Way too much confusion going on in people trying to answer this question.

Let's examine:

`2 * 2000000000`

This is an `int`

multiplied by an `int`

. §5/4 tells us:

If during the evaluation of an expression, the result is not mathematically deﬁned or not in the range of representable values for its type, the behavior is undeﬁned.

This result is mathematically defined, but is it in the range of representable values for `int`

?

That depends. On many common architectures `int`

has 32 bits to represent values, giving it a maximum value of 2,147,483,647. Since the mathematical result of this is 4,000,000,000, such an architecture would not be able to represent the value and the behavior is undefined. (This pretty much kills the question, because now the behavior of the entire program is undefined.)

But that's just dependent on the platform. If `int`

was 64 bits wide instead (note: `long long`

is guaranteed to have at least 64 bits to represent values), the result would fit just fine.

Let's just fix up the problem a bit though and go straight to this:

```
int x = -294967296; // -294,967,296
```

And let's further say this fits within the range of `int`

(which for 32 bit `int`

it does).

Now let's cast this to an `unsigned int`

:

```
unsigned int y = static_cast<unsigned int>(x);
```

What is the value of `y`

? **It has nothing to do with the bit representation of **`x`

.

There is no "bit cast" where the compiler simply treats the bits as an unsigned quantity. Conversions work with *values*. The *value* of a `signed int`

converted to an `unsigned int`

is defined in §4.7/2:

If the destination type is unsigned, the resulting value is the least unsigned integer congruent to the source integer (modulo 2^{n} where n is the number of bits used to represent the unsigned type). [Note: In a two’s complement representation, this conversion is conceptual and there is no change in the bit pattern (if there is no truncation). —end note ]

For us on our 32-bit (`unsigned`

) `int`

system, this means 4000000000. This works regardless of bits: two's-compliment, one's-compliment, magic's-compliment, etc. These are irrelevant.

The *reason* you see the value you wanted in the first palce (ignoring UB) is that on your two's-compliment machine, the difference between signed and unsigned integers is indeed a matter of viewing bits differently. So when you multiplied those two `int`

's, you were "really" multiplying two unsigned integers, ignoring the overflow, and viewing the result as a signed integer. Then the cast changes your view once more.

But the casting works independently of bits!

`2 * 2000000000`

is an expression that is evaluated as an`int`

(which overflows) then converted to`long long`

– andre Jan 15 '13 at 19:42valuesnot bits. And casting from signed to unsigned is done modulo the max value of the bits in the unsigned integer. The fact that on two's compliment machines this means simply interpreting the bits differently is neat but irrelevant. What matters is that (after some math)`2^32 - 294967296 = 4000000000`

. It works regardless of bit representation. – GManNickG Jan 15 '13 at 19:54`2 * 2000000000`

results in`-294967296`

, which very much does depend on the system and bit representation (particularly because it's undefined behavior anyway, in this case). But yes, it's not the cast that makes the magic work (like you correctly point out); it's the 2's complementedness of`int`

and the way overflow is being handled that makes it work. Just want to help make that a little clearer. – Cornstalks Jan 15 '13 at 20:02