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90842d3980
The current toolchain does not consistently generate it, and glibc does not use it. Reviewed-by: Szabolcs Nagy <szabolcs.nagy@arm.com>
1106 lines
46 KiB
Plaintext
1106 lines
46 KiB
Plaintext
@node Dynamic Linker
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@c @node Dynamic Linker, Internal Probes, Threads, Top
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@c %MENU% Loading programs and shared objects.
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@chapter Dynamic Linker
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@cindex dynamic linker
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@cindex dynamic loader
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The @dfn{dynamic linker} is responsible for loading dynamically linked
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programs and their dependencies (in the form of shared objects). The
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dynamic linker in @theglibc{} also supports loading shared objects (such
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as plugins) later at run time.
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Dynamic linkers are sometimes called @dfn{dynamic loaders}.
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@menu
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* Dynamic Linker Invocation:: Explicit invocation of the dynamic linker.
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* Dynamic Linker Introspection:: Interfaces for querying mapping information.
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* Dynamic Linker Hardening:: Avoiding unexpected issues with dynamic linking.
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@end menu
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@node Dynamic Linker Invocation
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@section Dynamic Linker Invocation
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@cindex program interpreter
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When a dynamically linked program starts, the operating system
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automatically loads the dynamic linker along with the program.
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@Theglibc{} also supports invoking the dynamic linker explicitly to
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launch a program. This command uses the implied dynamic linker
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(also sometimes called the @dfn{program interpreter}):
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@smallexample
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sh -c 'echo "Hello, world!"'
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@end smallexample
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This command specifies the dynamic linker explicitly:
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@smallexample
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ld.so /bin/sh -c 'echo "Hello, world!"'
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@end smallexample
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Note that @command{ld.so} does not search the @env{PATH} environment
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variable, so the full file name of the executable needs to be specified.
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The @command{ld.so} program supports various options. Options start
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@samp{--} and need to come before the program that is being launched.
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Some of the supported options are listed below.
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@table @code
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@item --list-diagnostics
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Print system diagnostic information in a machine-readable format.
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@xref{Dynamic Linker Diagnostics}.
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@end table
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@menu
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* Dynamic Linker Diagnostics:: Obtaining system diagnostic information.
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@end menu
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@node Dynamic Linker Diagnostics
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@subsection Dynamic Linker Diagnostics
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@cindex diagnostics (dynamic linker)
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The @samp{ld.so --list-diagnostics} produces machine-readable
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diagnostics output. This output contains system data that affects the
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behavior of @theglibc{}, and potentially application behavior as well.
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The exact set of diagnostic items can change between releases of
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@theglibc{}. The output format itself is not expected to change
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radically.
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The following table shows some example lines that can be written by the
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diagnostics command.
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@table @code
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@item dl_pagesize=0x1000
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The system page size is 4096 bytes.
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@item env[0x14]="LANG=en_US.UTF-8"
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This item indicates that the 21st environment variable at process
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startup contains a setting for @code{LANG}.
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@item env_filtered[0x22]="DISPLAY"
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The 35th environment variable is @code{DISPLAY}. Its value is not
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included in the output for privacy reasons because it is not recognized
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as harmless by the diagnostics code.
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@item path.prefix="/usr"
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This means that @theglibc{} was configured with @code{--prefix=/usr}.
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@item path.system_dirs[0x0]="/lib64/"
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@itemx path.system_dirs[0x1]="/usr/lib64/"
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The built-in dynamic linker search path contains two directories,
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@code{/lib64} and @code{/usr/lib64}.
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@end table
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@menu
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* Dynamic Linker Diagnostics Format:: Format of ld.so output.
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* Dynamic Linker Diagnostics Values:: Data contain in ld.so output.
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@end menu
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@node Dynamic Linker Diagnostics Format
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@subsubsection Dynamic Linker Diagnostics Format
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As seen above, diagnostic lines assign values (integers or strings) to a
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sequence of labeled subscripts, separated by @samp{.}. Some subscripts
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have integer indices associated with them. The subscript indices are
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not necessarily contiguous or small, so an associative array should be
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used to store them. Currently, all integers fit into the 64-bit
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unsigned integer range. Every access path to a value has a fixed type
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(string or integer) independent of subscript index values. Likewise,
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whether a subscript is indexed does not depend on previous indices (but
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may depend on previous subscript labels).
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A syntax description in ABNF (RFC 5234) follows. Note that
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@code{%x30-39} denotes the range of decimal digits. Diagnostic output
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lines are expected to match the @code{line} production.
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@c ABNF-START
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@smallexample
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HEXDIG = %x30-39 / %x61-6f ; lowercase a-f only
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ALPHA = %x41-5a / %x61-7a / %x7f ; letters and underscore
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ALPHA-NUMERIC = ALPHA / %x30-39 / "_"
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DQUOTE = %x22 ; "
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; Numbers are always hexadecimal and use a 0x prefix.
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hex-value-prefix = %x30 %x78
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hex-value = hex-value-prefix 1*HEXDIG
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; Strings use octal escape sequences and \\, \".
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string-char = %x20-21 / %x23-5c / %x5d-7e ; printable but not "\
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string-quoted-octal = %x30-33 2*2%x30-37
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string-quoted = "\" ("\" / DQUOTE / string-quoted-octal)
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string-value = DQUOTE *(string-char / string-quoted) DQUOTE
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value = hex-value / string-value
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label = ALPHA *ALPHA-NUMERIC
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index = "[" hex-value "]"
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subscript = label [index]
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line = subscript *("." subscript) "=" value
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@end smallexample
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@node Dynamic Linker Diagnostics Values
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@subsubsection Dynamic Linker Diagnostics Values
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As mentioned above, the set of diagnostics may change between
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@theglibc{} releases. Nevertheless, the following table documents a few
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common diagnostic items. All numbers are in hexadecimal, with a
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@samp{0x} prefix.
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@table @code
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@item dl_dst_lib=@var{string}
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The @code{$LIB} dynamic string token expands to @var{string}.
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@cindex HWCAP (diagnostics)
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@item dl_hwcap=@var{integer}
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@itemx dl_hwcap2=@var{integer}
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The HWCAP and HWCAP2 values, as returned for @code{getauxval}, and as
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used in other places depending on the architecture.
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@cindex page size (diagnostics)
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@item dl_pagesize=@var{integer}
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The system page size is @var{integer} bytes.
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@item dl_platform=@var{string}
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The @code{$PLATFORM} dynamic string token expands to @var{string}.
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@item dso.libc=@var{string}
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This is the soname of the shared @code{libc} object that is part of
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@theglibc{}. On most architectures, this is @code{libc.so.6}.
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@item env[@var{index}]=@var{string}
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@itemx env_filtered[@var{index}]=@var{string}
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An environment variable from the process environment. The integer
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@var{index} is the array index in the environment array. Variables
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under @code{env} include the variable value after the @samp{=} (assuming
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that it was present), variables under @code{env_filtered} do not.
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@item path.prefix=@var{string}
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This indicates that @theglibc{} was configured using
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@samp{--prefix=@var{string}}.
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@item path.sysconfdir=@var{string}
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@Theglibc{} was configured (perhaps implicitly) with
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@samp{--sysconfdir=@var{string}} (typically @code{/etc}).
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@item path.system_dirs[@var{index}]=@var{string}
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These items list the elements of the built-in array that describes the
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default library search path. The value @var{string} is a directory file
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name with a trailing @samp{/}.
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@item path.rtld=@var{string}
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This string indicates the application binary interface (ABI) file name
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of the run-time dynamic linker.
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@item version.release="stable"
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@itemx version.release="development"
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The value @code{"stable"} indicates that this build of @theglibc{} is
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from a release branch. Releases labeled as @code{"development"} are
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unreleased development versions.
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@cindex version (diagnostics)
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@item version.version="@var{major}.@var{minor}"
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@itemx version.version="@var{major}.@var{minor}.9000"
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@Theglibc{} version. Development releases end in @samp{.9000}.
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@cindex auxiliary vector (diagnostics)
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@item auxv[@var{index}].a_type=@var{type}
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@itemx auxv[@var{index}].a_val=@var{integer}
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@itemx auxv[@var{index}].a_val_string=@var{string}
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An entry in the auxiliary vector (specific to Linux). The values
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@var{type} (an integer) and @var{integer} correspond to the members of
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@code{struct auxv}. If the value is a string, @code{a_val_string} is
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used instead of @code{a_val}, so that values have consistent types.
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The @code{AT_HWCAP} and @code{AT_HWCAP2} values in this output do not
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reflect adjustment by @theglibc{}.
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@item uname.sysname=@var{string}
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@itemx uname.nodename=@var{string}
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@itemx uname.release=@var{string}
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@itemx uname.version=@var{string}
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@itemx uname.machine=@var{string}
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@itemx uname.domain=@var{string}
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These Linux-specific items show the values of @code{struct utsname}, as
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reported by the @code{uname} function. @xref{Platform Type}.
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@item aarch64.cpu_features.@dots{}
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These items are specific to the AArch64 architectures. They report data
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@theglibc{} uses to activate conditionally supported features such as
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BTI and MTE, and to select alternative function implementations.
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@item aarch64.processor[@var{index}].@dots{}
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These are additional items for the AArch64 architecture and are
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described below.
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@item aarch64.processor[@var{index}].requested=@var{kernel-cpu}
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The kernel is told to run the subsequent probing on the CPU numbered
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@var{kernel-cpu}. The values @var{kernel-cpu} and @var{index} can be
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distinct if there are gaps in the process CPU affinity mask. This line
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is not included if CPU affinity mask information is not available.
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@item aarch64.processor[@var{index}].observed=@var{kernel-cpu}
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This line reports the kernel CPU number @var{kernel-cpu} on which the
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probing code initially ran. If the CPU number cannot be obtained,
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this line is not printed.
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@item aarch64.processor[@var{index}].observed_node=@var{node}
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This reports the observed NUMA node number, as reported by the
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@code{getcpu} system call. If this information cannot be obtained, this
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line is not printed.
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@item aarch64.processor[@var{index}].midr_el1=@var{value}
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The value of the @code{midr_el1} system register on the processor
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@var{index}. This line is only printed if the kernel indicates that
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this system register is supported.
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@item aarch64.processor[@var{index}].dczid_el0=@var{value}
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The value of the @code{dczid_el0} system register on the processor
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@var{index}.
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@cindex CPUID (diagnostics)
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@item x86.cpu_features.@dots{}
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These items are specific to the i386 and x86-64 architectures. They
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reflect supported CPU features and information on cache geometry, mostly
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collected using the CPUID instruction.
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@item x86.processor[@var{index}].@dots{}
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These are additional items for the i386 and x86-64 architectures, as
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described below. They mostly contain raw data from the CPUID
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instruction. The probes are performed for each active CPU for the
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@code{ld.so} process, and data for different probed CPUs receives a
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uniqe @var{index} value. Some CPUID data is expected to differ from CPU
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core to CPU core. In some cases, CPUs are not correctly initialized and
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indicate the presence of different feature sets.
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@item x86.processor[@var{index}].requested=@var{kernel-cpu}
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The kernel is told to run the subsequent probing on the CPU numbered
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@var{kernel-cpu}. The values @var{kernel-cpu} and @var{index} can be
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distinct if there are gaps in the process CPU affinity mask. This line
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is not included if CPU affinity mask information is not available.
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@item x86.processor[@var{index}].observed=@var{kernel-cpu}
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This line reports the kernel CPU number @var{kernel-cpu} on which the
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probing code initially ran. If the CPU number cannot be obtained,
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this line is not printed.
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@item x86.processor[@var{index}].observed_node=@var{node}
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This reports the observed NUMA node number, as reported by the
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@code{getcpu} system call. If this information cannot be obtained, this
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line is not printed.
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@item x86.processor[@var{index}].cpuid_leaves=@var{count}
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This line indicates that @var{count} distinct CPUID leaves were
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encountered. (This reflects internal @code{ld.so} storage space, it
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does not directly correspond to @code{CPUID} enumeration ranges.)
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@item x86.processor[@var{index}].ecx_limit=@var{value}
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The CPUID data extraction code uses a brute-force approach to enumerate
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subleaves (see the @samp{.subleaf_eax} lines below). The last
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@code{%rcx} value used in a CPUID query on this probed CPU was
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@var{value}.
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@item x86.processor[@var{index}].cpuid.eax[@var{query_eax}].eax=@var{eax}
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@itemx x86.processor[@var{index}].cpuid.eax[@var{query_eax}].ebx=@var{ebx}
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@itemx x86.processor[@var{index}].cpuid.eax[@var{query_eax}].ecx=@var{ecx}
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@itemx x86.processor[@var{index}].cpuid.eax[@var{query_eax}].edx=@var{edx}
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These lines report the register contents after executing the CPUID
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instruction with @samp{%rax == @var{query_eax}} and @samp{%rcx == 0} (a
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@dfn{leaf}). For the first probed CPU (with a zero @var{index}), only
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leaves with non-zero register contents are reported. For subsequent
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CPUs, only leaves whose register contents differs from the previously
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probed CPUs (with @var{index} one less) are reported.
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Basic and extended leaves are reported using the same syntax. This
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means there is a large jump in @var{query_eax} for the first reported
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extended leaf.
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@item x86.processor[@var{index}].cpuid.subleaf_eax[@var{query_eax}].ecx[@var{query_ecx}].eax=@var{eax}
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@itemx x86.processor[@var{index}].cpuid.subleaf_eax[@var{query_eax}].ecx[@var{query_ecx}].ebx=@var{ebx}
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@itemx x86.processor[@var{index}].cpuid.subleaf_eax[@var{query_eax}].ecx[@var{query_ecx}].ecx=@var{ecx}
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@itemx x86.processor[@var{index}].cpuid.subleaf_eax[@var{query_eax}].ecx[@var{query_ecx}].edx=@var{edx}
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This is similar to the leaves above, but for a @dfn{subleaf}. For
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subleaves, the CPUID instruction is executed with @samp{%rax ==
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@var{query_eax}} and @samp{%rcx == @var{query_ecx}}, so the result
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depends on both register values. The same rules about filtering zero
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and identical results apply.
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@item x86.processor[@var{index}].cpuid.subleaf_eax[@var{query_eax}].ecx[@var{query_ecx}].until_ecx=@var{ecx_limit}
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Some CPUID results are the same regardless the @var{query_ecx} value.
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If this situation is detected, a line with the @samp{.until_ecx}
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selector ins included, and this indicates that the CPUID register
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contents is the same for @code{%rcx} values between @var{query_ecx}
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and @var{ecx_limit} (inclusive).
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@item x86.processor[@var{index}].cpuid.subleaf_eax[@var{query_eax}].ecx[@var{query_ecx}].ecx_query_mask=0xff
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This line indicates that in an @samp{.until_ecx} range, the CPUID
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instruction preserved the lowested 8 bits of the input @code{%rcx} in
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the output @code{%rcx} registers. Otherwise, the subleaves in the range
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have identical values. This special treatment is necessary to report
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compact range information in case such copying occurs (because the
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subleaves would otherwise be all different).
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@item x86.processor[@var{index}].xgetbv.ecx[@var{query_ecx}]=@var{result}
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This line shows the 64-bit @var{result} value in the @code{%rdx:%rax}
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register pair after executing the XGETBV instruction with @code{%rcx}
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set to @var{query_ecx}. Zero values and values matching the previously
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probed CPU are omitted. Nothing is printed if the system does not
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support the XGETBV instruction.
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@end table
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@node Dynamic Linker Introspection
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@section Dynamic Linker Introspection
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@Theglibc{} provides various functions for querying information from the
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dynamic linker.
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@deftypefun {int} dlinfo (void *@var{handle}, int @var{request}, void *@var{arg})
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@safety{@mtsafe{}@asunsafe{@asucorrupt{}}@acunsafe{@acucorrupt{}}}
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@standards{GNU, dlfcn.h}
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This function returns information about @var{handle} in the memory
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location @var{arg}, based on @var{request}. The @var{handle} argument
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must be a pointer returned by @code{dlopen} or @code{dlmopen}; it must
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not have been closed by @code{dlclose}.
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On success, @code{dlinfo} returns 0 for most request types; exceptions
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are noted below. If there is an error, the function returns @math{-1},
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and @code{dlerror} can be used to obtain a corresponding error message.
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The following operations are defined for use with @var{request}:
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@vtable @code
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@item RTLD_DI_LINKMAP
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The corresponding @code{struct link_map} pointer for @var{handle} is
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written to @code{*@var{arg}}. The @var{arg} argument must be the
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address of an object of type @code{struct link_map *}.
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@item RTLD_DI_LMID
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The namespace identifier of @var{handle} is written to
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@code{*@var{arg}}. The @var{arg} argument must be the address of an
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object of type @code{Lmid_t}.
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@item RTLD_DI_ORIGIN
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The value of the @code{$ORIGIN} dynamic string token for @var{handle} is
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written to the character array starting at @var{arg} as a
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null-terminated string.
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This request type should not be used because it is prone to buffer
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overflows.
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@item RTLD_DI_SERINFO
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@itemx RTLD_DI_SERINFOSIZE
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These requests can be used to obtain search path information for
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@var{handle}. For both requests, @var{arg} must point to a
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@code{Dl_serinfo} object. The @code{RTLD_DI_SERINFOSIZE} request must
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be made first; it updates the @code{dls_size} and @code{dls_cnt} members
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of the @code{Dl_serinfo} object. The caller should then allocate memory
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to store at least @code{dls_size} bytes and pass that buffer to a
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@code{RTLD_DI_SERINFO} request. This second request fills the
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@code{dls_serpath} array. The number of array elements was returned in
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the @code{dls_cnt} member in the initial @code{RTLD_DI_SERINFOSIZE}
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|
request. The caller is responsible for freeing the allocated buffer.
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This interface is prone to buffer overflows in multi-threaded processes
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because the required size can change between the
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@code{RTLD_DI_SERINFOSIZE} and @code{RTLD_DI_SERINFO} requests.
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@item RTLD_DI_TLS_DATA
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This request writes the address of the TLS block (in the current thread)
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for the shared object identified by @var{handle} to @code{*@var{arg}}.
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The argument @var{arg} must be the address of an object of type
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@code{void *}. A null pointer is written if the object does not have
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any associated TLS block.
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@item RTLD_DI_TLS_MODID
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This request writes the TLS module ID for the shared object @var{handle}
|
|
to @code{*@var{arg}}. The argument @var{arg} must be the address of an
|
|
object of type @code{size_t}. The module ID is zero if the object
|
|
does not have an associated TLS block.
|
|
|
|
@item RTLD_DI_PHDR
|
|
This request writes the address of the program header array to
|
|
@code{*@var{arg}}. The argument @var{arg} must be the address of an
|
|
object of type @code{const ElfW(Phdr) *} (that is,
|
|
@code{const Elf32_Phdr *} or @code{const Elf64_Phdr *}, as appropriate
|
|
for the current architecture). For this request, the value returned by
|
|
@code{dlinfo} is the number of program headers in the program header
|
|
array.
|
|
@end vtable
|
|
|
|
The @code{dlinfo} function is a GNU extension.
|
|
@end deftypefun
|
|
|
|
The remainder of this section documents the @code{_dl_find_object}
|
|
function and supporting types and constants.
|
|
|
|
@deftp {Data Type} {struct dl_find_object}
|
|
@standards{GNU, dlfcn.h}
|
|
This structure contains information about a main program or loaded
|
|
object. The @code{_dl_find_object} function uses it to return
|
|
result data to the caller.
|
|
|
|
@table @code
|
|
@item unsigned long long int dlfo_flags
|
|
Currently unused and always 0.
|
|
|
|
@item void *dlfo_map_start
|
|
The start address of the inspected mapping. This information comes from
|
|
the program header, so it follows its convention, and the address is not
|
|
necessarily page-aligned.
|
|
|
|
@item void *dlfo_map_end
|
|
The end address of the mapping.
|
|
|
|
@item struct link_map *dlfo_link_map
|
|
This member contains a pointer to the link map of the object.
|
|
|
|
@item void *dlfo_eh_frame
|
|
This member contains a pointer to the exception handling data of the
|
|
object. See @code{DLFO_EH_SEGMENT_TYPE} below.
|
|
|
|
@end table
|
|
|
|
This structure is a GNU extension.
|
|
@end deftp
|
|
|
|
@deftypevr Macro int DLFO_STRUCT_HAS_EH_DBASE
|
|
@standards{GNU, dlfcn.h}
|
|
On most targets, this macro is defined as @code{0}. If it is defined to
|
|
@code{1}, @code{struct dl_find_object} contains an additional member
|
|
@code{dlfo_eh_dbase} of type @code{void *}. It is the base address for
|
|
@code{DW_EH_PE_datarel} DWARF encodings to this location.
|
|
|
|
This macro is a GNU extension.
|
|
@end deftypevr
|
|
|
|
@deftypevr Macro int DLFO_STRUCT_HAS_EH_COUNT
|
|
@standards{GNU, dlfcn.h}
|
|
On most targets, this macro is defined as @code{0}. If it is defined to
|
|
@code{1}, @code{struct dl_find_object} contains an additional member
|
|
@code{dlfo_eh_count} of type @code{int}. It is the number of exception
|
|
handling entries in the EH frame segment identified by the
|
|
@code{dlfo_eh_frame} member.
|
|
|
|
This macro is a GNU extension.
|
|
@end deftypevr
|
|
|
|
@deftypevr Macro int DLFO_EH_SEGMENT_TYPE
|
|
@standards{GNU, dlfcn.h}
|
|
On targets using DWARF-based exception unwinding, this macro expands to
|
|
@code{PT_GNU_EH_FRAME}. This indicates that @code{dlfo_eh_frame} in
|
|
@code{struct dl_find_object} points to the @code{PT_GNU_EH_FRAME}
|
|
segment of the object. On targets that use other unwinding formats, the
|
|
macro expands to the program header type for the unwinding data.
|
|
|
|
This macro is a GNU extension.
|
|
@end deftypevr
|
|
|
|
@deftypefun {int} _dl_find_object (void *@var{address}, struct dl_find_object *@var{result})
|
|
@standards{GNU, dlfcn.h}
|
|
@safety{@mtsafe{}@assafe{}@acsafe{}}
|
|
On success, this function returns 0 and writes about the object
|
|
surrounding the address to @code{*@var{result}}. On failure, -1 is
|
|
returned.
|
|
|
|
The @var{address} can be a code address or data address. On
|
|
architectures using function descriptors, no attempt is made to decode
|
|
the function descriptor. Depending on how these descriptors are
|
|
implemented, @code{_dl_find_object} may return the object that defines
|
|
the function descriptor (and not the object that contains the code
|
|
implementing the function), or fail to find any object at all.
|
|
|
|
On success @var{address} is greater than or equal to
|
|
@code{@var{result}->dlfo_map_start} and less than
|
|
@code{@var{result}->dlfo_map_end}, that is, the supplied code address is
|
|
located within the reported mapping.
|
|
|
|
This function returns a pointer to the unwinding information for the
|
|
object that contains the program code @var{address} in
|
|
@code{@var{result}->dlfo_eh_frame}. If the platform uses DWARF
|
|
unwinding information, this is the in-memory address of the
|
|
@code{PT_GNU_EH_FRAME} segment. See @code{DLFO_EH_SEGMENT_TYPE} above.
|
|
In case @var{address} resides in an object that lacks unwinding information,
|
|
the function still returns 0, but sets @code{@var{result}->dlfo_eh_frame}
|
|
to a null pointer.
|
|
|
|
@code{_dl_find_object} itself is thread-safe. However, if the
|
|
application invokes @code{dlclose} for the object that contains
|
|
@var{address} concurrently with @code{_dl_find_object} or after the call
|
|
returns, accessing the unwinding data for that object or the link map
|
|
(through @code{@var{result}->dlfo_link_map}) is not safe. Therefore, the
|
|
application needs to ensure by other means (e.g., by convention) that
|
|
@var{address} remains a valid code address while the unwinding
|
|
information is processed.
|
|
|
|
This function is a GNU extension.
|
|
@end deftypefun
|
|
|
|
@node Dynamic Linker Hardening
|
|
@section Avoiding Unexpected Issues With Dynamic Linking
|
|
|
|
This section details recommendations for increasing application
|
|
robustness, by avoiding potential issues related to dynamic linking.
|
|
The recommendations have two main aims: reduce the involvement of the
|
|
dynamic linker in application execution after process startup, and
|
|
restrict the application to a dynamic linker feature set whose behavior
|
|
is more easily understood.
|
|
|
|
Key aspects of limiting dynamic linker usage after startup are: no use
|
|
of the @code{dlopen} function, disabling lazy binding, and using the
|
|
static TLS model. More easily understood dynamic linker behavior
|
|
requires avoiding name conflicts (symbols and sonames) and highly
|
|
customizable features like the audit subsystem.
|
|
|
|
Note that while these steps can be considered a form of application
|
|
hardening, they do not guard against potential harm from accidental or
|
|
deliberate loading of untrusted or malicious code. There is only
|
|
limited overlap with traditional security hardening for applications
|
|
running on GNU systems.
|
|
|
|
@subsection Restricted Dynamic Linker Features
|
|
|
|
Avoiding certain dynamic linker features can increase predictability of
|
|
applications and reduce the risk of running into dynamic linker defects.
|
|
|
|
@itemize @bullet
|
|
@item
|
|
Do not use the functions @code{dlopen}, @code{dlmopen}, or
|
|
@code{dlclose}. Dynamic loading and unloading of shared objects
|
|
introduces substantial complications related to symbol and thread-local
|
|
storage (TLS) management.
|
|
|
|
@item
|
|
Without the @code{dlopen} function, @code{dlsym} and @code{dlvsym}
|
|
cannot be used with shared object handles. Minimizing the use of both
|
|
functions is recommended. If they have to be used, only the
|
|
@code{RTLD_DEFAULT} pseudo-handle should be used.
|
|
|
|
@item
|
|
Use the local-exec or initial-exec TLS models. If @code{dlopen} is not
|
|
used, there are no compatibility concerns for initial-exec TLS. This
|
|
TLS model avoids most of the complexity around TLS access. In
|
|
particular, there are no TLS-related run-time memory allocations after
|
|
process or thread start.
|
|
|
|
If shared objects are expected to be used more generally, outside the
|
|
hardened, feature-restricted context, lack of compatibility between
|
|
@code{dlopen} and initial-exec TLS could be a concern. In that case,
|
|
the second-best alternative is to use global-dynamic TLS with GNU2 TLS
|
|
descriptors, for targets that fully implement them, including the fast
|
|
path for access to TLS variables defined in the initially loaded set of
|
|
objects. Like initial-exec TLS, this avoids memory allocations after
|
|
thread creation, but only if the @code{dlopen} function is not used.
|
|
|
|
@item
|
|
Do not use lazy binding. Lazy binding may require run-time memory
|
|
allocation, is not async-signal-safe, and introduces considerable
|
|
complexity.
|
|
|
|
@item
|
|
Make dependencies on shared objects explicit. Do not assume that
|
|
certain libraries (such as @code{libc.so.6}) are always loaded.
|
|
Specifically, if a main program or shared object references a symbol,
|
|
create an ELF @code{DT_NEEDED} dependency on that shared object, or on
|
|
another shared object that is documented (or otherwise guaranteed) to
|
|
have the required explicit dependency. Referencing a symbol without a
|
|
matching link dependency results in underlinking, and underlinked
|
|
objects cannot always be loaded correctly: Initialization of objects may
|
|
not happen in the required order.
|
|
|
|
@item
|
|
Do not create dependency loops between shared objects (@code{libA.so.1}
|
|
depending on @code{libB.so.1} depending on @code{libC.so.1} depending on
|
|
@code{libA.so.1}). @Theglibc{} has to initialize one of the objects in
|
|
the cycle first, and the choice of that object is arbitrary and can
|
|
change over time. The object which is initialized first (and other
|
|
objects involved in the cycle) may not run correctly because not all of
|
|
its dependencies have been initialized.
|
|
|
|
Underlinking (see above) can hide the presence of cycles.
|
|
|
|
@item
|
|
Limit the creation of indirect function (IFUNC) resolvers. These
|
|
resolvers run during relocation processing, when @theglibc{} is not in
|
|
a fully consistent state. If you write your own IFUNC resolvers, do
|
|
not depend on external data or function references in those resolvers.
|
|
|
|
@item
|
|
Do not use the audit functionality (@code{LD_AUDIT}, @code{DT_AUDIT},
|
|
@code{DT_DEPAUDIT}). Its callback and hooking capabilities introduce a
|
|
lot of complexity and subtly alter dynamic linker behavior in corner
|
|
cases even if the audit module is inactive.
|
|
|
|
@item
|
|
Do not use symbol interposition. Without symbol interposition, the
|
|
exact order in which shared objects are searched are less relevant.
|
|
|
|
Exceptions to this rule are copy relocations (see the next item), and
|
|
vague linkage, as used by the C++ implementation (see below).
|
|
|
|
@item
|
|
One potential source of symbol interposition is a combination of static
|
|
and dynamic linking, namely linking a static archive into multiple
|
|
dynamic shared objects. For such scenarios, the static library should
|
|
be converted into its own dynamic shared object.
|
|
|
|
A different approach to this situation uses hidden visibility for
|
|
symbols in the static library, but this can cause problems if the
|
|
library does not expect that multiple copies of its code coexist within
|
|
the same process, with no or partial sharing of state.
|
|
|
|
@item
|
|
If you use shared objects that are linked with @option{-Wl,-Bsymbolic}
|
|
(or equivalent) or use protected visibility, the code for the main
|
|
program must be built as @option{-fpic} or @option{-fPIC} to avoid
|
|
creating copy relocations (and the main program must not use copy
|
|
relocations for other reasons). Using @option{-fpie} or @option{-fPIE}
|
|
is not an alternative to PIC code in this context.
|
|
|
|
@item
|
|
Be careful about explicit section annotations. Make sure that the
|
|
target section matches the properties of the declared entity (e.g., no
|
|
writable objects in @code{.text}).
|
|
|
|
@item
|
|
Ensure that all assembler or object input files have the recommended
|
|
security markup, particularly for non-executable stack.
|
|
|
|
@item
|
|
Avoid using non-default linker flags and features. In particular, do
|
|
not use the @code{DT_PREINIT_ARRAY} dynamic tag, and do not flag
|
|
objects as @code{DF_1_INITFIRST}. Do not change the default linker
|
|
script of BFD ld. Do not override ABI defaults, such as the dynamic
|
|
linker path (with @option{--dynamic-linker}).
|
|
|
|
@item
|
|
Some features of @theglibc{} indirectly depend on run-time code loading
|
|
and @code{dlopen}. Use @code{iconv_open} with built-in converters only
|
|
(such as @code{UTF-8}). Do not use NSS functionality such as
|
|
@code{getaddrinfo} or @code{getpwuid_r} unless the system is configured
|
|
for built-in NSS service modules only (see below).
|
|
@end itemize
|
|
|
|
Several considerations apply to ELF constructors and destructors.
|
|
|
|
@itemize @bullet
|
|
@item
|
|
The dynamic linker does not take constructor and destructor priorities
|
|
into account when determining their execution order. Priorities are
|
|
only used by the link editor for ordering execution within a
|
|
completely linked object. If a dynamic shared object needs to be
|
|
initialized before another object, this can be expressed with a
|
|
@code{DT_NEEDED} dependency on the object that needs to be initialized
|
|
earlier.
|
|
|
|
@item
|
|
The recommendations to avoid cyclic dependencies and symbol
|
|
interposition make it less likely that ELF objects are accessed before
|
|
their ELF constructors have run. However, using @code{dlsym} and
|
|
@code{dlvsym}, it is still possible to access uninitialized facilities
|
|
even with these restrictions in place. (Of course, access to
|
|
uninitialized functionality is also possible within a single shared
|
|
object or the main executable, without resorting to explicit symbol
|
|
lookup.) Consider using dynamic, on-demand initialization instead. To
|
|
deal with access after de-initialization, it may be necessary to
|
|
implement special cases for that scenario, potentially with degraded
|
|
functionality.
|
|
|
|
@item
|
|
Be aware that when ELF destructors are executed, it is possible to
|
|
reference already-deconstructed shared objects. This can happen even in
|
|
the absence of @code{dlsym} and @code{dlvsym} function calls, for
|
|
example if client code using a shared object has registered callbacks or
|
|
objects with another shared object. The ELF destructor for the client
|
|
code is executed before the ELF destructor for the shared objects that
|
|
it uses, based on the expected dependency order.
|
|
|
|
@item
|
|
If @code{dlopen} and @code{dlmopen} are not used, @code{DT_NEEDED}
|
|
dependency information is complete, and lazy binding is disabled, the
|
|
execution order of ELF destructors is expected to be the reverse of the
|
|
ELF constructor order. However, two separate dependency sort operations
|
|
still occur. Even though the listed preconditions should ensure that
|
|
both sorts produce the same ordering, it is recommended not to depend on
|
|
the destructor order being the reverse of the constructor order.
|
|
@end itemize
|
|
|
|
The following items provide C++-specific guidance for preparing
|
|
applications. If another programming language is used and it uses these
|
|
toolchain features targeted at C++ to implement some language
|
|
constructs, these restrictions and recommendations still apply in
|
|
analogous ways.
|
|
|
|
@itemize @bullet
|
|
@item
|
|
C++ inline functions, templates, and other constructs may need to be
|
|
duplicated into multiple shared objects using vague linkage, resulting
|
|
in symbol interposition. This type of symbol interposition is
|
|
unproblematic, as long as the C++ one definition rule (ODR) is followed,
|
|
and all definitions in different translation units are equivalent
|
|
according to the language C++ rules.
|
|
|
|
@item
|
|
Be aware that under C++ language rules, it is unspecified whether
|
|
evaluating a string literal results in the same address for each
|
|
evaluation. This also applies to anonymous objects of static storage
|
|
duration that GCC creates, for example to implement the compound
|
|
literals C++ extension. As a result, comparing pointers to such
|
|
objects, or using them directly as hash table keys, may give unexpected
|
|
results.
|
|
|
|
By default, variables of block scope of static storage have consistent
|
|
addresses across different translation units, even if defined in
|
|
functions that use vague linkage.
|
|
|
|
@item
|
|
Special care is needed if a C++ project uses symbol visibility or
|
|
symbol version management (for example, the GCC @samp{visibility}
|
|
attribute, the GCC @option{-fvisibility} option, or a linker version
|
|
script with the linker option @option{--version-script}). It is
|
|
necessary to ensure that the symbol management remains consistent with
|
|
how the symbols are used. Some C++ constructs are implemented with
|
|
the help of ancillary symbols, which can make complicated to achieve
|
|
consistency. For example, an inline function that is always inlined
|
|
into its callers has no symbol footprint for the function itself, but
|
|
if the function contains a variable of static storage duration, this
|
|
variable may result in the creation of one or more global symbols.
|
|
For correctness, such symbols must be visible and bound to the same
|
|
object in all other places where the inline function may be called.
|
|
This requirement is not met if the symbol visibility is set to hidden,
|
|
or if symbols are assigned a textually different symbol version
|
|
(effectively creating two distinct symbols).
|
|
|
|
Due to the complex interaction between ELF symbol management and C++
|
|
symbol generation, it is recommended to use C++ language features for
|
|
symbol management, in particular inline namespaces.
|
|
|
|
@item
|
|
The toolchain and dynamic linker have multiple mechanisms that bypass
|
|
the usual symbol binding procedures. This means that the C++ one
|
|
definition rule (ODR) still holds even if certain symbol-based isolation
|
|
mechanisms are used, and object addresses are not shared across
|
|
translation units with incompatible type definitions.
|
|
|
|
This does not matter if the original (language-independent) advice
|
|
regarding symbol interposition is followed. However, as the advice may
|
|
be difficult to implement for C++ applications, it is recommended to
|
|
avoid ODR violations across the entire process image. Inline namespaces
|
|
can be helpful in this context because they can be used to create
|
|
distinct ELF symbols while maintaining source code compatibility at the
|
|
C++ level.
|
|
|
|
@item
|
|
Be aware that as a special case of interposed symbols, symbols with the
|
|
@code{STB_GNU_UNIQUE} binding type do not follow the usual ELF symbol
|
|
namespace isolation rules: such symbols bind across @code{RTLD_LOCAL}
|
|
boundaries. Furthermore, symbol versioning is ignored for such symbols;
|
|
they are bound by symbol name only. All their definitions and uses must
|
|
therefore be compatible. Hidden visibility still prevents the creation
|
|
of @code{STB_GNU_UNIQUE} symbols and can achieve isolation of
|
|
incompatible definitions.
|
|
|
|
@item
|
|
C++ constructor priorities only affect constructor ordering within one
|
|
shared object. Global constructor order across shared objects is
|
|
consistent with ELF dependency ordering if there are no ELF dependency
|
|
cycles.
|
|
|
|
@item
|
|
C++ exception handling and run-time type information (RTTI), as
|
|
implemented in the GNU toolchain, is not address-significant, and
|
|
therefore is not affected by the symbol binding behaviour of the dynamic
|
|
linker. This means that types of the same fully-qualified name (in
|
|
non-anonymous namespaces) are always considered the same from an
|
|
exception-handling or RTTI perspective. This is true even if the type
|
|
information object or vtable has hidden symbol visibility, or the
|
|
corresponding symbols are versioned under different symbol versions, or
|
|
the symbols are not bound to the same objects due to the use of
|
|
@code{RTLD_LOCAL} or @code{dlmopen}.
|
|
|
|
This can cause issues in applications that contain multiple incompatible
|
|
definitions of the same type. Inline namespaces can be used to create
|
|
distinct symbols at the ELF layer, avoiding this type of issue.
|
|
|
|
@item
|
|
C++ exception handling across multiple @code{dlmopen} namespaces may
|
|
not work, particular with the unwinder in GCC versions before 12.
|
|
Current toolchain versions are able to process unwinding tables across
|
|
@code{dlmopen} boundaries. However, note that type comparison is
|
|
name-based, not address-based (see the previous item), so exception
|
|
types may still be matched in unexpected ways. An important special
|
|
case of exception handling, invoking destructors for variables of block
|
|
scope, is not impacted by this RTTI type-sharing. Likewise, regular
|
|
virtual member function dispatch for objects is unaffected (but still
|
|
requires that the type definitions match in all directly involved
|
|
translation units).
|
|
|
|
Once more, inline namespaces can be used to create distinct ELF symbols
|
|
for different types.
|
|
|
|
@item
|
|
Although the C++ standard requires that destructors for global objects
|
|
run in the opposite order of their constructors, the Itanium C++ ABI
|
|
requires a different destruction order in some cases. As a result, do
|
|
not depend on the precise destructor invocation order in applications
|
|
that use @code{dlclose}.
|
|
|
|
@item
|
|
Registering destructors for later invocation allocates memory and may
|
|
silently fail if insufficient memory is available. As a result, the
|
|
destructor is never invoked. This applies to all forms of destructor
|
|
registration, with the exception of thread-local variables (see the next
|
|
item). To avoid this issue, ensure that such objects merely have
|
|
trivial destructors, avoiding the need for registration, and deallocate
|
|
resources using a different mechanism (for example, from an ELF
|
|
destructor).
|
|
|
|
@item
|
|
A similar issue exists for @code{thread_local} variables with thread
|
|
storage duration of types that have non-trivial destructors. However,
|
|
in this case, memory allocation failure during registration leads to
|
|
process termination. If process termination is not acceptable, use
|
|
@code{thread_local} variables with trivial destructors only.
|
|
Functions for per-thread cleanup can be registered using
|
|
@code{pthread_key_create} (globally for all threads) and activated
|
|
using @code{pthread_setspecific} (on each thread). Note that a
|
|
@code{pthread_key_create} call may still fail (and
|
|
@code{pthread_create} keys are a limited resource in @theglibc{}), but
|
|
this failure can be handled without terminating the process.
|
|
@end itemize
|
|
|
|
@subsection Producing Matching Binaries
|
|
|
|
This subsection recommends tools and build flags for producing
|
|
applications that meet the recommendations of the previous subsection.
|
|
|
|
@itemize @bullet
|
|
@item
|
|
Use BFD ld (@command{bfd.ld}) from GNU binutils to produce binaries,
|
|
invoked through a compiler driver such as @command{gcc}. The version
|
|
should be not too far ahead of what was current when the version of
|
|
@theglibc{} was first released.
|
|
|
|
@item
|
|
Do not use a binutils release that is older than the one used to build
|
|
@theglibc{} itself.
|
|
|
|
@item
|
|
Compile with @option{-ftls-model=initial-exec} to force the initial-exec
|
|
TLS model.
|
|
|
|
@item
|
|
Link with @option{-Wl,-z,now} to disable lazy binding.
|
|
|
|
@item
|
|
Link with @option{-Wl,-z,relro} to enable RELRO (which is the default on
|
|
most targets).
|
|
|
|
@item
|
|
Specify all direct shared objects dependencies using @option{-l} options
|
|
to avoid underlinking. Rely on @code{.so} files (which can be linker
|
|
scripts) and searching with the @option{-l} option. Do not specify the
|
|
file names of shared objects on the linker command line.
|
|
|
|
@item
|
|
Consider using @option{-Wl,-z,defs} to treat underlinking as an error
|
|
condition.
|
|
|
|
@item
|
|
When creating a shared object (linked with @option{-shared}), use
|
|
@option{-Wl,-soname,lib@dots{}} to set a soname that matches the final
|
|
installed name of the file.
|
|
|
|
@item
|
|
Do not use the @option{-rpath} linker option. (As explained below, all
|
|
required shared objects should be installed into the default search
|
|
path.)
|
|
|
|
@item
|
|
Use @option{-Wl,--error-rwx-segments} and @option{-Wl,--error-execstack} to
|
|
instruct the link editor to fail the link if the resulting final object
|
|
would have read-write-execute segments or an executable stack. Such
|
|
issues usually indicate that the input files are not marked up
|
|
correctly.
|
|
|
|
@item
|
|
Ensure that for each @code{LOAD} segment in the ELF program header, file
|
|
offsets, memory sizes, and load addresses are multiples of the largest
|
|
page size supported at run time. Similarly, the start address and size
|
|
of the @code{GNU_RELRO} range should be multiples of the page size.
|
|
|
|
Avoid creating gaps between @code{LOAD} segments. The difference
|
|
between the load addresses of two subsequent @code{LOAD} segments should
|
|
be the size of the first @code{LOAD} segment. (This may require linking
|
|
with @option{-Wl,-z,noseparate-code}.)
|
|
|
|
This may not be possible to achieve with the currently available link
|
|
editors.
|
|
|
|
@item
|
|
If the multiple-of-page-size criterion for the @code{GNU_RELRO} region
|
|
cannot be achieved, ensure that the process memory image right before
|
|
the start of the region does not contain executable or writable memory.
|
|
@c https://sourceware.org/pipermail/libc-alpha/2022-May/138638.html
|
|
@end itemize
|
|
|
|
@subsection Checking Binaries
|
|
|
|
In some cases, if the previous recommendations are not followed, this
|
|
can be determined from the produced binaries. This section contains
|
|
suggestions for verifying aspects of these binaries.
|
|
|
|
@itemize @bullet
|
|
@item
|
|
To detect underlinking, examine the dynamic symbol table, for example
|
|
using @samp{readelf -sDW}. If the symbol is defined in a shared object
|
|
that uses symbol versioning, it must carry a symbol version, as in
|
|
@samp{pthread_kill@@GLIBC_2.34}.
|
|
|
|
@item
|
|
Examine the dynamic segment with @samp{readelf -dW} to check that all
|
|
the required @code{NEEDED} entries are present. (It is not necessary to
|
|
list indirect dependencies if these dependencies are guaranteed to
|
|
remain during the evolution of the explicitly listed direct
|
|
dependencies.)
|
|
|
|
@item
|
|
The @code{NEEDED} entries should not contain full path names including
|
|
slashes, only @code{sonames}.
|
|
|
|
@item
|
|
For a further consistency check, collect all shared objects referenced
|
|
via @code{NEEDED} entries in dynamic segments, transitively, starting at
|
|
the main program. Then determine their dynamic symbol tables (using
|
|
@samp{readelf -sDW}, for example). Ideally, every symbol should be
|
|
defined at most once, so that symbol interposition does not happen.
|
|
|
|
If there are interposed data symbols, check if the single interposing
|
|
definition is in the main program. In this case, there must be a copy
|
|
relocation for it. (This only applies to targets with copy relocations.)
|
|
|
|
Function symbols should only be interposed in C++ applications, to
|
|
implement vague linkage. (See the discussion in the C++ recommendations
|
|
above.)
|
|
|
|
@item
|
|
Using the previously collected @code{NEEDED} entries, check that the
|
|
dependency graph does not contain any cycles.
|
|
|
|
@item
|
|
The dynamic segment should also mention @code{BIND_NOW} on the
|
|
@code{FLAGS} line or @code{NOW} on the @code{FLAGS_1} line (one is
|
|
enough).
|
|
|
|
@item
|
|
Ensure that only static TLS relocations (thread-pointer relative offset
|
|
locations) are used, for example @code{R_AARCH64_TLS_TPREL} and
|
|
@code{X86_64_TPOFF64}. As the second-best option, and only if
|
|
compatibility with non-hardened applications using @code{dlopen} is
|
|
needed, GNU2 TLS descriptor relocations can be used (for example,
|
|
@code{R_AARCH64_TLSDESC} or @code{R_X86_64_TLSDESC}).
|
|
|
|
@item
|
|
There should not be references to the traditional TLS function symbols
|
|
@code{__tls_get_addr}, @code{__tls_get_offset},
|
|
@code{__tls_get_addr_opt} in the dynamic symbol table (in the
|
|
@samp{readelf -sDW} output). Supporting global dynamic TLS relocations
|
|
(such as @code{R_AARCH64_TLS_DTPMOD}, @code{R_AARCH64_TLS_DTPREL},
|
|
@code{R_X86_64_DTPMOD64}, @code{R_X86_64_DTPOFF64}) should not be used,
|
|
either.
|
|
|
|
@item
|
|
Likewise, the functions @code{dlopen}, @code{dlmopen}, @code{dlclose}
|
|
should not be referenced from the dynamic symbol table.
|
|
|
|
@item
|
|
For shared objects, there should be a @code{SONAME} entry that matches
|
|
the file name (the base name, i.e., the part after the slash). The
|
|
@code{SONAME} string must not contain a slash @samp{/}.
|
|
|
|
@item
|
|
For all objects, the dynamic segment (as shown by @samp{readelf -dW})
|
|
should not contain @code{RPATH} or @code{RUNPATH} entries.
|
|
|
|
@item
|
|
Likewise, the dynamic segment should not show any @code{AUDIT},
|
|
@code{DEPAUDIT}, @code{AUXILIARY}, @code{FILTER}, or
|
|
@code{PREINIT_ARRAY} tags.
|
|
|
|
@item
|
|
If the dynamic segment contains a (deprecated) @code{HASH} tag, it
|
|
must also contain a @code{GNU_HASH} tag.
|
|
|
|
@item
|
|
The @code{INITFIRST} flag (undeer @code{FLAGS_1}) should not be used.
|
|
|
|
@item
|
|
The program header must not have @code{LOAD} segments that are writable
|
|
and executable at the same time.
|
|
|
|
@item
|
|
All produced objects should have a @code{GNU_STACK} program header that
|
|
is not marked as executable. (However, on some newer targets, a
|
|
non-executable stack is the default, so the @code{GNU_STACK} program
|
|
header is not required.)
|
|
@end itemize
|
|
|
|
@subsection Run-time Considerations
|
|
|
|
In addition to preparing program binaries in a recommended fashion, the
|
|
run-time environment should be set up in such a way that problematic
|
|
dynamic linker features are not used.
|
|
|
|
@itemize @bullet
|
|
@item
|
|
Install shared objects using their sonames in a default search path
|
|
directory (usually @file{/usr/lib64}). Do not use symbolic links.
|
|
@c This is currently not standard practice.
|
|
|
|
@item
|
|
The default search path must not contain objects with duplicate file
|
|
names or sonames.
|
|
|
|
@item
|
|
Do not use environment variables (@code{LD_@dots{}} variables such as
|
|
@code{LD_PRELOAD} or @code{LD_LIBRARY_PATH}, or @code{GLIBC_TUNABLES})
|
|
to change default dynamic linker behavior.
|
|
|
|
@item
|
|
Do not install shared objects in non-default locations. (Such locations
|
|
are listed explicitly in the configuration file for @command{ldconfig},
|
|
usually @file{/etc/ld.so.conf}, or in files included from there.)
|
|
|
|
@item
|
|
In relation to the previous item, do not install any objects it
|
|
@code{glibc-hwcaps} subdirectories.
|
|
|
|
@item
|
|
Do not configure dynamically-loaded NSS service modules, to avoid
|
|
accidental internal use of the @code{dlopen} facility. The @code{files}
|
|
and @code{dns} modules are built in and do not rely on @code{dlopen}.
|
|
|
|
@item
|
|
Do not truncate and overwrite files containing programs and shared
|
|
objects in place, while they are used. Instead, write the new version
|
|
to a different path and use @code{rename} to replace the
|
|
already-installed version.
|
|
|
|
@item
|
|
Be aware that during a component update procedure that involves multiple
|
|
object files (shared objects and main programs), concurrently starting
|
|
processes may observe an inconsistent combination of object files (some
|
|
already updated, some still at the previous version). For example,
|
|
this can happen during an update of @theglibc{} itself.
|
|
@end itemize
|
|
|
|
@c FIXME these are undocumented:
|
|
@c dladdr
|
|
@c dladdr1
|
|
@c dlclose
|
|
@c dlerror
|
|
@c dlmopen
|
|
@c dlopen
|
|
@c dlsym
|
|
@c dlvsym
|