**The short answer**

Integral types (JLS 4.2.1) are categorically different from floating point types (JLS 4.2.3). There may be similarities in behavior and operations, but there are also characteristically distinguishing differences such that confusing the two can lead to many pitfalls.

The difference in behavior upon division by zero is just one of these differences. Thus, the short answer is that Java behaves this way because the language says so.

### On integral and floating point values

The values of the integral types are integers in the following ranges:

`byte`

: from `-128`

to `127`

, inclusive, i.e. `[-2`

^{7}`, 2`

^{7}`-1]`

`short`

: from `-32768`

to `32767`

, inclusive, i.e. `[-2`

^{15}`, 2`

^{15}`-1]`

`int`

: from `-2147483648`

to `2147483647`

, inclusive, i.e. `[-2`

^{31}`, 2`

^{31}`-1]`

`long`

: from `-9223372036854775808`

to `9223372036854775807`

, inclusive, i.e. `[-2`

^{63}`, 2`

^{63}`-1]`

`char`

, from `'\u0000'`

to `'\uffff'`

inclusive, that is, from `0`

to `65535`

, i.e. `[0, 2`

^{16}`-1]`

The floating-point types are `float`

and `double`

, which are conceptually associated with the single-precision 32-bit and double-precision 64-bit format IEEE 754 values and operations.

Their values are ordered as follows, from smallest to greatest:

- negative infinity,
- negative finite nonzero values,
- positive and negative zero (i.e.
`0.0 == -0.0`

),
- positive finite nonzero values, and
- positive infinity.

Additionally, there are special *Not-a-Number* (`NaN`

) values, which are *unordered*. This means that if either (or both!) operand is `NaN`

:

- numerical comparison operators
`<`

, `<=`

, `>`

, and `>=`

return `false`

- numerical equality operator
`==`

returns `false`

- numerical inequality operator
`!=`

returns `true`

In particular, `x != x`

is `true`

if and only if `x`

is `NaN`

.

For e.g. `double`

, the infinities and `NaN`

can be referred to as:

The situation is analogous with `float`

and `Float`

.

### On when exceptions may be thrown

Numerical operations may only throw an `Exception`

in these cases:

`NullPointerException`

, if unboxing conversion of a `null`

reference is required
`ArithmeticException`

, if the right hand side is zero for *integer* divide/remainder operations
`OutOfMemoryError`

, if boxing conversion is required and there is not sufficient memory

They are ordered by importance, with regards to being common source for pitfalls. Generally speaking:

- Be especially careful with box types, as just like all other reference types, they may be
`null`

- Be especially careful with the right hand side of an integer division/remainder operations
- Arithmetic overflow/underflow
*DOES NOT* cause an exception to be thrown
- Loss of precision
*DOES NOT* cause an exception to be thrown
- A mathematically indefinite floating point operation
*DOES NOT* cause an exception to be thrown

### On division by zero

For *integer* operation:

- Division and remainder operations throws
`ArithmeticException`

if the right hand side is zero

For *floating point* operation:

- If the left operand is
`NaN`

or `0`

, the result is `NaN`

.
- If the operation is
*division*, it overflows and the result is a signed infinity
- If the operation is
*remainder*, the result is `NaN`

The general rule for all floating point operation is as follows:

- An operation that overflows produces a signed infinity.
- An operation that underflows produces a denormalized value or a signed zero.
- An operation that has no mathematically definite result produces
`NaN`

.
- All numeric operations with
`NaN`

as an operand produce `NaN`

as a result.

### Appendix

There are still many issues not covered by this already long answer, but readers are encouraged to browse related questions and referenced materials.

### Related questions