glibc/linuxthreads/pthread.c
Ulrich Drepper 41b37cb517 Update.
* manager.c (pthread_handle_free): Likewise.
2000-06-10 07:58:50 +00:00

998 lines
34 KiB
C

/* Linuxthreads - a simple clone()-based implementation of Posix */
/* threads for Linux. */
/* Copyright (C) 1996 Xavier Leroy (Xavier.Leroy@inria.fr) */
/* */
/* This program is free software; you can redistribute it and/or */
/* modify it under the terms of the GNU Library General Public License */
/* as published by the Free Software Foundation; either version 2 */
/* of the License, or (at your option) any later version. */
/* */
/* This program 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 Library General Public License for more details. */
/* Thread creation, initialization, and basic low-level routines */
#include <errno.h>
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <fcntl.h>
#include <sys/wait.h>
#include <sys/resource.h>
#include <shlib-compat.h>
#include "pthread.h"
#include "internals.h"
#include "spinlock.h"
#include "restart.h"
/* Sanity check. */
#if __ASSUME_REALTIME_SIGNALS && !defined __SIGRTMIN
# error "This must not happen; new kernel assumed but old headers"
#endif
/* Descriptor of the initial thread */
struct _pthread_descr_struct __pthread_initial_thread = {
{
{
&__pthread_initial_thread /* pthread_descr self */
}
},
&__pthread_initial_thread, /* pthread_descr p_nextlive */
&__pthread_initial_thread, /* pthread_descr p_prevlive */
NULL, /* pthread_descr p_nextwaiting */
NULL, /* pthread_descr p_nextlock */
PTHREAD_THREADS_MAX, /* pthread_t p_tid */
0, /* int p_pid */
0, /* int p_priority */
&__pthread_handles[0].h_lock, /* struct _pthread_fastlock * p_lock */
0, /* int p_signal */
NULL, /* sigjmp_buf * p_signal_buf */
NULL, /* sigjmp_buf * p_cancel_buf */
0, /* char p_terminated */
0, /* char p_detached */
0, /* char p_exited */
NULL, /* void * p_retval */
0, /* int p_retval */
NULL, /* pthread_descr p_joining */
NULL, /* struct _pthread_cleanup_buffer * p_cleanup */
0, /* char p_cancelstate */
0, /* char p_canceltype */
0, /* char p_canceled */
NULL, /* int *p_errnop */
0, /* int p_errno */
NULL, /* int *p_h_errnop */
0, /* int p_h_errno */
NULL, /* char * p_in_sighandler */
0, /* char p_sigwaiting */
PTHREAD_START_ARGS_INITIALIZER(NULL),
/* struct pthread_start_args p_start_args */
{NULL}, /* void ** p_specific[PTHREAD_KEY_1STLEVEL_SIZE] */
{NULL}, /* void * p_libc_specific[_LIBC_TSD_KEY_N] */
0, /* int p_userstack */
NULL, /* void * p_guardaddr */
0, /* size_t p_guardsize */
0, /* Always index 0 */
0, /* int p_report_events */
{{{0, }}, 0, NULL}, /* td_eventbuf_t p_eventbuf */
ATOMIC_INITIALIZER, /* struct pthread_atomic p_resume_count */
0, /* char p_woken_by_cancel */
NULL, /* struct pthread_extricate_if *p_extricate */
NULL, /* pthread_readlock_info *p_readlock_list; */
NULL, /* pthread_readlock_info *p_readlock_free; */
0 /* int p_untracked_readlock_count; */
};
/* Descriptor of the manager thread; none of this is used but the error
variables, the p_pid and p_priority fields,
and the address for identification. */
struct _pthread_descr_struct __pthread_manager_thread = {
{
{
&__pthread_manager_thread /* pthread_descr self */
}
},
NULL, /* pthread_descr p_nextlive */
NULL, /* pthread_descr p_prevlive */
NULL, /* pthread_descr p_nextwaiting */
NULL, /* pthread_descr p_nextlock */
0, /* int p_tid */
0, /* int p_pid */
0, /* int p_priority */
&__pthread_handles[1].h_lock, /* struct _pthread_fastlock * p_lock */
0, /* int p_signal */
NULL, /* sigjmp_buf * p_signal_buf */
NULL, /* sigjmp_buf * p_cancel_buf */
0, /* char p_terminated */
0, /* char p_detached */
0, /* char p_exited */
NULL, /* void * p_retval */
0, /* int p_retval */
NULL, /* pthread_descr p_joining */
NULL, /* struct _pthread_cleanup_buffer * p_cleanup */
0, /* char p_cancelstate */
0, /* char p_canceltype */
0, /* char p_canceled */
&__pthread_manager_thread.p_errno, /* int *p_errnop */
0, /* int p_errno */
NULL, /* int *p_h_errnop */
0, /* int p_h_errno */
NULL, /* char * p_in_sighandler */
0, /* char p_sigwaiting */
PTHREAD_START_ARGS_INITIALIZER(__pthread_manager),
/* struct pthread_start_args p_start_args */
{NULL}, /* void ** p_specific[PTHREAD_KEY_1STLEVEL_SIZE] */
{NULL}, /* void * p_libc_specific[_LIBC_TSD_KEY_N] */
0, /* int p_userstack */
NULL, /* void * p_guardaddr */
0, /* size_t p_guardsize */
1, /* Always index 1 */
0, /* int p_report_events */
{{{0, }}, 0, NULL}, /* td_eventbuf_t p_eventbuf */
ATOMIC_INITIALIZER, /* struct pthread_atomic p_resume_count */
0, /* char p_woken_by_cancel */
NULL, /* struct pthread_extricate_if *p_extricate */
NULL, /* pthread_readlock_info *p_readlock_list; */
NULL, /* pthread_readlock_info *p_readlock_free; */
0 /* int p_untracked_readlock_count; */
};
/* Pointer to the main thread (the father of the thread manager thread) */
/* Originally, this is the initial thread, but this changes after fork() */
pthread_descr __pthread_main_thread = &__pthread_initial_thread;
/* Limit between the stack of the initial thread (above) and the
stacks of other threads (below). Aligned on a STACK_SIZE boundary. */
char *__pthread_initial_thread_bos = NULL;
/* File descriptor for sending requests to the thread manager. */
/* Initially -1, meaning that the thread manager is not running. */
int __pthread_manager_request = -1;
/* Other end of the pipe for sending requests to the thread manager. */
int __pthread_manager_reader;
/* Limits of the thread manager stack */
char *__pthread_manager_thread_bos = NULL;
char *__pthread_manager_thread_tos = NULL;
/* For process-wide exit() */
int __pthread_exit_requested = 0;
int __pthread_exit_code = 0;
#if !__ASSUME_REALTIME_SIGNALS
/* Pointers that select new or old suspend/resume functions
based on availability of rt signals. */
void (*__pthread_restart)(pthread_descr) = __pthread_restart_old;
void (*__pthread_suspend)(pthread_descr) = __pthread_suspend_old;
int (*__pthread_timedsuspend)(pthread_descr, const struct timespec *) = __pthread_timedsuspend_old;
#endif /* __ASSUME_REALTIME_SIGNALS */
/* Communicate relevant LinuxThreads constants to gdb */
const int __pthread_threads_max = PTHREAD_THREADS_MAX;
const int __pthread_sizeof_handle = sizeof(struct pthread_handle_struct);
const int __pthread_offsetof_descr = offsetof(struct pthread_handle_struct,
h_descr);
const int __pthread_offsetof_pid = offsetof(struct _pthread_descr_struct,
p_pid);
const int __linuxthread_pthread_sizeof_descr
= sizeof(struct _pthread_descr_struct);
/* These variables are used by the setup code. */
extern int _errno;
extern int _h_errno;
/* Forward declarations */
static void pthread_exit_process(int retcode, void *arg);
static void pthread_handle_sigcancel(int sig);
static void pthread_handle_sigrestart(int sig);
static void pthread_handle_sigdebug(int sig);
/* Signal numbers used for the communication.
In these variables we keep track of the used variables. If the
platform does not support any real-time signals we will define the
values to some unreasonable value which will signal failing of all
the functions below. */
#ifndef __SIGRTMIN
static int current_rtmin = -1;
static int current_rtmax = -1;
int __pthread_sig_restart = SIGUSR1;
int __pthread_sig_cancel = SIGUSR2;
int __pthread_sig_debug = 0;
#else
static int current_rtmin;
static int current_rtmax;
#if __SIGRTMAX - __SIGRTMIN >= 3
int __pthread_sig_restart = __SIGRTMIN;
int __pthread_sig_cancel = __SIGRTMIN + 1;
int __pthread_sig_debug = __SIGRTMIN + 2;
#else
int __pthread_sig_restart = SIGUSR1;
int __pthread_sig_cancel = SIGUSR2;
int __pthread_sig_debug = 0;
#endif
static int rtsigs_initialized;
#include "testrtsig.h"
static void
init_rtsigs (void)
{
#if !__ASSUME_REALTIME_SIGNALS
if (!kernel_has_rtsig ())
{
current_rtmin = -1;
current_rtmax = -1;
# if __SIGRTMAX - __SIGRTMIN >= 3
__pthread_sig_restart = SIGUSR1;
__pthread_sig_cancel = SIGUSR2;
__pthread_sig_debug = 0;
# endif
}
else
#endif /* __ASSUME_REALTIME_SIGNALS */
{
#if __SIGRTMAX - __SIGRTMIN >= 3
current_rtmin = __SIGRTMIN + 3;
# if !__ASSUME_REALTIME_SIGNALS
__pthread_restart = __pthread_restart_new;
__pthread_suspend = __pthread_wait_for_restart_signal;
__pthread_timedsuspend = __pthread_timedsuspend_new;
# endif /* __ASSUME_REALTIME_SIGNALS */
#else
current_rtmin = __SIGRTMIN;
#endif
current_rtmax = __SIGRTMAX;
}
rtsigs_initialized = 1;
}
#endif
/* Return number of available real-time signal with highest priority. */
int
__libc_current_sigrtmin (void)
{
#ifdef __SIGRTMIN
if (!rtsigs_initialized)
init_rtsigs ();
#endif
return current_rtmin;
}
/* Return number of available real-time signal with lowest priority. */
int
__libc_current_sigrtmax (void)
{
#ifdef __SIGRTMIN
if (!rtsigs_initialized)
init_rtsigs ();
#endif
return current_rtmax;
}
/* Allocate real-time signal with highest/lowest available
priority. Please note that we don't use a lock since we assume
this function to be called at program start. */
int
__libc_allocate_rtsig (int high)
{
#ifndef __SIGRTMIN
return -1;
#else
if (!rtsigs_initialized)
init_rtsigs ();
if (current_rtmin == -1 || current_rtmin > current_rtmax)
/* We don't have anymore signal available. */
return -1;
return high ? current_rtmin++ : current_rtmax--;
#endif
}
/* Initialize the pthread library.
Initialization is split in two functions:
- a constructor function that blocks the __pthread_sig_restart signal
(must do this very early, since the program could capture the signal
mask with e.g. sigsetjmp before creating the first thread);
- a regular function called from pthread_create when needed. */
static void pthread_initialize(void) __attribute__((constructor));
extern void *__dso_handle __attribute__ ((weak));
/* Do some minimal initialization which has to be done during the
startup of the C library. */
void
__pthread_initialize_minimal(void)
{
/* The errno/h_errno variable of the main thread are the global ones. */
__pthread_initial_thread.p_errnop = &_errno;
__pthread_initial_thread.p_h_errnop = &_h_errno;
/* If we have special thread_self processing, initialize that for the
main thread now. */
#ifdef INIT_THREAD_SELF
INIT_THREAD_SELF(&__pthread_initial_thread, 0);
#endif
}
static void pthread_initialize(void)
{
struct sigaction sa;
sigset_t mask;
struct rlimit limit;
int max_stack;
/* If already done (e.g. by a constructor called earlier!), bail out */
if (__pthread_initial_thread_bos != NULL) return;
#ifdef TEST_FOR_COMPARE_AND_SWAP
/* Test if compare-and-swap is available */
__pthread_has_cas = compare_and_swap_is_available();
#endif
/* For the initial stack, reserve at least STACK_SIZE bytes of stack
below the current stack address, and align that on a
STACK_SIZE boundary. */
__pthread_initial_thread_bos =
(char *)(((long)CURRENT_STACK_FRAME - 2 * STACK_SIZE) & ~(STACK_SIZE - 1));
/* Update the descriptor for the initial thread. */
__pthread_initial_thread.p_pid = __getpid();
/* Play with the stack size limit to make sure that no stack ever grows
beyond STACK_SIZE minus one page (to act as a guard page). */
getrlimit(RLIMIT_STACK, &limit);
max_stack = STACK_SIZE - __getpagesize();
if (limit.rlim_cur > max_stack) {
limit.rlim_cur = max_stack;
setrlimit(RLIMIT_STACK, &limit);
}
/* Likewise for the resolver state _res. */
__pthread_initial_thread.p_resp = &_res;
#ifdef __SIGRTMIN
/* Initialize real-time signals. */
init_rtsigs ();
#endif
/* Setup signal handlers for the initial thread.
Since signal handlers are shared between threads, these settings
will be inherited by all other threads. */
sa.sa_handler = pthread_handle_sigrestart;
sigemptyset(&sa.sa_mask);
sa.sa_flags = 0;
__sigaction(__pthread_sig_restart, &sa, NULL);
sa.sa_handler = pthread_handle_sigcancel;
// sa.sa_flags = 0;
__sigaction(__pthread_sig_cancel, &sa, NULL);
if (__pthread_sig_debug > 0) {
sa.sa_handler = pthread_handle_sigdebug;
sigemptyset(&sa.sa_mask);
// sa.sa_flags = 0;
__sigaction(__pthread_sig_debug, &sa, NULL);
}
/* Initially, block __pthread_sig_restart. Will be unblocked on demand. */
sigemptyset(&mask);
sigaddset(&mask, __pthread_sig_restart);
sigprocmask(SIG_BLOCK, &mask, NULL);
/* Register an exit function to kill all other threads. */
/* Do it early so that user-registered atexit functions are called
before pthread_exit_process. */
if (&__dso_handle != NULL)
/* The cast is a bit unclean. The function expects two arguments but
we can only pass one. Fortunately this is not a problem since the
second argument of `pthread_exit_process' is simply ignored. */
__cxa_atexit((void (*) (void *)) pthread_exit_process, NULL, __dso_handle);
else
__on_exit (pthread_exit_process, NULL);
}
void __pthread_initialize(void)
{
pthread_initialize();
}
int __pthread_initialize_manager(void)
{
int manager_pipe[2];
int pid;
struct pthread_request request;
/* If basic initialization not done yet (e.g. we're called from a
constructor run before our constructor), do it now */
if (__pthread_initial_thread_bos == NULL) pthread_initialize();
/* Setup stack for thread manager */
__pthread_manager_thread_bos = malloc(THREAD_MANAGER_STACK_SIZE);
if (__pthread_manager_thread_bos == NULL) return -1;
__pthread_manager_thread_tos =
__pthread_manager_thread_bos + THREAD_MANAGER_STACK_SIZE;
/* Setup pipe to communicate with thread manager */
if (pipe(manager_pipe) == -1) {
free(__pthread_manager_thread_bos);
return -1;
}
/* Start the thread manager */
pid = 0;
if (__pthread_initial_thread.p_report_events)
{
/* It's a bit more complicated. We have to report the creation of
the manager thread. */
int idx = __td_eventword (TD_CREATE);
uint32_t mask = __td_eventmask (TD_CREATE);
if ((mask & (__pthread_threads_events.event_bits[idx]
| __pthread_initial_thread.p_eventbuf.eventmask.event_bits[idx]))
!= 0)
{
pid = __clone(__pthread_manager_event,
(void **) __pthread_manager_thread_tos,
CLONE_VM | CLONE_FS | CLONE_FILES | CLONE_SIGHAND,
(void *)(long)manager_pipe[0]);
if (pid != -1)
{
/* Now fill in the information about the new thread in
the newly created thread's data structure. We cannot let
the new thread do this since we don't know whether it was
already scheduled when we send the event. */
__pthread_manager_thread.p_eventbuf.eventdata =
&__pthread_manager_thread;
__pthread_manager_thread.p_eventbuf.eventnum = TD_CREATE;
__pthread_last_event = &__pthread_manager_thread;
__pthread_manager_thread.p_tid = 2* PTHREAD_THREADS_MAX + 1;
__pthread_manager_thread.p_pid = pid;
/* Now call the function which signals the event. */
__linuxthreads_create_event ();
/* Now restart the thread. */
__pthread_unlock(__pthread_manager_thread.p_lock);
}
}
}
if (pid == 0)
pid = __clone(__pthread_manager, (void **) __pthread_manager_thread_tos,
CLONE_VM | CLONE_FS | CLONE_FILES | CLONE_SIGHAND,
(void *)(long)manager_pipe[0]);
if (pid == -1) {
free(__pthread_manager_thread_bos);
__libc_close(manager_pipe[0]);
__libc_close(manager_pipe[1]);
return -1;
}
__pthread_manager_request = manager_pipe[1]; /* writing end */
__pthread_manager_reader = manager_pipe[0]; /* reading end */
__pthread_manager_thread.p_tid = 2* PTHREAD_THREADS_MAX + 1;
__pthread_manager_thread.p_pid = pid;
/* Make gdb aware of new thread manager */
if (__pthread_threads_debug && __pthread_sig_debug > 0)
{
raise(__pthread_sig_debug);
/* We suspend ourself and gdb will wake us up when it is
ready to handle us. */
__pthread_wait_for_restart_signal(thread_self());
}
/* Synchronize debugging of the thread manager */
request.req_kind = REQ_DEBUG;
__libc_write(__pthread_manager_request, (char *) &request, sizeof(request));
return 0;
}
/* Thread creation */
int __pthread_create_2_1(pthread_t *thread, const pthread_attr_t *attr,
void * (*start_routine)(void *), void *arg)
{
pthread_descr self = thread_self();
struct pthread_request request;
int retval;
if (__pthread_manager_request < 0) {
if (__pthread_initialize_manager() < 0) return EAGAIN;
}
request.req_thread = self;
request.req_kind = REQ_CREATE;
request.req_args.create.attr = attr;
request.req_args.create.fn = start_routine;
request.req_args.create.arg = arg;
sigprocmask(SIG_SETMASK, (const sigset_t *) NULL,
&request.req_args.create.mask);
__libc_write(__pthread_manager_request, (char *) &request, sizeof(request));
suspend(self);
retval = THREAD_GETMEM(self, p_retcode);
if (retval == 0)
*thread = (pthread_t) THREAD_GETMEM(self, p_retval);
return retval;
}
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(pthread_t *thread, 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. */
pthread_attr_t new_attr;
if (attr != NULL)
{
size_t ps = __getpagesize ();
memcpy (&new_attr, attr,
(size_t) &(((pthread_attr_t*)NULL)->__guardsize));
new_attr.__guardsize = ps;
new_attr.__stackaddr_set = 0;
new_attr.__stackaddr = NULL;
new_attr.__stacksize = STACK_SIZE - ps;
attr = &new_attr;
}
return __pthread_create_2_1 (thread, attr, start_routine, arg);
}
compat_symbol (libpthread, __pthread_create_2_0, pthread_create, GLIBC_2_0);
#endif
/* Simple operations on thread identifiers */
pthread_t pthread_self(void)
{
pthread_descr self = thread_self();
return THREAD_GETMEM(self, p_tid);
}
int pthread_equal(pthread_t thread1, pthread_t thread2)
{
return thread1 == thread2;
}
/* Helper function for thread_self in the case of user-provided stacks */
#ifndef THREAD_SELF
pthread_descr __pthread_find_self()
{
char * sp = CURRENT_STACK_FRAME;
pthread_handle h;
/* __pthread_handles[0] is the initial thread, __pthread_handles[1] is
the manager threads handled specially in thread_self(), so start at 2 */
h = __pthread_handles + 2;
while (! (sp <= (char *) h->h_descr && sp >= h->h_bottom)) h++;
return h->h_descr;
}
#endif
/* Thread scheduling */
int pthread_setschedparam(pthread_t thread, int policy,
const struct sched_param *param)
{
pthread_handle handle = thread_handle(thread);
pthread_descr th;
__pthread_lock(&handle->h_lock, NULL);
if (invalid_handle(handle, thread)) {
__pthread_unlock(&handle->h_lock);
return ESRCH;
}
th = handle->h_descr;
if (__sched_setscheduler(th->p_pid, policy, param) == -1) {
__pthread_unlock(&handle->h_lock);
return errno;
}
th->p_priority = policy == SCHED_OTHER ? 0 : param->sched_priority;
__pthread_unlock(&handle->h_lock);
if (__pthread_manager_request >= 0)
__pthread_manager_adjust_prio(th->p_priority);
return 0;
}
int pthread_getschedparam(pthread_t thread, int *policy,
struct sched_param *param)
{
pthread_handle handle = thread_handle(thread);
int pid, pol;
__pthread_lock(&handle->h_lock, NULL);
if (invalid_handle(handle, thread)) {
__pthread_unlock(&handle->h_lock);
return ESRCH;
}
pid = handle->h_descr->p_pid;
__pthread_unlock(&handle->h_lock);
pol = __sched_getscheduler(pid);
if (pol == -1) return errno;
if (__sched_getparam(pid, param) == -1) return errno;
*policy = pol;
return 0;
}
int __pthread_yield ()
{
/* For now this is equivalent with the POSIX call. */
return sched_yield ();
}
weak_alias (__pthread_yield, pthread_yield)
/* Process-wide exit() request */
static void pthread_exit_process(int retcode, void *arg)
{
struct pthread_request request;
pthread_descr self = thread_self();
if (__pthread_manager_request >= 0) {
request.req_thread = self;
request.req_kind = REQ_PROCESS_EXIT;
request.req_args.exit.code = retcode;
__libc_write(__pthread_manager_request,
(char *) &request, sizeof(request));
suspend(self);
/* Main thread should accumulate times for thread manager and its
children, so that timings for main thread account for all threads. */
if (self == __pthread_main_thread)
waitpid(__pthread_manager_thread.p_pid, NULL, __WCLONE);
}
}
/* The handler for the RESTART signal just records the signal received
in the thread descriptor, and optionally performs a siglongjmp
(for pthread_cond_timedwait). */
static void pthread_handle_sigrestart(int sig)
{
pthread_descr self = thread_self();
THREAD_SETMEM(self, p_signal, sig);
if (THREAD_GETMEM(self, p_signal_jmp) != NULL)
siglongjmp(*THREAD_GETMEM(self, p_signal_jmp), 1);
}
/* The handler for the CANCEL signal checks for cancellation
(in asynchronous mode), for process-wide exit and exec requests.
For the thread manager thread, redirect the signal to
__pthread_manager_sighandler. */
static void pthread_handle_sigcancel(int sig)
{
pthread_descr self = thread_self();
sigjmp_buf * jmpbuf;
if (self == &__pthread_manager_thread)
{
__pthread_manager_sighandler(sig);
return;
}
if (__pthread_exit_requested) {
/* Main thread should accumulate times for thread manager and its
children, so that timings for main thread account for all threads. */
if (self == __pthread_main_thread)
waitpid(__pthread_manager_thread.p_pid, NULL, __WCLONE);
_exit(__pthread_exit_code);
}
if (THREAD_GETMEM(self, p_canceled)
&& THREAD_GETMEM(self, p_cancelstate) == PTHREAD_CANCEL_ENABLE) {
if (THREAD_GETMEM(self, p_canceltype) == PTHREAD_CANCEL_ASYNCHRONOUS)
pthread_exit(PTHREAD_CANCELED);
jmpbuf = THREAD_GETMEM(self, p_cancel_jmp);
if (jmpbuf != NULL) {
THREAD_SETMEM(self, p_cancel_jmp, NULL);
siglongjmp(*jmpbuf, 1);
}
}
}
/* Handler for the DEBUG signal.
The debugging strategy is as follows:
On reception of a REQ_DEBUG request (sent by new threads created to
the thread manager under debugging mode), the thread manager throws
__pthread_sig_debug to itself. The debugger (if active) intercepts
this signal, takes into account new threads and continue execution
of the thread manager by propagating the signal because it doesn't
know what it is specifically done for. In the current implementation,
the thread manager simply discards it. */
static void pthread_handle_sigdebug(int sig)
{
/* Nothing */
}
/* Reset the state of the thread machinery after a fork().
Close the pipe used for requests and set the main thread to the forked
thread.
Notice that we can't free the stack segments, as the forked thread
may hold pointers into them. */
void __pthread_reset_main_thread()
{
pthread_descr self = thread_self();
if (__pthread_manager_request != -1) {
/* Free the thread manager stack */
free(__pthread_manager_thread_bos);
__pthread_manager_thread_bos = __pthread_manager_thread_tos = NULL;
/* Close the two ends of the pipe */
__libc_close(__pthread_manager_request);
__libc_close(__pthread_manager_reader);
__pthread_manager_request = __pthread_manager_reader = -1;
}
/* Update the pid of the main thread */
THREAD_SETMEM(self, p_pid, __getpid());
/* Make the forked thread the main thread */
__pthread_main_thread = self;
THREAD_SETMEM(self, p_nextlive, self);
THREAD_SETMEM(self, p_prevlive, self);
/* Now this thread modifies the global variables. */
THREAD_SETMEM(self, p_errnop, &_errno);
THREAD_SETMEM(self, p_h_errnop, &_h_errno);
THREAD_SETMEM(self, p_resp, &_res);
}
/* Process-wide exec() request */
void __pthread_kill_other_threads_np(void)
{
struct sigaction sa;
/* Terminate all other threads and thread manager */
pthread_exit_process(0, NULL);
/* Make current thread the main thread in case the calling thread
changes its mind, does not exec(), and creates new threads instead. */
__pthread_reset_main_thread();
/* Reset the signal handlers behaviour for the signals the
implementation uses since this would be passed to the new
process. */
sigemptyset(&sa.sa_mask);
sa.sa_flags = 0;
sa.sa_handler = SIG_DFL;
__sigaction(__pthread_sig_restart, &sa, NULL);
__sigaction(__pthread_sig_cancel, &sa, NULL);
if (__pthread_sig_debug > 0)
__sigaction(__pthread_sig_debug, &sa, NULL);
}
weak_alias (__pthread_kill_other_threads_np, pthread_kill_other_threads_np)
/* Concurrency symbol level. */
static int current_level;
int __pthread_setconcurrency(int level)
{
/* We don't do anything unless we have found a useful interpretation. */
current_level = level;
return 0;
}
weak_alias (__pthread_setconcurrency, pthread_setconcurrency)
int __pthread_getconcurrency(void)
{
return current_level;
}
weak_alias (__pthread_getconcurrency, pthread_getconcurrency)
void __pthread_set_own_extricate_if(pthread_descr self, pthread_extricate_if *peif)
{
__pthread_lock(self->p_lock, self);
THREAD_SETMEM(self, p_extricate, peif);
__pthread_unlock(self->p_lock);
}
/* Primitives for controlling thread execution */
void __pthread_wait_for_restart_signal(pthread_descr self)
{
sigset_t mask;
sigprocmask(SIG_SETMASK, NULL, &mask); /* Get current signal mask */
sigdelset(&mask, __pthread_sig_restart); /* Unblock the restart signal */
do {
self->p_signal = 0;
sigsuspend(&mask); /* Wait for signal */
} while (self->p_signal !=__pthread_sig_restart );
}
#if !__ASSUME_REALTIME_SIGNALS
/* The _old variants are for 2.0 and early 2.1 kernels which don't have RT
signals.
On these kernels, we use SIGUSR1 and SIGUSR2 for restart and cancellation.
Since the restart signal does not queue, we use an atomic counter to create
queuing semantics. This is needed to resolve a rare race condition in
pthread_cond_timedwait_relative. */
void __pthread_restart_old(pthread_descr th)
{
if (atomic_increment(&th->p_resume_count) == -1)
kill(th->p_pid, __pthread_sig_restart);
}
void __pthread_suspend_old(pthread_descr self)
{
if (atomic_decrement(&self->p_resume_count) <= 0)
__pthread_wait_for_restart_signal(self);
}
int
__pthread_timedsuspend_old(pthread_descr self, const struct timespec *abstime)
{
sigset_t unblock, initial_mask;
int was_signalled = 0;
sigjmp_buf jmpbuf;
if (atomic_decrement(&self->p_resume_count) == 0) {
/* Set up a longjmp handler for the restart signal, unblock
the signal and sleep. */
if (sigsetjmp(jmpbuf, 1) == 0) {
THREAD_SETMEM(self, p_signal_jmp, &jmpbuf);
THREAD_SETMEM(self, p_signal, 0);
/* Unblock the restart signal */
sigemptyset(&unblock);
sigaddset(&unblock, __pthread_sig_restart);
sigprocmask(SIG_UNBLOCK, &unblock, &initial_mask);
while (1) {
struct timeval now;
struct timespec reltime;
/* Compute a time offset relative to now. */
__gettimeofday (&now, NULL);
reltime.tv_nsec = abstime->tv_nsec - now.tv_usec * 1000;
reltime.tv_sec = abstime->tv_sec - now.tv_sec;
if (reltime.tv_nsec < 0) {
reltime.tv_nsec += 1000000000;
reltime.tv_sec -= 1;
}
/* Sleep for the required duration. If woken by a signal,
resume waiting as required by Single Unix Specification. */
if (reltime.tv_sec < 0 || __libc_nanosleep(&reltime, NULL) == 0)
break;
}
/* Block the restart signal again */
sigprocmask(SIG_SETMASK, &initial_mask, NULL);
was_signalled = 0;
} else {
was_signalled = 1;
}
THREAD_SETMEM(self, p_signal_jmp, NULL);
}
/* Now was_signalled is true if we exited the above code
due to the delivery of a restart signal. In that case,
we know we have been dequeued and resumed and that the
resume count is balanced. Otherwise, there are some
cases to consider. First, try to bump up the resume count
back to zero. If it goes to 1, it means restart() was
invoked on this thread. The signal must be consumed
and the count bumped down and everything is cool. We
can return a 1 to the caller.
Otherwise, no restart was delivered yet, so a potential
race exists; we return a 0 to the caller which must deal
with this race in an appropriate way; for example by
atomically removing the thread from consideration for a
wakeup---if such a thing fails, it means a restart is
being delivered. */
if (!was_signalled) {
if (atomic_increment(&self->p_resume_count) != -1) {
__pthread_wait_for_restart_signal(self);
atomic_decrement(&self->p_resume_count); /* should be zero now! */
/* woke spontaneously and consumed restart signal */
return 1;
}
/* woke spontaneously but did not consume restart---caller must resolve */
return 0;
}
/* woken due to restart signal */
return 1;
}
#endif /* __ASSUME_REALTIME_SIGNALS */
void __pthread_restart_new(pthread_descr th)
{
kill(th->p_pid, __pthread_sig_restart);
}
/* There is no __pthread_suspend_new because it would just
be a wasteful wrapper for __pthread_wait_for_restart_signal */
int
__pthread_timedsuspend_new(pthread_descr self, const struct timespec *abstime)
{
sigset_t unblock, initial_mask;
int was_signalled = 0;
sigjmp_buf jmpbuf;
if (sigsetjmp(jmpbuf, 1) == 0) {
THREAD_SETMEM(self, p_signal_jmp, &jmpbuf);
THREAD_SETMEM(self, p_signal, 0);
/* Unblock the restart signal */
sigemptyset(&unblock);
sigaddset(&unblock, __pthread_sig_restart);
sigprocmask(SIG_UNBLOCK, &unblock, &initial_mask);
while (1) {
struct timeval now;
struct timespec reltime;
/* Compute a time offset relative to now. */
__gettimeofday (&now, NULL);
reltime.tv_nsec = abstime->tv_nsec - now.tv_usec * 1000;
reltime.tv_sec = abstime->tv_sec - now.tv_sec;
if (reltime.tv_nsec < 0) {
reltime.tv_nsec += 1000000000;
reltime.tv_sec -= 1;
}
/* Sleep for the required duration. If woken by a signal,
resume waiting as required by Single Unix Specification. */
if (reltime.tv_sec < 0 || __libc_nanosleep(&reltime, NULL) == 0)
break;
}
/* Block the restart signal again */
sigprocmask(SIG_SETMASK, &initial_mask, NULL);
was_signalled = 0;
} else {
was_signalled = 1;
}
THREAD_SETMEM(self, p_signal_jmp, NULL);
/* Now was_signalled is true if we exited the above code
due to the delivery of a restart signal. In that case,
everything is cool. We have been removed from whatever
we were waiting on by the other thread, and consumed its signal.
Otherwise we this thread woke up spontaneously, or due to a signal other
than restart. This is an ambiguous case that must be resolved by
the caller; the thread is still eligible for a restart wakeup
so there is a race. */
return was_signalled;
}
/* Debugging aid */
#ifdef DEBUG
#include <stdarg.h>
void __pthread_message(char * fmt, ...)
{
char buffer[1024];
va_list args;
sprintf(buffer, "%05d : ", __getpid());
va_start(args, fmt);
vsnprintf(buffer + 8, sizeof(buffer) - 8, fmt, args);
va_end(args);
__libc_write(2, buffer, strlen(buffer));
}
#endif
#ifndef SHARED
/* We need a hook to force the cancelation wrappers to be linked in when
static libpthread is used. */
extern const int __pthread_provide_wrappers;
static const int *const __pthread_require_wrappers =
&__pthread_provide_wrappers;
#endif