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Everybody knows you're not supposed to compare floats directly, but rather using a tolerance:

float a,b;
float epsilon = 1e-6f;
bool equal = (fabs(a-b) < epsilon);

I was wondering if the same applies to comparing a value to zero before using it in division.

float a, b;
if (a != 0.0f) b = 1/a; // oops?

Do I also need to compare with epsilon in this case?

share|improve this question
Don't check for 0 at all. Let it crash hard! – Luchian Grigore Aug 24 '12 at 18:05
Everybody knows you're not supposed to compare floats using a tolerance, but rather in a way that makes sense for what you want. @LuchianGrigore it won't crash. – R. Martinho Fernandes Aug 24 '12 at 18:05
You won't have errors if b isn't exactly 0. But if b is too small, the result may not make sense, it depends on your application logic. – Denys Séguret Aug 24 '12 at 18:07
@LuchianGrigore Only if you don't know what to do in case of 0. But I'm pretty sure that there are cases where it makes sense to treat 0 specially. Also, not all environments make it crash, some just give you a strange value (I'm not sure if it's NaN, one of the infinities, or something else). – delnan Aug 24 '12 at 18:07
Potentially consider using Q numbers, if they are suitable to your situation... – 0909EM Aug 24 '12 at 18:08
up vote 62 down vote accepted

Floating point division by zero is not an error. It raises a floating point exception (which is a no-op unless you're actively checking them) on implementations that support floating point exceptions, and has well-defined result: either positive or negative infinity (if the numerator is nonzero), or NAN (if the numerator is zero).

It's also possible to get infinity (and an overflow exception) as the result when the denominator is nonzero but very close to zero (e.g. subnormal), but again this is not an error. It's just how floating point works.

Edit: Note that, as Eric has pointed out in the comments, this answer assumes the requirements of Annex F, an optional part of the C standard detailing floating point behavior and aligning it with the IEEE standard for floating point. In the absence of IEEE arithmetic, C does not define floating point division by zero (and in fact, the results of all floating point operations are implementation-defined and may be defined as complete nonsense and still conform to the C standard), so if you're dealing with an outlandish C implementation that does not honor IEEE floating point, you'll have to consult the documentation for the implementation you're using to answer this question.

share|improve this answer
Let me underscore: a floating-point exception is not a C++ exception. You can't put a try-catch block around it. You won't see it unless you go gunning for it, and that takes a bit of expertise. As @R.. said, it's a no-op unless you know how to find it. And you don't want to do that unless you're an expert. – Pete Becker Aug 24 '12 at 18:39
Thanks Pete for emphasizing that point. Unless you're using fenv.h (most people haven't even heard of it, much less used it), floating point exceptions are irrelevant/no-ops. – R.. Aug 24 '12 at 18:41
The C standard does not define the default floating-point environment unless an implementation adopts Annex F. Without Annex F, traps may be enabled by default. Using high-performance options when compiling may enable modes that do not conform to the C standard or with IEEE 754. A blanket statement that division by zero is not an error is unwarranted. – Eric Postpischil Aug 24 '12 at 19:07
Without Annex F, there are basically no requirements on behavior of floating point. 2.0+2.0==5.0 can be true. It's meaningless to talk about floating point in C without assuming Annex F. – R.. Aug 24 '12 at 19:43
Can you please cite the part of the C standard that implies 2.0+2.0!=5.0? I am not aware of any such requirement. – R.. Aug 24 '12 at 20:38

Yes, dividing by small numbers can cause the same effects as dividing by zero, including traps, in some situations.

Some C implementations (and some other computing environments) may execute in a flush-underflow mode, especially if options for high-performance are used. In this mode, dividing by a denormal can cause the same result as dividing by zero. Flush-underflow mode is not uncommon when vector (SIMD) instructions are used.

Denormal numbers are those with the minimum exponent in the floating-point format which are so small that the implicit bit of the significand is 0 instead of 1. For IEEE 754, single-precision, this is non-zero numbers with magnitude less than 2-126. For double-precision, it is non-zero numbers with magnitude less than 2-1022.

Handling denormal numbers correctly (in accordance with IEEE 754) requires additional computing time in some processors. To avoid this delay when it is not needed, processors may have a mode which convert denormal operands to zero. Dividing a number by a denormal operand will then produce the same result as dividing by zero, even if the usual result would be finite.

As noted in other answers, dividing by zero is not an error in C implementations that adopt Annex F of the C standard. Not all implementations that do. In implementations that do not, you cannot be sure whether floating-point traps are enabled, in particular the trap for the divide-by-zero exception, without additional specifications about your environment.

Depending on your situation, you might also have to guard against other code in your application altering the floating-point environment.

share|improve this answer
Totally nitpicky point: the 2008 revision of IEEE-754 changed "denormal" to "subnormal". This change in terminology does not change any of the points made above. – Pete Becker Aug 24 '12 at 19:26
requires additional computing time in some processors In fact, it's not in some processors — it's in most of the current processors, including x86 and ARM ones. – Ruslan Aug 11 '15 at 8:36

To answer the question in the title of your post, dividing by a very small number will not cause a division by zero, but it may cause the result to become an infinity:

double x = 1E-300;
cout << x << endl;
double y = 1E300;
cout << y << endl;
double z = y / x;
cout << z << endl;
cout << (z == std::numeric_limits<double>::infinity()) << endl;

This produces the following output:

share|improve this answer
Is it possible to test if a value is infinity? – neuviemeporte Aug 24 '12 at 18:36
z!=z is false for infinities. It's only true for nans. – R.. Aug 24 '12 at 18:41
@neuviemeporte Yes - take a look at the update to the answer. – dasblinkenlight Aug 24 '12 at 18:42
@R.. Thanks, I went to check the trick, and it didn't work, so I went for a lengthier way of checking it. – dasblinkenlight Aug 24 '12 at 18:43
@neuviemeporte Since C99 in math.h the macro int isfinite(float x) is defined, that returns a non-zero result only when x is finite. See – halex Aug 24 '12 at 18:55

Only a division by exactly 0.f will raise a division by zero exception.

However, division by a really small number can generate an overflow exception - the result is so large that it no longer can be represented by a float. The division will return infinity.

The float representation of infinity can be used in calculations so there might not be a need to check for it if the rest of your implementation can handle it.

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Do I also need to compare with epsilon in this case?

You won't ever receive a divide by zero error, as 0.0f is represented exactly in an IEEE float.

That being said you may still want to use some tolerance - though this depends completely on your application. If the "zero" value is the result of other math, it's possible to get a very small, non-zero number, which may cause an unexpected result after your division. If you want to treat "near zero" numbers as zero, a tolerance would be appropriate. This completely depends on your application and goals, however.

If your compiler is using IEEE 754 standards for exception handling, then divide by zero, as well as a division by a value which is small enough to cause an overflow, would both result in a value of +/- infiniti. This could mean that you could want to include the check for very small numbers (that would cause an overflow on your platform). For example, on Windows, float and double both conform to the specifications, which could cause a very small divisor to create +/- infiniti, just like a zero value.

If your compiler/platform is not following IEEE 754 floating point standards, then I believe the results are platform specific.

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Was that really the question? It's great that 0 is represented exactly, but does that imply no other value can have the same result as divison by zero? – delnan Aug 24 '12 at 18:09
@delnan It's not exactly clear - given teh question "Can a near-zero floating value cause a divide-by-zero error?" - yes, I think this answers it directly ;) I did try to raise other points, though, in my answer... – Reed Copsey Aug 24 '12 at 18:10
I'm also referring to that part of the question. After all, it is conceivable (for uneducated me) that some values extremely close to zero cause the same floating point exception as division by exact zero does. -1 for now. – delnan Aug 24 '12 at 18:12
@delnan Typically a true "divide by zero" is really only divide by zero. I believe this may be platform specific though - for example, on Windows, div/0 will raise EXCEPTION_FLT_DIVIDE_BY_ZERO by I believe div/(nr 0) can raise EXCEPTION_FLT_OVERFLOW on windows - See:… – Reed Copsey Aug 24 '12 at 18:15
Please, add this kind of information to the answer instead. – delnan Aug 24 '12 at 18:17

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