## Making your approach work:

First we fix your original approach:

```
a = exprnd(1,10000, 1);
x = 0:0.02:10;
count = zeros(size(x)); %%// <= Preallocate the count-vector
for i = 1:length(x);
%%// <= removed the line "count = 0"
for j = 1:length(a);
if (a(j) <= x(i))
count(i) = count(i) + 1; %%// <= Changed count to count(i)
end
end
end
```

This will make your approach work. If you want to compute this for relatively large vectors `a`

and `x`

, this will be quite slow, as the overall complexity is `O(n^2)`

. (Assuming `n==length(x)==length(a)`

.)

You could use a different approach for faster runtimes:

## Approach of complexity `O(n*log(n))`

using `sort`

:

Here is an algorithm of complexity `O(n*log(n))`

instead of `O(n^2)`

.
It is based on Matlab's `sort`

being stable and the positions being returned. Assume `x`

is sorted, if you then sort `[a(:); x(:)]`

, the new position of `x(1)`

will be `1`

plus the number of elements of `a`

smaller than or equal to `x(1)`

. The new position of `x(2)`

will be `2`

plus the number of elements of `a`

smaller than or equal to `x(2)`

. So the number of elements in `a`

that are smaller than `x(i)`

equals the new position of `x(i)`

minus `i`

.

```
function aSmallerThanxMat = aSmallerThanx(a, x)
%%// Remember dimension of x
dimX = size(x);
%%// Sort x and remember original ordering Ix
[xsorted, Ix] = sort(x(:));
%%// How many as are smaller than sortedX
[~,Iaxsorted] = sort([a(:); xsorted(:)]);
Iaxsortedinv(Iaxsorted) = 1:numel(Iaxsorted);
aSmallerThanSortedx = Iaxsortedinv(numel(a)+1:end)-(1:numel(xsorted));
%%// Get original ordering of x back
aSmallerThanx(Ix) = aSmallerThanSortedx;
%%// Reshape x to original array size
aSmallerThanxMat = reshape(aSmallerThanx, dimX);
```

This approach might be a bit more difficult to grasp, but for large vectors, you will get a considerable speedup.

## Similar approach using `sort`

and `for`

:

The concept of this approach is very similar, but more traditional using loops:
First we sort `x`

and `a`

. Then we step through the `x(i_x)`

. If `x(i_x)`

it is larger than the current `a(i_a)`

, we increment `i_a`

. If it is smaller than the current `i_a`

, then `i_a-1`

is the number of elements in `a`

that are smaller or equal to `x(i_x)`

.

```
function aSmallerThanx = aSmallerThanx(a, x)
asorted = sort(a(:));
[xsorted, Ix] = sort(x(:));
aSmallerThanx = zeros(size(x));
i_a = 1;
for i_x = 1:numel(xsorted)
for i_a = i_a:numel(asorted)+1
if i_a>numel(asorted) || xsorted(i_x)<asorted(i_a)
aSmallerThanx(Ix(i_x)) = i_a-1;
break
end
end
end
```

## Approach using `histc`

:

This one is even better: It creates bins in between the values of `x`

, counts the values of `a`

, that fall into each bin, then sums them up beginning from the left.

```
function result = aSmallerThanx(a, x)
[xsorted, Ix] = sort(x(:));
bincounts = histc(a, [-Inf; xsorted]);
result(Ix) = cumsum(bincounts(1:end-1));
```

## Comparison:

Here is a runtime comparison of your approach, *Ander Biguri*'s `for+sum`

loop approach, *mehmet*'s `bsxfun`

approach, the two approaches using `sort`

and the `histc`

approach:
For vectors of length 16384, the `histc`

approach is 2300 times faster than the original approach.

`cumsum`

and`histc`

. – knedlsepp Jan 21 '15 at 0:15