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|
// SPDX-License-Identifier: GPL-2.0-only
/*
* Kernel-based Virtual Machine -- Performance Monitoring Unit support
*
* Copyright 2015 Red Hat, Inc. and/or its affiliates.
*
* Authors:
* Avi Kivity <avi@redhat.com>
* Gleb Natapov <gleb@redhat.com>
* Wei Huang <wei@redhat.com>
*/
#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
#include <linux/types.h>
#include <linux/kvm_host.h>
#include <linux/perf_event.h>
#include <linux/bsearch.h>
#include <linux/sort.h>
#include <asm/perf_event.h>
#include <asm/cpu_device_id.h>
#include "x86.h"
#include "cpuid.h"
#include "lapic.h"
#include "pmu.h"
/* This is enough to filter the vast majority of currently defined events. */
#define KVM_PMU_EVENT_FILTER_MAX_EVENTS 300
struct x86_pmu_capability __read_mostly kvm_pmu_cap;
EXPORT_SYMBOL_GPL(kvm_pmu_cap);
/* Precise Distribution of Instructions Retired (PDIR) */
static const struct x86_cpu_id vmx_pebs_pdir_cpu[] = {
X86_MATCH_INTEL_FAM6_MODEL(ICELAKE_D, NULL),
X86_MATCH_INTEL_FAM6_MODEL(ICELAKE_X, NULL),
/* Instruction-Accurate PDIR (PDIR++) */
X86_MATCH_INTEL_FAM6_MODEL(SAPPHIRERAPIDS_X, NULL),
{}
};
/* Precise Distribution (PDist) */
static const struct x86_cpu_id vmx_pebs_pdist_cpu[] = {
X86_MATCH_INTEL_FAM6_MODEL(SAPPHIRERAPIDS_X, NULL),
{}
};
/* NOTE:
* - Each perf counter is defined as "struct kvm_pmc";
* - There are two types of perf counters: general purpose (gp) and fixed.
* gp counters are stored in gp_counters[] and fixed counters are stored
* in fixed_counters[] respectively. Both of them are part of "struct
* kvm_pmu";
* - pmu.c understands the difference between gp counters and fixed counters.
* However AMD doesn't support fixed-counters;
* - There are three types of index to access perf counters (PMC):
* 1. MSR (named msr): For example Intel has MSR_IA32_PERFCTRn and AMD
* has MSR_K7_PERFCTRn and, for families 15H and later,
* MSR_F15H_PERF_CTRn, where MSR_F15H_PERF_CTR[0-3] are
* aliased to MSR_K7_PERFCTRn.
* 2. MSR Index (named idx): This normally is used by RDPMC instruction.
* For instance AMD RDPMC instruction uses 0000_0003h in ECX to access
* C001_0007h (MSR_K7_PERCTR3). Intel has a similar mechanism, except
* that it also supports fixed counters. idx can be used to as index to
* gp and fixed counters.
* 3. Global PMC Index (named pmc): pmc is an index specific to PMU
* code. Each pmc, stored in kvm_pmc.idx field, is unique across
* all perf counters (both gp and fixed). The mapping relationship
* between pmc and perf counters is as the following:
* * Intel: [0 .. KVM_INTEL_PMC_MAX_GENERIC-1] <=> gp counters
* [INTEL_PMC_IDX_FIXED .. INTEL_PMC_IDX_FIXED + 2] <=> fixed
* * AMD: [0 .. AMD64_NUM_COUNTERS-1] and, for families 15H
* and later, [0 .. AMD64_NUM_COUNTERS_CORE-1] <=> gp counters
*/
static struct kvm_pmu_ops kvm_pmu_ops __read_mostly;
#define KVM_X86_PMU_OP(func) \
DEFINE_STATIC_CALL_NULL(kvm_x86_pmu_##func, \
*(((struct kvm_pmu_ops *)0)->func));
#define KVM_X86_PMU_OP_OPTIONAL KVM_X86_PMU_OP
#include <asm/kvm-x86-pmu-ops.h>
void kvm_pmu_ops_update(const struct kvm_pmu_ops *pmu_ops)
{
memcpy(&kvm_pmu_ops, pmu_ops, sizeof(kvm_pmu_ops));
#define __KVM_X86_PMU_OP(func) \
static_call_update(kvm_x86_pmu_##func, kvm_pmu_ops.func);
#define KVM_X86_PMU_OP(func) \
WARN_ON(!kvm_pmu_ops.func); __KVM_X86_PMU_OP(func)
#define KVM_X86_PMU_OP_OPTIONAL __KVM_X86_PMU_OP
#include <asm/kvm-x86-pmu-ops.h>
#undef __KVM_X86_PMU_OP
}
static inline void __kvm_perf_overflow(struct kvm_pmc *pmc, bool in_pmi)
{
struct kvm_pmu *pmu = pmc_to_pmu(pmc);
bool skip_pmi = false;
if (pmc->perf_event && pmc->perf_event->attr.precise_ip) {
if (!in_pmi) {
/*
* TODO: KVM is currently _choosing_ to not generate records
* for emulated instructions, avoiding BUFFER_OVF PMI when
* there are no records. Strictly speaking, it should be done
* as well in the right context to improve sampling accuracy.
*/
skip_pmi = true;
} else {
/* Indicate PEBS overflow PMI to guest. */
skip_pmi = __test_and_set_bit(GLOBAL_STATUS_BUFFER_OVF_BIT,
(unsigned long *)&pmu->global_status);
}
} else {
__set_bit(pmc->idx, (unsigned long *)&pmu->global_status);
}
if (pmc->intr && !skip_pmi)
kvm_make_request(KVM_REQ_PMI, pmc->vcpu);
}
static void kvm_perf_overflow(struct perf_event *perf_event,
struct perf_sample_data *data,
struct pt_regs *regs)
{
struct kvm_pmc *pmc = perf_event->overflow_handler_context;
/*
* Ignore asynchronous overflow events for counters that are scheduled
* to be reprogrammed, e.g. if a PMI for the previous event races with
* KVM's handling of a related guest WRMSR.
*/
if (test_and_set_bit(pmc->idx, pmc_to_pmu(pmc)->reprogram_pmi))
return;
__kvm_perf_overflow(pmc, true);
kvm_make_request(KVM_REQ_PMU, pmc->vcpu);
}
static u64 pmc_get_pebs_precise_level(struct kvm_pmc *pmc)
{
/*
* For some model specific pebs counters with special capabilities
* (PDIR, PDIR++, PDIST), KVM needs to raise the event precise
* level to the maximum value (currently 3, backwards compatible)
* so that the perf subsystem would assign specific hardware counter
* with that capability for vPMC.
*/
if ((pmc->idx == 0 && x86_match_cpu(vmx_pebs_pdist_cpu)) ||
(pmc->idx == 32 && x86_match_cpu(vmx_pebs_pdir_cpu)))
return 3;
/*
* The non-zero precision level of guest event makes the ordinary
* guest event becomes a guest PEBS event and triggers the host
* PEBS PMI handler to determine whether the PEBS overflow PMI
* comes from the host counters or the guest.
*/
return 1;
}
static u64 get_sample_period(struct kvm_pmc *pmc, u64 counter_value)
{
u64 sample_period = (-counter_value) & pmc_bitmask(pmc);
if (!sample_period)
sample_period = pmc_bitmask(pmc) + 1;
return sample_period;
}
static int pmc_reprogram_counter(struct kvm_pmc *pmc, u32 type, u64 config,
bool exclude_user, bool exclude_kernel,
bool intr)
{
struct kvm_pmu *pmu = pmc_to_pmu(pmc);
struct perf_event *event;
struct perf_event_attr attr = {
.type = type,
.size = sizeof(attr),
.pinned = true,
.exclude_idle = true,
.exclude_host = 1,
.exclude_user = exclude_user,
.exclude_kernel = exclude_kernel,
.config = config,
};
bool pebs = test_bit(pmc->idx, (unsigned long *)&pmu->pebs_enable);
attr.sample_period = get_sample_period(pmc, pmc->counter);
if ((attr.config & HSW_IN_TX_CHECKPOINTED) &&
guest_cpuid_is_intel(pmc->vcpu)) {
/*
* HSW_IN_TX_CHECKPOINTED is not supported with nonzero
* period. Just clear the sample period so at least
* allocating the counter doesn't fail.
*/
attr.sample_period = 0;
}
if (pebs) {
/*
* For most PEBS hardware events, the difference in the software
* precision levels of guest and host PEBS events will not affect
* the accuracy of the PEBS profiling result, because the "event IP"
* in the PEBS record is calibrated on the guest side.
*/
attr.precise_ip = pmc_get_pebs_precise_level(pmc);
}
event = perf_event_create_kernel_counter(&attr, -1, current,
kvm_perf_overflow, pmc);
if (IS_ERR(event)) {
pr_debug_ratelimited("kvm_pmu: event creation failed %ld for pmc->idx = %d\n",
PTR_ERR(event), pmc->idx);
return PTR_ERR(event);
}
pmc->perf_event = event;
pmc_to_pmu(pmc)->event_count++;
pmc->is_paused = false;
pmc->intr = intr || pebs;
return 0;
}
static bool pmc_pause_counter(struct kvm_pmc *pmc)
{
u64 counter = pmc->counter;
u64 prev_counter;
/* update counter, reset event value to avoid redundant accumulation */
if (pmc->perf_event && !pmc->is_paused)
counter += perf_event_pause(pmc->perf_event, true);
/*
* Snapshot the previous counter *after* accumulating state from perf.
* If overflow already happened, hardware (via perf) is responsible for
* generating a PMI. KVM just needs to detect overflow on emulated
* counter events that haven't yet been processed.
*/
prev_counter = counter & pmc_bitmask(pmc);
counter += pmc->emulated_counter;
pmc->counter = counter & pmc_bitmask(pmc);
pmc->emulated_counter = 0;
pmc->is_paused = true;
return pmc->counter < prev_counter;
}
static bool pmc_resume_counter(struct kvm_pmc *pmc)
{
if (!pmc->perf_event)
return false;
/* recalibrate sample period and check if it's accepted by perf core */
if (is_sampling_event(pmc->perf_event) &&
perf_event_period(pmc->perf_event,
get_sample_period(pmc, pmc->counter)))
return false;
if (test_bit(pmc->idx, (unsigned long *)&pmc_to_pmu(pmc)->pebs_enable) !=
(!!pmc->perf_event->attr.precise_ip))
return false;
/* reuse perf_event to serve as pmc_reprogram_counter() does*/
perf_event_enable(pmc->perf_event);
pmc->is_paused = false;
return true;
}
static void pmc_release_perf_event(struct kvm_pmc *pmc)
{
if (pmc->perf_event) {
perf_event_release_kernel(pmc->perf_event);
pmc->perf_event = NULL;
pmc->current_config = 0;
pmc_to_pmu(pmc)->event_count--;
}
}
static void pmc_stop_counter(struct kvm_pmc *pmc)
{
if (pmc->perf_event) {
pmc->counter = pmc_read_counter(pmc);
pmc_release_perf_event(pmc);
}
}
static void pmc_update_sample_period(struct kvm_pmc *pmc)
{
if (!pmc->perf_event || pmc->is_paused ||
!is_sampling_event(pmc->perf_event))
return;
perf_event_period(pmc->perf_event,
get_sample_period(pmc, pmc->counter));
}
void pmc_write_counter(struct kvm_pmc *pmc, u64 val)
{
/*
* Drop any unconsumed accumulated counts, the WRMSR is a write, not a
* read-modify-write. Adjust the counter value so that its value is
* relative to the current count, as reading the current count from
* perf is faster than pausing and repgrogramming the event in order to
* reset it to '0'. Note, this very sneakily offsets the accumulated
* emulated count too, by using pmc_read_counter()!
*/
pmc->emulated_counter = 0;
pmc->counter += val - pmc_read_counter(pmc);
pmc->counter &= pmc_bitmask(pmc);
pmc_update_sample_period(pmc);
}
EXPORT_SYMBOL_GPL(pmc_write_counter);
static int filter_cmp(const void *pa, const void *pb, u64 mask)
{
u64 a = *(u64 *)pa & mask;
u64 b = *(u64 *)pb & mask;
return (a > b) - (a < b);
}
static int filter_sort_cmp(const void *pa, const void *pb)
{
return filter_cmp(pa, pb, (KVM_PMU_MASKED_ENTRY_EVENT_SELECT |
KVM_PMU_MASKED_ENTRY_EXCLUDE));
}
/*
* For the event filter, searching is done on the 'includes' list and
* 'excludes' list separately rather than on the 'events' list (which
* has both). As a result the exclude bit can be ignored.
*/
static int filter_event_cmp(const void *pa, const void *pb)
{
return filter_cmp(pa, pb, (KVM_PMU_MASKED_ENTRY_EVENT_SELECT));
}
static int find_filter_index(u64 *events, u64 nevents, u64 key)
{
u64 *fe = bsearch(&key, events, nevents, sizeof(events[0]),
filter_event_cmp);
if (!fe)
return -1;
return fe - events;
}
static bool is_filter_entry_match(u64 filter_event, u64 umask)
{
u64 mask = filter_event >> (KVM_PMU_MASKED_ENTRY_UMASK_MASK_SHIFT - 8);
u64 match = filter_event & KVM_PMU_MASKED_ENTRY_UMASK_MATCH;
BUILD_BUG_ON((KVM_PMU_ENCODE_MASKED_ENTRY(0, 0xff, 0, false) >>
(KVM_PMU_MASKED_ENTRY_UMASK_MASK_SHIFT - 8)) !=
ARCH_PERFMON_EVENTSEL_UMASK);
return (umask & mask) == match;
}
static bool filter_contains_match(u64 *events, u64 nevents, u64 eventsel)
{
u64 event_select = eventsel & kvm_pmu_ops.EVENTSEL_EVENT;
u64 umask = eventsel & ARCH_PERFMON_EVENTSEL_UMASK;
int i, index;
index = find_filter_index(events, nevents, event_select);
if (index < 0)
return false;
/*
* Entries are sorted by the event select. Walk the list in both
* directions to process all entries with the targeted event select.
*/
for (i = index; i < nevents; i++) {
if (filter_event_cmp(&events[i], &event_select))
break;
if (is_filter_entry_match(events[i], umask))
return true;
}
for (i = index - 1; i >= 0; i--) {
if (filter_event_cmp(&events[i], &event_select))
break;
if (is_filter_entry_match(events[i], umask))
return true;
}
return false;
}
static bool is_gp_event_allowed(struct kvm_x86_pmu_event_filter *f,
u64 eventsel)
{
if (filter_contains_match(f->includes, f->nr_includes, eventsel) &&
!filter_contains_match(f->excludes, f->nr_excludes, eventsel))
return f->action == KVM_PMU_EVENT_ALLOW;
return f->action == KVM_PMU_EVENT_DENY;
}
static bool is_fixed_event_allowed(struct kvm_x86_pmu_event_filter *filter,
int idx)
{
int fixed_idx = idx - INTEL_PMC_IDX_FIXED;
if (filter->action == KVM_PMU_EVENT_DENY &&
test_bit(fixed_idx, (ulong *)&filter->fixed_counter_bitmap))
return false;
if (filter->action == KVM_PMU_EVENT_ALLOW &&
!test_bit(fixed_idx, (ulong *)&filter->fixed_counter_bitmap))
return false;
return true;
}
static bool check_pmu_event_filter(struct kvm_pmc *pmc)
{
struct kvm_x86_pmu_event_filter *filter;
struct kvm *kvm = pmc->vcpu->kvm;
filter = srcu_dereference(kvm->arch.pmu_event_filter, &kvm->srcu);
if (!filter)
return true;
if (pmc_is_gp(pmc))
return is_gp_event_allowed(filter, pmc->eventsel);
return is_fixed_event_allowed(filter, pmc->idx);
}
static bool pmc_event_is_allowed(struct kvm_pmc *pmc)
{
return pmc_is_globally_enabled(pmc) && pmc_speculative_in_use(pmc) &&
static_call(kvm_x86_pmu_hw_event_available)(pmc) &&
check_pmu_event_filter(pmc);
}
static void reprogram_counter(struct kvm_pmc *pmc)
{
struct kvm_pmu *pmu = pmc_to_pmu(pmc);
u64 eventsel = pmc->eventsel;
u64 new_config = eventsel;
bool emulate_overflow;
u8 fixed_ctr_ctrl;
emulate_overflow = pmc_pause_counter(pmc);
if (!pmc_event_is_allowed(pmc))
goto reprogram_complete;
if (emulate_overflow)
__kvm_perf_overflow(pmc, false);
if (eventsel & ARCH_PERFMON_EVENTSEL_PIN_CONTROL)
printk_once("kvm pmu: pin control bit is ignored\n");
if (pmc_is_fixed(pmc)) {
fixed_ctr_ctrl = fixed_ctrl_field(pmu->fixed_ctr_ctrl,
pmc->idx - INTEL_PMC_IDX_FIXED);
if (fixed_ctr_ctrl & 0x1)
eventsel |= ARCH_PERFMON_EVENTSEL_OS;
if (fixed_ctr_ctrl & 0x2)
eventsel |= ARCH_PERFMON_EVENTSEL_USR;
if (fixed_ctr_ctrl & 0x8)
eventsel |= ARCH_PERFMON_EVENTSEL_INT;
new_config = (u64)fixed_ctr_ctrl;
}
if (pmc->current_config == new_config && pmc_resume_counter(pmc))
goto reprogram_complete;
pmc_release_perf_event(pmc);
pmc->current_config = new_config;
/*
* If reprogramming fails, e.g. due to contention, leave the counter's
* regprogram bit set, i.e. opportunistically try again on the next PMU
* refresh. Don't make a new request as doing so can stall the guest
* if reprogramming repeatedly fails.
*/
if (pmc_reprogram_counter(pmc, PERF_TYPE_RAW,
(eventsel & pmu->raw_event_mask),
!(eventsel & ARCH_PERFMON_EVENTSEL_USR),
!(eventsel & ARCH_PERFMON_EVENTSEL_OS),
eventsel & ARCH_PERFMON_EVENTSEL_INT))
return;
reprogram_complete:
clear_bit(pmc->idx, (unsigned long *)&pmc_to_pmu(pmc)->reprogram_pmi);
}
void kvm_pmu_handle_event(struct kvm_vcpu *vcpu)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
int bit;
for_each_set_bit(bit, pmu->reprogram_pmi, X86_PMC_IDX_MAX) {
struct kvm_pmc *pmc = static_call(kvm_x86_pmu_pmc_idx_to_pmc)(pmu, bit);
if (unlikely(!pmc)) {
clear_bit(bit, pmu->reprogram_pmi);
continue;
}
reprogram_counter(pmc);
}
/*
* Unused perf_events are only released if the corresponding MSRs
* weren't accessed during the last vCPU time slice. kvm_arch_sched_in
* triggers KVM_REQ_PMU if cleanup is needed.
*/
if (unlikely(pmu->need_cleanup))
kvm_pmu_cleanup(vcpu);
}
/* check if idx is a valid index to access PMU */
bool kvm_pmu_is_valid_rdpmc_ecx(struct kvm_vcpu *vcpu, unsigned int idx)
{
return static_call(kvm_x86_pmu_is_valid_rdpmc_ecx)(vcpu, idx);
}
bool is_vmware_backdoor_pmc(u32 pmc_idx)
{
switch (pmc_idx) {
case VMWARE_BACKDOOR_PMC_HOST_TSC:
case VMWARE_BACKDOOR_PMC_REAL_TIME:
case VMWARE_BACKDOOR_PMC_APPARENT_TIME:
return true;
}
return false;
}
static int kvm_pmu_rdpmc_vmware(struct kvm_vcpu *vcpu, unsigned idx, u64 *data)
{
u64 ctr_val;
switch (idx) {
case VMWARE_BACKDOOR_PMC_HOST_TSC:
ctr_val = rdtsc();
break;
case VMWARE_BACKDOOR_PMC_REAL_TIME:
ctr_val = ktime_get_boottime_ns();
break;
case VMWARE_BACKDOOR_PMC_APPARENT_TIME:
ctr_val = ktime_get_boottime_ns() +
vcpu->kvm->arch.kvmclock_offset;
break;
default:
return 1;
}
*data = ctr_val;
return 0;
}
int kvm_pmu_rdpmc(struct kvm_vcpu *vcpu, unsigned idx, u64 *data)
{
bool fast_mode = idx & (1u << 31);
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
struct kvm_pmc *pmc;
u64 mask = fast_mode ? ~0u : ~0ull;
if (!pmu->version)
return 1;
if (is_vmware_backdoor_pmc(idx))
return kvm_pmu_rdpmc_vmware(vcpu, idx, data);
pmc = static_call(kvm_x86_pmu_rdpmc_ecx_to_pmc)(vcpu, idx, &mask);
if (!pmc)
return 1;
if (!kvm_is_cr4_bit_set(vcpu, X86_CR4_PCE) &&
(static_call(kvm_x86_get_cpl)(vcpu) != 0) &&
kvm_is_cr0_bit_set(vcpu, X86_CR0_PE))
return 1;
*data = pmc_read_counter(pmc) & mask;
return 0;
}
void kvm_pmu_deliver_pmi(struct kvm_vcpu *vcpu)
{
if (lapic_in_kernel(vcpu)) {
static_call_cond(kvm_x86_pmu_deliver_pmi)(vcpu);
kvm_apic_local_deliver(vcpu->arch.apic, APIC_LVTPC);
}
}
bool kvm_pmu_is_valid_msr(struct kvm_vcpu *vcpu, u32 msr)
{
switch (msr) {
case MSR_CORE_PERF_GLOBAL_STATUS:
case MSR_CORE_PERF_GLOBAL_CTRL:
case MSR_CORE_PERF_GLOBAL_OVF_CTRL:
return kvm_pmu_has_perf_global_ctrl(vcpu_to_pmu(vcpu));
default:
break;
}
return static_call(kvm_x86_pmu_msr_idx_to_pmc)(vcpu, msr) ||
static_call(kvm_x86_pmu_is_valid_msr)(vcpu, msr);
}
static void kvm_pmu_mark_pmc_in_use(struct kvm_vcpu *vcpu, u32 msr)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
struct kvm_pmc *pmc = static_call(kvm_x86_pmu_msr_idx_to_pmc)(vcpu, msr);
if (pmc)
__set_bit(pmc->idx, pmu->pmc_in_use);
}
int kvm_pmu_get_msr(struct kvm_vcpu *vcpu, struct msr_data *msr_info)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
u32 msr = msr_info->index;
switch (msr) {
case MSR_CORE_PERF_GLOBAL_STATUS:
case MSR_AMD64_PERF_CNTR_GLOBAL_STATUS:
msr_info->data = pmu->global_status;
break;
case MSR_AMD64_PERF_CNTR_GLOBAL_CTL:
case MSR_CORE_PERF_GLOBAL_CTRL:
msr_info->data = pmu->global_ctrl;
break;
case MSR_AMD64_PERF_CNTR_GLOBAL_STATUS_CLR:
case MSR_CORE_PERF_GLOBAL_OVF_CTRL:
msr_info->data = 0;
break;
default:
return static_call(kvm_x86_pmu_get_msr)(vcpu, msr_info);
}
return 0;
}
int kvm_pmu_set_msr(struct kvm_vcpu *vcpu, struct msr_data *msr_info)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
u32 msr = msr_info->index;
u64 data = msr_info->data;
u64 diff;
/*
* Note, AMD ignores writes to reserved bits and read-only PMU MSRs,
* whereas Intel generates #GP on attempts to write reserved/RO MSRs.
*/
switch (msr) {
case MSR_CORE_PERF_GLOBAL_STATUS:
if (!msr_info->host_initiated)
return 1; /* RO MSR */
fallthrough;
case MSR_AMD64_PERF_CNTR_GLOBAL_STATUS:
/* Per PPR, Read-only MSR. Writes are ignored. */
if (!msr_info->host_initiated)
break;
if (data & pmu->global_status_mask)
return 1;
pmu->global_status = data;
break;
case MSR_AMD64_PERF_CNTR_GLOBAL_CTL:
data &= ~pmu->global_ctrl_mask;
fallthrough;
case MSR_CORE_PERF_GLOBAL_CTRL:
if (!kvm_valid_perf_global_ctrl(pmu, data))
return 1;
if (pmu->global_ctrl != data) {
diff = pmu->global_ctrl ^ data;
pmu->global_ctrl = data;
reprogram_counters(pmu, diff);
}
break;
case MSR_CORE_PERF_GLOBAL_OVF_CTRL:
/*
* GLOBAL_OVF_CTRL, a.k.a. GLOBAL STATUS_RESET, clears bits in
* GLOBAL_STATUS, and so the set of reserved bits is the same.
*/
if (data & pmu->global_status_mask)
return 1;
fallthrough;
case MSR_AMD64_PERF_CNTR_GLOBAL_STATUS_CLR:
if (!msr_info->host_initiated)
pmu->global_status &= ~data;
break;
default:
kvm_pmu_mark_pmc_in_use(vcpu, msr_info->index);
return static_call(kvm_x86_pmu_set_msr)(vcpu, msr_info);
}
return 0;
}
static void kvm_pmu_reset(struct kvm_vcpu *vcpu)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
struct kvm_pmc *pmc;
int i;
pmu->need_cleanup = false;
bitmap_zero(pmu->reprogram_pmi, X86_PMC_IDX_MAX);
for_each_set_bit(i, pmu->all_valid_pmc_idx, X86_PMC_IDX_MAX) {
pmc = static_call(kvm_x86_pmu_pmc_idx_to_pmc)(pmu, i);
if (!pmc)
continue;
pmc_stop_counter(pmc);
pmc->counter = 0;
pmc->emulated_counter = 0;
if (pmc_is_gp(pmc))
pmc->eventsel = 0;
}
pmu->fixed_ctr_ctrl = pmu->global_ctrl = pmu->global_status = 0;
static_call_cond(kvm_x86_pmu_reset)(vcpu);
}
/*
* Refresh the PMU configuration for the vCPU, e.g. if userspace changes CPUID
* and/or PERF_CAPABILITIES.
*/
void kvm_pmu_refresh(struct kvm_vcpu *vcpu)
{
if (KVM_BUG_ON(kvm_vcpu_has_run(vcpu), vcpu->kvm))
return;
/*
* Stop/release all existing counters/events before realizing the new
* vPMU model.
*/
kvm_pmu_reset(vcpu);
bitmap_zero(vcpu_to_pmu(vcpu)->all_valid_pmc_idx, X86_PMC_IDX_MAX);
static_call(kvm_x86_pmu_refresh)(vcpu);
}
void kvm_pmu_init(struct kvm_vcpu *vcpu)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
memset(pmu, 0, sizeof(*pmu));
static_call(kvm_x86_pmu_init)(vcpu);
kvm_pmu_refresh(vcpu);
}
/* Release perf_events for vPMCs that have been unused for a full time slice. */
void kvm_pmu_cleanup(struct kvm_vcpu *vcpu)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
struct kvm_pmc *pmc = NULL;
DECLARE_BITMAP(bitmask, X86_PMC_IDX_MAX);
int i;
pmu->need_cleanup = false;
bitmap_andnot(bitmask, pmu->all_valid_pmc_idx,
pmu->pmc_in_use, X86_PMC_IDX_MAX);
for_each_set_bit(i, bitmask, X86_PMC_IDX_MAX) {
pmc = static_call(kvm_x86_pmu_pmc_idx_to_pmc)(pmu, i);
if (pmc && pmc->perf_event && !pmc_speculative_in_use(pmc))
pmc_stop_counter(pmc);
}
static_call_cond(kvm_x86_pmu_cleanup)(vcpu);
bitmap_zero(pmu->pmc_in_use, X86_PMC_IDX_MAX);
}
void kvm_pmu_destroy(struct kvm_vcpu *vcpu)
{
kvm_pmu_reset(vcpu);
}
static void kvm_pmu_incr_counter(struct kvm_pmc *pmc)
{
pmc->emulated_counter++;
kvm_pmu_request_counter_reprogram(pmc);
}
static inline bool eventsel_match_perf_hw_id(struct kvm_pmc *pmc,
unsigned int perf_hw_id)
{
return !((pmc->eventsel ^ perf_get_hw_event_config(perf_hw_id)) &
AMD64_RAW_EVENT_MASK_NB);
}
static inline bool cpl_is_matched(struct kvm_pmc *pmc)
{
bool select_os, select_user;
u64 config;
if (pmc_is_gp(pmc)) {
config = pmc->eventsel;
select_os = config & ARCH_PERFMON_EVENTSEL_OS;
select_user = config & ARCH_PERFMON_EVENTSEL_USR;
} else {
config = fixed_ctrl_field(pmc_to_pmu(pmc)->fixed_ctr_ctrl,
pmc->idx - INTEL_PMC_IDX_FIXED);
select_os = config & 0x1;
select_user = config & 0x2;
}
return (static_call(kvm_x86_get_cpl)(pmc->vcpu) == 0) ? select_os : select_user;
}
void kvm_pmu_trigger_event(struct kvm_vcpu *vcpu, u64 perf_hw_id)
{
struct kvm_pmu *pmu = vcpu_to_pmu(vcpu);
struct kvm_pmc *pmc;
int i;
for_each_set_bit(i, pmu->all_valid_pmc_idx, X86_PMC_IDX_MAX) {
pmc = static_call(kvm_x86_pmu_pmc_idx_to_pmc)(pmu, i);
if (!pmc || !pmc_event_is_allowed(pmc))
continue;
/* Ignore checks for edge detect, pin control, invert and CMASK bits */
if (eventsel_match_perf_hw_id(pmc, perf_hw_id) && cpl_is_matched(pmc))
kvm_pmu_incr_counter(pmc);
}
}
EXPORT_SYMBOL_GPL(kvm_pmu_trigger_event);
static bool is_masked_filter_valid(const struct kvm_x86_pmu_event_filter *filter)
{
u64 mask = kvm_pmu_ops.EVENTSEL_EVENT |
KVM_PMU_MASKED_ENTRY_UMASK_MASK |
KVM_PMU_MASKED_ENTRY_UMASK_MATCH |
KVM_PMU_MASKED_ENTRY_EXCLUDE;
int i;
for (i = 0; i < filter->nevents; i++) {
if (filter->events[i] & ~mask)
return false;
}
return true;
}
static void convert_to_masked_filter(struct kvm_x86_pmu_event_filter *filter)
{
int i, j;
for (i = 0, j = 0; i < filter->nevents; i++) {
/*
* Skip events that are impossible to match against a guest
* event. When filtering, only the event select + unit mask
* of the guest event is used. To maintain backwards
* compatibility, impossible filters can't be rejected :-(
*/
if (filter->events[i] & ~(kvm_pmu_ops.EVENTSEL_EVENT |
ARCH_PERFMON_EVENTSEL_UMASK))
continue;
/*
* Convert userspace events to a common in-kernel event so
* only one code path is needed to support both events. For
* the in-kernel events use masked events because they are
* flexible enough to handle both cases. To convert to masked
* events all that's needed is to add an "all ones" umask_mask,
* (unmasked filter events don't support EXCLUDE).
*/
filter->events[j++] = filter->events[i] |
(0xFFULL << KVM_PMU_MASKED_ENTRY_UMASK_MASK_SHIFT);
}
filter->nevents = j;
}
static int prepare_filter_lists(struct kvm_x86_pmu_event_filter *filter)
{
int i;
if (!(filter->flags & KVM_PMU_EVENT_FLAG_MASKED_EVENTS))
convert_to_masked_filter(filter);
else if (!is_masked_filter_valid(filter))
return -EINVAL;
/*
* Sort entries by event select and includes vs. excludes so that all
* entries for a given event select can be processed efficiently during
* filtering. The EXCLUDE flag uses a more significant bit than the
* event select, and so the sorted list is also effectively split into
* includes and excludes sub-lists.
*/
sort(&filter->events, filter->nevents, sizeof(filter->events[0]),
filter_sort_cmp, NULL);
i = filter->nevents;
/* Find the first EXCLUDE event (only supported for masked events). */
if (filter->flags & KVM_PMU_EVENT_FLAG_MASKED_EVENTS) {
for (i = 0; i < filter->nevents; i++) {
if (filter->events[i] & KVM_PMU_MASKED_ENTRY_EXCLUDE)
break;
}
}
filter->nr_includes = i;
filter->nr_excludes = filter->nevents - filter->nr_includes;
filter->includes = filter->events;
filter->excludes = filter->events + filter->nr_includes;
return 0;
}
int kvm_vm_ioctl_set_pmu_event_filter(struct kvm *kvm, void __user *argp)
{
struct kvm_pmu_event_filter __user *user_filter = argp;
struct kvm_x86_pmu_event_filter *filter;
struct kvm_pmu_event_filter tmp;
struct kvm_vcpu *vcpu;
unsigned long i;
size_t size;
int r;
if (copy_from_user(&tmp, user_filter, sizeof(tmp)))
return -EFAULT;
if (tmp.action != KVM_PMU_EVENT_ALLOW &&
tmp.action != KVM_PMU_EVENT_DENY)
return -EINVAL;
if (tmp.flags & ~KVM_PMU_EVENT_FLAGS_VALID_MASK)
return -EINVAL;
if (tmp.nevents > KVM_PMU_EVENT_FILTER_MAX_EVENTS)
return -E2BIG;
size = struct_size(filter, events, tmp.nevents);
filter = kzalloc(size, GFP_KERNEL_ACCOUNT);
if (!filter)
return -ENOMEM;
filter->action = tmp.action;
filter->nevents = tmp.nevents;
filter->fixed_counter_bitmap = tmp.fixed_counter_bitmap;
filter->flags = tmp.flags;
r = -EFAULT;
if (copy_from_user(filter->events, user_filter->events,
sizeof(filter->events[0]) * filter->nevents))
goto cleanup;
r = prepare_filter_lists(filter);
if (r)
goto cleanup;
mutex_lock(&kvm->lock);
filter = rcu_replace_pointer(kvm->arch.pmu_event_filter, filter,
mutex_is_locked(&kvm->lock));
mutex_unlock(&kvm->lock);
synchronize_srcu_expedited(&kvm->srcu);
BUILD_BUG_ON(sizeof(((struct kvm_pmu *)0)->reprogram_pmi) >
sizeof(((struct kvm_pmu *)0)->__reprogram_pmi));
kvm_for_each_vcpu(i, vcpu, kvm)
atomic64_set(&vcpu_to_pmu(vcpu)->__reprogram_pmi, -1ull);
kvm_make_all_cpus_request(kvm, KVM_REQ_PMU);
r = 0;
cleanup:
kfree(filter);
return r;
}
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