# Multiply a 3D matrix with a 2D matrix

Suppose I have an AxBxC matrix `X` and a BxD matrix `Y`.

Is there a non-loop method by which I can multiply each of the C AxB matrices with `Y`?

-
Why would you bother? I look at Gnovice's (correct) solution and it would take me a significant amount of time to understand what that does. I then look at Zaid's and understand instantly. If there is a performance difference, there is a maintance cost to consider also. – MatlabDoug Nov 17 '09 at 13:38
This isn't about performance or readability - just mere curiosity since I knew it was possible to operate on each 3D matrix individually but couldn't figure out how. I know that Gnovice's solution will be much slower than Zaid's "solution" and Amro's solution but, as I said, that's not the point. – Jacob Nov 17 '09 at 13:47
Now you've totally lost me... what is it that you're after? – Zaid Nov 17 '09 at 15:14
A non-loop method by which I can multiply each of the C AxB matrices with Y, e.g. Amro's & GNovice's solutions. – Jacob Nov 17 '09 at 15:33
@Jacob: 1. the solution by gnovice IS NOT slower then that of amro. 2. The solution of gnovice uses cellfun which is a wrapper around a loop. So you can make a function from Zaid's solution, call it prod3D.m and voilà, you have a non-loop method for multiplying X and Y. 3. Do not forget that 80% of software cost is maintenance. – Mikhail Nov 18 '09 at 10:01

You can do this in one line using the functions NUM2CELL to break the matrix `X` into a cell array and CELLFUN to operate across the cells:

``````Z = cellfun(@(x) x*Y,num2cell(X,[1 2]),'UniformOutput',false);
``````

The result `Z` is a 1-by-C cell array where each cell contains an A-by-D matrix. If you want `Z` to be an A-by-D-by-C matrix, you can use the CAT function:

``````Z = cat(3,Z{:});
``````

NOTE: My old solution used MAT2CELL instead of NUM2CELL, which wasn't as succinct:

``````[A,B,C] = size(X);
Z = cellfun(@(x) x*Y,mat2cell(X,A,B,ones(1,C)),'UniformOutput',false);
``````
-
This is exactly what I was looking for. – Jacob Nov 17 '09 at 4:45
With this solution the loop is inside cellfun. But it is nevertheless 10% faster then solution provided by amro (on large matrces, shortly before MATLAB runs out of memory). – Mikhail Nov 17 '09 at 11:37
I'm curious as to the 2 downvotes I got. Whether or not you like the answer, it does answer the question by avoiding explicit use of a for loop. – gnovice Nov 17 '09 at 15:01
Man, who would've thought a simple question like this would be so controversial? – Jacob Nov 17 '09 at 15:42
@Jacob: Yeah, it appears to have spawned some debate. Since I had seen you answering MATLAB questions before, I figured you already knew how to do this using loops (the most straight-forward way). I just assumed you were asking the question out of curiosity for what other ways it could also be done. – gnovice Nov 17 '09 at 15:51

I would think recursion, but that's the only other non- loop method you can do

-
In MATLAB? I think there might be other options .. – Jacob Nov 16 '09 at 23:00

You could "unroll" the loop, ie write out all the multiplications sequentially that would occur in the loop

-
Suppose C is variable .. among other things. – Jacob Nov 16 '09 at 22:46

Nope. There are several ways, but it always comes out in a loop, direct or indirect.

Just to please my curiosity, why would you want that anyway ?

-
Why would I want to do it without a loop? Just old habits. MATLAB is supposed to be loop-optimized now with JITA, but I try to avoid them whenever I can - and I have a strong feeling it is possible to solve this without loops. – Jacob Nov 16 '09 at 23:02
yes, ok, i can understand that. (on the opposite, i sometimes do stuff which can be done without a loop in a loop, since i find it easier to read <-- :( old habits, too :) – Rook Nov 16 '09 at 23:38

Here's a one-line solution (two if you want to split into 3rd dimension):

``````A = 2;
B = 3;
C = 4;
D = 5;

X = rand(A,B,C);
Y = rand(B,D);

%# calculate result in one big matrix
Z = reshape(reshape(permute(X, [2 1 3]), [A B*C]), [B A*C])' * Y;

%'# split into third dimension
Z = permute(reshape(Z',[D A C]),[2 1 3]);
``````

Hence now: `Z(:,:,i)` contains the result of `X(:,:,i) * Y`

Explanation:

The above may look confusing, but the idea is simple. First I start by take the third dimension of `X` and do a vertical concatenation along the first dim:

``````XX = cat(1, X(:,:,1), X(:,:,2), ..., X(:,:,C))
``````

... the difficulty was that `C` is a variable, hence you can't generalize that expression using cat or vertcat. Next we multiply this by `Y`:

``````ZZ = XX * Y;
``````

Finally I split it back into the third dimension:

``````Z(:,:,1) = ZZ(1:2, :);
Z(:,:,2) = ZZ(3:4, :);
Z(:,:,3) = ZZ(5:6, :);
Z(:,:,4) = ZZ(7:8, :);
``````

So you can see it only requires one matrix multiplication, but you have to reshape the matrix before and after.

-
Thanks! I was hoping for a solution along the lines of `bsxfun` but this looks interesting – Jacob Nov 17 '09 at 0:20
there was no need. As you can see from the explanation I added, it was only a matter of preparing the matrix by rearranging its shape, so that a simple multiplication would suffice. – Amro Nov 17 '09 at 17:18
Nice solution but it can produce a memory overflow because of the reshaping – gaborous Jun 14 '14 at 16:36
@user1121352: as was mentioned by the OP in the comments, the motivation here was to explore alternative solutions (for fun) rather than producing faster or more readable code... In production code, I would stick with the straightforward for-loop :) – Amro Jun 14 '14 at 16:52

As a personal preference, I like my code to be as succinct and readable as possible.

Here's what I would have done, though it doesn't meet your 'no-loops' requirement:

``````for m = 1:C

Z(:,:,m) = X(:,:,m)*Y;

end
``````

This results in an A x D x C matrix Z.

And of course, you can always pre-allocate Z to speed things up by using `Z = zeros(A,D,C);`.

-
-1 : because this is not a real solution regardless of your disclaimer. If you have any opinions on succinctness or readability, please leave them as comments. – Jacob Nov 17 '09 at 13:51
+1 because it's also faster than gnovice and amro's fine solutions. – Ramashalanka Mar 9 '10 at 0:28
+1 for readability - but please pre-allocate Z with `Z = zeros([A D C]);`! – Floris Jul 9 '13 at 15:44

• ndmult, by ajuanpi (Juan Pablo Carbajal), 2013, GNU GPL

• 2 arrays
• dim

## Example

`````` nT = 100;
t = 2*pi*linspace (0,1,nT)’;

# 2 experiments measuring 3 signals at nT timestamps
signals = zeros(nT,3,2);
signals(:,:,1) = [sin(2*t) cos(2*t) sin(4*t).^2];
signals(:,:,2) = [sin(2*t+pi/4) cos(2*t+pi/4) sin(4*t+pi/6).^2];

sT(:,:,1) = signals(:,:,1)’;
sT(:,:,2) = signals(:,:,2)’;
G = ndmult (signals,sT,[1 2]);
``````

## Source

``````function M = ndmult (A,B,dim)
dA = dim(1);
dB = dim(2);

# reshape A into 2d
sA = size (A);
nA = length (sA);
perA = [1:(dA-1) (dA+1):(nA-1) nA dA](1:nA);
Ap = permute (A, perA);
Ap = reshape (Ap, prod (sA(perA(1:end-1))), sA(perA(end)));

# reshape B into 2d
sB = size (B);
nB = length (sB);
perB = [dB 1:(dB-1) (dB+1):(nB-1) nB](1:nB);
Bp = permute (B, perB);
Bp = reshape (Bp, sB(perB(1)), prod (sB(perB(2:end))));

# multiply
M = Ap * Bp;

# reshape back to original format
s = [sA(perA(1:end-1)) sB(perB(2:end))];
M = squeeze (reshape (M, s));
endfunction
``````
-

I'm approaching the exact same issue, with an eye for the most efficient method. There are roughly three approaches that i see around, short of using outside libraries (i.e., mtimesx):

1. Loop through slices of the 3D matrix
2. repmat-and-permute wizardry
3. cellfun multiplication

I recently compared all three methods to see which was quickest. My intuition was that (2) would be the winner. Here's the code:

``````% generate data
A = 20;
B = 30;
C = 40;
D = 50;

X = rand(A,B,C);
Y = rand(B,D);

% ------ Approach 1: Loop (via @Zaid)
tic
Z1 = zeros(A,D,C);
for m = 1:C
Z1(:,:,m) = X(:,:,m)*Y;
end
toc

% ------ Approach 2: Reshape+Permute (via @Amro)
tic
Z2 = reshape(reshape(permute(X, [2 1 3]), [A B*C]), [B A*C])' * Y;
Z2 = permute(reshape(Z2',[D A C]),[2 1 3]);
toc

% ------ Approach 3: cellfun (via @gnovice)
tic
Z3 = cellfun(@(x) x*Y,num2cell(X,[1 2]),'UniformOutput',false);
Z3 = cat(3,Z3{:});
toc
``````

All three approaches produced the same output (phew!), but, surprisingly, the loop was the fastest:

``````Elapsed time is 0.000418 seconds.
Elapsed time is 0.000887 seconds.
Elapsed time is 0.001841 seconds.
``````

These differences become more dramatic with larger data. But with much bigger data, (3) beats (2). In all cases, the loop method is best.

``````% pretty big data...
A = 200;
B = 300;
C = 400;
D = 500;
Elapsed time is 0.373831 seconds.
Elapsed time is 0.638041 seconds.
Elapsed time is 0.724581 seconds.

% even bigger....
A = 200;
B = 200;
C = 400;
D = 5000;
Elapsed time is 4.314076 seconds.
Elapsed time is 11.553289 seconds.
Elapsed time is 5.233725 seconds.
``````

Besides its efficiency gains, the loop is also best in terms of readability. Loop away!

-