I am going to use 8-bit integers for simplicity.

In binary, 8 bit ranges from `00000000b`

to `11111111b`

.

```
00000000b = 0d
11111111b = 255d
```

So how do computer add signs to an integer? It's two's complement.

For unsigned integer, we convert `11111111b`

from binary to denary by this way:

```
11111111b
= 1*2^7 + 1*2^6 + 1*2^5 + 1*2^4 + 1*2^3 + 1*2^2 + 1*2^1 + 1*2^0
= 1*128 + 1*64 + 1*32 + 1*16 + 1*8 + 1*4 + 1*2 + 1*1
= 255d
```

So how about signed integer `11111111b`

? Here is a simple way:

```
v----------(sign flag 1=negative)
11111111b
= 1*(-2^7) + 1*2^6 + 1*2^5 + 1*2^4 + 1*2^3 + 1*2^2 + 1*2^1 + 1*2^0
= 1*(-128) + 1*64 + 1*32 + 1*16 + 1*8 + 1*4 + 1*2 + 1*1
= -1d
```

In general, the most significant bit of a signed number is the sign flag.

To convert negative denary number to two's complement:

```
-18d
========
without sign 0001 0010
one's complement 1110 1101 (inverted)
*two's complement 1110 1110 (one's complement + 1)
```

The range of a 8-bit signed integer is from `-2^7`

to `2^7-1`

.

Now what is overflow? Let's see:

```
01111111b
= 127d
01111111b + 1
= 10000000b
= 1*(-2^7) + 0*2^6 + 0*2^5 + 0*2^4 + 0*2^3 + 0*2^2 + 0*2^1 + 0*2^0
= 1*(-128) + 0*64 + 0*32 + 0*16 + 0*8 + 0*4 + 0*2 + 0*1
= -128d
127d + 1d
=========
0111 1111 (127d) +
+0000 0001 (1d) +
----------
1000 0000 (-128d) - (overflow)
```

So if we add 1 to the largest 8-bit signed integer, the result is the smallest 8-bit signed integer. +ve + +ve -> -ve is an overflow error.

How about subtractions? 45-16? (+ve + -ve -> +ve)

```
45d - 16d
=========
0010 1101 (45d) +
+1111 0000 (-16d) -
----------
1 0001 1101 (29d) +
^---------------------(discard)
```

How about 45-64? (+ve + -ve -> -ve)

```
45d - 64d
=========
0010 1101 (45d) +
+1100 0000 (-64d) -
----------
1110 1101 (-19d) -
```

How about -64-64? (-ve + -ve -> -ve)

```
-64d - 65d
=========
1100 0000 (-64d) -
+1100 0000 (-64d) -
----------
1 1000 0000 (-128d) +
^---------------------(discard)
```

How about -64-65?

```
-64d - 65d
=========
1100 0000 (-64d) -
+1011 1111 (-65d) -
----------
1 0111 1111 (127d) + (underflow)
^---------------------(discard)
```

So -ve + -ve -> +ve is an underflow error.

The situation is similar for 32-bit integers, just more bits available.

For your question `2*1500000000`

, if we treat them as 32-bit unsigned integer, the result is `3000000000`

and its binary representation is:

```
1011 0010 1101 0000 0101 1110 0000 0000
= 1*2^31 + 0*2^30 + ...
= 1*2147483648 + 0*1073741824 + ...
= 3000000000d
```

But if we treat it as a 32-bit signed integer:

```
v------(Let's recall this is the sign flag)
1011 0010 1101 0000 0101 1110 0000 0000
= 1*(-2^31) + 0*2^30 + ...
= 1*(-2147483648) + 0*1073741824 + ...
= -1294967296d
```

**ADDED:** Overflow of unsigned integer

The overflow of unsigned integer is quite similar:

```
11111111b
= 255d
11111111b + 1
= 00000000b
= 0d
255d + 1d
=========
1111 1111 (255d) +
+0000 0001 (1d) +
----------
1 0000 0000 (0d) - (overflow)
^---------------------(discard)
```

That's why for 32-bit unsigned integers it is always `mod 2^32`

.

And BTW, this is not only for Java, but for most programming languages like C/C++. Some other programming languages may automatically handle overflow and change type to a higher precision or to floating point, like PHP/JavaScript.

`k*value MOD -value == 0`

is true (where`k`

and`value`

are integers). – Nadir Sampaoli Jul 1 '12 at 11:54