I'm writing some AVX code and I need to load from potentially unaligned memory. I'm currently loading 4 doubles, hence I would use intrinsic instruction _mm256_loadu_pd; the code I've written is:
__m256d d1 = _mm256_loadu_pd(vInOut + i*4);
I've then compiled with options -O3 -mavx -g and subsequently used objdump to get the assembler code plus annotated code and line (objdump -S -M intel -l avx.obj).When I look into the underlying assembler code, I find the following:
vmovupd xmm0,XMMWORD PTR [rsi+rax*1]
vinsertf128 ymm0,ymm0,XMMWORD PTR [rsi+rax*1+0x10],0x1
I was expecting to see this:
vmovupd ymm0,XMMWORD PTR [rsi+rax*1]
and fully use the 256 bit register (ymm0), instead it looks like gcc has decided to fill in the 128 bit part (xmm0) and then load again the other half with vinsertf128.
Is someone able to explain this?
Equivalent code is getting compiled with a single vmovupd in MSVC VS 2012.
I'm running gcc (Ubuntu 7.3.0-27ubuntu1~18.04) 7.3.0 on Ubuntu 18.04 x86-64.
GCC's default tuning (-mtune=generic) includes -mavx256-split-unaligned-load and -mavx256-split-unaligned-store, because that gives a minor speedup on some CPUs (e.g. first-gen Sandybridge, and some AMD CPUs) in some cases when memory is actually misaligned at runtime.
Use -O3 -mno-avx256-split-unaligned-load -mno-avx256-split-unaligned-store if you don't want this, or better, use -mtune=haswell. Or use -march=native to optimize for your own computer. There's no "generic-avx2" tuning. (https://gcc.gnu.org/onlinedocs/gcc/x86-Options.html).
Intel Sandybridge runs 256-bit loads as a single uop that takes 2 cycles in a load port. (Unlike AMD which decodes all 256-bit vector instructions as 2 separate uops.) Sandybridge has a problem with unaligned 256-bit loads (if the address is actually misaligned at runtime). I don't know the details, and haven't found much specific info on exactly what the slowdown is. Perhaps because it uses a banked cache, with 16-byte banks? But IvyBridge handles 256-bit loads better and still has banked cache.
According to the GCC mailing list message about the code that implements the option (https://gcc.gnu.org/ml/gcc-patches/2011-03/msg01847.html), "It speeds up some SPEC CPU 2006 benchmarks by up to 6%." (I think that's for Sandybridge, the only Intel AVX CPU that existed at the time.)
But if memory is actually 32-byte aligned at runtime, this is pure downside even on Sandybridge and most AMD CPUs1. So with this tuning option, you potentially lose just from failing to tell your compiler about alignment guarantees. And if your loop runs on aligned memory most of the time, you'd better compile at least that compilation unit with -mno-avx256-split-unaligned-load or tuning options that imply that.
Splitting in software imposes the cost all the time. Letting hardware handle it makes the aligned case perfectly efficient (except stores on Piledriver1), with the misaligned case possibly slower than with software splitting on some CPUs. So it's the pessimistic approach, and makes sense if it's really likely that the data really is misaligned at runtime, rather than just not guaranteed to always be aligned at compile time. e.g. maybe you have a function that's called most of the time with aligned buffers, but you still want it to work for rare / small cases where it's called with misaligned buffers. In that case, a split-load/store strategy is inappropriate even on Sandybridge.
It's common for buffers to be 16-byte aligned but not 32-byte aligned because malloc on x86-64 glibc (and new in libstdc++) returns 16-byte aligned buffers (because alignof(maxalign_t) == 16). For large buffers, the pointer is normally 16 bytes after the start of a page, so it's always misaligned for alignments larger than 16. Use aligned_alloc instead.
Note that -mavx and -mavx2 don't change tuning options at all: gcc -O3 -mavx2 still tunes for all CPUs, including ones that can't actually run AVX2 instructions. This is pretty dumb, because you should use a single unaligned 256-bit load if tuning for "the average AVX2 CPU". Unfortunately gcc has no option to do that, and -mavx2 doesn't imply -mno-avx256-split-unaligned-load or anything. See https://gcc.gnu.org/bugzilla/show_bug.cgi?id=80568 and https://gcc.gnu.org/bugzilla/show_bug.cgi?id=78762 for feature requests to have instruction-set selection influence tuning.
This is why you should use -march=native to make binaries for local use, or maybe -march=sandybridge -mtune=haswell to make binaries that can run on a wide range of machines, but will probably mostly run on newer hardware that has AVX. (Note that even Skylake Pentium/Celeron CPUs don't have AVX or BMI2; probably on CPUs with any defects in the upper half of 256-bit execution units or register files, they disable decoding of VEX prefixes and sell them as low-end Pentium.)
gcc8.2's tuning options are as follows. (-march=x implies -mtune=x). https://gcc.gnu.org/onlinedocs/gcc/x86-Options.html.
I checked on the Godbolt compiler explorer by compiling with -O3 -fverbose-asm and looking at the comments which include a full dump of all implied options. I included _mm256_loadu/storeu_ps functions, and a simple float loop that can auto-vectorize, so we can also look at what the compiler does.
Use -mprefer-vector-width=256 (gcc8) or -mno-prefer-avx128 (gcc7 and earlier) to override tuning options like -mtune=bdver3 and get 256-bit auto-vectorization if you want, instead of only with manual vectorization.
default / -mtune=generic: both -mavx256-split-unaligned-load and -store. Arguably less and less appropriate as Intel Haswell and later become more common, and the downside on recent AMD CPUs is I think still small. Especially splitting unaligned loads, which AMD tuning options don't enable.
-march=sandybridge and -march=ivybridge: split both. (I think I've read that IvyBridge improved handling of unaligned 256-bit loads or stores, so it's less appropriate for cases where the data might be aligned at runtime.)
-march=haswell and later: neither splitting option enabled.
-march=knl: neither splitting option enabled. (Silvermont/Atom don't have AVX)
-mtune=intel: neither splitting option enabled. Even with gcc8, auto-vectorization with -mtune=intel -mavx chooses to reach an alignment boundary for the read/write destination array, unlike gcc8's normal strategy of just using unaligned. (Again, another case of software handling that always has a cost vs. letting the hardware deal with the exceptional case.)
-march=bdver1 (Bulldozer): -mavx256-split-unaligned-store, but not loads.
It also sets the gcc8 equivalent gcc7 and earlier -mprefer-avx128 (auto-vectorization will only use 128-bit AVX, but of course intrinsics can still use 256-bit vectors).
-march=bdver2 (Piledriver), bdver3 (Steamroller), bdver4 (Excavator). same as Bulldozer. They auto-vectorize an FP a[i] += b[i] loop with software prefetch and enough unrolling to only prefetch once per cache line!
-march=znver1 (Zen): -mavx256-split-unaligned-store but not loads, still auto-vectorizing with only 128-bit, but this time without SW prefetch.
-march=btver2 (AMD Fam16h, aka Jaguar): neither splitting option enabled, auto-vectorizing like Bulldozer-family with only 128-bit vectors + SW prefetch.
-march=eden-x4 (Via Eden with AVX2): neither splitting option enabled, but the -march option doesn't even enable -mavx, and auto-vectorization uses movlps / movhps 8-byte loads, which is really dumb. At least use movsd instead of movlps to break the false dependency. But if you enable -mavx, it uses 128-bit unaligned loads. Really weird / inconsistent behaviour here, unless there's some strange front-end for this.
options (enabled as part of -march=sandybridge for example, presumably also for Bulldozer-family (-march=bdver2 is piledriver). That doesn't solve the problem when the compiler knows the memory is aligned, though.
Footnote 1: AMD Piledriver has a performance bug that makes 256-bit store throughput terrible: even vmovaps [mem], ymm aligned stores running one per 17 to 20 clocks according to Agner Fog's microarch pdf (https://agner.org/optimize/). This effect isn't present in Bulldozer or Steamroller/Excavator.
Agner Fog says 256-bit AVX throughput in general (not loads/stores specifically) on Bulldozer/Piledriver is typically worse than 128-bit AVX, partly because it can't decode instructions in a 2-2 uop pattern. Steamroller makes 256-bit close to break-even (if it doesn't cost extra shuffles). But register-register vmovaps ymm instructions still only benefit from mov-elimination for the low 128 bits on Bulldozer-family.
But closed-source software or binary distributions typically don't have the luxury of building with -march=native on every target architecture, so there's a tradeoff when making a binary that can run on any AVX-supporting CPU. Gaining big speedup with 256-bit code on some CPUs is typically worth it as long as there aren't catastrophic downsides on other CPUs.
Splitting unaligned loads/stores is an attempt to avoid big problems on some CPUs. It costs extra uop throughput, and extra ALU uops, on recent CPUs. But at least vinsertf128 ymm, [mem], 1 doesn't need the shuffle unit on port 5 on Haswell/Skylake: it can run on any vector ALU port. (And it doesn't micro-fuse, so it costs 2 uops of front-end bandwidth.)
PS:
Most code isn't compiled by bleeding edge compilers, so changing the "generic" tuning now will take a while before code compiled with an updated tuning will get into use. (Of course, most code is compiled with just -O2 or -O3, and this option only affects AVX code-gen anyway. But many people unfortunately use -O3 -mavx2 instead of -O3 -march=native. So they can miss out on FMA, BMI1/2, popcnt, and other things their CPU supports.
GCC's generic tuning splits unaligned 256-bit loads to help older processors. (Subsequent changes avoid splitting loads in generic tuning, I believe.)
You can tune for more recent Intel CPUs using something like -mtune=intel or -mtune=skylake, and you will get a single instruction, as intended.
Related
Title says it all. What are the differences and tradeoffs between -march=haswell, -march=core-avx2, and -mavx2 for compiling avx2 intrinsics?
I know that -mavx2 is a flag and -march=haswell/core-avx2 are architectures which just translate to a bunch of flags. So -mavx2 is a subset of the other two. But beyond that, how do I choose the right one for my application?
In particular, if I'm compiling for Skylake and adding -mtune=skylake, but I can't actually do -march=skylake, how do I decide and why? (That's my particular case, but also interested in the more general tradeoffs).
-march sets -mtune, and enables other useful stuff you forgot like -mfma and -mbmi / -mbmi2 which aren't implied by -mavx2.
Unfortunately GCC's -mtune=generic doesn't adapt itself to the subset of CPUs that support the extensions enabled. Most notably, -mavx2 rules out Sandy Bridge, but doesn't imply -mno-avx256-split-unaligned-load -mno-avx256-split-unaligned-store (Why doesn't gcc resolve _mm256_loadu_pd as single vmovupd?). Out of all AVX2 CPUs, only I think Excavator would really benefit much from those options, and it's not a big fraction of market share, and I think misaligned 32-byte load/store isn't disastrous on it like it was on Sandybridge. GCC11 and later have a tune=generic that does do unaligned 32-byte load/store (https://godbolt.org/z/qr9cEcne3) so this specific issue is no longer critical if you only care about AVX2 and newer CPUs. But still you generally want a -mtune= option somewhat appropriate for the set of CPUs you're targeting. But usually erring on the side of less loop unrolling, since too much can hurt I-cache / uop cache hit rate.
AVX2 CPUs have been widespread for long enough that -mtune=generic happens to be mostly appropriate for them in GCC11 and later, fortunately. (Especially CPUs like Haswell and Zen2 that have 32-byte-wide load/store units). But in general, with other CPU features and other far-future cases, that won't always be true.
But still don't just use -mavx2, that will leave out -mfma (which all AVX2 CPUs support except for one Via model), and leave out -mbmi/2 which I think all AVX2 CPUs also support. More efficient variable-count shifts are always nice, and so is lzcnt/tzcnt and efficient x &= x-1 lowest-set-bit idioms.
-march=haswell -mtune=skylake could be useful if you want to enable a Haswell baseline for compatibility, but tune for Skylake. (There's very little difference between tuning heuristics for those microarchitectures, and probably no new instructions that GCC would use automatically. For SKL specifically, see also How can I mitigate the impact of the Intel jcc erratum on gcc? which isn't implied by -march=skylake)
-march=core-avx2 and similar are an obsolete naming convention
It's just a synonym for -march=haswell, AFAIK. But maybe leaving -mtune=generic, unlike -march=haswell which sets -mtune=haswell. How to correctly determine -march and -mtune for Intel processors? has more details.
-march=core-i7 is I think just a synonym for Nehalem, which is really dumb because Nehalem (1st-gen i7) is a different microarchitecture from Sandy Bridge and later (2nd-gen i7). Intel unfortunately kept that branding through SnB's major re-architecting of the internals, although the 3-level cache with shared inclusive L3 has been a constant.
There's no such thing as "a generic i7", because i7 includes two different microarchitectures, one with a uop cache, one without.
Good riddance to those stupid ambiguous confusing -march= / -mtune names that are trying to be generic but actually aren't.
It would be nice if there was a -march=generic-avx2 to tune for Haswell and later, Zen1 and later, etc., using the common subset of instructions they all support efficiently. And setting tuning options appropriate for all of them, not going too crazy unrolling. But there isn't.
Or more generally, -mtune=generic-enabled or something that would look at the enabled -m options and not care about CPUs that couldn't run this code. e.g. not doing rep ret if you enabled any features that a Phenom II couldn't run, such as AVX. GCC bug 78762 is basically a feature request for that.
(Current GCC -mtune=generic no longer uses rep ret; Phenom II is old enough that GCC doesn't spend extra code-size to avoid potholes there. Most binary releases of software built with GCC use a GCC version that was in development a year or more before that, so there's some lead time in terms of what's appropriate for -mtune=generic. The CPU with a glass jaw / performance pothole you're working around doesn't have to be totally gone before a current nightly build of GCC stops tuning for it.)
Following the advice of Linus Torvalds (and cross platform performance), I wish to not use avx512. Is there a flag I can specify to the compiler (both gcc and msvc) such that all avx512 instructions are split into pairs of avx2 instructions if a library I am using tries to use axv512 either from intrinsics or compiler optimiszation?
No, compile your code not to use AVX-512 in the first place by telling the compiler it can't; you only have to do anything about code using intrinsics that require AVX-512.
However, if you're compiling for a CPU that supports AVX-512, it's often worth using it, especially with 256-bit vectors to avoid the turbo-frequency and other penalties that come with 512-bit vectors. GCC's default tuning is already -mprefer-vector-width=256 for CPUs like -march=skylake-avx512.
If you want to make a binary that can run on CPUs without AVX-512, then yes obviously you need to make sure it never executes and instructions that would fault without it. e.g. gcc -O3 -march=znver2 or -march=skylake or whatever. Neither of those target arch options include AVX-512. Or -march=native if compiling for whatever CPU you have.
But if you do have a CPU that supports AVX-512, and you want to not use it, you can use something like -march=native -mno-avx512f (All other AVX-512 extensions depend on the "Foundation" AVX-512F, so disabling that also prevents even AVX-512VL for 128 and 256-bit vectors.)
(Part of the benefit of -march=native and then disabling stuff is to also set tuning options. If you want a binary that runs well on both Skylake and Zen2, I'm not sure what to recommend; probably -march=skylake or -march=znver2 are both ok; there's the default "tune=generic" but it cares too much about really old CPUs that don't even support AVX2, like Sandybridge: Why doesn't gcc resolve _mm256_loadu_pd as single vmovupd?)
Intrinsics
Even with intrinsics, GCC will only ever emit instructions supported by the target options, so -mno-avx512f can let you be sure you didn't miss anything. You'll get compile time errors, instead of EVEX instructions slipping through the cracks.
(MSVC is different and is designed around a single-binary model where using new instruction-sets is done in functions that you only call if the CPU supports it, so it won't stop you from using AVX-512. AFAIK, MSVC still doesn't even have an option to auto-vectorize with AVX-512, only /arch:AVX2. But anyway, MSVC won't emit AVX-512 instructions on its own if you don't tell it to, if you don't use any option like /arch:AVX512 if such a thing exists; AFAIK it doesn't have a /arch:native unfortunately. With MSVC you do have to be sure you caught all uses of intrinsics, although compiling with GCC can help to make sure your codebase doesn't do that.)
If you still want to compile code that uses _mm512_add_epi32 or _mm256_ternlog_epi32 or whatever, you'll need a version of immintrin.h that defines __m512i as a struct/class with two __m256i members and emulates all the intrinsics. Some AVX512 intrinsics won't be cheap to emulate, especially masked operations, and the whole concept of compare-into-mask to get an integer instead of a vector. So it's probably a bad idea to try to make this happen fully transparently; instead just get GCC to stop you from using any AVX-512 instructions while you make AVX2-only versions of any intrinsics code that didn't already have AVX2 versions.
Last time this came up, Coding on insufficient hardware, I was able to find an avxintrin-emu.h that let you develop for AVX while only compiling for SSE4. But I didn't find an equivalent for AVX-512. (Normally you would compile an AVX-512 binary and test it on an emulator like SDE that emulates at runtime, not compile-time.)
Agner Fog's VectorClass wrapper library (https://www.agner.org/optimize/#vectorclass) has support for basic operations like + - * /, and shuffles and blends, and has versions 512-bit vectors emulated with a pair of AVX2 vectors. (And VCL types are implicitly convertible to __m256i or __m512i and so on, so for operations it doesn't have its own functions for, you can use Intel intrinsics. But then you're back in the same boat of needing a library that emulates __m256_ternlog_epi32 with only AVX2 instructions.)
This won't stop libc from possibly using hand-written AVX-512 instructions in functions like strcmp or log/exp, since dynamic CPU dispatching happens at run-time, and you can't stop your CPU from reporting that it supports AVX-512. (Except with a VM, or by telling the kernel not to enable AVX-512 at boot, if Linux has an option for that.)
I'm writing some AVX code and I need to load from potentially unaligned memory. I'm currently loading 4 doubles, hence I would use intrinsic instruction _mm256_loadu_pd; the code I've written is:
__m256d d1 = _mm256_loadu_pd(vInOut + i*4);
I've then compiled with options -O3 -mavx -g and subsequently used objdump to get the assembler code plus annotated code and line (objdump -S -M intel -l avx.obj).When I look into the underlying assembler code, I find the following:
vmovupd xmm0,XMMWORD PTR [rsi+rax*1]
vinsertf128 ymm0,ymm0,XMMWORD PTR [rsi+rax*1+0x10],0x1
I was expecting to see this:
vmovupd ymm0,XMMWORD PTR [rsi+rax*1]
and fully use the 256 bit register (ymm0), instead it looks like gcc has decided to fill in the 128 bit part (xmm0) and then load again the other half with vinsertf128.
Is someone able to explain this?
Equivalent code is getting compiled with a single vmovupd in MSVC VS 2012.
I'm running gcc (Ubuntu 7.3.0-27ubuntu1~18.04) 7.3.0 on Ubuntu 18.04 x86-64.
GCC's default tuning (-mtune=generic) includes -mavx256-split-unaligned-load and -mavx256-split-unaligned-store, because that gives a minor speedup on some CPUs (e.g. first-gen Sandybridge, and some AMD CPUs) in some cases when memory is actually misaligned at runtime.
Use -O3 -mno-avx256-split-unaligned-load -mno-avx256-split-unaligned-store if you don't want this, or better, use -mtune=haswell. Or use -march=native to optimize for your own computer. There's no "generic-avx2" tuning. (https://gcc.gnu.org/onlinedocs/gcc/x86-Options.html).
Intel Sandybridge runs 256-bit loads as a single uop that takes 2 cycles in a load port. (Unlike AMD which decodes all 256-bit vector instructions as 2 separate uops.) Sandybridge has a problem with unaligned 256-bit loads (if the address is actually misaligned at runtime). I don't know the details, and haven't found much specific info on exactly what the slowdown is. Perhaps because it uses a banked cache, with 16-byte banks? But IvyBridge handles 256-bit loads better and still has banked cache.
According to the GCC mailing list message about the code that implements the option (https://gcc.gnu.org/ml/gcc-patches/2011-03/msg01847.html), "It speeds up some SPEC CPU 2006 benchmarks by up to 6%." (I think that's for Sandybridge, the only Intel AVX CPU that existed at the time.)
But if memory is actually 32-byte aligned at runtime, this is pure downside even on Sandybridge and most AMD CPUs1. So with this tuning option, you potentially lose just from failing to tell your compiler about alignment guarantees. And if your loop runs on aligned memory most of the time, you'd better compile at least that compilation unit with -mno-avx256-split-unaligned-load or tuning options that imply that.
Splitting in software imposes the cost all the time. Letting hardware handle it makes the aligned case perfectly efficient (except stores on Piledriver1), with the misaligned case possibly slower than with software splitting on some CPUs. So it's the pessimistic approach, and makes sense if it's really likely that the data really is misaligned at runtime, rather than just not guaranteed to always be aligned at compile time. e.g. maybe you have a function that's called most of the time with aligned buffers, but you still want it to work for rare / small cases where it's called with misaligned buffers. In that case, a split-load/store strategy is inappropriate even on Sandybridge.
It's common for buffers to be 16-byte aligned but not 32-byte aligned because malloc on x86-64 glibc (and new in libstdc++) returns 16-byte aligned buffers (because alignof(maxalign_t) == 16). For large buffers, the pointer is normally 16 bytes after the start of a page, so it's always misaligned for alignments larger than 16. Use aligned_alloc instead.
Note that -mavx and -mavx2 don't change tuning options at all: gcc -O3 -mavx2 still tunes for all CPUs, including ones that can't actually run AVX2 instructions. This is pretty dumb, because you should use a single unaligned 256-bit load if tuning for "the average AVX2 CPU". Unfortunately gcc has no option to do that, and -mavx2 doesn't imply -mno-avx256-split-unaligned-load or anything. See https://gcc.gnu.org/bugzilla/show_bug.cgi?id=80568 and https://gcc.gnu.org/bugzilla/show_bug.cgi?id=78762 for feature requests to have instruction-set selection influence tuning.
This is why you should use -march=native to make binaries for local use, or maybe -march=sandybridge -mtune=haswell to make binaries that can run on a wide range of machines, but will probably mostly run on newer hardware that has AVX. (Note that even Skylake Pentium/Celeron CPUs don't have AVX or BMI2; probably on CPUs with any defects in the upper half of 256-bit execution units or register files, they disable decoding of VEX prefixes and sell them as low-end Pentium.)
gcc8.2's tuning options are as follows. (-march=x implies -mtune=x). https://gcc.gnu.org/onlinedocs/gcc/x86-Options.html.
I checked on the Godbolt compiler explorer by compiling with -O3 -fverbose-asm and looking at the comments which include a full dump of all implied options. I included _mm256_loadu/storeu_ps functions, and a simple float loop that can auto-vectorize, so we can also look at what the compiler does.
Use -mprefer-vector-width=256 (gcc8) or -mno-prefer-avx128 (gcc7 and earlier) to override tuning options like -mtune=bdver3 and get 256-bit auto-vectorization if you want, instead of only with manual vectorization.
default / -mtune=generic: both -mavx256-split-unaligned-load and -store. Arguably less and less appropriate as Intel Haswell and later become more common, and the downside on recent AMD CPUs is I think still small. Especially splitting unaligned loads, which AMD tuning options don't enable.
-march=sandybridge and -march=ivybridge: split both. (I think I've read that IvyBridge improved handling of unaligned 256-bit loads or stores, so it's less appropriate for cases where the data might be aligned at runtime.)
-march=haswell and later: neither splitting option enabled.
-march=knl: neither splitting option enabled. (Silvermont/Atom don't have AVX)
-mtune=intel: neither splitting option enabled. Even with gcc8, auto-vectorization with -mtune=intel -mavx chooses to reach an alignment boundary for the read/write destination array, unlike gcc8's normal strategy of just using unaligned. (Again, another case of software handling that always has a cost vs. letting the hardware deal with the exceptional case.)
-march=bdver1 (Bulldozer): -mavx256-split-unaligned-store, but not loads.
It also sets the gcc8 equivalent gcc7 and earlier -mprefer-avx128 (auto-vectorization will only use 128-bit AVX, but of course intrinsics can still use 256-bit vectors).
-march=bdver2 (Piledriver), bdver3 (Steamroller), bdver4 (Excavator). same as Bulldozer. They auto-vectorize an FP a[i] += b[i] loop with software prefetch and enough unrolling to only prefetch once per cache line!
-march=znver1 (Zen): -mavx256-split-unaligned-store but not loads, still auto-vectorizing with only 128-bit, but this time without SW prefetch.
-march=btver2 (AMD Fam16h, aka Jaguar): neither splitting option enabled, auto-vectorizing like Bulldozer-family with only 128-bit vectors + SW prefetch.
-march=eden-x4 (Via Eden with AVX2): neither splitting option enabled, but the -march option doesn't even enable -mavx, and auto-vectorization uses movlps / movhps 8-byte loads, which is really dumb. At least use movsd instead of movlps to break the false dependency. But if you enable -mavx, it uses 128-bit unaligned loads. Really weird / inconsistent behaviour here, unless there's some strange front-end for this.
options (enabled as part of -march=sandybridge for example, presumably also for Bulldozer-family (-march=bdver2 is piledriver). That doesn't solve the problem when the compiler knows the memory is aligned, though.
Footnote 1: AMD Piledriver has a performance bug that makes 256-bit store throughput terrible: even vmovaps [mem], ymm aligned stores running one per 17 to 20 clocks according to Agner Fog's microarch pdf (https://agner.org/optimize/). This effect isn't present in Bulldozer or Steamroller/Excavator.
Agner Fog says 256-bit AVX throughput in general (not loads/stores specifically) on Bulldozer/Piledriver is typically worse than 128-bit AVX, partly because it can't decode instructions in a 2-2 uop pattern. Steamroller makes 256-bit close to break-even (if it doesn't cost extra shuffles). But register-register vmovaps ymm instructions still only benefit from mov-elimination for the low 128 bits on Bulldozer-family.
But closed-source software or binary distributions typically don't have the luxury of building with -march=native on every target architecture, so there's a tradeoff when making a binary that can run on any AVX-supporting CPU. Gaining big speedup with 256-bit code on some CPUs is typically worth it as long as there aren't catastrophic downsides on other CPUs.
Splitting unaligned loads/stores is an attempt to avoid big problems on some CPUs. It costs extra uop throughput, and extra ALU uops, on recent CPUs. But at least vinsertf128 ymm, [mem], 1 doesn't need the shuffle unit on port 5 on Haswell/Skylake: it can run on any vector ALU port. (And it doesn't micro-fuse, so it costs 2 uops of front-end bandwidth.)
PS:
Most code isn't compiled by bleeding edge compilers, so changing the "generic" tuning now will take a while before code compiled with an updated tuning will get into use. (Of course, most code is compiled with just -O2 or -O3, and this option only affects AVX code-gen anyway. But many people unfortunately use -O3 -mavx2 instead of -O3 -march=native. So they can miss out on FMA, BMI1/2, popcnt, and other things their CPU supports.
GCC's generic tuning splits unaligned 256-bit loads to help older processors. (Subsequent changes avoid splitting loads in generic tuning, I believe.)
You can tune for more recent Intel CPUs using something like -mtune=intel or -mtune=skylake, and you will get a single instruction, as intended.
Let's say I take a compiler: gcc 4.8. And processor from intel, let's say skylake or some other fancy new family.
checking this question: How to see which flags -march=native will activate?; if I do gcc -march=native -E -v - </dev/null 2>&1 | grep cc1, this will spout out some flags for the host machine, which is the above processor, skylake.
How does gcc know what flags to enable disable... when 4.8 was released before skylake processors were out? What about other newer family of processors?
Consequently, next question is upgrading the compiler to latest necessary for it accurately and optimally compile for target processor which is new?
The question isn't really specific to gcc/intel, I would like to know how others maintain synchronicity between processor and compiler too.
Old compilers don't know how to tune for new microarchitectures. (And are also missing out on better optimization in general: New versions of gcc/clang usually add new optimizations that help across the board, e.g. gcc8 can coalesce loads/stores of multiple adjacent small variables or array elements into a single 4 or 8-byte load or store. This helps on everything.)
They can also only use ISA extensions they know about.
They can make correct code because new x86 CPUs are still x86, and are backwards compatible with code for older CPUs1. Same with ARM. The ARMv8 ISA is backwards compatible with ARMv7, ARMv6, and so on, so new ARM CPUs can run existing ARM binaries. (There are some AArch64 CPUs that dropped support for 32-bit mode, but nevermind that.)
Consequently, next question is upgrading the compiler to latest necessary for it accurately and optimally compile for target processor which is new?
Yes, you want your compiler to at least know about your CPU for tuning options.
But yes, always, even when your CPU isn't new. New compiler versions often benefit old CPUs, too, but yes a new set of SIMD extensions to auto-vectorize with can lead to potentially large speedups for code that spends a lot of time in one hot loop. Assuming that loop auto-vectorizes well.
e.g. Phoronix recently posted GCC 5 Through GCC 10 Compiler Benchmarks - Five Years Worth Of C/C++ Compiler Performance where they benchmarked on an i7 5960X (Haswell-E) CPU. I think GCC5 knows about -march=haswell. GCC9.2 makes measurably faster code than even gcc8 on some benchmarks.
But I can pretty much guarantee it's not optimal!! Compilers are good over large scales but there's usually something a human can find in a single hot loop, if they know the low level details of optimizing for a given microarchitecture. It's merely as good as you're going to get from any compiler. (Actually performance regressions exist, so even that's not always true. File a missed-optimization bug if you find one).
-march=native does two separate things
CPU feature detection to enable stuff like -mfma and -mbmi2. This is easy on x86 with the CPUID instruction. GCC will enable all extensions it knows about that are supported by the actual CPU. e.g. I think GCC4.8 was the first GCC to know about any AVX512 extensions, so you might even get some AVX512 auto-vectorization on an Ice Lake or Skylake-avx512. Whether it does a good job or not is another matter, for anything non-trivial. But no AVX512 with GCC4.7.
CPU type detection to set -mtune=skylake. This depends on GCC actually recognizing your specific CPU as something it knows about. If not, it falls back to -mtune=generic. It might detect (with CPUID) your L1/L2/L3 cache sizes and use that to influence some tuning decisions like inlining / unrolling, instead of using a known size for -mtune=haswell. I don't think that's a big deal; current compilers don't AFAIK introduce cache-blocking optimizations to matmul loops or things like that, and that's where knowing cache sizes really matters.
CPU type detection can also use CPUID on x86; the vendor-string and model / family / stepping numbers uniquely identify the microarchitecture. ((wikipedia), sandpile, InstLatx64, https://agner.org/optimize/)
x86 is very much designed to support single binaries that run on multiple microarchitectures and might want do to runtime feature detection / dispatching. So an efficient / portable / extensible CPU detection mechanism exists in the form of the CPUID instruction, introduced in Pentium and some late 486 CPUs. (And thus baseline for x86-64.)
Other ISAs are more often used in embedded uses where code gets recompiled for the specific CPU. They mostly don't have as good support for runtime detection. GCC might have to install a handler for SIGILL and just try running some instructions. Or query the OS which knows what's supported, e.g. Linux's /proc/cpuinfo.
Footnote 1:
For x86 specifically, its main claim to fame / reason for popularity is strict backwards compatibility. A new CPU that fails to run some existing programs would be a lot harder to sell, so vendors don't do that. They'll even bend over backwards to go beyond the on-paper ISA docs to make sure existing code keeps working. As former Intel architect Andy Glew said: All or almost all modern Intel processors are stricter than the manual. (For self-modifying code, and in general).
Modern PC motherboard firmwares even still emulate the legacy hardware of an IBM PC/XT when you boot in legacy BIOS mode, as well as implementing a software ABI for disk, keyboard, and screen access. So even bootloaders and stuff like GRUB have a consistent backwards-compatible interface to use, before they load a kernel which has actual drivers for the real hardware that's actually present.
A modern PC can I think still run real MS-DOS (the operating system) binaries in 16-bit real mode.
Adding new instruction opcodes without breaking backwards compat makes variable-length x86 machine code instructions ever more complex, and careless / anti-competitive developments in x86's history haven't helped, leading to more bloated instruction encodings for SSSE3 and later, for example. See Agner Fog's article Stop the instruction set war.
Code that depended on rep foo to decode as foo can break, though: Intel's manuals are pretty clear that random prefixes can cause code to misbehave in future. This makes it safe for Intel or AMD to introduce new instructions that decode in a known way on old CPUs, but do something new on newer CPUs. Like pause = rep nop. Or transactional memory HLE uses prefixes on locked instructions that old CPUs will ignore.
And prefixes like VEX (AVX) and EVEX (AVX512) are carefully chosen to not overlap with valid encodings of instructions, especially in 32-bit mode. See How does the instruction decoder differentiate between EVEX prefix and BOUND opcode in 32-bit mode?. This is one reason why 32-bit mode can still only use 8 vector registers (zmm0..7) even with VEX or EVEX which allow ymm0..15 or zmm0..31 respectively in 64-bit mode. (In 32-bit mode, a VEX prefix is invalid encodings of some opcode. In 64-bit mode, that opcode isn't valid in the first place to the later bytes are more flexible. But to simplify decoder HW they aren't fundamentally different.)
MIPS32r6 / MIPS64r6 in 2014 is one notable example that's not backwards compatible. It rearranged a few opcodes for instructions that stayed the same, and removed some instructions to reuse their opcode for other new instructions, e.g. branches without a delay slot. This is highly unusual and only makes sense for CPUs that are used for embedded systems (like current MIPS). Recompiling everything for MIPS32r6 is not a problem for an embedded system.
Some compiles can make binaries that do runtime CPU detection and dispatching so they can take advantage of whatever a CPU supports, but still of course only for extensions that the compiler knows about when it compiles. The AVX+FMA machine-code version of a function has to be there in the executable, so a compiler from before those were even announced wouldn't have been able to create such machine code.
And before real CPUs with the features were available, compiler devs hadn't had a chance to tune code-gen for those features yet, so a newer compiler might make better code for the same CPU features.
GCC has some support for this, via its ifunc mechanism, but IIRC you can't do that without source changes.
Intel's compiler (ICC) I think does support multi-versioning some hot functions when auto-vectorizing, with just command-line options.
It can only happen if the new processor is specifically designed to be backwards compatible with older models.
Forget gcc for a moment. You have a compiled X86 binary from year 2000, say, an executable built for the original Windows NT. Will a Skylake CPU run it? You betcha. Will an Itanium CPU run iit? Nope, it is not designed to do that. It is a completely different architecture
Now that executable most probably wouldn't use the Skylake efficiently, but that's the whole point of evolving architectures and introducing new instructions.
Returning to gcc, -march=native is not magic. It cannot possibly divine out the new instructions and new timings. It simply selects the "best" instruction set it knows that is supported by the CPU it runs on. How it's done is architecture specific. X86 CPUs can be queried about their capabilities with the the CPUID instruction. Other architectures may do it differently.
To put it another way, -O3 -march=native optimizes for the machine you compiled on, so it's good when you're compiling code to run on the build host. A binary built with -march=native on a Nehalem system is essentially the same as one built with -march=nehalem on any system. -march=native might detect your specific L3 cache size instead of using a default for that, if any GCC tuning decisions (like inlining or unrolling) depend on L3 size. Except if you run an old compiler on a new CPU it doesn't recognize, you get feature detection for stuff like -mavx but for tuning only tune=generic.
None of this can take advantage of new features like AVX2 or BMI2 when running on a Skylake or Ice Lake system. And some specific tuning decisions that were good on Nehalem might be sub-optimal on a different CPU. (Although this is less likely; Intel mostly maintains backwards compatibility for performance as well as correctness. Getting everyone to recompile everything for P4 didn't work out so they usually try to make existing binaries run well on new CPUs.)
Some compiles can make binaries that do runtime CPU detection and dispatching so they can take advantage of whatever a CPU supports, but only for extensions that the compiler knows about when it compiled. The AVX+FMA machine-code version of a function has to be there in the executable, so a compiler from before those were even announced wouldn't have been able to create such machine code. And before real CPUs with the features were available, compiler devs hadn't had a chance to tune code-gen for those features yet, so a newer compiler might make better code for the same CPU features.
When compiled for processor that support AVX extension (say -m64 -march=corei7-avx -mtune=corei7-avx is applicable), does it make sense to use -mfpmath=both -mavx keys at the same time? Does not it so much that it causes the compiler to use three sets of instructions (i87, SSE, AVX) at the same time? Or just i87 for scalars (in some sense) and AVX for vectors only?
The AVX registers are only extensions of the SSE registers. You cannot mix SSE and AVX instructions to increase the number of available registers (you can still mix x87 and AVX instructions, I assume this is what -mfpmath=both does in this case).
See for instance the discussion “Mixing AVX and SSE” on this page.
You normally don't want this; I don't think gcc is smart enough at deciding to use x87 when there's high register pressure to make it worth it.
x87 and SSE/AVX instructions compete for the same FP execution units on normal x86 CPUs (Intel and AMD), so you don't get more throughput from interleaving them.
Normally you should just use -mfpmath=sse (which means AVX when used with -mavx, or better -mfpmath=sse -march=native. The default for x86-64 is sse, so -mfpmath=sse only changes anything for -m32, AFAIK.
The main benefit of -mfpmath=both is more total registers, but managing the x87 register stack often costs extra instructions. Moving data between x87 and AVX also costs a store/reload (store-forwarding round trip, ~6 cycle latency on Haswell, http://agner.org/optimize/), so it's only really useful if you have two independent sets of calculations for the compiler to interleave. Otherwise it's not better than normal spill/reload.
Last time I looked at gcc -O3 -mfpmath=both, the results were not impressive: https://godbolt.org/g/p2KLEC shows gcc5.4 using some store/reloads to bounce data between x87 and xmm (AVX) registers. It would be better off just keeping some of the constants in memory.