I'm having a theoretical (non-deterministic, hard to test, never happened in practice) hardware issue reported by hardware vendor where double-word write to certain memory ranges may corrupt any future bus transfers.

While I don't have any double-word writes explicitly in C code, I'm worried the compiler is allowed (in current or future implementations) to coalesce multiple adjacent word assignments into a single double-word assignment.

The compiler is not allowed to reorder assignments of volatiles, but it is unclear (to me) whether coalescing counts as reordering. My gut says it is, but I've been corrected by language lawyers before!


typedef struct
   volatile unsigned reg0;
   volatile unsigned reg1;
} Module;

volatile Module* module = (volatile Module*)0xFF000000u;

// two word stores, or one double-word store?
module->reg0 = 1;
module->reg1 = 2;

(I'll ask my compiler vendor about this separately, but I'm curious what the canonical/community interpretation of the standard is.)

  • 7
    Have you checked the assembly generated by the compiler to see whether it is doing this? May 20, 2021 at 8:57
  • 7
    If the memory is mapped as "cacheable" or "write-combinable" then it could be the MMU combining the two single-word writes into a double-word write.
    – Ian Abbott
    May 20, 2021 at 9:14
  • @EricPostpischil Working on it. Making scripts to filter out possible occurrences. Project build system is resisting :-(
    – Andreas
    May 20, 2021 at 10:49
  • @Lundin Now looking like it does in vendor API.
    – Andreas
    May 20, 2021 at 10:53

5 Answers 5


No, the compiler is absolutely not allowed to optimize those two writes into a single double word write. It's kind of hard to quote the standard since the part regarding optimizations and side effects is so fuzzily written. The relevant parts are found in C17

The semantic descriptions in this International Standard describe the behavior of an abstract machine in which issues of optimization are irrelevant.

Accessing a volatile object, modifying an object, modifying a file, or calling a function that does any of those operations are all side effects, which are changes in the state of the execution environment.

In the abstract machine, all expressions are evaluated as specified by the semantics. An actual implementation need not evaluate part of an expression if it can deduce that its value is not used and that no needed side effects are produced (including any caused by calling a function or accessing a volatile object).

Accesses to volatile objects are evaluated strictly according to the rules of the abstract machine.

When you access part of a struct, that in itself is a side-effect, which may have consequences that the compiler can't determine. Suppose for example that your struct is a hardware register map and those registers need to be written in a certain order. Like for example some microcontroller documentation could be along the lines of: "reg0 enables the hardware peripheral and must be written to before you can configure the details in reg1".

A compiler that would merge the volatile object writes into a single one would be non-conforming and plain broken.

  • 3
    Ohhh didn't think of the struct access. The pointer in this case should not be volatile then, leaving only the members volatile (and down the nested volatile rabbit hole we go). Damn, C is hard. Happy to see you were able to look past that. The "real" code in question does not have that aspect, but it was too gnarly to make a good example from.
    – Andreas
    May 20, 2021 at 11:10
  • 12
    @Andreas If the struct access is volatile, then member access will be volatile even if the members are not declared volatile. Same as for "const".
    – Ian Abbott
    May 20, 2021 at 12:14
  • This is wrong, though a very very common misconcpeption. The standard maps program texts to sequences of observable actions of the abstract machine. It does not say how those are reflected in reality. Moreover it explicitly says that what constitutes a volatile access, what gets to be a volatile externally observed action, is implementation-defined. The standard says nothing about object code.
    – philipxy
    May 21, 2021 at 23:56

The compiler is not allowed to make two such assignments into a single memory write. There must be two independent writes from the core. The answer from @Lundin gives relevant references to the C standard.

However, be aware that a cache - if present - may trick you. The keyword volatile doesn't imply "uncached" memory. So besides using volatile, you also need to make sure that the address 0xFF000000 is mapped as uncached. If the address is mapped as cached, the cache HW may turn the two assignments into a single memory write. In other words - for cached memory two core memory write operations may end up as a single write operation on the systems memory interface.

  • 6
    volatile absolutely means uncached memory. A system that does pre-fetch reads of volatile qualified variables is not compliant. volatile access has to be performed according to the sequence points placed around the variables. As CPUs have evolved, there's been attempts by hardware and/or compiler vendors to push this burden of memory barrier-like behavior onto the application programmers. But C has never allowed speculative or out of order execution of volatile access. It's not the application programmer's fault if someone has released hardware which can't execute compliant C.
    – Lundin
    May 20, 2021 at 10:16
  • 6
    @Lundin I like to see some reference for that claim as I disagree. Also this little example ideone.com/U8Sq9n shows that the compiler doesn't map volatile variables any different than ordinary variables. May 20, 2021 at 10:50
  • 17
    @Lundin: C has never allowed speculative or OoO execution of volatile access - that's different from "uncacheable". You seem to be talking about not hoisting loads/sinking stores out of loops in asm. But that's totally different from hardware prefetch on write-back cacheable memory regions. You can look at it as C guaranteeing that loads/stores to the cache coherency domain are a visible side-effect, not the true contents of DRAM. SW can't observe DRAM (except possibly via another mapping of the same physical address, or on a hypothetical system with non-coherent shared memory) May 20, 2021 at 17:17
  • 13
    @Lundin: If you want MMIO accesses to work properly, you need to make sure the address range including the MMIO address is mapped uncacheable even if you're writing asm by hand; it's implausible and impractical for a C compiler to do this for you for global volatile int foo;. May 20, 2021 at 17:19
  • 7
    @Lundin You can qualify automatic variables as volatile. Does that mean then that the compiler has to emit code to turn off caching for that section of the stack? Never seen that before and seems absurd. (an automatic variable qualified volatile is quite useful e.g. if you single-step through the program and want to change it from a debugger).
    – fuz
    May 21, 2021 at 12:21

The behavior of volatile seems to be up to the implementation, partly because of a curious sentence which says: "What constitutes an access to an object that has volatile-qualified type is implementation-defined".

In ISO C 99, section, there is also:

3 In the abstract machine, all expressions are evaluated as specified by the semantics. An actual implementation need not evaluate part of an expression if it can deduce that its value is not used and that no needed side effects are produced (including any caused by calling a function or accessing a volatile object).

So although requirements are given that a volatile object must be treated in accordance with the abstract semantics (i.e not optimized), curiously, the abstract semantics itself allows for the elimination of dead code and data flows, which are examples of optimizations!

I'm afraid that to know what volatile will and will not do, you have to go by your compiler's documentation.

  • Made me look deeper into vendor docs. Found this in section describing implementation defined behavior: "What constitutes an access to an object that has volatile-qualified type (6.7.3)." - Any reference to an object with volatile type results in an access. The order in which volatile objects are accessed is defined by the order expressed in the source code. References to non-volatile objects are scheduled in arbitrary order, within the constraints given by dependencies. (Followed by a paragraph on how passing a flag to the compiler makes any volatile access a memory barrier!)
    – Andreas
    May 25, 2021 at 7:51
  • @Andreas About the original question: if you have a program which depends on writes to that structure not being coalesced, it is unlikely you are working in the realm of portable ISO C. On the other hand, there are a couple of required uses of volatile in strictly conforming programs: use of volatile sig_atomic_t in an asynchronous signal handler,and using volatile on the local variables of a function which are modified between context being saved with setjmp and restored with longjmp. As far as standard C is concerned, we can regard volatile as existing for those situations.
    – Kaz
    May 25, 2021 at 8:24

The C Standard is agnostic to any relationship between operations on volatile objects and operations on the actual machine. While most implementations would specify that a construct like *(char volatile*)0x1234 = 0x56; would generate a byte store with value 0x56 to hardware address 0x1234, an implementation could, at its leisure, allocate space for e.g. an 8192-byte array and specify that *(char volatile*)0x1234 = 0x56; would immediately store 0x56 to element 0x1234 of that array, without ever doing anything with hardware address 0x1234. Alternatively, an implementation may include some process that periodically stores whatever happens to be in 0x1234 of that array to hardware address 0x56.

All that is required for conformance is that all operations on volatile objects within a single thread are, from the standpoint of the Abstract machine, regarded as absolutely sequenced. From the point of view of the Standard, implementations can convert such accesses into real machine operations in whatever fashion they see fit.

  • 2
    Moreover what constitutes a volatile access is implementation-defined.
    – philipxy
    May 22, 2021 at 0:00
  • 1
    @philipxy: Indeed so. Commercial compilers would generally treat a volatile write as forcing a compiler to effectively flush all "register cached" objects, allowing code for things like background I/O that were written for any such compiler on a particular platform to work with any other vendor's compiler that used similar semantics. Clang and gcc, however, refuse to support such semantics since they view such code as "broken".
    – supercat
    May 23, 2021 at 6:03

Changing it will change the observable behavior of the program. So compiler is not allowed to do so.

  • 6
    The sequence of actual hardware memory operations is only "observable" if an implementation chooses to specify it as such. Nothing would forbid an implementation from include its own virtual machine where volatile stores update the virtual machine state immediately, but such updates take awhile to be translated into operations on real machine hardware.
    – supercat
    May 20, 2021 at 20:44

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