| blob | 3d11d6219cdd56da07191fa8d2154285019ac4e5 |
1 // SPDX-License-Identifier: GPL-2.0
2 /*
3 * 6522 Versatile Interface Adapter (VIA)
4 *
5 * There are two of these on the Mac II. Some IRQs are vectored
6 * via them as are assorted bits and bobs - eg RTC, ADB.
7 *
8 * CSA: Motorola seems to have removed documentation on the 6522 from
9 * their web site; try
10 * http://nerini.drf.com/vectrex/other/text/chips/6522/
11 * http://www.zymurgy.net/classic/vic20/vicdet1.htm
12 * and
13 * http://193.23.168.87/mikro_laborversuche/via_iobaustein/via6522_1.html
14 * for info. A full-text web search on 6522 AND VIA will probably also
15 * net some usefulness. <cananian@alumni.princeton.edu> 20apr1999
16 *
17 * Additional data is here (the SY6522 was used in the Mac II etc):
18 * http://www.6502.org/documents/datasheets/synertek/synertek_sy6522.pdf
19 * http://www.6502.org/documents/datasheets/synertek/synertek_sy6522_programming_reference.pdf
20 *
21 * PRAM/RTC access algorithms are from the NetBSD RTC toolkit version 1.08b
22 * by Erik Vogan and adapted to Linux by Joshua M. Thompson (funaho@jurai.org)
23 *
24 */
26 #include <linux/clocksource.h>
27 #include <linux/types.h>
28 #include <linux/kernel.h>
29 #include <linux/mm.h>
30 #include <linux/delay.h>
31 #include <linux/init.h>
32 #include <linux/module.h>
33 #include <linux/irq.h>
35 #include <asm/macintosh.h>
36 #include <asm/macints.h>
37 #include <asm/mac_via.h>
38 #include <asm/mac_psc.h>
39 #include <asm/mac_oss.h>
47 /*
48 * Globals for accessing the VIA chip registers without having to
49 * check if we're hitting a real VIA or an RBV. Normally you could
50 * just hit the combined register (ie, vIER|rIER) but that seems to
51 * break on AV Macs...probably because they actually decode more than
52 * eight address bits. Why can't Apple engineers at least be
53 * _consistently_ lazy? - 1999-05-21 (jmt)
54 */
58 /*
59 * On Macs with a genuine VIA chip there is no way to mask an individual slot
60 * interrupt. This limitation also seems to apply to VIA clone logic cores in
61 * Quadra-like ASICs. (RBV and OSS machines don't have this limitation.)
62 *
63 * We used to fake it by configuring the relevant VIA pin as an output
64 * (to mask the interrupt) or input (to unmask). That scheme did not work on
65 * (at least) the Quadra 700. A NuBus card's /NMRQ signal is an open-collector
66 * circuit (see Designing Cards and Drivers for Macintosh II and Macintosh SE,
67 * p. 10-11 etc) but VIA outputs are not (see datasheet).
68 *
69 * Driving these outputs high must cause the VIA to source current and the
70 * card to sink current when it asserts /NMRQ. Current will flow but the pin
71 * voltage is uncertain and so the /NMRQ condition may still cause a transition
72 * at the VIA2 CA1 input (which explains the lost interrupts). A side effect
73 * is that a disabled slot IRQ can never be tested as pending or not.
74 *
75 * Driving these outputs low doesn't work either. All the slot /NMRQ lines are
76 * (active low) OR'd together to generate the CA1 (aka "SLOTS") interrupt (see
77 * The Guide To Macintosh Family Hardware, 2nd edition p. 167). If we drive a
78 * disabled /NMRQ line low, the falling edge immediately triggers a CA1
79 * interrupt and all slot interrupts after that will generate no transition
80 * and therefore no interrupt, even after being re-enabled.
81 *
82 * So we make the VIA port A I/O lines inputs and use nubus_disabled to keep
83 * track of their states. When any slot IRQ becomes disabled we mask the CA1
84 * umbrella interrupt. Only when all slot IRQs become enabled do we unmask
85 * the CA1 interrupt. It must remain enabled even when cards have no interrupt
86 * handler registered. Drivers must therefore disable a slot interrupt at the
87 * device before they call free_irq (like shared and autovector interrupts).
88 *
89 * There is also a related problem when MacOS is used to boot Linux. A network
90 * card brought up by a MacOS driver may raise an interrupt while Linux boots.
91 * This can be fatal since it can't be handled until the right driver loads
92 * (if such a driver exists at all). Apparently related to this hardware
93 * limitation, "Designing Cards and Drivers", p. 9-8, says that a slot
94 * interrupt with no driver would crash MacOS (the book was written before
95 * the appearance of Macs with RBV or OSS).
96 */
103 /*
104 * Initialize the VIAs
105 *
106 * First we figure out where they actually _are_ as well as what type of
107 * VIA we have for VIA2 (it could be a real VIA or an RBV or even an OSS.)
108 * Then we pretty much clear them out and disable all IRQ sources.
109 */
112 {
122 /* IIci, IIsi, IIvx, IIvi (P6xx), LC series */
131 /* on most RBVs (& unlike the VIAs), you */
132 /* need to set bit 7 when you write to IFR */
133 /* in order for your clear to occur. */
135 }
142 /* Quadra and early MacIIs agree on the VIA locations */
158 }
159 }
161 #ifdef DEBUG_VIA
163 #endif
165 /*
166 * Shut down all IRQ sources, reset the timers, and
167 * kill the timer latch on VIA1.
168 */
179 /*
180 * SE/30: disable video IRQ
181 */
186 }
192 /*
193 * Set the RTC bits to a known state: all lines to outputs and
194 * RTC disabled (yes that's 0 to enable and 1 to disable).
195 */
199 }
201 /* Everything below this point is VIA2/RBV only... */
216 }
218 /*
219 * Now initialize VIA2. For RBV we just kill all interrupts;
220 * for a regular VIA we also reset the timers and stuff.
221 */
232 }
236 /* Everything below this point is VIA2 only... */
241 /*
242 * Set vPCR for control line interrupts.
243 *
244 * CA1 (SLOTS IRQ), CB1 (ASC IRQ): negative edge trigger.
245 *
246 * Macs with ESP SCSI have a negative edge triggered SCSI interrupt.
247 * Testing reveals that PowerBooks do too. However, the SE/30
248 * schematic diagram shows an active high NCR5380 IRQ line.
249 */
253 /* CA2 (SCSI DRQ), CB2 (SCSI IRQ): indep. input, pos. edge */
256 /* CA2 (SCSI DRQ), CB2 (SCSI IRQ): indep. input, neg. edge */
258 }
259 }
261 /*
262 * Debugging dump, used in various places to see what's going on.
263 */
266 {
285 }
286 }
288 /*
289 * Flush the L2 cache on Macs that have it by flipping
290 * the system into 24-bit mode for an instant.
291 */
294 {
301 }
303 /*
304 * Initialize VIA2 for Nubus access
305 */
308 {
309 /* unlock nubus transactions */
313 /* set the line to be an output on non-RBV machines */
317 /* this seems to be an ADB bit on PMU machines */
318 /* according to MkLinux. -- jmt */
320 }
322 /*
323 * Disable the slot interrupts. On some hardware that's not possible.
324 * On some hardware it's unclear what all of these I/O lines do.
325 */
333 /* RBV. Disable all the slot interrupts. SIER works like IER. */
336 }
337 }
340 {
346 /* Make the port A line an input. Probably redundant. */
348 /* The top two bits are RAM size outputs. */
351 /* Allow NuBus slots 9 through F. */
353 }
354 fallthrough;
358 }
359 }
362 {
366 /* Ensure that the umbrella CA1 interrupt remains enabled. */
372 }
373 }
375 /*
376 * The generic VIA interrupt routines (shamelessly stolen from Alan Cox's
377 * via6522.c :-), disable/pending masks added.
378 */
380 #define VIA_TIMER_1_INT BIT(6)
383 {
404 }
412 }
416 }
419 {
433 }
437 }
439 /*
440 * Dispatch Nubus interrupts. We are called as a secondary dispatch by the
441 * VIA2 dispatcher as a fast interrupt handler.
442 */
445 {
452 else
464 }
469 /* clear the CA1 interrupt and make certain there's no more. */
474 else
477 }
479 /*
480 * Register the interrupt dispatchers for VIA or RBV machines only.
481 */
484 {
486 /* software interrupt */
488 /* via1 interrupt */
492 }
495 }
511 /* Enable the CA1 interrupt when no slot is disabled. */
516 /* On RBV, enable the slot interrupt.
517 * SIER works like IER.
518 */
521 }
522 }
523 }
544 }
545 }
546 }
549 {
552 else
554 }
558 {
560 }
563 /* timer and clock source */
569 #define VIA_TC_LOW (VIA_TC & 0xFF)
570 #define VIA_TC_HIGH (VIA_TC >> 8)
580 };
585 {
591 }
594 {
596 NULL)) {
599 }
606 }
609 {
611 u8 count_high;
612 u16 count;
613 u32 ticks;
615 /*
616 * Timer counter wrap-around is detected with the timer interrupt flag
617 * but reading the counter low byte (vT1CL) would reset the flag.
618 * Also, accessing both counter registers is essentially a data race.
619 * These problems are avoided by ignoring the low byte. Clock accuracy
620 * is 256 times worse (error can reach 0.327 ms) but CPU overhead is
621 * reduced by avoiding slow VIA register accesses.
622 */
636 }