Overflow is possible only when both numbers have the same sign. If both are positive, then you have overflow if mathematically A + B > LLONG_MAX
, or equivalently B > LLONG_MAX - A
. Since the right hand side is non-negative, the latter condition already implies B > 0
. The analogous argument shows that for the negative case, we also need not check the sign of B
(thanks to Ben Voigt for pointing out that the sign check on B
is unnecessary). Then you can check
if (A > 0) {
return B > (LLONG_MAX - A);
}
if (A < 0) {
return B < (LLONG_MIN - A);
}
return false;
to detect overflow. These computations cannot overflow due to the initial checks.
Checking the sign of the result of A + B
would work with guaranteed wrap-around semantics of overflowing integer computations. But overflow of signed integers is undefined behaviour, and even on CPUs where wrap-around is the implemented behaviour, the compiler may assume that no undefined behaviour occurs and remove the overflow-check altogether when implemented thus. So the check suggested in the comments to the question is highly unreliable.
if ((A<0 && B<0 && A+B>0) || (A>0 && B>0 && A+B<0)){/*Overflow*/}
You can only have overflow if both A and B have the same sign. If they do, and A+B doesn't have the same sign, then you have overflow issues. In other news, this is basically the fastest method around, since it executes in constant time, and only does the addition once.A=B=0x8000000000000000
, thenA+B=0
and your code doesn't work :p