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This is libc.info, produced by makeinfo version 6.5 from libc.texinfo.
This file documents the GNU C Library.
This is The GNU C Library Reference Manual, for version 2.28.
Copyright © 19932018 Free Software Foundation, Inc.
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3 or
any later version published by the Free Software Foundation; with the
Invariant Sections being “Free Software Needs Free Documentation” and
“GNU Lesser General Public License”, the Front-Cover texts being “A GNU
Manual”, and with the Back-Cover Texts as in (a) below. A copy of the
license is included in the section entitled "GNU Free Documentation
License".
(a) The FSFs Back-Cover Text is: “You have the freedom to copy and
modify this GNU manual. Buying copies from the FSF supports it in
developing GNU and promoting software freedom.”
INFO-DIR-SECTION Software libraries
START-INFO-DIR-ENTRY
* Libc: (libc). C library.
END-INFO-DIR-ENTRY
INFO-DIR-SECTION GNU C library functions and macros
START-INFO-DIR-ENTRY
* ALTWERASE: (libc)Local Modes.
* ARGP_ERR_UNKNOWN: (libc)Argp Parser Functions.
* ARG_MAX: (libc)General Limits.
* BC_BASE_MAX: (libc)Utility Limits.
* BC_DIM_MAX: (libc)Utility Limits.
* BC_SCALE_MAX: (libc)Utility Limits.
* BC_STRING_MAX: (libc)Utility Limits.
* BRKINT: (libc)Input Modes.
* BUFSIZ: (libc)Controlling Buffering.
* CCTS_OFLOW: (libc)Control Modes.
* CHAR_BIT: (libc)Width of Type.
* CHILD_MAX: (libc)General Limits.
* CIGNORE: (libc)Control Modes.
* CLK_TCK: (libc)Processor Time.
* CLOCAL: (libc)Control Modes.
* CLOCKS_PER_SEC: (libc)CPU Time.
* COLL_WEIGHTS_MAX: (libc)Utility Limits.
* CPU_CLR: (libc)CPU Affinity.
* CPU_ISSET: (libc)CPU Affinity.
* CPU_SET: (libc)CPU Affinity.
* CPU_SETSIZE: (libc)CPU Affinity.
* CPU_ZERO: (libc)CPU Affinity.
* CREAD: (libc)Control Modes.
* CRTS_IFLOW: (libc)Control Modes.
* CS5: (libc)Control Modes.
* CS6: (libc)Control Modes.
* CS7: (libc)Control Modes.
* CS8: (libc)Control Modes.
* CSIZE: (libc)Control Modes.
* CSTOPB: (libc)Control Modes.
* DTTOIF: (libc)Directory Entries.
* E2BIG: (libc)Error Codes.
* EACCES: (libc)Error Codes.
* EADDRINUSE: (libc)Error Codes.
* EADDRNOTAVAIL: (libc)Error Codes.
* EADV: (libc)Error Codes.
* EAFNOSUPPORT: (libc)Error Codes.
* EAGAIN: (libc)Error Codes.
* EALREADY: (libc)Error Codes.
* EAUTH: (libc)Error Codes.
* EBACKGROUND: (libc)Error Codes.
* EBADE: (libc)Error Codes.
* EBADF: (libc)Error Codes.
* EBADFD: (libc)Error Codes.
* EBADMSG: (libc)Error Codes.
* EBADR: (libc)Error Codes.
* EBADRPC: (libc)Error Codes.
* EBADRQC: (libc)Error Codes.
* EBADSLT: (libc)Error Codes.
* EBFONT: (libc)Error Codes.
* EBUSY: (libc)Error Codes.
* ECANCELED: (libc)Error Codes.
* ECHILD: (libc)Error Codes.
* ECHO: (libc)Local Modes.
* ECHOCTL: (libc)Local Modes.
* ECHOE: (libc)Local Modes.
* ECHOK: (libc)Local Modes.
* ECHOKE: (libc)Local Modes.
* ECHONL: (libc)Local Modes.
* ECHOPRT: (libc)Local Modes.
* ECHRNG: (libc)Error Codes.
* ECOMM: (libc)Error Codes.
* ECONNABORTED: (libc)Error Codes.
* ECONNREFUSED: (libc)Error Codes.
* ECONNRESET: (libc)Error Codes.
* ED: (libc)Error Codes.
* EDEADLK: (libc)Error Codes.
* EDEADLOCK: (libc)Error Codes.
* EDESTADDRREQ: (libc)Error Codes.
* EDIED: (libc)Error Codes.
* EDOM: (libc)Error Codes.
* EDOTDOT: (libc)Error Codes.
* EDQUOT: (libc)Error Codes.
* EEXIST: (libc)Error Codes.
* EFAULT: (libc)Error Codes.
* EFBIG: (libc)Error Codes.
* EFTYPE: (libc)Error Codes.
* EGRATUITOUS: (libc)Error Codes.
* EGREGIOUS: (libc)Error Codes.
* EHOSTDOWN: (libc)Error Codes.
* EHOSTUNREACH: (libc)Error Codes.
* EHWPOISON: (libc)Error Codes.
* EIDRM: (libc)Error Codes.
* EIEIO: (libc)Error Codes.
* EILSEQ: (libc)Error Codes.
* EINPROGRESS: (libc)Error Codes.
* EINTR: (libc)Error Codes.
* EINVAL: (libc)Error Codes.
* EIO: (libc)Error Codes.
* EISCONN: (libc)Error Codes.
* EISDIR: (libc)Error Codes.
* EISNAM: (libc)Error Codes.
* EKEYEXPIRED: (libc)Error Codes.
* EKEYREJECTED: (libc)Error Codes.
* EKEYREVOKED: (libc)Error Codes.
* EL2HLT: (libc)Error Codes.
* EL2NSYNC: (libc)Error Codes.
* EL3HLT: (libc)Error Codes.
* EL3RST: (libc)Error Codes.
* ELIBACC: (libc)Error Codes.
* ELIBBAD: (libc)Error Codes.
* ELIBEXEC: (libc)Error Codes.
* ELIBMAX: (libc)Error Codes.
* ELIBSCN: (libc)Error Codes.
* ELNRNG: (libc)Error Codes.
* ELOOP: (libc)Error Codes.
* EMEDIUMTYPE: (libc)Error Codes.
* EMFILE: (libc)Error Codes.
* EMLINK: (libc)Error Codes.
* EMSGSIZE: (libc)Error Codes.
* EMULTIHOP: (libc)Error Codes.
* ENAMETOOLONG: (libc)Error Codes.
* ENAVAIL: (libc)Error Codes.
* ENEEDAUTH: (libc)Error Codes.
* ENETDOWN: (libc)Error Codes.
* ENETRESET: (libc)Error Codes.
* ENETUNREACH: (libc)Error Codes.
* ENFILE: (libc)Error Codes.
* ENOANO: (libc)Error Codes.
* ENOBUFS: (libc)Error Codes.
* ENOCSI: (libc)Error Codes.
* ENODATA: (libc)Error Codes.
* ENODEV: (libc)Error Codes.
* ENOENT: (libc)Error Codes.
* ENOEXEC: (libc)Error Codes.
* ENOKEY: (libc)Error Codes.
* ENOLCK: (libc)Error Codes.
* ENOLINK: (libc)Error Codes.
* ENOMEDIUM: (libc)Error Codes.
* ENOMEM: (libc)Error Codes.
* ENOMSG: (libc)Error Codes.
* ENONET: (libc)Error Codes.
* ENOPKG: (libc)Error Codes.
* ENOPROTOOPT: (libc)Error Codes.
* ENOSPC: (libc)Error Codes.
* ENOSR: (libc)Error Codes.
* ENOSTR: (libc)Error Codes.
* ENOSYS: (libc)Error Codes.
* ENOTBLK: (libc)Error Codes.
* ENOTCONN: (libc)Error Codes.
* ENOTDIR: (libc)Error Codes.
* ENOTEMPTY: (libc)Error Codes.
* ENOTNAM: (libc)Error Codes.
* ENOTRECOVERABLE: (libc)Error Codes.
* ENOTSOCK: (libc)Error Codes.
* ENOTSUP: (libc)Error Codes.
* ENOTTY: (libc)Error Codes.
* ENOTUNIQ: (libc)Error Codes.
* ENXIO: (libc)Error Codes.
* EOF: (libc)EOF and Errors.
* EOPNOTSUPP: (libc)Error Codes.
* EOVERFLOW: (libc)Error Codes.
* EOWNERDEAD: (libc)Error Codes.
* EPERM: (libc)Error Codes.
* EPFNOSUPPORT: (libc)Error Codes.
* EPIPE: (libc)Error Codes.
* EPROCLIM: (libc)Error Codes.
* EPROCUNAVAIL: (libc)Error Codes.
* EPROGMISMATCH: (libc)Error Codes.
* EPROGUNAVAIL: (libc)Error Codes.
* EPROTO: (libc)Error Codes.
* EPROTONOSUPPORT: (libc)Error Codes.
* EPROTOTYPE: (libc)Error Codes.
* EQUIV_CLASS_MAX: (libc)Utility Limits.
* ERANGE: (libc)Error Codes.
* EREMCHG: (libc)Error Codes.
* EREMOTE: (libc)Error Codes.
* EREMOTEIO: (libc)Error Codes.
* ERESTART: (libc)Error Codes.
* ERFKILL: (libc)Error Codes.
* EROFS: (libc)Error Codes.
* ERPCMISMATCH: (libc)Error Codes.
* ESHUTDOWN: (libc)Error Codes.
* ESOCKTNOSUPPORT: (libc)Error Codes.
* ESPIPE: (libc)Error Codes.
* ESRCH: (libc)Error Codes.
* ESRMNT: (libc)Error Codes.
* ESTALE: (libc)Error Codes.
* ESTRPIPE: (libc)Error Codes.
* ETIME: (libc)Error Codes.
* ETIMEDOUT: (libc)Error Codes.
* ETOOMANYREFS: (libc)Error Codes.
* ETXTBSY: (libc)Error Codes.
* EUCLEAN: (libc)Error Codes.
* EUNATCH: (libc)Error Codes.
* EUSERS: (libc)Error Codes.
* EWOULDBLOCK: (libc)Error Codes.
* EXDEV: (libc)Error Codes.
* EXFULL: (libc)Error Codes.
* EXIT_FAILURE: (libc)Exit Status.
* EXIT_SUCCESS: (libc)Exit Status.
* EXPR_NEST_MAX: (libc)Utility Limits.
* FD_CLOEXEC: (libc)Descriptor Flags.
* FD_CLR: (libc)Waiting for I/O.
* FD_ISSET: (libc)Waiting for I/O.
* FD_SET: (libc)Waiting for I/O.
* FD_SETSIZE: (libc)Waiting for I/O.
* FD_ZERO: (libc)Waiting for I/O.
* FE_SNANS_ALWAYS_SIGNAL: (libc)Infinity and NaN.
* FILENAME_MAX: (libc)Limits for Files.
* FLUSHO: (libc)Local Modes.
* FOPEN_MAX: (libc)Opening Streams.
* FP_ILOGB0: (libc)Exponents and Logarithms.
* FP_ILOGBNAN: (libc)Exponents and Logarithms.
* FP_LLOGB0: (libc)Exponents and Logarithms.
* FP_LLOGBNAN: (libc)Exponents and Logarithms.
* F_DUPFD: (libc)Duplicating Descriptors.
* F_GETFD: (libc)Descriptor Flags.
* F_GETFL: (libc)Getting File Status Flags.
* F_GETLK: (libc)File Locks.
* F_GETOWN: (libc)Interrupt Input.
* F_OFD_GETLK: (libc)Open File Description Locks.
* F_OFD_SETLK: (libc)Open File Description Locks.
* F_OFD_SETLKW: (libc)Open File Description Locks.
* F_OK: (libc)Testing File Access.
* F_SETFD: (libc)Descriptor Flags.
* F_SETFL: (libc)Getting File Status Flags.
* F_SETLK: (libc)File Locks.
* F_SETLKW: (libc)File Locks.
* F_SETOWN: (libc)Interrupt Input.
* HUGE_VAL: (libc)Math Error Reporting.
* HUGE_VALF: (libc)Math Error Reporting.
* HUGE_VALL: (libc)Math Error Reporting.
* HUGE_VAL_FN: (libc)Math Error Reporting.
* HUGE_VAL_FNx: (libc)Math Error Reporting.
* HUPCL: (libc)Control Modes.
* I: (libc)Complex Numbers.
* ICANON: (libc)Local Modes.
* ICRNL: (libc)Input Modes.
* IEXTEN: (libc)Local Modes.
* IFNAMSIZ: (libc)Interface Naming.
* IFTODT: (libc)Directory Entries.
* IGNBRK: (libc)Input Modes.
* IGNCR: (libc)Input Modes.
* IGNPAR: (libc)Input Modes.
* IMAXBEL: (libc)Input Modes.
* INADDR_ANY: (libc)Host Address Data Type.
* INADDR_BROADCAST: (libc)Host Address Data Type.
* INADDR_LOOPBACK: (libc)Host Address Data Type.
* INADDR_NONE: (libc)Host Address Data Type.
* INFINITY: (libc)Infinity and NaN.
* INLCR: (libc)Input Modes.
* INPCK: (libc)Input Modes.
* IPPORT_RESERVED: (libc)Ports.
* IPPORT_USERRESERVED: (libc)Ports.
* ISIG: (libc)Local Modes.
* ISTRIP: (libc)Input Modes.
* IXANY: (libc)Input Modes.
* IXOFF: (libc)Input Modes.
* IXON: (libc)Input Modes.
* LINE_MAX: (libc)Utility Limits.
* LINK_MAX: (libc)Limits for Files.
* L_ctermid: (libc)Identifying the Terminal.
* L_cuserid: (libc)Who Logged In.
* L_tmpnam: (libc)Temporary Files.
* MAXNAMLEN: (libc)Limits for Files.
* MAXSYMLINKS: (libc)Symbolic Links.
* MAX_CANON: (libc)Limits for Files.
* MAX_INPUT: (libc)Limits for Files.
* MB_CUR_MAX: (libc)Selecting the Conversion.
* MB_LEN_MAX: (libc)Selecting the Conversion.
* MDMBUF: (libc)Control Modes.
* MSG_DONTROUTE: (libc)Socket Data Options.
* MSG_OOB: (libc)Socket Data Options.
* MSG_PEEK: (libc)Socket Data Options.
* NAME_MAX: (libc)Limits for Files.
* NAN: (libc)Infinity and NaN.
* NCCS: (libc)Mode Data Types.
* NGROUPS_MAX: (libc)General Limits.
* NOFLSH: (libc)Local Modes.
* NOKERNINFO: (libc)Local Modes.
* NSIG: (libc)Standard Signals.
* NULL: (libc)Null Pointer Constant.
* ONLCR: (libc)Output Modes.
* ONOEOT: (libc)Output Modes.
* OPEN_MAX: (libc)General Limits.
* OPOST: (libc)Output Modes.
* OXTABS: (libc)Output Modes.
* O_ACCMODE: (libc)Access Modes.
* O_APPEND: (libc)Operating Modes.
* O_ASYNC: (libc)Operating Modes.
* O_CREAT: (libc)Open-time Flags.
* O_EXCL: (libc)Open-time Flags.
* O_EXEC: (libc)Access Modes.
* O_EXLOCK: (libc)Open-time Flags.
* O_FSYNC: (libc)Operating Modes.
* O_IGNORE_CTTY: (libc)Open-time Flags.
* O_NDELAY: (libc)Operating Modes.
* O_NOATIME: (libc)Operating Modes.
* O_NOCTTY: (libc)Open-time Flags.
* O_NOLINK: (libc)Open-time Flags.
* O_NONBLOCK: (libc)Open-time Flags.
* O_NONBLOCK: (libc)Operating Modes.
* O_NOTRANS: (libc)Open-time Flags.
* O_RDONLY: (libc)Access Modes.
* O_RDWR: (libc)Access Modes.
* O_READ: (libc)Access Modes.
* O_SHLOCK: (libc)Open-time Flags.
* O_SYNC: (libc)Operating Modes.
* O_TMPFILE: (libc)Open-time Flags.
* O_TRUNC: (libc)Open-time Flags.
* O_WRITE: (libc)Access Modes.
* O_WRONLY: (libc)Access Modes.
* PARENB: (libc)Control Modes.
* PARMRK: (libc)Input Modes.
* PARODD: (libc)Control Modes.
* PATH_MAX: (libc)Limits for Files.
* PA_FLAG_MASK: (libc)Parsing a Template String.
* PENDIN: (libc)Local Modes.
* PF_FILE: (libc)Local Namespace Details.
* PF_INET6: (libc)Internet Namespace.
* PF_INET: (libc)Internet Namespace.
* PF_LOCAL: (libc)Local Namespace Details.
* PF_UNIX: (libc)Local Namespace Details.
* PIPE_BUF: (libc)Limits for Files.
* P_tmpdir: (libc)Temporary Files.
* RAND_MAX: (libc)ISO Random.
* RE_DUP_MAX: (libc)General Limits.
* RLIM_INFINITY: (libc)Limits on Resources.
* R_OK: (libc)Testing File Access.
* SA_NOCLDSTOP: (libc)Flags for Sigaction.
* SA_ONSTACK: (libc)Flags for Sigaction.
* SA_RESTART: (libc)Flags for Sigaction.
* SEEK_CUR: (libc)File Positioning.
* SEEK_END: (libc)File Positioning.
* SEEK_SET: (libc)File Positioning.
* SIGABRT: (libc)Program Error Signals.
* SIGALRM: (libc)Alarm Signals.
* SIGBUS: (libc)Program Error Signals.
* SIGCHLD: (libc)Job Control Signals.
* SIGCLD: (libc)Job Control Signals.
* SIGCONT: (libc)Job Control Signals.
* SIGEMT: (libc)Program Error Signals.
* SIGFPE: (libc)Program Error Signals.
* SIGHUP: (libc)Termination Signals.
* SIGILL: (libc)Program Error Signals.
* SIGINFO: (libc)Miscellaneous Signals.
* SIGINT: (libc)Termination Signals.
* SIGIO: (libc)Asynchronous I/O Signals.
* SIGIOT: (libc)Program Error Signals.
* SIGKILL: (libc)Termination Signals.
* SIGLOST: (libc)Operation Error Signals.
* SIGPIPE: (libc)Operation Error Signals.
* SIGPOLL: (libc)Asynchronous I/O Signals.
* SIGPROF: (libc)Alarm Signals.
* SIGQUIT: (libc)Termination Signals.
* SIGSEGV: (libc)Program Error Signals.
* SIGSTOP: (libc)Job Control Signals.
* SIGSYS: (libc)Program Error Signals.
* SIGTERM: (libc)Termination Signals.
* SIGTRAP: (libc)Program Error Signals.
* SIGTSTP: (libc)Job Control Signals.
* SIGTTIN: (libc)Job Control Signals.
* SIGTTOU: (libc)Job Control Signals.
* SIGURG: (libc)Asynchronous I/O Signals.
* SIGUSR1: (libc)Miscellaneous Signals.
* SIGUSR2: (libc)Miscellaneous Signals.
* SIGVTALRM: (libc)Alarm Signals.
* SIGWINCH: (libc)Miscellaneous Signals.
* SIGXCPU: (libc)Operation Error Signals.
* SIGXFSZ: (libc)Operation Error Signals.
* SIG_ERR: (libc)Basic Signal Handling.
* SNAN: (libc)Infinity and NaN.
* SNANF: (libc)Infinity and NaN.
* SNANFN: (libc)Infinity and NaN.
* SNANFNx: (libc)Infinity and NaN.
* SNANL: (libc)Infinity and NaN.
* SOCK_DGRAM: (libc)Communication Styles.
* SOCK_RAW: (libc)Communication Styles.
* SOCK_RDM: (libc)Communication Styles.
* SOCK_SEQPACKET: (libc)Communication Styles.
* SOCK_STREAM: (libc)Communication Styles.
* SOL_SOCKET: (libc)Socket-Level Options.
* SSIZE_MAX: (libc)General Limits.
* STREAM_MAX: (libc)General Limits.
* SUN_LEN: (libc)Local Namespace Details.
* S_IFMT: (libc)Testing File Type.
* S_ISBLK: (libc)Testing File Type.
* S_ISCHR: (libc)Testing File Type.
* S_ISDIR: (libc)Testing File Type.
* S_ISFIFO: (libc)Testing File Type.
* S_ISLNK: (libc)Testing File Type.
* S_ISREG: (libc)Testing File Type.
* S_ISSOCK: (libc)Testing File Type.
* S_TYPEISMQ: (libc)Testing File Type.
* S_TYPEISSEM: (libc)Testing File Type.
* S_TYPEISSHM: (libc)Testing File Type.
* TMP_MAX: (libc)Temporary Files.
* TOSTOP: (libc)Local Modes.
* TZNAME_MAX: (libc)General Limits.
* VDISCARD: (libc)Other Special.
* VDSUSP: (libc)Signal Characters.
* VEOF: (libc)Editing Characters.
* VEOL2: (libc)Editing Characters.
* VEOL: (libc)Editing Characters.
* VERASE: (libc)Editing Characters.
* VINTR: (libc)Signal Characters.
* VKILL: (libc)Editing Characters.
* VLNEXT: (libc)Other Special.
* VMIN: (libc)Noncanonical Input.
* VQUIT: (libc)Signal Characters.
* VREPRINT: (libc)Editing Characters.
* VSTART: (libc)Start/Stop Characters.
* VSTATUS: (libc)Other Special.
* VSTOP: (libc)Start/Stop Characters.
* VSUSP: (libc)Signal Characters.
* VTIME: (libc)Noncanonical Input.
* VWERASE: (libc)Editing Characters.
* WCHAR_MAX: (libc)Extended Char Intro.
* WCHAR_MIN: (libc)Extended Char Intro.
* WCOREDUMP: (libc)Process Completion Status.
* WEOF: (libc)EOF and Errors.
* WEOF: (libc)Extended Char Intro.
* WEXITSTATUS: (libc)Process Completion Status.
* WIFEXITED: (libc)Process Completion Status.
* WIFSIGNALED: (libc)Process Completion Status.
* WIFSTOPPED: (libc)Process Completion Status.
* WSTOPSIG: (libc)Process Completion Status.
* WTERMSIG: (libc)Process Completion Status.
* W_OK: (libc)Testing File Access.
* X_OK: (libc)Testing File Access.
* _Complex_I: (libc)Complex Numbers.
* _Exit: (libc)Termination Internals.
* _IOFBF: (libc)Controlling Buffering.
* _IOLBF: (libc)Controlling Buffering.
* _IONBF: (libc)Controlling Buffering.
* _Imaginary_I: (libc)Complex Numbers.
* _PATH_UTMP: (libc)Manipulating the Database.
* _PATH_WTMP: (libc)Manipulating the Database.
* _POSIX2_C_DEV: (libc)System Options.
* _POSIX2_C_VERSION: (libc)Version Supported.
* _POSIX2_FORT_DEV: (libc)System Options.
* _POSIX2_FORT_RUN: (libc)System Options.
* _POSIX2_LOCALEDEF: (libc)System Options.
* _POSIX2_SW_DEV: (libc)System Options.
* _POSIX_CHOWN_RESTRICTED: (libc)Options for Files.
* _POSIX_JOB_CONTROL: (libc)System Options.
* _POSIX_NO_TRUNC: (libc)Options for Files.
* _POSIX_SAVED_IDS: (libc)System Options.
* _POSIX_VDISABLE: (libc)Options for Files.
* _POSIX_VERSION: (libc)Version Supported.
* __fbufsize: (libc)Controlling Buffering.
* __flbf: (libc)Controlling Buffering.
* __fpending: (libc)Controlling Buffering.
* __fpurge: (libc)Flushing Buffers.
* __freadable: (libc)Opening Streams.
* __freading: (libc)Opening Streams.
* __fsetlocking: (libc)Streams and Threads.
* __fwritable: (libc)Opening Streams.
* __fwriting: (libc)Opening Streams.
* __gconv_end_fct: (libc)glibc iconv Implementation.
* __gconv_fct: (libc)glibc iconv Implementation.
* __gconv_init_fct: (libc)glibc iconv Implementation.
* __ppc_get_timebase: (libc)PowerPC.
* __ppc_get_timebase_freq: (libc)PowerPC.
* __ppc_mdoio: (libc)PowerPC.
* __ppc_mdoom: (libc)PowerPC.
* __ppc_set_ppr_low: (libc)PowerPC.
* __ppc_set_ppr_med: (libc)PowerPC.
* __ppc_set_ppr_med_high: (libc)PowerPC.
* __ppc_set_ppr_med_low: (libc)PowerPC.
* __ppc_set_ppr_very_low: (libc)PowerPC.
* __ppc_yield: (libc)PowerPC.
* __riscv_flush_icache: (libc)RISC-V.
* __va_copy: (libc)Argument Macros.
* _exit: (libc)Termination Internals.
* _flushlbf: (libc)Flushing Buffers.
* _tolower: (libc)Case Conversion.
* _toupper: (libc)Case Conversion.
* a64l: (libc)Encode Binary Data.
* abort: (libc)Aborting a Program.
* abs: (libc)Absolute Value.
* accept: (libc)Accepting Connections.
* access: (libc)Testing File Access.
* acos: (libc)Inverse Trig Functions.
* acosf: (libc)Inverse Trig Functions.
* acosfN: (libc)Inverse Trig Functions.
* acosfNx: (libc)Inverse Trig Functions.
* acosh: (libc)Hyperbolic Functions.
* acoshf: (libc)Hyperbolic Functions.
* acoshfN: (libc)Hyperbolic Functions.
* acoshfNx: (libc)Hyperbolic Functions.
* acoshl: (libc)Hyperbolic Functions.
* acosl: (libc)Inverse Trig Functions.
* addmntent: (libc)mtab.
* addseverity: (libc)Adding Severity Classes.
* adjtime: (libc)High-Resolution Calendar.
* adjtimex: (libc)High-Resolution Calendar.
* aio_cancel64: (libc)Cancel AIO Operations.
* aio_cancel: (libc)Cancel AIO Operations.
* aio_error64: (libc)Status of AIO Operations.
* aio_error: (libc)Status of AIO Operations.
* aio_fsync64: (libc)Synchronizing AIO Operations.
* aio_fsync: (libc)Synchronizing AIO Operations.
* aio_init: (libc)Configuration of AIO.
* aio_read64: (libc)Asynchronous Reads/Writes.
* aio_read: (libc)Asynchronous Reads/Writes.
* aio_return64: (libc)Status of AIO Operations.
* aio_return: (libc)Status of AIO Operations.
* aio_suspend64: (libc)Synchronizing AIO Operations.
* aio_suspend: (libc)Synchronizing AIO Operations.
* aio_write64: (libc)Asynchronous Reads/Writes.
* aio_write: (libc)Asynchronous Reads/Writes.
* alarm: (libc)Setting an Alarm.
* aligned_alloc: (libc)Aligned Memory Blocks.
* alloca: (libc)Variable Size Automatic.
* alphasort64: (libc)Scanning Directory Content.
* alphasort: (libc)Scanning Directory Content.
* argp_error: (libc)Argp Helper Functions.
* argp_failure: (libc)Argp Helper Functions.
* argp_help: (libc)Argp Help.
* argp_parse: (libc)Argp.
* argp_state_help: (libc)Argp Helper Functions.
* argp_usage: (libc)Argp Helper Functions.
* argz_add: (libc)Argz Functions.
* argz_add_sep: (libc)Argz Functions.
* argz_append: (libc)Argz Functions.
* argz_count: (libc)Argz Functions.
* argz_create: (libc)Argz Functions.
* argz_create_sep: (libc)Argz Functions.
* argz_delete: (libc)Argz Functions.
* argz_extract: (libc)Argz Functions.
* argz_insert: (libc)Argz Functions.
* argz_next: (libc)Argz Functions.
* argz_replace: (libc)Argz Functions.
* argz_stringify: (libc)Argz Functions.
* asctime: (libc)Formatting Calendar Time.
* asctime_r: (libc)Formatting Calendar Time.
* asin: (libc)Inverse Trig Functions.
* asinf: (libc)Inverse Trig Functions.
* asinfN: (libc)Inverse Trig Functions.
* asinfNx: (libc)Inverse Trig Functions.
* asinh: (libc)Hyperbolic Functions.
* asinhf: (libc)Hyperbolic Functions.
* asinhfN: (libc)Hyperbolic Functions.
* asinhfNx: (libc)Hyperbolic Functions.
* asinhl: (libc)Hyperbolic Functions.
* asinl: (libc)Inverse Trig Functions.
* asprintf: (libc)Dynamic Output.
* assert: (libc)Consistency Checking.
* assert_perror: (libc)Consistency Checking.
* atan2: (libc)Inverse Trig Functions.
* atan2f: (libc)Inverse Trig Functions.
* atan2fN: (libc)Inverse Trig Functions.
* atan2fNx: (libc)Inverse Trig Functions.
* atan2l: (libc)Inverse Trig Functions.
* atan: (libc)Inverse Trig Functions.
* atanf: (libc)Inverse Trig Functions.
* atanfN: (libc)Inverse Trig Functions.
* atanfNx: (libc)Inverse Trig Functions.
* atanh: (libc)Hyperbolic Functions.
* atanhf: (libc)Hyperbolic Functions.
* atanhfN: (libc)Hyperbolic Functions.
* atanhfNx: (libc)Hyperbolic Functions.
* atanhl: (libc)Hyperbolic Functions.
* atanl: (libc)Inverse Trig Functions.
* atexit: (libc)Cleanups on Exit.
* atof: (libc)Parsing of Floats.
* atoi: (libc)Parsing of Integers.
* atol: (libc)Parsing of Integers.
* atoll: (libc)Parsing of Integers.
* backtrace: (libc)Backtraces.
* backtrace_symbols: (libc)Backtraces.
* backtrace_symbols_fd: (libc)Backtraces.
* basename: (libc)Finding Tokens in a String.
* basename: (libc)Finding Tokens in a String.
* bcmp: (libc)String/Array Comparison.
* bcopy: (libc)Copying Strings and Arrays.
* bind: (libc)Setting Address.
* bind_textdomain_codeset: (libc)Charset conversion in gettext.
* bindtextdomain: (libc)Locating gettext catalog.
* brk: (libc)Resizing the Data Segment.
* bsearch: (libc)Array Search Function.
* btowc: (libc)Converting a Character.
* bzero: (libc)Copying Strings and Arrays.
* cabs: (libc)Absolute Value.
* cabsf: (libc)Absolute Value.
* cabsfN: (libc)Absolute Value.
* cabsfNx: (libc)Absolute Value.
* cabsl: (libc)Absolute Value.
* cacos: (libc)Inverse Trig Functions.
* cacosf: (libc)Inverse Trig Functions.
* cacosfN: (libc)Inverse Trig Functions.
* cacosfNx: (libc)Inverse Trig Functions.
* cacosh: (libc)Hyperbolic Functions.
* cacoshf: (libc)Hyperbolic Functions.
* cacoshfN: (libc)Hyperbolic Functions.
* cacoshfNx: (libc)Hyperbolic Functions.
* cacoshl: (libc)Hyperbolic Functions.
* cacosl: (libc)Inverse Trig Functions.
* call_once: (libc)Call Once.
* calloc: (libc)Allocating Cleared Space.
* canonicalize: (libc)FP Bit Twiddling.
* canonicalize_file_name: (libc)Symbolic Links.
* canonicalizef: (libc)FP Bit Twiddling.
* canonicalizefN: (libc)FP Bit Twiddling.
* canonicalizefNx: (libc)FP Bit Twiddling.
* canonicalizel: (libc)FP Bit Twiddling.
* carg: (libc)Operations on Complex.
* cargf: (libc)Operations on Complex.
* cargfN: (libc)Operations on Complex.
* cargfNx: (libc)Operations on Complex.
* cargl: (libc)Operations on Complex.
* casin: (libc)Inverse Trig Functions.
* casinf: (libc)Inverse Trig Functions.
* casinfN: (libc)Inverse Trig Functions.
* casinfNx: (libc)Inverse Trig Functions.
* casinh: (libc)Hyperbolic Functions.
* casinhf: (libc)Hyperbolic Functions.
* casinhfN: (libc)Hyperbolic Functions.
* casinhfNx: (libc)Hyperbolic Functions.
* casinhl: (libc)Hyperbolic Functions.
* casinl: (libc)Inverse Trig Functions.
* catan: (libc)Inverse Trig Functions.
* catanf: (libc)Inverse Trig Functions.
* catanfN: (libc)Inverse Trig Functions.
* catanfNx: (libc)Inverse Trig Functions.
* catanh: (libc)Hyperbolic Functions.
* catanhf: (libc)Hyperbolic Functions.
* catanhfN: (libc)Hyperbolic Functions.
* catanhfNx: (libc)Hyperbolic Functions.
* catanhl: (libc)Hyperbolic Functions.
* catanl: (libc)Inverse Trig Functions.
* catclose: (libc)The catgets Functions.
* catgets: (libc)The catgets Functions.
* catopen: (libc)The catgets Functions.
* cbrt: (libc)Exponents and Logarithms.
* cbrtf: (libc)Exponents and Logarithms.
* cbrtfN: (libc)Exponents and Logarithms.
* cbrtfNx: (libc)Exponents and Logarithms.
* cbrtl: (libc)Exponents and Logarithms.
* ccos: (libc)Trig Functions.
* ccosf: (libc)Trig Functions.
* ccosfN: (libc)Trig Functions.
* ccosfNx: (libc)Trig Functions.
* ccosh: (libc)Hyperbolic Functions.
* ccoshf: (libc)Hyperbolic Functions.
* ccoshfN: (libc)Hyperbolic Functions.
* ccoshfNx: (libc)Hyperbolic Functions.
* ccoshl: (libc)Hyperbolic Functions.
* ccosl: (libc)Trig Functions.
* ceil: (libc)Rounding Functions.
* ceilf: (libc)Rounding Functions.
* ceilfN: (libc)Rounding Functions.
* ceilfNx: (libc)Rounding Functions.
* ceill: (libc)Rounding Functions.
* cexp: (libc)Exponents and Logarithms.
* cexpf: (libc)Exponents and Logarithms.
* cexpfN: (libc)Exponents and Logarithms.
* cexpfNx: (libc)Exponents and Logarithms.
* cexpl: (libc)Exponents and Logarithms.
* cfgetispeed: (libc)Line Speed.
* cfgetospeed: (libc)Line Speed.
* cfmakeraw: (libc)Noncanonical Input.
* cfsetispeed: (libc)Line Speed.
* cfsetospeed: (libc)Line Speed.
* cfsetspeed: (libc)Line Speed.
* chdir: (libc)Working Directory.
* chmod: (libc)Setting Permissions.
* chown: (libc)File Owner.
* cimag: (libc)Operations on Complex.
* cimagf: (libc)Operations on Complex.
* cimagfN: (libc)Operations on Complex.
* cimagfNx: (libc)Operations on Complex.
* cimagl: (libc)Operations on Complex.
* clearenv: (libc)Environment Access.
* clearerr: (libc)Error Recovery.
* clearerr_unlocked: (libc)Error Recovery.
* clock: (libc)CPU Time.
* clog10: (libc)Exponents and Logarithms.
* clog10f: (libc)Exponents and Logarithms.
* clog10fN: (libc)Exponents and Logarithms.
* clog10fNx: (libc)Exponents and Logarithms.
* clog10l: (libc)Exponents and Logarithms.
* clog: (libc)Exponents and Logarithms.
* clogf: (libc)Exponents and Logarithms.
* clogfN: (libc)Exponents and Logarithms.
* clogfNx: (libc)Exponents and Logarithms.
* clogl: (libc)Exponents and Logarithms.
* close: (libc)Opening and Closing Files.
* closedir: (libc)Reading/Closing Directory.
* closelog: (libc)closelog.
* cnd_broadcast: (libc)ISO C Condition Variables.
* cnd_destroy: (libc)ISO C Condition Variables.
* cnd_init: (libc)ISO C Condition Variables.
* cnd_signal: (libc)ISO C Condition Variables.
* cnd_timedwait: (libc)ISO C Condition Variables.
* cnd_wait: (libc)ISO C Condition Variables.
* confstr: (libc)String Parameters.
* conj: (libc)Operations on Complex.
* conjf: (libc)Operations on Complex.
* conjfN: (libc)Operations on Complex.
* conjfNx: (libc)Operations on Complex.
* conjl: (libc)Operations on Complex.
* connect: (libc)Connecting.
* copy_file_range: (libc)Copying File Data.
* copysign: (libc)FP Bit Twiddling.
* copysignf: (libc)FP Bit Twiddling.
* copysignfN: (libc)FP Bit Twiddling.
* copysignfNx: (libc)FP Bit Twiddling.
* copysignl: (libc)FP Bit Twiddling.
* cos: (libc)Trig Functions.
* cosf: (libc)Trig Functions.
* cosfN: (libc)Trig Functions.
* cosfNx: (libc)Trig Functions.
* cosh: (libc)Hyperbolic Functions.
* coshf: (libc)Hyperbolic Functions.
* coshfN: (libc)Hyperbolic Functions.
* coshfNx: (libc)Hyperbolic Functions.
* coshl: (libc)Hyperbolic Functions.
* cosl: (libc)Trig Functions.
* cpow: (libc)Exponents and Logarithms.
* cpowf: (libc)Exponents and Logarithms.
* cpowfN: (libc)Exponents and Logarithms.
* cpowfNx: (libc)Exponents and Logarithms.
* cpowl: (libc)Exponents and Logarithms.
* cproj: (libc)Operations on Complex.
* cprojf: (libc)Operations on Complex.
* cprojfN: (libc)Operations on Complex.
* cprojfNx: (libc)Operations on Complex.
* cprojl: (libc)Operations on Complex.
* creal: (libc)Operations on Complex.
* crealf: (libc)Operations on Complex.
* crealfN: (libc)Operations on Complex.
* crealfNx: (libc)Operations on Complex.
* creall: (libc)Operations on Complex.
* creat64: (libc)Opening and Closing Files.
* creat: (libc)Opening and Closing Files.
* crypt: (libc)Passphrase Storage.
* crypt_r: (libc)Passphrase Storage.
* csin: (libc)Trig Functions.
* csinf: (libc)Trig Functions.
* csinfN: (libc)Trig Functions.
* csinfNx: (libc)Trig Functions.
* csinh: (libc)Hyperbolic Functions.
* csinhf: (libc)Hyperbolic Functions.
* csinhfN: (libc)Hyperbolic Functions.
* csinhfNx: (libc)Hyperbolic Functions.
* csinhl: (libc)Hyperbolic Functions.
* csinl: (libc)Trig Functions.
* csqrt: (libc)Exponents and Logarithms.
* csqrtf: (libc)Exponents and Logarithms.
* csqrtfN: (libc)Exponents and Logarithms.
* csqrtfNx: (libc)Exponents and Logarithms.
* csqrtl: (libc)Exponents and Logarithms.
* ctan: (libc)Trig Functions.
* ctanf: (libc)Trig Functions.
* ctanfN: (libc)Trig Functions.
* ctanfNx: (libc)Trig Functions.
* ctanh: (libc)Hyperbolic Functions.
* ctanhf: (libc)Hyperbolic Functions.
* ctanhfN: (libc)Hyperbolic Functions.
* ctanhfNx: (libc)Hyperbolic Functions.
* ctanhl: (libc)Hyperbolic Functions.
* ctanl: (libc)Trig Functions.
* ctermid: (libc)Identifying the Terminal.
* ctime: (libc)Formatting Calendar Time.
* ctime_r: (libc)Formatting Calendar Time.
* cuserid: (libc)Who Logged In.
* daddl: (libc)Misc FP Arithmetic.
* dcgettext: (libc)Translation with gettext.
* dcngettext: (libc)Advanced gettext functions.
* ddivl: (libc)Misc FP Arithmetic.
* dgettext: (libc)Translation with gettext.
* difftime: (libc)Elapsed Time.
* dirfd: (libc)Opening a Directory.
* dirname: (libc)Finding Tokens in a String.
* div: (libc)Integer Division.
* dmull: (libc)Misc FP Arithmetic.
* dngettext: (libc)Advanced gettext functions.
* drand48: (libc)SVID Random.
* drand48_r: (libc)SVID Random.
* drem: (libc)Remainder Functions.
* dremf: (libc)Remainder Functions.
* dreml: (libc)Remainder Functions.
* dsubl: (libc)Misc FP Arithmetic.
* dup2: (libc)Duplicating Descriptors.
* dup: (libc)Duplicating Descriptors.
* ecvt: (libc)System V Number Conversion.
* ecvt_r: (libc)System V Number Conversion.
* endfsent: (libc)fstab.
* endgrent: (libc)Scanning All Groups.
* endhostent: (libc)Host Names.
* endmntent: (libc)mtab.
* endnetent: (libc)Networks Database.
* endnetgrent: (libc)Lookup Netgroup.
* endprotoent: (libc)Protocols Database.
* endpwent: (libc)Scanning All Users.
* endservent: (libc)Services Database.
* endutent: (libc)Manipulating the Database.
* endutxent: (libc)XPG Functions.
* envz_add: (libc)Envz Functions.
* envz_entry: (libc)Envz Functions.
* envz_get: (libc)Envz Functions.
* envz_merge: (libc)Envz Functions.
* envz_remove: (libc)Envz Functions.
* envz_strip: (libc)Envz Functions.
* erand48: (libc)SVID Random.
* erand48_r: (libc)SVID Random.
* erf: (libc)Special Functions.
* erfc: (libc)Special Functions.
* erfcf: (libc)Special Functions.
* erfcfN: (libc)Special Functions.
* erfcfNx: (libc)Special Functions.
* erfcl: (libc)Special Functions.
* erff: (libc)Special Functions.
* erffN: (libc)Special Functions.
* erffNx: (libc)Special Functions.
* erfl: (libc)Special Functions.
* err: (libc)Error Messages.
* errno: (libc)Checking for Errors.
* error: (libc)Error Messages.
* error_at_line: (libc)Error Messages.
* errx: (libc)Error Messages.
* execl: (libc)Executing a File.
* execle: (libc)Executing a File.
* execlp: (libc)Executing a File.
* execv: (libc)Executing a File.
* execve: (libc)Executing a File.
* execvp: (libc)Executing a File.
* exit: (libc)Normal Termination.
* exp10: (libc)Exponents and Logarithms.
* exp10f: (libc)Exponents and Logarithms.
* exp10fN: (libc)Exponents and Logarithms.
* exp10fNx: (libc)Exponents and Logarithms.
* exp10l: (libc)Exponents and Logarithms.
* exp2: (libc)Exponents and Logarithms.
* exp2f: (libc)Exponents and Logarithms.
* exp2fN: (libc)Exponents and Logarithms.
* exp2fNx: (libc)Exponents and Logarithms.
* exp2l: (libc)Exponents and Logarithms.
* exp: (libc)Exponents and Logarithms.
* expf: (libc)Exponents and Logarithms.
* expfN: (libc)Exponents and Logarithms.
* expfNx: (libc)Exponents and Logarithms.
* expl: (libc)Exponents and Logarithms.
* explicit_bzero: (libc)Erasing Sensitive Data.
* expm1: (libc)Exponents and Logarithms.
* expm1f: (libc)Exponents and Logarithms.
* expm1fN: (libc)Exponents and Logarithms.
* expm1fNx: (libc)Exponents and Logarithms.
* expm1l: (libc)Exponents and Logarithms.
* fMaddfN: (libc)Misc FP Arithmetic.
* fMaddfNx: (libc)Misc FP Arithmetic.
* fMdivfN: (libc)Misc FP Arithmetic.
* fMdivfNx: (libc)Misc FP Arithmetic.
* fMmulfN: (libc)Misc FP Arithmetic.
* fMmulfNx: (libc)Misc FP Arithmetic.
* fMsubfN: (libc)Misc FP Arithmetic.
* fMsubfNx: (libc)Misc FP Arithmetic.
* fMxaddfN: (libc)Misc FP Arithmetic.
* fMxaddfNx: (libc)Misc FP Arithmetic.
* fMxdivfN: (libc)Misc FP Arithmetic.
* fMxdivfNx: (libc)Misc FP Arithmetic.
* fMxmulfN: (libc)Misc FP Arithmetic.
* fMxmulfNx: (libc)Misc FP Arithmetic.
* fMxsubfN: (libc)Misc FP Arithmetic.
* fMxsubfNx: (libc)Misc FP Arithmetic.
* fabs: (libc)Absolute Value.
* fabsf: (libc)Absolute Value.
* fabsfN: (libc)Absolute Value.
* fabsfNx: (libc)Absolute Value.
* fabsl: (libc)Absolute Value.
* fadd: (libc)Misc FP Arithmetic.
* faddl: (libc)Misc FP Arithmetic.
* fchdir: (libc)Working Directory.
* fchmod: (libc)Setting Permissions.
* fchown: (libc)File Owner.
* fclose: (libc)Closing Streams.
* fcloseall: (libc)Closing Streams.
* fcntl: (libc)Control Operations.
* fcvt: (libc)System V Number Conversion.
* fcvt_r: (libc)System V Number Conversion.
* fdatasync: (libc)Synchronizing I/O.
* fdim: (libc)Misc FP Arithmetic.
* fdimf: (libc)Misc FP Arithmetic.
* fdimfN: (libc)Misc FP Arithmetic.
* fdimfNx: (libc)Misc FP Arithmetic.
* fdiml: (libc)Misc FP Arithmetic.
* fdiv: (libc)Misc FP Arithmetic.
* fdivl: (libc)Misc FP Arithmetic.
* fdopen: (libc)Descriptors and Streams.
* fdopendir: (libc)Opening a Directory.
* feclearexcept: (libc)Status bit operations.
* fedisableexcept: (libc)Control Functions.
* feenableexcept: (libc)Control Functions.
* fegetenv: (libc)Control Functions.
* fegetexcept: (libc)Control Functions.
* fegetexceptflag: (libc)Status bit operations.
* fegetmode: (libc)Control Functions.
* fegetround: (libc)Rounding.
* feholdexcept: (libc)Control Functions.
* feof: (libc)EOF and Errors.
* feof_unlocked: (libc)EOF and Errors.
* feraiseexcept: (libc)Status bit operations.
* ferror: (libc)EOF and Errors.
* ferror_unlocked: (libc)EOF and Errors.
* fesetenv: (libc)Control Functions.
* fesetexcept: (libc)Status bit operations.
* fesetexceptflag: (libc)Status bit operations.
* fesetmode: (libc)Control Functions.
* fesetround: (libc)Rounding.
* fetestexcept: (libc)Status bit operations.
* fetestexceptflag: (libc)Status bit operations.
* feupdateenv: (libc)Control Functions.
* fflush: (libc)Flushing Buffers.
* fflush_unlocked: (libc)Flushing Buffers.
* fgetc: (libc)Character Input.
* fgetc_unlocked: (libc)Character Input.
* fgetgrent: (libc)Scanning All Groups.
* fgetgrent_r: (libc)Scanning All Groups.
* fgetpos64: (libc)Portable Positioning.
* fgetpos: (libc)Portable Positioning.
* fgetpwent: (libc)Scanning All Users.
* fgetpwent_r: (libc)Scanning All Users.
* fgets: (libc)Line Input.
* fgets_unlocked: (libc)Line Input.
* fgetwc: (libc)Character Input.
* fgetwc_unlocked: (libc)Character Input.
* fgetws: (libc)Line Input.
* fgetws_unlocked: (libc)Line Input.
* fileno: (libc)Descriptors and Streams.
* fileno_unlocked: (libc)Descriptors and Streams.
* finite: (libc)Floating Point Classes.
* finitef: (libc)Floating Point Classes.
* finitel: (libc)Floating Point Classes.
* flockfile: (libc)Streams and Threads.
* floor: (libc)Rounding Functions.
* floorf: (libc)Rounding Functions.
* floorfN: (libc)Rounding Functions.
* floorfNx: (libc)Rounding Functions.
* floorl: (libc)Rounding Functions.
* fma: (libc)Misc FP Arithmetic.
* fmaf: (libc)Misc FP Arithmetic.
* fmafN: (libc)Misc FP Arithmetic.
* fmafNx: (libc)Misc FP Arithmetic.
* fmal: (libc)Misc FP Arithmetic.
* fmax: (libc)Misc FP Arithmetic.
* fmaxf: (libc)Misc FP Arithmetic.
* fmaxfN: (libc)Misc FP Arithmetic.
* fmaxfNx: (libc)Misc FP Arithmetic.
* fmaxl: (libc)Misc FP Arithmetic.
* fmaxmag: (libc)Misc FP Arithmetic.
* fmaxmagf: (libc)Misc FP Arithmetic.
* fmaxmagfN: (libc)Misc FP Arithmetic.
* fmaxmagfNx: (libc)Misc FP Arithmetic.
* fmaxmagl: (libc)Misc FP Arithmetic.
* fmemopen: (libc)String Streams.
* fmin: (libc)Misc FP Arithmetic.
* fminf: (libc)Misc FP Arithmetic.
* fminfN: (libc)Misc FP Arithmetic.
* fminfNx: (libc)Misc FP Arithmetic.
* fminl: (libc)Misc FP Arithmetic.
* fminmag: (libc)Misc FP Arithmetic.
* fminmagf: (libc)Misc FP Arithmetic.
* fminmagfN: (libc)Misc FP Arithmetic.
* fminmagfNx: (libc)Misc FP Arithmetic.
* fminmagl: (libc)Misc FP Arithmetic.
* fmod: (libc)Remainder Functions.
* fmodf: (libc)Remainder Functions.
* fmodfN: (libc)Remainder Functions.
* fmodfNx: (libc)Remainder Functions.
* fmodl: (libc)Remainder Functions.
* fmtmsg: (libc)Printing Formatted Messages.
* fmul: (libc)Misc FP Arithmetic.
* fmull: (libc)Misc FP Arithmetic.
* fnmatch: (libc)Wildcard Matching.
* fopen64: (libc)Opening Streams.
* fopen: (libc)Opening Streams.
* fopencookie: (libc)Streams and Cookies.
* fork: (libc)Creating a Process.
* forkpty: (libc)Pseudo-Terminal Pairs.
* fpathconf: (libc)Pathconf.
* fpclassify: (libc)Floating Point Classes.
* fprintf: (libc)Formatted Output Functions.
* fputc: (libc)Simple Output.
* fputc_unlocked: (libc)Simple Output.
* fputs: (libc)Simple Output.
* fputs_unlocked: (libc)Simple Output.
* fputwc: (libc)Simple Output.
* fputwc_unlocked: (libc)Simple Output.
* fputws: (libc)Simple Output.
* fputws_unlocked: (libc)Simple Output.
* fread: (libc)Block Input/Output.
* fread_unlocked: (libc)Block Input/Output.
* free: (libc)Freeing after Malloc.
* freopen64: (libc)Opening Streams.
* freopen: (libc)Opening Streams.
* frexp: (libc)Normalization Functions.
* frexpf: (libc)Normalization Functions.
* frexpfN: (libc)Normalization Functions.
* frexpfNx: (libc)Normalization Functions.
* frexpl: (libc)Normalization Functions.
* fromfp: (libc)Rounding Functions.
* fromfpf: (libc)Rounding Functions.
* fromfpfN: (libc)Rounding Functions.
* fromfpfNx: (libc)Rounding Functions.
* fromfpl: (libc)Rounding Functions.
* fromfpx: (libc)Rounding Functions.
* fromfpxf: (libc)Rounding Functions.
* fromfpxfN: (libc)Rounding Functions.
* fromfpxfNx: (libc)Rounding Functions.
* fromfpxl: (libc)Rounding Functions.
* fscanf: (libc)Formatted Input Functions.
* fseek: (libc)File Positioning.
* fseeko64: (libc)File Positioning.
* fseeko: (libc)File Positioning.
* fsetpos64: (libc)Portable Positioning.
* fsetpos: (libc)Portable Positioning.
* fstat64: (libc)Reading Attributes.
* fstat: (libc)Reading Attributes.
* fsub: (libc)Misc FP Arithmetic.
* fsubl: (libc)Misc FP Arithmetic.
* fsync: (libc)Synchronizing I/O.
* ftell: (libc)File Positioning.
* ftello64: (libc)File Positioning.
* ftello: (libc)File Positioning.
* ftruncate64: (libc)File Size.
* ftruncate: (libc)File Size.
* ftrylockfile: (libc)Streams and Threads.
* ftw64: (libc)Working with Directory Trees.
* ftw: (libc)Working with Directory Trees.
* funlockfile: (libc)Streams and Threads.
* futimes: (libc)File Times.
* fwide: (libc)Streams and I18N.
* fwprintf: (libc)Formatted Output Functions.
* fwrite: (libc)Block Input/Output.
* fwrite_unlocked: (libc)Block Input/Output.
* fwscanf: (libc)Formatted Input Functions.
* gamma: (libc)Special Functions.
* gammaf: (libc)Special Functions.
* gammal: (libc)Special Functions.
* gcvt: (libc)System V Number Conversion.
* get_avphys_pages: (libc)Query Memory Parameters.
* get_current_dir_name: (libc)Working Directory.
* get_nprocs: (libc)Processor Resources.
* get_nprocs_conf: (libc)Processor Resources.
* get_phys_pages: (libc)Query Memory Parameters.
* getauxval: (libc)Auxiliary Vector.
* getc: (libc)Character Input.
* getc_unlocked: (libc)Character Input.
* getchar: (libc)Character Input.
* getchar_unlocked: (libc)Character Input.
* getcontext: (libc)System V contexts.
* getcwd: (libc)Working Directory.
* getdate: (libc)General Time String Parsing.
* getdate_r: (libc)General Time String Parsing.
* getdelim: (libc)Line Input.
* getdomainnname: (libc)Host Identification.
* getegid: (libc)Reading Persona.
* getentropy: (libc)Unpredictable Bytes.
* getenv: (libc)Environment Access.
* geteuid: (libc)Reading Persona.
* getfsent: (libc)fstab.
* getfsfile: (libc)fstab.
* getfsspec: (libc)fstab.
* getgid: (libc)Reading Persona.
* getgrent: (libc)Scanning All Groups.
* getgrent_r: (libc)Scanning All Groups.
* getgrgid: (libc)Lookup Group.
* getgrgid_r: (libc)Lookup Group.
* getgrnam: (libc)Lookup Group.
* getgrnam_r: (libc)Lookup Group.
* getgrouplist: (libc)Setting Groups.
* getgroups: (libc)Reading Persona.
* gethostbyaddr: (libc)Host Names.
* gethostbyaddr_r: (libc)Host Names.
* gethostbyname2: (libc)Host Names.
* gethostbyname2_r: (libc)Host Names.
* gethostbyname: (libc)Host Names.
* gethostbyname_r: (libc)Host Names.
* gethostent: (libc)Host Names.
* gethostid: (libc)Host Identification.
* gethostname: (libc)Host Identification.
* getitimer: (libc)Setting an Alarm.
* getline: (libc)Line Input.
* getloadavg: (libc)Processor Resources.
* getlogin: (libc)Who Logged In.
* getmntent: (libc)mtab.
* getmntent_r: (libc)mtab.
* getnetbyaddr: (libc)Networks Database.
* getnetbyname: (libc)Networks Database.
* getnetent: (libc)Networks Database.
* getnetgrent: (libc)Lookup Netgroup.
* getnetgrent_r: (libc)Lookup Netgroup.
* getopt: (libc)Using Getopt.
* getopt_long: (libc)Getopt Long Options.
* getopt_long_only: (libc)Getopt Long Options.
* getpagesize: (libc)Query Memory Parameters.
* getpass: (libc)getpass.
* getpayload: (libc)FP Bit Twiddling.
* getpayloadf: (libc)FP Bit Twiddling.
* getpayloadfN: (libc)FP Bit Twiddling.
* getpayloadfNx: (libc)FP Bit Twiddling.
* getpayloadl: (libc)FP Bit Twiddling.
* getpeername: (libc)Who is Connected.
* getpgid: (libc)Process Group Functions.
* getpgrp: (libc)Process Group Functions.
* getpid: (libc)Process Identification.
* getppid: (libc)Process Identification.
* getpriority: (libc)Traditional Scheduling Functions.
* getprotobyname: (libc)Protocols Database.
* getprotobynumber: (libc)Protocols Database.
* getprotoent: (libc)Protocols Database.
* getpt: (libc)Allocation.
* getpwent: (libc)Scanning All Users.
* getpwent_r: (libc)Scanning All Users.
* getpwnam: (libc)Lookup User.
* getpwnam_r: (libc)Lookup User.
* getpwuid: (libc)Lookup User.
* getpwuid_r: (libc)Lookup User.
* getrandom: (libc)Unpredictable Bytes.
* getrlimit64: (libc)Limits on Resources.
* getrlimit: (libc)Limits on Resources.
* getrusage: (libc)Resource Usage.
* gets: (libc)Line Input.
* getservbyname: (libc)Services Database.
* getservbyport: (libc)Services Database.
* getservent: (libc)Services Database.
* getsid: (libc)Process Group Functions.
* getsockname: (libc)Reading Address.
* getsockopt: (libc)Socket Option Functions.
* getsubopt: (libc)Suboptions.
* gettext: (libc)Translation with gettext.
* gettimeofday: (libc)High-Resolution Calendar.
* getuid: (libc)Reading Persona.
* getumask: (libc)Setting Permissions.
* getutent: (libc)Manipulating the Database.
* getutent_r: (libc)Manipulating the Database.
* getutid: (libc)Manipulating the Database.
* getutid_r: (libc)Manipulating the Database.
* getutline: (libc)Manipulating the Database.
* getutline_r: (libc)Manipulating the Database.
* getutmp: (libc)XPG Functions.
* getutmpx: (libc)XPG Functions.
* getutxent: (libc)XPG Functions.
* getutxid: (libc)XPG Functions.
* getutxline: (libc)XPG Functions.
* getw: (libc)Character Input.
* getwc: (libc)Character Input.
* getwc_unlocked: (libc)Character Input.
* getwchar: (libc)Character Input.
* getwchar_unlocked: (libc)Character Input.
* getwd: (libc)Working Directory.
* glob64: (libc)Calling Glob.
* glob: (libc)Calling Glob.
* globfree64: (libc)More Flags for Globbing.
* globfree: (libc)More Flags for Globbing.
* gmtime: (libc)Broken-down Time.
* gmtime_r: (libc)Broken-down Time.
* grantpt: (libc)Allocation.
* gsignal: (libc)Signaling Yourself.
* gtty: (libc)BSD Terminal Modes.
* hasmntopt: (libc)mtab.
* hcreate: (libc)Hash Search Function.
* hcreate_r: (libc)Hash Search Function.
* hdestroy: (libc)Hash Search Function.
* hdestroy_r: (libc)Hash Search Function.
* hsearch: (libc)Hash Search Function.
* hsearch_r: (libc)Hash Search Function.
* htonl: (libc)Byte Order.
* htons: (libc)Byte Order.
* hypot: (libc)Exponents and Logarithms.
* hypotf: (libc)Exponents and Logarithms.
* hypotfN: (libc)Exponents and Logarithms.
* hypotfNx: (libc)Exponents and Logarithms.
* hypotl: (libc)Exponents and Logarithms.
* iconv: (libc)Generic Conversion Interface.
* iconv_close: (libc)Generic Conversion Interface.
* iconv_open: (libc)Generic Conversion Interface.
* if_freenameindex: (libc)Interface Naming.
* if_indextoname: (libc)Interface Naming.
* if_nameindex: (libc)Interface Naming.
* if_nametoindex: (libc)Interface Naming.
* ilogb: (libc)Exponents and Logarithms.
* ilogbf: (libc)Exponents and Logarithms.
* ilogbfN: (libc)Exponents and Logarithms.
* ilogbfNx: (libc)Exponents and Logarithms.
* ilogbl: (libc)Exponents and Logarithms.
* imaxabs: (libc)Absolute Value.
* imaxdiv: (libc)Integer Division.
* in6addr_any: (libc)Host Address Data Type.
* in6addr_loopback: (libc)Host Address Data Type.
* index: (libc)Search Functions.
* inet_addr: (libc)Host Address Functions.
* inet_aton: (libc)Host Address Functions.
* inet_lnaof: (libc)Host Address Functions.
* inet_makeaddr: (libc)Host Address Functions.
* inet_netof: (libc)Host Address Functions.
* inet_network: (libc)Host Address Functions.
* inet_ntoa: (libc)Host Address Functions.
* inet_ntop: (libc)Host Address Functions.
* inet_pton: (libc)Host Address Functions.
* initgroups: (libc)Setting Groups.
* initstate: (libc)BSD Random.
* initstate_r: (libc)BSD Random.
* innetgr: (libc)Netgroup Membership.
* ioctl: (libc)IOCTLs.
* isalnum: (libc)Classification of Characters.
* isalpha: (libc)Classification of Characters.
* isascii: (libc)Classification of Characters.
* isatty: (libc)Is It a Terminal.
* isblank: (libc)Classification of Characters.
* iscanonical: (libc)Floating Point Classes.
* iscntrl: (libc)Classification of Characters.
* isdigit: (libc)Classification of Characters.
* iseqsig: (libc)FP Comparison Functions.
* isfinite: (libc)Floating Point Classes.
* isgraph: (libc)Classification of Characters.
* isgreater: (libc)FP Comparison Functions.
* isgreaterequal: (libc)FP Comparison Functions.
* isinf: (libc)Floating Point Classes.
* isinff: (libc)Floating Point Classes.
* isinfl: (libc)Floating Point Classes.
* isless: (libc)FP Comparison Functions.
* islessequal: (libc)FP Comparison Functions.
* islessgreater: (libc)FP Comparison Functions.
* islower: (libc)Classification of Characters.
* isnan: (libc)Floating Point Classes.
* isnan: (libc)Floating Point Classes.
* isnanf: (libc)Floating Point Classes.
* isnanl: (libc)Floating Point Classes.
* isnormal: (libc)Floating Point Classes.
* isprint: (libc)Classification of Characters.
* ispunct: (libc)Classification of Characters.
* issignaling: (libc)Floating Point Classes.
* isspace: (libc)Classification of Characters.
* issubnormal: (libc)Floating Point Classes.
* isunordered: (libc)FP Comparison Functions.
* isupper: (libc)Classification of Characters.
* iswalnum: (libc)Classification of Wide Characters.
* iswalpha: (libc)Classification of Wide Characters.
* iswblank: (libc)Classification of Wide Characters.
* iswcntrl: (libc)Classification of Wide Characters.
* iswctype: (libc)Classification of Wide Characters.
* iswdigit: (libc)Classification of Wide Characters.
* iswgraph: (libc)Classification of Wide Characters.
* iswlower: (libc)Classification of Wide Characters.
* iswprint: (libc)Classification of Wide Characters.
* iswpunct: (libc)Classification of Wide Characters.
* iswspace: (libc)Classification of Wide Characters.
* iswupper: (libc)Classification of Wide Characters.
* iswxdigit: (libc)Classification of Wide Characters.
* isxdigit: (libc)Classification of Characters.
* iszero: (libc)Floating Point Classes.
* j0: (libc)Special Functions.
* j0f: (libc)Special Functions.
* j0fN: (libc)Special Functions.
* j0fNx: (libc)Special Functions.
* j0l: (libc)Special Functions.
* j1: (libc)Special Functions.
* j1f: (libc)Special Functions.
* j1fN: (libc)Special Functions.
* j1fNx: (libc)Special Functions.
* j1l: (libc)Special Functions.
* jn: (libc)Special Functions.
* jnf: (libc)Special Functions.
* jnfN: (libc)Special Functions.
* jnfNx: (libc)Special Functions.
* jnl: (libc)Special Functions.
* jrand48: (libc)SVID Random.
* jrand48_r: (libc)SVID Random.
* kill: (libc)Signaling Another Process.
* killpg: (libc)Signaling Another Process.
* l64a: (libc)Encode Binary Data.
* labs: (libc)Absolute Value.
* lcong48: (libc)SVID Random.
* lcong48_r: (libc)SVID Random.
* ldexp: (libc)Normalization Functions.
* ldexpf: (libc)Normalization Functions.
* ldexpfN: (libc)Normalization Functions.
* ldexpfNx: (libc)Normalization Functions.
* ldexpl: (libc)Normalization Functions.
* ldiv: (libc)Integer Division.
* lfind: (libc)Array Search Function.
* lgamma: (libc)Special Functions.
* lgamma_r: (libc)Special Functions.
* lgammaf: (libc)Special Functions.
* lgammafN: (libc)Special Functions.
* lgammafN_r: (libc)Special Functions.
* lgammafNx: (libc)Special Functions.
* lgammafNx_r: (libc)Special Functions.
* lgammaf_r: (libc)Special Functions.
* lgammal: (libc)Special Functions.
* lgammal_r: (libc)Special Functions.
* link: (libc)Hard Links.
* linkat: (libc)Hard Links.
* lio_listio64: (libc)Asynchronous Reads/Writes.
* lio_listio: (libc)Asynchronous Reads/Writes.
* listen: (libc)Listening.
* llabs: (libc)Absolute Value.
* lldiv: (libc)Integer Division.
* llogb: (libc)Exponents and Logarithms.
* llogbf: (libc)Exponents and Logarithms.
* llogbfN: (libc)Exponents and Logarithms.
* llogbfNx: (libc)Exponents and Logarithms.
* llogbl: (libc)Exponents and Logarithms.
* llrint: (libc)Rounding Functions.
* llrintf: (libc)Rounding Functions.
* llrintfN: (libc)Rounding Functions.
* llrintfNx: (libc)Rounding Functions.
* llrintl: (libc)Rounding Functions.
* llround: (libc)Rounding Functions.
* llroundf: (libc)Rounding Functions.
* llroundfN: (libc)Rounding Functions.
* llroundfNx: (libc)Rounding Functions.
* llroundl: (libc)Rounding Functions.
* localeconv: (libc)The Lame Way to Locale Data.
* localtime: (libc)Broken-down Time.
* localtime_r: (libc)Broken-down Time.
* log10: (libc)Exponents and Logarithms.
* log10f: (libc)Exponents and Logarithms.
* log10fN: (libc)Exponents and Logarithms.
* log10fNx: (libc)Exponents and Logarithms.
* log10l: (libc)Exponents and Logarithms.
* log1p: (libc)Exponents and Logarithms.
* log1pf: (libc)Exponents and Logarithms.
* log1pfN: (libc)Exponents and Logarithms.
* log1pfNx: (libc)Exponents and Logarithms.
* log1pl: (libc)Exponents and Logarithms.
* log2: (libc)Exponents and Logarithms.
* log2f: (libc)Exponents and Logarithms.
* log2fN: (libc)Exponents and Logarithms.
* log2fNx: (libc)Exponents and Logarithms.
* log2l: (libc)Exponents and Logarithms.
* log: (libc)Exponents and Logarithms.
* logb: (libc)Exponents and Logarithms.
* logbf: (libc)Exponents and Logarithms.
* logbfN: (libc)Exponents and Logarithms.
* logbfNx: (libc)Exponents and Logarithms.
* logbl: (libc)Exponents and Logarithms.
* logf: (libc)Exponents and Logarithms.
* logfN: (libc)Exponents and Logarithms.
* logfNx: (libc)Exponents and Logarithms.
* login: (libc)Logging In and Out.
* login_tty: (libc)Logging In and Out.
* logl: (libc)Exponents and Logarithms.
* logout: (libc)Logging In and Out.
* logwtmp: (libc)Logging In and Out.
* longjmp: (libc)Non-Local Details.
* lrand48: (libc)SVID Random.
* lrand48_r: (libc)SVID Random.
* lrint: (libc)Rounding Functions.
* lrintf: (libc)Rounding Functions.
* lrintfN: (libc)Rounding Functions.
* lrintfNx: (libc)Rounding Functions.
* lrintl: (libc)Rounding Functions.
* lround: (libc)Rounding Functions.
* lroundf: (libc)Rounding Functions.
* lroundfN: (libc)Rounding Functions.
* lroundfNx: (libc)Rounding Functions.
* lroundl: (libc)Rounding Functions.
* lsearch: (libc)Array Search Function.
* lseek64: (libc)File Position Primitive.
* lseek: (libc)File Position Primitive.
* lstat64: (libc)Reading Attributes.
* lstat: (libc)Reading Attributes.
* lutimes: (libc)File Times.
* madvise: (libc)Memory-mapped I/O.
* makecontext: (libc)System V contexts.
* mallinfo: (libc)Statistics of Malloc.
* malloc: (libc)Basic Allocation.
* mallopt: (libc)Malloc Tunable Parameters.
* mblen: (libc)Non-reentrant Character Conversion.
* mbrlen: (libc)Converting a Character.
* mbrtowc: (libc)Converting a Character.
* mbsinit: (libc)Keeping the state.
* mbsnrtowcs: (libc)Converting Strings.
* mbsrtowcs: (libc)Converting Strings.
* mbstowcs: (libc)Non-reentrant String Conversion.
* mbtowc: (libc)Non-reentrant Character Conversion.
* mcheck: (libc)Heap Consistency Checking.
* memalign: (libc)Aligned Memory Blocks.
* memccpy: (libc)Copying Strings and Arrays.
* memchr: (libc)Search Functions.
* memcmp: (libc)String/Array Comparison.
* memcpy: (libc)Copying Strings and Arrays.
* memfd_create: (libc)Memory-mapped I/O.
* memfrob: (libc)Obfuscating Data.
* memmem: (libc)Search Functions.
* memmove: (libc)Copying Strings and Arrays.
* mempcpy: (libc)Copying Strings and Arrays.
* memrchr: (libc)Search Functions.
* memset: (libc)Copying Strings and Arrays.
* mkdir: (libc)Creating Directories.
* mkdtemp: (libc)Temporary Files.
* mkfifo: (libc)FIFO Special Files.
* mknod: (libc)Making Special Files.
* mkstemp: (libc)Temporary Files.
* mktemp: (libc)Temporary Files.
* mktime: (libc)Broken-down Time.
* mlock2: (libc)Page Lock Functions.
* mlock: (libc)Page Lock Functions.
* mlockall: (libc)Page Lock Functions.
* mmap64: (libc)Memory-mapped I/O.
* mmap: (libc)Memory-mapped I/O.
* modf: (libc)Rounding Functions.
* modff: (libc)Rounding Functions.
* modffN: (libc)Rounding Functions.
* modffNx: (libc)Rounding Functions.
* modfl: (libc)Rounding Functions.
* mount: (libc)Mount-Unmount-Remount.
* mprobe: (libc)Heap Consistency Checking.
* mprotect: (libc)Memory Protection.
* mrand48: (libc)SVID Random.
* mrand48_r: (libc)SVID Random.
* mremap: (libc)Memory-mapped I/O.
* msync: (libc)Memory-mapped I/O.
* mtrace: (libc)Tracing malloc.
* mtx_destroy: (libc)ISO C Mutexes.
* mtx_init: (libc)ISO C Mutexes.
* mtx_lock: (libc)ISO C Mutexes.
* mtx_timedlock: (libc)ISO C Mutexes.
* mtx_trylock: (libc)ISO C Mutexes.
* mtx_unlock: (libc)ISO C Mutexes.
* munlock: (libc)Page Lock Functions.
* munlockall: (libc)Page Lock Functions.
* munmap: (libc)Memory-mapped I/O.
* muntrace: (libc)Tracing malloc.
* nan: (libc)FP Bit Twiddling.
* nanf: (libc)FP Bit Twiddling.
* nanfN: (libc)FP Bit Twiddling.
* nanfNx: (libc)FP Bit Twiddling.
* nanl: (libc)FP Bit Twiddling.
* nanosleep: (libc)Sleeping.
* nearbyint: (libc)Rounding Functions.
* nearbyintf: (libc)Rounding Functions.
* nearbyintfN: (libc)Rounding Functions.
* nearbyintfNx: (libc)Rounding Functions.
* nearbyintl: (libc)Rounding Functions.
* nextafter: (libc)FP Bit Twiddling.
* nextafterf: (libc)FP Bit Twiddling.
* nextafterfN: (libc)FP Bit Twiddling.
* nextafterfNx: (libc)FP Bit Twiddling.
* nextafterl: (libc)FP Bit Twiddling.
* nextdown: (libc)FP Bit Twiddling.
* nextdownf: (libc)FP Bit Twiddling.
* nextdownfN: (libc)FP Bit Twiddling.
* nextdownfNx: (libc)FP Bit Twiddling.
* nextdownl: (libc)FP Bit Twiddling.
* nexttoward: (libc)FP Bit Twiddling.
* nexttowardf: (libc)FP Bit Twiddling.
* nexttowardl: (libc)FP Bit Twiddling.
* nextup: (libc)FP Bit Twiddling.
* nextupf: (libc)FP Bit Twiddling.
* nextupfN: (libc)FP Bit Twiddling.
* nextupfNx: (libc)FP Bit Twiddling.
* nextupl: (libc)FP Bit Twiddling.
* nftw64: (libc)Working with Directory Trees.
* nftw: (libc)Working with Directory Trees.
* ngettext: (libc)Advanced gettext functions.
* nice: (libc)Traditional Scheduling Functions.
* nl_langinfo: (libc)The Elegant and Fast Way.
* nrand48: (libc)SVID Random.
* nrand48_r: (libc)SVID Random.
* ntohl: (libc)Byte Order.
* ntohs: (libc)Byte Order.
* ntp_adjtime: (libc)High Accuracy Clock.
* ntp_gettime: (libc)High Accuracy Clock.
* obstack_1grow: (libc)Growing Objects.
* obstack_1grow_fast: (libc)Extra Fast Growing.
* obstack_alignment_mask: (libc)Obstacks Data Alignment.
* obstack_alloc: (libc)Allocation in an Obstack.
* obstack_base: (libc)Status of an Obstack.
* obstack_blank: (libc)Growing Objects.
* obstack_blank_fast: (libc)Extra Fast Growing.
* obstack_chunk_size: (libc)Obstack Chunks.
* obstack_copy0: (libc)Allocation in an Obstack.
* obstack_copy: (libc)Allocation in an Obstack.
* obstack_finish: (libc)Growing Objects.
* obstack_free: (libc)Freeing Obstack Objects.
* obstack_grow0: (libc)Growing Objects.
* obstack_grow: (libc)Growing Objects.
* obstack_init: (libc)Preparing for Obstacks.
* obstack_int_grow: (libc)Growing Objects.
* obstack_int_grow_fast: (libc)Extra Fast Growing.
* obstack_next_free: (libc)Status of an Obstack.
* obstack_object_size: (libc)Growing Objects.
* obstack_object_size: (libc)Status of an Obstack.
* obstack_printf: (libc)Dynamic Output.
* obstack_ptr_grow: (libc)Growing Objects.
* obstack_ptr_grow_fast: (libc)Extra Fast Growing.
* obstack_room: (libc)Extra Fast Growing.
* obstack_vprintf: (libc)Variable Arguments Output.
* offsetof: (libc)Structure Measurement.
* on_exit: (libc)Cleanups on Exit.
* open64: (libc)Opening and Closing Files.
* open: (libc)Opening and Closing Files.
* open_memstream: (libc)String Streams.
* opendir: (libc)Opening a Directory.
* openlog: (libc)openlog.
* openpty: (libc)Pseudo-Terminal Pairs.
* parse_printf_format: (libc)Parsing a Template String.
* pathconf: (libc)Pathconf.
* pause: (libc)Using Pause.
* pclose: (libc)Pipe to a Subprocess.
* perror: (libc)Error Messages.
* pipe: (libc)Creating a Pipe.
* pkey_alloc: (libc)Memory Protection.
* pkey_free: (libc)Memory Protection.
* pkey_get: (libc)Memory Protection.
* pkey_mprotect: (libc)Memory Protection.
* pkey_set: (libc)Memory Protection.
* popen: (libc)Pipe to a Subprocess.
* posix_fallocate64: (libc)Storage Allocation.
* posix_fallocate: (libc)Storage Allocation.
* posix_memalign: (libc)Aligned Memory Blocks.
* pow: (libc)Exponents and Logarithms.
* powf: (libc)Exponents and Logarithms.
* powfN: (libc)Exponents and Logarithms.
* powfNx: (libc)Exponents and Logarithms.
* powl: (libc)Exponents and Logarithms.
* pread64: (libc)I/O Primitives.
* pread: (libc)I/O Primitives.
* preadv2: (libc)Scatter-Gather.
* preadv64: (libc)Scatter-Gather.
* preadv64v2: (libc)Scatter-Gather.
* preadv: (libc)Scatter-Gather.
* printf: (libc)Formatted Output Functions.
* printf_size: (libc)Predefined Printf Handlers.
* printf_size_info: (libc)Predefined Printf Handlers.
* psignal: (libc)Signal Messages.
* pthread_getattr_default_np: (libc)Default Thread Attributes.
* pthread_getspecific: (libc)Thread-specific Data.
* pthread_key_create: (libc)Thread-specific Data.
* pthread_key_delete: (libc)Thread-specific Data.
* pthread_setattr_default_np: (libc)Default Thread Attributes.
* pthread_setspecific: (libc)Thread-specific Data.
* ptsname: (libc)Allocation.
* ptsname_r: (libc)Allocation.
* putc: (libc)Simple Output.
* putc_unlocked: (libc)Simple Output.
* putchar: (libc)Simple Output.
* putchar_unlocked: (libc)Simple Output.
* putenv: (libc)Environment Access.
* putpwent: (libc)Writing a User Entry.
* puts: (libc)Simple Output.
* pututline: (libc)Manipulating the Database.
* pututxline: (libc)XPG Functions.
* putw: (libc)Simple Output.
* putwc: (libc)Simple Output.
* putwc_unlocked: (libc)Simple Output.
* putwchar: (libc)Simple Output.
* putwchar_unlocked: (libc)Simple Output.
* pwrite64: (libc)I/O Primitives.
* pwrite: (libc)I/O Primitives.
* pwritev2: (libc)Scatter-Gather.
* pwritev64: (libc)Scatter-Gather.
* pwritev64v2: (libc)Scatter-Gather.
* pwritev: (libc)Scatter-Gather.
* qecvt: (libc)System V Number Conversion.
* qecvt_r: (libc)System V Number Conversion.
* qfcvt: (libc)System V Number Conversion.
* qfcvt_r: (libc)System V Number Conversion.
* qgcvt: (libc)System V Number Conversion.
* qsort: (libc)Array Sort Function.
* raise: (libc)Signaling Yourself.
* rand: (libc)ISO Random.
* rand_r: (libc)ISO Random.
* random: (libc)BSD Random.
* random_r: (libc)BSD Random.
* rawmemchr: (libc)Search Functions.
* read: (libc)I/O Primitives.
* readdir64: (libc)Reading/Closing Directory.
* readdir64_r: (libc)Reading/Closing Directory.
* readdir: (libc)Reading/Closing Directory.
* readdir_r: (libc)Reading/Closing Directory.
* readlink: (libc)Symbolic Links.
* readv: (libc)Scatter-Gather.
* realloc: (libc)Changing Block Size.
* reallocarray: (libc)Changing Block Size.
* realpath: (libc)Symbolic Links.
* recv: (libc)Receiving Data.
* recvfrom: (libc)Receiving Datagrams.
* recvmsg: (libc)Receiving Datagrams.
* regcomp: (libc)POSIX Regexp Compilation.
* regerror: (libc)Regexp Cleanup.
* regexec: (libc)Matching POSIX Regexps.
* regfree: (libc)Regexp Cleanup.
* register_printf_function: (libc)Registering New Conversions.
* remainder: (libc)Remainder Functions.
* remainderf: (libc)Remainder Functions.
* remainderfN: (libc)Remainder Functions.
* remainderfNx: (libc)Remainder Functions.
* remainderl: (libc)Remainder Functions.
* remove: (libc)Deleting Files.
* rename: (libc)Renaming Files.
* rewind: (libc)File Positioning.
* rewinddir: (libc)Random Access Directory.
* rindex: (libc)Search Functions.
* rint: (libc)Rounding Functions.
* rintf: (libc)Rounding Functions.
* rintfN: (libc)Rounding Functions.
* rintfNx: (libc)Rounding Functions.
* rintl: (libc)Rounding Functions.
* rmdir: (libc)Deleting Files.
* round: (libc)Rounding Functions.
* roundeven: (libc)Rounding Functions.
* roundevenf: (libc)Rounding Functions.
* roundevenfN: (libc)Rounding Functions.
* roundevenfNx: (libc)Rounding Functions.
* roundevenl: (libc)Rounding Functions.
* roundf: (libc)Rounding Functions.
* roundfN: (libc)Rounding Functions.
* roundfNx: (libc)Rounding Functions.
* roundl: (libc)Rounding Functions.
* rpmatch: (libc)Yes-or-No Questions.
* sbrk: (libc)Resizing the Data Segment.
* scalb: (libc)Normalization Functions.
* scalbf: (libc)Normalization Functions.
* scalbl: (libc)Normalization Functions.
* scalbln: (libc)Normalization Functions.
* scalblnf: (libc)Normalization Functions.
* scalblnfN: (libc)Normalization Functions.
* scalblnfNx: (libc)Normalization Functions.
* scalblnl: (libc)Normalization Functions.
* scalbn: (libc)Normalization Functions.
* scalbnf: (libc)Normalization Functions.
* scalbnfN: (libc)Normalization Functions.
* scalbnfNx: (libc)Normalization Functions.
* scalbnl: (libc)Normalization Functions.
* scandir64: (libc)Scanning Directory Content.
* scandir: (libc)Scanning Directory Content.
* scanf: (libc)Formatted Input Functions.
* sched_get_priority_max: (libc)Basic Scheduling Functions.
* sched_get_priority_min: (libc)Basic Scheduling Functions.
* sched_getaffinity: (libc)CPU Affinity.
* sched_getparam: (libc)Basic Scheduling Functions.
* sched_getscheduler: (libc)Basic Scheduling Functions.
* sched_rr_get_interval: (libc)Basic Scheduling Functions.
* sched_setaffinity: (libc)CPU Affinity.
* sched_setparam: (libc)Basic Scheduling Functions.
* sched_setscheduler: (libc)Basic Scheduling Functions.
* sched_yield: (libc)Basic Scheduling Functions.
* secure_getenv: (libc)Environment Access.
* seed48: (libc)SVID Random.
* seed48_r: (libc)SVID Random.
* seekdir: (libc)Random Access Directory.
* select: (libc)Waiting for I/O.
* sem_close: (libc)Semaphores.
* sem_destroy: (libc)Semaphores.
* sem_getvalue: (libc)Semaphores.
* sem_init: (libc)Semaphores.
* sem_open: (libc)Semaphores.
* sem_post: (libc)Semaphores.
* sem_timedwait: (libc)Semaphores.
* sem_trywait: (libc)Semaphores.
* sem_unlink: (libc)Semaphores.
* sem_wait: (libc)Semaphores.
* semctl: (libc)Semaphores.
* semget: (libc)Semaphores.
* semop: (libc)Semaphores.
* semtimedop: (libc)Semaphores.
* send: (libc)Sending Data.
* sendmsg: (libc)Receiving Datagrams.
* sendto: (libc)Sending Datagrams.
* setbuf: (libc)Controlling Buffering.
* setbuffer: (libc)Controlling Buffering.
* setcontext: (libc)System V contexts.
* setdomainname: (libc)Host Identification.
* setegid: (libc)Setting Groups.
* setenv: (libc)Environment Access.
* seteuid: (libc)Setting User ID.
* setfsent: (libc)fstab.
* setgid: (libc)Setting Groups.
* setgrent: (libc)Scanning All Groups.
* setgroups: (libc)Setting Groups.
* sethostent: (libc)Host Names.
* sethostid: (libc)Host Identification.
* sethostname: (libc)Host Identification.
* setitimer: (libc)Setting an Alarm.
* setjmp: (libc)Non-Local Details.
* setlinebuf: (libc)Controlling Buffering.
* setlocale: (libc)Setting the Locale.
* setlogmask: (libc)setlogmask.
* setmntent: (libc)mtab.
* setnetent: (libc)Networks Database.
* setnetgrent: (libc)Lookup Netgroup.
* setpayload: (libc)FP Bit Twiddling.
* setpayloadf: (libc)FP Bit Twiddling.
* setpayloadfN: (libc)FP Bit Twiddling.
* setpayloadfNx: (libc)FP Bit Twiddling.
* setpayloadl: (libc)FP Bit Twiddling.
* setpayloadsig: (libc)FP Bit Twiddling.
* setpayloadsigf: (libc)FP Bit Twiddling.
* setpayloadsigfN: (libc)FP Bit Twiddling.
* setpayloadsigfNx: (libc)FP Bit Twiddling.
* setpayloadsigl: (libc)FP Bit Twiddling.
* setpgid: (libc)Process Group Functions.
* setpgrp: (libc)Process Group Functions.
* setpriority: (libc)Traditional Scheduling Functions.
* setprotoent: (libc)Protocols Database.
* setpwent: (libc)Scanning All Users.
* setregid: (libc)Setting Groups.
* setreuid: (libc)Setting User ID.
* setrlimit64: (libc)Limits on Resources.
* setrlimit: (libc)Limits on Resources.
* setservent: (libc)Services Database.
* setsid: (libc)Process Group Functions.
* setsockopt: (libc)Socket Option Functions.
* setstate: (libc)BSD Random.
* setstate_r: (libc)BSD Random.
* settimeofday: (libc)High-Resolution Calendar.
* setuid: (libc)Setting User ID.
* setutent: (libc)Manipulating the Database.
* setutxent: (libc)XPG Functions.
* setvbuf: (libc)Controlling Buffering.
* shm_open: (libc)Memory-mapped I/O.
* shm_unlink: (libc)Memory-mapped I/O.
* shutdown: (libc)Closing a Socket.
* sigaction: (libc)Advanced Signal Handling.
* sigaddset: (libc)Signal Sets.
* sigaltstack: (libc)Signal Stack.
* sigblock: (libc)BSD Signal Handling.
* sigdelset: (libc)Signal Sets.
* sigemptyset: (libc)Signal Sets.
* sigfillset: (libc)Signal Sets.
* siginterrupt: (libc)BSD Signal Handling.
* sigismember: (libc)Signal Sets.
* siglongjmp: (libc)Non-Local Exits and Signals.
* sigmask: (libc)BSD Signal Handling.
* signal: (libc)Basic Signal Handling.
* signbit: (libc)FP Bit Twiddling.
* significand: (libc)Normalization Functions.
* significandf: (libc)Normalization Functions.
* significandl: (libc)Normalization Functions.
* sigpause: (libc)BSD Signal Handling.
* sigpending: (libc)Checking for Pending Signals.
* sigprocmask: (libc)Process Signal Mask.
* sigsetjmp: (libc)Non-Local Exits and Signals.
* sigsetmask: (libc)BSD Signal Handling.
* sigstack: (libc)Signal Stack.
* sigsuspend: (libc)Sigsuspend.
* sin: (libc)Trig Functions.
* sincos: (libc)Trig Functions.
* sincosf: (libc)Trig Functions.
* sincosfN: (libc)Trig Functions.
* sincosfNx: (libc)Trig Functions.
* sincosl: (libc)Trig Functions.
* sinf: (libc)Trig Functions.
* sinfN: (libc)Trig Functions.
* sinfNx: (libc)Trig Functions.
* sinh: (libc)Hyperbolic Functions.
* sinhf: (libc)Hyperbolic Functions.
* sinhfN: (libc)Hyperbolic Functions.
* sinhfNx: (libc)Hyperbolic Functions.
* sinhl: (libc)Hyperbolic Functions.
* sinl: (libc)Trig Functions.
* sleep: (libc)Sleeping.
* snprintf: (libc)Formatted Output Functions.
* socket: (libc)Creating a Socket.
* socketpair: (libc)Socket Pairs.
* sprintf: (libc)Formatted Output Functions.
* sqrt: (libc)Exponents and Logarithms.
* sqrtf: (libc)Exponents and Logarithms.
* sqrtfN: (libc)Exponents and Logarithms.
* sqrtfNx: (libc)Exponents and Logarithms.
* sqrtl: (libc)Exponents and Logarithms.
* srand48: (libc)SVID Random.
* srand48_r: (libc)SVID Random.
* srand: (libc)ISO Random.
* srandom: (libc)BSD Random.
* srandom_r: (libc)BSD Random.
* sscanf: (libc)Formatted Input Functions.
* ssignal: (libc)Basic Signal Handling.
* stat64: (libc)Reading Attributes.
* stat: (libc)Reading Attributes.
* stime: (libc)Simple Calendar Time.
* stpcpy: (libc)Copying Strings and Arrays.
* stpncpy: (libc)Truncating Strings.
* strcasecmp: (libc)String/Array Comparison.
* strcasestr: (libc)Search Functions.
* strcat: (libc)Concatenating Strings.
* strchr: (libc)Search Functions.
* strchrnul: (libc)Search Functions.
* strcmp: (libc)String/Array Comparison.
* strcoll: (libc)Collation Functions.
* strcpy: (libc)Copying Strings and Arrays.
* strcspn: (libc)Search Functions.
* strdup: (libc)Copying Strings and Arrays.
* strdupa: (libc)Copying Strings and Arrays.
* strerror: (libc)Error Messages.
* strerror_r: (libc)Error Messages.
* strfmon: (libc)Formatting Numbers.
* strfromd: (libc)Printing of Floats.
* strfromf: (libc)Printing of Floats.
* strfromfN: (libc)Printing of Floats.
* strfromfNx: (libc)Printing of Floats.
* strfroml: (libc)Printing of Floats.
* strfry: (libc)Shuffling Bytes.
* strftime: (libc)Formatting Calendar Time.
* strlen: (libc)String Length.
* strncasecmp: (libc)String/Array Comparison.
* strncat: (libc)Truncating Strings.
* strncmp: (libc)String/Array Comparison.
* strncpy: (libc)Truncating Strings.
* strndup: (libc)Truncating Strings.
* strndupa: (libc)Truncating Strings.
* strnlen: (libc)String Length.
* strpbrk: (libc)Search Functions.
* strptime: (libc)Low-Level Time String Parsing.
* strrchr: (libc)Search Functions.
* strsep: (libc)Finding Tokens in a String.
* strsignal: (libc)Signal Messages.
* strspn: (libc)Search Functions.
* strstr: (libc)Search Functions.
* strtod: (libc)Parsing of Floats.
* strtof: (libc)Parsing of Floats.
* strtofN: (libc)Parsing of Floats.
* strtofNx: (libc)Parsing of Floats.
* strtoimax: (libc)Parsing of Integers.
* strtok: (libc)Finding Tokens in a String.
* strtok_r: (libc)Finding Tokens in a String.
* strtol: (libc)Parsing of Integers.
* strtold: (libc)Parsing of Floats.
* strtoll: (libc)Parsing of Integers.
* strtoq: (libc)Parsing of Integers.
* strtoul: (libc)Parsing of Integers.
* strtoull: (libc)Parsing of Integers.
* strtoumax: (libc)Parsing of Integers.
* strtouq: (libc)Parsing of Integers.
* strverscmp: (libc)String/Array Comparison.
* strxfrm: (libc)Collation Functions.
* stty: (libc)BSD Terminal Modes.
* swapcontext: (libc)System V contexts.
* swprintf: (libc)Formatted Output Functions.
* swscanf: (libc)Formatted Input Functions.
* symlink: (libc)Symbolic Links.
* sync: (libc)Synchronizing I/O.
* syscall: (libc)System Calls.
* sysconf: (libc)Sysconf Definition.
* sysctl: (libc)System Parameters.
* syslog: (libc)syslog; vsyslog.
* system: (libc)Running a Command.
* sysv_signal: (libc)Basic Signal Handling.
* tan: (libc)Trig Functions.
* tanf: (libc)Trig Functions.
* tanfN: (libc)Trig Functions.
* tanfNx: (libc)Trig Functions.
* tanh: (libc)Hyperbolic Functions.
* tanhf: (libc)Hyperbolic Functions.
* tanhfN: (libc)Hyperbolic Functions.
* tanhfNx: (libc)Hyperbolic Functions.
* tanhl: (libc)Hyperbolic Functions.
* tanl: (libc)Trig Functions.
* tcdrain: (libc)Line Control.
* tcflow: (libc)Line Control.
* tcflush: (libc)Line Control.
* tcgetattr: (libc)Mode Functions.
* tcgetpgrp: (libc)Terminal Access Functions.
* tcgetsid: (libc)Terminal Access Functions.
* tcsendbreak: (libc)Line Control.
* tcsetattr: (libc)Mode Functions.
* tcsetpgrp: (libc)Terminal Access Functions.
* tdelete: (libc)Tree Search Function.
* tdestroy: (libc)Tree Search Function.
* telldir: (libc)Random Access Directory.
* tempnam: (libc)Temporary Files.
* textdomain: (libc)Locating gettext catalog.
* tfind: (libc)Tree Search Function.
* tgamma: (libc)Special Functions.
* tgammaf: (libc)Special Functions.
* tgammafN: (libc)Special Functions.
* tgammafNx: (libc)Special Functions.
* tgammal: (libc)Special Functions.
* thrd_create: (libc)ISO C Thread Management.
* thrd_current: (libc)ISO C Thread Management.
* thrd_detach: (libc)ISO C Thread Management.
* thrd_equal: (libc)ISO C Thread Management.
* thrd_exit: (libc)ISO C Thread Management.
* thrd_join: (libc)ISO C Thread Management.
* thrd_sleep: (libc)ISO C Thread Management.
* thrd_yield: (libc)ISO C Thread Management.
* time: (libc)Simple Calendar Time.
* timegm: (libc)Broken-down Time.
* timelocal: (libc)Broken-down Time.
* times: (libc)Processor Time.
* tmpfile64: (libc)Temporary Files.
* tmpfile: (libc)Temporary Files.
* tmpnam: (libc)Temporary Files.
* tmpnam_r: (libc)Temporary Files.
* toascii: (libc)Case Conversion.
* tolower: (libc)Case Conversion.
* totalorder: (libc)FP Comparison Functions.
* totalorderf: (libc)FP Comparison Functions.
* totalorderfN: (libc)FP Comparison Functions.
* totalorderfNx: (libc)FP Comparison Functions.
* totalorderl: (libc)FP Comparison Functions.
* totalordermag: (libc)FP Comparison Functions.
* totalordermagf: (libc)FP Comparison Functions.
* totalordermagfN: (libc)FP Comparison Functions.
* totalordermagfNx: (libc)FP Comparison Functions.
* totalordermagl: (libc)FP Comparison Functions.
* toupper: (libc)Case Conversion.
* towctrans: (libc)Wide Character Case Conversion.
* towlower: (libc)Wide Character Case Conversion.
* towupper: (libc)Wide Character Case Conversion.
* trunc: (libc)Rounding Functions.
* truncate64: (libc)File Size.
* truncate: (libc)File Size.
* truncf: (libc)Rounding Functions.
* truncfN: (libc)Rounding Functions.
* truncfNx: (libc)Rounding Functions.
* truncl: (libc)Rounding Functions.
* tsearch: (libc)Tree Search Function.
* tss_create: (libc)ISO C Thread-local Storage.
* tss_delete: (libc)ISO C Thread-local Storage.
* tss_get: (libc)ISO C Thread-local Storage.
* tss_set: (libc)ISO C Thread-local Storage.
* ttyname: (libc)Is It a Terminal.
* ttyname_r: (libc)Is It a Terminal.
* twalk: (libc)Tree Search Function.
* tzset: (libc)Time Zone Functions.
* ufromfp: (libc)Rounding Functions.
* ufromfpf: (libc)Rounding Functions.
* ufromfpfN: (libc)Rounding Functions.
* ufromfpfNx: (libc)Rounding Functions.
* ufromfpl: (libc)Rounding Functions.
* ufromfpx: (libc)Rounding Functions.
* ufromfpxf: (libc)Rounding Functions.
* ufromfpxfN: (libc)Rounding Functions.
* ufromfpxfNx: (libc)Rounding Functions.
* ufromfpxl: (libc)Rounding Functions.
* ulimit: (libc)Limits on Resources.
* umask: (libc)Setting Permissions.
* umount2: (libc)Mount-Unmount-Remount.
* umount: (libc)Mount-Unmount-Remount.
* uname: (libc)Platform Type.
* ungetc: (libc)How Unread.
* ungetwc: (libc)How Unread.
* unlink: (libc)Deleting Files.
* unlockpt: (libc)Allocation.
* unsetenv: (libc)Environment Access.
* updwtmp: (libc)Manipulating the Database.
* utime: (libc)File Times.
* utimes: (libc)File Times.
* utmpname: (libc)Manipulating the Database.
* utmpxname: (libc)XPG Functions.
* va_arg: (libc)Argument Macros.
* va_copy: (libc)Argument Macros.
* va_end: (libc)Argument Macros.
* va_start: (libc)Argument Macros.
* valloc: (libc)Aligned Memory Blocks.
* vasprintf: (libc)Variable Arguments Output.
* verr: (libc)Error Messages.
* verrx: (libc)Error Messages.
* versionsort64: (libc)Scanning Directory Content.
* versionsort: (libc)Scanning Directory Content.
* vfork: (libc)Creating a Process.
* vfprintf: (libc)Variable Arguments Output.
* vfscanf: (libc)Variable Arguments Input.
* vfwprintf: (libc)Variable Arguments Output.
* vfwscanf: (libc)Variable Arguments Input.
* vlimit: (libc)Limits on Resources.
* vprintf: (libc)Variable Arguments Output.
* vscanf: (libc)Variable Arguments Input.
* vsnprintf: (libc)Variable Arguments Output.
* vsprintf: (libc)Variable Arguments Output.
* vsscanf: (libc)Variable Arguments Input.
* vswprintf: (libc)Variable Arguments Output.
* vswscanf: (libc)Variable Arguments Input.
* vsyslog: (libc)syslog; vsyslog.
* vtimes: (libc)Resource Usage.
* vwarn: (libc)Error Messages.
* vwarnx: (libc)Error Messages.
* vwprintf: (libc)Variable Arguments Output.
* vwscanf: (libc)Variable Arguments Input.
* wait3: (libc)BSD Wait Functions.
* wait4: (libc)Process Completion.
* wait: (libc)Process Completion.
* waitpid: (libc)Process Completion.
* warn: (libc)Error Messages.
* warnx: (libc)Error Messages.
* wcpcpy: (libc)Copying Strings and Arrays.
* wcpncpy: (libc)Truncating Strings.
* wcrtomb: (libc)Converting a Character.
* wcscasecmp: (libc)String/Array Comparison.
* wcscat: (libc)Concatenating Strings.
* wcschr: (libc)Search Functions.
* wcschrnul: (libc)Search Functions.
* wcscmp: (libc)String/Array Comparison.
* wcscoll: (libc)Collation Functions.
* wcscpy: (libc)Copying Strings and Arrays.
* wcscspn: (libc)Search Functions.
* wcsdup: (libc)Copying Strings and Arrays.
* wcsftime: (libc)Formatting Calendar Time.
* wcslen: (libc)String Length.
* wcsncasecmp: (libc)String/Array Comparison.
* wcsncat: (libc)Truncating Strings.
* wcsncmp: (libc)String/Array Comparison.
* wcsncpy: (libc)Truncating Strings.
* wcsnlen: (libc)String Length.
* wcsnrtombs: (libc)Converting Strings.
* wcspbrk: (libc)Search Functions.
* wcsrchr: (libc)Search Functions.
* wcsrtombs: (libc)Converting Strings.
* wcsspn: (libc)Search Functions.
* wcsstr: (libc)Search Functions.
* wcstod: (libc)Parsing of Floats.
* wcstof: (libc)Parsing of Floats.
* wcstofN: (libc)Parsing of Floats.
* wcstofNx: (libc)Parsing of Floats.
* wcstoimax: (libc)Parsing of Integers.
* wcstok: (libc)Finding Tokens in a String.
* wcstol: (libc)Parsing of Integers.
* wcstold: (libc)Parsing of Floats.
* wcstoll: (libc)Parsing of Integers.
* wcstombs: (libc)Non-reentrant String Conversion.
* wcstoq: (libc)Parsing of Integers.
* wcstoul: (libc)Parsing of Integers.
* wcstoull: (libc)Parsing of Integers.
* wcstoumax: (libc)Parsing of Integers.
* wcstouq: (libc)Parsing of Integers.
* wcswcs: (libc)Search Functions.
* wcsxfrm: (libc)Collation Functions.
* wctob: (libc)Converting a Character.
* wctomb: (libc)Non-reentrant Character Conversion.
* wctrans: (libc)Wide Character Case Conversion.
* wctype: (libc)Classification of Wide Characters.
* wmemchr: (libc)Search Functions.
* wmemcmp: (libc)String/Array Comparison.
* wmemcpy: (libc)Copying Strings and Arrays.
* wmemmove: (libc)Copying Strings and Arrays.
* wmempcpy: (libc)Copying Strings and Arrays.
* wmemset: (libc)Copying Strings and Arrays.
* wordexp: (libc)Calling Wordexp.
* wordfree: (libc)Calling Wordexp.
* wprintf: (libc)Formatted Output Functions.
* write: (libc)I/O Primitives.
* writev: (libc)Scatter-Gather.
* wscanf: (libc)Formatted Input Functions.
* y0: (libc)Special Functions.
* y0f: (libc)Special Functions.
* y0fN: (libc)Special Functions.
* y0fNx: (libc)Special Functions.
* y0l: (libc)Special Functions.
* y1: (libc)Special Functions.
* y1f: (libc)Special Functions.
* y1fN: (libc)Special Functions.
* y1fNx: (libc)Special Functions.
* y1l: (libc)Special Functions.
* yn: (libc)Special Functions.
* ynf: (libc)Special Functions.
* ynfN: (libc)Special Functions.
* ynfNx: (libc)Special Functions.
* ynl: (libc)Special Functions.
END-INFO-DIR-ENTRY

File: libc.info, Node: General Time String Parsing, Prev: Low-Level Time String Parsing, Up: Parsing Date and Time
21.4.6.2 A More User-friendly Way to Parse Times and Dates
..........................................................
The Unix standard defines another function for parsing date strings.
The interface is weird, but if the function happens to suit your
application it is just fine. It is problematic to use this function in
multi-threaded programs or libraries, since it returns a pointer to a
static variable, and uses a global variable and global state (an
environment variable).
-- Variable: getdate_err
This variable of type int contains the error code of the last
unsuccessful call to getdate. Defined values are:
1
The environment variable DATEMSK is not defined or null.
2
The template file denoted by the DATEMSK environment
variable cannot be opened.
3
Information about the template file cannot retrieved.
4
The template file is not a regular file.
5
An I/O error occurred while reading the template file.
6
Not enough memory available to execute the function.
7
The template file contains no matching template.
8
The input date is invalid, but would match a template
otherwise. This includes dates like February 31st, and dates
which cannot be represented in a time_t variable.
-- Function: struct tm * getdate (const char *STRING)
Preliminary: | MT-Unsafe race:getdate env locale | AS-Unsafe heap
lock | AC-Unsafe lock mem fd | *Note POSIX Safety Concepts::.
The interface to getdate is the simplest possible for a function
to parse a string and return the value. STRING is the input string
and the result is returned in a statically-allocated variable.
The details about how the string is processed are hidden from the
user. In fact, they can be outside the control of the program.
Which formats are recognized is controlled by the file named by the
environment variable DATEMSK. This file should contain lines of
valid format strings which could be passed to strptime.
The getdate function reads these format strings one after the
other and tries to match the input string. The first line which
completely matches the input string is used.
Elements not initialized through the format string retain the
values present at the time of the getdate function call.
The formats recognized by getdate are the same as for strptime.
See above for an explanation. There are only a few extensions to
the strptime behavior:
• If the %Z format is given the broken-down time is based on
the current time of the timezone matched, not of the current
timezone of the runtime environment.
_Note_: This is not implemented (currently). The problem is
that timezone names are not unique. If a fixed timezone is
assumed for a given string (say EST meaning US East Coast
time), then uses for countries other than the USA will fail.
So far we have found no good solution to this.
• If only the weekday is specified the selected day depends on
the current date. If the current weekday is greater than or
equal to the tm_wday value the current weeks day is chosen,
otherwise the day next week is chosen.
• A similar heuristic is used when only the month is given and
not the year. If the month is greater than or equal to the
current month, then the current year is used. Otherwise it
wraps to next year. The first day of the month is assumed if
one is not explicitly specified.
• The current hour, minute, and second are used if the
appropriate value is not set through the format.
• If no date is given tomorrows date is used if the time is
smaller than the current time. Otherwise todays date is
taken.
It should be noted that the format in the template file need not
only contain format elements. The following is a list of possible
format strings (taken from the Unix standard):
%m
%A %B %d, %Y %H:%M:%S
%A
%B
%m/%d/%y %I %p
%d,%m,%Y %H:%M
at %A the %dst of %B in %Y
run job at %I %p,%B %dnd
%A den %d. %B %Y %H.%M Uhr
As you can see, the template list can contain very specific strings
like run job at %I %p,%B %dnd. Using the above list of templates
and assuming the current time is Mon Sep 22 12:19:47 EDT 1986, we
can obtain the following results for the given input.
Input Match Result
Mon %a Mon Sep 22 12:19:47 EDT 1986
Sun %a Sun Sep 28 12:19:47 EDT 1986
Fri %a Fri Sep 26 12:19:47 EDT 1986
September %B Mon Sep 1 12:19:47 EDT 1986
January %B Thu Jan 1 12:19:47 EST 1987
December %B Mon Dec 1 12:19:47 EST 1986
Sep Mon %b %a Mon Sep 1 12:19:47 EDT 1986
Jan Fri %b %a Fri Jan 2 12:19:47 EST 1987
Dec Mon %b %a Mon Dec 1 12:19:47 EST 1986
Jan Wed 1989 %b %a %Y Wed Jan 4 12:19:47 EST 1989
Fri 9 %a %H Fri Sep 26 09:00:00 EDT 1986
Feb 10:30 %b %H:%S Sun Feb 1 10:00:30 EST 1987
10:30 %H:%M Tue Sep 23 10:30:00 EDT 1986
13:30 %H:%M Mon Sep 22 13:30:00 EDT 1986
The return value of the function is a pointer to a static variable
of type struct tm, or a null pointer if an error occurred. The
result is only valid until the next getdate call, making this
function unusable in multi-threaded applications.
The errno variable is _not_ changed. Error conditions are stored
in the global variable getdate_err. See the description above
for a list of the possible error values.
_Warning:_ The getdate function should _never_ be used in
SUID-programs. The reason is obvious: using the DATEMSK
environment variable you can get the function to open any arbitrary
file and chances are high that with some bogus input (such as a
binary file) the program will crash.
-- Function: int getdate_r (const char *STRING, struct tm *TP)
Preliminary: | MT-Safe env locale | AS-Unsafe heap lock | AC-Unsafe
lock mem fd | *Note POSIX Safety Concepts::.
The getdate_r function is the reentrant counterpart of getdate.
It does not use the global variable getdate_err to signal an
error, but instead returns an error code. The same error codes as
described in the getdate_err documentation above are used, with 0
meaning success.
Moreover, getdate_r stores the broken-down time in the variable
of type struct tm pointed to by the second argument, rather than
in a static variable.
This function is not defined in the Unix standard. Nevertheless it
is available on some other Unix systems as well.
The warning against using getdate in SUID-programs applies to
getdate_r as well.

File: libc.info, Node: TZ Variable, Next: Time Zone Functions, Prev: Parsing Date and Time, Up: Calendar Time
21.4.7 Specifying the Time Zone with TZ
-----------------------------------------
In POSIX systems, a user can specify the time zone by means of the TZ
environment variable. For information about how to set environment
variables, see *note Environment Variables::. The functions for
accessing the time zone are declared in time.h.
You should not normally need to set TZ. If the system is
configured properly, the default time zone will be correct. You might
set TZ if you are using a computer over a network from a different
time zone, and would like times reported to you in the time zone local
to you, rather than what is local to the computer.
In POSIX.1 systems the value of the TZ variable can be in one of
three formats. With the GNU C Library, the most common format is the
last one, which can specify a selection from a large database of time
zone information for many regions of the world. The first two formats
are used to describe the time zone information directly, which is both
more cumbersome and less precise. But the POSIX.1 standard only
specifies the details of the first two formats, so it is good to be
familiar with them in case you come across a POSIX.1 system that doesnt
support a time zone information database.
The first format is used when there is no Daylight Saving Time (or
summer time) in the local time zone:
STD OFFSET
The STD string specifies the name of the time zone. It must be three
or more characters long and must not contain a leading colon, embedded
digits, commas, nor plus and minus signs. There is no space character
separating the time zone name from the OFFSET, so these restrictions are
necessary to parse the specification correctly.
The OFFSET specifies the time value you must add to the local time to
get a Coordinated Universal Time value. It has syntax like
[+|-]HH[:MM[:SS]]. This is positive if the local time zone is
west of the Prime Meridian and negative if it is east. The hour must be
between 0 and 24, and the minute and seconds between 0 and 59.
For example, here is how we would specify Eastern Standard Time, but
without any Daylight Saving Time alternative:
EST+5
The second format is used when there is Daylight Saving Time:
STD OFFSET DST [OFFSET],START[/TIME],END[/TIME]
The initial STD and OFFSET specify the standard time zone, as
described above. The DST string and OFFSET specify the name and offset
for the corresponding Daylight Saving Time zone; if the OFFSET is
omitted, it defaults to one hour ahead of standard time.
The remainder of the specification describes when Daylight Saving
Time is in effect. The START field is when Daylight Saving Time goes
into effect and the END field is when the change is made back to
standard time. The following formats are recognized for these fields:
JN
This specifies the Julian day, with N between 1 and 365.
February 29 is never counted, even in leap years.
N
This specifies the Julian day, with N between 0 and 365.
February 29 is counted in leap years.
MM.W.D
This specifies day D of week W of month M. The day D must be
between 0 (Sunday) and 6. The week W must be between 1 and
5; week 1 is the first week in which day D occurs, and week 5
specifies the _last_ D day in the month. The month M should be
between 1 and 12.
The TIME fields specify when, in the local time currently in effect,
the change to the other time occurs. If omitted, the default is
02:00:00. The hours part of the time fields can range from 167
through 167; this is an extension to POSIX.1, which allows only the
range 0 through 24.
Here are some example TZ values, including the appropriate Daylight
Saving Time and its dates of applicability. In North American Eastern
Standard Time (EST) and Eastern Daylight Time (EDT), the normal offset
from UTC is 5 hours; since this is west of the prime meridian, the sign
is positive. Summer time begins on Marchs second Sunday at 2:00am, and
ends on Novembers first Sunday at 2:00am.
EST+5EDT,M3.2.0/2,M11.1.0/2
Israel Standard Time (IST) and Israel Daylight Time (IDT) are 2 hours
ahead of the prime meridian in winter, springing forward an hour on
Marchs fourth Thursday at 26:00 (i.e., 02:00 on the first Friday on or
after March 23), and falling back on Octobers last Sunday at 02:00.
IST-2IDT,M3.4.4/26,M10.5.0
Western Argentina Summer Time (WARST) is 3 hours behind the prime
meridian all year. There is a dummy fall-back transition on December 31
at 25:00 daylight saving time (i.e., 24:00 standard time, equivalent to
January 1 at 00:00 standard time), and a simultaneous spring-forward
transition on January 1 at 00:00 standard time, so daylight saving time
is in effect all year and the initial WART is a placeholder.
WART4WARST,J1/0,J365/25
Western Greenland Time (WGT) and Western Greenland Summer Time (WGST)
are 3 hours behind UTC in the winter. Its clocks follow the European
Union rules of springing forward by one hour on Marchs last Sunday at
01:00 UTC (02:00 local time) and falling back on Octobers last Sunday
at 01:00 UTC (01:00 local time).
WGT3WGST,M3.5.0/-2,M10.5.0/-1
The schedule of Daylight Saving Time in any particular jurisdiction
has changed over the years. To be strictly correct, the conversion of
dates and times in the past should be based on the schedule that was in
effect then. However, this format has no facilities to let you specify
how the schedule has changed from year to year. The most you can do is
specify one particular schedule—usually the present day schedule—and
this is used to convert any date, no matter when. For precise time zone
specifications, it is best to use the time zone information database
(see below).
The third format looks like this:
:CHARACTERS
Each operating system interprets this format differently; in the GNU
C Library, CHARACTERS is the name of a file which describes the time
zone.
If the TZ environment variable does not have a value, the operation
chooses a time zone by default. In the GNU C Library, the default time
zone is like the specification TZ=:/etc/localtime (or
TZ=:/usr/local/etc/localtime, depending on how the GNU C Library was
configured; *note Installation::). Other C libraries use their own rule
for choosing the default time zone, so there is little we can say about
them.
If CHARACTERS begins with a slash, it is an absolute file name;
otherwise the library looks for the file
/usr/share/zoneinfo/CHARACTERS. The zoneinfo directory contains
data files describing local time zones in many different parts of the
world. The names represent major cities, with subdirectories for
geographical areas; for example, America/New_York, Europe/London,
Asia/Hong_Kong. These data files are installed by the system
administrator, who also sets /etc/localtime to point to the data file
for the local time zone. The files typically come from the Time Zone
Database (http://www.iana.org/time-zones) of time zone and daylight
saving time information for most regions of the world, which is
maintained by a community of volunteers and put in the public domain.

File: libc.info, Node: Time Zone Functions, Next: Time Functions Example, Prev: TZ Variable, Up: Calendar Time
21.4.8 Functions and Variables for Time Zones
---------------------------------------------
-- Variable: char * tzname [2]
The array tzname contains two strings, which are the standard
names of the pair of time zones (standard and Daylight Saving) that
the user has selected. tzname[0] is the name of the standard
time zone (for example, "EST"), and tzname[1] is the name for
the time zone when Daylight Saving Time is in use (for example,
"EDT"). These correspond to the STD and DST strings
(respectively) from the TZ environment variable. If Daylight
Saving Time is never used, tzname[1] is the empty string.
The tzname array is initialized from the TZ environment
variable whenever tzset, ctime, strftime, mktime, or
localtime is called. If multiple abbreviations have been used
(e.g. "EWT" and "EDT" for U.S. Eastern War Time and Eastern
Daylight Time), the array contains the most recent abbreviation.
The tzname array is required for POSIX.1 compatibility, but in
GNU programs it is better to use the tm_zone member of the
broken-down time structure, since tm_zone reports the correct
abbreviation even when it is not the latest one.
Though the strings are declared as char * the user must refrain
from modifying these strings. Modifying the strings will almost
certainly lead to trouble.
-- Function: void tzset (void)
Preliminary: | MT-Safe env locale | AS-Unsafe heap lock | AC-Unsafe
lock mem fd | *Note POSIX Safety Concepts::.
The tzset function initializes the tzname variable from the
value of the TZ environment variable. It is not usually
necessary for your program to call this function, because it is
called automatically when you use the other time conversion
functions that depend on the time zone.
The following variables are defined for compatibility with System V
Unix. Like tzname, these variables are set by calling tzset or the
other time conversion functions.
-- Variable: long int timezone
This contains the difference between UTC and the latest local
standard time, in seconds west of UTC. For example, in the U.S.
Eastern time zone, the value is 5*60*60. Unlike the tm_gmtoff
member of the broken-down time structure, this value is not
adjusted for daylight saving, and its sign is reversed. In GNU
programs it is better to use tm_gmtoff, since it contains the
correct offset even when it is not the latest one.
-- Variable: int daylight
This variable has a nonzero value if Daylight Saving Time rules
apply. A nonzero value does not necessarily mean that Daylight
Saving Time is now in effect; it means only that Daylight Saving
Time is sometimes in effect.

File: libc.info, Node: Time Functions Example, Prev: Time Zone Functions, Up: Calendar Time
21.4.9 Time Functions Example
-----------------------------
Here is an example program showing the use of some of the calendar time
functions.
#include <time.h>
#include <stdio.h>
#define SIZE 256
int
main (void)
{
char buffer[SIZE];
time_t curtime;
struct tm *loctime;
/* Get the current time. */
curtime = time (NULL);
/* Convert it to local time representation. */
loctime = localtime (&curtime);
/* Print out the date and time in the standard format. */
fputs (asctime (loctime), stdout);
/* Print it out in a nice format. */
strftime (buffer, SIZE, "Today is %A, %B %d.\n", loctime);
fputs (buffer, stdout);
strftime (buffer, SIZE, "The time is %I:%M %p.\n", loctime);
fputs (buffer, stdout);
return 0;
}
It produces output like this:
Wed Jul 31 13:02:36 1991
Today is Wednesday, July 31.
The time is 01:02 PM.

File: libc.info, Node: Setting an Alarm, Next: Sleeping, Prev: Calendar Time, Up: Date and Time
21.5 Setting an Alarm
=====================
The alarm and setitimer functions provide a mechanism for a process
to interrupt itself in the future. They do this by setting a timer;
when the timer expires, the process receives a signal.
Each process has three independent interval timers available:
• A real-time timer that counts elapsed time. This timer sends a
SIGALRM signal to the process when it expires.
• A virtual timer that counts processor time used by the process.
This timer sends a SIGVTALRM signal to the process when it
expires.
• A profiling timer that counts both processor time used by the
process, and processor time spent in system calls on behalf of the
process. This timer sends a SIGPROF signal to the process when
it expires.
This timer is useful for profiling in interpreters. The interval
timer mechanism does not have the fine granularity necessary for
profiling native code.
You can only have one timer of each kind set at any given time. If
you set a timer that has not yet expired, that timer is simply reset to
the new value.
You should establish a handler for the appropriate alarm signal using
signal or sigaction before issuing a call to setitimer or alarm.
Otherwise, an unusual chain of events could cause the timer to expire
before your program establishes the handler. In this case it would be
terminated, since termination is the default action for the alarm
signals. *Note Signal Handling::.
To be able to use the alarm function to interrupt a system call which
might block otherwise indefinitely it is important to _not_ set the
SA_RESTART flag when registering the signal handler using sigaction.
When not using sigaction things get even uglier: the signal function
has fixed semantics with respect to restarts. The BSD semantics for
this function is to set the flag. Therefore, if sigaction for
whatever reason cannot be used, it is necessary to use sysv_signal and
not signal.
The setitimer function is the primary means for setting an alarm.
This facility is declared in the header file sys/time.h. The alarm
function, declared in unistd.h, provides a somewhat simpler interface
for setting the real-time timer.
-- Data Type: struct itimerval
This structure is used to specify when a timer should expire. It
contains the following members:
struct timeval it_interval
This is the period between successive timer interrupts. If
zero, the alarm will only be sent once.
struct timeval it_value
This is the period between now and the first timer interrupt.
If zero, the alarm is disabled.
The struct timeval data type is described in *note Elapsed
Time::.
-- Function: int setitimer (int WHICH, const struct itimerval *NEW,
struct itimerval *OLD)
Preliminary: | MT-Safe timer | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The setitimer function sets the timer specified by WHICH
according to NEW. The WHICH argument can have a value of
ITIMER_REAL, ITIMER_VIRTUAL, or ITIMER_PROF.
If OLD is not a null pointer, setitimer returns information about
any previous unexpired timer of the same kind in the structure it
points to.
The return value is 0 on success and -1 on failure. The
following errno error conditions are defined for this function:
EINVAL
The timer period is too large.
-- Function: int getitimer (int WHICH, struct itimerval *OLD)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The getitimer function stores information about the timer
specified by WHICH in the structure pointed at by OLD.
The return value and error conditions are the same as for
setitimer.
ITIMER_REAL
This constant can be used as the WHICH argument to the setitimer
and getitimer functions to specify the real-time timer.
ITIMER_VIRTUAL
This constant can be used as the WHICH argument to the setitimer
and getitimer functions to specify the virtual timer.
ITIMER_PROF
This constant can be used as the WHICH argument to the setitimer
and getitimer functions to specify the profiling timer.
-- Function: unsigned int alarm (unsigned int SECONDS)
Preliminary: | MT-Safe timer | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The alarm function sets the real-time timer to expire in SECONDS
seconds. If you want to cancel any existing alarm, you can do this
by calling alarm with a SECONDS argument of zero.
The return value indicates how many seconds remain before the
previous alarm would have been sent. If there was no previous
alarm, alarm returns zero.
The alarm function could be defined in terms of setitimer like
this:
unsigned int
alarm (unsigned int seconds)
{
struct itimerval old, new;
new.it_interval.tv_usec = 0;
new.it_interval.tv_sec = 0;
new.it_value.tv_usec = 0;
new.it_value.tv_sec = (long int) seconds;
if (setitimer (ITIMER_REAL, &new, &old) < 0)
return 0;
else
return old.it_value.tv_sec;
}
There is an example showing the use of the alarm function in *note
Handler Returns::.
If you simply want your process to wait for a given number of
seconds, you should use the sleep function. *Note Sleeping::.
You shouldnt count on the signal arriving precisely when the timer
expires. In a multiprocessing environment there is typically some
amount of delay involved.
*Portability Note:* The setitimer and getitimer functions are
derived from BSD Unix, while the alarm function is specified by the
POSIX.1 standard. setitimer is more powerful than alarm, but
alarm is more widely used.

File: libc.info, Node: Sleeping, Prev: Setting an Alarm, Up: Date and Time
21.6 Sleeping
=============
The function sleep gives a simple way to make the program wait for a
short interval. If your program doesnt use signals (except to
terminate), then you can expect sleep to wait reliably throughout the
specified interval. Otherwise, sleep can return sooner if a signal
arrives; if you want to wait for a given interval regardless of signals,
use select (*note Waiting for I/O::) and dont specify any descriptors
to wait for.
-- Function: unsigned int sleep (unsigned int SECONDS)
Preliminary: | MT-Unsafe sig:SIGCHLD/linux | AS-Unsafe | AC-Unsafe
| *Note POSIX Safety Concepts::.
The sleep function waits for SECONDS seconds or until a signal is
delivered, whichever happens first.
If sleep returns because the requested interval is over, it
returns a value of zero. If it returns because of delivery of a
signal, its return value is the remaining time in the sleep
interval.
The sleep function is declared in unistd.h.
Resist the temptation to implement a sleep for a fixed amount of time
by using the return value of sleep, when nonzero, to call sleep
again. This will work with a certain amount of accuracy as long as
signals arrive infrequently. But each signal can cause the eventual
wakeup time to be off by an additional second or so. Suppose a few
signals happen to arrive in rapid succession by bad luck—there is no
limit on how much this could shorten or lengthen the wait.
Instead, compute the calendar time at which the program should stop
waiting, and keep trying to wait until that calendar time. This wont
be off by more than a second. With just a little more work, you can use
select and make the waiting period quite accurate. (Of course, heavy
system load can cause additional unavoidable delays—unless the machine
is dedicated to one application, there is no way you can avoid this.)
On some systems, sleep can do strange things if your program uses
SIGALRM explicitly. Even if SIGALRM signals are being ignored or
blocked when sleep is called, sleep might return prematurely on
delivery of a SIGALRM signal. If you have established a handler for
SIGALRM signals and a SIGALRM signal is delivered while the process
is sleeping, the action taken might be just to cause sleep to return
instead of invoking your handler. And, if sleep is interrupted by
delivery of a signal whose handler requests an alarm or alters the
handling of SIGALRM, this handler and sleep will interfere.
On GNU systems, it is safe to use sleep and SIGALRM in the same
program, because sleep does not work by means of SIGALRM.
-- Function: int nanosleep (const struct timespec *REQUESTED_TIME,
struct timespec *REMAINING)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
If resolution to seconds is not enough the nanosleep function can
be used. As the name suggests the sleep interval can be specified
in nanoseconds. The actual elapsed time of the sleep interval
might be longer since the system rounds the elapsed time you
request up to the next integer multiple of the actual resolution
the system can deliver.
*requested_time is the elapsed time of the interval you want to
sleep.
The function returns as *remaining the elapsed time left in the
interval for which you requested to sleep. If the interval
completed without getting interrupted by a signal, this is zero.
struct timespec is described in *Note Elapsed Time::.
If the function returns because the interval is over the return
value is zero. If the function returns -1 the global variable
ERRNO is set to the following values:
EINTR
The call was interrupted because a signal was delivered to the
thread. If the REMAINING parameter is not the null pointer
the structure pointed to by REMAINING is updated to contain
the remaining elapsed time.
EINVAL
The nanosecond value in the REQUESTED_TIME parameter contains
an illegal value. Either the value is negative or greater
than or equal to 1000 million.
This function is a cancellation point in multi-threaded programs.
This is a problem if the thread allocates some resources (like
memory, file descriptors, semaphores or whatever) at the time
nanosleep is called. If the thread gets canceled these resources
stay allocated until the program ends. To avoid this calls to
nanosleep should be protected using cancellation handlers.
The nanosleep function is declared in time.h.

File: libc.info, Node: Resource Usage And Limitation, Next: Non-Local Exits, Prev: Date and Time, Up: Top
22 Resource Usage And Limitation
********************************
This chapter describes functions for examining how much of various kinds
of resources (CPU time, memory, etc.) a process has used and getting
and setting limits on future usage.
* Menu:
* Resource Usage:: Measuring various resources used.
* Limits on Resources:: Specifying limits on resource usage.
* Priority:: Reading or setting process run priority.
* Memory Resources:: Querying memory available resources.
* Processor Resources:: Learn about the processors available.

File: libc.info, Node: Resource Usage, Next: Limits on Resources, Up: Resource Usage And Limitation
22.1 Resource Usage
===================
The function getrusage and the data type struct rusage are used to
examine the resource usage of a process. They are declared in
sys/resource.h.
-- Function: int getrusage (int PROCESSES, struct rusage *RUSAGE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function reports resource usage totals for processes specified
by PROCESSES, storing the information in *RUSAGE.
In most systems, PROCESSES has only two valid values:
RUSAGE_SELF
Just the current process.
RUSAGE_CHILDREN
All child processes (direct and indirect) that have already
terminated.
The return value of getrusage is zero for success, and -1 for
failure.
EINVAL
The argument PROCESSES is not valid.
One way of getting resource usage for a particular child process is
with the function wait4, which returns totals for a child when it
terminates. *Note BSD Wait Functions::.
-- Data Type: struct rusage
This data type stores various resource usage statistics. It has
the following members, and possibly others:
struct timeval ru_utime
Time spent executing user instructions.
struct timeval ru_stime
Time spent in operating system code on behalf of PROCESSES.
long int ru_maxrss
The maximum resident set size used, in kilobytes. That is,
the maximum number of kilobytes of physical memory that
PROCESSES used simultaneously.
long int ru_ixrss
An integral value expressed in kilobytes times ticks of
execution, which indicates the amount of memory used by text
that was shared with other processes.
long int ru_idrss
An integral value expressed the same way, which is the amount
of unshared memory used for data.
long int ru_isrss
An integral value expressed the same way, which is the amount
of unshared memory used for stack space.
long int ru_minflt
The number of page faults which were serviced without
requiring any I/O.
long int ru_majflt
The number of page faults which were serviced by doing I/O.
long int ru_nswap
The number of times PROCESSES was swapped entirely out of main
memory.
long int ru_inblock
The number of times the file system had to read from the disk
on behalf of PROCESSES.
long int ru_oublock
The number of times the file system had to write to the disk
on behalf of PROCESSES.
long int ru_msgsnd
Number of IPC messages sent.
long int ru_msgrcv
Number of IPC messages received.
long int ru_nsignals
Number of signals received.
long int ru_nvcsw
The number of times PROCESSES voluntarily invoked a context
switch (usually to wait for some service).
long int ru_nivcsw
The number of times an involuntary context switch took place
(because a time slice expired, or another process of higher
priority was scheduled).
vtimes is a historical function that does some of what getrusage
does. getrusage is a better choice.
vtimes and its vtimes data structure are declared in
sys/vtimes.h.
-- Function: int vtimes (struct vtimes *CURRENT, struct vtimes *CHILD)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
vtimes reports resource usage totals for a process.
If CURRENT is non-null, vtimes stores resource usage totals for
the invoking process alone in the structure to which it points. If
CHILD is non-null, vtimes stores resource usage totals for all
past children (which have terminated) of the invoking process in
the structure to which it points.
-- Data Type: struct vtimes
This data type contains information about the resource usage
of a process. Each member corresponds to a member of the
struct rusage data type described above.
vm_utime
User CPU time. Analogous to ru_utime in struct
rusage
vm_stime
System CPU time. Analogous to ru_stime in struct
rusage
vm_idsrss
Data and stack memory. The sum of the values that would
be reported as ru_idrss and ru_isrss in struct
rusage
vm_ixrss
Shared memory. Analogous to ru_ixrss in struct
rusage
vm_maxrss
Maximent resident set size. Analogous to ru_maxrss in
struct rusage
vm_majflt
Major page faults. Analogous to ru_majflt in struct
rusage
vm_minflt
Minor page faults. Analogous to ru_minflt in struct
rusage
vm_nswap
Swap count. Analogous to ru_nswap in struct rusage
vm_inblk
Disk reads. Analogous to ru_inblk in struct rusage
vm_oublk
Disk writes. Analogous to ru_oublk in struct rusage
The return value is zero if the function succeeds; -1 otherwise.
An additional historical function for examining resource usage,
vtimes, is supported but not documented here. It is declared in
sys/vtimes.h.

File: libc.info, Node: Limits on Resources, Next: Priority, Prev: Resource Usage, Up: Resource Usage And Limitation
22.2 Limiting Resource Usage
============================
You can specify limits for the resource usage of a process. When the
process tries to exceed a limit, it may get a signal, or the system call
by which it tried to do so may fail, depending on the resource. Each
process initially inherits its limit values from its parent, but it can
subsequently change them.
There are two per-process limits associated with a resource:
“current limit”
The current limit is the value the system will not allow usage to
exceed. It is also called the “soft limit” because the process
being limited can generally raise the current limit at will.
“maximum limit”
The maximum limit is the maximum value to which a process is
allowed to set its current limit. It is also called the “hard
limit” because there is no way for a process to get around it. A
process may lower its own maximum limit, but only the superuser may
increase a maximum limit.
The symbols for use with getrlimit, setrlimit, getrlimit64, and
setrlimit64 are defined in sys/resource.h.
-- Function: int getrlimit (int RESOURCE, struct rlimit *RLP)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
Read the current and maximum limits for the resource RESOURCE and
store them in *RLP.
The return value is 0 on success and -1 on failure. The only
possible errno error condition is EFAULT.
When the sources are compiled with _FILE_OFFSET_BITS == 64 on a
32-bit system this function is in fact getrlimit64. Thus, the
LFS interface transparently replaces the old interface.
-- Function: int getrlimit64 (int RESOURCE, struct rlimit64 *RLP)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is similar to getrlimit but its second parameter is
a pointer to a variable of type struct rlimit64, which allows it
to read values which wouldnt fit in the member of a struct
rlimit.
If the sources are compiled with _FILE_OFFSET_BITS == 64 on a
32-bit machine, this function is available under the name
getrlimit and so transparently replaces the old interface.
-- Function: int setrlimit (int RESOURCE, const struct rlimit *RLP)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
Store the current and maximum limits for the resource RESOURCE in
*RLP.
The return value is 0 on success and -1 on failure. The
following errno error condition is possible:
EPERM
• The process tried to raise a current limit beyond the
maximum limit.
• The process tried to raise a maximum limit, but is not
superuser.
When the sources are compiled with _FILE_OFFSET_BITS == 64 on a
32-bit system this function is in fact setrlimit64. Thus, the
LFS interface transparently replaces the old interface.
-- Function: int setrlimit64 (int RESOURCE, const struct rlimit64 *RLP)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is similar to setrlimit but its second parameter is
a pointer to a variable of type struct rlimit64 which allows it
to set values which wouldnt fit in the member of a struct
rlimit.
If the sources are compiled with _FILE_OFFSET_BITS == 64 on a
32-bit machine this function is available under the name
setrlimit and so transparently replaces the old interface.
-- Data Type: struct rlimit
This structure is used with getrlimit to receive limit values,
and with setrlimit to specify limit values for a particular
process and resource. It has two fields:
rlim_t rlim_cur
The current limit
rlim_t rlim_max
The maximum limit.
For getrlimit, the structure is an output; it receives the
current values. For setrlimit, it specifies the new values.
For the LFS functions a similar type is defined in sys/resource.h.
-- Data Type: struct rlimit64
This structure is analogous to the rlimit structure above, but
its components have wider ranges. It has two fields:
rlim64_t rlim_cur
This is analogous to rlimit.rlim_cur, but with a different
type.
rlim64_t rlim_max
This is analogous to rlimit.rlim_max, but with a different
type.
Here is a list of resources for which you can specify a limit.
Memory and file sizes are measured in bytes.
RLIMIT_CPU
The maximum amount of CPU time the process can use. If it runs for
longer than this, it gets a signal: SIGXCPU. The value is
measured in seconds. *Note Operation Error Signals::.
RLIMIT_FSIZE
The maximum size of file the process can create. Trying to write a
larger file causes a signal: SIGXFSZ. *Note Operation Error
Signals::.
RLIMIT_DATA
The maximum size of data memory for the process. If the process
tries to allocate data memory beyond this amount, the allocation
function fails.
RLIMIT_STACK
The maximum stack size for the process. If the process tries to
extend its stack past this size, it gets a SIGSEGV signal. *Note
Program Error Signals::.
RLIMIT_CORE
The maximum size core file that this process can create. If the
process terminates and would dump a core file larger than this,
then no core file is created. So setting this limit to zero
prevents core files from ever being created.
RLIMIT_RSS
The maximum amount of physical memory that this process should get.
This parameter is a guide for the systems scheduler and memory
allocator; the system may give the process more memory when there
is a surplus.
RLIMIT_MEMLOCK
The maximum amount of memory that can be locked into physical
memory (so it will never be paged out).
RLIMIT_NPROC
The maximum number of processes that can be created with the same
user ID. If you have reached the limit for your user ID, fork
will fail with EAGAIN. *Note Creating a Process::.
RLIMIT_NOFILE
RLIMIT_OFILE
The maximum number of files that the process can open. If it tries
to open more files than this, its open attempt fails with errno
EMFILE. *Note Error Codes::. Not all systems support this
limit; GNU does, and 4.4 BSD does.
RLIMIT_AS
The maximum size of total memory that this process should get. If
the process tries to allocate more memory beyond this amount with,
for example, brk, malloc, mmap or sbrk, the allocation
function fails.
RLIM_NLIMITS
The number of different resource limits. Any valid RESOURCE
operand must be less than RLIM_NLIMITS.
-- Constant: rlim_t RLIM_INFINITY
This constant stands for a value of “infinity” when supplied as the
limit value in setrlimit.
The following are historical functions to do some of what the
functions above do. The functions above are better choices.
ulimit and the command symbols are declared in ulimit.h.
-- Function: long int ulimit (int CMD, ...)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
ulimit gets the current limit or sets the current and maximum
limit for a particular resource for the calling process according
to the command CMD.
If you are getting a limit, the command argument is the only
argument. If you are setting a limit, there is a second argument:
long int LIMIT which is the value to which you are setting the
limit.
The CMD values and the operations they specify are:
GETFSIZE
Get the current limit on the size of a file, in units of 512
bytes.
SETFSIZE
Set the current and maximum limit on the size of a file to
LIMIT * 512 bytes.
There are also some other CMD values that may do things on some
systems, but they are not supported.
Only the superuser may increase a maximum limit.
When you successfully get a limit, the return value of ulimit is
that limit, which is never negative. When you successfully set a
limit, the return value is zero. When the function fails, the
return value is -1 and errno is set according to the reason:
EPERM
A process tried to increase a maximum limit, but is not
superuser.
vlimit and its resource symbols are declared in sys/vlimit.h.
-- Function: int vlimit (int RESOURCE, int LIMIT)
Preliminary: | MT-Unsafe race:setrlimit | AS-Unsafe | AC-Safe |
*Note POSIX Safety Concepts::.
vlimit sets the current limit for a resource for a process.
RESOURCE identifies the resource:
LIM_CPU
Maximum CPU time. Same as RLIMIT_CPU for setrlimit.
LIM_FSIZE
Maximum file size. Same as RLIMIT_FSIZE for setrlimit.
LIM_DATA
Maximum data memory. Same as RLIMIT_DATA for setrlimit.
LIM_STACK
Maximum stack size. Same as RLIMIT_STACK for setrlimit.
LIM_CORE
Maximum core file size. Same as RLIMIT_COR for setrlimit.
LIM_MAXRSS
Maximum physical memory. Same as RLIMIT_RSS for
setrlimit.
The return value is zero for success, and -1 with errno set
accordingly for failure:
EPERM
The process tried to set its current limit beyond its maximum
limit.

File: libc.info, Node: Priority, Next: Memory Resources, Prev: Limits on Resources, Up: Resource Usage And Limitation
22.3 Process CPU Priority And Scheduling
========================================
When multiple processes simultaneously require CPU time, the systems
scheduling policy and process CPU priorities determine which processes
get it. This section describes how that determination is made and GNU C
Library functions to control it.
It is common to refer to CPU scheduling simply as scheduling and a
process CPU priority simply as the process priority, with the CPU
resource being implied. Bear in mind, though, that CPU time is not the
only resource a process uses or that processes contend for. In some
cases, it is not even particularly important. Giving a process a high
“priority” may have very little effect on how fast a process runs with
respect to other processes. The priorities discussed in this section
apply only to CPU time.
CPU scheduling is a complex issue and different systems do it in
wildly different ways. New ideas continually develop and find their way
into the intricacies of the various systems scheduling algorithms.
This section discusses the general concepts, some specifics of systems
that commonly use the GNU C Library, and some standards.
For simplicity, we talk about CPU contention as if there is only one
CPU in the system. But all the same principles apply when a processor
has multiple CPUs, and knowing that the number of processes that can run
at any one time is equal to the number of CPUs, you can easily
extrapolate the information.
The functions described in this section are all defined by the
POSIX.1 and POSIX.1b standards (the sched... functions are POSIX.1b).
However, POSIX does not define any semantics for the values that these
functions get and set. In this chapter, the semantics are based on the
Linux kernels implementation of the POSIX standard. As you will see,
the Linux implementation is quite the inverse of what the authors of the
POSIX syntax had in mind.
* Menu:
* Absolute Priority:: The first tier of priority. Posix
* Realtime Scheduling:: Scheduling among the process nobility
* Basic Scheduling Functions:: Get/set scheduling policy, priority
* Traditional Scheduling:: Scheduling among the vulgar masses
* CPU Affinity:: Limiting execution to certain CPUs

File: libc.info, Node: Absolute Priority, Next: Realtime Scheduling, Up: Priority
22.3.1 Absolute Priority
------------------------
Every process has an absolute priority, and it is represented by a
number. The higher the number, the higher the absolute priority.
On systems of the past, and most systems today, all processes have
absolute priority 0 and this section is irrelevant. In that case, *Note
Traditional Scheduling::. Absolute priorities were invented to
accommodate realtime systems, in which it is vital that certain
processes be able to respond to external events happening in real time,
which means they cannot wait around while some other process that _wants
to_, but doesnt _need to_ run occupies the CPU.
When two processes are in contention to use the CPU at any instant,
the one with the higher absolute priority always gets it. This is true
even if the process with the lower priority is already using the CPU
(i.e., the scheduling is preemptive). Of course, were only talking
about processes that are running or “ready to run,” which means they are
ready to execute instructions right now. When a process blocks to wait
for something like I/O, its absolute priority is irrelevant.
*NB:* The term “runnable” is a synonym for “ready to run.”
When two processes are running or ready to run and both have the same
absolute priority, its more interesting. In that case, who gets the
CPU is determined by the scheduling policy. If the processes have
absolute priority 0, the traditional scheduling policy described in
*note Traditional Scheduling:: applies. Otherwise, the policies
described in *note Realtime Scheduling:: apply.
You normally give an absolute priority above 0 only to a process that
can be trusted not to hog the CPU. Such processes are designed to block
(or terminate) after relatively short CPU runs.
A process begins life with the same absolute priority as its parent
process. Functions described in *note Basic Scheduling Functions:: can
change it.
Only a privileged process can change a process absolute priority to
something other than 0. Only a privileged process or the target
process owner can change its absolute priority at all.
POSIX requires absolute priority values used with the realtime
scheduling policies to be consecutive with a range of at least 32. On
Linux, they are 1 through 99. The functions sched_get_priority_max
and sched_set_priority_min portably tell you what the range is on a
particular system.
22.3.1.1 Using Absolute Priority
................................
One thing you must keep in mind when designing real time applications is
that having higher absolute priority than any other process doesnt
guarantee the process can run continuously. Two things that can wreck a
good CPU run are interrupts and page faults.
Interrupt handlers live in that limbo between processes. The CPU is
executing instructions, but they arent part of any process. An
interrupt will stop even the highest priority process. So you must
allow for slight delays and make sure that no device in the system has
an interrupt handler that could cause too long a delay between
instructions for your process.
Similarly, a page fault causes what looks like a straightforward
sequence of instructions to take a long time. The fact that other
processes get to run while the page faults in is of no consequence,
because as soon as the I/O is complete, the higher priority process will
kick them out and run again, but the wait for the I/O itself could be a
problem. To neutralize this threat, use mlock or mlockall.
There are a few ramifications of the absoluteness of this priority on
a single-CPU system that you need to keep in mind when you choose to set
a priority and also when youre working on a program that runs with high
absolute priority. Consider a process that has higher absolute priority
than any other process in the system and due to a bug in its program, it
gets into an infinite loop. It will never cede the CPU. You cant run a
command to kill it because your command would need to get the CPU in
order to run. The errant program is in complete control. It controls
the vertical, it controls the horizontal.
There are two ways to avoid this: 1) keep a shell running somewhere
with a higher absolute priority or 2) keep a controlling terminal
attached to the high priority process group. All the priority in the
world wont stop an interrupt handler from running and delivering a
signal to the process if you hit Control-C.
Some systems use absolute priority as a means of allocating a fixed
percentage of CPU time to a process. To do this, a super high priority
privileged process constantly monitors the process CPU usage and raises
its absolute priority when the process isnt getting its entitled share
and lowers it when the process is exceeding it.
*NB:* The absolute priority is sometimes called the “static
priority.” We dont use that term in this manual because it misses the
most important feature of the absolute priority: its absoluteness.

File: libc.info, Node: Realtime Scheduling, Next: Basic Scheduling Functions, Prev: Absolute Priority, Up: Priority
22.3.2 Realtime Scheduling
--------------------------
Whenever two processes with the same absolute priority are ready to run,
the kernel has a decision to make, because only one can run at a time.
If the processes have absolute priority 0, the kernel makes this
decision as described in *note Traditional Scheduling::. Otherwise, the
decision is as described in this section.
If two processes are ready to run but have different absolute
priorities, the decision is much simpler, and is described in *note
Absolute Priority::.
Each process has a scheduling policy. For processes with absolute
priority other than zero, there are two available:
1. First Come First Served
2. Round Robin
The most sensible case is where all the processes with a certain
absolute priority have the same scheduling policy. Well discuss that
first.
In Round Robin, processes share the CPU, each one running for a small
quantum of time (“time slice”) and then yielding to another in a
circular fashion. Of course, only processes that are ready to run and
have the same absolute priority are in this circle.
In First Come First Served, the process that has been waiting the
longest to run gets the CPU, and it keeps it until it voluntarily
relinquishes the CPU, runs out of things to do (blocks), or gets
preempted by a higher priority process.
First Come First Served, along with maximal absolute priority and
careful control of interrupts and page faults, is the one to use when a
process absolutely, positively has to run at full CPU speed or not at
all.
Judicious use of sched_yield function invocations by processes with
First Come First Served scheduling policy forms a good compromise
between Round Robin and First Come First Served.
To understand how scheduling works when processes of different
scheduling policies occupy the same absolute priority, you have to know
the nitty gritty details of how processes enter and exit the ready to
run list.
In both cases, the ready to run list is organized as a true queue,
where a process gets pushed onto the tail when it becomes ready to run
and is popped off the head when the scheduler decides to run it. Note
that ready to run and running are two mutually exclusive states. When
the scheduler runs a process, that process is no longer ready to run and
no longer in the ready to run list. When the process stops running, it
may go back to being ready to run again.
The only difference between a process that is assigned the Round
Robin scheduling policy and a process that is assigned First Come First
Serve is that in the former case, the process is automatically booted
off the CPU after a certain amount of time. When that happens, the
process goes back to being ready to run, which means it enters the queue
at the tail. The time quantum were talking about is small. Really
small. This is not your fathers timesharing. For example, with the
Linux kernel, the round robin time slice is a thousand times shorter
than its typical time slice for traditional scheduling.
A process begins life with the same scheduling policy as its parent
process. Functions described in *note Basic Scheduling Functions:: can
change it.
Only a privileged process can set the scheduling policy of a process
that has absolute priority higher than 0.

File: libc.info, Node: Basic Scheduling Functions, Next: Traditional Scheduling, Prev: Realtime Scheduling, Up: Priority
22.3.3 Basic Scheduling Functions
---------------------------------
This section describes functions in the GNU C Library for setting the
absolute priority and scheduling policy of a process.
*Portability Note:* On systems that have the functions in this
section, the macro _POSIX_PRIORITY_SCHEDULING is defined in
<unistd.h>.
For the case that the scheduling policy is traditional scheduling,
more functions to fine tune the scheduling are in *note Traditional
Scheduling::.
Dont try to make too much out of the naming and structure of these
functions. They dont match the concepts described in this manual
because the functions are as defined by POSIX.1b, but the implementation
on systems that use the GNU C Library is the inverse of what the POSIX
structure contemplates. The POSIX scheme assumes that the primary
scheduling parameter is the scheduling policy and that the priority
value, if any, is a parameter of the scheduling policy. In the
implementation, though, the priority value is king and the scheduling
policy, if anything, only fine tunes the effect of that priority.
The symbols in this section are declared by including file sched.h.
-- Data Type: struct sched_param
This structure describes an absolute priority.
int sched_priority
absolute priority value
-- Function: int sched_setscheduler (pid_t PID, int POLICY, const
struct sched_param *PARAM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function sets both the absolute priority and the scheduling
policy for a process.
It assigns the absolute priority value given by PARAM and the
scheduling policy POLICY to the process with Process ID PID, or the
calling process if PID is zero. If POLICY is negative,
sched_setscheduler keeps the existing scheduling policy.
The following macros represent the valid values for POLICY:
SCHED_OTHER
Traditional Scheduling
SCHED_FIFO
First In First Out
SCHED_RR
Round Robin
On success, the return value is 0. Otherwise, it is -1 and
ERRNO is set accordingly. The errno values specific to this
function are:
EPERM
• The calling process does not have CAP_SYS_NICE
permission and POLICY is not SCHED_OTHER (or its
negative and the existing policy is not SCHED_OTHER.
• The calling process does not have CAP_SYS_NICE
permission and its owner is not the target process
owner. I.e., the effective uid of the calling process is
neither the effective nor the real uid of process PID.
ESRCH
There is no process with pid PID and PID is not zero.
EINVAL
• POLICY does not identify an existing scheduling policy.
• The absolute priority value identified by *PARAM is
outside the valid range for the scheduling policy POLICY
(or the existing scheduling policy if POLICY is negative)
or PARAM is null. sched_get_priority_max and
sched_get_priority_min tell you what the valid range
is.
• PID is negative.
-- Function: int sched_getscheduler (pid_t PID)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function returns the scheduling policy assigned to the process
with Process ID (pid) PID, or the calling process if PID is zero.
The return value is the scheduling policy. See
sched_setscheduler for the possible values.
If the function fails, the return value is instead -1 and errno
is set accordingly.
The errno values specific to this function are:
ESRCH
There is no process with pid PID and it is not zero.
EINVAL
PID is negative.
Note that this function is not an exact mate to
sched_setscheduler because while that function sets the
scheduling policy and the absolute priority, this function gets
only the scheduling policy. To get the absolute priority, use
sched_getparam.
-- Function: int sched_setparam (pid_t PID, const struct sched_param
*PARAM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function sets a process absolute priority.
It is functionally identical to sched_setscheduler with POLICY =
-1.
-- Function: int sched_getparam (pid_t PID, struct sched_param *PARAM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function returns a process absolute priority.
PID is the Process ID (pid) of the process whose absolute priority
you want to know.
PARAM is a pointer to a structure in which the function stores the
absolute priority of the process.
On success, the return value is 0. Otherwise, it is -1 and
errno is set accordingly. The errno values specific to this
function are:
ESRCH
There is no process with pid PID and it is not zero.
EINVAL
PID is negative.
-- Function: int sched_get_priority_min (int POLICY)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function returns the lowest absolute priority value that is
allowable for a process with scheduling policy POLICY.
On Linux, it is 0 for SCHED_OTHER and 1 for everything else.
On success, the return value is 0. Otherwise, it is -1 and
ERRNO is set accordingly. The errno values specific to this
function are:
EINVAL
POLICY does not identify an existing scheduling policy.
-- Function: int sched_get_priority_max (int POLICY)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function returns the highest absolute priority value that is
allowable for a process that with scheduling policy POLICY.
On Linux, it is 0 for SCHED_OTHER and 99 for everything else.
On success, the return value is 0. Otherwise, it is -1 and
ERRNO is set accordingly. The errno values specific to this
function are:
EINVAL
POLICY does not identify an existing scheduling policy.
-- Function: int sched_rr_get_interval (pid_t PID, struct timespec
*INTERVAL)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function returns the length of the quantum (time slice) used
with the Round Robin scheduling policy, if it is used, for the
process with Process ID PID.
It returns the length of time as INTERVAL.
With a Linux kernel, the round robin time slice is always 150
microseconds, and PID need not even be a real pid.
The return value is 0 on success and in the pathological case
that it fails, the return value is -1 and errno is set
accordingly. There is nothing specific that can go wrong with this
function, so there are no specific errno values.
-- Function: int sched_yield (void)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function voluntarily gives up the process claim on the CPU.
Technically, sched_yield causes the calling process to be made
immediately ready to run (as opposed to running, which is what it
was before). This means that if it has absolute priority higher
than 0, it gets pushed onto the tail of the queue of processes that
share its absolute priority and are ready to run, and it will run
again when its turn next arrives. If its absolute priority is 0,
it is more complicated, but still has the effect of yielding the
CPU to other processes.
If there are no other processes that share the calling process
absolute priority, this function doesnt have any effect.
To the extent that the containing program is oblivious to what
other processes in the system are doing and how fast it executes,
this function appears as a no-op.
The return value is 0 on success and in the pathological case
that it fails, the return value is -1 and errno is set
accordingly. There is nothing specific that can go wrong with this
function, so there are no specific errno values.

File: libc.info, Node: Traditional Scheduling, Next: CPU Affinity, Prev: Basic Scheduling Functions, Up: Priority
22.3.4 Traditional Scheduling
-----------------------------
This section is about the scheduling among processes whose absolute
priority is 0. When the system hands out the scraps of CPU time that
are left over after the processes with higher absolute priority have
taken all they want, the scheduling described herein determines who
among the great unwashed processes gets them.
* Menu:
* Traditional Scheduling Intro::
* Traditional Scheduling Functions::

File: libc.info, Node: Traditional Scheduling Intro, Next: Traditional Scheduling Functions, Up: Traditional Scheduling
22.3.4.1 Introduction To Traditional Scheduling
...............................................
Long before there was absolute priority (See *note Absolute Priority::),
Unix systems were scheduling the CPU using this system. When POSIX came
in like the Romans and imposed absolute priorities to accommodate the
needs of realtime processing, it left the indigenous Absolute Priority
Zero processes to govern themselves by their own familiar scheduling
policy.
Indeed, absolute priorities higher than zero are not available on
many systems today and are not typically used when they are, being
intended mainly for computers that do realtime processing. So this
section describes the only scheduling many programmers need to be
concerned about.
But just to be clear about the scope of this scheduling: Any time a
process with an absolute priority of 0 and a process with an absolute
priority higher than 0 are ready to run at the same time, the one with
absolute priority 0 does not run. If its already running when the
higher priority ready-to-run process comes into existence, it stops
immediately.
In addition to its absolute priority of zero, every process has
another priority, which we will refer to as "dynamic priority" because
it changes over time. The dynamic priority is meaningless for processes
with an absolute priority higher than zero.
The dynamic priority sometimes determines who gets the next turn on
the CPU. Sometimes it determines how long turns last. Sometimes it
determines whether a process can kick another off the CPU.
In Linux, the value is a combination of these things, but mostly it
just determines the length of the time slice. The higher a process
dynamic priority, the longer a shot it gets on the CPU when it gets one.
If it doesnt use up its time slice before giving up the CPU to do
something like wait for I/O, it is favored for getting the CPU back when
its ready for it, to finish out its time slice. Other than that,
selection of processes for new time slices is basically round robin.
But the scheduler does throw a bone to the low priority processes: A
process dynamic priority rises every time it is snubbed in the
scheduling process. In Linux, even the fat kid gets to play.
The fluctuation of a process dynamic priority is regulated by
another value: The “nice” value. The nice value is an integer, usually
in the range -20 to 20, and represents an upper limit on a process
dynamic priority. The higher the nice number, the lower that limit.
On a typical Linux system, for example, a process with a nice value
of 20 can get only 10 milliseconds on the CPU at a time, whereas a
process with a nice value of -20 can achieve a high enough priority to
get 400 milliseconds.
The idea of the nice value is deferential courtesy. In the
beginning, in the Unix garden of Eden, all processes shared equally in
the bounty of the computer system. But not all processes really need
the same share of CPU time, so the nice value gave a courteous process
the ability to refuse its equal share of CPU time that others might
prosper. Hence, the higher a process nice value, the nicer the process
is. (Then a snake came along and offered some process a negative nice
value and the system became the crass resource allocation system we know
today.)
Dynamic priorities tend upward and downward with an objective of
smoothing out allocation of CPU time and giving quick response time to
infrequent requests. But they never exceed their nice limits, so on a
heavily loaded CPU, the nice value effectively determines how fast a
process runs.
In keeping with the socialistic heritage of Unix process priority, a
process begins life with the same nice value as its parent process and
can raise it at will. A process can also raise the nice value of any
other process owned by the same user (or effective user). But only a
privileged process can lower its nice value. A privileged process can
also raise or lower another process nice value.
GNU C Library functions for getting and setting nice values are
described in *Note Traditional Scheduling Functions::.

File: libc.info, Node: Traditional Scheduling Functions, Prev: Traditional Scheduling Intro, Up: Traditional Scheduling
22.3.4.2 Functions For Traditional Scheduling
.............................................
This section describes how you can read and set the nice value of a
process. All these symbols are declared in sys/resource.h.
The function and macro names are defined by POSIX, and refer to
"priority," but the functions actually have to do with nice values, as
the terms are used both in the manual and POSIX.
The range of valid nice values depends on the kernel, but typically
it runs from -20 to 20. A lower nice value corresponds to higher
priority for the process. These constants describe the range of
priority values:
PRIO_MIN
The lowest valid nice value.
PRIO_MAX
The highest valid nice value.
-- Function: int getpriority (int CLASS, int ID)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
Return the nice value of a set of processes; CLASS and ID specify
which ones (see below). If the processes specified do not all have
the same nice value, this returns the lowest value that any of them
has.
On success, the return value is 0. Otherwise, it is -1 and
errno is set accordingly. The errno values specific to this
function are:
ESRCH
The combination of CLASS and ID does not match any existing
process.
EINVAL
The value of CLASS is not valid.
If the return value is -1, it could indicate failure, or it could
be the nice value. The only way to make certain is to set errno =
0 before calling getpriority, then use errno != 0 afterward as
the criterion for failure.
-- Function: int setpriority (int CLASS, int ID, int NICEVAL)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
Set the nice value of a set of processes to NICEVAL; CLASS and ID
specify which ones (see below).
The return value is 0 on success, and -1 on failure. The
following errno error condition are possible for this function:
ESRCH
The combination of CLASS and ID does not match any existing
process.
EINVAL
The value of CLASS is not valid.
EPERM
The call would set the nice value of a process which is owned
by a different user than the calling process (i.e., the target
process real or effective uid does not match the calling
process effective uid) and the calling process does not have
CAP_SYS_NICE permission.
EACCES
The call would lower the process nice value and the process
does not have CAP_SYS_NICE permission.
The arguments CLASS and ID together specify a set of processes in
which you are interested. These are the possible values of CLASS:
PRIO_PROCESS
One particular process. The argument ID is a process ID (pid).
PRIO_PGRP
All the processes in a particular process group. The argument ID
is a process group ID (pgid).
PRIO_USER
All the processes owned by a particular user (i.e., whose real uid
indicates the user). The argument ID is a user ID (uid).
If the argument ID is 0, it stands for the calling process, its
process group, or its owner (real uid), according to CLASS.
-- Function: int nice (int INCREMENT)
Preliminary: | MT-Unsafe race:setpriority | AS-Unsafe | AC-Safe |
*Note POSIX Safety Concepts::.
Increment the nice value of the calling process by INCREMENT. The
return value is the new nice value on success, and -1 on failure.
In the case of failure, errno will be set to the same values as
for setpriority.
Here is an equivalent definition of nice:
int
nice (int increment)
{
int result, old = getpriority (PRIO_PROCESS, 0);
result = setpriority (PRIO_PROCESS, 0, old + increment);
if (result != -1)
return old + increment;
else
return -1;
}

File: libc.info, Node: CPU Affinity, Prev: Traditional Scheduling, Up: Priority
22.3.5 Limiting execution to certain CPUs
-----------------------------------------
On a multi-processor system the operating system usually distributes the
different processes which are runnable on all available CPUs in a way
which allows the system to work most efficiently. Which processes and
threads run can be to some extend be control with the scheduling
functionality described in the last sections. But which CPU finally
executes which process or thread is not covered.
There are a number of reasons why a program might want to have
control over this aspect of the system as well:
• One thread or process is responsible for absolutely critical work
which under no circumstances must be interrupted or hindered from
making progress by other processes or threads using CPU resources.
In this case the special process would be confined to a CPU which
no other process or thread is allowed to use.
• The access to certain resources (RAM, I/O ports) has different
costs from different CPUs. This is the case in NUMA (Non-Uniform
Memory Architecture) machines. Preferably memory should be
accessed locally but this requirement is usually not visible to the
scheduler. Therefore forcing a process or thread to the CPUs which
have local access to the most-used memory helps to significantly
boost the performance.
• In controlled runtimes resource allocation and book-keeping work
(for instance garbage collection) is performance local to
processors. This can help to reduce locking costs if the resources
do not have to be protected from concurrent accesses from different
processors.
The POSIX standard up to this date is of not much help to solve this
problem. The Linux kernel provides a set of interfaces to allow
specifying _affinity sets_ for a process. The scheduler will schedule
the thread or process on CPUs specified by the affinity masks. The
interfaces which the GNU C Library define follow to some extent the
Linux kernel interface.
-- Data Type: cpu_set_t
This data set is a bitset where each bit represents a CPU. How the
systems CPUs are mapped to bits in the bitset is system dependent.
The data type has a fixed size; in the unlikely case that the
number of bits are not sufficient to describe the CPUs of the
system a different interface has to be used.
This type is a GNU extension and is defined in sched.h.
To manipulate the bitset, to set and reset bits, a number of macros
are defined. Some of the macros take a CPU number as a parameter. Here
it is important to never exceed the size of the bitset. The following
macro specifies the number of bits in the cpu_set_t bitset.
-- Macro: int CPU_SETSIZE
The value of this macro is the maximum number of CPUs which can be
handled with a cpu_set_t object.
The type cpu_set_t should be considered opaque; all manipulation
should happen via the next four macros.
-- Macro: void CPU_ZERO (cpu_set_t *SET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This macro initializes the CPU set SET to be the empty set.
This macro is a GNU extension and is defined in sched.h.
-- Macro: void CPU_SET (int CPU, cpu_set_t *SET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This macro adds CPU to the CPU set SET.
The CPU parameter must not have side effects since it is evaluated
more than once.
This macro is a GNU extension and is defined in sched.h.
-- Macro: void CPU_CLR (int CPU, cpu_set_t *SET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This macro removes CPU from the CPU set SET.
The CPU parameter must not have side effects since it is evaluated
more than once.
This macro is a GNU extension and is defined in sched.h.
-- Macro: int CPU_ISSET (int CPU, const cpu_set_t *SET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This macro returns a nonzero value (true) if CPU is a member of the
CPU set SET, and zero (false) otherwise.
The CPU parameter must not have side effects since it is evaluated
more than once.
This macro is a GNU extension and is defined in sched.h.
CPU bitsets can be constructed from scratch or the currently
installed affinity mask can be retrieved from the system.
-- Function: int sched_getaffinity (pid_t PID, size_t CPUSETSIZE,
cpu_set_t *CPUSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function stores the CPU affinity mask for the process or
thread with the ID PID in the CPUSETSIZE bytes long bitmap pointed
to by CPUSET. If successful, the function always initializes all
bits in the cpu_set_t object and returns zero.
If PID does not correspond to a process or thread on the system the
or the function fails for some other reason, it returns -1 and
errno is set to represent the error condition.
ESRCH
No process or thread with the given ID found.
EFAULT
The pointer CPUSET does not point to a valid object.
This function is a GNU extension and is declared in sched.h.
Note that it is not portably possible to use this information to
retrieve the information for different POSIX threads. A separate
interface must be provided for that.
-- Function: int sched_setaffinity (pid_t PID, size_t CPUSETSIZE, const
cpu_set_t *CPUSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function installs the CPUSETSIZE bytes long affinity mask
pointed to by CPUSET for the process or thread with the ID PID. If
successful the function returns zero and the scheduler will in the
future take the affinity information into account.
If the function fails it will return -1 and errno is set to the
error code:
ESRCH
No process or thread with the given ID found.
EFAULT
The pointer CPUSET does not point to a valid object.
EINVAL
The bitset is not valid. This might mean that the affinity
set might not leave a processor for the process or thread to
run on.
This function is a GNU extension and is declared in sched.h.

File: libc.info, Node: Memory Resources, Next: Processor Resources, Prev: Priority, Up: Resource Usage And Limitation
22.4 Querying memory available resources
========================================
The amount of memory available in the system and the way it is organized
determines oftentimes the way programs can and have to work. For
functions like mmap it is necessary to know about the size of
individual memory pages and knowing how much memory is available enables
a program to select appropriate sizes for, say, caches. Before we get
into these details a few words about memory subsystems in traditional
Unix systems will be given.
* Menu:
* Memory Subsystem:: Overview about traditional Unix memory handling.
* Query Memory Parameters:: How to get information about the memory
subsystem?

File: libc.info, Node: Memory Subsystem, Next: Query Memory Parameters, Up: Memory Resources
22.4.1 Overview about traditional Unix memory handling
------------------------------------------------------
Unix systems normally provide processes virtual address spaces. This
means that the addresses of the memory regions do not have to correspond
directly to the addresses of the actual physical memory which stores the
data. An extra level of indirection is introduced which translates
virtual addresses into physical addresses. This is normally done by the
hardware of the processor.
Using a virtual address space has several advantages. The most
important is process isolation. The different processes running on the
system cannot interfere directly with each other. No process can write
into the address space of another process (except when shared memory is
used but then it is wanted and controlled).
Another advantage of virtual memory is that the address space the
processes see can actually be larger than the physical memory available.
The physical memory can be extended by storage on an external media
where the content of currently unused memory regions is stored. The
address translation can then intercept accesses to these memory regions
and make memory content available again by loading the data back into
memory. This concept makes it necessary that programs which have to use
lots of memory know the difference between available virtual address
space and available physical memory. If the working set of virtual
memory of all the processes is larger than the available physical memory
the system will slow down dramatically due to constant swapping of
memory content from the memory to the storage media and back. This is
called “thrashing”.
A final aspect of virtual memory which is important and follows from
what is said in the last paragraph is the granularity of the virtual
address space handling. When we said that the virtual address handling
stores memory content externally it cannot do this on a byte-by-byte
basis. The administrative overhead does not allow this (leaving alone
the processor hardware). Instead several thousand bytes are handled
together and form a “page”. The size of each page is always a power of
two bytes. The smallest page size in use today is 4096, with 8192,
16384, and 65536 being other popular sizes.

File: libc.info, Node: Query Memory Parameters, Prev: Memory Subsystem, Up: Memory Resources
22.4.2 How to get information about the memory subsystem?
---------------------------------------------------------
The page size of the virtual memory the process sees is essential to
know in several situations. Some programming interfaces (e.g., mmap,
*note Memory-mapped I/O::) require the user to provide information
adjusted to the page size. In the case of mmap it is necessary to
provide a length argument which is a multiple of the page size. Another
place where the knowledge about the page size is useful is in memory
allocation. If one allocates pieces of memory in larger chunks which
are then subdivided by the application code it is useful to adjust the
size of the larger blocks to the page size. If the total memory
requirement for the block is close (but not larger) to a multiple of the
page size the kernels memory handling can work more effectively since
it only has to allocate memory pages which are fully used. (To do this
optimization it is necessary to know a bit about the memory allocator
which will require a bit of memory itself for each block and this
overhead must not push the total size over the page size multiple.)
The page size traditionally was a compile time constant. But recent
development of processors changed this. Processors now support
different page sizes and they can possibly even vary among different
processes on the same system. Therefore the system should be queried at
runtime about the current page size and no assumptions (except about it
being a power of two) should be made.
The correct interface to query about the page size is sysconf
(*note Sysconf Definition::) with the parameter _SC_PAGESIZE. There
is a much older interface available, too.
-- Function: int getpagesize (void)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The getpagesize function returns the page size of the process.
This value is fixed for the runtime of the process but can vary in
different runs of the application.
The function is declared in unistd.h.
Widely available on System V derived systems is a method to get
information about the physical memory the system has. The call
sysconf (_SC_PHYS_PAGES)
returns the total number of pages of physical memory the system has.
This does not mean all this memory is available. This information can
be found using
sysconf (_SC_AVPHYS_PAGES)
These two values help to optimize applications. The value returned
for _SC_AVPHYS_PAGES is the amount of memory the application can use
without hindering any other process (given that no other process
increases its memory usage). The value returned for _SC_PHYS_PAGES is
more or less a hard limit for the working set. If all applications
together constantly use more than that amount of memory the system is in
trouble.
The GNU C Library provides in addition to these already described way
to get this information two functions. They are declared in the file
sys/sysinfo.h. Programmers should prefer to use the sysconf method
described above.
-- Function: long int get_phys_pages (void)
Preliminary: | MT-Safe | AS-Unsafe heap lock | AC-Unsafe lock fd
mem | *Note POSIX Safety Concepts::.
The get_phys_pages function returns the total number of pages of
physical memory the system has. To get the amount of memory this
number has to be multiplied by the page size.
This function is a GNU extension.
-- Function: long int get_avphys_pages (void)
Preliminary: | MT-Safe | AS-Unsafe heap lock | AC-Unsafe lock fd
mem | *Note POSIX Safety Concepts::.
The get_avphys_pages function returns the number of available
pages of physical memory the system has. To get the amount of
memory this number has to be multiplied by the page size.
This function is a GNU extension.

File: libc.info, Node: Processor Resources, Prev: Memory Resources, Up: Resource Usage And Limitation
22.5 Learn about the processors available
=========================================
The use of threads or processes with shared memory allows an application
to take advantage of all the processing power a system can provide. If
the task can be parallelized the optimal way to write an application is
to have at any time as many processes running as there are processors.
To determine the number of processors available to the system one can
run
sysconf (_SC_NPROCESSORS_CONF)
which returns the number of processors the operating system configured.
But it might be possible for the operating system to disable individual
processors and so the call
sysconf (_SC_NPROCESSORS_ONLN)
returns the number of processors which are currently online (i.e.,
available).
For these two pieces of information the GNU C Library also provides
functions to get the information directly. The functions are declared
in sys/sysinfo.h.
-- Function: int get_nprocs_conf (void)
Preliminary: | MT-Safe | AS-Unsafe heap lock | AC-Unsafe lock fd
mem | *Note POSIX Safety Concepts::.
The get_nprocs_conf function returns the number of processors the
operating system configured.
This function is a GNU extension.
-- Function: int get_nprocs (void)
Preliminary: | MT-Safe | AS-Safe | AC-Safe fd | *Note POSIX Safety
Concepts::.
The get_nprocs function returns the number of available
processors.
This function is a GNU extension.
Before starting more threads it should be checked whether the
processors are not already overused. Unix systems calculate something
called the “load average”. This is a number indicating how many
processes were running. This number is an average over different
periods of time (normally 1, 5, and 15 minutes).
-- Function: int getloadavg (double LOADAVG[], int NELEM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe fd | *Note POSIX Safety
Concepts::.
This function gets the 1, 5 and 15 minute load averages of the
system. The values are placed in LOADAVG. getloadavg will place
at most NELEM elements into the array but never more than three
elements. The return value is the number of elements written to
LOADAVG, or -1 on error.
This function is declared in stdlib.h.

File: libc.info, Node: Non-Local Exits, Next: Signal Handling, Prev: Resource Usage And Limitation, Up: Top
23 Non-Local Exits
******************
Sometimes when your program detects an unusual situation inside a deeply
nested set of function calls, you would like to be able to immediately
return to an outer level of control. This section describes how you can
do such “non-local exits” using the setjmp and longjmp functions.
* Menu:
* Intro: Non-Local Intro. When and how to use these facilities.
* Details: Non-Local Details. Functions for non-local exits.
* Non-Local Exits and Signals:: Portability issues.
* System V contexts:: Complete context control a la System V.

File: libc.info, Node: Non-Local Intro, Next: Non-Local Details, Up: Non-Local Exits
23.1 Introduction to Non-Local Exits
====================================
As an example of a situation where a non-local exit can be useful,
suppose you have an interactive program that has a “main loop” that
prompts for and executes commands. Suppose the “read” command reads
input from a file, doing some lexical analysis and parsing of the input
while processing it. If a low-level input error is detected, it would
be useful to be able to return immediately to the “main loop” instead of
having to make each of the lexical analysis, parsing, and processing
phases all have to explicitly deal with error situations initially
detected by nested calls.
(On the other hand, if each of these phases has to do a substantial
amount of cleanup when it exits—such as closing files, deallocating
buffers or other data structures, and the like—then it can be more
appropriate to do a normal return and have each phase do its own
cleanup, because a non-local exit would bypass the intervening phases
and their associated cleanup code entirely. Alternatively, you could
use a non-local exit but do the cleanup explicitly either before or
after returning to the “main loop”.)
In some ways, a non-local exit is similar to using the return
statement to return from a function. But while return abandons only a
single function call, transferring control back to the point at which it
was called, a non-local exit can potentially abandon many levels of
nested function calls.
You identify return points for non-local exits by calling the
function setjmp. This function saves information about the execution
environment in which the call to setjmp appears in an object of type
jmp_buf. Execution of the program continues normally after the call
to setjmp, but if an exit is later made to this return point by
calling longjmp with the corresponding jmp_buf object, control is
transferred back to the point where setjmp was called. The return
value from setjmp is used to distinguish between an ordinary return
and a return made by a call to longjmp, so calls to setjmp usually
appear in an if statement.
Here is how the example program described above might be set up:
#include <setjmp.h>
#include <stdlib.h>
#include <stdio.h>
jmp_buf main_loop;
void
abort_to_main_loop (int status)
{
longjmp (main_loop, status);
}
int
main (void)
{
while (1)
if (setjmp (main_loop))
puts ("Back at main loop....");
else
do_command ();
}
void
do_command (void)
{
char buffer[128];
if (fgets (buffer, 128, stdin) == NULL)
abort_to_main_loop (-1);
else
exit (EXIT_SUCCESS);
}
The function abort_to_main_loop causes an immediate transfer of
control back to the main loop of the program, no matter where it is
called from.
The flow of control inside the main function may appear a little
mysterious at first, but it is actually a common idiom with setjmp. A
normal call to setjmp returns zero, so the “else” clause of the
conditional is executed. If abort_to_main_loop is called somewhere
within the execution of do_command, then it actually appears as if the
_same_ call to setjmp in main were returning a second time with a
value of -1.
So, the general pattern for using setjmp looks something like:
if (setjmp (BUFFER))
/* Code to clean up after premature return. */
...
else
/* Code to be executed normally after setting up the return point. */
...

File: libc.info, Node: Non-Local Details, Next: Non-Local Exits and Signals, Prev: Non-Local Intro, Up: Non-Local Exits
23.2 Details of Non-Local Exits
===============================
Here are the details on the functions and data structures used for
performing non-local exits. These facilities are declared in
setjmp.h.
-- Data Type: jmp_buf
Objects of type jmp_buf hold the state information to be restored
by a non-local exit. The contents of a jmp_buf identify a
specific place to return to.
-- Macro: int setjmp (jmp_buf STATE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
When called normally, setjmp stores information about the
execution state of the program in STATE and returns zero. If
longjmp is later used to perform a non-local exit to this STATE,
setjmp returns a nonzero value.
-- Function: void longjmp (jmp_buf STATE, int VALUE)
Preliminary: | MT-Safe | AS-Unsafe plugin corrupt lock/hurd |
AC-Unsafe corrupt lock/hurd | *Note POSIX Safety Concepts::.
This function restores current execution to the state saved in
STATE, and continues execution from the call to setjmp that
established that return point. Returning from setjmp by means of
longjmp returns the VALUE argument that was passed to longjmp,
rather than 0. (But if VALUE is given as 0, setjmp returns
1).
There are a lot of obscure but important restrictions on the use of
setjmp and longjmp. Most of these restrictions are present because
non-local exits require a fair amount of magic on the part of the C
compiler and can interact with other parts of the language in strange
ways.
The setjmp function is actually a macro without an actual function
definition, so you shouldnt try to #undef it or take its address. In
addition, calls to setjmp are safe in only the following contexts:
• As the test expression of a selection or iteration statement (such
as if, switch, or while).
• As one operand of an equality or comparison operator that appears
as the test expression of a selection or iteration statement. The
other operand must be an integer constant expression.
• As the operand of a unary ! operator, that appears as the test
expression of a selection or iteration statement.
• By itself as an expression statement.
Return points are valid only during the dynamic extent of the
function that called setjmp to establish them. If you longjmp to a
return point that was established in a function that has already
returned, unpredictable and disastrous things are likely to happen.
You should use a nonzero VALUE argument to longjmp. While
longjmp refuses to pass back a zero argument as the return value from
setjmp, this is intended as a safety net against accidental misuse and
is not really good programming style.
When you perform a non-local exit, accessible objects generally
retain whatever values they had at the time longjmp was called. The
exception is that the values of automatic variables local to the
function containing the setjmp call that have been changed since the
call to setjmp are indeterminate, unless you have declared them
volatile.

File: libc.info, Node: Non-Local Exits and Signals, Next: System V contexts, Prev: Non-Local Details, Up: Non-Local Exits
23.3 Non-Local Exits and Signals
================================
In BSD Unix systems, setjmp and longjmp also save and restore the
set of blocked signals; see *note Blocking Signals::. However, the
POSIX.1 standard requires setjmp and longjmp not to change the set
of blocked signals, and provides an additional pair of functions
(sigsetjmp and siglongjmp) to get the BSD behavior.
The behavior of setjmp and longjmp in the GNU C Library is
controlled by feature test macros; see *note Feature Test Macros::. The
default in the GNU C Library is the POSIX.1 behavior rather than the BSD
behavior.
The facilities in this section are declared in the header file
setjmp.h.
-- Data Type: sigjmp_buf
This is similar to jmp_buf, except that it can also store state
information about the set of blocked signals.
-- Function: int sigsetjmp (sigjmp_buf STATE, int SAVESIGS)
Preliminary: | MT-Safe | AS-Unsafe lock/hurd | AC-Unsafe lock/hurd
| *Note POSIX Safety Concepts::.
This is similar to setjmp. If SAVESIGS is nonzero, the set of
blocked signals is saved in STATE and will be restored if a
siglongjmp is later performed with this STATE.
-- Function: void siglongjmp (sigjmp_buf STATE, int VALUE)
Preliminary: | MT-Safe | AS-Unsafe plugin corrupt lock/hurd |
AC-Unsafe corrupt lock/hurd | *Note POSIX Safety Concepts::.
This is similar to longjmp except for the type of its STATE
argument. If the sigsetjmp call that set this STATE used a
nonzero SAVESIGS flag, siglongjmp also restores the set of
blocked signals.

File: libc.info, Node: System V contexts, Prev: Non-Local Exits and Signals, Up: Non-Local Exits
23.4 Complete Context Control
=============================
The Unix standard provides one more set of functions to control the
execution path and these functions are more powerful than those
discussed in this chapter so far. These functions were part of the
original System V API and by this route were added to the Unix API.
Besides on branded Unix implementations these interfaces are not widely
available. Not all platforms and/or architectures the GNU C Library is
available on provide this interface. Use configure to detect the
availability.
Similar to the jmp_buf and sigjmp_buf types used for the
variables to contain the state of the longjmp functions the interfaces
of interest here have an appropriate type as well. Objects of this type
are normally much larger since more information is contained. The type
is also used in a few more places as we will see. The types and
functions described in this section are all defined and declared
respectively in the ucontext.h header file.
-- Data Type: ucontext_t
The ucontext_t type is defined as a structure with at least the
following elements:
ucontext_t *uc_link
This is a pointer to the next context structure which is used
if the context described in the current structure returns.
sigset_t uc_sigmask
Set of signals which are blocked when this context is used.
stack_t uc_stack
Stack used for this context. The value need not be (and
normally is not) the stack pointer. *Note Signal Stack::.
mcontext_t uc_mcontext
This element contains the actual state of the process. The
mcontext_t type is also defined in this header but the
definition should be treated as opaque. Any use of knowledge
of the type makes applications less portable.
Objects of this type have to be created by the user. The
initialization and modification happens through one of the following
functions:
-- Function: int getcontext (ucontext_t *UCP)
Preliminary: | MT-Safe race:ucp | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The getcontext function initializes the variable pointed to by
UCP with the context of the calling thread. The context contains
the content of the registers, the signal mask, and the current
stack. Executing the contents would start at the point where the
getcontext call just returned.
*Compatibility Note:* Depending on the operating system,
information about the current contexts stack may be in the
uc_stack field of UCP, or it may instead be in
architecture-specific subfields of the uc_mcontext field.
The function returns 0 if successful. Otherwise it returns -1
and sets ERRNO accordingly.
The getcontext function is similar to setjmp but it does not
provide an indication of whether getcontext is returning for the first
time or whether an initialized context has just been restored. If this
is necessary the user has to determine this herself. This must be done
carefully since the context contains registers which might contain
register variables. This is a good situation to define variables with
volatile.
Once the context variable is initialized it can be used as is or it
can be modified using the makecontext function. The latter is
normally done when implementing co-routines or similar constructs.
-- Function: void makecontext (ucontext_t *UCP, void (*FUNC) (void),
int ARGC, ...)
Preliminary: | MT-Safe race:ucp | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The UCP parameter passed to makecontext shall be initialized by a
call to getcontext. The context will be modified in a way such
that if the context is resumed it will start by calling the
function func which gets ARGC integer arguments passed. The
integer arguments which are to be passed should follow the ARGC
parameter in the call to makecontext.
Before the call to this function the uc_stack and uc_link
element of the UCP structure should be initialized. The uc_stack
element describes the stack which is used for this context. No two
contexts which are used at the same time should use the same memory
region for a stack.
The uc_link element of the object pointed to by UCP should be a
pointer to the context to be executed when the function FUNC
returns or it should be a null pointer. See setcontext for more
information about the exact use.
While allocating the memory for the stack one has to be careful.
Most modern processors keep track of whether a certain memory region is
allowed to contain code which is executed or not. Data segments and
heap memory are normally not tagged to allow this. The result is that
programs would fail. Examples for such code include the calling
sequences the GNU C compiler generates for calls to nested functions.
Safe ways to allocate stacks correctly include using memory on the
original threads stack or explicitly allocating memory tagged for
execution using (*note Memory-mapped I/O::).
*Compatibility note*: The current Unix standard is very imprecise
about the way the stack is allocated. All implementations seem to agree
that the uc_stack element must be used but the values stored in the
elements of the stack_t value are unclear. The GNU C Library and most
other Unix implementations require the ss_sp value of the uc_stack
element to point to the base of the memory region allocated for the
stack and the size of the memory region is stored in ss_size. There
are implementations out there which require ss_sp to be set to the
value the stack pointer will have (which can, depending on the direction
the stack grows, be different). This difference makes the makecontext
function hard to use and it requires detection of the platform at
compile time.
-- Function: int setcontext (const ucontext_t *UCP)
Preliminary: | MT-Safe race:ucp | AS-Unsafe corrupt | AC-Unsafe
corrupt | *Note POSIX Safety Concepts::.
The setcontext function restores the context described by UCP.
The context is not modified and can be reused as often as wanted.
If the context was created by getcontext execution resumes with
the registers filled with the same values and the same stack as if
the getcontext call just returned.
If the context was modified with a call to makecontext execution
continues with the function passed to makecontext which gets the
specified parameters passed. If this function returns execution is
resumed in the context which was referenced by the uc_link
element of the context structure passed to makecontext at the
time of the call. If uc_link was a null pointer the application
terminates normally with an exit status value of EXIT_SUCCESS
(*note Program Termination::).
If the context was created by a call to a signal handler or from
any other source then the behaviour of setcontext is unspecified.
Since the context contains information about the stack no two
threads should use the same context at the same time. The result
in most cases would be disastrous.
The setcontext function does not return unless an error occurred
in which case it returns -1.
The setcontext function simply replaces the current context with
the one described by the UCP parameter. This is often useful but there
are situations where the current context has to be preserved.
-- Function: int swapcontext (ucontext_t *restrict OUCP, const
ucontext_t *restrict UCP)
Preliminary: | MT-Safe race:oucp race:ucp | AS-Unsafe corrupt |
AC-Unsafe corrupt | *Note POSIX Safety Concepts::.
The swapcontext function is similar to setcontext but instead
of just replacing the current context the latter is first saved in
the object pointed to by OUCP as if this was a call to
getcontext. The saved context would resume after the call to
swapcontext.
Once the current context is saved the context described in UCP is
installed and execution continues as described in this context.
If swapcontext succeeds the function does not return unless the
context OUCP is used without prior modification by makecontext.
The return value in this case is 0. If the function fails it
returns -1 and sets ERRNO accordingly.
Example for SVID Context Handling
=================================
The easiest way to use the context handling functions is as a
replacement for setjmp and longjmp. The context contains on most
platforms more information which may lead to fewer surprises but this
also means using these functions is more expensive (besides being less
portable).
int
random_search (int n, int (*fp) (int, ucontext_t *))
{
volatile int cnt = 0;
ucontext_t uc;
/* Safe current context. */
if (getcontext (&uc) < 0)
return -1;
/* If we have not tried N times try again. */
if (cnt++ < n)
/* Call the function with a new random number
and the context. */
if (fp (rand (), &uc) != 0)
/* We found what we were looking for. */
return 1;
/* Not found. */
return 0;
}
Using contexts in such a way enables emulating exception handling.
The search functions passed in the FP parameter could be very large,
nested, and complex which would make it complicated (or at least would
require a lot of code) to leave the function with an error value which
has to be passed down to the caller. By using the context it is
possible to leave the search function in one step and allow restarting
the search which also has the nice side effect that it can be
significantly faster.
Something which is harder to implement with setjmp and longjmp is
to switch temporarily to a different execution path and then resume
where execution was stopped.
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <ucontext.h>
#include <sys/time.h>
/* Set by the signal handler. */
static volatile int expired;
/* The contexts. */
static ucontext_t uc[3];
/* We do only a certain number of switches. */
static int switches;
/* This is the function doing the work. It is just a
skeleton, real code has to be filled in. */
static void
f (int n)
{
int m = 0;
while (1)
{
/* This is where the work would be done. */
if (++m % 100 == 0)
{
putchar ('.');
fflush (stdout);
}
/* Regularly the EXPIRE variable must be checked. */
if (expired)
{
/* We do not want the program to run forever. */
if (++switches == 20)
return;
printf ("\nswitching from %d to %d\n", n, 3 - n);
expired = 0;
/* Switch to the other context, saving the current one. */
swapcontext (&uc[n], &uc[3 - n]);
}
}
}
/* This is the signal handler which simply set the variable. */
void
handler (int signal)
{
expired = 1;
}
int
main (void)
{
struct sigaction sa;
struct itimerval it;
char st1[8192];
char st2[8192];
/* Initialize the data structures for the interval timer. */
sa.sa_flags = SA_RESTART;
sigfillset (&sa.sa_mask);
sa.sa_handler = handler;
it.it_interval.tv_sec = 0;
it.it_interval.tv_usec = 1;
it.it_value = it.it_interval;
/* Install the timer and get the context we can manipulate. */
if (sigaction (SIGPROF, &sa, NULL) < 0
|| setitimer (ITIMER_PROF, &it, NULL) < 0
|| getcontext (&uc[1]) == -1
|| getcontext (&uc[2]) == -1)
abort ();
/* Create a context with a separate stack which causes the
function f to be call with the parameter 1.
Note that the uc_link points to the main context
which will cause the program to terminate once the function
return. */
uc[1].uc_link = &uc[0];
uc[1].uc_stack.ss_sp = st1;
uc[1].uc_stack.ss_size = sizeof st1;
makecontext (&uc[1], (void (*) (void)) f, 1, 1);
/* Similarly, but 2 is passed as the parameter to f. */
uc[2].uc_link = &uc[0];
uc[2].uc_stack.ss_sp = st2;
uc[2].uc_stack.ss_size = sizeof st2;
makecontext (&uc[2], (void (*) (void)) f, 1, 2);
/* Start running. */
swapcontext (&uc[0], &uc[1]);
putchar ('\n');
return 0;
}
This an example how the context functions can be used to implement
co-routines or cooperative multi-threading. All that has to be done is
to call every once in a while swapcontext to continue running a
different context. It is not recommended to do the context switching
from the signal handler directly since leaving the signal handler via
setcontext if the signal was delivered during code that was not
asynchronous signal safe could lead to problems. Setting a variable in
the signal handler and checking it in the body of the functions which
are executed is a safer approach. Since swapcontext is saving the
current context it is possible to have multiple different scheduling
points in the code. Execution will always resume where it was left.

File: libc.info, Node: Signal Handling, Next: Program Basics, Prev: Non-Local Exits, Up: Top
24 Signal Handling
******************
A “signal” is a software interrupt delivered to a process. The
operating system uses signals to report exceptional situations to an
executing program. Some signals report errors such as references to
invalid memory addresses; others report asynchronous events, such as
disconnection of a phone line.
The GNU C Library defines a variety of signal types, each for a
particular kind of event. Some kinds of events make it inadvisable or
impossible for the program to proceed as usual, and the corresponding
signals normally abort the program. Other kinds of signals that report
harmless events are ignored by default.
If you anticipate an event that causes signals, you can define a
handler function and tell the operating system to run it when that
particular type of signal arrives.
Finally, one process can send a signal to another process; this
allows a parent process to abort a child, or two related processes to
communicate and synchronize.
* Menu:
* Concepts of Signals:: Introduction to the signal facilities.
* Standard Signals:: Particular kinds of signals with
standard names and meanings.
* Signal Actions:: Specifying what happens when a
particular signal is delivered.
* Defining Handlers:: How to write a signal handler function.
* Interrupted Primitives:: Signal handlers affect use of open,
read, write and other functions.
* Generating Signals:: How to send a signal to a process.
* Blocking Signals:: Making the system hold signals temporarily.
* Waiting for a Signal:: Suspending your program until a signal
arrives.
* Signal Stack:: Using a Separate Signal Stack.
* BSD Signal Handling:: Additional functions for backward
compatibility with BSD.

File: libc.info, Node: Concepts of Signals, Next: Standard Signals, Up: Signal Handling
24.1 Basic Concepts of Signals
==============================
This section explains basic concepts of how signals are generated, what
happens after a signal is delivered, and how programs can handle
signals.
* Menu:
* Kinds of Signals:: Some examples of what can cause a signal.
* Signal Generation:: Concepts of why and how signals occur.
* Delivery of Signal:: Concepts of what a signal does to the
process.

File: libc.info, Node: Kinds of Signals, Next: Signal Generation, Up: Concepts of Signals
24.1.1 Some Kinds of Signals
----------------------------
A signal reports the occurrence of an exceptional event. These are some
of the events that can cause (or “generate”, or “raise”) a signal:
• A program error such as dividing by zero or issuing an address
outside the valid range.
• A user request to interrupt or terminate the program. Most
environments are set up to let a user suspend the program by typing
C-z, or terminate it with C-c. Whatever key sequence is used,
the operating system sends the proper signal to interrupt the
process.
• The termination of a child process.
• Expiration of a timer or alarm.
• A call to kill or raise by the same process.
• A call to kill from another process. Signals are a limited but
useful form of interprocess communication.
• An attempt to perform an I/O operation that cannot be done.
Examples are reading from a pipe that has no writer (*note Pipes
and FIFOs::), and reading or writing to a terminal in certain
situations (*note Job Control::).
Each of these kinds of events (excepting explicit calls to kill and
raise) generates its own particular kind of signal. The various kinds
of signals are listed and described in detail in *note Standard
Signals::.

File: libc.info, Node: Signal Generation, Next: Delivery of Signal, Prev: Kinds of Signals, Up: Concepts of Signals
24.1.2 Concepts of Signal Generation
------------------------------------
In general, the events that generate signals fall into three major
categories: errors, external events, and explicit requests.
An error means that a program has done something invalid and cannot
continue execution. But not all kinds of errors generate signals—in
fact, most do not. For example, opening a nonexistent file is an error,
but it does not raise a signal; instead, open returns -1. In
general, errors that are necessarily associated with certain library
functions are reported by returning a value that indicates an error.
The errors which raise signals are those which can happen anywhere in
the program, not just in library calls. These include division by zero
and invalid memory addresses.
An external event generally has to do with I/O or other processes.
These include the arrival of input, the expiration of a timer, and the
termination of a child process.
An explicit request means the use of a library function such as
kill whose purpose is specifically to generate a signal.
Signals may be generated “synchronously” or “asynchronously”. A
synchronous signal pertains to a specific action in the program, and is
delivered (unless blocked) during that action. Most errors generate
signals synchronously, and so do explicit requests by a process to
generate a signal for that same process. On some machines, certain
kinds of hardware errors (usually floating-point exceptions) are not
reported completely synchronously, but may arrive a few instructions
later.
Asynchronous signals are generated by events outside the control of
the process that receives them. These signals arrive at unpredictable
times during execution. External events generate signals
asynchronously, and so do explicit requests that apply to some other
process.
A given type of signal is either typically synchronous or typically
asynchronous. For example, signals for errors are typically synchronous
because errors generate signals synchronously. But any type of signal
can be generated synchronously or asynchronously with an explicit
request.

File: libc.info, Node: Delivery of Signal, Prev: Signal Generation, Up: Concepts of Signals
24.1.3 How Signals Are Delivered
--------------------------------
When a signal is generated, it becomes “pending”. Normally it remains
pending for just a short period of time and then is “delivered” to the
process that was signaled. However, if that kind of signal is currently
“blocked”, it may remain pending indefinitely—until signals of that kind
are “unblocked”. Once unblocked, it will be delivered immediately.
*Note Blocking Signals::.
When the signal is delivered, whether right away or after a long
delay, the “specified action” for that signal is taken. For certain
signals, such as SIGKILL and SIGSTOP, the action is fixed, but for
most signals, the program has a choice: ignore the signal, specify a
“handler function”, or accept the “default action” for that kind of
signal. The program specifies its choice using functions such as
signal or sigaction (*note Signal Actions::). We sometimes say that
a handler “catches” the signal. While the handler is running, that
particular signal is normally blocked.
If the specified action for a kind of signal is to ignore it, then
any such signal which is generated is discarded immediately. This
happens even if the signal is also blocked at the time. A signal
discarded in this way will never be delivered, not even if the program
subsequently specifies a different action for that kind of signal and
then unblocks it.
If a signal arrives which the program has neither handled nor
ignored, its “default action” takes place. Each kind of signal has its
own default action, documented below (*note Standard Signals::). For
most kinds of signals, the default action is to terminate the process.
For certain kinds of signals that represent “harmless” events, the
default action is to do nothing.
When a signal terminates a process, its parent process can determine
the cause of termination by examining the termination status code
reported by the wait or waitpid functions. (This is discussed in
more detail in *note Process Completion::.) The information it can get
includes the fact that termination was due to a signal and the kind of
signal involved. If a program you run from a shell is terminated by a
signal, the shell typically prints some kind of error message.
The signals that normally represent program errors have a special
property: when one of these signals terminates the process, it also
writes a “core dump file” which records the state of the process at the
time of termination. You can examine the core dump with a debugger to
investigate what caused the error.
If you raise a “program error” signal by explicit request, and this
terminates the process, it makes a core dump file just as if the signal
had been due directly to an error.

File: libc.info, Node: Standard Signals, Next: Signal Actions, Prev: Concepts of Signals, Up: Signal Handling
24.2 Standard Signals
=====================
This section lists the names for various standard kinds of signals and
describes what kind of event they mean. Each signal name is a macro
which stands for a positive integer—the “signal number” for that kind of
signal. Your programs should never make assumptions about the numeric
code for a particular kind of signal, but rather refer to them always by
the names defined here. This is because the number for a given kind of
signal can vary from system to system, but the meanings of the names are
standardized and fairly uniform.
The signal names are defined in the header file signal.h.
-- Macro: int NSIG
The value of this symbolic constant is the total number of signals
defined. Since the signal numbers are allocated consecutively,
NSIG is also one greater than the largest defined signal number.
* Menu:
* Program Error Signals:: Used to report serious program errors.
* Termination Signals:: Used to interrupt and/or terminate the
program.
* Alarm Signals:: Used to indicate expiration of timers.
* Asynchronous I/O Signals:: Used to indicate input is available.
* Job Control Signals:: Signals used to support job control.
* Operation Error Signals:: Used to report operational system errors.
* Miscellaneous Signals:: Miscellaneous Signals.
* Signal Messages:: Printing a message describing a signal.

File: libc.info, Node: Program Error Signals, Next: Termination Signals, Up: Standard Signals
24.2.1 Program Error Signals
----------------------------
The following signals are generated when a serious program error is
detected by the operating system or the computer itself. In general,
all of these signals are indications that your program is seriously
broken in some way, and theres usually no way to continue the
computation which encountered the error.
Some programs handle program error signals in order to tidy up before
terminating; for example, programs that turn off echoing of terminal
input should handle program error signals in order to turn echoing back
on. The handler should end by specifying the default action for the
signal that happened and then reraising it; this will cause the program
to terminate with that signal, as if it had not had a handler. (*Note
Termination in Handler::.)
Termination is the sensible ultimate outcome from a program error in
most programs. However, programming systems such as Lisp that can load
compiled user programs might need to keep executing even if a user
program incurs an error. These programs have handlers which use
longjmp to return control to the command level.
The default action for all of these signals is to cause the process
to terminate. If you block or ignore these signals or establish
handlers for them that return normally, your program will probably break
horribly when such signals happen, unless they are generated by raise
or kill instead of a real error.
When one of these program error signals terminates a process, it also
writes a “core dump file” which records the state of the process at the
time of termination. The core dump file is named core and is written
in whichever directory is current in the process at the time. (On
GNU/Hurd systems, you can specify the file name for core dumps with the
environment variable COREFILE.) The purpose of core dump files is so
that you can examine them with a debugger to investigate what caused the
error.
-- Macro: int SIGFPE
The SIGFPE signal reports a fatal arithmetic error. Although the
name is derived from “floating-point exception”, this signal
actually covers all arithmetic errors, including division by zero
and overflow. If a program stores integer data in a location which
is then used in a floating-point operation, this often causes an
“invalid operation” exception, because the processor cannot
recognize the data as a floating-point number.
Actual floating-point exceptions are a complicated subject because
there are many types of exceptions with subtly different meanings,
and the SIGFPE signal doesnt distinguish between them. The
IEEE Standard for Binary Floating-Point Arithmetic (ANSI/IEEE Std
754-1985 and ANSI/IEEE Std 854-1987) defines various
floating-point exceptions and requires conforming computer systems
to report their occurrences. However, this standard does not
specify how the exceptions are reported, or what kinds of handling
and control the operating system can offer to the programmer.
BSD systems provide the SIGFPE handler with an extra argument that
distinguishes various causes of the exception. In order to access this
argument, you must define the handler to accept two arguments, which
means you must cast it to a one-argument function type in order to
establish the handler. The GNU C Library does provide this extra
argument, but the value is meaningful only on operating systems that
provide the information (BSD systems and GNU systems).
FPE_INTOVF_TRAP
Integer overflow (impossible in a C program unless you enable
overflow trapping in a hardware-specific fashion).
FPE_INTDIV_TRAP
Integer division by zero.
FPE_SUBRNG_TRAP
Subscript-range (something that C programs never check for).
FPE_FLTOVF_TRAP
Floating overflow trap.
FPE_FLTDIV_TRAP
Floating/decimal division by zero.
FPE_FLTUND_TRAP
Floating underflow trap. (Trapping on floating underflow is not
normally enabled.)
FPE_DECOVF_TRAP
Decimal overflow trap. (Only a few machines have decimal
arithmetic and C never uses it.)
-- Macro: int SIGILL
The name of this signal is derived from “illegal instruction”; it
usually means your program is trying to execute garbage or a
privileged instruction. Since the C compiler generates only valid
instructions, SIGILL typically indicates that the executable file
is corrupted, or that you are trying to execute data. Some common
ways of getting into the latter situation are by passing an invalid
object where a pointer to a function was expected, or by writing
past the end of an automatic array (or similar problems with
pointers to automatic variables) and corrupting other data on the
stack such as the return address of a stack frame.
SIGILL can also be generated when the stack overflows, or when
the system has trouble running the handler for a signal.
-- Macro: int SIGSEGV
This signal is generated when a program tries to read or write
outside the memory that is allocated for it, or to write memory
that can only be read. (Actually, the signals only occur when the
program goes far enough outside to be detected by the systems
memory protection mechanism.) The name is an abbreviation for
“segmentation violation”.
Common ways of getting a SIGSEGV condition include dereferencing
a null or uninitialized pointer, or when you use a pointer to step
through an array, but fail to check for the end of the array. It
varies among systems whether dereferencing a null pointer generates
SIGSEGV or SIGBUS.
-- Macro: int SIGBUS
This signal is generated when an invalid pointer is dereferenced.
Like SIGSEGV, this signal is typically the result of
dereferencing an uninitialized pointer. The difference between the
two is that SIGSEGV indicates an invalid access to valid memory,
while SIGBUS indicates an access to an invalid address. In
particular, SIGBUS signals often result from dereferencing a
misaligned pointer, such as referring to a four-word integer at an
address not divisible by four. (Each kind of computer has its own
requirements for address alignment.)
The name of this signal is an abbreviation for “bus error”.
-- Macro: int SIGABRT
This signal indicates an error detected by the program itself and
reported by calling abort. *Note Aborting a Program::.
-- Macro: int SIGIOT
Generated by the PDP-11 “iot” instruction. On most machines, this
is just another name for SIGABRT.
-- Macro: int SIGTRAP
Generated by the machines breakpoint instruction, and possibly
other trap instructions. This signal is used by debuggers. Your
program will probably only see SIGTRAP if it is somehow executing
bad instructions.
-- Macro: int SIGEMT
Emulator trap; this results from certain unimplemented instructions
which might be emulated in software, or the operating systems
failure to properly emulate them.
-- Macro: int SIGSYS
Bad system call; that is to say, the instruction to trap to the
operating system was executed, but the code number for the system
call to perform was invalid.

File: libc.info, Node: Termination Signals, Next: Alarm Signals, Prev: Program Error Signals, Up: Standard Signals
24.2.2 Termination Signals
--------------------------
These signals are all used to tell a process to terminate, in one way or
another. They have different names because theyre used for slightly
different purposes, and programs might want to handle them differently.
The reason for handling these signals is usually so your program can
tidy up as appropriate before actually terminating. For example, you
might want to save state information, delete temporary files, or restore
the previous terminal modes. Such a handler should end by specifying
the default action for the signal that happened and then reraising it;
this will cause the program to terminate with that signal, as if it had
not had a handler. (*Note Termination in Handler::.)
The (obvious) default action for all of these signals is to cause the
process to terminate.
-- Macro: int SIGTERM
The SIGTERM signal is a generic signal used to cause program
termination. Unlike SIGKILL, this signal can be blocked,
handled, and ignored. It is the normal way to politely ask a
program to terminate.
The shell command kill generates SIGTERM by default.
-- Macro: int SIGINT
The SIGINT (“program interrupt”) signal is sent when the user
types the INTR character (normally C-c). *Note Special
Characters::, for information about terminal driver support for
C-c.
-- Macro: int SIGQUIT
The SIGQUIT signal is similar to SIGINT, except that its
controlled by a different key—the QUIT character, usually C-\—and
produces a core dump when it terminates the process, just like a
program error signal. You can think of this as a program error
condition “detected” by the user.
*Note Program Error Signals::, for information about core dumps.
*Note Special Characters::, for information about terminal driver
support.
Certain kinds of cleanups are best omitted in handling SIGQUIT.
For example, if the program creates temporary files, it should
handle the other termination requests by deleting the temporary
files. But it is better for SIGQUIT not to delete them, so that
the user can examine them in conjunction with the core dump.
-- Macro: int SIGKILL
The SIGKILL signal is used to cause immediate program
termination. It cannot be handled or ignored, and is therefore
always fatal. It is also not possible to block this signal.
This signal is usually generated only by explicit request. Since
it cannot be handled, you should generate it only as a last resort,
after first trying a less drastic method such as C-c or
SIGTERM. If a process does not respond to any other termination
signals, sending it a SIGKILL signal will almost always cause it
to go away.
In fact, if SIGKILL fails to terminate a process, that by itself
constitutes an operating system bug which you should report.
The system will generate SIGKILL for a process itself under some
unusual conditions where the program cannot possibly continue to
run (even to run a signal handler).
-- Macro: int SIGHUP
The SIGHUP (“hang-up”) signal is used to report that the users
terminal is disconnected, perhaps because a network or telephone
connection was broken. For more information about this, see *note
Control Modes::.
This signal is also used to report the termination of the
controlling process on a terminal to jobs associated with that
session; this termination effectively disconnects all processes in
the session from the controlling terminal. For more information,
see *note Termination Internals::.

File: libc.info, Node: Alarm Signals, Next: Asynchronous I/O Signals, Prev: Termination Signals, Up: Standard Signals
24.2.3 Alarm Signals
--------------------
These signals are used to indicate the expiration of timers. *Note
Setting an Alarm::, for information about functions that cause these
signals to be sent.
The default behavior for these signals is to cause program
termination. This default is rarely useful, but no other default would
be useful; most of the ways of using these signals would require handler
functions in any case.
-- Macro: int SIGALRM
This signal typically indicates expiration of a timer that measures
real or clock time. It is used by the alarm function, for
example.
-- Macro: int SIGVTALRM
This signal typically indicates expiration of a timer that measures
CPU time used by the current process. The name is an abbreviation
for “virtual time alarm”.
-- Macro: int SIGPROF
This signal typically indicates expiration of a timer that measures
both CPU time used by the current process, and CPU time expended on
behalf of the process by the system. Such a timer is used to
implement code profiling facilities, hence the name of this signal.

File: libc.info, Node: Asynchronous I/O Signals, Next: Job Control Signals, Prev: Alarm Signals, Up: Standard Signals
24.2.4 Asynchronous I/O Signals
-------------------------------
The signals listed in this section are used in conjunction with
asynchronous I/O facilities. You have to take explicit action by
calling fcntl to enable a particular file descriptor to generate these
signals (*note Interrupt Input::). The default action for these signals
is to ignore them.
-- Macro: int SIGIO
This signal is sent when a file descriptor is ready to perform
input or output.
On most operating systems, terminals and sockets are the only kinds
of files that can generate SIGIO; other kinds, including ordinary
files, never generate SIGIO even if you ask them to.
On GNU systems SIGIO will always be generated properly if you
successfully set asynchronous mode with fcntl.
-- Macro: int SIGURG
This signal is sent when “urgent” or out-of-band data arrives on a
socket. *Note Out-of-Band Data::.
-- Macro: int SIGPOLL
This is a System V signal name, more or less similar to SIGIO.
It is defined only for compatibility.

File: libc.info, Node: Job Control Signals, Next: Operation Error Signals, Prev: Asynchronous I/O Signals, Up: Standard Signals
24.2.5 Job Control Signals
--------------------------
These signals are used to support job control. If your system doesnt
support job control, then these macros are defined but the signals
themselves cant be raised or handled.
You should generally leave these signals alone unless you really
understand how job control works. *Note Job Control::.
-- Macro: int SIGCHLD
This signal is sent to a parent process whenever one of its child
processes terminates or stops.
The default action for this signal is to ignore it. If you
establish a handler for this signal while there are child processes
that have terminated but not reported their status via wait or
waitpid (*note Process Completion::), whether your new handler
applies to those processes or not depends on the particular
operating system.
-- Macro: int SIGCLD
This is an obsolete name for SIGCHLD.
-- Macro: int SIGCONT
You can send a SIGCONT signal to a process to make it continue.
This signal is special—it always makes the process continue if it
is stopped, before the signal is delivered. The default behavior
is to do nothing else. You cannot block this signal. You can set
a handler, but SIGCONT always makes the process continue
regardless.
Most programs have no reason to handle SIGCONT; they simply
resume execution without realizing they were ever stopped. You can
use a handler for SIGCONT to make a program do something special
when it is stopped and continued—for example, to reprint a prompt
when it is suspended while waiting for input.
-- Macro: int SIGSTOP
The SIGSTOP signal stops the process. It cannot be handled,
ignored, or blocked.
-- Macro: int SIGTSTP
The SIGTSTP signal is an interactive stop signal. Unlike
SIGSTOP, this signal can be handled and ignored.
Your program should handle this signal if you have a special need
to leave files or system tables in a secure state when a process is
stopped. For example, programs that turn off echoing should handle
SIGTSTP so they can turn echoing back on before stopping.
This signal is generated when the user types the SUSP character
(normally C-z). For more information about terminal driver
support, see *note Special Characters::.
-- Macro: int SIGTTIN
A process cannot read from the users terminal while it is running
as a background job. When any process in a background job tries to
read from the terminal, all of the processes in the job are sent a
SIGTTIN signal. The default action for this signal is to stop
the process. For more information about how this interacts with
the terminal driver, see *note Access to the Terminal::.
-- Macro: int SIGTTOU
This is similar to SIGTTIN, but is generated when a process in a
background job attempts to write to the terminal or set its modes.
Again, the default action is to stop the process. SIGTTOU is
only generated for an attempt to write to the terminal if the
TOSTOP output mode is set; *note Output Modes::.
While a process is stopped, no more signals can be delivered to it
until it is continued, except SIGKILL signals and (obviously)
SIGCONT signals. The signals are marked as pending, but not delivered
until the process is continued. The SIGKILL signal always causes
termination of the process and cant be blocked, handled or ignored.
You can ignore SIGCONT, but it always causes the process to be
continued anyway if it is stopped. Sending a SIGCONT signal to a
process causes any pending stop signals for that process to be
discarded. Likewise, any pending SIGCONT signals for a process are
discarded when it receives a stop signal.
When a process in an orphaned process group (*note Orphaned Process
Groups::) receives a SIGTSTP, SIGTTIN, or SIGTTOU signal and does
not handle it, the process does not stop. Stopping the process would
probably not be very useful, since there is no shell program that will
notice it stop and allow the user to continue it. What happens instead
depends on the operating system you are using. Some systems may do
nothing; others may deliver another signal instead, such as SIGKILL or
SIGHUP. On GNU/Hurd systems, the process dies with SIGKILL; this
avoids the problem of many stopped, orphaned processes lying around the
system.

File: libc.info, Node: Operation Error Signals, Next: Miscellaneous Signals, Prev: Job Control Signals, Up: Standard Signals
24.2.6 Operation Error Signals
------------------------------
These signals are used to report various errors generated by an
operation done by the program. They do not necessarily indicate a
programming error in the program, but an error that prevents an
operating system call from completing. The default action for all of
them is to cause the process to terminate.
-- Macro: int SIGPIPE
Broken pipe. If you use pipes or FIFOs, you have to design your
application so that one process opens the pipe for reading before
another starts writing. If the reading process never starts, or
terminates unexpectedly, writing to the pipe or FIFO raises a
SIGPIPE signal. If SIGPIPE is blocked, handled or ignored, the
offending call fails with EPIPE instead.
Pipes and FIFO special files are discussed in more detail in *note
Pipes and FIFOs::.
Another cause of SIGPIPE is when you try to output to a socket
that isnt connected. *Note Sending Data::.
-- Macro: int SIGLOST
Resource lost. This signal is generated when you have an advisory
lock on an NFS file, and the NFS server reboots and forgets about
your lock.
On GNU/Hurd systems, SIGLOST is generated when any server program
dies unexpectedly. It is usually fine to ignore the signal;
whatever call was made to the server that died just returns an
error.
-- Macro: int SIGXCPU
CPU time limit exceeded. This signal is generated when the process
exceeds its soft resource limit on CPU time. *Note Limits on
Resources::.
-- Macro: int SIGXFSZ
File size limit exceeded. This signal is generated when the
process attempts to extend a file so it exceeds the processs soft
resource limit on file size. *Note Limits on Resources::.

File: libc.info, Node: Miscellaneous Signals, Next: Signal Messages, Prev: Operation Error Signals, Up: Standard Signals
24.2.7 Miscellaneous Signals
----------------------------
These signals are used for various other purposes. In general, they
will not affect your program unless it explicitly uses them for
something.
-- Macro: int SIGUSR1
-- Macro: int SIGUSR2
The SIGUSR1 and SIGUSR2 signals are set aside for you to use
any way you want. Theyre useful for simple interprocess
communication, if you write a signal handler for them in the
program that receives the signal.
There is an example showing the use of SIGUSR1 and SIGUSR2 in
*note Signaling Another Process::.
The default action is to terminate the process.
-- Macro: int SIGWINCH
Window size change. This is generated on some systems (including
GNU) when the terminal drivers record of the number of rows and
columns on the screen is changed. The default action is to ignore
it.
If a program does full-screen display, it should handle SIGWINCH.
When the signal arrives, it should fetch the new screen size and
reformat its display accordingly.
-- Macro: int SIGINFO
Information request. On 4.4 BSD and GNU/Hurd systems, this signal
is sent to all the processes in the foreground process group of the
controlling terminal when the user types the STATUS character in
canonical mode; *note Signal Characters::.
If the process is the leader of the process group, the default
action is to print some status information about the system and
what the process is doing. Otherwise the default is to do nothing.

File: libc.info, Node: Signal Messages, Prev: Miscellaneous Signals, Up: Standard Signals
24.2.8 Signal Messages
----------------------
We mentioned above that the shell prints a message describing the signal
that terminated a child process. The clean way to print a message
describing a signal is to use the functions strsignal and psignal.
These functions use a signal number to specify which kind of signal to
describe. The signal number may come from the termination status of a
child process (*note Process Completion::) or it may come from a signal
handler in the same process.
-- Function: char * strsignal (int SIGNUM)
Preliminary: | MT-Unsafe race:strsignal locale | AS-Unsafe init
i18n corrupt heap | AC-Unsafe init corrupt mem | *Note POSIX Safety
Concepts::.
This function returns a pointer to a statically-allocated string
containing a message describing the signal SIGNUM. You should not
modify the contents of this string; and, since it can be rewritten
on subsequent calls, you should save a copy of it if you need to
reference it later.
This function is a GNU extension, declared in the header file
string.h.
-- Function: void psignal (int SIGNUM, const char *MESSAGE)
Preliminary: | MT-Safe locale | AS-Unsafe corrupt i18n heap |
AC-Unsafe lock corrupt mem | *Note POSIX Safety Concepts::.
This function prints a message describing the signal SIGNUM to the
standard error output stream stderr; see *note Standard
Streams::.
If you call psignal with a MESSAGE that is either a null pointer
or an empty string, psignal just prints the message corresponding
to SIGNUM, adding a trailing newline.
If you supply a non-null MESSAGE argument, then psignal prefixes
its output with this string. It adds a colon and a space character
to separate the MESSAGE from the string corresponding to SIGNUM.
This function is a BSD feature, declared in the header file
signal.h.
There is also an array sys_siglist which contains the messages for
the various signal codes. This array exists on BSD systems, unlike
strsignal.

File: libc.info, Node: Signal Actions, Next: Defining Handlers, Prev: Standard Signals, Up: Signal Handling
24.3 Specifying Signal Actions
==============================
The simplest way to change the action for a signal is to use the
signal function. You can specify a built-in action (such as to ignore
the signal), or you can “establish a handler”.
The GNU C Library also implements the more versatile sigaction
facility. This section describes both facilities and gives suggestions
on which to use when.
* Menu:
* Basic Signal Handling:: The simple signal function.
* Advanced Signal Handling:: The more powerful sigaction function.
* Signal and Sigaction:: How those two functions interact.
* Sigaction Function Example:: An example of using the sigaction function.
* Flags for Sigaction:: Specifying options for signal handling.
* Initial Signal Actions:: How programs inherit signal actions.

File: libc.info, Node: Basic Signal Handling, Next: Advanced Signal Handling, Up: Signal Actions
24.3.1 Basic Signal Handling
----------------------------
The signal function provides a simple interface for establishing an
action for a particular signal. The function and associated macros are
declared in the header file signal.h.
-- Data Type: sighandler_t
This is the type of signal handler functions. Signal handlers take
one integer argument specifying the signal number, and have return
type void. So, you should define handler functions like this:
void HANDLER (int signum) { ... }
The name sighandler_t for this data type is a GNU extension.
-- Function: sighandler_t signal (int SIGNUM, sighandler_t ACTION)
Preliminary: | MT-Safe sigintr | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The signal function establishes ACTION as the action for the
signal SIGNUM.
The first argument, SIGNUM, identifies the signal whose behavior
you want to control, and should be a signal number. The proper way
to specify a signal number is with one of the symbolic signal names
(*note Standard Signals::)—dont use an explicit number, because
the numerical code for a given kind of signal may vary from
operating system to operating system.
The second argument, ACTION, specifies the action to use for the
signal SIGNUM. This can be one of the following:
SIG_DFL
SIG_DFL specifies the default action for the particular
signal. The default actions for various kinds of signals are
stated in *note Standard Signals::.
SIG_IGN
SIG_IGN specifies that the signal should be ignored.
Your program generally should not ignore signals that
represent serious events or that are normally used to request
termination. You cannot ignore the SIGKILL or SIGSTOP
signals at all. You can ignore program error signals like
SIGSEGV, but ignoring the error wont enable the program to
continue executing meaningfully. Ignoring user requests such
as SIGINT, SIGQUIT, and SIGTSTP is unfriendly.
When you do not wish signals to be delivered during a certain
part of the program, the thing to do is to block them, not
ignore them. *Note Blocking Signals::.
HANDLER
Supply the address of a handler function in your program, to
specify running this handler as the way to deliver the signal.
For more information about defining signal handler functions,
see *note Defining Handlers::.
If you set the action for a signal to SIG_IGN, or if you set it
to SIG_DFL and the default action is to ignore that signal, then
any pending signals of that type are discarded (even if they are
blocked). Discarding the pending signals means that they will
never be delivered, not even if you subsequently specify another
action and unblock this kind of signal.
The signal function returns the action that was previously in
effect for the specified SIGNUM. You can save this value and
restore it later by calling signal again.
If signal cant honor the request, it returns SIG_ERR instead.
The following errno error conditions are defined for this
function:
EINVAL
You specified an invalid SIGNUM; or you tried to ignore or
provide a handler for SIGKILL or SIGSTOP.
*Compatibility Note:* A problem encountered when working with the
signal function is that it has different semantics on BSD and SVID
systems. The difference is that on SVID systems the signal handler is
deinstalled after signal delivery. On BSD systems the handler must be
explicitly deinstalled. In the GNU C Library we use the BSD version by
default. To use the SVID version you can either use the function
sysv_signal (see below) or use the _XOPEN_SOURCE feature select
macro (*note Feature Test Macros::). In general, use of these functions
should be avoided because of compatibility problems. It is better to
use sigaction if it is available since the results are much more
reliable.
Here is a simple example of setting up a handler to delete temporary
files when certain fatal signals happen:
#include <signal.h>
void
termination_handler (int signum)
{
struct temp_file *p;
for (p = temp_file_list; p; p = p->next)
unlink (p->name);
}
int
main (void)
{
...
if (signal (SIGINT, termination_handler) == SIG_IGN)
signal (SIGINT, SIG_IGN);
if (signal (SIGHUP, termination_handler) == SIG_IGN)
signal (SIGHUP, SIG_IGN);
if (signal (SIGTERM, termination_handler) == SIG_IGN)
signal (SIGTERM, SIG_IGN);
...
}
Note that if a given signal was previously set to be ignored, this code
avoids altering that setting. This is because non-job-control shells
often ignore certain signals when starting children, and it is important
for the children to respect this.
We do not handle SIGQUIT or the program error signals in this
example because these are designed to provide information for debugging
(a core dump), and the temporary files may give useful information.
-- Function: sighandler_t sysv_signal (int SIGNUM, sighandler_t ACTION)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The sysv_signal implements the behavior of the standard signal
function as found on SVID systems. The difference to BSD systems
is that the handler is deinstalled after a delivery of a signal.
*Compatibility Note:* As said above for signal, this function
should be avoided when possible. sigaction is the preferred
method.
-- Function: sighandler_t ssignal (int SIGNUM, sighandler_t ACTION)
Preliminary: | MT-Safe sigintr | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The ssignal function does the same thing as signal; it is
provided only for compatibility with SVID.
-- Macro: sighandler_t SIG_ERR
The value of this macro is used as the return value from signal
to indicate an error.

File: libc.info, Node: Advanced Signal Handling, Next: Signal and Sigaction, Prev: Basic Signal Handling, Up: Signal Actions
24.3.2 Advanced Signal Handling
-------------------------------
The sigaction function has the same basic effect as signal: to
specify how a signal should be handled by the process. However,
sigaction offers more control, at the expense of more complexity. In
particular, sigaction allows you to specify additional flags to
control when the signal is generated and how the handler is invoked.
The sigaction function is declared in signal.h.
-- Data Type: struct sigaction
Structures of type struct sigaction are used in the sigaction
function to specify all the information about how to handle a
particular signal. This structure contains at least the following
members:
sighandler_t sa_handler
This is used in the same way as the ACTION argument to the
signal function. The value can be SIG_DFL, SIG_IGN, or
a function pointer. *Note Basic Signal Handling::.
sigset_t sa_mask
This specifies a set of signals to be blocked while the
handler runs. Blocking is explained in *note Blocking for
Handler::. Note that the signal that was delivered is
automatically blocked by default before its handler is
started; this is true regardless of the value in sa_mask.
If you want that signal not to be blocked within its handler,
you must write code in the handler to unblock it.
int sa_flags
This specifies various flags which can affect the behavior of
the signal. These are described in more detail in *note Flags
for Sigaction::.
-- Function: int sigaction (int SIGNUM, const struct sigaction
*restrict ACTION, struct sigaction *restrict OLD-ACTION)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The ACTION argument is used to set up a new action for the signal
SIGNUM, while the OLD-ACTION argument is used to return information
about the action previously associated with this signal. (In other
words, OLD-ACTION has the same purpose as the signal functions
return value—you can check to see what the old action in effect for
the signal was, and restore it later if you want.)
Either ACTION or OLD-ACTION can be a null pointer. If OLD-ACTION
is a null pointer, this simply suppresses the return of information
about the old action. If ACTION is a null pointer, the action
associated with the signal SIGNUM is unchanged; this allows you to
inquire about how a signal is being handled without changing that
handling.
The return value from sigaction is zero if it succeeds, and -1
on failure. The following errno error conditions are defined for
this function:
EINVAL
The SIGNUM argument is not valid, or you are trying to trap or
ignore SIGKILL or SIGSTOP.

File: libc.info, Node: Signal and Sigaction, Next: Sigaction Function Example, Prev: Advanced Signal Handling, Up: Signal Actions
24.3.3 Interaction of signal and sigaction
----------------------------------------------
Its possible to use both the signal and sigaction functions within
a single program, but you have to be careful because they can interact
in slightly strange ways.
The sigaction function specifies more information than the signal
function, so the return value from signal cannot express the full
range of sigaction possibilities. Therefore, if you use signal to
save and later reestablish an action, it may not be able to reestablish
properly a handler that was established with sigaction.
To avoid having problems as a result, always use sigaction to save
and restore a handler if your program uses sigaction at all. Since
sigaction is more general, it can properly save and reestablish any
action, regardless of whether it was established originally with
signal or sigaction.
On some systems if you establish an action with signal and then
examine it with sigaction, the handler address that you get may not be
the same as what you specified with signal. It may not even be
suitable for use as an action argument with signal. But you can rely
on using it as an argument to sigaction. This problem never happens
on GNU systems.
So, youre better off using one or the other of the mechanisms
consistently within a single program.
*Portability Note:* The basic signal function is a feature of
ISO C, while sigaction is part of the POSIX.1 standard. If you are
concerned about portability to non-POSIX systems, then you should use
the signal function instead.

File: libc.info, Node: Sigaction Function Example, Next: Flags for Sigaction, Prev: Signal and Sigaction, Up: Signal Actions
24.3.4 sigaction Function Example
-----------------------------------
In *note Basic Signal Handling::, we gave an example of establishing a
simple handler for termination signals using signal. Here is an
equivalent example using sigaction:
#include <signal.h>
void
termination_handler (int signum)
{
struct temp_file *p;
for (p = temp_file_list; p; p = p->next)
unlink (p->name);
}
int
main (void)
{
...
struct sigaction new_action, old_action;
/* Set up the structure to specify the new action. */
new_action.sa_handler = termination_handler;
sigemptyset (&new_action.sa_mask);
new_action.sa_flags = 0;
sigaction (SIGINT, NULL, &old_action);
if (old_action.sa_handler != SIG_IGN)
sigaction (SIGINT, &new_action, NULL);
sigaction (SIGHUP, NULL, &old_action);
if (old_action.sa_handler != SIG_IGN)
sigaction (SIGHUP, &new_action, NULL);
sigaction (SIGTERM, NULL, &old_action);
if (old_action.sa_handler != SIG_IGN)
sigaction (SIGTERM, &new_action, NULL);
...
}
The program just loads the new_action structure with the desired
parameters and passes it in the sigaction call. The usage of
sigemptyset is described later; see *note Blocking Signals::.
As in the example using signal, we avoid handling signals
previously set to be ignored. Here we can avoid altering the signal
handler even momentarily, by using the feature of sigaction that lets
us examine the current action without specifying a new one.
Here is another example. It retrieves information about the current
action for SIGINT without changing that action.
struct sigaction query_action;
if (sigaction (SIGINT, NULL, &query_action) < 0)
/* sigaction returns -1 in case of error. */
else if (query_action.sa_handler == SIG_DFL)
/* SIGINT is handled in the default, fatal manner. */
else if (query_action.sa_handler == SIG_IGN)
/* SIGINT is ignored. */
else
/* A programmer-defined signal handler is in effect. */

File: libc.info, Node: Flags for Sigaction, Next: Initial Signal Actions, Prev: Sigaction Function Example, Up: Signal Actions
24.3.5 Flags for sigaction
----------------------------
The sa_flags member of the sigaction structure is a catch-all for
special features. Most of the time, SA_RESTART is a good value to use
for this field.
The value of sa_flags is interpreted as a bit mask. Thus, you
should choose the flags you want to set, OR those flags together, and
store the result in the sa_flags member of your sigaction structure.
Each signal number has its own set of flags. Each call to
sigaction affects one particular signal number, and the flags that you
specify apply only to that particular signal.
In the GNU C Library, establishing a handler with signal sets all
the flags to zero except for SA_RESTART, whose value depends on the
settings you have made with siginterrupt. *Note Interrupted
Primitives::, to see what this is about.
These macros are defined in the header file signal.h.
-- Macro: int SA_NOCLDSTOP
This flag is meaningful only for the SIGCHLD signal. When the
flag is set, the system delivers the signal for a terminated child
process but not for one that is stopped. By default, SIGCHLD is
delivered for both terminated children and stopped children.
Setting this flag for a signal other than SIGCHLD has no effect.
-- Macro: int SA_ONSTACK
If this flag is set for a particular signal number, the system uses
the signal stack when delivering that kind of signal. *Note Signal
Stack::. If a signal with this flag arrives and you have not set a
signal stack, the system terminates the program with SIGILL.
-- Macro: int SA_RESTART
This flag controls what happens when a signal is delivered during
certain primitives (such as open, read or write), and the
signal handler returns normally. There are two alternatives: the
library function can resume, or it can return failure with error
code EINTR.
The choice is controlled by the SA_RESTART flag for the
particular kind of signal that was delivered. If the flag is set,
returning from a handler resumes the library function. If the flag
is clear, returning from a handler makes the function fail. *Note
Interrupted Primitives::.

File: libc.info, Node: Initial Signal Actions, Prev: Flags for Sigaction, Up: Signal Actions
24.3.6 Initial Signal Actions
-----------------------------
When a new process is created (*note Creating a Process::), it inherits
handling of signals from its parent process. However, when you load a
new process image using the exec function (*note Executing a File::),
any signals that youve defined your own handlers for revert to their
SIG_DFL handling. (If you think about it a little, this makes sense;
the handler functions from the old program are specific to that program,
and arent even present in the address space of the new program image.)
Of course, the new program can establish its own handlers.
When a program is run by a shell, the shell normally sets the initial
actions for the child process to SIG_DFL or SIG_IGN, as appropriate.
Its a good idea to check to make sure that the shell has not set up an
initial action of SIG_IGN before you establish your own signal
handlers.
Here is an example of how to establish a handler for SIGHUP, but
not if SIGHUP is currently ignored:
...
struct sigaction temp;
sigaction (SIGHUP, NULL, &temp);
if (temp.sa_handler != SIG_IGN)
{
temp.sa_handler = handle_sighup;
sigemptyset (&temp.sa_mask);
sigaction (SIGHUP, &temp, NULL);
}

File: libc.info, Node: Defining Handlers, Next: Interrupted Primitives, Prev: Signal Actions, Up: Signal Handling
24.4 Defining Signal Handlers
=============================
This section describes how to write a signal handler function that can
be established with the signal or sigaction functions.
A signal handler is just a function that you compile together with
the rest of the program. Instead of directly invoking the function, you
use signal or sigaction to tell the operating system to call it when
a signal arrives. This is known as “establishing” the handler. *Note
Signal Actions::.
There are two basic strategies you can use in signal handler
functions:
• You can have the handler function note that the signal arrived by
tweaking some global data structures, and then return normally.
• You can have the handler function terminate the program or transfer
control to a point where it can recover from the situation that
caused the signal.
You need to take special care in writing handler functions because
they can be called asynchronously. That is, a handler might be called
at any point in the program, unpredictably. If two signals arrive
during a very short interval, one handler can run within another. This
section describes what your handler should do, and what you should
avoid.
* Menu:
* Handler Returns:: Handlers that return normally, and what
this means.
* Termination in Handler:: How handler functions terminate a program.
* Longjmp in Handler:: Nonlocal transfer of control out of a
signal handler.
* Signals in Handler:: What happens when signals arrive while
the handler is already occupied.
* Merged Signals:: When a second signal arrives before the
first is handled.
* Nonreentrancy:: Do not call any functions unless you know they
are reentrant with respect to signals.
* Atomic Data Access:: A single handler can run in the middle of
reading or writing a single object.

File: libc.info, Node: Handler Returns, Next: Termination in Handler, Up: Defining Handlers
24.4.1 Signal Handlers that Return
----------------------------------
Handlers which return normally are usually used for signals such as
SIGALRM and the I/O and interprocess communication signals. But a
handler for SIGINT might also return normally after setting a flag
that tells the program to exit at a convenient time.
It is not safe to return normally from the handler for a program
error signal, because the behavior of the program when the handler
function returns is not defined after a program error. *Note Program
Error Signals::.
Handlers that return normally must modify some global variable in
order to have any effect. Typically, the variable is one that is
examined periodically by the program during normal operation. Its data
type should be sig_atomic_t for reasons described in *note Atomic Data
Access::.
Here is a simple example of such a program. It executes the body of
the loop until it has noticed that a SIGALRM signal has arrived. This
technique is useful because it allows the iteration in progress when the
signal arrives to complete before the loop exits.
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
/* This flag controls termination of the main loop. */
volatile sig_atomic_t keep_going = 1;
/* The signal handler just clears the flag and re-enables itself. */
void
catch_alarm (int sig)
{
keep_going = 0;
signal (sig, catch_alarm);
}
void
do_stuff (void)
{
puts ("Doing stuff while waiting for alarm....");
}
int
main (void)
{
/* Establish a handler for SIGALRM signals. */
signal (SIGALRM, catch_alarm);
/* Set an alarm to go off in a little while. */
alarm (2);
/* Check the flag once in a while to see when to quit. */
while (keep_going)
do_stuff ();
return EXIT_SUCCESS;
}

File: libc.info, Node: Termination in Handler, Next: Longjmp in Handler, Prev: Handler Returns, Up: Defining Handlers
24.4.2 Handlers That Terminate the Process
------------------------------------------
Handler functions that terminate the program are typically used to cause
orderly cleanup or recovery from program error signals and interactive
interrupts.
The cleanest way for a handler to terminate the process is to raise
the same signal that ran the handler in the first place. Here is how to
do this:
volatile sig_atomic_t fatal_error_in_progress = 0;
void
fatal_error_signal (int sig)
{
/* Since this handler is established for more than one kind of signal,
it might still get invoked recursively by delivery of some other kind
of signal. Use a static variable to keep track of that. */
if (fatal_error_in_progress)
raise (sig);
fatal_error_in_progress = 1;
/* Now do the clean up actions:
- reset terminal modes
- kill child processes
- remove lock files */
...
/* Now reraise the signal. We reactivate the signals
default handling, which is to terminate the process.
We could just call exit or abort,
but reraising the signal sets the return status
from the process correctly. */
signal (sig, SIG_DFL);
raise (sig);
}

File: libc.info, Node: Longjmp in Handler, Next: Signals in Handler, Prev: Termination in Handler, Up: Defining Handlers
24.4.3 Nonlocal Control Transfer in Handlers
--------------------------------------------
You can do a nonlocal transfer of control out of a signal handler using
the setjmp and longjmp facilities (*note Non-Local Exits::).
When the handler does a nonlocal control transfer, the part of the
program that was running will not continue. If this part of the program
was in the middle of updating an important data structure, the data
structure will remain inconsistent. Since the program does not
terminate, the inconsistency is likely to be noticed later on.
There are two ways to avoid this problem. One is to block the signal
for the parts of the program that update important data structures.
Blocking the signal delays its delivery until it is unblocked, once the
critical updating is finished. *Note Blocking Signals::.
The other way is to re-initialize the crucial data structures in the
signal handler, or to make their values consistent.
Here is a rather schematic example showing the reinitialization of
one global variable.
#include <signal.h>
#include <setjmp.h>
jmp_buf return_to_top_level;
volatile sig_atomic_t waiting_for_input;
void
handle_sigint (int signum)
{
/* We may have been waiting for input when the signal arrived,
but we are no longer waiting once we transfer control. */
waiting_for_input = 0;
longjmp (return_to_top_level, 1);
}
int
main (void)
{
...
signal (SIGINT, sigint_handler);
...
while (1) {
prepare_for_command ();
if (setjmp (return_to_top_level) == 0)
read_and_execute_command ();
}
}
/* Imagine this is a subroutine used by various commands. */
char *
read_data ()
{
if (input_from_terminal) {
waiting_for_input = 1;
...
waiting_for_input = 0;
} else {
...
}
}

File: libc.info, Node: Signals in Handler, Next: Merged Signals, Prev: Longjmp in Handler, Up: Defining Handlers
24.4.4 Signals Arriving While a Handler Runs
--------------------------------------------
What happens if another signal arrives while your signal handler
function is running?
When the handler for a particular signal is invoked, that signal is
automatically blocked until the handler returns. That means that if two
signals of the same kind arrive close together, the second one will be
held until the first has been handled. (The handler can explicitly
unblock the signal using sigprocmask, if you want to allow more
signals of this type to arrive; see *note Process Signal Mask::.)
However, your handler can still be interrupted by delivery of another
kind of signal. To avoid this, you can use the sa_mask member of the
action structure passed to sigaction to explicitly specify which
signals should be blocked while the signal handler runs. These signals
are in addition to the signal for which the handler was invoked, and any
other signals that are normally blocked by the process. *Note Blocking
for Handler::.
When the handler returns, the set of blocked signals is restored to
the value it had before the handler ran. So using sigprocmask inside
the handler only affects what signals can arrive during the execution of
the handler itself, not what signals can arrive once the handler
returns.
*Portability Note:* Always use sigaction to establish a handler for
a signal that you expect to receive asynchronously, if you want your
program to work properly on System V Unix. On this system, the handling
of a signal whose handler was established with signal automatically
sets the signals action back to SIG_DFL, and the handler must
re-establish itself each time it runs. This practice, while
inconvenient, does work when signals cannot arrive in succession.
However, if another signal can arrive right away, it may arrive before
the handler can re-establish itself. Then the second signal would
receive the default handling, which could terminate the process.

File: libc.info, Node: Merged Signals, Next: Nonreentrancy, Prev: Signals in Handler, Up: Defining Handlers
24.4.5 Signals Close Together Merge into One
--------------------------------------------
If multiple signals of the same type are delivered to your process
before your signal handler has a chance to be invoked at all, the
handler may only be invoked once, as if only a single signal had
arrived. In effect, the signals merge into one. This situation can
arise when the signal is blocked, or in a multiprocessing environment
where the system is busy running some other processes while the signals
are delivered. This means, for example, that you cannot reliably use a
signal handler to count signals. The only distinction you can reliably
make is whether at least one signal has arrived since a given time in
the past.
Here is an example of a handler for SIGCHLD that compensates for
the fact that the number of signals received may not equal the number of
child processes that generate them. It assumes that the program keeps
track of all the child processes with a chain of structures as follows:
struct process
{
struct process *next;
/* The process ID of this child. */
int pid;
/* The descriptor of the pipe or pseudo terminal
on which output comes from this child. */
int input_descriptor;
/* Nonzero if this process has stopped or terminated. */
sig_atomic_t have_status;
/* The status of this child; 0 if running,
otherwise a status value from waitpid. */
int status;
};
struct process *process_list;
This example also uses a flag to indicate whether signals have
arrived since some time in the past—whenever the program last cleared it
to zero.
/* Nonzero means some childs status has changed
so look at process_list for the details. */
int process_status_change;
Here is the handler itself:
void
sigchld_handler (int signo)
{
int old_errno = errno;
while (1) {
register int pid;
int w;
struct process *p;
/* Keep asking for a status until we get a definitive result. */
do
{
errno = 0;
pid = waitpid (WAIT_ANY, &w, WNOHANG | WUNTRACED);
}
while (pid <= 0 && errno == EINTR);
if (pid <= 0) {
/* A real failure means there are no more
stopped or terminated child processes, so return. */
errno = old_errno;
return;
}
/* Find the process that signaled us, and record its status. */
for (p = process_list; p; p = p->next)
if (p->pid == pid) {
p->status = w;
/* Indicate that the status field
has data to look at. We do this only after storing it. */
p->have_status = 1;
/* If process has terminated, stop waiting for its output. */
if (WIFSIGNALED (w) || WIFEXITED (w))
if (p->input_descriptor)
FD_CLR (p->input_descriptor, &input_wait_mask);
/* The program should check this flag from time to time
to see if there is any news in process_list. */
++process_status_change;
}
/* Loop around to handle all the processes
that have something to tell us. */
}
}
Here is the proper way to check the flag process_status_change:
if (process_status_change) {
struct process *p;
process_status_change = 0;
for (p = process_list; p; p = p->next)
if (p->have_status) {
... Examine p->status ...
}
}
It is vital to clear the flag before examining the list; otherwise, if a
signal were delivered just before the clearing of the flag, and after
the appropriate element of the process list had been checked, the status
change would go unnoticed until the next signal arrived to set the flag
again. You could, of course, avoid this problem by blocking the signal
while scanning the list, but it is much more elegant to guarantee
correctness by doing things in the right order.
The loop which checks process status avoids examining p->status
until it sees that status has been validly stored. This is to make sure
that the status cannot change in the middle of accessing it. Once
p->have_status is set, it means that the child process is stopped or
terminated, and in either case, it cannot stop or terminate again until
the program has taken notice. *Note Atomic Usage::, for more
information about coping with interruptions during accesses of a
variable.
Here is another way you can test whether the handler has run since
the last time you checked. This technique uses a counter which is never
changed outside the handler. Instead of clearing the count, the program
remembers the previous value and sees whether it has changed since the
previous check. The advantage of this method is that different parts of
the program can check independently, each part checking whether there
has been a signal since that part last checked.
sig_atomic_t process_status_change;
sig_atomic_t last_process_status_change;
...
{
sig_atomic_t prev = last_process_status_change;
last_process_status_change = process_status_change;
if (last_process_status_change != prev) {
struct process *p;
for (p = process_list; p; p = p->next)
if (p->have_status) {
... Examine p->status ...
}
}
}

File: libc.info, Node: Nonreentrancy, Next: Atomic Data Access, Prev: Merged Signals, Up: Defining Handlers
24.4.6 Signal Handling and Nonreentrant Functions
-------------------------------------------------
Handler functions usually dont do very much. The best practice is to
write a handler that does nothing but set an external variable that the
program checks regularly, and leave all serious work to the program.
This is best because the handler can be called asynchronously, at
unpredictable times—perhaps in the middle of a primitive function, or
even between the beginning and the end of a C operator that requires
multiple instructions. The data structures being manipulated might
therefore be in an inconsistent state when the handler function is
invoked. Even copying one int variable into another can take two
instructions on most machines.
This means you have to be very careful about what you do in a signal
handler.
• If your handler needs to access any global variables from your
program, declare those variables volatile. This tells the
compiler that the value of the variable might change
asynchronously, and inhibits certain optimizations that would be
invalidated by such modifications.
• If you call a function in the handler, make sure it is “reentrant”
with respect to signals, or else make sure that the signal cannot
interrupt a call to a related function.
A function can be non-reentrant if it uses memory that is not on the
stack.
• If a function uses a static variable or a global variable, or a
dynamically-allocated object that it finds for itself, then it is
non-reentrant and any two calls to the function can interfere.
For example, suppose that the signal handler uses gethostbyname.
This function returns its value in a static object, reusing the
same object each time. If the signal happens to arrive during a
call to gethostbyname, or even after one (while the program is
still using the value), it will clobber the value that the program
asked for.
However, if the program does not use gethostbyname or any other
function that returns information in the same object, or if it
always blocks signals around each use, then you are safe.
There are a large number of library functions that return values in
a fixed object, always reusing the same object in this fashion, and
all of them cause the same problem. Function descriptions in this
manual always mention this behavior.
• If a function uses and modifies an object that you supply, then it
is potentially non-reentrant; two calls can interfere if they use
the same object.
This case arises when you do I/O using streams. Suppose that the
signal handler prints a message with fprintf. Suppose that the
program was in the middle of an fprintf call using the same
stream when the signal was delivered. Both the signal handlers
message and the programs data could be corrupted, because both
calls operate on the same data structure—the stream itself.
However, if you know that the stream that the handler uses cannot
possibly be used by the program at a time when signals can arrive,
then you are safe. It is no problem if the program uses some other
stream.
• On most systems, malloc and free are not reentrant, because
they use a static data structure which records what memory blocks
are free. As a result, no library functions that allocate or free
memory are reentrant. This includes functions that allocate space
to store a result.
The best way to avoid the need to allocate memory in a handler is
to allocate in advance space for signal handlers to use.
The best way to avoid freeing memory in a handler is to flag or
record the objects to be freed, and have the program check from
time to time whether anything is waiting to be freed. But this
must be done with care, because placing an object on a chain is not
atomic, and if it is interrupted by another signal handler that
does the same thing, you could “lose” one of the objects.
• Any function that modifies errno is non-reentrant, but you can
correct for this: in the handler, save the original value of
errno and restore it before returning normally. This prevents
errors that occur within the signal handler from being confused
with errors from system calls at the point the program is
interrupted to run the handler.
This technique is generally applicable; if you want to call in a
handler a function that modifies a particular object in memory, you
can make this safe by saving and restoring that object.
• Merely reading from a memory object is safe provided that you can
deal with any of the values that might appear in the object at a
time when the signal can be delivered. Keep in mind that
assignment to some data types requires more than one instruction,
which means that the handler could run “in the middle of” an
assignment to the variable if its type is not atomic. *Note Atomic
Data Access::.
• Merely writing into a memory object is safe as long as a sudden
change in the value, at any time when the handler might run, will
not disturb anything.

File: libc.info, Node: Atomic Data Access, Prev: Nonreentrancy, Up: Defining Handlers
24.4.7 Atomic Data Access and Signal Handling
---------------------------------------------
Whether the data in your application concerns atoms, or mere text, you
have to be careful about the fact that access to a single datum is not
necessarily “atomic”. This means that it can take more than one
instruction to read or write a single object. In such cases, a signal
handler might be invoked in the middle of reading or writing the object.
There are three ways you can cope with this problem. You can use
data types that are always accessed atomically; you can carefully
arrange that nothing untoward happens if an access is interrupted, or
you can block all signals around any access that had better not be
interrupted (*note Blocking Signals::).
* Menu:
* Non-atomic Example:: A program illustrating interrupted access.
* Types: Atomic Types. Data types that guarantee no interruption.
* Usage: Atomic Usage. Proving that interruption is harmless.

File: libc.info, Node: Non-atomic Example, Next: Atomic Types, Up: Atomic Data Access
24.4.7.1 Problems with Non-Atomic Access
........................................
Here is an example which shows what can happen if a signal handler runs
in the middle of modifying a variable. (Interrupting the reading of a
variable can also lead to paradoxical results, but here we only show
writing.)
#include <signal.h>
#include <stdio.h>
volatile struct two_words { int a, b; } memory;
void
handler(int signum)
{
printf ("%d,%d\n", memory.a, memory.b);
alarm (1);
}
int
main (void)
{
static struct two_words zeros = { 0, 0 }, ones = { 1, 1 };
signal (SIGALRM, handler);
memory = zeros;
alarm (1);
while (1)
{
memory = zeros;
memory = ones;
}
}
This program fills memory with zeros, ones, zeros, ones,
alternating forever; meanwhile, once per second, the alarm signal
handler prints the current contents. (Calling printf in the handler
is safe in this program because it is certainly not being called outside
the handler when the signal happens.)
Clearly, this program can print a pair of zeros or a pair of ones.
But thats not all it can do! On most machines, it takes several
instructions to store a new value in memory, and the value is stored
one word at a time. If the signal is delivered in between these
instructions, the handler might find that memory.a is zero and
memory.b is one (or vice versa).
On some machines it may be possible to store a new value in memory
with just one instruction that cannot be interrupted. On these
machines, the handler will always print two zeros or two ones.

File: libc.info, Node: Atomic Types, Next: Atomic Usage, Prev: Non-atomic Example, Up: Atomic Data Access
24.4.7.2 Atomic Types
.....................
To avoid uncertainty about interrupting access to a variable, you can
use a particular data type for which access is always atomic:
sig_atomic_t. Reading and writing this data type is guaranteed to
happen in a single instruction, so theres no way for a handler to run
“in the middle” of an access.
The type sig_atomic_t is always an integer data type, but which one
it is, and how many bits it contains, may vary from machine to machine.
-- Data Type: sig_atomic_t
This is an integer data type. Objects of this type are always
accessed atomically.
In practice, you can assume that int is atomic. You can also
assume that pointer types are atomic; that is very convenient. Both of
these assumptions are true on all of the machines that the GNU C Library
supports and on all POSIX systems we know of.

File: libc.info, Node: Atomic Usage, Prev: Atomic Types, Up: Atomic Data Access
24.4.7.3 Atomic Usage Patterns
..............................
Certain patterns of access avoid any problem even if an access is
interrupted. For example, a flag which is set by the handler, and
tested and cleared by the main program from time to time, is always safe
even if access actually requires two instructions. To show that this is
so, we must consider each access that could be interrupted, and show
that there is no problem if it is interrupted.
An interrupt in the middle of testing the flag is safe because either
its recognized to be nonzero, in which case the precise value doesnt
matter, or it will be seen to be nonzero the next time its tested.
An interrupt in the middle of clearing the flag is no problem because
either the value ends up zero, which is what happens if a signal comes
in just before the flag is cleared, or the value ends up nonzero, and
subsequent events occur as if the signal had come in just after the flag
was cleared. As long as the code handles both of these cases properly,
it can also handle a signal in the middle of clearing the flag. (This
is an example of the sort of reasoning you need to do to figure out
whether non-atomic usage is safe.)
Sometimes you can ensure uninterrupted access to one object by
protecting its use with another object, perhaps one whose type
guarantees atomicity. *Note Merged Signals::, for an example.

File: libc.info, Node: Interrupted Primitives, Next: Generating Signals, Prev: Defining Handlers, Up: Signal Handling
24.5 Primitives Interrupted by Signals
======================================
A signal can arrive and be handled while an I/O primitive such as open
or read is waiting for an I/O device. If the signal handler returns,
the system faces the question: what should happen next?
POSIX specifies one approach: make the primitive fail right away.
The error code for this kind of failure is EINTR. This is flexible,
but usually inconvenient. Typically, POSIX applications that use signal
handlers must check for EINTR after each library function that can
return it, in order to try the call again. Often programmers forget to
check, which is a common source of error.
The GNU C Library provides a convenient way to retry a call after a
temporary failure, with the macro TEMP_FAILURE_RETRY:
-- Macro: TEMP_FAILURE_RETRY (EXPRESSION)
This macro evaluates EXPRESSION once, and examines its value as
type long int. If the value equals -1, that indicates a
failure and errno should be set to show what kind of failure. If
it fails and reports error code EINTR, TEMP_FAILURE_RETRY
evaluates it again, and over and over until the result is not a
temporary failure.
The value returned by TEMP_FAILURE_RETRY is whatever value
EXPRESSION produced.
BSD avoids EINTR entirely and provides a more convenient approach:
to restart the interrupted primitive, instead of making it fail. If you
choose this approach, you need not be concerned with EINTR.
You can choose either approach with the GNU C Library. If you use
sigaction to establish a signal handler, you can specify how that
handler should behave. If you specify the SA_RESTART flag, return
from that handler will resume a primitive; otherwise, return from that
handler will cause EINTR. *Note Flags for Sigaction::.
Another way to specify the choice is with the siginterrupt
function. *Note BSD Signal Handling::.
When you dont specify with sigaction or siginterrupt what a
particular handler should do, it uses a default choice. The default
choice in the GNU C Library is to make primitives fail with EINTR.
The description of each primitive affected by this issue lists
EINTR among the error codes it can return.
There is one situation where resumption never happens no matter which
choice you make: when a data-transfer function such as read or write
is interrupted by a signal after transferring part of the data. In this
case, the function returns the number of bytes already transferred,
indicating partial success.
This might at first appear to cause unreliable behavior on
record-oriented devices (including datagram sockets; *note Datagrams::),
where splitting one read or write into two would read or write two
records. Actually, there is no problem, because interruption after a
partial transfer cannot happen on such devices; they always transfer an
entire record in one burst, with no waiting once data transfer has
started.

File: libc.info, Node: Generating Signals, Next: Blocking Signals, Prev: Interrupted Primitives, Up: Signal Handling
24.6 Generating Signals
=======================
Besides signals that are generated as a result of a hardware trap or
interrupt, your program can explicitly send signals to itself or to
another process.
* Menu:
* Signaling Yourself:: A process can send a signal to itself.
* Signaling Another Process:: Send a signal to another process.
* Permission for kill:: Permission for using kill.
* Kill Example:: Using kill for Communication.

File: libc.info, Node: Signaling Yourself, Next: Signaling Another Process, Up: Generating Signals
24.6.1 Signaling Yourself
-------------------------
A process can send itself a signal with the raise function. This
function is declared in signal.h.
-- Function: int raise (int SIGNUM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The raise function sends the signal SIGNUM to the calling
process. It returns zero if successful and a nonzero value if it
fails. About the only reason for failure would be if the value of
SIGNUM is invalid.
-- Function: int gsignal (int SIGNUM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The gsignal function does the same thing as raise; it is
provided only for compatibility with SVID.
One convenient use for raise is to reproduce the default behavior
of a signal that you have trapped. For instance, suppose a user of your
program types the SUSP character (usually C-z; *note Special
Characters::) to send it an interactive stop signal (SIGTSTP), and you
want to clean up some internal data buffers before stopping. You might
set this up like this:
#include <signal.h>
/* When a stop signal arrives, set the action back to the default
and then resend the signal after doing cleanup actions. */
void
tstp_handler (int sig)
{
signal (SIGTSTP, SIG_DFL);
/* Do cleanup actions here. */
...
raise (SIGTSTP);
}
/* When the process is continued again, restore the signal handler. */
void
cont_handler (int sig)
{
signal (SIGCONT, cont_handler);
signal (SIGTSTP, tstp_handler);
}
/* Enable both handlers during program initialization. */
int
main (void)
{
signal (SIGCONT, cont_handler);
signal (SIGTSTP, tstp_handler);
...
}
*Portability note:* raise was invented by the ISO C committee.
Older systems may not support it, so using kill may be more portable.
*Note Signaling Another Process::.

File: libc.info, Node: Signaling Another Process, Next: Permission for kill, Prev: Signaling Yourself, Up: Generating Signals
24.6.2 Signaling Another Process
--------------------------------
The kill function can be used to send a signal to another process. In
spite of its name, it can be used for a lot of things other than causing
a process to terminate. Some examples of situations where you might
want to send signals between processes are:
• A parent process starts a child to perform a task—perhaps having
the child running an infinite loop—and then terminates the child
when the task is no longer needed.
• A process executes as part of a group, and needs to terminate or
notify the other processes in the group when an error or other
event occurs.
• Two processes need to synchronize while working together.
This section assumes that you know a little bit about how processes
work. For more information on this subject, see *note Processes::.
The kill function is declared in signal.h.
-- Function: int kill (pid_t PID, int SIGNUM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The kill function sends the signal SIGNUM to the process or
process group specified by PID. Besides the signals listed in
*note Standard Signals::, SIGNUM can also have a value of zero to
check the validity of the PID.
The PID specifies the process or process group to receive the
signal:
PID > 0
The process whose identifier is PID.
PID == 0
All processes in the same process group as the sender.
PID < -1
The process group whose identifier is PID.
PID == -1
If the process is privileged, send the signal to all processes
except for some special system processes. Otherwise, send the
signal to all processes with the same effective user ID.
A process can send a signal to itself with a call like
kill (getpid(), SIGNUM). If kill is used by a process to send
a signal to itself, and the signal is not blocked, then kill
delivers at least one signal (which might be some other pending
unblocked signal instead of the signal SIGNUM) to that process
before it returns.
The return value from kill is zero if the signal can be sent
successfully. Otherwise, no signal is sent, and a value of -1 is
returned. If PID specifies sending a signal to several processes,
kill succeeds if it can send the signal to at least one of them.
Theres no way you can tell which of the processes got the signal
or whether all of them did.
The following errno error conditions are defined for this
function:
EINVAL
The SIGNUM argument is an invalid or unsupported number.
EPERM
You do not have the privilege to send a signal to the process
or any of the processes in the process group named by PID.
ESRCH
The PID argument does not refer to an existing process or
group.
-- Function: int killpg (int PGID, int SIGNUM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is similar to kill, but sends signal SIGNUM to the process
group PGID. This function is provided for compatibility with BSD;
using kill to do this is more portable.
As a simple example of kill, the call kill (getpid (), SIG) has
the same effect as raise (SIG).

File: libc.info, Node: Permission for kill, Next: Kill Example, Prev: Signaling Another Process, Up: Generating Signals
24.6.3 Permission for using kill
----------------------------------
There are restrictions that prevent you from using kill to send
signals to any random process. These are intended to prevent antisocial
behavior such as arbitrarily killing off processes belonging to another
user. In typical use, kill is used to pass signals between parent,
child, and sibling processes, and in these situations you normally do
have permission to send signals. The only common exception is when you
run a setuid program in a child process; if the program changes its real
UID as well as its effective UID, you may not have permission to send a
signal. The su program does this.
Whether a process has permission to send a signal to another process
is determined by the user IDs of the two processes. This concept is
discussed in detail in *note Process Persona::.
Generally, for a process to be able to send a signal to another
process, either the sending process must belong to a privileged user
(like root), or the real or effective user ID of the sending process
must match the real or effective user ID of the receiving process. If
the receiving process has changed its effective user ID from the
set-user-ID mode bit on its process image file, then the owner of the
process image file is used in place of its current effective user ID. In
some implementations, a parent process might be able to send signals to
a child process even if the user IDs dont match, and other
implementations might enforce other restrictions.
The SIGCONT signal is a special case. It can be sent if the sender
is part of the same session as the receiver, regardless of user IDs.

File: libc.info, Node: Kill Example, Prev: Permission for kill, Up: Generating Signals
24.6.4 Using kill for Communication
-------------------------------------
Here is a longer example showing how signals can be used for
interprocess communication. This is what the SIGUSR1 and SIGUSR2
signals are provided for. Since these signals are fatal by default, the
process that is supposed to receive them must trap them through signal
or sigaction.
In this example, a parent process forks a child process and then
waits for the child to complete its initialization. The child process
tells the parent when it is ready by sending it a SIGUSR1 signal,
using the kill function.
#include <signal.h>
#include <stdio.h>
#include <sys/types.h>
#include <unistd.h>
/* When a SIGUSR1 signal arrives, set this variable. */
volatile sig_atomic_t usr_interrupt = 0;
void
synch_signal (int sig)
{
usr_interrupt = 1;
}
/* The child process executes this function. */
void
child_function (void)
{
/* Perform initialization. */
printf ("I'm here!!! My pid is %d.\n", (int) getpid ());
/* Let parent know youre done. */
kill (getppid (), SIGUSR1);
/* Continue with execution. */
puts ("Bye, now....");
exit (0);
}
int
main (void)
{
struct sigaction usr_action;
sigset_t block_mask;
pid_t child_id;
/* Establish the signal handler. */
sigfillset (&block_mask);
usr_action.sa_handler = synch_signal;
usr_action.sa_mask = block_mask;
usr_action.sa_flags = 0;
sigaction (SIGUSR1, &usr_action, NULL);
/* Create the child process. */
child_id = fork ();
if (child_id == 0)
child_function (); /* Does not return. */
/* Busy wait for the child to send a signal. */
while (!usr_interrupt)
;
/* Now continue execution. */
puts ("That's all, folks!");
return 0;
}
This example uses a busy wait, which is bad, because it wastes CPU
cycles that other programs could otherwise use. It is better to ask the
system to wait until the signal arrives. See the example in *note
Waiting for a Signal::.

File: libc.info, Node: Blocking Signals, Next: Waiting for a Signal, Prev: Generating Signals, Up: Signal Handling
24.7 Blocking Signals
=====================
Blocking a signal means telling the operating system to hold it and
deliver it later. Generally, a program does not block signals
indefinitely—it might as well ignore them by setting their actions to
SIG_IGN. But it is useful to block signals briefly, to prevent them
from interrupting sensitive operations. For instance:
• You can use the sigprocmask function to block signals while you
modify global variables that are also modified by the handlers for
these signals.
• You can set sa_mask in your sigaction call to block certain
signals while a particular signal handler runs. This way, the
signal handler can run without being interrupted itself by signals.
* Menu:
* Why Block:: The purpose of blocking signals.
* Signal Sets:: How to specify which signals to
block.
* Process Signal Mask:: Blocking delivery of signals to your
process during normal execution.
* Testing for Delivery:: Blocking to Test for Delivery of
a Signal.
* Blocking for Handler:: Blocking additional signals while a
handler is being run.
* Checking for Pending Signals:: Checking for Pending Signals
* Remembering a Signal:: How you can get almost the same
effect as blocking a signal, by
handling it and setting a flag
to be tested later.

File: libc.info, Node: Why Block, Next: Signal Sets, Up: Blocking Signals
24.7.1 Why Blocking Signals is Useful
-------------------------------------
Temporary blocking of signals with sigprocmask gives you a way to
prevent interrupts during critical parts of your code. If signals
arrive in that part of the program, they are delivered later, after you
unblock them.
One example where this is useful is for sharing data between a signal
handler and the rest of the program. If the type of the data is not
sig_atomic_t (*note Atomic Data Access::), then the signal handler
could run when the rest of the program has only half finished reading or
writing the data. This would lead to confusing consequences.
To make the program reliable, you can prevent the signal handler from
running while the rest of the program is examining or modifying that
data—by blocking the appropriate signal around the parts of the program
that touch the data.
Blocking signals is also necessary when you want to perform a certain
action only if a signal has not arrived. Suppose that the handler for
the signal sets a flag of type sig_atomic_t; you would like to test
the flag and perform the action if the flag is not set. This is
unreliable. Suppose the signal is delivered immediately after you test
the flag, but before the consequent action: then the program will
perform the action even though the signal has arrived.
The only way to test reliably for whether a signal has yet arrived is
to test while the signal is blocked.
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