# Time Complexity of a nested for loop that parses a matrix

Let's say I have a matrix that has X rows and Y columns. The total number of elements is X*Y, correct? So does that make n=X*Y?

``````for (i=0; i<X; i++)
{
for (j=0; j<Y; j++)
{
print(matrix[i][j]);
}
}
``````

Then wouldn't that mean that this nested for loop is O(n)? Or am I misunderstanding how time complexities work?

Generally, I thought all nested for loops were O(n^2), but if it goes through X*Y calls to print(), doesn't that mean that the time complexity is O(X*Y) and X*Y is equal to n?

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There are two sizes involved here. First there is the dimension of the matrix `X * Y` This corresponds to what is known in complexity theory you normally have a parameter called the size of input. Let `n` denote this size of input.

On the other hand in linear algebra complexity is normally parameterized by the dimension of the vector space that linear operators act upon. Here an `X` by `Y` matrix acts from the vector space of dimension `X` to the vector space of dimension `Y`. When `X = Y = m` as is often the case in linear algebra texts, your complexity estimations would take `m` as a parameter and the complexity of the nested loop would be `O(m^2)`.

In general let `m = max(X,Y)` then

`````` O(m^2) = O(n)
``````

And that is the complexity of the nested loop.

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How do you deduct `O(m^2) = O(n)`? That's obviously wrong! Would it work like that we would just put every polynomial problem to linear space :) – user221931 Mar 4 '14 at 3:34
You say: `In general let m = max(X,Y) then O(m^2) = O(n)`. That is just blatantly wrong no matter how you puy it. But `O(X*Y)=O(n^2)` is perfectly valid, you don't need to `n=max(X,Y)` since it's big O not big Theta notation and it is implied. The way you have your answer now, you claim that "a nested loop is O(n)", if you make a paper and prove it you're in for a Nobel :) – user221931 Mar 4 '14 at 15:42
And to clarify for OP and anyone else, `O(X*Y)` is `O(n^2)`, because X and Y are variables. `O(X*Y)` can be `O(n)` ONLY if X OR Y is a constant (no matter how big), because it won't grow. Finally `O(X*Y)` can be `O(1)` ONLY if X AND Y are constants, then the function can't grow and it takes the same time to execute. – user221931 Mar 4 '14 at 15:52
Honestly, it's as simple as 1+1=2 in regard to big O notation: nested loops are O(n^2) because you have N iterations repeated over N iterations, that's N^2 in total. And O(n^2) can't be equal to O(n) like you have it, that is mathematically and logically absurd, can't you recognize that? If it would be the case then there would be no polynomial space because every problem could be "relaxed" to a linear one. So, try it yourself with some numbers or check this. The O(n) in the first example evolves NON nested loops. – user221931 Mar 4 '14 at 17:37
@user221931 You are given a list of values `a_1,..a_n`. Where `n=p*q` (n is p multiplied by q) now you have the following pseudocode fragment `for(i=0;i<p;i++)for(j=0;j<q;j++)m[i][j]=a_f(i,j);` where `f(i,j)=i*q+j`. You can check that this nested loop would perform exactly `n` iterations. That is why we can write `O(n)` here. – Dmitri Chubarov Mar 4 '14 at 18:04

You are right when you say `n = X x Y` but wrong when you say the nested loops should be `O(n)`. The meaning of nested loop can be understood if you dry run your code. You will notice that for each iteration of the outer loop the inner loop runs `n` (or what ever is the size condition) times. Hence, by simple math, you can deduce that its `O(n^2)`. But, if you had just one loop when you will be iterating over `(X x Y)` (Eg: `for(i = 0; i<(X*Y); i++)` elements, then it will be `O(n)` cause you are not restarting your iteration at any point of time. Hope this makes sense.

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If you have a matrix of size rows*columns, then the inner loop (let's say) is O(columns), and the nested loops together are O(rows*columns).

You are confusing a problem size of N for a problem size of N^2. You can either say your matrix is size N or your matrix is size N^2, though unless your matrix is square you should say that you have a matrix of size Rows*Columns.

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Generally, I thought all nested for loops were O(n^2),

You are wrong about that. What confuses you I guess is that often people use as an example square(X==Y) matrix so complexity is n*n(X==n,Y==n).

If you want to practise your O(*) skills try to figure out why matrix multiplication is O(n^3). IF you dont know the algorithm for matrix multiplication it is easy to find it online.

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