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procpfl.s@ c65a0e2

Last change on this file since c65a0e2 was c65a0e2, checked in by Thomas Lopatic <thomas@…>, 7 years ago
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Rev	Line
[c65a0e2]	1	* ------------------------------------------------------------------------------
	2	* procpfl.s -- process pendant functions (sustain release processing)
	3	* Version 8 -- 1988-08-31 -- D.N. Lynx Crowe
	4	* ------------------------------------------------------------------------------
	5	.text
	6	*
	7	.xdef _procpfl
	8	*
	9	.xdef _curpf_f * current function (v/p)
	10	.xdef _curpf_l * current pflist entry
	11	.xdef _curpf_t * current trigger
	12	*
	13	.xref _irand
	14	.xref _xgetran
	15	*
	16	.xref _expbit
	17	.xref _funcndx
	18	.xref _pflist
	19	.xref _pfqhdr
	20	.xref _prstab
	21	.xref _ptoftab
	22	.xref _timemlt
	23	.xref _trgtab
	24	.xref _valents
	25	.xref _vce2grp
	26	.xref _vce2trg
	27	.xref _veltab
	28	*
	29	.page
	30	* ------------------------------------------------------------------------------
	31	* Register usage
	32	* --------------
	33	* d0 scratch
	34	* d1 FPU function index
	35	* d2 point index from FH_CPT (idfcpt)
	36	* d3 scratch
	37	* d4 jump point number from PT_PAR1 (ippar1)
	38	* d5 scratch
	39	*
	40	* a0 scratch
	41	* a1 function header base
	42	* a2 point table base
	43	* a3 FPU base
	44	*
	45	* ------------------------------------------------------------------------------
	46	* FPU definitions
	47	* ---------------
	48	*
	49	UPD_BIT .equ $0001 * update bit (1 = update)
	50	INT_BIT .equ $0002 * int. bit (0 = disable)
	51	RAT_BIT .equ $0004 * ratio bit (0 = ratio)
	52	*
	53	VSUBNBIT .equ 3 * new value select bit number
	54	VAL_BITS .equ $0018 * new value select bit mask
	55	*
	56	MSK_RNVB .equ $000C * new value / ratio bits
	57	MSK_ONVB .equ $0010 * old new value bit
	58	*
	59	FKILL .equ $0014 * kill value for function
	60	FSEND .equ $0015 * send new value to function
	61	*
	62	CLREXP .equ $8000 * clear value for time exponent
	63	CLRMNT .equ $8000 * clear value for time mantissa
	64	*
	65	* ------------------------------------------------------------------------------
	66	* Miscellaneous definitions
	67	* -------------------------
	68	*
	69	PCHMAX .equ 21920 * maximum pitch value
	70	VALMAX .equ 32000 * maximum value to send to FPU
	71	VALMIN .equ -32000 * minimum value to send to FPU
	72	*
	73	LSPCH .equ 2 * left shift for sources to freq
	74	*
	75	VALLEN .equ 10 * length of the 'valent' struct
	76	VT_VAL .equ 8 * value offset in 'valent'
	77	*
	78	.page
	79	* ------------------------------------------------------------------------------
	80	* FPU addresses
	81	* -------------
	82	*
	83	FPUBASE .equ $180000 * FPU base address
	84	*
	85	FPUWST .equ FPUBASE * FPU waveshape base
	86	FPUFUNC .equ FPUBASE+$4000 * FPU function base
	87	FPUINT1 .equ FPUBASE+$4000 * FPU int. input address (R/O)
	88	FPUINT2 .equ FPUBASE+$6000 * FPU int. reset address (W/O)
	89	FPUCFG .equ FPUBASE+$5FE0 * FPU config. data address (W/O)
	90	*
	91	F_CTL .equ $00 * control word
	92	F_VAL10 .equ $02 * new value "10"
	93	F_CV1 .equ $08 * control voltage 1
	94	F_SF1 .equ $0A * scale factor 1
	95	F_CV2 .equ $0C * control voltage 2
	96	F_SF2 .equ $0E * scale factor 2
	97	F_CV3 .equ $10 * control voltage 3
	98	F_SF3 .equ $12 * scale factor 3
	99	F_MNT .equ $14 * time mantissa
	100	F_EXP .equ $16 * time exponent
	101	F_VAL01 .equ $1C * new value "01"
	102	*
	103	P_FREQ1 .equ $0020 * frequency 1
	104	P_FREQ2 .equ $0060 * frequency 2
	105	P_FREQ3 .equ $00A0 * frequency 3
	106	P_FREQ4 .equ $00E0 * frequency 4
	107	P_FILTER .equ $0140 * filter
	108	P_FILTRQ .equ $00C0 * filter q
	109	*
	110	P_INDEX1 .equ $0120 * index 1
	111	P_INDEX2 .equ $0160 * index 2
	112	P_INDEX3 .equ $0180 * index 3
	113	P_INDEX4 .equ $01A0 * index 4
	114	P_INDEX5 .equ $01C0 * index 5
	115	P_INDEX6 .equ $01E0 * index 6
	116	*
	117	P_LEVEL .equ $0040 * level
	118	*
	119	P_LOCN .equ $0080 * location
	120	P_DYNAM .equ $0100 * dynamics
	121	*
	122	.page
	123	* ------------------------------------------------------------------------------
	124	* Structure definitions
	125	* ------------------------------------------------------------------------------
	126	* The following MUST match the idfnhdr structure definition in instdsp.h:
	127	*
	128	FH_LEN .equ 12 * length of the idfnhdr structure
	129	*
	130	FH_PCH .equ 0 * WORD - pitch offset
	131	FH_MLT .equ 2 * WORD - overall value multiplier
	132	FH_SRC .equ 4 * BYTE - overall value source
	133	FH_PIF .equ 5 * BYTE - # of points in the function
	134	FH_PT1 .equ 6 * BYTE - index of first point
	135	FH_TMD .equ 7 * BYTE - trigger mode / control bits
	136	FH_CPT .equ 8 * BYTE - current point
	137	FH_PRM .equ 9 * BYTE - misc. function parameter
	138	FH_TRG .equ 10 * WORD - trigger
	139	*
	140	I_ACTIVE .equ 1 * 'Active' bit number (in FH_TMD)
	141	*
	142	MSK_CTL .equ $001C * mask for FPU hardware bits (in FH_TMD)
	143	*
	144	* ------------------------------------------------------------------------------
	145	* The following MUST match the instpnt structure definition in instdsp.h:
	146	*
	147	PT_LEN .equ 12 * length of the instpnt structure
	148	*
	149	PT_TIM .equ 0 * WORD - time (packed)
	150	PT_VAL .equ 2 * WORD - value
	151	PT_VMLT .equ 4 * WORD - value multiplier
	152	PT_VSRC .equ 6 * BYTE - value source
	153	PT_ACT .equ 7 * BYTE - action
	154	PT_PAR1 .equ 8 * BYTE - parameter 1
	155	PT_PAR2 .equ 9 * BYTE - parameter 2
	156	PT_PAR3 .equ 10 * BYTE - parameter 3
	157	PT_PAD .equ 11 * BYTE - padding for even boundary
	158	*
	159	MSK_MNT .equ $FFF0 * mask for mantissa (in PT_TIM)
	160	MSK_EXP .equ $000F * mask for exponent (in PT_TIM)
	161	*
	162	MAX_ACT .equ 7 * maximum action code value
	163	*
	164	* ------------------------------------------------------------------------------
	165	* Source definitions -- must match those in 'smdefs.h'
	166	*
	167	SM_RAND .equ 1 * random
	168	SM_PTCH .equ 5 * pitch
	169	SM_KPRS .equ 6 * key pressure
	170	SM_KVEL .equ 7 * key velocity
	171	SM_FREQ .equ 10 * frequency
	172	*
	173	.page
	174	*
	175	* Layout of pflist entries 32 bytes each
	176	* ------------------------
	177	PF_NEXT .equ 0 * LONG - next entry pointer
	178	PF_TRIG .equ 4 * WORD - trigger number
	179	PF_FUNC .equ 6 * WORD - fpuifnc value
	180	PF_D1 .equ 8 * LONG - d1
	181	PF_D2 .equ 12 * LONG - d2
	182	PF_D4 .equ 16 * LONG - d4
	183	PF_A1 .equ 20 * LONG - a1
	184	PF_A2 .equ 24 * LONG - a2
	185	PF_A3 .equ 28 * LONG - a3
	186	*
	187	* Parameter offset
	188	* ----------------
	189	TRIG .equ 8 * WORD - trigger number
	190	*
	191	* Register equates
	192	* ----------------
	193	RCUR .equ a4 * current pflist entry pointer
	194	RPRV .equ a5 * previous pflist entry pointer
	195	*
	196	.page
	197	* ------------------------------------------------------------------------------
	198	* _procpfl() -- process pendant functions
	199	*
	200	* void
	201	* procpfl(trig);
	202	* unsigned trig;
	203	*
	204	* Processes pendant (sustained) functions by restarting them
	205	* when the trigger (trig) that's sustaining them is released.
	206	* Invoked by key release processing in msm() and localkb().
	207	*
	208	* ------------------------------------------------------------------------------
	209	*
	210	_procpfl: nop * FOR DEBUGGING PATCH
	211	*
	212	link a6,#0 * allocate stack frame
	213	movem.l d3-d7/a3-a5,-(a7) * preserve registers we use
	214	*
	215	move.w sr,d7 * save interrupt state
	216	move.w #$2200,sr * turn off FPU interrupts
	217	*
	218	move.w TRIG(a6),d6 * get trigger we're processing
	219	move.w d6,_curpf_t * ...
	220	movea.l #_pflist,RPRV * point at 'previous' pflist entry
	221	bra pfscan * go scan the chain
	222	*
	223	pfpass: movea.l RCUR,RPRV * point at previous entry
	224	*
	225	pfscan: move.l (RPRV),d5 * get next pflist entry pointer
	226	beq pfexit * done if no more
	227	*
	228	movea.l d5,RCUR * point at current entry
	229	move.l d5,_curpf_l * ...
	230	*
	231	cmp.w PF_TRIG(RCUR),d6 * see if this entry is wanted
	232	bne pfpass * jump if not
	233	*
	234	movem.l PF_D1(RCUR),d1-d2/d4/a1-a3 * restore processing state
	235	move.w PF_FUNC(RCUR),_curpf_f * ...
	236	*
	237	btst #I_ACTIVE,FH_TMD(a1) * see if function is active
	238	bne doact * continue function if so
	239	*
	240	bra stopfn * stop function if not
	241	*
	242	pfnext: move.l (RCUR),(RPRV) * remove entry from pflist
	243	move.l _pfqhdr,(RCUR) * chain entry to free list
	244	move.l RCUR,_pfqhdr * ...
	245	bra pfscan * go look at next entry
	246	*
	247	pfexit: move.w d7,sr * restore interrupt level
	248	movem.l (a7)+,d3-d7/a3-a5 * restore the registers we used
	249	unlk a6 * deallocate stack frame
	250	rts * return to caller
	251	*
	252	.page
	253	*
	254	* ------------------------------------------------------------------------------
	255	* stop a function
	256	* ------------------------------------------------------------------------------
	257	stopfn: move.b FH_TMD(a1),d0 * get function control bits
	258	andi.w #MSK_RNVB,d0 * mask for ratio / new new-value bit
	259	move.w d0,d3 * isolate new new-value bit
	260	add.w d3,d3 * ... from function header
	261	andi.w #MSK_ONVB,d3 * ... shift to old new-value bit
	262	or.w d3,d0 * ... and put new bit in old bit
	263	move.w d0,F_CTL(a3,d1.W) * stop the function
	264	bclr #I_ACTIVE,FH_TMD(a1) * reset the active bit
	265	bra pfnext * go restore registers and exit
	266	*
	267	* ------------------------------------------------------------------------------
	268	* setup for and dispatch to the proper action handler
	269	* ------------------------------------------------------------------------------
	270	doact: clr.w d2 * get current point index in d2
	271	move.b FH_CPT(a1),d2 * ...
	272	lsl.w #2,d2 * multiply it by the length of a point
	273	move.w d2,d0 * ... (fast multiply by PT_LEN = 12
	274	add.w d2,d2 * ... via shift and add)
	275	add.w d0,d2 * ...
	276	clr.w d4 * get jump point # into d4
	277	move.b PT_PAR1(a2,d2.W),d4 * ...
	278	clr.w d3 * get action code in d3
	279	move.b PT_ACT(a2,d2.W),d3 * ...
	280	cmpi.b #MAX_ACT,d3 * check against the limit
	281	bgt stopfn * stop things if it's a bad action code
	282	*
	283	lsl.w #2,d3 * develop index to action dispatch table
	284	lea actab,a0 * get the address of the action handler
	285	movea.l 0(a0,d3.W),a0 * ...
	286	*
	287	* ------------------------------------------------------------------------------
	288	* At this point we're ready to do the action associated with the point,
	289	* and the registers are set up, and will remain, as follows:
	290	*
	291	* d1 FPU function index a1 function header base
	292	* d2 point table index a2 point table base
	293	* a3 FPU function base
	294	* d4 jump point number
	295	*
	296	* d0, d3, d5, and a0 are used as scratch throughout the code.
	297	*
	298	* ------------------------------------------------------------------------------
	299	*
	300	jmp (a0) * dispatch to action handler
	301	*
	302	.page
	303	* ------------------------------------------------------------------------------
	304	* act0 -- AC_NULL -- no action
	305	* ---- --------------------
	306	act0: move.b FH_PT1(a1),d0 * get first point number
	307	add.b FH_PIF(a1),d0 * add number of points in function
	308	subq.b #1,d0 * make it last point number
	309	cmp.b FH_CPT(a1),d0 * see if we're at the last point
	310	beq stopfn * stop function if so
	311	*
	312	addq.b #1,FH_CPT(a1) * update function header for next point
	313	addi.w #PT_LEN,d2 * advance the point index
	314	*
	315	* ------------------------------------------------------------------------------
	316	* outseg -- output a segment
	317	* ------ ----------------
	318	outseg: move.w PT_TIM(a2,d2.w),d3 * get packed time
	319	move.w d3,d0 * extract mantissa
	320	andi.w #MSK_MNT,d0 * ...
	321	mulu _timemlt,d0 * multiply by panel time pot value
	322	lsr.l #8,d0 * ... and scale it
	323	lsr.l #7,d0 * ...
	324	move.w d0,F_MNT(a3,d1.W) * send mantissa to FPU
	325	andi.w #MSK_EXP,d3 * extract exponent code
	326	add.w d3,d3 * look up decoded exponent
	327	lea _expbit,a0 * ... in expbit
	328	move.w 0(a0,d3.W),F_EXP(a3,d1.W) * send exponent to FPU
	329	move.w PT_VAL(a2,d2.W),d3 * get the function value
	330	*
	331	.page
	332	* ------------------------------------------------------------------------------
	333	* get the point source, if any
	334	* ------------------------------------------------------------------------------
	335	tst.w PT_VMLT(a2,d2.W) * see if we have a point mlt.
	336	beq nosrc * don't do anything for zero
	337	*
	338	clr.w d0 * get the source number
	339	move.b PT_VSRC(a2,d2.W),d0 * ...
	340	beq nosrc * don't do anything for zero
	341	*
	342	* ------------------------------------------------------------------------------
	343	* SM_RAND -- random
	344	* ------------------------------------------------------------------------------
	345	cmpi.w #SM_RAND,d0 * is this the random source ?
	346	bne srctyp0 * jump if not
	347	*
	348	movem.l d1-d2/a0-a2,-(a7) * preserve registers around call
	349	move.w PT_VMLT(a2,d2.W),-(a7) * pass multiplier to xgetran()
	350	jsr _xgetran * call for a random number
	351	tst.w (a7)+ * clean up stack
	352	movem.l (a7)+,d1-d2/a0-a2 * restore registers
	353	move.w d0,d5 * put random value in the value register
	354	bra applym * go apply the multiplier
	355	*
	356	.page
	357	* ------------------------------------------------------------------------------
	358	* SM_FREQ -- frequency
	359	* ------------------------------------------------------------------------------
	360	srctyp0: cmpi.w #SM_FREQ,d0 * is this the frequency source ?
	361	bne srctyp1 * jump if not
	362	*
	363	move.w (a1),d0 * get the pitch
	364	lsr.w #6,d0 * shift to a word index
	365	andi.w #$01FE,d0 * mask out extraneous bits
	366	lea _ptoftab,a0 * get entry from ptoftab[]
	367	move.w 0(a0,d0.W),d5 * ...
	368	bra applym * go apply the multiplier
	369	*
	370	* ------------------------------------------------------------------------------
	371	* SM_PTCH -- pitch
	372	* ------------------------------------------------------------------------------
	373	srctyp1: cmpi.w #SM_PTCH,d0 * is this the pitch source ?
	374	bne srctyp2 * jump if not
	375	*
	376	move.w (a1),d5 * get the pitch as the value
	377	bra applym * go apply the multiplier
	378	*
	379	* ------------------------------------------------------------------------------
	380	* SM_KVEL -- velocity
	381	* ------------------------------------------------------------------------------
	382	srctyp2: cmpi.w #SM_KVEL,d0 * is this the key velocity source ?
	383	bne srctyp3 * jump if not
	384	*
	385	move.w FH_TRG(a1),d0 * get the trigger number
	386	add.w d0,d0 * ... as a word index
	387	lea _veltab,a0 * ... into veltab[]
	388	move.w 0(a0,d0.W),d5 * get the velocity from veltab[trg]
	389	bra applym * go apply the multiplier
	390	*
	391	* ------------------------------------------------------------------------------
	392	* SM_KPRS -- pressure
	393	* ------------------------------------------------------------------------------
	394	srctyp3: cmpi.w #SM_KPRS,d0 * is this the key pressure source ?
	395	bne srctyp4 * jump if not (must be an analog input)
	396	*
	397	move.w FH_TRG(a1),d0 * get the trigger number
	398	add.w d0,d0 * ... as a word index
	399	lea _prstab,a0 * ... into prstab[]
	400	move.w 0(a0,d0.W),d5 * get the pressure from prstab[trg]
	401	bra applym * go apply the multiplier
	402	*
	403	.page
	404	* ------------------------------------------------------------------------------
	405	* all other sources come out of the valents[] array
	406	* ------------------------------------------------------------------------------
	407	srctyp4: lea _vce2grp,a0 * point at vce2grp[]
	408	move.w _curpf_f,d5 * get voice number in d5
	409	lsr.w #3,d5 * ...
	410	andi.w #$001E,d5 * ... as a word index
	411	move.w 0(a0,d5.W),d5 * get the group number
	412	subq.w #1,d5 * ...
	413	lsl.w #4,d5 * shift it left a nybble
	414	or.w d5,d0 * OR it into the source number
	415	add.w d0,d0 * make source number a valents[] index
	416	move.w d0,d5 * ... (fast multiply by VALLEN = 10
	417	lsl.w #2,d0 * ... via shift and add)
	418	add.w d5,d0 * ...
	419	lea _valents,a0 * get base of valents[]
	420	move.w VT_VAL(a0,d0.W),d5 * get value
	421	*
	422	* ------------------------------------------------------------------------------
	423	* apply the multiplier to the source, and add it to the function value
	424	* ------------------------------------------------------------------------------
	425	applym: muls PT_VMLT(a2,d2.W),d5 * apply the multiplier
	426	asr.l #7,d5 * scale the result
	427	asr.l #8,d5 * ...
	428	ext.l d3 * add the function value
	429	add.l d3,d5 * ...
	430	cmpi.l #VALMAX,d5 * check for overflow
	431	ble srcmlt1 * jump if no overflow
	432	*
	433	move.l #VALMAX,d5 * limit at VALMAX
	434	bra srcmlt2 * ...
	435	*
	436	srcmlt1: cmpi.l #VALMIN,d5 * check for underflow
	437	bge srcmlt2 * jump if no underflow
	438	*
	439	move.l #VALMIN,d5 * limit at VALMIN
	440	*
	441	srcmlt2: move.w d5,d3 * setup value for output to FPU
	442	*
	443	.page
	444	* ------------------------------------------------------------------------------
	445	* adjust the value according to the function type
	446	* ------------------------------------------------------------------------------
	447	nosrc: move.w d1,d0 * get function type
	448	andi.w #$01E0,d0 * ...
	449	*
	450	* ------------------------------------------------------------------------------
	451	* level or location
	452	* ------------------------------------------------------------------------------
	453	cmpi.w #P_LEVEL,d0 * see if it's the level
	454	beq outsegl * jump if so
	455	*
	456	cmpi.w #P_LOCN,d0 * see if it's the location
	457	bne outsegf * jump if not
	458	*
	459	tst.w d3 * check sign of value
	460	bpl outsegc * jump if positive
	461	*
	462	clr.w d3 * force negative values to 0
	463	*
	464	outsegc: asr.w #5,d3 * shift value to LS bits
	465	sub.w #500,d3 * subtract 5.00 from value
	466	asl.w #6,d3 * readjust to MS bits
	467	bra outseg3 * go output the value
	468	*
	469	outsegl: tst.w d3 * check sign of value
	470	bpl outsegm * jump if positive
	471	*
	472	clr.w d3 * limit negative values at 0
	473	*
	474	outsegm: asr.w #5,d3 * shift value to LS bits
	475	sub.w #500,d3 * subtract 5.00 from value
	476	asl.w #6,d3 * readjust to MS bits
	477	bra outseg3 * go output the value
	478	*
	479	.page
	480	* ------------------------------------------------------------------------------
	481	* filter
	482	* ------------------------------------------------------------------------------
	483	outsegf: cmpi.w #P_FILTER,d0 * see if it's the filter
	484	bne outsegp * jump if not
	485	*
	486	ext.l d3 * make function value a long
	487	asr.l #1,d3 * multiply function value by .75
	488	move.l d3,d0 * ... (fast multiply by .75
	489	asr.l #1,d0 * ... via shift and add)
	490	add.l d0,d3 * ...
	491	move.w (a1),d0 * add pitch
	492	ext.l d0 * ...
	493	add.l d0,d3 * ...
	494	cmpi.l #VALMAX,d3 * see if it's within limits
	495	ble outsega * ...
	496	*
	497	move.w #VALMAX,d3 * limit at VALMAX
	498	bra outseg3 * ...
	499	*
	500	outsega: cmpi.l #VALMIN,d3 * ...
	501	bge outseg3 * ...
	502	*
	503	move.w #VALMIN,d3 * limit at VALMIN
	504	bra outseg3 * ...
	505	*
	506	.page
	507	* ------------------------------------------------------------------------------
	508	* freq 1..4
	509	* ------------------------------------------------------------------------------
	510	outsegp: cmpi.w #P_FREQ1,d0 * see if it's freq1
	511	beq outseg0 * go process freq1
	512	*
	513	outsegq: cmpi.w #P_FREQ2,d0 * see if it's freq2
	514	beq outseg0 * process it if so
	515	*
	516	cmpi.w #P_FREQ3,d0 * see if it's freq3
	517	beq outseg0 * process it if so
	518	*
	519	cmpi.w #P_FREQ4,d0 * see if it's freq4
	520	bne outseg3 * jump if not
	521	*
	522	outseg0: ext.l d3 * scale the point value to cents offset
	523	asr.l #5,d3 * ...
	524	sub.l #500,d3 * ... value - 500
	525	asl.l #LSPCH,d3 * mult. by 2 and scale for 1/2 cent lsb
	526	move.w (a1),d0 * add pitch from function header
	527	ext.l d0 * ...
	528	add.l d0,d3 * ...
	529	cmp.l #PCHMAX,d3 * see if result is valid
	530	ble outseg3 * jump if within pitch limits
	531	*
	532	move.l #PCHMAX,d3 * limit at maximum pitch
	533	*
	534	* ------------------------------------------------------------------------------
	535	* send the value to the FPU
	536	* ------------------------------------------------------------------------------
	537	outseg3: move.b FH_TMD(a1),d0 * get hardware bits from function header
	538	eor.w #VAL_BITS,d0 * toggle new value select bits
	539	move.b d0,FH_TMD(a1) * store updated word
	540	btst.l #VSUBNBIT,d0 * check which value address to use
	541	beq outseg1
	542	*
	543	move.w d3,F_VAL01(a3,d1.W) * send value to FPU
	544	bra outseg2
	545	*
	546	outseg1: move.w d3,F_VAL10(a3,d1.W) * send value to FPU
	547	*
	548	outseg2: andi.w #MSK_CTL,d0 * mask off software bits
	549	ori.w #UPD_BIT+INT_BIT,d0 * set the update & !lastseg bits
	550	move.w d0,F_CTL(a3,d1.W) * send control word to FPU
	551	bra pfnext * done -- exit
	552	*
	553	.page
	554	*
	555	* ------------------------------------------------------------------------------
	556	* act2 -- AC_ENBL -- stop if key is up
	557	* ---- ----------------------------
	558	act2: move.w _curpf_f,d0 * get voice as a word index
	559	lsr.w #3,d0 * ...
	560	andi.w #$001E,d0 * ...
	561	lea _vce2trg,a0 * check to see if voice is free
	562	move.w 0(a0,d0.W),d0 * ...
	563	cmpi.w #-1,d0 * ...
	564	beq stopfn * if so, stop the function
	565	*
	566	btst #15,d0 * see if voice is held
	567	bne act0 * continue if so
	568	*
	569	btst #14,d0 * ...
	570	bne act0 * ...
	571	*
	572	lea _trgtab,a0 * check trigger table entry
	573	tst.b 0(a0,d0.W) * ...
	574	bne act0 * if trigger is active, continue
	575	*
	576	bra stopfn * if not, stop the function
	577	*
	578	* ------------------------------------------------------------------------------
	579	* act3 -- AC_JUMP -- unconditional jump
	580	* ---- -----------------------------
	581	act3: cmp.b FH_PIF(a1),d4 * check jump point against limit
	582	bcc stopfn * stop function if jump point invalid
	583	*
	584	clr.w d2 * get index of first point
	585	move.b FH_PT1(a1),d2 * ...
	586	add.b d4,d2 * add jump point
	587	move.b d2,FH_CPT(a1) * make it the current point
	588	lsl.w #2,d2 * develop new point index in d2
	589	move.w d2,d0 * ... (fast multiply by PT_LEN = 12
	590	add.w d2,d2 * ... via shift and add)
	591	add.w d0,d2 * ...
	592	bra outseg * output the segment
	593	*
	594	.page
	595	*
	596	* ------------------------------------------------------------------------------
	597	* act4 -- AC_LOOP -- jump to point PT_PAR1 PT_PAR2 times
	598	* ---- ----------------------------------------------
	599	act4: tst.b PT_PAR3(a2,d2.W) * check counter
	600	bne act4a * jump if it's running
	601	*
	602	move.b PT_PAR2(a2,d2.W),d0 * get parameter
	603	subi.w #90,d0 * put parameter in random range
	604	bmi act4b * treat as normal if < 90
	605	*
	606	movem.l d1-d2/a0-a2,-(a7) * get ranged random number
	607	move.w d0,-(a7) * ...
	608	jsr _irand * ...
	609	tst.w (a7)+ * ...
	610	movem.l (a7)+,d1-d2/a0-a2 * ...
	611	move.b d0,PT_PAR3(a2,d2.w) * set counter
	612	beq act0 * next segment if cntr set to 0
	613	*
	614	bra act3 * else jump to the point
	615	*
	616	act4b: move.b PT_PAR2(a2,d2.W),PT_PAR3(a2,d2.W) * set counter
	617	beq act0 * next segment if cntr set to 0
	618	*
	619	bra act3 * else jump to the point
	620	*
	621	act4a: subq.b #1,PT_PAR3(a2,d2.W) * decrement counter
	622	beq act0 * next segment if cntr ran out
	623	*
	624	bra act3 * jump if it's still non-zero
	625	*
	626	* ------------------------------------------------------------------------------
	627	* act5 -- AC_KYUP -- jump if key is up
	628	* ---- ----------------------------
	629	act5: move.w _curpf_f,d0 * get voice as a word index
	630	lsr.w #3,d0 * ...
	631	andi.w #$001E,d0 * ...
	632	lea _vce2trg,a0 * check to see if voice is free
	633	move.w 0(a0,d0.W),d0 * ...
	634	cmpi.w #-1,d0 * ...
	635	beq act3 * if so (inactive), do the jump
	636	*
	637	btst #15,d0 * see if voice is held
	638	bne act0 * continue if so
	639	*
	640	btst #14,d0 * ...
	641	bne act0 * ...
	642	*
	643	lea _trgtab,a0 * check trigger table entry
	644	tst.b 0(a0,d0.W) * see if the trigger is active
	645	beq act3 * if not, do the jump
	646	*
	647	bra act0 * if so, do next segment
	648	*
	649	.page
	650	*
	651	* ------------------------------------------------------------------------------
	652	* act6 -- AC_KYDN -- jump if key is down
	653	* ---- ------------------------------
	654	act6: move.w _curpf_f,d0 * get voice as a word index
	655	lsr.w #3,d0 * ...
	656	andi.w #$001E,d0 * ...
	657	lea _vce2trg,a0 * check to see if voice is free
	658	move.w 0(a0,d0.W),d0 * ...
	659	cmpi.w #-1,d0 * ...
	660	beq act0 * if so (inactive), continue
	661	*
	662	btst #15,d0 * see if voice is held
	663	bne act3 * do jump if so
	664	*
	665	btst #14,d0 * ...
	666	bne act3 * ...
	667	*
	668	lea _trgtab,a0 * check trigger table entry
	669	tst.b 0(a0,d0.W) * see if the trigger is active
	670	bne act3 * if so, do the jump
	671	*
	672	bra act0 * if not, do next segment
	673	*
	674	* ------------------------------------------------------------------------------
	675	act7: bra act0 * AC_HERE: treat act7 as AC_NULL
	676	*
	677	.page
	678	*
	679	* act1 -- AC_SUST -- pause if key is down (sustain)
	680	* ---- -----------------------------------------
	681	act1: move.w _curpf_f,d0 * get voice as a word index
	682	lsr.w #3,d0 * ...
	683	andi.w #$001E,d0 * ...
	684	lea _vce2trg,a0 * point at voice to trigger table
	685	move.w 0(a0,d0.W),d0 * get trigger table entry
	686	cmpi.w #-1,d0 * see if voice is free
	687	beq act0 * treat as no-op if so
	688	*
	689	btst #15,d0 * see if voice is held by a pedal
	690	bne act1a * sustain if so
	691	*
	692	btst #14,d0 * see if voice is sustained by a pedal
	693	bne act1a * sustain if so
	694	*
	695	lea _trgtab,a0 * point at trigger table
	696	tst.b 0(a0,d0.W) * check trigger status
	697	beq act0 * continue if not active
	698	*
	699	act1a: move.l _pfqhdr,d3 * see if any pflist entries remain
	700	beq act0 * no-op if not (shouldn't happen ...)
	701	*
	702	move.b FH_PT1(a1),d0 * get first point number
	703	add.b FH_PIF(a1),d0 * add base to first point
	704	subq.b #1,d0 * make d0 last point number
	705	cmp.b FH_CPT(a1),d0 * check current point number
	706	beq stopfn * done if this is the last point
	707	*
	708	addq.b #1,FH_CPT(a1) * update current point number
	709	addi.w #PT_LEN,d2 * update point index
	710	movea.l d3,a0 * acquire a new pflist entry
	711	move.l (a0),_pfqhdr * ...
	712	move.l _pflist,(a0) * ...
	713	move.l a0,_pflist * ...
	714	move.w FH_TRG(a1),PF_TRIG(a0) * set trigger number in entry
	715	move.w _curpf_f,PF_FUNC(a0) * set v/p word in entry
	716	movem.l d1-d2/d4/a1-a3,PF_D1(a0) * set registers in entry
	717	move.b FH_TMD(a1),d0 * stop the function
	718	andi.w #MSK_RNVB,d0 * ...
	719	move.w d0,d3 * ...
	720	add.w d3,d3 * ...
	721	andi.w #MSK_ONVB,d3 * ...
	722	or.w d3,d0 * ...
	723	move.w d0,F_CTL(a3,d1.W) * ...
	724	bra pfnext * go do next list entry
	725	*
	726	.page
	727	* ------------------------------------------------------------------------------
	728	.data
	729	* ------------------------------------------------------------------------------
	730	*
	731	* actab -- action code dispatch table
	732	* ----- --------------------------
	733	actab: dc.l act0 * 0 - AC_NULL: no action
	734	dc.l act1 * 1 - AC_SUST: sustain
	735	dc.l act2 * 2 - AC_ENBL: enable
	736	dc.l act3 * 3 - AC_JUMP: unconditional jump
	737	dc.l act4 * 4 - AC_LOOP: jump n times (loop)
	738	dc.l act5 * 5 - AC_KYUP: jump if key up (enable jump)
	739	dc.l act6 * 6 - AC_KYDN: jump if key down (sustain jump)
	740	dc.l act7 * 7 - AC_HERE: here on key up
	741	*
	742	* ------------------------------------------------------------------------------
	743	.bss
	744	* ------------------------------------------------------------------------------
	745	*
	746	* ----------------- local variables --------------------------------------------
	747	*
	748	_curpf_f: ds.w 1 * interrupting voice & parameter from FPU
	749	*
	750	* ----------------- debug variables --------------------------------------------
	751	*
	752	_curpf_t: ds.w 1 * current trigger
	753	*
	754	_curpf_l: ds.l 1 * current pflist entry
	755	*
	756	* ------------------------------------------------------------------------------
	757	*
	758	.end

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