관리-도구
편집 파일: dependency_graph.rb
# frozen_string_literal: true require 'set' require 'tsort' module Gem::Resolver::Molinillo # A directed acyclic graph that is tuned to hold named dependencies class DependencyGraph include Enumerable # Enumerates through the vertices of the graph. # @return [Array<Vertex>] The graph's vertices. def each vertices.values.each { |v| yield v } end include TSort # @visibility private alias_method :tsort_each_node, :each # @visibility private def tsort_each_child(vertex, &block) vertex.successors.each(&block) end # Topologically sorts the given vertices. # @param [Enumerable<Vertex>] vertices the vertices to be sorted, which must # all belong to the same graph. # @return [Array<Vertex>] The sorted vertices. def self.tsort(vertices) TSort.tsort( lambda { |b| vertices.each(&b) }, lambda { |v, &b| (v.successors & vertices).each(&b) } ) end # A directed edge of a {DependencyGraph} # @attr [Vertex] origin The origin of the directed edge # @attr [Vertex] destination The destination of the directed edge # @attr [Object] requirement The requirement the directed edge represents Edge = Struct.new(:origin, :destination, :requirement) # @return [{String => Vertex}] the vertices of the dependency graph, keyed # by {Vertex#name} attr_reader :vertices # Initializes an empty dependency graph def initialize @vertices = {} end # Initializes a copy of a {DependencyGraph}, ensuring that all {#vertices} # are properly copied. # @param [DependencyGraph] other the graph to copy. def initialize_copy(other) super @vertices = {} traverse = lambda do |new_v, old_v| return if new_v.outgoing_edges.size == old_v.outgoing_edges.size old_v.outgoing_edges.each do |edge| destination = add_vertex(edge.destination.name, edge.destination.payload) add_edge_no_circular(new_v, destination, edge.requirement) traverse.call(destination, edge.destination) end end other.vertices.each do |name, vertex| new_vertex = add_vertex(name, vertex.payload, vertex.root?) new_vertex.explicit_requirements.replace(vertex.explicit_requirements) traverse.call(new_vertex, vertex) end end # @return [String] a string suitable for debugging def inspect "#{self.class}:#{vertices.values.inspect}" end # @return [Boolean] whether the two dependency graphs are equal, determined # by a recursive traversal of each {#root_vertices} and its # {Vertex#successors} def ==(other) return false unless other vertices.each do |name, vertex| other_vertex = other.vertex_named(name) return false unless other_vertex return false unless other_vertex.successors.map(&:name).to_set == vertex.successors.map(&:name).to_set end end # @param [String] name # @param [Object] payload # @param [Array<String>] parent_names # @param [Object] requirement the requirement that is requiring the child # @return [void] def add_child_vertex(name, payload, parent_names, requirement) vertex = add_vertex(name, payload) parent_names.each do |parent_name| unless parent_name vertex.root = true next end parent_node = vertex_named(parent_name) add_edge(parent_node, vertex, requirement) end vertex end # Adds a vertex with the given name, or updates the existing one. # @param [String] name # @param [Object] payload # @return [Vertex] the vertex that was added to `self` def add_vertex(name, payload, root = false) vertex = vertices[name] ||= Vertex.new(name, payload) vertex.payload ||= payload vertex.root ||= root vertex end # Detaches the {#vertex_named} `name` {Vertex} from the graph, recursively # removing any non-root vertices that were orphaned in the process # @param [String] name # @return [void] def detach_vertex_named(name) return unless vertex = vertices.delete(name) vertex.outgoing_edges.each do |e| v = e.destination v.incoming_edges.delete(e) detach_vertex_named(v.name) unless v.root? || v.predecessors.any? end end # @param [String] name # @return [Vertex,nil] the vertex with the given name def vertex_named(name) vertices[name] end # @param [String] name # @return [Vertex,nil] the root vertex with the given name def root_vertex_named(name) vertex = vertex_named(name) vertex if vertex && vertex.root? end # Adds a new {Edge} to the dependency graph # @param [Vertex] origin # @param [Vertex] destination # @param [Object] requirement the requirement that this edge represents # @return [Edge] the added edge def add_edge(origin, destination, requirement) if destination.path_to?(origin) raise CircularDependencyError.new([origin, destination]) end add_edge_no_circular(origin, destination, requirement) end private # Adds a new {Edge} to the dependency graph without checking for # circularity. def add_edge_no_circular(origin, destination, requirement) edge = Edge.new(origin, destination, requirement) origin.outgoing_edges << edge destination.incoming_edges << edge edge end # A vertex in a {DependencyGraph} that encapsulates a {#name} and a # {#payload} class Vertex # @return [String] the name of the vertex attr_accessor :name # @return [Object] the payload the vertex holds attr_accessor :payload # @return [Arrary<Object>] the explicit requirements that required # this vertex attr_reader :explicit_requirements # @return [Boolean] whether the vertex is considered a root vertex attr_accessor :root alias_method :root?, :root # Initializes a vertex with the given name and payload. # @param [String] name see {#name} # @param [Object] payload see {#payload} def initialize(name, payload) @name = name @payload = payload @explicit_requirements = [] @outgoing_edges = [] @incoming_edges = [] end # @return [Array<Object>] all of the requirements that required # this vertex def requirements incoming_edges.map(&:requirement) + explicit_requirements end # @return [Array<Edge>] the edges of {#graph} that have `self` as their # {Edge#origin} attr_accessor :outgoing_edges # @return [Array<Edge>] the edges of {#graph} that have `self` as their # {Edge#destination} attr_accessor :incoming_edges # @return [Array<Vertex>] the vertices of {#graph} that have an edge with # `self` as their {Edge#destination} def predecessors incoming_edges.map(&:origin) end # @return [Array<Vertex>] the vertices of {#graph} where `self` is a # {#descendent?} def recursive_predecessors vertices = predecessors vertices += vertices.map(&:recursive_predecessors).flatten(1) vertices.uniq! vertices end # @return [Array<Vertex>] the vertices of {#graph} that have an edge with # `self` as their {Edge#origin} def successors outgoing_edges.map(&:destination) end # @return [Array<Vertex>] the vertices of {#graph} where `self` is an # {#ancestor?} def recursive_successors vertices = successors vertices += vertices.map(&:recursive_successors).flatten(1) vertices.uniq! vertices end # @return [String] a string suitable for debugging def inspect "#{self.class}:#{name}(#{payload.inspect})" end # @return [Boolean] whether the two vertices are equal, determined # by a recursive traversal of each {Vertex#successors} def ==(other) shallow_eql?(other) && successors.to_set == other.successors.to_set end # @param [Vertex] other the other vertex to compare to # @return [Boolean] whether the two vertices are equal, determined # solely by {#name} and {#payload} equality def shallow_eql?(other) other && name == other.name && payload == other.payload end alias_method :eql?, :== # @return [Fixnum] a hash for the vertex based upon its {#name} def hash name.hash end # Is there a path from `self` to `other` following edges in the # dependency graph? # @return true iff there is a path following edges within this {#graph} def path_to?(other) equal?(other) || successors.any? { |v| v.path_to?(other) } end alias_method :descendent?, :path_to? # Is there a path from `other` to `self` following edges in the # dependency graph? # @return true iff there is a path following edges within this {#graph} def ancestor?(other) other.path_to?(self) end alias_method :is_reachable_from?, :ancestor? end end end