Emuskald considers himself a master of flow algorithms. Now he has completed his most ingenious program yet — it calculates the maximum flow in an undirected graph. The graph consists of n vertices and m edges. Vertices are numbered from 1 to n. Vertices 1 and n being the source and the sink respectively.

However, his max-flow algorithm seems to have a little flaw — it only finds the flow volume for each edge, but not its direction. Help him find for each edge the direction of the flow through this edges. Note, that the resulting flow should be correct maximum flow.

More formally. You are given an undirected graph. For each it's undirected edge (a_i, b_i) you are given the flow volume c_i. You should direct all edges in such way that the following conditions hold:

1. for each vertex v (1 < v < n), sum of c_i of incoming edges is equal to the sum of c_i of outcoming edges;
2. vertex with number 1 has no incoming edges;
3. the obtained directed graph does not have cycles.

The first line of input contains two space-separated integers n and m (2 ≤ n ≤ 2·10⁵, n - 1 ≤ m ≤ 2·10⁵), the number of vertices and edges in the graph. The following m lines contain three space-separated integers a_i, b_i and c_i (1 ≤ a_i, b_i ≤ n, a_i ≠ b_i, 1 ≤ c_i ≤ 10⁴), which means that there is an undirected edge from a_i to b_i with flow volume c_i.

It is guaranteed that there are no two edges connecting the same vertices; the given graph is connected; a solution always exists.

Output m lines, each containing one integer d_i, which should be 0 if the direction of the i-th edge is a_i → b_i (the flow goes from vertex a_i to vertex b_i) and should be 1 otherwise. The edges are numbered from 1 to m in the order they are given in the input.

If there are several solutions you can print any of them.