| blob | dffa786f61fe1b17c2a3a4b2e00f07d7e3a8bc2f |
1 /* -*- mode: c; c-basic-offset: 8 -*- */
3 /* Copyright (C) 1999,2001
4 *
5 * Author: J.E.J.Bottomley@HansenPartnership.com
6 *
7 * linux/arch/i386/kernel/voyager_smp.c
8 *
9 * This file provides all the same external entries as smp.c but uses
10 * the voyager hal to provide the functionality
11 */
12 #include <linux/module.h>
13 #include <linux/mm.h>
14 #include <linux/kernel_stat.h>
15 #include <linux/delay.h>
16 #include <linux/mc146818rtc.h>
17 #include <linux/cache.h>
18 #include <linux/interrupt.h>
19 #include <linux/init.h>
20 #include <linux/kernel.h>
21 #include <linux/bootmem.h>
22 #include <linux/completion.h>
23 #include <asm/desc.h>
24 #include <asm/voyager.h>
25 #include <asm/vic.h>
26 #include <asm/mtrr.h>
27 #include <asm/pgalloc.h>
28 #include <asm/tlbflush.h>
29 #include <asm/arch_hooks.h>
31 /* TLB state -- visible externally, indexed physically */
34 /* CPU IRQ affinity -- set to all ones initially */
38 /* per CPU data structure (for /proc/cpuinfo et al), visible externally
39 * indexed physically */
43 /* physical ID of the CPU used to boot the system */
46 /* The memory line addresses for the Quad CPIs */
49 /* The masks for the Extended VIC processors, filled in by cat_init */
52 /* Masks for the extended Quad processors which cannot be VIC booted */
55 /* The mask for the Quad Processors (both extended and non-extended) */
58 /* Total count of live CPUs, used in process.c to display
59 * the CPU information and in irq.c for the per CPU irq
60 * activity count. Finally exported by i386_ksyms.c */
63 /* Have we found an SMP box - used by time.c to do the profiling
64 interrupt for timeslicing; do not set to 1 until the per CPU timer
65 interrupt is active */
68 /* Used for the invalidate map that's also checked in the spinlock */
71 /* Bitmask of currently online CPUs - used by setup.c for
72 /proc/cpuinfo, visible externally but still physical */
76 /* Bitmask of CPUs present in the system - exported by i386_syms.c, used
77 * by scheduler but indexed physically */
80 /* The internal functions */
103 /* Inline functions */
105 {
108 }
111 {
116 #ifdef VOYAGER_DEBUG
121 #endif
123 }
124 }
125 }
128 {
132 }
135 {
138 else
140 }
143 {
147 }
150 {
153 }
156 {
160 }
163 {
168 }
171 {
176 else
181 /* These are slightly strange. Even on the Quad card,
182 * They are vectored as VIC CPIs */
185 else
191 }
192 }
194 /* local variables */
196 /* The VIC IRQ descriptors -- these look almost identical to the
197 * 8259 IRQs except that masks and things must be kept per processor
198 */
205 };
207 /* used to count up as CPUs are brought on line (starts at 0) */
210 /* steal a page from the bottom of memory for the trampoline and
211 * squirrel its address away here. This will be in kernel virtual
212 * space */
215 /* The per cpu profile stuff - used in smp_local_timer_interrupt */
220 /* the map used to check if a CPU has booted */
223 /* the synchronize flag used to hold all secondary CPUs spinning in
224 * a tight loop until the boot sequence is ready for them */
227 /* This is for the new dynamic CPU boot code */
233 /* The per processor IRQ masks (these are usually kept in sync) */
236 /* the list of IRQs to be enabled by the VIC_ENABLE_IRQ_CPI */
239 /* Lock for enable/disable of VIC interrupts */
242 /* The boot processor is correctly set up in PC mode when it
243 * comes up, but the secondaries need their master/slave 8259
244 * pairs initializing correctly */
246 /* Interrupt counters (per cpu) and total - used to try to
247 * even up the interrupt handling routines */
252 /* Since we can only use CPI0, we fake all the other CPIs */
255 /* debugging routine to read the isr of the cpu's pic */
257 {
258 __u16 isr;
266 }
269 {
271 /* not a quad, no setup */
273 }
278 /* the QIC duplicate of the VIC base register */
282 /* FIXME: should set up the QIC timer and memory parity
283 * error vectors here */
284 }
285 }
288 {
290 /* clear the claim registers for dynamic routing */
295 /* Set the Primary and Secondary Microchannel vector
296 * bases to be the same as the ordinary interrupts
297 *
298 * FIXME: This would be more efficient using separate
299 * vectors. */
302 /* Now initiallise the master PIC belonging to this CPU by
303 * sending the four ICWs */
305 /* ICW1: level triggered, ICW4 needed */
308 /* ICW2: vector base */
311 /* ICW3: slave at line 2 */
314 /* ICW4: 8086 mode */
317 /* now the same for the slave PIC */
319 /* ICW1: level trigger, ICW4 needed */
322 /* ICW2: slave vector base */
325 /* ICW3: slave ID */
328 /* ICW4: 8086 mode */
330 }
333 {
342 /* FIXME: this would be >>3 &0x7 on the 32 way */
344 /* don't lower our own mask! */
347 /* masquerade as local Quad CPU */
349 /* enable the startup CPI */
351 /* restore cpu id */
353 }
355 }
356 }
358 /* Set up all the basic stuff: read the SMP config and make all the
359 * SMP information reflect only the boot cpu. All others will be
360 * brought on-line later. */
362 {
369 /* initialize the CPU structures (moved from smp_boot_cpus) */
372 }
375 /* The boot CPU must be extended */
377 /* initially, all of the first 8 CPUs can boot */
379 /* set up everything for just this CPU, we can alter
380 * this as we start the other CPUs later */
381 /* now get the CPU disposition from the extended CMOS */
395 /* Here we set up the VIC to enable SMP */
396 /* enable the CPIs by writing the base vector to their register */
399 /* set the claim registers for static routing --- Boot CPU gets
400 * all interrupts untill all other CPUs started */
403 /* Set the Primary and Secondary Microchannel vector
404 * bases to be the same as the ordinary interrupts
405 *
406 * FIXME: This would be more efficient using separate
407 * vectors. */
411 /* Finally tell the firmware that we're driving */
413 VOYAGER_SUS_IN_CONTROL_PORT);
417 }
419 /*
420 * The bootstrap kernel entry code has set these up. Save them
421 * for a given CPU, id is physical */
423 {
429 }
431 /* set up the trampoline and return the physical address of the code */
433 {
434 /* these two are global symbols in trampoline.S */
441 }
443 /* Routine initially called when a non-boot CPU is brought online */
445 {
447 /* external functions not defined in the headers */
452 /* OK, we're in the routine */
455 /* setup the 8259 master slave pair belonging to this CPU ---
456 * we won't actually receive any until the boot CPU
457 * relinquishes it's static routing mask */
463 /* clear the boot CPI */
464 __u8 dummy;
466 dummy =
469 }
471 /* lower the mask to receive CPIs */
476 /* enable interrupts */
479 /* get our bogomips */
482 /* save our processor parameters */
485 /* if we're a quad, we may need to bootstrap other CPUs */
488 /* FIXME: this is rather a poor hack to prevent the CPU
489 * activating softirqs while it's supposed to be waiting for
490 * permission to proceed. Without this, the new per CPU stuff
491 * in the softirqs will fail */
495 /* signal that we're done */
507 }
509 /* Routine to kick start the given CPU and wait for it to report ready
510 * (or timeout in startup). When this routine returns, the requested
511 * CPU is either fully running and configured or known to be dead.
512 *
513 * We call this routine sequentially 1 CPU at a time, so no need for
514 * locking */
517 {
522 & ~(voyager_extended_vic_processors
525 /* This is an area in head.S which was used to set up the
526 * initial kernel stack. We need to alter this to give the
527 * booting CPU a new stack (taken from its idle process) */
532 /* This is the format of the CPI IDT gate (in real mode) which
533 * we're hijacking to boot the CPU */
536 __u16 Offset;
537 __u16 Segment;
539 __u32 val;
545 /* There's a clever trick to this: The linux trampoline is
546 * compiled to begin at absolute location zero, so make the
547 * address zero but have the data segment selector compensate
548 * for the actual address */
552 cpucount++;
559 /* init_tasks (in sched.c) is indexed logically */
567 /* Note: Don't modify initial ss override */
572 /* init lowmem identity mapping */
579 hijack_vector =
585 hijack_vector =
589 /* VIC errata, may also receive interrupt at this address */
590 hijack_vector =
595 }
596 /* All non-boot CPUs start with interrupts fully masked. Need
597 * to lower the mask of the CPI we're about to send. We do
598 * this in the VIC by masquerading as the processor we're
599 * about to boot and lowering its interrupt mask */
605 /* here we're altering registers belonging to `cpu' */
608 /* now go back to our original identity */
611 /* and boot the CPU */
614 }
618 /* now wait for it to become ready (or timeout) */
623 }
624 /* reset the page table */
642 else
645 cpucount--;
646 }
647 }
650 {
653 /* CAT BUS initialisation must be done after the memory */
654 /* FIXME: The L4 has a catbus too, it just needs to be
655 * accessed in a totally different way */
659 /* now that the cat has probed the Voyager System Bus, sanity
660 * check the cpu map */
664 /* should panic */
667 }
669 voyager_extended_vic_processors =
672 /* this sets up the idle task to run on the current cpu */
674 /* Remove the global_irq_holder setting, it triggers a BUG() on
675 * schedule at the moment */
676 //global_irq_holder = boot_cpu_id;
678 /* FIXME: Need to do something about this but currently only works
679 * on CPUs with a tsc which none of mine have.
680 smp_tune_scheduling();
681 */
687 /* booting on a Quad CPU */
691 }
693 /* enable our own CPIs */
699 /* loop over all the extended VIC CPUs and boot them. The
700 * Quad CPUs must be bootstrapped by their extended VIC cpu */
705 /* This udelay seems to be needed for the Quad boots
706 * don't remove unless you know what you're doing */
708 }
709 /* we could compute the total bogomips here, but why bother?,
710 * Code added from smpboot.c */
711 {
720 }
725 /* that's it, switch to symmetric mode */
731 }
733 /* Reload the secondary CPUs task structure (this function does not
734 * return ) */
736 {
737 #if 0
738 // AC kernels only
740 #endif
742 /*
743 * We don't actually need to load the full TSS,
744 * basically just the stack pointer and the eip.
745 */
750 }
752 /* handle a Voyager SYS_INT -- If we don't, the base board will
753 * panic the system.
754 *
755 * System interrupts occur because some problem was detected on the
756 * various busses. To find out what you have to probe all the
757 * hardware via the CAT bus. FIXME: At the moment we do nothing. */
759 {
762 }
764 /* Handle a voyager CMN_INT; These interrupts occur either because of
765 * a system status change or because a single bit memory error
766 * occurred. FIXME: At the moment, ignore all this. */
768 {
772 /* common ints are broadcast, so make sure we only do this once */
777 in_cmn_int++;
787 unlock_end:
790 }
792 /*
793 * Reschedule call back. Nothing to do, all the work is done
794 * automatically when we return from the interrupt. */
796 {
797 /* do nothing */
798 }
804 /*
805 * We cannot call mmdrop() because we are in interrupt context,
806 * instead update mm->cpu_vm_mask.
807 *
808 * We need to reload %cr3 since the page tables may be going
809 * away from under us..
810 */
812 {
817 }
819 /*
820 * Invalidate call-back
821 */
823 {
828 /* This will flood messages. Don't uncomment unless you see
829 * Problems with cross cpu invalidation
830 VDEBUG(("VOYAGER SMP: CPU%d received INVALIDATE_CPI\n",
831 smp_processor_id()));
832 */
838 else
842 }
846 }
848 /* All the new flush operations for 2.4 */
850 /* This routine is called with a physical cpu mask */
851 static void
854 {
871 /*
872 * We have to send the CPI only to
873 * CPUs affected.
874 */
883 }
884 }
886 /* Uncomment only to debug invalidation problems
887 VDEBUG(("VOYAGER SMP: Completed invalidate CPI (CPU%d)\n", cpu));
888 */
893 }
896 {
908 }
911 {
921 else
923 }
928 }
931 {
941 else
943 }
949 }
953 /* enable the requested IRQs */
955 {
956 __u8 irq;
966 }
971 }
973 /*
974 * CPU halt call-back
975 */
977 {
983 }
993 };
997 /* execute a thread on a new CPU. The function to be called must be
998 * previously set up. This is used to schedule a function for
999 * execution on all CPUs - set up the function then broadcast a
1000 * function_interrupt CPI to come here on each CPU */
1002 {
1005 /* must take copy of wait because call_data may be replaced
1006 * unless the function is waiting for us to finish */
1010 /*
1011 * Notify initiating CPU that I've grabbed the data and am
1012 * about to execute the function
1013 */
1016 /* If the bit wasn't set, this could be a replay */
1020 }
1021 /*
1022 * At this point the info structure may be out of scope unless wait==1
1023 */
1031 }
1032 }
1034 static int
1037 {
1046 /* Can deadlock when called with interrupts disabled */
1059 /* Send a message to all other CPUs and wait for them to respond */
1062 /* Wait for response */
1073 }
1075 /* Sorry about the name. In an APIC based system, the APICs
1076 * themselves are programmed to send a timer interrupt. This is used
1077 * by linux to reschedule the processor. Voyager doesn't have this,
1078 * so we use the system clock to interrupt one processor, which in
1079 * turn, broadcasts a timer CPI to all the others --- we receive that
1080 * CPI here. We don't use this actually for counting so losing
1081 * ticks doesn't matter
1082 *
1083 * FIXME: For those CPUs which actually have a local APIC, we could
1084 * try to use it to trigger this interrupt instead of having to
1085 * broadcast the timer tick. Unfortunately, all my pentium DYADs have
1086 * no local APIC, so I can't do this
1087 *
1088 * This function is currently a placeholder and is unused in the code */
1090 {
1094 }
1096 /* All of the QUAD interrupt GATES */
1098 {
1103 }
1106 {
1109 }
1112 {
1115 }
1118 {
1121 }
1124 {
1127 }
1130 {
1136 else
1150 }
1153 {
1159 }
1161 /* flush the TLB of every active CPU in the system */
1163 {
1165 }
1167 /* used to set up the trampoline for other CPUs when the memory manager
1168 * is sorted out */
1170 {
1174 }
1176 /* send a reschedule CPI to one CPU by physical CPU number*/
1178 {
1180 }
1183 {
1184 __u8 i;
1192 }
1195 }
1198 {
1200 }
1202 /* broadcast a halt to all other CPUs */
1204 {
1206 }
1208 /* this function is triggered in time.c when a clock tick fires
1209 * we need to re-broadcast the tick to all CPUs */
1211 {
1214 }
1216 /* local (per CPU) timer interrupt. It does both profiling and
1217 * process statistics/rescheduling.
1218 *
1219 * We do profiling in every local tick, statistics/rescheduling
1220 * happen only every 'profiling multiplier' ticks. The default
1221 * multiplier is 1 and it can be changed by writing the new multiplier
1222 * value into /proc/profile.
1223 */
1225 {
1231 /*
1232 * The multiplier may have changed since the last time we got
1233 * to this point as a result of the user writing to
1234 * /proc/profile. In this case we need to adjust the APIC
1235 * timer accordingly.
1236 *
1237 * Interrupts are already masked off at this point.
1238 */
1242 /* FIXME: need to update the vic timer tick here */
1245 }
1248 }
1251 /* only extended VIC processors participate in
1252 * interrupt distribution */
1255 /*
1256 * We take the 'long' return path, and there every subsystem
1257 * grabs the appropriate locks (kernel lock/ irq lock).
1258 *
1259 * we might want to decouple profiling from the 'long path',
1260 * and do the profiling totally in assembly.
1261 *
1262 * Currently this isn't too much of an issue (performance wise),
1263 * we can take more than 100K local irqs per second on a 100 MHz P5.
1264 */
1268 /* get here every 16 ticks (about every 1/6 of a second) */
1270 /* Change our priority to give someone else a chance at getting
1271 * the IRQ. The algorithm goes like this:
1272 *
1273 * In the VIC, the dynamically routed interrupt is always
1274 * handled by the lowest priority eligible (i.e. receiving
1275 * interrupts) CPU. If >1 eligible CPUs are equal lowest, the
1276 * lowest processor number gets it.
1277 *
1278 * The priority of a CPU is controlled by a special per-CPU
1279 * VIC priority register which is 3 bits wide 0 being lowest
1280 * and 7 highest priority..
1281 *
1282 * Therefore we subtract the average number of interrupts from
1283 * the number we've fielded. If this number is negative, we
1284 * lower the activity count and if it is positive, we raise
1285 * it.
1286 *
1287 * I'm afraid this still leads to odd looking interrupt counts:
1288 * the totals are all roughly equal, but the individual ones
1289 * look rather skewed.
1290 *
1291 * FIXME: This algorithm is total crap when mixed with SMP
1292 * affinity code since we now try to even up the interrupt
1293 * counts when an affinity binding is keeping them on a
1294 * particular CPU*/
1305 #ifdef VOYAGER_DEBUG
1307 /* print this message roughly every 25 secs */
1310 }
1311 #endif
1312 }
1314 /* setup the profiling timer */
1316 {
1322 /*
1323 * Set the new multiplier for each CPU. CPUs don't start using the
1324 * new values until the next timer interrupt in which they do process
1325 * accounting.
1326 */
1331 }
1333 /* This is a bit of a mess, but forced on us by the genirq changes
1334 * there's no genirq handler that really does what voyager wants
1335 * so hack it up with the simple IRQ handler */
1337 {
1341 }
1343 /* The CPIs are handled in the per cpu 8259s, so they must be
1344 * enabled to be received: FIX: enabling the CPIs in the early
1345 * boot sequence interferes with bug checking; enable them later
1346 * on in smp_init */
1347 #define VIC_SET_GATE(cpi, vector) \
1348 set_intr_gate((cpi) + VIC_DEFAULT_CPI_BASE, (vector))
1349 #define QIC_SET_GATE(cpi, vector) \
1350 set_intr_gate((cpi) + QIC_DEFAULT_CPI_BASE, (vector))
1353 {
1356 /* initialize the per cpu irq mask to all disabled */
1371 /* now put the VIC descriptor into the first 48 IRQs
1372 *
1373 * This is for later: first 16 correspond to PC IRQs; next 16
1374 * are Primary MC IRQs and final 16 are Secondary MC IRQs */
1377 }
1379 /* send a CPI at level cpi to a set of cpus in cpuset (set 1 bit per
1380 * processor to receive CPI */
1382 {
1387 /* fake CPI are only used for booting, so send to the
1388 * extended quads as well---Quads must be VIC booted */
1391 }
1401 }
1404 }
1406 /* Acknowledge receipt of CPI in the QIC, clear in QIC hardware and
1407 * set the cache line to shared by reading it.
1408 *
1409 * DON'T make this inline otherwise the cache line read will be
1410 * optimised away
1411 * */
1413 {
1420 }
1423 {
1431 }
1432 /* also clear at the VIC, just in case (nop for non-extended proc) */
1434 }
1436 /* Acknowledge receipt of CPI in the VIC (essentially an EOI) */
1438 {
1439 #ifdef VOYAGER_DEBUG
1441 __u16 isr;
1448 }
1449 #endif
1450 /* send specific EOI; the two system interrupts have
1451 * bit 4 set for a separate vector but behave as the
1452 * corresponding 3 bit intr */
1455 #ifdef VOYAGER_DEBUG
1458 }
1460 #endif
1461 }
1463 /* cribbed with thanks from irq.c */
1464 #define __byte(x,y) (((unsigned char *)&(y))[x])
1465 #define cached_21(cpu) (__byte(0,vic_irq_mask[cpu]))
1466 #define cached_A1(cpu) (__byte(1,vic_irq_mask[cpu]))
1469 {
1473 }
1475 /* The enable and disable routines. This is where we run into
1476 * conflicting architectural philosophy. Fundamentally, the voyager
1477 * architecture does not expect to have to disable interrupts globally
1478 * (the IRQ controllers belong to each CPU). The processor masquerade
1479 * which is used to start the system shouldn't be used in a running OS
1480 * since it will cause great confusion if two separate CPUs drive to
1481 * the same IRQ controller (I know, I've tried it).
1482 *
1483 * The solution is a variant on the NCR lazy SPL design:
1484 *
1485 * 1) To disable an interrupt, do nothing (other than set the
1486 * IRQ_DISABLED flag). This dares the interrupt actually to arrive.
1487 *
1488 * 2) If the interrupt dares to come in, raise the local mask against
1489 * it (this will result in all the CPU masks being raised
1490 * eventually).
1491 *
1492 * 3) To enable the interrupt, lower the mask on the local CPU and
1493 * broadcast an Interrupt enable CPI which causes all other CPUs to
1494 * adjust their masks accordingly. */
1497 {
1498 /* linux doesn't to processor-irq affinity, so enable on
1499 * all CPUs we know about */
1512 /* irq has no affinity for this CPU, ignore */
1514 }
1520 }
1521 }
1525 }
1528 {
1529 /* lazy disable, do nothing */
1530 }
1533 {
1551 }
1552 }
1555 {
1576 }
1577 }
1579 /* The VIC is level triggered, so the ack can only be issued after the
1580 * interrupt completes. However, we do Voyager lazy interrupt
1581 * handling here: It is an extremely expensive operation to mask an
1582 * interrupt in the vic, so we merely set a flag (IRQ_DISABLED). If
1583 * this interrupt actually comes in, then we mask and ack here to push
1584 * the interrupt off to another CPU */
1586 {
1591 vic_intr_total++;
1595 /* The irq is not in our affinity mask, push it off
1596 * onto another CPU */
1600 /* set IRQ_INPROGRESS to prevent the handler in irq.c from
1601 * actually calling the interrupt routine */
1604 /* Damn, the interrupt actually arrived, do the lazy
1605 * disable thing. The interrupt routine in irq.c will
1606 * not handle a IRQ_DISABLED interrupt, so nothing more
1607 * need be done here */
1614 }
1617 }
1619 /* Finish the VIC interrupt: basically mask */
1621 {
1625 {
1627 #ifdef VOYAGER_DEBUG
1628 __u16 isr;
1629 #endif
1634 #ifdef VOYAGER_DEBUG
1635 /* DEBUG: before we ack, check what's in progress */
1640 __u8 real_cpu;
1648 VIC_PROCESSOR_ID);
1651 printk
1655 }
1657 }
1658 }
1660 /* as soon as we ack, the interrupt is eligible for
1661 * receipt by another CPU so everything must be in
1662 * order here */
1665 /* replay is set if we disable the interrupt
1666 * in the before_handle_vic_irq() routine, so
1667 * clear the in progress bit here to allow the
1668 * next CPU to handle this correctly */
1670 }
1671 #ifdef VOYAGER_DEBUG
1677 }
1680 /* All code after this point is out of the main path - the IRQ
1681 * may be intercepted by another CPU if reasserted */
1682 }
1684 /* Linux processor - interrupt affinity manipulations.
1685 *
1686 * For each processor, we maintain a 32 bit irq affinity mask.
1687 * Initially it is set to all 1's so every processor accepts every
1688 * interrupt. In this call, we change the processor's affinity mask:
1689 *
1690 * Change from enable to disable:
1691 *
1692 * If the interrupt ever comes in to the processor, we will disable it
1693 * and ack it to push it off to another CPU, so just accept the mask here.
1694 *
1695 * Change from disable to enable:
1696 *
1697 * change the mask and then do an interrupt enable CPI to re-enable on
1698 * the selected processors */
1701 {
1702 /* Only extended processors handle interrupts */
1710 /* can't have no CPUs to accept the interrupt -- extremely
1711 * bad things will happen */
1715 /* can't change the affinity of the timer IRQ. This
1716 * is due to the constraint in the voyager
1717 * architecture that the CPI also comes in on and IRQ
1718 * line and we have chosen IRQ0 for this. If you
1719 * raise the mask on this interrupt, the processor
1720 * will no-longer be able to accept VIC CPIs */
1724 /* You can only have 32 interrupts in a voyager system
1725 * (and 32 only if you have a secondary microchannel
1726 * bus) */
1733 /* enable the interrupt for this cpu */
1736 /* disable the interrupt for this cpu */
1738 }
1739 }
1740 /* this is magic, we now have the correct affinity maps, so
1741 * enable the interrupt. This will send an enable CPI to
1742 * those CPUs who need to enable it in their local masks,
1743 * causing them to correct for the new affinity . If the
1744 * interrupt is currently globally disabled, it will simply be
1745 * disabled again as it comes in (voyager lazy disable). If
1746 * the affinity map is tightened to disable the interrupt on a
1747 * cpu, it will be pushed off when it comes in */
1749 }
1752 {
1758 }
1759 }
1761 /* enable the CPIs. In the VIC, the CPIs are delivered by the 8259
1762 * but are not vectored by it. This means that the 8259 mask must be
1763 * lowered to receive them */
1765 {
1768 /* just take a copy of the current mask (nop for boot cpu) */
1773 /* for sys int and cmn int */
1781 }
1785 }
1788 {
1791 /* dump the interrupt masks of each processor */
1811 #if 0
1812 /* These lines are put in to try to unstick an un ack'd irq */
1821 VIC_PROCESSOR_ID);
1825 }
1826 }
1827 }
1828 #endif
1829 }
1830 }
1833 {
1836 else
1838 }
1841 {
1842 /* FIXME: ignore max_cpus for now */
1844 }
1847 {
1855 }
1858 {
1859 /* This only works at boot for x86. See "rewrite" above. */
1863 /* In case one didn't come up */
1866 /* Unleash the CPU! */
1871 }
1874 {
1876 }
1879 {
1882 }
1893 };