These are examples of the Narrowing Primitive Conversion operation.

In your first example, `long`

to `int`

:

A narrowing conversion of a signed integer to an integral type T simply discards all but the n lowest order bits, where n is the number of bits used to represent type T. In addition to a possible loss of information about the magnitude of the numeric value, this may cause the sign of the resulting value to differ from the sign of the input value.

So your `(int) 2147483648l`

is taking the 64 bits of the `long`

:

00000000 00000000 00000000 00000000 10000000 00000000 00000000 00000000

...and dropping the top 32 bits entirely:

10000000 00000000 00000000 00000000

...and taking the remaining 32 bits as an `int`

. Since the leftmost of those is now a sign bit (`long`

and `int`

are stored as two's complement), and since it happens to be set in your `2147483648l`

value, you end up with a negative number. Since no other bits are set, in two's complement, that means you have the lowest negative number `int`

can represent: -2147483648.

The `float`

to `int`

example follows a more complex rule. The relevant parts for your value are:

...if the floating-point number is not an infinity, the floating-point value is rounded to an integer value V, rounding toward zero using IEEE 754 round-toward-zero mode (§4.2.3).

...[if] the value [is] too large (a positive value of large magnitude or positive infinity), [then] the result of the first step is the largest representable value of type int or long.

*(But see the part of the spec linked above for the details.)*

So since `2147483648f`

rounds to `2147483648`

, and `2147483648`

is too large to fit in `int`

, the largest value for `int`

(`2147483647`

) is used instead.

So in the `long`

to `int`

, it's bit fiddling; in the `float`

to `int`

, it's more mathematical.

In a comment you've asked:

Do you know why both `(short) 32768`

and `(short) 32768f`

evaluate to `-32768`

? I was exepecting the latter to evaluate to `32767`

.

Excellent question, and that's where my *"see the part of the spec linked above for the details"* above comes in. :-) `(short) 32768f`

does, in effect, `(short)(int)32768f`

:

In the spec section linked above, under "A narrowing conversion of a floating-point number to an integral type T takes two steps:", it says

- In the first step, the floating-point number is converted either to a
`long`

, if T is `long`

, or to an `int`

, if T is `byte`

, `short`

, `char`

, or `int`

...

and then later in Step 2's second bullet:

- * If T is
`byte`

, `char`

, or `short`

, the result of the conversion is the result of a narrowing conversion to type T (§5.1.3) of the result of the first step.

So in step one, `32768f`

becomes `32768`

(an `int`

value), and then of course `(short)32768`

does the bit-chopping we saw in `long`

=> `int`

above, giving us a `short`

value of `-32768`

.