First, integral types are required to be represented using a pure binary system, and so far the tutorial is correct.

Second, a `short`

is required to be at least 16 bits. If it's more, then you won't see the effect that you did, or any effect. It's unclear from your description whether the tutorial blindly assumes that `short`

is necessarily 16 bits (wrong), or whether it's just using *some* concrete example, with the understanding that it depends on compiler etc.

Third, the conversion to signed type … ~~is formally Implementation Defined Behavior if the value cannot be represented. This means that you are not guaranteed a change of value. Instead you ~~*can*, in principle, get any effect, such as a crash.

~~[example of other behavior lacking because I'm unable to cajole g++ 4.8.2 into trapping for your example code, even with ~~`-ftrapv`

]

… yields a value that's either the same, if it can be represented, or otherwise defined by the implementation.

That said, C++ guarantees that **unsigned arithmetic** is performed modulo 2^{n}, where *n* is the number of value representation bits, e.g. 16 in your example. And with the very common **two's complement form** representation of signed integers, a negative integer value -*x* is represented as the bitpattern for -*x* + 2^{n}. So if you start with the latter value (the interpretation of the bitpattern as unsigned) as 50 000, with 16 value bits and two's complement form, you get the signed value 50 000 - 2^{16} = 50 000 - 65 536 = -15 536

`-15,536`

which is the case. The bits haven't changed; only the interpretation of them. – Brian Roach Apr 14 '14 at 21:26