d1/d21/cseri_8f_source.html

       SUBROUTINE cseri(Z, FNU, KODE, N, Y, NZ, TOL, ELIM, ALIM)
 C***BEGIN PROLOGUE  CSERI
 C***REFER TO  CBESI,CBESK
 C
 C     CSERI COMPUTES THE I BESSEL FUNCTION FOR REAL(Z).GE.0.0 BY
 C     MEANS OF THE POWER SERIES FOR LARGE CABS(Z) IN THE
 C     REGION CABS(Z).LE.2*SQRT(FNU+1). NZ=0 IS A NORMAL RETURN.
 C     NZ.GT.0 MEANS THAT THE LAST NZ COMPONENTS WERE SET TO ZERO
 C     DUE TO UNDERFLOW. NZ.LT.0 MEANS UNDERFLOW OCCURRED, BUT THE
 C     CONDITION CABS(Z).LE.2*SQRT(FNU+1) WAS VIOLATED AND THE
 C     COMPUTATION MUST BE COMPLETED IN ANOTHER ROUTINE WITH N=N-ABS(NZ).
 C
 C***ROUTINES CALLED  CUCHK,GAMLN,R1MACH
 C***END PROLOGUE  CSERI
       COMPLEX AK1, CK, COEF, CONE, CRSC, CZ, CZERO, HZ, RZ, S1, S2, W,
      * Y, Z
       REAL AA, ACZ, AK, ALIM, ARM, ASCLE, ATOL, AZ, DFNU, ELIM, FNU,
      * FNUP, RAK1, RS, RTR1, S, SS, TOL, X, GAMLN, R1MACH
       INTEGER I, IB, IDUM, IFLAG, IL, K, KODE, L, M, N, NN, NW, NZ
       dimension y(n), w(2)
       DATA czero, cone / (0.0e0,0.0e0), (1.0e0,0.0e0) /
 C
       nz = 0
       az = cabs(z)
       IF (az.EQ.0.0e0) GO TO 150
       x = REAL(Z)
       arm = 1.0e+3*r1mach(1)
       rtr1 = sqrt(arm)
       crsc = cmplx(1.0e0,0.0e0)
       iflag = 0
       IF (az.LT.arm) GO TO 140
       hz = z*cmplx(0.5e0,0.0e0)
       cz = czero
       IF (az.GT.rtr1) cz = hz*hz
       acz = cabs(cz)
       nn = n
       ck = clog(hz)
    10 CONTINUE
       dfnu = fnu + float(nn-1)
       fnup = dfnu + 1.0e0
 C-----------------------------------------------------------------------
 C     UNDERFLOW TEST
 C-----------------------------------------------------------------------
       ak1 = ck*cmplx(dfnu,0.0e0)
       ak = gamln(fnup,idum)
       ak1 = ak1 - cmplx(ak,0.0e0)
       IF (kode.EQ.2) ak1 = ak1 - cmplx(x,0.0e0)
       rak1 = REAL(AK1)
       IF (rak1.GT.(-elim)) GO TO 30
    20 CONTINUE
       nz = nz + 1
       y(nn) = czero
       IF (acz.GT.dfnu) GO TO 170
       nn = nn - 1
       IF (nn.EQ.0) RETURN
       GO TO 10
    30 CONTINUE
       IF (rak1.GT.(-alim)) GO TO 40
       iflag = 1
       ss = 1.0e0/tol
       crsc = cmplx(tol,0.0e0)
       ascle = arm*ss
    40 CONTINUE
       ak = aimag(ak1)
       aa = exp(rak1)
       IF (iflag.EQ.1) aa = aa*ss
       coef = cmplx(aa,0.0e0)*cmplx(cos(ak),sin(ak))
       atol = tol*acz/fnup
       il = min0(2,nn)
       DO 80 i=1,il
         dfnu = fnu + float(nn-i)
         fnup = dfnu + 1.0e0
         s1 = cone
         IF (acz.LT.tol*fnup) GO TO 60
         ak1 = cone
         ak = fnup + 2.0e0
         s = fnup
         aa = 2.0e0
    50   CONTINUE
         rs = 1.0e0/s
         ak1 = ak1*cz*cmplx(rs,0.0e0)
         s1 = s1 + ak1
         s = s + ak
         ak = ak + 2.0e0
         aa = aa*acz*rs
         IF (aa.GT.atol) GO TO 50
    60   CONTINUE
         m = nn - i + 1
         s2 = s1*coef
         w(i) = s2
         IF (iflag.EQ.0) GO TO 70
         CALL cuchk(s2, nw, ascle, tol)
         IF (nw.NE.0) GO TO 20
    70   CONTINUE
         y(m) = s2*crsc
         IF (i.NE.il) coef = coef*cmplx(dfnu,0.0e0)/hz
    80 CONTINUE
       IF (nn.LE.2) RETURN
       k = nn - 2
       ak = float(k)
       rz = (cone+cone)/z
       IF (iflag.EQ.1) GO TO 110
       ib = 3
    90 CONTINUE
       DO 100 i=ib,nn
         y(k) = cmplx(ak+fnu,0.0e0)*rz*y(k+1) + y(k+2)
         ak = ak - 1.0e0
         k = k - 1
   100 CONTINUE
       RETURN
 C-----------------------------------------------------------------------
 C     RECUR BACKWARD WITH SCALED VALUES
 C-----------------------------------------------------------------------
   110 CONTINUE
 C-----------------------------------------------------------------------
 C     EXP(-ALIM)=EXP(-ELIM)/TOL=APPROX. ONE PRECISION ABOVE THE
 C     UNDERFLOW LIMIT = ASCLE = R1MACH(1)*CSCL*1.0E+3
 C-----------------------------------------------------------------------
       s1 = w(1)
       s2 = w(2)
       DO 120 l=3,nn
         ck = s2
         s2 = s1 + cmplx(ak+fnu,0.0e0)*rz*s2
         s1 = ck
         ck = s2*crsc
         y(k) = ck
         ak = ak - 1.0e0
         k = k - 1
         IF (cabs(ck).GT.ascle) GO TO 130
   120 CONTINUE
       RETURN
   130 CONTINUE
       ib = l + 1
       IF (ib.GT.nn) RETURN
       GO TO 90
   140 CONTINUE
       nz = n
       IF (fnu.EQ.0.0e0) nz = nz - 1
   150 CONTINUE
       y(1) = czero
       IF (fnu.EQ.0.0e0) y(1) = cone
       IF (n.EQ.1) RETURN
       DO 160 i=2,n
         y(i) = czero
   160 CONTINUE
       RETURN
 C-----------------------------------------------------------------------
 C     RETURN WITH NZ.LT.0 IF CABS(Z*Z/4).GT.FNU+N-NZ-1 COMPLETE
 C     THE CALCULATION IN CBINU WITH N=N-IABS(NZ)
 C-----------------------------------------------------------------------
   170 CONTINUE
       nz = -nz
       RETURN
       END
cmplx
double complex cmplx
Definition: Faddeeva.cc:217

dimension
OCTAVE_EXPORT octave_value_list etc The functions then dimension(columns)