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Following on from my previous question, can we prove that the standard allows us to pass an empty range to a standard algorithm?

Paragraph 24.1/7 defines an "empty range" as the range [i,i) (where i is valid), and i would appear to be "reachable" from itself, but I'm not sure that this qualifies as a proof.

In particular, we run into trouble when looking at the sorting functions. For example, std::sort:

Complexity: O(N log(N)) (where N == last - first) comparisons

Since log(0) is generally considered to be undefined, and I don't know what 0*undefined is, could there be a problem here?


(Yes, ok, I'm being a bit pedantic. Of course no self-respecting stdlib implementation would cause a practical problem with an empty range passed to std::sort. But I'm wondering whether there's a potential hole in the standard wording here.)

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Two SO users need to read the language-lawyer tag wiki: «Typical questions concern gaps between "what will usually work in practice" and "what the spec actually guarantees".» –  Lightness Races in Orbit Sep 21 '11 at 19:32
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3 Answers 3

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I don't seem much room for question. In §24.1/6 we're told:

An iterator j is called reachable from an iterator i if and only if there is a finite sequence of applications of the expression ++i that makes i == j.

and in $24.1/7:

Range [i, j) is valid if and only if j is reachable from i.

Since 0 is finite, [i, i) is a valid range. §24.1/7 goes on to say:

The result of the application of functions in the library to invalid ranges is undefined.

That doesn't go quite so far as to say that a valid range guarantees defined results (reasonable, since there are other requirements, such as on the comparison function) but certainly seems to imply that a range being empty, in itself, should not lead to UB or anything like that. In particular, however, the standard makes an empty range just another valid range; there's no real differentiation between empty and non-empty valid ranges, so what applies to a non-empty valid range applies equally well to an empty valid range.

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Indeed. I think that your answer agrees with my conclusions thus far, and it certainly seems to be as thorough as anything I can come up with. –  Lightness Races in Orbit Sep 21 '11 at 19:36
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Big-O notation is defined in terms of the limit of the function. An algorithm with actual running time g(N) is O(f(N)) if and only if lim N→∞ g(N)/f(N) is a non-negative real number g(N)/f(N) is less than some positive real number C for all values N greater than some constant k (the exact values of C and k are immaterial; you just have to be able to find any C and k that makes this true). (thanks for the correction, Jesse!)

You'll note that the actual number of elements is not relevant in big-O analysis. Big-O analysis says nothing about the behavior of the algorithm for small numbers of elements; therefore, it does not matter if f(N) is defined at N=0. More importantly, the actual runtime behavior is controlled by a different function g(N), which may well be defined at N=0 even if f(0) is undefined.

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OK, so there's no issue with the complexity requirements, and we can just lean on the fact that the range satisfies all stated iterator requirements? –  Lightness Races in Orbit Sep 21 '11 at 19:18
    
I can't speak to the standard's wording as I don't have a copy of the standard, sorry. –  bdonlan Sep 21 '11 at 19:18
    
OK; that's what I'm after, really. –  Lightness Races in Orbit Sep 21 '11 at 19:19
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To be pedantic (since the OP was as well :), Big-O notation is not about the limit; g(N) is O(f(N)) on the range I if there is some positive constant C such that g(N) <= C f(N) for all N in I. So there really is something to say about N = 0, if the standard wanted to. (And you can replace the range I with "for large N", meaning, there is some range [N_0, infinity), which is presumably what the standard means by complexity) –  Jesse Beder Sep 21 '11 at 19:21
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By the way, the main distinction I'm trying to draw is that the limit of g(N)/f(N) may not exist (it just needs to have an upper limit). –  Jesse Beder Sep 21 '11 at 19:24
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Apart from the relevant answer given by @bdonlan, note also that f(n) = n * log(n) does have a well-defined limit as n goes to zero, namely 0. This is because the logarithm diverges more slowly than any polynomial, in particular, slower than n. So all is well :-)

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However, there's still an issue with, for example, lower_bound, whose complexity requirement is "at most log2(last-first) + O(1) comparisons". This doesn't use O-notation for the logarithmic part, so @bdonlan's argument doesn't apply; and log2(n) doesn't have a limit as n goes to zero. The best we can do here is argue that log2(0) is negative (even though it's undefined), and (if we're talking about C++11) invoke 17.5.1.4/6 ("If the formulation of a complexity requirement calls for a negative number of operations, the actual requirement is zero operations.") –  Mike Seymour Sep 22 '11 at 1:17
    
@Mike: OK, fair enough, though of course in reality there wasn't any issue to begin with, since big-O notation describes asymptotic behaviour, so the behaviour on any bounded interval is irrelevant. Thanks for pointing this out, though :-) –  Kerrek SB Sep 22 '11 at 1:27
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