program main !*****************************************************************************80 ! !! disk01_positive_monte_carlo_test() tests disk01_positive_monte_carlo(). ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 05 May 2016 ! ! Author: ! ! John Burkardt ! implicit none call timestamp ( ) write ( *, '(a)' ) ' ' write ( *, '(a)' ) 'disk01_positive_monte_carlo_test():' write ( *, '(a)' ) ' Fortran90 version' write ( *, '(a)' ) ' Test disk01_positive_monte_carlo().' call test01 ( ) ! ! Terminate. ! write ( *, '(a)' ) ' ' write ( *, '(a)' ) 'disk01_positive_monte_carlo_test():' write ( *, '(a)' ) ' Normal end of execution.' write ( *, '(a)' ) ' ' call timestamp ( ) stop 0 end subroutine test01 ( ) !*****************************************************************************80 ! !! test01() uses disk01_positive_sample() with an increasing number of points. ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 02 January 2014 ! ! Author: ! ! John Burkardt ! implicit none integer, parameter :: rk = kind ( 1.0D+00 ) real ( kind = rk ), parameter :: r8_pi = 3.141592653589793D+00 real ( kind = rk ) disk01_positive_area integer e(2) real ( kind = rk ) err real ( kind = rk ) exact integer i integer j integer n real ( kind = rk ) q real ( kind = rk ), allocatable :: value(:) real ( kind = rk ), allocatable :: x(:,:) write ( *, '(a)' ) '' write ( *, '(a)' ) 'test01():' write ( *, '(a)' ) ' Use disk01_positive_sample() to estimate integrals' write ( *, '(a)' ) ' in the unit quarter disk.' do i = 0, 4 e(1) = i do j = 0, 4 - e(1) e(2) = j call disk01_positive_monomial_integral ( e, exact ) write ( *, '(a)' ) '' write ( *, '(a,i1,a,i1)' ) ' Estimate integral of X^', e(1), 'Y^', e(2) write ( *, '(a)' ) '' write ( *, '(a)' ) ' N Estimate Error' write ( *, '(a)' ) '' n = 1 do while ( n <= 65536 ) allocate ( x(1:2,1:n) ) call disk01_positive_sample ( n, x ) allocate ( value(1:n) ) call monomial_value ( 2, n, e, x, value ) q = disk01_positive_area ( ) * sum ( value(1:n) ) / real ( n, kind = rk ) err = abs ( q - exact ) write ( *, '(2x,i8,2x,g14.6,2x,e10.2)' ) n, q, err deallocate ( value ) deallocate ( x ) n = 2 * n end do write ( *, '(2x,a8,2x,g14.6,2x,e10.2)' ) ' Exact:', exact, 0.0D+00 end do end do return end subroutine timestamp ( ) !*****************************************************************************80 ! !! timestamp() prints the current YMDHMS date as a time stamp. ! ! Example: ! ! 31 May 2001 9:45:54.872 AM ! ! Licensing: ! ! This code is distributed under the MIT license. ! ! Modified: ! ! 18 May 2013 ! ! Author: ! ! John Burkardt ! implicit none character ( len = 8 ) ampm integer d integer h integer m integer mm character ( len = 9 ), parameter, dimension(12) :: month = (/ & 'January ', 'February ', 'March ', 'April ', & 'May ', 'June ', 'July ', 'August ', & 'September', 'October ', 'November ', 'December ' /) integer n integer s integer values(8) integer y call date_and_time ( values = values ) y = values(1) m = values(2) d = values(3) h = values(5) n = values(6) s = values(7) mm = values(8) if ( h < 12 ) then ampm = 'AM' else if ( h == 12 ) then if ( n == 0 .and. s == 0 ) then ampm = 'Noon' else ampm = 'PM' end if else h = h - 12 if ( h < 12 ) then ampm = 'PM' else if ( h == 12 ) then if ( n == 0 .and. s == 0 ) then ampm = 'Midnight' else ampm = 'AM' end if end if end if write ( *, '(i2,1x,a,1x,i4,2x,i2,a1,i2.2,a1,i2.2,a1,i3.3,1x,a)' ) & d, trim ( month(m) ), y, h, ':', n, ':', s, '.', mm, trim ( ampm ) return end