I was solving this problem : http://www.spoj.com/status/SAM,iiit/
I somehow arrived at the solution but I still can't prove it mathematically.
What the problem statement:
There are 'n' toys (1<=n<=10^5) on a shelf.A child is on the floor.He demands toys in a sequence to play with , specified by 'p' (1<=p<=5*10^5).His mother gives him a toy from the shelf if the child demanded a toy which is not on floor.At a time only 'k'(1<=k<=n) toys can be there on floor.So mother when giving toy from shelf can pick a toy from floor and put it back to shelf if she wants. So we have to minimize total number of times mother picks toys from shelf.
(a)Variable and functions:
Keep a set of toys on floor and a variable ans(initially 0),which stores the answer. Also next,next[i] tells when will toy number 'i' come next in the demand sequence, ie. index of its next occurrence in demand sequence. update next[x] updates next[x] to store the next index of its occurrence in demand sequence.If there is no further occurrence next[x]=MAX_INTEGER;
Following are the cases: 1.If child demands a 'x' toy from shelf: increment ans If there are less than k elements then: add the element to the set update next[x] If there are k elements: remove the element from set whose value of next is largest add element 'x' to set update next[x] 2.If child demands toy from floor say toy 'x': update next[x] ans is the final answer.
Now I can't prove why this greedy type approach is mathematically correct.