We are having N gold coins and M silver coins. There are k items each having some cost, A gold coins and B silver coins, where A or B can be zero also.
What can be algorithm to purchase maximum number of items?
We are having N gold coins and M silver coins. There are k items each having some cost, A gold coins and B silver coins, where A or B can be zero also. What can be algorithm to purchase maximum number of items? 


In this problem, every item has a two dimensional cost. Let item i have cost c[i] = < a, b > where a is the cost in gold coins and b in the cost of silver coins. The items can now be partially ordered so that item i is 'notmoreexpensive' than item j if
Note that this is a partial order. Two items <1, 2> and <2, 1> are not comparable in this partial ordering; neither one is notmoreexpensive than the other. It is now clear that a greedy algorithm can safely buy items as long as they are 'notmoreexpensive' compared to every other item remaining, but when there are multiple noncomparable items available, more analysis (e.g. search) can be needed. For example, if the costs are
this results in this partial order:
(most expensive item on the bottom). A greedy algorithm would purchase first <1, 1>. After that, both <2, 1> and <1, 2> are viable purchasing options. If the algorithm chooses to buy <2, 1>, the next to buy is then <1, 2> because it is now notmoreexpensive than all other remaining items (<3, 3>). Simple greedy algorithms can fail. With the setup <2, 1>, <1, 2>, <3, 0> and initial amount of coins gold = 4, silver = 2, the optimal solution is to by <1, 2> and <3, 0>, but buying <2, 1> first leads to being able to purchase only that item (purchases is left with <2, 1> coins that doesn't allow to buy any of the two remaining items). I would approach this buy building the partial order structure and then performing a backtracking search. If time constraints wouldn't allow for full backtracking, I would use limited backtracking as a heuristics for an otherwise greedy algorithm. 


Is this the Knapsack Problem?The problem you described is not the Knapsack problem. Here, you only want to maximize the number of items, not their total cost. In the Knapsack problem, you're interested instead in maximizing the total cost, while respecting the sack's capacity. In order words, you want to grab the most valuable items that would fit in your sack. You don't really care about how many of them, but only that they're the most valuable ones! Below, we'll at two variants of the problem:
Single Currency VariantAssuming you're only allowed to spend N gold coins and M silver coins, here is an algorithm that should work:
This algorithm only takes O(nlogn) time because of the sorting. MultiCurrency VariantThe above solution assumes that the two currencies can be converted to each other. Another variation of the problem involves orthogonal currencies, where the two currencies are not convertible to each other. In this case, all costs will be specified as vectors. In order to solve this problem using a dynamic programming algorithm. We need to ask if exhibits the following two traits:
Imagine a twodimensional table with N rows and M columns. The
Our algorithm essentially will fill out this table. In row To complete the table, we could use two lexicographically sorted arrays,
where This solution takes O((MN + n)logn) time to compute and uses O(MN + n) space. 


There is no "algorithm." You're describing a version of the Knapsack Problem, a wellknown NPcomplete problem. For SMALL versions of the problem, with small N,M, and k, you just go through all the different combinations. For larger versions, there is no known way to find an "optimal" solution that takes less than the lifetime of the universe to compute. The closest thing there is to solving this involves a field known as linear programming. It's... not a simple thing, but you can go read up on it if you like. 

