rubyx/lib/parslet/transform.rb


require 'parslet/pattern'

# Transforms an expression tree into something else. The transformation
# performs a depth-first, post-order traversal of the expression tree. During
# that traversal, each time a rule matches a node, the node is replaced by the
# result of the block associated to the rule. Otherwise the node is accepted
# as is into the result tree.
#
# This is almost what you would generally do with a tree visitor, except that
# you can match several levels of the tree at once. 
#
# As a consequence of this, the resulting tree will contain pieces of the
# original tree and new pieces. Most likely, you will want to transform the
# original tree wholly, so this isn't a problem.
#
# You will not be able to create a loop, given that each node will be replaced
# only once and then left alone. This means that the results of a replacement
# will not be acted upon. 
#
# Example: 
#
#   class Example < Parslet::Transform
#     rule(:string => simple(:x)) {  # (1)
#       StringConstant.new(x)
#     }
#   end
#
# A tree transform (Parslet::Transform) is defined by a set of rules. Each
# rule can be defined by calling #rule with the pattern as argument. The block
# given will be called every time the rule matches somewhere in the tree given
# to #apply. It is passed a Hash containing all the variable bindings of this
# pattern match. 
#   
# In the above example, (1) illustrates a simple matching rule. 
#
# Let's say you want to parse matching parentheses and distill a maximum nest
# depth. You would probably write a parser like the one in example/parens.rb;
# here's the relevant part: 
#
#   rule(:balanced) {
#     str('(').as(:l) >> balanced.maybe.as(:m) >> str(')').as(:r)
#   }
#
# If you now apply this to a string like '(())', you get a intermediate parse
# tree that looks like this: 
#
#   {
#     l: '(', 
#     m: {
#       l: '(', 
#       m: nil, 
#       r: ')' 
#     }, 
#     r: ')' 
#   }
#
# This parse tree is good for debugging, but what we would really like to have
# is just the nesting depth. This transformation rule will produce that: 
#
#   rule(:l => '(', :m => simple(:x), :r => ')') { 
#     # innermost :m will contain nil
#     x.nil? ? 1 : x+1
#   }
#
# = Usage patterns
#
# There are four ways of using this class. The first one is very much
# recommended, followed by the second one for generality. The other ones are
# omitted here. 
#
# Recommended usage is as follows: 
#
#   class MyTransformator < Parslet::Transform
#     rule(...) { ... }
#     rule(...) { ... }
#     # ...
#   end
#   MyTransformator.new.apply(tree)
#
# Alternatively, you can use the Transform class as follows: 
#
#   transform = Parslet::Transform.new do
#     rule(...) { ... }
#   end
#   transform.apply(tree)
#
# = Execution context
#
# The execution context of action blocks differs depending on the arity of 
# said blocks. This can be confusing. It is however somewhat intentional. You 
# should not create fat Transform descendants containing a lot of helper methods, 
# instead keep your AST class construction in global scope or make it available
# through a factory. The following piece of code illustrates usage of global
# scope: 
#
#   transform = Parslet::Transform.new do
#     rule(...) { AstNode.new(a_variable) }
#     rule(...) { Ast.node(a_variable) } # modules are nice
#   end
#   transform.apply(tree)
#
# And here's how you would use a class builder (a factory):
#
#   transform = Parslet::Transform.new do
#     rule(...) { builder.add_node(a_variable) }
#     rule(...) { |d| d[:builder].add_node(d[:a_variable]) }
#   end
#   transform.apply(tree, :builder => Builder.new)
#
# As you can see, Transform allows you to inject local context for your rule
# action blocks to use. 
#
class Parslet::Transform
  # FIXME: Maybe only part of it? Or maybe only include into constructor
  # context?
  include Parslet   
  
  class << self
    # FIXME: Only do this for subclasses?
    include Parslet
    
    # Define a rule for the transform subclass. 
    #
    def rule(expression, &block)
      @__transform_rules ||= []
      @__transform_rules << [Parslet::Pattern.new(expression), block]
    end
    
    # Allows accessing the class' rules
    #
    def rules 
      @__transform_rules || []
    end
  end
  
  def initialize(&block) 
    @rules = []
    
    if block
      instance_eval(&block)
    end
  end
  
  # Defines a rule to be applied whenever apply is called on a tree. A rule
  # is composed of two parts: 
  # 
  # * an *expression pattern*
  # * a *transformation block*
  #
  def rule(expression, &block)
    @rules << [
      Parslet::Pattern.new(expression), 
      block
    ]
  end
  
  # Applies the transformation to a tree that is generated by Parslet::Parser
  # or a simple parslet. Transformation will proceed down the tree, replacing
  # parts/all of it with new objects. The resulting object will be returned. 
  #
  def apply(obj, context=nil)
    transform_elt(
      case obj
        when Hash
          recurse_hash(obj, context)
        when Array
          recurse_array(obj, context)
      else
        obj
      end, 
      context
    )
  end
  
  # Executes the block on the bindings obtained by Pattern#match, if such a match
  # can be made. Depending on the arity of the given block, it is called in 
  # one of two environments: the current one or a clean toplevel environment.
  #
  # If you would like the current environment preserved, please use the 
  # arity 1 variant of the block. Alternatively, you can inject a context object
  # and call methods on it (think :ctx => self).
  #
  #   # the local variable a is simulated
  #   t.call_on_match(:a => :b) { a } 
  #   # no change of environment here
  #   t.call_on_match(:a => :b) { |d| d[:a] }
  #
  def call_on_match(bindings, block)
    if block
      if block.arity == 1
        return block.call(bindings)
      else
        context = Context.new(bindings)
        return context.instance_eval(&block)
      end
    end
  end
  
  # Allow easy access to all rules, the ones defined in the instance and the 
  # ones predefined in a subclass definition. 
  #
  def rules 
    self.class.rules + @rules
  end
  
  # @api private 
  #
  def transform_elt(elt, context) 
    rules.each do |pattern, block|
      if bindings=pattern.match(elt, context)
        # Produces transformed value
        return call_on_match(bindings, block)
      end
    end
    
    # No rule matched - element is not transformed
    return elt
  end

  # @api private 
  #
  def recurse_hash(hsh, ctx) 
    hsh.inject({}) do |new_hsh, (k,v)|
      new_hsh[k] = apply(v, ctx)
      new_hsh
    end
  end
  # @api private 
  #
  def recurse_array(ary, ctx) 
    ary.map { |elt| apply(elt, ctx) }
  end
end

require 'parslet/context'
vendored parslet, deemed stable enough and better without dependency 2014-04-27 14:34:35 +02:00
			`require 'parslet/pattern'`

			`# Transforms an expression tree into something else. The transformation`
			`# performs a depth-first, post-order traversal of the expression tree. During`
			`# that traversal, each time a rule matches a node, the node is replaced by the`
			`# result of the block associated to the rule. Otherwise the node is accepted`
			`# as is into the result tree.`
			`#`
			`# This is almost what you would generally do with a tree visitor, except that`
			`# you can match several levels of the tree at once.`
			`#`
			`# As a consequence of this, the resulting tree will contain pieces of the`
			`# original tree and new pieces. Most likely, you will want to transform the`
			`# original tree wholly, so this isn't a problem.`
			`#`
			`# You will not be able to create a loop, given that each node will be replaced`
			`# only once and then left alone. This means that the results of a replacement`
			`# will not be acted upon.`
			`#`
			`# Example:`
			`#`
			`# class Example < Parslet::Transform`
			`# rule(:string => simple(:x)) { # (1)`
introduce constant class and add block to compile signature(wip, work in progress) 2014-05-13 15:24:19 +02:00			`# StringConstant.new(x)`
vendored parslet, deemed stable enough and better without dependency 2014-04-27 14:34:35 +02:00			`# }`
			`# end`
			`#`
			`# A tree transform (Parslet::Transform) is defined by a set of rules. Each`
			`# rule can be defined by calling #rule with the pattern as argument. The block`
			`# given will be called every time the rule matches somewhere in the tree given`
			`# to #apply. It is passed a Hash containing all the variable bindings of this`
			`# pattern match.`
			`#`
			`# In the above example, (1) illustrates a simple matching rule.`
			`#`
			`# Let's say you want to parse matching parentheses and distill a maximum nest`
			`# depth. You would probably write a parser like the one in example/parens.rb;`
			`# here's the relevant part:`
			`#`
			`# rule(:balanced) {`
			`# str('(').as(:l) >> balanced.maybe.as(:m) >> str(')').as(:r)`
			`# }`
			`#`
			`# If you now apply this to a string like '(())', you get a intermediate parse`
			`# tree that looks like this:`
			`#`
			`# {`
			`# l: '(',`
			`# m: {`
			`# l: '(',`
			`# m: nil,`
			`# r: ')'`
			`# },`
			`# r: ')'`
			`# }`
			`#`
			`# This parse tree is good for debugging, but what we would really like to have`
			`# is just the nesting depth. This transformation rule will produce that:`
			`#`
			`# rule(:l => '(', :m => simple(:x), :r => ')') {`
			`# # innermost :m will contain nil`
			`# x.nil? ? 1 : x+1`
			`# }`
			`#`
			`# = Usage patterns`
			`#`
			`# There are four ways of using this class. The first one is very much`
			`# recommended, followed by the second one for generality. The other ones are`
			`# omitted here.`
			`#`
			`# Recommended usage is as follows:`
			`#`
			`# class MyTransformator < Parslet::Transform`
			`# rule(...) { ... }`
			`# rule(...) { ... }`
			`# # ...`
			`# end`
			`# MyTransformator.new.apply(tree)`
			`#`
			`# Alternatively, you can use the Transform class as follows:`
			`#`
			`# transform = Parslet::Transform.new do`
			`# rule(...) { ... }`
			`# end`
			`# transform.apply(tree)`
			`#`
			`# = Execution context`
			`#`
			`# The execution context of action blocks differs depending on the arity of`
			`# said blocks. This can be confusing. It is however somewhat intentional. You`
			`# should not create fat Transform descendants containing a lot of helper methods,`
			`# instead keep your AST class construction in global scope or make it available`
			`# through a factory. The following piece of code illustrates usage of global`
			`# scope:`
			`#`
			`# transform = Parslet::Transform.new do`
			`# rule(...) { AstNode.new(a_variable) }`
			`# rule(...) { Ast.node(a_variable) } # modules are nice`
			`# end`
			`# transform.apply(tree)`
			`#`
			`# And here's how you would use a class builder (a factory):`
			`#`
			`# transform = Parslet::Transform.new do`
			`# rule(...) { builder.add_node(a_variable) }`
			`# rule(...) { \|d\| d[:builder].add_node(d[:a_variable]) }`
			`# end`
			`# transform.apply(tree, :builder => Builder.new)`
			`#`
			`# As you can see, Transform allows you to inject local context for your rule`
			`# action blocks to use.`
			`#`
			`class Parslet::Transform`
			`# FIXME: Maybe only part of it? Or maybe only include into constructor`
			`# context?`
			`include Parslet`

			`class << self`
			`# FIXME: Only do this for subclasses?`
			`include Parslet`

			`# Define a rule for the transform subclass.`
			`#`
			`def rule(expression, &block)`
			`@__transform_rules \|\|= []`
			`@__transform_rules << [Parslet::Pattern.new(expression), block]`
			`end`

			`# Allows accessing the class' rules`
			`#`
			`def rules`
			`@__transform_rules \|\| []`
			`end`
			`end`

			`def initialize(&block)`
			`@rules = []`

			`if block`
			`instance_eval(&block)`
			`end`
			`end`

			`# Defines a rule to be applied whenever apply is called on a tree. A rule`
			`# is composed of two parts:`
			`#`
			`# * an expression pattern`
			`# * a transformation block`
			`#`
			`def rule(expression, &block)`
			`@rules << [`
			`Parslet::Pattern.new(expression),`
			`block`
			`]`
			`end`

			`# Applies the transformation to a tree that is generated by Parslet::Parser`
			`# or a simple parslet. Transformation will proceed down the tree, replacing`
			`# parts/all of it with new objects. The resulting object will be returned.`
			`#`
			`def apply(obj, context=nil)`
			`transform_elt(`
			`case obj`
			`when Hash`
			`recurse_hash(obj, context)`
			`when Array`
			`recurse_array(obj, context)`
			`else`
			`obj`
			`end,`
			`context`
			`)`
			`end`

			`# Executes the block on the bindings obtained by Pattern#match, if such a match`
			`# can be made. Depending on the arity of the given block, it is called in`
			`# one of two environments: the current one or a clean toplevel environment.`
			`#`
			`# If you would like the current environment preserved, please use the`
			`# arity 1 variant of the block. Alternatively, you can inject a context object`
			`# and call methods on it (think :ctx => self).`
			`#`
			`# # the local variable a is simulated`
			`# t.call_on_match(:a => :b) { a }`
			`# # no change of environment here`
			`# t.call_on_match(:a => :b) { \|d\| d[:a] }`
			`#`
			`def call_on_match(bindings, block)`
			`if block`
			`if block.arity == 1`
			`return block.call(bindings)`
			`else`
			`context = Context.new(bindings)`
			`return context.instance_eval(&block)`
			`end`
			`end`
			`end`

			`# Allow easy access to all rules, the ones defined in the instance and the`
			`# ones predefined in a subclass definition.`
			`#`
			`def rules`
			`self.class.rules + @rules`
			`end`

			`# @api private`
			`#`
			`def transform_elt(elt, context)`
			`rules.each do \|pattern, block\|`
			`if bindings=pattern.match(elt, context)`
			`# Produces transformed value`
			`return call_on_match(bindings, block)`
			`end`
			`end`

			`# No rule matched - element is not transformed`
			`return elt`
			`end`

			`# @api private`
			`#`
			`def recurse_hash(hsh, ctx)`
			`hsh.inject({}) do \|new_hsh, (k,v)\|`
			`new_hsh[k] = apply(v, ctx)`
			`new_hsh`
			`end`
			`end`
			`# @api private`
			`#`
			`def recurse_array(ary, ctx)`
			`ary.map { \|elt\| apply(elt, ctx) }`
			`end`
			`end`

			`require 'parslet/context'`