You can do this fully vectorized like so:

```
n = numel(xl);
[X, Y] = meshgrid(1:n,1:n);
Ix = X(:)
Iy = Y(:)
reshape(sqrt((xl(Ix)-xl(Iy)).^2+(yl(Ix)-yl(Iy)).^2+(zl(Ix)-zl(Iy)).^2), n, n);
```

If you look at `Ix`

and `Iy`

(try it for like a 3x3 dataset), they make every combination of linear indexes possible for each of your matrices. Now you can just do each subtraction in one shot!

However mixing the suggestions of shoelzer and Jost will give you an almost identical performance performance boost:

```
n = 50;
xl = rand(n,1);
yl = rand(n,1);
zl = rand(n,1);
tic
for t = 1:100
distanceMatrix = zeros(n); %// Preallocation
for i=1:n
for j=min(i+1,n):n %// Taking advantge of symmetry
distanceMatrix(i,j) = sqrt((xl(i)-xl(j))^2+(yl(i)-yl(j))^2+(zl(i)-zl(j))^2);
end
end
d1 = distanceMatrix + distanceMatrix'; %'
end
toc
%// Vectorized solution that creates linear indices using meshgrid
tic
for t = 1:100
[X, Y] = meshgrid(1:n,1:n);
Ix = X(:);
Iy = Y(:);
d2 = reshape(sqrt((xl(Ix)-xl(Iy)).^2+(yl(Ix)-yl(Iy)).^2+(zl(Ix)-zl(Iy)).^2), n, n);
end
toc
```

Returns:

```
Elapsed time is 0.023332 seconds.
Elapsed time is 0.024454 seconds.
```

But if I change `n`

to `500`

then I get

```
Elapsed time is 1.227956 seconds.
Elapsed time is 2.030925 seconds.
```

Which just goes to show that you should always bench mark solutions in Matlab before writing off loops as slow! In this case, depending on the scale of your solution, loops could be significantly faster.

`pdist`

the distances are only calculated once. Then one can use`squareform`

to build the symmetric distance matrix. See my answer here. You can also type`edit squareform`

to see the code used (no`for`

loop).`pdist`

(a native C function) and`squareform`

are the only way to go, unless you want to try compiling mex code for a bit more speed.