# 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?

• There is some interesting discussion on this in this pdf: cs.berkeley.edu/~wkahan/ieee754status/IEEE754.PDF. – Kirby Feb 4 '13 at 7:23
• 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) = ∞ – phuclv 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.

• 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
• @supercat you should definitely write your comment as an answer – Walter Tross Dec 22 '15 at 18:37

I'm not sure why you would believe this to be nonsense.

The simplistic definition of `a / b`, at least for non-zero `b`, is the unique number of `b`s that has to be subtracted from `a` before you get to zero.

Expanding that to the case where `b` can be zero, the number that has to be subtracted from any non-zero number to get to zero is indeed infinite, because you'll never get to zero.

Another way to look at it is to talk in terms of limits. As a positive number `n` approaches zero, the expression `1 / n` approaches "infinity". You'll notice I've quoted that word because I'm a firm believer in not propagating the delusion that infinity is actually a concrete number :-)

`NaN` is reserved for situations where the number cannot be represented (even approximately) by any other value (including the infinities), it is considered distinct from all those other values.

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 - it could be 1, 7, 42, 3.14159 or any other value.

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 to the complex plane for that), cannot be represented.

• 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
• Just to add, Numberphile (youtube.com/watch?v=BRRolKTlF6Q) has a great video on why `x / 0` should not be considered infinity including addressing the thought that "I can take 0 from x an infinite number of times". The summary is that form a algebra point of view, you are are never supposed to say something is "equal to infinity", since at you point out it's not a number. – Evan Teran Dec 4 '15 at 16:59
• "The number of 0s that has to be subtracted from any non-zero number to get to zero is indeed infinite." — no, because you /still/ don't get to zero after infinitely many zero-subtractions. – Daan Wilmer Dec 8 '15 at 15:50

In mathematics, division by zero is undefined because zero has no sign, therefore two results are equally possible, and exclusive: negative infinity or positive infinity (but not both).

In (most) computing, 0.0 has a sign. Therefore we know what direction we are approaching from, and what sign infinity would have. This is especially true when 0.0 represents a non-zero value too small to be expressed by the system, as it frequently the case.

The only time NaN would be appropriate is if the system knows with certainty that the denominator is truly, exactly zero. And it can't unless there is a special way to designate that, which would add overhead.

NOTE: I re-wrote this following a valuable comment from @Cubic.

I think the correct answer to this has to come from calculus and the notion of limits. Consider the limit of `f(x)/g(x)` as `x->0` under the assumption that `g(0) == 0`. There are two broad cases that are interesting here:

1. If `f(0) != 0`, then the limit as `x->0` is either plus or minus infinity, or it's undefined. If `g(x)` takes both signs in the neighborhood of `x==0`, then the limit is undefined (left and right limits don't agree). If `g(x)` has only one sign near 0, however, the limit will be defined and be either positive or negative infinity. More on this later.
2. If `f(0) == 0` as well, then the limit can be anything, including positive infinity, negative infinity, a finite number, or undefined.

In the second case, generally speaking, you cannot say anything at all. Arguably, in the second case `NaN` is the only viable answer.

Now in the first case, why choose one particular sign when either is possible or it might be undefined? As a practical matter, it gives you more flexibility in cases where you do know something about the sign of the denominator, at relatively little cost in the cases where you don't. You may have a formula, for example, where you know analytically that `g(x) >= 0` for all `x`, say, for example, `g(x) = x*x`. In that case the limit is defined and it's infinity with sign equal to the sign of `f(0)`. You might want to take advantage of that as a convenience in your code. In other cases, where you don't know anything about the sign of `g`, you cannot generally take advantage of it, but the cost here is just that you need to trap for a few extra cases - positive and negative infinity - in addition to `NaN` if you want to fully error check your code. There is some price there, but it's not large compared to the flexibility gained in other cases.

Why worry about general functions when the question was about "simple division"? One common reason is that if you're computing your numerator and denominator through other arithmetic operations, you accumulate round-off errors. The presence of those errors can be abstracted into the general formula format shown above. For example `f(x) = x + e`, where `x` is the analytically correct, exact answer, `e` represents the error from round-off, and `f(x)` is the floating point number that you actually have on the machine at execution.

• "When n==0, then you have no limit at all since, approached form the left, you get negative infinity and, approached from the right, you get positive infinity. From calculus, when the left and right limits do not match you have no limit at all" I'm astonished that you do remember this much, and somehow still get it wrong in your first sentence. Indeed, the limit is undefined if the "left" and "right" limits disagree... but this is the case for any `n`, not just 0. It's not uncommon to get these wrong, but please don't lecture people on subjects you don't understand. – Cubic Feb 19 '18 at 14:20
• @Cubic There is something wrong here, so I'll either correct or delete shortly. Interestingly though, especially considering your nasty tone, your comment is also wrong. When n==0 in the expression that I wrote, the limit is 0. That's a special case where the limit is defined because, in that case, the left and right limits do agree. – Brick Feb 19 '18 at 14:51
• Haha, maybe I should've taken my own advice then ;) Not sure what you mean by nasty tone though. – Cubic Feb 19 '18 at 15:27
• Again, I don't quite see it. I meant it quite literally, don't answer questions you don't have the answer to, otherwise you'll just perpetuate common misconceptions. I try to abide by that myself, but obviously sometimes you're just wrong without realising it (like I helpfully demonstrated here myself). – Cubic Feb 19 '18 at 16:30
• @Cubic See if you like this one version. If so, I propose that we each delete our comments on the old answer. (I'll take an up-vote or the disappearance of your comments as agreement!) :) If still not precise enough, I'm open to another revision or abandoning it. (Despite my mistake, I do know something here....) – Brick Feb 19 '18 at 17:31