# How fast can 'finding the max in an array' possibly get?

This question comes from a discussion that was touched off on this other question: Parallelize already linear-time algorithm. It is not homework.

You are given an array of N numbers, and a machine with P processors and a shared CREW memory (Concurrent Read, Exclusive Write memory).

What is the tightest upper bound on the fastest algorithm to find the largest number in the array? [Obviously, also: What is the algorithm itself?]

I am not referring to the total amount of work performed [which can never be less than O(N)].

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What does 'fastest' mean here? Wouldn't it depend on the relative costs of executing code, reading memory, writing memory, comparing numbers, and also on how the cache works? –  user97370 Dec 23 '11 at 11:28
@aix: You could be right. I don't mind if somebody flags it for a move there. Until then, I'm letting it stay here. It still is about programming after all. –  ArjunShankar Dec 23 '11 at 11:31
@PaulHankin: I'm talking about complexity here. i.e. drop all the constants like '5ms' to read, '10ns' a cycle, cache hits, etc. Just consider stuff like 'read', 'write', 'compare' as 1 operation: en.wikipedia.org/wiki/Analysis_of_algorithms –  ArjunShankar Dec 23 '11 at 11:34
@casperOne This question involve facts, and has a unique correct answer. It is not a matter of opinion, debate, polling, etc., so I think it should be re-opened. –  dasblinkenlight Dec 26 '11 at 9:10
@casperOne - Since when did people start having 'opinions' or 'polls' or 'debates' on a tight upper bound to the time taken to solve a precisely defined problem? –  ArjunShankar Dec 27 '11 at 10:12

I think it's O(N/P') + O(Log2(P')), where P'=min{N,P}. P' processors search for max of N/P' elements each, followed by Log2 pairwise merges done in parallel. The first P'/2 merges are done by even-numbered processors, next 'P'/4' - by processors at locations divisible by 8, then by 16, and so on.

Edit P' is introduced to cover the case when you have significantly more processor nodes than the elements that you need to search.

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I am not sure the Log2(P) argument holds: It assumes P % 2 == 0, also it doesn't consider the cost of distributing the work to the P processors, which I suspect to be linear –  Eugen Rieck Dec 23 '11 at 11:42
@EugenRieck Distributing can be done in O(1) by communicating N to all processors and assuming that they already know P and their own number: first processor gets 0..N/P part of the array, second gets N/P..2N/P', and so on. The main idea is that merging the results can be done in parallel, too: I think it is independent of the actual number of processors. –  dasblinkenlight Dec 23 '11 at 11:53
Communicating N could be as simple as writing N into a predetermined location in memory, where all CPUs can read it concurrently, so yes. I agree that communication can be done in O(1). –  ArjunShankar Dec 23 '11 at 13:01
@dasblinkenlight: Consider whether this bound accounts for a rather large machine. Then every cycle, the processors can reduce the input size by half (there are so many processors that even in the first cycle, each gets only 2 numbers to compare). Ofcourse, every cycle, the number of CPUs with work to do will halve. –  ArjunShankar Dec 23 '11 at 13:08
@ArjunShankar I think that is already accounted for: in cases where P is close to N, the value of N/P would be close to 1, so the result would be dominated by Log2(P). –  dasblinkenlight Dec 23 '11 at 13:12

Cook, Dwork, and Reischuk showed that any CREW algorithm for finding the maximum of n elements must run in Omega(lg n) time, even with an unlimited number of processors and unlimited memory. If I remember correctly, an algorithm with a matching upper bound appears in their paper:

Stephen Cook, Cynthia Dwork, and Rüdiger Reischuk. Upper and lower time bounds for parallel random access machines without simultaneous writes. SIAM Journal on Computing, 15(1):87-97, 1986.

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The following is optimal bound:

If p <= n/log n you can do it in O(n/p) time; otherwise it's O(log n) i.e. when p>n/log n you gain nothing compared to p=n/log n.

Proof - lower bound:

Claim 1: You can never do faster than Ω(n/p), because p processors can give only speedup of p

Claim 2: You can never do faster than Ω(log n), because of CREW model (see unforgiven's paper); if you want to check if a 0-1 array has at least one 1, you need O(log n) time.

Proof - upper bound:

Claim 3: You can find maximum using n/log n processors and in O(log n) time

Proof: It is easy to find maximum using n processors and log n time; but in fact, in this algorithm most processors are dormant most of the time; by suitable dovetailing, (see e.g. Papadimitriou's complexity book) their number can be lowered to n/log n.

Now, given less than n/log n processors you can give work assigned to K processors to 1 processor, this divides processor requirement by K and multiplies required time by K.

Let K=(n/log n)/p; the previous algorithm runs in time O(K log n) = O(n/p), and requires n / (log n * K) = p processors.

Edited: I just realized that when p <= n/log n, dasblinkenlight's algorithm has the same asymptotic runtime:

n/p + log p <= n/p + log(n/log n) <= n/p + log n <= n/p + n/p <= 2n/p = O(n/p)

so you can use that algorithm, which has complexity O(n/p) when p <= n/log n and O(log n) otherwise.

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+1 for a well thought of answer, and for considering the issues raised by two other answers. –  ArjunShankar Dec 29 '11 at 10:06

I suspect this to be O(N/P)+O(P)

• Sharing the work between P processors has a cost of O(P)
• combining the work done by P processors has also costs of O(P)
• A perfect parallell search of N items by P processors has time cost of O(N/P)

My naive algorithm would be to

• write item 0 into a CREW cell labelled "result"
• start P completly independent searches, each through 1/P th of the N items
• upon completion of each search use CAS spinloop to replace "result" with result of partial search, if it is larger. (Depending on your definition of CREW you might not need the spinloop)
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This analysis is way too pessimistic even on real hardware that we actually have. Reducing a value from P processors can be done in O(lg P)` time. –  Novelocrat Dec 23 '11 at 22:55
The obvious question is: if P >> N you mean that 2P processors will do the task slower than P processors? –  Serge Dundich Dec 26 '11 at 7:59

For P=N^2 it is O(1).

All initialize Boolean array CannotBeMax[i] = FALSE

Proc (i,j) sets CannotBeMax[i] = A[i] < A[j]

Max is A[CannotBeMax[i] == FALSE]

Note that all concurrent writes attempt to write identical info so the answer is consistent no matter which one succeeds.

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Right. +1. The algorithm you describe, while correct, is relevant for a CRCW PRAM with the 'common' write scheme. My question was specifically for a CREW (Concurrent Read, Exclusive Write) machine, where concurrent writes are not allowed. –  ArjunShankar Jul 26 '12 at 6:59