the problem requires us to find out the number of ways of placing R coins on a N*M grid such that each row and column has at least one coin. Constraints given are N , M < 200 , R < N*M. I initially thought of backtracking, but i was made to realise that it would never finish in time . Can someone guide me to another solution? (DP , closed form formula.) any pointers would be nice. Thanks.

AnswerAccording to OEIS sequence A055602 one possible solution to this is:
You will need to evaluate N+1 different values for a. Assuming you have precomputed binomial coefficients, each evaluation of a is O(M) so the total complexity is O(NM). InterpretationThis formula can be derived using the inclusionexclusion principle twice. a(m,n,r) is the number of ways of putting r coins on a grid of size m*n such that every one of the m columns is occupied, but not all the rows are necessarily occupied. InclusionExclusion turns this into the correct answer. (The idea is that we get our first estimate from a(M,N,R). This overestimates the correct answer because not all rows are occupied so we subtract cases a(M,N1,R) where we only occupy N1 rows. This then underestimates so we need to correct again...) Similarly we can compute a(m,n,r) by considering b(m,n,r) which is the number of ways of placing r coins on a grid where we don't care about rows or columns being occupied. This can be derived simply from the number of ways of choosing r places in a grid size m*n , i.e. binomial(m*n,r). We use IE to turn this into the function a(m,n,r) where we know that all columns are occupied. If you want to allow different conditions on the number of coins on each square, then you can just change b(m,n,r) to the appropriate counting function. 


This is tough, but if you begin by working out how many ways you can have at least one coin on each row and column (call them reserve coins). The answer will be the product of #1 #4 is where the trickier stuff takes place. For N*M where N!=M, 

