;;==========================================================================;; ;; Joe Zbiciak's Moving Object Test. Real simple test case. ;; ;; Copyright 2002, Joe Zbiciak, im14u2c AT primenet DOT com. ;; ;; http://www.primenet.com/~im14u2c/intv/ ;; ;; This software is licensed under the GNU GPL. See COPYING.txt for info. ;; ;;==========================================================================;; ;* ======================================================================== *; ;* TO BUILD IN BIN+CFG FORMAT: *; ;* as1600 -o mob_test.bin -l mob_test.lst mob_test.asm *; ;* *; ;* TO BUILD IN ROM FORMAT: *; ;* as1600 -o mob_test.rom -l mob_test.lst mob_test.asm *; ;* ======================================================================== *; ROMW 16 ; Use 16-bit ROM ;------------------------------------------------------------------------------ ; Include system information ;------------------------------------------------------------------------------ INCLUDE "../library/gimini.asm" ;------------------------------------------------------------------------------ ; Global constants and configuration. ;------------------------------------------------------------------------------ GROM EQU $3000 ; GROM base address GRAM EQU $3800 ; GRAM base address TSKQM EQU $7 ; Task queue is 8 entries large MAXTSK EQU 4 ; Right now allow 4 active tasks COLSTK EQU STIC.mode VBLANK EQU STIC.viden CS0 EQU STIC.cs0 CS1 EQU STIC.cs1 CS2 EQU STIC.cs2 CS3 EQU STIC.cs3 CB EQU STIC.bord ;------------------------------------------------------------------------------ ; Allocate 8-bit variables in Scratch RAM ;------------------------------------------------------------------------------ SCRATCH ORG $100, $100, "-RWBN" ISRVEC RMB 2 ; Always at $100 / $101 ; Task-oriented 8-bit variables TSKQHD RMB 1 ; Task queue head TSKQTL RMB 1 ; Task queue tail TSKDQ RMB 2*(TSKQM+1) ; Task data queue WTIMER RMB 1 ; Wait timer OVRFLO RMB 1 ; Number of overflows observed TSKACT RMB 1 ; Number of active tasks ; Hand-controller 8-bit variables SH_TMP RMB 1 ; Temp storage. SH_LR0 RMB 3 ;\ SH_FL0 EQU SH_LR0 + 1 ; |-- Three bytes for left controller SH_LV0 EQU SH_LR0 + 2 ;/ SH_LR1 RMB 3 ;\ SH_FL1 EQU SH_LR1 + 1 ; |-- Three bytes for right controller SH_LV1 EQU SH_LR1 + 2 ;/ ; Demo-specific variables CURMOB RMB 1 ; Currently selected MOB HDLYSH RMB 1 ; Horizontal delay (shadowed) VDLYSH RMB 1 ; Vertical delay (shadowed) DOCLR RMB 1 ; Flag: Clear collision bits? _SCRATCH EQU $ ; end of scratch area ;------------------------------------------------------------------------------ ; Allocate 16-bit variables in System RAM ;------------------------------------------------------------------------------ SYSTEM ORG $2F0, $2F0, "-RWBN" STACK RMB 32 ; Reserve 32 words for the stack ; Task-oriented 16-bit variables TSKQ RMB (TSKQM + 1) ; Task queue TSKTBL RMB (MAXTSK * 4) ; Timer task table ; Hand-controller 16-bit variables SHDISP RMB 1 ; ScanHand dispatch ; STIC shadow STICSH RMB 24 ; Room for X, Y, and A regs only. _SYSTEM EQU $ ; end of system area ;------------------------------------------------------------------------------ ; EXEC-friendly ROM header. ;------------------------------------------------------------------------------ ORG $5000 ; Use default memory map ROMHDR: BIDECLE ZERO ; MOB picture base (points to NULL list) BIDECLE ZERO ; Process table (points to NULL list) BIDECLE START ; Program start address BIDECLE ZERO ; Bkgnd picture base (points to NULL list) BIDECLE ONES ; GRAM pictures (points to NULL list) BIDECLE TITLE ; Cartridge title/date DECLE $03C0 ; No ECS title, run code after title, ; ... no clicks ZERO: DECLE $0000 ; Screen border control DECLE $0000 ; 0 = color stack, 1 = f/b mode DECLE C_BLK, C_BLK ; Initial color stack 0 and 1: Black DECLE C_BLK, C_BLK ; Initial color stack 2 and 3: Black DECLE C_BLK ; Initial border color: Black ONES: DECLE $1, $0 ;------------------------------------------------------------------------------ ;; ======================================================================== ;; ;; TITLE / START ;; ;; ;; ;; This contains the title string and the startup code. We pre-empt the ;; ;; EXEC's initialization sequence by setting the "Special Copyright" bit ;; ;; in location $500C. This causes the code at 'START' to run before the ;; ;; built-in title screen is completely displayed. ;; ;; ;; ;; The Startup code does very little. Mainly, it sets the Interrupt ;; ;; Service Routine vector to point to our _real_ initialization routine, ;; ;; INIT. This is done because we can only get to GRAM and STIC registers ;; ;; during the vertical retrace, and vertical retrace is signaled by an ;; ;; interrupt. (Actually, we can have access to GRAM/STIC for longer ;; ;; if we don't hit the STIC 'handshake' at location $20, but then the ;; ;; display blanks. During INIT, the display does blank briefly.) ;; ;; ======================================================================== ;; TITLE: BYTE 100, "MOB Test", 0 ; ; Intercept/preempt EXEC initialization and just do our own. ; We call no EXEC routines in this program. START: CLRR R4 ; Zero all system RAM, PSG0,& STIC. MVII #$20, R1 ; $00...$1F. (The STIC) JSRD R5, FILLZERO ADDI #8, R4 ; $28...$32. (The rest of the STIC) MVII #11, R1 CALL FILLZERO MVII #$F0, R4 ; $F0...$35D. We spare the rand seed values MVII #$26D, R1 ; in $35E..$35F to add some randomness. CALL FILLZERO MVII #INIT, R0 ; Our initialization routine MVII #ISRVEC, R4 ; ISR vector MVO@ R0, R4 ; Write low half SWAP R0 ; MVO@ R0, R4 ; Write high half MOVR PC, R5 ; Loop starting at the next instruction. @@spin: EIS ; This falls through to STUB which causes ; our loop (saves a couple DECLEs.) ;; ======================================================================== ;; ;; STUB ;; ;; Null routine used in dispatchers where no behavior is defined/desired. ;; ;; ======================================================================== ;; STUB: JR R5 ; Stub routine ;; ======================================================================== ;; ;; INIT ;; ;; Initializes the ISR, etc. Gets everything ready to run. ;; ;; This is called via the ISR dispatcher, so it's safe to bang GRAM from ;; ;; here, too. ;; ;; ;; ;; -- Zero out memory to get started ;; ;; -- Set up variables that need to be set up here and there ;; ;; -- Set up GRAM image ;; ;; -- Drop into the main state-machine ;; ;; ======================================================================== ;; INIT: PROC DIS MVII #$2F0, R6 ; Reset the stack pointer ; Stub out all of the task hooks MVII #MY_ISR,R0 ; Point ISR vector to our ISR MVO R0, ISRVEC ; store low half of ISR vector SWAP R0 ; MVO R0, ISRVEC+1 ; store high half of ISR vector ; Default the GRAM image to be same as GROM. MVII #GROM, R5 ; Point R5 at GROM MVII #GRAM, R4 ; Point R4 at GRAM MVII #$200, R0 @@gromcopy: MVI@ R5, R1 MVO@ R1, R4 DECR R0 BNEQ @@gromcopy ; Copy our GRAM font into GRAM overtop of default ; ; Font data is broken up into spans of characters that are copied ; into GRAM. Each span is defined as follows. ; ; Span Header: 2 Decles ; DECLE Skip Length (in bytes of GRAM memory) ; DECLE Span Length (in bytes of GRAM memory) ; Span Data -- up to Span Length Decles. ; ; Span Data is run-length encoded using the upper two bits of the ; decle to specify the run length. Valid run lengths are 0..3, ; with 0 meaning "just copy this byte to the GRAM", and 3 meaning ; "copy this byte to GRAM and make three more copies in the locations ; afterwards". To see what I mean, look at the font data in ; "font.asm". ; ; The run length encoding does not change the value used for ; 'span length'. The span length is always given in terms of ; # of GRAM locations, and not number of decles in the FONT data. ; ; The font is terminated with a span of length 0. CALL LOADFONT DECLE FONT ; Ok, everything's ready to roll now. EIS ;; ================================================================ ;; ;; Lets do it! ;; ;; ================================================================ ;; CALL MOBTEST ; Set up object test's tasks. CALL RUNQ ; Let all the tasks run. DECR PC ; Should never get here... ENDP ;; ======================================================================== ;; ;; LOADFONT -- Loads our set of pictures into GRAM ;; ;; ======================================================================== ;; LOADFONT PROC MVI@ R5, R0 PSHR R5 MOVR R0, R5 MVII #GRAM, R4 ; Point R4 at GRAM @@gramloop: MVI@ R5, R0 ; Get skip & span len. (in GRAM bytes) TSTR R0 ; Quit if skip/span == 0. BEQ @@gramdone MOVR R0, R1 ANDI #$7F8, R0 ; Extract span length. XORR R0, R1 ; Clear away span bits from word SWAP R1 ; Extrack skip value. ADDR R1, R4 ; Skip our output pointer. SLR R0, 1 ; Divide count by 2. @@charloop: MVI@ R5, R1 ; Get two bytes MVO@ R1, R4 ; Put the first byte SWAP R1 ; Put the other byte into position MVO@ R1, R4 ; Put the second byte DECR R0 ; Sheesh, do I have to spell this out? BNEQ @@charloop ; inner loop B @@gramloop ; outer loop @@gramdone: PULR PC ENDP ;; ======================================================================== ;; ;; MOBTEST ;; ;; This sets up the main MOBTEST screen and all the event handlers. Then ;; ;; it sits back and lets it all happen. ;; ;; ======================================================================== ;; MOBTEST PROC PSHR R5 CALL CLRSCR ; Clear the display ;; Display the MOB-test screen. ;; It's pretty ugly, but who cares? CALL PRINT.FLS DECLE $007, $200 ;01234567890123456789 DECLE "[ Joe's 'MOB' Test ]", 0 ;; Start a MARQUEE task for the title string (cheesy, I know) MVII #2 + 256*16, R2 ; Length 16, Offset 2 CALL STARTTASK DECLE 0 ; Task #0 DECLE MARQUEE ; MARQUEE task DECLE 20, 20 ; Period: every 10 ticks CALL STARTTASK DECLE 2 ; Task #2 DECLE SHOWMOBS ; SHOWMOBS task DECLE 8, 8 ; Period: every 4 ticks MVII #3, R0 ; Enable 3 tasks. Task 1 is key rpt MVO R0, TSKACT ;; Set our hand controller dispatcher MVII #MOBHAND, R0 MVO R0, SHDISP ;; Clear our STIC shadow MVII #$20, R1 ; Zero out the STIC shadow MVII #STICSH,R4 CALL FILLZERO ;; Set our initial MOB state up by writing to the STIC shadow MVII #$3800, R0 ; PRIO=1, FG bit3 = 1, GRAM = 1 MVII #STICSH+$10, R4 ; Point to shadow copy of A regs. MVII #8, R1 ; All 8 MOBs @@ml0: MVO@ R0, R4 ;\ INCR R0 ; |__ Set the 'A' register for all DECR R1 ; | 8 MOBs such that PRIO=1, bit3 BNEQ @@ml0 ;/ of FG=1 and GRAM=1. MVII #8, R1 ; 8 MOBs MVII #STICSH+$00, R4 ; Point R4 to shadow copy of X regs MVII #STICSH+$08, R5 ; Point R5 to shadow copy of Y regs MVII #$300 + 76, R2 ; Set VISB + INTR and center onscreen MVII #20, R3 ; Middle of third row of cards @@ml1: MVO@ R2, R4 ;\ INCR R2 ; | Line up all 8 MOBs in a thin MVO@ R3, R5 ; |-- line in middle of 3rd row. DECR R1 ; | Set VISB=1 and INTR=1 on each. BNEQ @@ml1 ;/ ;; Show initial MOB state CALL SHOWMOBS ; Show updated MOB status. CLRR R2 MVO R2, DOCLR ; don't clear collision info by default INCR R2 CALL PICK ; Select MOB 0 PULR PC ENDP ;; ======================================================================== ;; ;; MY_ISR -- Shadows the STIC registers in 16-bit RAM. ;; ;; ;; ;; This routine is called from an interrupt context. It makes a ;; ;; "shadow" copy of the STIC registers from RAM to the STIC. It also ;; ;; reads out a copy of the MOB collision registers and places their ;; ;; values in the shadow copy. This allows our main program to access ;; ;; a copy of the STIC registers at any time, not just during vertical ;; ;; retrace. ;; ;; ======================================================================== ;; MY_ISR PROC PSHR R5 ;; Force color-stack mode, enable display MVI COLSTK, R0 MVO R0, VBLANK ;; Poke in the hdly/vdly shadow amounts MVI HDLYSH, R0 MVO R0, $30 MVI VDLYSH, R0 MVO R0, $31 MVI VDLYSH, R0 MVO R0, $22 ;; Set up color stack, bgcolor: CLRR R0 MVO R0, CS0 ; CS0 == Black MVO R0, CS2 ; CS2 == Black INCR R0 MVO R0, CS1 ; CS1 == Blue (for selection bar) MVII #9, R0 MVO R0, CB ; Border == Cyan MVI CS3, R0 INCR R0 MVO R0, CS3 ; CS3 == prev_CS3 + 1 ;; Point to RAM mirror and to STIC MVII #STICSH,R4 CLRR R5 ;; First, copy MOB parameters from RAM to STIC ($00..$17) MVII #$18, R1 @@l1: MVI@ R4, R0 ; Read from RAM MVO@ R0, R5 ; Write to STIC DECR R1 BNEQ @@l1 ;; Next, copy MOB interactions from STIC to RAM ;; If DOCLR is set, write zeros back to collision registers MVII #$8, R1 MVI DOCLR, R0 SARC R0, 1 BNC @@l3 @@l2: MVI@ R5, R0 ; Read from STIC DECR R5 MVO@ R0, R4 ; Write to RAM CLRR R0 MVO@ R0, R5 ; Write to STIC DECR R1 BNEQ @@l2 B @@leave @@l3: MVI@ R5, R0 ; Read from STIC MVO@ R0, R4 ; Write to RAM DECR R1 BNEQ @@l3 ;; Lastly, return via DOTIMER to update timer-based tasks @@leave PULR R5 B DOTIMER ENDP ;; ======================================================================== ;; ;; MOBHAND ;; ;; Table of keypad dispatches ;; ;; ======================================================================== ;; MOBHAND PROC DECLE HIT_KEYPAD ; Process keypad DECLE HIT_ACTION ; Process action-keys DECLE HIT_DISC ; Process DISC inputs ENDP ;; ======================================================================== ;; ;; HIT_KEYPAD -- handle keypad dispatching. ;; ;; ======================================================================== ;; HIT_KEYPAD PROC ANDI #$FF, R2 ; Ignore controller number CMPI #$01, R2 ; BLT INCCARD ; key == 0 ==> Increment card # CMPI #$09, R2 ; BLT PICK ; 1 <= key < 9 ==> Pick Object BEQ INCHDLY ; key == 9 ==> Incr. horiz delay CMPI #$0B, R2 ; BLT INCVDLY ; key == 10 ==> Incr. vert delay BEQ TOG_DOCLR ; key == 11 ==> Toggle do-clear. ; JR R5 ; key > 11 (release event?) ==> Return. ENDP ;; ======================================================================== ;; ;; HIT_ACTION -- handle action-key dispatching ;; ;; ======================================================================== ;; HIT_ACTION PROC ANDI #$FF, R2 ; Ignore controller number DECR R2 ; BEQ TOG_VIS ; Top: Toggle VISB bit for MOB DECR R2 ; BEQ TOG_PRI ; Lower-left: Toggle PRIO bit for MOB DECR R2 ; BEQ TOG_INT ; Lower-right: Togglie INTR bit for MOB JR R5 ; Key-release: Ignore ENDP ;; ======================================================================== ;; ;; HIT_DISC -- handle disc dispatching. ;; ;; This also handles the "repeating" nature of the DISC. ;; ;; ======================================================================== ;; HIT_DISC PROC ANDI #$FF, R2 ; Ignore controller number CMPI #$80, R2 ; \__ shut off keyrepeat on release BGE @@release ; / ADDI #2, R2 ; \__ Rotate by 2 to make decoding easier ANDI #$F, R2 ; / MVII #MOVE.d,R3 ; 10, 11, 12, 13 ==> Move down CMPI #4, R2 ; BGE @@not_r ; MVII #MOVE.r,R3 ; 14, 15, 0, 1 ==> Move right B @@got_it @@not_r CMPI #8, R2 ; BGE @@not_u ; MVII #MOVE.u,R3 ; 2, 3, 4, 5 ==> Move up B @@got_it @@not_u CMPI #12, R2 ; BGE @@got_it ; MVII #MOVE.l,R3 ; 6, 7, 8, 9 ==> Move left @@got_it: PSHR R5 MOVR R3, R2 CALL STARTTASK ; Set up key-repeating. DECLE 1 ; Task #1 DECLE @@repeat ; KEYREPEAT task DECLE 30, 4 ; First repeat 250ms, rest @ 30Hz PULR R5 @@repeat: JR R2 ; Jump to the movement routine. @@release: MVII #1, R3 B STOPTASK ENDP ;; ======================================================================== ;; ;; PICK -- Pick a MOB to make "current" ;; ;; ======================================================================== ;; PICK PROC ;; Remember the newly selected MOB DECR R2 MVO R2, CURMOB ;; Update the highlight bar. We do this by stepping through all 8 ;; rows, de-highlighting the rows that aren't current, and ;; highlighting the one row that IS current. MVII #$200 + 40, R4 CLRR R0 @@l: CLRR R1 CMPR R0, R2 ; Is this the row? BNEQ @@not ; No: De-highlight it MVII #$2000, R1 ; Yes: Highlight it by advancing color-stack @@not: MVO@ R1, R4 ; Set/clear colorstack bit at left edge ADDI #18, R4 ; MVO@ R1, R4 ; Set/clear colorstack bit at right edge INCR R0 ;\ CMPI #8, R0 ; |-- Have we done all 8 yet? BLT @@l ;/ JR R5 ENDP ;; ======================================================================== ;; ;; MOVE -- Move a MOB. ;; ;; This just adds or subtracts 1 from either the X or Y coord. depending ;; ;; on the direction pressed on the DISC. ;; ;; ======================================================================== ;; MOVE PROC @@u: CLRR R0 MVII #$FFFF, R1 B @@move @@d: CLRR R0 MVII #1, R1 B @@move @@l: MVII #$FFFF, R0 CLRR R1 B @@move @@r: MVII #1, R0 CLRR R1 @@move: ;; When we get to this point, R0 has our X offset, and ;; R1 has our Y offset. MVI CURMOB, R2 ; Get our current MOB # ADDI #STICSH,R2 ; R2 points to X coord MVII #8, R3 ADDR R2, R3 ; R3 points to Y coord ADD@ R2, R0 ; Add X offset to X coordinate MVI@ R2, R4 ; Get original X register value ANDI #$00FF, R0 ; Keep only X coord part of updated X reg. ANDI #$FF00, R4 ; Keep the non-coord parts of original X reg. ADDR R4, R0 ; Merge the two halves together MVO@ R0, R2 ; Store out the updated X register. ADD@ R3, R1 ; Add Y offset to Y coordinate MVI@ R3, R4 ; Get original Y register value ANDI #$007F, R1 ; Keep only Y coord part of update Y reg. ANDI #$FF80, R4 ; Keep non-coord parts of original Y reg. ADDR R4, R1 ; Merge the two halves together MVO@ R1, R3 ; Store out the updated Y register PSHR R5 ; \ CALL RATELIMIT ; |__ Don't let this puppy move too fast. DECLE 1 ; | PULR PC ; / ENDP ;; ======================================================================== ;; ;; TOG_DOCLR -- Toggle the "clear all collisions" mode ;; ;; ======================================================================== ;; TOG_DOCLR PROC MVI DOCLR, R0 XORI #1, R0 MVO R0, DOCLR JR R5 ENDP ;; ======================================================================== ;; ;; TOG_VIS -- Toggle visibility for a MOB ;; ;; ======================================================================== ;; TOG_VIS PROC MVI CURMOB, R2 ADDI #STICSH,R2 MVII #$0200, R1 XOR@ R2, R1 MVO@ R1, R2 MVI CURMOB, R0 B SHOWMOB ENDP ;; ======================================================================== ;; ;; TOG_INT -- Toggle interaction bit for a MOB ;; ;; ======================================================================== ;; TOG_INT PROC MVI CURMOB, R2 ADDI #STICSH,R2 MVII #$0100, R1 XOR@ R2, R1 MVO@ R1, R2 MVI CURMOB, R0 B SHOWMOB ENDP ;; ======================================================================== ;; ;; TOG_PRI -- Toggle priority for a MOB ;; ;; ======================================================================== ;; TOG_PRI PROC MVI CURMOB, R2 ADDI #STICSH + $10,R2 MVII #$2000, R1 XOR@ R2, R1 MVO@ R1, R2 MVI CURMOB, R0 B SHOWMOB ENDP ;; ======================================================================== ;; ;; INCHDLY -- Increase horizontal delay ;; ;; ======================================================================== ;; INCHDLY PROC MVI HDLYSH, R0 INCR R0 MVO R0, HDLYSH MVI CURMOB, R0 B SHOWMOB ENDP ;; ======================================================================== ;; ;; INCVDLY -- Increase vertical delay ;; ;; ======================================================================== ;; INCVDLY PROC MVI VDLYSH, R0 INCR R0 MVO R0, VDLYSH MVI CURMOB, R0 B SHOWMOB ENDP ;; ======================================================================== ;; ;; INCCARD -- Set the card for a MOB. ;; ;; ======================================================================== ;; INCCARD PROC MVI CURMOB, R3 ADDI #STICSH + $10,R3 MVI@ R3, R2 ADDI #8, R2 ANDI #$38, R2 MVII #$FE07, R1 AND@ R3, R1 ADDR R2, R1 MVO@ R1, R3 JR R5 ENDP ;; ======================================================================== ;; ;; SHOWMOB -- Show MOB info for MOB # given in R0. ;; ;; ======================================================================== ;; SHOWMOB PROC PSHR R5 PSHR R4 PSHR R3 NOP ; needed to prevent display glitch PSHR R2 PSHR R1 PSHR R0 ;; Move to row "MOB# + 2" MOVR R0, R1 SLL R1, 2 ADDR R0, R1 SLL R1, 2 ; R1 = R0 * 5. MVII #$200+41, R4 ADDR R1, R4 ; R4 = ptr to row "MOB# + 2", col #1 ;; Get STIC Shadow ptr MVII #STICSH, R5 ADDR R0, R5 ;; Now display the X/Y/A/C registers MVII #7, R1 MVI@ R5, R0 PSHR R5 CALL HEX12 PULR R5 INCR R4 ADDI #7, R5 MVI@ R5, R0 PSHR R5 CALL HEX12 PULR R5 INCR R4 ADDI #7, R5 MVI@ R5, R0 PSHR R5 CALL HEX16 PULR R5 INCR R4 ADDI #7, R5 MVI@ R5, R0 CALL HEX16 PULR R0 PULR R1 PULR R2 PULR R3 PULR R4 PULR PC ENDP ;; ======================================================================== ;; ;; SQUARES -- Colored square "string". ;; ;; ======================================================================== ;; SQUARES PROC @@sqr EQU 01000000000000b ; Selects 'colored square mode' @@cs_pix0_0 EQU 00000000000000b ; ColSqr Pixel 0, color == 0 @@cs_pix0_1 EQU 00000000000001b ; ColSqr Pixel 0, color == 1 @@cs_pix0_2 EQU 00000000000010b ; ColSqr Pixel 0, color == 2 @@cs_pix0_3 EQU 00000000000011b ; ColSqr Pixel 0, color == 3 @@cs_pix0_4 EQU 00000000000100b ; ColSqr Pixel 0, color == 4 @@cs_pix0_5 EQU 00000000000101b ; ColSqr Pixel 0, color == 5 @@cs_pix0_6 EQU 00000000000110b ; ColSqr Pixel 0, color == 6 @@cs_pix0_7 EQU 00000000000111b ; ColSqr Pixel 0, color == 7 @@cs_pix1_0 EQU 00000000000000b ; ColSqr Pixel 1, color == 0 @@cs_pix1_1 EQU 00000000001000b ; ColSqr Pixel 1, color == 1 @@cs_pix1_2 EQU 00000000010000b ; ColSqr Pixel 1, color == 2 @@cs_pix1_3 EQU 00000000011000b ; ColSqr Pixel 1, color == 3 @@cs_pix1_4 EQU 00000000100000b ; ColSqr Pixel 1, color == 4 @@cs_pix1_5 EQU 00000000101000b ; ColSqr Pixel 1, color == 5 @@cs_pix1_6 EQU 00000000110000b ; ColSqr Pixel 1, color == 6 @@cs_pix1_7 EQU 00000000111000b ; ColSqr Pixel 1, color == 7 @@cs_pix2_0 EQU 00000000000000b ; ColSqr Pixel 2, color == 0 @@cs_pix2_1 EQU 00000001000000b ; ColSqr Pixel 2, color == 1 @@cs_pix2_2 EQU 00000010000000b ; ColSqr Pixel 2, color == 2 @@cs_pix2_3 EQU 00000011000000b ; ColSqr Pixel 2, color == 3 @@cs_pix2_4 EQU 00000100000000b ; ColSqr Pixel 2, color == 4 @@cs_pix2_5 EQU 00000101000000b ; ColSqr Pixel 2, color == 5 @@cs_pix2_6 EQU 00000110000000b ; ColSqr Pixel 2, color == 6 @@cs_pix2_7 EQU 00000111000000b ; ColSqr Pixel 2, color == 7 @@cs_pix3_0 EQU 00000000000000b ; ColSqr Pixel 3, color == 0 @@cs_pix3_1 EQU 00001000000000b ; ColSqr Pixel 3, color == 1 @@cs_pix3_2 EQU 00010000000000b ; ColSqr Pixel 3, color == 2 @@cs_pix3_3 EQU 00011000000000b ; ColSqr Pixel 3, color == 3 @@cs_pix3_4 EQU 10000000000000b ; ColSqr Pixel 3, color == 4 @@cs_pix3_5 EQU 10001000000000b ; ColSqr Pixel 3, color == 5 @@cs_pix3_6 EQU 10010000000000b ; ColSqr Pixel 3, color == 6 @@cs_pix3_7 EQU 10011000000000b ; ColSqr Pixel 3, color == 7 DECLE $2000 DECLE @@cs_pix0_0 + @@cs_pix1_0 + @@cs_pix2_1 + @@cs_pix3_1 + @@sqr DECLE @@cs_pix0_2 + @@cs_pix1_2 + @@cs_pix2_3 + @@cs_pix3_3 + @@sqr DECLE @@cs_pix0_4 + @@cs_pix1_4 + @@cs_pix2_5 + @@cs_pix3_5 + @@sqr DECLE @@cs_pix0_6 + @@cs_pix1_6 + @@cs_pix2_7 + @@cs_pix3_7 + @@sqr DECLE 0, $2000 ENDP ;; ======================================================================== ;; ;; SHOWMOBS -- Show info for all 8 MOBs, as well as our clear-toggle mode. ;; ;; ======================================================================== ;; SHOWMOBS PROC PSHR R5 CLRR R0 @@l: CALL SHOWMOB INCR R0 CMPI #8, R0 BLT @@l MVII #$200 + 10*20 + 7, R4 MVII #7, R1 MVII #SQUARES, R5 @@l2: MVI@ R5, R0 MVO@ R0, R4 DECR R1 BNEQ @@l2 CALL PRINT.FLS DECLE $003, $200 + 20*11 + 5 DECLE "Clear: ", 0 MVI DOCLR, R0 SARC R0, 1 BNC @@off CALL PRINT.FLS DECLE $006, $200 + 20*11 + 12 DECLE "ON!", 0 PULR PC @@off: CALL PRINT.FLS DECLE $003, $200 + 20*11 + 12 DECLE "Off", 0 PULR PC ENDP ;; ======================================================================== ;; ;; FONT data ;; ;; ======================================================================== ;; FONT: PROC ;; Skipped 0 indices. ;; Encoding span of 8 entries DECLE $0040 DECLE $0000 ;........ ; - - - ;........ DECLE $0000 ;........ ; - - - ;........ DECLE $0000 ;........ ; - - - ;........ DECLE $0100 ;........ ; - - - ;.......# DECLE $FFFF ;######## ; - - - ;######## DECLE $FFFF ;######## ; - - - ;######## DECLE $FFFF ;######## ; - - - ;######## DECLE $FFFF ;######## ; - - - ;######## DECLE $F0F0 ;####.... ; - - - ;####.... DECLE $F0F0 ;####.... ; - - - ;####.... DECLE $0000 ;........ ; - - - ;........ DECLE $0000 ;........ ; - - - ;........ DECLE $0F0F ;....#### ; - - - ;....#### DECLE $0F0F ;....#### ; - - - ;....#### DECLE $0000 ;........ ; - - - ;........ DECLE $0000 ;........ ; - - - ;........ DECLE $0000 ;........ ; - - - ;........ DECLE $0000 ;........ ; - - - ;........ DECLE $0F0F ;....#### ; - - - ;....#### DECLE $0F0F ;....#### ; - - - ;....#### DECLE $0000 ;........ ; - - - ;........ DECLE $0000 ;........ ; - - - ;........ DECLE $F0F0 ;####.... ; - - - ;####.... DECLE $F0F0 ;####.... ; - - - ;####.... DECLE $55AA ;#.#.#.#. ; - - - ;.#.#.#.# DECLE $55AA ;#.#.#.#. ; - - - ;.#.#.#.# DECLE $55AA ;#.#.#.#. ; - - - ;.#.#.#.# DECLE $55AA ;#.#.#.#. ; - - - ;.#.#.#.# DECLE $AA55 ;.#.#.#.# ; - - - ;#.#.#.#. DECLE $AA55 ;.#.#.#.# ; - - - ;#.#.#.#. DECLE $AA55 ;.#.#.#.# ; - - - ;#.#.#.#. DECLE $AA55 ;.#.#.#.# ; - - - ;#.#.#.#. ;; End of font. DECLE $0000 ;; Total chars: 4 characters ;; Total length: 18 decles ;; Decles/char: 4.500 decles/character ENDP ;; ======================================================================== ;; ;; MARQUEE ;; ;; Cycles colors on a string of text. ;; ;; ;; ;; INPUTS: ;; ;; R2 -- Task instance data: ;; ;; Low byte of instance data gives screen offset. ;; ;; High byte of instance data gives length. ;; ;; ======================================================================== ;; MARQUEE PROC MOVR R2, R3 ANDI #$FF, R3 ; R3 == screen offset. XORR R3, R2 SWAP R2 ; R2 == length. ADDI #$200, R3 ; Convert screen offset into actual address. MVI@ R3, R0 ; Get first display word from string. MVII #$7, R1 ; Color mask for three LSBs. ANDR R1, R0 ; Get color from leading character in string. COMR R1 ; Invert our mask, so we can replace colors. @@loop: DECR R0 ; Cycle color by decrementing BNEQ @@ok ; Make sure it didn't go to zero! MVII #$7, R0 ; If it did, set it back to 7. @@ok: MVI@ R3, R4 ; Get a character from the display. ANDR R1, R4 ; Mask away its color bits. ADDR R0, R4 ; Replace them with our new color bits. MVO@ R4, R3 ; Write the modified character to the display. INCR R3 ; Move to next character. DECR R2 ; Loop until done. BNEQ @@loop JR R5 ; Return. ENDP ;; ======================================================================== ;; ;; LIBRARY INCLUDES ;; ;; ======================================================================== ;; INCLUDE "../library/hexdisp.asm" ; for HEX16, HEX12 INCLUDE "../library/print.asm" ; for PRINT.xxx INCLUDE "../library/fillmem.asm" ; for FILLZERO, FILLMEM, CLRSCR INCLUDE "../task/scanhand.asm" ; SCANHAND (include before taskq!) INCLUDE "../task/timer.asm" ; timer-based tasks INCLUDE "../task/taskq.asm" ; task RUNQ ;* ======================================================================== *; ;* 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 2 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, write to the Free Software *; ;* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. *; ;* ======================================================================== *; ;* Copyright (c) 2002, Joseph Zbiciak *; ;* ======================================================================== *;