# Dinic algorithm implementation and a spoj puzzle

I am trying to solve this problem on http://www.spoj.com/problems/FASTFLOW/

I suppose dinic's algorithm is suitable for this problem. But it runs in O(E.V^2) time which is too slow for this problem in the worst case. Any suggestions for a different algorithm or for improving the running time of this algorithm?

EDIT: I am including my implementation of dinic's algorithm. Apparently, it contains some mistake...Could anyone give some test case or help in debugging the logic of program.

``````//#define DEBUG       //comment when you have to disable all debug macros.
#define NDEBUG    //comment when all assert statements have to be disabled.
#include <iostream>
#include <cstring>
#include <sstream>
#include <cstdlib>
#include <cstdio>
#include <cmath>
#include <vector>
#include <set>
#include <map>
#include <bitset>
#include <climits>
#include <ctime>
#include <algorithm>
#include <functional>
#include <stack>
#include <queue>
#include <list>
#include <deque>
#include <sys/time.h>
#include <iomanip>
#include <cstdarg>
#include <utility> //std::pair
#include <cassert>
#define tr(c,i) for(typeof(c.begin()) i = (c).begin(); i != (c).end(); i++)
#define present(c,x) ((c).find(x) != (c).end())
#define all(x) x.begin(), x.end()
#define pb push_back
#define mp make_pair
#define log2(x) (log(x)/log(2))
#define ARRAY_SIZE(arr) (1[&arr]-arr)
#define INDEX(arr,elem)        (lower_bound(all(arr),elem)-arr.begin())
#define lld long long int
#define MOD 1000000007
#define gcd __gcd
#define equals(a,b) (a.compareTo(b)==0)    //for strings only
using namespace std;

#ifdef DEBUG
#define debug(args...)            {dbg,args; cerr<<endl;}
#else
#define debug(args...)              // Just strip off all debug tokens
#endif

struct debugger
{
template<typename T> debugger& operator , (const T& v)
{
cerr<<v<<" ";
return *this;
}

}dbg;

/**********************************MAIN CODE***************************************************/

//runs in O(V^2E) time.
//might consider using a 1-d array of size V*V for large values of V

vector<vector<lld> > flow, capacity, level_graph;
lld V;

void init(lld v)
{
V=v;
flow.resize(V+1);
capacity.resize(V+1);
level_graph.resize(V+1);
for(lld i=0;i<=V;i++)
flow[i].resize(V+1), capacity[i].resize(V+1), level_graph[i].resize(V+1);
}

void add_edge(lld u, lld v, lld uv, lld vu=0)
{
capacity[u][v]=uv;
capacity[v][u]=vu;
flow[u][v]=uv;             //will store the present capacity. facility for the residual graph
flow[v][u]=vu;
}

void update_residual_graph(lld source, lld destination, lld *parent)        //push augment flow in the residual graph and modify the latter.
{
lld i=destination, aug=LLONG_MAX;
while(parent[i]!=-2)
{
//debug(i);
aug=min(aug,flow[parent[i]][i]);
i=parent[i];
}
i=destination;
while(parent[i]!=-2)
{
flow[parent[i]][i]-=aug;
flow[i][parent[i]]=capacity[parent[i]][i]-flow[parent[i]][i];
i=parent[i];
}
}

bool DFS(lld source, lld destination)
{
stack<lld> state;
bool visited[V+1], present;
lld parent[V+1],t;
memset(visited, false, sizeof(visited));
memset(parent, -1, sizeof(parent));
parent[source]=-2;
state.push(source);
visited[source]=true;
while(!state.empty())
{
t=state.top();
present=false;
{
parent[*it]=t;
if(!visited[*it] && level_graph[t][*it])
{
present=true;
state.push(*it);
visited[*it]=true;
if(*it==destination)
update_residual_graph(source,destination,parent);   //update residual graph
}

}
if(!present)
state.pop();
}
return parent[destination]!=-1;
}

bool BFS(lld source, lld destination)
{
//create level graph usign BFS
fill(level_graph.begin(), level_graph.end(), vector<lld>(V+1,-1));
lld i,j;
for(i=1;i<=V;i++)

queue<lld> state;
lld level[V+1],t;      //record of minimum distance from source
memset(level,-1, sizeof(level));
state.push(source);
level[source]=0;
while(!state.empty())
{
t=state.front();
state.pop();
{
if((level[*it]==-1 && flow[t][*it]) || (level[*it]==level[t]+1))
{
level_graph[t][*it]=flow[t][*it];
level[*it]=level[t]+1;
state.push(*it);
}
}
}
if(level[destination]==-1)
return false;

//call DFS and update the residual graph
return DFS(source,destination);

}

lld maximum_flow(lld source, lld destination)
{
while(BFS(source,destination));
lld max_flow=0;
max_flow+=flow[*it][source];
return max_flow;
}

int main()
{
lld e,u,v,n,c;
//cout<<"V:"<<endl;
cin>>n>>e;
init(n);

cout<<maximum_flow(1,n)<<endl;

}
``````
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