Add Fortran (Fixed Form) syntax test file

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Mohamed Abdelnour 2021-05-30 11:42:05 +02:00 committed by David Peter
parent 702b5caf2d
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C Fortran 77 implementation of a quicksort algorithm for arrays with
C real entries.
C ----------
C June 2019 
C Jason Allen Anema, Ph.D.
C Division of Statistical Genomics
C Department of Genetics
C Washington University School of Medicine in St. Louis
C 
C This work is partially supported NIH grant AG023746
C ----------
C Insertion sort is used for short arrays, as quicksort is slower on
C these.
C 
C Hoare partition scheme is used (sweeping left and right), as it does
C three times fewer swaps on average that the Lamuto partition scheme.
C In conjunction with this, tripartite partition is performed
C concurrently (solving the "Dutch National Flag problem"). This avoids 
C horrible runtimes on highly repetitive arrays. For example, without 
C this, an array of random zeros and ones would have a runtime of
C O(N^2), but now has a runtime of O(N). The runtime for this algorthm
C on arrays with k highly repetitive entries is now O(kN).
C 
C For medium length (sub)arrays, pivots are choosen using
C Median-of-Three, and those three items are sorted. For longer (sub)arrays
C the pseudomedian of nine (Median of medians). This avoids O(N^2) runtime on
C nonrandom inputs such as increasing and decreasing sequences. 
C
C See Louis Bentley, Jon & McIlroy, Douglas. (1993). Engineering a Sort Function.
C Softw., Pract. Exper.. 23. 1249-1265. 10.1002/spe.4380231105 for details. 
C
C The ordering on elements of the array are defined by a comparison
C function,compar, that is a user-supplied INTEGER*2 function of the form
C compar(a,b) which returns:
C -1 if a precedes b
C +1 if b precedes a
C 0 is a and b are considered equivalent
C and thus defines a total ordering.
C 
C If one would like to use the standard order on integers, the
C compar function could be written in a file "compint.F" as:
C ----------------------------------------------------------------
C INTEGER*2 FUNCTION compint(a,b)
C INTEGER a, b
C if(a.lt.b)then
C compint = -1
C elseif(a.gt.b)then
C compint = +1
C else
C compint = 0
C endif
C END
C ----------------------------------------------------------------
C Then in your program, call quicksort with:
C call quicksort_real_F77(array, n, compint)
C
C The maximal length of an array in this implementation is (2^31-1),
C but can be changed to allow for length up to (2^63-1) by changing the
C data types of the relevant variables and constants. If you wish to 
C sort longer arrays, of length N, you'll need to customize variable 
C and constant types and set mstack to be at least (2*log_2(N)+2). 
C
C ----------------------------------------------------------------
C Copyright 2019 Jason Allen Anema
C 
C Permission is hereby granted, free of charge, to any person obtaining
C a copy of this software and associated documentation files (the "Software"),
C to deal in the Software without restriction, including without limitation the
C rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
C sell copies of the Software, and to permit persons to whom the Software is
C furnished to do so, subject to the following conditions:
C
C The above copyright notice and this permission notice shall be included
C in all copies or substantial portions of the Software.
C
C THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
C OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
C FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
C THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
C LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
C FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
C IN THE SOFTWARE.
C -------------------------------------------------------------------
C
 SUBROUTINE quicksort_real_F77(array,n,compar)
 INTEGER n, maxins, maxmid, mstack
 REAL array(n)
 PARAMETER (maxins = 7, maxmid = 40, mstack = 128)
C maxins: maximal size of (sub)arrays to be sorted with
C insertion sort.
C maxmid: maximal size of (sub)arrays that will be quicksorted with
C Median-of-Three pivots.
C mstack: maximal size of required auxiliary storage (a stack), plus 2 
C extra spots, which tracks the starts and ends of yet unsorted 
C subarrays. mstack = 130 is large enough to handle arrays up to 
C length 2^63-1. This maximal size follows from
C processing smaller arrays first and pigeonhole principal.
C 
 INTEGER a, d, i, j, k, s, lo, mid, hi, tstack, bstack(mstack)
C a, d, i, j, k, s: indices
C lo, mid, and hi: their natural location in a (sub)array
C tstack: equal to twice the number of additional subarrays still 
C needing to be sorted
C bstack: stack of the endpoints of unsorted subarrays
 INTEGER pm1, pm2, pm3, pm4, pm5, pm6, pm7, pm8, pm9
C for pseudomedian of nine positions in (sub)arrays
 REAL piv, temp
C piv is to store the pivot's value
C 
 EXTERNAL compar
 INTEGER*2 compar
C compar is a user-supplied INTEGER*2 function of the form
C compar(a,b) which returns:
C -1 if a precedes b
C +1 if b precedes a
C 0 is a and b are considered equivalent
C and thus defines a total ordering. 
 tstack = 0
 lo = 1 
 hi = n
C
C Insertion sort subarrays of size maxins or less
 1 if(hi-lo+1.le.maxins)then
 do 10, i = lo + 1, hi, 1
 temp = array(i)
 do 11 j = i - 1, lo, -1
 if(compar(array(j), temp).le.0)goto 2
 array(j+1)=array(j)
 11 continue
 j = lo - 1
 2 array(j+1) = temp
 10 continue
 if(tstack.eq.0)return
C Pop the bstack, and start new partitioning
 hi = bstack(tstack)
 lo = bstack(tstack-1)
 tstack = tstack - 2
 else
C Use Median-of-Three as choice of pivot (median of lo, middle, hi)
C and reorder those elements appropriately when subarrays are medium
C length (between maxins and maxmid)
 mid = lo + (hi-lo)/2
 if(hi-lo.le.maxmid)then
 if(compar(array(mid), array(lo)).eq.-1)then
 temp = array(lo)
 array(lo) = array(mid)
 array(mid) = temp
 endif
 if(compar(array(hi), array(lo)).eq.-1)then
 temp = array(hi)
 array(hi) = array(lo)
 array(lo) = temp
 endif
 if(compar(array(hi), array(mid)).eq.-1)then
 temp = array(hi)
 array(hi) = array(mid)
 array(mid) = temp
 endif
C Use pseudomedian of nine (Median of medians) as choice of pivot when 
C subarrays are longer than maxmid. Note that doing it this way requires only 12
C comparisons for finding the pivot.
 elseif(hi-lo+1.gt.maxmid)then
 pm1 = lo
 pm5 = lo + (hi-lo)/2
 pm9 = hi
 pm3 = lo + (pm5-lo)/2
 pm7 = pm5 + (hi-pm5)/2
 pm2 = lo + (pm3-lo)/2
 pm4 = pm3 + (pm5-pm3)/2
 pm6 = pm5 + (pm7-pm5)/2
 pm8 = pm7 + (pm9-pm7)/2
C Median and sorting for pm1, pm2, pm3
 if(compar(array(pm2), array(pm1)).eq.-1)then
 temp = array(pm1)
 array(pm1) = array(pm2)
 array(pm2) = temp
 endif
 if(compar(array(pm3), array(pm1)).eq.-1)then
 temp = array(pm3)
 array(pm3) = array(pm1)
 array(pm1) = temp
 endif
 if(compar(array(pm3), array(pm2)).eq.-1)then
 temp = array(pm3)
 array(pm3) = array(pm2)
 array(pm2) = temp
 endif
C Median and sorting for pm4, pm5, pm6
 if(compar(array(pm5), array(pm4)).eq.-1)then
 temp = array(pm4)
 array(pm4) = array(pm5)
 array(pm5) = temp
 endif
 if(compar(array(pm6), array(pm4)).eq.-1)then
 temp = array(pm6)
 array(pm6) = array(pm4)
 array(pm4) = temp
 endif
 if(compar(array(pm6), array(pm5)).eq.-1)then
 temp = array(pm6)
 array(pm6) = array(pm5)
 array(pm5) = temp
 endif
C Median and sorting for pm7, pm8, pm9
 if(compar(array(pm8), array(pm7)).eq.-1)then
 temp = array(pm7)
 array(pm7) = array(pm8)
 array(pm8) = temp
 endif
 if(compar(array(pm9), array(pm7)).eq.-1)then
 temp = array(pm9)
 array(pm9) = array(pm7)
 array(pm7) = temp
 endif
 if(compar(array(pm9), array(pm8)).eq.-1)then
 temp = array(pm9)
 array(pm9) = array(pm8)
 array(pm8) = temp
 endif
C Median of the medians (which are now pm2, pm5, pm8)
 if(compar(array(pm5), array(pm2)).eq.-1)then
 temp = array(pm2)
 array(pm2) = array(pm5)
 array(pm5) = temp
 endif
 if(compar(array(pm8), array(pm2)).eq.-1)then
 temp = array(pm8)
 array(pm8) = array(pm2)
 array(pm2) = temp
 endif
 if(compar(array(pm8), array(pm5)).eq.-1)then
 temp = array(pm8)
 array(pm8) = array(pm5)
 array(pm5) = temp
 endif
 endif
C Pivot assigned for medium and long length subarrays.
C Note that pm5 = mid
 piv = array(mid)
C Initialize pointers for partitioning
 i = lo-1
 j = hi+1
C Initialize counts of repeat values of pivot.
 a = 0
 d = 0
C Beginning of outer loop for placing pivot.
 3 continue
C Scan up to find an element > piv.
 i = i + 1
C Check if pointers crossed.
 if(j.lt.i)goto 5
C Check if i pointer hit hi boundary.
 if(i.eq.hi)goto 4
C 
 if(compar(array(i), piv).eq.-1)goto 3
C Check for copies of pivot from scanning right. 
 if(compar(array(i), piv).eq.0)then
 array(i) = array(lo+a)
 array(lo+a) = piv
 a = a + 1
 goto 3 
 endif
C Beginning of innerloop for placing pivot.
 4 continue
C Scan down to find an element < piv.
 j = j - 1
C Check if pointers crossed.
 if(j.lt.i)goto 5
 if(compar(array(j), piv).eq.1)goto 4
C Check for copies of pivot from scanning left. 
 if(compar(array(j), piv).eq.0)then
 array(j) = array(hi-d)
 array(hi-d) = piv
 d = d + 1
 goto 4 
 endif
C Check if pointers crossed.
 if(j.lt.i)goto 5
C Exchange elements
 temp = array(i)
 array(i) = array(j)
 array(j) = temp
C End of outermost loop for placing pivot.
 goto 3
C Insert all copies of pivot in appropriate place
 5 s = MIN(a, j-lo-a+1)
 DO 6 k = 1, s
 array(lo-1+k) = array(i-k)
 array(i-k) = piv
 6 CONTINUE
 s = MIN(d, hi-j-d)
 DO 7 k = 1, s
 array(hi+1-k) = array(j+k)
 array(j+k) = piv
 7 CONTINUE
C Increase effective stack size
 tstack = tstack + 2 
C Push pointers to larger subarray on stack for later processing,
C process smaller subarray immediately. 
 if(tstack.gt.mstack) THEN
 WRITE(*,*)'Stack size is too small in quicksort fortran code quicksort_real_F77.F' 
 WRITE(*,*)'Are you sure you want to sort an array this long?'
 WRITE(*,*)'Your array has more than 2^63-1 entries?'
 WRITE(*,*)'If so, set mstack parameter to be at least:'
 WRITE(*,*)'2*ceiling(log_2(N))+2, for N = length of array,'
 WRITE(*,*)'and recompile this subroutine.'
 RETURN 
 endif
 if(hi-j-d-1.ge.j-a-lo)then
 bstack(tstack) = hi
 bstack(tstack-1) = MIN(j+d+1, hi)
 hi=MAX(j-a,lo)
 else
 bstack(tstack)=MAX(j-a,lo)
 bstack(tstack-1)=lo
 lo=MIN(j+d+1,hi)
 endif
C
C end of outermost if statement 
 endif
 goto 1
C END of subroutine quicksort
 END

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The `quicksort_real_F77.F` file has been added from https://github.com/jasonanema/Quicksort_Fortran77 under the following license:
```text
MIT License
Copyright (c) 2019 Jason Anema
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE.
```

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C Fortran 77 implementation of a quicksort algorithm for arrays with
C real entries.
C ----------
C June 2019
C Jason Allen Anema, Ph.D.
C Division of Statistical Genomics
C Department of Genetics
C Washington University School of Medicine in St. Louis
C
C This work is partially supported NIH grant AG023746
C ----------
C Insertion sort is used for short arrays, as quicksort is slower on
C these.
C
C Hoare partition scheme is used (sweeping left and right), as it does
C three times fewer swaps on average that the Lamuto partition scheme.
C In conjunction with this, tripartite partition is performed
C concurrently (solving the "Dutch National Flag problem"). This avoids
C horrible runtimes on highly repetitive arrays. For example, without
C this, an array of random zeros and ones would have a runtime of
C O(N^2), but now has a runtime of O(N). The runtime for this algorthm
C on arrays with k highly repetitive entries is now O(kN).
C
C For medium length (sub)arrays, pivots are choosen using
C Median-of-Three, and those three items are sorted. For longer (sub)arrays
C the pseudomedian of nine (Median of medians). This avoids O(N^2) runtime on
C nonrandom inputs such as increasing and decreasing sequences.
C
C See Louis Bentley, Jon & McIlroy, Douglas. (1993). Engineering a Sort Function.
C Softw., Pract. Exper.. 23. 1249-1265. 10.1002/spe.4380231105 for details.
C
C The ordering on elements of the array are defined by a comparison
C function,compar, that is a user-supplied INTEGER*2 function of the form
C compar(a,b) which returns:
C -1 if a precedes b
C +1 if b precedes a
C 0 is a and b are considered equivalent
C and thus defines a total ordering.
C
C If one would like to use the standard order on integers, the
C compar function could be written in a file "compint.F" as:
C ----------------------------------------------------------------
C INTEGER*2 FUNCTION compint(a,b)
C INTEGER a, b
C if(a.lt.b)then
C compint = -1
C elseif(a.gt.b)then
C compint = +1
C else
C compint = 0
C endif
C END
C ----------------------------------------------------------------
C Then in your program, call quicksort with:
C call quicksort_real_F77(array, n, compint)
C
C The maximal length of an array in this implementation is (2^31-1),
C but can be changed to allow for length up to (2^63-1) by changing the
C data types of the relevant variables and constants. If you wish to
C sort longer arrays, of length N, you'll need to customize variable
C and constant types and set mstack to be at least (2*log_2(N)+2).
C
C ----------------------------------------------------------------
C Copyright 2019 Jason Allen Anema
C
C Permission is hereby granted, free of charge, to any person obtaining
C a copy of this software and associated documentation files (the "Software"),
C to deal in the Software without restriction, including without limitation the
C rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
C sell copies of the Software, and to permit persons to whom the Software is
C furnished to do so, subject to the following conditions:
C
C The above copyright notice and this permission notice shall be included
C in all copies or substantial portions of the Software.
C
C THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
C OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
C FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
C THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
C LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
C FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
C IN THE SOFTWARE.
C -------------------------------------------------------------------
C
SUBROUTINE quicksort_real_F77(array,n,compar)
INTEGER n, maxins, maxmid, mstack
REAL array(n)
PARAMETER (maxins = 7, maxmid = 40, mstack = 128)
C maxins: maximal size of (sub)arrays to be sorted with
C insertion sort.
C maxmid: maximal size of (sub)arrays that will be quicksorted with
C Median-of-Three pivots.
C mstack: maximal size of required auxiliary storage (a stack), plus 2
C extra spots, which tracks the starts and ends of yet unsorted
C subarrays. mstack = 130 is large enough to handle arrays up to
C length 2^63-1. This maximal size follows from
C processing smaller arrays first and pigeonhole principal.
C
INTEGER a, d, i, j, k, s, lo, mid, hi, tstack, bstack(mstack)
C a, d, i, j, k, s: indices
C lo, mid, and hi: their natural location in a (sub)array
C tstack: equal to twice the number of additional subarrays still
C needing to be sorted
C bstack: stack of the endpoints of unsorted subarrays
INTEGER pm1, pm2, pm3, pm4, pm5, pm6, pm7, pm8, pm9
C for pseudomedian of nine positions in (sub)arrays
REAL piv, temp
C piv is to store the pivot's value
C
EXTERNAL compar
INTEGER*2 compar
C compar is a user-supplied INTEGER*2 function of the form
C compar(a,b) which returns:
C -1 if a precedes b
C +1 if b precedes a
C 0 is a and b are considered equivalent
C and thus defines a total ordering.
tstack = 0
lo = 1
hi = n
C
C Insertion sort subarrays of size maxins or less
1 if(hi-lo+1.le.maxins)then
do 10, i = lo + 1, hi, 1
temp = array(i)
do 11 j = i - 1, lo, -1
if(compar(array(j), temp).le.0)goto 2
array(j+1)=array(j)
11 continue
j = lo - 1
2 array(j+1) = temp
10 continue
if(tstack.eq.0)return
C Pop the bstack, and start new partitioning
hi = bstack(tstack)
lo = bstack(tstack-1)
tstack = tstack - 2
else
C Use Median-of-Three as choice of pivot (median of lo, middle, hi)
C and reorder those elements appropriately when subarrays are medium
C length (between maxins and maxmid)
mid = lo + (hi-lo)/2
if(hi-lo.le.maxmid)then
if(compar(array(mid), array(lo)).eq.-1)then
temp = array(lo)
array(lo) = array(mid)
array(mid) = temp
endif
if(compar(array(hi), array(lo)).eq.-1)then
temp = array(hi)
array(hi) = array(lo)
array(lo) = temp
endif
if(compar(array(hi), array(mid)).eq.-1)then
temp = array(hi)
array(hi) = array(mid)
array(mid) = temp
endif
C Use pseudomedian of nine (Median of medians) as choice of pivot when
C subarrays are longer than maxmid. Note that doing it this way requires only 12
C comparisons for finding the pivot.
elseif(hi-lo+1.gt.maxmid)then
pm1 = lo
pm5 = lo + (hi-lo)/2
pm9 = hi
pm3 = lo + (pm5-lo)/2
pm7 = pm5 + (hi-pm5)/2
pm2 = lo + (pm3-lo)/2
pm4 = pm3 + (pm5-pm3)/2
pm6 = pm5 + (pm7-pm5)/2
pm8 = pm7 + (pm9-pm7)/2
C Median and sorting for pm1, pm2, pm3
if(compar(array(pm2), array(pm1)).eq.-1)then
temp = array(pm1)
array(pm1) = array(pm2)
array(pm2) = temp
endif
if(compar(array(pm3), array(pm1)).eq.-1)then
temp = array(pm3)
array(pm3) = array(pm1)
array(pm1) = temp
endif
if(compar(array(pm3), array(pm2)).eq.-1)then
temp = array(pm3)
array(pm3) = array(pm2)
array(pm2) = temp
endif
C Median and sorting for pm4, pm5, pm6
if(compar(array(pm5), array(pm4)).eq.-1)then
temp = array(pm4)
array(pm4) = array(pm5)
array(pm5) = temp
endif
if(compar(array(pm6), array(pm4)).eq.-1)then
temp = array(pm6)
array(pm6) = array(pm4)
array(pm4) = temp
endif
if(compar(array(pm6), array(pm5)).eq.-1)then
temp = array(pm6)
array(pm6) = array(pm5)
array(pm5) = temp
endif
C Median and sorting for pm7, pm8, pm9
if(compar(array(pm8), array(pm7)).eq.-1)then
temp = array(pm7)
array(pm7) = array(pm8)
array(pm8) = temp
endif
if(compar(array(pm9), array(pm7)).eq.-1)then
temp = array(pm9)
array(pm9) = array(pm7)
array(pm7) = temp
endif
if(compar(array(pm9), array(pm8)).eq.-1)then
temp = array(pm9)
array(pm9) = array(pm8)
array(pm8) = temp
endif
C Median of the medians (which are now pm2, pm5, pm8)
if(compar(array(pm5), array(pm2)).eq.-1)then
temp = array(pm2)
array(pm2) = array(pm5)
array(pm5) = temp
endif
if(compar(array(pm8), array(pm2)).eq.-1)then
temp = array(pm8)
array(pm8) = array(pm2)
array(pm2) = temp
endif
if(compar(array(pm8), array(pm5)).eq.-1)then
temp = array(pm8)
array(pm8) = array(pm5)
array(pm5) = temp
endif
endif
C Pivot assigned for medium and long length subarrays.
C Note that pm5 = mid
piv = array(mid)
C Initialize pointers for partitioning
i = lo-1
j = hi+1
C Initialize counts of repeat values of pivot.
a = 0
d = 0
C Beginning of outer loop for placing pivot.
3 continue
C Scan up to find an element > piv.
i = i + 1
C Check if pointers crossed.
if(j.lt.i)goto 5
C Check if i pointer hit hi boundary.
if(i.eq.hi)goto 4
C
if(compar(array(i), piv).eq.-1)goto 3
C Check for copies of pivot from scanning right.
if(compar(array(i), piv).eq.0)then
array(i) = array(lo+a)
array(lo+a) = piv
a = a + 1
goto 3
endif
C Beginning of innerloop for placing pivot.
4 continue
C Scan down to find an element < piv.
j = j - 1
C Check if pointers crossed.
if(j.lt.i)goto 5
if(compar(array(j), piv).eq.1)goto 4
C Check for copies of pivot from scanning left.
if(compar(array(j), piv).eq.0)then
array(j) = array(hi-d)
array(hi-d) = piv
d = d + 1
goto 4
endif
C Check if pointers crossed.
if(j.lt.i)goto 5
C Exchange elements
temp = array(i)
array(i) = array(j)
array(j) = temp
C End of outermost loop for placing pivot.
goto 3
C Insert all copies of pivot in appropriate place
5 s = MIN(a, j-lo-a+1)
DO 6 k = 1, s
array(lo-1+k) = array(i-k)
array(i-k) = piv
6 CONTINUE
s = MIN(d, hi-j-d)
DO 7 k = 1, s
array(hi+1-k) = array(j+k)
array(j+k) = piv
7 CONTINUE
C Increase effective stack size
tstack = tstack + 2
C Push pointers to larger subarray on stack for later processing,
C process smaller subarray immediately.
if(tstack.gt.mstack) THEN
WRITE(*,*)'Stack size is too small in quicksort fortran code quicksort_real_F77.F'
WRITE(*,*)'Are you sure you want to sort an array this long?'
WRITE(*,*)'Your array has more than 2^63-1 entries?'
WRITE(*,*)'If so, set mstack parameter to be at least:'
WRITE(*,*)'2*ceiling(log_2(N))+2, for N = length of array,'
WRITE(*,*)'and recompile this subroutine.'
RETURN
endif
if(hi-j-d-1.ge.j-a-lo)then
bstack(tstack) = hi
bstack(tstack-1) = MIN(j+d+1, hi)
hi=MAX(j-a,lo)
else
bstack(tstack)=MAX(j-a,lo)
bstack(tstack-1)=lo
lo=MIN(j+d+1,hi)
endif
C
C end of outermost if statement
endif
goto 1
C END of subroutine quicksort
END