History

Torsten Ruger 474cd4b348 linker and collector test work again had to give space a fixed number of addresses		2018-07-02 16:19:01 +03:00
..
builtin	unify space collection attribute naming	2018-07-02 15:49:51 +03:00
instructions	clean up booting	2018-07-01 14:12:42 +03:00
position	code listener now get platform explicitly	2018-07-02 09:39:07 +03:00
assembler.rb	have to pass constants around now	2018-07-01 14:11:29 +03:00
binary_writer.rb	jump was written off the end of binary code, fixed	2018-05-28 11:45:04 +03:00
builder.rb	back to method_compiler	2018-06-30 23:26:28 +03:00
builtin.rb	let boot_functions return the compilers	2018-06-30 23:16:17 +03:00
collector.rb	have to pass constants around now	2018-07-01 14:11:29 +03:00
fake_memory.rb	use fake memory	2018-05-28 15:09:59 +03:00
instruction.rb	split create_binary into two phases	2018-06-17 13:53:17 +03:00
interpreter_platform.rb	fix platform derivation and some tests	2018-07-01 21:27:27 +03:00
interpreter.rb	linker and collector test work again	2018-07-02 16:19:01 +03:00
linker.rb	linker and collector test work again	2018-07-02 16:19:01 +03:00
method_compiler.rb	return the linker from mom_compiler	2018-07-01 21:51:48 +03:00
padding.rb	fix opal error	2018-05-20 15:51:36 +03:00
parfait_adapter.rb	move adapter stuff around	2018-06-29 14:26:25 +03:00
parfait_boot.rb	unify space collection attribute naming	2018-07-02 15:49:51 +03:00
platform.rb	platform helper	2018-07-02 09:36:29 +03:00
README.md	polish docs	2018-03-11 16:11:15 +05:30
register_value.rb	rename risc_value to register_value	2018-06-29 11:39:07 +03:00
text_writer.rb	objects didn't get positions	2018-06-16 10:58:54 +03:00

README.md

Risc Machine

The RiscMachine, is an abstract machine with registers. Think of it as an arm machine with normal instruction names. It is not however an abstraction of existing hardware, but only of that subset that we need.

Our primary objective is to compile typed code to this level, so the register machine has:

object access instructions
object load
object oriented call semantics
extended (and extensible) branching
normal integer operators (but no sub word instructions)

All data is in objects.

The register machine is aware of Parfait objects, and specifically uses Message and Frame to express call semantics.

Calls and syscalls

The RiscMachine only uses 1 fixed register, the currently worked on Message. (and assumes a program counter and flags, neither of which are directly manipulated)

There is no stack, rather messages form a linked list, and preparing to call, the data is pre-filled into the next message. Calling then means moving the new message to the current one and jumping to the address of the method. Returning is the somewhat reverse process.

Syscalls are implemented by one Syscall instruction. The Risc machine does not specify/limit the meaning or number of syscalls. This is implemented by the level below, eg the arm/interpreter.

Interpreter

There is an interpreter that can interpret compiled register machine programs. This is very handy for debugging (and nothing else).

Even more handy is the graphical interface for the interpreter, which is in it's own repository: rubyx-debugger.

Arm / Elf

There is also a (very straightforward) transformation to arm instructions. Together with the also quite minimal elf module, arm binaries can be produced.

These binaries have no external dependencies and in fact can not even call c at the moment (only syscalls :-)).