# Arithmetic Algorithm

I was going through some interview question and stumbled upon this question. p(x) = a0 + a1x + a2x^2 + ... + anx^n. What algorithm could you use to to compute the value of p(x) in O(N^2) ? I'm totally clueless about how to approach this problem.

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Which value? Also I think you mean p(x) = a0 + a1x + a2x^2 + ... + anx^n. –  Pieter Bos Sep 5 '12 at 16:47
What kind of job is that? –  user120929 Sep 5 '12 at 16:49
Value of P(x) and yes, that is what I meant –  Nick Chris Sep 5 '12 at 16:50
@LeonardoCooper - Software Developer –  Nick Chris Sep 5 '12 at 16:51
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## 2 Answers

You can do it in `O(N)` with direct evaluation or with Horner's method. A useful chart for complexity of various operations and the methods involved can be found here:

Computational complexity of mathematical operations

Horner's method is a serial procedure that optimizes "sub-expressions of form (A+ Bx) which be evaluated using a native multiply–accumulate instruction on some architectures". A more parallel version is Estrin's scheme.

Since you can compute the `p(x)` in `O(N)` time, apply this method `N` times to achieve `O(N^2)` (if that is really what you are after...).

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It is explicitly asked to be done in O(N^2) –  Nick Chris Sep 5 '12 at 16:55
@NickChris O(N^2) is a superset of O(N). –  sepp2k Sep 5 '12 at 17:00
Maybe the interviewer assumed that `pow(X,N)` is implemented in O(N) time using iterated multiplication? In which case direct evaluation is O(N^2). –  Kevin Sep 5 '12 at 17:02
@Kevin Horner's method does not require the use of `pow`, so this still isn't an issue. It is possible that the interviewer wasn't aware of any other method than direct evaluation though! –  Hooked Sep 5 '12 at 17:04
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Since each term is independent and there are N terms, you must performs `O(N)` calculations of a polynomial term. Since the worst cast term is `(a_n)*(x^n)` and `x^n` can be computed in `O(N)` you have exactly `O(N^2)` time for the naive implementation of the algorithm.

There are tricks however to compute `x^n` in less than O(N) time so you could do even better: see an implementation of pow(). Also Hoener's method as described by other answers provides a fast implementation which is `O(N)` time and thus also `O(N^2)` time.

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