# frozen_string_literal: true module RuboCop module AST class NodePattern # Base class for AST Nodes of a `NodePattern` class Node < ::Parser::AST::Node extend SimpleForwardable include ::RuboCop::AST::Descendence MATCHES_WITHIN_SET = %i[symbol number string].to_set.freeze private_constant :MATCHES_WITHIN_SET ### # To be overridden by subclasses ### def rest? false end def capture? false end # @return [Integer, Range] An Integer for fixed length terms, otherwise a Range. # Note: `arity.end` may be `Float::INFINITY` def arity 1 end # @return [Array, nil] replace node with result, or `nil` if no change requested. def in_sequence_head nil end ### # Utilities ### # @return [Array] def children_nodes children.grep(Node) end # @return [Node] most nodes have only one child def child children[0] end # @return [Integer] nb of captures of that node and its descendants def nb_captures children_nodes.sum(&:nb_captures) end # @return [Boolean] returns whether it matches a variable number of elements def variadic? arity.is_a?(Range) end # @return [Boolean] returns true for nodes having a Ruby literal equivalent # that matches within a Set (e.g. `42`, `:sym` but not `/regexp/`) def matches_within_set? MATCHES_WITHIN_SET.include?(type) end # @return [Range] arity as a Range def arity_range a = arity a.is_a?(Range) ? a : INT_TO_RANGE[a] end def with(type: @type, children: @children, location: @location) self.class.new(type, children, { location: location }) end def source_range loc.expression end INT_TO_RANGE = Hash.new { |h, k| h[k] = k..k } private_constant :INT_TO_RANGE # :nodoc: module ForbidInSeqHead def in_sequence_head raise NodePattern::Invalid, "A sequence can not start with a #{type}" end end ### # Subclasses for specific node types ### # Node class for `$something` class Capture < Node # Delegate most introspection methods to it's only child def_delegators :child, :arity, :rest? def capture? true end def nb_captures 1 + super end def in_sequence_head wildcard, original_child = child.in_sequence_head return unless original_child [wildcard, self] # ($...) => (_ $...) end end # Node class for `(type first second ...)` class Sequence < Node include ForbidInSeqHead def initialize(type, children = [], properties = {}) if (replace = children.first.in_sequence_head) children = [*replace, *children[1..]] end super end end # Node class for `predicate?(:arg, :list)` class Predicate < Node def method_name children.first end def arg_list children[1..] end end FunctionCall = Predicate # Node class for `int+` class Repetition < Node include ForbidInSeqHead def operator children[1] end ARITIES = { '*': 0..Float::INFINITY, '+': 1..Float::INFINITY, '?': 0..1 }.freeze def arity ARITIES[operator] end end # Node class for `...` class Rest < Node ARITY = (0..Float::INFINITY).freeze private_constant :ARITY def rest? true end def arity ARITY end def in_sequence_head [Node.new(:wildcard), self] end end # Node class for `` class AnyOrder < Node include ForbidInSeqHead ARITIES = Hash.new { |h, k| h[k] = k - 1..Float::INFINITY } private_constant :ARITIES def term_nodes ends_with_rest? ? children[0...-1] : children end def ends_with_rest? children.last.rest? end def rest_node children.last if ends_with_rest? end def arity return children.size unless ends_with_rest? ARITIES[children.size] end end # A list (potentially empty) of nodes; part of a Union class Subsequence < Node include ForbidInSeqHead def arity min, max = children.map { |child| child.arity_range.minmax }.transpose.map(&:sum) min == max ? min || 0 : min..max # NOTE: || 0 for empty case, where min == max == nil. end def in_sequence_head super if children.empty? return unless (replace = children.first.in_sequence_head) [with(children: [*replace, *children[1..]])] end end # Node class for `{ ... }` class Union < Node def arity minima, maxima = children.map { |child| child.arity_range.minmax }.transpose min = minima.min max = maxima.max min == max ? min : min..max end def in_sequence_head return unless children.any?(&:in_sequence_head) new_children = children.map do |child| next child unless (replace = child.in_sequence_head) if replace.size > 1 Subsequence.new(:subsequence, replace, loc: child.loc) else replace.first end end [with(children: new_children)] end end # Registry MAP = Hash.new(Node).merge!( sequence: Sequence, repetition: Repetition, rest: Rest, capture: Capture, predicate: Predicate, any_order: AnyOrder, function_call: FunctionCall, subsequence: Subsequence, union: Union ).freeze end end end end