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I'm running on an x86 CentOS 6.3 (kernel v2.6.32) system.

I compiled the following function into a bare-bones character driver module as an experiment to see how the Linux kernel reacts to floating point operations.

static unsigned floatstuff(void){
    float x = 3.14;
    x *= 2.5;
    return x;
}

...

printk(KERN_INFO "x: %u", x);

The code compiled (which wasn't expecting) so I inserted the module and checked the log with dmesg. The log showed: x: 7.

This seems strange; I thought you couldn't perform floating point operations in the Linux kernel -- save some exceptions such as kernel_fpu_begin(). How did the module perform the floating point operation?

Is this because I'm on an x86 processor?

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1  
Why wouldn't a kernel be able to do floating-point operations? –  Mysticial Apr 8 '13 at 16:11
    
Why are you so surprised? A kernel module is, after all, just another piece of code to be executed by the CPU. As long as it can execute the opcodes you throw at it, you're fine. –  Daniel Kamil Kozar Apr 8 '13 at 16:11
6  
Also, it's quite possible that the arithmetic is performed during the compilation and all that remains is a return 7;. –  Daniel Fischer Apr 8 '13 at 16:12
    
@DanielFischer You are correct: the floating point operations were being optimized out. I now get the following error when I try to perform the operations: Unknown symbol _mulsf3. Is this the error I was expecting (that the floating point multiplication can't be performed)? –  Vilhelm Gray Apr 8 '13 at 16:24
4  
This is already answered here: stackoverflow.com/questions/13886338/… The question is more of a not-so-correct statement the answer is explanatory. And you can do FP in kernel. –  jim mcnamara Apr 8 '13 at 16:26

1 Answer 1

up vote 2 down vote accepted

Not sure where this perception is coming from. But the kernel executes on the same processor as the user mode code, and therefore has access to the same instruction set. If the processor can do floating point (directly or by a co-processor), the kernel can too.

Maybe you are thinking of cases where floating point arithmetic is emulated in software. But even so, it would be available in kernel (well, unless disabled somehow).

I am curious, where is this perception coming from? Maybe I am missing something.

Found this. Seems to be a good explanation.

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Perhaps my question is a bit misleading. I understand that the FPU can execute these floating point instructions (i.e. the machine code itself is system agnostic), but I'm confused on how to get my C code to compile without the GCC errors about undefined symbols such as __fixunssfsi when I'm compiling the kernel module. I suspect this is just GCC depending on helper routines in a library the kernel excludes, so how do I get around this so that the correct machine code is generated -- the processor supports floating point after-all. –  Vilhelm Gray Apr 8 '13 at 17:47
    
Let me add that I am aware floating point registers are not saved; I don't particularly care about this trashing a userland program since I'm purely experimenting with code to get a better understanding of the behavior. –  Vilhelm Gray Apr 8 '13 at 17:50
1  
I figured it out; I needed to pass this compiler flag to GCC: -mhard-float. –  Vilhelm Gray Apr 8 '13 at 18:13
    
The point is that the floating point state is not correctly saved & restored from inside the kernel, e.g. when scheduling tasks (it is saved only from inside application's point of view). –  Basile Starynkevitch Apr 8 '13 at 18:32

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