#include <bits/stdc++.h>
using namespace std;
#define INF INT_MAX
#define NIL 0
const int nmax = 18;
class Edge{
public:
int i, j, cost;
Edge(int _i, int _j, int _cost) : i(_i), j(_j), cost(_cost){}
friend bool operator<(const Edge& e1, const Edge& e2) {
return e1.cost < e2.cost;
}
// util in ordonarea dupa cost
};
// o structura de tip muchie, utila in problema APM cand, aplicand algoritmul lui Kruskall
// avem nevoie sa sortam muchiile crescator dupa cost
struct parentRank {
int parent;
int rank;
};
class Disjoint {
public:
vector<parentRank> info;
Disjoint(int);
int findRep(int);
void reunion(int, int);
};
Disjoint::Disjoint(int n) {
info.resize(n + 1);
for(int i = 1; i <= n; ++i) {
info[i].parent = i;
info[i].rank = 0;
}
}
int Disjoint::findRep(int x) {
if(x == info[x].parent)
return x;
return info[x].parent = findRep(info[x].parent);
}
void Disjoint::reunion(int x, int y) {
int repX = this->findRep(x);
int repY = this->findRep(y);
if(info[repX].rank > info[repY].rank)
info[repX].parent = repY;
else
if(info[repX].rank < info[repY].rank)
info[repY].parent = repX;
else {
info[repX].rank++;
info[repY].parent = repX;
}
}
// in principiu util doar pt HavelHakimi
void countSort(vector<int>& input)
{
map<int, int> freq;
for (int x: input) {
freq[x]++;
}
int i = 0;
for (auto p: freq)
{
while (p.second--) {
input[i++] = p.first;
}
}
}
bool HavelHakimi(vector<int> d){
int n = d.size();
int sum = 0;
for(auto degree: d) {
if(degree > n - 1)
return false;
sum += degree;
}
while(d.size()){
countSort(d);
int biggest = d[0];
d.erase(d.begin());
for(int i = 0; i < biggest; ++i)
{
--d[i];
if(d[i] < 0){
return false;
}
}
}
return true;
}
int extractMin(priority_queue<pair<int, int>, vector<pair<int, int>>, greater<pair<int, int>>>& pq){
int temp = pq.top().second;
pq.pop();
return temp;
}
class Graph {
public:
int V;
int E;
vector<vector<pair<int, int>>> adj;
// lista de adiacenta a nodului 'n' e formata din perechi de tipul
// {vecin, cost}, unde cost = costul muchiei {n, vecin}.
// daca graful n-are costuri pe muchii cost = 0, deoarece un graf
// fara costuri pe muchii este un caz particular de graf cu costuri pe muhcii, unde toate costurile sunt = 0
Graph(int, int, vector<vector<pair<int, int>>>);
// constructorul care contine doar informatii de tipul
// 'graful este orientat/neorientat si are/n-are costuri pe muchii'
void build(int, int, vector<vector<pair<int, int>>>);
// metoda care - mi construieste graful, initializandu - i numarul de noduri si muchii
// dar si lista de adiacenta
void DFSUtil(int, vector<bool>&, vector<int>&);
// metoda ajutatoare pentru DFS, primeste ca parametrii nodul de unde incepe parcurgerea, vectorul care tine
// minte nodurile vizitate / nevizitate (pe care il modifica) si insula curenta (pe care o formeaza, fiind de asemenea
// transmisa prin referinta
vector<int> DFS(int, vector<bool>&);
// metoda care returneaza (intr-un vector) ordinea parcurgerii dfs incepand din nodul primit ca prim parametru.
// de asemenea primeste si un parametru de tip vector de bool (true / false) care modifica nodurile vizitate
// la parcurgerea curenta
int connectedComponents();
// metoda care - mi returneaza numarul de componente conexe dintr - un graf neorientat
pair<vector<int>, vector<int>> bfs(int src);
// returnez ordinea parcurgerii bfs, dar si
// un vector de distante minime. Amandoua sunt relevante
// si specifice parcurgerii in latime
void dfForTopoSort(int, vector<bool>&, stack<int>&);
// metoda df pentru sortare topologica, primeste ca argumente nodul de unde incepe aceasta parcurgere,
// vectorul de care tine minte pentru noduri daca sunt vizitate / nevizitate pe care il si actualizeaza
// si o stiva (pe care o construieste, fiind transmisa prin referinta) ce va contine nodurile in ordinea
// inversa a timpilor de finalizare
vector<int> topoSort();
// metoda care - mi returneaza un vector continand nodurile intr-o ordine de sortare topologica
void DFKosaraju(vector<vector<pair<int, int>>>, vector<vector<int>>&, int, vector<bool>&);
// DF util pentru Kosaraju, primeste lista de adiacenta a grafului transpus, lista componentelor conexe pe care o actualizeaza, fiind
// transmisa prin referinta, nodul de start al DF - ului si vectorul care contine informatii de tip vizitat / nevizitat despre noduri
// de asemenea transmis prin referinta pentru ca - l modifica
vector<vector<int>> Kosaraju();
// algoritmul lui Kosaraju, imi returneaza lista componentelor conexe, adica o lista de liste de noduri
vector<vector<int>> biconnectedComponents();
void dfBCC(int, vector<bool>&, vector<int>&, vector<int>&, vector<vector<int>>&, stack<pair<int, int>>&);
int diameter();
static vector<vector<int>> RoyFloyd(vector<vector<int>>&);
vector<int> Dijkstra();
pair<vector<Edge>, int> MSTKruskall();
vector<int> BellmanFord();
vector<int> EulerCircuit();
void dfEuler(int, vector<int>&, vector<vector<int>>&, vector<bool>&, vector<int>&, vector<int>&);
int minCostHamiltonianCircuit();
vector<pair<int, int>> hopcroftKarp(int N, int M);
bool bfsMatching(int N, int M, vector<int>&, vector<int>&, vector<int>&);
bool dfsMatching(int crt, int N, int M, vector<int>&, vector<int>&, vector<int>&);
int maxFlow();
bool bfsForMaxFlow(vector<int>&, vector<vector<int>>&, vector<vector<int>>&);
};
Graph::Graph(int _V, int _E, vector<vector<pair<int, int>>> _adj) : V (_V), E(_E), adj(_adj) {
}
void Graph::DFSUtil(int v, vector<bool>& vis, vector<int>& island){
for(auto i : adj[v]){
int ngb = i.first;
if(!(vis[ngb])) {
island.push_back(ngb);
vis[ngb] = true;
DFSUtil(ngb, vis, island);
}
}
}
vector<int> Graph::DFS(int src, vector<bool>& vis) {
// prin "island" returnez 'insula' obtinuta din parcurgerea dfs din nodul curent, adica in principiu
// nodurile din componenta sa conexa (in grafuri neorientate e mai intuitiv) si in ordinea dfs
vector<int> island;
DFSUtil(src, vis, island);
return island;
}
int Graph::connectedComponents() {
int nrIslands = 0;
vector<bool> vis;
vis.resize(V + 1, false);
for(int i = 1; i <= V; ++i) {
if(!vis[i]){
++nrIslands;
DFS(i, vis);
}
}
return nrIslands;
}
// returnez un vector al distantelor minime
// dar si un vector ce contine ordinea parcurgerii bfs
pair<vector<int>, vector<int>> Graph::bfs(int src) {
pair<vector<int>, vector<int>> toReturn;
queue<int> q;
q.push(src);
vector<int> bfsOrder;
vector<int> dist;
dist.resize(V + 1, -1);
q.push(src);
dist[src] = 0;
while(!(q.empty())){
int dad = q.front();
bfsOrder.push_back(dad);
q.pop();
for(auto i : adj[dad]) {
int ngb = i.first;
if(dist[ngb] == - 1){
dist[ngb] = dist[dad] + 1;
q.push(ngb);
}
}
}
toReturn.first = dist;
toReturn.second = bfsOrder;
return toReturn;
}
void Graph::dfForTopoSort(int src, vector<bool>& vis, stack<int>& st) {
for(auto i: adj[src]) {
int ngb = i.first;
if(vis[ngb] == false) {
vis[ngb] = true;
dfForTopoSort(ngb, vis, st);
}
}
st.push(src);
}
vector<int> Graph::topoSort(){
vector<bool> vis;
stack<int> st;
vis.resize(V + 1, false);
for(int i = 1; i <= V; ++i)
if(!vis[i]) {
vis[i] = true;
dfForTopoSort(i, vis, st);
}
vector<int> topoSorted;
while(st.size()) {
topoSorted.push_back(st.top());
st.pop();
}
return topoSorted;
}
void Graph::DFKosaraju(vector<vector<pair<int, int>>> adjT, vector<vector<int>>& sol, int node, vector<bool>& visT){
sol[sol.size() - 1].push_back(node);
visT[node] = true;
for(auto i: adjT[node]) {
int ngb = i.first;
if(visT[ngb] == false)
{
DFKosaraju(adjT, sol, ngb, visT);
}
}
}
vector<vector<int>> Graph::Kosaraju() {
vector<vector<pair<int, int>>> adjT;
adjT.resize(V + 1);
for(int i = 1; i <= V; ++i)
for(auto ngb : adj[i])
adjT[ngb.first].push_back(make_pair(i, 0));
vector<bool> visT;
vector<bool> vis;
visT.resize(V + 1, false);
vis.resize(V + 1, false);
stack<int> st;
vector<vector<int>> stronglyCC;
for(int i = 1; i <= V; ++i)
if(!vis[i])
{
vis[i] = true;
dfForTopoSort(i, vis, st);
// construim stiva specifica sortarii topologice
// adica cu nodurile in ordinea inversa a timpilor de finalizare
// e un pic impropriu sa vorbim despre sortare topologica si componente tare
// conexe in aceeasi problema deoarece exista unei componente tare conexe
// implica existenta unui ciclu, si stim ca grafurile care contin cicluri
// nu admit sortare topologica, dar alegerea nodurilor in ordinea inversa a
// timpilor de finalizare este valabila pentru ambele probleme
}
while(st.size())
{
stronglyCC.push_back(vector<int>());
while(st.size() && visT[st.top()] == true)
st.pop();
if(st.size())
{
int crt = st.top();
DFKosaraju(adjT, stronglyCC, crt, visT);
}
}
return stronglyCC;
}
vector<vector<int>> Graph::biconnectedComponents() {
vector<bool> vis;
vis.resize(V + 1, false);
vector<int> level;
level.resize(V + 1);
vector<int> minLevel;
minLevel.resize(V + 1);
vector<vector<int>> BCC;
stack<pair<int, int>> edges;
level[1] = 0;
dfBCC(1, vis, level, minLevel, BCC, edges);
return BCC;
}
void Graph::dfBCC(int crt, vector<bool>& vis, vector<int>& level, vector<int>& minLevel, vector<vector<int>>& BCC, stack<pair<int, int>>& edges) {
vis[crt] = true;
minLevel[crt] = level[crt];
for(auto i: adj[crt]) {
int ngb = i.first;
if(vis[ngb] == false) {
level[ngb] = level[crt] + 1;
edges.push(make_pair(crt, ngb));
dfBCC(ngb, vis, level, minLevel, BCC, edges);
if(minLevel[ngb] >= level[crt]) {
BCC.push_back(vector<int>());
BCC[BCC.size() - 1].push_back(crt);
while((edges.top().first == crt && edges.top().second == ngb) == false) {
BCC[BCC.size() - 1].push_back(edges.top().second);
edges.pop();
}
BCC[BCC.size() - 1].push_back(ngb);
edges.pop();
}
minLevel[crt] = min(minLevel[crt], minLevel[ngb]);
}
else if (level[crt] - level[ngb] >= 2)
minLevel[crt] = min(minLevel[crt], level[ngb]);
}
}
int Graph::diameter() {
vector<int> dst = (this->bfs(1)).first;
int maxDist = -1;
int maxDistVertex = 0;
for(int i = 1; i <= V; ++i)
if(dst[i] > maxDist) {
maxDist = dst[i];
maxDistVertex = i;
}
dst = (this->bfs(maxDistVertex)).first;
for(int i = 1; i <= V; ++i)
if(dst[i] > maxDist) {
maxDist = dst[i];
maxDistVertex = i;
}
return maxDist + 1;
}
vector<vector<int>> Graph::RoyFloyd(vector<vector<int>>& costMatrix) {
int N = costMatrix.size() - 1;
for(int k = 0; k < N; ++k)
// pana la pasul asta, am calculat distanta minima la i la j folosindu-ma de nodurile 0..k - 1 (DACA EXISTA!)
for(int i = 0; i < N; ++i)
for(int j = 0; j < N; ++j)
if((costMatrix[i][j] > costMatrix[i][k] + costMatrix[k][j] || (costMatrix[i][j] == 0 && i != j)) && (costMatrix[i][k] * costMatrix[k][j] != 0))
costMatrix[i][j] = costMatrix[i][k] + costMatrix[k][j];
return costMatrix;
}
vector<int> Graph::Dijkstra(){
priority_queue<pair<int, int>, vector<pair<int, int>>, greater<pair<int, int>>> pq; /// tine perechi de tip (cost, nod)
// min heap ce tine perechi de tipul {cost, nod}
vector<int> minDistances;
minDistances.resize(V + 1);
minDistances[1] = 0;
for(int i = 2; i <= V; ++i)
minDistances[i] = INF;
pq.push(make_pair(0, 1));
vector<bool> extractedBefore;
extractedBefore.resize(V + 1, false);
while(!(pq.empty())){
int crt = extractMin(pq);
if(extractedBefore[crt] == true)
continue;
extractedBefore[crt] = true;
for(auto i: adj[crt]){
int ngb = i.first;
int cost = i.second;
if(cost + minDistances[crt] < minDistances[ngb])
{
minDistances[ngb] = cost + minDistances[crt];
pq.push(make_pair(minDistances[ngb], ngb));
}
}
}
for(int i = 2; i <= V; ++i)
if(minDistances[i] == INF)
minDistances[i] = 0;
return minDistances;
}
pair<vector<Edge>, int> Graph::MSTKruskall() {
vector<Edge> mst;
vector<Edge> edges;
for(int i = 1; i <= V; ++i) {
int src = i;
for(int j = 0; j < adj[i].size(); ++j) {
int dest = adj[i][j].first;
int cost = adj[i][j].second;
if(src > dest) {
Edge tempEdge = Edge(src, dest, cost);
edges.push_back(tempEdge);
}
}
}
int total = 0;
sort(edges.begin(), edges.end());
Disjoint d(V);
int cnt = 0;
for(int i = 0; i < edges.size() && cnt <= E - 1; ++i) {
Edge tempEdge = edges[i];
if(d.findRep(edges[i].i) != d.findRep(edges[i].j)) {
++cnt;
mst.push_back(tempEdge);
d.reunion(tempEdge.i, tempEdge.j);
total += tempEdge.cost;
}
}
return make_pair(mst, total);
}
vector<int> Graph::BellmanFord() {
queue<int> q;
vector<bool> inQ;
inQ.resize(V + 1, false);
vector<int> minDistances;
minDistances.resize(V + 1, INF);
vector<int> cnt;
cnt.resize(V + 1, 0);
minDistances[1] = 0;
q.push(1);
inQ[1] = true;
while(!(q.empty())) {
int crt = q.front();
q.pop();
inQ[crt] = false;
for(auto i: adj[crt]){
int ngb = i.first;
int cost = i.second;
if(minDistances[crt] + cost < minDistances[ngb]){
minDistances[ngb] = minDistances[crt] + cost;
if(inQ[ngb] == false)
{ q.push(ngb);
inQ[ngb] = true;
++cnt[ngb];
if(cnt[ngb] > V)
{
// dau o dimensiune imposibila ca sa fie clar ca e situatie speciala (CICLU NEGATIV)
minDistances.resize(V + 2, -1);
return minDistances;
}
}
}
}
}
return minDistances;
}
vector<int> Graph::EulerCircuit() {
vector<int> L;
vector<int> R;
vector<bool> used;
used.resize(E + 1, false);
vector<vector<int>> adjEdges;
adjEdges.resize(V + 1);
L.resize(E + 1);
R.resize(E + 1);
int cnt = 0;
for(int i = 1; i <= V; ++i)
for(auto j : adj[i]) {
int ngb = j.first;
adjEdges[i].push_back(++cnt);
adjEdges[ngb].push_back(cnt);
L[cnt] = i;
R[cnt] = ngb;
}
for(int i = 1; i <= V; ++i) {
if(adjEdges[i].size() % 2) {
vector<int> err;
err.resize(V + 2, -1);
return err;
}
}
/*for(int i = 1; i <= V; ++i) {
cout << i << ": ";
for(int j = 0; j < adjEdges[i].size(); ++j)
cout << adjEdges[i][j] << ' ';
cout << '\n';
}*/
vector<int> circuit;
dfEuler(1, circuit, adjEdges, used, L, R);
circuit.pop_back();
return circuit;
}
void Graph::dfEuler(int crt, vector<int>& circuit, vector<vector<int>>& adjEdges, vector<bool>& used, vector<int>& L, vector<int>& R) {
while(adjEdges[crt].size()) {
int e = adjEdges[crt].back();
adjEdges[crt].pop_back();
if(used[e] == false) {
used[e] = true;
int other = crt ^ L[e] ^ R[e];
dfEuler(other, circuit, adjEdges, used, L, R);
}
}
circuit.push_back(crt);
}
int Graph::minCostHamiltonianCircuit() {
int minCost[1 << nmax + 5][nmax], costMatrix[nmax][nmax];
for (int i = 0; i < V; ++i)
for (int j = 0; j < V; ++j)
costMatrix[i][j] = INF / 2;
for(int i = 0; i < V; ++i) {
for(auto j: adj[i]){
int ngb = j.first;
int cost = j.second;
costMatrix[i][ngb] = cost;
}
}
int pow = 1 << V;
for (int i = 0; i < pow ;++i)
for (int j = 0; j < V; ++j)
minCost[i][j]= INF / 2;
minCost[1][0]=0;
for (int i = 0; i < pow; ++i)
for (int j = 0; j < V; ++j)
if ((i & (1 << j)))
for (int intermediar = 0; intermediar < V; ++intermediar)
if (intermediar != j && (i & (1 << intermediar)))
minCost[i][j] = min(minCost[i ^ (1 << j)][intermediar] + costMatrix[intermediar][j], minCost[i][j]);
int minimum = minCost[pow - 1][0];
for (int i = 1; i < V; ++i) {
if(minCost[pow - 1][i] + costMatrix[i][0] < minimum)
minimum = minCost[pow - 1][i] + costMatrix[i][0];
}
return minimum;
}
vector<pair<int, int>> Graph::hopcroftKarp(int N, int M) {
vector<int> L, R, dist;
L.resize(N + 1);
R.resize(M + 1);
dist.resize(N + 1);
for(int i = 0; i <= N; ++i)
L[i] = NIL;
for(int i = 0; i <= M; ++i)
R[i] = NIL;
int matching = 0;
while(bfsMatching(N, M, dist, L, R)) {
for(int i = 1; i <= N; ++i)
if(L[i] == NIL && dfsMatching(i, N, M, dist, L, R))
++matching;
}
vector<pair<int, int>> matches;
for(int i = 1; i <= N; ++i) {
if(L[i] != NIL)
matches.push_back(make_pair(i, L[i]));
}
return matches;
}
bool Graph::bfsMatching(int N, int M, vector<int>& dist, vector<int>& L, vector<int>& R) {
queue<int> q;
for(int i = 1; i <= N; ++i) {
if(L[i] == NIL) {
dist[i] = 0;
q.push(i);
}
else
dist[i] = INF;
}
dist[NIL] = INF;
while(q.empty() == false) {
int crt = q.front();
q.pop();
if(dist[crt] < dist[NIL]) {
for(auto i: adj[crt]) {
int ngb = i.first;
if(dist[R[ngb]] == INF) {
dist[R[ngb]] = dist[crt] + 1;
q.push(R[ngb]);
}
}
}
}
return (dist[NIL] != INF);
}
bool Graph::dfsMatching(int crt, int N, int M, vector<int>& dist, vector<int>& L, vector<int>& R) {
if(crt != NIL) {
for(auto i: adj[crt]) {
int ngb = i.first;
if(dist[R[ngb]] == dist[crt] + 1) {
if(dfsMatching(R[ngb], N, M, dist, L, R)) {
R[ngb] = crt;
L[crt] = ngb;
return true;
}
}
}
dist[crt] = INF;
return false;
}
return true;
}
bool Graph::bfsForMaxFlow(vector<int>& dad, vector<vector<int>>& capacity, vector<vector<int>>& f) {
vector<bool> vis;
vis.resize(V + 1, false);
dad.resize(V + 1, 0);
queue<int> q;
q.push(1);
vis[1] = true;
while(q.empty() == false) {
int crt = q.front();
q.pop();
for(auto i: adj[crt]) {
int ngb = i.first;
if(vis[ngb] == false && capacity[crt][ngb] > f[crt][ngb]) {
q.push(ngb);
vis[ngb] = true;
dad[ngb] = crt;
if(ngb == V)
return true;
}
}
}
return false;
}
int Graph::maxFlow() {
vector<vector<int>> capacity;
vector<vector<int>> f;
capacity.resize(V + 1);
for(int i = 0; i <= V; ++i)
capacity[i].resize(V + 1, 0);
f.resize(V + 1);
for(int i = 0; i <= V; ++i)
f[i].resize(V + 1, 0);
vector<int> dad;
dad.resize(V + 1, 0);
int flow = 0;
for(int i = 1; i <= V; ++i)
for(auto j: adj[i]) {
int ngb = j.first;
int cap = j.second;
capacity[i][ngb] = cap;
}
while(bfsForMaxFlow(dad, capacity, f)) {
int i = INT_MAX;
int crt = V;
while(crt != 1) {
i = min(i, capacity[dad[crt]][crt] - f[dad[crt]][crt]);
crt = dad[crt];
}
crt = V;
while(crt != 1) {
f[dad[crt]][crt] += i;
f[crt][dad[crt]] -= i;
crt = dad[crt];
}
flow += i;
}
return flow;
}
int main()
{
/*
// problema dfs pe pe infoarena
// https://www.infoarena.ro/problema/dfs
ifstream fin("dfs.in");
ofstream fout("dfs.out");
int v, e;
fin >> v >> e;
vector<vector<pair<int, int>>> adj;
adj.resize(v + 1);
Graph g(undirected, unweighted);
for(int i = 1; i <= e; ++i) {
int src, dst;
fin >> src >> dst;
adj[src].push_back(make_pair(dst, 0));
adj[dst].push_back(make_pair(src, 0));
}
g.build(v, e, adj);
fout << g.connectedComponents();
*/
// problema bfs de pe infoarena
// https://www.infoarena.ro/problema/bfs
/*
// problema Sortare topologica de pe infoarena
// https://www.infoarena.ro/problema/sortaret
ifstream fin("sortaret.in");
ofstream fout("sortaret.out");
int v, e, start;
Graph g(directed, unweighted);
vector<vector<pair<int, int>>> adj;
fin >> v >> e;
adj.resize(v + 1);
for(int i = 1; i <= e; ++i) {
int src, dst;
fin >> src >> dst;
adj[src].push_back(make_pair(dst, 0));
}
g.build(v, e, adj);
vector<int> topoOrder = g.topoSort();
for(auto v: topoOrder)
fout << v << ' ';
fout << '\n';
*/
/* pentru HavelHakimi, in vectorul 'forHavelHakimi'
punem secventa de numere despre care vrem sa vedem
daca poate reprezenta secventa gradelor unui graf
vector<int> forHavelHakimi = {1, 2, 1};
cout << HavelHakimi(forHavelHakimi);
*/
/*
*/
/*
ifstream fin("ctc.in");
ofstream fout("ctc.out");
int v, e;
vector<vector<pair<int, int>>> adj;
fin >> v >> e;
adj.resize(v + 1);
for(int i = 1; i <= e; ++i) {
int src, dst;
fin >> src >> dst;
adj[src].push_back(make_pair(dst, 0));
}
Graph g(v, e, adj);
vector<vector<int>> SOL = g.Kosaraju();
fout << SOL.size() - 1 << '\n';
for(int i = 0; i < SOL.size(); ++i)
{
for(int j = 0; j < SOL[i].size(); ++j)
fout << SOL[i][j] << ' ';
fout << '\n';
}
*/
/*
ifstream fin("biconex.in");
ofstream fout("biconex.out");
int v, e;
vector<vector<pair<int, int>>> adj;
fin >> v >> e;
adj.resize(v + 5);
for(int i = 1; i <= e; ++i) {
int src, dst;
fin >> src >> dst;
adj[src].push_back(make_pair(dst, 0));
adj[dst].push_back(make_pair(src, 0));
}
Graph g(v, e, adj);
vector<vector<int>> SOL = g.biconnectedComponents();
fout << SOL.size() << '\n';
for(int i = 0; i < SOL.size(); ++i) {
for(int j = 0; j < SOL[i].size(); ++j)
fout << SOL[i][j] << ' ';
fout << '\n';
}
*/
/*
ifstream fin("darb.in");
ofstream fout("darb.out");
int v, e; vector<vector<pair<int, int>>> adj;
fin >> v;
e = v - 1;
adj.resize(v + 1);
for(int i = 1; i <= v - 1; ++i) {
int src, dst;
fin >> src >> dst;
adj[src].push_back(make_pair(dst, 0));
adj[dst].push_back(make_pair(src, 0));
}
Graph g(v, e, adj);
fout << g.diameter();
*/
/*
ifstream fin("dijkstra.in");
ofstream fout("dijkstra.out");
int v, e;
vector<vector<pair<int, int>>> adj;
fin >> v >> e;
adj.resize(v + 1);
for(int i = 1; i <= e; ++i) {
int dst, src, cost;
fin >> src >> dst >> cost;
adj[src].push_back(make_pair(dst, cost));
}
Graph g(v, e, adj);
vector<int> minDistances = g.Dijkstra();
for(int i = 2; i < minDistances.size(); ++i)
fout << minDistances[i] << ' ';
fout << '\n';
*/
/*
ifstream fin("apm.in");
ofstream fout("apm.out");
int V, E;
fin >> V >> E;
Disjoint d(V);
vector<vector<pair<int, int>>> adj;
adj.resize(V + 1);
for(int i = 1; i <= E; ++i) {
int x, y, c;
fin >> x >> y >> c;
adj[x].push_back(make_pair(y, c));
adj[y].push_back(make_pair(x, c));
}
Graph g(V, E, adj);
pair<vector<Edge>, int> edgesCost = g.MSTKruskall();
vector<Edge> edges = edgesCost.first;
int cost = edgesCost.second;
fout << cost << '\n';
fout << edges.size() << '\n';
for(auto edge: edges) {
fout << edge.i << ' ' << edge.j << '\n';
}
*/
/*
ifstream fin("bellmanford.in");
ofstream fout("bellmanford.out");
int V, E;
fin >> V >> E;
vector<vector<pair<int, int>>> adj;
adj.resize(V + 1);
for(int i = 1; i <= E; ++i) {
int src, dst, cost;
fin >> src >> dst >> cost;
adj[src].push_back(make_pair(dst, cost));
}
Graph g(V, E, adj);
vector<int> minDistances = g.BellmanFord();
if(minDistances.size() == V + 2)
{fout << "Ciclu negativ!\n"; return 0;}
for(int i = 2; i <= V; ++i)
fout << minDistances[i] << ' ';
fout << '\n';
*/
/*
ifstream fin("ciclueuler.in");
ofstream fout("ciclueuler.out");
int V, E;
vector<vector<pair<int, int>>> adj;
fin >> V >> E;
adj.resize(V + 1);
// nu am neaparat nevoie de lista de adiacenta in forma asta
// dar o fac ca sa fie in spiritul clasei
for(int i = 1; i <= E; ++i) {
int src, dst;
fin >> src >> dst;
adj[src].push_back(make_pair(dst, 0));
}
Graph g(V, E, adj);
vector<int> circuit = g.EulerCircuit();
for(int i = 0; i < circuit.size(); ++i) {
fout << circuit[i] << ' ';
}
*/
/*
ifstream fin("hamilton.in");
ofstream fout("hamilton.out");
int v, e;
vector<vector<pair<int, int>>> adj;
fin >> v >> e;
adj.resize(v + 5);
for(int i = 1; i <= e; ++i) {
int src, dst, cost;
fin >> src >> dst >> cost;
adj[src].push_back(make_pair(dst, cost));
}
Graph g(v, e, adj);
int minimum = g.minCostHamiltonianCircuit();
if(minimum == INF / 2)
fout << "Nu exista solutie\n";
else
fout << minimum << '\n';
*/
/*
ifstream fin("cuplaj.in");
ofstream fout("cuplaj.out");
// Aceasta problema are structura destul de diferita de restul,
// fiind vorba de un graf bipartit, dar o voi pastra
int N, M, E;
fin >> N >> M >> E;
vector<vector<pair<int, int>>> adj;
adj.resize(N + 5);
for(int i = 1; i <= E; ++i) {
int src, dst;
fin >> src >> dst;
adj[src].push_back(make_pair(dst, 0));
}
Graph g(N, E, adj);
vector<pair<int, int>> matches;
matches = g.hopcroftKarp(N, M);
fout << matches.size() << '\n';
for(auto match: matches) {
fout << match.first << ' ' << match.second << '\n';
}
*/
ifstream fin("maxflow.in");
ofstream fout("maxflow.out");
int V, E;
vector<vector<pair<int, int>>> adj;
fin >> V >> E;
adj.resize(V + 1);
for(int i = 1; i <= E; ++i) {
int src, dst, capacity;
fin >> src >> dst >> capacity;
// desi putin impropriu, aici in lista de adicenta
// tin perechi de tipul {vecin, capacitate}
adj[src].push_back(make_pair(dst, capacity));
adj[dst].push_back(make_pair(src, capacity));
}
Graph g(V, E, adj);
int maxFlow = g.maxFlow();
fout << maxFlow << '\n';
return 0;
}
Alex Oporanu oporanu.alex