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 indexes are
    #  in bytes, so *4
    # if an instruction is passed in we get the index with index function
    def arm_index index
      index = index.index if index.is_a?(Register::Instruction)
      raise "index error 0" if index == 0
      index * 4
    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 , arm_index(code) )
    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_GetSlot code
      if(code.index.is_a? Numeric)
        ArmMachine.ldr( code.register ,  code.array , arm_index(code) )
      else
        ArmMachine.ldr( code.register ,  code.array , code.index , :shift_lsl => 2 )
      end
    end

    def translate_SetSlot code
      if(code.index.is_a? Numeric)
        ArmMachine.str( code.register ,  code.array , arm_index(code) )
      else
        ArmMachine.str( code.register ,  code.array , code.index , :shift_lsl => 2 )
      end
    end

    def translate_GetByte code
      if(code.index.is_a? Numeric)
        ArmMachine.ldrb( code.register ,  code.array , arm_index(code) )
      else
        ArmMachine.ldrb( code.register ,  code.array , code.index )
      end
    end

    def translate_SetByte code
      if(code.index.is_a? Numeric)
        ArmMachine.strb( code.register ,  code.array , arm_index(code) )
      else
        ArmMachine.strb( code.register ,  code.array , code.index )
      end
    end

    def translate_FunctionCall code
      ArmMachine.b( code.method.instructions )
    end

    def translate_FunctionReturn code
      ArmMachine.ldr( :pc ,  code.register , arm_index(code) )
    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

    def translate_OperatorInstruction code
      left = code.left
      right = code.right
      case code.operator.to_s
      when "+"
        c = ArmMachine.add(left , left , right)
      when "-"
        c = ArmMachine.sub(left , left , right)
      when "&"
        c = ArmMachine.and(left , left , right)
      when "|"
        c = ArmMachine.orr(left , left , right)
      when "*"
        c = ArmMachine.mul(left , right , left) #arm rule about left not being result, lukily commutative
      when ">>"
        c = ArmMachine.mov(left , left , :shift_asr => right) #arm rule about left not being result, lukily commutative
      when "<<"
        c = ArmMachine.mov(left , left , :shift_lsl => right) #arm rule about left not being result, lukily commutative
      else
        raise "unimplemented  '#{code.operator}' #{code}"
      end
      c
    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_IsPlus code
      ArmMachine.bpl( code.label)
    end

    def translate_IsMinus code
      ArmMachine.bmi( code.label)
    end

    def translate_IsZero code
      ArmMachine.beq( code.label)
    end

    def translate_IsOverflow code
      ArmMachine.bvs( 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.add( :r1 ,  :r1 , 12 ) # adjust for object header
      codes.append ArmMachine.mov( :r0 ,  1 )  # write to stdout == 1
      syscall(int_code , codes )
    end

    def exit int_code
      codes =  ArmMachine.ldr( :r0 ,  :r0 , arm_index(Register.resolve_index(:Message , :return_value)) )
      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`

fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`# arm indexes are`
			`# in bytes, so *4`
fix arm (assembled) indexing by having a dummy 0 index in salaam. when assembled 2015-11-15 19:42:07 +01:00			`# if an instruction is passed in we get the index with index function`
fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`def arm_index index`
			`index = index.index if index.is_a?(Register::Instruction)`
			`raise "index error 0" if index == 0`
fix arm (assembled) indexing by having a dummy 0 index in salaam. when assembled 2015-11-15 19:42:07 +01:00			`index * 4`
fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`end`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`# 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`
fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`ArmMachine.str( :lr , code.register , arm_index(code) )`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`end`

translate and interpret new instructions 2015-11-19 09:09:55 +01:00			`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`

remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`def translate_GetSlot code`
allow for registers in get slot 2015-11-07 18:38:03 +01:00			`if(code.index.is_a? Numeric)`
fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`ArmMachine.ldr( code.register , code.array , arm_index(code) )`
allow for registers in get slot 2015-11-07 18:38:03 +01:00			`else`
use arm shift at runtime arm indexes are in bytes (x4) at compile time but at runtime we only have the array indexes, iw word indexes arm has the nice barrel shifter to save us an extra instruction 2015-11-19 11:48:13 +01:00			`ArmMachine.ldr( code.register , code.array , code.index , :shift_lsl => 2 )`
allow for registers in get slot 2015-11-07 18:38:03 +01:00			`end`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`end`

			`def translate_SetSlot code`
add set_internal and the set_slot with register very much like the get_slot for get_internal 2015-11-08 16:10:36 +01:00			`if(code.index.is_a? Numeric)`
fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`ArmMachine.str( code.register , code.array , arm_index(code) )`
add set_internal and the set_slot with register very much like the get_slot for get_internal 2015-11-08 16:10:36 +01:00			`else`
use arm shift at runtime arm indexes are in bytes (x4) at compile time but at runtime we only have the array indexes, iw word indexes arm has the nice barrel shifter to save us an extra instruction 2015-11-19 11:48:13 +01:00			`ArmMachine.str( code.register , code.array , code.index , :shift_lsl => 2 )`
add set_internal and the set_slot with register very much like the get_slot for get_internal 2015-11-08 16:10:36 +01:00			`end`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`end`

translate and interpret new instructions 2015-11-19 09:09:55 +01:00			`def translate_GetByte code`
			`if(code.index.is_a? Numeric)`
			`ArmMachine.ldrb( code.register , code.array , arm_index(code) )`
			`else`
			`ArmMachine.ldrb( code.register , code.array , code.index )`
			`end`
			`end`

			`def translate_SetByte code`
			`if(code.index.is_a? Numeric)`
			`ArmMachine.strb( code.register , code.array , arm_index(code) )`
			`else`
			`ArmMachine.strb( code.register , code.array , code.index )`
			`end`
			`end`

remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`def translate_FunctionCall code`
fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`ArmMachine.b( code.method.instructions )`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`end`

			`def translate_FunctionReturn code`
fix arm indexes needs rethought fixed for static use, but what about dynamic 2015-11-14 23:35:12 +01:00			`ArmMachine.ldr( :pc , code.register , arm_index(code) )`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`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`

update arm and implement most operators multiplication wasn’t implemented and division isn’t part if arm neither is rotate by register 2015-11-12 19:02:14 +01:00			`def translate_OperatorInstruction code`
			`left = code.left`
			`right = code.right`
			`case code.operator.to_s`
			`when "+"`
			`c = ArmMachine.add(left , left , right)`
			`when "-"`
			`c = ArmMachine.sub(left , left , right)`
			`when "&"`
			`c = ArmMachine.and(left , left , right)`
			`when "\|"`
			`c = ArmMachine.orr(left , left , right)`
			`when "*"`
			`c = ArmMachine.mul(left , right , left) #arm rule about left not being result, lukily commutative`
implement arm branches which backfired into interpreter as plus actually means 0 or plus in arm may still change back but for now 2015-11-13 23:20:03 +01:00			`when ">>"`
			`c = ArmMachine.mov(left , left , :shift_asr => right) #arm rule about left not being result, lukily commutative`
			`when "<<"`
			`c = ArmMachine.mov(left , left , :shift_lsl => right) #arm rule about left not being result, lukily commutative`
update arm and implement most operators multiplication wasn’t implemented and division isn’t part if arm neither is rotate by register 2015-11-12 19:02:14 +01:00			`else`
			`raise "unimplemented '#{code.operator}' #{code}"`
			`end`
			`c`
			`end`

remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`# 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
implement arm branches which backfired into interpreter as plus actually means 0 or plus in arm may still change back but for now 2015-11-13 23:20:03 +01:00			`def translate_IsPlus code`
			`ArmMachine.bpl( code.label)`
			`end`

			`def translate_IsMinus code`
			`ArmMachine.bmi( code.label)`
			`end`

			`def translate_IsZero code`
			`ArmMachine.beq( code.label)`
			`end`

			`def translate_IsOverflow code`
			`ArmMachine.bvs( code.label)`
			`end`

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`
putstring unfolds length which means sys call doesn’t need to and also interpreter sometimes gets a symbol length 2015-11-16 17:03:29 +01:00			`codes = ArmMachine.add( :r1 , :r1 , 12 ) # adjust for object header`
implement string length 2015-11-15 10:28:16 +01:00			`codes.append ArmMachine.mov( :r0 , 1 ) # write to stdout == 1`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`syscall(int_code , codes )`
			`end`

			`def exit int_code`
putstring unfolds length which means sys call doesn’t need to and also interpreter sometimes gets a symbol length 2015-11-16 17:03:29 +01:00			`codes = ArmMachine.ldr( :r0 , :r0 , arm_index(Register.resolve_index(:Message , :return_value)) )`
remove passes and achieve the same by translating 2015-10-24 10:42:36 +02:00			`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`