from small one page howto to huge articles all in one place

search text in:

Which linux distribution do you use?

poll results

Last additions:
using iotop to find disk usage hogs

using iotop to find disk usage hogs






average rating: 1.7 (82 votes) (1=very good 6=terrible)

May 25th. 2007:




why adblockers are bad

Workaround and fixes for the current Core Dump Handling vulnerability affected kernels

Workaround and fixes for the current Core Dump Handling vulnerability affected kernels






average rating: 1.3 (27 votes) (1=very good 6=terrible)

April, 26th. 2006:

You are here: manpages


Section: Linux Programmer's Manual (8)
Updated: 2015-02-21
Index Return to Main Contents

NAME,* - dynamic linker/loader  


The dynamic linker can be run either indirectly by running some dynamically linked program or library (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/* [OPTIONS] [PROGRAM [ARGUMENTS]]  


The programs and* find and load the 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 handles a.out binaries, a format used long ago;* handles ELF (/lib/ for libc5, /lib/ for glibc2), which everybody has been using for years now. Otherwise, both have the same behavior, and use the same support files and programs ldd(1), ldconfig(8), and /etc/

When resolving library dependencies, the dynamic linker first inspects each dependency string to see if it contains a slash (this can occur if a library 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 library is loaded using that pathname.

If a library dependency does not contain a slash, then it is searched for in the following order:

(ELF only) Using the directories specified in the DT_RPATH dynamic section attribute of the binary if present and DT_RUNPATH attribute does not exist. Use of DT_RPATH is deprecated.
Using the environment variable LD_LIBRARY_PATH. Except if the executable is a set-user-ID/set-group-ID binary, in which case it is ignored.
(ELF only) Using the directories specified in the DT_RUNPATH dynamic section attribute of the binary if present.
From the cache file /etc/, which contains a compiled list of candidate libraries previously found in the augmented library path. If, however, the binary was linked with the -z nodeflib linker option, libraries in the default library paths are skipped. Libraries installed in hardware capability directories (see below) are preferred to other libraries.
In the default path /lib, and then /usr/lib. If the binary was linked with the -z nodeflib linker option, this step is skipped.

Rpath token expansion understands certain strings in an rpath specification (DT_RPATH or DT_RUNPATH); those strings are substituted as follows

$ORIGIN (or equivalently ${ORIGIN})
This expands to the directory containing the program or shared library. Thus, an application located in somedir/app could be compiled with

    gcc -Wl,-rpath,aq$ORIGIN/../libaq

so that it finds an associated shared library 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 libraries.

$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)).


List all dependencies and how they are resolved.
Verify that program is dynamically linked and this dynamic linker can handle it.
Do not use /etc/
--library-path path
Use path instead of LD_LIBRARY_PATH environment variable setting (see below).
--inhibit-rpath list
Ignore RPATH and RUNPATH information in object names in list. This option is ignored if is set-user-ID or set-group-ID.
--audit list
Use objects named in list as auditors.


Among the more important environment variables are the following:
(glibc since 2.2.3) Each shared library 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 libraries 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 libraries required by myprog:

$ LD_ASSUME_KERNEL=2.2.5 ./myprog

On systems that provide multiple versions of a shared library (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 library 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).

(libc5; glibc since 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.
A colon-separated list of directories in which to search for ELF libraries at execution-time. Similar to the PATH environment variable. Ignored in set-user-ID and set-group-ID programs.
A list of additional, user-specified, ELF shared libraries to be loaded before all others. The items of the list can be separated by spaces or colons. This can be used to selectively override functions in other shared libraries. The libraries are searched for using the rules given under DESCRIPTION. For set-user-ID/set-group-ID ELF binaries, preload pathnames containing slashes are ignored, and libraries in the standard search directories are loaded only if the set-user-ID permission bit is enabled on the library file.
(ELF only) If set to a nonempty string, causes the program to list its dynamic library 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.

(libc5) Version of LD_LIBRARY_PATH for a.out binaries only. Old versions of also supported LD_ELF_LIBRARY_PATH.
(libc5) Version of LD_PRELOAD for a.out binaries only. Old versions of also supported LD_ELF_PRELOAD.
(glibc since 2.4) A colon-separated 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 libraries can be used to audit the operation of the dynamic linker. LD_AUDIT is ignored for set-user-ID/set-group-ID binaries.

The dynamic linker will notify the audit libraries at so-called auditing checkpoints---for example, loading a new library, resolving a symbol, or calling a symbol from another shared object---by calling an appropriate function within the audit library. 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.

(glibc since 2.1.95) Do not update the GOT (global offset table) and PLT (procedure linkage table) after resolving a symbol.
(glibc since 2.1) Output verbose debugging information about the dynamic linker. If set to all prints all debugging information it has, if set to help prints a help message about which categories can be specified in this environment variable. Since glibc 2.3.4, LD_DEBUG is ignored for set-user-ID/set-group-ID binaries.
(glibc since 2.1) File in which LD_DEBUG output should be written. The default is standard error. LD_DEBUG_OUTPUT is ignored for set-user-ID/set-group-ID binaries.
(glibc since 2.1.91) Allow weak symbols to be overridden (reverting to old glibc behavior). For security reasons, since glibc 2.3.4, LD_DYNAMIC_WEAK is ignored for set-user-ID/set-group-ID binaries.
(glibc since 2.1) Mask for hardware capabilities.
(a.out only)(libc5) Don't ignore the directory in the names of a.out libraries to be loaded. Use of this option is strongly discouraged.
(a.out only)(libc5) Suppress warnings about a.out libraries with incompatible minor version numbers.
(glibc since 2.1) Path where the binary is found (for non-set-user-ID programs). For security reasons, since glibc 2.4, LD_ORIGIN_PATH is ignored for set-user-ID/set-group-ID binaries.
(glibc since 2.4) 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.
(glibc since 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".
(glibc since 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 for set-user-ID and set-group-ID programs, which always use /var/profile.
(glibc since 2.1) Show auxiliary array passed up from the kernel. For security reasons, since glibc 2.3.5, LD_SHOW_AUXV is ignored for set-user-ID/set-group-ID binaries.
(glibc since 2.4) 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.
By default (i.e., if this variable is not defined) executables and prelinked shared objects will honor base addresses of their dependent libraries 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. This variable is ignored by set-user-ID and set-group-ID programs.
(glibc since 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.
(ELF only)(glibc since 2.1.3) If set to a nonempty string, warn about unresolved symbols.
(libc5) argv[0] to be used by ldd(1) when none is present.


a.out dynamic linker/loader
ELF dynamic linker/loader
File containing a compiled list of directories in which to search for libraries and an ordered list of candidate libraries.
File containing a whitespace-separated list of ELF shared libraries to be loaded before the program.
shared libraries


The functionality is available for executables compiled using libc version 4.4.3 or greater. ELF functionality is available since Linux 1.1.52 and libc5.  

Hardware capabilities

Some libraries are compiled using hardware-specific instructions which do not exist on every CPU. Such libraries 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 library. 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:
ev4, ev5, ev56, ev6, ev67
loongson2e, loongson2f, octeon, octeon2
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
flush, muldiv, stbar, swap, ultra3, v9, v9v, v9v2
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


ld(1), ldd(1), pldd(1), sprof(1), dlopen(3), getauxval(3), rtld-audit(7), ldconfig(8), sln(8)  


This page is part of release 3.81 of the Linux man-pages project. A description of the project, information about reporting bugs, and the latest version of this page, can be found at



Rpath token expansion
Hardware capabilities

Please read "Why adblockers are bad".

Other free services
Shorten long
URLs to short
links like
Reverse DNS lookup
Find out which hostname(s)
resolve to a
given IP or other hostnames for the server
rdf newsfeed | rss newsfeed | Atom newsfeed
- Powered by LeopardCMS - Running on Gentoo -
Copyright 2004-2013 Sascha Nitsch Unternehmensberatung UG(haftungsbeschränkt)
Valid XHTML1.1 : Valid CSS : buttonmaker
- Level Triple-A Conformance to Web Content Accessibility Guidelines 1.0 -
- Copyright and legal notices -
Time to create this page: 3.4 ms