Declaring function arguments parameters const
indicates that the function promises not to change these values.
In C, function arguments are passed by value rather than by reference. While Although a function may change the values passed in, these changed values are discarded once the function returns. For this reason, most many programmers assume a function will not change its arguments , and declaring them that declaring the function's parameters as const
is unnecessary.
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void foo(int x) { x = 3; /* Visible only lastsin untilthe end of function */ /* ... */ } |
Pointers behave in a similar fashion. A function may change a pointer to reference a different object, or NULL
, yet that change is discarded once the function exits. Consequently, declaring a pointer as const
is unnecessary.
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void foo(int *x) { x = NULL; /* Visible only lasts until end ofin the function */ /* ... */ } |
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Noncompliant Code Example
Unlike passed-by-value arguments and pointers, pointed-to values are a concern. A function may modify a value referenced by a pointer argument, with the modification being retained leading to a side effect that persists even after the function exits. Modification of the pointed-to value is not diagnosed by the compiler, which assumes this behavior was intended.
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void foo(int *x) { if (x != NULL) { *x = 3; /* visibleVisible outside function */ } /* ... */ } |
...
If a function modifies a the function parameter is const
-qualified, any attempt to modify the pointed-to value , declaring this value as const
will be caught by the compilershould cause the compiler to issue a diagnostic message.
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void foo(const int const * x) { if (x != NULL) { *x = 3; /* generates compiler errorCompiler should generate diagnostic message */ } /* ... */ } |
As a result, the const
violation must be resolved before the code can be compiled without a diagnostic message being issued.
Compliant Solution
If a function does not modify the pointed-to value, it should declare this value as const
. This improves code readability and consistency.This compliant solution addresses the const
violation by not modifying the constant argument:
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void foo(const int const * x) { if (x != NULL) { printf("Value is %d\n", *x); } /* ... */ } |
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Noncompliant Code Example
This non-compliant noncompliant code example , defines a fictional version of the standard strcat()
function called strcat_nc()
. This function differs from strcat()
in that the second argument is not const
-qualified.
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char *strcat_nc(char *s1, char *s2); char *c_str1 = "c_str1"; const char const *c_str2 = "c_str2"; char c_str3[9] = "c_str3"; const char const c_str4[9] = "c_str4"; strcat_nc(c_str3, c_str2); /* Compiler warns that c_str2 is const */ strcat_nc(c_str1, c_str3); /* Oops, attemptsAttempts to overwrite string literal! */ strcat_nc(c_str4, c_str3); /* Compiler warns that c_str4 is const */ |
The function would behave behaves the same as strcat()
, but the compiler generates warnings in incorrect locations , and fails to generate them in correct locations.
In the first strcat_nc()
call, the compiler will generate generates a warning about attempting to cast away const
on str2
. This is a good warning, as c_str2
because strcat_nc()
does not modify its second argument , yet fails to declare it const
.
In the second strcat_nc()
call, the compiler will happily compile compiles the code with no warnings, but the resulting code will attempt to modify the "c_str1"
literal, which may be impossible; the literal may not be defined in the heap. This violates STR05-AC. Use pointers to const when referring to string literals and STR30-C. Do not attempt to modify string literals.
In the final strcat_nc()
call, the compiler generates a warning about ateempting attempting to cast away const
on c_str4
. This , which is a valid warning.
Compliant Solution
This compliant solution uses the prototype for the strcat()
from C90. Although the restrict
type qualifier did not exist in C90, const
did. In general, the arguments function parameters should be declared in a manner consistent with the semantics of the function. In the case of strcat()
, the initial argument can be changed by the function while , but the second argument cannot.
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char *strcat(char *s1, const char const *s2); char *c_str1 = "c_str1"; const char const *c_str2 = "c_str2"; char c_str3[9] = "c_str3"; const char const c_str4[9] = "c_str4"; strcat(c_str3, c_str2); strcat(str3, str1); /* Args reversed to prevent overwriting string literal */ strcat(c_str3, c_str1); strcat(c_str4, c_str3); /* Compiler warns that c_str4 is const */ |
The const
-qualification of the second argument, s2
, eliminates the spurious warning in the initial invocation , but maintains the valid warning on the final invocation in which a const
-qualified object is passed as the first argument (which can change). Finally, the middle strcat()
invocation is now valid , as str1
because c_str3
is a valid destination string, as the string exists on the stack and may be safely modified.
Risk Assessment
Not declaring Failing to declare an unchanging value const
prohibits the function from working with values already cast as const
. One could sidestep this problem by typecasting This problem can be sidestepped by type casting away the const
, but that doing so violates EXP05-AC. Do not cast away a const qualification.
Recommendation | Severity | Likelihood | Remediation Cost | Priority | Level |
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DCL13-C | Low | Unlikely | Low | P3 | L3 |
Automated Detection
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
Astrée |
| parameter-missing-const | Fully checked | ||||||
Axivion Bauhaus Suite |
| CertC-DCL13 | |||||||
CodeSonar |
| LANG.TYPE.CBCONST | Pointed-to Type Could Be const | ||||||
Compass/ROSE | Can detect violations of this recommendation while checking for violations of recommendation DCL00-C. Const-qualify immutable objects | ||||||||
| CC2.DCL13 | Fully implemented | |||||||
Helix QAC |
| C0431, C3673, C3677 | |||||||
Klocwork |
| MISRA.PPARAM.NEEDS.CONST | |||||||
LDRA tool suite |
| 120 D | Fully implemented | ||||||
Parasoft C/C++test |
| CERT_C-DCL13-a | A |
medium
unlikely
high
P2
pointer parameter in a function prototype should be declared as pointer to const if the pointer is not used to modify the addressed object | |||||||||
PC-lint Plus |
| 111, 818 | Fully supported | ||||||
Polyspace Bug Finder |
| CERT C: Rec. DCL13-C | Checks for pointer to non-const qualified function parameter (rec. fully covered) | ||||||
RuleChecker |
| parameter-missing-const | Fully checked |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
References
Wiki Markup |
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\[[ISO/IEC 9899-1999|AA. C References#ISO/IEC 9899-1999]\]
\[[ISO/IEC PDTR 24772|AA. C References#ISO/IEC PDTR 24772]\] "CSJ Passing parameters and return values" |
Related Guidelines
SEI CERT C++ Coding Standard | VOID DCL13-CPP. Declare function parameters that are pointers to values not changed by the function as const |
ISO/IEC TR 24772:2013 | Passing Parameters and Return Values [CSJ] |
MISRA C:2012 | Rule 8.13 (advisory) |
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DCL12-A. Create and use abstract data types 02. Declarations and Initialization (DCL)