# Difference in accuracy with floating point division vs multiplication

Is there a difference between this:

``````average = (x1+x2)/2;
deviation1 = x1 -average;
deviation2 = x2 -average;
variance = deviation1*deviation1 + deviation2*deviation2;
``````

and this:

``````average2 = (x1+x2);
deviation1 = 2*x1 -average2;
deviation2 = 2*x2 -average2;
variance = (deviation1*deviation1 + deviation2*deviation2) / 4;
``````

Note that in the second version I am trying to delay division as late as possible. Does the second version [delay divisions] increase accuracy in general?

Snippet above is only intended as an example, I am not trying to optimize this particular snippet.

BTW, I am asking about division in general, not just by 2 or a power of 2 as they reduce to simple shifts in IEEE 754 representation. I took division by 2, just to illustrate the issue using a very simple example.

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Why are you trying to delay it? What do you expect to gain from that? –  paxdiablo Jun 26 '11 at 7:31
@paxdiablo - that's the exact question - do I gain precision (not perf.) by delaying it. –  Fakrudeen Jun 26 '11 at 7:34
actually you should be asking about accuracy rather than precision but the answer is still the same –  David Heffernan Jun 26 '11 at 7:48
Is this language-agnostic? Shouldn't you also worry about positions where type-changes occur? Are they integers, floats, strings? When are they changed into something else? –  Nanne Jun 26 '11 at 8:00
@David - yes - I really meant accuracy - thanks for the correction. –  Fakrudeen Jun 26 '11 at 9:33

There's nothing to be gained from this. You are only changing the scale but you'd don't get any more significant figures in your calculation.

The Wikipedia article on variance explains at a high level some of the options for calculation variance in a robust fashion.

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The point is I am postponing division to as late as possible. Can you site a reference why they are the same? I know about "What Every Computer Scientist Should Know About Floating-Point Arithmetic" - but it doesn't talk about this exact thing. –  Fakrudeen Jun 26 '11 at 7:30
what's special about division? It's the same as multiplication. You replace divide by 2 with multiply by 2. It's addition and subtraction that you need to worry about. –  David Heffernan Jun 26 '11 at 7:37
But wouldn't there be 6 round off in first and only 2 in second? I should try to reduce round off as much as possible? First: 1'/',2'-',2'*' and 1'+'. Second: 1'/' and 1 conversion. Assuming x1 and x2 are int. –  Priyank Bhatnagar Jun 26 '11 at 7:51
@logic what are you talking about. 1. Question is about floating point. 2. You don't get round off with int. –  David Heffernan Jun 26 '11 at 7:53
Division just shifts the scale. Your real problem with variance calculation is cancellation from the subtractions. –  David Heffernan Jun 26 '11 at 9:54

You do not gain precision from this since IEEE754 (which is probably what you're using under the covers) gives you the same precision (number of bits) at whatever scale you're working. For example 3.14159 x 107 will be as precise as 3.14159 x 1010.

The only possible advantage (of the former) is that you may avoid overflow when setting the deviations. But, as long as the values themselves are less than half of the maximum possible, that won't be a problem.

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I think you mean accuracy rather than precision. –  David Heffernan Jun 26 '11 at 7:51
@David, no, I meant precision as in how precise the value is. The precision is a specific IEEE754 term meaning the number of bits in the significand plus one (for the implied bit). Accuracy is a more amorphous concept since a value with a higher scale and same precision can be less accurate (if you consider accuracy to be how close a number is to it's exact value). –  paxdiablo Jun 26 '11 at 8:12
I clearly don't understand your argument. I don't understand why precision is relevant. What's important is how close you are to the true answer, not how many bits you have in your significand. –  David Heffernan Jun 26 '11 at 8:28
Yes I know all that. My answer says the same but I don't use the term precision so loosely. All values have the same precision. A random value will have the same precision as the closest representation to the true value. –  David Heffernan Jun 26 '11 at 9:19
I know what precision is. I know you aren't making it up. It's just not the point. If the question is about finding a method that results in an answer close to the true value then precision is irrelevant. All answers have the same precision. –  David Heffernan Jun 26 '11 at 9:49

I have to agree with David Heffernan, it won't give you a higher precision.

The reason is how float values are stored. You have some bits representing the significant digits and some bits representing the exponent (for example 3.1714x10-12). The bits for the significant digits will always be the same no matter how large your number is - which means in the end the result will not really be a different one.

Even worse - delaying the division can get you an overflow if you have very large numbers.

If you really need a higher precision there are lots of Libraries allowing large numbers or numbers with higher precision.

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Javascript? Did someone mention Javascript? –  paxdiablo Jun 26 '11 at 7:45
sorry - that was my mistake. I corrected my answer. It will be the same for C/C++/C#/Java and so on. –  Preli Jun 26 '11 at 7:48

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.

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Are you really asserting that simulation with random data is the best way to analyse numerical stability of an algorithm? –  David Heffernan Jun 26 '11 at 8:05
@David: no.......... –  ninjagecko Jun 26 '11 at 8:22
so this is the best way to do what exactly? –  David Heffernan Jun 26 '11 at 8:29