If you do not have `XOR`

, then of course you can do the same with ordinary "unchecked" sum, that is sum of 32-bit integers with "wrap around" (no "overflow checking", sometimes known as `unchecked`

context).

This is addition modulo 2^{32}. I will consider the "unsigned" case. If you 32-bit int uses two's complement, it is just the same. (To a mathematician, two's complement is still just addition (and multiplication) modulo 2^{32}, we only pick a different canonical representative for each equivalence class modulo 2^{32}.)

If we had had *all* the non-zero 32-bit integers, we would have:

```
1 + 2 + 3 + … + 4294967295 ≡ 2147483648
```

One way of realizing this is to take the first and the last term together, they give zero (modulo 2^{32}). Then the second term (`2`

) and the second-last term (`4294967294`

) also give zero. Thus all terms cancel except the middle one (`2147483648`

) which is then equal to the sum.

From this equality, imagine you subtract one of the numbers (call it `x`

) on both sides of the `≡`

symbol. From this, you see that you find the missing number by starting from `2147483648`

and subtracting (still `unchecked`

) from that all of the numbers you are given. Then you end up with the missing number:

```
missingNumber ≡ 2147483648 - x1 - x2 - x3 - … - x4294967294
```

Of course, this is the same as moonshadow's solution, just carried out in the ring of integers modulo 2^{32}.

The elegant `XOR`

solution (sykora's answer) can also be written in the same way, and with that `XOR`

functions as both `+`

and `-`

at the same time. That is, if we had *all* the non-zero 32-bit integers, then

```
1 XOR 2 XOR 3 XOR … XOR 4294967295 ≡ 0
```

and then `XOR`

with the missing number `x`

on both sides of the `≡`

symbol to see that:

```
missingNumber ≡ x1 XOR x2 XOR x3 XOR … XOR x4294967294
```