# Is it possible to get 0 by subtracting two unequal floating point numbers?

Is it possible to get division by 0 (or infinity) in the following example?

``````public double calculation(double a, double b)
{
if (a == b)
{
return 0;
}
else
{
return 2 / (a - b);
}
}
``````

In normal cases it will not, of course. But what if `a` and `b` are very close, can `(a-b)` result in being `0` due to precision of the calculation?

Note that this question is for Java, but I think it will apply to most programming languages.

• I would have to try all combinations of doubles, that will take a while :) – Thirler Feb 12 '15 at 10:01
• @Thirler sounds like a time to use JUnit Testing to me! – Matt Clark Feb 12 '15 at 10:02
• @bluebrain, my guess is that your your literal number 2.000 etc contains to many decimals to be represented by a float. So the last ones will not be represented by the actual used number in the comparison. – Thirler Feb 12 '15 at 10:08
• @Thirler probably. 'you can't really guarantee that the number you assign to the float or double is exact' – guness Feb 12 '15 at 10:11
• Just note that returning 0 in that case can lead to hard-to-debug ambiguity, so make sure you really want to return 0 instead of throwing an exception or returning a NaN. – m0skit0 Feb 12 '15 at 14:45

In Java, `a - b` is never equal to `0` if `a != b`. This is because Java mandates IEEE 754 floating point operations which support denormalized numbers. From the spec:

In particular, the Java programming language requires support of IEEE 754 denormalized floating-point numbers and gradual underflow, which make it easier to prove desirable properties of particular numerical algorithms. Floating-point operations do not "flush to zero" if the calculated result is a denormalized number.

If an FPU works with denormalized numbers, subtracting unequal numbers can never produce zero (unlike multiplication), also see this question.

For other languages, it depends. In C or C++, for example, IEEE 754 support is optional.

That said, it is possible for the expression `2 / (a - b)` to overflow, for example with `a = 5e-308` and `b = 4e-308`.

• However OP wants to know about 2/(a-b). Can this be guaranteed to be finite? – Taemyr Feb 12 '15 at 10:47
• Thanks for the answer, I added a link to wikipedia for the explanation of denormalized numbers. – Thirler Feb 12 '15 at 10:57
• @Taemyr See my edit. The division actually can overflow. – nwellnhof Feb 12 '15 at 11:03
• @Taemyr `(a,b) = (3,1)` => `2/(a-b) = 2/(3-1) = 2/2 = 1` Whether this is true with IEEE floating point, I don't know – Cole Johnson Feb 12 '15 at 18:59
• @DrewDormann IEEE 754 is also optional for C99. See Annex F of the standard. – nwellnhof Feb 18 '15 at 10:40

As a workaround, what about the following?

``````public double calculation(double a, double b) {
double c = a - b;
if (c == 0)
{
return 0;
}
else
{
return 2 / c;
}
}
``````

That way you don't depend on IEEE support in any language.

• Avoid the problem and simplify the test all at once. Me like. – Joshua Feb 12 '15 at 16:24
• -1 If `a=b`, you shouldn't be returning `0`. Dividing by `0` in IEEE 754 gets you infinity, not an exception. You're avoiding the problem, so returning `0` is a bug waiting to happen. Consider `1/x + 1`. If `x=0`, that'd result in `1`, not the correct value: infinity. – Cole Johnson Feb 12 '15 at 19:05
• @ColeJohnson the correct answer is not infinity either (unless you specify which side the limit comes from, right side = +inf, left side = -inf, unspecified = undefined or NaN). – Nick T Feb 12 '15 at 20:10
• @ChrisHayes: This is a valid answer to the question recognizing that the question may be an XY problem: meta.stackexchange.com/questions/66377/what-is-the-xy-problem – slebetman Feb 13 '15 at 2:17
• @ColeJohnson Returning `0` is not really the issue. This is what the OP does in the question. You could put an exception or whatever is appropriate for the situation in that part of the block. If you don't like returning `0`, that should a criticism of the question. Certainly, doing as the OP did doesn't warrant a downvote to the answer. This question has nothing to do with further computations after the given function completes. For all you know, the program's requirements necessitate returning `0`. – jpmc26 Feb 13 '15 at 17:30

You wouldn't get a division by zero regardless of the value of `a - b`, since floating point division by 0 doesn't throw an exception. It returns infinity.

Now, the only way `a == b` would return true is if `a` and `b` contain the exact same bits. If they differ by just the least significant bit, the difference between them will not be 0.

EDIT :

As Bathsheba correctly commented, there are some exceptions:

1. "Not a number compares" false with itself but will have identical bit patterns.

2. -0.0 is defined to compare true with +0.0, and their bit patterns are different.

So if both `a` and `b` are `Double.NaN`, you will reach the else clause, but since `NaN - NaN` also returns `NaN`, you will not be dividing by zero.

• Eran; not strictly true. "Not a number compares" false with itself but will have identical bit patterns. Also -0.0 is defined to compare true with +0.0, and their bit patterns are different. – Bathsheba Feb 12 '15 at 10:00
• @Bathsheba I didn't consider these special cases. Thanks for the comment. – Eran Feb 12 '15 at 10:01
• @Eran, very good point that division by 0 will return infinity in a floating point. Added it to the question. – Thirler Feb 12 '15 at 10:06
• @Prashant but the division wouldn't take place in this case, since a == b would return true. – Eran Feb 12 '15 at 12:58
• Actually you could get a FP exception for division by zero, it's an option defined by the IEEE-754 standard, although it's probably not what most people would mean with "exception" ;) – Voo Feb 12 '15 at 20:32

There is no case where a division by zero can happen here.

The SMT Solver Z3 supports precise IEEE floating point arithmetic. Let's ask Z3 to find numbers `a` and `b` such that `a != b && (a - b) == 0`:

``````(set-info :status unknown)
(set-logic QF_FP)
(declare-fun b () (FloatingPoint 8 24))
(declare-fun a () (FloatingPoint 8 24))
(declare-fun rm () RoundingMode)
(assert
(and (not (fp.eq a b)) (fp.eq (fp.sub rm a b) +zero) true))
(check-sat)
``````

The result is `UNSAT`. There are no such numbers.

The above SMTLIB string also allows Z3 to pick an arbitrary rounding mode (`rm`). This means that the result holds for all possible rounding modes (of which there are five). The result also includes the possibility that any of the variables in play might be `NaN` or infinity.

`a == b` is implemented as `fp.eq` quality so that `+0f` and `-0f` compare equal. The comparison with zero is implemented using `fp.eq` as well. Since the question is aimed at avoiding a division by zero this is the appropriate comparison.

If the equality test was implemented using bitwise equality, `+0f` and `-0f` would have been a way to make `a - b` zero. An incorrect previous version of this answer contains mode details about that case for the curious.

Z3 Online does not yet support the FPA theory. This result was obtained using the latest unstable branch. It can be reproduced using the .NET bindings as follows:

``````var fpSort = context.MkFPSort32();
var aExpr = (FPExpr)context.MkConst("a", fpSort);
var bExpr = (FPExpr)context.MkConst("b", fpSort);
var rmExpr = (FPRMExpr)context.MkConst("rm", context.MkFPRoundingModeSort());
var fpZero = context.MkFP(0f, fpSort);
var subExpr = context.MkFPSub(rmExpr, aExpr, bExpr);
var constraintExpr = context.MkAnd(
context.MkNot(context.MkFPEq(aExpr, bExpr)),
context.MkFPEq(subExpr, fpZero),
context.MkTrue()
);

var smtlibString = context.BenchmarkToSMTString(null, "QF_FP", null, null, new BoolExpr[0], constraintExpr);

var solver = context.MkSimpleSolver();
solver.Assert(constraintExpr);

var status = solver.Check();
Console.WriteLine(status);
``````

Using Z3 to answer IEEE float questions is nice because it is hard to overlook cases (such as `NaN`, `-0f`, `+-inf`) and you can ask arbitrary questions. No need to interpret and cite specifications. You can even ask mixed float and integer questions such as "is this particular `int log2(float)` algorithm correct?".

• Can you please add a link to SMT Solver Z3 and a link to an online interpreter? While this answer seems totally legit, someone can think that these results are wrong. – A.L Feb 15 '15 at 0:36
• @A.L good idea. – usr Feb 15 '15 at 10:36

The supplied function can indeed return infinity:

``````public class Test {
public static double calculation(double a, double b)
{
if (a == b)
{
return 0;
}
else
{
return 2 / (a - b);
}
}

/**
* @param args
*/
public static void main(String[] args) {
double d1 = Double.MIN_VALUE;
double d2 = 2.0 * Double.MIN_VALUE;
System.out.println("Result: " + calculation(d1, d2));
}
}
``````

The output is `Result: -Infinity`.

When the result of the division is to big to be stored in a double, infinity is returned even if the denominator is non-zero.

In a floating-point implementation that conforms to IEEE-754, each floating-point type can hold numbers in two formats. One ("normalized") is used for most floating-point values, but the second-smallest number it can represent is only a tiny bit larger than the smallest, and so the difference between them is not representable in that same format. The other ("denormalized") format is used only for very small numbers that are not representable in the first format.

Circuitry to handle the denormalized floating-point format efficiently is expensive, and not all processors include it. Some processors offer a choice between either having operations on really small numbers be much slower than operations on other values, or having the processor simply regard numbers which are too small for normalized format as zero.

The Java specifications imply that implementations should support denormalized format, even on machines where doing so would make code run more slowly. On the other hand, it's possible that some implementations might offer options to allow code to run faster in exchange for slightly sloppy handling of values which would for most purposes be way too small to matter (in cases where values are too small to matter, it can be annoying having calculations with them take ten times as long as calculations that do matter, so in many practical situations flush-to-zero is more useful than slow-but-accurate arithmetic).

In olden times before IEEE 754, it was quite possible that a != b didn't imply a-b != 0 and vice versa. That was one of the reasons to create IEEE 754 in the first place.

With IEEE 754 it is almost guaranteed. C or C++ compilers are allowed to do an operation with higher precision than needed. So if a and b are not variables but expressions, then (a + b) != c doesn't imply (a + b) - c != 0, because a + b could be calculated once with higher precision, and once without higher precision.

Many FPUs can be switched to a mode where they don't return denormalized numbers but replace them with 0. In that mode, if a and b are tiny normalised numbers where the difference is smaller than the smallest normalised number but greater than 0, a != b also doesn't guarantee a == b.

"Never compare floating-point numbers" is cargo cult programming. Among the people who have the mantra "you need an epsilon", most have no idea how to choose that epsilon properly.

I can think of a case where you might be able to cause this to happen. Here's an analogous sample in base 10 - really, this would happen in base 2, of course.

Floating point numbers are stored more or less in scientific notation - that is, instead of seeing 35.2, the number being stored would be more like 3.52e2.

Imagine for the sake of convenience that we have a floating point unit that operates in base 10 and has 3 digits of accuracy. What happens when you subtract 9.99 from 10.0?

1.00e2-9.99e1

Shift to give each value the same exponent

1.00e2-0.999e2

Round to 3 digits

1.00e2-1.00e2

Uh oh!

Whether this can happen ultimately depends on the FPU design. Since the range of exponents for a double is very large, the hardware has to round internally at some point, but in the case above, just 1 extra digit internally will prevent any problem.

• The registers holding the aligned operands for subtraction are required to hold extra two bits, called "guard bits", to deal with this situation. In the scenario where the subtraction would cause a borrow from the most significant bit, either the smaller operand's magnitude must exceed half that of the larger operand (implying that it can only have one extra bit of precision) or else the result must be at least half the magnitude of the smaller operand (implying that it will only need only one more bit, plus information sufficient to ensure correct rounding). – supercat Feb 12 '15 at 16:54
• “Whether this can happen ultimately depends on the FPU design” No, it cannot happen because the Java definition says it can't. The FPU design does not have anything to do with it. – Pascal Cuoq Feb 13 '15 at 1:57
• @PascalCuoq: Correct me if I'm wrong, but `strictfp` is not enabled, it's possible for calculations to yield values which are too small for `double` but will fit in an extended-precision floating-point value. – supercat Feb 13 '15 at 16:04
• @supercat The absence of `strictfp` only influences the values of “intermediate results”, and I am quoting from docs.oracle.com/javase/specs/jls/se7/html/jls-15.html#jls-15.4 . `a` and `b` are `double` variables, not intermediate results, so their values are double-precision values, thus are multiples of 2^-1074. The subtraction of these two double-precision values is consequently a multiple of 2^-1074, so the wider exponent range does change the property that the difference is 0 iff a == b. – Pascal Cuoq Feb 13 '15 at 16:16
• @supercat This makes sense - you'd only need one extra bit to do this. – Keldor314 Feb 16 '15 at 10:45

You shouldn't ever compare floats or doubles for equality; because, you can't really guarantee that the number you assign to the float or double is exact.

To compare floats for equality sanely, you need to check if the value is "close enough" to the same value:

``````if ((first >= second - error) || (first <= second + error)
``````
• "Shouldn't ever" is a bit strong, but generally this is good advice. – Mark Pattison Feb 12 '15 at 10:01
• While you are true, `abs(first - second) < error` (or `<= error`) is easier and more concise. – glglgl Feb 12 '15 at 10:02
• While true in most cases (not all), doesn't really answer the question. – milleniumbug Feb 12 '15 at 10:56
• Testing floating-point numbers for equality is quite often useful. There is nothing sane about comparing with an epsilon that has not been carefully chosen, and even less sane about comparing with an epsilon when one is testing for equality. – tmyklebu Feb 13 '15 at 0:24
• If you sort an array on a floating-point key, I can guarantee that your code won't work if you try to use tricks comparing floating-point numbers with an epsilon. Because the guarantee that a == b and b == c implies a == c isn't there anymore. For hash tables, the exact same problem. When equality isn't transitive, your algorithms just break. – gnasher729 Feb 14 '15 at 19:04

Division by zero is undefined, since the limit from positive numbers tend to infinity, the limited from negative numbers tend to negative infinity.

Not sure if this is C++ or Java since there is no language tag.

``````double calculation(double a, double b)
{
if (a == b)
{
return nan(""); // C++

return Double.NaN; // Java
}
else
{
return 2 / (a - b);
}
}
``````

The core problem is that computer representation of a double (aka float, or real number in mathematical language) is wrong when you have "too much" decimal, for instance when you deal with double that can't be written as a numerical value (pi or the result of 1/3).

So a==b can't be done with any double value of a and b, how to you deal with a==b when a=0.333 and b=1/3 ? Depending of your OS vs FPU vs number vs language versus count of 3 after 0, you will have true or false.

Anyway if you do "double value calculation" on a computer, you have to deal with accuracy, so instead of doing `a==b`, you have to do `absolute_value(a-b)<epsilon`, and epsilon is relative to what you are modeling at that time in your algorithm. You can't have an epsilon value for all of your double comparison.

In brief, when you type a==b, you have a mathemical expression that can't be translated on a computer (for any floating point number).

PS: hum, everything I answer here is yet more or less in others responses and comments.

Based on @malarres response and @Taemyr comment, here is my little contribution:

``````public double calculation(double a, double b)
{
double c = 2 / (a - b);

// Should not have a big cost.
if (isnan(c) || isinf(c))
{
return 0; // A 'whatever' value.
}
else
{
return c;
}
}
``````

My point is to says: the easyest way to know if the result of the division is nan or inf is actualy to perform the division.

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