-IHALOY 40.41 40.31 IF (.NOT.LMYF) IY2 = IY2+IHALOY 40.41 40.31 !$ LLOCK(:,IY1+1) = .FALSE. 40.31 40.22 ELSE IF (SWPDIR.EQ.4) THEN KSX = -1 KSY = +1 DDX = +DX DDY = -DY IF (KREPTX.EQ.0) THEN IX1 = 2 IF (.NOT.LMXF) IX1 = IX1-1+IHALOX 40.41 40.31 !$ LLOCK(IX1-1,:) = .FALSE. 40.31 40.22 ELSE IX1 = 1 ENDIF IX2 = MXC IY1 = MYC-1 IY2 = 1 IF (.NOT.LMXL) IX2 = IX2-IHALOX 40.41 40.31 IF (.NOT.LMYL) IY1 = IY1+1-IHALOY 40.41 40.31 IF (.NOT.LMYF) IY2 = IY2+IHALOY 40.41 40.31 !$ LLOCK(:,IY1+1) = .FALSE. 40.31 40.22 ENDIF ! IYSTEP = KSY ! ! *** change values of variables for one-dimensional run *** 32.02 ! IF ( ONED ) THEN 32.02 IY1 = 1 32.02 IY2 = 1 32.02 KSY = 0 32.02 IYSTEP = 1 ENDIF 32.02 ! IF (SCREEN.NE.PRINTF) THEN IF (NSTATC.EQ.1) THEN 40.00 IF (IAMMASTER) WRITE(SCREEN,313) CHTIME, IT, 40.95 40.30 & ITER, SWPDIR 40.30 313 FORMAT ('+time ', A18, ', step ',I6, '; iteration ' & ,I4, '; sweep ',I1) 40.23 40.00 ELSE WRITE(PRINTF,314) ITER, SWPDIR IF (IAMMASTER) THEN 40.95 40.30 IF (SWPDIR.EQ.1) THEN 40.30 WRITE(SCREEN,314) ITER, SWPDIR 40.30 ELSE 40.30 WRITE(SCREEN,315) ITER, SWPDIR 40.30 END IF 40.30 END IF 40.30 314 FORMAT (' iteration ', I4, '; sweep ', I1) 40.23 30.50 315 FORMAT ('+iteration ', I4, '; sweep ', I1) 40.23 30.50 ENDIF ENDIF ! !---------------------------------------------------------------------- 40.31 ! End master thread region and synchronize threads 40.31 !---------------------------------------------------------------------- 40.31 !$OMP END MASTER 40.31 !$OMP BARRIER 40.31 !$OMP FLUSH 40.31 ! !WFR! ====================================================================== 40.30 !WFR! 40.30 !WFR! Set up start and end indices for respectively 40.30 !WFR! IX- and IY-loops appropriated for block 40.30 !WFR! wavefront approach within distributed-memory 40.30 !WFR! environment 40.30 !WFR! 40.30 !WFR! ====================================================================== 40.30 !WFR !WFR IF ( MXCGL.GT.MYCGL .OR. .NOT.PARLL ) THEN 40.30 !WFR JS = IY1 40.30 !WFR JE = IY2 40.30 !WFR INCJ = -IYSTEP 40.30 !WFR IS = IX1 40.30 !WFR IE = IX2 40.30 !WFR INCI = -KSX 40.30 !WFR IF (SWPDIR.EQ.1) THEN 40.30 !WFR JSD = JE - 1 40.30 !WFR JED = JS - 1 40.30 !WFR JNODE = INODE 40.30 !WFR JWFRS = 0 40.30 !WFR JWFRE = NPROC-1 40.30 !WFR ELSE IF (SWPDIR.EQ.2) THEN 40.30 !WFR JSD = JE - 1 40.30 !WFR JED = JS - 1 40.30 !WFR JNODE = NPROC+1-INODE 40.30 !WFR JWFRS = 0 40.30 !WFR JWFRE = NPROC-1 40.30 !WFR ELSE IF (SWPDIR.EQ.3) THEN 40.30 !WFR JSD = JS - 1 40.30 !WFR JED = JE - 1 40.30 !WFR JNODE = NPROC+1-INODE 40.30 !WFR JWFRS = NPROC-1 40.30 !WFR JWFRE = 0 40.30 !WFR ELSE IF (SWPDIR.EQ.4) THEN 40.30 !WFR JSD = JS - 1 40.30 !WFR JED = JE - 1 40.30 !WFR JNODE = INODE 40.30 !WFR JWFRS = NPROC-1 40.30 !WFR JWFRE = 0 40.30 !WFR END IF 40.30 !WFR ELSE 40.30 !WFR JS = IX1 40.30 !WFR JE = IX2 40.30 !WFR INCJ = -KSX 40.30 !WFR IS = IY1 40.30 !WFR IE = IY2 40.30 !WFR INCI = -IYSTEP 40.30 !WFR IF (SWPDIR.EQ.1) THEN 40.30 !WFR JSD = JE - 1 40.30 !WFR JED = JS - 1 40.30 !WFR JNODE = INODE 40.30 !WFR JWFRS = 0 40.30 !WFR JWFRE = NPROC-1 40.30 !WFR ELSE IF (SWPDIR.EQ.2) THEN 40.30 !WFR JSD = JS - 1 40.30 !WFR JED = JE - 1 40.30 !WFR JNODE = INODE 40.30 !WFR JWFRS = NPROC-1 40.30 !WFR JWFRE = 0 40.30 !WFR ELSE IF (SWPDIR.EQ.3) THEN 40.30 !WFR JSD = JS - 1 40.30 !WFR JED = JE - 1 40.30 !WFR JNODE = NPROC+1-INODE 40.30 !WFR JWFRS = NPROC-1 40.30 !WFR JWFRE = 0 40.30 !WFR ELSE IF (SWPDIR.EQ.4) THEN 40.30 !WFR JSD = JE - 1 40.30 !WFR JED = JS - 1 40.30 !WFR JNODE = NPROC+1-INODE 40.30 !WFR JWFRS = 0 40.30 !WFR JWFRE = NPROC-1 40.30 !WFR END IF 40.30 !WFR END IF 40.30 !---------------------------------------------------------------------- 40.22 ! Execute loop over rows of spatial grid in a 40.22 ! pipelined parallel manner within OpenMP environment 40.22 !---------------------------------------------------------------------- 40.22 !$OMP DO SCHEDULE(STATIC,1) 40.22 !$OMP+FIRSTPRIVATE(WWINT) 40.31 40.22 !$OMP+LASTPRIVATE(WWINT) 40.31 40.22 !JAC DO 400 IY = IY1, IY2, -IYSTEP 32.02 !JAC DO 390 IX = IX1, IX2, -KSX !WFR! ====================================================================== 40.30 !WFR! 40.30 !WFR! Within distributed-memory environment, current 40.30 !WFR! sweep is carry out in a block wavefront manner 40.30 !WFR! 40.30 !WFR! ====================================================================== 40.30 !WFR !WFR DO 400 JDUM = JS+JWFRS, JE+JWFRE, INCJ 40.30 !WFR !WFR JJ = JDUM-JNODE+1 40.30 !WFR IF (JNODE.GE.JDUM-JSD .AND. JNODE.LE.JDUM-JED) THEN 40.30 !WFR !WFR!MPI! ====================================================================== 40.30 !WFR!MPI! 40.30 !WFR!MPI! Receive action density from previous updated 40.30 !WFR!MPI! row within distributed-memory environment 40.30 !WFR!MPI! 40.30 !WFR!MPI! ====================================================================== 40.30 !WFR!MPI !WFR!TIMG!MPI CALL SWTSTA(213) 40.30 !WFR!MPI IF ( MXCGL.GT.MYCGL ) THEN 40.30 !WFR!MPI DO III = LSTCP, 1, -1 40.31 !WFR!MPI CALL SWRECVAC(AC2,IS-III*INCI,JJ,SWPDIR,KGRPNT) 40.31 !WFR!MPI END DO 40.31 !WFR!MPI ELSE 40.30 !WFR!MPI DO III = LSTCP, 1, -1 40.31 !WFR!MPI CALL SWRECVAC(AC2,JJ,IS-III*INCI,SWPDIR,KGRPNT) 40.31 !WFR!MPI END DO 40.31 !WFR!MPI END IF 40.30 !WFR!TIMG!MPI CALL SWTSTO(213) 40.30 !WFR!MPI IF (STPNOW()) RETURN 40.30 !WFR !WFR DO 390 II = IS, IE, INCI 40.30 !WFR IF ( MXCGL.GT.MYCGL .OR. .NOT.PARLL ) THEN 40.30 !WFR IX = II 40.30 !WFR IY = JJ 40.30 !WFR ELSE 40.30 !WFR IX = JJ 40.30 !WFR IY = II 40.30 !WFR END IF 40.30 !---------------------------------------------------------------------- 40.22 ! The next while loop will guarantee execution within 40.22 ! OpenMP environment will not proceed until the data 40.22 ! dependencies for grid point (IX,IY) are satisfied. 40.22 ! Since we parallelize only in the y-direction, we only 40.31 ! need to check data dependencies in the y-direction. 40.31 ! The flush is required to ensure each thread has a 40.22 ! consistent view of LLOCK. 40.22 !---------------------------------------------------------------------- 40.22 !$ IF ( .NOT.ONED ) THEN 40.31 !$ DO WHILE(LLOCK(IX,IY+IYSTEP)) 40.31 !$OMP FLUSH (LLOCK) 40.31 !$ END DO 40.31 !$OMP FLUSH 40.31 !$ END IF 40.31 !TIMG CALL SWTSTA(104) 40.23 CALL SWOMPU (SWPDIR,KSX ,KSY , & IX ,IY ,DDX , & DDY ,DT ,SNLC1 , & DAL1 ,DAL2 ,DAL3 , & XIS ,SWTSDA ,INOCNT , 40.31 & AC2 ,COMPDA ,SPCDIR , & SPCSIG ,XYTST ,ITER , 30.72 & CGO , 40.41 40.22 & CAX ,CAY ,CAS , 40.22 & CAD ,SWMATR ,LSWMAT , 40.22 & KWAVE ,DMW , 40.59 40.22 & ALIMW ,GROWW , 40.17 40.22 & UE ,SA1 ,SA2 , 40.22 & DA1C ,DA1P ,DA1M , 40.22 & DA2C ,DA2P ,DA2M , 40.22 & SFNL ,DSNL ,MEMNL4 , 40.22 & IDCMIN ,IDCMAX , 40.41 40.22 & WWINT ,WWAWG ,WWSWG , 40.22 & ISCMIN ,ISCMAX , 40.41 40.22 & ANYWND ,AC1 ,IT , 40.22 & XCGRID ,YCGRID , 40.41 30.72 & KGRPNT ,CROSS , 300597 & OBREDF ,REFLSO , 40.41 40.22 & ISLMIN ,NFLIM ,NRSCAL , 40.23 & MEMSINA ,MEMSINB , 40.88 & CAX1 ,CAY1 40.22 & ) !TIMG CALL SWTSTO(104) 40.23 !MPI IF (STPNOW()) RETURN 34.01 !---------------------------------------------------------------------- 40.22 ! Once the computation is done for grid point (IX,IY) the 40.22 ! thread signals that the data is available by changing 40.22 ! LLOCK(IX,IY). 40.22 !---------------------------------------------------------------------- 40.22 !$OMP FLUSH 40.31 !$ LLOCK(IX,IY) = .FALSE. 40.31 40.22 !$OMP FLUSH (LLOCK) 40.31 390 CONTINUE !WFR!MPI! ====================================================================== 40.30 !WFR!MPI! 40.30 !WFR!MPI! Send action density to next row 40.30 !WFR!MPI! within distributed-memory environment 40.30 !WFR!MPI! 40.30 !WFR!MPI! ====================================================================== 40.30 !WFR!MPI !WFR!TIMG!MPI CALL SWTSTA(213) 40.30 !WFR!MPI IF ( MXCGL.GT.MYCGL ) THEN 40.30 !WFR!MPI DO III = LSTCP-1, 0, -1 40.31 !WFR!MPI CALL SWSENDAC(AC2,IE-III*INCI,JJ,SWPDIR,KGRPNT) 40.31 !WFR!MPI END DO 40.31 !WFR!MPI ELSE 40.30 !WFR!MPI DO III = LSTCP-1, 0, -1 40.31 !WFR!MPI CALL SWSENDAC(AC2,JJ,IE-III*INCI,SWPDIR,KGRPNT) 40.31 !WFR!MPI END DO 40.31 !WFR!MPI END IF 40.30 !WFR!TIMG!MPI CALL SWTSTO(213) 40.30 !WFR!MPI IF (STPNOW()) RETURN 40.30 !WFR END IF 40.30 !WFR 400 CONTINUE !$OMP ENDDO NOWAIT 40.22 !JAC !JAC! ====================================================================== 40.30 !JAC! 40.30 !JAC! Exchange action densities at subdomain interfaces 40.30 !JAC! within distributed-memory environment 40.30 !JAC! 40.30 !JAC! ====================================================================== 40.30 !JAC !JAC IF ( ISWP.EQ.3 ) THEN 40.30 !JAC!TIMG CALL SWTSTA(213) 40.30 !JAC DO ID = 1, MDC 40.30 !JAC DO IS = 1, MSC 40.30 !JAC AC2LOC(:) = AC2(ID,IS,:) 40.30 !JAC CALL SWEXCHG( AC2LOC, 0, KGRPNT ) 40.30 !JAC!MPI IF (STPNOW()) RETURN 40.30 !JAC AC2(ID,IS,:) = AC2LOC(:) 40.30 !JAC END DO 40.30 !JAC END DO 40.30 !JAC CALL SWSYNC 40.30 !JAC!MPI IF (STPNOW()) RETURN 40.30 !JAC!TIMG CALL SWTSTO(213) 40.30 !JAC END IF 40.30 !---------------------------------------------------------------------- 40.22 ! Synchronize threads before checking stop condition and 40.22 ! before starting next sweep direction. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP BARRIER 40.22 410 CONTINUE !WFR!MPI! !WFR!MPI! --- exchange action densities at subdomain interfaces 40.31 !WFR!MPI! within distributed-memory environment if S&L scheme 40.31 !WFR!MPI! is employed because of one downwind point present 40.31 !WFR!MPI! !WFR!MPI IF (PROPSC.EQ.3) THEN 40.31 !WFR!TIMG!MPI CALL SWTSTA(213) 40.31 !WFR!MPI DO ID = 1, MDC 40.31 !WFR!MPI DO IS = 1, MSC 40.31 !WFR!MPI AC2LOC(:) = AC2(ID,IS,:) 40.31 !WFR!MPI CALL SWEXCHG( AC2LOC, KGRPNT ) 40.31 !WFR!MPI AC2(ID,IS,:) = AC2LOC(:) 40.31 !WFR!MPI END DO 40.31 !WFR!MPI END DO 40.31 !WFR!TIMG!MPI CALL SWTSTO(213) 40.31 !WFR!MPI IF (STPNOW()) RETURN 40.31 !WFR!MPI END IF 40.31 !---------------------------------------------------------------------- 40.31 ! Each thread sum contributions to the global INOCNV counter 40.31 ! which counts the number of grid points over the four sweeps 40.31 ! in which the SIP solver did not converge. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP ATOMIC 40.31 INOCNV = INOCNV + INOCNT 40.31 !---------------------------------------------------------------------- 40.31 ! Synchronize threads before master thread stores source terms 40.31 ! and computes wave induced setup. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP BARRIER 40.31 !---------------------------------------------------------------------- 40.22 ! Begin master thread region. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP MASTER 40.22 ! IF ( ITEST.GE.30 .OR. IDEBUG.EQ.1 ) THEN 40.23 NWETP = 0 40.23 DO 109 IP = 2, MCGRD 40.23 IF (COMPDA(IP,JDP2).GT.DEPMIN) NWETP = NWETP + 1 40.23 109 CONTINUE 40.23 ! 40.23 MXNFL = MAXVAL(NFLIM) 40.23 NPFL = COUNT(MASK=NFLIM>0) 40.23 ! 40.23 MNISL = MINVAL(ISLMIN) 40.23 ! 40.23 MXNFR = MAXVAL(NRSCAL) 40.23 NPFR = COUNT(MASK=NRSCAL>0) 40.23 ! 40.23 !MPI! ====================================================================== 40.30 !MPI! 40.30 !MPI! Gather data meant for global reductions in arrays 40.30 !MPI! IARR and ARR within distributed-memory environment 40.30 !MPI! 40.30 !MPI! ====================================================================== 40.30 !MPI! 40.30 !MPI IARR(1) = NWETP 40.30 !MPI IARR(2) = NPFL 40.30 !MPI IARR(3) = NPFR 40.30 !MPI IARR(4) = INOCNV 40.30 !MPI! 40.30 !MPI ARR(1) = REAL(MXNFL) 40.30 !MPI ARR(2) = REAL(MXNFR) 40.30 !MPI! 40.30 !MPI! --- carry out reductions across all nodes 40.30 !MPI! 40.30 !MPI CALL SWREDUCE( ARR, 4, SWREAL, SWMAX ) 40.30 !MPI IF (STPNOW()) RETURN 40.30 !MPI CALL SWREDUCE( IARR, 4, SWINT , SWSUM ) 40.30 !MPI IF (STPNOW()) RETURN 40.30 !MPI CALL SWREDUCE( MNISL, 1, SWINT , SWMIN ) 40.30 !MPI IF (STPNOW()) RETURN 40.30 !MPI! 40.30 !MPI NWETP = IARR(1) 40.30 !MPI NPFL = IARR(2) 40.30 !MPI NPFR = IARR(3) 40.30 !MPI INOCNV = IARR(4) 40.30 !MPI! 40.30 !MPI MXNFL = NINT(ARR(1)) 40.30 !MPI MXNFR = NINT(ARR(2)) 40.30 !MPI! 40.30 FRAC = REAL(NPFL)*100./REAL(NWETP) 40.23 IF(NPFL.GT.0) WRITE(PRINTF,110) 'limiter',FRAC,MXNFL 40.23 IF (NSTATC.EQ.0 .AND. NPFL.GT.0 .AND. IAMMASTER) 40.95 40.23 & WRITE(SCREEN,110) 'limiter',FRAC,MXNFL 40.23 ! 40.23 IF (NPFL.GT.0) WRITE(PRINTF,111) SPCSIG(MNISL)/PI2 40.23 IF (NSTATC.EQ.0 .AND. NPFL.GT.0 .AND. IAMMASTER) 40.95 40.23 & WRITE(SCREEN,111) SPCSIG(MNISL)/PI2 40.23 ! 40.23 FRAC = REAL(NPFR)*100./REAL(NWETP) 40.23 IF(NPFR.GT.0) WRITE(PRINTF,110) 'rescaling',FRAC,MXNFR 40.23 IF (NSTATC.EQ.0 .AND. NPFR.GT.0 .AND. IAMMASTER) 40.95 40.23 & WRITE(SCREEN,110) 'rescaling',FRAC,MXNFR 40.23 ! 40.23 110 FORMAT(1X,'use of ',A9,' in ',F6.2, 40.23 & ' % of wet points with maximum in spectral space = ', 40.23 & I4) 40.23 111 FORMAT(1X, 40.23 & 'lowest frequency occured above which limiter is applied = ', 40.23 & F7.4,' Hz') 40.23 END IF 40.23 ! ! *** store the source terms for test gridpoints *** ! *** in the files IFPAR, IFS1D and IFS2D *** ! !TIMG CALL SWTSTA(105) 40.23 IF (NPTST.GT.0 .AND. NSTATM.EQ.0 40.00 & ) THEN IF (IFPAR.GT.0) WRITE (IFPAR, 12) ITER 40.00 IF (IFS1D.GT.0) WRITE (IFS1D, 12) ITER 40.00 IF (IFS2D.GT.0) WRITE (IFS2D, 12) ITER 40.00 12 FORMAT (I4, T41, 'iteration') CALL PLTSRC (SWTSDA(1,1,1,JPWNDS) ,SWTSDA(1,1,1,JPWNDD) , & SWTSDA(1,1,1,JPWCAP) ,SWTSDA(1,1,1,JPBTFR) , & SWTSDA(1,1,1,JPWBRK) ,SWTSDA(1,1,1,JP4S) , & SWTSDA(1,1,1,JP4D) ,SWTSDA(1,1,1,JPTRI) , & SWTSDA(1,1,1,JPVEGT) ,SWTSDA(1,1,1,JPTURB) , 40.35 40.55 & SWTSDA(1,1,1,JPMUD) ,SWTSDA(1,1,1,JPICE) , 41.75 40.59 & SWTSDA(1,1,1,JPSWEL) , 40.88 & AC2 ,SPCSIG , 40.00 & COMPDA(1,JDP2) ,XYTST , & KGRPNT ) 40.00 END IF !TIMG CALL SWTSTO(105) 40.23 ! ! *** compute wave-induced setup *** 32.02 ! !TIMG CALL SWTSTA(106) 40.23 IF (LSETUP.GT.0) 31.03 & CALL SETUPP ( KGRPNT, MSTPDA, SETPDA, AC2, COMPDA(1,JDP2), 40.41 & COMPDA(1,JDPSAV), COMPDA(1,JSETUP), 40.41 & XCGRID, YCGRID, SPCSIG, SPCDIR ) 40.41 !TIMG CALL SWTSTO(106) 40.23 ! !---------------------------------------------------------------------- 40.31 ! End master thread region. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP END MASTER 40.31 ! ! *** check if numerical accuracy has been reached *** ! *** this is done in parallel within OpenMP environment *** 40.31 ! !TIMG CALL SWTSTA(102) 40.23 IF (PNUMS(21).EQ.0.) THEN 40.41 CALL SACCUR (COMPDA(1,JDP2),KGRPNT , 40.30 & XYTST , 40.41 & AC2 ,SPCSIG ,ACCUR , 30.72 & HSAC1 ,HSAC2 ,SACC1 , 30.90 40.22 & SACC2 ,COMPDA(1,JDHS) ,COMPDA(1,JDTM) , 40.31 30.90 40.22 & I1MYC ,I2MYC ) 40.31 ELSE IF (PNUMS(21).EQ.1.) THEN 40.41 CALL SWSTPC ( HSAC0 ,HSAC1 ,HSAC2 , 40.41 & SACC0 ,SACC1 ,SACC2 , 40.93 40.41 & HSDIFC ,TMDIFC , 40.93 40.41 & COMPDA(1,JDHS),COMPDA(1,JDTM) , 40.41 & COMPDA(1,JDP2),ACCUR , 40.41 & I1MYC ,I2MYC ) 40.93 END IF 40.41 !TIMG CALL SWTSTO(102) 40.23 ! !---------------------------------------------------------------------- 40.31 ! Begin master thread region. 40.31 !---------------------------------------------------------------------- 40.31 !$OMP MASTER 40.31 ! ! *** info regarding the iteration process and the accuracy *** ! IF (PNUMS(21).EQ.1. .AND. ITER.EQ.1) THEN 40.41 WRITE(PRINTF,113) 40.41 IF (NSTATC.EQ.0.AND.IAMMASTER) WRITE(SCREEN,113) 40.95 40.41 ELSE 40.41 WRITE(PRINTF,112) ACCUR,PNUMS(4) 30.72 IF (NSTATC.EQ.0.AND.IAMMASTER) 40.95 40.30 & WRITE(SCREEN,112) ACCUR,PNUMS(4) 40.30 40.00 END IF 40.41 112 FORMAT(' accuracy OK in ',F6.2, & ' % of wet grid points (',F6.2,' % required)',/ ) 113 FORMAT(' not possible to compute, first iteration',/) 40.41 ! ! *** number of points in which the penta-diagonal solver *** ! *** did not converged *** ! IF ( ITEST.GE.30 .OR. IDEBUG.EQ.1 ) THEN IF ((DYNDEP .OR. ICUR.EQ.1) .AND. INOCNV .NE. 0) THEN 40.31 40.23 WRITE(PRINTF,122) INOCNV 40.23 END IF END IF 122 FORMAT(2X,'SIP solver: no convergence in ',I4,' gridpoints') 40.23 ! !---------------------------------------------------------------------- 40.22 ! End master thread region. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP END MASTER 40.22 ! !MPI! --- exchange COMPDA at subdomain interfaces !MPI! within distributed-memory environment !MPI! !TIMG!MPI CALL SWTSTA(213) !MPI DO J = 1, MCMVAR !WFR!MPI CALL SWEXCHG( COMPDA(1,J), KGRPNT ) !JAC!MPI CALL SWEXCHG( COMPDA(1,J), 0, KGRPNT ) !MPI ENDDO !TIMG!MPI CALL SWTSTO(213) !MPI IF (STPNOW()) RETURN ! !---------------------------------------------------------------------- 40.22 ! Synchronize threads before checking accuracy and before 40.22 ! starting next iteration. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP BARRIER 40.22 ! ! *** if accuracy has been reached then the iteration *** ! *** can be terminated ---> goto 470 *** ! IF ( (ITER.NE.1 .OR. PNUMS(21).EQ.0.) .AND. 40.41 & ACCUR.GE.PNUMS(4) ) GOTO 470 40.41 ! 450 CONTINUE 30.00 470 CONTINUE !TIMG CALL SWTSTO(103) 40.23 !---------------------------------------------------------------------- 40.22 ! Begin deallocate private arrays. 40.22 !---------------------------------------------------------------------- 40.22 !TIMG CALL SWTSTA(101) 40.23 DEALLOCATE(IDCMIN) 40.22 DEALLOCATE(IDCMAX) 40.22 DEALLOCATE(ISCMIN) 40.22 DEALLOCATE(ISCMAX) 40.22 DEALLOCATE(CGO) 40.22 DEALLOCATE(KWAVE) 40.22 DEALLOCATE(DMW) 40.59 DEALLOCATE(CAX) 40.22 DEALLOCATE(CAY) 40.22 DEALLOCATE(CAS) 40.22 DEALLOCATE(CAD) 40.22 DEALLOCATE(CAX1) 40.22 DEALLOCATE(CAY1) 40.22 DEALLOCATE(ALIMW) 40.22 DEALLOCATE(UE) 40.22 DEALLOCATE(SA1) 40.22 DEALLOCATE(SA2) 40.22 DEALLOCATE(SFNL) 40.22 DEALLOCATE(DA1C) 40.22 DEALLOCATE(DA1P) 40.22 DEALLOCATE(DA1M) 40.22 DEALLOCATE(DA2C) 40.22 DEALLOCATE(DA2P) 40.22 DEALLOCATE(DA2M) 40.22 DEALLOCATE(DSNL) 40.22 DEALLOCATE(OBREDF) 40.22 DEALLOCATE(REFLSO) 40.41 DEALLOCATE(GROWW) 40.22 DEALLOCATE(ANYWND) 40.22 DEALLOCATE(SWMATR) 40.22 DEALLOCATE(LSWMAT) 40.22 !TIMG CALL SWTSTO(101) 40.23 !---------------------------------------------------------------------- 40.22 ! End deallocate private arrays. 40.22 !---------------------------------------------------------------------- 40.22 !---------------------------------------------------------------------- 40.22 ! End parallel region. 40.22 !---------------------------------------------------------------------- 40.22 !$OMP END PARALLEL 40.22 ! ! Print message when the solver did not converge in setup calculation ! IF (.NOT.CSETUP) THEN 30.82 WRITE(PRINTF,124) 30.82 IF (SCREEN.NE.PRINTF.AND.NSTATC.EQ.0.AND.IAMMASTER) 40.95 40.30 40.13 & WRITE(SCREEN,124) 30.82 END IF 30.82 124 FORMAT(1X,'no convergence in set-up calculation') 30.82 ! !TIMG CALL SWTSTA(105) 40.23 IF (NPTST.GT.0 .AND. NSTATM.EQ.1 40.00 & ) THEN IF (IFPAR.GT.0) WRITE (IFPAR, 11) CHTIME 40.00 IF (IFS1D.GT.0) WRITE (IFS1D, 11) CHTIME 40.00 IF (IFS2D.GT.0) WRITE (IFS2D, 11) CHTIME 40.00 11 FORMAT (A, T41, 'date-time') CALL PLTSRC (SWTSDA(1,1,1,JPWNDS) ,SWTSDA(1,1,1,JPWNDD) , & SWTSDA(1,1,1,JPWCAP) ,SWTSDA(1,1,1,JPBTFR) , & SWTSDA(1,1,1,JPWBRK) ,SWTSDA(1,1,1,JP4S) , & SWTSDA(1,1,1,JP4D) ,SWTSDA(1,1,1,JPTRI) , & SWTSDA(1,1,1,JPVEGT) ,SWTSDA(1,1,1,JPTURB) , 40.35 40.55 & SWTSDA(1,1,1,JPMUD) ,SWTSDA(1,1,1,JPICE) , 41.75 40.59 & SWTSDA(1,1,1,JPSWEL) , 40.88 & AC2 ,SPCSIG , 40.00 & COMPDA(1,JDP2) ,XYTST , & KGRPNT ) 40.00 END IF !TIMG CALL SWTSTO(105) 40.23 !---------------------------------------------------------------------- 40.22 ! Begin deallocate shared arrays. 40.22 !---------------------------------------------------------------------- 40.22 !TIMG CALL SWTSTA(101) 40.23 DEALLOCATE(SETPDA) 40.22 DEALLOCATE(HSAC1) 40.22 DEALLOCATE(HSAC2) 40.22 DEALLOCATE(SACC1) 40.22 DEALLOCATE(SACC2) 40.22 DEALLOCATE(HSAC0) 40.41 DEALLOCATE(HSDIFC) 40.41 DEALLOCATE(SACC0) 40.93 DEALLOCATE(TMDIFC) 40.93 DEALLOCATE(ISLMIN) 40.23 DEALLOCATE(NFLIM) 40.23 DEALLOCATE(NRSCAL) 40.23 DEALLOCATE(MEMNL4) 40.22 DEALLOCATE(MEMSINA) 40.88 DEALLOCATE(MEMSINB) 40.88 !$ DEALLOCATE(LLOCK) 40.22 !MPI DEALLOCATE(AC2LOC) 40.30 DEALLOCATE(SWTSDA) 40.31 !TIMG CALL SWTSTO(101) 40.23 !---------------------------------------------------------------------- 40.22 ! End deallocate shared arrays. 40.22 !---------------------------------------------------------------------- 40.22 ! RETURN END subroutine SWCOMP ! !************************************************************************ ! SUBROUTINE SWOMPU (SWPDIR ,KSX ,KSY , & IX ,IY ,DDX , & DDY ,DT ,SNLC1 , & DAL1 ,DAL2 ,DAL3 , & XIS ,SWTSDA ,INOCNV , & AC2 ,COMPDA ,SPCDIR , & SPCSIG ,XYTST ,ITER , 30.72 & CGO , 40.41 40.22 & CAX ,CAY ,CAS , & CAD ,SWMATR ,LSWMAT , 30.90 & KWAVE ,DMW , 40.59 & ALIMW ,GROWW , 40.17 & UE ,SA1 ,SA2 , & DA1C ,DA1P ,DA1M , & DA2C ,DA2P ,DA2M , & SFNL ,DSNL ,MEMNL4 , & IDCMIN ,IDCMAX , & WWINT ,WWAWG ,WWSWG , & ISCMIN ,ISCMAX , 40.41 & ANYWND ,AC1 ,IT , & XCGRID ,YCGRID , 40.41 30.72 & KGRPNT ,CROSS , 16/MAY & OBREDF ,REFLSO , 40.41 040697 & ISLMIN ,NFLIM ,NRSCAL , 40.23 & MEMSINA ,MEMSINB , 40.88 & CAX1,CAY1 33.08 & ) ! !************************************************************************ USE OCPCOMM1 40.41 USE OCPCOMM2 40.41 USE OCPCOMM3 40.41 USE OCPCOMM4 40.41 USE SWCOMM1 40.41 USE SWCOMM2 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE M_PARALL 40.31 ! IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.70: Nico Booij ! 30.72: IJsbrand Haagsma ! 30.80: Nico Booij ! 30,81: Annette Kieftenburg ! 30.82: IJsbrand Haagsma ! 30.90: IJsbrand Haagsma (Equivalence version) ! 32.02: Roeland Ris & Cor van der Schelde (1D-version) ! 33.08: W. Erick Rogers (some S&L scheme-related changes) ! 33.09: Nico Booij (spherical coord.) ! 33.10: Nico Booij and Erick Rogers (2nd order upwind) ! 34.01: Jeroen Adema ! 40.00: Nico Booij ! 40.02: IJsbrand Haagsma ! 40.03, 40.13: Nico Booij ! 40.08: Erick Rogers ! 40.09: Annette Kieftenburg ! 40.16: IJsbrand Haagsma ! 40.17: IJsbrand Haagsma ! 40.22: John Cazes and Tim Campbell ! 40.23: Marcel Zijlema ! 40.28: Annette Kieftenburg ! 40.30: Marcel Zijlema ! 40.41: Marcel Zijlema ! 40.59: W. Erick Rogers ! 40.61: Roop Lalbeharry ! 41.75: W. Erick Rogers ! ! 1. Updates ! ! 30.72, Nov. 97: Declaration of ISTAT, ITFRE, DDIR, DX, DY, GRAV, ! PI, U10 and WDIC removed because they are ! common and already declared in the INCLUDE file ! 32.02, Jan. 98: Introduced 1D-version ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 30.72, Feb. 98: Modified argument list for update CGSTAB solver ! 30.70, Feb. 98: argument list of WINDP1 changed, current vel. added ! 40.00, July 98: KCGRD removed from Call WINDP1 ! 40.00, Aug. 98: argument OBREDF added in call SPREDT ! subr SWTRCF called to calculate obstacle reduction factors ! 30.90, Oct. 98: Introduced EQUIVALENCE POOL-arrays ! 30.82, Oct. 98: Updated description several variables ! 30.80, Nov. 98: Provision for limitation on Ctheta (refraction) ! 30.81, Jan. 99: Replaced variable STATUS by IERR (because STATUS is a ! reserved word) ! 34.01, Feb. 99: Introducing STPNOW ! 33.08 July 98: some S&L scheme-related changes ! 30.80, Aug. 99: Argument list SPROSD modified ! 40.10, Nov. 99: two arguments in call SWTRCF changed; ! CHS -> COMPDA(1,JHS) and WLEV2 -> COMPDA(1,JWLV2) ! 33.09, Nov. 99: call DSPHER added (ray curvature due to spherical coord.) ! 33.10, Jan. 00: changes re: the SORDUP scheme ! 40.09, May 00: Argument list SWTRCF modified ! 40.03, Jun. 00: new version of SPROSD has new argument list ! Ursell array added to argument list of SDISPA and SOURCE ! readability of test output improved ! 40.10, Sep. 00: Replaced SDISPA with SINTGRL ! 40.02, Sep. 00: Replaced SWMATR(1,1,JABIN) with LSWMAT (logical equivalence) ! 40.13, Mar. 01: if point was dry at previous time level, fall back to BSBT scheme ! order of calling SWAPAR and SPROXY changed, in order ! to get correct values of CGO as input to SPROXY ! 40.22, Sep. 01: Removed WAREA constructs and split SWMATR into 40.22 ! SWMATR(real) and LSWMAT(logical). 40.22 ! 40.22, Sep. 01: Changed array definitions to use the parameter 40.22 ! MICMAX instead of ICMAX. 40.22 ! 40.13, Oct. 01: loop over IC moved to subroutines SWAPAR and SPROXY ! 40.16, Dec. 01: Implementation of limiter switches ! 40.17, Dec. 01: Implementation of Multiple DIA ! 40.28, Dec. 01: Argument list SWTRCF modified 40.28 ! 40.23, Aug. 02: Print of CPU times added ! 40.23, Aug. 02: Introducing arrays NFLIM and NRSCAL ! 40.30, Mar. 03: correcting indices of test point with offsets MXF, MYF ! 40.08, Mar. 03: Dimensioning of RDX, RDX changed to be consistent ! with other subroutines ! 40.41, Aug. 04: code optimization ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! 40.59, Aug. 07: stencil numbering made consistent, so that if used for ! varied purposes (e.g. SPROSD), if-then not required ! 40.61, Nov. 06: Hersbach and Janssen (1999) limiter option added ! 41.75, Jan. 19: adding sea ice ! ! 2. Purpose ! ! This subroutine computes the wave spectrum for one sweep ! direction, and is called four times per iteration. ! ! 3. Method ! ! ! THIS IS THE STENCIL USED WITH THE S&L SCHEME: 33.08 ! 33.08 ! IY+1 o 11 o 4 o 12 33.08 ! | | | 33.08 ! 8 6 | 2 | 1 | 5 33.08 ! IY O----O----O----*----O 33.08 ! | | | 33.08 ! 10 | 3 | 13 33.08 ! IY-1 o----o----o 33.08 ! | 33.08 ! | 33.08 ! IY-2 O 7 33.08 ! | 33.08 ! | 33.08 ! IY-3 O 9 33.08 ! ! ^ ^ ^ ^ ^ ! | | | | | 33.08 ! IX-3 IX-2 IX-1 IX IX+1 ! ! 1: IX , IY 33.10 ! 2: IX-1, IY 33.10 ! 3: IX , IY-1 33.10 ! 4: IX , IY+1 33.10 ! 5: IX+1, IY 33.10 ! 6: IX-2, IY 33.10 ! 7: IX , IY-2 33.10 ! 8: IX-3, IY 33.10 ! 9: IX , IY-3 33.10 ! 10: IX-1, IY-1 33.10 ! 11: IX-1, IY+1 ! 12: IX+1, IY+1 ! 13: IX+1, IY-1 ! ! THIS IS THE STENCIL USED WITH THE *OLD* SORDUP SCHEME: 40.59 ! 33.10 ! 4 2 33.10 ! IY O----O----* 1 33.10 ! | 33.10 ! | 33.10 ! IY-1 O 3 33.10 ! | 33.10 ! | 33.10 ! IY-2 O 5 33.10 ! 33.10 ! ^ ^ ^ 33.10 ! | | | 33.10 ! IX-2 IX-1 IX 33.10 ! 1: IX , IY 33.10 ! 2: IX-1, IY 33.10 ! 3: IX , IY-1 33.10 ! 4: IX-2, IY 33.10 ! 5: IX , IY-2 33.10 ! ! THIS IS THE STENCIL USED WITH THE *NEW* SORDUP SCHEME: 40.59 ! (NUMBERING HAS CHANGED) 40.59 ! 40.59 ! O 4(7) 40.59 ! | 40.59 ! | 40.59 ! 6(4) 2(2) | 1(1) 5(6) 40.59 ! IY O------O------*------O 40.59 ! | 40.59 ! | 40.59 ! | 40.59 ! IY-1 O 3(3) 40.59 ! | 40.59 ! | 40.59 ! | 40.59 ! IY-2 O 7(5) 40.59 ! 40.59 ! ^ ^ ^ 40.59 ! | | | 40.59 ! IX-2 IX-1 IX 40.59 ! 1: IX , IY 40.59 ! 2: IX-1, IY 40.59 ! 3: IX , IY-1 40.59 ! 4: IX , IY+1 7==>4 40.59 ! 5: IX+1, IY 6==>5 40.59 ! 6: IX-2, IY 4==>6 40.59 ! 7: IX , IY-2 5==>7 40.59 ! 40.59 ! AND THE BSBT SCHEME: 40.59 ! 40.59 ! O 4 40.59 ! | 40.59 ! 2 | 1 5 40.59 ! O------*------O 40.59 ! | 40.59 ! | 40.59 ! 3 O 40.59 ! 1: IX , IY 40.59 ! 2: IX-1, IY 40.59 ! 3: IX , IY-1 40.59 ! 4: IX , IY+1 40.59 ! 5: IX+1, IY 40.59 ! ! 4. Argument variables ! ! ITER : input Iteration counter for SWAN ! IT : input Time step counter for SWAN ! INTEGER ITER, IT ! ! i SPCDIR: (*,1); spectral directions (radians) 30.82 ! (*,2); cosine of spectral directions 30.82 ! (*,3); sine of spectral directions 30.82 ! (*,4); cosine^2 of spectral directions 30.82 ! (*,5); cosine*sine of spectral directions 30.82 ! (*,6); sine^2 of spectral directions 30.82 ! i SPCSIG: Relative frequencies in computational domain in sigma-space 30.72 ! i XCGRID: Coordinates of computational grid in x-direction 30.72 ! i YCGRID: Coordinates of computational grid in y-direction 30.72 ! REAL :: SPCDIR(MDC,6) 30.82 REAL :: SPCSIG(MSC) 30.72 REAL :: XCGRID(MXC,MYC), YCGRID(MXC,MYC) 30.72 ! ! Since the real piece of LSWMAT was removed, the dimensions of 40.22 ! LSWMAT are now MLSWMAT not MSWMAT. 40.22 LOGICAL :: LSWMAT(MDC,MSC,MLSWMAT) 30.90 40.22 ! ! 7. Common blocks used ! ! ! 8. Subroutines used ! ! SPREDT ! SWAPAR ! SPROXY ! SINTGRL ! SOURCE ! ACTION ! SOLMAT ! SOLMT1 ! SPROSD ! SWPSEL ! ! 9. Subroutines calling ! ! SWCOMP ! ! 10. Error messages ! ! --- ! ! 11. Remarks ! ! --- ! ! 12. Structure ! ! --------------------------------------------------------- ! Call WINDP2 to compute some wave parameters necessarry for ! the wind subroutines. The wind sea energy spectrum ! is computed before every iteration ! Compute for the two nearby points: ! {to reduce the size of the arrays K, CPX, CPY, CAX, CAY, CAS, CAD ! and CGO, CP use a FUNCTION ICODE(_,_) in were the information ! of the nearby gridpoints is stored. ! The size of the arrays of the wave parameters are reduced significantly, ! par example: CAX(ID,IS,IX,IY) --> CAX(ID,IS,ICMAX) with ICMAX = 3 ! If a higher order scheme is used ICMAX can be increased so that points ! at locations ksx = -2,+2 and ksy = -2,+2 can be used: ! ! o ksy=+2 ! | ! | ! o ksy=+1 with: * = (0,0) ! | ! | ! o------o------*------o------o ! ksx=-2 ksx=-1 | ksx=+1 ksx=+2 ! | ! o ksy=-1 ! | ! | ! o ksy=-2 ! ! Molecule: ! ! (4) 2 ! o------o------* 1 Central grid point : IC = 1 30.70(?), 33.10 ! | Point in X-direction : IC = 2 30.70(?), 33.10 ! | Point in Y-direction : IC = 3 30.70(?), 33.10 ! 3 o Point in X-direction : IC = (4) 30.70(?), 33.10 ! | Point in Y-diretion : IC = (5) 30.70(?), 33.10 ! | 5 gridpoints --> ICC = 5 30.70(?), 33.10 ! (5) o ( ) = is not used by default (BSBT) scheme 30.70(?), 33.10 ! ! Notice that IX and IY are still in the argument list because of ! the counter of DEP2(IX,IY) and UX2(IX,IY) and UY2(IX,IY) ! ! ! For every ICC = 1 to ICMAX do ! If (ICC = 1) then ! IC = ICODE(0,0) {central gridpoint} ! ICX = IX ! ICY = IY ! -------------------------------------------------- ! Else if (ICC = 2) then ! IC = ICODE(KSX,0) {left or right gridpoint} ! ICX = IX+KSX ! ICY = IY ! -------------------------------------------------- ! Else if (ICC = 3 ) then ! IC = ICODE(0,KSY) {top or bottom gridpoint) ! ICX = IX ! ICY = IY+KSY ! -------------------------------------------------- ! End if ! ! ----------------------------------------------------------------- ! For each gridpoint (IC=1,2,3) do: ! Call SWAPAR to compute the wavenumber K and the group velocity CGO ! Call SPROXY to compute propagation velocities CAX, CAY of ! energy propagates ! If central gridpoint (IC=1) do ! Call SWGEOM to compute geometric quantities due to ! curvilinear grid ! Call SWPSEL to compute the bins that fall within a sweep ! and which are propagated within a sweep ! Call SPROSD to calculate the propagation velocities in ! spectral space (CAS and CAD) ! ------------------------------------------------------- ! If depth > 1.e-4 then do ! If wind is present : ! Call WINDP1 to compute the wind speed, PM frequency, mean ! wind direction, wind friction velocity and counters ! ----------------------------------------------------------------- ! Call CNTAIL to compute the contribution of high frequency ! tail to the spectrum ! ----------------------------------------------------------------- ! For the first iteration (ITER = 1), do: ! Call SPREDT to estimate the action density in stationary mode ! ----------------------------------------------------------------- ! Call SINTGRL to compute some wave parameters (mean frequency ! mean wave number, near bottom velocity and signi- ! ficant wave height, fraction of breaking waves ! ----------------------------------------------------------------- ! Call SOURCE to compute the source terms for each bin which fall ! within a sweep: ! 1. Dissipation by wave-bottom effects ! 2. Dissipation due to surf breaking ! 3. Dissipation due to whitecapping ! 4. Generation of wave energy by wind effects ! 5. Nonlinear wave-wave interactions (quadruplets) ! 6. Nonlinear wave-wave interactions (triads) ! 7. Dissipation due to vegetation ! 8. Dissipation due to turbulence ! 9. Fluid mud-induced wave dissipation ! 10. Dissipation by sea ice ! ----------------------------------------------------------------- ! Call ACTION calculate the derivatives in x,y,s,d space and store ! the results in the corresponding arrays ! ----------------------------------------------------------------- ! If a current is present do ! If implicit scheme in frequency space do ! ----- ! Call SWSIP to solve penta-diagonal system by means ! of Stone's SIP solver ! ----- ! endif ! else if no current is present do ! Call SOLMAT to solve tri-diagonal system ! end if ! ------------------------------------------------------------------ ! CALL WINDP3 for a first or second generation model: limit the ! computed action density in a gridpoint according to ! the saturation spectra. ! --------------------------------------------------------- ! End of SWOMPU ! --------------------------------------------------------- ! ! 13. Source text ! INTEGER IC ,IX ,IY ,IS ,SWPDIR, 40.00 & KSX ,KSY , 40.00 & IDWMIN,IDWMAX,IDTOT ,ISTOT ,IDDLOW,IDDTOP, & ISSTOP,INOCNV 40.00 INTEGER LINK(MICMAX) 33.09 ! REAL DDX ,DDY ,DT , 40.00 & ETOT ,AC2TOT,ABRBOT,HM ,HS ,QBLOC , 40.00 & SMESPC,KMESPC,ETOTW ,WIND10,FPM , & THETAW,SNLC1 ,DAL1 ,DAL2 ,DAL3 ,XIS , & UFRIC ,SMEBRK,KTETA ! LOGICAL INSIDE 33.09 LOGICAL LPREDT ! INTEGER :: XYTST(2*NPTST) ,IDCMIN(MSC) 40.22 INTEGER :: IDCMAX(MSC) ,ISCMIN(MDC) ,ISCMAX(MDC) INTEGER :: WWINT(*) INTEGER :: KGRPNT(MXC,MYC) 40.00 INTEGER :: CROSS(2,MCGRD) ! ! *** number of arrays for SWAN *** ! REAL :: AC2(MDC,MSC,MCGRD) 30.21 REAL :: AC1(MDC,MSC,MCGRD) 30.00 REAL :: COMPDA(MCGRD,MCMVAR) ! Changed ICMAX to MICMAX, since MICMAX doesn't vary over gridpoint 40.22 REAL :: CGO(MSC,MICMAX) , 40.22 & CAX(MDC,MSC,MICMAX) , 40.22 & CAY(MDC,MSC,MICMAX) , 40.22 & CAX1(MDC,MSC,MICMAX) , 33.08 40.22 & CAY1(MDC,MSC,MICMAX) , 33.08 40.22 & CAS(MDC,MSC,MICMAX) , 40.22 & CAD(MDC,MSC,MICMAX) 40.22 REAL :: ALIMW(MDC,MSC) ! Since the logical piece of SWMATR was removed, the 40.22 ! dimensions of SWMATR are now MSWMATR not MSWMAT 40.22 REAL :: SWMATR(MDC,MSC,MSWMATR) 40.22 ! Changed ICMAX to MICMAX, since MICMAX doesn't vary over gridpoint 40.22 REAL :: KWAVE(MSC,MICMAX), DMW(MSC,MICMAX) , 40.59 40.17 40.22 & UE(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & SA1(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & SA2(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & DA1C(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & DA1P(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & DA1M(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & DA2C(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & DA2P(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & DA2M(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & SFNL(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & DSNL(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) , & MEMNL4(MDC,MSC,MCGRD) , 30.21 & MEMSINA(MDC,MSC,MCGRD) , 40.88 & MEMSINB(MDC,MSC,MCGRD) , 40.88 & SWTSDA(MDC,MSC,NPTSTA,MTSVAR) , 40.00 & WWAWG(*) , & WWSWG(*) , & RDX(MICMAX) ,RDY(MICMAX) , 15/MAY 40.08 & OBREDF(MDC,MSC,2) , 040697 & REFLSO(MDC,MSC) 40.41 REAL :: URMSTOP(MCGRD) 40.88 ! LOGICAL GROWW(MDC,MSC) , & ANYWND(MDC) ! INTEGER :: ISLMIN(MCGRD), NFLIM(MCGRD), NRSCAL(MCGRD) 40.23 ! INTEGER IENT, NLINK, ILINK, II, INDEX, ID, IDC, ISC, & ID_MIN, ID_MAX, IDDUM ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SWOMPU') ! *** Get grid point numbers for points in computational stencil *** IXCGRD(1) = IX 40.00 IYCGRD(1) = IY 40.00 KCGRD(1) = KGRPNT(IX,IY) 30.21 IF (KCGRD(1).GT.1) THEN 40.00 IXCGRD(2) = IX+KSX 40.00 IYCGRD(2) = IY 40.00 IXCGRD(3) = IX 40.00 IYCGRD(3) = IY+KSY 40.00 IXCGRD(4) = IX 40.59 IYCGRD(4) = IY-KSY 40.59 IXCGRD(5) = IX-KSX 40.59 IYCGRD(5) = IY 40.59 PROPSL = PROPSC 33.09 IF (PROPSC.EQ.1) THEN 33.09 ICMAX = 5 40.59 ELSE ! add more points for higher order schemes 33.10 ICMAX = 7 40.59 33.10 IXCGRD(6) = IX+2*KSX 40.59 33.10 IYCGRD(6) = IY 40.59 33.10 IXCGRD(7) = IX 40.59 33.10 IYCGRD(7) = IY+2*KSY 40.59 33.10 ENDIF IF (PROPSC.EQ.3) THEN ! add more points for S&L scheme ICMAX = 13 33.09 IXCGRD(8) = IX+3*KSX 33.09 IYCGRD(8) = IY 33.09 IXCGRD(9) = IX 33.09 IYCGRD(9) = IY+3*KSY 33.09 IXCGRD(10) = IX+KSX 33.09 IYCGRD(10) = IY+KSY 33.09 IXCGRD(11) = IX+KSX IYCGRD(11) = IY-KSY IXCGRD(12) = IX-KSX IYCGRD(12) = IY-KSY IXCGRD(13) = IX-KSX IYCGRD(13) = IY+KSY ENDIF DO IC = 2, ICMAX 40.00 ! if one of the points of a stencil is outside the computational 33.09 ! domain, fall back to first order scheme 33.09 ! Note that stencil of first order scheme has been increased to 5 40.59 ! Also note that points 4 and 5 are used only for SPROSD. 40.59 ! In cases where user has chosen the first order scheme (PROPSC=1) , and 40.59 ! points 4 and/or 5 fall outside the grid, we do not want to set PROPSL=0. 40.59 ! However, we do want to set INSIDE=FALSE, so that KCGRD(IC) = 1, so that 40.59 ! SPROSD will know that the point is not available. As the code is written 40.59 ! now, no change is required. But also be aware that refraction will no 40.59 ! longer be calculated at the last grid point (i.e. SPROSD is not coded to 40.59 ! fall back to the first order scheme, it just set C_theta=0). 40.59 INSIDE = .TRUE. 33.09 IF (IXCGRD(IC).LT.1) THEN 33.09 IF (KREPTX.GT.0) THEN 33.09 ! domain is repeating in x-direction 33.09 IXCGRD(IC) = IXCGRD(IC) + MXC 33.09 ELSE 33.09 IF (IC.LE.3) THEN 33.09 PROPSL = 0 33.09 ELSE 33.09 IF (PROPSC.GT.1) PROPSL = 1 33.09 ENDIF 33.09 INSIDE = .FALSE. 33.09 ENDIF 33.09 ENDIF 33.09 IF (IXCGRD(IC).GT.MXC) THEN 33.09 IF (KREPTX.GT.0) THEN 33.09 IXCGRD(IC) = IXCGRD(IC) - MXC 33.09 ELSE 33.09 IF (IC.LE.3) THEN 33.09 PROPSL = 0 33.09 ELSE 33.09 IF (PROPSC.GT.1) PROPSL = 1 33.09 ENDIF 33.09 INSIDE = .FALSE. 33.09 ENDIF 33.09 ENDIF 33.09 IF (IYCGRD(IC).LT.1 .OR. IYCGRD(IC).GT.MYC) THEN 33.09 IF (.NOT.ONED) THEN 33.09 IF (IC.LE.3) THEN 33.09 PROPSL = 0 33.09 ELSE 33.09 IF (PROPSC.GT.1) PROPSL = 1 33.09 ENDIF 33.09 ENDIF 33.09 INSIDE = .FALSE. 33.09 ENDIF 33.09 IF (INSIDE) THEN 33.09 KCGRD(IC) = KGRPNT(IXCGRD(IC),IYCGRD(IC)) 40.00 ELSE 33.09 KCGRD(IC) = 1 33.09 ENDIF 33.09 ! if point in stencil is dry, fall back to BSBT scheme. 33.10 IF (PROPSC.GT.1) THEN 33.10 IF (COMPDA(KCGRD(IC),JDP2).LE.DEPMIN) PROPSL = 1 33.10 IF (NSTATC.GT.0) THEN 40.13 ! if nonstationary, check also previous time level 40.13 IF (COMPDA(KCGRD(IC),JDP1).LE.DEPMIN) PROPSL = 1 40.13 ENDIF 40.13 END IF 33.10 ENDDO IF (PROPSL.EQ.0) THEN 33.09 ICMAX = 1 33.09 ELSEIF (PROPSL.EQ.1) THEN 33.09 ICMAX = 5 40.59 33.09 ENDIF 33.09 ELSE PROPSL = 0 40.13 ICMAX = 1 40.13 ENDIF ! ! *** If there are obstacles crossing the points in the stencil *** ! *** then fall back to first order scheme *** ! !TIMG CALL SWTSTA(136) 40.23 IF (NUMOBS.NE.0 .AND. PROPSL.NE.1) THEN IF (PROPSL.EQ.3) THEN NLINK = 10 IF (SWPDIR .EQ. 1 ) THEN LINK(1) = CROSS(1,KCGRD(1)) 33.08 LINK(2) = CROSS(2,KCGRD(1)) LINK(3) = CROSS(1,KCGRD(2)) LINK(4) = CROSS(2,KCGRD(2)) LINK(5) = CROSS(1,KCGRD(3)) LINK(6) = CROSS(2,KCGRD(3)) LINK(7) = CROSS(2,KCGRD(4)) LINK(8) = CROSS(1,KCGRD(5)) LINK(9) = CROSS(1,KCGRD(6)) LINK(10) = CROSS(2,KCGRD(7)) ELSE IF (SWPDIR .EQ. 2) THEN LINK(1) = CROSS(1,KCGRD(2)) 33.08 LINK(2) = CROSS(2,KCGRD(1)) LINK(3) = CROSS(1,KCGRD(6)) LINK(4) = CROSS(2,KCGRD(2)) LINK(5) = CROSS(1,KCGRD(10)) LINK(6) = CROSS(2,KCGRD(3)) LINK(7) = CROSS(2,KCGRD(4)) LINK(8) = CROSS(1,KCGRD(1)) LINK(9) = CROSS(1,KCGRD(8)) LINK(10) = CROSS(2,KCGRD(7)) ELSE IF (SWPDIR .EQ. 3) THEN LINK(1) = CROSS(1,KCGRD(2)) 33.08 LINK(2) = CROSS(2,KCGRD(3)) LINK(3) = CROSS(1,KCGRD(6)) LINK(4) = CROSS(2,KCGRD(10)) LINK(5) = CROSS(1,KCGRD(10)) LINK(6) = CROSS(2,KCGRD(7)) LINK(7) = CROSS(2,KCGRD(1)) LINK(8) = CROSS(1,KCGRD(1)) LINK(9) = CROSS(1,KCGRD(8)) LINK(10) = CROSS(2,KCGRD(9)) ELSE IF (SWPDIR .EQ. 4) THEN LINK(1) = CROSS(1,KCGRD(1)) 33.08 LINK(2) = CROSS(2,KCGRD(3)) LINK(3) = CROSS(1,KCGRD(2)) LINK(4) = CROSS(2,KCGRD(10)) LINK(5) = CROSS(1,KCGRD(3)) LINK(6) = CROSS(2,KCGRD(7)) LINK(7) = CROSS(2,KCGRD(1)) LINK(8) = CROSS(1,KCGRD(5)) LINK(9) = CROSS(1,KCGRD(6)) LINK(10) = CROSS(2,KCGRD(9)) ENDIF ELSE IF (PROPSL.EQ.2) THEN 33.10 NLINK = 4 33.10 IF (SWPDIR .EQ. 1 ) THEN 33.10 LINK(1) = CROSS(1,KCGRD(1)) 33.10 LINK(2) = CROSS(2,KCGRD(1)) 33.10 LINK(3) = CROSS(1,KCGRD(2)) 33.10 LINK(4) = CROSS(2,KCGRD(3)) 33.10 ELSE IF (SWPDIR .EQ. 2) THEN 33.10 LINK(1) = CROSS(1,KCGRD(2)) 33.10 LINK(2) = CROSS(2,KCGRD(1)) 33.10 LINK(3) = CROSS(1,KCGRD(6)) 40.59 33.10 LINK(4) = CROSS(2,KCGRD(3)) 33.10 ELSE IF (SWPDIR .EQ. 3) THEN 33.10 LINK(1) = CROSS(1,KCGRD(2)) 33.10 LINK(2) = CROSS(2,KCGRD(3)) 33.10 LINK(3) = CROSS(1,KCGRD(6)) 40.59 33.10 LINK(4) = CROSS(2,KCGRD(7)) 40.59 33.10 ELSE IF (SWPDIR .EQ. 4) THEN 33.10 LINK(1) = CROSS(1,KCGRD(1)) 33.10 LINK(2) = CROSS(2,KCGRD(3)) 33.10 LINK(3) = CROSS(1,KCGRD(2)) 33.10 LINK(4) = CROSS(2,KCGRD(7)) 40.59 33.10 ENDIF 33.10 ENDIF 33.10 IF (PROPSL.GT.1) THEN 33.10 ! if there is an obstacle crossing, fall back to 1st order 33.10 DO ILINK = 1, NLINK 33.08 IF (LINK(ILINK).GT.0) PROPSL = 1 33.08 ENDDO ENDIF ENDIF !TIMG CALL SWTSTO(136) 40.23 IF (ITEST .GE. 180 ) THEN WRITE(PRINTF,188) SWPDIR 188 FORMAT(' Points in stencil in subr SWOMPU, sweep : ',I1, & /,'POINT( IX, IY), INDEX, COORDX, COORDY') ! DO IC = 1, ICMAX 40.00 IF ( KCGRD(IC).EQ.1 ) CYCLE ! if point is not valid, then cycle WRITE(PRINTF,187) IXCGRD(IC), IYCGRD(IC), KCGRD(IC), 40.00 & XCGRID(IXCGRD(IC),IYCGRD(IC)), YCGRID(IXCGRD(IC),IYCGRD(IC)) 40.00 187 FORMAT(4X,I4,1X,I4,3X,I5,5X,F10.2,4X,F10.2) ENDDO 40.00 ENDIF ! ! *** determine whether the point is a test point *** ! IPTST = 0 TESTFL = .FALSE. IF (NPTST.GT.0) THEN DO 20 II = 1, NPTST IF (IX.NE.XYTST(2*II-1)) GOTO 20 IF (IY.NE.XYTST(2*II )) GOTO 20 ! IPTST = II TESTFL = .TRUE. IF (ITEST .GE. 10) & WRITE(PRINTF, 18) IPTST, IX+MXF-2, IY+MYF-2, KCGRD(1), ITER, 40.30 & SWPDIR 40.30 18 FORMAT(' Test point ', I2, ', (ix,iy)', 2I5, & ', point index ',I5, 30.21 & ', iter ', I2, ', sweep ', I1) 20 CONTINUE ENDIF ! IF (TESTFL .AND. ITEST .GE. 220) THEN 40.00 INDEX = KGRPNT(IX,IY) WRITE(PRINTF,322) IX+MXF-1,IY+MYF-1,INDEX 40.30 322 FORMAT(' Action densities for IX IY IDNX: ', 2I4, I7) 40.00 DO IS = 1, MSC WRITE(PRINTF, 323) IS 323 FORMAT(' frequency ', I4) WRITE(PRINTF, 324) (AC2(ID,IS,INDEX), ID=1, MDC) 40.00 324 FORMAT (100E12.4) ENDDO ENDIF ! IF(TESTFL.AND.ITEST.GE.10) WRITE(PRINTF,2321) SWPDIR,IX+MXF-1, 40.30 & IY+MYF-1 40.30 2321 FORMAT(//,' sweep direction and node IX, IY ',3I4) ! ! --- in case of non-active point set action density in land points ! equal to zero and go back to main program IF (KCGRD(1).LE.1 .OR. COMPDA(KCGRD(1),JDP2).LE.DEPMIN) THEN 40.41 25/MAR DO IS = 1, MSC DO ID = 1, MDC AC2(ID,IS,KCGRD(1)) = 0. 30.21 ENDDO ENDDO COMPDA(KCGRD(1),JHS) = 0. 40.41 RETURN END IF ! IF (KCGRD(2) .LE. 1) RETURN 30.70 IF (.NOT.ONED .AND. (KCGRD(3).LE.1)) RETURN 30.70 ! IF (PROPSL.EQ.3 .AND. NSTATC.GT.0) THEN 33.08 ! calculate propagation velocities for old time level 40.13 ! (needed for S&L scheme nonstationary) 40.13 ! COMPDA(1,JDP2) is dep2 ;change to..dep1 which is COMPDA(1,JDP1) 33.08 ! COMPDA(1,JVX2) is ux2 ;change to..ux1 which is COMPDA(1,JVX1) 33.08 ! COMPDA(1,JVY2) is uy2 ;change to..uy1 which is COMPDA(1,JVY1) 33.08 ! ! we could save CPU time by calculating the CAX values only once 33.08 ! when CAX is constant, but this would require SWAN to 33.08 ! save CAX over the entire grid (more memory). 33.08 ! ! if nonstationary, then CAX1 is not necessarily equal to CAX 33.08 ! also, if we are using the BSBT scheme only, 33.08 ! then CAX1, CAY1 are not needed. 33.08 ! !TIMG CALL SWTSTA(110) 40.23 CALL SWAPAR ( COMPDA(1,JDP1), COMPDA(1,JMUDL1), 40.59 40.41 & KWAVE, CGO, DMW, SPCSIG ) 40.59 40.41 !TIMG CALL SWTSTO(110) 40.23 ! ! *** compute the propagation velocities CAX1 and CAY1 *** ! *** for all directions for the gridpoints IC = 1 to ICMAX *** !TIMG CALL SWTSTA(111) 40.23 CALL SPROXY (CAX1 , & CAY1 ,CGO ,SPCDIR(1,2) , 33.08 & SPCDIR(1,3) ,COMPDA(1,JVX1) ,COMPDA(1,JVY1) , 33.08 & SWPDIR & ) 33.08 !TIMG CALL SWTSTO(111) 40.23 ! END IF 33.08 ! calculate propagation velocities for new time level 40.13 ! *** Compute wavenumber KWAVE and group velocity CGO *** ! *** in the gridpoints of the stencil *** !TIMG CALL SWTSTA(110) 40.23 CALL SWAPAR ( COMPDA(1,JDP2), COMPDA(1,JMUDL2), 40.59 40.41 & KWAVE, CGO, DMW, SPCSIG ) 40.59 40.41 !TIMG CALL SWTSTO(110) 40.23 ! ! *** compute the propagation velocities CAX and CAY *** ! *** for all directions for the gridpoints IC = 1 to ICMAX *** ! !TIMG CALL SWTSTA(111) 40.23 CALL SPROXY (CAX , & CAY ,CGO ,SPCDIR(1,2) , & SPCDIR(1,3) ,COMPDA(1,JVX2) ,COMPDA(1,JVY2) , & SWPDIR & ) !TIMG CALL SWTSTO(111) 40.23 ! ! --- compute geometric quantities due to curvilinear grid 40.41 ! !TIMG CALL SWTSTA(112) CALL SWGEOM ( RDX, RDY, XCGRID, YCGRID, SWPDIR ) 40.41 !TIMG CALL SWTSTO(112) ! ! *** compute minimum and maximum counter (IDCMIN and *** ! *** IDCMAX) and fill the array ANYBIN to determine *** ! *** if a bin lies within the sweep considered *** ! !TIMG CALL SWTSTA(112) 40.23 CALL SWPSEL (SWPDIR ,IDCMIN , & IDCMAX ,CAX , & CAY ,LSWMAT(1,1,JABIN), 40.02 & ISCMIN , 40.00 & ISCMAX ,IDTOT ,ISTOT , & IDDLOW ,IDDTOP ,ISSTOP , & COMPDA(1,JDP2) ,COMPDA(1,JVX2) ,COMPDA(1,JVY2), & SPCDIR ,RDX ,RDY , 40.41 30.72 & KGRPNT 40.13 & ) !TIMG CALL SWTSTO(112) 40.23 ! *** compute the propagation velocities CAS and CAD *** !TIMG CALL SWTSTA(113) 40.23 CALL SPROSD (SPCSIG ,KWAVE ,CAS , 40.03 & CAD ,CGO , 30.80 & COMPDA(1,JDP2) ,COMPDA(1,JDP1) ,SPCDIR(1,2) , & SPCDIR(1,3) ,COMPDA(1,JVX2) ,COMPDA(1,JVY2) , & SPCDIR(1,4) ,SPCDIR(1,6) ,SPCDIR(1,5) , 30.80 & RDX ,RDY , 30.80 & CAX ,CAY , 40.02 & XCGRID ,YCGRID , 40.03 & IDDLOW ,IDDTOP 40.61 & ) !TIMG CALL SWTSTO(113) 40.23 !TIMG CALL SWTSTA(114) 40.23 IF (KSPHER.GT.0 .AND. IREFR.NE.0) THEN 40.41 ! ! *** compute the change of propagation velocity CAD *** ! *** due to the use of spherical coordinates *** ! CALL DSPHER (CAD ,CAX , 40.41 33.09 & CAY , 40.41 & LSWMAT(1,1,JABIN) ,YCGRID , 40.02 & SPCDIR(1,2) ,SPCDIR(1,3) ) 40.41 ENDIF !TIMG CALL SWTSTO(114) 40.23 ! IF ( IDTOT.GT.0 ) THEN 40.41 25/MAR ! ! *** initialize friction velocity and Fpm frequency even *** ! *** when there is no wind input *** ! UFRIC = 1.E-15 FPM = 1.E-15 IF ( IWIND .GE. 1 ) THEN ! ! *** compute the wind speed, mean wind direction, the *** ! *** PM frequency, wind friction velocity U* and the *** ! *** minimum and maximum counters for active wind input *** ! !TIMG CALL SWTSTA(115) 40.23 CALL WINDP1 (WIND10 ,THETAW , & IDWMIN ,IDWMAX , & FPM ,UFRIC , & COMPDA(1,JWX2) ,COMPDA(1,JWY2) , & ANYWND ,SPCDIR , 40.00 & COMPDA(1,JVX2) ,COMPDA(1,JVY2) ,SPCSIG ,AC2 41.33 30.70 & ,SWMATR(1,1,JGEN0), KWAVE 40.88 & ) !TIMG CALL SWTSTO(115) 40.23 IF (IWIND.NE.4) COMPDA(KCGRD(1),JUSTAR) = UFRIC END IF ! ! *** estimate action density in case of first iteration *** ! *** in stationary mode (since it is zero in first *** ! stationary run) *** ! LPREDT=.FALSE. IF (ICOND.NE.4 .AND. ITER.EQ.1 .AND. NSTATC.EQ.0) THEN 40.41 40.00 LPREDT=.TRUE. COMPDA(KCGRD(1),JHS) = 0. GOTO 333 END IF 330 IF (LPREDT) THEN CALL SPREDT (SWPDIR ,AC2 ,CAX , & CAY ,IDCMIN ,IDCMAX , & ISSTOP ,LSWMAT(1,1,JABIN) , 40.02 & XCGRID ,YCGRID , 41.53 & RDX ,RDY ,OBREDF ) 40.00 LPREDT=.FALSE. END IF ! ! Calculate various integral parameters for use in the source terms ! !TIMG CALL SWTSTA(116) 40.23 CALL SINTGRL (SPCDIR ,KWAVE ,AC2 , 40.02 & COMPDA(1,JDP2) ,QBLOC ,COMPDA(1,JURSEL), 40.02 & RDX ,RDY , 40.02 & AC2TOT ,ETOT , 40.02 & ABRBOT ,COMPDA(1,JUBOT) ,HS , 40.02 & COMPDA(1,JQB) , 40.02 & HM ,KMESPC ,SMEBRK ,KTETA , 41.47 40.02 & COMPDA(1,JPBOT) , 40.51 & COMPDA(1,JBOTLV) ,COMPDA(1,JGAMMA) , 41.38 & COMPDA(1,JRESPL) ,SWPDIR , 41.38 40.16 & URMSTOP , 40.88 & IDDLOW ,IDDTOP ) 41.38 !TIMG CALL SWTSTO(116) 40.23 ! COMPDA(KCGRD(1),JHS) = HS 30.70 ! ! *** If there are obstacles crossing the points in the stencil *** ! *** then the transmission and reflection coeff. are computed *** ! *** and also the contribution to the source term *** ! 333 CONTINUE !TIMG CALL SWTSTA(136) 40.23 IF (NUMOBS .NE. 0) THEN ! ! *** OBREDF(:,:,2) are the transmission coeff for the two links *** ! *** in the stencil (between the three point on the stencil) *** ! *** REFLSO(:,:) contains the contribution to the source term *** ! DO IDC = 1, MDC DO ISC = 1, MSC OBREDF(IDC,ISC,1) = 1. 40.00 OBREDF(IDC,ISC,2) = 1. 40.00 REFLSO(IDC,ISC ) = 0. ENDDO ENDDO ! IF (SWPDIR .EQ. 1 ) THEN LINK(1) = CROSS(1,KCGRD(1)) LINK(2) = CROSS(2,KCGRD(1)) ELSE IF (SWPDIR .EQ. 2) THEN LINK(1) = CROSS(1,KCGRD(2)) LINK(2) = CROSS(2,KCGRD(1)) ELSE IF (SWPDIR .EQ. 3) THEN LINK(1) = CROSS(1,KCGRD(2)) LINK(2) = CROSS(2,KCGRD(3)) ELSE IF (SWPDIR .EQ. 4) THEN LINK(1) = CROSS(1,KCGRD(1)) LINK(2) = CROSS(2,KCGRD(3)) ENDIF IF (LINK(1) .NE. 0 .OR. LINK(2) .NE. 0) THEN 40.00 IF (ITEST .GE. 120) WRITE(PRINTF,10) & SWPDIR,KCGRD(1),LINK(1),LINK(2) 10 FORMAT(' SWOMPU: SWPDIR POINT LINK1 LINK2 = ',4(1X,I5)) ! CALL SWTRCF (COMPDA(1,JDP2),COMPDA(1,JWLV2), 41.71 40.31 40.09 & COMPDA(1,JHS), LINK, OBREDF, 40.09 & AC2, REFLSO, KGRPNT, XCGRID, 40.41 40.09 & YCGRID, CAX, CAY, RDX, RDY, LSWMAT(1,1,JABIN), 40.02 & SPCSIG, SPCDIR) 40.13 40.28 ENDIF ! ENDIF !TIMG CALL SWTSTO(136) 40.23 IF (LPREDT) GOTO 330 ! ! *** compute source terms and fill the matrix *** ! !TIMG CALL SWTSTA(117) 40.23 CALL SOURCE (ITER ,IX ,IY , & SWPDIR ,KWAVE ,SPCSIG , 30.72 & SPCDIR(1,2) ,SPCDIR(1,3) ,AC2 , & COMPDA(1,JDP2) ,SWMATR(1,1,JMATD) ,SWMATR(1,1,JMATR) , & ABRBOT ,KMESPC ,SMESPC , & COMPDA(1,JUBOT) ,UFRIC ,COMPDA(1,JVX2) , & COMPDA(1,JVY2) ,IDCMIN ,IDCMAX , & IDDLOW ,IDDTOP ,IDWMIN , & IDWMAX ,ISSTOP ,SWTSDA(1,1,1,JPWNDS), & SWTSDA(1,1,1,JPWNDD),SWTSDA(1,1,1,JPWCAP),SWTSDA(1,1,1,JPBTFR), & SWTSDA(1,1,1,JPSWEL), 40.88 & SWTSDA(1,1,1,JPWBRK),SWTSDA(1,1,1,JP4S) ,SWTSDA(1,1,1,JP4D) , & SWTSDA(1,1,1,JPVEGT),SWTSDA(1,1,1,JPTURB),SWTSDA(1,1,1,JPMUD) , 40.59 40.35 40.55 & SWTSDA(1,1,1,JPICE) , 41.75 & SWTSDA(1,1,1,JPTRI) , HS , 40.22 & ETOT ,QBLOC ,THETAW , & HM ,FPM ,WIND10 , & ETOTW ,GROWW ,ALIMW , & SMEBRK ,KTETA ,SNLC1 , 41.47 & DAL1 ,DAL2 ,DAL3 , & UE ,SA1 , 40.17 & SA2 ,DA1C ,DA1P , & DA1M ,DA2C ,DA2P , & DA2M ,SFNL ,DSNL , & MEMNL4 ,WWINT ,WWAWG , & WWSWG ,CGO ,COMPDA(1,JUSTAR) , & COMPDA(1,JZEL) ,SPCDIR ,ANYWND , & DMW , 40.59 & MEMSINA ,MEMSINB , 40.88 & SWMATR(1,1,JDIS0) ,SWMATR(1,1,JDIS1) , & SWMATR(1,1,JGEN0) ,SWMATR(1,1,JGEN1) , 40.85 & SWMATR(1,1,JRED0) ,SWMATR(1,1,JRED1) , 40.85 & XIS ,COMPDA(1,JFRC2) ,IT , 40.00 & COMPDA(1,JNPLA2) ,COMPDA(1,JTURB2) ,COMPDA(1,JMUDL2) , 40.59 40.35 40.55 & COMPDA(1,JAICE2) ,COMPDA(1,JHICE2) , 41.75 & COMPDA(1,JURSEL) ,LSWMAT(1,1,JABIN) ,REFLSO , 40.41 40.03 & COMPDA(1,JTAUW) & ,URMSTOP 40.88 & ) 30.21 !TIMG CALL SWTSTO(117) 40.23 ! ! *** compute transport of action and fill the matrix *** ! !TIMG CALL SWTSTA(118) 40.23 CALL ACTION (IDCMIN ,IDCMAX ,SPCSIG , 33.09 & AC2 ,CAX ,CAY , & CAS ,CAD ,SWMATR(1,1,JMATL) , & SWMATR(1,1,JMATD) ,SWMATR(1,1,JMATU) ,SWMATR(1,1,JMATR) , & SWMATR(1,1,JMAT5) , 40.22 & SWMATR(1,1,JMAT6) ,ISCMIN ,ISCMAX , & IDDLOW ,IDDTOP ,ISSTOP , & LSWMAT(1,1,JABLK) ,LSWMAT(1,1,JABIN) , 30.90 & SWMATR(1,1,JLEK1) ,AC1 , 40.00 & DYNDEP ,RDX ,RDY , 30.51 & SWPDIR ,IX ,IY , & KSX ,KSY , & XCGRID ,YCGRID , 40.41 & ITER ,KGRPNT ,OBREDF , 40.41 & CAX1 ,CAY1 ,SPCDIR , 33.08 & CGO ,SWMATR(1,1,JTRA0) ,SWMATR(1,1,JTRA1) 40.85 33.08 & ) !TIMG CALL SWTSTO(118) 40.23 ! ! matrix is computed now; updating action densities starts ! provided ACUPDA is true ! IF (.NOT.ACUPDA) THEN 40.07 IF (TESTFL .AND. ITEST.GE.30) WRITE (PRINTF, *) ' No update' 40.07 GOTO 700 40.07 ENDIF 40.07 ! ! preparatory steps before solution of linear system ! !TIMG CALL SWTSTA(119) 40.23 CALL SOLPRE(AC2 ,SWMATR(1,1,JAOLD) , 40.00 & SWMATR(1,1,JMATR) ,SWMATR(1,1,JMATL) , & SWMATR(1,1,JMATD) ,SWMATR(1,1,JMATU) , & SWMATR(1,1,JMAT5) ,SWMATR(1,1,JMAT6) , & IDCMIN ,IDCMAX , & LSWMAT(1,1,JABIN) , & IDTOT ,ISTOT , & IDDLOW ,IDDTOP , & ISSTOP , & SPCSIG ) 40.41 40.23 !TIMG CALL SWTSTO(119) 40.23 ! IF ( DYNDEP .OR. ICUR .EQ. 1 40.00 & ) THEN 30.00 ! ! *** Implicit or explicit scheme in frequency space and *** ! *** implicit scheme in directional space *** ! IF ( INT(PNUMS(8)) .EQ. 1 ) THEN ! ! *** Implicit scheme in frequency space. Solve penta- *** ! *** diagonal system with the SIP solver *** ! !TIMG CALL SWTSTA(120) 40.23 CALL SWSIP ( AC2, SWMATR(1,1,JMATD), SWMATR(1,1,JMATR), & SWMATR(1,1,JMATL), SWMATR(1,1,JMATU), & SWMATR(1,1,JMAT5), SWMATR(1,1,JMAT6), & SWMATR(1,1,JAOLD), & PNUMS(12), NINT(PNUMS(14)), NINT(PNUMS(13)), & INOCNV, IDDLOW, IDDTOP, ISSTOP, IDCMIN, 40.41 & IDCMAX ) !TIMG CALL SWTSTO(120) 40.23 ! ELSE IF (INT(PNUMS(8)).EQ.2 .OR. INT(PNUMS(8)).EQ.3) THEN 40.00 ! ! *** Explicit scheme in frequency space. Energy near the *** ! *** blocking point is removed from the spectrum based *** ! *** on CFL criterion *** ! !TIMG CALL SWTSTA(120) 40.23 CALL SOLMT1 (IDCMIN ,IDCMAX , 40.00 & AC2 ,SWMATR(1,1,JMATR) , & SWMATR(1,1,JMATD) ,SWMATR(1,1,JMATU) , & SWMATR(1,1,JMATL) , 40.23 & ISSTOP , 40.41 40.23 & LSWMAT(1,1,JABLK) ,IDDLOW , 30.90 & IDDTOP ) 5/mar !TIMG CALL SWTSTO(120) 40.23 ! END IF ! ELSE 40.00 ! ! *** No current. Only implicit scheme in directional space *** ! *** Solve the tri-diagonal matrix with Thomas algorithm *** ! !TIMG CALL SWTSTA(120) 40.23 CALL SOLMAT (IDCMIN ,IDCMAX , 40.00 & AC2 ,SWMATR(1,1,JMATR) , & SWMATR(1,1,JMATD) ,SWMATR(1,1,JMATU) , & SWMATR(1,1,JMATL) 40.23 & ) !TIMG CALL SWTSTO(120) 40.23 ! END IF ! ! *** test output *** ! IF ( TESTFL .AND. ITEST .GE. 90 ) THEN WRITE (PRTEST, *) ' solution vector' 40.00 WRITE (PRTEST, *) ' IS ID1 ID2 action densities' 40.00 DO IS = 1, MSC ID_MIN = IDCMIN(IS) ID_MAX = IDCMAX(IS) WRITE(PRINTF,6621) IS, ID_MIN, ID_MAX, & (AC2(MOD(IDDUM-1+MDC,MDC)+1, IS, KCGRD(1)), 40.00 & IDDUM = ID_MIN, ID_MAX) 6621 FORMAT(3I4,600(1X,E12.4)) 40.03 ENDDO END IF ! ! *** if negative action density occur rescale with a factor *** ! *** only the sector computed is rescaled !! *** ! !TIMG CALL SWTSTA(121) 40.23 IF (BRESCL) CALL RESCALE(AC2, ISSTOP, IDCMIN, IDCMAX, NRSCAL) 40.23 40.00 !TIMG CALL SWTSTO(121) 40.23 ! ! calculate propagation, generation, dissipation, redistribution ! leak and radiation stress in present grid point ! !TIMG CALL SWTSTA(124) 40.23 IF ( LADDS ) 40.85 & CALL ADDDIS (COMPDA(1,JDISS) ,COMPDA(1,JLEAK) , & AC2 ,LSWMAT(1,1,JABIN) , 40.02 & SWMATR(1,1,JDIS0) ,SWMATR(1,1,JDIS1) , & SWMATR(1,1,JGEN0) ,SWMATR(1,1,JGEN1) , 40.85 & SWMATR(1,1,JRED0) ,SWMATR(1,1,JRED1) , 40.85 & SWMATR(1,1,JTRA0) ,SWMATR(1,1,JTRA1) , 40.85 & SWMATR(1,1,JMATL) ,SWMATR(1,1,JMATU) , 40.85 & SWMATR(1,1,JMAT5) ,SWMATR(1,1,JMAT6) , 40.85 & COMPDA(1,JDSXB) , 40.67 40.61 & COMPDA(1,JDSXS) , 40.67 40.61 & COMPDA(1,JDSXW) , 40.67 40.61 & COMPDA(1,JDSXV) ,COMPDA(1,JDSXT) , 40.35 40.67 40.61 & COMPDA(1,JDSXM) , 40.67 40.61 & COMPDA(1,JDSXI) , 41.75 & COMPDA(1,JDSXL) , 40.88 & COMPDA(1,JGSXW) ,COMPDA(1,JGENR) , 40.85 & COMPDA(1,JRSXQ) ,COMPDA(1,JRSXT) , 40.85 & COMPDA(1,JREDS) , 40.85 & COMPDA(1,JTSXG) ,COMPDA(1,JTSXT) , 40.85 & COMPDA(1,JTSXS) ,COMPDA(1,JTRAN) , 40.85 & SWMATR(1,1,JLEK1) ,COMPDA(1,JRADS) , 40.85 & SPCSIG 30.72 & ) !TIMG CALL SWTSTO(124) 40.23 ! ! limit the change of the spectrum ! !TIMG CALL SWTSTA(122) 40.23 IF (PNUMS(20).LT.100.) THEN IF (IWIND.NE.4 .OR. NSTATC.NE.1) THEN 40.96 40.61 ! default limiter CALL PHILIM (AC2, SWMATR(1,1,JAOLD), 40.31 40.16 & CGO, KWAVE, 40.00 & SPCSIG, LSWMAT(1,1,JABIN), & ISLMIN, NFLIM, 40.23 & QBLOC) 30.82 ELSE ! Hersbach and Janssen (1999) limiter 40.61 CALL HJLIM (AC2, SWMATR(1,1,JAOLD), 40.61 & CGO, KWAVE, 40.61 & SPCSIG, LSWMAT(1,1,JABIN), 40.61 & ISLMIN, NFLIM, 40.61 & QBLOC, COMPDA(1,JUSTAR)) 40.61 END IF END IF !TIMG CALL SWTSTO(122) 40.23 ! ! *** reduce the computed energy density if the value is *** ! *** larger then the limit value as computed in SWIND *** ! *** in case of first or second generation mode *** ! !TIMG CALL SWTSTA(123) 40.23 IF ( IWIND .EQ. 1 .OR. IWIND .EQ. 2 ) & CALL WINDP3 (ISSTOP, ALIMW, AC2, GROWW, IDCMIN, IDCMAX ) 40.41 30.21 !TIMG CALL SWTSTO(123) 40.23 ! ! *** test output *** ! IF ( TESTFL .AND. ITEST .GE. 70 ) THEN WRITE (PRINTF, *) ' action densities after adaptations' 40.00 WRITE (PRTEST, *) ' IS ID1 ID2 action densities' 40.00 DO IS = 1, MSC ID_MIN = IDCMIN(IS) ID_MAX = IDCMAX(IS) WRITE(PRINTF,6621) IS, ID_MIN, ID_MAX, & (AC2(MOD(IDDUM-1+MDC,MDC)+1, IS, KCGRD(1)), 40.00 & IDDUM = ID_MIN, ID_MAX) ENDDO END IF ! 700 CONTINUE 40.07 ! END IF ! ! End of the subroutine SWOMPU RETURN END !**************************************************************** ! SUBROUTINE SWPRSET (SPCSIG) ! !**************************************************************** ! USE OCPCOMM4 USE SWCOMM2 USE SWCOMM3 USE SWCOMM4 ! IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.80: Marcel Zijlema ! ! 1. Updates ! ! 40.80, Oct. 07: New subroutine ! ! 2. Purpose ! ! Print all the settings used in SWAN run ! ! 4. Argument variables ! ! SPCSIG Relative frequencies in computational domain in sigma-space ! REAL SPCSIG(MSC) ! ! 6. Local variables ! ! ICMX : stencil size ! IENT : number of entries in this subroutine ! IS : loop counter ! INTEGER ICMX, IS, IENT INTEGER II ! dummy variable 41.75 ! ! 9. Subroutines calling ! ! SWCOMP ! ! 13. Source text ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SWPRSET') WRITE(PRINTF,333) 'SWAN' 40.00 333 FORMAT(/, &'----------------------------------------------------------------' &,/, &' COMPUTATIONAL PART OF ', A &,/, &'----------------------------------------------------------------' &,/) ! IF ( ONED ) THEN 32.02 WRITE(PRINTF,*) 'One-dimensional mode of SWAN is activated' 32.02 ENDIF 32.02 ! IF (OPTG.NE.5) THEN 40.80 WRITE(PRINTF,7001) MXC,MYC 7001 FORMAT(' Gridresolution : MXC ',I12 ,' MYC ',I12) WRITE(PRINTF,7002) MCGRD 40.41 7002 FORMAT(' : MCGRD ',I12) 40.41 WRITE(PRINTF,7101) MSC,MDC 7101 FORMAT(' : MSC ',I12 ,' MDC ',I12) ELSE WRITE(PRINTF,7102) MSC,MDC 7102 FORMAT(' Gridresolution : MSC ',I12 ,' MDC ',I12) ENDIF WRITE(PRINTF,7201) MTC 40.41 7201 FORMAT(' : MTC ',I12) 40.41 WRITE(PRINTF,7301) NSTATC, ITERMX 7301 FORMAT(' : NSTATC ',I12 ,' ITERMX',I12) WRITE(PRINTF,7013) ITFRE,IREFR 7013 FORMAT(' Propagation flags : ITFRE ',I12 ,' IREFR ',I12) WRITE(PRINTF,7014) IBOT,ISURF 7014 FORMAT(' Source term flags : IBOT ',I12 ,' ISURF ',I12) WRITE(PRINTF,7114) IWCAP,IWIND 7114 FORMAT(' : IWCAP ',I12 ,' IWIND ',I12) WRITE(PRINTF,7015) ITRIAD,IQUAD 7015 FORMAT(' : ITRIAD ',I12 ,' IQUAD ',I12) WRITE(PRINTF,7016) IVEG, ITURBV 40.35 40.55 7016 FORMAT(' : IVEG ',I12 ,' ITURBV',I12) 40.35 40.55 WRITE(PRINTF,7017) IMUD, IICE 41.75 40.59 7017 FORMAT(' : IMUD ',I12 ,' IICE ',I12) 41.75 40.59 IF (OPTG.NE.5) WRITE(PRINTF,7004) DX,DY 40.80 7004 FORMAT(' Spatial step : DX ',E12.4,' DY ',E12.4) WRITE(PRINTF,7104) EXP(ALOG(SHIG/SLOW)/REAL(MSC-1))-1., 40.41 & DDIR/DEGRAD 40.41 7104 FORMAT(' Spectral bin : df/f ',E12.4,' DDIR ',E12.4) 40.41 WRITE(PRINTF,7003) GRAV, RHO 40.41 7003 FORMAT(' Physical constants : GRAV ',E12.4,' RHO ',E12.4) 40.41 WRITE(PRINTF,7027) U10 , WDIC/DEGRAD 7027 FORMAT(' Wind input : WSPEED ',E12.4,' DIR ',E12.4) WRITE(PRINTF,'(A,F5.2)')' : ICEWIND ',ICEWIND 41.75 WRITE(PRINTF,7123) PWTAIL(1),PWTAIL(2) 7123 FORMAT(' Tail parameters : E(f) ',E12.4,' E(k) ',E12.4) WRITE(PRINTF,7133) PWTAIL(3),PWTAIL(4) 7133 FORMAT(' : A(f) ',E12.4,' A(k) ',E12.4) WRITE(PRINTF,8013) PNUMS(1), PNUMS(4) 40.41 8013 FORMAT(' Accuracy parameters : DREL ',E12.4,' NPNTS ',E12.4) 40.41 IF (PNUMS(21).EQ.0.) THEN 40.41 WRITE(PRINTF,8213) PNUMS(15),PNUMS(16) 40.41 ELSE IF (PNUMS(21).EQ.1.) THEN 40.41 WRITE(PRINTF,8214) PNUMS(2),PNUMS(15) 40.41 END IF 40.41 8213 FORMAT(' : DHOVAL ',E12.4,' DTOVAL',E12.4) 40.41 8214 FORMAT(' : DHABS ',E12.4,' CURVAT',E12.4) 40.41 WRITE(PRINTF,3613) PNUMS(20) 3613 FORMAT(' : GRWMX ',E12.4) WRITE(PRINTF,8508) WLEV, DEPMIN 40.41 8508 FORMAT(' Drying/flooding : LEVEL ',E12.4,' DEPMIN',E12.4) 40.41 IF (BNAUT) THEN 40.41 WRITE (PRINTF,8510) 'nautical ' 40.41 ELSE 40.41 WRITE (PRINTF,8510) 'Cartesian' 40.41 ENDIF 40.41 8510 FORMAT(' The ',A9, 40.41 & ' convention for wind and wave directions is used') 40.41 IF (OPTG.EQ.5) THEN 40.80 WRITE(PRINTF,8511) 'BSBT ' 40.80 ELSEIF (PROPSC.EQ.3) THEN 40.80 40.41 WRITE(PRINTF,8511) 'S&L ' 40.41 ICMX = 13 40.41 ELSEIF (PROPSC.EQ.2) THEN 40.41 WRITE(PRINTF,8511) 'SORDUP' 40.41 ICMX = 7 40.59 40.41 ELSE 40.41 WRITE(PRINTF,8511) 'BSBT ' 40.41 ICMX = 5 40.59 40.41 ENDIF 40.41 8511 FORMAT(' Scheme for geographic propagation is ',A6) 40.41 IF (OPTG.NE.5) WRITE(PRINTF,8512) PROPSC, ICMX 40.80 40.41 8512 FORMAT(' Scheme geogr. space : PROPSC ',I12 ,' ICMAX ',I12) 40.41 WRITE(PRINTF,8513) PNUMS(7), PNUMS(6) 40.41 8513 FORMAT(' Scheme spectral space: CSS ',E12.4,' CDD ',E12.4) 40.41 ! IF ( (DYNDEP .OR. ICUR.EQ.1) .AND. INT(PNUMS(8)).EQ.1 ) THEN 40.41 WRITE(PRINTF,*) 'Solver is SIP' 40.23 WRITE(PRINTF,2213) PNUMS(12), INT(PNUMS(13)) 2213 FORMAT(' : EPS2 ',E12.4,' OUTPUT',I12) WRITE(PRINTF,8223) INT(PNUMS(14)) 8223 FORMAT(' : NITER ',I12) ENDIF ! IF (ICUR.GT.0) THEN WRITE (PRINTF,7115) 'on' ELSE WRITE (PRINTF,7115) 'off' ENDIF 7115 FORMAT(' Current is ', A3) ! IF (IQUAD.GT.0) THEN WRITE(PRINTF,8413) IQUAD 8413 FORMAT(' Quadruplets : IQUAD ',I12) IF (IQUAD.LE.3 .OR. IQUAD.EQ.8) THEN 40.41 WRITE(PRINTF,8414) PQUAD(1), PQUAD(2) 40.41 8414 FORMAT(' : LAMBDA ',E12.4, 40.41 & ' CNL4 ',E12.4) 40.41 WRITE(PRINTF,8415) PQUAD(3), PQUAD(4) 40.41 8415 FORMAT(' : CSH1 ',E12.4, 40.41 & ' CSH2 ',E12.4) 40.41 WRITE(PRINTF,8416) PQUAD(5) 40.41 8416 FORMAT(' : CSH3 ',E12.4) 40.41 ENDIF 40.41 WRITE(PRINTF,8417) PTRIAD(3) 40.41 8417 FORMAT(' Maximum Ursell nr for Snl4 : ',E12.4) 40.41 ELSE WRITE (PRINTF, *) 'Quadruplets is off' ENDIF 40.41 IF (ITRIAD.GT.0) THEN 40.41 WRITE(PRINTF,9413) ITRIAD, PTRIAD(1) 9413 FORMAT(' Triads : ITRIAD ',I12 , & ' TRFAC ',E12.4) WRITE(PRINTF,9414) PTRIAD(2), PTRIAD(4) 40.41 9414 FORMAT(' : CUTFR ',E12.4, 40.41 & ' URCRI ',E12.4) 40.41 WRITE(PRINTF,9415) PTRIAD(5) 40.41 9415 FORMAT(' Minimum Ursell nr for Snl3 : ',E12.4) 40.41 ELSE WRITE (PRINTF, *) 'Triads is off' ENDIF 40.41 IF (IBOT.EQ.2) THEN WRITE(PRINTF,7005) PBOT(2), PBOT(1) 7005 FORMAT(' Collins (`72) : CFW ',E12.4,' CFC ',E12.4) ELSEIF (IBOT.EQ.3) THEN WRITE(PRINTF,7335) PBOT(4), PBOT(5) 7335 FORMAT(' Madsen et al. (`84) : MF ',E12.4,' KN ',E12.4) ELSEIF (IBOT.EQ.1) THEN WRITE(PRINTF,7325) PBOT(3) 7325 FORMAT(' JONSWAP (`73) : GAMMA ',E12.4) ELSEIF (IBOT.EQ.4) THEN 41.04 WRITE(PRINTF,7326) PBOT(6), PBOT(7) 7326 FORMAT(' JONSWAP (`73) : GAMMA1 ',E12.4,' GAMMA2',E12.4) WRITE(PRINTF,7327) PBOT(8), PBOT(9) 7327 FORMAT(' : DSPR1 ',E12.4,' DSPR2 ',E12.4) ELSEIF (IBOT.EQ.5) THEN 41.51 WRITE(PRINTF,7328) PBOT(6) 7328 FORMAT(' RIPPLES (`07) : CF ',E12.4) ELSE WRITE (PRINTF, *) 'Bottom friction is off' ENDIF ! IF (IVEG.EQ.1) THEN 40.55 WRITE(PRINTF,7006) 40.55 7006 FORMAT(' Vegetation due to Dalrymple (1984)') 40.55 ELSE 40.55 WRITE (PRINTF, *) 'Vegetation is off' 40.55 ENDIF 40.55 ! IF (ITURBV.EQ.1) THEN 40.35 WRITE(PRINTF,7007) PTURBV(1), PTURBV(2) 40.35 7007 FORMAT(' Turbulent viscosity : CTB ',E12.4,' TBCUR ',E12.4) 40.35 ELSE 40.35 WRITE (PRINTF, *) 'Turbulence is off' 40.35 ENDIF 40.35 ! IF (IMUD.EQ.1) THEN 40.59 WRITE(PRINTF,7008) PMUD(2), PMUD(3) 40.59 7008 FORMAT(' Mud Ng (2000) : RHOM ',E12.4,' KINVIS',E12.4) 40.59 ELSE 40.59 WRITE (PRINTF, *) 'Fluid mud is off' 40.59 ENDIF 40.59 ! IF (IICE.EQ.1) THEN 41.75 WRITE(PRINTF,'(A)')'Sea ice: CTGA with CICE' 41.75 ELSEIF (IICE.EQ.2) THEN 41.75 WRITE(PRINTF,'(A)')'Sea ice: CTGA with CICE ADCICE' 41.75 ELSEIF (IICE.EQ.3) THEN 41.75 WRITE(PRINTF,'(A)')'Sea ice: IC4M2 with parameters:' 41.75 DO II=1,8 41.75 WRITE(PRINTF,'(A,I2.2,A,E12.4)')' ',II,' :: ',PIC4M2(II) 41.75 END DO 41.75 ELSE 41.75 WRITE (PRINTF, *) 'Dissipation by sea ice is off' 41.75 ENDIF 41.75 ! IF (IWCAP.EQ.1) THEN WRITE(PRINTF,'(2A,E12.4)')' W-cap Komen (`84) : ', & 'EMPCOF (CDS2): ',PWCAP(1) WRITE(PRINTF,'(2A,E12.4)')' W-cap Komen (`84) : ', & 'APM (STPM) : ',PWCAP(2) WRITE(PRINTF,'(2A,E12.4)')' W-cap Komen (`84) : ', & 'POWST : ',PWCAP(9) WRITE(PRINTF,'(2A,E12.4)')' W-cap Komen (`84) : ', & 'DELTA : ',PWCAP(10) WRITE(PRINTF,'(2A,E12.4)')' W-cap Komen (`84) : ', & 'POWK : ',PWCAP(11) ELSEIF (IWCAP.EQ.2) THEN WRITE(PRINTF,6335) PWCAP(3),PWCAP(4) 6335 FORMAT(' W-cap Janssen (`90) : CFJANS ',E12.4, & ' DELTA ',E12.4) ELSEIF (IWCAP.EQ.3) THEN WRITE(PRINTF,6135) PWCAP(5) 6135 FORMAT(' W-cap Longuet-Higgins: CFLHIG ',E12.4) ELSEIF (IWCAP.EQ.4) THEN WRITE(PRINTF,6136) PWCAP(6), PWCAP(7) 6136 FORMAT(' W-cap Battjes/Janssen: BJSTP ',E12.4, & ' BJALF ',E12.4) ELSEIF (IWCAP.EQ.5) THEN WRITE(PRINTF,6136) PWCAP(6), PWCAP(7) WRITE(PRINTF,6137) PWCAP(8) 6137 FORMAT(' : KCONV ',E12.4) ELSEIF (IWCAP.EQ.7) THEN 40.53 WRITE(PRINTF,6139) PWCAP(1), PWCAP(12) 40.53 WRITE(PRINTF,6140) PWCAP(9), PWCAP(11) 40.53 6139 FORMAT(' W-cap Alves-Banner : CDS2 ', 40.53 & E12.4,' BR ',E12.4) 40.53 6140 FORMAT(' : POWST ', 40.53 & E12.4,' POWK ',E12.4) 40.53 ELSEIF (IWCAP.EQ.8) THEN WRITE(PRINTF,6141) A1SDS , A2SDS 40.88 WRITE(PRINTF,6142) P1SDS , P2SDS 40.88 WRITE(PRINTF,6143) CDSV 40.88 WRITE(PRINTF,6144) UPWARDS 40.88 WRITE(PRINTF,6145) VECTOR_TAU 40.88 WRITE(PRINTF,6146) TRUE_U10 40.88 WRITE(PRINTF,6147) WNDSCL 40.88 WRITE(PRINTF,6148) CDFAC 40.88 6141 FORMAT(' W-cap Babanin : A1 ', 40.88 & E12.4,' A2 ',E12.4) 40.88 6142 FORMAT(' : P1 ', 40.88 & E12.4,' P2 ',E12.4) 40.88 6143 FORMAT(' : CDSV ', 40.88 & E12.4) 40.88 6144 FORMAT(' Babanin Sds: concave up behavior : ', L3 ) 40.88 6145 FORMAT(' DBYB Sin: tau calculated from vector: ', L3 ) 40.88 6146 FORMAT(' DBYB Sin: true U10 used : ', L3 ) 40.88 6147 FORMAT(' DBYB Sin: U10PROXY = ',F6.1,' * Ustar' ) 40.88 6148 FORMAT(' DBYB Sin: factor on Cdrag to counter wind bias:',F6.3) 40.88 ELSE WRITE (PRINTF, *) 'Whitecapping is off' ENDIF ! IF (IWIND.GT.0) THEN IF (IDRAG.EQ.1) THEN WRITE(PRINTF, *) 'Wind drag is Wu' ELSE IF (IDRAG.EQ.2) THEN WRITE(PRINTF, *) 'Wind drag is fit' ELSE IF (IDRAG.EQ.3) THEN WRITE(PRINTF, *) 'Wind drag is swell' !ADC ELSE IF (IDRAG.EQ.0) THEN !ADC WRITE(PRINTF, *) 'Wind drag is ADCIRC formulation' ELSE IF (IDRAG.EQ.4) THEN WRITE(PRINTF, *) 'Wind drag is Hwang' ELSE IF (IDRAG.EQ.5) THEN WRITE(PRINTF, *) 'Wind drag is Fan' ELSE IF (IDRAG.EQ.6) THEN WRITE(PRINTF, *) 'Wind drag is ECMWF' ENDIF ENDIF ! IF (IWIND.EQ.3) THEN 40.88 WRITE (PRINTF, *) 'Snyder/Komen wind input' 40.88 ELSEIF (IWIND.EQ.4) THEN WRITE (PRINTF, *) 'Janssen wind input' ELSEIF (IWIND.EQ.5) THEN WRITE (PRINTF, *) 'Yan/Westhuysen wind input' ELSEIF (IWIND.EQ.8) THEN 40.88 WRITE (PRINTF, *) 'DBYB/Tsagareli/Rogers wind input' 40.88 ENDIF 40.88 ! IF (ISURF.EQ.1) THEN WRITE(PRINTF,7012) PSURF(1),PSURF(2) 7012 FORMAT(' Battjes&Janssen (`78): ALPHA ',E12.4, & ' GAMMA ',E12.4) ELSEIF (ISURF.EQ.2) THEN 970219 WRITE(PRINTF,7212) PSURF(1), PSURF(4) 7212 FORMAT(' Nelson (`94) : ALPHA ',E12.4, & ' GAMmin',E12.4) WRITE(PRINTF,7213) PSURF(5) 7213 FORMAT(' GAMmax ',E12.4) ELSEIF (ISURF.EQ.3) THEN 41.03 WRITE(PRINTF,7214) PSURF(1), PSURF(4) 7214 FORMAT(' Ruessink et al (2003): ALPHA ',E12.4, & ' A ',E12.4) WRITE(PRINTF,7215) PSURF(5) 7215 FORMAT(' B ',E12.4) ELSEIF (ISURF.EQ.4) THEN 41.03 WRITE(PRINTF,7216) PSURF(1), PSURF(4) 7216 FORMAT(' Thornton&Guza (`83) : ALPHA ',E12.4, & ' GAMMA ',E12.4) WRITE(PRINTF,7217) PSURF(5) 7217 FORMAT(' N ',E12.4) ELSEIF (ISURF.EQ.6) THEN 41.38 WRITE(PRINTF,7220) PSURF(1), PSURF(4) 7220 FORMAT(' beta-kd (2013) : ALPHA ',E12.4, & ' GAMMA0',E12.4) WRITE(PRINTF,7221) PSURF(5), PSURF(6) 7221 FORMAT(' A1 ',E12.4, & ' A2 ',E12.4) WRITE(PRINTF,7222) PSURF(7) 7222 FORMAT(' A3 ',E12.4) ELSE WRITE (PRINTF, *) 'Surf breaking is off' ENDIF ! IF (LSETUP.GT.0) THEN WRITE(PRINTF,7109) PSETUP(2) 7109 FORMAT(' Set-up : SUPCOR ',E12.4) ELSE WRITE (PRINTF, *) 'Set-up is off' ENDIF ! IF (IDIFFR.EQ.1) THEN 40.41 WRITE(PRINTF,7110) PDIFFR(1), NINT(PDIFFR(2)) 7110 FORMAT(' Diffraction : SMPAR ',E12.4, & ' SMNUM ',I12) ELSE WRITE (PRINTF, *) 'Diffraction is off' ENDIF ! WRITE(PRINTF,7126) PWIND(14), PWIND(15) 7126 FORMAT(' Janssen (`89,`90) : ALPHA ',E12.4, & ' KAPPA ',E12.4) WRITE(PRINTF,7136) PWIND(16), PWIND(17) 7136 FORMAT(' Janssen (`89,`90) : RHOA ',E12.4, & ' RHOW ',E12.4) WRITE(PRINTF,*) WRITE(PRINTF,1012) PWIND(1), PWIND(2) 1012 FORMAT(' 1st and 2nd gen. wind: CF10 ',E12.4, & ' CF20 ',E12.4) WRITE(PRINTF,1013) PWIND(3), PWIND(4) 1013 FORMAT(' : CF30 ',E12.4, & ' CF40 ',E12.4) WRITE(PRINTF,1014) PWIND(5), PWIND(6) 1014 FORMAT(' : CF50 ',E12.4, & ' CF60 ',E12.4) WRITE(PRINTF,1015) PWIND(7), PWIND(8) 1015 FORMAT(' : CF70 ',E12.4, & ' CF80 ',E12.4) WRITE(PRINTF,1016) PWIND(9), PWIND(10) 1016 FORMAT(' : RHOAW ',E12.4, & ' EDMLPM',E12.4) WRITE(PRINTF,1017) PWIND(11), PWIND(12) 1017 FORMAT(' : CDRAG ',E12.4, & ' UMIN ',E12.4) WRITE(PRINTF,1018) PWIND(13) 1018 FORMAT(' : LIM_PM ',E12.4) ! WRITE(PRINTF,*) IF ( ITEST .GT. 2 ) THEN DO IS = 1, MSC WRITE(PRINTF,*)' IS and SPCSIG(IS) :',IS,SPCSIG(IS) 30.72 ENDDO WRITE(PRINTF,*) ENDIF RETURN END !**************************************************************** ! SUBROUTINE SACCUR (DEP2 ,KGRPNT , & XYTST , 40.41 & AC2 ,SPCSIG ,ACCUR , 30.72 & HSACC1 ,HSACC2 ,SACC1 , & SACC2 ,DELHS ,DELTM , 40.31 & I1MYC ,I2MYC ) 40.31 ! !**************************************************************** ! USE OCPCOMM1 40.41 USE OCPCOMM2 40.41 USE OCPCOMM3 40.41 USE OCPCOMM4 40.41 USE SWCOMM1 40.41 USE SWCOMM2 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE M_PARALL 40.31 ! IMPLICIT NONE ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmer(s): R.C. Ris | ! | Modified by R. Padilla and N. Booij | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.72: IJsbrand Haagsma ! 30.82: IJsbrand Haagsma ! 40.03: Nico Booij ! 40.22: John Cazes and Tim Campbell ! 40.30: Marcel Zijlema ! 40.31: Tim Campbell and John Cazes ! 40.41: Marcel Zijlema ! ! 1. Update ! ! 30.72, Nov. 97: Declaration of DDIR, PI and PI2 removed because ! they are common and already declared in the ! INCLUDE file ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 30.82, Aug. 99: Introduced a new overall measure for checking accuracy ! 30.82, Aug. 99: Changed all variables INDEX to INDX, since INDEX is reserved ! 40.03, Feb. 00: test level of message changed ! 40.22, Sep. 01: Added initialization of SACC1 and HSACC1 elements 40.22 ! that are not wet points. 40.22 ! 40.30, Mar. 03: introduction distributed-memory approach using MPI ! 40.31, Jul. 03: some improvements and corrections w.r.t. OpenMP ! 40.41, Aug. 04: add some test output for checking accuracy ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! To check the accuracy of the final computation. If a certain ! accuracy has been reached then terminate the iteration process ! ! 3. Method ! ! --- ! ! 4. Argument variables ! ! AC2 action density ! ACCUR indicates percentage of grid points in ! which accuracy is reached ! DELHS difference in Hs between last 2 iterations ! DELTM difference in Tm01 between last 2 iterations ! DEP2 depth ! HSACC1 significant wave height at iter-1 ! HSACC2 significant wave height at iter ! I1MYC lower index for thread loop over y-grid row ! I2MYC upper index for thread loop over y-grid row ! KGRPNT indirect addressing ! SACC1 mean wave frequency at iter-1 ! SACC2 mean wave frequency at iter ! SPCSIG relative frequencies in computational domain ! in sigma-space 30.72 ! XYTST coordinates of test points ! INTEGER I1MYC, I2MYC 40.31 REAL ACCUR INTEGER KGRPNT(MXC,MYC) INTEGER XYTST(2*NPTST) 40.41 REAL AC2(MDC,MSC,MCGRD) , & DEP2(MCGRD) , & HSACC1(MCGRD) , & HSACC2(MCGRD) , & SACC1(MCGRD) , & SACC2(MCGRD) , & DELHS(MCGRD) , & DELTM(MCGRD) REAL SPCSIG(MSC) 30.72 ! ! 6. Local variables ! INTEGER IS ,ID ,WETGRD,IACCUR,IX,IY,IX1,IX2,IY1,IY2 INTEGER WETGRDt, IACCURt 40.31 ! ! INDX : counter 30.82 ! NINDX : number of gridpoints to average over 30.82 ! INTEGER INDX, NINDX 30.82 INTEGER NINDXt 40.31 ! REAL SME_T ,SME_B , 30.72 & TMREL ,HSREL ,TMABS ,HSABS 30.72 REAL ARR(2) 40.30 ! ! HSMN2 : mean Hs over space at current iteration level 30.82 ! HSOVAL: Overall accuracy measure for Hs 30.82 ! SMN2 : mean Tm over space at current iteration level 30.82 ! TMOVAL: Overall accuracy measure for Tm 30.82 ! REAL HSMN2, HSOVAL, SMN2, TMOVAL 30.82 REAL HSMN2t, SMN2t 40.31 ! ! LHEAD : logical indicating to write header 40.41 ! TSTFL : indicates whether grid point is a test point 40.41 ! LOGICAL LHEAD, TSTFL 40.41 ! INTEGER IENT, II REAL ACS2, ACS3 ! ! 7. Common blocks used ! ! Place local summed variables in common block so they will 40.31 ! be scoped as shared 40.31 COMMON/SACCUR_MT_COM/HSMN2,SMN2,NINDX,WETGRD,IACCUR 40.31 ! ! 8. Subroutines used ! ! EQREAL Boolean function which compares two REAL values ! STRACE Tracing routine for debugging ! STPNOW Logical indicating whether program must ! terminated or not ! SWREDUCE Performs a global reduction ! LOGICAL EQREAL !MPI LOGICAL STPNOW ! ! 9. Subroutines calling ! ! SWCOMP (in SWANCOM1) ! ! 12. Structure ! ! --------------------------------------------------------------- ! If not the first iteration, the do ! Set old values in dummy array ! --------------------------------------------------------------- ! Do for every x and y ! Compute the mean action density frequency SACC1 and the ! and the significant waveheight HSACC1 ! --------------------------------------------------------------- ! If relative error for mean frequency or significant wave height ! > certain given value then increase variable with one and ! compute the relative number of gridpoints in where the accuracy ! has not been reached ! --------------------------------------------------------------- ! End of the subroutine SACCUR ! ---------------------------------------------------------------- ! ! 13. Source text ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SACCUR') ! !$OMP MASTER 40.31 ! Master thread initialize the shared variables 40.31 HSMN2 = 0. 40.31 SMN2 = 0. 40.31 NINDX = 0 40.31 WETGRD = 0 40.31 IACCUR = 0 40.31 !$OMP END MASTER 40.31 !$OMP BARRIER 40.31 ! IF ( LMXF ) THEN 40.41 40.30 IX1 = 1 ELSE IX1 = 1+IHALOX END IF IF ( LMXL ) THEN IX2 = MXC ELSE IX2 = MXC-IHALOX END IF IF ( LMYF ) THEN IY1 = I1MYC ELSE IY1 = 1+IHALOY END IF IF ( LMYL ) THEN IY2 = I2MYC ELSE IY2 = MYC-IHALOY END IF ! ! *** If the computation is non steady : check the gridpoints *** ! *** at the different "timesteps" if they are still the same *** ! *** then WETGRD is the same. If not: change this subroutine *** ! *** *** ! *** +++++++++++++++++++ +++++++++++++++++++++ *** ! *** +++++++++++++++++++ +++++++++++++++++++++ *** ! *** ++++++++ ++++++ +++++++++ ++++++ *** ! *** + + ++++ + *** ! *** + + +++ + *** ! *** + + ++ + *** ! *** + + + + *** ! *** + t=0 + + t=t+1 + *** ! *** + + + + *** ! *** +++++++++++++++++++ +++++++++++++++++++++ *** ! *** *** ! WETGRDt = 0 40.31 DO 101 IX = IX1, IX2 DO 100 IY = IY1, IY2 INDX = KGRPNT(IX,IY) IF (DEP2(INDX) .GT. DEPMIN) THEN 25/MAR HSACC1(INDX) = MAX( 1.E-20 , HSACC2(INDX) ) 30.21 SACC1(INDX) = MAX( 1.E-20 , SACC2(INDX) ) 30.21 WETGRDt = WETGRDt + 1 40.31 ! Added to initialize HSACC1 and SACC1 values. 40.22 ELSE 40.22 HSACC1(INDX) = 0. 40.22 SACC1(INDX) = 0. 40.22 END IF 40.22 100 CONTINUE 101 CONTINUE ! ! *** first criterion to terminate the iteration process *** ! *** *** ! *** RELATIVE error : *** ! *** Hs2 - Hs1 Tm2 - Tm1 *** ! *** DREL = ---------- and ---------- *** ! *** Hs1 Tm1 *** ! *** *** ! *** ABSOLUTE error : *** ! *** *** ! *** DHABS = Hs2 - Hs1 < PNUMS(2) *** ! *** DTABS = Tm2 - Tm1 < PNUMS(3) *** ! *** *** ! DO 201 IX = IX1, IX2 DO 200 IY = IY1, IY2 INDX = KGRPNT(IX,IY) ! ! *** Compute the mean ENERGY DENSITY frequency and *** ! *** significant waveheight over the full spectrum *** ! *** per gridpoint *** ! IF (DEP2(INDX) .GT. DEPMIN) THEN 25/MAR SME_T = 0. SME_B = 0. DO 180 IS = 1, MSC DO 170 ID = 1, MDC ACS2 = SPCSIG(IS)**2 * AC2(ID,IS,INDX) 30.72 ACS3 = SPCSIG(IS) * ACS2 30.72 SME_B = SME_B + ACS2 SME_T = SME_T + ACS3 170 CONTINUE 180 CONTINUE SME_B = SME_B * FRINTF * DDIR 30.50 SME_T = SME_T * FRINTF * DDIR 30.50 ! ! *** mean frequency and significant wave height per gridpoint *** ! IF ( SME_B .LE. 0. ) THEN SME_B = 1.E-20 SACC2(INDX) = 1.E-20 30.21 HSACC2(INDX) = 1.E-20 30.21 ELSE SACC2(INDX) = MAX ( 1.E-20 , (SME_T / SME_B) ) 30.21 HSACC2(INDX) = MAX ( 1.E-20 , (4. * SQRT(SME_B)) ) 30.21 END IF END IF 200 CONTINUE 201 CONTINUE ! ! *** the mean significant waveheight and the mean *** ! *** relative frequency over the gridpoints which *** ! *** depth is larger than 0 m. *** ! *** The amount of gridpoints is denoted with the *** ! *** variable : NINDX *** ! *** These values are used to compute the SRELF *** ! *** and the HSRELF instead of SACC2 and HSACC2 *** ! ! Note that initialization of ACCUR is not needed since it is 40.31 ! not being summed upon 40.31 IACCURt = 0 40.31 ! ! Calculate the mean Hs and Tm over all wet gridpoints. These means ! are then used as an overall accuracy measure. ! HSMN2t= 0. 40.31 30.82 SMN2t= 0. 40.31 30.82 NINDXt= 0 40.31 30.82 ! DO 301 IX = IX1, IX2 DO 300 IY = IY1, IY2 INDX = KGRPNT(IX,IY) IF (DEP2(INDX).GT.DEPMIN) THEN 30.82 HSMN2t = HSMN2t + HSACC2(INDX) 40.31 30.82 SMN2t = SMN2t + SACC2(INDX) 40.31 30.82 NINDXt = NINDXt + 1 40.31 30.82 END IF 30.82 300 CONTINUE 30.82 301 CONTINUE ! ! Global sum of NINDX 40.31 !$OMP ATOMIC 40.31 NINDX = NINDX + NINDXt 40.31 !$OMP ATOMIC 40.31 HSMN2 = HSMN2 + HSMN2t 40.31 !$OMP ATOMIC 40.31 SMN2 = SMN2 + SMN2t 40.31 ! !$OMP BARRIER 40.31 !$OMP MASTER 40.31 ARR(1) = HSMN2 40.30 ARR(2) = SMN2 40.30 CALL SWREDUCE( ARR, 2, SWREAL, SWSUM ) 40.30 CALL SWREDUCE( NINDX, 1, SWINT, SWSUM ) 40.41 !MPI IF (STPNOW()) RETURN 40.30 HSMN2 = ARR(1) / REAL(NINDX) 40.30 30.82 SMN2 = ARR(2) / REAL(NINDX) 40.30 30.82 !$OMP END MASTER 40.31 !$OMP BARRIER 40.31 ! ! Calculate a set of accuracy parameters based on relative, absolute ! and overall accuracy measures for Hs and Tm ! LHEAD=.TRUE. 40.41 DO 401 IX = IX1, IX2 DO 400 IY = IY1, IY2 INDX = KGRPNT(IX,IY) ! --- determine whether the point is a test point 40.41 TSTFL = .FALSE. 40.41 IF (NPTST.GT.0) THEN 40.41 DO 20 II = 1, NPTST 40.41 IF (IX.NE.XYTST(2*II-1)) GOTO 20 40.41 IF (IY.NE.XYTST(2*II )) GOTO 20 40.41 TSTFL = .TRUE. 40.41 20 CONTINUE 40.41 END IF 40.41 IF ( DEP2(INDX) .GT. DEPMIN ) THEN 25/MAR TMREL = ABS ( SACC2(INDX) - SACC1(INDX) ) / & SACC1(INDX) 30.21 TMABS = ABS ( ( PI2/SACC2(INDX)) - (PI2/SACC1(INDX)) ) 30.21 TMOVAL = ABS ( SACC2(INDX) - SACC1(INDX) ) / SMN2 30.82 ! HSREL = ABS ( HSACC2(INDX) - HSACC1(INDX) ) / & HSACC1(INDX) 30.21 HSABS = ABS ( HSACC2(INDX) - HSACC1(INDX) ) 30.21 HSOVAL = ABS ( HSACC2(INDX) - HSACC1(INDX) ) / HSMN2 30.82 ! IF (EQREAL(SACC1(INDX),1.E-20) .OR. 40.41 & EQREAL(SACC2(INDX),1.E-20) ) THEN 40.41 DELTM(INDX) = 0. 40.41 ELSE 40.41 DELTM(INDX) = TMABS END IF 40.41 DELHS(INDX) = HSABS ! ! *** gridpoint in which mean period and wave height *** ! *** have reached required accuracy *** ! IF ( ITEST .GE. 30 .AND. TESTFL) THEN WRITE(PRINTF,3002) SACC2(INDX), SACC1(INDX), & HSACC2(INDX), HSACC1(INDX) 30.21 3002 FORMAT(' SACCUR: SA2 SA1 HSA2 HSA1 :',4E12.4) WRITE(PRINTF,2002) TMREL, HSREL, TMABS, HSABS 2002 FORMAT(' SACCUR: TMREL HSREL TMABS HSABS :',4E12.4) ENDIF ! IF ( (TMREL .LE. PNUMS(1) .OR. TMOVAL .LE. PNUMS(16)) .AND. 30.82 & (HSREL .LE. PNUMS(1) .OR. HSOVAL .LE. PNUMS(15)) ) THEN 30.82 IACCURt = IACCURt + 1 40.31 END IF ! IF (TSTFL) THEN 40.41 IF (LHEAD) WRITE(PRINTF,501) 40.41 WRITE(PRINTF,502) IX+MXF-2, IY+MYF-2, HSREL, HSOVAL, 40.41 & TMREL, TMOVAL 40.41 501 FORMAT(25X,'dHrel ','dHoval ', 40.41 & 'dTm01rel ','dTm01oval ') 40.41 502 FORMAT(1X,SS,'(IX,IY)=(',I5,',',I5,')',' ', 40.41 & 1PE13.6E2,' ',1PE13.6E2,' ',1PE13.6E2,' ', 40.41 & 1PE13.6E2) 40.41 LHEAD=.FALSE. 40.41 END IF 40.41 ELSE ! *** otherwise set arrays equal 0 *** DELTM(INDX) = 0.0 DELHS(INDX) = 0.0 END IF ! ! Test output at test points ! IF ( ITEST .GE. 30 .AND. TESTFL) THEN 30.82 WRITE(PRINTF,1003) TMREL, TMABS, TMOVAL 30.82 1003 FORMAT(' SACCUR: TMREL, TMABS, TMOVAL :',3E12.4) 30.82 WRITE(PRINTF,1004) HSREL, HSABS, HSOVAL 30.82 1004 FORMAT(' SACCUR: HSREL, HSABS, HSOVAL :',3E12.4) 30.82 END IF 30.82 ! 400 CONTINUE 401 CONTINUE ! ! Global sum of IACCUR and WETGRD 40.31 !$OMP ATOMIC 40.31 IACCUR = IACCUR + IACCURt 40.31 !$OMP ATOMIC 40.31 WETGRD = WETGRD + WETGRDt 40.31 ! !$OMP BARRIER 40.31 !$OMP MASTER 40.31 ! CALL SWREDUCE ( IACCUR, 1, SWINT, SWSUM ) 40.30 !MPI IF (STPNOW()) RETURN 40.30 ACCUR = REAL(IACCUR) * 100. / REAL(NINDX) !$OMP END MASTER 40.31 !$OMP BARRIER 40.31 ! ! *** test output *** ! !$OMP MASTER 40.31 IF ( ITEST .GE. 30 ) THEN 40.03 WRITE(PRINTF,1002) PNUMS(1), PNUMS(2), PNUMS(3) 1002 FORMAT(' SACCUR: PNUMS(1) DHABS DTABS :',3E12.4) WRITE(PRINTF,1008) NINDX,IACCUR,ACCUR 1008 FORMAT(' SACCUR: WETGRD IACCUR ACCUR :',2I8,E12.4) END IF !$OMP END MASTER 40.31 ! ! End of the subroutine SACCUR RETURN END ! !**************************************************************** ! SUBROUTINE INSAC (AC2 ,SPCSIG ,DEP2 , 30.72 & HSACC2 ,SACC2 ,KGRPNT , 40.31 40.30 & I1MYC ,I2MYC ) 40.31 ! !**************************************************************** ! USE OCPCOMM1 40.41 USE OCPCOMM2 40.41 USE OCPCOMM3 40.41 USE OCPCOMM4 40.41 USE SWCOMM1 40.41 USE SWCOMM2 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE M_PARALL 40.31 ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmer(s): R.C. Ris | ! | Modified by R. Padilla and N. Booij | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.72: IJsbrand Haagsma ! 40.30: Marcel Zijlema ! 40.31: Tim Campbell and John Cazes ! 40.41: Marcel Zijlema ! ! 1. Update ! ! 30.72, Nov. 97: Declartion of DDIR removed because it is a common ! and already declared in the INCLUDE file ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 40.30, Mar. 03: introduction distributed-memory approach using MPI ! 40.31, Jul. 03: some improvements and corrections w.r.t. OpenMP ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! To check the accuracy of the final computation. If a certain ! accuracy has been reached then quit the iteration process ! ! 3. Method ! ! --- ! ! 4. Argument variables ! ! SPCSIG: Relative frequencies in computational domain in sigma-space 30.72 ! REAL SPCSIG(MSC) 30.72 ! ! IX Counter of gridpoints in x-direction ! IY Counter of gridpoints in y-direction ! IS Counter of relative frequency band ! ID Counter of the spectral direction ! ICMAX Maximum counter for the points of the molecul ! ITER Number of iteration i.e. number of full sweeps ! MXC Maximum counter of gridppoints in x-direction ! MYC Maximum counter of gridppoints in y-direction ! MSC Maximum counter of relative frequency ! MDC Maximum counter of directional distribution ! ! REALS: ! --------- ! ! DDIR Spectral direction band width ! DS Width of the frequency band ! ! one and more dimensional arrays: ! --------------------------------- ! ! AC2 4D Action density as function of D,S,X,Y at time T ! DEP2 2D Depth ! HSACC2 2D Dummy array for the significant wave height ! (old value) ! SACC2 2D Dummy array for the mean frequency (old value) ! ! 5. SUBROUTINES CALLING ! ! SWOMPU ! ! 6. SUBROUTINES USED ! ! --- ! ! 7. ERROR MESSAGES ! ! --- ! ! 8. REMARKS ! ! 9. STRUCTURE ! ! --------------------------------------------------------------- ! If the first iteration, the do ! Set old values in dummy array ! --------------------------------------------------------------- ! End of the subroutine INSAC ! ---------------------------------------------------------------- ! ! 10. SOURCE ! !************************************************************************ ! INTEGER IS ,ID, IX, IY, IX1, IX2, IY1, IY2 INTEGER I1MYC, I2MYC 40.31 ! INTEGER KGRPNT(MXC,MYC) REAL SME_T ,SME_B 30.72 ! REAL AC2(MDC,MSC,MCGRD) , 30.21 & DEP2(MCGRD) , 30.21 & HSACC2(MCGRD) , 30.21 & SACC2(MCGRD) 30.21 ! INTEGER IENT ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'INSAC') ! IF ( LMXF ) THEN 40.41 40.30 IX1 = 1 ELSE IX1 = 1+IHALOX END IF IF ( LMXL ) THEN IX2 = MXC ELSE IX2 = MXC-IHALOX END IF IF ( LMYF ) THEN IY1 = I1MYC ELSE IY1 = 1+IHALOY END IF IF ( LMYL ) THEN IY2 = I2MYC ELSE IY2 = MYC-IHALOY END IF ! DO 30 IX = IX1, IX2 DO 20 IY = IY1, IY2 ! ! *** Compute the mean ENERGY DENSITY frequency SACC2 *** ! *** and the wavenumber HSACC2 average over the full *** ! *** spectrum per gridpoint *** ! IND = KGRPNT(IX,IY) IF (DEP2(IND) .GT. DEPMIN ) THEN 25/MAR SME_T = 0. SME_B = 0. DO 18 IS = 1, MSC DO 17 ID = 1, MDC ACS2 = SPCSIG(IS)**2 * AC2(ID,IS,IND) 30.72 ACS3 = SPCSIG(IS) * ACS2 30.72 SME_B = SME_B + ACS2 SME_T = SME_T + ACS3 17 CONTINUE 18 CONTINUE SME_B = SME_B * FRINTF * DDIR 30.50 SME_T = SME_T * FRINTF * DDIR 30.50 ! ! *** mean frequency and significant wave height *** ! *** per gridpoint *** ! IF ( SME_B .LE. 0. ) THEN SACC2(IND) = 1.E-20 HSACC2(IND) = 1.E-20 ELSE SACC2(IND) = MAX ( 1.E-20 , (SME_T / SME_B) ) HSACC2(IND) = MAX ( 1.E-20 , (4. * SQRT(SME_B)) ) END IF ELSE SACC2(IND) = 0. HSACC2(IND) = 0. END IF 20 CONTINUE 30 CONTINUE ! ! End of the subroutine INSAC RETURN END ! !**************************************************************** ! SUBROUTINE ACTION (IDCMIN ,IDCMAX ,SPCSIG , 33.09 & AC2 ,CAX ,CAY , & CAS ,CAD ,IMATLA , & IMATDA ,IMATUA ,IMATRA , & IMAT5L , 40.22 & IMAT6U ,ISCMIN ,ISCMAX , & IDDLOW ,IDDTOP ,ISSTOP , & ANYBLK ,ANYBIN , & LEAKC1 ,AC1 , 40.00 & DYNDEP ,RDX ,RDY , 30.51 & SWPDIR ,IX ,IY , & KSX ,KSY , & XCGRID ,YCGRID , 40.41 & ITER ,KGRPNT ,OBREDF , 40.41 & CAX1 ,CAY1 ,SPCDIR , 33.08 & CGO ,TRAC0 ,TRAC1 40.85 33.08 & ) ! !**************************************************************** ! USE TIMECOMM 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE OCPCOMM4 40.41 ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.72: IJsbrand Haagsma ! 30.74: IJsbrand Haagsma (Include version) ! 33.08: W. Erick Rogers (some S&L scheme-related changes) ! 33.09: Nico Booij and Erick Rogers ! 33.10: Nico Booij and Erick Rogers ! 40.03: Nico Booij ! 40.08: Erick Rogers ! 40.09: Annette Kieftenburg ! 40.22: John Cazes and Tim Campbell ! 40.23: Marcel Zijlema ! 40.28: Annette Kieftenburg ! 40.41: Marcel Zijlema ! 40.85: Marcel Zijlema ! ! 1. Updates ! ! 30.74, Nov. 97: Prepared for version with INCLUDE statements ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 30.70, Mar. 98: water level (WLEV2) and wave height (CHS) in comp. grid ! added as arguments (needed for SWTRCF) ! Call SWTRCF modified ! 33.08, July 98: some S&L scheme-related changes ! 33.09, Sept 99: changes re: the spherical coordinates ! 33.10, Jan. 00: changes re: the SORDUP scheme ! 40.09, May 00: Argument list SWTRCF modified ! 40.03, Apr. 00: integers LINK1 and LINK2 replaced by array LINK(1:MICMAX) ! 40.22, Sep. 01: Removed WAREA array. 40.22 ! 40.22, Sep. 01: Changed array definitions to use the parameter 40.22 ! MICMAX instead of ICMAX. 40.22 ! 40.28, Dec. 01: Argument list SWTRCF modified 40.28 ! 40.23, Aug. 02: Print of CPU times added ! 40.23, Nov. 02: call to SWFLXD added ! 40.08, Mar. 03: Dimensioning of RDX, RDX changed to be consistent ! with other subroutines ! 40.41, Aug. 04: call to SWTRCF removed because superfluous ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! 40.85, Aug. 08: add transport for output purposes ! ! 2. Purpose ! ! to determine the transport, refraction and the source terms ! of the action balance equation ! ! 3. Method ! ! --- ! ! 4. Argument variables ! ! SPCSIG: Relative frequencies in computational domain in sigma-space 30.72 ! XCGRID: Coordinates of computational grid in x-direction 30.72 ! YCGRID: Coordinates of computational grid in y-direction 30.72 ! REAL SPCSIG(MSC) 30.72 REAL XCGRID(MXC,MYC), YCGRID(MXC,MYC) 30.72 ! ! IX Counter of gridpoints in x-direction ! IY Counter of gridpoints in y-direction ! ICMAX Maximum counter for the points of the molecul ! MXC Maximum counter of gridppoints in x-direction ! MYC Maximum counter of gridppoints in y-direction ! MSC Maximum counter of relative frequency ! MDC Maximum counter of directional distribution ! KSX Dummy variable to get the right sign in the ! numerical difference scheme in X-direction ! depending on the sweep direction, KSX = -1 or +1 ! KSY Dummy variable to get the right sign in the ! numerical difference scheme in Y-direction ! depending on the sweep direction, KSY = -1 or +1 ! IDTOT,ISTOT Maximum range between the counters in directional ! space and frequency space respectively ! IDDLOW Minimum counter per sweep taken over all ! frequencies ! IDDTOP Maximum counter per sweep taken over all ! frequencies ! ISSTOP Maximum counter per sweep taken over all ! frequencies ! ! ! REALS: ! --------- ! ! DX,DY Step size in x-direction and y-direction ! DDX Same as DX but with correct sign depending of the ! direction of the sweep ! DDY Same as DY but with correct sign depending of the ! direction of the sweep ! ! one and more dimensional arrays: ! --------------------------------- ! ! AC2 4D Action density as function of D,S,X,Y at time T ! CAD 3D Wave transport velocity in spectral direction as ! function of (ID,IS,IC) ! CAS 3D Wave transport velocity in frequency-direction as ! as function of (ID,IS,IC) ! CAX 3D Wave transport velocity in X-dirction as function of ! (ID,IS,IC) ! CAY 3D Wave transport velocity in Y-dirction as function of ! (ID,IS,IC) ! IMATDA 2D Coefficients of main diagonal of matrix ! IMATLA 2D Coefficients of lower diagonal of matrix ! IMATUA 2D Coefficients of upper diagonal of matrix ! IMATRA 2D Coefficients of right hand side ! IMAT5L 2D coefficient of lower diagonal in presence of ! a current (see routine SWSIP) ! IMAT6U 2D coefficient of upper diagonal in presence of ! a current (see routine SWSIP) ! ! 7. Common blocks used ! ! ! 8. Subroutines used ! ! STRSXY ! SORDUP ! SANDL ! STRSSI ! STRSSB ! STRSD ! SWFLXD ! ! 9. Subroutines calling ! ! SWOMPU ! ! 10. Error messages ! ! --- ! ! 11. Remarks ! ! --- ! ! 12. Structure ! ! ------------------------------------------------------------------- ! *** transport in geographical space *** ! Call STRSX to compute the propagation terms in X-direction ! Call STRSY to compute the propagation terms in Y-direction ! ------------------------------------------------------------------- ! *** transport in frequency space *** ! If implicit scheme in frequency space then ! --- ! Call STRSSI to compute the propagation terms in S-direction ! --- ! else if explicit scheme in frequency space and the energy near ! the blocking point is removed from the spectrum then ! --- ! Call STRSSB to compute the propagation terms in S-direction ! --- ! endif ! ------------------------------------------------------------------- ! IF no flux-limiting DO ! Call STRSD to compute the propagation terms in directional domain ! ELSE IF flux-limiting DO ! Call SWFLXD ! --------------------------------------------------------- ! End of subroutine ACTION ! --------------------------------------------------------- ! ! 13. Source text ! INTEGER IDDLOW ,IDDTOP ,ISSTOP , 33.09 NB! & SWPDIR ,ITER 33.09 NB! ! LOGICAL DYNDEP 33.09 ! INTEGER :: IDCMIN(MSC), IDCMAX(MSC) INTEGER :: ISCMIN(MDC), ISCMAX(MDC) INTEGER :: KGRPNT(MXC,MYC) ! REAL :: AC2(MDC,MSC,MCGRD) ,AC1(MDC,MSC,MCGRD) REAL :: CAX(MDC,MSC,MICMAX) ,CAY(MDC,MSC,MICMAX) 40.22 REAL :: CAX1(MDC,MSC,MICMAX) ,CAY1(MDC,MSC,MICMAX) 33.08 40.22 REAL :: CGO(MSC,MICMAX) 33.08 40.22 REAL :: CAS(MDC,MSC,MICMAX) ,CAD(MDC,MSC,MICMAX) 40.22 REAL :: IMATLA(MDC,MSC) ,IMATDA(MDC,MSC) , & IMATUA(MDC,MSC) ,IMATRA(MDC,MSC) , & IMAT5L(MDC,MSC) ,IMAT6U(MDC,MSC) , & LEAKC1(MDC,MSC) REAL :: RDX(MICMAX) ,RDY(MICMAX) , 33.09 40.08 & OBREDF(MDC,MSC,2) , & SPCDIR(MDC,6) 33.08 REAL :: TRAC0 (1:MDC,1:MSC,1:MTRNP) 40.85 REAL :: TRAC1 (1:MDC,1:MSC,1:MTRNP) 40.85 ! LOGICAL ANYBLK(MDC,MSC) ,ANYBIN(MDC,MSC) ! INTEGER IENT ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'ACTION') ! ! *** set the coefficients in the arrays 0 *** ! DO IS = 1, MSC 17/JAN DO ID = 1, MDC IMATLA(ID,IS) = 0. IMATUA(ID,IS) = 0. IMAT5L(ID,IS) = 0. 40.23 IMAT6U(ID,IS) = 0. 40.23 ENDDO ENDDO ! ! set leak coefficient at 0 ! DO ISC = 1, MSC DO IDC = 1, MDC LEAKC1(IDC,ISC) = 0. ENDDO ENDDO ! ! *** set all transport coeff at 0 *** ! TRAC0(1:MDC,1:MSC,1:MTRNP) = 0. 40.85 TRAC1(1:MDC,1:MSC,1:MTRNP) = 0. 40.85 ! !TIMG CALL SWTSTA(140) 40.23 ! ! *** Call propagation module in X-Y space *** ! ! --- depending on PROPSL, call STRSXY or other scheme 33.10 IF (PROPSL.EQ.3) THEN ! use S&L scheme CALL SANDL(ISSTOP ,IDCMIN ,IDCMAX ,CGO ,CAX , 33.09 & CAY ,AC2 ,AC1 ,IMATRA ,IMATDA , 33.09 & RDX ,RDY ,CAX1 ,CAY1 ,SPCDIR , 33.09 & TRAC0 ,TRAC1 ) 40.85 ELSE IF (PROPSL.EQ.2) THEN ! use SORDUP scheme 33.10 CALL SORDUP(ISSTOP ,IDCMIN ,IDCMAX ,CAX , 33.10 & CAY ,AC2 ,IMATRA ,IMATDA , 33.10 & RDX ,RDY ,TRAC0 ,TRAC1 ) 40.85 33.10 ELSE ! use BSBT scheme CALL STRSXY(ISSTOP ,IDCMIN ,IDCMAX ,CAX , 40.00 & CAY ,AC2 ,AC1 ,IMATRA ,IMATDA , & RDX ,RDY , 40.00 & OBREDF ,TRAC0 ,TRAC1 ) 40.85 40.00 ! END IF 33.08 !TIMG CALL SWTSTO(140) 40.23 ! ! *** test output *** ! IF ( TESTFL .AND. ITEST .GE. 120 ) THEN WRITE(PRINTF,111) KCGRD(1) 111 FORMAT(' ACTION POINT :',I5) WRITE(PRINTF,*) WRITE(PRINTF,*) ' matrix coefficients in action after strs(x-y)' WRITE(PRINTF,*) WRITE(PRINTF,*) & ' IS ID IMAT5L IMATDA IMAT6U IMATRA CAS' DO IDDUM = IDDLOW, IDDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IF (ISCMIN(ID).GT.0) THEN DO IS = ISCMIN(ID), ISCMAX(ID) WRITE(PRINTF,2101) IS, ID, IMAT5L(ID,IS),IMATDA(ID,IS), & IMAT6U(ID,IS),IMATRA(ID,IS),CAS(ID,IS,1) 2101 FORMAT(1X,2I4,4X,4E12.4,E10.2) ENDDO ENDIF ENDDO END IF ! !TIMG CALL SWTSTA(141) 40.23 IF ( (DYNDEP .OR. ICUR.EQ.1) .AND. ITFRE.NE.0 ) THEN 40.41 40.00 ! ! *** call propagation module in S-direction *** ! IF ( INT(PNUMS(8)) .EQ. 1 ) THEN ! ! *** use implicit scheme for the integration in frequency *** ! *** space (no a priori assumptions) *** ! CALL STRSSI (SPCSIG , & CAS ,IMAT5L ,IMATDA ,IMAT6U ,ANYBIN , & IMATRA ,AC2 ,ISCMIN ,ISCMAX ,IDDLOW , & IDDTOP ,TRAC0 ,TRAC1 ) 40.85 40.41 30.21 ! ELSE IF ( INT(PNUMS(8)) .EQ. 2 ) THEN ! ! *** Explicit numerical scheme in frequency space *** ! *** based on flux transport of action across *** ! *** boundaries. Energy is removed from the spectrum *** ! *** based on a CFL criterion *** ! CALL STRSSB (IDDLOW ,IDDTOP , & IDCMIN ,IDCMAX ,ISSTOP ,CAX ,CAY , & CAS ,AC2 ,SPCSIG ,IMATRA , & ANYBLK ,RDX ,RDY ,TRAC0 ) 41.07 40.41 30.21 ! END IF END IF !TIMG CALL SWTSTO(141) 40.23 ! ! *** call propagation module in D-direction *** ! !TIMG CALL SWTSTA(142) 40.23 IF ( IREFR.NE.0 ) THEN 40.41 IF ( PROPFL.EQ.0 ) THEN 40.23 CALL STRSD (DDIR ,IDCMIN , & IDCMAX ,CAD ,IMATLA ,IMATDA ,IMATUA , & IMATRA ,AC2 ,ISSTOP , & ANYBIN ,LEAKC1 ,TRAC0 ,TRAC1 ) 40.85 40.41 30.21 ELSE IF ( PROPFL.EQ.1 ) THEN 40.23 CALL SWFLXD (CAD, IMATLA, IMATDA, IMATUA, IMATRA, 40.23 & AC2, DDIR, ANYBIN, LEAKC1, IDCMIN, 40.23 & IDCMAX, ISSTOP) 40.23 END IF 40.23 END IF 40.41 !TIMG CALL SWTSTO(142) 40.23 ! ! *** test; remove on vector computer *** ! IF ( TESTFL .AND. ITEST .GE. 70 ) THEN WRITE(PRINTF,*) ' *** Values at end of subroutine action ***' WRITE (PRINTF,6120) KCGRD(1), MCGRD, MSC, MDC 6120 FORMAT (' ACTION: POINT MCGRD MSC MDC : ',4I5) WRITE (PRINTF,6220) IDDLOW,IDDTOP,ISSTOP, ICMAX 6220 FORMAT (' ACTION: IDLW IDTP ISTOP ICMAX : ',4I4) WRITE (PRINTF,6020) KCGRD(1), KCGRD(2), KCGRD(3) 6020 FORMAT (' ACTION: KCGRD(1), KCGRD(2), KCGRD(3) : ',3I4) WRITE (PRINTF,6022) RDX(1), RDX(2), RDY(1), RDY(2) 6022 FORMAT (' ACTION:RDX(1) RDX(2) RDY(1) RDY(2) : ',4E12.4) IF (ITEST.GE.210) THEN 40.00 DO IS = 1, MSC WRITE(PRINTF,6420) SPCSIG(IS),IDCMIN(IS),IDCMAX(IS) 30.72 6420 FORMAT (' ACTION: SPCSIG IDCMIN IDCMAX : ',F8.4,2I6) 30.72 ENDDO DO IS = 1, MSC WRITE(PRINTF,*) 'IS ',IS DO ID = 1, MDC WRITE(PRINTF,6320) ID, CAX(ID,IS,1), CAY(ID,IS,1), & CAS(ID,IS,1), CAD(ID,IS,1), AC2(ID,IS,KCGRD(1)) 6320 FORMAT(' ACTION: ID CAX CAY CAS CAD AC2:',I3,5E12.4) ENDDO ENDDO ENDIF 40.00 WRITE(PRINTF,*) ' *** end of subr ACTION *** ' 40.00 END IF ! End of subroutine ACTION RETURN END !**************************************************************** ! SUBROUTINE SINTGRL(SPCDIR ,KWAVE ,AC2 , 40.02 & DEP2 ,QB_LOC ,URSELL , 40.02 & RDX ,RDY , 40.02 & AC2TOT ,ETOT , 40.02 & ABRBOT ,UBOT ,HS ,QB , 40.02 & HM ,KMESPC ,SMEBRK ,KTETA , 41.47 40.02 & TMBOT ,BOTLV ,GAMBR ,RESPL , 41.38 40.51 40.16 & SWPDIR , 41.38 & URMSTOP , 40.88 & IDDLOW ,IDDTOP ) 41.38 ! !**************************************************************** ! USE OCPCOMM4 40.41 USE SWCOMM1 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE M_WCAP ! IMPLICIT NONE ! ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.02: IJsbrand Haagsma ! 40.08: Erick Rogers ! 40.13: Nico Booij ! 40.16: IJsbrand Haagsma ! 40.22: John Cazes and Tim Campbell ! 40.41: Marcel Zijlema ! 40.51: Marcel Zijlema ! 41.38: James Salmon ! ! 1. Updates ! ! 40.02, Jan. 00: New, based on the old SDISPA subroutine ! 40.02, Oct. 00: KWAVE removed in call BRKPAR ! 40.13, Aug. 01: reduction of spectrum not for Mode Noupdate ! 40.22, Sep. 01: Changed array definitions to use the parameter 40.22 ! MICMAX instead of ICMAX. 40.22 ! 40.22, Sep. 01: Changed allocated arrays to static arrays to fix 40.22 ! OpenMP problems with arrays allocated in parallel 40.22 ! regions. 40.22 ! 40.22, Oct. 01: PSURF(2) is no longer used as a variable ! 40.16, Dec. 01: Implemented limiter switches ! 40.08, Mar. 03: Dimensioning of RDX, RDX changed to be consistent ! with other subroutines ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! 40.51, Feb. 05: near bottom wave period added ! 41.38, Apr. 12: extension to nkd scaling ! ! 2. Purpose ! ! To compute several integrals used in SWAN and some general parameters ! ! 3. Method ! ! The total energy ETOT is calculate as the following integral ! ! ETOT = Integrate [ AC2(theta,sigma) sigma dsigma dtheta ] ! ! To avoid too high dissipation by breaking, ETOT is maximised by a maximum ! total energy EMAX based on the maximum wave heigth HM: ! ! HM = PSURF(2) depth ! ! 2 ! EMAX = 0.25 * HM ! ! When EMAX > ETOT, then the action density AC2 is reduced by EMAX/ETOT ! ! In the physicaly unrealistic case that ETOT <= 0, the integrals and other parameters ! get values that represent a steady sea-state with wind close to zero. ! ! The following integrals are calculated: ! ! 2 ! AB2 = Integrate [ (AC2(theta,sigma) sigma / Sinh [ K(sigma) depth ]) dsigma dtheta ] ! ! ACTOT = Integrate [ AC2(theta,sigma) dsigma dtheta ] ! ! EDRKTOT=Integrate [ (AC2(theta,sigma) sigma / Sqrt [ K(sigma) ]) dsigma dtheta ] ! ! EKTOT = Integrate [ AC2(theta,sigma) K(sigma) sigma dsigma dtheta ] ! ! 2 ! ETOT1 = Integrate [ AC2(theta,sigma) sigma dsigma dtheta ] ! ! 3 ! ETOT2 = Integrate [ AC2(theta,sigma) sigma dsigma dtheta ] ! ! 5 ! ETOT4 = Integrate [ AC2(theta,sigma) sigma dsigma dtheta ] ! ! 3 2 ! UB2 = Integrate [ (AC2(theta,sigma) sigma / Sinh [ K(sigma) depth ]) dsigma dtheta ] ! ! For reasons of ??, in the calculation of UB2, AB2, ETOTM2, ETOTM4, the high frequency ! tail is ignored. ! ! Based on these integrals the following parameters are calculated: ! ! ABRBOT = Sqrt [ 2 AB2 ] ! HS = 4 Sqrt [ ETOT ] ! 2 ! KM_WAM = (ETOT / EDRKTOT) ! QB : computed in the subroutine FRABRE ! SIGM01 = ETOT1 / ETOT ! SIGM_10 = ETOT / ACTOT ! UBOT = Sqrt [ UB2 ] NOTE: THIS IS THE ROOT MEAN SQUARE OF THE ORBITAL MOTION NEAR THE BOTTOM!!! ! TMBOT = 2 PI Sqrt [ AB2 / UB2 ] ! ! 4. Argument variables ! ! ABRBOT: Near bottom excursion ! AC2 : Action density as function of ID, IS, IX and IY ! AC2TOT: Total action density per gridpoint ! BOTLV : Bottom depth ! DEP2 : Water depth ! ETOT : Total wave energy density ! GAMBR : breaker parameter as function of IX and IY ! HM : Maximum wave height ! HS : Significant wave height ! KMESPC: Mean average wavenumber according to the WAM-formulation ! KTETA : number of directional partitions 41.47 ! KWAVE : Wavenumber ! QB : Fraction of breaking waves ! QB_LOC: Fraction of breaking waves at current grid-point ! RESPL : response length ! SMEBRK: Mean frequency according to first order moment ! SWPDIR: Number of current sweep direction 40.16 ! UBOT : Near bottom velocity as function of IX and IY ! URSELL: Ursell number as function of IX and IY ! TMBOT : near bottom wave period 40.51 INTEGER, INTENT(IN) :: SWPDIR 40.16 INTEGER, INTENT(IN) :: IDDLOW, IDDTOP 41.38 REAL, INTENT(IN) :: DEP2(MCGRD), BOTLV(MCGRD) REAL, INTENT(INOUT) :: GAMBR(MCGRD), RESPL(MCGRD) 41.38 ! Changed ICMAX to MICMAX, since MICMAX doesn't vary over gridpoint 40.22 REAL, INTENT(IN) :: KWAVE(MSC,MICMAX) 40.22 REAL, INTENT(IN) :: RDX(MICMAX), RDY(MICMAX) 40.08 REAL, INTENT(IN) :: SPCDIR(MDC,6) ! REAL, INTENT(IN OUT) :: AC2(MDC,MSC,MCGRD) REAL, INTENT(IN OUT) :: QB(MCGRD) REAL, INTENT(IN OUT) :: UBOT(MCGRD) REAL, INTENT(IN OUT) :: URMSTOP(MCGRD) 40.88 REAL, INTENT(IN OUT) :: URSELL(MCGRD) REAL, INTENT(IN OUT) :: TMBOT(MCGRD) 40.51 ! REAL, INTENT(OUT) :: ABRBOT, ETOT, HM, HS, QB_LOC REAL, INTENT(OUT) :: AC2TOT, KMESPC, SMEBRK, KTETA ! ! 6. Local variables ! ! IENT : Number of entries in this subroutine ! IS : Counter for the relative frequency band ! INTEGER, SAVE :: IENT = 0 ! ! AB2 : Sum of E_DSHKD2_DS_DD ! ACTOT_DSIG : Integration term for calculating ACTOT ! ARR : auxiliary array ! EDRKTOT_SWELL : Swell-part of EDRKTOT ! EMAX : Maximum energy according calculated HM ! ETOT_DRK_DSIG : Integration term for calculating EDRKTOT ! ETOT_K_DSIG : Integration term for calculating EKTOT ! ETOT_DSHKD2_DSIG : Integration term for calculating AB2 ! ETOT_DSIG : Integration term for calculating ETOT ! ETOT_SIG_DSIG : Integration term for calculating ETOT1 ! ETOT_SIG2_DSIG : Integration term for calculating ETOT2 ! ETOT_SIG2_DSHKD2_DSIG: Integration term for calculating UB2 ! ETOT_SIG4_DSIG : Integration term for calculating ETOT4 ! ETOT_SIG_2_DSIG : Integration term for calculating ETOT_2 ! ETOT_2 : (negative) second moment of the energy density ! FRINT_X_DDIR : FRINTF * DDIR ! KLOC : help variable to compute wave number based on sigma0,-2 ! SINH_K_X_DEP_2 : SINH(KWAVE*DEP2)**2 ! UB2 : Sum of ETOT_SIG2_DSHKD2_DSIG ! WH : fraction of breaking waves ! REAL :: AB2, EMAX, UB2, ETOT_2, KLOC(1), ARR(1) REAL :: WH REAL :: FRINTF_X_DDIR REAL :: BRCOEF ! variable breaking coefficient (calc. in BRKPAR) 40.22 REAL :: UT2 40.88 ! REAL :: ETOT_DSIG(MSC) 40.22 REAL :: ACTOT_DSIG(MSC), ETOT_DSHKD2_DSIG(MSC) 40.22 REAL :: ETOT_DRK_DSIG(MSC), ETOT_SIG2_DSIG(MSC) 40.22 REAL :: ETOT_K_DSIG(MSC), ETOT_SIG_DSIG(MSC) 40.22 REAL :: ETOT_SIG2_DSHKD2_DSIG(MSC) 40.22 REAL :: ETOT_SIG2_DTHKD2_DSIG(MSC) 40.88 REAL :: ETOT_SIG4_DSIG(MSC) 40.22 REAL :: SINH_K_X_DEP_2(MSC) 40.22 REAL :: TANH_K_X_DEP_2(MSC) 40.88 REAL :: ETOT_SIG_2_DSIG(MSC) 41.38 ! ! 9. STRUCTURE ! ! ---------------------------------------------------------- ! Determine ETOT ! If energy level is too large compared with depth ! Then reduce action densities ! ------------------------------------------------------ ! For all spectral frequencies do ! determine wavenumber K and K*depth ! For every spectral direction do ! add AC2 to sum of action densities ! -------------------------------------------------- ! add contributions to various moments of energy density ! --------------------------------------------------------- ! add tail contributions ! determine average frequency and wavenumber ! ---------------------------------------------------------- ! If B&J surf breaking is used ! Then call FRABRE to compute fraction of breaking waves ! ---------------------------------------------------------- ! determine orbital motion near the bottom ! ---------------------------------------------------------- ! ! 13. Source text: ! IF (LTRACE) CALL STRACE (IENT,'SINTGRL') ! ! Initialisation ! KM_WAM = 10. KM01 = 10. ! SIGM01 = 10. SIGM_10 = 10. ! HS = 0. HM = 0.1 ! QB(KCGRD(1)) = 0. ABRBOT = 0.001 UBOT(KCGRD(1)) = 0. URMSTOP(KCGRD(1)) = 0. TMBOT(KCGRD(1))= 0. ! ! Calculate total spectral energy ! FRINTF_X_DDIR = FRINTF * DDIR ETOT_DSIG(:) = SUM(AC2(:,:,KCGRD(1)),DIM=1) * SIGPOW(:,2) * & FRINTF_X_DDIR ETOT = SUM(ETOT_DSIG) ! ! *** add high frequency tail *** ! ETOT = ETOT + ETOT_DSIG(MSC) * PWTAIL(6) / FRINTF ! ! --- compute maximum energy based on maximum wave height ! EMAX = 0.25 * ( PSURF(2) * DEP2(KCGRD(1)) )**2 ! ! --- reduce action density if necessary ! IF (ACUPDA .AND. ETOT .GT. EMAX .AND. ISURF .GE. 1) THEN 40.13 AC2(:,:,KCGRD(1)) = MAX(0.,(EMAX/ETOT)*AC2(:,:,KCGRD(1))) ! IF (TESTFL.AND.ITEST.GE.80) & WRITE (PRTEST,7) DEP2(KCGRD(1)), EMAX, ETOT 7 FORMAT (' energy is reduced in SINTGRL', 4(1x, e12.4)) ! ! Correct value for ETOT ! ETOT = EMAX ! ENDIF ! IF ( ETOT .GT. 0. ) THEN ! ! Calculate all other integrals ! ! SINH_K_X_DEP_2(:) = SINH(MIN(30., & KWAVE(:,1)*DEP2(KCGRD(1))) & )**2 TANH_K_X_DEP_2(:) = TANH(MIN(30., & KWAVE(:,1)*DEP2(KCGRD(1))) & )**2 ACTOT_DSIG(:) = SUM(AC2(:,:,KCGRD(1)),DIM=1) * & SIGPOW(:,1) * FRINTF_X_DDIR ETOT_SIG_DSIG(:) = ACTOT_DSIG(:) * SIGPOW(:,2) ETOT_SIG2_DSIG(:) = ACTOT_DSIG(:) * SIGPOW(:,3) ETOT_SIG4_DSIG(:) = ACTOT_DSIG(:) * SIGPOW(:,5) ETOT_SIG_2_DSIG(:) = ACTOT_DSIG(:) / SIGPOW(:,1) 41.38 ETOT_DRK_DSIG(:) = ETOT_DSIG(:) / SQRT(KWAVE(:,1)) ETOT_K_DSIG(:) = ETOT_DSIG(:) * KWAVE(:,1) ETOT_DSHKD2_DSIG(:) = ETOT_DSIG(:) / SINH_K_X_DEP_2(:) ETOT_SIG2_DSHKD2_DSIG(:) = ETOT_SIG2_DSIG(:) / SINH_K_X_DEP_2(:) ETOT_SIG2_DTHKD2_DSIG(:) = ETOT_SIG2_DSIG(:) / TANH_K_X_DEP_2(:) 40.88 ! ACTOT = SUM(ACTOT_DSIG) ETOT1 = SUM(ETOT_SIG_DSIG) ETOT2 = SUM(ETOT_SIG2_DSIG) ETOT4 = SUM(ETOT_SIG4_DSIG) ETOT_2 = SUM(ETOT_SIG_2_DSIG) 41.38 EDRKTOT = SUM(ETOT_DRK_DSIG) EKTOT = SUM(ETOT_K_DSIG) UB2 = SUM(ETOT_SIG2_DSHKD2_DSIG) UT2 = SUM(ETOT_SIG2_DTHKD2_DSIG) AB2 = SUM(ETOT_DSHKD2_DSIG) ! ! Add high frequency tails ! ACTOT = ACTOT + PWTAIL(5) * ACTOT_DSIG(MSC) / FRINTF ETOT1 = ETOT1 + PWTAIL(7) * ETOT_DSIG(MSC) * & SIGPOW(MSC,1) / FRINTF ETOT_2 = ETOT_2 + PWTAIL(4) * ACTOT_DSIG(MSC) / 41.38 & SIGPOW(MSC,1) / FRINTF 41.38 EDRKTOT = EDRKTOT + PWTAIL(5) * ETOT_DSIG(MSC) / & (SQRT(KWAVE(MSC,1)) * FRINTF) EKTOT = EKTOT + PWTAIL(8) * ETOT_DSIG(MSC) * & KWAVE(MSC,1) / FRINTF ! ! Calculate the mean frequencies SIGM01 and SIGM_10, ! mean wavenumbers KM_WAM, KM01 and significant waveheight HS ! IF (ETOT1 .GT. 0.) SIGM01 = ETOT1 / ETOT IF (EKTOT .GT. 0.) KM01 = EKTOT / ETOT IF (ACTOT .GT. 0.) SIGM_10 = ETOT / ACTOT IF (EDRKTOT .GT. 0. ) THEN KM_WAM = ( ETOT / EDRKTOT )**2. SIGM_WAM = SQRT(GRAV*KM_WAM*TANH(KM_WAM*DEP2(KCGRD(1)))) 41.47 ENDIF IF ( ETOT .GT. 1.E-20 ) THEN HS = 4. * SQRT (ETOT) END IF ! ! Calculate the orbital velocity UBOT, orbital excursion ABRBOT and ! near bottom wave period TMBOT 40.51 ! IF ( UB2 .GT. 0.) UBOT(KCGRD(1)) = SQRT ( UB2 ) IF ( AB2 .GT. 0.) ABRBOT = SQRT (2. * AB2) IF ( UB2 .GT. 0. .AND. AB2 .GT. 0. ) 40.51 & TMBOT(KCGRD(1)) = PI2*SQRT(AB2/UB2) 40.51 IF ( UT2 .GT. 0.) URMSTOP(KCGRD(1)) = SQRT ( 2. * UT2 ) 40.88 ! ENDIF ! ! --- compute actual maximum wave height based on breaking model ! include wave directionality, if appropriate 41.47 ! IF ( ISURF.GT.0 ) THEN ! compute some parameters for breaker models CALL BRKPAR (BRCOEF, SPCDIR(1,2), SPCDIR(1,3), AC2, & SIGPOW(:,1), DEP2, BOTLV, GAMBR, RESPL, 41.38 & RDX, RDY, KWAVE, IDDLOW, IDDTOP, SPCDIR(1,1), 41.38 41.03 40.22 & KTETA ) 41.47 HM = BRCOEF * DEP2(KCGRD(1)) 40.22 ELSE ! breaking disabled, assign very high value to HM HM = 100. 40.22 ENDIF ! ! --- calculate fraction of breakers ! IF ( ETOT .GT. 0. ) THEN ! ! --- calculate Qb when Battjes/Janssen breaking is activated ! IF ( ISURF.NE.4 41.38 & ) THEN CALL FRABRE (HM, ETOT, QB(KCGRD(1)), KTETA) 41.47 ! ! --- calculate Qb when Thornton/Guza breaking is activated 41.03 ! ELSEIF (ISURF.EQ.4) THEN WH = (2.*SQRT(2.*ETOT)/HM)**PSURF(5) WH = MIN(1.,WH) QB(KCGRD(1)) = WH ENDIF ! ENDIF ! ! *** calculate Ursell number *** ! *** update only for first encounter in a sweep 40.16 ! IF ( ITRIAD.GT.0 40.41 & ) THEN 40.41 IF (( SWPDIR .EQ. 1) .OR. 40.16 & ( SWPDIR .EQ. 2 .AND. IXCGRD(1) .EQ. 1) .OR. 40.16 & ( SWPDIR .EQ. 3 .AND. IYCGRD(1) .EQ. 1) .OR. 40.16 & ( SWPDIR .EQ. 4 .AND. 40.16 & (IXCGRD(1).EQ.MXC .AND. IYCGRD(1).EQ.1) )) THEN 40.16 URSELL(KCGRD(1)) = (GRAV*HS) / & (2.*SQRT(2.)*SIGM01**2*DEP2(KCGRD(1))**2) ENDIF 40.16 ELSE 40.41 URSELL(KCGRD(1)) = 0. 40.41 END IF 40.41 ! QB_LOC = QB(KCGRD(1)) ! ! *** test output *** ! IF (TESTFL .AND. ITEST.GE.60) THEN WRITE(PRTEST, 901) ETOT, HS, SIGM_10, KM_WAM, ABRBOT 901 FORMAT (' SINTGRL: ETOT Hs Sigma K Aorb', 5(1X, E11.4)) END IF ! ! Set variables used outside the whitecapping scope ! AC2TOT = ACTOT KMESPC = KM_WAM SMEBRK = SIGM01 ! RETURN ! END SUBROUTINE SINTGRL ! !**************************************************************** ! SUBROUTINE SOLPRE (AC2 ,AC2OLD , 40.00 & IMATRA ,IMATLA , & IMATDA ,IMATUA , & IMAT5L ,IMAT6U , & IDCMIN ,IDCMAX , & ANYBIN , & IDTOT ,ISTOT , & IDDLOW ,IDDTOP , & ISSTOP , & SPCSIG ) 40.41 40.23 ! !**************************************************************** ! USE SWCOMM2 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE OCPCOMM4 40.41 USE M_PARALL 40.31 ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.00: Nico Booij ! 40.23: Marcel Zijlema ! 40.30: Marcel Zijlema ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 40.00, Feb. 99: New subroutine common tasks before solution of linear ! system (software moved from SOLBAND, SOLMAT and SOLMT1) ! 40.23, Aug. 02: implementation of under-relaxation technique ! 40.30, Mar. 03: correcting indices of test point with offsets MXF, MYF ! 40.41, Aug. 04: code optimized ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! Copy local spectrum to array AC2OLD before solving system, ! apply under-relaxation approach in active bins, fill matrix ! arrays for non-active bins and write test output ! ! 3. Method ! ! --- ! ! 4. Argument variables ! ! one and more dimensional arrays: ! --------------------------------- ! AC2 4D Action density as function of D,S,X,Y and T ! AC2OLD 2D Values of action density at previous iteration ! IMATDA 2D Coefficients of diagonal of matrix ! IMATLA 2D Coefficients of lower diagonal of matrix ! IMATUA 2D Coefficients of upper diagonal of matrix ! IMATRA 2D Coefficients of right hand side of matrix ! IMAT5L 2D Coefficients for implicit calculation in ! frequency space (lower diagonal) ! IMAT6U 2D Coefficients for implicit calculation in ! frequency space (upper diagonal) ! SPCSIG 1D Relative frequencies in sigma-space ! REAL AC2(MDC,MSC,MCGRD) , & IMATRA(MDC,MSC) , & IMATLA(MDC,MSC) , & IMATDA(MDC,MSC) , & IMATUA(MDC,MSC) , & IMAT5L(MDC,MSC) , & IMAT6U(MDC,MSC) , & AC2OLD(MDC,MSC) , & SPCSIG(MSC) ! ! IDCMIN 1D Integer array containing minimum counter ! IDCMAX 1D Integer array containing maximum counter ! INTEGER IDCMIN(MSC) , & IDCMAX(MSC) ! ! ANYBIN 2D Logical array. if a certain bin is enclosed ! in a sweep then ANYBIN is TRUE . array is ! used to determine whether some coefficients ! in the array have to be changed ! LOGICAL ANYBIN(MDC,MSC) ! ! 7. Common blocks used ! ! ! 5. SUBROUTINES CALLING ! ! SWOMPU ! ! 6. SUBROUTINES USED ! ! NONE ! ! 7. ERROR MESSAGES ! ! --- ! ! 8. REMARKS ! ! ! 9. STRUCTURE ! ! ! 10. SOURCE ! !************************************************************************ ! INTEGER IS ,ID ,IDDUM , & IDDLOW , & IDDTOP ,IDTOT ,ISTOT ,ISSTOP REAL ALFA 40.23 ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SOLPRE') ! ! --- apply under-relaxation approach, if requested ! ALFA = PNUMS(30) 40.41 IF (ALFA.GT.0. .AND. NSTATC.EQ.0) THEN 40.41 DO IS = 1, ISSTOP DO IDDUM = IDCMIN(IS), IDCMAX(IS) ID = MOD(IDDUM-1 + MDC, MDC) + 1 IMATDA(ID,IS) = IMATDA(ID,IS) + ALFA*SPCSIG(IS) 40.23 IMATRA(ID,IS) = IMATRA(ID,IS) + ALFA*SPCSIG(IS)* 40.23 & AC2(ID,IS,KCGRD(1)) 40.23 END DO END DO END IF ! ! --- when ambient currents are involved or when the spectral space ! is not a circular one (use SECTOR instead of CIRCLE in command ! CGRID), some bins do not fall within the current sweep (in ! particular, when SECTOR = 0 or 4 i.c. ICUR=1 or SECTOR = 4 i.c. ! FULCIR=.FALSE., see routine SWPSEL for meaning of SECTOR). For ! such bins, the corresponding rows in the matrix are reset such ! that the solution AC2 does not change: the main diagonal is set ! to 1, the off-diagonals are set to 0 and the righ-hand side is ! set to AC2. ! IF ( ICUR.EQ.1 .OR. .NOT.FULCIR ) THEN 40.41 DO IS = 1, MSC DO ID = 1, MDC IF ( .NOT. ANYBIN(ID,IS) ) THEN IMATLA(ID,IS) = 0. IMATDA(ID,IS) = 1. IMATUA(ID,IS) = 0. IMATRA(ID,IS) = AC2(ID,IS,KCGRD(1)) 30.21 IMAT5L(ID,IS) = 0. IMAT6U(ID,IS) = 0. END IF ENDDO ENDDO END IF ! ! *** the action density is stored in an auxiliary array AC2OLD *** ! DO IS = 1, MSC DO ID = 1, MDC AC2OLD(ID,IS) = AC2(ID,IS,KCGRD(1)) ENDDO ENDDO ! ! *** test output *** ! IF ( TESTFL .AND. ITEST .GE. 70 ) THEN WRITE (PRINTF,6120) IXCGRD(1)+MXF-2, IYCGRD(1)+MYF-2 40.30 6120 FORMAT (' SOLPRE: Matrix values for point:', 2I5) WRITE (PRINTF,6121) 6121 FORMAT (' bin diagonal r.h.s. ID-1 ID+1', & ' IS-1 IS+1') ! DO IS = 1, ISSTOP ID_MIN = IDCMIN(IS) ID_MAX = IDCMAX(IS) DO IDDUM = ID_MIN, ID_MAX ID = MOD(IDDUM-1 + MDC, MDC) + 1 IF ( DYNDEP .OR. ICUR .EQ. 1 ) THEN 40.00 WRITE(PRINTF,6620) ID, IS, IMATDA(ID,IS), IMATRA(ID,IS), & IMATLA(ID,IS), IMATUA(ID,IS), IMAT5L(ID,IS), IMAT6U(ID,IS) 6620 FORMAT(2I3,6(1X,E12.4)) ELSE WRITE(PRINTF,6620) ID, IS, IMATDA(ID,IS), IMATRA(ID,IS), & IMATLA(ID,IS), IMATUA(ID,IS) ENDIF ENDDO ENDDO END IF ! RETURN END ! !**************************************************************** ! SUBROUTINE SOLMAT (IDCMIN ,IDCMAX , 40.00 & AC2 ,IMATRA , & IMATDA ,IMATUA , & IMATLA 40.23 & ) ! !**************************************************************** USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE OCPCOMM4 40.41 USE M_PARALL 40.31 ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.72: IJsbrand Haagsma ! 40.30: Marcel Zijlema ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 40.00, Feb. 99: swcomm3 introduced ! 40.30, Mar. 03: correcting indices of test point with offsets MXF, MYF ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! SUBROUTINE to solve the linear system which is filled in the ! subroutine ACTION. The solution give the values for the ! wave action for every frequency and every direction. ! The system is solved by means of the Thomas sweep algorithm ! in the spectral direction only. ! ! 3. Method ! ! Solver for tri-diagonal matrix: ! ! ! / 2 3 \ / \ ! | 1 2 3 | | | ! | 1 2 3 | | N | = RHS ! | 1 2 3 | | | ! \ 1 2 / \ / ! ! ! This method consists of forward and backward sweeps. ! ! 4. Argument variables ! ! ! IX Counter of gridpoints in x-direction ! IY Counter of gridpoints in y-direction ! IS Counter of relative frequency band ! ID Counter of directional distribution ! J Dummy counter ! MXC Maximum counter of gridppoints in x-direction ! MYC Maximum counter of gridppoints in y-direction ! MSC Maximum counter of relative frequency ! MDC Maximum counter of directional distribution ! ! REALS: ! --------- ! ! SP Dummy variable ! TEMP Dummy variable ! ! one and more dimensional arrays: ! --------------------------------- ! AC2 4D Action density as function of D,S,X,Y and T ! IMATDA 2D Coefficients of diagonal of matrix ! IMATLA 2D Coefficients of lower diagonal of matrix ! IMATUA 2D Coefficients of upper diagonal of matrix ! IMATRA 2D Coefficients of right hand side of matrix ! IDCMIN 1D Integer array containing minimum counter ! IDCMAX 1D Integer array containing maximum counter ! ! 7. Common blocks used ! ! ! 8. Subroutines used ! ! --- ! ! 9. Subroutines calling ! ! SWOMPU ! ! 10. Error messages ! ! --- ! ! 11. Remarks ! ! --- ! ! 12. Structure ! ! ------------------------------------------------------------- ! For every D-direction within the sector do ! Eliminate the lower diagonal ! ------------------------------------------------------------- ! For every D-direction within the sector do ! Solve the linear equation to get the wave action for every ! direction (ID) ! ------------------------------------------------------------- ! Set all the values in the arrays to zero: ! IMATRA(MDC,MSC),IMATLA(MDC,MSC),IMATDA(MDC,MSC),IMATUA(MDC,MSC) ! ------------------------------------------------------------ ! ! 13. Source text ! ! INTEGER IS ,ID ,J ,ID_MIN ,ID_MAX 40.00 ! REAL SP ,TEMP 40.23 ! REAL AC2(MDC,MSC,MCGRD) , & IMATRA(MDC,MSC) , & IMATLA(MDC,MSC) , & IMATDA(MDC,MSC) , & IMATUA(MDC,MSC) ! INTEGER IDCMIN(MSC) , & IDCMAX(MSC) ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SOLMAT') ! ! **** 17/JAN IN MOD ( , ) ; + MDC WAS ADDED **** ! DO 180 IS = 1, MSC ID_MIN = IDCMIN(IS) 3/MAR ID_MAX = IDCMAX(IS) 3/MAR ! ! *** elimination of the lower diagonal of the first matrix *** ! DO 100 IDDUM = (ID_MIN+1), ID_MAX 20.43 ID = MOD(IDDUM-1+MDC, MDC) + 1 17/JAN IDM1 = MOD(IDDUM-2+MDC, MDC) + 1 17/JAN SP = IMATDA(IDM1,IS) 20.43 IF ( ABS(SP) .LE. 1.E-20 ) THEN TEMP = IMATLA(ID,IS) / SIGN( 1.E-20 , SP) ELSE TEMP = IMATLA(ID,IS) / SP END IF IMATDA(ID,IS) = IMATDA(ID,IS) - TEMP * IMATUA(IDM1,IS) 20.43 IMATRA(ID,IS) = IMATRA(ID,IS) - TEMP * IMATRA(IDM1,IS) 20.43 100 CONTINUE ! ! *** solving of the linear equations for the wave action *** ! ! *** first for ID_MAX, then for the others *** ! ID = MOD(ID_MAX-1+MDC, MDC) + 1 17/JAN SP = IMATDA(ID,IS) IF ( ABS(SP) .LE. 1.E-20 ) THEN TEMP = SIGN (1.E-20 , SP) ELSE TEMP = SP END IF ! ! *** wave action for ID_MAX *** ! AC2(ID,IS,KCGRD(1)) = IMATRA(ID,IS) / TEMP ! DO 150 J = 1, (ID_MAX-ID_MIN) ID = MOD(ID_MAX-J-1+MDC, MDC) +1 17/JAN IDP1 = MOD(ID_MAX-J+MDC, MDC) +1 17/JAN SP = IMATDA(ID,IS) IF ( ABS(SP) .LE. 1.E-20 ) THEN TEMP = SIGN (1.E-20 , SP) ELSE TEMP = SP END IF AC2(ID,IS,KCGRD(1)) = ( IMATRA(ID,IS) - IMATUA(ID,IS) * & AC2(IDP1,IS,KCGRD(1)) ) / TEMP 20. ! 150 CONTINUE ! IF ( ITEST .GE. 120 .AND. TESTFL ) THEN WRITE(PRINTF,6009) KCGRD(1),ID_MIN,ID_MAX 6009 FORMAT(' SOLMAT: POINT ID_MIN ID_MAX :',3I5) DO 169 IDDUM = ID_MIN, ID_MAX ID = MOD(IDDUM-1+MDC, MDC) + 1 17/ WRITE (PRINTF,6010) IS,ID,AC2(ID,IS,KCGRD(1)) 6010 FORMAT(' IS ID AC2() :',2I5,2X,E12.4) 169 CONTINUE END IF ! 180 CONTINUE ! ! *** set all the coefficients in the arrays 0 *** ! DO IS = 1, MSC DO ID = 1, MDC IMATRA(ID,IS) = 0. IMATDA(ID,IS) = 0. ENDDO ENDDO ! IF ( TESTFL .AND. ITEST.GE. 40 ) THEN WRITE (PRINTF,6020) IXCGRD(1)+MXF-2, IYCGRD(1)+MYF-2 6020 FORMAT(' SOLMAT: point :',2I5) WRITE(PRINTF,*) END IF ! ! End of the subroutine SOLMAT ! RETURN END ! !**************************************************************** ! SUBROUTINE SOLMT1 (IDCMIN ,IDCMAX , 40.00 & AC2 ,IMATRA , & IMATDA ,IMATUA , & IMATLA , 40.23 & ISSTOP , 40.41 40.23 & ANYBLK ,IDDLOW , & IDDTOP ) ! !**************************************************************** ! USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE OCPCOMM4 40.41 ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.72: IJsbrand Haagsma ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 40.00, Feb. 99: swcomm3 introduced ! 40.41, Aug. 04: array SECTOR removed and some corrections if SECTOR=0 ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! subroutine to solve the linear system which is filled in the ! subroutines ACTION and SOURCE. The solution give the values ! for the wave action for every frequency and every direction. ! Ambient currents are involved and the propagation term in 40.41 ! frequency space is discretized explicitly. 40.41 ! The system is solved by means of the Thomas sweep algorithm ! in the spectral direction only. ! ! 3. Method ! ! Solver for tridiagonal matrix with a possible coefficient ! at the bottom left position and top right position due ! to periodicity in theta-space: ! ! ! / 2 3 1 \ / \ ! | 1 2 3 | | | ! | 1 2 3 | | N | = RHS ! | 1 2 3 | | | ! \ 3 1 2 / \ / ! ! ! This method consists of forward and backward sweeps. ! ! 4. Argument variables ! ! ! IX Counter of gridpoints in x-direction ! IY Counter of gridpoints in y-direction ! IS Counter of relative frequency band ! ID Counter of directional distribution ! J Dummy counter ! MXC Maximum counter of gridppoints in x-direction ! MYC Maximum counter of gridppoints in y-direction ! MSC Maximum counter of relative frequency ! MDC Maximum counter of directional distribution ! ! REALS: ! --------- ! ! SP Dummy variable ! TEMP Dummy variable ! ! one and more dimensional arrays: ! --------------------------------- ! AC2 4D Action density as function of D,S,X,Y and T ! IMATDA 2D Coefficients of diagonal of matrix ! IMATLA 2D Coefficients of lower diagonal of matrix ! IMATUA 2D Coefficients of upper diagonal of matrix ! IMATRA 2D Coefficients of right hand side of matrix ! IDCMIN 1D Integer array containing minimum counter ! IDCMAX 1D Integer array containing maximum counter ! ICOLU2 1D In presence of a current the spectral direction can ! be circular and closed. Matrix coefficients appear in ! the top right and bottom left corner of the matrix ! After pivoting --> coefficients are stored in ICOLU2 ! space ! ! 7. Common blocks used ! ! ! 5. SUBROUTINES CALLING ! ! SWOMPU ! ! 6. SUBROUTINES USED ! ! NONE ! ! 7. ERROR MESSAGES ! ! --- ! ! 8. REMARKS ! ! ! 9. STRUCTURE ! ! ------------------------------------------------------------- ! For every D-direction within the sector do ! Eliminate the lower diagonal ! ------------------------------------------------------------- ! For every D-direction within the sector do ! Solve the linear equation to get the wave action for every ! direction (ID) ! ------------------------------------------------------------- ! Set all the values in the arrays to zero: ! IMATRA(MDC,MSC),IMATLA(MDC,MSC),IMATDA(MDC,MSC),IMATUA(MDC,MSC) ! ------------------------------------------------------------ ! End of SOLMT1 ! ------------------------------------------------------------ ! ! 10. SOURCE ! !************************************************************************ ! INTEGER IS ,ID ,J ,IDDUM ,IIDM , & IIDP ,ISSTOP ,IDDTOP ,IDDLOW 40.00 ! REAL SP ,TEMP ,CORMAT ,TEMP1 40.23 ! REAL AC2(MDC,MSC,MCGRD) , 30.21 & IMATRA(MDC,MSC) , & IMATLA(MDC,MSC) , & IMATDA(MDC,MSC) , & IMATUA(MDC,MSC) , & ICOLU2(MDC) ! INTEGER IDCMIN(MSC) , & IDCMAX(MSC) ! LOGICAL ANYBLK(MDC,MSC) ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SOLMT1') ! ! *** since explicit scheme is used and when CFL exceeds CFL max *** ! *** then bin should not be propagated within the current sweep *** ! DO IS = 1, ISSTOP DO IDDUM = IDDLOW, IDDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IF ( ANYBLK(ID,IS) ) THEN IMATLA(ID,IS) = 0. IMATDA(ID,IS) = 1. IMATUA(ID,IS) = 0. IMATRA(ID,IS) = 0. END IF ENDDO ENDDO ! ! *** start process of elimination *** ! DO 180 IS = 1, MSC ! ! *** set values in auxiliary array for last *** ! *** column equal zero *** ! DO ID = 1, MDC ICOLU2(ID) = 0. ENDDO ! IF ( IDCMIN(IS).LE.IDCMAX(IS) ) THEN 40.41 IDLOW = IDCMIN(IS) IDTOP = IDCMAX(IS) ELSE 40.41 IDLOW = 1 IDTOP = MDC END IF 40.41 ! ! *** set values in coefficients in left bottom element *** ! *** and right top element. Situation only occurs if *** ! *** the matrix is solved for all directions *** ! IF ( IDLOW .EQ. 1 .AND. IDTOP .EQ. MDC ) THEN CORMAT = IMATUA(MDC,IS) ICOLU2(1) = IMATLA(1,IS) ELSE CORMAT = 0. ICOLU2(1) = 0. END IF ! ! *** elimination of the lower diagonal of the first matrix *** ! DO 100 IDDUM = (IDLOW+1 ), IDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IIDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 SP = IMATDA(IIDM,IS) IF ( ABS(SP) .LE. 1.E-20 ) THEN TEMP = IMATLA(ID,IS) / SIGN( 1.E-20 , SP) TEMP1 = CORMAT / SIGN(1.E-20 , SP) ELSE TEMP = IMATLA(ID,IS) / SP TEMP1 = CORMAT / SP END IF IMATDA(ID,IS) = IMATDA(ID,IS) - TEMP * IMATUA(IIDM,IS) IMATRA(ID,IS) = IMATRA(ID,IS) - TEMP * IMATRA(IIDM,IS) IMATRA(IDTOP,IS) = IMATRA(IDTOP,IS) - TEMP1 * & IMATRA(IIDM,IS) CORMAT = 0. - TEMP1 * IMATUA(IIDM,IS) ! IF ( IDDUM .LT. (IDTOP-1) ) THEN ICOLU2(ID) = - TEMP * ICOLU2(IIDM) ELSE IMATUA(ID,IS) = IMATUA(ID,IS) - TEMP * ICOLU2(IIDM) END IF IF ( IDDUM .LT. IDTOP ) THEN IMATDA(IDTOP,IS) = IMATDA(IDTOP,IS) - TEMP1 * & ICOLU2(IIDM) ELSE IMATDA(IDTOP,IS) = IMATDA(IDTOP,IS) - TEMP1 * & IMATUA(IIDM,IS) END IF ! 100 CONTINUE ! ! *** solving of the linear equations for the wave action *** ! ! *** first for IDTOP, then for the others *** ! SP = IMATDA(IDTOP,IS) IF ( ABS(SP) .LE. 1.E-20 ) THEN TEMP = SIGN (1.E-20 , SP) ELSE TEMP = SP END IF ! ! *** wave action for IDCMAX *** ! AC2(IDTOP,IS,KCGRD(1)) = IMATRA(IDTOP,IS) / TEMP ! DO 150 J = 1, (IDTOP-IDLOW) IDDUM = IDTOP - J ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IIDP = MOD ( IDDUM + MDC , MDC ) + 1 SP = IMATDA(ID,IS) IF ( ABS(SP) .LE. 1.E-20 ) THEN TEMP = SIGN (1.E-20 , SP) ELSE TEMP = SP END IF AC2(ID,IS,KCGRD(1)) = ( IMATRA(ID,IS) - IMATUA(ID,IS) * 30.21 & AC2(IIDP,IS,KCGRD(1)) - ICOLU2(ID) * & AC2(IDTOP,IS,KCGRD(1)) ) / TEMP 150 CONTINUE ! ! *** extended info for SOLMT1 *** ! IF ( ITEST .GE. 13 .AND. TESTFL ) THEN WRITE(PRINTF,*) 'SOLMT1' WRITE(PRINTF,*) ' matrix coefficients after pivoting ' WRITE(PRINTF,*) WRITE(PRINTF,*) & 'ID IDDUM IMATLA IMATDA IMATUA ICOLU2 IMATRA' DO 2100 IDDUM = IDLOW, IDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 WRITE(PRINTF,2101) ID, IDDUM,IMATLA(ID,IS),IMATDA(ID,IS), & IMATUA(ID,IS),ICOLU2(ID),IMATRA(ID,IS) 2101 FORMAT(2I3,5E12.4) 2100 CONTINUE WRITE(PRINTF,*) DO 2010 IDDUM = IDLOW, IDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 WRITE (PRINTF,6010) IS,ID,AC2(ID,IS,KCGRD(1)) 6010 FORMAT(' IS ID and resolved vector :',2I5,2X,E12.4) 2010 CONTINUE WRITE(PRINTF,*) END IF 180 CONTINUE ! ! *** set all the coefficients in the arrays 0 *** ! DO IS = 1, MSC DO ID = 1, MDC IMATRA(ID,IS) = 0. IMATDA(ID,IS) = 0. ICOLU2(ID) = 0. ENDDO ENDDO ! ! End of the subroutine SOLMT1 ! RETURN END ! !**************************************************************** ! SUBROUTINE SOURCE (ITER ,IX ,IY , & SWPDIR ,KWAVE ,SPCSIG , 30.72 & ECOS ,ESIN ,AC2 , & DEP2 ,IMATDA ,IMATRA , & ABRBOT ,KMESPC ,SMESPC , & UBOT ,UFRIC ,UX2 , & UY2 ,IDCMIN ,IDCMAX , & IDDLOW ,IDDTOP ,IDWMIN , & IDWMAX ,ISSTOP ,PLWNDS , & PLWNDD ,PLWCAP ,PLBTFR , & PLSWEL , 40.88 & PLWBRK ,PLNL4S ,PLNL4D , & PLVEGT ,PLTURB ,PLMUD , 40.59 40.35 40.55 & PLICE , 41.75 & PLTRI , HS , 40.22 & ETOT ,QBLOC ,THETAW , & HM ,FPM ,WIND10 , & ETOTW ,GROWW ,ALIMW , & SMEBRK ,KTETA ,SNLC1 , 41.47 & DAL1 ,DAL2 ,DAL3 , & UE ,SA1 , 40.17 & SA2 ,DA1C ,DA1P , & DA1M ,DA2C ,DA2P , & DA2M ,SFNL ,DSNL , & MEMNL4 ,WWINT ,WWAWG , & WWSWG ,CGO ,USTAR , & ZELEN ,SPCDIR ,ANYWND , & DMW , 40.59 & MEMSINA ,MEMSINB , 40.88 & DISSC0 ,DISSC1 ,GENC0 , 40.85 & GENC1 ,REDC0 ,REDC1 , 40.85 & XIS ,FRCOEF ,IT , 30.00 & NPLA2 ,TURBV2 ,MUDL2 , 40.59 40.35 40.55 & AICE2 ,HICE2 , 41.75 & URSELL ,ANYBIN ,REFLSO , 40.41 40.03 & TAUWV & ,URMSTOP 40.88 & ) 30.21 ! !**************************************************************** USE OCPCOMM1 40.41 USE OCPCOMM2 40.41 USE OCPCOMM3 40.41 USE OCPCOMM4 40.41 USE SWCOMM1 40.41 USE SWCOMM2 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE M_SNL4 40.17 USE SdsBabanin 40.88 IMPLICIT NONE 40.17 ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! 0. Authors ! ! 30.72: IJsbrand Haagsma ! 30.81: Annette Kieftenburg ! 30.82: IJsbrand Haagsma ! 32.06: Roeland Ris ! 40.02: IJsbrand Haagsma ! 40.03: Nico Booij ! 40.12: IJsbrand Haagsma ! 40.17: IJsbrand Haagsma ! 40.22: John Cazes and Tim Campbell ! 40.23: Marcel Zijlema ! 40.35: Nico Booij ! 40.41: Andre van der Westhuysen ! 40.41: Marcel Zijlema ! 40.55: Marcel Zijlema ! 40.59: Erick Rogers ! 40.61: Marcel Zijlema ! 40.85: Marcel Zijlema ! 41.75: Erick Rogers ! ! 1. Updates ! ! 20.72, Jan. 96: Common introduced ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 30.82, Oct. 98: Updated description several variables ! 32.06, June 99: Updated argument list of WNDPAR ! 30.81, Sep. 99: Updated argument list of SSURF ! 40.03, Apr. 00: array Ursell added in argument list ! 40.02, Sep. 00: Replaced SWCAP1-5 by SWCAP ! 40.02, Oct. 00: References to CDRAGP and TAUWP removed ! 40.12, Nov. 00: Added WCAP to dissipation output (bug fix 40.11 A) ! 40.22, Sep. 01: Removed WAREA array. 40.22 ! 40.22, Sep. 01: Changed array definitions to use the parameter 40.22 ! MICMAX instead of ICMAX. 40.22 ! 40.17, Dec. 01: Implemented Multiple DIA 40.17 ! 40.23, Aug. 02: Print of CPU times added ! 40.23, Aug. 02: Parameter list of SWSNL2 and FILNL3 changed ! 40.35, Jun. 04: add turbulent viscosity model ! 40.41, May 04: Implementation of XNL (WRT) interface ! 40.41, Aug. 04: contribution due to reflection added to right-hand ! side of the system of equations ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! 40.55, Dec. 05: introducing vegetation model ! 40.59, Aug. 07: introducing fluid mud-induced dissipation model ! 40.61, Sep. 06: introduction of all separate dissipation coefficients ! for output purposes ! 40.85, Aug. 08: add generation and redistribition for output purposes ! 41.75, Jan. 19: add dissipation by sea ice ! ! 2. Purpose ! ! to compute the source terms, i.e., bottom friction, ! wave breaking, wind input, white capping and non linear ! wave wave interactions ! ! 3. Method ! ! --- ! ! 4. Argument variables ! ! i ECOS : =SPCDIR(*,2); cosine of spectral directions ! i ESIN : =SPCDIR(*,3); sine of spectral directions ! i SPCDIR: (*,1); spectral directions (radians) 30.82 ! (*,2); cosine of spectral directions 30.82 ! (*,3); sine of spectral directions 30.82 ! (*,4); cosine^2 of spectral directions 30.82 ! (*,5); cosine*sine of spectral directions 30.82 ! (*,6); sine^2 of spectral directions 30.82 ! i SPCSIG: Relative frequencies in computational domain in sigma-space 30.72 ! REAL ECOS(MDC) REAL ESIN(MDC) REAL SPCDIR(MDC,6) 30.82 REAL SPCSIG(MSC) 30.72 ! ! INTEGERS: ! -------------------------------------------------------------- ! IS Counter of relative frequency band ! IBOT Indicator for bottom friction ! ICUR Indicator for current ! ISURF Indicator for wave breaking ! ITRIAD Indicator for nonlinear triad interactions ! IQUAD Indicator for nonlinear quadruplet interactions ! IWCAP Indicator for wave capping ! IWIND Indicator for which wind generation model is used ! ICMAX Maximum array size for the points of the molecul ! MSC Maximum counter of relative frequency in ! computational model ! MDC Maximum counter of directional distribution in ! computational model (2PI / DDIR + 1) ! MTC Maximum counter of the time, i.e.: ! (total time in proto type) / (time step) ! MBOT Maximum array size for PBOT ! MSURF Maximum array size for PSSURF ! MTRIAD Maximum array size for PTRIAD ! MWCAP Maximum array size for PWCAP ! MWIND Maximum array size for PWIND ! ISSTOP Max frequency that is propagated within a sweep ! ! REALS: ! -------- ! ! DS Width of frequency band (is not constant because ! of the logharitmic distribution of the frequency ! direction of the sweep (+1. OR -1. ) no input ! GRAV Gravitational acceleration ! ABRBOT Near bottom excursion amplitude ! EMAX Maximum energy according to the depth and the ! breaker parameter ! ETOT Total energy density per gridpoint ! ETOTW Total energy of the wind sea spectrum ! GRAV Gravitational acceleration ! HM Maximum wave height ! KMESPC Mean average wavenumber over full spectrum ! SMESPC Mean average frequency over full spectrum ! QBLOC Fraction of breaking waves ! ! one and more dimensional arrays: ! --------------------------------- ! ! AC2 4D (Nonstationary case) action density as function ! of D,S,X,Y at time T+DT ! DEP2 2D (Nonstationary case) depth as function of X and Y ! at time T+DIT ! ECOS 1D Represent the values of cos(d) of each spectral ! direction ! ESIN 1D Represent the values of sin(d) of each spectral ! direction ! ALIMW 1D Maximum energy by wind growth. ! IMATDA 2D coefficients of main diagonal ! IMATRA 2D right-hand side ! KWAVE 2D wavenumber as function of the relative frequency S ! and position IC(ix,iy) ! PBOT 1D Coefficient for the bottom friction models ! PSURF 1D Coefficient for the wave breaking model ! PTRIAD 1D Coefficient for the triad interaction model ! PWCAP 1D Coefficient for the white capping model ! PWIND 1D Coefficient for the wind growth model ! UBOT 2D Absolute orbital velocity in a gridpoint (IX,IY) ! UX2 2D (Nonstationary case) X-component of current velocity ! in (X,Y) at time T+DIT ! UY2 2D (Nonstationary case) Y-component of current velocity ! in (X,Y) at time T+DIT ! USTAR 2D Friction velocity at previous iteration for ! Janssen (1989,1990) wind input formulation ! ZELEN 2D Roughness length at previous iteration for ! Janssen (1989,1990) wind input formulation ! ! Coefficients for the arrays: ! ----------------------------- ! default ! value: ! ! PBOT(1) = CFC 0.005 (Putnam and Collins equation) ! PBOT(2) = CFW 0.01 (Putnam and Collins equation) ! PBOT(3) = GAMJNS 0.038 (Jonswap formulation) ! note: this lower friction value combined with second order polynomial wind drag ! PBOT(4) = MF -0.08 (Madsen et al. equation) ! PBOT(5) = KN 0.05 (Madsen et al. bottom roughness) ! ! PSURF(1) = ALFA 1.0 (Battjes & Janssen, 1978) ! PSURF(2) = GAMMA 0.73 (breaking criterium) ! ! PWCAP(1) = ALFAWC 2.36e-5 (Emperical coefficient) ! PWCAP(2) = ALFAPM 3.02E-3 (Alpha of Pierson Moskowitz frequency) ! PWCAP(3) = CFJANS 4.5 ! PWCAP(4) = DELTA 0.5 ! PWCAP(5) = CFLHIG 1. ! PWCAP(6) = GAMBTJ 0.88 (Steepness limited wave breaking ) ! ! PWIND(1) = CF10 188.0 (second generation wind growth model) ! PWIND(2) = CF20 0.59 (second generation wind growth model) ! PWIND(3) = CF30 0.12 (second generation wind growth model) ! PWIND(4) = CF40 250.0 (second generation wind growth model) ! PWIND(5) = CF50 0.0023 (second generation wind growth model) ! PWIND(6) = CF60 -0.2233 (second generation wind growth model) ! PWIND(7) = CF70 0. (second generation wind growth model) ! PWIND(8) = CF80 -0.56 (second generation wind growth model) ! PWIND(9) = RHOAW 0.00125 (density air / density water) ! PWIND(10) = EDMLPM 0.0036 (limit energy Pierson Moskowitz) ! PWIND(11) = CDRAG 0.0012 (drag coefficient) ! PWIND(12) = UMIN 1.0 (minimum wind velocity) ! PWIND(13) = PMLM 0.13 ( ) ! ! arrays for Janssen (`89) ! ----------- ! PWIND(14) 1D alfa (which is tuned at 0.01) ! PWIND(15) 1D Kappa ( 0.41) ! PWIND(16) 1D Rho air (1.28) ! PWIND(17) 1D Rho water (1025) ! ! 6. Local variables ! ! IT : Number of the time-step 40.17 ! ! IQERR : Error indicator for SWINTFXNL interface 40.41 INTEGER IQERR 40.41 ! INTEGER :: ID, IDIA, IDC, IERR, IENT, IS, ISC, IT 40.17 INTEGER :: N2, LMAX 40.17 REAL :: DQ, DQ2, DT2 40.17 ! ! 7. Common blocks used ! ! 8. REMARKS ! ! On setting the AICELOC variable: ! * PIC4M2(1) should be used for AICELOC *only* if VARAICE is false. ! * We check for case of IICE>3 as a reminder to update this subroutine ! if/when new S_ice routines are added. ! ! On setting HICELOC variable: ! This is not used by any subroutine yet. Therefore it is not set here. ! However, it can easily be added later by following example of AICELOC ! We are already bringing the HICE2 variable into SOURCE in anticipation ! of adding HICELOC later, for future version of SICE subroutine ! ! 9. STRUCTURE ! ! ------------------------------------------------------------ ! If SBOT is on (IBOT > 0 ) then, ! Call SBOT to compute the source term due to bottom friction ! according to Hasselmann et al. (1974), Putnam and Jonsson (1949), ! Madsen et al. (1991) or Smith et al. (2011) ! ------------------------------------------------------------ ! If SVEG is on (IVEG > 0 ) then, ! Call SVEG to compute the source term due to vegetation ! dissipation according to Dalrymple (1984) ! ------------------------------------------------------------ ! If STURBV is on (ITURBV > 0 ) then, ! Call STURBV to compute the source term due to turbulence ! dissipation according to Tolman (1961) ! ------------------------------------------------------------ ! If SMUD is on (IMUD > 0 ) then, ! Call SMUD to compute the source term due to fluid mud ! dissipation according to Ng (2000) ! ------------------------------------------------------------ ! If SICE is on (IICE > 2 ) then, ! Call SICE to compute the source term due to dissipation by sea ice. ! For IICE=3, use method IC4M2 : polynomial parametric function ! ------------------------------------------------------------ ! If SSURF is on (ISURF > 0 ) then, ! Call SSURF to compute the source term due to wave breaking ! ------------------------------------------------------------ ! IF IWIND =1 OR IWIND =2 THEN ! Call WNDPAR (first or second generation mode of source terms ! using the DOLPHIN-B formulations) ! ! else if IWIND = 3 then ! input source term according to Snyder (1981) ! Call SWIND3 ! else if IWIND = 4 then ! input source term according to Janssen (1989,1991) ! Call SWIND4 ! else if IWIND = 5 then ! input source term according to Yan (1989) [reduces to Snyder form ! for low frequencies and to Plant's (1982) form for high freq. ! Call SWIND5 ! else if IWIND = 8 then ! input source term according to Rogers et al. (JTECH 2012) ! based on work of Donelan, Babanin, Tsagareli and others ! Call SWIND_DBYB ! ------------------------------------------------------------ ! If IWCAP > 1 then ! Call SWCAP to compute the source term for white capping 40.02 ! --------------------------------------------------------------------- ! If ITRIAD > 0 then 30.80 ! Call SWLTA to compute the nonlinear 3 wave-wave interactions ! based on the LTA technique (Eldeberky, 1996) ! --------------------------------------------------------------------- ! If Ursell < Urmax ! Then If IQUAD = 1 ! Then Call SWSNL1 to compute the nonlinear 4-wave interactions ! semi-implicit per sweep direction ! Else if IQUAD = 2 ! Then Call SWSNL2 to compute the nonlinear 4-wave interactions ! fully explicit per sweep direction ! Else if IQUAD = 3 ! Then Call SWSNL3 to compute the nonlinear 4-wave interactions ! fully explicit per iteration ! Call FILNL3 to get values for interactions from array ! for full circle ! --------------------------------------------------------------------- ! ! 10. SOURCE ! !************************************************************************ ! INTEGER ITER ,IDWMIN ,IDWMAX ,SWPDIR ,ISSTOP , & IDDTOP ,IDDLOW ,IX ,IY ! REAL ABRBOT ,ETOT ,HM ,QBLOC ,ETOTW , & FPM ,WIND10 ,THETAW ,SMESPC ,KMESPC , & SNLC1 ,FACHFR ,DAL1 ,DAL2 ,DAL3 , & UFRIC ,SMEBRK ,HS ,XIS ,KTETA , & AICELOC ! REAL :: AC2(MDC,MSC,MCGRD) 30.21 REAL :: DEP2(MCGRD) REAL :: ALIMW(MDC,MSC) REAL :: IMATDA(MDC,MSC) REAL :: IMATRA(MDC,MSC) ! Changed ICMAX to MICMAX, since MICMAX doesn't vary over gridpoint 40.22 REAL :: KWAVE(MSC,MICMAX) 40.22 REAL :: DMW(MSC,MICMAX) 40.59 REAL :: UBOT(MCGRD) REAL :: UX2(MCGRD) REAL :: UY2(MCGRD) REAL :: UE(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: SA1(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: SA2(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: DA1C(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: DA1P(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: DA1M(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: DA2C(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: DA2P(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: DA2M(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: SFNL(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: DSNL(MSC4MI:MSC4MA , MDC4MI:MDC4MA ) REAL :: MEMNL4(MDC,MSC,MCGRD) REAL :: MEMSINA(MDC,MSC,MCGRD) REAL :: MEMSINB(MDC,MSC,MCGRD) REAL :: PLWNDS(MDC,MSC,NPTST) REAL :: PLWNDD(MDC,MSC,NPTST) REAL :: PLWCAP(MDC,MSC,NPTST) REAL :: PLBTFR(MDC,MSC,NPTST) REAL :: PLWBRK(MDC,MSC,NPTST) REAL :: PLNL4S(MDC,MSC,NPTST) REAL :: PLNL4D(MDC,MSC,NPTST) REAL :: PLVEGT(MDC,MSC,NPTST) 40.55 REAL :: PLTURB(MDC,MSC,NPTST) 40.35 REAL :: PLMUD (MDC,MSC,NPTST) 40.59 REAL :: PLICE (MDC,MSC,NPTST) 41.75 REAL :: PLSWEL(MDC,MSC,NPTST) 40.88 REAL :: PLTRI(MDC,MSC,NPTST) REAL :: WWAWG(*) REAL :: WWSWG(*) REAL :: CGO(MSC,MICMAX) 40.22 REAL :: USTAR(MCGRD) REAL :: ZELEN(MCGRD) REAL :: TAUWV(MCGRD) REAL :: DISSC0(1:MDC,1:MSC,1:MDISP) 40.67 REAL :: DISSC1(1:MDC,1:MSC,1:MDISP) 40.67 REAL :: GENC0 (1:MDC,1:MSC,1:MGENR) 40.85 REAL :: GENC1 (1:MDC,1:MSC,1:MGENR) 40.85 REAL :: REDC0 (1:MDC,1:MSC,1:MREDS) 40.85 REAL :: REDC1 (1:MDC,1:MSC,1:MREDS) 40.85 REAL :: URSELL(MCGRD) 40.03 REAL :: FRCOEF(MCGRD) 20.68 REAL :: NPLA2(MCGRD) 40.55 REAL :: TURBV2(MCGRD) 40.35 REAL :: MUDL2(MCGRD) 40.59 REAL, INTENT(IN) :: AICE2(MCGRD) 41.75 REAL, INTENT(IN) :: HICE2(MCGRD) 41.75 REAL :: REFLSO(MDC,MSC) 40.41 REAL :: URMSTOP(MCGRD) 40.88 ! INTEGER IDCMIN(MSC) , & IDCMAX(MSC) , & WWINT(*) ! LOGICAL GROWW(MDC,MSC) , & ANYBIN(MDC,MSC), 40.41 & ANYWND(MDC) ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SOURCE') ! ! *** set relevant matrix elements to 0 *** ! IF (OPTG.NE.5) THEN 40.80 IMATRA = 0. IMATDA = 0. ENDIF ! ! *** set all dissipation coeff at 0 *** ! DISSC0(1:MDC,1:MSC,1:MDISP) = 0. 40.67 DISSC1(1:MDC,1:MSC,1:MDISP) = 0. 40.67 ! ! *** set all generation coeff at 0 *** ! GENC0(1:MDC,1:MSC,1:MGENR) = 0. 40.85 GENC1(1:MDC,1:MSC,1:MGENR) = 0. 40.85 ! ! *** set all redistribution coeff at 0 *** ! REDC0(1:MDC,1:MSC,1:MREDS) = 0. 40.85 REDC1(1:MDC,1:MSC,1:MREDS) = 0. 40.85 ! ! *** set local ice concentration *** 41.75 ! (see Remarks) 41.75 AICELOC = 0. 41.75 IF ( VARAICE ) THEN 41.75 AICELOC = AICE2(KCGRD(1)) 41.75 ELSEIF ( IICE.EQ.3 ) THEN 41.75 AICELOC = PIC4M2(1) 41.75 ELSEIF ( IICE.GT.3 ) THEN 41.75 CALL MSGERR (3,'invalid IICE option') 41.75 ENDIF 41.75 ! !TIMG CALL SWTSTA(130) 40.23 IF (IBOT .GE. 1) THEN ! ! *** wave-bottom interactions *** ! CALL SBOT (ABRBOT ,DEP2 ,ECOS ,ESIN ,AC2 , 41.04 & IMATDA ,KWAVE ,SPCSIG ,UBOT ,UX2 , 30.72 & UY2 ,IDCMIN ,IDCMAX ,IT ,ITER , 41.51 & SWPDIR ,PLBTFR ,ISSTOP ,DISSC1 ,VARFR , 41.51 40.67 & FRCOEF ) END IF !TIMG CALL SWTSTO(130) 40.23 ! !TIMG CALL SWTSTA(138) 40.59 IF ( IMUD.GE.1 ) THEN 40.59 ! ! *** wave-mud interactions *** 40.59 ! ! *** energy dissipation according to Ng (2000) 40.59 ! CALL SMUD ( DEP2 ,IMATDA , & KWAVE ,CGO ,DMW , 40.59 & IDCMIN ,IDCMAX ,ISSTOP , 40.59 & DISSC1 ,PLMUD ) 40.67 40.61 40.59 END IF 40.59 !TIMG CALL SWTSTO(138) 40.59 ! !TIMG CALL SWTSTA(139) 40.55 IF ( IVEG.GE.1 ) THEN 40.55 ! ! *** wave-vegetation interactions *** 40.55 ! ! *** energy dissipation according to Dalrymple (1984) 40.55 ! CALL SVEG (DEP2 ,IMATDA ,ETOT ,SMEBRK , 40.58 40.55 & KMESPC ,PLVEGT , 40.58 40.55 & IDCMIN ,IDCMAX ,ISSTOP ,DISSC1 , 40.55 & NPLA2 ) 40.67 40.61 40.55 END IF 40.55 !TIMG CALL SWTSTO(139) 40.55 ! !TIMG CALL SWTSTA(143) 40.35 IF ( ITURBV.GE.1 ) THEN 40.35 ! ! *** dissipation due to turbulent viscosity *** 40.35 ! CALL STURBV (TURBV2 ,DEP2 ,IMATDA , 40.35 & IDCMIN ,IDCMAX ,ISSTOP , 40.35 & KWAVE ,DISSC1 ,PLTURB ) 40.35 END IF 40.35 !TIMG CALL SWTSTO(143) 40.35 ! !TIMG CALL SWTSTA(144) 41.75 IF ( IICE.GE.2 ) THEN 41.75 ! 41.75 ! *** dissipation by sea ice *** 41.75 ! 41.75 CALL SICE (IMATDA , IDCMIN , IDCMAX , ISSTOP 41.75 & , DISSC1 , PLICE , AICELOC 41.75 & , SPCSIG , CGO 41.75 & ) 41.75 ! 41.75 END IF 41.75 !TIMG CALL SWTSTO(144) 41.75 ! !TIMG CALL SWTSTA(131) 40.23 IF (ISURF .GE. 1) THEN ! ! *** calculate surf breaking source term (5 formulations) *** 41.03 ! CALL SSURF (ETOT ,HM ,QBLOC ,SMEBRK ,KTETA , 41.47 & KMESPC ,SPCSIG ,AC2 ,IMATRA , 30.81 & IMATDA ,IDCMIN ,IDCMAX ,PLWBRK , & ISSTOP ,DISSC0 ,DISSC1 ) 40.67 40.61 30.21 ! END IF !TIMG CALL SWTSTO(131) 40.23 ! !TIMG CALL SWTSTA(132) 40.23 IF ( IWIND .GE. 3 & ) THEN ! ! *** linear wind input according to Cavaleri and Malanotte *** ! *** Rizolli (1981) for a third generation mode of SWAN *** ! IF (PWIND(31) .GT. 1.E-20) THEN IF ( IWIND.NE.8 ) THEN CALL SWIND0 (IDCMIN ,IDCMAX ,ISSTOP , & SPCSIG ,THETAW ,ANYWND , & UFRIC ,FPM ,PLWNDS , & IMATRA ,SPCDIR ,GENC0 , & KWAVE ,AICELOC ) ELSE IF ( SWPDIR .EQ. 1 .OR. & (SWPDIR .EQ. 2 .AND. IX .EQ. 1) .OR. & (SWPDIR .EQ. 3 .AND. IY .EQ. 1) .OR. & (SWPDIR .EQ. 4 .AND. (IX.EQ.MXC .AND. IY.EQ.1)) ) & CALL SWIND0_NRL (SPCSIG ,THETAW ,ANYWND , & UFRIC ,FPM ,MEMSINA , & SPCDIR ,KWAVE ) ! ! *** get source term value of array MEMSINA for the bin that *** ! *** falls within a sweep and store in right hand side IMATRA *** ! CALL FILSIN( MEMSINA, IDCMIN, IDCMAX, IMATRA, ANYWND, & PLWNDS , ISSTOP, GENC0 , AICELOC ) ENDIF ENDIF ENDIF ! IF ( IWIND .EQ. 1 .OR. IWIND .EQ. 2 ) THEN 970220 ! CALL WNDPAR (ISSTOP,IDWMIN,IDWMAX,IDCMIN,IDCMAX, 32.06 & DEP2 ,WIND10,GENC0,GENC1, 40.85 32.06 & THETAW,AC2 ,KWAVE ,IMATRA,IMATDA, 32.06 & SPCSIG,CGO ,ALIMW ,GROWW ,ETOTW , 32.06 & PLWNDS,PLWNDD,SPCDIR,ITER,AICELOC ) 41.75 32.06 ! ! ELSE IF ( IWIND .EQ. 3 ) THEN ! ! *** Wind input according to Snyder et al (1981) *** ! CALL SWIND3 (SPCSIG ,THETAW , & KWAVE ,IMATRA ,GENC0 , & IDCMIN ,IDCMAX ,AC2 ,UFRIC , & FPM ,PLWNDS ,ISSTOP ,SPCDIR , & ANYWND ,AICELOC ) ! ELSE IF ( IWIND .EQ. 4 ) THEN ! ! *** Wind input according to Janssen (1989,1991) *** ! CALL SWIND4 (IDWMIN ,IDWMAX , & SPCSIG ,WIND10 ,THETAW ,XIS , & DDIR ,KWAVE ,IMATRA ,GENC0 , & IDCMIN ,IDCMAX ,AC2 ,UFRIC , & PLWNDS ,ISSTOP ,ITER ,USTAR ,ZELEN , & SPCDIR ,ANYWND ,IT ,TAUWV ,AICELOC ) ! ELSE IF ( IWIND .EQ. 5 ) THEN ! ! *** Wind input according to Yan (1989) *** ! CALL SWIND5 (SPCSIG ,THETAW ,ISSTOP , & UFRIC ,KWAVE ,IMATRA ,IDCMIN , & IDCMAX ,AC2 ,ANYWND ,PLWNDS , & SPCDIR ,GENC0 ,AICELOC ) ! ELSE IF ( IWIND .EQ. 8 ) THEN ! ! *** wind according to Rogers et al. (JTECH 2012) ! based on work of Donelan, Babanin, Tsagareli and others ! IF ( SWPDIR .EQ. 1 .OR. & (SWPDIR .EQ. 2 .AND. IX .EQ. 1) .OR. & (SWPDIR .EQ. 3 .AND. IY .EQ. 1) .OR. & (SWPDIR .EQ. 4 .AND. (IX.EQ.MXC .AND. IY.EQ.1)) ) & CALL SWIND_DBYB (SPCSIG ,THETAW ,KWAVE ,MEMSINA , & MEMSINB ,AC2 ,UFRIC ,WIND10 , & SPCDIR ,ANYWND ,CGO ,ZELEN ) ! ! *** get source term value of array MEMSINB for the bin that *** ! *** falls within a sweep and store in right hand side IMATRA *** ! CALL FILSIN( MEMSINB, IDCMIN, IDCMAX, IMATRA, ANYWND, & PLWNDS , ISSTOP, GENC0 , AICELOC ) END IF !TIMG CALL SWTSTO(132) 40.23 ! ! Calculate whitecapping source term (multiple formulations) 40.31 40.02 ! !TIMG CALL SWTSTA(133) 40.23 IF (IWCAP.GE.1) THEN IF (IWCAP.LE.7) CALL SWCAP (SPCDIR ,SPCSIG ,KWAVE ,AC2 , 40.02 & IDCMIN ,IDCMAX ,ISSTOP , 40.02 & ETOT ,IMATDA ,IMATRA ,PLWCAP , 40.02 & CGO ,UFRIC , 40.53 & DEP2 ,DISSC1 ,DISSC0 ) 40.67 40.61 40.12 IF (IWCAP.EQ.8) CALL SWCAP8 (SPCDIR ,SPCSIG ,KWAVE ,AC2 , & IDCMIN ,IDCMAX ,ISSTOP , & ETOT ,IMATDA ,IMATRA ,PLWCAP , & CGO ,UFRIC , & DEP2 ,DISSC1 ,DISSC0 ) END IF ! ! For now, we only call SSWELL if Babanin physics are in use IF (IWCAP.EQ.8) THEN IF (ZIEGER) THEN CALL SSWELL_ZIEGER (SPCSIG, KWAVE, AC2, CGO, ISSTOP & ,IDCMIN ,IDCMAX, MDC, DISSC1, IMATDA & ,TESTFL,IPTST,PLSWEL) ELSE IF (ROGERS) THEN CALL SSWELL_ROGERS (SPCSIG, KWAVE, IDCMIN, IDCMAX & ,ISSTOP , DISSC1 ,ETOT ,IMATDA & ,URMSTOP(KCGRD(1)), GRAV , PWIND(9), MDC & ,TESTFL,IPTST,PLSWEL,CGO,CDSV,FESWELL) ELSE IF (ARDHUIN) THEN CALL SSWELL_ARDHUIN (SPCSIG, THETAW, KWAVE, IDCMIN, & IDCMAX, ISSTOP, DISSC1, ETOT, IMATDA, & SPCDIR, UFRIC , & URMSTOP(KCGRD(1)), GRAV,PWIND(9), & TESTFL,IPTST,PLSWEL,MDC,CGO,CDSV) ELSE CALL MSGERR(4,' Sswell must be defined! ') ! note that CGO is for diagnostic purposes only, may be omitted ! excluded : SPCDIR AC2 DEP2 IMATRA END IF END IF !TIMG CALL SWTSTO(133) 40.23 ! ! compute nonlinear interactions, starting with triads NB! ! !TIMG CALL SWTSTA(134) 40.23 IF (ITRIAD .GT. 0) THEN ! ! *** compute the 3 wave-wave interactions if in each *** NB! ! *** geographical gridpoint a continuous spectrum *** ! *** is present, i.e., after first iteration *** ! IF ( ICUR .EQ. 0 .OR. ITER .GT. 1 ) THEN ! IF (ITRIAD.EQ.1.OR.ITRIAD.EQ.11) THEN ! LTA CALL SWLTA ( AC2 , DEP2 , CGO , SPCSIG, 40.56 & KWAVE , IMATRA, IMATDA, REDC0 , REDC1 , 40.85 & IDDLOW, IDDTOP, ISSTOP, IDCMIN, IDCMAX, & HS , SMEBRK, PLTRI , URSELL ) ELSEIF (ITRIAD.EQ.2) THEN ! SPB CALL SWSPB (AC2 , DEP2 , CGO , SPCSIG, & KWAVE , IMATRA, IMATDA, REDC0 , REDC1 , & IDDLOW, IDDTOP, ISSTOP, IDCMIN, IDCMAX, & PLTRI ) ELSEIF (ITRIAD.EQ.5) THEN ! DCTA CALL STRICL (AC2(1,1,KCGRD(1)) ,DEP2(KCGRD(1)), & SPCSIG ,KWAVE , & IDDLOW,IDDTOP,ANYBIN,IMATDA,IMATRA, & CGO ,KMESPC ,ETOT ,SMEBRK) ENDIF ! ENDIF ! ENDIF !TIMG CALL SWTSTO(134) 40.23 ! ! --- compute quadruplet interactions if Ursell number < Urmax 40.41 ! (usually, Urmax = 0.1, but here Urmax = 10) 40.41 ! !TIMG CALL SWTSTA(135) 40.23 IF (URSELL(KCGRD(1)).LT.PTRIAD(3)) THEN 40.03 ! ! *** compute the counters for the nonlinear four *** ! *** wave-wave interactions in spectral space *** ! *** and high frequency factor *** ! IF ( IQUAD .GE. 1 ) THEN CALL RANGE4 (WWINT ,IDDLOW,IDDTOP ) 40.00 FACHFR = 1. / XIS ** PWTAIL(1) 20.72 ENDIF ! IF (IQUAD .EQ. 1) THEN ! ! *** semi-implicit calculation for al the bins that fall *** ! *** within a sweep. No additional array is required *** ! CALL SWSNL1 ( WWINT ,WWAWG ,WWSWG , 34.00 & IDCMIN ,IDCMAX ,UE ,SA1 , 40.17 & SA2 ,DA1C ,DA1P ,DA1M ,DA2C , & DA2P ,DA2M ,SPCSIG ,SNLC1 ,KMESPC , 30.72 & FACHFR ,ISSTOP ,DAL1 ,DAL2 ,DAL3 , & SFNL ,DSNL ,DEP2 ,AC2 ,IMATDA , & IMATRA ,PLNL4S ,PLNL4D , 34.00 & IDDLOW ,IDDTOP ,REDC0 ,REDC1 ) 40.85 34.00 ! ELSE IF ( IQUAD .EQ. 2) THEN ! ! *** fully explicit calculation for al the bins that fall *** ! *** within a sweep. No additional array is required *** ! CALL SWSNL2 ( IDDLOW ,IDDTOP ,WWINT , 34.00 & WWAWG ,UE ,SA1 ,ISSTOP , 40.17 & SA2 ,SPCSIG ,SNLC1 ,DAL1 ,DAL2 , 30.72 & DAL3 ,SFNL ,DEP2 ,AC2 ,KMESPC , & REDC0 ,REDC1 ,IMATDA ,IMATRA , 40.85 40.23 34.00 & FACHFR ,PLNL4S , IDCMIN ,IDCMAX ) 34.00 ! ELSE IF ( IQUAD .EQ. 3) THEN ! ! *** fully explicit calculation of the 4 wave-wave inter- *** ! *** actions for the full circle (1 -> MDC). An additional *** ! *** array is required in which the values are stored prior*** ! *** to every iteration *** ! IF ( ITER .EQ. 1 ) THEN ! ! *** calculate the interactions every sweep in each grid *** ! *** point for the first iteration to ensure stable *** ! *** behaviour of the model *** ! CALL SWSNL3 ( WWINT ,WWAWG , 40.17 & UE ,SA1 ,SA2 ,SPCSIG ,SNLC1 , 40.17 30.72 & DAL1 ,DAL2 ,DAL3 ,SFNL ,DEP2 , 40.17 & AC2 ,KMESPC ,MEMNL4 ,FACHFR ) 40.17 ! ELSE IF ( ITER .GT. 1 .AND. ( SWPDIR .EQ. 1 .OR. & ( SWPDIR .EQ. 2 .AND. IX .EQ. 1) .OR. & ( SWPDIR .EQ. 3 .AND. IY .EQ. 1) .OR. & ( SWPDIR .EQ. 4 .AND. (IX.EQ.MXC .AND. IY.EQ.1)) )) THEN ! CALL SWSNL3 ( WWINT ,WWAWG , 40.17 & UE ,SA1 ,SA2 ,SPCSIG ,SNLC1 , 40.17 30.72 & DAL1 ,DAL2 ,DAL3 ,SFNL ,DEP2 , 40.17 & AC2 ,KMESPC ,MEMNL4 ,FACHFR ) 40.17 ! ENDIF ! ! *** Get source term value of additional array for the bin *** ! *** that fall within a sweep and store in right hand vector *** ! CALL FILNL3 (IDCMIN ,IDCMAX ,IMATRA ,IMATDA ,AC2 , 40.23 & MEMNL4 ,PLNL4S ,ISSTOP ,REDC0 ,REDC1 ) 40.85 40.41 ELSE IF (IQUAD .EQ. 4) THEN 40.17 ! Multiple DIA according to Hashimoto (1999) 40.17 IF ((ITER.EQ.1).OR.( ITER .GT. 1 .AND. ( SWPDIR .EQ. 1 .OR. & ( SWPDIR .EQ. 2 .AND. IX .EQ. 1) .OR. & ( SWPDIR .EQ. 3 .AND. IY .EQ. 1) .OR. & ( SWPDIR .EQ. 4 .AND. (IX.EQ.MXC .AND. IY.EQ.1))))) THEN DO IDIA=1,MDIA 40.17 PQUAD(1) = LAMBDA(IDIA) 40.17 CALL FAC4WW (XIS ,SNLC1 , 40.41 40.17 & DAL1 ,DAL2 ,DAL3 ,SPCSIG, 40.17 & WWINT ,WWAWG ,WWSWG ) 40.17 FACHFR = 1. / XIS ** PWTAIL(1) 40.17 CALL RANGE4 (WWINT ,IDDLOW,IDDTOP ) 40.17 CALL SWSNL4 (WWINT ,WWAWG , 40.17 & SPCSIG ,SNLC1 , 40.17 & DAL1 ,DAL2 ,DAL3 ,DEP2 , 40.17 & AC2 ,KMESPC ,MEMNL4 ,FACHFR , 40.17 & IDIA ,ITER ) 40.17 END DO ENDIF ! Fill the matrix per sweep even though the quadruplets are calculated ! only once per iteration CALL FILNL3 (IDCMIN ,IDCMAX ,IMATRA ,IMATDA ,AC2 , 40.23 & MEMNL4 ,PLNL4S ,ISSTOP ,REDC0 ,REDC1 ) 40.85 40.41 ! ELSE IF ( IQUAD .EQ. 8) THEN 40.41 ! ! --- fully explicit calculation of the 4 wave-wave ! interactions for the full circle. The interactions ! in neighbouring bins are interpolated in piecewise ! constant manner. An additional array is required in ! which the values are stored prior to every iteration ! IF ( ITER .EQ. 1 ) THEN ! ! *** calculate the interactions every sweep in each grid *** ! *** point for the first iteration to ensure stable *** ! *** behaviour of the model *** ! CALL SWSNL8 (WWINT ,UE ,SA1 ,SA2 ,SPCSIG , & SNLC1 ,DAL1 ,DAL2 ,DAL3 ,SFNL , & DEP2 ,AC2 ,KMESPC ,MEMNL4 ,FACHFR ) ! ELSE IF ( ITER .GT. 1 .AND. ( SWPDIR .EQ. 1 .OR. & ( SWPDIR .EQ. 2 .AND. IX .EQ. 1) .OR. & ( SWPDIR .EQ. 3 .AND. IY .EQ. 1) .OR. & ( SWPDIR .EQ. 4 .AND. (IX.EQ.MXC .AND. IY.EQ.1)) )) THEN ! CALL SWSNL8 (WWINT ,UE ,SA1 ,SA2 ,SPCSIG , & SNLC1 ,DAL1 ,DAL2 ,DAL3 ,SFNL , & DEP2 ,AC2 ,KMESPC ,MEMNL4 ,FACHFR ) ! ENDIF ! ! *** get source term value of additional array for the bin *** ! *** that fall within a sweep and store in right hand vector *** ! CALL FILNL3 (IDCMIN ,IDCMAX ,IMATRA ,IMATDA ,AC2 , & MEMNL4 ,PLNL4S ,ISSTOP ,REDC0 ,REDC1 ) 40.85 40.41 ! ELSEIF ((IQUAD.EQ.51).OR.(IQUAD.EQ.52).OR.(IQUAD.EQ.53)) THEN 40.41 ! ! Calculate the quadruplets using the XNL interface of 40.41 ! G. van Vledder 40.41 ! ! Avoid calculation of the quadruplets in more than one sweep 40.41 ! IF ((ITER .GE. 1) .AND. 40.41 & ( (SWPDIR.EQ.1) .OR. 40.41 & ((SWPDIR.EQ.2).AND.(IX.EQ.1) ).OR. 40.41 & ((SWPDIR.EQ.3).AND.(IY.EQ.1) .AND.(.NOT.ONED)).OR. 40.41 & ((SWPDIR.EQ.4).AND.(IX.EQ.MXC).AND.(IY.EQ.1) 40.41 & .AND.(.NOT.ONED)) ) 40.41 & ) THEN 40.41 ! IF (ITEST.GE.30) WRITE(PRINTF,'(A,4I6,F12.2)') 40.41 & 'SOURCE XNL: iter, swpdir, kcgrd(1), iquad, depth:', 40.41 & ITER, SWPDIR, KCGRD(1), IQUAD, DEP2(KCGRD(1)) 40.41 CALL SWINTFXNL(AC2,SPCSIG,SPCDIR,MDC,MSC,MCGRD, 40.41 & DEP2,IQUAD,MEMNL4,KCGRD,ICMAX,IQERR) 40.41 ! ENDIF 40.41 ! IF (ITEST.GE.30) THEN 40.41 WRITE (PRTEST,*) '+SOURCE: IX, IY, SWPDIR: ', 40.41 & IX, IY, SWPDIR 40.41 ENDIF 40.41 IF (TESTFL.AND.ITEST.GE.100) THEN 40.41 DO IS=1, MSC 40.41 DO ID = 1, MDC 40.41 WRITE(PRINTF,9300) IS,ID,MEMNL4(ID,IS,KCGRD(1)) 40.41 9300 FORMAT(' SOURCE: IS ID MEMNL(): ',2I6,E12.4) 40.41 ENDDO 40.41 ENDDO 40.41 ENDIF 40.41 ! CALL FILNL3 (IDCMIN ,IDCMAX ,IMATRA ,IMATDA ,AC2 , 40.41 & MEMNL4 ,PLNL4S ,ISSTOP ,REDC0 ,REDC1 ) 40.85 40.41 ! IF (ITEST.GE.30) THEN 40.41 WRITE (PRTEST,*) '+SOURCE: ITER, IQUAD, SWPDIR, IQERR: ', 40.41 & ITER, IQUAD, SWPDIR, IQERR 40.41 ENDIF 40.41 ! ENDIF ENDIF !TIMG CALL SWTSTO(135) 40.23 ! ! --- add contribution due to reflection of obstacles ! !TIMG CALL SWTSTA(136) 40.41 IF (NUMOBS.NE.0) THEN 40.41 DO IS = 1, MSC 40.41 DO ID = 1, MDC 40.41 IF (ANYBIN(ID,IS)) 40.41 & IMATRA(ID,IS) = IMATRA(ID,IS) + REFLSO(ID,IS) 40.41 END DO 40.41 END DO 40.41 END IF 40.41 !TIMG CALL SWTSTO(136) 40.41 ! ! End of the subroutine SOURCE RETURN END ! !************************************************************************ ! * SUBROUTINE PHILIM(AC2,AC2OLD,CGO,KWAVE,SPCSIG,ANYBIN,ISLMIN,NFLIM, & QB_LOC) ! * !************************************************************************ ! USE SWCOMM3 40.41 ! IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.82: IJsbrand Haagsma ! 40.16: IJsbrand Haagsma ! 40.23: Marcel Zijlema ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 30.82, Feb. 99: New subroutine ! 40.16, Dec. 01: Implemented limiter switch ! 40.23, Aug. 02: Store number of frequency use of limiter ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! Limits the change in action density between two iterations to a ! certain percentage of the (directionally independent) Phillips ! equilibrium level ! ! 3. Method ! ! The maximum change of energy density per bin is related to ! the (directionally independent) Phillips equilibrium level. ! This change is estimated as: ! ! |D E(s)| = factor * alpha_PM * g^2 / (s^5) ! ! in which the Phillips' constant for a Pierson-Moskowitz ! spectrum (alpha_PM) is taken to be 0.0081. Note that this ! is a measure for a 1D spectrum. In SWAN, factor = 0.1 ! (stored in PNUMS(20)). ! ! In terms of action density, we have ! ! |D N(s)| = factor * alpha_PM * g^2 / (s^6) ! ! Expressing in wave number k, this becomes with a deep ! water approach of s^2 = gk: ! ! |D N(s)| = factor * alpha_PM / (s^2 k^2) ! ! Furthermore, with s = 2*k*c_g (deep water), we finally ! have (Ris, 1997, p.36): ! ! alpha_PM ! |D N(s,t)| = factor ----------- ! 2 s k^3 c_g ! ! In cases where waves are breaking the dissipation of energy ! is not limited. This is assumed to be the case when the ! fraction of breaking waves Qb is more than 1.e-5. ! ! 4. Argument variables ! LOGICAL ANYBIN(MDC,MSC) ! ! ISLMIN: Lowest sigma-index occured in applying limiter ! NFLIM : Number of frequency use of limiter ! QB_LOC: Local value of Qb (fraction of breaking waves) ! INTEGER ISLMIN(MCGRD), NFLIM(MCGRD) REAL QB_LOC REAL AC2(MDC,MSC,MCGRD) REAL AC2OLD(MDC,MSC) REAL CGO(MSC,MICMAX) REAL KWAVE(MSC,MICMAX) REAL SPCSIG(MSC) ! ! 6. Local variables ! ! ID : Counter for directional (theta) space ! IS : Counter for frequency (sigma) space ! INTEGER ID,IS ! ! DAC2MX: Maximum deviation of action density AC2 between iterations ! REAL DAC2MX ! ! 13. Source text ! IF (MSC.GT.3) THEN DO IS=1,MSC DAC2MX=ABS((PNUMS(20)*0.0081)/ & (2.*SPCSIG(IS)*(KWAVE(IS,1)**3)*CGO(IS,1))) DO ID=1,MDC IF (ANYBIN(ID,IS) .AND. & AC2(ID,IS,KCGRD(1)).GT.AC2OLD(ID,IS)+DAC2MX) THEN AC2(ID,IS,KCGRD(1))=AC2OLD(ID,IS)+DAC2MX NFLIM(KCGRD(1)) = NFLIM(KCGRD(1)) + 1 ISLMIN(KCGRD(1)) = MIN(IS,ISLMIN(KCGRD(1))) END IF END DO IF (QB_LOC.LT.PNUMS(28)) THEN 40.16 DO ID=1,MDC IF (ANYBIN(ID,IS) .AND. & AC2(ID,IS,KCGRD(1)).LT.AC2OLD(ID,IS)-DAC2MX) THEN AC2(ID,IS,KCGRD(1))=AC2OLD(ID,IS)-DAC2MX NFLIM(KCGRD(1)) = NFLIM(KCGRD(1)) + 1 ISLMIN(KCGRD(1)) = MIN(IS,ISLMIN(KCGRD(1))) END IF END DO END IF END DO END IF RETURN END !************************************************************************ ! * SUBROUTINE HJLIM(AC2,AC2OLD,CGO,KWAVE,SPCSIG,ANYBIN,ISLMIN,NFLIM, & QB_LOC,USTAR) ! * !************************************************************************ ! USE SWCOMM3 USE TIMECOMM ! IMPLICIT NONE ! ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.61: Roop Lalbeharry ! ! 1. Updates ! ! 40.61, Nov. 06: New subroutine ! ! 2. Purpose ! ! Limits the change in action density between two iterations to ! the (directionally independent) Hersbach and Janssen (1999) limiter ! ! 3. Method ! ! The maximum change of energy density per bin is related to ! the (directionally independent) Hersbach and Janssen (1999) limiter ! This change is estimated in terms of frequency and energy density as: ! ! |D E(f,t)| = 3.0 * 1.0E-7 * g * u* * f_c * dt/ (f^4) ! ! in which f_c is the model's cut off frequency and u* the ! friction velocity and dt integration time step (sec) ! ! In terms of action density and angular frequency and for deep water, ! we have: ! ! |D N(s,t)| = C_HJ * u* / (s^3 * k) ! ! where C_HJ = (2.0 * PI)^2 * 3.0 * 1.0E-7 * s_c * dt and ! u* = max(u*, g*s*_pm/s); s*_pm = 2.*PI*f*_pm; f*_pm = 5.6 * 1.0E-3 ! ! Compare with Ris's(1997, p.36) formulation for deep water: ! ! alpha_PM ! |D N(s,t)| = factor ----------- ; factor = 0.1, alpha_PM = 0.0081 ! 2 s k^3 c_g ! ! In cases where waves are breaking the dissipation of energy ! is not limited. This is assumed to be the case when the ! fraction of breaking waves Qb is more than 1.e-5. ! ! 4. Argument variables ! LOGICAL ANYBIN(MDC,MSC) ! ! ISLMIN: Lowest sigma-index occured in applying limiter ! NFLIM : Number of frequency use of limiter ! QB_LOC: Local value of Qb (fraction of breaking waves) ! INTEGER ISLMIN(MCGRD), NFLIM(MCGRD) REAL QB_LOC REAL AC2(MDC,MSC,MCGRD) REAL AC2OLD(MDC,MSC) REAL CGO(MSC,MICMAX) REAL KWAVE(MSC,MICMAX) REAL SPCSIG(MSC) REAL USTAR(MCGRD) ! ! 6. Local variables ! ! ID : Counter for directional (theta) space ! IS : Counter for frequency (sigma) space ! INTEGER ID,IS ! ! DAC2MX: Maximum deviation of action density AC2 between iterations ! REAL DAC2MX, UFRIC_VEL, C_HJ, SPM_NOND ! ! 13. Source text ! C_HJ = PI2**2*3.0*1.0E-7*DT*SPCSIG(MSC) SPM_NOND = PI2 * 5.6 * 1.0E-3 IF (MSC.GT.3) THEN DO IS=1,MSC UFRIC_VEL = MAX(USTAR(KCGRD(1)), GRAV*SPM_NOND/SPCSIG(IS)) DAC2MX=ABS((C_HJ*UFRIC_VEL)/ & (SPCSIG(IS)**3*KWAVE(IS,1))) DO ID=1,MDC IF (ANYBIN(ID,IS) .AND. & AC2(ID,IS,KCGRD(1)).GT.AC2OLD(ID,IS)+DAC2MX) THEN AC2(ID,IS,KCGRD(1))=AC2OLD(ID,IS)+DAC2MX NFLIM(KCGRD(1)) = NFLIM(KCGRD(1)) + 1 ISLMIN(KCGRD(1)) = MIN(IS,ISLMIN(KCGRD(1))) END IF END DO IF (QB_LOC.LT.PNUMS(28)) THEN DO ID=1,MDC IF (ANYBIN(ID,IS) .AND. & AC2(ID,IS,KCGRD(1)).LT.AC2OLD(ID,IS)-DAC2MX) THEN AC2(ID,IS,KCGRD(1))=AC2OLD(ID,IS)-DAC2MX NFLIM(KCGRD(1)) = NFLIM(KCGRD(1)) + 1 ISLMIN(KCGRD(1)) = MIN(IS,ISLMIN(KCGRD(1))) END IF END DO END IF END DO END IF RETURN END !**************************************************************** ! SUBROUTINE RESCALE (AC2, ISSTOP, IDCMIN, IDCMAX, NRSCAL) ! !**************************************************************** USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE OCPCOMM4 40.41 USE M_PARALL 40.31 IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! 0. Authors ! ! 40.00: Nico Booij ! 40.23: Marcel Zijlema ! 40.30: Marcel Zijlema ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 40.00, Feb. 99: New subroutine (software moved from subroutines ! SOLBAND, SOLMT1 and SOLMAT ! 40.23, Aug. 02: Store number of frequency use of rescaling ! 40.30, Mar. 03: correcting indices of test point with offsets MXF, MYF ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! Remove negative values from a computed action density spectrum ! ! 3. Method ! ! Make negative action densities 0 at the expense of other action densities ! for the frequency ! ! 4. Argument variables ! ! AC2 action densities ! REAL AC2(MDC,MSC,MCGRD) ! ! ISSTOP maximum frequency counter in this sweep ! INTEGER ISSTOP ! ! IDCMIN Integer array containing minimum counter of directions ! IDCMAX Integer array containing maximum counter ! NRSCAL Number of frequency use of rescaling ! INTEGER IDCMIN(MSC), IDCMAX(MSC) INTEGER NRSCAL(MCGRD) ! ! 7. Common blocks used ! ! ! 5. SUBROUTINES CALLING ! ! SWOMPU ! ! 6. SUBROUTINES USED ! ! NONE ! ! 7. ERROR MESSAGES ! ! --- ! ! 8. REMARKS ! ! --- ! ! 9. STRUCTURE ! ! ------------------------------------------------------------- ! For all frequencies do ! Make ATOT equal to integral of action density over direction ! Make ATOTP equal to integral of positive action density ! Determine FACTOR ! If negative values do occur ! Then for all directions do ! If action density is negative ! Then make action density =0 ! Else multiply action density by FACTOR ! ------------------------------------------------------------ ! ! 10. SOURCE ! !************************************************************************ ! ! local variables ! ! IS counter of frequency ! ID counter of direction ! IDDUM uncorrected counter of direction ! INTEGER IS ,ID ,IDDUM, IENT ! ! ATOT integral of action density for one frequency ! ATOTP integral of positive action density for one frequency ! FACTOR ! REAL ATOT ,ATOTP ,FACTOR ! ! NEGVAL if True, there are negative values in the spectrum ! LOGICAL NEGVAL ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'RESCALE') ! ! *** if negative action density occur rescale with a factor *** ! *** only the sector computed is rescaled !! *** ! DO 180 IS = 1 , ISSTOP ATOT = 0. ATOTP = 0. FACTOR = 0. NEGVAL = .FALSE. DO 160 IDDUM = IDCMIN(IS), IDCMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 ATOT = ATOT + AC2(ID,IS,KCGRD(1)) IF ( AC2(ID,IS,KCGRD(1)) .LT. 0. ) THEN NRSCAL(KCGRD(1)) = NRSCAL(KCGRD(1)) + 1 NEGVAL = .TRUE. ELSE ATOTP = ATOTP + AC2(ID,IS,KCGRD(1)) END IF 160 CONTINUE IF (NEGVAL) THEN IF ( ATOTP .LT. 1.E-15 ) ATOTP = 1.E-15 FACTOR = ATOT / ATOTP ! ! *** rescale *** ! DO 170 IDDUM = IDCMIN(IS), IDCMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IF ( AC2(ID,IS,KCGRD(1)) .LT. 0.) THEN AC2(ID,IS,KCGRD(1)) = 0. END IF IF ( FACTOR .GE. 0. ) THEN AC2(ID,IS,KCGRD(1)) = FACTOR * AC2(ID,IS,KCGRD(1)) ENDIF 170 CONTINUE ! IF ( ITEST .GE. 120 .AND. TESTFL ) & WRITE (PRINTF, 171) IXCGRD(1)+MXF-2, IYCGRD(1)+MYF-2, IS, & FACTOR , ATOT, ATOTP 171 FORMAT(' Rescale in Point, Isig, Factor, ATOT, ATOTP:', & 3I4, 3(1X,E11.4)) ENDIF 180 CONTINUE RETURN END !**************************************************************** ! SUBROUTINE SWSIP ( AC2 , IMATDA, IMATRA, IMATLA, IMATUA, & IMAT5L, IMAT6U, AC2OLD, REPS , MAXIT , & IAMOUT, INOCNV, IDDLOW, IDDTOP, ISSTOP, 40.41 & IDCMIN, IDCMAX ) 40.41 ! !**************************************************************** ! USE SWCOMM1 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE OCPCOMM4 40.41 USE M_PARALL 40.31 IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering and Geosciences | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmer: Marcel Zijlema | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.23: Marcel Zijlema ! 40.30: Marcel Zijlema ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 40.23, Oct. 02: New subroutine ! 40.30, Mar. 03: introduction distributed-memory approach using MPI ! 40.41, Mar. 04: parameter ALFA set to 0.0, extra test output ! and some corrections if SECTOR=0 ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! Solves penta-diagonal system of equations in ! spectral space by means of Stone's SIP solver ! ! 4. Argument variables ! ! AC2 action density ! AC2OLD action density at previous iteration ! IAMOUT control parameter indicating the amount of ! output required ! 0: no output ! 1: only fatal errors will be printed ! 2: gives output concerning the iteration process ! 3: additional information about the iteration ! is printed ! IDCMAX maximum counter in directional space ! IDCMIN minimum counter in directional space ! IDDLOW minimum direction that is propagated within a sweep ! IDDTOP maximum direction that is propagated within a sweep ! IMAT5L coefficients of lower diagonal in sigma-space ! IMAT6U coefficients of upper diagonal in sigma-space ! IMATDA coefficients of main diagonal ! IMATLA coefficients of lower diagonal in theta-space ! IMATUA coefficients of upper diagonal in theta-space ! IMATRA right-hand side ! INOCNV integer indicating number of grid points in which ! solver does not converged ! ISSTOP maximum frequency counter in a sweep ! MAXIT the maximum number of iterations to be performed in ! the linear solver ! REPS accuracy with respect to the right-hand side used ! in the following termination criterion: ! ! ||b-Ax || < reps*||b|| ! k ! INTEGER IAMOUT, INOCNV, IDDLOW, IDDTOP, ISSTOP, MAXIT INTEGER IDCMIN(MSC), IDCMAX(MSC) REAL REPS REAL AC2(MDC,MSC,MCGRD), & IMATDA(MDC,MSC), IMATRA(MDC,MSC), & IMAT5L(MDC,MSC), IMAT6U(MDC,MSC), & IMATLA(MDC,MSC), IMATUA(MDC,MSC), & AC2OLD(MDC,MSC) ! ! 5. Parameter variables ! ! ALFA relaxation parameter used in the SIP solver ! SMALL : a small number ! REAL ALFA, SMALL PARAMETER (ALFA=0.0,SMALL=1.E-15) 40.41 ! ! 6. Local variables ! ! BNORM : 2-norm of right-hand side vector ! CMAT5L: coefficients of lower diagonal in sigma-space ! obtained by an incomplete lower-upper factorization ! CMAT6U: coefficients of upper diagonal in sigma-space ! obtained by an incomplete lower-upper factorization ! CMATDA: coefficients of main diagonal obtained by an ! incomplete lower-upper factorization ! CMATLA: coefficients of lower diagonal in theta-space ! obtained by an incomplete lower-upper factorization ! CMATUA: coefficients of upper diagonal in theta-space ! obtained by an incomplete lower-upper factorization ! EPSLIN: required accuracy in the linear solver ! ICONV : indicator for convergence (1=yes, 0=no) ! ID : loop counter ! IDDL : minimum counter in theta-space of modulo MDC ! IDDT : maximum counter in theta-space of modulo MDC ! IDDUM : loop counter ! IDM : index of point ID-1 ! IDMAX : local array of maximum counter in theta-space ! IDMIN : local array of minimum counter in theta-space ! IDP : index of point ID+1 ! IENT : number of entries ! IS : loop counter ! ISM : index of point IS-1 ! ISP : index of point IS+1 ! IT : iteration count ! LOPERI: auxiliary vector meant for computation in ! periodic theta-space ! P1 : auxiliary factor ! P2 : auxiliary factor ! P3 : auxiliary factor ! RES : the residual vector ! RNORM : 2-norm of residual vector ! RNRM0 : 2-norm of initial residual vector ! UEPS : minimal accuracy based on machine precision ! UPPERI: auxiliary vector meant for computation in ! periodic theta-space ! INTEGER ICONV, ID, IDDL, IDDT, IDDUM, IDM, IDP, IENT, & IS, ISM, ISP, IT INTEGER IDMIN(MSC), IDMAX(MSC) REAL BNORM, EPSLIN, P1, P2, P3, RNORM, RNRM0, UEPS REAL RES(MDC,MSC) , CMATDA(MDC,MSC), & CMAT5L(MDC,MSC), CMAT6U(MDC,MSC), & CMATLA(MDC,MSC), CMATUA(MDC,MSC), & LOPERI(MSC) , UPPERI(MSC) ! ! 7. Common blocks used ! ! ! 8. Subroutines used ! ! STRACE Tracing routine for debugging ! ! 9. Subroutines calling ! ! SWOMPU (in SWANCOM1) ! ! 12. Structure ! ! The system of equations is solved using an incomplete ! factorization technique called Strongly Implicit Procedure ! (SIP) as described in ! ! H.L. Stone ! Iterative solution of implicit approximations of ! multidimensional partial differential equations ! SIAM J. of Numer. Anal., vol. 5, 530-558, 1968 ! ! This method constructs an incomplete lower-upper factorization ! that has the same sparsity as the original matrix. Hereby, a ! parameter alfa is used, which should be 0.0 in case of SWAN 40.41 ! (when alfa > 0.95, the method may diverge). ! ! Afterward, the resulting system is solved in an iterative manner ! by forward and backward substitutions. ! ! 13. Source text ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SWSIP') ! --- initialize arrays RES = 0. CMATDA = 0. CMATLA = 0. CMATUA = 0. CMAT5L = 0. CMAT6U = 0. LOPERI = 0. UPPERI = 0. ! --- in case of periodicity in theta-space, store values ! of matrix coefficients corresponding to left bottom and ! right top DO IS = 1, ISSTOP IF ( IDCMIN(IS).EQ.1 .AND. IDCMAX(IS).EQ.MDC ) THEN UPPERI(IS) = IMATLA( 1,IS) LOPERI(IS) = IMATUA(MDC,IS) END IF END DO ! --- when no bins fall within the sweep, i.e. SECTOR = 0, ! reset the bounds of sector as 1..MDC (routine SOLPRE ! has clear the rows in the matrix that do not belong ! to the sweep) DO IS = 1, ISSTOP IF ( IDCMIN(IS).LE.IDCMAX(IS) ) THEN IDMIN(IS) = IDCMIN(IS) IDMAX(IS) = IDCMAX(IS) ELSE IDMIN(IS) = 1 IDMAX(IS) = MDC END IF END DO IT = 0 ICONV = 0 ! --- construct L and U matrices (stored in CMAT[xx]) BNORM = 0. IS = 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 CMAT5L(ID,IS) = IMAT5L(ID,IS) CMATLA(ID,IS) = IMATLA(ID,IS) CMATDA(ID,IS) = 1./(IMATDA(ID,IS)+SMALL) CMAT6U(ID,IS) = IMAT6U(ID,IS)*CMATDA(ID,IS) CMATUA(ID,IS) = IMATUA(ID,IS)*CMATDA(ID,IS) BNORM = BNORM + IMATRA(ID,IS)*IMATRA(ID,IS) DO IDDUM = IDMIN(IS)+1, IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 P2 = ALFA*CMAT6U(IDM,IS) CMAT5L(ID,IS) = IMAT5L(ID,IS) CMATLA(ID,IS) = IMATLA(ID,IS)/(1.+P2) P2 = P2*CMATLA(ID,IS) P3 = IMATDA(ID,IS) + P2 & -CMATLA(ID,IS)*CMATUA(IDM,IS ) & +SMALL CMATDA(ID,IS) = 1./P3 CMAT6U(ID,IS) = (IMAT6U(ID,IS)-P2)*CMATDA(ID,IS) CMATUA(ID,IS) = IMATUA(ID,IS)*CMATDA(ID,IS) BNORM = BNORM + IMATRA(ID,IS)*IMATRA(ID,IS) END DO DO IS = 2, ISSTOP ISM = IS - 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 P1 = ALFA*CMATUA(ID,ISM) CMAT5L(ID,IS) = IMAT5L(ID,IS)/(1.+P1) CMATLA(ID,IS) = IMATLA(ID,IS) P1 = P1*CMAT5L(ID,IS) P3 = IMATDA(ID,IS) + P1 & -CMAT5L(ID,IS)*CMAT6U(ID,ISM) & +SMALL CMATDA(ID,IS) = 1./P3 CMAT6U(ID,IS) = IMAT6U(ID,IS)*CMATDA(ID,IS) CMATUA(ID,IS) = (IMATUA(ID,IS)-P1)*CMATDA(ID,IS) BNORM = BNORM + IMATRA(ID,IS)*IMATRA(ID,IS) DO IDDUM = IDMIN(IS)+1, IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 P1 = ALFA*CMATUA(ID ,ISM) P2 = ALFA*CMAT6U(IDM,IS ) CMAT5L(ID,IS) = IMAT5L(ID,IS)/(1.+P1) CMATLA(ID,IS) = IMATLA(ID,IS)/(1.+P2) P1 = P1*CMAT5L(ID,IS) P2 = P2*CMATLA(ID,IS) P3 = IMATDA(ID,IS) + P1 + P2 & -CMAT5L(ID,IS)*CMAT6U(ID ,ISM) & -CMATLA(ID,IS)*CMATUA(IDM,IS ) & +SMALL CMATDA(ID,IS) = 1./P3 CMAT6U(ID,IS) = (IMAT6U(ID,IS)-P2)*CMATDA(ID,IS) CMATUA(ID,IS) = (IMATUA(ID,IS)-P1)*CMATDA(ID,IS) BNORM = BNORM + IMATRA(ID,IS)*IMATRA(ID,IS) END DO END DO BNORM = SQRT(BNORM) EPSLIN = REPS*BNORM UEPS = 1000.*UNDFLW*BNORM IF ( EPSLIN.LT.UEPS .AND. BNORM.GT.0. ) THEN IF ( IAMOUT.GE.1 ) THEN WRITE (PRINTF,'(A)') & ' ++ SWSIP: the required accuracy is too small' WRITE (PRINTF,*) & ' required accuracy = ',EPSLIN WRITE (PRINTF,*) & ' appropriate accuracy = ',UEPS END IF EPSLIN = UEPS END IF ! --- solve the system by forward and backward substitutions ! in an iterative manner 10 IF ( ICONV.EQ.0 .AND. IT.LT.MAXIT ) THEN IT = IT + 1 ICONV = 1 RNORM = 0. IS = 1 ISP = IS + 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 IDDT = MOD ( IDMAX(IS) - 1 + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) & -UPPERI(IS)*AC2(IDDT,IS,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = RES(ID,IS)*CMATDA(ID,IS) DO IDDUM = IDMIN(IS)+1, IDMAX(IS)-1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMATLA(ID,IS)*RES(IDM,IS))* & CMATDA(ID,IS) END DO IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDDL = MOD ( IDMIN(IS) - 1 + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -LOPERI(IS)*AC2(IDDL,IS,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMATLA(ID,IS)*RES(IDM,IS))* & CMATDA(ID,IS) DO IS = 2, ISSTOP-1 ISM = IS - 1 ISP = IS + 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 IDDT = MOD ( IDMAX(IS) - 1 + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) & -UPPERI(IS)*AC2(IDDT,IS,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMAT5L(ID,IS)*RES(ID,ISM))* & CMATDA(ID,IS) DO IDDUM = IDMIN(IS)+1, IDMAX(IS)-1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMAT5L(ID,IS)*RES(ID ,ISM) & - CMATLA(ID,IS)*RES(IDM,IS ))* & CMATDA(ID,IS) END DO IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDDL = MOD ( IDMIN(IS) - 1 + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -LOPERI(IS)*AC2(IDDL,IS,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMAT5L(ID,IS)*RES(ID ,ISM) & - CMATLA(ID,IS)*RES(IDM,IS ))* & CMATDA(ID,IS) END DO IS = ISSTOP ISM = IS - 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 IDDT = MOD ( IDMAX(IS) - 1 + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) & -UPPERI(IS)*AC2(IDDT,IS,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMAT5L(ID,IS)*RES(ID,ISM))* & CMATDA(ID,IS) DO IDDUM = IDMIN(IS)+1, IDMAX(IS)-1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMAT5L(ID,IS)*RES(ID ,ISM) & - CMATLA(ID,IS)*RES(IDM,IS ))* & CMATDA(ID,IS) END DO IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDDL = MOD ( IDMIN(IS) - 1 + MDC , MDC ) + 1 RES(ID,IS) = IMATRA(ID,IS) & -IMATDA(ID,IS)*AC2(ID ,IS ,KCGRD(1)) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -LOPERI(IS)*AC2(IDDL,IS,KCGRD(1)) RNORM = RNORM + RES(ID,IS)*RES(ID,IS) RES(ID,IS) = (RES(ID,IS) - CMAT5L(ID,IS)*RES(ID ,ISM) & - CMATLA(ID,IS)*RES(IDM,IS ))* & CMATDA(ID,IS) IF ( RNORM.GT.1.E8 ) THEN IT = MAXIT + 1 ICONV = 0 GOTO 10 END IF RNORM=SQRT(RNORM) IF ( IAMOUT.EQ.3 .AND. IT.EQ.1 ) RNRM0 = RNORM IF ( IAMOUT.EQ.2 ) THEN WRITE (PRINTF,'(A,I3,A,E12.6)') & ' ++ SWSIP: iter = ',IT,' res = ',RNORM END IF IS = ISSTOP IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 AC2(ID,IS,KCGRD(1)) = AC2(ID,IS,KCGRD(1)) + RES(ID,IS) DO IDDUM = IDMAX(IS)-1, IDMIN(IS), -1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 RES(ID,IS) = RES(ID,IS) - CMATUA(ID,IS)*RES(IDP,IS) AC2(ID,IS,KCGRD(1)) = AC2(ID,IS,KCGRD(1)) + RES(ID,IS) END DO DO IS = ISSTOP-1, 1, -1 ISP = IS + 1 IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 RES(ID,IS) = RES(ID,IS) - CMAT6U(ID,IS)*RES(ID,ISP) AC2(ID,IS,KCGRD(1)) = AC2(ID,IS,KCGRD(1)) + RES(ID,IS) DO IDDUM = IDMAX(IS)-1, IDMIN(IS), -1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 RES(ID,IS) = RES(ID,IS) - CMAT6U(ID,IS)*RES(ID ,ISP) & - CMATUA(ID,IS)*RES(IDP,IS ) AC2(ID,IS,KCGRD(1)) = AC2(ID,IS,KCGRD(1)) + RES(ID,IS) END DO END DO IF ( RNORM.GT.UNDFLW**2 .AND. RNORM.GT.EPSLIN ) ICONV = 0 GOTO 10 END IF ! --- investigate the reason to stop IF ( ICONV.EQ.0 ) THEN AC2(:,:,KCGRD(1)) = AC2OLD(:,:) INOCNV = INOCNV + 1 END IF IF ( ICONV.EQ.0 .AND. IAMOUT.GE.1 ) THEN IF (ERRPTS.GT.0.AND.IAMMASTER) THEN WRITE(ERRPTS,100) IXCGRD(1)+MXF-1, IYCGRD(1)+MYF-1, 2 END IF 100 FORMAT (I4,1X,I4,1X,I2) WRITE (PRINTF,'(A,I5,A,I5,A)') & ' ++ SWSIP: no convergence in grid point (', & IXCGRD(1)+MXF-1,',',IYCGRD(1)+MYF-1,')' WRITE (PRINTF,'(A,I3)') & ' total number of iterations = ',IT WRITE (PRINTF,'(A,E12.6)') & ' 2-norm of the residual = ',RNORM WRITE (PRINTF,'(A,E12.6)') & ' required accuracy = ',EPSLIN ELSE IF ( IAMOUT.EQ.3 ) THEN WRITE (PRINTF,'(A,E12.6)') & ' ++ SWSIP: 2-norm of the initial residual = ',RNRM0 WRITE (PRINTF,'(A,I3)') & ' total number of iterations = ',IT WRITE (PRINTF,'(A,E12.6)') & ' 2-norm of the residual = ',RNORM END IF ! --- test output IF ( TESTFL .AND. ITEST.GE.120 ) THEN WRITE(PRTEST,*) WRITE(PRTEST,*) ' Subroutine SWSIP' WRITE(PRTEST,*) WRITE(PRTEST,200) KCGRD(1), MDC, MSC 200 FORMAT(' SWSIP : POINT MDC MSC :',3I5) WRITE(PRTEST,250) IDDLOW, IDDTOP, ISSTOP 250 FORMAT(' SWSIP : IDDLOW IDDTOP ISSTOP :',3I4) WRITE(PRTEST,*) WRITE(PRTEST,*) ' coefficients of matrix and rhs ' WRITE(PRTEST,*) WRITE(PRTEST,'(A111)') & ' IS ID IMATLA IMATDA'// & ' IMATUA IMATRA IMAT5L'// & ' IMAT6U AC2' DO IDDUM = IDDLOW, IDDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 DO IS = 1, ISSTOP WRITE(PRTEST,300) IS, ID, & IMATLA(ID,IS), IMATDA(ID,IS), & IMATUA(ID,IS), IMATRA(ID,IS), & IMAT5L(ID,IS), IMAT6U(ID,IS), & AC2(ID,IS,KCGRD(1)) 300 FORMAT(2I3,7E15.7) END DO END DO WRITE(PRTEST,*) WRITE(PRTEST,*)'IS ID LPER UPER ' DO IDDUM = IDDLOW, IDDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IF ( ID.EQ.1 .OR. ID.EQ.MDC ) THEN DO IS = 1, ISSTOP WRITE(PRTEST,350) IS, ID, LOPERI(IS), UPPERI(IS) 350 FORMAT(2I3,2E15.7) END DO END IF END DO END IF ! --- set matrix coefficients to zero IMATDA = 0. IMATRA = 0. RETURN END !**************************************************************** ! SUBROUTINE SWSOR ( AC2 , IMATDA, IMATRA, IMATLA, IMATUA, & IMAT5L, IMAT6U, AC2OLD, REPS , MAXIT , & IAMOUT, INOCNV, IDDLOW, IDDTOP, ISSTOP, & IDCMIN, IDCMAX ) ! !**************************************************************** ! USE SWCOMM1 USE SWCOMM3 USE SWCOMM4 USE OCPCOMM4 USE M_PARALL IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering and Geosciences | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmer: Marcel Zijlema | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 40.41, Nov. 04: New subroutine ! ! 2. Purpose ! ! Solves penta-diagonal system of equations in ! spectral space with point SOR method ! ! 4. Argument variables ! ! AC2 action density ! AC2OLD action density at previous iteration ! IAMOUT control parameter indicating the amount of ! output required ! 0: no output ! 1: only fatal errors will be printed ! 2: gives output concerning the iteration process ! 3: additional information about the iteration ! is printed ! IDCMAX maximum counter in directional space ! IDCMIN minimum counter in directional space ! IDDLOW minimum direction that is propagated within a sweep ! IDDTOP maximum direction that is propagated within a sweep ! IMAT5L coefficients of lower diagonal in sigma-space ! IMAT6U coefficients of upper diagonal in sigma-space ! IMATDA coefficients of main diagonal ! IMATLA coefficients of lower diagonal in theta-space ! IMATUA coefficients of upper diagonal in theta-space ! IMATRA right-hand side ! INOCNV integer indicating number of grid points in which ! solver does not converged ! ISSTOP maximum frequency counter in a sweep ! MAXIT the maximum number of iterations to be performed in ! the linear solver ! REPS relative accuracy of the final approximation ! INTEGER IAMOUT, INOCNV, IDDLOW, IDDTOP, ISSTOP, MAXIT INTEGER IDCMIN(MSC), IDCMAX(MSC) REAL REPS REAL AC2(MDC,MSC,MCGRD), & IMATDA(MDC,MSC), IMATRA(MDC,MSC), & IMAT5L(MDC,MSC), IMAT6U(MDC,MSC), & IMATLA(MDC,MSC), IMATUA(MDC,MSC), & AC2OLD(MDC,MSC) ! ! 5. Parameter variables ! ! OMEG : relaxation parameter ! REAL OMEG PARAMETER (OMEG=0.8) ! ! 6. Local variables ! ! AC2I : intermediate action density ! ICONV : indicator for convergence (1=yes, 0=no) ! ID : loop counter in theta-space ! IDDL : minimum counter in theta-space of modulo MDC ! IDDT : maximum counter in theta-space of modulo MDC ! IDDUM : loop counter ! IDINF : index of point ID with largest error in solution ! IDM : index of point ID-1 ! IDMAX : local array of maximum counter in theta-space ! IDMIN : local array of minimum counter in theta-space ! IDP : index of point ID+1 ! IENT : number of entries ! INVMDA: inverse of main diagonal ! IS : loop counter in sigma-space ! ISINF : index of point IS with largest error in solution ! ISM : index of point IS-1 ! ISP : index of point IS+1 ! IT : iteration count ! LOPERI: auxiliary vector meant for computation in ! periodic theta-space ! RES : residual ! RESM : inf-norm of residual vector ! RESM0 : inf-norm of initial residual vector ! UPPERI: auxiliary vector meant for computation in ! periodic theta-space ! INTEGER ICONV, ID, IDINF, IDDL, IDDT, IDDUM, IDM, IDP, IENT, & IS, ISINF, ISM, ISP, IT INTEGER IDMIN(MSC), IDMAX(MSC) REAL AC2I, RES, RESM, RESM0 REAL LOPERI(MSC), UPPERI(MSC), INVMDA(MDC,MSC) ! ! 7. Common blocks used ! ! ! 8. Subroutines used ! ! MSGERR Writes error message ! STRACE Tracing routine for debugging ! ! 9. Subroutines calling ! ! SWOMPU (in SWANCOM1) ! ! 12. Structure ! ! The system of equations is solved using the SOR technique in ! pointwise manner ! Note that with omeg=1, the Gauss-Seidel method is recovered ! ! Convergence is reached, if the difference between two consecutive ! iteration levels measured w.r.t. the maximum norm is smaller than ! given tolerance ! ! 13. Source text ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SWSOR') ! --- initialize arrays LOPERI = 0. UPPERI = 0. INVMDA = 0. ! --- in case of periodicity in theta-space, store values ! of matrix coefficients corresponding to left bottom and ! right top DO IS = 1, ISSTOP IF ( IDCMIN(IS).EQ.1 .AND. IDCMAX(IS).EQ.MDC ) THEN UPPERI(IS) = IMATLA( 1,IS) LOPERI(IS) = IMATUA(MDC,IS) END IF END DO ! --- when no bins fall within the sweep, i.e. SECTOR = 0, ! reset the bounds of sector as 1..MDC (routine SOLPRE ! has clear the rows in the matrix that do not belong ! to the sweep) DO IS = 1, ISSTOP IF ( IDCMIN(IS).LE.IDCMAX(IS) ) THEN IDMIN(IS) = IDCMIN(IS) IDMAX(IS) = IDCMAX(IS) ELSE IDMIN(IS) = 1 IDMAX(IS) = MDC END IF END DO ! --- store inverse of main diagonal DO IS = 1, ISSTOP DO IDDUM = IDMIN(IS), IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IF ( IMATDA(ID,IS).NE.0. ) THEN INVMDA(ID,IS) = 1./IMATDA(ID,IS) ELSE CALL MSGERR ( 3, & 'Main diagonal of spectral matrix is zero!' ) END IF END DO END DO IT = 0 ICONV = 0 ! --- start iteration process 10 IF ( ICONV.EQ.0 .AND. IT.LT.MAXIT ) THEN IT = IT + 1 ICONV = 1 RESM = 0. IDINF = 0 ISINF = 0 IS = 1 ISP = IS + 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 IDDT = MOD ( IDMAX(IS) - 1 + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) & -UPPERI(IS)*AC2(IDDT,IS,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I DO IDDUM = IDMIN(IS)+1, IDMAX(IS)-1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I END DO IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDDL = MOD ( IDMIN(IS) - 1 + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -LOPERI(IS)*AC2(IDDL,IS,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I DO IS = 2, ISSTOP-1 ISM = IS - 1 ISP = IS + 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 IDDT = MOD ( IDMAX(IS) - 1 + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) & -UPPERI(IS)*AC2(IDDT,IS,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I DO IDDUM = IDMIN(IS)+1, IDMAX(IS)-1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+ & (1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I END DO IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDDL = MOD ( IDMIN(IS) - 1 + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMAT6U(ID,IS)*AC2(ID ,ISP,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -LOPERI(IS)*AC2(IDDL,IS,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I END DO IS = ISSTOP ISM = IS - 1 IDDUM = IDMIN(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 IDDT = MOD ( IDMAX(IS) - 1 + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) & -UPPERI(IS)*AC2(IDDT,IS,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I DO IDDUM = IDMIN(IS)+1, IDMAX(IS)-1 ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDP = MOD ( IDDUM + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -IMATUA(ID,IS)*AC2(IDP,IS ,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I END DO IDDUM = IDMAX(IS) ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IDM = MOD ( IDDUM - 2 + MDC , MDC ) + 1 IDDL = MOD ( IDMIN(IS) - 1 + MDC , MDC ) + 1 AC2I = IMATRA(ID,IS) & -IMAT5L(ID,IS)*AC2(ID ,ISM,KCGRD(1)) & -IMATLA(ID,IS)*AC2(IDM,IS ,KCGRD(1)) & -LOPERI(IS)*AC2(IDDL,IS,KCGRD(1)) AC2I = AC2I*OMEG*INVMDA(ID,IS)+(1.-OMEG)*AC2(ID,IS,KCGRD(1)) RES = ABS(AC2(ID,IS,KCGRD(1)) - AC2I) IF ( RES.GT.RESM ) THEN RESM = RES IDINF = ID ISINF = IS END IF AC2(ID,IS,KCGRD(1)) = AC2I IF ( RESM.GT.1.E8 ) THEN IT = MAXIT + 1 ICONV = 0 GOTO 10 END IF IF ( IAMOUT.EQ.2 ) THEN WRITE (PRINTF,'(A,I3,A,E12.6,A,I3,A,I3,A)') & ' ++ SWSOR: iter = ',IT,' res = ',RESM, & ' in (ID,IS) = (',IDINF,',',ISINF,')' END IF IF ( IAMOUT.EQ.3 .AND. IT.EQ.1 ) RESM0 = RESM IF ( RESM.GT.REPS ) ICONV = 0 GOTO 10 END IF ! --- investigate the reason to stop IF ( ICONV.EQ.0 ) THEN AC2(:,:,KCGRD(1)) = AC2OLD(:,:) INOCNV = INOCNV + 1 END IF IF ( ICONV.EQ.0 .AND. IAMOUT.GE.1 ) THEN IF (ERRPTS.GT.0.AND.IAMMASTER) THEN WRITE(ERRPTS,100) IXCGRD(1)+MXF-1, IYCGRD(1)+MYF-1, 2 END IF 100 FORMAT (I4,1X,I4,1X,I2) WRITE (PRINTF,'(A,I5,A,I5,A)') & ' ++ SWSOR: no convergence in grid point (', & IXCGRD(1)+MXF-1,',',IYCGRD(1)+MYF-1,')' WRITE (PRINTF,'(A,I3)') & ' total number of iterations = ',IT WRITE (PRINTF,'(A,E12.6)') & ' inf-norm of the residual = ',RESM WRITE (PRINTF,'(A,E12.6)') & ' required accuracy = ',REPS ELSE IF ( IAMOUT.EQ.3 ) THEN WRITE (PRINTF,'(A,E12.6)') & ' ++ SWSOR: inf-norm of the initial residual = ',RESM0 WRITE (PRINTF,'(A,I3)') & ' total number of iterations = ',IT WRITE (PRINTF,'(A,E12.6)') & ' inf-norm of the residual = ',RESM END IF ! --- test output IF ( TESTFL .AND. ITEST.GE.120 ) THEN WRITE(PRTEST,*) WRITE(PRTEST,*) ' Subroutine SWSOR' WRITE(PRTEST,*) WRITE(PRTEST,200) KCGRD(1), MDC, MSC 200 FORMAT(' SWSOR : POINT MDC MSC :',3I5) WRITE(PRTEST,250) IDDLOW, IDDTOP, ISSTOP 250 FORMAT(' SWSOR : IDDLOW IDDTOP ISSTOP :',3I4) WRITE(PRTEST,*) WRITE(PRTEST,*) ' coefficients of matrix and rhs ' WRITE(PRTEST,*) WRITE(PRTEST,'(A111)') & ' IS ID IMATLA IMATDA'// & ' IMATUA IMATRA IMAT5L'// & ' IMAT6U AC2' DO IDDUM = IDDLOW, IDDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 DO IS = 1, ISSTOP WRITE(PRTEST,300) IS, ID, & IMATLA(ID,IS), IMATDA(ID,IS), & IMATUA(ID,IS), IMATRA(ID,IS), & IMAT5L(ID,IS), IMAT6U(ID,IS), & AC2(ID,IS,KCGRD(1)) 300 FORMAT(2I3,7E15.7) END DO END DO WRITE(PRTEST,*) WRITE(PRTEST,*)'IS ID LPER UPER ' DO IDDUM = IDDLOW, IDDTOP ID = MOD ( IDDUM - 1 + MDC , MDC ) + 1 IF ( ID.EQ.1 .OR. ID.EQ.MDC ) THEN DO IS = 1, ISSTOP WRITE(PRTEST,350) IS, ID, LOPERI(IS), UPPERI(IS) 350 FORMAT(2I3,2E15.7) END DO END IF END DO END IF ! --- set matrix coefficients to zero IMATDA = 0. IMATRA = 0. IMATLA = 0. IMATUA = 0. IMAT5L = 0. IMAT6U = 0. RETURN END !**************************************************************** ! SUBROUTINE SWMTLB ( N1, N2, M1, M2 ) ! !**************************************************************** ! USE OCPCOMM4 40.41 ! IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.31: Tim Campbell and John Cazes ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 40.31, Jul. 03: New subroutine ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! ! 2. Purpose ! ! Given global loop bounds N1 and N2, compute loop bounds ! M1 and M2 for calling thread ! ! 4. Argument variables ! ! M1 lower index of thread loop ! M2 upper index of thread loop ! N1 lower index of global loop ! N2 upper index of global loop ! INTEGER N1, N2, M1, M2 ! ! 6. Local variables ! ! ID : thread number ! IENT : number of entries ! NCH : auxiliary integer ! NTH : number of threads ! INTEGER ID, IENT, NTH, NCH !$ INTEGER OMP_GET_NUM_THREADS, OMP_GET_THREAD_NUM !$ EXTERNAL OMP_GET_NUM_THREADS, OMP_GET_THREAD_NUM ! ! 8. Subroutines used ! ! --- ! ! 9. Subroutines calling ! ! --- ! ! 10. Error messages ! ! --- ! ! 11. Remarks ! ! --- ! ! 12. Structure ! ! Description of the pseudo code ! ! 13. Source text ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SWMTLB') NTH = 1 ID = 0 !$ NTH = OMP_GET_NUM_THREADS() !$ ID = OMP_GET_THREAD_NUM() NCH = (N2-N1+1)/NTH M1 = ID*NCH+N1 M2 = (ID+1)*NCH+N1-1 IF(ID.EQ.NTH-1) M2 = N2 RETURN END !**************************************************************** ! SUBROUTINE SWSTPC ( HSACC0, HSACC1, HSACC2, SACC0 , SACC1, & SACC2 , HSDIFC, TMDIFC, DELHS , DELTM, & DEP2 , ACCUR , I1MYC , I2MYC ) ! !**************************************************************** ! USE OCPCOMM4 40.41 USE SWCOMM3 40.41 USE SWCOMM4 40.41 USE M_GENARR USE M_PARALL IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.41: Andre van der Westhuysen ! 40.41: Marcel Zijlema ! 40.93: Andre van der Westhuysen ! ! 1. Updates ! ! 40.41, Jun. 04: New subroutine ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! 40.93, Sep. 08: extended with curvature of Tm ! ! 2. Purpose ! ! Check convergence based on the relative, absolute ! and curvature values of wave height and period ! ! 4. Argument variables ! ! ACCUR indicates percentage of grid points in ! which accuracy is reached ! DELHS difference in Hs between last 2 iterations ! DELTM difference in Tm between last 2 iterations ! DEP2 depth ! HSACC0 significant wave height at iter-2 ! HSACC1 significant wave height at iter-1 ! HSACC2 significant wave height at iter ! HSDIFC difference of Hs(i) - Hs(i-2) meant for ! computation of curvature of Hs ! I1MYC lower index for thread loop over y-grid row ! I2MYC upper index for thread loop over y-grid row ! SACC0 mean wave frequency at iter-2 ! SACC1 mean wave frequency at iter-1 ! SACC2 mean wave frequency at iter ! TMDIFC difference of Tm(i) - Tm(i-2) meant for ! computation of curvature of Tm ! INTEGER I1MYC, I2MYC REAL ACCUR REAL DEP2(MCGRD) , & HSACC0(MCGRD) , & HSACC1(MCGRD) , & HSACC2(MCGRD) , & SACC0(MCGRD) , & SACC1(MCGRD) , & SACC2(MCGRD) , & DELHS(MCGRD) , & DELTM(MCGRD) , & HSDIFC(MCGRD) , & TMDIFC(MCGRD) ! ! 6. Local variables ! ! ACS2 : auxiliary variable ! ACS3 : auxiliary variable ! HSABS : absolute value of Hs ! HSCURV: curvature value of Hs ! HSDIFO: previous value of HSDIFC ! HSREL : relative value of Hs ! IACCUR: indicates number of grid points in which ! accuracy is reached ! IARR : auxiliary array meant for global reduction ! ID : counter of direction ! IENT : number of entries ! II : loop variable ! INDX : index for indirect address ! IS : counter of frequency ! IX : loop counter ! IX1 : lower index in x-direction ! IX2 : upper index in x-direction ! IY : loop counter ! IY1 : lower index in y-direction ! IY2 : upper index in y-direction ! LHEAD : logical indicating to write header ! TMABS : absolute value of Tm ! TMCURV: curvature value of Tm ! TMDIFO: previous value of TMDIFC ! TMREL : relative value of Tm ! TSTFL : indicates whether grid point is a test point ! WETGRD: number of wet grid points ! XMOM0 : zeroth moment ! XMOM1 : first moment ! INTEGER ID, IS, IENT, II, INDX, IX, IY, IX1, IX2, IY1, IY2 INTEGER IACCUR, WETGRD, IACCURt, WETGRDt, IARR(2) REAL ACS2, ACS3, HSREL ,HSABS, HSCURV, HSDIFO, TMABS, & TMREL, TMCURV, TMDIFO, XMOM0, XMOM1 LOGICAL LHEAD, TSTFL ! ! 7. Common blocks used ! COMMON/SWSTPC_MT_COM/WETGRD,IACCUR ! ! SWSTPC_MT_COM place local summed variables WETGRD and IACCUR ! in common block so they will be scoped as shared ! ! 8. Subroutines used ! ! EQREAL Boolean function which compares two REAL values ! STRACE Tracing routine for debugging ! STPNOW Logical indicating whether program must ! terminated or not ! SWREDUCE Performs a global reduction ! LOGICAL EQREAL !MPI LOGICAL STPNOW ! ! 9. Subroutines calling ! ! SWCOMP (in SWANCOM1) ! ! 12. Structure ! ! master thread initialize the shared variables ! store Hs and Tm as old values and count number of wet grid points ! compute new values of Hs and Tm ! calculate a set of accuracy parameters based on relative, ! absolute and curvature values of Hs, Tm and check accuracy ! global sum of IACCUR and WETGRD ! carry out reductions across all nodes ! ! 13. Source text SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SWSTPC') ! --- master thread initialize the shared variables !$OMP MASTER WETGRD = 0 IACCUR = 0 !$OMP END MASTER !$OMP BARRIER IF ( LMXF ) THEN IX1 = 1 ELSE IX1 = 1+IHALOX END IF IF ( LMXL ) THEN IX2 = MXC ELSE IX2 = MXC-IHALOX END IF IF ( LMYF ) THEN IY1 = I1MYC ELSE IY1 = 1+IHALOY END IF IF ( LMYL ) THEN IY2 = I2MYC ELSE IY2 = MYC-IHALOY END IF ! --- store Hs and Tm as old values and count number of wet grid points WETGRDt = 0 DO IX = IX1, IX2 DO IY = IY1, IY2 INDX = KGRPNT(IX,IY) IF ( DEP2(INDX).GT.DEPMIN ) THEN HSACC0(INDX) = MAX( 1.E-20 , HSACC1(INDX) ) HSACC1(INDX) = MAX( 1.E-20 , HSACC2(INDX) ) SACC0 (INDX) = MAX( 1.E-20 , SACC1 (INDX) ) 40.93 SACC1 (INDX) = MAX( 1.E-20 , SACC2 (INDX) ) WETGRDt = WETGRDt + 1 ELSE HSACC0(INDX) = 0. HSACC1(INDX) = 0. SACC0 (INDX) = 0. 40.93 SACC1 (INDX) = 0. END IF END DO END DO ! --- compute new values of Hs and Tm DO IX = IX1, IX2 DO IY = IY1, IY2 INDX = KGRPNT(IX,IY) IF ( DEP2(INDX).GT.DEPMIN ) THEN XMOM0 = 0. XMOM1 = 0. DO IS = 1, MSC DO ID = 1, MDC ACS2 = SPCSIG(IS)**2 * AC2(ID,IS,INDX) ACS3 = SPCSIG(IS) * ACS2 XMOM0 = XMOM0 + ACS2 XMOM1 = XMOM1 + ACS3 END DO END DO XMOM0 = XMOM0 * FRINTF * DDIR XMOM1 = XMOM1 * FRINTF * DDIR IF ( XMOM0.GT.0. ) THEN HSACC2(INDX) = MAX ( 1.E-20 , 4.*SQRT(XMOM0) ) SACC2 (INDX) = MAX ( 1.E-20 , (XMOM1/XMOM0) ) ELSE HSACC2(INDX) = 1.E-20 SACC2 (INDX) = 1.E-20 END IF END IF END DO END DO IACCURt = 0 ! --- calculate a set of accuracy parameters based on relative, ! absolute and curvature values of Hs and check accuracy LHEAD=.TRUE. DO IX = IX1, IX2 DO IY = IY1, IY2 INDX = KGRPNT(IX,IY) ! --- determine whether the point is a test point TSTFL = .FALSE. IF (NPTST.GT.0) THEN DO 20 II = 1, NPTST IF (IX.NE.XYTST(2*II-1)) GOTO 20 IF (IY.NE.XYTST(2*II )) GOTO 20 TSTFL = .TRUE. 20 CONTINUE END IF DELHS(INDX) = 0.0 DELTM(INDX) = 0.0 IF ( DEP2(INDX).GT.DEPMIN ) THEN HSABS = ABS ( HSACC2(INDX) - HSACC1(INDX) ) HSREL = HSABS / HSACC2(INDX) TMABS = ABS ( (PI2/SACC2(INDX)) - (PI2/SACC1(INDX)) ) TMREL = TMABS / SACC2(INDX) 40.93 HSDIFO = HSDIFC(INDX) HSDIFC(INDX) = 0.5*( HSACC2(INDX) - HSACC0(INDX) ) HSCURV = ABS(HSDIFC(INDX) - HSDIFO)/HSACC2(INDX) TMDIFO = TMDIFC(INDX) 40.93 TMDIFC(INDX) = 0.5*( SACC2(INDX) - SACC0(INDX) ) 40.93 TMCURV = ABS(TMDIFC(INDX) - TMDIFO)/SACC2(INDX) 40.93 DELHS(INDX) = HSABS IF (EQREAL(SACC1(INDX),1.E-20) .OR. & EQREAL(SACC2(INDX),1.E-20) ) THEN DELTM(INDX) = 0. ELSE DELTM(INDX) = TMABS END IF ! --- add gridpoint in which wave height and period have ! reached required accuracy IF ( ( HSCURV.LE.PNUMS(15) .AND. & (HSREL.LE.PNUMS(1) .OR. HSABS.LE.PNUMS(2)) ) .AND. 40.93 & ( TMCURV.LE.PNUMS(16) .AND. 40.93 & (TMREL.LE.PNUMS(1) .OR. TMABS.LE.PNUMS(3)) ) ) THEN 40.93 IACCURt = IACCURt + 1 END IF IF (TSTFL) THEN IF (LHEAD) WRITE(PRINTF,501) WRITE(PRINTF,502) IX+MXF-2, IY+MYF-2, HSABS, HSREL, & HSCURV, TMABS, TMREL, TMCURV 40.93 501 FORMAT(25X,'dHabs ','dHrel ', & 'Curvature H ', 40.93 & 'dTabs ','dTrel ', 40.93 & 'Curvature T ') 40.93 502 FORMAT(1X,SS,'(IX,IY)=(',I5,',',I5,')',' ', & 1PE13.6E2,' ',1PE13.6E2,' ',1PE13.6E2,' ', 40.93 & 1PE13.6E2,' ',1PE13.6E2,' ',1PE13.6E2) LHEAD=.FALSE. END IF END IF END DO END DO ! ! --- global sum of IACCUR and WETGRD !$OMP ATOMIC IACCUR = IACCUR + IACCURt !$OMP ATOMIC WETGRD = WETGRD + WETGRDt ! --- carry out reductions across all nodes !$OMP BARRIER !$OMP MASTER IARR(1) = IACCUR IARR(2) = WETGRD CALL SWREDUCE ( IARR, 2, SWINT, SWSUM ) !MPI IF (STPNOW()) RETURN IACCUR = IARR(1) WETGRD = IARR(2) ACCUR = CEILING(REAL(IACCUR) * 10000. / REAL(WETGRD))/100. !$OMP END MASTER !$OMP BARRIER ! ! --- test output ! !$OMP MASTER IF ( ITEST.GE.30 ) THEN WRITE(PRINTF,1002) PNUMS(1), PNUMS(2), PNUMS(15) 1002 FORMAT(' SWSTPC: DHREL DHABS CURV :',3E12.4) WRITE(PRINTF,1008) WETGRD,IACCUR,ACCUR 1008 FORMAT(' SWSTPC: WETGRD IACCUR ACCUR :',2I8,E12.4) END IF !$OMP END MASTER RETURN END !******************************************************************** ! * SUBROUTINE SETUPP (KGRPNT, MSTPDA, SETPDA, AC2, DEP2, DEPSAV, & SETUP2, XCGRID, YCGRID, SPCSIG, SPCDIR ) 40.41 30.82 ! * !******************************************************************** ! USE OCPCOMM4 40.41 USE SWCOMM3 40.41 ! IMPLICIT NONE ! ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 30.70: Nico Booij ! 30.72: IJsbrand Haagsma ! 30.81: Annette Kieftenburg ! 30.82: IJsbrand Haagsma ! 31.03: Annette Kieftenburg ! 31.04: Nico Booij ! 32.01: Roeland Ris ! 32.03: IJsbrand Haagsma ! 34.01: Jeroen Adema ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 32.01, Sept 97: New Subroutine ! 32.03, Feb. 98: Comma added in FORMAT to prevent compilation error ! 30.72, Feb. 98: Introduced generic names XCGRID, YCGRID and SPCSIG for SWAN ! 30.70, Feb. 98: transformation of radiation stress in 1D case ! 30.82, Oct. 98: Updated description of several variables ! 30.81, Dec. 98: Argument list KSCIP1 adjusted ! 34.01, Feb. 99: Introducing STPNOW ! 30.82, July 99: Corrected argumentlist SETUPP and SETUP2D ! 30.82, July 99: Corrected argumentlist KSCIP1 ! 40.41, Oct. 04: common blocks replaced by modules, include files removed ! 40.41, Dec. 04: this routine is reconsidered, cleaned up and moved to SWANCOM1 ! ! 2. Purpose ! ! computes the wave-induced forces and adds the set-up to the depth ! ! 3. Method ! ! The wave-induced setup is calculated for the one-dimensional ! mode of SWAN using the following equation: ! ! d Sxx d eta ! ----- + ( d + eta ) ----- = 0 ! d x d x ! ! This equation is integrated using the forward Euler technique ! ! For the two-dimensional case, a 2D Poisson equation in general coordinates ! is solved by means of vertex-centered finite volume method ! ! 4. Argument variables ! ! AC2 input action density ! DEPSAV input depth following from original bottom and water level ! DEP2 i/o total depth including set-up ! on entry: includes previous estimate of set-up ! on exit : includes new estimate of set-up ! KGRPNT input indirect addresses for grid points ! MSTPDA input number of (aux.) data per grid point ! value is set at 23 in SWANCOM1 40.41 ! SETPDA i/o auxiliary data for computation of set-up ! 1: x-comp of force, 2: y-comp of force, ! 3: radiation stress component RSxx, 4: RSxy, ! 5: RSyy ! SETPDA(*,6..MSTPDA) is used as work array ! SETUP2 output computed set-up ! SPCDIR input (*,1); spectral directions (radians) 30.82 ! (*,2); cosine of spectral directions 30.82 ! (*,3); sine of spectral directions 30.82 ! (*,4); cosine^2 of spectral directions 30.82 ! (*,5); cosine*sine of spectral directions 30.82 ! (*,6); sine^2 of spectral directions 30.82 ! SPCSIG input Relative frequencies in computational domain 30.72 ! in sigma-space 30.72 ! XCGRID input Coordinates of computational grid in x-direction 30.72 ! YCGRID input Coordinates of computational grid in y-direction 30.72 ! INTEGER MSTPDA, KGRPNT(MXC,MYC) ! REAL AC2(MDC,MSC,MCGRD) REAL DEP2(MCGRD) REAL DEPSAV(MCGRD) REAL SETPDA(MCGRD,MSTPDA) 40.41 REAL SETUP2(MCGRD) REAL SPCDIR(MDC,6) 30.82 REAL SPCSIG(MSC) 30.72 REAL XCGRID(MXC,MYC), YCGRID(MXC,MYC) 30.72 ! ! 5. Parameter variables ! ! --- ! ! 6. Local variables ! ! CG group velocity ! CHARS array to pass character info to MSGERR ! CK CGO*KWAVE ! DDET determinant ! DEPMAX maximum depth ! DEPLOC local depth ! DIX di/dx ! DIY di/dy ! DJX dj/dx ! DJY dj/dy ! DP1 depth in point i in 1-D case ! DP2 depth in point i+1 in 1-D case ! DS2 square of mesh length in x- or y-direction ! DXI dx/di ! DXJ dx/dj ! DYI dy/di ! DYJ dy/dj ! ELOC local energy ! ETA1 setup in point i in 1-D case ! ETA2 setup in point i+1 in 1-D case ! ID counter in directional space ! IDXMAX index of location with maximum depth ! IENT number of entries ! IF1 first non-character in string1 ! IL1 last non-character in string1 ! INDX address of current grid point (ix,iy) ! INDXB address of grid point (ix,iy-1) ! INDXL address of grid point (ix-1,iy) ! INDXR address of grid point (ix+1,iy) ! INDXU address of grid point (ix,iy+1) ! IS counter in frequency space ! IX counter in x-direction ! IXLO counter in x-direction for neighbouring grid point ! IXUP counter in x-direction for neighbouring grid point ! IY counter in y-direction ! IYLO counter in y-direction for neighbouring grid point ! IYUP counter in y-direction for neighbouring grid point ! K wavenumber ! LINK counter for neighbouring grid points ! MSGSTR string to pass message to call MSGERR ! N CGroup/CPhase ! ND derivative of N with respect to depth ! NEIGHB boolean variable indicating whether neighbouring point is wet ! RRDI 1/number of steps in i-direction ! RRDJ 1/number of steps in j-direction ! RSXX xx-component of the radiation stress ! RSXXI derivative of RSXX in i-direction ! RSXXJ derivative of RSXX in j-direction ! RSXY xy-component of the radiation stress ! RSXYI derivative of RSXY in i-direction ! RSXYJ derivative of RSXY in j-direction ! RSYY yy-component of the radiation stress ! RSYYI derivative of RSYY in i-direction ! RSYYJ derivative of RSYY in j-direction ! S_UPCOR total correction to setup (user defined and S_UPDP) ! S_UPDP setup at location with maximum depth, before correction ! SIG dummy variable for frequency ! SXX1 radiation stress in point i in 1-D case ! SXX2 radiation stress in point i+1 in 1-D case ! INTEGER IDXMAX, INDXR, INDXU, INDXB, & ID, IENT, INDX, INDXL, IS, IX, & IXLO, IXUP, IY, IYLO, IYUP, LINK ! REAL CK, DDET, DEPLOC, DEPMAX, DIX, DIY, DJX, DJY, 31.04 & DP1, DP2, DS2, DXI, DXJ, DYI, DYJ, ELOC, ETA1, ETA2, & RRDI, RRDJ, RSXX, RSXXI, RSXXJ, RSXY, & RSXYI, RSXYJ, RSYY, RSYYI, RSYYJ, & S_UPCOR, 30.82 & S_UPDP, 31.03 & SXX1 ,SXX2 REAL CG(1), K(1), N(1), ND(1), SIG(1) 30.82 INTEGER IF1, IL1 CHARACTER*20 INTSTR, CHARS(1) CHARACTER*80 MSGSTR ! LOGICAL NEIGHB ! ! 8. Subroutines used ! ! INTSTR Converts integer to string ! KSCIP1 Calculates KWAVE, CGO ! MSGERR Writes error message ! SETUP2D Computation of the change of waterlevel by waves, ! a 2D Poisson equation in general coordinates is solved ! STRACE Tracing routine for debugging ! TXPBLA Removes leading and trailing blanks in string ! ! 9. Subroutines calling ! ! SWCOMP ! ! 10. Error messages ! ! setup in dry point is unequal to zero ! ! 11. Remarks ! ! 12. Structure ! ! --------------------------------------------------------- ! For all grid points do ! If depth > DEPMIN ! Then Integrate over spectrum to compute RSxx, RSxy, RSyy ! --------------------------------------------------------- ! If one-dimensional mode of SWAN ! Then Calculate Setup in all grid points ! Else Call SETUP2 to compute setup in all grid points ! --------------------------------------------------------- ! S_UPDP is setup in deepest point ! Add user defined correction to setup 30.82 ! For all grid points do ! If dep2 > DEPMIN ! SETUP2 := SETUP2 - S_UPCOR ! If dep2 > DEPMIN ! compute new value for DEP2 ! --------------------------------------------------------- ! For all grid points do ! If depth < DEPMIN ! Then If water level + setup in neighbouring point above ! bottom level in current point ! Then make depth equal to neighbouring water level ! + SETUP - bottom level in current point ! --------------------------------------------------------- ! ! 13. Source text ! !*********************************************************************** SAVE IENT DATA IENT /0/ CALL STRACE (IENT, 'SETUPP') ! DEPMAX = 0. 31.03 IDXMAX = 0 40.41 ! 31.03 ! --- initializing SETPDA array 31.03 ! 31.03 SETPDA = 0. 40.41 ! DO IY = 1, MYC DO IX = 1, MXC INDX = KGRPNT(IX,IY) IF (INDX.GT.1) THEN IF (DEP2(INDX).GT.DEPMIN) THEN ! 31.03 ! --- seek deepest point 31.03 ! 31.03 IF (DEPSAV(INDX).GT.DEPMAX) THEN 31.03 DEPMAX = DEPSAV(INDX) 31.03 IDXMAX = INDX 40.41 ENDIF 31.03 ! ! --- compute radiation stress components RSXX, RSXY and RSYY ! RSXX = 0. RSXY = 0. RSYY = 0. DEPLOC = DEP2(INDX) 40.41 DO IS = 1, MSC SIG(1) = SPCSIG(IS) 30.82 CALL KSCIP1 (1,SIG,DEPLOC,K,CG,N,ND) 30.82 CK = CG(1) * K(1) 30.82 DO ID = 1, MDC ELOC = SIG(1) * AC2(ID,IS,INDX) 30.82 ! - 31.03 ! |{cos(Theta)}^2 for i = 4 31.03 ! SPCDIR(ID,i) is <| sin(Theta)cos(Theta) for i = 5 31.03 ! |{sin(Theta)}^2 for i = 6 31.03 ! - 31.03 ! 31.03 RSXX = RSXX + (CK*SPCDIR(ID,4)+CK - SIG(1)/2.) * ELOC 30.82 RSXY = RSXY + CK*SPCDIR(ID,5) * ELOC 31.03 RSYY = RSYY + (CK*SPCDIR(ID,6)+CK - SIG(1)/2.) * ELOC 30.82 ENDDO ENDDO ! ! --- store radiation stress components in array SETPDA ! ! DDIR is width of directional band ! FRINTF is frequency integration factor df/f ! IF (ONED) THEN 30.70 ! transform to computational direction SETPDA(INDX,3) = DDIR * FRINTF * 31.04 & ((COSPC*RSXX + SINPC*RSXY) * COSPC + 30.70 & (COSPC*RSXY + SINPC*RSYY) * SINPC) 30.70 ELSE 30.70 SETPDA(INDX,3) = RSXX * DDIR * FRINTF SETPDA(INDX,4) = RSXY * DDIR * FRINTF SETPDA(INDX,5) = RSYY * DDIR * FRINTF ENDIF 30.70 ENDIF 31.03 ENDIF ENDDO ENDDO ! IF ( ONED ) THEN ! ! *** compute on the basis of the radiation stresses the setup *** ! DO IY = 1, MYC ! *** boundary condition *** SETUP2(KGRPNT(1,IY)) = 0. ETA2 = 0. DO IX = 1, MXC-1 INDX = KGRPNT(IX ,IY) INDXR = KGRPNT(IX+1,IY) DP1 = DEP2(INDX ) DP2 = DEP2(INDXR) IF ( INDX .GT.1 .AND. DP1.GT.DEPMIN .AND. 40.41 & INDXR.GT.1 .AND. DP2.GT.DEPMIN ) THEN 40.41 ETA1 = SETUP2(INDX) SXX1 = SETPDA(INDX ,3) 40.41 31.04 SXX2 = SETPDA(INDXR,3) 40.41 31.04 ETA2 = ETA1 + ( SXX1 - SXX2 ) / ( 0.5 * ( DP2 + DP1 ) ) SETUP2(INDXR) = ETA2 ELSE SETUP2(INDXR) = 0. 40.41 END IF END DO END DO ! ELSE ! ! --- compute forces by taking derivative of radiation stress ! DO IY = 1, MYC DO IX = 1, MXC INDX = KGRPNT(IX,IY) 31.03 DEPLOC = DEP2(INDX) IF (INDX.GT.1 .AND. DEPLOC.GT.DEPMIN) THEN IF (IX.EQ.1) THEN IXLO = 1 IXUP = 2 ELSE IF (IX.EQ.MXC) THEN IXLO = MXC-1 IXUP = MXC ELSE IXLO = IX-1 IXUP = IX+1 END IF IF (DEP2(KGRPNT(IXLO,IY)).LE.DEPMIN) IXLO = IX 31.03 IF (DEP2(KGRPNT(IXUP,IY)).LE.DEPMIN) IXUP = IX 31.03 INDXL = KGRPNT(IXLO,IY) INDXR = KGRPNT(IXUP,IY) IF (IXLO.EQ.IXUP) THEN RRDI = 1.E-20 ELSE RRDI = 1. / REAL(IXUP-IXLO) END IF IF (IY.EQ.1) THEN 31.03 IYLO = 1 IYUP = 2 ELSE IF (IY.EQ.MYC) THEN IYLO = MYC-1 IYUP = MYC ELSE IYLO = IY-1 IYUP = IY+1 ENDIF IF (DEP2(KGRPNT(IX,IYLO)).LE.DEPMIN) IYLO = IY 31.03 IF (DEP2(KGRPNT(IX,IYUP)).LE.DEPMIN) IYUP = IY 31.03 INDXB = KGRPNT(IX,IYLO) INDXU = KGRPNT(IX,IYUP) IF (IYLO.EQ.IYUP) THEN RRDJ = 1.E-20 ELSE RRDJ = 1. / REAL(IYUP-IYLO) END IF ! ! --- determine (x,y) derivatives w.r.t. i and j ! DXI = RRDI * (XCGRID(IXUP,IY)-XCGRID(IXLO,IY)) DYI = RRDI * (YCGRID(IXUP,IY)-YCGRID(IXLO,IY)) DXJ = RRDJ * (XCGRID(IX,IYUP)-XCGRID(IX,IYLO)) DYJ = RRDJ * (YCGRID(IX,IYUP)-YCGRID(IX,IYLO)) ! RSXXI = RRDI * (SETPDA(INDXR,3)-SETPDA(INDXL,3)) RSXXJ = RRDJ * (SETPDA(INDXU,3)-SETPDA(INDXB,3)) 31.03 RSXYI = RRDI * (SETPDA(INDXR,4)-SETPDA(INDXL,4)) RSXYJ = RRDJ * (SETPDA(INDXU,4)-SETPDA(INDXB,4)) 31.03 RSYYI = RRDI * (SETPDA(INDXR,5)-SETPDA(INDXL,5)) RSYYJ = RRDJ * (SETPDA(INDXU,5)-SETPDA(INDXB,5)) 31.03 ! IF (IXLO.EQ.IXUP.AND.IYLO.EQ.IYUP) THEN 31.03 ! point surrounded by dry points 31.03 DIX = 0. 31.04 DIY = 0. 31.04 DJX = 0. 31.04 DJY = 0. 31.04 ELSE IF (IXLO.EQ.IXUP) THEN 31.03 ! no forces in i-direction 31.03 DS2 = DXJ**2 + DYJ**2 31.04 DIX = 0. 31.04 DIY = 0. 31.04 DJX = DXJ/DS2 31.04 DJY = DYJ/DS2 31.04 ELSE IF (IYLO.EQ.IYUP) THEN 31.03 ! no forces in j-direction 31.03 DS2 = DXI**2 + DYI**2 31.04 DIX = DXI/DS2 31.04 DIY = DYI/DS2 31.04 DJX = 0. 31.04 DJY = 0. 31.04 ELSE 31.03 ! coefficients for transformation from ! (i,j)-gradients to (x,y)-gradients DDET = DXI*DYJ - DXJ*DYI DIX = DYJ / DDET DIY = -DXJ / DDET DJX = -DYI / DDET DJY = DXI / DDET END IF 31.04 ! ! --- forces based on spatial gradients of radiation stresses SETPDA(INDX,1) = & -(RSXXI*DIX + RSXXJ*DJX + RSXYI*DIY + RSXYJ*DJY) 31.03 SETPDA(INDX,2) = & -(RSXYI*DIX + RSXYJ*DJX + RSYYI*DIY + RSYYJ*DJY) 31.03 ! END IF END DO END DO ! ! --- compute set-up in two dimensions ! CALL SETUP2D( SETUP2, XCGRID, YCGRID, SETPDA(1,1), SETPDA(1,2), 40.41 & KGRPNT, DEP2, SETPDA(1,6), SETPDA(1,15), 40.41 & SETPDA(1,16) ) 40.41 ! END IF ! IF (LSETUP.EQ.1) THEN 31.04 ! set set-up to 0 for deepest point (This is allowed because the 31.03 ! solution of a Poisson equation + constant is again a solution of 31.03 ! the same Poisson equation) 31.03 S_UPDP = SETUP2(IDXMAX) 31.03 S_UPCOR = S_UPDP - PSETUP(2) 30.82 DO IY = 1, MYC 31.03 DO IX = 1, MXC 31.03 INDX = KGRPNT(IX,IY) 31.03 IF (INDX.GT.1) THEN 31.03 IF (DEP2(INDX).GT.DEPMIN) THEN 31.03 SETUP2(INDX) = SETUP2(INDX) - S_UPCOR 30.82 ELSE IF (ABS(SETUP2(INDX)).GT.1.E-7) THEN 31.03 CHARS(1) = INTSTR(INDX) 40.41 CALL TXPBLA(CHARS(1),IF1,IL1) 40.41 MSGSTR = 'Set-up in dry point with index '// 40.41 & CHARS(1)(IF1:IL1) 40.41 CALL MSGERR ( 2, MSGSTR ) 40.41 END IF 31.03 END IF 31.03 END IF 31.03 END DO 31.03 END DO 31.03 END IF 31.04 ! ! --- include computed set-up to depth ! DO IY = 1, MYC DO IX = 1, MXC INDX = KGRPNT(IX,IY) IF (INDX.GT.1) THEN DEP2(INDX) = DEPSAV(INDX) + SETUP2(INDX) END IF END DO END DO ! ! --- check whether dry points should be inundated ! DO IY = 1, MYC DO IX = 1, MXC INDX = KGRPNT(IX,IY) ! Note: KGRPNT(.,.) = 1 means a permanently dry point! 31.03 IF (INDX.GT.1) THEN IF (DEP2(INDX).LE.DEPMIN) THEN DO LINK = 1, 4 NEIGHB = .TRUE. IF (LINK.EQ.1) THEN IF (IX.EQ.1) THEN NEIGHB = .FALSE. ELSE INDXL = KGRPNT(IX-1,IY) IF (INDXL.LE.1) NEIGHB = .FALSE. ENDIF ELSE IF (LINK.EQ.2) THEN IF (IY.EQ.1) THEN NEIGHB = .FALSE. ELSE INDXL = KGRPNT(IX,IY-1) IF (INDXL.LE.1) NEIGHB = .FALSE. ENDIF ELSE IF (LINK.EQ.3) THEN IF (IX.EQ.MXC) THEN NEIGHB = .FALSE. ELSE INDXL = KGRPNT(IX+1,IY) IF (INDXL.LE.1) NEIGHB = .FALSE. ENDIF ELSE IF (LINK.EQ.4) THEN IF (IY.EQ.MYC) THEN NEIGHB = .FALSE. ELSE INDXL = KGRPNT(IX,IY+1) IF (INDXL.LE.1) NEIGHB = .FALSE. ENDIF ENDIF IF (NEIGHB) THEN 31.03 IF (DEPSAV(INDX) + SETUP2(INDXL) .GT. DEPMIN) THEN 31.03 SETUP2(INDX) = SETUP2(INDXL) 31.03 DEP2(INDX) = DEPSAV(INDX) + SETUP2(INDXL) 31.03 ENDIF 31.03 ENDIF ENDDO ENDIF ENDIF ENDDO ENDDO ! RETURN ! end of subroutine SETUPP END !**************************************************************** ! SUBROUTINE SETUP2D ( SETUP , XCGRID, YCGRID, WFRCX, WFRCY, & KGRPNT, DEPTH , AMAT , RHS , JCTA ) ! !**************************************************************** ! USE OCPCOMM4 USE SWCOMM3 ! IMPLICIT NONE ! ! ! --|-----------------------------------------------------------|-- ! | Delft University of Technology | ! | Faculty of Civil Engineering | ! | Environmental Fluid Mechanics Section | ! | P.O. Box 5048, 2600 GA Delft, The Netherlands | ! | | ! | Programmers: The SWAN team | ! --|-----------------------------------------------------------|-- ! ! ! SWAN (Simulating WAves Nearshore); a third generation wave model ! Copyright (C) 1993-2020 Delft University of Technology ! ! This program is free software; you can redistribute it and/or ! modify it under the terms of the GNU General Public License as ! published by the Free Software Foundation; either version 2 of ! the License, or (at your option) any later version. ! ! This program is distributed in the hope that it will be useful, ! but WITHOUT ANY WARRANTY; without even the implied warranty of ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ! GNU General Public License for more details. ! ! A copy of the GNU General Public License is available at ! http://www.gnu.org/copyleft/gpl.html#SEC3 ! or by writing to the Free Software Foundation, Inc., ! 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ! ! ! 0. Authors ! ! 40.41: Marcel Zijlema ! ! 1. Updates ! ! 40.41, Dec. 04: New subroutine ! ! 2. Purpose ! ! Computation of the change of waterlevel due to waves ! ! 3. Method ! ! A 2D Poisson equation in general coordinates is solved ! Vertex-centered finite volume method is employed ! The system of equations is solved using a SOR method ! ! 4. Argument variables ! ! AMAT the coefficient matrix used in the linear system ! DEPTH water depth ! JCTA Jacobian times contravariant base vectors: ! (K) ! JCTA(I,J,K,L) contains a in cell with index point I ! L ! and point type J ! KGRPNT indirect addressing for grid points ! RHS the right-hand side vector of the system of equations ! SETUP set-up ! WFRCX x-component of wave-induced force ! WFRCY y-component of wave-induced force ! XCGRID x-coordinates of computational grid ! YCGRID y-coordinates of computational grid ! INTEGER KGRPNT(MXC,MYC) REAL XCGRID(MXC,MYC), YCGRID(MXC,MYC) REAL DEPTH(MCGRD), SETUP(MCGRD), WFRCX(MCGRD), WFRCY(MCGRD) REAL AMAT(MCGRD,9), JCTA(MCGRD,2,2,2), RHS(MCGRD) ! ! 5. Parameter variables ! ! RELAX : relaxation parameter ! = -1: relaxation parameter based on gridsizes ! <> -1: a fixed (initial) relaxation parameter ! REAL RELAX PARAMETER (RELAX=-1.) ! ! 6. Local variables ! ! CONTRB: auxiliary variable containing contribution to the matrix ! DEPF : water depth in flux point ! FACT : a factor ! IAMOUT: control parameter indicating the amount of ! output required ! 0: no output ! 1: only fatal errors will be printed ! 2: gives output concerning the iteration process ! 3: additional information about the iteration ! is printed ! ICONV : indicator for convergence (1=yes, 0=no) ! IENT : number of entries ! II : iteration count in case of omega#1 ! INDX : index counter for point (ix ,iy ) in computational grid ! INDXB : index counter for point (ix ,iy-1) in computational grid ! INDXL : index counter for point (ix-1,iy ) in computational grid ! INDXLB: index counter for point (ix-1,iy-1) in computational grid ! INDXLU: index counter for point (ix-1,iy+1) in computational grid ! INDXR : index counter for point (ix+1,iy ) in computational grid ! INDXRB: index counter for point (ix+1,iy-1) in computational grid ! INDXRU: index counter for point (ix+1,iy+1) in computational grid ! INDXU : index counter for point (ix ,iy+1) in computational grid ! IT : iteration count ! IX : counter in x-direction ! IXINF : point in x-direction with largest error in solution ! IY : counter in y-direction ! IYINF : point in y-direction with largest error in solution ! JAC : Jacobian ! MAXIT : the maximum number of iterations to be performed in ! the linear solver ! RES : residual ! RESM : inf-norm of residual vector ! RESMI : intermediate inf-norm of residual vector ! RESMO : inf-norm of residual vector at previous iteration ! RESM0 : inf-norm of initial residual vector ! REPS : relative accuracy of the final approximation ! RHOV : estimated largest real eigenvalue ! SETPI : intermediate solution for set-up ! XL : measure of convergence speed ! XOM : actual relaxation parameter ! XOMEG : optimal overrelaxation parameter for SOR method ! INTEGER IAMOUT, ICONV, IENT, INDX, INDXB, INDXL, INDXLB, INDXLU, & INDXR, INDXRB, INDXRU, INDXU, IT, IX, IXINF, IY, IYINF, & II, MAXIT REAL CONTRB, DEPF, FACT, JAC, RES, RESM, RESMI, RESMO, RESM0, & REPS, RHOV, SETPI, XL, XOM, XOMEG ! ! 7. Common blocks used ! ! ! 8. Subroutines used ! ! STRACE Tracing routine for debugging ! ! 9. Subroutines calling ! ! SETUPP ! ! 10. Error messages ! ! --- ! ! 11. Remarks ! ! 1) point type (=1,2) defines the position of the point in a cell: ! ! *-------* ! | | ! 2 | ! | | ! *---1---* ! ! * = cell corner, depth point ! ! 2) Neumann boundary condition is imposed on all the boundaries ! ! 3) The determination of the overrelaxation factor by means of ! alternatively switching between 1 and optimal omega is based ! on the method as described in ! ! E.F.F. Botta and M.H.M. Ellenbroek ! A modified SOR method for the Poisson equation in unsteady ! free-surface flow calculations ! J. Comput. Phys., vol. 60, 119-134, 1985 ! ! 12. Structure ! ! initialize some arrays ! determine contravariant base vectors times Jacobian ! build right-hand side of the system of equations ! build the matrix of the linear system ! in case of nesting put Dirichlet boundary condition ! set parameters for the solver ! determine relaxation factor ! solve the system of equations ! investigate the reason to stop ! ! 13. Source text ! SAVE IENT DATA IENT/0/ IF (LTRACE) CALL STRACE (IENT,'SETUP2D') ! --- initialize some arrays AMAT = 0. JCTA = 0. RHS = 0. ! --- determine contravariant base vector a^(1) times Jacobian ! in point type 1 DO IX = 1, MXC-1 INDX = KGRPNT(IX,1) IF ( INDX.GT.1 ) THEN JCTA(INDX,1,1,1) = 0.5*( YCGRID(IX+1,2) + & YCGRID(IX ,2) - & YCGRID(IX+1,1) - & YCGRID(IX ,1) ) JCTA(INDX,1,1,2) = 0.5*( XCGRID(IX+1,1) + & XCGRID(IX ,1) - & XCGRID(IX+1,2) - & XCGRID(IX ,2) ) END IF END DO DO IY = 2, MYC-1 DO IX = 1, MXC-1 INDX = KGRPNT(IX,IY) IF ( INDX.GT.1 ) THEN JCTA(INDX,1,1,1) = 0.25*( YCGRID(IX+1,IY+1) + & YCGRID(IX ,IY+1) - & YCGRID(IX+1,IY-1) - & YCGRID(IX ,IY-1) ) JCTA(INDX,1,1,2) = 0.25*( XCGRID(IX+1,IY-1) + & XCGRID(IX ,IY-1) - & XCGRID(IX+1,IY+1) - & XCGRID(IX ,IY+1) ) END IF END DO END DO DO IX = 1, MXC-1 INDX = KGRPNT(IX,MYC) IF ( INDX.GT.1 ) THEN JCTA(INDX,1,1,1) = 0.5*( YCGRID(IX+1,MYC ) + & YCGRID(IX ,MYC ) - & YCGRID(IX+1,MYC-1) - & YCGRID(IX ,MYC-1) ) JCTA(INDX,1,1,2) = 0.5*( XCGRID(IX+1,MYC-1) + & XCGRID(IX ,MYC-1) - & XCGRID(IX+1,MYC ) - & XCGRID(IX ,MYC ) ) END IF END DO ! --- determine contravariant base vector a^(1) times Jacobian ! in point type 2 DO IY = 1, MYC-1 DO IX = 1, MXC INDX = KGRPNT(IX,IY) IF ( INDX.GT.1 ) THEN JCTA(INDX,2,1,1) = YCGRID(IX,IY+1) - YCGRID(IX,IY ) JCTA(INDX,2,1,2) = XCGRID(IX,IY ) - XCGRID(IX,IY+1) END IF END DO END DO ! --- determine contravariant base vector a^(2) times Jacobian ! in point type 1 DO IY = 1, MYC DO IX = 1, MXC-1 INDX = KGRPNT(IX,IY) IF ( INDX.GT.1 ) THEN JCTA(INDX,1,2,1) = YCGRID(IX ,IY) - YCGRID(IX+1,IY) JCTA(INDX,1,2,2) = XCGRID(IX+1,IY) - XCGRID(IX ,IY) END IF END DO END DO ! --- determine contravariant base vector a^(2) times Jacobian ! in point type 2 DO IY = 1, MYC-1 INDX = KGRPNT(1,IY) IF ( INDX.GT.1 ) THEN JCTA(INDX,2,2,1) = 0.5*( YCGRID(1,IY+1) + & YCGRID(1,IY ) - & YCGRID(2,IY+1) - & YCGRID(2,IY ) ) JCTA(INDX,2,2,2) = 0.5*( XCGRID(2,IY+1) + & XCGRID(2,IY ) - & XCGRID(1,IY+1) - & XCGRID(1,IY ) ) END IF DO IX = 2, MXC-1 INDX = KGRPNT(IX,IY) IF ( INDX.GT.1 ) THEN JCTA(INDX,2,2,1) = 0.25*( YCGRID(IX-1,IY+1) + & YCGRID(IX-1,IY ) - & YCGRID(IX+1,IY+1) - & YCGRID(IX+1,IY ) ) JCTA(INDX,2,2,2) = 0.25*( XCGRID(IX+1,IY+1) + & XCGRID(IX+1,IY ) - & XCGRID(IX-1,IY+1) - & XCGRID(IX-1,IY ) ) END IF END DO INDX = KGRPNT(MXC,IY) IF ( INDX.GT.1 ) THEN JCTA(INDX,2,2,1) = 0.5*( YCGRID(MXC-1,IY+1) + & YCGRID(MXC-1,IY ) - & YCGRID(MXC ,IY+1) - & YCGRID(MXC ,IY ) ) JCTA(INDX,2,2,2) = 0.5*( XCGRID(MXC ,IY+1) + & XCGRID(MXC ,IY ) - & XCGRID(MXC-1,IY+1) - & XCGRID(MXC-1,IY ) ) END IF END DO ! --- build right-hand side of the system of equations ! --- interior domain DO IY = 2, MYC-1 DO IX = 2, MXC-1 INDX = KGRPNT(IX ,IY ) INDXL = KGRPNT(IX-1,IY ) INDXR = KGRPNT(IX+1,IY ) INDXB = KGRPNT(IX ,IY-1) INDXU = KGRPNT(IX ,IY+1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - 0.5*JCTA(INDX,1,1,1) & *(WFRCX(INDX)+WFRCX(INDXR)) & - 0.5*JCTA(INDX,1,1,2) & *(WFRCY(INDX)+WFRCY(INDXR)) END IF ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + 0.5*JCTA(INDXL,1,1,1) & *(WFRCX(INDXL)+WFRCX(INDX)) & + 0.5*JCTA(INDXL,1,1,2) & *(WFRCY(INDXL)+WFRCY(INDX)) END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - 0.5*JCTA(INDX,2,2,1) & *(WFRCX(INDX)+WFRCX(INDXU)) & - 0.5*JCTA(INDX,2,2,2) & *(WFRCY(INDX)+WFRCY(INDXU)) END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + 0.5*JCTA(INDXB,2,2,1) & *(WFRCX(INDXB)+WFRCX(INDX)) & + 0.5*JCTA(INDXB,2,2,2) & *(WFRCY(INDXB)+WFRCY(INDX)) END IF END IF END DO END DO ! --- lower boundary (IY=1) DO IX = 2, MXC-1 INDX = KGRPNT(IX ,1) INDXL = KGRPNT(IX-1,1) INDXR = KGRPNT(IX+1,1) INDXU = KGRPNT(IX ,2) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - 0.5*JCTA(INDX,1,1,1) & *(WFRCX(INDX)+WFRCX(INDXR)) & - 0.5*JCTA(INDX,1,1,2) & *(WFRCY(INDX)+WFRCY(INDXR)) END IF ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + 0.5*JCTA(INDXL,1,1,1) & *(WFRCX(INDXL)+WFRCX(INDX)) & + 0.5*JCTA(INDXL,1,1,2) & *(WFRCY(INDXL)+WFRCY(INDX)) END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - JCTA(INDX,2,2,1) & *(WFRCX(INDX)+WFRCX(INDXU)) & - JCTA(INDX,2,2,2) & *(WFRCY(INDX)+WFRCY(INDXU)) END IF END IF END DO ! --- upper boundary (IY=MYC) DO IX = 2, MXC-1 INDX = KGRPNT(IX ,MYC ) INDXL = KGRPNT(IX-1,MYC ) INDXR = KGRPNT(IX+1,MYC ) INDXB = KGRPNT(IX ,MYC-1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - 0.5*JCTA(INDX,1,1,1) & *(WFRCX(INDX)+WFRCX(INDXR)) & - 0.5*JCTA(INDX,1,1,2) & *(WFRCY(INDX)+WFRCY(INDXR)) END IF ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + 0.5*JCTA(INDXL,1,1,1) & *(WFRCX(INDXL)+WFRCX(INDX)) & + 0.5*JCTA(INDXL,1,1,2) & *(WFRCY(INDXL)+WFRCY(INDX)) END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + JCTA(INDXB,2,2,1) & *(WFRCX(INDXB)+WFRCX(INDX)) & + JCTA(INDXB,2,2,2) & *(WFRCY(INDXB)+WFRCY(INDX)) END IF END IF END DO ! --- left boundary (IX=1) DO IY = 2, MYC-1 INDX = KGRPNT(1,IY ) INDXR = KGRPNT(2,IY ) INDXB = KGRPNT(1,IY-1) INDXU = KGRPNT(1,IY+1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - JCTA(INDX,1,1,1) & *(WFRCX(INDX)+WFRCX(INDXR)) & - JCTA(INDX,1,1,2) & *(WFRCY(INDX)+WFRCY(INDXR)) END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - 0.5*JCTA(INDX,2,2,1) & *(WFRCX(INDX)+WFRCX(INDXU)) & - 0.5*JCTA(INDX,2,2,2) & *(WFRCY(INDX)+WFRCY(INDXU)) END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + 0.5*JCTA(INDXB,2,2,1) & *(WFRCX(INDXB)+WFRCX(INDX)) & + 0.5*JCTA(INDXB,2,2,2) & *(WFRCY(INDXB)+WFRCY(INDX)) END IF END IF END DO ! --- right boundary (IX=MXC) DO IY = 2, MYC-1 INDX = KGRPNT(MXC ,IY ) INDXL = KGRPNT(MXC-1,IY ) INDXB = KGRPNT(MXC ,IY-1) INDXU = KGRPNT(MXC ,IY+1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + JCTA(INDXL,1,1,1) & *(WFRCX(INDXL)+WFRCX(INDX)) & + JCTA(INDXL,1,1,2) & *(WFRCY(INDXL)+WFRCY(INDX)) END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - 0.5*JCTA(INDX,2,2,1) & *(WFRCX(INDX)+WFRCX(INDXU)) & - 0.5*JCTA(INDX,2,2,2) & *(WFRCY(INDX)+WFRCY(INDXU)) END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + 0.5*JCTA(INDXB,2,2,1) & *(WFRCX(INDXB)+WFRCX(INDX)) & + 0.5*JCTA(INDXB,2,2,2) & *(WFRCY(INDXB)+WFRCY(INDX)) END IF END IF END DO ! --- left-lower corner (IX=1,IY=1) INDX = KGRPNT(1,1) INDXR = KGRPNT(2,1) INDXU = KGRPNT(1,2) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - JCTA(INDX,1,1,1) & *(WFRCX(INDX)+WFRCX(INDXR)) & - JCTA(INDX,1,1,2) & *(WFRCY(INDX)+WFRCY(INDXR)) END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - JCTA(INDX,2,2,1) & *(WFRCX(INDX)+WFRCX(INDXU)) & - JCTA(INDX,2,2,2) & *(WFRCY(INDX)+WFRCY(INDXU)) END IF END IF ! --- right-lower corner (IX=MXC,IY=1) INDX = KGRPNT(MXC ,1) INDXL = KGRPNT(MXC-1,1) INDXU = KGRPNT(MXC ,2) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + JCTA(INDXL,1,1,1) & *(WFRCX(INDXL)+WFRCX(INDX)) & + JCTA(INDXL,1,1,2) & *(WFRCY(INDXL)+WFRCY(INDX)) END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - JCTA(INDX,2,2,1) & *(WFRCX(INDX)+WFRCX(INDXU)) & - JCTA(INDX,2,2,2) & *(WFRCY(INDX)+WFRCY(INDXU)) END IF END IF ! --- left-upper corner (IX=1,IY=MYC) INDX = KGRPNT(1,MYC ) INDXR = KGRPNT(2,MYC ) INDXB = KGRPNT(1,MYC-1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) - JCTA(INDX,1,1,1) & *(WFRCX(INDX)+WFRCX(INDXR)) & - JCTA(INDX,1,1,2) & *(WFRCY(INDX)+WFRCY(INDXR)) END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + JCTA(INDXB,2,2,1) & *(WFRCX(INDXB)+WFRCX(INDX)) & + JCTA(INDXB,2,2,2) & *(WFRCY(INDXB)+WFRCY(INDX)) END IF END IF ! --- right-upper corner (IX=MXC,IY=MYC) INDX = KGRPNT(MXC ,MYC ) INDXL = KGRPNT(MXC-1,MYC ) INDXB = KGRPNT(MXC ,MYC-1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + JCTA(INDXL,1,1,1) & *(WFRCX(INDXL)+WFRCX(INDX)) & + JCTA(INDXL,1,1,2) & *(WFRCY(INDXL)+WFRCY(INDX)) END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN RHS(INDX) = RHS(INDX) + JCTA(INDXB,2,2,1) & *(WFRCX(INDXB)+WFRCX(INDX)) & + JCTA(INDXB,2,2,2) & *(WFRCY(INDXB)+WFRCY(INDX)) END IF END IF ! --- build the matrix of the linear system ! --- interior domain DO IY = 2, MYC-1 DO IX = 2, MXC-1 INDX = KGRPNT(IX ,IY ) INDXL = KGRPNT(IX-1,IY ) INDXR = KGRPNT(IX+1,IY ) INDXB = KGRPNT(IX ,IY-1) INDXU = KGRPNT(IX ,IY+1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDX)+DEPTH(INDXR)) JAC = JCTA(INDX,1,1,1)*JCTA(INDX,1,2,2) - & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,1,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,6) = AMAT(INDX,6) + CONTRB CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,2,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,2)) AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) - 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDXL)+DEPTH(INDX)) JAC = JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,2) - & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,1,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,5) = AMAT(INDX,5) - CONTRB CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) + 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDX)+DEPTH(INDXU)) JAC = JCTA(INDX,2,1,1)*JCTA(INDX,2,2,2) - & JCTA(INDX,2,1,2)*JCTA(INDX,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,2,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,8) = AMAT(INDX,8) + CONTRB CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,1,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,1,2)) AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) - 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDXB)+DEPTH(INDX)) JAC = JCTA(INDXB,2,1,1)*JCTA(INDXB,2,2,2) - & JCTA(INDXB,2,1,2)*JCTA(INDXB,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,2,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,3) = AMAT(INDX,3) - CONTRB CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,1,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,1,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) + 0.25*CONTRB AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB END IF END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF END DO END DO ! --- lower boundary (IY=1) DO IX = 2, MXC-1 INDX = KGRPNT(IX ,1) INDXL = KGRPNT(IX-1,1) INDXR = KGRPNT(IX+1,1) INDXU = KGRPNT(IX ,2) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDX)+DEPTH(INDXR)) JAC = JCTA(INDX,1,1,1)*JCTA(INDX,1,2,2) - & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,1,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,6) = AMAT(INDX,6) + CONTRB CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,2,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,2)) AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) - 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDXL)+DEPTH(INDX)) JAC = JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,2) - & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,1,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,5) = AMAT(INDX,5) - CONTRB CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) + 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN DEPF = DEPTH(INDX)+DEPTH(INDXU) JAC = JCTA(INDX,2,1,1)*JCTA(INDX,2,2,2) - & JCTA(INDX,2,1,2)*JCTA(INDX,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,2,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,8) = AMAT(INDX,8) + CONTRB CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,1,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,1,2)) AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) - 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF AMAT(INDX,5) = AMAT(INDX,5) + 2.*AMAT(INDX,2) AMAT(INDX,7) = AMAT(INDX,7) - AMAT(INDX,2) AMAT(INDX,2) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,3) AMAT(INDX,8) = AMAT(INDX,8) - AMAT(INDX,3) AMAT(INDX,3) = 0. AMAT(INDX,6) = AMAT(INDX,6) + 2.*AMAT(INDX,4) AMAT(INDX,9) = AMAT(INDX,9) - AMAT(INDX,4) AMAT(INDX,4) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF END DO ! --- upper boundary (IY=MYC) DO IX = 2, MXC-1 INDX = KGRPNT(IX ,MYC ) INDXL = KGRPNT(IX-1,MYC ) INDXR = KGRPNT(IX+1,MYC ) INDXB = KGRPNT(IX ,MYC-1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDX)+DEPTH(INDXR)) JAC = JCTA(INDX,1,1,1)*JCTA(INDX,1,2,2) - & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,1,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,6) = AMAT(INDX,6) + CONTRB CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,2,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,2)) AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) - 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDXL)+DEPTH(INDX)) JAC = JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,2) - & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,1,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,5) = AMAT(INDX,5) - CONTRB CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) + 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN DEPF = DEPTH(INDXB)+DEPTH(INDX) JAC = JCTA(INDXB,2,1,1)*JCTA(INDXB,2,2,2) - & JCTA(INDXB,2,1,2)*JCTA(INDXB,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,2,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,3) = AMAT(INDX,3) - CONTRB CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,1,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,1,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) + 0.25*CONTRB AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB END IF AMAT(INDX,5) = AMAT(INDX,5) + 2.*AMAT(INDX,7) AMAT(INDX,2) = AMAT(INDX,2) - AMAT(INDX,7) AMAT(INDX,7) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,8) AMAT(INDX,3) = AMAT(INDX,3) - AMAT(INDX,8) AMAT(INDX,8) = 0. AMAT(INDX,6) = AMAT(INDX,6) + 2.*AMAT(INDX,9) AMAT(INDX,4) = AMAT(INDX,4) - AMAT(INDX,9) AMAT(INDX,9) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF END DO ! --- left boundary (IX=1) DO IY = 2, MYC-1 INDX = KGRPNT(1,IY ) INDXR = KGRPNT(2,IY ) INDXB = KGRPNT(1,IY-1) INDXU = KGRPNT(1,IY+1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN DEPF = DEPTH(INDX)+DEPTH(INDXR) JAC = JCTA(INDX,1,1,1)*JCTA(INDX,1,2,2) - & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,1,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,6) = AMAT(INDX,6) + CONTRB CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,2,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,2)) AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) - 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDX)+DEPTH(INDXU)) JAC = JCTA(INDX,2,1,1)*JCTA(INDX,2,2,2) - & JCTA(INDX,2,1,2)*JCTA(INDX,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,2,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,8) = AMAT(INDX,8) + CONTRB CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,1,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,1,2)) AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) - 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDXB)+DEPTH(INDX)) JAC = JCTA(INDXB,2,1,1)*JCTA(INDXB,2,2,2) - & JCTA(INDXB,2,1,2)*JCTA(INDXB,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,2,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,3) = AMAT(INDX,3) - CONTRB CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,1,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,1,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) + 0.25*CONTRB AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB END IF AMAT(INDX,3) = AMAT(INDX,3) + 2.*AMAT(INDX,2) AMAT(INDX,4) = AMAT(INDX,4) - AMAT(INDX,2) AMAT(INDX,2) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,5) AMAT(INDX,6) = AMAT(INDX,6) - AMAT(INDX,5) AMAT(INDX,5) = 0. AMAT(INDX,8) = AMAT(INDX,8) + 2.*AMAT(INDX,7) AMAT(INDX,9) = AMAT(INDX,9) - AMAT(INDX,7) AMAT(INDX,7) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF END DO ! --- right boundary (IX=MXC) DO IY = 2, MYC-1 INDX = KGRPNT(MXC ,IY ) INDXL = KGRPNT(MXC-1,IY ) INDXB = KGRPNT(MXC ,IY-1) INDXU = KGRPNT(MXC ,IY+1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN DEPF = DEPTH(INDXL)+DEPTH(INDX) JAC = JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,2) - & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,1,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,5) = AMAT(INDX,5) - CONTRB CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) + 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDX)+DEPTH(INDXU)) JAC = JCTA(INDX,2,1,1)*JCTA(INDX,2,2,2) - & JCTA(INDX,2,1,2)*JCTA(INDX,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,2,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,8) = AMAT(INDX,8) + CONTRB CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,1,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,1,2)) AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) - 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN DEPF = 0.5*(DEPTH(INDXB)+DEPTH(INDX)) JAC = JCTA(INDXB,2,1,1)*JCTA(INDXB,2,2,2) - & JCTA(INDXB,2,1,2)*JCTA(INDXB,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,2,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,3) = AMAT(INDX,3) - CONTRB CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,1,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,1,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) + 0.25*CONTRB AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB END IF AMAT(INDX,3) = AMAT(INDX,3) + 2.*AMAT(INDX,4) AMAT(INDX,2) = AMAT(INDX,2) - AMAT(INDX,4) AMAT(INDX,4) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,6) AMAT(INDX,5) = AMAT(INDX,5) - AMAT(INDX,6) AMAT(INDX,6) = 0. AMAT(INDX,8) = AMAT(INDX,8) + 2.*AMAT(INDX,9) AMAT(INDX,7) = AMAT(INDX,7) - AMAT(INDX,9) AMAT(INDX,9) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF END DO ! --- left-lower corner (IX=1,IY=1) INDX = KGRPNT(1,1) INDXR = KGRPNT(2,1) INDXU = KGRPNT(1,2) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN DEPF = DEPTH(INDX)+DEPTH(INDXR) JAC = JCTA(INDX,1,1,1)*JCTA(INDX,1,2,2) - & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,1,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,6) = AMAT(INDX,6) + CONTRB CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,2,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,2)) AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) - 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN DEPF = DEPTH(INDX)+DEPTH(INDXU) JAC = JCTA(INDX,2,1,1)*JCTA(INDX,2,2,2) - & JCTA(INDX,2,1,2)*JCTA(INDX,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,2,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,8) = AMAT(INDX,8) + CONTRB CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,1,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,1,2)) AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) - 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,3) AMAT(INDX,8) = AMAT(INDX,8) - AMAT(INDX,3) AMAT(INDX,3) = 0. AMAT(INDX,6) = AMAT(INDX,6) + 2.*AMAT(INDX,4) AMAT(INDX,9) = AMAT(INDX,9) - AMAT(INDX,4) AMAT(INDX,4) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,5) AMAT(INDX,6) = AMAT(INDX,6) - AMAT(INDX,5) AMAT(INDX,5) = 0. AMAT(INDX,8) = AMAT(INDX,8) + 2.*AMAT(INDX,7) AMAT(INDX,9) = AMAT(INDX,9) - AMAT(INDX,7) AMAT(INDX,7) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF ! --- right-lower corner (IX=MXC,IY=1) INDX = KGRPNT(MXC ,1) INDXL = KGRPNT(MXC-1,1) INDXU = KGRPNT(MXC ,2) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN DEPF = DEPTH(INDXL)+DEPTH(INDX) JAC = JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,2) - & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,1,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,5) = AMAT(INDX,5) - CONTRB CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) + 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB END IF ! --- contribution of upper flux IF ( INDXU.GT.1 .AND. DEPTH(INDXU).GT.DEPMIN ) THEN DEPF = DEPTH(INDX)+DEPTH(INDXU) JAC = JCTA(INDX,2,1,1)*JCTA(INDX,2,2,2) - & JCTA(INDX,2,1,2)*JCTA(INDX,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,2,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,8) = AMAT(INDX,8) + CONTRB CONTRB = FACT*(JCTA(INDX,2,2,1)*JCTA(INDX,2,1,1)+ & JCTA(INDX,2,2,2)*JCTA(INDX,2,1,2)) AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) - 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF AMAT(INDX,5) = AMAT(INDX,5) + 2.*AMAT(INDX,2) AMAT(INDX,7) = AMAT(INDX,7) - AMAT(INDX,2) AMAT(INDX,2) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,3) AMAT(INDX,8) = AMAT(INDX,8) - AMAT(INDX,3) AMAT(INDX,3) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,6) AMAT(INDX,5) = AMAT(INDX,5) - AMAT(INDX,6) AMAT(INDX,6) = 0. AMAT(INDX,8) = AMAT(INDX,8) + 2.*AMAT(INDX,9) AMAT(INDX,7) = AMAT(INDX,7) - AMAT(INDX,9) AMAT(INDX,9) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF ! --- left-upper corner (IX=1,IY=MYC) INDX = KGRPNT(1,MYC ) INDXR = KGRPNT(2,MYC ) INDXB = KGRPNT(1,MYC-1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of right flux IF ( INDXR.GT.1 .AND. DEPTH(INDXR).GT.DEPMIN ) THEN DEPF = DEPTH(INDX)+DEPTH(INDXR) JAC = JCTA(INDX,1,1,1)*JCTA(INDX,1,2,2) - & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,1,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) - CONTRB AMAT(INDX,6) = AMAT(INDX,6) + CONTRB CONTRB = FACT*(JCTA(INDX,1,1,1)*JCTA(INDX,1,2,1)+ & JCTA(INDX,1,1,2)*JCTA(INDX,1,2,2)) AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) - 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB AMAT(INDX,9) = AMAT(INDX,9) + 0.25*CONTRB END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN DEPF = DEPTH(INDXB)+DEPTH(INDX) JAC = JCTA(INDXB,2,1,1)*JCTA(INDXB,2,2,2) - & JCTA(INDXB,2,1,2)*JCTA(INDXB,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,2,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,3) = AMAT(INDX,3) - CONTRB CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,1,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,1,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) + 0.25*CONTRB AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB END IF AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,8) AMAT(INDX,3) = AMAT(INDX,3) - AMAT(INDX,8) AMAT(INDX,8) = 0. AMAT(INDX,6) = AMAT(INDX,6) + 2.*AMAT(INDX,9) AMAT(INDX,4) = AMAT(INDX,4) - AMAT(INDX,9) AMAT(INDX,9) = 0. AMAT(INDX,3) = AMAT(INDX,3) + 2.*AMAT(INDX,2) AMAT(INDX,4) = AMAT(INDX,4) - AMAT(INDX,2) AMAT(INDX,2) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,5) AMAT(INDX,6) = AMAT(INDX,6) - AMAT(INDX,5) AMAT(INDX,5) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF ! --- right-upper corner (IX=MXC,IY=MYC) INDX = KGRPNT(MXC ,MYC ) INDXL = KGRPNT(MXC-1,MYC ) INDXB = KGRPNT(MXC ,MYC-1) IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN ! --- contribution of left flux IF ( INDXL.GT.1 .AND. DEPTH(INDXL).GT.DEPMIN ) THEN DEPF = DEPTH(INDXL)+DEPTH(INDX) JAC = JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,2) - & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,1,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,1,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,5) = AMAT(INDX,5) - CONTRB CONTRB = -FACT*(JCTA(INDXL,1,1,1)*JCTA(INDXL,1,2,1)+ & JCTA(INDXL,1,1,2)*JCTA(INDXL,1,2,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,3) = AMAT(INDX,3) - 0.25*CONTRB AMAT(INDX,7) = AMAT(INDX,7) + 0.25*CONTRB AMAT(INDX,8) = AMAT(INDX,8) + 0.25*CONTRB END IF ! --- contribution of bottom flux IF ( INDXB.GT.1 .AND. DEPTH(INDXB).GT.DEPMIN ) THEN DEPF = DEPTH(INDXB)+DEPTH(INDX) JAC = JCTA(INDXB,2,1,1)*JCTA(INDXB,2,2,2) - & JCTA(INDXB,2,1,2)*JCTA(INDXB,2,2,1) IF ( JAC.NE.0. ) THEN FACT = -DEPF/JAC ELSE FACT = 0. END IF CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,2,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,2,2)) AMAT(INDX,1) = AMAT(INDX,1) + CONTRB AMAT(INDX,3) = AMAT(INDX,3) - CONTRB CONTRB = -FACT*(JCTA(INDXB,2,2,1)*JCTA(INDXB,2,1,1)+ & JCTA(INDXB,2,2,2)*JCTA(INDXB,2,1,2)) AMAT(INDX,2) = AMAT(INDX,2) - 0.25*CONTRB AMAT(INDX,4) = AMAT(INDX,4) + 0.25*CONTRB AMAT(INDX,5) = AMAT(INDX,5) - 0.25*CONTRB AMAT(INDX,6) = AMAT(INDX,6) + 0.25*CONTRB END IF AMAT(INDX,5) = AMAT(INDX,5) + 2.*AMAT(INDX,7) AMAT(INDX,2) = AMAT(INDX,2) - AMAT(INDX,7) AMAT(INDX,7) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,8) AMAT(INDX,3) = AMAT(INDX,3) - AMAT(INDX,8) AMAT(INDX,8) = 0. AMAT(INDX,3) = AMAT(INDX,3) + 2.*AMAT(INDX,4) AMAT(INDX,2) = AMAT(INDX,2) - AMAT(INDX,4) AMAT(INDX,4) = 0. AMAT(INDX,1) = AMAT(INDX,1) + 2.*AMAT(INDX,6) AMAT(INDX,5) = AMAT(INDX,5) - AMAT(INDX,6) AMAT(INDX,6) = 0. END IF IF ( AMAT(INDX,1).EQ.0. ) THEN AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 RHS (INDX ) = 0.0 END IF ! --- in case of nesting put Dirichlet boundary condition IF ( LSETUP.EQ.2 ) THEN ! --- left and right boundaries DO IY = 1, MYC DO IX = 1, MXC, MXC-1 INDX = KGRPNT(IX,IY) AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN RHS(INDX) = SETUP(INDX) ELSE RHS(INDX) = 0.0 END IF END DO END DO ! --- lower and upper boundaries DO IY = 1, MYC, MYC-1 DO IX = 1, MXC INDX = KGRPNT(IX,IY) AMAT(INDX,:) = 0.0 AMAT(INDX,1) = 1.0 IF ( INDX.GT.1 .AND. DEPTH(INDX).GT.DEPMIN ) THEN RHS(INDX) = SETUP(INDX) ELSE RHS(INDX) = 0.0 END IF END DO END DO END IF ! --- set parameters for the solver REPS = PNUMS(23) IAMOUT = INT(PNUMS(24)) MAXIT = INT(PNUMS(25)) CSETUP = .TRUE. ! --- determine relaxation factor IF ( RELAX.EQ.-1. ) THEN IF ( MCGRD.LT.100 ) THEN RHOV = 1. - 1./REAL(MCGRD) ELSE IF ( MCGRD.LT.1000 ) THEN RHOV = 1. - 3./REAL(MCGRD) ELSE RHOV = 1. - 10./REAL(MCGRD) END IF XOMEG = 2./(1.+SQRT(1.-RHOV*RHOV)) ELSE XOMEG = RELAX END IF IT = 0 ICONV = 0 RESM = 1. XOM = 1. ! --- solve the system of equations 10 IF ( ICONV.EQ.0 .AND. IT.LT.MAXIT ) THEN IT = IT + 1 ICONV = 1 RESMO = RESM RESM = 0. IXINF = 0 IYINF = 0 ! --- interior domain DO IY = 2, MYC-1 DO IX = 2, MXC-1 INDX = KGRPNT(IX ,IY ) INDXL = KGRPNT(IX-1,IY ) INDXR = KGRPNT(IX+1,IY ) INDXB = KGRPNT(IX ,IY-1) INDXU = KGRPNT(IX ,IY+1) INDXLB = KGRPNT(IX-1,IY-1) INDXRB = KGRPNT(IX+1,IY-1) INDXLU = KGRPNT(IX-1,IY+1) INDXRU = KGRPNT(IX+1,IY+1) SETPI = RHS(INDX) - AMAT(INDX,2)*SETUP(INDXLB) & - AMAT(INDX,3)*SETUP(INDXB ) & - AMAT(INDX,4)*SETUP(INDXRB) & - AMAT(INDX,5)*SETUP(INDXL ) & - AMAT(INDX,6)*SETUP(INDXR ) & - AMAT(INDX,7)*SETUP(INDXLU) & - AMAT(INDX,8)*SETUP(INDXU ) & - AMAT(INDX,9)*SETUP(INDXRU) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = IX IYINF = IY END IF SETUP(INDX) = SETPI END DO END DO ! --- lower boundary (IY=1) DO IX = 2, MXC-1 INDX = KGRPNT(IX ,1) INDXL = KGRPNT(IX-1,1) INDXR = KGRPNT(IX+1,1) INDXU = KGRPNT(IX ,2) INDXLU = KGRPNT(IX-1,2) INDXRU = KGRPNT(IX+1,2) SETPI = RHS(INDX) - AMAT(INDX,5)*SETUP(INDXL ) & - AMAT(INDX,6)*SETUP(INDXR ) & - AMAT(INDX,7)*SETUP(INDXLU) & - AMAT(INDX,8)*SETUP(INDXU ) & - AMAT(INDX,9)*SETUP(INDXRU) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = IX IYINF = 1 END IF SETUP(INDX) = SETPI END DO ! --- upper boundary (IY=MYC) DO IX = 2, MXC-1 INDX = KGRPNT(IX ,MYC ) INDXL = KGRPNT(IX-1,MYC ) INDXR = KGRPNT(IX+1,MYC ) INDXB = KGRPNT(IX ,MYC-1) INDXLB = KGRPNT(IX-1,MYC-1) INDXRB = KGRPNT(IX+1,MYC-1) SETPI = RHS(INDX) - AMAT(INDX,2)*SETUP(INDXLB) & - AMAT(INDX,3)*SETUP(INDXB ) & - AMAT(INDX,4)*SETUP(INDXRB) & - AMAT(INDX,5)*SETUP(INDXL ) & - AMAT(INDX,6)*SETUP(INDXR ) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = IX IYINF = MYC END IF SETUP(INDX) = SETPI END DO ! --- left boundary (IX=1) DO IY = 2, MYC-1 INDX = KGRPNT(1,IY ) INDXR = KGRPNT(2,IY ) INDXB = KGRPNT(1,IY-1) INDXU = KGRPNT(1,IY+1) INDXRB = KGRPNT(2,IY-1) INDXRU = KGRPNT(2,IY+1) SETPI = RHS(INDX) - AMAT(INDX,3)*SETUP(INDXB ) & - AMAT(INDX,4)*SETUP(INDXRB) & - AMAT(INDX,6)*SETUP(INDXR ) & - AMAT(INDX,8)*SETUP(INDXU ) & - AMAT(INDX,9)*SETUP(INDXRU) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = 1 IYINF = IY END IF SETUP(INDX) = SETPI END DO ! --- right boundary (IX=MXC) DO IY = 2, MYC-1 INDX = KGRPNT(MXC ,IY ) INDXL = KGRPNT(MXC-1,IY ) INDXB = KGRPNT(MXC ,IY-1) INDXU = KGRPNT(MXC ,IY+1) INDXLB = KGRPNT(MXC-1,IY-1) INDXLU = KGRPNT(MXC-1,IY+1) SETPI = RHS(INDX) - AMAT(INDX,2)*SETUP(INDXLB) & - AMAT(INDX,3)*SETUP(INDXB ) & - AMAT(INDX,5)*SETUP(INDXL ) & - AMAT(INDX,7)*SETUP(INDXLU) & - AMAT(INDX,8)*SETUP(INDXU ) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = MXC IYINF = IY END IF SETUP(INDX) = SETPI END DO ! --- left-lower corner (IX=1,IY=1) INDX = KGRPNT(1,1) INDXR = KGRPNT(2,1) INDXU = KGRPNT(1,2) INDXRU = KGRPNT(2,2) SETPI = RHS(INDX) - AMAT(INDX,6)*SETUP(INDXR ) & - AMAT(INDX,8)*SETUP(INDXU ) & - AMAT(INDX,9)*SETUP(INDXRU) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = 1 IYINF = 1 END IF SETUP(INDX) = SETPI ! --- right-lower corner (IX=MXC,IY=1) INDX = KGRPNT(MXC ,1) INDXL = KGRPNT(MXC-1,1) INDXU = KGRPNT(MXC ,2) INDXLU = KGRPNT(MXC-1,2) SETPI = RHS(INDX) - AMAT(INDX,5)*SETUP(INDXL ) & - AMAT(INDX,7)*SETUP(INDXLU) & - AMAT(INDX,8)*SETUP(INDXU ) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = MXC IYINF = 1 END IF SETUP(INDX) = SETPI ! --- left-upper corner (IX=1,IY=MYC) INDX = KGRPNT(1,MYC ) INDXR = KGRPNT(2,MYC ) INDXB = KGRPNT(1,MYC-1) INDXRB = KGRPNT(2,MYC-1) SETPI = RHS(INDX) - AMAT(INDX,3)*SETUP(INDXB ) & - AMAT(INDX,4)*SETUP(INDXRB) & - AMAT(INDX,6)*SETUP(INDXR ) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = 1 IYINF = MYC END IF SETUP(INDX) = SETPI ! --- right-upper corner (IX=MXC,IY=MYC) INDX = KGRPNT(MXC ,MYC ) INDXL = KGRPNT(MXC-1,MYC ) INDXB = KGRPNT(MXC ,MYC-1) INDXLB = KGRPNT(MXC-1,MYC-1) SETPI = RHS(INDX) - AMAT(INDX,2)*SETUP(INDXLB) & - AMAT(INDX,3)*SETUP(INDXB ) & - AMAT(INDX,5)*SETUP(INDXL ) SETPI = XOM*SETPI/AMAT(INDX,1) + (1.-XOM)*SETUP(INDX) RES = ABS(SETUP(INDX) - SETPI) IF ( RES.GT.RESM ) THEN RESM = RES IXINF = MXC IYINF = MYC END IF SETUP(INDX) = SETPI IF ( RESM.GT.1.E8 ) THEN IT = MAXIT + 1 ICONV = 0 GOTO 10 END IF IF ( IAMOUT.EQ.2 ) THEN WRITE (PRINTF,'(A,I3,A,E12.6,A,I3,A,I3,A)') & ' ++ SETUP2D: iter = ',IT,' res = ',RESM, & ' in (IX,IY) = (',IXINF,',',IYINF,')' END IF IF ( IAMOUT.EQ.3 .AND. IT.EQ.1 ) RESM0 = RESM IF ( RESM.GT.REPS ) THEN IF ( XOM.NE.1. ) THEN II = II + 1 IF ( II.EQ.0 ) RESMI = RESM IF ( II.GT.0 .AND. & RESM.GT.10.*RESMI*(XOMEG-1.)**II ) XOM = 1. ELSE XL = RESM/RESMO IF ( XL.GT.0.9*RHOV*RHOV ) THEN XOM = XOMEG II = -10 END IF END IF ICONV = 0 END IF GOTO 10 END IF ! --- investigate the reason to stop IF ( ICONV.EQ.0 ) THEN CSETUP = .FALSE. IF ( RESM.GT.1.E8 ) SETUP = 0. END IF IF ( ICONV.EQ.0 .AND. IAMOUT.GE.1 ) THEN WRITE (PRINTF,'(A)') & ' ++ SETUP2D: no convergence for 2D Poisson equation' WRITE (PRINTF,'(A,I4)') & ' total number of iterations = ',IT WRITE (PRINTF,'(A,E12.6)') & ' inf-norm of the residual = ',RESM WRITE (PRINTF,'(A,E12.6)') & ' required accuracy = ',REPS ELSE IF ( IAMOUT.EQ.3 ) THEN WRITE (PRINTF,'(A,E12.6)') & ' ++ SETUP2D: inf-norm of the initial residual = ',RESM0 WRITE (PRINTF,'(A,I4)') & ' total number of iterations = ',IT WRITE (PRINTF,'(A,E12.6)') & ' inf-norm of the residual = ',RESM END IF RETURN END