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I’m currently coding highly optimised versions of some C99 standard library string functions, like strlen(), memset(), etc, using x86-64 assembly with SSE-2 instructions.

So far I’ve managed to get excellent results in terms of performance, but I sometimes get weird behaviour when I try to optimise more.

For instance, adding or even removing some simple instructions, or simply reorganising some local labels used with jumps completely degrades the overall performances. And there’s absolutely no reason in terms of code.

So my guess is that there is some issues with code alignment, and/or with branches which get mispredicted.

I know that, even with the same architecture (x86-64), different CPUs have different algorithms for branch prediction.

But is there some general advices, when developing for high performances on x86-64, about code alignment and branch prediction?

In particular, about alignment, should I ensure all labels used by jump instructions are aligned on a DWORD?

_func:
    ; ... Some code ...
    test rax, rax
    jz   .label
    ; ... Some code ...
    ret
    .label:
        ; ... Some code ...
        ret

In the previous code, should I use an align directive before .label:, like:

align 4
.label:

If so, is it enough to align on a DWORD when using SSE-2?

And about branch prediction, is there a «preffered» way to organize the labels used by jump instructions, in order to help the CPU, or are today's CPUs smart enough to determine that at runtime by counting the number of times a branch is taken?

EDIT

Ok, here's a concrete example - here's the start of strlen() with SSE-2:

_strlen64_sse2:
    mov         rsi,    rdi
    and         rdi,    -16
    pxor        xmm0,   xmm0
    pcmpeqb     xmm0,   [ rdi ]
    pmovmskb    rdx,    xmm0
    ; ...

Running it 10'000'000 times with a 1000 character string gives about 0.48 seconds, which is fine.
But it does not check for a NULL string input. So obviously, I'll add a simple check:

_strlen64_sse2:
    test       rdi,    rdi
    jz          .null
    ; ...

Same test, it runs now in 0.59 seconds. But if I align the code after this check:

_strlen64_sse2:
    test       rdi,    rdi
    jz          .null
    align      8
    ; ...

The original performances are back. I used 8 for alignment, as 4 doesn't change anything.
Can anyone explain this, and give some advices about when to align, or not to align code sections?

EDIT 2

Of course, it's not as simple as aligning every branch target. If I do it, performances will usually get worse, unless some specific cases like above.

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3  
SSE2 has branch hint prefixes (2E and 3E). –  Kerrek SB Aug 7 '13 at 21:21
    
@KerrekSB Thanks for the comment. Are those instructions still used by modern CPUs, or are they simply ignored? I can't find anything about them in Intel's optimisation manual for x86-64... –  Macmade Aug 7 '13 at 21:36
    
Those should still work in modern CPUs, and AFAIK those work(ed) even before SSE2 –  Drew McGowen Aug 7 '13 at 21:37
6  
Branch hints are ignored by all processors except P4. –  harold Aug 7 '13 at 21:38
2  
I wonder how useful this level of optimization will be in a more realistic setting where the entire string doesn't live in L1 cache, which it clearly does for the benchmark you're using. The 20% performance differences you're worried about could be totally insignificant compared to memory fetch costs. –  Gene Aug 16 '13 at 17:04

2 Answers 2

To extends on TheCodeArtist's answer, who made some good points, here are a few additional stuff and details, as I was actually able to solve the problem.

1 - Code alignment

Intel recommends aligning code and branch targets on 16-byte boundaries:

3.4.1.5 - Assembly/Compiler Coding Rule 12. (M impact, H generality)
All branch targets should be 16-byte aligned.

While this is usually a good advice, it should be done carefully.
Blindly 16-byte aligning everything may lead to performance lost, so this should be tested on each branch target before applying.

As TheCodeArtist pointed it out, using multi-byte NOPs may help here, as simply using standard one-byte NOPs may not bring the expected performance gain of code alignment.

As a sidenote, the .p2align directive is not available in NASM or YASM.
But they do support alignment with other instructions than NOPs with the standard align directive:

align 16, xor rax, rax

2 . Branch prediction

This turned out to be the most important part.
While it's right that every generation of x86-64 CPUs have different branch prediction algorithms, some simple rules can be applied generally to help the CPU predicting which branch will likely be taken.

The CPU tries to keep a branching history in the BTB (Branch Target Buffer).
But when branch information is not available in the BTB, the CPU will use what they call static prediction, which obey to simple rules, as mentioned in Intel's manuals:

  1. Predict forward conditional branches to be not taken.
  2. Predict backward conditional branches to be taken.

Here's an example for the first case:

test rax, rax
jz   .label

; Fallthrough - Most likely

.label:

    ; Forward branch - Most unlikely

Instructions under .label is the unlikely condition, because .label is declared after the actual branch.

For the second case:

.label:

    ; Backward branch - Most likely

test rax, rax
jz   .label

; Fallthrough - Most unlikely

Here, the instructions under .label are the likely condition, as .label is declared before the actual branch.

So each conditional branch should always follow this simple pattern.
And of course, this is also suitable for loops.

As I mentioned before, this was the most important part.

I was experiencing unpredictable performance gains or losses while adding simple tests that should logically improve the overall performances.
Sticking blindly to these rules solved the issues.
If not, the addition of a branch for optimisation purpose may have the opposite result.

TheCodeArtist also mentions loop unrolling in his answer.
While this wasn't the issue, as my loops were already unrolled, I mention it here as it's indeed extremely important, and brings substantial performance gains.

And as a last note for the readers, while this may seem obvious and wasn't the problem here, don't branch when unnecessary.

Starting with the Pentium Pro, x86 processors have conditional move instructions, which may help to eliminate branching and suppress the risk of misprediction:

test   rax, rax
cmovz  rbx, rcx

So just in case, nice thing to keep in mind.

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1  
While your and TCA's answers are good general principles, the deeper question is when these rules actually apply. In general, this can't be answered without (lots of) reference to the details of the target CPU. While avoiding branch misprediction is critical, this loop should be predicted correctly every iteration but the exit regardless of which way you jump. I think your real issue with alignment is with instruction decoding and the micro-op loop buffer. Are you possibly testing this on an older processor? Could you post your full code? I think more exploration might be interesting. –  Nathan Kurz Aug 19 '13 at 22:36

Alignment optimisations

1. Use .p2align <abs-expr> <abs-expr> <abs-expr> instead of align.

Grants fine-grained control using its 3 params

  • param1 - Align to what boundary.
  • param2 - Fill padding with what (zeroes or NOPs).
  • param3 - Do NOT align if padding would exceed specified number of bytes.

2. Align the start of a frequently used code blocks to cache-line size boundaries.

  • This increases the chances that the entire code-block lies in a single cache-line. Once loaded into the L1-cache, then can run entirely without the need to access RAM for instruction fetch. This is highly beneficial for loops with a large number of iterations.

3. Use multi-byte NOPs for padding to reduce the time spent executing NOPs.

  /* nop */
  static const char nop_1[] = { 0x90 };

  /* xchg %ax,%ax */
  static const char nop_2[] = { 0x66, 0x90 };

  /* nopl (%[re]ax) */
  static const char nop_3[] = { 0x0f, 0x1f, 0x00 };

  /* nopl 0(%[re]ax) */
  static const char nop_4[] = { 0x0f, 0x1f, 0x40, 0x00 };

  /* nopl 0(%[re]ax,%[re]ax,1) */
  static const char nop_5[] = { 0x0f, 0x1f, 0x44, 0x00, 0x00 };

  /* nopw 0(%[re]ax,%[re]ax,1) */
  static const char nop_6[] = { 0x66, 0x0f, 0x1f, 0x44, 0x00, 0x00 };

  /* nopl 0L(%[re]ax) */
  static const char nop_7[] = { 0x0f, 0x1f, 0x80, 0x00, 0x00, 0x00, 0x00 };

  /* nopl 0L(%[re]ax,%[re]ax,1) */
  static const char nop_8[] =
    { 0x0f, 0x1f, 0x84, 0x00, 0x00, 0x00, 0x00, 0x00};

  /* nopw 0L(%[re]ax,%[re]ax,1) */
  static const char nop_9[] =
    { 0x66, 0x0f, 0x1f, 0x84, 0x00, 0x00, 0x00, 0x00, 0x00 };

  /* nopw %cs:0L(%[re]ax,%[re]ax,1) */
  static const char nop_10[] =
    { 0x66, 0x2e, 0x0f, 0x1f, 0x84, 0x00, 0x00, 0x00, 0x00, 0x00 };

(upto 10byte NOPs for x86. Source binutils-2.2.3.)


Branch-prediction optimisations

Lot of variations between x86_64 micro-architectures/generations. However a common set of guidelines that are applicable for all of them can be summarised as follows. Reference : Section 3 of Agner Fog's x86 micro-architecture manual.

1. Stick to short jumps.

  • Far jumps are not predicted i.e. pipeline always stalls on a conditional far jump.

2. Un-roll large loops.

  • Loop detection logic is guaranteed to work ONLY for loops with < 64 iterations. This is due to the fact that a branch instruction is recognized as having loop behavior if it goes one way n-1 times and then goes the other way 1 time, for any n upto 64.
share|improve this answer
    
Thank you for the answer, especially for multi-byte NOPs. I'll add further details in another answer, as it may also help people. In the meantime, I'm awarding the bounty to you, to thank you taking time to write a detailed answer, even if it don't answer everything : ) –  Macmade Aug 17 '13 at 9:39
    
Thank you. :-) Looking forward to your answer with the details that you came across in your research. –  TheCodeArtist Aug 17 '13 at 9:48

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