freebsd-nq/sys/kern/kern_umtx.c
Kyle Evans 60e60e73fd freebsd32: take the _umtx_op struct definitions back
Providing these in freebsd32.h facilitates local testing/measuring of the
structs rather than forcing one to locally recreate them. Sanity checking
offsets/sizes remains in kern_umtx.c where these are typically used.
2020-11-23 00:58:14 +00:00

4696 lines
107 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2015, 2016 The FreeBSD Foundation
* Copyright (c) 2004, David Xu <davidxu@freebsd.org>
* Copyright (c) 2002, Jeffrey Roberson <jeff@freebsd.org>
* All rights reserved.
*
* Portions of this software were developed by Konstantin Belousov
* under sponsorship from the FreeBSD Foundation.
*
* 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 unmodified, 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 ``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 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.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include "opt_umtx_profiling.h"
#include <sys/param.h>
#include <sys/kernel.h>
#include <sys/fcntl.h>
#include <sys/file.h>
#include <sys/filedesc.h>
#include <sys/limits.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/mman.h>
#include <sys/mutex.h>
#include <sys/priv.h>
#include <sys/proc.h>
#include <sys/resource.h>
#include <sys/resourcevar.h>
#include <sys/rwlock.h>
#include <sys/sbuf.h>
#include <sys/sched.h>
#include <sys/smp.h>
#include <sys/sysctl.h>
#include <sys/sysent.h>
#include <sys/systm.h>
#include <sys/sysproto.h>
#include <sys/syscallsubr.h>
#include <sys/taskqueue.h>
#include <sys/time.h>
#include <sys/eventhandler.h>
#include <sys/umtx.h>
#include <security/mac/mac_framework.h>
#include <vm/vm.h>
#include <vm/vm_param.h>
#include <vm/pmap.h>
#include <vm/vm_map.h>
#include <vm/vm_object.h>
#include <machine/atomic.h>
#include <machine/cpu.h>
#include <compat/freebsd32/freebsd32.h>
#ifdef COMPAT_FREEBSD32
#include <compat/freebsd32/freebsd32_proto.h>
#endif
#define _UMUTEX_TRY 1
#define _UMUTEX_WAIT 2
#ifdef UMTX_PROFILING
#define UPROF_PERC_BIGGER(w, f, sw, sf) \
(((w) > (sw)) || ((w) == (sw) && (f) > (sf)))
#endif
/* Priority inheritance mutex info. */
struct umtx_pi {
/* Owner thread */
struct thread *pi_owner;
/* Reference count */
int pi_refcount;
/* List entry to link umtx holding by thread */
TAILQ_ENTRY(umtx_pi) pi_link;
/* List entry in hash */
TAILQ_ENTRY(umtx_pi) pi_hashlink;
/* List for waiters */
TAILQ_HEAD(,umtx_q) pi_blocked;
/* Identify a userland lock object */
struct umtx_key pi_key;
};
/* A userland synchronous object user. */
struct umtx_q {
/* Linked list for the hash. */
TAILQ_ENTRY(umtx_q) uq_link;
/* Umtx key. */
struct umtx_key uq_key;
/* Umtx flags. */
int uq_flags;
#define UQF_UMTXQ 0x0001
/* The thread waits on. */
struct thread *uq_thread;
/*
* Blocked on PI mutex. read can use chain lock
* or umtx_lock, write must have both chain lock and
* umtx_lock being hold.
*/
struct umtx_pi *uq_pi_blocked;
/* On blocked list */
TAILQ_ENTRY(umtx_q) uq_lockq;
/* Thread contending with us */
TAILQ_HEAD(,umtx_pi) uq_pi_contested;
/* Inherited priority from PP mutex */
u_char uq_inherited_pri;
/* Spare queue ready to be reused */
struct umtxq_queue *uq_spare_queue;
/* The queue we on */
struct umtxq_queue *uq_cur_queue;
};
TAILQ_HEAD(umtxq_head, umtx_q);
/* Per-key wait-queue */
struct umtxq_queue {
struct umtxq_head head;
struct umtx_key key;
LIST_ENTRY(umtxq_queue) link;
int length;
};
LIST_HEAD(umtxq_list, umtxq_queue);
/* Userland lock object's wait-queue chain */
struct umtxq_chain {
/* Lock for this chain. */
struct mtx uc_lock;
/* List of sleep queues. */
struct umtxq_list uc_queue[2];
#define UMTX_SHARED_QUEUE 0
#define UMTX_EXCLUSIVE_QUEUE 1
LIST_HEAD(, umtxq_queue) uc_spare_queue;
/* Busy flag */
char uc_busy;
/* Chain lock waiters */
int uc_waiters;
/* All PI in the list */
TAILQ_HEAD(,umtx_pi) uc_pi_list;
#ifdef UMTX_PROFILING
u_int length;
u_int max_length;
#endif
};
#define UMTXQ_LOCKED_ASSERT(uc) mtx_assert(&(uc)->uc_lock, MA_OWNED)
/*
* Don't propagate time-sharing priority, there is a security reason,
* a user can simply introduce PI-mutex, let thread A lock the mutex,
* and let another thread B block on the mutex, because B is
* sleeping, its priority will be boosted, this causes A's priority to
* be boosted via priority propagating too and will never be lowered even
* if it is using 100%CPU, this is unfair to other processes.
*/
#define UPRI(td) (((td)->td_user_pri >= PRI_MIN_TIMESHARE &&\
(td)->td_user_pri <= PRI_MAX_TIMESHARE) ?\
PRI_MAX_TIMESHARE : (td)->td_user_pri)
#define GOLDEN_RATIO_PRIME 2654404609U
#ifndef UMTX_CHAINS
#define UMTX_CHAINS 512
#endif
#define UMTX_SHIFTS (__WORD_BIT - 9)
#define GET_SHARE(flags) \
(((flags) & USYNC_PROCESS_SHARED) == 0 ? THREAD_SHARE : PROCESS_SHARE)
#define BUSY_SPINS 200
struct abs_timeout {
int clockid;
bool is_abs_real; /* TIMER_ABSTIME && CLOCK_REALTIME* */
struct timespec cur;
struct timespec end;
};
struct umtx_copyops {
int (*copyin_timeout)(const void *uaddr, struct timespec *tsp);
int (*copyin_umtx_time)(const void *uaddr, size_t size,
struct _umtx_time *tp);
int (*copyin_robust_lists)(const void *uaddr, size_t size,
struct umtx_robust_lists_params *rbp);
int (*copyout_timeout)(void *uaddr, size_t size,
struct timespec *tsp);
const size_t timespec_sz;
const size_t umtx_time_sz;
const bool compat32;
};
_Static_assert(sizeof(struct umutex) == sizeof(struct umutex32), "umutex32");
_Static_assert(__offsetof(struct umutex, m_spare[0]) ==
__offsetof(struct umutex32, m_spare[0]), "m_spare32");
int umtx_shm_vnobj_persistent = 0;
SYSCTL_INT(_kern_ipc, OID_AUTO, umtx_vnode_persistent, CTLFLAG_RWTUN,
&umtx_shm_vnobj_persistent, 0,
"False forces destruction of umtx attached to file, on last close");
static int umtx_max_rb = 1000;
SYSCTL_INT(_kern_ipc, OID_AUTO, umtx_max_robust, CTLFLAG_RWTUN,
&umtx_max_rb, 0,
"Maximum number of robust mutexes allowed for each thread");
static uma_zone_t umtx_pi_zone;
static struct umtxq_chain umtxq_chains[2][UMTX_CHAINS];
static MALLOC_DEFINE(M_UMTX, "umtx", "UMTX queue memory");
static int umtx_pi_allocated;
static SYSCTL_NODE(_debug, OID_AUTO, umtx, CTLFLAG_RW | CTLFLAG_MPSAFE, 0,
"umtx debug");
SYSCTL_INT(_debug_umtx, OID_AUTO, umtx_pi_allocated, CTLFLAG_RD,
&umtx_pi_allocated, 0, "Allocated umtx_pi");
static int umtx_verbose_rb = 1;
SYSCTL_INT(_debug_umtx, OID_AUTO, robust_faults_verbose, CTLFLAG_RWTUN,
&umtx_verbose_rb, 0,
"");
#ifdef UMTX_PROFILING
static long max_length;
SYSCTL_LONG(_debug_umtx, OID_AUTO, max_length, CTLFLAG_RD, &max_length, 0, "max_length");
static SYSCTL_NODE(_debug_umtx, OID_AUTO, chains, CTLFLAG_RD | CTLFLAG_MPSAFE, 0,
"umtx chain stats");
#endif
static void abs_timeout_update(struct abs_timeout *timo);
static void umtx_shm_init(void);
static void umtxq_sysinit(void *);
static void umtxq_hash(struct umtx_key *key);
static struct umtxq_chain *umtxq_getchain(struct umtx_key *key);
static void umtxq_lock(struct umtx_key *key);
static void umtxq_unlock(struct umtx_key *key);
static void umtxq_busy(struct umtx_key *key);
static void umtxq_unbusy(struct umtx_key *key);
static void umtxq_insert_queue(struct umtx_q *uq, int q);
static void umtxq_remove_queue(struct umtx_q *uq, int q);
static int umtxq_sleep(struct umtx_q *uq, const char *wmesg, struct abs_timeout *);
static int umtxq_count(struct umtx_key *key);
static struct umtx_pi *umtx_pi_alloc(int);
static void umtx_pi_free(struct umtx_pi *pi);
static int do_unlock_pp(struct thread *td, struct umutex *m, uint32_t flags,
bool rb);
static void umtx_thread_cleanup(struct thread *td);
SYSINIT(umtx, SI_SUB_EVENTHANDLER+1, SI_ORDER_MIDDLE, umtxq_sysinit, NULL);
#define umtxq_signal(key, nwake) umtxq_signal_queue((key), (nwake), UMTX_SHARED_QUEUE)
#define umtxq_insert(uq) umtxq_insert_queue((uq), UMTX_SHARED_QUEUE)
#define umtxq_remove(uq) umtxq_remove_queue((uq), UMTX_SHARED_QUEUE)
static struct mtx umtx_lock;
#ifdef UMTX_PROFILING
static void
umtx_init_profiling(void)
{
struct sysctl_oid *chain_oid;
char chain_name[10];
int i;
for (i = 0; i < UMTX_CHAINS; ++i) {
snprintf(chain_name, sizeof(chain_name), "%d", i);
chain_oid = SYSCTL_ADD_NODE(NULL,
SYSCTL_STATIC_CHILDREN(_debug_umtx_chains), OID_AUTO,
chain_name, CTLFLAG_RD | CTLFLAG_MPSAFE, NULL,
"umtx hash stats");
SYSCTL_ADD_INT(NULL, SYSCTL_CHILDREN(chain_oid), OID_AUTO,
"max_length0", CTLFLAG_RD, &umtxq_chains[0][i].max_length, 0, NULL);
SYSCTL_ADD_INT(NULL, SYSCTL_CHILDREN(chain_oid), OID_AUTO,
"max_length1", CTLFLAG_RD, &umtxq_chains[1][i].max_length, 0, NULL);
}
}
static int
sysctl_debug_umtx_chains_peaks(SYSCTL_HANDLER_ARGS)
{
char buf[512];
struct sbuf sb;
struct umtxq_chain *uc;
u_int fract, i, j, tot, whole;
u_int sf0, sf1, sf2, sf3, sf4;
u_int si0, si1, si2, si3, si4;
u_int sw0, sw1, sw2, sw3, sw4;
sbuf_new(&sb, buf, sizeof(buf), SBUF_FIXEDLEN);
for (i = 0; i < 2; i++) {
tot = 0;
for (j = 0; j < UMTX_CHAINS; ++j) {
uc = &umtxq_chains[i][j];
mtx_lock(&uc->uc_lock);
tot += uc->max_length;
mtx_unlock(&uc->uc_lock);
}
if (tot == 0)
sbuf_printf(&sb, "%u) Empty ", i);
else {
sf0 = sf1 = sf2 = sf3 = sf4 = 0;
si0 = si1 = si2 = si3 = si4 = 0;
sw0 = sw1 = sw2 = sw3 = sw4 = 0;
for (j = 0; j < UMTX_CHAINS; j++) {
uc = &umtxq_chains[i][j];
mtx_lock(&uc->uc_lock);
whole = uc->max_length * 100;
mtx_unlock(&uc->uc_lock);
fract = (whole % tot) * 100;
if (UPROF_PERC_BIGGER(whole, fract, sw0, sf0)) {
sf0 = fract;
si0 = j;
sw0 = whole;
} else if (UPROF_PERC_BIGGER(whole, fract, sw1,
sf1)) {
sf1 = fract;
si1 = j;
sw1 = whole;
} else if (UPROF_PERC_BIGGER(whole, fract, sw2,
sf2)) {
sf2 = fract;
si2 = j;
sw2 = whole;
} else if (UPROF_PERC_BIGGER(whole, fract, sw3,
sf3)) {
sf3 = fract;
si3 = j;
sw3 = whole;
} else if (UPROF_PERC_BIGGER(whole, fract, sw4,
sf4)) {
sf4 = fract;
si4 = j;
sw4 = whole;
}
}
sbuf_printf(&sb, "queue %u:\n", i);
sbuf_printf(&sb, "1st: %u.%u%% idx: %u\n", sw0 / tot,
sf0 / tot, si0);
sbuf_printf(&sb, "2nd: %u.%u%% idx: %u\n", sw1 / tot,
sf1 / tot, si1);
sbuf_printf(&sb, "3rd: %u.%u%% idx: %u\n", sw2 / tot,
sf2 / tot, si2);
sbuf_printf(&sb, "4th: %u.%u%% idx: %u\n", sw3 / tot,
sf3 / tot, si3);
sbuf_printf(&sb, "5th: %u.%u%% idx: %u\n", sw4 / tot,
sf4 / tot, si4);
}
}
sbuf_trim(&sb);
sbuf_finish(&sb);
sysctl_handle_string(oidp, sbuf_data(&sb), sbuf_len(&sb), req);
sbuf_delete(&sb);
return (0);
}
static int
sysctl_debug_umtx_chains_clear(SYSCTL_HANDLER_ARGS)
{
struct umtxq_chain *uc;
u_int i, j;
int clear, error;
clear = 0;
error = sysctl_handle_int(oidp, &clear, 0, req);
if (error != 0 || req->newptr == NULL)
return (error);
if (clear != 0) {
for (i = 0; i < 2; ++i) {
for (j = 0; j < UMTX_CHAINS; ++j) {
uc = &umtxq_chains[i][j];
mtx_lock(&uc->uc_lock);
uc->length = 0;
uc->max_length = 0;
mtx_unlock(&uc->uc_lock);
}
}
}
return (0);
}
SYSCTL_PROC(_debug_umtx_chains, OID_AUTO, clear,
CTLTYPE_INT | CTLFLAG_RW | CTLFLAG_MPSAFE, 0, 0,
sysctl_debug_umtx_chains_clear, "I",
"Clear umtx chains statistics");
SYSCTL_PROC(_debug_umtx_chains, OID_AUTO, peaks,
CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, 0, 0,
sysctl_debug_umtx_chains_peaks, "A",
"Highest peaks in chains max length");
#endif
static void
umtxq_sysinit(void *arg __unused)
{
int i, j;
umtx_pi_zone = uma_zcreate("umtx pi", sizeof(struct umtx_pi),
NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0);
for (i = 0; i < 2; ++i) {
for (j = 0; j < UMTX_CHAINS; ++j) {
mtx_init(&umtxq_chains[i][j].uc_lock, "umtxql", NULL,
MTX_DEF | MTX_DUPOK);
LIST_INIT(&umtxq_chains[i][j].uc_queue[0]);
LIST_INIT(&umtxq_chains[i][j].uc_queue[1]);
LIST_INIT(&umtxq_chains[i][j].uc_spare_queue);
TAILQ_INIT(&umtxq_chains[i][j].uc_pi_list);
umtxq_chains[i][j].uc_busy = 0;
umtxq_chains[i][j].uc_waiters = 0;
#ifdef UMTX_PROFILING
umtxq_chains[i][j].length = 0;
umtxq_chains[i][j].max_length = 0;
#endif
}
}
#ifdef UMTX_PROFILING
umtx_init_profiling();
#endif
mtx_init(&umtx_lock, "umtx lock", NULL, MTX_DEF);
umtx_shm_init();
}
struct umtx_q *
umtxq_alloc(void)
{
struct umtx_q *uq;
uq = malloc(sizeof(struct umtx_q), M_UMTX, M_WAITOK | M_ZERO);
uq->uq_spare_queue = malloc(sizeof(struct umtxq_queue), M_UMTX,
M_WAITOK | M_ZERO);
TAILQ_INIT(&uq->uq_spare_queue->head);
TAILQ_INIT(&uq->uq_pi_contested);
uq->uq_inherited_pri = PRI_MAX;
return (uq);
}
void
umtxq_free(struct umtx_q *uq)
{
MPASS(uq->uq_spare_queue != NULL);
free(uq->uq_spare_queue, M_UMTX);
free(uq, M_UMTX);
}
static inline void
umtxq_hash(struct umtx_key *key)
{
unsigned n;
n = (uintptr_t)key->info.both.a + key->info.both.b;
key->hash = ((n * GOLDEN_RATIO_PRIME) >> UMTX_SHIFTS) % UMTX_CHAINS;
}
static inline struct umtxq_chain *
umtxq_getchain(struct umtx_key *key)
{
if (key->type <= TYPE_SEM)
return (&umtxq_chains[1][key->hash]);
return (&umtxq_chains[0][key->hash]);
}
/*
* Lock a chain.
*/
static inline void
umtxq_lock(struct umtx_key *key)
{
struct umtxq_chain *uc;
uc = umtxq_getchain(key);
mtx_lock(&uc->uc_lock);
}
/*
* Unlock a chain.
*/
static inline void
umtxq_unlock(struct umtx_key *key)
{
struct umtxq_chain *uc;
uc = umtxq_getchain(key);
mtx_unlock(&uc->uc_lock);
}
/*
* Set chain to busy state when following operation
* may be blocked (kernel mutex can not be used).
*/
static inline void
umtxq_busy(struct umtx_key *key)
{
struct umtxq_chain *uc;
uc = umtxq_getchain(key);
mtx_assert(&uc->uc_lock, MA_OWNED);
if (uc->uc_busy) {
#ifdef SMP
if (smp_cpus > 1) {
int count = BUSY_SPINS;
if (count > 0) {
umtxq_unlock(key);
while (uc->uc_busy && --count > 0)
cpu_spinwait();
umtxq_lock(key);
}
}
#endif
while (uc->uc_busy) {
uc->uc_waiters++;
msleep(uc, &uc->uc_lock, 0, "umtxqb", 0);
uc->uc_waiters--;
}
}
uc->uc_busy = 1;
}
/*
* Unbusy a chain.
*/
static inline void
umtxq_unbusy(struct umtx_key *key)
{
struct umtxq_chain *uc;
uc = umtxq_getchain(key);
mtx_assert(&uc->uc_lock, MA_OWNED);
KASSERT(uc->uc_busy != 0, ("not busy"));
uc->uc_busy = 0;
if (uc->uc_waiters)
wakeup_one(uc);
}
static inline void
umtxq_unbusy_unlocked(struct umtx_key *key)
{
umtxq_lock(key);
umtxq_unbusy(key);
umtxq_unlock(key);
}
static struct umtxq_queue *
umtxq_queue_lookup(struct umtx_key *key, int q)
{
struct umtxq_queue *uh;
struct umtxq_chain *uc;
uc = umtxq_getchain(key);
UMTXQ_LOCKED_ASSERT(uc);
LIST_FOREACH(uh, &uc->uc_queue[q], link) {
if (umtx_key_match(&uh->key, key))
return (uh);
}
return (NULL);
}
static inline void
umtxq_insert_queue(struct umtx_q *uq, int q)
{
struct umtxq_queue *uh;
struct umtxq_chain *uc;
uc = umtxq_getchain(&uq->uq_key);
UMTXQ_LOCKED_ASSERT(uc);
KASSERT((uq->uq_flags & UQF_UMTXQ) == 0, ("umtx_q is already on queue"));
uh = umtxq_queue_lookup(&uq->uq_key, q);
if (uh != NULL) {
LIST_INSERT_HEAD(&uc->uc_spare_queue, uq->uq_spare_queue, link);
} else {
uh = uq->uq_spare_queue;
uh->key = uq->uq_key;
LIST_INSERT_HEAD(&uc->uc_queue[q], uh, link);
#ifdef UMTX_PROFILING
uc->length++;
if (uc->length > uc->max_length) {
uc->max_length = uc->length;
if (uc->max_length > max_length)
max_length = uc->max_length;
}
#endif
}
uq->uq_spare_queue = NULL;
TAILQ_INSERT_TAIL(&uh->head, uq, uq_link);
uh->length++;
uq->uq_flags |= UQF_UMTXQ;
uq->uq_cur_queue = uh;
return;
}
static inline void
umtxq_remove_queue(struct umtx_q *uq, int q)
{
struct umtxq_chain *uc;
struct umtxq_queue *uh;
uc = umtxq_getchain(&uq->uq_key);
UMTXQ_LOCKED_ASSERT(uc);
if (uq->uq_flags & UQF_UMTXQ) {
uh = uq->uq_cur_queue;
TAILQ_REMOVE(&uh->head, uq, uq_link);
uh->length--;
uq->uq_flags &= ~UQF_UMTXQ;
if (TAILQ_EMPTY(&uh->head)) {
KASSERT(uh->length == 0,
("inconsistent umtxq_queue length"));
#ifdef UMTX_PROFILING
uc->length--;
#endif
LIST_REMOVE(uh, link);
} else {
uh = LIST_FIRST(&uc->uc_spare_queue);
KASSERT(uh != NULL, ("uc_spare_queue is empty"));
LIST_REMOVE(uh, link);
}
uq->uq_spare_queue = uh;
uq->uq_cur_queue = NULL;
}
}
/*
* Check if there are multiple waiters
*/
static int
umtxq_count(struct umtx_key *key)
{
struct umtxq_queue *uh;
UMTXQ_LOCKED_ASSERT(umtxq_getchain(key));
uh = umtxq_queue_lookup(key, UMTX_SHARED_QUEUE);
if (uh != NULL)
return (uh->length);
return (0);
}
/*
* Check if there are multiple PI waiters and returns first
* waiter.
*/
static int
umtxq_count_pi(struct umtx_key *key, struct umtx_q **first)
{
struct umtxq_queue *uh;
*first = NULL;
UMTXQ_LOCKED_ASSERT(umtxq_getchain(key));
uh = umtxq_queue_lookup(key, UMTX_SHARED_QUEUE);
if (uh != NULL) {
*first = TAILQ_FIRST(&uh->head);
return (uh->length);
}
return (0);
}
/*
* Wake up threads waiting on an userland object.
*/
static int
umtxq_signal_queue(struct umtx_key *key, int n_wake, int q)
{
struct umtxq_queue *uh;
struct umtx_q *uq;
int ret;
ret = 0;
UMTXQ_LOCKED_ASSERT(umtxq_getchain(key));
uh = umtxq_queue_lookup(key, q);
if (uh != NULL) {
while ((uq = TAILQ_FIRST(&uh->head)) != NULL) {
umtxq_remove_queue(uq, q);
wakeup(uq);
if (++ret >= n_wake)
return (ret);
}
}
return (ret);
}
/*
* Wake up specified thread.
*/
static inline void
umtxq_signal_thread(struct umtx_q *uq)
{
UMTXQ_LOCKED_ASSERT(umtxq_getchain(&uq->uq_key));
umtxq_remove(uq);
wakeup(uq);
}
static inline int
tstohz(const struct timespec *tsp)
{
struct timeval tv;
TIMESPEC_TO_TIMEVAL(&tv, tsp);
return tvtohz(&tv);
}
static void
abs_timeout_init(struct abs_timeout *timo, int clockid, int absolute,
const struct timespec *timeout)
{
timo->clockid = clockid;
if (!absolute) {
timo->is_abs_real = false;
abs_timeout_update(timo);
timespecadd(&timo->cur, timeout, &timo->end);
} else {
timo->end = *timeout;
timo->is_abs_real = clockid == CLOCK_REALTIME ||
clockid == CLOCK_REALTIME_FAST ||
clockid == CLOCK_REALTIME_PRECISE;
/*
* If is_abs_real, umtxq_sleep will read the clock
* after setting td_rtcgen; otherwise, read it here.
*/
if (!timo->is_abs_real) {
abs_timeout_update(timo);
}
}
}
static void
abs_timeout_init2(struct abs_timeout *timo, const struct _umtx_time *umtxtime)
{
abs_timeout_init(timo, umtxtime->_clockid,
(umtxtime->_flags & UMTX_ABSTIME) != 0, &umtxtime->_timeout);
}
static inline void
abs_timeout_update(struct abs_timeout *timo)
{
kern_clock_gettime(curthread, timo->clockid, &timo->cur);
}
static int
abs_timeout_gethz(struct abs_timeout *timo)
{
struct timespec tts;
if (timespeccmp(&timo->end, &timo->cur, <=))
return (-1);
timespecsub(&timo->end, &timo->cur, &tts);
return (tstohz(&tts));
}
static uint32_t
umtx_unlock_val(uint32_t flags, bool rb)
{
if (rb)
return (UMUTEX_RB_OWNERDEAD);
else if ((flags & UMUTEX_NONCONSISTENT) != 0)
return (UMUTEX_RB_NOTRECOV);
else
return (UMUTEX_UNOWNED);
}
/*
* Put thread into sleep state, before sleeping, check if
* thread was removed from umtx queue.
*/
static inline int
umtxq_sleep(struct umtx_q *uq, const char *wmesg, struct abs_timeout *abstime)
{
struct umtxq_chain *uc;
int error, timo;
if (abstime != NULL && abstime->is_abs_real) {
curthread->td_rtcgen = atomic_load_acq_int(&rtc_generation);
abs_timeout_update(abstime);
}
uc = umtxq_getchain(&uq->uq_key);
UMTXQ_LOCKED_ASSERT(uc);
for (;;) {
if (!(uq->uq_flags & UQF_UMTXQ)) {
error = 0;
break;
}
if (abstime != NULL) {
timo = abs_timeout_gethz(abstime);
if (timo < 0) {
error = ETIMEDOUT;
break;
}
} else
timo = 0;
error = msleep(uq, &uc->uc_lock, PCATCH | PDROP, wmesg, timo);
if (error == EINTR || error == ERESTART) {
umtxq_lock(&uq->uq_key);
break;
}
if (abstime != NULL) {
if (abstime->is_abs_real)
curthread->td_rtcgen =
atomic_load_acq_int(&rtc_generation);
abs_timeout_update(abstime);
}
umtxq_lock(&uq->uq_key);
}
curthread->td_rtcgen = 0;
return (error);
}
/*
* Convert userspace address into unique logical address.
*/
int
umtx_key_get(const void *addr, int type, int share, struct umtx_key *key)
{
struct thread *td = curthread;
vm_map_t map;
vm_map_entry_t entry;
vm_pindex_t pindex;
vm_prot_t prot;
boolean_t wired;
key->type = type;
if (share == THREAD_SHARE) {
key->shared = 0;
key->info.private.vs = td->td_proc->p_vmspace;
key->info.private.addr = (uintptr_t)addr;
} else {
MPASS(share == PROCESS_SHARE || share == AUTO_SHARE);
map = &td->td_proc->p_vmspace->vm_map;
if (vm_map_lookup(&map, (vm_offset_t)addr, VM_PROT_WRITE,
&entry, &key->info.shared.object, &pindex, &prot,
&wired) != KERN_SUCCESS) {
return (EFAULT);
}
if ((share == PROCESS_SHARE) ||
(share == AUTO_SHARE &&
VM_INHERIT_SHARE == entry->inheritance)) {
key->shared = 1;
key->info.shared.offset = (vm_offset_t)addr -
entry->start + entry->offset;
vm_object_reference(key->info.shared.object);
} else {
key->shared = 0;
key->info.private.vs = td->td_proc->p_vmspace;
key->info.private.addr = (uintptr_t)addr;
}
vm_map_lookup_done(map, entry);
}
umtxq_hash(key);
return (0);
}
/*
* Release key.
*/
void
umtx_key_release(struct umtx_key *key)
{
if (key->shared)
vm_object_deallocate(key->info.shared.object);
}
/*
* Fetch and compare value, sleep on the address if value is not changed.
*/
static int
do_wait(struct thread *td, void *addr, u_long id,
struct _umtx_time *timeout, int compat32, int is_private)
{
struct abs_timeout timo;
struct umtx_q *uq;
u_long tmp;
uint32_t tmp32;
int error = 0;
uq = td->td_umtxq;
if ((error = umtx_key_get(addr, TYPE_SIMPLE_WAIT,
is_private ? THREAD_SHARE : AUTO_SHARE, &uq->uq_key)) != 0)
return (error);
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
umtxq_lock(&uq->uq_key);
umtxq_insert(uq);
umtxq_unlock(&uq->uq_key);
if (compat32 == 0) {
error = fueword(addr, &tmp);
if (error != 0)
error = EFAULT;
} else {
error = fueword32(addr, &tmp32);
if (error == 0)
tmp = tmp32;
else
error = EFAULT;
}
umtxq_lock(&uq->uq_key);
if (error == 0) {
if (tmp == id)
error = umtxq_sleep(uq, "uwait", timeout == NULL ?
NULL : &timo);
if ((uq->uq_flags & UQF_UMTXQ) == 0)
error = 0;
else
umtxq_remove(uq);
} else if ((uq->uq_flags & UQF_UMTXQ) != 0) {
umtxq_remove(uq);
}
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
if (error == ERESTART)
error = EINTR;
return (error);
}
/*
* Wake up threads sleeping on the specified address.
*/
int
kern_umtx_wake(struct thread *td, void *uaddr, int n_wake, int is_private)
{
struct umtx_key key;
int ret;
if ((ret = umtx_key_get(uaddr, TYPE_SIMPLE_WAIT,
is_private ? THREAD_SHARE : AUTO_SHARE, &key)) != 0)
return (ret);
umtxq_lock(&key);
umtxq_signal(&key, n_wake);
umtxq_unlock(&key);
umtx_key_release(&key);
return (0);
}
/*
* Lock PTHREAD_PRIO_NONE protocol POSIX mutex.
*/
static int
do_lock_normal(struct thread *td, struct umutex *m, uint32_t flags,
struct _umtx_time *timeout, int mode)
{
struct abs_timeout timo;
struct umtx_q *uq;
uint32_t owner, old, id;
int error, rv;
id = td->td_tid;
uq = td->td_umtxq;
error = 0;
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
/*
* Care must be exercised when dealing with umtx structure. It
* can fault on any access.
*/
for (;;) {
rv = fueword32(&m->m_owner, &owner);
if (rv == -1)
return (EFAULT);
if (mode == _UMUTEX_WAIT) {
if (owner == UMUTEX_UNOWNED ||
owner == UMUTEX_CONTESTED ||
owner == UMUTEX_RB_OWNERDEAD ||
owner == UMUTEX_RB_NOTRECOV)
return (0);
} else {
/*
* Robust mutex terminated. Kernel duty is to
* return EOWNERDEAD to the userspace. The
* umutex.m_flags UMUTEX_NONCONSISTENT is set
* by the common userspace code.
*/
if (owner == UMUTEX_RB_OWNERDEAD) {
rv = casueword32(&m->m_owner,
UMUTEX_RB_OWNERDEAD, &owner,
id | UMUTEX_CONTESTED);
if (rv == -1)
return (EFAULT);
if (rv == 0) {
MPASS(owner == UMUTEX_RB_OWNERDEAD);
return (EOWNERDEAD); /* success */
}
MPASS(rv == 1);
rv = thread_check_susp(td, false);
if (rv != 0)
return (rv);
continue;
}
if (owner == UMUTEX_RB_NOTRECOV)
return (ENOTRECOVERABLE);
/*
* Try the uncontested case. This should be
* done in userland.
*/
rv = casueword32(&m->m_owner, UMUTEX_UNOWNED,
&owner, id);
/* The address was invalid. */
if (rv == -1)
return (EFAULT);
/* The acquire succeeded. */
if (rv == 0) {
MPASS(owner == UMUTEX_UNOWNED);
return (0);
}
/*
* If no one owns it but it is contested try
* to acquire it.
*/
MPASS(rv == 1);
if (owner == UMUTEX_CONTESTED) {
rv = casueword32(&m->m_owner,
UMUTEX_CONTESTED, &owner,
id | UMUTEX_CONTESTED);
/* The address was invalid. */
if (rv == -1)
return (EFAULT);
if (rv == 0) {
MPASS(owner == UMUTEX_CONTESTED);
return (0);
}
if (rv == 1) {
rv = thread_check_susp(td, false);
if (rv != 0)
return (rv);
}
/*
* If this failed the lock has
* changed, restart.
*/
continue;
}
/* rv == 1 but not contested, likely store failure */
rv = thread_check_susp(td, false);
if (rv != 0)
return (rv);
}
if (mode == _UMUTEX_TRY)
return (EBUSY);
/*
* If we caught a signal, we have retried and now
* exit immediately.
*/
if (error != 0)
return (error);
if ((error = umtx_key_get(m, TYPE_NORMAL_UMUTEX,
GET_SHARE(flags), &uq->uq_key)) != 0)
return (error);
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_insert(uq);
umtxq_unlock(&uq->uq_key);
/*
* Set the contested bit so that a release in user space
* knows to use the system call for unlock. If this fails
* either some one else has acquired the lock or it has been
* released.
*/
rv = casueword32(&m->m_owner, owner, &old,
owner | UMUTEX_CONTESTED);
/* The address was invalid or casueword failed to store. */
if (rv == -1 || rv == 1) {
umtxq_lock(&uq->uq_key);
umtxq_remove(uq);
umtxq_unbusy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
if (rv == -1)
return (EFAULT);
if (rv == 1) {
rv = thread_check_susp(td, false);
if (rv != 0)
return (rv);
}
continue;
}
/*
* We set the contested bit, sleep. Otherwise the lock changed
* and we need to retry or we lost a race to the thread
* unlocking the umtx.
*/
umtxq_lock(&uq->uq_key);
umtxq_unbusy(&uq->uq_key);
MPASS(old == owner);
error = umtxq_sleep(uq, "umtxn", timeout == NULL ?
NULL : &timo);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
if (error == 0)
error = thread_check_susp(td, false);
}
return (0);
}
/*
* Unlock PTHREAD_PRIO_NONE protocol POSIX mutex.
*/
static int
do_unlock_normal(struct thread *td, struct umutex *m, uint32_t flags, bool rb)
{
struct umtx_key key;
uint32_t owner, old, id, newlock;
int error, count;
id = td->td_tid;
again:
/*
* Make sure we own this mtx.
*/
error = fueword32(&m->m_owner, &owner);
if (error == -1)
return (EFAULT);
if ((owner & ~UMUTEX_CONTESTED) != id)
return (EPERM);
newlock = umtx_unlock_val(flags, rb);
if ((owner & UMUTEX_CONTESTED) == 0) {
error = casueword32(&m->m_owner, owner, &old, newlock);
if (error == -1)
return (EFAULT);
if (error == 1) {
error = thread_check_susp(td, false);
if (error != 0)
return (error);
goto again;
}
MPASS(old == owner);
return (0);
}
/* We should only ever be in here for contested locks */
if ((error = umtx_key_get(m, TYPE_NORMAL_UMUTEX, GET_SHARE(flags),
&key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
count = umtxq_count(&key);
umtxq_unlock(&key);
/*
* When unlocking the umtx, it must be marked as unowned if
* there is zero or one thread only waiting for it.
* Otherwise, it must be marked as contested.
*/
if (count > 1)
newlock |= UMUTEX_CONTESTED;
error = casueword32(&m->m_owner, owner, &old, newlock);
umtxq_lock(&key);
umtxq_signal(&key, 1);
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
if (error == -1)
return (EFAULT);
if (error == 1) {
if (old != owner)
return (EINVAL);
error = thread_check_susp(td, false);
if (error != 0)
return (error);
goto again;
}
return (0);
}
/*
* Check if the mutex is available and wake up a waiter,
* only for simple mutex.
*/
static int
do_wake_umutex(struct thread *td, struct umutex *m)
{
struct umtx_key key;
uint32_t owner;
uint32_t flags;
int error;
int count;
again:
error = fueword32(&m->m_owner, &owner);
if (error == -1)
return (EFAULT);
if ((owner & ~UMUTEX_CONTESTED) != 0 && owner != UMUTEX_RB_OWNERDEAD &&
owner != UMUTEX_RB_NOTRECOV)
return (0);
error = fueword32(&m->m_flags, &flags);
if (error == -1)
return (EFAULT);
/* We should only ever be in here for contested locks */
if ((error = umtx_key_get(m, TYPE_NORMAL_UMUTEX, GET_SHARE(flags),
&key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
count = umtxq_count(&key);
umtxq_unlock(&key);
if (count <= 1 && owner != UMUTEX_RB_OWNERDEAD &&
owner != UMUTEX_RB_NOTRECOV) {
error = casueword32(&m->m_owner, UMUTEX_CONTESTED, &owner,
UMUTEX_UNOWNED);
if (error == -1) {
error = EFAULT;
} else if (error == 1) {
umtxq_lock(&key);
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
error = thread_check_susp(td, false);
if (error != 0)
return (error);
goto again;
}
}
umtxq_lock(&key);
if (error == 0 && count != 0) {
MPASS((owner & ~UMUTEX_CONTESTED) == 0 ||
owner == UMUTEX_RB_OWNERDEAD ||
owner == UMUTEX_RB_NOTRECOV);
umtxq_signal(&key, 1);
}
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
return (error);
}
/*
* Check if the mutex has waiters and tries to fix contention bit.
*/
static int
do_wake2_umutex(struct thread *td, struct umutex *m, uint32_t flags)
{
struct umtx_key key;
uint32_t owner, old;
int type;
int error;
int count;
switch (flags & (UMUTEX_PRIO_INHERIT | UMUTEX_PRIO_PROTECT |
UMUTEX_ROBUST)) {
case 0:
case UMUTEX_ROBUST:
type = TYPE_NORMAL_UMUTEX;
break;
case UMUTEX_PRIO_INHERIT:
type = TYPE_PI_UMUTEX;
break;
case (UMUTEX_PRIO_INHERIT | UMUTEX_ROBUST):
type = TYPE_PI_ROBUST_UMUTEX;
break;
case UMUTEX_PRIO_PROTECT:
type = TYPE_PP_UMUTEX;
break;
case (UMUTEX_PRIO_PROTECT | UMUTEX_ROBUST):
type = TYPE_PP_ROBUST_UMUTEX;
break;
default:
return (EINVAL);
}
if ((error = umtx_key_get(m, type, GET_SHARE(flags), &key)) != 0)
return (error);
owner = 0;
umtxq_lock(&key);
umtxq_busy(&key);
count = umtxq_count(&key);
umtxq_unlock(&key);
error = fueword32(&m->m_owner, &owner);
if (error == -1)
error = EFAULT;
/*
* Only repair contention bit if there is a waiter, this means
* the mutex is still being referenced by userland code,
* otherwise don't update any memory.
*/
while (error == 0 && (owner & UMUTEX_CONTESTED) == 0 &&
(count > 1 || (count == 1 && (owner & ~UMUTEX_CONTESTED) != 0))) {
error = casueword32(&m->m_owner, owner, &old,
owner | UMUTEX_CONTESTED);
if (error == -1) {
error = EFAULT;
break;
}
if (error == 0) {
MPASS(old == owner);
break;
}
owner = old;
error = thread_check_susp(td, false);
}
umtxq_lock(&key);
if (error == EFAULT) {
umtxq_signal(&key, INT_MAX);
} else if (count != 0 && ((owner & ~UMUTEX_CONTESTED) == 0 ||
owner == UMUTEX_RB_OWNERDEAD || owner == UMUTEX_RB_NOTRECOV))
umtxq_signal(&key, 1);
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
return (error);
}
static inline struct umtx_pi *
umtx_pi_alloc(int flags)
{
struct umtx_pi *pi;
pi = uma_zalloc(umtx_pi_zone, M_ZERO | flags);
TAILQ_INIT(&pi->pi_blocked);
atomic_add_int(&umtx_pi_allocated, 1);
return (pi);
}
static inline void
umtx_pi_free(struct umtx_pi *pi)
{
uma_zfree(umtx_pi_zone, pi);
atomic_add_int(&umtx_pi_allocated, -1);
}
/*
* Adjust the thread's position on a pi_state after its priority has been
* changed.
*/
static int
umtx_pi_adjust_thread(struct umtx_pi *pi, struct thread *td)
{
struct umtx_q *uq, *uq1, *uq2;
struct thread *td1;
mtx_assert(&umtx_lock, MA_OWNED);
if (pi == NULL)
return (0);
uq = td->td_umtxq;
/*
* Check if the thread needs to be moved on the blocked chain.
* It needs to be moved if either its priority is lower than
* the previous thread or higher than the next thread.
*/
uq1 = TAILQ_PREV(uq, umtxq_head, uq_lockq);
uq2 = TAILQ_NEXT(uq, uq_lockq);
if ((uq1 != NULL && UPRI(td) < UPRI(uq1->uq_thread)) ||
(uq2 != NULL && UPRI(td) > UPRI(uq2->uq_thread))) {
/*
* Remove thread from blocked chain and determine where
* it should be moved to.
*/
TAILQ_REMOVE(&pi->pi_blocked, uq, uq_lockq);
TAILQ_FOREACH(uq1, &pi->pi_blocked, uq_lockq) {
td1 = uq1->uq_thread;
MPASS(td1->td_proc->p_magic == P_MAGIC);
if (UPRI(td1) > UPRI(td))
break;
}
if (uq1 == NULL)
TAILQ_INSERT_TAIL(&pi->pi_blocked, uq, uq_lockq);
else
TAILQ_INSERT_BEFORE(uq1, uq, uq_lockq);
}
return (1);
}
static struct umtx_pi *
umtx_pi_next(struct umtx_pi *pi)
{
struct umtx_q *uq_owner;
if (pi->pi_owner == NULL)
return (NULL);
uq_owner = pi->pi_owner->td_umtxq;
if (uq_owner == NULL)
return (NULL);
return (uq_owner->uq_pi_blocked);
}
/*
* Floyd's Cycle-Finding Algorithm.
*/
static bool
umtx_pi_check_loop(struct umtx_pi *pi)
{
struct umtx_pi *pi1; /* fast iterator */
mtx_assert(&umtx_lock, MA_OWNED);
if (pi == NULL)
return (false);
pi1 = pi;
for (;;) {
pi = umtx_pi_next(pi);
if (pi == NULL)
break;
pi1 = umtx_pi_next(pi1);
if (pi1 == NULL)
break;
pi1 = umtx_pi_next(pi1);
if (pi1 == NULL)
break;
if (pi == pi1)
return (true);
}
return (false);
}
/*
* Propagate priority when a thread is blocked on POSIX
* PI mutex.
*/
static void
umtx_propagate_priority(struct thread *td)
{
struct umtx_q *uq;
struct umtx_pi *pi;
int pri;
mtx_assert(&umtx_lock, MA_OWNED);
pri = UPRI(td);
uq = td->td_umtxq;
pi = uq->uq_pi_blocked;
if (pi == NULL)
return;
if (umtx_pi_check_loop(pi))
return;
for (;;) {
td = pi->pi_owner;
if (td == NULL || td == curthread)
return;
MPASS(td->td_proc != NULL);
MPASS(td->td_proc->p_magic == P_MAGIC);
thread_lock(td);
if (td->td_lend_user_pri > pri)
sched_lend_user_prio(td, pri);
else {
thread_unlock(td);
break;
}
thread_unlock(td);
/*
* Pick up the lock that td is blocked on.
*/
uq = td->td_umtxq;
pi = uq->uq_pi_blocked;
if (pi == NULL)
break;
/* Resort td on the list if needed. */
umtx_pi_adjust_thread(pi, td);
}
}
/*
* Unpropagate priority for a PI mutex when a thread blocked on
* it is interrupted by signal or resumed by others.
*/
static void
umtx_repropagate_priority(struct umtx_pi *pi)
{
struct umtx_q *uq, *uq_owner;
struct umtx_pi *pi2;
int pri;
mtx_assert(&umtx_lock, MA_OWNED);
if (umtx_pi_check_loop(pi))
return;
while (pi != NULL && pi->pi_owner != NULL) {
pri = PRI_MAX;
uq_owner = pi->pi_owner->td_umtxq;
TAILQ_FOREACH(pi2, &uq_owner->uq_pi_contested, pi_link) {
uq = TAILQ_FIRST(&pi2->pi_blocked);
if (uq != NULL) {
if (pri > UPRI(uq->uq_thread))
pri = UPRI(uq->uq_thread);
}
}
if (pri > uq_owner->uq_inherited_pri)
pri = uq_owner->uq_inherited_pri;
thread_lock(pi->pi_owner);
sched_lend_user_prio(pi->pi_owner, pri);
thread_unlock(pi->pi_owner);
if ((pi = uq_owner->uq_pi_blocked) != NULL)
umtx_pi_adjust_thread(pi, uq_owner->uq_thread);
}
}
/*
* Insert a PI mutex into owned list.
*/
static void
umtx_pi_setowner(struct umtx_pi *pi, struct thread *owner)
{
struct umtx_q *uq_owner;
uq_owner = owner->td_umtxq;
mtx_assert(&umtx_lock, MA_OWNED);
MPASS(pi->pi_owner == NULL);
pi->pi_owner = owner;
TAILQ_INSERT_TAIL(&uq_owner->uq_pi_contested, pi, pi_link);
}
/*
* Disown a PI mutex, and remove it from the owned list.
*/
static void
umtx_pi_disown(struct umtx_pi *pi)
{
mtx_assert(&umtx_lock, MA_OWNED);
TAILQ_REMOVE(&pi->pi_owner->td_umtxq->uq_pi_contested, pi, pi_link);
pi->pi_owner = NULL;
}
/*
* Claim ownership of a PI mutex.
*/
static int
umtx_pi_claim(struct umtx_pi *pi, struct thread *owner)
{
struct umtx_q *uq;
int pri;
mtx_lock(&umtx_lock);
if (pi->pi_owner == owner) {
mtx_unlock(&umtx_lock);
return (0);
}
if (pi->pi_owner != NULL) {
/*
* userland may have already messed the mutex, sigh.
*/
mtx_unlock(&umtx_lock);
return (EPERM);
}
umtx_pi_setowner(pi, owner);
uq = TAILQ_FIRST(&pi->pi_blocked);
if (uq != NULL) {
pri = UPRI(uq->uq_thread);
thread_lock(owner);
if (pri < UPRI(owner))
sched_lend_user_prio(owner, pri);
thread_unlock(owner);
}
mtx_unlock(&umtx_lock);
return (0);
}
/*
* Adjust a thread's order position in its blocked PI mutex,
* this may result new priority propagating process.
*/
void
umtx_pi_adjust(struct thread *td, u_char oldpri)
{
struct umtx_q *uq;
struct umtx_pi *pi;
uq = td->td_umtxq;
mtx_lock(&umtx_lock);
/*
* Pick up the lock that td is blocked on.
*/
pi = uq->uq_pi_blocked;
if (pi != NULL) {
umtx_pi_adjust_thread(pi, td);
umtx_repropagate_priority(pi);
}
mtx_unlock(&umtx_lock);
}
/*
* Sleep on a PI mutex.
*/
static int
umtxq_sleep_pi(struct umtx_q *uq, struct umtx_pi *pi, uint32_t owner,
const char *wmesg, struct abs_timeout *timo, bool shared)
{
struct thread *td, *td1;
struct umtx_q *uq1;
int error, pri;
#ifdef INVARIANTS
struct umtxq_chain *uc;
uc = umtxq_getchain(&pi->pi_key);
#endif
error = 0;
td = uq->uq_thread;
KASSERT(td == curthread, ("inconsistent uq_thread"));
UMTXQ_LOCKED_ASSERT(umtxq_getchain(&uq->uq_key));
KASSERT(uc->uc_busy != 0, ("umtx chain is not busy"));
umtxq_insert(uq);
mtx_lock(&umtx_lock);
if (pi->pi_owner == NULL) {
mtx_unlock(&umtx_lock);
td1 = tdfind(owner, shared ? -1 : td->td_proc->p_pid);
mtx_lock(&umtx_lock);
if (td1 != NULL) {
if (pi->pi_owner == NULL)
umtx_pi_setowner(pi, td1);
PROC_UNLOCK(td1->td_proc);
}
}
TAILQ_FOREACH(uq1, &pi->pi_blocked, uq_lockq) {
pri = UPRI(uq1->uq_thread);
if (pri > UPRI(td))
break;
}
if (uq1 != NULL)
TAILQ_INSERT_BEFORE(uq1, uq, uq_lockq);
else
TAILQ_INSERT_TAIL(&pi->pi_blocked, uq, uq_lockq);
uq->uq_pi_blocked = pi;
thread_lock(td);
td->td_flags |= TDF_UPIBLOCKED;
thread_unlock(td);
umtx_propagate_priority(td);
mtx_unlock(&umtx_lock);
umtxq_unbusy(&uq->uq_key);
error = umtxq_sleep(uq, wmesg, timo);
umtxq_remove(uq);
mtx_lock(&umtx_lock);
uq->uq_pi_blocked = NULL;
thread_lock(td);
td->td_flags &= ~TDF_UPIBLOCKED;
thread_unlock(td);
TAILQ_REMOVE(&pi->pi_blocked, uq, uq_lockq);
umtx_repropagate_priority(pi);
mtx_unlock(&umtx_lock);
umtxq_unlock(&uq->uq_key);
return (error);
}
/*
* Add reference count for a PI mutex.
*/
static void
umtx_pi_ref(struct umtx_pi *pi)
{
UMTXQ_LOCKED_ASSERT(umtxq_getchain(&pi->pi_key));
pi->pi_refcount++;
}
/*
* Decrease reference count for a PI mutex, if the counter
* is decreased to zero, its memory space is freed.
*/
static void
umtx_pi_unref(struct umtx_pi *pi)
{
struct umtxq_chain *uc;
uc = umtxq_getchain(&pi->pi_key);
UMTXQ_LOCKED_ASSERT(uc);
KASSERT(pi->pi_refcount > 0, ("invalid reference count"));
if (--pi->pi_refcount == 0) {
mtx_lock(&umtx_lock);
if (pi->pi_owner != NULL)
umtx_pi_disown(pi);
KASSERT(TAILQ_EMPTY(&pi->pi_blocked),
("blocked queue not empty"));
mtx_unlock(&umtx_lock);
TAILQ_REMOVE(&uc->uc_pi_list, pi, pi_hashlink);
umtx_pi_free(pi);
}
}
/*
* Find a PI mutex in hash table.
*/
static struct umtx_pi *
umtx_pi_lookup(struct umtx_key *key)
{
struct umtxq_chain *uc;
struct umtx_pi *pi;
uc = umtxq_getchain(key);
UMTXQ_LOCKED_ASSERT(uc);
TAILQ_FOREACH(pi, &uc->uc_pi_list, pi_hashlink) {
if (umtx_key_match(&pi->pi_key, key)) {
return (pi);
}
}
return (NULL);
}
/*
* Insert a PI mutex into hash table.
*/
static inline void
umtx_pi_insert(struct umtx_pi *pi)
{
struct umtxq_chain *uc;
uc = umtxq_getchain(&pi->pi_key);
UMTXQ_LOCKED_ASSERT(uc);
TAILQ_INSERT_TAIL(&uc->uc_pi_list, pi, pi_hashlink);
}
/*
* Lock a PI mutex.
*/
static int
do_lock_pi(struct thread *td, struct umutex *m, uint32_t flags,
struct _umtx_time *timeout, int try)
{
struct abs_timeout timo;
struct umtx_q *uq;
struct umtx_pi *pi, *new_pi;
uint32_t id, old_owner, owner, old;
int error, rv;
id = td->td_tid;
uq = td->td_umtxq;
if ((error = umtx_key_get(m, (flags & UMUTEX_ROBUST) != 0 ?
TYPE_PI_ROBUST_UMUTEX : TYPE_PI_UMUTEX, GET_SHARE(flags),
&uq->uq_key)) != 0)
return (error);
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
umtxq_lock(&uq->uq_key);
pi = umtx_pi_lookup(&uq->uq_key);
if (pi == NULL) {
new_pi = umtx_pi_alloc(M_NOWAIT);
if (new_pi == NULL) {
umtxq_unlock(&uq->uq_key);
new_pi = umtx_pi_alloc(M_WAITOK);
umtxq_lock(&uq->uq_key);
pi = umtx_pi_lookup(&uq->uq_key);
if (pi != NULL) {
umtx_pi_free(new_pi);
new_pi = NULL;
}
}
if (new_pi != NULL) {
new_pi->pi_key = uq->uq_key;
umtx_pi_insert(new_pi);
pi = new_pi;
}
}
umtx_pi_ref(pi);
umtxq_unlock(&uq->uq_key);
/*
* Care must be exercised when dealing with umtx structure. It
* can fault on any access.
*/
for (;;) {
/*
* Try the uncontested case. This should be done in userland.
*/
rv = casueword32(&m->m_owner, UMUTEX_UNOWNED, &owner, id);
/* The address was invalid. */
if (rv == -1) {
error = EFAULT;
break;
}
/* The acquire succeeded. */
if (rv == 0) {
MPASS(owner == UMUTEX_UNOWNED);
error = 0;
break;
}
if (owner == UMUTEX_RB_NOTRECOV) {
error = ENOTRECOVERABLE;
break;
}
/*
* Avoid overwriting a possible error from sleep due
* to the pending signal with suspension check result.
*/
if (error == 0) {
error = thread_check_susp(td, true);
if (error != 0)
break;
}
/* If no one owns it but it is contested try to acquire it. */
if (owner == UMUTEX_CONTESTED || owner == UMUTEX_RB_OWNERDEAD) {
old_owner = owner;
rv = casueword32(&m->m_owner, owner, &owner,
id | UMUTEX_CONTESTED);
/* The address was invalid. */
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 1) {
if (error == 0) {
error = thread_check_susp(td, true);
if (error != 0)
break;
}
/*
* If this failed the lock could
* changed, restart.
*/
continue;
}
MPASS(rv == 0);
MPASS(owner == old_owner);
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
error = umtx_pi_claim(pi, td);
umtxq_unbusy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
if (error != 0) {
/*
* Since we're going to return an
* error, restore the m_owner to its
* previous, unowned state to avoid
* compounding the problem.
*/
(void)casuword32(&m->m_owner,
id | UMUTEX_CONTESTED, old_owner);
}
if (error == 0 && old_owner == UMUTEX_RB_OWNERDEAD)
error = EOWNERDEAD;
break;
}
if ((owner & ~UMUTEX_CONTESTED) == id) {
error = EDEADLK;
break;
}
if (try != 0) {
error = EBUSY;
break;
}
/*
* If we caught a signal, we have retried and now
* exit immediately.
*/
if (error != 0)
break;
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
/*
* Set the contested bit so that a release in user space
* knows to use the system call for unlock. If this fails
* either some one else has acquired the lock or it has been
* released.
*/
rv = casueword32(&m->m_owner, owner, &old, owner |
UMUTEX_CONTESTED);
/* The address was invalid. */
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
if (rv == 1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = thread_check_susp(td, true);
if (error != 0)
break;
/*
* The lock changed and we need to retry or we
* lost a race to the thread unlocking the
* umtx. Note that the UMUTEX_RB_OWNERDEAD
* value for owner is impossible there.
*/
continue;
}
umtxq_lock(&uq->uq_key);
/* We set the contested bit, sleep. */
MPASS(old == owner);
error = umtxq_sleep_pi(uq, pi, owner & ~UMUTEX_CONTESTED,
"umtxpi", timeout == NULL ? NULL : &timo,
(flags & USYNC_PROCESS_SHARED) != 0);
if (error != 0)
continue;
error = thread_check_susp(td, false);
if (error != 0)
break;
}
umtxq_lock(&uq->uq_key);
umtx_pi_unref(pi);
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
return (error);
}
/*
* Unlock a PI mutex.
*/
static int
do_unlock_pi(struct thread *td, struct umutex *m, uint32_t flags, bool rb)
{
struct umtx_key key;
struct umtx_q *uq_first, *uq_first2, *uq_me;
struct umtx_pi *pi, *pi2;
uint32_t id, new_owner, old, owner;
int count, error, pri;
id = td->td_tid;
usrloop:
/*
* Make sure we own this mtx.
*/
error = fueword32(&m->m_owner, &owner);
if (error == -1)
return (EFAULT);
if ((owner & ~UMUTEX_CONTESTED) != id)
return (EPERM);
new_owner = umtx_unlock_val(flags, rb);
/* This should be done in userland */
if ((owner & UMUTEX_CONTESTED) == 0) {
error = casueword32(&m->m_owner, owner, &old, new_owner);
if (error == -1)
return (EFAULT);
if (error == 1) {
error = thread_check_susp(td, true);
if (error != 0)
return (error);
goto usrloop;
}
if (old == owner)
return (0);
owner = old;
}
/* We should only ever be in here for contested locks */
if ((error = umtx_key_get(m, (flags & UMUTEX_ROBUST) != 0 ?
TYPE_PI_ROBUST_UMUTEX : TYPE_PI_UMUTEX, GET_SHARE(flags),
&key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
count = umtxq_count_pi(&key, &uq_first);
if (uq_first != NULL) {
mtx_lock(&umtx_lock);
pi = uq_first->uq_pi_blocked;
KASSERT(pi != NULL, ("pi == NULL?"));
if (pi->pi_owner != td && !(rb && pi->pi_owner == NULL)) {
mtx_unlock(&umtx_lock);
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
/* userland messed the mutex */
return (EPERM);
}
uq_me = td->td_umtxq;
if (pi->pi_owner == td)
umtx_pi_disown(pi);
/* get highest priority thread which is still sleeping. */
uq_first = TAILQ_FIRST(&pi->pi_blocked);
while (uq_first != NULL &&
(uq_first->uq_flags & UQF_UMTXQ) == 0) {
uq_first = TAILQ_NEXT(uq_first, uq_lockq);
}
pri = PRI_MAX;
TAILQ_FOREACH(pi2, &uq_me->uq_pi_contested, pi_link) {
uq_first2 = TAILQ_FIRST(&pi2->pi_blocked);
if (uq_first2 != NULL) {
if (pri > UPRI(uq_first2->uq_thread))
pri = UPRI(uq_first2->uq_thread);
}
}
thread_lock(td);
sched_lend_user_prio(td, pri);
thread_unlock(td);
mtx_unlock(&umtx_lock);
if (uq_first)
umtxq_signal_thread(uq_first);
} else {
pi = umtx_pi_lookup(&key);
/*
* A umtx_pi can exist if a signal or timeout removed the
* last waiter from the umtxq, but there is still
* a thread in do_lock_pi() holding the umtx_pi.
*/
if (pi != NULL) {
/*
* The umtx_pi can be unowned, such as when a thread
* has just entered do_lock_pi(), allocated the
* umtx_pi, and unlocked the umtxq.
* If the current thread owns it, it must disown it.
*/
mtx_lock(&umtx_lock);
if (pi->pi_owner == td)
umtx_pi_disown(pi);
mtx_unlock(&umtx_lock);
}
}
umtxq_unlock(&key);
/*
* When unlocking the umtx, it must be marked as unowned if
* there is zero or one thread only waiting for it.
* Otherwise, it must be marked as contested.
*/
if (count > 1)
new_owner |= UMUTEX_CONTESTED;
again:
error = casueword32(&m->m_owner, owner, &old, new_owner);
if (error == 1) {
error = thread_check_susp(td, false);
if (error == 0)
goto again;
}
umtxq_unbusy_unlocked(&key);
umtx_key_release(&key);
if (error == -1)
return (EFAULT);
if (error == 0 && old != owner)
return (EINVAL);
return (error);
}
/*
* Lock a PP mutex.
*/
static int
do_lock_pp(struct thread *td, struct umutex *m, uint32_t flags,
struct _umtx_time *timeout, int try)
{
struct abs_timeout timo;
struct umtx_q *uq, *uq2;
struct umtx_pi *pi;
uint32_t ceiling;
uint32_t owner, id;
int error, pri, old_inherited_pri, su, rv;
id = td->td_tid;
uq = td->td_umtxq;
if ((error = umtx_key_get(m, (flags & UMUTEX_ROBUST) != 0 ?
TYPE_PP_ROBUST_UMUTEX : TYPE_PP_UMUTEX, GET_SHARE(flags),
&uq->uq_key)) != 0)
return (error);
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
su = (priv_check(td, PRIV_SCHED_RTPRIO) == 0);
for (;;) {
old_inherited_pri = uq->uq_inherited_pri;
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
rv = fueword32(&m->m_ceilings[0], &ceiling);
if (rv == -1) {
error = EFAULT;
goto out;
}
ceiling = RTP_PRIO_MAX - ceiling;
if (ceiling > RTP_PRIO_MAX) {
error = EINVAL;
goto out;
}
mtx_lock(&umtx_lock);
if (UPRI(td) < PRI_MIN_REALTIME + ceiling) {
mtx_unlock(&umtx_lock);
error = EINVAL;
goto out;
}
if (su && PRI_MIN_REALTIME + ceiling < uq->uq_inherited_pri) {
uq->uq_inherited_pri = PRI_MIN_REALTIME + ceiling;
thread_lock(td);
if (uq->uq_inherited_pri < UPRI(td))
sched_lend_user_prio(td, uq->uq_inherited_pri);
thread_unlock(td);
}
mtx_unlock(&umtx_lock);
rv = casueword32(&m->m_owner, UMUTEX_CONTESTED, &owner,
id | UMUTEX_CONTESTED);
/* The address was invalid. */
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 0) {
MPASS(owner == UMUTEX_CONTESTED);
error = 0;
break;
}
/* rv == 1 */
if (owner == UMUTEX_RB_OWNERDEAD) {
rv = casueword32(&m->m_owner, UMUTEX_RB_OWNERDEAD,
&owner, id | UMUTEX_CONTESTED);
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 0) {
MPASS(owner == UMUTEX_RB_OWNERDEAD);
error = EOWNERDEAD; /* success */
break;
}
/*
* rv == 1, only check for suspension if we
* did not already catched a signal. If we
* get an error from the check, the same
* condition is checked by the umtxq_sleep()
* call below, so we should obliterate the
* error to not skip the last loop iteration.
*/
if (error == 0) {
error = thread_check_susp(td, false);
if (error == 0) {
if (try != 0)
error = EBUSY;
else
continue;
}
error = 0;
}
} else if (owner == UMUTEX_RB_NOTRECOV) {
error = ENOTRECOVERABLE;
}
if (try != 0)
error = EBUSY;
/*
* If we caught a signal, we have retried and now
* exit immediately.
*/
if (error != 0)
break;
umtxq_lock(&uq->uq_key);
umtxq_insert(uq);
umtxq_unbusy(&uq->uq_key);
error = umtxq_sleep(uq, "umtxpp", timeout == NULL ?
NULL : &timo);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
mtx_lock(&umtx_lock);
uq->uq_inherited_pri = old_inherited_pri;
pri = PRI_MAX;
TAILQ_FOREACH(pi, &uq->uq_pi_contested, pi_link) {
uq2 = TAILQ_FIRST(&pi->pi_blocked);
if (uq2 != NULL) {
if (pri > UPRI(uq2->uq_thread))
pri = UPRI(uq2->uq_thread);
}
}
if (pri > uq->uq_inherited_pri)
pri = uq->uq_inherited_pri;
thread_lock(td);
sched_lend_user_prio(td, pri);
thread_unlock(td);
mtx_unlock(&umtx_lock);
}
if (error != 0 && error != EOWNERDEAD) {
mtx_lock(&umtx_lock);
uq->uq_inherited_pri = old_inherited_pri;
pri = PRI_MAX;
TAILQ_FOREACH(pi, &uq->uq_pi_contested, pi_link) {
uq2 = TAILQ_FIRST(&pi->pi_blocked);
if (uq2 != NULL) {
if (pri > UPRI(uq2->uq_thread))
pri = UPRI(uq2->uq_thread);
}
}
if (pri > uq->uq_inherited_pri)
pri = uq->uq_inherited_pri;
thread_lock(td);
sched_lend_user_prio(td, pri);
thread_unlock(td);
mtx_unlock(&umtx_lock);
}
out:
umtxq_unbusy_unlocked(&uq->uq_key);
umtx_key_release(&uq->uq_key);
return (error);
}
/*
* Unlock a PP mutex.
*/
static int
do_unlock_pp(struct thread *td, struct umutex *m, uint32_t flags, bool rb)
{
struct umtx_key key;
struct umtx_q *uq, *uq2;
struct umtx_pi *pi;
uint32_t id, owner, rceiling;
int error, pri, new_inherited_pri, su;
id = td->td_tid;
uq = td->td_umtxq;
su = (priv_check(td, PRIV_SCHED_RTPRIO) == 0);
/*
* Make sure we own this mtx.
*/
error = fueword32(&m->m_owner, &owner);
if (error == -1)
return (EFAULT);
if ((owner & ~UMUTEX_CONTESTED) != id)
return (EPERM);
error = copyin(&m->m_ceilings[1], &rceiling, sizeof(uint32_t));
if (error != 0)
return (error);
if (rceiling == -1)
new_inherited_pri = PRI_MAX;
else {
rceiling = RTP_PRIO_MAX - rceiling;
if (rceiling > RTP_PRIO_MAX)
return (EINVAL);
new_inherited_pri = PRI_MIN_REALTIME + rceiling;
}
if ((error = umtx_key_get(m, (flags & UMUTEX_ROBUST) != 0 ?
TYPE_PP_ROBUST_UMUTEX : TYPE_PP_UMUTEX, GET_SHARE(flags),
&key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
umtxq_unlock(&key);
/*
* For priority protected mutex, always set unlocked state
* to UMUTEX_CONTESTED, so that userland always enters kernel
* to lock the mutex, it is necessary because thread priority
* has to be adjusted for such mutex.
*/
error = suword32(&m->m_owner, umtx_unlock_val(flags, rb) |
UMUTEX_CONTESTED);
umtxq_lock(&key);
if (error == 0)
umtxq_signal(&key, 1);
umtxq_unbusy(&key);
umtxq_unlock(&key);
if (error == -1)
error = EFAULT;
else {
mtx_lock(&umtx_lock);
if (su != 0)
uq->uq_inherited_pri = new_inherited_pri;
pri = PRI_MAX;
TAILQ_FOREACH(pi, &uq->uq_pi_contested, pi_link) {
uq2 = TAILQ_FIRST(&pi->pi_blocked);
if (uq2 != NULL) {
if (pri > UPRI(uq2->uq_thread))
pri = UPRI(uq2->uq_thread);
}
}
if (pri > uq->uq_inherited_pri)
pri = uq->uq_inherited_pri;
thread_lock(td);
sched_lend_user_prio(td, pri);
thread_unlock(td);
mtx_unlock(&umtx_lock);
}
umtx_key_release(&key);
return (error);
}
static int
do_set_ceiling(struct thread *td, struct umutex *m, uint32_t ceiling,
uint32_t *old_ceiling)
{
struct umtx_q *uq;
uint32_t flags, id, owner, save_ceiling;
int error, rv, rv1;
error = fueword32(&m->m_flags, &flags);
if (error == -1)
return (EFAULT);
if ((flags & UMUTEX_PRIO_PROTECT) == 0)
return (EINVAL);
if (ceiling > RTP_PRIO_MAX)
return (EINVAL);
id = td->td_tid;
uq = td->td_umtxq;
if ((error = umtx_key_get(m, (flags & UMUTEX_ROBUST) != 0 ?
TYPE_PP_ROBUST_UMUTEX : TYPE_PP_UMUTEX, GET_SHARE(flags),
&uq->uq_key)) != 0)
return (error);
for (;;) {
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
rv = fueword32(&m->m_ceilings[0], &save_ceiling);
if (rv == -1) {
error = EFAULT;
break;
}
rv = casueword32(&m->m_owner, UMUTEX_CONTESTED, &owner,
id | UMUTEX_CONTESTED);
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 0) {
MPASS(owner == UMUTEX_CONTESTED);
rv = suword32(&m->m_ceilings[0], ceiling);
rv1 = suword32(&m->m_owner, UMUTEX_CONTESTED);
error = (rv == 0 && rv1 == 0) ? 0: EFAULT;
break;
}
if ((owner & ~UMUTEX_CONTESTED) == id) {
rv = suword32(&m->m_ceilings[0], ceiling);
error = rv == 0 ? 0 : EFAULT;
break;
}
if (owner == UMUTEX_RB_OWNERDEAD) {
error = EOWNERDEAD;
break;
} else if (owner == UMUTEX_RB_NOTRECOV) {
error = ENOTRECOVERABLE;
break;
}
/*
* If we caught a signal, we have retried and now
* exit immediately.
*/
if (error != 0)
break;
/*
* We set the contested bit, sleep. Otherwise the lock changed
* and we need to retry or we lost a race to the thread
* unlocking the umtx.
*/
umtxq_lock(&uq->uq_key);
umtxq_insert(uq);
umtxq_unbusy(&uq->uq_key);
error = umtxq_sleep(uq, "umtxpp", NULL);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
}
umtxq_lock(&uq->uq_key);
if (error == 0)
umtxq_signal(&uq->uq_key, INT_MAX);
umtxq_unbusy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
if (error == 0 && old_ceiling != NULL) {
rv = suword32(old_ceiling, save_ceiling);
error = rv == 0 ? 0 : EFAULT;
}
return (error);
}
/*
* Lock a userland POSIX mutex.
*/
static int
do_lock_umutex(struct thread *td, struct umutex *m,
struct _umtx_time *timeout, int mode)
{
uint32_t flags;
int error;
error = fueword32(&m->m_flags, &flags);
if (error == -1)
return (EFAULT);
switch (flags & (UMUTEX_PRIO_INHERIT | UMUTEX_PRIO_PROTECT)) {
case 0:
error = do_lock_normal(td, m, flags, timeout, mode);
break;
case UMUTEX_PRIO_INHERIT:
error = do_lock_pi(td, m, flags, timeout, mode);
break;
case UMUTEX_PRIO_PROTECT:
error = do_lock_pp(td, m, flags, timeout, mode);
break;
default:
return (EINVAL);
}
if (timeout == NULL) {
if (error == EINTR && mode != _UMUTEX_WAIT)
error = ERESTART;
} else {
/* Timed-locking is not restarted. */
if (error == ERESTART)
error = EINTR;
}
return (error);
}
/*
* Unlock a userland POSIX mutex.
*/
static int
do_unlock_umutex(struct thread *td, struct umutex *m, bool rb)
{
uint32_t flags;
int error;
error = fueword32(&m->m_flags, &flags);
if (error == -1)
return (EFAULT);
switch (flags & (UMUTEX_PRIO_INHERIT | UMUTEX_PRIO_PROTECT)) {
case 0:
return (do_unlock_normal(td, m, flags, rb));
case UMUTEX_PRIO_INHERIT:
return (do_unlock_pi(td, m, flags, rb));
case UMUTEX_PRIO_PROTECT:
return (do_unlock_pp(td, m, flags, rb));
}
return (EINVAL);
}
static int
do_cv_wait(struct thread *td, struct ucond *cv, struct umutex *m,
struct timespec *timeout, u_long wflags)
{
struct abs_timeout timo;
struct umtx_q *uq;
uint32_t flags, clockid, hasw;
int error;
uq = td->td_umtxq;
error = fueword32(&cv->c_flags, &flags);
if (error == -1)
return (EFAULT);
error = umtx_key_get(cv, TYPE_CV, GET_SHARE(flags), &uq->uq_key);
if (error != 0)
return (error);
if ((wflags & CVWAIT_CLOCKID) != 0) {
error = fueword32(&cv->c_clockid, &clockid);
if (error == -1) {
umtx_key_release(&uq->uq_key);
return (EFAULT);
}
if (clockid < CLOCK_REALTIME ||
clockid >= CLOCK_THREAD_CPUTIME_ID) {
/* hmm, only HW clock id will work. */
umtx_key_release(&uq->uq_key);
return (EINVAL);
}
} else {
clockid = CLOCK_REALTIME;
}
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_insert(uq);
umtxq_unlock(&uq->uq_key);
/*
* Set c_has_waiters to 1 before releasing user mutex, also
* don't modify cache line when unnecessary.
*/
error = fueword32(&cv->c_has_waiters, &hasw);
if (error == 0 && hasw == 0)
suword32(&cv->c_has_waiters, 1);
umtxq_unbusy_unlocked(&uq->uq_key);
error = do_unlock_umutex(td, m, false);
if (timeout != NULL)
abs_timeout_init(&timo, clockid, (wflags & CVWAIT_ABSTIME) != 0,
timeout);
umtxq_lock(&uq->uq_key);
if (error == 0) {
error = umtxq_sleep(uq, "ucond", timeout == NULL ?
NULL : &timo);
}
if ((uq->uq_flags & UQF_UMTXQ) == 0)
error = 0;
else {
/*
* This must be timeout,interrupted by signal or
* surprious wakeup, clear c_has_waiter flag when
* necessary.
*/
umtxq_busy(&uq->uq_key);
if ((uq->uq_flags & UQF_UMTXQ) != 0) {
int oldlen = uq->uq_cur_queue->length;
umtxq_remove(uq);
if (oldlen == 1) {
umtxq_unlock(&uq->uq_key);
suword32(&cv->c_has_waiters, 0);
umtxq_lock(&uq->uq_key);
}
}
umtxq_unbusy(&uq->uq_key);
if (error == ERESTART)
error = EINTR;
}
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
return (error);
}
/*
* Signal a userland condition variable.
*/
static int
do_cv_signal(struct thread *td, struct ucond *cv)
{
struct umtx_key key;
int error, cnt, nwake;
uint32_t flags;
error = fueword32(&cv->c_flags, &flags);
if (error == -1)
return (EFAULT);
if ((error = umtx_key_get(cv, TYPE_CV, GET_SHARE(flags), &key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
cnt = umtxq_count(&key);
nwake = umtxq_signal(&key, 1);
if (cnt <= nwake) {
umtxq_unlock(&key);
error = suword32(&cv->c_has_waiters, 0);
if (error == -1)
error = EFAULT;
umtxq_lock(&key);
}
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
return (error);
}
static int
do_cv_broadcast(struct thread *td, struct ucond *cv)
{
struct umtx_key key;
int error;
uint32_t flags;
error = fueword32(&cv->c_flags, &flags);
if (error == -1)
return (EFAULT);
if ((error = umtx_key_get(cv, TYPE_CV, GET_SHARE(flags), &key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
umtxq_signal(&key, INT_MAX);
umtxq_unlock(&key);
error = suword32(&cv->c_has_waiters, 0);
if (error == -1)
error = EFAULT;
umtxq_unbusy_unlocked(&key);
umtx_key_release(&key);
return (error);
}
static int
do_rw_rdlock(struct thread *td, struct urwlock *rwlock, long fflag,
struct _umtx_time *timeout)
{
struct abs_timeout timo;
struct umtx_q *uq;
uint32_t flags, wrflags;
int32_t state, oldstate;
int32_t blocked_readers;
int error, error1, rv;
uq = td->td_umtxq;
error = fueword32(&rwlock->rw_flags, &flags);
if (error == -1)
return (EFAULT);
error = umtx_key_get(rwlock, TYPE_RWLOCK, GET_SHARE(flags), &uq->uq_key);
if (error != 0)
return (error);
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
wrflags = URWLOCK_WRITE_OWNER;
if (!(fflag & URWLOCK_PREFER_READER) && !(flags & URWLOCK_PREFER_READER))
wrflags |= URWLOCK_WRITE_WAITERS;
for (;;) {
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1) {
umtx_key_release(&uq->uq_key);
return (EFAULT);
}
/* try to lock it */
while (!(state & wrflags)) {
if (__predict_false(URWLOCK_READER_COUNT(state) ==
URWLOCK_MAX_READERS)) {
umtx_key_release(&uq->uq_key);
return (EAGAIN);
}
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state + 1);
if (rv == -1) {
umtx_key_release(&uq->uq_key);
return (EFAULT);
}
if (rv == 0) {
MPASS(oldstate == state);
umtx_key_release(&uq->uq_key);
return (0);
}
error = thread_check_susp(td, true);
if (error != 0)
break;
state = oldstate;
}
if (error)
break;
/* grab monitor lock */
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
/*
* re-read the state, in case it changed between the try-lock above
* and the check below
*/
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1)
error = EFAULT;
/* set read contention bit */
while (error == 0 && (state & wrflags) &&
!(state & URWLOCK_READ_WAITERS)) {
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state | URWLOCK_READ_WAITERS);
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 0) {
MPASS(oldstate == state);
goto sleep;
}
state = oldstate;
error = thread_check_susp(td, false);
if (error != 0)
break;
}
if (error != 0) {
umtxq_unbusy_unlocked(&uq->uq_key);
break;
}
/* state is changed while setting flags, restart */
if (!(state & wrflags)) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = thread_check_susp(td, true);
if (error != 0)
break;
continue;
}
sleep:
/*
* Contention bit is set, before sleeping, increase
* read waiter count.
*/
rv = fueword32(&rwlock->rw_blocked_readers,
&blocked_readers);
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
suword32(&rwlock->rw_blocked_readers, blocked_readers+1);
while (state & wrflags) {
umtxq_lock(&uq->uq_key);
umtxq_insert(uq);
umtxq_unbusy(&uq->uq_key);
error = umtxq_sleep(uq, "urdlck", timeout == NULL ?
NULL : &timo);
umtxq_busy(&uq->uq_key);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
if (error)
break;
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1) {
error = EFAULT;
break;
}
}
/* decrease read waiter count, and may clear read contention bit */
rv = fueword32(&rwlock->rw_blocked_readers,
&blocked_readers);
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
suword32(&rwlock->rw_blocked_readers, blocked_readers-1);
if (blocked_readers == 1) {
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
for (;;) {
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state & ~URWLOCK_READ_WAITERS);
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 0) {
MPASS(oldstate == state);
break;
}
state = oldstate;
error1 = thread_check_susp(td, false);
if (error1 != 0) {
if (error == 0)
error = error1;
break;
}
}
}
umtxq_unbusy_unlocked(&uq->uq_key);
if (error != 0)
break;
}
umtx_key_release(&uq->uq_key);
if (error == ERESTART)
error = EINTR;
return (error);
}
static int
do_rw_wrlock(struct thread *td, struct urwlock *rwlock, struct _umtx_time *timeout)
{
struct abs_timeout timo;
struct umtx_q *uq;
uint32_t flags;
int32_t state, oldstate;
int32_t blocked_writers;
int32_t blocked_readers;
int error, error1, rv;
uq = td->td_umtxq;
error = fueword32(&rwlock->rw_flags, &flags);
if (error == -1)
return (EFAULT);
error = umtx_key_get(rwlock, TYPE_RWLOCK, GET_SHARE(flags), &uq->uq_key);
if (error != 0)
return (error);
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
blocked_readers = 0;
for (;;) {
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1) {
umtx_key_release(&uq->uq_key);
return (EFAULT);
}
while ((state & URWLOCK_WRITE_OWNER) == 0 &&
URWLOCK_READER_COUNT(state) == 0) {
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state | URWLOCK_WRITE_OWNER);
if (rv == -1) {
umtx_key_release(&uq->uq_key);
return (EFAULT);
}
if (rv == 0) {
MPASS(oldstate == state);
umtx_key_release(&uq->uq_key);
return (0);
}
state = oldstate;
error = thread_check_susp(td, true);
if (error != 0)
break;
}
if (error) {
if ((state & (URWLOCK_WRITE_OWNER |
URWLOCK_WRITE_WAITERS)) == 0 &&
blocked_readers != 0) {
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_signal_queue(&uq->uq_key, INT_MAX,
UMTX_SHARED_QUEUE);
umtxq_unbusy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
}
break;
}
/* grab monitor lock */
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
/*
* Re-read the state, in case it changed between the
* try-lock above and the check below.
*/
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1)
error = EFAULT;
while (error == 0 && ((state & URWLOCK_WRITE_OWNER) ||
URWLOCK_READER_COUNT(state) != 0) &&
(state & URWLOCK_WRITE_WAITERS) == 0) {
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state | URWLOCK_WRITE_WAITERS);
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 0) {
MPASS(oldstate == state);
goto sleep;
}
state = oldstate;
error = thread_check_susp(td, false);
if (error != 0)
break;
}
if (error != 0) {
umtxq_unbusy_unlocked(&uq->uq_key);
break;
}
if ((state & URWLOCK_WRITE_OWNER) == 0 &&
URWLOCK_READER_COUNT(state) == 0) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = thread_check_susp(td, false);
if (error != 0)
break;
continue;
}
sleep:
rv = fueword32(&rwlock->rw_blocked_writers,
&blocked_writers);
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
suword32(&rwlock->rw_blocked_writers, blocked_writers + 1);
while ((state & URWLOCK_WRITE_OWNER) ||
URWLOCK_READER_COUNT(state) != 0) {
umtxq_lock(&uq->uq_key);
umtxq_insert_queue(uq, UMTX_EXCLUSIVE_QUEUE);
umtxq_unbusy(&uq->uq_key);
error = umtxq_sleep(uq, "uwrlck", timeout == NULL ?
NULL : &timo);
umtxq_busy(&uq->uq_key);
umtxq_remove_queue(uq, UMTX_EXCLUSIVE_QUEUE);
umtxq_unlock(&uq->uq_key);
if (error)
break;
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1) {
error = EFAULT;
break;
}
}
rv = fueword32(&rwlock->rw_blocked_writers,
&blocked_writers);
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
suword32(&rwlock->rw_blocked_writers, blocked_writers-1);
if (blocked_writers == 1) {
rv = fueword32(&rwlock->rw_state, &state);
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
for (;;) {
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state & ~URWLOCK_WRITE_WAITERS);
if (rv == -1) {
error = EFAULT;
break;
}
if (rv == 0) {
MPASS(oldstate == state);
break;
}
state = oldstate;
error1 = thread_check_susp(td, false);
/*
* We are leaving the URWLOCK_WRITE_WAITERS
* behind, but this should not harm the
* correctness.
*/
if (error1 != 0) {
if (error == 0)
error = error1;
break;
}
}
rv = fueword32(&rwlock->rw_blocked_readers,
&blocked_readers);
if (rv == -1) {
umtxq_unbusy_unlocked(&uq->uq_key);
error = EFAULT;
break;
}
} else
blocked_readers = 0;
umtxq_unbusy_unlocked(&uq->uq_key);
}
umtx_key_release(&uq->uq_key);
if (error == ERESTART)
error = EINTR;
return (error);
}
static int
do_rw_unlock(struct thread *td, struct urwlock *rwlock)
{
struct umtx_q *uq;
uint32_t flags;
int32_t state, oldstate;
int error, rv, q, count;
uq = td->td_umtxq;
error = fueword32(&rwlock->rw_flags, &flags);
if (error == -1)
return (EFAULT);
error = umtx_key_get(rwlock, TYPE_RWLOCK, GET_SHARE(flags), &uq->uq_key);
if (error != 0)
return (error);
error = fueword32(&rwlock->rw_state, &state);
if (error == -1) {
error = EFAULT;
goto out;
}
if (state & URWLOCK_WRITE_OWNER) {
for (;;) {
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state & ~URWLOCK_WRITE_OWNER);
if (rv == -1) {
error = EFAULT;
goto out;
}
if (rv == 1) {
state = oldstate;
if (!(oldstate & URWLOCK_WRITE_OWNER)) {
error = EPERM;
goto out;
}
error = thread_check_susp(td, true);
if (error != 0)
goto out;
} else
break;
}
} else if (URWLOCK_READER_COUNT(state) != 0) {
for (;;) {
rv = casueword32(&rwlock->rw_state, state,
&oldstate, state - 1);
if (rv == -1) {
error = EFAULT;
goto out;
}
if (rv == 1) {
state = oldstate;
if (URWLOCK_READER_COUNT(oldstate) == 0) {
error = EPERM;
goto out;
}
error = thread_check_susp(td, true);
if (error != 0)
goto out;
} else
break;
}
} else {
error = EPERM;
goto out;
}
count = 0;
if (!(flags & URWLOCK_PREFER_READER)) {
if (state & URWLOCK_WRITE_WAITERS) {
count = 1;
q = UMTX_EXCLUSIVE_QUEUE;
} else if (state & URWLOCK_READ_WAITERS) {
count = INT_MAX;
q = UMTX_SHARED_QUEUE;
}
} else {
if (state & URWLOCK_READ_WAITERS) {
count = INT_MAX;
q = UMTX_SHARED_QUEUE;
} else if (state & URWLOCK_WRITE_WAITERS) {
count = 1;
q = UMTX_EXCLUSIVE_QUEUE;
}
}
if (count) {
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_signal_queue(&uq->uq_key, count, q);
umtxq_unbusy(&uq->uq_key);
umtxq_unlock(&uq->uq_key);
}
out:
umtx_key_release(&uq->uq_key);
return (error);
}
#if defined(COMPAT_FREEBSD9) || defined(COMPAT_FREEBSD10)
static int
do_sem_wait(struct thread *td, struct _usem *sem, struct _umtx_time *timeout)
{
struct abs_timeout timo;
struct umtx_q *uq;
uint32_t flags, count, count1;
int error, rv, rv1;
uq = td->td_umtxq;
error = fueword32(&sem->_flags, &flags);
if (error == -1)
return (EFAULT);
error = umtx_key_get(sem, TYPE_SEM, GET_SHARE(flags), &uq->uq_key);
if (error != 0)
return (error);
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
again:
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_insert(uq);
umtxq_unlock(&uq->uq_key);
rv = casueword32(&sem->_has_waiters, 0, &count1, 1);
if (rv == 0)
rv1 = fueword32(&sem->_count, &count);
if (rv == -1 || (rv == 0 && (rv1 == -1 || count != 0)) ||
(rv == 1 && count1 == 0)) {
umtxq_lock(&uq->uq_key);
umtxq_unbusy(&uq->uq_key);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
if (rv == 1) {
rv = thread_check_susp(td, true);
if (rv == 0)
goto again;
error = rv;
goto out;
}
if (rv == 0)
rv = rv1;
error = rv == -1 ? EFAULT : 0;
goto out;
}
umtxq_lock(&uq->uq_key);
umtxq_unbusy(&uq->uq_key);
error = umtxq_sleep(uq, "usem", timeout == NULL ? NULL : &timo);
if ((uq->uq_flags & UQF_UMTXQ) == 0)
error = 0;
else {
umtxq_remove(uq);
/* A relative timeout cannot be restarted. */
if (error == ERESTART && timeout != NULL &&
(timeout->_flags & UMTX_ABSTIME) == 0)
error = EINTR;
}
umtxq_unlock(&uq->uq_key);
out:
umtx_key_release(&uq->uq_key);
return (error);
}
/*
* Signal a userland semaphore.
*/
static int
do_sem_wake(struct thread *td, struct _usem *sem)
{
struct umtx_key key;
int error, cnt;
uint32_t flags;
error = fueword32(&sem->_flags, &flags);
if (error == -1)
return (EFAULT);
if ((error = umtx_key_get(sem, TYPE_SEM, GET_SHARE(flags), &key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
cnt = umtxq_count(&key);
if (cnt > 0) {
/*
* Check if count is greater than 0, this means the memory is
* still being referenced by user code, so we can safely
* update _has_waiters flag.
*/
if (cnt == 1) {
umtxq_unlock(&key);
error = suword32(&sem->_has_waiters, 0);
umtxq_lock(&key);
if (error == -1)
error = EFAULT;
}
umtxq_signal(&key, 1);
}
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
return (error);
}
#endif
static int
do_sem2_wait(struct thread *td, struct _usem2 *sem, struct _umtx_time *timeout)
{
struct abs_timeout timo;
struct umtx_q *uq;
uint32_t count, flags;
int error, rv;
uq = td->td_umtxq;
flags = fuword32(&sem->_flags);
if (timeout != NULL)
abs_timeout_init2(&timo, timeout);
again:
error = umtx_key_get(sem, TYPE_SEM, GET_SHARE(flags), &uq->uq_key);
if (error != 0)
return (error);
umtxq_lock(&uq->uq_key);
umtxq_busy(&uq->uq_key);
umtxq_insert(uq);
umtxq_unlock(&uq->uq_key);
rv = fueword32(&sem->_count, &count);
if (rv == -1) {
umtxq_lock(&uq->uq_key);
umtxq_unbusy(&uq->uq_key);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
return (EFAULT);
}
for (;;) {
if (USEM_COUNT(count) != 0) {
umtxq_lock(&uq->uq_key);
umtxq_unbusy(&uq->uq_key);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
return (0);
}
if (count == USEM_HAS_WAITERS)
break;
rv = casueword32(&sem->_count, 0, &count, USEM_HAS_WAITERS);
if (rv == 0)
break;
umtxq_lock(&uq->uq_key);
umtxq_unbusy(&uq->uq_key);
umtxq_remove(uq);
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
if (rv == -1)
return (EFAULT);
rv = thread_check_susp(td, true);
if (rv != 0)
return (rv);
goto again;
}
umtxq_lock(&uq->uq_key);
umtxq_unbusy(&uq->uq_key);
error = umtxq_sleep(uq, "usem", timeout == NULL ? NULL : &timo);
if ((uq->uq_flags & UQF_UMTXQ) == 0)
error = 0;
else {
umtxq_remove(uq);
if (timeout != NULL && (timeout->_flags & UMTX_ABSTIME) == 0) {
/* A relative timeout cannot be restarted. */
if (error == ERESTART)
error = EINTR;
if (error == EINTR) {
abs_timeout_update(&timo);
timespecsub(&timo.end, &timo.cur,
&timeout->_timeout);
}
}
}
umtxq_unlock(&uq->uq_key);
umtx_key_release(&uq->uq_key);
return (error);
}
/*
* Signal a userland semaphore.
*/
static int
do_sem2_wake(struct thread *td, struct _usem2 *sem)
{
struct umtx_key key;
int error, cnt, rv;
uint32_t count, flags;
rv = fueword32(&sem->_flags, &flags);
if (rv == -1)
return (EFAULT);
if ((error = umtx_key_get(sem, TYPE_SEM, GET_SHARE(flags), &key)) != 0)
return (error);
umtxq_lock(&key);
umtxq_busy(&key);
cnt = umtxq_count(&key);
if (cnt > 0) {
/*
* If this was the last sleeping thread, clear the waiters
* flag in _count.
*/
if (cnt == 1) {
umtxq_unlock(&key);
rv = fueword32(&sem->_count, &count);
while (rv != -1 && count & USEM_HAS_WAITERS) {
rv = casueword32(&sem->_count, count, &count,
count & ~USEM_HAS_WAITERS);
if (rv == 1) {
rv = thread_check_susp(td, true);
if (rv != 0)
break;
}
}
if (rv == -1)
error = EFAULT;
else if (rv > 0) {
error = rv;
}
umtxq_lock(&key);
}
umtxq_signal(&key, 1);
}
umtxq_unbusy(&key);
umtxq_unlock(&key);
umtx_key_release(&key);
return (error);
}
inline int
umtx_copyin_timeout(const void *uaddr, struct timespec *tsp)
{
int error;
error = copyin(uaddr, tsp, sizeof(*tsp));
if (error == 0) {
if (tsp->tv_sec < 0 ||
tsp->tv_nsec >= 1000000000 ||
tsp->tv_nsec < 0)
error = EINVAL;
}
return (error);
}
static inline int
umtx_copyin_umtx_time(const void *uaddr, size_t size, struct _umtx_time *tp)
{
int error;
if (size <= sizeof(tp->_timeout)) {
tp->_clockid = CLOCK_REALTIME;
tp->_flags = 0;
error = copyin(uaddr, &tp->_timeout, sizeof(tp->_timeout));
} else
error = copyin(uaddr, tp, sizeof(*tp));
if (error != 0)
return (error);
if (tp->_timeout.tv_sec < 0 ||
tp->_timeout.tv_nsec >= 1000000000 || tp->_timeout.tv_nsec < 0)
return (EINVAL);
return (0);
}
static int
umtx_copyin_robust_lists(const void *uaddr, size_t size,
struct umtx_robust_lists_params *rb)
{
if (size > sizeof(*rb))
return (EINVAL);
return (copyin(uaddr, rb, size));
}
static int
umtx_copyout_timeout(void *uaddr, size_t sz, struct timespec *tsp)
{
/*
* Should be guaranteed by the caller, sz == uaddr1 - sizeof(_umtx_time)
* and we're only called if sz >= sizeof(timespec) as supplied in the
* copyops.
*/
KASSERT(sz >= sizeof(*tsp),
("umtx_copyops specifies incorrect sizes"));
return (copyout(tsp, uaddr, sizeof(*tsp)));
}
static int
__umtx_op_unimpl(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (EOPNOTSUPP);
}
static int
__umtx_op_wait(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time timeout, *tm_p;
int error;
if (uap->uaddr2 == NULL)
tm_p = NULL;
else {
error = ops->copyin_umtx_time(
uap->uaddr2, (size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
tm_p = &timeout;
}
return (do_wait(td, uap->obj, uap->val, tm_p, ops->compat32, 0));
}
static int
__umtx_op_wait_uint(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time timeout, *tm_p;
int error;
if (uap->uaddr2 == NULL)
tm_p = NULL;
else {
error = ops->copyin_umtx_time(
uap->uaddr2, (size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
tm_p = &timeout;
}
return (do_wait(td, uap->obj, uap->val, tm_p, 1, 0));
}
static int
__umtx_op_wait_uint_private(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time *tm_p, timeout;
int error;
if (uap->uaddr2 == NULL)
tm_p = NULL;
else {
error = ops->copyin_umtx_time(
uap->uaddr2, (size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
tm_p = &timeout;
}
return (do_wait(td, uap->obj, uap->val, tm_p, 1, 1));
}
static int
__umtx_op_wake(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (kern_umtx_wake(td, uap->obj, uap->val, 0));
}
#define BATCH_SIZE 128
static int
__umtx_op_nwake_private_native(struct thread *td, struct _umtx_op_args *uap)
{
char *uaddrs[BATCH_SIZE], **upp;
int count, error, i, pos, tocopy;
upp = (char **)uap->obj;
error = 0;
for (count = uap->val, pos = 0; count > 0; count -= tocopy,
pos += tocopy) {
tocopy = MIN(count, BATCH_SIZE);
error = copyin(upp + pos, uaddrs, tocopy * sizeof(char *));
if (error != 0)
break;
for (i = 0; i < tocopy; ++i) {
kern_umtx_wake(td, uaddrs[i], INT_MAX, 1);
}
maybe_yield();
}
return (error);
}
static int
__umtx_op_nwake_private_compat32(struct thread *td, struct _umtx_op_args *uap)
{
uint32_t uaddrs[BATCH_SIZE], *upp;
int count, error, i, pos, tocopy;
upp = (uint32_t *)uap->obj;
error = 0;
for (count = uap->val, pos = 0; count > 0; count -= tocopy,
pos += tocopy) {
tocopy = MIN(count, BATCH_SIZE);
error = copyin(upp + pos, uaddrs, tocopy * sizeof(uint32_t));
if (error != 0)
break;
for (i = 0; i < tocopy; ++i) {
kern_umtx_wake(td, (void *)(uintptr_t)uaddrs[i],
INT_MAX, 1);
}
maybe_yield();
}
return (error);
}
static int
__umtx_op_nwake_private(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
if (ops->compat32)
return (__umtx_op_nwake_private_compat32(td, uap));
return (__umtx_op_nwake_private_native(td, uap));
}
static int
__umtx_op_wake_private(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (kern_umtx_wake(td, uap->obj, uap->val, 1));
}
static int
__umtx_op_lock_umutex(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time *tm_p, timeout;
int error;
/* Allow a null timespec (wait forever). */
if (uap->uaddr2 == NULL)
tm_p = NULL;
else {
error = ops->copyin_umtx_time(
uap->uaddr2, (size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
tm_p = &timeout;
}
return (do_lock_umutex(td, uap->obj, tm_p, 0));
}
static int
__umtx_op_trylock_umutex(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_lock_umutex(td, uap->obj, NULL, _UMUTEX_TRY));
}
static int
__umtx_op_wait_umutex(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time *tm_p, timeout;
int error;
/* Allow a null timespec (wait forever). */
if (uap->uaddr2 == NULL)
tm_p = NULL;
else {
error = ops->copyin_umtx_time(
uap->uaddr2, (size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
tm_p = &timeout;
}
return (do_lock_umutex(td, uap->obj, tm_p, _UMUTEX_WAIT));
}
static int
__umtx_op_wake_umutex(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_wake_umutex(td, uap->obj));
}
static int
__umtx_op_unlock_umutex(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_unlock_umutex(td, uap->obj, false));
}
static int
__umtx_op_set_ceiling(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_set_ceiling(td, uap->obj, uap->val, uap->uaddr1));
}
static int
__umtx_op_cv_wait(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct timespec *ts, timeout;
int error;
/* Allow a null timespec (wait forever). */
if (uap->uaddr2 == NULL)
ts = NULL;
else {
error = ops->copyin_timeout(uap->uaddr2, &timeout);
if (error != 0)
return (error);
ts = &timeout;
}
return (do_cv_wait(td, uap->obj, uap->uaddr1, ts, uap->val));
}
static int
__umtx_op_cv_signal(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_cv_signal(td, uap->obj));
}
static int
__umtx_op_cv_broadcast(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_cv_broadcast(td, uap->obj));
}
static int
__umtx_op_rw_rdlock(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time timeout;
int error;
/* Allow a null timespec (wait forever). */
if (uap->uaddr2 == NULL) {
error = do_rw_rdlock(td, uap->obj, uap->val, 0);
} else {
error = ops->copyin_umtx_time(uap->uaddr2,
(size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
error = do_rw_rdlock(td, uap->obj, uap->val, &timeout);
}
return (error);
}
static int
__umtx_op_rw_wrlock(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time timeout;
int error;
/* Allow a null timespec (wait forever). */
if (uap->uaddr2 == NULL) {
error = do_rw_wrlock(td, uap->obj, 0);
} else {
error = ops->copyin_umtx_time(uap->uaddr2,
(size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
error = do_rw_wrlock(td, uap->obj, &timeout);
}
return (error);
}
static int
__umtx_op_rw_unlock(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_rw_unlock(td, uap->obj));
}
#if defined(COMPAT_FREEBSD9) || defined(COMPAT_FREEBSD10)
static int
__umtx_op_sem_wait(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time *tm_p, timeout;
int error;
/* Allow a null timespec (wait forever). */
if (uap->uaddr2 == NULL)
tm_p = NULL;
else {
error = ops->copyin_umtx_time(
uap->uaddr2, (size_t)uap->uaddr1, &timeout);
if (error != 0)
return (error);
tm_p = &timeout;
}
return (do_sem_wait(td, uap->obj, tm_p));
}
static int
__umtx_op_sem_wake(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_sem_wake(td, uap->obj));
}
#endif
static int
__umtx_op_wake2_umutex(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_wake2_umutex(td, uap->obj, uap->val));
}
static int
__umtx_op_sem2_wait(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct _umtx_time *tm_p, timeout;
size_t uasize;
int error;
/* Allow a null timespec (wait forever). */
if (uap->uaddr2 == NULL) {
uasize = 0;
tm_p = NULL;
} else {
uasize = (size_t)uap->uaddr1;
error = ops->copyin_umtx_time(uap->uaddr2, uasize, &timeout);
if (error != 0)
return (error);
tm_p = &timeout;
}
error = do_sem2_wait(td, uap->obj, tm_p);
if (error == EINTR && uap->uaddr2 != NULL &&
(timeout._flags & UMTX_ABSTIME) == 0 &&
uasize >= ops->umtx_time_sz + ops->timespec_sz) {
error = ops->copyout_timeout(
(void *)((uintptr_t)uap->uaddr2 + ops->umtx_time_sz),
uasize - ops->umtx_time_sz, &timeout._timeout);
if (error == 0) {
error = EINTR;
}
}
return (error);
}
static int
__umtx_op_sem2_wake(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (do_sem2_wake(td, uap->obj));
}
#define USHM_OBJ_UMTX(o) \
((struct umtx_shm_obj_list *)(&(o)->umtx_data))
#define USHMF_REG_LINKED 0x0001
#define USHMF_OBJ_LINKED 0x0002
struct umtx_shm_reg {
TAILQ_ENTRY(umtx_shm_reg) ushm_reg_link;
LIST_ENTRY(umtx_shm_reg) ushm_obj_link;
struct umtx_key ushm_key;
struct ucred *ushm_cred;
struct shmfd *ushm_obj;
u_int ushm_refcnt;
u_int ushm_flags;
};
LIST_HEAD(umtx_shm_obj_list, umtx_shm_reg);
TAILQ_HEAD(umtx_shm_reg_head, umtx_shm_reg);
static uma_zone_t umtx_shm_reg_zone;
static struct umtx_shm_reg_head umtx_shm_registry[UMTX_CHAINS];
static struct mtx umtx_shm_lock;
static struct umtx_shm_reg_head umtx_shm_reg_delfree =
TAILQ_HEAD_INITIALIZER(umtx_shm_reg_delfree);
static void umtx_shm_free_reg(struct umtx_shm_reg *reg);
static void
umtx_shm_reg_delfree_tq(void *context __unused, int pending __unused)
{
struct umtx_shm_reg_head d;
struct umtx_shm_reg *reg, *reg1;
TAILQ_INIT(&d);
mtx_lock(&umtx_shm_lock);
TAILQ_CONCAT(&d, &umtx_shm_reg_delfree, ushm_reg_link);
mtx_unlock(&umtx_shm_lock);
TAILQ_FOREACH_SAFE(reg, &d, ushm_reg_link, reg1) {
TAILQ_REMOVE(&d, reg, ushm_reg_link);
umtx_shm_free_reg(reg);
}
}
static struct task umtx_shm_reg_delfree_task =
TASK_INITIALIZER(0, umtx_shm_reg_delfree_tq, NULL);
static struct umtx_shm_reg *
umtx_shm_find_reg_locked(const struct umtx_key *key)
{
struct umtx_shm_reg *reg;
struct umtx_shm_reg_head *reg_head;
KASSERT(key->shared, ("umtx_p_find_rg: private key"));
mtx_assert(&umtx_shm_lock, MA_OWNED);
reg_head = &umtx_shm_registry[key->hash];
TAILQ_FOREACH(reg, reg_head, ushm_reg_link) {
KASSERT(reg->ushm_key.shared,
("non-shared key on reg %p %d", reg, reg->ushm_key.shared));
if (reg->ushm_key.info.shared.object ==
key->info.shared.object &&
reg->ushm_key.info.shared.offset ==
key->info.shared.offset) {
KASSERT(reg->ushm_key.type == TYPE_SHM, ("TYPE_USHM"));
KASSERT(reg->ushm_refcnt > 0,
("reg %p refcnt 0 onlist", reg));
KASSERT((reg->ushm_flags & USHMF_REG_LINKED) != 0,
("reg %p not linked", reg));
reg->ushm_refcnt++;
return (reg);
}
}
return (NULL);
}
static struct umtx_shm_reg *
umtx_shm_find_reg(const struct umtx_key *key)
{
struct umtx_shm_reg *reg;
mtx_lock(&umtx_shm_lock);
reg = umtx_shm_find_reg_locked(key);
mtx_unlock(&umtx_shm_lock);
return (reg);
}
static void
umtx_shm_free_reg(struct umtx_shm_reg *reg)
{
chgumtxcnt(reg->ushm_cred->cr_ruidinfo, -1, 0);
crfree(reg->ushm_cred);
shm_drop(reg->ushm_obj);
uma_zfree(umtx_shm_reg_zone, reg);
}
static bool
umtx_shm_unref_reg_locked(struct umtx_shm_reg *reg, bool force)
{
bool res;
mtx_assert(&umtx_shm_lock, MA_OWNED);
KASSERT(reg->ushm_refcnt > 0, ("ushm_reg %p refcnt 0", reg));
reg->ushm_refcnt--;
res = reg->ushm_refcnt == 0;
if (res || force) {
if ((reg->ushm_flags & USHMF_REG_LINKED) != 0) {
TAILQ_REMOVE(&umtx_shm_registry[reg->ushm_key.hash],
reg, ushm_reg_link);
reg->ushm_flags &= ~USHMF_REG_LINKED;
}
if ((reg->ushm_flags & USHMF_OBJ_LINKED) != 0) {
LIST_REMOVE(reg, ushm_obj_link);
reg->ushm_flags &= ~USHMF_OBJ_LINKED;
}
}
return (res);
}
static void
umtx_shm_unref_reg(struct umtx_shm_reg *reg, bool force)
{
vm_object_t object;
bool dofree;
if (force) {
object = reg->ushm_obj->shm_object;
VM_OBJECT_WLOCK(object);
object->flags |= OBJ_UMTXDEAD;
VM_OBJECT_WUNLOCK(object);
}
mtx_lock(&umtx_shm_lock);
dofree = umtx_shm_unref_reg_locked(reg, force);
mtx_unlock(&umtx_shm_lock);
if (dofree)
umtx_shm_free_reg(reg);
}
void
umtx_shm_object_init(vm_object_t object)
{
LIST_INIT(USHM_OBJ_UMTX(object));
}
void
umtx_shm_object_terminated(vm_object_t object)
{
struct umtx_shm_reg *reg, *reg1;
bool dofree;
if (LIST_EMPTY(USHM_OBJ_UMTX(object)))
return;
dofree = false;
mtx_lock(&umtx_shm_lock);
LIST_FOREACH_SAFE(reg, USHM_OBJ_UMTX(object), ushm_obj_link, reg1) {
if (umtx_shm_unref_reg_locked(reg, true)) {
TAILQ_INSERT_TAIL(&umtx_shm_reg_delfree, reg,
ushm_reg_link);
dofree = true;
}
}
mtx_unlock(&umtx_shm_lock);
if (dofree)
taskqueue_enqueue(taskqueue_thread, &umtx_shm_reg_delfree_task);
}
static int
umtx_shm_create_reg(struct thread *td, const struct umtx_key *key,
struct umtx_shm_reg **res)
{
struct umtx_shm_reg *reg, *reg1;
struct ucred *cred;
int error;
reg = umtx_shm_find_reg(key);
if (reg != NULL) {
*res = reg;
return (0);
}
cred = td->td_ucred;
if (!chgumtxcnt(cred->cr_ruidinfo, 1, lim_cur(td, RLIMIT_UMTXP)))
return (ENOMEM);
reg = uma_zalloc(umtx_shm_reg_zone, M_WAITOK | M_ZERO);
reg->ushm_refcnt = 1;
bcopy(key, &reg->ushm_key, sizeof(*key));
reg->ushm_obj = shm_alloc(td->td_ucred, O_RDWR, false);
reg->ushm_cred = crhold(cred);
error = shm_dotruncate(reg->ushm_obj, PAGE_SIZE);
if (error != 0) {
umtx_shm_free_reg(reg);
return (error);
}
mtx_lock(&umtx_shm_lock);
reg1 = umtx_shm_find_reg_locked(key);
if (reg1 != NULL) {
mtx_unlock(&umtx_shm_lock);
umtx_shm_free_reg(reg);
*res = reg1;
return (0);
}
reg->ushm_refcnt++;
TAILQ_INSERT_TAIL(&umtx_shm_registry[key->hash], reg, ushm_reg_link);
LIST_INSERT_HEAD(USHM_OBJ_UMTX(key->info.shared.object), reg,
ushm_obj_link);
reg->ushm_flags = USHMF_REG_LINKED | USHMF_OBJ_LINKED;
mtx_unlock(&umtx_shm_lock);
*res = reg;
return (0);
}
static int
umtx_shm_alive(struct thread *td, void *addr)
{
vm_map_t map;
vm_map_entry_t entry;
vm_object_t object;
vm_pindex_t pindex;
vm_prot_t prot;
int res, ret;
boolean_t wired;
map = &td->td_proc->p_vmspace->vm_map;
res = vm_map_lookup(&map, (uintptr_t)addr, VM_PROT_READ, &entry,
&object, &pindex, &prot, &wired);
if (res != KERN_SUCCESS)
return (EFAULT);
if (object == NULL)
ret = EINVAL;
else
ret = (object->flags & OBJ_UMTXDEAD) != 0 ? ENOTTY : 0;
vm_map_lookup_done(map, entry);
return (ret);
}
static void
umtx_shm_init(void)
{
int i;
umtx_shm_reg_zone = uma_zcreate("umtx_shm", sizeof(struct umtx_shm_reg),
NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0);
mtx_init(&umtx_shm_lock, "umtxshm", NULL, MTX_DEF);
for (i = 0; i < nitems(umtx_shm_registry); i++)
TAILQ_INIT(&umtx_shm_registry[i]);
}
static int
umtx_shm(struct thread *td, void *addr, u_int flags)
{
struct umtx_key key;
struct umtx_shm_reg *reg;
struct file *fp;
int error, fd;
if (__bitcount(flags & (UMTX_SHM_CREAT | UMTX_SHM_LOOKUP |
UMTX_SHM_DESTROY| UMTX_SHM_ALIVE)) != 1)
return (EINVAL);
if ((flags & UMTX_SHM_ALIVE) != 0)
return (umtx_shm_alive(td, addr));
error = umtx_key_get(addr, TYPE_SHM, PROCESS_SHARE, &key);
if (error != 0)
return (error);
KASSERT(key.shared == 1, ("non-shared key"));
if ((flags & UMTX_SHM_CREAT) != 0) {
error = umtx_shm_create_reg(td, &key, &reg);
} else {
reg = umtx_shm_find_reg(&key);
if (reg == NULL)
error = ESRCH;
}
umtx_key_release(&key);
if (error != 0)
return (error);
KASSERT(reg != NULL, ("no reg"));
if ((flags & UMTX_SHM_DESTROY) != 0) {
umtx_shm_unref_reg(reg, true);
} else {
#if 0
#ifdef MAC
error = mac_posixshm_check_open(td->td_ucred,
reg->ushm_obj, FFLAGS(O_RDWR));
if (error == 0)
#endif
error = shm_access(reg->ushm_obj, td->td_ucred,
FFLAGS(O_RDWR));
if (error == 0)
#endif
error = falloc_caps(td, &fp, &fd, O_CLOEXEC, NULL);
if (error == 0) {
shm_hold(reg->ushm_obj);
finit(fp, FFLAGS(O_RDWR), DTYPE_SHM, reg->ushm_obj,
&shm_ops);
td->td_retval[0] = fd;
fdrop(fp, td);
}
}
umtx_shm_unref_reg(reg, false);
return (error);
}
static int
__umtx_op_shm(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops __unused)
{
return (umtx_shm(td, uap->uaddr1, uap->val));
}
static int
__umtx_op_robust_lists(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *ops)
{
struct umtx_robust_lists_params rb;
int error;
if (ops->compat32) {
if ((td->td_pflags2 & TDP2_COMPAT32RB) == 0 &&
(td->td_rb_list != 0 || td->td_rbp_list != 0 ||
td->td_rb_inact != 0))
return (EBUSY);
} else if ((td->td_pflags2 & TDP2_COMPAT32RB) != 0) {
return (EBUSY);
}
bzero(&rb, sizeof(rb));
error = ops->copyin_robust_lists(uap->uaddr1, uap->val, &rb);
if (error != 0)
return (error);
if (ops->compat32)
td->td_pflags2 |= TDP2_COMPAT32RB;
td->td_rb_list = rb.robust_list_offset;
td->td_rbp_list = rb.robust_priv_list_offset;
td->td_rb_inact = rb.robust_inact_offset;
return (0);
}
#if defined(__i386__) || defined(__amd64__)
/*
* Provide the standard 32-bit definitions for x86, since native/compat32 use a
* 32-bit time_t there. Other architectures just need the i386 definitions
* along with their standard compat32.
*/
struct timespecx32 {
int64_t tv_sec;
int32_t tv_nsec;
};
struct umtx_timex32 {
struct timespecx32 _timeout;
uint32_t _flags;
uint32_t _clockid;
};
#ifndef __i386__
#define timespeci386 timespec32
#define umtx_timei386 umtx_time32
#endif
#else /* !__i386__ && !__amd64__ */
/* 32-bit architectures can emulate i386, so define these almost everywhere. */
struct timespeci386 {
int32_t tv_sec;
int32_t tv_nsec;
};
struct umtx_timei386 {
struct timespeci386 _timeout;
uint32_t _flags;
uint32_t _clockid;
};
#if defined(__LP64__)
#define timespecx32 timespec32
#define umtx_timex32 umtx_time32
#endif
#endif
static int
umtx_copyin_robust_lists32(const void *uaddr, size_t size,
struct umtx_robust_lists_params *rbp)
{
struct umtx_robust_lists_params_compat32 rb32;
int error;
if (size > sizeof(rb32))
return (EINVAL);
bzero(&rb32, sizeof(rb32));
error = copyin(uaddr, &rb32, size);
if (error != 0)
return (error);
CP(rb32, *rbp, robust_list_offset);
CP(rb32, *rbp, robust_priv_list_offset);
CP(rb32, *rbp, robust_inact_offset);
return (0);
}
#ifndef __i386__
static inline int
umtx_copyin_timeouti386(const void *uaddr, struct timespec *tsp)
{
struct timespeci386 ts32;
int error;
error = copyin(uaddr, &ts32, sizeof(ts32));
if (error == 0) {
if (ts32.tv_sec < 0 ||
ts32.tv_nsec >= 1000000000 ||
ts32.tv_nsec < 0)
error = EINVAL;
else {
CP(ts32, *tsp, tv_sec);
CP(ts32, *tsp, tv_nsec);
}
}
return (error);
}
static inline int
umtx_copyin_umtx_timei386(const void *uaddr, size_t size, struct _umtx_time *tp)
{
struct umtx_timei386 t32;
int error;
t32._clockid = CLOCK_REALTIME;
t32._flags = 0;
if (size <= sizeof(t32._timeout))
error = copyin(uaddr, &t32._timeout, sizeof(t32._timeout));
else
error = copyin(uaddr, &t32, sizeof(t32));
if (error != 0)
return (error);
if (t32._timeout.tv_sec < 0 ||
t32._timeout.tv_nsec >= 1000000000 || t32._timeout.tv_nsec < 0)
return (EINVAL);
TS_CP(t32, *tp, _timeout);
CP(t32, *tp, _flags);
CP(t32, *tp, _clockid);
return (0);
}
static int
umtx_copyout_timeouti386(void *uaddr, size_t sz, struct timespec *tsp)
{
struct timespeci386 remain32 = {
.tv_sec = tsp->tv_sec,
.tv_nsec = tsp->tv_nsec,
};
/*
* Should be guaranteed by the caller, sz == uaddr1 - sizeof(_umtx_time)
* and we're only called if sz >= sizeof(timespec) as supplied in the
* copyops.
*/
KASSERT(sz >= sizeof(remain32),
("umtx_copyops specifies incorrect sizes"));
return (copyout(&remain32, uaddr, sizeof(remain32)));
}
#endif /* !__i386__ */
#if defined(__i386__) || defined(__LP64__)
static inline int
umtx_copyin_timeoutx32(const void *uaddr, struct timespec *tsp)
{
struct timespecx32 ts32;
int error;
error = copyin(uaddr, &ts32, sizeof(ts32));
if (error == 0) {
if (ts32.tv_sec < 0 ||
ts32.tv_nsec >= 1000000000 ||
ts32.tv_nsec < 0)
error = EINVAL;
else {
CP(ts32, *tsp, tv_sec);
CP(ts32, *tsp, tv_nsec);
}
}
return (error);
}
static inline int
umtx_copyin_umtx_timex32(const void *uaddr, size_t size, struct _umtx_time *tp)
{
struct umtx_timex32 t32;
int error;
t32._clockid = CLOCK_REALTIME;
t32._flags = 0;
if (size <= sizeof(t32._timeout))
error = copyin(uaddr, &t32._timeout, sizeof(t32._timeout));
else
error = copyin(uaddr, &t32, sizeof(t32));
if (error != 0)
return (error);
if (t32._timeout.tv_sec < 0 ||
t32._timeout.tv_nsec >= 1000000000 || t32._timeout.tv_nsec < 0)
return (EINVAL);
TS_CP(t32, *tp, _timeout);
CP(t32, *tp, _flags);
CP(t32, *tp, _clockid);
return (0);
}
static int
umtx_copyout_timeoutx32(void *uaddr, size_t sz, struct timespec *tsp)
{
struct timespecx32 remain32 = {
.tv_sec = tsp->tv_sec,
.tv_nsec = tsp->tv_nsec,
};
/*
* Should be guaranteed by the caller, sz == uaddr1 - sizeof(_umtx_time)
* and we're only called if sz >= sizeof(timespec) as supplied in the
* copyops.
*/
KASSERT(sz >= sizeof(remain32),
("umtx_copyops specifies incorrect sizes"));
return (copyout(&remain32, uaddr, sizeof(remain32)));
}
#endif /* __i386__ || __LP64__ */
typedef int (*_umtx_op_func)(struct thread *td, struct _umtx_op_args *uap,
const struct umtx_copyops *umtx_ops);
static const _umtx_op_func op_table[] = {
[UMTX_OP_RESERVED0] = __umtx_op_unimpl,
[UMTX_OP_RESERVED1] = __umtx_op_unimpl,
[UMTX_OP_WAIT] = __umtx_op_wait,
[UMTX_OP_WAKE] = __umtx_op_wake,
[UMTX_OP_MUTEX_TRYLOCK] = __umtx_op_trylock_umutex,
[UMTX_OP_MUTEX_LOCK] = __umtx_op_lock_umutex,
[UMTX_OP_MUTEX_UNLOCK] = __umtx_op_unlock_umutex,
[UMTX_OP_SET_CEILING] = __umtx_op_set_ceiling,
[UMTX_OP_CV_WAIT] = __umtx_op_cv_wait,
[UMTX_OP_CV_SIGNAL] = __umtx_op_cv_signal,
[UMTX_OP_CV_BROADCAST] = __umtx_op_cv_broadcast,
[UMTX_OP_WAIT_UINT] = __umtx_op_wait_uint,
[UMTX_OP_RW_RDLOCK] = __umtx_op_rw_rdlock,
[UMTX_OP_RW_WRLOCK] = __umtx_op_rw_wrlock,
[UMTX_OP_RW_UNLOCK] = __umtx_op_rw_unlock,
[UMTX_OP_WAIT_UINT_PRIVATE] = __umtx_op_wait_uint_private,
[UMTX_OP_WAKE_PRIVATE] = __umtx_op_wake_private,
[UMTX_OP_MUTEX_WAIT] = __umtx_op_wait_umutex,
[UMTX_OP_MUTEX_WAKE] = __umtx_op_wake_umutex,
#if defined(COMPAT_FREEBSD9) || defined(COMPAT_FREEBSD10)
[UMTX_OP_SEM_WAIT] = __umtx_op_sem_wait,
[UMTX_OP_SEM_WAKE] = __umtx_op_sem_wake,
#else
[UMTX_OP_SEM_WAIT] = __umtx_op_unimpl,
[UMTX_OP_SEM_WAKE] = __umtx_op_unimpl,
#endif
[UMTX_OP_NWAKE_PRIVATE] = __umtx_op_nwake_private,
[UMTX_OP_MUTEX_WAKE2] = __umtx_op_wake2_umutex,
[UMTX_OP_SEM2_WAIT] = __umtx_op_sem2_wait,
[UMTX_OP_SEM2_WAKE] = __umtx_op_sem2_wake,
[UMTX_OP_SHM] = __umtx_op_shm,
[UMTX_OP_ROBUST_LISTS] = __umtx_op_robust_lists,
};
static const struct umtx_copyops umtx_native_ops = {
.copyin_timeout = umtx_copyin_timeout,
.copyin_umtx_time = umtx_copyin_umtx_time,
.copyin_robust_lists = umtx_copyin_robust_lists,
.copyout_timeout = umtx_copyout_timeout,
.timespec_sz = sizeof(struct timespec),
.umtx_time_sz = sizeof(struct _umtx_time),
};
#ifndef __i386__
static const struct umtx_copyops umtx_native_opsi386 = {
.copyin_timeout = umtx_copyin_timeouti386,
.copyin_umtx_time = umtx_copyin_umtx_timei386,
.copyin_robust_lists = umtx_copyin_robust_lists32,
.copyout_timeout = umtx_copyout_timeouti386,
.timespec_sz = sizeof(struct timespeci386),
.umtx_time_sz = sizeof(struct umtx_timei386),
.compat32 = true,
};
#endif
#if defined(__i386__) || defined(__LP64__)
/* i386 can emulate other 32-bit archs, too! */
static const struct umtx_copyops umtx_native_opsx32 = {
.copyin_timeout = umtx_copyin_timeoutx32,
.copyin_umtx_time = umtx_copyin_umtx_timex32,
.copyin_robust_lists = umtx_copyin_robust_lists32,
.copyout_timeout = umtx_copyout_timeoutx32,
.timespec_sz = sizeof(struct timespecx32),
.umtx_time_sz = sizeof(struct umtx_timex32),
.compat32 = true,
};
#ifdef COMPAT_FREEBSD32
#ifdef __amd64__
#define umtx_native_ops32 umtx_native_opsi386
#else
#define umtx_native_ops32 umtx_native_opsx32
#endif
#endif /* COMPAT_FREEBSD32 */
#endif /* __i386__ || __LP64__ */
#define UMTX_OP__FLAGS (UMTX_OP__32BIT | UMTX_OP__I386)
static int
kern__umtx_op(struct thread *td, void *obj, int op, unsigned long val,
void *uaddr1, void *uaddr2, const struct umtx_copyops *ops)
{
struct _umtx_op_args uap = {
.obj = obj,
.op = op & ~UMTX_OP__FLAGS,
.val = val,
.uaddr1 = uaddr1,
.uaddr2 = uaddr2
};
if ((uap.op >= nitems(op_table)))
return (EINVAL);
return ((*op_table[uap.op])(td, &uap, ops));
}
int
sys__umtx_op(struct thread *td, struct _umtx_op_args *uap)
{
static const struct umtx_copyops *umtx_ops;
umtx_ops = &umtx_native_ops;
#ifdef __LP64__
if ((uap->op & (UMTX_OP__32BIT | UMTX_OP__I386)) != 0) {
if ((uap->op & UMTX_OP__I386) != 0)
umtx_ops = &umtx_native_opsi386;
else
umtx_ops = &umtx_native_opsx32;
}
#elif !defined(__i386__)
/* We consider UMTX_OP__32BIT a nop on !i386 ILP32. */
if ((uap->op & UMTX_OP__I386) != 0)
umtx_ops = &umtx_native_opsi386;
#else
/* Likewise, UMTX_OP__I386 is a nop on i386. */
if ((uap->op & UMTX_OP__32BIT) != 0)
umtx_ops = &umtx_native_opsx32;
#endif
return (kern__umtx_op(td, uap->obj, uap->op, uap->val, uap->uaddr1,
uap->uaddr2, umtx_ops));
}
#ifdef COMPAT_FREEBSD32
int
freebsd32__umtx_op(struct thread *td, struct freebsd32__umtx_op_args *uap)
{
return (kern__umtx_op(td, uap->obj, uap->op, uap->val, uap->uaddr,
uap->uaddr2, &umtx_native_ops32));
}
#endif
void
umtx_thread_init(struct thread *td)
{
td->td_umtxq = umtxq_alloc();
td->td_umtxq->uq_thread = td;
}
void
umtx_thread_fini(struct thread *td)
{
umtxq_free(td->td_umtxq);
}
/*
* It will be called when new thread is created, e.g fork().
*/
void
umtx_thread_alloc(struct thread *td)
{
struct umtx_q *uq;
uq = td->td_umtxq;
uq->uq_inherited_pri = PRI_MAX;
KASSERT(uq->uq_flags == 0, ("uq_flags != 0"));
KASSERT(uq->uq_thread == td, ("uq_thread != td"));
KASSERT(uq->uq_pi_blocked == NULL, ("uq_pi_blocked != NULL"));
KASSERT(TAILQ_EMPTY(&uq->uq_pi_contested), ("uq_pi_contested is not empty"));
}
/*
* exec() hook.
*
* Clear robust lists for all process' threads, not delaying the
* cleanup to thread exit, since the relevant address space is
* destroyed right now.
*/
void
umtx_exec(struct proc *p)
{
struct thread *td;
KASSERT(p == curproc, ("need curproc"));
KASSERT((p->p_flag & P_HADTHREADS) == 0 ||
(p->p_flag & P_STOPPED_SINGLE) != 0,
("curproc must be single-threaded"));
/*
* There is no need to lock the list as only this thread can be
* running.
*/
FOREACH_THREAD_IN_PROC(p, td) {
KASSERT(td == curthread ||
((td->td_flags & TDF_BOUNDARY) != 0 && TD_IS_SUSPENDED(td)),
("running thread %p %p", p, td));
umtx_thread_cleanup(td);
td->td_rb_list = td->td_rbp_list = td->td_rb_inact = 0;
}
}
/*
* thread exit hook.
*/
void
umtx_thread_exit(struct thread *td)
{
umtx_thread_cleanup(td);
}
static int
umtx_read_uptr(struct thread *td, uintptr_t ptr, uintptr_t *res, bool compat32)
{
u_long res1;
uint32_t res32;
int error;
if (compat32) {
error = fueword32((void *)ptr, &res32);
if (error == 0)
res1 = res32;
} else {
error = fueword((void *)ptr, &res1);
}
if (error == 0)
*res = res1;
else
error = EFAULT;
return (error);
}
static void
umtx_read_rb_list(struct thread *td, struct umutex *m, uintptr_t *rb_list,
bool compat32)
{
struct umutex32 m32;
if (compat32) {
memcpy(&m32, m, sizeof(m32));
*rb_list = m32.m_rb_lnk;
} else {
*rb_list = m->m_rb_lnk;
}
}
static int
umtx_handle_rb(struct thread *td, uintptr_t rbp, uintptr_t *rb_list, bool inact,
bool compat32)
{
struct umutex m;
int error;
KASSERT(td->td_proc == curproc, ("need current vmspace"));
error = copyin((void *)rbp, &m, sizeof(m));
if (error != 0)
return (error);
if (rb_list != NULL)
umtx_read_rb_list(td, &m, rb_list, compat32);
if ((m.m_flags & UMUTEX_ROBUST) == 0)
return (EINVAL);
if ((m.m_owner & ~UMUTEX_CONTESTED) != td->td_tid)
/* inact is cleared after unlock, allow the inconsistency */
return (inact ? 0 : EINVAL);
return (do_unlock_umutex(td, (struct umutex *)rbp, true));
}
static void
umtx_cleanup_rb_list(struct thread *td, uintptr_t rb_list, uintptr_t *rb_inact,
const char *name, bool compat32)
{
int error, i;
uintptr_t rbp;
bool inact;
if (rb_list == 0)
return;
error = umtx_read_uptr(td, rb_list, &rbp, compat32);
for (i = 0; error == 0 && rbp != 0 && i < umtx_max_rb; i++) {
if (rbp == *rb_inact) {
inact = true;
*rb_inact = 0;
} else
inact = false;
error = umtx_handle_rb(td, rbp, &rbp, inact, compat32);
}
if (i == umtx_max_rb && umtx_verbose_rb) {
uprintf("comm %s pid %d: reached umtx %smax rb %d\n",
td->td_proc->p_comm, td->td_proc->p_pid, name, umtx_max_rb);
}
if (error != 0 && umtx_verbose_rb) {
uprintf("comm %s pid %d: handling %srb error %d\n",
td->td_proc->p_comm, td->td_proc->p_pid, name, error);
}
}
/*
* Clean up umtx data.
*/
static void
umtx_thread_cleanup(struct thread *td)
{
struct umtx_q *uq;
struct umtx_pi *pi;
uintptr_t rb_inact;
bool compat32;
/*
* Disown pi mutexes.
*/
uq = td->td_umtxq;
if (uq != NULL) {
if (uq->uq_inherited_pri != PRI_MAX ||
!TAILQ_EMPTY(&uq->uq_pi_contested)) {
mtx_lock(&umtx_lock);
uq->uq_inherited_pri = PRI_MAX;
while ((pi = TAILQ_FIRST(&uq->uq_pi_contested)) != NULL) {
pi->pi_owner = NULL;
TAILQ_REMOVE(&uq->uq_pi_contested, pi, pi_link);
}
mtx_unlock(&umtx_lock);
}
sched_lend_user_prio_cond(td, PRI_MAX);
}
compat32 = (td->td_pflags2 & TDP2_COMPAT32RB) != 0;
td->td_pflags2 &= ~TDP2_COMPAT32RB;
if (td->td_rb_inact == 0 && td->td_rb_list == 0 && td->td_rbp_list == 0)
return;
/*
* Handle terminated robust mutexes. Must be done after
* robust pi disown, otherwise unlock could see unowned
* entries.
*/
rb_inact = td->td_rb_inact;
if (rb_inact != 0)
(void)umtx_read_uptr(td, rb_inact, &rb_inact, compat32);
umtx_cleanup_rb_list(td, td->td_rb_list, &rb_inact, "", compat32);
umtx_cleanup_rb_list(td, td->td_rbp_list, &rb_inact, "priv ", compat32);
if (rb_inact != 0)
(void)umtx_handle_rb(td, rb_inact, NULL, true, compat32);
}