The logical sum yields $1$ if at least one of the bits $x$ and $y$ is $1$. Conversely, it yields $0$ only if both of them are $0$.

Example

0110 | 0101 = 0111

Constraints

• $2 \leq N \leq 5\times 10^5$
• $0\leq A_i,B_i \leq 31$
• All values in the input are integers.

Input

The input is given from Standard Input in the following format:

Output

Print the maximum possible $\displaystyle\sum_{i=0}^{N-1} (A_i|B_i)$.

3
0 1 3
0 2 3

8

If Takahashi does not perform the operation, $A$ remains $(0,1,3)$, and we have $\displaystyle\sum_{i=0}^{N-1} (A_i|B_i)=(0|0)+(1|2)+(3|3)=0+3+3=6$;
if he performs the operation once, making $A=(1,3,0)$, we have $\displaystyle\sum_{i=0}^{N-1} (A_i|B_i)=(1|0)+(3|2)+(0|3)=1+3+3=7$; and
if he performs the operation twice, making $A=(3,0,1)$, we have $\displaystyle\sum_{i=0}^{N-1} (A_i|B_i)=(3|0)+(0|2)+(1|3)=3+2+3=8$.
If he performs the operation three or more times, $A$ becomes one of the sequences above, so the maximum possible $\displaystyle\sum_{i=0}^{N-1} (A_i|B_i)$ is $8$, which should be printed.

5
1 6 1 4 3
0 6 4 0 1

23

The value is maximized if he performs the operation three times, making $A=(4,3,1,6,1)$,
where $\displaystyle\sum_{i=0}^{N-1} (A_i|B_i)=(4|0)+(3|6)+(1|4)+(6|0)+(1|1)=4+7+5+6+1=23$.