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I'm trying to build a library for a Cortex A9 ARM processor(an OMAP4 to be more specific) and I'm in a little bit of confusion regarding which\when to use NEON vs VFP in the context of floating point operations and SIMD. To be noted that I know the difference between the 2 hardware coprocessor units(as also outlined here on SO), I just have some misunderstanding regarding their proper usage.

Related to this I'm using the following compilation flags:

-O3 -mcpu=cortex-a9 -mfpu=neon -mfloat-abi=softfp
-O3 -mcpu=cortex-a9 -mfpu=vfpv3 -mfloat-abi=softfp
--cpu=Cortex-A9 --apcs=/softfp
--cpu=Cortex-A9 --fpu=VFPv3 --apcs=/softfp

I've read through the ARM documentation, a lot of wiki(like this one), forum and blog posts and everybody seems to agree that using NEON is better than using VFP or at least mixing NEON(e.g. using the instrinsics to implement some algos in SIMD) and VFP is not such a good idea; I'm not 100% sure yet if this applies in the context of the entire application\library or just to specific places(functions) in code.

So I'm using neon as the FPU for my application as I also want to use the intrinsics. As a result I'm in a little bit of trouble and my confusion on how to best use these features(NEON vs VFP) on the Cortex A9 just deepens further instead of clearing up. I have some code that does benchmarking for my app and uses some custom made timer classes in which calculations are based on double precision floating point. Using NEON as the FPU gives completely inappropriate results(trying to print those values results in printing mostly inf and NaN; the same code works without a hitch when built for x86). So I changed my calculations to use single precision floating point as is documented that NEON does not handle double precision floating point. My benchmarks still don't give the proper results(and what's worst is that now it does not work anymore on x86; I think it's because of the lost in precision but I'm not sure). So I'm almost completely lost: on one hand I want to use NEON for the SIMD capabilities and using it as the FPU does not provide the proper results, on the other hand mixing it with the VFP does not seem a very good idea. Any advice in this area will be greatly appreciated !!

I found in the article in the above mentioned wiki a summary of what should be done for floating point optimization in the context of NEON:


  • Only use single precision floating point
  • Use NEON intrinsics / ASM when ever you find a bottlenecking FP function. You can do better than the compiler.
  • Minimize Conditional Branches
  • Enable RunFast mode

For softfp:

  • Inline floating point code (unless its very large)
  • Pass FP arguments via pointers instead of by value and do integer work in between function calls.


I cannot use hard for the float ABI as I cannot link with the libraries I have available. Most of the reccomendations make sense to me(except the "runfast mode" which I don't understand exactly what's supposed to do and the fact that at this moment in time I could do better than the compiler) but I keep getting inconsistent results and I'm not sure of anything right now.

Could anyone shed some light on how to properly use the floating point and the NEON for the Cortex A9/A8 and which compilation flags should I use?

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Give auto-vectorization a shot too. If using the ARM RVCT compiler, add --vectorize to the command line (You might need a professional RVCT license in order to try this though, so pls keep that in mind) –  NullPointer Sep 1 '11 at 14:02
Your suggestion is related to the SIMD. My issue is about properly using the floating point capabilities of either NEON of the VFP unit. –  celavek Sep 1 '11 at 14:45

2 Answers 2

I think this question should be split up into several, adding some code examples and detailing target platform and versions of toolchains used.

But to cover one part of confusion: The recommendation to "use NEON as the FPU" sounds like a misunderstanding. NEON is a SIMD engine, the VFP is an FPU. You can use NEON for single-precision floating-point operations on up to 4 single-precision values in parallel, which (when possible) is good for performance.

--mfpu=neon can be seen as shorthand for --mfpu=neon-vfpv3.

See http://gcc.gnu.org/onlinedocs/gcc/ARM-Options.html for more information.

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I'd stay away from VFP. It's just like the Thmub mode : It's meant to be for compilers. There's no point in optimizing for them.

It might sound rude, but I really don't see any point in NEON intrinsics either. It's more trouble than help - if any.

Just invest two or three days in basic ARM assembly: you only need to learn few instructions for loop control/termination.

Then you can start writing native NEON codes without worrying about the compiler doing something astral spitting out tons of errors/warnings.

Learning NEON instructions is less demanding than all those intrinsics macros. And all above this, the results are so much better.

Fully optimized NEON native codes usually run more than twice as fast than well-written intrinsics counterparts.

Just compare the OP's version with mine in the link below, you'll then know what I mean.

Optimizing RGBA8888 to RGB565 conversion with NEON


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Bad support of NEON intrinsics is GCC's problem. Better compilers optimize them quite well. However, I agree, sometimes it's easier to write in direct asm than wasting time figuring out what's the right intrinsic name for some opcode –  Pavel Dec 1 '11 at 6:00
Also, VFP and and SIMD are different things. You'll waste time and might not get appropriate results with NEON for sqrt for example. –  Pavel Dec 1 '11 at 6:02

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