VDSO(7)                                                                 Linux Programmer's Manual                                                                VDSO(7)

NAME
       vdso - overview of the virtual ELF dynamic shared object

SYNOPSIS
       #include <sys/auxv.h>

       void *vdso = (uintptr_t) getauxval(AT_SYSINFO_EHDR);

DESCRIPTION
       The  "vDSO"  (virtual  dynamic shared object) is a small shared library that the kernel automatically maps into the address space of all user-space applications.
       Applications usually do not need to concern themselves with these details as the vDSO is most commonly called by the C library.  This way you  can  code  in  the
       normal way using standard functions and the C library will take care of using any functionality that is available via the vDSO.

       Why  does the vDSO exist at all?  There are some system calls the kernel provides that user-space code ends up using frequently, to the point that such calls can
       dominate overall performance.  This is due both to the frequency of the call as well as the context-switch overhead that results from exiting user space and  en‐
       tering the kernel.

       The  rest  of this documentation is geared toward the curious and/or C library writers rather than general developers.  If you're trying to call the vDSO in your
       own application rather than using the C library, you're most likely doing it wrong.

   Example background
       Making system calls can be slow.  In x86 32-bit systems, you can trigger a software interrupt (int $0x80) to tell the kernel you wish  to  make  a  system  call.
       However,  this  instruction is expensive: it goes through the full interrupt-handling paths in the processor's microcode as well as in the kernel.  Newer proces‐
       sors have faster (but backward incompatible) instructions to initiate system calls.  Rather than require the C library to figure out  if  this  functionality  is
       available at run time, the C library can use functions provided by the kernel in the vDSO.

       Note  that  the  terminology can be confusing.  On x86 systems, the vDSO function used to determine the preferred method of making a system call is named "__ker‐
       nel_vsyscall", but on x86-64, the term "vsyscall" also refers to an obsolete way to ask the kernel what time it is or what CPU the caller is on.

       One frequently used system call is gettimeofday(2).  This system call is called both directly by user-space applications as well as indirectly by the C  library.
       Think  timestamps or timing loops or polling—all of these frequently need to know what time it is right now.  This information is also not secret—any application
       in any privilege mode (root or any unprivileged user) will get the same answer.  Thus the kernel arranges for the information required to answer this question to
       be placed in memory the process can access.  Now a call to gettimeofday(2) changes from a system call to a normal function call and a few memory accesses.

   Finding the vDSO
       The  base address of the vDSO (if one exists) is passed by the kernel to each program in the initial auxiliary vector (see getauxval(3)), via the AT_SYSINFO_EHDR
       tag.

       You must not assume the vDSO is mapped at any particular location in the user's memory map.  The base address will usually be randomized at run time every time a
       new process image is created (at execve(2) time).  This is done for security reasons, to prevent "return-to-libc" attacks.

       For  some architectures, there is also an AT_SYSINFO tag.  This is used only for locating the vsyscall entry point and is frequently omitted or set to 0 (meaning
       it's not available).  This tag is a throwback to the initial vDSO work (see History below) and its use should be avoided.

   File format
       Since the vDSO is a fully formed ELF image, you can do symbol lookups on it.  This allows new symbols to be added with newer kernel releases, and  allows  the  C
       library  to  detect  available functionality at run time when running under different kernel versions.  Oftentimes the C library will do detection with the first
       call and then cache the result for subsequent calls.

       All symbols are also versioned (using the GNU version format).  This allows the kernel to update the function signature without breaking backward  compatibility.
       This means changing the arguments that the function accepts as well as the return value.  Thus, when looking up a symbol in the vDSO, you must always include the
       version to match the ABI you expect.

       Typically the vDSO follows the naming convention of prefixing all symbols with "__vdso_" or "__kernel_" so as to distinguish them from  other  standard  symbols.
       For example, the "gettimeofday" function is named "__vdso_gettimeofday".

       You use the standard C calling conventions when calling any of these functions.  No need to worry about weird register or stack behavior.

NOTES
   Source
       When  you  compile  the kernel, it will automatically compile and link the vDSO code for you.  You will frequently find it under the architecture-specific direc‐
       tory:

           find arch/$ARCH/ -name '*vdso*.so*' -o -name '*gate*.so*'

   vDSO names
       The name of the vDSO varies across architectures.  It will often show up in things like glibc's ldd(1) output.  The exact name should not matter to any code,  so
       do not hardcode it.

       user ABI   vDSO name
       ─────────────────────────────
       aarch64    linux-vdso.so.1
       arm        linux-vdso.so.1
       ia64       linux-gate.so.1
       mips       linux-vdso.so.1
       ppc/32     linux-vdso32.so.1
       ppc/64     linux-vdso64.so.1
       riscv      linux-vdso.so.1
       s390       linux-vdso32.so.1
       s390x      linux-vdso64.so.1
       sh         linux-gate.so.1
       i386       linux-gate.so.1
       x86-64     linux-vdso.so.1
       x86/x32    linux-vdso.so.1

   strace(1), seccomp(2), and the vDSO
       When  tracing  systems  calls  with strace(1), symbols (system calls) that are exported by the vDSO will not appear in the trace output.  Those system calls will
       likewise not be visible to seccomp(2) filters.

ARCHITECTURE-SPECIFIC NOTES
       The subsections below provide architecture-specific notes on the vDSO.

       Note that the vDSO that is used is based on the ABI of your user-space code and not the ABI of the kernel.  Thus, for example, when you run an  i386  32-bit  ELF
       binary, you'll get the same vDSO regardless of whether you run it under an i386 32-bit kernel or under an x86-64 64-bit kernel.  Therefore, the name of the user-
       space ABI should be used to determine which of the sections below is relevant.

   ARM functions
       The table below lists the symbols exported by the vDSO.

       symbol                 version
       ────────────────────────────────────────────────────────────
       __vdso_gettimeofday    LINUX_2.6 (exported since Linux 4.1)
       __vdso_clock_gettime   LINUX_2.6 (exported since Linux 4.1)

       Additionally, the ARM port has a code page full of utility functions.  Since it's just a raw page of code, there is no ELF information for doing  symbol  lookups
       or versioning.  It does provide support for different versions though.

       For  information  on this code page, it's best to refer to the kernel documentation as it's extremely detailed and covers everything you need to know: Documenta‐
       tion/arm/kernel_user_helpers.txt.

   aarch64 functions
       The table below lists the symbols exported by the vDSO.

       symbol                   version
       ──────────────────────────────────────
       __kernel_rt_sigreturn    LINUX_2.6.39
       __kernel_gettimeofday    LINUX_2.6.39
       __kernel_clock_gettime   LINUX_2.6.39
       __kernel_clock_getres    LINUX_2.6.39

   bfin (Blackfin) functions (port removed in Linux 4.17)
       As this CPU lacks a memory management unit (MMU), it doesn't set up a vDSO in the normal sense.  Instead, it maps at boot time a few raw functions into  a  fixed
       location  in memory.  User-space applications then call directly into that region.  There is no provision for backward compatibility beyond sniffing raw opcodes,
       but as this is an embedded CPU, it can get away with things—some of the object formats it runs aren't even ELF based (they're bFLT/FLAT).

       For information on this code page, it's best to refer to the public documentation:
       http://docs.blackfin.uclinux.org/doku.php?id=linux-kernel:fixed-code

   mips functions
       The table below lists the symbols exported by the vDSO.

       symbol                   version
       ──────────────────────────────────────────────────────────────
       __kernel_gettimeofday    LINUX_2.6 (exported since Linux 4.4)
       __kernel_clock_gettime   LINUX_2.6 (exported since Linux 4.4)

   ia64 (Itanium) functions
       The table below lists the symbols exported by the vDSO.

       symbol                       version
       ───────────────────────────────────────
       __kernel_sigtramp            LINUX_2.5
       __kernel_syscall_via_break   LINUX_2.5
       __kernel_syscall_via_epc     LINUX_2.5

       The Itanium port is somewhat tricky.  In addition to the vDSO above, it also has "light-weight system calls" (also known as "fast syscalls" or "fsys").  You  can
       invoke  these  via the __kernel_syscall_via_epc vDSO helper.  The system calls listed here have the same semantics as if you called them directly via syscall(2),
       so refer to the relevant documentation for each.  The table below lists the functions available via this mechanism.

       function
       ────────────────
       clock_gettime
       getcpu
       getpid
       getppid
       gettimeofday
       set_tid_address

   parisc (hppa) functions
       The parisc port has a code page with utility functions called a gateway page.  Rather than use the normal ELF auxiliary vector approach, it passes the address of
       the  page  to  the  process  via the SR2 register.  The permissions on the page are such that merely executing those addresses automatically executes with kernel
       privileges and not in user space.  This is done to match the way HP-UX works.

       Since it's just a raw page of code, there is no ELF information for doing symbol lookups or versioning.  Simply call into the appropriate offset via  the  branch
       instruction, for example:

           ble <offset>(%sr2, %r0)

       offset   function
       ────────────────────────────────────────────
       00b0     lws_entry (CAS operations)
       00e0     set_thread_pointer (used by glibc)
       0100     linux_gateway_entry (syscall)

   ppc/32 functions
       The table below lists the symbols exported by the vDSO.  The functions marked with a * are available only when the kernel is a PowerPC64 (64-bit) kernel.

       symbol                     version
       ────────────────────────────────────────
       __kernel_clock_getres      LINUX_2.6.15
       __kernel_clock_gettime     LINUX_2.6.15
       __kernel_clock_gettime64   LINUX_5.11
       __kernel_datapage_offset   LINUX_2.6.15
       __kernel_get_syscall_map   LINUX_2.6.15
       __kernel_get_tbfreq        LINUX_2.6.15
       __kernel_getcpu *          LINUX_2.6.15
       __kernel_gettimeofday      LINUX_2.6.15
       __kernel_sigtramp_rt32     LINUX_2.6.15
       __kernel_sigtramp32        LINUX_2.6.15
       __kernel_sync_dicache      LINUX_2.6.15
       __kernel_sync_dicache_p5   LINUX_2.6.15

       In  kernel  versions  before  Linux  5.6,  the  CLOCK_REALTIME_COARSE and CLOCK_MONOTONIC_COARSE clocks are not supported by the __kernel_clock_getres and __ker‐
       nel_clock_gettime interfaces; the kernel falls back to the real system call.

   ppc/64 functions
       The table below lists the symbols exported by the vDSO.

       symbol                     version
       ────────────────────────────────────────
       __kernel_clock_getres      LINUX_2.6.15
       __kernel_clock_gettime     LINUX_2.6.15
       __kernel_datapage_offset   LINUX_2.6.15
       __kernel_get_syscall_map   LINUX_2.6.15
       __kernel_get_tbfreq        LINUX_2.6.15
       __kernel_getcpu            LINUX_2.6.15
       __kernel_gettimeofday      LINUX_2.6.15
       __kernel_sigtramp_rt64     LINUX_2.6.15
       __kernel_sync_dicache      LINUX_2.6.15
       __kernel_sync_dicache_p5   LINUX_2.6.15

       In kernel versions before Linux 4.16, the CLOCK_REALTIME_COARSE and CLOCK_MONOTONIC_COARSE clocks are not  supported  by  the  __kernel_clock_getres  and  __ker‐
       nel_clock_gettime interfaces; the kernel falls back to the real system call.

   riscv functions
       The table below lists the symbols exported by the vDSO.

       symbol                   version
       ────────────────────────────────────
       __kernel_rt_sigreturn    LINUX_4.15
       __kernel_gettimeofday    LINUX_4.15
       __kernel_clock_gettime   LINUX_4.15
       __kernel_clock_getres    LINUX_4.15
       __kernel_getcpu          LINUX_4.15
       __kernel_flush_icache    LINUX_4.15

   s390 functions
       The table below lists the symbols exported by the vDSO.

       symbol                   version
       ──────────────────────────────────────
       __kernel_clock_getres    LINUX_2.6.29
       __kernel_clock_gettime   LINUX_2.6.29
       __kernel_gettimeofday    LINUX_2.6.29

   s390x functions
       The table below lists the symbols exported by the vDSO.

       symbol                   version
       ──────────────────────────────────────
       __kernel_clock_getres    LINUX_2.6.29
       __kernel_clock_gettime   LINUX_2.6.29
       __kernel_gettimeofday    LINUX_2.6.29

   sh (SuperH) functions
       The table below lists the symbols exported by the vDSO.

       symbol                  version
       ──────────────────────────────────
       __kernel_rt_sigreturn   LINUX_2.6
       __kernel_sigreturn      LINUX_2.6
       __kernel_vsyscall       LINUX_2.6

   i386 functions
       The table below lists the symbols exported by the vDSO.

       symbol                  version
       ──────────────────────────────────────────────────────────────
       __kernel_sigreturn      LINUX_2.5

       __kernel_rt_sigreturn   LINUX_2.5
       __kernel_vsyscall       LINUX_2.5
       __vdso_clock_gettime    LINUX_2.6 (exported since Linux 3.15)
       __vdso_gettimeofday     LINUX_2.6 (exported since Linux 3.15)
       __vdso_time             LINUX_2.6 (exported since Linux 3.15)

   x86-64 functions
       The  table  below  lists the symbols exported by the vDSO.  All of these symbols are also available without the "__vdso_" prefix, but you should ignore those and
       stick to the names below.

       symbol                 version
       ─────────────────────────────────
       __vdso_clock_gettime   LINUX_2.6
       __vdso_getcpu          LINUX_2.6
       __vdso_gettimeofday    LINUX_2.6
       __vdso_time            LINUX_2.6

   x86/x32 functions
       The table below lists the symbols exported by the vDSO.

       symbol                 version
       ─────────────────────────────────
       __vdso_clock_gettime   LINUX_2.6
       __vdso_getcpu          LINUX_2.6
       __vdso_gettimeofday    LINUX_2.6
       __vdso_time            LINUX_2.6

   History
       The vDSO was originally just a single function—the vsyscall.  In older kernels, you might see that name in a process's memory map rather than "vdso".  Over time,
       people realized that this mechanism was a great way to pass more functionality to user space, so it was reconceived as a vDSO in the current format.

SEE ALSO
       syscalls(2), getauxval(3), proc(5)

       The documents, examples, and source code in the Linux source code tree:

           Documentation/ABI/stable/vdso
           Documentation/ia64/fsys.txt
           Documentation/vDSO/* (includes examples of using the vDSO)

           find arch/ -iname '*vdso*' -o -iname '*gate*'

Linux                                                                          2021-08-27                                                                        VDSO(7)