In this problem your task is to come up with a week schedule of classes in university for professors and student groups. Consider that there are 6 educational days in week and maximum number of classes per educational day is 7 (classes numerated from 1 to 7 for each educational day).

It is known that in university n students study, m professors work and there are a classrooms for conducting classes. Also you have two-dimensional array with n × m size which contains the following information. The number which stays in i-th row and j-th column equals to the number of classes which professor j must conduct with the group i in a single week. The schedule which you output must satisfy to array described above.

There are several other conditions for schedule. Single professor can not conduct more than one class. Similarly, single student group can not be on more than one class at the same time.

Let define a fatigue function for professors and student groups. Call this function f.

To single professor fatigue calculated in the following way. Let look on classes which this professor must conduct in each of the 6-th educational days. Let x be the number of class which professor will firstly conduct in day i and let y — the last class for this professor. Then the value (2 + y - x + 1)·(2 + y - x + 1) must be added to professor's fatigue. If professor has no classes in day i, nothing is added to professor's fatigue.

For single student group fatigue is calculated similarly. Lets look at classes of this group in each of the 6 educational days. Let x be the number of first class for this group on day i and let y — the last class for this group. Then the value (2 + y - x + 1)·(2 + y - x + 1) must be added to this group's fatigue. If student group has no classes in day i, nothing is added to group's fatigue.

So the value of function f equals to total {fatigue} for all n student groups and for all m professors.

Your task is to come up with such a schedule which minimizes the value of function f.

Jury prepared some solution of this problem. For each test you will get a certain number of points. It equals to result of division of the value of function f from the jury solution by the value of function f for schedule which your program output (i. e. the smaller value of {fatigue} function your program find the more points you will get), multiplied by 100. In the other words if the value of f for jury solution equals to p and for your solution — to q, you will get 100·p / q points (note, that the number of points is a real number). The points will be added together for all tests. The goal is to score as many points as possible.