glibc/nptl/pthread_create.c
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/* Copyright (C) 2002-2007,2008,2009 Free Software Foundation, Inc.
This file is part of the GNU C Library.
Contributed by Ulrich Drepper <drepper@redhat.com>, 2002.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, write to the Free
Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
02111-1307 USA. */
#include <errno.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include "pthreadP.h"
#include <hp-timing.h>
#include <ldsodefs.h>
#include <atomic.h>
#include <libc-internal.h>
#include <resolv.h>
#include <kernel-features.h>
#include <shlib-compat.h>
/* Local function to start thread and handle cleanup. */
static int start_thread (void *arg);
/* Nozero if debugging mode is enabled. */
int __pthread_debug;
/* Globally enabled events. */
static td_thr_events_t __nptl_threads_events __attribute_used__;
/* Pointer to descriptor with the last event. */
static struct pthread *__nptl_last_event __attribute_used__;
/* Number of threads running. */
unsigned int __nptl_nthreads = 1;
/* Code to allocate and deallocate a stack. */
#include "allocatestack.c"
/* Code to create the thread. */
#include <createthread.c>
struct pthread *
internal_function
__find_in_stack_list (pd)
struct pthread *pd;
{
list_t *entry;
struct pthread *result = NULL;
lll_lock (stack_cache_lock, LLL_PRIVATE);
list_for_each (entry, &stack_used)
{
struct pthread *curp;
curp = list_entry (entry, struct pthread, list);
if (curp == pd)
{
result = curp;
break;
}
}
if (result == NULL)
list_for_each (entry, &__stack_user)
{
struct pthread *curp;
curp = list_entry (entry, struct pthread, list);
if (curp == pd)
{
result = curp;
break;
}
}
lll_unlock (stack_cache_lock, LLL_PRIVATE);
return result;
}
/* Deallocate POSIX thread-local-storage. */
void
attribute_hidden
__nptl_deallocate_tsd (void)
{
struct pthread *self = THREAD_SELF;
/* Maybe no data was ever allocated. This happens often so we have
a flag for this. */
if (THREAD_GETMEM (self, specific_used))
{
size_t round;
size_t cnt;
round = 0;
do
{
size_t idx;
/* So far no new nonzero data entry. */
THREAD_SETMEM (self, specific_used, false);
for (cnt = idx = 0; cnt < PTHREAD_KEY_1STLEVEL_SIZE; ++cnt)
{
struct pthread_key_data *level2;
level2 = THREAD_GETMEM_NC (self, specific, cnt);
if (level2 != NULL)
{
size_t inner;
for (inner = 0; inner < PTHREAD_KEY_2NDLEVEL_SIZE;
++inner, ++idx)
{
void *data = level2[inner].data;
if (data != NULL)
{
/* Always clear the data. */
level2[inner].data = NULL;
/* Make sure the data corresponds to a valid
key. This test fails if the key was
deallocated and also if it was
re-allocated. It is the user's
responsibility to free the memory in this
case. */
if (level2[inner].seq
== __pthread_keys[idx].seq
/* It is not necessary to register a destructor
function. */
&& __pthread_keys[idx].destr != NULL)
/* Call the user-provided destructor. */
__pthread_keys[idx].destr (data);
}
}
}
else
idx += PTHREAD_KEY_1STLEVEL_SIZE;
}
if (THREAD_GETMEM (self, specific_used) == 0)
/* No data has been modified. */
goto just_free;
}
/* We only repeat the process a fixed number of times. */
while (__builtin_expect (++round < PTHREAD_DESTRUCTOR_ITERATIONS, 0));
/* Just clear the memory of the first block for reuse. */
memset (&THREAD_SELF->specific_1stblock, '\0',
sizeof (self->specific_1stblock));
just_free:
/* Free the memory for the other blocks. */
for (cnt = 1; cnt < PTHREAD_KEY_1STLEVEL_SIZE; ++cnt)
{
struct pthread_key_data *level2;
level2 = THREAD_GETMEM_NC (self, specific, cnt);
if (level2 != NULL)
{
/* The first block is allocated as part of the thread
descriptor. */
free (level2);
THREAD_SETMEM_NC (self, specific, cnt, NULL);
}
}
THREAD_SETMEM (self, specific_used, false);
}
}
/* Deallocate a thread's stack after optionally making sure the thread
descriptor is still valid. */
void
internal_function
__free_tcb (struct pthread *pd)
{
/* The thread is exiting now. */
if (__builtin_expect (atomic_bit_test_set (&pd->cancelhandling,
TERMINATED_BIT) == 0, 1))
{
/* Remove the descriptor from the list. */
if (DEBUGGING_P && __find_in_stack_list (pd) == NULL)
/* Something is really wrong. The descriptor for a still
running thread is gone. */
abort ();
/* Free TPP data. */
if (__builtin_expect (pd->tpp != NULL, 0))
{
struct priority_protection_data *tpp = pd->tpp;
pd->tpp = NULL;
free (tpp);
}
/* Queue the stack memory block for reuse and exit the process. The
kernel will signal via writing to the address returned by
QUEUE-STACK when the stack is available. */
__deallocate_stack (pd);
}
}
static int
start_thread (void *arg)
{
struct pthread *pd = (struct pthread *) arg;
#if HP_TIMING_AVAIL
/* Remember the time when the thread was started. */
hp_timing_t now;
HP_TIMING_NOW (now);
THREAD_SETMEM (pd, cpuclock_offset, now);
#endif
/* Initialize resolver state pointer. */
__resp = &pd->res;
#ifdef __NR_set_robust_list
# ifndef __ASSUME_SET_ROBUST_LIST
if (__set_robust_list_avail >= 0)
# endif
{
INTERNAL_SYSCALL_DECL (err);
/* This call should never fail because the initial call in init.c
succeeded. */
INTERNAL_SYSCALL (set_robust_list, err, 2, &pd->robust_head,
sizeof (struct robust_list_head));
}
#endif
/* If the parent was running cancellation handlers while creating
the thread the new thread inherited the signal mask. Reset the
cancellation signal mask. */
if (__builtin_expect (pd->parent_cancelhandling & CANCELING_BITMASK, 0))
{
INTERNAL_SYSCALL_DECL (err);
sigset_t mask;
__sigemptyset (&mask);
__sigaddset (&mask, SIGCANCEL);
(void) INTERNAL_SYSCALL (rt_sigprocmask, err, 4, SIG_UNBLOCK, &mask,
NULL, _NSIG / 8);
}
/* This is where the try/finally block should be created. For
compilers without that support we do use setjmp. */
struct pthread_unwind_buf unwind_buf;
/* No previous handlers. */
unwind_buf.priv.data.prev = NULL;
unwind_buf.priv.data.cleanup = NULL;
int not_first_call;
not_first_call = setjmp ((struct __jmp_buf_tag *) unwind_buf.cancel_jmp_buf);
if (__builtin_expect (! not_first_call, 1))
{
/* Store the new cleanup handler info. */
THREAD_SETMEM (pd, cleanup_jmp_buf, &unwind_buf);
if (__builtin_expect (pd->stopped_start, 0))
{
int oldtype = CANCEL_ASYNC ();
/* Get the lock the parent locked to force synchronization. */
lll_lock (pd->lock, LLL_PRIVATE);
/* And give it up right away. */
lll_unlock (pd->lock, LLL_PRIVATE);
CANCEL_RESET (oldtype);
}
/* Run the code the user provided. */
#ifdef CALL_THREAD_FCT
THREAD_SETMEM (pd, result, CALL_THREAD_FCT (pd));
#else
THREAD_SETMEM (pd, result, pd->start_routine (pd->arg));
#endif
}
/* Run the destructor for the thread-local data. */
__nptl_deallocate_tsd ();
/* Clean up any state libc stored in thread-local variables. */
__libc_thread_freeres ();
/* If this is the last thread we terminate the process now. We
do not notify the debugger, it might just irritate it if there
is no thread left. */
if (__builtin_expect (atomic_decrement_and_test (&__nptl_nthreads), 0))
/* This was the last thread. */
exit (0);
/* Report the death of the thread if this is wanted. */
if (__builtin_expect (pd->report_events, 0))
{
/* See whether TD_DEATH is in any of the mask. */
const int idx = __td_eventword (TD_DEATH);
const uint32_t mask = __td_eventmask (TD_DEATH);
if ((mask & (__nptl_threads_events.event_bits[idx]
| pd->eventbuf.eventmask.event_bits[idx])) != 0)
{
/* Yep, we have to signal the death. Add the descriptor to
the list but only if it is not already on it. */
if (pd->nextevent == NULL)
{
pd->eventbuf.eventnum = TD_DEATH;
pd->eventbuf.eventdata = pd;
do
pd->nextevent = __nptl_last_event;
while (atomic_compare_and_exchange_bool_acq (&__nptl_last_event,
pd, pd->nextevent));
}
/* Now call the function to signal the event. */
__nptl_death_event ();
}
}
/* The thread is exiting now. Don't set this bit until after we've hit
the event-reporting breakpoint, so that td_thr_get_info on us while at
the breakpoint reports TD_THR_RUN state rather than TD_THR_ZOMBIE. */
atomic_bit_set (&pd->cancelhandling, EXITING_BIT);
#ifndef __ASSUME_SET_ROBUST_LIST
/* If this thread has any robust mutexes locked, handle them now. */
# if __WORDSIZE == 64
void *robust = pd->robust_head.list;
# else
__pthread_slist_t *robust = pd->robust_list.__next;
# endif
/* We let the kernel do the notification if it is able to do so.
If we have to do it here there for sure are no PI mutexes involved
since the kernel support for them is even more recent. */
if (__set_robust_list_avail < 0
&& __builtin_expect (robust != (void *) &pd->robust_head, 0))
{
do
{
struct __pthread_mutex_s *this = (struct __pthread_mutex_s *)
((char *) robust - offsetof (struct __pthread_mutex_s,
__list.__next));
robust = *((void **) robust);
# ifdef __PTHREAD_MUTEX_HAVE_PREV
this->__list.__prev = NULL;
# endif
this->__list.__next = NULL;
lll_robust_dead (this->__lock, /* XYZ */ LLL_SHARED);
}
while (robust != (void *) &pd->robust_head);
}
#endif
/* If the thread is detached free the TCB. */
if (IS_DETACHED (pd))
/* Free the TCB. */
__free_tcb (pd);
else if (__builtin_expect (pd->cancelhandling & SETXID_BITMASK, 0))
{
/* Some other thread might call any of the setXid functions and expect
us to reply. In this case wait until we did that. */
do
lll_futex_wait (&pd->setxid_futex, 0, LLL_PRIVATE);
while (pd->cancelhandling & SETXID_BITMASK);
/* Reset the value so that the stack can be reused. */
pd->setxid_futex = 0;
}
/* We cannot call '_exit' here. '_exit' will terminate the process.
The 'exit' implementation in the kernel will signal when the
process is really dead since 'clone' got passed the CLONE_CLEARTID
flag. The 'tid' field in the TCB will be set to zero.
The exit code is zero since in case all threads exit by calling
'pthread_exit' the exit status must be 0 (zero). */
__exit_thread_inline (0);
/* NOTREACHED */
return 0;
}
/* Default thread attributes for the case when the user does not
provide any. */
static const struct pthread_attr default_attr =
{
/* Just some value > 0 which gets rounded to the nearest page size. */
.guardsize = 1,
};
int
__pthread_create_2_1 (newthread, attr, start_routine, arg)
pthread_t *newthread;
const pthread_attr_t *attr;
void *(*start_routine) (void *);
void *arg;
{
STACK_VARIABLES;
const struct pthread_attr *iattr = (struct pthread_attr *) attr;
if (iattr == NULL)
/* Is this the best idea? On NUMA machines this could mean
accessing far-away memory. */
iattr = &default_attr;
struct pthread *pd = NULL;
int err = ALLOCATE_STACK (iattr, &pd);
if (__builtin_expect (err != 0, 0))
/* Something went wrong. Maybe a parameter of the attributes is
invalid or we could not allocate memory. */
return err;
/* Initialize the TCB. All initializations with zero should be
performed in 'get_cached_stack'. This way we avoid doing this if
the stack freshly allocated with 'mmap'. */
#ifdef TLS_TCB_AT_TP
/* Reference to the TCB itself. */
pd->header.self = pd;
/* Self-reference for TLS. */
pd->header.tcb = pd;
#endif
/* Store the address of the start routine and the parameter. Since
we do not start the function directly the stillborn thread will
get the information from its thread descriptor. */
pd->start_routine = start_routine;
pd->arg = arg;
/* Copy the thread attribute flags. */
struct pthread *self = THREAD_SELF;
pd->flags = ((iattr->flags & ~(ATTR_FLAG_SCHED_SET | ATTR_FLAG_POLICY_SET))
| (self->flags & (ATTR_FLAG_SCHED_SET | ATTR_FLAG_POLICY_SET)));
/* Initialize the field for the ID of the thread which is waiting
for us. This is a self-reference in case the thread is created
detached. */
pd->joinid = iattr->flags & ATTR_FLAG_DETACHSTATE ? pd : NULL;
/* The debug events are inherited from the parent. */
pd->eventbuf = self->eventbuf;
/* Copy the parent's scheduling parameters. The flags will say what
is valid and what is not. */
pd->schedpolicy = self->schedpolicy;
pd->schedparam = self->schedparam;
/* Copy the stack guard canary. */
#ifdef THREAD_COPY_STACK_GUARD
THREAD_COPY_STACK_GUARD (pd);
#endif
/* Copy the pointer guard value. */
#ifdef THREAD_COPY_POINTER_GUARD
THREAD_COPY_POINTER_GUARD (pd);
#endif
/* Determine scheduling parameters for the thread. */
if (attr != NULL
&& __builtin_expect ((iattr->flags & ATTR_FLAG_NOTINHERITSCHED) != 0, 0)
&& (iattr->flags & (ATTR_FLAG_SCHED_SET | ATTR_FLAG_POLICY_SET)) != 0)
{
INTERNAL_SYSCALL_DECL (scerr);
/* Use the scheduling parameters the user provided. */
if (iattr->flags & ATTR_FLAG_POLICY_SET)
pd->schedpolicy = iattr->schedpolicy;
else if ((pd->flags & ATTR_FLAG_POLICY_SET) == 0)
{
pd->schedpolicy = INTERNAL_SYSCALL (sched_getscheduler, scerr, 1, 0);
pd->flags |= ATTR_FLAG_POLICY_SET;
}
if (iattr->flags & ATTR_FLAG_SCHED_SET)
memcpy (&pd->schedparam, &iattr->schedparam,
sizeof (struct sched_param));
else if ((pd->flags & ATTR_FLAG_SCHED_SET) == 0)
{
INTERNAL_SYSCALL (sched_getparam, scerr, 2, 0, &pd->schedparam);
pd->flags |= ATTR_FLAG_SCHED_SET;
}
/* Check for valid priorities. */
int minprio = INTERNAL_SYSCALL (sched_get_priority_min, scerr, 1,
iattr->schedpolicy);
int maxprio = INTERNAL_SYSCALL (sched_get_priority_max, scerr, 1,
iattr->schedpolicy);
if (pd->schedparam.sched_priority < minprio
|| pd->schedparam.sched_priority > maxprio)
{
err = EINVAL;
goto errout;
}
}
/* Pass the descriptor to the caller. */
*newthread = (pthread_t) pd;
/* Remember whether the thread is detached or not. In case of an
error we have to free the stacks of non-detached stillborn
threads. */
bool is_detached = IS_DETACHED (pd);
/* Start the thread. */
err = create_thread (pd, iattr, STACK_VARIABLES_ARGS);
if (err != 0)
{
/* Something went wrong. Free the resources. */
if (!is_detached)
{
errout:
__deallocate_stack (pd);
}
return err;
}
return 0;
}
versioned_symbol (libpthread, __pthread_create_2_1, pthread_create, GLIBC_2_1);
#if SHLIB_COMPAT(libpthread, GLIBC_2_0, GLIBC_2_1)
int
__pthread_create_2_0 (newthread, attr, start_routine, arg)
pthread_t *newthread;
const pthread_attr_t *attr;
void *(*start_routine) (void *);
void *arg;
{
/* The ATTR attribute is not really of type `pthread_attr_t *'. It has
the old size and access to the new members might crash the program.
We convert the struct now. */
struct pthread_attr new_attr;
if (attr != NULL)
{
struct pthread_attr *iattr = (struct pthread_attr *) attr;
size_t ps = __getpagesize ();
/* Copy values from the user-provided attributes. */
new_attr.schedparam = iattr->schedparam;
new_attr.schedpolicy = iattr->schedpolicy;
new_attr.flags = iattr->flags;
/* Fill in default values for the fields not present in the old
implementation. */
new_attr.guardsize = ps;
new_attr.stackaddr = NULL;
new_attr.stacksize = 0;
new_attr.cpuset = NULL;
/* We will pass this value on to the real implementation. */
attr = (pthread_attr_t *) &new_attr;
}
return __pthread_create_2_1 (newthread, attr, start_routine, arg);
}
compat_symbol (libpthread, __pthread_create_2_0, pthread_create,
GLIBC_2_0);
#endif
/* Information for libthread_db. */
#include "../nptl_db/db_info.c"
/* If pthread_create is present, libgcc_eh.a and libsupc++.a expects some other POSIX thread
functions to be present as well. */
PTHREAD_STATIC_FN_REQUIRE (pthread_mutex_lock)
PTHREAD_STATIC_FN_REQUIRE (pthread_mutex_trylock)
PTHREAD_STATIC_FN_REQUIRE (pthread_mutex_unlock)
PTHREAD_STATIC_FN_REQUIRE (pthread_once)
PTHREAD_STATIC_FN_REQUIRE (pthread_cancel)
PTHREAD_STATIC_FN_REQUIRE (pthread_key_create)
PTHREAD_STATIC_FN_REQUIRE (pthread_key_delete)
PTHREAD_STATIC_FN_REQUIRE (pthread_setspecific)
PTHREAD_STATIC_FN_REQUIRE (pthread_getspecific)