I've noticed that in the tutorial the author mentioned that there exist an linear time solution, but I don't know what the solution is ...
→ Pay attention
→ Streams
→ Top rated
| # | User | Rating |
|---|---|---|
| 1 | jiangly | 3976 |
| 2 | tourist | 3815 |
| 3 | jqdai0815 | 3682 |
| 4 | ksun48 | 3614 |
| 5 | orzdevinwang | 3526 |
| 6 | ecnerwala | 3514 |
| 7 | Benq | 3482 |
| 8 | hos.lyric | 3382 |
| 9 | gamegame | 3374 |
| 10 | heuristica | 3357 |
→ Top contributors
| # | User | Contrib. |
|---|---|---|
| 1 | cry | 169 |
| 2 | -is-this-fft- | 165 |
| 3 | Um_nik | 161 |
| 3 | atcoder_official | 161 |
| 5 | djm03178 | 157 |
| 6 | Dominater069 | 156 |
| 7 | adamant | 154 |
| 8 | luogu_official | 152 |
| 9 | awoo | 151 |
| 10 | TheScrasse | 147 |
→ Find user
→ Recent actions
Codeforces (c) Copyright 2010-2025 Mike Mirzayanov
The only programming contests Web 2.0 platform
Server time: Jan/19/2025 02:15:36 (k1).
Desktop version, switch to mobile version.
Supported by
Find all the biconnected components, let there be $$$C$$$ such components.
Let $$$G$$$ be a graph with $$$C$$$ nodes. For some color $$$c$$$ let the indices of edges with such color be $$$c_1, c_2, \ldots, c_x$$$, let's add edge $$$c_i-c_{i-1}$$$ for every $$$x \geq i>1$$$ to $$$G$$$. If we do this for all colors we will have some connected components in $$$G$$$. It can be proven that for every connected component in $$$G$$$: we can have all the colors (in this component) in an optimal tree iff this component has a cycle or contains a vertex which corresponds to a bridge BCC in the original graph.
All of this can be done in linear time.