# Recurrence Relation

Why is the recurrence relation of recursive factorial algorithm this?

``````T(n)=1 for n=0
T(n)=1+T(n-1) for n>0
``````

Why is it not this?

``````T(n)=1 for n=0
T(n)=n*T(n-1) for n>0
``````

Putting values of n i.e 1,2,3,4...... the second recurrence relation holds(The factorials are correctly calculated) not the first one.

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This question is very confusing... You first formula is not factorial. It is simply T(n) = n + 1, for all n. Factorial of n is the product of the first n positive integers: factorial(1) = 1. factorial(n) = n * factorial(n-1). Your second formula is essentially correct.

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So what is the time complexity for the second algorithm?? Is it exponential? –  Prasoon Saurav Sep 4 '09 at 15:54
I think I saw the first recurrence relation here books.google.co.in/… –  Prasoon Saurav Sep 4 '09 at 15:58
The theoretical time complexity is linear. To compute a factorial of n you need to perform n multiplications: O(n). The value of n!, on the other hand grows faster than any exponential. Of course, the complexity of computing n! increases if you want full precision for a large n, so that n! has more bits than the integer on your machine. Then you need to perform infinite precision arithmetic, which adds complexity. –  Dima Sep 4 '09 at 16:06
even with your pointer, i'm not able to find the right relation. Are you sure you were not looking at the Fibonacci number ? (it's closer but not right either..) –  LB40 Sep 4 '09 at 16:09
This is called "flat recursion", i. e. the function only makes one recursive call to itself. Flat recursion takes liner time to compute. On the other hand, if the function makes more than one call to itself, you have a deep recursion, that takes exponential time. Example: f(x) = f(x-1) + f(x-2). At each level of recursion you double the number of calls to f, i. e. f() is called 2^n times. –  Dima Sep 4 '09 at 16:10

I assume that you have bad information. The second recurrence relation you cite is the correct one, as you have observed. The first one just generates the natural numbers.

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Looks like T(n) is the recurrence relation of the time complexity of the recursive factorial algorithm, assuming constant time multiplication. Perhaps you misread your source?

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Where did you find the first one ? It's completely wrong.

It's only going to add 1 each time whatever the value is .

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What he put was not the factorial recursion, but the time complexity of it.
Assuming this is the pseudocode for such a recurrence:

``````1. func factorial(n)
2.   if (n == 0)
3.      return 1
4.   return n * (factorial - 1)
``````
• I am assuming that tail-recursion elimination is not involved.

Line 2 and 3 costs a constant time, c1 and c2.
Line 4 costs a constant time as well. However, it calls factorial(n-1) which will take some time T(n-1). Also, the time it takes to multiply factorial(n-1) by n can be ignored once T(n-1) is used.
Time for the whole function is just the sum: T(n) = c1 + c2 + T(n-1).
This, in big-o notation, is reduced to T(n) = 1 + T(n-1).

This is, as Diam has pointed out, is a flat recursion, therefore its running time should be O(n). Its space complexity will be enormous though.

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we generally use recurrence relation to find the time complexity of algorithm.

Here, the function T(n) is not actually for calculating the value of an factorial but it is telling you about the time complexity of the factorial algorithm.

It means for finding a factorial of n it will take 1 more operation than factorial of n-1 (i.e. T(n)=T(n-1)+1) and so on.

so correct recurrence relation for a recursive factorial algorithm is T(n)=1 for n=0 T(n)=1+T(n-1) for n>0 not that you mentioned later.

like recurrence for tower of hanoi is T(n)=2T(n-1)+1 for n>0;

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T(n) = T(n-1) + 1 is correct recurrence equation for factorial of n. This equation gives you the time to compute factorial of n NOT value of the factorial of n.

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