# Time complexity of a recursive algorithm

How can I calculate the time complexity of a recursive algorithm?

``````int pow1(int x,int n) {
if(n==0){
return 1;
}
else{
return x * pow1(x, n-1);
}
}

int pow2(int x,int n) {
if(n==0){
return 1;
}
else if(n&1){
int p = pow2(x, (n-1)/2)
return x * p * p;
}
else {
int p = pow2(x, n/2)
return p * p;
}
}
``````
-
I never quite grasped this, I've read some less technical books on algorithms / data structures and how to implement them, but never really got the Big O stuff, so I will be interested in these answers too –  user132014 Apr 25 '10 at 17:19

Analysing recursive functions (or even evaulating them) is a nontrivial task. A (in my opinion) good introduction can be found in Don Knuths Concrete Mathematics.

However, let's analyse these examples now:

We define a function that gives us the time needed by a function. Let's say that `t(n)` denotes the time needed by `pow(x,n)`, i.e. a function of `n`.

Then we can conclude, that `t(0)=c`, because if we call `pow(x,0)`, we have to check wether (`n==0`), and then return 1, wich can be done in constant time (hence the constant `c`).

Now we consider the other case: `n>0`. Here we obtain `t(n) = d + t(n-1)`. That's because we have again to check `n==1`, compute `pow(x, n-1`, hence (`t(n-1)`), and multiply the result by `x`. Checking and multiplying can be done in constant time (constant `d`), the recursive calculation of `pow` needs `t(n-1)`.

Now we can "expand" the term `t(n)`:

``````t(n) =
d + t(n-1) =
d + (d + t(n-2)) =
d + d + t(n-2) =
d + d + d + t(n-3) =
... =
d + d + d + ... + t(1) =
d + d + d + ... + c
``````

So, how long does it take until we reach `t(1)`? Since we start at `t(n)` and we subtract 1 in each step, it takes `n-1` steps to reach `t(n-(n-1)) = t(1)`. That, on the other hands, means, that we get `n-1` times the constant `d`, and `t(1)` is evaluated to `c`.

So we obtain:

``````t(n) =
...
d + d + d + ... + c =
(n-1) * d + c
``````

So we get that `t(n)=(n-1) * d + c` wich is element of O(n).

`pow2` can be done using Masters theorem. Since we can assume that time functions for algorithms are monotonically increasing. So now we have the time `t(n)` needed for the computation of `pow2(x,n)`:

``````t(0) = c (since constant time needed fo computation of pow(x,0))
``````

for `n>0` we get

``````        / t((n-1)/2) + d if n is odd  (d is constant cost)
t(n) = <
\ t(n/2) + d     if n is even (d is constant cost)
``````

The above can be "simplified" to:

``````t(n) = floor(t(n/2)) + d <= t(n/2) + d (since t is monotonically increasing)
``````

So we obtain `t(n) <= t(n/2) + d`, wich can be solved using the masters theorem to `t(n) = O(log n)` (see section Application to Popular Algorithms in the wikipedia link, example "Binary Search").

-

-

Complexity of both functions ignoring recursion is O(1)

For the first algorithm pow1(x, n) complexity is O(n) because the depth of recursion correlates with n linearly.

For the second complexity is O(log n). Here we recurse approximately log2(n) times. Throwing out 2 we get log n.

-
Complexity of both functions is O(1) — What? –  KennyTM Apr 25 '10 at 17:32
It's O(1) ignoring the recursive call but could be expressed differently. The point is that the total complexity depends solely on the recursion depth. –  fgb Apr 25 '10 at 17:39

You have a function where a single run is done in O(1). (Condition checking, returning, and multiplication are constant time.)

What you have left is then your recursion. What you need to do is analyze how often the function would end up calling itself. In pow1, it'll happen N times. N*O(1)=O(N).

For pow2, it's the same principle - a single run of the function runs in O(1). However, this time you're halving N every time. That means it will run log2(N) times - effectively once per bit. log2(N)*O(1)=O(log(N)).

Something which might help you is to exploit the fact that recursion can always be expressed as iteration (not always very simply, but it's possible. We can express pow1 as

``````result = 1;
while(n != 0)
{
result = result*n;
n = n - 1;
}
``````

Now you have an iterative algorithm instead, and you might find it easier to analyze it that way.

-