# Describing the divide, conquer, combining parts of a divide-and-conquer algorithm

I'm solving a practice quiz and came across the following question

Write down the recurrence corresponding to the below divide and conquer algorithm, labeling exactly the components for each of: dividing, conquering, and combining.

``````1. Foo (p, r):
2.     if p = r
3.          return (1)
4.     else
5.         s ← 1
6.         for i = p to r
7.             s ← s * i
8.         q ← Foo(p, r − 1) * s
9.     return (q)
``````

My attempt at an answer.

1. Let T(n) be the work done by Foo over p to r, so T(n) is equivalent of Foo(p, r) where n is r - p + 1.

2. I get the following recurrence T(n) = T(n - 1) + Θ(n) + Θ(1)

3. The dividing part would be a constant Θ(1) which corresponds to the r-1 operation.

4. The conquering part would be the T(n - 1) which is recursively solving the sub-problem.

5. The combining part is a constant Θ(1) for the multiplication operation of T(n - 1) * s.

But that seems wrong as I didn't mention the Θ(n). What part of dividing, conquering, combining should the Θ(n) of lines 6,7 fall into?

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Umm, where does "Theta" come from in the code above? Or "T"? – Jim Clay Nov 17 '11 at 17:42
@JimClay I meant the theta of asymptotic notation, and edited my post to try and clarify what I meant by T(n) – ayh Nov 17 '11 at 18:03
Wow, nowadays even divide by 1 (calling itself only once) can be called "divide and conquer"... – kennytm Nov 17 '11 at 18:13
@KennyTM +1 LOL You're right it's a quite bad example of divide and conquer... also the algorithm itself does not make any sense, for Foo(p, r) it calculates the product r (r-1)^2 (r-2)^3 ... p^(r-p+1) ... why is that useful? The algorithm is also as fast as a trivial iterative implementation, so no benefit from "divide and conquer" here – Antti Huima Nov 19 '11 at 1:57