Алгоритм Форда-Фалкерсона: различия между версиями
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| (не показана 1 промежуточная версия этого же участника) | |||
| Строка 1: | Строка 1: | ||
class Graph { | class Graph { | ||
struct Edge { | struct Edge { | ||
int a, b, capacity, flow; | int a, b, capacity, flow = 0; | ||
Edge(int a, int b, int capacity) : | Edge(int a, int b, int capacity) : | ||
a(a), b(b), capacity(capacity | a(a), b(b), capacity(capacity) {} | ||
int other(int v) const { | int other(int v) const { | ||
| Строка 14: | Строка 14: | ||
} | } | ||
void addFlowTo(int v, int | void addFlowTo(int v, int deltaFlow) { | ||
flow += (v == b ? | flow += (v == b ? deltaFlow : -deltaFlow); | ||
} | } | ||
}; | }; | ||
vector<Edge> edges; | vector<Edge> edges; | ||
vector<vector<int>> | vector<vector<int>> graph; | ||
vector<bool> visited; | vector<bool> visited; | ||
vector<int> edgeTo; | vector<int> edgeTo; | ||
| Строка 26: | Строка 26: | ||
void dfs(int v) { | void dfs(int v) { | ||
visited[v] = 1; | visited[v] = 1; | ||
for (int e : | for (int e : graph[v]) { | ||
int to = edges[e].other(v); | int to = edges[e].other(v); | ||
if (!visited[to] && edges[e].capacityTo(to) | if (!visited[to] && edges[e].capacityTo(to)) { | ||
edgeTo[to] = e; | edgeTo[to] = e; | ||
dfs(to); | dfs(to); | ||
| Строка 35: | Строка 35: | ||
} | } | ||
bool hasPath(int | bool hasPath(int start, int finish) { | ||
visited.assign(visited.size(), 0); | |||
dfs( | dfs(start); | ||
return visited[ | return visited[finish]; | ||
} | } | ||
int bottleneckCapacity(int | int bottleneckCapacity(int start, int finish) { | ||
int bCapacity = 1e9; | int bCapacity = 1e9; | ||
for (int v = | for (int v = finish; v != start; v = edges[edgeTo[v]].other(v)) | ||
bCapacity = min(bCapacity, edges[edgeTo[v]].capacityTo(v)); | bCapacity = min(bCapacity, edges[edgeTo[v]].capacityTo(v)); | ||
return bCapacity; | return bCapacity; | ||
} | } | ||
void addFlow(int | void addFlow(int start, int finish, int deltaFlow) { | ||
for (int v = | for (int v = finish; v != start; v = edges[edgeTo[v]].other(v)) | ||
edges[edgeTo[v]].addFlowTo(v, | edges[edgeTo[v]].addFlowTo(v, deltaFlow); | ||
} | } | ||
public: | public: | ||
Graph(int vertexCount) | Graph(int vertexCount) : | ||
graph(vertexCount), visited(vertexCount), edgeTo(vertexCount) {} | |||
void addEdge(int from, int to, int capacity) { | void addEdge(int from, int to, int capacity) { | ||
edges.push_back(Edge(from, to, capacity)); | edges.push_back(Edge(from, to, capacity)); | ||
graph[from].push_back(edges.size() - 1); | |||
graph[to].push_back(edges.size() - 1); | |||
} | } | ||
long long maxFlow(int | long long maxFlow(int start, int finish) { | ||
long long flow = 0; | long long flow = 0; | ||
while (hasPath( | while (hasPath(start, finish)) { | ||
int deltaFlow = bottleneckCapacity( | int deltaFlow = bottleneckCapacity(start, finish); | ||
addFlow( | addFlow(start, finish, deltaFlow); | ||
flow += deltaFlow; | flow += deltaFlow; | ||
} | } | ||
Текущая версия от 13:23, 1 июля 2023
class Graph {
struct Edge {
int a, b, capacity, flow = 0;
Edge(int a, int b, int capacity) :
a(a), b(b), capacity(capacity) {}
int other(int v) const {
return v == a ? b : a;
}
int capacityTo(int v) const {
return v == b ? capacity - flow : flow;
}
void addFlowTo(int v, int deltaFlow) {
flow += (v == b ? deltaFlow : -deltaFlow);
}
};
vector<Edge> edges;
vector<vector<int>> graph;
vector<bool> visited;
vector<int> edgeTo;
void dfs(int v) {
visited[v] = 1;
for (int e : graph[v]) {
int to = edges[e].other(v);
if (!visited[to] && edges[e].capacityTo(to)) {
edgeTo[to] = e;
dfs(to);
}
}
}
bool hasPath(int start, int finish) {
visited.assign(visited.size(), 0);
dfs(start);
return visited[finish];
}
int bottleneckCapacity(int start, int finish) {
int bCapacity = 1e9;
for (int v = finish; v != start; v = edges[edgeTo[v]].other(v))
bCapacity = min(bCapacity, edges[edgeTo[v]].capacityTo(v));
return bCapacity;
}
void addFlow(int start, int finish, int deltaFlow) {
for (int v = finish; v != start; v = edges[edgeTo[v]].other(v))
edges[edgeTo[v]].addFlowTo(v, deltaFlow);
}
public:
Graph(int vertexCount) :
graph(vertexCount), visited(vertexCount), edgeTo(vertexCount) {}
void addEdge(int from, int to, int capacity) {
edges.push_back(Edge(from, to, capacity));
graph[from].push_back(edges.size() - 1);
graph[to].push_back(edges.size() - 1);
}
long long maxFlow(int start, int finish) {
long long flow = 0;
while (hasPath(start, finish)) {
int deltaFlow = bottleneckCapacity(start, finish);
addFlow(start, finish, deltaFlow);
flow += deltaFlow;
}
return flow;
}
};
Ссылки
Теория:
- algs4.cs.princeton.edu — 6.4 Maximum Flow
- neerc.ifmo.ru/wiki — Алгоритм Форда-Фалкерсона
- Brilliant.org — Ford-Fulkerson Algorithm
Демонстрация:
Код:
- CodeLibrary — Maximum flow. Ford-Fulkerson alogithm in O(V^2 * FLOW)
- Algos — Ford-Fulkerson maxflow
- algs4.cs.princeton.edu/code — capacitated edge with flow, capacitated network, maxflow–mincut (несмотря на название, используется алгоритм Эдмондса-Карпа)
Задачи: