/* Copyright (C) 2002-2014 Free Software Foundation, Inc. This file is part of the GNU C Library. Contributed by Ulrich Drepper , 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, see . */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef TLS_MULTIPLE_THREADS_IN_TCB /* Pointer to the corresponding variable in libc. */ int *__libc_multiple_threads_ptr attribute_hidden; #endif /* Size and alignment of static TLS block. */ size_t __static_tls_size; size_t __static_tls_align_m1; #ifndef __ASSUME_SET_ROBUST_LIST /* Negative if we do not have the system call and we can use it. */ int __set_robust_list_avail; # define set_robust_list_not_avail() \ __set_robust_list_avail = -1 #else # define set_robust_list_not_avail() do { } while (0) #endif #ifndef __ASSUME_FUTEX_CLOCK_REALTIME /* Nonzero if we do not have FUTEX_CLOCK_REALTIME. */ int __have_futex_clock_realtime; # define __set_futex_clock_realtime() \ __have_futex_clock_realtime = 1 #else #define __set_futex_clock_realtime() do { } while (0) #endif /* Version of the library, used in libthread_db to detect mismatches. */ static const char nptl_version[] __attribute_used__ = VERSION; #ifndef SHARED extern void __libc_setup_tls (size_t tcbsize, size_t tcbalign); #endif #ifdef SHARED static #else extern #endif void __nptl_set_robust (struct pthread *); #ifdef SHARED static void nptl_freeres (void); static const struct pthread_functions pthread_functions = { .ptr_pthread_attr_destroy = __pthread_attr_destroy, # if SHLIB_COMPAT(libpthread, GLIBC_2_0, GLIBC_2_1) .ptr___pthread_attr_init_2_0 = __pthread_attr_init_2_0, # endif .ptr___pthread_attr_init_2_1 = __pthread_attr_init_2_1, .ptr_pthread_attr_getdetachstate = __pthread_attr_getdetachstate, .ptr_pthread_attr_setdetachstate = __pthread_attr_setdetachstate, .ptr_pthread_attr_getinheritsched = __pthread_attr_getinheritsched, .ptr_pthread_attr_setinheritsched = __pthread_attr_setinheritsched, .ptr_pthread_attr_getschedparam = __pthread_attr_getschedparam, .ptr_pthread_attr_setschedparam = __pthread_attr_setschedparam, .ptr_pthread_attr_getschedpolicy = __pthread_attr_getschedpolicy, .ptr_pthread_attr_setschedpolicy = __pthread_attr_setschedpolicy, .ptr_pthread_attr_getscope = __pthread_attr_getscope, .ptr_pthread_attr_setscope = __pthread_attr_setscope, .ptr_pthread_condattr_destroy = __pthread_condattr_destroy, .ptr_pthread_condattr_init = __pthread_condattr_init, .ptr___pthread_cond_broadcast = __pthread_cond_broadcast, .ptr___pthread_cond_destroy = __pthread_cond_destroy, .ptr___pthread_cond_init = __pthread_cond_init, .ptr___pthread_cond_signal = __pthread_cond_signal, .ptr___pthread_cond_wait = __pthread_cond_wait, .ptr___pthread_cond_timedwait = __pthread_cond_timedwait, # if SHLIB_COMPAT(libpthread, GLIBC_2_0, GLIBC_2_3_2) .ptr___pthread_cond_broadcast_2_0 = __pthread_cond_broadcast_2_0, .ptr___pthread_cond_destroy_2_0 = __pthread_cond_destroy_2_0, .ptr___pthread_cond_init_2_0 = __pthread_cond_init_2_0, .ptr___pthread_cond_signal_2_0 = __pthread_cond_signal_2_0, .ptr___pthread_cond_wait_2_0 = __pthread_cond_wait_2_0, .ptr___pthread_cond_timedwait_2_0 = __pthread_cond_timedwait_2_0, # endif .ptr_pthread_equal = __pthread_equal, .ptr___pthread_exit = __pthread_exit, .ptr_pthread_getschedparam = __pthread_getschedparam, .ptr_pthread_setschedparam = __pthread_setschedparam, .ptr_pthread_mutex_destroy = __pthread_mutex_destroy, .ptr_pthread_mutex_init = __pthread_mutex_init, .ptr_pthread_mutex_lock = __pthread_mutex_lock, .ptr_pthread_mutex_unlock = __pthread_mutex_unlock, .ptr_pthread_self = __pthread_self, .ptr_pthread_setcancelstate = __pthread_setcancelstate, .ptr_pthread_setcanceltype = __pthread_setcanceltype, .ptr___pthread_cleanup_upto = __pthread_cleanup_upto, .ptr___pthread_once = __pthread_once, .ptr___pthread_rwlock_rdlock = __pthread_rwlock_rdlock, .ptr___pthread_rwlock_wrlock = __pthread_rwlock_wrlock, .ptr___pthread_rwlock_unlock = __pthread_rwlock_unlock, .ptr___pthread_key_create = __pthread_key_create, .ptr___pthread_getspecific = __pthread_getspecific, .ptr___pthread_setspecific = __pthread_setspecific, .ptr__pthread_cleanup_push_defer = __pthread_cleanup_push_defer, .ptr__pthread_cleanup_pop_restore = __pthread_cleanup_pop_restore, .ptr_nthreads = &__nptl_nthreads, .ptr___pthread_unwind = &__pthread_unwind, .ptr__nptl_deallocate_tsd = __nptl_deallocate_tsd, .ptr__nptl_setxid = __nptl_setxid, /* For now only the stack cache needs to be freed. */ .ptr_freeres = nptl_freeres, .ptr_set_robust = __nptl_set_robust }; # define ptr_pthread_functions &pthread_functions #else # define ptr_pthread_functions NULL #endif #ifdef SHARED /* This function is called indirectly from the freeres code in libc. */ static void __libc_freeres_fn_section nptl_freeres (void) { __unwind_freeres (); __free_stacks (0); } static #endif void __nptl_set_robust (struct pthread *self) { #ifdef __NR_set_robust_list INTERNAL_SYSCALL_DECL (err); INTERNAL_SYSCALL (set_robust_list, err, 2, &self->robust_head, sizeof (struct robust_list_head)); #endif } #ifdef SIGCANCEL /* For asynchronous cancellation we use a signal. This is the handler. */ static void sigcancel_handler (int sig, siginfo_t *si, void *ctx) { /* Determine the process ID. It might be negative if the thread is in the middle of a fork() call. */ pid_t pid = THREAD_GETMEM (THREAD_SELF, pid); if (__glibc_unlikely (pid < 0)) pid = -pid; /* Safety check. It would be possible to call this function for other signals and send a signal from another process. This is not correct and might even be a security problem. Try to catch as many incorrect invocations as possible. */ if (sig != SIGCANCEL || si->si_pid != pid || si->si_code != SI_TKILL) return; struct pthread *self = THREAD_SELF; int oldval = THREAD_GETMEM (self, cancelhandling); while (1) { /* We are canceled now. When canceled by another thread this flag is already set but if the signal is directly send (internally or from another process) is has to be done here. */ int newval = oldval | CANCELING_BITMASK | CANCELED_BITMASK; if (oldval == newval || (oldval & EXITING_BITMASK) != 0) /* Already canceled or exiting. */ break; int curval = THREAD_ATOMIC_CMPXCHG_VAL (self, cancelhandling, newval, oldval); if (curval == oldval) { /* Set the return value. */ THREAD_SETMEM (self, result, PTHREAD_CANCELED); /* Make sure asynchronous cancellation is still enabled. */ if ((newval & CANCELTYPE_BITMASK) != 0) /* Run the registered destructors and terminate the thread. */ __do_cancel (); break; } oldval = curval; } } #endif #ifdef SIGSETXID struct xid_command *__xidcmd attribute_hidden; /* We use the SIGSETXID signal in the setuid, setgid, etc. implementations to tell each thread to call the respective setxid syscall on itself. This is the handler. */ static void sighandler_setxid (int sig, siginfo_t *si, void *ctx) { /* Determine the process ID. It might be negative if the thread is in the middle of a fork() call. */ pid_t pid = THREAD_GETMEM (THREAD_SELF, pid); int result; if (__glibc_unlikely (pid < 0)) pid = -pid; /* Safety check. It would be possible to call this function for other signals and send a signal from another process. This is not correct and might even be a security problem. Try to catch as many incorrect invocations as possible. */ if (sig != SIGSETXID || si->si_pid != pid || si->si_code != SI_TKILL) return; INTERNAL_SYSCALL_DECL (err); result = INTERNAL_SYSCALL_NCS (__xidcmd->syscall_no, err, 3, __xidcmd->id[0], __xidcmd->id[1], __xidcmd->id[2]); int error = 0; if (__glibc_unlikely (INTERNAL_SYSCALL_ERROR_P (result, err))) error = INTERNAL_SYSCALL_ERRNO (result, err); __nptl_setxid_error (__xidcmd, error); /* Reset the SETXID flag. */ struct pthread *self = THREAD_SELF; int flags, newval; do { flags = THREAD_GETMEM (self, cancelhandling); newval = THREAD_ATOMIC_CMPXCHG_VAL (self, cancelhandling, flags & ~SETXID_BITMASK, flags); } while (flags != newval); /* And release the futex. */ self->setxid_futex = 1; lll_futex_wake (&self->setxid_futex, 1, LLL_PRIVATE); if (atomic_decrement_val (&__xidcmd->cntr) == 0) lll_futex_wake (&__xidcmd->cntr, 1, LLL_PRIVATE); } #endif /* When using __thread for this, we do it in libc so as not to give libpthread its own TLS segment just for this. */ extern void **__libc_dl_error_tsd (void) __attribute__ ((const)); /* This can be set by the debugger before initialization is complete. */ static bool __nptl_initial_report_events __attribute_used__; void __pthread_initialize_minimal_internal (void) { #ifndef SHARED /* Unlike in the dynamically linked case the dynamic linker has not taken care of initializing the TLS data structures. */ __libc_setup_tls (TLS_TCB_SIZE, TLS_TCB_ALIGN); /* We must prevent gcc from being clever and move any of the following code ahead of the __libc_setup_tls call. This function will initialize the thread register which is subsequently used. */ __asm __volatile (""); #endif /* Minimal initialization of the thread descriptor. */ struct pthread *pd = THREAD_SELF; #ifdef __NR_set_tid_address INTERNAL_SYSCALL_DECL (err); pd->pid = pd->tid = INTERNAL_SYSCALL (set_tid_address, err, 1, &pd->tid); #endif THREAD_SETMEM (pd, specific[0], &pd->specific_1stblock[0]); THREAD_SETMEM (pd, user_stack, true); if (LLL_LOCK_INITIALIZER != 0) THREAD_SETMEM (pd, lock, LLL_LOCK_INITIALIZER); #if HP_TIMING_AVAIL THREAD_SETMEM (pd, cpuclock_offset, GL(dl_cpuclock_offset)); #endif /* Initialize the robust mutex data. */ #ifdef __PTHREAD_MUTEX_HAVE_PREV pd->robust_prev = &pd->robust_head; #endif pd->robust_head.list = &pd->robust_head; #ifdef __NR_set_robust_list pd->robust_head.futex_offset = (offsetof (pthread_mutex_t, __data.__lock) - offsetof (pthread_mutex_t, __data.__list.__next)); int res = INTERNAL_SYSCALL (set_robust_list, err, 2, &pd->robust_head, sizeof (struct robust_list_head)); if (INTERNAL_SYSCALL_ERROR_P (res, err)) #endif set_robust_list_not_avail (); #ifdef __NR_futex # ifndef __ASSUME_PRIVATE_FUTEX /* Private futexes are always used (at least internally) so that doing the test once this early is beneficial. */ { int word = 0; word = INTERNAL_SYSCALL (futex, err, 3, &word, FUTEX_WAKE | FUTEX_PRIVATE_FLAG, 1); if (!INTERNAL_SYSCALL_ERROR_P (word, err)) THREAD_SETMEM (pd, header.private_futex, FUTEX_PRIVATE_FLAG); } /* Private futexes have been introduced earlier than the FUTEX_CLOCK_REALTIME flag. We don't have to run the test if we know the former are not supported. This also means we know the kernel will return ENOSYS for unknown operations. */ if (THREAD_GETMEM (pd, header.private_futex) != 0) # endif # ifndef __ASSUME_FUTEX_CLOCK_REALTIME { int word = 0; /* NB: the syscall actually takes six parameters. The last is the bit mask. But since we will not actually wait at all the value is irrelevant. Given that passing six parameters is difficult on some architectures we just pass whatever random value the calling convention calls for to the kernel. It causes no harm. */ word = INTERNAL_SYSCALL (futex, err, 5, &word, FUTEX_WAIT_BITSET | FUTEX_CLOCK_REALTIME | FUTEX_PRIVATE_FLAG, 1, NULL, 0); assert (INTERNAL_SYSCALL_ERROR_P (word, err)); if (INTERNAL_SYSCALL_ERRNO (word, err) != ENOSYS) __set_futex_clock_realtime (); } # endif #endif /* Set initial thread's stack block from 0 up to __libc_stack_end. It will be bigger than it actually is, but for unwind.c/pt-longjmp.c purposes this is good enough. */ THREAD_SETMEM (pd, stackblock_size, (size_t) __libc_stack_end); /* Initialize the list of all running threads with the main thread. */ INIT_LIST_HEAD (&__stack_user); list_add (&pd->list, &__stack_user); /* Before initializing __stack_user, the debugger could not find us and had to set __nptl_initial_report_events. Propagate its setting. */ THREAD_SETMEM (pd, report_events, __nptl_initial_report_events); #if defined SIGCANCEL || defined SIGSETXID struct sigaction sa; __sigemptyset (&sa.sa_mask); # ifdef SIGCANCEL /* Install the cancellation signal handler. If for some reason we cannot install the handler we do not abort. Maybe we should, but it is only asynchronous cancellation which is affected. */ sa.sa_sigaction = sigcancel_handler; sa.sa_flags = SA_SIGINFO; (void) __libc_sigaction (SIGCANCEL, &sa, NULL); # endif # ifdef SIGSETXID /* Install the handle to change the threads' uid/gid. */ sa.sa_sigaction = sighandler_setxid; sa.sa_flags = SA_SIGINFO | SA_RESTART; (void) __libc_sigaction (SIGSETXID, &sa, NULL); # endif /* The parent process might have left the signals blocked. Just in case, unblock it. We reuse the signal mask in the sigaction structure. It is already cleared. */ # ifdef SIGCANCEL __sigaddset (&sa.sa_mask, SIGCANCEL); # endif # ifdef SIGSETXID __sigaddset (&sa.sa_mask, SIGSETXID); # endif (void) INTERNAL_SYSCALL (rt_sigprocmask, err, 4, SIG_UNBLOCK, &sa.sa_mask, NULL, _NSIG / 8); #endif /* Get the size of the static and alignment requirements for the TLS block. */ size_t static_tls_align; _dl_get_tls_static_info (&__static_tls_size, &static_tls_align); /* Make sure the size takes all the alignments into account. */ if (STACK_ALIGN > static_tls_align) static_tls_align = STACK_ALIGN; __static_tls_align_m1 = static_tls_align - 1; __static_tls_size = roundup (__static_tls_size, static_tls_align); /* Determine the default allowed stack size. This is the size used in case the user does not specify one. */ struct rlimit limit; if (getrlimit (RLIMIT_STACK, &limit) != 0 || limit.rlim_cur == RLIM_INFINITY) /* The system limit is not usable. Use an architecture-specific default. */ limit.rlim_cur = ARCH_STACK_DEFAULT_SIZE; else if (limit.rlim_cur < PTHREAD_STACK_MIN) /* The system limit is unusably small. Use the minimal size acceptable. */ limit.rlim_cur = PTHREAD_STACK_MIN; /* Make sure it meets the minimum size that allocate_stack (allocatestack.c) will demand, which depends on the page size. */ const uintptr_t pagesz = GLRO(dl_pagesize); const size_t minstack = pagesz + __static_tls_size + MINIMAL_REST_STACK; if (limit.rlim_cur < minstack) limit.rlim_cur = minstack; /* Round the resource limit up to page size. */ limit.rlim_cur = ALIGN_UP (limit.rlim_cur, pagesz); lll_lock (__default_pthread_attr_lock, LLL_PRIVATE); __default_pthread_attr.stacksize = limit.rlim_cur; __default_pthread_attr.guardsize = GLRO (dl_pagesize); lll_unlock (__default_pthread_attr_lock, LLL_PRIVATE); #ifdef SHARED /* Transfer the old value from the dynamic linker's internal location. */ *__libc_dl_error_tsd () = *(*GL(dl_error_catch_tsd)) (); GL(dl_error_catch_tsd) = &__libc_dl_error_tsd; /* Make __rtld_lock_{,un}lock_recursive use pthread_mutex_{,un}lock, keep the lock count from the ld.so implementation. */ GL(dl_rtld_lock_recursive) = (void *) __pthread_mutex_lock; GL(dl_rtld_unlock_recursive) = (void *) __pthread_mutex_unlock; unsigned int rtld_lock_count = GL(dl_load_lock).mutex.__data.__count; GL(dl_load_lock).mutex.__data.__count = 0; while (rtld_lock_count-- > 0) __pthread_mutex_lock (&GL(dl_load_lock).mutex); GL(dl_make_stack_executable_hook) = &__make_stacks_executable; #endif GL(dl_init_static_tls) = &__pthread_init_static_tls; GL(dl_wait_lookup_done) = &__wait_lookup_done; /* Register the fork generation counter with the libc. */ #ifndef TLS_MULTIPLE_THREADS_IN_TCB __libc_multiple_threads_ptr = #endif __libc_pthread_init (&__fork_generation, __reclaim_stacks, ptr_pthread_functions); /* Determine whether the machine is SMP or not. */ __is_smp = is_smp_system (); } strong_alias (__pthread_initialize_minimal_internal, __pthread_initialize_minimal) size_t __pthread_get_minstack (const pthread_attr_t *attr) { struct pthread_attr *iattr = (struct pthread_attr *) attr; return (GLRO(dl_pagesize) + __static_tls_size + PTHREAD_STACK_MIN + iattr->guardsize); }