mandel-6502/readme.md

# Mandel-6502

Work-in-progress Mandelbrot fractal viewer for Atari 8-bit home computers. Mostly an excuse to write an integer multiplication routine for the 6502 for practice.

Goals:

* have fun learning 6502 assembly
* make an old machine do something inefficient as efficiently as possible.
* post cool screenshots of low-res fractals

Non-goals:

* maintain anything long-term (but feel free to copy/fork if you want to make major changes!)

Enjoy! I'll probably work on this off and on for the next few weeks until I've got it producing fractals.

-- brooke, january 2023 - february 2024

## Current state

Basic rendering is functional, but no interactive behavior (zoom/pan) or benchmarking is done yet.

The 16-bit signed integer multiplication works; it takes two 16-bit inputs and emits one 32-bit output in the zero page, using the Atari OS ROM's floating point registers as workspaces. Inputs are clobbered.

The main loop is a basic add-and-shift, using 16-bit adds which requires flipping the sign of negative inputs (otherwise you'd have to add all those sign-extension bits). Runs in 470-780 cycles depending on input.

The mandelbrot calculations are done using 4.12-precision fixed point numbers. It may be possible to squish this down to 3.13.

Iterations are capped at 255.

The pixels are run in a progressive layout to get the basic shape on screen faster.

## Next steps

Add a running counter of ms/px using the vertical blank interrupts as a timer. This'll show how further work improves it!

Check for cycles in (zx,zy) output when in the 'lake'; if values repeat, they cannot escape. This is a big time saver in fractint.

I may be able to do a faster multiply using tables of squares for 8-bit component multiplication.

## Deps and build instructions

I'm using `ca65` as a macro assembler, and have a Unix-style `Makefile` for building. Should work fairly easily on Linux and Mac. Might work on "raw" Windows but I use WSL for that.

Currently produces a `.xex` executable, which can be booted up in common Atari emulators and some i/o devices.
readme 2023-01-05 03:15:26 +00:00			`# Mandel-6502`

tyop 2023-01-05 05:04:53 +00:00			`Work-in-progress Mandelbrot fractal viewer for Atari 8-bit home computers. Mostly an excuse to write an integer multiplication routine for the 6502 for practice.`
readme 2023-01-05 03:15:26 +00:00
			`Goals:`
update readme 2023-01-07 01:28:35 +00:00
readme 2023-01-05 03:15:26 +00:00			`* have fun learning 6502 assembly`
			`* make an old machine do something inefficient as efficiently as possible.`
			`* post cool screenshots of low-res fractals`

			`Non-goals:`
update readme 2023-01-07 01:28:35 +00:00
readme 2023-01-05 03:15:26 +00:00			`* maintain anything long-term (but feel free to copy/fork if you want to make major changes!)`

			`Enjoy! I'll probably work on this off and on for the next few weeks until I've got it producing fractals.`

Progressive pixel layout 2024-02-04 22:25:15 +00:00			`-- brooke, january 2023 - february 2024`
readme 2023-01-05 03:15:26 +00:00
			`## Current state`

update readme & doc comments & vars 2023-01-22 22:34:30 +00:00			`Basic rendering is functional, but no interactive behavior (zoom/pan) or benchmarking is done yet.`

			`The 16-bit signed integer multiplication works; it takes two 16-bit inputs and emits one 32-bit output in the zero page, using the Atari OS ROM's floating point registers as workspaces. Inputs are clobbered.`
readme 2023-01-05 03:15:26 +00:00
whoops 2023-01-05 04:57:07 +00:00			`The main loop is a basic add-and-shift, using 16-bit adds which requires flipping the sign of negative inputs (otherwise you'd have to add all those sign-extension bits). Runs in 470-780 cycles depending on input.`
readme 2023-01-05 03:15:26 +00:00
update readme & doc comments & vars 2023-01-22 22:34:30 +00:00			`The mandelbrot calculations are done using 4.12-precision fixed point numbers. It may be possible to squish this down to 3.13.`
Note how many cycles loop unrolling saves +4 cycles one-time setup ldx #8 ; 2 cyc for first 8 ldx #8 ; 2 cyc for second 8 (different shift behavior) -5 cycles/iter to get bit now lsr arg + 1 ; 5 cyc rol arg ; 5 cyc +10 cycles/iter to get the bit in a loop dex ; 2 cyc bne ; 2 cyc 4 cycles/iter for the loop 4 + (14 * 16) = 4 + 224 = 228 2023-01-05 05:02:18 +00:00
update readme & doc comments & vars 2023-01-22 22:34:30 +00:00			`Iterations are capped at 255.`
update readme 2023-01-07 01:28:35 +00:00
Progressive pixel layout 2024-02-04 22:25:15 +00:00			`The pixels are run in a progressive layout to get the basic shape on screen faster.`

update readme 2023-01-07 01:28:35 +00:00			`## Next steps`

update readme & doc comments & vars 2023-01-22 22:34:30 +00:00			`Add a running counter of ms/px using the vertical blank interrupts as a timer. This'll show how further work improves it!`
update readme 2023-01-07 01:28:35 +00:00
update readme & doc comments & vars 2023-01-22 22:34:30 +00:00			`Check for cycles in (zx,zy) output when in the 'lake'; if values repeat, they cannot escape. This is a big time saver in fractint.`
readme 2023-01-05 03:15:26 +00:00
update readme & doc comments & vars 2023-01-22 22:34:30 +00:00			`I may be able to do a faster multiply using tables of squares for 8-bit component multiplication.`
readme 2023-01-05 03:15:26 +00:00
			`## Deps and build instructions`

tyop 2023-01-05 05:04:53 +00:00			I'm using `ca65` as a macro assembler, and have a Unix-style `Makefile` for building. Should work fairly easily on Linux and Mac. Might work on "raw" Windows but I use WSL for that.
readme 2023-01-05 03:15:26 +00:00
			Currently produces a `.xex` executable, which can be booted up in common Atari emulators and some i/o devices.