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quantum_package/src/Utils/sort.irp.f

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BEGIN_TEMPLATE
subroutine insertion_$Xsort (x,iorder,isize)
implicit none
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BEGIN_DOC
! Sort array x(isize) using the insertion sort algorithm.
! iorder in input should be (1,2,3,...,isize), and in output
! contains the new order of the elements.
END_DOC
$type,intent(inout) :: x(isize)
integer,intent(inout) :: iorder(isize)
integer,intent(in) :: isize
$type :: xtmp
integer :: i, i0, j, jmax
do i=1,isize
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xtmp = x(i)
i0 = iorder(i)
j = i-1
do j=i-1,1,-1
if ( x(j) > xtmp ) then
x(j+1) = x(j)
iorder(j+1) = iorder(j)
else
exit
endif
enddo
x(j+1) = xtmp
iorder(j+1) = i0
enddo
end subroutine insertion_$Xsort
subroutine heap_$Xsort(x,iorder,isize)
implicit none
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BEGIN_DOC
! Sort array x(isize) using the heap sort algorithm.
! iorder in input should be (1,2,3,...,isize), and in output
! contains the new order of the elements.
END_DOC
$type,intent(inout) :: x(isize)
integer,intent(inout) :: iorder(isize)
integer,intent(in) :: isize
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integer :: i, k, j, l, i0
$type :: xtemp
l = isize/2+1
k = isize
do while (.True.)
if (l>1) then
l=l-1
xtemp = x(l)
i0 = iorder(l)
else
xtemp = x(k)
i0 = iorder(k)
x(k) = x(1)
iorder(k) = iorder(1)
k = k-1
if (k == 1) then
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x(1) = xtemp
iorder(1) = i0
exit
endif
endif
i=l
j = ishft(l,1)
do while (j<k)
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if ( x(j) < x(j+1) ) then
j=j+1
endif
if (xtemp < x(j)) then
x(i) = x(j)
iorder(i) = iorder(j)
i = j
j = ishft(j,1)
else
j = k+1
endif
enddo
if (j==k) then
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if (xtemp < x(j)) then
x(i) = x(j)
iorder(i) = iorder(j)
i = j
j = ishft(j,1)
else
j = k+1
endif
endif
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x(i) = xtemp
iorder(i) = i0
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enddo
end subroutine heap_$Xsort
subroutine heap_$Xsort_big(x,iorder,isize)
implicit none
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BEGIN_DOC
! Sort array x(isize) using the heap sort algorithm.
! iorder in input should be (1,2,3,...,isize), and in output
! contains the new order of the elements.
! This is a version for very large arrays where the indices need
! to be in integer*8 format
END_DOC
$type,intent(inout) :: x(isize)
integer*8,intent(inout) :: iorder(isize)
integer*8,intent(in) :: isize
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integer*8 :: i, k, j, l, i0
$type :: xtemp
l = isize/2+1
k = isize
do while (.True.)
if (l>1) then
l=l-1
xtemp = x(l)
i0 = iorder(l)
else
xtemp = x(k)
i0 = iorder(k)
x(k) = x(1)
iorder(k) = iorder(1)
k = k-1
if (k == 1) then
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x(1) = xtemp
iorder(1) = i0
exit
endif
endif
i=l
j = ishft(l,1)
do while (j<k)
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if ( x(j) < x(j+1) ) then
j=j+1
endif
if (xtemp < x(j)) then
x(i) = x(j)
iorder(i) = iorder(j)
i = j
j = ishft(j,1)
else
j = k+1
endif
enddo
if (j==k) then
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if (xtemp < x(j)) then
x(i) = x(j)
iorder(i) = iorder(j)
i = j
j = ishft(j,1)
else
j = k+1
endif
endif
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x(i) = xtemp
iorder(i) = i0
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enddo
end subroutine heap_$Xsort$big
subroutine $Xsort(x,iorder,isize)
implicit none
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BEGIN_DOC
! Sort array x(isize).
! iorder in input should be (1,2,3,...,isize), and in output
! contains the new order of the elements.
END_DOC
$type,intent(inout) :: x(isize)
integer,intent(inout) :: iorder(isize)
integer,intent(in) :: isize
if (isize < 32) then
call insertion_$Xsort(x,iorder,isize)
else
call heap_$Xsort(x,iorder,isize)
endif
end subroutine $Xsort
SUBST [ X, type ]
; real ;;
d ; double precision ;;
i ; integer ;;
i8 ; integer*8 ;;
i2 ; integer*2 ;;
END_TEMPLATE
BEGIN_TEMPLATE
subroutine $Xset_order(x,iorder,isize)
implicit none
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BEGIN_DOC
! array A has already been sorted, and iorder has contains the new order of
! elements of A. This subroutine changes the order of x to match the new order of A.
END_DOC
integer :: isize
$type :: x(*)
$type,allocatable :: xtmp(:)
integer :: iorder(*)
integer :: i
allocate(xtmp(isize))
do i=1,isize
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xtmp(i) = x(iorder(i))
enddo
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do i=1,isize
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x(i) = xtmp(i)
enddo
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deallocate(xtmp)
end
SUBST [ X, type ]
; real ;;
d ; double precision ;;
i ; integer ;;
i8; integer*8 ;;
i2; integer*2 ;;
END_TEMPLATE
BEGIN_TEMPLATE
subroutine insertion_$Xsort_big (x,iorder,isize)
implicit none
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BEGIN_DOC
! Sort array x(isize) using the insertion sort algorithm.
! iorder in input should be (1,2,3,...,isize), and in output
! contains the new order of the elements.
! This is a version for very large arrays where the indices need
! to be in integer*8 format
END_DOC
$type,intent(inout) :: x(isize)
integer*8,intent(inout) :: iorder(isize)
integer*8,intent(in) :: isize
$type :: xtmp
integer*8 :: i, i0, j, jmax
do i=1_8,isize
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xtmp = x(i)
i0 = iorder(i)
j = i-1_8
do j=i-1_8,1_8,-1_8
if ( x(j) > xtmp ) then
x(j+1_8) = x(j)
iorder(j+1_8) = iorder(j)
else
exit
endif
enddo
x(j+1_8) = xtmp
iorder(j+1_8) = i0
enddo
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end subroutine insertion_$Xsort
subroutine $Xset_order_big(x,iorder,isize)
implicit none
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BEGIN_DOC
! array A has already been sorted, and iorder has contains the new order of
! elements of A. This subroutine changes the order of x to match the new order of A.
! This is a version for very large arrays where the indices need
! to be in integer*8 format
END_DOC
integer*8 :: isize
$type :: x(*)
$type, allocatable :: xtmp(:)
integer*8 :: iorder(*)
integer*8 :: i
allocate(xtmp(isize))
do i=1_8,isize
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xtmp(i) = x(iorder(i))
enddo
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do i=1_8,isize
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x(i) = xtmp(i)
enddo
deallocate(xtmp)
end
SUBST [ X, type ]
; real ;;
d ; double precision ;;
i ; integer ;;
i8; integer*8 ;;
i2; integer*2 ;;
END_TEMPLATE
BEGIN_TEMPLATE
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recursive subroutine $Xradix_sort$big(x,iorder,isize,iradix)
implicit none
BEGIN_DOC
! Sort integer array x(isize) using the radix sort algorithm.
! iorder in input should be (1,2,3,...,isize), and in output
! contains the new order of the elements.
! iradix should be -1 in input.
END_DOC
$int_type, intent(in) :: isize
$int_type, intent(inout) :: iorder(isize)
$type, intent(inout) :: x(isize)
integer, intent(in) :: iradix
integer :: iradix_new
$type, allocatable :: x2(:), x1(:)
$int_type, allocatable :: iorder1(:),iorder2(:)
$int_type :: i0, i1, i2, i3, i
integer, parameter :: integer_size=$octets
$type, parameter :: zero=$zero
$type :: mask
integer :: nthreads, omp_get_num_threads
!DIR$ ATTRIBUTES ALIGN : 128 :: iorder1,iorder2, x2, x1
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if (iradix == -1) then
! Find most significant bit
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i0 = 0_8
i3 = -1_8
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do i=1,isize
i3 = max(i3,x(i))
enddo
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iradix_new = integer_size-1-leadz(i3)
mask = ibset(zero,iradix_new)
nthreads = 1
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! nthreads = 1+ishft(omp_get_num_threads(),-1)
integer :: err
allocate(x1(isize/nthreads+1),iorder1(isize/nthreads+1),x2(isize/nthreads+1),iorder2(isize/nthreads+1),stat=err)
if (err /= 0) then
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print *, irp_here, ': Unable to allocate arrays'
stop
endif
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i1=1_8
i2=1_8
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do i=1,isize
if (iand(mask,x(i)) == zero) then
iorder1(i1) = iorder(i)
x1(i1) = x(i)
i1 = i1+1_8
else
iorder2(i2) = iorder(i)
x2(i2) = x(i)
i2 = i2+1_8
endif
enddo
i1=i1-1_8
i2=i2-1_8
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do i=1,i1
iorder(i0+i) = iorder1(i)
x(i0+i) = x1(i)
enddo
i0 = i0+i1
i3 = i0
deallocate(x1,iorder1,stat=err)
if (err /= 0) then
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print *, irp_here, ': Unable to deallocate arrays x1, iorder1'
stop
endif
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do i=1,i2
iorder(i0+i) = iorder2(i)
x(i0+i) = x2(i)
enddo
i0 = i0+i2
deallocate(x2,iorder2,stat=err)
if (err /= 0) then
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print *, irp_here, ': Unable to deallocate arrays x2, iorder2'
stop
endif
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if (i3>1) then
call $Xradix_sort$big(x,iorder,i3,iradix_new-1)
endif
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if (isize-i3>1) then
call $Xradix_sort$big(x(i3+1),iorder(i3+1),isize-i3,iradix_new-1)
endif
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return
endif
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ASSERT (iradix >= 0)
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if (isize < 48) then
call insertion_$Xsort$big(x,iorder,isize)
return
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endif
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allocate(x2(isize),iorder2(isize),stat=err)
if (err /= 0) then
print *, irp_here, ': Unable to allocate arrays x1, iorder1'
stop
endif
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mask = ibset(zero,iradix)
i0=1
i1=1
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do i=1,isize
if (iand(mask,x(i)) == zero) then
iorder(i0) = iorder(i)
x(i0) = x(i)
i0 = i0+1
else
iorder2(i1) = iorder(i)
x2(i1) = x(i)
i1 = i1+1
endif
enddo
i0=i0-1
i1=i1-1
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do i=1,i1
iorder(i0+i) = iorder2(i)
x(i0+i) = x2(i)
enddo
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deallocate(x2,iorder2,stat=err)
if (err /= 0) then
print *, irp_here, ': Unable to allocate arrays x2, iorder2'
stop
endif
if (iradix == 0) then
return
endif
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if (i1>1) then
call $Xradix_sort$big(x(i0+1),iorder(i0+1),i1,iradix-1)
endif
if (i0>1) then
call $Xradix_sort$big(x,iorder,i0,iradix-1)
endif
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end
SUBST [ X, type, octets, is_big, big, int_type, zero ]
i ; integer ; 32 ; .False. ; ; integer ; 0;;
i8 ; integer*8 ; 32 ; .False. ; ; integer ; 0_8;;
i2 ; integer*2 ; 32 ; .False. ; ; integer ; 0;;
i ; integer ; 64 ; .True. ; _big ; integer*8 ; 0 ;;
i8 ; integer*8 ; 64 ; .True. ; _big ; integer*8 ; 0_8 ;;
END_TEMPLATE