linux_dsm_epyc7002/arch/powerpc/perf/power8-pmu.c

845 lines
24 KiB
C
Raw Normal View History

/*
* Performance counter support for POWER8 processors.
*
* Copyright 2009 Paul Mackerras, IBM Corporation.
* Copyright 2013 Michael Ellerman, IBM Corporation.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*/
#define pr_fmt(fmt) "power8-pmu: " fmt
#include <linux/kernel.h>
#include <linux/perf_event.h>
#include <asm/firmware.h>
powerpc/perf: Add per-event excludes on Power8 Power8 has a new register (MMCR2), which contains individual freeze bits for each counter. This is an improvement on previous chips as it means we can have multiple events on the PMU at the same time with different exclude_{user,kernel,hv} settings. Previously we had to ensure all events on the PMU had the same exclude settings. The core of the patch is fairly simple. We use the 207S feature flag to indicate that the PMU backend supports per-event excludes, if it's set we skip the generic logic that enforces the equality of excludes between events. We also use that flag to skip setting the freeze bits in MMCR0, the PMU backend is expected to have handled setting them in MMCR2. The complication arises with EBB. The FCxP bits in MMCR2 are accessible R/W to a task using EBB. Which means a task using EBB will be able to see that we are using MMCR2 for freezing, whereas the old logic which used MMCR0 is not user visible. The task can not see or affect exclude_kernel & exclude_hv, so we only need to consider exclude_user. The table below summarises the behaviour both before and after this commit is applied: exclude_user true false ------------------------------------ | User visible | N N Before | Can freeze | Y Y | Can unfreeze | N Y ------------------------------------ | User visible | Y Y After | Can freeze | Y Y | Can unfreeze | Y/N Y ------------------------------------ So firstly I assert that the simple visibility of the exclude_user setting in MMCR2 is a non-issue. The event belongs to the task, and was most likely created by the task. So the exclude_user setting is not privileged information in any way. Secondly, the behaviour in the exclude_user = false case is unchanged. This is important as it is the case that is actually useful, ie. the event is created with no exclude setting and the task uses MMCR2 to implement exclusion manually. For exclude_user = true there is no meaningful change to freezing the event. Previously the task could use MMCR2 to freeze the event, though it was already frozen with MMCR0. With the new code the task can use MMCR2 to freeze the event, though it was already frozen with MMCR2. The only real change is when exclude_user = true and the task tries to use MMCR2 to unfreeze the event. Previously this had no effect, because the event was already frozen in MMCR0. With the new code the task can unfreeze the event in MMCR2, but at some indeterminate time in the future the kernel will overwrite its setting and refreeze the event. Therefore my final assertion is that any task using exclude_user = true and also fiddling with MMCR2 was deeply confused before this change, and remains so after it. Signed-off-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2014-07-23 18:12:38 +07:00
#include <asm/cputable.h>
/*
* Some power8 event codes.
*/
#define PM_CYC 0x0001e
#define PM_GCT_NOSLOT_CYC 0x100f8
#define PM_CMPLU_STALL 0x4000a
#define PM_INST_CMPL 0x00002
#define PM_BRU_FIN 0x10068
#define PM_BR_MPRED_CMPL 0x400f6
/* All L1 D cache load references counted at finish, gated by reject */
#define PM_LD_REF_L1 0x100ee
/* Load Missed L1 */
#define PM_LD_MISS_L1 0x3e054
/* Store Missed L1 */
#define PM_ST_MISS_L1 0x300f0
/* L1 cache data prefetches */
#define PM_L1_PREF 0x0d8b8
/* Instruction fetches from L1 */
#define PM_INST_FROM_L1 0x04080
/* Demand iCache Miss */
#define PM_L1_ICACHE_MISS 0x200fd
/* Instruction Demand sectors wriittent into IL1 */
#define PM_L1_DEMAND_WRITE 0x0408c
/* Instruction prefetch written into IL1 */
#define PM_IC_PREF_WRITE 0x0408e
/* The data cache was reloaded from local core's L3 due to a demand load */
#define PM_DATA_FROM_L3 0x4c042
/* Demand LD - L3 Miss (not L2 hit and not L3 hit) */
#define PM_DATA_FROM_L3MISS 0x300fe
/* All successful D-side store dispatches for this thread */
#define PM_L2_ST 0x17080
/* All successful D-side store dispatches for this thread that were L2 Miss */
#define PM_L2_ST_MISS 0x17082
/* Total HW L3 prefetches(Load+store) */
#define PM_L3_PREF_ALL 0x4e052
/* Data PTEG reload */
#define PM_DTLB_MISS 0x300fc
/* ITLB Reloaded */
#define PM_ITLB_MISS 0x400fc
/*
* Raw event encoding for POWER8:
*
* 60 56 52 48 44 40 36 32
* | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - |
* | | [ ] [ thresh_cmp ] [ thresh_ctl ]
* | | | |
* | | *- IFM (Linux) thresh start/stop OR FAB match -*
* | *- BHRB (Linux)
* *- EBB (Linux)
*
* 28 24 20 16 12 8 4 0
* | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - |
* [ ] [ sample ] [cache] [ pmc ] [unit ] c m [ pmcxsel ]
* | | | | |
* | | | | *- mark
* | | *- L1/L2/L3 cache_sel |
* | | |
* | *- sampling mode for marked events *- combine
* |
* *- thresh_sel
*
* Below uses IBM bit numbering.
*
* MMCR1[x:y] = unit (PMCxUNIT)
* MMCR1[x] = combine (PMCxCOMB)
*
* if pmc == 3 and unit == 0 and pmcxsel[0:6] == 0b0101011
* # PM_MRK_FAB_RSP_MATCH
* MMCR1[20:27] = thresh_ctl (FAB_CRESP_MATCH / FAB_TYPE_MATCH)
* else if pmc == 4 and unit == 0xf and pmcxsel[0:6] == 0b0101001
* # PM_MRK_FAB_RSP_MATCH_CYC
* MMCR1[20:27] = thresh_ctl (FAB_CRESP_MATCH / FAB_TYPE_MATCH)
* else
* MMCRA[48:55] = thresh_ctl (THRESH START/END)
*
* if thresh_sel:
* MMCRA[45:47] = thresh_sel
*
* if thresh_cmp:
* MMCRA[22:24] = thresh_cmp[0:2]
* MMCRA[25:31] = thresh_cmp[3:9]
*
* if unit == 6 or unit == 7
* MMCRC[53:55] = cache_sel[1:3] (L2EVENT_SEL)
* else if unit == 8 or unit == 9:
* if cache_sel[0] == 0: # L3 bank
* MMCRC[47:49] = cache_sel[1:3] (L3EVENT_SEL0)
* else if cache_sel[0] == 1:
* MMCRC[50:51] = cache_sel[2:3] (L3EVENT_SEL1)
* else if cache_sel[1]: # L1 event
* MMCR1[16] = cache_sel[2]
 * MMCR1[17] = cache_sel[3]
*
* if mark:
* MMCRA[63] = 1 (SAMPLE_ENABLE)
* MMCRA[57:59] = sample[0:2] (RAND_SAMP_ELIG)
 * MMCRA[61:62] = sample[3:4] (RAND_SAMP_MODE)
*
* if EBB and BHRB:
* MMCRA[32:33] = IFM
*
*/
#define EVENT_EBB_MASK 1ull
#define EVENT_EBB_SHIFT PERF_EVENT_CONFIG_EBB_SHIFT
#define EVENT_BHRB_MASK 1ull
#define EVENT_BHRB_SHIFT 62
#define EVENT_WANTS_BHRB (EVENT_BHRB_MASK << EVENT_BHRB_SHIFT)
#define EVENT_IFM_MASK 3ull
#define EVENT_IFM_SHIFT 60
#define EVENT_THR_CMP_SHIFT 40 /* Threshold CMP value */
#define EVENT_THR_CMP_MASK 0x3ff
#define EVENT_THR_CTL_SHIFT 32 /* Threshold control value (start/stop) */
#define EVENT_THR_CTL_MASK 0xffull
#define EVENT_THR_SEL_SHIFT 29 /* Threshold select value */
#define EVENT_THR_SEL_MASK 0x7
#define EVENT_THRESH_SHIFT 29 /* All threshold bits */
#define EVENT_THRESH_MASK 0x1fffffull
#define EVENT_SAMPLE_SHIFT 24 /* Sampling mode & eligibility */
#define EVENT_SAMPLE_MASK 0x1f
#define EVENT_CACHE_SEL_SHIFT 20 /* L2/L3 cache select */
#define EVENT_CACHE_SEL_MASK 0xf
#define EVENT_IS_L1 (4 << EVENT_CACHE_SEL_SHIFT)
#define EVENT_PMC_SHIFT 16 /* PMC number (1-based) */
#define EVENT_PMC_MASK 0xf
#define EVENT_UNIT_SHIFT 12 /* Unit */
#define EVENT_UNIT_MASK 0xf
#define EVENT_COMBINE_SHIFT 11 /* Combine bit */
#define EVENT_COMBINE_MASK 0x1
#define EVENT_MARKED_SHIFT 8 /* Marked bit */
#define EVENT_MARKED_MASK 0x1
#define EVENT_IS_MARKED (EVENT_MARKED_MASK << EVENT_MARKED_SHIFT)
#define EVENT_PSEL_MASK 0xff /* PMCxSEL value */
/* Bits defined by Linux */
#define EVENT_LINUX_MASK \
((EVENT_EBB_MASK << EVENT_EBB_SHIFT) | \
(EVENT_BHRB_MASK << EVENT_BHRB_SHIFT) | \
(EVENT_IFM_MASK << EVENT_IFM_SHIFT))
#define EVENT_VALID_MASK \
((EVENT_THRESH_MASK << EVENT_THRESH_SHIFT) | \
(EVENT_SAMPLE_MASK << EVENT_SAMPLE_SHIFT) | \
(EVENT_CACHE_SEL_MASK << EVENT_CACHE_SEL_SHIFT) | \
(EVENT_PMC_MASK << EVENT_PMC_SHIFT) | \
(EVENT_UNIT_MASK << EVENT_UNIT_SHIFT) | \
(EVENT_COMBINE_MASK << EVENT_COMBINE_SHIFT) | \
(EVENT_MARKED_MASK << EVENT_MARKED_SHIFT) | \
EVENT_LINUX_MASK | \
EVENT_PSEL_MASK)
/* MMCRA IFM bits - POWER8 */
#define POWER8_MMCRA_IFM1 0x0000000040000000UL
#define POWER8_MMCRA_IFM2 0x0000000080000000UL
#define POWER8_MMCRA_IFM3 0x00000000C0000000UL
#define ONLY_PLM \
(PERF_SAMPLE_BRANCH_USER |\
PERF_SAMPLE_BRANCH_KERNEL |\
PERF_SAMPLE_BRANCH_HV)
/*
* Layout of constraint bits:
*
* 60 56 52 48 44 40 36 32
* | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - |
* [ fab_match ] [ thresh_cmp ] [ thresh_ctl ] [ ]
* |
* thresh_sel -*
*
* 28 24 20 16 12 8 4 0
* | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - | - - - - |
* [ ] | [ ] [ sample ] [ ] [6] [5] [4] [3] [2] [1]
* | | | |
* BHRB IFM -* | | | Count of events for each PMC.
* EBB -* | | p1, p2, p3, p4, p5, p6.
* L1 I/D qualifier -* |
* nc - number of counters -*
*
* The PMC fields P1..P6, and NC, are adder fields. As we accumulate constraints
* we want the low bit of each field to be added to any existing value.
*
* Everything else is a value field.
*/
#define CNST_FAB_MATCH_VAL(v) (((v) & EVENT_THR_CTL_MASK) << 56)
#define CNST_FAB_MATCH_MASK CNST_FAB_MATCH_VAL(EVENT_THR_CTL_MASK)
/* We just throw all the threshold bits into the constraint */
#define CNST_THRESH_VAL(v) (((v) & EVENT_THRESH_MASK) << 32)
#define CNST_THRESH_MASK CNST_THRESH_VAL(EVENT_THRESH_MASK)
#define CNST_EBB_VAL(v) (((v) & EVENT_EBB_MASK) << 24)
#define CNST_EBB_MASK CNST_EBB_VAL(EVENT_EBB_MASK)
#define CNST_IFM_VAL(v) (((v) & EVENT_IFM_MASK) << 25)
#define CNST_IFM_MASK CNST_IFM_VAL(EVENT_IFM_MASK)
#define CNST_L1_QUAL_VAL(v) (((v) & 3) << 22)
#define CNST_L1_QUAL_MASK CNST_L1_QUAL_VAL(3)
#define CNST_SAMPLE_VAL(v) (((v) & EVENT_SAMPLE_MASK) << 16)
#define CNST_SAMPLE_MASK CNST_SAMPLE_VAL(EVENT_SAMPLE_MASK)
/*
* For NC we are counting up to 4 events. This requires three bits, and we need
* the fifth event to overflow and set the 4th bit. To achieve that we bias the
* fields by 3 in test_adder.
*/
#define CNST_NC_SHIFT 12
#define CNST_NC_VAL (1 << CNST_NC_SHIFT)
#define CNST_NC_MASK (8 << CNST_NC_SHIFT)
#define POWER8_TEST_ADDER (3 << CNST_NC_SHIFT)
/*
* For the per-PMC fields we have two bits. The low bit is added, so if two
* events ask for the same PMC the sum will overflow, setting the high bit,
* indicating an error. So our mask sets the high bit.
*/
#define CNST_PMC_SHIFT(pmc) ((pmc - 1) * 2)
#define CNST_PMC_VAL(pmc) (1 << CNST_PMC_SHIFT(pmc))
#define CNST_PMC_MASK(pmc) (2 << CNST_PMC_SHIFT(pmc))
/* Our add_fields is defined as: */
#define POWER8_ADD_FIELDS \
CNST_PMC_VAL(1) | CNST_PMC_VAL(2) | CNST_PMC_VAL(3) | \
CNST_PMC_VAL(4) | CNST_PMC_VAL(5) | CNST_PMC_VAL(6) | CNST_NC_VAL
/* Bits in MMCR1 for POWER8 */
#define MMCR1_UNIT_SHIFT(pmc) (60 - (4 * ((pmc) - 1)))
#define MMCR1_COMBINE_SHIFT(pmc) (35 - ((pmc) - 1))
#define MMCR1_PMCSEL_SHIFT(pmc) (24 - (((pmc) - 1)) * 8)
#define MMCR1_FAB_SHIFT 36
#define MMCR1_DC_QUAL_SHIFT 47
#define MMCR1_IC_QUAL_SHIFT 46
/* Bits in MMCRA for POWER8 */
#define MMCRA_SAMP_MODE_SHIFT 1
#define MMCRA_SAMP_ELIG_SHIFT 4
#define MMCRA_THR_CTL_SHIFT 8
#define MMCRA_THR_SEL_SHIFT 16
#define MMCRA_THR_CMP_SHIFT 32
#define MMCRA_SDAR_MODE_TLB (1ull << 42)
#define MMCRA_IFM_SHIFT 30
powerpc/perf: Add per-event excludes on Power8 Power8 has a new register (MMCR2), which contains individual freeze bits for each counter. This is an improvement on previous chips as it means we can have multiple events on the PMU at the same time with different exclude_{user,kernel,hv} settings. Previously we had to ensure all events on the PMU had the same exclude settings. The core of the patch is fairly simple. We use the 207S feature flag to indicate that the PMU backend supports per-event excludes, if it's set we skip the generic logic that enforces the equality of excludes between events. We also use that flag to skip setting the freeze bits in MMCR0, the PMU backend is expected to have handled setting them in MMCR2. The complication arises with EBB. The FCxP bits in MMCR2 are accessible R/W to a task using EBB. Which means a task using EBB will be able to see that we are using MMCR2 for freezing, whereas the old logic which used MMCR0 is not user visible. The task can not see or affect exclude_kernel & exclude_hv, so we only need to consider exclude_user. The table below summarises the behaviour both before and after this commit is applied: exclude_user true false ------------------------------------ | User visible | N N Before | Can freeze | Y Y | Can unfreeze | N Y ------------------------------------ | User visible | Y Y After | Can freeze | Y Y | Can unfreeze | Y/N Y ------------------------------------ So firstly I assert that the simple visibility of the exclude_user setting in MMCR2 is a non-issue. The event belongs to the task, and was most likely created by the task. So the exclude_user setting is not privileged information in any way. Secondly, the behaviour in the exclude_user = false case is unchanged. This is important as it is the case that is actually useful, ie. the event is created with no exclude setting and the task uses MMCR2 to implement exclusion manually. For exclude_user = true there is no meaningful change to freezing the event. Previously the task could use MMCR2 to freeze the event, though it was already frozen with MMCR0. With the new code the task can use MMCR2 to freeze the event, though it was already frozen with MMCR2. The only real change is when exclude_user = true and the task tries to use MMCR2 to unfreeze the event. Previously this had no effect, because the event was already frozen in MMCR0. With the new code the task can unfreeze the event in MMCR2, but at some indeterminate time in the future the kernel will overwrite its setting and refreeze the event. Therefore my final assertion is that any task using exclude_user = true and also fiddling with MMCR2 was deeply confused before this change, and remains so after it. Signed-off-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2014-07-23 18:12:38 +07:00
/* Bits in MMCR2 for POWER8 */
#define MMCR2_FCS(pmc) (1ull << (63 - (((pmc) - 1) * 9)))
#define MMCR2_FCP(pmc) (1ull << (62 - (((pmc) - 1) * 9)))
#define MMCR2_FCH(pmc) (1ull << (57 - (((pmc) - 1) * 9)))
static inline bool event_is_fab_match(u64 event)
{
/* Only check pmc, unit and pmcxsel, ignore the edge bit (0) */
event &= 0xff0fe;
/* PM_MRK_FAB_RSP_MATCH & PM_MRK_FAB_RSP_MATCH_CYC */
return (event == 0x30056 || event == 0x4f052);
}
static int power8_get_constraint(u64 event, unsigned long *maskp, unsigned long *valp)
{
unsigned int unit, pmc, cache, ebb;
unsigned long mask, value;
mask = value = 0;
if (event & ~EVENT_VALID_MASK)
return -1;
pmc = (event >> EVENT_PMC_SHIFT) & EVENT_PMC_MASK;
unit = (event >> EVENT_UNIT_SHIFT) & EVENT_UNIT_MASK;
cache = (event >> EVENT_CACHE_SEL_SHIFT) & EVENT_CACHE_SEL_MASK;
ebb = (event >> EVENT_EBB_SHIFT) & EVENT_EBB_MASK;
if (pmc) {
u64 base_event;
if (pmc > 6)
return -1;
/* Ignore Linux defined bits when checking event below */
base_event = event & ~EVENT_LINUX_MASK;
if (pmc >= 5 && base_event != 0x500fa && base_event != 0x600f4)
return -1;
mask |= CNST_PMC_MASK(pmc);
value |= CNST_PMC_VAL(pmc);
}
if (pmc <= 4) {
/*
* Add to number of counters in use. Note this includes events with
* a PMC of 0 - they still need a PMC, it's just assigned later.
* Don't count events on PMC 5 & 6, there is only one valid event
* on each of those counters, and they are handled above.
*/
mask |= CNST_NC_MASK;
value |= CNST_NC_VAL;
}
if (unit >= 6 && unit <= 9) {
/*
* L2/L3 events contain a cache selector field, which is
* supposed to be programmed into MMCRC. However MMCRC is only
* HV writable, and there is no API for guest kernels to modify
* it. The solution is for the hypervisor to initialise the
* field to zeroes, and for us to only ever allow events that
* have a cache selector of zero. The bank selector (bit 3) is
* irrelevant, as long as the rest of the value is 0.
*/
if (cache & 0x7)
return -1;
} else if (event & EVENT_IS_L1) {
mask |= CNST_L1_QUAL_MASK;
value |= CNST_L1_QUAL_VAL(cache);
}
if (event & EVENT_IS_MARKED) {
mask |= CNST_SAMPLE_MASK;
value |= CNST_SAMPLE_VAL(event >> EVENT_SAMPLE_SHIFT);
}
/*
* Special case for PM_MRK_FAB_RSP_MATCH and PM_MRK_FAB_RSP_MATCH_CYC,
* the threshold control bits are used for the match value.
*/
if (event_is_fab_match(event)) {
mask |= CNST_FAB_MATCH_MASK;
value |= CNST_FAB_MATCH_VAL(event >> EVENT_THR_CTL_SHIFT);
} else {
/*
* Check the mantissa upper two bits are not zero, unless the
* exponent is also zero. See the THRESH_CMP_MANTISSA doc.
*/
unsigned int cmp, exp;
cmp = (event >> EVENT_THR_CMP_SHIFT) & EVENT_THR_CMP_MASK;
exp = cmp >> 7;
if (exp && (cmp & 0x60) == 0)
return -1;
mask |= CNST_THRESH_MASK;
value |= CNST_THRESH_VAL(event >> EVENT_THRESH_SHIFT);
}
if (!pmc && ebb)
/* EBB events must specify the PMC */
return -1;
if (event & EVENT_WANTS_BHRB) {
if (!ebb)
/* Only EBB events can request BHRB */
return -1;
mask |= CNST_IFM_MASK;
value |= CNST_IFM_VAL(event >> EVENT_IFM_SHIFT);
}
/*
* All events must agree on EBB, either all request it or none.
* EBB events are pinned & exclusive, so this should never actually
* hit, but we leave it as a fallback in case.
*/
mask |= CNST_EBB_VAL(ebb);
value |= CNST_EBB_MASK;
*maskp = mask;
*valp = value;
return 0;
}
static int power8_compute_mmcr(u64 event[], int n_ev,
unsigned int hwc[], unsigned long mmcr[],
struct perf_event *pevents[])
{
powerpc/perf: Add per-event excludes on Power8 Power8 has a new register (MMCR2), which contains individual freeze bits for each counter. This is an improvement on previous chips as it means we can have multiple events on the PMU at the same time with different exclude_{user,kernel,hv} settings. Previously we had to ensure all events on the PMU had the same exclude settings. The core of the patch is fairly simple. We use the 207S feature flag to indicate that the PMU backend supports per-event excludes, if it's set we skip the generic logic that enforces the equality of excludes between events. We also use that flag to skip setting the freeze bits in MMCR0, the PMU backend is expected to have handled setting them in MMCR2. The complication arises with EBB. The FCxP bits in MMCR2 are accessible R/W to a task using EBB. Which means a task using EBB will be able to see that we are using MMCR2 for freezing, whereas the old logic which used MMCR0 is not user visible. The task can not see or affect exclude_kernel & exclude_hv, so we only need to consider exclude_user. The table below summarises the behaviour both before and after this commit is applied: exclude_user true false ------------------------------------ | User visible | N N Before | Can freeze | Y Y | Can unfreeze | N Y ------------------------------------ | User visible | Y Y After | Can freeze | Y Y | Can unfreeze | Y/N Y ------------------------------------ So firstly I assert that the simple visibility of the exclude_user setting in MMCR2 is a non-issue. The event belongs to the task, and was most likely created by the task. So the exclude_user setting is not privileged information in any way. Secondly, the behaviour in the exclude_user = false case is unchanged. This is important as it is the case that is actually useful, ie. the event is created with no exclude setting and the task uses MMCR2 to implement exclusion manually. For exclude_user = true there is no meaningful change to freezing the event. Previously the task could use MMCR2 to freeze the event, though it was already frozen with MMCR0. With the new code the task can use MMCR2 to freeze the event, though it was already frozen with MMCR2. The only real change is when exclude_user = true and the task tries to use MMCR2 to unfreeze the event. Previously this had no effect, because the event was already frozen in MMCR0. With the new code the task can unfreeze the event in MMCR2, but at some indeterminate time in the future the kernel will overwrite its setting and refreeze the event. Therefore my final assertion is that any task using exclude_user = true and also fiddling with MMCR2 was deeply confused before this change, and remains so after it. Signed-off-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2014-07-23 18:12:38 +07:00
unsigned long mmcra, mmcr1, mmcr2, unit, combine, psel, cache, val;
unsigned int pmc, pmc_inuse;
int i;
pmc_inuse = 0;
/* First pass to count resource use */
for (i = 0; i < n_ev; ++i) {
pmc = (event[i] >> EVENT_PMC_SHIFT) & EVENT_PMC_MASK;
if (pmc)
pmc_inuse |= 1 << pmc;
}
/* In continous sampling mode, update SDAR on TLB miss */
mmcra = MMCRA_SDAR_MODE_TLB;
powerpc/perf: Add per-event excludes on Power8 Power8 has a new register (MMCR2), which contains individual freeze bits for each counter. This is an improvement on previous chips as it means we can have multiple events on the PMU at the same time with different exclude_{user,kernel,hv} settings. Previously we had to ensure all events on the PMU had the same exclude settings. The core of the patch is fairly simple. We use the 207S feature flag to indicate that the PMU backend supports per-event excludes, if it's set we skip the generic logic that enforces the equality of excludes between events. We also use that flag to skip setting the freeze bits in MMCR0, the PMU backend is expected to have handled setting them in MMCR2. The complication arises with EBB. The FCxP bits in MMCR2 are accessible R/W to a task using EBB. Which means a task using EBB will be able to see that we are using MMCR2 for freezing, whereas the old logic which used MMCR0 is not user visible. The task can not see or affect exclude_kernel & exclude_hv, so we only need to consider exclude_user. The table below summarises the behaviour both before and after this commit is applied: exclude_user true false ------------------------------------ | User visible | N N Before | Can freeze | Y Y | Can unfreeze | N Y ------------------------------------ | User visible | Y Y After | Can freeze | Y Y | Can unfreeze | Y/N Y ------------------------------------ So firstly I assert that the simple visibility of the exclude_user setting in MMCR2 is a non-issue. The event belongs to the task, and was most likely created by the task. So the exclude_user setting is not privileged information in any way. Secondly, the behaviour in the exclude_user = false case is unchanged. This is important as it is the case that is actually useful, ie. the event is created with no exclude setting and the task uses MMCR2 to implement exclusion manually. For exclude_user = true there is no meaningful change to freezing the event. Previously the task could use MMCR2 to freeze the event, though it was already frozen with MMCR0. With the new code the task can use MMCR2 to freeze the event, though it was already frozen with MMCR2. The only real change is when exclude_user = true and the task tries to use MMCR2 to unfreeze the event. Previously this had no effect, because the event was already frozen in MMCR0. With the new code the task can unfreeze the event in MMCR2, but at some indeterminate time in the future the kernel will overwrite its setting and refreeze the event. Therefore my final assertion is that any task using exclude_user = true and also fiddling with MMCR2 was deeply confused before this change, and remains so after it. Signed-off-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2014-07-23 18:12:38 +07:00
mmcr1 = mmcr2 = 0;
/* Second pass: assign PMCs, set all MMCR1 fields */
for (i = 0; i < n_ev; ++i) {
pmc = (event[i] >> EVENT_PMC_SHIFT) & EVENT_PMC_MASK;
unit = (event[i] >> EVENT_UNIT_SHIFT) & EVENT_UNIT_MASK;
combine = (event[i] >> EVENT_COMBINE_SHIFT) & EVENT_COMBINE_MASK;
psel = event[i] & EVENT_PSEL_MASK;
if (!pmc) {
for (pmc = 1; pmc <= 4; ++pmc) {
if (!(pmc_inuse & (1 << pmc)))
break;
}
pmc_inuse |= 1 << pmc;
}
if (pmc <= 4) {
mmcr1 |= unit << MMCR1_UNIT_SHIFT(pmc);
mmcr1 |= combine << MMCR1_COMBINE_SHIFT(pmc);
mmcr1 |= psel << MMCR1_PMCSEL_SHIFT(pmc);
}
if (event[i] & EVENT_IS_L1) {
cache = event[i] >> EVENT_CACHE_SEL_SHIFT;
mmcr1 |= (cache & 1) << MMCR1_IC_QUAL_SHIFT;
cache >>= 1;
mmcr1 |= (cache & 1) << MMCR1_DC_QUAL_SHIFT;
}
if (event[i] & EVENT_IS_MARKED) {
mmcra |= MMCRA_SAMPLE_ENABLE;
val = (event[i] >> EVENT_SAMPLE_SHIFT) & EVENT_SAMPLE_MASK;
if (val) {
mmcra |= (val & 3) << MMCRA_SAMP_MODE_SHIFT;
mmcra |= (val >> 2) << MMCRA_SAMP_ELIG_SHIFT;
}
}
/*
* PM_MRK_FAB_RSP_MATCH and PM_MRK_FAB_RSP_MATCH_CYC,
* the threshold bits are used for the match value.
*/
if (event_is_fab_match(event[i])) {
mmcr1 |= ((event[i] >> EVENT_THR_CTL_SHIFT) &
EVENT_THR_CTL_MASK) << MMCR1_FAB_SHIFT;
} else {
val = (event[i] >> EVENT_THR_CTL_SHIFT) & EVENT_THR_CTL_MASK;
mmcra |= val << MMCRA_THR_CTL_SHIFT;
val = (event[i] >> EVENT_THR_SEL_SHIFT) & EVENT_THR_SEL_MASK;
mmcra |= val << MMCRA_THR_SEL_SHIFT;
val = (event[i] >> EVENT_THR_CMP_SHIFT) & EVENT_THR_CMP_MASK;
mmcra |= val << MMCRA_THR_CMP_SHIFT;
}
if (event[i] & EVENT_WANTS_BHRB) {
val = (event[i] >> EVENT_IFM_SHIFT) & EVENT_IFM_MASK;
mmcra |= val << MMCRA_IFM_SHIFT;
}
powerpc/perf: Add per-event excludes on Power8 Power8 has a new register (MMCR2), which contains individual freeze bits for each counter. This is an improvement on previous chips as it means we can have multiple events on the PMU at the same time with different exclude_{user,kernel,hv} settings. Previously we had to ensure all events on the PMU had the same exclude settings. The core of the patch is fairly simple. We use the 207S feature flag to indicate that the PMU backend supports per-event excludes, if it's set we skip the generic logic that enforces the equality of excludes between events. We also use that flag to skip setting the freeze bits in MMCR0, the PMU backend is expected to have handled setting them in MMCR2. The complication arises with EBB. The FCxP bits in MMCR2 are accessible R/W to a task using EBB. Which means a task using EBB will be able to see that we are using MMCR2 for freezing, whereas the old logic which used MMCR0 is not user visible. The task can not see or affect exclude_kernel & exclude_hv, so we only need to consider exclude_user. The table below summarises the behaviour both before and after this commit is applied: exclude_user true false ------------------------------------ | User visible | N N Before | Can freeze | Y Y | Can unfreeze | N Y ------------------------------------ | User visible | Y Y After | Can freeze | Y Y | Can unfreeze | Y/N Y ------------------------------------ So firstly I assert that the simple visibility of the exclude_user setting in MMCR2 is a non-issue. The event belongs to the task, and was most likely created by the task. So the exclude_user setting is not privileged information in any way. Secondly, the behaviour in the exclude_user = false case is unchanged. This is important as it is the case that is actually useful, ie. the event is created with no exclude setting and the task uses MMCR2 to implement exclusion manually. For exclude_user = true there is no meaningful change to freezing the event. Previously the task could use MMCR2 to freeze the event, though it was already frozen with MMCR0. With the new code the task can use MMCR2 to freeze the event, though it was already frozen with MMCR2. The only real change is when exclude_user = true and the task tries to use MMCR2 to unfreeze the event. Previously this had no effect, because the event was already frozen in MMCR0. With the new code the task can unfreeze the event in MMCR2, but at some indeterminate time in the future the kernel will overwrite its setting and refreeze the event. Therefore my final assertion is that any task using exclude_user = true and also fiddling with MMCR2 was deeply confused before this change, and remains so after it. Signed-off-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2014-07-23 18:12:38 +07:00
if (pevents[i]->attr.exclude_user)
mmcr2 |= MMCR2_FCP(pmc);
if (pevents[i]->attr.exclude_hv)
mmcr2 |= MMCR2_FCH(pmc);
if (pevents[i]->attr.exclude_kernel) {
if (cpu_has_feature(CPU_FTR_HVMODE))
mmcr2 |= MMCR2_FCH(pmc);
else
mmcr2 |= MMCR2_FCS(pmc);
}
hwc[i] = pmc - 1;
}
/* Return MMCRx values */
mmcr[0] = 0;
/* pmc_inuse is 1-based */
if (pmc_inuse & 2)
mmcr[0] = MMCR0_PMC1CE;
if (pmc_inuse & 0x7c)
mmcr[0] |= MMCR0_PMCjCE;
/* If we're not using PMC 5 or 6, freeze them */
if (!(pmc_inuse & 0x60))
mmcr[0] |= MMCR0_FC56;
mmcr[1] = mmcr1;
mmcr[2] = mmcra;
powerpc/perf: Add per-event excludes on Power8 Power8 has a new register (MMCR2), which contains individual freeze bits for each counter. This is an improvement on previous chips as it means we can have multiple events on the PMU at the same time with different exclude_{user,kernel,hv} settings. Previously we had to ensure all events on the PMU had the same exclude settings. The core of the patch is fairly simple. We use the 207S feature flag to indicate that the PMU backend supports per-event excludes, if it's set we skip the generic logic that enforces the equality of excludes between events. We also use that flag to skip setting the freeze bits in MMCR0, the PMU backend is expected to have handled setting them in MMCR2. The complication arises with EBB. The FCxP bits in MMCR2 are accessible R/W to a task using EBB. Which means a task using EBB will be able to see that we are using MMCR2 for freezing, whereas the old logic which used MMCR0 is not user visible. The task can not see or affect exclude_kernel & exclude_hv, so we only need to consider exclude_user. The table below summarises the behaviour both before and after this commit is applied: exclude_user true false ------------------------------------ | User visible | N N Before | Can freeze | Y Y | Can unfreeze | N Y ------------------------------------ | User visible | Y Y After | Can freeze | Y Y | Can unfreeze | Y/N Y ------------------------------------ So firstly I assert that the simple visibility of the exclude_user setting in MMCR2 is a non-issue. The event belongs to the task, and was most likely created by the task. So the exclude_user setting is not privileged information in any way. Secondly, the behaviour in the exclude_user = false case is unchanged. This is important as it is the case that is actually useful, ie. the event is created with no exclude setting and the task uses MMCR2 to implement exclusion manually. For exclude_user = true there is no meaningful change to freezing the event. Previously the task could use MMCR2 to freeze the event, though it was already frozen with MMCR0. With the new code the task can use MMCR2 to freeze the event, though it was already frozen with MMCR2. The only real change is when exclude_user = true and the task tries to use MMCR2 to unfreeze the event. Previously this had no effect, because the event was already frozen in MMCR0. With the new code the task can unfreeze the event in MMCR2, but at some indeterminate time in the future the kernel will overwrite its setting and refreeze the event. Therefore my final assertion is that any task using exclude_user = true and also fiddling with MMCR2 was deeply confused before this change, and remains so after it. Signed-off-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2014-07-23 18:12:38 +07:00
mmcr[3] = mmcr2;
return 0;
}
#define MAX_ALT 2
/* Table of alternatives, sorted by column 0 */
static const unsigned int event_alternatives[][MAX_ALT] = {
{ 0x10134, 0x301e2 }, /* PM_MRK_ST_CMPL */
{ 0x10138, 0x40138 }, /* PM_BR_MRK_2PATH */
{ 0x18082, 0x3e05e }, /* PM_L3_CO_MEPF */
{ 0x1d14e, 0x401e8 }, /* PM_MRK_DATA_FROM_L2MISS */
{ 0x1e054, 0x4000a }, /* PM_CMPLU_STALL */
{ 0x20036, 0x40036 }, /* PM_BR_2PATH */
{ 0x200f2, 0x300f2 }, /* PM_INST_DISP */
{ 0x200f4, 0x600f4 }, /* PM_RUN_CYC */
{ 0x2013c, 0x3012e }, /* PM_MRK_FILT_MATCH */
{ 0x3e054, 0x400f0 }, /* PM_LD_MISS_L1 */
{ 0x400fa, 0x500fa }, /* PM_RUN_INST_CMPL */
};
/*
* Scan the alternatives table for a match and return the
* index into the alternatives table if found, else -1.
*/
static int find_alternative(u64 event)
{
int i, j;
for (i = 0; i < ARRAY_SIZE(event_alternatives); ++i) {
if (event < event_alternatives[i][0])
break;
for (j = 0; j < MAX_ALT && event_alternatives[i][j]; ++j)
if (event == event_alternatives[i][j])
return i;
}
return -1;
}
static int power8_get_alternatives(u64 event, unsigned int flags, u64 alt[])
{
int i, j, num_alt = 0;
u64 alt_event;
alt[num_alt++] = event;
i = find_alternative(event);
if (i >= 0) {
/* Filter out the original event, it's already in alt[0] */
for (j = 0; j < MAX_ALT; ++j) {
alt_event = event_alternatives[i][j];
if (alt_event && alt_event != event)
alt[num_alt++] = alt_event;
}
}
if (flags & PPMU_ONLY_COUNT_RUN) {
/*
* We're only counting in RUN state, so PM_CYC is equivalent to
* PM_RUN_CYC and PM_INST_CMPL === PM_RUN_INST_CMPL.
*/
j = num_alt;
for (i = 0; i < num_alt; ++i) {
switch (alt[i]) {
case 0x1e: /* PM_CYC */
alt[j++] = 0x600f4; /* PM_RUN_CYC */
break;
case 0x600f4: /* PM_RUN_CYC */
alt[j++] = 0x1e;
break;
case 0x2: /* PM_PPC_CMPL */
alt[j++] = 0x500fa; /* PM_RUN_INST_CMPL */
break;
case 0x500fa: /* PM_RUN_INST_CMPL */
alt[j++] = 0x2; /* PM_PPC_CMPL */
break;
}
}
num_alt = j;
}
return num_alt;
}
static void power8_disable_pmc(unsigned int pmc, unsigned long mmcr[])
{
if (pmc <= 3)
mmcr[1] &= ~(0xffUL << MMCR1_PMCSEL_SHIFT(pmc + 1));
}
PMU_FORMAT_ATTR(event, "config:0-49");
PMU_FORMAT_ATTR(pmcxsel, "config:0-7");
PMU_FORMAT_ATTR(mark, "config:8");
PMU_FORMAT_ATTR(combine, "config:11");
PMU_FORMAT_ATTR(unit, "config:12-15");
PMU_FORMAT_ATTR(pmc, "config:16-19");
PMU_FORMAT_ATTR(cache_sel, "config:20-23");
PMU_FORMAT_ATTR(sample_mode, "config:24-28");
PMU_FORMAT_ATTR(thresh_sel, "config:29-31");
PMU_FORMAT_ATTR(thresh_stop, "config:32-35");
PMU_FORMAT_ATTR(thresh_start, "config:36-39");
PMU_FORMAT_ATTR(thresh_cmp, "config:40-49");
static struct attribute *power8_pmu_format_attr[] = {
&format_attr_event.attr,
&format_attr_pmcxsel.attr,
&format_attr_mark.attr,
&format_attr_combine.attr,
&format_attr_unit.attr,
&format_attr_pmc.attr,
&format_attr_cache_sel.attr,
&format_attr_sample_mode.attr,
&format_attr_thresh_sel.attr,
&format_attr_thresh_stop.attr,
&format_attr_thresh_start.attr,
&format_attr_thresh_cmp.attr,
NULL,
};
struct attribute_group power8_pmu_format_group = {
.name = "format",
.attrs = power8_pmu_format_attr,
};
static const struct attribute_group *power8_pmu_attr_groups[] = {
&power8_pmu_format_group,
NULL,
};
static int power8_generic_events[] = {
[PERF_COUNT_HW_CPU_CYCLES] = PM_CYC,
[PERF_COUNT_HW_STALLED_CYCLES_FRONTEND] = PM_GCT_NOSLOT_CYC,
[PERF_COUNT_HW_STALLED_CYCLES_BACKEND] = PM_CMPLU_STALL,
[PERF_COUNT_HW_INSTRUCTIONS] = PM_INST_CMPL,
[PERF_COUNT_HW_BRANCH_INSTRUCTIONS] = PM_BRU_FIN,
[PERF_COUNT_HW_BRANCH_MISSES] = PM_BR_MPRED_CMPL,
[PERF_COUNT_HW_CACHE_REFERENCES] = PM_LD_REF_L1,
[PERF_COUNT_HW_CACHE_MISSES] = PM_LD_MISS_L1,
};
static u64 power8_bhrb_filter_map(u64 branch_sample_type)
{
u64 pmu_bhrb_filter = 0;
/* BHRB and regular PMU events share the same privilege state
* filter configuration. BHRB is always recorded along with a
* regular PMU event. As the privilege state filter is handled
* in the basic PMC configuration of the accompanying regular
* PMU event, we ignore any separate BHRB specific request.
*/
/* No branch filter requested */
if (branch_sample_type & PERF_SAMPLE_BRANCH_ANY)
return pmu_bhrb_filter;
/* Invalid branch filter options - HW does not support */
if (branch_sample_type & PERF_SAMPLE_BRANCH_ANY_RETURN)
return -1;
if (branch_sample_type & PERF_SAMPLE_BRANCH_IND_CALL)
return -1;
if (branch_sample_type & PERF_SAMPLE_BRANCH_ANY_CALL) {
pmu_bhrb_filter |= POWER8_MMCRA_IFM1;
return pmu_bhrb_filter;
}
/* Every thing else is unsupported */
return -1;
}
static void power8_config_bhrb(u64 pmu_bhrb_filter)
{
/* Enable BHRB filter in PMU */
mtspr(SPRN_MMCRA, (mfspr(SPRN_MMCRA) | pmu_bhrb_filter));
}
#define C(x) PERF_COUNT_HW_CACHE_##x
/*
* Table of generalized cache-related events.
* 0 means not supported, -1 means nonsensical, other values
* are event codes.
*/
static int power8_cache_events[C(MAX)][C(OP_MAX)][C(RESULT_MAX)] = {
[ C(L1D) ] = {
[ C(OP_READ) ] = {
[ C(RESULT_ACCESS) ] = PM_LD_REF_L1,
[ C(RESULT_MISS) ] = PM_LD_MISS_L1,
},
[ C(OP_WRITE) ] = {
[ C(RESULT_ACCESS) ] = 0,
[ C(RESULT_MISS) ] = PM_ST_MISS_L1,
},
[ C(OP_PREFETCH) ] = {
[ C(RESULT_ACCESS) ] = PM_L1_PREF,
[ C(RESULT_MISS) ] = 0,
},
},
[ C(L1I) ] = {
[ C(OP_READ) ] = {
[ C(RESULT_ACCESS) ] = PM_INST_FROM_L1,
[ C(RESULT_MISS) ] = PM_L1_ICACHE_MISS,
},
[ C(OP_WRITE) ] = {
[ C(RESULT_ACCESS) ] = PM_L1_DEMAND_WRITE,
[ C(RESULT_MISS) ] = -1,
},
[ C(OP_PREFETCH) ] = {
[ C(RESULT_ACCESS) ] = PM_IC_PREF_WRITE,
[ C(RESULT_MISS) ] = 0,
},
},
[ C(LL) ] = {
[ C(OP_READ) ] = {
[ C(RESULT_ACCESS) ] = PM_DATA_FROM_L3,
[ C(RESULT_MISS) ] = PM_DATA_FROM_L3MISS,
},
[ C(OP_WRITE) ] = {
[ C(RESULT_ACCESS) ] = PM_L2_ST,
[ C(RESULT_MISS) ] = PM_L2_ST_MISS,
},
[ C(OP_PREFETCH) ] = {
[ C(RESULT_ACCESS) ] = PM_L3_PREF_ALL,
[ C(RESULT_MISS) ] = 0,
},
},
[ C(DTLB) ] = {
[ C(OP_READ) ] = {
[ C(RESULT_ACCESS) ] = 0,
[ C(RESULT_MISS) ] = PM_DTLB_MISS,
},
[ C(OP_WRITE) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
[ C(OP_PREFETCH) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
},
[ C(ITLB) ] = {
[ C(OP_READ) ] = {
[ C(RESULT_ACCESS) ] = 0,
[ C(RESULT_MISS) ] = PM_ITLB_MISS,
},
[ C(OP_WRITE) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
[ C(OP_PREFETCH) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
},
[ C(BPU) ] = {
[ C(OP_READ) ] = {
[ C(RESULT_ACCESS) ] = PM_BRU_FIN,
[ C(RESULT_MISS) ] = PM_BR_MPRED_CMPL,
},
[ C(OP_WRITE) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
[ C(OP_PREFETCH) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
},
[ C(NODE) ] = {
[ C(OP_READ) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
[ C(OP_WRITE) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
[ C(OP_PREFETCH) ] = {
[ C(RESULT_ACCESS) ] = -1,
[ C(RESULT_MISS) ] = -1,
},
},
};
#undef C
static struct power_pmu power8_pmu = {
.name = "POWER8",
.n_counter = 6,
.max_alternatives = MAX_ALT + 1,
.add_fields = POWER8_ADD_FIELDS,
.test_adder = POWER8_TEST_ADDER,
.compute_mmcr = power8_compute_mmcr,
.config_bhrb = power8_config_bhrb,
.bhrb_filter_map = power8_bhrb_filter_map,
.get_constraint = power8_get_constraint,
.get_alternatives = power8_get_alternatives,
.disable_pmc = power8_disable_pmc,
.flags = PPMU_HAS_SSLOT | PPMU_HAS_SIER | PPMU_ARCH_207S,
.n_generic = ARRAY_SIZE(power8_generic_events),
.generic_events = power8_generic_events,
.cache_events = &power8_cache_events,
.attr_groups = power8_pmu_attr_groups,
.bhrb_nr = 32,
};
static int __init init_power8_pmu(void)
{
int rc;
if (!cur_cpu_spec->oprofile_cpu_type ||
strcmp(cur_cpu_spec->oprofile_cpu_type, "ppc64/power8"))
return -ENODEV;
rc = register_power_pmu(&power8_pmu);
if (rc)
return rc;
/* Tell userspace that EBB is supported */
cur_cpu_spec->cpu_user_features2 |= PPC_FEATURE2_EBB;
if (cpu_has_feature(CPU_FTR_PMAO_BUG))
pr_info("PMAO restore workaround active.\n");
return 0;
}
early_initcall(init_power8_pmu);