Knights in Fen

There are black and white knights on a 5 by 5 chessboard. There are twelve of each color, and there is one square that is empty. At any time, a knight can move into an empty square as long as it moves like a knight in normal chess (what else did you expect?).

Given an initial position of the board, the question is: “what is the minimum number of moves in which we can reach the final position”, which is:

\includegraphics[width=0.2\textwidth ]{knightsfen-1}


First line of the input file contains an integer $N$ ($N<14$) that indicates how many sets of inputs are there. The description of each set is given below:

Each set consists of five lines; each line represents one row of a chessboard. The positions occupied by white knights are marked by $0$ and the positions occupied by black knights are marked by $1$. The space corresponds to the empty square on board.

There is no blank line between the two sets of input.

The first set of the sample input below corresponds to this configuration:

\includegraphics[width=0.2\textwidth ]{knightsfen-2}


For each set your task is to find the minimum number of moves leading from the starting input configuration to the final one. If that number is bigger than $10$, then output one line stating

Unsolvable in less than 11 move(s).

otherwise output one line stating

Solvable in $n$ move(s).

where $n \leq 10$.

The output for each set is produced in a single line as shown in the sample output.

Sample Input 1 Sample Output 1
110 1
01 11
Unsolvable in less than 11 move(s).
Solvable in 7 move(s).