Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have the following problem:

  • Let there be n projects.
  • Let Fi(x) equal to the number of points you will obtain if you spent x units of time working on project i.
  • You have T units of time to use and work on any project you would like.

The goal is to maximize the number of points you will earn and the F functions are non-decreasing.

The F functions have diminishing marginal return, in other words spending x+1 unit of time working on a particular project will yield less of an increase in total points earned from that project than spending x unit of time on the project did.

I have come up with the following O(nlogn + Tlogn) algorithm but I am supposed to find an algorithm running in O(n + Tlogn):

sum = 0
gain[] = sort(fi(1))

for sum < T
    getMax(gain) // assume that the max gain corresponds to project "P"
    gain.sortedInsert(Fp(schedule[P] + 1) - gain[P])

return schedule

That is, it takes O(nlogn) to sort the initial gain array and O(Tlogn) to run through the loop. I have thought through this problem more than I care to admit and cannot come up with an algorithm that would run in O(n + Tlogn).

share|improve this question

1 Answer 1

up vote 1 down vote accepted

For the first case, use a Heap, constructing the heap will take O(n) time, and each ExtractMin & DecreaseKey function call will take O(logN) time.

For the second case construct a nXT table where ith column denotes the solution for the case T=i. i+1 th column should only depend on the values on the ith column and the function F, hence calculatable in O(nT) time. I did not think all the cases thoroughly but this should give you a good start.

share|improve this answer
I wasn't aware of the ability to build a min/max heap in linear time; Thanks a lot, this allows for my solution of case 1 to run in O(n + TlogN). –  Pi_ Nov 22 '12 at 20:23

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.