require_relative 'undefined' require_relative 'enumerable' require_relative 'trie' require_relative 'sorted_set' require 'set' module SpeckleConnector module Immutable # `Immutable::Set` is a collection of unordered values with no duplicates. Testing whether # an object is present in the `Set` can be done in constant time. `Set` is also `Enumerable`, so you can # iterate over the members of the set with {#each}, transform them with {#map}, filter # them with {#select}, and so on. Some of the `Enumerable` methods are overridden to # return `immutable-ruby` collections. # # Like the `Set` class in Ruby's standard library, which we will call RubySet, # `Immutable::Set` defines equivalency of objects using `#hash` and `#eql?`. No two # objects with the same `#hash` code, and which are also `#eql?`, can coexist in the # same `Set`. If one is already in the `Set`, attempts to add another one will have # no effect. # # `Set`s have no natural ordering and cannot be compared using `#<=>`. However, they # define {#<}, {#>}, {#<=}, and {#>=} as shorthand for {#proper_subset?}, # {#proper_superset?}, {#subset?}, and {#superset?} respectively. # # The basic set-theoretic operations {#union}, {#intersection}, {#difference}, and # {#exclusion} work with any `Enumerable` object. # # A `Set` can be created in either of the following ways: # # Immutable::Set.new([1, 2, 3]) # any Enumerable can be used to initialize # Immutable::Set['A', 'B', 'C', 'D'] # # The latter 2 forms of initialization can be used with your own, custom subclasses # of `Immutable::Set`. # # Unlike RubySet, all methods which you might expect to "modify" an `Immutable::Set` # actually return a new set and leave the existing one unchanged. # # @example # set1 = Immutable::Set[1, 2] # => Immutable::Set[1, 2] # set2 = Immutable::Set[1, 2] # => Immutable::Set[1, 2] # set1 == set2 # => true # set3 = set1.add("foo") # => Immutable::Set[1, 2, "foo"] # set3 - set2 # => Immutable::Set["foo"] # set3.subset?(set1) # => false # set1.subset?(set3) # => true # class Set include SpeckleConnector::Immutable::Enumerable class << self # Create a new `Set` populated with the given items. # @return [Set] def [](*items) items.empty? ? empty : new(items) end # Return an empty `Set`. If used on a subclass, returns an empty instance # of that class. # # @return [Set] def empty @empty ||= new end # "Raw" allocation of a new `Set`. Used internally to create a new # instance quickly after obtaining a modified {Trie}. # # @return [Set] # @private def alloc(trie = EmptyTrie) allocate.tap { |s| s.instance_variable_set(:@trie, trie) }.freeze end end def initialize(items=[]) @trie = Trie.new(0) items.each { |item| @trie.put!(item, nil) } freeze end # Return `true` if this `Set` contains no items. # @return [Boolean] def empty? @trie.empty? end # Return the number of items in this `Set`. # @return [Integer] def size @trie.size end alias length size # Return a new `Set` with `item` added. If `item` is already in the set, # return `self`. # # @example # Immutable::Set[1, 2, 3].add(4) # => Immutable::Set[1, 2, 4, 3] # Immutable::Set[1, 2, 3].add(2) # => Immutable::Set[1, 2, 3] # # @param item [Object] The object to add # @return [Set] def add(item) include?(item) ? self : self.class.alloc(@trie.put(item, nil)) end alias << add # If `item` is not a member of this `Set`, return a new `Set` with `item` added. # Otherwise, return `false`. # # @example # Immutable::Set[1, 2, 3].add?(4) # => Immutable::Set[1, 2, 4, 3] # Immutable::Set[1, 2, 3].add?(2) # => false # # @param item [Object] The object to add # @return [Set, false] def add?(item) !include?(item) && add(item) end # Return a new `Set` with `item` removed. If `item` is not a member of the set, # return `self`. # # @example # Immutable::Set[1, 2, 3].delete(1) # => Immutable::Set[2, 3] # Immutable::Set[1, 2, 3].delete(99) # => Immutable::Set[1, 2, 3] # # @param item [Object] The object to remove # @return [Set] def delete(item) trie = @trie.delete(item) new_trie(trie) end # If `item` is a member of this `Set`, return a new `Set` with `item` removed. # Otherwise, return `false`. # # @example # Immutable::Set[1, 2, 3].delete?(1) # => Immutable::Set[2, 3] # Immutable::Set[1, 2, 3].delete?(99) # => false # # @param item [Object] The object to remove # @return [Set, false] def delete?(item) include?(item) && delete(item) end # Call the block once for each item in this `Set`. No specific iteration order # is guaranteed, but the order will be stable for any particular `Set`. If # no block is given, an `Enumerator` is returned instead. # # @example # Immutable::Set["Dog", "Elephant", "Lion"].each { |e| puts e } # Elephant # Dog # Lion # # => Immutable::Set["Dog", "Elephant", "Lion"] # # @yield [item] Once for each item. # @return [self, Enumerator] def each return to_enum if not block_given? @trie.each { |key, _| yield(key) } self end # Call the block once for each item in this `Set`. Iteration order will be # the opposite of {#each}. If no block is given, an `Enumerator` is # returned instead. # # @example # Immutable::Set["Dog", "Elephant", "Lion"].reverse_each { |e| puts e } # Lion # Dog # Elephant # # => Immutable::Set["Dog", "Elephant", "Lion"] # # @yield [item] Once for each item. # @return [self] def reverse_each return enum_for(:reverse_each) if not block_given? @trie.reverse_each { |key, _| yield(key) } self end # Return a new `Set` with all the items for which the block returns true. # # @example # Immutable::Set["Elephant", "Dog", "Lion"].select { |e| e.size >= 4 } # # => Immutable::Set["Elephant", "Lion"] # @yield [item] Once for each item. # @return [Set] def select return enum_for(:select) unless block_given? trie = @trie.select { |key, _| yield(key) } new_trie(trie) end alias find_all select alias keep_if select # Call the block once for each item in this `Set`. All the values returned # from the block will be gathered into a new `Set`. If no block is given, # an `Enumerator` is returned instead. # # @example # Immutable::Set["Cat", "Elephant", "Dog", "Lion"].map { |e| e.size } # # => Immutable::Set[8, 4, 3] # # @yield [item] Once for each item. # @return [Set] def map return enum_for(:map) if not block_given? return self if empty? self.class.new(super) end alias collect map # Return `true` if the given item is present in this `Set`. More precisely, # return `true` if an object with the same `#hash` code, and which is also `#eql?` # to the given object is present. # # @example # Immutable::Set["A", "B", "C"].include?("B") # => true # Immutable::Set["A", "B", "C"].include?("Z") # => false # # @param object [Object] The object to check for # @return [Boolean] def include?(object) @trie.key?(object) end alias member? include? # Return a member of this `Set`. The member chosen will be the first one which # would be yielded by {#each}. If the set is empty, return `nil`. # # @example # Immutable::Set["A", "B", "C"].first # => "C" # # @return [Object] def first (entry = @trie.at(0)) && entry[0] end # Return a {SortedSet} which contains the same items as this `Set`, ordered by # the given comparator block. # # @example # Immutable::Set["Elephant", "Dog", "Lion"].sort # # => Immutable::SortedSet["Dog", "Elephant", "Lion"] # Immutable::Set["Elephant", "Dog", "Lion"].sort { |a,b| a.size <=> b.size } # # => Immutable::SortedSet["Dog", "Lion", "Elephant"] # # @yield [a, b] Any number of times with different pairs of elements. # @yieldreturn [Integer] Negative if the first element should be sorted # lower, positive if the latter element, or 0 if # equal. # @return [SortedSet] def sort(&comparator) SortedSet.new(to_a, &comparator) end # Return a {SortedSet} which contains the same items as this `Set`, ordered # by mapping each item through the provided block to obtain sort keys, and # then sorting the keys. # # @example # Immutable::Set["Elephant", "Dog", "Lion"].sort_by { |e| e.size } # # => Immutable::SortedSet["Dog", "Lion", "Elephant"] # # @yield [item] Once for each item to create the set, and then potentially # again depending on what operations are performed on the # returned {SortedSet}. As such, it is recommended that the # block be a pure function. # @yieldreturn [Object] sort key for the item # @return [SortedSet] def sort_by(&mapper) SortedSet.new(to_a, &mapper) end # Return a new `Set` which contains all the members of both this `Set` and `other`. # `other` can be any `Enumerable` object. # # @example # Immutable::Set[1, 2] | Immutable::Set[2, 3] # => Immutable::Set[1, 2, 3] # # @param other [Enumerable] The collection to merge with # @return [Set] def union(other) if other.is_a?(SpeckleConnector::Immutable::Set) if other.size > size small_set_pairs = @trie large_set_trie = other.instance_variable_get(:@trie) else small_set_pairs = other.instance_variable_get(:@trie) large_set_trie = @trie end else if other.respond_to?(:lazy) small_set_pairs = other.lazy.map { |e| [e, nil] } else small_set_pairs = other.map { |e| [e, nil] } end large_set_trie = @trie end trie = large_set_trie.bulk_put(small_set_pairs) new_trie(trie) end alias | union alias + union alias merge union # Return a new `Set` which contains all the items which are members of both # this `Set` and `other`. `other` can be any `Enumerable` object. # # @example # Immutable::Set[1, 2] & Immutable::Set[2, 3] # => Immutable::Set[2] # # @param other [Enumerable] The collection to intersect with # @return [Set] def intersection(other) if other.size < @trie.size if other.is_a?(SpeckleConnector::Immutable::Set) trie = other.instance_variable_get(:@trie).select { |key, _| include?(key) } else trie = Trie.new(0) other.each { |obj| trie.put!(obj, nil) if include?(obj) } end else trie = @trie.select { |key, _| other.include?(key) } end new_trie(trie) end alias & intersection # Return a new `Set` with all the items in `other` removed. `other` can be # any `Enumerable` object. # # @example # Immutable::Set[1, 2] - Immutable::Set[2, 3] # => Immutable::Set[1] # # @param other [Enumerable] The collection to subtract from this set # @return [Set] def difference(other) trie = if (@trie.size <= other.size) && (other.is_a?(SpeckleConnector::Immutable::Set) || (defined?(::Set) && other.is_a?(::Set))) @trie.select { |key, _| !other.include?(key) } else @trie.bulk_delete(other) end new_trie(trie) end alias subtract difference alias - difference # Return a new `Set` which contains all the items which are members of this # `Set` or of `other`, but not both. `other` can be any `Enumerable` object. # # @example # Immutable::Set[1, 2] ^ Immutable::Set[2, 3] # => Immutable::Set[1, 3] # # @param other [Enumerable] The collection to take the exclusive disjunction of # @return [Set] def exclusion(other) ((self | other) - (self & other)) end alias ^ exclusion # Return `true` if all items in this `Set` are also in `other`. # # @example # Immutable::Set[2, 3].subset?(Immutable::Set[1, 2, 3]) # => true # # @param other [Set] # @return [Boolean] def subset?(other) return false if other.size < size # This method has the potential to be very slow if 'other' is a large Array, so to avoid that, # we convert those Arrays to Sets before checking presence of items # Time to convert Array -> Set is linear in array.size # Time to check for presence of all items in an Array is proportional to set.size * array.size # Note that both sides of that equation have array.size -- hence those terms cancel out, # and the break-even point is solely dependent on the size of this collection # After doing some benchmarking to estimate the constants, it appears break-even is at ~190 items # We also check other.size, to avoid the more expensive #is_a? checks in cases where it doesn't matter # if other.size >= 150 && @trie.size >= 190 && !(other.is_a?(SpeckleConnector::Immutable::Set) || other.is_a?(::Set)) other = ::Set.new(other) end all? { |item| other.include?(item) } end alias <= subset? # Return `true` if all items in `other` are also in this `Set`. # # @example # Immutable::Set[1, 2, 3].superset?(Immutable::Set[2, 3]) # => true # # @param other [Set] # @return [Boolean] def superset?(other) other.subset?(self) end alias >= superset? # Returns `true` if `other` contains all the items in this `Set`, plus at least # one item which is not in this set. # # @example # Immutable::Set[2, 3].proper_subset?(Immutable::Set[1, 2, 3]) # => true # Immutable::Set[1, 2, 3].proper_subset?(Immutable::Set[1, 2, 3]) # => false # # @param other [Set] # @return [Boolean] def proper_subset?(other) return false if other.size <= size # See comments above if other.size >= 150 && @trie.size >= 190 && !(other.is_a?(SpeckleConnector::Immutable::Set) || other.is_a?(::Set)) other = ::Set.new(other) end all? { |item| other.include?(item) } end alias < proper_subset? # Returns `true` if this `Set` contains all the items in `other`, plus at least # one item which is not in `other`. # # @example # Immutable::Set[1, 2, 3].proper_superset?(Immutable::Set[2, 3]) # => true # Immutable::Set[1, 2, 3].proper_superset?(Immutable::Set[1, 2, 3]) # => false # # @param other [Set] # @return [Boolean] def proper_superset?(other) other.proper_subset?(self) end alias > proper_superset? # Return `true` if this `Set` and `other` do not share any items. # # @example # Immutable::Set[1, 2].disjoint?(Immutable::Set[8, 9]) # => true # # @param other [Set] # @return [Boolean] def disjoint?(other) if other.size <= size other.each { |item| return false if include?(item) } else # See comment on #subset? if other.size >= 150 && @trie.size >= 190 && !(other.is_a?(SpeckleConnector::Immutable::Set) || other.is_a?(::Set)) other = ::Set.new(other) end each { |item| return false if other.include?(item) } end true end # Return `true` if this `Set` and `other` have at least one item in common. # # @example # Immutable::Set[1, 2].intersect?(Immutable::Set[2, 3]) # => true # # @param other [Set] # @return [Boolean] def intersect?(other) !disjoint?(other) end # Recursively insert the contents of any nested `Set`s into this `Set`, and # remove them. # # @example # Immutable::Set[Immutable::Set[1, 2], Immutable::Set[3, 4]].flatten # # => Immutable::Set[1, 2, 3, 4] # # @return [Set] def flatten reduce(self.class.empty) do |set, item| next set.union(item.flatten) if item.is_a?(Set) set.add(item) end end alias group group_by alias classify group_by # Return a randomly chosen item from this `Set`. If the set is empty, return `nil`. # # @example # Immutable::Set[1, 2, 3, 4, 5].sample # => 3 # # @return [Object] def sample empty? ? nil : @trie.at(rand(size))[0] end # Return an empty `Set` instance, of the same class as this one. Useful if you # have multiple subclasses of `Set` and want to treat them polymorphically. # # @return [Set] def clear self.class.empty end # Return true if `other` has the same type and contents as this `Set`. # # @param other [Object] The object to compare with # @return [Boolean] def eql?(other) return true if other.equal?(self) return false if not instance_of?(other.class) other_trie = other.instance_variable_get(:@trie) return false if @trie.size != other_trie.size @trie.each do |key, _| return false if !other_trie.key?(key) end true end alias == eql? # See `Object#hash`. # @return [Integer] def hash reduce(0) { |hash, item| (hash << 5) - hash + item.hash } end # Return `self`. Since this is an immutable object duplicates are # equivalent. # @return [Set] def dup self end alias clone dup def <=>(*_args) raise NotImplementedError, 'Sets are not ordered, so Enumerable#<=> will give a meaningless result' end def each_index(*_args) raise NotImplementedError, "members cannot be accessed by 'index', so #each_index is not meaningful" end # Return `self`. # # @return [self] def to_set self end # @private def marshal_dump output = {} each do |key| output[key] = nil end output end # @private def marshal_load(dictionary) @trie = dictionary.reduce(EmptyTrie) do |trie, key_value| trie.put(key_value.first, nil) end end private def new_trie(trie) if trie.empty? self.class.empty elsif trie.equal?(@trie) self else self.class.alloc(trie) end end end # The canonical empty `Set`. Returned by `Set[]` when # invoked with no arguments; also returned by `Set.empty`. Prefer using this # one rather than creating many empty sets using `Set.new`. # # @private EmptySet = SpeckleConnector::Immutable::Set.empty end end