'\" t .\" Copyright 2012 Michael Kerrisk .\" .\" SPDX-License-Identifier: Linux-man-pages-copyleft .\" .\" See also https://lwn.net/Articles/519085/ .\" .TH getauxval 3 2024-05-02 "Linux man-pages 6.8" .SH NAME getauxval \- retrieve a value from the auxiliary vector .SH LIBRARY Standard C library .RI ( libc ", " \-lc ) .SH SYNOPSIS .nf .B #include .P .BI "unsigned long getauxval(unsigned long " type ); .fi .SH DESCRIPTION The .BR getauxval () function retrieves values from the auxiliary vector, a mechanism that the kernel's ELF binary loader uses to pass certain information to user space when a program is executed. .P Each entry in the auxiliary vector consists of a pair of values: a type that identifies what this entry represents, and a value for that type. Given the argument .IR type , .BR getauxval () returns the corresponding value. .P The value returned for each .I type is given in the following list. Not all .I type values are present on all architectures. .TP .B AT_BASE The base address of the program interpreter (usually, the dynamic linker). .TP .B AT_BASE_PLATFORM A pointer to a string (PowerPC and MIPS only). On PowerPC, this identifies the real platform; may differ from .BR AT_PLATFORM "." On MIPS, .\" commit e585b768da111f2c2d413de6214e83bbdfee8f22 this identifies the ISA level (since Linux 5.7). .TP .B AT_CLKTCK The frequency with which .BR times (2) counts. This value can also be obtained via .IR sysconf(_SC_CLK_TCK) . .TP .B AT_DCACHEBSIZE The data cache block size. .TP .B AT_EGID The effective group ID of the thread. .TP .B AT_ENTRY The entry address of the executable. .TP .B AT_EUID The effective user ID of the thread. .TP .B AT_EXECFD File descriptor of program. .TP .B AT_EXECFN A pointer to a string containing the pathname used to execute the program. .TP .B AT_FLAGS Flags (unused). .TP .B AT_FPUCW Used FPU control word (SuperH architecture only). This gives some information about the FPU initialization performed by the kernel. .TP .B AT_GID The real group ID of the thread. .TP .B AT_HWCAP An architecture and ABI dependent bit-mask whose settings indicate detailed processor capabilities. The contents of the bit mask are hardware dependent (for example, see the kernel source file .I arch/x86/include/asm/cpufeature.h for details relating to the Intel x86 architecture; the value returned is the first 32-bit word of the array described there). A human-readable version of the same information is available via .IR /proc/cpuinfo . .TP .BR AT_HWCAP2 " (since glibc 2.18)" Further machine-dependent hints about processor capabilities. .TP .B AT_ICACHEBSIZE The instruction cache block size. .\" .TP .\" .BR AT_IGNORE .\" .TP .\" .BR AT_IGNOREPPC .\" .TP .\" .BR AT_NOTELF .TP .\" Kernel commit 98a5f361b8625c6f4841d6ba013bbf0e80d08147 .B AT_L1D_CACHEGEOMETRY Geometry of the L1 data cache, encoded with the cache line size in bytes in the bottom 16 bits and the cache associativity in the next 16 bits. The associativity is such that if N is the 16-bit value, the cache is N-way set associative. .TP .B AT_L1D_CACHESIZE The L1 data cache size. .TP .B AT_L1I_CACHEGEOMETRY Geometry of the L1 instruction cache, encoded as for .BR AT_L1D_CACHEGEOMETRY . .TP .B AT_L1I_CACHESIZE The L1 instruction cache size. .TP .B AT_L2_CACHEGEOMETRY Geometry of the L2 cache, encoded as for .BR AT_L1D_CACHEGEOMETRY . .TP .B AT_L2_CACHESIZE The L2 cache size. .TP .B AT_L3_CACHEGEOMETRY Geometry of the L3 cache, encoded as for .BR AT_L1D_CACHEGEOMETRY . .TP .B AT_L3_CACHESIZE The L3 cache size. .TP .B AT_PAGESZ The system page size (the same value returned by .IR sysconf(_SC_PAGESIZE) ). .TP .B AT_PHDR The address of the program headers of the executable. .TP .B AT_PHENT The size of program header entry. .TP .B AT_PHNUM The number of program headers. .TP .B AT_PLATFORM A pointer to a string that identifies the hardware platform that the program is running on. The dynamic linker uses this in the interpretation of .I rpath values. .TP .B AT_RANDOM The address of sixteen bytes containing a random value. .TP .B AT_SECURE Has a nonzero value if this executable should be treated securely. Most commonly, a nonzero value indicates that the process is executing a set-user-ID or set-group-ID binary (so that its real and effective UIDs or GIDs differ from one another), or that it gained capabilities by executing a binary file that has capabilities (see .BR capabilities (7)). Alternatively, a nonzero value may be triggered by a Linux Security Module. When this value is nonzero, the dynamic linker disables the use of certain environment variables (see .BR ld\-linux.so (8)) and glibc changes other aspects of its behavior. (See also .BR secure_getenv (3).) .TP .B AT_SYSINFO The entry point to the system call function in the vDSO. Not present/needed on all architectures (e.g., absent on x86-64). .TP .B AT_SYSINFO_EHDR The address of a page containing the virtual Dynamic Shared Object (vDSO) that the kernel creates in order to provide fast implementations of certain system calls. .TP .B AT_UCACHEBSIZE The unified cache block size. .TP .B AT_UID The real user ID of the thread. .SH RETURN VALUE On success, .BR getauxval () returns the value corresponding to .IR type . If .I type is not found, 0 is returned. .SH ERRORS .TP .BR ENOENT " (since glibc 2.19)" .\" commit b9ab448f980e296eac21ac65f53783967cc6037b No entry corresponding to .I type could be found in the auxiliary vector. .SH ATTRIBUTES For an explanation of the terms used in this section, see .BR attributes (7). .TS allbox; lbx lb lb l l l. Interface Attribute Value T{ .na .nh .BR getauxval () T} Thread safety MT-Safe .TE .SH STANDARDS GNU. .SH HISTORY glibc 2.16. .SH NOTES The primary consumer of the information in the auxiliary vector is the dynamic linker, .BR ld\-linux.so (8). The auxiliary vector is a convenient and efficient shortcut that allows the kernel to communicate a certain set of standard information that the dynamic linker usually or always needs. In some cases, the same information could be obtained by system calls, but using the auxiliary vector is cheaper. .P The auxiliary vector resides just above the argument list and environment in the process address space. The auxiliary vector supplied to a program can be viewed by setting the .B LD_SHOW_AUXV environment variable when running a program: .P .in +4n .EX $ LD_SHOW_AUXV=1 sleep 1 .EE .in .P The auxiliary vector of any process can (subject to file permissions) be obtained via .IR /proc/ pid /auxv ; see .BR proc (5) for more information. .SH BUGS Before the addition of the .B ENOENT error in glibc 2.19, there was no way to unambiguously distinguish the case where .I type could not be found from the case where the value corresponding to .I type was zero. .SH SEE ALSO .BR execve (2), .BR secure_getenv (3), .BR vdso (7), .BR ld\-linux.so (8)