rubyx/lib/virtual/machine.rb

require 'parslet/convenience'
require_relative "collector"
module Virtual
  # The Virtual Machine is a object based virtual machine in which ruby is implemented.
  #
  # It is minimal and realistic and low level
  # - minimal means that if one thing can be implemented by another, it is left out. This is quite
  #    the opposite from ruby, which has several loops, many redundant if forms and the like.
  # - realistic means it is easy to implement on a 32 bit machine (arm) and possibly 64 bit.
  #     Memory access,some registers of same size are the underlying hardware. (not ie byte machine)
  # - low level means it's basic instructions are realively easily implemented in a register machine.
  #      Low level means low level in oo terms though, so basic instruction to implement oo
  #  #
  # The ast is transformed to virtual-machine objects, some of which represent code, some data.
  #
  # The next step transforms to the register machine layer, which is quite close to what actually
  #  executes. The step after transforms to Arm, which creates executables.
  #
  # More concretely, a virtual machine is a sort of oo turing machine, it has a current instruction,
  # executes the instructions, fetches the next one and so on.
  # Off course the instructions are not soo simple, but in oo terms quite so.
  #
  # The machine is virtual in the sense that it is completely modeled in software,
  # it's complete state explicitly available (not implicitly by walking stacks or something)

  # The machine has a no register, but objects that represent it's state. There are four
  # - message : the currently executing message (See Parfait::Message)
  # - receiver : or self.  This is actually an instance of Message, but "hoisted" out
  # -  frame : A pssible frame for temporary data. Also part of the message and "hoisted" out
  # - next_message: A message object that the current activation wants to send.
  #
  # Messages form a linked list (not a stack) and the Space is responsible for storing
  # and handing out empty messages
  #
  # The "machine" is not part of the run-time (Parfait)

  class Machine
    include Collector

    def initialize
      @parser  = Parser::Salama.new
      @passes = [   ]
      @objects = {}
      @booted = false
    end
    attr_reader  :passes , :space , :class_mappings , :init , :objects , :booted

    # run all passes before the pass given
    # also collect the  block to run the passes on and
    # runs housekeeping Minimizer and Collector
    # Has to be called before run_after
    def run_before stop_at
      @blocks = [@init]
      @space.classes.values.each do |c|
        c.instance_methods.each do |f|
          nb = f.source.blocks
          @blocks += nb
        end
      end
      @passes.each do |pass_class|
        #puts "running #{pass_class}"
        run_blocks_for pass_class
        return if stop_at == pass_class
      end
    end

    # run all passes after the pass given
    # run_before MUST be called first.
    # the two are meant as a poor mans breakoint
    def run_after start_at
      run = false
      @passes.each do |pass_class|
        if run
          #puts "running #{pass_class}"
          run_blocks_for pass_class
        else
          run = true if start_at == pass_class
        end
      end
    end

    # as before, run all passes that are registered
    # (but now finer control with before/after versions)
    def run_passes
      return if @passes.empty?
      run_before @passes.first
      run_after @passes.first
    end

    # Objects are data and get assembled after functions
    def add_object o
      return false if @objects[o.object_id]
      return if o.is_a? Fixnum
      raise "adding non parfait #{o.class}" unless o.is_a? Parfait::Object or o.is_a? Symbol
      @objects[o.object_id] = o
      true
    end

    # Passes may be added to by anyone who wants
    # This is intentionally quite flexible, though one sometimes has to watch the order of them
    # most ordering is achieved by ordering the requires and using add_pass
    # but more precise control is possible with the _after and _before versions

    def add_pass pass
      @passes << pass
    end
    def add_pass_after( pass , after)
      index = @passes.index(after)
      raise "No such pass (#{pass}) to add after: #{after}" unless index
      @passes.insert(index+1 , pass)
    end
    def add_pass_before( pass , after)
      index = @passes.index(after)
      raise "No such pass to add after: #{after}" unless index
      @passes.insert(index , pass)
    end

    def boot
      boot_parfait!
      @init = Block.new("init", :__init__ )
      branch = Register::AlwaysBranch.new( "__init__" , self.space.get_init.source.blocks.first )
      @init.add_code branch
      @booted = true
      self
    end

    def parse_and_compile bytes
      syntax  = @parser.parse_with_debug(bytes)
      parts = Parser::Transform.new.apply(syntax)
      #puts parts.inspect
      Phisol::Compiler.compile( parts )
    end

    private
    def run_blocks_for pass_class
      parts = pass_class.split("::")
      pass = Object.const_get(parts[0]).const_get parts[1]
      raise "no such pass-class as #{pass_class}" unless pass
      @blocks.each do |block|
        raise "nil block " unless block
        pass.new.run(block)
      end
    end

  end

  # Module function to retrieve singleton
  def self.machine
    unless defined?(@machine)
      @machine = Machine.new
    end
    @machine
  end

end

Parfait::Method.class_eval do
  # for testing we need to reuse the main function (or do we?)
  # so remove the code that is there
  def clear_source
    self.source.send :initialize , self
  end

end

require_relative "boot"