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  • 样条曲线的Fortran程序

    subroutine basis_function_b_val ( tdata, tval, yval )
    !
    !*******************************************************************************
    !
    !! BASIS_FUNCTION_B_VAL evaluates the B spline basis function.
    !
    !
    !  Discussion:
    !
    !    The B spline basis function is a piecewise cubic which
    !    has the properties that:
    !
    !    * it equals 2/3 at TDATA(3), 1/6 at TDATA(2) and TDATA(4);
    !    * it is 0 for TVAL <= TDATA(1) or TDATA(5) <= TVAL;
    !    * it is strictly increasing from TDATA(1) to TDATA(3),
    !      and strictly decreasing from TDATA(3) to TDATA(5);
    !    * the function and its first two derivatives are continuous
    !      at each node TDATA(I).
    !
    !  Reference:
    !
    !    Alan Davies and Philip Samuels,
    !    An Introduction to Computational Geometry for Curves and Surfaces,
    !    Clarendon Press, 1996.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real TDATA(5), the nodes associated with the basis function.
    !    The entries of TDATA are assumed to be distinct and increasing.
    !
    !    Input, real TVAL, a point at which the B spline basis function is
    !    to be evaluated.
    !
    !    Output, real YVAL, the value of the function at TVAL.
    !
      implicit none
    !
      integer, parameter :: ndata = 5
    !
      integer left
      integer right
      real tdata(ndata)
      real tval
      real u
      real yval
    !
      if ( tval <= tdata(1) .or. tval >= tdata(ndata) ) then
        yval = 0.0E+00
        return
      end if
    !
    !  Find the interval [ TDATA(LEFT), TDATA(RIGHT) ] containing TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  U is the normalized coordinate of TVAL in this interval.
    !
      u = ( tval - tdata(left) ) / ( tdata(right) - tdata(left) )
    !
    !  Now evaluate the function.
    !
      if ( tval < tdata(2) ) then
        yval = u**3 / 6.0E+00
      else if ( tval < tdata(3) ) then
        yval = ( 1.0E+00 + 3.0E+00 * u + 3.0E+00 * u**2 - 3.0E+00 * u**3 ) / 6.0E+00
      else if ( tval < tdata(4) ) then
        yval = ( 4.0E+00 - 6.0E+00 * u**2 + 3.0E+00 * u**3 ) / 6.0E+00
      else if ( tval < tdata(5) ) then
        yval = ( 1.0E+00 - u )**3 / 6.0E+00
      end if
    
      return
    end
    subroutine basis_function_beta_val ( beta1, beta2, tdata, tval, yval )
    !
    !*******************************************************************************
    !
    !! BASIS_FUNCTION_BETA_VAL evaluates the beta spline basis function.
    !
    !
    !  Discussion:
    !
    !    With BETA1 = 1 and BETA2 = 0, the beta spline basis function 
    !    equals the B spline basis function.
    !
    !    With BETA1 large, and BETA2 = 0, the beta spline basis function
    !    skews to the right, that is, its maximum increases, and occurs
    !    to the right of the center.
    !
    !    With BETA1 = 1 and BETA2 large, the beta spline becomes more like
    !    a linear basis function; that is, its value in the outer two intervals
    !    goes to zero, and its behavior in the inner two intervals approaches
    !    a piecewise linear function that is 0 at the second node, 1 at the
    !    third, and 0 at the fourth.
    !
    !  Reference:
    !
    !    Alan Davies and Philip Samuels,
    !    An Introduction to Computational Geometry for Curves and Surfaces,
    !    Clarendon Press, 1996, page 129.
    !
    !  Modified:
    !
    !    09 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real BETA1, the skew or bias parameter.
    !    BETA1 = 1 for no skew or bias.
    !
    !    Input, real BETA2, the tension parameter.
    !    BETA2 = 0 for no tension.
    !
    !    Input, real TDATA(5), the nodes associated with the basis function.
    !    The entries of TDATA are assumed to be distinct and increasing.
    !
    !    Input, real TVAL, a point at which the B spline basis function is
    !    to be evaluated.
    !
    !    Output, real YVAL, the value of the function at TVAL.
    !
      implicit none
    !
      integer, parameter :: ndata = 5
    !
      real a
      real b
      real beta1
      real beta2
      real c
      real d
      integer left
      integer right
      real tdata(ndata)
      real tval
      real u
      real yval
    !
      if ( tval <= tdata(1) .or. tval >= tdata(ndata) ) then
        yval = 0.0E+00
        return
      end if
    !
    !  Find the interval [ TDATA(LEFT), TDATA(RIGHT) ] containing TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  U is the normalized coordinate of TVAL in this interval.
    !
      u = ( tval - tdata(left) ) / ( tdata(right) - tdata(left) )
    !
    !  Now evaluate the function.
    !
      if ( tval < tdata(2) ) then
    
        yval = 2.0E+00 * u**3 
    
      else if ( tval < tdata(3) ) then
    
        a = beta2 + 4.0E+00 * beta1 + 4.0E+00 * beta1**2 &
          + 6.0E+00 * ( 1.0E+00 - beta1**2 ) &
          - 3.0E+00 * ( 2.0E+00 + beta2 + 2.0E+00 * beta1 ) &
          + 2.0E+00 * ( 1.0E+00 + beta2 + beta1 + beta1**2 )
    
        b = - 6.0E+00 * ( 1.0E+00 - beta1**2 ) &
            + 6.0E+00 * ( 2.0E+00 + beta2 + 2.0E+00 * beta1 ) &
            - 6.0E+00 * ( 1.0E+00 + beta2 + beta1 + beta1**2 )
    
        c = - 3.0E+00 * ( 2.0E+00 + beta2 + 2.0E+00 * beta1 ) &
            + 6.0E+00 * ( 1.0E+00 + beta2 + beta1 + beta1**2 )
    
        d = - 2.0E+00 * ( 1.0E+00 + beta2 + beta1 + beta1**2 )
    
        yval = a + b * u + c * u**2 + d * u**3
    
      else if ( tval < tdata(4) ) then
    
        a = beta2 + 4.0E+00 * beta1 + 4.0E+00 * beta1**2
    
        b = - 6.0E+00 * ( beta1 - beta1**3 )
    
        c = - 3.0E+00 * ( beta2 + 2.0E+00 * beta1**2 + 2.0E+00 * beta1**3 )
    
        d = 2.0E+00 * ( beta2 + beta1 + beta1**2 + beta1**3 )
    
        yval = a + b * u + c * u**2 + d * u**3
    
      else if ( tval < tdata(5) ) then
    
        yval = 2.0E+00 * beta1**3 * ( 1.0E+00 - u )**3
    
      end if
    
      yval = yval / ( 2.0E+00 + beta2 + 4.0E+00 * beta1 + 4.0E+00 * beta1**2 &
        + 2.0E+00 * beta1**3 )
    
      return
    end
    subroutine basis_matrix_b_uni ( mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_B_UNI sets up the uniform B spline basis matrix.
    !
    !
    !  Reference:
    !
    !    Foley, van Dam, Feiner, Hughes,
    !    Computer Graphics: Principles and Practice,
    !    page 493.
    !
    !  Modified:
    !
    !    05 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Output, real MBASIS(4,4), the basis matrix.
    !
      implicit none
    !
      real mbasis(4,4)
    !
      mbasis(1,1) = - 1.0E+00 / 6.0E+00
      mbasis(1,2) =   3.0E+00 / 6.0E+00
      mbasis(1,3) = - 3.0E+00 / 6.0E+00
      mbasis(1,4) =   1.0E+00 / 6.0E+00
    
      mbasis(2,1) =   3.0E+00 / 6.0E+00
      mbasis(2,2) = - 6.0E+00 / 6.0E+00
      mbasis(2,3) =   3.0E+00 / 6.0E+00
      mbasis(2,4) =   0.0E+00
    
      mbasis(3,1) = - 3.0E+00 / 6.0E+00
      mbasis(3,2) =   0.0E+00
      mbasis(3,3) =   3.0E+00 / 6.0E+00
      mbasis(3,4) =   0.0E+00
    
      mbasis(4,1) =   1.0E+00 / 6.0E+00
      mbasis(4,2) =   4.0E+00 / 6.0E+00
      mbasis(4,3) =   1.0E+00 / 6.0E+00
      mbasis(4,4) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_beta_uni ( beta1, beta2, mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_BETA_UNI sets up the uniform beta spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    If BETA1 = 1 and BETA2 = 0, then the beta spline reduces to 
    !    the B spline.
    !
    !  Reference:
    !
    !    Foley, van Dam, Feiner, Hughes,
    !    Computer Graphics: Principles and Practice,
    !    page 505.
    !
    !  Modified:
    !
    !    03 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real BETA1, the skew or bias parameter.
    !    BETA1 = 1 for no skew or bias.
    !
    !    Input, real BETA2, the tension parameter.
    !    BETA2 = 0 for no tension.
    !
    !    Output, real MBASIS(4,4), the basis matrix.
    !
      implicit none
    !
      real beta1
      real beta2
      real delta
      integer i
      integer j
      real mbasis(4,4)
    !
      mbasis(1,1) = - 2.0E+00 * beta1**3
      mbasis(1,2) =   2.0E+00 * ( beta2 + beta1**3 + beta1**2 + beta1 )
      mbasis(1,3) = - 2.0E+00 * ( beta2 + beta1**2 + beta1 + 1.0E+00 )
      mbasis(1,4) =   2.0E+00
    
      mbasis(2,1) =   6.0E+00 * beta1**3
      mbasis(2,2) = - 3.0E+00 * ( beta2 + 2.0E+00 * beta1**3 + 2.0E+00 * beta1**2 )
      mbasis(2,3) =   3.0E+00 * ( beta2 + 2.0E+00 * beta1**2 )
      mbasis(2,4) =   0.0E+00
    
      mbasis(3,1) = - 6.0E+00 * beta1**3
      mbasis(3,2) =   6.0E+00 * beta1 * ( beta1 - 1.0E+00 ) * ( beta1 + 1.0E+00 )
      mbasis(3,3) =   6.0E+00 * beta1
      mbasis(3,4) =   0.0E+00
    
      mbasis(4,1) =   2.0E+00 * beta1**3
      mbasis(4,2) =   4.0E+00 * beta1 * ( beta1 + 1.0E+00 ) + beta2
      mbasis(4,3) =   2.0E+00
      mbasis(4,4) =   0.0E+00
    
      delta = beta2 + 2.0E+00 * beta1**3 + 4.0E+00 * beta1**2 &
        + 4.0E+00 * beta1 + 2.0E+00
    
      mbasis(1:4,1:4) = mbasis(1:4,1:4) / delta
    
      return
    end
    subroutine basis_matrix_bezier ( mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_BEZIER_UNI sets up the cubic Bezier spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points are stored as
    !    ( P1, P2, P3, P4 ).  P1 is the function value at T = 0, while
    !    P2 is used to approximate the derivative at T = 0 by
    !    dP/dt = 3 * ( P2 - P1 ).  Similarly, P4 is the function value
    !    at T = 1, and P3 is used to approximate the derivative at T = 1
    !    by dP/dT = 3 * ( P4 - P3 ).
    !
    !  Reference:
    !
    !    Foley, van Dam, Feiner, Hughes,
    !    Computer Graphics: Principles and Practice,
    !    page 489.
    !
    !  Modified:
    !
    !    05 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Output, real MBASIS(4,4), the basis matrix.
    !
      implicit none
    !
      real mbasis(4,4)
    !
      mbasis(1,1) = - 1.0E+00
      mbasis(1,2) =   3.0E+00
      mbasis(1,3) = - 3.0E+00
      mbasis(1,4) =   1.0E+00
    
      mbasis(2,1) =   3.0E+00
      mbasis(2,2) = - 6.0E+00
      mbasis(2,3) =   3.0E+00
      mbasis(2,4) =   0.0E+00
    
      mbasis(3,1) = - 3.0E+00
      mbasis(3,2) =   3.0E+00
      mbasis(3,3) =   0.0E+00
      mbasis(3,4) =   0.0E+00
    
      mbasis(4,1) =   1.0E+00
      mbasis(4,2) =   0.0E+00
      mbasis(4,3) =   0.0E+00
      mbasis(4,4) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_hermite ( mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_HERMITE sets up the Hermite spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points are stored as
    !    ( P1, P2, P1', P2' ), with P1 and P1' being the data value and 
    !    the derivative dP/dT at T = 0, while P2 and P2' apply at T = 1.
    !
    !  Reference:
    !
    !    Foley, van Dam, Feiner, Hughes,
    !    Computer Graphics: Principles and Practice,
    !    page 484.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Output, real MBASIS(4,4), the basis matrix.
    !
      implicit none
    !
      real mbasis(4,4)
    !
      mbasis(1,1) =   2.0E+00
      mbasis(1,2) = - 2.0E+00
      mbasis(1,3) =   1.0E+00
      mbasis(1,4) =   1.0E+00
    
      mbasis(2,1) = - 3.0E+00
      mbasis(2,2) =   3.0E+00
      mbasis(2,3) = - 2.0E+00
      mbasis(2,4) = - 1.0E+00
    
      mbasis(3,1) =   0.0E+00
      mbasis(3,2) =   0.0E+00
      mbasis(3,3) =   1.0E+00
      mbasis(3,4) =   0.0E+00
    
      mbasis(4,1) =   1.0E+00
      mbasis(4,2) =   0.0E+00
      mbasis(4,3) =   0.0E+00
      mbasis(4,4) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_overhauser_nonuni ( alpha, beta, mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_OVERHAUSER_NONUNI sets up the nonuniform Overhauser spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points P1, P2, P3 and
    !    P4 are not uniformly spaced in T, and that P2 corresponds to T = 0,
    !    and P3 to T = 1.
    !
    !  Modified:
    !
    !    05 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real ALPHA, BETA.
    !    ALPHA = | P2 - P1 | / ( | P3 - P2 | + | P2 - P1 | )
    !    BETA  = | P3 - P2 | / ( | P4 - P3 | + | P3 - P2 | ).
    !
    !    Output, real MBASIS(4,4), the basis matrix.
    !
      implicit none
    !
      real alpha
      real beta
      real mbasis(4,4)
    !
      mbasis(1,1) = - ( 1.0E+00 - alpha )**2 / alpha
      mbasis(1,2) =   beta + ( 1.0E+00 - alpha ) / alpha
      mbasis(1,3) =   alpha - 1.0E+00 / ( 1.0E+00 - beta )
      mbasis(1,4) =   beta**2 / ( 1.0E+00 - beta )
    
      mbasis(2,1) =   2.0E+00 * ( 1.0E+00 - alpha )**2 / alpha
      mbasis(2,2) = ( - 2.0E+00 * ( 1.0E+00 - alpha ) - alpha * beta ) / alpha
      mbasis(2,3) = ( 2.0E+00 * ( 1.0E+00 - alpha ) &
        - beta * ( 1.0E+00 - 2.0E+00 * alpha ) ) / ( 1.0E+00 - beta )
      mbasis(2,4) = - beta**2 / ( 1.0E+00 - beta )
    
      mbasis(3,1) = - ( 1.0E+00 - alpha )**2 / alpha
      mbasis(3,2) =   ( 1.0E+00 - 2.0E+00 * alpha ) / alpha
      mbasis(3,3) =   alpha
      mbasis(3,4) =   0.0E+00
    
      mbasis(4,1) =   0.0E+00
      mbasis(4,2) =   1.0E+00
      mbasis(4,3) =   0.0E+00
      mbasis(4,4) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_overhauser_nul ( alpha, mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_OVERHAUSER_NUL sets up the left nonuniform Overhauser spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points P1, P2, and
    !    P3 are not uniformly spaced in T, and that P1 corresponds to T = 0,
    !    and P2 to T = 1. (???)
    !
    !  Modified:
    !
    !    27 August 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real ALPHA.
    !    ALPHA = | P2 - P1 | / ( | P3 - P2 | + | P2 - P1 | )
    !
    !    Output, real MBASIS(3,3), the basis matrix.
    !
      implicit none
    !
      real alpha
      real mbasis(3,3)
    !
      mbasis(1,1) =   1.0E+00 / alpha
      mbasis(1,2) = - 1.0E+00 / ( alpha * ( 1.0E+00 - alpha ) )
      mbasis(1,3) =   1.0E+00 / ( 1.0E+00 - alpha )
    
      mbasis(2,1) = - ( 1.0E+00 + alpha ) / alpha
      mbasis(2,2) =   1.0E+00 / ( alpha * ( 1.0E+00 - alpha ) )
      mbasis(2,3) = - alpha / ( 1.0E+00 - alpha )
    
      mbasis(3,1) =   1.0E+00
      mbasis(3,2) =   0.0E+00
      mbasis(3,3) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_overhauser_nur ( beta, mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_OVERHAUSER_NUR sets up the right nonuniform Overhauser spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points PN-2, PN-1, and
    !    PN are not uniformly spaced in T, and that PN-1 corresponds to T = 0,
    !    and PN to T = 1. (???)
    !
    !  Modified:
    !
    !    27 August 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real BETA.
    !    BETA = | P(N) - P(N-1) | / ( | P(N) - P(N-1) | + | P(N-1) - P(N-2) | )
    !
    !    Output, real MBASIS(3,3), the basis matrix.
    !
      implicit none
    !
      real beta
      real mbasis(3,3)
    !
      mbasis(1,1) =   1.0E+00 / beta
      mbasis(1,2) = - 1.0E+00 / ( beta * ( 1.0E+00 - beta ) )
      mbasis(1,3) =   1.0E+00 / ( 1.0E+00 - beta )
    
      mbasis(2,1) = - ( 1.0E+00 + beta ) / beta
      mbasis(2,2) =   1.0E+00 / ( beta * ( 1.0E+00 - beta ) )
      mbasis(2,3) = - beta / ( 1.0E+00 - beta )
    
      mbasis(3,1) =   1.0E+00
      mbasis(3,2) =   0.0E+00
      mbasis(3,3) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_overhauser_uni ( mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_OVERHAUSER_UNI sets up the uniform Overhauser spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points P1, P2, P3 and
    !    P4 are uniformly spaced in T, and that P2 corresponds to T = 0,
    !    and P3 to T = 1.
    !
    !  Reference:
    !
    !    Foley, van Dam, Feiner, Hughes,
    !    Computer Graphics: Principles and Practice,
    !    page 505.
    !
    !  Modified:
    !
    !    05 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Output, real MBASIS(4,4), the basis matrix.
    !
      implicit none
    !
      real mbasis(4,4)
    !
      mbasis(1,1) = - 1.0E+00 / 2.0E+00
      mbasis(1,2) =   3.0E+00 / 2.0E+00
      mbasis(1,3) = - 3.0E+00 / 2.0E+00
      mbasis(1,4) =   1.0E+00 / 2.0E+00
    
      mbasis(2,1) =   2.0E+00 / 2.0E+00
      mbasis(2,2) = - 5.0E+00 / 2.0E+00
      mbasis(2,3) =   4.0E+00 / 2.0E+00
      mbasis(2,4) = - 1.0E+00 / 2.0E+00
    
      mbasis(3,1) = - 1.0E+00 / 2.0E+00
      mbasis(3,2) =   0.0E+00
      mbasis(3,3) =   1.0E+00 / 2.0E+00
      mbasis(3,4) =   0.0E+00
    
      mbasis(4,1) =   0.0E+00
      mbasis(4,2) =   2.0E+00 / 2.0E+00
      mbasis(4,3) =   0.0E+00
      mbasis(4,4) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_overhauser_uni_l ( mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_OVERHAUSER_UNI_L sets up the left uniform Overhauser spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points P1, P2, and P3
    !    are not uniformly spaced in T, and that P1 corresponds to T = 0,
    !    and P2 to T = 1.
    !
    !  Modified:
    !
    !    05 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Output, real MBASIS(3,3), the basis matrix.
    !
      implicit none
    !
      real mbasis(3,3)
    !
      mbasis(1,1) =   2.0E+00
      mbasis(1,2) = - 4.0E+00
      mbasis(1,3) =   2.0E+00
    
      mbasis(2,1) = - 3.0E+00
      mbasis(2,2) =   4.0E+00
      mbasis(2,3) = - 1.0E+00
    
      mbasis(3,1) =   1.0E+00
      mbasis(3,2) =   0.0E+00
      mbasis(3,3) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_overhauser_uni_r ( mbasis )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_OVERHAUSER_UNI_R sets up the right uniform Overhauser spline basis matrix.
    !
    !
    !  Discussion:
    !
    !    This basis matrix assumes that the data points P(N-2), P(N-1), 
    !    and P(N) are uniformly spaced in T, and that P(N-1) corresponds to 
    !    T = 0, and P(N) to T = 1.
    !
    !  Modified:
    !
    !    05 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Output, real MBASIS(3,3), the basis matrix.
    !
      implicit none
    !
      real mbasis(3,3)
    !
      mbasis(1,1) =   2.0E+00
      mbasis(1,2) = - 4.0E+00
      mbasis(1,3) =   2.0E+00
    
      mbasis(2,1) = - 3.0E+00
      mbasis(2,2) =   4.0E+00
      mbasis(2,3) = - 1.0E+00
    
      mbasis(3,1) =   1.0E+00
      mbasis(3,2) =   0.0E+00
      mbasis(3,3) =   0.0E+00
    
      return
    end
    subroutine basis_matrix_tmp ( left, n, mbasis, ndata, tdata, ydata, tval, yval )
    !
    !*******************************************************************************
    !
    !! BASIS_MATRIX_TMP computes Q = T * MBASIS * P
    !
    !
    !  Discussion:
    !
    !    YDATA is a vector of data values, most frequently the values of some
    !    function sampled at uniformly spaced points.  MBASIS is the basis
    !    matrix for a particular kind of spline.  T is a vector of the
    !    powers of the normalized difference between TVAL and the left
    !    endpoint of the interval.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer LEFT, indicats that TVAL is in the interval
    !    [ TDATA(LEFT), TDATA(LEFT+1) ], or that this is the "nearest"
    !    interval to TVAL.
    !    For TVAL < TDATA(1), use LEFT = 1.
    !    For TVAL > TDATA(NDATA), use LEFT = NDATA - 1.
    !
    !    Input, integer N, the order of the basis matrix.
    !
    !    Input, real MBASIS(N,N), the basis matrix.
    !
    !    Input, integer NDATA, the dimension of the vectors TDATA and YDATA.
    !
    !    Input, real TDATA(NDATA), the abscissa values.  This routine
    !    assumes that the TDATA values are uniformly spaced, with an
    !    increment of 1.0.
    !
    !    Input, real YDATA(NDATA), the data values to be interpolated or 
    !    approximated.
    !
    !    Input, real TVAL, the value of T at which the spline is to be
    !    evaluated.
    !
    !    Output, real YVAL, the value of the spline at TVAL.
    !
      implicit none
    !
      integer, parameter :: maxn = 4
      integer n
      integer ndata
    !
      real arg
      integer first
      integer i
      integer j
      integer left
      real mbasis(n,n)
      real tdata(ndata)
      real temp
      real tval
      real tvec(maxn)
      real ydata(ndata)
      real yval
    !
      if ( left == 1 ) then
        arg = 0.5 * ( tval - tdata(left) )
        first = left
      else if ( left < ndata - 1 ) then
        arg = tval - tdata(left)
        first = left - 1
      else if ( left == ndata - 1 ) then
        arg = 0.5E+00 * ( 1.0E+00 + tval - tdata(left) )
        first = left - 1
      end if
    
      do i = 1, n - 1
        tvec(i) = arg**( n - i )
      end do
      tvec(n) = 1.0E+00
    
      yval = 0.0E+00
      do j = 1, n
        yval = yval + dot_product ( tvec(1:n), mbasis(1:n,j) ) &
          * ydata(first - 1 + j)
      end do
    
      return
    end
    subroutine bc_val ( n, t, xcon, ycon, xval, yval )
    !
    !*******************************************************************************
    !
    !! BC_VAL evaluates a parameterized Bezier curve.
    !
    !
    !  Discussion:
    !
    !    BC_VAL(T) is the value of a vector function of the form
    !
    !      BC_VAL(T) = ( X(T), Y(T) )
    !
    !    where
    !
    !      X(T) = Sum (i = 0 to N) XCON(I) * BERN(I,N)(T)
    !      Y(T) = Sum (i = 0 to N) YCON(I) * BERN(I,N)(T)
    !
    !    where BERN(I,N)(T) is the I-th Bernstein polynomial of order N
    !    defined on the interval [0,1], and where XCON(*) and YCON(*)
    !    are the coordinates of N+1 "control points".
    !
    !  Modified:
    !
    !    02 March 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the order of the Bezier curve, which
    !    must be at least 0.
    !
    !    Input, real T, the point at which the Bezier curve should
    !    be evaluated.  The best results are obtained within the interval
    !    [0,1] but T may be anywhere.
    !
    !    Input, real XCON(0:N), YCON(0:N), the X and Y coordinates
    !    of the control points.  The Bezier curve will pass through
    !    the points ( XCON(0), YCON(0) ) and ( XCON(N), YCON(N) ), but
    !    generally NOT through the other control points.
    !
    !    Output, real XVAL, YVAL, the X and Y coordinates of the point
    !    on the Bezier curve corresponding to the given T value.
    !
      implicit none
    !
      integer n
    !
      real bval(0:n)
      integer i
      real t
      real xcon(0:n)
      real xval
      real ycon(0:n)
      real yval
    !
      call bp01 ( n, bval, t )
    
      xval = dot_product ( xcon(0:n), bval(0:n) )
      yval = dot_product ( ycon(0:n), bval(0:n) )
    
      return
    end
    function bez_val ( n, x, a, b, y )
    !
    !*******************************************************************************
    !
    !! BEZ_VAL evaluates a Bezier function at a point.
    !
    !
    !  Discussion:
    !
    !    The Bezier function has the form:
    !
    !      BEZ(X) = Sum (i = 0 to N) Y(I) * BERN(N,I)( (X-A)/(B-A) )
    !
    !    where BERN(N,I)(X) is the I-th Bernstein polynomial of order N
    !    defined on the interval [0,1], and Y(*) is a set of
    !    coefficients.
    !
    !    If we define the N+1 equally spaced
    !
    !      X(I) = ( (N-I)*A + I*B)/ N,
    !
    !    for I = 0 to N, then the pairs ( X(I), Y(I) ) can be regarded as
    !    "control points".
    !
    !  Modified:
    !
    !    02 March 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the order of the Bezier function, which
    !    must be at least 0.
    !
    !    Input, real X, the point at which the Bezier function should
    !    be evaluated.  The best results are obtained within the interval
    !    [A,B] but X may be anywhere.
    !
    !    Input, real A, B, the interval over which the Bezier function
    !    has been defined.  This is the interval in which the control
    !    points have been set up.  Note BEZ(A) = Y(0) and BEZ(B) = Y(N),
    !    although BEZ will not, in general pass through the other
    !    control points.  A and B must not be equal.
    !
    !    Input, real Y(0:N), a set of data defining the Y coordinates
    !    of the control points.
    !
    !    Output, real BEZ_VAL, the value of the Bezier function at X.
    !
      implicit none
    !
      integer n
    !
      real a
      real b
      real bez_val
      real bval(0:n)
      integer i
      integer ncopy
      real x
      real x01
      real y(0:n)
    !
      if ( b - a == 0.0E+00 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'BEZ_VAL - Fatal error!'
        write ( *, '(a,g14.6)' ) '  Null interval, A = B = ', a
        stop
      end if
    
      x01 = ( x - a ) / ( b - a )
    
      ncopy = n
      call bp01 ( ncopy, bval, x01 )
    
      bez_val = dot_product ( y(0:n), bval(0:n) )
    
      return
    end
    subroutine bp01 ( n, bern, x )
    !
    !*******************************************************************************
    !
    !! BP01 evaluates the Bernstein basis polynomials for [01,1] at a point X.
    !
    !
    !  Formula:
    !
    !    BERN(N,I,X) = [N!/(I!*(N-I)!)] * (1-X)**(N-I) * X**I
    !
    !  First values:
    !
    !    B(0,0,X) = 1
    !
    !    B(1,0,X) =      1-X
    !    B(1,1,X) =                X
    !
    !    B(2,0,X) =     (1-X)**2
    !    B(2,1,X) = 2 * (1-X)    * X
    !    B(2,2,X) =                X**2
    !
    !    B(3,0,X) =     (1-X)**3
    !    B(3,1,X) = 3 * (1-X)**2 * X
    !    B(3,2,X) = 3 * (1-X)    * X**2
    !    B(3,3,X) =                X**3
    !
    !    B(4,0,X) =     (1-X)**4
    !    B(4,1,X) = 4 * (1-X)**3 * X
    !    B(4,2,X) = 6 * (1-X)**2 * X**2
    !    B(4,3,X) = 4 * (1-X)    * X**3
    !    B(4,4,X) =                X**4
    !
    !  Special values:
    !
    !    B(N,I,1/2) = C(N,K) / 2**N
    !
    !  Modified:
    !
    !    12 January 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the degree of the Bernstein basis polynomials.
    !    For any N greater than or equal to 0, there is a set of N+1 Bernstein
    !    basis polynomials, each of degree N, which form a basis for
    !    all polynomials on [0,1].
    !
    !    Output, real BERN(0:N), the values of the N+1 Bernstein basis
    !    polynomials at X.
    !
    !    Input, real X, the point at which the polynomials are to be
    !    evaluated.
    !
      implicit none
    !
      integer n
    !
      real bern(0:n)
      integer i
      integer j
      real x
    !
      if ( n == 0 ) then
    
        bern(0) = 1.0E+00
    
      else if ( n > 0 ) then
    
        bern(0) = 1.0E+00 - x
        bern(1) = x
    
        do i = 2, n
          bern(i) = x * bern(i-1)
          do j = i-1, 1, -1
            bern(j) = x * bern(j-1) + ( 1.0E+00 - x ) * bern(j)
          end do
          bern(0) = ( 1.0E+00 - x ) * bern(0)
        end do
    
      end if
    
      return
    end
    subroutine bp_approx ( n, a, b, ydata, xval, yval )
    !
    !*******************************************************************************
    !
    !! BP_APPROX evaluates the Bernstein polynomial for F(X) on [A,B].
    !
    !
    !  Formula:
    !
    !    BERN(F)(X) = SUM ( 0 <= I <= N ) F(X(I)) * B_BASE(I,X)
    !
    !    where
    !
    !      X(I) = ( ( N - I ) * A + I * B ) / N
    !      B_BASE(I,X) is the value of the I-th Bernstein basis polynomial at X.
    !
    !  Discussion:
    !
    !    The Bernstein polynomial BERN(F) for F(X) is an approximant, not an
    !    interpolant; in other words, its value is not guaranteed to equal
    !    that of F at any particular point.  However, for a fixed interval
    !    [A,B], if we let N increase, the Bernstein polynomial converges
    !    uniformly to F everywhere in [A,B], provided only that F is continuous.
    !    Even if F is not continuous, but is bounded, the polynomial converges
    !    pointwise to F(X) at all points of continuity.  On the other hand,
    !    the convergence is quite slow compared to other interpolation
    !    and approximation schemes.
    !
    !  Modified:
    !
    !    10 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the degree of the Bernstein polynomial to be used.
    !
    !    Input, real A, B, the endpoints of the interval on which the
    !    approximant is based.  A and B should not be equal.
    !
    !    Input, real YDATA(0:N), the data values at N+1 equally spaced points 
    !    in [A,B].  If N = 0, then the evaluation point should be 0.5 * ( A + B).
    !    Otherwise, evaluation point I should be ( (N-I)*A + I*B ) / N ).
    !
    !    Input, real XVAL, the point at which the Bernstein polynomial 
    !    approximant is to be evaluated.  XVAL does not have to lie in the 
    !    interval [A,B].
    !
    !    Output, real YVAL, the value of the Bernstein polynomial approximant
    !    for F, based in [A,B], evaluated at XVAL.
    !
      implicit none
    !
      integer n
    !
      real a
      real b
      real bvec(0:n)
      integer i
      real xval
      real ydata(0:n)
      real yval
    !
    !  Evaluate the Bernstein basis polynomials at XVAL.
    !
      call bpab ( n, bvec, xval, a, b )
    !
    !  Now compute the sum of YDATA(I) * BVEC(I).
    !
      yval = dot_product ( ydata(0:n), bvec(0:n) )
    
      return
    end
    subroutine bpab ( n, bern, x, a, b )
    !
    !*******************************************************************************
    !
    !! BPAB evaluates the Bernstein basis polynomials for [A,B] at a point X.
    !
    !
    !  Formula:
    !
    !    BERN(N,I,X) = [N!/(I!*(N-I)!)] * (B-X)**(N-I) * (X-A)**I / (B-A)**N
    !
    !  First values:
    !
    !    B(0,0,X) =   1
    !
    !    B(1,0,X) = (      B-X                ) / (B-A)
    !    B(1,1,X) = (                 X-A     ) / (B-A)
    !
    !    B(2,0,X) = (     (B-X)**2            ) / (B-A)**2
    !    B(2,1,X) = ( 2 * (B-X)    * (X-A)    ) / (B-A)**2
    !    B(2,2,X) = (                (X-A)**2 ) / (B-A)**2
    !
    !    B(3,0,X) = (     (B-X)**3            ) / (B-A)**3
    !    B(3,1,X) = ( 3 * (B-X)**2 * (X-A)    ) / (B-A)**3
    !    B(3,2,X) = ( 3 * (B-X)    * (X-A)**2 ) / (B-A)**3
    !    B(3,3,X) = (                (X-A)**3 ) / (B-A)**3
    !
    !    B(4,0,X) = (     (B-X)**4            ) / (B-A)**4
    !    B(4,1,X) = ( 4 * (B-X)**3 * (X-A)    ) / (B-A)**4
    !    B(4,2,X) = ( 6 * (B-X)**2 * (X-A)**2 ) / (B-A)**4
    !    B(4,3,X) = ( 4 * (B-X)    * (X-A)**3 ) / (B-A)**4
    !    B(4,4,X) = (                (X-A)**4 ) / (B-A)**4
    !
    !  Modified:
    !
    !    12 January 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the degree of the Bernstein basis polynomials.
    !    For any N greater than or equal to 0, there is a set of N+1 
    !    Bernstein basis polynomials, each of degree N, which form a basis 
    !    for polynomials on [A,B].
    !
    !    Output, real BERN(0:N), the values of the N+1 Bernstein basis
    !    polynomials at X.
    !
    !    Input, real X, the point at which the polynomials are to be
    !    evaluated.  X need not lie in the interval [A,B].
    !
    !    Input, real A, B, the endpoints of the interval on which the
    !    polynomials are to be based.  A and B should not be equal.
    !
      implicit none
    !
      integer n
    !
      real a
      real b
      real bern(0:n)
      integer i
      integer j
      real x
    !
      if ( b == a ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'BPAB - Fatal error!'
        write ( *, '(a,g14.6)' ) '  A = B = ', a
        stop
      end if
    
      if ( n == 0 ) then
    
        bern(0) = 1.0E+00
    
      else if ( n > 0 ) then
    
        bern(0) = ( b - x ) / ( b - a )
        bern(1) = ( x - a ) / ( b - a )
    
        do i = 2, n
          bern(i) = ( x - a ) * bern(i-1) / ( b - a )
          do j = i-1, 1, -1
            bern(j) = ( ( b - x ) * bern(j) + ( x - a ) * bern(j-1) ) / ( b - a )
          end do
          bern(0) = ( b - x ) * bern(0) / ( b - a )
        end do
    
      end if
    
      return
    end
    subroutine data_to_dif ( diftab, ntab, xtab, ytab )
    !
    !*******************************************************************************
    !
    !! DATA_TO_DIF sets up a divided difference table from raw data.
    !
    !
    !  Discussion:
    !
    !    Space can be saved by using a single array for both the DIFTAB and
    !    YTAB dummy parameters.  In that case, the divided difference table will
    !    overwrite the Y data without interfering with the computation.
    !
    !  Modified:
    !
    !    11 April 2000
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Output, real DIFTAB(NTAB), the divided difference coefficients 
    !    corresponding to the input (XTAB,YTAB).
    !
    !    Input, integer NTAB, the number of pairs of points
    !    (XTAB(I),YTAB(I)) which are to be used as data.  The
    !    number of entries to be used in DIFTAB, XTAB and YTAB.
    !
    !    Input, real XTAB(NTAB), the X values at which data was taken.
    !    These values must be distinct.
    !
    !    Input, real YTAB(NTAB), the corresponding Y values.
    !
      implicit none
    !
      integer ntab
    !
      real diftab(ntab)
      integer i
      integer j
      logical rvec_distinct
      real xtab(ntab)
      real ytab(ntab)
    !
      if ( .not. rvec_distinct ( ntab, xtab ) ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'DATA_TO_DIF - Fatal error!'
        write ( *, '(a)' ) '  Two entries of XTAB are equal!'
        return
      end if
    !
    !  Copy the data values into DIFTAB.
    !
      diftab(1:ntab) = ytab(1:ntab)
    !
    !  Compute the divided differences.
    !
      do i = 2, ntab
        do j = ntab, i, -1
    
          diftab(j) = ( diftab(j) - diftab(j-1) ) / ( xtab(j) - xtab(j+1-i) )
    
        end do
      end do
     
      return
    end
    subroutine dif_val ( diftab, ntab, xtab, xval, yval )
    !
    !*******************************************************************************
    !
    !! DIF_VAL evaluates a divided difference polynomial at a point.
    !
    !
    !  Modified:
    !
    !    11 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real DIFTAB(NTAB), the divided difference polynomial coefficients.
    !
    !    Input, integer NTAB, the number of divided difference
    !    coefficients in DIFTAB, and the number of points XTAB.
    !
    !    Input, real XTAB(NTAB), the X values upon which the
    !    divided difference polynomial is based.
    !
    !    Input, real XVAL, a value of X at which the polynomial
    !    is to be evaluated.
    !
    !    Output, real YVAL, the value of the polynomial at XVAL.
    !
      implicit none
    !
      integer ntab
    !
      real diftab(ntab)
      integer i
      real xtab(ntab)
      real xval
      real yval
    !
      yval = diftab(ntab)
      do i = 1, ntab-1
        yval = diftab(ntab-i) + ( xval - xtab(ntab-i) ) * yval
      end do
     
      return
    end
    subroutine least_set ( ntab, xtab, ytab, ndeg, ptab, array, eps, ierror )
    !
    !*******************************************************************************
    !
    !! LEAST_SET constructs the least squares polynomial approximation to data.
    !
    !
    !  Discussion:
    !
    !    The routine LEAST_EVAL must be used to evaluate the approximation at a
    !    point.
    !
    !  Modified:
    !
    !    20 November 2000
    !
    !  Parameters:
    !
    !    Input, integer NTAB, the number of data points.
    !
    !    Input, real XTAB(NTAB), the X data.  The values in XTAB
    !    should be distinct, and in increasing order.
    !
    !    Input, real YTAB(NTAB), the Y data values corresponding
    !    to the X data in XTAB.
    !
    !    Input, integer NDEG, the degree of the polynomial which the
    !    program is to use.  NDEG must be at least 1, and less than or 
    !    equal to NTAB-1.
    !
    !    Output, real PTAB(NTAB).  PTAB(I) is the value of the
    !    least squares polynomial at the point XTAB(I).
    !
    !    Output, real ARRAY(2*NTAB+3*NDEG), an array containing data about 
    !    the polynomial.
    !
    !    Output, real EPS, the root-mean-square discrepancy of the
    !    polynomial fit.
    !
    !    Output, integer IERROR, error flag.
    !    zero, no error occurred;
    !    nonzero, an error occurred, and the polynomial could not be computed.
    !
      implicit none
    !
      integer ndeg
      integer ntab
    !
      real array(2*ntab+3*ndeg)
      real eps
      real error
      integer i
      integer i0l1
      integer i1l1
      integer ierror
      integer it
      integer k
      integer mdeg
      real ptab(ntab)
      real rn0
      real rn1
      real s
      real sum2
      real xtab(ntab)
      real y_sum
      real ytab(ntab)
    !
      ierror = 0
    !
    !  Check NDEG.
    !
      if ( ndeg < 1 ) then
        ierror = 1
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'LEAST_SET - Fatal error!'
        write ( *, '(a)' ) '  NDEG < 1.'
        return
      else if ( ndeg >= ntab ) then
        ierror = 1
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'LEAST_SET - Fatal error!'
        write ( *, '(a)' ) '  NDEG >= NTAB.'
        return
      end if
    !
    !  Check that the abscissas are strictly increasing.
    !
      do i = 1, ntab-1
        if ( xtab(i) >= xtab(i+1) ) then
          ierror = 1
          write ( *, '(a)' ) ' '
          write ( *, '(a)' ) 'LEAST_SET - Fatal error!'
          write ( *, '(a)' ) '  XTAB must be strictly increasing, but'
          write ( *, '(a,i6,a,g14.6)' ) '  XTAB(', i, ') = ', xtab(i)
          write ( *, '(a,i6,a,g14.6)' ) '  XTAB(', i+1, ') = ', xtab(i+1)
          return
        end if
      end do
    
      i0l1 = 3 * ndeg
      i1l1 = 3 * ndeg + ntab
    
      y_sum = sum ( ytab )
      rn0 = ntab
      array(2*ndeg) = y_sum / real ( ntab )
    
      ptab(1:ntab) = y_sum / real ( ntab )
    
      error = 0.0E+00
      do i = 1, ntab
        error = error + ( y_sum / real ( ntab ) - ytab(i) )**2
      end do
    
      if ( ndeg == 0 ) then
        eps = sqrt ( error / real ( ntab ) )
        return
      end if
    
      array(1) = sum ( xtab ) / real ( ntab )
    
      s = 0.0E+00
      sum2 = 0.0E+00
      do i = 1, ntab
        array(i1l1+i) = xtab(i) - array(1)
        s = s + array(i1l1+i)**2
        sum2 = sum2 + array(i1l1+i) * ( ytab(i) - ptab(i) )
      end do
    
      rn1 = s
      array(2*ndeg+1) = sum2 / s
    
      do i = 1, ntab
        ptab(i) = ptab(i) + sum2 * array(i1l1+i) / s
      end do
    
      error = sum ( ( ptab(1:ntab) - ytab(1:ntab) )**2 )
    
      if ( ndeg == 1 ) then
        eps = sqrt ( error / real ( ntab ) )
        return
      end if
    
      do i = 1, ntab
        array(3*ndeg+i) = 1.0E+00
      end do
    
      mdeg = 2
      k = 2
    
      do
    
        array(ndeg-1+k) = rn1 / rn0
    
        sum2 = 0.0E+00
        do i = 1, ntab
          sum2 = sum2 + xtab(i) * array(i1l1+i)**2
        end do
    
        array(k) = sum2 / rn1
    
        s = 0.0E+00
        sum2 = 0.0E+00
        do i = 1, ntab
          array(i0l1+i) = ( xtab(i) - array(k) ) * array(i1l1+i) &
            - array(ndeg-1+k) * array(i0l1+i)
          s = s + array(i0l1+i)**2
          sum2 = sum2 + array(i0l1+i) * ( ytab(i) - ptab(i) )
        end do
    
        rn0 = rn1
        rn1 = s
        it = i0l1
        i0l1 = i1l1
        i1l1 = it
        array(2*ndeg+k) = sum2 / rn1
    
        do i = 1, ntab
          ptab(i) = ptab(i) + sum2 * array(i1l1+i) / rn1
        end do
    
        error = sum ( ( ptab(1:ntab) - ytab(1:ntab) )**2 )
    
        if ( mdeg >= ndeg ) then
          exit
        end if
    
        mdeg = mdeg + 1
        k = k + 1
    
      end do
    
      eps = sqrt ( error / real ( ntab ) )
    
      return
    end
    subroutine least_val ( x, ndeg, array, value )
    !
    !*******************************************************************************
    !
    !! LEAST_VAL evaluates a least squares polynomial defined by LEAST_SET.
    !
    !
    !  Modified:
    !
    !    01 March 1999
    !
    !  Parameters:
    !
    !    Input, real X, the point at which the polynomial is to be evaluated.
    !
    !    Input, integer NDEG, the degree of the polynomial fit used.
    !    This is the value of NDEG as returned from LEAST_SET.
    !
    !    Input, real ARRAY(*), an array of a certain dimension.
    !    See LEAST_SET for details on the size of ARRAY.
    !    ARRAY contains information about the polynomial, as set up by LEAST_SET.
    !
    !    Output, real VALUE, the value of the polynomial at X.
    !
      implicit none
    !
      real array(*)
      real dk
      real dkp1
      real dkp2
      integer k
      integer l
      integer ndeg
      real value
      real x
    !
      if ( ndeg <= 0 ) then
    
        value = array(2*ndeg)
    
      else if ( ndeg == 1 ) then
    
        value = array(2*ndeg) + array(2*ndeg+1) * ( x - array(1) )
    
      else
    
        dkp2 = array(3*ndeg)
        dkp1 = array(3*ndeg-1) + ( x - array(ndeg) ) * dkp2
    
        do l = 1, ndeg-2
    
          k = ndeg - 1 - l
    
          dk = array(2*ndeg+k) + ( x - array(k+1) ) * dkp1 - array(ndeg+1+k) * dkp2
    
          dkp2 = dkp1
    
          dkp1 = dk
    
        end do
    
        value = array(2*ndeg) + ( x - array(1) ) * dkp1 - array(ndeg+1) * dkp2
    
      end if
    
      return
    end
    subroutine parabola_val2 ( ndim, ndata, tdata, ydata, left, tval, yval )
    !
    !*******************************************************************************
    !
    !! PARABOLA_VAL2 evaluates a parabolic interpolant through tabular data.
    !
    !
    !  Discussion:
    !
    !    This routine is a utility routine used by OVERHAUSER_SPLINE_VAL.
    !    It constructs the parabolic interpolant through the data in
    !    3 consecutive entries of a table and evaluates this interpolant
    !    at a given abscissa value.
    !
    !  Modified:
    !
    !    02 March 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDIM, the dimension of a single data point.
    !    NDIM must be at least 1.
    !
    !    Input, integer NDATA, the number of data points.
    !    NDATA must be at least 3.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data points.  The
    !    values in TDATA must be in strictly ascending order.
    !
    !    Input, real YDATA(NDIM,NDATA), the data points corresponding to
    !    the abscissas.
    !
    !    Input, integer LEFT, the location of the first of the three
    !    consecutive data points through which the parabolic interpolant
    !    must pass.  1 <= LEFT <= NDATA - 2.
    !
    !    Input, real TVAL, the value of T at which the parabolic interpolant
    !    is to be evaluated.  Normally, TDATA(1) <= TVAL <= T(NDATA), and
    !    the data will be interpolated.  For TVAL outside this range,
    !    extrapolation will be used.
    !
    !    Output, real YVAL(NDIM), the value of the parabolic interpolant at TVAL.
    !
      implicit none
    !
      integer ndata
      integer ndim
    !
      real dif1
      real dif2
      integer i
      integer left
      real t1
      real t2
      real t3
      real tval
      real tdata(ndata)
      real ydata(ndim,ndata)
      real y1
      real y2
      real y3
      real yval(ndim)
    !
    !  Check.
    !
      if ( left < 1 .or. left > ndata-2 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'PARABOLA_VAL2 - Fatal error!'
        write ( *, '(a)' ) '  LEFT < 1 or LEFT > NDATA-2.'
        stop
      end if
    
      if ( ndim < 1 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'PARABOLA_VAL2 - Fatal error!'
        write ( *, '(a)' ) '  NDIM < 1.'
        stop
      end if
    !
    !  Copy out the three abscissas.
    !
      t1 = tdata(left)
      t2 = tdata(left+1)
      t3 = tdata(left+2)
    
      if ( t1 >= t2 .or. t2 >= t3 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'PARABOLA_VAL2 - Fatal error!'
        write ( *, '(a)' ) '  T1 >= T2 or T2 >= T3.'
        stop
      end if
    !
    !  Construct and evaluate a parabolic interpolant for the data
    !  in each dimension.
    !
      do i = 1, ndim
    
        y1 = ydata(i,left)
        y2 = ydata(i,left+1)
        y3 = ydata(i,left+2)
    
        dif1 = ( y2 - y1 ) / ( t2 - t1 )
        dif2 = ( ( y3 - y1 ) / ( t3 - t1 ) &
             - ( y2 - y1 ) / ( t2 - t1 ) ) / ( t3 - t2 )
    
        yval(i) = y1 + ( tval - t1 ) * ( dif1 + ( tval - t2 ) * dif2 )
    
      end do
    
      return
    end
    subroutine r_random ( rlo, rhi, r )
    !
    !*******************************************************************************
    !
    !! R_RANDOM returns a random real in a given range.
    !
    !
    !  Modified:
    !
    !    06 April 2001
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real RLO, RHI, the minimum and maximum values.
    !
    !    Output, real R, the randomly chosen value.
    !
      implicit none
    !
      real r
      real rhi
      real rlo
      real t
    !
    !  Pick T, a random number in (0,1).
    !
      call random_number ( harvest = t )
    !
    !  Set R in ( RLO, RHI ).
    !
      r = ( 1.0E+00 - t ) * rlo + t * rhi
    
      return
    end
    subroutine r_swap ( x, y )
    !
    !*******************************************************************************
    !
    !! R_SWAP swaps two real values.
    !
    !
    !  Modified:
    !
    !    01 May 2000
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input/output, real X, Y.  On output, the values of X and
    !    Y have been interchanged.
    !
      implicit none
    !
      real x
      real y
      real z
    !
      z = x
      x = y
      y = z
    
      return
    end
    subroutine rvec_bracket ( n, x, xval, left, right )
    !
    !*******************************************************************************
    !
    !! RVEC_BRACKET searches a sorted array for successive brackets of a value.
    !
    !
    !  Discussion:
    !
    !    If the values in the vector are thought of as defining intervals
    !    on the real line, then this routine searches for the interval
    !    nearest to or containing the given value.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, length of input array.
    !
    !    Input, real X(N), an array sorted into ascending order.
    !
    !    Input, real XVAL, a value to be bracketed.
    !
    !    Output, integer LEFT, RIGHT, the results of the search.
    !    Either:
    !      XVAL < X(1), when LEFT = 1, RIGHT = 2;
    !      XVAL > X(N), when LEFT = N-1, RIGHT = N;
    !    or
    !      X(LEFT) <= XVAL <= X(RIGHT).
    !
      implicit none
    !
      integer n
    !
      integer i
      integer left
      integer right
      real x(n)
      real xval
    !
      do i = 2, n - 1
    
        if ( xval < x(i) ) then
          left = i - 1
          right = i
          return
        end if
    
       end do
    
      left = n - 1
      right = n
    
      return
    end
    subroutine rvec_bracket3 ( n, t, tval, left )
    !
    !*******************************************************************************
    !
    !! RVEC_BRACKET3 finds the interval containing or nearest a given value.
    !
    !
    !  Discussion:
    !
    !    The routine always returns the index LEFT of the sorted array
    !    T with the property that either
    !    *  T is contained in the interval [ T(LEFT), T(LEFT+1) ], or
    !    *  T < T(LEFT) = T(1), or
    !    *  T > T(LEFT+1) = T(N).
    !
    !    The routine is useful for interpolation problems, where
    !    the abscissa must be located within an interval of data
    !    abscissas for interpolation, or the "nearest" interval
    !    to the (extreme) abscissa must be found so that extrapolation
    !    can be carried out.
    !
    !  Modified:
    !
    !    05 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, length of the input array.
    !
    !    Input, real T(N), an array sorted into ascending order.
    !
    !    Input, real TVAL, a value to be bracketed by entries of T.
    !
    !    Input/output, integer LEFT.
    !
    !    On input, if 1 <= LEFT <= N-1, LEFT is taken as a suggestion for the
    !    interval [ T(LEFT), T(LEFT+1) ] in which TVAL lies.  This interval
    !    is searched first, followed by the appropriate interval to the left
    !    or right.  After that, a binary search is used.
    !
    !    On output, LEFT is set so that the interval [ T(LEFT), T(LEFT+1) ]
    !    is the closest to TVAL; it either contains TVAL, or else TVAL
    !    lies outside the interval [ T(1), T(N) ].
    !
      implicit none
    !
      integer n
    !
      integer high
      integer left
      integer low
      integer mid
      real t(n)
      real tval
    !
    !  Check the input data.
    !
      if ( n < 2 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'RVEC_BRACKET3 - Fatal error!'
        write ( *, '(a)' ) '  N must be at least 2.'
        stop
      end if
    !
    !  If LEFT is not between 1 and N-1, set it to the middle value.
    !
      if ( left < 1 .or. left > n - 1 ) then
        left = ( n + 1 ) / 2
      end if
    !
    !  CASE 1: TVAL < T(LEFT):
    !  Search for TVAL in [T(I), T(I+1)] for intervals I = 1 to LEFT-1.
    !
      if ( tval < t(left) ) then
    
        if ( left == 1 ) then
          return
        else if ( left == 2 ) then
          left = 1
          return
        else if ( tval >= t(left-1) ) then
          left = left - 1
          return
        else if ( tval <= t(2) ) then
          left = 1
          return
        end if
    !
    !  ...Binary search for TVAL in [T(I), T(I+1)] for intervals I = 2 to LEFT-2.
    !
        low = 2
        high = left - 2
    
        do
    
          if ( low == high ) then
            left = low
            return
          end if
    
          mid = ( low + high + 1 ) / 2
    
          if ( tval >= t(mid) ) then
            low = mid
          else
            high = mid - 1
          end if
    
        end do
    !
    !  CASE2: T(LEFT+1) < TVAL:
    !  Search for TVAL in {T(I),T(I+1)] for intervals I = LEFT+1 to N-1.
    !
      else if ( tval > t(left+1) ) then
    
        if ( left == n - 1 ) then
          return
        else if ( left == n - 2 ) then
          left = left + 1
          return
        else if ( tval <= t(left+2) ) then
          left = left + 1
          return
        else if ( tval >= t(n-1) ) then
          left = n - 1
          return
        end if
    !
    !  ...Binary search for TVAL in [T(I), T(I+1)] for intervals I = LEFT+2 to N-2.
    !
        low = left + 2
        high = n - 2
    
        do
    
          if ( low == high ) then
            left = low
            return
          end if
    
          mid = ( low + high + 1 ) / 2
    
          if ( tval >= t(mid) ) then
            low = mid
          else
            high = mid - 1
          end if
    
        end do
    !
    !  CASE3: T(LEFT) <= TVAL <= T(LEFT+1):
    !  T is in [T(LEFT), T(LEFT+1)], as the user said it might be.
    !
      else
    
      end if
    
      return
    end
    function rvec_distinct ( n, x )
    !
    !*******************************************************************************
    !
    !! RVEC_DISTINCT is true if the entries in a real vector are distinct.
    !
    !
    !  Modified:
    !
    !    16 September 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the number of entries in the vector.
    !
    !    Input, real X(N), the vector to be checked.
    !
    !    Output, logical RVEC_DISTINCT is .TRUE. if all N elements of X 
    !    are distinct.
    !
      implicit none
    !
      integer n
    !
      integer i
      integer j
      logical rvec_distinct
      real x(n)
    !
      rvec_distinct = .false.
    
      do i = 2, n
        do j = 1, i - 1 
          if ( x(i) == x(j) ) then
            return
          end if
        end do
      end do
    
      rvec_distinct = .true.
    
      return
    end
    subroutine rvec_even ( alo, ahi, n, a )
    !
    !*******************************************************************************
    !
    !! RVEC_EVEN returns N real values, evenly spaced between ALO and AHI.
    !
    !
    !  Modified:
    !
    !    31 October 2000
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real ALO, AHI, the low and high values.
    !
    !    Input, integer N, the number of values.
    !
    !    Output, real 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 n
    !
      real a(n)
      real ahi
      real alo
      integer i
    !
      if ( n == 1 ) then
    
        a(1) = 0.5E+00 * ( alo + ahi )
    
      else
    
        do i = 1, n
          a(i) = ( real ( n - i ) * alo + real ( i - 1 ) * ahi ) / real ( n - 1 )
        end do
    
      end if
    
      return
    end
    subroutine rvec_order_type ( n, a, order )
    !
    !*******************************************************************************
    !
    !! RVEC_ORDER_TYPE determines if a real array is (non)strictly ascending/descending.
    !
    !
    !  Modified:
    !
    !    20 July 2000
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the number of entries of the array.
    !
    !    Input, real A(N), the array to be checked.
    !
    !    Output, integer ORDER, order indicator:
    !    -1, no discernable order;
    !    0, all entries are equal;
    !    1, ascending order;
    !    2, strictly ascending order;
    !    3, descending order;
    !    4, strictly descending order.
    !
      implicit none
    !
      integer n
    !
      real a(n)
      integer i
      integer order
    !
    !  Search for the first value not equal to A(1).
    !
      i = 1
    
      do
    
        i = i + 1
    
        if ( i > n ) then
          order = 0
          return
        end if
    
        if ( a(i) > a(1) ) then
    
          if ( i == 2 ) then
            order = 2
          else
            order = 1
          end if
    
          exit
    
        else if ( a(i) < a(1) ) then
    
          if ( i == 2 ) then
            order = 4
          else
            order = 3
          end if
    
          exit
    
        end if
    
      end do
    !
    !  Now we have a "direction".  Examine subsequent entries.
    !
      do
    
        i = i + 1
        if ( i > n ) then
          exit
        end if
    
        if ( order == 1 ) then
    
          if ( a(i) < a(i-1) ) then
            order = -1
            exit
          end if
    
        else if ( order == 2 ) then
    
          if ( a(i) < a(i-1) ) then
            order = -1
            exit
          else if ( a(i) == a(i-1) ) then
            order = 1
          end if
    
        else if ( order == 3 ) then
    
          if ( a(i) > a(i-1) ) then
            order = -1
            exit
          end if
    
        else if ( order == 4 ) then
    
          if ( a(i) > a(i-1) ) then
            order = -1
            exit
          else if ( a(i) == a(i-1) ) then
            order = 3
          end if
    
        end if
    
      end do
     
      return
    end
    subroutine rvec_print ( n, a, title )
    !
    !*******************************************************************************
    !
    !! RVEC_PRINT prints a real vector.
    !
    !
    !  Modified:
    !
    !    16 December 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the number of components of the vector.
    !
    !    Input, real A(N), the vector to be printed.
    !
    !    Input, character ( len = * ) TITLE, a title to be printed first.
    !    TITLE may be blank.
    !
      implicit none
    !
      integer n
    !
      real a(n)
      integer i
      character ( len = * ) title
    !
      if ( title /= ' ' ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) trim ( title )
      end if
    
      write ( *, '(a)' ) ' '
      do i = 1, n
        write ( *, '(i6,g14.6)' ) i, a(i)
      end do
    
      return
    end
    subroutine rvec_random ( alo, ahi, n, a )
    !
    !*******************************************************************************
    !
    !! RVEC_RANDOM returns a random real vector in a given range.
    !
    !
    !  Modified:
    !
    !    04 February 2001
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real ALO, AHI, the range allowed for the entries.
    !
    !    Input, integer N, the number of entries in the vector.
    !
    !    Output, real A(N), the vector of randomly chosen values.
    !
      implicit none
    !
      integer n
    !
      real a(n)
      real ahi
      real alo
      integer i
    !
      do i = 1, n
        call r_random ( alo, ahi, a(i) )
      end do
    
      return
    end
    subroutine rvec_sort_bubble_a ( n, a )
    !
    !*******************************************************************************
    !
    !! RVEC_SORT_BUBBLE_A ascending sorts a real array using bubble sort.
    !
    !
    !  Discussion:
    !
    !    Bubble sort is simple to program, but inefficient.  It should not
    !    be used for large arrays.
    !
    !  Modified:
    !
    !    01 February 2001
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the number of entries in the array.
    !
    !    Input/output, real A(N).
    !    On input, an unsorted array.
    !    On output, the array has been sorted.
    !
      implicit none
    !
      integer n
    !
      real a(n)
      integer i
      integer j
    !
      do i = 1, n-1
        do j = i+1, n
          if ( a(i) > a(j) ) then
            call r_swap ( a(i), a(j) )
          end if
        end do
      end do
    
      return
    end
    subroutine s3_fs ( a1, a2, a3, n, b, x )
    !
    !*******************************************************************************
    !
    !! S3_FS factors and solves a tridiagonal linear system.
    !
    !
    !  Note:
    !
    !    This algorithm requires that each diagonal entry be nonzero.
    !
    !  Modified:
    !
    !    05 December 1998
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input/output, real A1(2:N), A2(1:N), A3(1:N-1).
    !    On input, the nonzero diagonals of the linear system.
    !    On output, the data in these vectors has been overwritten
    !    by factorization information.
    !
    !    Input, integer N, the order of the linear system.
    !
    !    Input/output, real B(N).
    !    On input, B contains the right hand side of the linear system.
    !    On output, B has been overwritten by factorization information.
    !
    !    Output, real X(N), the solution of the linear system.
    !
      implicit none
    !
      integer n
    !
      real a1(2:n)
      real a2(1:n)
      real a3(1:n-1)
      real b(n)
      integer i
      real x(n)
      real xmult
    !
    !  The diagonal entries can't be zero.
    !
      do i = 1, n
        if ( a2(i) == 0.0E+00 ) then
          write ( *, '(a)' ) ' '
          write ( *, '(a)' ) 'S3_FS - Fatal error!'
          write ( *, '(a,i6,a)' ) '  A2(', i, ') = 0.'
          return
        end if
      end do
    
      do i = 2, n-1
    
        xmult = a1(i) / a2(i-1)
        a2(i) = a2(i) - xmult * a3(i-1)
    
        b(i) = b(i) - xmult * b(i-1)
    
      end do
    
      xmult = a1(n) / a2(n-1)
      a2(n) = a2(n) - xmult * a3(n-1)
    
      x(n) = ( b(n) - xmult * b(n-1) ) / a2(n)
      do i = n-1, 1, -1
        x(i) = ( b(i) - a3(i) * x(i+1) ) / a2(i)
      end do
    
      return
    end
    subroutine sgtsl ( n, c, d, e, b, info )
    !
    !*******************************************************************************
    !
    !! SGTSL solves a general tridiagonal linear system.
    !
    !
    !  Reference:
    !
    !    Dongarra, Moler, Bunch and Stewart,
    !    LINPACK User's Guide,
    !    SIAM, (Society for Industrial and Applied Mathematics),
    !    3600 University City Science Center,
    !    Philadelphia, PA, 19104-2688.
    !    ISBN 0-89871-172-X
    !
    !  Modified:
    !
    !    31 October 2001
    !
    !  Parameters:
    !
    !    Input, integer N, the order of the tridiagonal matrix.
    !
    !    Input/output, real C(N), contains the subdiagonal of the tridiagonal
    !    matrix in entries C(2:N).  On output, C is destroyed.
    !
    !    Input/output, real D(N).  On input, the diagonal of the matrix.
    !    On output, D is destroyed.
    !
    !    Input/output, real E(N), contains the superdiagonal of the tridiagonal
    !    matrix in entries E(1:N-1).  On output E is destroyed.
    !
    !    Input/output, real B(N).  On input, the right hand side.  On output,
    !    the solution.
    !
    !    Output, integer INFO, error flag.
    !    0, normal value.
    !    K, the K-th element of the diagonal becomes exactly zero.  The
    !       subroutine returns if this error condition is detected.
    !
      implicit none
    !
      integer n
    !
      real b(n)
      real c(n)
      real d(n)
      real e(n)
      integer info
      integer k
      real t
    !
      info = 0
      c(1) = d(1)
    
      if ( n >= 2 ) then
    
        d(1) = e(1)
        e(1) = 0.0E+00
        e(n) = 0.0E+00
    
        do k = 1, n - 1
    !
    !  Find the larger of the two rows, and interchange if necessary.
    !
          if ( abs ( c(k+1) ) >= abs ( c(k) ) ) then
            call r_swap ( c(k), c(k+1) )
            call r_swap ( d(k), d(k+1) )
            call r_swap ( e(k), e(k+1) )
            call r_swap ( b(k), b(k+1) )
          end if
    !
    !  Fail if no nonzero pivot could be found.
    !
          if ( c(k) == 0.0E+00 ) then
            info = k
            return
          end if
    !
    !  Zero elements.
    !
          t = -c(k+1) / c(k)
          c(k+1) = d(k+1) + t * d(k)
          d(k+1) = e(k+1) + t * e(k)
          e(k+1) = 0.0E+00
          b(k+1) = b(k+1) + t * b(k)
    
        end do
    
      end if
    
      if ( c(n) == 0.0E+00 ) then
        info = n
        return
      end if
    !
    !  Back solve.
    !
      b(n) = b(n) / c(n)
    
      if ( n > 1 ) then
    
        b(n-1) = ( b(n-1) - d(n-1) * b(n) ) / c(n-1)
    
        do k = n-2, 1, -1
          b(k) = ( b(k) - d(k) * b(k+1) - e(k) * b(k+2) ) / c(k)
        end do
    
      end if
    
      return
    end
    subroutine spline_b_val ( ndata, tdata, ydata, tval, yval )
    !
    !*******************************************************************************
    !
    !! SPLINE_B_VAL evaluates a cubic B spline approximant.
    !
    !
    !  Discussion:
    !
    !    The cubic B spline will approximate the data, but is not 
    !    designed to interpolate it.
    !
    !    In effect, two "phantom" data values are appended to the data,
    !    so that the spline will interpolate the first and last data values.
    !
    !  Modified:
    !
    !    07 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data values.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data.
    !
    !    Input, real YDATA(NDATA), the data values.
    !
    !    Input, real TVAL, a point at which the spline is to be evaluated.
    !
    !    Output, real YVAL, the value of the function at TVAL.
    !
      implicit none
    !
      integer ndata
    !
      real bval
      integer left
      integer right
      real tdata(ndata)
      real tval
      real u
      real ydata(ndata)
      real yval
    !
    !  Find the nearest interval [ TDATA(LEFT), TDATA(RIGHT) ] to TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Evaluate the 5 nonzero B spline basis functions in the interval,
    !  weighted by their corresponding data values.
    !
      u = ( tval - tdata(left) ) / ( tdata(right) - tdata(left) )
      yval = 0.0E+00
    !
    !  B function associated with node LEFT - 1, (or "phantom node"),
    !  evaluated in its 4th interval.
    !
      bval = ( 1.0E+00 - 3.0E+00 * u + 3.0E+00 * u**2 - u**3 ) / 6.0E+00
      if ( left-1 > 0 ) then
        yval = yval + ydata(left-1) * bval
      else
        yval = yval + ( 2.0E+00 * ydata(1) - ydata(2) ) * bval
      end if
    !
    !  B function associated with node LEFT,
    !  evaluated in its third interval.
    !
      bval = ( 4.0E+00 - 6.0E+00 * u**2 + 3.0E+00 * u**3 ) / 6.0E+00
      yval = yval + ydata(left) * bval
    !
    !  B function associated with node RIGHT,
    !  evaluated in its second interval.
    !
      bval = ( 1.0E+00 + 3.0E+00 * u + 3.0E+00 * u**2 - 3.0E+00 * u**3 ) / 6.0E+00
      yval = yval + ydata(right) * bval
    !
    !  B function associated with node RIGHT+1, (or "phantom node"),
    !  evaluated in its first interval.
    !
      bval = u**3 / 6.0E+00
      if ( right+1 <= ndata ) then
        yval = yval + ydata(right+1) * bval
      else
        yval = yval + ( 2.0E+00 * ydata(ndata) - ydata(ndata-1) ) * bval
      end if
    
      return
    end
    subroutine spline_beta_val ( beta1, beta2, ndata, tdata, ydata, tval, yval )
    !
    !*******************************************************************************
    !
    !! SPLINE_BETA_VAL evaluates a cubic beta spline approximant.
    !
    !
    !  Discussion:
    !
    !    The cubic beta spline will approximate the data, but is not 
    !    designed to interpolate it.
    !
    !    If BETA1 = 1 and BETA2 = 0, the cubic beta spline will be the
    !    same as the cubic B spline approximant.
    !
    !    With BETA1 = 1 and BETA2 large, the beta spline becomes more like
    !    a linear spline.
    !
    !    In effect, two "phantom" data values are appended to the data,
    !    so that the spline will interpolate the first and last data values.
    !
    !  Modified:
    !
    !    12 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, real BETA1, the skew or bias parameter.
    !    BETA1 = 1 for no skew or bias.
    !
    !    Input, real BETA2, the tension parameter.
    !    BETA2 = 0 for no tension.
    !
    !    Input, integer NDATA, the number of data values.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data.
    !
    !    Input, real YDATA(NDATA), the data values.
    !
    !    Input, real TVAL, a point at which the spline is to be evaluated.
    !
    !    Output, real YVAL, the value of the function at TVAL.
    !
      implicit none
    !
      integer ndata
    !
      real a
      real b
      real beta1
      real beta2
      real bval
      real c
      real d
      real delta
      integer left
      integer right
      real tdata(ndata)
      real tval
      real u
      real ydata(ndata)
      real yval
    !
    !  Find the nearest interval [ TDATA(LEFT), TDATA(RIGHT) ] to TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Evaluate the 5 nonzero beta spline basis functions in the interval,
    !  weighted by their corresponding data values.
    !
      u = ( tval - tdata(left) ) / ( tdata(right) - tdata(left) )
    
      delta = 2.0E+00 + beta2 + 4.0E+00 * beta1 + 4.0E+00 * beta1**2 &
        + 2.0E+00 * beta1**3
    
      yval = 0.0E+00
    !
    !  Beta function associated with node LEFT - 1, (or "phantom node"),
    !  evaluated in its 4th interval.
    !
      bval = ( 2.0E+00 * beta1**3 * ( 1.0E+00 - u )**3 ) / delta
    
      if ( left-1 > 0 ) then
        yval = yval + ydata(left-1) * bval
      else
        yval = yval + ( 2.0E+00 * ydata(1) - ydata(2) ) * bval
      end if
    !
    !  Beta function associated with node LEFT,
    !  evaluated in its third interval.
    !
      a = beta2 + 4.0E+00 * beta1 + 4.0E+00 * beta1**2
    
      b = - 6.0E+00 * beta1 * ( 1.0E+00 - beta1 ) * ( 1.0E+00 + beta1 )
    
      c = - 3.0E+00 * ( beta2 + 2.0E+00 * beta1**2 + 2.0E+00 * beta1**3 )
    
      d = 2.0E+00 * ( beta2 + beta1 + beta1**2 + beta1**3 )
    
      bval = ( a + u * ( b + u * ( c + u * d ) ) ) / delta
    
      yval = yval + ydata(left) * bval
    !
    !  Beta function associated with node RIGHT,
    !  evaluated in its second interval.
    !
      a = 2.0E+00
    
      b = 6.0E+00 * beta1
    
      c = 3.0E+00 * beta2 + 6.0E+00 * beta1**2
    
      d = - 2.0E+00 * ( 1.0E+00 + beta2 + beta1 + beta1**2 )
    
      bval = ( a + u * ( b + u * ( c + u * d ) ) ) / delta
    
      yval = yval + ydata(right) * bval
    !
    !  Beta function associated with node RIGHT+1, (or "phantom node"),
    !  evaluated in its first interval.
    !
      bval = 2.0E+00 * u**3 / delta
    
      if ( right+1 <= ndata ) then
        yval = yval + ydata(right+1) * bval
      else
        yval = yval + ( 2.0E+00 * ydata(ndata) - ydata(ndata-1) ) * bval
      end if
    
      return
    end
    subroutine spline_constant_val ( ndata, tdata, ydata, tval, yval )
    !
    !*******************************************************************************
    !
    !! SPLINE_CONSTANT_VAL evaluates a piecewise constant spline at a point.
    !
    !
    !  Discussion:
    !
    !    NDATA-1 points TDATA define NDATA intervals, with the first
    !    and last being semi-infinite.
    !
    !    The value of the spline anywhere in interval I is YDATA(I).
    !
    !  Modified:
    !
    !    16 November 2001
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points defining the spline.
    !
    !    Input, real TDATA(NDATA-1), the breakpoints.  The values of TDATA should
    !    be distinct and increasing.
    !
    !    Input, YDATA(NDATA), the values of the spline in the intervals
    !    defined by the breakpoints.
    !
    !    Input, real TVAL, the point at which the spline is to be evaluated.
    !
    !    Output, real YVAL, the value of the spline at TVAL.  
    !
      implicit none
    !
      integer ndata
    !
      integer i
      real tdata(ndata-1)
      real tval
      real ydata(ndata)
      real yval
    !
      do i = 1, ndata-1
        if ( tval <= tdata(i) ) then
          yval = ydata(i)
          return
        end if
      end do
    
      yval = ydata(ndata)
    
      return
    end
    subroutine spline_cubic_set ( n, t, y, ibcbeg, ybcbeg, ibcend, ybcend, ypp )
    !
    !*******************************************************************************
    !
    !! SPLINE_CUBIC_SET computes the second derivatives of a cubic spline.
    !
    !
    !  Discussion:
    !
    !    For data interpolation, the user must call SPLINE_CUBIC_SET to 
    !    determine the second derivative data, passing in the data to be 
    !    interpolated, and the desired boundary conditions.
    !
    !    The data to be interpolated, plus the SPLINE_CUBIC_SET output, 
    !    defines the spline.  The user may then call SPLINE_CUBIC_VAL to 
    !    evaluate the spline at any point.
    !
    !    The cubic spline is a piecewise cubic polynomial.  The intervals
    !    are determined by the "knots" or abscissas of the data to be
    !    interpolated.  The cubic spline has continous first and second
    !    derivatives over the entire interval of interpolation.  
    !
    !    For any point T in the interval T(IVAL), T(IVAL+1), the form of
    !    the spline is
    !
    !      SPL(T) = A(IVAL)
    !             + B(IVAL) * ( T - T(IVAL) ) 
    !             + C(IVAL) * ( T - T(IVAL) )**2
    !             + D(IVAL) * ( T - T(IVAL) )**3
    !
    !    If we assume that we know the values Y(*) and YPP(*), which represent
    !    the values and second derivatives of the spline at each knot, then
    !    the coefficients can be computed as:
    !
    !      A(IVAL) = Y(IVAL)
    !      B(IVAL) = ( Y(IVAL+1) - Y(IVAL) ) / ( T(IVAL+1) - T(IVAL) )
    !        - ( YPP(IVAL+1) + 2 * YPP(IVAL) ) * ( T(IVAL+1) - T(IVAL) ) / 6
    !      C(IVAL) = YPP(IVAL) / 2
    !      D(IVAL) = ( YPP(IVAL+1) - YPP(IVAL) ) / ( 6 * ( T(IVAL+1) - T(IVAL) ) )
    !
    !    Since the first derivative of the spline is
    !
    !      SPL'(T) =     B(IVAL)
    !              + 2 * C(IVAL) * ( T - T(IVAL) )
    !              + 3 * D(IVAL) * ( T - T(IVAL) )**2,
    !
    !    the requirement that the first derivative be continuous at interior
    !    knot I results in a total of N-2 equations, of the form:
    !
    !      B(IVAL-1) + 2 C(IVAL-1) * (T(IVAL)-T(IVAL-1)) 
    !      + 3 * D(IVAL-1) * (T(IVAL) - T(IVAL-1))**2 = B(IVAL)
    !
    !    or, setting H(IVAL) = T(IVAL+1) - T(IVAL)
    !
    !      ( Y(IVAL) - Y(IVAL-1) ) / H(IVAL-1)
    !      - ( YPP(IVAL) + 2 * YPP(IVAL-1) ) * H(IVAL-1) / 6
    !      + YPP(IVAL-1) * H(IVAL-1)
    !      + ( YPP(IVAL) - YPP(IVAL-1) ) * H(IVAL-1) / 2
    !      = 
    !      ( Y(IVAL+1) - Y(IVAL) ) / H(IVAL)
    !      - ( YPP(IVAL+1) + 2 * YPP(IVAL) ) * H(IVAL) / 6
    !
    !    or
    !
    !      YPP(IVAL-1) * H(IVAL-1) + 2 * YPP(IVAL) * ( H(IVAL-1) + H(IVAL) )
    !      + YPP(IVAL) * H(IVAL) 
    !      =
    !      6 * ( Y(IVAL+1) - Y(IVAL) ) / H(IVAL)
    !      - 6 * ( Y(IVAL) - Y(IVAL-1) ) / H(IVAL-1)    
    !
    !    Boundary conditions must be applied at the first and last knots.  
    !    The resulting tridiagonal system can be solved for the YPP values.
    !
    !  Modified:
    !
    !    20 November 2000
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the number of data points; N must be at least 2. 
    !
    !    Input, real T(N), the points where data is specified.  
    !    The values should be distinct, and increasing.
    !
    !    Input, real Y(N), the data values to be interpolated.
    !
    !    Input, integer IBCBEG, the left boundary condition flag:
    !
    !      0: the spline should be a quadratic over the first interval;
    !      1: the first derivative at the left endpoint should be YBCBEG;
    !      2: the second derivative at the left endpoint should be YBCBEG.
    !
    !    Input, real YBCBEG, the left boundary value, if needed.
    !
    !    Input, integer IBCEND, the right boundary condition flag:
    !
    !      0: the spline should be a quadratic over the last interval;
    !      1: the first derivative at the right endpoint should be YBCEND;
    !      2: the second derivative at the right endpoint should be YBCEND.
    !
    !    Input, real YBCEND, the right boundary value, if needed.
    !
    !    Output, real YPP(N), the second derivatives of the cubic spline.
    !
      implicit none
    !
      integer n
    !
      real diag(n)
      integer i
      integer ibcbeg
      integer ibcend
      real sub(2:n)
      real sup(1:n-1)
      real t(n)
      real y(n)
      real ybcbeg
      real ybcend
      real ypp(n)
    !
    !  Check.
    !
      if ( n <= 1 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_CUBIC_SET - Fatal error!'
        write ( *, '(a)' ) '  The number of knots must be at least 2.'
        write ( *, '(a,i6)' ) '  The input value of N = ', n
        stop
      end if
    
      do i = 1, n-1
        if ( t(i) >= t(i+1) ) then
          write ( *, '(a)' ) ' '
          write ( *, '(a)' ) 'SPLINE_CUBIC_SET - Fatal error!'
          write ( *, '(a)' ) '  The knots must be strictly increasing, but'
          write ( *, '(a,i6,a,g14.6)' ) '  T(',  i,') = ', t(i)
          write ( *, '(a,i6,a,g14.6)' ) '  T(',i+1,') = ', t(i+1)
          stop
        end if
      end do
    !
    !  Set the first equation.
    !
      if ( ibcbeg == 0 ) then
        ypp(1) = 0.0E+00
        diag(1) = 1.0E+00
        sup(1) = -1.0E+00
      else if ( ibcbeg == 1 ) then
        ypp(1) = ( y(2) - y(1) ) / ( t(2) - t(1) ) - ybcbeg
        diag(1) = ( t(2) - t(1) ) / 3.0E+00 
        sup(1) = ( t(2) - t(1) ) / 6.0E+00
      else if ( ibcbeg == 2 ) then
        ypp(1) = ybcbeg
        diag(1) = 1.0E+00
        sup(1) = 0.0E+00
      else
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_CUBIC_SET - Fatal error!'
        write ( *, '(a)' ) '  The boundary flag IBCBEG must be 0, 1 or 2.'
        write ( *, '(a,i6)' ) '  The input value is IBCBEG = ', ibcbeg
        stop
      end if
    !
    !  Set the intermediate equations.
    !
      do i = 2, n-1
        ypp(i) = ( y(i+1) - y(i) ) / ( t(i+1) - t(i) ) &
               - ( y(i) - y(i-1) ) / ( t(i) - t(i-1) )
        sub(i) = ( t(i) - t(i-1) ) / 6.0E+00
        diag(i) = ( t(i+1) - t(i-1) ) / 3.0E+00
        sup(i) = ( t(i+1) - t(i) ) / 6.0E+00
      end do
    !
    !  Set the last equation.
    !
      if ( ibcend == 0 ) then
        ypp(n) = 0.0E+00
        sub(n) = -1.0E+00
        diag(n) = 1.0E+00
      else if ( ibcend == 1 ) then
        ypp(n) = ybcend - ( y(n) - y(n-1) ) / ( t(n) - t(n-1) )
        sub(n) = ( t(n) - t(n-1) ) / 6.0E+00
        diag(n) = ( t(n) - t(n-1) ) / 3.0E+00
      else if ( ibcend == 2 ) then
        ypp(n) = ybcend
        sub(n) = 0.0E+00
        diag(n) = 1.0E+00
      else
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_CUBIC_SET - Fatal error!'
        write ( *, '(a)' ) '  The boundary flag IBCEND must be 0, 1 or 2.'
        write ( *, '(a,i6)' ) '  The input value is IBCEND = ', ibcend
        stop
      end if
    !
    !  Special case:
    !    N = 2, IBCBEG = IBCEND = 0.
    !
      if ( n == 2 .and. ibcbeg == 0 .and. ibcend == 0 ) then
    
        ypp(1) = 0.0E+00
        ypp(2) = 0.0E+00
    !
    !  Solve the linear system.
    !
      else
    
        call s3_fs ( sub, diag, sup, n, ypp, ypp )
    
      end if
    
      return
    end
    subroutine spline_cubic_val ( n, t, y, ypp, tval, yval, ypval, yppval )
    !
    !*******************************************************************************
    !
    !! SPLINE_CUBIC_VAL evaluates a cubic spline at a specific point.
    !
    !
    !  Discussion:
    !
    !    SPLINE_CUBIC_SET must have already been called to define the 
    !    values of YPP.
    !
    !    For any point T in the interval T(IVAL), T(IVAL+1), the form of
    !    the spline is
    !
    !      SPL(T) = A 
    !             + B * ( T - T(IVAL) ) 
    !             + C * ( T - T(IVAL) )**2
    !             + D * ( T - T(IVAL) )**3
    !
    !    Here:
    !      A = Y(IVAL)
    !      B = ( Y(IVAL+1) - Y(IVAL) ) / ( T(IVAL+1) - T(IVAL) )
    !        - ( YPP(IVAL+1) + 2 * YPP(IVAL) ) * ( T(IVAL+1) - T(IVAL) ) / 6
    !      C = YPP(IVAL) / 2
    !      D = ( YPP(IVAL+1) - YPP(IVAL) ) / ( 6 * ( T(IVAL+1) - T(IVAL) ) )
    !
    !  Modified:
    !
    !    20 November 2000
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the number of data values.
    !
    !    Input, real T(N), the knot values.
    !
    !    Input, real Y(N), the data values at the knots.
    !
    !    Input, real YPP(N), the second derivatives of the spline at the knots.
    !
    !    Input, real TVAL, a point, typically between T(1) and T(N), at 
    !    which the spline is to be evalulated.  If TVAL lies outside 
    !    this range, extrapolation is used.
    !
    !    Output, real YVAL, YPVAL, YPPVAL, the value of the spline, and
    !    its first two derivatives at TVAL.
    !
      implicit none
    !
      integer n
    !
      real dt
      real h
      integer left
      integer right
      real t(n)
      real tval
      real y(n)
      real ypp(n)
      real yppval
      real ypval
      real yval
    !
    !  Determine the interval [T(LEFT), T(RIGHT)] that contains TVAL.
    !  Values below T(1) or above T(N) use extrapolation.
    !
      call rvec_bracket ( n, t, tval, left, right )
    !
    !  Evaluate the polynomial.
    !
      dt = tval - t(left)
      h = t(right) - t(left)
    
      yval = y(left) &
           + dt * ( ( y(right) - y(left) ) / h &
                  - ( ypp(right) / 6.0E+00 + ypp(left) / 3.0E+00 ) * h &
           + dt * ( 0.5E+00 * ypp(left) &
           + dt * ( ( ypp(right) - ypp(left) ) / ( 6.0E+00 * h ) ) ) )
    
      ypval = ( y(right) - y(left) ) / h &
           - ( ypp(right) / 6.0E+00 + ypp(left) / 3.0E+00 ) * h &
           + dt * ( ypp(left) &
           + dt * ( 0.5E+00 * ( ypp(right) - ypp(left) ) / h ) )
    
      yppval = ypp(left) + dt * ( ypp(right) - ypp(left) ) / h 
    
      return
    end
    subroutine spline_cubic_val2 ( n, t, y, ypp, left, tval, yval, ypval, yppval )
    !
    !*******************************************************************************
    !
    !! SPLINE_CUBIC_VAL2 evaluates a cubic spline at a specific point.
    !
    !
    !  Discussion:
    !
    !    This routine is a modification of SPLINE_CUBIC_VAL; it allows the
    !    user to speed up the code by suggesting the appropriate T interval
    !    to search first.
    !
    !    SPLINE_CUBIC_SET must have already been called to define the
    !    values of YPP.
    !
    !    In the LEFT interval, let RIGHT = LEFT+1.  The form of the spline is
    !
    !      SPL(T) = 
    !          A
    !        + B * ( T - T(LEFT) )
    !        + C * ( T - T(LEFT) )**2
    !        + D * ( T - T(LEFT) )**3
    !
    !    Here:
    !      A = Y(LEFT)
    !      B = ( Y(RIGHT) - Y(LEFT) ) / ( T(RIGHT) - T(LEFT) )
    !        - ( YPP(RIGHT) + 2 * YPP(LEFT) ) * ( T(RIGHT) - T(LEFT) ) / 6
    !      C = YPP(LEFT) / 2
    !      D = ( YPP(RIGHT) - YPP(LEFT) ) / ( 6 * ( T(RIGHT) - T(LEFT) ) )
    !
    !  Modified:
    !
    !    20 November 2000
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer N, the number of knots.
    !
    !    Input, real T(N), the knot values.
    !
    !    Input, real Y(N), the data values at the knots.
    !
    !    Input, real YPP(N), the second derivatives of the spline at
    !    the knots.
    !
    !    Input/output, integer LEFT, the suggested T interval to search.
    !    LEFT should be between 1 and N-1.  If LEFT is not in this range,
    !    then its value will be ignored.  On output, LEFT is set to the
    !    actual interval in which TVAL lies.
    !
    !    Input, real TVAL, a point, typically between T(1) and T(N), at
    !    which the spline is to be evalulated.  If TVAL lies outside
    !    this range, extrapolation is used.
    !
    !    Output, real YVAL, YPVAL, YPPVAL, the value of the spline, and
    !    its first two derivatives at TVAL.
    !
      implicit none
    !
      integer n
    !
      real dt
      real h
      integer left
      integer right
      real t(n)
      real tval
      real y(n)
      real ypp(n)
      real yppval
      real ypval
      real yval
    !
    !  Determine the interval [T(LEFT), T(RIGHT)] that contains TVAL.
    !  
    !  What you want from RVEC_BRACKET3 is that TVAL is to be computed
    !  by the data in interval {T(LEFT), T(RIGHT)].
    !
      left = 0
      call rvec_bracket3 ( n, t, tval, left )
      right = left + 1
    !
    !  In the interval LEFT, the polynomial is in terms of a normalized
    !  coordinate  ( DT / H ) between 0 and 1.
    !
      dt = tval - t(left)
      h = t(right) - t(left)
    
      yval = y(left) + dt * ( ( y(right) - y(left) ) / h &
                  - ( ypp(right) / 6.0E+00 + ypp(left) / 3.0E+00 ) * h &
           + dt * ( 0.5E+00 * ypp(left) &
           + dt * ( ( ypp(right) - ypp(left) ) / ( 6.0E+00 * h ) ) ) )
    
      ypval = ( y(right) - y(left) ) / h &
          - ( ypp(right) / 6.0E+00 + ypp(left) / 3.0E+00 ) * h &
          + dt * ( ypp(left) &
          + dt * ( 0.5E+00 * ( ypp(right) - ypp(left) ) / h ) )
    
      yppval = ypp(left) + dt * ( ypp(right) - ypp(left) ) / h
    
      return
    end
    subroutine spline_hermite_set ( ndata, tdata, c )
    !
    !*************************************************************************
    !
    !! SPLINE_HERMITE_SET sets up a piecewise cubic Hermite interpolant.
    !
    !
    !  Reference:
    !
    !    Conte and de Boor,
    !    Algorithm CALCCF,
    !    Elementary Numerical Analysis,
    !    1973, page 235.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points.
    !    NDATA must be at least 2.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data points.
    !    The entries of TDATA are assumed to be strictly increasing.
    !
    !    Input/output, real C(4,NDATA).
    !
    !    On input, C(1,I) and C(2,I) should contain the value of the
    !    function and its derivative at TDATA(I), for I = 1 to NDATA.
    !    These values will not be changed by this routine.
    !
    !    On output, C(3,I) and C(4,I) contain the quadratic
    !    and cubic coefficients of the Hermite polynomial
    !    in the interval (TDATA(I), TDATA(I+1)), for I=1 to NDATA-1.
    !    C(3,NDATA) and C(4,NDATA) are set to 0.
    !
    !    In the interval (TDATA(I), TDATA(I+1)), the interpolating Hermite
    !    polynomial is given by
    !
    !    SVAL(TVAL) =                 C(1,I)
    !       + ( TVAL - TDATA(I) ) * ( C(2,I)
    !       + ( TVAL - TDATA(I) ) * ( C(3,I)
    !       + ( TVAL - TDATA(I) ) *   C(4,I) ) )
    !
      implicit none
    !
      integer ndata
    !
      real c(4,ndata)
      real divdif1
      real divdif3
      real dt
      integer i
      real tdata(ndata)
    !
      do i = 1, ndata-1
        dt = tdata(i+1) - tdata(i)
        divdif1 = ( c(1,i+1) - c(1,i) ) / dt
        divdif3 = c(2,i) + c(2,i+1) - 2.0E+00 * divdif1
        c(3,i) = ( divdif1 - c(2,i) - divdif3 ) / dt
        c(4,i) = divdif3 / dt**2
      end do
    
      c(3,ndata) = 0.0E+00
      c(4,ndata) = 0.0E+00
    
      return
    end
    subroutine spline_hermite_val ( ndata, tdata, c, tval, sval )
    !
    !*************************************************************************
    !
    !! SPLINE_HERMITE_VAL evaluates a piecewise cubic Hermite interpolant.
    !
    !
    !  Discussion:
    !
    !    SPLINE_HERMITE_SET must be called first, to set up the
    !    spline data from the raw function and derivative data.
    !
    !  Reference:
    !
    !    Conte and de Boor,
    !    Algorithm PCUBIC,
    !    Elementary Numerical Analysis,
    !    1973, page 234.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points.
    !    NDATA is assumed to be at least 2.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data points.
    !    The entries of TDATA are assumed to be strictly increasing.
    !
    !    Input, real C(4,NDATA), contains the data computed by
    !    SPLINE_HERMITE_SET.
    !
    !    Input, real TVAL, the point where the interpolant is to
    !    be evaluated.
    !
    !    Output, real SVAL, the value of the interpolant at TVAL.
    !
      implicit none
    !
      integer ndata
    !
      real c(4,ndata)
      real dt
      integer left
      integer right
      real sval
      real tdata(ndata)
      real tval
    !
    !  Find the interval [ TDATA(LEFT), TDATA(RIGHT) ] that contains
    !  or is nearest to TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Evaluate the cubic polynomial.
    !
      dt = tval - tdata(left)
    
      sval = c(1,left) + dt * ( c(2,left) + dt * ( c(3,left) + dt * c(4,left) ) )
    
      return
    end
    subroutine spline_linear_int ( ndata, tdata, ydata, a, b, int_val )
    !
    !*******************************************************************************
    !
    !! SPLINE_LINEAR_INT evaluates the integral of a linear spline.
    !
    !
    !  Modified:
    !
    !    01 November 2001
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points defining the spline.
    !
    !    Input, real TDATA(NDATA), YDATA(NDATA), the values of the independent
    !    and dependent variables at the data points.  The values of TDATA should
    !    be distinct and increasing.
    !
    !    Input, real A, B, the interval over which the integral is desired.
    !
    !    Output, real INT_VAL, the value of the integral.
    !
      implicit none
    !
      integer ndata
    !
      real a
      real a_copy
      integer a_left
      integer a_right
      real b
      real b_copy
      integer b_left
      integer b_right
      integer i_left
      real int_val
      real tdata(ndata)
      real tval
      real ydata(ndata)
      real yp
      real yval
    !
      int_val = 0.0E+00 
    
      if ( a == b ) then
        return
      end if
    
      a_copy = min ( a, b )
      b_copy = max ( a, b )
    !
    !  Find the interval [ TDATA(A_LEFT), TDATA(A_RIGHT) ] that contains, or is
    !  nearest to, A.
    !
      call rvec_bracket ( ndata, tdata, a_copy, a_left, a_right )
    !
    !  Find the interval [ TDATA(B_LEFT), TDATA(B_RIGHT) ] that contains, or is
    !  nearest to, B.
    !
      call rvec_bracket ( ndata, tdata, b_copy, b_left, b_right )
    !
    !  If A and B are in the same interval...
    !
      if ( a_left == b_left ) then
    
        tval = ( a_copy + b_copy ) / 2.0E+00
    
        yp = ( ydata(a_right) - ydata(a_left) ) / &
             ( tdata(a_right) - tdata(a_left) )
    
        yval = ydata(a_left) + ( tval - tdata(a_left) ) * yp
    
        int_val = yval * ( b_copy - a_copy )
    
        return
      end if
    !
    !  Otherwise, integrate from:
    !
    !  A               to TDATA(A_RIGHT),
    !  TDATA(A_RIGHT)  to TDATA(A_RIGHT+1),...
    !  TDATA(B_LEFT-1) to TDATA(B_LEFT),
    !  TDATA(B_LEFT)   to B.
    !
    !  Use the fact that the integral of a linear function is the
    !  value of the function at the midpoint times the width of the interval.
    !
      tval = ( a_copy + tdata(a_right) ) / 2.0E+00
    
      yp = ( ydata(a_right) - ydata(a_left) ) / &
           ( tdata(a_right) - tdata(a_left) )
    
      yval = ydata(a_left) + ( tval - tdata(a_left) ) * yp
    
      int_val = int_val + yval * ( tdata(a_right) - a_copy )
    
      do i_left = a_right, b_left - 1
    
        tval = ( tdata(i_left+1) + tdata(i_left) ) / 2.0E+00
    
        yp = ( ydata(i_left+1) - ydata(i_left) ) / &
             ( tdata(i_left+1) - tdata(i_left) )
    
        yval = ydata(i_left) + ( tval - tdata(i_left) ) * yp
    
        int_val = int_val + yval * ( tdata(i_left + 1) - tdata(i_left) )
    
      end do
    
      tval = ( tdata(b_left) + b_copy ) / 2.0E+00
    
      yp = ( ydata(b_right) - ydata(b_left) ) / &
           ( tdata(b_right) - tdata(b_left) )
    
      yval = ydata(b_left) + ( tval - tdata(b_left) ) * yp
    
      int_val = int_val + yval * ( b_copy - tdata(b_left) )
    
      if ( b < a ) then
        int_val = - int_val
      end if
    
      return
    end
    subroutine spline_linear_intset ( int_n, int_x, int_v, data_n, data_x, data_y )
    !
    !*******************************************************************************
    !
    !! SPLINE_LINEAR_INTSET sets a linear spline with given integral properties.
    !
    !
    !  Discussion:
    !
    !    The user has in mind an interval, divided by INT_N+1 points into
    !    INT_N intervals.  A linear spline is to be constructed,
    !    with breakpoints at the centers of each interval, and extending
    !    continuously to the left of the first and right of the last
    !    breakpoints.  The constraint on the linear spline is that it is
    !    required that it have a given integral value over each interval.
    !
    !    A tridiagonal linear system of equations is solved for the
    !    values of the spline at the breakpoints.
    !
    !  Modified:
    !
    !    02 November 2001
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer INT_N, the number of intervals.
    !
    !    Input, real INT_X(INT_N+1), the points that define the intervals.
    !    Interval I lies between INT_X(I) and INT_X(I+1).
    !
    !    Input, real INT_V(INT_N), the desired value of the integral of the
    !    linear spline over each interval.
    !
    !    Output, integer DATA_N, the number of data points defining the spline.
    !    (This is the same as INT_N).
    !
    !    Output, real DATA_X(DATA_N), DATA_Y(DATA_N), the values of the independent
    !    and dependent variables at the data points.  The values of DATA_X are
    !    the interval midpoints.  The values of DATA_Y are determined in such
    !    a way that the exact integral of the linear spline over interval I
    !    is equal to INT_V(I).
    !
      implicit none
    !
      integer int_n
    !
      real c(int_n)
      real d(int_n)
      integer data_n
      real data_x(int_n)
      real data_y(int_n)
      real e(int_n)
      integer info
      real int_v(int_n)
      real int_x(int_n+1)
    !
    !  Set up the easy stuff.
    !
      data_n = int_n
      data_x(1:data_n) = 0.5E+00 * ( int_x(1:data_n) + int_x(2:data_n+1) )
    !
    !  Set up C, D, E, the coefficients of the linear system.
    !
      c(1) = 0.0E+00
      c(2:data_n-1) = 1.0 &
        - ( 0.5 * ( data_x(2:data_n-1) + int_x(2:data_n-1) ) &
        - data_x(1:data_n-2) ) &
        / ( data_x(2:data_n-1) - data_x(1:data_n-2) )
      c(data_n) = 0.0E+00
    
      d(1) = int_x(2) - int_x(1)
    
      d(2:data_n-1) = 1.0 &
        + ( 0.5 * ( data_x(2:data_n-1) + int_x(2:data_n-1) ) &
        - data_x(1:data_n-2) ) &
        / ( data_x(2:data_n-1) - data_x(1:data_n-2) ) &
        - ( 0.5 * ( data_x(2:data_n-1) + int_x(3:data_n) ) - data_x(2:data_n-1) ) &
        / ( data_x(3:data_n) - data_x(2:data_n-1) )
    
      d(data_n) = int_x(data_n+1) - int_x(data_n)
    
      e(1) = 0.0E+00
    
      e(2:data_n-1) = ( 0.5 * ( data_x(2:data_n-1) + int_x(3:data_n) ) &
        - data_x(2:data_n-1) ) / ( data_x(3:data_n) - data_x(2:data_n-1) )
    
      e(data_n) = 0.0E+00
    !
    !  Set up DATA_Y, which begins as the right hand side of the linear system.
    !
      data_y(1) = int_v(1)
      data_y(2:data_n-1) = 2.0E+00 * int_v(2:data_n-1) &
        / ( int_x(3:int_n) - int_x(2:int_n-1) )
      data_y(data_n) = int_v(data_n)
    !
    !  Solve the linear system.
    !
      call sgtsl ( data_n, c, d, e, data_y, info )
    
      if ( info /= 0 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_LINEAR_INTSET - Fatal error!'
        write ( *, '(a)' ) '  The linear system is singular.'
        stop
      end if
    
      return
    end
    subroutine spline_linear_val ( ndata, tdata, ydata, tval, yval, ypval )
    !
    !*******************************************************************************
    !
    !! SPLINE_LINEAR_VAL evaluates a linear spline at a specific point.
    !
    !
    !  Discussion:
    !
    !    Because of the extremely simple form of the linear spline,
    !    the raw data points ( TDATA(I), YDATA(I)) can be used directly to
    !    evaluate the spline at any point.  No processing of the data
    !    is required.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points defining the spline.
    !
    !    Input, real TDATA(NDATA), YDATA(NDATA), the values of the independent
    !    and dependent variables at the data points.  The values of TDATA should
    !    be distinct and increasing.
    !
    !    Input, real TVAL, the point at which the spline is to be evaluated.
    !
    !    Output, real YVAL, YPVAL, the value of the spline and its first
    !    derivative dYdT at TVAL.  YPVAL is not reliable if TVAL is exactly
    !    equal to TDATA(I) for some I.
    !
      implicit none
    !
      integer ndata
    !
      integer left
      integer right
      real tdata(ndata)
      real tval
      real ydata(ndata)
      real ypval
      real yval
    !
    !  Find the interval [ TDATA(LEFT), TDATA(RIGHT) ] that contains, or is
    !  nearest to, TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Now evaluate the piecewise linear function.
    !
      ypval = ( ydata(right) - ydata(left) ) / ( tdata(right) - tdata(left) )
    
      yval = ydata(left) +  ( tval - tdata(left) ) * ypval
    
      return
    end
    subroutine spline_overhauser_nonuni_val ( ndata, tdata, ydata, tval, yval )
    !
    !*******************************************************************************
    !
    !! SPLINE_OVERHAUSER_NONUNI_VAL evaluates the nonuniform Overhauser spline.
    !
    !
    !  Discussion:
    !
    !    The nonuniformity refers to the fact that the abscissas values
    !    need not be uniformly spaced.
    !
    !  Diagnostics:
    !
    !    The values of ALPHA and BETA have to be properly assigned.
    !    The basis matrices for the first and last interval have to
    !    be computed.
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data points.
    !    The values of TDATA are assumed to be distinct and increasing.
    !
    !    Input, real YDATA(NDATA), the data values.
    !
    !    Input, real TVAL, the value where the spline is to
    !    be evaluated.
    !
    !    Output, real YVAL, the value of the spline at TVAL.
    !
      implicit none
    !
      integer ndata
    !
      real alpha
      real beta
      integer left
      real mbasis(4,4)
      real mbasis_l(3,3)
      real mbasis_r(3,3)
      integer right
      real tdata(ndata)
      real tval
      real ydata(ndata)
      real yval
    !
    !  Find the nearest interval [ TDATA(LEFT), TDATA(RIGHT) ] to TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Evaluate the spline in the given interval.
    !
      if ( left == 1 ) then
    
        alpha = 1.0E+00
        call basis_matrix_overhauser_nul ( alpha, mbasis_l )
    
        call basis_matrix_tmp ( 1, 3, mbasis_l, ndata, tdata, ydata, tval, yval )
    
      else if ( left < ndata-1 ) then
    
        alpha = 1.0E+00
        beta = 1.0E+00
        call basis_matrix_overhauser_nonuni ( alpha, beta, mbasis )
    
        call basis_matrix_tmp ( left, 4, mbasis, ndata, tdata, ydata, tval, yval )
    
      else if ( left == ndata-1 ) then
    
        beta = 1.0E+00
        call basis_matrix_overhauser_nur ( beta, mbasis_r )
    
        call basis_matrix_tmp ( left, 3, mbasis_r, ndata, tdata, ydata, tval, yval )
    
      end if
    
      return
    end
    subroutine spline_overhauser_uni_val ( ndata, tdata, ydata, tval, yval )
    !
    !*******************************************************************************
    !
    !! SPLINE_OVERHAUSER_UNI_VAL evaluates the uniform Overhauser spline.
    !
    !
    !  Modified:
    !
    !    06 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data points.
    !    The values of TDATA are assumed to be distinct and increasing.
    !    This routine also assumes that the values of TDATA are uniformly
    !    spaced; for instance, TDATA(1) = 10, TDATA(2) = 11, TDATA(3) = 12...
    !
    !    Input, real YDATA(NDATA), the data values.
    !
    !    Input, real TVAL, the value where the spline is to
    !    be evaluated.
    !
    !    Output, real YVAL, the value of the spline at TVAL.
    !
      implicit none
    !
      integer ndata
    !
      integer left
      real mbasis(4,4)
      real mbasis_l(3,3)
      real mbasis_r(3,3)
      integer right
      real tdata(ndata)
      real tval
      real ydata(ndata)
      real yval
    !
    !  Find the nearest interval [ TDATA(LEFT), TDATA(RIGHT) ] to TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Evaluate the spline in the given interval.
    !
      if ( left == 1 ) then
    
        call basis_matrix_overhauser_uni_l ( mbasis_l )
    
        call basis_matrix_tmp ( 1, 3, mbasis_l, ndata, tdata, ydata, tval, yval )
    
      else if ( left < ndata-1 ) then
    
        call basis_matrix_overhauser_uni ( mbasis )
    
        call basis_matrix_tmp ( left, 4, mbasis, ndata, tdata, ydata, tval, yval )
    
      else if ( left == ndata-1 ) then
    
        call basis_matrix_overhauser_uni_r ( mbasis_r )
    
        call basis_matrix_tmp ( left, 3, mbasis_r, ndata, tdata, ydata, tval, yval )
    
      end if
    
      return
    end
    subroutine spline_overhauser_val ( ndim, ndata, tdata, ydata, tval, yval )
    !
    !*******************************************************************************
    !
    !! SPLINE_OVERHAUSER_VAL evaluates an Overhauser spline.
    !
    !
    !  Discussion:
    !
    !    Over the first and last intervals, the Overhauser spline is a 
    !    quadratic.  In the intermediate intervals, it is a piecewise cubic.
    !    The Overhauser spline is also known as the Catmull-Rom spline.
    !
    !  Reference:
    !
    !    H Brewer and D Anderson,
    !    Visual Interaction with Overhauser Curves and Surfaces,
    !    SIGGRAPH 77, pages 132-137.
    !
    !    E Catmull and R Rom,
    !    A Class of Local Interpolating Splines,
    !    in Computer Aided Geometric Design,
    !    edited by R Barnhill and R Reisenfeld,
    !    Academic Press, 1974, pages 317-326.
    !
    !    David Rogers and Alan Adams,
    !    Mathematical Elements of Computer Graphics,
    !    McGraw Hill, 1990, Second Edition, pages 278-289.
    !
    !  Modified:
    !
    !   08 April 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDIM, the dimension of a single data point.
    !    NDIM must be at least 1.  There is an internal limit on NDIM,
    !    called MAXDIM, which is presently set to 5.
    !
    !    Input, integer NDATA, the number of data points.
    !    NDATA must be at least 3.
    !
    !    Input, real TDATA(NDATA), the abscissas of the data points.  The
    !    values in TDATA must be in strictly ascending order.
    !
    !    Input, real YDATA(NDIM,NDATA), the data points corresponding to
    !    the abscissas.
    !
    !    Input, real TVAL, the abscissa value at which the spline
    !    is to be evaluated.  Normally, TDATA(1) <= TVAL <= T(NDATA), and 
    !    the data will be interpolated.  For TVAL outside this range, 
    !    extrapolation will be used.
    !
    !    Output, real YVAL(NDIM), the value of the spline at TVAL.
    !
      implicit none
    !
      integer, parameter :: MAXDIM = 5
      integer ndata
      integer ndim
    !
      integer i
      integer left
      integer order
      integer right
      real tdata(ndata)
      real tval
      real ydata(ndim,ndata)
      real yl(MAXDIM)
      real yr(MAXDIM)
      real yval(ndim)
    !
    !  Check.
    !
      call rvec_order_type ( ndata, tdata, order )
    
      if ( order /= 2 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_OVERHAUSER_VAL - Fatal error!'
        write ( *, '(a)' ) '  The data abscissas are not strictly ascending.'
        stop
      end if
    
      if ( ndata < 3 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_OVERHAUSER_VAL - Fatal error!'
        write ( *, '(a)' ) '  NDATA < 3.'
        stop
      end if
    
      if ( ndim < 1 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_OVERHAUSER_VAL - Fatal error!'
        write ( *, '(a)' ) '  NDIM < 1.'
        stop
      end if
    
      if ( ndim > maxdim ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_OVERHAUSER_VAL - Fatal error!'
        write ( *, '(a)' ) '  NDIM > MAXDIM.'
        stop
      end if
    !
    !  Locate the abscissa interval T(LEFT), T(LEFT+1) nearest to or 
    !  containing TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Evaluate the "left hand" quadratic defined at T(LEFT-1), T(LEFT), T(RIGHT).
    !
      if ( left-1 > 0 ) then
        call parabola_val2 ( ndim, ndata, tdata, ydata, left-1, tval, yl )
      end if
    !
    !  Evaluate the "right hand" quadratic defined at T(LEFT), T(RIGHT), T(RIGHT+1).
    !
      if ( right+1 <= ndata ) then
        call parabola_val2 ( ndim, ndata, tdata, ydata, left, tval, yr )
      end if
    !
    !  Average the quadratics.
    !
      if ( left == 1 ) then
    
        yval(1:ndim) = yr(1:ndim)
    
      else if ( right < ndata ) then
    
        yval(1:ndim) =  ( ( tdata(right) - tval ) * yl(1:ndim) &
          + ( tval - tdata(left) ) * yr(1:ndim) ) / ( tdata(right) - tdata(left) )
    
      else
    
        yval(1:ndim) = yl(1:ndim)
    
      end if
    
      return
    end
    subroutine spline_quadratic_val ( ndata, tdata, ydata, tval, yval, ypval )
    !
    !*******************************************************************************
    !
    !! SPLINE_QUADRATIC_VAL evaluates a quadratic spline at a specific point.
    !
    !
    !  Discussion:
    !
    !    Because of the simple form of a piecewise quadratic spline,
    !    the raw data points ( TDATA(I), YDATA(I)) can be used directly to
    !    evaluate the spline at any point.  No processing of the data
    !    is required.
    !
    !  Modified:
    !
    !    24 October 1999
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    Input, integer NDATA, the number of data points defining the spline.
    !    NDATA should be odd.
    !
    !    Input, real TDATA(NDATA), YDATA(NDATA), the values of the independent
    !    and dependent variables at the data points.  The values of TDATA should
    !    be distinct and increasing.
    !
    !    Input, real TVAL, the point at which the spline is to be evaluated.
    !
    !    Output, real YVAL, YPVAL, the value of the spline and its first
    !    derivative dYdT at TVAL.  YPVAL is not reliable if TVAL is exactly
    !    equal to TDATA(I) for some I.
    !
      implicit none
    !
      integer ndata
    !
      real dif1
      real dif2
      integer left
      integer right
      real t1
      real t2
      real t3
      real tdata(ndata)
      real tval
      real y1
      real y2
      real y3
      real ydata(ndata)
      real ypval
      real yval
    !
      if ( mod ( ndata, 3 ) == 0 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_QUADRATIC_VAL - Fatal error!'
        write ( *, '(a)' ) '  NDATA must be odd.'
        stop
      end if
    !
    !  Find the interval [ TDATA(LEFT), TDATA(RIGHT) ] that contains, or is
    !  nearest to, TVAL.
    !
      call rvec_bracket ( ndata, tdata, tval, left, right )
    !
    !  Force LEFT to be odd.
    !
      if ( mod ( left, 2 ) == 0 ) then
        left = left - 1
      end if
    !
    !  Copy out the three abscissas.
    !
      t1 = tdata(left)
      t2 = tdata(left+1)
      t3 = tdata(left+2)
    
      if ( t1 >= t2 .or. t2 >= t3 ) then
        write ( *, '(a)' ) ' '
        write ( *, '(a)' ) 'SPLINE_QUADRATIC_VAL - Fatal error!'
        write ( *, '(a)' ) '  T1 >= T2 or T2 >= T3.'
        stop
      end if
    !
    !  Construct and evaluate a parabolic interpolant for the data
    !  in each dimension.
    !
      y1 = ydata(left)
      y2 = ydata(left+1)
      y3 = ydata(left+2)
    
      dif1 = ( y2 - y1 ) / ( t2 - t1 )
    
      dif2 = ( ( y3 - y1 ) / ( t3 - t1 ) &
           - ( y2 - y1 ) / ( t2 - t1 ) ) / ( t3 - t2 )
    
      yval = y1 + ( tval - t1 ) * ( dif1 + ( tval - t2 ) * dif2 )
      ypval = dif1 + dif2 * ( 2.0E+00 * tval - t1 - t2 )
    
      return
    end
    subroutine timestamp ( )
    !
    !*******************************************************************************
    !
    !! TIMESTAMP prints the current YMDHMS date as a time stamp.
    !
    !
    !  Example:
    !
    !    May 31 2001   9:45:54.872 AM
    !
    !  Modified:
    !
    !    31 May 2001
    !
    !  Author:
    !
    !    John Burkardt
    !
    !  Parameters:
    !
    !    None
    !
      implicit none
    !
      character ( len = 8 ) ampm
      integer d
      character ( len = 8 ) date
      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
      character ( len = 10 )  time
      integer values(8)
      integer y
      character ( len = 5 ) zone
    !
      call date_and_time ( date, time, zone, 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 ( *, '(a,1x,i2,1x,i4,2x,i2,a1,i2.2,a1,i2.2,a1,i3.3,1x,a)' ) &
        trim ( month(m) ), d, y, h, ':', n, ':', s, '.', mm, trim ( ampm )
    
      return
    end
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  • 原文地址:https://www.cnblogs.com/China3S/p/3526664.html
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