graph/complement.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2019 The Gonum Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package graph

 // Complement provides the complement of a graph. The complement will not include
 // self-edges, and edges within the complement will not hold any information other
 // than the nodes in the original graph and the connection topology. Nodes returned
 // by the Complement directly or via queries to returned Edges will be those stored
 // in the original graph.
 type Complement struct {
 	Graph
 }

 // Edge returns the edge from u to v if such an edge exists and nil otherwise.
 // The node v must be directly reachable from u as defined by the From method.
 func (g Complement) Edge(uid, vid int64) Edge {
 	if g.Graph.Edge(uid, vid) != nil || uid == vid {
 		return nil
 	}
 	u := g.Node(uid)
 	v := g.Node(vid)
 	if u == nil || v == nil {
 		return nil
 	}
 	return shadow{F: u, T: v}
 }

 // From returns all nodes in g that can be reached directly from u in
 // the complement.
 func (g Complement) From(uid int64) Nodes {
 	if g.Node(uid) == nil {
 		return Empty
 	}
 	// At this point, we guarantee that g.Graph.From(uid) returns a set of
 	// nodes in g.Nodes(), and that uid corresponds to a node in g.Nodes().
 	return newNodeFilterIterator(g.Nodes(), g.Graph.From(uid), uid)
 }

 // HasEdgeBetween returns whether an edge exists between nodes x and y.
 func (g Complement) HasEdgeBetween(xid, yid int64) bool {
 	return xid != yid &&
 		g.Node(xid) != nil && g.Node(yid) != nil &&
 		!g.Graph.HasEdgeBetween(xid, yid)
 }

 // shadow is an edge that is not exposed to the user.
 type shadow struct{ F, T Node }

 func (e shadow) From() Node         { return e.F }
 func (e shadow) To() Node           { return e.T }
 func (e shadow) ReversedEdge() Edge { return shadow{F: e.T, T: e.F} }

 // nodeFilterIterator combines Nodes to produce a single stream of
 // filtered nodes.
 type nodeFilterIterator struct {
 	src Nodes

 	// filter indicates the node in n with the key ID should be filtered out.
 	filter map[int64]bool
 }

 // newNodeFilterIterator returns a new nodeFilterIterator. The nodes in filter and
 // the nodes corresponding the root node ID must be in the src set of nodes. This
 // invariant is not checked.
 func newNodeFilterIterator(src, filter Nodes, root int64) *nodeFilterIterator {
 	n := nodeFilterIterator{src: src, filter: map[int64]bool{root: true}}
 	for filter.Next() {
 		n.filter[filter.Node().ID()] = true
 	}
 	filter.Reset()
 	n.src.Reset()
 	return &n
 }

 func (n *nodeFilterIterator) Len() int {
 	return n.src.Len() - len(n.filter)
 }

 func (n *nodeFilterIterator) Next() bool {
 	for n.src.Next() {
 		if !n.filter[n.src.Node().ID()] {
 			return true
 		}
 	}
 	return false
 }

 func (n *nodeFilterIterator) Node() Node {
 	return n.src.Node()
 }

 func (n *nodeFilterIterator) Reset() {
 	n.src.Reset()
 }
	// Copyright ©2019 The Gonum Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package graph

	// Complement provides the complement of a graph. The complement will not include
	// self-edges, and edges within the complement will not hold any information other
	// than the nodes in the original graph and the connection topology. Nodes returned
	// by the Complement directly or via queries to returned Edges will be those stored
	// in the original graph.
	type Complement struct {
	Graph
	}

	// Edge returns the edge from u to v if such an edge exists and nil otherwise.
	// The node v must be directly reachable from u as defined by the From method.
	func (g Complement) Edge(uid, vid int64) Edge {
	if g.Graph.Edge(uid, vid) != nil \|\| uid == vid {
	return nil
	}
	u := g.Node(uid)
	v := g.Node(vid)
	if u == nil \|\| v == nil {
	return nil
	}
	return shadow{F: u, T: v}
	}

	// From returns all nodes in g that can be reached directly from u in
	// the complement.
	func (g Complement) From(uid int64) Nodes {
	if g.Node(uid) == nil {
	return Empty
	}
	// At this point, we guarantee that g.Graph.From(uid) returns a set of
	// nodes in g.Nodes(), and that uid corresponds to a node in g.Nodes().
	return newNodeFilterIterator(g.Nodes(), g.Graph.From(uid), uid)
	}

	// HasEdgeBetween returns whether an edge exists between nodes x and y.
	func (g Complement) HasEdgeBetween(xid, yid int64) bool {
	return xid != yid &&
	g.Node(xid) != nil && g.Node(yid) != nil &&
	!g.Graph.HasEdgeBetween(xid, yid)
	}

	// shadow is an edge that is not exposed to the user.
	type shadow struct{ F, T Node }

	func (e shadow) From() Node { return e.F }
	func (e shadow) To() Node { return e.T }
	func (e shadow) ReversedEdge() Edge { return shadow{F: e.T, T: e.F} }

	// nodeFilterIterator combines Nodes to produce a single stream of
	// filtered nodes.
	type nodeFilterIterator struct {
	src Nodes

	// filter indicates the node in n with the key ID should be filtered out.
	filter map[int64]bool
	}

	// newNodeFilterIterator returns a new nodeFilterIterator. The nodes in filter and
	// the nodes corresponding the root node ID must be in the src set of nodes. This
	// invariant is not checked.
	func newNodeFilterIterator(src, filter Nodes, root int64) *nodeFilterIterator {
	n := nodeFilterIterator{src: src, filter: map[int64]bool{root: true}}
	for filter.Next() {
	n.filter[filter.Node().ID()] = true
	}
	filter.Reset()
	n.src.Reset()
	return &n
	}

	func (n *nodeFilterIterator) Len() int {
	return n.src.Len() - len(n.filter)
	}

	func (n *nodeFilterIterator) Next() bool {
	for n.src.Next() {
	if !n.filter[n.src.Node().ID()] {
	return true
	}
	}
	return false
	}

	func (n *nodeFilterIterator) Node() Node {
	return n.src.Node()
	}

	func (n *nodeFilterIterator) Reset() {
	n.src.Reset()
	}