Correct me if I'm wrong, but although this answer points to part of the implementation, I found that there is more to `rand()`

used in `stdlib`

, which is from `[glibc][2]`

. From the 2.32 version obtained from here, the `stdlib`

folder contains a `random.c`

file which explains that a simple linear congruential algorithm is used. The folder also has `rand.c`

and `rand_r.c`

which can show you more of the source code. `stdlib.h`

contained in the same folder will show you the values used for macros like `RAND_MAX`

.

/* An improved random number generation package. In addition to the
standard rand()/srand() like interface, this package also has a
special state info interface. The initstate() routine is called
with a seed, an array of bytes, and a count of how many bytes are
being passed in; this array is then initialized to contain
information for random number generation with that much state
information. Good sizes for the amount of state information are
32, 64, 128, and 256 bytes. The state can be switched by calling
the setstate() function with the same array as was initialized with
initstate(). By default, the package runs with 128 bytes of state

information and generates far better random numbers than a linear

congruential generator. If the amount of state information is less
than 32 bytes, a simple linear congruential R.N.G. is used.
Internally, the state information is treated as an array of longs;
the zeroth element of the array is the type of R.N.G. being used
(small integer); the remainder of the array is the state
information for the R.N.G. Thus, 32 bytes of state information
will give 7 longs worth of state information, which will allow a
degree seven polynomial. (Note: The zeroth word of state

information also has some other information stored in it; see setstate
for details). The random number generation technique is a linear
feedback shift register approach, employing trinomials (since there
are fewer terms to sum up that way). In this approach, the least
significant bit of all the numbers in the state table will act as a
linear feedback shift register, and will have period 2^deg - 1
(where deg is the degree of the polynomial being used, assuming
that the polynomial is irreducible and primitive). The higher order
bits will have longer periods, since their values are also
influenced by pseudo-random carries out of the lower bits. The

total period of the generator is approximately deg*(2**deg - 1); thus
doubling the amount of state information has a vast influence on the**

period of the generator. Note: The deg*(2deg - 1) is an
approximation only good for large deg, when the period of the shift
register is the dominant factor. With deg equal to seven, the
period is actually much longer than the 7*(2**7 - 1) predicted by
this formula. */

`rand()`

.)