subroutine get_unit ( iunit )

!*****************************************************************************80
!
!! get_unit() returns a free FORTRAN unit number.
!
!  Discussion:
!
!    A "free" FORTRAN unit number is an integer between 1 and 99 which
!    is not currently associated with an I/O device.  A free FORTRAN unit
!    number is needed in order to open a file with the OPEN command.
!
!    If IUNIT = 0, then no free FORTRAN unit could be found, although
!    all 99 units were checked (except for units 5, 6 and 9, which
!    are commonly reserved for console I/O).
!
!    Otherwise, IUNIT is an integer between 1 and 99, representing a
!    free FORTRAN unit.  Note that GET_UNIT assumes that units 5 and 6
!    are special, and will never return those values.
!
!  Licensing:
!
!    This code is distributed under the MIT license. 
!
!  Modified:
!
!    26 October 2008
!
!  Author:
!
!    John Burkardt
!
!  Parameters:
!
!    Output, integer IUNIT, the free unit number.
!
  implicit none

  integer i
  integer ios
  integer iunit
  logical lopen

  iunit = 0

  do i = 1, 99

    if ( i /= 5 .and. i /= 6 .and. i /= 9 ) then

      inquire ( unit = i, opened = lopen, iostat = ios )

      if ( ios == 0 ) then
        if ( .not. lopen ) then
          iunit = i
          return
        end if
      end if

    end if

  end do

  return
end
function i4_uniform_ab ( a, b )

!*****************************************************************************80
!
!! i4_uniform_ab() returns a scaled pseudorandom I4.
!
!  Discussion:
!
!    An I4 is an integer value.
!
!    The pseudorandom number will be scaled to be uniformly distributed
!    between A and B.
!
!  Licensing:
!
!    This code is distributed under the MIT license. 
!
!  Modified:
!
!    27 August 2021
!
!  Author:
!
!    John Burkardt
!
!  Input:
!
!    integer a, b: the limits of the interval.
!
!  Output:
!
!    integer i4_uniform_ab: a number between A and B.
!
  implicit none

  integer, parameter :: rk = kind ( 1.0D+00 )

  integer a
  integer b
  integer i4_uniform_ab
  real ( kind = rk ) r

  call random_number ( harvest = r )
  i4_uniform_ab = a + int ( ( b + 1 - a ) * r )

  return
end
subroutine latin_center ( dim_num, point_num, x )

!*****************************************************************************80
!
!! LATIN_CENTER returns points in a Latin Center Square.
!
!  Discussion:
!
!    In each spatial dimension, there will be exactly one
!    point with the coordinate value 
!
!      ( 1, 3, 5, ..., 2*point_num-1 ) / ( 2 * point_num )
!
!  Licensing:
!
!    This code is distributed under the MIT license. 
!
!  Modified:
!
!    20 March 2003
!
!  Author:
!
!    John Burkardt
!
!  Parameters:
!
!    Input, integer DIM_NUM, the spatial dimension.
!
!    Input, integer POINT_NUM, the number of points.
!
!    Output, real ( kind = rk ) X(DIM_NUM,POINT_NUM), the points.
!
  implicit none

  integer, parameter :: rk = kind ( 1.0D+00 )

  integer dim_num
  integer point_num

  integer :: base = 1
  integer i
  integer j
  integer perm(point_num)
  real ( kind = rk ) x(dim_num,point_num)

  do i = 1, dim_num

    call perm_uniform ( point_num, base, perm )

    do j = 1, point_num
      x(i,j) = real ( 2 * perm(j) - 1, kind = rk ) &
             / real ( 2 * point_num, kind = rk )
    end do

  end do

  return
end
subroutine perm_uniform ( n, base, p )

!*****************************************************************************80
!
!! PERM_UNIFORM selects a random permutation of N objects.
!
!  Licensing:
!
!    This code is distributed under the MIT license. 
!
!  Modified:
!
!    18 November 2008
!
!  Author:
!
!    John Burkardt
!
!  Reference:
!
!    Albert Nijenhuis, Herbert Wilf,
!    Combinatorial Algorithms,
!    Academic Press, 1978, second edition,
!    ISBN 0-12-519260-6.
!
!  Parameters:
!
!    Input, integer N, the number of objects to be permuted.
!
!    Input, integer BASE, is 0 for a 0-based permutation and 1 for 
!    a 1-based permutation.
!
!    Output, integer P(N), the permutation.  P(I) is the "new"
!    location of the object originally at I.
!
  implicit none

  integer n

  integer base
  integer i
  integer i4_uniform_ab
  integer j
  integer k
  integer p(n)

  do i = 1, n
    p(i) = ( i - 1 ) + base
  end do

  do i = 1, n
    j = i4_uniform_ab ( i, n )
    k    = p(i)
    p(i) = p(j)
    p(j) = k
  end do

  return
end
subroutine r8mat_write ( output_filename, m, n, table )

!*****************************************************************************80
!
!! R8MAT_WRITE writes an R8MAT file.
!
!  Discussion:
!
!    An R8MAT is an array of R8 values.
!
!  Licensing:
!
!    This code is distributed under the MIT license.
!
!  Modified:
!
!    31 May 2009
!
!  Author:
!
!    John Burkardt
!
!  Parameters:
!
!    Input, character ( len = * ) OUTPUT_FILENAME, the output file name.
!
!    Input, integer M, the spatial dimension.
!
!    Input, integer N, the number of points.
!
!    Input, real ( kind = rk ) TABLE(M,N), the table data.
!
  implicit none

  integer, parameter :: rk = kind ( 1.0D+00 )

  integer m
  integer n

  integer j
  character ( len = * ) output_filename
  integer output_status
  integer output_unit
  character ( len = 30 ) string
  real ( kind = rk ) table(m,n)
!
!  Open the file.
!
  call get_unit ( output_unit )

  open ( unit = output_unit, file = output_filename, &
    status = 'replace', iostat = output_status )

  if ( output_status /= 0 ) then
    write ( *, '(a)' ) ' '
    write ( *, '(a)' ) 'R8MAT_WRITE - Fatal error!'
    write ( *, '(a,i8)' ) '  Could not open the output file "' // &
      trim ( output_filename ) // '" on unit ', output_unit
    output_unit = -1
    stop
  end if
!
!  Create a format string.
!
!  For less precision in the output file, try:
!
!                                            '(', m, 'g', 14, '.', 6, ')'
!
  if ( 0 < m .and. 0 < n ) then

    write ( string, '(a1,i8,a1,i8,a1,i8,a1)' ) '(', m, 'g', 24, '.', 16, ')'
!
!  Write the data.
!
    do j = 1, n
      write ( output_unit, string ) table(1:m,j)
    end do

  end if
!
!  Close the file.
!
  close ( unit = output_unit )

  return
end
subroutine s_to_i4 ( s, value, ierror, length )

!*****************************************************************************80
!
!! S_TO_I4 reads an integer value from a string.
!
!  Discussion:
!
!    Instead of ICHAR, we now use the IACHAR function, which
!    guarantees the ASCII collating sequence.
!
!  Licensing:
!
!    This code is distributed under the MIT license. 
!
!  Modified:
!
!    12 January 2009
!
!  Author:
!
!    John Burkardt
!
!  Parameters:
!
!    Input, character ( len = * ) S, a string to be examined.
!
!    Output, integer VALUE, the integer value read from the string.
!    If the string is blank, then VALUE will be returned 0.
!
!    Output, integer IERROR, an error flag.
!    0, no error.
!    1, an error occurred.
!
!    Output, integer LENGTH, the number of characters 
!    of S used to make the integer.
!
  implicit none

  character c
  integer i
  integer ierror
  integer isgn
  integer length
  character ( len = * ) s
  integer state
  character :: TAB = achar ( 9 )
  integer value

  value = 0
  ierror = 0
  length = 0

  state = 0
  isgn = 1

  do i = 1, len_trim ( s )

    c = s(i:i)
!
!  STATE = 0, haven't read anything.
!
    if ( state == 0 ) then

      if ( c == ' ' .or. c == TAB ) then

      else if ( c == '-' ) then
        state = 1
        isgn = -1
      else if ( c == '+' ) then
        state = 1
        isgn = +1
      else if ( lle ( '0', c ) .and. lle ( c, '9' ) ) then
        state = 2
        value = iachar ( c ) - iachar ( '0' )
      else
        ierror = 1
        return
      end if
!
!  STATE = 1, have read the sign, expecting digits or spaces.
!
    else if ( state == 1 ) then

      if ( c == ' ' .or. c == TAB ) then

      else if ( lle ( '0', c ) .and. lle ( c, '9' ) ) then
        state = 2
        value = iachar ( c ) - iachar ( '0' )
      else
        ierror = 1
        return
      end if
!
!  STATE = 2, have read at least one digit, expecting more.
!
    else if ( state == 2 ) then

      if ( lle ( '0', c ) .and. lle ( c, '9' ) ) then

        value = 10 * value + iachar ( c ) - iachar ( '0' )

      else

        value = isgn * value
        ierror = 0
        length = i - 1
        return

      end if

    end if

  end do
!
!  If we read all the characters in the string, see if we're OK.
!
  if ( state == 2 ) then

    value = isgn * value
    ierror = 0
    length = len_trim ( s )

  else

    value = 0
    ierror = 1
    length = 0

  end if

  return
end
subroutine timestamp ( )

!*****************************************************************************80
!
!! TIMESTAMP prints the current YMDHMS date as a time stamp.
!
!  Example:
!
!    31 May 2001   9:45:54.872 AM
!
!  Licensing:
!
!    This code is distributed under the MIT license.
!
!  Modified:
!
!    18 May 2013
!
!  Author:
!
!    John Burkardt
!
  implicit none

  character ( len = 8 ) ampm
  integer d
  integer h
  integer m
  integer mm
  character ( len = 9 ), parameter, dimension(12) :: month = (/ &
    'January  ', 'February ', 'March    ', 'April    ', &
    'May      ', 'June     ', 'July     ', 'August   ', &
    'September', 'October  ', 'November ', 'December ' /)
  integer n
  integer s
  integer values(8)
  integer y

  call date_and_time ( values = values )

  y = values(1)
  m = values(2)
  d = values(3)
  h = values(5)
  n = values(6)
  s = values(7)
  mm = values(8)

  if ( h < 12 ) then
    ampm = 'AM'
  else if ( h == 12 ) then
    if ( n == 0 .and. s == 0 ) then
      ampm = 'Noon'
    else
      ampm = 'PM'
    end if
  else
    h = h - 12
    if ( h < 12 ) then
      ampm = 'PM'
    else if ( h == 12 ) then
      if ( n == 0 .and. s == 0 ) then
        ampm = 'Midnight'
      else
        ampm = 'AM'
      end if
    end if
  end if

  write ( *, '(i2.2,1x,a,1x,i4,2x,i2,a1,i2.2,a1,i2.2,a1,i3.3,1x,a)' ) &
    d, trim ( month(m) ), y, h, ':', n, ':', s, '.', mm, trim ( ampm )

  return
end