subroutine cchdc(a,lda,p,work,jpvt,job,info)
      integer lda,p,jpvt(1),job,info
      complex a(lda,1),work(1)
c
c     cchdc computes the cholesky decomposition of a positive definite
c     matrix.  a pivoting option allows the user to estimate the
c     condition of a positive definite matrix or determine the rank
c     of a positive semidefinite matrix.
c
c     on entry
c
c         a      complex(lda,p).
c                a contains the matrix whose decomposition is to
c                be computed.  onlt the upper half of a need be stored.
c                the lower part of the array a is not referenced.
c
c         lda    integer.
c                lda is the leading dimension of the array a.
c
c         p      integer.
c                p is the order of the matrix.
c
c         work   complex.
c                work is a work array.
c
c         jpvt   integer(p).
c                jpvt contains integers that control the selection
c                of the pivot elements, if pivoting has been requested.
c                each diagonal element a(k,k)
c                is placed in one of three classes according to the
c                value of jpvt(k).
c
c                   if jpvt(k) .gt. 0, then x(k) is an initial
c                                      element.
c
c                   if jpvt(k) .eq. 0, then x(k) is a free element.
c
c                   if jpvt(k) .lt. 0, then x(k) is a final element.
c
c                before the decomposition is computed, initial elements
c                are moved by symmetric row and column interchanges to
c                the beginning of the array a and final
c                elements to the end.  both initial and final elements
c                are frozen in place during the computation and only
c                free elements are moved.  at the k-th stage of the
c                reduction, if a(k,k) is occupied by a free element
c                it is interchanged with the largest free element
c                a(l,l) with l .ge. k.  jpvt is not referenced if
c                job .eq. 0.
c
c        job     integer.
c                job is an integer that initiates column pivoting.
c                if job .eq. 0, no pivoting is done.
c                if job .ne. 0, pivoting is done.
c
c     on return
c
c         a      a contains in its upper half the cholesky factor
c                of the matrix a as it has been permuted by pivoting.
c
c         jpvt   jpvt(j) contains the index of the diagonal element
c                of a that was moved into the j-th position,
c                provided pivoting was requested.
c
c         info   contains the index of the last positive diagonal
c                element of the cholesky factor.
c
c     for positive definite matrices info = p is the normal return.
c     for pivoting with positive semidefinite matrices info will
c     in general be less than p.  however, info may be greater than
c     the rank of a, since rounding error can cause an otherwise zero
c     element to be positive. indefinite systems will always cause
c     info to be less than p.
c
c     linpack. this version dated 03/19/79 .
c     j.j. dongarra and g.w. stewart, argonne national laboratory and
c     university of maryland.
c
c
c     blas caxpy,cswap
c     fortran sqrt,real,conjg
c
c     internal variables
c
      integer pu,pl,plp1,i,j,jp,jt,k,kb,km1,kp1,l,maxl
      complex temp
      real maxdia
      logical swapk,negk
c
      pl = 1
      pu = 0
      info = p
      if (job .eq. 0) go to 160
c
c        pivoting has been requested. rearrange the
c        the elements according to jpvt.
c
         do 70 k = 1, p
            swapk = jpvt(k) .gt. 0
            negk = jpvt(k) .lt. 0
            jpvt(k) = k
            if (negk) jpvt(k) = -jpvt(k)
            if (.not.swapk) go to 60
               if (k .eq. pl) go to 50
                  call cswap(pl-1,a(1,k),1,a(1,pl),1)
                  temp = a(k,k)
                  a(k,k) = a(pl,pl)
                  a(pl,pl) = temp
                  a(pl,k) = conjg(a(pl,k))
                  plp1 = pl + 1
                  if (p .lt. plp1) go to 40
                  do 30 j = plp1, p
                     if (j .ge. k) go to 10
                        temp = conjg(a(pl,j))
                        a(pl,j) = conjg(a(j,k))
                        a(j,k) = temp
                     go to 20
   10                continue
                     if (j .eq. k) go to 20
                        temp = a(k,j)
                        a(k,j) = a(pl,j)
                        a(pl,j) = temp
   20                continue
   30             continue
   40             continue
                  jpvt(k) = jpvt(pl)
                  jpvt(pl) = k
   50          continue
               pl = pl + 1
   60       continue
   70    continue
         pu = p
         if (p .lt. pl) go to 150
         do 140 kb = pl, p
            k = p - kb + pl
            if (jpvt(k) .ge. 0) go to 130
               jpvt(k) = -jpvt(k)
               if (pu .eq. k) go to 120
                  call cswap(k-1,a(1,k),1,a(1,pu),1)
                  temp = a(k,k)
                  a(k,k) = a(pu,pu)
                  a(pu,pu) = temp
                  a(k,pu) = conjg(a(k,pu))
                  kp1 = k + 1
                  if (p .lt. kp1) go to 110
                  do 100 j = kp1, p
                     if (j .ge. pu) go to 80
                        temp = conjg(a(k,j))
                        a(k,j) = conjg(a(j,pu))
                        a(j,pu) = temp
                     go to 90
   80                continue
                     if (j .eq. pu) go to 90
                        temp = a(k,j)
                        a(k,j) = a(pu,j)
                        a(pu,j) = temp
   90                continue
  100             continue
  110             continue
                  jt = jpvt(k)
                  jpvt(k) = jpvt(pu)
                  jpvt(pu) = jt
  120          continue
               pu = pu - 1
  130       continue
  140    continue
  150    continue
  160 continue
      do 270 k = 1, p
c
c        reduction loop.
c
         maxdia = real(a(k,k))
         kp1 = k + 1
         maxl = k
c
c        determine the pivot element.
c
         if (k .lt. pl .or. k .ge. pu) go to 190
            do 180 l = kp1, pu
               if (real(a(l,l)) .le. maxdia) go to 170
                  maxdia = real(a(l,l))
                  maxl = l
  170          continue
  180       continue
  190    continue
c
c        quit if the pivot element is not positive.
c
         if (maxdia .gt. 0.0e0) go to 200
            info = k - 1
c     ......exit
            go to 280
  200    continue
         if (k .eq. maxl) go to 210
c
c           start the pivoting and update jpvt.
c
            km1 = k - 1
            call cswap(km1,a(1,k),1,a(1,maxl),1)
            a(maxl,maxl) = a(k,k)
            a(k,k) = cmplx(maxdia,0.0e0)
            jp = jpvt(maxl)
            jpvt(maxl) = jpvt(k)
            jpvt(k) = jp
            a(k,maxl) = conjg(a(k,maxl))
  210    continue
c
c        reduction step. pivoting is contained across the rows.
c
         work(k) = cmplx(sqrt(real(a(k,k))),0.0e0)
         a(k,k) = work(k)
         if (p .lt. kp1) go to 260
         do 250 j = kp1, p
            if (k .eq. maxl) go to 240
               if (j .ge. maxl) go to 220
                  temp = conjg(a(k,j))
                  a(k,j) = conjg(a(j,maxl))
                  a(j,maxl) = temp
               go to 230
  220          continue
               if (j .eq. maxl) go to 230
                  temp = a(k,j)
                  a(k,j) = a(maxl,j)
                  a(maxl,j) = temp
  230          continue
  240       continue
            a(k,j) = a(k,j)/work(k)
            work(j) = conjg(a(k,j))
            temp = -a(k,j)
            call caxpy(j-k,temp,work(kp1),1,a(kp1,j),1)
  250    continue
  260    continue
  270 continue
  280 continue
      return
      end