I am just learning MATLAB and I find it hard to understand the **performance factors of loops vs vectorized functions.**

In my previous question: Nested for loops extremely slow in MATLAB (preallocated) I realized that using a vectorized function vs. 4 nested loops made a **7x times difference in running time**.

In that example instead of looping through all dimensions of a 4 dimensional array and calculating median for each vector, it was much cleaner and faster to just call median(stack, n) where n meant the working dimension of the median function.

But median is just a very easy example and *I was just lucky* that it had this **dimension parameter implemented**.

My question is that ** how do you write a function yourself which works as efficiently as one which has this dimension range implemented**?

For example you have a function `my_median_1D`

which only works on a 1-D vector and returns a number.

How do you write a function `my_median_nD`

which acts like MATLAB's median, by taking an n-dimensional array and a *"working dimension"* parameter?

**Update**

I found the code for calculating median in higher dimensions

```
% In all other cases, use linear indexing to determine exact location
% of medians. Use linear indices to extract medians, then reshape at
% end to appropriate size.
cumSize = cumprod(s);
total = cumSize(end); % Equivalent to NUMEL(x)
numMedians = total / nCompare;
numConseq = cumSize(dim - 1); % Number of consecutive indices
increment = cumSize(dim); % Gap between runs of indices
ixMedians = 1;
y = repmat(x(1),numMedians,1); % Preallocate appropriate type
% Nested FOR loop tracks down medians by their indices.
for seqIndex = 1:increment:total
for consIndex = half*numConseq:(half+1)*numConseq-1
absIndex = seqIndex + consIndex;
y(ixMedians) = x(absIndex);
ixMedians = ixMedians + 1;
end
end
% Average in second value if n is even
if 2*half == nCompare
ixMedians = 1;
for seqIndex = 1:increment:total
for consIndex = (half-1)*numConseq:half*numConseq-1
absIndex = seqIndex + consIndex;
y(ixMedians) = meanof(x(absIndex),y(ixMedians));
ixMedians = ixMedians + 1;
end
end
end
% Check last indices for NaN
ixMedians = 1;
for seqIndex = 1:increment:total
for consIndex = (nCompare-1)*numConseq:nCompare*numConseq-1
absIndex = seqIndex + consIndex;
if isnan(x(absIndex))
y(ixMedians) = NaN;
end
ixMedians = ixMedians + 1;
end
end
```

Could you explain to me that **why is this code so effective compared to the simple nested loops**? It has nested loops just like the other function.

I don't understand **how could it be 7x times faster** and also, that **why is it so complicated**.

**Update 2**

I realized that using median was not a good example as it is a complicated function itself requiring sorting of the array or other neat tricks. I re-did the tests with mean instead and the results are even more crazy:
**19 seconds vs 0.12 seconds.**
It means that the **built in way for sum is 160 times faster than the nested loops**.

It is really hard for me to understand how can an industry leading language have such an extreme performance difference based on the programming style, but I see the points mentioned in the answers below.