rubyx/lib/core/kernel.rb

module Core
  class Kernel
    
    #there are no Kernel instances, only class methods.
    # We use this module syntax to avoid the (ugly) self (also eases searching).
    module ClassMethods
      def main_start block
        #TODO extract args into array of strings
        Vm::RegisterMachine.instance.main_start block
        block
      end
      def main_exit block
        # Machine.exit mov r7 , 0  + swi 0 
        Vm::RegisterMachine.instance.main_exit block
        block
      end
      def function_entry block , f_name
        Vm::RegisterMachine.instance.function_entry block , f_name
      end
      def function_exit block , f_name
        Vm::RegisterMachine.instance.function_exit block , f_name
      end

      #TODO this is in the wrong place. It is a function that returns a function object
      #   while all other methods add their code into some block. --> kernel
      def putstring context 
        function = Vm::Function.new(:putstring , Vm::Integer , [] )
        block = function.body
        # should be another level of indirection, ie write(io,str)
        ret = Vm::RegisterMachine.instance.write_stdout(block)
        function.set_return ret
        function
      end

      def putint context
        putint_function = Vm::Function.new(:putint , Vm::Integer , [] , Vm::Integer )
        buffer = Vm::StringConstant.new("           ") # create a buffer
        context.object_space.add_object buffer              # and save it (function local variable: a no no)
        int = putint_function.receiver
        moved_int = putint_function.new_local
        utoa = context.object_space.get_or_create_class(:Object).get_or_create_function(:utoa)
        b = putint_function.body
        b.mov( moved_int ,  int ) #move arg up
        #b.a       buffer  => int          # string to write to
        
        b.add( int ,  buffer ,nil )   # string to write to
        b.add(int , int ,  buffer.length - 3) 
        b.call( utoa )
        # And now we "just" have to print it, using the write_stdout
        b.add( int ,  buffer , nil )   # string to write to
        b.mov( moved_int ,  buffer.length )
        Vm::RegisterMachine.instance.write_stdout(putint_function.body)
        putint_function
      end

      # The conversion to base10 is quite a bit more complicated than i thought. The bulk of it is in div10
      # We set up variables, do the devision and write the result to the string
      # then check if were done and recurse if neccessary
      # As we write before we recurse (save a push) we write the number backwards
      # arguments: string address , integer
      def utoa context
        utoa_function = Vm::Function.new(:utoa , Vm::Integer , [ Vm::Integer ] , Vm::Integer )
        str_addr = utoa_function.receiver
        number = utoa_function.args.first
        remainder = utoa_function.new_local
        Vm::RegisterMachine.instance.div10( utoa_function.body , number  , remainder )
        # make char out of digit (by using ascii encoding) 48 == "0"
        b = utoa_function.body
        b.add(remainder , remainder , 48)
        b.strb( remainder, str_addr ) 
        b.sub( str_addr,  str_addr ,  1 ) 
        b.cmp( number ,  0 )
        b.callne( utoa_function  )
        return utoa_function
      end

      # testing method, hand coded fibo, expects arg in 1 
      # result comes in 7
      # a hand coded version of the fibonachi numbers
      #  not my hand off course, found in the net from a basic introduction
      def fibo context
        fibo_function = Vm::Function.new(:fibo , Vm::Integer , [] , Vm::Integer )
        result = fibo_function.return_type
        int = fibo_function.receiver
        count = fibo_function.new_local
        f1 = fibo_function.new_local
        f2 = fibo_function.new_local
        b = fibo_function.body
        
        b.cmp  int , 1
        b.mov( result, int , condition_code: :le)
        b.mov( :pc , :lr , condition_code: :le)
        b.push [  count , f1 , f2 , :lr]
        b.mov f1 , 1
        b.mov f2 , 0
        b.sub count , int , 2 

        l = fibo_function.body.new_block("loop")
        
        l.add f1 , f1 , f2
        l.sub f2 , f1 , f2
        l.sub count ,  count , 1 , set_update_status: 1
        l.bpl( l )
        l.mov( result , f1 )
        fibo_function.set_return result
        l.pop [ count , f1 , f2 , :pc]
        fibo_function
      end

    end
    
    extend ClassMethods
  end
end
move kernel to core and apply the classmethod pattern to all core classes 2014-05-06 11:47:07 +02:00			`module Core`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`class Kernel`

			`#there are no Kernel instances, only class methods.`
crystal says Hello. 2014-05-06 20:36:28 +02:00			`# We use this module syntax to avoid the (ugly) self (also eases searching).`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`module ClassMethods`
checkpointing on the mad road to register allocation 2014-05-13 17:21:24 +02:00			`def main_start block`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`#TODO extract args into array of strings`
rename c to register machine 2014-05-21 18:43:46 +02:00			`Vm::RegisterMachine.instance.main_start block`
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`block`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`end`
checkpointing on the mad road to register allocation 2014-05-13 17:21:24 +02:00			`def main_exit block`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`# Machine.exit mov r7 , 0 + swi 0`
rename c to register machine 2014-05-21 18:43:46 +02:00			`Vm::RegisterMachine.instance.main_exit block`
clean up intruction instantiation and fix tests 2014-05-14 09:47:30 +02:00			`block`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`end`
checkpointing on the mad road to register allocation 2014-05-13 17:21:24 +02:00			`def function_entry block , f_name`
rename c to register machine 2014-05-21 18:43:46 +02:00			`Vm::RegisterMachine.instance.function_entry block , f_name`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`end`
checkpointing on the mad road to register allocation 2014-05-13 17:21:24 +02:00			`def function_exit block , f_name`
rename c to register machine 2014-05-21 18:43:46 +02:00			`Vm::RegisterMachine.instance.function_exit block , f_name`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`end`
first oo steps are wobbly, but a string.plus parses 2014-06-01 13:24:54 +02:00
coming together, more and more each day 2014-05-13 20:06:12 +02:00			`#TODO this is in the wrong place. It is a function that returns a function object`
			`# while all other methods add their code into some block. --> kernel`
fixing fragment tests, most done 2014-06-07 22:22:32 +02:00			`def putstring context`
			`function = Vm::Function.new(:putstring , Vm::Integer , [] )`
coming together, more and more each day 2014-05-13 20:06:12 +02:00			`block = function.body`
			`# should be another level of indirection, ie write(io,str)`
rename c to register machine 2014-05-21 18:43:46 +02:00			`ret = Vm::RegisterMachine.instance.write_stdout(block)`
working on registers, awip (a work in progress) 2014-05-25 07:43:07 +02:00			`function.set_return ret`
coming together, more and more each day 2014-05-13 20:06:12 +02:00			`function`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00			`end`
work on Integer.to_s , not a simple task as it turns out 2014-05-15 15:54:23 +02:00
adding receiver and a register abstraction 2014-06-06 20:49:03 +02:00			`def putint context`
			`putint_function = Vm::Function.new(:putint , Vm::Integer , [] , Vm::Integer )`
improve argument handling for puntint 2014-05-19 11:18:01 +02:00			`buffer = Vm::StringConstant.new(" ") # create a buffer`
renamed program to boot_space, as in object_space at boot time. thats the way its going 2014-05-31 11:52:29 +02:00			`context.object_space.add_object buffer # and save it (function local variable: a no no)`
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`int = putint_function.receiver`
start using locals 2014-05-21 18:06:21 +02:00			`moved_int = putint_function.new_local`
kernel functions are not fixed to be Object functions 2014-05-31 15:19:44 +02:00			`utoa = context.object_space.get_or_create_class(:Object).get_or_create_function(:utoa)`
putint works, work on syntax goes on 2014-05-19 14:44:12 +02:00			`b = putint_function.body`
			`b.mov( moved_int , int ) #move arg up`
			`#b.a buffer => int # string to write to`

			`b.add( int , buffer ,nil ) # string to write to`
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`b.add(int , int , buffer.length - 3)`
putint works, work on syntax goes on 2014-05-19 14:44:12 +02:00			`b.call( utoa )`
strangely the coredumps stopped. sure didnt feel like they would 2014-05-16 22:08:45 +02:00			`# And now we "just" have to print it, using the write_stdout`
putint works, work on syntax goes on 2014-05-19 14:44:12 +02:00			`b.add( int , buffer , nil ) # string to write to`
			`b.mov( moved_int , buffer.length )`
rename c to register machine 2014-05-21 18:43:46 +02:00			`Vm::RegisterMachine.instance.write_stdout(putint_function.body)`
improve argument handling for puntint 2014-05-19 11:18:01 +02:00			`putint_function`
work on Integer.to_s , not a simple task as it turns out 2014-05-15 15:54:23 +02:00			`end`
coding the weird udiv10 and utoa 2014-05-16 18:55:46 +02:00
a bit of cleanup and the good news is, we can output a (small) number 2014-05-16 22:24:19 +02:00			`# The conversion to base10 is quite a bit more complicated than i thought. The bulk of it is in div10`
			`# We set up variables, do the devision and write the result to the string`
			`# then check if were done and recurse if neccessary`
			`# As we write before we recurse (save a push) we write the number backwards`
improve argument handling for puntint 2014-05-19 11:18:01 +02:00			`# arguments: string address , integer`
coding the weird udiv10 and utoa 2014-05-16 18:55:46 +02:00			`def utoa context`
adding receiver and a register abstraction 2014-06-06 20:49:03 +02:00			`utoa_function = Vm::Function.new(:utoa , Vm::Integer , [ Vm::Integer ] , Vm::Integer )`
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`str_addr = utoa_function.receiver`
			`number = utoa_function.args.first`
start using locals 2014-05-21 18:06:21 +02:00			`remainder = utoa_function.new_local`
rename c to register machine 2014-05-21 18:43:46 +02:00			`Vm::RegisterMachine.instance.div10( utoa_function.body , number , remainder )`
a bit of cleanup and the good news is, we can output a (small) number 2014-05-16 22:24:19 +02:00			`# make char out of digit (by using ascii encoding) 48 == "0"`
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`b = utoa_function.body`
			`b.add(remainder , remainder , 48)`
fix the load memory instruction 2014-06-01 21:06:59 +02:00			`b.strb( remainder, str_addr )`
putint works, work on syntax goes on 2014-05-19 14:44:12 +02:00			`b.sub( str_addr, str_addr , 1 )`
			`b.cmp( number , 0 )`
			`b.callne( utoa_function )`
improve argument handling for puntint 2014-05-19 11:18:01 +02:00			`return utoa_function`
coding the weird udiv10 and utoa 2014-05-16 18:55:46 +02:00			`end`
adds hand coded fibo, works 2014-05-19 16:32:41 +02:00
fix the handcoded fibonacci (registers again) 2014-05-25 12:34:06 +02:00			`# testing method, hand coded fibo, expects arg in 1`
			`# result comes in 7`
adds hand coded fibo, works 2014-05-19 16:32:41 +02:00			`# a hand coded version of the fibonachi numbers`
			`# not my hand off course, found in the net from a basic introduction`
			`def fibo context`
adding receiver and a register abstraction 2014-06-06 20:49:03 +02:00			`fibo_function = Vm::Function.new(:fibo , Vm::Integer , [] , Vm::Integer )`
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`result = fibo_function.return_type`
			`int = fibo_function.receiver`
move towards locals (not hardcoding registers) 2014-05-21 18:27:27 +02:00			`count = fibo_function.new_local`
			`f1 = fibo_function.new_local`
			`f2 = fibo_function.new_local`
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`b = fibo_function.body`
fix fibo with new syntax. certainly works for operators, but not everything 2014-05-21 11:47:40 +02:00
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`b.cmp int , 1`
fix fibo with new syntax. certainly works for operators, but not everything 2014-05-21 11:47:40 +02:00			`b.mov( result, int , condition_code: :le)`
			`b.mov( :pc , :lr , condition_code: :le)`
			`b.push [ count , f1 , f2 , :lr]`
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`b.mov f1 , 1`
			`b.mov f2 , 0`
			`b.sub count , int , 2`
fix fibo with new syntax. certainly works for operators, but not everything 2014-05-21 11:47:40 +02:00
removed the (too) fancy dsl. Also introduce register indirection 2014-06-07 16:59:44 +02:00			`l = fibo_function.body.new_block("loop")`

			`l.add f1 , f1 , f2`
			`l.sub f2 , f1 , f2`
			`l.sub count , count , 1 , set_update_status: 1`
fix the handcoded fibonacci (registers again) 2014-05-25 12:34:06 +02:00			`l.bpl( l )`
			`l.mov( result , f1 )`
			`fibo_function.set_return result`
fix fibo with new syntax. certainly works for operators, but not everything 2014-05-21 11:47:40 +02:00			`l.pop [ count , f1 , f2 , :pc]`
adds hand coded fibo, works 2014-05-19 16:32:41 +02:00			`fibo_function`
			`end`

more random code 2014-05-02 07:02:25 +02:00			`end`
work on function entry and exit. fix stack instructions 2014-05-06 11:42:43 +02:00
			`extend ClassMethods`
more random code 2014-05-02 07:02:25 +02:00			`end`
			`end`