dos33fsprogs/games/ootw
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ending
intro
old_title
ootw_c1
ootw_c2
ootw_c3
ootw_c4
ootw_c5
ootw_c6
ootw_c7
ootw_c8
ootw_c9
ootw_c10
ootw_c11
ootw_c12
ootw_c13
ootw_c14
ootw_c15
pt3_player
qboot
sprites
tests
alien_laser.s
alien.s
blast.s
charger.s
collision.s
decompress_fast_v2.s
door.s
dummy_friend.s
FAQ
friend.s
gr_copy_offset.s
gr_copy.s
gr_fast_clear.s
gr_hlin.s
gr_make_quake.s
gr_offsets_hl.s
gr_offsets.s
gr_overlay.s
gr_pageflip.s
gr_plot.s
gr_putsprite_crop.s
gr_putsprite_flipped.s
gr_putsprite.s
gr_run_sequence2.s
gr_run_sequence_rle.s
gr_run_sequence.s
gr_trapezoid.s
gr_twoscreen_scroll.s
gr_unrle.s
gr_vlin.s
gun.s
hardware.inc
hello2.bas.old
hello.bas
hello.bas.old
keyboard.s
laser.s
lz4_decode.s
Makefile
ootw_side2.dsk
ootw_side3.dsk
ootw.dsk
physicist.s
random16.s
README
shield.s
text_print.s
TODO
zp.inc

Another / Out-of-This World Demake for Apple II+
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
	by Vince "Deater" Weaver (vince@deater.net) 
		http://www.deater.net/weave/vmwprod/ootw/
	Disk and LZ4 routines by qkumba

+ The game "Another World" was released in 1991.
	Written by Eric Chahi.
  It was eventually ported to many systems (I played it on IBM PC).

  It even got an Apple IIgs port (the IIgs is 16-bit with fancy
	graphics and sound).  However you couldn't play it on
	earlier Apple II systems... until now.

+ I was inspired to do this by this amazing PICO-8 version of:
	https://liquidream.itch.io/another-world-survival

  and thought the Apple II lo-res palette (15 colors, 40x48 graphics)
  might be just barely enough to do it justice.

==================
Game controls:
==================

  This info appears while loading too, but if you are in an emulator with
	fast disk access it might not be on the screen long enough to see.

	D ->		- move right (twice to run)
	A <-		- move left (twice to run)
	W up		- jump
	S down		- crouch / pickup
	space		- kick / gun
	L		- charge weapon

  During the intro, you can press R to make it repeat forever.

  Hints for those who have never actually played the original game:

	+ At initial arrival, hit up a bunch of times to escape the
		tentacle monster.  On an original II w/o autorepeat
		you might have to bang on the keyboard a lot.
	+ You can kick some enemies.  Crouch-kicking is sometimes
		a bit easier than stand-kicking.
	+ When running (i.e. after pressing left or right twice)
		you can press "up" to run-jump which is faster than
		plain running.  That might be useful if you need
		to out-run something.
	+ When you get the gun, use space to fire the laser.
		You can use "L" to charge your gun for special actions.
		Charge a little bit then press "L" (or any key)
		to create a shield.
		Charge a longer time (a few seconds, when the charge
		ball gets bigger) and it will make a giant blast capable
		of destroying doors and shields.


  Note: the original Apple II had no up/down buttons, which is why
	you can also use WASD for movement.  Different emulators handle
	this differently, but if for some reason up/down is not working
	try using W/S instead.

  Joystick support: none yet?
	It should be possible, I just haven't had time to implement yet.

  Keyboard Limitations:
	Note, Apple II has simplistic keyboard support.
	In general it's not possible to read more than one key at a time.
	Additionally, on older models there's no auto-repeat unless you
		hold down the REPT key, which makes running difficult.
	This means it's really not possible to use the keyboard the
		same way as the original game (which had you do things
		like holding down spacebar to charge the gun and then
		firing when you release it.  Same for running faster
		by holding left/right and space at the same time).

==================
Development notes:
==================

Ootw Memory map:
	00	zero page
	01	stack
	02	disk-filename (30 bytes)
	03	nibble table/disk data
	04-07	GR page0
	08-0b	GR page1
	0c-0f	background  ($c00 = disk load buffer)
	10-13	background overlay
	14-16	loader
	17-bf	program-data (41.25k)
	bc-bf   earthquake background (shifted)
	c0-cf	I/O
	d0-ff	ROM


Intro Memory map:
	00	zero page
	01	stack
	02	disk filename (30 bytes)
	03	nibble table/disk data
	04-07	GR page0
	08-0b	GR page1
	0c-0f	offscreen data  ($c00 = disk load buffer)
	10-13	offscreen data2
	14-16	loader
	17-89	program/compressed-data (30.25k)
	90-bf	currently decompressed level data (12k)
	c0-cf	I/O
	d0-ff	ROM


Intro Memory squeeze!

	10,748 over	all graphics in
	10,734 over	remove extraneous blank bg image
	 8,658 over	re-arrange memory map, 42k avail now
	 8,562 over	move gr_make_quake out of common code
	 8,374 over	remove extraneous code (mostly put_sprite_flipped)
	 5,469 over     allow changing bg on fly in sequence
	 4,122 over	modify cyan frames to be on fly
	 2,749 over	do same for zappo routines
	 2,493 over	squish disk loader vars to page 3
	 2,165 over	horrible hack to auto-go to next image in sequence
	 2,114 over	move bg loading into seq
	 2,053 over	make elevator indicator a loop
	 1,347 over	use LZ4 instead of RLE

Gave up, see if we can compress in chunks and decompress, sort of like
my chiptune player does.


Let's take a 12k region of memory = $3000
	$C000 - $3000 = starting at $9000


ID1 =	1461		2143\
ID2 =   1759		2687|--- together in 01
ID3 =	1195		1879/
ID4 =   2514		8280\--- in 04
ID5 =	1947		3492/
ID6 =	2584		3610\ --- in 06
ID7 =   2834		3606/
ID8 =	3705		4918 | -- in 08
ID9 =	4494		5901\  -- in 09
ID10 =	3397		5558/
	=====          ======
	25890             12k


ootw memory squeeze:
	after full rope sequence in:	23065
	make transparent overlays:	13971
	add end-of-l1 cutscene:		26464
	make transparent overlays:	17821
	add in rest of end cutscene	23906
	make those transparent		21236


ootw2 memory squeeze:
	before intro			3872
	after intro			9234



LOADER=1400		TITLE=1.75k = 7 pages = load at $D00
	2560 max size allowed


L2 Memory map:
	00	zero page
	01	stack
	02	disk-filename
	03	nibble table/disk data
	04-07	GR page0
	08-0b	GR page1
	0c-0f	offscreen data  ($c00 = disk load buffer)
	10-13	offscreen data2
	14-16	loader

	17+	game	

	c0-cf	I/O
	d0-ff	ROM



since there seems to be vague interest in this, reasons to use the
various graphics modes.

lores benefits:
+ 40x48, 15 colors (two greys) (which is fine, as I use one for sprite transparency)
+ hardware page flipping
+ each display only 1kB (leaving lots of room for code) (also fast to clear screen)
+ (software) sprites and animations are relatively small

lores downsides:
+ blocky
+ pixels are rectangular
+ framebuffer is non-linear (to get to next line requires a lookup table, not a simple add)
+ odd/even lines are high/low nibble in a byte, so to draw sprites properly need a lot of shifting an masking (I cheat and only allow sprites on even lines)
+ framebuffer has "memory holes" between lines.  These are areas of memory reserved for expansion card use, so you can't just load a 1kB image straight to the framebuffer as it could break things.
+ NTSC artifact fringing between colors
+ lores PAGE2 is not frequently used so is broken in some emulators and on some early IIgs models


hires benefits:
+ 140x192 6 colors
+ hardware page flipping

hires downsides:
+ non-linear framebuffer even worse than lo-res
+ 8kB per page.  two pages of hires takes 1/3 of total RAM in an Apple II+
+ NTSC artifact color.  If the bit patterns in adjacent pixels is 00 it makes black, 11 makes white, so if you join two different colors you get lines between them
+ you get 7 pixels per 2-bytes.  Which means a lot of dividing by 7, slow on 6502
+ each 3.5 pixels has a bit indicating palette (black,white,green,purple) or (black,white,orange,blue).  You get zx-spectrum like color clash if you try to mix colors too close together
+ to get fast software sprites usually you make a set of 7 pre-shifted versions of the sprites, which takes up a lot of room



double-lores
+ 80x48, 15 colors
+ requires IIe or newer (80 column card)
+ requires drawing extra 1kB of data to bank-switched AUX RAM
+ AUX ram colors are shifted one bit to left from main bank colors
+ while it's possible to get hardware page flipping, it's really complex

double-hires
+ 140x192, 15 colors!
+ requires IIe or newer and 128k of RAM
+ requires drawing 8k of additional data to bank-switched AUX RAM
+ again, page flipping is complex


In any case, I chose lo-res for the Another World conversion for 3 reasons
1. Another World traditionally has 16 colors (and I like the lo-res colors)
2. I wanted to fit levels in 48k, and as many as possible on a 140k disk
3. I am too lazy to implement a full hi-res sprite library


The recent C64 Another World conversion looks much more impressive and hi-res,
but I think they use a 1MB cartridge just for the intro movie alone
(which is possible larger than the size of the original game for the Amiga).



DISK:
~~~~~

DISK1:
	TITLE		 2540	10s	0T10S	T1
	INTRO		35049	137s	8T9S	T2..T10
	OOTW_C1		24094	95s	5T15S	T11-T16
	OOTW_C2		31845	125s	7T13S	T17-T24
	OOTW_C3		 3420	14s	0T14S	T25
	OOTW_C4		15643	62s	3T14S	T26-T29
	OOTW_C5		10333	41s	2T9S	T30-T32
				====
				484s = 121k

DISK2:
	TITLE		2540	10s	0T10S	T1
	OOTW_C6		9605	38s	2T6S	T2-T4
	OOTW_C7		9704	38s	2T6S	T5-T7
	OOTW_C8		9823	39s	2T7S	T8-T10
	OOTW_C9		9646	38s	2T6S	T11-T13
	OOTW_C10	9646	38s	2T6S	T14-T16
				====
				201s = 50k

DISK3:
	TITLE		 2540	10s	0T10S	T1
	OOTW_C11	 9643	38s	2T6S	T2-T4
	OOTW_C12	 9707	38s	2T6S	T5-T7
	OOTW_C13	 9828	39s	2T7S	T8-T10
	OOTW_C14	 9749	38s	2T6S	T11-T12
	OOTW_C15	24658	97s	6T1S	T13-T19
	ENDING		22899	90s	5T10S	T20-T25
				====
				350 = 87.5k