The question is way too broad for a complete answer, but let me cherry-pick a couple of interesting points:
Why "equally likely"
Suppose you have a simple random number generator that generate the numbers 0, 1, ..., 10 each with equal probability (think of this as the classic
rand()). Now you want a random number in the range 0, 1, 2, each with equal probability. Your knee-jerk reaction would be to take
rand() % 3. But wait, the remainders 0 and 1 occur more often than the remainder 2, so this isn't correct!
This is why we need proper distributions, which take a source of uniform random integers and turn them into our desired distribution, like
Uniform[0,2] in the example. Best to leave this to a good library!
Thus at the heart of all randomness is a good pseudo-random number generator that generates a sequence of numbers that uniformly distributed over a certain interval, and which ideally have a very long period. The standard implementation of
rand() isn't often the best, and thus it's good to have a choice. Linear-congruential and the Mersenne twister are two good choices (LG is actually often used by
rand(), too); again, it's good to let the library handle that.
How it works
Easy: first, set up an engine and seed it. The seed fully determines the entire sequence of "random" numbers, so a) use a different one (e.g. taken from
/dev/urandom) each time, and b) store the seed if you wish to recreate a sequence of random choices.
typedef std::mt19937 MyRNG; // the Mersenne Twister with a popular choice of parameters
uint32_t seed_val; // populate somehow
MyRNG rng; // e.g. keep one global instance (per thread)
Now we can create distributions:
std::uniform_int_distribution<uint32_t> uint_dist; // by default range [0, MAX]
std::uniform_int_distribution<uint32_t> uint_dist10(0,10); // range [0,10]
std::normal_distribution<double> normal_dist(mean, stddeviation); // N(mean, stddeviation)
...And use the engine to create random numbers!
std::cout << uint_dist(rng) << " "
<< uint_dist10(rng) << " "
<< normal_dist(rng) << std::endl;
One more important reason to prefer
<random> over the traditional
rand() is that it is now very clear and obvious how to make random number generation threadsafe: Either provide each thread with its own, thread-local engine, seeded on a thread-local seed, or synchronize access to the engine object.
- An interesting article on TR1 random on codeguru.
- Wikipedia has a good summary (thanks, @Justin).
- In principle, each engine should typedef a
result_type, which is the correct integral type to use for the seed. I think I had a buggy implementation once which forced me to force the seed for
uint32_t on x64, eventually this should be fixed and you can say
MyRNG::result_type seed_val and thus make the engine very easily replaceable.