That'll depend on what sort of type `UINT32`

really is.

If it's an unsigned type (as you'd expect) then results are guaranteed to be reduced modulo the largest value that can be represented + 1, so code like this:

```
if (std::numeric_limits<T>::is_unsigned)
assert(std::numeric_limits<T>::max()+1==0);
```

...should succeed. OTOH, based on the name, we'd typically expect that to be a 32-bit type regardless of the implementation, register size, etc., so we'd expect to get the same result regardless.

Edit: [sorry, had to stop and feed baby for a few minutes] I should add in more detail. Although we can certainly hope it's unlikely in practice, it's conceivable that `UINT32`

could really be (say) a 16-bit `unsigned short`

. For the sake of discussion, let's assume that `int`

is 32 bits.

In this case, `dword+1`

would involve math between an `unsigned short`

and an `int`

(the implicit type of `1`

). In that case, `dword`

would actually be initialized to 65535. Then, when you did the addition, that `65535`

would be promoted to a 32-bit `int`

, and `1`

added as an `int`

, so the result would be 65536.

At least in theory, the same basic thing could happen if UINT32 was an unsigned 32-bit type (as we'd expect) but `int`

was a 64-bit type. Again, `dword`

would be promoted to `int`

before doing the math, so the math would be done on 64-bit quantities rather than 32-bit, so (again) the result would not wrap around to 0.

`UINT32`

will be the same size on both 32 and 64 bit architectures so you'd expect it to act the same. – Mark Ransom Apr 3 '13 at 23:10