Wikifang:Network Translation Patchsite/BugVM: Difference between revisions

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(Document the WINWAIT opcode ($60))
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| || || WINBRK <br> [[#op_ADA|$ADA]] || || || || || || || || || || || || ||
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A blinking A-button prompt will be displayed at the bottom-right of the window range.
A blinking A-button prompt will be displayed at the bottom-right of the window range.
|-
! Opcode !! Encoding(s) !! Native Impl. !! Operand Args !! Stack Args !! Description
|- id='op_97C'
| WINBRK <br> (WINdow BReaK) || $82 || $ADA || None || None || Insert a 'page break' of sorts between two full windows' worth of text.
Internally this is equivalent to a WINWAIT followed by a WINCLR.
|}
|}



Revision as of 18:06, 7 September 2017

Bugsite contains a virtual machine which executes all (non-IRQ) game logic. It is a stack-based virtual machine with a large number of opcodes specific to the game.

Data and Link Stacks

Two stacks are managed by the VM: a link stack and a data stack. The link stack ($C100) supports up to $3F call frames of 4 bytes each, which is manipulated entirely by the call, jump-far, and return opcodes. The data stack ($C200) supports up to $55 data items of 3 bytes each. Each data item consists of a little-endian 16-bit word followed by a tag byte, which specifies if it's...

  • $3D an immediate value
  • $1D a word index into the indirect memory array
  • $1E a bit index into the predicate array

Data items are pushed onto the stack as immediate values and then cast to indirect or predicate offsets as necessary. Both stacks grow upwards from their base address.

Indirect & Predicate Memory

BugVM allows direct access (read and write) to indirect and predicate memory. Indirect memory covers WRAM3:$C400 to WRAM3:$D7FF, and is indexed using word offsets. Predicate memory covers WRAM3:$D800 to WRAM3:$DFFF and is indexed as a massive bitfield.

Indirect and predicate memory can be saved to and loaded from SRAM using opcodes $47 and $48, along with additional data in SRAM.

Known Indirect Memory Slots

Index WRAM Addr. Name Purpose
$01 $C402 W_System_GameVersion Stores the version of the game the user is playing.

0 is Alpha version, 1 is Beta version

$12 $C424 W_BugVM_StringArena Stores the current location of the end of the string-builder arena, used by the DB opcode to store embedded string data.
$172 $C6E4 W_MainScript_PortraitID Stores the currently selected character portrait, if any.
$580 - $59F $CF00-$CF3F W_Battle_AttrStaging Stores the most recently loaded RPG Attribute Table entry.

Linkage Directory (BugFS)

Bugsite contains a filesystem which almost pervasively enumerates all resources within the game. Each file is exclusively referred to with it's 16-bit linkage identifier; there are no file names and only one directory. Almost all resource loads, except some game data tables, are mediated through BugFS. Graphics and tilemaps are loaded by ID and BugVM code can farjump/farcall to the start of another section by ID.

The directory's structure is that of an array of entry structures. The directory array starts at $A:$4000, and the ID indexes this array by 8 bytes. Directory entries appear to be stored in the same order as where their data is stored in ROM. The directory spans $1000 entries, across 2 banks; though it could be extended further if the referenced data were to be moved to a later bank. Approximately 40 entries at the end of the directory are zero-size files (pointing to ROM $7F:70FF) and may be unused filler entries.

Offset Name Type
$0 Bank 8-bit bank index
$1 Offset 16-bit offset Offset is relative to $4000, not a pointer
$3 Size 16-bit size

Each directory entry is 5 bytes long. Fields include a bank index, byte offset into that bank (0 means a pointer of $4000), and total size. Much like the directory itself, files are allowed and expected to span across bank boundaries. Native code that reads BugFS files will need to account for bank switching. Directory entries are stored with an 8-byte alignment (3 padding bytes).

RPG Attribute Tables

Certain tables of game attributes are not stored as BugFS files. These data tables include listings for monsters, battle moves, chips, key items, and encounters. Not much is known about these tables, except for the fact that they are universally arrays of $40 bytes and often contain a name string at offset $30. Specialized BugVM instructions exist to load a single table entry into W_Battle_AttrStaging and to print the name at offset $30.

Location Size Contents
$4:4000, $5:4000 $4000 Bugs Instructions that read from the monster table will select bank $4 for Alpha Version and bank $5 for Beta Version. Beta's table is present and unmodified in Alpha, and vice versa.
$6:4000 $4000 Moves
$7:4000 $A80 Chips After the entry at $7:4A40 none of the remaining items in this table appear to have valid name data and are thus likely to be something else.
$7:6000 $1240 Key Items After the entry at $7:7200 none of the remaining items in this table appear to have valid name data and are thus likely to be something else.
$8:4000, $9:4000 $4000 Encounters Instructions that read from the encounter table will select bank $8 for Alpha Version and bank $9 for Beta Version. Beta's table is present and unmodified in Alpha, and vice versa.

Initial State

Execution of BugVM always starts from the beginning of linkage $0. Indirect and predicate memory is set to $0 upon game initialization.

Instruction Set

BugVM takes instructions as 8-bit opcodes which can optionally accept additional parameters. Most opcodes take arguments from the stack, rather than from the instruction stream. Native implementations for a particular opcode are referenced from the opcode table at $3E00, reproduced below:

x0 x1 x2 x3 x4 x5 x6 x7 x8 x9 xA xB xC xD xE xF
0x NOP
$5E9
ENOP $01
$5E9
ENOP $02
$5E9
???
$671
ENOP $04
$5E9
ENOP $05
$5E9
STR
$68C
SUML
$6C0
ANDL
$6CA
OR
$6D7
XOR
$6E2
AND
$6ED
CMP_EQ
$6F8
CMP_NEQ
$705
CMP_LT
$712
CMP_LEQ
$723
1x CMP_GT
$752
CMP_GEQ
$763
???
$772
SLA
$784
SUB
$796
ADD
$7A1
MOD
$7A9
DIV
$7C3
MUL
$7ED
PNOP $19
$80B
PNOP $1A
$80C
PNOP $1B
$80D
PNOP $1C
$80E
INDIR
$80F
PRED
$820
ENOP $1F
$5E9
2x ENOP $20
$5E9
ENOP $21
$5E9
ENOP $22
$5E9
ENOP $23
$5E9
ENOP $24
$5E9
ENOP $25
$5E9
ENOP $26
$5E9
ENOP $27
$5E9
ENOP $28
$5E9
ENOP $29
$5E9
ENOP $2A
$5E9
ENOP $2B
$5E9
POPALL
$831
ENOP $2D
$5E9
ENOP $2E
$5E9
PNOP $2F
$835
3x PNOP $30
$836
PNOP $31
$837
PNOP $32
$838
PNOP $33
$839
PNOP $34
$83A
PNOP $35
$87B
NPREF
$87C
JMPT
$887
JMP
$8AC
RET
$8BB
PNOP $3A
$8DB
PNOP $3B
$8DC
PNOP $3C
$8DD
IMMED
$8DE
DB
$941
JAL
$8F0
4x WINWAIT
$A12
PRINT
$A84
5x WINCLR
$97C
RESLD
$9C6
6x FARCALL
$91B
FARJMP
$83B
7x TILELD
$1BAC
8x WINBRK
$ADA
9x PRKEY
$165A
Ax BLKKEY
$42A
PRMOVE
$1668
BLKMOVE
$3FE
PRMON
$1622
Bx BLKMON
$39C
Cx
Dx
Ex BLKCHIP
$456
PRCHIP
$1661
Fx BLKENC
$3CD

Boolean Logic & Comparison Operators

As convention for this table we treat zero as boolean TRUE and one as boolean FALSE. Other non-zero values are treated as FALSE, but boolean opcodes will not return nonstandard values.

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
SUML
(SUM Logical)
$07 $6C0 None arg1, arg2 (TOP) -> bool (TOP) Add arg1 and arg2. Push TRUE if result is zero, FALSE if non-zero.
ANDL
(AND Logical)
$08 $6CA None arg1, arg2 (TOP) -> bool (TOP) Bitwise-AND arg1 and arg2. Push TRUE if result is zero, FALSE if non-zero.
CMP_EQ
(CoMParison EQual)
$0C $6F8 None arg1, arg2 (TOP) -> bool (TOP) Compare arg1 and arg2. Push TRUE if both arguments are equal, FALSE otherwise.
CMP_NEQ
(CoMParison Not EQual)
$0D $705 None arg1, arg2 (TOP) -> bool (TOP) Compare arg1 and arg2. Push TRUE if both arguments are not equal, FALSE otherwise.
CMP_LT
(CoMParison Less Than)
$0E $712 None arg1, arg2 (TOP) -> bool (TOP) Compare arg1 and arg2. Push TRUE if arg1 is less than arg2, FALSE otherwise.
CMP_LEQ
(CoMParison Less or EQual)
$0F $723 None arg1, arg2 (TOP) -> bool (TOP) Compare arg1 and arg2. Push TRUE if arg1 is less than or equal to arg2, FALSE otherwise.
CMP_GT
(CoMParison Greater Than)
$10 $752 None arg1, arg2 (TOP) -> bool (TOP) Compare arg1 and arg2. Push TRUE if arg1 is greater than arg2, FALSE otherwise.
CMP_GEQ
(CoMParison Greater or EQual)
$11 $763 None arg1, arg2 (TOP) -> bool (TOP) Compare arg1 and arg2. Push TRUE if arg1 is greater than or equal to arg2, FALSE otherwise.

Bitwise logic

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
OR
(bitwise OR)
$09 $6D7 None arg1, arg2 (TOP) -> value (TOP) Bitwise-OR arg1 and arg2 as the return value.
XOR
(bitwise eXclusive OR)
$0A $6E2 None arg1, arg2 (TOP) -> value (TOP) Bitwise-XOR arg1 and arg2 as the return value.
AND
(bitwise AND)
$0B $6ED None arg1, arg2 (TOP) -> value (TOP) Bitwise-AND arg1 and arg2 as the return value.
SLA
(Shift-Left Arithmetic)
$13 $784 None bits, shift (TOP) -> value (TOP) Shift bits left, shift times, while inserting zero bits, to produce value.

Arithmetic

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
SUB
(SUBtraction)
$14 $796 None minuend, subtrahend (TOP) -> difference (TOP) Subtract subtrahend from minuend to produce difference.
ADD
(ADDition)
$15 $7A1 None addend1, addend2 (TOP) -> sum (TOP) Add addend1 to addend2 to produce sum.
MOD
(MODulo)
$16 $7A9 None dividend, divisor (TOP) -> remainder (TOP) Integer-divide dividend by divisor and return only the remainder.
DIV
(DIVide)
$17 $7C3 None dividend, divisor (TOP) -> quotient (TOP) Integer-divide dividend by divisor and return only the quotient.
MUL
(MULtiply)
$18 $7ED None multiplicand, multiplier (TOP) -> product (TOP) Multiply multiplicand by multiplier to produce the product.

Memory & Stack Manipulation

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
STR
(SToRe)
$06 $68C None &address, value (TOP) -> (TOP) Store the value at the memory location referenced by &address. The exact memory operations performed depend on the target of *address.

If address is an indirect index, the memory location referenced by *address will be set to value.

If address is a predicate index, the bit referenced by *address will be set or reset based on if value is zero or non-zero.

It is illegal to STR into an immediate value, and doing so will cause the VM to halt operation.

INDIR
(INDIRect)
$1D $80F None immed (TOP) -> &address (TOP) Cast the value immed into an indirect memory index &address.
PRED
(PREDicate)
$1E $820 None immed (TOP) -> &pred (TOP) Cast the value immed into a predicate memory index &pred.
POPALL
(POP ALL)
$2C $831 None anything (TOP) -> (EMPTY) Empty the stack.
IMMED
(IMMEDiate)
$3D $8DE immed (16b) (TOP) -> immed (TOP) Push immed onto the data stack as an immediate value.
DB
(Declare Bytes)
$3E $941 string (null-terminated) (TOP) -> straddr (TOP) Copy null-terminated string data from the instruction stream into the string-building arena referred to by $C424.

The address of the newly copied string data will be pushed onto the data stack as an immediate value.

Execution Control

Execution Control opcodes control the address of the next instruction to execute, determined by BugVM's program counter. It consists of a bank address, base address, and offset address. The linkage directory determines what the bank and base addresses of a section are. The offset address is added to the base in order to calculate the address of the next instruction.

Caution: Parameters named "offset" for jump instructions refer to the program counter offset address, and do not imply the existence of PC-relative jumps instructions within Bugsite.

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
JMPT
(JuMP if True)
$37 $887 offset (16b) bool (TOP) -> (TOP) Jump to a new offset within the current linkage section if bool is TRUE.
JMP
(JuMP)
$38 $8AC offset (16b) None Jump to a new offset within the current linkage section.
RET
(RETurn)
$39 $8BB None None Return to the previously linked return address.
JAL
(Jump And Link)
$3F $8F0 offset (16b) None Jump to a new offset within the current linkage section. Store the offset of the next instruction on the link stack.
FARCALL $6A $91B None linkage_index (TOP) -> (TOP) Jump to the start of a new linkage section. Store the offset of the next instruction on the stack.
FARJMP
(FAR JuMP)
$6B $83B None linkage_index (TOP) -> (TOP) Jump to the start of a new linkage section, erasing the link stack in the process.

The previous linkage section is stored for later use.

NOP and NOP-alikes

BugVM contains a number of opcodes which do nothing, including both a single implementation of a NOP opcode used to fill in blank spots in the table as well as individual implementations which presumably did something in the past.

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
NOP
(Null OPeration),
ENOP $nn (Effective Null OPeration)
Too many to list $5E9 None None Does nothing.

This particular null-op implementation is used many times to fill space in the opcode table.

PNOP $19
(Probable Null OPeration)
$19 $80B None None Does nothing.
PNOP $1A
(Probable Null OPeration)
$1A $80C None None Does nothing.
PNOP $1B
(Probable Null OPeration)
$1B $80D None None Does nothing.
PNOP $1C
(Probable Null OPeration)
$1C $80E None None Does nothing.
PNOP $2F
(Probable Null OPeration)
$2F $835 None None Does nothing.
PNOP $30
(Probable Null OPeration)
$30 $836 None None Does nothing.
PNOP $31
(Probable Null OPeration)
$31 $837 None None Does nothing.
PNOP $32
(Probable Null OPeration)
$32 $838 None None Does nothing.
PNOP $33
(Probable Null OPeration)
$33 $839 None None Does nothing.
PNOP $34
(Probable Null OPeration)
$34 $83A None None Does nothing.
PNOP $35
(Probable Null OPeration)
$35 $87B None None Does nothing.
NPREF
(Null PREFix)
$36 $87C opcode, ??? None Executes the next opcode as normal.

This would appear to be just another NOP, but it's native implementation actually loads and executes the next byte as an opcode. Hence, it works like a prefix byte that does nothing.

Perhaps in a previous revision of the game, NPREF had a use.

PNOP $3A
(Probable Null OPeration)
$3A $8DB None None Does nothing.
PNOP $3B
(Probable Null OPeration)
$3B $8DC None None Does nothing.
PNOP $3C
(Probable Null OPeration)
$3C $8DB None None Does nothing.

Graphics Functions

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
TILELD
(TILE LoaD)
$72 $1BAC None base_attr, base_tile, tile_y, tile_x, linkage_index (TOP) -> (TOP) Load a precomposed tilemap from BugFS file linkage_index into the first tilemap in VRAM ($9800).

The base_tile and base_attr parameters allow the user to add a dynamic tile index and palette index offset to the tilemap. For example, if you loaded the tilemap's graphics into slot $30 on the second VRAM tile bank, with color data starting at BG palette 3, you could set base_tile to $30 and base_attr to Bank 1, Palette 3.

Tile X and Y coordinates allow you to control where the tilemap data is written. These coordinates are in tile units and are relative to the first visible tile on the screen (based on the current screen scroll).

RESLD
(RESource LoaD)
$5F $9C6 None linkage_index, copy_start, copy_len, target_addr, target_bank (TOP) -> (TOP) Load graphics resources from BugFS file linkage_index into tile memory.

copy_start determines how far into the resource to copy from, and copy_len determines how much to copy from that point. Both of these are in units of 32 bytes - exactly the size of a single tile.

target_addr and target_bank determines where to place the copied resources in VRAM. They are native memory pointers, not indexed to anything.

PRINT
(PRINT)
$4C $A84 None string_addr (TOP) -> (TOP) Print tile text onto the screen.

string_addr points to a null-terminated string in unbanked memory - usually some portion of the string arena that is written to by DB. Since that opcode returns an unbanked memory pointer on stack, one can print to the screen using just DB and PRINT opcodes.

The character $7F is special-cased in this function to print the player's name at $C9F0.

PRINT uses tile text in order to draw letters. A tile font must have been previously loaded in VRAM at tile location 0; it's encoded character value will be used as a tile index to draw with.

Window Management

Windows are regions of the background layer adorned with a border, intended to be drawn over the active playfield to represent dialogue or certain kinds of menus.

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
WINCLR
(WINdow CLeaR)
$5B $97C None None Clear the active window region.

Tiles will be set to $20, which is the encoded byte for a space. In any loaded font, this tile is intended to be blank.

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
WINWAIT
(WINdow WAIT)
$60 $A12 None None Wait for user input.

BugVM execution will halt until the user presses the "A" button on the system.

A blinking A-button prompt will be displayed at the bottom-right of the window range.

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
WINBRK
(WINdow BReaK)
$82 $ADA None None Insert a 'page break' of sorts between two full windows' worth of text.

Internally this is equivalent to a WINWAIT followed by a WINCLR.

Attribute Table Utilities

Opcode Encoding(s) Native Impl. Operand Args Stack Args Description
PRKEY
(PRint KEY item)
$9F $165A None attr_index (TOP) -> (TOP) Read the given Key Item's Attribute Table block and print it's name.
BLKKEY
(BLocK KEY item)
$A0 $42A None attr_index (TOP) -> (TOP) Read the given Key Item's Attribute Table block into W_Battle_AttrStaging.
PRMOVE
(PRint MOVE)
$A1 $1668 None attr_index (TOP) -> (TOP) Read the given Battle Move's Attribute Table block and print it's name.
BLKMOVE
(BLocK MOVE)
$A2 $3FE None attr_index (TOP) -> (TOP) Read the given Battle Move's Attribute Table block into W_Battle_AttrStaging.
PRMON
(PRint MONster)
$AF $1622 None attr_index (TOP) -> (TOP) Read the given Bug's Attribute Table block and print it's name.
BLKMON
(BLocK MONster)
$BB $39C None attr_index (TOP) -> (TOP) Read the given Bug's Attribute Table block into W_Battle_AttrStaging.

This instruction switches between two different Attribute Tables based on the value of W_System_GameVersion.

PRCHIP
(PRint CHIP)
$E3 $1661 None attr_index (TOP) -> (TOP) Read the given Chip's Attribute Table block and print it's name.
BLKCHIP
(BLocK CHIP)
$E2 $456 None attr_index (TOP) -> (TOP) Read the given Chip's Attribute Table block into W_Battle_AttrStaging.
BLKENC
(BLocK ENCounter)
$F1 $3CD None attr_index (TOP) -> (TOP) Read the given Encounter's Attribute Table block into W_Battle_AttrStaging.

There does not appear to be a PRENC instruction.

This instruction switches between two different Attribute Tables based on the value of W_System_GameVersion.

PRNAME
(PRint NAME)
$A5 $162A None None Print the name of the currently loaded Attribute Table block.

All PRint instructions that reference Attribute Table data execute this opcode. It prints data from $CF30, which is an offset into W_Battle_AttrStaging that appears to be a standard offset for this kind of data.