qpms/amos/zmlri.f

      SUBROUTINE ZMLRI(ZR, ZI, FNU, KODE, N, YR, YI, NZ, TOL)
C***BEGIN PROLOGUE  ZMLRI
C***REFER TO  ZBESI,ZBESK
C
C     ZMLRI COMPUTES THE I BESSEL FUNCTION FOR RE(Z).GE.0.0 BY THE
C     MILLER ALGORITHM NORMALIZED BY A NEUMANN SERIES.
C
C***ROUTINES CALLED  DGAMLN,D1MACH,AZABS,AZEXP,AZLOG,ZMLT
C***END PROLOGUE  ZMLRI
C     COMPLEX CK,CNORM,CONE,CTWO,CZERO,PT,P1,P2,RZ,SUM,Y,Z
      DOUBLE PRECISION ACK, AK, AP, AT, AZ, BK, CKI, CKR, CNORMI,
     * CNORMR, CONEI, CONER, FKAP, FKK, FLAM, FNF, FNU, PTI, PTR, P1I,
     * P1R, P2I, P2R, RAZ, RHO, RHO2, RZI, RZR, SCLE, STI, STR, SUMI,
     * SUMR, TFNF, TOL, TST, YI, YR, ZEROI, ZEROR, ZI, ZR, DGAMLN,
     * D1MACH, AZABS
      INTEGER I, IAZ, IDUM, IFNU, INU, ITIME, K, KK, KM, KODE, M, N, NZ
      DIMENSION YR(N), YI(N)
      DATA ZEROR,ZEROI,CONER,CONEI / 0.0D0, 0.0D0, 1.0D0, 0.0D0 /
      SCLE = D1MACH(1)/TOL
      NZ=0
      AZ = AZABS(ZR,ZI)
      IAZ = INT(SNGL(AZ))
      IFNU = INT(SNGL(FNU))
      INU = IFNU + N - 1
      AT = DBLE(FLOAT(IAZ)) + 1.0D0
      RAZ = 1.0D0/AZ
      STR = ZR*RAZ
      STI = -ZI*RAZ
      CKR = STR*AT*RAZ
      CKI = STI*AT*RAZ
      RZR = (STR+STR)*RAZ
      RZI = (STI+STI)*RAZ
      P1R = ZEROR
      P1I = ZEROI
      P2R = CONER
      P2I = CONEI
      ACK = (AT+1.0D0)*RAZ
      RHO = ACK + DSQRT(ACK*ACK-1.0D0)
      RHO2 = RHO*RHO
      TST = (RHO2+RHO2)/((RHO2-1.0D0)*(RHO-1.0D0))
      TST = TST/TOL
C-----------------------------------------------------------------------
C     COMPUTE RELATIVE TRUNCATION ERROR INDEX FOR SERIES
C-----------------------------------------------------------------------
      AK = AT
      DO 10 I=1,80
        PTR = P2R
        PTI = P2I
        P2R = P1R - (CKR*PTR-CKI*PTI)
        P2I = P1I - (CKI*PTR+CKR*PTI)
        P1R = PTR
        P1I = PTI
        CKR = CKR + RZR
        CKI = CKI + RZI
        AP = AZABS(P2R,P2I)
        IF (AP.GT.TST*AK*AK) GO TO 20
        AK = AK + 1.0D0
   10 CONTINUE
      GO TO 110
   20 CONTINUE
      I = I + 1
      K = 0
      IF (INU.LT.IAZ) GO TO 40
C-----------------------------------------------------------------------
C     COMPUTE RELATIVE TRUNCATION ERROR FOR RATIOS
C-----------------------------------------------------------------------
      P1R = ZEROR
      P1I = ZEROI
      P2R = CONER
      P2I = CONEI
      AT = DBLE(FLOAT(INU)) + 1.0D0
      STR = ZR*RAZ
      STI = -ZI*RAZ
      CKR = STR*AT*RAZ
      CKI = STI*AT*RAZ
      ACK = AT*RAZ
      TST = DSQRT(ACK/TOL)
      ITIME = 1
      DO 30 K=1,80
        PTR = P2R
        PTI = P2I
        P2R = P1R - (CKR*PTR-CKI*PTI)
        P2I = P1I - (CKR*PTI+CKI*PTR)
        P1R = PTR
        P1I = PTI
        CKR = CKR + RZR
        CKI = CKI + RZI
        AP = AZABS(P2R,P2I)
        IF (AP.LT.TST) GO TO 30
        IF (ITIME.EQ.2) GO TO 40
        ACK = AZABS(CKR,CKI)
        FLAM = ACK + DSQRT(ACK*ACK-1.0D0)
        FKAP = AP/AZABS(P1R,P1I)
        RHO = DMIN1(FLAM,FKAP)
        TST = TST*DSQRT(RHO/(RHO*RHO-1.0D0))
        ITIME = 2
   30 CONTINUE
      GO TO 110
   40 CONTINUE
C-----------------------------------------------------------------------
C     BACKWARD RECURRENCE AND SUM NORMALIZING RELATION
C-----------------------------------------------------------------------
      K = K + 1
      KK = MAX0(I+IAZ,K+INU)
      FKK = DBLE(FLOAT(KK))
      P1R = ZEROR
      P1I = ZEROI
C-----------------------------------------------------------------------
C     SCALE P2 AND SUM BY SCLE
C-----------------------------------------------------------------------
      P2R = SCLE
      P2I = ZEROI
      FNF = FNU - DBLE(FLOAT(IFNU))
      TFNF = FNF + FNF
      BK = DGAMLN(FKK+TFNF+1.0D0,IDUM) - DGAMLN(FKK+1.0D0,IDUM) -
     * DGAMLN(TFNF+1.0D0,IDUM)
      BK = DEXP(BK)
      SUMR = ZEROR
      SUMI = ZEROI
      KM = KK - INU
      DO 50 I=1,KM
        PTR = P2R
        PTI = P2I
        P2R = P1R + (FKK+FNF)*(RZR*PTR-RZI*PTI)
        P2I = P1I + (FKK+FNF)*(RZI*PTR+RZR*PTI)
        P1R = PTR
        P1I = PTI
        AK = 1.0D0 - TFNF/(FKK+TFNF)
        ACK = BK*AK
        SUMR = SUMR + (ACK+BK)*P1R
        SUMI = SUMI + (ACK+BK)*P1I
        BK = ACK
        FKK = FKK - 1.0D0
   50 CONTINUE
      YR(N) = P2R
      YI(N) = P2I
      IF (N.EQ.1) GO TO 70
      DO 60 I=2,N
        PTR = P2R
        PTI = P2I
        P2R = P1R + (FKK+FNF)*(RZR*PTR-RZI*PTI)
        P2I = P1I + (FKK+FNF)*(RZI*PTR+RZR*PTI)
        P1R = PTR
        P1I = PTI
        AK = 1.0D0 - TFNF/(FKK+TFNF)
        ACK = BK*AK
        SUMR = SUMR + (ACK+BK)*P1R
        SUMI = SUMI + (ACK+BK)*P1I
        BK = ACK
        FKK = FKK - 1.0D0
        M = N - I + 1
        YR(M) = P2R
        YI(M) = P2I
   60 CONTINUE
   70 CONTINUE
      IF (IFNU.LE.0) GO TO 90
      DO 80 I=1,IFNU
        PTR = P2R
        PTI = P2I
        P2R = P1R + (FKK+FNF)*(RZR*PTR-RZI*PTI)
        P2I = P1I + (FKK+FNF)*(RZR*PTI+RZI*PTR)
        P1R = PTR
        P1I = PTI
        AK = 1.0D0 - TFNF/(FKK+TFNF)
        ACK = BK*AK
        SUMR = SUMR + (ACK+BK)*P1R
        SUMI = SUMI + (ACK+BK)*P1I
        BK = ACK
        FKK = FKK - 1.0D0
   80 CONTINUE
   90 CONTINUE
      PTR = ZR
      PTI = ZI
      IF (KODE.EQ.2) PTR = ZEROR
      CALL AZLOG(RZR, RZI, STR, STI, IDUM)
      P1R = -FNF*STR + PTR
      P1I = -FNF*STI + PTI
      AP = DGAMLN(1.0D0+FNF,IDUM)
      PTR = P1R - AP
      PTI = P1I
C-----------------------------------------------------------------------
C     THE DIVISION CEXP(PT)/(SUM+P2) IS ALTERED TO AVOID OVERFLOW
C     IN THE DENOMINATOR BY SQUARING LARGE QUANTITIES
C-----------------------------------------------------------------------
      P2R = P2R + SUMR
      P2I = P2I + SUMI
      AP = AZABS(P2R,P2I)
      P1R = 1.0D0/AP
      CALL AZEXP(PTR, PTI, STR, STI)
      CKR = STR*P1R
      CKI = STI*P1R
      PTR = P2R*P1R
      PTI = -P2I*P1R
      CALL ZMLT(CKR, CKI, PTR, PTI, CNORMR, CNORMI)
      DO 100 I=1,N
        STR = YR(I)*CNORMR - YI(I)*CNORMI
        YI(I) = YR(I)*CNORMI + YI(I)*CNORMR
        YR(I) = STR
  100 CONTINUE
      RETURN
  110 CONTINUE
      NZ=-2
      RETURN
      END
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`SUBROUTINE ZMLRI(ZR, ZI, FNU, KODE, N, YR, YI, NZ, TOL)`
			`C***BEGIN PROLOGUE ZMLRI`
			`C***REFER TO ZBESI,ZBESK`
			`C`
			`C ZMLRI COMPUTES THE I BESSEL FUNCTION FOR RE(Z).GE.0.0 BY THE`
			`C MILLER ALGORITHM NORMALIZED BY A NEUMANN SERIES.`
			`C`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`C***ROUTINES CALLED DGAMLN,D1MACH,AZABS,AZEXP,AZLOG,ZMLT`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`C***END PROLOGUE ZMLRI`
			`C COMPLEX CK,CNORM,CONE,CTWO,CZERO,PT,P1,P2,RZ,SUM,Y,Z`
			`DOUBLE PRECISION ACK, AK, AP, AT, AZ, BK, CKI, CKR, CNORMI,`
			`* CNORMR, CONEI, CONER, FKAP, FKK, FLAM, FNF, FNU, PTI, PTR, P1I,`
			`* P1R, P2I, P2R, RAZ, RHO, RHO2, RZI, RZR, SCLE, STI, STR, SUMI,`
			`* SUMR, TFNF, TOL, TST, YI, YR, ZEROI, ZEROR, ZI, ZR, DGAMLN,`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`* D1MACH, AZABS`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`INTEGER I, IAZ, IDUM, IFNU, INU, ITIME, K, KK, KM, KODE, M, N, NZ`
			`DIMENSION YR(N), YI(N)`
			`DATA ZEROR,ZEROI,CONER,CONEI / 0.0D0, 0.0D0, 1.0D0, 0.0D0 /`
			`SCLE = D1MACH(1)/TOL`
			`NZ=0`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`AZ = AZABS(ZR,ZI)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`IAZ = INT(SNGL(AZ))`
			`IFNU = INT(SNGL(FNU))`
			`INU = IFNU + N - 1`
			`AT = DBLE(FLOAT(IAZ)) + 1.0D0`
			`RAZ = 1.0D0/AZ`
			`STR = ZR*RAZ`
			`STI = -ZI*RAZ`
			`CKR = STRATRAZ`
			`CKI = STIATRAZ`
			`RZR = (STR+STR)*RAZ`
			`RZI = (STI+STI)*RAZ`
			`P1R = ZEROR`
			`P1I = ZEROI`
			`P2R = CONER`
			`P2I = CONEI`
			`ACK = (AT+1.0D0)*RAZ`
			`RHO = ACK + DSQRT(ACK*ACK-1.0D0)`
			`RHO2 = RHO*RHO`
			`TST = (RHO2+RHO2)/((RHO2-1.0D0)*(RHO-1.0D0))`
			`TST = TST/TOL`
			`C-----------------------------------------------------------------------`
			`C COMPUTE RELATIVE TRUNCATION ERROR INDEX FOR SERIES`
			`C-----------------------------------------------------------------------`
			`AK = AT`
			`DO 10 I=1,80`
			`PTR = P2R`
			`PTI = P2I`
			`P2R = P1R - (CKRPTR-CKIPTI)`
			`P2I = P1I - (CKIPTR+CKRPTI)`
			`P1R = PTR`
			`P1I = PTI`
			`CKR = CKR + RZR`
			`CKI = CKI + RZI`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`AP = AZABS(P2R,P2I)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`IF (AP.GT.TSTAKAK) GO TO 20`
			`AK = AK + 1.0D0`
			`10 CONTINUE`
			`GO TO 110`
			`20 CONTINUE`
			`I = I + 1`
			`K = 0`
			`IF (INU.LT.IAZ) GO TO 40`
			`C-----------------------------------------------------------------------`
			`C COMPUTE RELATIVE TRUNCATION ERROR FOR RATIOS`
			`C-----------------------------------------------------------------------`
			`P1R = ZEROR`
			`P1I = ZEROI`
			`P2R = CONER`
			`P2I = CONEI`
			`AT = DBLE(FLOAT(INU)) + 1.0D0`
			`STR = ZR*RAZ`
			`STI = -ZI*RAZ`
			`CKR = STRATRAZ`
			`CKI = STIATRAZ`
			`ACK = AT*RAZ`
			`TST = DSQRT(ACK/TOL)`
			`ITIME = 1`
			`DO 30 K=1,80`
			`PTR = P2R`
			`PTI = P2I`
			`P2R = P1R - (CKRPTR-CKIPTI)`
			`P2I = P1I - (CKRPTI+CKIPTR)`
			`P1R = PTR`
			`P1I = PTI`
			`CKR = CKR + RZR`
			`CKI = CKI + RZI`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`AP = AZABS(P2R,P2I)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`IF (AP.LT.TST) GO TO 30`
			`IF (ITIME.EQ.2) GO TO 40`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`ACK = AZABS(CKR,CKI)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`FLAM = ACK + DSQRT(ACK*ACK-1.0D0)`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`FKAP = AP/AZABS(P1R,P1I)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`RHO = DMIN1(FLAM,FKAP)`
			`TST = TSTDSQRT(RHO/(RHORHO-1.0D0))`
			`ITIME = 2`
			`30 CONTINUE`
			`GO TO 110`
			`40 CONTINUE`
			`C-----------------------------------------------------------------------`
			`C BACKWARD RECURRENCE AND SUM NORMALIZING RELATION`
			`C-----------------------------------------------------------------------`
			`K = K + 1`
			`KK = MAX0(I+IAZ,K+INU)`
			`FKK = DBLE(FLOAT(KK))`
			`P1R = ZEROR`
			`P1I = ZEROI`
			`C-----------------------------------------------------------------------`
			`C SCALE P2 AND SUM BY SCLE`
			`C-----------------------------------------------------------------------`
			`P2R = SCLE`
			`P2I = ZEROI`
			`FNF = FNU - DBLE(FLOAT(IFNU))`
			`TFNF = FNF + FNF`
			`BK = DGAMLN(FKK+TFNF+1.0D0,IDUM) - DGAMLN(FKK+1.0D0,IDUM) -`
			`* DGAMLN(TFNF+1.0D0,IDUM)`
			`BK = DEXP(BK)`
			`SUMR = ZEROR`
			`SUMI = ZEROI`
			`KM = KK - INU`
			`DO 50 I=1,KM`
			`PTR = P2R`
			`PTI = P2I`
			`P2R = P1R + (FKK+FNF)(RZRPTR-RZI*PTI)`
			`P2I = P1I + (FKK+FNF)(RZIPTR+RZR*PTI)`
			`P1R = PTR`
			`P1I = PTI`
			`AK = 1.0D0 - TFNF/(FKK+TFNF)`
			`ACK = BK*AK`
			`SUMR = SUMR + (ACK+BK)*P1R`
			`SUMI = SUMI + (ACK+BK)*P1I`
			`BK = ACK`
			`FKK = FKK - 1.0D0`
			`50 CONTINUE`
			`YR(N) = P2R`
			`YI(N) = P2I`
			`IF (N.EQ.1) GO TO 70`
			`DO 60 I=2,N`
			`PTR = P2R`
			`PTI = P2I`
			`P2R = P1R + (FKK+FNF)(RZRPTR-RZI*PTI)`
			`P2I = P1I + (FKK+FNF)(RZIPTR+RZR*PTI)`
			`P1R = PTR`
			`P1I = PTI`
			`AK = 1.0D0 - TFNF/(FKK+TFNF)`
			`ACK = BK*AK`
			`SUMR = SUMR + (ACK+BK)*P1R`
			`SUMI = SUMI + (ACK+BK)*P1I`
			`BK = ACK`
			`FKK = FKK - 1.0D0`
			`M = N - I + 1`
			`YR(M) = P2R`
			`YI(M) = P2I`
			`60 CONTINUE`
			`70 CONTINUE`
			`IF (IFNU.LE.0) GO TO 90`
			`DO 80 I=1,IFNU`
			`PTR = P2R`
			`PTI = P2I`
			`P2R = P1R + (FKK+FNF)(RZRPTR-RZI*PTI)`
			`P2I = P1I + (FKK+FNF)(RZRPTI+RZI*PTR)`
			`P1R = PTR`
			`P1I = PTI`
			`AK = 1.0D0 - TFNF/(FKK+TFNF)`
			`ACK = BK*AK`
			`SUMR = SUMR + (ACK+BK)*P1R`
			`SUMI = SUMI + (ACK+BK)*P1I`
			`BK = ACK`
			`FKK = FKK - 1.0D0`
			`80 CONTINUE`
			`90 CONTINUE`
			`PTR = ZR`
			`PTI = ZI`
			`IF (KODE.EQ.2) PTR = ZEROR`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`CALL AZLOG(RZR, RZI, STR, STI, IDUM)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`P1R = -FNF*STR + PTR`
			`P1I = -FNF*STI + PTI`
			`AP = DGAMLN(1.0D0+FNF,IDUM)`
			`PTR = P1R - AP`
			`PTI = P1I`
			`C-----------------------------------------------------------------------`
			`C THE DIVISION CEXP(PT)/(SUM+P2) IS ALTERED TO AVOID OVERFLOW`
			`C IN THE DENOMINATOR BY SQUARING LARGE QUANTITIES`
			`C-----------------------------------------------------------------------`
			`P2R = P2R + SUMR`
			`P2I = P2I + SUMI`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`AP = AZABS(P2R,P2I)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`P1R = 1.0D0/AP`
Replace original netlib amos routines with those in scipy. Note: apparently, one could also use amos from openspecfun https://github.com/JuliaMath/openspecfun Former-commit-id: 77d61fe6486803684201480410021fd173172cc0 2019-03-20 12:25:42 +02:00			`CALL AZEXP(PTR, PTI, STR, STI)`
Add AMOS routines from netlib Former-commit-id: c6fe0e468937daa36fe5f6692af5d24d4df3f851 2019-03-19 16:42:47 +02:00			`CKR = STR*P1R`
			`CKI = STI*P1R`
			`PTR = P2R*P1R`
			`PTI = -P2I*P1R`
			`CALL ZMLT(CKR, CKI, PTR, PTI, CNORMR, CNORMI)`
			`DO 100 I=1,N`
			`STR = YR(I)CNORMR - YI(I)CNORMI`
			`YI(I) = YR(I)CNORMI + YI(I)CNORMR`
			`YR(I) = STR`
			`100 CONTINUE`
			`RETURN`
			`110 CONTINUE`
			`NZ=-2`
			`RETURN`
			`END`