ld.so, ld-linux.so - dynamic linker/loader
The dynamic linker can be run either indirectly by running some
dynamically linked program or shared object (in which case no command-line
options to the dynamic linker can be passed and, in the ELF case, the
dynamic linker which is stored in the .interp section of the program
is executed) or directly by running:
/lib/ld-linux.so.* [OPTIONS] [PROGRAM [ARGUMENTS]]
The programs ld.so and ld-linux.so* find and load
the shared objects (shared libraries) needed by a program, prepare the
program to run, and then run it.
Linux binaries require dynamic linking (linking at run time)
unless the -static option was given to ld(1) during
compilation.
The program ld.so handles a.out binaries, a binary format
used long ago. The program ld-linux.so* (/lib/ld-linux.so.1
for libc5, /lib/ld-linux.so.2 for glibc2) handles binaries that are
in the more modern ELF format. Both programs have the same behavior, and use
the same support files and programs (ldd(1), ldconfig(8), and
/etc/ld.so.conf).
When resolving shared object dependencies, the dynamic linker
first inspects each dependency string to see if it contains a slash (this
can occur if a shared object pathname containing slashes was specified at
link time). If a slash is found, then the dependency string is interpreted
as a (relative or absolute) pathname, and the shared object is loaded using
that pathname.
If a shared object dependency does not contain a slash, then it is
searched for in the following order:
- (1)
- Using the directories specified in the DT_RPATH dynamic section attribute
of the binary if present and DT_RUNPATH attribute does not exist.
- (2)
- Using the environment variable LD_LIBRARY_PATH, unless the
executable is being run in secure-execution mode (see below), in which
case this variable is ignored.
- (3)
- Using the directories specified in the DT_RUNPATH dynamic section
attribute of the binary if present. Such directories are searched only to
find those objects required by DT_NEEDED (direct dependencies) entries and
do not apply to those objects' children, which must themselves have their
own DT_RUNPATH entries. This is unlike DT_RPATH, which is applied to
searches for all children in the dependency tree.
- (4)
- From the cache file /etc/ld.so.cache, which contains a compiled
list of candidate shared objects previously found in the augmented library
path. If, however, the binary was linked with the -z nodefaultlib
linker option, shared objects in the default paths are skipped. Shared
objects installed in hardware capability directories (see below) are
preferred to other shared objects.
- (5)
- In the default path /lib, and then /usr/lib. (On some 64-bit
architectures, the default paths for 64-bit shared objects are
/lib64, and then /usr/lib64.) If the binary was linked with
the -z nodefaultlib linker option, this step is skipped.
In several places, the dynamic linker expands dynamic string
tokens:
- •
- In the environment variables LD_LIBRARY_PATH, LD_PRELOAD,
and LD_AUDIT,
- •
- inside the values of the dynamic section tags DT_NEEDED,
DT_RPATH, DT_RUNPATH, DT_AUDIT, and
DT_DEPAUDIT of ELF binaries,
- •
- in the arguments to the ld.so command line options --audit,
--library-path, and --preload (see below), and
- •
- in the filename arguments to the dlopen(3) and dlmopen(3)
functions.
The substituted tokens are as follows:
- $ORIGIN (or equivalently ${ORIGIN})
- This expands to the directory containing the program or shared object.
Thus, an application located in somedir/app could be compiled
with
-
gcc -Wl,-rpath,'$ORIGIN/../lib'
- so that it finds an associated shared object in somedir/lib no
matter where somedir is located in the directory hierarchy. This
facilitates the creation of "turn-key" applications that do not
need to be installed into special directories, but can instead be unpacked
into any directory and still find their own shared objects.
- $LIB (or equivalently ${LIB})
- This expands to lib or lib64 depending on the architecture
(e.g., on x86-64, it expands to lib64 and on x86-32, it expands to
lib).
- $PLATFORM (or equivalently ${PLATFORM})
- This expands to a string corresponding to the processor type of the host
system (e.g., "x86_64"). On some architectures, the Linux kernel
doesn't provide a platform string to the dynamic linker. The value of this
string is taken from the AT_PLATFORM value in the auxiliary vector
(see getauxval(3)).
Note that the dynamic string tokens have to be quoted properly
when set from a shell, to prevent their expansion as shell or environment
variables.
- --argv0 string
(since glibc 2.33)
- Set argv[0] to the value string before running the
program.
- --audit
list
- Use objects named in list as auditors. The objects in list
are delimited by colons.
- --glibc-hwcaps-mask
list
- only search built-in subdirectories if in list.
- --glibc-hwcaps-prepend
list
- Search glibc-hwcaps subdirectories in list.
- --inhibit-cache
- Do not use /etc/ld.so.cache.
- --library-path
path
- Use path instead of LD_LIBRARY_PATH environment variable
setting (see below). The names ORIGIN, LIB, and
PLATFORM are interpreted as for the LD_LIBRARY_PATH
environment variable.
- --inhibit-rpath
list
- Ignore RPATH and RUNPATH information in object names in list. This
option is ignored when running in secure-execution mode (see below). The
objects in list are delimited by colons or spaces.
- --list
- List all dependencies and how they are resolved.
- --list-diagnostics (since glibc 2.33)
- Print system diagnostic information in a machine-readable format, such as
some internal loader variables, the auxiliary vector (see
getauxval(3)), and the environment variables. On some
architectures, the command might print additional information (like the
cpu features used in GNU indirect function selection on x86).
--list-tunables (since glibc 2.33) Print the names and values of
all tunables, along with the minimum and maximum allowed values.
- --preload
list (since glibc 2.30)
- Preload the objects specified in list. The objects in list
are delimited by colons or spaces. The objects are preloaded as explained
in the description of the LD_PRELOAD environment variable
below.
- By contrast with LD_PRELOAD, the --preload option provides a
way to perform preloading for a single executable without affecting
preloading performed in any child process that executes a new
program.
- --verify
- Verify that program is dynamically linked and this dynamic linker can
handle it.
Various environment variables influence the operation of the
dynamic linker.
For security reasons, if the dynamic linker determines that a
binary should be run in secure-execution mode, the effects of some
environment variables are voided or modified, and furthermore those
environment variables are stripped from the environment, so that the program
does not even see the definitions. Some of these environment variables
affect the operation of the dynamic linker itself, and are described below.
Other environment variables treated in this way include: GCONV_PATH,
GETCONF_DIR, HOSTALIASES, LOCALDOMAIN, LD_AUDIT,
LD_DEBUG, LD_DEBUG_OUTPUT, LD_DYNAMIC_WEAK,
LD_HWCAP_MASK, LD_LIBRARY_PATH, LD_ORIGIN_PATH,
LD_PRELOAD, LD_PROFILE, LD_SHOW_AUXV,
LOCALDOMAIN, LOCPATH, MALLOC_TRACE, NIS_PATH,
NLSPATH, RESOLV_HOST_CONF, RES_OPTIONS, TMPDIR,
and TZDIR.
A binary is executed in secure-execution mode if the
AT_SECURE entry in the auxiliary vector (see getauxval(3)) has
a nonzero value. This entry may have a nonzero value for various reasons,
including:
- •
- The process's real and effective user IDs differ, or the real and
effective group IDs differ. This typically occurs as a result of executing
a set-user-ID or set-group-ID program.
- •
- A process with a non-root user ID executed a binary that conferred
capabilities to the process.
- •
- A nonzero value may have been set by a Linux Security Module.
Among the more important environment variables are the
following:
- LD_ASSUME_KERNEL
(from glibc 2.2.3 to glibc 2.36)
- Each shared object can inform the dynamic linker of the minimum kernel ABI
version that it requires. (This requirement is encoded in an ELF note
section that is viewable via readelf -n as a section labeled
NT_GNU_ABI_TAG.) At run time, the dynamic linker determines the ABI
version of the running kernel and will reject loading shared objects that
specify minimum ABI versions that exceed that ABI version.
- LD_ASSUME_KERNEL can be used to cause the dynamic linker to assume
that it is running on a system with a different kernel ABI version. For
example, the following command line causes the dynamic linker to assume it
is running on Linux 2.2.5 when loading the shared objects required by
myprog:
-
$ LD_ASSUME_KERNEL=2.2.5 ./myprog
- On systems that provide multiple versions of a shared object (in different
directories in the search path) that have different minimum kernel ABI
version requirements, LD_ASSUME_KERNEL can be used to select the
version of the object that is used (dependent on the directory search
order).
- Historically, the most common use of the LD_ASSUME_KERNEL feature
was to manually select the older LinuxThreads POSIX threads implementation
on systems that provided both LinuxThreads and NPTL (which latter was
typically the default on such systems); see pthreads(7).
- LD_BIND_NOW
(since glibc 2.1.1)
- If set to a nonempty string, causes the dynamic linker to resolve all
symbols at program startup instead of deferring function call resolution
to the point when they are first referenced. This is useful when using a
debugger.
- LD_LIBRARY_PATH
- A list of directories in which to search for ELF libraries at execution
time. The items in the list are separated by either colons or semicolons,
and there is no support for escaping either separator. A zero-length
directory name indicates the current working directory.
- This variable is ignored in secure-execution mode.
- Within the pathnames specified in LD_LIBRARY_PATH, the dynamic
linker expands the tokens $ORIGIN, $LIB, and
$PLATFORM (or the versions using curly braces around the names) as
described above in Dynamic string tokens. Thus, for example, the
following would cause a library to be searched for in either the
lib or lib64 subdirectory below the directory containing the
program to be executed:
-
$ LD_LIBRARY_PATH='$ORIGIN/$LIB' prog
- (Note the use of single quotes, which prevent expansion of $ORIGIN
and $LIB as shell variables!)
- LD_PRELOAD
- A list of additional, user-specified, ELF shared objects to be loaded
before all others. This feature can be used to selectively override
functions in other shared objects.
- The items of the list can be separated by spaces or colons, and there is
no support for escaping either separator. The objects are searched for
using the rules given under DESCRIPTION. Objects are searched for and
added to the link map in the left-to-right order specified in the
list.
- In secure-execution mode, preload pathnames containing slashes are
ignored. Furthermore, shared objects are preloaded only from the standard
search directories and only if they have set-user-ID mode bit enabled
(which is not typical).
- Within the names specified in the LD_PRELOAD list, the dynamic
linker understands the tokens $ORIGIN, $LIB, and
$PLATFORM (or the versions using curly braces around the names) as
described above in Dynamic string tokens. (See also the discussion
of quoting under the description of LD_LIBRARY_PATH.)
- There are various methods of specifying libraries to be preloaded, and
these are handled in the following order:
- (1)
- The LD_PRELOAD environment variable.
- (2)
- The --preload command-line option when invoking the dynamic linker
directly.
- (3)
- The /etc/ld.so.preload file (described below).
- LD_TRACE_LOADED_OBJECTS
- If set (to any value), causes the program to list its dynamic
dependencies, as if run by ldd(1), instead of running
normally.
Then there are lots of more or less obscure variables, many
obsolete or only for internal use.
- LD_AUDIT (since
glibc 2.4)
- A list of user-specified, ELF shared objects to be loaded before all
others in a separate linker namespace (i.e., one that does not intrude
upon the normal symbol bindings that would occur in the process) These
objects can be used to audit the operation of the dynamic linker. The
items in the list are colon-separated, and there is no support for
escaping the separator.
- LD_AUDIT is ignored in secure-execution mode.
- The dynamic linker will notify the audit shared objects at so-called
auditing checkpoints—for example, loading a new shared object,
resolving a symbol, or calling a symbol from another shared
object—by calling an appropriate function within the audit shared
object. For details, see rtld-audit(7). The auditing interface is
largely compatible with that provided on Solaris, as described in its
Linker and Libraries Guide, in the chapter Runtime Linker
Auditing Interface.
- Within the names specified in the LD_AUDIT list, the dynamic linker
understands the tokens $ORIGIN, $LIB, and $PLATFORM
(or the versions using curly braces around the names) as described above
in Dynamic string tokens. (See also the discussion of quoting under
the description of LD_LIBRARY_PATH.)
- Since glibc 2.13, in secure-execution mode, names in the audit list that
contain slashes are ignored, and only shared objects in the standard
search directories that have the set-user-ID mode bit enabled are
loaded.
- LD_BIND_NOT
(since glibc 2.1.95)
- If this environment variable is set to a nonempty string, do not update
the GOT (global offset table) and PLT (procedure linkage table) after
resolving a function symbol. By combining the use of this variable with
LD_DEBUG (with the categories bindings and symbols),
one can observe all run-time function bindings.
- LD_DEBUG (since
glibc 2.1)
- Output verbose debugging information about operation of the dynamic
linker. The content of this variable is one of more of the following
categories, separated by colons, commas, or (if the value is quoted)
spaces:
- help
- Specifying help in the value of this variable does not run the
specified program, and displays a help message about which categories can
be specified in this environment variable.
- all
- Print all debugging information (except statistics and
unused; see below).
- bindings
- Display information about which definition each symbol is bound to.
- files
- Display progress for input file.
- libs
- Display library search paths.
- reloc
- Display relocation processing.
- scopes
- Display scope information.
- statistics
- Display relocation statistics.
- symbols
- Display search paths for each symbol look-up.
- unused
- Determine unused DSOs.
- versions
- Display version dependencies.
- Since glibc 2.3.4, LD_DEBUG is ignored in secure-execution mode,
unless the file /etc/suid-debug exists (the content of the file is
irrelevant).
- LD_DEBUG_OUTPUT
(since glibc 2.1)
- By default, LD_DEBUG output is written to standard error. If
LD_DEBUG_OUTPUT is defined, then output is written to the pathname
specified by its value, with the suffix "." (dot) followed by
the process ID appended to the pathname.
- LD_DEBUG_OUTPUT is ignored in secure-execution mode.
- LD_DYNAMIC_WEAK
(since glibc 2.1.91)
- By default, when searching shared libraries to resolve a symbol reference,
the dynamic linker will resolve to the first definition it finds.
- Old glibc versions (before glibc 2.2), provided a different behavior: if
the linker found a symbol that was weak, it would remember that symbol and
keep searching in the remaining shared libraries. If it subsequently found
a strong definition of the same symbol, then it would instead use that
definition. (If no further symbol was found, then the dynamic linker would
use the weak symbol that it initially found.)
- The old glibc behavior was nonstandard. (Standard practice is that the
distinction between weak and strong symbols should have effect only at
static link time.) In glibc 2.2, the dynamic linker was modified to
provide the current behavior (which was the behavior that was provided by
most other implementations at that time).
- Defining the LD_DYNAMIC_WEAK environment variable (with any value)
provides the old (nonstandard) glibc behavior, whereby a weak symbol in
one shared library may be overridden by a strong symbol subsequently
discovered in another shared library. (Note that even when this variable
is set, a strong symbol in a shared library will not override a weak
definition of the same symbol in the main program.)
- Since glibc 2.3.4, LD_DYNAMIC_WEAK is ignored in secure-execution
mode.
- LD_HWCAP_MASK
(from glibc 2.1 to glibc 2.38)
- Mask for hardware capabilities. Since glibc 2.26, the option might be
ignored if glibc does not support tunables.
- LD_ORIGIN_PATH
(since glibc 2.1)
- Path where the binary is found.
- Since glibc 2.4, LD_ORIGIN_PATH is ignored in secure-execution
mode.
- LD_POINTER_GUARD
(from glibc 2.4 to glibc 2.22)
- Set to 0 to disable pointer guarding. Any other value enables pointer
guarding, which is also the default. Pointer guarding is a security
mechanism whereby some pointers to code stored in writable program memory
(return addresses saved by setjmp(3) or function pointers used by
various glibc internals) are mangled semi-randomly to make it more
difficult for an attacker to hijack the pointers for use in the event of a
buffer overrun or stack-smashing attack. Since glibc 2.23,
LD_POINTER_GUARD can no longer be used to disable pointer guarding,
which is now always enabled.
- LD_PROFILE
(since glibc 2.1)
- The name of a (single) shared object to be profiled, specified either as a
pathname or a soname. Profiling output is appended to the file whose name
is: $LD_PROFILE_OUTPUT/$LD_PROFILE.profile.
- Since glibc 2.2.5, LD_PROFILE uses a different default path in
secure-execution mode.
- LD_PROFILE_OUTPUT
(since glibc 2.1)
- Directory where LD_PROFILE output should be written. If this
variable is not defined, or is defined as an empty string, then the
default is /var/tmp.
- LD_PROFILE_OUTPUT is ignored in secure-execution mode; instead
/var/profile is always used.
- LD_SHOW_AUXV
(since glibc 2.1)
- If this environment variable is defined (with any value), show the
auxiliary array passed up from the kernel (see also
getauxval(3)).
- Since glibc 2.3.4, LD_SHOW_AUXV is ignored in secure-execution
mode.
- LD_TRACE_PRELINKING
(from glibc 2.4 to glibc 2.35)
- If this environment variable is defined, trace prelinking of the object
whose name is assigned to this environment variable. (Use ldd(1) to
get a list of the objects that might be traced.) If the object name is not
recognized, then all prelinking activity is traced.
- LD_USE_LOAD_BIAS
(from glibc 2.3.3 to glibc 2.35)
- By default (i.e., if this variable is not defined), executables and
prelinked shared objects will honor base addresses of their dependent
shared objects and (nonprelinked) position-independent executables (PIEs)
and other shared objects will not honor them. If LD_USE_LOAD_BIAS
is defined with the value 1, both executables and PIEs will honor the base
addresses. If LD_USE_LOAD_BIAS is defined with the value 0, neither
executables nor PIEs will honor the base addresses.
- Since glibc 2.3.3, this variable is ignored in secure-execution mode.
- LD_VERBOSE
(since glibc 2.1)
- If set to a nonempty string, output symbol versioning information about
the program if the LD_TRACE_LOADED_OBJECTS environment variable has
been set.
- LD_WARN (since
glibc 2.1.3)
- If set to a nonempty string, warn about unresolved symbols.
- LD_PREFER_MAP_32BIT_EXEC
(x86-64 only; since glibc 2.23)
- According to the Intel Silvermont software optimization guide, for 64-bit
applications, branch prediction performance can be negatively impacted
when the target of a branch is more than 4 GB away from the branch.
If this environment variable is set (to any value), the dynamic linker
will first try to map executable pages using the mmap(2)
MAP_32BIT flag, and fall back to mapping without that flag if that
attempt fails. NB: MAP_32BIT will map to the low 2 GB (not
4 GB) of the address space.
- Because MAP_32BIT reduces the address range available for address
space layout randomization (ASLR), LD_PREFER_MAP_32BIT_EXEC is
always disabled in secure-execution mode.
- /lib/ld.so
- a.out dynamic linker/loader
- /lib/ld-linux.so.{1,2}
- ELF dynamic linker/loader
- /etc/ld.so.cache
- File containing a compiled list of directories in which to search for
shared objects and an ordered list of candidate shared objects. See
ldconfig(8).
- /etc/ld.so.preload
- File containing a whitespace-separated list of ELF shared objects to be
loaded before the program. See the discussion of LD_PRELOAD above.
If both LD_PRELOAD and /etc/ld.so.preload are employed, the
libraries specified by LD_PRELOAD are preloaded first.
/etc/ld.so.preload has a system-wide effect, causing the specified
libraries to be preloaded for all programs that are executed on the
system. (This is usually undesirable, and is typically employed only as an
emergency remedy, for example, as a temporary workaround to a library
misconfiguration issue.)
- lib*.so*
- shared objects
Some shared objects are compiled using hardware-specific
instructions which do not exist on every CPU. Such objects should be
installed in directories whose names define the required hardware
capabilities, such as /usr/lib/sse2/. The dynamic linker checks these
directories against the hardware of the machine and selects the most
suitable version of a given shared object. Hardware capability directories
can be cascaded to combine CPU features. The list of supported hardware
capability names depends on the CPU. The following names are currently
recognized:
- Alpha
- ev4, ev5, ev56, ev6, ev67
- MIPS
- loongson2e, loongson2f, octeon, octeon2
- PowerPC
- 4xxmac, altivec, arch_2_05, arch_2_06, booke, cellbe, dfp, efpdouble,
efpsingle, fpu, ic_snoop, mmu, notb, pa6t, power4, power5, power5+,
power6x, ppc32, ppc601, ppc64, smt, spe, ucache, vsx
- SPARC
- flush, muldiv, stbar, swap, ultra3, v9, v9v, v9v2
- s390
- dfp, eimm, esan3, etf3enh, g5, highgprs, hpage, ldisp, msa, stfle, z900,
z990, z9-109, z10, zarch
- x86 (32-bit
only)
- acpi, apic, clflush, cmov, cx8, dts, fxsr, ht, i386, i486, i586, i686,
mca, mmx, mtrr, pat, pbe, pge, pn, pse36, sep, ss, sse, sse2, tm
The legacy hardware capabilities support has the drawback that
each new feature added grows the search path exponentially, because it has
to be added to every combination of the other existing features.
For instance, on x86 32-bit, if the hardware supports i686
and sse2, the resulting search path will be
i686/sse2:i686:sse2:.. A new capability newcap will set the
search path to
newcap/i686/sse2:newcap/i686:newcap/sse2:newcap:i686/sse2:i686:sse2:.
- glibc 2.33 added a new
hardware capability scheme,
- where under each CPU architecture, certain levels can be defined, grouping
support for certain features or special instructions. Each architecture
level has a fixed set of paths that it adds to the dynamic linker search
list, depending on the hardware of the machine. Since each new
architecture level is not combined with previously existing ones, the new
scheme does not have the drawback of growing the dynamic linker search
list uncontrollably.
For instance, on x86 64-bit, if the hardware supports
x86_64-v3 (for instance Intel Haswell or AMD Excavator), the
resulting search path will be
glibc-hwcaps/x86-64-v3:glibc-hwcaps/x86-64-v2:. The following paths
are currently supported, in priority order.
- PowerPC (64-bit little-endian only)
- power10, power9
- s390 (64-bit only)
- z16, z15, z14, z13
- x86 (64-bit
only)
- x86-64-v4, x86-64-v3, x86-64-v2
glibc 2.37 removed support for the legacy hardware
capabilities.
ld(1), ldd(1), pldd(1), sprof(1),
dlopen(3), getauxval(3), elf(5),
capabilities(7), rtld-audit(7), ldconfig(8),
sln(8)