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If a random generator function is not supplied to the random_shuffle algorithm in the standard library, will successive runs of the program produce the same random sequence if supplied with the same data?

For example, if

std::random_shuffle(filenames.begin(), filenames.end());

is performed on the same list of filenames from a directory in successive runs of the program, is the random sequence produced the same as that in the prior run?

share|improve this question
You know, you could try it and see... queue the talks on random seeding :) – Andrew White Aug 9 '11 at 16:53
I do get the same results -- just trying to make sure this is the expected behavior. The answer may, of course, also be "yes, this happens but that's an accident because the behavior is undefined." – drb Aug 9 '11 at 16:58
@drb: Yes, see my answer. – user195488 Aug 9 '11 at 16:58
up vote 6 down vote accepted

25.2.11 just says that the elements are shuffled with uniform distribution. It makes no guarantees as to which RNG is used behind the scenes (unless you pass one in) so you can't rely on any such behavior.

In order to guarantee the same shuffle outcome you'll need to provide your own RNG that provides those guarantees, but I suspect even then if you update your standard library the random_shuffle algorithm itself could change effects.

share|improve this answer
+1, although I don't know about "unfortunate". Even if the standard were to say something about the RNG used, I would expect it to permit the implementation to use rand(). So at the very least, the previous calls to srand() and rand() would need to be the same on every run in order for the result to be the same. Also, note that the definition of random_shuffle doesn't actually say that it uses the third argument ;-) – Steve Jessop Aug 9 '11 at 17:10
@Steve Jessop Good point about that, I'll excise that word as subjective. – Mark B Aug 9 '11 at 17:11
One thing I've noticed is that whatever the default RNG is, it is always seeded with the same value at initialization. Without calling srand() before using std::random_shuffle, the first call to it will always produce the same result on the same container. – Sean Aug 9 '11 at 17:42
@Sean: that's the usual way because rand() is required to behave at program start the same as if seeded with srand(0). So any implementation of random_shuffle using rand() will behave as you observe. A linux implementation could read straight from /dev/random if it wanted to, or (to be less anti-social) seed a PRNG from /dev/urandom, but gcc's implementation that I have on my machine just uses rand(). – Steve Jessop Aug 9 '11 at 17:51

If you use the same random generator, with the same seed, and the same starting sequence, the results will be the same. A computer is, after all, deterministic in its behavior (modulo threading issues and a few other odds and ends).

If you do not specify a generator, the default generator is implementation defined. Most implementations, I think, use std::rand() (which can cause problems, particularly when the number of elements in the sequence is larger than RAND_MAX). I would recommend getting a generator with known quality, and using it.

If you don't correctly seed the generator which is being used (another reason to not use the default, since how you seed it will depend on the implementation), then you'll get what you get. In the case of std::rand(), the default always uses the same seed. How you seed depends on the generator used. What you use to seed it should be vary from one run to the other; for many applications, time(NULL) is sufficient; on a Unix platform, I'd recommend reading however many bytes it takes from /dev/random. Otherwise, hashing other information (IP address of the machine, process id, etc.) can also improve things---it means that two users starting the program at exactly the same second will still get different sequences. (But this is really only relevant if you're working in a networked environment.)

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I think std::rand is sufficient for most programs. Obviously if you're doing poker or cryptography you'll want a better algorithm. – Billy ONeal Aug 9 '11 at 17:42
@Billy: the value of RAND_MAX matters, though. On Windows it's only 32k, so maybe "most programs" only need small random numbers, but you still need to be aware of the limitation, you can't think "I don't need crytographically secure unpredictability, therefore I can just use rand". – Steve Jessop Aug 9 '11 at 17:55
It was, in fact, the value of RAND_MAX that I was mainly thinking of (although I've seen implementations of rand that were really, really bad). If you have more than 32k elements, of course, using rand() will skew things horribly, but since the implementation must map the value to [0...n), unless the number of elements is considerably smaller than RAND_MAX, there will be noticeable skew. – James Kanze Aug 10 '11 at 8:12

You may produce an identical result every run of the program. You can add a custom random number generator (which can be seeded from an external source) as an additional argument to std::random_shuffle if this is a problem. The function would be the third argument. Some people recommend call srand(unsigned(time(NULL))); before random_shuffle, but the results are often times implementation defined (and unreliable).

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People certainly do call srand(unsigned(time(NULL))); But I've yet to hear anybody recommend it! – TonyK Aug 9 '11 at 17:04
@TonyK: You are right.. edited :) – user195488 Aug 9 '11 at 17:06
Regarding unsigned(time(NULL)): tiresome pedantry, but C++ allows time_t to be a floating point type, and converting an out-of-range floating value to an integer type is undefined behavior. Silly, because time_t is more loosely specified than anyone has any real need for, but there it is. Yet another fact about portability that nobody needs to know in practice :-) – Steve Jessop Aug 9 '11 at 17:22
@Steve: Good info, thanks Steve! – user195488 Aug 9 '11 at 17:29

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