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I expected the following code to produce: "Both are equal", but I got "Both are NOT equal":

float a=1.3f;
double b=1.3;
 System.out.println("Both are equal");
 System.out.println("Both are NOT equal");

What is the reason for this?

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It's because the closest float value to 1.3 isn't the same as the closest double value to 1.3. Neither value will be exactly 1.3 - that can't be represented exactly in a non-recurring binary representation.

To give a different understanding of why this happens, suppose we had two decimal floating point types - decimal5 and decimal10, where the number represents the number of significant digits. Now suppose we tried to assign the value of "a third" to both of them. You'd end up with

decimal5 oneThird = 0.33333
decimal10 oneThird = 0.3333333333

Clearly those values aren't equal. It's exactly the same thing here, just with different bases involved.

However if you restrict the values to the less-precise type, you'll find they are equal in this particular case:

double d = 1.3d;
float f = 1.3f;
System.out.println((float) d == f); // Prints true

That's not guaranteed to be the case, however. Sometimes the approximation from the decimal literal to the double representation, and then the approximation of that value to the float representation, ends up being less accurate than the straight decimal to float approximation. One example of this 1.0000001788139343 (thanks to stephentyrone for finding this example).

Somewaht more safely, you can do the comparison between doubles, but use a float literal in the original assignment:

double d = 1.3f;
float f = 1.3f;
System.out.println(d == f); // Prints true

In the latter case, it's a bit like saying:

decimal10 oneThird = 0.3333300000

However, as pointed out in the comments, you almost certainly shouldn't be comparing floating point values with ==. It's almost never the right thing to do, because of precisely this sort of thing. Usually if you want to compare two values you do it with some sort of "fuzzy" equality comparison, checking whether the two numbers are "close enough" for your purposes. See the Java Traps: double page for more information.

If you really need to check for absolute equality, that usually indicates that you should be using a different numeric format in the first place - for instance, for financial data you should probably be using BigDecimal.

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Very nice explanation, though it is possible for a carefully crafted decimal value to fail the comparison ((float)decimalValueAsDouble == decimalValueAsFloat), due to a double rounding. – Stephen Canon Oct 2 '09 at 0:56
@stephentyrone: Yes, I suspected it might be - although I haven't come up with any examples yet. – Jon Skeet Oct 2 '09 at 5:23
The only thing worrying me with this post is that it somehow gives the OP the impression that he can cast and use == if he doesn't understand the comments. Someone else posted this link: which explains it quite well. – Fredrik Oct 2 '09 at 5:51
@Jon Skeet: 1.0000001788139343 is such a number. In hex, its value is 0x1.000002ffffffff...; the two closest single precision numbers are 0x1.000002 and 0x1.000004. Rounding directly to single gives the slightly closer 0x1.000002, whereas rounding to double gives 0x1.000003, which is exactly half-way; when this value is rounded to single, the "ties to even" rule is used, and the result is 0x1.000004. – Stephen Canon Oct 2 '09 at 16:36
@Fredrik, @stephentyrone: Thanks, will apply put both of these in the answer. – Jon Skeet Oct 2 '09 at 16:48

A float is a single precision floating point number. A double is a double precision floating point number. More details here:

Note: It is a bad idea to check exact equality for floating point numbers. Most of the time, you want to do a comparison based on a delta or tolerance value.

For example:

float a = 1.3f;
double b = 1.3;
float delta = 0.000001f;
if (Math.abs(a - b) < delta)
    System.out.println("Close enough!");
    System.out.println("Not very close!");

Some numbers can't be represented exactly in floating point (e.g. 0.01) so you might get unexpected results when you compare for equality.

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Never check for equality between floating point numbers. Specifically, to answer your question, the number 1.3 is hard to represent in binar floating point and the souls and float representations are different.

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You would have gotten a +1 from me if your post wasn't filled with typos. – Mike Cooper Oct 1 '09 at 7:01

Read this article.

The above article clearly illustrates with examples your scenario while using double and float types.

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float a=1.3f;
double b=1.3;

At this point you have two variables containing binary approximations to the Real number 1.3. The first approximation is accurate to about 7 decimal digits, and the second one is accurate to about 15 decimal digits.

if(a==b) {

The expression a==b is evaluate in two stages. First the value of a is converted from a float to a double by padding the binary representation. The result is still only accurate to about 7 decimal digits as a representation of the Real 1.3. Next you compare the two different approximations. Since they are different, the result of a==b is false.

There are two lessons to learn:

  1. Floating point (and double) literals are almost always approximations; e.g. actual number that corresponds to the literal 1.3f is not exactly equal to the Real number 1.3.

  2. Every time you do a floating point computation, errors creep in. These errors tend to build up. So when you are comparing floating points / double numbers it is usually a mistake to use a simple "==", "<", etcetera. Instead you should use |a - b| < delta where delta is chosen appropriately. (And figuring out what is an appropriate delta is not always straight-forward either.)

  3. You should have taken that course in Numerical Analysis :-)

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The problem, fundamentally, is that while there are many double values which a particular float value could represent, the system performs a double-to-float comparison by selecting one a particular double value. If I had my druthers, implicit double-to-float conversions would generally be allowed and implicit float-to-double generally prohibited, but floating-point operands could only be compared with precisely-matching types (some cases may require both operands to float, but others, double; neither is sufficiently dominant to be a "safe" default). – supercat Jun 7 '13 at 16:06

The problem is that Java (and alas .NET as well) is inconsistent about whether a float value represents a single precise numeric quantity or a range of quantities. If a float is considered to represents an exact numeric quantity of the form Mant * 2^Exp, where Mant is an integer 0 to 2^25 and Exp is an integer), then an attempt to cast any number not of that form to float should throw an exception. If it's considered to represent "the locus of numbers for which some particular representation in the above form has been deemed likely to be the best", then a double-to-float cast would be correct even for double values not of the above form [casting the double that best represents a quantity to a float will almost always yield the float that best represents that quantity, though in some corner cases (e.g. numeric quantities in the range 8888888.500000000001 to 8888888.500000000932) the float which is chosen may be a few parts per trillion worse than the best possible float representation of the actual numeric quantity].

To use an analogy, suppose two people each have a ten-centimeter-long object and they measure it. Bob uses an expensive set of calibers and determines that his object is 3.937008" long. Joe uses a tape measure and determines that his object is 3 15/16" long. Are the objects the same size? If one converts Joe's measurement to millionths of an inch (3.937500") the measurements will appear different, but one instead converts Bob's measurement to the nearest 1/256" fraction, they will appear equal. Although the former comparison might seem more "precise", the latter is apt to be more meaningful. Joe's measurement if 3 15/16" doesn't really mean 3.937500"--it means "a distance which, using a tape measure, is indistinguishable from 3 15/16". And 3.937008" is, like the size of Joe's object, a distance which using a tape measure would be indistinguishable from 3 15/16.

Unfortunately, even though it would be more meaningful to compare the measurements using the lower precision, Java's floating-point-comparison rules assume that a float represents a single precise numeric quantity, and performs comparisons on that basis. While there are some cases where this is useful (e.g. knowing whether the particular double produced by casting some value to float and back to double would match the starting value), in general direct equality comparisons between float and double are not meaningful. Even though Java does not require it, one should always cast the operands of a floating-point equality comparison to be the same type. The semantics that result from casting the double to float before the comparison are different from those of casting the float to double, and the behavior Java picks by default (cast the float to double) is often semantically wrong.

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