I'm seeing 15% performance degradation of the same C++ code compiled to exactly same machine instructions but located on differently aligned addresses. When my tiny main loop starts at 0x415220 it's faster then when it is at 0x415250. I'm running this on Intel Core2 Duo. I use gcc 4.4.5 on x86_64 Ubuntu.

Can anybody explain the cause of slowdown and how I can force gcc to optimally align the loop?

Here is the disassembly for both cases with profiler annotation:

  415220 576      12.56% |XXXXXXXXXXXXXX       48 c1 eb 08           shr    $0x8,%rbx
  415224 110       2.40% |XX                   0f b6 c3              movzbl %bl,%eax
  415227           0.00% |                     41 0f b6 04 00        movzbl (%r8,%rax,1),%eax
  41522c 40        0.87% |                     48 8b 04 c1           mov    (%rcx,%rax,8),%rax
  415230 806      17.58% |XXXXXXXXXXXXXXXXXXX  4c 63 f8              movslq %eax,%r15
  415233 186       4.06% |XXXX                 48 c1 e8 20           shr    $0x20,%rax
  415237 102       2.22% |XX                   4c 01 f9              add    %r15,%rcx
  41523a 414       9.03% |XXXXXXXXXX           a8 0f                 test   $0xf,%al
  41523c 680      14.83% |XXXXXXXXXXXXXXXX     74 45                 je     415283 ::Run(char const*, char const*)+0x4b3>
  41523e           0.00% |                     41 89 c7              mov    %eax,%r15d
  415241           0.00% |                     41 83 e7 01           and    $0x1,%r15d
  415245           0.00% |                     41 83 ff 01           cmp    $0x1,%r15d
  415249           0.00% |                     41 89 c7              mov    %eax,%r15d
  415250 679      13.05% |XXXXXXXXXXXXXXXX     48 c1 eb 08           shr    $0x8,%rbx
  415254 124       2.38% |XX                   0f b6 c3              movzbl %bl,%eax
  415257           0.00% |                     41 0f b6 04 00        movzbl (%r8,%rax,1),%eax
  41525c 43        0.83% |X                    48 8b 04 c1           mov    (%rcx,%rax,8),%rax
  415260 828      15.91% |XXXXXXXXXXXXXXXXXXX  4c 63 f8              movslq %eax,%r15
  415263 388       7.46% |XXXXXXXXX            48 c1 e8 20           shr    $0x20,%rax
  415267 141       2.71% |XXX                  4c 01 f9              add    %r15,%rcx
  41526a 634      12.18% |XXXXXXXXXXXXXXX      a8 0f                 test   $0xf,%al
  41526c 749      14.39% |XXXXXXXXXXXXXXXXXX   74 45                 je     4152b3 ::Run(char const*, char const*)+0x4c3>
  41526e           0.00% |                     41 89 c7              mov    %eax,%r15d
  415271           0.00% |                     41 83 e7 01           and    $0x1,%r15d
  415275           0.00% |                     41 83 ff 01           cmp    $0x1,%r15d
  415279           0.00% |                     41 89 c7              mov    %eax,%r15d
  • 3
    use the --march=XXX option, if the arch is the same as the machine compiling on you can do: -march=native In short give the compiler as much info as you can about the target platform, also perform pgo, by initially compiling with -pg -fprofile-generate then run the program then recompile again with -fprofile-use – Matthieu N. Dec 26 '10 at 3:41

Gcc has a -falign-loops=n option where n is the maximum number of bytes to skip, if omitted machine default will be used. Gcc auto-enables this at -O2 and -O3 optimization levels.


On Intel CPUs which have Loop Stream Detection, loop body code alignment can promote the effectiveness, particularly with normal levels of unrolling. Alignment pays a penalty when first entering the loop from the top. You didn't show the code there, where there would be somewhat nonsensical glorified no-op instructions in the aligned case. gcc normally uses conditional alignment, which applies alignment only in the cases where a limited amount of padding is needed. When I looked into it once, the options which affect this behavior didn't seem very effective. As Alexander said, it's important to set a value for -march or -mtune so that gcc can use the relevant alignment settings. All compilers I use fail to align loop body for some cases, and there seems no control over this.

  • I thought the loop buffer on Nehalem and later made alignment basically irrelevant for loops that fit inside it. No decoding happens, and it just replays the up-to-28 uops it holds. Can it not hold as many uops if there are alignment boundaries? Or issue less than 4 uops in some cycles? My understanding comes from Agner Fog's microarch doc Of course, this question is about a Core2, where the loop buffer is at the predecode stage (insn length detection), buffering up to 64B of x86 machine code. Is that what you meant? – Peter Cordes Feb 10 '16 at 1:00
  • According to my understanding, getting full benefit of the decoded uops buffer does depend on the code alignment. Thus there may be an interaction with the amount of unrolling. On the recent models, the buffer is large enough in my benchmarks to accommodate unroll by 4 with alignment, as limited unrolling may still be useful on bigger loops which fall out of the buffer size limit. There are other factors involved, such as the limit on how many active paths with conditional jump are accommodated. gcc typically uses .p2align 4,,10. – tim18 Feb 11 '16 at 8:43

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