basic parallel programming concept: cost of search with N processors

I am asking this question to make sure some concept of parallel computing concept.

Lets give a simple example: We have a set of `n` numbers, what's the best running time to search a item from it if we have at least `n/3` parallel computers?

I think this will still be `O(n)`, but not sure if I am right. Since the constant part of the big-Oh expression can be erased?

Thank you

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Each computer searches 3 items. That's O(1). Then again, collecting the results is O(n) :P – Amadan May 15 '12 at 10:28

It could be O(1) or O(ln n).

Given each of your n/3 computers n/(n/3) numbers; they all get essentially 3 values. It takes them individually constant time to search their constant sized-set and return a result ("0 --> not found", k if found at the kth position in the array, if each is given K*(n/3) as the index in an array to start). So, the value is found in time O(1).

The issue comes in reporting the answer. Something has choose among the responses from the n/3 machines to pick a unique result. Typically this requires a "repeated" choice among the subsets of machines, which you can do in O(n) time but in parallel systems is often done with a "reduction" operator (such as SUM or MAX or ...). Such reduction operators can be (and usually are) implemented using a reduction tree, which is logarithmic.

Some parallel hardware has very fast reduction hardware, but is it still logarithmic. Weirdly enough, if you have n/1000 CPUs, you'll still get O(1) search times (with a big constant), and O(ln n) reduction times with a very small constant. It'll "look" like constant time if you ignore the O notation.

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Also, if it's a simple search to determine presence, you could take "whoever reports first" (if you just need a simple yes or no) and ignore everyone else; which is essentially `O(1)` for "present" (but pretty bad for "absent"); i.e. guaranteed `O(1)` if you know the thing is in there but just want to find the first occurence. If you don't know it's in there, you have to wait for everyone to report. – Amadan May 15 '12 at 10:48

This strictly depends on the underlying parallel model. Indeed, the final reduction step in which every processor defines a flag Found x and all processors perform a parallel reduction may have a different complexity. See in particular the COMMON CRCW PRAM case.

For a message-passing setting:

• T(n) = O(n/p + log p) for p < n
• T(n) = O(log n) for p = O(n)

For a shared-memory setting:

a) EREW PRAM

• T(n) = O(n/p + log p) for p < n
• T(n) = O(log n) for p = O(n)

b) CREW PRAM

concurrent reads do not help: the final reduction step still takes O(log p) time anyway

• T(n) = O(n/p + log p) for p < n
• T(n) = O(log n) for p = O(n)

c) COMMON CRCW PRAM

concurrent writes really help: the final reduction step takes now O(1) time, those processors with the flag Found x set can write simultaneously the same value in a shared location

• T(n) = O(n/p) for p < n
• T(n) = O(1) for p = O(n)
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