I assume you use
floor because negative values are possible, and because you don't want an anomaly due to the default truncation when you cast to
int (values rounding toward zero from both sides, making some oversized voxels).
If you can specify a safe most-negative value for each value in the vector, you could subtract that (negative) value, or rather the nearest more-negative multiple of
_gridIntervalSize, before the cast, and drop the
fmod may ensure you have a safe most-negative value, and replace the integer
%, but it's probably an anti-optimisation. Still, as a quick change, it may be worth checking.
Also, check whether your platform supports vector instructions, and whether your compiler can easily be encouraged to use them. x86 chips certainly have integer vector instructions as well as float (the old Pentium 1 MMX instructions, for a start) and might be able to handle this much more efficiently than the "normal" CPU instruction set. This may even be a case for digging out the list of vector instruction intrinsics for your compiler and doing some hand-optimisation. Just check what the compiler can do for you first - I'm not sure how much of this kind of optimisation compilers will do for you already.
One probably trivial piece of micro-optimisation...
return (mx * _gridSize + my) * _gridSize + mz;
Saves one integer multiplication. Trivial, of course, and the compiler may catch it anyway, but this is an old habitual thing.
Oh - watch the leading underscores. Those are reserved identifiers. Not likely to cause a problem, but you can't complain if they do.
Another way to avoid the
floor is to handle positive and negative separately. If you are willing to accept that items bang-on-the-edge of a grid cell may be in the wrong cell (possible anyway since floats should be considered approximate). Just apply a
-1 offset in the negative case, to pull it away from the zero by almost exactly right amount to compensate for the truncation. You might consider a bit-fiddling increment-the-mantissa afterwards (to get already integer values in the cell you'd expect) but this is probably unnecessary.
If you can impose power-of-two limitations to your sizes, there may be a bit-fiddling way to efficiently extract the grid position from a float, avoiding some or all of the multiply, floor and
% for each of x, y and z, assuming a standard floating point representation (ie this is non-portable). Again, handle positive and negative separately. Extract the exponent, bit-shift the mantissa accordingly, then mask out unwanted bits.