rubyx/lib/vm/c_machine.rb

module Vm

  # Our virtual c-machine has a number of registers of a given size and uses a stack
  # So much so standard
  # But our machine is oo, meaning that the register contents is typed. 
  # Off course current hardware does not have that (a perceived issue), but for our machine we pretend.
  # So internally we have at least 8 word registers, one of which is used to keep track of types*
  # and any number of scratch registers
  # but externally it's all Values (see there)
  
  # * Note that register content is typed externally. Not as in mri, where int's are tagged. Floats can's
  #   be tagged and lambda should be it's own type, so tagging does not work
  
  # A Machines main responsibility in the framework is to instantiate Instruction

  # Value functions are mapped to machines by concatenating the values class name + the methd name
  # Example:  IntegerValue.plus( value ) ->  Machine.signed_plus (value )
  
  # Also, shortcuts are created to easily instantiate Instruction objects. The "standard" set of instructions
  # (arm-influenced) provides for normal operations on a register machine, 
  # Example:  pop -> StackInstruction.new( {:opcode => :pop}.merge(options) )
  # Instructions work with options, so you can pass anything in, and the only thing the functions does
  # is save you typing the clazz.new. It passes the function name as the :opcode
   
  class CMachine
  
    # hmm, not pretty but for now
    @@instance = nil
    
    attr_reader :registers
    attr_reader :scratch
    attr_reader :pc
    attr_reader :stack
    # is often a pseudo register (ie doesn't support move or other operations).
    # Still, using if to express tests makes sense, not just for 
    # consistency in this code, but also because that is what is actually done
    attr_reader :status  

    # conditions specify all the possibilities for branches. Branches are b +  condition
    # Example:  beq means brach if equal. 
    # :al means always, so bal is an unconditional branch (but b() also works)
    CONDITIONS = [ :al , :eq , :ne , :lt , :le, :ge, :gt , :cs , :mi , :hi , :cc , :pl, :ls , :vc , :vs ]
    
    # here we create the shortcuts for the "standard" instructions, see above
    # Derived machines may use own instructions and define functions for them if so desired
    def initialize
      [:push, :pop].each do |inst|
        define_instruction_one(inst , StackInstruction)
      end
      [:adc, :add, :and, :bic, :eor, :orr, :rsb, :rsc, :sbc, :sub].each do |inst|
        define_instruction_one(inst , LogicInstruction)
      end
      [:mov, :mvn].each do |inst|
        define_instruction_one(inst , MoveInstruction)
      end
      [:cmn, :cmp, :teq, :tst].each do |inst|
        define_instruction_two(inst , CompareInstruction)
      end
      [:strb, :str , :ldrb, :ldr].each do |inst|
        define_instruction_one(inst , MemoryInstruction)
      end
      [:b, :call , :swi].each do |inst|
        define_instruction_one(inst , CallInstruction)
      end
      # create all possible brach instructions, but the CallInstruction demangles the 
      # code, and has opcode set to :b and :condition_code set to the condition
      CONDITIONS.each do |suffix|
        define_instruction_one("b#{suffix}".to_sym , CallInstruction)
        define_instruction_one("call#{suffix}".to_sym , CallInstruction)
      end
    end

    def create_method(name,  &block)
        self.class.send(:define_method, name , &block)
    end


    def self.instance
      @@instance
    end
    def self.instance= machine
      @@instance = machine
    end
    private
    #defining the instruction (opcode, symbol) as an given class.
    # the class is a Vm::Instruction derived base class and to create machine specific function
    #  an actual machine must create derived classes (from this base class) 
    # These instruction classes must follow a naming pattern and take a hash in the contructor
    #  Example, a mov() opcode  instantiates a Vm::MoveInstruction
    #   for an Arm machine, a class Arm::MoveInstruction < Vm::MoveInstruction exists, and it will
    #    be used to define the mov on an arm machine. 
    # This methods picks up that derived class and calls a define_instruction methods that can 
    #   be overriden in subclasses 
    def define_instruction_one(inst , clazz ,  defaults = {} )
      clazz =  class_for(clazz)
      create_method(inst) do |first , options = nil|
        options = {} if options == nil
        options.merge defaults
        options[:opcode] = inst
        clazz.new(first , options)
      end
    end

    # same for two args (left right, from to etc)
    def define_instruction_two(inst , clazz ,  defaults = {} )
      clazz =  class_for(clazz)
      create_method(inst) do |first ,second , options = nil|
        options = {} if options == nil
        options.merge defaults
        options[:opcode] = inst
        clazz.new(first , second ,options)
      end
    end

    def class_for clazz
      c_name = clazz.name
      my_module = self.class.name.split("::").first
      clazz_name = clazz.name.split("::").last
      if(my_module != Vm )
        module_class = eval("#{my_module}::#{clazz_name}") rescue nil
        clazz = module_class if module_class
      end
      clazz
    end
  end
end
Semi random code for the next step 2014-04-28 21:08:09 +02:00			`module Vm`
more random code 2014-05-02 07:02:25 +02:00
rename machine to c_machine 2014-05-13 16:06:42 +02:00			`# Our virtual c-machine has a number of registers of a given size and uses a stack`
more random code 2014-05-02 07:02:25 +02:00			`# So much so standard`
			`# But our machine is oo, meaning that the register contents is typed.`
			`# Off course current hardware does not have that (a perceived issue), but for our machine we pretend.`
			`# So internally we have at least 8 word registers, one of which is used to keep track of types*`
			`# and any number of scratch registers`
			`# but externally it's all Values (see there)`

			`# * Note that register content is typed externally. Not as in mri, where int's are tagged. Floats can's`
			`# be tagged and lambda should be it's own type, so tagging does not work`

more semi random code, a checkpoint 2014-05-03 14:13:44 +02:00			`# A Machines main responsibility in the framework is to instantiate Instruction`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00
more semi random code, a checkpoint 2014-05-03 14:13:44 +02:00			`# Value functions are mapped to machines by concatenating the values class name + the methd name`
introduce constant class and add block to compile signature(wip, work in progress) 2014-05-13 15:24:19 +02:00			`# Example: IntegerValue.plus( value ) -> Machine.signed_plus (value )`
more random code 2014-05-02 07:02:25 +02:00
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00			`# Also, shortcuts are created to easily instantiate Instruction objects. The "standard" set of instructions`
			`# (arm-influenced) provides for normal operations on a register machine,`
			`# Example: pop -> StackInstruction.new( {:opcode => :pop}.merge(options) )`
			`# Instructions work with options, so you can pass anything in, and the only thing the functions does`
			`# is save you typing the clazz.new. It passes the function name as the :opcode`

rename machine to c_machine 2014-05-13 16:06:42 +02:00			`class CMachine`
more random code 2014-05-02 07:02:25 +02:00
more semi random code, a checkpoint 2014-05-03 14:13:44 +02:00			`# hmm, not pretty but for now`
			`@@instance = nil`

more random code 2014-05-02 07:02:25 +02:00			`attr_reader :registers`
			`attr_reader :scratch`
			`attr_reader :pc`
			`attr_reader :stack`
			`# is often a pseudo register (ie doesn't support move or other operations).`
			`# Still, using if to express tests makes sense, not just for`
			`# consistency in this code, but also because that is what is actually done`
			`attr_reader :status`
more semi random code, a checkpoint 2014-05-03 14:13:44 +02:00
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`# conditions specify all the possibilities for branches. Branches are b + condition`
			`# Example: beq means brach if equal.`
			`# :al means always, so bal is an unconditional branch (but b() also works)`
			`CONDITIONS = [ :al , :eq , :ne , :lt , :le, :ge, :gt , :cs , :mi , :hi , :cc , :pl, :ls , :vc , :vs ]`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00
			`# here we create the shortcuts for the "standard" instructions, see above`
			`# Derived machines may use own instructions and define functions for them if so desired`
			`def initialize`
			`[:push, :pop].each do \|inst\|`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`define_instruction_one(inst , StackInstruction)`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00			`end`
			`[:adc, :add, :and, :bic, :eor, :orr, :rsb, :rsc, :sbc, :sub].each do \|inst\|`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`define_instruction_one(inst , LogicInstruction)`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00			`end`
			`[:mov, :mvn].each do \|inst\|`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`define_instruction_one(inst , MoveInstruction)`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00			`end`
			`[:cmn, :cmp, :teq, :tst].each do \|inst\|`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`define_instruction_two(inst , CompareInstruction)`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00			`end`
			`[:strb, :str , :ldrb, :ldr].each do \|inst\|`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`define_instruction_one(inst , MemoryInstruction)`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00			`end`
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`[:b, :call , :swi].each do \|inst\|`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`define_instruction_one(inst , CallInstruction)`
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`end`
			`# create all possible brach instructions, but the CallInstruction demangles the`
			`# code, and has opcode set to :b and :condition_code set to the condition`
			`CONDITIONS.each do \|suffix\|`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`define_instruction_one("b#{suffix}".to_sym , CallInstruction)`
			`define_instruction_one("call#{suffix}".to_sym , CallInstruction)`
so close i can smell it, checkpoint 2014-05-03 21:18:04 +02:00			`end`
			`end`

			`def create_method(name, &block)`
			`self.class.send(:define_method, name , &block)`
			`end`


more semi random code, a checkpoint 2014-05-03 14:13:44 +02:00			`def self.instance`
			`@@instance`
			`end`
			`def self.instance= machine`
			`@@instance = machine`
			`end`
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`private`
			`#defining the instruction (opcode, symbol) as an given class.`
			`# the class is a Vm::Instruction derived base class and to create machine specific function`
			`# an actual machine must create derived classes (from this base class)`
			`# These instruction classes must follow a naming pattern and take a hash in the contructor`
			`# Example, a mov() opcode instantiates a Vm::MoveInstruction`
			`# for an Arm machine, a class Arm::MoveInstruction < Vm::MoveInstruction exists, and it will`
			`# be used to define the mov on an arm machine.`
			`# This methods picks up that derived class and calls a define_instruction methods that can`
			`# be overriden in subclasses`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`def define_instruction_one(inst , clazz , defaults = {} )`
			`clazz = class_for(clazz)`
			`create_method(inst) do \|first , options = nil\|`
			`options = {} if options == nil`
			`options.merge defaults`
			`options[:opcode] = inst`
			`clazz.new(first , options)`
			`end`
			`end`

			`# same for two args (left right, from to etc)`
			`def define_instruction_two(inst , clazz , defaults = {} )`
			`clazz = class_for(clazz)`
			`create_method(inst) do \|first ,second , options = nil\|`
			`options = {} if options == nil`
			`options.merge defaults`
			`options[:opcode] = inst`
			`clazz.new(first , second ,options)`
			`end`
			`end`

			`def class_for clazz`
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`c_name = clazz.name`
			`my_module = self.class.name.split("::").first`
			`clazz_name = clazz.name.split("::").last`
			`if(my_module != Vm )`
			`module_class = eval("#{my_module}::#{clazz_name}") rescue nil`
			`clazz = module_class if module_class`
			`end`
started naming instruction arguments properly, starting with compare 2014-05-18 10:11:26 +02:00			`clazz`
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`end`
Semi random code for the next step 2014-04-28 21:08:09 +02:00			`end`
			`end`