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I was talking with a student the other day about the common complexity classes of algorithms, like O(n), O(nk), O(n lg n), O(2n), O(n!), etc. I was trying to come up with an example of a problem for which solutions whose best known runtime is super-exponential, such as O(22n), but still decidable (e.g. not the halting problem!) The only example I know of is satisfiability of Presburger arithmetic, which I don't think any intro CS students would really understand or be able to relate to.

My question is whether there is a well-known problem whose best known solution has runtime that is superexponential; at least ω(n!) or ω(nn). I would really hope that there is some "reasonable" problem meeting this description, but I'm not aware of any.

Thanks for any advice you can offer!

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Interesting question. Going beyond that: is there any program which is guaranteed to terminate for any finite combination of input symbols, but whose worst-case time and space requirements for a given input size cannot be computed in bounded time? Note that restricting the question to "any valid input" would render the question meaningless: if the validity of input can be determined in valid time, then termination would be guaranteed for all inputs; if it can't, then any undecidable problem would complete for those inputs where it completes and wouldn't for those where it doesn't. –  supercat Aug 5 '11 at 15:07

4 Answers 4

up vote 5 down vote accepted

Maximum Parsimony is the problem of finding an evolutionary tree connecting n DNA sequences (representing species) that requires the fewest single-nucleotide mutations. The n given sequences are constrained to appear at the leaves; the tree topology and the sequences at internal nodes are what we get to choose.

In more CS terms: We are given a bunch of length-k strings that must appear at the leaves of some tree, and we have to choose a tree, plus a length-k string for each internal node in the tree, so as to minimise the sum of Hamming distances across all edges.

When a fixed tree is also given, the optimal assignment of sequences to internal nodes can be determined very efficiently using the Fitch algorithm. But in the usual case, a tree is not given (i.e. we are asked to find the optimal tree), and this makes the problem NP-hard, meaning that every tree must in principle be tried. Even though an evolutionary tree has a root (representing the hypothetical ancestor), we only need to consider distinct unrooted trees, since the minimum number of mutations required is not affected by the position of the root. For n species there are 3 * 5 * 7 * ... * (2n-5) leaf-labelled unrooted binary trees. (There is just one such tree with 3 species, which has a single internal vertex and 3 edges; the 4th species can be inserted at any of the 3 edges to produce a distinct 5-edge tree; the 5th species can be inserted at any of these 5 edges, and so on -- this process generates all trees exactly once.) This is sometimes written (2n-5)!!, with !! meaning "double factorial".

In practice, branch and bound is used, and on most real datasets this manages to avoid evaluating most trees. But highly "non-treelike" random data requires all, or almost all (2n-5)!! trees to be examined -- since in this case many trees have nearly equal minimum mutation counts.

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@j_random_hacker- My understanding is that n!! < n!, since double-factorial means n(n-2)(n-4)...(1), rather than (n!)!. Is this incorrect? –  templatetypedef Mar 16 '11 at 6:27
You're right. But bear in mind that there is a 2n (rather than just an n) under the double factorial sign for this problem, and (2n)!! > n! for all n > 0. Actually I'm not sure what the tightest "canonical" big-O complexity measure for this is. –  j_random_hacker Mar 16 '11 at 9:12
@j_random_hacker- I think a "canonical" big-O for this would be O(2^n n!), since each term of the double-factorial is just over twice as large as its counterpart in the regular factorial and there's n of them. This looks like a great answer; thanks for posting it! –  templatetypedef Mar 17 '11 at 21:11
Thanks! Your big-O expression looks dead-on to me. –  j_random_hacker Mar 18 '11 at 1:53

Showing all permutation of string of length n is n!, finding Hamiltonian cycle is n!, minimum graph coloring, ....

Edit: even faster Ackerman functions. In fact they seems without bound function.

A(x,y) = y+1 (if x = 0)
A(x,y) = A(x-1,1) (if y=0)
A(x,y) = A(x-1, A(x,y-1)) otherwise.

from wiki:
A(4,3) = 2^2^65536,...
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All permutations runs in O(n n!), as does finding a Hamiltonian cycle. This is indeed w(n!), but what I was hoping for was something even faster-growing than this. Thanks for posting this, though; you're absolutely right! –  templatetypedef Mar 6 '11 at 10:38
Hamilton cycle and graph coloring have exponential time DPs. –  user635541 Mar 6 '11 at 16:38
@user635541, I don't know any exponential time DP for HC ( and I think there isn't), but if there is, it's big enough, Also After OP wants better example I suggest ackerman function. –  Saeed Amiri Mar 7 '11 at 5:55
@user635541, yes you are right, HC can have a simple DP with running time 2^n*poly(n) and may be there are even better algorithms by use of graph decompositions. –  Saeed Amiri Jan 20 '14 at 10:41

Do algorithms to compute real numbers to a certain precision count? The formula for the area of the Mandelbrot set converges extremely slowly; 10118 terms for two digits, 101181 terms for three.

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This is not a practical everyday problem, but it's a way to construct relatively straightforward problems of increasing complexity.

  • The Kolmogorov complexity K(x) is the size of the smallest program that outputs the string $x$ on a pre-determined universal computer U. It's easy to show that most strings cannot be compressed at all (since there are more strings of length n than programs of length n).
  • If we give U a maximum running time (say some polynomial function P), we get a time-bounded Kolmogorov complexity. The same counting argument holds: there are some strings that are incompressible under this time bounded Kolmogorov complexity. Let's call the first such string (of some length n) xP
  • Since the time-bounded Kolmogorov complexity is computable, we can test all strings, and find xP
  • Finding xP can't be done in polynomial time, or we could use this algorithm to compress it, so finding it must be a super-polynomial problem. We do know we can find it in exp(P) time, though. (Jumping over some technical details here)
  • So now we have a time-bound E = exp(P). We can repeat the procedure to find xE, and so on.

This approach gives us a decidable super-F problem for every time-constructible function F: find the first string of length n (some large constant) that is incompressible under time-bound F.

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