Struct petgraph::visit::Dfs [−] [src]

pub struct Dfs<N, VM> {
    pub stack: Vec<N>,
    pub discovered: VM,
}

Visit nodes of a graph in a depth-first-search (DFS) emitting nodes in preorder (when they are first discovered).

The traversal starts at a given node and only traverses nodes reachable from it.

Dfs is not recursive.

Dfs does not itself borrow the graph, and because of this you can run a traversal over a graph while still retaining mutable access to it, if you use it like the following example:

use petgraph::Graph;
use petgraph::visit::Dfs;

let mut graph = Graph::<_,()>::new();
let a = graph.add_node(0);

let mut dfs = Dfs::new(&graph, a);
while let Some(nx) = dfs.next(&graph) {
    // we can access `graph` mutably here still
    graph[nx] += 1;
}

assert_eq!(graph[a], 1);

Note: The algorithm may not behave correctly if nodes are removed during iteration. It may not necessarily visit added nodes or edges.

Fields

stack: Vec<N>

The stack of nodes to visit

discovered: VM

The map of discovered nodes

Methods

`impl<N, VM> Dfs<N, VM> where N: Copy + PartialEq, VM: VisitMap<N>,`
[src]

`pub fn new<G>(graph: G, start: N) -> Self where G: GraphRef + Visitable<NodeId = N, Map = VM>,`
[src]

Create a new Dfs, using the graph's visitor map, and put start in the stack of nodes to visit.

`pub fn from_parts(stack: Vec<N>, discovered: VM) -> Self`
[src]

Create a Dfs from a vector and a visit map

`pub fn reset<G>(&mut self, graph: G) where G: GraphRef + Visitable<NodeId = N, Map = VM>,`
[src]

Clear the visit state

`pub fn empty<G>(graph: G) -> Self where G: GraphRef + Visitable<NodeId = N, Map = VM>,`
[src]

Create a new Dfs using the graph's visitor map, and no stack.

`pub fn move_to(&mut self, start: N)`
[src]

Keep the discovered map, but clear the visit stack and restart the dfs from a particular node.

`pub fn next<G>(&mut self, graph: G) -> Option<N> where G: IntoNeighbors<NodeId = N>,`
[src]

Return the next node in the dfs, or None if the traversal is done.

Trait Implementations

`impl<N: Clone, VM: Clone> Clone for Dfs<N, VM>`
[src]

`fn clone(&self) -> Dfs<N, VM>`
[src]

Returns a copy of the value. Read more

`fn clone_from(&mut self, source: &Self)`
1.0.0
[src]

Performs copy-assignment from source. Read more

`impl<N: Debug, VM: Debug> Debug for Dfs<N, VM>`
[src]

`fn fmt(&self, __arg_0: &mut Formatter) -> Result`
[src]

Formats the value using the given formatter. Read more

`impl<G> Walker<G> for Dfs<G::NodeId, G::Map> where G: IntoNeighbors + Visitable,`
[src]

`type Item = G::NodeId`

`fn walk_next(&mut self, context: G) -> Option<Self::Item>`
[src]

Advance to the next item

ⓘImportant traits for WalkerIter<W, C>
Important traits for WalkerIter<W, C>
`impl<W, C> Iterator for WalkerIter<W, C> where W: Walker<C>, C: Clone, type Item = W::Item;`
`fn iter(self, context: Context) -> WalkerIter<Self, Context> where Self: Sized, Context: Clone,`
[src]

Create an iterator out of the walker and given context.

Struct petgraph::visit::Dfs [−] [src]

Fields

Methods

impl<N, VM> Dfs<N, VM> where N: Copy + PartialEq, VM: VisitMap<N>, [src]

pub fn new<G>(graph: G, start: N) -> Self where G: GraphRef + Visitable<NodeId = N, Map = VM>, [src]

pub fn from_parts(stack: Vec<N>, discovered: VM) -> Self[src]

pub fn reset<G>(&mut self, graph: G) where G: GraphRef + Visitable<NodeId = N, Map = VM>, [src]

pub fn empty<G>(graph: G) -> Self where G: GraphRef + Visitable<NodeId = N, Map = VM>, [src]

pub fn move_to(&mut self, start: N)[src]

pub fn next<G>(&mut self, graph: G) -> Option<N> where G: IntoNeighbors<NodeId = N>, [src]

Trait Implementations

impl<N: Clone, VM: Clone> Clone for Dfs<N, VM>[src]

fn clone(&self) -> Dfs<N, VM>[src]

fn clone_from(&mut self, source: &Self)1.0.0[src]

impl<N: Debug, VM: Debug> Debug for Dfs<N, VM>[src]

fn fmt(&self, __arg_0: &mut Formatter) -> Result[src]

impl<G> Walker<G> for Dfs<G::NodeId, G::Map> where G: IntoNeighbors + Visitable, [src]

type Item = G::NodeId

fn walk_next(&mut self, context: G) -> Option<Self::Item>[src]

ⓘImportant traits for WalkerIter<W, C>Important traits for WalkerIter<W, C>impl<W, C> Iterator for WalkerIter<W, C> where W: Walker<C>, C: Clone, type Item = W::Item;fn iter(self, context: Context) -> WalkerIter<Self, Context> where Self: Sized, Context: Clone, [src]

Important traits for WalkerIter<W, C>