# frozen_string_literal: true
module RuboCop
module AST
# `RuboCop::AST::Node` is a subclass of `Parser::AST::Node`. It provides
# access to parent nodes and an object-oriented way to traverse an AST with
# the power of `Enumerable`.
#
# It has predicate methods for every node type, like this:
#
# @example
# node.send_type? # Equivalent to: `node.type == :send`
# node.op_asgn_type? # Equivalent to: `node.type == :op_asgn`
#
# # Non-word characters (other than a-zA-Z0-9_) in type names are omitted.
# node.defined_type? # Equivalent to: `node.type == :defined?`
#
# # Find the first lvar node under the receiver node.
# lvar_node = node.each_descendant.find(&:lvar_type?)
#
class Node < Parser::AST::Node # rubocop:disable Metrics/ClassLength
include RuboCop::AST::Sexp
extend NodePattern::Macros
include RuboCop::AST::Descendence
# @api private
# <=> isn't included here, because it doesn't return a boolean.
COMPARISON_OPERATORS = %i[== === != <= >= > <].to_set.freeze
# @api private
TRUTHY_LITERALS = %i[str dstr xstr int float sym dsym array
hash regexp true irange erange complex
rational regopt].to_set.freeze
# @api private
FALSEY_LITERALS = %i[false nil].to_set.freeze
# @api private
LITERALS = (TRUTHY_LITERALS + FALSEY_LITERALS).freeze
# @api private
COMPOSITE_LITERALS = %i[dstr xstr dsym array hash irange
erange regexp].to_set.freeze
# @api private
BASIC_LITERALS = (LITERALS - COMPOSITE_LITERALS).freeze
# @api private
MUTABLE_LITERALS = %i[str dstr xstr array hash
regexp irange erange].to_set.freeze
# @api private
IMMUTABLE_LITERALS = (LITERALS - MUTABLE_LITERALS).freeze
# @api private
EQUALS_ASSIGNMENTS = %i[lvasgn ivasgn cvasgn gvasgn
casgn masgn rasgn mrasgn].to_set.freeze
# @api private
SHORTHAND_ASSIGNMENTS = %i[op_asgn or_asgn and_asgn].to_set.freeze
# @api private
ASSIGNMENTS = (EQUALS_ASSIGNMENTS + SHORTHAND_ASSIGNMENTS).freeze
# @api private
BASIC_CONDITIONALS = %i[if while until].to_set.freeze
# @api private
CONDITIONALS = (BASIC_CONDITIONALS + [:case]).freeze
# @api private
POST_CONDITION_LOOP_TYPES = %i[while_post until_post].to_set.freeze
# @api private
LOOP_TYPES = (POST_CONDITION_LOOP_TYPES + %i[while until for]).freeze
# @api private
VARIABLES = %i[ivar gvar cvar lvar].to_set.freeze
# @api private
REFERENCES = %i[nth_ref back_ref].to_set.freeze
# @api private
KEYWORDS = %i[alias and break case class def defs defined?
kwbegin do else ensure for if module next
not or postexe redo rescue retry return self
super zsuper then undef until when while
yield].to_set.freeze
# @api private
OPERATOR_KEYWORDS = %i[and or].to_set.freeze
# @api private
SPECIAL_KEYWORDS = %w[__FILE__ __LINE__ __ENCODING__].to_set.freeze
# @api private
ARGUMENT_TYPES = %i[arg optarg restarg kwarg kwoptarg kwrestarg blockarg].to_set.freeze
LITERAL_RECURSIVE_METHODS = (COMPARISON_OPERATORS + %i[* ! <=>]).freeze
LITERAL_RECURSIVE_TYPES = (OPERATOR_KEYWORDS + COMPOSITE_LITERALS + %i[begin pair]).freeze
private_constant :LITERAL_RECURSIVE_METHODS, :LITERAL_RECURSIVE_TYPES
# @see https://www.rubydoc.info/gems/ast/AST/Node:initialize
def initialize(type, children = [], properties = {})
@mutable_attributes = {}
# ::AST::Node#initialize freezes itself.
super
# #parent= may be invoked multiple times for a node because there are
# pending nodes while constructing AST and they are replaced later.
# For example, `lvar` and `send` type nodes are initially created as an
# `ident` type node and fixed to the appropriate type later.
# So, the #parent attribute needs to be mutable.
each_child_node do |child_node|
child_node.parent = self unless child_node.complete?
end
end
Parser::Meta::NODE_TYPES.each do |node_type|
method_name = "#{node_type.to_s.gsub(/\W/, '')}_type?"
define_method(method_name) do
type == node_type
end
end
# Returns the parent node, or `nil` if the receiver is a root node.
#
# @return [Node, nil] the parent node or `nil`
def parent
@mutable_attributes[:parent]
end
def parent=(node)
@mutable_attributes[:parent] = node
end
# @return [Boolean]
def parent?
!!parent
end
# @return [Boolean]
def root?
!parent
end
def complete!
@mutable_attributes.freeze
each_child_node(&:complete!)
end
def complete?
@mutable_attributes.frozen?
end
protected :parent=
# Override `AST::Node#updated` so that `AST::Processor` does not try to
# mutate our ASTs. Since we keep references from children to parents and
# not just the other way around, we cannot update an AST and share
# identical subtrees. Rather, the entire AST must be copied any time any
# part of it is changed.
def updated(type = nil, children = nil, properties = {})
properties[:location] ||= @location
klass = RuboCop::AST::Builder::NODE_MAP[type || @type] || Node
klass.new(type || @type, children || @children, properties)
end
# Returns the index of the receiver node in its siblings. (Sibling index
# uses zero based numbering.)
# Use is discouraged, this is a potentially slow method.
#
# @return [Integer, nil] the index of the receiver node in its siblings
def sibling_index
parent&.children&.index { |sibling| sibling.equal?(self) }
end
# Use is discouraged, this is a potentially slow method and can lead
# to even slower algorithms
# @return [Node, nil] the right (aka next) sibling
def right_sibling
return unless parent
parent.children[sibling_index + 1].freeze
end
# Use is discouraged, this is a potentially slow method and can lead
# to even slower algorithms
# @return [Node, nil] the left (aka previous) sibling
def left_sibling
i = sibling_index
return if i.nil? || i.zero?
parent.children[i - 1].freeze
end
# Use is discouraged, this is a potentially slow method and can lead
# to even slower algorithms
# @return [Array<Node>] the left (aka previous) siblings
def left_siblings
return [].freeze unless parent
parent.children[0...sibling_index].freeze
end
# Use is discouraged, this is a potentially slow method and can lead
# to even slower algorithms
# @return [Array<Node>] the right (aka next) siblings
def right_siblings
return [].freeze unless parent
parent.children[sibling_index + 1..-1].freeze
end
# Common destructuring method. This can be used to normalize
# destructuring for different variations of the node.
# Some node types override this with their own custom
# destructuring method.
#
# @return [Array<Node>] the different parts of the ndde
def node_parts
to_a
end
# Calls the given block for each ancestor node from parent to root.
# If no block is given, an `Enumerator` is returned.
#
# @overload each_ancestor
# Yield all nodes.
# @overload each_ancestor(type)
# Yield only nodes matching the type.
# @param [Symbol] type a node type
# @overload each_ancestor(type_a, type_b, ...)
# Yield only nodes matching any of the types.
# @param [Symbol] type_a a node type
# @param [Symbol] type_b a node type
# @yieldparam [Node] node each ancestor node
# @return [self] if a block is given
# @return [Enumerator] if no block is given
def each_ancestor(*types, &block)
return to_enum(__method__, *types) unless block_given?
visit_ancestors(types, &block)
self
end
# Returns an array of ancestor nodes.
# This is a shorthand for `node.each_ancestor.to_a`.
#
# @return [Array<Node>] an array of ancestor nodes
def ancestors
each_ancestor.to_a
end
# Note: Some rare nodes may have no source, like `s(:args)` in `foo {}`
# @return [String, nil]
def source
loc.expression&.source
end
def source_range
loc.expression
end
def first_line
loc.line
end
def last_line
loc.last_line
end
def line_count
return 0 unless source_range
source_range.last_line - source_range.first_line + 1
end
def nonempty_line_count
source.lines.grep(/\S/).size
end
def source_length
source_range ? source_range.size : 0
end
## Destructuring
def_node_matcher :receiver, <<~PATTERN
{(send $_ ...) ({block numblock} (send $_ ...) ...)}
PATTERN
def_node_matcher :str_content, '(str $_)'
def const_name
return unless const_type?
namespace, name = *self
if namespace && !namespace.cbase_type?
"#{namespace.const_name}::#{name}"
else
name.to_s
end
end
def_node_matcher :defined_module0, <<~PATTERN
{(class (const $_ $_) ...)
(module (const $_ $_) ...)
(casgn $_ $_ (send #global_const?({:Class :Module}) :new ...))
(casgn $_ $_ (block (send #global_const?({:Class :Module}) :new ...) ...))}
PATTERN
private :defined_module0
def defined_module
namespace, name = *defined_module0
s(:const, namespace, name) if name
end
def defined_module_name
(const = defined_module) && const.const_name
end
## Searching the AST
def parent_module_name
# what class or module is this method/constant/etc definition in?
# returns nil if answer cannot be determined
ancestors = each_ancestor(:class, :module, :sclass, :casgn, :block)
result = ancestors.map do |ancestor|
parent_module_name_part(ancestor) { |full_name| return full_name }
end.compact.reverse.join('::')
result.empty? ? 'Object' : result
end
## Predicates
def multiline?
line_count > 1
end
def single_line?
line_count == 1
end
def empty_source?
source_length.zero?
end
# Some cops treat the shovel operator as a kind of assignment.
def_node_matcher :assignment_or_similar?, <<~PATTERN
{assignment? (send _recv :<< ...)}
PATTERN
def literal?
LITERALS.include?(type)
end
def basic_literal?
BASIC_LITERALS.include?(type)
end
def truthy_literal?
TRUTHY_LITERALS.include?(type)
end
def falsey_literal?
FALSEY_LITERALS.include?(type)
end
def mutable_literal?
MUTABLE_LITERALS.include?(type)
end
def immutable_literal?
IMMUTABLE_LITERALS.include?(type)
end
%i[literal basic_literal].each do |kind|
recursive_kind = :"recursive_#{kind}?"
kind_filter = :"#{kind}?"
define_method(recursive_kind) do
case type
when :send
LITERAL_RECURSIVE_METHODS.include?(method_name) &&
receiver.send(recursive_kind) &&
arguments.all?(&recursive_kind)
when LITERAL_RECURSIVE_TYPES
children.compact.all?(&recursive_kind)
else
send(kind_filter)
end
end
end
def variable?
VARIABLES.include?(type)
end
def reference?
REFERENCES.include?(type)
end
def equals_asgn?
EQUALS_ASSIGNMENTS.include?(type)
end
def shorthand_asgn?
SHORTHAND_ASSIGNMENTS.include?(type)
end
def assignment?
ASSIGNMENTS.include?(type)
end
def basic_conditional?
BASIC_CONDITIONALS.include?(type)
end
def conditional?
CONDITIONALS.include?(type)
end
def post_condition_loop?
POST_CONDITION_LOOP_TYPES.include?(type)
end
# Note: `loop { }` is a normal method call and thus not a loop keyword.
def loop_keyword?
LOOP_TYPES.include?(type)
end
def keyword?
return true if special_keyword? || send_type? && prefix_not?
return false unless KEYWORDS.include?(type)
!OPERATOR_KEYWORDS.include?(type) || loc.operator.is?(type.to_s)
end
def special_keyword?
SPECIAL_KEYWORDS.include?(source)
end
def operator_keyword?
OPERATOR_KEYWORDS.include?(type)
end
def parenthesized_call?
loc.respond_to?(:begin) && loc.begin && loc.begin.is?('(')
end
def call_type?
send_type? || csend_type?
end
def chained?
parent&.call_type? && eql?(parent.receiver)
end
def argument?
parent&.send_type? && parent.arguments.include?(self)
end
def argument_type?
ARGUMENT_TYPES.include?(type)
end
def boolean_type?
true_type? || false_type?
end
def numeric_type?
int_type? || float_type?
end
def range_type?
irange_type? || erange_type?
end
def guard_clause?
node = and_type? || or_type? ? rhs : self
node.match_guard_clause?
end
def_node_matcher :match_guard_clause?, <<~PATTERN
[${(send nil? {:raise :fail} ...) return break next} single_line?]
PATTERN
def_node_matcher :proc?, <<~PATTERN
{(block (send nil? :proc) ...)
(block (send #global_const?(:Proc) :new) ...)
(send #global_const?(:Proc) :new)}
PATTERN
def_node_matcher :lambda?, '({block numblock} (send nil? :lambda) ...)'
def_node_matcher :lambda_or_proc?, '{lambda? proc?}'
def_node_matcher :global_const?, '(const {nil? cbase} %1)'
def_node_matcher :class_constructor?, <<~PATTERN
{ (send #global_const?({:Class :Module :Struct}) :new ...)
(block (send #global_const?({:Class :Module :Struct}) :new ...) ...)}
PATTERN
# @deprecated Use `:class_constructor?`
def_node_matcher :struct_constructor?, <<~PATTERN
(block (send #global_const?(:Struct) :new ...) _ $_)
PATTERN
def_node_matcher :class_definition?, <<~PATTERN
{(class _ _ $_)
(sclass _ $_)
(block (send #global_const?({:Struct :Class}) :new ...) _ $_)}
PATTERN
def_node_matcher :module_definition?, <<~PATTERN
{(module _ $_)
(block (send #global_const?(:Module) :new ...) _ $_)}
PATTERN
# Some expressions are evaluated for their value, some for their side
# effects, and some for both
# If we know that an expression is useful only for its side effects, that
# means we can transform it in ways which preserve the side effects, but
# change the return value
# So, does the return value of this node matter? If we changed it to
# `(...; nil)`, might that affect anything?
#
# rubocop:disable Metrics/MethodLength
def value_used?
# Be conservative and return true if we're not sure.
return false if parent.nil?
case parent.type
when :array, :defined?, :dstr, :dsym, :eflipflop, :erange, :float,
:hash, :iflipflop, :irange, :not, :pair, :regexp, :str, :sym,
:when, :xstr
parent.value_used?
when :begin, :kwbegin
begin_value_used?
when :for
for_value_used?
when :case, :if
case_if_value_used?
when :while, :until, :while_post, :until_post
while_until_value_used?
else
true
end
end
# rubocop:enable Metrics/MethodLength
# Some expressions are evaluated for their value, some for their side
# effects, and some for both.
# If we know that expressions are useful only for their return values,
# and have no side effects, that means we can reorder them, change the
# number of times they are evaluated, or replace them with other
# expressions which are equivalent in value.
# So, is evaluation of this node free of side effects?
#
def pure?
# Be conservative and return false if we're not sure
case type
when :__FILE__, :__LINE__, :const, :cvar, :defined?, :false, :float,
:gvar, :int, :ivar, :lvar, :nil, :str, :sym, :true, :regopt
true
when :and, :array, :begin, :case, :dstr, :dsym, :eflipflop, :ensure,
:erange, :for, :hash, :if, :iflipflop, :irange, :kwbegin, :not,
:or, :pair, :regexp, :until, :until_post, :when, :while,
:while_post
child_nodes.all?(&:pure?)
else
false
end
end
private
def visit_ancestors(types)
last_node = self
while (current_node = last_node.parent)
yield current_node if types.empty? ||
types.include?(current_node.type)
last_node = current_node
end
end
def begin_value_used?
# the last child node determines the value of the parent
sibling_index == parent.children.size - 1 ? parent.value_used? : false
end
def for_value_used?
# `for var in enum; body; end`
# (for <var> <enum> <body>)
sibling_index == 2 ? parent.value_used? : true
end
def case_if_value_used?
# (case <condition> <when...>)
# (if <condition> <truebranch> <falsebranch>)
sibling_index.zero? ? true : parent.value_used?
end
def while_until_value_used?
# (while <condition> <body>) -> always evaluates to `nil`
sibling_index.zero?
end
def parent_module_name_part(node)
case node.type
when :class, :module, :casgn
# TODO: if constant name has cbase (leading ::), then we don't need
# to keep traversing up through nested classes/modules
node.defined_module_name
when :sclass
yield parent_module_name_for_sclass(node)
else # block
parent_module_name_for_block(node) { yield nil }
end
end
def parent_module_name_for_sclass(sclass_node)
# TODO: look for constant definition and see if it is nested
# inside a class or module
subject = sclass_node.children[0]
if subject.const_type?
"#<Class:#{subject.const_name}>"
elsif subject.self_type?
"#<Class:#{sclass_node.parent_module_name}>"
end
end
def parent_module_name_for_block(ancestor)
if ancestor.method?(:class_eval)
# `class_eval` with no receiver applies to whatever module or class
# we are currently in
return unless (receiver = ancestor.receiver)
yield unless receiver.const_type?
receiver.const_name
elsif !new_class_or_module_block?(ancestor)
yield
end
end
def_node_matcher :new_class_or_module_block?, <<~PATTERN
^(casgn _ _ (block (send (const _ {:Class :Module}) :new) ...))
PATTERN
end
end
end