# Why does division by zero in IEEE754 standard results in Infinite value?

I'm just curious, why in `IEEE-754` any non zero float number divided by zero results in infinite value? It's a nonsense from the mathematical perspective. So I think that correct result for this operation is NaN.

Function f(x) = 1/x is not defined when x=0, if x is a real number. For example, function sqrt is not defined for any negative number and sqrt(-1.0f) if `IEEE-754` produces a `NaN` value. But 1.0f/0 is `Inf`.

But for some reason this is not the case in `IEEE-754`. There must be a reason for this, maybe some optimization or compatibility reasons.

So what's the point?

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There is some interesting discussion on this in this pdf: cs.berkeley.edu/~wkahan/ieee754status/IEEE754.PDF. –  Kirby Feb 4 '13 at 7:23
There is no one, single, unifying "the mathematical perspective". There are all sorts of branches of mathematics and, within those, many different interpretations of the concept of infinity and division-by-zero. –  Lightness Races in Orbit Feb 4 '13 at 8:49
Both limits, approaching from left and from right, are defined. That's why it's commonly accepted that result is infinity. –  Michael Pankov Feb 4 '13 at 11:05
why nonsense? From a mathematical perspective lim[x→0](1/x) = ∞ –  Lưu Vĩnh Phúc Dec 22 '13 at 13:58
Right limit is ∞, left limit is -∞ and function f(x) = 1/x doesn't exist at f(0). –  Lazin Dec 23 '13 at 14:44

It's a nonsense from the mathematical perspective.

Yes. No. Sort of.

The thing is: Floating-point numbers are approximations. You want to use a wide range of exponents and a limited number of digits and get results which are not completely wrong. :)

The idea behind IEEE-754 is that every operation could trigger "traps" which indicate possible problems. They are

• Illegal (senseless operation like sqrt of negative number)
• Overflow (too big)
• Underflow (too small)
• Division by zero (The thing you do not like)
• Inexact (This operation may give you wrong results because you are losing precision)

Now many people like scientists and engineers do not want to be bothered with writing trap routines. So Kahan, the inventor of IEEE-754, decided that every operation should also return a sensible default value if no trap routines exist.

They are

• NaN for illegal values
• signed infinities for Overflow
• signed zeroes for Underflow
• NaN for indeterminate results (0/0) and infinities for (x/0 x != 0)
• normal operation result for Inexact

The thing is that in 99% of all cases zeroes are caused by underflow and therefore in 99% of all times Infinity is "correct" even if wrong from a mathematical perspective.

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The last sentence sound very pragmatic for me. –  Lazin Feb 4 '13 at 10:36
The level of numerical "sensibility" could be improved if literal zero, as well as the results of positive underflow, negative underflow, and subtraction of indistinguishable values, were all distinct, but adding such additional forms of "zero" would have complicated floating-point hardware. The IEEE standard merges the above into two forms of zero, which causes some things that should be NaN to become +INF. I suspect the rationale was that having division by +/- zero yield +/- INF instead of NaN wouldn't add much hardware, and would occasionally be useful. –  supercat Feb 4 '13 at 16:32
Yes, and this clarifies rationale behind signed zero in IEEE standard. –  Lazin Feb 8 '13 at 7:07

Why do you believe this to be nonsense?

The simplistic definition of `a / b` is the number of `b`s that has to be subtracted from `a` before you get to zero.

The number of `0`s that has to be subtracted from any non-zero number to get to zero is indeed infinite.

`NaN` is reserved for situations where the number cannot be represented (even approximately) by any other value.

For example, `0 / 0` (using our simplistic definition above) can have any amount of `b`s subtracted from `a` to reach 0. Hence the result is indeterminate.

Similarly things like the square root of a negative number, which has no value in the real plane used by IEEE754 (you have to go complex), cannot be represented.

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On the other hand if 1/0 is Inf than Inf*0 must be equal to 1 but this is not the case :) –  Lazin Feb 4 '13 at 7:26
@Lazin, while that is humorous, it doesn't actually work that way since "infinity" is a concept meaning "beyond number", it isn't actually a number itself. So, while 1/0 gives you something beyond number, an infinite number of zeros will always be 0. Now my head is about to explode because all that transfinite rubbish I forgot so long ago is flooding my cranium - I'll have to invoice you for removing the gore and brain matter from my keyboard :-) –  paxdiablo Feb 4 '13 at 7:42
@paxdiablo Whether infinity is part of an arithmetic system depends entirely on how that system is defined. Consider projective and extended real line arithmetic. –  Patricia Shanahan Feb 4 '13 at 17:21