# Determining the big Oh for (n-1)+(n-1)

I have been trying to get my head around this perticular complexity computation but everything i read about this type of complexity says to me that it is of type big O(2^n) but if i add a counter to the code and check how many times it iterates per given n it seems to follow the curve of 4^n instead. Maybe i just misunderstood as i placed an count++; inside the scope.

Is this not of type big O(2^n)?

``````   public int test(int n)
{
if (n == 0)
return 0;
else
return test(n-1) + test(n-1);
}
``````

I would appreciate any hints or explanation on this! I completely new to this complexity calculation and this one has thrown me off the track.

//Regards

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Try counting it up (by hand) for the first few `n`s (say `0<=n<=5`) and I think it'll make sense fairly quickly. However, as it's written now it'll return `0` no matter what `n` you begin with. –  iamnotmaynard Apr 16 '13 at 20:34
What was the code with the counter? –  iamnotmaynard Apr 16 '13 at 20:40

``````int test(int n)
{
printf("%d\n", n);

if (n == 0) {
return 0;
}
else {
return test(n - 1) + test(n - 1);
}
}
``````

With a printout at the top of the function, running `test(8)` and counting the number of times each `n` is printed yields this output, which clearly shows 2n growth.

``````\$ ./test | sort | uniq -c
256 0
128 1
64 2
32 3
16 4
8 5
4 6
2 7
1 8
``````

(`uniq -c` counts the number of times each line occurs. `0` is printed 256 times, `1` 128 times, etc.)

Perhaps you mean you got a result of O(2n+1), rather than O(4n)? If you add up all of these numbers you'll get 511, which for n=8 is 2n+1-1.

If that's what you meant, then that's fine. O(2n+1) = O(2⋅2n) = O(2n)

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First off: the 'else' statement is obsolete since the if already returns if it evaluates to true.

On topic: every iteration forks 2 different iterations, which fork 2 iterations themselves, etc. etc. As such, for n=1 the function is called 2 times, plus the originating call. For n=2 it is called 4+1 times, then 8+1, then 16+1 etc. The complexity is therefore clearly 2^n, since the constant is cancelled out by the exponential.

I suspect your counter wasn't properly reset between calls.

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Let x(n) be a number of total calls of `test`.

``````x(0) = 1

x(n) = 2 * x(n - 1) = 2 * 2 * x(n-2) = 2 * 2 * ... * 2
``````

There is total of n twos - hence 2^n calls.

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The complexity `T(n)` of this function can be easily shown to equal `c + 2*T(n-1)`. The recurrence given by

``````T(0) = 0
T(n) = c + 2*T(n-1)
``````

Has as its solution c*(2^n - 1), or something like that. It's O(2^n).

Now, if you take the input size of your function to be `m = lg n`, as might be acceptable in this scenario (the number of bits to represent `n`, the true input size) then this is, in fact, an `O(m^4)` algorithm... since O(n^2) = O(m^4).

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