rubyx/lib/vool/statements/send_statement.rb
2017-09-14 18:42:01 +03:00

117 lines
4.3 KiB
Ruby

module Vool
class SendStatement < Statement
attr_reader :name , :receiver , :arguments
def initialize(name , receiver , arguments )
@name , @receiver , @arguments = name , receiver , arguments
@arguments ||= []
end
def collect(arr)
@receiver.collect(arr)
@arguments.each do |arg|
arg.collect(arr)
end
super
end
# Sending in a dynamic language is off course not as simple as just calling.
# The function that needs to be called depends after all on the receiver,
# and no guarantees can be made on what that is.
#
# It helps to know that usually (>99%) the class of the receiver does not change.
# Our stategy then is to cache the functions and only dynamically determine it in
# case of a miss (the 1%, and first invocation)
#
# As cache key we must use the type of the object (which is the first word of _every_ object)
# as that is constant, and function implementations depend on the type (not class)
#
# A Send breaks down to 2 steps:
# - Setting up the next message, with receiver, arguments, and (importantly) return address
# - a CachedCall , or a SimpleCall, depending on wether the receiver type can be determined
#
# FIXME: we now presume direct (assignable) values for the arguments and receiver.
# in a not so distant future, temporary variables will have to be created
# and complex statements hoisted to assign to them. pps: same as in conditions
def to_mom( in_method )
if(@receiver.ct_type)
simple_call(in_method)
else
cached_call(in_method)
end
end
def message_setup(in_method)
setup = [Mom::MessageSetup.new(in_method)]
receiver = @receiver.slot_class.new([:message , :next_message , :receiver] , @receiver)
arg_target = [:message , :next_message , :arguments]
args = []
@arguments.each_with_index do |arg , index|
args << arg.slot_class.new( arg_target + [index] , arg)
end
setup << Mom::ArgumentTransfer.new( receiver , args )
end
def simple_call(in_method)
type = @receiver.ct_type
called_method = type.resolve_method(@name)
raise "No method #{@name} for #{type}" unless called_method
Mom::Statements.new( message_setup(in_method) << Mom::SimpleCall.new( called_method) )
end
# this breaks cleanly into two parts:
# - check the cached type and if neccessary update
# - call the cached method
def cached_call(in_method)
create_tmps(in_method)
Mom::Statements.new( cache_check(in_method) + call_cached_method(in_method) )
end
def flatten
raise "flat"
end
# check that current type is the cached type
# if not, change and find method for the type (simple_call to resolve_method)
# conceptually easy in ruby, but we have to compile that "easy" ruby
def cache_check(in_method)
# if cached_type != current_type
# cached_type = current_type
# cached_method = current_type.resolve_method(method.name)
if_true = [build_type_cache_update , build_method_cache_update] #@if_true.to_mom( in_method ) #find and assign
[Mom::IfStatement.new( build_condition , if_true )]
end
# this may look like a simple_call, but the difference is that we don't know
# the method until run-time. Alas the setup is the same
def call_cached_method(in_method)
message_setup(in_method) << Mom::DynamicCall.new( method_var_name)
end
private
# cached type and method are stored in the frame as local variables.
# this creates the varables in the frame. Names are method_var_name and type_var_name
def create_tmps(in_method)
in_method.create_tmp
end
# we store the (one!) cached mathod in the frame, under the name that this
# method returns
def method_var_name
"cached_method_#{object_id}"
end
def type_var_name
"cached_type_#{object_id}"
end
private
def build_condition
cached_type = Mom::SlotDefinition.new(:message , [:frame , type_var_name])
current_type = Mom::SlotDefinition.new(:message , [:self , :type])
Mom::NotSameCheck.new(cached_type , current_type)
end
def build_type_cache_update
end
def build_method_cache_update
end
end
end