psblas3/base/serial/psb_ip_reord_mod.f90

!!$ 
!!$              Parallel Sparse BLAS  version 2.2
!!$    (C) Copyright 2006/2007/2008
!!$                       Salvatore Filippone    University of Rome Tor Vergata
!!$                       Alfredo Buttari        University of Rome Tor Vergata
!!$ 
!!$  Redistribution and use in source and binary forms, with or without
!!$  modification, are permitted provided that the following conditions
!!$  are met:
!!$    1. Redistributions of source code must retain the above copyright
!!$       notice, this list of conditions and the following disclaimer.
!!$    2. Redistributions in binary form must reproduce the above copyright
!!$       notice, this list of conditions, and the following disclaimer in the
!!$       documentation and/or other materials provided with the distribution.
!!$    3. The name of the PSBLAS group or the names of its contributors may
!!$       not be used to endorse or promote products derived from this
!!$       software without specific written permission.
!!$ 
!!$  THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
!!$  ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
!!$  TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
!!$  PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE PSBLAS GROUP OR ITS CONTRIBUTORS
!!$  BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
!!$  CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
!!$  SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
!!$  INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
!!$  CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
!!$  ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
!!$  POSSIBILITY OF SUCH DAMAGE.
!!$ 
!!$  
!
!  Reorder (an) input vector(s) based on a list sort output.
!  Based on: D. E. Knuth: The Art of Computer Programming
!            vol. 3: Sorting and Searching, Addison Wesley, 1973
!            ex. 5.2.12
!
!
module psb_ip_reord_mod 
  use psb_const_mod
  
  interface psb_ip_reord
    module procedure psb_ip_reord_i1,&
         & psb_ip_reord_s1, psb_ip_reord_d1,&
         & psb_ip_reord_c1, psb_ip_reord_z1,&
         & psb_ip_reord_i1i1,&
         & psb_ip_reord_s1i1, psb_ip_reord_d1i1,&
         & psb_ip_reord_c1i1, psb_ip_reord_z1i1,&
         & psb_ip_reord_s1i2, psb_ip_reord_d1i2,&
         & psb_ip_reord_c1i2, psb_ip_reord_z1i2,&
         & psb_ip_reord_s1i3, psb_ip_reord_d1i3,&
         & psb_ip_reord_c1i3, psb_ip_reord_z1i3


  end interface

contains
  
  subroutine psb_ip_reord_i1(n,x,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    integer             :: x(*)
    
    integer :: lswap, lp, k
    integer :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_i1

  
  subroutine psb_ip_reord_s1(n,x,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_spk_)      :: x(*)
    
    integer :: lswap, lp, k
    real(psb_spk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_s1
  
  subroutine psb_ip_reord_d1(n,x,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_dpk_)      :: x(*)
    
    integer :: lswap, lp, k
    real(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_d1


  subroutine psb_ip_reord_c1(n,x,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_spk_)   :: x(*)
    
    integer :: lswap, lp, k
    complex(psb_spk_) :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_c1
  
  subroutine psb_ip_reord_z1(n,x,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_dpk_)   :: x(*)
    
    integer :: lswap, lp, k
    complex(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_z1

  
  subroutine psb_ip_reord_i1i1(n,x,indx,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    integer             :: x(*)
    integer             :: indx(*) 
    
    integer :: lswap, lp, k, ixswap
    integer :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      ixswap   = indx(lp)
      indx(lp) = indx(k)
      indx(k)  = ixswap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_i1i1

  
  subroutine psb_ip_reord_s1i1(n,x,indx,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_spk_)      :: x(*)
    integer             :: indx(*) 

    
    integer :: lswap, lp, k, ixswap
    real(psb_spk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      ixswap   = indx(lp)
      indx(lp) = indx(k)
      indx(k)  = ixswap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_s1i1
  
  subroutine psb_ip_reord_d1i1(n,x,indx,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_dpk_)      :: x(*)
    integer             :: indx(*) 
    
    integer :: lswap, lp, k, ixswap
    real(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      ixswap   = indx(lp)
      indx(lp) = indx(k)
      indx(k)  = ixswap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_d1i1


  subroutine psb_ip_reord_c1i1(n,x,indx,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_spk_)   :: x(*)
    integer             :: indx(*) 
    
    integer :: lswap, lp, k, ixswap
    complex(psb_spk_) :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      ixswap   = indx(lp)
      indx(lp) = indx(k)
      indx(k)  = ixswap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_c1i1
  
  subroutine psb_ip_reord_z1i1(n,x,indx,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_dpk_)   :: x(*)
    integer             :: indx(*) 
    
    integer :: lswap, lp, k, ixswap
    complex(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      ixswap   = indx(lp)
      indx(lp) = indx(k)
      indx(k)  = ixswap
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_z1i1


  subroutine psb_ip_reord_s1i2(n,x,i1,i2,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_spk_)      :: x(*)
    integer             :: i1(*), i2(*) 

    
    integer :: lswap, lp, k, isw1, isw2
    real(psb_spk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_s1i2
  
  subroutine psb_ip_reord_d1i2(n,x,i1,i2,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_dpk_)      :: x(*)
    integer             :: i1(*), i2(*) 

    
    integer :: lswap, lp, k, isw1, isw2
    real(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_d1i2
  
  subroutine psb_ip_reord_c1i2(n,x,i1,i2,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_spk_)   :: x(*)
    integer             :: i1(*), i2(*) 

    
    integer :: lswap, lp, k, isw1, isw2
    complex(psb_spk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_c1i2
  
  subroutine psb_ip_reord_z1i2(n,x,i1,i2,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_dpk_)   :: x(*)
    integer             :: i1(*), i2(*) 

    
    integer :: lswap, lp, k, isw1, isw2
    complex(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_z1i2

 
  subroutine psb_ip_reord_s1i3(n,x,i1,i2,i3,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_spk_)      :: x(*)
    integer             :: i1(*), i2(*), i3(*)  

    
    integer :: lswap, lp, k, isw1, isw2, isw3
    real(psb_spk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      isw3     = i3(lp)
      i3(lp)   = i3(k)
      i3(k)    = isw3
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_s1i3
  
  subroutine psb_ip_reord_d1i3(n,x,i1,i2,i3,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    real(psb_dpk_)      :: x(*)
    integer             :: i1(*), i2(*),i3(*)

    
    integer :: lswap, lp, k, isw1, isw2,isw3
    real(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      isw3     = i3(lp)
      i3(lp)   = i3(k)
      i3(k)    = isw3
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_d1i3
  
  subroutine psb_ip_reord_c1i3(n,x,i1,i2,i3,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_spk_)   :: x(*)
    integer             :: i1(*), i2(*), i3(*) 

    
    integer :: lswap, lp, k, isw1, isw2, isw3
    complex(psb_spk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      isw3     = i3(lp)
      i3(lp)   = i3(k)
      i3(k)    = isw3
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_c1i3
  
  subroutine psb_ip_reord_z1i3(n,x,i1,i2,i3,iaux)
    integer, intent(in) :: n
    integer             :: iaux(0:*) 
    complex(psb_dpk_)   :: x(*)
    integer             :: i1(*), i2(*), i3(*)

    
    integer :: lswap, lp, k, isw1, isw2, isw3
    complex(psb_dpk_)  :: swap

    lp = iaux(0)
    k  = 1
    do 
      if ((lp==0).or.(k>n)) exit
      do 
        if (lp >= k) exit
        lp = iaux(lp)
      end do
      swap     = x(lp)
      x(lp)    = x(k)
      x(k)     = swap
      isw1     = i1(lp)
      i1(lp)   = i1(k)
      i1(k)    = isw1
      isw2     = i2(lp)
      i2(lp)   = i2(k)
      i2(k)    = isw2
      isw3     = i3(lp)
      i3(lp)   = i3(k)
      i3(k)    = isw3
      lswap    = iaux(lp)
      iaux(lp) = iaux(k)
      iaux(k)  = lp
      lp = lswap 
      k  = k + 1
    enddo
    return
  end subroutine psb_ip_reord_z1i3

 
end module psb_ip_reord_mod
psblas: base/serial/Makefile base/serial/aux/camsr.f90 base/serial/aux/camsrx.f90 base/serial/aux/dmsr.f90 base/serial/aux/dmsrx.f90 base/serial/aux/imsr.f90 base/serial/aux/imsrx.f90 base/serial/aux/smsr.f90 base/serial/aux/smsrx.f90 base/serial/aux/zamsr.f90 base/serial/aux/zamsrx.f90 base/serial/dp/Makefile base/serial/dp/ccoco.f base/serial/dp/ccocr.f base/serial/dp/dcoco.f base/serial/dp/dcocr.f base/serial/dp/djdcox.f base/serial/dp/reordvn.f base/serial/dp/scoco.f base/serial/dp/scocr.f base/serial/dp/zcoco.f base/serial/dp/zcocr.f base/serial/psb_cfixcoo.f90 base/serial/psb_dfixcoo.f90 base/serial/psb_ip_reord_mod.f90 base/serial/psb_sfixcoo.f90 base/serial/psb_zfixcoo.f90 Defined a new module ip_reord to handle reordering based on a list-sort output; this will avoid future type mismatch, such as the one causing trouble in the final mld2p4 testing for complex single precision. 17 years ago			`!!$`
			`!!$ Parallel Sparse BLAS version 2.2`
			`!!$ (C) Copyright 2006/2007/2008`
			`!!$ Salvatore Filippone University of Rome Tor Vergata`
			`!!$ Alfredo Buttari University of Rome Tor Vergata`
			`!!$`
			`!!$ Redistribution and use in source and binary forms, with or without`
			`!!$ modification, are permitted provided that the following conditions`
			`!!$ are met:`
			`!!$ 1. Redistributions of source code must retain the above copyright`
			`!!$ notice, this list of conditions and the following disclaimer.`
			`!!$ 2. Redistributions in binary form must reproduce the above copyright`
			`!!$ notice, this list of conditions, and the following disclaimer in the`
			`!!$ documentation and/or other materials provided with the distribution.`
			`!!$ 3. The name of the PSBLAS group or the names of its contributors may`
			`!!$ not be used to endorse or promote products derived from this`
			`!!$ software without specific written permission.`
			`!!$`
			`!!$ THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS`
			!!$ ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
			`!!$ TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR`
			`!!$ PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE PSBLAS GROUP OR ITS CONTRIBUTORS`
			`!!$ BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR`
			`!!$ CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF`
			`!!$ SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS`
			`!!$ INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN`
			`!!$ CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)`
			`!!$ ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE`
			`!!$ POSSIBILITY OF SUCH DAMAGE.`
			`!!$`
			`!!$`
			`!`
			`! Reorder (an) input vector(s) based on a list sort output.`
			`! Based on: D. E. Knuth: The Art of Computer Programming`
			`! vol. 3: Sorting and Searching, Addison Wesley, 1973`
			`! ex. 5.2.12`
			`!`
			`!`
			`module psb_ip_reord_mod`
			`use psb_const_mod`

			`interface psb_ip_reord`
			`module procedure psb_ip_reord_i1,&`
			`& psb_ip_reord_s1, psb_ip_reord_d1,&`
			`& psb_ip_reord_c1, psb_ip_reord_z1,&`
			`& psb_ip_reord_i1i1,&`
			`& psb_ip_reord_s1i1, psb_ip_reord_d1i1,&`
			`& psb_ip_reord_c1i1, psb_ip_reord_z1i1,&`
			`& psb_ip_reord_s1i2, psb_ip_reord_d1i2,&`
			`& psb_ip_reord_c1i2, psb_ip_reord_z1i2,&`
			`& psb_ip_reord_s1i3, psb_ip_reord_d1i3,&`
			`& psb_ip_reord_c1i3, psb_ip_reord_z1i3`


			`end interface`

			`contains`

			`subroutine psb_ip_reord_i1(n,x,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`integer :: x(*)`

			`integer :: lswap, lp, k`
			`integer :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_i1`


			`subroutine psb_ip_reord_s1(n,x,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_spk_) :: x(*)`

			`integer :: lswap, lp, k`
			`real(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_s1`

			`subroutine psb_ip_reord_d1(n,x,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_dpk_) :: x(*)`

			`integer :: lswap, lp, k`
			`real(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_d1`



			`subroutine psb_ip_reord_c1(n,x,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_spk_) :: x(*)`

			`integer :: lswap, lp, k`
			`complex(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_c1`

			`subroutine psb_ip_reord_z1(n,x,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_dpk_) :: x(*)`

			`integer :: lswap, lp, k`
			`complex(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_z1`


			`subroutine psb_ip_reord_i1i1(n,x,indx,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`integer :: x(*)`
			`integer :: indx(*)`

			`integer :: lswap, lp, k, ixswap`
			`integer :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`ixswap = indx(lp)`
			`indx(lp) = indx(k)`
			`indx(k) = ixswap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_i1i1`


			`subroutine psb_ip_reord_s1i1(n,x,indx,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_spk_) :: x(*)`
			`integer :: indx(*)`


			`integer :: lswap, lp, k, ixswap`
			`real(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`ixswap = indx(lp)`
			`indx(lp) = indx(k)`
			`indx(k) = ixswap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_s1i1`

			`subroutine psb_ip_reord_d1i1(n,x,indx,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_dpk_) :: x(*)`
			`integer :: indx(*)`

			`integer :: lswap, lp, k, ixswap`
			`real(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`ixswap = indx(lp)`
			`indx(lp) = indx(k)`
			`indx(k) = ixswap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_d1i1`



			`subroutine psb_ip_reord_c1i1(n,x,indx,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_spk_) :: x(*)`
			`integer :: indx(*)`

			`integer :: lswap, lp, k, ixswap`
			`complex(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`ixswap = indx(lp)`
			`indx(lp) = indx(k)`
			`indx(k) = ixswap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_c1i1`

			`subroutine psb_ip_reord_z1i1(n,x,indx,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_dpk_) :: x(*)`
			`integer :: indx(*)`

			`integer :: lswap, lp, k, ixswap`
			`complex(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`ixswap = indx(lp)`
			`indx(lp) = indx(k)`
			`indx(k) = ixswap`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_z1i1`


			`subroutine psb_ip_reord_s1i2(n,x,i1,i2,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_spk_) :: x(*)`
			`integer :: i1(), i2()`


			`integer :: lswap, lp, k, isw1, isw2`
			`real(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_s1i2`

			`subroutine psb_ip_reord_d1i2(n,x,i1,i2,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_dpk_) :: x(*)`
			`integer :: i1(), i2()`


			`integer :: lswap, lp, k, isw1, isw2`
			`real(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_d1i2`

			`subroutine psb_ip_reord_c1i2(n,x,i1,i2,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_spk_) :: x(*)`
			`integer :: i1(), i2()`


			`integer :: lswap, lp, k, isw1, isw2`
			`complex(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_c1i2`

			`subroutine psb_ip_reord_z1i2(n,x,i1,i2,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_dpk_) :: x(*)`
			`integer :: i1(), i2()`


			`integer :: lswap, lp, k, isw1, isw2`
			`complex(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_z1i2`


			`subroutine psb_ip_reord_s1i3(n,x,i1,i2,i3,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_spk_) :: x(*)`
			`integer :: i1(), i2(), i3(*)`


			`integer :: lswap, lp, k, isw1, isw2, isw3`
			`real(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`isw3 = i3(lp)`
			`i3(lp) = i3(k)`
			`i3(k) = isw3`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_s1i3`

			`subroutine psb_ip_reord_d1i3(n,x,i1,i2,i3,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`real(psb_dpk_) :: x(*)`
			`integer :: i1(), i2(),i3(*)`


			`integer :: lswap, lp, k, isw1, isw2,isw3`
			`real(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`isw3 = i3(lp)`
			`i3(lp) = i3(k)`
			`i3(k) = isw3`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_d1i3`

			`subroutine psb_ip_reord_c1i3(n,x,i1,i2,i3,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_spk_) :: x(*)`
			`integer :: i1(), i2(), i3(*)`


			`integer :: lswap, lp, k, isw1, isw2, isw3`
			`complex(psb_spk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`isw3 = i3(lp)`
			`i3(lp) = i3(k)`
			`i3(k) = isw3`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_c1i3`

			`subroutine psb_ip_reord_z1i3(n,x,i1,i2,i3,iaux)`
			`integer, intent(in) :: n`
			`integer :: iaux(0:*)`
			`complex(psb_dpk_) :: x(*)`
			`integer :: i1(), i2(), i3(*)`


			`integer :: lswap, lp, k, isw1, isw2, isw3`
			`complex(psb_dpk_) :: swap`

			`lp = iaux(0)`
			`k = 1`
			`do`
			`if ((lp==0).or.(k>n)) exit`
			`do`
			`if (lp >= k) exit`
			`lp = iaux(lp)`
			`end do`
			`swap = x(lp)`
			`x(lp) = x(k)`
			`x(k) = swap`
			`isw1 = i1(lp)`
			`i1(lp) = i1(k)`
			`i1(k) = isw1`
			`isw2 = i2(lp)`
			`i2(lp) = i2(k)`
			`i2(k) = isw2`
			`isw3 = i3(lp)`
			`i3(lp) = i3(k)`
			`i3(k) = isw3`
			`lswap = iaux(lp)`
			`iaux(lp) = iaux(k)`
			`iaux(k) = lp`
			`lp = lswap`
			`k = k + 1`
			`enddo`
			`return`
			`end subroutine psb_ip_reord_z1i3`


			`end module psb_ip_reord_mod`