Are loads of variables that are aligned on word boundaries faster than unaligned load operations on x86/64 (Intel/AMD 64 bit) processors?

A colleague of mine argues that unaligned loads are slow and should be avoided. He cites the padding of items to word boundaries in structs as a proof that unaligned loads are slow. Example:

struct A {
  char a;
  uint64_t b;

The struct A as usually a size of 16 bytes.

On the other hand, the documentation of the Snappy compressor states that Snappy assumes that "unaligned 32- and 64-bit loads and stores are cheap". According to the source code this is true of Intel 32 and 64-bit processors.

So: What is the truth here? If and by how much are unaligned loads slower? Under which circumstances?


A Random Guy On The Internet I've found says that for the 486 says that an aligned 32-bit access takes one cycle. An unaligned 32-bit access that spans quads but is within the same cache line takes four cycles. An unaligned etc that spans multiple cache lines can take an extra six to twelve cycles.

Given that an unaligned access requires accessing multiple quads of memory, pretty much by definition, I'm not at all surprised by this. I'd imagine that better caching performance on modern processors makes the cost a little less bad, but it's still something to be avoided.

(Incidentally, if your code has any pretensions to portability... ia32 and descendants are pretty much the only modern architectures that support unaligned accesses at all. ARM, for example, can very between throwing an exception, emulating the access in software, or just loading the wrong value, depending on OS!)

Update: Here's someone who actually went and measured it. On his hardware he reckons unaligned access to be half as fast as aligned. Go try it for yourself...

  • Some ARM variants cause an exception on unaligned accesses, but others will decompose them into smaller parts. On the Cortex M3, a word(32) load/store on a halfword(16) boundary will be decomposed into two halfword parts; a word load/store on a byte boundary will be decomposed into three: two byte accesses and a word access. Note that not all instructions allow unaligned accesses. – supercat Feb 20 '12 at 17:12
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    On recent Intel x86 (Nehalem and newer), unaligned loads and stores only have a penalty when you cross a cache line (or worse, a page line). See agner.org/optimize for the microarch guide with the details. It can be worth adding a prologue to loops, to do unaligned until you reach an aligned address, so the main loop runs on aligned data, if you're processing every byte. – Peter Cordes Sep 1 '15 at 20:28
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    This is old info, unaligned loads and stores have a very small penalty now: lemire.me/blog/2012/05/31/… – Eloff Feb 4 '16 at 5:11
  • Modern MIPS (MIPS64 / MIPS64 r6) removes the unaligned split load/store instructions, and requires that implementations support unaliged addresses for the normal lw / sw instructions. As transistor budgets grow even for embedded CPUs, more and more of them support unaligned accesses efficiently. It's useful for compression algorithms, among other things. – Peter Cordes Jan 22 '18 at 7:37

Aligned loads are stores are faster, two excerpts from the Intel Optimization Manual cleanly point this out:


Align data, paying attention to data layout and stack alignment


Alignment and forwarding problems are among the most common sources of large delays on processors based on Intel NetBurst microarchitecture.


3.6.4 Alignment

Alignment of data concerns all kinds of variables:

• Dynamically allocated variables

• Members of a data structure

• Global or local variables

• Parameters passed on the stack

Misaligned data access can incur significant performance penalties. This is particularly true for cache line splits.

Following that part in 3.6.4, there is a nice rule for compiler developers:

Assembly/Compiler Coding Rule 45. (H impact, H generality) Align data on natural operand size address boundaries. If the data will be accessed with vector instruction loads and stores, align the data on 16-byte boundaries.

followed by a listing of alignment rules and another gem in 3.6.6

User/Source Coding Rule 6. (H impact, M generality) Pad data structures defined in the source code so that every data element is aligned to a natural operand size address boundary.

Both rules are marked as high impact, meaning they can greatly change performance, along with the excerpts, the rest of Section 3.6 is filled with other reasons to naturally align your data. Its well worth any developers time to read these manuals, if only to understand the hardware he/she is working on.

  • If you can guarantee that your unaligned load/store doesn't cross a cache line boundary, there's no penalty on modern Intel. (On modern AMD, maybe a 32-byte or 16-byte boundary). Usually by far the easiest way to avoid cache-line splits is natural alignment, though, but if you have a 64-byte aligned struct, then having misaligned fields within it is fine. – Peter Cordes Jan 22 '18 at 7:40

To fix up a misaligned read, the processor needs to do two aligned reads and fix up the result. This is slower than having to do one read and no fix-ups.

The Snappy code has special reasons for exploiting unaligned access. It will work on x86_64; it won't work on architectures where unaligned access is not an option, and it will work slowly where fixing up unaligned access is a system call or a similarly expensive operation. (On DEC Alpha, there was a mechanism approximately equivalent to a system call for fixing up unaligned access, and you had to turn it on for your program.)

Using unaligned access is an informed decision that the authors of Snappy made. It does not make it sensible for everyone to emulate it. Compiler writers would be excoriated for the poor performance of their code if they used it by default, for example.


Unaligned loads/stores should never be used, but the reason is not performance. The reason is that the C language forbids them (both via the alignment rules and the aliasing rules), and they don't work on many systems without extremely slow emulation code - code which may also break the C11 memory model needed for proper behavior of multi-threaded code, unless it's done on a purely byte-by-byte level.

As for x86 and x86_64, for most operations (except some SSE instructions), misaligned load and store are allowed, but that doesn't mean they're as fast as correct accesses. It just means the CPU does the emulation for you, and does it somewhat more efficiently than you could do yourself. As an example, a memcpy-type loop that's doing misaligned word-size reads and writes will be moderately slower than the same memcpy doing aligned access, but it will also be faster than writing your own byte-by-byte copy loop.

  • Suppose one wishes to copy 64Kbytes of data where the source and destination are aligned differently. What would you consider to be the tradeoffs between (1) copy as bytes; (2) align either the source or destination, and copy as longwords with one aligned and one unaligned pointer; (3) align either the source or destination, and manipulate that as words and the other part as bytes or halfwords; (4) manipulate both source and destination as words, using bit-shifting as needed to combine source and destination. Bear in mind that what's fast on today's CPU's may be slow on tomorrow's. – supercat Feb 20 '12 at 17:16
  • Unless you're the one implementing the system, I would use the system's memcpy. It's likely to be using whatever is known to be fastest, and perhaps more importantly you don't have to worry that the compiler will figure out you broke the aliasing rules and thereby break your code. – R.. Feb 20 '12 at 17:20
  • @R: Fair point about memcpy in the case where one will be simply copying data. What if one will be doing something just a little more complicated, e.g. an equivalent to--assuming bytes-- while(n--) *dest++ ^= *src++; If both have identical alignment, clearly using words for most of the operation should allow a major speedup, but what would be the most reasonable pattern for coding such a thing? – supercat Feb 20 '12 at 17:23
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    Again, due to aliasing rules, you're going to have to tiptoe around manipulating data as anything other than it's actual type or a char type, but for the time being it seems safe enough to do that either by ensuring the function is external and not subject to LTO, or perhaps using volatile. With that problem solved, for most purposes i would manipulate the buffers as size_t if they're aligned, and unsigned char otherwise. You could probably get some more performance doing clever stuff when the alignment doesn't match, but I generally favor simplicity unless the performance is critical. – R.. Feb 20 '12 at 17:27
  • Also note that using size_t is not purely portable, as it could have padding bits. In that case you might prefer to pick the largest uintXX_t smaller than or equal in size to size_t using some preprocessor/limits.h trickery. – R.. Feb 20 '12 at 17:29

Unaligned 32 and 64 bit access is NOT cheap.

I did tests to verify this. My results on Core i5 M460 (64 bit) were as follows: fastest integer type was 32 bit wide. 64 bit alignment was slightly slower but almost the same. 16 bit alignment and 8 bit alignment were both noticeably slower than both 32 and 64 bit alignment. 16 bit being slower than 8 bit alignment. The by far slowest form of access was non aligned 32 bit access that was 3.5 times slower than aligned 32 bit access (fastest of them) and unaligned 32 bit access was even 40% slower than unaligned 64 bit access.

Results: https://github.com/mkschreder/align-test/blob/master/results-i5-64bit.jpg?raw=true Source code: https://github.com/mkschreder/align-test

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