cp-documentation
This documentation is automatically generated by online-judge-tools/verification-helper
AtCoder Library Practice Contest - E MinCostFlow
(Test/Manual/practice2_e.test.cpp)
- View this file on GitHub
- Last update: 2024-01-04 02:51:07+09:00
- Problem: https://onlinejudge.u-aizu.ac.jp/courses/lesson/2/ITP1/1/ITP1_1_A
- Link: https://atcoder.jp/contests/practice2/submissions/49008995
知らなかったテクがあった。
最小費用流に帰着するが、最小費用最大流ではない( $NK$ 流すのが最適とは限らない )
こういう時はsourceからsinkに向けて容量無限、コスト $0$ の辺を張ると良い。
今回は最大化問題を最小化問題に変換するために(コストをマイナス1倍しており、負コストを解消するため)下駄を履かせているので、この辺にも下駄を履かせること
Depends on
- SuccessiveShortestPath (最小費用流、最短路反復法)
(Src/Graph/Flow/SuccessiveShortestPath.hpp)
- ioまわりの設定
(Src/Template/IOSetting.hpp)
- 標準データ型のエイリアス
(Src/Template/TypeAlias.hpp)
- Src/Utility/U32Pair.hpp
Code
#define PROBLEM "https://onlinejudge.u-aizu.ac.jp/courses/lesson/2/ITP1/1/ITP1_1_A"
#include "../../Src/Template/IOSetting.hpp"
#include "../../Src/Graph/Flow/SuccessiveShortestPath.hpp"
#include <iostream>
#include <string>
#include <vector>
/*
* AtCoder Library Practice Contest - E MinCostFlow
* https://atcoder.jp/contests/practice2/submissions/49008995
*/
void solve() {
using namespace zawa;
SetFastIO();
int n, k; std::cin >> n >> k;
SuccessiveShortestPath<int, long long> mcf(2 * n + 2);
int source{2 * n}, sink{2 * n + 1};
for (int i{} ; i < n ; i++) {
mcf.addEdge(source, i, k, 0);
mcf.addEdge(n + i, sink, k, 0);
}
const long long INF{(long long)1e9};
std::vector A(n, std::vector<int>(n));
std::vector id(n, std::vector<int>(n));
for (int i{} ; i < n ; i++) {
for (int j{} ; j < n ; j++) {
int a; std::cin >> a;
A[i][j] = a;
a = INF - a;
id[i][j] = mcf.addEdge(i, n + j, 1, a);
}
}
mcf.addEdge(source, sink, INF, INF);
assert(mcf.flow(source, sink, n * k));
std::vector S(n, std::string(n, '.'));
long long ans{};
for (int i{} ; i < n ; i++) {
for (int j{} ; j < n ; j++) {
if (mcf.flowed(id[i][j])) {
ans += A[i][j];
S[i][j] = 'X';
}
}
}
std::cout << ans << '\n';
for (int i{} ; i < n ; i++) {
std::cout << S[i] << '\n';
}
}
int main() {
#ifdef ATCODER
solve();
#else
std::cout << "Hello World" << '\n';
#endif
}#line 1 "Test/Manual/practice2_e.test.cpp"
#define PROBLEM "https://onlinejudge.u-aizu.ac.jp/courses/lesson/2/ITP1/1/ITP1_1_A"
#line 2 "Src/Template/IOSetting.hpp"
#line 2 "Src/Template/TypeAlias.hpp"
#include <cstdint>
#include <cstddef>
namespace zawa {
using i16 = std::int16_t;
using i32 = std::int32_t;
using i64 = std::int64_t;
using i128 = __int128_t;
using u8 = std::uint8_t;
using u16 = std::uint16_t;
using u32 = std::uint32_t;
using u64 = std::uint64_t;
using usize = std::size_t;
} // namespace zawa
#line 4 "Src/Template/IOSetting.hpp"
#include <iostream>
#include <iomanip>
namespace zawa {
void SetFastIO() {
std::cin.tie(nullptr)->sync_with_stdio(false);
}
void SetPrecision(u32 dig) {
std::cout << std::fixed << std::setprecision(dig);
}
} // namespace zawa
#line 2 "Src/Graph/Flow/SuccessiveShortestPath.hpp"
#line 2 "Src/Utility/U32Pair.hpp"
#line 4 "Src/Utility/U32Pair.hpp"
#include <functional>
#line 7 "Src/Utility/U32Pair.hpp"
namespace zawa {
class U32Pair {
private:
static constexpr u32 SHIFT{32};
static constexpr u32 MASK{static_cast<u32>((1LL << SHIFT) - 1)};
u64 value_{};
public:
constexpr U32Pair() {}
constexpr U32Pair(u32 first, u32 second) {
value_ = (static_cast<u64>(first) << SHIFT) | second;
}
constexpr u32 first() const noexcept {
return static_cast<u32>(value_ >> SHIFT);
}
constexpr u32 second() const noexcept {
return static_cast<u32>(value_ & MASK);
}
constexpr u64 combined() const noexcept {
return value_;
}
constexpr U32Pair& operator=(const U32Pair& rhs) {
value_ = rhs.value_;
return *this;
}
friend constexpr bool operator==(const U32Pair& lhs, const U32Pair& rhs) {
return lhs.value_ == rhs.value_;
}
friend constexpr bool operator!=(const U32Pair& lhs, const U32Pair& rhs) {
return lhs.value_ != rhs.value_;
}
friend constexpr bool operator<(const U32Pair& lhs, const U32Pair& rhs) {
return lhs.value_ < rhs.value_;
}
friend constexpr bool operator<=(const U32Pair& lhs, const U32Pair& rhs) {
return lhs.value_ <= rhs.value_;
}
friend constexpr bool operator>(const U32Pair& lhs, const U32Pair& rhs) {
return lhs.value_ > rhs.value_;
}
friend constexpr bool operator>=(const U32Pair& lhs, const U32Pair& rhs) {
return lhs.value_ >= rhs.value_;
}
friend std::ostream& operator<<(std::ostream& os, const U32Pair& pair) {
os << '(' << pair.first() << ',' << pair.second() << ')';
return os;
}
};
struct U32PairHash {
usize operator()(const U32Pair& pair) const noexcept {
return std::hash<u64>{}(pair.combined());
}
};
} // namespace zawa
#line 5 "Src/Graph/Flow/SuccessiveShortestPath.hpp"
#include <cassert>
#include <limits>
#include <queue>
#include <type_traits>
#include <utility>
#include <vector>
namespace zawa {
template <class Cap, class Cost>
class SuccessiveShortestPath {
public:
static_assert(std::is_signed_v<Cost>, U"Cost must be signed");
static constexpr Cost invalid{(std::numeric_limits<Cost>::max() >> 1) - 1};
static constexpr u32 reverseId(u32 i) noexcept {
return i ^ 1;
}
struct Edge {
u32 from{}, to{};
Cap residual{};
Cost cost{};
Edge() = default;
Edge(u32 from, u32 to, const Cap& cap, const Cost& cost)
: from{from}, to{to}, residual{cap}, cost{cost} {}
};
usize n_{}, m_{};
std::vector<Edge> edges_;
std::vector<std::vector<u32>> g_;
std::vector<Cost> dist_, potential_;
std::vector<U32Pair> prev_;
Cost mcf_{};
constexpr usize size() const noexcept {
return n_;
}
constexpr usize edgeSize() const noexcept {
return m_;
}
SuccessiveShortestPath() = default;
SuccessiveShortestPath(usize n, usize m = usize{})
: n_{n}, m_{}, edges_{}, g_(n), dist_(n), potential_(n), prev_(n), mcf_{} {
g_.shrink_to_fit();
dist_.shrink_to_fit();
potential_.shrink_to_fit();
prev_.shrink_to_fit();
edges_.reserve(2 * m);
}
void emplace(u32 from, u32 to, const Cap& cap, const Cost& cost) {
g_[from].emplace_back(m_);
edges_.emplace_back(from, to, cap, cost);
m_++;
}
u32 addEdge(u32 from, u32 to, const Cap& cap, const Cost& cost) {
assert(from < size());
assert(to < size());
u32 res{static_cast<u32>(m_)};
emplace(from, to, cap, cost);
emplace(to, from, Cap{}, -cost);
return res;
}
inline u32 from(u32 i) const noexcept {
return edges_[i].from;
}
inline u32 to(u32 i) const noexcept {
return edges_[i].to;
}
inline const Cap& residual(u32 i) const noexcept {
return edges_[i].residual;
}
inline const Cost& cost(u32 i) const noexcept {
return edges_[i].cost;
}
inline const Cap& flowed(u32 i) const noexcept {
assert(i < edgeSize());
return residual(i ^ 1);
}
inline const Cap& capcacity(u32 i) const noexcept {
assert(i < edgeSize());
return residual(i) + flowed(i);
}
inline Cost edgeCost(u32 i) const noexcept {
return potential_[from(i)] + cost(i) - potential_[to(i)];
}
bool relax(u32 i) {
if (residual(i) > 0 and dist_[to(i)] > dist_[from(i)] + edgeCost(i)) {
dist_[to(i)] = dist_[from(i)] + edgeCost(i);
prev_[to(i)] = U32Pair{from(i), i};
return true;
}
return false;
}
bool dijkstra(u32 s, u32 t) {
assert(s < size());
assert(t < size());
std::fill(dist_.begin(), dist_.end(), invalid);
dist_[s] = Cost{};
using qt = std::pair<Cost, u32>;
std::priority_queue<qt, std::vector<qt>, std::greater<qt>> que;
que.emplace(dist_[s], s);
while (que.size()) {
auto [d, v]{que.top()};
que.pop();
if (dist_[v] < d) continue;
for (u32 i : g_[v]) {
if (relax(i)) {
que.emplace(dist_[to(i)], to(i));
}
}
}
return dist_[t] < invalid;
}
bool dagdp(u32 s, u32 t) {
assert(s < size());
assert(t < size());
std::fill(dist_.begin(), dist_.end(), invalid);
dist_[s] = Cost{};
std::vector<u32> ord;
ord.reserve(size());
std::vector<bool> vis(size());
vis[s] = true;
ord.push_back(s);
for (u32 i{} ; i < ord.size() ; i++) {
u32 v{ord[i]};
for (auto e : g_[v]) {
if (!vis[to(e)]) {
ord.push_back(to(e));
vis[to(e)] = true;
}
relax(e);
}
}
return dist_[t] < invalid;
}
bool bellmanford(u32 s, u32 t) {
assert(s < size());
assert(t < size());
std::fill(dist_.begin(), dist_.end(), invalid);
dist_[s] = Cost{};
for (u32 i{} ; i + 1 < size() ; i++) {
for (u32 j{} ; j < edgeSize() ; j++) {
relax(j);
}
}
return dist_[t] < invalid;
}
void updatePotential() {
for (u32 v{} ; v < size() ; v++) {
potential_[v] = potential_[v] + (dist_[v] == invalid ? Cost{} : dist_[v]);
}
}
Cap flush(u32 s, u32 t, Cap up = std::numeric_limits<Cap>::max()) {
for (u32 v{t} ; v != s ; v = prev_[v].first()) {
up = std::min(up, residual(prev_[v].second()));
}
for (u32 v{t} ; v != s ; v = prev_[v].first()) {
edges_[prev_[v].second()].residual -= up;
edges_[prev_[v].second() ^ 1].residual += up;
}
return up;
}
bool flow(u32 s, u32 t, Cap flow) {
assert(s < size());
assert(t < size());
while (flow > 0 and dijkstra(s, t)) {
updatePotential();
Cap water{flush(s, t, flow)};
mcf_ += potential_[t] * water;
flow -= water;
}
return flow == 0;
}
Cap maxflow(u32 s, u32 t) {
assert(s < size());
assert(t < size());
Cap flow{};
while (dijkstra(s, t)) {
updatePotential();
Cap water{flush(s, t)};
mcf_ += potential_[t] * water;
flow += water;
}
return flow;
}
std::vector<Cost> slope(u32 s, u32 t) {
assert(s < size());
assert(t < size());
Cap flow{};
std::vector<Cost> res;
while (dijkstra(s, t)) {
updatePotential();
Cap water{flush(s, t)};
for (u32 i{} ; i < water ; i++) {
res.emplace_back(mcf_);
mcf_ += potential_[t];
flow++;
}
}
res.emplace_back(mcf_);
return res;
}
struct Line {
Cap dn{}, up{};
Cost slope{};
Line() = default;
Line(Cap dn, Cap up, Cost slope) : dn{dn}, up{up}, slope{slope} {}
};
std::vector<Line> slopeACL(u32 s, u32 t) {
assert(s < size());
assert(t < size());
Cap flow{};
std::vector<Line> res;
while (dijkstra(s, t)) {
updatePotential();
Cap water{flush(s, t)};
mcf_ += potential_[t] * water;
res.emplace_back(flow, flow + water, potential_[t]);
flow += water;
}
return res;
}
Cost minCost() const noexcept {
return mcf_;
}
};
} // namespace zawa
#line 5 "Test/Manual/practice2_e.test.cpp"
#line 7 "Test/Manual/practice2_e.test.cpp"
#include <string>
#line 9 "Test/Manual/practice2_e.test.cpp"
/*
* AtCoder Library Practice Contest - E MinCostFlow
* https://atcoder.jp/contests/practice2/submissions/49008995
*/
void solve() {
using namespace zawa;
SetFastIO();
int n, k; std::cin >> n >> k;
SuccessiveShortestPath<int, long long> mcf(2 * n + 2);
int source{2 * n}, sink{2 * n + 1};
for (int i{} ; i < n ; i++) {
mcf.addEdge(source, i, k, 0);
mcf.addEdge(n + i, sink, k, 0);
}
const long long INF{(long long)1e9};
std::vector A(n, std::vector<int>(n));
std::vector id(n, std::vector<int>(n));
for (int i{} ; i < n ; i++) {
for (int j{} ; j < n ; j++) {
int a; std::cin >> a;
A[i][j] = a;
a = INF - a;
id[i][j] = mcf.addEdge(i, n + j, 1, a);
}
}
mcf.addEdge(source, sink, INF, INF);
assert(mcf.flow(source, sink, n * k));
std::vector S(n, std::string(n, '.'));
long long ans{};
for (int i{} ; i < n ; i++) {
for (int j{} ; j < n ; j++) {
if (mcf.flowed(id[i][j])) {
ans += A[i][j];
S[i][j] = 'X';
}
}
}
std::cout << ans << '\n';
for (int i{} ; i < n ; i++) {
std::cout << S[i] << '\n';
}
}
int main() {
#ifdef ATCODER
solve();
#else
std::cout << "Hello World" << '\n';
#endif
}