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I have written a library, where I use CMake for verifying the presence of headers for MMX, SSE, SSE2, SSE4, AVX, AVX2, and AVX-512. In addition to this, I check for the presence of the instructions and if present, I add the necessary compiler flags, -msse2 -mavx -mfma etc.

This is all very good, but I would like to deploy a single binary, which works across a range of generations of processors.

Question: Is it possible to tell the compiler (GCC) that whenever it optimizes a function using SIMD, it must generate code for a list of architectures? And of of course introduce high-level branches

I am thinking similar to how the compiler generates code for functions, where input pointers are either 4 or 8 byte aligned. To prevent this, I use the __builtin_assume_aligned macro.

What is best practice? Multiple binaries? Naming?

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    That's a thing that the Intel compiler can do, and is also done (although mostly manually AFAIK) in libstdc++. Some capability test is done at program start, and then critical functions are dispatched to different versions depending from the availability of extended instruction sets. Jun 10, 2017 at 23:48
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    GCC can also do that for a specific processor, but I would like to list a range of processors and have it generate multiple solutions - preferably including high-level branches. If this isn't possible - is there a convention for naming multiple binaries
    – Jens Munk
    Jun 10, 2017 at 23:51

2 Answers 2

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As long as you don't care about portability, yes.

Recent versions of GCC make this easier than any other compiler I'm aware of by using the target_clones function attribute. Just add the attribute, with a list of targets you want to create versions for, and GCC will automatically create the different variants, as well as a dispatch function to choose a version automatically at runtime.

If you want a bit more portability you can use the target attribute, which clang and icc also support, but you'll have to write the dispatch function yourself (which isn't difficult), and emit the function multiple times (generally using a macro, or repeatedly including a header).

AFAIK, if you want your code to work with MSVC you'll need multiple compiler invocations with different options.

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    Thanks. I am compiling the library for both *NIX and Windows and using a fairly old version of gcc, 4.9. I will try the target_clones function. For MSVC, I will try to work something out.
    – Jens Munk
    Jun 11, 2017 at 4:39
  • Unfortunately target_clones didn't appear until gcc 6.
    – nemequ
    Jun 11, 2017 at 16:37
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    It is not as easy as you might think, @Jens. I'm not familiar with GCC's target_clones feature, but this looks like a smart innovation. MSVC doesn't have anything similar, so you will always be fighting against the tools. A separate DLL is the only sane solution. You will have to write all of your own dynamic dispatching logic, of course. I personally prefer shipping multiple versions of the EXE, optimized for each supported architecture, and selectable dynamically with an installer. Jun 12, 2017 at 11:59
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    A separate shared library isn't necessary; you can ship multiple versions of the same function (assuming symbol names are different) by compiling the same file with different macros defined. The dispatch function is pretty easy, too (I have some code at github.com/nemequ/portable-snippets/tree/master/cpu which does a lot of the work). From my perspective the difficult part is the build system; each compiler requires different flags for different features, each target CPU has different features, and each build system (autotools, cmake, meson, etc.) needs a different implementation.
    – nemequ
    Jun 12, 2017 at 18:51
  • @nemequ. I will look into the code at github. I would like to spent some time on finding a good solution. The code is open source anyway, but I would like to ship binaries working for multiple platforms.
    – Jens Munk
    Jun 15, 2017 at 8:04
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If you're talking about just getting the compiler to generate SSE/AVX etc instructions, and you've got "general purpose" code (ie you're not explicitly vectorising using intrinsics, or got lots of code that the compiler will spot and auto-vectorise) then I should warn you that AVX, AVX2 or AVX512 compiling your entire codebase will probably run significantly slower than compiling for SSE versions.

When AVX opcodes using the upper halves of the registers are detected, the CPU powers up the upper half of the circuitry (which is otherwise powered down). This consumes more power, generates more heat and reduces the base clock speed of the chip, typically by 10-20% depending on the mix of high power and low-power opcodes, so you lose maybe 15% of performance immediately, and then have to be doing quite a lot of vectorised processing in order to make up for this performance deficit before you start seeing any gains.

See my longer explanation and references in this thread.

If on the other hand you're explicitly vectorising using intrinsics and you're sure you have large enough burst of AVX etc to make it worthwhile, I've successfully written code where I tell MSVC to compile for SSE2 (default for x64) but then I dynamically check the CPU capabilities and some functions switch to a codepath implemented using AVX intrinsics.

MSVC allows this (it will produce warnings, but you can silence these), but the same technique is hard to make work under GCC 4.9 as the intrinsics are only considered declared by the compiler when the appropriate code generation flag is used. [UPDATE: @nemequ explains below how you can make this work under gcc using attributes to decorate the functions] Depending on the version of GCC you may have to compile files with different flags to get a workable system.

Oh, and you have to watch for AVX-SSE transitions too (call VZEROUPPER when you leave an AVX section of code to return to SSE code) - it can be done but I found that understanding the CPU implications was a bigger battle than I originally envisaged.

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  • Everything is explicitly vectorized. Using gcc, a test program executes 1.8 uop/clk. I get a speedup of 87x compared to optimizing scalar code. I check for presence of headers and instructions for selecting codepath. Using MSVC I disable AVX2 except for when it is used explicitly. Enabling AVX2 makes it slower. A lot of unwanted code is generated for multiple alignments. Need __builtin_assume_aligned
    – Jens Munk
    Jun 17, 2017 at 7:55
  • In that case you'd probably find icc is the best option if it's available to you as it will automatically generate codepaths for multiple instruction sets and do runtime dispatchng. If you have to stay with MSVC and gcc, I think you'll have to do your own runtime dispatching on MSVC, and runtime dispatch between modules compiled with different code-gen options for gcc 4.9.x ... later versions may well do very different things but I'm stuck on 4.9 for now so can't say.
    – Tim
    Jun 17, 2017 at 9:04
  • Oh, and I don't worry about alignment .... on modern chips, even when executing SSE instructions, an unaligned load op of an aligned address is basically as fast as an aligned load op on the same address. So I use unaligned ops everywhere (but try to ensure allocations are aligned) - for me the added complexity wasn't worth it.
    – Tim
    Jun 17, 2017 at 9:07
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    GCC allows you to use intrinsics ISA extensions not declared at compile-time by attaching the target attribute to the function. See gcc.gnu.org/onlinedocs/gcc/…
    – nemequ
    Jun 18, 2017 at 18:12
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    Turns out there is an option for that. Try using gcc -mprefer-avx128 -O3 -march=native for your code. (128-bit AVX instructions don't trigger the turbo limiting.) -mprefer-avx128 is enabled by default for AMD Bulldozer (-mtune=bdver1). Jul 2, 2017 at 6:04

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