| blob | ecddac4a02b95abc11f80dbff860d2bdaea32fbd |
1 /*
2 * Macintosh interrupts
3 *
4 * General design:
5 * In contrary to the Amiga and Atari platforms, the Mac hardware seems to
6 * exclusively use the autovector interrupts (the 'generic level0-level7'
7 * interrupts with exception vectors 0x19-0x1f). The following interrupt levels
8 * are used:
9 * 1 - VIA1
10 * - slot 0: one second interrupt (CA2)
11 * - slot 1: VBlank (CA1)
12 * - slot 2: ADB data ready (SR full)
13 * - slot 3: ADB data (CB2)
14 * - slot 4: ADB clock (CB1)
15 * - slot 5: timer 2
16 * - slot 6: timer 1
17 * - slot 7: status of IRQ; signals 'any enabled int.'
18 *
19 * 2 - VIA2 or RBV
20 * - slot 0: SCSI DRQ (CA2)
21 * - slot 1: NUBUS IRQ (CA1) need to read port A to find which
22 * - slot 2: /EXP IRQ (only on IIci)
23 * - slot 3: SCSI IRQ (CB2)
24 * - slot 4: ASC IRQ (CB1)
25 * - slot 5: timer 2 (not on IIci)
26 * - slot 6: timer 1 (not on IIci)
27 * - slot 7: status of IRQ; signals 'any enabled int.'
28 *
29 * 2 - OSS (IIfx only?)
30 * - slot 0: SCSI interrupt
31 * - slot 1: Sound interrupt
32 *
33 * Levels 3-6 vary by machine type. For VIA or RBV Macintoshes:
34 *
35 * 3 - unused (?)
36 *
37 * 4 - SCC (slot number determined by reading RR3 on the SSC itself)
38 * - slot 1: SCC channel A
39 * - slot 2: SCC channel B
40 *
41 * 5 - unused (?)
42 * [serial errors or special conditions seem to raise level 6
43 * interrupts on some models (LC4xx?)]
44 *
45 * 6 - off switch (?)
46 *
47 * For OSS Macintoshes (IIfx only at this point):
48 *
49 * 3 - Nubus interrupt
50 * - slot 0: Slot $9
51 * - slot 1: Slot $A
52 * - slot 2: Slot $B
53 * - slot 3: Slot $C
54 * - slot 4: Slot $D
55 * - slot 5: Slot $E
56 *
57 * 4 - SCC IOP
58 * - slot 1: SCC channel A
59 * - slot 2: SCC channel B
60 *
61 * 5 - ISM IOP (ADB?)
62 *
63 * 6 - unused
64 *
65 * For PSC Macintoshes (660AV, 840AV):
66 *
67 * 3 - PSC level 3
68 * - slot 0: MACE
69 *
70 * 4 - PSC level 4
71 * - slot 1: SCC channel A interrupt
72 * - slot 2: SCC channel B interrupt
73 * - slot 3: MACE DMA
74 *
75 * 5 - PSC level 5
76 *
77 * 6 - PSC level 6
78 *
79 * Finally we have good 'ole level 7, the non-maskable interrupt:
80 *
81 * 7 - NMI (programmer's switch on the back of some Macs)
82 * Also RAM parity error on models which support it (IIc, IIfx?)
83 *
84 * The current interrupt logic looks something like this:
85 *
86 * - We install dispatchers for the autovector interrupts (1-7). These
87 * dispatchers are responsible for querying the hardware (the
88 * VIA/RBV/OSS/PSC chips) to determine the actual interrupt source. Using
89 * this information a machspec interrupt number is generated by placing the
90 * index of the interrupt hardware into the low three bits and the original
91 * autovector interrupt number in the upper 5 bits. The handlers for the
92 * resulting machspec interrupt are then called.
93 *
94 * - Nubus is a special case because its interrupts are hidden behind two
95 * layers of hardware. Nubus interrupts come in as index 1 on VIA #2,
96 * which translates to IRQ number 17. In this spot we install _another_
97 * dispatcher. This dispatcher finds the interrupting slot number (9-F) and
98 * then forms a new machspec interrupt number as above with the slot number
99 * minus 9 in the low three bits and the pseudo-level 7 in the upper five
100 * bits. The handlers for this new machspec interrupt number are then
101 * called. This puts Nubus interrupts into the range 56-62.
102 *
103 * - The Baboon interrupts (used on some PowerBooks) are an even more special
104 * case. They're hidden behind the Nubus slot $C interrupt thus adding a
105 * third layer of indirection. Why oh why did the Apple engineers do that?
106 *
107 * - We support "fast" and "slow" handlers, just like the Amiga port. The
108 * fast handlers are called first and with all interrupts disabled. They
109 * are expected to execute quickly (hence the name). The slow handlers are
110 * called last with interrupts enabled and the interrupt level restored.
111 * They must therefore be reentrant.
112 *
113 * TODO:
114 *
115 */
117 #include <linux/module.h>
118 #include <linux/types.h>
119 #include <linux/kernel.h>
120 #include <linux/sched.h>
121 #include <linux/kernel_stat.h>
123 #include <linux/delay.h>
124 #include <linux/seq_file.h>
126 #include <asm/system.h>
127 #include <asm/irq.h>
128 #include <asm/traps.h>
129 #include <asm/bootinfo.h>
130 #include <asm/machw.h>
131 #include <asm/macintosh.h>
132 #include <asm/mac_via.h>
133 #include <asm/mac_psc.h>
134 #include <asm/hwtest.h>
135 #include <asm/errno.h>
136 #include <asm/macints.h>
137 #include <asm/irq_regs.h>
139 #define DEBUG_SPURIOUS
140 #define SHUTUP_SONIC
142 /* SCC interrupt mask */
146 /*
147 * VIA/RBV hooks
148 */
157 /*
158 * OSS hooks
159 */
170 /*
171 * PSC hooks
172 */
183 /*
184 * IOP hooks
185 */
189 /*
190 * Baboon hooks
191 */
202 /*
203 * SCC interrupt routines
204 */
209 /*
210 * console_loglevel determines NMI handler function
211 */
216 /* #define DEBUG_MACINTS */
226 };
229 {
230 #ifdef DEBUG_MACINTS
232 #endif
237 /* Make sure the SONIC interrupt is cleared or things get ugly */
238 #ifdef SHUTUP_SONIC
240 /* This address should hopefully be mapped already */
244 }
248 /*
249 * Now register the handlers for the master IRQ handlers
250 * at levels 1-7. Most of the work is done elsewhere.
251 */
255 else
263 mac_nmi_handler);
264 #ifdef DEBUG_MACINTS
266 #endif
267 }
269 /*
270 * mac_enable_irq - enable an interrupt source
271 * mac_disable_irq - disable an interrupt source
272 * mac_clear_irq - clears a pending interrupt
273 * mac_pending_irq - Returns the pending status of an IRQ (nonzero = pending)
274 *
275 * These routines are just dispatchers to the VIA/OSS/PSC routines.
276 */
279 {
290 else
308 }
309 }
312 {
323 else
341 }
342 }
345 {
354 else
370 }
371 }
374 {
382 else
392 }
394 }
400 {
404 }
406 }
412 {
414 /*
415 * generate debug output on NMI switch if 'debug' kernel option given
416 * (only works with Penguin!)
417 */
419 in_nmi++;
429 }
437 #if 0
452 #else
453 /* printk("NMI "); */
454 #endif
455 }
456 in_nmi--;
458 }
460 /*
461 * Simple routines for masking and unmasking
462 * SCC interrupts in cases where this can't be
463 * done in hardware (only the PSC can do that.)
464 */
467 {
471 }
474 {
478 }
480 /*
481 * SCC master interrupt handler. We have to do a bit of magic here
482 * to figure out what channel gave us the interrupt; putting this
483 * here is cleaner than hacking it into drivers/char/macserial.c.
484 */
487 {
492 /* Read RR3 from the chip. Always do this on channel A */
493 /* This must be an atomic operation so disable irqs. */
500 /* Now dispatch. Bits 0-2 are for channel B and */
501 /* bits 3-5 are for channel A. We can safely */
502 /* ignore the remaining bits here. */
503 /* */
504 /* Note that we're ignoring scc_mask for now. */
505 /* If we actually mask the ints then we tend to */
506 /* get hammered by very persistent SCC irqs, */
507 /* and since they're autovector interrupts they */
508 /* pretty much kill the system. */
514 }