Well, this is not at all an optimization question.
I am writing a (for now) simple Linux kernel module in which I need to find the average of some positions. These positions are stored as floating point (i.e.
float) variables. (I am the author of the whole thing, so I can change that, but I'd rather keep the precission of float and not get involved in that if I can avoid it).
Now, these position values are stored (or at least used to) in the kernel simply for storage. One user application writes these data (through shared memory (I am using RTAI, so yes I have shared memory between kernel and user spaces)) and others read from it. I assume read and write from float variables would not use the FPU so this is safe.
By safe, I mean avoiding FPU in the kernel, not to mention some systems may not even have an FPU. I am not going to use kernel_fpu_begin/end, as that likely breaks the real-time-ness of my tasks.
Now in my kernel module, I really don't need much precision (since the positions are averaged anyway), but I would need it up to say 0.001. My question is, how can I portably turn a floating point number to an integer (1000 times the original number) without using the FPU?
I thought about manually extracting the number from the float's bit-pattern, but I'm not sure if it's a good idea as I am not sure how endian-ness affects it, or even if floating points in all architectures are standard.