# glibc rand function implementation

I'm reading c standard library rand() function implementation with glibc source code. stdlib/random_r.c, line 359

``````int
__random_r (buf, result)
struct random_data *buf;
int32_t *result;
{
int32_t *state;

if (buf == NULL || result == NULL)
goto fail;

state = buf->state;

if (buf->rand_type == TYPE_0)
{
int32_t val = state[0];
val = ((state[0] * 1103515245) + 12345) & 0x7fffffff;
state[0] = val;
*result = val;
}
else
{
int32_t *fptr = buf->fptr;
int32_t *rptr = buf->rptr;
int32_t *end_ptr = buf->end_ptr;
int32_t val;

val = *fptr += *rptr;
/* Chucking least random bit.  */
*result = (val >> 1) & 0x7fffffff;
++fptr;
if (fptr >= end_ptr)
{
fptr = state;
++rptr;
}
else
{
++rptr;
if (rptr >= end_ptr)
rptr = state;
}
buf->fptr = fptr;
buf->rptr = rptr;
}
return 0;

fail:
__set_errno (EINVAL);
return -1;
}
``````

I don't understand how random_r generate random number when `(buf->rand_type != TYPE_0)`, anyone please explain? Thanks.

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Looks like a standard old-fashioned linear congruential generator to me (Google it). Not a good algorithm, but OK for simple uses. –  Lee Daniel Crocker Sep 5 '13 at 13:51

The two implementations are exactly the same, except that they use different random data.

The `TYPE_0` always uses the magic numbers `1103515245` and `12345`, together with the current state.

Otherwise, it uses magic numbers taken from a pool of random data (presumably acquired from `/dev/urandom` or the like; I haven't checked). Each time it is called it walks a bit further through the pool. As it goes it replaces the data with new pseudo-random numbers, based on the original ones, so that it gets new numbers when it wraps around and starts the walk again.

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It does use a pool of random data, but not acquired from devices. –  lulyon Sep 6 '13 at 1:55
This answer is completely wrong and ridiculous. How could it be possible to use random `/dev/urandom` data in `rand()`? `rand()` is a pseudorandom generator, it must replay the same sequences for the same seed. It cannot use any random (or pseudorandom data which it does not control) as an input, because it would not be able to replay the same sequences for the same seed. –  Piotr Jurkiewicz Sep 13 at 2:32
The clause in brackets may be wrong, the rest not; i read the code. –  ams Sep 13 at 7:33

`glibc` `rand()` has two different generator implementations:

1. A simple linear congruential generator (LCG), defined by the following equation:

`val = ((state * 1103515245) + 12345) & 0x7fffffff`

(`& 0x7fffffff` throws away the least random most significant bit)

This is a very simple, single state LCG. It has some drawbacks. The most important is that, because it is a single state generator, it does not generate fully pseudorandom number on each `rand()` call. What it really do is that it traverses the whole range (2^31) in a pseudorandom order. It has a meaningful implication: when you obtained some number it means that you will not obtain that number again in the present period. You will obtain that number again in the next 2^31 `rand()` call, no sooner, no later.

This generator is called the `TYPE_0` in the `glibc` source.

2. A slightly more advanced, additive feedback generator. That generator has many states, what means that it does not have the "property of traversing" described above. You can get the same number twice (or more times) during the same period.

You can find an excellent description of that algorithm here.

This generator is called the `TYPE_1`, `TYPE_2`, `TYPE_3` or `TYPE_4` in the `glibc` source.

Coming back to your question, that is how it generates values:

``````seeding_stage() // (code omitted here, see the description from above link)

for (i=344; i<MAX; i++)
{
r[i] = r[i-31] + r[i-3];
val = ((unsigned int) r[i]) >> 1;
}
``````

The code after the `else` in your question is simply the above code, but written in different way (using pointers to the array containing previous values).

Which generator is used depends on the size of initial state set with the `initstate()` function. The first (LCG) generator is used only when state size is 8 bytes. When it is bigger, the second generator is used. When you set your seed using `srand()` the size of state is 128 bytes by default, so the second generator is used. Everything is written in comments in the `glibc` source file referenced by you in your question.

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In case anyone else needs a simple reimplementation of the GNU C Library's srand()/rand() functions, this C# class reproduces the generated random numbers exactly. The unchecked keyword is to explicitly allow integer overflow. (Based on Piotr Jurkiewicz's answer.)

``````public class GnuRand
{
private uint[] r;
private int n;

public GnuRand(uint seed)
{
r = new uint[344];

unchecked
{
r[0] = seed;
for (int i = 1; i < 31; i++)
{
r[i] = (uint)((16807 * (ulong)r[i - 1]) % 2147483647);
}
for (int i = 31; i < 34; i++)
{
r[i] = r[i - 31];
}
for (int i = 34; i < 344; i++)
{
r[i] = r[i - 31] + r[i - 3];
}
}

n = 0;
}

public int Next()
{
unchecked
{
uint x = r[n % 344] = r[(n + 313) % 344] + r[(n + 341) % 344];
n = (n + 1) % 344;
return (int)(x >> 1);
}
}
}
``````
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