Name
get_thread_area, set_thread_area - manipulate thread-local storage informationLibrary
Standard C library ( libc ", " -lc )Synopsis
"#include <sys/syscall.h>" " /* Definition of " SYS_* " constants */"#include <unistd.h> #if defined __i386__ || defined __x86_64__ "# include <asm/ldt.h>" " /* Definition of " "struct user_desc" " */"int syscall(SYS_get_thread_area, struct user_desc * u_info );
int syscall(SYS_set_thread_area, struct user_desc * u_info );
#elif defined __m68k__ "int syscall(SYS_get_thread_area);" int syscall(SYS_set_thread_area, unsigned long tp );
#elif defined __mips__ int syscall(SYS_set_thread_area, unsigned long addr );
#endif
Note :
glibc provides no wrappers for these system calls, necessitating the use of syscall(2).
Description
These calls provide architecture-specific support for a thread-local storage implementation. At the moment, set_thread_area() is available on m68k, MIPS, and x86 (both 32-bit and 64-bit variants); get_thread_area() is available on m68k and x86.On m68k and MIPS, set_thread_area() allows storing an arbitrary pointer (provided in the tp argument on m68k and in the addr argument on MIPS) in the kernel data structure associated with the calling thread; this pointer can later be retrieved using get_thread_area() (see also NOTES for information regarding obtaining the thread pointer on MIPS).
On x86, Linux dedicates three global descriptor table (GDT) entries for thread-local storage. For more information about the GDT, see the Intel Software Developer's Manual or the AMD Architecture Programming Manual.
Both of these system calls take an argument that is a pointer to a structure of the following type:
struct user_desc { unsigned int entry_number; unsigned int base_addr; unsigned int limit; unsigned int seg_32bit:1; unsigned int contents:2; unsigned int read_exec_only:1; unsigned int limit_in_pages:1; unsigned int seg_not_present:1; unsigned int useable:1; #ifdef __x86_64__ unsigned int lm:1; #endif };
get_thread_area() reads the GDT entry indicated by u_info->entry_number and fills in the rest of the fields in u_info
.
set_thread_area() sets a TLS entry in the GDT.
The TLS array entry set by set_thread_area() corresponds to the value of u_info->entry_number passed in by the user. If this value is in bounds, set_thread_area() writes the TLS descriptor pointed to by u_info into the thread's TLS array.
When set_thread_area() is passed an entry_number of -1, it searches for a free TLS entry. If set_thread_area() finds a free TLS entry, the value of u_info->entry_number is set upon return to show which entry was changed.
A user_desc is considered "empty" if read_exec_only and seg_not_present are set to 1 and all of the other fields are 0. If an "empty" descriptor is passed to set_thread_area() the corresponding TLS entry will be cleared. See BUGS for additional details.
Since Linux 3.19, set_thread_area() cannot be used to write non-present segments, 16-bit segments, or code segments, although clearing a segment is still acceptable.
Return Value
On x86, these system calls return 0 on success, and -1 on failure, with errno set to indicate the error.On MIPS and m68k, set_thread_area() always returns 0. On m68k, get_thread_area() returns the thread area pointer value (previously set via set_thread_area()
Errors
EFAULT u_info is an invalid pointer.
EINVAL u_info->entry_number is out of bounds.
ENOSYS get_thread_area() or set_thread_area() was invoked as a 64-bit system call.
ESRCH ( set_thread_area ()) A free TLS entry could not be located.
Standards
Linux.History
set_thread_area() Linux 2.5.29.
get_thread_area() Linux 2.5.32.
Notes
These system calls are generally intended for use only by threading libraries.arch_prctl(2) can interfere with set_thread_area() on x86. See arch_prctl(2) for more details. This is not normally a problem, as arch_prctl(2) is normally used only by 64-bit programs.
On MIPS, the current value of the thread area pointer can be obtained using the instruction:
rdhwr dest, $29
This instruction traps and is handled by kernel.
Bugs
On 64-bit kernels before Linux 3.19, one of the padding bits inuser_desc
, if set, would prevent the descriptor from being considered empty (see modify_ldt(2)). As a result, the only reliable way to clear a TLS entry is to use memset(3) to zero the entire user_desc structure, including padding bits, and then to set the read_exec_only and seg_not_present bits. On Linux 3.19, a user_desc consisting entirely of zeros except for entry_number will also be interpreted as a request to clear a TLS entry, but this behaved differently on older kernels. Prior to Linux 3.19, the DS and ES segment registers must not reference TLS entries.
See Also
- arch_prctl(2),
- modify_ldt(2),
- ptrace(2) ( PTRACE_GET_THREAD_AREA " and " PTRACE_SET_THREAD_AREA )