# GSS1 -SPOJ - Segment tree TLE

The link to the problem is http://www.spoj.com/problems/GSS1/

I'm solving the problem by using a segment tree - I am saving the sum, the max ,leftmost max, and the right most max at every node. I then search the graph to find the answer to a specific interval. How could I increase the speed of this code?

``````import java.util.Scanner;
//TLE
class GSS1 {

static class Node{
int max;
int MaxL;
int MaxR;
int sum;

public Node(int max, int MaxL, int MaxR, int sum){
this.max=max;
this.MaxL=MaxL;
this.MaxR=MaxR;
this.sum=sum;
}

public Node(){

}
}

static class SegmentTree{

private Node[] tree;
private int maxsize;
private int height;

private  final int STARTINDEX = 0;
private  final int ENDINDEX;
private  final int ROOT = 0;
Node s;

public SegmentTree(int size){
height = (int)(Math.ceil(Math.log(size) /  Math.log(2)));
maxsize = 2 * (int) Math.pow(2, height) - 1;
tree = new Node[maxsize];
for(int i=0;i<tree.length;i++){
tree[i]=new Node();
}
ENDINDEX = size - 1;
s=new Node();
s.MaxL=Integer.MIN_VALUE;
s.MaxR=Integer.MIN_VALUE;
s.sum=Integer.MIN_VALUE;
s.max=Integer.MIN_VALUE;

}

private int leftchild(int pos){
return 2 * pos + 1;
}

private int rightchild(int pos){
return 2 * pos + 2;
}

private int mid(int start, int end){
return (start + (end - start) / 2);
}

private Node constructSegmentTreeUtil(int[] elements, int startIndex, int endIndex, int current){
if (startIndex == endIndex)
{
tree[current].max=tree[current].MaxL=tree[current].MaxR=tree[current].sum=elements[startIndex];
return tree[current];
}
int mid = mid(startIndex, endIndex);
Node left=constructSegmentTreeUtil(elements, startIndex, mid, leftchild(current));
Node right=constructSegmentTreeUtil(elements, mid + 1, endIndex, rightchild(current));
tree[current].max = Math.max(left.max, right.max);
tree[current].MaxL = Math.max(left.MaxL , left.sum+right.MaxL);
tree[current].MaxR = Math.max(right.MaxR , right.sum+left.MaxR);
tree[current].sum = left.sum+right.sum;
return tree[current];
}

public void constructSegmentTree(int[] elements){
constructSegmentTreeUtil(elements, STARTINDEX, ENDINDEX, ROOT);
}

private Node getSumUtil(int startIndex, int endIndex, int queryStart, int queryEnd, int current){

if (queryStart <= startIndex && queryEnd >= endIndex ){
return tree[current];
}
if (endIndex < queryStart || startIndex > queryEnd){
return s;
}
int mid = mid(startIndex, endIndex);

Node left=getSumUtil(startIndex, mid, queryStart, queryEnd, leftchild(current));
Node right=getSumUtil( mid + 1, endIndex, queryStart, queryEnd, rightchild(current));

Node current_Node=new Node();
current_Node.max = Math.max(left.max, right.max);
current_Node.MaxL = Math.max(left.MaxL , left.sum+right.MaxL);
current_Node.MaxR = Math.max(right.MaxR , right.sum+left.MaxR);
current_Node.sum = left.sum+right.sum;
return current_Node;

}

public int getMaxSum(int queryStart, int queryEnd){
if(queryStart < 0 || queryEnd > tree.length)
{System.out.println("inside negative");
return Integer.MIN_VALUE;
}
return getMax(getSumUtil(STARTINDEX, ENDINDEX, queryStart, queryEnd, ROOT));
}

public int getMax(Node r){
return Math.max(Math.max(r.max, r.MaxL),Math.max(r.MaxR, r.sum));
}

public int getFirst(){
return tree[0].MaxL;
}

}

public static void main(String[] args) {
Scanner input=new Scanner(System.in);

int numbers[]=new int [input.nextInt()];

for(int i=0;i<numbers.length;i++){
numbers[i]=input.nextInt();
}

SegmentTree tree=new SegmentTree(numbers.length);
tree.constructSegmentTree(numbers);

int cases=input.nextInt();

int x;
int y;
int query;
for(int i=0;i<cases;i++){
x=input.nextInt()-1;
y=input.nextInt()-1;

System.out.println(tree.getMaxSum(x, y));
}

}
``````

}

-
What's the complexity of your algorithm? Have you tried running it on random input and checking how long it takes? From my experience your should get at least a runtime of one fourth the time limit on a modern machine for it to pass on Pyramid –  Niklas B. Apr 30 '14 at 2:07
It passes on the first 8 test cases, but fails on the ninth so I'm assuming that the 9th test cases has the largest input. I think that the complexity of my algorithm is O(nlogn) –  The Bear Apr 30 '14 at 3:05
@TheBear: I think it's no coincidence that only few people managed to solve this using Java. The time limit is pretty tough, so you will probably need a lot of constant optimizations to squeeze it through if you want to stick with Java. Maybe using an array to represent the tree (like an implicit heap) is faster than allocating each node at once. I/O speed is probably also an issue here, `Scanner` is notoriously slow, which is why people typically use they're own buffered I/O integer parsing routines for competitive programming purposes. –  Niklas B. Apr 30 '14 at 6:44
@PhamTrung Yes you're right, it should be `tree[current].max = Math.max(left.max, Math.max(right.max, left.maxR + right.maxL));` –  Niklas B. Apr 30 '14 at 7:33
I can not imagine that you would not have found this with random testing. Always use random testing on SPOJ or similar sites when you are out of ideas on what cases your code would not work –  Niklas B. Apr 30 '14 at 18:17

Your approach is right but I/O speed also matters for this question, as the timing constraints are very tight. You should use a custom reader since `Scanner` is very slow. Use the below mentioned class for reading input.

``````class Reader {
final private int BUFFER_SIZE = 1 << 16;private DataInputStream din;private byte[] buffer;private int bufferPointer, bytesRead;