I want to divide a graph with N weighted-vertices and N-1 edges into three parts such that the maximum of the sum of weights of all the vertices in each of the parts is minimized. This is the actual problem i am trying to solve, http://www.iarcs.org.in/inoi/contests/jan2006/Advanced-1.php
I considered the following method
/*Edges are stored in an array E, and also in an adjacency matrix for depth first search. Every edge in E has two attributes a and b which are the nodes of the edge*/ min-max = infinity for i -> 0 to length(E): for j -> i+1 to length(E): /*Call depth first search on the nodes of both the edges E[i] and E[j] the depth first search returns the sum of weights of the vertices it visits, we keep track of the maximum weight returned by dfs*/ Adjacency-matrix[E[i].a][E[i].b] = 0; Adjacency-matrix[E[j].a][E[j].b] = 0; max = 0 temp = dfs(E[i].a) if temp > max then max = temp temp = dfs(E[i].b) if temp > max then max = temp temp = dfs(E[i].a) if temp > max then max = temp temp = dfs(E[i].a) if temp > max then max = temp if max < min-max min-max = max Adjacency-matrix[E[i].a][E[i].b] = 1; Adjacency-matrix[E[j].a][E[j].b] = 1; /*The depth first search is called four times but it will terminate one time if we keep track of the visited vertices because there are only three components*/ /*After the outer loop terminates what we have in min-max will be the answer*/
The above algorithm takes O(n^3) time, as the number of edges will be n-1 the outer loop will run (n-1)! times that takes O(n^2) the dfs will visit each vertex only one so that is O(n) time.
But the problem is that n can be <= 3000 and O(n^3) time is not good for this problem. Is there any other method which will calculate the solve the question in the link faster than n^3?
EDIT:I implemented @BorisStrandjev's algorithm in c, it gave me a correct answer for the test input in the question, but for all other test inputs it gives a wrong answer, here is a link to my code in ideone http://ideone.com/67GSa2, the output here should be 390 but the program prints 395.
I am trying to find if i have made any mistake in my code but i dont see any. Can anyone please help me here the answers my code gave are very close to the correct answer so is there anything more to the algorithm?
EDIT 2:In the following graph-
@BorisStrandjev, your algorithm will chose i as 1, j as 2 in one of the iterations, but then the third part (3,4) is invalid.
I finally got the mistake in my code, instead of V[i] storing sum of i and all its descendants it stored V[i] and its ancestors, otherwise it would solve the above example correctly, thanks to all of you for your help.