glibc/nptl/allocatestack.c
Alexandre Oliva 17af5da98c [PR19826] fix non-LE TLS in static programs
An earlier fix for TLS dropped early initialization of DTV entries for
modules using static TLS, leaving it for __tls_get_addr to set them
up.  That worked on platforms that require the GD access model to be
relaxed to LE in the main executable, but it caused a regression on
platforms that allow GD in the main executable, particularly in
statically-linked programs: they use a custom __tls_get_addr that does
not update the DTV, which fails when the DTV early initialization is
not performed.

In static programs, __libc_setup_tls performs the DTV initialization
for the main thread, but the DTV of other threads is set up in
_dl_allocate_tls_init, so that's the fix that matters.

Restoring the initialization in the remaining functions modified by
this patch was just for uniformity.  It's not clear that it is ever
needed: even on platforms that allow GD in the main executable, the
dynamically-linked version of __tls_get_addr would set up the DTV
entries, even for static TLS modules, while updating the DTV counter.

for  ChangeLog

	[BZ #19826]
	* elf/dl-tls.c (_dl_allocate_tls_init): Restore DTV early
	initialization of static TLS entries.
	* elf/dl-reloc.c (_dl_nothread_init_static_tls): Likewise.
	* nptl/allocatestack.c (init_one_static_tls): Likewise.
2016-09-21 22:01:16 -03:00

1296 lines
36 KiB
C

/* Copyright (C) 2002-2016 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, see
<http://www.gnu.org/licenses/>. */
#include <assert.h>
#include <errno.h>
#include <signal.h>
#include <stdint.h>
#include <string.h>
#include <unistd.h>
#include <sys/mman.h>
#include <sys/param.h>
#include <dl-sysdep.h>
#include <dl-tls.h>
#include <tls.h>
#include <list.h>
#include <lowlevellock.h>
#include <futex-internal.h>
#include <kernel-features.h>
#include <stack-aliasing.h>
#ifndef NEED_SEPARATE_REGISTER_STACK
/* Most architectures have exactly one stack pointer. Some have more. */
# define STACK_VARIABLES void *stackaddr = NULL
/* How to pass the values to the 'create_thread' function. */
# define STACK_VARIABLES_ARGS stackaddr
/* How to declare function which gets there parameters. */
# define STACK_VARIABLES_PARMS void *stackaddr
/* How to declare allocate_stack. */
# define ALLOCATE_STACK_PARMS void **stack
/* This is how the function is called. We do it this way to allow
other variants of the function to have more parameters. */
# define ALLOCATE_STACK(attr, pd) allocate_stack (attr, pd, &stackaddr)
#else
/* We need two stacks. The kernel will place them but we have to tell
the kernel about the size of the reserved address space. */
# define STACK_VARIABLES void *stackaddr = NULL; size_t stacksize = 0
/* How to pass the values to the 'create_thread' function. */
# define STACK_VARIABLES_ARGS stackaddr, stacksize
/* How to declare function which gets there parameters. */
# define STACK_VARIABLES_PARMS void *stackaddr, size_t stacksize
/* How to declare allocate_stack. */
# define ALLOCATE_STACK_PARMS void **stack, size_t *stacksize
/* This is how the function is called. We do it this way to allow
other variants of the function to have more parameters. */
# define ALLOCATE_STACK(attr, pd) \
allocate_stack (attr, pd, &stackaddr, &stacksize)
#endif
/* Default alignment of stack. */
#ifndef STACK_ALIGN
# define STACK_ALIGN __alignof__ (long double)
#endif
/* Default value for minimal stack size after allocating thread
descriptor and guard. */
#ifndef MINIMAL_REST_STACK
# define MINIMAL_REST_STACK 4096
#endif
/* Newer kernels have the MAP_STACK flag to indicate a mapping is used for
a stack. Use it when possible. */
#ifndef MAP_STACK
# define MAP_STACK 0
#endif
/* This yields the pointer that TLS support code calls the thread pointer. */
#if TLS_TCB_AT_TP
# define TLS_TPADJ(pd) (pd)
#elif TLS_DTV_AT_TP
# define TLS_TPADJ(pd) ((struct pthread *)((char *) (pd) + TLS_PRE_TCB_SIZE))
#endif
/* Cache handling for not-yet free stacks. */
/* Maximum size in kB of cache. */
static size_t stack_cache_maxsize = 40 * 1024 * 1024; /* 40MiBi by default. */
static size_t stack_cache_actsize;
/* Mutex protecting this variable. */
static int stack_cache_lock = LLL_LOCK_INITIALIZER;
/* List of queued stack frames. */
static LIST_HEAD (stack_cache);
/* List of the stacks in use. */
static LIST_HEAD (stack_used);
/* We need to record what list operations we are going to do so that,
in case of an asynchronous interruption due to a fork() call, we
can correct for the work. */
static uintptr_t in_flight_stack;
/* List of the threads with user provided stacks in use. No need to
initialize this, since it's done in __pthread_initialize_minimal. */
list_t __stack_user __attribute__ ((nocommon));
hidden_data_def (__stack_user)
#if COLORING_INCREMENT != 0
/* Number of threads created. */
static unsigned int nptl_ncreated;
#endif
/* Check whether the stack is still used or not. */
#define FREE_P(descr) ((descr)->tid <= 0)
static void
stack_list_del (list_t *elem)
{
in_flight_stack = (uintptr_t) elem;
atomic_write_barrier ();
list_del (elem);
atomic_write_barrier ();
in_flight_stack = 0;
}
static void
stack_list_add (list_t *elem, list_t *list)
{
in_flight_stack = (uintptr_t) elem | 1;
atomic_write_barrier ();
list_add (elem, list);
atomic_write_barrier ();
in_flight_stack = 0;
}
/* We create a double linked list of all cache entries. Double linked
because this allows removing entries from the end. */
/* Get a stack frame from the cache. We have to match by size since
some blocks might be too small or far too large. */
static struct pthread *
get_cached_stack (size_t *sizep, void **memp)
{
size_t size = *sizep;
struct pthread *result = NULL;
list_t *entry;
lll_lock (stack_cache_lock, LLL_PRIVATE);
/* Search the cache for a matching entry. We search for the
smallest stack which has at least the required size. Note that
in normal situations the size of all allocated stacks is the
same. As the very least there are only a few different sizes.
Therefore this loop will exit early most of the time with an
exact match. */
list_for_each (entry, &stack_cache)
{
struct pthread *curr;
curr = list_entry (entry, struct pthread, list);
if (FREE_P (curr) && curr->stackblock_size >= size)
{
if (curr->stackblock_size == size)
{
result = curr;
break;
}
if (result == NULL
|| result->stackblock_size > curr->stackblock_size)
result = curr;
}
}
if (__builtin_expect (result == NULL, 0)
/* Make sure the size difference is not too excessive. In that
case we do not use the block. */
|| __builtin_expect (result->stackblock_size > 4 * size, 0))
{
/* Release the lock. */
lll_unlock (stack_cache_lock, LLL_PRIVATE);
return NULL;
}
/* Don't allow setxid until cloned. */
result->setxid_futex = -1;
/* Dequeue the entry. */
stack_list_del (&result->list);
/* And add to the list of stacks in use. */
stack_list_add (&result->list, &stack_used);
/* And decrease the cache size. */
stack_cache_actsize -= result->stackblock_size;
/* Release the lock early. */
lll_unlock (stack_cache_lock, LLL_PRIVATE);
/* Report size and location of the stack to the caller. */
*sizep = result->stackblock_size;
*memp = result->stackblock;
/* Cancellation handling is back to the default. */
result->cancelhandling = 0;
result->cleanup = NULL;
/* No pending event. */
result->nextevent = NULL;
/* Clear the DTV. */
dtv_t *dtv = GET_DTV (TLS_TPADJ (result));
for (size_t cnt = 0; cnt < dtv[-1].counter; ++cnt)
free (dtv[1 + cnt].pointer.to_free);
memset (dtv, '\0', (dtv[-1].counter + 1) * sizeof (dtv_t));
/* Re-initialize the TLS. */
_dl_allocate_tls_init (TLS_TPADJ (result));
return result;
}
/* Free stacks until cache size is lower than LIMIT. */
void
__free_stacks (size_t limit)
{
/* We reduce the size of the cache. Remove the last entries until
the size is below the limit. */
list_t *entry;
list_t *prev;
/* Search from the end of the list. */
list_for_each_prev_safe (entry, prev, &stack_cache)
{
struct pthread *curr;
curr = list_entry (entry, struct pthread, list);
if (FREE_P (curr))
{
/* Unlink the block. */
stack_list_del (entry);
/* Account for the freed memory. */
stack_cache_actsize -= curr->stackblock_size;
/* Free the memory associated with the ELF TLS. */
_dl_deallocate_tls (TLS_TPADJ (curr), false);
/* Remove this block. This should never fail. If it does
something is really wrong. */
if (munmap (curr->stackblock, curr->stackblock_size) != 0)
abort ();
/* Maybe we have freed enough. */
if (stack_cache_actsize <= limit)
break;
}
}
}
/* Add a stack frame which is not used anymore to the stack. Must be
called with the cache lock held. */
static inline void
__attribute ((always_inline))
queue_stack (struct pthread *stack)
{
/* We unconditionally add the stack to the list. The memory may
still be in use but it will not be reused until the kernel marks
the stack as not used anymore. */
stack_list_add (&stack->list, &stack_cache);
stack_cache_actsize += stack->stackblock_size;
if (__glibc_unlikely (stack_cache_actsize > stack_cache_maxsize))
__free_stacks (stack_cache_maxsize);
}
static int
internal_function
change_stack_perm (struct pthread *pd
#ifdef NEED_SEPARATE_REGISTER_STACK
, size_t pagemask
#endif
)
{
#ifdef NEED_SEPARATE_REGISTER_STACK
void *stack = (pd->stackblock
+ (((((pd->stackblock_size - pd->guardsize) / 2)
& pagemask) + pd->guardsize) & pagemask));
size_t len = pd->stackblock + pd->stackblock_size - stack;
#elif _STACK_GROWS_DOWN
void *stack = pd->stackblock + pd->guardsize;
size_t len = pd->stackblock_size - pd->guardsize;
#elif _STACK_GROWS_UP
void *stack = pd->stackblock;
size_t len = (uintptr_t) pd - pd->guardsize - (uintptr_t) pd->stackblock;
#else
# error "Define either _STACK_GROWS_DOWN or _STACK_GROWS_UP"
#endif
if (mprotect (stack, len, PROT_READ | PROT_WRITE | PROT_EXEC) != 0)
return errno;
return 0;
}
/* Returns a usable stack for a new thread either by allocating a
new stack or reusing a cached stack of sufficient size.
ATTR must be non-NULL and point to a valid pthread_attr.
PDP must be non-NULL. */
static int
allocate_stack (const struct pthread_attr *attr, struct pthread **pdp,
ALLOCATE_STACK_PARMS)
{
struct pthread *pd;
size_t size;
size_t pagesize_m1 = __getpagesize () - 1;
assert (powerof2 (pagesize_m1 + 1));
assert (TCB_ALIGNMENT >= STACK_ALIGN);
/* Get the stack size from the attribute if it is set. Otherwise we
use the default we determined at start time. */
if (attr->stacksize != 0)
size = attr->stacksize;
else
{
lll_lock (__default_pthread_attr_lock, LLL_PRIVATE);
size = __default_pthread_attr.stacksize;
lll_unlock (__default_pthread_attr_lock, LLL_PRIVATE);
}
/* Get memory for the stack. */
if (__glibc_unlikely (attr->flags & ATTR_FLAG_STACKADDR))
{
uintptr_t adj;
char *stackaddr = (char *) attr->stackaddr;
/* Assume the same layout as the _STACK_GROWS_DOWN case, with struct
pthread at the top of the stack block. Later we adjust the guard
location and stack address to match the _STACK_GROWS_UP case. */
if (_STACK_GROWS_UP)
stackaddr += attr->stacksize;
/* If the user also specified the size of the stack make sure it
is large enough. */
if (attr->stacksize != 0
&& attr->stacksize < (__static_tls_size + MINIMAL_REST_STACK))
return EINVAL;
/* Adjust stack size for alignment of the TLS block. */
#if TLS_TCB_AT_TP
adj = ((uintptr_t) stackaddr - TLS_TCB_SIZE)
& __static_tls_align_m1;
assert (size > adj + TLS_TCB_SIZE);
#elif TLS_DTV_AT_TP
adj = ((uintptr_t) stackaddr - __static_tls_size)
& __static_tls_align_m1;
assert (size > adj);
#endif
/* The user provided some memory. Let's hope it matches the
size... We do not allocate guard pages if the user provided
the stack. It is the user's responsibility to do this if it
is wanted. */
#if TLS_TCB_AT_TP
pd = (struct pthread *) ((uintptr_t) stackaddr
- TLS_TCB_SIZE - adj);
#elif TLS_DTV_AT_TP
pd = (struct pthread *) (((uintptr_t) stackaddr
- __static_tls_size - adj)
- TLS_PRE_TCB_SIZE);
#endif
/* The user provided stack memory needs to be cleared. */
memset (pd, '\0', sizeof (struct pthread));
/* The first TSD block is included in the TCB. */
pd->specific[0] = pd->specific_1stblock;
/* Remember the stack-related values. */
pd->stackblock = (char *) stackaddr - size;
pd->stackblock_size = size;
/* This is a user-provided stack. It will not be queued in the
stack cache nor will the memory (except the TLS memory) be freed. */
pd->user_stack = true;
/* This is at least the second thread. */
pd->header.multiple_threads = 1;
#ifndef TLS_MULTIPLE_THREADS_IN_TCB
__pthread_multiple_threads = *__libc_multiple_threads_ptr = 1;
#endif
#ifndef __ASSUME_PRIVATE_FUTEX
/* The thread must know when private futexes are supported. */
pd->header.private_futex = THREAD_GETMEM (THREAD_SELF,
header.private_futex);
#endif
#ifdef NEED_DL_SYSINFO
SETUP_THREAD_SYSINFO (pd);
#endif
/* The process ID is also the same as that of the caller. */
pd->pid = THREAD_GETMEM (THREAD_SELF, pid);
/* Don't allow setxid until cloned. */
pd->setxid_futex = -1;
/* Allocate the DTV for this thread. */
if (_dl_allocate_tls (TLS_TPADJ (pd)) == NULL)
{
/* Something went wrong. */
assert (errno == ENOMEM);
return errno;
}
/* Prepare to modify global data. */
lll_lock (stack_cache_lock, LLL_PRIVATE);
/* And add to the list of stacks in use. */
list_add (&pd->list, &__stack_user);
lll_unlock (stack_cache_lock, LLL_PRIVATE);
}
else
{
/* Allocate some anonymous memory. If possible use the cache. */
size_t guardsize;
size_t reqsize;
void *mem;
const int prot = (PROT_READ | PROT_WRITE
| ((GL(dl_stack_flags) & PF_X) ? PROT_EXEC : 0));
#if COLORING_INCREMENT != 0
/* Add one more page for stack coloring. Don't do it for stacks
with 16 times pagesize or larger. This might just cause
unnecessary misalignment. */
if (size <= 16 * pagesize_m1)
size += pagesize_m1 + 1;
#endif
/* Adjust the stack size for alignment. */
size &= ~__static_tls_align_m1;
assert (size != 0);
/* Make sure the size of the stack is enough for the guard and
eventually the thread descriptor. */
guardsize = (attr->guardsize + pagesize_m1) & ~pagesize_m1;
if (__builtin_expect (size < ((guardsize + __static_tls_size
+ MINIMAL_REST_STACK + pagesize_m1)
& ~pagesize_m1),
0))
/* The stack is too small (or the guard too large). */
return EINVAL;
/* Try to get a stack from the cache. */
reqsize = size;
pd = get_cached_stack (&size, &mem);
if (pd == NULL)
{
/* To avoid aliasing effects on a larger scale than pages we
adjust the allocated stack size if necessary. This way
allocations directly following each other will not have
aliasing problems. */
#if MULTI_PAGE_ALIASING != 0
if ((size % MULTI_PAGE_ALIASING) == 0)
size += pagesize_m1 + 1;
#endif
mem = mmap (NULL, size, prot,
MAP_PRIVATE | MAP_ANONYMOUS | MAP_STACK, -1, 0);
if (__glibc_unlikely (mem == MAP_FAILED))
return errno;
/* SIZE is guaranteed to be greater than zero.
So we can never get a null pointer back from mmap. */
assert (mem != NULL);
#if COLORING_INCREMENT != 0
/* Atomically increment NCREATED. */
unsigned int ncreated = atomic_increment_val (&nptl_ncreated);
/* We chose the offset for coloring by incrementing it for
every new thread by a fixed amount. The offset used
module the page size. Even if coloring would be better
relative to higher alignment values it makes no sense to
do it since the mmap() interface does not allow us to
specify any alignment for the returned memory block. */
size_t coloring = (ncreated * COLORING_INCREMENT) & pagesize_m1;
/* Make sure the coloring offsets does not disturb the alignment
of the TCB and static TLS block. */
if (__glibc_unlikely ((coloring & __static_tls_align_m1) != 0))
coloring = (((coloring + __static_tls_align_m1)
& ~(__static_tls_align_m1))
& ~pagesize_m1);
#else
/* Unless specified we do not make any adjustments. */
# define coloring 0
#endif
/* Place the thread descriptor at the end of the stack. */
#if TLS_TCB_AT_TP
pd = (struct pthread *) ((char *) mem + size - coloring) - 1;
#elif TLS_DTV_AT_TP
pd = (struct pthread *) ((((uintptr_t) mem + size - coloring
- __static_tls_size)
& ~__static_tls_align_m1)
- TLS_PRE_TCB_SIZE);
#endif
/* Remember the stack-related values. */
pd->stackblock = mem;
pd->stackblock_size = size;
/* We allocated the first block thread-specific data array.
This address will not change for the lifetime of this
descriptor. */
pd->specific[0] = pd->specific_1stblock;
/* This is at least the second thread. */
pd->header.multiple_threads = 1;
#ifndef TLS_MULTIPLE_THREADS_IN_TCB
__pthread_multiple_threads = *__libc_multiple_threads_ptr = 1;
#endif
#ifndef __ASSUME_PRIVATE_FUTEX
/* The thread must know when private futexes are supported. */
pd->header.private_futex = THREAD_GETMEM (THREAD_SELF,
header.private_futex);
#endif
#ifdef NEED_DL_SYSINFO
SETUP_THREAD_SYSINFO (pd);
#endif
/* Don't allow setxid until cloned. */
pd->setxid_futex = -1;
/* The process ID is also the same as that of the caller. */
pd->pid = THREAD_GETMEM (THREAD_SELF, pid);
/* Allocate the DTV for this thread. */
if (_dl_allocate_tls (TLS_TPADJ (pd)) == NULL)
{
/* Something went wrong. */
assert (errno == ENOMEM);
/* Free the stack memory we just allocated. */
(void) munmap (mem, size);
return errno;
}
/* Prepare to modify global data. */
lll_lock (stack_cache_lock, LLL_PRIVATE);
/* And add to the list of stacks in use. */
stack_list_add (&pd->list, &stack_used);
lll_unlock (stack_cache_lock, LLL_PRIVATE);
/* There might have been a race. Another thread might have
caused the stacks to get exec permission while this new
stack was prepared. Detect if this was possible and
change the permission if necessary. */
if (__builtin_expect ((GL(dl_stack_flags) & PF_X) != 0
&& (prot & PROT_EXEC) == 0, 0))
{
int err = change_stack_perm (pd
#ifdef NEED_SEPARATE_REGISTER_STACK
, ~pagesize_m1
#endif
);
if (err != 0)
{
/* Free the stack memory we just allocated. */
(void) munmap (mem, size);
return err;
}
}
/* Note that all of the stack and the thread descriptor is
zeroed. This means we do not have to initialize fields
with initial value zero. This is specifically true for
the 'tid' field which is always set back to zero once the
stack is not used anymore and for the 'guardsize' field
which will be read next. */
}
/* Create or resize the guard area if necessary. */
if (__glibc_unlikely (guardsize > pd->guardsize))
{
#ifdef NEED_SEPARATE_REGISTER_STACK
char *guard = mem + (((size - guardsize) / 2) & ~pagesize_m1);
#elif _STACK_GROWS_DOWN
char *guard = mem;
#elif _STACK_GROWS_UP
char *guard = (char *) (((uintptr_t) pd - guardsize) & ~pagesize_m1);
#endif
if (mprotect (guard, guardsize, PROT_NONE) != 0)
{
mprot_error:
lll_lock (stack_cache_lock, LLL_PRIVATE);
/* Remove the thread from the list. */
stack_list_del (&pd->list);
lll_unlock (stack_cache_lock, LLL_PRIVATE);
/* Get rid of the TLS block we allocated. */
_dl_deallocate_tls (TLS_TPADJ (pd), false);
/* Free the stack memory regardless of whether the size
of the cache is over the limit or not. If this piece
of memory caused problems we better do not use it
anymore. Uh, and we ignore possible errors. There
is nothing we could do. */
(void) munmap (mem, size);
return errno;
}
pd->guardsize = guardsize;
}
else if (__builtin_expect (pd->guardsize - guardsize > size - reqsize,
0))
{
/* The old guard area is too large. */
#ifdef NEED_SEPARATE_REGISTER_STACK
char *guard = mem + (((size - guardsize) / 2) & ~pagesize_m1);
char *oldguard = mem + (((size - pd->guardsize) / 2) & ~pagesize_m1);
if (oldguard < guard
&& mprotect (oldguard, guard - oldguard, prot) != 0)
goto mprot_error;
if (mprotect (guard + guardsize,
oldguard + pd->guardsize - guard - guardsize,
prot) != 0)
goto mprot_error;
#elif _STACK_GROWS_DOWN
if (mprotect ((char *) mem + guardsize, pd->guardsize - guardsize,
prot) != 0)
goto mprot_error;
#elif _STACK_GROWS_UP
if (mprotect ((char *) pd - pd->guardsize,
pd->guardsize - guardsize, prot) != 0)
goto mprot_error;
#endif
pd->guardsize = guardsize;
}
/* The pthread_getattr_np() calls need to get passed the size
requested in the attribute, regardless of how large the
actually used guardsize is. */
pd->reported_guardsize = guardsize;
}
/* Initialize the lock. We have to do this unconditionally since the
stillborn thread could be canceled while the lock is taken. */
pd->lock = LLL_LOCK_INITIALIZER;
/* The robust mutex lists also need to be initialized
unconditionally because the cleanup for the previous stack owner
might have happened in the kernel. */
pd->robust_head.futex_offset = (offsetof (pthread_mutex_t, __data.__lock)
- offsetof (pthread_mutex_t,
__data.__list.__next));
pd->robust_head.list_op_pending = NULL;
#ifdef __PTHREAD_MUTEX_HAVE_PREV
pd->robust_prev = &pd->robust_head;
#endif
pd->robust_head.list = &pd->robust_head;
/* We place the thread descriptor at the end of the stack. */
*pdp = pd;
#if _STACK_GROWS_DOWN
void *stacktop;
# if TLS_TCB_AT_TP
/* The stack begins before the TCB and the static TLS block. */
stacktop = ((char *) (pd + 1) - __static_tls_size);
# elif TLS_DTV_AT_TP
stacktop = (char *) (pd - 1);
# endif
# ifdef NEED_SEPARATE_REGISTER_STACK
*stack = pd->stackblock;
*stacksize = stacktop - *stack;
# else
*stack = stacktop;
# endif
#else
*stack = pd->stackblock;
#endif
return 0;
}
void
internal_function
__deallocate_stack (struct pthread *pd)
{
lll_lock (stack_cache_lock, LLL_PRIVATE);
/* Remove the thread from the list of threads with user defined
stacks. */
stack_list_del (&pd->list);
/* Not much to do. Just free the mmap()ed memory. Note that we do
not reset the 'used' flag in the 'tid' field. This is done by
the kernel. If no thread has been created yet this field is
still zero. */
if (__glibc_likely (! pd->user_stack))
(void) queue_stack (pd);
else
/* Free the memory associated with the ELF TLS. */
_dl_deallocate_tls (TLS_TPADJ (pd), false);
lll_unlock (stack_cache_lock, LLL_PRIVATE);
}
int
internal_function
__make_stacks_executable (void **stack_endp)
{
/* First the main thread's stack. */
int err = _dl_make_stack_executable (stack_endp);
if (err != 0)
return err;
#ifdef NEED_SEPARATE_REGISTER_STACK
const size_t pagemask = ~(__getpagesize () - 1);
#endif
lll_lock (stack_cache_lock, LLL_PRIVATE);
list_t *runp;
list_for_each (runp, &stack_used)
{
err = change_stack_perm (list_entry (runp, struct pthread, list)
#ifdef NEED_SEPARATE_REGISTER_STACK
, pagemask
#endif
);
if (err != 0)
break;
}
/* Also change the permission for the currently unused stacks. This
might be wasted time but better spend it here than adding a check
in the fast path. */
if (err == 0)
list_for_each (runp, &stack_cache)
{
err = change_stack_perm (list_entry (runp, struct pthread, list)
#ifdef NEED_SEPARATE_REGISTER_STACK
, pagemask
#endif
);
if (err != 0)
break;
}
lll_unlock (stack_cache_lock, LLL_PRIVATE);
return err;
}
/* In case of a fork() call the memory allocation in the child will be
the same but only one thread is running. All stacks except that of
the one running thread are not used anymore. We have to recycle
them. */
void
__reclaim_stacks (void)
{
struct pthread *self = (struct pthread *) THREAD_SELF;
/* No locking necessary. The caller is the only stack in use. But
we have to be aware that we might have interrupted a list
operation. */
if (in_flight_stack != 0)
{
bool add_p = in_flight_stack & 1;
list_t *elem = (list_t *) (in_flight_stack & ~(uintptr_t) 1);
if (add_p)
{
/* We always add at the beginning of the list. So in this case we
only need to check the beginning of these lists to see if the
pointers at the head of the list are inconsistent. */
list_t *l = NULL;
if (stack_used.next->prev != &stack_used)
l = &stack_used;
else if (stack_cache.next->prev != &stack_cache)
l = &stack_cache;
if (l != NULL)
{
assert (l->next->prev == elem);
elem->next = l->next;
elem->prev = l;
l->next = elem;
}
}
else
{
/* We can simply always replay the delete operation. */
elem->next->prev = elem->prev;
elem->prev->next = elem->next;
}
}
/* Mark all stacks except the still running one as free. */
list_t *runp;
list_for_each (runp, &stack_used)
{
struct pthread *curp = list_entry (runp, struct pthread, list);
if (curp != self)
{
/* This marks the stack as free. */
curp->tid = 0;
/* The PID field must be initialized for the new process. */
curp->pid = self->pid;
/* Account for the size of the stack. */
stack_cache_actsize += curp->stackblock_size;
if (curp->specific_used)
{
/* Clear the thread-specific data. */
memset (curp->specific_1stblock, '\0',
sizeof (curp->specific_1stblock));
curp->specific_used = false;
for (size_t cnt = 1; cnt < PTHREAD_KEY_1STLEVEL_SIZE; ++cnt)
if (curp->specific[cnt] != NULL)
{
memset (curp->specific[cnt], '\0',
sizeof (curp->specific_1stblock));
/* We have allocated the block which we do not
free here so re-set the bit. */
curp->specific_used = true;
}
}
}
}
/* Reset the PIDs in any cached stacks. */
list_for_each (runp, &stack_cache)
{
struct pthread *curp = list_entry (runp, struct pthread, list);
curp->pid = self->pid;
}
/* Add the stack of all running threads to the cache. */
list_splice (&stack_used, &stack_cache);
/* Remove the entry for the current thread to from the cache list
and add it to the list of running threads. Which of the two
lists is decided by the user_stack flag. */
stack_list_del (&self->list);
/* Re-initialize the lists for all the threads. */
INIT_LIST_HEAD (&stack_used);
INIT_LIST_HEAD (&__stack_user);
if (__glibc_unlikely (THREAD_GETMEM (self, user_stack)))
list_add (&self->list, &__stack_user);
else
list_add (&self->list, &stack_used);
/* There is one thread running. */
__nptl_nthreads = 1;
in_flight_stack = 0;
/* Initialize locks. */
stack_cache_lock = LLL_LOCK_INITIALIZER;
__default_pthread_attr_lock = LLL_LOCK_INITIALIZER;
}
#if HP_TIMING_AVAIL
# undef __find_thread_by_id
/* Find a thread given the thread ID. */
attribute_hidden
struct pthread *
__find_thread_by_id (pid_t tid)
{
struct pthread *result = NULL;
lll_lock (stack_cache_lock, LLL_PRIVATE);
/* Iterate over the list with system-allocated threads first. */
list_t *runp;
list_for_each (runp, &stack_used)
{
struct pthread *curp;
curp = list_entry (runp, struct pthread, list);
if (curp->tid == tid)
{
result = curp;
goto out;
}
}
/* Now the list with threads using user-allocated stacks. */
list_for_each (runp, &__stack_user)
{
struct pthread *curp;
curp = list_entry (runp, struct pthread, list);
if (curp->tid == tid)
{
result = curp;
goto out;
}
}
out:
lll_unlock (stack_cache_lock, LLL_PRIVATE);
return result;
}
#endif
#ifdef SIGSETXID
static void
internal_function
setxid_mark_thread (struct xid_command *cmdp, struct pthread *t)
{
int ch;
/* Wait until this thread is cloned. */
if (t->setxid_futex == -1
&& ! atomic_compare_and_exchange_bool_acq (&t->setxid_futex, -2, -1))
do
futex_wait_simple (&t->setxid_futex, -2, FUTEX_PRIVATE);
while (t->setxid_futex == -2);
/* Don't let the thread exit before the setxid handler runs. */
t->setxid_futex = 0;
do
{
ch = t->cancelhandling;
/* If the thread is exiting right now, ignore it. */
if ((ch & EXITING_BITMASK) != 0)
{
/* Release the futex if there is no other setxid in
progress. */
if ((ch & SETXID_BITMASK) == 0)
{
t->setxid_futex = 1;
futex_wake (&t->setxid_futex, 1, FUTEX_PRIVATE);
}
return;
}
}
while (atomic_compare_and_exchange_bool_acq (&t->cancelhandling,
ch | SETXID_BITMASK, ch));
}
static void
internal_function
setxid_unmark_thread (struct xid_command *cmdp, struct pthread *t)
{
int ch;
do
{
ch = t->cancelhandling;
if ((ch & SETXID_BITMASK) == 0)
return;
}
while (atomic_compare_and_exchange_bool_acq (&t->cancelhandling,
ch & ~SETXID_BITMASK, ch));
/* Release the futex just in case. */
t->setxid_futex = 1;
futex_wake (&t->setxid_futex, 1, FUTEX_PRIVATE);
}
static int
internal_function
setxid_signal_thread (struct xid_command *cmdp, struct pthread *t)
{
if ((t->cancelhandling & SETXID_BITMASK) == 0)
return 0;
int val;
INTERNAL_SYSCALL_DECL (err);
val = INTERNAL_SYSCALL (tgkill, err, 3, THREAD_GETMEM (THREAD_SELF, pid),
t->tid, SIGSETXID);
/* If this failed, it must have had not started yet or else exited. */
if (!INTERNAL_SYSCALL_ERROR_P (val, err))
{
atomic_increment (&cmdp->cntr);
return 1;
}
else
return 0;
}
/* Check for consistency across set*id system call results. The abort
should not happen as long as all privileges changes happen through
the glibc wrappers. ERROR must be 0 (no error) or an errno
code. */
void
attribute_hidden
__nptl_setxid_error (struct xid_command *cmdp, int error)
{
do
{
int olderror = cmdp->error;
if (olderror == error)
break;
if (olderror != -1)
/* Mismatch between current and previous results. */
abort ();
}
while (atomic_compare_and_exchange_bool_acq (&cmdp->error, error, -1));
}
int
attribute_hidden
__nptl_setxid (struct xid_command *cmdp)
{
int signalled;
int result;
lll_lock (stack_cache_lock, LLL_PRIVATE);
__xidcmd = cmdp;
cmdp->cntr = 0;
cmdp->error = -1;
struct pthread *self = THREAD_SELF;
/* Iterate over the list with system-allocated threads first. */
list_t *runp;
list_for_each (runp, &stack_used)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self)
continue;
setxid_mark_thread (cmdp, t);
}
/* Now the list with threads using user-allocated stacks. */
list_for_each (runp, &__stack_user)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self)
continue;
setxid_mark_thread (cmdp, t);
}
/* Iterate until we don't succeed in signalling anyone. That means
we have gotten all running threads, and their children will be
automatically correct once started. */
do
{
signalled = 0;
list_for_each (runp, &stack_used)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self)
continue;
signalled += setxid_signal_thread (cmdp, t);
}
list_for_each (runp, &__stack_user)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self)
continue;
signalled += setxid_signal_thread (cmdp, t);
}
int cur = cmdp->cntr;
while (cur != 0)
{
futex_wait_simple ((unsigned int *) &cmdp->cntr, cur,
FUTEX_PRIVATE);
cur = cmdp->cntr;
}
}
while (signalled != 0);
/* Clean up flags, so that no thread blocks during exit waiting
for a signal which will never come. */
list_for_each (runp, &stack_used)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self)
continue;
setxid_unmark_thread (cmdp, t);
}
list_for_each (runp, &__stack_user)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self)
continue;
setxid_unmark_thread (cmdp, t);
}
/* This must be last, otherwise the current thread might not have
permissions to send SIGSETXID syscall to the other threads. */
INTERNAL_SYSCALL_DECL (err);
result = INTERNAL_SYSCALL_NCS (cmdp->syscall_no, err, 3,
cmdp->id[0], cmdp->id[1], cmdp->id[2]);
int error = 0;
if (__glibc_unlikely (INTERNAL_SYSCALL_ERROR_P (result, err)))
{
error = INTERNAL_SYSCALL_ERRNO (result, err);
__set_errno (error);
result = -1;
}
__nptl_setxid_error (cmdp, error);
lll_unlock (stack_cache_lock, LLL_PRIVATE);
return result;
}
#endif /* SIGSETXID. */
static inline void __attribute__((always_inline))
init_one_static_tls (struct pthread *curp, struct link_map *map)
{
# if TLS_TCB_AT_TP
void *dest = (char *) curp - map->l_tls_offset;
# elif TLS_DTV_AT_TP
void *dest = (char *) curp + map->l_tls_offset + TLS_PRE_TCB_SIZE;
# else
# error "Either TLS_TCB_AT_TP or TLS_DTV_AT_TP must be defined"
# endif
/* Fill in the DTV slot so that a later LD/GD access will find it. */
dtv_t *dtv = GET_DTV (TLS_TPADJ (curp));
dtv[map->l_tls_modid].pointer.to_free = NULL;
dtv[map->l_tls_modid].pointer.val = dest;
/* Initialize the memory. */
memset (__mempcpy (dest, map->l_tls_initimage, map->l_tls_initimage_size),
'\0', map->l_tls_blocksize - map->l_tls_initimage_size);
}
void
attribute_hidden
__pthread_init_static_tls (struct link_map *map)
{
lll_lock (stack_cache_lock, LLL_PRIVATE);
/* Iterate over the list with system-allocated threads first. */
list_t *runp;
list_for_each (runp, &stack_used)
init_one_static_tls (list_entry (runp, struct pthread, list), map);
/* Now the list with threads using user-allocated stacks. */
list_for_each (runp, &__stack_user)
init_one_static_tls (list_entry (runp, struct pthread, list), map);
lll_unlock (stack_cache_lock, LLL_PRIVATE);
}
void
attribute_hidden
__wait_lookup_done (void)
{
lll_lock (stack_cache_lock, LLL_PRIVATE);
struct pthread *self = THREAD_SELF;
/* Iterate over the list with system-allocated threads first. */
list_t *runp;
list_for_each (runp, &stack_used)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self || t->header.gscope_flag == THREAD_GSCOPE_FLAG_UNUSED)
continue;
int *const gscope_flagp = &t->header.gscope_flag;
/* We have to wait until this thread is done with the global
scope. First tell the thread that we are waiting and
possibly have to be woken. */
if (atomic_compare_and_exchange_bool_acq (gscope_flagp,
THREAD_GSCOPE_FLAG_WAIT,
THREAD_GSCOPE_FLAG_USED))
continue;
do
futex_wait_simple ((unsigned int *) gscope_flagp,
THREAD_GSCOPE_FLAG_WAIT, FUTEX_PRIVATE);
while (*gscope_flagp == THREAD_GSCOPE_FLAG_WAIT);
}
/* Now the list with threads using user-allocated stacks. */
list_for_each (runp, &__stack_user)
{
struct pthread *t = list_entry (runp, struct pthread, list);
if (t == self || t->header.gscope_flag == THREAD_GSCOPE_FLAG_UNUSED)
continue;
int *const gscope_flagp = &t->header.gscope_flag;
/* We have to wait until this thread is done with the global
scope. First tell the thread that we are waiting and
possibly have to be woken. */
if (atomic_compare_and_exchange_bool_acq (gscope_flagp,
THREAD_GSCOPE_FLAG_WAIT,
THREAD_GSCOPE_FLAG_USED))
continue;
do
futex_wait_simple ((unsigned int *) gscope_flagp,
THREAD_GSCOPE_FLAG_WAIT, FUTEX_PRIVATE);
while (*gscope_flagp == THREAD_GSCOPE_FLAG_WAIT);
}
lll_unlock (stack_cache_lock, LLL_PRIVATE);
}