There are generally two types of SIMD instructions:

A. Ones that work with aligned memory addresses, that will raise general-protection (#GP) exception if the address is not aligned on the operand size boundary:

movaps  xmm0, xmmword ptr [rax]
vmovaps ymm0, ymmword ptr [rax]
vmovaps zmm0, zmmword ptr [rax]

B. And the ones that work with unaligned memory addresses, that will not raise such exception:

movups  xmm0, xmmword ptr [rax]
vmovups ymm0, ymmword ptr [rax]
vmovups zmm0, zmmword ptr [rax]

But I'm just curious, why would I want to shoot myself in the foot and use aligned memory instructions from the first group at all?

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    The aligned vs non-aligned loads is an historical artefact (see this). Today unaligned load performs the same - though a naturally aligned operand has the benefit of never crossing a cache line or a page. Commented Sep 3, 2018 at 10:08
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    @memo linked answers are full of misinformation and outdated information. Unaligned operations only have some minor penalties now. Anyway since Nehalem it's the alignment of the address that matters, not the alignment of the instruction.
    – user555045
    Commented Sep 3, 2018 at 10:45
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    @memo mostly yes, there is still a use as a built-in "assert aligned", some compilers have stopped using them
    – user555045
    Commented Sep 3, 2018 at 11:03
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    @harold Both Microsoft and Intel have taken this to a new level. As of VS2017 and ICC2018, both compilers will generate unaligned moves even for pre-Nehalem targets. MS has received strong negative feedback on this, but they don't care anymore since pre-Nehalem is too old.
    – Mysticial
    Commented Sep 4, 2018 at 17:39
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    @MikeF Possibly. Each store to the cache is atomic but older CPUs with a narrow bus width will implement a SSE store as two/four independent stores. Each store is pushed and then flushed from the store buffer independently and if the third faults due to delayed TLB invalidation (see then the first may have already been flushed to the cache. I believe that Intel is saying that they are free to implement SIMD loads/stores as sequence of repeated load/store uOPs. Will a lock prefix fix this? I don't see how. Why don't you ask here on SO officially? It's interesting! Commented Sep 27, 2018 at 14:40

2 Answers 2

  • Unaligned access: Only movups/vmovups can be used. The same penalties discussed in the aligned access case (see next) apply here too. In addition, accesses that cross a cache line or virtual page boundary always incur penalty on all processors.
  • Aligned access:
    • On Intel Nehalem and later (including Silvermont and later) and AMD Bulldozer and later: After predecoding, they are executed in the same exact way for the same operands. This includes support for move elimination. For the fetch and predecode stages, they consume the same exact resources for the same operands.
    • On pre-Nehalem and Bonnell and pre-Bulldozer: They get decoded into different fused domain uops and unfused domain uops. movups/vmovups consume more resources (up to twice as much) in the frontend and the backend of the pipeline. In other words, movups/vmovups can be up to twice as slow as movaps/vmovaps in terms of latency and/or throughput.

Therefore, if you don't care about the older microarchitectures, both are technically equivalent. Although if you know or expect the data to be aligned, you should use the aligned instructions to ensure that the data is indeed aligned without having to add explicit checks in the code.

  • Thanks. I'm curious though, if both tend to be roughly the same in performance on the modern CPUs why didn't they eliminate that #GP exception in (v)movaps instructions? Why not just alias them.
    – MikeF
    Commented Sep 3, 2018 at 18:11
  • @MikeF The instructions have different encodings and existing applications may require one or both instructions. So both encodings need to be supported to run such applications. Also aligned versions implement the alignment checks in hardware, which may eliminate the need to perform these checks in software for code that requires aligned data.
    – Hadi Brais
    Commented Sep 3, 2018 at 18:23
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    @MikeF - because once an instruction is defined one way in the ISA you cannot gerannly change its behavior through a simple doc update! Exceptions are part of this behavior.
    – BeeOnRope
    Commented Sep 3, 2018 at 22:49
  • Another factor is memory disambiguation on Sandybridge (and possibly some newers arches) the Intel Arch Manual: "The following loads are not disambiguated. The execution of these loads is stalled until addresses of all previous stores are known. • Loads that cross the 16-byte boundary • 32-byte Intel AVX loads that are not 32-byte aligned. ". Which could be a significant difference if the workload had intermixed loads / stores.
    – Noah
    Commented Jun 21, 2021 at 15:45
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    @Noah: Not sure this is the idea place for these comments either; you could post it as an answer on What's the actual effect of successful unaligned accesses on x86?. (Or maybe on How can I accurately benchmark unaligned access speed on x86_64 to discuss how to actually benchmark the difference). This Q&A is mostly about the fact that movups has no penalty when the address is actually aligned at run-time on modern CPUs, but not earlier. Commented Jun 21, 2021 at 16:37

I think there is a subtle difference between using _mm_loadu_ps and _mm_load_ps even on "Intel Nehalem and later (including Silvermont and later) and AMD Bulldozer and later" which can have an impact on performance.

Operations which fold a load and another operation such as multiplication into one instruction can only be done with load, not loadu intrinsics, unless you compile with AVX enabled to allow unaligned memory operands.

Consider the following code

#include <x86intrin.h>
__m128 foo(float *x, float *y) {
    __m128 vx = _mm_loadu_ps(x);
    __m128 vy = _mm_loadu_ps(y);
    return vx*vy;

This gets converted to

movups  xmm0, XMMWORD PTR [rdi]
movups  xmm1, XMMWORD PTR [rsi]
mulps   xmm0, xmm1

however if the aligned load intrinsics (_mm_load_ps) are used, it's compiled to

movaps  xmm0, XMMWORD PTR [rdi]
mulps   xmm0, XMMWORD PTR [rsi]

which saves one instruction. But if the compiler can use VEX encoded loads, it's only two instructions for unaligned as well.

vmovups xmm0, XMMWORD PTR [rsi]
vmulps  xmm0, xmm0, XMMWORD PTR [rdi]

Therefor for aligned access although there is no difference in performance when using the instructions movaps and movups on Intel Nehalem and later or Silvermont and later, or AMD Bulldozer and later.

But there can be a difference in performance when using _mm_loadu_ps and _mm_load_ps intrinsics when compiling without AVX enabled, in cases where the compiler's tradeoff is not movaps vs. movups, it's between movups or folding a load into an ALU instruction. (Which happens when the vector is only used as an input to one thing, otherwise the compiler will use a mov* load to get the result in a register for reuse.)

  • The OP is asking about asm instructions, not load intrinsics. Still, upvoted for a useful related point. (AVX instructions don't require their memory operands to be aligned, but SSE does, so compiling loadu intrinsics without AVX can cost you extra instructions which matters even on modern CPUs.) Commented Sep 18, 2018 at 7:34
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    Yes, that's why I upvoted. I think this answer makes it well now. Commented Sep 18, 2018 at 8:22
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    @MikeF read-modify (e.g. mul + read) operations require aligned memory with SSE but not with with AVX.
    – Z boson
    Commented Sep 20, 2018 at 7:18
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    @PeterCordes, I meant simply that there are at least two kinds SIMD read instructions: read only and modify+read. And for SSE there is an asymmetry between aligned and unaligned such that only aligned modify+reads are possible. The OP only asked about read instructions but may have wanted to know about read+modify instructions also.
    – Z boson
    Commented Sep 20, 2018 at 7:58
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    Oh, yes I agree, it's an often-parroted answer that Nehalem has efficient unaligned loads, and then incorrectly extrapolating from movups being efficient to _mm_loadu_ps being efficient. All my edits were to make that point more clearly. It's micro-fusion that makes it a win (or AMD's behaviour of only needing 1 m-op / uop even with a mem src). In terms of uops, addps xmm1, [rdi] decodes on Intel to the same kind of uop as a movaps load, micro-fused with the same kind of uop as addps xmm0,xmm1, so you could add that in, but your first version seemed confused about isns vs. intrin Commented Sep 20, 2018 at 8:47

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