The algorithm is simple. First, sort the problems by `v_i`

, then, for each problem, find the number of problems in the interval `(v_i-K, v_i]`

. The maximum of those numbers is the result. The second phase can be done in `O(n)`

, so the most costly operation is sorting, making the whole algorithm `O(n log n)`

. Look here for a demonstration of the work of the algorithm on your data and K=35 in a spreadsheet.

## Why does this work

Let's reformulate the problem to the problem of graph coloring. We create graph G as follows: vertices will be the problems and there will be an edge between two problems iff `|v_i - v_j| < K`

.

In such graph, independent sets exactly correspond to sets of problems doable on the same day. (<=) If the set can be done on a day, it is surely an independent set. (=>) If the set doesn't contain two problems not satisfying the K-difference criterion, you can just sort them according to the difficulty and solve them in this order. Both condition will be satisfied this way.

Therefore, it easily follows that colorings of graph G exactly correspond to schedules of the problems on different days, with each color corresponding to one day.

So, we want to find the chromaticity of graph G. This will be easy once we recognize the graph is an interval graph, which is a perfect graph, those have chromaticity equal to cliqueness, and both can be found by a simple algorithm.

Interval graphs are graphs of intervals on the real line, edges are between intervals that intersect. Our graph, as can be easily seen, is an interval graph (for each problem, assign an interval `(v_i-K, v_i]`

. It can be easily seen that the edges of this interval graph are exactly the edges of our graph).

*Lemma 1*: In an interval graph, there exist a vertex whose neighbors form a clique.

*Proof* is easy. You just take the interval with the lowest upper bound (or highest lower bound) of all. Any intervals intersecting it have the upper bound higher, therefore, the upper bound of the first interval is contained in the intersection of them all. Therefore, they intersect each other and form a clique. qed

*Lemma 2*: In a family of graphs closed on induced subgraphs and having the property from lemma 1 (existence of vertex, whose neighbors form a clique), the following algorithm produces minimal coloring:

- Find the vertex
*x*, whose neighbors form a clique.
- Remove
*x* from the graph, making its subgraph G'.
- Color G' recursively
- Color
*x* by the least color not found on its neighbors

*Proof*: In (3), the algorithm produces optimal coloring of the subgraph G' by induction hypothesis + closeness of our family on induced subgraphs. In (4), the algorithm only chooses a new color `n`

if there is a clique of size `n-1`

on the neighbors of *x*. That means, with *x*, there is a clique of size `n`

in G, so its chromaticity must be at least `n`

. Therefore, the color given by the algorithm to a vertex is always `<= chromaticity(G)`

, which means the coloring is optimal. (Obviously, the algorithm produces a valid coloring). qed

*Corollary*: Interval graphs are perfect (perfect <=> chromaticity == cliqueness)

So we just have to find the cliqueness of G. That is easy easy for interval graphs: You just process the segments of the real line not containing interval boundaries and count the number of intervals intersecting there, which is even easier in your case, where the intervals have uniform length. This leads to an algorithm outlined in the beginning of this post.

`5 1 5 3 4 5 6`

is solvable in 1 day ? – Ashish Negi Nov 1 '13 at 6:22