SixtyPical/README.markdown

SixtyPical
==========

SixtyPical is a very low-level programming language, similar to 6502 assembly,
with static analysis through type-checking and abstract interpretation.

It is a **work in progress**, currently at the **proof-of-concept** stage.

It is expected that a common use case for SixtyPical would be retroprogramming
for the Commodore 64 and other 6502-based computers such as the VIC-20.

Many SixtyPical instructions map precisely to 6502 opcodes.  However, SixtyPical
is not an assembly language: the programmer does not have total control over
the layout of code and data in memory.  Some 6502 opcodes have no SixtyPical
equivalent, while some have an equivalent that acts in a slightly different
(but intuitively related) way.  And some commands are unique to SixtyPical.

`sixtypical` is the reference implementation of SixtyPical.  It is written in
Haskell.  It can currently parse and check a SixtyPical program, and can
emit an Ophis assembler listing for it.

This distribution will soon be placed under an open-source license.

Quick Start
-----------

If you have `ghc`, Ophis, and VICE 2.4 installed, clone this repo, `cd` into it,
and run

    ./loadngo.sh eg/demo.60p

The Big Idea(s)
---------------

### Typed Addresses ###

SixtyPical distinguishes several kinds of addresses: those that hold a byte,
those that hold a word (in low-byte-high-byte sequence), those that are the
beginning of a table of bytes, and vectors (those that hold a word pointer to a
machine-language routine.)  It prevents the program from accessing them in
certain ways.  For example, these are illegal:
    
    reserve byte lives
    reserve word score
    routine do_it {
        lda score        ; no! can't treat word as if it were a byte
        lda lives, x     ; no! can't treat a byte as if it were a table
    }

### Abstract Interpretation ###

SixtyPical tries to prevent the program from using data that has no meaning.

The instructions of a routine are analyzed using abstract interpretation.
One thing we specifically do is determine which registers and memory locations
are *not* affected by the routine.  For example, the following:

    routine do_it {
        lda #0
        jsr update_score
        sta vic_border_colour    ; uh... what do we know about reg A here?
    }

...is illegal *unless* one of the following is true:

*   the A register is declared to be a meaningful output of `update_score`
*   `update_score` was determined to not change the value of the A register

The first case must be done with an explicit declaration on `update_score`.
The second case will be be inferred using abstract interpretation of the code
of `update_score`.

### Structured Programming ###

SixtyPical eschews labels for code and instead organizes code into _blocks_.

Instead of the assembly-language subroutine, SixtyPical provides the _routine_
as the abstraction for a reusable sequence of code.  A routine may be called,
or may be included inline, by another routine.  The body of a routine is a
block.

Along with routines, you get `if`, `repeat`, and `with` constructs which take
blocks.  The `with` construct takes an instruction like `sei` and implicitly
(and unavoidably) inserts the corresponding `cli` at the end of the block.

Abstract interpretation extends to `if` blocks.  The two incoming contexts are
merged, and any storage locations poisoned in either context are considered
poisoned in the result context.

(Same should apply for `repeat` and `with` and, really, many other cases
which there just aren't enough test cases for yet.)

### "It's a Partial Solution" ###

SixtyPical does not attempt to force your typed, abstractly interpreted
program to be absolutely watertight.  In assembly language on an 8-bit
microprocessor, you will sometimes _need_ to do dangerous and tricky things,
like self-modifying code and cycle-counting, in order to accomplish a
sophisticated effect, like a raster interrupt trick.

For that reason, `sixtypical` does not attempt to emit a fully-formed
Ophis assembler source.  Instead, it expects you to mix its output with
some raw Ophis assembler to make a complete program.  This "mixin" may contain
as much unchecked assembler code as you like.  An example is provided in the
`lib` directory which adds a prelude that makes the resulting program
runnable from Commodore BASIC 2.0 and stores uninitialized data at `$C000`.

In addition, various checks are not attempted (such as tracking the usage
of an indirect indexed table) and other checks may be subverted (for example
by `locate`ing two variables with two different types of storage at the same
address.)

In summary, SixtyPical helps you write a very-nearly-assembly-level program
which is a bit more "solid" than raw assembly, but it still expects you to
know what you're doing down there.

For More Information
--------------------

For more information, see the docs (which are written in the form of
Falderal literate test suites.  If you have Falderal installed, you can run
the tests with `./test.sh`.)

Ideas
-----

These aren't implemented yet:

*   Inside a routine, an address may be declared with `temporary`.  This is like
    `static` in C, except the value at that address is not guaranteed to be
    retained between invokations of the routine.  Such addresses may only be used
    within the routine where they are declared.  If analysis indicates that two
    temporary addresses are never used simultaneously, they may be merged
    to the same address.

Internals
---------

Some (OK, a lot) of the Haskell code is kind of gross and non-idiomatic.
The parser, in particular, would not be described as "elegant".  There
could definitely be more higher-order functions defined and used.  At the
same time, I'm really not a fan of pointless style — I prefer it when things
are written out explicitly and pedantically.  Still, there are places where
an added `foldr` or two would not be unwelcome...

TODO
----

*   Initial values for reserved tables
*   Character tables ("strings" to everybody else)
*   Addressing modes — indexed mode on more instructions
*   `jsr (vector)`
*   `jmp routine`
*   `outputs` on externals
*   Routine is a kind of StorageLocation?  (Location)?
*   remove DELTA -> ADD/SUB (requires carry be notated on ADD and SUB though)