Illusion of Gaia/Notes: Difference between revisions

The following article is a Notes Page for Illusion of Gaia.

Map assets

Assets for each map are loaded based on a table at $0d8000. The engine seeks through this table when a map is loaded, looking for the map's ID header.

The format of a map's entry in the table is db MapNum : db $00 followed by one or more of the following header cards:

Always uncompressed: palette data (card $04), music data (card $11). Other data can be compressed in Quintet's LZ format, in which case the Size bytes here are ignored. If the data has #$0000 for its "compressed size", it is taken as uncompressed and the Size bytes here are used.

Most of these can occur in any order and any number, and will override previous data in a logical way. However, $03 with IsSprites=0 must precede $05/$06 in order to set up VRAM and the decompression buffer, and $05 for each layer must precede $06 for that layer.

Map design tables

Actor lists

Actor lists per map start at $0c8200. Each valid map has an actor list, addressed by indexed pointers at $0c8000.

Entries in actor lists are of the form:

db PosX,PosY,Param : dl EntryPtr-3 : db StatsIndex[,MonsterId,DeathActionIndex]

• PosX,PosY - usually the spawn point, in tiles from the map's northwest corner. Some actors override and use for different purposes.

• Param - if odd, usually represents an actor-specific parameter, e.g. "contents of this Dark Space"; right-shifted 1 bit and stored in actor-page $0E. If even, bit-3 is cleared and Param becomes the high byte of the actor's sprite OAM override.

• EntryPtr - address where actor code execution will start. The list points 3 bytes earlier, to a byte+word header: starting sprite ID, then starting actor-page $10/$11 (physics and rendering flags).

• StatsIndex - monster's stat block, indexing a table of HP/STR/DEF/DP at $81abf0 + 4*StatsIndex. Actors not involved in combat should have StatsIndex=0, in which case MonsterId and DeathActionIndex are omitted and the next entry in the list begins.

• MonsterId - labels the monster to track its death through map transitions. If MonsterId is 0, it always respawns. Otherwise, it stays dead until the death tracking flag is cleared: usually by going to the world map, by player death, or manually.

• DeathActionIndex - indexes a map rearrangement (BG layer tile copy). When the monster dies, the map rearrangement is triggered automatically, as if by calling cop #$32 : db DeathActionIndex : cop #$33.

• The actor list ends with $FF, followed by the name of the map (if any), followed by $CA.

Thinker lists

Thinker lists per map start at $0ce7e5. Each valid map has a thinker list, addressed by indexed pointers at $0ce5e5.

Entries in thinker lists are of the form:

db Param : dl EntryPtr-2

Param is a thinker-specific parameter, e.g. "palette bundle index". EntryPtr is the code execution start point. The list points two bytes earlier, to a word header copied into $7f000e,x. Flag #$0004 in the header means execute-after-actors if set, before-actors if clear.

Actor code

Each actor has a base address / ID, which indexes $30 blocks of RAM at each of $7e0000,x, $7f0000,x, and $7f1000,x. The actor list is a doubly linked list. Each frame, the list is processed in forward order running actor code, then post-processed (e.g. collision detection) in reverse.

Each actor has a dynamic code entry point. The handler invokes code by the equivalent of jsl EntryPtr.

At entrancy, actor code should assume that the processor state is:

m=0, x=0, d=0, i=1
X = ActorID
D = ActorID
DBR = $81

Actor code must restore this state before it exits, except that X need not be restored. Actor code must exit via the equivalent of rtl at the stack level of entrancy.

At $7e0000,x (which is also the direct page) most memory is used by the engine:

$7e:00   long EntryPtr  Pointer to code that will be run on this actor's turn.
$7e:03   byte dummy03   Dummy byte, makes it easier to handle EntryPtr.
$7e:04   word PrevId    Pointer to actor (= actor ID) before this one in the list.
$7e:06   word NextId    Pointer to actor (= actor ID) after this one in the list.
$7e:08   word WaitTime  Frames to wait before running code again, e.g. animation timer.
$7e:0a   long ArgPtr    While in a COP, pointer to COP argument or return address.
$7e:0d   byte dummy0d   Dummy byte, makes it easier to handle ArgPtr.
$7e:0e   word OamXor    XOR'd with OAM for palette changes etc. if actor has a sprite.
$7e:10   word Flags10   Actor state flags.
$7e:12   word Flags12   Actor state flags.
$7e:14   word PosX      Actor x position, pixels, from northwest corner of map.
$7e:16   word PosY      Actor y position, pixels, from northwest corner of map.
$7e:18   word OffsX     Offset of sprite from PosX, if actor has a sprite.
$7e:1a   word OffsY     Offset of sprite from PosY, if actor has a sprite.
$7e:1c   word OffsXMir  As OffsX, if the h-mirror flag in $0e were flipped.
$7e:1e   word OffsYMir  As OffsY, if the v-mirror flag in $0e were flipped.
$7e:20   byte HitboxW   Hitbox size, West (-x) direction. If no hitbox, free.
$7e:21   byte HitboxE   Hitbox size, East (+x) direction. If no hitbox, free.
$7e:22   byte HitboxN   Hitbox size, North (-y) direction. If no hitbox, free.
$7e:23   byte HitboxS   Hitbox size, South (+y) direction. If no hitbox, free.
$7e:24   word Free24    Free memory.
$7e:26   word Free26    Free memory.
$7e:28   word SprIdx    Sprite (graphics) index, if actor has a sprite.
$7e:2a   word SprFrame  Animation frame of sprite, if actor has a sprite.
$7e:2c   word MoveX     Movement data or address of current move pattern, x direction.
$7e:2e   word MoveY     Movement data or address of current move pattern, y direction.

At $7f0000,x is a mix of engine, subroutine, and free memory:

$7f:00   dwrd AnimScr1  Scratch bytes for sprite animation COPs.
$7f:04   word RetPtr1   Return pointer set by some COPs.
$7f:06   long SprSetPtr Pointer to spriteset (e.g. "Diamond Mine"), which $7e:28 indexes.
$7f:09   byte dummy09   Dummy byte for SprSetPtr.
$7f:0a   word ChatPtr   How actor interacts with player. Specifics depend on flags.
$7f:0c   word SprMetPtr Pointer to metasprite (i.e. sprite tile assembly data).
$7f:0e   word AnimScr2  Scratch bytes for sprite animation COPs.
$7f:10   word OrbitAng  Not reserved. Orbit routines use this as orbiting angle.
$7f:12   word OrbitDia  Not reserved. Orbit routines use this as orbiting diameter.
$7f:14   word LoopCntr  Not reserved. Some COPs use this as a loop counter.
$7f:16   word SprTimer  Timer for sprite animation COPs.
$7f:18   word MoveXAlt  Alternate MoveX, meaning depends on context.
$7f:1a   word MoveYAlt  Alternate MoveY, meaning depends on context.
$7f:1c   word ParentId  If set, and conditions are met, actor dies with its parent.
$7f:1e   word RetPtr2   Return pointer set by some COPs.
$7f:20   word StatsPtr  Pointer to monster's HP/STR/DEF/DP stats.
$7f:22   word EnemyNum  Dungeon-level enemy number for flagging killed enemies.
$7f:24   word DeathIdx  Index of map rearrangement script to perform on death.
$7f:26   word CurrHp    Current HP.
$7f:28   word IframeCtr Abs. value is iframes; typically positive means stunned.
$7f:2a   word Flags7F2A Actor state flags.
$7f:2c   word MoveScr1  Scratch bytes for some movement COPs.
$7f:2e   word MoveScr2  Scratch bytes for some movement COPs.

Memory at $7f1000,x is mostly unreserved:

$7f1000  word HitPtr    When hit by player, EntryPtr is set to HitPtr.
$7f1002  word DodgePtr  When player attacks, EntryPtr is set to DodgePtr.
$7f1004  long DiePtr    When actor dies, EntryPtr is set to DiePtr.
$7f1007  byte dummy4    Dummy byte for DiePtr.
$7f1008  word CollPtr   When actor collides with player, EntryPtr is set to CollPtr if Flags7F2A is so set.
$7f100a  .... Free100A  Through $7f100f, no use known; probably free.
$7f1010  .... Scr1010   Through $7f1017, scratch bytes for some COPs, otherwise free.
$7f1018  long SnapPtr   COP #$43 stores caller here; no other use known.
$7f101b  byte dummy5    Dummy byte for SnapPtr.
$7f101c  word Free101C  No use known; probably free.
$7f101e  word ChainDmg  When colliding with an actor, damage to deal to it.
$7f1020  .... Free1020  Through $7f102f, no use known; probably free.

To save ROM space, actor code uses the COP opcode ($02) and its label as a subroutine caller. Arguments follow the COP label. Example:

02 d0    cop #$D0        ; If game flag
a9 00      db $a9, $00   ;   $A9 is set to 0,
ab cd      dw JmpTarget  ;   go to JmpTarget = $cdab. Else,
02 e0    cop #$E0        ; Die.

Different COPs may return control to the actor after the arguments or at some other address; or may exit (return control to the engine) via pla : pla : rtl, which is equivalent to rtl at the stack level of actor entrancy.

It is always safe to call COP with the processor state as:

m=0, x=0, d=0, i=1
X = ActorID
D = ActorID
DBR = $81

Some COPs do not require this state.

Most COPs restore non-scratch state upon returning. A few COPs are explicitly state-altering. No COP has a state-altering side effect.

Registers A and Y as well as n,v,z,c are clobbered by the COP handler. Some COPs return useful values in them.

The valid COPs are:

Flags are stored in $10, $12, and $7F:2A:

$10 & #$8000   Is Player
$10 & #$4000   Offscreen (engine temp flag)
$10 & #$2000   Disable rendering and collisions
$10 & #$1000   Interactable/chattable/useable
$10 & #$0800   Continue acting during dialogue
$10 & #$0400   Is weapon of Player (e.g. Friar)
$10 & #$0200   Disable collisions with weapons
$10 & #$0100   Disable collisions with Player
$10 & #$0080   Is hurt (engine temp flag)
$10 & #$0040   Is dying (engine temp flag)
$10 & #$0020   Is item pickup, e.g. DP (but other obscure uses too)
$10 & #$0010   Invulnerable; make clanging sound on hit
$10 & #$0008   If moving via COP #$8x, collide with walls
$10 & #$0004   Is colliding with a wall (engine temp flag)
$10 & #$0002   Maximum OAM priority
$10 & #$0001   Minimum OAM priority

$12 & #$8000   ?
$12 & #$4000   If moving via COP #$8x, force movement to be west/south
$12 & #$2000   If moving via COP #$8x, force movement to be east/north
$12 & #$1000   ?
$12 & #$0800   ?
$12 & #$0400   ?
$12 & #$0200   ?
$12 & #$0100   Constant hitbox (even if sprite changes)
$12 & #$0080   Cut bottom 8px of hitbox (to seem of higher elevation)
$12 & #$0040   Remove children on death
$12 & #$0020   Hide HP
$12 & #$0010   Disable recoil on damage
$12 & #$0008   ?
$12 & #$0004   ?
$12 & #$0002   Persistent h-mirror OAM flag (resist being changed by COPs)
$12 & #$0001   Disable stun on damage

$7F:2A & #$0080   Exclude from monster counter on radar
$7F:2A & #$0010   Enable CollPtr
$7F:2A & #$0002   Forced movement (e.g. recoil or cop #$22) in progress (engine temp flag)
$7F:2A & #$xxxx   Others unknown

Thinker code

To run code during VBlank, at end-of-frame, or while other processing is paused (e.g. during music loads), use a thinker. These are like lightweight, no-sprite actors. Most concepts about actor code apply to thinkers.

In thinker memory, if flag #$0004 in $7f000e,x is set, code will run after actor processing. If clear, code will run after the NMI handler. The NMI handler finishes during VBlank (unless you seriously abuse DMA), so thinkers can e.g. do ad hoc updates to CGRAM or MMIO registers.

Key points:

• Thinker memory is blocks of $10 bytes, instead of $30.
• Direct page $00 - $0d have the same meaning as for actors. $0e/f as well as $7f:0e/f contain different flags. Other memory is free.
• Don't use COPs that affect properties the thinker doesn't have, e.g. position, sprite, physics. Probably the only useful COPs are #$36 - #$3D and #$C1 - #$DB.
• To die, a thinker must call COP #$3D and subsequently rtl.

Sprite data format

VRAM characters for most actors are loaded by map header $03. It is possible to load VRAM ad hoc, e.g. with cop #$4f, but ad hoc changes are permanently lost if the player opens the inventory screen.

VRAM characters for the player are loaded from pointers in a table at $81d971:

{
.long ptrAnimationList00    ; Will
.long ptrCharacterData00    ; Will
.long ptrAnimationList01    ; Freedan
.long ptrCharacterData01    ; Freedan
.long ptrAnimationList02    ; Shadow
.long ptrCharacterData02    ; Shadow
  ; etc. for transformations, abilities
}

Actor sprites/animations are chosen from an AnimationList a.k.a. SpriteSet. Actor memory $7f0008,x is a pointer to an AnimationList. For monsters the AnimationList is map-specific, always at $7e4000, and loaded by map header $10.

The AnimationList/SpriteSet format is:

AnimationList:
{
.word ptrAnimationData00    ; e.g. Will facing south, or Viper fluttering
.word ptrAnimationData01    ; e.g. Will facing north, or Viper fast-fluttering
  ; etc.
}

AnimationData:
{
.word frameDuration00       ; e.g. $77 frames of...
.word ptrMetasprite00       ; e.g. Will staring, followed by
.word frameDuration01       ; e.g. $04 frames of...
.word ptrMetasprite01       ; e.g. Will blinking
  ; etc.
.word $FFFF
}

Metasprite:
{
.byte xOffset
.byte xOffsetMirror
.byte yOffset
.byte yOffsetMirror
.byte xRecoilHitboxOffset       ; RecoilHitbox is used when
.byte yRecoilHitboxOffset       ; actor is recoiling from
.byte xRecoilHitboxSizeInTiles  ; damage, for wall collisions
.byte yRecoilHitboxSizeInTiles  ; and bumping other actors.
.byte xHostileHitboxOffset      ; HostileHitbox is used
.byte xHostileHitboxSize        ; when damaging other actors.
.byte yHostileHitboxOffset
.byte yHostileHitboxSize
.byte numSprites
{ Sprite00 }                 ; e.g. a head
{ Sprite01 }                 ; e.g. an arm
; etc.
}

Sprite:
{
.byte isLargeSpriteBool       ; 8x8 small, 16x16 large
.byte xOffset
.byte xOffsetMirror
.byte yOffset
.byte yOffsetMirror
.word propertiesAndAddress    ; i.e. OAM data, vhoopppccccccccc
}

For Player sprites, character data is pushed to VRAM from ROM CharacterData + ((propertiesAndAddress & $01FF) << 5). For all other sprites, propertiesAndAddress is the sprite's literal OAM data, so the Address portion is a VRAM word-address.

Palette bundle data format

Ad hoc palette changes (i.e. CGRAM updates) are conventionally performed using scripted palette bundles. There are $80 palette bundles, all in bank $16 and indexed by pointers at $168000. A palette bundle contains one or more palette sequences. Sequences contains blocks of palette data that are sequentially written to the same region of CGRAM (via cop #$39). Sequences are not interruptible, but after cycling through the entire sequence, the calling code may restart the same sequence (via cop #$36) or switch to a different sequence in the bundle (via lda #SequenceNum : sta $0e).

The indexed pointers in bank $16 point to palette bundle headers, which contain 6 bytes for every sequence in the bundle:

PaletteSequenceHeader:
{
.byte numPalettes
.word dataSourceAddress
.byte cgramTargetWord      ; or $00 to write COLDATA instead of CGRAM
.byte numBytesMinusOne     ; or $02 to write COLDATA instead of CGRAM
.byte delayFrames          ; until next CGRAM write
}

followed by a terminal $00.

Palette source data within a bundle can overlap. This is a common design for e.g. wave or flame effects, where a small number of colors are rolled cyclically through CGRAM.

A thinker-type actor is usually used to handle palette bundles; this has the advantage that (due to how thinker initialization is coded) the palette bundle can be efficiently spawned using cop #$3B with Param = the desired palette bundle index. Common palette bundle handler actors are $80b519 which runs a bundle's first sequence exactly once then dies, and $80b520 which runs a bundle's first sequence repeatedly forever.