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Pseudo random Pseudorandom number generators use mathematical algorithms to produce a sequence of numbers with good statistical properties, but the numbers produced are not genuinely random.

The C Standard function rand(available in stdlib.h) does not have good random number properties) function makes no guarantees as to the quality of the random sequence produced. The numbers generated by some implementations of rand() have a comparatively short cycle , and the numbers may can be predictable. To achieve the best random numbers possible, an implementation-specific function must be used.

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 Applications that have strong pseudorandom number requirements must use a generator that is known to be sufficient for their needs.

Noncompliant Code Example

The following noncompliant code generates an ID with a numeric part produced by calling the rand() function. The IDs produced are predictable and have limited randomness.

#include <stdio.h>
#include <stdlib.h>
 
enum { len = 12 };
char id[len];
 
void func(void) {
  /*
   * id will hold the ID, starting with the characters "ID" */
   *  "ID" followed by a random integer.
     */*
  followed by a random integer */
char id[len];  
  int r;
  int num;
  /* ... */
  r = rand();  /* generateGenerate a random integer */
  num = snprintf(id, len, "ID%-d", r);  /* generateGenerate the ID */
  /* ... */
}

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Compliant

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Solution (

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POSIX)

A better pseudo random number generator is the BSD function This compliant solution replaces the rand() function with the POSIX random(). function:

#include <stdio.h>
#include <stdlib.h>
#include <time.h>

enum { len = 12 };
char id[len]; 

void func(void) {
  /*
   * id will hold the ID, starting with the characters "ID" */
   *  "ID" followed by a random integer.
     */*
  followed by a random integer */
char id[len];  
  int r;
  int num;
  /* ... */
srandom(time(0)
  struct timespec ts;
  if (timespec_get(&ts, TIME_UTC) == 0) {
    /* Handle error */
  }
  srandom(ts.tv_nsec ^ ts.tv_sec);  /* seedSeed the PRNG with the current time */
  /* ... */
  r = random();  /* generateGenerate a random integer */
  num = snprintf(id, len, "ID%-d", r);  /* generateGenerate the ID */
  /* ... */
}

However, the The POSIX random() function uses time(0) as seed. With a trivial seed like time(0), however, the results from random() are also predictable.

Compliant Solution (Linux, Solaris, Mac OS X, NetBSD, OpenBSD)

To generate an unpredictable number, use an unpredictable seed and a cryptographically strong mixing function. On Unix systems, for example, decent results can be obtained by reading /dev/urandom, which will not block the application.

When unpredictability really matters (session IDs and crypto keys) use a cryptographical library and seed it with data that are read from /dev/random.

is a better pseudorandom number generator. Although on some platforms the low dozen bits generated by rand() go through a cyclic pattern, all the bits generated by random() are usable. The rand48 family of functions provides another alternative for pseudorandom numbers.

Although not specified by POSIX, arc4random() is another possibility for systems that support it. The arc4random(3) manual page [OpenBSD] states

... provides higher quality of data than those described in rand(3), random(3), and drand48(3).

To achieve the best random numbers possible, an implementation-specific function must be used. When unpredictability is crucial and speed is not an issue, as in the creation of strong cryptographic keys, use a true entropy source, such as /dev/random, or a hardware device capable of generating random numbers. The /dev/random device may can block for a long time if there are not enough events going on to generate sufficient randomness; /dev/urandom does not block.)The rand48 family of functions provides another psuedo-random alternativeentropy.

Compliant Solution (Windows)

On Windows platforms, the BCryptGenRandom() function can be used to generate cryptographically strong random numbers. The Microsoft Developer Network BCryptGenRandom() reference [MSDN] states:

The default random number provider implements an algorithm for generating random numbers that complies with the NIST SP800-90 standard, specifically the CTR_DRBG portion of that standard.

#include <Windows.h>
long int li;
FILE* fd;

if(!(fd = fopen("/dev/random", "r")#include <bcrypt.h>
#include <stdio.h>

#pragma comment(lib, "Bcrypt")

void func(void) {
  BCRYPT_ALG_HANDLE Prov;
 /* Handleint errorBuffer;
 condition */
}

if(fread(&li, sizeof(li), 1, fd) != sizeof(li (!BCRYPT_SUCCESS(
          BCryptOpenAlgorithmProvider(&Prov, BCRYPT_RNG_ALGORITHM,
                                      NULL, 0))) {
    /* Handlehandle error condition */
}

fclose(fd);

printf("Random number: %ld\n", li);

Compliant Solution (Windows)

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(someone on a Windows machine should test this out - avolkovi)

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On Windows platforms, the CryptGenRandom() function may be used to generate cryptographically strong random numbers. It is important to note, however, that the exact details of the implementation are unknown, and it is undetermined as to what source of entropy the CryptGenRandom() uses.

If an application has access to a good random source, it can fill the pbBuffer buffer with some random data before calling CryptGenRandom(). The CSP then uses this data to further randomize its internal seed. It is acceptable to omit the step of initializing the pbBuffer buffer before calling CryptGenRandom().

#include<Wincrypt.h>

 
HCRYPTPROV hCryptProv;
union {
    BYTE bs[sizeof(long int)];
    long int li;
} rand_buf;

if(!CryptGenRandom(hCryptProv, sizeof(rand_buf), &rand_buf  }
  if (!BCRYPT_SUCCESS(BCryptGenRandom(Prov, (PUCHAR) (&Buffer),
                                      sizeof(Buffer), 0))) {
    /* Handlehandle error */
} else {}
    printf("Random number: %ld%d\n", Buffer);
  BCryptCloseAlgorithmProvider(Prov, rand_buf.li0);
}

Risk Assessment

Using The use of the rand() function leads to possibly can result in predictable random numbers.

Automated Detection

Related Vulnerabilities

Search for vulnerabilities resulting from the violation of this rule on the CERT website.

References

\[[ISO/IEC 9899-1999|AA. C References#ISO/IEC 9899-1999]\] Section 7.20.2.1, "The rand function"

Related Guidelines

Key here (explains table format and definitions)

CERT-CWE Mapping Notes

Key here for mapping notes

CWE-327 and MSC30-C

• CWE-327 forbids “broken or risky cryptographic algorithms” but does not specify what constitutes such an algo.

• Per CERT judgement, rand() qualifies, so:

• CWE-327 = Union( MSC30-C, list) where list =

• Invocation of broken/risky crypto algorithms besides rand()

CWE-338 and MSC30-C

CWE-338 = Union( MSC30-C, list) where list =

• Use of a weak PRNG besides standard C rand().

CWE-330 and MSC30-C

Independent( MSC30-C, MSC32-C, CON33-C)

CWE-330 = Union( MSC30-C, MSC32-C, CON33-C, list) where list = other improper use or creation of random values. (EG the would qualify)

MSC30-C, MSC32-C and CON33-C are independent, they have no intersections. They each specify distinct errors regarding PRNGs.

CWE-676 and MSC30-C

• Independent( ENV33-C, CON33-C, STR31-C, EXP33-C, MSC30-C, ERR34-C)

• MSC30-C implies that rand() is dangerous.

• CWE-676 = Union( MSC30-C, list) where list =

• Invocation of other dangerous functions, besides rand().

Bibliography

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Image Added Image Added Image AddedMSC13-A. Detect and remove unused values      14. Miscellaneous (MSC)       MSC31-C. Ensure that return values are compared against the proper type