Many methods found in high-performance algorithms could be (and are) simplified if they were allowed to read a small amount past the end of input buffers. Here, "small amount" generally means up to W - 1 bytes past the end, where W is the word size in bytes of the algorithm (e.g., up to 7 bytes for an algorithm processing the input in 64-bit chunks).

It's clear that writing past the end of an input buffer is never safe, in general, since you may clobber data beyond the buffer1. It is also clear that reading past the end of a buffer into another page may trigger a segmentation fault/access violation, since the next page may not be readable.

In the special case of reading aligned values, however, a page fault seems impossible, at least on x86. On that platform, pages (and hence memory protection flags) have a 4K granularity (larger pages, e.g. 2MiB or 1GiB, are possible, but these are multiples of 4K) and so aligned reads will only access bytes in the same page as the valid part of the buffer.

Here's a canonical example of some loop that aligns its input and reads up to 7 bytes past the end of buffer:

int processBytes(uint8_t *input, size_t size) {

    uint64_t *input64 = (uint64_t *)input, end64 = (uint64_t *)(input + size);
    int res;

    if (size < 8) {
        // special case for short inputs that we aren't concerned with here
        return shortMethod();

    // check the first 8 bytes
    if ((res = match(*input)) >= 0) {
        return input + res;

    // align pointer to the next 8-byte boundary
    input64 = (ptrdiff_t)(input64 + 1) & ~0x7;

    for (; input64 < end64; input64++) {
        if ((res = match(*input64)) > 0) {
            return input + res < input + size ? input + res : -1;

    return -1;

The inner function int match(uint64_t bytes) isn't shown, but it is something that looks for a byte matching a certain pattern, and returns the lowest such position (0-7) if found or -1 otherwise.

First, cases with size < 8 are pawned off to another function for simplicity of exposition. Then a single check is done for the first 8 (unaligned bytes). Then a loop is done for the remaining floor((size - 7) / 8) chunks of 8 bytes2. This loop may read up to 7 bytes past the end of the buffer (the 7 byte case occurs when input & 0xF == 1). However, return call has a check which excludes any spurious matches which occur beyond the end of the buffer.

Practically speaking, is such a function safe on x86 and x86-64?

These types of overreads are common in high performance code. Special tail code to avoid such overreads is also common. Sometimes you see the latter type replacing the former to silence tools like valgrind. Sometimes you see a proposal to do such a replacement, which is rejected on the grounds the idiom is safe and the tool is in error (or simply too conservative)3.

A note for language lawyers:

Reading from a pointer beyond its allocated size is definitely not allowed in the standard. I appreciate language lawyer answers, and even occasionally write them myself, and I'll even be happy when someone digs up the chapter and verse which shows the code above is undefined behavior and hence not safe in the strictest sense (and I'll copy the details here). Ultimately though, that's not what I'm after. As a practical matter, many common idioms involving pointer conversion, structure access though such pointers and so are technically undefined, but are widespread in high quality and high performance code. Often there is no alternative, or the alternative runs at half speed or less.

If you wish, consider a modified version of this question, which is:

After the above code has been compiled to x86/x86-64 assembly, and the user has verified that it is compiled in the expected way (i.e., the compiler hasn't used a provable partially out-of-bounds access to do something really clever, is executing the compiled program safe?

In that respect, this question is both a C question and a x86 assembly question. Most of the code using this trick that I've seen is written in C, and C is still the dominant language for high performance libraries, easily eclipsing lower level stuff like asm, and higher level stuff like <everything else>. At least outside of the hardcore numerical niche where FORTRAN still plays ball. So I'm interested in the C-compiler-and-below view of the question, which is why I didn't formulate it as a pure x86 assembly question.

All that said, while I am only moderately interested in a link to the standard showing this is UD, I am very interested in any details of actual implementations that can use this particular UD to produce unexpected code. Now I don't think this can happen without some deep pretty deep cross-procedure analysis, but the gcc overflow stuff surprised a lot of people too...

1 Even in apparently harmless cases, e.g., where the same value is written back, it can break concurrent code.

2 Note for this overlapping to work requires that this function and match() function to behave in a specific idempotent way - in particular that the return value supports overlapping checks. So a "find first byte matching pattern" works since all the match() calls are still in-order. A "count bytes matching pattern" method would not work, however, since some bytes could be double counted. As an aside: some functions such as "return the minimum byte" call would work even without the in-order restriction, but need to examine all bytes.

3 It's worth noting here that for valgrind's Memcheck there is a flag, --partial-loads-ok which controls whether such reads are in fact reported as an error. The default is yes, means that in general such loads are not treated as immediate errors, but that an effort is made to track the subsequent use of loaded bytes, some of which are valid and some of which are not, with an error being flagged if the out-of-range bytes are used. In cases such as the example above, in which the entire word is accessed in match(), such analysis will conclude the bytes are accessed, even though the results are ultimately discarded. Valgrind cannot in general determine whether invalid bytes from a partial load are actually used (and detection in general is probably very hard).

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    Theoretically a C compiler could implement its own checks that are more restrictive than those of the underlying hardware. – Barmar Jun 13 '16 at 23:43
  • If your user has verified that it is compiled in "the expected way", where the expected way is that the access is safe, then it is safe. Unfortunately if your user is not reading the assembly intermediate code he/she is not going to have any such guarantees. Don't do it. (You can make it safe by implementing your own memory managment) – BadZen Jun 13 '16 at 23:44
  • This looks more like an answer than a question :) As for the special tail code, that's normally only done if the algorithm proceeds in chunks but doesn't align first. – Jester Jun 13 '16 at 23:44
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    Well, there's always asm(). :) – Barmar Jun 14 '16 at 0:00
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    With regard to your first question, C makes no guarantees that the memory model you are working with even corresponds to anything in the underlying hardware for that sort of 'edge case' (with a couple of exceptions for things like word size, and even then it struggles). So no-go on that front. The "language legalese" says 'undefined' for good reason. With regard to the second question, you'd need to post specific ASM for the question to be meaningful. – BadZen Jun 14 '16 at 0:11

Yes, it's safe in x86 asm, and existing libc strlen(3) implementations take advantage of this.

It's also safe in C compiled for x86, as far as I know. Reading outside an object is of course Undefined Behaviour in C, but it's well-defined for C-targeting-x86. I think it's not the kind of UB that aggressive compilers will assume can't happen while optimizing, but confirmation from a compiler-writer on this point would be good, especially for cases where it's easily provable at compile-time that an access goes out of past the end of an object. (See discussion in comments with @RossRidge: a previous version of this answer asserted that it was absolutely safe, but that LLVM blog post doesn't really read that way).

The data you get is unpredictable garbage, but there won't be any other potential side-effects. As long as the your program isn't affected by the garbage bytes, it's fine. (e.g. use bithacks to find if one of the bytes of a uint64_t are zero, then a byte loop to find the first zero byte, regardless of what garbage is beyond it.)

Similarly, creating unaligned pointers with a cast is UB in the C standard (even if you don't dereference them). It is well-defined in all known C compilers when targeting x86. Intel's SSE intrinsics even require it; e.g. __m128i _mm_loadu_si128 (__m128i const* mem_addr) takes a pointer to an unaligned 16-byte __m128i.

(For AVX512, they've finally changed that inconvenient design choice to void* for new intrinsics like __m512i _mm512_loadu_si512 (void const* mem_addr)).

Even dereferencing an unaligned uint64_t* or int* is safe (and has well-defined behaviour) in C compiled for x86. However, dereferencing a __m128i* directly (instead of using load/store intrinsics) will use movdqa, which faults on unaligned pointers.

Usually loops like this avoid touching any extra cache-lines they don't need to touch, not just pages, for performance reasons.

It's extremely unlikely that there would be memory-mapped I/O registers in the same page as a buffer you wanted to loop over with wide loads, or especially the same 64B cache-line, even if you're calling functions like this from a device driver (or a user-space program like an X server that has mapped some MMIO space).

If you're processing a 60-byte buffer and need to avoid reading from a 4-byte MMIO register, you'll know about it. This sort of situation doesn't happen for normal code.

strlen is the canonical example of a loop that processes an implicit-length buffer and thus can't vectorize without reading past the end of a buffer. If you need to avoid reading past the terminating 0 byte, you can only read one byte at a time.

For example, glibc's implementation uses a prologue to handle data up to the first 64B alignment boundary. Then in the main loop (gitweb link to the asm source), it loads a whole 64B cache line using four SSE2 aligned loads. It merges them down to one vector with pminub (min of unsigned bytes), so the final vector will have a zero element only if any of the four vectors had a zero. After finding that the end of the string was somewhere in that cache line, it re-checks each of the four vectors separately to see where. (Using the typical pcmpeqb against a vector of all-zero, and pmovmskb / bsf to find the position within the vector.) glibc used to have a couple different strlen strategies to choose from, but the current one is good on all x86-64 CPUs.

Loading 64B at a time is of course only safe from a 64B-aligned pointer, since naturally-aligned accesses can't cross cache-line or page-line boundaries.

If you do know the length of a buffer ahead of time, you can avoid reading past the end by handling the bytes beyond the last aligned vector using an unaligned load that ends at the last byte of the buffer. (Again, this only works with idempotent algorithms, like memcpy, which don't care if they do overlapping stores into the destination. Modify-in-place algorithms often can't do this, except with something like converting a string to upper-case with SSE2, where it's ok to reprocess data that's already been upcased. Other than the store-forwarding stall if you do an unaligned load that overlaps with your last aligned store.)

  • Err,umm... strlen (sort of) takes advantage of this, not by actually reading beyond the end of the buffer, but in casting to unsigned (if I recall correctly) and then unrolling and checking each of the 4-bytes for a nul-byte (in order) and then bailing at the nul-byte prior to actually accessing the nul-byte + 1. I'm not saying its a bad analogy, but it's not quite a 1:1 analogy either. – David C. Rankin Jun 14 '16 at 4:49
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    @DavidC.Rankin: Think about what it means to load a uint32_t from memory into a register, when the terminating 0 might be the first byte. And besides that, I linked and explained the actual asm source for glibc's strlen, which reads in 64-byte chunks. So it reads up to 63 bytes beyond the end of the string, using 16-byte vectors. – Peter Cordes Jun 14 '16 at 5:00
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    @DavidC.Rankin: uint32_t foo = *(uint32_t*)aligned_pointer will compile to a 32bit load. It doesn't matter if you only test the bytes of foo one at a time. If the behaviour of your code depends on what's in the bytes after the terminating 0, that's a bug, but loading them at all is what might cause a problem. Access checks happen on loads/stores; no information about where data came from is tracked by registers. glibc's strlen implementation even feeds the whole 64B through the ALUs to comine it down to one thing it can branch on. – Peter Cordes Jun 14 '16 at 5:17
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    Thanks @PeterCordes, that's a comprehensive answer. Noting that existing widely used implementations do this gives a lot of weight to the idea that it's OK in other code too (for the limited cases where it makes a measurable difference). – BeeOnRope Jun 16 '16 at 23:23
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    If you have an array of known length, I think it's usually best to handle the last elements with an unaligned load that stops at the end anyway. So in practice, I think it should only be done in cases where the iteration count isn't known at the start of the loop, so the compiler will not be able to prove anything anyway. – Peter Cordes Jun 19 '16 at 4:51

If you permit consideration of non-CPU devices, then one example of a potentially unsafe operation is accessing out-of-bounds regions of PCI-mapped memory pages. There's no guarantee that the target device is using the same page size or alignment as the main memory subsystem. Attempting to access, for example, address [cpu page base]+0x800 may trigger a device page fault if the device is in a 2KiB page mode. This will usually cause a system bugcheck.

  • Can user-space code access such memory? Does access past the end of a PCI page trigger a page fault on x86/x86-64 systems? – BeeOnRope Jun 14 '16 at 0:24
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    @BeeOnRope Generally only the OS and kernel-mode components are allowed to create this kind of mapping, but there are several paths in which a kernel-mode component will hand off the mapped region to user-mode. For example, CUDA does this, and for similar performance reasons to the CPU side, usually does not perform any bounds checking on accesses. Accessing off the end will trigger a device page fault, which is usually worse than a process page fault, and often leaves the OS unrecoverable. Not sure about CUDA specifically though. – MooseBoys Jun 14 '16 at 0:36
  • Interesting. So if some PCI device is mapped at 0x50-0x94, and then I do an 8-byte read at 0x90, the CPU will pass through something like {8 byte read at 0x90 - 0x50 = 0x40} and then the PCI device will barf because its mapped region only covers (94-50) = 0x44 bytes? Or where exactly does the redirection from a memory access to a PCI device access happen? Kernel level? Hardware (CPU/MMU) level? – BeeOnRope Jun 14 '16 at 0:41
  • That seems like an OS bug if it hands off a mapping to user space in such a way that the user-mode process can perform an access that crashes the whole system. Regardless of what the C spec says about undefined behavior, operating systems are not supposed to allow user-mode code to cause unrecoverable system-level errors. Anything undefined should be confined to the process. – Barmar Jun 14 '16 at 0:49
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    @Barmar: It happens all the time that sufficiently privileged user-mode programs get direct access to hardware, which is certainly sufficient to crash the system. man 2 iopl on a Linux box if you'd like to play around. X servers would likely be unusably slow if they didn't do this. (Or for a more dignified way for a userspace program to crash the system, man 2 shutdown.) – Nate Eldredge Jun 14 '16 at 1:07

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