There is a rectangular grid of coins, with heads being represented by the value 1 and tails being represented by the value 0. You represent this using a 2D integer array table (between 1 to 10 rows/columns, inclusive).
In each move, you choose any single cell (R, C) in the grid (R-th row, C-th column) and flip the coins in all cells (r, c), where r is between 0 and R, inclusive, and c is between 0 and C, inclusive. Flipping a coin means inverting the value of a cell from zero to one or one to zero.
Return the minimum number of moves required to change all the cells in the grid to tails. This will always be possible.
1111 1111 returns: 1 01 01 returns: 2 010101011010000101010101 returns: 20 000 000 001 011 returns: 6
This is what i tried: Since the order of flipping doesn't matter, and making a move on a coin twice is like not making a move at all, we can just find all distinct combinations of flipping coins, and minimizing the size of good combinations(good meaning those that give all tails).
This can be done by making a set consisting of all coins, each represented by an index.(i.e. if there were 20 coins in all, this set would contain 20 elements, giving them an index 1 to 20). Then make all possible subsets and see which of them give the answer(i.e. if making a move on the coins in the subset gives us all tails). Finally, minimize size of the good combinations.
I don't know if I've been able to express myself too clearly... I'll post a code if you want. Anyway, this method is too time consuming and wasteful, and not possible for no.of coins>20(in my code). How to go about this?