Versions Compared

Key

  • This line was added.
  • This line was removed.
  • Formatting was changed.

Wiki MarkupAs described in - depth in [DCL34-C. Use volatile for data that cannot be cached|DCL34in rule DCL22-C. Use volatile for data that cannot be cached], a {{volatile}}\-qualified variable "shall be evaluated strictly according to the rules of the abstract machine" \ [[ISO/IEC 9899:1999|AA. C References#ISO/IEC 9899-1999]\].  In other words, the {{volatile}} qualifier is used to instruct the compiler to not make caching optimizations about a variable.

Wiki Markup
However, as demonstrated in \[[Eide and Regehr|AA. C References#Eide and Regehr]\], all tested compilers generated some percentage of incorrect compiled code with regards to {{volatile}} accesses.  Therefore, it is necessary to know how your compiler behaves when the standard {{volatile}} behavior is required.  There is also a workaround that eliminates some or all of these errors \[[Eide and Regehr|AA. C References#Eide and Regehr]\].

Noncompliant Code Example

2011]. In other words, the volatile qualifier is used to instruct the compiler to not make caching optimizations about a variable.

However, as demonstrated in "Volatiles Are Miscompiled, and What to Do about It" [Eide and Regehr], all tested compilers generated some percentage of incorrect compiled code with regard to volatile accesses. Therefore, it is necessary to know how your compiler behaves when the standard volatile behavior is required. The authors also provide a workaround that eliminates some or all of these errors.

Noncompliant Code Example

As demonstrated in Eide and Regehr's work, the following code example compiles incorrectly using GCC 4.3.0 for IA32 and the -Os optimization Wiki MarkupAs demonstrated in \[[Eide and Regehr|AA. C References#Eide and Regehr]\], the following code example compiles incorrectly using GCC version 4.3.0 for IA32 and the {{\-Os}} optimization flag:

Code Block
bgColor#ffcccc
langc
const volatile int x;
volatile int y;
void foo(void) {
  for(y = 0; y < 10; y++) {
    int z = x;
  }
}

...

Because the variable {{x}} is {{volatile}}\-qualified, it should be accessed ten accessed 10 times in this program. &nbsp; However, as shown in the compiled object code, it is accessed only accessed once due to a loop-hoisting optimization \ [[Eide and Regehr|AA. C References#Eide and Regehr]\]:

Code Block
bgColor#ffcccc
langc

foo:
  movl $0, y
  movl x, %eax
  jmp .L2
.L3:
  movl y, %eax
  incl %eax
  movl %eax, y
.L2:
  movl y, %eax
  cmpl $10, %eax
  jg .L3
  ret

Should x represent a hardware register or some other memory-mapped device that has side effects when accessed, the previous miscompiled code example may produce unexpected behavior.

Compliant Solution

...

Eide and Regehr tested a workaround by wrapping {{volatile}} accesses with function calls. &nbsp; They describe it with the intuition that "we can replace an action that compilers empirically get wrong by a different action --- a function call --- that compilers can get right" \[[Eide and Regehr|AA. C References#Eide and Regehr]\]. For example, the workaround for the noncompliant code example would be:different action—a function call—that compilers can get right" [Eide and Regehr]. For example, the workaround for the noncompliant code example would be

Code Block
bgColor#ccccff
langc

int vol_read_int(volatile int *vp) {
  return *vp;
}
volatile int *vol_id_int(volatile int *vp) {
  return vp;
}

const volatile int x;
volatile int y;
void foo(void) {
  for(*vol_id_int(&y) = 0; vol_read_int(&y) < 10; *vol_id_int(&y) = vol_read_int(&y) + 1) {
    int z = vol_read_int(&x);
  }
}

...

The workarounds proposed in \[[Eide and Regehr|AA. C References#Eide and Regehr]\] fix many of the {{volatile}}\-access bugs in the tested compilers.&nbsp; However, compilers are always changing so critical sections of code should be compiled as if for deployment and the compiled object code should be inspected for the correct behavior.

...

proposed by Eide and Regehr fix many of the volatile-access bugs in the tested compilers. However, compilers are always changing, so critical sections of code should be compiled as if for deployment, and the compiled object code should be inspected for the correct behavior.

Risk Assessment

The volatile qualifier should be used with caution in mission-critical situations. Always make sure that code that assumes certain behavior when using the volatile qualifier is inspected at the object code level for compiler bugs.

Rule

Severity

Likelihood

Remediation Cost

Priority

Level

DCL17-C

medium Medium

probable Probable

high High

P4

L3

References

...

Automated Detection

Tool

Version

Checker

Description

LDRA tool suite 
Include Page
LDRA_V
LDRA_V
134 SPartially implemented

Bibliography

[Eide and Regehr]"Volatiles Are Miscompiled, and What to Do about It"
[ISO/IEC 9899:2011]Subclause 6.7.3,

...

"Type

...

Qualifiers"

 

...

Image Added Image Added Image AddedDCL16-C. Use 'L', not 'l', to indicate a long value      02. Declarations and Initialization (DCL)      DCL18-C. Beware integer constants beginning with 0