class Prism::IntegerNode

Experimental RBS support (using type sampling data from the type_fusion project). 

# sig/prism/node.rbs

class Prism::IntegerNode < Prism::Node
  def accept: (Analyzer::Visitor visitor) -> Array[]
  def compact_child_nodes: () -> Array[]
  def initialize: (Integer flags, Prism::Location location) -> void
end

^
1
Represents an integer number literal.

def self.type

def self.type: () -> Symbol

class, but should be faster in a case statement or an array comparison.
Note that like #type, it will still be slower than using == for a single
splitting on the type of the node without having to do a long === chain.
Similar to #type, this method returns a symbol that you can use for 
def self.type
  :integer_node
end

def accept(visitor)

Experimental RBS support (using type sampling data from the type_fusion project). 

def accept: (Analyzer::Visitor visitor) ->

This signature was generated using 5 samples from 1 application.

def accept: (Visitor visitor) -> void 
def accept(visitor)
  visitor.visit_integer_node(self)
end

def binary?

def binary?: () -> bool 
def binary?
  flags.anybits?(IntegerBaseFlags::BINARY)
end

def child_nodes

def child_nodes: () -> Array[nil | Node] 
def child_nodes
  []
end

def comment_targets

def comment_targets: () -> Array[Node | Location] 
def comment_targets
  []
end

def compact_child_nodes

Experimental RBS support (using type sampling data from the type_fusion project). 

def compact_child_nodes: () ->

This signature was generated using 4 samples from 1 application.

def compact_child_nodes: () -> Array[Node] 
def compact_child_nodes
  []
end

def copy(**params)

def copy: (**params) -> IntegerNode 
def copy(**params)
  IntegerNode.new(
    params.fetch(:flags) { flags },
    params.fetch(:location) { location },
  )
end

def decimal?

def decimal?: () -> bool 
def decimal?
  flags.anybits?(IntegerBaseFlags::DECIMAL)
end

def deconstruct_keys(keys)

def deconstruct_keys: (Array[Symbol] keys) -> { flags: Integer, location: Location } 
def deconstruct_keys(keys)
  { flags: flags, location: location }
end

def hexadecimal?

def hexadecimal?: () -> bool 
def hexadecimal?
  flags.anybits?(IntegerBaseFlags::HEXADECIMAL)
end

def initialize(flags, location)

Experimental RBS support (using type sampling data from the type_fusion project). 

def initialize: (Integer flags, Prism::Location location) -> void

This signature was generated using 5 samples from 1 application.

def initialize: (Integer flags, Location location) -> void 
def initialize(flags, location)
  @newline = false
  @flags = flags
  @location = location
end

def inspect(inspector = NodeInspector.new)

def inspect(NodeInspector inspector) -> String 
def inspect(inspector = NodeInspector.new)
  inspector << inspector.header(self)
  flags = [("binary" if binary?), ("decimal" if decimal?), ("octal" if octal?), ("hexadecimal" if hexadecimal?)].compact
  inspector << "└── flags: #{flags.empty? ? "∅" : flags.join(", ")}\n"
  inspector.to_str
end

def octal?

def octal?: () -> bool 
def octal?
  flags.anybits?(IntegerBaseFlags::OCTAL)
end

def type

def type: () -> Symbol

keys will use a jump table.
you can take advantage of the fact that case statements with all symbol
it uses a single integer comparison, but also because if you're on CRuby
can use for comparison. This is faster than the other approaches because
Instead, you can call #type, which will return to you a symbol that you

method calls, and/or array allocations.
these approaches are relatively slow because of the constant lookups,
case statement and doing `case node; when cls1; when cls2; end`. Both of
calling `[cls1, cls2].include?(node.class)` or putting the node into a
classes to see what kind of behavior to perform. Usually this is done by
Sometimes you want to check an instance of a node against a list of 
def type
  :integer_node
end

def value

Returns the value of the node as a Ruby Integer. 
def value
  Integer(slice)
end