Bingo is a game of chance played by a group of players. Each player has his or her own bingo card with a $5$by$5$ grid of numbers. Each number appears at most once per card. The bingo caller calls out a sequence of randomly drawn numbers, and the players mark the numbers that appear on their card as they are called out. The winner is the player that completes a line of five marked numbers (horizontally, vertically or diagonally) on his or her card. The winning player then yells “bingo” and the game ends.
You have been volunteering with a local youth group and have been running bingo games for the children. They love bingo, but every time two or more kids yell “bingo” at the same time, a spirited “disagreement” breaks out. You’ve created a slightly modified version of bingo (in the hopes of introducing fewer ties): the cards are $5$by$5$ grids with a number from $1$ to $3\, 000$ in each of the $25$ cells, and a winner is only declared when a player has $5$ numbers in a row. Note that in this new game, players cannot win via columns or diagonals.
Alas, these changes did not eliminate ties or the subsequent disagreements. To prevent further disagreements, you’ve decided to analyze the sets of cards to determine if there is any possibility that a tie (where two kids can yell bingo at the same time) can occur. Write a program that takes a collection of bingo cards and determines if there is any possible sequence of numbers that could be called so that the game ends, and a tie between two or more players occurs, when the last number in the sequence is called.
For example, consider the following two bingo cards:
$ \begin{array}{ccccc} 3 & 29 & 45 & 56 & 68 \\ 1 & 19 & 43 & 50 & 72 \\ 11 & 25 & 40 & 49 & 61 \\ 9 & 23 & 31 & 58 & 63 \\ 4 & 27 & 42 & 54 & 71 \end{array} $ 

$ \begin{array}{ccccc} 14 & 23 & 39 & 59 & 63 \\ 8 & 17 & 35 & 55 & 61 \\ 15 & 26 & 42 & 53 & 71 \\ 10 & 25 & 31 & 57 & 64 \\ 6 & 20 & 44 & 52 & 68 \\ \end{array} $ 
Then this set of two cards could result in a tie if the sequence of numbers called was
\[ 40~ 61~ 64~ 10~ 57~ 49~ 11~ 31~ 25 \]This sequence would result in the card on the left completing the third row and the card on the right completing the fourth row when the number $25$ is called.
The first line of the input is an integer $n$ ($2 \leq n \leq 100$), the number of bingo cards. After the first line are the $n$ bingo cards, each separated from the next by a blank line of input.
Each bingo card consists of five lines of input. Each line consists of five integers in the range from $1$ to $3\, 000$. The numbers on each bingo card are unique.
If no ties are possible between any two cards, output “no ties”. Otherwise, output the two numbers $a$ and $b$ ($1 \le a < b \le n$) identifying the two cards for which a tie could occur, where the cards are numbered from $1$ to $n$ in the order that they appear in the input. If multiple pairs of cards can tie, output the pair with the smallest $a$, breaking any remaining ties with the smallest $b$.
Sample Input 1  Sample Output 1 

2 3 29 45 56 68 1 19 43 50 72 11 25 40 49 61 9 23 31 58 63 4 27 42 54 71 14 23 39 59 63 8 17 35 55 61 15 26 42 53 71 10 25 31 57 64 6 20 44 52 68 
1 2 
Sample Input 2  Sample Output 2 

2 2189 2127 1451 982 835 150 1130 779 1326 1149 2697 2960 315 534 2537 2750 1771 875 1702 430 300 2657 2827 983 947 886 738 2569 1107 2758 2795 173 1718 2294 1732 1188 2273 2489 1251 2224 431 1050 1764 1193 1566 1194 1561 162 1673 2411 
no ties 