source: LMDZ6/branches/Amaury_dev/libf/filtrez/lmdz_filtreg.F90 @ 5227

! $Id$

MODULE lmdz_filtreg
  USE lmdz_paramet
  IMPLICIT NONE; PRIVATE
  PUBLIC matriceun, matriceus, matricevn, matricevs, matrinvn, matrinvs, &
          inifilr, filtreg

  REAL, DIMENSION(:, :, :), ALLOCATABLE :: matriceun, matriceus, matricevn
  REAL, DIMENSION(:, :, :), ALLOCATABLE :: matricevs, matrinvn, matrinvs

CONTAINS

  SUBROUTINE filtreg(champ, nlat, nbniv, ifiltre, iaire, &
          griscal, iter)
  USE lmdz_dimensions, ONLY: iim, jjm, llm, ndm
    USE lmdz_coefils, ONLY: jfiltnu, jfiltnv, jfiltsu, jfiltsv, sddu, sddv, unsddu, unsddv, modfrstv, modfrstu

    !=======================================================================

    !   Auteur: P. Le Van        07/10/97
    !   ------

    !   Objet: filtre matriciel longitudinal ,avec les matrices precalculees
    !                 pour l'operateur  Filtre    .
    !   ------

    !   Arguments:
    !   ----------

    !  nblat                 nombre de latitudes a filtrer
    !  nbniv                 nombre de niveaux verticaux a filtrer
    !  champ(iip1,nblat,nbniv)  en entree : champ a filtrer
    !                        en sortie : champ filtre
    !  ifiltre               +1  Transformee directe
    !                        -1  Transformee inverse
    !                        +2  Filtre directe
    !                        -2  Filtre inverse

    !  iaire                 1   si champ intensif
    !                        2   si champ extensif (pondere par les aires)

    !  iter                  1   filtre simple

    !=======================================================================


    !                  Variable Intensive
    !            ifiltre = 1     filtre directe
    !            ifiltre =-1     filtre inverse

    !                  Variable Extensive
    !            ifiltre = 2     filtre directe
    !            ifiltre =-2     filtre inverse

    !



    INTEGER :: nlat, nbniv, ifiltre, iter
    INTEGER :: i, j, l, k
    INTEGER :: iim2, immjm
    INTEGER :: jdfil1, jdfil2, jffil1, jffil2, jdfil, jffil

    REAL :: champ(iip1, nlat, nbniv)

    REAL :: eignq(iim, nlat, nbniv), sdd1(iim), sdd2(iim)
    LOGICAL :: griscal
    INTEGER :: hemisph, iaire

    LOGICAL, SAVE :: first = .TRUE.

    REAL, SAVE :: sdd12(iim, 4)

    INTEGER, PARAMETER :: type_sddu = 1
    INTEGER, PARAMETER :: type_sddv = 2
    INTEGER, PARAMETER :: type_unsddu = 3
    INTEGER, PARAMETER :: type_unsddv = 4

    INTEGER :: sdd1_type, sdd2_type

    IF (iim == 1) return ! no filtre in 2D y-z

    IF (first) THEN
      sdd12(1:iim, type_sddu) = sddu(1:iim)
      sdd12(1:iim, type_sddv) = sddv(1:iim)
      sdd12(1:iim, type_unsddu) = unsddu(1:iim)
      sdd12(1:iim, type_unsddv) = unsddv(1:iim)

      first = .FALSE.
    ENDIF

    IF(ifiltre==1.OR.ifiltre==-1) &
            stop 'Pas de transformee simple dans cette version'

    IF(iter== 2)  THEN
      PRINT *, ' Pas d iteration du filtre dans cette version !'&
              &, ' Utiliser old_filtreg et repasser !'
      STOP
    ENDIF

    IF(ifiltre== -2 .AND..NOT.griscal)     THEN
      PRINT *, ' Cette routine ne calcule le filtre inverse que ' &
              , ' sur la grille des scalaires !'
      STOP
    ENDIF

    IF(ifiltre/=2 .AND.ifiltre/= - 2)  THEN
      PRINT *, ' Probleme dans filtreg car ifiltre NE 2 et NE -2' &
              , ' corriger et repasser !'
      STOP
    ENDIF

    iim2 = iim * iim
    immjm = iim * jjm

    IF(griscal)   THEN
      IF(nlat /= jjp1)  THEN
        PRINT  1111
        STOP
      ELSE

        IF(iaire==1)  THEN
          sdd1_type = type_sddv
          sdd2_type = type_unsddv
        ELSE
          sdd1_type = type_unsddv
          sdd2_type = type_sddv
        ENDIF

        ! IF( iaire.EQ.1 )  THEN
        !    CALL SCOPY(  iim,    sddv, 1,  sdd1, 1 )
        !    CALL SCOPY(  iim,  unsddv, 1,  sdd2, 1 )
        ! ELSE
        !    CALL SCOPY(  iim,  unsddv, 1,  sdd1, 1 )
        !    CALL SCOPY(  iim,    sddv, 1,  sdd2, 1 )
        ! END IF

        jdfil1 = 2
        jffil1 = jfiltnu
        jdfil2 = jfiltsu
        jffil2 = jjm
      END IF
    ELSE
      IF(nlat/=jjm)  THEN
        PRINT  2222
        STOP
      ELSE

        IF(iaire==1)  THEN
          sdd1_type = type_sddu
          sdd2_type = type_unsddu
        ELSE
          sdd1_type = type_unsddu
          sdd2_type = type_sddu
        ENDIF

        ! IF( iaire.EQ.1 )  THEN
        !    CALL SCOPY(  iim,    sddu, 1,  sdd1, 1 )
        !    CALL SCOPY(  iim,  unsddu, 1,  sdd2, 1 )
        ! ELSE
        !    CALL SCOPY(  iim,  unsddu, 1,  sdd1, 1 )
        !    CALL SCOPY(  iim,    sddu, 1,  sdd2, 1 )
        ! END IF

        jdfil1 = 1
        jffil1 = jfiltnv
        jdfil2 = jfiltsv
        jffil2 = jjm
      END IF
    END IF

    DO hemisph = 1, 2

      IF (hemisph==1)  THEN
        jdfil = jdfil1
        jffil = jffil1
      ELSE
        jdfil = jdfil2
        jffil = jffil2
      END IF

      DO l = 1, nbniv
        DO j = jdfil, jffil
          DO i = 1, iim
            champ(i, j, l) = champ(i, j, l) * sdd12(i, sdd1_type) ! sdd1(i)
          END DO
        END DO
      END DO

      IF(hemisph == 1)      THEN

        IF(ifiltre == -2)   THEN

          DO j = jdfil, jffil
#ifdef BLAS
              CALL SGEMM("N", "N", iim, nbniv, iim, 1.0, &
                    matrinvn(1,1,j), &
                    iim, champ(1,j,1), iip1*nlat, 0.0, &
                    eignq(1,j-jdfil+1,1), iim*nlat)
#else
            eignq(:, j - jdfil + 1, :) &
                    = matmul(matrinvn(:, :, j), champ(:iim, j, :))
#endif
          END DO

        ELSE IF (griscal)     THEN

          DO j = jdfil, jffil
#ifdef BLAS
              CALL SGEMM("N", "N", iim, nbniv, iim, 1.0, &
                    matriceun(1,1,j), &
                    iim, champ(1,j,1), iip1*nlat, 0.0, &
                    eignq(1,j-jdfil+1,1), iim*nlat)
#else
            eignq(:, j - jdfil + 1, :) &
                    = matmul(matriceun(:, :, j), champ(:iim, j, :))
#endif
          END DO

        ELSE

          DO j = jdfil, jffil
#ifdef BLAS
              CALL SGEMM("N", "N", iim, nbniv, iim, 1.0, &
                    matricevn(1,1,j), &
                    iim, champ(1,j,1), iip1*nlat, 0.0, &
                    eignq(1,j-jdfil+1,1), iim*nlat)
#else
            eignq(:, j - jdfil + 1, :) &
                    = matmul(matricevn(:, :, j), champ(:iim, j, :))
#endif
          END DO

        ENDIF

      ELSE

        IF(ifiltre == -2)   THEN

          DO j = jdfil, jffil
#ifdef BLAS
              CALL SGEMM("N", "N", iim, nbniv, iim, 1.0, &
                    matrinvs(1,1,j-jfiltsu+1), &
                    iim, champ(1,j,1), iip1*nlat, 0.0, &
                    eignq(1,j-jdfil+1,1), iim*nlat)
#else
            eignq(:, j - jdfil + 1, :) &
                    = matmul(matrinvs(:, :, j - jfiltsu + 1), &
                    champ(:iim, j, :))
#endif
          END DO

        ELSE IF (griscal)     THEN

          DO j = jdfil, jffil
#ifdef BLAS
              CALL SGEMM("N", "N", iim, nbniv, iim, 1.0, &
                    matriceus(1,1,j-jfiltsu+1), &
                    iim, champ(1,j,1), iip1*nlat, 0.0, &
                    eignq(1,j-jdfil+1,1), iim*nlat)
#else
            eignq(:, j - jdfil + 1, :) &
                    = matmul(matriceus(:, :, j - jfiltsu + 1), &
                    champ(:iim, j, :))
#endif
          END DO

        ELSE

          DO j = jdfil, jffil
#ifdef BLAS
              CALL SGEMM("N", "N", iim, nbniv, iim, 1.0, &
                    matricevs(1,1,j-jfiltsv+1), &
                    iim, champ(1,j,1), iip1*nlat, 0.0, &
                    eignq(1,j-jdfil+1,1), iim*nlat)
#else
            eignq(:, j - jdfil + 1, :) &
                    = matmul(matricevs(:, :, j - jfiltsv + 1), &
                    champ(:iim, j, :))
#endif
          END DO

        ENDIF

      ENDIF

      IF(ifiltre== 2)  THEN

        DO l = 1, nbniv
          DO j = jdfil, jffil
            DO i = 1, iim
              champ(i, j, l) = &
                      (champ(i, j, l) + eignq(i, j - jdfil + 1, l)) &
                              * sdd12(i, sdd2_type) ! sdd2(i)
            END DO
          END DO
        END DO

      ELSE

        DO l = 1, nbniv
          DO j = jdfil, jffil
            DO i = 1, iim
              champ(i, j, l) = &
                      (champ(i, j, l) - eignq(i, j - jdfil + 1, l)) &
                              * sdd12(i, sdd2_type) ! sdd2(i)
            END DO
          END DO
        END DO

      ENDIF

      DO l = 1, nbniv
        DO j = jdfil, jffil
          champ(iip1, j, l) = champ(1, j, l)
        END DO
      END DO

    ENDDO

    1111   FORMAT(//20x, 'ERREUR dans le dimensionnement du tableau  CHAMP a&
            &     filtrer, sur la grille des scalaires'/)
    2222   FORMAT(//20x, 'ERREUR dans le dimensionnement du tableau CHAMP a fi&
            &     ltrer, sur la grille de V ou de Z'/)
    RETURN
  END SUBROUTINE filtreg

  SUBROUTINE inifgn(dv)

    !    ...  H.Upadyaya , O.Sharma  ...

    USE lmdz_coefils, ONLY: sddv, sddu, unsddu, unsddv, eignfnv, eignfnu
    USE lmdz_ssum_scopy, ONLY: ssum
    USE lmdz_comgeom

USE lmdz_dimensions, ONLY: iim, jjm, llm, ndm
  USE lmdz_paramet
    IMPLICIT NONE




    REAL :: vec(iim, iim), vec1(iim, iim)
    REAL :: dlonu(iim), dlonv(iim)
    REAL :: du(iim), dv(iim), d(iim)
    REAL :: pi
    INTEGER :: i, j, k, imm1, nrot
    !

    imm1 = iim - 1
    pi = 2. * ASIN(1.)

    DO i = 1, iim
      dlonu(i) = xprimu(i)
      dlonv(i) = xprimv(i)
    END DO

    DO i = 1, iim
      sddv(i) = SQRT(dlonv(i))
      sddu(i) = SQRT(dlonu(i))
      unsddu(i) = 1. / sddu(i)
      unsddv(i) = 1. / sddv(i)
    END DO

    DO j = 1, iim
      DO i = 1, iim
        vec(i, j) = 0.
        vec1(i, j) = 0.
        eignfnv(i, j) = 0.
        eignfnu(i, j) = 0.
      END DO
    END DO


    eignfnv(1, 1) = -1.
    eignfnv(iim, 1) = 1.
    DO i = 1, imm1
      eignfnv(i + 1, i + 1) = -1.
      eignfnv(i, i + 1) = 1.
    END DO
    DO j = 1, iim
      DO i = 1, iim
        eignfnv(i, j) = eignfnv(i, j) / (sddu(i) * sddv(j))
      END DO
    END DO
    DO j = 1, iim
      DO i = 1, iim
        eignfnu(i, j) = -eignfnv(j, i)
      END DO
    END DO

    DO j = 1, iim
      DO i = 1, iim
        vec (i, j) = 0.0
        vec1(i, j) = 0.0
        DO k = 1, iim
          vec (i, j) = vec(i, j) + eignfnu(i, k) * eignfnv(k, j)
          vec1(i, j) = vec1(i, j) + eignfnv(i, k) * eignfnu(k, j)
        ENDDO
      ENDDO
    ENDDO


    CALL jacobi(vec, iim, iim, dv, eignfnv, nrot)
    CALL acc(eignfnv, d, iim)
    CALL eigen_sort(dv, eignfnv, iim, iim)

    CALL jacobi(vec1, iim, iim, du, eignfnu, nrot)
    CALL acc(eignfnu, d, iim)
    CALL eigen_sort(du, eignfnu, iim, iim)

    !c   ancienne version avec appels IMSL

    ! CALL MXM(eignfnu,iim,eignfnv,iim,vec,iim)
    ! CALL MXM(eignfnv,iim,eignfnu,iim,vec1,iim)
    !     CALL EVCSF(iim,vec,iim,dv,eignfnv,iim)
    ! CALL acc(eignfnv,d,iim)
    ! CALL eigen(eignfnv,dv)

    ! CALL EVCSF(iim,vec1,iim,du,eignfnu,iim)
    ! CALL acc(eignfnu,d,iim)
    ! CALL eigen(eignfnu,du)

    RETURN
  END SUBROUTINE inifgn

  SUBROUTINE JACOBI(A, N, NP, D, V, NROT)
    IMPLICIT NONE
    ! Arguments:
    INTEGER, INTENT(IN) :: N
    INTEGER, INTENT(IN) :: NP
    INTEGER, INTENT(OUT) :: NROT
    REAL, INTENT(INOUT) :: A(NP, NP)
    REAL, INTENT(OUT) :: D(NP)
    REAL, INTENT(OUT) :: V(NP, NP)

    ! local variables:
    INTEGER :: IP, IQ, I, J
    REAL :: SM, TRESH, G, H, T, THETA, C, S, TAU
    REAL :: B(N)
    REAL :: Z(N)

    DO IP = 1, N
      DO IQ = 1, N
        V(IP, IQ) = 0.
      ENDDO
      V(IP, IP) = 1.
    ENDDO
    DO IP = 1, N
      B(IP) = A(IP, IP)
      D(IP) = B(IP)
      Z(IP) = 0.
    ENDDO
    NROT = 0
    DO I = 1, 50 ! 50? I suspect this should be NP
      !     but convergence is fast enough anyway
      SM = 0.
      DO IP = 1, N - 1
        DO IQ = IP + 1, N
          SM = SM + ABS(A(IP, IQ))
        ENDDO
      ENDDO
      IF(SM==0.)RETURN
      IF(I<4)THEN
        TRESH = 0.2 * SM / N**2
      ELSE
        TRESH = 0.
      ENDIF
      DO IP = 1, N - 1
        DO IQ = IP + 1, N
          G = 100. * ABS(A(IP, IQ))
          IF((I>4).AND.(ABS(D(IP)) + G==ABS(D(IP))) &
                  .AND.(ABS(D(IQ)) + G==ABS(D(IQ))))THEN
            A(IP, IQ) = 0.
          ELSE IF(ABS(A(IP, IQ))>TRESH)THEN
            H = D(IQ) - D(IP)
            IF(ABS(H) + G==ABS(H))THEN
              T = A(IP, IQ) / H
            ELSE
              THETA = 0.5 * H / A(IP, IQ)
              T = 1. / (ABS(THETA) + SQRT(1. + THETA**2))
              IF(THETA<0.)T = -T
            ENDIF
            C = 1. / SQRT(1 + T**2)
            S = T * C
            TAU = S / (1. + C)
            H = T * A(IP, IQ)
            Z(IP) = Z(IP) - H
            Z(IQ) = Z(IQ) + H
            D(IP) = D(IP) - H
            D(IQ) = D(IQ) + H
            A(IP, IQ) = 0.
            DO J = 1, IP - 1
              G = A(J, IP)
              H = A(J, IQ)
              A(J, IP) = G - S * (H + G * TAU)
              A(J, IQ) = H + S * (G - H * TAU)
            ENDDO
            DO J = IP + 1, IQ - 1
              G = A(IP, J)
              H = A(J, IQ)
              A(IP, J) = G - S * (H + G * TAU)
              A(J, IQ) = H + S * (G - H * TAU)
            ENDDO
            DO J = IQ + 1, N
              G = A(IP, J)
              H = A(IQ, J)
              A(IP, J) = G - S * (H + G * TAU)
              A(IQ, J) = H + S * (G - H * TAU)
            ENDDO
            DO J = 1, N
              G = V(J, IP)
              H = V(J, IQ)
              V(J, IP) = G - S * (H + G * TAU)
              V(J, IQ) = H + S * (G - H * TAU)
            ENDDO
            NROT = NROT + 1
          ENDIF
        ENDDO
      ENDDO
      DO IP = 1, N
        B(IP) = B(IP) + Z(IP)
        D(IP) = B(IP)
        Z(IP) = 0.
      ENDDO
    ENDDO ! of DO I=1,50
    STOP 'Jacobi: 50 iterations should never happen'

  END SUBROUTINE JACOBI

  SUBROUTINE eigen_sort(d, v, n, np)
    INTEGER :: n, np
    REAL :: d(np), v(np, np)
    INTEGER :: i, j, k
    REAL :: p

    DO i = 1, n - 1
      k = i
      p = d(i)
      DO j = i + 1, n
        IF(d(j)>=p) THEN
          k = j
          p = d(j)
        ENDIF
      ENDDO

      IF(k/=i) THEN
        d(k) = d(i)
        d(i) = p
        DO j = 1, n
          p = v(j, i)
          v(j, i) = v(j, k)
          v(j, k) = p
        ENDDO
      ENDIF
    ENDDO

    RETURN
  END SUBROUTINE eigen_sort

  SUBROUTINE acc(vec, d, im)
    USE lmdz_ssum_scopy, ONLY: ssum
    IMPLICIT NONE
    INTEGER :: im
    REAL :: vec(im, im), d(im)
    INTEGER :: i, j
    REAL :: sum
    DO j = 1, im
      DO i = 1, im
        d(i) = vec(i, j) * vec(i, j)
      enddo
      sum = ssum(im, d, 1)
      sum = sqrt(sum)
      DO i = 1, im
        vec(i, j) = vec(i, j) / sum
      enddo
    enddo
    RETURN
  END SUBROUTINE acc


  SUBROUTINE inifilr
#ifdef CPP_PARA
  USE lmdz_filtre_fft, ONLY: use_filtre_fft,Init_filtre_fft
  USE lmdz_filtre_fft_loc, ONLY: Init_filtre_fft_loc=>Init_filtre_fft    !
#endif
    USE serre_mod, ONLY: alphax
    USE logic_mod, ONLY: fxyhypb, ysinus
    USE comconst_mod, ONLY: maxlatfilter
    USE lmdz_coefils, ONLY: modfrstv, modfrstu, jfiltnu, jfiltnv, coefilu, coefilv, &
            coefilu2, coefilv2, eignfnv, eignfnu, jfiltsu, jfiltsv
  USE lmdz_dimensions, ONLY: iim, jjm, llm, ndm
    USE lmdz_comgeom
    USE lmdz_paramet

    !    ... H. Upfiltreg_modadhyaya, O.Sharma   ...

    !     version 3 .....

    !     Correction  le 28/10/97    P. Le Van .
    !  -------------------------------------------------------------------

    REAL  dlonu(iim), dlatu(jjm)
    REAL  rlamda(iim), eignvl(iim)

    REAL    lamdamax, pi, cof
    INTEGER i, j, modemax, imx, k, kf, ii
    REAL dymin, dxmin, colat0
    REAL eignft(iim, iim), coff

    LOGICAL, SAVE :: first_call_inifilr = .TRUE.

    INTEGER   ISMIN
    EXTERNAL  ISMIN
    INTEGER iymin
    INTEGER ixmineq

    ! ------------------------------------------------------------
    !   This routine computes the eigenfunctions of the laplacien
    !   on the stretched grid, and the filtering coefficients

    !  We designate:
    !   eignfn   eigenfunctions of the discrete laplacien
    !   eigenvl  eigenvalues
    !   jfiltn   indexof the last scalar line filtered in NH
    !   jfilts   index of the first line filtered in SH
    !   modfrst  index of the mode from WHERE modes are filtered
    !   modemax  maximum number of modes ( im )
    !   coefil   filtering coefficients ( lamda_max*COS(rlat)/lamda )
    !   sdd      SQRT( dx )

    !     the modes are filtered from modfrst to modemax

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

    IF (iim == 1) return ! No filtre in 2D y-z

    pi = 2. * ASIN(1.)

    DO i = 1, iim
      dlonu(i) = xprimu(i)
    ENDDO

    CALL inifgn(eignvl)

    PRINT *, 'inifilr: EIGNVL '
    PRINT 250, eignvl
    250 FORMAT(1x, 5e14.6)

    ! compute eigenvalues and eigenfunctions


    !.................................................................

    !  compute the filtering coefficients for scalar lines and 
    !  meridional wind v-lines

    !  we filter all those latitude lines WHERE coefil < 1
    !  NO FILTERING AT POLES

    !  colat0 is to be used  when alpha (stretching coefficient)
    !  is set equal to zero for the regular grid CASE 

    !    .......   Calcul  de  colat0   .........
    !     .....  colat0 = minimum de ( 0.5, min dy/ min dx )   ...

    DO j = 1, jjm
      dlatu(j) = rlatu(j) - rlatu(j + 1)
    ENDDO

    dxmin = dlonu(1)
    DO  i = 2, iim
      dxmin = MIN(dxmin, dlonu(i))
    ENDDO
    dymin = dlatu(1)
    DO j = 2, jjm
      dymin = MIN(dymin, dlatu(j))
    ENDDO

    ! For a regular grid, we want the filter to start at latitudes
    ! corresponding to lengths dx of the same size as dy (in terms
    ! of angles: dx=2*dy) => at colat0=0.5 (i.e. colatitude=30 degrees
    !  <=> latitude=60 degrees).
    ! Same idea for the zoomed grid: start filtering polewards as soon
    ! as length dx becomes of the same size as dy 

    ! if maxlatfilter >0, prescribe the colat0 value from the .def files

    IF (maxlatfilter < 0.) THEN

      colat0 = MIN(0.5, dymin / dxmin)
      ! colat0  =  1.

      IF(.NOT.fxyhypb.AND.ysinus)  THEN
        colat0 = 0.6
        !         ...... a revoir  pour  ysinus !   .......
        alphax = 0.
      ENDIF

    ELSE

      colat0 = (90.0 - maxlatfilter) / 180.0 * pi

    ENDIF

    PRINT 50, colat0, alphax
    50  FORMAT(/15x, ' Inifilr colat0 alphax ', 2e16.7)

    IF(alphax==1.)  THEN
      PRINT *, ' Inifilr  alphax doit etre  <  a 1.  Corriger '
      STOP
    ENDIF

    lamdamax = iim / (pi * colat0 * (1. - alphax))

    !                        ... Correction  le 28/10/97  ( P.Le Van ) ..

    DO i = 2, iim
      rlamda(i) = lamdamax / SQRT(ABS(eignvl(i)))
    ENDDO

    DO j = 1, jjm
      DO i = 1, iim
        coefilu(i, j) = 0.0
        coefilv(i, j) = 0.0
        coefilu2(i, j) = 0.0
        coefilv2(i, j) = 0.0
      ENDDO
    ENDDO

    !    ... Determination de jfiltnu,jfiltnv,jfiltsu,jfiltsv ....
    !    .........................................................

    modemax = iim

    !!!!    imx = modemax - 4 * (modemax/iim)

    imx = iim

    PRINT *, 'inifilr: TRUNCATION AT ', imx

    ! Ehouarn: set up some defaults
    jfiltnu = 2 ! avoid north pole
    jfiltsu = jjm ! avoid south pole (which is at jjm+1)
    jfiltnv = 1 ! NB: no poles on the V grid
    jfiltsv = jjm

    DO j = 2, jjm / 2 + 1
      cof = COS(rlatu(j)) / colat0
      IF (cof < 1.) THEN
        IF(rlamda(imx) * COS(rlatu(j))<1.) THEN
          jfiltnu = j
        ENDIF
      ENDIF

      cof = COS(rlatu(jjp1 - j + 1)) / colat0
      IF (cof < 1.) THEN
        IF(rlamda(imx) * COS(rlatu(jjp1 - j + 1))<1.) THEN
          jfiltsu = jjp1 - j + 1
        ENDIF
      ENDIF
    ENDDO

    DO j = 1, jjm / 2
      cof = COS(rlatv(j)) / colat0
      IF (cof < 1.) THEN
        IF(rlamda(imx) * COS(rlatv(j))<1.) THEN
          jfiltnv = j
        ENDIF
      ENDIF

      cof = COS(rlatv(jjm - j + 1)) / colat0
      IF (cof < 1.) THEN
        IF(rlamda(imx) * COS(rlatv(jjm - j + 1))<1.) THEN
          jfiltsv = jjm - j + 1
        ENDIF
      ENDIF
    ENDDO

    IF(jfiltnu> jjm / 2 + 1)  THEN
      PRINT *, ' jfiltnu en dehors des valeurs acceptables ', jfiltnu
      STOP
    ENDIF

    IF(jfiltsu>  jjm + 1)  THEN
      PRINT *, ' jfiltsu en dehors des valeurs acceptables ', jfiltsu
      STOP
    ENDIF

    IF(jfiltnv> jjm / 2)  THEN
      PRINT *, ' jfiltnv en dehors des valeurs acceptables ', jfiltnv
      STOP
    ENDIF

    IF(jfiltsv>     jjm)  THEN
      PRINT *, ' jfiltsv en dehors des valeurs acceptables ', jfiltsv
      STOP
    ENDIF

    PRINT *, 'inifilr: jfiltnv jfiltsv jfiltnu jfiltsu ', &
            jfiltnv, jfiltsv, jfiltnu, jfiltsu

    IF(first_call_inifilr) THEN
      ALLOCATE(matriceun(iim, iim, jfiltnu))
      ALLOCATE(matriceus(iim, iim, jjm - jfiltsu + 1))
      ALLOCATE(matricevn(iim, iim, jfiltnv))
      ALLOCATE(matricevs(iim, iim, jjm - jfiltsv + 1))
      ALLOCATE(matrinvn(iim, iim, jfiltnu))
      ALLOCATE(matrinvs(iim, iim, jjm - jfiltsu + 1))
      first_call_inifilr = .FALSE.
    ENDIF

    !   ... Determination de coefilu,coefilv,n=modfrstu,modfrstv ....
    !................................................................

    DO j = 1, jjm
      !default initialization: all modes are retained (i.e. no filtering)
      modfrstu(j) = iim
      modfrstv(j) = iim
    ENDDO

    DO j = 2, jfiltnu
      DO k = 2, modemax
        cof = rlamda(k) * COS(rlatu(j))
        IF (cof < 1.) GOTO 82
      ENDDO
      GOTO 84
      82     modfrstu(j) = k

      kf = modfrstu(j)
      DO k = kf, modemax
        cof = rlamda(k) * COS(rlatu(j))
        coefilu(k, j) = cof - 1.
        coefilu2(k, j) = cof * cof - 1.
      ENDDO
      84     CONTINUE
    ENDDO

    DO j = 1, jfiltnv

      DO k = 2, modemax
        cof = rlamda(k) * COS(rlatv(j))
        IF (cof < 1.) GOTO 87
      ENDDO
      GOTO 89
      87     modfrstv(j) = k

      kf = modfrstv(j)
      DO k = kf, modemax
        cof = rlamda(k) * COS(rlatv(j))
        coefilv(k, j) = cof - 1.
        coefilv2(k, j) = cof * cof - 1.
      ENDDO
      89     CONTINUE
    ENDDO

    DO j = jfiltsu, jjm
      DO k = 2, modemax
        cof = rlamda(k) * COS(rlatu(j))
        IF (cof < 1.) GOTO 92
      ENDDO
      GOTO 94
      92     modfrstu(j) = k

      kf = modfrstu(j)
      DO k = kf, modemax
        cof = rlamda(k) * COS(rlatu(j))
        coefilu(k, j) = cof - 1.
        coefilu2(k, j) = cof * cof - 1.
      ENDDO
      94     CONTINUE
    ENDDO

    DO j = jfiltsv, jjm
      DO k = 2, modemax
        cof = rlamda(k) * COS(rlatv(j))
        IF (cof < 1.) GOTO 97
      ENDDO
      GOTO 99
      97     modfrstv(j) = k

      kf = modfrstv(j)
      DO k = kf, modemax
        cof = rlamda(k) * COS(rlatv(j))
        coefilv(k, j) = cof - 1.
        coefilv2(k, j) = cof * cof - 1.
      ENDDO
      99     CONTINUE
    ENDDO

    IF(jfiltnv>=jjm / 2 .OR. jfiltnu>=jjm / 2)THEN
      ! Ehouarn: and what are these for??? Trying to handle a limit case
      !          where filters extend to and meet at the equator?
      IF(jfiltnv==jfiltsv)jfiltsv = 1 + jfiltnv
      IF(jfiltnu==jfiltsu)jfiltsu = 1 + jfiltnu

      PRINT *, 'jfiltnv jfiltsv jfiltnu jfiltsu', &
              jfiltnv, jfiltsv, jfiltnu, jfiltsu
    ENDIF

    PRINT *, '   Modes premiers  v  '
    PRINT 334, modfrstv
    PRINT *, '   Modes premiers  u  '
    PRINT 334, modfrstu

    !   ...................................................................

    !   ... Calcul de la matrice filtre 'matriceu'  pour les champs situes
    !                       sur la grille scalaire                 ........
    !   ...................................................................

    DO j = 2, jfiltnu

      DO i = 1, iim
        coff = coefilu(i, j)
        IF(i<modfrstu(j)) coff = 0.
        DO k = 1, iim
          eignft(i, k) = eignfnv(k, i) * coff
        ENDDO
      ENDDO ! of DO i=1,iim

#ifdef BLAS
       CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
            eignfnv, iim, eignft, iim, 0.0, matriceun(1,1,j), iim)
#else
      DO k = 1, iim
        DO i = 1, iim
          matriceun(i, k, j) = 0.0
          DO ii = 1, iim
            matriceun(i, k, j) = matriceun(i, k, j) &
                    + eignfnv(i, ii) * eignft(ii, k)
          ENDDO
        ENDDO
      ENDDO ! of DO k = 1, iim
#endif

    ENDDO ! of DO j = 2, jfiltnu

    DO j = jfiltsu, jjm

      DO i = 1, iim
        coff = coefilu(i, j)
        IF(i<modfrstu(j)) coff = 0.
        DO k = 1, iim
          eignft(i, k) = eignfnv(k, i) * coff
        ENDDO
      ENDDO ! of DO i=1,iim
#ifdef BLAS
       CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
            eignfnv, iim, eignft, iim, 0.0, &
            matriceus(1,1,j-jfiltsu+1), iim)
#else
      DO k = 1, iim
        DO i = 1, iim
          matriceus(i, k, j - jfiltsu + 1) = 0.0
          DO ii = 1, iim
            matriceus(i, k, j - jfiltsu + 1) = matriceus(i, k, j - jfiltsu + 1) &
                    + eignfnv(i, ii) * eignft(ii, k)
          ENDDO
        ENDDO
      ENDDO ! of DO k = 1, iim
#endif

    ENDDO ! of DO j = jfiltsu, jjm

    !   ...................................................................

    !   ... Calcul de la matrice filtre 'matricev'  pour les champs situes
    !                       sur la grille   de V ou de Z           ........
    !   ...................................................................

    DO j = 1, jfiltnv

      DO i = 1, iim
        coff = coefilv(i, j)
        IF(i<modfrstv(j)) coff = 0.
        DO k = 1, iim
          eignft(i, k) = eignfnu(k, i) * coff
        ENDDO
      ENDDO

#ifdef BLAS
       CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
            eignfnu, iim, eignft, iim, 0.0, matricevn(1,1,j), iim)
#else
      DO k = 1, iim
        DO i = 1, iim
          matricevn(i, k, j) = 0.0
          DO ii = 1, iim
            matricevn(i, k, j) = matricevn(i, k, j) &
                    + eignfnu(i, ii) * eignft(ii, k)
          ENDDO
        ENDDO
      ENDDO
#endif

    ENDDO ! of DO j = 1, jfiltnv

    DO j = jfiltsv, jjm

      DO i = 1, iim
        coff = coefilv(i, j)
        IF(i<modfrstv(j)) coff = 0.
        DO k = 1, iim
          eignft(i, k) = eignfnu(k, i) * coff
        ENDDO
      ENDDO

#ifdef BLAS
       CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
            eignfnu, iim, eignft, iim, 0.0, & 
            matricevs(1,1,j-jfiltsv+1), iim)
#else
      DO k = 1, iim
        DO i = 1, iim
          matricevs(i, k, j - jfiltsv + 1) = 0.0
          DO ii = 1, iim
            matricevs(i, k, j - jfiltsv + 1) = matricevs(i, k, j - jfiltsv + 1) &
                    + eignfnu(i, ii) * eignft(ii, k)
          ENDDO
        ENDDO
      ENDDO
#endif

    ENDDO ! of DO j = jfiltsv, jjm

    !   ...................................................................

    !   ... Calcul de la matrice filtre 'matrinv'  pour les champs situes
    !              sur la grille scalaire , pour le filtre inverse ........
    !   ...................................................................

    DO j = 2, jfiltnu

      DO i = 1, iim
        coff = coefilu(i, j) / (1. + coefilu(i, j))
        IF(i<modfrstu(j)) coff = 0.
        DO k = 1, iim
          eignft(i, k) = eignfnv(k, i) * coff
        ENDDO
      ENDDO

#ifdef BLAS
       CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
            eignfnv, iim, eignft, iim, 0.0, matrinvn(1,1,j), iim)
#else
      DO k = 1, iim
        DO i = 1, iim
          matrinvn(i, k, j) = 0.0
          DO ii = 1, iim
            matrinvn(i, k, j) = matrinvn(i, k, j) &
                    + eignfnv(i, ii) * eignft(ii, k)
          ENDDO
        ENDDO
      ENDDO
#endif

    ENDDO ! of DO j = 2, jfiltnu

    DO j = jfiltsu, jjm

      DO i = 1, iim
        coff = coefilu(i, j) / (1. + coefilu(i, j))
        IF(i<modfrstu(j)) coff = 0.
        DO k = 1, iim
          eignft(i, k) = eignfnv(k, i) * coff
        ENDDO
      ENDDO
#ifdef BLAS
       CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
            eignfnv, iim, eignft, iim, 0.0, matrinvs(1,1,j-jfiltsu+1), iim)
#else
      DO k = 1, iim
        DO i = 1, iim
          matrinvs(i, k, j - jfiltsu + 1) = 0.0
          DO ii = 1, iim
            matrinvs(i, k, j - jfiltsu + 1) = matrinvs(i, k, j - jfiltsu + 1) &
                    + eignfnv(i, ii) * eignft(ii, k)
          ENDDO
        ENDDO
      ENDDO
#endif

    ENDDO ! of DO j = jfiltsu, jjm

#ifdef CPP_PARA
    IF (use_filtre_fft) THEN
       CALL Init_filtre_fft(coefilu,modfrstu,jfiltnu,jfiltsu,  &
                           coefilv,modfrstv,jfiltnv,jfiltsv)
       CALL Init_filtre_fft_loc(coefilu,modfrstu,jfiltnu,jfiltsu,  &
                           coefilv,modfrstv,jfiltnv,jfiltsv)
    ENDIF
#endif
    !   ...................................................................

    334 FORMAT(1x, 24i3)

  END SUBROUTINE inifilr

END MODULE lmdz_filtreg