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According to this java.sun page == is the equality comparison operator for floating point numbers in Java.

However, when I type this code:

           if(sectionID == currentSectionID)

into my editor and run static analysis, I get: "JAVA0078 Floating point values compared with =="

What is wrong with using == to compare floating point values? What is the correct way to do it?

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Because comparing floats with == is problematic, it's unwise to use them as IDs; the names in your example code suggest that's what you are doing; long integers (longs) are preferred, and the de facto standard for IDs. – Carl Manaster Jul 6 '09 at 17:35
Yeah, was that just a random example or do you actually use floats as IDs? Is there a reason? – Per Wiklander Feb 13 '10 at 20:12
"for float fields, use the Float.compare method; and for double fields, use Double.compare. The special treatment of float and double fields is made necessary by the existence of Float.NaN, -0.0f and the analogous double constants; see the Float.equals documentation for details." (Joshua Bloch: Effective Java) – lbalazscs Nov 3 '14 at 0:58

19 Answers 19

the correct way to test floats for 'equality' is:

if(Math.abs(sectionID - currentSectionID) < epsilon)

where epsilon is a very small number like 0.00000001, depending on the desired precision.

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See the link in the accepted answer (cygnus-software.com/papers/comparingfloats/comparingfloats.htm) for why a fixed epsilon isn't always a good idea. Specifically, as the values in the floats being compared get large (or small), the epsilon is no longer appropriate. (Using epsilon is fine if you know your float values are all relatively reasonable, though.) – P.T. Dec 13 '11 at 2:05
@P.T Can he multiply epsilon with one numbers and change function to if(Math.abs(sectionID - currentSectionID) < epsilon*sectionID to tackle that issue? – enthusiasticgeek Nov 6 '14 at 23:11
This may even be the best answer so far, but it is still flawed. Where do you get the epsilon from? – Michael Piefel Apr 27 '15 at 15:34

Floating point values can be off by a little bit, so they may not report as exactly equal. For example, setting a float to "6.1" and then printing it out again, you may get a reported value of something like "6.099999904632568359375". This is fundamental to the way floats work; therefore, you don't want to compare them using equality, but rather comparison within a range, that is, if the diff of the float to the number you want to compare it to is less than a certain absolute value.

This article on the Register gives a good overview of why this is the case; useful and interesting reading.

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@Chris Dodd - right, which is what I said. – KevinDTimm Jul 6 '09 at 20:33
@kevindtimm : so you will do your equality tests like so then if (number == 6.099999904632568359375) any time you wish to know of number is equals to 6.1... Yes you are correct... everything in the computer is strictly deterministic, just that the approximations used for floats are counter-intuitive when doing math problems. – Newtopian Jul 22 '09 at 1:29
Floating point values are only nondeterministically imprecise on very specific hardware. – Stuart P. Bentley Jun 3 '11 at 18:57
@Stuart I could be mistaken, but I don't think the FDIV bug was non-deterministic. The answers given by the hardware did not conform to specification, but they were deterministic, in that the same calculation always produced the same incorrect result – Gravity Jul 27 '11 at 4:43
@Gravity You can argue that any behavior is deterministic given a specific set of caveats. – Stuart P. Bentley Aug 21 '11 at 4:41

Just to give the reason behind what everyone else is saying.

The binary representation of a float is kind of annoying.

In binary, most programmers know the correlation between 1b=1d, 10b=2d, 100b=4d, 1000b=8d

Well it works the other way too.

.1b=.5d, .01b=.25d, .001b=.125, ...

The problem is that there is no exact way to represent most decimal numbers like .1, .2, .3, etc. All you can do is approximate in binary. The system does a little fudge-rounding when the numbers print so that it displays .1 instead of .10000000000001 or .999999999999 (which are probably just as close to the stored representation as .1 is)

Edit from comment: The reason this is a problem is our expectations. We fully expect 2/3 to be fudged at some point when we convert it to decimal, either .7 or .67 or .666667.. But we don't automatically expect .1 to be rounded in the same way as 2/3--and that's exactly what's happening.

By the way, if you are curious the number it stores internally is a pure binary representation using a binary "Scientific Notation". So if you told it to store the decimal number 10.75d, it would store 1010b for the 10, and .11b for the decimal. So it would store .101011 then it saves a few bits at the end to say: Move the decimal point four places right.

(Although technically it's no longer a decimal point, it's now a binary point, but that terminology wouldn't have made things more understandable for most people who would find this answer of any use.)

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You're describing fixed-point math. – mkb Jul 6 '09 at 18:14
@Matt K - um, not fixed point; if you "save a few bits at the end to say move the decimal point [N] bits to the right", that is floating point. Fixed point takes the position of the radix point to be, well, fixed. Also, in general, since shifting the binamal (?) point can always be made to leave you with a '1' in the leftmost position, you will find some systems that omit the leading '1', devoting the space thus liberated (1 bit!) to extending the range of the exponent. – JustJeff Jul 6 '09 at 18:52
The problem has nothing to do with binary vs. decimal representation. With decimal floating-point, you still have things like (1 / 3) * 3 == 0.9999999999999999999999999999. – dan04 Oct 28 '10 at 12:44
@dan04 yes, because 1/3 has no decimal OR binary representation, it does have a trinary representation and would convert correctly that way :). The numbers I listed (.1, .25, etc) all have perfect decimal representations but no binary representation--and people are used to those having "exact" representations. BCD would handle them perfectly. That's the difference. – Bill K Oct 28 '10 at 17:19
This should have way more upvotes, since it describes the REAL problem behind the issue. – Levit Mar 25 '15 at 7:51

What is wrong with using == to compare floating point values?

Because it's not true that 0.1 + 0.2 == 0.3

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You can easily see this using this convertor applet: h-schmidt.net/FloatApplet/IEEE754.html – Joeri Sebrechts Jul 6 '09 at 18:29
what about Float.compare(0.1f+0.2f, 0.3f) == 0 ? – Aquarius Power Jan 26 at 4:31

Foating point values are not reliable, due to roundoff error.

As such they should probably not be used for as key values, such as sectionID. Use integers instead, or long if int doesn't contain enough possible values.

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Agreed. Given that these are IDs, there is no reason to complicate things with floating point arithmetic. – Yohnny Jul 6 '09 at 17:34
Or a long. Depending on how many unique IDs get generated in the future, an int may not be large enough. – Wayne Hartman Jul 6 '09 at 18:23

This is a problem not specific to java. Using == to compare two floats/doubles/any decimal type number can potentially cause problems because of the way they are stored. A single-precision float (as per IEEE standard 754) has 32 bits, distributed as follows:

1 bit - Sign (0 = positive, 1 = negative)
8 bits - Exponent (a special (bias-127) representation of the x in 2^x)
23 bits - Mantisa. The actuall number that is stored.

The mantisa is what causes the problem. It's kinda like scientific notation, only the number in base 2 (binary) looks like 1.110011 x 2^5 or something similar. But in binary, the first 1 is always a 1 (except for the representation of 0)

Therefore, to save a bit of memory space (pun intended), IEEE deccided that the 1 should be assumed. For example, a mantisa of 1011 really is 1.1011.

This can cause some issues with comparison, esspecially with 0 since 0 cannot possibly be represented exactly in a float. This is the main reason the == is discouraged, in addition to the floating point math issues described by other answers.

Java has a unique problem in that the language is universal across many different platforms, each of which could have it's own unique float format. That makes it even more important to avoid ==.

The proper way to compare two floats (not-language specific mind you) for equality is as follows:

if(ABS(float1 - float2) < ACCEPTABLE_ERROR)
    //they are approximately equal

where ACCEPTABLE_ERROR is #defined or some other constant equal to 0.000000001 or whatever precision is required, as Victor mentioned already.

Some languages have this functionality or this constant built in, but generally this is a good habit to be in.

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Java has a defined behavior for floats. It is not platform dependent. – Yishai Jan 22 '10 at 0:21

I think there is a lot of confusion around floats (and doubles), it is good to clear it up.

  1. There is nothing inherently wrong in using floats as IDs in standard-compliant JVM [*]. If you simply set the float ID to x, do nothing with it (i.e. no arithmetics) and later test for y == x, you'll be fine. Also there is nothing wrong in using them as keys in a HashMap. What you cannot do is assume equalities like x == (x - y) + y, etc. This being said, people usually use integer types as IDs, and you can observe that most people here are put off by this code, so for practical reasons, it is better to adhere to conventions. Note that there are as many different double values as there are long values, so you gain nothing by using double. Also, generating "next available ID" can be tricky with doubles and requires some knowledge of the floating-point arithmetic. Not worth the trouble.

  2. On the other hand, relying on numerical equality of the results of two mathematically equivalent computations is risky. This is because of the rounding errors and loss of precision when converting from decimal to binary representation. This has been discussed to death on SO.

[*] When I said "standard-compliant JVM" I wanted to exclude certain brain-damaged JVM implementations. See this.

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When using floats as IDs, one must be careful to either ensure that they are compared using == rather than equals, or else ensure that no float which compares unequal to itself gets stored in a table. Otherwise, a program which tries to e.g. count how many unique results can be produced from an expression when fed various inputs may regard every NaN value as unique. – supercat Jul 27 '14 at 17:54

In addition to previous answers, you should be aware that there are strange behaviours associated with -0.0f and +0.0f (they are == but not equals) and Float.NaN (it is equals but not ==) (hope I've got that right - argh, don't do it!).

Edit: Let's check!

import static java.lang.Float.NaN;
public class Fl {
    public static void main(String[] args) {
        System.err.println(          -0.0f   ==              0.0f);   // true
        System.err.println(new Float(-0.0f).equals(new Float(0.0f))); // false
        System.err.println(            NaN   ==               NaN);   // false
        System.err.println(new Float(  NaN).equals(new Float( NaN))); // true

Welcome to IEEE/754.

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If something is ==, then they are identical down to the bit. How could they not be equals()? Maybe you have it backwards? – mkb Jul 6 '09 at 18:15
Added test code. == is screwy for float and doubles. – Tom Hawtin - tackline Jul 6 '09 at 18:50
@Matt NaN is special. Double.isNaN(double x) in Java is actually implemented as { return x != x; }... – quant_dev Jul 6 '09 at 19:10
With floats, == doesn't mean that numbers are "identical to the bit" (the same number can be represented with different bit patterns, though only one of them is normalized form). As well, -0.0f and 0.0f are represented by different bit patterns (the sign bit is different), but compare as equal with == (but not with equals). Your assumption that == is bitwise comparison is, generally speaking, wrong. – Pavel Minaev Jul 22 '09 at 1:27

Here is a very long (but hopefully useful) discussion about this and many other floating point issues you may encounter: What Every Computer Scientist Should Know About Floating-Point Arithmetic

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First of all, are they float or Float? If one of them is a Float, you should use the equals() method. Also, probably best to use the static Float.compare method.

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you may want it to be ==, but 123.4444444444443 != 123.4444444444442

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If you *have to* use floats, strictfp keyword may be useful.


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Or may be even more useful for different architectures. – joey rohan Apr 3 '15 at 7:57

You can use Float.floatToIntBits().

Float.floatToIntBits(sectionID) == Float.floatToIntBits(currentSectionID)
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You are on the right track. floatToIntBits() is the right way to go, but it would be easier to just use Float's built in equals() function. See here: stackoverflow.com/a/3668105/2066079 . You can see that the default equals() utilizes floatToIntBits internally. – dberm22 Apr 4 '14 at 13:03
Yes if they are Float objects. You can use above equation for primitives. – aamadmi Apr 4 '14 at 18:08

The following automatically uses the best precision:

 * Compare to floats for (almost) equality. Will check whether they are
 * at most 5 ULP apart.
public static boolean isFloatingEqual(float v1, float v2) {
    if (v1 == v2)
        return true;
    float absoluteDifference = Math.abs(v1 - v2);
    float maxUlp = Math.max(Math.ulp(v1), Math.ulp(v2));
    return absoluteDifference < 5 * maxUlp;

Of course, you might choose more or less than 5 ULPs (‘unit in the last place’).

If you’re into the Apache Commons library, the Precision class has compareTo() and equals() with both epsilon and ULP.

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The correct way would be

java.lang.Float.compare(float1, float2)
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Float.compare(float1, float2) returns an int, so it cannot be used instead of float1 == float2 in the if condition. Moreover, it doesn't really solve the underlying problem which this warning is referring to -- that if floats are results of numerical calculation, float1 != float2 may occur just due to rounding errors. – quant_dev Jul 6 '09 at 19:07
right, you cannot copy paste, you have to check the doc first. – Eric Jul 6 '09 at 19:17
What you can do instead of float1 == float2 is Float.compare(float1,float2) == 0. – deterb Jul 19 '09 at 18:23
This doesn't buy you anything - you still get Float.compare(1.1 + 2.2, 3.3) != 0 – Pavel Minaev Jul 22 '09 at 1:25
-1 for the incorrect answer. – DejanLekic Oct 9 '13 at 16:20

Two different calculations which produce equal real numbers do not necessarily produce equal floating point numbers. People who use == to compare the results of calculations usually end up being surprised by this, so the warning helps flag what might otherwise be a subtle and difficult to reproduce bug.

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Are you dealing with outsourced code that would use floats for things named sectionID and currentSectionID? Just curious.

@Bill K: "The binary representation of a float is kind of annoying." How so? How would you do it better? There are certain numbers that cannot be represented in any base properly, because they never end. Pi is a good example. You can only approximate it. If you have a better solution, contact Intel.

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As mentioned in other answers, doubles can have small deviations. And you could write your own method to compare them using an "acceptable" deviation. However ...

There is an apache class for comparing doubles: org.apache.commons.math3.util.Precision

It contains some interesting constants: SAFE_MIN and EPSILON, which are the maximum possible deviations of simple arithmetic operations.

It also provides the necessary methods to compare, equal or round doubles. (using ulps or absolute deviation)

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One way to reduce rounding error is to use double rather than float. This won't make the problem go away, but it does reduce the amount of error in your program and float is almost never the best choice. IMHO.

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