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store.go
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store.go
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package graph
import (
"fmt"
"sync"
)
// Store represents a storage for vertices and edges. The graph library provides an in-memory store
// by default and accepts any Store implementation to work with - for example, an SQL store.
//
// When implementing your own Store, make sure the individual methods and their behavior adhere to
// this documentation. Otherwise, the graphs aren't guaranteed to behave as expected.
type Store[K comparable, T any] interface {
// AddVertex should add the given vertex with the given hash value and vertex properties to the
// graph. If the vertex already exists, it is up to you whether ErrVertexAlreadyExists or no
// error should be returned.
AddVertex(hash K, value T, properties VertexProperties) error
// Vertex should return the vertex and vertex properties with the given hash value. If the
// vertex doesn't exist, ErrVertexNotFound should be returned.
Vertex(hash K) (T, VertexProperties, error)
// RemoveVertex should remove the vertex with the given hash value. If the vertex doesn't
// exist, ErrVertexNotFound should be returned. If the vertex has edges to other vertices,
// ErrVertexHasEdges should be returned.
RemoveVertex(hash K) error
// ListVertices should return all vertices in the graph in a slice.
ListVertices() ([]K, error)
// VertexCount should return the number of vertices in the graph. This should be equal to the
// length of the slice returned by ListVertices.
VertexCount() (int, error)
// AddEdge should add an edge between the vertices with the given source and target hashes.
//
// If either vertex doesn't exit, ErrVertexNotFound should be returned for the respective
// vertex. If the edge already exists, ErrEdgeAlreadyExists should be returned.
AddEdge(sourceHash, targetHash K, edge Edge[K]) error
// UpdateEdge should update the edge between the given vertices with the data of the given
// Edge instance. If the edge doesn't exist, ErrEdgeNotFound should be returned.
UpdateEdge(sourceHash, targetHash K, edge Edge[K]) error
// RemoveEdge should remove the edge between the vertices with the given source and target
// hashes.
//
// If either vertex doesn't exist, it is up to you whether ErrVertexNotFound or no error should
// be returned. If the edge doesn't exist, it is up to you whether ErrEdgeNotFound or no error
// should be returned.
RemoveEdge(sourceHash, targetHash K) error
// Edge should return the edge joining the vertices with the given hash values. It should
// exclusively look for an edge between the source and the target vertex, not vice versa. The
// graph implementation does this for undirected graphs itself.
//
// Note that unlike Graph.Edge, this function is supposed to return an Edge[K], i.e. an edge
// that only contains the vertex hashes instead of the vertices themselves.
//
// If the edge doesn't exist, ErrEdgeNotFound should be returned.
Edge(sourceHash, targetHash K) (Edge[K], error)
// ListEdges should return all edges in the graph in a slice.
ListEdges() ([]Edge[K], error)
// EdgeCount should return the number of edges in the graph. This should be equal to the
// length of the slice returned by ListEdges.
EdgeCount() (int, error)
}
type memoryStore[K comparable, T any] struct {
lock sync.RWMutex
vertices map[K]T
vertexProperties map[K]VertexProperties
// outEdges and inEdges store all outgoing and ingoing edges for all vertices. For O(1) access,
// these edges themselves are stored in maps whose keys are the hashes of the target vertices.
outEdges map[K]map[K]Edge[K] // source -> target
inEdges map[K]map[K]Edge[K] // target -> source
edgeCount int
}
func newMemoryStore[K comparable, T any]() Store[K, T] {
return &memoryStore[K, T]{
vertices: make(map[K]T),
vertexProperties: make(map[K]VertexProperties),
outEdges: make(map[K]map[K]Edge[K]),
inEdges: make(map[K]map[K]Edge[K]),
}
}
func (s *memoryStore[K, T]) AddVertex(k K, t T, p VertexProperties) error {
s.lock.Lock()
defer s.lock.Unlock()
if _, ok := s.vertices[k]; ok {
return ErrVertexAlreadyExists
}
s.vertices[k] = t
s.vertexProperties[k] = p
return nil
}
func (s *memoryStore[K, T]) ListVertices() ([]K, error) {
s.lock.RLock()
defer s.lock.RUnlock()
hashes := make([]K, 0, len(s.vertices))
for k := range s.vertices {
hashes = append(hashes, k)
}
return hashes, nil
}
func (s *memoryStore[K, T]) VertexCount() (int, error) {
s.lock.RLock()
defer s.lock.RUnlock()
return len(s.vertices), nil
}
func (s *memoryStore[K, T]) Vertex(k K) (T, VertexProperties, error) {
s.lock.RLock()
defer s.lock.RUnlock()
v, ok := s.vertices[k]
if !ok {
return v, VertexProperties{}, ErrVertexNotFound
}
p := s.vertexProperties[k]
return v, p, nil
}
func (s *memoryStore[K, T]) RemoveVertex(k K) error {
s.lock.RLock()
defer s.lock.RUnlock()
if _, ok := s.vertices[k]; !ok {
return ErrVertexNotFound
}
if edges, ok := s.inEdges[k]; ok {
if len(edges) > 0 {
return ErrVertexHasEdges
}
delete(s.inEdges, k)
}
if edges, ok := s.outEdges[k]; ok {
if len(edges) > 0 {
return ErrVertexHasEdges
}
delete(s.outEdges, k)
}
delete(s.vertices, k)
delete(s.vertexProperties, k)
return nil
}
func (s *memoryStore[K, T]) AddEdge(sourceHash, targetHash K, edge Edge[K]) error {
s.lock.Lock()
defer s.lock.Unlock()
if _, ok := s.outEdges[sourceHash]; !ok {
s.outEdges[sourceHash] = make(map[K]Edge[K])
}
s.outEdges[sourceHash][targetHash] = edge
if _, ok := s.inEdges[targetHash]; !ok {
s.inEdges[targetHash] = make(map[K]Edge[K])
}
s.inEdges[targetHash][sourceHash] = edge
s.edgeCount++
return nil
}
func (s *memoryStore[K, T]) UpdateEdge(sourceHash, targetHash K, edge Edge[K]) error {
s.lock.Lock()
defer s.lock.Unlock()
targetEdges, ok := s.outEdges[sourceHash]
if !ok {
return ErrEdgeNotFound
}
_, ok = targetEdges[targetHash]
if !ok {
return ErrEdgeNotFound
}
s.outEdges[sourceHash][targetHash] = edge
s.inEdges[targetHash][sourceHash] = edge
return nil
}
func (s *memoryStore[K, T]) RemoveEdge(sourceHash, targetHash K) error {
s.lock.Lock()
defer s.lock.Unlock()
delete(s.inEdges[targetHash], sourceHash)
delete(s.outEdges[sourceHash], targetHash)
s.edgeCount--
return nil
}
func (s *memoryStore[K, T]) Edge(sourceHash, targetHash K) (Edge[K], error) {
s.lock.RLock()
defer s.lock.RUnlock()
sourceEdges, ok := s.outEdges[sourceHash]
if !ok {
return Edge[K]{}, ErrEdgeNotFound
}
edge, ok := sourceEdges[targetHash]
if !ok {
return Edge[K]{}, ErrEdgeNotFound
}
return edge, nil
}
func (s *memoryStore[K, T]) EdgeCount() (int, error) {
s.lock.RLock()
defer s.lock.RUnlock()
return s.edgeCount, nil
}
func (s *memoryStore[K, T]) ListEdges() ([]Edge[K], error) {
s.lock.RLock()
defer s.lock.RUnlock()
res := make([]Edge[K], 0, s.edgeCount)
for _, edges := range s.outEdges {
for _, edge := range edges {
res = append(res, edge)
}
}
return res, nil
}
// CreatesCycle is a fastpath version of [CreatesCycle] that avoids calling
// [PredecessorMap], which generates large amounts of garbage to collect.
//
// Because CreatesCycle doesn't need to modify the PredecessorMap, we can use
// inEdges instead to compute the same thing without creating any copies.
func (s *memoryStore[K, T]) CreatesCycle(source, target K) (bool, error) {
s.lock.RLock()
defer s.lock.RUnlock()
if _, ok := s.vertices[source]; !ok {
return false, fmt.Errorf("could not get vertex with hash %v", source)
}
if _, ok := s.vertices[target]; !ok {
return false, fmt.Errorf("could not get vertex with hash %v", target)
}
if source == target {
return true, nil
}
stack := newStack[K]()
visited := make(map[K]struct{})
stack.push(source)
for !stack.isEmpty() {
currentHash, _ := stack.pop()
if _, ok := visited[currentHash]; !ok {
// If the adjacent vertex also is the target vertex, the target is a
// parent of the source vertex. An edge would introduce a cycle.
if currentHash == target {
return true, nil
}
visited[currentHash] = struct{}{}
for adjacency := range s.inEdges[currentHash] {
stack.push(adjacency)
}
}
}
return false, nil
}