Ints and floats are pretty different beasts in Java. Ints are encoded as two's complement, which has a single 0 value. Floats use IEEE 754 (the 32-bit variant for floats, and 64-bit for doubles). IEEE 754 is somewhat complex, but for purpose of this answer, you just need to know that it has three sections, the first of which is a sign bit. That means for any float, there's a positive and negative variant¹. That includes 0, so floats actually have two "zero" values, +0 and -0.

As an aside, the two's complement that ints use is not the only way to encode integers in computer science. There are other methods, like ones' complement, but they have quirks — like having both a +0 and -0 as distinct values. ;-)

When you compare float primitives (and doubles), Java treats +0 and -0 as equal. But when you box them, Java treats them separately, as described in `Float#equals`

. This lets the equals method be consistent with their `hashCode`

implementation (as well as `compareTo`

), which just uses the bits of the float (including that signed value) and shoves them as-is into an int.

They could have picked some other option for equals/hashCode/compareTo, but they didn't. I'm not sure what the design considerations there were. But in at least one regard, `Float#equals`

was always going to diverge from the float primitive's `==`

: In primitives, `NaN != NaN`

, but for all objects, `o.equals(o)`

must also be true. That means that if you had `Float f = Float.NaN`

, then `f.equals(f)`

even though `f.floatValue() != f.floatValue()`

.

¹ NaN (not-a-number) values have a sign bit, but it doesn't have any meaning other than for ordering, and Java ignores it (even for ordering).

`i`

and`i2`

are exactly the same. Then when you create new`Integer`

s they both wrap the exact same value.`I1.equals(I)`

will be true.`int i = Integer.MIN_VALUE, i2 = -i;`

…`new`

for the wrapper types here. Just use, e.g.`Integer i = 0, i2 = -i; System.out.println(i.equals(i2)); Float f1 = 0f, f2 = -f1; System.out.println(f1.equals(f2));`