freebsd-nq/sys/kern/kern_fail.c
Pedro F. Giffuni 8a36da99de sys/kern: adoption of SPDX licensing ID tags.
Mainly focus on files that use BSD 2-Clause license, however the tool I
was using misidentified many licenses so this was mostly a manual - error
prone - task.

The Software Package Data Exchange (SPDX) group provides a specification
to make it easier for automated tools to detect and summarize well known
opensource licenses. We are gradually adopting the specification, noting
that the tags are considered only advisory and do not, in any way,
superceed or replace the license texts.
2017-11-27 15:20:12 +00:00

1127 lines
29 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2009 Isilon Inc http://www.isilon.com/
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
/**
* @file
*
* fail(9) Facility.
*
* @ingroup failpoint_private
*/
/**
* @defgroup failpoint fail(9) Facility
*
* Failpoints allow for injecting fake errors into running code on the fly,
* without modifying code or recompiling with flags. Failpoints are always
* present, and are very efficient when disabled. Failpoints are described
* in man fail(9).
*/
/**
* @defgroup failpoint_private Private fail(9) Implementation functions
*
* Private implementations for the actual failpoint code.
*
* @ingroup failpoint
*/
/**
* @addtogroup failpoint_private
* @{
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include "opt_stack.h"
#include <sys/ctype.h>
#include <sys/errno.h>
#include <sys/fail.h>
#include <sys/kernel.h>
#include <sys/libkern.h>
#include <sys/limits.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/mutex.h>
#include <sys/proc.h>
#include <sys/sbuf.h>
#include <sys/sleepqueue.h>
#include <sys/sx.h>
#include <sys/sysctl.h>
#include <sys/types.h>
#include <machine/atomic.h>
#include <machine/stdarg.h>
#ifdef ILOG_DEFINE_FOR_FILE
ILOG_DEFINE_FOR_FILE(L_ISI_FAIL_POINT, L_ILOG, fail_point);
#endif
static MALLOC_DEFINE(M_FAIL_POINT, "Fail Points", "fail points system");
#define fp_free(ptr) free(ptr, M_FAIL_POINT)
#define fp_malloc(size, flags) malloc((size), M_FAIL_POINT, (flags))
#define fs_free(ptr) fp_free(ptr)
#define fs_malloc() fp_malloc(sizeof(struct fail_point_setting), \
M_WAITOK | M_ZERO)
/**
* These define the wchans that are used for sleeping, pausing respectively.
* They are chosen arbitrarily but need to be distinct to the failpoint and
* the sleep/pause distinction.
*/
#define FP_SLEEP_CHANNEL(fp) (void*)(fp)
#define FP_PAUSE_CHANNEL(fp) __DEVOLATILE(void*, &fp->fp_setting)
/**
* Don't allow more than this many entries in a fail point set by sysctl.
* The 99.99...% case is to have 1 entry. I can't imagine having this many
* entries, so it should not limit us. Saves on re-mallocs while holding
* a non-sleepable lock.
*/
#define FP_MAX_ENTRY_COUNT 20
/* Used to drain sbufs to the sysctl output */
int fail_sysctl_drain_func(void *, const char *, int);
/* Head of tailq of struct fail_point_entry */
TAILQ_HEAD(fail_point_entry_queue, fail_point_entry);
/**
* fp entries garbage list; outstanding entries are cleaned up in the
* garbage collector
*/
STAILQ_HEAD(fail_point_setting_garbage, fail_point_setting);
static struct fail_point_setting_garbage fp_setting_garbage =
STAILQ_HEAD_INITIALIZER(fp_setting_garbage);
static struct mtx mtx_garbage_list;
MTX_SYSINIT(mtx_garbage_list, &mtx_garbage_list, "fail point garbage mtx",
MTX_SPIN);
static struct sx sx_fp_set;
SX_SYSINIT(sx_fp_set, &sx_fp_set, "fail point set sx");
/**
* Failpoint types.
* Don't change these without changing fail_type_strings in fail.c.
* @ingroup failpoint_private
*/
enum fail_point_t {
FAIL_POINT_OFF, /**< don't fail */
FAIL_POINT_PANIC, /**< panic */
FAIL_POINT_RETURN, /**< return an errorcode */
FAIL_POINT_BREAK, /**< break into the debugger */
FAIL_POINT_PRINT, /**< print a message */
FAIL_POINT_SLEEP, /**< sleep for some msecs */
FAIL_POINT_PAUSE, /**< sleep until failpoint is set to off */
FAIL_POINT_YIELD, /**< yield the cpu */
FAIL_POINT_DELAY, /**< busy wait the cpu */
FAIL_POINT_NUMTYPES,
FAIL_POINT_INVALID = -1
};
static struct {
const char *name;
int nmlen;
} fail_type_strings[] = {
#define FP_TYPE_NM_LEN(s) { s, sizeof(s) - 1 }
[FAIL_POINT_OFF] = FP_TYPE_NM_LEN("off"),
[FAIL_POINT_PANIC] = FP_TYPE_NM_LEN("panic"),
[FAIL_POINT_RETURN] = FP_TYPE_NM_LEN("return"),
[FAIL_POINT_BREAK] = FP_TYPE_NM_LEN("break"),
[FAIL_POINT_PRINT] = FP_TYPE_NM_LEN("print"),
[FAIL_POINT_SLEEP] = FP_TYPE_NM_LEN("sleep"),
[FAIL_POINT_PAUSE] = FP_TYPE_NM_LEN("pause"),
[FAIL_POINT_YIELD] = FP_TYPE_NM_LEN("yield"),
[FAIL_POINT_DELAY] = FP_TYPE_NM_LEN("delay"),
};
#define FE_COUNT_UNTRACKED (INT_MIN)
/**
* Internal structure tracking a single term of a complete failpoint.
* @ingroup failpoint_private
*/
struct fail_point_entry {
volatile bool fe_stale;
enum fail_point_t fe_type; /**< type of entry */
int fe_arg; /**< argument to type (e.g. return value) */
int fe_prob; /**< likelihood of firing in millionths */
int32_t fe_count; /**< number of times to fire, -1 means infinite */
pid_t fe_pid; /**< only fail for this process */
struct fail_point *fe_parent; /**< backpointer to fp */
TAILQ_ENTRY(fail_point_entry) fe_entries; /**< next entry ptr */
};
struct fail_point_setting {
STAILQ_ENTRY(fail_point_setting) fs_garbage_link;
struct fail_point_entry_queue fp_entry_queue;
struct fail_point * fs_parent;
struct mtx feq_mtx; /* Gives fail_point_pause something to do. */
};
/**
* Defines stating the equivalent of probablilty one (100%)
*/
enum {
PROB_MAX = 1000000, /* probability between zero and this number */
PROB_DIGITS = 6 /* number of zero's in above number */
};
/* Get a ref on an fp's fp_setting */
static inline struct fail_point_setting *fail_point_setting_get_ref(
struct fail_point *fp);
/* Release a ref on an fp_setting */
static inline void fail_point_setting_release_ref(struct fail_point *fp);
/* Allocate and initialize a struct fail_point_setting */
static struct fail_point_setting *fail_point_setting_new(struct
fail_point *);
/* Free a struct fail_point_setting */
static void fail_point_setting_destroy(struct fail_point_setting *fp_setting);
/* Allocate and initialize a struct fail_point_entry */
static struct fail_point_entry *fail_point_entry_new(struct
fail_point_setting *);
/* Free a struct fail_point_entry */
static void fail_point_entry_destroy(struct fail_point_entry *fp_entry);
/* Append fp setting to garbage list */
static inline void fail_point_setting_garbage_append(
struct fail_point_setting *fp_setting);
/* Swap fp's setting with fp_setting_new */
static inline struct fail_point_setting *
fail_point_swap_settings(struct fail_point *fp,
struct fail_point_setting *fp_setting_new);
/* Free up any zero-ref setting in the garbage queue */
static void fail_point_garbage_collect(void);
/* If this fail point's setting are empty, then swap it out to NULL. */
static inline void fail_point_eval_swap_out(struct fail_point *fp,
struct fail_point_setting *fp_setting);
bool
fail_point_is_off(struct fail_point *fp)
{
bool return_val;
struct fail_point_setting *fp_setting;
struct fail_point_entry *ent;
return_val = true;
fp_setting = fail_point_setting_get_ref(fp);
if (fp_setting != NULL) {
TAILQ_FOREACH(ent, &fp_setting->fp_entry_queue,
fe_entries) {
if (!ent->fe_stale) {
return_val = false;
break;
}
}
}
fail_point_setting_release_ref(fp);
return (return_val);
}
/* Allocate and initialize a struct fail_point_setting */
static struct fail_point_setting *
fail_point_setting_new(struct fail_point *fp)
{
struct fail_point_setting *fs_new;
fs_new = fs_malloc();
fs_new->fs_parent = fp;
TAILQ_INIT(&fs_new->fp_entry_queue);
mtx_init(&fs_new->feq_mtx, "fail point entries", NULL, MTX_SPIN);
fail_point_setting_garbage_append(fs_new);
return (fs_new);
}
/* Free a struct fail_point_setting */
static void
fail_point_setting_destroy(struct fail_point_setting *fp_setting)
{
struct fail_point_entry *ent;
while (!TAILQ_EMPTY(&fp_setting->fp_entry_queue)) {
ent = TAILQ_FIRST(&fp_setting->fp_entry_queue);
TAILQ_REMOVE(&fp_setting->fp_entry_queue, ent, fe_entries);
fail_point_entry_destroy(ent);
}
fs_free(fp_setting);
}
/* Allocate and initialize a struct fail_point_entry */
static struct fail_point_entry *
fail_point_entry_new(struct fail_point_setting *fp_setting)
{
struct fail_point_entry *fp_entry;
fp_entry = fp_malloc(sizeof(struct fail_point_entry),
M_WAITOK | M_ZERO);
fp_entry->fe_parent = fp_setting->fs_parent;
fp_entry->fe_prob = PROB_MAX;
fp_entry->fe_pid = NO_PID;
fp_entry->fe_count = FE_COUNT_UNTRACKED;
TAILQ_INSERT_TAIL(&fp_setting->fp_entry_queue, fp_entry,
fe_entries);
return (fp_entry);
}
/* Free a struct fail_point_entry */
static void
fail_point_entry_destroy(struct fail_point_entry *fp_entry)
{
fp_free(fp_entry);
}
/* Get a ref on an fp's fp_setting */
static inline struct fail_point_setting *
fail_point_setting_get_ref(struct fail_point *fp)
{
struct fail_point_setting *fp_setting;
/* Invariant: if we have a ref, our pointer to fp_setting is safe */
atomic_add_acq_32(&fp->fp_ref_cnt, 1);
fp_setting = fp->fp_setting;
return (fp_setting);
}
/* Release a ref on an fp_setting */
static inline void
fail_point_setting_release_ref(struct fail_point *fp)
{
KASSERT(&fp->fp_ref_cnt > 0, ("Attempting to deref w/no refs"));
atomic_subtract_rel_32(&fp->fp_ref_cnt, 1);
}
/* Append fp entries to fp garbage list */
static inline void
fail_point_setting_garbage_append(struct fail_point_setting *fp_setting)
{
mtx_lock_spin(&mtx_garbage_list);
STAILQ_INSERT_TAIL(&fp_setting_garbage, fp_setting,
fs_garbage_link);
mtx_unlock_spin(&mtx_garbage_list);
}
/* Swap fp's entries with fp_setting_new */
static struct fail_point_setting *
fail_point_swap_settings(struct fail_point *fp,
struct fail_point_setting *fp_setting_new)
{
struct fail_point_setting *fp_setting_old;
fp_setting_old = fp->fp_setting;
fp->fp_setting = fp_setting_new;
return (fp_setting_old);
}
static inline void
fail_point_eval_swap_out(struct fail_point *fp,
struct fail_point_setting *fp_setting)
{
/* We may have already been swapped out and replaced; ignore. */
if (fp->fp_setting == fp_setting)
fail_point_swap_settings(fp, NULL);
}
/* Free up any zero-ref entries in the garbage queue */
static void
fail_point_garbage_collect(void)
{
struct fail_point_setting *fs_current, *fs_next;
struct fail_point_setting_garbage fp_ents_free_list;
/**
* We will transfer the entries to free to fp_ents_free_list while holding
* the spin mutex, then free it after we drop the lock. This avoids
* triggering witness due to sleepable mutexes in the memory
* allocator.
*/
STAILQ_INIT(&fp_ents_free_list);
mtx_lock_spin(&mtx_garbage_list);
STAILQ_FOREACH_SAFE(fs_current, &fp_setting_garbage, fs_garbage_link,
fs_next) {
if (fs_current->fs_parent->fp_setting != fs_current &&
fs_current->fs_parent->fp_ref_cnt == 0) {
STAILQ_REMOVE(&fp_setting_garbage, fs_current,
fail_point_setting, fs_garbage_link);
STAILQ_INSERT_HEAD(&fp_ents_free_list, fs_current,
fs_garbage_link);
}
}
mtx_unlock_spin(&mtx_garbage_list);
STAILQ_FOREACH_SAFE(fs_current, &fp_ents_free_list, fs_garbage_link,
fs_next)
fail_point_setting_destroy(fs_current);
}
/* Drain out all refs from this fail point */
static inline void
fail_point_drain(struct fail_point *fp, int expected_ref)
{
struct fail_point_setting *entries;
entries = fail_point_swap_settings(fp, NULL);
/**
* We have unpaused all threads; so we will wait no longer
* than the time taken for the longest remaining sleep, or
* the length of time of a long-running code block.
*/
while (fp->fp_ref_cnt > expected_ref) {
wakeup(FP_PAUSE_CHANNEL(fp));
tsleep(&fp, PWAIT, "fail_point_drain", hz / 100);
}
fail_point_swap_settings(fp, entries);
}
static inline void
fail_point_pause(struct fail_point *fp, enum fail_point_return_code *pret,
struct mtx *mtx_sleep)
{
if (fp->fp_pre_sleep_fn)
fp->fp_pre_sleep_fn(fp->fp_pre_sleep_arg);
msleep_spin(FP_PAUSE_CHANNEL(fp), mtx_sleep, "failpt", 0);
if (fp->fp_post_sleep_fn)
fp->fp_post_sleep_fn(fp->fp_post_sleep_arg);
}
static inline void
fail_point_sleep(struct fail_point *fp, int msecs,
enum fail_point_return_code *pret)
{
int timo;
/* Convert from millisecs to ticks, rounding up */
timo = howmany((int64_t)msecs * hz, 1000L);
if (timo > 0) {
if (!(fp->fp_flags & FAIL_POINT_USE_TIMEOUT_PATH)) {
if (fp->fp_pre_sleep_fn)
fp->fp_pre_sleep_fn(fp->fp_pre_sleep_arg);
tsleep(FP_SLEEP_CHANNEL(fp), PWAIT, "failpt", timo);
if (fp->fp_post_sleep_fn)
fp->fp_post_sleep_fn(fp->fp_post_sleep_arg);
} else {
if (fp->fp_pre_sleep_fn)
fp->fp_pre_sleep_fn(fp->fp_pre_sleep_arg);
timeout(fp->fp_post_sleep_fn, fp->fp_post_sleep_arg,
timo);
*pret = FAIL_POINT_RC_QUEUED;
}
}
}
static char *parse_fail_point(struct fail_point_setting *, char *);
static char *parse_term(struct fail_point_setting *, char *);
static char *parse_number(int *out_units, int *out_decimal, char *);
static char *parse_type(struct fail_point_entry *, char *);
/**
* Initialize a fail_point. The name is formed in a printf-like fashion
* from "fmt" and subsequent arguments. This function is generally used
* for custom failpoints located at odd places in the sysctl tree, and is
* not explicitly needed for standard in-line-declared failpoints.
*
* @ingroup failpoint
*/
void
fail_point_init(struct fail_point *fp, const char *fmt, ...)
{
va_list ap;
char *name;
int n;
fp->fp_setting = NULL;
fp->fp_flags = 0;
/* Figure out the size of the name. */
va_start(ap, fmt);
n = vsnprintf(NULL, 0, fmt, ap);
va_end(ap);
/* Allocate the name and fill it in. */
name = fp_malloc(n + 1, M_WAITOK);
if (name != NULL) {
va_start(ap, fmt);
vsnprintf(name, n + 1, fmt, ap);
va_end(ap);
}
fp->fp_name = name;
fp->fp_location = "";
fp->fp_flags |= FAIL_POINT_DYNAMIC_NAME;
fp->fp_pre_sleep_fn = NULL;
fp->fp_pre_sleep_arg = NULL;
fp->fp_post_sleep_fn = NULL;
fp->fp_post_sleep_arg = NULL;
}
/**
* Free the resources held by a fail_point, and wake any paused threads.
* Thou shalt not allow threads to hit this fail point after you enter this
* function, nor shall you call this multiple times for a given fp.
* @ingroup failpoint
*/
void
fail_point_destroy(struct fail_point *fp)
{
fail_point_drain(fp, 0);
if ((fp->fp_flags & FAIL_POINT_DYNAMIC_NAME) != 0) {
fp_free(__DECONST(void *, fp->fp_name));
fp->fp_name = NULL;
}
fp->fp_flags = 0;
sx_xlock(&sx_fp_set);
fail_point_garbage_collect();
sx_xunlock(&sx_fp_set);
}
/**
* This does the real work of evaluating a fail point. If the fail point tells
* us to return a value, this function returns 1 and fills in 'return_value'
* (return_value is allowed to be null). If the fail point tells us to panic,
* we never return. Otherwise we just return 0 after doing some work, which
* means "keep going".
*/
enum fail_point_return_code
fail_point_eval_nontrivial(struct fail_point *fp, int *return_value)
{
bool execute = false;
struct fail_point_entry *ent;
struct fail_point_setting *fp_setting;
enum fail_point_return_code ret;
int cont;
int count;
int msecs;
int usecs;
ret = FAIL_POINT_RC_CONTINUE;
cont = 0; /* don't continue by default */
fp_setting = fail_point_setting_get_ref(fp);
if (fp_setting == NULL)
goto abort;
TAILQ_FOREACH(ent, &fp_setting->fp_entry_queue, fe_entries) {
if (ent->fe_stale)
continue;
if (ent->fe_prob < PROB_MAX &&
ent->fe_prob < random() % PROB_MAX)
continue;
if (ent->fe_pid != NO_PID && ent->fe_pid != curproc->p_pid)
continue;
if (ent->fe_count != FE_COUNT_UNTRACKED) {
count = ent->fe_count;
while (count > 0) {
if (atomic_cmpset_32(&ent->fe_count, count, count - 1)) {
count--;
execute = true;
break;
}
count = ent->fe_count;
}
if (execute == false)
/* We lost the race; consider the entry stale and bail now */
continue;
if (count == 0)
ent->fe_stale = true;
}
switch (ent->fe_type) {
case FAIL_POINT_PANIC:
panic("fail point %s panicking", fp->fp_name);
/* NOTREACHED */
case FAIL_POINT_RETURN:
if (return_value != NULL)
*return_value = ent->fe_arg;
ret = FAIL_POINT_RC_RETURN;
break;
case FAIL_POINT_BREAK:
printf("fail point %s breaking to debugger\n",
fp->fp_name);
breakpoint();
break;
case FAIL_POINT_PRINT:
printf("fail point %s executing\n", fp->fp_name);
cont = ent->fe_arg;
break;
case FAIL_POINT_SLEEP:
msecs = ent->fe_arg;
if (msecs)
fail_point_sleep(fp, msecs, &ret);
break;
case FAIL_POINT_PAUSE:
/**
* Pausing is inherently strange with multiple
* entries given our design. That is because some
* entries could be unreachable, for instance in cases like:
* pause->return. We can never reach the return entry.
* The sysctl layer actually truncates all entries after
* a pause for this reason.
*/
mtx_lock_spin(&fp_setting->feq_mtx);
fail_point_pause(fp, &ret, &fp_setting->feq_mtx);
mtx_unlock_spin(&fp_setting->feq_mtx);
break;
case FAIL_POINT_YIELD:
kern_yield(PRI_UNCHANGED);
break;
case FAIL_POINT_DELAY:
usecs = ent->fe_arg;
DELAY(usecs);
break;
default:
break;
}
if (cont == 0)
break;
}
if (fail_point_is_off(fp))
fail_point_eval_swap_out(fp, fp_setting);
abort:
fail_point_setting_release_ref(fp);
return (ret);
}
/**
* Translate internal fail_point structure into human-readable text.
*/
static void
fail_point_get(struct fail_point *fp, struct sbuf *sb,
bool verbose)
{
struct fail_point_entry *ent;
struct fail_point_setting *fp_setting;
struct fail_point_entry *fp_entry_cpy;
int cnt_sleeping;
int idx;
int printed_entry_count;
cnt_sleeping = 0;
idx = 0;
printed_entry_count = 0;
fp_entry_cpy = fp_malloc(sizeof(struct fail_point_entry) *
(FP_MAX_ENTRY_COUNT + 1), M_WAITOK);
fp_setting = fail_point_setting_get_ref(fp);
if (fp_setting != NULL) {
TAILQ_FOREACH(ent, &fp_setting->fp_entry_queue, fe_entries) {
if (ent->fe_stale)
continue;
KASSERT(printed_entry_count < FP_MAX_ENTRY_COUNT,
("FP entry list larger than allowed"));
fp_entry_cpy[printed_entry_count] = *ent;
++printed_entry_count;
}
}
fail_point_setting_release_ref(fp);
/* This is our equivalent of a NULL terminator */
fp_entry_cpy[printed_entry_count].fe_type = FAIL_POINT_INVALID;
while (idx < printed_entry_count) {
ent = &fp_entry_cpy[idx];
++idx;
if (ent->fe_prob < PROB_MAX) {
int decimal = ent->fe_prob % (PROB_MAX / 100);
int units = ent->fe_prob / (PROB_MAX / 100);
sbuf_printf(sb, "%d", units);
if (decimal) {
int digits = PROB_DIGITS - 2;
while (!(decimal % 10)) {
digits--;
decimal /= 10;
}
sbuf_printf(sb, ".%0*d", digits, decimal);
}
sbuf_printf(sb, "%%");
}
if (ent->fe_count >= 0)
sbuf_printf(sb, "%d*", ent->fe_count);
sbuf_printf(sb, "%s", fail_type_strings[ent->fe_type].name);
if (ent->fe_arg)
sbuf_printf(sb, "(%d)", ent->fe_arg);
if (ent->fe_pid != NO_PID)
sbuf_printf(sb, "[pid %d]", ent->fe_pid);
if (TAILQ_NEXT(ent, fe_entries))
sbuf_printf(sb, "->");
}
if (!printed_entry_count)
sbuf_printf(sb, "off");
fp_free(fp_entry_cpy);
if (verbose) {
#ifdef STACK
/* Print number of sleeping threads. queue=0 is the argument
* used by msleep when sending our threads to sleep. */
sbuf_printf(sb, "\nsleeping_thread_stacks = {\n");
sleepq_sbuf_print_stacks(sb, FP_SLEEP_CHANNEL(fp), 0,
&cnt_sleeping);
sbuf_printf(sb, "},\n");
#endif
sbuf_printf(sb, "sleeping_thread_count = %d,\n",
cnt_sleeping);
#ifdef STACK
sbuf_printf(sb, "paused_thread_stacks = {\n");
sleepq_sbuf_print_stacks(sb, FP_PAUSE_CHANNEL(fp), 0,
&cnt_sleeping);
sbuf_printf(sb, "},\n");
#endif
sbuf_printf(sb, "paused_thread_count = %d\n",
cnt_sleeping);
}
}
/**
* Set an internal fail_point structure from a human-readable failpoint string
* in a lock-safe manner.
*/
static int
fail_point_set(struct fail_point *fp, char *buf)
{
struct fail_point_entry *ent, *ent_next;
struct fail_point_setting *entries;
bool should_wake_paused;
bool should_truncate;
int error;
error = 0;
should_wake_paused = false;
should_truncate = false;
/* Parse new entries. */
/**
* ref protects our new malloc'd stuff from being garbage collected
* before we link it.
*/
fail_point_setting_get_ref(fp);
entries = fail_point_setting_new(fp);
if (parse_fail_point(entries, buf) == NULL) {
STAILQ_REMOVE(&fp_setting_garbage, entries,
fail_point_setting, fs_garbage_link);
fail_point_setting_destroy(entries);
error = EINVAL;
goto end;
}
/**
* Transfer the entries we are going to keep to a new list.
* Get rid of useless zero probability entries, and entries with hit
* count 0.
* If 'off' is present, and it has no hit count set, then all entries
* after it are discarded since they are unreachable.
*/
TAILQ_FOREACH_SAFE(ent, &entries->fp_entry_queue, fe_entries, ent_next) {
if (ent->fe_prob == 0 || ent->fe_count == 0) {
printf("Discarding entry which cannot execute %s\n",
fail_type_strings[ent->fe_type].name);
TAILQ_REMOVE(&entries->fp_entry_queue, ent,
fe_entries);
fp_free(ent);
continue;
} else if (should_truncate) {
printf("Discarding unreachable entry %s\n",
fail_type_strings[ent->fe_type].name);
TAILQ_REMOVE(&entries->fp_entry_queue, ent,
fe_entries);
fp_free(ent);
continue;
}
if (ent->fe_type == FAIL_POINT_OFF) {
should_wake_paused = true;
if (ent->fe_count == FE_COUNT_UNTRACKED) {
should_truncate = true;
TAILQ_REMOVE(&entries->fp_entry_queue, ent,
fe_entries);
fp_free(ent);
}
} else if (ent->fe_type == FAIL_POINT_PAUSE) {
should_truncate = true;
} else if (ent->fe_type == FAIL_POINT_SLEEP && (fp->fp_flags &
FAIL_POINT_NONSLEEPABLE)) {
/**
* If this fail point is annotated as being in a
* non-sleepable ctx, convert sleep to delay and
* convert the msec argument to usecs.
*/
printf("Sleep call request on fail point in "
"non-sleepable context; using delay instead "
"of sleep\n");
ent->fe_type = FAIL_POINT_DELAY;
ent->fe_arg *= 1000;
}
}
if (TAILQ_EMPTY(&entries->fp_entry_queue)) {
entries = fail_point_swap_settings(fp, NULL);
if (entries != NULL)
wakeup(FP_PAUSE_CHANNEL(fp));
} else {
if (should_wake_paused)
wakeup(FP_PAUSE_CHANNEL(fp));
fail_point_swap_settings(fp, entries);
}
end:
#ifdef IWARNING
if (error)
IWARNING("Failed to set %s %s to %s",
fp->fp_name, fp->fp_location, buf);
else
INOTICE("Set %s %s to %s",
fp->fp_name, fp->fp_location, buf);
#endif /* IWARNING */
fail_point_setting_release_ref(fp);
return (error);
}
#define MAX_FAIL_POINT_BUF 1023
/**
* Handle kernel failpoint set/get.
*/
int
fail_point_sysctl(SYSCTL_HANDLER_ARGS)
{
struct fail_point *fp;
char *buf;
struct sbuf sb, *sb_check;
int error;
buf = NULL;
error = 0;
fp = arg1;
sb_check = sbuf_new(&sb, NULL, 1024, SBUF_AUTOEXTEND);
if (sb_check != &sb)
return (ENOMEM);
sbuf_set_drain(&sb, (sbuf_drain_func *)fail_sysctl_drain_func, req);
/* Setting */
/**
* Lock protects any new entries from being garbage collected before we
* can link them to the fail point.
*/
sx_xlock(&sx_fp_set);
if (req->newptr) {
if (req->newlen > MAX_FAIL_POINT_BUF) {
error = EINVAL;
goto out;
}
buf = fp_malloc(req->newlen + 1, M_WAITOK);
error = SYSCTL_IN(req, buf, req->newlen);
if (error)
goto out;
buf[req->newlen] = '\0';
error = fail_point_set(fp, buf);
}
fail_point_garbage_collect();
sx_xunlock(&sx_fp_set);
/* Retrieving. */
fail_point_get(fp, &sb, false);
out:
sbuf_finish(&sb);
sbuf_delete(&sb);
if (buf)
fp_free(buf);
return (error);
}
int
fail_point_sysctl_status(SYSCTL_HANDLER_ARGS)
{
struct fail_point *fp;
struct sbuf sb, *sb_check;
fp = arg1;
sb_check = sbuf_new(&sb, NULL, 1024, SBUF_AUTOEXTEND);
if (sb_check != &sb)
return (ENOMEM);
sbuf_set_drain(&sb, (sbuf_drain_func *)fail_sysctl_drain_func, req);
/* Retrieving. */
fail_point_get(fp, &sb, true);
sbuf_finish(&sb);
sbuf_delete(&sb);
/**
* Lock protects any new entries from being garbage collected before we
* can link them to the fail point.
*/
sx_xlock(&sx_fp_set);
fail_point_garbage_collect();
sx_xunlock(&sx_fp_set);
return (0);
}
int
fail_sysctl_drain_func(void *sysctl_args, const char *buf, int len)
{
struct sysctl_req *sa;
int error;
sa = sysctl_args;
error = SYSCTL_OUT(sa, buf, len);
if (error == ENOMEM)
return (-1);
else
return (len);
}
/**
* Internal helper function to translate a human-readable failpoint string
* into a internally-parsable fail_point structure.
*/
static char *
parse_fail_point(struct fail_point_setting *ents, char *p)
{
/* <fail_point> ::
* <term> ( "->" <term> )*
*/
uint8_t term_count;
term_count = 1;
p = parse_term(ents, p);
if (p == NULL)
return (NULL);
while (*p != '\0') {
term_count++;
if (p[0] != '-' || p[1] != '>' ||
(p = parse_term(ents, p+2)) == NULL ||
term_count > FP_MAX_ENTRY_COUNT)
return (NULL);
}
return (p);
}
/**
* Internal helper function to parse an individual term from a failpoint.
*/
static char *
parse_term(struct fail_point_setting *ents, char *p)
{
struct fail_point_entry *ent;
ent = fail_point_entry_new(ents);
/*
* <term> ::
* ( (<float> "%") | (<integer> "*" ) )*
* <type>
* [ "(" <integer> ")" ]
* [ "[pid " <integer> "]" ]
*/
/* ( (<float> "%") | (<integer> "*" ) )* */
while (isdigit(*p) || *p == '.') {
int units, decimal;
p = parse_number(&units, &decimal, p);
if (p == NULL)
return (NULL);
if (*p == '%') {
if (units > 100) /* prevent overflow early */
units = 100;
ent->fe_prob = units * (PROB_MAX / 100) + decimal;
if (ent->fe_prob > PROB_MAX)
ent->fe_prob = PROB_MAX;
} else if (*p == '*') {
if (!units || units < 0 || decimal)
return (NULL);
ent->fe_count = units;
} else
return (NULL);
p++;
}
/* <type> */
p = parse_type(ent, p);
if (p == NULL)
return (NULL);
if (*p == '\0')
return (p);
/* [ "(" <integer> ")" ] */
if (*p != '(')
return (p);
p++;
if (!isdigit(*p) && *p != '-')
return (NULL);
ent->fe_arg = strtol(p, &p, 0);
if (*p++ != ')')
return (NULL);
/* [ "[pid " <integer> "]" ] */
#define PID_STRING "[pid "
if (strncmp(p, PID_STRING, sizeof(PID_STRING) - 1) != 0)
return (p);
p += sizeof(PID_STRING) - 1;
if (!isdigit(*p))
return (NULL);
ent->fe_pid = strtol(p, &p, 0);
if (*p++ != ']')
return (NULL);
return (p);
}
/**
* Internal helper function to parse a numeric for a failpoint term.
*/
static char *
parse_number(int *out_units, int *out_decimal, char *p)
{
char *old_p;
/**
* <number> ::
* <integer> [ "." <integer> ] |
* "." <integer>
*/
/* whole part */
old_p = p;
*out_units = strtol(p, &p, 10);
if (p == old_p && *p != '.')
return (NULL);
/* fractional part */
*out_decimal = 0;
if (*p == '.') {
int digits = 0;
p++;
while (isdigit(*p)) {
int digit = *p - '0';
if (digits < PROB_DIGITS - 2)
*out_decimal = *out_decimal * 10 + digit;
else if (digits == PROB_DIGITS - 2 && digit >= 5)
(*out_decimal)++;
digits++;
p++;
}
if (!digits) /* need at least one digit after '.' */
return (NULL);
while (digits++ < PROB_DIGITS - 2) /* add implicit zeros */
*out_decimal *= 10;
}
return (p); /* success */
}
/**
* Internal helper function to parse an individual type for a failpoint term.
*/
static char *
parse_type(struct fail_point_entry *ent, char *beg)
{
enum fail_point_t type;
int len;
for (type = FAIL_POINT_OFF; type < FAIL_POINT_NUMTYPES; type++) {
len = fail_type_strings[type].nmlen;
if (strncmp(fail_type_strings[type].name, beg, len) == 0) {
ent->fe_type = type;
return (beg + len);
}
}
return (NULL);
}
/* The fail point sysctl tree. */
SYSCTL_NODE(_debug, OID_AUTO, fail_point, CTLFLAG_RW, 0, "fail points");
/* Debugging/testing stuff for fail point */
static int
sysctl_test_fail_point(SYSCTL_HANDLER_ARGS)
{
KFAIL_POINT_RETURN(DEBUG_FP, test_fail_point);
return (0);
}
SYSCTL_OID(_debug_fail_point, OID_AUTO, test_trigger_fail_point,
CTLTYPE_STRING | CTLFLAG_RD, NULL, 0, sysctl_test_fail_point, "A",
"Trigger test fail points");