| blob | 2e3eb7431571603fc9cd2452df25a32c6cd4c6da |
1 /*
2 * Performance event support - powerpc architecture code
3 *
4 * Copyright 2008-2009 Paul Mackerras, IBM Corporation.
5 *
6 * This program is free software; you can redistribute it and/or
7 * modify it under the terms of the GNU General Public License
8 * as published by the Free Software Foundation; either version
9 * 2 of the License, or (at your option) any later version.
10 */
11 #include <linux/kernel.h>
12 #include <linux/sched.h>
13 #include <linux/perf_event.h>
14 #include <linux/percpu.h>
15 #include <linux/hardirq.h>
16 #include <linux/uaccess.h>
17 #include <asm/reg.h>
18 #include <asm/pmc.h>
19 #include <asm/machdep.h>
20 #include <asm/firmware.h>
21 #include <asm/ptrace.h>
22 #include <asm/code-patching.h>
24 #define BHRB_MAX_ENTRIES 32
25 #define BHRB_TARGET 0x0000000000000002
26 #define BHRB_PREDICTION 0x0000000000000001
27 #define BHRB_EA 0xFFFFFFFFFFFFFFFCUL
35 u8 pmcs_enabled;
39 /*
40 * The order of the MMCR array is:
41 * - 64-bit, MMCR0, MMCR1, MMCRA, MMCR2
42 * - 32-bit, MMCR0, MMCR1, MMCR2
43 */
54 /* BHRB bits */
60 u64 ic_init;
61 };
67 /*
68 * Normally, to ignore kernel events we set the FCS (freeze counters
69 * in supervisor mode) bit in MMCR0, but if the kernel runs with the
70 * hypervisor bit set in the MSR, or if we are running on a processor
71 * where the hypervisor bit is forced to 1 (as on Apple G5 processors),
72 * then we need to use the FCHV bit to ignore kernel events.
73 */
76 /*
77 * 32-bit doesn't have MMCRA but does have an MMCR2,
78 * and a few other names are different.
79 */
80 #ifdef CONFIG_PPC32
82 #define MMCR0_FCHV 0
83 #define MMCR0_PMCjCE MMCR0_PMCnCE
84 #define MMCR0_FC56 0
85 #define MMCR0_PMAO 0
86 #define MMCR0_EBE 0
87 #define MMCR0_BHRBA 0
88 #define MMCR0_PMCC 0
89 #define MMCR0_PMCC_U6 0
91 #define SPRN_MMCRA SPRN_MMCR2
92 #define MMCRA_SAMPLE_ENABLE 0
95 {
97 }
100 {
102 }
104 {
106 }
108 {
110 }
113 {
115 }
122 {
124 }
132 {
134 }
138 {
139 /*
140 * When we take a performance monitor exception the regs are setup
141 * using perf_read_regs() which overloads some fields, in particular
142 * regs->result to tell us whether to use SIAR.
143 *
144 * However if the regs are from another exception, eg. a syscall, then
145 * they have not been setup using perf_read_regs() and so regs->result
146 * is something random.
147 */
149 }
151 /*
152 * Things that are specific to 64-bit implementations.
153 */
154 #ifdef CONFIG_PPC64
157 {
164 }
167 }
169 /*
170 * The user wants a data address recorded.
171 * If we're not doing instruction sampling, give them the SDAR
172 * (sampled data address). If we are doing instruction sampling, then
173 * only give them the SDAR if it corresponds to the instruction
174 * pointed to by SIAR; this is indicated by the [POWER6_]MMCRA_SDSYNC, the
175 * [POWER7P_]MMCRA_SDAR_VALID bit in MMCRA, or the SDAR_VALID bit in SIER.
176 */
178 {
193 else
197 }
201 }
204 {
214 }
217 {
227 }
230 {
236 }
239 {
245 /*
246 * If we don't have flags in MMCRA, rather than using
247 * the MSR, we intuit the flags from the address in
248 * SIAR which should give slightly more reliable
249 * results
250 */
256 }
258 /* PR has priority over HV, so order below is important */
266 }
268 /*
269 * Overload regs->dsisr to store MMCRA so we only need to read it once
270 * on each interrupt.
271 * Overload regs->dar to store SIER if we have it.
272 * Overload regs->result to specify whether we should use the MSR (result
273 * is zero) or the SIAR (result is non zero).
274 */
276 {
286 /*
287 * If this isn't a PMU exception (eg a software event) the SIAR is
288 * not valid. Use pt_regs.
289 *
290 * If it is a marked event use the SIAR.
291 *
292 * If the PMU doesn't update the SIAR for non marked events use
293 * pt_regs.
294 *
295 * If the PMU has HV/PR flags then check to see if they
296 * place the exception in userspace. If so, use pt_regs. In
297 * continuous sampling mode the SIAR and the PMU exception are
298 * not synchronised, so they may be many instructions apart.
299 * This can result in confusing backtraces. We still want
300 * hypervisor samples as well as samples in the kernel with
301 * interrupts off hence the userspace check.
302 */
313 else
317 }
319 /*
320 * If interrupts were soft-disabled when a PMU interrupt occurs, treat
321 * it as an NMI.
322 */
324 {
326 }
328 /*
329 * On processors like P7+ that have the SIAR-Valid bit, marked instructions
330 * must be sampled only if the SIAR-valid bit is set.
331 *
332 * For unmarked instructions and for processors that don't have the SIAR-Valid
333 * bit, assume that SIAR is valid.
334 */
336 {
346 }
349 }
352 /* Reset all possible BHRB entries */
354 {
356 }
359 {
365 /* Clear BHRB if we changed task context to avoid data leaks */
369 }
372 }
375 {
386 /* BHRB cannot be turned off when other
387 * events are active on the PMU.
388 */
390 /* avoid stale pointer */
392 }
393 }
395 /* Called from ctxsw to prevent one process's branch entries to
396 * mingle with the other process's entries during context switch.
397 */
399 {
405 }
406 /* Calculate the to address for a branch */
408 {
411 __u64 target;
416 /* Userspace: need copy instruction here then translate it */
422 }
429 /* Translate relative branch target from kernel to user address */
431 }
433 /* Processing BHRB entries */
435 {
436 u64 val;
437 u64 addr;
443 /* Assembly read function */
446 /* Terminal marker: End of valid BHRB entries */
453 /* invalid entry */
456 /* Branches are read most recent first (ie. mfbhrb 0 is
457 * the most recent branch).
458 * There are two types of valid entries:
459 * 1) a target entry which is the to address of a
460 * computed goto like a blr,bctr,btar. The next
461 * entry read from the bhrb will be branch
462 * corresponding to this target (ie. the actual
463 * blr/bctr/btar instruction).
464 * 2) a from address which is an actual branch. If a
465 * target entry proceeds this, then this is the
466 * matching branch for that target. If this is not
467 * following a target entry, then this is a branch
468 * where the target is given as an immediate field
469 * in the instruction (ie. an i or b form branch).
470 * In this case we need to read the instruction from
471 * memory to determine the target/to address.
472 */
475 /* Target branches use two entries
476 * (ie. computed gotos/XL form)
477 */
482 /* Get from address in next entry */
486 /* Shouldn't have two targets in a
487 row.. Reset index and try again */
488 r_index--;
490 }
493 /* Branches to immediate field
494 (ie I or B form) */
500 }
501 u_index++;
503 }
504 }
507 }
510 {
511 /*
512 * This could be a per-PMU callback, but we'd rather avoid the cost. We
513 * check that the PMU supports EBB, meaning those that don't can still
514 * use bit 63 of the event code for something else if they wish.
515 */
518 }
521 {
524 /* Event and group leader must agree on EBB */
541 }
544 }
547 {
551 /*
552 * IFF this is the first time we've added an EBB event, set
553 * PMXE in the user MMCR0 so we can detect when it's cleared by
554 * userspace. We need this so that we can context switch while
555 * userspace is in the EBB handler (where PMXE is 0).
556 */
559 }
562 {
571 }
574 {
580 /* Enable EBB and read/write to all 6 PMCs and BHRB for userspace */
583 /*
584 * Add any bits from the user MMCR0, FC or PMAO. This is compatible
585 * with pmao_restore_workaround() because we may add PMAO but we never
586 * clear it here.
587 */
590 /*
591 * Be careful not to set PMXE if userspace had it cleared. This is also
592 * compatible with pmao_restore_workaround() because it has already
593 * cleared PMXE and we leave PMAO alone.
594 */
602 /*
603 * Merge the kernel & user values of MMCR2. The semantics we implement
604 * are that the user MMCR2 can set bits, ie. cause counters to freeze,
605 * but not clear bits. If a task wants to be able to clear bits, ie.
606 * unfreeze counters, it should not set exclude_xxx in its events and
607 * instead manage the MMCR2 entirely by itself.
608 */
610 out:
612 }
615 {
621 /*
622 * On POWER8E there is a hardware defect which affects the PMU context
623 * switch logic, ie. power_pmu_disable/enable().
624 *
625 * When a counter overflows PMXE is cleared and FC/PMAO is set in MMCR0
626 * by the hardware. Sometime later the actual PMU exception is
627 * delivered.
628 *
629 * If we context switch, or simply disable/enable, the PMU prior to the
630 * exception arriving, the exception will be lost when we clear PMAO.
631 *
632 * When we reenable the PMU, we will write the saved MMCR0 with PMAO
633 * set, and this _should_ generate an exception. However because of the
634 * defect no exception is generated when we write PMAO, and we get
635 * stuck with no counters counting but no exception delivered.
636 *
637 * The workaround is to detect this case and tweak the hardware to
638 * create another pending PMU exception.
639 *
640 * We do that by setting up PMC6 (cycles) for an imminent overflow and
641 * enabling the PMU. That causes a new exception to be generated in the
642 * chip, but we don't take it yet because we have interrupts hard
643 * disabled. We then write back the PMU state as we want it to be seen
644 * by the exception handler. When we reenable interrupts the exception
645 * handler will be called and see the correct state.
646 *
647 * The logic is the same for EBB, except that the exception is gated by
648 * us having interrupts hard disabled as well as the fact that we are
649 * not in userspace. The exception is finally delivered when we return
650 * to userspace.
651 */
653 /* Only if PMAO is set and PMAO_SYNC is clear */
657 /* If we're doing EBB, only if BESCR[GE] is set */
661 /*
662 * We are already soft-disabled in power_pmu_enable(). We need to hard
663 * disable to actually prevent the PMU exception from firing.
664 */
667 /*
668 * This is a bit gross, but we know we're on POWER8E and have 6 PMCs.
669 * Using read/write_pmc() in a for loop adds 12 function calls and
670 * almost doubles our code size.
671 */
679 /* Ensure all freeze bits are unset */
682 /* Set up PMC6 to overflow in one cycle */
685 /* Enable exceptions and unfreeze PMC6 */
688 /* Now we need to refreeze and restore the PMCs */
697 }
700 {
706 }
711 /*
712 * Read one performance monitor counter (PMC).
713 */
715 {
737 #ifdef CONFIG_PPC64
748 }
750 }
752 /*
753 * Write one PMC.
754 */
756 {
776 #ifdef CONFIG_PPC64
786 }
787 }
789 /* Called from sysrq_handle_showregs() */
791 {
821 #ifdef CONFIG_PPC64
832 }
833 #endif
838 }
840 /*
841 * Check if a set of events can all go on the PMU at once.
842 * If they can't, this will look at alternative codes for the events
843 * and see if any combination of alternative codes is feasible.
844 * The feasible set is returned in event_id[].
845 */
849 {
860 /* First see if the events will go on as-is */
867 }
871 }
882 }
886 /* doesn't work, gather alternatives... */
897 }
899 /* enumerate all possibilities and see if any will work */
905 /* we're backtracking, restore context */
909 }
910 /*
911 * See if any alternative k for event_id i,
912 * where k > j, will satisfy the constraints.
913 */
921 }
923 /*
924 * No feasible alternative, backtrack
925 * to event_id i-1 and continue enumerating its
926 * alternatives from where we got up to.
927 */
931 /*
932 * Found a feasible alternative for event_id i,
933 * remember where we got up to with this event_id,
934 * go on to the next event_id, and start with
935 * the first alternative for it.
936 */
944 }
945 }
947 /* OK, we have a feasible combination, tell the caller the solution */
951 }
953 /*
954 * Check if newly-added events have consistent settings for
955 * exclude_{user,kernel,hv} with each other and any previously
956 * added events.
957 */
960 {
965 /*
966 * If the PMU we're on supports per event exclude settings then we
967 * don't need to do any of this logic. NB. This assumes no PMU has both
968 * per event exclude and limited PMCs.
969 */
982 }
993 }
994 }
1002 }
1005 {
1008 /*
1009 * POWER7 can roll back counter values, if the new value is smaller
1010 * than the previous value it will cause the delta and the counter to
1011 * have bogus values unless we rolled a counter over. If a coutner is
1012 * rolled back, it will be smaller, but within 256, which is the maximum
1013 * number of events to rollback at once. If we detect a rollback
1014 * return 0. This can lead to a small lack of precision in the
1015 * counters.
1016 */
1021 }
1024 {
1040 else
1042 }
1045 }
1047 /*
1048 * Performance monitor interrupts come even when interrupts
1049 * are soft-disabled, as long as interrupts are hard-enabled.
1050 * Therefore we treat them like NMIs.
1051 */
1060 else
1062 }
1070 /*
1071 * A number of places program the PMC with (0x80000000 - period_left).
1072 * We never want period_left to be less than 1 because we will program
1073 * the PMC with a value >= 0x800000000 and an edge detected PMC will
1074 * roll around to 0 before taking an exception. We have seen this
1075 * on POWER8.
1076 *
1077 * To fix this, clamp the minimum value of period_left to 1.
1078 */
1085 }
1087 /*
1088 * On some machines, PMC5 and PMC6 can't be written, don't respect
1089 * the freeze conditions, and don't generate interrupts. This tells
1090 * us if `event' is using such a PMC.
1091 */
1093 {
1096 }
1100 {
1115 }
1116 }
1120 {
1133 }
1134 }
1136 /*
1137 * Since limited events don't respect the freeze conditions, we
1138 * have to read them immediately after freezing or unfreezing the
1139 * other events. We try to keep the values from the limited
1140 * events as consistent as possible by keeping the delay (in
1141 * cycles and instructions) between freezing/unfreezing and reading
1142 * the limited events as small and consistent as possible.
1143 * Therefore, if any limited events are in use, we read them
1144 * both, and always in the same order, to minimize variability,
1145 * and do it inside the same asm that writes MMCR0.
1146 */
1148 {
1154 }
1156 /*
1157 * Write MMCR0, then read PMC5 and PMC6 immediately.
1158 * To ensure we don't get a performance monitor interrupt
1159 * between writing MMCR0 and freezing/thawing the limited
1160 * events, we first write MMCR0 with the event overflow
1161 * interrupt enable bits turned off.
1162 */
1171 else
1174 /*
1175 * Write the full MMCR0 including the event overflow interrupt
1176 * enable bits, if necessary.
1177 */
1180 }
1182 /*
1183 * Disable all events to prevent PMU interrupts and to allow
1184 * events to be added or removed.
1185 */
1187 {
1197 /*
1198 * Check if we ever enabled the PMU on this cpu.
1199 */
1203 }
1205 /*
1206 * Set the 'freeze counters' bit, clear EBE/BHRBA/PMCC/PMAO/FC56
1207 */
1211 MMCR0_FC56);
1213 /*
1214 * The barrier is to make sure the mtspr has been
1215 * executed and the PMU has frozen the events etc.
1216 * before we return.
1217 */
1221 /*
1222 * Disable instruction sampling if it was enabled
1223 */
1228 }
1234 }
1237 }
1239 /*
1240 * Re-enable all events if disable == 0.
1241 * If we were previously disabled and events were added, then
1242 * put the new config on the PMU.
1243 */
1245 {
1251 s64 left;
1268 }
1272 /*
1273 * EBB requires an exclusive group and all events must have the EBB
1274 * flag set, or not set, so we can just check a single event. Also we
1275 * know we have at least one event.
1276 */
1279 /*
1280 * If we didn't change anything, or only removed events,
1281 * no need to recalculate MMCR* settings and reset the PMCs.
1282 * Just reenable the PMU with the current MMCR* settings
1283 * (possibly updated for removal of events).
1284 */
1289 }
1291 /*
1292 * Clear all MMCR settings and recompute them for the new set of events.
1293 */
1298 /* shouldn't ever get here */
1301 }
1304 /*
1305 * Add in MMCR0 freeze bits corresponding to the attr.exclude_*
1306 * bits for the first event. We have already checked that all
1307 * events have the same value for these bits as the first event.
1308 */
1316 }
1318 /*
1319 * Write the new configuration to MMCR* with the freeze
1320 * bit set and set the hardware events to their initial values.
1321 * Then unfreeze the events.
1322 */
1331 /*
1332 * Read off any pre-existing events that need to move
1333 * to another PMC.
1334 */
1341 }
1342 }
1344 /*
1345 * Initialize the PMCs for all the new and moved events.
1346 */
1358 }
1368 }
1370 }
1378 }
1382 out_enable:
1393 /*
1394 * Enable instruction sampling if necessary
1395 */
1399 }
1401 out:
1404 }
1409 {
1419 }
1428 }
1429 }
1431 }
1433 /*
1434 * Add a event to the PMU.
1435 * If all events are not already frozen, then we disable and
1436 * re-enable the PMU in order to get hw_perf_enable to do the
1437 * actual work of reconfiguring the PMU.
1438 */
1440 {
1449 /*
1450 * Add the event to the list (if there is room)
1451 * and check whether the total set is still feasible.
1452 */
1461 /*
1462 * This event may have been disabled/stopped in record_and_restart()
1463 * because we exceeded the ->event_limit. If re-starting the event,
1464 * clear the ->hw.state (STOPPED and UPTODATE flags), so the user
1465 * notification is re-enabled.
1466 */
1469 else
1472 /*
1473 * If group events scheduling transaction was started,
1474 * skip the schedulability test here, it will be performed
1475 * at commit time(->commit_txn) as a whole
1476 */
1486 nocheck:
1493 out:
1498 }
1500 /*
1501 * Workaround for POWER9 DD1 to use the Instruction Counter
1502 * register value for instruction counting
1503 */
1510 }
1512 /*
1513 * Remove a event from the PMU.
1514 */
1516 {
1533 }
1539 }
1542 }
1543 }
1551 }
1553 }
1555 /* disable exceptions if no events are running */
1557 }
1564 }
1566 /*
1567 * POWER-PMU does not support disabling individual counters, hence
1568 * program their cycle counter to their max value and ignore the interrupts.
1569 */
1572 {
1574 s64 left;
1601 }
1604 {
1623 }
1625 /*
1626 * Start group events scheduling transaction
1627 * Set the flag to make pmu::enable() not perform the
1628 * schedulability test, it will be performed at commit time
1629 *
1630 * We only support PERF_PMU_TXN_ADD transactions. Save the
1631 * transaction flags but otherwise ignore non-PERF_PMU_TXN_ADD
1632 * transactions.
1633 */
1635 {
1646 }
1648 /*
1649 * Stop group events scheduling transaction
1650 * Clear the flag and pmu::enable() will perform the
1651 * schedulability test.
1652 */
1654 {
1666 }
1668 /*
1669 * Commit group events scheduling transaction
1670 * Perform the group schedulability test as a whole
1671 * Return 0 if success
1672 */
1674 {
1687 }
1702 }
1704 /*
1705 * Return 1 if we might be able to put event on a limited PMC,
1706 * or 0 if not.
1707 * A event can only go on a limited PMC if it counts something
1708 * that a limited PMC can count, doesn't require interrupts, and
1709 * doesn't exclude any processor mode.
1710 */
1713 {
1726 /*
1727 * The requested event_id isn't on a limited PMC already;
1728 * see if any alternative code goes on a limited PMC.
1729 */
1737 }
1739 /*
1740 * Find an alternative event_id that goes on a normal PMC, if possible,
1741 * and return the event_id code, or 0 if there is no such alternative.
1742 * (Note: event_id code 0 is "don't count" on all machines.)
1743 */
1745 {
1754 }
1756 /* Number of perf_events counting hardware events */
1758 /* Used to avoid races in calling reserve/release_pmc_hardware */
1761 /*
1762 * Release the PMU if this is the last perf_event.
1763 */
1765 {
1771 }
1772 }
1774 /*
1775 * Translate a generic cache event_id config to a raw event_id code.
1776 */
1778 {
1785 /* unpack config */
1802 }
1805 {
1806 u64 ev;
1819 /* PMU has BHRB enabled */
1822 }
1841 }
1846 /*
1847 * If we are not running on a hypervisor, force the
1848 * exclude_hv bit to 0 so that we don't care what
1849 * the user set it to.
1850 */
1854 /*
1855 * If this is a per-task event, then we can use
1856 * PM_RUN_* events interchangeably with their non RUN_*
1857 * equivalents, e.g. PM_RUN_CYC instead of PM_CYC.
1858 * XXX we should check if the task is an idle task.
1859 */
1864 /*
1865 * If this machine has limited events, check whether this
1866 * event_id could go on a limited event.
1867 */
1872 /*
1873 * The requested event_id is on a limited PMC,
1874 * but we can't use a limited PMC; see if any
1875 * alternative goes on a normal PMC.
1876 */
1880 }
1881 }
1883 /* Extra checks for EBB */
1888 /*
1889 * If this is in a group, check if it can go on with all the
1890 * other hardware events in the group. We assume the event
1891 * hasn't been linked into its leader's sibling list at this point.
1892 */
1899 }
1916 }
1917 }
1928 /*
1929 * For EBB events we just context switch the PMC value, we don't do any
1930 * of the sample_period logic. We use hw.prev_count for this.
1931 */
1935 /*
1936 * See if we need to reserve the PMU.
1937 * If no events are currently in use, then we have to take a
1938 * mutex to ensure that we don't race with another task doing
1939 * reserve_pmc_hardware or release_pmc_hardware.
1940 */
1947 else
1950 }
1954 }
1957 {
1959 }
1963 {
1969 }
1985 };
1987 /*
1988 * A counter has overflowed; update its count and record
1989 * things if requested. Note that interrupts are hard-disabled
1990 * here so there is no possibility of being interrupted.
1991 */
1994 {
2002 }
2004 /* we don't have to worry about interrupts here */
2009 /*
2010 * See if the total period for this event has expired,
2011 * and update for the next period.
2012 */
2016 left++;
2024 }
2027 }
2034 /*
2035 * Finally record data if requested.
2036 */
2051 }
2063 }
2064 }
2066 /*
2067 * Called from generic code to get the misc flags (i.e. processor mode)
2068 * for an event_id.
2069 */
2071 {
2077 PERF_RECORD_MISC_KERNEL;
2078 }
2080 /*
2081 * Called from generic code to get the instruction pointer
2082 * for an event_id.
2083 */
2085 {
2092 else
2094 }
2097 {
2098 /*
2099 * Events on POWER7 can roll back if a speculative event doesn't
2100 * eventually complete. Unfortunately in some rare cases they will
2101 * raise a performance monitor exception. We need to catch this to
2102 * ensure we reset the PMC. In all cases the PMC will be 256 or less
2103 * cycles from overflow.
2104 *
2105 * We only do this if the first pass fails to find any overflowing
2106 * PMCs because a user might set a period of less than 256 and we
2107 * don't want to mistakenly reset them.
2108 */
2113 }
2116 {
2121 }
2123 /*
2124 * Performance monitor interrupt stuff
2125 */
2127 {
2144 else
2147 /* Read all the PMCs since we'll need them a bunch of times */
2151 /* Try to find what caused the IRQ */
2158 /*
2159 * We've found one that's overflowed. For active
2160 * counters we need to log this. For inactive
2161 * counters, we need to reset it anyway
2162 */
2171 }
2172 }
2174 /* reset non active counters that have overflowed */
2176 }
2178 /* check active counters for special buggy p7 overflow */
2184 /* event has overflowed in a buggy way*/
2188 regs);
2189 }
2190 }
2191 }
2195 /*
2196 * Reset MMCR0 to its normal value. This will set PMXE and
2197 * clear FC (freeze counters) and PMAO (perf mon alert occurred)
2198 * and thus allow interrupts to occur again.
2199 * XXX might want to use MSR.PM to keep the events frozen until
2200 * we get back out of this interrupt.
2201 */
2206 else
2208 }
2211 {
2217 }
2219 }
2222 {
2232 #ifdef MSR_HV
2233 /*
2234 * Use FCHV to ignore kernel events if MSR.HV is set.
2235 */
2244 }