double precision function dnrm2 ( n, dx, incx)
      integer i, incx, ix, j, n, next
      double precision   dx(1), cutlo, cuthi, hitest, sum, xmax,zero,one
      data   zero, one /0.0d0, 1.0d0/
c
c     euclidean norm of the n-vector stored in dx() with storage
c     increment incx .
c     if    n .le. 0 return with result = 0.
c     if n .ge. 1 then incx must be .ge. 1
c
c           c.l.lawson, 1978 jan 08
c     modified to correct failure to update ix, 1/25/92.
c     modified 3/93 to return if incx .le. 0.
c
c     four phase method     using two built-in constants that are
c     hopefully applicable to all machines.
c         cutlo = maximum of  dsqrt(u/eps)  over all known machines.
c         cuthi = minimum of  dsqrt(v)      over all known machines.
c     where
c         eps = smallest no. such that eps + 1. .gt. 1.
c         u   = smallest positive no.   (underflow limit)
c         v   = largest  no.            (overflow  limit)
c
c     brief outline of algorithm..
c
c     phase 1    scans zero components.
c     move to phase 2 when a component is nonzero and .le. cutlo
c     move to phase 3 when a component is .gt. cutlo
c     move to phase 4 when a component is .ge. cuthi/m
c     where m = n for x() real and m = 2*n for complex.
c
c     values for cutlo and cuthi..
c     from the environmental parameters listed in the imsl converter
c     document the limiting values are as follows..
c     cutlo, s.p.   u/eps = 2**(-102) for  honeywell.  close seconds are
c                   univac and dec at 2**(-103)
c                   thus cutlo = 2**(-51) = 4.44089e-16
c     cuthi, s.p.   v = 2**127 for univac, honeywell, and dec.
c                   thus cuthi = 2**(63.5) = 1.30438e19
c     cutlo, d.p.   u/eps = 2**(-67) for honeywell and dec.
c                   thus cutlo = 2**(-33.5) = 8.23181d-11
c     cuthi, d.p.   same as s.p.  cuthi = 1.30438d19
c     data cutlo, cuthi / 8.232d-11,  1.304d19 /
c     data cutlo, cuthi / 4.441e-16,  1.304e19 /
      data cutlo, cuthi / 8.232d-11,  1.304d19 /
c
      if(n .gt. 0 .and. incx.gt.0) go to 10
         dnrm2  = zero
         go to 300
c
   10 assign 30 to next
      sum = zero
      i = 1
      ix = 1
c                                                 begin main loop
   20    go to next,(30, 50, 70, 110)
   30 if( dabs(dx(i)) .gt. cutlo) go to 85
      assign 50 to next
      xmax = zero
c
c                        phase 1.  sum is zero
c
   50 if( dx(i) .eq. zero) go to 200
      if( dabs(dx(i)) .gt. cutlo) go to 85
c
c                                prepare for phase 2.
      assign 70 to next
      go to 105
c
c                                prepare for phase 4.
c
  100 continue
      ix = j
      assign 110 to next
      sum = (sum / dx(i)) / dx(i)
  105 xmax = dabs(dx(i))
      go to 115
c
c                   phase 2.  sum is small.
c                             scale to avoid destructive underflow.
c
   70 if( dabs(dx(i)) .gt. cutlo ) go to 75
c
c                     common code for phases 2 and 4.
c                     in phase 4 sum is large.  scale to avoid overflow.
c
  110 if( dabs(dx(i)) .le. xmax ) go to 115
         sum = one + sum * (xmax / dx(i))**2
         xmax = dabs(dx(i))
         go to 200
c
  115 sum = sum + (dx(i)/xmax)**2
      go to 200
c
c
c                  prepare for phase 3.
c
   75 sum = (sum * xmax) * xmax
c
c
c     for real or d.p. set hitest = cuthi/n
c     for complex      set hitest = cuthi/(2*n)
c
   85 hitest = cuthi/float( n )
c
c                   phase 3.  sum is mid-range.  no scaling.
c
      do 95 j = ix,n
      if(dabs(dx(i)) .ge. hitest) go to 100
         sum = sum + dx(i)**2
         i = i + incx
   95 continue
      dnrm2 = dsqrt( sum )
      go to 300
c
  200 continue
      ix = ix + 1
      i = i + incx
      if( ix .le. n ) go to 20
c
c              end of main loop.
c
c              compute square root and adjust for scaling.
c
      dnrm2 = xmax * dsqrt(sum)
  300 continue
      return
      end