87

I need a function that (like SecureZeroMemory from the WinAPI) always zeros memory and doesn't get optimized away, even if the compiler thinks the memory is never going to accessed again after that. Seems like a perfect candidate for volatile. But I'm having some problems actually getting this to work with GCC. Here is an example function:

void volatileZeroMemory(volatile void* ptr, unsigned long long size)
{
    volatile unsigned char* bytePtr = (volatile unsigned char*)ptr;

    while (size--)
    {
        *bytePtr++ = 0;
    }
}

Simple enough. But the code that GCC actually generates if you call it varies wildly with the compiler version and the amount of bytes you're actually trying to zero. https://godbolt.org/g/cMaQm2

  • GCC 4.4.7 and 4.5.3 never ignore the volatile.
  • GCC 4.6.4 and 4.7.3 ignore volatile for array sizes 1, 2, and 4.
  • GCC 4.8.1 until 4.9.2 ignore volatile for array sizes 1 and 2.
  • GCC 5.1 until 5.3 ignore volatile for array sizes 1, 2, 4, 8.
  • GCC 6.1 just ignores it for any array size (bonus points for consistency).

Any other compiler I have tested (clang, icc, vc) generates the stores one would expect, with any compiler version and any array size. So at this point I'm wondering, is this a (pretty old and severe?) GCC compiler bug, or is the definition of volatile in the standard that imprecise that this is actually conforming behavior, making it essentially impossible to write a portable "SecureZeroMemory" function?

Edit: Some interesting observations.

#include <cstddef>
#include <cstdint>
#include <cstring>
#include <atomic>

void callMeMaybe(char* buf);

void volatileZeroMemory(volatile void* ptr, std::size_t size)
{
    for (auto bytePtr = static_cast<volatile std::uint8_t*>(ptr); size-- > 0; )
    {
        *bytePtr++ = 0;
    }

    //std::atomic_thread_fence(std::memory_order_release);
}

std::size_t foo()
{
    char arr[8];
    callMeMaybe(arr);
    volatileZeroMemory(arr, sizeof arr);
    return sizeof arr;
}

The possible write from callMeMaybe() will make all GCC versions except 6.1 generate the expected stores. Commenting in the memory fence will also make GCC 6.1 generate the stores, although only in combination with the possible write from callMeMaybe().

Someone has also suggested to flush the caches. Microsoft does not try to flush the cache at all in "SecureZeroMemory". The cache is likely going to be invalidated pretty fast anyway, so this is probably not be a big deal. Also, if another program was trying to probe the data, or if it was going to be written to the page file, it would always be the zeroed version.

There are also some concerns about GCC 6.1 using memset() in the standalone function. The GCC 6.1 compiler on godbolt might a broken build, as GCC 6.1 seems to generate a normal loop (like 5.3 does on godbolt) for the standalone function for some people. (Read comments of zwol's answer.)

  • 4
    IMHO using volatile is a bug unless proven otherwise. But most likely a bug. volatile is so underspecified as to be dangerous - just don't use it. – Jesper Juhl Jul 6 '16 at 18:09
  • 19
    @JesperJuhl: No, volatile is appropriate in this case. – Dietrich Epp Jul 6 '16 at 18:10
  • 8
    @NathanOliver: That won't work, because compilers can optimize out dead stores even if they use memset. The problem is that compilers know exactly what memset does. – Dietrich Epp Jul 6 '16 at 18:10
  • 7
    @PaulStelian: That would make a volatile pointer, we want a pointer to volatile (we don't care whether ++ is strict, but whether *p = 0 is strict). – Dietrich Epp Jul 6 '16 at 18:12
  • 7
    @JesperJuhl: There's nothing under-specified about volatile. – GManNickG Jul 6 '16 at 18:22
80

GCC's behavior may be conforming, and even if it isn't, you should not rely on volatile to do what you want in cases like these. The C committee designed volatile for memory-mapped hardware registers and for variables modified during abnormal control flow (e.g. signal handlers and setjmp). Those are the only things it is reliable for. It is not safe to use as a general "don't optimize this out" annotation.

In particular, the standard is unclear on a key point. (I've converted your code to C; there shouldn't be any divergence between C and C++ here. I've also manually done the inlining that would happen before the questionable optimization, to show what the compiler "sees" at that point.)

extern void use_arr(void *, size_t);
void foo(void)
{
    char arr[8];
    use_arr(arr, sizeof arr);

    for (volatile char *p = (volatile char *)arr;
         p < (volatile char *)(arr + 8);
         p++)
      *p = 0;
}

The memory-clearing loop accesses arr through a volatile-qualified lvalue, but arr itself is not declared volatile. It is, therefore, at least arguably allowed for the C compiler to infer that the stores made by the loop are "dead", and delete the loop altogether. There's text in the C Rationale that implies that the committee meant to require those stores to be preserved, but the standard itself does not actually make that requirement, as I read it.

For more discussion of what the standard does or does not require, see Why is a volatile local variable optimised differently from a volatile argument, and why does the optimiser generate a no-op loop from the latter?, Does accessing a declared non-volatile object through a volatile reference/pointer confer volatile rules upon said accesses?, and GCC bug 71793.

For more on what the committee thought volatile was for, search the C99 Rationale for the word "volatile". John Regehr's paper "Volatiles are Miscompiled" illustrates in detail how programmer expectations for volatile may not be satisfied by production compilers. The LLVM team's series of essays "What Every C Programmer Should Know About Undefined Behavior" does not touch specifically on volatile but will help you understand how and why modern C compilers are not "portable assemblers".


To the practical question of how to implement a function that does what you wanted volatileZeroMemory to do: Regardless of what the standard requires or was meant to require, it would be wisest to assume that you can't use volatile for this. There is an alternative that can be relied on to work, because it would break far too much other stuff if it didn't work:

extern void memory_optimization_fence(void *ptr, size_t size);
inline void
explicit_bzero(void *ptr, size_t size)
{
   memset(ptr, 0, size);
   memory_optimization_fence(ptr, size);
}

/* in a separate source file */
void memory_optimization_fence(void *unused1, size_t unused2) {}

However, you must make absolutely sure that memory_optimization_fence is not inlined under any circumstances. It must be in its own source file and it must not be subjected to link-time optimization.

There are other options, relying on compiler extensions, that may be usable under some circumstances and can generate tighter code (one of them appeared in a previous edition of this answer), but none are universal.

(I recommend calling the function explicit_bzero, because it is available under that name in more than one C library. There are at least four other contenders for the name, but each has been adopted only by a single C library.)

You should also know that, even if you can get this to work, it may not be enough. In particular, consider

struct aes_expanded_key { __uint128_t rndk[16]; };

void encrypt(const char *key, const char *iv,
             const char *in, char *out, size_t size)
{
    aes_expanded_key ek;
    expand_key(key, ek);
    encrypt_with_ek(ek, iv, in, out, size);
    explicit_bzero(&ek, sizeof ek);
}

Assuming hardware with AES acceleration instructions, if expand_key and encrypt_with_ek are inline, the compiler may be able to keep ek entirely in the vector register file -- until the call to explicit_bzero, which forces it to copy the sensitive data onto the stack just to erase it, and, worse, doesn't do a darn thing about the keys that are still sitting in the vector registers!

  • 6
    That's interesting... I'd be interested in seeing a reference to the committee's comments. – Dietrich Epp Jul 6 '16 at 18:28
  • 10
    How does this square with 6.7.3(7)'s definition of volatile as [...] Therefore any expression referring to such an object shall be evaluated strictly according to the rules of the abstract machine, as described in 5.1.2.3. Furthermore, at every sequence point the value last stored in the object shall agree with that prescribed by the abstract machine, except as modified by the unknown factors mentioned previously. What constitutes an access to an object that has volatile-qualified type is implementation-defined. ? – Iwillnotexist Idonotexist Jul 6 '16 at 18:40
  • 15
    @IwillnotexistIdonotexist The key word in that passage is object. volatile sig_atomic_t flag; is a volatile object. *(volatile char *)foo is merely an access through a volatile-qualified lvalue and the standard does not require that to have any special effects. – zwol Jul 6 '16 at 18:49
  • 3
    The Standard says what criteria something must meet to be a "compliant" implementation. It makes no effort to describe what criteria an implementation on a given platform must meet to be a "good" implementation or a "usable" one. GCC's treatment of volatile may be sufficient to make it a "compliant" implementation, but that doesn't mean it's sufficient to be "good" or "useful". For many kinds of systems programming it should be regarded as woefully deficient in those regards. – supercat Jul 6 '16 at 22:27
  • 3
    The C spec also rather directly says "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)." (emphasize mine). – Johannes Schaub - litb Jul 7 '16 at 17:10
15

I need a function that (like SecureZeroMemory from the WinAPI) always zeros memory and doesn't get optimized away,

This is what the standard function memset_s is for.


As to whether this behavior with volatile is conforming or not, that's a bit hard to say, and volatile has been said to have long been plagued with bugs.

One issue is that the specs say that "Accesses to volatile objects are evaluated strictly according to the rules of the abstract machine." But that only refers to 'volatile objects', not accessing a non-volatile object via a pointer that has had volatile added. So apparently if a compiler can tell that you're not really accessing a volatile object then it's not required to treat the object as volatile after all.

  • 4
    Note: This is part of the C11 standard, and is not available in all toolchains yet. – Dietrich Epp Jul 6 '16 at 18:15
  • 5
    One should note that interestingly, this function is standardized for C11 but not for C++11, C++14 or C++17. So technically it's not a solution for C++, but I agree that this seems like the best option from a practical perspective. At this point I do wonder though if the behavior from GCC is conforming or not. Edit: Actually, VS 2015 doesn't have memset_s, so it's not all that portable yet. – cooky451 Jul 6 '16 at 18:16
  • 2
    @cooky451 I thought C++17 pulls the C11 standard library in by reference (see second Misc). – nwp Jul 6 '16 at 18:23
  • 13
    Also, describing memset_s as C11-standard is an overstatement. It is part of Annex K, which is optional in C11 (and therefore also optional in C++). Basically all implementors, including Microsoft, whose idea it was in the first place (!), have declined to pick it up; last I heard they were talking about scrapping it in C-next. – zwol Jul 6 '16 at 18:26
  • 8
    @cooky451 In certain circles, Microsoft is notorious for forcing stuff into the C standard over basically everyone else's objections and then not bothering to implement it themselves. (The most egregious example of this is C99's relaxation of the rules for what the underlying type of size_t is allowed to be. The Win64 ABI is not conformant with C90. That would have been ... not ok, but not terrible ... if MSVC had actually picked up C99 things like uintmax_t and %zu in a timely fashion, but they didn't.) – zwol Jul 6 '16 at 18:52
2

I offer this version as portable C++ (although the semantics are subtly different):

void volatileZeroMemory(volatile void* const ptr, unsigned long long size)
{
    volatile unsigned char* bytePtr = new (ptr) volatile unsigned char[size];

    while (size--)
    {
        *bytePtr++ = 0;
    }
}

Now you have write accesses to a volatile object, not merely accesses to a non-volatile object made through a volatile view of the object.

The semantic difference is that it now formally ends the lifetime of whatever object(s) occupied the memory region, because the memory has been reused. So access to the object after zeroing its contents is now surely undefined behavior (formerly it would have been undefined behavior in most cases, but some exceptions surely existed).

To use this zeroing during an object's lifetime instead of at the end, the caller should use placement new to put a new instance of the original type back again.

The code can be made shorter (albeit less clear) by using value initialization:

void volatileZeroMemory(volatile void* const ptr, unsigned long long size)
{
    new (ptr) volatile unsigned char[size] ();
}

and at this point it is a one-liner and barely warrants a helper function at all.

  • 1
    If accesses to the object after the function executes would invoke UB, that would mean that such accesses could yield the values the object held before it was "cleared". How is that not the opposite of security? – supercat Jul 18 '18 at 21:53
0

It should be possible to write a portable version of the function by using a volatile object on the right-hand side and forcing the compiler to preserve the stores to the array.

void volatileZeroMemory(void* ptr, unsigned long long size)
{
    volatile unsigned char zero = 0;
    unsigned char* bytePtr = static_cast<unsigned char*>(ptr);

    while (size--)
    {
        *bytePtr++ = zero;
    }

    zero = static_cast<unsigned char*>(ptr)[zero];
}

The zero object is declared volatile that ensures the compiler can make no assumptions about its value even though it always evaluates as zero.

The final assignment expression reads from a volatile index in the array and stores the value in a volatile object. Since this read cannot be optimized, it ensures that the compiler must generate the stores specified in the loop.

  • 1
    This doesn't work at all... just look at the code that is being generated. – cooky451 Jul 6 '16 at 20:41
  • 1
    Having read my generated ASM mo' better, it seems to inline the function call and retain the looping, but not do any storing to *ptr during that loop, or actually anything at all... just looping. wtf, there goes my brain. – underscore_d Jul 6 '16 at 21:20
  • 3
    @underscore_d It's because it's optimizing away the store while preserving the read of the volatile. – D Krueger Jul 6 '16 at 21:25
  • 1
    Yeah, and it dumps the result to an unchanging edx: I get this: .L16: subq $1, %rax; movzbl -1(%rsp), %edx; jne .L16 – underscore_d Jul 6 '16 at 21:29
  • 1
    If I change the function to allow passing an arbitrary volatile unsigned char const fill byte... it doesn't even read it. The generated inlined call to volatileFill() is just [load RAX with sizeof] .L9: subq $1, %rax; jne .L9. Why does the optimiser (A) not re-read the fill byte and (B) bother preserving the loop where it doesn't do anything? – underscore_d Jul 6 '16 at 21:34

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