rubyx/lib/arm/translator.rb

module Arm
  class Translator

    # translator should translate from register instructio set to it's own (arm eg)
    # for each instruction we call the translator with translate_XXX
    #  with XXX being the class name.
    # the result is replaced in the stream
    def translate  instruction
      class_name = instruction.class.name.split("::").last
      self.send( "translate_#{class_name}".to_sym , instruction)
    end

    # don't replace labels
    def translate_Label code
      nil
    end

    # Arm stores the return address in a register (not on the stack)
    # The register is called link , or lr for short .
    # Maybe because it provides the "link" back to the caller
    # the vm defines a register for the location, so we store it there.
    def translate_SaveReturn code
      ArmMachine.str( :lr ,  code.register , 4 * code.index )
    end

    def translate_GetSlot code
      # times 4 because arm works in bytes, but vm in words
      if(code.index.is_a? Numeric)
        ArmMachine.ldr( code.register ,  code.array , 4 * code.index )
      else
        ArmMachine.ldr( code.register ,  code.array , code.index )
      end
    end

    def translate_RegisterTransfer code
      # Register machine convention is from => to
      # But arm has the receiver/result as the first
      ArmMachine.mov( code.to , code.from)
    end

    def translate_SetSlot code
      # times 4 because arm works in bytes, but vm in words
      ArmMachine.str( code.register ,  code.array , 4 * code.index )
    end

    def translate_FunctionCall code
      ArmMachine.call( code.method )
    end

    def translate_FunctionReturn code
      ArmMachine.ldr( :pc ,  code.register , 4 * code.index )
    end

    def translate_LoadConstant code
      constant = code.constant
      if constant.is_a?(Parfait::Object) or constant.is_a?(Symbol) or constant.is_a?(Register::Label)
        return ArmMachine.add( code.register , constant )
      else
        return ArmMachine.mov( code.register ,  constant )
      end
    end

    # This implements branch logic, which is simply assembler branch
    #
    # The only target for a call is a Block, so we just need to get the address for the code
    # and branch to it.
    def translate_Branch code
      ArmMachine.b( code.label )
    end

    def translate_Syscall code
      call_codes = { :putstring => 4 , :exit => 1    }
      int_code = call_codes[code.name]
      raise "Not implemented syscall, #{code.name}" unless int_code
      send( code.name , int_code )
    end

    def putstring int_code
      codes = ArmMachine.ldr( :r1 , Register.message_reg, 4 * Register.resolve_index(:message , :receiver))
      codes.append ArmMachine.add( :r1 ,  :r1 , 8 )
      codes.append ArmMachine.mov( :r0 ,  1 )
      codes.append ArmMachine.mov( :r2 ,  12 ) # String length, obvious TODO
      syscall(int_code , codes )
    end

    def exit int_code
      codes = Register::Label.new(nil , "exit")
      syscall int_code , codes
    end

    private

    # syscall is always triggered by swi(0)
    # The actual code (ie the index of the kernel function) is in r7
    def syscall int_code , codes
      codes.append ArmMachine.mov( :r7 ,  int_code )
      codes.append ArmMachine.swi( 0 )
      codes
    end

  end
end
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`module Arm`
			`class Translator`

use translator and remove passes the only passes that were left were reg -> arm those are almost completely one to one, so the idea of passes didn’t fit 2015-10-24 16:11:18 +02:00			`# translator should translate from register instructio set to it's own (arm eg)`
			`# for each instruction we call the translator with translate_XXX`
			`# with XXX being the class name.`
			`# the result is replaced in the stream`
			`def translate instruction`
			`class_name = instruction.class.name.split("::").last`
			`self.send( "translate_#{class_name}".to_sym , instruction)`
			`end`

remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`# don't replace labels`
			`def translate_Label code`
			`nil`
			`end`

			`# Arm stores the return address in a register (not on the stack)`
			`# The register is called link , or lr for short .`
			`# Maybe because it provides the "link" back to the caller`
			`# the vm defines a register for the location, so we store it there.`
			`def translate_SaveReturn code`
			`ArmMachine.str( :lr , code.register , 4 * code.index )`
			`end`

			`def translate_GetSlot code`
			`# times 4 because arm works in bytes, but vm in words`
allow for registers in get slot 2015-11-07 18:38:03 +01:00			`if(code.index.is_a? Numeric)`
			`ArmMachine.ldr( code.register , code.array , 4 * code.index )`
			`else`
			`ArmMachine.ldr( code.register , code.array , code.index )`
			`end`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`end`

			`def translate_RegisterTransfer code`
			`# Register machine convention is from => to`
			`# But arm has the receiver/result as the first`
			`ArmMachine.mov( code.to , code.from)`
			`end`

			`def translate_SetSlot code`
			`# times 4 because arm works in bytes, but vm in words`
			`ArmMachine.str( code.register , code.array , 4 * code.index )`
			`end`

			`def translate_FunctionCall code`
			`ArmMachine.call( code.method )`
			`end`

			`def translate_FunctionReturn code`
			`ArmMachine.ldr( :pc , code.register , 4 * code.index )`
			`end`

			`def translate_LoadConstant code`
			`constant = code.constant`
let labels be constants 2015-11-03 15:20:25 +01:00			`if constant.is_a?(Parfait::Object) or constant.is_a?(Symbol) or constant.is_a?(Register::Label)`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`return ArmMachine.add( code.register , constant )`
			`else`
let labels be constants 2015-11-03 15:20:25 +01:00			`return ArmMachine.mov( code.register , constant )`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`end`
			`end`

			`# This implements branch logic, which is simply assembler branch`
			`#`
			`# The only target for a call is a Block, so we just need to get the address for the code`
			`# and branch to it.`
			`def translate_Branch code`
use translator and remove passes the only passes that were left were reg -> arm those are almost completely one to one, so the idea of passes didn’t fit 2015-10-24 16:11:18 +02:00			`ArmMachine.b( code.label )`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`end`
use translator and remove passes the only passes that were left were reg -> arm those are almost completely one to one, so the idea of passes didn’t fit 2015-10-24 16:11:18 +02:00
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`def translate_Syscall code`
			`call_codes = { :putstring => 4 , :exit => 1 }`
			`int_code = call_codes[code.name]`
			`raise "Not implemented syscall, #{code.name}" unless int_code`
			`send( code.name , int_code )`
			`end`

			`def putstring int_code`
			`codes = ArmMachine.ldr( :r1 , Register.message_reg, 4 * Register.resolve_index(:message , :receiver))`
			`codes.append ArmMachine.add( :r1 , :r1 , 8 )`
			`codes.append ArmMachine.mov( :r0 , 1 )`
			`codes.append ArmMachine.mov( :r2 , 12 ) # String length, obvious TODO`
			`syscall(int_code , codes )`
			`end`

			`def exit int_code`
			`codes = Register::Label.new(nil , "exit")`
			`syscall int_code , codes`
			`end`

			`private`

			`# syscall is always triggered by swi(0)`
			`# The actual code (ie the index of the kernel function) is in r7`
			`def syscall int_code , codes`
			`codes.append ArmMachine.mov( :r7 , int_code )`
			`codes.append ArmMachine.swi( 0 )`
			`codes`
			`end`

			`end`
			`end`