Fastest data structure for residual graphs

I am trying to implement a flow algorithm with thousands of nodes and edges, therefore I need efficient data structures. Currently I do the following:

Structure Node:

``````Double Linked Array (Parents) //Edges that enter the node (basicaly a tuple that contains a pointer to the parent node and the weight, current flow of the edge
Double Linked Array (Sons) //Edges that leave the node
``````

The problem is, when I perform a BFS, given a node v I need to look at the edges in the residual graph (basically backwards edges for the edges you send flow on), that leave v. Because I can have parallel edges I need to always know which backwards edge comes from which forward edge.

Currently I am solving the problem by first handling all edges in Sons(v), and then I defined a map that gives me the index of the Parents(w) in the destination node w of all those edges. Therefore I get the backwards edge I stored and can perform my algorithm. However those maps have log(E) access time which slows my algorithm down way too much. How should I approach this problem (the double linked lists are implemented as std::vector)?

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The representation I use is something like an edge list but with additional information

``````typedef long long dintype;
struct edge{
edge(int t_ = 0,int n_ = 0, dintype c_ = 0){
to = t_;
next = n_;
cap = c_;
}
int to,next;
dintype cap;
};
const int max_edges = 131010;
const int max_nodes = 16010;
edge e[max_edges];
int first[max_nodes]; // initialize this array with -1
int edges_num;
inline void add_edge(int from,int to, dintype cap){
if(edges_num == 0){
memset(first,-1,sizeof(first));
}
e[edges_num].to = to;e[edges_num].cap = cap;
e[edges_num].next = first[from];first[from] = edges_num++;

e[edges_num].to = from;e[edges_num].cap = 0;
e[edges_num].next = first[to];first[to] = edges_num++;
}
``````

I have used global arrays to be able to explain the idea better. I use this for my dinitz algorithm.

Now a bit of explanation. In the array "e" I hold all the edges. In the array first[v] I hold the index of the first edge going out of v in the array e. If an edge is present in index idx in the array e then the reverse edge is stored in the element with index idx^1. So this representation enables us to both have a neighbours list(strarting from first[v] and following the next index until it becomes -1) and be able to access the reverse edge in constant time.

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``````int src,snk,nnode,nedge;
int fin[100000],dist[100000];//nodes
int cap[100000],next[100000],to[100000];
void init(int s,int sn,int n)
{
src=s,snk=sn,nnode=n,nedge=0;
memset(fin,-1,sizeof(fin));
}
{
to[nedge]=v,cap[nedge]=c,next[nedge]=fin[u],fin[u]=nedge++;
to[nedge]=u,cap[nedge]=0,next[nedge]=fin[v],fin[v]=nedge++;
}
bool bfs()
{
int e,u,v;
memset(dist,-1,sizeof(dist));
dist[src]=0;
queue<int> q;
q.push(src);
while(!q.empty())
{
u=q.front();
q.pop();
for(e=fin[u];e>=0;e=next[e])
{
v=to[e];
if(cap[e]>0&&dist[v]==-1)
{
dist[v]=dist[u]+1;
q.push(v);
}
}
}
if(dist[snk]==-1)
return false;
else
return true;
}
int dfs(int u,int flow)
{
if(u==snk)
return flow;
int e,v,df;
for(e=fin[u];e>=0;e=next[e])
{
v=to[e];
if(cap[e]>0&&dist[v]==dist[u]+1)
{
df=dfs(v,min(cap[e],flow));
if(df>0)
{
cap[e]-=df;
cap[e^1]+=df;
return df;
}
}
}
return 0;
}
int dinitz()
{
int ans=0;
int df,i;
while(bfs())
{
while(1)
{
df=dfs(src,INT_MAX);
if(df>0)
ans+=df;
else
break;
}
}
return ans;
}
``````

This is my code for dinitz algorithm here init function initializes the adjacency list add adds a new edge in the list,fin gives the last node in that adjacency list so u can access all the elements in the list through following loop

``````for(e=fin[u];e>=0;e=next[e])
{
v=to[e];
}
``````

where u is the node whose adjacent element u want to find v will give the adjacent element to u also while finding the max flow u need both forward edge and backward edge so suppose the forward edge is e then the backward edge will be e^1 and vice versa, but for that the starting index for the edges should be zero

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