Computation Time with respect to local variable assignment

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Simon Baeuerle
Simon Baeuerle el 3 de En. de 2022
Respondida: Maneet Kaur Bagga el 15 de Sept. de 2023
I came across a funny computation time increase, which was entirely unexpected for me.
For context: I am programming a (single) shooting algorithm in an object oriented toolbox (for an ODE solution branch continuation).
The relevant part of the code is the function shooting_single_auto_fun.
Version 1:
function g = shoot_single_auto_fun(obj,x,mu,DYN)
s = x(1:(end-1),:); %state vector (last entry is the (unknown) base frequency of the solution)
% Call ode45 to compute a curve section. If the algorithm converges (periodic solution is found), the
% curve is closed.
[~,temp] = ode45(@(t,y)FCNwrapper(t,y,@(tau,z)DYN.rhs(tau,z,mu)),[0,2*pi],x,obj.odeOpts);
f = DYN.rhs(0,DYN.x0(1:(end-1),:),mu);
g = temp(end,1:(end-1)).'-s; %The curve is closed, if the first and last point of the curve are identical
g(end+1,:) = f.'*(s-DYN.x0(1:(end-1),:)); %Autonomous system: Frequency is also unknown. Additional equation needed. This is the Poincare condition
end
%For the autonomous case a function wrapper is needed, which adds the
%equation T' = 0, which needs to be added to the function and multiplies the right hand side f of
%the original ODE with T/2*pi
function dzdt = FCNwrapper(t,y,Fcn)
z = y(1:(end-1),:);
base_frqn = y(end,:);
dzdt = 1./base_frqn.*Fcn(t,z);
dzdt(end+1,:) = 0;
end
This function "shoots"/computes one period of a solution curve. The intitial coditions IC (including the base frequency/period duration of the solution) gets adapted by a Newont-type solver (fsolve) until the computed curve is closed (g becomes approximately 0 - a periodic solution is found).
In this context, shoot_single_auto_fun is a method of a general Shooting class and DYN ist an object of class in which all relevant parameters are defined.
An alternative code version reads:
Version 2:
function g = shoot_single_auto_fun(obj,x,mu,DYN)
%This time: allocate the two values
Fcn = DYN.rhs; %function handle to the right side of the first order ODE
x0 = DYN.IC; %Initial condition - gets adapted by the Newton-type solver
s = x(1:(end-1),:);
[~,temp] = ode45(@(t,y)FCNwrapper(t,y,@(tau,z)Fcn(tau,z,mu)),[0,2*pi],x,obj.odeOpts);
f = Fcn(0,x0(1:(end-1),:),mu);
g = temp(end,1:(end-1)).'-s;
g(end+1,:) = f.'*(s-x0(1:(end-1),:)); %This is the Poincare condition
end
%For the autonomous case a function wrapper is needed, which adds the
%equation T' = 0, which needs to be added to the function and multiplies the right hand side f of
%the original ODE with T/2*pi
function dzdt = FCNwrapper(t,y,Fcn)
z = y(1:(end-1),:);
base_frqn = y(end,:);
dzdt = 1./base_frqn.*Fcn(t,z);
dzdt(end+1,:) = 0;
end
Now: version 2 is up to 50% faster, than version 1.
Since I know, which one is faster - the problem is "solved". But I wanna know why!
Does anyone have any idea why this is happening?

Respuestas (1)

Maneet Kaur Bagga
Maneet Kaur Bagga el 15 de Sept. de 2023
Hi Simon,
The difference in performance between Version 1 and Version 2 of the code can be attributed to the way function handles are used in MATLAB as:
  • In Version 1, the function handle "@(tau,z)DYN.rhs(tau,z,mu)" is created inside the "ode45" call. This means that for each time step, a new function handle is created, which incurs some overhead.
  • In Version 2, the function handle "Fcn = DYN.rhs" is assigned outside the "ode45" call. This means that the function handle is created only once, and then reused for each time step. This eliminates the overhead of creating a new function handle repeatedly.
  • By avoiding the creation of multiple function handles in each time step, Version 2 reduces the computational overhead and improves the overall performance of the code. This might be a possible reason for the better efficiency and time complexity of version 2.
Hope this helps!
Thank You
Maneet Bagga

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