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C++ compilers are allowed to optimize away writes into memory:

     //all this code can be eliminated
     char buffer[size];
     std::fill_n( buffer, size, 0);

When dealing with sensitive data the typical approach is using volatile* pointers to ensure that memory writes are emitted by the compiler. Here's how SecureZeroMemory() function in Visual C++ runtime library is implemented (WinNT.h):

     __in_bcount(cnt) PVOID ptr, __in SIZE_T cnt )
    volatile char *vptr = (volatile char *)ptr;
#if defined(_M_AMD64)
    __stosb((PBYTE )((DWORD64)vptr), 0, cnt);
    while (cnt) {
        *vptr = 0;
    return ptr;

The function casts the passed pointer to a volatile* pointer and then writes through the latter. However if I use it on a local variable:

char buffer[size];
SecureZeroMemory( buffer, size );

the variable itself is not volatile. So according to C++ Standard definition of observable behavior writes into buffer don't count as observable behavior and looks like it can be optimized away.

Now there're a lot of comments below about page files, caches, etc, which are all valid, but let's just ignore them in this question. The only thing this question is about is whether the code for memory writes is optimized away or not.

Is it possible to ensure that code doing writes into memory is not optimized away in C++? Is the solution in SecureZeroMemory() compliant to C++ Standard?

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can't you use volatile char buffer[size];? –  BigBoss Nov 7 '12 at 11:31
It doesn't matter whether buffer is volatile or not. The writes are through an lvalue of a volatile type and that's all that matters. [intro.execution]/12 –  avakar Nov 7 '12 at 11:33
@Rook: That's a good question, but again, those reads don't affect observable behavior any more than the writes. –  sharptooth Nov 7 '12 at 11:42
Also, bear in mind that the standard describes the effects of volatile access using the C++ abstract machine. How this machine maps to your (real) architecture is debatable. Whether a volatile write ends up storing a value into RAM, whether it just emits the value into a shared cache, or whether it writes into a stale swap page is something you'd have to ask your compiler vendor. –  avakar Nov 7 '12 at 11:43
The latter, by the way, will not happen on any architecture I know. You have to make an effort to ensure that the password doesn't end up lying in the page file. –  avakar Nov 7 '12 at 11:45
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4 Answers

up vote 6 down vote accepted

There is no portable solution. If it wants to, the compiler could have made copies of the data while you were using it in multiple places in memory and any zero function could zero only the one it's using at that time. Any solution will be non-portable.

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With liubrary functions like SecureZeroMemory, the library writers will typically have taken pains to ensure that such functions will not be inlined by the compiler. This means that in the snippet

char buffer[size];
SecureZeroMemory( buffer, size );

the compiler does not know what SecureZeroMemory does with buffer, so the optimizer can't prove that taking the snippet out does not affect the observable behaviour of the program. In other words, the library writers will already have done all that is possible to ensure such code is not optimized away.

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In case of Visual C++ SecureZeroMemory() is implemented right in the WinNT.h header, so the compiler can see its inner workings. –  sharptooth Nov 8 '12 at 9:08
@sharptooth: Then it is likely that the authors of SecureZeroMemory know that the use of volatile prevents the Visual C++ optimizer from optimizing the code away. The authors of SecureZeroMemory give certain guarantees about the function, so it is their job to ensure the optimizer does not void those guarantees. –  Bart van Ingen Schenau Nov 8 '12 at 9:14
Well, great, now I have to port the code to some other compiler - what do I do? –  sharptooth Nov 8 '12 at 9:16
@sharptooth: That's not your problem. To be compatible, the new compiler will have to support all the extensions needed to compile WinNT.h. This is no exception. –  MSalters Nov 8 '12 at 9:35
@sharptooth: For something with semantics as tricky as SecureZeroMemory, you're going to need some help from the compiler. No getting around that. Another compiler may use another approach, so don't get hung up on this particular approach. –  MSalters Nov 8 '12 at 10:27
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The volatile keyword can be applied to a pointer (or reference, in C++) without requiring a cast, meaning that accesses through this pointer are not to be optimized out. The declaration of the variable does not matter.

The behaviour is analogous to const:

char buffer[16];
char const *p = buffer;

buffer[0] = 'a';          // okay
p[0] = 'b';               // error

That a const pointer to the buffer exists does not alter the behaviour of the variable in any way, only the behaviour of the modified pointer. If the variable is declared const, then it is forbidden to generate non-const pointers to it:

char const buffer[16];
char *p = buffer;         // error


char buffer[16];
char volatile *p = buffer;

buffer[0] = 'a';          // may be optimized out
p[0] = 'b';               // will be emitted


char volatile buffer[16];
char *p = buffer;         // error

The compiler is free to remove accesses through non-volatile lvalues as well as function calls where it can prove that no accesses to volatile lvalues happen.

The RtlSecureZeroMemory function is safe to use because the compiler can either see the definition (including the volatile access inside the loop or, depending on the platform, the assembler statement, which is opaque to the compiler and thus assumed to be unoptimizable), or it has to assume that the function will perform a volatile access.

If you wish to avoid the dependency on the <winnt.h> header file, then a similar function will work fine with any conforming compiler.

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This is all great, but a tiny citation from C++ Standard (preferably C++03) would be just great. –  sharptooth Nov 8 '12 at 10:55
That doesn't work. Nothing prevents the compiler from making a copy of the buffer for you to operate on with your volatile pointers so long as all subsequent accesses go to the copy. So that won't ensure the previous data is erased. All the previous accesses can be optimized however the compiler likes. –  David Schwartz Nov 8 '12 at 11:38
@David Schwartz: Whatever, let's pretend it doesn't happen. How do I prevent writes being optimized away? –  sharptooth Nov 8 '12 at 12:28
Just pretend they aren't optimized away then. –  David Schwartz Nov 8 '12 at 13:02
@sharptooth: Then you have your answer -- it can't be done. Sorry. Your question is basically, "How can I do something that can't be done portably in a portable way?" And the answer is that you can't. You have an impossible requirement. –  David Schwartz Nov 9 '12 at 15:10
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There is always a race condition between when there is sensitive information in memory and the time you wipe it out. In that window of time your application could crash and dump core or a malicious user could get a memory dump of the process' address space with sensitive information in plain text.

May be you should not store sensitive information in memory in plain text. This way you achieve better security and bypass this issue completely.

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Memory dumps are just great, yet getting them is not trivial. It's much more likely that a program accidentally sends the data itself. –  sharptooth Nov 8 '12 at 10:16
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