; DMGTRIS ; Copyright (C) 2023 - Randy Thiemann ; This program is free software: you can redistribute it and/or modify ; it under the terms of the GNU General Public License as published by ; the Free Software Foundation, either version 3 of the License, or ; (at your option) any later version. ; This program is distributed in the hope that it will be useful, ; but WITHOUT ANY WARRANTY; without even the implied warranty of ; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ; GNU General Public License for more details. ; You should have received a copy of the GNU General Public License ; along with this program. If not, see . IF !DEF(FIELD_ASM) DEF FIELD_ASM EQU 1 INCLUDE "globals.asm" DEF DELAY_STATE_DETERMINE_DELAY EQU 0 DEF DELAY_STATE_LINE_CLEAR EQU 1 DEF DELAY_STATE_LINE_PRE_CLEAR EQU 2 DEF DELAY_STATE_ARE EQU 3 DEF DELAY_STATE_PRE_ARE EQU 4 SECTION "Field Variables", WRAM0 wField:: ds (10*24) wBackupField:: ds (10*24) wShadowField:: ds (14*26) wWideField:: ds (5*10) wWideBlittedField:: ds (20*10) wDelayState: ds 1 SECTION "High Field Variables", HRAM hPieceDataBase: ds 2 hPieceDataBaseFast: ds 2 hPieceDataOffset: ds 1 hCurrentLockDelayRemaining:: ds 1 hGrounded: ds 1 hWantedTile: ds 1 hWantedG: ds 1 hActualG: ds 1 hGravityCtr: ds 1 hWantX: ds 1 hYPosAtStartOfFrame: ds 1 hWantRotation: ds 1 hRemainingDelay:: ds 1 hClearedLines: ds 4 hLineClearCt: ds 1 hComboCt: ds 1 hLockDelayForce: ds 1 hDownFrames: ds 1 hAwardDownBonus: ds 1 hStalePiece: ds 1 hBravo: ds 1 hShouldLockIfGrounded: ds 1 SECTION "Field Function Unbanked", ROM0 ; Blits the field onto the tile map. ; On the GBC, this chain calls into a special version that takes ; advantage of the GBC's CPU. BlitField:: ld a, [wInitialA] cp a, $11 jp z, GBCBlitField ; What to copy ld de, wField + 40 ; Where to put it ld hl, FIELD_TOP_LEFT ; How much to increment hl after each row ld bc, 32-10 ; The first 14 rows can be blitted without checking for vram access. REPT 14 REPT 10 ld a, [de] ld [hl+], a inc de ENDR add hl, bc ENDR : ldh a, [rLY] cp a, 0 jr nz, :- ; The last 6 rows need some care. REPT 6 ; Wait until start of drawing, then insert 35 nops. : ldh a, [rSTAT] and a, 3 cp a, 3 jr nz, :- REPT 35 nop ENDR ; Blit a line. REPT 10 ld a, [de] ld [hl+], a inc de ENDR ; Increment HL so that the next line can be blitted. add hl, bc ENDR ; This function is actually called as the vblank handler for the gameplay state. ; This is why it jumps straight back to the event loop. jp EventLoop ; Blits the field onto the tile map. ; On the GBC, this chain calls into a special version that takes ; advantage of the GBC's CPU. BigBlitField:: ld a, [wInitialA] cp a, $11 jp z, GBCBlitField ; What to copy ld de, wWideBlittedField ; Where to put it ld hl, FIELD_TOP_LEFT ; How much to increment hl after each row ld bc, 32-10 ; The first 14 rows can be blitted without checking for vram access. REPT 14 REPT 10 ld a, [de] ld [hl+], a inc de ENDR add hl, bc ENDR : ldh a, [rLY] cp a, 0 jr nz, :- ; The last 6 rows need some care. REPT 6 ; Wait until start of drawing, then insert 35 nops. : ldh a, [rSTAT] and a, 3 cp a, 3 jr nz, :- REPT 35 nop ENDR ; Blit a line. REPT 10 ld a, [de] ld [hl+], a inc de ENDR ; Increment HL so that the next line can be blitted. add hl, bc ENDR ; This function is actually called as the vblank handler for the gameplay state. ; This is why it jumps straight back to the event loop. jp EventLoop SECTION "Field Function Banked Gameplay", ROMX, BANK[BANK_GAMEPLAY] ; Initializes the field completely blank. ; Initializes the combo counter to 1. ; Initializes the bravo counter to 0. ; Initializes the shadow field. FieldInit:: xor a, a ldh [hBravo], a ld a, 1 ldh [hComboCt], a ld hl, wField ld bc, 10*24 ld d, TILE_BLANK call UnsafeMemSet ld hl, wShadowField ld bc, 14*26 ld d, $FF jp UnsafeMemSet ; Fills the field with the empty tile. FieldClear:: ld hl, wField ld bc, 10*24 ld d, TILE_FIELD_EMPTY jp UnsafeMemSet ; Backs up the field. ; This backup field is used for pausing the game. ToBackupField:: ld de, wField ld hl, wBackupField ld bc, 10*24 jp UnsafeMemCopy ; Restores the backup of the field for ending pause mode. FromBackupField:: ld hl, wField ld de, wBackupField ld bc, 10*24 jp UnsafeMemCopy ; Copies the field to the shadow field. ; This shadow field is used to calculate whether or not the piece can fit. ToShadowField:: ld hl, wField ld de, wShadowField+2 ld c, 24 .outer ld b, 10 .inner ld a, [hl+] ld [de], a inc de dec b jr nz, .inner inc de inc de inc de inc de dec c jr nz, .outer ret ; Restores the shadow field to the main field. FromShadowField: ld hl, wField ld de, wShadowField+2 ld c, 24 .outer ld b, 10 .inner ld a, [de] ld [hl+], a inc de dec b jr nz, .inner inc de inc de inc de inc de dec c jr nz, .outer ret ; The current piece ID is used to get the offset into the rotation states ; corresponding to that piece's zero rotation. SetPieceData: ldh a, [hCurrentPiece] sla a sla a sla a sla a ld c, a ld b, 0 ld hl, sPieceRotationStates add hl, bc ld a, l ldh [hPieceDataBase], a ld a, h ldh [hPieceDataBase+1], a ld hl, sPieceFastRotationStates add hl, bc ld a, l ldh [hPieceDataBaseFast], a ld a, h ldh [hPieceDataBaseFast+1], a ret ; The rotation state is a further offset of 4 bytes. SetPieceDataOffset: ldh a, [hCurrentPieceRotationState] sla a sla a ldh [hPieceDataOffset], a ret ; Converts piece Y in B and a piece X in A to a pointer to the shadow field in HL. XYToSFieldPtr: ld hl, wShadowField ld de, 14 inc a inc b : dec b jr z, :+ add hl, de jr :- : dec a ret z inc hl jr :- ret ; Converts piece Y in B and a piece X in A to a pointer to the field in HL. XYToFieldPtr: ld hl, wField-2 ld de, 10 inc a inc b : dec b jr z, :+ add hl, de jr :- : dec a ret z inc hl jr :- ret ; This function makes HL point to the correct offset into the rotation data. ; This version of the data is used for thorough checking (T, J, and L have ; a middle column exception.) GetPieceData: ldh a, [hPieceDataBase] ld l, a ldh a, [hPieceDataBase+1] ld h, a ldh a, [hPieceDataOffset] ld c, a ld b, 0 add hl, bc ret ; Same as the above but for the fast data. This data is used when the exact ; cell that failed isn't important. GetPieceDataFast: ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hPieceDataOffset] ld c, a xor a, a ld b, a add hl, bc ret ; Checks if the piece can fit at the current position. ; HL should point to the piece's rotation state data. ; DE should be pointing to the right place in the SHADOW field. ; This will return with $FF in A if the piece fits, or with the ; exact cell that caused the first failure in A. CanPieceFit: xor a, a ld b, a ; Row 1 bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, .r1end ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz .r1end REPT 11 inc de ENDR ; Row 2 inc b inc hl bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, .r2end ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz .r2end REPT 11 inc de ENDR ; Row 3 inc b inc hl bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, .r3end ld a, [de] cp a, TILE_FIELD_EMPTY ret nz .r3end REPT 11 inc de ENDR ; Row 4 inc b inc hl bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz ; If we got here, the piece can fit. : ld a, $FF ret ; Checks if the piece can fit at the current position, but fast. ; HL should point to the piece's fast rotation state data. ; DE should be pointing to the right place in the SHADOW field. ; This will return with $FF in A if the piece fits, or with a non-$FF ; value if it doesn't. CanPieceFitFast: ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, $FF ret ; This function will draw the piece even if it can't fit. ; We use this to draw a final failed spawn before going game ; over. ForceSpawnPiece:: call SetPieceData call SetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToFieldPtr ld d, h ld e, l call GetPieceData ld b, GAME_OVER_OTHER push hl push de pop hl pop de jp DrawPiece ; Initialize the state for a new piece and attempts to spawn it. ; On return, A will be $FF if the piece fit. TrySpawnPiece:: ; Always reset these for a new piece. xor a, a ldh [hStalePiece], a ldh [hDownFrames], a ldh [hAwardDownBonus], a ldh [hLockDelayForce], a ldh [hShouldLockIfGrounded], a ldh [hGravityCtr], a ldh [hGrounded], a ldh a, [hCurrentLockDelay] ldh [hCurrentLockDelayRemaining], a ld a, $FF ldh [hRemainingDelay], a ld a, DELAY_STATE_DETERMINE_DELAY ld [wDelayState], a ; Point the piece data to the correct piece. call SetPieceData call SetPieceDataOffset ; Get the piece's spawn position. ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ; Check if the piece can spawn. ld d, h ld e, l call GetPieceDataFast call CanPieceFitFast ; A will be $FF if the piece can fit. cp a, $FF ret z ; Otherwise, try in this order: 0, 1, 3, 2 ldh a, [hCurrentPieceRotationState] ldh [hWantRotation], a ; Try rotation state 0. .try0 cp a, 0 jr z, .try1 xor a, a ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l call GetPieceDataFast call CanPieceFitFast cp a, $FF ret z ; Try rotation state 1. .try1 ldh a, [hWantRotation] cp a, 1 jr z, .try3 ld a, 1 ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l call GetPieceDataFast call CanPieceFitFast cp a, $FF ret z ; Try rotation state 3. .try3 ldh a, [hWantRotation] cp a, 3 jr z, .try2 ld a, 3 ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l call GetPieceDataFast call CanPieceFitFast cp a, $FF ret z ; Try rotation state 2. .try2 ld a, 2 ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l call GetPieceDataFast jp CanPieceFitFast ; Draws the piece onto the field. ; B is the tile. ; DE should point to the piece's rotation state data. ; HL should be pointing to the right place in the NORMAL field. DrawPiece: ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a jr z, .r1end2 ld [hl], b .r1end2 REPT 7 inc hl ENDR ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a jr z, .r2end2 ld [hl], b .r2end2 REPT 7 inc hl ENDR ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a jr z, .r3end2 ld [hl], b .r3end2 REPT 7 inc hl ENDR ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a ret z ld [hl], b ret FindMaxG: ; Find the deepest the piece can go. ; We cache this pointer, cause it otherwise takes too much time. ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr push hl ld a, 1 ldh [hActualG], a .try ld de, 14 pop hl add hl, de push hl ld d, h ld e, l call GetPieceDataFast call CanPieceFitFast cp a, $FF jr nz, .found ldh a, [hActualG] inc a ldh [hActualG], a jr .try .found pop hl ldh a, [hActualG] dec a ldh [hActualG], a ret ; This is the main function that will process input, gravity, and locking. ; It should be ran once per frame as long as lock delay is greater than 0. FieldProcess:: ; ************************************************************** ; SETUP ; Wipe out the piece. ldh a, [hCurrentPieceY] ldh [hYPosAtStartOfFrame], a call FromShadowField ; Cleanup from last frame. ldh a, [hCurrentPieceX] ldh [hWantX], a ldh a, [hCurrentPieceRotationState] ldh [hWantRotation], a ; Is this the first frame of the piece? .firstframe ldh a, [hStalePiece] cp a, 0 jr nz, .handleselect ld a, $FF ldh [hStalePiece], a jp .skipmovement ; ************************************************************** ; HANDLE SELECT ; Check if we're about to hold. Return if so. .handleselect ldh a, [hSelectState] cp a, 1 jr nz, .wantrotccw ldh a, [hHoldSpent] cp a, $FF ret nz ; ************************************************************** ; HANDLE ROTATION ; Want rotate CCW? .wantrotccw ld a, [wSwapABState] cp a, 0 jr z, .ldb1 .lda1 ldh a, [hAState] jr .cp1 .ldb1 ldh a, [hBState] .cp1 cp a, 1 jr nz, .wantrotcw ldh a, [hWantRotation] inc a and a, $03 ldh [hWantRotation], a jr .tryrot ; Want rotate CW? .wantrotcw ld a, [wSwapABState] cp a, 0 jr z, .lda2 .ldb2 ldh a, [hBState] jr .cp2 .lda2 ldh a, [hAState] .cp2 cp a, 1 jp nz, .norot ldh a, [hWantRotation] dec a and a, $03 ldh [hWantRotation], a ; Try the rotation. .tryrot ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBase] ld l, a ldh a, [hPieceDataBase+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call CanPieceFit ; This does have to be the "slow" version. cp a, $FF jr nz, .maybekick ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; Try kicks if the piece isn't I or O. And in the case of J L and T, only if the blocked side is the left or right. .maybekick ld c, a ; No kicks for NES mode. ld a, [wRotModeState] cp a, ROT_MODE_NES jp z, .norot ldh a, [hCurrentPiece] ; O pieces never kick, obviously. cp a, PIECE_O jp z, .norot ; S/Z always kick. cp a, PIECE_S jr z, .trykickright cp a, PIECE_Z jr z, .trykickright ; I piece only kicks in ARS2 cp a, PIECE_I jr nz, :+ ld a, [wRotModeState] cp a, ROT_MODE_ARSTI jp nz, .norot ldh a, [hWantRotation] bit 0, a jp nz, .checki jr .trykickright ; T/L/J only kick if not through the middle axis. : ld a, c cp a, 1 jp z, .maybetgm3rot cp a, 5 jr z, .maybetgm3rot cp a, 9 jr z, .maybetgm3rot ; A step to the right. .trykickright ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] inc a call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call CanPieceFitFast cp a, $FF jr nz, .trykickleft ldh a, [hCurrentPieceX] inc a ldh [hCurrentPieceX], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; And a step to the left. .trykickleft ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] dec a call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call CanPieceFitFast cp a, $FF jr nz, .maybetgm3rot ldh a, [hCurrentPieceX] dec a ldh [hCurrentPieceX], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; In ARS2 mode, there are a few other kicks possible. .maybetgm3rot ld a, [wRotModeState] cp a, ROT_MODE_ARSTI jp nz, .norot ; In the case of a T piece, try the space above. .checkt ldh a, [hCurrentPiece] cp a, PIECE_T jr nz, .checki ldh a, [hCurrentPieceY] dec a ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call CanPieceFitFast cp a, $FF jp nz, .norot ldh a, [hCurrentPieceY] dec a ldh [hCurrentPieceY], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set lock delay forcing to 1 if it's 0. cp a, 0 jr nz, :+ inc a ldh [hLockDelayForce], a jp .norot : cp a, 1 ; Or to 2 if it's 1. jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; In the case of an I piece... .checki ldh a, [hCurrentPiece] cp a, PIECE_I jp nz, .norot ; What direction do we want to end up? ldh a, [hWantRotation] bit 0, a jp z, .tryiright2 ; Flat? Sideways kicks are fine. ; Upright? Only up kicks. ; Are we grounded? Don't kick if we aren't. ldh a, [hActualG] cp a, 0 jp nz, .norot ; Try up once. .tryiup1 ldh a, [hCurrentPieceY] dec a ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call CanPieceFitFast cp a, $FF jr nz, .tryiup2 ldh a, [hCurrentPieceY] dec a ldh [hCurrentPieceY], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set lock delay forcing to 1 if it's 0. cp a, 0 jr nz, :+ inc a ldh [hLockDelayForce], a jp .norot : cp a, 1 ; Or to 2 if it's 1. jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; Try up twice. .tryiup2 ldh a, [hCurrentPieceY] dec a dec a ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call CanPieceFitFast cp a, $FF jr nz, .norot ldh a, [hCurrentPieceY] dec a dec a ldh [hCurrentPieceY], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set lock delay forcing to 1 if it's 0. cp a, 0 jr nz, :+ inc a ldh [hLockDelayForce], a jp .norot : cp a, 1 ; Or to 2 if it's 1. jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; Try right twice. .tryiright2 ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] inc a inc a call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call CanPieceFitFast cp a, $FF jr nz, .norot ldh a, [hCurrentPieceX] inc a inc a ldh [hCurrentPieceX], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a ; ************************************************************** ; HANDLE MOVEMENT ; Do we want to move left? .norot ldh a, [hLeftState] ; Check if held for 1 frame. If so we move. cp a, 1 jr z, .doleft cp a, 0 ; We never want to move if the button wasn't held. jr z, .wantright ld b, a ldh a, [hCurrentIntegerGravity] cp a, 20 ; No increased DAS at 20G. jr z, .checkdasleft ldh a, [hGrounded] ; If we're grounded, assume some urgency in getting DAS charged, charge at twice the rate. cp a, $FF jr nz, .checkdasleft inc b ld a, b ldh [hLeftState], a .checkdasleft ldh a, [hCurrentDAS] ld c, a ld a, b cp a, c jr c, .wantright .doleft ldh a, [hWantX] dec a ldh [hWantX], a jr .trymove ; Do we want to move right? .wantright ldh a, [hRightState] ; Check if held for 1 frame. If so we move. cp a, 1 jr z, .doright cp a, 0 ; We never want to move if the button wasn't held. jr z, .donemanipulating ld b, a ldh a, [hCurrentIntegerGravity] cp a, 20 ; No increased DAS at 20G. jr z, .checkdasright ldh a, [hGrounded] ; If we're grounded, assume some urgency in getting DAS charged, charge at twice the rate. cp a, $FF jr nz, .checkdasright inc b ld a, b ldh [hRightState], a .checkdasright ldh a, [hCurrentDAS] ld c, a ld a, b cp a, c jr c, .donemanipulating .doright ldh a, [hWantX] inc a ldh [hWantX], a ; Try the movement. .trymove ldh a, [hCurrentPieceY] ld b, a ldh a, [hWantX] call XYToSFieldPtr ld d, h ld e, l call GetPieceDataFast call CanPieceFitFast cp a, $FF jr nz, .donemanipulating ldh a, [hWantX] ldh [hCurrentPieceX], a ; ************************************************************** ; HANDLE MAXIMUM FALL ; This little maneuver is going to cost us 51 years. .skipmovement .donemanipulating : call FindMaxG ; ************************************************************** ; HANDLE UP ; Assume 1G or lower. ld a, 1 ldh [hWantedG], a ; Is a hard/sonic drop requested? Skip if in 20G mode. ldh a, [hCurrentIntegerGravity] cp a, 20 jr z, .postdrop ldh a, [hUpState] cp a, 1 jr nz, .postdrop ; What kind, if any? ld a, [wDropModeState] cp a, DROP_MODE_NONE jr z, .postdrop cp a, DROP_MODE_LOCK jr z, .harddrop cp a, DROP_MODE_HARD jr z, .harddrop ; Sonic drop. .sonicdrop ld a, [wDropModeState] cp a, DROP_MODE_SNIC jr z, :+ ld a, $FF ldh [hShouldLockIfGrounded], a : ld a, $FF ldh [hAwardDownBonus], a ld a, 20 ldh [hWantedG], a jr .grav ; Hard drop. .harddrop ld a, $FF ldh [hAwardDownBonus], a ld a, 20 ldh [hWantedG], a ld b, a ldh a, [hActualG] cp a, b jr nc, :+ ld b, a : ldh a, [hCurrentPieceY] add a, b ldh [hCurrentPieceY], a xor a, a ldh [hCurrentLockDelayRemaining], a ld a, SFX_LOCK call SFXTriggerNoise jp .draw ; If we press down, we want to do a soft drop. .postdrop ldh a, [hDownState] cp a, 0 jr z, :+ ldh a, [hDownFrames] inc a ldh [hDownFrames], a ld a, $FF ldh [hGravityCtr], a ld a, [wDropModeState] cp a, DROP_MODE_HARD jr nz, :+ ld a, $FF ldh [hShouldLockIfGrounded], a ; Gravity? : ldh a, [hCurrentFractionalGravity] cp a, $00 ; 0 is the sentinel value that should be interpreted as "every frame" jr z, :+ ld b, a ldh a, [hGravityCtr] add a, b ldh [hGravityCtr], a jr nc, .nograv : ldh a, [hCurrentIntegerGravity] ldh [hWantedG], a ; Can we drop the full requested distance? .grav ldh a, [hWantedG] ld b, a ldh a, [hActualG] cp a, b jr c, .smallg ; Yes. Do it. .bigg ldh a, [hWantedG] ld b, a ldh a, [hCurrentPieceY] add a, b ldh [hCurrentPieceY], a jr .postgrav ; No. Smaller distance. .smallg ldh a, [hActualG] ld b, a ldh a, [hCurrentPieceY] add a, b ldh [hCurrentPieceY], a ; ************************************************************** ; HANDLE LOCKING ; Are we grounded? .postgrav .nograv xor a, a ldh [hGrounded], a ldh a, [hYPosAtStartOfFrame] ld b, a ldh a, [hCurrentPieceY] cp a, b jr z, .noreset ldh a, [hCurrentLockDelay] ldh [hCurrentLockDelayRemaining], a .noreset ldh a, [hCurrentPieceY] inc a ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l call GetPieceDataFast call CanPieceFitFast cp a, $FF jp z, .notgrounded ; We're grounded. .grounded ld a, $FF ldh [hGrounded], a ldh a, [hCurrentPieceY] ld b, a ldh a, [hYPosAtStartOfFrame] cp a, b jr z, .postcheckforfirmdropsound ; Never play the sound if we didn't change rows. ldh a, [hDownState] cp a, 0 jr nz, .postcheckforfirmdropsound ; Don't play the sound if we're holding down. ; Play the firm drop sound, and also reset the lock delay since the piece stepped down. .playfirmdropsound ld a, SFX_LAND call SFXTriggerNoise ; If the down button is held, lock. .postcheckforfirmdropsound ldh a, [hDownState] cp a, 0 jr z, .neutralcheck ; Don't lock on down for hard drop mode immediately. ld a, [wDropModeState] cp a, DROP_MODE_HARD jr nz, :+ ld a, $FF ldh [hShouldLockIfGrounded], a jr .dontforcelock ; Lock on down in modes <20G. : ldh a, [hCurrentIntegerGravity] cp a, 20 jr nz, .forcelock ; In 20G mode, only lock if down has been pressed for exactly 1 frame. ldh a, [hDownState] cp a, 1 jr z, .forcelock jr .dontforcelock ; If the down button is not held, check if we're neutral and if that should lock. .neutralcheck ldh a, [hShouldLockIfGrounded] cp a, 0 jr z, .dontforcelock ; Check for neutral. ldh a, [hUpState] cp a, 0 jr nz, .dontforcelock ldh a, [hLeftState] cp a, 0 jr nz, .dontforcelock ldh a, [hRightState] cp a, 0 jr nz, .dontforcelock ; Lock on neutral for a few modes. ld a, [wDropModeState] cp a, DROP_MODE_FIRM jr z, .forcelock cp a, DROP_MODE_HARD jr z, .forcelock jr .dontforcelock ; Set the lock delay to 0 and save it. .forcelock xor a, a ldh [hCurrentLockDelayRemaining], a jr .dolock ; Load the lock delay. ; Decrement it by one and save it. .dontforcelock ldh a, [hCurrentLockDelayRemaining] dec a ldh [hCurrentLockDelayRemaining], a ; Are we out of lock delay? .checklockdelay cp a, 0 jr nz, .checkfortgm3lockexception ; If not, check if the TGM3 exception applies. jr .dolock ; Otherwise, lock! ; TGM3 sometimes forces a piece to immediately lock. .checkfortgm3lockexception ldh a, [hLockDelayForce] cp a, 2 jr nz, .draw ; It's not forced, so go to drawing. xor a, a ; It is forced, so force it! ldh [hCurrentLockDelayRemaining], a ; Play the locking sound and draw the piece. .dolock ld a, SFX_LOCK call SFXTriggerNoise jr .draw ; If we weren't grounded, reset the lock force. .notgrounded xor a, a ldh [hShouldLockIfGrounded], a ; ************************************************************** ; HANDLE DRAWING ; Draw the piece. .draw ; If the piece is locked, skip the ghost piece. ldh a, [hCurrentLockDelayRemaining] cp a, 0 jr z, .postghost ; If the gravity is <= 1G, draw a ghost piece. ldh a, [hWantedG] cp a, 1 jr nz, .postghost ld a, [wInitialA] ; Let's not do the flickering on the GBC. cp a, $11 jr z, .ghost ldh a, [hEvenFrame] cp a, 1 jr nz, .postghost .ghost ldh a, [hYPosAtStartOfFrame] ld b, a ldh a, [hActualG] add a, b ld b, a ldh a, [hCurrentPieceX] call XYToFieldPtr ld d, h ld e, l call GetPieceData ld a, TILE_GHOST ld b, a push hl push de pop hl pop de call DrawPiece .postghost ; If the lock delay is at the highest value, draw the piece normally. ldh a, [hCurrentPiece] ld b, TILE_PIECE_0 add a, b ldh [hWantedTile], a ldh a, [hCurrentLockDelay] ld b, a ldh a, [hCurrentLockDelayRemaining] cp a, b jr z, .drawpiece ; If the lock delay is 0, draw the piece in the final color. ldh a, [hWantedTile] add a, 7 ldh [hWantedTile], a ldh a, [hCurrentLockDelayRemaining] cp a, 0 jr z, .drawpiece ; If we're not grounded, draw the piece normally. ldh a, [hWantedTile] sub a, 7 ldh [hWantedTile], a ldh a, [hGrounded] cp a, $FF jr nz, .drawpiece ; Otherwise, look it up. call GetTileShade .drawpiece ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToFieldPtr ld d, h ld e, l call GetPieceData ldh a, [hWantedTile] ld b, a push hl push de pop hl pop de call DrawPiece ret ; Performs a lookup to see how "locked" the piece is. GetTileShade: ldh a, [hCurrentLockDelay] cp a, 30 jr nc, .max30 cp a, 20 jr nc, .max20 cp a, 10 jr nc, .max10 jr .max0 ret .max30 ldh a, [hCurrentLockDelayRemaining] cp a, 4 ret c cp a, 8 jp c, .s6 cp a, 12 jr c, .s5 cp a, 16 jr c, .s4 cp a, 20 jr c, .s3 cp a, 24 jr c, .s2 cp a, 28 jr c, .s1 jr .s0 .max20 ldh a, [hCurrentLockDelayRemaining] cp a, 2 ret c cp a, 5 jr c, .s6 cp a, 7 jr c, .s5 cp a, 10 jr c, .s4 cp a, 12 jr c, .s3 cp a, 15 jr c, .s2 cp a, 17 jr c, .s1 jr .s0 .max10 ldh a, [hCurrentLockDelayRemaining] cp a, 1 ret c cp a, 2 jr c, .s6 cp a, 3 jr c, .s5 cp a, 5 jr c, .s4 cp a, 6 jr c, .s3 cp a, 7 jr c, .s2 cp a, 8 jr c, .s1 jr .s0 .max0 jr .s4 .s0 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0 add a, b ldh [hWantedTile], a ret .s1 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(2*7) add a, b ldh [hWantedTile], a ret .s2 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(3*7) add a, b ldh [hWantedTile], a ret .s3 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(4*7) add a, b ldh [hWantedTile], a ret .s4 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(5*7) add a, b ldh [hWantedTile], a ret .s5 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(6*7) add a, b ldh [hWantedTile], a ret .s6 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(7*7) add a, b ldh [hWantedTile], a ret ; This is called every frame after a piece has been locked until the delay state ends. ; Lines are cleared, levels and score are awarded, and ARE time is waited out. FieldDelay:: ; Switch on the delay state. ld a, [wDelayState] cp DELAY_STATE_DETERMINE_DELAY jr z, .determine cp DELAY_STATE_LINE_PRE_CLEAR jr z, .prelineclear cp DELAY_STATE_LINE_CLEAR jp z, .lineclear cp DELAY_STATE_PRE_ARE jp z, .preare jp .are ; Check if there were line clears. ; If so, we need to do a line clear delay. ; Otherwise, we skip to ARE delay. .determine ; Increment bravo by 4. ldh a, [hBravo] add a, 4 ldh [hBravo], a ; Are there line clears? call ToShadowField call FindClearedLines ldh a, [hClearedLines] ld b, a ldh a, [hClearedLines+1] ld c, a ldh a, [hClearedLines+2] ld d, a ldh a, [hClearedLines+3] and a, b and a, c and a, d cp a, $FF jr z, .skip ld a, DELAY_STATE_LINE_PRE_CLEAR ; If there were line clears, do a line clear delay, then a LINE_ARE delay. ld [wDelayState], a ldh a, [hCurrentLineClearDelay] ldh [hRemainingDelay], a call MarkClear jp .prelineclear .skip ld a, DELAY_STATE_PRE_ARE ; If there were no line clears, do an ARE delay. ld [wDelayState], a ldh a, [hCurrentARE] ldh [hRemainingDelay], a jp .preare ; Pre-line clear delay. ; If we had line clears, immediately hand out the score and the levels. .prelineclear: ld a, DELAY_STATE_LINE_CLEAR ld [wDelayState], a ldh a, [hLineClearCt] cp a, 0 jr z, .lineclear ; If not, just skip the phase. ; There were line clears! Clear the level counter breakpoint. xor a, a ldh [hRequiresLineClear], a ; Decrement bravo by 10 for each line clear. ldh a, [hLineClearCt] ld b, a ldh a, [hBravo] : sub a, 10 dec b jr nz, :- ldh [hBravo], a ; Increment the level counter by the amount of lines. .applylines ldh a, [hLineClearCt] ld e, a call LevelUp ; Score the line clears. ; Get the new level. ldh a, [hLevel] ld l, a ldh a, [hLevel+1] ld h, a ; Divide by 4. srl h rr l srl h rr l ; Add 1. inc hl ; Add soft drop points. ldh a, [hDownFrames] ld c, a xor a, a ld b, a ; Lock bonus? ldh a, [hAwardDownBonus] cp a, $FF jr nz, .premultiplier ld a, 10 add a, c ld c, a ; Final total pre-multipliers. .premultiplier add hl, bc ; Copy the running total for multiplication. ld b, h ld c, l ; Do we have a bravo? x4 if so. .bravo ldh a, [hBravo] cp a, 0 jr nz, .lineclears add hl, bc jr c, .forcemax add hl, bc jr c, .forcemax add hl, bc jr c, .forcemax ld b, h ld c, l ; x line clears .lineclears ldh a, [hLineClearCt] dec a jr z, .combo : add hl, bc jr c, .forcemax dec a jr nz, :- ld b, h ld c, l ; x combo .combo ldh a, [hComboCt] dec a jr z, .applyscore : add hl, bc jr c, .forcemax dec a jr nz, :- jr .applyscore ; Overflow = 65535 .forcemax ld a, $FF ld h, a ld l, a ; And apply the score. .applyscore ld a, l ldh [hScoreIncrement], a ld a, h ldh [hScoreIncrement+1], a call IncreaseScore ; Update the combo counter. ldh a, [hLineClearCt] ld b, a ldh a, [hComboCt] ; Old combo count. add b ; + lines add b ; + lines sub 2 ; - 2 ldh [hComboCt], a ; Line clear delay. ; Count down the delay. If we're out of delay, clear the lines and go to LINE_ARE. .lineclear ldh a, [hRemainingDelay] dec a ldh [hRemainingDelay], a cp a, 0 ret nz call ClearLines ld a, SFX_LINE_CLEAR call SFXTriggerNoise : ldh a, [hCurrentLineARE] ldh [hRemainingDelay], a ; Pre-ARE delay. .preare: ld a, DELAY_STATE_ARE ld [wDelayState], a ; Copy over the newly cleaned field. call ToShadowField ; Don't do anything if there were line clears ldh a, [hLineClearCt] cp a, 0 jr nz, .are ; Otherwise, reset the combo. ld a, 1 ldh [hComboCt], a ; ARE delay. ; Count down the delay. If it hits 0, award levels and score if necessary, then end the delay phase. .are ldh a, [hRemainingDelay] dec a ldh [hRemainingDelay], a cp a, 0 ret nz ; Add one level if we're not at a breakpoint. ldh a, [hRequiresLineClear] cp a, $FF jr z, :+ ld e, 1 call LevelUp ; Cycle the RNG. : ldh a, [hNextPiece] ldh [hCurrentPiece], a call GetNextPiece ; Kill the sound for the next piece. jp SFXKill ; Shifts B into the line clear list. ; Also increments the line clear count. AppendClearedLine: ldh a, [hLineClearCt] inc a ldh [hLineClearCt], a ldh a, [hClearedLines+2] ldh [hClearedLines+3], a ldh a, [hClearedLines+1] ldh [hClearedLines+2], a ldh a, [hClearedLines] ldh [hClearedLines+1], a ld a, b ldh [hClearedLines], a ret ; Scans the field for lines that are completely filled with non-empty spaces. ; Every time one is found, it is added to a list. FindClearedLines: xor a, a ldh [hLineClearCt], a ld a, $FF ld c, 0 ldh [hClearedLines], a ldh [hClearedLines+1], a ldh [hClearedLines+2], a ldh [hClearedLines+3], a DEF row = 23 REPT 24 ld hl, wShadowField+2+(row*14) ld b, 11 : ld a, [hl+] dec b cp a, $FF jr z, :+ cp a, TILE_FIELD_EMPTY jr nz, :- : xor a, a cp a, b jr nz, .next\@ ld b, 23-row call AppendClearedLine inc c ld a, 4 cp a, c ret z DEF row -= 1 .next\@ ENDR ret ; Goes through the list of cleared lines and marks those lines with the "line clear" tile. MarkClear: ldh a, [hClearedLines] cp a, $FF ret z ld hl, wField+(24*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 10 ld d, TILE_CLEARING call UnsafeMemSet ldh a, [hClearedLines+1] cp a, $FF ret z ld hl, wField+(24*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 10 ld d, TILE_CLEARING call UnsafeMemSet ldh a, [hClearedLines+2] cp a, $FF ret z ld hl, wField+(24*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 10 ld d, TILE_CLEARING call UnsafeMemSet ldh a, [hClearedLines+3] cp a, $FF ret z ld hl, wField+(24*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 10 ld d, TILE_CLEARING jp UnsafeMemSet ; Once again, scans the field for cleared lines, but this time removes them. ClearLines: ld de, 0 DEF row = 23 REPT 23 ; Check if the row begins with a clearing tile. ld hl, wField+(row*10) ld a, [hl] cp a, TILE_CLEARING ; If it does, increment the clearing counter, but skip this line. jr nz, .clear\@ inc de inc de inc de inc de inc de inc de inc de inc de inc de inc de jr .r\@ .clear\@ ; If there's 0 lines that need to be moved down, skip this line. xor a, a cp a, e jr z, .r\@ ; Otherwise... ld bc, wField+(row*10) add hl, de : ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc .r\@ DEF row -= 1 ENDR ; Make sure there's no garbage in the top de lines. .fixgarbo ld hl, wField : xor a, a or a, d or a, e ret z ld a, TILE_FIELD_EMPTY ld [hl+], a dec de jr :- ret SECTION "Field Function Banked Gameplay Big", ROMX, BANK[BANK_GAMEPLAY_BIG] ; Initializes the field completely blank. ; Initializes the combo counter to 1. ; Initializes the bravo counter to 0. ; Initializes the shadow field. BigFieldInit:: xor a, a ldh [hBravo], a ld a, 1 ldh [hComboCt], a ld hl, wField ld bc, 10*24 ld d, TILE_BLANK call UnsafeMemSet ld hl, wWideBlittedField ld bc, 10*20 ld d, TILE_BLANK call UnsafeMemSet ld hl, wShadowField ld bc, 14*26 ld d, $FF jp UnsafeMemSet ; Fills the field with the empty tile. BigFieldClear:: ld hl, wField ld bc, 10*24 ld d, 0 call UnsafeMemSet DEF row = 0 REPT 14 ld hl, wField + (row*10) ld bc, 5 ld d, TILE_FIELD_EMPTY call UnsafeMemSet DEF row += 1 ENDR ret ; Backs up the field. ; This backup field is used for pausing the game. BigToBackupField:: ld de, wField ld hl, wBackupField ld bc, 10*24 jp UnsafeMemCopy ; Restores the backup of the field for ending pause mode. BigFromBackupField:: ld hl, wField ld de, wBackupField ld bc, 10*24 jp UnsafeMemCopy ; Copies the field to the shadow field. ; This shadow field is used to calculate whether or not the piece can fit. BigToShadowField:: ld hl, wField ld de, wShadowField+2 ld c, 24 .outer ld b, 10 .inner ld a, [hl+] ld [de], a inc de dec b jr nz, .inner inc de inc de inc de inc de dec c jr nz, .outer ret ; Restores the shadow field to the main field. BigFromShadowField: ld hl, wField ld de, wShadowField+2 ld c, 24 .outer ld b, 10 .inner ld a, [de] ld [hl+], a inc de dec b jr nz, .inner inc de inc de inc de inc de dec c jr nz, .outer ret ; The current piece ID is used to get the offset into the rotation states ; corresponding to that piece's zero rotation. BigSetPieceData: ldh a, [hCurrentPiece] sla a sla a sla a sla a ld c, a ld b, 0 ld hl, sBigPieceRotationStates add hl, bc ld a, l ldh [hPieceDataBase], a ld a, h ldh [hPieceDataBase+1], a ld hl, sBigPieceFastRotationStates add hl, bc ld a, l ldh [hPieceDataBaseFast], a ld a, h ldh [hPieceDataBaseFast+1], a ret ; The rotation state is a further offset of 4 bytes. BigSetPieceDataOffset: ldh a, [hCurrentPieceRotationState] sla a sla a ldh [hPieceDataOffset], a ret ; Converts piece Y in B and a piece X in A to a pointer to the shadow field in HL. BigXYToSFieldPtr: ld hl, wShadowField ld de, 14 inc a inc b : dec b jr z, :+ add hl, de jr :- : dec a ret z inc hl jr :- ret ; Converts piece Y in B and a piece X in A to a pointer to the field in HL. BigXYToFieldPtr: ld hl, wField-2 ld de, 10 inc a inc b : dec b jr z, :+ add hl, de jr :- : dec a ret z inc hl jr :- ret ; This function makes HL point to the correct offset into the rotation data. ; This version of the data is used for thorough checking (T, J, and L have ; a middle column exception.) BigGetPieceData: ldh a, [hPieceDataBase] ld l, a ldh a, [hPieceDataBase+1] ld h, a ldh a, [hPieceDataOffset] ld c, a ld b, 0 add hl, bc ret ; Same as the above but for the fast data. This data is used when the exact ; cell that failed isn't important. BigGetPieceDataFast: ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hPieceDataOffset] ld c, a xor a, a ld b, a add hl, bc ret ; Checks if the piece can fit at the current position. ; HL should point to the piece's rotation state data. ; DE should be pointing to the right place in the SHADOW field. ; This will return with $FF in A if the piece fits, or with the ; exact cell that caused the first failure in A. BigCanPieceFit: xor a, a ld b, a ; Row 1 bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, .r1end ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz .r1end REPT 11 inc de ENDR ; Row 2 inc b inc hl bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, .r2end ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz .r2end REPT 11 inc de ENDR ; Row 3 inc b inc hl bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, .r3end ld a, [de] cp a, TILE_FIELD_EMPTY ret nz .r3end REPT 11 inc de ENDR ; Row 4 inc b inc hl bit 3, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 2, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 1, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz : inc de inc b bit 0, [hl] jr z, :+ ld a, [de] cp a, TILE_FIELD_EMPTY ld a, b ret nz ; If we got here, the piece can fit. : ld a, $FF ret ; Checks if the piece can fit at the current position, but fast. ; HL should point to the piece's fast rotation state data. ; DE should be pointing to the right place in the SHADOW field. ; This will return with $FF in A if the piece fits, or with a non-$FF ; value if it doesn't. BigCanPieceFitFast: ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, [hl+] add a, e ld e, a adc a, d sub e ld d, a ld a, [de] cp a, TILE_FIELD_EMPTY jr z, :+ xor a, a ret : ld a, $FF ret ; This function will draw the piece even if it can't fit. ; We use this to draw a final failed spawn before going game ; over. BigForceSpawnPiece:: call BigSetPieceData call BigSetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToFieldPtr ld d, h ld e, l call BigGetPieceData ld b, GAME_OVER_OTHER push hl push de pop hl pop de jp BigDrawPiece ; Initialize the state for a new piece and attempts to spawn it. ; On return, A will be $FF if the piece fit. BigTrySpawnPiece:: ; Always reset these for a new piece. xor a, a ldh [hStalePiece], a ldh [hDownFrames], a ldh [hAwardDownBonus], a ldh [hLockDelayForce], a ldh [hShouldLockIfGrounded], a ldh [hGravityCtr], a ldh [hGrounded], a ldh a, [hCurrentLockDelay] ldh [hCurrentLockDelayRemaining], a ld a, $FF ldh [hRemainingDelay], a ld a, DELAY_STATE_DETERMINE_DELAY ld [wDelayState], a ; Point the piece data to the correct piece. call BigSetPieceData call BigSetPieceDataOffset ; Get the piece's spawn position. ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ; Check if the piece can spawn. ld d, h ld e, l call BigGetPieceDataFast call BigCanPieceFitFast ; A will be $FF if the piece can fit. cp a, $FF ret z ; Otherwise, try in this order: 0, 1, 3, 2 ldh a, [hCurrentPieceRotationState] ldh [hWantRotation], a ; Try rotation state 0. .try0 cp a, 0 jr z, .try1 xor a, a ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call XYToSFieldPtr ld d, h ld e, l call BigGetPieceDataFast call BigCanPieceFitFast cp a, $FF ret z ; Try rotation state 1. .try1 ldh a, [hWantRotation] cp a, 1 jr z, .try3 ld a, 1 ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l call BigGetPieceDataFast call BigCanPieceFitFast cp a, $FF ret z ; Try rotation state 3. .try3 ldh a, [hWantRotation] cp a, 3 jr z, .try2 ld a, 3 ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l call BigGetPieceDataFast call BigCanPieceFitFast cp a, $FF ret z ; Try rotation state 2. .try2 ld a, 2 ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l call BigGetPieceDataFast jp BigCanPieceFitFast ; Draws the piece onto the field. ; B is the tile. ; DE should point to the piece's rotation state data. ; HL should be pointing to the right place in the NORMAL field. BigDrawPiece: ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a jr z, .r1end2 ld [hl], b .r1end2 REPT 7 inc hl ENDR ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a jr z, .r2end2 ld [hl], b .r2end2 REPT 7 inc hl ENDR ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a jr z, .r3end2 ld [hl], b .r3end2 REPT 7 inc hl ENDR ld a, [de] inc de bit 3, a jr z, :+ ld [hl], b : inc hl bit 2, a jr z, :+ ld [hl], b : inc hl bit 1, a jr z, :+ ld [hl], b : inc hl bit 0, a ret z ld [hl], b ret BigFindMaxG: ; Find the deepest the piece can go. ; We cache this pointer, cause it otherwise takes too much time. ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr push hl ld a, 1 ldh [hActualG], a .try ld de, 14 pop hl add hl, de push hl ld d, h ld e, l call BigGetPieceDataFast call BigCanPieceFitFast cp a, $FF jr nz, .found ldh a, [hActualG] inc a ldh [hActualG], a jr .try .found pop hl ldh a, [hActualG] dec a ldh [hActualG], a ret ; This is the main function that will process input, gravity, and locking. ; It should be ran once per frame as long as lock delay is greater than 0. BigFieldProcess:: ; ************************************************************** ; SETUP ; Wipe out the piece. ldh a, [hCurrentPieceY] ldh [hYPosAtStartOfFrame], a call BigFromShadowField ; Cleanup from last frame. ldh a, [hCurrentPieceX] ldh [hWantX], a ldh a, [hCurrentPieceRotationState] ldh [hWantRotation], a ; Is this the first frame of the piece? .firstframe ldh a, [hStalePiece] cp a, 0 jr nz, .handleselect ld a, $FF ldh [hStalePiece], a jp .skipmovement ; ************************************************************** ; HANDLE SELECT ; Check if we're about to hold. Return if so. .handleselect ldh a, [hSelectState] cp a, 1 jr nz, .wantrotccw ldh a, [hHoldSpent] cp a, $FF ret nz ; ************************************************************** ; HANDLE ROTATION ; Want rotate CCW? .wantrotccw ld a, [wSwapABState] cp a, 0 jr z, .ldb1 .lda1 ldh a, [hAState] jr .cp1 .ldb1 ldh a, [hBState] .cp1 cp a, 1 jr nz, .wantrotcw ldh a, [hWantRotation] inc a and a, $03 ldh [hWantRotation], a jr .tryrot ; Want rotate CW? .wantrotcw ld a, [wSwapABState] cp a, 0 jr z, .lda2 .ldb2 ldh a, [hBState] jr .cp2 .lda2 ldh a, [hAState] .cp2 cp a, 1 jp nz, .norot ldh a, [hWantRotation] dec a and a, $03 ldh [hWantRotation], a ; Try the rotation. .tryrot ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBase] ld l, a ldh a, [hPieceDataBase+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call BigCanPieceFit ; This does have to be the "slow" version. cp a, $FF jr nz, .maybekick ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; Try kicks if the piece isn't I or O. And in the case of J L and T, only if the blocked side is the left or right. .maybekick ld c, a ; No kicks for NES mode. ld a, [wRotModeState] cp a, ROT_MODE_NES jp z, .norot ldh a, [hCurrentPiece] ; O pieces never kick, obviously. cp a, PIECE_O jp z, .norot ; S/Z always kick. cp a, PIECE_S jr z, .trykickright cp a, PIECE_Z jr z, .trykickright ; I piece only kicks in ARS2 cp a, PIECE_I jr nz, :+ ld a, [wRotModeState] cp a, ROT_MODE_ARSTI jp nz, .norot ldh a, [hWantRotation] bit 0, a jp nz, .checki jr .trykickright ; T/L/J only kick if not through the middle axis. : ld a, c cp a, 1 jp z, .maybetgm3rot cp a, 5 jr z, .maybetgm3rot cp a, 9 jr z, .maybetgm3rot ; A step to the right. .trykickright ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] inc a call BigXYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call BigCanPieceFitFast cp a, $FF jr nz, .trykickleft ldh a, [hCurrentPieceX] inc a ldh [hCurrentPieceX], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; And a step to the left. .trykickleft ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] dec a call BigXYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call BigCanPieceFitFast cp a, $FF jr nz, .maybetgm3rot ldh a, [hCurrentPieceX] dec a ldh [hCurrentPieceX], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; In ARS2 mode, there are a few other kicks possible. .maybetgm3rot ld a, [wRotModeState] cp a, ROT_MODE_ARSTI jp nz, .norot ; In the case of a T piece, try the space above. .checkt ldh a, [hCurrentPiece] cp a, PIECE_T jr nz, .checki ldh a, [hCurrentPieceY] dec a ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call BigCanPieceFitFast cp a, $FF jp nz, .norot ldh a, [hCurrentPieceY] dec a ldh [hCurrentPieceY], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set lock delay forcing to 1 if it's 0. cp a, 0 jr nz, :+ inc a ldh [hLockDelayForce], a jp .norot : cp a, 1 ; Or to 2 if it's 1. jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; In the case of an I piece... .checki ldh a, [hCurrentPiece] cp a, PIECE_I jp nz, .norot ; What direction do we want to end up? ldh a, [hWantRotation] bit 0, a jp z, .tryiright2 ; Flat? Sideways kicks are fine. ; Upright? Only up kicks. ; Are we grounded? Don't kick if we aren't. ldh a, [hActualG] cp a, 0 jp nz, .norot ; Try up once. .tryiup1 ldh a, [hCurrentPieceY] dec a ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call BigCanPieceFitFast cp a, $FF jr nz, .tryiup2 ldh a, [hCurrentPieceY] dec a ldh [hCurrentPieceY], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set lock delay forcing to 1 if it's 0. cp a, 0 jr nz, :+ inc a ldh [hLockDelayForce], a jp .norot : cp a, 1 ; Or to 2 if it's 1. jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; Try up twice. .tryiup2 ldh a, [hCurrentPieceY] dec a dec a ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call BigCanPieceFitFast cp a, $FF jr nz, .norot ldh a, [hCurrentPieceY] dec a dec a ldh [hCurrentPieceY], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call BigSetPieceDataOffset ldh a, [hLockDelayForce] ; Set lock delay forcing to 1 if it's 0. cp a, 0 jr nz, :+ inc a ldh [hLockDelayForce], a jp .norot : cp a, 1 ; Or to 2 if it's 1. jp nz, .norot inc a ldh [hLockDelayForce], a jp .norot ; Try right twice. .tryiright2 ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] inc a inc a call XYToSFieldPtr ld d, h ld e, l ldh a, [hPieceDataBaseFast] ld l, a ldh a, [hPieceDataBaseFast+1] ld h, a ldh a, [hWantRotation] sla a sla a push bc ld c, a xor a, a ld b, a add hl, bc pop bc call BigCanPieceFitFast cp a, $FF jr nz, .norot ldh a, [hCurrentPieceX] inc a inc a ldh [hCurrentPieceX], a ldh a, [hWantRotation] ldh [hCurrentPieceRotationState], a call SetPieceDataOffset ldh a, [hLockDelayForce] ; Set the forced lock delay to 2 if it's 1. cp a, 1 jp nz, .norot inc a ldh [hLockDelayForce], a ; ************************************************************** ; HANDLE MOVEMENT ; Do we want to move left? .norot ldh a, [hLeftState] ; Check if held for 1 frame. If so we move. cp a, 1 jr z, .doleft cp a, 0 ; We never want to move if the button wasn't held. jr z, .wantright ld b, a ldh a, [hCurrentIntegerGravity] cp a, 20 ; No increased DAS at 20G. jr z, .checkdasleft ldh a, [hGrounded] ; If we're grounded, assume some urgency in getting DAS charged, charge at twice the rate. cp a, $FF jr nz, .checkdasleft inc b ld a, b ldh [hLeftState], a .checkdasleft ldh a, [hCurrentDAS] ld c, a ld a, b cp a, c jr c, .wantright .doleft ldh a, [hWantX] dec a ldh [hWantX], a jr .trymove ; Do we want to move right? .wantright ldh a, [hRightState] ; Check if held for 1 frame. If so we move. cp a, 1 jr z, .doright cp a, 0 ; We never want to move if the button wasn't held. jr z, .donemanipulating ld b, a ldh a, [hCurrentIntegerGravity] cp a, 20 ; No increased DAS at 20G. jr z, .checkdasright ldh a, [hGrounded] ; If we're grounded, assume some urgency in getting DAS charged, charge at twice the rate. cp a, $FF jr nz, .checkdasright inc b ld a, b ldh [hRightState], a .checkdasright ldh a, [hCurrentDAS] ld c, a ld a, b cp a, c jr c, .donemanipulating .doright ldh a, [hWantX] inc a ldh [hWantX], a ; Try the movement. .trymove ldh a, [hCurrentPieceY] ld b, a ldh a, [hWantX] call BigXYToSFieldPtr ld d, h ld e, l call BigGetPieceDataFast call BigCanPieceFitFast cp a, $FF jr nz, .donemanipulating ldh a, [hWantX] ldh [hCurrentPieceX], a ; ************************************************************** ; HANDLE MAXIMUM FALL ; This little maneuver is going to cost us 51 years. .skipmovement .donemanipulating : call BigFindMaxG ; ************************************************************** ; HANDLE UP ; Assume 1G or lower. ld a, 1 ldh [hWantedG], a ; Is a hard/sonic drop requested? Skip if in 20G mode. ldh a, [hCurrentIntegerGravity] cp a, 20 jr z, .postdrop ldh a, [hUpState] cp a, 1 jr nz, .postdrop ; What kind, if any? ld a, [wDropModeState] cp a, DROP_MODE_NONE jr z, .postdrop cp a, DROP_MODE_LOCK jr z, .harddrop cp a, DROP_MODE_HARD jr z, .harddrop ; Sonic drop. .sonicdrop ld a, [wDropModeState] cp a, DROP_MODE_SNIC jr z, :+ ld a, $FF ldh [hShouldLockIfGrounded], a : ld a, $FF ldh [hAwardDownBonus], a ld a, 20 ldh [hWantedG], a jr .grav ; Hard drop. .harddrop ld a, $FF ldh [hAwardDownBonus], a ld a, 20 ldh [hWantedG], a ld b, a ldh a, [hActualG] cp a, b jr nc, :+ ld b, a : ldh a, [hCurrentPieceY] add a, b ldh [hCurrentPieceY], a xor a, a ldh [hCurrentLockDelayRemaining], a ld a, SFX_LOCK call SFXTriggerNoise jp .draw ; If we press down, we want to do a soft drop. .postdrop ldh a, [hDownState] cp a, 0 jr z, :+ ldh a, [hDownFrames] inc a ldh [hDownFrames], a ld a, $FF ldh [hGravityCtr], a ld a, [wDropModeState] cp a, DROP_MODE_HARD jr nz, :+ ld a, $FF ldh [hShouldLockIfGrounded], a ; Gravity? : ldh a, [hCurrentFractionalGravity] cp a, $00 ; 0 is the sentinel value that should be interpreted as "every frame" jr z, :+ ld b, a ldh a, [hGravityCtr] add a, b ldh [hGravityCtr], a jr nc, .nograv : ldh a, [hCurrentIntegerGravity] ldh [hWantedG], a ; Can we drop the full requested distance? .grav ldh a, [hWantedG] ld b, a ldh a, [hActualG] cp a, b jr c, .smallg ; Yes. Do it. .bigg ldh a, [hWantedG] ld b, a ldh a, [hCurrentPieceY] add a, b ldh [hCurrentPieceY], a jr .postgrav ; No. Smaller distance. .smallg ldh a, [hActualG] ld b, a ldh a, [hCurrentPieceY] add a, b ldh [hCurrentPieceY], a ; ************************************************************** ; HANDLE LOCKING ; Are we grounded? .postgrav .nograv xor a, a ldh [hGrounded], a ldh a, [hYPosAtStartOfFrame] ld b, a ldh a, [hCurrentPieceY] cp a, b jr z, .noreset ldh a, [hCurrentLockDelay] ldh [hCurrentLockDelayRemaining], a .noreset ldh a, [hCurrentPieceY] inc a ld b, a ldh a, [hCurrentPieceX] call BigXYToSFieldPtr ld d, h ld e, l call BigGetPieceDataFast call BigCanPieceFitFast cp a, $FF jp z, .notgrounded ; We're grounded. .grounded ld a, $FF ldh [hGrounded], a ldh a, [hCurrentPieceY] ld b, a ldh a, [hYPosAtStartOfFrame] cp a, b jr z, .postcheckforfirmdropsound ; Never play the sound if we didn't change rows. ldh a, [hDownState] cp a, 0 jr nz, .postcheckforfirmdropsound ; Don't play the sound if we're holding down. ; Play the firm drop sound, and also reset the lock delay since the piece stepped down. .playfirmdropsound ld a, SFX_LAND call SFXTriggerNoise ; If the down button is held, lock. .postcheckforfirmdropsound ldh a, [hDownState] cp a, 0 jr z, .neutralcheck ; Don't lock on down for hard drop mode immediately. ld a, [wDropModeState] cp a, DROP_MODE_HARD jr nz, :+ ld a, $FF ldh [hShouldLockIfGrounded], a jr .dontforcelock ; Lock on down in modes <20G. : ldh a, [hCurrentIntegerGravity] cp a, 20 jr nz, .forcelock ; In 20G mode, only lock if down has been pressed for exactly 1 frame. ldh a, [hDownState] cp a, 1 jr z, .forcelock jr .dontforcelock ; If the down button is not held, check if we're neutral and if that should lock. .neutralcheck ldh a, [hShouldLockIfGrounded] cp a, 0 jr z, .dontforcelock ; Check for neutral. ldh a, [hUpState] cp a, 0 jr nz, .dontforcelock ldh a, [hLeftState] cp a, 0 jr nz, .dontforcelock ldh a, [hRightState] cp a, 0 jr nz, .dontforcelock ; Lock on neutral for a few modes. ld a, [wDropModeState] cp a, DROP_MODE_FIRM jr z, .forcelock cp a, DROP_MODE_HARD jr z, .forcelock jr .dontforcelock ; Set the lock delay to 0 and save it. .forcelock xor a, a ldh [hCurrentLockDelayRemaining], a jr .dolock ; Load the lock delay. ; Decrement it by one and save it. .dontforcelock ldh a, [hCurrentLockDelayRemaining] dec a ldh [hCurrentLockDelayRemaining], a ; Are we out of lock delay? .checklockdelay cp a, 0 jr nz, .checkfortgm3lockexception ; If not, check if the TGM3 exception applies. jr .dolock ; Otherwise, lock! ; TGM3 sometimes forces a piece to immediately lock. .checkfortgm3lockexception ldh a, [hLockDelayForce] cp a, 2 jr nz, .draw ; It's not forced, so go to drawing. xor a, a ; It is forced, so force it! ldh [hCurrentLockDelayRemaining], a ; Play the locking sound and draw the piece. .dolock ld a, SFX_LOCK call SFXTriggerNoise jr .draw ; If we weren't grounded, reset the lock force. .notgrounded xor a, a ldh [hShouldLockIfGrounded], a ; ************************************************************** ; HANDLE DRAWING ; Draw the piece. .draw ; If the piece is locked, skip the ghost piece. ldh a, [hCurrentLockDelayRemaining] cp a, 0 jr z, .postghost ; If the gravity is <= 1G, draw a ghost piece. ldh a, [hWantedG] cp a, 1 jr nz, .postghost ld a, [wInitialA] ; Let's not do the flickering on the GBC. cp a, $11 jr z, .ghost ldh a, [hEvenFrame] cp a, 1 jr nz, .postghost .ghost ldh a, [hYPosAtStartOfFrame] ld b, a ldh a, [hActualG] add a, b ld b, a ldh a, [hCurrentPieceX] call BigXYToFieldPtr ld d, h ld e, l call BigGetPieceData ld a, TILE_GHOST ld b, a push hl push de pop hl pop de call BigDrawPiece .postghost ; If the lock delay is at the highest value, draw the piece normally. ldh a, [hCurrentPiece] ld b, TILE_PIECE_0 add a, b ldh [hWantedTile], a ldh a, [hCurrentLockDelay] ld b, a ldh a, [hCurrentLockDelayRemaining] cp a, b jr z, .drawpiece ; If the lock delay is 0, draw the piece in the final color. ldh a, [hWantedTile] add a, 7 ldh [hWantedTile], a ldh a, [hCurrentLockDelayRemaining] cp a, 0 jr z, .drawpiece ; If we're not grounded, draw the piece normally. ldh a, [hWantedTile] sub a, 7 ldh [hWantedTile], a ldh a, [hGrounded] cp a, $FF jr nz, .drawpiece ; Otherwise, look it up. call BigGetTileShade .drawpiece ldh a, [hCurrentPieceY] ld b, a ldh a, [hCurrentPieceX] call BigXYToFieldPtr ld d, h ld e, l call BigGetPieceData ldh a, [hWantedTile] ld b, a push hl push de pop hl pop de call BigDrawPiece jp WidenField ; Performs a lookup to see how "locked" the piece is. BigGetTileShade: ldh a, [hCurrentLockDelay] cp a, 30 jr nc, .max30 cp a, 20 jr nc, .max20 cp a, 10 jr nc, .max10 jr .max0 ret .max30 ldh a, [hCurrentLockDelayRemaining] cp a, 4 ret c cp a, 8 jp c, .s6 cp a, 12 jr c, .s5 cp a, 16 jr c, .s4 cp a, 20 jr c, .s3 cp a, 24 jr c, .s2 cp a, 28 jr c, .s1 jr .s0 .max20 ldh a, [hCurrentLockDelayRemaining] cp a, 2 ret c cp a, 5 jr c, .s6 cp a, 7 jr c, .s5 cp a, 10 jr c, .s4 cp a, 12 jr c, .s3 cp a, 15 jr c, .s2 cp a, 17 jr c, .s1 jr .s0 .max10 ldh a, [hCurrentLockDelayRemaining] cp a, 1 ret c cp a, 2 jr c, .s6 cp a, 3 jr c, .s5 cp a, 5 jr c, .s4 cp a, 6 jr c, .s3 cp a, 7 jr c, .s2 cp a, 8 jr c, .s1 jr .s0 .max0 jr .s4 .s0 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0 add a, b ldh [hWantedTile], a ret .s1 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(2*7) add a, b ldh [hWantedTile], a ret .s2 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(3*7) add a, b ldh [hWantedTile], a ret .s3 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(4*7) add a, b ldh [hWantedTile], a ret .s4 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(5*7) add a, b ldh [hWantedTile], a ret .s5 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(6*7) add a, b ldh [hWantedTile], a ret .s6 ldh a, [hCurrentPiece] ld b, TILE_PIECE_0+(7*7) add a, b ldh [hWantedTile], a ret ; This is called every frame after a piece has been locked until the delay state ends. ; Lines are cleared, levels and score are awarded, and ARE time is waited out. BigFieldDelay:: ; Switch on the delay state. ld a, [wDelayState] cp DELAY_STATE_DETERMINE_DELAY jr z, .determine cp DELAY_STATE_LINE_PRE_CLEAR jr z, .prelineclear cp DELAY_STATE_LINE_CLEAR jp z, .lineclear cp DELAY_STATE_PRE_ARE jp z, .preare jp .are ; Check if there were line clears. ; If so, we need to do a line clear delay. ; Otherwise, we skip to ARE delay. .determine ; Increment bravo by 4. ldh a, [hBravo] add a, 4 ldh [hBravo], a ; Are there line clears? call BigToShadowField call BigFindClearedLines ldh a, [hClearedLines] ld b, a ldh a, [hClearedLines+1] ld c, a ldh a, [hClearedLines+2] ld d, a ldh a, [hClearedLines+3] and a, b and a, c and a, d cp a, $FF jr z, .skip ld a, DELAY_STATE_LINE_PRE_CLEAR ; If there were line clears, do a line clear delay, then a LINE_ARE delay. ld [wDelayState], a ldh a, [hCurrentLineClearDelay] ldh [hRemainingDelay], a call BigMarkClear jp .prelineclear .skip ld a, DELAY_STATE_PRE_ARE ; If there were no line clears, do an ARE delay. ld [wDelayState], a ldh a, [hCurrentARE] ldh [hRemainingDelay], a jp .preare ; Pre-line clear delay. ; If we had line clears, immediately hand out the score and the levels. .prelineclear: ld a, DELAY_STATE_LINE_CLEAR ld [wDelayState], a ldh a, [hLineClearCt] cp a, 0 jr z, .lineclear ; If not, just skip the phase. ; There were line clears! Clear the level counter breakpoint. xor a, a ldh [hRequiresLineClear], a ; Decrement bravo by 10 for each line clear. ldh a, [hLineClearCt] ld b, a ldh a, [hBravo] : sub a, 10 dec b jr nz, :- ldh [hBravo], a ; Increment the level counter by the amount of lines. .applylines ldh a, [hLineClearCt] ld e, a call LevelUp ; Score the line clears. ; Get the new level. ldh a, [hLevel] ld l, a ldh a, [hLevel+1] ld h, a ; Divide by 4. srl h rr l srl h rr l ; Add 1. inc hl ; Add soft drop points. ldh a, [hDownFrames] ld c, a xor a, a ld b, a ; Lock bonus? ldh a, [hAwardDownBonus] cp a, $FF jr nz, .premultiplier ld a, 10 add a, c ld c, a ; Final total pre-multipliers. .premultiplier add hl, bc ; Copy the running total for multiplication. ld b, h ld c, l ; Do we have a bravo? x4 if so. .bravo ldh a, [hBravo] cp a, 0 jr nz, .lineclears add hl, bc jr c, .forcemax add hl, bc jr c, .forcemax add hl, bc jr c, .forcemax ld b, h ld c, l ; x line clears .lineclears ldh a, [hLineClearCt] dec a jr z, .combo : add hl, bc jr c, .forcemax dec a jr nz, :- ld b, h ld c, l ; x combo .combo ldh a, [hComboCt] dec a jr z, .applyscore : add hl, bc jr c, .forcemax dec a jr nz, :- jr .applyscore ; Overflow = 65535 .forcemax ld a, $FF ld h, a ld l, a ; And apply the score. .applyscore ld a, l ldh [hScoreIncrement], a ld a, h ldh [hScoreIncrement+1], a call IncreaseScore ; Update the combo counter. ldh a, [hLineClearCt] ld b, a ldh a, [hComboCt] ; Old combo count. add b ; + lines add b ; + lines sub 2 ; - 2 ldh [hComboCt], a ; Line clear delay. ; Count down the delay. If we're out of delay, clear the lines and go to LINE_ARE. .lineclear ldh a, [hRemainingDelay] dec a ldh [hRemainingDelay], a cp a, 0 jp nz, WidenField call BigClearLines ld a, SFX_LINE_CLEAR call SFXTriggerNoise : ldh a, [hCurrentLineARE] ldh [hRemainingDelay], a ; Pre-ARE delay. .preare: ld a, DELAY_STATE_ARE ld [wDelayState], a ; Copy over the newly cleaned field. call BigToShadowField ; Don't do anything if there were line clears ldh a, [hLineClearCt] cp a, 0 jr nz, .are ; Otherwise, reset the combo. ld a, 1 ldh [hComboCt], a ; ARE delay. ; Count down the delay. If it hits 0, award levels and score if necessary, then end the delay phase. .are ldh a, [hRemainingDelay] dec a ldh [hRemainingDelay], a cp a, 0 jp nz, WidenField ; Add one level if we're not at a breakpoint. ldh a, [hRequiresLineClear] cp a, $FF jr z, :+ ld e, 1 call LevelUp ; Cycle the RNG. : ldh a, [hNextPiece] ldh [hCurrentPiece], a call GetNextPiece ; Kill the sound for the next piece. jp SFXKill ; Shifts B into the line clear list. ; Also increments the line clear count. BigAppendClearedLine: ldh a, [hLineClearCt] inc a ldh [hLineClearCt], a ldh a, [hClearedLines+2] ldh [hClearedLines+3], a ldh a, [hClearedLines+1] ldh [hClearedLines+2], a ldh a, [hClearedLines] ldh [hClearedLines+1], a ld a, b ldh [hClearedLines], a ret ; Scans the field for lines that are completely filled with non-empty spaces. ; Every time one is found, it is added to a list. BigFindClearedLines: xor a, a ldh [hLineClearCt], a ld a, $FF ld c, 0 ldh [hClearedLines], a ldh [hClearedLines+1], a ldh [hClearedLines+2], a ldh [hClearedLines+3], a DEF row = 13 REPT 14 ld hl, wShadowField+2+(row*14) ld b, 11 : ld a, [hl+] dec b cp a, $FF jr z, :+ cp a, TILE_FIELD_EMPTY jr nz, :- : xor a, a cp a, b jr nz, .next\@ ld b, 13-row call BigAppendClearedLine inc c ld a, 4 cp a, c ret z DEF row -= 1 .next\@ ENDR ret ; Goes through the list of cleared lines and marks those lines with the "line clear" tile. BigMarkClear: ldh a, [hClearedLines] cp a, $FF ret z ld hl, wField+(14*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 5 ld d, TILE_CLEARING call UnsafeMemSet ldh a, [hClearedLines+1] cp a, $FF ret z ld hl, wField+(14*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 5 ld d, TILE_CLEARING call UnsafeMemSet ldh a, [hClearedLines+2] cp a, $FF ret z ld hl, wField+(14*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 5 ld d, TILE_CLEARING call UnsafeMemSet ldh a, [hClearedLines+3] cp a, $FF ret z ld hl, wField+(14*10) : ld bc, -10 add hl, bc dec a cp a, $FF jr nz, :- ld bc, 5 ld d, TILE_CLEARING jp UnsafeMemSet ; Once again, scans the field for cleared lines, but this time removes them. BigClearLines: ld de, 0 DEF row = 23 REPT 23 ; Check if the row begins with a clearing tile. ld hl, wField+(row*10) ld a, [hl] cp a, TILE_CLEARING ; If it does, increment the clearing counter, but skip this line. jr nz, .clear\@ inc de inc de inc de inc de inc de inc de inc de inc de inc de inc de jr .r\@ .clear\@ ; If there's 0 lines that need to be moved down, skip this line. xor a, a cp a, e jr z, .r\@ ; Otherwise... ld bc, wField+(row*10) add hl, de : ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc ld a, [bc] ld [hl+], a inc bc .r\@ DEF row -= 1 ENDR ; Make sure there's no garbage in the top de lines. .fixgarbo ld hl, wField : xor a, a or a, d or a, e ret z ld a, TILE_FIELD_EMPTY ld [hl+], a ld [hl+], a ld [hl+], a ld [hl+], a ld [hl+], a ld a, 0 ld [hl+], a ld [hl+], a ld [hl+], a ld [hl+], a ld [hl+], a dec de dec de dec de dec de dec de dec de dec de dec de dec de dec de jr :- ret WidenField:: ld de, wField+(4*10) ld hl, wWideField ld bc, 5 call UnsafeMemCopy ld de, wField+(5*10) ld hl, wWideField+5 ld bc, 5 call UnsafeMemCopy ld de, wField+(6*10) ld hl, wWideField+10 ld bc, 5 call UnsafeMemCopy ld de, wField+(7*10) ld hl, wWideField+15 ld bc, 5 call UnsafeMemCopy ld de, wField+(8*10) ld hl, wWideField+20 ld bc, 5 call UnsafeMemCopy ld de, wField+(9*10) ld hl, wWideField+25 ld bc, 5 call UnsafeMemCopy ld de, wField+(10*10) ld hl, wWideField+30 ld bc, 5 call UnsafeMemCopy ld de, wField+(11*10) ld hl, wWideField+35 ld bc, 5 call UnsafeMemCopy ld de, wField+(12*10) ld hl, wWideField+40 ld bc, 5 call UnsafeMemCopy ld de, wField+(13*10) ld hl, wWideField+45 ld bc, 5 call UnsafeMemCopy DEF piece = 0 REPT 50 ld a, [wWideField+piece] ld hl, wWideBlittedField+((piece/5)*20)+((piece%5) * 2) ld [hl+], a ld [hl], a ld hl, wWideBlittedField+((piece/5)*20)+((piece%5) * 2)+10 ld [hl+], a ld [hl], a DEF piece += 1 ENDR ret ENDC