# What exactly is augmenting path?

When talking about `computing network flows`, the Algorithm Design Manual says:

Traditional network flow algorithms are based on the idea of augmenting paths, and repeatedly finding a path of positive capacity from s to t and adding it to the flow. It can be shown that the flow through a network is optimal if and only if it contains no augmenting path.

I don't understand what is `augmenting paths`. I have googled, and found:

but they all reference to the quote above.

Can anyone please really clearly explain what is an `augmenting path`?

An augmenting path is a simple path - a path that does not contain cycles - through the graph using only edges with positive capacity from the source to the sink.

So the statement above is somehow obvious - if you can not find a path from the source to the sink that only uses positive capacity edges, then the flow can not be increased.

By the way the proof of that statement is not that easy.

Augmenting means increase-make larger. In a given flow network `G=(V,E)` and a flow `f` an augmenting path `p` is a simple path from `source s` to `sink t` in the residual network `Gf`. By the definition of `residual network`, we may increase the flow on an edge `(u,v)` of an augmenting path by up to a capacity `Cf(u,v)` without violating constraint, on whichever of `(u,v)` and `(v,u)` is in the original flow network `G`. Also the maximum amount by which we can increase the flow on each edge in an augmented path p is called the `residual capacity of p`. The proof can be found in the introduction to algorithms by thomas h. cormen etc...

And how do you find out the augmenting path from source to sink? Using modified version of BFS. You do BFS from source till you reach sink and you traverse an edge only if it has residual capacity (i.e. for that edge, its max capacity - current flow > 0). And for this path from source to sink, you maintain minimum residual capacity, which is the maximum flow you can pass through that path. High level code snippet to get the idea:

``````bool maxFlowAchieved = false;
int maxFlow = 0;  // keeps track of what is the max flow in the network
while(!maxFlowAchieved)
{
//BFS returns collection of Edges in the traversal order from source to sink
std::vector<Edge*> path = BFS(source, sink);
maxFlowAchieved = path.size() == 0;  // all paths exhausted
if(maxFlowAchieved)
break;
// traverse each edge in the path and find minimum residual capacity
// edge->residual = edge->maxCapacity - edge->currentflow
int allowedFlow = GetMinResidualOnPath(path);