Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Peter Zijlstra | 1329 | 32.77% | 11 | 18.03% |
Kim Phillips | 1087 | 26.80% | 5 | 8.20% |
Robert Richter | 736 | 18.15% | 9 | 14.75% |
Jacob Shin | 286 | 7.05% | 4 | 6.56% |
Tom Lendacky | 264 | 6.51% | 4 | 6.56% |
Joerg Roedel | 135 | 3.33% | 2 | 3.28% |
Jiri Olsa | 121 | 2.98% | 2 | 3.28% |
Stéphane Eranian | 27 | 0.67% | 4 | 6.56% |
Ingo Molnar | 17 | 0.42% | 2 | 3.28% |
Kevin Winchester | 14 | 0.35% | 1 | 1.64% |
Borislav Petkov | 10 | 0.25% | 3 | 4.92% |
Thomas Gleixner | 5 | 0.12% | 2 | 3.28% |
Pu Wen | 4 | 0.10% | 1 | 1.64% |
Christoph Lameter | 4 | 0.10% | 1 | 1.64% |
Adam Borowski | 3 | 0.07% | 1 | 1.64% |
Rafael J. Wysocki | 3 | 0.07% | 1 | 1.64% |
Vince Weaver | 3 | 0.07% | 2 | 3.28% |
Matt Fleming | 2 | 0.05% | 1 | 1.64% |
Randy Dunlap | 2 | 0.05% | 1 | 1.64% |
Yazen Ghannam | 1 | 0.02% | 1 | 1.64% |
Janakarajan Natarajan | 1 | 0.02% | 1 | 1.64% |
Joe Perches | 1 | 0.02% | 1 | 1.64% |
Andre Przywara | 1 | 0.02% | 1 | 1.64% |
Total | 4056 | 61 |
// SPDX-License-Identifier: GPL-2.0-only #include <linux/perf_event.h> #include <linux/export.h> #include <linux/types.h> #include <linux/init.h> #include <linux/slab.h> #include <linux/delay.h> #include <linux/jiffies.h> #include <asm/apicdef.h> #include <asm/nmi.h> #include "../perf_event.h" static DEFINE_PER_CPU(unsigned long, perf_nmi_tstamp); static unsigned long perf_nmi_window; /* AMD Event 0xFFF: Merge. Used with Large Increment per Cycle events */ #define AMD_MERGE_EVENT ((0xFULL << 32) | 0xFFULL) #define AMD_MERGE_EVENT_ENABLE (AMD_MERGE_EVENT | ARCH_PERFMON_EVENTSEL_ENABLE) static __initconst const u64 amd_hw_cache_event_ids [PERF_COUNT_HW_CACHE_MAX] [PERF_COUNT_HW_CACHE_OP_MAX] [PERF_COUNT_HW_CACHE_RESULT_MAX] = { [ C(L1D) ] = { [ C(OP_READ) ] = { [ C(RESULT_ACCESS) ] = 0x0040, /* Data Cache Accesses */ [ C(RESULT_MISS) ] = 0x0141, /* Data Cache Misses */ }, [ C(OP_WRITE) ] = { [ C(RESULT_ACCESS) ] = 0, [ C(RESULT_MISS) ] = 0, }, [ C(OP_PREFETCH) ] = { [ C(RESULT_ACCESS) ] = 0x0267, /* Data Prefetcher :attempts */ [ C(RESULT_MISS) ] = 0x0167, /* Data Prefetcher :cancelled */ }, }, [ C(L1I ) ] = { [ C(OP_READ) ] = { [ C(RESULT_ACCESS) ] = 0x0080, /* Instruction cache fetches */ [ C(RESULT_MISS) ] = 0x0081, /* Instruction cache misses */ }, [ C(OP_WRITE) ] = { [ C(RESULT_ACCESS) ] = -1, [ C(RESULT_MISS) ] = -1, }, [ C(OP_PREFETCH) ] = { [ C(RESULT_ACCESS) ] = 0x014B, /* Prefetch Instructions :Load */ [ C(RESULT_MISS) ] = 0, }, }, [ C(LL ) ] = { [ C(OP_READ) ] = { [ C(RESULT_ACCESS) ] = 0x037D, /* Requests to L2 Cache :IC+DC */ [ C(RESULT_MISS) ] = 0x037E, /* L2 Cache Misses : IC+DC */ }, [ C(OP_WRITE) ] = { [ C(RESULT_ACCESS) ] = 0x017F, /* L2 Fill/Writeback */ [ C(RESULT_MISS) ] = 0, }, [ C(OP_PREFETCH) ] = { [ C(RESULT_ACCESS) ] = 0, [ C(RESULT_MISS) ] = 0, }, }, [ C(DTLB) ] = { [ C(OP_READ) ] = { [ C(RESULT_ACCESS) ] = 0x0040, /* Data Cache Accesses */ [ C(RESULT_MISS) ] = 0x0746, /* L1_DTLB_AND_L2_DLTB_MISS.ALL */ }, [ C(OP_WRITE) ] = { [ C(RESULT_ACCESS) ] = 0, [ C(RESULT_MISS) ] = 0, }, [ C(OP_PREFETCH) ] = { [ C(RESULT_ACCESS) ] = 0, [ C(RESULT_MISS) ] = 0, }, }, [ C(ITLB) ] = { [ C(OP_READ) ] = { [ C(RESULT_ACCESS) ] = 0x0080, /* Instruction fecthes */ [ C(RESULT_MISS) ] = 0x0385, /* L1_ITLB_AND_L2_ITLB_MISS.ALL */ }, [ 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) ] = 0x00c2, /* Retired Branch Instr. */ [ C(RESULT_MISS) ] = 0x00c3, /* Retired Mispredicted BI */ }, [ 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) ] = 0xb8e9, /* CPU Request to Memory, l+r */ [ C(RESULT_MISS) ] = 0x98e9, /* CPU Request to Memory, r */ }, [ C(OP_WRITE) ] = { [ C(RESULT_ACCESS) ] = -1, [ C(RESULT_MISS) ] = -1, }, [ C(OP_PREFETCH) ] = { [ C(RESULT_ACCESS) ] = -1, [ C(RESULT_MISS) ] = -1, }, }, }; static __initconst const u64 amd_hw_cache_event_ids_f17h [PERF_COUNT_HW_CACHE_MAX] [PERF_COUNT_HW_CACHE_OP_MAX] [PERF_COUNT_HW_CACHE_RESULT_MAX] = { [C(L1D)] = { [C(OP_READ)] = { [C(RESULT_ACCESS)] = 0x0040, /* Data Cache Accesses */ [C(RESULT_MISS)] = 0xc860, /* L2$ access from DC Miss */ }, [C(OP_WRITE)] = { [C(RESULT_ACCESS)] = 0, [C(RESULT_MISS)] = 0, }, [C(OP_PREFETCH)] = { [C(RESULT_ACCESS)] = 0xff5a, /* h/w prefetch DC Fills */ [C(RESULT_MISS)] = 0, }, }, [C(L1I)] = { [C(OP_READ)] = { [C(RESULT_ACCESS)] = 0x0080, /* Instruction cache fetches */ [C(RESULT_MISS)] = 0x0081, /* Instruction cache misses */ }, [C(OP_WRITE)] = { [C(RESULT_ACCESS)] = -1, [C(RESULT_MISS)] = -1, }, [C(OP_PREFETCH)] = { [C(RESULT_ACCESS)] = 0, [C(RESULT_MISS)] = 0, }, }, [C(LL)] = { [C(OP_READ)] = { [C(RESULT_ACCESS)] = 0, [C(RESULT_MISS)] = 0, }, [C(OP_WRITE)] = { [C(RESULT_ACCESS)] = 0, [C(RESULT_MISS)] = 0, }, [C(OP_PREFETCH)] = { [C(RESULT_ACCESS)] = 0, [C(RESULT_MISS)] = 0, }, }, [C(DTLB)] = { [C(OP_READ)] = { [C(RESULT_ACCESS)] = 0xff45, /* All L2 DTLB accesses */ [C(RESULT_MISS)] = 0xf045, /* L2 DTLB misses (PT walks) */ }, [C(OP_WRITE)] = { [C(RESULT_ACCESS)] = 0, [C(RESULT_MISS)] = 0, }, [C(OP_PREFETCH)] = { [C(RESULT_ACCESS)] = 0, [C(RESULT_MISS)] = 0, }, }, [C(ITLB)] = { [C(OP_READ)] = { [C(RESULT_ACCESS)] = 0x0084, /* L1 ITLB misses, L2 ITLB hits */ [C(RESULT_MISS)] = 0xff85, /* L1 ITLB misses, L2 misses */ }, [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)] = 0x00c2, /* Retired Branch Instr. */ [C(RESULT_MISS)] = 0x00c3, /* Retired Mispredicted BI */ }, [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)] = 0, [C(RESULT_MISS)] = 0, }, [C(OP_WRITE)] = { [C(RESULT_ACCESS)] = -1, [C(RESULT_MISS)] = -1, }, [C(OP_PREFETCH)] = { [C(RESULT_ACCESS)] = -1, [C(RESULT_MISS)] = -1, }, }, }; /* * AMD Performance Monitor K7 and later, up to and including Family 16h: */ static const u64 amd_perfmon_event_map[PERF_COUNT_HW_MAX] = { [PERF_COUNT_HW_CPU_CYCLES] = 0x0076, [PERF_COUNT_HW_INSTRUCTIONS] = 0x00c0, [PERF_COUNT_HW_CACHE_REFERENCES] = 0x077d, [PERF_COUNT_HW_CACHE_MISSES] = 0x077e, [PERF_COUNT_HW_BRANCH_INSTRUCTIONS] = 0x00c2, [PERF_COUNT_HW_BRANCH_MISSES] = 0x00c3, [PERF_COUNT_HW_STALLED_CYCLES_FRONTEND] = 0x00d0, /* "Decoder empty" event */ [PERF_COUNT_HW_STALLED_CYCLES_BACKEND] = 0x00d1, /* "Dispatch stalls" event */ }; /* * AMD Performance Monitor Family 17h and later: */ static const u64 amd_f17h_perfmon_event_map[PERF_COUNT_HW_MAX] = { [PERF_COUNT_HW_CPU_CYCLES] = 0x0076, [PERF_COUNT_HW_INSTRUCTIONS] = 0x00c0, [PERF_COUNT_HW_CACHE_REFERENCES] = 0xff60, [PERF_COUNT_HW_CACHE_MISSES] = 0x0964, [PERF_COUNT_HW_BRANCH_INSTRUCTIONS] = 0x00c2, [PERF_COUNT_HW_BRANCH_MISSES] = 0x00c3, [PERF_COUNT_HW_STALLED_CYCLES_FRONTEND] = 0x0287, [PERF_COUNT_HW_STALLED_CYCLES_BACKEND] = 0x0187, }; static u64 amd_pmu_event_map(int hw_event) { if (boot_cpu_data.x86 >= 0x17) return amd_f17h_perfmon_event_map[hw_event]; return amd_perfmon_event_map[hw_event]; } /* * Previously calculated offsets */ static unsigned int event_offsets[X86_PMC_IDX_MAX] __read_mostly; static unsigned int count_offsets[X86_PMC_IDX_MAX] __read_mostly; /* * Legacy CPUs: * 4 counters starting at 0xc0010000 each offset by 1 * * CPUs with core performance counter extensions: * 6 counters starting at 0xc0010200 each offset by 2 */ static inline int amd_pmu_addr_offset(int index, bool eventsel) { int offset; if (!index) return index; if (eventsel) offset = event_offsets[index]; else offset = count_offsets[index]; if (offset) return offset; if (!boot_cpu_has(X86_FEATURE_PERFCTR_CORE)) offset = index; else offset = index << 1; if (eventsel) event_offsets[index] = offset; else count_offsets[index] = offset; return offset; } /* * AMD64 events are detected based on their event codes. */ static inline unsigned int amd_get_event_code(struct hw_perf_event *hwc) { return ((hwc->config >> 24) & 0x0f00) | (hwc->config & 0x00ff); } static inline bool amd_is_pair_event_code(struct hw_perf_event *hwc) { if (!(x86_pmu.flags & PMU_FL_PAIR)) return false; switch (amd_get_event_code(hwc)) { case 0x003: return true; /* Retired SSE/AVX FLOPs */ default: return false; } } static int amd_core_hw_config(struct perf_event *event) { if (event->attr.exclude_host && event->attr.exclude_guest) /* * When HO == GO == 1 the hardware treats that as GO == HO == 0 * and will count in both modes. We don't want to count in that * case so we emulate no-counting by setting US = OS = 0. */ event->hw.config &= ~(ARCH_PERFMON_EVENTSEL_USR | ARCH_PERFMON_EVENTSEL_OS); else if (event->attr.exclude_host) event->hw.config |= AMD64_EVENTSEL_GUESTONLY; else if (event->attr.exclude_guest) event->hw.config |= AMD64_EVENTSEL_HOSTONLY; if ((x86_pmu.flags & PMU_FL_PAIR) && amd_is_pair_event_code(&event->hw)) event->hw.flags |= PERF_X86_EVENT_PAIR; return 0; } static inline int amd_is_nb_event(struct hw_perf_event *hwc) { return (hwc->config & 0xe0) == 0xe0; } static inline int amd_has_nb(struct cpu_hw_events *cpuc) { struct amd_nb *nb = cpuc->amd_nb; return nb && nb->nb_id != -1; } static int amd_pmu_hw_config(struct perf_event *event) { int ret; /* pass precise event sampling to ibs: */ if (event->attr.precise_ip && get_ibs_caps()) return -ENOENT; if (has_branch_stack(event)) return -EOPNOTSUPP; ret = x86_pmu_hw_config(event); if (ret) return ret; if (event->attr.type == PERF_TYPE_RAW) event->hw.config |= event->attr.config & AMD64_RAW_EVENT_MASK; return amd_core_hw_config(event); } static void __amd_put_nb_event_constraints(struct cpu_hw_events *cpuc, struct perf_event *event) { struct amd_nb *nb = cpuc->amd_nb; int i; /* * need to scan whole list because event may not have * been assigned during scheduling * * no race condition possible because event can only * be removed on one CPU at a time AND PMU is disabled * when we come here */ for (i = 0; i < x86_pmu.num_counters; i++) { if (cmpxchg(nb->owners + i, event, NULL) == event) break; } } /* * AMD64 NorthBridge events need special treatment because * counter access needs to be synchronized across all cores * of a package. Refer to BKDG section 3.12 * * NB events are events measuring L3 cache, Hypertransport * traffic. They are identified by an event code >= 0xe00. * They measure events on the NorthBride which is shared * by all cores on a package. NB events are counted on a * shared set of counters. When a NB event is programmed * in a counter, the data actually comes from a shared * counter. Thus, access to those counters needs to be * synchronized. * * We implement the synchronization such that no two cores * can be measuring NB events using the same counters. Thus, * we maintain a per-NB allocation table. The available slot * is propagated using the event_constraint structure. * * We provide only one choice for each NB event based on * the fact that only NB events have restrictions. Consequently, * if a counter is available, there is a guarantee the NB event * will be assigned to it. If no slot is available, an empty * constraint is returned and scheduling will eventually fail * for this event. * * Note that all cores attached the same NB compete for the same * counters to host NB events, this is why we use atomic ops. Some * multi-chip CPUs may have more than one NB. * * Given that resources are allocated (cmpxchg), they must be * eventually freed for others to use. This is accomplished by * calling __amd_put_nb_event_constraints() * * Non NB events are not impacted by this restriction. */ static struct event_constraint * __amd_get_nb_event_constraints(struct cpu_hw_events *cpuc, struct perf_event *event, struct event_constraint *c) { struct hw_perf_event *hwc = &event->hw; struct amd_nb *nb = cpuc->amd_nb; struct perf_event *old; int idx, new = -1; if (!c) c = &unconstrained; if (cpuc->is_fake) return c; /* * detect if already present, if so reuse * * cannot merge with actual allocation * because of possible holes * * event can already be present yet not assigned (in hwc->idx) * because of successive calls to x86_schedule_events() from * hw_perf_group_sched_in() without hw_perf_enable() */ for_each_set_bit(idx, c->idxmsk, x86_pmu.num_counters) { if (new == -1 || hwc->idx == idx) /* assign free slot, prefer hwc->idx */ old = cmpxchg(nb->owners + idx, NULL, event); else if (nb->owners[idx] == event) /* event already present */ old = event; else continue; if (old && old != event) continue; /* reassign to this slot */ if (new != -1) cmpxchg(nb->owners + new, event, NULL); new = idx; /* already present, reuse */ if (old == event) break; } if (new == -1) return &emptyconstraint; return &nb->event_constraints[new]; } static struct amd_nb *amd_alloc_nb(int cpu) { struct amd_nb *nb; int i; nb = kzalloc_node(sizeof(struct amd_nb), GFP_KERNEL, cpu_to_node(cpu)); if (!nb) return NULL; nb->nb_id = -1; /* * initialize all possible NB constraints */ for (i = 0; i < x86_pmu.num_counters; i++) { __set_bit(i, nb->event_constraints[i].idxmsk); nb->event_constraints[i].weight = 1; } return nb; } static int amd_pmu_cpu_prepare(int cpu) { struct cpu_hw_events *cpuc = &per_cpu(cpu_hw_events, cpu); WARN_ON_ONCE(cpuc->amd_nb); if (!x86_pmu.amd_nb_constraints) return 0; cpuc->amd_nb = amd_alloc_nb(cpu); if (!cpuc->amd_nb) return -ENOMEM; return 0; } static void amd_pmu_cpu_starting(int cpu) { struct cpu_hw_events *cpuc = &per_cpu(cpu_hw_events, cpu); void **onln = &cpuc->kfree_on_online[X86_PERF_KFREE_SHARED]; struct amd_nb *nb; int i, nb_id; cpuc->perf_ctr_virt_mask = AMD64_EVENTSEL_HOSTONLY; if (!x86_pmu.amd_nb_constraints) return; nb_id = topology_die_id(cpu); WARN_ON_ONCE(nb_id == BAD_APICID); for_each_online_cpu(i) { nb = per_cpu(cpu_hw_events, i).amd_nb; if (WARN_ON_ONCE(!nb)) continue; if (nb->nb_id == nb_id) { *onln = cpuc->amd_nb; cpuc->amd_nb = nb; break; } } cpuc->amd_nb->nb_id = nb_id; cpuc->amd_nb->refcnt++; } static void amd_pmu_cpu_dead(int cpu) { struct cpu_hw_events *cpuhw; if (!x86_pmu.amd_nb_constraints) return; cpuhw = &per_cpu(cpu_hw_events, cpu); if (cpuhw->amd_nb) { struct amd_nb *nb = cpuhw->amd_nb; if (nb->nb_id == -1 || --nb->refcnt == 0) kfree(nb); cpuhw->amd_nb = NULL; } } /* * When a PMC counter overflows, an NMI is used to process the event and * reset the counter. NMI latency can result in the counter being updated * before the NMI can run, which can result in what appear to be spurious * NMIs. This function is intended to wait for the NMI to run and reset * the counter to avoid possible unhandled NMI messages. */ #define OVERFLOW_WAIT_COUNT 50 static void amd_pmu_wait_on_overflow(int idx) { unsigned int i; u64 counter; /* * Wait for the counter to be reset if it has overflowed. This loop * should exit very, very quickly, but just in case, don't wait * forever... */ for (i = 0; i < OVERFLOW_WAIT_COUNT; i++) { rdmsrl(x86_pmu_event_addr(idx), counter); if (counter & (1ULL << (x86_pmu.cntval_bits - 1))) break; /* Might be in IRQ context, so can't sleep */ udelay(1); } } static void amd_pmu_disable_all(void) { struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events); int idx; x86_pmu_disable_all(); /* * This shouldn't be called from NMI context, but add a safeguard here * to return, since if we're in NMI context we can't wait for an NMI * to reset an overflowed counter value. */ if (in_nmi()) return; /* * Check each counter for overflow and wait for it to be reset by the * NMI if it has overflowed. This relies on the fact that all active * counters are always enabled when this function is called and * ARCH_PERFMON_EVENTSEL_INT is always set. */ for (idx = 0; idx < x86_pmu.num_counters; idx++) { if (!test_bit(idx, cpuc->active_mask)) continue; amd_pmu_wait_on_overflow(idx); } } static void amd_pmu_disable_event(struct perf_event *event) { x86_pmu_disable_event(event); /* * This can be called from NMI context (via x86_pmu_stop). The counter * may have overflowed, but either way, we'll never see it get reset * by the NMI if we're already in the NMI. And the NMI latency support * below will take care of any pending NMI that might have been * generated by the overflow. */ if (in_nmi()) return; amd_pmu_wait_on_overflow(event->hw.idx); } /* * Because of NMI latency, if multiple PMC counters are active or other sources * of NMIs are received, the perf NMI handler can handle one or more overflowed * PMC counters outside of the NMI associated with the PMC overflow. If the NMI * doesn't arrive at the LAPIC in time to become a pending NMI, then the kernel * back-to-back NMI support won't be active. This PMC handler needs to take into * account that this can occur, otherwise this could result in unknown NMI * messages being issued. Examples of this is PMC overflow while in the NMI * handler when multiple PMCs are active or PMC overflow while handling some * other source of an NMI. * * Attempt to mitigate this by creating an NMI window in which un-handled NMIs * received during this window will be claimed. This prevents extending the * window past when it is possible that latent NMIs should be received. The * per-CPU perf_nmi_tstamp will be set to the window end time whenever perf has * handled a counter. When an un-handled NMI is received, it will be claimed * only if arriving within that window. */ static int amd_pmu_handle_irq(struct pt_regs *regs) { int handled; /* Process any counter overflows */ handled = x86_pmu_handle_irq(regs); /* * If a counter was handled, record a timestamp such that un-handled * NMIs will be claimed if arriving within that window. */ if (handled) { this_cpu_write(perf_nmi_tstamp, jiffies + perf_nmi_window); return handled; } if (time_after(jiffies, this_cpu_read(perf_nmi_tstamp))) return NMI_DONE; return NMI_HANDLED; } static struct event_constraint * amd_get_event_constraints(struct cpu_hw_events *cpuc, int idx, struct perf_event *event) { /* * if not NB event or no NB, then no constraints */ if (!(amd_has_nb(cpuc) && amd_is_nb_event(&event->hw))) return &unconstrained; return __amd_get_nb_event_constraints(cpuc, event, NULL); } static void amd_put_event_constraints(struct cpu_hw_events *cpuc, struct perf_event *event) { if (amd_has_nb(cpuc) && amd_is_nb_event(&event->hw)) __amd_put_nb_event_constraints(cpuc, event); } PMU_FORMAT_ATTR(event, "config:0-7,32-35"); PMU_FORMAT_ATTR(umask, "config:8-15" ); PMU_FORMAT_ATTR(edge, "config:18" ); PMU_FORMAT_ATTR(inv, "config:23" ); PMU_FORMAT_ATTR(cmask, "config:24-31" ); static struct attribute *amd_format_attr[] = { &format_attr_event.attr, &format_attr_umask.attr, &format_attr_edge.attr, &format_attr_inv.attr, &format_attr_cmask.attr, NULL, }; /* AMD Family 15h */ #define AMD_EVENT_TYPE_MASK 0x000000F0ULL #define AMD_EVENT_FP 0x00000000ULL ... 0x00000010ULL #define AMD_EVENT_LS 0x00000020ULL ... 0x00000030ULL #define AMD_EVENT_DC 0x00000040ULL ... 0x00000050ULL #define AMD_EVENT_CU 0x00000060ULL ... 0x00000070ULL #define AMD_EVENT_IC_DE 0x00000080ULL ... 0x00000090ULL #define AMD_EVENT_EX_LS 0x000000C0ULL #define AMD_EVENT_DE 0x000000D0ULL #define AMD_EVENT_NB 0x000000E0ULL ... 0x000000F0ULL /* * AMD family 15h event code/PMC mappings: * * type = event_code & 0x0F0: * * 0x000 FP PERF_CTL[5:3] * 0x010 FP PERF_CTL[5:3] * 0x020 LS PERF_CTL[5:0] * 0x030 LS PERF_CTL[5:0] * 0x040 DC PERF_CTL[5:0] * 0x050 DC PERF_CTL[5:0] * 0x060 CU PERF_CTL[2:0] * 0x070 CU PERF_CTL[2:0] * 0x080 IC/DE PERF_CTL[2:0] * 0x090 IC/DE PERF_CTL[2:0] * 0x0A0 --- * 0x0B0 --- * 0x0C0 EX/LS PERF_CTL[5:0] * 0x0D0 DE PERF_CTL[2:0] * 0x0E0 NB NB_PERF_CTL[3:0] * 0x0F0 NB NB_PERF_CTL[3:0] * * Exceptions: * * 0x000 FP PERF_CTL[3], PERF_CTL[5:3] (*) * 0x003 FP PERF_CTL[3] * 0x004 FP PERF_CTL[3], PERF_CTL[5:3] (*) * 0x00B FP PERF_CTL[3] * 0x00D FP PERF_CTL[3] * 0x023 DE PERF_CTL[2:0] * 0x02D LS PERF_CTL[3] * 0x02E LS PERF_CTL[3,0] * 0x031 LS PERF_CTL[2:0] (**) * 0x043 CU PERF_CTL[2:0] * 0x045 CU PERF_CTL[2:0] * 0x046 CU PERF_CTL[2:0] * 0x054 CU PERF_CTL[2:0] * 0x055 CU PERF_CTL[2:0] * 0x08F IC PERF_CTL[0] * 0x187 DE PERF_CTL[0] * 0x188 DE PERF_CTL[0] * 0x0DB EX PERF_CTL[5:0] * 0x0DC LS PERF_CTL[5:0] * 0x0DD LS PERF_CTL[5:0] * 0x0DE LS PERF_CTL[5:0] * 0x0DF LS PERF_CTL[5:0] * 0x1C0 EX PERF_CTL[5:3] * 0x1D6 EX PERF_CTL[5:0] * 0x1D8 EX PERF_CTL[5:0] * * (*) depending on the umask all FPU counters may be used * (**) only one unitmask enabled at a time */ static struct event_constraint amd_f15_PMC0 = EVENT_CONSTRAINT(0, 0x01, 0); static struct event_constraint amd_f15_PMC20 = EVENT_CONSTRAINT(0, 0x07, 0); static struct event_constraint amd_f15_PMC3 = EVENT_CONSTRAINT(0, 0x08, 0); static struct event_constraint amd_f15_PMC30 = EVENT_CONSTRAINT_OVERLAP(0, 0x09, 0); static struct event_constraint amd_f15_PMC50 = EVENT_CONSTRAINT(0, 0x3F, 0); static struct event_constraint amd_f15_PMC53 = EVENT_CONSTRAINT(0, 0x38, 0); static struct event_constraint * amd_get_event_constraints_f15h(struct cpu_hw_events *cpuc, int idx, struct perf_event *event) { struct hw_perf_event *hwc = &event->hw; unsigned int event_code = amd_get_event_code(hwc); switch (event_code & AMD_EVENT_TYPE_MASK) { case AMD_EVENT_FP: switch (event_code) { case 0x000: if (!(hwc->config & 0x0000F000ULL)) break; if (!(hwc->config & 0x00000F00ULL)) break; return &amd_f15_PMC3; case 0x004: if (hweight_long(hwc->config & ARCH_PERFMON_EVENTSEL_UMASK) <= 1) break; return &amd_f15_PMC3; case 0x003: case 0x00B: case 0x00D: return &amd_f15_PMC3; } return &amd_f15_PMC53; case AMD_EVENT_LS: case AMD_EVENT_DC: case AMD_EVENT_EX_LS: switch (event_code) { case 0x023: case 0x043: case 0x045: case 0x046: case 0x054: case 0x055: return &amd_f15_PMC20; case 0x02D: return &amd_f15_PMC3; case 0x02E: return &amd_f15_PMC30; case 0x031: if (hweight_long(hwc->config & ARCH_PERFMON_EVENTSEL_UMASK) <= 1) return &amd_f15_PMC20; return &emptyconstraint; case 0x1C0: return &amd_f15_PMC53; default: return &amd_f15_PMC50; } case AMD_EVENT_CU: case AMD_EVENT_IC_DE: case AMD_EVENT_DE: switch (event_code) { case 0x08F: case 0x187: case 0x188: return &amd_f15_PMC0; case 0x0DB ... 0x0DF: case 0x1D6: case 0x1D8: return &amd_f15_PMC50; default: return &amd_f15_PMC20; } case AMD_EVENT_NB: /* moved to uncore.c */ return &emptyconstraint; default: return &emptyconstraint; } } static struct event_constraint pair_constraint; static struct event_constraint * amd_get_event_constraints_f17h(struct cpu_hw_events *cpuc, int idx, struct perf_event *event) { struct hw_perf_event *hwc = &event->hw; if (amd_is_pair_event_code(hwc)) return &pair_constraint; return &unconstrained; } static void amd_put_event_constraints_f17h(struct cpu_hw_events *cpuc, struct perf_event *event) { struct hw_perf_event *hwc = &event->hw; if (is_counter_pair(hwc)) --cpuc->n_pair; } static ssize_t amd_event_sysfs_show(char *page, u64 config) { u64 event = (config & ARCH_PERFMON_EVENTSEL_EVENT) | (config & AMD64_EVENTSEL_EVENT) >> 24; return x86_event_sysfs_show(page, config, event); } static __initconst const struct x86_pmu amd_pmu = { .name = "AMD", .handle_irq = amd_pmu_handle_irq, .disable_all = amd_pmu_disable_all, .enable_all = x86_pmu_enable_all, .enable = x86_pmu_enable_event, .disable = amd_pmu_disable_event, .hw_config = amd_pmu_hw_config, .schedule_events = x86_schedule_events, .eventsel = MSR_K7_EVNTSEL0, .perfctr = MSR_K7_PERFCTR0, .addr_offset = amd_pmu_addr_offset, .event_map = amd_pmu_event_map, .max_events = ARRAY_SIZE(amd_perfmon_event_map), .num_counters = AMD64_NUM_COUNTERS, .cntval_bits = 48, .cntval_mask = (1ULL << 48) - 1, .apic = 1, /* use highest bit to detect overflow */ .max_period = (1ULL << 47) - 1, .get_event_constraints = amd_get_event_constraints, .put_event_constraints = amd_put_event_constraints, .format_attrs = amd_format_attr, .events_sysfs_show = amd_event_sysfs_show, .cpu_prepare = amd_pmu_cpu_prepare, .cpu_starting = amd_pmu_cpu_starting, .cpu_dead = amd_pmu_cpu_dead, .amd_nb_constraints = 1, }; static int __init amd_core_pmu_init(void) { u64 even_ctr_mask = 0ULL; int i; if (!boot_cpu_has(X86_FEATURE_PERFCTR_CORE)) return 0; /* Avoid calculating the value each time in the NMI handler */ perf_nmi_window = msecs_to_jiffies(100); /* * If core performance counter extensions exists, we must use * MSR_F15H_PERF_CTL/MSR_F15H_PERF_CTR msrs. See also * amd_pmu_addr_offset(). */ x86_pmu.eventsel = MSR_F15H_PERF_CTL; x86_pmu.perfctr = MSR_F15H_PERF_CTR; x86_pmu.num_counters = AMD64_NUM_COUNTERS_CORE; /* * AMD Core perfctr has separate MSRs for the NB events, see * the amd/uncore.c driver. */ x86_pmu.amd_nb_constraints = 0; if (boot_cpu_data.x86 == 0x15) { pr_cont("Fam15h "); x86_pmu.get_event_constraints = amd_get_event_constraints_f15h; } if (boot_cpu_data.x86 >= 0x17) { pr_cont("Fam17h+ "); /* * Family 17h and compatibles have constraints for Large * Increment per Cycle events: they may only be assigned an * even numbered counter that has a consecutive adjacent odd * numbered counter following it. */ for (i = 0; i < x86_pmu.num_counters - 1; i += 2) even_ctr_mask |= 1 << i; pair_constraint = (struct event_constraint) __EVENT_CONSTRAINT(0, even_ctr_mask, 0, x86_pmu.num_counters / 2, 0, PERF_X86_EVENT_PAIR); x86_pmu.get_event_constraints = amd_get_event_constraints_f17h; x86_pmu.put_event_constraints = amd_put_event_constraints_f17h; x86_pmu.perf_ctr_pair_en = AMD_MERGE_EVENT_ENABLE; x86_pmu.flags |= PMU_FL_PAIR; } pr_cont("core perfctr, "); return 0; } __init int amd_pmu_init(void) { int ret; /* Performance-monitoring supported from K7 and later: */ if (boot_cpu_data.x86 < 6) return -ENODEV; x86_pmu = amd_pmu; ret = amd_core_pmu_init(); if (ret) return ret; if (num_possible_cpus() == 1) { /* * No point in allocating data structures to serialize * against other CPUs, when there is only the one CPU. */ x86_pmu.amd_nb_constraints = 0; } if (boot_cpu_data.x86 >= 0x17) memcpy(hw_cache_event_ids, amd_hw_cache_event_ids_f17h, sizeof(hw_cache_event_ids)); else memcpy(hw_cache_event_ids, amd_hw_cache_event_ids, sizeof(hw_cache_event_ids)); return 0; } void amd_pmu_enable_virt(void) { struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events); cpuc->perf_ctr_virt_mask = 0; /* Reload all events */ amd_pmu_disable_all(); x86_pmu_enable_all(0); } EXPORT_SYMBOL_GPL(amd_pmu_enable_virt); void amd_pmu_disable_virt(void) { struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events); /* * We only mask out the Host-only bit so that host-only counting works * when SVM is disabled. If someone sets up a guest-only counter when * SVM is disabled the Guest-only bits still gets set and the counter * will not count anything. */ cpuc->perf_ctr_virt_mask = AMD64_EVENTSEL_HOSTONLY; /* Reload all events */ amd_pmu_disable_all(); x86_pmu_enable_all(0); } EXPORT_SYMBOL_GPL(amd_pmu_disable_virt);
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