subroutine imtqlx ( n, d, e, z ) !*****************************************************************************80 ! !! imtqlx() diagonalizes a symmetric tridiagonal matrix. ! ! Discussion: ! ! This routine is a slightly modified version of the EISPACK routine to ! perform the implicit QL algorithm on a symmetric tridiagonal matrix. ! ! The authors thank the authors of EISPACK for permission to use this ! routine. ! ! It has been modified to produce the product Q' * Z, where Z is an input ! vector and Q is the orthogonal matrix diagonalizing the input matrix. ! The changes consist (essentially) of applying the orthogonal ! transformations directly to Z as they are generated. ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 27 December 2009 ! ! Author: ! ! Original FORTRAN77 version by Sylvan Elhay, Jaroslav Kautsky. ! FORTRAN90 version by John Burkardt. ! ! Reference: ! ! Sylvan Elhay, Jaroslav Kautsky, ! Algorithm 655: IQPACK, FORTRAN Subroutines for the Weights of ! Interpolatory Quadrature, ! ACM Transactions on Mathematical Software, ! Volume 13, Number 4, December 1987, pages 399-415. ! ! Roger Martin, James Wilkinson, ! The Implicit QL Algorithm, ! Numerische Mathematik, ! Volume 12, Number 5, December 1968, pages 377-383. ! ! Parameters: ! ! Input, integer N, the order of the matrix. ! ! Input/output, real ( kind = rk ) D(N), the diagonal entries of the matrix. ! On output, the information in D has been overwritten. ! ! Input/output, real ( kind = rk ) E(N), the subdiagonal entries of the ! matrix, in entries E(1) through E(N-1). On output, the information in ! E has been overwritten. ! ! Input/output, real ( kind = rk ) Z(N). On input, a vector. On output, ! the value of Q' * Z, where Q is the matrix that diagonalizes the ! input symmetric tridiagonal matrix. ! implicit none integer, parameter :: rk = kind ( 1.0D+00 ) integer n real ( kind = rk ) b real ( kind = rk ) c real ( kind = rk ) d(n) real ( kind = rk ) e(n) real ( kind = rk ) f real ( kind = rk ) g integer i integer ii integer, parameter :: itn = 30 integer j integer k integer l integer m integer mml real ( kind = rk ) p real ( kind = rk ) prec real ( kind = rk ) r real ( kind = rk ) s real ( kind = rk ) z(n) prec = epsilon ( prec ) if ( n == 1 ) then return end if e(n) = 0.0D+00 do l = 1, n j = 0 do do m = l, n if ( m == n ) then exit end if if ( abs ( e(m) ) <= prec * ( abs ( d(m) ) + abs ( d(m+1) ) ) ) then exit end if end do p = d(l) if ( m == l ) then exit end if if ( itn <= j ) then write ( *, '(a)' ) ' ' write ( *, '(a)' ) 'IMTQLX - Fatal error!' write ( *, '(a)' ) ' Iteration limit exceeded.' write ( *, '(a,i8)' ) ' J = ', j write ( *, '(a,i8)' ) ' L = ', l write ( *, '(a,i8)' ) ' M = ', m write ( *, '(a,i8)' ) ' N = ', n stop end if j = j + 1 g = ( d(l+1) - p ) / ( 2.0D+00 * e(l) ) r = sqrt ( g * g + 1.0D+00 ) g = d(m) - p + e(l) / ( g + sign ( r, g ) ) s = 1.0D+00 c = 1.0D+00 p = 0.0D+00 mml = m - l do ii = 1, mml i = m - ii f = s * e(i) b = c * e(i) if ( abs ( g ) <= abs ( f ) ) then c = g / f r = sqrt ( c * c + 1.0D+00 ) e(i+1) = f * r s = 1.0D+00 / r c = c * s else s = f / g r = sqrt ( s * s + 1.0D+00 ) e(i+1) = g * r c = 1.0D+00 / r s = s * c end if g = d(i+1) - p r = ( d(i) - g ) * s + 2.0D+00 * c * b p = s * r d(i+1) = g + p g = c * r - b f = z(i+1) z(i+1) = s * z(i) + c * f z(i) = c * z(i) - s * f end do d(l) = d(l) - p e(l) = g e(m) = 0.0D+00 end do end do ! ! Sorting. ! do ii = 2, n i = ii - 1 k = i p = d(i) do j = ii, n if ( d(j) < p ) then k = j p = d(j) end if end do if ( k /= i ) then d(k) = d(i) d(i) = p p = z(i) z(i) = z(k) z(k) = p end if end do return end subroutine r8mat_print ( m, n, a, title ) !*****************************************************************************80 ! !! R8MAT_PRINT prints an R8MAT. ! ! Discussion: ! ! An R8MAT is an array of R8 values. ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 12 September 2004 ! ! Author: ! ! John Burkardt ! ! Parameters: ! ! Input, integer M, the number of rows in A. ! ! Input, integer N, the number of columns in A. ! ! Input, real ( kind = rk ) A(M,N), the matrix. ! ! Input, character ( len = * ) TITLE, a title. ! implicit none integer, parameter :: rk = kind ( 1.0D+00 ) integer m integer n real ( kind = rk ) a(m,n) character ( len = * ) title call r8mat_print_some ( m, n, a, 1, 1, m, n, title ) return end subroutine r8mat_print_some ( m, n, a, ilo, jlo, ihi, jhi, title ) !*****************************************************************************80 ! !! R8MAT_PRINT_SOME prints some of an R8MAT. ! ! Discussion: ! ! An R8MAT is an MxN array of R8's, stored by (I,J) -> [I+J*M]. ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 10 September 2009 ! ! Author: ! ! John Burkardt ! ! Parameters: ! ! Input, integer M, N, the number of rows and columns. ! ! Input, real ( kind = rk ) A(M,N), an M by N matrix to be printed. ! ! Input, integer ILO, JLO, the first row and column to print. ! ! Input, integer IHI, JHI, the last row and column to print. ! ! Input, character ( len = * ) TITLE, a title. ! implicit none integer, parameter :: rk = kind ( 1.0D+00 ) integer, parameter :: incx = 5 integer m integer n real ( kind = rk ) a(m,n) character ( len = 14 ) ctemp(incx) integer i integer i2hi integer i2lo integer ihi integer ilo integer inc integer j integer j2 integer j2hi integer j2lo integer jhi integer jlo character ( len = * ) title write ( *, '(a)' ) ' ' write ( *, '(a)' ) trim ( title ) if ( m <= 0 .or. n <= 0 ) then write ( *, '(a)' ) ' ' write ( *, '(a)' ) ' (None)' return end if do j2lo = max ( jlo, 1 ), min ( jhi, n ), incx j2hi = j2lo + incx - 1 j2hi = min ( j2hi, n ) j2hi = min ( j2hi, jhi ) inc = j2hi + 1 - j2lo write ( *, '(a)' ) ' ' do j = j2lo, j2hi j2 = j + 1 - j2lo write ( ctemp(j2), '(i8,6x)' ) j end do write ( *, '('' Col '',5a14)' ) ctemp(1:inc) write ( *, '(a)' ) ' Row' write ( *, '(a)' ) ' ' i2lo = max ( ilo, 1 ) i2hi = min ( ihi, m ) do i = i2lo, i2hi do j2 = 1, inc j = j2lo - 1 + j2 if ( a(i,j) == real ( int ( a(i,j) ), kind = rk ) ) then write ( ctemp(j2), '(f8.0,6x)' ) a(i,j) else write ( ctemp(j2), '(g14.6)' ) a(i,j) end if end do write ( *, '(i5,a,5a14)' ) i, ':', ( ctemp(j), j = 1, inc ) end do end do return end subroutine r8vec_even ( n, alo, ahi, a ) !*****************************************************************************80 ! !! R8VEC_EVEN returns an R8VEC of evenly spaced values. ! ! Discussion: ! ! An R8VEC is a vector of R8's. ! ! If N is 1, then the midpoint is returned. ! ! Otherwise, the two endpoints are returned, and N-2 evenly ! spaced points between them. ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 09 December 2004 ! ! Author: ! ! John Burkardt ! ! Parameters: ! ! Input, integer N, the number of values. ! ! Input, real ( kind = rk ) ALO, AHI, the low and high values. ! ! Output, real ( kind = rk ) A(N), N evenly spaced values. ! Normally, A(1) = ALO and A(N) = AHI. ! However, if N = 1, then A(1) = 0.5*(ALO+AHI). ! implicit none integer, parameter :: rk = kind ( 1.0D+00 ) integer n real ( kind = rk ) a(n) real ( kind = rk ) ahi real ( kind = rk ) alo integer i if ( n == 1 ) then a(1) = 0.5D+00 * ( alo + ahi ) else do i = 1, n a(i) = ( real ( n - i, kind = rk ) * alo & + real ( i - 1, kind = rk ) * ahi ) & / real ( n - 1, kind = rk ) end do end if return end subroutine r8vec_print ( n, a, title ) !*****************************************************************************80 ! !! R8VEC_PRINT prints an R8VEC. ! ! Discussion: ! ! An R8VEC is a vector of R8's. ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 22 August 2000 ! ! Author: ! ! John Burkardt ! ! Parameters: ! ! Input, integer N, the number of components of the vector. ! ! Input, real ( kind = rk ) A(N), the vector to be printed. ! ! Input, character ( len = * ) TITLE, a title. ! implicit none integer, parameter :: rk = kind ( 1.0D+00 ) integer n real ( kind = rk ) a(n) integer i character ( len = * ) title write ( *, '(a)' ) ' ' write ( *, '(a)' ) trim ( title ) write ( *, '(a)' ) ' ' do i = 1, n write ( *, '(2x,i8,a,1x,g16.8)' ) i, ':', a(i) end do return end subroutine sgqf ( nt, aj, bj, zemu, t, wts ) !*****************************************************************************80 ! !! SGQF computes knots and weights of a Gauss Quadrature formula. ! ! Discussion: ! ! This routine computes all the knots and weights of a Gauss quadrature ! formula with simple knots from the Jacobi matrix and the zero-th ! moment of the weight function, using the Golub-Welsch technique. ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 04 January 2010 ! ! Author: ! ! Original FORTRAN77 version by Sylvan Elhay, Jaroslav Kautsky. ! FORTRAN90 version by John Burkardt. ! ! Reference: ! ! Sylvan Elhay, Jaroslav Kautsky, ! Algorithm 655: IQPACK, FORTRAN Subroutines for the Weights of ! Interpolatory Quadrature, ! ACM Transactions on Mathematical Software, ! Volume 13, Number 4, December 1987, pages 399-415. ! ! Parameters: ! ! Input, integer NT, the number of knots. ! ! Input, real ( kind = rk ) AJ(NT), the diagonal of the Jacobi matrix. ! ! Input/output, real ( kind = rk ) BJ(NT), the subdiagonal of the Jacobi ! matrix, in entries 1 through NT-1. On output, BJ has been overwritten. ! ! Input, real ( kind = rk ) ZEMU, the zero-th moment of the weight function. ! ! Output, real ( kind = rk ) T(NT), the knots. ! ! Output, real ( kind = rk ) WTS(NT), the weights. ! implicit none integer, parameter :: rk = kind ( 1.0D+00 ) integer nt real ( kind = rk ) aj(nt) real ( kind = rk ) bj(nt) real ( kind = rk ) t(nt) real ( kind = rk ) wts(nt) real ( kind = rk ) zemu ! ! Exit if the zero-th moment is not positive. ! if ( zemu <= 0.0D+00 ) then write ( *, '(a)' ) ' ' write ( *, '(a)' ) 'SGQF - Fatal error!' write ( *, '(a)' ) ' ZEMU <= 0.' stop 1 end if ! ! Set up vectors for IMTQLX. ! t(1:nt) = aj(1:nt) wts(1) = sqrt ( zemu ) wts(2:nt) = 0.0D+00 ! ! Diagonalize the Jacobi matrix. ! call imtqlx ( nt, t, bj, wts ) wts(1:nt) = wts(1:nt)**2 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