The best way to answer your question would be to run tests (both randomly-distributed and range-based?) and see if the resulting numbers differ at all in the binary representation.

Note that one issue you'll have if you do this is that your functions won't work for value `> MAX_INT/2`

, because of the way you code average.

```
avg = (x1+x2)/2 # clobbers numbers > MAX_INT/2
avg = 0.5*x1 + 0.5*x2 # no clobbering
```

This is almost certainly not an issue though unless you are writing a language-level library. And if most of your numbers are small, it may not matter at all? In fact it probably isn't worth considering, since the value of variance will exceed `MAX_INT`

since it is inherenty a squared quantity; I'd say you might wish to use standard deviation, but no one does that.

Here I do some experiments in python (which I think supports the IEEE whatever-it-is by virtue of probably delegating math to C libraries...):

```
>>> def compare(numer, denom):
... assert ((numer/denom)*2).hex()==((2*numer)/denom).hex()
>>> [compare(a,b) for a,b in product(range(1,100),range(1,100))]
```

No problem, I think because division and multiplication by 2 is nicely representable in binary. However try multiplication and division by 3:

```
>>> def compare(numer, denom):
... assert ((numer/denom)*3).hex()==((3*numer)/denom).hex(), '...'
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
File "<stdin>", line 1, in <listcomp>
File "<stdin>", line 2, in compare
AssertionError: 0x1.3333333333334p-1!=0x1.3333333333333p-1
```

Does it probably matter much? Perhaps if you're working with very small numbers (in which case you may wish to use **log arithmetic**). However if you're working with large numbers (uncommon in probability) and you delay division, you will as I mentioned risk overflow, but even worse, **risk bugs due to hard-to-read code**.

Whyare you trying to delay it? What do you expect to gain from that? – paxdiablo Jun 26 '11 at 7:31