# MATLAB: How to vector-multiply two arrays of matrices?

I have two 3-dimensional arrays, the first two dimensions of which represent matrices and the last one counts through a parameterspace, as a simple example take

``````A = repmat([1,2; 3,4], [1 1 4]);
``````

(but assume `A(:,:,j)` is different for each `j`). How can one easily perform a per-`j` matrix multiplication of two such matrix-arrays `A` and `B`?

``````C = A; % pre-allocate, nan(size(A,1), size(B,2)) would be better but slower
for jj = 1:size(A, 3)
C(:,:,jj) = A(:,:,jj) * B(:,:,jj);
end
``````

certainly does the job, but if the third dimension is more like 1e3 elements this is very slow since it doesn't use MATLAB's vectorization. So, is there a faster way?

-
Have you actually timed the loop? For resent Matlab versions it might be quite fast. How much faster you expect the 'vectorized' version to bee? Thanks –  eat Jul 5 '11 at 10:19
@eat: for 1000 parameters, it's a factor of 7 (MATLAB R2010a) and I'm using this inside an optimization loop, so it's important - I found a solution now, I'll post it after lunch –  Tobias Kienzler Jul 5 '11 at 10:30
possible duplicate of Multiply a 3D matrix with a 2D matrix –  gnovice Jul 5 '11 at 14:58
@TobiasKienzler: I assume you are pre-allocating the matrix `C`?? –  Amro Jul 5 '11 at 16:45

Here is my benchmark test comparing the methods mentioned in @TobiasKienzler answer. I am using the TIMEIT function to get more accurate timings.

``````function [t,v] = matrixMultTest()
n = 2; m = 2; p = 1e5;
A = rand(n,m,p);
B = rand(m,n,p);

%# time functions
t = zeros(5,1);
t(1) = timeit( @() func1(A,B,n,m,p) );
t(2) = timeit( @() func2(A,B,n,m,p) );
t(3) = timeit( @() func3(A,B,n,m,p) );
t(4) = timeit( @() func4(A,B,n,m,p) );
t(5) = timeit( @() func5(A,B,n,m,p) );

%# check the results
v = cell(5,1);
v{1} = func1(A,B,n,m,p);
v{2} = func2(A,B,n,m,p);
v{3} = func3(A,B,n,m,p);
v{4} = func4(A,B,n,m,p);
v{5} = func5(A,B,n,m,p);
assert( isequal(v{:}) )
end

%# simple FOR-loop
function C = func1(A,B,n,m,p)
C = zeros(n,n,p);
for k=1:p
C(:,:,k) = A(:,:,k) * B(:,:,k);
end
end

%# ARRAYFUN
function C = func2(A,B,n,m,p)
C = arrayfun(@(k) A(:,:,k)*B(:,:,k), 1:p, 'UniformOutput',false);
C = cat(3, C{:});
end

%# NUM2CELL/FOR-loop/CELL2MAT
function C = func3(A,B,n,m,p)
Ac = num2cell(A, [1 2]);
Bc = num2cell(B, [1 2]);
C = cell(1,1,p);
for k=1:p
C{k} = Ac{k} * Bc{k};
end;
C = cell2mat(C);
end

%# NUM2CELL/CELLFUN/CELL2MAT
function C = func4(A,B,n,m,p)
Ac = num2cell(A, [1 2]);
Bc = num2cell(B, [1 2]);
C = cellfun(@mtimes, Ac, Bc, 'UniformOutput', false);
C = cell2mat(C);
end

%# Loop Unrolling
function C = func5(A,B,n,m,p)
C = zeros(n,n,p);
C(1,1,:) = A(1,1,:).*B(1,1,:) + A(1,2,:).*B(2,1,:);
C(1,2,:) = A(1,1,:).*B(1,2,:) + A(1,2,:).*B(2,2,:);
C(2,1,:) = A(2,1,:).*B(1,1,:) + A(2,2,:).*B(2,1,:);
C(2,2,:) = A(2,1,:).*B(1,2,:) + A(2,2,:).*B(2,2,:);
end
``````

The results:

``````>> [t,v] = matrixMultTest();
>> t
t =
0.63633      # FOR-loop
1.5902       # ARRAYFUN
1.1257       # NUM2CELL/FOR-loop/CELL2MAT
1.0759       # NUM2CELL/CELLFUN/CELL2MAT
0.05712      # Loop Unrolling
``````

As I explained in the comments, a simple FOR-loop is the best solution (short of loop unwinding in the last case, which is only feasible for these small 2-by-2 matrices).

-
thanks, I didn't know about `timeit` –  Tobias Kienzler Jul 14 '11 at 4:33

I did some timing tests now, the fastest way for 2x2xN turns out to be calculating the matrix elements:

``````C = A;
C(1,1,:) = A(1,1,:).*B(1,1,:) + A(1,2,:).*B(2,1,:);
C(1,2,:) = A(1,1,:).*B(1,2,:) + A(1,2,:).*B(2,2,:);
C(2,1,:) = A(2,1,:).*B(1,1,:) + A(2,2,:).*B(2,1,:);
C(2,2,:) = A(2,1,:).*B(1,2,:) + A(2,2,:).*B(2,2,:);
``````

In the general case it turns out the for loop is actually the fastest (don't forget to pre-allocate C though!).

Should one already have the result as cell-array of matrices though, using cellfun is the fastest choice, it is also faster than looping over the cell elements:

``````C = cellfun(@mtimes, A, B, 'UniformOutput', false);
``````

However, having to call num2cell first (`Ac = num2cell(A, [1 2])`) and `cell2mat` for the 3d-array case wastes too much time.

Here's some timing I did for a random set of 2 x 2 x 1e4:

`````` array-for: 0.057112
arrayfun : 0.14206
num2cell : 0.079468
cell-for : 0.033173
cellfun  : 0.025223
cell2mat : 0.010213
explicit : 0.0021338
``````

Explicit refers to using direct calculation of the 2 x 2 matrix elements, see bellow. The result is similar for new random arrays, `cellfun` is the fastest if no `num2cell` is required before and there is no restriction to 2x2xN. For general 3d-arrays looping over the third dimension is indeed the fastest choice already. Here's the timing code:

``````n = 2;
m = 2;
l = 1e4;

A = rand(n,m,l);
B = rand(m,n,l);

% naive for-loop:
tic
%Cf = nan(n,n,l);
Cf = A;
for jl = 1:l
Cf(:,:,jl) = A(:,:,jl) * B(:,:,jl);
end;
disp([' array-for: ' num2str(toc)]);

% using arrayfun:
tic
Ca = arrayfun(@(k) A(:,:,k)*B(:,:,k), 1:size(A,3), 'UniformOutput',false);
Ca = cat(3,Ca{:});
disp([' arrayfun : ' num2str(toc)]);

tic
Ac = num2cell(A, [1 2]);
Bc = num2cell(B, [1 2]);
disp([' num2cell : ' num2str(toc)]);

% cell for-loop:
tic
Cfc = Ac;
for jl = 1:l
Cfc{jl} = Ac{jl} * Bc{jl};
end;
disp([' cell-for : ' num2str(toc)]);

% using cellfun:
tic
Cc = cellfun(@mtimes, Ac, Bc, 'UniformOutput', false);
disp([' cellfun  : ' num2str(toc)]);

tic
Cc = cell2mat(Cc);
disp([' cell2mat : ' num2str(toc)]);

tic
Cm = A;
Cm(1,1,:) = A(1,1,:).*B(1,1,:) + A(1,2,:).*B(2,1,:);
Cm(1,2,:) = A(1,1,:).*B(1,2,:) + A(1,2,:).*B(2,2,:);
Cm(2,1,:) = A(2,1,:).*B(1,1,:) + A(2,2,:).*B(2,1,:);
Cm(2,2,:) = A(2,1,:).*B(1,2,:) + A(2,2,:).*B(2,2,:);
disp([' explicit : ' num2str(toc)]);

disp(' ');
``````
-
Clever indeed. You may indeed need later to accept your own answer ;). Thanks –  eat Jul 5 '11 at 11:42
Don't be fooled by CELLFUN, there is a hidden loop inside... So its really simpler to just write: `C = arrayfun(@(k) A(:,:,k)*B(:,:,k), 1:size(A,3), 'UniformOutput',false); C = cat(3,C{:});`. Both are not really better than the original for-loop! –  Amro Jul 5 '11 at 16:43
@Amro: you're right, I did timing tests now. `arrayfun` was almost exactly as fast/slow as `num2cell + cellfun + cell2mat`, turns out the original for-loop is really the fastest (and yes, I pre-allocated `C`) unless you already have cells –  Tobias Kienzler Jul 12 '11 at 11:43
@TobiasKienzler: I posted some benchmark tests of my own... As expected, FOR-loops are pretty fast, especially with the Just-in-Time (JIT) accelerator improvements in recent versions of MATLAB –  Amro Jul 14 '11 at 0:47

One technique would be to create a 2Nx2N sparse matrix and embed on the diagonal the 2x2 matrices, for both A and B. Do the product with sparse matrices and take the result with slightly clever indexing and reshape it to 2x2xN.

But I doubt this will be faster than simple looping.

-
good idea, though your doubt is probably correct. In case you're interested, I found a solution using cellfun –  Tobias Kienzler Jul 5 '11 at 11:20

An even faster method, in my experience, is to use dot multiplication and summation over the three-dimensional matrix. The following function, function z_matmultiply(A,B) multiplies two three dimensional matrices which have the same depth. Dot multiplication is done in a manner that is as parallel as possible, thus you might want to check the speed of this function and compare it to others over a large number of repetitions.

``````function C = z_matmultiply(A,B)

[ma,na,oa] = size(A);
[mb,nb,ob] = size(B);

%preallocate the output as we will do a loop soon
C = zeros(ma,nb,oa);

%error message if the dimensions are not appropriate
if na ~= mb || oa ~= ob
fprintf('\n z_matmultiply warning: Matrix Dimmensions Inconsistent \n')
else

% if statement minimizes for loops by looping the smallest matrix dimension
if ma > nb
for j = 1:nb
Bp(j,:,:) = B(:,j,:);
C(:,j,:) = sum(A.*repmat(Bp(j,:,:),[ma,1]),2);
end
else
for i = 1:ma
Ap(:,i,:) = A(i,:,:);
C(i,:,:) = sum(repmat(Ap(:,i,:),[1,nb]).*B,1);
end
end

end
``````
-
you can use `bsxfun` instead of `repmat`. –  Shai Oct 22 '13 at 15:09
–  Shai Oct 22 '13 at 15:10