# Matlab matrix multiplication speed

I was wondering how can matlab multiply two matrices so fast. When multiplying two NxN matrices, N^3 multiplications are performed. Even with the Strassen Algorithm it takes N^2.8 multiplications, which is still a large number. I was running the following test program:

``````a = rand(2160);
b = rand(2160);
tic;a*b;toc
``````

2160 was used because 2160^3=~10^10 ( a*b should be about 10^10 multiplications)

I got:

``````Elapsed time is 1.164289 seconds.
``````

(I'm running on 2.4Ghz notebook and no threading occurs) which mean my computer made ~10^10 operation in a little more than 1 second.

How this could be??

• Actually, the 'Ma' in Matlab stands for magic. – H.Muster Oct 4 '12 at 7:04
• How do you know no threading occurs? – nneonneo Oct 4 '12 at 7:06
• Are you sure it is computed on the CPU? mathworks.com/discovery/matlab-gpu.html – Ivan Kuckir Oct 4 '12 at 7:12
• Matlab definitely multi-threads. I'm testing it on my machine right now and it's using 4 cores. – Mysticial Oct 4 '12 at 7:13
• Matlab certainly does multi-thread, at least R2011b does with default settings and no interference from the o/s. – High Performance Mark Oct 4 '12 at 7:14

It's a combination of several things:

• The core is heavily optimized with vector instructions.

Here's the numbers on my machine: Core i7 920 @ 3.5 GHz (4 cores)

``````>> a = rand(10000);
>> b = rand(10000);
>> tic;a*b;toc
Elapsed time is 52.624931 seconds.
``````

Task Manager shows 4 cores of CPU usage.

Now for some math:

``````Number of multiplies = 10000^3 = 1,000,000,000,000 = 10^12

Max multiplies in 53 secs =
(3.5 GHz) * (4 cores) * (2 mul/cycle via SSE) * (52.6 secs) = 1.47 * 10^12
``````

So Matlab is achieving about `1 / 1.47 = 68%` efficiency of the maximum possible CPU throughput.

I see nothing out of the ordinary.

• One other 'thing' in the combination (which you are too polite to mention): many programmers have no idea how sophisticated modern CPUs are and just what the designers have done to wring flops out of them. – High Performance Mark Oct 4 '12 at 7:21
• matrix matrix multiplication also performs adds, not only muls. I think that your performance estimates should include 4 FLOPs/cycle via SSE, but twice as many operations. Am I correct? And is your MATLAB not using AVX-enabled BLAS? – angainor Oct 4 '12 at 7:56
• @angainor It's actually one `add` and one `mul` per cycle. Each one can be SSE. However, the add and muls are separate execution units, so you can't "double up" on one if you don't use the other. – Mysticial Oct 4 '12 at 7:59
• Thats correct. Just for the sake of this analysis, adds should be included. The results are the same, just that you made a non-trivial shortcut. Might be hard to understand for someone who does not know what you wrote in the comment. – angainor Oct 4 '12 at 8:01
• The OP was only counting multiplications. I didn't want to confuse him with additions as well (even though they come out to be exactly the same). – Mysticial Oct 4 '12 at 8:02

To check whether you do or not use multi-threading in MATLAB use this command

``````maxNumCompThreads(n)
``````

This sets the number of cores to use to n. Now I have a Core i7-2620M, which has a maximum frequency of 2.7GHz, but it also has a turbo mode with 3.4GHz. The CPU has two cores. Let's see:

``````A = rand(5000);
B = rand(5000);
tic; C=A*B; toc
Elapsed time is 10.167093 seconds.

tic; C=A*B; toc
Elapsed time is 5.864663 seconds.
``````

Let's look at the single CPU results. A*B executes approximately 5000^3 multiplications and additions. So the performance of single-threaded code is

``````5000^3*2/10.8 = 23 GFLOP/s
``````

Now the CPU. 3.4 GHz, and Sandy Bridge can do maximum 8 FLOPs per cycle with AVX:

``````3.4 [Ginstructions/second] * 8 [FLOPs/instruction] = 27.2 GFLOP/s peak performance
``````

So single core performance is around 85% peak, which is to be expected for this problem.

You really need to look deeply into the capabilities of your CPU to get accurate performannce estimates.