1

I need to use a Fortran code to solve stochastic differential equation (SDE). I looked at the famous Fortran code website by Burkardt,

https://people.math.sc.edu/Burkardt/f_src/stochastic_rk/stochastic_rk.html

I particular looked at the rk4_ti_step subroutine in stochastic_rk.f90 code,

https://people.math.sc.edu/Burkardt/f_src/stochastic_rk/stochastic_rk.f90

My optimized version is below,

subroutine rk4_ti_step_mod ( x, t, h, q, fi, gi, seed, xstar )
use random  
implicit none
real ( kind = 8 ), external :: fi
real ( kind = 8 ), external :: gi
real ( kind = 8 ) h
real ( kind = 8 ) k1
real ( kind = 8 ) k2
real ( kind = 8 ) k3
real ( kind = 8 ) k4
real ( kind = 8 ) q
real ( kind = 8 ) r8_normal_01
integer ( kind = 4 ) seed
real ( kind = 8 ) t
real ( kind = 8 ) t1
real ( kind = 8 ) t2
real ( kind = 8 ) t3
real ( kind = 8 ) t4
real ( kind = 8 ) w1
real ( kind = 8 ) w2
real ( kind = 8 ) w3
real ( kind = 8 ) w4
real ( kind = 8 ) x
real ( kind = 8 ) x1
real ( kind = 8 ) x2
real ( kind = 8 ) x3
real ( kind = 8 ) x4
real ( kind = 8 ) xstar   
real ( kind = 8 ) :: qoh
real ( kind = 8 ) :: normal(4)
real ( kind = 8 ), parameter :: a21 = 2.71644396264860D+00 &
,a31 = - 6.95653259006152D+00 &
,a32 =   0.78313689457981D+00 &
,a41 =   0.0D+00 &
,a42 =   0.48257353309214D+00 &
,a43 =   0.26171080165848D+00 &
,a51 =   0.47012396888046D+00 &
,a52 =   0.36597075368373D+00 &
,a53 =   0.08906615686702D+00 &
,a54 =   0.07483912056879D+00 &
,q1 =   2.12709852335625D+00 &
,q2 =   2.73245878238737D+00 &
,q3 =  11.22760917474960D+00 &
,q4 =  13.36199560336697D+00
real ( kind = 8 ), parameter, dimension(4) :: qarray = [ 2.12709852335625D+00 &
    ,2.73245878238737D+00 &
    ,11.22760917474960D+00 &
    ,13.36199560336697D+00 ]
real ( kind = 8 ) :: warray(4)
integer (kind = 4) :: i
qoh = q / h
normal = gaussian(4) 
do i =1,4
    warray(i) = normal(i)*sqrt(qarray(i)*qoh)
enddo
t1 = t
x1 = x
k1 = h * ( fi ( x1 ) + gi ( x1 ) * warray(1) ) 
t2 = t1 + a21 * h
x2 = x1 + a21 * k1
k2 = h * ( fi ( x2 ) + gi ( x2 ) * warray(2) )
t3 = t1 + ( a31  + a32 )* h
x3 = x1 + a31 * k1 + a32 * k2
k3 = h * ( fi ( x3 ) + gi ( x3 ) * warray(3) )
t4 = t1 + ( a41  + a42 + a43 ) * h
x4 = x1 + a41 * k1 + a42 * k2
k4 = h * ( fi ( x4 ) + gi ( x4 ) * warray(4) )
xstar = x1 + a51 * k1 + a52 * k2 + a53 * k3 + a54 * k4
return
end

Note that I use my module of random number, and gaussian is my random number function, this part does not matter.

I just wonder,

  1. Can anyone give some suggestions as to can the code be further optimized?
  2. Does anyone know what is the best/fastest SDE Fortran subroutine? Or what algorithm is the best?

Thank you very much!

17
  • 1
    A few changes should be made, but none will likely improve performance.
    – steve
    Sep 12 at 5:10
  • 1
    To be honest there's not a lot that can be said WRT optimisation without seeing a whole code, or at the very least the functions referenced in the above routine. But I would note you could avoid a small number of sqrts by calculating Sqrt( qoh ) once, and storing the sqrt of qarray in a parameter (making reasonable assumptions about the routine gaussian() ). But there is so little work shown here I doubt it will change much.
    – Ian Bush
    Sep 12 at 7:37
  • 2
    Stylistically note Real( 8 ) and Integer( 4 ) are not portable, not guaranteed to be supported by your compiler, and may not do what you expect them to do. See stackoverflow.com/questions/838310/fortran-90-kind-parameter for better ways - personally I would recommend using iso_fortran_env noted in the comments. External subprograms are also not best practice nowadays, stick them in modules.
    – Ian Bush
    Sep 12 at 7:40
  • 4
    The first step of optimising your code should always be to profile your code, so you know what parts of the code are taking the most time. Without this information (or a minimal reproducible example) there's not a lot we can say to help. Sep 12 at 8:08
  • 1
    Having said that, I wonder why you are using many scalar variables rather than vectors and matrices? If you roll e.g. x1 to x4 and k1 to k4 into vectors x and k (stored as arrays in Fortran) then you can write things like k = h * (fi(x) + gi(x)*warray), which will let the compiler do things like vectorise your code. Sep 12 at 8:12
2

The interdependence of x and c means you can't turn as much into linear algebra as I first thought, but I'd still expect some speedup by grouping everything into appropriate arrays as:

subroutine rk4_ti_step_mod ( x, t, h, q, fi, gi, seed, xstar )
  use random  
  implicit none
  
  integer, parameter :: dp = selected_real_kind(15,307)
  integer, parameter :: ip = selected_int_kind(9)
  
  real(dp), intent(in) :: x
  real(dp), intent(in) :: t  
  real(dp), intent(in) :: h
  real(dp), intent(in) :: q
  real(dp), external :: fi
  real(dp), external :: gi
  integer(ip), intent(in) :: seed
  real(dp), intent(out) :: xstar

  real(dp), parameter :: as(4,5) = reshape([ &
     &  0.0_dp,              0.0_dp,              0.0_dp,              0.0_dp, &
     &  2.71644396264860_dp, 0.0_dp,              0.0_dp,              0.0_dp, &
     & -6.95653259006152_dp, 0.78313689457981_dp, 0.0_dp,              0.0_dp, &
     &  0.0_dp,              0.48257353309214_dp, 0.26171080165848_dp, 0.0_dp, &
     &  0.47012396888046_dp, 0.36597075368373_dp, 0.08906615686702_dp, 0.07483912056879_dp &
     & ], [4,5])
  real(dp), parameter :: qs(4) = [ &
     &  2.12709852335625_dp, &
     &  2.73245878238737_dp, &
     & 11.22760917474960_dp, &
     & 13.36199560336697_dp ]

  real(dp) :: ks(4)
  real(dp) :: r8_normal_01
  real(dp) :: ts(4)
  real(dp) :: ws(4)
  real(dp) :: xs(4)
  real(dp) :: normal(4)
  real(dp) :: warray(4)
  
  normal = gaussian(4) 
  warray = normal*sqrt(qs)*sqrt(q/h)
  
  do i=1,4
    ts(i) = t + sum(as(:i-1,i)) * h
    xs(i) = x + dot_product(as(:i-1,i), ks(:i-1))
    ks(i) = h * (fi(xs(i)) + gi(xs(i))*warray(i))
  enddo
 
  xstar = x + dot_product(as(:,5), ks)
end subroutine

although it's difficult to tell without knowing anything about fi and gi.

Also note you don't seem to be using the t1 to t4 variables.

4
  • Thank you very much! The fi = -x, gi=1.0. Indeed, this code was initially written by John Burcardt. In the rk4_ti subroutine (ti means time invariant), t1 to t4 is not really used. I guess he wrote here is for illustration. But in the rk4_tv subroutine (tv means time variant), t1 to t4 are used.
    – CRquantum
    Sep 12 at 20:28
  • 1
    I checked, your version the speed is the same as my version. But yours is more concise. Thank you very much!
    – CRquantum
    Sep 12 at 20:35
  • May I ask a stupid question, I see your nice code have things like, ks(:i-1). However, when k=1, it looks like it will access ks(:0) which is out of the range. However it does not really happen. Therefore by doing ks(:i-1), is it automatically begin from ks(:i-1) where i-1 >= 1 ?
    – CRquantum
    Sep 13 at 4:10
  • ks(:0) is just an empty slice, equivalent to []. If an optimising compiler unrolls the loop, it should be able to just drop the sum([]) and dot_product([],[]) lines. Sep 13 at 7:16

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