OK, seems I just can't give it a rest :)

## Simplest solution

```
int A[N] = {...};
int signed_1(n) { return n%2<1 ? +n : -n; } // 0,-1,+2,-3,+4,-5,+6,-7,...
int signed_2(n) { return n%4<2 ? +n : -n; } // 0,+1,-2,-3,+4,+5,-6,-7,...
long S1 = 0; // or int64, or long long, or some user-defined class
long S2 = 0; // so that it has enough bits to contain sum without overflow
for (int i=0; i<N-2; ++i)
{
S1 += signed_1(A[i]) - signed_1(i);
S2 += signed_2(A[i]) - signed_2(i);
}
for (int i=N-2; i<N; ++i)
{
S1 += signed_1(A[i]);
S2 += signed_2(A[i]);
}
S1 = abs(S1);
S2 = abs(S2);
assert(S1 != S2); // this algorithm fails in this case
p = (S1+S2)/2;
q = abs(S1-S2)/2;
```

One sum (S1 or S2) contains p and q with the same sign, the other sum - with opposite signs, all other members are eliminated.

*S1 and S2 must have enough bits to accommodate sums, the algorithm does not stand for overflow because of abs().*

if abs(S1)==abs(S2) then the algorithm fails, though this value will still be the difference between p and q (i.e. abs(p - q) == abs(S1)).

## Previous solution

I doubt somebody will ever encounter such a problem in the field ;)

and I guess, I know the teacher's expectation:

Lets take array {0,1,2,...,n-2,n-1},

The given one can be produced by replacing last two elements n-2 and n-1 with unknown p and q (less order)

so, the sum of elements will be (n-1)n/2 *+ p + q - (n-2) - (n-1)*

the sum of squares (n-1)n(2n-1)/6 *+ p^2 + q^2 - (n-2)^2 - (n-1)^2*

Simple math remains:

```
(1) p+q = S1
(2) p^2+q^2 = S2
```

Surely you won't solve it as math classes teach to solve square equations.

First, calculate everything modulo 2^32, that is, allow for overflow.

Then check pairs {p,q}: {0, S1}, {1, S1-1} ... against expression (2) to find candidates *(there might be more than 2 due to modulo and squaring)*

And finally check found candidates if they really are present in array twice.