module Risc class LinkException < Exception end # Assemble the object machine into a binary. # Assemble first to get positions, then write # The assemble function determines the length of an object and then actually # writes the bytes they are pretty much dependant. In an earlier version they were # functions on the objects, but now it has gone to a visitor pattern. class Assembler include Logging log_level :info MARKER = 0xA51AF00D def initialize( machine , objects) @machine = machine @objects = objects @load_at = 0x8054 # this is linux/arm end def assemble at = 0 #need the initial jump at 0 and then functions @machine.cpu_init.set_position( 0) at = @machine.cpu_init.byte_length at = assemble_objects( at ) # and then everything code asseble_code_from( at ) end def asseble_code_from( at ) @objects.each do |id , objekt| next unless objekt.is_a? Parfait::TypedMethod log.debug "CODE1 #{objekt.name}" # create binary for assembly objekt.create_binary if objekt.is_a? Parfait::TypedMethod binary = objekt.binary Positioned.set_position(binary,at) objekt.cpu_instructions.set_position( at + 12) # BinaryCode header len = 4 * 14 at += binary.padded_length nekst = binary.next while(nekst) Positioned.set_position(nekst , at) at += binary.padded_length nekst = nekst.next len += 4 * 16 #puts "LENGTH #{len}" end log.debug "CODE2 #{objekt.name} at #{Positioned.position(binary)} len: #{len}" end at end def assemble_objects( at ) at += 8 # thats the padding # want to have the objects first in the executable @objects.each do | id , objekt| if objekt.is_a? Risc::Label # will get assembled as method.cpu_instructions Positioned.set_position(objekt,at) next end next if objekt.is_a? Parfait::BinaryCode Positioned.set_position(objekt,at) at += objekt.padded_length end at end def write_as_string # must be same order as assemble begin return try_write rescue LinkException # knowing that we fix the problem, we hope to get away with retry. retry end end # private method to implement write_as_string. May throw link Exception in which # case we try again. Once. def try_write assemble try_write_debug try_write_create_binary try_write_objects try_write_method log.debug "Assembled #{stream_position} bytes" return @stream.string end # debugging loop accesses all positions to force an error if it's not set def try_write_debug all = @objects.values.sort{|a,b| Positioned.position(a) <=> Positioned.position(b)} all.each do |objekt| next if objekt.is_a?(Risc::Label) log.debug "Linked #{objekt.class}(#{objekt.object_id}) at #{Positioned.position(objekt)} / #{objekt.padded_length}" Positioned.position(objekt) end end def try_write_create_binary # first we need to create the binary code for the methods @objects.each do |id , objekt| next unless objekt.is_a? Parfait::TypedMethod assemble_binary_method(objekt) end @stream = StringIO.new @machine.init.assemble( @stream ) 8.times do @stream.write_unsigned_int_8(0) end end def try_write_objects # then the objects , not code yet @objects.each do | id, objekt| next if objekt.is_a? Parfait::BinaryCode next if objekt.is_a? Risc::Label # ignore write_any( objekt ) end end def try_write_method # then write the methods to file @objects.each do |id, objekt| next unless objekt.is_a? Parfait::BinaryCode write_any( objekt ) end end # assemble the MethodSource into a stringio # and then plonk that binary data into the method.code array def assemble_binary_method method stream = StringIO.new #puts "Method #{method.source.cpu_instructions.to_ac}" begin #puts "assemble #{method.source.cpu_instructions}" method.cpu_instructions.assemble_all( stream ) rescue => e log.debug "Assembly error #{method.name}\n#{method.to_rxf.to_s[0...2000]}" raise e end write_binary_method_to_stream( method, stream) end def write_binary_method_to_stream(method, stream) write_binary_method_checks(method,stream) index = 1 stream.each_byte do |b| method.binary.set_char(index , b ) index = index + 1 end end def write_binary_method_checks(method,stream) stream.rewind length = stream.length binary = method.binary total_byte_length = method.cpu_instructions.total_byte_length log.debug "Assembled code #{method.name} with length #{length}" raise "length error #{binary.char_length} != #{total_byte_length}" if binary.char_length <= total_byte_length raise "length error #{length} != #{total_byte_length}" if total_byte_length != length end def write_any obj write_any_log( obj , "Write") if @stream.length != Positioned.position(obj) raise "Write #{obj.class} #{obj.object_id} at #{stream_position} not #{Positioned.position(obj)}" end write_any_out(obj) write_any_log( obj , "Wrote") Positioned.position(obj) end def write_any_log( obj , at) log.debug "#{at} #{obj.class}(#{obj.object_id}) at stream #{stream_position} pos:#{Positioned.position(obj)} , len:#{obj.padded_length}" end def write_any_out(obj) if obj.is_a?(Parfait::Word) or obj.is_a?(Symbol) write_String obj else write_object obj end end # write type of the instance, and the variables that are passed # variables ar values, ie int or refs. For refs the object needs to save the object first def write_object( object ) write_object_check(object) obj_written = write_object_variables(object) log.debug "instances=#{object.get_instance_variables.inspect} mem_len=#{object.padded_length}" indexed_written = write_object_indexed(object) log.debug "type #{obj_written} , total #{obj_written + indexed_written} (array #{indexed_written})" log.debug "Len = #{object.get_length} , inst = #{object.get_type.instance_length}" if object.is_a? Parfait::Type pad_after( obj_written + indexed_written ) Positioned.position(object) end def write_object_check(object) log.debug "Write object #{object.class} #{object.inspect}" unless @objects.has_key? object.object_id raise "Object(#{object.object_id}) not linked #{object.inspect}" end end def write_object_indexed(object) written = 0 if( object.is_a? Parfait::List) object.each do |inst| write_ref_for(inst) written += 4 end end written end def write_object_variables(object) @stream.write_signed_int_32( MARKER ) written = 0 # compensate for the "secrect" marker object.get_instance_variables.each do |var| inst = object.get_instance_variable(var) #puts "Nil for #{object.class}.#{var}" unless inst write_ref_for(inst) written += 4 end written end def write_BinaryCode code write_String code end def write_String( string ) if string.is_a? Parfait::Word str = string.to_string raise "length mismatch #{str.length} != #{string.char_length}" if str.length != string.char_length end str = string.to_s if string.is_a? Symbol log.debug "#{string.class} is #{string} at #{Positioned.position(string)} length #{string.length}" write_checked_string(string , str) end def write_checked_string(string, str) @stream.write_signed_int_32( MARKER ) write_ref_for( string.get_type ) #ref @stream.write_signed_int_32( str.length ) #int @stream.write str pad_after(str.length + 8 ) # type , length *4 == 12 log.debug "String (#{string.length}) stream #{@stream.length}" end def write_Symbol(sym) return write_String(sym) end private # write means we write the resulting address straight into the assembler stream # object means the object of which we write the address def write_ref_for object case object when nil @stream.write_signed_int_32(0) when Fixnum @stream.write_signed_int_32(object) else @stream.write_signed_int_32(Positioned.position(object) + @load_at) end end # pad_after is always in bytes and pads (writes 0's) up to the next 8 word boundary def pad_after length before = stream_position pad = Padding.padding_for(length) - 4 # four is for the MARKER we write pad.times do @stream.write_unsigned_int_8(0) end after = stream_position log.debug "padded #{length} with #{pad} stream #{before}/#{after}" end # return the stream length as hex def stream_position @stream.length end end RxFile::Volotile.add(Assembler , [:objects]) end