# Matlab tic toc accuracy

I'm measuring some code in loop

``````fps = zeros(1, 100);
for i=1:100

t = tic
I = fetch_image_from_source(); % function to get image
fps(i) = 1./ toc(t);

end
plot(fps);
``````

And I get average 50 fps.

Then I'd like to add `imshow()` to my code. I understand that `imshow` is very slow, but I won't include `imshow` inside `tic-toc` commands:

``````fps = zeros(1, 100);
figure;
for i=1:100

t = tic
I = fetch_image_from_source(); % function to get image
fps(i) = 1./ toc(t);

imshow(I); drawnow;

end
plot(fps);
``````

And I get fps about 20%-30% slower. Why does it happen? Because `imshow()` is outside `tic-toc`

-
What version of MATLAB are you using? Are these results consistent? If so, try disabling JIT acceleration with `feature accel off` before running this and see if it's reproducible. –  Eitan T Sep 2 '13 at 14:03
Also try using FRAPS for frame rate measurements. –  Mikhail Sep 3 '13 at 0:30

Here is a matlab's doc about time in general and how elapsed time was and is currently measured in matlab. We can read that "tic and toc [offers] the highest accuracy and most predictable behavior". I think it is valid statement.

The drop of performance observed here is not due to a bad measure of elapsed time, and not related either to the use of `imshow` or `drawnow` functions. I will argue that it is related to a cache system.

The figure below displays the results of four tests, each of them having its own `tic/toc` baseline measure (plotted in blue) for 100 iterations. The green line shows the performance in different conditions:

``````(1)    for ii=1:100
t = tic;                %single tic/toc
fps(ii,2) = 1./toc(t);
rand(1000);             %extra function outside tic/toc
end
``````

As reported in your question, we can observe a slower frame per second (FPS; I would say 30%) despite `rand` being outside of the tic/toc block. The extra function can be of any type (`plot`, `surf`, `imshow`, `sum`), you will always observe a performance drop.

``````(2)    for ii=1:100
t = tic;                %first tic/toc
fps(ii,2) = 1./toc(t);
t = tic;                %second tic/toc
fps(ii,2) = 1./toc(t);
rand(1000);             %extra function outside tic/toc
end
``````

In the second subplot, the tic/toc block is repeated twice. The `fps` measurement is therefore executed two times and only the second measure is kept. We see that the performance drop is not there anymore - just like the first tic/toc call prepared the second one (warm-up). I interpret this in term of cache: the instructions and/or data are executed and then kept in a low level memory - the second call is faster.

``````(3)    for ii=1:100
t = tic;                     %first tic/toc
fps(ii,2) = 1./toc(t);
for ij = 1:10000             %10,000 extra tic/toc
tic;
tmp = toc;
end
end
``````

The third subplot used 10,000 tic/toc as an extra function in a single call scenario. You can see the the performance is nearly identical. The whole set of data/instructions in this subplot is only related to tic/toc - again, with a fast cache access.

``````(4)    for ii=1:100               %first tic/toc block
t = tic;
fps(ii,1) = 1./toc(t);
end
for ii=1:100               %second tic/toc block
t = tic;
fps(ii,2) = 1./toc(t);
end
``````

Finally, the fourth subplot shows two consecutive block of tic/toc calls. We can see that the second one performs better than the first one (a warm-up effect).

The overall pattern shown here is not related to `imshow`, does not depend on `JIT` of `accel`, but depends only on successive calls to a particular function. I interpret this in terms of cache, but I lack some kind of formal evidence.

Here are the plots

and the code

``````%% EXTRA FUNCTION (single call)
fps = zeros(2, 100);

% first case: 100 tic/toc
for ii=1:100
t = tic;
fps(ii,1) = 1./toc(t);
end

%second case: 100 tic/toc + additional function
for ii=1:100

t = tic;
fps(ii,2) = 1./toc(t);

% graph or scalar functions (uncomment to test)
%drawnow;
%plot(1:10)
rand(1000);
%ones(1000, 1000);
%sum(1:1000000);
%diff(1:1000000);
end

h = figure('Color','w','Position',[10 10 600 800]);

subplot(4,1,1);
plot(fps); legend({'tic/toc only','extra function'});
ylabel('FPS');
title('extra function, single call','FontSize',14);
set(gca,'FontSize',14, 'YLim', [0 3.5e5]);

%% EXTRA FUNCTION (double call)
fps = zeros(2, 100);

% first case: 100 tic/toc
for ii=1:100
t = tic;
fps(ii,1) = 1./toc(t);
end

%second case: 100 tic/toc + additional function (except tic/toc)
for ii=1:100

%first call
t = tic;
fps(ii,2) = 1./toc(t);

%second call (identical to first)
t = tic;
fps(ii,2) = 1./toc(t);

rand(1000);
end

subplot(4,1,2);
plot(fps); legend({'tic/toc only','extra function'});
ylabel('FPS');
title('extra function, double call','FontSize',14);
set(gca,'FontSize',14, 'YLim', [0 3.5e5]);

%% EXTRA FUNCTION (double call)
fps = zeros(2, 100);

% first case: 100 tic/toc
for ii=1:100
t = tic;
fps(ii,1) = 1./toc(t);
end

%second case: 100 tic/toc + 10000 tic/toc
for ii=1:100

t = tic;
fps(ii,2) = 1./toc(t);

for ij = 1:10000
tic;
tmp = toc;
end

end

subplot(4,1,3);
plot(fps); legend({'tic/toc','extra tic/toc'});
ylabel('FPS');
title('Identical function calls','FontSize',14);
set(gca,'FontSize',14, 'YLim', [0 3.5e5]);

%% TIC/TOC call twice
fps = zeros(2, 100);

% first case: 100 tic/toc
for ii=1:100
t = tic;
fps(ii,1) = 1./toc(t);
end

for ii=1:100
t = tic;
fps(ii,2) = 1./toc(t);
end

subplot(4,1,4);
plot(fps); legend({'tic/toc (1)','tic/toc (2)'});
ylabel('FPS');
title('tic/toc twice','FontSize',14);
set(gca,'FontSize',14, 'YLim', [0 3.5e5]);
``````
-
+1: Interesting. I wonder if these tests be affected by `feature accel off`. –  Eitan T Sep 3 '13 at 11:39
@Eitan T - these patterns are not influenced by `feature('accel','off');` and `feature('JIT','off');`. But there might be another reason for the performance drop, as I don't have a method to say "instructions/data are stored in cache" - we only see the by-products here. –  macduf Sep 3 '13 at 11:49
I understand that. Just shootin' in the dark here. You got points for the effort, nevertheless. –  Eitan T Sep 3 '13 at 12:14

The number of computational threads used by MATLAB is based on the value of `maxNumCompThreads`. If you set this to `1`, then both cases should theoretically yield the same fps.

You can do achieve this as:

``````LASTN = maxNumCompThreads(N);
``````

Here `N` ought to be `1` and `LASTN` will give you the previous maximum number of computational threads, which may be useful later in case you want to reset the preference.

-
So why would this affect one case and not the other? –  Eitan T Sep 2 '13 at 11:23
@EitanT: I don't have access to MATLAB to confirm right now, but I'm guessing that the `imshow` may be taken care of by additional threads coming into play. –  Roney Michael Sep 2 '13 at 11:26
I still don't understand how that would account for the slowdown caused by adding `imshow`... –  Eitan T Sep 2 '13 at 11:30
From documentation of this method: `"Note: maxNumCompThreads will be removed in a future version. You can set the -singleCompThread option when starting MATLAB to limit MATLAB to a single computational thread. By default, MATLAB makes use of the multithreading capabilities of the computer on which it is running."` And when I call this function, it returns 4. –  Evghenii Sep 2 '13 at 11:39
@EitanT: Just guessing here, but it could be that the JIT is smart enough (or stupid enough) to offload the `imshow` to a separate thread, and the call to `fetch_image_from_source` to a separate thread, but keeps the `tic/toc` in the main thread. This would imply that the overhead of starting the thread and transferring the data for the `fetch_image_from_source`-thread adds up on each iteration. –  Rody Oldenhuis Sep 2 '13 at 13:05