Today (09.03.2013) at 14:00 UTC the sixth (the last regular) contest of the Croatian Olympiad in Informatics. takes place. You can login/register here. Duration: 3 hours. Good luck!
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Today (09.03.2013) at 14:00 UTC the sixth (the last regular) contest of the Croatian Olympiad in Informatics. takes place. You can login/register here. Duration: 3 hours. Good luck!
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I believe it is on 9 March :[ http://hsin.hr/coci]
Oops, thanks a lot.
May anyone suggest a suitable method to solve 4th problem ? I only came up with the following observation.
I used 2 segment trees to handle the horizontal and vertical cases , but that scored 80 / 120 , due to exceeding the memory limit in the last 2 testcases. I think there are some tricks(coordinate compression , solving the horizontal cases then clearing the segment tree then solving the vertical cases) , but I'm not sure if they can help out.
And may anyone suggest how to approach 5-th problem ?
If you have the range of [0..2^x-1] you can easily store a segment tree in one array of integers — for values. Every other needed information is easily computed on-the-go.
You only need to do two sweep lines, one for the X queries, and another for the Y queries.
In each sweep line, you need to keep a counter that tells you the number of active triangles.
Regarding the 4th problem: First off, lets simplify the prob by assuming we deal with rectangles rather than triangles. Using that simplification we can make two arrays X and Y. where we are going to append X_min and X_max and Y_min and Y_max for each rectangle respectively. Secondly, we make two new arrays for X and Y: X' and Y' where on the i-th index we write the number of rectangles, edges of which are situated on the different sides of X[i].
This is just an idea.
The 5th problem can be solved with a simple O(N2) DP. The key observation is that any two adjacent elements in a good sequence differ by not more than 1. The reverse is also true: any sequence in which every two adjacent elements differ by not more than 1 and the first and the last elements are equal to 0 is good.
I would also say that the correct relief of length N form a bijection with correct bracket sequence of length N-1, where in N-1 spaces we can put spaces as well. For example in 3rd sample case:
The numbers represent the level of bracket sequence at a given point.
I had implemented the same idea, and it got accepted.
also we can improve this using combinatorics making the solution become O(N)
Can u explain more about the O(N) solution? I can't solve it with O(N^2) neither because of memory limit...
you use dinamic array as i think dn[N][N]
you can use dinamic array like this dn[2][N]
because f(n,k) = f(n+1,k)+f(n+1,k-1)+f(n+1,k+1)
n is the position in the array and k is the what is the array[i]
so you must only know N th and N+1 th rows .
Just published Results.