generate random 64 bit integer

i need your help and please give me some advice.from programming pearls i have studded that to generate random 30 bit integer we should write like this

``````RAND_MAX*rand()+rand()
``````

but what could i do for generate not 30,but 64 bit random integer?i think that very inefficient method will be if i multiply two 30 bit integer and then multiply again 4 bit integer,so what kind of method should i use? i am using now popcount_1 different method for 64 bit and would like to test it on random integers(i am also measuring time which each one takes to accomplish task)

-
you can also shift and add them up.. –  duedl0r Nov 14 '11 at 10:19

This could be a solution, without multiplication:

``````r30 = RAND_MAX*rand()+rand()
s30 = RAND_MAX*rand()+rand()
t4  = rand() & 0xf

res = (r30 << 34) + (s30 << 4) + t4
``````
-
great thanks very much –  dato datuashvili Nov 14 '11 at 10:29
This assumes that `RAND_MAX` is 1<<15. If you do assume this, why not: `rand() + rand() << 15 + rand() << 30 + rand() << 45 + (rand() & 0xf) << 60` ? No multiplications at all. –  MSalters Nov 14 '11 at 14:39
Why not just do something like `return ((unsigned long long)rand() << 48) | ((unsigned long long)rand() << 32) | ((unsigned long long)rand() << 16) | ((unsigned long long)rand() & 0xffff);` ? Here you have no multiplications at all, just shifts. –  Inge Henriksen Apr 2 '13 at 10:13
Although, yes, you can generate 64 bits It would seem to me the resolution of the random number generated can't be larger than random number seed. –  Cris Sep 21 '13 at 12:16

If you're using C++11, look at http://en.cppreference.com/w/cpp/numeric/random.

-

First, I have my doubts about the solution you post for a 30 bit integer. `RAND_MAX` itself could be a 31 bit value, and ```RAND_MAX * rand() + rand()``` is likely to overflow, producing undefined behavior (and in practice, negative values).

If you need a value larger than the guaranteed minimum of `RAND_MAX`, or for that matter, anything that isn't significantly smaller than `RAND_MAX`, the only solution will be to use successive calls to `rand()`, and combine the values, but you need to do this carefully, and validate the results. (Most implementations of `rand()` use linear congruent generators, which while adequate for some tasks, aren't particularly good in this case.) Anyway, something like:

``````unsigned
rand256()
{
static unsigned const limit = RAND_MAX - RAND_MAX % 256;
unsigned result = rand();
while ( result >= limit ) {
result = rand();
}
return result % 256;
}

unsigned long long
rand64bits()
{
unsigned long long results = 0ULL;
for ( int count = 8; count > 0; -- count ) {
results = 256U * results + rand256();
}
return results;
}
``````

(The code in `rand256` is designed to eliminate the otherwise unavoidable bias you get when mapping `RAND_MAX` values to 256 values.)

-
How do I control the precision in this code. Say I want to generate 61 bit random numbers instead of 64 bits. I think if i start the count from 7 instead of 8, I would get a 56 bit random number. Am I right? –  arunmoezhi Nov 13 '13 at 1:25
@arunmoezhi If you can generate 64 random bits, you can generate 61 by generating 64, and throwing 3 away; e.g. by masking out the top three bits. –  James Kanze Nov 13 '13 at 9:31
makes sense. Thanks. Your solution looks nice. But it would be more helpful if you can add some explanations to it. It took me some time to understand what you were doing. –  arunmoezhi Nov 14 '13 at 6:50

If boost is an option, you could use boost random.

-
are you sure that it can generate 64bit? Your link states otherweise: "mt19937 produces integers in the range [0, 2^32-1]." –  duedl0r Nov 14 '11 at 10:26
Take a look at the various generators (boost.org/doc/libs/1_47_0/doc/html/boost_random/…), for instance at `ranlux64_3`. –  Andrea Bergia Nov 14 '11 at 10:30
@duedl0r If it does generate a good random value over the entire interval `[0, 2^32-1]`, then it should be rather trivial to combine two calls to generate a good 64 bit random value. (For a sufficiently loose definition of "good", of course. The basic generator still needs a period of 2^64 or more, or there will be a lot of values which can never be generated.) –  James Kanze Nov 14 '11 at 10:45
Statistically speaking, to generate all values you probably need a generator designed with a period of at least 2^64. Practically speaking, for most applications a simple solution with shifting / multiplications can work well enough. –  Andrea Bergia Nov 14 '11 at 10:53
With the default choice (mt19937), period really isn't an issue. 2^19937 is a whole lot more than the lifetime of the universe. –  MSalters Nov 14 '11 at 11:48

A random 64 bit int is essentially 64 random bits interpreted as an int.

Fill a byte array of length 8 with random bytes (see here for how) and interpret these as an int (see here for how).

-
I have a suspicion that with most implementations of `rand()` you won't get a particularly uniform distribution by doing that. –  Flexo Nov 14 '11 at 10:45

A generic solution:

``````template <unsigned long long I> struct log2 {
static const int result = 1 + log2<I/2>::result;
};
template <> struct log2<1> {
static const int result = 0;
};

template <typename UINT> UINT genrand() {
UINT result = 0;
int bits = std::numeric_limits<UINT>::digits;
int rand_bits = log2<RAND_MAX>::result;
while (bits > 0) {
int r = rand();
while (r >= (1<<rand_bits)) r = rand(); // Retry if too big.
result <<= rand_bits;
result += r;
bits -= rand_bits;
}
return result;
}
``````

Use: `unsigned long long R = genrand<unsigned long long>();`.

The `bits` counter keeps track of the number of bits still needed.

-