linux/kernel/events/core.c
Andrii Nakryiko 66c8473135 bpf: move sleepable flag from bpf_prog_aux to bpf_prog
prog->aux->sleepable is checked very frequently as part of (some) BPF
program run hot paths. So this extra aux indirection seems wasteful and
on busy systems might cause unnecessary memory cache misses.

Let's move sleepable flag into prog itself to eliminate unnecessary
pointer dereference.

Signed-off-by: Andrii Nakryiko <andrii@kernel.org>
Acked-by: Jiri Olsa <jolsa@kernel.org>
Message-ID: <20240309004739.2961431-1-andrii@kernel.org>
Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2024-03-11 16:41:25 -07:00

13888 lines
334 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Performance events core code:
*
* Copyright (C) 2008 Thomas Gleixner <tglx@linutronix.de>
* Copyright (C) 2008-2011 Red Hat, Inc., Ingo Molnar
* Copyright (C) 2008-2011 Red Hat, Inc., Peter Zijlstra
* Copyright © 2009 Paul Mackerras, IBM Corp. <paulus@au1.ibm.com>
*/
#include <linux/fs.h>
#include <linux/mm.h>
#include <linux/cpu.h>
#include <linux/smp.h>
#include <linux/idr.h>
#include <linux/file.h>
#include <linux/poll.h>
#include <linux/slab.h>
#include <linux/hash.h>
#include <linux/tick.h>
#include <linux/sysfs.h>
#include <linux/dcache.h>
#include <linux/percpu.h>
#include <linux/ptrace.h>
#include <linux/reboot.h>
#include <linux/vmstat.h>
#include <linux/device.h>
#include <linux/export.h>
#include <linux/vmalloc.h>
#include <linux/hardirq.h>
#include <linux/hugetlb.h>
#include <linux/rculist.h>
#include <linux/uaccess.h>
#include <linux/syscalls.h>
#include <linux/anon_inodes.h>
#include <linux/kernel_stat.h>
#include <linux/cgroup.h>
#include <linux/perf_event.h>
#include <linux/trace_events.h>
#include <linux/hw_breakpoint.h>
#include <linux/mm_types.h>
#include <linux/module.h>
#include <linux/mman.h>
#include <linux/compat.h>
#include <linux/bpf.h>
#include <linux/filter.h>
#include <linux/namei.h>
#include <linux/parser.h>
#include <linux/sched/clock.h>
#include <linux/sched/mm.h>
#include <linux/proc_ns.h>
#include <linux/mount.h>
#include <linux/min_heap.h>
#include <linux/highmem.h>
#include <linux/pgtable.h>
#include <linux/buildid.h>
#include <linux/task_work.h>
#include "internal.h"
#include <asm/irq_regs.h>
typedef int (*remote_function_f)(void *);
struct remote_function_call {
struct task_struct *p;
remote_function_f func;
void *info;
int ret;
};
static void remote_function(void *data)
{
struct remote_function_call *tfc = data;
struct task_struct *p = tfc->p;
if (p) {
/* -EAGAIN */
if (task_cpu(p) != smp_processor_id())
return;
/*
* Now that we're on right CPU with IRQs disabled, we can test
* if we hit the right task without races.
*/
tfc->ret = -ESRCH; /* No such (running) process */
if (p != current)
return;
}
tfc->ret = tfc->func(tfc->info);
}
/**
* task_function_call - call a function on the cpu on which a task runs
* @p: the task to evaluate
* @func: the function to be called
* @info: the function call argument
*
* Calls the function @func when the task is currently running. This might
* be on the current CPU, which just calls the function directly. This will
* retry due to any failures in smp_call_function_single(), such as if the
* task_cpu() goes offline concurrently.
*
* returns @func return value or -ESRCH or -ENXIO when the process isn't running
*/
static int
task_function_call(struct task_struct *p, remote_function_f func, void *info)
{
struct remote_function_call data = {
.p = p,
.func = func,
.info = info,
.ret = -EAGAIN,
};
int ret;
for (;;) {
ret = smp_call_function_single(task_cpu(p), remote_function,
&data, 1);
if (!ret)
ret = data.ret;
if (ret != -EAGAIN)
break;
cond_resched();
}
return ret;
}
/**
* cpu_function_call - call a function on the cpu
* @cpu: target cpu to queue this function
* @func: the function to be called
* @info: the function call argument
*
* Calls the function @func on the remote cpu.
*
* returns: @func return value or -ENXIO when the cpu is offline
*/
static int cpu_function_call(int cpu, remote_function_f func, void *info)
{
struct remote_function_call data = {
.p = NULL,
.func = func,
.info = info,
.ret = -ENXIO, /* No such CPU */
};
smp_call_function_single(cpu, remote_function, &data, 1);
return data.ret;
}
static void perf_ctx_lock(struct perf_cpu_context *cpuctx,
struct perf_event_context *ctx)
{
raw_spin_lock(&cpuctx->ctx.lock);
if (ctx)
raw_spin_lock(&ctx->lock);
}
static void perf_ctx_unlock(struct perf_cpu_context *cpuctx,
struct perf_event_context *ctx)
{
if (ctx)
raw_spin_unlock(&ctx->lock);
raw_spin_unlock(&cpuctx->ctx.lock);
}
#define TASK_TOMBSTONE ((void *)-1L)
static bool is_kernel_event(struct perf_event *event)
{
return READ_ONCE(event->owner) == TASK_TOMBSTONE;
}
static DEFINE_PER_CPU(struct perf_cpu_context, perf_cpu_context);
struct perf_event_context *perf_cpu_task_ctx(void)
{
lockdep_assert_irqs_disabled();
return this_cpu_ptr(&perf_cpu_context)->task_ctx;
}
/*
* On task ctx scheduling...
*
* When !ctx->nr_events a task context will not be scheduled. This means
* we can disable the scheduler hooks (for performance) without leaving
* pending task ctx state.
*
* This however results in two special cases:
*
* - removing the last event from a task ctx; this is relatively straight
* forward and is done in __perf_remove_from_context.
*
* - adding the first event to a task ctx; this is tricky because we cannot
* rely on ctx->is_active and therefore cannot use event_function_call().
* See perf_install_in_context().
*
* If ctx->nr_events, then ctx->is_active and cpuctx->task_ctx are set.
*/
typedef void (*event_f)(struct perf_event *, struct perf_cpu_context *,
struct perf_event_context *, void *);
struct event_function_struct {
struct perf_event *event;
event_f func;
void *data;
};
static int event_function(void *info)
{
struct event_function_struct *efs = info;
struct perf_event *event = efs->event;
struct perf_event_context *ctx = event->ctx;
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_context *task_ctx = cpuctx->task_ctx;
int ret = 0;
lockdep_assert_irqs_disabled();
perf_ctx_lock(cpuctx, task_ctx);
/*
* Since we do the IPI call without holding ctx->lock things can have
* changed, double check we hit the task we set out to hit.
*/
if (ctx->task) {
if (ctx->task != current) {
ret = -ESRCH;
goto unlock;
}
/*
* We only use event_function_call() on established contexts,
* and event_function() is only ever called when active (or
* rather, we'll have bailed in task_function_call() or the
* above ctx->task != current test), therefore we must have
* ctx->is_active here.
*/
WARN_ON_ONCE(!ctx->is_active);
/*
* And since we have ctx->is_active, cpuctx->task_ctx must
* match.
*/
WARN_ON_ONCE(task_ctx != ctx);
} else {
WARN_ON_ONCE(&cpuctx->ctx != ctx);
}
efs->func(event, cpuctx, ctx, efs->data);
unlock:
perf_ctx_unlock(cpuctx, task_ctx);
return ret;
}
static void event_function_call(struct perf_event *event, event_f func, void *data)
{
struct perf_event_context *ctx = event->ctx;
struct task_struct *task = READ_ONCE(ctx->task); /* verified in event_function */
struct event_function_struct efs = {
.event = event,
.func = func,
.data = data,
};
if (!event->parent) {
/*
* If this is a !child event, we must hold ctx::mutex to
* stabilize the event->ctx relation. See
* perf_event_ctx_lock().
*/
lockdep_assert_held(&ctx->mutex);
}
if (!task) {
cpu_function_call(event->cpu, event_function, &efs);
return;
}
if (task == TASK_TOMBSTONE)
return;
again:
if (!task_function_call(task, event_function, &efs))
return;
raw_spin_lock_irq(&ctx->lock);
/*
* Reload the task pointer, it might have been changed by
* a concurrent perf_event_context_sched_out().
*/
task = ctx->task;
if (task == TASK_TOMBSTONE) {
raw_spin_unlock_irq(&ctx->lock);
return;
}
if (ctx->is_active) {
raw_spin_unlock_irq(&ctx->lock);
goto again;
}
func(event, NULL, ctx, data);
raw_spin_unlock_irq(&ctx->lock);
}
/*
* Similar to event_function_call() + event_function(), but hard assumes IRQs
* are already disabled and we're on the right CPU.
*/
static void event_function_local(struct perf_event *event, event_f func, void *data)
{
struct perf_event_context *ctx = event->ctx;
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct task_struct *task = READ_ONCE(ctx->task);
struct perf_event_context *task_ctx = NULL;
lockdep_assert_irqs_disabled();
if (task) {
if (task == TASK_TOMBSTONE)
return;
task_ctx = ctx;
}
perf_ctx_lock(cpuctx, task_ctx);
task = ctx->task;
if (task == TASK_TOMBSTONE)
goto unlock;
if (task) {
/*
* We must be either inactive or active and the right task,
* otherwise we're screwed, since we cannot IPI to somewhere
* else.
*/
if (ctx->is_active) {
if (WARN_ON_ONCE(task != current))
goto unlock;
if (WARN_ON_ONCE(cpuctx->task_ctx != ctx))
goto unlock;
}
} else {
WARN_ON_ONCE(&cpuctx->ctx != ctx);
}
func(event, cpuctx, ctx, data);
unlock:
perf_ctx_unlock(cpuctx, task_ctx);
}
#define PERF_FLAG_ALL (PERF_FLAG_FD_NO_GROUP |\
PERF_FLAG_FD_OUTPUT |\
PERF_FLAG_PID_CGROUP |\
PERF_FLAG_FD_CLOEXEC)
/*
* branch priv levels that need permission checks
*/
#define PERF_SAMPLE_BRANCH_PERM_PLM \
(PERF_SAMPLE_BRANCH_KERNEL |\
PERF_SAMPLE_BRANCH_HV)
enum event_type_t {
EVENT_FLEXIBLE = 0x1,
EVENT_PINNED = 0x2,
EVENT_TIME = 0x4,
/* see ctx_resched() for details */
EVENT_CPU = 0x8,
EVENT_CGROUP = 0x10,
EVENT_ALL = EVENT_FLEXIBLE | EVENT_PINNED,
};
/*
* perf_sched_events : >0 events exist
*/
static void perf_sched_delayed(struct work_struct *work);
DEFINE_STATIC_KEY_FALSE(perf_sched_events);
static DECLARE_DELAYED_WORK(perf_sched_work, perf_sched_delayed);
static DEFINE_MUTEX(perf_sched_mutex);
static atomic_t perf_sched_count;
static DEFINE_PER_CPU(struct pmu_event_list, pmu_sb_events);
static atomic_t nr_mmap_events __read_mostly;
static atomic_t nr_comm_events __read_mostly;
static atomic_t nr_namespaces_events __read_mostly;
static atomic_t nr_task_events __read_mostly;
static atomic_t nr_freq_events __read_mostly;
static atomic_t nr_switch_events __read_mostly;
static atomic_t nr_ksymbol_events __read_mostly;
static atomic_t nr_bpf_events __read_mostly;
static atomic_t nr_cgroup_events __read_mostly;
static atomic_t nr_text_poke_events __read_mostly;
static atomic_t nr_build_id_events __read_mostly;
static LIST_HEAD(pmus);
static DEFINE_MUTEX(pmus_lock);
static struct srcu_struct pmus_srcu;
static cpumask_var_t perf_online_mask;
static struct kmem_cache *perf_event_cache;
/*
* perf event paranoia level:
* -1 - not paranoid at all
* 0 - disallow raw tracepoint access for unpriv
* 1 - disallow cpu events for unpriv
* 2 - disallow kernel profiling for unpriv
*/
int sysctl_perf_event_paranoid __read_mostly = 2;
/* Minimum for 512 kiB + 1 user control page */
int sysctl_perf_event_mlock __read_mostly = 512 + (PAGE_SIZE / 1024); /* 'free' kiB per user */
/*
* max perf event sample rate
*/
#define DEFAULT_MAX_SAMPLE_RATE 100000
#define DEFAULT_SAMPLE_PERIOD_NS (NSEC_PER_SEC / DEFAULT_MAX_SAMPLE_RATE)
#define DEFAULT_CPU_TIME_MAX_PERCENT 25
int sysctl_perf_event_sample_rate __read_mostly = DEFAULT_MAX_SAMPLE_RATE;
static int max_samples_per_tick __read_mostly = DIV_ROUND_UP(DEFAULT_MAX_SAMPLE_RATE, HZ);
static int perf_sample_period_ns __read_mostly = DEFAULT_SAMPLE_PERIOD_NS;
static int perf_sample_allowed_ns __read_mostly =
DEFAULT_SAMPLE_PERIOD_NS * DEFAULT_CPU_TIME_MAX_PERCENT / 100;
static void update_perf_cpu_limits(void)
{
u64 tmp = perf_sample_period_ns;
tmp *= sysctl_perf_cpu_time_max_percent;
tmp = div_u64(tmp, 100);
if (!tmp)
tmp = 1;
WRITE_ONCE(perf_sample_allowed_ns, tmp);
}
static bool perf_rotate_context(struct perf_cpu_pmu_context *cpc);
int perf_event_max_sample_rate_handler(struct ctl_table *table, int write,
void *buffer, size_t *lenp, loff_t *ppos)
{
int ret;
int perf_cpu = sysctl_perf_cpu_time_max_percent;
/*
* If throttling is disabled don't allow the write:
*/
if (write && (perf_cpu == 100 || perf_cpu == 0))
return -EINVAL;
ret = proc_dointvec_minmax(table, write, buffer, lenp, ppos);
if (ret || !write)
return ret;
max_samples_per_tick = DIV_ROUND_UP(sysctl_perf_event_sample_rate, HZ);
perf_sample_period_ns = NSEC_PER_SEC / sysctl_perf_event_sample_rate;
update_perf_cpu_limits();
return 0;
}
int sysctl_perf_cpu_time_max_percent __read_mostly = DEFAULT_CPU_TIME_MAX_PERCENT;
int perf_cpu_time_max_percent_handler(struct ctl_table *table, int write,
void *buffer, size_t *lenp, loff_t *ppos)
{
int ret = proc_dointvec_minmax(table, write, buffer, lenp, ppos);
if (ret || !write)
return ret;
if (sysctl_perf_cpu_time_max_percent == 100 ||
sysctl_perf_cpu_time_max_percent == 0) {
printk(KERN_WARNING
"perf: Dynamic interrupt throttling disabled, can hang your system!\n");
WRITE_ONCE(perf_sample_allowed_ns, 0);
} else {
update_perf_cpu_limits();
}
return 0;
}
/*
* perf samples are done in some very critical code paths (NMIs).
* If they take too much CPU time, the system can lock up and not
* get any real work done. This will drop the sample rate when
* we detect that events are taking too long.
*/
#define NR_ACCUMULATED_SAMPLES 128
static DEFINE_PER_CPU(u64, running_sample_length);
static u64 __report_avg;
static u64 __report_allowed;
static void perf_duration_warn(struct irq_work *w)
{
printk_ratelimited(KERN_INFO
"perf: interrupt took too long (%lld > %lld), lowering "
"kernel.perf_event_max_sample_rate to %d\n",
__report_avg, __report_allowed,
sysctl_perf_event_sample_rate);
}
static DEFINE_IRQ_WORK(perf_duration_work, perf_duration_warn);
void perf_sample_event_took(u64 sample_len_ns)
{
u64 max_len = READ_ONCE(perf_sample_allowed_ns);
u64 running_len;
u64 avg_len;
u32 max;
if (max_len == 0)
return;
/* Decay the counter by 1 average sample. */
running_len = __this_cpu_read(running_sample_length);
running_len -= running_len/NR_ACCUMULATED_SAMPLES;
running_len += sample_len_ns;
__this_cpu_write(running_sample_length, running_len);
/*
* Note: this will be biased artifically low until we have
* seen NR_ACCUMULATED_SAMPLES. Doing it this way keeps us
* from having to maintain a count.
*/
avg_len = running_len/NR_ACCUMULATED_SAMPLES;
if (avg_len <= max_len)
return;
__report_avg = avg_len;
__report_allowed = max_len;
/*
* Compute a throttle threshold 25% below the current duration.
*/
avg_len += avg_len / 4;
max = (TICK_NSEC / 100) * sysctl_perf_cpu_time_max_percent;
if (avg_len < max)
max /= (u32)avg_len;
else
max = 1;
WRITE_ONCE(perf_sample_allowed_ns, avg_len);
WRITE_ONCE(max_samples_per_tick, max);
sysctl_perf_event_sample_rate = max * HZ;
perf_sample_period_ns = NSEC_PER_SEC / sysctl_perf_event_sample_rate;
if (!irq_work_queue(&perf_duration_work)) {
early_printk("perf: interrupt took too long (%lld > %lld), lowering "
"kernel.perf_event_max_sample_rate to %d\n",
__report_avg, __report_allowed,
sysctl_perf_event_sample_rate);
}
}
static atomic64_t perf_event_id;
static void update_context_time(struct perf_event_context *ctx);
static u64 perf_event_time(struct perf_event *event);
void __weak perf_event_print_debug(void) { }
static inline u64 perf_clock(void)
{
return local_clock();
}
static inline u64 perf_event_clock(struct perf_event *event)
{
return event->clock();
}
/*
* State based event timekeeping...
*
* The basic idea is to use event->state to determine which (if any) time
* fields to increment with the current delta. This means we only need to
* update timestamps when we change state or when they are explicitly requested
* (read).
*
* Event groups make things a little more complicated, but not terribly so. The
* rules for a group are that if the group leader is OFF the entire group is
* OFF, irrespecive of what the group member states are. This results in
* __perf_effective_state().
*
* A futher ramification is that when a group leader flips between OFF and
* !OFF, we need to update all group member times.
*
*
* NOTE: perf_event_time() is based on the (cgroup) context time, and thus we
* need to make sure the relevant context time is updated before we try and
* update our timestamps.
*/
static __always_inline enum perf_event_state
__perf_effective_state(struct perf_event *event)
{
struct perf_event *leader = event->group_leader;
if (leader->state <= PERF_EVENT_STATE_OFF)
return leader->state;
return event->state;
}
static __always_inline void
__perf_update_times(struct perf_event *event, u64 now, u64 *enabled, u64 *running)
{
enum perf_event_state state = __perf_effective_state(event);
u64 delta = now - event->tstamp;
*enabled = event->total_time_enabled;
if (state >= PERF_EVENT_STATE_INACTIVE)
*enabled += delta;
*running = event->total_time_running;
if (state >= PERF_EVENT_STATE_ACTIVE)
*running += delta;
}
static void perf_event_update_time(struct perf_event *event)
{
u64 now = perf_event_time(event);
__perf_update_times(event, now, &event->total_time_enabled,
&event->total_time_running);
event->tstamp = now;
}
static void perf_event_update_sibling_time(struct perf_event *leader)
{
struct perf_event *sibling;
for_each_sibling_event(sibling, leader)
perf_event_update_time(sibling);
}
static void
perf_event_set_state(struct perf_event *event, enum perf_event_state state)
{
if (event->state == state)
return;
perf_event_update_time(event);
/*
* If a group leader gets enabled/disabled all its siblings
* are affected too.
*/
if ((event->state < 0) ^ (state < 0))
perf_event_update_sibling_time(event);
WRITE_ONCE(event->state, state);
}
/*
* UP store-release, load-acquire
*/
#define __store_release(ptr, val) \
do { \
barrier(); \
WRITE_ONCE(*(ptr), (val)); \
} while (0)
#define __load_acquire(ptr) \
({ \
__unqual_scalar_typeof(*(ptr)) ___p = READ_ONCE(*(ptr)); \
barrier(); \
___p; \
})
static void perf_ctx_disable(struct perf_event_context *ctx, bool cgroup)
{
struct perf_event_pmu_context *pmu_ctx;
list_for_each_entry(pmu_ctx, &ctx->pmu_ctx_list, pmu_ctx_entry) {
if (cgroup && !pmu_ctx->nr_cgroups)
continue;
perf_pmu_disable(pmu_ctx->pmu);
}
}
static void perf_ctx_enable(struct perf_event_context *ctx, bool cgroup)
{
struct perf_event_pmu_context *pmu_ctx;
list_for_each_entry(pmu_ctx, &ctx->pmu_ctx_list, pmu_ctx_entry) {
if (cgroup && !pmu_ctx->nr_cgroups)
continue;
perf_pmu_enable(pmu_ctx->pmu);
}
}
static void ctx_sched_out(struct perf_event_context *ctx, enum event_type_t event_type);
static void ctx_sched_in(struct perf_event_context *ctx, enum event_type_t event_type);
#ifdef CONFIG_CGROUP_PERF
static inline bool
perf_cgroup_match(struct perf_event *event)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
/* @event doesn't care about cgroup */
if (!event->cgrp)
return true;
/* wants specific cgroup scope but @cpuctx isn't associated with any */
if (!cpuctx->cgrp)
return false;
/*
* Cgroup scoping is recursive. An event enabled for a cgroup is
* also enabled for all its descendant cgroups. If @cpuctx's
* cgroup is a descendant of @event's (the test covers identity
* case), it's a match.
*/
return cgroup_is_descendant(cpuctx->cgrp->css.cgroup,
event->cgrp->css.cgroup);
}
static inline void perf_detach_cgroup(struct perf_event *event)
{
css_put(&event->cgrp->css);
event->cgrp = NULL;
}
static inline int is_cgroup_event(struct perf_event *event)
{
return event->cgrp != NULL;
}
static inline u64 perf_cgroup_event_time(struct perf_event *event)
{
struct perf_cgroup_info *t;
t = per_cpu_ptr(event->cgrp->info, event->cpu);
return t->time;
}
static inline u64 perf_cgroup_event_time_now(struct perf_event *event, u64 now)
{
struct perf_cgroup_info *t;
t = per_cpu_ptr(event->cgrp->info, event->cpu);
if (!__load_acquire(&t->active))
return t->time;
now += READ_ONCE(t->timeoffset);
return now;
}
static inline void __update_cgrp_time(struct perf_cgroup_info *info, u64 now, bool adv)
{
if (adv)
info->time += now - info->timestamp;
info->timestamp = now;
/*
* see update_context_time()
*/
WRITE_ONCE(info->timeoffset, info->time - info->timestamp);
}
static inline void update_cgrp_time_from_cpuctx(struct perf_cpu_context *cpuctx, bool final)
{
struct perf_cgroup *cgrp = cpuctx->cgrp;
struct cgroup_subsys_state *css;
struct perf_cgroup_info *info;
if (cgrp) {
u64 now = perf_clock();
for (css = &cgrp->css; css; css = css->parent) {
cgrp = container_of(css, struct perf_cgroup, css);
info = this_cpu_ptr(cgrp->info);
__update_cgrp_time(info, now, true);
if (final)
__store_release(&info->active, 0);
}
}
}
static inline void update_cgrp_time_from_event(struct perf_event *event)
{
struct perf_cgroup_info *info;
/*
* ensure we access cgroup data only when needed and
* when we know the cgroup is pinned (css_get)
*/
if (!is_cgroup_event(event))
return;
info = this_cpu_ptr(event->cgrp->info);
/*
* Do not update time when cgroup is not active
*/
if (info->active)
__update_cgrp_time(info, perf_clock(), true);
}
static inline void
perf_cgroup_set_timestamp(struct perf_cpu_context *cpuctx)
{
struct perf_event_context *ctx = &cpuctx->ctx;
struct perf_cgroup *cgrp = cpuctx->cgrp;
struct perf_cgroup_info *info;
struct cgroup_subsys_state *css;
/*
* ctx->lock held by caller
* ensure we do not access cgroup data
* unless we have the cgroup pinned (css_get)
*/
if (!cgrp)
return;
WARN_ON_ONCE(!ctx->nr_cgroups);
for (css = &cgrp->css; css; css = css->parent) {
cgrp = container_of(css, struct perf_cgroup, css);
info = this_cpu_ptr(cgrp->info);
__update_cgrp_time(info, ctx->timestamp, false);
__store_release(&info->active, 1);
}
}
/*
* reschedule events based on the cgroup constraint of task.
*/
static void perf_cgroup_switch(struct task_struct *task)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_cgroup *cgrp;
/*
* cpuctx->cgrp is set when the first cgroup event enabled,
* and is cleared when the last cgroup event disabled.
*/
if (READ_ONCE(cpuctx->cgrp) == NULL)
return;
WARN_ON_ONCE(cpuctx->ctx.nr_cgroups == 0);
cgrp = perf_cgroup_from_task(task, NULL);
if (READ_ONCE(cpuctx->cgrp) == cgrp)
return;
perf_ctx_lock(cpuctx, cpuctx->task_ctx);
perf_ctx_disable(&cpuctx->ctx, true);
ctx_sched_out(&cpuctx->ctx, EVENT_ALL|EVENT_CGROUP);
/*
* must not be done before ctxswout due
* to update_cgrp_time_from_cpuctx() in
* ctx_sched_out()
*/
cpuctx->cgrp = cgrp;
/*
* set cgrp before ctxsw in to allow
* perf_cgroup_set_timestamp() in ctx_sched_in()
* to not have to pass task around
*/
ctx_sched_in(&cpuctx->ctx, EVENT_ALL|EVENT_CGROUP);
perf_ctx_enable(&cpuctx->ctx, true);
perf_ctx_unlock(cpuctx, cpuctx->task_ctx);
}
static int perf_cgroup_ensure_storage(struct perf_event *event,
struct cgroup_subsys_state *css)
{
struct perf_cpu_context *cpuctx;
struct perf_event **storage;
int cpu, heap_size, ret = 0;
/*
* Allow storage to have sufficent space for an iterator for each
* possibly nested cgroup plus an iterator for events with no cgroup.
*/
for (heap_size = 1; css; css = css->parent)
heap_size++;
for_each_possible_cpu(cpu) {
cpuctx = per_cpu_ptr(&perf_cpu_context, cpu);
if (heap_size <= cpuctx->heap_size)
continue;
storage = kmalloc_node(heap_size * sizeof(struct perf_event *),
GFP_KERNEL, cpu_to_node(cpu));
if (!storage) {
ret = -ENOMEM;
break;
}
raw_spin_lock_irq(&cpuctx->ctx.lock);
if (cpuctx->heap_size < heap_size) {
swap(cpuctx->heap, storage);
if (storage == cpuctx->heap_default)
storage = NULL;
cpuctx->heap_size = heap_size;
}
raw_spin_unlock_irq(&cpuctx->ctx.lock);
kfree(storage);
}
return ret;
}
static inline int perf_cgroup_connect(int fd, struct perf_event *event,
struct perf_event_attr *attr,
struct perf_event *group_leader)
{
struct perf_cgroup *cgrp;
struct cgroup_subsys_state *css;
struct fd f = fdget(fd);
int ret = 0;
if (!f.file)
return -EBADF;
css = css_tryget_online_from_dir(f.file->f_path.dentry,
&perf_event_cgrp_subsys);
if (IS_ERR(css)) {
ret = PTR_ERR(css);
goto out;
}
ret = perf_cgroup_ensure_storage(event, css);
if (ret)
goto out;
cgrp = container_of(css, struct perf_cgroup, css);
event->cgrp = cgrp;
/*
* all events in a group must monitor
* the same cgroup because a task belongs
* to only one perf cgroup at a time
*/
if (group_leader && group_leader->cgrp != cgrp) {
perf_detach_cgroup(event);
ret = -EINVAL;
}
out:
fdput(f);
return ret;
}
static inline void
perf_cgroup_event_enable(struct perf_event *event, struct perf_event_context *ctx)
{
struct perf_cpu_context *cpuctx;
if (!is_cgroup_event(event))
return;
event->pmu_ctx->nr_cgroups++;
/*
* Because cgroup events are always per-cpu events,
* @ctx == &cpuctx->ctx.
*/
cpuctx = container_of(ctx, struct perf_cpu_context, ctx);
if (ctx->nr_cgroups++)
return;
cpuctx->cgrp = perf_cgroup_from_task(current, ctx);
}
static inline void
perf_cgroup_event_disable(struct perf_event *event, struct perf_event_context *ctx)
{
struct perf_cpu_context *cpuctx;
if (!is_cgroup_event(event))
return;
event->pmu_ctx->nr_cgroups--;
/*
* Because cgroup events are always per-cpu events,
* @ctx == &cpuctx->ctx.
*/
cpuctx = container_of(ctx, struct perf_cpu_context, ctx);
if (--ctx->nr_cgroups)
return;
cpuctx->cgrp = NULL;
}
#else /* !CONFIG_CGROUP_PERF */
static inline bool
perf_cgroup_match(struct perf_event *event)
{
return true;
}
static inline void perf_detach_cgroup(struct perf_event *event)
{}
static inline int is_cgroup_event(struct perf_event *event)
{
return 0;
}
static inline void update_cgrp_time_from_event(struct perf_event *event)
{
}
static inline void update_cgrp_time_from_cpuctx(struct perf_cpu_context *cpuctx,
bool final)
{
}
static inline int perf_cgroup_connect(pid_t pid, struct perf_event *event,
struct perf_event_attr *attr,
struct perf_event *group_leader)
{
return -EINVAL;
}
static inline void
perf_cgroup_set_timestamp(struct perf_cpu_context *cpuctx)
{
}
static inline u64 perf_cgroup_event_time(struct perf_event *event)
{
return 0;
}
static inline u64 perf_cgroup_event_time_now(struct perf_event *event, u64 now)
{
return 0;
}
static inline void
perf_cgroup_event_enable(struct perf_event *event, struct perf_event_context *ctx)
{
}
static inline void
perf_cgroup_event_disable(struct perf_event *event, struct perf_event_context *ctx)
{
}
static void perf_cgroup_switch(struct task_struct *task)
{
}
#endif
/*
* set default to be dependent on timer tick just
* like original code
*/
#define PERF_CPU_HRTIMER (1000 / HZ)
/*
* function must be called with interrupts disabled
*/
static enum hrtimer_restart perf_mux_hrtimer_handler(struct hrtimer *hr)
{
struct perf_cpu_pmu_context *cpc;
bool rotations;
lockdep_assert_irqs_disabled();
cpc = container_of(hr, struct perf_cpu_pmu_context, hrtimer);
rotations = perf_rotate_context(cpc);
raw_spin_lock(&cpc->hrtimer_lock);
if (rotations)
hrtimer_forward_now(hr, cpc->hrtimer_interval);
else
cpc->hrtimer_active = 0;
raw_spin_unlock(&cpc->hrtimer_lock);
return rotations ? HRTIMER_RESTART : HRTIMER_NORESTART;
}
static void __perf_mux_hrtimer_init(struct perf_cpu_pmu_context *cpc, int cpu)
{
struct hrtimer *timer = &cpc->hrtimer;
struct pmu *pmu = cpc->epc.pmu;
u64 interval;
/*
* check default is sane, if not set then force to
* default interval (1/tick)
*/
interval = pmu->hrtimer_interval_ms;
if (interval < 1)
interval = pmu->hrtimer_interval_ms = PERF_CPU_HRTIMER;
cpc->hrtimer_interval = ns_to_ktime(NSEC_PER_MSEC * interval);
raw_spin_lock_init(&cpc->hrtimer_lock);
hrtimer_init(timer, CLOCK_MONOTONIC, HRTIMER_MODE_ABS_PINNED_HARD);
timer->function = perf_mux_hrtimer_handler;
}
static int perf_mux_hrtimer_restart(struct perf_cpu_pmu_context *cpc)
{
struct hrtimer *timer = &cpc->hrtimer;
unsigned long flags;
raw_spin_lock_irqsave(&cpc->hrtimer_lock, flags);
if (!cpc->hrtimer_active) {
cpc->hrtimer_active = 1;
hrtimer_forward_now(timer, cpc->hrtimer_interval);
hrtimer_start_expires(timer, HRTIMER_MODE_ABS_PINNED_HARD);
}
raw_spin_unlock_irqrestore(&cpc->hrtimer_lock, flags);
return 0;
}
static int perf_mux_hrtimer_restart_ipi(void *arg)
{
return perf_mux_hrtimer_restart(arg);
}
void perf_pmu_disable(struct pmu *pmu)
{
int *count = this_cpu_ptr(pmu->pmu_disable_count);
if (!(*count)++)
pmu->pmu_disable(pmu);
}
void perf_pmu_enable(struct pmu *pmu)
{
int *count = this_cpu_ptr(pmu->pmu_disable_count);
if (!--(*count))
pmu->pmu_enable(pmu);
}
static void perf_assert_pmu_disabled(struct pmu *pmu)
{
WARN_ON_ONCE(*this_cpu_ptr(pmu->pmu_disable_count) == 0);
}
static void get_ctx(struct perf_event_context *ctx)
{
refcount_inc(&ctx->refcount);
}
static void *alloc_task_ctx_data(struct pmu *pmu)
{
if (pmu->task_ctx_cache)
return kmem_cache_zalloc(pmu->task_ctx_cache, GFP_KERNEL);
return NULL;
}
static void free_task_ctx_data(struct pmu *pmu, void *task_ctx_data)
{
if (pmu->task_ctx_cache && task_ctx_data)
kmem_cache_free(pmu->task_ctx_cache, task_ctx_data);
}
static void free_ctx(struct rcu_head *head)
{
struct perf_event_context *ctx;
ctx = container_of(head, struct perf_event_context, rcu_head);
kfree(ctx);
}
static void put_ctx(struct perf_event_context *ctx)
{
if (refcount_dec_and_test(&ctx->refcount)) {
if (ctx->parent_ctx)
put_ctx(ctx->parent_ctx);
if (ctx->task && ctx->task != TASK_TOMBSTONE)
put_task_struct(ctx->task);
call_rcu(&ctx->rcu_head, free_ctx);
}
}
/*
* Because of perf_event::ctx migration in sys_perf_event_open::move_group and
* perf_pmu_migrate_context() we need some magic.
*
* Those places that change perf_event::ctx will hold both
* perf_event_ctx::mutex of the 'old' and 'new' ctx value.
*
* Lock ordering is by mutex address. There are two other sites where
* perf_event_context::mutex nests and those are:
*
* - perf_event_exit_task_context() [ child , 0 ]
* perf_event_exit_event()
* put_event() [ parent, 1 ]
*
* - perf_event_init_context() [ parent, 0 ]
* inherit_task_group()
* inherit_group()
* inherit_event()
* perf_event_alloc()
* perf_init_event()
* perf_try_init_event() [ child , 1 ]
*
* While it appears there is an obvious deadlock here -- the parent and child
* nesting levels are inverted between the two. This is in fact safe because
* life-time rules separate them. That is an exiting task cannot fork, and a
* spawning task cannot (yet) exit.
*
* But remember that these are parent<->child context relations, and
* migration does not affect children, therefore these two orderings should not
* interact.
*
* The change in perf_event::ctx does not affect children (as claimed above)
* because the sys_perf_event_open() case will install a new event and break
* the ctx parent<->child relation, and perf_pmu_migrate_context() is only
* concerned with cpuctx and that doesn't have children.
*
* The places that change perf_event::ctx will issue:
*
* perf_remove_from_context();
* synchronize_rcu();
* perf_install_in_context();
*
* to affect the change. The remove_from_context() + synchronize_rcu() should
* quiesce the event, after which we can install it in the new location. This
* means that only external vectors (perf_fops, prctl) can perturb the event
* while in transit. Therefore all such accessors should also acquire
* perf_event_context::mutex to serialize against this.
*
* However; because event->ctx can change while we're waiting to acquire
* ctx->mutex we must be careful and use the below perf_event_ctx_lock()
* function.
*
* Lock order:
* exec_update_lock
* task_struct::perf_event_mutex
* perf_event_context::mutex
* perf_event::child_mutex;
* perf_event_context::lock
* perf_event::mmap_mutex
* mmap_lock
* perf_addr_filters_head::lock
*
* cpu_hotplug_lock
* pmus_lock
* cpuctx->mutex / perf_event_context::mutex
*/
static struct perf_event_context *
perf_event_ctx_lock_nested(struct perf_event *event, int nesting)
{
struct perf_event_context *ctx;
again:
rcu_read_lock();
ctx = READ_ONCE(event->ctx);
if (!refcount_inc_not_zero(&ctx->refcount)) {
rcu_read_unlock();
goto again;
}
rcu_read_unlock();
mutex_lock_nested(&ctx->mutex, nesting);
if (event->ctx != ctx) {
mutex_unlock(&ctx->mutex);
put_ctx(ctx);
goto again;
}
return ctx;
}
static inline struct perf_event_context *
perf_event_ctx_lock(struct perf_event *event)
{
return perf_event_ctx_lock_nested(event, 0);
}
static void perf_event_ctx_unlock(struct perf_event *event,
struct perf_event_context *ctx)
{
mutex_unlock(&ctx->mutex);
put_ctx(ctx);
}
/*
* This must be done under the ctx->lock, such as to serialize against
* context_equiv(), therefore we cannot call put_ctx() since that might end up
* calling scheduler related locks and ctx->lock nests inside those.
*/
static __must_check struct perf_event_context *
unclone_ctx(struct perf_event_context *ctx)
{
struct perf_event_context *parent_ctx = ctx->parent_ctx;
lockdep_assert_held(&ctx->lock);
if (parent_ctx)
ctx->parent_ctx = NULL;
ctx->generation++;
return parent_ctx;
}
static u32 perf_event_pid_type(struct perf_event *event, struct task_struct *p,
enum pid_type type)
{
u32 nr;
/*
* only top level events have the pid namespace they were created in
*/
if (event->parent)
event = event->parent;
nr = __task_pid_nr_ns(p, type, event->ns);
/* avoid -1 if it is idle thread or runs in another ns */
if (!nr && !pid_alive(p))
nr = -1;
return nr;
}
static u32 perf_event_pid(struct perf_event *event, struct task_struct *p)
{
return perf_event_pid_type(event, p, PIDTYPE_TGID);
}
static u32 perf_event_tid(struct perf_event *event, struct task_struct *p)
{
return perf_event_pid_type(event, p, PIDTYPE_PID);
}
/*
* If we inherit events we want to return the parent event id
* to userspace.
*/
static u64 primary_event_id(struct perf_event *event)
{
u64 id = event->id;
if (event->parent)
id = event->parent->id;
return id;
}
/*
* Get the perf_event_context for a task and lock it.
*
* This has to cope with the fact that until it is locked,
* the context could get moved to another task.
*/
static struct perf_event_context *
perf_lock_task_context(struct task_struct *task, unsigned long *flags)
{
struct perf_event_context *ctx;
retry:
/*
* One of the few rules of preemptible RCU is that one cannot do
* rcu_read_unlock() while holding a scheduler (or nested) lock when
* part of the read side critical section was irqs-enabled -- see
* rcu_read_unlock_special().
*
* Since ctx->lock nests under rq->lock we must ensure the entire read
* side critical section has interrupts disabled.
*/
local_irq_save(*flags);
rcu_read_lock();
ctx = rcu_dereference(task->perf_event_ctxp);
if (ctx) {
/*
* If this context is a clone of another, it might
* get swapped for another underneath us by
* perf_event_task_sched_out, though the
* rcu_read_lock() protects us from any context
* getting freed. Lock the context and check if it
* got swapped before we could get the lock, and retry
* if so. If we locked the right context, then it
* can't get swapped on us any more.
*/
raw_spin_lock(&ctx->lock);
if (ctx != rcu_dereference(task->perf_event_ctxp)) {
raw_spin_unlock(&ctx->lock);
rcu_read_unlock();
local_irq_restore(*flags);
goto retry;
}
if (ctx->task == TASK_TOMBSTONE ||
!refcount_inc_not_zero(&ctx->refcount)) {
raw_spin_unlock(&ctx->lock);
ctx = NULL;
} else {
WARN_ON_ONCE(ctx->task != task);
}
}
rcu_read_unlock();
if (!ctx)
local_irq_restore(*flags);
return ctx;
}
/*
* Get the context for a task and increment its pin_count so it
* can't get swapped to another task. This also increments its
* reference count so that the context can't get freed.
*/
static struct perf_event_context *
perf_pin_task_context(struct task_struct *task)
{
struct perf_event_context *ctx;
unsigned long flags;
ctx = perf_lock_task_context(task, &flags);
if (ctx) {
++ctx->pin_count;
raw_spin_unlock_irqrestore(&ctx->lock, flags);
}
return ctx;
}
static void perf_unpin_context(struct perf_event_context *ctx)
{
unsigned long flags;
raw_spin_lock_irqsave(&ctx->lock, flags);
--ctx->pin_count;
raw_spin_unlock_irqrestore(&ctx->lock, flags);
}
/*
* Update the record of the current time in a context.
*/
static void __update_context_time(struct perf_event_context *ctx, bool adv)
{
u64 now = perf_clock();
lockdep_assert_held(&ctx->lock);
if (adv)
ctx->time += now - ctx->timestamp;
ctx->timestamp = now;
/*
* The above: time' = time + (now - timestamp), can be re-arranged
* into: time` = now + (time - timestamp), which gives a single value
* offset to compute future time without locks on.
*
* See perf_event_time_now(), which can be used from NMI context where
* it's (obviously) not possible to acquire ctx->lock in order to read
* both the above values in a consistent manner.
*/
WRITE_ONCE(ctx->timeoffset, ctx->time - ctx->timestamp);
}
static void update_context_time(struct perf_event_context *ctx)
{
__update_context_time(ctx, true);
}
static u64 perf_event_time(struct perf_event *event)
{
struct perf_event_context *ctx = event->ctx;
if (unlikely(!ctx))
return 0;
if (is_cgroup_event(event))
return perf_cgroup_event_time(event);
return ctx->time;
}
static u64 perf_event_time_now(struct perf_event *event, u64 now)
{
struct perf_event_context *ctx = event->ctx;
if (unlikely(!ctx))
return 0;
if (is_cgroup_event(event))
return perf_cgroup_event_time_now(event, now);
if (!(__load_acquire(&ctx->is_active) & EVENT_TIME))
return ctx->time;
now += READ_ONCE(ctx->timeoffset);
return now;
}
static enum event_type_t get_event_type(struct perf_event *event)
{
struct perf_event_context *ctx = event->ctx;
enum event_type_t event_type;
lockdep_assert_held(&ctx->lock);
/*
* It's 'group type', really, because if our group leader is
* pinned, so are we.
*/
if (event->group_leader != event)
event = event->group_leader;
event_type = event->attr.pinned ? EVENT_PINNED : EVENT_FLEXIBLE;
if (!ctx->task)
event_type |= EVENT_CPU;
return event_type;
}
/*
* Helper function to initialize event group nodes.
*/
static void init_event_group(struct perf_event *event)
{
RB_CLEAR_NODE(&event->group_node);
event->group_index = 0;
}
/*
* Extract pinned or flexible groups from the context
* based on event attrs bits.
*/
static struct perf_event_groups *
get_event_groups(struct perf_event *event, struct perf_event_context *ctx)
{
if (event->attr.pinned)
return &ctx->pinned_groups;
else
return &ctx->flexible_groups;
}
/*
* Helper function to initializes perf_event_group trees.
*/
static void perf_event_groups_init(struct perf_event_groups *groups)
{
groups->tree = RB_ROOT;
groups->index = 0;
}
static inline struct cgroup *event_cgroup(const struct perf_event *event)
{
struct cgroup *cgroup = NULL;
#ifdef CONFIG_CGROUP_PERF
if (event->cgrp)
cgroup = event->cgrp->css.cgroup;
#endif
return cgroup;
}
/*
* Compare function for event groups;
*
* Implements complex key that first sorts by CPU and then by virtual index
* which provides ordering when rotating groups for the same CPU.
*/
static __always_inline int
perf_event_groups_cmp(const int left_cpu, const struct pmu *left_pmu,
const struct cgroup *left_cgroup, const u64 left_group_index,
const struct perf_event *right)
{
if (left_cpu < right->cpu)
return -1;
if (left_cpu > right->cpu)
return 1;
if (left_pmu) {
if (left_pmu < right->pmu_ctx->pmu)
return -1;
if (left_pmu > right->pmu_ctx->pmu)
return 1;
}
#ifdef CONFIG_CGROUP_PERF
{
const struct cgroup *right_cgroup = event_cgroup(right);
if (left_cgroup != right_cgroup) {
if (!left_cgroup) {
/*
* Left has no cgroup but right does, no
* cgroups come first.
*/
return -1;
}
if (!right_cgroup) {
/*
* Right has no cgroup but left does, no
* cgroups come first.
*/
return 1;
}
/* Two dissimilar cgroups, order by id. */
if (cgroup_id(left_cgroup) < cgroup_id(right_cgroup))
return -1;
return 1;
}
}
#endif
if (left_group_index < right->group_index)
return -1;
if (left_group_index > right->group_index)
return 1;
return 0;
}
#define __node_2_pe(node) \
rb_entry((node), struct perf_event, group_node)
static inline bool __group_less(struct rb_node *a, const struct rb_node *b)
{
struct perf_event *e = __node_2_pe(a);
return perf_event_groups_cmp(e->cpu, e->pmu_ctx->pmu, event_cgroup(e),
e->group_index, __node_2_pe(b)) < 0;
}
struct __group_key {
int cpu;
struct pmu *pmu;
struct cgroup *cgroup;
};
static inline int __group_cmp(const void *key, const struct rb_node *node)
{
const struct __group_key *a = key;
const struct perf_event *b = __node_2_pe(node);
/* partial/subtree match: @cpu, @pmu, @cgroup; ignore: @group_index */
return perf_event_groups_cmp(a->cpu, a->pmu, a->cgroup, b->group_index, b);
}
static inline int
__group_cmp_ignore_cgroup(const void *key, const struct rb_node *node)
{
const struct __group_key *a = key;
const struct perf_event *b = __node_2_pe(node);
/* partial/subtree match: @cpu, @pmu, ignore: @cgroup, @group_index */
return perf_event_groups_cmp(a->cpu, a->pmu, event_cgroup(b),
b->group_index, b);
}
/*
* Insert @event into @groups' tree; using
* {@event->cpu, @event->pmu_ctx->pmu, event_cgroup(@event), ++@groups->index}
* as key. This places it last inside the {cpu,pmu,cgroup} subtree.
*/
static void
perf_event_groups_insert(struct perf_event_groups *groups,
struct perf_event *event)
{
event->group_index = ++groups->index;
rb_add(&event->group_node, &groups->tree, __group_less);
}
/*
* Helper function to insert event into the pinned or flexible groups.
*/
static void
add_event_to_groups(struct perf_event *event, struct perf_event_context *ctx)
{
struct perf_event_groups *groups;
groups = get_event_groups(event, ctx);
perf_event_groups_insert(groups, event);
}
/*
* Delete a group from a tree.
*/
static void
perf_event_groups_delete(struct perf_event_groups *groups,
struct perf_event *event)
{
WARN_ON_ONCE(RB_EMPTY_NODE(&event->group_node) ||
RB_EMPTY_ROOT(&groups->tree));
rb_erase(&event->group_node, &groups->tree);
init_event_group(event);
}
/*
* Helper function to delete event from its groups.
*/
static void
del_event_from_groups(struct perf_event *event, struct perf_event_context *ctx)
{
struct perf_event_groups *groups;
groups = get_event_groups(event, ctx);
perf_event_groups_delete(groups, event);
}
/*
* Get the leftmost event in the {cpu,pmu,cgroup} subtree.
*/
static struct perf_event *
perf_event_groups_first(struct perf_event_groups *groups, int cpu,
struct pmu *pmu, struct cgroup *cgrp)
{
struct __group_key key = {
.cpu = cpu,
.pmu = pmu,
.cgroup = cgrp,
};
struct rb_node *node;
node = rb_find_first(&key, &groups->tree, __group_cmp);
if (node)
return __node_2_pe(node);
return NULL;
}
static struct perf_event *
perf_event_groups_next(struct perf_event *event, struct pmu *pmu)
{
struct __group_key key = {
.cpu = event->cpu,
.pmu = pmu,
.cgroup = event_cgroup(event),
};
struct rb_node *next;
next = rb_next_match(&key, &event->group_node, __group_cmp);
if (next)
return __node_2_pe(next);
return NULL;
}
#define perf_event_groups_for_cpu_pmu(event, groups, cpu, pmu) \
for (event = perf_event_groups_first(groups, cpu, pmu, NULL); \
event; event = perf_event_groups_next(event, pmu))
/*
* Iterate through the whole groups tree.
*/
#define perf_event_groups_for_each(event, groups) \
for (event = rb_entry_safe(rb_first(&((groups)->tree)), \
typeof(*event), group_node); event; \
event = rb_entry_safe(rb_next(&event->group_node), \
typeof(*event), group_node))
/*
* Add an event from the lists for its context.
* Must be called with ctx->mutex and ctx->lock held.
*/
static void
list_add_event(struct perf_event *event, struct perf_event_context *ctx)
{
lockdep_assert_held(&ctx->lock);
WARN_ON_ONCE(event->attach_state & PERF_ATTACH_CONTEXT);
event->attach_state |= PERF_ATTACH_CONTEXT;
event->tstamp = perf_event_time(event);
/*
* If we're a stand alone event or group leader, we go to the context
* list, group events are kept attached to the group so that
* perf_group_detach can, at all times, locate all siblings.
*/
if (event->group_leader == event) {
event->group_caps = event->event_caps;
add_event_to_groups(event, ctx);
}
list_add_rcu(&event->event_entry, &ctx->event_list);
ctx->nr_events++;
if (event->hw.flags & PERF_EVENT_FLAG_USER_READ_CNT)
ctx->nr_user++;
if (event->attr.inherit_stat)
ctx->nr_stat++;
if (event->state > PERF_EVENT_STATE_OFF)
perf_cgroup_event_enable(event, ctx);
ctx->generation++;
event->pmu_ctx->nr_events++;
}
/*
* Initialize event state based on the perf_event_attr::disabled.
*/
static inline void perf_event__state_init(struct perf_event *event)
{
event->state = event->attr.disabled ? PERF_EVENT_STATE_OFF :
PERF_EVENT_STATE_INACTIVE;
}
static int __perf_event_read_size(u64 read_format, int nr_siblings)
{
int entry = sizeof(u64); /* value */
int size = 0;
int nr = 1;
if (read_format & PERF_FORMAT_TOTAL_TIME_ENABLED)
size += sizeof(u64);
if (read_format & PERF_FORMAT_TOTAL_TIME_RUNNING)
size += sizeof(u64);
if (read_format & PERF_FORMAT_ID)
entry += sizeof(u64);
if (read_format & PERF_FORMAT_LOST)
entry += sizeof(u64);
if (read_format & PERF_FORMAT_GROUP) {
nr += nr_siblings;
size += sizeof(u64);
}
/*
* Since perf_event_validate_size() limits this to 16k and inhibits
* adding more siblings, this will never overflow.
*/
return size + nr * entry;
}
static void __perf_event_header_size(struct perf_event *event, u64 sample_type)
{
struct perf_sample_data *data;
u16 size = 0;
if (sample_type & PERF_SAMPLE_IP)
size += sizeof(data->ip);
if (sample_type & PERF_SAMPLE_ADDR)
size += sizeof(data->addr);
if (sample_type & PERF_SAMPLE_PERIOD)
size += sizeof(data->period);
if (sample_type & PERF_SAMPLE_WEIGHT_TYPE)
size += sizeof(data->weight.full);
if (sample_type & PERF_SAMPLE_READ)
size += event->read_size;
if (sample_type & PERF_SAMPLE_DATA_SRC)
size += sizeof(data->data_src.val);
if (sample_type & PERF_SAMPLE_TRANSACTION)
size += sizeof(data->txn);
if (sample_type & PERF_SAMPLE_PHYS_ADDR)
size += sizeof(data->phys_addr);
if (sample_type & PERF_SAMPLE_CGROUP)
size += sizeof(data->cgroup);
if (sample_type & PERF_SAMPLE_DATA_PAGE_SIZE)
size += sizeof(data->data_page_size);
if (sample_type & PERF_SAMPLE_CODE_PAGE_SIZE)
size += sizeof(data->code_page_size);
event->header_size = size;
}
/*
* Called at perf_event creation and when events are attached/detached from a
* group.
*/
static void perf_event__header_size(struct perf_event *event)
{
event->read_size =
__perf_event_read_size(event->attr.read_format,
event->group_leader->nr_siblings);
__perf_event_header_size(event, event->attr.sample_type);
}
static void perf_event__id_header_size(struct perf_event *event)
{
struct perf_sample_data *data;
u64 sample_type = event->attr.sample_type;
u16 size = 0;
if (sample_type & PERF_SAMPLE_TID)
size += sizeof(data->tid_entry);
if (sample_type & PERF_SAMPLE_TIME)
size += sizeof(data->time);
if (sample_type & PERF_SAMPLE_IDENTIFIER)
size += sizeof(data->id);
if (sample_type & PERF_SAMPLE_ID)
size += sizeof(data->id);
if (sample_type & PERF_SAMPLE_STREAM_ID)
size += sizeof(data->stream_id);
if (sample_type & PERF_SAMPLE_CPU)
size += sizeof(data->cpu_entry);
event->id_header_size = size;
}
/*
* Check that adding an event to the group does not result in anybody
* overflowing the 64k event limit imposed by the output buffer.
*
* Specifically, check that the read_size for the event does not exceed 16k,
* read_size being the one term that grows with groups size. Since read_size
* depends on per-event read_format, also (re)check the existing events.
*
* This leaves 48k for the constant size fields and things like callchains,
* branch stacks and register sets.
*/
static bool perf_event_validate_size(struct perf_event *event)
{
struct perf_event *sibling, *group_leader = event->group_leader;
if (__perf_event_read_size(event->attr.read_format,
group_leader->nr_siblings + 1) > 16*1024)
return false;
if (__perf_event_read_size(group_leader->attr.read_format,
group_leader->nr_siblings + 1) > 16*1024)
return false;
/*
* When creating a new group leader, group_leader->ctx is initialized
* after the size has been validated, but we cannot safely use
* for_each_sibling_event() until group_leader->ctx is set. A new group
* leader cannot have any siblings yet, so we can safely skip checking
* the non-existent siblings.
*/
if (event == group_leader)
return true;
for_each_sibling_event(sibling, group_leader) {
if (__perf_event_read_size(sibling->attr.read_format,
group_leader->nr_siblings + 1) > 16*1024)
return false;
}
return true;
}
static void perf_group_attach(struct perf_event *event)
{
struct perf_event *group_leader = event->group_leader, *pos;
lockdep_assert_held(&event->ctx->lock);
/*
* We can have double attach due to group movement (move_group) in
* perf_event_open().
*/
if (event->attach_state & PERF_ATTACH_GROUP)
return;
event->attach_state |= PERF_ATTACH_GROUP;
if (group_leader == event)
return;
WARN_ON_ONCE(group_leader->ctx != event->ctx);
group_leader->group_caps &= event->event_caps;
list_add_tail(&event->sibling_list, &group_leader->sibling_list);
group_leader->nr_siblings++;
group_leader->group_generation++;
perf_event__header_size(group_leader);
for_each_sibling_event(pos, group_leader)
perf_event__header_size(pos);
}
/*
* Remove an event from the lists for its context.
* Must be called with ctx->mutex and ctx->lock held.
*/
static void
list_del_event(struct perf_event *event, struct perf_event_context *ctx)
{
WARN_ON_ONCE(event->ctx != ctx);
lockdep_assert_held(&ctx->lock);
/*
* We can have double detach due to exit/hot-unplug + close.
*/
if (!(event->attach_state & PERF_ATTACH_CONTEXT))
return;
event->attach_state &= ~PERF_ATTACH_CONTEXT;
ctx->nr_events--;
if (event->hw.flags & PERF_EVENT_FLAG_USER_READ_CNT)
ctx->nr_user--;
if (event->attr.inherit_stat)
ctx->nr_stat--;
list_del_rcu(&event->event_entry);
if (event->group_leader == event)
del_event_from_groups(event, ctx);
/*
* If event was in error state, then keep it
* that way, otherwise bogus counts will be
* returned on read(). The only way to get out
* of error state is by explicit re-enabling
* of the event
*/
if (event->state > PERF_EVENT_STATE_OFF) {
perf_cgroup_event_disable(event, ctx);
perf_event_set_state(event, PERF_EVENT_STATE_OFF);
}
ctx->generation++;
event->pmu_ctx->nr_events--;
}
static int
perf_aux_output_match(struct perf_event *event, struct perf_event *aux_event)
{
if (!has_aux(aux_event))
return 0;
if (!event->pmu->aux_output_match)
return 0;
return event->pmu->aux_output_match(aux_event);
}
static void put_event(struct perf_event *event);
static void event_sched_out(struct perf_event *event,
struct perf_event_context *ctx);
static void perf_put_aux_event(struct perf_event *event)
{
struct perf_event_context *ctx = event->ctx;
struct perf_event *iter;
/*
* If event uses aux_event tear down the link
*/
if (event->aux_event) {
iter = event->aux_event;
event->aux_event = NULL;
put_event(iter);
return;
}
/*
* If the event is an aux_event, tear down all links to
* it from other events.
*/
for_each_sibling_event(iter, event->group_leader) {
if (iter->aux_event != event)
continue;
iter->aux_event = NULL;
put_event(event);
/*
* If it's ACTIVE, schedule it out and put it into ERROR
* state so that we don't try to schedule it again. Note
* that perf_event_enable() will clear the ERROR status.
*/
event_sched_out(iter, ctx);
perf_event_set_state(event, PERF_EVENT_STATE_ERROR);
}
}
static bool perf_need_aux_event(struct perf_event *event)
{
return !!event->attr.aux_output || !!event->attr.aux_sample_size;
}
static int perf_get_aux_event(struct perf_event *event,
struct perf_event *group_leader)
{
/*
* Our group leader must be an aux event if we want to be
* an aux_output. This way, the aux event will precede its
* aux_output events in the group, and therefore will always
* schedule first.
*/
if (!group_leader)
return 0;
/*
* aux_output and aux_sample_size are mutually exclusive.
*/
if (event->attr.aux_output && event->attr.aux_sample_size)
return 0;
if (event->attr.aux_output &&
!perf_aux_output_match(event, group_leader))
return 0;
if (event->attr.aux_sample_size && !group_leader->pmu->snapshot_aux)
return 0;
if (!atomic_long_inc_not_zero(&group_leader->refcount))
return 0;
/*
* Link aux_outputs to their aux event; this is undone in
* perf_group_detach() by perf_put_aux_event(). When the
* group in torn down, the aux_output events loose their
* link to the aux_event and can't schedule any more.
*/
event->aux_event = group_leader;
return 1;
}
static inline struct list_head *get_event_list(struct perf_event *event)
{
return event->attr.pinned ? &event->pmu_ctx->pinned_active :
&event->pmu_ctx->flexible_active;
}
/*
* Events that have PERF_EV_CAP_SIBLING require being part of a group and
* cannot exist on their own, schedule them out and move them into the ERROR
* state. Also see _perf_event_enable(), it will not be able to recover
* this ERROR state.
*/
static inline void perf_remove_sibling_event(struct perf_event *event)
{
event_sched_out(event, event->ctx);
perf_event_set_state(event, PERF_EVENT_STATE_ERROR);
}
static void perf_group_detach(struct perf_event *event)
{
struct perf_event *leader = event->group_leader;
struct perf_event *sibling, *tmp;
struct perf_event_context *ctx = event->ctx;
lockdep_assert_held(&ctx->lock);
/*
* We can have double detach due to exit/hot-unplug + close.
*/
if (!(event->attach_state & PERF_ATTACH_GROUP))
return;
event->attach_state &= ~PERF_ATTACH_GROUP;
perf_put_aux_event(event);
/*
* If this is a sibling, remove it from its group.
*/
if (leader != event) {
list_del_init(&event->sibling_list);
event->group_leader->nr_siblings--;
event->group_leader->group_generation++;
goto out;
}
/*
* If this was a group event with sibling events then
* upgrade the siblings to singleton events by adding them
* to whatever list we are on.
*/
list_for_each_entry_safe(sibling, tmp, &event->sibling_list, sibling_list) {
if (sibling->event_caps & PERF_EV_CAP_SIBLING)
perf_remove_sibling_event(sibling);
sibling->group_leader = sibling;
list_del_init(&sibling->sibling_list);
/* Inherit group flags from the previous leader */
sibling->group_caps = event->group_caps;
if (sibling->attach_state & PERF_ATTACH_CONTEXT) {
add_event_to_groups(sibling, event->ctx);
if (sibling->state == PERF_EVENT_STATE_ACTIVE)
list_add_tail(&sibling->active_list, get_event_list(sibling));
}
WARN_ON_ONCE(sibling->ctx != event->ctx);
}
out:
for_each_sibling_event(tmp, leader)
perf_event__header_size(tmp);
perf_event__header_size(leader);
}
static void sync_child_event(struct perf_event *child_event);
static void perf_child_detach(struct perf_event *event)
{
struct perf_event *parent_event = event->parent;
if (!(event->attach_state & PERF_ATTACH_CHILD))
return;
event->attach_state &= ~PERF_ATTACH_CHILD;
if (WARN_ON_ONCE(!parent_event))
return;
lockdep_assert_held(&parent_event->child_mutex);
sync_child_event(event);
list_del_init(&event->child_list);
}
static bool is_orphaned_event(struct perf_event *event)
{
return event->state == PERF_EVENT_STATE_DEAD;
}
static inline int
event_filter_match(struct perf_event *event)
{
return (event->cpu == -1 || event->cpu == smp_processor_id()) &&
perf_cgroup_match(event);
}
static void
event_sched_out(struct perf_event *event, struct perf_event_context *ctx)
{
struct perf_event_pmu_context *epc = event->pmu_ctx;
struct perf_cpu_pmu_context *cpc = this_cpu_ptr(epc->pmu->cpu_pmu_context);
enum perf_event_state state = PERF_EVENT_STATE_INACTIVE;
// XXX cpc serialization, probably per-cpu IRQ disabled
WARN_ON_ONCE(event->ctx != ctx);
lockdep_assert_held(&ctx->lock);
if (event->state != PERF_EVENT_STATE_ACTIVE)
return;
/*
* Asymmetry; we only schedule events _IN_ through ctx_sched_in(), but
* we can schedule events _OUT_ individually through things like
* __perf_remove_from_context().
*/
list_del_init(&event->active_list);
perf_pmu_disable(event->pmu);
event->pmu->del(event, 0);
event->oncpu = -1;
if (event->pending_disable) {
event->pending_disable = 0;
perf_cgroup_event_disable(event, ctx);
state = PERF_EVENT_STATE_OFF;
}
if (event->pending_sigtrap) {
bool dec = true;
event->pending_sigtrap = 0;
if (state != PERF_EVENT_STATE_OFF &&
!event->pending_work) {
event->pending_work = 1;
dec = false;
WARN_ON_ONCE(!atomic_long_inc_not_zero(&event->refcount));
task_work_add(current, &event->pending_task, TWA_RESUME);
}
if (dec)
local_dec(&event->ctx->nr_pending);
}
perf_event_set_state(event, state);
if (!is_software_event(event))
cpc->active_oncpu--;
if (event->attr.freq && event->attr.sample_freq)
ctx->nr_freq--;
if (event->attr.exclusive || !cpc->active_oncpu)
cpc->exclusive = 0;
perf_pmu_enable(event->pmu);
}
static void
group_sched_out(struct perf_event *group_event, struct perf_event_context *ctx)
{
struct perf_event *event;
if (group_event->state != PERF_EVENT_STATE_ACTIVE)
return;
perf_assert_pmu_disabled(group_event->pmu_ctx->pmu);
event_sched_out(group_event, ctx);
/*
* Schedule out siblings (if any):
*/
for_each_sibling_event(event, group_event)
event_sched_out(event, ctx);
}
#define DETACH_GROUP 0x01UL
#define DETACH_CHILD 0x02UL
#define DETACH_DEAD 0x04UL
/*
* Cross CPU call to remove a performance event
*
* We disable the event on the hardware level first. After that we
* remove it from the context list.
*/
static void
__perf_remove_from_context(struct perf_event *event,
struct perf_cpu_context *cpuctx,
struct perf_event_context *ctx,
void *info)
{
struct perf_event_pmu_context *pmu_ctx = event->pmu_ctx;
unsigned long flags = (unsigned long)info;
if (ctx->is_active & EVENT_TIME) {
update_context_time(ctx);
update_cgrp_time_from_cpuctx(cpuctx, false);
}
/*
* Ensure event_sched_out() switches to OFF, at the very least
* this avoids raising perf_pending_task() at this time.
*/
if (flags & DETACH_DEAD)
event->pending_disable = 1;
event_sched_out(event, ctx);
if (flags & DETACH_GROUP)
perf_group_detach(event);
if (flags & DETACH_CHILD)
perf_child_detach(event);
list_del_event(event, ctx);
if (flags & DETACH_DEAD)
event->state = PERF_EVENT_STATE_DEAD;
if (!pmu_ctx->nr_events) {
pmu_ctx->rotate_necessary = 0;
if (ctx->task && ctx->is_active) {
struct perf_cpu_pmu_context *cpc;
cpc = this_cpu_ptr(pmu_ctx->pmu->cpu_pmu_context);
WARN_ON_ONCE(cpc->task_epc && cpc->task_epc != pmu_ctx);
cpc->task_epc = NULL;
}
}
if (!ctx->nr_events && ctx->is_active) {
if (ctx == &cpuctx->ctx)
update_cgrp_time_from_cpuctx(cpuctx, true);
ctx->is_active = 0;
if (ctx->task) {
WARN_ON_ONCE(cpuctx->task_ctx != ctx);
cpuctx->task_ctx = NULL;
}
}
}
/*
* Remove the event from a task's (or a CPU's) list of events.
*
* If event->ctx is a cloned context, callers must make sure that
* every task struct that event->ctx->task could possibly point to
* remains valid. This is OK when called from perf_release since
* that only calls us on the top-level context, which can't be a clone.
* When called from perf_event_exit_task, it's OK because the
* context has been detached from its task.
*/
static void perf_remove_from_context(struct perf_event *event, unsigned long flags)
{
struct perf_event_context *ctx = event->ctx;
lockdep_assert_held(&ctx->mutex);
/*
* Because of perf_event_exit_task(), perf_remove_from_context() ought
* to work in the face of TASK_TOMBSTONE, unlike every other
* event_function_call() user.
*/
raw_spin_lock_irq(&ctx->lock);
if (!ctx->is_active) {
__perf_remove_from_context(event, this_cpu_ptr(&perf_cpu_context),
ctx, (void *)flags);
raw_spin_unlock_irq(&ctx->lock);
return;
}
raw_spin_unlock_irq(&ctx->lock);
event_function_call(event, __perf_remove_from_context, (void *)flags);
}
/*
* Cross CPU call to disable a performance event
*/
static void __perf_event_disable(struct perf_event *event,
struct perf_cpu_context *cpuctx,
struct perf_event_context *ctx,
void *info)
{
if (event->state < PERF_EVENT_STATE_INACTIVE)
return;
if (ctx->is_active & EVENT_TIME) {
update_context_time(ctx);
update_cgrp_time_from_event(event);
}
perf_pmu_disable(event->pmu_ctx->pmu);
if (event == event->group_leader)
group_sched_out(event, ctx);
else
event_sched_out(event, ctx);
perf_event_set_state(event, PERF_EVENT_STATE_OFF);
perf_cgroup_event_disable(event, ctx);
perf_pmu_enable(event->pmu_ctx->pmu);
}
/*
* Disable an event.
*
* If event->ctx is a cloned context, callers must make sure that
* every task struct that event->ctx->task could possibly point to
* remains valid. This condition is satisfied when called through
* perf_event_for_each_child or perf_event_for_each because they
* hold the top-level event's child_mutex, so any descendant that
* goes to exit will block in perf_event_exit_event().
*
* When called from perf_pending_irq it's OK because event->ctx
* is the current context on this CPU and preemption is disabled,
* hence we can't get into perf_event_task_sched_out for this context.
*/
static void _perf_event_disable(struct perf_event *event)
{
struct perf_event_context *ctx = event->ctx;
raw_spin_lock_irq(&ctx->lock);
if (event->state <= PERF_EVENT_STATE_OFF) {
raw_spin_unlock_irq(&ctx->lock);
return;
}
raw_spin_unlock_irq(&ctx->lock);
event_function_call(event, __perf_event_disable, NULL);
}
void perf_event_disable_local(struct perf_event *event)
{
event_function_local(event, __perf_event_disable, NULL);
}
/*
* Strictly speaking kernel users cannot create groups and therefore this
* interface does not need the perf_event_ctx_lock() magic.
*/
void perf_event_disable(struct perf_event *event)
{
struct perf_event_context *ctx;
ctx = perf_event_ctx_lock(event);
_perf_event_disable(event);
perf_event_ctx_unlock(event, ctx);
}
EXPORT_SYMBOL_GPL(perf_event_disable);
void perf_event_disable_inatomic(struct perf_event *event)
{
event->pending_disable = 1;
irq_work_queue(&event->pending_irq);
}
#define MAX_INTERRUPTS (~0ULL)
static void perf_log_throttle(struct perf_event *event, int enable);
static void perf_log_itrace_start(struct perf_event *event);
static int
event_sched_in(struct perf_event *event, struct perf_event_context *ctx)
{
struct perf_event_pmu_context *epc = event->pmu_ctx;
struct perf_cpu_pmu_context *cpc = this_cpu_ptr(epc->pmu->cpu_pmu_context);
int ret = 0;
WARN_ON_ONCE(event->ctx != ctx);
lockdep_assert_held(&ctx->lock);
if (event->state <= PERF_EVENT_STATE_OFF)
return 0;
WRITE_ONCE(event->oncpu, smp_processor_id());
/*
* Order event::oncpu write to happen before the ACTIVE state is
* visible. This allows perf_event_{stop,read}() to observe the correct
* ->oncpu if it sees ACTIVE.
*/
smp_wmb();
perf_event_set_state(event, PERF_EVENT_STATE_ACTIVE);
/*
* Unthrottle events, since we scheduled we might have missed several
* ticks already, also for a heavily scheduling task there is little
* guarantee it'll get a tick in a timely manner.
*/
if (unlikely(event->hw.interrupts == MAX_INTERRUPTS)) {
perf_log_throttle(event, 1);
event->hw.interrupts = 0;
}
perf_pmu_disable(event->pmu);
perf_log_itrace_start(event);
if (event->pmu->add(event, PERF_EF_START)) {
perf_event_set_state(event, PERF_EVENT_STATE_INACTIVE);
event->oncpu = -1;
ret = -EAGAIN;
goto out;
}
if (!is_software_event(event))
cpc->active_oncpu++;
if (event->attr.freq && event->attr.sample_freq)
ctx->nr_freq++;
if (event->attr.exclusive)
cpc->exclusive = 1;
out:
perf_pmu_enable(event->pmu);
return ret;
}
static int
group_sched_in(struct perf_event *group_event, struct perf_event_context *ctx)
{
struct perf_event *event, *partial_group = NULL;
struct pmu *pmu = group_event->pmu_ctx->pmu;
if (group_event->state == PERF_EVENT_STATE_OFF)
return 0;
pmu->start_txn(pmu, PERF_PMU_TXN_ADD);
if (event_sched_in(group_event, ctx))
goto error;
/*
* Schedule in siblings as one group (if any):
*/
for_each_sibling_event(event, group_event) {
if (event_sched_in(event, ctx)) {
partial_group = event;
goto group_error;
}
}
if (!pmu->commit_txn(pmu))
return 0;
group_error:
/*
* Groups can be scheduled in as one unit only, so undo any
* partial group before returning:
* The events up to the failed event are scheduled out normally.
*/
for_each_sibling_event(event, group_event) {
if (event == partial_group)
break;
event_sched_out(event, ctx);
}
event_sched_out(group_event, ctx);
error:
pmu->cancel_txn(pmu);
return -EAGAIN;
}
/*
* Work out whether we can put this event group on the CPU now.
*/
static int group_can_go_on(struct perf_event *event, int can_add_hw)
{
struct perf_event_pmu_context *epc = event->pmu_ctx;
struct perf_cpu_pmu_context *cpc = this_cpu_ptr(epc->pmu->cpu_pmu_context);
/*
* Groups consisting entirely of software events can always go on.
*/
if (event->group_caps & PERF_EV_CAP_SOFTWARE)
return 1;
/*
* If an exclusive group is already on, no other hardware
* events can go on.
*/
if (cpc->exclusive)
return 0;
/*
* If this group is exclusive and there are already
* events on the CPU, it can't go on.
*/
if (event->attr.exclusive && !list_empty(get_event_list(event)))
return 0;
/*
* Otherwise, try to add it if all previous groups were able
* to go on.
*/
return can_add_hw;
}
static void add_event_to_ctx(struct perf_event *event,
struct perf_event_context *ctx)
{
list_add_event(event, ctx);
perf_group_attach(event);
}
static void task_ctx_sched_out(struct perf_event_context *ctx,
enum event_type_t event_type)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
if (!cpuctx->task_ctx)
return;
if (WARN_ON_ONCE(ctx != cpuctx->task_ctx))
return;
ctx_sched_out(ctx, event_type);
}
static void perf_event_sched_in(struct perf_cpu_context *cpuctx,
struct perf_event_context *ctx)
{
ctx_sched_in(&cpuctx->ctx, EVENT_PINNED);
if (ctx)
ctx_sched_in(ctx, EVENT_PINNED);
ctx_sched_in(&cpuctx->ctx, EVENT_FLEXIBLE);
if (ctx)
ctx_sched_in(ctx, EVENT_FLEXIBLE);
}
/*
* We want to maintain the following priority of scheduling:
* - CPU pinned (EVENT_CPU | EVENT_PINNED)
* - task pinned (EVENT_PINNED)
* - CPU flexible (EVENT_CPU | EVENT_FLEXIBLE)
* - task flexible (EVENT_FLEXIBLE).
*
* In order to avoid unscheduling and scheduling back in everything every
* time an event is added, only do it for the groups of equal priority and
* below.
*
* This can be called after a batch operation on task events, in which case
* event_type is a bit mask of the types of events involved. For CPU events,
* event_type is only either EVENT_PINNED or EVENT_FLEXIBLE.
*/
/*
* XXX: ctx_resched() reschedule entire perf_event_context while adding new
* event to the context or enabling existing event in the context. We can
* probably optimize it by rescheduling only affected pmu_ctx.
*/
static void ctx_resched(struct perf_cpu_context *cpuctx,
struct perf_event_context *task_ctx,
enum event_type_t event_type)
{
bool cpu_event = !!(event_type & EVENT_CPU);
/*
* If pinned groups are involved, flexible groups also need to be
* scheduled out.
*/
if (event_type & EVENT_PINNED)
event_type |= EVENT_FLEXIBLE;
event_type &= EVENT_ALL;
perf_ctx_disable(&cpuctx->ctx, false);
if (task_ctx) {
perf_ctx_disable(task_ctx, false);
task_ctx_sched_out(task_ctx, event_type);
}
/*
* Decide which cpu ctx groups to schedule out based on the types
* of events that caused rescheduling:
* - EVENT_CPU: schedule out corresponding groups;
* - EVENT_PINNED task events: schedule out EVENT_FLEXIBLE groups;
* - otherwise, do nothing more.
*/
if (cpu_event)
ctx_sched_out(&cpuctx->ctx, event_type);
else if (event_type & EVENT_PINNED)
ctx_sched_out(&cpuctx->ctx, EVENT_FLEXIBLE);
perf_event_sched_in(cpuctx, task_ctx);
perf_ctx_enable(&cpuctx->ctx, false);
if (task_ctx)
perf_ctx_enable(task_ctx, false);
}
void perf_pmu_resched(struct pmu *pmu)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_context *task_ctx = cpuctx->task_ctx;
perf_ctx_lock(cpuctx, task_ctx);
ctx_resched(cpuctx, task_ctx, EVENT_ALL|EVENT_CPU);
perf_ctx_unlock(cpuctx, task_ctx);
}
/*
* Cross CPU call to install and enable a performance event
*
* Very similar to remote_function() + event_function() but cannot assume that
* things like ctx->is_active and cpuctx->task_ctx are set.
*/
static int __perf_install_in_context(void *info)
{
struct perf_event *event = info;
struct perf_event_context *ctx = event->ctx;
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_context *task_ctx = cpuctx->task_ctx;
bool reprogram = true;
int ret = 0;
raw_spin_lock(&cpuctx->ctx.lock);
if (ctx->task) {
raw_spin_lock(&ctx->lock);
task_ctx = ctx;
reprogram = (ctx->task == current);
/*
* If the task is running, it must be running on this CPU,
* otherwise we cannot reprogram things.
*
* If its not running, we don't care, ctx->lock will
* serialize against it becoming runnable.
*/
if (task_curr(ctx->task) && !reprogram) {
ret = -ESRCH;
goto unlock;
}
WARN_ON_ONCE(reprogram && cpuctx->task_ctx && cpuctx->task_ctx != ctx);
} else if (task_ctx) {
raw_spin_lock(&task_ctx->lock);
}
#ifdef CONFIG_CGROUP_PERF
if (event->state > PERF_EVENT_STATE_OFF && is_cgroup_event(event)) {
/*
* If the current cgroup doesn't match the event's
* cgroup, we should not try to schedule it.
*/
struct perf_cgroup *cgrp = perf_cgroup_from_task(current, ctx);
reprogram = cgroup_is_descendant(cgrp->css.cgroup,
event->cgrp->css.cgroup);
}
#endif
if (reprogram) {
ctx_sched_out(ctx, EVENT_TIME);
add_event_to_ctx(event, ctx);
ctx_resched(cpuctx, task_ctx, get_event_type(event));
} else {
add_event_to_ctx(event, ctx);
}
unlock:
perf_ctx_unlock(cpuctx, task_ctx);
return ret;
}
static bool exclusive_event_installable(struct perf_event *event,
struct perf_event_context *ctx);
/*
* Attach a performance event to a context.
*
* Very similar to event_function_call, see comment there.
*/
static void
perf_install_in_context(struct perf_event_context *ctx,
struct perf_event *event,
int cpu)
{
struct task_struct *task = READ_ONCE(ctx->task);
lockdep_assert_held(&ctx->mutex);
WARN_ON_ONCE(!exclusive_event_installable(event, ctx));
if (event->cpu != -1)
WARN_ON_ONCE(event->cpu != cpu);
/*
* Ensures that if we can observe event->ctx, both the event and ctx
* will be 'complete'. See perf_iterate_sb_cpu().
*/
smp_store_release(&event->ctx, ctx);
/*
* perf_event_attr::disabled events will not run and can be initialized
* without IPI. Except when this is the first event for the context, in
* that case we need the magic of the IPI to set ctx->is_active.
*
* The IOC_ENABLE that is sure to follow the creation of a disabled
* event will issue the IPI and reprogram the hardware.
*/
if (__perf_effective_state(event) == PERF_EVENT_STATE_OFF &&
ctx->nr_events && !is_cgroup_event(event)) {
raw_spin_lock_irq(&ctx->lock);
if (ctx->task == TASK_TOMBSTONE) {
raw_spin_unlock_irq(&ctx->lock);
return;
}
add_event_to_ctx(event, ctx);
raw_spin_unlock_irq(&ctx->lock);
return;
}
if (!task) {
cpu_function_call(cpu, __perf_install_in_context, event);
return;
}
/*
* Should not happen, we validate the ctx is still alive before calling.
*/
if (WARN_ON_ONCE(task == TASK_TOMBSTONE))
return;
/*
* Installing events is tricky because we cannot rely on ctx->is_active
* to be set in case this is the nr_events 0 -> 1 transition.
*
* Instead we use task_curr(), which tells us if the task is running.
* However, since we use task_curr() outside of rq::lock, we can race
* against the actual state. This means the result can be wrong.
*
* If we get a false positive, we retry, this is harmless.
*
* If we get a false negative, things are complicated. If we are after
* perf_event_context_sched_in() ctx::lock will serialize us, and the
* value must be correct. If we're before, it doesn't matter since
* perf_event_context_sched_in() will program the counter.
*
* However, this hinges on the remote context switch having observed
* our task->perf_event_ctxp[] store, such that it will in fact take
* ctx::lock in perf_event_context_sched_in().
*
* We do this by task_function_call(), if the IPI fails to hit the task
* we know any future context switch of task must see the
* perf_event_ctpx[] store.
*/
/*
* This smp_mb() orders the task->perf_event_ctxp[] store with the
* task_cpu() load, such that if the IPI then does not find the task
* running, a future context switch of that task must observe the
* store.
*/
smp_mb();
again:
if (!task_function_call(task, __perf_install_in_context, event))
return;
raw_spin_lock_irq(&ctx->lock);
task = ctx->task;
if (WARN_ON_ONCE(task == TASK_TOMBSTONE)) {
/*
* Cannot happen because we already checked above (which also
* cannot happen), and we hold ctx->mutex, which serializes us
* against perf_event_exit_task_context().
*/
raw_spin_unlock_irq(&ctx->lock);
return;
}
/*
* If the task is not running, ctx->lock will avoid it becoming so,
* thus we can safely install the event.
*/
if (task_curr(task)) {
raw_spin_unlock_irq(&ctx->lock);
goto again;
}
add_event_to_ctx(event, ctx);
raw_spin_unlock_irq(&ctx->lock);
}
/*
* Cross CPU call to enable a performance event
*/
static void __perf_event_enable(struct perf_event *event,
struct perf_cpu_context *cpuctx,
struct perf_event_context *ctx,
void *info)
{
struct perf_event *leader = event->group_leader;
struct perf_event_context *task_ctx;
if (event->state >= PERF_EVENT_STATE_INACTIVE ||
event->state <= PERF_EVENT_STATE_ERROR)
return;
if (ctx->is_active)
ctx_sched_out(ctx, EVENT_TIME);
perf_event_set_state(event, PERF_EVENT_STATE_INACTIVE);
perf_cgroup_event_enable(event, ctx);
if (!ctx->is_active)
return;
if (!event_filter_match(event)) {
ctx_sched_in(ctx, EVENT_TIME);
return;
}
/*
* If the event is in a group and isn't the group leader,
* then don't put it on unless the group is on.
*/
if (leader != event && leader->state != PERF_EVENT_STATE_ACTIVE) {
ctx_sched_in(ctx, EVENT_TIME);
return;
}
task_ctx = cpuctx->task_ctx;
if (ctx->task)
WARN_ON_ONCE(task_ctx != ctx);
ctx_resched(cpuctx, task_ctx, get_event_type(event));
}
/*
* Enable an event.
*
* If event->ctx is a cloned context, callers must make sure that
* every task struct that event->ctx->task could possibly point to
* remains valid. This condition is satisfied when called through
* perf_event_for_each_child or perf_event_for_each as described
* for perf_event_disable.
*/
static void _perf_event_enable(struct perf_event *event)
{
struct perf_event_context *ctx = event->ctx;
raw_spin_lock_irq(&ctx->lock);
if (event->state >= PERF_EVENT_STATE_INACTIVE ||
event->state < PERF_EVENT_STATE_ERROR) {
out:
raw_spin_unlock_irq(&ctx->lock);
return;
}
/*
* If the event is in error state, clear that first.
*
* That way, if we see the event in error state below, we know that it
* has gone back into error state, as distinct from the task having
* been scheduled away before the cross-call arrived.
*/
if (event->state == PERF_EVENT_STATE_ERROR) {
/*
* Detached SIBLING events cannot leave ERROR state.
*/
if (event->event_caps & PERF_EV_CAP_SIBLING &&
event->group_leader == event)
goto out;
event->state = PERF_EVENT_STATE_OFF;
}
raw_spin_unlock_irq(&ctx->lock);
event_function_call(event, __perf_event_enable, NULL);
}
/*
* See perf_event_disable();
*/
void perf_event_enable(struct perf_event *event)
{
struct perf_event_context *ctx;
ctx = perf_event_ctx_lock(event);
_perf_event_enable(event);
perf_event_ctx_unlock(event, ctx);
}
EXPORT_SYMBOL_GPL(perf_event_enable);
struct stop_event_data {
struct perf_event *event;
unsigned int restart;
};
static int __perf_event_stop(void *info)
{
struct stop_event_data *sd = info;
struct perf_event *event = sd->event;
/* if it's already INACTIVE, do nothing */
if (READ_ONCE(event->state) != PERF_EVENT_STATE_ACTIVE)
return 0;
/* matches smp_wmb() in event_sched_in() */
smp_rmb();
/*
* There is a window with interrupts enabled before we get here,
* so we need to check again lest we try to stop another CPU's event.
*/
if (READ_ONCE(event->oncpu) != smp_processor_id())
return -EAGAIN;
event->pmu->stop(event, PERF_EF_UPDATE);
/*
* May race with the actual stop (through perf_pmu_output_stop()),
* but it is only used for events with AUX ring buffer, and such
* events will refuse to restart because of rb::aux_mmap_count==0,
* see comments in perf_aux_output_begin().
*
* Since this is happening on an event-local CPU, no trace is lost
* while restarting.
*/
if (sd->restart)
event->pmu->start(event, 0);
return 0;
}
static int perf_event_stop(struct perf_event *event, int restart)
{
struct stop_event_data sd = {
.event = event,
.restart = restart,
};
int ret = 0;
do {
if (READ_ONCE(event->state) != PERF_EVENT_STATE_ACTIVE)
return 0;
/* matches smp_wmb() in event_sched_in() */
smp_rmb();
/*
* We only want to restart ACTIVE events, so if the event goes
* inactive here (event->oncpu==-1), there's nothing more to do;
* fall through with ret==-ENXIO.
*/
ret = cpu_function_call(READ_ONCE(event->oncpu),
__perf_event_stop, &sd);
} while (ret == -EAGAIN);
return ret;
}
/*
* In order to contain the amount of racy and tricky in the address filter
* configuration management, it is a two part process:
*
* (p1) when userspace mappings change as a result of (1) or (2) or (3) below,
* we update the addresses of corresponding vmas in
* event::addr_filter_ranges array and bump the event::addr_filters_gen;
* (p2) when an event is scheduled in (pmu::add), it calls
* perf_event_addr_filters_sync() which calls pmu::addr_filters_sync()
* if the generation has changed since the previous call.
*
* If (p1) happens while the event is active, we restart it to force (p2).
*
* (1) perf_addr_filters_apply(): adjusting filters' offsets based on
* pre-existing mappings, called once when new filters arrive via SET_FILTER
* ioctl;
* (2) perf_addr_filters_adjust(): adjusting filters' offsets based on newly
* registered mapping, called for every new mmap(), with mm::mmap_lock down
* for reading;
* (3) perf_event_addr_filters_exec(): clearing filters' offsets in the process
* of exec.
*/
void perf_event_addr_filters_sync(struct perf_event *event)
{
struct perf_addr_filters_head *ifh = perf_event_addr_filters(event);
if (!has_addr_filter(event))
return;
raw_spin_lock(&ifh->lock);
if (event->addr_filters_gen != event->hw.addr_filters_gen) {
event->pmu->addr_filters_sync(event);
event->hw.addr_filters_gen = event->addr_filters_gen;
}
raw_spin_unlock(&ifh->lock);
}
EXPORT_SYMBOL_GPL(perf_event_addr_filters_sync);
static int _perf_event_refresh(struct perf_event *event, int refresh)
{
/*
* not supported on inherited events
*/
if (event->attr.inherit || !is_sampling_event(event))
return -EINVAL;
atomic_add(refresh, &event->event_limit);
_perf_event_enable(event);
return 0;
}
/*
* See perf_event_disable()
*/
int perf_event_refresh(struct perf_event *event, int refresh)
{
struct perf_event_context *ctx;
int ret;
ctx = perf_event_ctx_lock(event);
ret = _perf_event_refresh(event, refresh);
perf_event_ctx_unlock(event, ctx);
return ret;
}
EXPORT_SYMBOL_GPL(perf_event_refresh);
static int perf_event_modify_breakpoint(struct perf_event *bp,
struct perf_event_attr *attr)
{
int err;
_perf_event_disable(bp);
err = modify_user_hw_breakpoint_check(bp, attr, true);
if (!bp->attr.disabled)
_perf_event_enable(bp);
return err;
}
/*
* Copy event-type-independent attributes that may be modified.
*/
static void perf_event_modify_copy_attr(struct perf_event_attr *to,
const struct perf_event_attr *from)
{
to->sig_data = from->sig_data;
}
static int perf_event_modify_attr(struct perf_event *event,
struct perf_event_attr *attr)
{
int (*func)(struct perf_event *, struct perf_event_attr *);
struct perf_event *child;
int err;
if (event->attr.type != attr->type)
return -EINVAL;
switch (event->attr.type) {
case PERF_TYPE_BREAKPOINT:
func = perf_event_modify_breakpoint;
break;
default:
/* Place holder for future additions. */
return -EOPNOTSUPP;
}
WARN_ON_ONCE(event->ctx->parent_ctx);
mutex_lock(&event->child_mutex);
/*
* Event-type-independent attributes must be copied before event-type
* modification, which will validate that final attributes match the
* source attributes after all relevant attributes have been copied.
*/
perf_event_modify_copy_attr(&event->attr, attr);
err = func(event, attr);
if (err)
goto out;
list_for_each_entry(child, &event->child_list, child_list) {
perf_event_modify_copy_attr(&child->attr, attr);
err = func(child, attr);
if (err)
goto out;
}
out:
mutex_unlock(&event->child_mutex);
return err;
}
static void __pmu_ctx_sched_out(struct perf_event_pmu_context *pmu_ctx,
enum event_type_t event_type)
{
struct perf_event_context *ctx = pmu_ctx->ctx;
struct perf_event *event, *tmp;
struct pmu *pmu = pmu_ctx->pmu;
if (ctx->task && !ctx->is_active) {
struct perf_cpu_pmu_context *cpc;
cpc = this_cpu_ptr(pmu->cpu_pmu_context);
WARN_ON_ONCE(cpc->task_epc && cpc->task_epc != pmu_ctx);
cpc->task_epc = NULL;
}
if (!event_type)
return;
perf_pmu_disable(pmu);
if (event_type & EVENT_PINNED) {
list_for_each_entry_safe(event, tmp,
&pmu_ctx->pinned_active,
active_list)
group_sched_out(event, ctx);
}
if (event_type & EVENT_FLEXIBLE) {
list_for_each_entry_safe(event, tmp,
&pmu_ctx->flexible_active,
active_list)
group_sched_out(event, ctx);
/*
* Since we cleared EVENT_FLEXIBLE, also clear
* rotate_necessary, is will be reset by
* ctx_flexible_sched_in() when needed.
*/
pmu_ctx->rotate_necessary = 0;
}
perf_pmu_enable(pmu);
}
static void
ctx_sched_out(struct perf_event_context *ctx, enum event_type_t event_type)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_pmu_context *pmu_ctx;
int is_active = ctx->is_active;
bool cgroup = event_type & EVENT_CGROUP;
event_type &= ~EVENT_CGROUP;
lockdep_assert_held(&ctx->lock);
if (likely(!ctx->nr_events)) {
/*
* See __perf_remove_from_context().
*/
WARN_ON_ONCE(ctx->is_active);
if (ctx->task)
WARN_ON_ONCE(cpuctx->task_ctx);
return;
}
/*
* Always update time if it was set; not only when it changes.
* Otherwise we can 'forget' to update time for any but the last
* context we sched out. For example:
*
* ctx_sched_out(.event_type = EVENT_FLEXIBLE)
* ctx_sched_out(.event_type = EVENT_PINNED)
*
* would only update time for the pinned events.
*/
if (is_active & EVENT_TIME) {
/* update (and stop) ctx time */
update_context_time(ctx);
update_cgrp_time_from_cpuctx(cpuctx, ctx == &cpuctx->ctx);
/*
* CPU-release for the below ->is_active store,
* see __load_acquire() in perf_event_time_now()
*/
barrier();
}
ctx->is_active &= ~event_type;
if (!(ctx->is_active & EVENT_ALL))
ctx->is_active = 0;
if (ctx->task) {
WARN_ON_ONCE(cpuctx->task_ctx != ctx);
if (!ctx->is_active)
cpuctx->task_ctx = NULL;
}
is_active ^= ctx->is_active; /* changed bits */
list_for_each_entry(pmu_ctx, &ctx->pmu_ctx_list, pmu_ctx_entry) {
if (cgroup && !pmu_ctx->nr_cgroups)
continue;
__pmu_ctx_sched_out(pmu_ctx, is_active);
}
}
/*
* Test whether two contexts are equivalent, i.e. whether they have both been
* cloned from the same version of the same context.
*
* Equivalence is measured using a generation number in the context that is
* incremented on each modification to it; see unclone_ctx(), list_add_event()
* and list_del_event().
*/
static int context_equiv(struct perf_event_context *ctx1,
struct perf_event_context *ctx2)
{
lockdep_assert_held(&ctx1->lock);
lockdep_assert_held(&ctx2->lock);
/* Pinning disables the swap optimization */
if (ctx1->pin_count || ctx2->pin_count)
return 0;
/* If ctx1 is the parent of ctx2 */
if (ctx1 == ctx2->parent_ctx && ctx1->generation == ctx2->parent_gen)
return 1;
/* If ctx2 is the parent of ctx1 */
if (ctx1->parent_ctx == ctx2 && ctx1->parent_gen == ctx2->generation)
return 1;
/*
* If ctx1 and ctx2 have the same parent; we flatten the parent
* hierarchy, see perf_event_init_context().
*/
if (ctx1->parent_ctx && ctx1->parent_ctx == ctx2->parent_ctx &&
ctx1->parent_gen == ctx2->parent_gen)
return 1;
/* Unmatched */
return 0;
}
static void __perf_event_sync_stat(struct perf_event *event,
struct perf_event *next_event)
{
u64 value;
if (!event->attr.inherit_stat)
return;
/*
* Update the event value, we cannot use perf_event_read()
* because we're in the middle of a context switch and have IRQs
* disabled, which upsets smp_call_function_single(), however
* we know the event must be on the current CPU, therefore we
* don't need to use it.
*/
if (event->state == PERF_EVENT_STATE_ACTIVE)
event->pmu->read(event);
perf_event_update_time(event);
/*
* In order to keep per-task stats reliable we need to flip the event
* values when we flip the contexts.
*/
value = local64_read(&next_event->count);
value = local64_xchg(&event->count, value);
local64_set(&next_event->count, value);
swap(event->total_time_enabled, next_event->total_time_enabled);
swap(event->total_time_running, next_event->total_time_running);
/*
* Since we swizzled the values, update the user visible data too.
*/
perf_event_update_userpage(event);
perf_event_update_userpage(next_event);
}
static void perf_event_sync_stat(struct perf_event_context *ctx,
struct perf_event_context *next_ctx)
{
struct perf_event *event, *next_event;
if (!ctx->nr_stat)
return;
update_context_time(ctx);
event = list_first_entry(&ctx->event_list,
struct perf_event, event_entry);
next_event = list_first_entry(&next_ctx->event_list,
struct perf_event, event_entry);
while (&event->event_entry != &ctx->event_list &&
&next_event->event_entry != &next_ctx->event_list) {
__perf_event_sync_stat(event, next_event);
event = list_next_entry(event, event_entry);
next_event = list_next_entry(next_event, event_entry);
}
}
#define double_list_for_each_entry(pos1, pos2, head1, head2, member) \
for (pos1 = list_first_entry(head1, typeof(*pos1), member), \
pos2 = list_first_entry(head2, typeof(*pos2), member); \
!list_entry_is_head(pos1, head1, member) && \
!list_entry_is_head(pos2, head2, member); \
pos1 = list_next_entry(pos1, member), \
pos2 = list_next_entry(pos2, member))
static void perf_event_swap_task_ctx_data(struct perf_event_context *prev_ctx,
struct perf_event_context *next_ctx)
{
struct perf_event_pmu_context *prev_epc, *next_epc;
if (!prev_ctx->nr_task_data)
return;
double_list_for_each_entry(prev_epc, next_epc,
&prev_ctx->pmu_ctx_list, &next_ctx->pmu_ctx_list,
pmu_ctx_entry) {
if (WARN_ON_ONCE(prev_epc->pmu != next_epc->pmu))
continue;
/*
* PMU specific parts of task perf context can require
* additional synchronization. As an example of such
* synchronization see implementation details of Intel
* LBR call stack data profiling;
*/
if (prev_epc->pmu->swap_task_ctx)
prev_epc->pmu->swap_task_ctx(prev_epc, next_epc);
else
swap(prev_epc->task_ctx_data, next_epc->task_ctx_data);
}
}
static void perf_ctx_sched_task_cb(struct perf_event_context *ctx, bool sched_in)
{
struct perf_event_pmu_context *pmu_ctx;
struct perf_cpu_pmu_context *cpc;
list_for_each_entry(pmu_ctx, &ctx->pmu_ctx_list, pmu_ctx_entry) {
cpc = this_cpu_ptr(pmu_ctx->pmu->cpu_pmu_context);
if (cpc->sched_cb_usage && pmu_ctx->pmu->sched_task)
pmu_ctx->pmu->sched_task(pmu_ctx, sched_in);
}
}
static void
perf_event_context_sched_out(struct task_struct *task, struct task_struct *next)
{
struct perf_event_context *ctx = task->perf_event_ctxp;
struct perf_event_context *next_ctx;
struct perf_event_context *parent, *next_parent;
int do_switch = 1;
if (likely(!ctx))
return;
rcu_read_lock();
next_ctx = rcu_dereference(next->perf_event_ctxp);
if (!next_ctx)
goto unlock;
parent = rcu_dereference(ctx->parent_ctx);
next_parent = rcu_dereference(next_ctx->parent_ctx);
/* If neither context have a parent context; they cannot be clones. */
if (!parent && !next_parent)
goto unlock;
if (next_parent == ctx || next_ctx == parent || next_parent == parent) {
/*
* Looks like the two contexts are clones, so we might be
* able to optimize the context switch. We lock both
* contexts and check that they are clones under the
* lock (including re-checking that neither has been
* uncloned in the meantime). It doesn't matter which
* order we take the locks because no other cpu could
* be trying to lock both of these tasks.
*/
raw_spin_lock(&ctx->lock);
raw_spin_lock_nested(&next_ctx->lock, SINGLE_DEPTH_NESTING);
if (context_equiv(ctx, next_ctx)) {
perf_ctx_disable(ctx, false);
/* PMIs are disabled; ctx->nr_pending is stable. */
if (local_read(&ctx->nr_pending) ||
local_read(&next_ctx->nr_pending)) {
/*
* Must not swap out ctx when there's pending
* events that rely on the ctx->task relation.
*/
raw_spin_unlock(&next_ctx->lock);
rcu_read_unlock();
goto inside_switch;
}
WRITE_ONCE(ctx->task, next);
WRITE_ONCE(next_ctx->task, task);
perf_ctx_sched_task_cb(ctx, false);
perf_event_swap_task_ctx_data(ctx, next_ctx);
perf_ctx_enable(ctx, false);
/*
* RCU_INIT_POINTER here is safe because we've not
* modified the ctx and the above modification of
* ctx->task and ctx->task_ctx_data are immaterial
* since those values are always verified under
* ctx->lock which we're now holding.
*/
RCU_INIT_POINTER(task->perf_event_ctxp, next_ctx);
RCU_INIT_POINTER(next->perf_event_ctxp, ctx);
do_switch = 0;
perf_event_sync_stat(ctx, next_ctx);
}
raw_spin_unlock(&next_ctx->lock);
raw_spin_unlock(&ctx->lock);
}
unlock:
rcu_read_unlock();
if (do_switch) {
raw_spin_lock(&ctx->lock);
perf_ctx_disable(ctx, false);
inside_switch:
perf_ctx_sched_task_cb(ctx, false);
task_ctx_sched_out(ctx, EVENT_ALL);
perf_ctx_enable(ctx, false);
raw_spin_unlock(&ctx->lock);
}
}
static DEFINE_PER_CPU(struct list_head, sched_cb_list);
static DEFINE_PER_CPU(int, perf_sched_cb_usages);
void perf_sched_cb_dec(struct pmu *pmu)
{
struct perf_cpu_pmu_context *cpc = this_cpu_ptr(pmu->cpu_pmu_context);
this_cpu_dec(perf_sched_cb_usages);
barrier();
if (!--cpc->sched_cb_usage)
list_del(&cpc->sched_cb_entry);
}
void perf_sched_cb_inc(struct pmu *pmu)
{
struct perf_cpu_pmu_context *cpc = this_cpu_ptr(pmu->cpu_pmu_context);
if (!cpc->sched_cb_usage++)
list_add(&cpc->sched_cb_entry, this_cpu_ptr(&sched_cb_list));
barrier();
this_cpu_inc(perf_sched_cb_usages);
}
/*
* This function provides the context switch callback to the lower code
* layer. It is invoked ONLY when the context switch callback is enabled.
*
* This callback is relevant even to per-cpu events; for example multi event
* PEBS requires this to provide PID/TID information. This requires we flush
* all queued PEBS records before we context switch to a new task.
*/
static void __perf_pmu_sched_task(struct perf_cpu_pmu_context *cpc, bool sched_in)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct pmu *pmu;
pmu = cpc->epc.pmu;
/* software PMUs will not have sched_task */
if (WARN_ON_ONCE(!pmu->sched_task))
return;
perf_ctx_lock(cpuctx, cpuctx->task_ctx);
perf_pmu_disable(pmu);
pmu->sched_task(cpc->task_epc, sched_in);
perf_pmu_enable(pmu);
perf_ctx_unlock(cpuctx, cpuctx->task_ctx);
}
static void perf_pmu_sched_task(struct task_struct *prev,
struct task_struct *next,
bool sched_in)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_cpu_pmu_context *cpc;
/* cpuctx->task_ctx will be handled in perf_event_context_sched_in/out */
if (prev == next || cpuctx->task_ctx)
return;
list_for_each_entry(cpc, this_cpu_ptr(&sched_cb_list), sched_cb_entry)
__perf_pmu_sched_task(cpc, sched_in);
}
static void perf_event_switch(struct task_struct *task,
struct task_struct *next_prev, bool sched_in);
/*
* Called from scheduler to remove the events of the current task,
* with interrupts disabled.
*
* We stop each event and update the event value in event->count.
*
* This does not protect us against NMI, but disable()
* sets the disabled bit in the control field of event _before_
* accessing the event control register. If a NMI hits, then it will
* not restart the event.
*/
void __perf_event_task_sched_out(struct task_struct *task,
struct task_struct *next)
{
if (__this_cpu_read(perf_sched_cb_usages))
perf_pmu_sched_task(task, next, false);
if (atomic_read(&nr_switch_events))
perf_event_switch(task, next, false);
perf_event_context_sched_out(task, next);
/*
* if cgroup events exist on this CPU, then we need
* to check if we have to switch out PMU state.
* cgroup event are system-wide mode only
*/
perf_cgroup_switch(next);
}
static bool perf_less_group_idx(const void *l, const void *r)
{
const struct perf_event *le = *(const struct perf_event **)l;
const struct perf_event *re = *(const struct perf_event **)r;
return le->group_index < re->group_index;
}
static void swap_ptr(void *l, void *r)
{
void **lp = l, **rp = r;
swap(*lp, *rp);
}
static const struct min_heap_callbacks perf_min_heap = {
.elem_size = sizeof(struct perf_event *),
.less = perf_less_group_idx,
.swp = swap_ptr,
};
static void __heap_add(struct min_heap *heap, struct perf_event *event)
{
struct perf_event **itrs = heap->data;
if (event) {
itrs[heap->nr] = event;
heap->nr++;
}
}
static void __link_epc(struct perf_event_pmu_context *pmu_ctx)
{
struct perf_cpu_pmu_context *cpc;
if (!pmu_ctx->ctx->task)
return;
cpc = this_cpu_ptr(pmu_ctx->pmu->cpu_pmu_context);
WARN_ON_ONCE(cpc->task_epc && cpc->task_epc != pmu_ctx);
cpc->task_epc = pmu_ctx;
}
static noinline int visit_groups_merge(struct perf_event_context *ctx,
struct perf_event_groups *groups, int cpu,
struct pmu *pmu,
int (*func)(struct perf_event *, void *),
void *data)
{
#ifdef CONFIG_CGROUP_PERF
struct cgroup_subsys_state *css = NULL;
#endif
struct perf_cpu_context *cpuctx = NULL;
/* Space for per CPU and/or any CPU event iterators. */
struct perf_event *itrs[2];
struct min_heap event_heap;
struct perf_event **evt;
int ret;
if (pmu->filter && pmu->filter(pmu, cpu))
return 0;
if (!ctx->task) {
cpuctx = this_cpu_ptr(&perf_cpu_context);
event_heap = (struct min_heap){
.data = cpuctx->heap,
.nr = 0,
.size = cpuctx->heap_size,
};
lockdep_assert_held(&cpuctx->ctx.lock);
#ifdef CONFIG_CGROUP_PERF
if (cpuctx->cgrp)
css = &cpuctx->cgrp->css;
#endif
} else {
event_heap = (struct min_heap){
.data = itrs,
.nr = 0,
.size = ARRAY_SIZE(itrs),
};
/* Events not within a CPU context may be on any CPU. */
__heap_add(&event_heap, perf_event_groups_first(groups, -1, pmu, NULL));
}
evt = event_heap.data;
__heap_add(&event_heap, perf_event_groups_first(groups, cpu, pmu, NULL));
#ifdef CONFIG_CGROUP_PERF
for (; css; css = css->parent)
__heap_add(&event_heap, perf_event_groups_first(groups, cpu, pmu, css->cgroup));
#endif
if (event_heap.nr) {
__link_epc((*evt)->pmu_ctx);
perf_assert_pmu_disabled((*evt)->pmu_ctx->pmu);
}
min_heapify_all(&event_heap, &perf_min_heap);
while (event_heap.nr) {
ret = func(*evt, data);
if (ret)
return ret;
*evt = perf_event_groups_next(*evt, pmu);
if (*evt)
min_heapify(&event_heap, 0, &perf_min_heap);
else
min_heap_pop(&event_heap, &perf_min_heap);
}
return 0;
}
/*
* Because the userpage is strictly per-event (there is no concept of context,
* so there cannot be a context indirection), every userpage must be updated
* when context time starts :-(
*
* IOW, we must not miss EVENT_TIME edges.
*/
static inline bool event_update_userpage(struct perf_event *event)
{
if (likely(!atomic_read(&event->mmap_count)))
return false;
perf_event_update_time(event);
perf_event_update_userpage(event);
return true;
}
static inline void group_update_userpage(struct perf_event *group_event)
{
struct perf_event *event;
if (!event_update_userpage(group_event))
return;
for_each_sibling_event(event, group_event)
event_update_userpage(event);
}
static int merge_sched_in(struct perf_event *event, void *data)
{
struct perf_event_context *ctx = event->ctx;
int *can_add_hw = data;
if (event->state <= PERF_EVENT_STATE_OFF)
return 0;
if (!event_filter_match(event))
return 0;
if (group_can_go_on(event, *can_add_hw)) {
if (!group_sched_in(event, ctx))
list_add_tail(&event->active_list, get_event_list(event));
}
if (event->state == PERF_EVENT_STATE_INACTIVE) {
*can_add_hw = 0;
if (event->attr.pinned) {
perf_cgroup_event_disable(event, ctx);
perf_event_set_state(event, PERF_EVENT_STATE_ERROR);
} else {
struct perf_cpu_pmu_context *cpc;
event->pmu_ctx->rotate_necessary = 1;
cpc = this_cpu_ptr(event->pmu_ctx->pmu->cpu_pmu_context);
perf_mux_hrtimer_restart(cpc);
group_update_userpage(event);
}
}
return 0;
}
static void pmu_groups_sched_in(struct perf_event_context *ctx,
struct perf_event_groups *groups,
struct pmu *pmu)
{
int can_add_hw = 1;
visit_groups_merge(ctx, groups, smp_processor_id(), pmu,
merge_sched_in, &can_add_hw);
}
static void ctx_groups_sched_in(struct perf_event_context *ctx,
struct perf_event_groups *groups,
bool cgroup)
{
struct perf_event_pmu_context *pmu_ctx;
list_for_each_entry(pmu_ctx, &ctx->pmu_ctx_list, pmu_ctx_entry) {
if (cgroup && !pmu_ctx->nr_cgroups)
continue;
pmu_groups_sched_in(ctx, groups, pmu_ctx->pmu);
}
}
static void __pmu_ctx_sched_in(struct perf_event_context *ctx,
struct pmu *pmu)
{
pmu_groups_sched_in(ctx, &ctx->flexible_groups, pmu);
}
static void
ctx_sched_in(struct perf_event_context *ctx, enum event_type_t event_type)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
int is_active = ctx->is_active;
bool cgroup = event_type & EVENT_CGROUP;
event_type &= ~EVENT_CGROUP;
lockdep_assert_held(&ctx->lock);
if (likely(!ctx->nr_events))
return;
if (!(is_active & EVENT_TIME)) {
/* start ctx time */
__update_context_time(ctx, false);
perf_cgroup_set_timestamp(cpuctx);
/*
* CPU-release for the below ->is_active store,
* see __load_acquire() in perf_event_time_now()
*/
barrier();
}
ctx->is_active |= (event_type | EVENT_TIME);
if (ctx->task) {
if (!is_active)
cpuctx->task_ctx = ctx;
else
WARN_ON_ONCE(cpuctx->task_ctx != ctx);
}
is_active ^= ctx->is_active; /* changed bits */
/*
* First go through the list and put on any pinned groups
* in order to give them the best chance of going on.
*/
if (is_active & EVENT_PINNED)
ctx_groups_sched_in(ctx, &ctx->pinned_groups, cgroup);
/* Then walk through the lower prio flexible groups */
if (is_active & EVENT_FLEXIBLE)
ctx_groups_sched_in(ctx, &ctx->flexible_groups, cgroup);
}
static void perf_event_context_sched_in(struct task_struct *task)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_context *ctx;
rcu_read_lock();
ctx = rcu_dereference(task->perf_event_ctxp);
if (!ctx)
goto rcu_unlock;
if (cpuctx->task_ctx == ctx) {
perf_ctx_lock(cpuctx, ctx);
perf_ctx_disable(ctx, false);
perf_ctx_sched_task_cb(ctx, true);
perf_ctx_enable(ctx, false);
perf_ctx_unlock(cpuctx, ctx);
goto rcu_unlock;
}
perf_ctx_lock(cpuctx, ctx);
/*
* We must check ctx->nr_events while holding ctx->lock, such
* that we serialize against perf_install_in_context().
*/
if (!ctx->nr_events)
goto unlock;
perf_ctx_disable(ctx, false);
/*
* We want to keep the following priority order:
* cpu pinned (that don't need to move), task pinned,
* cpu flexible, task flexible.
*
* However, if task's ctx is not carrying any pinned
* events, no need to flip the cpuctx's events around.
*/
if (!RB_EMPTY_ROOT(&ctx->pinned_groups.tree)) {
perf_ctx_disable(&cpuctx->ctx, false);
ctx_sched_out(&cpuctx->ctx, EVENT_FLEXIBLE);
}
perf_event_sched_in(cpuctx, ctx);
perf_ctx_sched_task_cb(cpuctx->task_ctx, true);
if (!RB_EMPTY_ROOT(&ctx->pinned_groups.tree))
perf_ctx_enable(&cpuctx->ctx, false);
perf_ctx_enable(ctx, false);
unlock:
perf_ctx_unlock(cpuctx, ctx);
rcu_unlock:
rcu_read_unlock();
}
/*
* Called from scheduler to add the events of the current task
* with interrupts disabled.
*
* We restore the event value and then enable it.
*
* This does not protect us against NMI, but enable()
* sets the enabled bit in the control field of event _before_
* accessing the event control register. If a NMI hits, then it will
* keep the event running.
*/
void __perf_event_task_sched_in(struct task_struct *prev,
struct task_struct *task)
{
perf_event_context_sched_in(task);
if (atomic_read(&nr_switch_events))
perf_event_switch(task, prev, true);
if (__this_cpu_read(perf_sched_cb_usages))
perf_pmu_sched_task(prev, task, true);
}
static u64 perf_calculate_period(struct perf_event *event, u64 nsec, u64 count)
{
u64 frequency = event->attr.sample_freq;
u64 sec = NSEC_PER_SEC;
u64 divisor, dividend;
int count_fls, nsec_fls, frequency_fls, sec_fls;
count_fls = fls64(count);
nsec_fls = fls64(nsec);
frequency_fls = fls64(frequency);
sec_fls = 30;
/*
* We got @count in @nsec, with a target of sample_freq HZ
* the target period becomes:
*
* @count * 10^9
* period = -------------------
* @nsec * sample_freq
*
*/
/*
* Reduce accuracy by one bit such that @a and @b converge
* to a similar magnitude.
*/
#define REDUCE_FLS(a, b) \
do { \
if (a##_fls > b##_fls) { \
a >>= 1; \
a##_fls--; \
} else { \
b >>= 1; \
b##_fls--; \
} \
} while (0)
/*
* Reduce accuracy until either term fits in a u64, then proceed with
* the other, so that finally we can do a u64/u64 division.
*/
while (count_fls + sec_fls > 64 && nsec_fls + frequency_fls > 64) {
REDUCE_FLS(nsec, frequency);
REDUCE_FLS(sec, count);
}
if (count_fls + sec_fls > 64) {
divisor = nsec * frequency;
while (count_fls + sec_fls > 64) {
REDUCE_FLS(count, sec);
divisor >>= 1;
}
dividend = count * sec;
} else {
dividend = count * sec;
while (nsec_fls + frequency_fls > 64) {
REDUCE_FLS(nsec, frequency);
dividend >>= 1;
}
divisor = nsec * frequency;
}
if (!divisor)
return dividend;
return div64_u64(dividend, divisor);
}
static DEFINE_PER_CPU(int, perf_throttled_count);
static DEFINE_PER_CPU(u64, perf_throttled_seq);
static void perf_adjust_period(struct perf_event *event, u64 nsec, u64 count, bool disable)
{
struct hw_perf_event *hwc = &event->hw;
s64 period, sample_period;
s64 delta;
period = perf_calculate_period(event, nsec, count);
delta = (s64)(period - hwc->sample_period);
delta = (delta + 7) / 8; /* low pass filter */
sample_period = hwc->sample_period + delta;
if (!sample_period)
sample_period = 1;
hwc->sample_period = sample_period;
if (local64_read(&hwc->period_left) > 8*sample_period) {
if (disable)
event->pmu->stop(event, PERF_EF_UPDATE);
local64_set(&hwc->period_left, 0);
if (disable)
event->pmu->start(event, PERF_EF_RELOAD);
}
}
/*
* combine freq adjustment with unthrottling to avoid two passes over the
* events. At the same time, make sure, having freq events does not change
* the rate of unthrottling as that would introduce bias.
*/
static void
perf_adjust_freq_unthr_context(struct perf_event_context *ctx, bool unthrottle)
{
struct perf_event *event;
struct hw_perf_event *hwc;
u64 now, period = TICK_NSEC;
s64 delta;
/*
* only need to iterate over all events iff:
* - context have events in frequency mode (needs freq adjust)
* - there are events to unthrottle on this cpu
*/
if (!(ctx->nr_freq || unthrottle))
return;
raw_spin_lock(&ctx->lock);
list_for_each_entry_rcu(event, &ctx->event_list, event_entry) {
if (event->state != PERF_EVENT_STATE_ACTIVE)
continue;
// XXX use visit thingy to avoid the -1,cpu match
if (!event_filter_match(event))
continue;
perf_pmu_disable(event->pmu);
hwc = &event->hw;
if (hwc->interrupts == MAX_INTERRUPTS) {
hwc->interrupts = 0;
perf_log_throttle(event, 1);
event->pmu->start(event, 0);
}
if (!event->attr.freq || !event->attr.sample_freq)
goto next;
/*
* stop the event and update event->count
*/
event->pmu->stop(event, PERF_EF_UPDATE);
now = local64_read(&event->count);
delta = now - hwc->freq_count_stamp;
hwc->freq_count_stamp = now;
/*
* restart the event
* reload only if value has changed
* we have stopped the event so tell that
* to perf_adjust_period() to avoid stopping it
* twice.
*/
if (delta > 0)
perf_adjust_period(event, period, delta, false);
event->pmu->start(event, delta > 0 ? PERF_EF_RELOAD : 0);
next:
perf_pmu_enable(event->pmu);
}
raw_spin_unlock(&ctx->lock);
}
/*
* Move @event to the tail of the @ctx's elegible events.
*/
static void rotate_ctx(struct perf_event_context *ctx, struct perf_event *event)
{
/*
* Rotate the first entry last of non-pinned groups. Rotation might be
* disabled by the inheritance code.
*/
if (ctx->rotate_disable)
return;
perf_event_groups_delete(&ctx->flexible_groups, event);
perf_event_groups_insert(&ctx->flexible_groups, event);
}
/* pick an event from the flexible_groups to rotate */
static inline struct perf_event *
ctx_event_to_rotate(struct perf_event_pmu_context *pmu_ctx)
{
struct perf_event *event;
struct rb_node *node;
struct rb_root *tree;
struct __group_key key = {
.pmu = pmu_ctx->pmu,
};
/* pick the first active flexible event */
event = list_first_entry_or_null(&pmu_ctx->flexible_active,
struct perf_event, active_list);
if (event)
goto out;
/* if no active flexible event, pick the first event */
tree = &pmu_ctx->ctx->flexible_groups.tree;
if (!pmu_ctx->ctx->task) {
key.cpu = smp_processor_id();
node = rb_find_first(&key, tree, __group_cmp_ignore_cgroup);
if (node)
event = __node_2_pe(node);
goto out;
}
key.cpu = -1;
node = rb_find_first(&key, tree, __group_cmp_ignore_cgroup);
if (node) {
event = __node_2_pe(node);
goto out;
}
key.cpu = smp_processor_id();
node = rb_find_first(&key, tree, __group_cmp_ignore_cgroup);
if (node)
event = __node_2_pe(node);
out:
/*
* Unconditionally clear rotate_necessary; if ctx_flexible_sched_in()
* finds there are unschedulable events, it will set it again.
*/
pmu_ctx->rotate_necessary = 0;
return event;
}
static bool perf_rotate_context(struct perf_cpu_pmu_context *cpc)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_pmu_context *cpu_epc, *task_epc = NULL;
struct perf_event *cpu_event = NULL, *task_event = NULL;
int cpu_rotate, task_rotate;
struct pmu *pmu;
/*
* Since we run this from IRQ context, nobody can install new
* events, thus the event count values are stable.
*/
cpu_epc = &cpc->epc;
pmu = cpu_epc->pmu;
task_epc = cpc->task_epc;
cpu_rotate = cpu_epc->rotate_necessary;
task_rotate = task_epc ? task_epc->rotate_necessary : 0;
if (!(cpu_rotate || task_rotate))
return false;
perf_ctx_lock(cpuctx, cpuctx->task_ctx);
perf_pmu_disable(pmu);
if (task_rotate)
task_event = ctx_event_to_rotate(task_epc);
if (cpu_rotate)
cpu_event = ctx_event_to_rotate(cpu_epc);
/*
* As per the order given at ctx_resched() first 'pop' task flexible
* and then, if needed CPU flexible.
*/
if (task_event || (task_epc && cpu_event)) {
update_context_time(task_epc->ctx);
__pmu_ctx_sched_out(task_epc, EVENT_FLEXIBLE);
}
if (cpu_event) {
update_context_time(&cpuctx->ctx);
__pmu_ctx_sched_out(cpu_epc, EVENT_FLEXIBLE);
rotate_ctx(&cpuctx->ctx, cpu_event);
__pmu_ctx_sched_in(&cpuctx->ctx, pmu);
}
if (task_event)
rotate_ctx(task_epc->ctx, task_event);
if (task_event || (task_epc && cpu_event))
__pmu_ctx_sched_in(task_epc->ctx, pmu);
perf_pmu_enable(pmu);
perf_ctx_unlock(cpuctx, cpuctx->task_ctx);
return true;
}
void perf_event_task_tick(void)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_context *ctx;
int throttled;
lockdep_assert_irqs_disabled();
__this_cpu_inc(perf_throttled_seq);
throttled = __this_cpu_xchg(perf_throttled_count, 0);
tick_dep_clear_cpu(smp_processor_id(), TICK_DEP_BIT_PERF_EVENTS);
perf_adjust_freq_unthr_context(&cpuctx->ctx, !!throttled);
rcu_read_lock();
ctx = rcu_dereference(current->perf_event_ctxp);
if (ctx)
perf_adjust_freq_unthr_context(ctx, !!throttled);
rcu_read_unlock();
}
static int event_enable_on_exec(struct perf_event *event,
struct perf_event_context *ctx)
{
if (!event->attr.enable_on_exec)
return 0;
event->attr.enable_on_exec = 0;
if (event->state >= PERF_EVENT_STATE_INACTIVE)
return 0;
perf_event_set_state(event, PERF_EVENT_STATE_INACTIVE);
return 1;
}
/*
* Enable all of a task's events that have been marked enable-on-exec.
* This expects task == current.
*/
static void perf_event_enable_on_exec(struct perf_event_context *ctx)
{
struct perf_event_context *clone_ctx = NULL;
enum event_type_t event_type = 0;
struct perf_cpu_context *cpuctx;
struct perf_event *event;
unsigned long flags;
int enabled = 0;
local_irq_save(flags);
if (WARN_ON_ONCE(current->perf_event_ctxp != ctx))
goto out;
if (!ctx->nr_events)
goto out;
cpuctx = this_cpu_ptr(&perf_cpu_context);
perf_ctx_lock(cpuctx, ctx);
ctx_sched_out(ctx, EVENT_TIME);
list_for_each_entry(event, &ctx->event_list, event_entry) {
enabled |= event_enable_on_exec(event, ctx);
event_type |= get_event_type(event);
}
/*
* Unclone and reschedule this context if we enabled any event.
*/
if (enabled) {
clone_ctx = unclone_ctx(ctx);
ctx_resched(cpuctx, ctx, event_type);
} else {
ctx_sched_in(ctx, EVENT_TIME);
}
perf_ctx_unlock(cpuctx, ctx);
out:
local_irq_restore(flags);
if (clone_ctx)
put_ctx(clone_ctx);
}
static void perf_remove_from_owner(struct perf_event *event);
static void perf_event_exit_event(struct perf_event *event,
struct perf_event_context *ctx);
/*
* Removes all events from the current task that have been marked
* remove-on-exec, and feeds their values back to parent events.
*/
static void perf_event_remove_on_exec(struct perf_event_context *ctx)
{
struct perf_event_context *clone_ctx = NULL;
struct perf_event *event, *next;
unsigned long flags;
bool modified = false;
mutex_lock(&ctx->mutex);
if (WARN_ON_ONCE(ctx->task != current))
goto unlock;
list_for_each_entry_safe(event, next, &ctx->event_list, event_entry) {
if (!event->attr.remove_on_exec)
continue;
if (!is_kernel_event(event))
perf_remove_from_owner(event);
modified = true;
perf_event_exit_event(event, ctx);
}
raw_spin_lock_irqsave(&ctx->lock, flags);
if (modified)
clone_ctx = unclone_ctx(ctx);
raw_spin_unlock_irqrestore(&ctx->lock, flags);
unlock:
mutex_unlock(&ctx->mutex);
if (clone_ctx)
put_ctx(clone_ctx);
}
struct perf_read_data {
struct perf_event *event;
bool group;
int ret;
};
static int __perf_event_read_cpu(struct perf_event *event, int event_cpu)
{
u16 local_pkg, event_pkg;
if ((unsigned)event_cpu >= nr_cpu_ids)
return event_cpu;
if (event->group_caps & PERF_EV_CAP_READ_ACTIVE_PKG) {
int local_cpu = smp_processor_id();
event_pkg = topology_physical_package_id(event_cpu);
local_pkg = topology_physical_package_id(local_cpu);
if (event_pkg == local_pkg)
return local_cpu;
}
return event_cpu;
}
/*
* Cross CPU call to read the hardware event
*/
static void __perf_event_read(void *info)
{
struct perf_read_data *data = info;
struct perf_event *sub, *event = data->event;
struct perf_event_context *ctx = event->ctx;
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct pmu *pmu = event->pmu;
/*
* If this is a task context, we need to check whether it is
* the current task context of this cpu. If not it has been
* scheduled out before the smp call arrived. In that case
* event->count would have been updated to a recent sample
* when the event was scheduled out.
*/
if (ctx->task && cpuctx->task_ctx != ctx)
return;
raw_spin_lock(&ctx->lock);
if (ctx->is_active & EVENT_TIME) {
update_context_time(ctx);
update_cgrp_time_from_event(event);
}
perf_event_update_time(event);
if (data->group)
perf_event_update_sibling_time(event);
if (event->state != PERF_EVENT_STATE_ACTIVE)
goto unlock;
if (!data->group) {
pmu->read(event);
data->ret = 0;
goto unlock;
}
pmu->start_txn(pmu, PERF_PMU_TXN_READ);
pmu->read(event);
for_each_sibling_event(sub, event) {
if (sub->state == PERF_EVENT_STATE_ACTIVE) {
/*
* Use sibling's PMU rather than @event's since
* sibling could be on different (eg: software) PMU.
*/
sub->pmu->read(sub);
}
}
data->ret = pmu->commit_txn(pmu);
unlock:
raw_spin_unlock(&ctx->lock);
}
static inline u64 perf_event_count(struct perf_event *event)
{
return local64_read(&event->count) + atomic64_read(&event->child_count);
}
static void calc_timer_values(struct perf_event *event,
u64 *now,
u64 *enabled,
u64 *running)
{
u64 ctx_time;
*now = perf_clock();
ctx_time = perf_event_time_now(event, *now);
__perf_update_times(event, ctx_time, enabled, running);
}
/*
* NMI-safe method to read a local event, that is an event that
* is:
* - either for the current task, or for this CPU
* - does not have inherit set, for inherited task events
* will not be local and we cannot read them atomically
* - must not have a pmu::count method
*/
int perf_event_read_local(struct perf_event *event, u64 *value,
u64 *enabled, u64 *running)
{
unsigned long flags;
int event_oncpu;
int event_cpu;
int ret = 0;
/*
* Disabling interrupts avoids all counter scheduling (context
* switches, timer based rotation and IPIs).
*/
local_irq_save(flags);
/*
* It must not be an event with inherit set, we cannot read
* all child counters from atomic context.
*/
if (event->attr.inherit) {
ret = -EOPNOTSUPP;
goto out;
}
/* If this is a per-task event, it must be for current */
if ((event->attach_state & PERF_ATTACH_TASK) &&
event->hw.target != current) {
ret = -EINVAL;
goto out;
}
/*
* Get the event CPU numbers, and adjust them to local if the event is
* a per-package event that can be read locally
*/
event_oncpu = __perf_event_read_cpu(event, event->oncpu);
event_cpu = __perf_event_read_cpu(event, event->cpu);
/* If this is a per-CPU event, it must be for this CPU */
if (!(event->attach_state & PERF_ATTACH_TASK) &&
event_cpu != smp_processor_id()) {
ret = -EINVAL;
goto out;
}
/* If this is a pinned event it must be running on this CPU */
if (event->attr.pinned && event_oncpu != smp_processor_id()) {
ret = -EBUSY;
goto out;
}
/*
* If the event is currently on this CPU, its either a per-task event,
* or local to this CPU. Furthermore it means its ACTIVE (otherwise
* oncpu == -1).
*/
if (event_oncpu == smp_processor_id())
event->pmu->read(event);
*value = local64_read(&event->count);
if (enabled || running) {
u64 __enabled, __running, __now;
calc_timer_values(event, &__now, &__enabled, &__running);
if (enabled)
*enabled = __enabled;
if (running)
*running = __running;
}
out:
local_irq_restore(flags);
return ret;
}
static int perf_event_read(struct perf_event *event, bool group)
{
enum perf_event_state state = READ_ONCE(event->state);
int event_cpu, ret = 0;
/*
* If event is enabled and currently active on a CPU, update the
* value in the event structure:
*/
again:
if (state == PERF_EVENT_STATE_ACTIVE) {
struct perf_read_data data;
/*
* Orders the ->state and ->oncpu loads such that if we see
* ACTIVE we must also see the right ->oncpu.
*
* Matches the smp_wmb() from event_sched_in().
*/
smp_rmb();
event_cpu = READ_ONCE(event->oncpu);
if ((unsigned)event_cpu >= nr_cpu_ids)
return 0;
data = (struct perf_read_data){
.event = event,
.group = group,
.ret = 0,
};
preempt_disable();
event_cpu = __perf_event_read_cpu(event, event_cpu);
/*
* Purposely ignore the smp_call_function_single() return
* value.
*
* If event_cpu isn't a valid CPU it means the event got
* scheduled out and that will have updated the event count.
*
* Therefore, either way, we'll have an up-to-date event count
* after this.
*/
(void)smp_call_function_single(event_cpu, __perf_event_read, &data, 1);
preempt_enable();
ret = data.ret;
} else if (state == PERF_EVENT_STATE_INACTIVE) {
struct perf_event_context *ctx = event->ctx;
unsigned long flags;
raw_spin_lock_irqsave(&ctx->lock, flags);
state = event->state;
if (state != PERF_EVENT_STATE_INACTIVE) {
raw_spin_unlock_irqrestore(&ctx->lock, flags);
goto again;
}
/*
* May read while context is not active (e.g., thread is
* blocked), in that case we cannot update context time
*/
if (ctx->is_active & EVENT_TIME) {
update_context_time(ctx);
update_cgrp_time_from_event(event);
}
perf_event_update_time(event);
if (group)
perf_event_update_sibling_time(event);
raw_spin_unlock_irqrestore(&ctx->lock, flags);
}
return ret;
}
/*
* Initialize the perf_event context in a task_struct:
*/
static void __perf_event_init_context(struct perf_event_context *ctx)
{
raw_spin_lock_init(&ctx->lock);
mutex_init(&ctx->mutex);
INIT_LIST_HEAD(&ctx->pmu_ctx_list);
perf_event_groups_init(&ctx->pinned_groups);
perf_event_groups_init(&ctx->flexible_groups);
INIT_LIST_HEAD(&ctx->event_list);
refcount_set(&ctx->refcount, 1);
}
static void
__perf_init_event_pmu_context(struct perf_event_pmu_context *epc, struct pmu *pmu)
{
epc->pmu = pmu;
INIT_LIST_HEAD(&epc->pmu_ctx_entry);
INIT_LIST_HEAD(&epc->pinned_active);
INIT_LIST_HEAD(&epc->flexible_active);
atomic_set(&epc->refcount, 1);
}
static struct perf_event_context *
alloc_perf_context(struct task_struct *task)
{
struct perf_event_context *ctx;
ctx = kzalloc(sizeof(struct perf_event_context), GFP_KERNEL);
if (!ctx)
return NULL;
__perf_event_init_context(ctx);
if (task)
ctx->task = get_task_struct(task);
return ctx;
}
static struct task_struct *
find_lively_task_by_vpid(pid_t vpid)
{
struct task_struct *task;
rcu_read_lock();
if (!vpid)
task = current;
else
task = find_task_by_vpid(vpid);
if (task)
get_task_struct(task);
rcu_read_unlock();
if (!task)
return ERR_PTR(-ESRCH);
return task;
}
/*
* Returns a matching context with refcount and pincount.
*/
static struct perf_event_context *
find_get_context(struct task_struct *task, struct perf_event *event)
{
struct perf_event_context *ctx, *clone_ctx = NULL;
struct perf_cpu_context *cpuctx;
unsigned long flags;
int err;
if (!task) {
/* Must be root to operate on a CPU event: */
err = perf_allow_cpu(&event->attr);
if (err)
return ERR_PTR(err);
cpuctx = per_cpu_ptr(&perf_cpu_context, event->cpu);
ctx = &cpuctx->ctx;
get_ctx(ctx);
raw_spin_lock_irqsave(&ctx->lock, flags);
++ctx->pin_count;
raw_spin_unlock_irqrestore(&ctx->lock, flags);
return ctx;
}
err = -EINVAL;
retry:
ctx = perf_lock_task_context(task, &flags);
if (ctx) {
clone_ctx = unclone_ctx(ctx);
++ctx->pin_count;
raw_spin_unlock_irqrestore(&ctx->lock, flags);
if (clone_ctx)
put_ctx(clone_ctx);
} else {
ctx = alloc_perf_context(task);
err = -ENOMEM;
if (!ctx)
goto errout;
err = 0;
mutex_lock(&task->perf_event_mutex);
/*
* If it has already passed perf_event_exit_task().
* we must see PF_EXITING, it takes this mutex too.
*/
if (task->flags & PF_EXITING)
err = -ESRCH;
else if (task->perf_event_ctxp)
err = -EAGAIN;
else {
get_ctx(ctx);
++ctx->pin_count;
rcu_assign_pointer(task->perf_event_ctxp, ctx);
}
mutex_unlock(&task->perf_event_mutex);
if (unlikely(err)) {
put_ctx(ctx);
if (err == -EAGAIN)
goto retry;
goto errout;
}
}
return ctx;
errout:
return ERR_PTR(err);
}
static struct perf_event_pmu_context *
find_get_pmu_context(struct pmu *pmu, struct perf_event_context *ctx,
struct perf_event *event)
{
struct perf_event_pmu_context *new = NULL, *epc;
void *task_ctx_data = NULL;
if (!ctx->task) {
/*
* perf_pmu_migrate_context() / __perf_pmu_install_event()
* relies on the fact that find_get_pmu_context() cannot fail
* for CPU contexts.
*/
struct perf_cpu_pmu_context *cpc;
cpc = per_cpu_ptr(pmu->cpu_pmu_context, event->cpu);
epc = &cpc->epc;
raw_spin_lock_irq(&ctx->lock);
if (!epc->ctx) {
atomic_set(&epc->refcount, 1);
epc->embedded = 1;
list_add(&epc->pmu_ctx_entry, &ctx->pmu_ctx_list);
epc->ctx = ctx;
} else {
WARN_ON_ONCE(epc->ctx != ctx);
atomic_inc(&epc->refcount);
}
raw_spin_unlock_irq(&ctx->lock);
return epc;
}
new = kzalloc(sizeof(*epc), GFP_KERNEL);
if (!new)
return ERR_PTR(-ENOMEM);
if (event->attach_state & PERF_ATTACH_TASK_DATA) {
task_ctx_data = alloc_task_ctx_data(pmu);
if (!task_ctx_data) {
kfree(new);
return ERR_PTR(-ENOMEM);
}
}
__perf_init_event_pmu_context(new, pmu);
/*
* XXX
*
* lockdep_assert_held(&ctx->mutex);
*
* can't because perf_event_init_task() doesn't actually hold the
* child_ctx->mutex.
*/
raw_spin_lock_irq(&ctx->lock);
list_for_each_entry(epc, &ctx->pmu_ctx_list, pmu_ctx_entry) {
if (epc->pmu == pmu) {
WARN_ON_ONCE(epc->ctx != ctx);
atomic_inc(&epc->refcount);
goto found_epc;
}
}
epc = new;
new = NULL;
list_add(&epc->pmu_ctx_entry, &ctx->pmu_ctx_list);
epc->ctx = ctx;
found_epc:
if (task_ctx_data && !epc->task_ctx_data) {
epc->task_ctx_data = task_ctx_data;
task_ctx_data = NULL;
ctx->nr_task_data++;
}
raw_spin_unlock_irq(&ctx->lock);
free_task_ctx_data(pmu, task_ctx_data);
kfree(new);
return epc;
}
static void get_pmu_ctx(struct perf_event_pmu_context *epc)
{
WARN_ON_ONCE(!atomic_inc_not_zero(&epc->refcount));
}
static void free_epc_rcu(struct rcu_head *head)
{
struct perf_event_pmu_context *epc = container_of(head, typeof(*epc), rcu_head);
kfree(epc->task_ctx_data);
kfree(epc);
}
static void put_pmu_ctx(struct perf_event_pmu_context *epc)
{
struct perf_event_context *ctx = epc->ctx;
unsigned long flags;
/*
* XXX
*
* lockdep_assert_held(&ctx->mutex);
*
* can't because of the call-site in _free_event()/put_event()
* which isn't always called under ctx->mutex.
*/
if (!atomic_dec_and_raw_lock_irqsave(&epc->refcount, &ctx->lock, flags))
return;
WARN_ON_ONCE(list_empty(&epc->pmu_ctx_entry));
list_del_init(&epc->pmu_ctx_entry);
epc->ctx = NULL;
WARN_ON_ONCE(!list_empty(&epc->pinned_active));
WARN_ON_ONCE(!list_empty(&epc->flexible_active));
raw_spin_unlock_irqrestore(&ctx->lock, flags);
if (epc->embedded)
return;
call_rcu(&epc->rcu_head, free_epc_rcu);
}
static void perf_event_free_filter(struct perf_event *event);
static void free_event_rcu(struct rcu_head *head)
{
struct perf_event *event = container_of(head, typeof(*event), rcu_head);
if (event->ns)
put_pid_ns(event->ns);
perf_event_free_filter(event);
kmem_cache_free(perf_event_cache, event);
}
static void ring_buffer_attach(struct perf_event *event,
struct perf_buffer *rb);
static void detach_sb_event(struct perf_event *event)
{
struct pmu_event_list *pel = per_cpu_ptr(&pmu_sb_events, event->cpu);
raw_spin_lock(&pel->lock);
list_del_rcu(&event->sb_list);
raw_spin_unlock(&pel->lock);
}
static bool is_sb_event(struct perf_event *event)
{
struct perf_event_attr *attr = &event->attr;
if (event->parent)
return false;
if (event->attach_state & PERF_ATTACH_TASK)
return false;
if (attr->mmap || attr->mmap_data || attr->mmap2 ||
attr->comm || attr->comm_exec ||
attr->task || attr->ksymbol ||
attr->context_switch || attr->text_poke ||
attr->bpf_event)
return true;
return false;
}
static void unaccount_pmu_sb_event(struct perf_event *event)
{
if (is_sb_event(event))
detach_sb_event(event);
}
#ifdef CONFIG_NO_HZ_FULL
static DEFINE_SPINLOCK(nr_freq_lock);
#endif
static void unaccount_freq_event_nohz(void)
{
#ifdef CONFIG_NO_HZ_FULL
spin_lock(&nr_freq_lock);
if (atomic_dec_and_test(&nr_freq_events))
tick_nohz_dep_clear(TICK_DEP_BIT_PERF_EVENTS);
spin_unlock(&nr_freq_lock);
#endif
}
static void unaccount_freq_event(void)
{
if (tick_nohz_full_enabled())
unaccount_freq_event_nohz();
else
atomic_dec(&nr_freq_events);
}
static void unaccount_event(struct perf_event *event)
{
bool dec = false;
if (event->parent)
return;
if (event->attach_state & (PERF_ATTACH_TASK | PERF_ATTACH_SCHED_CB))
dec = true;
if (event->attr.mmap || event->attr.mmap_data)
atomic_dec(&nr_mmap_events);
if (event->attr.build_id)
atomic_dec(&nr_build_id_events);
if (event->attr.comm)
atomic_dec(&nr_comm_events);
if (event->attr.namespaces)
atomic_dec(&nr_namespaces_events);
if (event->attr.cgroup)
atomic_dec(&nr_cgroup_events);
if (event->attr.task)
atomic_dec(&nr_task_events);
if (event->attr.freq)
unaccount_freq_event();
if (event->attr.context_switch) {
dec = true;
atomic_dec(&nr_switch_events);
}
if (is_cgroup_event(event))
dec = true;
if (has_branch_stack(event))
dec = true;
if (event->attr.ksymbol)
atomic_dec(&nr_ksymbol_events);
if (event->attr.bpf_event)
atomic_dec(&nr_bpf_events);
if (event->attr.text_poke)
atomic_dec(&nr_text_poke_events);
if (dec) {
if (!atomic_add_unless(&perf_sched_count, -1, 1))
schedule_delayed_work(&perf_sched_work, HZ);
}
unaccount_pmu_sb_event(event);
}
static void perf_sched_delayed(struct work_struct *work)
{
mutex_lock(&perf_sched_mutex);
if (atomic_dec_and_test(&perf_sched_count))
static_branch_disable(&perf_sched_events);
mutex_unlock(&perf_sched_mutex);
}
/*
* The following implement mutual exclusion of events on "exclusive" pmus
* (PERF_PMU_CAP_EXCLUSIVE). Such pmus can only have one event scheduled
* at a time, so we disallow creating events that might conflict, namely:
*
* 1) cpu-wide events in the presence of per-task events,
* 2) per-task events in the presence of cpu-wide events,
* 3) two matching events on the same perf_event_context.
*
* The former two cases are handled in the allocation path (perf_event_alloc(),
* _free_event()), the latter -- before the first perf_install_in_context().
*/
static int exclusive_event_init(struct perf_event *event)
{
struct pmu *pmu = event->pmu;
if (!is_exclusive_pmu(pmu))
return 0;
/*
* Prevent co-existence of per-task and cpu-wide events on the
* same exclusive pmu.
*
* Negative pmu::exclusive_cnt means there are cpu-wide
* events on this "exclusive" pmu, positive means there are
* per-task events.
*
* Since this is called in perf_event_alloc() path, event::ctx
* doesn't exist yet; it is, however, safe to use PERF_ATTACH_TASK
* to mean "per-task event", because unlike other attach states it
* never gets cleared.
*/
if (event->attach_state & PERF_ATTACH_TASK) {
if (!atomic_inc_unless_negative(&pmu->exclusive_cnt))
return -EBUSY;
} else {
if (!atomic_dec_unless_positive(&pmu->exclusive_cnt))
return -EBUSY;
}
return 0;
}
static void exclusive_event_destroy(struct perf_event *event)
{
struct pmu *pmu = event->pmu;
if (!is_exclusive_pmu(pmu))
return;
/* see comment in exclusive_event_init() */
if (event->attach_state & PERF_ATTACH_TASK)
atomic_dec(&pmu->exclusive_cnt);
else
atomic_inc(&pmu->exclusive_cnt);
}
static bool exclusive_event_match(struct perf_event *e1, struct perf_event *e2)
{
if ((e1->pmu == e2->pmu) &&
(e1->cpu == e2->cpu ||
e1->cpu == -1 ||
e2->cpu == -1))
return true;
return false;
}
static bool exclusive_event_installable(struct perf_event *event,
struct perf_event_context *ctx)
{
struct perf_event *iter_event;
struct pmu *pmu = event->pmu;
lockdep_assert_held(&ctx->mutex);
if (!is_exclusive_pmu(pmu))
return true;
list_for_each_entry(iter_event, &ctx->event_list, event_entry) {
if (exclusive_event_match(iter_event, event))
return false;
}
return true;
}
static void perf_addr_filters_splice(struct perf_event *event,
struct list_head *head);
static void _free_event(struct perf_event *event)
{
irq_work_sync(&event->pending_irq);
unaccount_event(event);
security_perf_event_free(event);
if (event->rb) {
/*
* Can happen when we close an event with re-directed output.
*
* Since we have a 0 refcount, perf_mmap_close() will skip
* over us; possibly making our ring_buffer_put() the last.
*/
mutex_lock(&event->mmap_mutex);
ring_buffer_attach(event, NULL);
mutex_unlock(&event->mmap_mutex);
}
if (is_cgroup_event(event))
perf_detach_cgroup(event);
if (!event->parent) {
if (event->attr.sample_type & PERF_SAMPLE_CALLCHAIN)
put_callchain_buffers();
}
perf_event_free_bpf_prog(event);
perf_addr_filters_splice(event, NULL);
kfree(event->addr_filter_ranges);
if (event->destroy)
event->destroy(event);
/*
* Must be after ->destroy(), due to uprobe_perf_close() using
* hw.target.
*/
if (event->hw.target)
put_task_struct(event->hw.target);
if (event->pmu_ctx)
put_pmu_ctx(event->pmu_ctx);
/*
* perf_event_free_task() relies on put_ctx() being 'last', in particular
* all task references must be cleaned up.
*/
if (event->ctx)
put_ctx(event->ctx);
exclusive_event_destroy(event);
module_put(event->pmu->module);
call_rcu(&event->rcu_head, free_event_rcu);
}
/*
* Used to free events which have a known refcount of 1, such as in error paths
* where the event isn't exposed yet and inherited events.
*/
static void free_event(struct perf_event *event)
{
if (WARN(atomic_long_cmpxchg(&event->refcount, 1, 0) != 1,
"unexpected event refcount: %ld; ptr=%p\n",
atomic_long_read(&event->refcount), event)) {
/* leak to avoid use-after-free */
return;
}
_free_event(event);
}
/*
* Remove user event from the owner task.
*/
static void perf_remove_from_owner(struct perf_event *event)
{
struct task_struct *owner;
rcu_read_lock();
/*
* Matches the smp_store_release() in perf_event_exit_task(). If we
* observe !owner it means the list deletion is complete and we can
* indeed free this event, otherwise we need to serialize on
* owner->perf_event_mutex.
*/
owner = READ_ONCE(event->owner);
if (owner) {
/*
* Since delayed_put_task_struct() also drops the last
* task reference we can safely take a new reference
* while holding the rcu_read_lock().
*/
get_task_struct(owner);
}
rcu_read_unlock();
if (owner) {
/*
* If we're here through perf_event_exit_task() we're already
* holding ctx->mutex which would be an inversion wrt. the
* normal lock order.
*
* However we can safely take this lock because its the child
* ctx->mutex.
*/
mutex_lock_nested(&owner->perf_event_mutex, SINGLE_DEPTH_NESTING);
/*
* We have to re-check the event->owner field, if it is cleared
* we raced with perf_event_exit_task(), acquiring the mutex
* ensured they're done, and we can proceed with freeing the
* event.
*/
if (event->owner) {
list_del_init(&event->owner_entry);
smp_store_release(&event->owner, NULL);
}
mutex_unlock(&owner->perf_event_mutex);
put_task_struct(owner);
}
}
static void put_event(struct perf_event *event)
{
if (!atomic_long_dec_and_test(&event->refcount))
return;
_free_event(event);
}
/*
* Kill an event dead; while event:refcount will preserve the event
* object, it will not preserve its functionality. Once the last 'user'
* gives up the object, we'll destroy the thing.
*/
int perf_event_release_kernel(struct perf_event *event)
{
struct perf_event_context *ctx = event->ctx;
struct perf_event *child, *tmp;
LIST_HEAD(free_list);
/*
* If we got here through err_alloc: free_event(event); we will not
* have attached to a context yet.
*/
if (!ctx) {
WARN_ON_ONCE(event->attach_state &
(PERF_ATTACH_CONTEXT|PERF_ATTACH_GROUP));
goto no_ctx;
}
if (!is_kernel_event(event))
perf_remove_from_owner(event);
ctx = perf_event_ctx_lock(event);
WARN_ON_ONCE(ctx->parent_ctx);
/*
* Mark this event as STATE_DEAD, there is no external reference to it
* anymore.
*
* Anybody acquiring event->child_mutex after the below loop _must_
* also see this, most importantly inherit_event() which will avoid
* placing more children on the list.
*
* Thus this guarantees that we will in fact observe and kill _ALL_
* child events.
*/
perf_remove_from_context(event, DETACH_GROUP|DETACH_DEAD);
perf_event_ctx_unlock(event, ctx);
again:
mutex_lock(&event->child_mutex);
list_for_each_entry(child, &event->child_list, child_list) {
/*
* Cannot change, child events are not migrated, see the
* comment with perf_event_ctx_lock_nested().
*/
ctx = READ_ONCE(child->ctx);
/*
* Since child_mutex nests inside ctx::mutex, we must jump
* through hoops. We start by grabbing a reference on the ctx.
*
* Since the event cannot get freed while we hold the
* child_mutex, the context must also exist and have a !0
* reference count.
*/
get_ctx(ctx);
/*
* Now that we have a ctx ref, we can drop child_mutex, and
* acquire ctx::mutex without fear of it going away. Then we
* can re-acquire child_mutex.
*/
mutex_unlock(&event->child_mutex);
mutex_lock(&ctx->mutex);
mutex_lock(&event->child_mutex);
/*
* Now that we hold ctx::mutex and child_mutex, revalidate our
* state, if child is still the first entry, it didn't get freed
* and we can continue doing so.
*/
tmp = list_first_entry_or_null(&event->child_list,
struct perf_event, child_list);
if (tmp == child) {
perf_remove_from_context(child, DETACH_GROUP);
list_move(&child->child_list, &free_list);
/*
* This matches the refcount bump in inherit_event();
* this can't be the last reference.
*/
put_event(event);
}
mutex_unlock(&event->child_mutex);
mutex_unlock(&ctx->mutex);
put_ctx(ctx);
goto again;
}
mutex_unlock(&event->child_mutex);
list_for_each_entry_safe(child, tmp, &free_list, child_list) {
void *var = &child->ctx->refcount;
list_del(&child->child_list);
free_event(child);
/*
* Wake any perf_event_free_task() waiting for this event to be
* freed.
*/
smp_mb(); /* pairs with wait_var_event() */
wake_up_var(var);
}
no_ctx:
put_event(event); /* Must be the 'last' reference */
return 0;
}
EXPORT_SYMBOL_GPL(perf_event_release_kernel);
/*
* Called when the last reference to the file is gone.
*/
static int perf_release(struct inode *inode, struct file *file)
{
perf_event_release_kernel(file->private_data);
return 0;
}
static u64 __perf_event_read_value(struct perf_event *event, u64 *enabled, u64 *running)
{
struct perf_event *child;
u64 total = 0;
*enabled = 0;
*running = 0;
mutex_lock(&event->child_mutex);
(void)perf_event_read(event, false);
total += perf_event_count(event);
*enabled += event->total_time_enabled +
atomic64_read(&event->child_total_time_enabled);
*running += event->total_time_running +
atomic64_read(&event->child_total_time_running);
list_for_each_entry(child, &event->child_list, child_list) {
(void)perf_event_read(child, false);
total += perf_event_count(child);
*enabled += child->total_time_enabled;
*running += child->total_time_running;
}
mutex_unlock(&event->child_mutex);
return total;
}
u64 perf_event_read_value(struct perf_event *event, u64 *enabled, u64 *running)
{
struct perf_event_context *ctx;
u64 count;
ctx = perf_event_ctx_lock(event);
count = __perf_event_read_value(event, enabled, running);
perf_event_ctx_unlock(event, ctx);
return count;
}
EXPORT_SYMBOL_GPL(perf_event_read_value);
static int __perf_read_group_add(struct perf_event *leader,
u64 read_format, u64 *values)
{
struct perf_event_context *ctx = leader->ctx;
struct perf_event *sub, *parent;
unsigned long flags;
int n = 1; /* skip @nr */
int ret;
ret = perf_event_read(leader, true);
if (ret)
return ret;
raw_spin_lock_irqsave(&ctx->lock, flags);
/*
* Verify the grouping between the parent and child (inherited)
* events is still in tact.
*
* Specifically:
* - leader->ctx->lock pins leader->sibling_list
* - parent->child_mutex pins parent->child_list
* - parent->ctx->mutex pins parent->sibling_list
*
* Because parent->ctx != leader->ctx (and child_list nests inside
* ctx->mutex), group destruction is not atomic between children, also
* see perf_event_release_kernel(). Additionally, parent can grow the
* group.
*
* Therefore it is possible to have parent and child groups in a
* different configuration and summing over such a beast makes no sense
* what so ever.
*
* Reject this.
*/
parent = leader->parent;
if (parent &&
(parent->group_generation != leader->group_generation ||
parent->nr_siblings != leader->nr_siblings)) {
ret = -ECHILD;
goto unlock;
}
/*
* Since we co-schedule groups, {enabled,running} times of siblings
* will be identical to those of the leader, so we only publish one
* set.
*/
if (read_format & PERF_FORMAT_TOTAL_TIME_ENABLED) {
values[n++] += leader->total_time_enabled +
atomic64_read(&leader->child_total_time_enabled);
}
if (read_format & PERF_FORMAT_TOTAL_TIME_RUNNING) {
values[n++] += leader->total_time_running +
atomic64_read(&leader->child_total_time_running);
}
/*
* Write {count,id} tuples for every sibling.
*/
values[n++] += perf_event_count(leader);
if (read_format & PERF_FORMAT_ID)
values[n++] = primary_event_id(leader);
if (read_format & PERF_FORMAT_LOST)
values[n++] = atomic64_read(&leader->lost_samples);
for_each_sibling_event(sub, leader) {
values[n++] += perf_event_count(sub);
if (read_format & PERF_FORMAT_ID)
values[n++] = primary_event_id(sub);
if (read_format & PERF_FORMAT_LOST)
values[n++] = atomic64_read(&sub->lost_samples);
}
unlock:
raw_spin_unlock_irqrestore(&ctx->lock, flags);
return ret;
}
static int perf_read_group(struct perf_event *event,
u64 read_format, char __user *buf)
{
struct perf_event *leader = event->group_leader, *child;
struct perf_event_context *ctx = leader->ctx;
int ret;
u64 *values;
lockdep_assert_held(&ctx->mutex);
values = kzalloc(event->read_size, GFP_KERNEL);
if (!values)
return -ENOMEM;
values[0] = 1 + leader->nr_siblings;
mutex_lock(&leader->child_mutex);
ret = __perf_read_group_add(leader, read_format, values);
if (ret)
goto unlock;
list_for_each_entry(child, &leader->child_list, child_list) {
ret = __perf_read_group_add(child, read_format, values);
if (ret)
goto unlock;
}
mutex_unlock(&leader->child_mutex);
ret = event->read_size;
if (copy_to_user(buf, values, event->read_size))
ret = -EFAULT;
goto out;
unlock:
mutex_unlock(&leader->child_mutex);
out:
kfree(values);
return ret;
}
static int perf_read_one(struct perf_event *event,
u64 read_format, char __user *buf)
{
u64 enabled, running;
u64 values[5];
int n = 0;
values[n++] = __perf_event_read_value(event, &enabled, &running);
if (read_format & PERF_FORMAT_TOTAL_TIME_ENABLED)
values[n++] = enabled;
if (read_format & PERF_FORMAT_TOTAL_TIME_RUNNING)
values[n++] = running;
if (read_format & PERF_FORMAT_ID)
values[n++] = primary_event_id(event);
if (read_format & PERF_FORMAT_LOST)
values[n++] = atomic64_read(&event->lost_samples);
if (copy_to_user(buf, values, n * sizeof(u64)))
return -EFAULT;
return n * sizeof(u64);
}
static bool is_event_hup(struct perf_event *event)
{
bool no_children;
if (event->state > PERF_EVENT_STATE_EXIT)
return false;
mutex_lock(&event->child_mutex);
no_children = list_empty(&event->child_list);
mutex_unlock(&event->child_mutex);
return no_children;
}
/*
* Read the performance event - simple non blocking version for now
*/
static ssize_t
__perf_read(struct perf_event *event, char __user *buf, size_t count)
{
u64 read_format = event->attr.read_format;
int ret;
/*
* Return end-of-file for a read on an event that is in
* error state (i.e. because it was pinned but it couldn't be
* scheduled on to the CPU at some point).
*/
if (event->state == PERF_EVENT_STATE_ERROR)
return 0;
if (count < event->read_size)
return -ENOSPC;
WARN_ON_ONCE(event->ctx->parent_ctx);
if (read_format & PERF_FORMAT_GROUP)
ret = perf_read_group(event, read_format, buf);
else
ret = perf_read_one(event, read_format, buf);
return ret;
}
static ssize_t
perf_read(struct file *file, char __user *buf, size_t count, loff_t *ppos)
{
struct perf_event *event = file->private_data;
struct perf_event_context *ctx;
int ret;
ret = security_perf_event_read(event);
if (ret)
return ret;
ctx = perf_event_ctx_lock(event);
ret = __perf_read(event, buf, count);
perf_event_ctx_unlock(event, ctx);
return ret;
}
static __poll_t perf_poll(struct file *file, poll_table *wait)
{
struct perf_event *event = file->private_data;
struct perf_buffer *rb;
__poll_t events = EPOLLHUP;
poll_wait(file, &event->waitq, wait);
if (is_event_hup(event))
return events;
/*
* Pin the event->rb by taking event->mmap_mutex; otherwise
* perf_event_set_output() can swizzle our rb and make us miss wakeups.
*/
mutex_lock(&event->mmap_mutex);
rb = event->rb;
if (rb)
events = atomic_xchg(&rb->poll, 0);
mutex_unlock(&event->mmap_mutex);
return events;
}
static void _perf_event_reset(struct perf_event *event)
{
(void)perf_event_read(event, false);
local64_set(&event->count, 0);
perf_event_update_userpage(event);
}
/* Assume it's not an event with inherit set. */
u64 perf_event_pause(struct perf_event *event, bool reset)
{
struct perf_event_context *ctx;
u64 count;
ctx = perf_event_ctx_lock(event);
WARN_ON_ONCE(event->attr.inherit);
_perf_event_disable(event);
count = local64_read(&event->count);
if (reset)
local64_set(&event->count, 0);
perf_event_ctx_unlock(event, ctx);
return count;
}
EXPORT_SYMBOL_GPL(perf_event_pause);
/*
* Holding the top-level event's child_mutex means that any
* descendant process that has inherited this event will block
* in perf_event_exit_event() if it goes to exit, thus satisfying the
* task existence requirements of perf_event_enable/disable.
*/
static void perf_event_for_each_child(struct perf_event *event,
void (*func)(struct perf_event *))
{
struct perf_event *child;
WARN_ON_ONCE(event->ctx->parent_ctx);
mutex_lock(&event->child_mutex);
func(event);
list_for_each_entry(child, &event->child_list, child_list)
func(child);
mutex_unlock(&event->child_mutex);
}
static void perf_event_for_each(struct perf_event *event,
void (*func)(struct perf_event *))
{
struct perf_event_context *ctx = event->ctx;
struct perf_event *sibling;
lockdep_assert_held(&ctx->mutex);
event = event->group_leader;
perf_event_for_each_child(event, func);
for_each_sibling_event(sibling, event)
perf_event_for_each_child(sibling, func);
}
static void __perf_event_period(struct perf_event *event,
struct perf_cpu_context *cpuctx,
struct perf_event_context *ctx,
void *info)
{
u64 value = *((u64 *)info);
bool active;
if (event->attr.freq) {
event->attr.sample_freq = value;
} else {
event->attr.sample_period = value;
event->hw.sample_period = value;
}
active = (event->state == PERF_EVENT_STATE_ACTIVE);
if (active) {
perf_pmu_disable(event->pmu);
/*
* We could be throttled; unthrottle now to avoid the tick
* trying to unthrottle while we already re-started the event.
*/
if (event->hw.interrupts == MAX_INTERRUPTS) {
event->hw.interrupts = 0;
perf_log_throttle(event, 1);
}
event->pmu->stop(event, PERF_EF_UPDATE);
}
local64_set(&event->hw.period_left, 0);
if (active) {
event->pmu->start(event, PERF_EF_RELOAD);
perf_pmu_enable(event->pmu);
}
}
static int perf_event_check_period(struct perf_event *event, u64 value)
{
return event->pmu->check_period(event, value);
}
static int _perf_event_period(struct perf_event *event, u64 value)
{
if (!is_sampling_event(event))
return -EINVAL;
if (!value)
return -EINVAL;
if (event->attr.freq && value > sysctl_perf_event_sample_rate)
return -EINVAL;
if (perf_event_check_period(event, value))
return -EINVAL;
if (!event->attr.freq && (value & (1ULL << 63)))
return -EINVAL;
event_function_call(event, __perf_event_period, &value);
return 0;
}
int perf_event_period(struct perf_event *event, u64 value)
{
struct perf_event_context *ctx;
int ret;
ctx = perf_event_ctx_lock(event);
ret = _perf_event_period(event, value);
perf_event_ctx_unlock(event, ctx);
return ret;
}
EXPORT_SYMBOL_GPL(perf_event_period);
static const struct file_operations perf_fops;
static inline int perf_fget_light(int fd, struct fd *p)
{
struct fd f = fdget(fd);
if (!f.file)
return -EBADF;
if (f.file->f_op != &perf_fops) {
fdput(f);
return -EBADF;
}
*p = f;
return 0;
}
static int perf_event_set_output(struct perf_event *event,
struct perf_event *output_event);
static int perf_event_set_filter(struct perf_event *event, void __user *arg);
static int perf_copy_attr(struct perf_event_attr __user *uattr,
struct perf_event_attr *attr);
static long _perf_ioctl(struct perf_event *event, unsigned int cmd, unsigned long arg)
{
void (*func)(struct perf_event *);
u32 flags = arg;
switch (cmd) {
case PERF_EVENT_IOC_ENABLE:
func = _perf_event_enable;
break;
case PERF_EVENT_IOC_DISABLE:
func = _perf_event_disable;
break;
case PERF_EVENT_IOC_RESET:
func = _perf_event_reset;
break;
case PERF_EVENT_IOC_REFRESH:
return _perf_event_refresh(event, arg);
case PERF_EVENT_IOC_PERIOD:
{
u64 value;
if (copy_from_user(&value, (u64 __user *)arg, sizeof(value)))
return -EFAULT;
return _perf_event_period(event, value);
}
case PERF_EVENT_IOC_ID:
{
u64 id = primary_event_id(event);
if (copy_to_user((void __user *)arg, &id, sizeof(id)))
return -EFAULT;
return 0;
}
case PERF_EVENT_IOC_SET_OUTPUT:
{
int ret;
if (arg != -1) {
struct perf_event *output_event;
struct fd output;
ret = perf_fget_light(arg, &output);
if (ret)
return ret;
output_event = output.file->private_data;
ret = perf_event_set_output(event, output_event);
fdput(output);
} else {
ret = perf_event_set_output(event, NULL);
}
return ret;
}
case PERF_EVENT_IOC_SET_FILTER:
return perf_event_set_filter(event, (void __user *)arg);
case PERF_EVENT_IOC_SET_BPF:
{
struct bpf_prog *prog;
int err;
prog = bpf_prog_get(arg);
if (IS_ERR(prog))
return PTR_ERR(prog);
err = perf_event_set_bpf_prog(event, prog, 0);
if (err) {
bpf_prog_put(prog);
return err;
}
return 0;
}
case PERF_EVENT_IOC_PAUSE_OUTPUT: {
struct perf_buffer *rb;
rcu_read_lock();
rb = rcu_dereference(event->rb);
if (!rb || !rb->nr_pages) {
rcu_read_unlock();
return -EINVAL;
}
rb_toggle_paused(rb, !!arg);
rcu_read_unlock();
return 0;
}
case PERF_EVENT_IOC_QUERY_BPF:
return perf_event_query_prog_array(event, (void __user *)arg);
case PERF_EVENT_IOC_MODIFY_ATTRIBUTES: {
struct perf_event_attr new_attr;
int err = perf_copy_attr((struct perf_event_attr __user *)arg,
&new_attr);
if (err)
return err;
return perf_event_modify_attr(event, &new_attr);
}
default:
return -ENOTTY;
}
if (flags & PERF_IOC_FLAG_GROUP)
perf_event_for_each(event, func);
else
perf_event_for_each_child(event, func);
return 0;
}
static long perf_ioctl(struct file *file, unsigned int cmd, unsigned long arg)
{
struct perf_event *event = file->private_data;
struct perf_event_context *ctx;
long ret;
/* Treat ioctl like writes as it is likely a mutating operation. */
ret = security_perf_event_write(event);
if (ret)
return ret;
ctx = perf_event_ctx_lock(event);
ret = _perf_ioctl(event, cmd, arg);
perf_event_ctx_unlock(event, ctx);
return ret;
}
#ifdef CONFIG_COMPAT
static long perf_compat_ioctl(struct file *file, unsigned int cmd,
unsigned long arg)
{
switch (_IOC_NR(cmd)) {
case _IOC_NR(PERF_EVENT_IOC_SET_FILTER):
case _IOC_NR(PERF_EVENT_IOC_ID):
case _IOC_NR(PERF_EVENT_IOC_QUERY_BPF):
case _IOC_NR(PERF_EVENT_IOC_MODIFY_ATTRIBUTES):
/* Fix up pointer size (usually 4 -> 8 in 32-on-64-bit case */
if (_IOC_SIZE(cmd) == sizeof(compat_uptr_t)) {
cmd &= ~IOCSIZE_MASK;
cmd |= sizeof(void *) << IOCSIZE_SHIFT;
}
break;
}
return perf_ioctl(file, cmd, arg);
}
#else
# define perf_compat_ioctl NULL
#endif
int perf_event_task_enable(void)
{
struct perf_event_context *ctx;
struct perf_event *event;
mutex_lock(&current->perf_event_mutex);
list_for_each_entry(event, &current->perf_event_list, owner_entry) {
ctx = perf_event_ctx_lock(event);
perf_event_for_each_child(event, _perf_event_enable);
perf_event_ctx_unlock(event, ctx);
}
mutex_unlock(&current->perf_event_mutex);
return 0;
}
int perf_event_task_disable(void)
{
struct perf_event_context *ctx;
struct perf_event *event;
mutex_lock(&current->perf_event_mutex);
list_for_each_entry(event, &current->perf_event_list, owner_entry) {
ctx = perf_event_ctx_lock(event);
perf_event_for_each_child(event, _perf_event_disable);
perf_event_ctx_unlock(event, ctx);
}
mutex_unlock(&current->perf_event_mutex);
return 0;
}
static int perf_event_index(struct perf_event *event)
{
if (event->hw.state & PERF_HES_STOPPED)
return 0;
if (event->state != PERF_EVENT_STATE_ACTIVE)
return 0;
return event->pmu->event_idx(event);
}
static void perf_event_init_userpage(struct perf_event *event)
{
struct perf_event_mmap_page *userpg;
struct perf_buffer *rb;
rcu_read_lock();
rb = rcu_dereference(event->rb);
if (!rb)
goto unlock;
userpg = rb->user_page;
/* Allow new userspace to detect that bit 0 is deprecated */
userpg->cap_bit0_is_deprecated = 1;
userpg->size = offsetof(struct perf_event_mmap_page, __reserved);
userpg->data_offset = PAGE_SIZE;
userpg->data_size = perf_data_size(rb);
unlock:
rcu_read_unlock();
}
void __weak arch_perf_update_userpage(
struct perf_event *event, struct perf_event_mmap_page *userpg, u64 now)
{
}
/*
* Callers need to ensure there can be no nesting of this function, otherwise
* the seqlock logic goes bad. We can not serialize this because the arch
* code calls this from NMI context.
*/
void perf_event_update_userpage(struct perf_event *event)
{
struct perf_event_mmap_page *userpg;
struct perf_buffer *rb;
u64 enabled, running, now;
rcu_read_lock();
rb = rcu_dereference(event->rb);
if (!rb)
goto unlock;
/*
* compute total_time_enabled, total_time_running
* based on snapshot values taken when the event
* was last scheduled in.
*
* we cannot simply called update_context_time()
* because of locking issue as we can be called in
* NMI context
*/
calc_timer_values(event, &now, &enabled, &running);
userpg = rb->user_page;
/*
* Disable preemption to guarantee consistent time stamps are stored to
* the user page.
*/
preempt_disable();
++userpg->lock;
barrier();
userpg->index = perf_event_index(event);
userpg->offset = perf_event_count(event);
if (userpg->index)
userpg->offset -= local64_read(&event->hw.prev_count);
userpg->time_enabled = enabled +
atomic64_read(&event->child_total_time_enabled);
userpg->time_running = running +
atomic64_read(&event->child_total_time_running);
arch_perf_update_userpage(event, userpg, now);
barrier();
++userpg->lock;
preempt_enable();
unlock:
rcu_read_unlock();
}
EXPORT_SYMBOL_GPL(perf_event_update_userpage);
static vm_fault_t perf_mmap_fault(struct vm_fault *vmf)
{
struct perf_event *event = vmf->vma->vm_file->private_data;
struct perf_buffer *rb;
vm_fault_t ret = VM_FAULT_SIGBUS;
if (vmf->flags & FAULT_FLAG_MKWRITE) {
if (vmf->pgoff == 0)
ret = 0;
return ret;
}
rcu_read_lock();
rb = rcu_dereference(event->rb);
if (!rb)
goto unlock;
if (vmf->pgoff && (vmf->flags & FAULT_FLAG_WRITE))
goto unlock;
vmf->page = perf_mmap_to_page(rb, vmf->pgoff);
if (!vmf->page)
goto unlock;
get_page(vmf->page);
vmf->page->mapping = vmf->vma->vm_file->f_mapping;
vmf->page->index = vmf->pgoff;
ret = 0;
unlock:
rcu_read_unlock();
return ret;
}
static void ring_buffer_attach(struct perf_event *event,
struct perf_buffer *rb)
{
struct perf_buffer *old_rb = NULL;
unsigned long flags;
WARN_ON_ONCE(event->parent);
if (event->rb) {
/*
* Should be impossible, we set this when removing
* event->rb_entry and wait/clear when adding event->rb_entry.
*/
WARN_ON_ONCE(event->rcu_pending);
old_rb = event->rb;
spin_lock_irqsave(&old_rb->event_lock, flags);
list_del_rcu(&event->rb_entry);
spin_unlock_irqrestore(&old_rb->event_lock, flags);
event->rcu_batches = get_state_synchronize_rcu();
event->rcu_pending = 1;
}
if (rb) {
if (event->rcu_pending) {
cond_synchronize_rcu(event->rcu_batches);
event->rcu_pending = 0;
}
spin_lock_irqsave(&rb->event_lock, flags);
list_add_rcu(&event->rb_entry, &rb->event_list);
spin_unlock_irqrestore(&rb->event_lock, flags);
}
/*
* Avoid racing with perf_mmap_close(AUX): stop the event
* before swizzling the event::rb pointer; if it's getting
* unmapped, its aux_mmap_count will be 0 and it won't
* restart. See the comment in __perf_pmu_output_stop().
*
* Data will inevitably be lost when set_output is done in
* mid-air, but then again, whoever does it like this is
* not in for the data anyway.
*/
if (has_aux(event))
perf_event_stop(event, 0);
rcu_assign_pointer(event->rb, rb);
if (old_rb) {
ring_buffer_put(old_rb);
/*
* Since we detached before setting the new rb, so that we
* could attach the new rb, we could have missed a wakeup.
* Provide it now.
*/
wake_up_all(&event->waitq);
}
}
static void ring_buffer_wakeup(struct perf_event *event)
{
struct perf_buffer *rb;
if (event->parent)
event = event->parent;
rcu_read_lock();
rb = rcu_dereference(event->rb);
if (rb) {
list_for_each_entry_rcu(event, &rb->event_list, rb_entry)
wake_up_all(&event->waitq);
}
rcu_read_unlock();
}
struct perf_buffer *ring_buffer_get(struct perf_event *event)
{
struct perf_buffer *rb;
if (event->parent)
event = event->parent;
rcu_read_lock();
rb = rcu_dereference(event->rb);
if (rb) {
if (!refcount_inc_not_zero(&rb->refcount))
rb = NULL;
}
rcu_read_unlock();
return rb;
}
void ring_buffer_put(struct perf_buffer *rb)
{
if (!refcount_dec_and_test(&rb->refcount))
return;
WARN_ON_ONCE(!list_empty(&rb->event_list));
call_rcu(&rb->rcu_head, rb_free_rcu);
}
static void perf_mmap_open(struct vm_area_struct *vma)
{
struct perf_event *event = vma->vm_file->private_data;
atomic_inc(&event->mmap_count);
atomic_inc(&event->rb->mmap_count);
if (vma->vm_pgoff)
atomic_inc(&event->rb->aux_mmap_count);
if (event->pmu->event_mapped)
event->pmu->event_mapped(event, vma->vm_mm);
}
static void perf_pmu_output_stop(struct perf_event *event);
/*
* A buffer can be mmap()ed multiple times; either directly through the same
* event, or through other events by use of perf_event_set_output().
*
* In order to undo the VM accounting done by perf_mmap() we need to destroy
* the buffer here, where we still have a VM context. This means we need
* to detach all events redirecting to us.
*/
static void perf_mmap_close(struct vm_area_struct *vma)
{
struct perf_event *event = vma->vm_file->private_data;
struct perf_buffer *rb = ring_buffer_get(event);
struct user_struct *mmap_user = rb->mmap_user;
int mmap_locked = rb->mmap_locked;
unsigned long size = perf_data_size(rb);
bool detach_rest = false;
if (event->pmu->event_unmapped)
event->pmu->event_unmapped(event, vma->vm_mm);
/*
* rb->aux_mmap_count will always drop before rb->mmap_count and
* event->mmap_count, so it is ok to use event->mmap_mutex to
* serialize with perf_mmap here.
*/
if (rb_has_aux(rb) && vma->vm_pgoff == rb->aux_pgoff &&
atomic_dec_and_mutex_lock(&rb->aux_mmap_count, &event->mmap_mutex)) {
/*
* Stop all AUX events that are writing to this buffer,
* so that we can free its AUX pages and corresponding PMU
* data. Note that after rb::aux_mmap_count dropped to zero,
* they won't start any more (see perf_aux_output_begin()).
*/
perf_pmu_output_stop(event);
/* now it's safe to free the pages */
atomic_long_sub(rb->aux_nr_pages - rb->aux_mmap_locked, &mmap_user->locked_vm);
atomic64_sub(rb->aux_mmap_locked, &vma->vm_mm->pinned_vm);
/* this has to be the last one */
rb_free_aux(rb);
WARN_ON_ONCE(refcount_read(&rb->aux_refcount));
mutex_unlock(&event->mmap_mutex);
}
if (atomic_dec_and_test(&rb->mmap_count))
detach_rest = true;
if (!atomic_dec_and_mutex_lock(&event->mmap_count, &event->mmap_mutex))
goto out_put;
ring_buffer_attach(event, NULL);
mutex_unlock(&event->mmap_mutex);
/* If there's still other mmap()s of this buffer, we're done. */
if (!detach_rest)
goto out_put;
/*
* No other mmap()s, detach from all other events that might redirect
* into the now unreachable buffer. Somewhat complicated by the
* fact that rb::event_lock otherwise nests inside mmap_mutex.
*/
again:
rcu_read_lock();
list_for_each_entry_rcu(event, &rb->event_list, rb_entry) {
if (!atomic_long_inc_not_zero(&event->refcount)) {
/*
* This event is en-route to free_event() which will
* detach it and remove it from the list.
*/
continue;
}
rcu_read_unlock();
mutex_lock(&event->mmap_mutex);
/*
* Check we didn't race with perf_event_set_output() which can
* swizzle the rb from under us while we were waiting to
* acquire mmap_mutex.
*
* If we find a different rb; ignore this event, a next
* iteration will no longer find it on the list. We have to
* still restart the iteration to make sure we're not now
* iterating the wrong list.
*/
if (event->rb == rb)
ring_buffer_attach(event, NULL);
mutex_unlock(&event->mmap_mutex);
put_event(event);
/*
* Restart the iteration; either we're on the wrong list or
* destroyed its integrity by doing a deletion.
*/
goto again;
}
rcu_read_unlock();
/*
* It could be there's still a few 0-ref events on the list; they'll
* get cleaned up by free_event() -- they'll also still have their
* ref on the rb and will free it whenever they are done with it.
*
* Aside from that, this buffer is 'fully' detached and unmapped,
* undo the VM accounting.
*/
atomic_long_sub((size >> PAGE_SHIFT) + 1 - mmap_locked,
&mmap_user->locked_vm);
atomic64_sub(mmap_locked, &vma->vm_mm->pinned_vm);
free_uid(mmap_user);
out_put:
ring_buffer_put(rb); /* could be last */
}
static const struct vm_operations_struct perf_mmap_vmops = {
.open = perf_mmap_open,
.close = perf_mmap_close, /* non mergeable */
.fault = perf_mmap_fault,
.page_mkwrite = perf_mmap_fault,
};
static int perf_mmap(struct file *file, struct vm_area_struct *vma)
{
struct perf_event *event = file->private_data;
unsigned long user_locked, user_lock_limit;
struct user_struct *user = current_user();
struct perf_buffer *rb = NULL;
unsigned long locked, lock_limit;
unsigned long vma_size;
unsigned long nr_pages;
long user_extra = 0, extra = 0;
int ret = 0, flags = 0;
/*
* Don't allow mmap() of inherited per-task counters. This would
* create a performance issue due to all children writing to the
* same rb.
*/
if (event->cpu == -1 && event->attr.inherit)
return -EINVAL;
if (!(vma->vm_flags & VM_SHARED))
return -EINVAL;
ret = security_perf_event_read(event);
if (ret)
return ret;
vma_size = vma->vm_end - vma->vm_start;
if (vma->vm_pgoff == 0) {
nr_pages = (vma_size / PAGE_SIZE) - 1;
} else {
/*
* AUX area mapping: if rb->aux_nr_pages != 0, it's already
* mapped, all subsequent mappings should have the same size
* and offset. Must be above the normal perf buffer.
*/
u64 aux_offset, aux_size;
if (!event->rb)
return -EINVAL;
nr_pages = vma_size / PAGE_SIZE;
mutex_lock(&event->mmap_mutex);
ret = -EINVAL;
rb = event->rb;
if (!rb)
goto aux_unlock;
aux_offset = READ_ONCE(rb->user_page->aux_offset);
aux_size = READ_ONCE(rb->user_page->aux_size);
if (aux_offset < perf_data_size(rb) + PAGE_SIZE)
goto aux_unlock;
if (aux_offset != vma->vm_pgoff << PAGE_SHIFT)
goto aux_unlock;
/* already mapped with a different offset */
if (rb_has_aux(rb) && rb->aux_pgoff != vma->vm_pgoff)
goto aux_unlock;
if (aux_size != vma_size || aux_size != nr_pages * PAGE_SIZE)
goto aux_unlock;
/* already mapped with a different size */
if (rb_has_aux(rb) && rb->aux_nr_pages != nr_pages)
goto aux_unlock;
if (!is_power_of_2(nr_pages))
goto aux_unlock;
if (!atomic_inc_not_zero(&rb->mmap_count))
goto aux_unlock;
if (rb_has_aux(rb)) {
atomic_inc(&rb->aux_mmap_count);
ret = 0;
goto unlock;
}
atomic_set(&rb->aux_mmap_count, 1);
user_extra = nr_pages;
goto accounting;
}
/*
* If we have rb pages ensure they're a power-of-two number, so we
* can do bitmasks instead of modulo.
*/
if (nr_pages != 0 && !is_power_of_2(nr_pages))
return -EINVAL;
if (vma_size != PAGE_SIZE * (1 + nr_pages))
return -EINVAL;
WARN_ON_ONCE(event->ctx->parent_ctx);
again:
mutex_lock(&event->mmap_mutex);
if (event->rb) {
if (data_page_nr(event->rb) != nr_pages) {
ret = -EINVAL;
goto unlock;
}
if (!atomic_inc_not_zero(&event->rb->mmap_count)) {
/*
* Raced against perf_mmap_close(); remove the
* event and try again.
*/
ring_buffer_attach(event, NULL);
mutex_unlock(&event->mmap_mutex);
goto again;
}
goto unlock;
}
user_extra = nr_pages + 1;
accounting:
user_lock_limit = sysctl_perf_event_mlock >> (PAGE_SHIFT - 10);
/*
* Increase the limit linearly with more CPUs:
*/
user_lock_limit *= num_online_cpus();
user_locked = atomic_long_read(&user->locked_vm);
/*
* sysctl_perf_event_mlock may have changed, so that
* user->locked_vm > user_lock_limit
*/
if (user_locked > user_lock_limit)
user_locked = user_lock_limit;
user_locked += user_extra;
if (user_locked > user_lock_limit) {
/*
* charge locked_vm until it hits user_lock_limit;
* charge the rest from pinned_vm
*/
extra = user_locked - user_lock_limit;
user_extra -= extra;
}
lock_limit = rlimit(RLIMIT_MEMLOCK);
lock_limit >>= PAGE_SHIFT;
locked = atomic64_read(&vma->vm_mm->pinned_vm) + extra;
if ((locked > lock_limit) && perf_is_paranoid() &&
!capable(CAP_IPC_LOCK)) {
ret = -EPERM;
goto unlock;
}
WARN_ON(!rb && event->rb);
if (vma->vm_flags & VM_WRITE)
flags |= RING_BUFFER_WRITABLE;
if (!rb) {
rb = rb_alloc(nr_pages,
event->attr.watermark ? event->attr.wakeup_watermark : 0,
event->cpu, flags);
if (!rb) {
ret = -ENOMEM;
goto unlock;
}
atomic_set(&rb->mmap_count, 1);
rb->mmap_user = get_current_user();
rb->mmap_locked = extra;
ring_buffer_attach(event, rb);
perf_event_update_time(event);
perf_event_init_userpage(event);
perf_event_update_userpage(event);
} else {
ret = rb_alloc_aux(rb, event, vma->vm_pgoff, nr_pages,
event->attr.aux_watermark, flags);
if (!ret)
rb->aux_mmap_locked = extra;
}
unlock:
if (!ret) {
atomic_long_add(user_extra, &user->locked_vm);
atomic64_add(extra, &vma->vm_mm->pinned_vm);
atomic_inc(&event->mmap_count);
} else if (rb) {
atomic_dec(&rb->mmap_count);
}
aux_unlock:
mutex_unlock(&event->mmap_mutex);
/*
* Since pinned accounting is per vm we cannot allow fork() to copy our
* vma.
*/
vm_flags_set(vma, VM_DONTCOPY | VM_DONTEXPAND | VM_DONTDUMP);
vma->vm_ops = &perf_mmap_vmops;
if (event->pmu->event_mapped)
event->pmu->event_mapped(event, vma->vm_mm);
return ret;
}
static int perf_fasync(int fd, struct file *filp, int on)
{
struct inode *inode = file_inode(filp);
struct perf_event *event = filp->private_data;
int retval;
inode_lock(inode);
retval = fasync_helper(fd, filp, on, &event->fasync);
inode_unlock(inode);
if (retval < 0)
return retval;
return 0;
}
static const struct file_operations perf_fops = {
.llseek = no_llseek,
.release = perf_release,
.read = perf_read,
.poll = perf_poll,
.unlocked_ioctl = perf_ioctl,
.compat_ioctl = perf_compat_ioctl,
.mmap = perf_mmap,
.fasync = perf_fasync,
};
/*
* Perf event wakeup
*
* If there's data, ensure we set the poll() state and publish everything
* to user-space before waking everybody up.
*/
static inline struct fasync_struct **perf_event_fasync(struct perf_event *event)
{
/* only the parent has fasync state */
if (event->parent)
event = event->parent;
return &event->fasync;
}
void perf_event_wakeup(struct perf_event *event)
{
ring_buffer_wakeup(event);
if (event->pending_kill) {
kill_fasync(perf_event_fasync(event), SIGIO, event->pending_kill);
event->pending_kill = 0;
}
}
static void perf_sigtrap(struct perf_event *event)
{
/*
* We'd expect this to only occur if the irq_work is delayed and either
* ctx->task or current has changed in the meantime. This can be the
* case on architectures that do not implement arch_irq_work_raise().
*/
if (WARN_ON_ONCE(event->ctx->task != current))
return;
/*
* Both perf_pending_task() and perf_pending_irq() can race with the
* task exiting.
*/
if (current->flags & PF_EXITING)
return;
send_sig_perf((void __user *)event->pending_addr,
event->orig_type, event->attr.sig_data);
}
/*
* Deliver the pending work in-event-context or follow the context.
*/
static void __perf_pending_irq(struct perf_event *event)
{
int cpu = READ_ONCE(event->oncpu);
/*
* If the event isn't running; we done. event_sched_out() will have
* taken care of things.
*/
if (cpu < 0)
return;
/*
* Yay, we hit home and are in the context of the event.
*/
if (cpu == smp_processor_id()) {
if (event->pending_sigtrap) {
event->pending_sigtrap = 0;
perf_sigtrap(event);
local_dec(&event->ctx->nr_pending);
}
if (event->pending_disable) {
event->pending_disable = 0;
perf_event_disable_local(event);
}
return;
}
/*
* CPU-A CPU-B
*
* perf_event_disable_inatomic()
* @pending_disable = CPU-A;
* irq_work_queue();
*
* sched-out
* @pending_disable = -1;
*
* sched-in
* perf_event_disable_inatomic()
* @pending_disable = CPU-B;
* irq_work_queue(); // FAILS
*
* irq_work_run()
* perf_pending_irq()
*
* But the event runs on CPU-B and wants disabling there.
*/
irq_work_queue_on(&event->pending_irq, cpu);
}
static void perf_pending_irq(struct irq_work *entry)
{
struct perf_event *event = container_of(entry, struct perf_event, pending_irq);
int rctx;
/*
* If we 'fail' here, that's OK, it means recursion is already disabled
* and we won't recurse 'further'.
*/
rctx = perf_swevent_get_recursion_context();
/*
* The wakeup isn't bound to the context of the event -- it can happen
* irrespective of where the event is.
*/
if (event->pending_wakeup) {
event->pending_wakeup = 0;
perf_event_wakeup(event);
}
__perf_pending_irq(event);
if (rctx >= 0)
perf_swevent_put_recursion_context(rctx);
}
static void perf_pending_task(struct callback_head *head)
{
struct perf_event *event = container_of(head, struct perf_event, pending_task);
int rctx;
/*
* If we 'fail' here, that's OK, it means recursion is already disabled
* and we won't recurse 'further'.
*/
preempt_disable_notrace();
rctx = perf_swevent_get_recursion_context();
if (event->pending_work) {
event->pending_work = 0;
perf_sigtrap(event);
local_dec(&event->ctx->nr_pending);
}
if (rctx >= 0)
perf_swevent_put_recursion_context(rctx);
preempt_enable_notrace();
put_event(event);
}
#ifdef CONFIG_GUEST_PERF_EVENTS
struct perf_guest_info_callbacks __rcu *perf_guest_cbs;
DEFINE_STATIC_CALL_RET0(__perf_guest_state, *perf_guest_cbs->state);
DEFINE_STATIC_CALL_RET0(__perf_guest_get_ip, *perf_guest_cbs->get_ip);
DEFINE_STATIC_CALL_RET0(__perf_guest_handle_intel_pt_intr, *perf_guest_cbs->handle_intel_pt_intr);
void perf_register_guest_info_callbacks(struct perf_guest_info_callbacks *cbs)
{
if (WARN_ON_ONCE(rcu_access_pointer(perf_guest_cbs)))
return;
rcu_assign_pointer(perf_guest_cbs, cbs);
static_call_update(__perf_guest_state, cbs->state);
static_call_update(__perf_guest_get_ip, cbs->get_ip);
/* Implementing ->handle_intel_pt_intr is optional. */
if (cbs->handle_intel_pt_intr)
static_call_update(__perf_guest_handle_intel_pt_intr,
cbs->handle_intel_pt_intr);
}
EXPORT_SYMBOL_GPL(perf_register_guest_info_callbacks);
void perf_unregister_guest_info_callbacks(struct perf_guest_info_callbacks *cbs)
{
if (WARN_ON_ONCE(rcu_access_pointer(perf_guest_cbs) != cbs))
return;
rcu_assign_pointer(perf_guest_cbs, NULL);
static_call_update(__perf_guest_state, (void *)&__static_call_return0);
static_call_update(__perf_guest_get_ip, (void *)&__static_call_return0);
static_call_update(__perf_guest_handle_intel_pt_intr,
(void *)&__static_call_return0);
synchronize_rcu();
}
EXPORT_SYMBOL_GPL(perf_unregister_guest_info_callbacks);
#endif
static void
perf_output_sample_regs(struct perf_output_handle *handle,
struct pt_regs *regs, u64 mask)
{
int bit;
DECLARE_BITMAP(_mask, 64);
bitmap_from_u64(_mask, mask);
for_each_set_bit(bit, _mask, sizeof(mask) * BITS_PER_BYTE) {
u64 val;
val = perf_reg_value(regs, bit);
perf_output_put(handle, val);
}
}
static void perf_sample_regs_user(struct perf_regs *regs_user,
struct pt_regs *regs)
{
if (user_mode(regs)) {
regs_user->abi = perf_reg_abi(current);
regs_user->regs = regs;
} else if (!(current->flags & PF_KTHREAD)) {
perf_get_regs_user(regs_user, regs);
} else {
regs_user->abi = PERF_SAMPLE_REGS_ABI_NONE;
regs_user->regs = NULL;
}
}
static void perf_sample_regs_intr(struct perf_regs *regs_intr,
struct pt_regs *regs)
{
regs_intr->regs = regs;
regs_intr->abi = perf_reg_abi(current);
}
/*
* Get remaining task size from user stack pointer.
*
* It'd be better to take stack vma map and limit this more
* precisely, but there's no way to get it safely under interrupt,
* so using TASK_SIZE as limit.
*/
static u64 perf_ustack_task_size(struct pt_regs *regs)
{
unsigned long addr = perf_user_stack_pointer(regs);
if (!addr || addr >= TASK_SIZE)
return 0;
return TASK_SIZE - addr;
}
static u16
perf_sample_ustack_size(u16 stack_size, u16 header_size,
struct pt_regs *regs)
{
u64 task_size;
/* No regs, no stack pointer, no dump. */
if (!regs)
return 0;
/*
* Check if we fit in with the requested stack size into the:
* - TASK_SIZE
* If we don't, we limit the size to the TASK_SIZE.
*
* - remaining sample size
* If we don't, we customize the stack size to
* fit in to the remaining sample size.
*/
task_size = min((u64) USHRT_MAX, perf_ustack_task_size(regs));
stack_size = min(stack_size, (u16) task_size);
/* Current header size plus static size and dynamic size. */
header_size += 2 * sizeof(u64);
/* Do we fit in with the current stack dump size? */
if ((u16) (header_size + stack_size) < header_size) {
/*
* If we overflow the maximum size for the sample,
* we customize the stack dump size to fit in.
*/
stack_size = USHRT_MAX - header_size - sizeof(u64);
stack_size = round_up(stack_size, sizeof(u64));
}
return stack_size;
}
static void
perf_output_sample_ustack(struct perf_output_handle *handle, u64 dump_size,
struct pt_regs *regs)
{
/* Case of a kernel thread, nothing to dump */
if (!regs) {
u64 size = 0;
perf_output_put(handle, size);
} else {
unsigned long sp;
unsigned int rem;
u64 dyn_size;
/*
* We dump:
* static size
* - the size requested by user or the best one we can fit
* in to the sample max size
* data
* - user stack dump data
* dynamic size
* - the actual dumped size
*/
/* Static size. */
perf_output_put(handle, dump_size);
/* Data. */
sp = perf_user_stack_pointer(regs);
rem = __output_copy_user(handle, (void *) sp, dump_size);
dyn_size = dump_size - rem;
perf_output_skip(handle, rem);
/* Dynamic size. */
perf_output_put(handle, dyn_size);
}
}
static unsigned long perf_prepare_sample_aux(struct perf_event *event,
struct perf_sample_data *data,
size_t size)
{
struct perf_event *sampler = event->aux_event;
struct perf_buffer *rb;
data->aux_size = 0;
if (!sampler)
goto out;
if (WARN_ON_ONCE(READ_ONCE(sampler->state) != PERF_EVENT_STATE_ACTIVE))
goto out;
if (WARN_ON_ONCE(READ_ONCE(sampler->oncpu) != smp_processor_id()))
goto out;
rb = ring_buffer_get(sampler);
if (!rb)
goto out;
/*
* If this is an NMI hit inside sampling code, don't take
* the sample. See also perf_aux_sample_output().
*/
if (READ_ONCE(rb->aux_in_sampling)) {
data->aux_size = 0;
} else {
size = min_t(size_t, size, perf_aux_size(rb));
data->aux_size = ALIGN(size, sizeof(u64));
}
ring_buffer_put(rb);
out:
return data->aux_size;
}
static long perf_pmu_snapshot_aux(struct perf_buffer *rb,
struct perf_event *event,
struct perf_output_handle *handle,
unsigned long size)
{
unsigned long flags;
long ret;
/*
* Normal ->start()/->stop() callbacks run in IRQ mode in scheduler
* paths. If we start calling them in NMI context, they may race with
* the IRQ ones, that is, for example, re-starting an event that's just
* been stopped, which is why we're using a separate callback that
* doesn't change the event state.
*
* IRQs need to be disabled to prevent IPIs from racing with us.
*/
local_irq_save(flags);
/*
* Guard against NMI hits inside the critical section;
* see also perf_prepare_sample_aux().
*/
WRITE_ONCE(rb->aux_in_sampling, 1);
barrier();
ret = event->pmu->snapshot_aux(event, handle, size);
barrier();
WRITE_ONCE(rb->aux_in_sampling, 0);
local_irq_restore(flags);
return ret;
}
static void perf_aux_sample_output(struct perf_event *event,
struct perf_output_handle *handle,
struct perf_sample_data *data)
{
struct perf_event *sampler = event->aux_event;
struct perf_buffer *rb;
unsigned long pad;
long size;
if (WARN_ON_ONCE(!sampler || !data->aux_size))
return;
rb = ring_buffer_get(sampler);
if (!rb)
return;
size = perf_pmu_snapshot_aux(rb, sampler, handle, data->aux_size);
/*
* An error here means that perf_output_copy() failed (returned a
* non-zero surplus that it didn't copy), which in its current
* enlightened implementation is not possible. If that changes, we'd
* like to know.
*/
if (WARN_ON_ONCE(size < 0))
goto out_put;
/*
* The pad comes from ALIGN()ing data->aux_size up to u64 in
* perf_prepare_sample_aux(), so should not be more than that.
*/
pad = data->aux_size - size;
if (WARN_ON_ONCE(pad >= sizeof(u64)))
pad = 8;
if (pad) {
u64 zero = 0;
perf_output_copy(handle, &zero, pad);
}
out_put:
ring_buffer_put(rb);
}
/*
* A set of common sample data types saved even for non-sample records
* when event->attr.sample_id_all is set.
*/
#define PERF_SAMPLE_ID_ALL (PERF_SAMPLE_TID | PERF_SAMPLE_TIME | \
PERF_SAMPLE_ID | PERF_SAMPLE_STREAM_ID | \
PERF_SAMPLE_CPU | PERF_SAMPLE_IDENTIFIER)
static void __perf_event_header__init_id(struct perf_sample_data *data,
struct perf_event *event,
u64 sample_type)
{
data->type = event->attr.sample_type;
data->sample_flags |= data->type & PERF_SAMPLE_ID_ALL;
if (sample_type & PERF_SAMPLE_TID) {
/* namespace issues */
data->tid_entry.pid = perf_event_pid(event, current);
data->tid_entry.tid = perf_event_tid(event, current);
}
if (sample_type & PERF_SAMPLE_TIME)
data->time = perf_event_clock(event);
if (sample_type & (PERF_SAMPLE_ID | PERF_SAMPLE_IDENTIFIER))
data->id = primary_event_id(event);
if (sample_type & PERF_SAMPLE_STREAM_ID)
data->stream_id = event->id;
if (sample_type & PERF_SAMPLE_CPU) {
data->cpu_entry.cpu = raw_smp_processor_id();
data->cpu_entry.reserved = 0;
}
}
void perf_event_header__init_id(struct perf_event_header *header,
struct perf_sample_data *data,
struct perf_event *event)
{
if (event->attr.sample_id_all) {
header->size += event->id_header_size;
__perf_event_header__init_id(data, event, event->attr.sample_type);
}
}
static void __perf_event__output_id_sample(struct perf_output_handle *handle,
struct perf_sample_data *data)
{
u64 sample_type = data->type;
if (sample_type & PERF_SAMPLE_TID)
perf_output_put(handle, data->tid_entry);
if (sample_type & PERF_SAMPLE_TIME)
perf_output_put(handle, data->time);
if (sample_type & PERF_SAMPLE_ID)
perf_output_put(handle, data->id);
if (sample_type & PERF_SAMPLE_STREAM_ID)
perf_output_put(handle, data->stream_id);
if (sample_type & PERF_SAMPLE_CPU)
perf_output_put(handle, data->cpu_entry);
if (sample_type & PERF_SAMPLE_IDENTIFIER)
perf_output_put(handle, data->id);
}
void perf_event__output_id_sample(struct perf_event *event,
struct perf_output_handle *handle,
struct perf_sample_data *sample)
{
if (event->attr.sample_id_all)
__perf_event__output_id_sample(handle, sample);
}
static void perf_output_read_one(struct perf_output_handle *handle,
struct perf_event *event,
u64 enabled, u64 running)
{
u64 read_format = event->attr.read_format;
u64 values[5];
int n = 0;
values[n++] = perf_event_count(event);
if (read_format & PERF_FORMAT_TOTAL_TIME_ENABLED) {
values[n++] = enabled +
atomic64_read(&event->child_total_time_enabled);
}
if (read_format & PERF_FORMAT_TOTAL_TIME_RUNNING) {
values[n++] = running +
atomic64_read(&event->child_total_time_running);
}
if (read_format & PERF_FORMAT_ID)
values[n++] = primary_event_id(event);
if (read_format & PERF_FORMAT_LOST)
values[n++] = atomic64_read(&event->lost_samples);
__output_copy(handle, values, n * sizeof(u64));
}
static void perf_output_read_group(struct perf_output_handle *handle,
struct perf_event *event,
u64 enabled, u64 running)
{
struct perf_event *leader = event->group_leader, *sub;
u64 read_format = event->attr.read_format;
unsigned long flags;
u64 values[6];
int n = 0;
/*
* Disabling interrupts avoids all counter scheduling
* (context switches, timer based rotation and IPIs).
*/
local_irq_save(flags);
values[n++] = 1 + leader->nr_siblings;
if (read_format & PERF_FORMAT_TOTAL_TIME_ENABLED)
values[n++] = enabled;
if (read_format & PERF_FORMAT_TOTAL_TIME_RUNNING)
values[n++] = running;
if ((leader != event) &&
(leader->state == PERF_EVENT_STATE_ACTIVE))
leader->pmu->read(leader);
values[n++] = perf_event_count(leader);
if (read_format & PERF_FORMAT_ID)
values[n++] = primary_event_id(leader);
if (read_format & PERF_FORMAT_LOST)
values[n++] = atomic64_read(&leader->lost_samples);
__output_copy(handle, values, n * sizeof(u64));
for_each_sibling_event(sub, leader) {
n = 0;
if ((sub != event) &&
(sub->state == PERF_EVENT_STATE_ACTIVE))
sub->pmu->read(sub);
values[n++] = perf_event_count(sub);
if (read_format & PERF_FORMAT_ID)
values[n++] = primary_event_id(sub);
if (read_format & PERF_FORMAT_LOST)
values[n++] = atomic64_read(&sub->lost_samples);
__output_copy(handle, values, n * sizeof(u64));
}
local_irq_restore(flags);
}
#define PERF_FORMAT_TOTAL_TIMES (PERF_FORMAT_TOTAL_TIME_ENABLED|\
PERF_FORMAT_TOTAL_TIME_RUNNING)
/*
* XXX PERF_SAMPLE_READ vs inherited events seems difficult.
*
* The problem is that its both hard and excessively expensive to iterate the
* child list, not to mention that its impossible to IPI the children running
* on another CPU, from interrupt/NMI context.
*/
static void perf_output_read(struct perf_output_handle *handle,
struct perf_event *event)
{
u64 enabled = 0, running = 0, now;
u64 read_format = event->attr.read_format;
/*
* compute total_time_enabled, total_time_running
* based on snapshot values taken when the event
* was last scheduled in.
*
* we cannot simply called update_context_time()
* because of locking issue as we are called in
* NMI context
*/
if (read_format & PERF_FORMAT_TOTAL_TIMES)
calc_timer_values(event, &now, &enabled, &running);
if (event->attr.read_format & PERF_FORMAT_GROUP)
perf_output_read_group(handle, event, enabled, running);
else
perf_output_read_one(handle, event, enabled, running);
}
void perf_output_sample(struct perf_output_handle *handle,
struct perf_event_header *header,
struct perf_sample_data *data,
struct perf_event *event)
{
u64 sample_type = data->type;
perf_output_put(handle, *header);
if (sample_type & PERF_SAMPLE_IDENTIFIER)
perf_output_put(handle, data->id);
if (sample_type & PERF_SAMPLE_IP)
perf_output_put(handle, data->ip);
if (sample_type & PERF_SAMPLE_TID)
perf_output_put(handle, data->tid_entry);
if (sample_type & PERF_SAMPLE_TIME)
perf_output_put(handle, data->time);
if (sample_type & PERF_SAMPLE_ADDR)
perf_output_put(handle, data->addr);
if (sample_type & PERF_SAMPLE_ID)
perf_output_put(handle, data->id);
if (sample_type & PERF_SAMPLE_STREAM_ID)
perf_output_put(handle, data->stream_id);
if (sample_type & PERF_SAMPLE_CPU)
perf_output_put(handle, data->cpu_entry);
if (sample_type & PERF_SAMPLE_PERIOD)
perf_output_put(handle, data->period);
if (sample_type & PERF_SAMPLE_READ)
perf_output_read(handle, event);
if (sample_type & PERF_SAMPLE_CALLCHAIN) {
int size = 1;
size += data->callchain->nr;
size *= sizeof(u64);
__output_copy(handle, data->callchain, size);
}
if (sample_type & PERF_SAMPLE_RAW) {
struct perf_raw_record *raw = data->raw;
if (raw) {
struct perf_raw_frag *frag = &raw->frag;
perf_output_put(handle, raw->size);
do {
if (frag->copy) {
__output_custom(handle, frag->copy,
frag->data, frag->size);
} else {
__output_copy(handle, frag->data,
frag->size);
}
if (perf_raw_frag_last(frag))
break;
frag = frag->next;
} while (1);
if (frag->pad)
__output_skip(handle, NULL, frag->pad);
} else {
struct {
u32 size;
u32 data;
} raw = {
.size = sizeof(u32),
.data = 0,
};
perf_output_put(handle, raw);
}
}
if (sample_type & PERF_SAMPLE_BRANCH_STACK) {
if (data->br_stack) {
size_t size;
size = data->br_stack->nr
* sizeof(struct perf_branch_entry);
perf_output_put(handle, data->br_stack->nr);
if (branch_sample_hw_index(event))
perf_output_put(handle, data->br_stack->hw_idx);
perf_output_copy(handle, data->br_stack->entries, size);
/*
* Add the extension space which is appended
* right after the struct perf_branch_stack.
*/
if (data->br_stack_cntr) {
size = data->br_stack->nr * sizeof(u64);
perf_output_copy(handle, data->br_stack_cntr, size);
}
} else {
/*
* we always store at least the value of nr
*/
u64 nr = 0;
perf_output_put(handle, nr);
}
}
if (sample_type & PERF_SAMPLE_REGS_USER) {
u64 abi = data->regs_user.abi;
/*
* If there are no regs to dump, notice it through
* first u64 being zero (PERF_SAMPLE_REGS_ABI_NONE).
*/
perf_output_put(handle, abi);
if (abi) {
u64 mask = event->attr.sample_regs_user;
perf_output_sample_regs(handle,
data->regs_user.regs,
mask);
}
}
if (sample_type & PERF_SAMPLE_STACK_USER) {
perf_output_sample_ustack(handle,
data->stack_user_size,
data->regs_user.regs);
}
if (sample_type & PERF_SAMPLE_WEIGHT_TYPE)
perf_output_put(handle, data->weight.full);
if (sample_type & PERF_SAMPLE_DATA_SRC)
perf_output_put(handle, data->data_src.val);
if (sample_type & PERF_SAMPLE_TRANSACTION)
perf_output_put(handle, data->txn);
if (sample_type & PERF_SAMPLE_REGS_INTR) {
u64 abi = data->regs_intr.abi;
/*
* If there are no regs to dump, notice it through
* first u64 being zero (PERF_SAMPLE_REGS_ABI_NONE).
*/
perf_output_put(handle, abi);
if (abi) {
u64 mask = event->attr.sample_regs_intr;
perf_output_sample_regs(handle,
data->regs_intr.regs,
mask);
}
}
if (sample_type & PERF_SAMPLE_PHYS_ADDR)
perf_output_put(handle, data->phys_addr);
if (sample_type & PERF_SAMPLE_CGROUP)
perf_output_put(handle, data->cgroup);
if (sample_type & PERF_SAMPLE_DATA_PAGE_SIZE)
perf_output_put(handle, data->data_page_size);
if (sample_type & PERF_SAMPLE_CODE_PAGE_SIZE)
perf_output_put(handle, data->code_page_size);
if (sample_type & PERF_SAMPLE_AUX) {
perf_output_put(handle, data->aux_size);
if (data->aux_size)
perf_aux_sample_output(event, handle, data);
}
if (!event->attr.watermark) {
int wakeup_events = event->attr.wakeup_events;
if (wakeup_events) {
struct perf_buffer *rb = handle->rb;
int events = local_inc_return(&rb->events);
if (events >= wakeup_events) {
local_sub(wakeup_events, &rb->events);
local_inc(&rb->wakeup);
}
}
}
}
static u64 perf_virt_to_phys(u64 virt)
{
u64 phys_addr = 0;
if (!virt)
return 0;
if (virt >= TASK_SIZE) {
/* If it's vmalloc()d memory, leave phys_addr as 0 */
if (virt_addr_valid((void *)(uintptr_t)virt) &&
!(virt >= VMALLOC_START && virt < VMALLOC_END))
phys_addr = (u64)virt_to_phys((void *)(uintptr_t)virt);
} else {
/*
* Walking the pages tables for user address.
* Interrupts are disabled, so it prevents any tear down
* of the page tables.
* Try IRQ-safe get_user_page_fast_only first.
* If failed, leave phys_addr as 0.
*/
if (current->mm != NULL) {
struct page *p;
pagefault_disable();
if (get_user_page_fast_only(virt, 0, &p)) {
phys_addr = page_to_phys(p) + virt % PAGE_SIZE;
put_page(p);
}
pagefault_enable();
}
}
return phys_addr;
}
/*
* Return the pagetable size of a given virtual address.
*/
static u64 perf_get_pgtable_size(struct mm_struct *mm, unsigned long addr)
{
u64 size = 0;
#ifdef CONFIG_HAVE_FAST_GUP
pgd_t *pgdp, pgd;
p4d_t *p4dp, p4d;
pud_t *pudp, pud;
pmd_t *pmdp, pmd;
pte_t *ptep, pte;
pgdp = pgd_offset(mm, addr);
pgd = READ_ONCE(*pgdp);
if (pgd_none(pgd))
return 0;
if (pgd_leaf(pgd))
return pgd_leaf_size(pgd);
p4dp = p4d_offset_lockless(pgdp, pgd, addr);
p4d = READ_ONCE(*p4dp);
if (!p4d_present(p4d))
return 0;
if (p4d_leaf(p4d))
return p4d_leaf_size(p4d);
pudp = pud_offset_lockless(p4dp, p4d, addr);
pud = READ_ONCE(*pudp);
if (!pud_present(pud))
return 0;
if (pud_leaf(pud))
return pud_leaf_size(pud);
pmdp = pmd_offset_lockless(pudp, pud, addr);
again:
pmd = pmdp_get_lockless(pmdp);
if (!pmd_present(pmd))
return 0;
if (pmd_leaf(pmd))
return pmd_leaf_size(pmd);
ptep = pte_offset_map(&pmd, addr);
if (!ptep)
goto again;
pte = ptep_get_lockless(ptep);
if (pte_present(pte))
size = pte_leaf_size(pte);
pte_unmap(ptep);
#endif /* CONFIG_HAVE_FAST_GUP */
return size;
}
static u64 perf_get_page_size(unsigned long addr)
{
struct mm_struct *mm;
unsigned long flags;
u64 size;
if (!addr)
return 0;
/*
* Software page-table walkers must disable IRQs,
* which prevents any tear down of the page tables.
*/
local_irq_save(flags);
mm = current->mm;
if (!mm) {
/*
* For kernel threads and the like, use init_mm so that
* we can find kernel memory.
*/
mm = &init_mm;
}
size = perf_get_pgtable_size(mm, addr);
local_irq_restore(flags);
return size;
}
static struct perf_callchain_entry __empty_callchain = { .nr = 0, };
struct perf_callchain_entry *
perf_callchain(struct perf_event *event, struct pt_regs *regs)
{
bool kernel = !event->attr.exclude_callchain_kernel;
bool user = !event->attr.exclude_callchain_user;
/* Disallow cross-task user callchains. */
bool crosstask = event->ctx->task && event->ctx->task != current;
const u32 max_stack = event->attr.sample_max_stack;
struct perf_callchain_entry *callchain;
if (!kernel && !user)
return &__empty_callchain;
callchain = get_perf_callchain(regs, 0, kernel, user,
max_stack, crosstask, true);
return callchain ?: &__empty_callchain;
}
static __always_inline u64 __cond_set(u64 flags, u64 s, u64 d)
{
return d * !!(flags & s);
}
void perf_prepare_sample(struct perf_sample_data *data,
struct perf_event *event,
struct pt_regs *regs)
{
u64 sample_type = event->attr.sample_type;
u64 filtered_sample_type;
/*
* Add the sample flags that are dependent to others. And clear the
* sample flags that have already been done by the PMU driver.
*/
filtered_sample_type = sample_type;
filtered_sample_type |= __cond_set(sample_type, PERF_SAMPLE_CODE_PAGE_SIZE,
PERF_SAMPLE_IP);
filtered_sample_type |= __cond_set(sample_type, PERF_SAMPLE_DATA_PAGE_SIZE |
PERF_SAMPLE_PHYS_ADDR, PERF_SAMPLE_ADDR);
filtered_sample_type |= __cond_set(sample_type, PERF_SAMPLE_STACK_USER,
PERF_SAMPLE_REGS_USER);
filtered_sample_type &= ~data->sample_flags;
if (filtered_sample_type == 0) {
/* Make sure it has the correct data->type for output */
data->type = event->attr.sample_type;
return;
}
__perf_event_header__init_id(data, event, filtered_sample_type);
if (filtered_sample_type & PERF_SAMPLE_IP) {
data->ip = perf_instruction_pointer(regs);
data->sample_flags |= PERF_SAMPLE_IP;
}
if (filtered_sample_type & PERF_SAMPLE_CALLCHAIN)
perf_sample_save_callchain(data, event, regs);
if (filtered_sample_type & PERF_SAMPLE_RAW) {
data->raw = NULL;
data->dyn_size += sizeof(u64);
data->sample_flags |= PERF_SAMPLE_RAW;
}
if (filtered_sample_type & PERF_SAMPLE_BRANCH_STACK) {
data->br_stack = NULL;
data->dyn_size += sizeof(u64);
data->sample_flags |= PERF_SAMPLE_BRANCH_STACK;
}
if (filtered_sample_type & PERF_SAMPLE_REGS_USER)
perf_sample_regs_user(&data->regs_user, regs);
/*
* It cannot use the filtered_sample_type here as REGS_USER can be set
* by STACK_USER (using __cond_set() above) and we don't want to update
* the dyn_size if it's not requested by users.
*/
if ((sample_type & ~data->sample_flags) & PERF_SAMPLE_REGS_USER) {
/* regs dump ABI info */
int size = sizeof(u64);
if (data->regs_user.regs) {
u64 mask = event->attr.sample_regs_user;
size += hweight64(mask) * sizeof(u64);
}
data->dyn_size += size;
data->sample_flags |= PERF_SAMPLE_REGS_USER;
}
if (filtered_sample_type & PERF_SAMPLE_STACK_USER) {
/*
* Either we need PERF_SAMPLE_STACK_USER bit to be always
* processed as the last one or have additional check added
* in case new sample type is added, because we could eat
* up the rest of the sample size.
*/
u16 stack_size = event->attr.sample_stack_user;
u16 header_size = perf_sample_data_size(data, event);
u16 size = sizeof(u64);
stack_size = perf_sample_ustack_size(stack_size, header_size,
data->regs_user.regs);
/*
* If there is something to dump, add space for the dump
* itself and for the field that tells the dynamic size,
* which is how many have been actually dumped.
*/
if (stack_size)
size += sizeof(u64) + stack_size;
data->stack_user_size = stack_size;
data->dyn_size += size;
data->sample_flags |= PERF_SAMPLE_STACK_USER;
}
if (filtered_sample_type & PERF_SAMPLE_WEIGHT_TYPE) {
data->weight.full = 0;
data->sample_flags |= PERF_SAMPLE_WEIGHT_TYPE;
}
if (filtered_sample_type & PERF_SAMPLE_DATA_SRC) {
data->data_src.val = PERF_MEM_NA;
data->sample_flags |= PERF_SAMPLE_DATA_SRC;
}
if (filtered_sample_type & PERF_SAMPLE_TRANSACTION) {
data->txn = 0;
data->sample_flags |= PERF_SAMPLE_TRANSACTION;
}
if (filtered_sample_type & PERF_SAMPLE_ADDR) {
data->addr = 0;
data->sample_flags |= PERF_SAMPLE_ADDR;
}
if (filtered_sample_type & PERF_SAMPLE_REGS_INTR) {
/* regs dump ABI info */
int size = sizeof(u64);
perf_sample_regs_intr(&data->regs_intr, regs);
if (data->regs_intr.regs) {
u64 mask = event->attr.sample_regs_intr;
size += hweight64(mask) * sizeof(u64);
}
data->dyn_size += size;
data->sample_flags |= PERF_SAMPLE_REGS_INTR;
}
if (filtered_sample_type & PERF_SAMPLE_PHYS_ADDR) {
data->phys_addr = perf_virt_to_phys(data->addr);
data->sample_flags |= PERF_SAMPLE_PHYS_ADDR;
}
#ifdef CONFIG_CGROUP_PERF
if (filtered_sample_type & PERF_SAMPLE_CGROUP) {
struct cgroup *cgrp;
/* protected by RCU */
cgrp = task_css_check(current, perf_event_cgrp_id, 1)->cgroup;
data->cgroup = cgroup_id(cgrp);
data->sample_flags |= PERF_SAMPLE_CGROUP;
}
#endif
/*
* PERF_DATA_PAGE_SIZE requires PERF_SAMPLE_ADDR. If the user doesn't
* require PERF_SAMPLE_ADDR, kernel implicitly retrieve the data->addr,
* but the value will not dump to the userspace.
*/
if (filtered_sample_type & PERF_SAMPLE_DATA_PAGE_SIZE) {
data->data_page_size = perf_get_page_size(data->addr);
data->sample_flags |= PERF_SAMPLE_DATA_PAGE_SIZE;
}
if (filtered_sample_type & PERF_SAMPLE_CODE_PAGE_SIZE) {
data->code_page_size = perf_get_page_size(data->ip);
data->sample_flags |= PERF_SAMPLE_CODE_PAGE_SIZE;
}
if (filtered_sample_type & PERF_SAMPLE_AUX) {
u64 size;
u16 header_size = perf_sample_data_size(data, event);
header_size += sizeof(u64); /* size */
/*
* Given the 16bit nature of header::size, an AUX sample can
* easily overflow it, what with all the preceding sample bits.
* Make sure this doesn't happen by using up to U16_MAX bytes
* per sample in total (rounded down to 8 byte boundary).
*/
size = min_t(size_t, U16_MAX - header_size,
event->attr.aux_sample_size);
size = rounddown(size, 8);
size = perf_prepare_sample_aux(event, data, size);
WARN_ON_ONCE(size + header_size > U16_MAX);
data->dyn_size += size + sizeof(u64); /* size above */
data->sample_flags |= PERF_SAMPLE_AUX;
}
}
void perf_prepare_header(struct perf_event_header *header,
struct perf_sample_data *data,
struct perf_event *event,
struct pt_regs *regs)
{
header->type = PERF_RECORD_SAMPLE;
header->size = perf_sample_data_size(data, event);
header->misc = perf_misc_flags(regs);
/*
* If you're adding more sample types here, you likely need to do
* something about the overflowing header::size, like repurpose the
* lowest 3 bits of size, which should be always zero at the moment.
* This raises a more important question, do we really need 512k sized
* samples and why, so good argumentation is in order for whatever you
* do here next.
*/
WARN_ON_ONCE(header->size & 7);
}
static __always_inline int
__perf_event_output(struct perf_event *event,
struct perf_sample_data *data,
struct pt_regs *regs,
int (*output_begin)(struct perf_output_handle *,
struct perf_sample_data *,
struct perf_event *,
unsigned int))
{
struct perf_output_handle handle;
struct perf_event_header header;
int err;
/* protect the callchain buffers */
rcu_read_lock();
perf_prepare_sample(data, event, regs);
perf_prepare_header(&header, data, event, regs);
err = output_begin(&handle, data, event, header.size);
if (err)
goto exit;
perf_output_sample(&handle, &header, data, event);
perf_output_end(&handle);
exit:
rcu_read_unlock();
return err;
}
void
perf_event_output_forward(struct perf_event *event,
struct perf_sample_data *data,
struct pt_regs *regs)
{
__perf_event_output(event, data, regs, perf_output_begin_forward);
}
void
perf_event_output_backward(struct perf_event *event,
struct perf_sample_data *data,
struct pt_regs *regs)
{
__perf_event_output(event, data, regs, perf_output_begin_backward);
}
int
perf_event_output(struct perf_event *event,
struct perf_sample_data *data,
struct pt_regs *regs)
{
return __perf_event_output(event, data, regs, perf_output_begin);
}
/*
* read event_id
*/
struct perf_read_event {
struct perf_event_header header;
u32 pid;
u32 tid;
};
static void
perf_event_read_event(struct perf_event *event,
struct task_struct *task)
{
struct perf_output_handle handle;
struct perf_sample_data sample;
struct perf_read_event read_event = {
.header = {
.type = PERF_RECORD_READ,
.misc = 0,
.size = sizeof(read_event) + event->read_size,
},
.pid = perf_event_pid(event, task),
.tid = perf_event_tid(event, task),
};
int ret;
perf_event_header__init_id(&read_event.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event, read_event.header.size);
if (ret)
return;
perf_output_put(&handle, read_event);
perf_output_read(&handle, event);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
typedef void (perf_iterate_f)(struct perf_event *event, void *data);
static void
perf_iterate_ctx(struct perf_event_context *ctx,
perf_iterate_f output,
void *data, bool all)
{
struct perf_event *event;
list_for_each_entry_rcu(event, &ctx->event_list, event_entry) {
if (!all) {
if (event->state < PERF_EVENT_STATE_INACTIVE)
continue;
if (!event_filter_match(event))
continue;
}
output(event, data);
}
}
static void perf_iterate_sb_cpu(perf_iterate_f output, void *data)
{
struct pmu_event_list *pel = this_cpu_ptr(&pmu_sb_events);
struct perf_event *event;
list_for_each_entry_rcu(event, &pel->list, sb_list) {
/*
* Skip events that are not fully formed yet; ensure that
* if we observe event->ctx, both event and ctx will be
* complete enough. See perf_install_in_context().
*/
if (!smp_load_acquire(&event->ctx))
continue;
if (event->state < PERF_EVENT_STATE_INACTIVE)
continue;
if (!event_filter_match(event))
continue;
output(event, data);
}
}
/*
* Iterate all events that need to receive side-band events.
*
* For new callers; ensure that account_pmu_sb_event() includes
* your event, otherwise it might not get delivered.
*/
static void
perf_iterate_sb(perf_iterate_f output, void *data,
struct perf_event_context *task_ctx)
{
struct perf_event_context *ctx;
rcu_read_lock();
preempt_disable();
/*
* If we have task_ctx != NULL we only notify the task context itself.
* The task_ctx is set only for EXIT events before releasing task
* context.
*/
if (task_ctx) {
perf_iterate_ctx(task_ctx, output, data, false);
goto done;
}
perf_iterate_sb_cpu(output, data);
ctx = rcu_dereference(current->perf_event_ctxp);
if (ctx)
perf_iterate_ctx(ctx, output, data, false);
done:
preempt_enable();
rcu_read_unlock();
}
/*
* Clear all file-based filters at exec, they'll have to be
* re-instated when/if these objects are mmapped again.
*/
static void perf_event_addr_filters_exec(struct perf_event *event, void *data)
{
struct perf_addr_filters_head *ifh = perf_event_addr_filters(event);
struct perf_addr_filter *filter;
unsigned int restart = 0, count = 0;
unsigned long flags;
if (!has_addr_filter(event))
return;
raw_spin_lock_irqsave(&ifh->lock, flags);
list_for_each_entry(filter, &ifh->list, entry) {
if (filter->path.dentry) {
event->addr_filter_ranges[count].start = 0;
event->addr_filter_ranges[count].size = 0;
restart++;
}
count++;
}
if (restart)
event->addr_filters_gen++;
raw_spin_unlock_irqrestore(&ifh->lock, flags);
if (restart)
perf_event_stop(event, 1);
}
void perf_event_exec(void)
{
struct perf_event_context *ctx;
ctx = perf_pin_task_context(current);
if (!ctx)
return;
perf_event_enable_on_exec(ctx);
perf_event_remove_on_exec(ctx);
perf_iterate_ctx(ctx, perf_event_addr_filters_exec, NULL, true);
perf_unpin_context(ctx);
put_ctx(ctx);
}
struct remote_output {
struct perf_buffer *rb;
int err;
};
static void __perf_event_output_stop(struct perf_event *event, void *data)
{
struct perf_event *parent = event->parent;
struct remote_output *ro = data;
struct perf_buffer *rb = ro->rb;
struct stop_event_data sd = {
.event = event,
};
if (!has_aux(event))
return;
if (!parent)
parent = event;
/*
* In case of inheritance, it will be the parent that links to the
* ring-buffer, but it will be the child that's actually using it.
*
* We are using event::rb to determine if the event should be stopped,
* however this may race with ring_buffer_attach() (through set_output),
* which will make us skip the event that actually needs to be stopped.
* So ring_buffer_attach() has to stop an aux event before re-assigning
* its rb pointer.
*/
if (rcu_dereference(parent->rb) == rb)
ro->err = __perf_event_stop(&sd);
}
static int __perf_pmu_output_stop(void *info)
{
struct perf_event *event = info;
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct remote_output ro = {
.rb = event->rb,
};
rcu_read_lock();
perf_iterate_ctx(&cpuctx->ctx, __perf_event_output_stop, &ro, false);
if (cpuctx->task_ctx)
perf_iterate_ctx(cpuctx->task_ctx, __perf_event_output_stop,
&ro, false);
rcu_read_unlock();
return ro.err;
}
static void perf_pmu_output_stop(struct perf_event *event)
{
struct perf_event *iter;
int err, cpu;
restart:
rcu_read_lock();
list_for_each_entry_rcu(iter, &event->rb->event_list, rb_entry) {
/*
* For per-CPU events, we need to make sure that neither they
* nor their children are running; for cpu==-1 events it's
* sufficient to stop the event itself if it's active, since
* it can't have children.
*/
cpu = iter->cpu;
if (cpu == -1)
cpu = READ_ONCE(iter->oncpu);
if (cpu == -1)
continue;
err = cpu_function_call(cpu, __perf_pmu_output_stop, event);
if (err == -EAGAIN) {
rcu_read_unlock();
goto restart;
}
}
rcu_read_unlock();
}
/*
* task tracking -- fork/exit
*
* enabled by: attr.comm | attr.mmap | attr.mmap2 | attr.mmap_data | attr.task
*/
struct perf_task_event {
struct task_struct *task;
struct perf_event_context *task_ctx;
struct {
struct perf_event_header header;
u32 pid;
u32 ppid;
u32 tid;
u32 ptid;
u64 time;
} event_id;
};
static int perf_event_task_match(struct perf_event *event)
{
return event->attr.comm || event->attr.mmap ||
event->attr.mmap2 || event->attr.mmap_data ||
event->attr.task;
}
static void perf_event_task_output(struct perf_event *event,
void *data)
{
struct perf_task_event *task_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
struct task_struct *task = task_event->task;
int ret, size = task_event->event_id.header.size;
if (!perf_event_task_match(event))
return;
perf_event_header__init_id(&task_event->event_id.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event,
task_event->event_id.header.size);
if (ret)
goto out;
task_event->event_id.pid = perf_event_pid(event, task);
task_event->event_id.tid = perf_event_tid(event, task);
if (task_event->event_id.header.type == PERF_RECORD_EXIT) {
task_event->event_id.ppid = perf_event_pid(event,
task->real_parent);
task_event->event_id.ptid = perf_event_pid(event,
task->real_parent);
} else { /* PERF_RECORD_FORK */
task_event->event_id.ppid = perf_event_pid(event, current);
task_event->event_id.ptid = perf_event_tid(event, current);
}
task_event->event_id.time = perf_event_clock(event);
perf_output_put(&handle, task_event->event_id);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
out:
task_event->event_id.header.size = size;
}
static void perf_event_task(struct task_struct *task,
struct perf_event_context *task_ctx,
int new)
{
struct perf_task_event task_event;
if (!atomic_read(&nr_comm_events) &&
!atomic_read(&nr_mmap_events) &&
!atomic_read(&nr_task_events))
return;
task_event = (struct perf_task_event){
.task = task,
.task_ctx = task_ctx,
.event_id = {
.header = {
.type = new ? PERF_RECORD_FORK : PERF_RECORD_EXIT,
.misc = 0,
.size = sizeof(task_event.event_id),
},
/* .pid */
/* .ppid */
/* .tid */
/* .ptid */
/* .time */
},
};
perf_iterate_sb(perf_event_task_output,
&task_event,
task_ctx);
}
void perf_event_fork(struct task_struct *task)
{
perf_event_task(task, NULL, 1);
perf_event_namespaces(task);
}
/*
* comm tracking
*/
struct perf_comm_event {
struct task_struct *task;
char *comm;
int comm_size;
struct {
struct perf_event_header header;
u32 pid;
u32 tid;
} event_id;
};
static int perf_event_comm_match(struct perf_event *event)
{
return event->attr.comm;
}
static void perf_event_comm_output(struct perf_event *event,
void *data)
{
struct perf_comm_event *comm_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
int size = comm_event->event_id.header.size;
int ret;
if (!perf_event_comm_match(event))
return;
perf_event_header__init_id(&comm_event->event_id.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event,
comm_event->event_id.header.size);
if (ret)
goto out;
comm_event->event_id.pid = perf_event_pid(event, comm_event->task);
comm_event->event_id.tid = perf_event_tid(event, comm_event->task);
perf_output_put(&handle, comm_event->event_id);
__output_copy(&handle, comm_event->comm,
comm_event->comm_size);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
out:
comm_event->event_id.header.size = size;
}
static void perf_event_comm_event(struct perf_comm_event *comm_event)
{
char comm[TASK_COMM_LEN];
unsigned int size;
memset(comm, 0, sizeof(comm));
strscpy(comm, comm_event->task->comm, sizeof(comm));
size = ALIGN(strlen(comm)+1, sizeof(u64));
comm_event->comm = comm;
comm_event->comm_size = size;
comm_event->event_id.header.size = sizeof(comm_event->event_id) + size;
perf_iterate_sb(perf_event_comm_output,
comm_event,
NULL);
}
void perf_event_comm(struct task_struct *task, bool exec)
{
struct perf_comm_event comm_event;
if (!atomic_read(&nr_comm_events))
return;
comm_event = (struct perf_comm_event){
.task = task,
/* .comm */
/* .comm_size */
.event_id = {
.header = {
.type = PERF_RECORD_COMM,
.misc = exec ? PERF_RECORD_MISC_COMM_EXEC : 0,
/* .size */
},
/* .pid */
/* .tid */
},
};
perf_event_comm_event(&comm_event);
}
/*
* namespaces tracking
*/
struct perf_namespaces_event {
struct task_struct *task;
struct {
struct perf_event_header header;
u32 pid;
u32 tid;
u64 nr_namespaces;
struct perf_ns_link_info link_info[NR_NAMESPACES];
} event_id;
};
static int perf_event_namespaces_match(struct perf_event *event)
{
return event->attr.namespaces;
}
static void perf_event_namespaces_output(struct perf_event *event,
void *data)
{
struct perf_namespaces_event *namespaces_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
u16 header_size = namespaces_event->event_id.header.size;
int ret;
if (!perf_event_namespaces_match(event))
return;
perf_event_header__init_id(&namespaces_event->event_id.header,
&sample, event);
ret = perf_output_begin(&handle, &sample, event,
namespaces_event->event_id.header.size);
if (ret)
goto out;
namespaces_event->event_id.pid = perf_event_pid(event,
namespaces_event->task);
namespaces_event->event_id.tid = perf_event_tid(event,
namespaces_event->task);
perf_output_put(&handle, namespaces_event->event_id);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
out:
namespaces_event->event_id.header.size = header_size;
}
static void perf_fill_ns_link_info(struct perf_ns_link_info *ns_link_info,
struct task_struct *task,
const struct proc_ns_operations *ns_ops)
{
struct path ns_path;
struct inode *ns_inode;
int error;
error = ns_get_path(&ns_path, task, ns_ops);
if (!error) {
ns_inode = ns_path.dentry->d_inode;
ns_link_info->dev = new_encode_dev(ns_inode->i_sb->s_dev);
ns_link_info->ino = ns_inode->i_ino;
path_put(&ns_path);
}
}
void perf_event_namespaces(struct task_struct *task)
{
struct perf_namespaces_event namespaces_event;
struct perf_ns_link_info *ns_link_info;
if (!atomic_read(&nr_namespaces_events))
return;
namespaces_event = (struct perf_namespaces_event){
.task = task,
.event_id = {
.header = {
.type = PERF_RECORD_NAMESPACES,
.misc = 0,
.size = sizeof(namespaces_event.event_id),
},
/* .pid */
/* .tid */
.nr_namespaces = NR_NAMESPACES,
/* .link_info[NR_NAMESPACES] */
},
};
ns_link_info = namespaces_event.event_id.link_info;
perf_fill_ns_link_info(&ns_link_info[MNT_NS_INDEX],
task, &mntns_operations);
#ifdef CONFIG_USER_NS
perf_fill_ns_link_info(&ns_link_info[USER_NS_INDEX],
task, &userns_operations);
#endif
#ifdef CONFIG_NET_NS
perf_fill_ns_link_info(&ns_link_info[NET_NS_INDEX],
task, &netns_operations);
#endif
#ifdef CONFIG_UTS_NS
perf_fill_ns_link_info(&ns_link_info[UTS_NS_INDEX],
task, &utsns_operations);
#endif
#ifdef CONFIG_IPC_NS
perf_fill_ns_link_info(&ns_link_info[IPC_NS_INDEX],
task, &ipcns_operations);
#endif
#ifdef CONFIG_PID_NS
perf_fill_ns_link_info(&ns_link_info[PID_NS_INDEX],
task, &pidns_operations);
#endif
#ifdef CONFIG_CGROUPS
perf_fill_ns_link_info(&ns_link_info[CGROUP_NS_INDEX],
task, &cgroupns_operations);
#endif
perf_iterate_sb(perf_event_namespaces_output,
&namespaces_event,
NULL);
}
/*
* cgroup tracking
*/
#ifdef CONFIG_CGROUP_PERF
struct perf_cgroup_event {
char *path;
int path_size;
struct {
struct perf_event_header header;
u64 id;
char path[];
} event_id;
};
static int perf_event_cgroup_match(struct perf_event *event)
{
return event->attr.cgroup;
}
static void perf_event_cgroup_output(struct perf_event *event, void *data)
{
struct perf_cgroup_event *cgroup_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
u16 header_size = cgroup_event->event_id.header.size;
int ret;
if (!perf_event_cgroup_match(event))
return;
perf_event_header__init_id(&cgroup_event->event_id.header,
&sample, event);
ret = perf_output_begin(&handle, &sample, event,
cgroup_event->event_id.header.size);
if (ret)
goto out;
perf_output_put(&handle, cgroup_event->event_id);
__output_copy(&handle, cgroup_event->path, cgroup_event->path_size);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
out:
cgroup_event->event_id.header.size = header_size;
}
static void perf_event_cgroup(struct cgroup *cgrp)
{
struct perf_cgroup_event cgroup_event;
char path_enomem[16] = "//enomem";
char *pathname;
size_t size;
if (!atomic_read(&nr_cgroup_events))
return;
cgroup_event = (struct perf_cgroup_event){
.event_id = {
.header = {
.type = PERF_RECORD_CGROUP,
.misc = 0,
.size = sizeof(cgroup_event.event_id),
},
.id = cgroup_id(cgrp),
},
};
pathname = kmalloc(PATH_MAX, GFP_KERNEL);
if (pathname == NULL) {
cgroup_event.path = path_enomem;
} else {
/* just to be sure to have enough space for alignment */
cgroup_path(cgrp, pathname, PATH_MAX - sizeof(u64));
cgroup_event.path = pathname;
}
/*
* Since our buffer works in 8 byte units we need to align our string
* size to a multiple of 8. However, we must guarantee the tail end is
* zero'd out to avoid leaking random bits to userspace.
*/
size = strlen(cgroup_event.path) + 1;
while (!IS_ALIGNED(size, sizeof(u64)))
cgroup_event.path[size++] = '\0';
cgroup_event.event_id.header.size += size;
cgroup_event.path_size = size;
perf_iterate_sb(perf_event_cgroup_output,
&cgroup_event,
NULL);
kfree(pathname);
}
#endif
/*
* mmap tracking
*/
struct perf_mmap_event {
struct vm_area_struct *vma;
const char *file_name;
int file_size;
int maj, min;
u64 ino;
u64 ino_generation;
u32 prot, flags;
u8 build_id[BUILD_ID_SIZE_MAX];
u32 build_id_size;
struct {
struct perf_event_header header;
u32 pid;
u32 tid;
u64 start;
u64 len;
u64 pgoff;
} event_id;
};
static int perf_event_mmap_match(struct perf_event *event,
void *data)
{
struct perf_mmap_event *mmap_event = data;
struct vm_area_struct *vma = mmap_event->vma;
int executable = vma->vm_flags & VM_EXEC;
return (!executable && event->attr.mmap_data) ||
(executable && (event->attr.mmap || event->attr.mmap2));
}
static void perf_event_mmap_output(struct perf_event *event,
void *data)
{
struct perf_mmap_event *mmap_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
int size = mmap_event->event_id.header.size;
u32 type = mmap_event->event_id.header.type;
bool use_build_id;
int ret;
if (!perf_event_mmap_match(event, data))
return;
if (event->attr.mmap2) {
mmap_event->event_id.header.type = PERF_RECORD_MMAP2;
mmap_event->event_id.header.size += sizeof(mmap_event->maj);
mmap_event->event_id.header.size += sizeof(mmap_event->min);
mmap_event->event_id.header.size += sizeof(mmap_event->ino);
mmap_event->event_id.header.size += sizeof(mmap_event->ino_generation);
mmap_event->event_id.header.size += sizeof(mmap_event->prot);
mmap_event->event_id.header.size += sizeof(mmap_event->flags);
}
perf_event_header__init_id(&mmap_event->event_id.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event,
mmap_event->event_id.header.size);
if (ret)
goto out;
mmap_event->event_id.pid = perf_event_pid(event, current);
mmap_event->event_id.tid = perf_event_tid(event, current);
use_build_id = event->attr.build_id && mmap_event->build_id_size;
if (event->attr.mmap2 && use_build_id)
mmap_event->event_id.header.misc |= PERF_RECORD_MISC_MMAP_BUILD_ID;
perf_output_put(&handle, mmap_event->event_id);
if (event->attr.mmap2) {
if (use_build_id) {
u8 size[4] = { (u8) mmap_event->build_id_size, 0, 0, 0 };
__output_copy(&handle, size, 4);
__output_copy(&handle, mmap_event->build_id, BUILD_ID_SIZE_MAX);
} else {
perf_output_put(&handle, mmap_event->maj);
perf_output_put(&handle, mmap_event->min);
perf_output_put(&handle, mmap_event->ino);
perf_output_put(&handle, mmap_event->ino_generation);
}
perf_output_put(&handle, mmap_event->prot);
perf_output_put(&handle, mmap_event->flags);
}
__output_copy(&handle, mmap_event->file_name,
mmap_event->file_size);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
out:
mmap_event->event_id.header.size = size;
mmap_event->event_id.header.type = type;
}
static void perf_event_mmap_event(struct perf_mmap_event *mmap_event)
{
struct vm_area_struct *vma = mmap_event->vma;
struct file *file = vma->vm_file;
int maj = 0, min = 0;
u64 ino = 0, gen = 0;
u32 prot = 0, flags = 0;
unsigned int size;
char tmp[16];
char *buf = NULL;
char *name = NULL;
if (vma->vm_flags & VM_READ)
prot |= PROT_READ;
if (vma->vm_flags & VM_WRITE)
prot |= PROT_WRITE;
if (vma->vm_flags & VM_EXEC)
prot |= PROT_EXEC;
if (vma->vm_flags & VM_MAYSHARE)
flags = MAP_SHARED;
else
flags = MAP_PRIVATE;
if (vma->vm_flags & VM_LOCKED)
flags |= MAP_LOCKED;
if (is_vm_hugetlb_page(vma))
flags |= MAP_HUGETLB;
if (file) {
struct inode *inode;
dev_t dev;
buf = kmalloc(PATH_MAX, GFP_KERNEL);
if (!buf) {
name = "//enomem";
goto cpy_name;
}
/*
* d_path() works from the end of the rb backwards, so we
* need to add enough zero bytes after the string to handle
* the 64bit alignment we do later.
*/
name = file_path(file, buf, PATH_MAX - sizeof(u64));
if (IS_ERR(name)) {
name = "//toolong";
goto cpy_name;
}
inode = file_inode(vma->vm_file);
dev = inode->i_sb->s_dev;
ino = inode->i_ino;
gen = inode->i_generation;
maj = MAJOR(dev);
min = MINOR(dev);
goto got_name;
} else {
if (vma->vm_ops && vma->vm_ops->name)
name = (char *) vma->vm_ops->name(vma);
if (!name)
name = (char *)arch_vma_name(vma);
if (!name) {
if (vma_is_initial_heap(vma))
name = "[heap]";
else if (vma_is_initial_stack(vma))
name = "[stack]";
else
name = "//anon";
}
}
cpy_name:
strscpy(tmp, name, sizeof(tmp));
name = tmp;
got_name:
/*
* Since our buffer works in 8 byte units we need to align our string
* size to a multiple of 8. However, we must guarantee the tail end is
* zero'd out to avoid leaking random bits to userspace.
*/
size = strlen(name)+1;
while (!IS_ALIGNED(size, sizeof(u64)))
name[size++] = '\0';
mmap_event->file_name = name;
mmap_event->file_size = size;
mmap_event->maj = maj;
mmap_event->min = min;
mmap_event->ino = ino;
mmap_event->ino_generation = gen;
mmap_event->prot = prot;
mmap_event->flags = flags;
if (!(vma->vm_flags & VM_EXEC))
mmap_event->event_id.header.misc |= PERF_RECORD_MISC_MMAP_DATA;
mmap_event->event_id.header.size = sizeof(mmap_event->event_id) + size;
if (atomic_read(&nr_build_id_events))
build_id_parse(vma, mmap_event->build_id, &mmap_event->build_id_size);
perf_iterate_sb(perf_event_mmap_output,
mmap_event,
NULL);
kfree(buf);
}
/*
* Check whether inode and address range match filter criteria.
*/
static bool perf_addr_filter_match(struct perf_addr_filter *filter,
struct file *file, unsigned long offset,
unsigned long size)
{
/* d_inode(NULL) won't be equal to any mapped user-space file */
if (!filter->path.dentry)
return false;
if (d_inode(filter->path.dentry) != file_inode(file))
return false;
if (filter->offset > offset + size)
return false;
if (filter->offset + filter->size < offset)
return false;
return true;
}
static bool perf_addr_filter_vma_adjust(struct perf_addr_filter *filter,
struct vm_area_struct *vma,
struct perf_addr_filter_range *fr)
{
unsigned long vma_size = vma->vm_end - vma->vm_start;
unsigned long off = vma->vm_pgoff << PAGE_SHIFT;
struct file *file = vma->vm_file;
if (!perf_addr_filter_match(filter, file, off, vma_size))
return false;
if (filter->offset < off) {
fr->start = vma->vm_start;
fr->size = min(vma_size, filter->size - (off - filter->offset));
} else {
fr->start = vma->vm_start + filter->offset - off;
fr->size = min(vma->vm_end - fr->start, filter->size);
}
return true;
}
static void __perf_addr_filters_adjust(struct perf_event *event, void *data)
{
struct perf_addr_filters_head *ifh = perf_event_addr_filters(event);
struct vm_area_struct *vma = data;
struct perf_addr_filter *filter;
unsigned int restart = 0, count = 0;
unsigned long flags;
if (!has_addr_filter(event))
return;
if (!vma->vm_file)
return;
raw_spin_lock_irqsave(&ifh->lock, flags);
list_for_each_entry(filter, &ifh->list, entry) {
if (perf_addr_filter_vma_adjust(filter, vma,
&event->addr_filter_ranges[count]))
restart++;
count++;
}
if (restart)
event->addr_filters_gen++;
raw_spin_unlock_irqrestore(&ifh->lock, flags);
if (restart)
perf_event_stop(event, 1);
}
/*
* Adjust all task's events' filters to the new vma
*/
static void perf_addr_filters_adjust(struct vm_area_struct *vma)
{
struct perf_event_context *ctx;
/*
* Data tracing isn't supported yet and as such there is no need
* to keep track of anything that isn't related to executable code:
*/
if (!(vma->vm_flags & VM_EXEC))
return;
rcu_read_lock();
ctx = rcu_dereference(current->perf_event_ctxp);
if (ctx)
perf_iterate_ctx(ctx, __perf_addr_filters_adjust, vma, true);
rcu_read_unlock();
}
void perf_event_mmap(struct vm_area_struct *vma)
{
struct perf_mmap_event mmap_event;
if (!atomic_read(&nr_mmap_events))
return;
mmap_event = (struct perf_mmap_event){
.vma = vma,
/* .file_name */
/* .file_size */
.event_id = {
.header = {
.type = PERF_RECORD_MMAP,
.misc = PERF_RECORD_MISC_USER,
/* .size */
},
/* .pid */
/* .tid */
.start = vma->vm_start,
.len = vma->vm_end - vma->vm_start,
.pgoff = (u64)vma->vm_pgoff << PAGE_SHIFT,
},
/* .maj (attr_mmap2 only) */
/* .min (attr_mmap2 only) */
/* .ino (attr_mmap2 only) */
/* .ino_generation (attr_mmap2 only) */
/* .prot (attr_mmap2 only) */
/* .flags (attr_mmap2 only) */
};
perf_addr_filters_adjust(vma);
perf_event_mmap_event(&mmap_event);
}
void perf_event_aux_event(struct perf_event *event, unsigned long head,
unsigned long size, u64 flags)
{
struct perf_output_handle handle;
struct perf_sample_data sample;
struct perf_aux_event {
struct perf_event_header header;
u64 offset;
u64 size;
u64 flags;
} rec = {
.header = {
.type = PERF_RECORD_AUX,
.misc = 0,
.size = sizeof(rec),
},
.offset = head,
.size = size,
.flags = flags,
};
int ret;
perf_event_header__init_id(&rec.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event, rec.header.size);
if (ret)
return;
perf_output_put(&handle, rec);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
/*
* Lost/dropped samples logging
*/
void perf_log_lost_samples(struct perf_event *event, u64 lost)
{
struct perf_output_handle handle;
struct perf_sample_data sample;
int ret;
struct {
struct perf_event_header header;
u64 lost;
} lost_samples_event = {
.header = {
.type = PERF_RECORD_LOST_SAMPLES,
.misc = 0,
.size = sizeof(lost_samples_event),
},
.lost = lost,
};
perf_event_header__init_id(&lost_samples_event.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event,
lost_samples_event.header.size);
if (ret)
return;
perf_output_put(&handle, lost_samples_event);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
/*
* context_switch tracking
*/
struct perf_switch_event {
struct task_struct *task;
struct task_struct *next_prev;
struct {
struct perf_event_header header;
u32 next_prev_pid;
u32 next_prev_tid;
} event_id;
};
static int perf_event_switch_match(struct perf_event *event)
{
return event->attr.context_switch;
}
static void perf_event_switch_output(struct perf_event *event, void *data)
{
struct perf_switch_event *se = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
int ret;
if (!perf_event_switch_match(event))
return;
/* Only CPU-wide events are allowed to see next/prev pid/tid */
if (event->ctx->task) {
se->event_id.header.type = PERF_RECORD_SWITCH;
se->event_id.header.size = sizeof(se->event_id.header);
} else {
se->event_id.header.type = PERF_RECORD_SWITCH_CPU_WIDE;
se->event_id.header.size = sizeof(se->event_id);
se->event_id.next_prev_pid =
perf_event_pid(event, se->next_prev);
se->event_id.next_prev_tid =
perf_event_tid(event, se->next_prev);
}
perf_event_header__init_id(&se->event_id.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event, se->event_id.header.size);
if (ret)
return;
if (event->ctx->task)
perf_output_put(&handle, se->event_id.header);
else
perf_output_put(&handle, se->event_id);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
static void perf_event_switch(struct task_struct *task,
struct task_struct *next_prev, bool sched_in)
{
struct perf_switch_event switch_event;
/* N.B. caller checks nr_switch_events != 0 */
switch_event = (struct perf_switch_event){
.task = task,
.next_prev = next_prev,
.event_id = {
.header = {
/* .type */
.misc = sched_in ? 0 : PERF_RECORD_MISC_SWITCH_OUT,
/* .size */
},
/* .next_prev_pid */
/* .next_prev_tid */
},
};
if (!sched_in && task->on_rq) {
switch_event.event_id.header.misc |=
PERF_RECORD_MISC_SWITCH_OUT_PREEMPT;
}
perf_iterate_sb(perf_event_switch_output, &switch_event, NULL);
}
/*
* IRQ throttle logging
*/
static void perf_log_throttle(struct perf_event *event, int enable)
{
struct perf_output_handle handle;
struct perf_sample_data sample;
int ret;
struct {
struct perf_event_header header;
u64 time;
u64 id;
u64 stream_id;
} throttle_event = {
.header = {
.type = PERF_RECORD_THROTTLE,
.misc = 0,
.size = sizeof(throttle_event),
},
.time = perf_event_clock(event),
.id = primary_event_id(event),
.stream_id = event->id,
};
if (enable)
throttle_event.header.type = PERF_RECORD_UNTHROTTLE;
perf_event_header__init_id(&throttle_event.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event,
throttle_event.header.size);
if (ret)
return;
perf_output_put(&handle, throttle_event);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
/*
* ksymbol register/unregister tracking
*/
struct perf_ksymbol_event {
const char *name;
int name_len;
struct {
struct perf_event_header header;
u64 addr;
u32 len;
u16 ksym_type;
u16 flags;
} event_id;
};
static int perf_event_ksymbol_match(struct perf_event *event)
{
return event->attr.ksymbol;
}
static void perf_event_ksymbol_output(struct perf_event *event, void *data)
{
struct perf_ksymbol_event *ksymbol_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
int ret;
if (!perf_event_ksymbol_match(event))
return;
perf_event_header__init_id(&ksymbol_event->event_id.header,
&sample, event);
ret = perf_output_begin(&handle, &sample, event,
ksymbol_event->event_id.header.size);
if (ret)
return;
perf_output_put(&handle, ksymbol_event->event_id);
__output_copy(&handle, ksymbol_event->name, ksymbol_event->name_len);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
void perf_event_ksymbol(u16 ksym_type, u64 addr, u32 len, bool unregister,
const char *sym)
{
struct perf_ksymbol_event ksymbol_event;
char name[KSYM_NAME_LEN];
u16 flags = 0;
int name_len;
if (!atomic_read(&nr_ksymbol_events))
return;
if (ksym_type >= PERF_RECORD_KSYMBOL_TYPE_MAX ||
ksym_type == PERF_RECORD_KSYMBOL_TYPE_UNKNOWN)
goto err;
strscpy(name, sym, KSYM_NAME_LEN);
name_len = strlen(name) + 1;
while (!IS_ALIGNED(name_len, sizeof(u64)))
name[name_len++] = '\0';
BUILD_BUG_ON(KSYM_NAME_LEN % sizeof(u64));
if (unregister)
flags |= PERF_RECORD_KSYMBOL_FLAGS_UNREGISTER;
ksymbol_event = (struct perf_ksymbol_event){
.name = name,
.name_len = name_len,
.event_id = {
.header = {
.type = PERF_RECORD_KSYMBOL,
.size = sizeof(ksymbol_event.event_id) +
name_len,
},
.addr = addr,
.len = len,
.ksym_type = ksym_type,
.flags = flags,
},
};
perf_iterate_sb(perf_event_ksymbol_output, &ksymbol_event, NULL);
return;
err:
WARN_ONCE(1, "%s: Invalid KSYMBOL type 0x%x\n", __func__, ksym_type);
}
/*
* bpf program load/unload tracking
*/
struct perf_bpf_event {
struct bpf_prog *prog;
struct {
struct perf_event_header header;
u16 type;
u16 flags;
u32 id;
u8 tag[BPF_TAG_SIZE];
} event_id;
};
static int perf_event_bpf_match(struct perf_event *event)
{
return event->attr.bpf_event;
}
static void perf_event_bpf_output(struct perf_event *event, void *data)
{
struct perf_bpf_event *bpf_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
int ret;
if (!perf_event_bpf_match(event))
return;
perf_event_header__init_id(&bpf_event->event_id.header,
&sample, event);
ret = perf_output_begin(&handle, &sample, event,
bpf_event->event_id.header.size);
if (ret)
return;
perf_output_put(&handle, bpf_event->event_id);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
static void perf_event_bpf_emit_ksymbols(struct bpf_prog *prog,
enum perf_bpf_event_type type)
{
bool unregister = type == PERF_BPF_EVENT_PROG_UNLOAD;
int i;
if (prog->aux->func_cnt == 0) {
perf_event_ksymbol(PERF_RECORD_KSYMBOL_TYPE_BPF,
(u64)(unsigned long)prog->bpf_func,
prog->jited_len, unregister,
prog->aux->ksym.name);
} else {
for (i = 0; i < prog->aux->func_cnt; i++) {
struct bpf_prog *subprog = prog->aux->func[i];
perf_event_ksymbol(
PERF_RECORD_KSYMBOL_TYPE_BPF,
(u64)(unsigned long)subprog->bpf_func,
subprog->jited_len, unregister,
subprog->aux->ksym.name);
}
}
}
void perf_event_bpf_event(struct bpf_prog *prog,
enum perf_bpf_event_type type,
u16 flags)
{
struct perf_bpf_event bpf_event;
switch (type) {
case PERF_BPF_EVENT_PROG_LOAD:
case PERF_BPF_EVENT_PROG_UNLOAD:
if (atomic_read(&nr_ksymbol_events))
perf_event_bpf_emit_ksymbols(prog, type);
break;
default:
return;
}
if (!atomic_read(&nr_bpf_events))
return;
bpf_event = (struct perf_bpf_event){
.prog = prog,
.event_id = {
.header = {
.type = PERF_RECORD_BPF_EVENT,
.size = sizeof(bpf_event.event_id),
},
.type = type,
.flags = flags,
.id = prog->aux->id,
},
};
BUILD_BUG_ON(BPF_TAG_SIZE % sizeof(u64));
memcpy(bpf_event.event_id.tag, prog->tag, BPF_TAG_SIZE);
perf_iterate_sb(perf_event_bpf_output, &bpf_event, NULL);
}
struct perf_text_poke_event {
const void *old_bytes;
const void *new_bytes;
size_t pad;
u16 old_len;
u16 new_len;
struct {
struct perf_event_header header;
u64 addr;
} event_id;
};
static int perf_event_text_poke_match(struct perf_event *event)
{
return event->attr.text_poke;
}
static void perf_event_text_poke_output(struct perf_event *event, void *data)
{
struct perf_text_poke_event *text_poke_event = data;
struct perf_output_handle handle;
struct perf_sample_data sample;
u64 padding = 0;
int ret;
if (!perf_event_text_poke_match(event))
return;
perf_event_header__init_id(&text_poke_event->event_id.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event,
text_poke_event->event_id.header.size);
if (ret)
return;
perf_output_put(&handle, text_poke_event->event_id);
perf_output_put(&handle, text_poke_event->old_len);
perf_output_put(&handle, text_poke_event->new_len);
__output_copy(&handle, text_poke_event->old_bytes, text_poke_event->old_len);
__output_copy(&handle, text_poke_event->new_bytes, text_poke_event->new_len);
if (text_poke_event->pad)
__output_copy(&handle, &padding, text_poke_event->pad);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
void perf_event_text_poke(const void *addr, const void *old_bytes,
size_t old_len, const void *new_bytes, size_t new_len)
{
struct perf_text_poke_event text_poke_event;
size_t tot, pad;
if (!atomic_read(&nr_text_poke_events))
return;
tot = sizeof(text_poke_event.old_len) + old_len;
tot += sizeof(text_poke_event.new_len) + new_len;
pad = ALIGN(tot, sizeof(u64)) - tot;
text_poke_event = (struct perf_text_poke_event){
.old_bytes = old_bytes,
.new_bytes = new_bytes,
.pad = pad,
.old_len = old_len,
.new_len = new_len,
.event_id = {
.header = {
.type = PERF_RECORD_TEXT_POKE,
.misc = PERF_RECORD_MISC_KERNEL,
.size = sizeof(text_poke_event.event_id) + tot + pad,
},
.addr = (unsigned long)addr,
},
};
perf_iterate_sb(perf_event_text_poke_output, &text_poke_event, NULL);
}
void perf_event_itrace_started(struct perf_event *event)
{
event->attach_state |= PERF_ATTACH_ITRACE;
}
static void perf_log_itrace_start(struct perf_event *event)
{
struct perf_output_handle handle;
struct perf_sample_data sample;
struct perf_aux_event {
struct perf_event_header header;
u32 pid;
u32 tid;
} rec;
int ret;
if (event->parent)
event = event->parent;
if (!(event->pmu->capabilities & PERF_PMU_CAP_ITRACE) ||
event->attach_state & PERF_ATTACH_ITRACE)
return;
rec.header.type = PERF_RECORD_ITRACE_START;
rec.header.misc = 0;
rec.header.size = sizeof(rec);
rec.pid = perf_event_pid(event, current);
rec.tid = perf_event_tid(event, current);
perf_event_header__init_id(&rec.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event, rec.header.size);
if (ret)
return;
perf_output_put(&handle, rec);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
void perf_report_aux_output_id(struct perf_event *event, u64 hw_id)
{
struct perf_output_handle handle;
struct perf_sample_data sample;
struct perf_aux_event {
struct perf_event_header header;
u64 hw_id;
} rec;
int ret;
if (event->parent)
event = event->parent;
rec.header.type = PERF_RECORD_AUX_OUTPUT_HW_ID;
rec.header.misc = 0;
rec.header.size = sizeof(rec);
rec.hw_id = hw_id;
perf_event_header__init_id(&rec.header, &sample, event);
ret = perf_output_begin(&handle, &sample, event, rec.header.size);
if (ret)
return;
perf_output_put(&handle, rec);
perf_event__output_id_sample(event, &handle, &sample);
perf_output_end(&handle);
}
EXPORT_SYMBOL_GPL(perf_report_aux_output_id);
static int
__perf_event_account_interrupt(struct perf_event *event, int throttle)
{
struct hw_perf_event *hwc = &event->hw;
int ret = 0;
u64 seq;
seq = __this_cpu_read(perf_throttled_seq);
if (seq != hwc->interrupts_seq) {
hwc->interrupts_seq = seq;
hwc->interrupts = 1;
} else {
hwc->interrupts++;
if (unlikely(throttle &&
hwc->interrupts > max_samples_per_tick)) {
__this_cpu_inc(perf_throttled_count);
tick_dep_set_cpu(smp_processor_id(), TICK_DEP_BIT_PERF_EVENTS);
hwc->interrupts = MAX_INTERRUPTS;
perf_log_throttle(event, 0);
ret = 1;
}
}
if (event->attr.freq) {
u64 now = perf_clock();
s64 delta = now - hwc->freq_time_stamp;
hwc->freq_time_stamp = now;
if (delta > 0 && delta < 2*TICK_NSEC)
perf_adjust_period(event, delta, hwc->last_period, true);
}
return ret;
}
int perf_event_account_interrupt(struct perf_event *event)
{
return __perf_event_account_interrupt(event, 1);
}
static inline bool sample_is_allowed(struct perf_event *event, struct pt_regs *regs)
{
/*
* Due to interrupt latency (AKA "skid"), we may enter the
* kernel before taking an overflow, even if the PMU is only
* counting user events.
*/
if (event->attr.exclude_kernel && !user_mode(regs))
return false;
return true;
}
/*
* Generic event overflow handling, sampling.
*/
static int __perf_event_overflow(struct perf_event *event,
int throttle, struct perf_sample_data *data,
struct pt_regs *regs)
{
int events = atomic_read(&event->event_limit);
int ret = 0;
/*
* Non-sampling counters might still use the PMI to fold short
* hardware counters, ignore those.
*/
if (unlikely(!is_sampling_event(event)))
return 0;
ret = __perf_event_account_interrupt(event, throttle);
/*
* XXX event_limit might not quite work as expected on inherited
* events
*/
event->pending_kill = POLL_IN;
if (events && atomic_dec_and_test(&event->event_limit)) {
ret = 1;
event->pending_kill = POLL_HUP;
perf_event_disable_inatomic(event);
}
if (event->attr.sigtrap) {
/*
* The desired behaviour of sigtrap vs invalid samples is a bit
* tricky; on the one hand, one should not loose the SIGTRAP if
* it is the first event, on the other hand, we should also not
* trigger the WARN or override the data address.
*/
bool valid_sample = sample_is_allowed(event, regs);
unsigned int pending_id = 1;
if (regs)
pending_id = hash32_ptr((void *)instruction_pointer(regs)) ?: 1;
if (!event->pending_sigtrap) {
event->pending_sigtrap = pending_id;
local_inc(&event->ctx->nr_pending);
} else if (event->attr.exclude_kernel && valid_sample) {
/*
* Should not be able to return to user space without
* consuming pending_sigtrap; with exceptions:
*
* 1. Where !exclude_kernel, events can overflow again
* in the kernel without returning to user space.
*
* 2. Events that can overflow again before the IRQ-
* work without user space progress (e.g. hrtimer).
* To approximate progress (with false negatives),
* check 32-bit hash of the current IP.
*/
WARN_ON_ONCE(event->pending_sigtrap != pending_id);
}
event->pending_addr = 0;
if (valid_sample && (data->sample_flags & PERF_SAMPLE_ADDR))
event->pending_addr = data->addr;
irq_work_queue(&event->pending_irq);
}
READ_ONCE(event->overflow_handler)(event, data, regs);
if (*perf_event_fasync(event) && event->pending_kill) {
event->pending_wakeup = 1;
irq_work_queue(&event->pending_irq);
}
return ret;
}
int perf_event_overflow(struct perf_event *event,
struct perf_sample_data *data,
struct pt_regs *regs)
{
return __perf_event_overflow(event, 1, data, regs);
}
/*
* Generic software event infrastructure
*/
struct swevent_htable {
struct swevent_hlist *swevent_hlist;
struct mutex hlist_mutex;
int hlist_refcount;
/* Recursion avoidance in each contexts */
int recursion[PERF_NR_CONTEXTS];
};
static DEFINE_PER_CPU(struct swevent_htable, swevent_htable);
/*
* We directly increment event->count and keep a second value in
* event->hw.period_left to count intervals. This period event
* is kept in the range [-sample_period, 0] so that we can use the
* sign as trigger.
*/
u64 perf_swevent_set_period(struct perf_event *event)
{
struct hw_perf_event *hwc = &event->hw;
u64 period = hwc->last_period;
u64 nr, offset;
s64 old, val;
hwc->last_period = hwc->sample_period;
old = local64_read(&hwc->period_left);
do {
val = old;
if (val < 0)
return 0;
nr = div64_u64(period + val, period);
offset = nr * period;
val -= offset;
} while (!local64_try_cmpxchg(&hwc->period_left, &old, val));
return nr;
}
static void perf_swevent_overflow(struct perf_event *event, u64 overflow,
struct perf_sample_data *data,
struct pt_regs *regs)
{
struct hw_perf_event *hwc = &event->hw;
int throttle = 0;
if (!overflow)
overflow = perf_swevent_set_period(event);
if (hwc->interrupts == MAX_INTERRUPTS)
return;
for (; overflow; overflow--) {
if (__perf_event_overflow(event, throttle,
data, regs)) {
/*
* We inhibit the overflow from happening when
* hwc->interrupts == MAX_INTERRUPTS.
*/
break;
}
throttle = 1;
}
}
static void perf_swevent_event(struct perf_event *event, u64 nr,
struct perf_sample_data *data,
struct pt_regs *regs)
{
struct hw_perf_event *hwc = &event->hw;
local64_add(nr, &event->count);
if (!regs)
return;
if (!is_sampling_event(event))
return;
if ((event->attr.sample_type & PERF_SAMPLE_PERIOD) && !event->attr.freq) {
data->period = nr;
return perf_swevent_overflow(event, 1, data, regs);
} else
data->period = event->hw.last_period;
if (nr == 1 && hwc->sample_period == 1 && !event->attr.freq)
return perf_swevent_overflow(event, 1, data, regs);
if (local64_add_negative(nr, &hwc->period_left))
return;
perf_swevent_overflow(event, 0, data, regs);
}
static int perf_exclude_event(struct perf_event *event,
struct pt_regs *regs)
{
if (event->hw.state & PERF_HES_STOPPED)
return 1;
if (regs) {
if (event->attr.exclude_user && user_mode(regs))
return 1;
if (event->attr.exclude_kernel && !user_mode(regs))
return 1;
}
return 0;
}
static int perf_swevent_match(struct perf_event *event,
enum perf_type_id type,
u32 event_id,
struct perf_sample_data *data,
struct pt_regs *regs)
{
if (event->attr.type != type)
return 0;
if (event->attr.config != event_id)
return 0;
if (perf_exclude_event(event, regs))
return 0;
return 1;
}
static inline u64 swevent_hash(u64 type, u32 event_id)
{
u64 val = event_id | (type << 32);
return hash_64(val, SWEVENT_HLIST_BITS);
}
static inline struct hlist_head *
__find_swevent_head(struct swevent_hlist *hlist, u64 type, u32 event_id)
{
u64 hash = swevent_hash(type, event_id);
return &hlist->heads[hash];
}
/* For the read side: events when they trigger */
static inline struct hlist_head *
find_swevent_head_rcu(struct swevent_htable *swhash, u64 type, u32 event_id)
{
struct swevent_hlist *hlist;
hlist = rcu_dereference(swhash->swevent_hlist);
if (!hlist)
return NULL;
return __find_swevent_head(hlist, type, event_id);
}
/* For the event head insertion and removal in the hlist */
static inline struct hlist_head *
find_swevent_head(struct swevent_htable *swhash, struct perf_event *event)
{
struct swevent_hlist *hlist;
u32 event_id = event->attr.config;
u64 type = event->attr.type;
/*
* Event scheduling is always serialized against hlist allocation
* and release. Which makes the protected version suitable here.
* The context lock guarantees that.
*/
hlist = rcu_dereference_protected(swhash->swevent_hlist,
lockdep_is_held(&event->ctx->lock));
if (!hlist)
return NULL;
return __find_swevent_head(hlist, type, event_id);
}
static void do_perf_sw_event(enum perf_type_id type, u32 event_id,
u64 nr,
struct perf_sample_data *data,
struct pt_regs *regs)
{
struct swevent_htable *swhash = this_cpu_ptr(&swevent_htable);
struct perf_event *event;
struct hlist_head *head;
rcu_read_lock();
head = find_swevent_head_rcu(swhash, type, event_id);
if (!head)
goto end;
hlist_for_each_entry_rcu(event, head, hlist_entry) {
if (perf_swevent_match(event, type, event_id, data, regs))
perf_swevent_event(event, nr, data, regs);
}
end:
rcu_read_unlock();
}
DEFINE_PER_CPU(struct pt_regs, __perf_regs[4]);
int perf_swevent_get_recursion_context(void)
{
struct swevent_htable *swhash = this_cpu_ptr(&swevent_htable);
return get_recursion_context(swhash->recursion);
}
EXPORT_SYMBOL_GPL(perf_swevent_get_recursion_context);
void perf_swevent_put_recursion_context(int rctx)
{
struct swevent_htable *swhash = this_cpu_ptr(&swevent_htable);
put_recursion_context(swhash->recursion, rctx);
}
void ___perf_sw_event(u32 event_id, u64 nr, struct pt_regs *regs, u64 addr)
{
struct perf_sample_data data;
if (WARN_ON_ONCE(!regs))
return;
perf_sample_data_init(&data, addr, 0);
do_perf_sw_event(PERF_TYPE_SOFTWARE, event_id, nr, &data, regs);
}
void __perf_sw_event(u32 event_id, u64 nr, struct pt_regs *regs, u64 addr)
{
int rctx;
preempt_disable_notrace();
rctx = perf_swevent_get_recursion_context();
if (unlikely(rctx < 0))
goto fail;
___perf_sw_event(event_id, nr, regs, addr);
perf_swevent_put_recursion_context(rctx);
fail:
preempt_enable_notrace();
}
static void perf_swevent_read(struct perf_event *event)
{
}
static int perf_swevent_add(struct perf_event *event, int flags)
{
struct swevent_htable *swhash = this_cpu_ptr(&swevent_htable);
struct hw_perf_event *hwc = &event->hw;
struct hlist_head *head;
if (is_sampling_event(event)) {
hwc->last_period = hwc->sample_period;
perf_swevent_set_period(event);
}
hwc->state = !(flags & PERF_EF_START);
head = find_swevent_head(swhash, event);
if (WARN_ON_ONCE(!head))
return -EINVAL;
hlist_add_head_rcu(&event->hlist_entry, head);
perf_event_update_userpage(event);
return 0;
}
static void perf_swevent_del(struct perf_event *event, int flags)
{
hlist_del_rcu(&event->hlist_entry);
}
static void perf_swevent_start(struct perf_event *event, int flags)
{
event->hw.state = 0;
}
static void perf_swevent_stop(struct perf_event *event, int flags)
{
event->hw.state = PERF_HES_STOPPED;
}
/* Deref the hlist from the update side */
static inline struct swevent_hlist *
swevent_hlist_deref(struct swevent_htable *swhash)
{
return rcu_dereference_protected(swhash->swevent_hlist,
lockdep_is_held(&swhash->hlist_mutex));
}
static void swevent_hlist_release(struct swevent_htable *swhash)
{
struct swevent_hlist *hlist = swevent_hlist_deref(swhash);
if (!hlist)
return;
RCU_INIT_POINTER(swhash->swevent_hlist, NULL);
kfree_rcu(hlist, rcu_head);
}
static void swevent_hlist_put_cpu(int cpu)
{
struct swevent_htable *swhash = &per_cpu(swevent_htable, cpu);
mutex_lock(&swhash->hlist_mutex);
if (!--swhash->hlist_refcount)
swevent_hlist_release(swhash);
mutex_unlock(&swhash->hlist_mutex);
}
static void swevent_hlist_put(void)
{
int cpu;
for_each_possible_cpu(cpu)
swevent_hlist_put_cpu(cpu);
}
static int swevent_hlist_get_cpu(int cpu)
{
struct swevent_htable *swhash = &per_cpu(swevent_htable, cpu);
int err = 0;
mutex_lock(&swhash->hlist_mutex);
if (!swevent_hlist_deref(swhash) &&
cpumask_test_cpu(cpu, perf_online_mask)) {
struct swevent_hlist *hlist;
hlist = kzalloc(sizeof(*hlist), GFP_KERNEL);
if (!hlist) {
err = -ENOMEM;
goto exit;
}
rcu_assign_pointer(swhash->swevent_hlist, hlist);
}
swhash->hlist_refcount++;
exit:
mutex_unlock(&swhash->hlist_mutex);
return err;
}
static int swevent_hlist_get(void)
{
int err, cpu, failed_cpu;
mutex_lock(&pmus_lock);
for_each_possible_cpu(cpu) {
err = swevent_hlist_get_cpu(cpu);
if (err) {
failed_cpu = cpu;
goto fail;
}
}
mutex_unlock(&pmus_lock);
return 0;
fail:
for_each_possible_cpu(cpu) {
if (cpu == failed_cpu)
break;
swevent_hlist_put_cpu(cpu);
}
mutex_unlock(&pmus_lock);
return err;
}
struct static_key perf_swevent_enabled[PERF_COUNT_SW_MAX];
static void sw_perf_event_destroy(struct perf_event *event)
{
u64 event_id = event->attr.config;
WARN_ON(event->parent);
static_key_slow_dec(&perf_swevent_enabled[event_id]);
swevent_hlist_put();
}
static struct pmu perf_cpu_clock; /* fwd declaration */
static struct pmu perf_task_clock;
static int perf_swevent_init(struct perf_event *event)
{
u64 event_id = event->attr.config;
if (event->attr.type != PERF_TYPE_SOFTWARE)
return -ENOENT;
/*
* no branch sampling for software events
*/
if (has_branch_stack(event))
return -EOPNOTSUPP;
switch (event_id) {
case PERF_COUNT_SW_CPU_CLOCK:
event->attr.type = perf_cpu_clock.type;
return -ENOENT;
case PERF_COUNT_SW_TASK_CLOCK:
event->attr.type = perf_task_clock.type;
return -ENOENT;
default:
break;
}
if (event_id >= PERF_COUNT_SW_MAX)
return -ENOENT;
if (!event->parent) {
int err;
err = swevent_hlist_get();
if (err)
return err;
static_key_slow_inc(&perf_swevent_enabled[event_id]);
event->destroy = sw_perf_event_destroy;
}
return 0;
}
static struct pmu perf_swevent = {
.task_ctx_nr = perf_sw_context,
.capabilities = PERF_PMU_CAP_NO_NMI,
.event_init = perf_swevent_init,
.add = perf_swevent_add,
.del = perf_swevent_del,
.start = perf_swevent_start,
.stop = perf_swevent_stop,
.read = perf_swevent_read,
};
#ifdef CONFIG_EVENT_TRACING
static void tp_perf_event_destroy(struct perf_event *event)
{
perf_trace_destroy(event);
}
static int perf_tp_event_init(struct perf_event *event)
{
int err;
if (event->attr.type != PERF_TYPE_TRACEPOINT)
return -ENOENT;
/*
* no branch sampling for tracepoint events
*/
if (has_branch_stack(event))
return -EOPNOTSUPP;
err = perf_trace_init(event);
if (err)
return err;
event->destroy = tp_perf_event_destroy;
return 0;
}
static struct pmu perf_tracepoint = {
.task_ctx_nr = perf_sw_context,
.event_init = perf_tp_event_init,
.add = perf_trace_add,
.del = perf_trace_del,
.start = perf_swevent_start,
.stop = perf_swevent_stop,
.read = perf_swevent_read,
};
static int perf_tp_filter_match(struct perf_event *event,
struct perf_sample_data *data)
{
void *record = data->raw->frag.data;
/* only top level events have filters set */
if (event->parent)
event = event->parent;
if (likely(!event->filter) || filter_match_preds(event->filter, record))
return 1;
return 0;
}
static int perf_tp_event_match(struct perf_event *event,
struct perf_sample_data *data,
struct pt_regs *regs)
{
if (event->hw.state & PERF_HES_STOPPED)
return 0;
/*
* If exclude_kernel, only trace user-space tracepoints (uprobes)
*/
if (event->attr.exclude_kernel && !user_mode(regs))
return 0;
if (!perf_tp_filter_match(event, data))
return 0;
return 1;
}
void perf_trace_run_bpf_submit(void *raw_data, int size, int rctx,
struct trace_event_call *call, u64 count,
struct pt_regs *regs, struct hlist_head *head,
struct task_struct *task)
{
if (bpf_prog_array_valid(call)) {
*(struct pt_regs **)raw_data = regs;
if (!trace_call_bpf(call, raw_data) || hlist_empty(head)) {
perf_swevent_put_recursion_context(rctx);
return;
}
}
perf_tp_event(call->event.type, count, raw_data, size, regs, head,
rctx, task);
}
EXPORT_SYMBOL_GPL(perf_trace_run_bpf_submit);
static void __perf_tp_event_target_task(u64 count, void *record,
struct pt_regs *regs,
struct perf_sample_data *data,
struct perf_event *event)
{
struct trace_entry *entry = record;
if (event->attr.config != entry->type)
return;
/* Cannot deliver synchronous signal to other task. */
if (event->attr.sigtrap)
return;
if (perf_tp_event_match(event, data, regs))
perf_swevent_event(event, count, data, regs);
}
static void perf_tp_event_target_task(u64 count, void *record,
struct pt_regs *regs,
struct perf_sample_data *data,
struct perf_event_context *ctx)
{
unsigned int cpu = smp_processor_id();
struct pmu *pmu = &perf_tracepoint;
struct perf_event *event, *sibling;
perf_event_groups_for_cpu_pmu(event, &ctx->pinned_groups, cpu, pmu) {
__perf_tp_event_target_task(count, record, regs, data, event);
for_each_sibling_event(sibling, event)
__perf_tp_event_target_task(count, record, regs, data, sibling);
}
perf_event_groups_for_cpu_pmu(event, &ctx->flexible_groups, cpu, pmu) {
__perf_tp_event_target_task(count, record, regs, data, event);
for_each_sibling_event(sibling, event)
__perf_tp_event_target_task(count, record, regs, data, sibling);
}
}
void perf_tp_event(u16 event_type, u64 count, void *record, int entry_size,
struct pt_regs *regs, struct hlist_head *head, int rctx,
struct task_struct *task)
{
struct perf_sample_data data;
struct perf_event *event;
struct perf_raw_record raw = {
.frag = {
.size = entry_size,
.data = record,
},
};
perf_sample_data_init(&data, 0, 0);
perf_sample_save_raw_data(&data, &raw);
perf_trace_buf_update(record, event_type);
hlist_for_each_entry_rcu(event, head, hlist_entry) {
if (perf_tp_event_match(event, &data, regs)) {
perf_swevent_event(event, count, &data, regs);
/*
* Here use the same on-stack perf_sample_data,
* some members in data are event-specific and
* need to be re-computed for different sweveents.
* Re-initialize data->sample_flags safely to avoid
* the problem that next event skips preparing data
* because data->sample_flags is set.
*/
perf_sample_data_init(&data, 0, 0);
perf_sample_save_raw_data(&data, &raw);
}
}
/*
* If we got specified a target task, also iterate its context and
* deliver this event there too.
*/
if (task && task != current) {
struct perf_event_context *ctx;
rcu_read_lock();
ctx = rcu_dereference(task->perf_event_ctxp);
if (!ctx)
goto unlock;
raw_spin_lock(&ctx->lock);
perf_tp_event_target_task(count, record, regs, &data, ctx);
raw_spin_unlock(&ctx->lock);
unlock:
rcu_read_unlock();
}
perf_swevent_put_recursion_context(rctx);
}
EXPORT_SYMBOL_GPL(perf_tp_event);
#if defined(CONFIG_KPROBE_EVENTS) || defined(CONFIG_UPROBE_EVENTS)
/*
* Flags in config, used by dynamic PMU kprobe and uprobe
* The flags should match following PMU_FORMAT_ATTR().
*
* PERF_PROBE_CONFIG_IS_RETPROBE if set, create kretprobe/uretprobe
* if not set, create kprobe/uprobe
*
* The following values specify a reference counter (or semaphore in the
* terminology of tools like dtrace, systemtap, etc.) Userspace Statically
* Defined Tracepoints (USDT). Currently, we use 40 bit for the offset.
*
* PERF_UPROBE_REF_CTR_OFFSET_BITS # of bits in config as th offset
* PERF_UPROBE_REF_CTR_OFFSET_SHIFT # of bits to shift left
*/
enum perf_probe_config {
PERF_PROBE_CONFIG_IS_RETPROBE = 1U << 0, /* [k,u]retprobe */
PERF_UPROBE_REF_CTR_OFFSET_BITS = 32,
PERF_UPROBE_REF_CTR_OFFSET_SHIFT = 64 - PERF_UPROBE_REF_CTR_OFFSET_BITS,
};
PMU_FORMAT_ATTR(retprobe, "config:0");
#endif
#ifdef CONFIG_KPROBE_EVENTS
static struct attribute *kprobe_attrs[] = {
&format_attr_retprobe.attr,
NULL,
};
static struct attribute_group kprobe_format_group = {
.name = "format",
.attrs = kprobe_attrs,
};
static const struct attribute_group *kprobe_attr_groups[] = {
&kprobe_format_group,
NULL,
};
static int perf_kprobe_event_init(struct perf_event *event);
static struct pmu perf_kprobe = {
.task_ctx_nr = perf_sw_context,
.event_init = perf_kprobe_event_init,
.add = perf_trace_add,
.del = perf_trace_del,
.start = perf_swevent_start,
.stop = perf_swevent_stop,
.read = perf_swevent_read,
.attr_groups = kprobe_attr_groups,
};
static int perf_kprobe_event_init(struct perf_event *event)
{
int err;
bool is_retprobe;
if (event->attr.type != perf_kprobe.type)
return -ENOENT;
if (!perfmon_capable())
return -EACCES;
/*
* no branch sampling for probe events
*/
if (has_branch_stack(event))
return -EOPNOTSUPP;
is_retprobe = event->attr.config & PERF_PROBE_CONFIG_IS_RETPROBE;
err = perf_kprobe_init(event, is_retprobe);
if (err)
return err;
event->destroy = perf_kprobe_destroy;
return 0;
}
#endif /* CONFIG_KPROBE_EVENTS */
#ifdef CONFIG_UPROBE_EVENTS
PMU_FORMAT_ATTR(ref_ctr_offset, "config:32-63");
static struct attribute *uprobe_attrs[] = {
&format_attr_retprobe.attr,
&format_attr_ref_ctr_offset.attr,
NULL,
};
static struct attribute_group uprobe_format_group = {
.name = "format",
.attrs = uprobe_attrs,
};
static const struct attribute_group *uprobe_attr_groups[] = {
&uprobe_format_group,
NULL,
};
static int perf_uprobe_event_init(struct perf_event *event);
static struct pmu perf_uprobe = {
.task_ctx_nr = perf_sw_context,
.event_init = perf_uprobe_event_init,
.add = perf_trace_add,
.del = perf_trace_del,
.start = perf_swevent_start,
.stop = perf_swevent_stop,
.read = perf_swevent_read,
.attr_groups = uprobe_attr_groups,
};
static int perf_uprobe_event_init(struct perf_event *event)
{
int err;
unsigned long ref_ctr_offset;
bool is_retprobe;
if (event->attr.type != perf_uprobe.type)
return -ENOENT;
if (!perfmon_capable())
return -EACCES;
/*
* no branch sampling for probe events
*/
if (has_branch_stack(event))
return -EOPNOTSUPP;
is_retprobe = event->attr.config & PERF_PROBE_CONFIG_IS_RETPROBE;
ref_ctr_offset = event->attr.config >> PERF_UPROBE_REF_CTR_OFFSET_SHIFT;
err = perf_uprobe_init(event, ref_ctr_offset, is_retprobe);
if (err)
return err;
event->destroy = perf_uprobe_destroy;
return 0;
}
#endif /* CONFIG_UPROBE_EVENTS */
static inline void perf_tp_register(void)
{
perf_pmu_register(&perf_tracepoint, "tracepoint", PERF_TYPE_TRACEPOINT);
#ifdef CONFIG_KPROBE_EVENTS
perf_pmu_register(&perf_kprobe, "kprobe", -1);
#endif
#ifdef CONFIG_UPROBE_EVENTS
perf_pmu_register(&perf_uprobe, "uprobe", -1);
#endif
}
static void perf_event_free_filter(struct perf_event *event)
{
ftrace_profile_free_filter(event);
}
#ifdef CONFIG_BPF_SYSCALL
static void bpf_overflow_handler(struct perf_event *event,
struct perf_sample_data *data,
struct pt_regs *regs)
{
struct bpf_perf_event_data_kern ctx = {
.data = data,
.event = event,
};
struct bpf_prog *prog;
int ret = 0;
ctx.regs = perf_arch_bpf_user_pt_regs(regs);
if (unlikely(__this_cpu_inc_return(bpf_prog_active) != 1))
goto out;
rcu_read_lock();
prog = READ_ONCE(event->prog);
if (prog) {
perf_prepare_sample(data, event, regs);
ret = bpf_prog_run(prog, &ctx);
}
rcu_read_unlock();
out:
__this_cpu_dec(bpf_prog_active);
if (!ret)
return;
event->orig_overflow_handler(event, data, regs);
}
static int perf_event_set_bpf_handler(struct perf_event *event,
struct bpf_prog *prog,
u64 bpf_cookie)
{
if (event->overflow_handler_context)
/* hw breakpoint or kernel counter */
return -EINVAL;
if (event->prog)
return -EEXIST;
if (prog->type != BPF_PROG_TYPE_PERF_EVENT)
return -EINVAL;
if (event->attr.precise_ip &&
prog->call_get_stack &&
(!(event->attr.sample_type & PERF_SAMPLE_CALLCHAIN) ||
event->attr.exclude_callchain_kernel ||
event->attr.exclude_callchain_user)) {
/*
* On perf_event with precise_ip, calling bpf_get_stack()
* may trigger unwinder warnings and occasional crashes.
* bpf_get_[stack|stackid] works around this issue by using
* callchain attached to perf_sample_data. If the
* perf_event does not full (kernel and user) callchain
* attached to perf_sample_data, do not allow attaching BPF
* program that calls bpf_get_[stack|stackid].
*/
return -EPROTO;
}
event->prog = prog;
event->bpf_cookie = bpf_cookie;
event->orig_overflow_handler = READ_ONCE(event->overflow_handler);
WRITE_ONCE(event->overflow_handler, bpf_overflow_handler);
return 0;
}
static void perf_event_free_bpf_handler(struct perf_event *event)
{
struct bpf_prog *prog = event->prog;
if (!prog)
return;
WRITE_ONCE(event->overflow_handler, event->orig_overflow_handler);
event->prog = NULL;
bpf_prog_put(prog);
}
#else
static int perf_event_set_bpf_handler(struct perf_event *event,
struct bpf_prog *prog,
u64 bpf_cookie)
{
return -EOPNOTSUPP;
}
static void perf_event_free_bpf_handler(struct perf_event *event)
{
}
#endif
/*
* returns true if the event is a tracepoint, or a kprobe/upprobe created
* with perf_event_open()
*/
static inline bool perf_event_is_tracing(struct perf_event *event)
{
if (event->pmu == &perf_tracepoint)
return true;
#ifdef CONFIG_KPROBE_EVENTS
if (event->pmu == &perf_kprobe)
return true;
#endif
#ifdef CONFIG_UPROBE_EVENTS
if (event->pmu == &perf_uprobe)
return true;
#endif
return false;
}
int perf_event_set_bpf_prog(struct perf_event *event, struct bpf_prog *prog,
u64 bpf_cookie)
{
bool is_kprobe, is_uprobe, is_tracepoint, is_syscall_tp;
if (!perf_event_is_tracing(event))
return perf_event_set_bpf_handler(event, prog, bpf_cookie);
is_kprobe = event->tp_event->flags & TRACE_EVENT_FL_KPROBE;
is_uprobe = event->tp_event->flags & TRACE_EVENT_FL_UPROBE;
is_tracepoint = event->tp_event->flags & TRACE_EVENT_FL_TRACEPOINT;
is_syscall_tp = is_syscall_trace_event(event->tp_event);
if (!is_kprobe && !is_uprobe && !is_tracepoint && !is_syscall_tp)
/* bpf programs can only be attached to u/kprobe or tracepoint */
return -EINVAL;
if (((is_kprobe || is_uprobe) && prog->type != BPF_PROG_TYPE_KPROBE) ||
(is_tracepoint && prog->type != BPF_PROG_TYPE_TRACEPOINT) ||
(is_syscall_tp && prog->type != BPF_PROG_TYPE_TRACEPOINT))
return -EINVAL;
if (prog->type == BPF_PROG_TYPE_KPROBE && prog->sleepable && !is_uprobe)
/* only uprobe programs are allowed to be sleepable */
return -EINVAL;
/* Kprobe override only works for kprobes, not uprobes. */
if (prog->kprobe_override && !is_kprobe)
return -EINVAL;
if (is_tracepoint || is_syscall_tp) {
int off = trace_event_get_offsets(event->tp_event);
if (prog->aux->max_ctx_offset > off)
return -EACCES;
}
return perf_event_attach_bpf_prog(event, prog, bpf_cookie);
}
void perf_event_free_bpf_prog(struct perf_event *event)
{
if (!perf_event_is_tracing(event)) {
perf_event_free_bpf_handler(event);
return;
}
perf_event_detach_bpf_prog(event);
}
#else
static inline void perf_tp_register(void)
{
}
static void perf_event_free_filter(struct perf_event *event)
{
}
int perf_event_set_bpf_prog(struct perf_event *event, struct bpf_prog *prog,
u64 bpf_cookie)
{
return -ENOENT;
}
void perf_event_free_bpf_prog(struct perf_event *event)
{
}
#endif /* CONFIG_EVENT_TRACING */
#ifdef CONFIG_HAVE_HW_BREAKPOINT
void perf_bp_event(struct perf_event *bp, void *data)
{
struct perf_sample_data sample;
struct pt_regs *regs = data;
perf_sample_data_init(&sample, bp->attr.bp_addr, 0);
if (!bp->hw.state && !perf_exclude_event(bp, regs))
perf_swevent_event(bp, 1, &sample, regs);
}
#endif
/*
* Allocate a new address filter
*/
static struct perf_addr_filter *
perf_addr_filter_new(struct perf_event *event, struct list_head *filters)
{
int node = cpu_to_node(event->cpu == -1 ? 0 : event->cpu);
struct perf_addr_filter *filter;
filter = kzalloc_node(sizeof(*filter), GFP_KERNEL, node);
if (!filter)
return NULL;
INIT_LIST_HEAD(&filter->entry);
list_add_tail(&filter->entry, filters);
return filter;
}
static void free_filters_list(struct list_head *filters)
{
struct perf_addr_filter *filter, *iter;
list_for_each_entry_safe(filter, iter, filters, entry) {
path_put(&filter->path);
list_del(&filter->entry);
kfree(filter);
}
}
/*
* Free existing address filters and optionally install new ones
*/
static void perf_addr_filters_splice(struct perf_event *event,
struct list_head *head)
{
unsigned long flags;
LIST_HEAD(list);
if (!has_addr_filter(event))
return;
/* don't bother with children, they don't have their own filters */
if (event->parent)
return;
raw_spin_lock_irqsave(&event->addr_filters.lock, flags);
list_splice_init(&event->addr_filters.list, &list);
if (head)
list_splice(head, &event->addr_filters.list);
raw_spin_unlock_irqrestore(&event->addr_filters.lock, flags);
free_filters_list(&list);
}
/*
* Scan through mm's vmas and see if one of them matches the
* @filter; if so, adjust filter's address range.
* Called with mm::mmap_lock down for reading.
*/
static void perf_addr_filter_apply(struct perf_addr_filter *filter,
struct mm_struct *mm,
struct perf_addr_filter_range *fr)
{
struct vm_area_struct *vma;
VMA_ITERATOR(vmi, mm, 0);
for_each_vma(vmi, vma) {
if (!vma->vm_file)
continue;
if (perf_addr_filter_vma_adjust(filter, vma, fr))
return;
}
}
/*
* Update event's address range filters based on the
* task's existing mappings, if any.
*/
static void perf_event_addr_filters_apply(struct perf_event *event)
{
struct perf_addr_filters_head *ifh = perf_event_addr_filters(event);
struct task_struct *task = READ_ONCE(event->ctx->task);
struct perf_addr_filter *filter;
struct mm_struct *mm = NULL;
unsigned int count = 0;
unsigned long flags;
/*
* We may observe TASK_TOMBSTONE, which means that the event tear-down
* will stop on the parent's child_mutex that our caller is also holding
*/
if (task == TASK_TOMBSTONE)
return;
if (ifh->nr_file_filters) {
mm = get_task_mm(task);
if (!mm)
goto restart;
mmap_read_lock(mm);
}
raw_spin_lock_irqsave(&ifh->lock, flags);
list_for_each_entry(filter, &ifh->list, entry) {
if (filter->path.dentry) {
/*
* Adjust base offset if the filter is associated to a
* binary that needs to be mapped:
*/
event->addr_filter_ranges[count].start = 0;
event->addr_filter_ranges[count].size = 0;
perf_addr_filter_apply(filter, mm, &event->addr_filter_ranges[count]);
} else {
event->addr_filter_ranges[count].start = filter->offset;
event->addr_filter_ranges[count].size = filter->size;
}
count++;
}
event->addr_filters_gen++;
raw_spin_unlock_irqrestore(&ifh->lock, flags);
if (ifh->nr_file_filters) {
mmap_read_unlock(mm);
mmput(mm);
}
restart:
perf_event_stop(event, 1);
}
/*
* Address range filtering: limiting the data to certain
* instruction address ranges. Filters are ioctl()ed to us from
* userspace as ascii strings.
*
* Filter string format:
*
* ACTION RANGE_SPEC
* where ACTION is one of the
* * "filter": limit the trace to this region
* * "start": start tracing from this address
* * "stop": stop tracing at this address/region;
* RANGE_SPEC is
* * for kernel addresses: <start address>[/<size>]
* * for object files: <start address>[/<size>]@</path/to/object/file>
*
* if <size> is not specified or is zero, the range is treated as a single
* address; not valid for ACTION=="filter".
*/
enum {
IF_ACT_NONE = -1,
IF_ACT_FILTER,
IF_ACT_START,
IF_ACT_STOP,
IF_SRC_FILE,
IF_SRC_KERNEL,
IF_SRC_FILEADDR,
IF_SRC_KERNELADDR,
};
enum {
IF_STATE_ACTION = 0,
IF_STATE_SOURCE,
IF_STATE_END,
};
static const match_table_t if_tokens = {
{ IF_ACT_FILTER, "filter" },
{ IF_ACT_START, "start" },
{ IF_ACT_STOP, "stop" },
{ IF_SRC_FILE, "%u/%u@%s" },
{ IF_SRC_KERNEL, "%u/%u" },
{ IF_SRC_FILEADDR, "%u@%s" },
{ IF_SRC_KERNELADDR, "%u" },
{ IF_ACT_NONE, NULL },
};
/*
* Address filter string parser
*/
static int
perf_event_parse_addr_filter(struct perf_event *event, char *fstr,
struct list_head *filters)
{
struct perf_addr_filter *filter = NULL;
char *start, *orig, *filename = NULL;
substring_t args[MAX_OPT_ARGS];
int state = IF_STATE_ACTION, token;
unsigned int kernel = 0;
int ret = -EINVAL;
orig = fstr = kstrdup(fstr, GFP_KERNEL);
if (!fstr)
return -ENOMEM;
while ((start = strsep(&fstr, " ,\n")) != NULL) {
static const enum perf_addr_filter_action_t actions[] = {
[IF_ACT_FILTER] = PERF_ADDR_FILTER_ACTION_FILTER,
[IF_ACT_START] = PERF_ADDR_FILTER_ACTION_START,
[IF_ACT_STOP] = PERF_ADDR_FILTER_ACTION_STOP,
};
ret = -EINVAL;
if (!*start)
continue;
/* filter definition begins */
if (state == IF_STATE_ACTION) {
filter = perf_addr_filter_new(event, filters);
if (!filter)
goto fail;
}
token = match_token(start, if_tokens, args);
switch (token) {
case IF_ACT_FILTER:
case IF_ACT_START:
case IF_ACT_STOP:
if (state != IF_STATE_ACTION)
goto fail;
filter->action = actions[token];
state = IF_STATE_SOURCE;
break;
case IF_SRC_KERNELADDR:
case IF_SRC_KERNEL:
kernel = 1;
fallthrough;
case IF_SRC_FILEADDR:
case IF_SRC_FILE:
if (state != IF_STATE_SOURCE)
goto fail;
*args[0].to = 0;
ret = kstrtoul(args[0].from, 0, &filter->offset);
if (ret)
goto fail;
if (token == IF_SRC_KERNEL || token == IF_SRC_FILE) {
*args[1].to = 0;
ret = kstrtoul(args[1].from, 0, &filter->size);
if (ret)
goto fail;
}
if (token == IF_SRC_FILE || token == IF_SRC_FILEADDR) {
int fpos = token == IF_SRC_FILE ? 2 : 1;
kfree(filename);
filename = match_strdup(&args[fpos]);
if (!filename) {
ret = -ENOMEM;
goto fail;
}
}
state = IF_STATE_END;
break;
default:
goto fail;
}
/*
* Filter definition is fully parsed, validate and install it.
* Make sure that it doesn't contradict itself or the event's
* attribute.
*/
if (state == IF_STATE_END) {
ret = -EINVAL;
/*
* ACTION "filter" must have a non-zero length region
* specified.
*/
if (filter->action == PERF_ADDR_FILTER_ACTION_FILTER &&
!filter->size)
goto fail;
if (!kernel) {
if (!filename)
goto fail;
/*
* For now, we only support file-based filters
* in per-task events; doing so for CPU-wide
* events requires additional context switching
* trickery, since same object code will be
* mapped at different virtual addresses in
* different processes.
*/
ret = -EOPNOTSUPP;
if (!event->ctx->task)
goto fail;
/* look up the path and grab its inode */
ret = kern_path(filename, LOOKUP_FOLLOW,
&filter->path);
if (ret)
goto fail;
ret = -EINVAL;
if (!filter->path.dentry ||
!S_ISREG(d_inode(filter->path.dentry)
->i_mode))
goto fail;
event->addr_filters.nr_file_filters++;
}
/* ready to consume more filters */
kfree(filename);
filename = NULL;
state = IF_STATE_ACTION;
filter = NULL;
kernel = 0;
}
}
if (state != IF_STATE_ACTION)
goto fail;
kfree(filename);
kfree(orig);
return 0;
fail:
kfree(filename);
free_filters_list(filters);
kfree(orig);
return ret;
}
static int
perf_event_set_addr_filter(struct perf_event *event, char *filter_str)
{
LIST_HEAD(filters);
int ret;
/*
* Since this is called in perf_ioctl() path, we're already holding
* ctx::mutex.
*/
lockdep_assert_held(&event->ctx->mutex);
if (WARN_ON_ONCE(event->parent))
return -EINVAL;
ret = perf_event_parse_addr_filter(event, filter_str, &filters);
if (ret)
goto fail_clear_files;
ret = event->pmu->addr_filters_validate(&filters);
if (ret)
goto fail_free_filters;
/* remove existing filters, if any */
perf_addr_filters_splice(event, &filters);
/* install new filters */
perf_event_for_each_child(event, perf_event_addr_filters_apply);
return ret;
fail_free_filters:
free_filters_list(&filters);
fail_clear_files:
event->addr_filters.nr_file_filters = 0;
return ret;
}
static int perf_event_set_filter(struct perf_event *event, void __user *arg)
{
int ret = -EINVAL;
char *filter_str;
filter_str = strndup_user(arg, PAGE_SIZE);
if (IS_ERR(filter_str))
return PTR_ERR(filter_str);
#ifdef CONFIG_EVENT_TRACING
if (perf_event_is_tracing(event)) {
struct perf_event_context *ctx = event->ctx;
/*
* Beware, here be dragons!!
*
* the tracepoint muck will deadlock against ctx->mutex, but
* the tracepoint stuff does not actually need it. So
* temporarily drop ctx->mutex. As per perf_event_ctx_lock() we
* already have a reference on ctx.
*
* This can result in event getting moved to a different ctx,
* but that does not affect the tracepoint state.
*/
mutex_unlock(&ctx->mutex);
ret = ftrace_profile_set_filter(event, event->attr.config, filter_str);
mutex_lock(&ctx->mutex);
} else
#endif
if (has_addr_filter(event))
ret = perf_event_set_addr_filter(event, filter_str);
kfree(filter_str);
return ret;
}
/*
* hrtimer based swevent callback
*/
static enum hrtimer_restart perf_swevent_hrtimer(struct hrtimer *hrtimer)
{
enum hrtimer_restart ret = HRTIMER_RESTART;
struct perf_sample_data data;
struct pt_regs *regs;
struct perf_event *event;
u64 period;
event = container_of(hrtimer, struct perf_event, hw.hrtimer);
if (event->state != PERF_EVENT_STATE_ACTIVE)
return HRTIMER_NORESTART;
event->pmu->read(event);
perf_sample_data_init(&data, 0, event->hw.last_period);
regs = get_irq_regs();
if (regs && !perf_exclude_event(event, regs)) {
if (!(event->attr.exclude_idle && is_idle_task(current)))
if (__perf_event_overflow(event, 1, &data, regs))
ret = HRTIMER_NORESTART;
}
period = max_t(u64, 10000, event->hw.sample_period);
hrtimer_forward_now(hrtimer, ns_to_ktime(period));
return ret;
}
static void perf_swevent_start_hrtimer(struct perf_event *event)
{
struct hw_perf_event *hwc = &event->hw;
s64 period;
if (!is_sampling_event(event))
return;
period = local64_read(&hwc->period_left);
if (period) {
if (period < 0)
period = 10000;
local64_set(&hwc->period_left, 0);
} else {
period = max_t(u64, 10000, hwc->sample_period);
}
hrtimer_start(&hwc->hrtimer, ns_to_ktime(period),
HRTIMER_MODE_REL_PINNED_HARD);
}
static void perf_swevent_cancel_hrtimer(struct perf_event *event)
{
struct hw_perf_event *hwc = &event->hw;
if (is_sampling_event(event)) {
ktime_t remaining = hrtimer_get_remaining(&hwc->hrtimer);
local64_set(&hwc->period_left, ktime_to_ns(remaining));
hrtimer_cancel(&hwc->hrtimer);
}
}
static void perf_swevent_init_hrtimer(struct perf_event *event)
{
struct hw_perf_event *hwc = &event->hw;
if (!is_sampling_event(event))
return;
hrtimer_init(&hwc->hrtimer, CLOCK_MONOTONIC, HRTIMER_MODE_REL_HARD);
hwc->hrtimer.function = perf_swevent_hrtimer;
/*
* Since hrtimers have a fixed rate, we can do a static freq->period
* mapping and avoid the whole period adjust feedback stuff.
*/
if (event->attr.freq) {
long freq = event->attr.sample_freq;
event->attr.sample_period = NSEC_PER_SEC / freq;
hwc->sample_period = event->attr.sample_period;
local64_set(&hwc->period_left, hwc->sample_period);
hwc->last_period = hwc->sample_period;
event->attr.freq = 0;
}
}
/*
* Software event: cpu wall time clock
*/
static void cpu_clock_event_update(struct perf_event *event)
{
s64 prev;
u64 now;
now = local_clock();
prev = local64_xchg(&event->hw.prev_count, now);
local64_add(now - prev, &event->count);
}
static void cpu_clock_event_start(struct perf_event *event, int flags)
{
local64_set(&event->hw.prev_count, local_clock());
perf_swevent_start_hrtimer(event);
}
static void cpu_clock_event_stop(struct perf_event *event, int flags)
{
perf_swevent_cancel_hrtimer(event);
cpu_clock_event_update(event);
}
static int cpu_clock_event_add(struct perf_event *event, int flags)
{
if (flags & PERF_EF_START)
cpu_clock_event_start(event, flags);
perf_event_update_userpage(event);
return 0;
}
static void cpu_clock_event_del(struct perf_event *event, int flags)
{
cpu_clock_event_stop(event, flags);
}
static void cpu_clock_event_read(struct perf_event *event)
{
cpu_clock_event_update(event);
}
static int cpu_clock_event_init(struct perf_event *event)
{
if (event->attr.type != perf_cpu_clock.type)
return -ENOENT;
if (event->attr.config != PERF_COUNT_SW_CPU_CLOCK)
return -ENOENT;
/*
* no branch sampling for software events
*/
if (has_branch_stack(event))
return -EOPNOTSUPP;
perf_swevent_init_hrtimer(event);
return 0;
}
static struct pmu perf_cpu_clock = {
.task_ctx_nr = perf_sw_context,
.capabilities = PERF_PMU_CAP_NO_NMI,
.dev = PMU_NULL_DEV,
.event_init = cpu_clock_event_init,
.add = cpu_clock_event_add,
.del = cpu_clock_event_del,
.start = cpu_clock_event_start,
.stop = cpu_clock_event_stop,
.read = cpu_clock_event_read,
};
/*
* Software event: task time clock
*/
static void task_clock_event_update(struct perf_event *event, u64 now)
{
u64 prev;
s64 delta;
prev = local64_xchg(&event->hw.prev_count, now);
delta = now - prev;
local64_add(delta, &event->count);
}
static void task_clock_event_start(struct perf_event *event, int flags)
{
local64_set(&event->hw.prev_count, event->ctx->time);
perf_swevent_start_hrtimer(event);
}
static void task_clock_event_stop(struct perf_event *event, int flags)
{
perf_swevent_cancel_hrtimer(event);
task_clock_event_update(event, event->ctx->time);
}
static int task_clock_event_add(struct perf_event *event, int flags)
{
if (flags & PERF_EF_START)
task_clock_event_start(event, flags);
perf_event_update_userpage(event);
return 0;
}
static void task_clock_event_del(struct perf_event *event, int flags)
{
task_clock_event_stop(event, PERF_EF_UPDATE);
}
static void task_clock_event_read(struct perf_event *event)
{
u64 now = perf_clock();
u64 delta = now - event->ctx->timestamp;
u64 time = event->ctx->time + delta;
task_clock_event_update(event, time);
}
static int task_clock_event_init(struct perf_event *event)
{
if (event->attr.type != perf_task_clock.type)
return -ENOENT;
if (event->attr.config != PERF_COUNT_SW_TASK_CLOCK)
return -ENOENT;
/*
* no branch sampling for software events
*/
if (has_branch_stack(event))
return -EOPNOTSUPP;
perf_swevent_init_hrtimer(event);
return 0;
}
static struct pmu perf_task_clock = {
.task_ctx_nr = perf_sw_context,
.capabilities = PERF_PMU_CAP_NO_NMI,
.dev = PMU_NULL_DEV,
.event_init = task_clock_event_init,
.add = task_clock_event_add,
.del = task_clock_event_del,
.start = task_clock_event_start,
.stop = task_clock_event_stop,
.read = task_clock_event_read,
};
static void perf_pmu_nop_void(struct pmu *pmu)
{
}
static void perf_pmu_nop_txn(struct pmu *pmu, unsigned int flags)
{
}
static int perf_pmu_nop_int(struct pmu *pmu)
{
return 0;
}
static int perf_event_nop_int(struct perf_event *event, u64 value)
{
return 0;
}
static DEFINE_PER_CPU(unsigned int, nop_txn_flags);
static void perf_pmu_start_txn(struct pmu *pmu, unsigned int flags)
{
__this_cpu_write(nop_txn_flags, flags);
if (flags & ~PERF_PMU_TXN_ADD)
return;
perf_pmu_disable(pmu);
}
static int perf_pmu_commit_txn(struct pmu *pmu)
{
unsigned int flags = __this_cpu_read(nop_txn_flags);
__this_cpu_write(nop_txn_flags, 0);
if (flags & ~PERF_PMU_TXN_ADD)
return 0;
perf_pmu_enable(pmu);
return 0;
}
static void perf_pmu_cancel_txn(struct pmu *pmu)
{
unsigned int flags = __this_cpu_read(nop_txn_flags);
__this_cpu_write(nop_txn_flags, 0);
if (flags & ~PERF_PMU_TXN_ADD)
return;
perf_pmu_enable(pmu);
}
static int perf_event_idx_default(struct perf_event *event)
{
return 0;
}
static void free_pmu_context(struct pmu *pmu)
{
free_percpu(pmu->cpu_pmu_context);
}
/*
* Let userspace know that this PMU supports address range filtering:
*/
static ssize_t nr_addr_filters_show(struct device *dev,
struct device_attribute *attr,
char *page)
{
struct pmu *pmu = dev_get_drvdata(dev);
return scnprintf(page, PAGE_SIZE - 1, "%d\n", pmu->nr_addr_filters);
}
DEVICE_ATTR_RO(nr_addr_filters);
static struct idr pmu_idr;
static ssize_t
type_show(struct device *dev, struct device_attribute *attr, char *page)
{
struct pmu *pmu = dev_get_drvdata(dev);
return scnprintf(page, PAGE_SIZE - 1, "%d\n", pmu->type);
}
static DEVICE_ATTR_RO(type);
static ssize_t
perf_event_mux_interval_ms_show(struct device *dev,
struct device_attribute *attr,
char *page)
{
struct pmu *pmu = dev_get_drvdata(dev);
return scnprintf(page, PAGE_SIZE - 1, "%d\n", pmu->hrtimer_interval_ms);
}
static DEFINE_MUTEX(mux_interval_mutex);
static ssize_t
perf_event_mux_interval_ms_store(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
struct pmu *pmu = dev_get_drvdata(dev);
int timer, cpu, ret;
ret = kstrtoint(buf, 0, &timer);
if (ret)
return ret;
if (timer < 1)
return -EINVAL;
/* same value, noting to do */
if (timer == pmu->hrtimer_interval_ms)
return count;
mutex_lock(&mux_interval_mutex);
pmu->hrtimer_interval_ms = timer;
/* update all cpuctx for this PMU */
cpus_read_lock();
for_each_online_cpu(cpu) {
struct perf_cpu_pmu_context *cpc;
cpc = per_cpu_ptr(pmu->cpu_pmu_context, cpu);
cpc->hrtimer_interval = ns_to_ktime(NSEC_PER_MSEC * timer);
cpu_function_call(cpu, perf_mux_hrtimer_restart_ipi, cpc);
}
cpus_read_unlock();
mutex_unlock(&mux_interval_mutex);
return count;
}
static DEVICE_ATTR_RW(perf_event_mux_interval_ms);
static struct attribute *pmu_dev_attrs[] = {
&dev_attr_type.attr,
&dev_attr_perf_event_mux_interval_ms.attr,
&dev_attr_nr_addr_filters.attr,
NULL,
};
static umode_t pmu_dev_is_visible(struct kobject *kobj, struct attribute *a, int n)
{
struct device *dev = kobj_to_dev(kobj);
struct pmu *pmu = dev_get_drvdata(dev);
if (n == 2 && !pmu->nr_addr_filters)
return 0;
return a->mode;
}
static struct attribute_group pmu_dev_attr_group = {
.is_visible = pmu_dev_is_visible,
.attrs = pmu_dev_attrs,
};
static const struct attribute_group *pmu_dev_groups[] = {
&pmu_dev_attr_group,
NULL,
};
static int pmu_bus_running;
static struct bus_type pmu_bus = {
.name = "event_source",
.dev_groups = pmu_dev_groups,
};
static void pmu_dev_release(struct device *dev)
{
kfree(dev);
}
static int pmu_dev_alloc(struct pmu *pmu)
{
int ret = -ENOMEM;
pmu->dev = kzalloc(sizeof(struct device), GFP_KERNEL);
if (!pmu->dev)
goto out;
pmu->dev->groups = pmu->attr_groups;
device_initialize(pmu->dev);
dev_set_drvdata(pmu->dev, pmu);
pmu->dev->bus = &pmu_bus;
pmu->dev->parent = pmu->parent;
pmu->dev->release = pmu_dev_release;
ret = dev_set_name(pmu->dev, "%s", pmu->name);
if (ret)
goto free_dev;
ret = device_add(pmu->dev);
if (ret)
goto free_dev;
if (pmu->attr_update) {
ret = sysfs_update_groups(&pmu->dev->kobj, pmu->attr_update);
if (ret)
goto del_dev;
}
out:
return ret;
del_dev:
device_del(pmu->dev);
free_dev:
put_device(pmu->dev);
goto out;
}
static struct lock_class_key cpuctx_mutex;
static struct lock_class_key cpuctx_lock;
int perf_pmu_register(struct pmu *pmu, const char *name, int type)
{
int cpu, ret, max = PERF_TYPE_MAX;
mutex_lock(&pmus_lock);
ret = -ENOMEM;
pmu->pmu_disable_count = alloc_percpu(int);
if (!pmu->pmu_disable_count)
goto unlock;
pmu->type = -1;
if (WARN_ONCE(!name, "Can not register anonymous pmu.\n")) {
ret = -EINVAL;
goto free_pdc;
}
pmu->name = name;
if (type >= 0)
max = type;
ret = idr_alloc(&pmu_idr, pmu, max, 0, GFP_KERNEL);
if (ret < 0)
goto free_pdc;
WARN_ON(type >= 0 && ret != type);
type = ret;
pmu->type = type;
if (pmu_bus_running && !pmu->dev) {
ret = pmu_dev_alloc(pmu);
if (ret)
goto free_idr;
}
ret = -ENOMEM;
pmu->cpu_pmu_context = alloc_percpu(struct perf_cpu_pmu_context);
if (!pmu->cpu_pmu_context)
goto free_dev;
for_each_possible_cpu(cpu) {
struct perf_cpu_pmu_context *cpc;
cpc = per_cpu_ptr(pmu->cpu_pmu_context, cpu);
__perf_init_event_pmu_context(&cpc->epc, pmu);
__perf_mux_hrtimer_init(cpc, cpu);
}
if (!pmu->start_txn) {
if (pmu->pmu_enable) {
/*
* If we have pmu_enable/pmu_disable calls, install
* transaction stubs that use that to try and batch
* hardware accesses.
*/
pmu->start_txn = perf_pmu_start_txn;
pmu->commit_txn = perf_pmu_commit_txn;
pmu->cancel_txn = perf_pmu_cancel_txn;
} else {
pmu->start_txn = perf_pmu_nop_txn;
pmu->commit_txn = perf_pmu_nop_int;
pmu->cancel_txn = perf_pmu_nop_void;
}
}
if (!pmu->pmu_enable) {
pmu->pmu_enable = perf_pmu_nop_void;
pmu->pmu_disable = perf_pmu_nop_void;
}
if (!pmu->check_period)
pmu->check_period = perf_event_nop_int;
if (!pmu->event_idx)
pmu->event_idx = perf_event_idx_default;
list_add_rcu(&pmu->entry, &pmus);
atomic_set(&pmu->exclusive_cnt, 0);
ret = 0;
unlock:
mutex_unlock(&pmus_lock);
return ret;
free_dev:
if (pmu->dev && pmu->dev != PMU_NULL_DEV) {
device_del(pmu->dev);
put_device(pmu->dev);
}
free_idr:
idr_remove(&pmu_idr, pmu->type);
free_pdc:
free_percpu(pmu->pmu_disable_count);
goto unlock;
}
EXPORT_SYMBOL_GPL(perf_pmu_register);
void perf_pmu_unregister(struct pmu *pmu)
{
mutex_lock(&pmus_lock);
list_del_rcu(&pmu->entry);
/*
* We dereference the pmu list under both SRCU and regular RCU, so
* synchronize against both of those.
*/
synchronize_srcu(&pmus_srcu);
synchronize_rcu();
free_percpu(pmu->pmu_disable_count);
idr_remove(&pmu_idr, pmu->type);
if (pmu_bus_running && pmu->dev && pmu->dev != PMU_NULL_DEV) {
if (pmu->nr_addr_filters)
device_remove_file(pmu->dev, &dev_attr_nr_addr_filters);
device_del(pmu->dev);
put_device(pmu->dev);
}
free_pmu_context(pmu);
mutex_unlock(&pmus_lock);
}
EXPORT_SYMBOL_GPL(perf_pmu_unregister);
static inline bool has_extended_regs(struct perf_event *event)
{
return (event->attr.sample_regs_user & PERF_REG_EXTENDED_MASK) ||
(event->attr.sample_regs_intr & PERF_REG_EXTENDED_MASK);
}
static int perf_try_init_event(struct pmu *pmu, struct perf_event *event)
{
struct perf_event_context *ctx = NULL;
int ret;
if (!try_module_get(pmu->module))
return -ENODEV;
/*
* A number of pmu->event_init() methods iterate the sibling_list to,
* for example, validate if the group fits on the PMU. Therefore,
* if this is a sibling event, acquire the ctx->mutex to protect
* the sibling_list.
*/
if (event->group_leader != event && pmu->task_ctx_nr != perf_sw_context) {
/*
* This ctx->mutex can nest when we're called through
* inheritance. See the perf_event_ctx_lock_nested() comment.
*/
ctx = perf_event_ctx_lock_nested(event->group_leader,
SINGLE_DEPTH_NESTING);
BUG_ON(!ctx);
}
event->pmu = pmu;
ret = pmu->event_init(event);
if (ctx)
perf_event_ctx_unlock(event->group_leader, ctx);
if (!ret) {
if (!(pmu->capabilities & PERF_PMU_CAP_EXTENDED_REGS) &&
has_extended_regs(event))
ret = -EOPNOTSUPP;
if (pmu->capabilities & PERF_PMU_CAP_NO_EXCLUDE &&
event_has_any_exclude_flag(event))
ret = -EINVAL;
if (ret && event->destroy)
event->destroy(event);
}
if (ret)
module_put(pmu->module);
return ret;
}
static struct pmu *perf_init_event(struct perf_event *event)
{
bool extended_type = false;
int idx, type, ret;
struct pmu *pmu;
idx = srcu_read_lock(&pmus_srcu);
/*
* Save original type before calling pmu->event_init() since certain
* pmus overwrites event->attr.type to forward event to another pmu.
*/
event->orig_type = event->attr.type;
/* Try parent's PMU first: */
if (event->parent && event->parent->pmu) {
pmu = event->parent->pmu;
ret = perf_try_init_event(pmu, event);
if (!ret)
goto unlock;
}
/*
* PERF_TYPE_HARDWARE and PERF_TYPE_HW_CACHE
* are often aliases for PERF_TYPE_RAW.
*/
type = event->attr.type;
if (type == PERF_TYPE_HARDWARE || type == PERF_TYPE_HW_CACHE) {
type = event->attr.config >> PERF_PMU_TYPE_SHIFT;
if (!type) {
type = PERF_TYPE_RAW;
} else {
extended_type = true;
event->attr.config &= PERF_HW_EVENT_MASK;
}
}
again:
rcu_read_lock();
pmu = idr_find(&pmu_idr, type);
rcu_read_unlock();
if (pmu) {
if (event->attr.type != type && type != PERF_TYPE_RAW &&
!(pmu->capabilities & PERF_PMU_CAP_EXTENDED_HW_TYPE))
goto fail;
ret = perf_try_init_event(pmu, event);
if (ret == -ENOENT && event->attr.type != type && !extended_type) {
type = event->attr.type;
goto again;
}
if (ret)
pmu = ERR_PTR(ret);
goto unlock;
}
list_for_each_entry_rcu(pmu, &pmus, entry, lockdep_is_held(&pmus_srcu)) {
ret = perf_try_init_event(pmu, event);
if (!ret)
goto unlock;
if (ret != -ENOENT) {
pmu = ERR_PTR(ret);
goto unlock;
}
}
fail:
pmu = ERR_PTR(-ENOENT);
unlock:
srcu_read_unlock(&pmus_srcu, idx);
return pmu;
}
static void attach_sb_event(struct perf_event *event)
{
struct pmu_event_list *pel = per_cpu_ptr(&pmu_sb_events, event->cpu);
raw_spin_lock(&pel->lock);
list_add_rcu(&event->sb_list, &pel->list);
raw_spin_unlock(&pel->lock);
}
/*
* We keep a list of all !task (and therefore per-cpu) events
* that need to receive side-band records.
*
* This avoids having to scan all the various PMU per-cpu contexts
* looking for them.
*/
static void account_pmu_sb_event(struct perf_event *event)
{
if (is_sb_event(event))
attach_sb_event(event);
}
/* Freq events need the tick to stay alive (see perf_event_task_tick). */
static void account_freq_event_nohz(void)
{
#ifdef CONFIG_NO_HZ_FULL
/* Lock so we don't race with concurrent unaccount */
spin_lock(&nr_freq_lock);
if (atomic_inc_return(&nr_freq_events) == 1)
tick_nohz_dep_set(TICK_DEP_BIT_PERF_EVENTS);
spin_unlock(&nr_freq_lock);
#endif
}
static void account_freq_event(void)
{
if (tick_nohz_full_enabled())
account_freq_event_nohz();
else
atomic_inc(&nr_freq_events);
}
static void account_event(struct perf_event *event)
{
bool inc = false;
if (event->parent)
return;
if (event->attach_state & (PERF_ATTACH_TASK | PERF_ATTACH_SCHED_CB))
inc = true;
if (event->attr.mmap || event->attr.mmap_data)
atomic_inc(&nr_mmap_events);
if (event->attr.build_id)
atomic_inc(&nr_build_id_events);
if (event->attr.comm)
atomic_inc(&nr_comm_events);
if (event->attr.namespaces)
atomic_inc(&nr_namespaces_events);
if (event->attr.cgroup)
atomic_inc(&nr_cgroup_events);
if (event->attr.task)
atomic_inc(&nr_task_events);
if (event->attr.freq)
account_freq_event();
if (event->attr.context_switch) {
atomic_inc(&nr_switch_events);
inc = true;
}
if (has_branch_stack(event))
inc = true;
if (is_cgroup_event(event))
inc = true;
if (event->attr.ksymbol)
atomic_inc(&nr_ksymbol_events);
if (event->attr.bpf_event)
atomic_inc(&nr_bpf_events);
if (event->attr.text_poke)
atomic_inc(&nr_text_poke_events);
if (inc) {
/*
* We need the mutex here because static_branch_enable()
* must complete *before* the perf_sched_count increment
* becomes visible.
*/
if (atomic_inc_not_zero(&perf_sched_count))
goto enabled;
mutex_lock(&perf_sched_mutex);
if (!atomic_read(&perf_sched_count)) {
static_branch_enable(&perf_sched_events);
/*
* Guarantee that all CPUs observe they key change and
* call the perf scheduling hooks before proceeding to
* install events that need them.
*/
synchronize_rcu();
}
/*
* Now that we have waited for the sync_sched(), allow further
* increments to by-pass the mutex.
*/
atomic_inc(&perf_sched_count);
mutex_unlock(&perf_sched_mutex);
}
enabled:
account_pmu_sb_event(event);
}
/*
* Allocate and initialize an event structure
*/
static struct perf_event *
perf_event_alloc(struct perf_event_attr *attr, int cpu,
struct task_struct *task,
struct perf_event *group_leader,
struct perf_event *parent_event,
perf_overflow_handler_t overflow_handler,
void *context, int cgroup_fd)
{
struct pmu *pmu;
struct perf_event *event;
struct hw_perf_event *hwc;
long err = -EINVAL;
int node;
if ((unsigned)cpu >= nr_cpu_ids) {
if (!task || cpu != -1)
return ERR_PTR(-EINVAL);
}
if (attr->sigtrap && !task) {
/* Requires a task: avoid signalling random tasks. */
return ERR_PTR(-EINVAL);
}
node = (cpu >= 0) ? cpu_to_node(cpu) : -1;
event = kmem_cache_alloc_node(perf_event_cache, GFP_KERNEL | __GFP_ZERO,
node);
if (!event)
return ERR_PTR(-ENOMEM);
/*
* Single events are their own group leaders, with an
* empty sibling list:
*/
if (!group_leader)
group_leader = event;
mutex_init(&event->child_mutex);
INIT_LIST_HEAD(&event->child_list);
INIT_LIST_HEAD(&event->event_entry);
INIT_LIST_HEAD(&event->sibling_list);
INIT_LIST_HEAD(&event->active_list);
init_event_group(event);
INIT_LIST_HEAD(&event->rb_entry);
INIT_LIST_HEAD(&event->active_entry);
INIT_LIST_HEAD(&event->addr_filters.list);
INIT_HLIST_NODE(&event->hlist_entry);
init_waitqueue_head(&event->waitq);
init_irq_work(&event->pending_irq, perf_pending_irq);
init_task_work(&event->pending_task, perf_pending_task);
mutex_init(&event->mmap_mutex);
raw_spin_lock_init(&event->addr_filters.lock);
atomic_long_set(&event->refcount, 1);
event->cpu = cpu;
event->attr = *attr;
event->group_leader = group_leader;
event->pmu = NULL;
event->oncpu = -1;
event->parent = parent_event;
event->ns = get_pid_ns(task_active_pid_ns(current));
event->id = atomic64_inc_return(&perf_event_id);
event->state = PERF_EVENT_STATE_INACTIVE;
if (parent_event)
event->event_caps = parent_event->event_caps;
if (task) {
event->attach_state = PERF_ATTACH_TASK;
/*
* XXX pmu::event_init needs to know what task to account to
* and we cannot use the ctx information because we need the
* pmu before we get a ctx.
*/
event->hw.target = get_task_struct(task);
}
event->clock = &local_clock;
if (parent_event)
event->clock = parent_event->clock;
if (!overflow_handler && parent_event) {
overflow_handler = parent_event->overflow_handler;
context = parent_event->overflow_handler_context;
#if defined(CONFIG_BPF_SYSCALL) && defined(CONFIG_EVENT_TRACING)
if (overflow_handler == bpf_overflow_handler) {
struct bpf_prog *prog = parent_event->prog;
bpf_prog_inc(prog);
event->prog = prog;
event->orig_overflow_handler =
parent_event->orig_overflow_handler;
}
#endif
}
if (overflow_handler) {
event->overflow_handler = overflow_handler;
event->overflow_handler_context = context;
} else if (is_write_backward(event)){
event->overflow_handler = perf_event_output_backward;
event->overflow_handler_context = NULL;
} else {
event->overflow_handler = perf_event_output_forward;
event->overflow_handler_context = NULL;
}
perf_event__state_init(event);
pmu = NULL;
hwc = &event->hw;
hwc->sample_period = attr->sample_period;
if (attr->freq && attr->sample_freq)
hwc->sample_period = 1;
hwc->last_period = hwc->sample_period;
local64_set(&hwc->period_left, hwc->sample_period);
/*
* We currently do not support PERF_SAMPLE_READ on inherited events.
* See perf_output_read().
*/
if (attr->inherit && (attr->sample_type & PERF_SAMPLE_READ))
goto err_ns;
if (!has_branch_stack(event))
event->attr.branch_sample_type = 0;
pmu = perf_init_event(event);
if (IS_ERR(pmu)) {
err = PTR_ERR(pmu);
goto err_ns;
}
/*
* Disallow uncore-task events. Similarly, disallow uncore-cgroup
* events (they don't make sense as the cgroup will be different
* on other CPUs in the uncore mask).
*/
if (pmu->task_ctx_nr == perf_invalid_context && (task || cgroup_fd != -1)) {
err = -EINVAL;
goto err_pmu;
}
if (event->attr.aux_output &&
!(pmu->capabilities & PERF_PMU_CAP_AUX_OUTPUT)) {
err = -EOPNOTSUPP;
goto err_pmu;
}
if (cgroup_fd != -1) {
err = perf_cgroup_connect(cgroup_fd, event, attr, group_leader);
if (err)
goto err_pmu;
}
err = exclusive_event_init(event);
if (err)
goto err_pmu;
if (has_addr_filter(event)) {
event->addr_filter_ranges = kcalloc(pmu->nr_addr_filters,
sizeof(struct perf_addr_filter_range),
GFP_KERNEL);
if (!event->addr_filter_ranges) {
err = -ENOMEM;
goto err_per_task;
}
/*
* Clone the parent's vma offsets: they are valid until exec()
* even if the mm is not shared with the parent.
*/
if (event->parent) {
struct perf_addr_filters_head *ifh = perf_event_addr_filters(event);
raw_spin_lock_irq(&ifh->lock);
memcpy(event->addr_filter_ranges,
event->parent->addr_filter_ranges,
pmu->nr_addr_filters * sizeof(struct perf_addr_filter_range));
raw_spin_unlock_irq(&ifh->lock);
}
/* force hw sync on the address filters */
event->addr_filters_gen = 1;
}
if (!event->parent) {
if (event->attr.sample_type & PERF_SAMPLE_CALLCHAIN) {
err = get_callchain_buffers(attr->sample_max_stack);
if (err)
goto err_addr_filters;
}
}
err = security_perf_event_alloc(event);
if (err)
goto err_callchain_buffer;
/* symmetric to unaccount_event() in _free_event() */
account_event(event);
return event;
err_callchain_buffer:
if (!event->parent) {
if (event->attr.sample_type & PERF_SAMPLE_CALLCHAIN)
put_callchain_buffers();
}
err_addr_filters:
kfree(event->addr_filter_ranges);
err_per_task:
exclusive_event_destroy(event);
err_pmu:
if (is_cgroup_event(event))
perf_detach_cgroup(event);
if (event->destroy)
event->destroy(event);
module_put(pmu->module);
err_ns:
if (event->hw.target)
put_task_struct(event->hw.target);
call_rcu(&event->rcu_head, free_event_rcu);
return ERR_PTR(err);
}
static int perf_copy_attr(struct perf_event_attr __user *uattr,
struct perf_event_attr *attr)
{
u32 size;
int ret;
/* Zero the full structure, so that a short copy will be nice. */
memset(attr, 0, sizeof(*attr));
ret = get_user(size, &uattr->size);
if (ret)
return ret;
/* ABI compatibility quirk: */
if (!size)
size = PERF_ATTR_SIZE_VER0;
if (size < PERF_ATTR_SIZE_VER0 || size > PAGE_SIZE)
goto err_size;
ret = copy_struct_from_user(attr, sizeof(*attr), uattr, size);
if (ret) {
if (ret == -E2BIG)
goto err_size;
return ret;
}
attr->size = size;
if (attr->__reserved_1 || attr->__reserved_2 || attr->__reserved_3)
return -EINVAL;
if (attr->sample_type & ~(PERF_SAMPLE_MAX-1))
return -EINVAL;
if (attr->read_format & ~(PERF_FORMAT_MAX-1))
return -EINVAL;
if (attr->sample_type & PERF_SAMPLE_BRANCH_STACK) {
u64 mask = attr->branch_sample_type;
/* only using defined bits */
if (mask & ~(PERF_SAMPLE_BRANCH_MAX-1))
return -EINVAL;
/* at least one branch bit must be set */
if (!(mask & ~PERF_SAMPLE_BRANCH_PLM_ALL))
return -EINVAL;
/* propagate priv level, when not set for branch */
if (!(mask & PERF_SAMPLE_BRANCH_PLM_ALL)) {
/* exclude_kernel checked on syscall entry */
if (!attr->exclude_kernel)
mask |= PERF_SAMPLE_BRANCH_KERNEL;
if (!attr->exclude_user)
mask |= PERF_SAMPLE_BRANCH_USER;
if (!attr->exclude_hv)
mask |= PERF_SAMPLE_BRANCH_HV;
/*
* adjust user setting (for HW filter setup)
*/
attr->branch_sample_type = mask;
}
/* privileged levels capture (kernel, hv): check permissions */
if (mask & PERF_SAMPLE_BRANCH_PERM_PLM) {
ret = perf_allow_kernel(attr);
if (ret)
return ret;
}
}
if (attr->sample_type & PERF_SAMPLE_REGS_USER) {
ret = perf_reg_validate(attr->sample_regs_user);
if (ret)
return ret;
}
if (attr->sample_type & PERF_SAMPLE_STACK_USER) {
if (!arch_perf_have_user_stack_dump())
return -ENOSYS;
/*
* We have __u32 type for the size, but so far
* we can only use __u16 as maximum due to the
* __u16 sample size limit.
*/
if (attr->sample_stack_user >= USHRT_MAX)
return -EINVAL;
else if (!IS_ALIGNED(attr->sample_stack_user, sizeof(u64)))
return -EINVAL;
}
if (!attr->sample_max_stack)
attr->sample_max_stack = sysctl_perf_event_max_stack;
if (attr->sample_type & PERF_SAMPLE_REGS_INTR)
ret = perf_reg_validate(attr->sample_regs_intr);
#ifndef CONFIG_CGROUP_PERF
if (attr->sample_type & PERF_SAMPLE_CGROUP)
return -EINVAL;
#endif
if ((attr->sample_type & PERF_SAMPLE_WEIGHT) &&
(attr->sample_type & PERF_SAMPLE_WEIGHT_STRUCT))
return -EINVAL;
if (!attr->inherit && attr->inherit_thread)
return -EINVAL;
if (attr->remove_on_exec && attr->enable_on_exec)
return -EINVAL;
if (attr->sigtrap && !attr->remove_on_exec)
return -EINVAL;
out:
return ret;
err_size:
put_user(sizeof(*attr), &uattr->size);
ret = -E2BIG;
goto out;
}
static void mutex_lock_double(struct mutex *a, struct mutex *b)
{
if (b < a)
swap(a, b);
mutex_lock(a);
mutex_lock_nested(b, SINGLE_DEPTH_NESTING);
}
static int
perf_event_set_output(struct perf_event *event, struct perf_event *output_event)
{
struct perf_buffer *rb = NULL;
int ret = -EINVAL;
if (!output_event) {
mutex_lock(&event->mmap_mutex);
goto set;
}
/* don't allow circular references */
if (event == output_event)
goto out;
/*
* Don't allow cross-cpu buffers
*/
if (output_event->cpu != event->cpu)
goto out;
/*
* If its not a per-cpu rb, it must be the same task.
*/
if (output_event->cpu == -1 && output_event->hw.target != event->hw.target)
goto out;
/*
* Mixing clocks in the same buffer is trouble you don't need.
*/
if (output_event->clock != event->clock)
goto out;
/*
* Either writing ring buffer from beginning or from end.
* Mixing is not allowed.
*/
if (is_write_backward(output_event) != is_write_backward(event))
goto out;
/*
* If both events generate aux data, they must be on the same PMU
*/
if (has_aux(event) && has_aux(output_event) &&
event->pmu != output_event->pmu)
goto out;
/*
* Hold both mmap_mutex to serialize against perf_mmap_close(). Since
* output_event is already on rb->event_list, and the list iteration
* restarts after every removal, it is guaranteed this new event is
* observed *OR* if output_event is already removed, it's guaranteed we
* observe !rb->mmap_count.
*/
mutex_lock_double(&event->mmap_mutex, &output_event->mmap_mutex);
set:
/* Can't redirect output if we've got an active mmap() */
if (atomic_read(&event->mmap_count))
goto unlock;
if (output_event) {
/* get the rb we want to redirect to */
rb = ring_buffer_get(output_event);
if (!rb)
goto unlock;
/* did we race against perf_mmap_close() */
if (!atomic_read(&rb->mmap_count)) {
ring_buffer_put(rb);
goto unlock;
}
}
ring_buffer_attach(event, rb);
ret = 0;
unlock:
mutex_unlock(&event->mmap_mutex);
if (output_event)
mutex_unlock(&output_event->mmap_mutex);
out:
return ret;
}
static int perf_event_set_clock(struct perf_event *event, clockid_t clk_id)
{
bool nmi_safe = false;
switch (clk_id) {
case CLOCK_MONOTONIC:
event->clock = &ktime_get_mono_fast_ns;
nmi_safe = true;
break;
case CLOCK_MONOTONIC_RAW:
event->clock = &ktime_get_raw_fast_ns;
nmi_safe = true;
break;
case CLOCK_REALTIME:
event->clock = &ktime_get_real_ns;
break;
case CLOCK_BOOTTIME:
event->clock = &ktime_get_boottime_ns;
break;
case CLOCK_TAI:
event->clock = &ktime_get_clocktai_ns;
break;
default:
return -EINVAL;
}
if (!nmi_safe && !(event->pmu->capabilities & PERF_PMU_CAP_NO_NMI))
return -EINVAL;
return 0;
}
static bool
perf_check_permission(struct perf_event_attr *attr, struct task_struct *task)
{
unsigned int ptrace_mode = PTRACE_MODE_READ_REALCREDS;
bool is_capable = perfmon_capable();
if (attr->sigtrap) {
/*
* perf_event_attr::sigtrap sends signals to the other task.
* Require the current task to also have CAP_KILL.
*/
rcu_read_lock();
is_capable &= ns_capable(__task_cred(task)->user_ns, CAP_KILL);
rcu_read_unlock();
/*
* If the required capabilities aren't available, checks for
* ptrace permissions: upgrade to ATTACH, since sending signals
* can effectively change the target task.
*/
ptrace_mode = PTRACE_MODE_ATTACH_REALCREDS;
}
/*
* Preserve ptrace permission check for backwards compatibility. The
* ptrace check also includes checks that the current task and other
* task have matching uids, and is therefore not done here explicitly.
*/
return is_capable || ptrace_may_access(task, ptrace_mode);
}
/**
* sys_perf_event_open - open a performance event, associate it to a task/cpu
*
* @attr_uptr: event_id type attributes for monitoring/sampling
* @pid: target pid
* @cpu: target cpu
* @group_fd: group leader event fd
* @flags: perf event open flags
*/
SYSCALL_DEFINE5(perf_event_open,
struct perf_event_attr __user *, attr_uptr,
pid_t, pid, int, cpu, int, group_fd, unsigned long, flags)
{
struct perf_event *group_leader = NULL, *output_event = NULL;
struct perf_event_pmu_context *pmu_ctx;
struct perf_event *event, *sibling;
struct perf_event_attr attr;
struct perf_event_context *ctx;
struct file *event_file = NULL;
struct fd group = {NULL, 0};
struct task_struct *task = NULL;
struct pmu *pmu;
int event_fd;
int move_group = 0;
int err;
int f_flags = O_RDWR;
int cgroup_fd = -1;
/* for future expandability... */
if (flags & ~PERF_FLAG_ALL)
return -EINVAL;
err = perf_copy_attr(attr_uptr, &attr);
if (err)
return err;
/* Do we allow access to perf_event_open(2) ? */
err = security_perf_event_open(&attr, PERF_SECURITY_OPEN);
if (err)
return err;
if (!attr.exclude_kernel) {
err = perf_allow_kernel(&attr);
if (err)
return err;
}
if (attr.namespaces) {
if (!perfmon_capable())
return -EACCES;
}
if (attr.freq) {
if (attr.sample_freq > sysctl_perf_event_sample_rate)
return -EINVAL;
} else {
if (attr.sample_period & (1ULL << 63))
return -EINVAL;
}
/* Only privileged users can get physical addresses */
if ((attr.sample_type & PERF_SAMPLE_PHYS_ADDR)) {
err = perf_allow_kernel(&attr);
if (err)
return err;
}
/* REGS_INTR can leak data, lockdown must prevent this */
if (attr.sample_type & PERF_SAMPLE_REGS_INTR) {
err = security_locked_down(LOCKDOWN_PERF);
if (err)
return err;
}
/*
* In cgroup mode, the pid argument is used to pass the fd
* opened to the cgroup directory in cgroupfs. The cpu argument
* designates the cpu on which to monitor threads from that
* cgroup.
*/
if ((flags & PERF_FLAG_PID_CGROUP) && (pid == -1 || cpu == -1))
return -EINVAL;
if (flags & PERF_FLAG_FD_CLOEXEC)
f_flags |= O_CLOEXEC;
event_fd = get_unused_fd_flags(f_flags);
if (event_fd < 0)
return event_fd;
if (group_fd != -1) {
err = perf_fget_light(group_fd, &group);
if (err)
goto err_fd;
group_leader = group.file->private_data;
if (flags & PERF_FLAG_FD_OUTPUT)
output_event = group_leader;
if (flags & PERF_FLAG_FD_NO_GROUP)
group_leader = NULL;
}
if (pid != -1 && !(flags & PERF_FLAG_PID_CGROUP)) {
task = find_lively_task_by_vpid(pid);
if (IS_ERR(task)) {
err = PTR_ERR(task);
goto err_group_fd;
}
}
if (task && group_leader &&
group_leader->attr.inherit != attr.inherit) {
err = -EINVAL;
goto err_task;
}
if (flags & PERF_FLAG_PID_CGROUP)
cgroup_fd = pid;
event = perf_event_alloc(&attr, cpu, task, group_leader, NULL,
NULL, NULL, cgroup_fd);
if (IS_ERR(event)) {
err = PTR_ERR(event);
goto err_task;
}
if (is_sampling_event(event)) {
if (event->pmu->capabilities & PERF_PMU_CAP_NO_INTERRUPT) {
err = -EOPNOTSUPP;
goto err_alloc;
}
}
/*
* Special case software events and allow them to be part of
* any hardware group.
*/
pmu = event->pmu;
if (attr.use_clockid) {
err = perf_event_set_clock(event, attr.clockid);
if (err)
goto err_alloc;
}
if (pmu->task_ctx_nr == perf_sw_context)
event->event_caps |= PERF_EV_CAP_SOFTWARE;
if (task) {
err = down_read_interruptible(&task->signal->exec_update_lock);
if (err)
goto err_alloc;
/*
* We must hold exec_update_lock across this and any potential
* perf_install_in_context() call for this new event to
* serialize against exec() altering our credentials (and the
* perf_event_exit_task() that could imply).
*/
err = -EACCES;
if (!perf_check_permission(&attr, task))
goto err_cred;
}
/*
* Get the target context (task or percpu):
*/
ctx = find_get_context(task, event);
if (IS_ERR(ctx)) {
err = PTR_ERR(ctx);
goto err_cred;
}
mutex_lock(&ctx->mutex);
if (ctx->task == TASK_TOMBSTONE) {
err = -ESRCH;
goto err_locked;
}
if (!task) {
/*
* Check if the @cpu we're creating an event for is online.
*
* We use the perf_cpu_context::ctx::mutex to serialize against
* the hotplug notifiers. See perf_event_{init,exit}_cpu().
*/
struct perf_cpu_context *cpuctx = per_cpu_ptr(&perf_cpu_context, event->cpu);
if (!cpuctx->online) {
err = -ENODEV;
goto err_locked;
}
}
if (group_leader) {
err = -EINVAL;
/*
* Do not allow a recursive hierarchy (this new sibling
* becoming part of another group-sibling):
*/
if (group_leader->group_leader != group_leader)
goto err_locked;
/* All events in a group should have the same clock */
if (group_leader->clock != event->clock)
goto err_locked;
/*
* Make sure we're both events for the same CPU;
* grouping events for different CPUs is broken; since
* you can never concurrently schedule them anyhow.
*/
if (group_leader->cpu != event->cpu)
goto err_locked;
/*
* Make sure we're both on the same context; either task or cpu.
*/
if (group_leader->ctx != ctx)
goto err_locked;
/*
* Only a group leader can be exclusive or pinned
*/
if (attr.exclusive || attr.pinned)
goto err_locked;
if (is_software_event(event) &&
!in_software_context(group_leader)) {
/*
* If the event is a sw event, but the group_leader
* is on hw context.
*
* Allow the addition of software events to hw
* groups, this is safe because software events
* never fail to schedule.
*
* Note the comment that goes with struct
* perf_event_pmu_context.
*/
pmu = group_leader->pmu_ctx->pmu;
} else if (!is_software_event(event)) {
if (is_software_event(group_leader) &&
(group_leader->group_caps & PERF_EV_CAP_SOFTWARE)) {
/*
* In case the group is a pure software group, and we
* try to add a hardware event, move the whole group to
* the hardware context.
*/
move_group = 1;
}
/* Don't allow group of multiple hw events from different pmus */
if (!in_software_context(group_leader) &&
group_leader->pmu_ctx->pmu != pmu)
goto err_locked;
}
}
/*
* Now that we're certain of the pmu; find the pmu_ctx.
*/
pmu_ctx = find_get_pmu_context(pmu, ctx, event);
if (IS_ERR(pmu_ctx)) {
err = PTR_ERR(pmu_ctx);
goto err_locked;
}
event->pmu_ctx = pmu_ctx;
if (output_event) {
err = perf_event_set_output(event, output_event);
if (err)
goto err_context;
}
if (!perf_event_validate_size(event)) {
err = -E2BIG;
goto err_context;
}
if (perf_need_aux_event(event) && !perf_get_aux_event(event, group_leader)) {
err = -EINVAL;
goto err_context;
}
/*
* Must be under the same ctx::mutex as perf_install_in_context(),
* because we need to serialize with concurrent event creation.
*/
if (!exclusive_event_installable(event, ctx)) {
err = -EBUSY;
goto err_context;
}
WARN_ON_ONCE(ctx->parent_ctx);
event_file = anon_inode_getfile("[perf_event]", &perf_fops, event, f_flags);
if (IS_ERR(event_file)) {
err = PTR_ERR(event_file);
event_file = NULL;
goto err_context;
}
/*
* This is the point on no return; we cannot fail hereafter. This is
* where we start modifying current state.
*/
if (move_group) {
perf_remove_from_context(group_leader, 0);
put_pmu_ctx(group_leader->pmu_ctx);
for_each_sibling_event(sibling, group_leader) {
perf_remove_from_context(sibling, 0);
put_pmu_ctx(sibling->pmu_ctx);
}
/*
* Install the group siblings before the group leader.
*
* Because a group leader will try and install the entire group
* (through the sibling list, which is still in-tact), we can
* end up with siblings installed in the wrong context.
*
* By installing siblings first we NO-OP because they're not
* reachable through the group lists.
*/
for_each_sibling_event(sibling, group_leader) {
sibling->pmu_ctx = pmu_ctx;
get_pmu_ctx(pmu_ctx);
perf_event__state_init(sibling);
perf_install_in_context(ctx, sibling, sibling->cpu);
}
/*
* Removing from the context ends up with disabled
* event. What we want here is event in the initial
* startup state, ready to be add into new context.
*/
group_leader->pmu_ctx = pmu_ctx;
get_pmu_ctx(pmu_ctx);
perf_event__state_init(group_leader);
perf_install_in_context(ctx, group_leader, group_leader->cpu);
}
/*
* Precalculate sample_data sizes; do while holding ctx::mutex such
* that we're serialized against further additions and before
* perf_install_in_context() which is the point the event is active and
* can use these values.
*/
perf_event__header_size(event);
perf_event__id_header_size(event);
event->owner = current;
perf_install_in_context(ctx, event, event->cpu);
perf_unpin_context(ctx);
mutex_unlock(&ctx->mutex);
if (task) {
up_read(&task->signal->exec_update_lock);
put_task_struct(task);
}
mutex_lock(&current->perf_event_mutex);
list_add_tail(&event->owner_entry, &current->perf_event_list);
mutex_unlock(&current->perf_event_mutex);
/*
* Drop the reference on the group_event after placing the
* new event on the sibling_list. This ensures destruction
* of the group leader will find the pointer to itself in
* perf_group_detach().
*/
fdput(group);
fd_install(event_fd, event_file);
return event_fd;
err_context:
put_pmu_ctx(event->pmu_ctx);
event->pmu_ctx = NULL; /* _free_event() */
err_locked:
mutex_unlock(&ctx->mutex);
perf_unpin_context(ctx);
put_ctx(ctx);
err_cred:
if (task)
up_read(&task->signal->exec_update_lock);
err_alloc:
free_event(event);
err_task:
if (task)
put_task_struct(task);
err_group_fd:
fdput(group);
err_fd:
put_unused_fd(event_fd);
return err;
}
/**
* perf_event_create_kernel_counter
*
* @attr: attributes of the counter to create
* @cpu: cpu in which the counter is bound
* @task: task to profile (NULL for percpu)
* @overflow_handler: callback to trigger when we hit the event
* @context: context data could be used in overflow_handler callback
*/
struct perf_event *
perf_event_create_kernel_counter(struct perf_event_attr *attr, int cpu,
struct task_struct *task,
perf_overflow_handler_t overflow_handler,
void *context)
{
struct perf_event_pmu_context *pmu_ctx;
struct perf_event_context *ctx;
struct perf_event *event;
struct pmu *pmu;
int err;
/*
* Grouping is not supported for kernel events, neither is 'AUX',
* make sure the caller's intentions are adjusted.
*/
if (attr->aux_output)
return ERR_PTR(-EINVAL);
event = perf_event_alloc(attr, cpu, task, NULL, NULL,
overflow_handler, context, -1);
if (IS_ERR(event)) {
err = PTR_ERR(event);
goto err;
}
/* Mark owner so we could distinguish it from user events. */
event->owner = TASK_TOMBSTONE;
pmu = event->pmu;
if (pmu->task_ctx_nr == perf_sw_context)
event->event_caps |= PERF_EV_CAP_SOFTWARE;
/*
* Get the target context (task or percpu):
*/
ctx = find_get_context(task, event);
if (IS_ERR(ctx)) {
err = PTR_ERR(ctx);
goto err_alloc;
}
WARN_ON_ONCE(ctx->parent_ctx);
mutex_lock(&ctx->mutex);
if (ctx->task == TASK_TOMBSTONE) {
err = -ESRCH;
goto err_unlock;
}
pmu_ctx = find_get_pmu_context(pmu, ctx, event);
if (IS_ERR(pmu_ctx)) {
err = PTR_ERR(pmu_ctx);
goto err_unlock;
}
event->pmu_ctx = pmu_ctx;
if (!task) {
/*
* Check if the @cpu we're creating an event for is online.
*
* We use the perf_cpu_context::ctx::mutex to serialize against
* the hotplug notifiers. See perf_event_{init,exit}_cpu().
*/
struct perf_cpu_context *cpuctx =
container_of(ctx, struct perf_cpu_context, ctx);
if (!cpuctx->online) {
err = -ENODEV;
goto err_pmu_ctx;
}
}
if (!exclusive_event_installable(event, ctx)) {
err = -EBUSY;
goto err_pmu_ctx;
}
perf_install_in_context(ctx, event, event->cpu);
perf_unpin_context(ctx);
mutex_unlock(&ctx->mutex);
return event;
err_pmu_ctx:
put_pmu_ctx(pmu_ctx);
event->pmu_ctx = NULL; /* _free_event() */
err_unlock:
mutex_unlock(&ctx->mutex);
perf_unpin_context(ctx);
put_ctx(ctx);
err_alloc:
free_event(event);
err:
return ERR_PTR(err);
}
EXPORT_SYMBOL_GPL(perf_event_create_kernel_counter);
static void __perf_pmu_remove(struct perf_event_context *ctx,
int cpu, struct pmu *pmu,
struct perf_event_groups *groups,
struct list_head *events)
{
struct perf_event *event, *sibling;
perf_event_groups_for_cpu_pmu(event, groups, cpu, pmu) {
perf_remove_from_context(event, 0);
put_pmu_ctx(event->pmu_ctx);
list_add(&event->migrate_entry, events);
for_each_sibling_event(sibling, event) {
perf_remove_from_context(sibling, 0);
put_pmu_ctx(sibling->pmu_ctx);
list_add(&sibling->migrate_entry, events);
}
}
}
static void __perf_pmu_install_event(struct pmu *pmu,
struct perf_event_context *ctx,
int cpu, struct perf_event *event)
{
struct perf_event_pmu_context *epc;
struct perf_event_context *old_ctx = event->ctx;
get_ctx(ctx); /* normally find_get_context() */
event->cpu = cpu;
epc = find_get_pmu_context(pmu, ctx, event);
event->pmu_ctx = epc;
if (event->state >= PERF_EVENT_STATE_OFF)
event->state = PERF_EVENT_STATE_INACTIVE;
perf_install_in_context(ctx, event, cpu);
/*
* Now that event->ctx is updated and visible, put the old ctx.
*/
put_ctx(old_ctx);
}
static void __perf_pmu_install(struct perf_event_context *ctx,
int cpu, struct pmu *pmu, struct list_head *events)
{
struct perf_event *event, *tmp;
/*
* Re-instate events in 2 passes.
*
* Skip over group leaders and only install siblings on this first
* pass, siblings will not get enabled without a leader, however a
* leader will enable its siblings, even if those are still on the old
* context.
*/
list_for_each_entry_safe(event, tmp, events, migrate_entry) {
if (event->group_leader == event)
continue;
list_del(&event->migrate_entry);
__perf_pmu_install_event(pmu, ctx, cpu, event);
}
/*
* Once all the siblings are setup properly, install the group leaders
* to make it go.
*/
list_for_each_entry_safe(event, tmp, events, migrate_entry) {
list_del(&event->migrate_entry);
__perf_pmu_install_event(pmu, ctx, cpu, event);
}
}
void perf_pmu_migrate_context(struct pmu *pmu, int src_cpu, int dst_cpu)
{
struct perf_event_context *src_ctx, *dst_ctx;
LIST_HEAD(events);
/*
* Since per-cpu context is persistent, no need to grab an extra
* reference.
*/
src_ctx = &per_cpu_ptr(&perf_cpu_context, src_cpu)->ctx;
dst_ctx = &per_cpu_ptr(&perf_cpu_context, dst_cpu)->ctx;
/*
* See perf_event_ctx_lock() for comments on the details
* of swizzling perf_event::ctx.
*/
mutex_lock_double(&src_ctx->mutex, &dst_ctx->mutex);
__perf_pmu_remove(src_ctx, src_cpu, pmu, &src_ctx->pinned_groups, &events);
__perf_pmu_remove(src_ctx, src_cpu, pmu, &src_ctx->flexible_groups, &events);
if (!list_empty(&events)) {
/*
* Wait for the events to quiesce before re-instating them.
*/
synchronize_rcu();
__perf_pmu_install(dst_ctx, dst_cpu, pmu, &events);
}
mutex_unlock(&dst_ctx->mutex);
mutex_unlock(&src_ctx->mutex);
}
EXPORT_SYMBOL_GPL(perf_pmu_migrate_context);
static void sync_child_event(struct perf_event *child_event)
{
struct perf_event *parent_event = child_event->parent;
u64 child_val;
if (child_event->attr.inherit_stat) {
struct task_struct *task = child_event->ctx->task;
if (task && task != TASK_TOMBSTONE)
perf_event_read_event(child_event, task);
}
child_val = perf_event_count(child_event);
/*
* Add back the child's count to the parent's count:
*/
atomic64_add(child_val, &parent_event->child_count);
atomic64_add(child_event->total_time_enabled,
&parent_event->child_total_time_enabled);
atomic64_add(child_event->total_time_running,
&parent_event->child_total_time_running);
}
static void
perf_event_exit_event(struct perf_event *event, struct perf_event_context *ctx)
{
struct perf_event *parent_event = event->parent;
unsigned long detach_flags = 0;
if (parent_event) {
/*
* Do not destroy the 'original' grouping; because of the
* context switch optimization the original events could've
* ended up in a random child task.
*
* If we were to destroy the original group, all group related
* operations would cease to function properly after this
* random child dies.
*
* Do destroy all inherited groups, we don't care about those
* and being thorough is better.
*/
detach_flags = DETACH_GROUP | DETACH_CHILD;
mutex_lock(&parent_event->child_mutex);
}
perf_remove_from_context(event, detach_flags);
raw_spin_lock_irq(&ctx->lock);
if (event->state > PERF_EVENT_STATE_EXIT)
perf_event_set_state(event, PERF_EVENT_STATE_EXIT);
raw_spin_unlock_irq(&ctx->lock);
/*
* Child events can be freed.
*/
if (parent_event) {
mutex_unlock(&parent_event->child_mutex);
/*
* Kick perf_poll() for is_event_hup();
*/
perf_event_wakeup(parent_event);
free_event(event);
put_event(parent_event);
return;
}
/*
* Parent events are governed by their filedesc, retain them.
*/
perf_event_wakeup(event);
}
static void perf_event_exit_task_context(struct task_struct *child)
{
struct perf_event_context *child_ctx, *clone_ctx = NULL;
struct perf_event *child_event, *next;
WARN_ON_ONCE(child != current);
child_ctx = perf_pin_task_context(child);
if (!child_ctx)
return;
/*
* In order to reduce the amount of tricky in ctx tear-down, we hold
* ctx::mutex over the entire thing. This serializes against almost
* everything that wants to access the ctx.
*
* The exception is sys_perf_event_open() /
* perf_event_create_kernel_count() which does find_get_context()
* without ctx::mutex (it cannot because of the move_group double mutex
* lock thing). See the comments in perf_install_in_context().
*/
mutex_lock(&child_ctx->mutex);
/*
* In a single ctx::lock section, de-schedule the events and detach the
* context from the task such that we cannot ever get it scheduled back
* in.
*/
raw_spin_lock_irq(&child_ctx->lock);
task_ctx_sched_out(child_ctx, EVENT_ALL);
/*
* Now that the context is inactive, destroy the task <-> ctx relation
* and mark the context dead.
*/
RCU_INIT_POINTER(child->perf_event_ctxp, NULL);
put_ctx(child_ctx); /* cannot be last */
WRITE_ONCE(child_ctx->task, TASK_TOMBSTONE);
put_task_struct(current); /* cannot be last */
clone_ctx = unclone_ctx(child_ctx);
raw_spin_unlock_irq(&child_ctx->lock);
if (clone_ctx)
put_ctx(clone_ctx);
/*
* Report the task dead after unscheduling the events so that we
* won't get any samples after PERF_RECORD_EXIT. We can however still
* get a few PERF_RECORD_READ events.
*/
perf_event_task(child, child_ctx, 0);
list_for_each_entry_safe(child_event, next, &child_ctx->event_list, event_entry)
perf_event_exit_event(child_event, child_ctx);
mutex_unlock(&child_ctx->mutex);
put_ctx(child_ctx);
}
/*
* When a child task exits, feed back event values to parent events.
*
* Can be called with exec_update_lock held when called from
* setup_new_exec().
*/
void perf_event_exit_task(struct task_struct *child)
{
struct perf_event *event, *tmp;
mutex_lock(&child->perf_event_mutex);
list_for_each_entry_safe(event, tmp, &child->perf_event_list,
owner_entry) {
list_del_init(&event->owner_entry);
/*
* Ensure the list deletion is visible before we clear
* the owner, closes a race against perf_release() where
* we need to serialize on the owner->perf_event_mutex.
*/
smp_store_release(&event->owner, NULL);
}
mutex_unlock(&child->perf_event_mutex);
perf_event_exit_task_context(child);
/*
* The perf_event_exit_task_context calls perf_event_task
* with child's task_ctx, which generates EXIT events for
* child contexts and sets child->perf_event_ctxp[] to NULL.
* At this point we need to send EXIT events to cpu contexts.
*/
perf_event_task(child, NULL, 0);
}
static void perf_free_event(struct perf_event *event,
struct perf_event_context *ctx)
{
struct perf_event *parent = event->parent;
if (WARN_ON_ONCE(!parent))
return;
mutex_lock(&parent->child_mutex);
list_del_init(&event->child_list);
mutex_unlock(&parent->child_mutex);
put_event(parent);
raw_spin_lock_irq(&ctx->lock);
perf_group_detach(event);
list_del_event(event, ctx);
raw_spin_unlock_irq(&ctx->lock);
free_event(event);
}
/*
* Free a context as created by inheritance by perf_event_init_task() below,
* used by fork() in case of fail.
*
* Even though the task has never lived, the context and events have been
* exposed through the child_list, so we must take care tearing it all down.
*/
void perf_event_free_task(struct task_struct *task)
{
struct perf_event_context *ctx;
struct perf_event *event, *tmp;
ctx = rcu_access_pointer(task->perf_event_ctxp);
if (!ctx)
return;
mutex_lock(&ctx->mutex);
raw_spin_lock_irq(&ctx->lock);
/*
* Destroy the task <-> ctx relation and mark the context dead.
*
* This is important because even though the task hasn't been
* exposed yet the context has been (through child_list).
*/
RCU_INIT_POINTER(task->perf_event_ctxp, NULL);
WRITE_ONCE(ctx->task, TASK_TOMBSTONE);
put_task_struct(task); /* cannot be last */
raw_spin_unlock_irq(&ctx->lock);
list_for_each_entry_safe(event, tmp, &ctx->event_list, event_entry)
perf_free_event(event, ctx);
mutex_unlock(&ctx->mutex);
/*
* perf_event_release_kernel() could've stolen some of our
* child events and still have them on its free_list. In that
* case we must wait for these events to have been freed (in
* particular all their references to this task must've been
* dropped).
*
* Without this copy_process() will unconditionally free this
* task (irrespective of its reference count) and
* _free_event()'s put_task_struct(event->hw.target) will be a
* use-after-free.
*
* Wait for all events to drop their context reference.
*/
wait_var_event(&ctx->refcount, refcount_read(&ctx->refcount) == 1);
put_ctx(ctx); /* must be last */
}
void perf_event_delayed_put(struct task_struct *task)
{
WARN_ON_ONCE(task->perf_event_ctxp);
}
struct file *perf_event_get(unsigned int fd)
{
struct file *file = fget(fd);
if (!file)
return ERR_PTR(-EBADF);
if (file->f_op != &perf_fops) {
fput(file);
return ERR_PTR(-EBADF);
}
return file;
}
const struct perf_event *perf_get_event(struct file *file)
{
if (file->f_op != &perf_fops)
return ERR_PTR(-EINVAL);
return file->private_data;
}
const struct perf_event_attr *perf_event_attrs(struct perf_event *event)
{
if (!event)
return ERR_PTR(-EINVAL);
return &event->attr;
}
/*
* Inherit an event from parent task to child task.
*
* Returns:
* - valid pointer on success
* - NULL for orphaned events
* - IS_ERR() on error
*/
static struct perf_event *
inherit_event(struct perf_event *parent_event,
struct task_struct *parent,
struct perf_event_context *parent_ctx,
struct task_struct *child,
struct perf_event *group_leader,
struct perf_event_context *child_ctx)
{
enum perf_event_state parent_state = parent_event->state;
struct perf_event_pmu_context *pmu_ctx;
struct perf_event *child_event;
unsigned long flags;
/*
* Instead of creating recursive hierarchies of events,
* we link inherited events back to the original parent,
* which has a filp for sure, which we use as the reference
* count:
*/
if (parent_event->parent)
parent_event = parent_event->parent;
child_event = perf_event_alloc(&parent_event->attr,
parent_event->cpu,
child,
group_leader, parent_event,
NULL, NULL, -1);
if (IS_ERR(child_event))
return child_event;
pmu_ctx = find_get_pmu_context(child_event->pmu, child_ctx, child_event);
if (IS_ERR(pmu_ctx)) {
free_event(child_event);
return ERR_CAST(pmu_ctx);
}
child_event->pmu_ctx = pmu_ctx;
/*
* is_orphaned_event() and list_add_tail(&parent_event->child_list)
* must be under the same lock in order to serialize against
* perf_event_release_kernel(), such that either we must observe
* is_orphaned_event() or they will observe us on the child_list.
*/
mutex_lock(&parent_event->child_mutex);
if (is_orphaned_event(parent_event) ||
!atomic_long_inc_not_zero(&parent_event->refcount)) {
mutex_unlock(&parent_event->child_mutex);
/* task_ctx_data is freed with child_ctx */
free_event(child_event);
return NULL;
}
get_ctx(child_ctx);
/*
* Make the child state follow the state of the parent event,
* not its attr.disabled bit. We hold the parent's mutex,
* so we won't race with perf_event_{en, dis}able_family.
*/
if (parent_state >= PERF_EVENT_STATE_INACTIVE)
child_event->state = PERF_EVENT_STATE_INACTIVE;
else
child_event->state = PERF_EVENT_STATE_OFF;
if (parent_event->attr.freq) {
u64 sample_period = parent_event->hw.sample_period;
struct hw_perf_event *hwc = &child_event->hw;
hwc->sample_period = sample_period;
hwc->last_period = sample_period;
local64_set(&hwc->period_left, sample_period);
}
child_event->ctx = child_ctx;
child_event->overflow_handler = parent_event->overflow_handler;
child_event->overflow_handler_context
= parent_event->overflow_handler_context;
/*
* Precalculate sample_data sizes
*/
perf_event__header_size(child_event);
perf_event__id_header_size(child_event);
/*
* Link it up in the child's context:
*/
raw_spin_lock_irqsave(&child_ctx->lock, flags);
add_event_to_ctx(child_event, child_ctx);
child_event->attach_state |= PERF_ATTACH_CHILD;
raw_spin_unlock_irqrestore(&child_ctx->lock, flags);
/*
* Link this into the parent event's child list
*/
list_add_tail(&child_event->child_list, &parent_event->child_list);
mutex_unlock(&parent_event->child_mutex);
return child_event;
}
/*
* Inherits an event group.
*
* This will quietly suppress orphaned events; !inherit_event() is not an error.
* This matches with perf_event_release_kernel() removing all child events.
*
* Returns:
* - 0 on success
* - <0 on error
*/
static int inherit_group(struct perf_event *parent_event,
struct task_struct *parent,
struct perf_event_context *parent_ctx,
struct task_struct *child,
struct perf_event_context *child_ctx)
{
struct perf_event *leader;
struct perf_event *sub;
struct perf_event *child_ctr;
leader = inherit_event(parent_event, parent, parent_ctx,
child, NULL, child_ctx);
if (IS_ERR(leader))
return PTR_ERR(leader);
/*
* @leader can be NULL here because of is_orphaned_event(). In this
* case inherit_event() will create individual events, similar to what
* perf_group_detach() would do anyway.
*/
for_each_sibling_event(sub, parent_event) {
child_ctr = inherit_event(sub, parent, parent_ctx,
child, leader, child_ctx);
if (IS_ERR(child_ctr))
return PTR_ERR(child_ctr);
if (sub->aux_event == parent_event && child_ctr &&
!perf_get_aux_event(child_ctr, leader))
return -EINVAL;
}
if (leader)
leader->group_generation = parent_event->group_generation;
return 0;
}
/*
* Creates the child task context and tries to inherit the event-group.
*
* Clears @inherited_all on !attr.inherited or error. Note that we'll leave
* inherited_all set when we 'fail' to inherit an orphaned event; this is
* consistent with perf_event_release_kernel() removing all child events.
*
* Returns:
* - 0 on success
* - <0 on error
*/
static int
inherit_task_group(struct perf_event *event, struct task_struct *parent,
struct perf_event_context *parent_ctx,
struct task_struct *child,
u64 clone_flags, int *inherited_all)
{
struct perf_event_context *child_ctx;
int ret;
if (!event->attr.inherit ||
(event->attr.inherit_thread && !(clone_flags & CLONE_THREAD)) ||
/* Do not inherit if sigtrap and signal handlers were cleared. */
(event->attr.sigtrap && (clone_flags & CLONE_CLEAR_SIGHAND))) {
*inherited_all = 0;
return 0;
}
child_ctx = child->perf_event_ctxp;
if (!child_ctx) {
/*
* This is executed from the parent task context, so
* inherit events that have been marked for cloning.
* First allocate and initialize a context for the
* child.
*/
child_ctx = alloc_perf_context(child);
if (!child_ctx)
return -ENOMEM;
child->perf_event_ctxp = child_ctx;
}
ret = inherit_group(event, parent, parent_ctx, child, child_ctx);
if (ret)
*inherited_all = 0;
return ret;
}
/*
* Initialize the perf_event context in task_struct
*/
static int perf_event_init_context(struct task_struct *child, u64 clone_flags)
{
struct perf_event_context *child_ctx, *parent_ctx;
struct perf_event_context *cloned_ctx;
struct perf_event *event;
struct task_struct *parent = current;
int inherited_all = 1;
unsigned long flags;
int ret = 0;
if (likely(!parent->perf_event_ctxp))
return 0;
/*
* If the parent's context is a clone, pin it so it won't get
* swapped under us.
*/
parent_ctx = perf_pin_task_context(parent);
if (!parent_ctx)
return 0;
/*
* No need to check if parent_ctx != NULL here; since we saw
* it non-NULL earlier, the only reason for it to become NULL
* is if we exit, and since we're currently in the middle of
* a fork we can't be exiting at the same time.
*/
/*
* Lock the parent list. No need to lock the child - not PID
* hashed yet and not running, so nobody can access it.
*/
mutex_lock(&parent_ctx->mutex);
/*
* We dont have to disable NMIs - we are only looking at
* the list, not manipulating it:
*/
perf_event_groups_for_each(event, &parent_ctx->pinned_groups) {
ret = inherit_task_group(event, parent, parent_ctx,
child, clone_flags, &inherited_all);
if (ret)
goto out_unlock;
}
/*
* We can't hold ctx->lock when iterating the ->flexible_group list due
* to allocations, but we need to prevent rotation because
* rotate_ctx() will change the list from interrupt context.
*/
raw_spin_lock_irqsave(&parent_ctx->lock, flags);
parent_ctx->rotate_disable = 1;
raw_spin_unlock_irqrestore(&parent_ctx->lock, flags);
perf_event_groups_for_each(event, &parent_ctx->flexible_groups) {
ret = inherit_task_group(event, parent, parent_ctx,
child, clone_flags, &inherited_all);
if (ret)
goto out_unlock;
}
raw_spin_lock_irqsave(&parent_ctx->lock, flags);
parent_ctx->rotate_disable = 0;
child_ctx = child->perf_event_ctxp;
if (child_ctx && inherited_all) {
/*
* Mark the child context as a clone of the parent
* context, or of whatever the parent is a clone of.
*
* Note that if the parent is a clone, the holding of
* parent_ctx->lock avoids it from being uncloned.
*/
cloned_ctx = parent_ctx->parent_ctx;
if (cloned_ctx) {
child_ctx->parent_ctx = cloned_ctx;
child_ctx->parent_gen = parent_ctx->parent_gen;
} else {
child_ctx->parent_ctx = parent_ctx;
child_ctx->parent_gen = parent_ctx->generation;
}
get_ctx(child_ctx->parent_ctx);
}
raw_spin_unlock_irqrestore(&parent_ctx->lock, flags);
out_unlock:
mutex_unlock(&parent_ctx->mutex);
perf_unpin_context(parent_ctx);
put_ctx(parent_ctx);
return ret;
}
/*
* Initialize the perf_event context in task_struct
*/
int perf_event_init_task(struct task_struct *child, u64 clone_flags)
{
int ret;
child->perf_event_ctxp = NULL;
mutex_init(&child->perf_event_mutex);
INIT_LIST_HEAD(&child->perf_event_list);
ret = perf_event_init_context(child, clone_flags);
if (ret) {
perf_event_free_task(child);
return ret;
}
return 0;
}
static void __init perf_event_init_all_cpus(void)
{
struct swevent_htable *swhash;
struct perf_cpu_context *cpuctx;
int cpu;
zalloc_cpumask_var(&perf_online_mask, GFP_KERNEL);
for_each_possible_cpu(cpu) {
swhash = &per_cpu(swevent_htable, cpu);
mutex_init(&swhash->hlist_mutex);
INIT_LIST_HEAD(&per_cpu(pmu_sb_events.list, cpu));
raw_spin_lock_init(&per_cpu(pmu_sb_events.lock, cpu));
INIT_LIST_HEAD(&per_cpu(sched_cb_list, cpu));
cpuctx = per_cpu_ptr(&perf_cpu_context, cpu);
__perf_event_init_context(&cpuctx->ctx);
lockdep_set_class(&cpuctx->ctx.mutex, &cpuctx_mutex);
lockdep_set_class(&cpuctx->ctx.lock, &cpuctx_lock);
cpuctx->online = cpumask_test_cpu(cpu, perf_online_mask);
cpuctx->heap_size = ARRAY_SIZE(cpuctx->heap_default);
cpuctx->heap = cpuctx->heap_default;
}
}
static void perf_swevent_init_cpu(unsigned int cpu)
{
struct swevent_htable *swhash = &per_cpu(swevent_htable, cpu);
mutex_lock(&swhash->hlist_mutex);
if (swhash->hlist_refcount > 0 && !swevent_hlist_deref(swhash)) {
struct swevent_hlist *hlist;
hlist = kzalloc_node(sizeof(*hlist), GFP_KERNEL, cpu_to_node(cpu));
WARN_ON(!hlist);
rcu_assign_pointer(swhash->swevent_hlist, hlist);
}
mutex_unlock(&swhash->hlist_mutex);
}
#if defined CONFIG_HOTPLUG_CPU || defined CONFIG_KEXEC_CORE
static void __perf_event_exit_context(void *__info)
{
struct perf_cpu_context *cpuctx = this_cpu_ptr(&perf_cpu_context);
struct perf_event_context *ctx = __info;
struct perf_event *event;
raw_spin_lock(&ctx->lock);
ctx_sched_out(ctx, EVENT_TIME);
list_for_each_entry(event, &ctx->event_list, event_entry)
__perf_remove_from_context(event, cpuctx, ctx, (void *)DETACH_GROUP);
raw_spin_unlock(&ctx->lock);
}
static void perf_event_exit_cpu_context(int cpu)
{
struct perf_cpu_context *cpuctx;
struct perf_event_context *ctx;
// XXX simplify cpuctx->online
mutex_lock(&pmus_lock);
cpuctx = per_cpu_ptr(&perf_cpu_context, cpu);
ctx = &cpuctx->ctx;
mutex_lock(&ctx->mutex);
smp_call_function_single(cpu, __perf_event_exit_context, ctx, 1);
cpuctx->online = 0;
mutex_unlock(&ctx->mutex);
cpumask_clear_cpu(cpu, perf_online_mask);
mutex_unlock(&pmus_lock);
}
#else
static void perf_event_exit_cpu_context(int cpu) { }
#endif
int perf_event_init_cpu(unsigned int cpu)
{
struct perf_cpu_context *cpuctx;
struct perf_event_context *ctx;
perf_swevent_init_cpu(cpu);
mutex_lock(&pmus_lock);
cpumask_set_cpu(cpu, perf_online_mask);
cpuctx = per_cpu_ptr(&perf_cpu_context, cpu);
ctx = &cpuctx->ctx;
mutex_lock(&ctx->mutex);
cpuctx->online = 1;
mutex_unlock(&ctx->mutex);
mutex_unlock(&pmus_lock);
return 0;
}
int perf_event_exit_cpu(unsigned int cpu)
{
perf_event_exit_cpu_context(cpu);
return 0;
}
static int
perf_reboot(struct notifier_block *notifier, unsigned long val, void *v)
{
int cpu;
for_each_online_cpu(cpu)
perf_event_exit_cpu(cpu);
return NOTIFY_OK;
}
/*
* Run the perf reboot notifier at the very last possible moment so that
* the generic watchdog code runs as long as possible.
*/
static struct notifier_block perf_reboot_notifier = {
.notifier_call = perf_reboot,
.priority = INT_MIN,
};
void __init perf_event_init(void)
{
int ret;
idr_init(&pmu_idr);
perf_event_init_all_cpus();
init_srcu_struct(&pmus_srcu);
perf_pmu_register(&perf_swevent, "software", PERF_TYPE_SOFTWARE);
perf_pmu_register(&perf_cpu_clock, "cpu_clock", -1);
perf_pmu_register(&perf_task_clock, "task_clock", -1);
perf_tp_register();
perf_event_init_cpu(smp_processor_id());
register_reboot_notifier(&perf_reboot_notifier);
ret = init_hw_breakpoint();
WARN(ret, "hw_breakpoint initialization failed with: %d", ret);
perf_event_cache = KMEM_CACHE(perf_event, SLAB_PANIC);
/*
* Build time assertion that we keep the data_head at the intended
* location. IOW, validation we got the __reserved[] size right.
*/
BUILD_BUG_ON((offsetof(struct perf_event_mmap_page, data_head))
!= 1024);
}
ssize_t perf_event_sysfs_show(struct device *dev, struct device_attribute *attr,
char *page)
{
struct perf_pmu_events_attr *pmu_attr =
container_of(attr, struct perf_pmu_events_attr, attr);
if (pmu_attr->event_str)
return sprintf(page, "%s\n", pmu_attr->event_str);
return 0;
}
EXPORT_SYMBOL_GPL(perf_event_sysfs_show);
static int __init perf_event_sysfs_init(void)
{
struct pmu *pmu;
int ret;
mutex_lock(&pmus_lock);
ret = bus_register(&pmu_bus);
if (ret)
goto unlock;
list_for_each_entry(pmu, &pmus, entry) {
if (pmu->dev)
continue;
ret = pmu_dev_alloc(pmu);
WARN(ret, "Failed to register pmu: %s, reason %d\n", pmu->name, ret);
}
pmu_bus_running = 1;
ret = 0;
unlock:
mutex_unlock(&pmus_lock);
return ret;
}
device_initcall(perf_event_sysfs_init);
#ifdef CONFIG_CGROUP_PERF
static struct cgroup_subsys_state *
perf_cgroup_css_alloc(struct cgroup_subsys_state *parent_css)
{
struct perf_cgroup *jc;
jc = kzalloc(sizeof(*jc), GFP_KERNEL);
if (!jc)
return ERR_PTR(-ENOMEM);
jc->info = alloc_percpu(struct perf_cgroup_info);
if (!jc->info) {
kfree(jc);
return ERR_PTR(-ENOMEM);
}
return &jc->css;
}
static void perf_cgroup_css_free(struct cgroup_subsys_state *css)
{
struct perf_cgroup *jc = container_of(css, struct perf_cgroup, css);
free_percpu(jc->info);
kfree(jc);
}
static int perf_cgroup_css_online(struct cgroup_subsys_state *css)
{
perf_event_cgroup(css->cgroup);
return 0;
}
static int __perf_cgroup_move(void *info)
{
struct task_struct *task = info;
preempt_disable();
perf_cgroup_switch(task);
preempt_enable();
return 0;
}
static void perf_cgroup_attach(struct cgroup_taskset *tset)
{
struct task_struct *task;
struct cgroup_subsys_state *css;
cgroup_taskset_for_each(task, css, tset)
task_function_call(task, __perf_cgroup_move, task);
}
struct cgroup_subsys perf_event_cgrp_subsys = {
.css_alloc = perf_cgroup_css_alloc,
.css_free = perf_cgroup_css_free,
.css_online = perf_cgroup_css_online,
.attach = perf_cgroup_attach,
/*
* Implicitly enable on dfl hierarchy so that perf events can
* always be filtered by cgroup2 path as long as perf_event
* controller is not mounted on a legacy hierarchy.
*/
.implicit_on_dfl = true,
.threaded = true,
};
#endif /* CONFIG_CGROUP_PERF */
DEFINE_STATIC_CALL_RET0(perf_snapshot_branch_stack, perf_snapshot_branch_stack_t);