A pseudorandom number generator (PRNG) is a deterministic algorithm capable of generating sequences of numbers that approximate the properties of random numbers. Each sequence is completely determined by the initial state of the PRNG and the algorithm for changing the state. Most PRNGs make it possible to set the initial state, also called the seed state. Setting Setting the initial state is called called seeding the PRNG.
Calling a PRNG in the same initial state, either without seeding it explicitly or by seeding it with the same value, results in generating the same sequence of random numbers in different runs of the program. Suppose Consider a PRNG function that is called 10 times consecutively seeded with some initial seed value and is consecutively called to produce a sequence of 10 random numbers. Suppose also that this , S
. If the PRNG is not subsequently seeded . Running the code for the first time produces the sequence S = <r1, r2, r3, r4, r5, r6, r7, r8, r9, r10>
. Running the code a second time produces exactly the same S
sequence. Generally, any subsequent runs of the code with the same initial seed value, then it will generate the same sequence S
sequence.
As a result, after the first run of the an improperly seeded PRNG, an attacker can predict the sequence of random numbers that will be generated in the future runs. Improperly seeding or failing to seed the PRNG can lead to many vulnerabilities, especially in security protocols.
The solution is to always to ensure that your the PRNG is always properly seeded. Seeding a PRNG means that it A properly seeded PRNG will generate a different sequences sequence of random numbers at any call.each time it is run.
Not It is worth noting that not all random number generators can be seeded. True random number generators that rely on hardware to produce completely unpredictable results do not need to be and cannot be seeded. Some high-quality PRNGs, such as the /dev/random
device on some UNIX systems, also cannot be seeded. This rule applies only to algorithmic pseudorandom generators that make seeding possible.
MSC30-C. Do not use the rand() function for generating pseudorandom numbers addresses PRNGs from a different perspective, which is the cycle of the pseudorandom number sequence—that is, during a single run of a PRNG, the time interval after which the PRNG generates the same random numbers. MSC30-C disallows use of the rand()
function because it generates numbers that have a comparatively short cycle. The same rule proposes the use of the random()
function for POSIX and the CryptGenRandom()
function for Windows.
This rule examines, in terms of seeding, all three PRNGs mentioned in rule MSC30-C. Noncompliant code examples correspond to the use of a PRNG without a seed, while compliant solutions correspond to the same PRNG being properly seeded. This rule complies with MSC30-C and does not recommend the use of the rand()
function. Nevertheless, if it is unavoidable to use rand()
, it should at least be properly seeded.
Noncompliant Code Example
This noncompliant code example generates a sequence of 10 pseudorandom numbers using the rand()
function. When rand()
is not seeded, it uses 1
as a default seed. No matter how many times this code is executed, it always produces the same sequence.
Code Block | ||||
---|---|---|---|---|
| ||||
#include <stdio.h>
#include <stdlib.h>
void func(void) {
for (int i = 0; i < 10; ++i) {
/* Always generates the same sequence */
printf("%d, ", rand());
}
}
|
output:
1st run: 41, 18467, 6334, 26500, 19169, 15724, 11478, 29358, 26962, 24464,
2nd run: 41, 18467, 6334, 26500, 19169, 15724, 11478, 29358, 26962, 24464,
...
nth run: 41, 18467, 6334, 26500, 19169, 15724, 11478, 29358, 26962, 24464,
Noncompliant Code Example
Use srand()
before rand()
to seed the random sequence generated by rand()
. The code produces different random number sequences at different calls.
Code Block | ||||
---|---|---|---|---|
| ||||
#include <stdio.h>
#include <stdlib.h>
#include <time.h>
void func(void) {
srand(time(NULL)); /* Create seed based on current time */
for (int i = 0; i < 10; ++i) {
/* Generates different sequences at different runs */
printf("%d, ", rand());
}
} |
output:
1st run: 25121, 15571, 29839, 2454, 6844, 10186, 27534, 6693, 12456, 5756,
2nd run: 25134, 25796, 2992, 403, 15334, 25893, 7216, 27752, 12966, 13931,
3rd run: 25503, 27950, 22795, 32582, 1233, 10862, 31243, 24650, 11000, 7328,
Although the rand()
function is now properly seeded, this solution is still noncompliant because the numbers generated by rand()
have a comparatively short cycle, and the numbers can be predictable. (See MSC30-C. Do not use the rand() function for generating pseudorandom numbers.)
number generators that can be seeded.
Noncompliant Code Example (
...
POSIX)
This noncompliant code example generates a sequence of 10 pseudorandom numbers using the random()
function. When random()
is not seeded, it behaves like rand()
, producing the same sequence of random numbers at different callseach time any program that uses it is run.
Code Block | ||||
---|---|---|---|---|
| ||||
#include <stdio.h>
#include <stdlib.h>
void func(void) {
for (unsigned int i = 0; i < 10; ++i) {
/* Always generates the same sequence */
printf("%ld, ", random());
}
} |
The output
...
is as follows:
Code Block |
---|
1st run: 1804289383, 846930886, 1681692777, 1714636915, 1957747793, 424238335, 719885386, 1649760492, 596516649, 1189641421, 2nd run: 1804289383, 846930886, 1681692777, 1714636915, 1957747793, 424238335, 719885386, 1649760492, 596516649, 1189641421, ... nth run: 1804289383, 846930886, 1681692777, 1714636915, 1957747793, 424238335, 719885386, 1649760492, 596516649, 1189641421, |
...
Compliant Solution (POSIX)
Use Call srandom()
before invoking random()
to seed the random sequence generated by random()
. The code This compliant solution produces different random number sequences at different calls.each time the function is called, depending on the resolution of the system clock:
Code Block | ||||
---|---|---|---|---|
| ||||
#include <stdio.h> #include <stdlib.h> #include <time.h> void func(void) { /*struct Createtimespec seedts; based on current time counted as secondsif (timespec_get(&ts, TIME_UTC) == 0) { /* from 01/01/1970Handle error */ srandom(time(NULL))} else { srandom(ts.tv_nsec ^ ts.tv_sec); for (unsigned int i = 0; i < 10; ++i) { /* Generates different sequences at different runs */ printf printf("%ld, ", random()); } } } |
The output
...
is as follows:
Code Block |
---|
1st run: 198682410, 2076262355, 910374899, 428635843, 2084827500, 1558698420, 4459146, 733695321, 2044378618, 1649046624, 2nd run: 1127071427, 252907983, 1358798372, 2101446505, 1514711759, 229790273, 954268511, 1116446419, 368192457, 1297948050, 3rd run: 2052868434, 1645663878, 731874735, 1624006793, 938447420, 1046134947, 1901136083, 418123888, 836428296, 2017467418, |
...
This may not be sufficiently random for concurrent execution, which may lead to correlated generated series in different threadsIn the previous examples, seeding in rand()
and random()
is done using the time()
function, which returns the current time calculated as the number of seconds that have passed since January 1, 1970. Depending on the application and the desirable desired level of security, a programmer may choose alternative ways to seed PRNGs. In general, hardware is more capable than humans software of generating real random numbers (for example, by generating a sequence of bits by sampling the thermal noise of a diode and using the result as a seed).
Compliant Solution (Windows)
CryptGenRandomThe BCryptGenRandom()
function does not run the risk of not being properly seeded because its arguments serve as seeders.:
Code Block | ||||
---|---|---|---|---|
| ||||
#include <stdio.h> #include <Windows.h> #include <Bcrypt.h> #include <wincrypt<Ntstatus.h> #include <stdio<Wincrypt.h> void func(void) { HCRYPTPROV hCryptProvBCRYPT_ALG_HANDLE hAlgorithm = NULL; long rand_buf; /*PUCHAR AnpbBuffer example= of instantiating the CSP */ if (CryptAcquireContext(&hCryptProv, NULL, NULL, PROV_RSA_FULL, 0)) { printf("CryptAcquireContext succeeded.\n"); } else { printf("Error during CryptAcquireContext!\n"); } (PUCHAR) &rand_buf; ULONG cbBuffer = sizeof(rand_buf); ULONG dwFlags = BCRYPT_USE_SYSTEM_PREFERRED_RNG; NTSTATUS status; for (unsigned int i = 0; i < 10; ++i) { status if= (!CryptGenRandom(hCryptProv, sizeof(rand_buf), (BYTE *)&rand_buf))BCryptGenRandom(hAlgorithm, pbBuffer, cbBuffer, dwFlags); if (status == STATUS_SUCCESS) { printf("Error\n"%ld, ", rand_buf); } else { printf("%ld, ", rand_buf);/* Handle Error */ } } } |
The output
...
is as follows:
Code Block |
---|
1st run: - |
...
683378946, |
...
1957231690, |
...
1933176011, |
...
-1745403355, - |
...
883473417, |
...
882992405, |
...
169629816, |
...
1824800038, |
...
899851668, |
...
1702784647, 2nd run: |
...
-58750553, - |
...
1921870721, - |
...
1973269161, |
...
1512649964, - |
...
673518452, |
...
234003619, - |
...
1622633366, 1312389688, - |
...
2125631172, |
...
2067680022, |
...
3rd run: |
...
-189899579, |
...
1220698973, |
...
752205360, - |
...
1826365616, |
...
79310867, |
...
1430950090, |
...
-283206168, - |
...
941773185, |
...
129633665, |
...
543448789, |
Risk Assessment
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
MSC32-C | Medium | Likely | Low | P18 | L1 |
Automated Detection
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
Astrée |
| Supported, but no explicit checker | |||||||
Axivion Bauhaus Suite |
| CertC-MSC32 | |||||||
CodeSonar |
| HARDCODED.SEED | Hardcoded Seed in PRNG | ||||||
Cppcheck Premium |
| premium-cert-msc32-c | Fully implemented | ||||||
Helix QAC |
| C5031 C++5036 | |||||||
Klocwork |
| CERT.MSC.SEED_RANDOM | |||||||
PC-lint Plus |
| 2460, 2461, 2760 | Fully supported | ||||||
Polyspace Bug Finder |
| Checks for:
Rule fully covered. | |||||||
Parasoft C/C++test |
| CERT_C-MSC32-d | Properly seed pseudorandom number generators |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Related Guidelines
Key here (explains table format and definitions)
Taxonomy | Taxonomy item | Relationship |
---|---|---|
CERT C Secure Coding Standard | MSC30-C. Do not use the rand() function for generating pseudorandom numbers | Prior to 2018-01-12: CERT |
: Unspecified Relationship | |
CERT C | MSC51 |
-CPP. Ensure your random number generator is properly seeded |
Prior to 2018-01-12: CERT: Unspecified Relationship | |
CWE 2.11 | CWE-327, Use of a |
CWE-330, Use of insufficiently random values
Broken or Risky Cryptographic Algorithm | 2017-05-16: CERT: Rule subset of CWE | |
CWE 2.11 | CWE-330, Use of Insufficiently Random Values | 2017-06-28: CERT: Rule subset of CWE |
CWE 2.11 | CWE-331, Insufficient Entropy | 2017-06-28: CERT: Exact |
CERT-CWE Mapping Notes
Key here for mapping notes
CWE-327 and MSC32-C
- Intersection( MSC30-C, MSC32-C) = Ø
- MSC32-C says to properly seed pseudorandom number generators. For example, if you call rand(), make sure to seed it properly by calling srand() first. So far, we haven’t found any calls to rand().
- Failure to seed a PRNG causes it to produce reproducible (hence insecure) series of random numbers.
- CWE-327 = Union( MSC32-C, list) where list =
- Invocation of broken/risky crypto algorithms that are not properly seeded
CWE-330 and MSC32-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.
Bibliography
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