Struct swc_fast_graph::digraph::FastGraphMap

pub struct FastGraphMap<N, E, Ty> { /* private fields */ }

GraphMap<N, E, Ty> is a graph datastructure using an associative array of its node weights N.

It uses an combined adjacency list and sparse adjacency matrix representation, using O(|V| + |E|) space, and allows testing for edge existence in constant time.

GraphMap is parameterized over:

• Associated data N for nodes and E for edges, called weights.
• The node weight N must implement Copy and will be used as node identifier, duplicated into several places in the data structure. It must be suitable as a hash table key (implementing Eq + Hash). The node type must also implement Ord so that the implementation can order the pair (a, b) for an edge connecting any two nodes a and b.
• E can be of arbitrary type.
• Edge type Ty that determines whether the graph edges are directed or undirected.

You can use the type aliases UnGraphMap and DiGraphMap for convenience.

GraphMap does not allow parallel edges, but self loops are allowed.

Depends on crate feature graphmap (default).

Implementations

impl<N, E, Ty> FastGraphMap<N, E, Ty>where
    N: NodeTrait,
    Ty: EdgeType,

pub fn new() -> Self

Create a new GraphMap

pub fn with_capacity(nodes: usize, edges: usize) -> Self

Create a new GraphMap with estimated capacity.

pub fn capacity(&self) -> (usize, usize)

Return the current node and edge capacity of the graph.

pub fn is_directed(&self) -> bool

Whether the graph has directed edges.

pub fn from_edges<I>(iterable: I) -> Selfwhere
    I: IntoIterator,
    I::Item: IntoWeightedEdge<E, NodeId = N>,

Create a new GraphMap from an iterable of edges.

Node values are taken directly from the list. Edge weights E may either be specified in the list, or they are filled with default values.

Nodes are inserted automatically to match the edges.

use petgraph::graphmap::UnGraphMap;

// Create a new undirected GraphMap.
// Use a type hint to have `()` be the edge weight type.
let gr = UnGraphMap::<_, ()>::from_edges(&[
    (0, 1), (0, 2), (0, 3),
    (1, 2), (1, 3),
    (2, 3),
]);

pub fn node_count(&self) -> usize

Return the number of nodes in the graph.

pub fn edge_count(&self) -> usize

Return the number of edges in the graph.

pub fn clear(&mut self)

Remove all nodes and edges

pub fn add_node(&mut self, n: N) -> N

Add node n to the graph.

pub fn remove_node(&mut self, n: N) -> bool

Return true if node n was removed.

Computes in O(V) time, due to the removal of edges with other nodes.

pub fn contains_node(&self, n: N) -> bool

Return true if the node is contained in the graph.

pub fn add_edge(&mut self, a: N, b: N, weight: E) -> Option<E>

Add an edge connecting a and b to the graph, with associated data weight. For a directed graph, the edge is directed from a to b.

Inserts nodes a and/or b if they aren’t already part of the graph.

Return None if the edge did not previously exist, otherwise, the associated data is updated and the old value is returned as Some(old_weight).

// Create a GraphMap with directed edges, and add one edge to it
use petgraph::graphmap::DiGraphMap;

let mut g = DiGraphMap::new();
g.add_edge("x", "y", -1);
assert_eq!(g.node_count(), 2);
assert_eq!(g.edge_count(), 1);
assert!(g.contains_edge("x", "y"));
assert!(!g.contains_edge("y", "x"));

pub fn remove_edge(&mut self, a: N, b: N) -> Option<E>

Remove edge from a to b from the graph and return the edge weight.

Return None if the edge didn’t exist.

// Create a GraphMap with undirected edges, and add and remove an edge.
use petgraph::graphmap::UnGraphMap;

let mut g = UnGraphMap::new();
g.add_edge("x", "y", -1);

let edge_data = g.remove_edge("y", "x");
assert_eq!(edge_data, Some(-1));
assert_eq!(g.edge_count(), 0);

pub fn contains_edge(&self, a: N, b: N) -> bool

Return true if the edge connecting a with b is contained in the graph.

pub fn nodes(&self) -> Nodes<'_, N>

Return an iterator over the nodes of the graph.

Iterator element type is N.

pub fn neighbors(&self, a: N) -> Neighbors<'_, N, Ty>

Return an iterator of all nodes with an edge starting from a.

• Directed: Outgoing edges from a.
• Undirected: All edges from or to a.

Produces an empty iterator if the node doesn’t exist.
Iterator element type is N.

pub fn neighbors_directed(
    &self,
    a: N,
    dir: Direction
) -> NeighborsDirected<'_, N, Ty>

Return an iterator of all neighbors that have an edge between them and a, in the specified direction. If the graph’s edges are undirected, this is equivalent to .neighbors(a).

• Directed, Outgoing: All edges from a.
• Directed, Incoming: All edges to a.
• Undirected: All edges from or to a.

Produces an empty iterator if the node doesn’t exist.
Iterator element type is N.

pub fn edges(&self, from: N) -> Edges<'_, N, E, Ty>

Return an iterator of target nodes with an edge starting from a, paired with their respective edge weights.

• Directed: Outgoing edges from a.
• Undirected: All edges from or to a.

Produces an empty iterator if the node doesn’t exist.
Iterator element type is (N, &E).

pub fn edge_weight(&self, a: N, b: N) -> Option<&E>

Return a reference to the edge weight connecting a with b, or None if the edge does not exist in the graph.

pub fn edge_weight_mut(&mut self, a: N, b: N) -> Option<&mut E>

Return a mutable reference to the edge weight connecting a with b, or None if the edge does not exist in the graph.

pub fn all_edges(&self) -> AllEdges<'_, N, E, Ty>

Return an iterator over all edges of the graph with their weight in arbitrary order.

Iterator element type is (N, N, &E)

pub fn all_edges_mut(&mut self) -> AllEdgesMut<'_, N, E, Ty>

Return an iterator over all edges of the graph in arbitrary order, with a mutable reference to their weight.

Iterator element type is (N, N, &mut E)

pub fn into_graph<Ix>(self) -> Graph<N, E, Ty, Ix>where
    Ix: IndexType,

Return a Graph that corresponds to this GraphMap.

1. Note that node and edge indices in the Graph have nothing in common with the GraphMaps node weights N. The node weights N are used as node weights in the resulting Graph, too.
2. Note that the index type is user-chosen.

Computes in O(|V| + |E|) time (average).

Panics if the number of nodes or edges does not fit with the resulting graph’s index type.

Trait Implementations

impl<N: Clone, E: Clone, Ty: Clone> Clone for FastGraphMap<N, E, Ty>

fn clone(&self) -> FastGraphMap<N, E, Ty>

Returns a copy of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl<N: Eq + Hash + Debug, E: Debug, Ty: EdgeType> Debug for FastGraphMap<N, E, Ty>

fn fmt(&self, f: &mut Formatter<'_>) -> Result

Formats the value using the given formatter.

impl<N, E, Ty> Default for FastGraphMap<N, E, Ty>where
    N: NodeTrait,
    Ty: EdgeType,

Create a new empty GraphMap.

fn default() -> Self

Returns the “default value” for a type.

impl<N, E, Ty, Item> Extend<Item> for FastGraphMap<N, E, Ty>where
    Item: IntoWeightedEdge<E, NodeId = N>,
    N: NodeTrait,
    Ty: EdgeType,

Extend the graph from an iterable of edges.

Nodes are inserted automatically to match the edges.

fn extend<I>(&mut self, iterable: I)where
    I: IntoIterator<Item = Item>,

Extends a collection with the contents of an iterator.

fn extend_one(&mut self, item: A)

🔬This is a nightly-only experimental API. (extend_one)

Extends a collection with exactly one element.

fn extend_reserve(&mut self, additional: usize)

🔬This is a nightly-only experimental API. (extend_one)

Reserves capacity in a collection for the given number of additional elements.

impl<N, E, Ty, Item> FromIterator<Item> for FastGraphMap<N, E, Ty>where
    Item: IntoWeightedEdge<E, NodeId = N>,
    N: NodeTrait,
    Ty: EdgeType,

Create a new GraphMap from an iterable of edges.

fn from_iter<I>(iterable: I) -> Selfwhere
    I: IntoIterator<Item = Item>,

Creates a value from an iterator.

impl<N, E, Ty> GraphBase for FastGraphMap<N, E, Ty>where
    N: Copy + PartialEq,

type EdgeId = (N, N)

edge identifier

type NodeId = N

node identifier

impl<'a, N: 'a, E, Ty> IntoNeighbors for &'a FastGraphMap<N, E, Ty>where
    N: Copy + Ord + Hash,
    Ty: EdgeType,

type Neighbors = Neighbors<'a, N, Ty>

fn neighbors(self, n: Self::NodeId) -> Self::Neighbors

Return an iterator of the neighbors of node a.

impl<'a, N: 'a, E, Ty> IntoNeighborsDirected for &'a FastGraphMap<N, E, Ty>where
    N: Copy + Ord + Hash,
    Ty: EdgeType,

type NeighborsDirected = NeighborsDirected<'a, N, Ty>

fn neighbors_directed(self, n: N, dir: Direction) -> Self::NeighborsDirected

impl<'a, N, E: 'a, Ty> IntoNodeIdentifiers for &'a FastGraphMap<N, E, Ty>where
    N: NodeTrait,
    Ty: EdgeType,

type NodeIdentifiers = NodeIdentifiers<'a, N, E, Ty>

fn node_identifiers(self) -> Self::NodeIdentifiers

impl<N, E, Ty> NodeCount for FastGraphMap<N, E, Ty>where
    N: Copy + PartialEq,

fn node_count(&self) -> usize

impl<N, E, Ty> NodeIndexable for FastGraphMap<N, E, Ty>where
    N: NodeTrait,
    Ty: EdgeType,

fn node_bound(&self) -> usize

Return an upper bound of the node indices in the graph (suitable for the size of a bitmap).

fn to_index(&self, ix: Self::NodeId) -> usize

Convert a to an integer index.

fn from_index(&self, ix: usize) -> Self::NodeId

Convert i to a node index. i must be a valid value in the graph.

impl<N, E, Ty> Visitable for FastGraphMap<N, E, Ty>where
    N: Copy + Ord + Hash,
    Ty: EdgeType,

type Map = HashSet<N, RandomState>

The associated map type

fn visit_map(&self) -> AHashSet<N>

Create a new visitor map

fn reset_map(&self, map: &mut Self::Map)

Reset the visitor map (and resize to new size of graph if needed)