module Risc # An interpreter for the register level. As the register machine is a simple model, # interpreting it is not so terribly difficult. # # There is a certain amount of basic machinery to fetch and execute the next instruction # (as a cpu would), and then there is a method for each instruction. Eg an instruction SlotToReg # will be executed by method execute_SlotToReg # # The Interpreter (a bit like a cpu) has a state flag, a current instruction and registers # We collect the stdout (as a hack not to interpret the OS) in a string. It can also be passed # in to the init, as an IO # class Interpreter # fire events for changed pc and register contents include Util::Eventable include Util::Logging log_level :info attr_reader :instruction , :clock , :pc # current instruction and pc attr_reader :registers # the registers, 16 (a hash, sym -> contents) attr_reader :stdout, :state , :flags # somewhat like the flags on a cpu, hash sym => bool (zero .. . ) # start in state :stopped and set registers to unknown # Linker gives the state of the program # Passing a stdout in (an IO, only << called) can be used to get output immediately. def initialize( linker , stdout = "") @stdout , @clock , @pc , @state = stdout, 0 , 0 , :stopped @registers = {} reset_flags (0...InterpreterPlatform.new.num_registers).each do |reg| #set_register "r#{reg}".to_sym , "r#{reg}:unknown" end @linker = linker end def start_program() init = @linker.cpu_init set_state(:running) set_pc( Position.get(init).at ) end def set_state( state ) old = @state return if state == old @state = state trigger(:state_changed , old , state ) end # return the name of the register that the argument is mapped to # this info is in the Platform object in the linker instance # eg: syscall_1 maps to :r0 , and :message to :r13 # So as not to hardcode values (as used to ) def std_reg(name) @linker.platform.assign_reg?(name) end # set all flags to false def reset_flags @flags = { :zero => false , :plus => false , :minus => false , :overflow => false } end def set_pc( pos ) raise "Not int #{pos}" unless pos.is_a? Numeric position = Position.at(pos) raise "No position at 0x#{pos.to_s(16)}" unless position log.debug "" log.debug "Setting Position #{clock}-#{position}, " set_instruction( position.object ) @clock += 1 @pc = position.at end def set_instruction( instruction ) raise "set to same instruction #{instruction}:#{instruction.class} at #{clock}" if @instruction == instruction #log.debug "Setting Instruction #{instruction.class}" old = @instruction @instruction = instruction trigger(:instruction_changed, old , instruction) set_state( :exited ) unless instruction end def get_register( reg ) reg = reg.symbol if reg.is_a? Risc::RegisterValue #raise "Not a register #{reg}" unless Risc::RegisterValue.look_like_reg(reg) @registers[reg] end def set_register( reg , val ) reg = reg.symbol if reg.is_a? Risc::RegisterValue log.debug "setting #{reg} == #{val}" old = get_register( reg ) if val.is_a? ::Integer @flags[:zero] = (val == 0) @flags[:plus] = (val >= 0) @flags[:minus] = (val < 0) log.debug "Set_flags #{val} :#{@flags.inspect}" else @flags[:zero] = @flags[:plus] = true @flags[:minus] = false end return if old === val val = Parfait.object_space.nil_object if val.nil? #because that's what real code has @registers[reg] = val trigger(:register_changed, reg , old , val) end def tick unless @instruction log.debug "No Instruction , No Tick" return @clock end name = @instruction.class.name.split("::").last log.debug "#{@pc.to_s(16)}:#{@clock}: #{@instruction.to_s}" fetch = send "execute_#{name}" register_dump if fetch pc = @pc + @instruction.byte_length set_pc(pc) else log.debug "No Fetch" end @clock end # Instruction interpretation starts here def execute_DynamicJump method = get_register(@instruction.register) log.debug "Register at: #{@instruction.register} , has #{method.class}" pos = Position.get(method.binary) log.debug "Jump to binary at: #{pos} #{method.name}:#{method.binary.class}" raise "Invalid position for #{method.name}" unless pos.valid? pos = pos + Parfait::BinaryCode.byte_offset set_pc( pos ) false end def execute_Branch label = @instruction.label log.debug "Branch to Label: #{@instruction.label}" pos = Position.get(label).at pos += Parfait::BinaryCode.byte_offset if label.is_a?(Parfait::BinaryCode) set_pc( pos ) false end def execute_IsZero @flags[:zero] ? execute_Branch : true end def execute_IsNotZero @flags[:zero] ? true : execute_Branch end def execute_IsPlus @flags[:plus] ? execute_Branch : true end def execute_IsMinus @flags[:minus] ? execute_Branch : true end def execute_LoadConstant to = @instruction.register value = @instruction.constant value = value.address if value.is_a?(Label) set_register( to , value ) true end alias :execute_LoadData :execute_LoadConstant def execute_SlotToReg object = get_register( @instruction.array ) if( @instruction.index.is_a?(Numeric) ) index = @instruction.index else index = get_register(@instruction.index) end case object when Symbol if(index == 0) value = object.get_type elsif(index==1) value = object.to_s.length else raise "Must convert symbol to word:#{object}:#{index}" end when nil raise "error #{@instruction} retrieves nil" else value = object.get_internal_word( index ) #log.debug "Getting #{index} from #{object} value=#{value}" #log.debug "type=#{object.type} get_type=#{object.get_type} intern=#{object.get_internal_word(0)}" end log.debug "#{@instruction} == #{object}(#{Position.get(object)}) (#{value}|#{index})" set_register( @instruction.register , value ) true end def execute_RegToSlot value = get_register( @instruction.register ) object = get_register( @instruction.array ) if( @instruction.index.is_a?(Numeric) ) index = @instruction.index else index = get_register(@instruction.index) end object.set_internal_word( index , value ) log.debug "RegToSlot #{object}[#{index}] == #{value}" trigger(:object_changed, @instruction.array , index) true end def execute_ByteToReg object = get_register( @instruction.array ) if( @instruction.index.is_a?(Numeric) ) index = @instruction.index else index = get_register(@instruction.index) end raise "Unsupported action, must convert symbol to word:#{object}" if object.is_a?(Symbol) value = object.get_char( index ) #value = value.object_id unless value.is_a? ::Integer set_register( @instruction.register , value ) true end def execute_RegToByte value = get_register( @instruction.register ) object = get_register( @instruction.array ) if( @instruction.index.is_a?(Numeric) ) index = @instruction.index else index = get_register(@instruction.index) end object.set_char( index , value ) trigger(:object_changed, @instruction.array , index / 4 ) true end def execute_Transfer value = get_register @instruction.from set_register @instruction.to , value true end def execute_FunctionCall meth = @instruction.method at = Position.get(meth.binary) log.debug "Call to #{meth.name} at:#{at}" set_pc(at + Parfait::BinaryCode.byte_offset) false end def execute_FunctionReturn link = get_register( @instruction.register ) log.debug "Return to #{link.to_s(16)}" set_pc link.value false end def execute_Syscall name = @instruction.name ret_value = 0 case name when :putstring ret_value = handle_putstring when :exit set_instruction(nil) return false when :died raise "Method #{@registers[:r1].to_string} not found for #{@registers[std_reg(:syscall_1)]}" else raise "un-implemented syscall #{name}" end set_register( std_reg(:syscall_1) , ret_value ) # syscalls return into syscall_1 true end def handle_putstring # should test length, syscall_3 (syscall_1 is file_descriptor, ie stdout) str = get_register( std_reg(:syscall_2) ) case str when Symbol @stdout << str.to_s @stdout.flush if @stdout.respond_to?(:flush) return str.to_s.length when Parfait::Word @stdout << str.to_string @stdout.flush if @stdout.respond_to?(:flush) return str.char_length else raise "NO string for putstring #{str.class}:#{str.object_id}" unless str.is_a?(Symbol) end end def execute_OperatorInstruction reset_flags left = get_register(@instruction.left) || 0 rr = @instruction.right right = get_register(rr) || 0 result = handle_operator(left,right) if( result > 2**32 ) @flags[:overflow] = true result = result % 2**32 else result = result.to_i end log.debug "#{@instruction} == #{result}(#{result.class}) (#{left}|#{right})" set_register(@instruction.result , result) true end def make_op_arg(arg) case arg when Integer arg when Parfait::Word arg.to_string.to_sym.object_id when String arg.to_sym.object_id when Symbol arg.object_id when Parfait::Object arg.object_id else raise "Op arg #{arg}:#{arg.class}" end end def handle_operator(left, right) left = make_op_arg(left) right = make_op_arg(right) case @instruction.operator when :+ left + right when :- if( left.is_a?(String) or right.is_a?(String)) left == right ? 0 : 1 #for opal, and exception else left - right end when :>> left / (2**right) when :<< left * (2**right) when :* left * right when :& left & right when :| left | right else raise "unimplemented '#{@instruction.operator}' #{@instruction}" end end def register_dump @registers.keys.sort.each do |reg| value = @registers[reg] log.debug "#{reg}:#{value.to_s[0..50]}" end end def old_register_dump (0..7).collect do |reg| value = @registers["r#{reg}".to_sym] "#{reg}-" + case value when String value[0..10] else value.class.name.split("::").last end end.join("|") end end end