You are given an array, say A[], of N elements, initially all of them are equal to negative infinity.

Now you are asked to perform two types of queries(Total M queries):

Type 1. Given two integers a and d you need to update the array A[] from index l to index r. What you need to do exactly is - for each index l+i (where 0<=i<=r-l) which contains some value say 'val' you need to update the value of that index with maximum of a+i*d and val, i.e, A[l+i] = max(A[l+i], a+i*d).

Type 2. Given an integer 'i', you need to report the value of A[i].

Example : let N = 5 and M = 4

initially A[] = {-inf, -inf, -inf, -inf, -inf}
query 1: l = 2, r = 4, a = 2, d = 3
new A[] = {-inf, 2, 5, 8, -inf}
query 2: i = 3
output = 5
query 3: l = 3, r = 5, a = 10, d = -6
new A[] = {-inf, 2, 10, 8, -2}
query 4: i = 5
output = -2

Note : value of N and M can be as large as 100000 so I am looking for better algorithms than O(N*M).


  • 2
    You are given a homework assignment, say...
    – jonrsharpe
    Mar 11 '14 at 23:48
  • @jonrsharpe yes, you are right. That's why I am looking for some hints only and not for the whole solution.
    – user3288651
    Mar 11 '14 at 23:49
  • Hint: try doing stuff, see how far you get, and ask specific questions as they come up.
    – Sneftel
    Mar 11 '14 at 23:55
  • @Sneftel what I am thinking is to build a segment tree where I can update the ranges in log(N) time but updating a node itself is taking O(N) time, so I have no clue what to do.
    – user3288651
    Mar 12 '14 at 0:00
  • @Sneftel: For these kinds of questions it's hard to even come up with an initial approach. Assuming this is the case with OP, I fail to see how he or she could have decomposed the problem into "specific" subproblems. I guess that's just a general problem with Stack Overflow
    – Niklas B.
    Mar 12 '14 at 1:38

Think about the problem this way: You are managing a collection of piecewise linear functions fi(x) = ai x + bi (li <= x <= ri) subject to the following operations:

  • Add a new function
  • Find the maximum of all the functions added so far that are defined for a specific value of x

I see two possible approaches:

  1. Store only the maximum ("upper hull") of all the functions, which is in turn a collection of piecewise linear functions, but with disjoint definition intervals. UPDATE: I initially thought this could be done with a simple binary search tree, but it's not as simple as that, so I would go with option 2
  2. Follow a more standard approach and use a segment tree on the x range (the "array"), that stores sets of linear functions in its nodes. Now for a given x, you can walk up the tree to find out what linear functions are defined at that point and use the standard convex hull trick to find their maximum at x. Complexity: O(n + M * log n * log M)
  • Also any (complete) tree you build is going to be O(n) to build it. It's searching trees that is O(log n).
    – aruisdante
    Mar 12 '14 at 0:49
  • @aruisdante: Hah? Well I can build it in O(1) as well, but that's pretty irrelevant. Operations are O(log^2 n) for option 2 and O(log n) for option 1
    – Niklas B.
    Mar 12 '14 at 0:50
  • You can build it in O(1) if you can predict what's going into it. You'd be hard pressed to build it for random data. Unless I read the problem wrong and the linear functions are evenly spread, in which case yeah it'd be O(1) to build
    – aruisdante
    Mar 12 '14 at 0:52
  • Ah yeah, I didn't catch that you 'changed the base' for a lack of a better way to phrase it to make it the portion that is continuous so that you can do the array segmentation and make it O(1) to build.
    – aruisdante
    Mar 12 '14 at 0:58
  • How operations in option 2 can be done in O(logN*logM) ? I can't understand your solution completely. Lets say you are given 50000 update operations and 50000 query operation alternately(first update then query then update then query and so on) where all the update operation is from 1 to N. Then how does this solution handle this problem?
    – user3288651
    Mar 12 '14 at 1:06