proconlib
This documentation is automatically generated by competitive-verifier/competitive-verifier
tests/scc_graph/sccs.test.cpp
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- Last update: 2025-01-22 03:51:11+00:00
- Problem: https://judge.yosupo.jp/problem/scc
Depends on
- std::less by key (tools/less_by.hpp)
- Strongly connected component decomposition (tools/scc_graph.hpp)
Code
// competitive-verifier: PROBLEM https://judge.yosupo.jp/problem/scc
#include <iostream>
#include "tools/scc_graph.hpp"
using ll = long long;
int main() {
std::cin.tie(nullptr);
std::ios_base::sync_with_stdio(false);
ll N, M;
std::cin >> N >> M;
tools::scc_graph graph(N);
for (ll i = 0; i < M; ++i) {
ll a, b;
std::cin >> a >> b;
graph.add_edge(a, b);
}
graph.build();
std::cout << graph.sccs().size() << '\n';
for (const auto& scc : graph.sccs()) {
std::cout << scc.size();
for (const auto v : scc) {
std::cout << ' ' << v;
}
std::cout << '\n';
}
return 0;
}
#line 1 "tests/scc_graph/sccs.test.cpp"
// competitive-verifier: PROBLEM https://judge.yosupo.jp/problem/scc
#include <iostream>
#line 1 "tools/scc_graph.hpp"
#include <vector>
#include <utility>
#include <cstddef>
#include <cassert>
#include <stack>
#include <algorithm>
#line 1 "tools/less_by.hpp"
namespace tools {
template <class F>
class less_by {
private:
F selector;
public:
less_by(const F& selector) : selector(selector) {
}
template <class T>
bool operator()(const T& x, const T& y) const {
return selector(x) < selector(y);
}
};
}
#line 11 "tools/scc_graph.hpp"
namespace tools {
class scc_graph {
private:
::std::vector<::std::pair<::std::size_t, ::std::size_t>> m_edges;
::std::vector<::std::vector<::std::size_t>> m_graph;
::std::vector<::std::vector<::std::size_t>> m_rev_graph;
::std::vector<::std::size_t> m_vid2scc;
::std::vector<::std::vector<::std::size_t>> m_sccs;
::std::vector<::std::vector<::std::size_t>> m_edges_in_scc;
::std::vector<::std::vector<::std::pair<::std::size_t, ::std::vector<::std::size_t>>>> m_scc_graph;
::std::vector<::std::vector<::std::pair<::std::size_t, ::std::vector<::std::size_t>>>> m_rev_scc_graph;
bool m_built;
public:
scc_graph() = default;
scc_graph(const ::tools::scc_graph&) = default;
scc_graph(::tools::scc_graph&&) = default;
~scc_graph() = default;
::tools::scc_graph& operator=(const ::tools::scc_graph&) = default;
::tools::scc_graph& operator=(::tools::scc_graph&&) = default;
explicit scc_graph(const ::std::size_t n) : m_graph(n), m_rev_graph(n), m_vid2scc(n), m_built(false) {
}
::std::size_t size() const {
return this->m_graph.size();
}
::std::size_t add_edge(const ::std::size_t from, const ::std::size_t to) {
assert(from < this->size());
assert(to < this->size());
assert(!this->m_built);
const auto edge_id = this->m_edges.size();
this->m_edges.emplace_back(from, to);
this->m_graph[from].push_back(edge_id);
this->m_rev_graph[to].push_back(edge_id);
return edge_id;
}
::std::pair<::std::size_t, ::std::size_t> edge(const ::std::size_t i) const {
assert(i < this->m_edges.size());
return this->m_edges[i];
}
const ::std::vector<::std::size_t>& edges_from(const ::std::size_t i) const {
assert(i < this->size());
return this->m_graph[i];
}
const ::std::vector<::std::size_t>& edges_to(const ::std::size_t i) const {
assert(i < this->size());
return this->m_rev_graph[i];
}
void build() {
assert(!this->m_built);
::std::stack<::std::size_t> ordered_by_dfs;
{
::std::vector<bool> visited(this->size(), false);
::std::stack<::std::pair<bool, ::std::size_t>> stack;
for (::std::size_t i = this->size(); i --> 0;) {
stack.emplace(true, i);
}
while (!stack.empty()) {
const auto [pre, here] = stack.top();
stack.pop();
if (pre) {
if (visited[here]) continue;
visited[here] = true;
stack.emplace(false, here);
for (const auto e : this->m_graph[here]) {
const auto next = this->m_edges[e].second;
if (visited[next]) continue;
stack.emplace(true, next);
}
} else {
ordered_by_dfs.push(here);
}
}
}
{
::std::vector<bool> visited(this->size(), false);
while (!ordered_by_dfs.empty()) {
const auto root = ordered_by_dfs.top();
ordered_by_dfs.pop();
if (visited[root]) continue;
const auto scc_id = this->m_sccs.size();
this->m_sccs.emplace_back();
this->m_edges_in_scc.emplace_back();
this->m_scc_graph.emplace_back();
this->m_rev_scc_graph.emplace_back();
::std::stack<::std::size_t> stack({root});
while (!stack.empty()) {
const auto here = stack.top();
stack.pop();
if (visited[here]) continue;
visited[here] = true;
this->m_vid2scc[here] = scc_id;
this->m_sccs[scc_id].push_back(here);
for (const auto e : this->m_rev_graph[here]) {
const auto next = this->m_edges[e].first;
if (visited[next]) continue;
stack.push(next);
}
}
::std::vector<::std::size_t> buffer;
for (const auto v : this->m_sccs[scc_id]) {
for (const auto e : this->m_rev_graph[v]) {
const auto u = this->m_edges[e].first;
if (this->m_vid2scc[u] == this->m_vid2scc[v]) {
this->m_edges_in_scc[scc_id].push_back(e);
} else {
buffer.push_back(e);
}
}
}
::std::sort(buffer.begin(), buffer.end(), tools::less_by([&](const auto e) { return this->m_vid2scc[this->m_edges[e].first]; }));
for (::std::size_t l = 0, r = 0; l < buffer.size(); l = r) {
const auto u_scc_id = this->m_vid2scc[this->m_edges[buffer[l]].first];
this->m_rev_scc_graph[scc_id].emplace_back(u_scc_id, ::std::vector<::std::size_t>());
for (; r < buffer.size() && this->m_vid2scc[this->m_edges[buffer[l]].first] == this->m_vid2scc[this->m_edges[buffer[r]].first]; ++r);
for (::std::size_t i = l; i < r; ++i) {
this->m_rev_scc_graph[scc_id].back().second.push_back(buffer[i]);
}
}
}
for (::std::size_t v_scc_id = 0; v_scc_id < this->m_sccs.size(); ++v_scc_id) {
for (const auto& [u_scc_id, edge_ids] : this->m_rev_scc_graph[v_scc_id]) {
this->m_scc_graph[u_scc_id].emplace_back(v_scc_id, edge_ids);
}
}
}
this->m_built = true;
}
::std::size_t scc_id(const ::std::size_t i) const {
assert(i < this->size());
assert(this->m_built);
return this->m_vid2scc[i];
}
const ::std::vector<::std::vector<::std::size_t>>& sccs() const {
assert(this->m_built);
return this->m_sccs;
}
const ::std::vector<::std::size_t>& edges_in_scc(const ::std::size_t i) const {
assert(i < this->m_sccs.size());
assert(this->m_built);
return this->m_edges_in_scc[i];
}
const ::std::vector<::std::pair<::std::size_t, ::std::vector<::std::size_t>>>& edges_from_scc(const ::std::size_t i) const {
assert(i < this->m_sccs.size());
assert(this->m_built);
return this->m_scc_graph[i];
}
const ::std::vector<::std::pair<::std::size_t, ::std::vector<::std::size_t>>>& edges_to_scc(const ::std::size_t i) const {
assert(i < this->m_sccs.size());
assert(this->m_built);
return this->m_rev_scc_graph[i];
}
};
}
#line 5 "tests/scc_graph/sccs.test.cpp"
using ll = long long;
int main() {
std::cin.tie(nullptr);
std::ios_base::sync_with_stdio(false);
ll N, M;
std::cin >> N >> M;
tools::scc_graph graph(N);
for (ll i = 0; i < M; ++i) {
ll a, b;
std::cin >> a >> b;
graph.add_edge(a, b);
}
graph.build();
std::cout << graph.sccs().size() << '\n';
for (const auto& scc : graph.sccs()) {
std::cout << scc.size();
for (const auto v : scc) {
std::cout << ' ' << v;
}
std::cout << '\n';
}
return 0;
}
Test cases
| Env | Name | Status | Elapsed | Memory |
|---|---|---|---|---|
| g++ | example_00 |
AC |
5 ms | 4 MB |
| g++ | large_cycle_00 |
AC |
245 ms | 76 MB |
| g++ | max_random_00 |
AC |
703 ms | 197 MB |
| g++ | max_random_01 |
AC |
715 ms | 197 MB |
| g++ | max_random_02 |
AC |
714 ms | 198 MB |
| g++ | max_random_03 |
AC |
705 ms | 198 MB |
| g++ | max_random_04 |
AC |
707 ms | 198 MB |
| g++ | random_00 |
AC |
626 ms | 163 MB |
| g++ | random_01 |
AC |
585 ms | 174 MB |
| g++ | random_02 |
AC |
143 ms | 36 MB |
| g++ | random_03 |
AC |
161 ms | 92 MB |
| g++ | random_04 |
AC |
195 ms | 79 MB |