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gfiber / toolchains / mindspeed / f6153d9b5022adf0575515eaebc05c2a3b08c688 / . / arm-buildroot-linux-gnueabi / sysroot / usr / share / info / libc.info-2
blob: 59b46d85ff3565167a58bf2b660d475ed222249b [file] [log] [blame]
This is
/usr/local/google/home/jnewlin/src/uclibc/buildroot/output/build/glibc-2.19/build/manual/libc.info,
produced by makeinfo version 4.13 from libc.texinfo.
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.
* 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.
* DES_FAILED: (libc)DES Encryption.
* 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.
* 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.
* 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_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.
* 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_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.
* 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.
* SV_INTERRUPT: (libc)BSD Handler.
* SV_ONSTACK: (libc)BSD Handler.
* SV_RESETHAND: (libc)BSD Handler.
* 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_low: (libc)PowerPC.
* __ppc_yield: (libc)PowerPC.
* __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.
* acosh: (libc)Hyperbolic Functions.
* acoshf: (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.
* asinh: (libc)Hyperbolic Functions.
* asinhf: (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.
* atan2l: (libc)Inverse Trig Functions.
* atan: (libc)Inverse Trig Functions.
* atanf: (libc)Inverse Trig Functions.
* atanh: (libc)Hyperbolic Functions.
* atanhf: (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 and Concatenation.
* 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 and Concatenation.
* cabs: (libc)Absolute Value.
* cabsf: (libc)Absolute Value.
* cabsl: (libc)Absolute Value.
* cacos: (libc)Inverse Trig Functions.
* cacosf: (libc)Inverse Trig Functions.
* cacosh: (libc)Hyperbolic Functions.
* cacoshf: (libc)Hyperbolic Functions.
* cacoshl: (libc)Hyperbolic Functions.
* cacosl: (libc)Inverse Trig Functions.
* calloc: (libc)Allocating Cleared Space.
* canonicalize_file_name: (libc)Symbolic Links.
* carg: (libc)Operations on Complex.
* cargf: (libc)Operations on Complex.
* cargl: (libc)Operations on Complex.
* casin: (libc)Inverse Trig Functions.
* casinf: (libc)Inverse Trig Functions.
* casinh: (libc)Hyperbolic Functions.
* casinhf: (libc)Hyperbolic Functions.
* casinhl: (libc)Hyperbolic Functions.
* casinl: (libc)Inverse Trig Functions.
* catan: (libc)Inverse Trig Functions.
* catanf: (libc)Inverse Trig Functions.
* catanh: (libc)Hyperbolic Functions.
* catanhf: (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.
* cbc_crypt: (libc)DES Encryption.
* cbrt: (libc)Exponents and Logarithms.
* cbrtf: (libc)Exponents and Logarithms.
* cbrtl: (libc)Exponents and Logarithms.
* ccos: (libc)Trig Functions.
* ccosf: (libc)Trig Functions.
* ccosh: (libc)Hyperbolic Functions.
* ccoshf: (libc)Hyperbolic Functions.
* ccoshl: (libc)Hyperbolic Functions.
* ccosl: (libc)Trig Functions.
* ceil: (libc)Rounding Functions.
* ceilf: (libc)Rounding Functions.
* ceill: (libc)Rounding Functions.
* cexp: (libc)Exponents and Logarithms.
* cexpf: (libc)Exponents and Logarithms.
* cexpl: (libc)Exponents and Logarithms.
* cfgetispeed: (libc)Line Speed.
* cfgetospeed: (libc)Line Speed.
* cfmakeraw: (libc)Noncanonical Input.
* cfree: (libc)Freeing after Malloc.
* 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.
* 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.
* clog10l: (libc)Exponents and Logarithms.
* clog: (libc)Exponents and Logarithms.
* clogf: (libc)Exponents and Logarithms.
* clogl: (libc)Exponents and Logarithms.
* close: (libc)Opening and Closing Files.
* closedir: (libc)Reading/Closing Directory.
* closelog: (libc)closelog.
* confstr: (libc)String Parameters.
* conj: (libc)Operations on Complex.
* conjf: (libc)Operations on Complex.
* conjl: (libc)Operations on Complex.
* connect: (libc)Connecting.
* copysign: (libc)FP Bit Twiddling.
* copysignf: (libc)FP Bit Twiddling.
* copysignl: (libc)FP Bit Twiddling.
* cos: (libc)Trig Functions.
* cosf: (libc)Trig Functions.
* cosh: (libc)Hyperbolic Functions.
* coshf: (libc)Hyperbolic Functions.
* coshl: (libc)Hyperbolic Functions.
* cosl: (libc)Trig Functions.
* cpow: (libc)Exponents and Logarithms.
* cpowf: (libc)Exponents and Logarithms.
* cpowl: (libc)Exponents and Logarithms.
* cproj: (libc)Operations on Complex.
* cprojf: (libc)Operations on Complex.
* cprojl: (libc)Operations on Complex.
* creal: (libc)Operations on Complex.
* crealf: (libc)Operations on Complex.
* creall: (libc)Operations on Complex.
* creat64: (libc)Opening and Closing Files.
* creat: (libc)Opening and Closing Files.
* crypt: (libc)crypt.
* crypt_r: (libc)crypt.
* csin: (libc)Trig Functions.
* csinf: (libc)Trig Functions.
* csinh: (libc)Hyperbolic Functions.
* csinhf: (libc)Hyperbolic Functions.
* csinhl: (libc)Hyperbolic Functions.
* csinl: (libc)Trig Functions.
* csqrt: (libc)Exponents and Logarithms.
* csqrtf: (libc)Exponents and Logarithms.
* csqrtl: (libc)Exponents and Logarithms.
* ctan: (libc)Trig Functions.
* ctanf: (libc)Trig Functions.
* ctanh: (libc)Hyperbolic Functions.
* ctanhf: (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.
* dcgettext: (libc)Translation with gettext.
* dcngettext: (libc)Advanced gettext functions.
* des_setparity: (libc)DES Encryption.
* 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.
* 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.
* dup2: (libc)Duplicating Descriptors.
* dup: (libc)Duplicating Descriptors.
* ecb_crypt: (libc)DES Encryption.
* ecvt: (libc)System V Number Conversion.
* ecvt_r: (libc)System V Number Conversion.
* encrypt: (libc)DES Encryption.
* encrypt_r: (libc)DES Encryption.
* 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_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.
* erfcl: (libc)Special Functions.
* erff: (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.
* exp10l: (libc)Exponents and Logarithms.
* exp2: (libc)Exponents and Logarithms.
* exp2f: (libc)Exponents and Logarithms.
* exp2l: (libc)Exponents and Logarithms.
* exp: (libc)Exponents and Logarithms.
* expf: (libc)Exponents and Logarithms.
* expl: (libc)Exponents and Logarithms.
* expm1: (libc)Exponents and Logarithms.
* expm1f: (libc)Exponents and Logarithms.
* expm1l: (libc)Exponents and Logarithms.
* fabs: (libc)Absolute Value.
* fabsf: (libc)Absolute Value.
* fabsl: (libc)Absolute Value.
* 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.
* fdiml: (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.
* 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.
* fesetexceptflag: (libc)Status bit operations.
* fesetround: (libc)Rounding.
* fetestexcept: (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.
* floorl: (libc)Rounding Functions.
* fma: (libc)Misc FP Arithmetic.
* fmaf: (libc)Misc FP Arithmetic.
* fmal: (libc)Misc FP Arithmetic.
* fmax: (libc)Misc FP Arithmetic.
* fmaxf: (libc)Misc FP Arithmetic.
* fmaxl: (libc)Misc FP Arithmetic.
* fmemopen: (libc)String Streams.
* fmin: (libc)Misc FP Arithmetic.
* fminf: (libc)Misc FP Arithmetic.
* fminl: (libc)Misc FP Arithmetic.
* fmod: (libc)Remainder Functions.
* fmodf: (libc)Remainder Functions.
* fmodl: (libc)Remainder Functions.
* fmtmsg: (libc)Printing Formatted Messages.
* 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.
* frexpl: (libc)Normalization 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.
* 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.
* 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.
* 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.
* 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.
* 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.
* 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.
* iscntrl: (libc)Classification of Characters.
* isdigit: (libc)Classification of Characters.
* 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.
* 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.
* j0: (libc)Special Functions.
* j0f: (libc)Special Functions.
* j0l: (libc)Special Functions.
* j1: (libc)Special Functions.
* j1f: (libc)Special Functions.
* j1l: (libc)Special Functions.
* jn: (libc)Special Functions.
* jnf: (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.
* 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.
* lgammaf_r: (libc)Special Functions.
* lgammal: (libc)Special Functions.
* lgammal_r: (libc)Special Functions.
* link: (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.
* llrint: (libc)Rounding Functions.
* llrintf: (libc)Rounding Functions.
* llrintl: (libc)Rounding Functions.
* llround: (libc)Rounding Functions.
* llroundf: (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.
* log10l: (libc)Exponents and Logarithms.
* log1p: (libc)Exponents and Logarithms.
* log1pf: (libc)Exponents and Logarithms.
* log1pl: (libc)Exponents and Logarithms.
* log2: (libc)Exponents and Logarithms.
* log2f: (libc)Exponents and Logarithms.
* log2l: (libc)Exponents and Logarithms.
* log: (libc)Exponents and Logarithms.
* logb: (libc)Exponents and Logarithms.
* logbf: (libc)Exponents and Logarithms.
* logbl: (libc)Exponents and Logarithms.
* logf: (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.
* lrintl: (libc)Rounding Functions.
* lround: (libc)Rounding Functions.
* lroundf: (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 and Concatenation.
* memchr: (libc)Search Functions.
* memcmp: (libc)String/Array Comparison.
* memcpy: (libc)Copying and Concatenation.
* memfrob: (libc)Trivial Encryption.
* memmem: (libc)Search Functions.
* memmove: (libc)Copying and Concatenation.
* mempcpy: (libc)Copying and Concatenation.
* memrchr: (libc)Search Functions.
* memset: (libc)Copying and Concatenation.
* 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.
* 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.
* modfl: (libc)Rounding Functions.
* mount: (libc)Mount-Unmount-Remount.
* mprobe: (libc)Heap Consistency Checking.
* 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.
* 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.
* nanl: (libc)FP Bit Twiddling.
* nanosleep: (libc)Sleeping.
* nearbyint: (libc)Rounding Functions.
* nearbyintf: (libc)Rounding Functions.
* nearbyintl: (libc)Rounding Functions.
* nextafter: (libc)FP Bit Twiddling.
* nextafterf: (libc)FP Bit Twiddling.
* nextafterl: (libc)FP Bit Twiddling.
* nexttoward: (libc)FP Bit Twiddling.
* nexttowardf: (libc)FP Bit Twiddling.
* nexttowardl: (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.
* popen: (libc)Pipe to a Subprocess.
* posix_memalign: (libc)Aligned Memory Blocks.
* pow10: (libc)Exponents and Logarithms.
* pow10f: (libc)Exponents and Logarithms.
* pow10l: (libc)Exponents and Logarithms.
* pow: (libc)Exponents and Logarithms.
* powf: (libc)Exponents and Logarithms.
* powl: (libc)Exponents and Logarithms.
* pread64: (libc)I/O Primitives.
* pread: (libc)I/O Primitives.
* 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.
* 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.
* 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.
* 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.
* rintl: (libc)Rounding Functions.
* rmdir: (libc)Deleting Files.
* round: (libc)Rounding Functions.
* roundf: (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.
* scalblnl: (libc)Normalization Functions.
* scalbn: (libc)Normalization Functions.
* scalbnf: (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.
* 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.
* setkey: (libc)DES Encryption.
* setkey_r: (libc)DES Encryption.
* setlinebuf: (libc)Controlling Buffering.
* setlocale: (libc)Setting the Locale.
* setlogmask: (libc)setlogmask.
* setmntent: (libc)mtab.
* setnetent: (libc)Networks Database.
* setnetgrent: (libc)Lookup Netgroup.
* 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)Blocking in BSD.
* sigdelset: (libc)Signal Sets.
* sigemptyset: (libc)Signal Sets.
* sigfillset: (libc)Signal Sets.
* siginterrupt: (libc)BSD Handler.
* sigismember: (libc)Signal Sets.
* siglongjmp: (libc)Non-Local Exits and Signals.
* sigmask: (libc)Blocking in BSD.
* signal: (libc)Basic Signal Handling.
* signbit: (libc)FP Bit Twiddling.
* significand: (libc)Normalization Functions.
* significandf: (libc)Normalization Functions.
* significandl: (libc)Normalization Functions.
* sigpause: (libc)Blocking in BSD.
* sigpending: (libc)Checking for Pending Signals.
* sigprocmask: (libc)Process Signal Mask.
* sigsetjmp: (libc)Non-Local Exits and Signals.
* sigsetmask: (libc)Blocking in BSD.
* sigstack: (libc)Signal Stack.
* sigsuspend: (libc)Sigsuspend.
* sigvec: (libc)BSD Handler.
* sin: (libc)Trig Functions.
* sincos: (libc)Trig Functions.
* sincosf: (libc)Trig Functions.
* sincosl: (libc)Trig Functions.
* sinf: (libc)Trig Functions.
* sinh: (libc)Hyperbolic Functions.
* sinhf: (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.
* 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 and Concatenation.
* stpncpy: (libc)Copying and Concatenation.
* strcasecmp: (libc)String/Array Comparison.
* strcasestr: (libc)Search Functions.
* strcat: (libc)Copying and Concatenation.
* strchr: (libc)Search Functions.
* strchrnul: (libc)Search Functions.
* strcmp: (libc)String/Array Comparison.
* strcoll: (libc)Collation Functions.
* strcpy: (libc)Copying and Concatenation.
* strcspn: (libc)Search Functions.
* strdup: (libc)Copying and Concatenation.
* strdupa: (libc)Copying and Concatenation.
* strerror: (libc)Error Messages.
* strerror_r: (libc)Error Messages.
* strfmon: (libc)Formatting Numbers.
* strfry: (libc)strfry.
* strftime: (libc)Formatting Calendar Time.
* strlen: (libc)String Length.
* strncasecmp: (libc)String/Array Comparison.
* strncat: (libc)Copying and Concatenation.
* strncmp: (libc)String/Array Comparison.
* strncpy: (libc)Copying and Concatenation.
* strndup: (libc)Copying and Concatenation.
* strndupa: (libc)Copying and Concatenation.
* 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.
* 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.
* tanh: (libc)Hyperbolic Functions.
* tanhf: (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.
* tgammal: (libc)Special Functions.
* 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.
* 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.
* truncl: (libc)Rounding Functions.
* tsearch: (libc)Tree Search Function.
* ttyname: (libc)Is It a Terminal.
* ttyname_r: (libc)Is It a Terminal.
* twalk: (libc)Tree Search Function.
* tzset: (libc)Time Zone 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 and Concatenation.
* wcpncpy: (libc)Copying and Concatenation.
* wcrtomb: (libc)Converting a Character.
* wcscasecmp: (libc)String/Array Comparison.
* wcscat: (libc)Copying and Concatenation.
* wcschr: (libc)Search Functions.
* wcschrnul: (libc)Search Functions.
* wcscmp: (libc)String/Array Comparison.
* wcscoll: (libc)Collation Functions.
* wcscpy: (libc)Copying and Concatenation.
* wcscspn: (libc)Search Functions.
* wcsdup: (libc)Copying and Concatenation.
* wcsftime: (libc)Formatting Calendar Time.
* wcslen: (libc)String Length.
* wcsncasecmp: (libc)String/Array Comparison.
* wcsncat: (libc)Copying and Concatenation.
* wcsncmp: (libc)String/Array Comparison.
* wcsncpy: (libc)Copying and Concatenation.
* 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.
* 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 and Concatenation.
* wmemmove: (libc)Copying and Concatenation.
* wmempcpy: (libc)Copying and Concatenation.
* wmemset: (libc)Copying and Concatenation.
* 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.
* y0l: (libc)Special Functions.
* y1: (libc)Special Functions.
* y1f: (libc)Special Functions.
* y1l: (libc)Special Functions.
* yn: (libc)Special Functions.
* ynf: (libc)Special Functions.
* ynl: (libc)Special Functions.
END-INFO-DIR-ENTRY
This file documents the GNU C Library.
This is `The GNU C Library Reference Manual', for version 2.19
(Buildroot).
Copyright (C) 1993-2014 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 FSF's 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."

File: libc.info, Node: Wide Character Case Conversion, Prev: Using Wide Char Classes, Up: Character Handling
4.5 Mapping of wide characters.
===============================
The classification functions are also generalized by the ISO C
standard. Instead of just allowing the two standard mappings, a locale
can contain others. Again, the `localedef' program already supports
generating such locale data files.
-- Data Type: wctrans_t
This data type is defined as a scalar type which can hold a value
representing the locale-dependent character mapping. There is no
way to construct such a value apart from using the return value of
the `wctrans' function.
This type is defined in `wctype.h'.
-- Function: wctrans_t wctrans (const char *PROPERTY)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The `wctrans' function has to be used to find out whether a named
mapping is defined in the current locale selected for the
`LC_CTYPE' category. If the returned value is non-zero, you can
use it afterwards in calls to `towctrans'. If the return value is
zero no such mapping is known in the current locale.
Beside locale-specific mappings there are two mappings which are
guaranteed to be available in every locale:
`"tolower"' `"toupper"'
These functions are declared in `wctype.h'.
-- Function: wint_t towctrans (wint_t WC, wctrans_t DESC)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`towctrans' maps the input character WC according to the rules of
the mapping for which DESC is a descriptor, and returns the value
it finds. DESC must be obtained by a successful call to `wctrans'.
This function is declared in `wctype.h'.
For the generally available mappings, the ISO C standard defines
convenient shortcuts so that it is not necessary to call `wctrans' for
them.
-- Function: wint_t towlower (wint_t WC)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
If WC is an upper-case letter, `towlower' returns the corresponding
lower-case letter. If WC is not an upper-case letter, WC is
returned unchanged.
`towlower' can be implemented using
towctrans (wc, wctrans ("tolower"))
This function is declared in `wctype.h'.
-- Function: wint_t towupper (wint_t WC)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
If WC is a lower-case letter, `towupper' returns the corresponding
upper-case letter. Otherwise WC is returned unchanged.
`towupper' can be implemented using
towctrans (wc, wctrans ("toupper"))
This function is declared in `wctype.h'.
The same warnings given in the last section for the use of the wide
character classification functions apply here. It is not possible to
simply cast a `char' type value to a `wint_t' and use it as an argument
to `towctrans' calls.

File: libc.info, Node: String and Array Utilities, Next: Character Set Handling, Prev: Character Handling, Up: Top
5 String and Array Utilities
****************************
Operations on strings (or arrays of characters) are an important part of
many programs. The GNU C Library provides an extensive set of string
utility functions, including functions for copying, concatenating,
comparing, and searching strings. Many of these functions can also
operate on arbitrary regions of storage; for example, the `memcpy'
function can be used to copy the contents of any kind of array.
It's fairly common for beginning C programmers to "reinvent the
wheel" by duplicating this functionality in their own code, but it pays
to become familiar with the library functions and to make use of them,
since this offers benefits in maintenance, efficiency, and portability.
For instance, you could easily compare one string to another in two
lines of C code, but if you use the built-in `strcmp' function, you're
less likely to make a mistake. And, since these library functions are
typically highly optimized, your program may run faster too.
* Menu:
* Representation of Strings:: Introduction to basic concepts.
* String/Array Conventions:: Whether to use a string function or an
arbitrary array function.
* String Length:: Determining the length of a string.
* Copying and Concatenation:: Functions to copy the contents of strings
and arrays.
* String/Array Comparison:: Functions for byte-wise and character-wise
comparison.
* Collation Functions:: Functions for collating strings.
* Search Functions:: Searching for a specific element or substring.
* Finding Tokens in a String:: Splitting a string into tokens by looking
for delimiters.
* strfry:: Function for flash-cooking a string.
* Trivial Encryption:: Obscuring data.
* Encode Binary Data:: Encoding and Decoding of Binary Data.
* Argz and Envz Vectors:: Null-separated string vectors.

File: libc.info, Node: Representation of Strings, Next: String/Array Conventions, Up: String and Array Utilities
5.1 Representation of Strings
=============================
This section is a quick summary of string concepts for beginning C
programmers. It describes how character strings are represented in C
and some common pitfalls. If you are already familiar with this
material, you can skip this section.
A "string" is an array of `char' objects. But string-valued
variables are usually declared to be pointers of type `char *'. Such
variables do not include space for the text of a string; that has to be
stored somewhere else--in an array variable, a string constant, or
dynamically allocated memory (*note Memory Allocation::). It's up to
you to store the address of the chosen memory space into the pointer
variable. Alternatively you can store a "null pointer" in the pointer
variable. The null pointer does not point anywhere, so attempting to
reference the string it points to gets an error.
"string" normally refers to multibyte character strings as opposed to
wide character strings. Wide character strings are arrays of type
`wchar_t' and as for multibyte character strings usually pointers of
type `wchar_t *' are used.
By convention, a "null character", `'\0'', marks the end of a
multibyte character string and the "null wide character", `L'\0'',
marks the end of a wide character string. For example, in testing to
see whether the `char *' variable P points to a null character marking
the end of a string, you can write `!*P' or `*P == '\0''.
A null character is quite different conceptually from a null pointer,
although both are represented by the integer `0'.
"String literals" appear in C program source as strings of
characters between double-quote characters (`"') where the initial
double-quote character is immediately preceded by a capital `L' (ell)
character (as in `L"foo"'). In ISO C, string literals can also be
formed by "string concatenation": `"a" "b"' is the same as `"ab"'. For
wide character strings one can either use `L"a" L"b"' or `L"a" "b"'.
Modification of string literals is not allowed by the GNU C compiler,
because literals are placed in read-only storage.
Character arrays that are declared `const' cannot be modified
either. It's generally good style to declare non-modifiable string
pointers to be of type `const char *', since this often allows the C
compiler to detect accidental modifications as well as providing some
amount of documentation about what your program intends to do with the
string.
The amount of memory allocated for the character array may extend
past the null character that normally marks the end of the string. In
this document, the term "allocated size" is always used to refer to the
total amount of memory allocated for the string, while the term
"length" refers to the number of characters up to (but not including)
the terminating null character.
A notorious source of program bugs is trying to put more characters
in a string than fit in its allocated size. When writing code that
extends strings or moves characters into a pre-allocated array, you
should be very careful to keep track of the length of the text and make
explicit checks for overflowing the array. Many of the library
functions _do not_ do this for you! Remember also that you need to
allocate an extra byte to hold the null character that marks the end of
the string.
Originally strings were sequences of bytes where each byte
represents a single character. This is still true today if the strings
are encoded using a single-byte character encoding. Things are
different if the strings are encoded using a multibyte encoding (for
more information on encodings see *note Extended Char Intro::). There
is no difference in the programming interface for these two kind of
strings; the programmer has to be aware of this and interpret the byte
sequences accordingly.
But since there is no separate interface taking care of these
differences the byte-based string functions are sometimes hard to use.
Since the count parameters of these functions specify bytes a call to
`strncpy' could cut a multibyte character in the middle and put an
incomplete (and therefore unusable) byte sequence in the target buffer.
To avoid these problems later versions of the ISO C standard
introduce a second set of functions which are operating on "wide
characters" (*note Extended Char Intro::). These functions don't have
the problems the single-byte versions have since every wide character is
a legal, interpretable value. This does not mean that cutting wide
character strings at arbitrary points is without problems. It normally
is for alphabet-based languages (except for non-normalized text) but
languages based on syllables still have the problem that more than one
wide character is necessary to complete a logical unit. This is a
higher level problem which the C library functions are not designed to
solve. But it is at least good that no invalid byte sequences can be
created. Also, the higher level functions can also much easier operate
on wide character than on multibyte characters so that a general advise
is to use wide characters internally whenever text is more than simply
copied.
The remaining of this chapter will discuss the functions for handling
wide character strings in parallel with the discussion of the multibyte
character strings since there is almost always an exact equivalent
available.

File: libc.info, Node: String/Array Conventions, Next: String Length, Prev: Representation of Strings, Up: String and Array Utilities
5.2 String and Array Conventions
================================
This chapter describes both functions that work on arbitrary arrays or
blocks of memory, and functions that are specific to null-terminated
arrays of characters and wide characters.
Functions that operate on arbitrary blocks of memory have names
beginning with `mem' and `wmem' (such as `memcpy' and `wmemcpy') and
invariably take an argument which specifies the size (in bytes and wide
characters respectively) of the block of memory to operate on. The
array arguments and return values for these functions have type `void
*' or `wchar_t'. As a matter of style, the elements of the arrays used
with the `mem' functions are referred to as "bytes". You can pass any
kind of pointer to these functions, and the `sizeof' operator is useful
in computing the value for the size argument. Parameters to the `wmem'
functions must be of type `wchar_t *'. These functions are not really
usable with anything but arrays of this type.
In contrast, functions that operate specifically on strings and wide
character strings have names beginning with `str' and `wcs'
respectively (such as `strcpy' and `wcscpy') and look for a null
character to terminate the string instead of requiring an explicit size
argument to be passed. (Some of these functions accept a specified
maximum length, but they also check for premature termination with a
null character.) The array arguments and return values for these
functions have type `char *' and `wchar_t *' respectively, and the
array elements are referred to as "characters" and "wide characters".
In many cases, there are both `mem' and `str'/`wcs' versions of a
function. The one that is more appropriate to use depends on the exact
situation. When your program is manipulating arbitrary arrays or
blocks of storage, then you should always use the `mem' functions. On
the other hand, when you are manipulating null-terminated strings it is
usually more convenient to use the `str'/`wcs' functions, unless you
already know the length of the string in advance. The `wmem' functions
should be used for wide character arrays with known size.
Some of the memory and string functions take single characters as
arguments. Since a value of type `char' is automatically promoted into
a value of type `int' when used as a parameter, the functions are
declared with `int' as the type of the parameter in question. In case
of the wide character function the situation is similarly: the
parameter type for a single wide character is `wint_t' and not
`wchar_t'. This would for many implementations not be necessary since
the `wchar_t' is large enough to not be automatically promoted, but
since the ISO C standard does not require such a choice of types the
`wint_t' type is used.

File: libc.info, Node: String Length, Next: Copying and Concatenation, Prev: String/Array Conventions, Up: String and Array Utilities
5.3 String Length
=================
You can get the length of a string using the `strlen' function. This
function is declared in the header file `string.h'.
-- Function: size_t strlen (const char *S)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strlen' function returns the length of the null-terminated
string S in bytes. (In other words, it returns the offset of the
terminating null character within the array.)
For example,
strlen ("hello, world")
=> 12
When applied to a character array, the `strlen' function returns
the length of the string stored there, not its allocated size.
You can get the allocated size of the character array that holds a
string using the `sizeof' operator:
char string[32] = "hello, world";
sizeof (string)
=> 32
strlen (string)
=> 12
But beware, this will not work unless STRING is the character
array itself, not a pointer to it. For example:
char string[32] = "hello, world";
char *ptr = string;
sizeof (string)
=> 32
sizeof (ptr)
=> 4 /* (on a machine with 4 byte pointers) */
This is an easy mistake to make when you are working with
functions that take string arguments; those arguments are always
pointers, not arrays.
It must also be noted that for multibyte encoded strings the return
value does not have to correspond to the number of characters in
the string. To get this value the string can be converted to wide
characters and `wcslen' can be used or something like the following
code can be used:
/* The input is in `string'.
The length is expected in `n'. */
{
mbstate_t t;
char *scopy = string;
/* In initial state. */
memset (&t, '\0', sizeof (t));
/* Determine number of characters. */
n = mbsrtowcs (NULL, &scopy, strlen (scopy), &t);
}
This is cumbersome to do so if the number of characters (as
opposed to bytes) is needed often it is better to work with wide
characters.
The wide character equivalent is declared in `wchar.h'.
-- Function: size_t wcslen (const wchar_t *WS)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wcslen' function is the wide character equivalent to
`strlen'. The return value is the number of wide characters in the
wide character string pointed to by WS (this is also the offset of
the terminating null wide character of WS).
Since there are no multi wide character sequences making up one
character the return value is not only the offset in the array, it
is also the number of wide characters.
This function was introduced in Amendment 1 to ISO C90.
-- Function: size_t strnlen (const char *S, size_t MAXLEN)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strnlen' function returns the length of the string S in bytes
if this length is smaller than MAXLEN bytes. Otherwise it returns
MAXLEN. Therefore this function is equivalent to `(strlen (S) <
MAXLEN ? strlen (S) : MAXLEN)' but it is more efficient and works
even if the string S is not null-terminated.
char string[32] = "hello, world";
strnlen (string, 32)
=> 12
strnlen (string, 5)
=> 5
This function is a GNU extension and is declared in `string.h'.
-- Function: size_t wcsnlen (const wchar_t *WS, size_t MAXLEN)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`wcsnlen' is the wide character equivalent to `strnlen'. The
MAXLEN parameter specifies the maximum number of wide characters.
This function is a GNU extension and is declared in `wchar.h'.

File: libc.info, Node: Copying and Concatenation, Next: String/Array Comparison, Prev: String Length, Up: String and Array Utilities
5.4 Copying and Concatenation
=============================
You can use the functions described in this section to copy the contents
of strings and arrays, or to append the contents of one string to
another. The `str' and `mem' functions are declared in the header file
`string.h' while the `wstr' and `wmem' functions are declared in the
file `wchar.h'.
A helpful way to remember the ordering of the arguments to the
functions in this section is that it corresponds to an assignment
expression, with the destination array specified to the left of the
source array. All of these functions return the address of the
destination array.
Most of these functions do not work properly if the source and
destination arrays overlap. For example, if the beginning of the
destination array overlaps the end of the source array, the original
contents of that part of the source array may get overwritten before it
is copied. Even worse, in the case of the string functions, the null
character marking the end of the string may be lost, and the copy
function might get stuck in a loop trashing all the memory allocated to
your program.
All functions that have problems copying between overlapping arrays
are explicitly identified in this manual. In addition to functions in
this section, there are a few others like `sprintf' (*note Formatted
Output Functions::) and `scanf' (*note Formatted Input Functions::).
-- Function: void * memcpy (void *restrict TO, const void *restrict
FROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `memcpy' function copies SIZE bytes from the object beginning
at FROM into the object beginning at TO. The behavior of this
function is undefined if the two arrays TO and FROM overlap; use
`memmove' instead if overlapping is possible.
The value returned by `memcpy' is the value of TO.
Here is an example of how you might use `memcpy' to copy the
contents of an array:
struct foo *oldarray, *newarray;
int arraysize;
...
memcpy (new, old, arraysize * sizeof (struct foo));
-- Function: wchar_t * wmemcpy (wchar_t *restrict WTO, const wchar_t
*restrict WFROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wmemcpy' function copies SIZE wide characters from the object
beginning at WFROM into the object beginning at WTO. The behavior
of this function is undefined if the two arrays WTO and WFROM
overlap; use `wmemmove' instead if overlapping is possible.
The following is a possible implementation of `wmemcpy' but there
are more optimizations possible.
wchar_t *
wmemcpy (wchar_t *restrict wto, const wchar_t *restrict wfrom,
size_t size)
{
return (wchar_t *) memcpy (wto, wfrom, size * sizeof (wchar_t));
}
The value returned by `wmemcpy' is the value of WTO.
This function was introduced in Amendment 1 to ISO C90.
-- Function: void * mempcpy (void *restrict TO, const void *restrict
FROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `mempcpy' function is nearly identical to the `memcpy'
function. It copies SIZE bytes from the object beginning at
`from' into the object pointed to by TO. But instead of returning
the value of TO it returns a pointer to the byte following the
last written byte in the object beginning at TO. I.e., the value
is `((void *) ((char *) TO + SIZE))'.
This function is useful in situations where a number of objects
shall be copied to consecutive memory positions.
void *
combine (void *o1, size_t s1, void *o2, size_t s2)
{
void *result = malloc (s1 + s2);
if (result != NULL)
mempcpy (mempcpy (result, o1, s1), o2, s2);
return result;
}
This function is a GNU extension.
-- Function: wchar_t * wmempcpy (wchar_t *restrict WTO, const wchar_t
*restrict WFROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wmempcpy' function is nearly identical to the `wmemcpy'
function. It copies SIZE wide characters from the object
beginning at `wfrom' into the object pointed to by WTO. But
instead of returning the value of WTO it returns a pointer to the
wide character following the last written wide character in the
object beginning at WTO. I.e., the value is `WTO + SIZE'.
This function is useful in situations where a number of objects
shall be copied to consecutive memory positions.
The following is a possible implementation of `wmemcpy' but there
are more optimizations possible.
wchar_t *
wmempcpy (wchar_t *restrict wto, const wchar_t *restrict wfrom,
size_t size)
{
return (wchar_t *) mempcpy (wto, wfrom, size * sizeof (wchar_t));
}
This function is a GNU extension.
-- Function: void * memmove (void *TO, const void *FROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`memmove' copies the SIZE bytes at FROM into the SIZE bytes at TO,
even if those two blocks of space overlap. In the case of
overlap, `memmove' is careful to copy the original values of the
bytes in the block at FROM, including those bytes which also
belong to the block at TO.
The value returned by `memmove' is the value of TO.
-- Function: wchar_t * wmemmove (wchar_t *WTO, const wchar_t *WFROM,
size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`wmemmove' copies the SIZE wide characters at WFROM into the SIZE
wide characters at WTO, even if those two blocks of space overlap.
In the case of overlap, `memmove' is careful to copy the original
values of the wide characters in the block at WFROM, including
those wide characters which also belong to the block at WTO.
The following is a possible implementation of `wmemcpy' but there
are more optimizations possible.
wchar_t *
wmempcpy (wchar_t *restrict wto, const wchar_t *restrict wfrom,
size_t size)
{
return (wchar_t *) mempcpy (wto, wfrom, size * sizeof (wchar_t));
}
The value returned by `wmemmove' is the value of WTO.
This function is a GNU extension.
-- Function: void * memccpy (void *restrict TO, const void *restrict
FROM, int C, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function copies no more than SIZE bytes from FROM to TO,
stopping if a byte matching C is found. The return value is a
pointer into TO one byte past where C was copied, or a null
pointer if no byte matching C appeared in the first SIZE bytes of
FROM.
-- Function: void * memset (void *BLOCK, int C, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function copies the value of C (converted to an `unsigned
char') into each of the first SIZE bytes of the object beginning
at BLOCK. It returns the value of BLOCK.
-- Function: wchar_t * wmemset (wchar_t *BLOCK, wchar_t WC, size_t
SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function copies the value of WC into each of the first SIZE
wide characters of the object beginning at BLOCK. It returns the
value of BLOCK.
-- Function: char * strcpy (char *restrict TO, const char *restrict
FROM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This copies characters from the string FROM (up to and including
the terminating null character) into the string TO. Like
`memcpy', this function has undefined results if the strings
overlap. The return value is the value of TO.
-- Function: wchar_t * wcscpy (wchar_t *restrict WTO, const wchar_t
*restrict WFROM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This copies wide characters from the string WFROM (up to and
including the terminating null wide character) into the string
WTO. Like `wmemcpy', this function has undefined results if the
strings overlap. The return value is the value of WTO.
-- Function: char * strncpy (char *restrict TO, const char *restrict
FROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is similar to `strcpy' but always copies exactly
SIZE characters into TO.
If the length of FROM is more than SIZE, then `strncpy' copies
just the first SIZE characters. Note that in this case there is
no null terminator written into TO.
If the length of FROM is less than SIZE, then `strncpy' copies all
of FROM, followed by enough null characters to add up to SIZE
characters in all. This behavior is rarely useful, but it is
specified by the ISO C standard.
The behavior of `strncpy' is undefined if the strings overlap.
Using `strncpy' as opposed to `strcpy' is a way to avoid bugs
relating to writing past the end of the allocated space for TO.
However, it can also make your program much slower in one common
case: copying a string which is probably small into a potentially
large buffer. In this case, SIZE may be large, and when it is,
`strncpy' will waste a considerable amount of time copying null
characters.
-- Function: wchar_t * wcsncpy (wchar_t *restrict WTO, const wchar_t
*restrict WFROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is similar to `wcscpy' but always copies exactly
SIZE wide characters into WTO.
If the length of WFROM is more than SIZE, then `wcsncpy' copies
just the first SIZE wide characters. Note that in this case there
is no null terminator written into WTO.
If the length of WFROM is less than SIZE, then `wcsncpy' copies
all of WFROM, followed by enough null wide characters to add up to
SIZE wide characters in all. This behavior is rarely useful, but
it is specified by the ISO C standard.
The behavior of `wcsncpy' is undefined if the strings overlap.
Using `wcsncpy' as opposed to `wcscpy' is a way to avoid bugs
relating to writing past the end of the allocated space for WTO.
However, it can also make your program much slower in one common
case: copying a string which is probably small into a potentially
large buffer. In this case, SIZE may be large, and when it is,
`wcsncpy' will waste a considerable amount of time copying null
wide characters.
-- Function: char * strdup (const char *S)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
This function copies the null-terminated string S into a newly
allocated string. The string is allocated using `malloc'; see
*note Unconstrained Allocation::. If `malloc' cannot allocate
space for the new string, `strdup' returns a null pointer.
Otherwise it returns a pointer to the new string.
-- Function: wchar_t * wcsdup (const wchar_t *WS)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
This function copies the null-terminated wide character string WS
into a newly allocated string. The string is allocated using
`malloc'; see *note Unconstrained Allocation::. If `malloc'
cannot allocate space for the new string, `wcsdup' returns a null
pointer. Otherwise it returns a pointer to the new wide character
string.
This function is a GNU extension.
-- Function: char * strndup (const char *S, size_t SIZE)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
This function is similar to `strdup' but always copies at most
SIZE characters into the newly allocated string.
If the length of S is more than SIZE, then `strndup' copies just
the first SIZE characters and adds a closing null terminator.
Otherwise all characters are copied and the string is terminated.
This function is different to `strncpy' in that it always
terminates the destination string.
`strndup' is a GNU extension.
-- Function: char * stpcpy (char *restrict TO, const char *restrict
FROM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is like `strcpy', except that it returns a pointer to
the end of the string TO (that is, the address of the terminating
null character `to + strlen (from)') rather than the beginning.
For example, this program uses `stpcpy' to concatenate `foo' and
`bar' to produce `foobar', which it then prints.
#include <string.h>
#include <stdio.h>
int
main (void)
{
char buffer[10];
char *to = buffer;
to = stpcpy (to, "foo");
to = stpcpy (to, "bar");
puts (buffer);
return 0;
}
This function is not part of the ISO or POSIX standards, and is not
customary on Unix systems, but we did not invent it either.
Perhaps it comes from MS-DOG.
Its behavior is undefined if the strings overlap. The function is
declared in `string.h'.
-- Function: wchar_t * wcpcpy (wchar_t *restrict WTO, const wchar_t
*restrict WFROM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is like `wcscpy', except that it returns a pointer to
the end of the string WTO (that is, the address of the terminating
null character `wto + strlen (wfrom)') rather than the beginning.
This function is not part of ISO or POSIX but was found useful
while developing the GNU C Library itself.
The behavior of `wcpcpy' is undefined if the strings overlap.
`wcpcpy' is a GNU extension and is declared in `wchar.h'.
-- Function: char * stpncpy (char *restrict TO, const char *restrict
FROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is similar to `stpcpy' but copies always exactly
SIZE characters into TO.
If the length of FROM is more than SIZE, then `stpncpy' copies
just the first SIZE characters and returns a pointer to the
character directly following the one which was copied last. Note
that in this case there is no null terminator written into TO.
If the length of FROM is less than SIZE, then `stpncpy' copies all
of FROM, followed by enough null characters to add up to SIZE
characters in all. This behavior is rarely useful, but it is
implemented to be useful in contexts where this behavior of the
`strncpy' is used. `stpncpy' returns a pointer to the _first_
written null character.
This function is not part of ISO or POSIX but was found useful
while developing the GNU C Library itself.
Its behavior is undefined if the strings overlap. The function is
declared in `string.h'.
-- Function: wchar_t * wcpncpy (wchar_t *restrict WTO, const wchar_t
*restrict WFROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is similar to `wcpcpy' but copies always exactly
WSIZE characters into WTO.
If the length of WFROM is more than SIZE, then `wcpncpy' copies
just the first SIZE wide characters and returns a pointer to the
wide character directly following the last non-null wide character
which was copied last. Note that in this case there is no null
terminator written into WTO.
If the length of WFROM is less than SIZE, then `wcpncpy' copies
all of WFROM, followed by enough null characters to add up to SIZE
characters in all. This behavior is rarely useful, but it is
implemented to be useful in contexts where this behavior of the
`wcsncpy' is used. `wcpncpy' returns a pointer to the _first_
written null character.
This function is not part of ISO or POSIX but was found useful
while developing the GNU C Library itself.
Its behavior is undefined if the strings overlap.
`wcpncpy' is a GNU extension and is declared in `wchar.h'.
-- Macro: char * strdupa (const char *S)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This macro is similar to `strdup' but allocates the new string
using `alloca' instead of `malloc' (*note Variable Size
Automatic::). This means of course the returned string has the
same limitations as any block of memory allocated using `alloca'.
For obvious reasons `strdupa' is implemented only as a macro; you
cannot get the address of this function. Despite this limitation
it is a useful function. The following code shows a situation
where using `malloc' would be a lot more expensive.
#include <paths.h>
#include <string.h>
#include <stdio.h>
const char path[] = _PATH_STDPATH;
int
main (void)
{
char *wr_path = strdupa (path);
char *cp = strtok (wr_path, ":");
while (cp != NULL)
{
puts (cp);
cp = strtok (NULL, ":");
}
return 0;
}
Please note that calling `strtok' using PATH directly is invalid.
It is also not allowed to call `strdupa' in the argument list of
`strtok' since `strdupa' uses `alloca' (*note Variable Size
Automatic::) can interfere with the parameter passing.
This function is only available if GNU CC is used.
-- Macro: char * strndupa (const char *S, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is similar to `strndup' but like `strdupa' it
allocates the new string using `alloca' *note Variable Size
Automatic::. The same advantages and limitations of `strdupa' are
valid for `strndupa', too.
This function is implemented only as a macro, just like `strdupa'.
Just as `strdupa' this macro also must not be used inside the
parameter list in a function call.
`strndupa' is only available if GNU CC is used.
-- Function: char * strcat (char *restrict TO, const char *restrict
FROM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strcat' function is similar to `strcpy', except that the
characters from FROM are concatenated or appended to the end of
TO, instead of overwriting it. That is, the first character from
FROM overwrites the null character marking the end of TO.
An equivalent definition for `strcat' would be:
char *
strcat (char *restrict to, const char *restrict from)
{
strcpy (to + strlen (to), from);
return to;
}
This function has undefined results if the strings overlap.
-- Function: wchar_t * wcscat (wchar_t *restrict WTO, const wchar_t
*restrict WFROM)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wcscat' function is similar to `wcscpy', except that the
characters from WFROM are concatenated or appended to the end of
WTO, instead of overwriting it. That is, the first character from
WFROM overwrites the null character marking the end of WTO.
An equivalent definition for `wcscat' would be:
wchar_t *
wcscat (wchar_t *wto, const wchar_t *wfrom)
{
wcscpy (wto + wcslen (wto), wfrom);
return wto;
}
This function has undefined results if the strings overlap.
Programmers using the `strcat' or `wcscat' function (or the
following `strncat' or `wcsncar' functions for that matter) can easily
be recognized as lazy and reckless. In almost all situations the
lengths of the participating strings are known (it better should be
since how can one otherwise ensure the allocated size of the buffer is
sufficient?) Or at least, one could know them if one keeps track of the
results of the various function calls. But then it is very inefficient
to use `strcat'/`wcscat'. A lot of time is wasted finding the end of
the destination string so that the actual copying can start. This is a
common example:
/* This function concatenates arbitrarily many strings. The last
parameter must be `NULL'. */
char *
concat (const char *str, ...)
{
va_list ap, ap2;
size_t total = 1;
const char *s;
char *result;
va_start (ap, str);
va_copy (ap2, ap);
/* Determine how much space we need. */
for (s = str; s != NULL; s = va_arg (ap, const char *))
total += strlen (s);
va_end (ap);
result = (char *) malloc (total);
if (result != NULL)
{
result[0] = '\0';
/* Copy the strings. */
for (s = str; s != NULL; s = va_arg (ap2, const char *))
strcat (result, s);
}
va_end (ap2);
return result;
}
This looks quite simple, especially the second loop where the strings
are actually copied. But these innocent lines hide a major performance
penalty. Just imagine that ten strings of 100 bytes each have to be
concatenated. For the second string we search the already stored 100
bytes for the end of the string so that we can append the next string.
For all strings in total the comparisons necessary to find the end of
the intermediate results sums up to 5500! If we combine the copying
with the search for the allocation we can write this function more
efficient:
char *
concat (const char *str, ...)
{
va_list ap;
size_t allocated = 100;
char *result = (char *) malloc (allocated);
if (result != NULL)
{
char *newp;
char *wp;
const char *s;
va_start (ap, str);
wp = result;
for (s = str; s != NULL; s = va_arg (ap, const char *))
{
size_t len = strlen (s);
/* Resize the allocated memory if necessary. */
if (wp + len + 1 > result + allocated)
{
allocated = (allocated + len) * 2;
newp = (char *) realloc (result, allocated);
if (newp == NULL)
{
free (result);
return NULL;
}
wp = newp + (wp - result);
result = newp;
}
wp = mempcpy (wp, s, len);
}
/* Terminate the result string. */
*wp++ = '\0';
/* Resize memory to the optimal size. */
newp = realloc (result, wp - result);
if (newp != NULL)
result = newp;
va_end (ap);
}
return result;
}
With a bit more knowledge about the input strings one could fine-tune
the memory allocation. The difference we are pointing to here is that
we don't use `strcat' anymore. We always keep track of the length of
the current intermediate result so we can safe us the search for the
end of the string and use `mempcpy'. Please note that we also don't
use `stpcpy' which might seem more natural since we handle with
strings. But this is not necessary since we already know the length of
the string and therefore can use the faster memory copying function.
The example would work for wide characters the same way.
Whenever a programmer feels the need to use `strcat' she or he
should think twice and look through the program whether the code cannot
be rewritten to take advantage of already calculated results. Again: it
is almost always unnecessary to use `strcat'.
-- Function: char * strncat (char *restrict TO, const char *restrict
FROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is like `strcat' except that not more than SIZE
characters from FROM are appended to the end of TO. A single null
character is also always appended to TO, so the total allocated
size of TO must be at least `SIZE + 1' bytes longer than its
initial length.
The `strncat' function could be implemented like this:
char *
strncat (char *to, const char *from, size_t size)
{
memcpy (to + strlen (to), from, strnlen (from, size));
to[strlen (to) + strnlen (from, size)] = '\0';
return to;
}
The behavior of `strncat' is undefined if the strings overlap.
-- Function: wchar_t * wcsncat (wchar_t *restrict WTO, const wchar_t
*restrict WFROM, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is like `wcscat' except that not more than SIZE
characters from FROM are appended to the end of TO. A single null
character is also always appended to TO, so the total allocated
size of TO must be at least `SIZE + 1' bytes longer than its
initial length.
The `wcsncat' function could be implemented like this:
wchar_t *
wcsncat (wchar_t *restrict wto, const wchar_t *restrict wfrom,
size_t size)
{
memcpy (wto + wcslen (wto), wfrom, wcsnlen (wfrom, size) * sizeof (wchar_t));
wto[wcslen (to) + wcsnlen (wfrom, size)] = '\0';
return wto;
}
The behavior of `wcsncat' is undefined if the strings overlap.
Here is an example showing the use of `strncpy' and `strncat' (the
wide character version is equivalent). Notice how, in the call to
`strncat', the SIZE parameter is computed to avoid overflowing the
character array `buffer'.
#include <string.h>
#include <stdio.h>
#define SIZE 10
static char buffer[SIZE];
int
main (void)
{
strncpy (buffer, "hello", SIZE);
puts (buffer);
strncat (buffer, ", world", SIZE - strlen (buffer) - 1);
puts (buffer);
}
The output produced by this program looks like:
hello
hello, wo
-- Function: void bcopy (const void *FROM, void *TO, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is a partially obsolete alternative for `memmove', derived
from BSD. Note that it is not quite equivalent to `memmove',
because the arguments are not in the same order and there is no
return value.
-- Function: void bzero (void *BLOCK, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is a partially obsolete alternative for `memset', derived from
BSD. Note that it is not as general as `memset', because the only
value it can store is zero.

File: libc.info, Node: String/Array Comparison, Next: Collation Functions, Prev: Copying and Concatenation, Up: String and Array Utilities
5.5 String/Array Comparison
===========================
You can use the functions in this section to perform comparisons on the
contents of strings and arrays. As well as checking for equality, these
functions can also be used as the ordering functions for sorting
operations. *Note Searching and Sorting::, for an example of this.
Unlike most comparison operations in C, the string comparison
functions return a nonzero value if the strings are _not_ equivalent
rather than if they are. The sign of the value indicates the relative
ordering of the first characters in the strings that are not
equivalent: a negative value indicates that the first string is "less"
than the second, while a positive value indicates that the first string
is "greater".
The most common use of these functions is to check only for equality.
This is canonically done with an expression like `! strcmp (s1, s2)'.
All of these functions are declared in the header file `string.h'.
-- Function: int memcmp (const void *A1, const void *A2, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The function `memcmp' compares the SIZE bytes of memory beginning
at A1 against the SIZE bytes of memory beginning at A2. The value
returned has the same sign as the difference between the first
differing pair of bytes (interpreted as `unsigned char' objects,
then promoted to `int').
If the contents of the two blocks are equal, `memcmp' returns `0'.
-- Function: int wmemcmp (const wchar_t *A1, const wchar_t *A2, size_t
SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The function `wmemcmp' compares the SIZE wide characters beginning
at A1 against the SIZE wide characters beginning at A2. The value
returned is smaller than or larger than zero depending on whether
the first differing wide character is A1 is smaller or larger than
the corresponding character in A2.
If the contents of the two blocks are equal, `wmemcmp' returns `0'.
On arbitrary arrays, the `memcmp' function is mostly useful for
testing equality. It usually isn't meaningful to do byte-wise ordering
comparisons on arrays of things other than bytes. For example, a
byte-wise comparison on the bytes that make up floating-point numbers
isn't likely to tell you anything about the relationship between the
values of the floating-point numbers.
`wmemcmp' is really only useful to compare arrays of type `wchar_t'
since the function looks at `sizeof (wchar_t)' bytes at a time and this
number of bytes is system dependent.
You should also be careful about using `memcmp' to compare objects
that can contain "holes", such as the padding inserted into structure
objects to enforce alignment requirements, extra space at the end of
unions, and extra characters at the ends of strings whose length is less
than their allocated size. The contents of these "holes" are
indeterminate and may cause strange behavior when performing byte-wise
comparisons. For more predictable results, perform an explicit
component-wise comparison.
For example, given a structure type definition like:
struct foo
{
unsigned char tag;
union
{
double f;
long i;
char *p;
} value;
};
you are better off writing a specialized comparison function to compare
`struct foo' objects instead of comparing them with `memcmp'.
-- Function: int strcmp (const char *S1, const char *S2)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strcmp' function compares the string S1 against S2, returning
a value that has the same sign as the difference between the first
differing pair of characters (interpreted as `unsigned char'
objects, then promoted to `int').
If the two strings are equal, `strcmp' returns `0'.
A consequence of the ordering used by `strcmp' is that if S1 is an
initial substring of S2, then S1 is considered to be "less than"
S2.
`strcmp' does not take sorting conventions of the language the
strings are written in into account. To get that one has to use
`strcoll'.
-- Function: int wcscmp (const wchar_t *WS1, const wchar_t *WS2)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wcscmp' function compares the wide character string WS1
against WS2. The value returned is smaller than or larger than
zero depending on whether the first differing wide character is
WS1 is smaller or larger than the corresponding character in WS2.
If the two strings are equal, `wcscmp' returns `0'.
A consequence of the ordering used by `wcscmp' is that if WS1 is
an initial substring of WS2, then WS1 is considered to be "less
than" WS2.
`wcscmp' does not take sorting conventions of the language the
strings are written in into account. To get that one has to use
`wcscoll'.
-- Function: int strcasecmp (const char *S1, const char *S2)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
This function is like `strcmp', except that differences in case are
ignored. How uppercase and lowercase characters are related is
determined by the currently selected locale. In the standard `"C"'
locale the characters A" and a" do not match but in a locale which
regards these characters as parts of the alphabet they do match.
`strcasecmp' is derived from BSD.
-- Function: int wcscasecmp (const wchar_t *WS1, const wchar_t *WS2)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
This function is like `wcscmp', except that differences in case are
ignored. How uppercase and lowercase characters are related is
determined by the currently selected locale. In the standard `"C"'
locale the characters A" and a" do not match but in a locale which
regards these characters as parts of the alphabet they do match.
`wcscasecmp' is a GNU extension.
-- Function: int strncmp (const char *S1, const char *S2, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is the similar to `strcmp', except that no more than
SIZE characters are compared. In other words, if the two strings
are the same in their first SIZE characters, the return value is
zero.
-- Function: int wcsncmp (const wchar_t *WS1, const wchar_t *WS2,
size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function is the similar to `wcscmp', except that no more than
SIZE wide characters are compared. In other words, if the two
strings are the same in their first SIZE wide characters, the
return value is zero.
-- Function: int strncasecmp (const char *S1, const char *S2, size_t N)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
This function is like `strncmp', except that differences in case
are ignored. Like `strcasecmp', it is locale dependent how
uppercase and lowercase characters are related.
`strncasecmp' is a GNU extension.
-- Function: int wcsncasecmp (const wchar_t *WS1, const wchar_t *S2,
size_t N)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
This function is like `wcsncmp', except that differences in case
are ignored. Like `wcscasecmp', it is locale dependent how
uppercase and lowercase characters are related.
`wcsncasecmp' is a GNU extension.
Here are some examples showing the use of `strcmp' and `strncmp'
(equivalent examples can be constructed for the wide character
functions). These examples assume the use of the ASCII character set.
(If some other character set--say, EBCDIC--is used instead, then the
glyphs are associated with different numeric codes, and the return
values and ordering may differ.)
strcmp ("hello", "hello")
=> 0 /* These two strings are the same. */
strcmp ("hello", "Hello")
=> 32 /* Comparisons are case-sensitive. */
strcmp ("hello", "world")
=> -15 /* The character `'h'' comes before `'w''. */
strcmp ("hello", "hello, world")
=> -44 /* Comparing a null character against a comma. */
strncmp ("hello", "hello, world", 5)
=> 0 /* The initial 5 characters are the same. */
strncmp ("hello, world", "hello, stupid world!!!", 5)
=> 0 /* The initial 5 characters are the same. */
-- Function: int strverscmp (const char *S1, const char *S2)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The `strverscmp' function compares the string S1 against S2,
considering them as holding indices/version numbers. The return
value follows the same conventions as found in the `strcmp'
function. In fact, if S1 and S2 contain no digits, `strverscmp'
behaves like `strcmp'.
Basically, we compare strings normally (character by character),
until we find a digit in each string - then we enter a special
comparison mode, where each sequence of digits is taken as a
whole. If we reach the end of these two parts without noticing a
difference, we return to the standard comparison mode. There are
two types of numeric parts: "integral" and "fractional" (those
begin with a '0'). The types of the numeric parts affect the way
we sort them:
* integral/integral: we compare values as you would expect.
* fractional/integral: the fractional part is less than the
integral one. Again, no surprise.
* fractional/fractional: the things become a bit more complex.
If the common prefix contains only leading zeroes, the
longest part is less than the other one; else the comparison
behaves normally.
strverscmp ("no digit", "no digit")
=> 0 /* same behavior as strcmp. */
strverscmp ("item#99", "item#100")
=> <0 /* same prefix, but 99 < 100. */
strverscmp ("alpha1", "alpha001")
=> >0 /* fractional part inferior to integral one. */
strverscmp ("part1_f012", "part1_f01")
=> >0 /* two fractional parts. */
strverscmp ("foo.009", "foo.0")
=> <0 /* idem, but with leading zeroes only. */
This function is especially useful when dealing with filename
sorting, because filenames frequently hold indices/version numbers.
`strverscmp' is a GNU extension.
-- Function: int bcmp (const void *A1, const void *A2, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is an obsolete alias for `memcmp', derived from BSD.

File: libc.info, Node: Collation Functions, Next: Search Functions, Prev: String/Array Comparison, Up: String and Array Utilities
5.6 Collation Functions
=======================
In some locales, the conventions for lexicographic ordering differ from
the strict numeric ordering of character codes. For example, in Spanish
most glyphs with diacritical marks such as accents are not considered
distinct letters for the purposes of collation. On the other hand, the
two-character sequence `ll' is treated as a single letter that is
collated immediately after `l'.
You can use the functions `strcoll' and `strxfrm' (declared in the
headers file `string.h') and `wcscoll' and `wcsxfrm' (declared in the
headers file `wchar') to compare strings using a collation ordering
appropriate for the current locale. The locale used by these functions
in particular can be specified by setting the locale for the
`LC_COLLATE' category; see *note Locales::.
In the standard C locale, the collation sequence for `strcoll' is
the same as that for `strcmp'. Similarly, `wcscoll' and `wcscmp' are
the same in this situation.
Effectively, the way these functions work is by applying a mapping to
transform the characters in a string to a byte sequence that represents
the string's position in the collating sequence of the current locale.
Comparing two such byte sequences in a simple fashion is equivalent to
comparing the strings with the locale's collating sequence.
The functions `strcoll' and `wcscoll' perform this translation
implicitly, in order to do one comparison. By contrast, `strxfrm' and
`wcsxfrm' perform the mapping explicitly. If you are making multiple
comparisons using the same string or set of strings, it is likely to be
more efficient to use `strxfrm' or `wcsxfrm' to transform all the
strings just once, and subsequently compare the transformed strings
with `strcmp' or `wcscmp'.
-- Function: int strcoll (const char *S1, const char *S2)
Preliminary: | MT-Safe locale | AS-Unsafe heap | AC-Unsafe mem |
*Note POSIX Safety Concepts::.
The `strcoll' function is similar to `strcmp' but uses the
collating sequence of the current locale for collation (the
`LC_COLLATE' locale).
-- Function: int wcscoll (const wchar_t *WS1, const wchar_t *WS2)
Preliminary: | MT-Safe locale | AS-Unsafe heap | AC-Unsafe mem |
*Note POSIX Safety Concepts::.
The `wcscoll' function is similar to `wcscmp' but uses the
collating sequence of the current locale for collation (the
`LC_COLLATE' locale).
Here is an example of sorting an array of strings, using `strcoll'
to compare them. The actual sort algorithm is not written here; it
comes from `qsort' (*note Array Sort Function::). The job of the code
shown here is to say how to compare the strings while sorting them.
(Later on in this section, we will show a way to do this more
efficiently using `strxfrm'.)
/* This is the comparison function used with `qsort'. */
int
compare_elements (const void *v1, const void *v2)
{
char * const *p1 = v1;
char * const *p2 = v2;
return strcoll (*p1, *p2);
}
/* This is the entry point--the function to sort
strings using the locale's collating sequence. */
void
sort_strings (char **array, int nstrings)
{
/* Sort `temp_array' by comparing the strings. */
qsort (array, nstrings,
sizeof (char *), compare_elements);
}
-- Function: size_t strxfrm (char *restrict TO, const char *restrict
FROM, size_t SIZE)
Preliminary: | MT-Safe locale | AS-Unsafe heap | AC-Unsafe mem |
*Note POSIX Safety Concepts::.
The function `strxfrm' transforms the string FROM using the
collation transformation determined by the locale currently
selected for collation, and stores the transformed string in the
array TO. Up to SIZE characters (including a terminating null
character) are stored.
The behavior is undefined if the strings TO and FROM overlap; see
*note Copying and Concatenation::.
The return value is the length of the entire transformed string.
This value is not affected by the value of SIZE, but if it is
greater or equal than SIZE, it means that the transformed string
did not entirely fit in the array TO. In this case, only as much
of the string as actually fits was stored. To get the whole
transformed string, call `strxfrm' again with a bigger output
array.
The transformed string may be longer than the original string, and
it may also be shorter.
If SIZE is zero, no characters are stored in TO. In this case,
`strxfrm' simply returns the number of characters that would be
the length of the transformed string. This is useful for
determining what size the allocated array should be. It does not
matter what TO is if SIZE is zero; TO may even be a null pointer.
-- Function: size_t wcsxfrm (wchar_t *restrict WTO, const wchar_t
*WFROM, size_t SIZE)
Preliminary: | MT-Safe locale | AS-Unsafe heap | AC-Unsafe mem |
*Note POSIX Safety Concepts::.
The function `wcsxfrm' transforms wide character string WFROM
using the collation transformation determined by the locale
currently selected for collation, and stores the transformed
string in the array WTO. Up to SIZE wide characters (including a
terminating null character) are stored.
The behavior is undefined if the strings WTO and WFROM overlap;
see *note Copying and Concatenation::.
The return value is the length of the entire transformed wide
character string. This value is not affected by the value of
SIZE, but if it is greater or equal than SIZE, it means that the
transformed wide character string did not entirely fit in the
array WTO. In this case, only as much of the wide character
string as actually fits was stored. To get the whole transformed
wide character string, call `wcsxfrm' again with a bigger output
array.
The transformed wide character string may be longer than the
original wide character string, and it may also be shorter.
If SIZE is zero, no characters are stored in TO. In this case,
`wcsxfrm' simply returns the number of wide characters that would
be the length of the transformed wide character string. This is
useful for determining what size the allocated array should be
(remember to multiply with `sizeof (wchar_t)'). It does not
matter what WTO is if SIZE is zero; WTO may even be a null pointer.
Here is an example of how you can use `strxfrm' when you plan to do
many comparisons. It does the same thing as the previous example, but
much faster, because it has to transform each string only once, no
matter how many times it is compared with other strings. Even the time
needed to allocate and free storage is much less than the time we save,
when there are many strings.
struct sorter { char *input; char *transformed; };
/* This is the comparison function used with `qsort'
to sort an array of `struct sorter'. */
int
compare_elements (const void *v1, const void *v2)
{
const struct sorter *p1 = v1;
const struct sorter *p2 = v2;
return strcmp (p1->transformed, p2->transformed);
}
/* This is the entry point--the function to sort
strings using the locale's collating sequence. */
void
sort_strings_fast (char **array, int nstrings)
{
struct sorter temp_array[nstrings];
int i;
/* Set up `temp_array'. Each element contains
one input string and its transformed string. */
for (i = 0; i < nstrings; i++)
{
size_t length = strlen (array[i]) * 2;
char *transformed;
size_t transformed_length;
temp_array[i].input = array[i];
/* First try a buffer perhaps big enough. */
transformed = (char *) xmalloc (length);
/* Transform `array[i]'. */
transformed_length = strxfrm (transformed, array[i], length);
/* If the buffer was not large enough, resize it
and try again. */
if (transformed_length >= length)
{
/* Allocate the needed space. +1 for terminating
`NUL' character. */
transformed = (char *) xrealloc (transformed,
transformed_length + 1);
/* The return value is not interesting because we know
how long the transformed string is. */
(void) strxfrm (transformed, array[i],
transformed_length + 1);
}
temp_array[i].transformed = transformed;
}
/* Sort `temp_array' by comparing transformed strings. */
qsort (temp_array, sizeof (struct sorter),
nstrings, compare_elements);
/* Put the elements back in the permanent array
in their sorted order. */
for (i = 0; i < nstrings; i++)
array[i] = temp_array[i].input;
/* Free the strings we allocated. */
for (i = 0; i < nstrings; i++)
free (temp_array[i].transformed);
}
The interesting part of this code for the wide character version
would look like this:
void
sort_strings_fast (wchar_t **array, int nstrings)
{
...
/* Transform `array[i]'. */
transformed_length = wcsxfrm (transformed, array[i], length);
/* If the buffer was not large enough, resize it
and try again. */
if (transformed_length >= length)
{
/* Allocate the needed space. +1 for terminating
`NUL' character. */
transformed = (wchar_t *) xrealloc (transformed,
(transformed_length + 1)
* sizeof (wchar_t));
/* The return value is not interesting because we know
how long the transformed string is. */
(void) wcsxfrm (transformed, array[i],
transformed_length + 1);
}
...
Note the additional multiplication with `sizeof (wchar_t)' in the
`realloc' call.
*Compatibility Note:* The string collation functions are a new
feature of ISO C90. Older C dialects have no equivalent feature. The
wide character versions were introduced in Amendment 1 to ISO C90.

File: libc.info, Node: Search Functions, Next: Finding Tokens in a String, Prev: Collation Functions, Up: String and Array Utilities
5.7 Search Functions
====================
This section describes library functions which perform various kinds of
searching operations on strings and arrays. These functions are
declared in the header file `string.h'.
-- Function: void * memchr (const void *BLOCK, int C, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function finds the first occurrence of the byte C (converted
to an `unsigned char') in the initial SIZE bytes of the object
beginning at BLOCK. The return value is a pointer to the located
byte, or a null pointer if no match was found.
-- Function: wchar_t * wmemchr (const wchar_t *BLOCK, wchar_t WC,
size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function finds the first occurrence of the wide character WC
in the initial SIZE wide characters of the object beginning at
BLOCK. The return value is a pointer to the located wide
character, or a null pointer if no match was found.
-- Function: void * rawmemchr (const void *BLOCK, int C)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
Often the `memchr' function is used with the knowledge that the
byte C is available in the memory block specified by the
parameters. But this means that the SIZE parameter is not really
needed and that the tests performed with it at runtime (to check
whether the end of the block is reached) are not needed.
The `rawmemchr' function exists for just this situation which is
surprisingly frequent. The interface is similar to `memchr' except
that the SIZE parameter is missing. The function will look beyond
the end of the block pointed to by BLOCK in case the programmer
made an error in assuming that the byte C is present in the block.
In this case the result is unspecified. Otherwise the return
value is a pointer to the located byte.
This function is of special interest when looking for the end of a
string. Since all strings are terminated by a null byte a call
like
rawmemchr (str, '\0')
will never go beyond the end of the string.
This function is a GNU extension.
-- Function: void * memrchr (const void *BLOCK, int C, size_t SIZE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The function `memrchr' is like `memchr', except that it searches
backwards from the end of the block defined by BLOCK and SIZE
(instead of forwards from the front).
This function is a GNU extension.
-- Function: char * strchr (const char *STRING, int C)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strchr' function finds the first occurrence of the character
C (converted to a `char') in the null-terminated string beginning
at STRING. The return value is a pointer to the located
character, or a null pointer if no match was found.
For example,
strchr ("hello, world", 'l')
=> "llo, world"
strchr ("hello, world", '?')
=> NULL
The terminating null character is considered to be part of the
string, so you can use this function get a pointer to the end of a
string by specifying a null character as the value of the C
argument.
When `strchr' returns a null pointer, it does not let you know the
position of the terminating null character it has found. If you
need that information, it is better (but less portable) to use
`strchrnul' than to search for it a second time.
-- Function: wchar_t * wcschr (const wchar_t *WSTRING, int WC)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wcschr' function finds the first occurrence of the wide
character WC in the null-terminated wide character string
beginning at WSTRING. The return value is a pointer to the
located wide character, or a null pointer if no match was found.
The terminating null character is considered to be part of the wide
character string, so you can use this function get a pointer to
the end of a wide character string by specifying a null wude
character as the value of the WC argument. It would be better
(but less portable) to use `wcschrnul' in this case, though.
-- Function: char * strchrnul (const char *STRING, int C)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`strchrnul' is the same as `strchr' except that if it does not
find the character, it returns a pointer to string's terminating
null character rather than a null pointer.
This function is a GNU extension.
-- Function: wchar_t * wcschrnul (const wchar_t *WSTRING, wchar_t WC)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`wcschrnul' is the same as `wcschr' except that if it does not
find the wide character, it returns a pointer to wide character
string's terminating null wide character rather than a null
pointer.
This function is a GNU extension.
One useful, but unusual, use of the `strchr' function is when one
wants to have a pointer pointing to the NUL byte terminating a string.
This is often written in this way:
s += strlen (s);
This is almost optimal but the addition operation duplicated a bit of
the work already done in the `strlen' function. A better solution is
this:
s = strchr (s, '\0');
There is no restriction on the second parameter of `strchr' so it
could very well also be the NUL character. Those readers thinking very
hard about this might now point out that the `strchr' function is more
expensive than the `strlen' function since we have two abort criteria.
This is right. But in the GNU C Library the implementation of `strchr'
is optimized in a special way so that `strchr' actually is faster.
-- Function: char * strrchr (const char *STRING, int C)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The function `strrchr' is like `strchr', except that it searches
backwards from the end of the string STRING (instead of forwards
from the front).
For example,
strrchr ("hello, world", 'l')
=> "ld"
-- Function: wchar_t * wcsrchr (const wchar_t *WSTRING, wchar_t C)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The function `wcsrchr' is like `wcschr', except that it searches
backwards from the end of the string WSTRING (instead of forwards
from the front).
-- Function: char * strstr (const char *HAYSTACK, const char *NEEDLE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is like `strchr', except that it searches HAYSTACK for a
substring NEEDLE rather than just a single character. It returns
a pointer into the string HAYSTACK that is the first character of
the substring, or a null pointer if no match was found. If NEEDLE
is an empty string, the function returns HAYSTACK.
For example,
strstr ("hello, world", "l")
=> "llo, world"
strstr ("hello, world", "wo")
=> "world"
-- Function: wchar_t * wcsstr (const wchar_t *HAYSTACK, const wchar_t
*NEEDLE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is like `wcschr', except that it searches HAYSTACK for a
substring NEEDLE rather than just a single wide character. It
returns a pointer into the string HAYSTACK that is the first wide
character of the substring, or a null pointer if no match was
found. If NEEDLE is an empty string, the function returns
HAYSTACK.
-- Function: wchar_t * wcswcs (const wchar_t *HAYSTACK, const wchar_t
*NEEDLE)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`wcswcs' is a deprecated alias for `wcsstr'. This is the name
originally used in the X/Open Portability Guide before the
Amendment 1 to ISO C90 was published.
-- Function: char * strcasestr (const char *HAYSTACK, const char
*NEEDLE)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
This is like `strstr', except that it ignores case in searching for
the substring. Like `strcasecmp', it is locale dependent how
uppercase and lowercase characters are related.
For example,
strcasestr ("hello, world", "L")
=> "llo, world"
strcasestr ("hello, World", "wo")
=> "World"
-- Function: void * memmem (const void *HAYSTACK, size_t HAYSTACK-LEN,
const void *NEEDLE, size_t NEEDLE-LEN)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is like `strstr', but NEEDLE and HAYSTACK are byte arrays
rather than null-terminated strings. NEEDLE-LEN is the length of
NEEDLE and HAYSTACK-LEN is the length of HAYSTACK.
This function is a GNU extension.
-- Function: size_t strspn (const char *STRING, const char *SKIPSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strspn' ("string span") function returns the length of the
initial substring of STRING that consists entirely of characters
that are members of the set specified by the string SKIPSET. The
order of the characters in SKIPSET is not important.
For example,
strspn ("hello, world", "abcdefghijklmnopqrstuvwxyz")
=> 5
Note that "character" is here used in the sense of byte. In a
string using a multibyte character encoding (abstract) character
consisting of more than one byte are not treated as an entity.
Each byte is treated separately. The function is not
locale-dependent.
-- Function: size_t wcsspn (const wchar_t *WSTRING, const wchar_t
*SKIPSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wcsspn' ("wide character string span") function returns the
length of the initial substring of WSTRING that consists entirely
of wide characters that are members of the set specified by the
string SKIPSET. The order of the wide characters in SKIPSET is not
important.
-- Function: size_t strcspn (const char *STRING, const char *STOPSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strcspn' ("string complement span") function returns the
length of the initial substring of STRING that consists entirely
of characters that are _not_ members of the set specified by the
string STOPSET. (In other words, it returns the offset of the
first character in STRING that is a member of the set STOPSET.)
For example,
strcspn ("hello, world", " \t\n,.;!?")
=> 5
Note that "character" is here used in the sense of byte. In a
string using a multibyte character encoding (abstract) character
consisting of more than one byte are not treated as an entity.
Each byte is treated separately. The function is not
locale-dependent.
-- Function: size_t wcscspn (const wchar_t *WSTRING, const wchar_t
*STOPSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wcscspn' ("wide character string complement span") function
returns the length of the initial substring of WSTRING that
consists entirely of wide characters that are _not_ members of the
set specified by the string STOPSET. (In other words, it returns
the offset of the first character in STRING that is a member of
the set STOPSET.)
-- Function: char * strpbrk (const char *STRING, const char *STOPSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `strpbrk' ("string pointer break") function is related to
`strcspn', except that it returns a pointer to the first character
in STRING that is a member of the set STOPSET instead of the
length of the initial substring. It returns a null pointer if no
such character from STOPSET is found.
For example,
strpbrk ("hello, world", " \t\n,.;!?")
=> ", world"
Note that "character" is here used in the sense of byte. In a
string using a multibyte character encoding (abstract) character
consisting of more than one byte are not treated as an entity.
Each byte is treated separately. The function is not
locale-dependent.
-- Function: wchar_t * wcspbrk (const wchar_t *WSTRING, const wchar_t
*STOPSET)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `wcspbrk' ("wide character string pointer break") function is
related to `wcscspn', except that it returns a pointer to the first
wide character in WSTRING that is a member of the set STOPSET
instead of the length of the initial substring. It returns a null
pointer if no such character from STOPSET is found.
5.7.1 Compatibility String Search Functions
-------------------------------------------
-- Function: char * index (const char *STRING, int C)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`index' is another name for `strchr'; they are exactly the same.
New code should always use `strchr' since this name is defined in
ISO C while `index' is a BSD invention which never was available
on System V derived systems.
-- Function: char * rindex (const char *STRING, int C)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`rindex' is another name for `strrchr'; they are exactly the same.
New code should always use `strrchr' since this name is defined in
ISO C while `rindex' is a BSD invention which never was available
on System V derived systems.

File: libc.info, Node: Finding Tokens in a String, Next: strfry, Prev: Search Functions, Up: String and Array Utilities
5.8 Finding Tokens in a String
==============================
It's fairly common for programs to have a need to do some simple kinds
of lexical analysis and parsing, such as splitting a command string up
into tokens. You can do this with the `strtok' function, declared in
the header file `string.h'.
-- Function: char * strtok (char *restrict NEWSTRING, const char
*restrict DELIMITERS)
Preliminary: | MT-Unsafe race:strtok | AS-Unsafe | AC-Safe | *Note
POSIX Safety Concepts::.
A string can be split into tokens by making a series of calls to
the function `strtok'.
The string to be split up is passed as the NEWSTRING argument on
the first call only. The `strtok' function uses this to set up
some internal state information. Subsequent calls to get
additional tokens from the same string are indicated by passing a
null pointer as the NEWSTRING argument. Calling `strtok' with
another non-null NEWSTRING argument reinitializes the state
information. It is guaranteed that no other library function ever
calls `strtok' behind your back (which would mess up this internal
state information).
The DELIMITERS argument is a string that specifies a set of
delimiters that may surround the token being extracted. All the
initial characters that are members of this set are discarded.
The first character that is _not_ a member of this set of
delimiters marks the beginning of the next token. The end of the
token is found by looking for the next character that is a member
of the delimiter set. This character in the original string
NEWSTRING is overwritten by a null character, and the pointer to
the beginning of the token in NEWSTRING is returned.
On the next call to `strtok', the searching begins at the next
character beyond the one that marked the end of the previous token.
Note that the set of delimiters DELIMITERS do not have to be the
same on every call in a series of calls to `strtok'.
If the end of the string NEWSTRING is reached, or if the remainder
of string consists only of delimiter characters, `strtok' returns
a null pointer.
Note that "character" is here used in the sense of byte. In a
string using a multibyte character encoding (abstract) character
consisting of more than one byte are not treated as an entity.
Each byte is treated separately. The function is not
locale-dependent.
-- Function: wchar_t * wcstok (wchar_t *NEWSTRING, const wchar_t
*DELIMITERS, wchar_t **SAVE_PTR)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
A string can be split into tokens by making a series of calls to
the function `wcstok'.
The string to be split up is passed as the NEWSTRING argument on
the first call only. The `wcstok' function uses this to set up
some internal state information. Subsequent calls to get
additional tokens from the same wide character string are
indicated by passing a null pointer as the NEWSTRING argument,
which causes the pointer previously stored in SAVE_PTR to be used
instead.
The DELIMITERS argument is a wide character string that specifies
a set of delimiters that may surround the token being extracted.
All the initial wide characters that are members of this set are
discarded. The first wide character that is _not_ a member of
this set of delimiters marks the beginning of the next token. The
end of the token is found by looking for the next wide character
that is a member of the delimiter set. This wide character in the
original wide character string NEWSTRING is overwritten by a null
wide character, the pointer past the overwritten wide character is
saved in SAVE_PTR, and the pointer to the beginning of the token
in NEWSTRING is returned.
On the next call to `wcstok', the searching begins at the next
wide character beyond the one that marked the end of the previous
token. Note that the set of delimiters DELIMITERS do not have to
be the same on every call in a series of calls to `wcstok'.
If the end of the wide character string NEWSTRING is reached, or
if the remainder of string consists only of delimiter wide
characters, `wcstok' returns a null pointer.
*Warning:* Since `strtok' and `wcstok' alter the string they is
parsing, you should always copy the string to a temporary buffer before
parsing it with `strtok'/`wcstok' (*note Copying and Concatenation::).
If you allow `strtok' or `wcstok' to modify a string that came from
another part of your program, you are asking for trouble; that string
might be used for other purposes after `strtok' or `wcstok' has
modified it, and it would not have the expected value.
The string that you are operating on might even be a constant. Then
when `strtok' or `wcstok' tries to modify it, your program will get a
fatal signal for writing in read-only memory. *Note Program Error
Signals::. Even if the operation of `strtok' or `wcstok' would not
require a modification of the string (e.g., if there is exactly one
token) the string can (and in the GNU C Library case will) be modified.
This is a special case of a general principle: if a part of a program
does not have as its purpose the modification of a certain data
structure, then it is error-prone to modify the data structure
temporarily.
The function `strtok' is not reentrant, whereas `wcstok' is. *Note
Nonreentrancy::, for a discussion of where and why reentrancy is
important.
Here is a simple example showing the use of `strtok'.
#include <string.h>
#include <stddef.h>
...
const char string[] = "words separated by spaces -- and, punctuation!";
const char delimiters[] = " .,;:!-";
char *token, *cp;
...
cp = strdupa (string); /* Make writable copy. */
token = strtok (cp, delimiters); /* token => "words" */
token = strtok (NULL, delimiters); /* token => "separated" */
token = strtok (NULL, delimiters); /* token => "by" */
token = strtok (NULL, delimiters); /* token => "spaces" */
token = strtok (NULL, delimiters); /* token => "and" */
token = strtok (NULL, delimiters); /* token => "punctuation" */
token = strtok (NULL, delimiters); /* token => NULL */
The GNU C Library contains two more functions for tokenizing a string
which overcome the limitation of non-reentrancy. They are only
available for multibyte character strings.
-- Function: char * strtok_r (char *NEWSTRING, const char *DELIMITERS,
char **SAVE_PTR)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
Just like `strtok', this function splits the string into several
tokens which can be accessed by successive calls to `strtok_r'.
The difference is that, as in `wcstok', the information about the
next token is stored in the space pointed to by the third argument,
SAVE_PTR, which is a pointer to a string pointer. Calling
`strtok_r' with a null pointer for NEWSTRING and leaving SAVE_PTR
between the calls unchanged does the job without hindering
reentrancy.
This function is defined in POSIX.1 and can be found on many
systems which support multi-threading.
-- Function: char * strsep (char **STRING_PTR, const char *DELIMITER)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This function has a similar functionality as `strtok_r' with the
NEWSTRING argument replaced by the SAVE_PTR argument. The
initialization of the moving pointer has to be done by the user.
Successive calls to `strsep' move the pointer along the tokens
separated by DELIMITER, returning the address of the next token
and updating STRING_PTR to point to the beginning of the next
token.
One difference between `strsep' and `strtok_r' is that if the
input string contains more than one character from DELIMITER in a
row `strsep' returns an empty string for each pair of characters
from DELIMITER. This means that a program normally should test
for `strsep' returning an empty string before processing it.
This function was introduced in 4.3BSD and therefore is widely
available.
Here is how the above example looks like when `strsep' is used.
#include <string.h>
#include <stddef.h>
...
const char string[] = "words separated by spaces -- and, punctuation!";
const char delimiters[] = " .,;:!-";
char *running;
char *token;
...
running = strdupa (string);
token = strsep (&running, delimiters); /* token => "words" */
token = strsep (&running, delimiters); /* token => "separated" */
token = strsep (&running, delimiters); /* token => "by" */
token = strsep (&running, delimiters); /* token => "spaces" */
token = strsep (&running, delimiters); /* token => "" */
token = strsep (&running, delimiters); /* token => "" */
token = strsep (&running, delimiters); /* token => "" */
token = strsep (&running, delimiters); /* token => "and" */
token = strsep (&running, delimiters); /* token => "" */
token = strsep (&running, delimiters); /* token => "punctuation" */
token = strsep (&running, delimiters); /* token => "" */
token = strsep (&running, delimiters); /* token => NULL */
-- Function: char * basename (const char *FILENAME)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The GNU version of the `basename' function returns the last
component of the path in FILENAME. This function is the preferred
usage, since it does not modify the argument, FILENAME, and
respects trailing slashes. The prototype for `basename' can be
found in `string.h'. Note, this function is overriden by the XPG
version, if `libgen.h' is included.
Example of using GNU `basename':
#include <string.h>
int
main (int argc, char *argv[])
{
char *prog = basename (argv[0]);
if (argc < 2)
{
fprintf (stderr, "Usage %s <arg>\n", prog);
exit (1);
}
...
}
*Portability Note:* This function may produce different results on
different systems.
-- Function: char * basename (const char *PATH)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
This is the standard XPG defined `basename'. It is similar in
spirit to the GNU version, but may modify the PATH by removing
trailing '/' characters. If the PATH is made up entirely of '/'
characters, then "/" will be returned. Also, if PATH is `NULL' or
an empty string, then "." is returned. The prototype for the XPG
version can be found in `libgen.h'.
Example of using XPG `basename':
#include <libgen.h>
int
main (int argc, char *argv[])
{
char *prog;
char *path = strdupa (argv[0]);
prog = basename (path);
if (argc < 2)
{
fprintf (stderr, "Usage %s <arg>\n", prog);
exit (1);
}
...
}
-- Function: char * dirname (char *PATH)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `dirname' function is the compliment to the XPG version of
`basename'. It returns the parent directory of the file specified
by PATH. If PATH is `NULL', an empty string, or contains no '/'
characters, then "." is returned. The prototype for this function
can be found in `libgen.h'.

File: libc.info, Node: strfry, Next: Trivial Encryption, Prev: Finding Tokens in a String, Up: String and Array Utilities
5.9 strfry
==========
The function below addresses the perennial programming quandary: "How do
I take good data in string form and painlessly turn it into garbage?"
This is actually a fairly simple task for C programmers who do not use
the GNU C Library string functions, but for programs based on the GNU C
Library, the `strfry' function is the preferred method for destroying
string data.
The prototype for this function is in `string.h'.
-- Function: char * strfry (char *STRING)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`strfry' creates a pseudorandom anagram of a string, replacing the
input with the anagram in place. For each position in the string,
`strfry' swaps it with a position in the string selected at random
(from a uniform distribution). The two positions may be the same.
The return value of `strfry' is always STRING.
*Portability Note:* This function is unique to the GNU C Library.

File: libc.info, Node: Trivial Encryption, Next: Encode Binary Data, Prev: strfry, Up: String and Array Utilities
5.10 Trivial Encryption
=======================
The `memfrob' function converts an array of data to something
unrecognizable and back again. It is not encryption in its usual sense
since it is easy for someone to convert the encrypted data back to clear
text. The transformation is analogous to Usenet's "Rot13" encryption
method for obscuring offensive jokes from sensitive eyes and such.
Unlike Rot13, `memfrob' works on arbitrary binary data, not just text.
For true encryption, *Note Cryptographic Functions::.
This function is declared in `string.h'.
-- Function: void * memfrob (void *MEM, size_t LENGTH)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
`memfrob' transforms (frobnicates) each byte of the data structure
at MEM, which is LENGTH bytes long, by bitwise exclusive oring it
with binary 00101010. It does the transformation in place and its
return value is always MEM.
Note that `memfrob' a second time on the same data structure
returns it to its original state.
This is a good function for hiding information from someone who
doesn't want to see it or doesn't want to see it very much. To
really prevent people from retrieving the information, use
stronger encryption such as that described in *Note Cryptographic
Functions::.
*Portability Note:* This function is unique to the GNU C Library.

File: libc.info, Node: Encode Binary Data, Next: Argz and Envz Vectors, Prev: Trivial Encryption, Up: String and Array Utilities
5.11 Encode Binary Data
=======================
To store or transfer binary data in environments which only support text
one has to encode the binary data by mapping the input bytes to
characters in the range allowed for storing or transferring. SVID
systems (and nowadays XPG compliant systems) provide minimal support for
this task.
-- Function: char * l64a (long int N)
Preliminary: | MT-Unsafe race:l64a | AS-Unsafe | AC-Safe | *Note
POSIX Safety Concepts::.
This function encodes a 32-bit input value using characters from
the basic character set. It returns a pointer to a 7 character
buffer which contains an encoded version of N. To encode a series
of bytes the user must copy the returned string to a destination
buffer. It returns the empty string if N is zero, which is
somewhat bizarre but mandated by the standard.
*Warning:* Since a static buffer is used this function should not
be used in multi-threaded programs. There is no thread-safe
alternative to this function in the C library.
*Compatibility Note:* The XPG standard states that the return
value of `l64a' is undefined if N is negative. In the GNU
implementation, `l64a' treats its argument as unsigned, so it will
return a sensible encoding for any nonzero N; however, portable
programs should not rely on this.
To encode a large buffer `l64a' must be called in a loop, once for
each 32-bit word of the buffer. For example, one could do
something like this:
char *
encode (const void *buf, size_t len)
{
/* We know in advance how long the buffer has to be. */
unsigned char *in = (unsigned char *) buf;
char *out = malloc (6 + ((len + 3) / 4) * 6 + 1);
char *cp = out, *p;
/* Encode the length. */
/* Using `htonl' is necessary so that the data can be
decoded even on machines with different byte order.
`l64a' can return a string shorter than 6 bytes, so
we pad it with encoding of 0 ('.') at the end by
hand. */
p = stpcpy (cp, l64a (htonl (len)));
cp = mempcpy (p, "......", 6 - (p - cp));
while (len > 3)
{
unsigned long int n = *in++;
n = (n << 8) | *in++;
n = (n << 8) | *in++;
n = (n << 8) | *in++;
len -= 4;
p = stpcpy (cp, l64a (htonl (n)));
cp = mempcpy (p, "......", 6 - (p - cp));
}
if (len > 0)
{
unsigned long int n = *in++;
if (--len > 0)
{
n = (n << 8) | *in++;
if (--len > 0)
n = (n << 8) | *in;
}
cp = stpcpy (cp, l64a (htonl (n)));
}
*cp = '\0';
return out;
}
It is strange that the library does not provide the complete
functionality needed but so be it.
To decode data produced with `l64a' the following function should be
used.
-- Function: long int a64l (const char *STRING)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The parameter STRING should contain a string which was produced by
a call to `l64a'. The function processes at least 6 characters of
this string, and decodes the characters it finds according to the
table below. It stops decoding when it finds a character not in
the table, rather like `atoi'; if you have a buffer which has been
broken into lines, you must be careful to skip over the
end-of-line characters.
The decoded number is returned as a `long int' value.
The `l64a' and `a64l' functions use a base 64 encoding, in which
each character of an encoded string represents six bits of an input
word. These symbols are used for the base 64 digits:
0 1 2 3 4 5 6 7
0 `.' `/' `0' `1' `2' `3' `4' `5'
8 `6' `7' `8' `9' `A' `B' `C' `D'
16 `E' `F' `G' `H' `I' `J' `K' `L'
24 `M' `N' `O' `P' `Q' `R' `S' `T'
32 `U' `V' `W' `X' `Y' `Z' `a' `b'
40 `c' `d' `e' `f' `g' `h' `i' `j'
48 `k' `l' `m' `n' `o' `p' `q' `r'
56 `s' `t' `u' `v' `w' `x' `y' `z'
This encoding scheme is not standard. There are some other encoding
methods which are much more widely used (UU encoding, MIME encoding).
Generally, it is better to use one of these encodings.

File: libc.info, Node: Argz and Envz Vectors, Prev: Encode Binary Data, Up: String and Array Utilities
5.12 Argz and Envz Vectors
==========================
"argz vectors" are vectors of strings in a contiguous block of memory,
each element separated from its neighbors by null-characters (`'\0'').
"Envz vectors" are an extension of argz vectors where each element
is a name-value pair, separated by a `'='' character (as in a Unix
environment).
* Menu:
* Argz Functions:: Operations on argz vectors.
* Envz Functions:: Additional operations on environment vectors.

File: libc.info, Node: Argz Functions, Next: Envz Functions, Up: Argz and Envz Vectors
5.12.1 Argz Functions
---------------------
Each argz vector is represented by a pointer to the first element, of
type `char *', and a size, of type `size_t', both of which can be
initialized to `0' to represent an empty argz vector. All argz
functions accept either a pointer and a size argument, or pointers to
them, if they will be modified.
The argz functions use `malloc'/`realloc' to allocate/grow argz
vectors, and so any argz vector creating using these functions may be
freed by using `free'; conversely, any argz function that may grow a
string expects that string to have been allocated using `malloc' (those
argz functions that only examine their arguments or modify them in
place will work on any sort of memory). *Note Unconstrained
Allocation::.
All argz functions that do memory allocation have a return type of
`error_t', and return `0' for success, and `ENOMEM' if an allocation
error occurs.
These functions are declared in the standard include file `argz.h'.
-- Function: error_t argz_create (char *const ARGV[], char **ARGZ,
size_t *ARGZ_LEN)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `argz_create' function converts the Unix-style argument vector
ARGV (a vector of pointers to normal C strings, terminated by
`(char *)0'; *note Program Arguments::) into an argz vector with
the same elements, which is returned in ARGZ and ARGZ_LEN.
-- Function: error_t argz_create_sep (const char *STRING, int SEP,
char **ARGZ, size_t *ARGZ_LEN)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `argz_create_sep' function converts the null-terminated string
STRING into an argz vector (returned in ARGZ and ARGZ_LEN) by
splitting it into elements at every occurrence of the character
SEP.
-- Function: size_t argz_count (const char *ARGZ, size_t ARG_LEN)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
Returns the number of elements in the argz vector ARGZ and
ARGZ_LEN.
-- Function: void argz_extract (const char *ARGZ, size_t ARGZ_LEN,
char **ARGV)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `argz_extract' function converts the argz vector ARGZ and
ARGZ_LEN into a Unix-style argument vector stored in ARGV, by
putting pointers to every element in ARGZ into successive
positions in ARGV, followed by a terminator of `0'. ARGV must be
pre-allocated with enough space to hold all the elements in ARGZ
plus the terminating `(char *)0' (`(argz_count (ARGZ, ARGZ_LEN) +
1) * sizeof (char *)' bytes should be enough). Note that the
string pointers stored into ARGV point into ARGZ--they are not
copies--and so ARGZ must be copied if it will be changed while
ARGV is still active. This function is useful for passing the
elements in ARGZ to an exec function (*note Executing a File::).
-- Function: void argz_stringify (char *ARGZ, size_t LEN, int SEP)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `argz_stringify' converts ARGZ into a normal string with the
elements separated by the character SEP, by replacing each `'\0''
inside ARGZ (except the last one, which terminates the string)
with SEP. This is handy for printing ARGZ in a readable manner.
-- Function: error_t argz_add (char **ARGZ, size_t *ARGZ_LEN, const
char *STR)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `argz_add' function adds the string STR to the end of the argz
vector `*ARGZ', and updates `*ARGZ' and `*ARGZ_LEN' accordingly.
-- Function: error_t argz_add_sep (char **ARGZ, size_t *ARGZ_LEN,
const char *STR, int DELIM)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `argz_add_sep' function is similar to `argz_add', but STR is
split into separate elements in the result at occurrences of the
character DELIM. This is useful, for instance, for adding the
components of a Unix search path to an argz vector, by using a
value of `':'' for DELIM.
-- Function: error_t argz_append (char **ARGZ, size_t *ARGZ_LEN, const
char *BUF, size_t BUF_LEN)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `argz_append' function appends BUF_LEN bytes starting at BUF
to the argz vector `*ARGZ', reallocating `*ARGZ' to accommodate
it, and adding BUF_LEN to `*ARGZ_LEN'.
-- Function: void argz_delete (char **ARGZ, size_t *ARGZ_LEN, char
*ENTRY)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
If ENTRY points to the beginning of one of the elements in the
argz vector `*ARGZ', the `argz_delete' function will remove this
entry and reallocate `*ARGZ', modifying `*ARGZ' and `*ARGZ_LEN'
accordingly. Note that as destructive argz functions usually
reallocate their argz argument, pointers into argz vectors such as
ENTRY will then become invalid.
-- Function: error_t argz_insert (char **ARGZ, size_t *ARGZ_LEN, char
*BEFORE, const char *ENTRY)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `argz_insert' function inserts the string ENTRY into the argz
vector `*ARGZ' at a point just before the existing element pointed
to by BEFORE, reallocating `*ARGZ' and updating `*ARGZ' and
`*ARGZ_LEN'. If BEFORE is `0', ENTRY is added to the end instead
(as if by `argz_add'). Since the first element is in fact the
same as `*ARGZ', passing in `*ARGZ' as the value of BEFORE will
result in ENTRY being inserted at the beginning.
-- Function: char * argz_next (const char *ARGZ, size_t ARGZ_LEN,
const char *ENTRY)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `argz_next' function provides a convenient way of iterating
over the elements in the argz vector ARGZ. It returns a pointer
to the next element in ARGZ after the element ENTRY, or `0' if
there are no elements following ENTRY. If ENTRY is `0', the first
element of ARGZ is returned.
This behavior suggests two styles of iteration:
char *entry = 0;
while ((entry = argz_next (ARGZ, ARGZ_LEN, entry)))
ACTION;
(the double parentheses are necessary to make some C compilers
shut up about what they consider a questionable `while'-test) and:
char *entry;
for (entry = ARGZ;
entry;
entry = argz_next (ARGZ, ARGZ_LEN, entry))
ACTION;
Note that the latter depends on ARGZ having a value of `0' if it
is empty (rather than a pointer to an empty block of memory); this
invariant is maintained for argz vectors created by the functions
here.
-- Function: error_t argz_replace (char **ARGZ, size_t *ARGZ_LEN,
const char *STR, const char *WITH, unsigned *REPLACE_COUNT)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
Replace any occurrences of the string STR in ARGZ with WITH,
reallocating ARGZ as necessary. If REPLACE_COUNT is non-zero,
`*REPLACE_COUNT' will be incremented by number of replacements
performed.

File: libc.info, Node: Envz Functions, Prev: Argz Functions, Up: Argz and Envz Vectors
5.12.2 Envz Functions
---------------------
Envz vectors are just argz vectors with additional constraints on the
form of each element; as such, argz functions can also be used on them,
where it makes sense.
Each element in an envz vector is a name-value pair, separated by a
`'='' character; if multiple `'='' characters are present in an
element, those after the first are considered part of the value, and
treated like all other non-`'\0'' characters.
If _no_ `'='' characters are present in an element, that element is
considered the name of a "null" entry, as distinct from an entry with an
empty value: `envz_get' will return `0' if given the name of null
entry, whereas an entry with an empty value would result in a value of
`""'; `envz_entry' will still find such entries, however. Null entries
can be removed with `envz_strip' function.
As with argz functions, envz functions that may allocate memory (and
thus fail) have a return type of `error_t', and return either `0' or
`ENOMEM'.
These functions are declared in the standard include file `envz.h'.
-- Function: char * envz_entry (const char *ENVZ, size_t ENVZ_LEN,
const char *NAME)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `envz_entry' function finds the entry in ENVZ with the name
NAME, and returns a pointer to the whole entry--that is, the argz
element which begins with NAME followed by a `'='' character. If
there is no entry with that name, `0' is returned.
-- Function: char * envz_get (const char *ENVZ, size_t ENVZ_LEN, const
char *NAME)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `envz_get' function finds the entry in ENVZ with the name NAME
(like `envz_entry'), and returns a pointer to the value portion of
that entry (following the `'=''). If there is no entry with that
name (or only a null entry), `0' is returned.
-- Function: error_t envz_add (char **ENVZ, size_t *ENVZ_LEN, const
char *NAME, const char *VALUE)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `envz_add' function adds an entry to `*ENVZ' (updating `*ENVZ'
and `*ENVZ_LEN') with the name NAME, and value VALUE. If an entry
with the same name already exists in ENVZ, it is removed first.
If VALUE is `0', then the new entry will the special null type of
entry (mentioned above).
-- Function: error_t envz_merge (char **ENVZ, size_t *ENVZ_LEN, const
char *ENVZ2, size_t ENVZ2_LEN, int OVERRIDE)
Preliminary: | MT-Safe | AS-Unsafe heap | AC-Unsafe mem | *Note
POSIX Safety Concepts::.
The `envz_merge' function adds each entry in ENVZ2 to ENVZ, as if
with `envz_add', updating `*ENVZ' and `*ENVZ_LEN'. If OVERRIDE is
true, then values in ENVZ2 will supersede those with the same name
in ENVZ, otherwise not.
Null entries are treated just like other entries in this respect,
so a null entry in ENVZ can prevent an entry of the same name in
ENVZ2 from being added to ENVZ, if OVERRIDE is false.
-- Function: void envz_strip (char **ENVZ, size_t *ENVZ_LEN)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `envz_strip' function removes any null entries from ENVZ,
updating `*ENVZ' and `*ENVZ_LEN'.

File: libc.info, Node: Character Set Handling, Next: Locales, Prev: String and Array Utilities, Up: Top
6 Character Set Handling
************************
Character sets used in the early days of computing had only six, seven,
or eight bits for each character: there was never a case where more than
eight bits (one byte) were used to represent a single character. The
limitations of this approach became more apparent as more people
grappled with non-Roman character sets, where not all the characters
that make up a language's character set can be represented by 2^8
choices. This chapter shows the functionality that was added to the C
library to support multiple character sets.
* Menu:
* Extended Char Intro:: Introduction to Extended Characters.
* Charset Function Overview:: Overview about Character Handling
Functions.
* Restartable multibyte conversion:: Restartable multibyte conversion
Functions.
* Non-reentrant Conversion:: Non-reentrant Conversion Function.
* Generic Charset Conversion:: Generic Charset Conversion.

File: libc.info, Node: Extended Char Intro, Next: Charset Function Overview, Up: Character Set Handling
6.1 Introduction to Extended Characters
=======================================
A variety of solutions is available to overcome the differences between
character sets with a 1:1 relation between bytes and characters and
character sets with ratios of 2:1 or 4:1. The remainder of this
section gives a few examples to help understand the design decisions
made while developing the functionality of the C library.
A distinction we have to make right away is between internal and
external representation. "Internal representation" means the
representation used by a program while keeping the text in memory.
External representations are used when text is stored or transmitted
through some communication channel. Examples of external
representations include files waiting in a directory to be read and
parsed.
Traditionally there has been no difference between the two
representations. It was equally comfortable and useful to use the same
single-byte representation internally and externally. This comfort
level decreases with more and larger character sets.
One of the problems to overcome with the internal representation is
handling text that is externally encoded using different character
sets. Assume a program that reads two texts and compares them using
some metric. The comparison can be usefully done only if the texts are
internally kept in a common format.
For such a common format (= character set) eight bits are certainly
no longer enough. So the smallest entity will have to grow: "wide
characters" will now be used. Instead of one byte per character, two or
four will be used instead. (Three are not good to address in memory and
more than four bytes seem not to be necessary).
As shown in some other part of this manual, a completely new family
has been created of functions that can handle wide character texts in
memory. The most commonly used character sets for such internal wide
character representations are Unicode and ISO 10646 (also known as UCS
for Universal Character Set). Unicode was originally planned as a
16-bit character set; whereas, ISO 10646 was designed to be a 31-bit
large code space. The two standards are practically identical. They
have the same character repertoire and code table, but Unicode specifies
added semantics. At the moment, only characters in the first `0x10000'
code positions (the so-called Basic Multilingual Plane, BMP) have been
assigned, but the assignment of more specialized characters outside this
16-bit space is already in progress. A number of encodings have been
defined for Unicode and ISO 10646 characters: UCS-2 is a 16-bit word
that can only represent characters from the BMP, UCS-4 is a 32-bit word
than can represent any Unicode and ISO 10646 character, UTF-8 is an
ASCII compatible encoding where ASCII characters are represented by
ASCII bytes and non-ASCII characters by sequences of 2-6 non-ASCII
bytes, and finally UTF-16 is an extension of UCS-2 in which pairs of
certain UCS-2 words can be used to encode non-BMP characters up to
`0x10ffff'.
To represent wide characters the `char' type is not suitable. For
this reason the ISO C standard introduces a new type that is designed
to keep one character of a wide character string. To maintain the
similarity there is also a type corresponding to `int' for those
functions that take a single wide character.
-- Data type: wchar_t
This data type is used as the base type for wide character strings.
In other words, arrays of objects of this type are the equivalent
of `char[]' for multibyte character strings. The type is defined
in `stddef.h'.
The ISO C90 standard, where `wchar_t' was introduced, does not say
anything specific about the representation. It only requires that
this type is capable of storing all elements of the basic
character set. Therefore it would be legitimate to define
`wchar_t' as `char', which might make sense for embedded systems.
But in the GNU C Library `wchar_t' is always 32 bits wide and,
therefore, capable of representing all UCS-4 values and,
therefore, covering all of ISO 10646. Some Unix systems define
`wchar_t' as a 16-bit type and thereby follow Unicode very
strictly. This definition is perfectly fine with the standard,
but it also means that to represent all characters from Unicode
and ISO 10646 one has to use UTF-16 surrogate characters, which is
in fact a multi-wide-character encoding. But resorting to
multi-wide-character encoding contradicts the purpose of the
`wchar_t' type.
-- Data type: wint_t
`wint_t' is a data type used for parameters and variables that
contain a single wide character. As the name suggests this type
is the equivalent of `int' when using the normal `char' strings.
The types `wchar_t' and `wint_t' often have the same
representation if their size is 32 bits wide but if `wchar_t' is
defined as `char' the type `wint_t' must be defined as `int' due
to the parameter promotion.
This type is defined in `wchar.h' and was introduced in
Amendment 1 to ISO C90.
As there are for the `char' data type macros are available for
specifying the minimum and maximum value representable in an object of
type `wchar_t'.
-- Macro: wint_t WCHAR_MIN
The macro `WCHAR_MIN' evaluates to the minimum value representable
by an object of type `wint_t'.
This macro was introduced in Amendment 1 to ISO C90.
-- Macro: wint_t WCHAR_MAX
The macro `WCHAR_MAX' evaluates to the maximum value representable
by an object of type `wint_t'.
This macro was introduced in Amendment 1 to ISO C90.
Another special wide character value is the equivalent to `EOF'.
-- Macro: wint_t WEOF
The macro `WEOF' evaluates to a constant expression of type
`wint_t' whose value is different from any member of the extended
character set.
`WEOF' need not be the same value as `EOF' and unlike `EOF' it
also need _not_ be negative. In other words, sloppy code like
{
int c;
...
while ((c = getc (fp)) < 0)
...
}
has to be rewritten to use `WEOF' explicitly when wide characters
are used:
{
wint_t c;
...
while ((c = wgetc (fp)) != WEOF)
...
}
This macro was introduced in Amendment 1 to ISO C90 and is defined
in `wchar.h'.
These internal representations present problems when it comes to
storing and transmittal. Because each single wide character consists
of more than one byte, they are affected by byte-ordering. Thus,
machines with different endianesses would see different values when
accessing the same data. This byte ordering concern also applies for
communication protocols that are all byte-based and therefore require
that the sender has to decide about splitting the wide character in
bytes. A last (but not least important) point is that wide characters
often require more storage space than a customized byte-oriented
character set.
For all the above reasons, an external encoding that is different
from the internal encoding is often used if the latter is UCS-2 or
UCS-4. The external encoding is byte-based and can be chosen
appropriately for the environment and for the texts to be handled. A
variety of different character sets can be used for this external
encoding (information that will not be exhaustively presented
here-instead, a description of the major groups will suffice). All of
the ASCII-based character sets fulfill one requirement: they are
"filesystem safe." This means that the character `'/'' is used in the
encoding _only_ to represent itself. Things are a bit different for
character sets like EBCDIC (Extended Binary Coded Decimal Interchange
Code, a character set family used by IBM), but if the operating system
does not understand EBCDIC directly the parameters-to-system calls have
to be converted first anyhow.
* The simplest character sets are single-byte character sets. There
can be only up to 256 characters (for 8 bit character sets), which
is not sufficient to cover all languages but might be sufficient
to handle a specific text. Handling of a 8 bit character sets is
simple. This is not true for other kinds presented later, and
therefore, the application one uses might require the use of 8 bit
character sets.
* The ISO 2022 standard defines a mechanism for extended character
sets where one character _can_ be represented by more than one
byte. This is achieved by associating a state with the text.
Characters that can be used to change the state can be embedded in
the text. Each byte in the text might have a different
interpretation in each state. The state might even influence
whether a given byte stands for a character on its own or whether
it has to be combined with some more bytes.
In most uses of ISO 2022 the defined character sets do not allow
state changes that cover more than the next character. This has
the big advantage that whenever one can identify the beginning of
the byte sequence of a character one can interpret a text
correctly. Examples of character sets using this policy are the
various EUC character sets (used by Sun's operating systems,
EUC-JP, EUC-KR, EUC-TW, and EUC-CN) or Shift_JIS (SJIS, a Japanese
encoding).
But there are also character sets using a state that is valid for
more than one character and has to be changed by another byte
sequence. Examples for this are ISO-2022-JP, ISO-2022-KR, and
ISO-2022-CN.
* Early attempts to fix 8 bit character sets for other languages
using the Roman alphabet lead to character sets like ISO 6937.
Here bytes representing characters like the acute accent do not
produce output themselves: one has to combine them with other
characters to get the desired result. For example, the byte
sequence `0xc2 0x61' (non-spacing acute accent, followed by
lower-case `a') to get the "small a with acute" character. To
get the acute accent character on its own, one has to write `0xc2
0x20' (the non-spacing acute followed by a space).
Character sets like ISO 6937 are used in some embedded systems such
as teletex.
* Instead of converting the Unicode or ISO 10646 text used
internally, it is often also sufficient to simply use an encoding
different than UCS-2/UCS-4. The Unicode and ISO 10646 standards
even specify such an encoding: UTF-8. This encoding is able to
represent all of ISO 10646 31 bits in a byte string of length one
to six.
There were a few other attempts to encode ISO 10646 such as UTF-7,
but UTF-8 is today the only encoding that should be used. In
fact, with any luck UTF-8 will soon be the only external encoding
that has to be supported. It proves to be universally usable and
its only disadvantage is that it favors Roman languages by making
the byte string representation of other scripts (Cyrillic, Greek,
Asian scripts) longer than necessary if using a specific character
set for these scripts. Methods like the Unicode compression
scheme can alleviate these problems.
The question remaining is: how to select the character set or
encoding to use. The answer: you cannot decide about it yourself, it
is decided by the developers of the system or the majority of the
users. Since the goal is interoperability one has to use whatever the
other people one works with use. If there are no constraints, the
selection is based on the requirements the expected circle of users
will have. In other words, if a project is expected to be used in
only, say, Russia it is fine to use KOI8-R or a similar character set.
But if at the same time people from, say, Greece are participating one
should use a character set that allows all people to collaborate.
The most widely useful solution seems to be: go with the most general
character set, namely ISO 10646. Use UTF-8 as the external encoding
and problems about users not being able to use their own language
adequately are a thing of the past.
One final comment about the choice of the wide character
representation is necessary at this point. We have said above that the
natural choice is using Unicode or ISO 10646. This is not required,
but at least encouraged, by the ISO C standard. The standard defines
at least a macro `__STDC_ISO_10646__' that is only defined on systems
where the `wchar_t' type encodes ISO 10646 characters. If this symbol
is not defined one should avoid making assumptions about the wide
character representation. If the programmer uses only the functions
provided by the C library to handle wide character strings there should
be no compatibility problems with other systems.

File: libc.info, Node: Charset Function Overview, Next: Restartable multibyte conversion, Prev: Extended Char Intro, Up: Character Set Handling
6.2 Overview about Character Handling Functions
===============================================
A Unix C library contains three different sets of functions in two
families to handle character set conversion. One of the function
families (the most commonly used) is specified in the ISO C90 standard
and, therefore, is portable even beyond the Unix world. Unfortunately
this family is the least useful one. These functions should be avoided
whenever possible, especially when developing libraries (as opposed to
applications).
The second family of functions got introduced in the early Unix
standards (XPG2) and is still part of the latest and greatest Unix
standard: Unix 98. It is also the most powerful and useful set of
functions. But we will start with the functions defined in Amendment 1
to ISO C90.

File: libc.info, Node: Restartable multibyte conversion, Next: Non-reentrant Conversion, Prev: Charset Function Overview, Up: Character Set Handling
6.3 Restartable Multibyte Conversion Functions
==============================================
The ISO C standard defines functions to convert strings from a
multibyte representation to wide character strings. There are a number
of peculiarities:
* The character set assumed for the multibyte encoding is not
specified as an argument to the functions. Instead the character
set specified by the `LC_CTYPE' category of the current locale is
used; see *note Locale Categories::.
* The functions handling more than one character at a time require
NUL terminated strings as the argument (i.e., converting blocks of
text does not work unless one can add a NUL byte at an appropriate
place). The GNU C Library contains some extensions to the
standard that allow specifying a size, but basically they also
expect terminated strings.
Despite these limitations the ISO C functions can be used in many
contexts. In graphical user interfaces, for instance, it is not
uncommon to have functions that require text to be displayed in a wide
character string if the text is not simple ASCII. The text itself might
come from a file with translations and the user should decide about the
current locale, which determines the translation and therefore also the
external encoding used. In such a situation (and many others) the
functions described here are perfect. If more freedom while performing
the conversion is necessary take a look at the `iconv' functions (*note
Generic Charset Conversion::).
* Menu:
* Selecting the Conversion:: Selecting the conversion and its properties.
* Keeping the state:: Representing the state of the conversion.
* Converting a Character:: Converting Single Characters.
* Converting Strings:: Converting Multibyte and Wide Character
Strings.
* Multibyte Conversion Example:: A Complete Multibyte Conversion Example.

File: libc.info, Node: Selecting the Conversion, Next: Keeping the state, Up: Restartable multibyte conversion
6.3.1 Selecting the conversion and its properties
-------------------------------------------------
We already said above that the currently selected locale for the
`LC_CTYPE' category decides about the conversion that is performed by
the functions we are about to describe. Each locale uses its own
character set (given as an argument to `localedef') and this is the one
assumed as the external multibyte encoding. The wide character set is
always UCS-4 in the GNU C Library.
A characteristic of each multibyte character set is the maximum
number of bytes that can be necessary to represent one character. This
information is quite important when writing code that uses the
conversion functions (as shown in the examples below). The ISO C
standard defines two macros that provide this information.
-- Macro: int MB_LEN_MAX
`MB_LEN_MAX' specifies the maximum number of bytes in the multibyte
sequence for a single character in any of the supported locales.
It is a compile-time constant and is defined in `limits.h'.
-- Macro: int MB_CUR_MAX
`MB_CUR_MAX' expands into a positive integer expression that is the
maximum number of bytes in a multibyte character in the current
locale. The value is never greater than `MB_LEN_MAX'. Unlike
`MB_LEN_MAX' this macro need not be a compile-time constant, and in
the GNU C Library it is not.
`MB_CUR_MAX' is defined in `stdlib.h'.
Two different macros are necessary since strictly ISO C90 compilers
do not allow variable length array definitions, but still it is
desirable to avoid dynamic allocation. This incomplete piece of code
shows the problem:
{
char buf[MB_LEN_MAX];
ssize_t len = 0;
while (! feof (fp))
{
fread (&buf[len], 1, MB_CUR_MAX - len, fp);
/* ... process buf */
len -= used;
}
}
The code in the inner loop is expected to have always enough bytes in
the array BUF to convert one multibyte character. The array BUF has to
be sized statically since many compilers do not allow a variable size.
The `fread' call makes sure that `MB_CUR_MAX' bytes are always
available in BUF. Note that it isn't a problem if `MB_CUR_MAX' is not
a compile-time constant.

File: libc.info, Node: Keeping the state, Next: Converting a Character, Prev: Selecting the Conversion, Up: Restartable multibyte conversion
6.3.2 Representing the state of the conversion
----------------------------------------------
In the introduction of this chapter it was said that certain character
sets use a "stateful" encoding. That is, the encoded values depend in
some way on the previous bytes in the text.
Since the conversion functions allow converting a text in more than
one step we must have a way to pass this information from one call of
the functions to another.
-- Data type: mbstate_t
A variable of type `mbstate_t' can contain all the information
about the "shift state" needed from one call to a conversion
function to another.
`mbstate_t' is defined in `wchar.h'. It was introduced in
Amendment 1 to ISO C90.
To use objects of type `mbstate_t' the programmer has to define such
objects (normally as local variables on the stack) and pass a pointer to
the object to the conversion functions. This way the conversion
function can update the object if the current multibyte character set
is stateful.
There is no specific function or initializer to put the state object
in any specific state. The rules are that the object should always
represent the initial state before the first use, and this is achieved
by clearing the whole variable with code such as follows:
{
mbstate_t state;
memset (&state, '\0', sizeof (state));
/* from now on STATE can be used. */
...
}
When using the conversion functions to generate output it is often
necessary to test whether the current state corresponds to the initial
state. This is necessary, for example, to decide whether to emit
escape sequences to set the state to the initial state at certain
sequence points. Communication protocols often require this.
-- Function: int mbsinit (const mbstate_t *PS)
Preliminary: | MT-Safe | AS-Safe | AC-Safe | *Note POSIX Safety
Concepts::.
The `mbsinit' function determines whether the state object pointed
to by PS is in the initial state. If PS is a null pointer or the
object is in the initial state the return value is nonzero.
Otherwise it is zero.
`mbsinit' was introduced in Amendment 1 to ISO C90 and is declared
in `wchar.h'.
Code using `mbsinit' often looks similar to this:
{
mbstate_t state;
memset (&state, '\0', sizeof (state));
/* Use STATE. */
...
if (! mbsinit (&state))
{
/* Emit code to return to initial state. */
const wchar_t empty[] = L"";
const wchar_t *srcp = empty;
wcsrtombs (outbuf, &srcp, outbuflen, &state);
}
...
}
The code to emit the escape sequence to get back to the initial
state is interesting. The `wcsrtombs' function can be used to
determine the necessary output code (*note Converting Strings::).
Please note that with the GNU C Library it is not necessary to perform
this extra action for the conversion from multibyte text to wide
character text since the wide character encoding is not stateful. But
there is nothing mentioned in any standard that prohibits making
`wchar_t' using a stateful encoding.

File: libc.info, Node: Converting a Character, Next: Converting Strings, Prev: Keeping the state, Up: Restartable multibyte conversion
6.3.3 Converting Single Characters
----------------------------------
The most fundamental of the conversion functions are those dealing with
single characters. Please note that this does not always mean single
bytes. But since there is very often a subset of the multibyte
character set that consists of single byte sequences, there are
functions to help with converting bytes. Frequently, ASCII is a subpart
of the multibyte character set. In such a scenario, each ASCII
character stands for itself, and all other characters have at least a
first byte that is beyond the range 0 to 127.
-- Function: wint_t btowc (int C)
Preliminary: | MT-Safe | AS-Unsafe corrupt heap lock dlopen |
AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `btowc' function ("byte to wide character") converts a valid
single byte character C in the initial shift state into the wide
character equivalent using the conversion rules from the currently
selected locale of the `LC_CTYPE' category.
If `(unsigned char) C' is no valid single byte multibyte character
or if C is `EOF', the function returns `WEOF'.
Please note the restriction of C being tested for validity only in
the initial shift state. No `mbstate_t' object is used from which
the state information is taken, and the function also does not use
any static state.
The `btowc' function was introduced in Amendment 1 to ISO C90 and
is declared in `wchar.h'.
Despite the limitation that the single byte value is always
interpreted in the initial state, this function is actually useful most
of the time. Most characters are either entirely single-byte character
sets or they are extension to ASCII. But then it is possible to write
code like this (not that this specific example is very useful):
wchar_t *
itow (unsigned long int val)
{
static wchar_t buf[30];
wchar_t *wcp = &buf[29];
*wcp = L'\0';
while (val != 0)
{
*--wcp = btowc ('0' + val % 10);
val /= 10;
}
if (wcp == &buf[29])
*--wcp = L'0';
return wcp;
}
Why is it necessary to use such a complicated implementation and not
simply cast `'0' + val % 10' to a wide character? The answer is that
there is no guarantee that one can perform this kind of arithmetic on
the character of the character set used for `wchar_t' representation.
In other situations the bytes are not constant at compile time and so
the compiler cannot do the work. In situations like this, using
`btowc' is required.
There is also a function for the conversion in the other direction.
-- Function: int wctob (wint_t C)
Preliminary: | MT-Safe | AS-Unsafe corrupt heap lock dlopen |
AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `wctob' function ("wide character to byte") takes as the
parameter a valid wide character. If the multibyte representation
for this character in the initial state is exactly one byte long,
the return value of this function is this character. Otherwise
the return value is `EOF'.
`wctob' was introduced in Amendment 1 to ISO C90 and is declared
in `wchar.h'.
There are more general functions to convert single character from
multibyte representation to wide characters and vice versa. These
functions pose no limit on the length of the multibyte representation
and they also do not require it to be in the initial state.
-- Function: size_t mbrtowc (wchar_t *restrict PWC, const char
*restrict S, size_t N, mbstate_t *restrict PS)
Preliminary: | MT-Unsafe race:mbrtowc/!ps | AS-Unsafe corrupt heap
lock dlopen | AC-Unsafe corrupt lock mem fd | *Note POSIX Safety
Concepts::.
The `mbrtowc' function ("multibyte restartable to wide character")
converts the next multibyte character in the string pointed to by
S into a wide character and stores it in the wide character string
pointed to by PWC. The conversion is performed according to the
locale currently selected for the `LC_CTYPE' category. If the
conversion for the character set used in the locale requires a
state, the multibyte string is interpreted in the state
represented by the object pointed to by PS. If PS is a null
pointer, a static, internal state variable used only by the
`mbrtowc' function is used.
If the next multibyte character corresponds to the NUL wide
character, the return value of the function is 0 and the state
object is afterwards in the initial state. If the next N or fewer
bytes form a correct multibyte character, the return value is the
number of bytes starting from S that form the multibyte character.
The conversion state is updated according to the bytes consumed in
the conversion. In both cases the wide character (either the
`L'\0'' or the one found in the conversion) is stored in the
string pointed to by PWC if PWC is not null.
If the first N bytes of the multibyte string possibly form a valid
multibyte character but there are more than N bytes needed to
complete it, the return value of the function is `(size_t) -2' and
no value is stored. Please note that this can happen even if N
has a value greater than or equal to `MB_CUR_MAX' since the input
might contain redundant shift sequences.
If the first `n' bytes of the multibyte string cannot possibly form
a valid multibyte character, no value is stored, the global
variable `errno' is set to the value `EILSEQ', and the function
returns `(size_t) -1'. The conversion state is afterwards
undefined.
`mbrtowc' was introduced in Amendment 1 to ISO C90 and is declared
in `wchar.h'.
Use of `mbrtowc' is straightforward. A function that copies a
multibyte string into a wide character string while at the same time
converting all lowercase characters into uppercase could look like this
(this is not the final version, just an example; it has no error
checking, and sometimes leaks memory):
wchar_t *
mbstouwcs (const char *s)
{
size_t len = strlen (s);
wchar_t *result = malloc ((len + 1) * sizeof (wchar_t));
wchar_t *wcp = result;
wchar_t tmp[1];
mbstate_t state;
size_t nbytes;
memset (&state, '\0', sizeof (state));
while ((nbytes = mbrtowc (tmp, s, len, &state)) > 0)
{
if (nbytes >= (size_t) -2)
/* Invalid input string. */
return NULL;
*wcp++ = towupper (tmp[0]);
len -= nbytes;
s += nbytes;
}
return result;
}
The use of `mbrtowc' should be clear. A single wide character is
stored in `TMP[0]', and the number of consumed bytes is stored in the
variable NBYTES. If the conversion is successful, the uppercase
variant of the wide character is stored in the RESULT array and the
pointer to the input string and the number of available bytes is
adjusted.
The only non-obvious thing about `mbrtowc' might be the way memory
is allocated for the result. The above code uses the fact that there
can never be more wide characters in the converted results than there
are bytes in the multibyte input string. This method yields a
pessimistic guess about the size of the result, and if many wide
character strings have to be constructed this way or if the strings are
long, the extra memory required to be allocated because the input
string contains multibyte characters might be significant. The
allocated memory block can be resized to the correct size before
returning it, but a better solution might be to allocate just the right
amount of space for the result right away. Unfortunately there is no
function to compute the length of the wide character string directly
from the multibyte string. There is, however, a function that does
part of the work.
-- Function: size_t mbrlen (const char *restrict S, size_t N,
mbstate_t *PS)
Preliminary: | MT-Unsafe race:mbrlen/!ps | AS-Unsafe corrupt heap
lock dlopen | AC-Unsafe corrupt lock mem fd | *Note POSIX Safety
Concepts::.
The `mbrlen' function ("multibyte restartable length") computes
the number of at most N bytes starting at S, which form the next
valid and complete multibyte character.
If the next multibyte character corresponds to the NUL wide
character, the return value is 0. If the next N bytes form a valid
multibyte character, the number of bytes belonging to this
multibyte character byte sequence is returned.
If the first N bytes possibly form a valid multibyte character but
the character is incomplete, the return value is `(size_t) -2'.
Otherwise the multibyte character sequence is invalid and the
return value is `(size_t) -1'.
The multibyte sequence is interpreted in the state represented by
the object pointed to by PS. If PS is a null pointer, a state
object local to `mbrlen' is used.
`mbrlen' was introduced in Amendment 1 to ISO C90 and is declared
in `wchar.h'.
The attentive reader now will note that `mbrlen' can be implemented
as
mbrtowc (NULL, s, n, ps != NULL ? ps : &internal)
This is true and in fact is mentioned in the official specification.
How can this function be used to determine the length of the wide
character string created from a multibyte character string? It is not
directly usable, but we can define a function `mbslen' using it:
size_t
mbslen (const char *s)
{
mbstate_t state;
size_t result = 0;
size_t nbytes;
memset (&state, '\0', sizeof (state));
while ((nbytes = mbrlen (s, MB_LEN_MAX, &state)) > 0)
{
if (nbytes >= (size_t) -2)
/* Something is wrong. */
return (size_t) -1;
s += nbytes;
++result;
}
return result;
}
This function simply calls `mbrlen' for each multibyte character in
the string and counts the number of function calls. Please note that
we here use `MB_LEN_MAX' as the size argument in the `mbrlen' call.
This is acceptable since a) this value is larger than the length of the
longest multibyte character sequence and b) we know that the string S
ends with a NUL byte, which cannot be part of any other multibyte
character sequence but the one representing the NUL wide character.
Therefore, the `mbrlen' function will never read invalid memory.
Now that this function is available (just to make this clear, this
function is _not_ part of the GNU C Library) we can compute the number
of wide character required to store the converted multibyte character
string S using
wcs_bytes = (mbslen (s) + 1) * sizeof (wchar_t);
Please note that the `mbslen' function is quite inefficient. The
implementation of `mbstouwcs' with `mbslen' would have to perform the
conversion of the multibyte character input string twice, and this
conversion might be quite expensive. So it is necessary to think about
the consequences of using the easier but imprecise method before doing
the work twice.
-- Function: size_t wcrtomb (char *restrict S, wchar_t WC, mbstate_t
*restrict PS)
Preliminary: | MT-Unsafe race:wcrtomb/!ps | AS-Unsafe corrupt heap
lock dlopen | AC-Unsafe corrupt lock mem fd | *Note POSIX Safety
Concepts::.
The `wcrtomb' function ("wide character restartable to multibyte")
converts a single wide character into a multibyte string
corresponding to that wide character.
If S is a null pointer, the function resets the state stored in
the objects pointed to by PS (or the internal `mbstate_t' object)
to the initial state. This can also be achieved by a call like
this:
wcrtombs (temp_buf, L'\0', ps)
since, if S is a null pointer, `wcrtomb' performs as if it writes
into an internal buffer, which is guaranteed to be large enough.
If WC is the NUL wide character, `wcrtomb' emits, if necessary, a
shift sequence to get the state PS into the initial state followed
by a single NUL byte, which is stored in the string S.
Otherwise a byte sequence (possibly including shift sequences) is
written into the string S. This only happens if WC is a valid wide
character (i.e., it has a multibyte representation in the
character set selected by locale of the `LC_CTYPE' category). If
WC is no valid wide character, nothing is stored in the strings S,
`errno' is set to `EILSEQ', the conversion state in PS is
undefined and the return value is `(size_t) -1'.
If no error occurred the function returns the number of bytes
stored in the string S. This includes all bytes representing shift
sequences.
One word about the interface of the function: there is no parameter
specifying the length of the array S. Instead the function
assumes that there are at least `MB_CUR_MAX' bytes available since
this is the maximum length of any byte sequence representing a
single character. So the caller has to make sure that there is
enough space available, otherwise buffer overruns can occur.
`wcrtomb' was introduced in Amendment 1 to ISO C90 and is declared
in `wchar.h'.
Using `wcrtomb' is as easy as using `mbrtowc'. The following
example appends a wide character string to a multibyte character string.
Again, the code is not really useful (or correct), it is simply here to
demonstrate the use and some problems.
char *
mbscatwcs (char *s, size_t len, const wchar_t *ws)
{
mbstate_t state;
/* Find the end of the existing string. */
char *wp = strchr (s, '\0');
len -= wp - s;
memset (&state, '\0', sizeof (state));
do
{
size_t nbytes;
if (len < MB_CUR_LEN)
{
/* We cannot guarantee that the next
character fits into the buffer, so
return an error. */
errno = E2BIG;
return NULL;
}
nbytes = wcrtomb (wp, *ws, &state);
if (nbytes == (size_t) -1)
/* Error in the conversion. */
return NULL;
len -= nbytes;
wp += nbytes;
}
while (*ws++ != L'\0');
return s;
}
First the function has to find the end of the string currently in the
array S. The `strchr' call does this very efficiently since a
requirement for multibyte character representations is that the NUL byte
is never used except to represent itself (and in this context, the end
of the string).
After initializing the state object the loop is entered where the
first task is to make sure there is enough room in the array S. We
abort if there are not at least `MB_CUR_LEN' bytes available. This is
not always optimal but we have no other choice. We might have less
than `MB_CUR_LEN' bytes available but the next multibyte character
might also be only one byte long. At the time the `wcrtomb' call
returns it is too late to decide whether the buffer was large enough.
If this solution is unsuitable, there is a very slow but more accurate
solution.
...
if (len < MB_CUR_LEN)
{
mbstate_t temp_state;
memcpy (&temp_state, &state, sizeof (state));
if (wcrtomb (NULL, *ws, &temp_state) > len)
{
/* We cannot guarantee that the next
character fits into the buffer, so
return an error. */
errno = E2BIG;
return NULL;
}
}
...
Here we perform the conversion that might overflow the buffer so that
we are afterwards in the position to make an exact decision about the
buffer size. Please note the `NULL' argument for the destination
buffer in the new `wcrtomb' call; since we are not interested in the
converted text at this point, this is a nice way to express this. The
most unusual thing about this piece of code certainly is the duplication
of the conversion state object, but if a change of the state is
necessary to emit the next multibyte character, we want to have the
same shift state change performed in the real conversion. Therefore,
we have to preserve the initial shift state information.
There are certainly many more and even better solutions to this
problem. This example is only provided for educational purposes.

File: libc.info, Node: Converting Strings, Next: Multibyte Conversion Example, Prev: Converting a Character, Up: Restartable multibyte conversion
6.3.4 Converting Multibyte and Wide Character Strings
-----------------------------------------------------
The functions described in the previous section only convert a single
character at a time. Most operations to be performed in real-world
programs include strings and therefore the ISO C standard also defines
conversions on entire strings. However, the defined set of functions
is quite limited; therefore, the GNU C Library contains a few
extensions that can help in some important situations.
-- Function: size_t mbsrtowcs (wchar_t *restrict DST, const char
**restrict SRC, size_t LEN, mbstate_t *restrict PS)
Preliminary: | MT-Unsafe race:mbsrtowcs/!ps | AS-Unsafe corrupt
heap lock dlopen | AC-Unsafe corrupt lock mem fd | *Note POSIX
Safety Concepts::.
The `mbsrtowcs' function ("multibyte string restartable to wide
character string") converts a NUL-terminated multibyte character
string at `*SRC' into an equivalent wide character string,
including the NUL wide character at the end. The conversion is
started using the state information from the object pointed to by
PS or from an internal object of `mbsrtowcs' if PS is a null
pointer. Before returning, the state object is updated to match
the state after the last converted character. The state is the
initial state if the terminating NUL byte is reached and converted.
If DST is not a null pointer, the result is stored in the array
pointed to by DST; otherwise, the conversion result is not
available since it is stored in an internal buffer.
If LEN wide characters are stored in the array DST before reaching
the end of the input string, the conversion stops and LEN is
returned. If DST is a null pointer, LEN is never checked.
Another reason for a premature return from the function call is if
the input string contains an invalid multibyte sequence. In this
case the global variable `errno' is set to `EILSEQ' and the
function returns `(size_t) -1'.
In all other cases the function returns the number of wide
characters converted during this call. If DST is not null,
`mbsrtowcs' stores in the pointer pointed to by SRC either a null
pointer (if the NUL byte in the input string was reached) or the
address of the byte following the last converted multibyte
character.
`mbsrtowcs' was introduced in Amendment 1 to ISO C90 and is
declared in `wchar.h'.
The definition of the `mbsrtowcs' function has one important
limitation. The requirement that DST has to be a NUL-terminated string
provides problems if one wants to convert buffers with text. A buffer
is normally no collection of NUL-terminated strings but instead a
continuous collection of lines, separated by newline characters. Now
assume that a function to convert one line from a buffer is needed.
Since the line is not NUL-terminated, the source pointer cannot
directly point into the unmodified text buffer. This means, either one
inserts the NUL byte at the appropriate place for the time of the
`mbsrtowcs' function call (which is not doable for a read-only buffer
or in a multi-threaded application) or one copies the line in an extra
buffer where it can be terminated by a NUL byte. Note that it is not
in general possible to limit the number of characters to convert by
setting the parameter LEN to any specific value. Since it is not known
how many bytes each multibyte character sequence is in length, one can
only guess.
There is still a problem with the method of NUL-terminating a line
right after the newline character, which could lead to very strange
results. As said in the description of the `mbsrtowcs' function above
the conversion state is guaranteed to be in the initial shift state
after processing the NUL byte at the end of the input string. But this
NUL byte is not really part of the text (i.e., the conversion state
after the newline in the original text could be something different
than the initial shift state and therefore the first character of the
next line is encoded using this state). But the state in question is
never accessible to the user since the conversion stops after the NUL
byte (which resets the state). Most stateful character sets in use
today require that the shift state after a newline be the initial
state-but this is not a strict guarantee. Therefore, simply
NUL-terminating a piece of a running text is not always an adequate
solution and, therefore, should never be used in generally used code.
The generic conversion interface (*note Generic Charset Conversion::)
does not have this limitation (it simply works on buffers, not
strings), and the GNU C Library contains a set of functions that take
additional parameters specifying the maximal number of bytes that are
consumed from the input string. This way the problem of `mbsrtowcs''s
example above could be solved by determining the line length and
passing this length to the function.
-- Function: size_t wcsrtombs (char *restrict DST, const wchar_t
**restrict SRC, size_t LEN, mbstate_t *restrict PS)
Preliminary: | MT-Unsafe race:wcsrtombs/!ps | AS-Unsafe corrupt
heap lock dlopen | AC-Unsafe corrupt lock mem fd | *Note POSIX
Safety Concepts::.
The `wcsrtombs' function ("wide character string restartable to
multibyte string") converts the NUL-terminated wide character
string at `*SRC' into an equivalent multibyte character string and
stores the result in the array pointed to by DST. The NUL wide
character is also converted. The conversion starts in the state
described in the object pointed to by PS or by a state object
locally to `wcsrtombs' in case PS is a null pointer. If DST is a
null pointer, the conversion is performed as usual but the result
is not available. If all characters of the input string were
successfully converted and if DST is not a null pointer, the
pointer pointed to by SRC gets assigned a null pointer.
If one of the wide characters in the input string has no valid
multibyte character equivalent, the conversion stops early, sets
the global variable `errno' to `EILSEQ', and returns `(size_t) -1'.
Another reason for a premature stop is if DST is not a null
pointer and the next converted character would require more than
LEN bytes in total to the array DST. In this case (and if DEST is
not a null pointer) the pointer pointed to by SRC is assigned a
value pointing to the wide character right after the last one
successfully converted.
Except in the case of an encoding error the return value of the
`wcsrtombs' function is the number of bytes in all the multibyte
character sequences stored in DST. Before returning the state in
the object pointed to by PS (or the internal object in case PS is
a null pointer) is updated to reflect the state after the last
conversion. The state is the initial shift state in case the
terminating NUL wide character was converted.
The `wcsrtombs' function was introduced in Amendment 1 to ISO C90
and is declared in `wchar.h'.
The restriction mentioned above for the `mbsrtowcs' function applies
here also. There is no possibility of directly controlling the number
of input characters. One has to place the NUL wide character at the
correct place or control the consumed input indirectly via the
available output array size (the LEN parameter).
-- Function: size_t mbsnrtowcs (wchar_t *restrict DST, const char
**restrict SRC, size_t NMC, size_t LEN, mbstate_t *restrict
PS)
Preliminary: | MT-Unsafe race:mbsnrtowcs/!ps | AS-Unsafe corrupt
heap lock dlopen | AC-Unsafe corrupt lock mem fd | *Note POSIX
Safety Concepts::.
The `mbsnrtowcs' function is very similar to the `mbsrtowcs'
function. All the parameters are the same except for NMC, which is
new. The return value is the same as for `mbsrtowcs'.
This new parameter specifies how many bytes at most can be used
from the multibyte character string. In other words, the
multibyte character string `*SRC' need not be NUL-terminated. But
if a NUL byte is found within the NMC first bytes of the string,
the conversion stops here.
This function is a GNU extension. It is meant to work around the
problems mentioned above. Now it is possible to convert a buffer
with multibyte character text piece for piece without having to
care about inserting NUL bytes and the effect of NUL bytes on the
conversion state.
A function to convert a multibyte string into a wide character string
and display it could be written like this (this is not a really useful
example):
void
showmbs (const char *src, FILE *fp)
{
mbstate_t state;
int cnt = 0;
memset (&state, '\0', sizeof (state));
while (1)
{
wchar_t linebuf[100];
const char *endp = strchr (src, '\n');
size_t n;
/* Exit if there is no more line. */
if (endp == NULL)
break;
n = mbsnrtowcs (linebuf, &src, endp - src, 99, &state);
linebuf[n] = L'\0';
fprintf (fp, "line %d: \"%S\"\n", linebuf);
}
}
There is no problem with the state after a call to `mbsnrtowcs'.
Since we don't insert characters in the strings that were not in there
right from the beginning and we use STATE only for the conversion of
the given buffer, there is no problem with altering the state.
-- Function: size_t wcsnrtombs (char *restrict DST, const wchar_t
**restrict SRC, size_t NWC, size_t LEN, mbstate_t *restrict
PS)
Preliminary: | MT-Unsafe race:wcsnrtombs/!ps | AS-Unsafe corrupt
heap lock dlopen | AC-Unsafe corrupt lock mem fd | *Note POSIX
Safety Concepts::.
The `wcsnrtombs' function implements the conversion from wide
character strings to multibyte character strings. It is similar to
`wcsrtombs' but, just like `mbsnrtowcs', it takes an extra
parameter, which specifies the length of the input string.
No more than NWC wide characters from the input string `*SRC' are
converted. If the input string contains a NUL wide character in
the first NWC characters, the conversion stops at this place.
The `wcsnrtombs' function is a GNU extension and just like
`mbsnrtowcs' helps in situations where no NUL-terminated input
strings are available.

File: libc.info, Node: Multibyte Conversion Example, Prev: Converting Strings, Up: Restartable multibyte conversion
6.3.5 A Complete Multibyte Conversion Example
---------------------------------------------
The example programs given in the last sections are only brief and do
not contain all the error checking, etc. Presented here is a complete
and documented example. It features the `mbrtowc' function but it
should be easy to derive versions using the other functions.
int
file_mbsrtowcs (int input, int output)
{
/* Note the use of `MB_LEN_MAX'.
`MB_CUR_MAX' cannot portably be used here. */
char buffer[BUFSIZ + MB_LEN_MAX];
mbstate_t state;
int filled = 0;
int eof = 0;
/* Initialize the state. */
memset (&state, '\0', sizeof (state));
while (!eof)
{
ssize_t nread;
ssize_t nwrite;
char *inp = buffer;
wchar_t outbuf[BUFSIZ];
wchar_t *outp = outbuf;
/* Fill up the buffer from the input file. */
nread = read (input, buffer + filled, BUFSIZ);
if (nread < 0)
{
perror ("read");
return 0;
}
/* If we reach end of file, make a note to read no more. */
if (nread == 0)
eof = 1;
/* `filled' is now the number of bytes in `buffer'. */
filled += nread;
/* Convert those bytes to wide characters-as many as we can. */
while (1)
{
size_t thislen = mbrtowc (outp, inp, filled, &state);
/* Stop converting at invalid character;
this can mean we have read just the first part
of a valid character. */
if (thislen == (size_t) -1)
break;
/* We want to handle embedded NUL bytes
but the return value is 0. Correct this. */
if (thislen == 0)
thislen = 1;
/* Advance past this character. */
inp += thislen;
filled -= thislen;
++outp;
}
/* Write the wide characters we just made. */
nwrite = write (output, outbuf,
(outp - outbuf) * sizeof (wchar_t));
if (nwrite < 0)
{
perror ("write");
return 0;
}
/* See if we have a _real_ invalid character. */
if ((eof && filled > 0) || filled >= MB_CUR_MAX)
{
error (0, 0, "invalid multibyte character");
return 0;
}
/* If any characters must be carried forward,
put them at the beginning of `buffer'. */
if (filled > 0)
memmove (buffer, inp, filled);
}
return 1;
}

File: libc.info, Node: Non-reentrant Conversion, Next: Generic Charset Conversion, Prev: Restartable multibyte conversion, Up: Character Set Handling
6.4 Non-reentrant Conversion Function
=====================================
The functions described in the previous chapter are defined in
Amendment 1 to ISO C90, but the original ISO C90 standard also
contained functions for character set conversion. The reason that
these original functions are not described first is that they are almost
entirely useless.
The problem is that all the conversion functions described in the
original ISO C90 use a local state. Using a local state implies that
multiple conversions at the same time (not only when using threads)
cannot be done, and that you cannot first convert single characters and
then strings since you cannot tell the conversion functions which state
to use.
These original functions are therefore usable only in a very limited
set of situations. One must complete converting the entire string
before starting a new one, and each string/text must be converted with
the same function (there is no problem with the library itself; it is
guaranteed that no library function changes the state of any of these
functions). *For the above reasons it is highly requested that the
functions described in the previous section be used in place of
non-reentrant conversion functions.*
* Menu:
* Non-reentrant Character Conversion:: Non-reentrant Conversion of Single
Characters.
* Non-reentrant String Conversion:: Non-reentrant Conversion of Strings.
* Shift State:: States in Non-reentrant Functions.

File: libc.info, Node: Non-reentrant Character Conversion, Next: Non-reentrant String Conversion, Up: Non-reentrant Conversion
6.4.1 Non-reentrant Conversion of Single Characters
---------------------------------------------------
-- Function: int mbtowc (wchar_t *restrict RESULT, const char
*restrict STRING, size_t SIZE)
Preliminary: | MT-Unsafe race | AS-Unsafe corrupt heap lock dlopen
| AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `mbtowc' ("multibyte to wide character") function when called
with non-null STRING converts the first multibyte character
beginning at STRING to its corresponding wide character code. It
stores the result in `*RESULT'.
`mbtowc' never examines more than SIZE bytes. (The idea is to
supply for SIZE the number of bytes of data you have in hand.)
`mbtowc' with non-null STRING distinguishes three possibilities:
the first SIZE bytes at STRING start with valid multibyte
characters, they start with an invalid byte sequence or just part
of a character, or STRING points to an empty string (a null
character).
For a valid multibyte character, `mbtowc' converts it to a wide
character and stores that in `*RESULT', and returns the number of
bytes in that character (always at least 1 and never more than
SIZE).
For an invalid byte sequence, `mbtowc' returns -1. For an empty
string, it returns 0, also storing `'\0'' in `*RESULT'.
If the multibyte character code uses shift characters, then
`mbtowc' maintains and updates a shift state as it scans. If you
call `mbtowc' with a null pointer for STRING, that initializes the
shift state to its standard initial value. It also returns
nonzero if the multibyte character code in use actually has a
shift state. *Note Shift State::.
-- Function: int wctomb (char *STRING, wchar_t WCHAR)
Preliminary: | MT-Unsafe race | AS-Unsafe corrupt heap lock dlopen
| AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `wctomb' ("wide character to multibyte") function converts the
wide character code WCHAR to its corresponding multibyte character
sequence, and stores the result in bytes starting at STRING. At
most `MB_CUR_MAX' characters are stored.
`wctomb' with non-null STRING distinguishes three possibilities
for WCHAR: a valid wide character code (one that can be translated
to a multibyte character), an invalid code, and `L'\0''.
Given a valid code, `wctomb' converts it to a multibyte character,
storing the bytes starting at STRING. Then it returns the number
of bytes in that character (always at least 1 and never more than
`MB_CUR_MAX').
If WCHAR is an invalid wide character code, `wctomb' returns -1.
If WCHAR is `L'\0'', it returns `0', also storing `'\0'' in
`*STRING'.
If the multibyte character code uses shift characters, then
`wctomb' maintains and updates a shift state as it scans. If you
call `wctomb' with a null pointer for STRING, that initializes the
shift state to its standard initial value. It also returns
nonzero if the multibyte character code in use actually has a
shift state. *Note Shift State::.
Calling this function with a WCHAR argument of zero when STRING is
not null has the side-effect of reinitializing the stored shift
state _as well as_ storing the multibyte character `'\0'' and
returning 0.
Similar to `mbrlen' there is also a non-reentrant function that
computes the length of a multibyte character. It can be defined in
terms of `mbtowc'.
-- Function: int mblen (const char *STRING, size_t SIZE)
Preliminary: | MT-Unsafe race | AS-Unsafe corrupt heap lock dlopen
| AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `mblen' function with a non-null STRING argument returns the
number of bytes that make up the multibyte character beginning at
STRING, never examining more than SIZE bytes. (The idea is to
supply for SIZE the number of bytes of data you have in hand.)
The return value of `mblen' distinguishes three possibilities: the
first SIZE bytes at STRING start with valid multibyte characters,
they start with an invalid byte sequence or just part of a
character, or STRING points to an empty string (a null character).
For a valid multibyte character, `mblen' returns the number of
bytes in that character (always at least `1' and never more than
SIZE). For an invalid byte sequence, `mblen' returns -1. For an
empty string, it returns 0.
If the multibyte character code uses shift characters, then `mblen'
maintains and updates a shift state as it scans. If you call
`mblen' with a null pointer for STRING, that initializes the shift
state to its standard initial value. It also returns a nonzero
value if the multibyte character code in use actually has a shift
state. *Note Shift State::.
The function `mblen' is declared in `stdlib.h'.

File: libc.info, Node: Non-reentrant String Conversion, Next: Shift State, Prev: Non-reentrant Character Conversion, Up: Non-reentrant Conversion
6.4.2 Non-reentrant Conversion of Strings
-----------------------------------------
For convenience the ISO C90 standard also defines functions to convert
entire strings instead of single characters. These functions suffer
from the same problems as their reentrant counterparts from Amendment 1
to ISO C90; see *note Converting Strings::.
-- Function: size_t mbstowcs (wchar_t *WSTRING, const char *STRING,
size_t SIZE)
Preliminary: | MT-Safe | AS-Unsafe corrupt heap lock dlopen |
AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `mbstowcs' ("multibyte string to wide character string")
function converts the null-terminated string of multibyte
characters STRING to an array of wide character codes, storing not
more than SIZE wide characters into the array beginning at WSTRING.
The terminating null character counts towards the size, so if SIZE
is less than the actual number of wide characters resulting from
STRING, no terminating null character is stored.
The conversion of characters from STRING begins in the initial
shift state.
If an invalid multibyte character sequence is found, the `mbstowcs'
function returns a value of -1. Otherwise, it returns the number
of wide characters stored in the array WSTRING. This number does
not include the terminating null character, which is present if the
number is less than SIZE.
Here is an example showing how to convert a string of multibyte
characters, allocating enough space for the result.
wchar_t *
mbstowcs_alloc (const char *string)
{
size_t size = strlen (string) + 1;
wchar_t *buf = xmalloc (size * sizeof (wchar_t));
size = mbstowcs (buf, string, size);
if (size == (size_t) -1)
return NULL;
buf = xrealloc (buf, (size + 1) * sizeof (wchar_t));
return buf;
}
-- Function: size_t wcstombs (char *STRING, const wchar_t *WSTRING,
size_t SIZE)
Preliminary: | MT-Safe | AS-Unsafe corrupt heap lock dlopen |
AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `wcstombs' ("wide character string to multibyte string")
function converts the null-terminated wide character array WSTRING
into a string containing multibyte characters, storing not more
than SIZE bytes starting at STRING, followed by a terminating null
character if there is room. The conversion of characters begins in
the initial shift state.
The terminating null character counts towards the size, so if SIZE
is less than or equal to the number of bytes needed in WSTRING, no
terminating null character is stored.
If a code that does not correspond to a valid multibyte character
is found, the `wcstombs' function returns a value of -1.
Otherwise, the return value is the number of bytes stored in the
array STRING. This number does not include the terminating null
character, which is present if the number is less than SIZE.

File: libc.info, Node: Shift State, Prev: Non-reentrant String Conversion, Up: Non-reentrant Conversion
6.4.3 States in Non-reentrant Functions
---------------------------------------
In some multibyte character codes, the _meaning_ of any particular byte
sequence is not fixed; it depends on what other sequences have come
earlier in the same string. Typically there are just a few sequences
that can change the meaning of other sequences; these few are called
"shift sequences" and we say that they set the "shift state" for other
sequences that follow.
To illustrate shift state and shift sequences, suppose we decide that
the sequence `0200' (just one byte) enters Japanese mode, in which
pairs of bytes in the range from `0240' to `0377' are single
characters, while `0201' enters Latin-1 mode, in which single bytes in
the range from `0240' to `0377' are characters, and interpreted
according to the ISO Latin-1 character set. This is a multibyte code
that has two alternative shift states ("Japanese mode" and "Latin-1
mode"), and two shift sequences that specify particular shift states.
When the multibyte character code in use has shift states, then
`mblen', `mbtowc', and `wctomb' must maintain and update the current
shift state as they scan the string. To make this work properly, you
must follow these rules:
* Before starting to scan a string, call the function with a null
pointer for the multibyte character address--for example, `mblen
(NULL, 0)'. This initializes the shift state to its standard
initial value.
* Scan the string one character at a time, in order. Do not "back
up" and rescan characters already scanned, and do not intersperse
the processing of different strings.
Here is an example of using `mblen' following these rules:
void
scan_string (char *s)
{
int length = strlen (s);
/* Initialize shift state. */
mblen (NULL, 0);
while (1)
{
int thischar = mblen (s, length);
/* Deal with end of string and invalid characters. */
if (thischar == 0)
break;
if (thischar == -1)
{
error ("invalid multibyte character");
break;
}
/* Advance past this character. */
s += thischar;
length -= thischar;
}
}
The functions `mblen', `mbtowc' and `wctomb' are not reentrant when
using a multibyte code that uses a shift state. However, no other
library functions call these functions, so you don't have to worry that
the shift state will be changed mysteriously.

File: libc.info, Node: Generic Charset Conversion, Prev: Non-reentrant Conversion, Up: Character Set Handling
6.5 Generic Charset Conversion
==============================
The conversion functions mentioned so far in this chapter all had in
common that they operate on character sets that are not directly
specified by the functions. The multibyte encoding used is specified by
the currently selected locale for the `LC_CTYPE' category. The wide
character set is fixed by the implementation (in the case of the GNU C
Library it is always UCS-4 encoded ISO 10646.
This has of course several problems when it comes to general
character conversion:
* For every conversion where neither the source nor the destination
character set is the character set of the locale for the `LC_CTYPE'
category, one has to change the `LC_CTYPE' locale using
`setlocale'.
Changing the `LC_CTYPE' locale introduces major problems for the
rest of the programs since several more functions (e.g., the
character classification functions, *note Classification of
Characters::) use the `LC_CTYPE' category.
* Parallel conversions to and from different character sets are not
possible since the `LC_CTYPE' selection is global and shared by all
threads.
* If neither the source nor the destination character set is the
character set used for `wchar_t' representation, there is at least
a two-step process necessary to convert a text using the functions
above. One would have to select the source character set as the
multibyte encoding, convert the text into a `wchar_t' text, select
the destination character set as the multibyte encoding, and
convert the wide character text to the multibyte (= destination)
character set.
Even if this is possible (which is not guaranteed) it is a very
tiring work. Plus it suffers from the other two raised points
even more due to the steady changing of the locale.
The XPG2 standard defines a completely new set of functions, which
has none of these limitations. They are not at all coupled to the
selected locales, and they have no constraints on the character sets
selected for source and destination. Only the set of available
conversions limits them. The standard does not specify that any
conversion at all must be available. Such availability is a measure of
the quality of the implementation.
In the following text first the interface to `iconv' and then the
conversion function, will be described. Comparisons with other
implementations will show what obstacles stand in the way of portable
applications. Finally, the implementation is described in so far as
might interest the advanced user who wants to extend conversion
capabilities.
* Menu:
* Generic Conversion Interface:: Generic Character Set Conversion Interface.
* iconv Examples:: A complete `iconv' example.
* Other iconv Implementations:: Some Details about other `iconv'
Implementations.
* glibc iconv Implementation:: The `iconv' Implementation in the GNU C
library.

File: libc.info, Node: Generic Conversion Interface, Next: iconv Examples, Up: Generic Charset Conversion
6.5.1 Generic Character Set Conversion Interface
------------------------------------------------
This set of functions follows the traditional cycle of using a resource:
open-use-close. The interface consists of three functions, each of
which implements one step.
Before the interfaces are described it is necessary to introduce a
data type. Just like other open-use-close interfaces the functions
introduced here work using handles and the `iconv.h' header defines a
special type for the handles used.
-- Data Type: iconv_t
This data type is an abstract type defined in `iconv.h'. The user
must not assume anything about the definition of this type; it
must be completely opaque.
Objects of this type can get assigned handles for the conversions
using the `iconv' functions. The objects themselves need not be
freed, but the conversions for which the handles stand for have to.
The first step is the function to create a handle.
-- Function: iconv_t iconv_open (const char *TOCODE, const char
*FROMCODE)
Preliminary: | MT-Safe locale | AS-Unsafe corrupt heap lock dlopen
| AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The `iconv_open' function has to be used before starting a
conversion. The two parameters this function takes determine the
source and destination character set for the conversion, and if the
implementation has the possibility to perform such a conversion,
the function returns a handle.
If the wanted conversion is not available, the `iconv_open'
function returns `(iconv_t) -1'. In this case the global variable
`errno' can have the following values:
`EMFILE'
The process already has `OPEN_MAX' file descriptors open.
`ENFILE'
The system limit of open file is reached.
`ENOMEM'
Not enough memory to carry out the operation.
`EINVAL'
The conversion from FROMCODE to TOCODE is not supported.
It is not possible to use the same descriptor in different threads
to perform independent conversions. The data structures associated
with the descriptor include information about the conversion state.
This must not be messed up by using it in different conversions.
An `iconv' descriptor is like a file descriptor as for every use a
new descriptor must be created. The descriptor does not stand for
all of the conversions from FROMSET to TOSET.
The GNU C Library implementation of `iconv_open' has one
significant extension to other implementations. To ease the
extension of the set of available conversions, the implementation
allows storing the necessary files with data and code in an
arbitrary number of directories. How this extension must be
written will be explained below (*note glibc iconv
Implementation::). Here it is only important to say that all
directories mentioned in the `GCONV_PATH' environment variable are
considered only if they contain a file `gconv-modules'. These
directories need not necessarily be created by the system
administrator. In fact, this extension is introduced to help users
writing and using their own, new conversions. Of course, this
does not work for security reasons in SUID binaries; in this case
only the system directory is considered and this normally is
`PREFIX/lib/gconv'. The `GCONV_PATH' environment variable is
examined exactly once at the first call of the `iconv_open'
function. Later modifications of the variable have no effect.
The `iconv_open' function was introduced early in the X/Open
Portability Guide, version 2. It is supported by all commercial
Unices as it is required for the Unix branding. However, the
quality and completeness of the implementation varies widely. The
`iconv_open' function is declared in `iconv.h'.
The `iconv' implementation can associate large data structure with
the handle returned by `iconv_open'. Therefore, it is crucial to free
all the resources once all conversions are carried out and the
conversion is not needed anymore.
-- Function: int iconv_close (iconv_t CD)
Preliminary: | MT-Safe | AS-Unsafe corrupt heap lock dlopen |
AC-Unsafe corrupt lock mem | *Note POSIX Safety Concepts::.
The `iconv_close' function frees all resources associated with the
handle CD, which must have been returned by a successful call to
the `iconv_open' function.
If the function call was successful the return value is 0.
Otherwise it is -1 and `errno' is set appropriately. Defined
error are:
`EBADF'
The conversion descriptor is invalid.
The `iconv_close' function was introduced together with the rest
of the `iconv' functions in XPG2 and is declared in `iconv.h'.
The standard defines only one actual conversion function. This has,
therefore, the most general interface: it allows conversion from one
buffer to another. Conversion from a file to a buffer, vice versa, or
even file to file can be implemented on top of it.
-- Function: size_t iconv (iconv_t CD, char **INBUF, size_t
*INBYTESLEFT, char **OUTBUF, size_t *OUTBYTESLEFT)
Preliminary: | MT-Safe race:cd | AS-Safe | AC-Unsafe corrupt |
*Note POSIX Safety Concepts::.
The `iconv' function converts the text in the input buffer
according to the rules associated with the descriptor CD and
stores the result in the output buffer. It is possible to call the
function for the same text several times in a row since for
stateful character sets the necessary state information is kept in
the data structures associated with the descriptor.
The input buffer is specified by `*INBUF' and it contains
`*INBYTESLEFT' bytes. The extra indirection is necessary for
communicating the used input back to the caller (see below). It is
important to note that the buffer pointer is of type `char' and the
length is measured in bytes even if the input text is encoded in
wide characters.
The output buffer is specified in a similar way. `*OUTBUF' points
to the beginning of the buffer with at least `*OUTBYTESLEFT' bytes
room for the result. The buffer pointer again is of type `char'
and the length is measured in bytes. If OUTBUF or `*OUTBUF' is a
null pointer, the conversion is performed but no output is
available.
If INBUF is a null pointer, the `iconv' function performs the
necessary action to put the state of the conversion into the
initial state. This is obviously a no-op for non-stateful
encodings, but if the encoding has a state, such a function call
might put some byte sequences in the output buffer, which perform
the necessary state changes. The next call with INBUF not being a
null pointer then simply goes on from the initial state. It is
important that the programmer never makes any assumption as to
whether the conversion has to deal with states. Even if the input
and output character sets are not stateful, the implementation
might still have to keep states. This is due to the
implementation chosen for the GNU C Library as it is described
below. Therefore an `iconv' call to reset the state should always
be performed if some protocol requires this for the output text.
The conversion stops for one of three reasons. The first is that
all characters from the input buffer are converted. This actually
can mean two things: either all bytes from the input buffer are
consumed or there are some bytes at the end of the buffer that
possibly can form a complete character but the input is
incomplete. The second reason for a stop is that the output
buffer is full. And the third reason is that the input contains
invalid characters.
In all of these cases the buffer pointers after the last successful
conversion, for input and output buffer, are stored in INBUF and
OUTBUF, and the available room in each buffer is stored in
INBYTESLEFT and OUTBYTESLEFT.
Since the character sets selected in the `iconv_open' call can be
almost arbitrary, there can be situations where the input buffer
contains valid characters, which have no identical representation
in the output character set. The behavior in this situation is
undefined. The _current_ behavior of the GNU C Library in this
situation is to return with an error immediately. This certainly
is not the most desirable solution; therefore, future versions
will provide better ones, but they are not yet finished.
If all input from the input buffer is successfully converted and
stored in the output buffer, the function returns the number of
non-reversible conversions performed. In all other cases the
return value is `(size_t) -1' and `errno' is set appropriately.
In such cases the value pointed to by INBYTESLEFT is nonzero.
`EILSEQ'
The conversion stopped because of an invalid byte sequence in
the input. After the call, `*INBUF' points at the first byte
of the invalid byte sequence.
`E2BIG'
The conversion stopped because it ran out of space in the
output buffer.
`EINVAL'
The conversion stopped because of an incomplete byte sequence
at the end of the input buffer.
`EBADF'
The CD argument is invalid.
The `iconv' function was introduced in the XPG2 standard and is
declared in the `iconv.h' header.
The definition of the `iconv' function is quite good overall. It
provides quite flexible functionality. The only problems lie in the
boundary cases, which are incomplete byte sequences at the end of the
input buffer and invalid input. A third problem, which is not really a
design problem, is the way conversions are selected. The standard does
not say anything about the legitimate names, a minimal set of available
conversions. We will see how this negatively impacts other
implementations, as demonstrated below.

File: libc.info, Node: iconv Examples, Next: Other iconv Implementations, Prev: Generic Conversion Interface, Up: Generic Charset Conversion
6.5.2 A complete `iconv' example
--------------------------------
The example below features a solution for a common problem. Given that
one knows the internal encoding used by the system for `wchar_t'
strings, one often is in the position to read text from a file and store
it in wide character buffers. One can do this using `mbsrtowcs', but
then we run into the problems discussed above.
int
file2wcs (int fd, const char *charset, wchar_t *outbuf, size_t avail)
{
char inbuf[BUFSIZ];
size_t insize = 0;
char *wrptr = (char *) outbuf;
int result = 0;
iconv_t cd;
cd = iconv_open ("WCHAR_T", charset);
if (cd == (iconv_t) -1)
{
/* Something went wrong. */
if (errno == EINVAL)
error (0, 0, "conversion from '%s' to wchar_t not available",
charset);
else
perror ("iconv_open");
/* Terminate the output string. */
*outbuf = L'\0';
return -1;
}
while (avail > 0)
{
size_t nread;
size_t nconv;
char *inptr = inbuf;
/* Read more input. */
nread = read (fd, inbuf + insize, sizeof (inbuf) - insize);
if (nread == 0)
{
/* When we come here the file is completely read.
This still could mean there are some unused
characters in the `inbuf'. Put them back. */
if (lseek (fd, -insize, SEEK_CUR) == -1)
result = -1;
/* Now write out the byte sequence to get into the
initial state if this is necessary. */
iconv (cd, NULL, NULL, &wrptr, &avail);
break;
}
insize += nread;
/* Do the conversion. */
nconv = iconv (cd, &inptr, &insize, &wrptr, &avail);
if (nconv == (size_t) -1)
{
/* Not everything went right. It might only be
an unfinished byte sequence at the end of the
buffer. Or it is a real problem. */
if (errno == EINVAL)
/* This is harmless. Simply move the unused
bytes to the beginning of the buffer so that
they can be used in the next round. */
memmove (inbuf, inptr, insize);
else
{
/* It is a real problem. Maybe we ran out of
space in the output buffer or we have invalid
input. In any case back the file pointer to
the position of the last processed byte. */
lseek (fd, -insize, SEEK_CUR);
result = -1;
break;
}
}
}
/* Terminate the output string. */
if (avail >= sizeof (wchar_t))
*((wchar_t *) wrptr) = L'\0';
if (iconv_close (cd) != 0)
perror ("iconv_close");
return (wchar_t *) wrptr - outbuf;
}
This example shows the most important aspects of using the `iconv'
functions. It shows how successive calls to `iconv' can be used to
convert large amounts of text. The user does not have to care about
stateful encodings as the functions take care of everything.
An interesting point is the case where `iconv' returns an error and
`errno' is set to `EINVAL'. This is not really an error in the
transformation. It can happen whenever the input character set contains
byte sequences of more than one byte for some character and texts are
not processed in one piece. In this case there is a chance that a
multibyte sequence is cut. The caller can then simply read the
remainder of the takes and feed the offending bytes together with new
character from the input to `iconv' and continue the work. The
internal state kept in the descriptor is _not_ unspecified after such
an event as is the case with the conversion functions from the ISO C
standard.
The example also shows the problem of using wide character strings
with `iconv'. As explained in the description of the `iconv' function
above, the function always takes a pointer to a `char' array and the
available space is measured in bytes. In the example, the output
buffer is a wide character buffer; therefore, we use a local variable
WRPTR of type `char *', which is used in the `iconv' calls.
This looks rather innocent but can lead to problems on platforms that
have tight restriction on alignment. Therefore the caller of `iconv'
has to make sure that the pointers passed are suitable for access of
characters from the appropriate character set. Since, in the above
case, the input parameter to the function is a `wchar_t' pointer, this
is the case (unless the user violates alignment when computing the
parameter). But in other situations, especially when writing generic
functions where one does not know what type of character set one uses
and, therefore, treats text as a sequence of bytes, it might become
tricky.

File: libc.info, Node: Other iconv Implementations, Next: glibc iconv Implementation, Prev: iconv Examples, Up: Generic Charset Conversion
6.5.3 Some Details about other `iconv' Implementations
------------------------------------------------------
This is not really the place to discuss the `iconv' implementation of
other systems but it is necessary to know a bit about them to write
portable programs. The above mentioned problems with the specification
of the `iconv' functions can lead to portability issues.
The first thing to notice is that, due to the large number of
character sets in use, it is certainly not practical to encode the
conversions directly in the C library. Therefore, the conversion
information must come from files outside the C library. This is
usually done in one or both of the following ways:
* The C library contains a set of generic conversion functions that
can read the needed conversion tables and other information from
data files. These files get loaded when necessary.
This solution is problematic as it requires a great deal of effort
to apply to all character sets (potentially an infinite set). The
differences in the structure of the different character sets is so
large that many different variants of the table-processing
functions must be developed. In addition, the generic nature of
these functions make them slower than specifically implemented
functions.
* The C library only contains a framework that can dynamically load
object files and execute the conversion functions contained
therein.
This solution provides much more flexibility. The C library itself
contains only very little code and therefore reduces the general
memory footprint. Also, with a documented interface between the C
library and the loadable modules it is possible for third parties
to extend the set of available conversion modules. A drawback of
this solution is that dynamic loading must be available.
Some implementations in commercial Unices implement a mixture of
these possibilities; the majority implement only the second solution.
Using loadable modules moves the code out of the library itself and
keeps the door open for extensions and improvements, but this design is
also limiting on some platforms since not many platforms support dynamic
loading in statically linked programs. On platforms without this
capability it is therefore not possible to use this interface in
statically linked programs. The GNU C Library has, on ELF platforms, no
problems with dynamic loading in these situations; therefore, this
point is moot. The danger is that one gets acquainted with this
situation and forgets about the restrictions on other systems.
A second thing to know about other `iconv' implementations is that
the number of available conversions is often very limited. Some
implementations provide, in the standard release (not special
international or developer releases), at most 100 to 200 conversion
possibilities. This does not mean 200 different character sets are
supported; for example, conversions from one character set to a set of
10 others might count as 10 conversions. Together with the other
direction this makes 20 conversion possibilities used up by one
character set. One can imagine the thin coverage these platform
provide. Some Unix vendors even provide only a handful of conversions,
which renders them useless for almost all uses.
This directly leads to a third and probably the most problematic
point. The way the `iconv' conversion functions are implemented on all
known Unix systems and the availability of the conversion functions from
character set A to B and the conversion from B to C does _not_ imply
that the conversion from A to C is available.
This might not seem unreasonable and problematic at first, but it is
a quite big problem as one will notice shortly after hitting it. To
show the problem we assume to write a program that has to convert from
A to C. A call like
cd = iconv_open ("C", "A");
fails according to the assumption above. But what does the program do
now? The conversion is necessary; therefore, simply giving up is not
an option.
This is a nuisance. The `iconv' function should take care of this.
But how should the program proceed from here on? If it tries to convert
to character set B, first the two `iconv_open' calls
cd1 = iconv_open ("B", "A");
and
cd2 = iconv_open ("C", "B");
will succeed, but how to find B?
Unfortunately, the answer is: there is no general solution. On some
systems guessing might help. On those systems most character sets can
convert to and from UTF-8 encoded ISO 10646 or Unicode text. Beside
this only some very system-specific methods can help. Since the
conversion functions come from loadable modules and these modules must
be stored somewhere in the filesystem, one _could_ try to find them and
determine from the available file which conversions are available and
whether there is an indirect route from A to C.
This example shows one of the design errors of `iconv' mentioned
above. It should at least be possible to determine the list of
available conversion programmatically so that if `iconv_open' says
there is no such conversion, one could make sure this also is true for
indirect routes.

File: libc.info, Node: glibc iconv Implementation, Prev: Other iconv Implementations, Up: Generic Charset Conversion
6.5.4 The `iconv' Implementation in the GNU C Library
-----------------------------------------------------
After reading about the problems of `iconv' implementations in the last
section it is certainly good to note that the implementation in the GNU
C Library has none of the problems mentioned above. What follows is a
step-by-step analysis of the points raised above. The evaluation is
based on the current state of the development (as of January 1999).
The development of the `iconv' functions is not complete, but basic
functionality has solidified.
The GNU C Library's `iconv' implementation uses shared loadable
modules to implement the conversions. A very small number of
conversions are built into the library itself but these are only rather
trivial conversions.
All the benefits of loadable modules are available in the GNU C
Library implementation. This is especially appealing since the
interface is well documented (see below), and it, therefore, is easy to
write new conversion modules. The drawback of using loadable objects
is not a problem in the GNU C Library, at least on ELF systems. Since
the library is able to load shared objects even in statically linked
binaries, static linking need not be forbidden in case one wants to use
`iconv'.
The second mentioned problem is the number of supported conversions.
Currently, the GNU C Library supports more than 150 character sets. The
way the implementation is designed the number of supported conversions
is greater than 22350 (150 times 149). If any conversion from or to a
character set is missing, it can be added easily.
Particularly impressive as it may be, this high number is due to the
fact that the GNU C Library implementation of `iconv' does not have the
third problem mentioned above (i.e., whenever there is a conversion
from a character set A to B and from B to C it is always possible to
convert from A to C directly). If the `iconv_open' returns an error
and sets `errno' to `EINVAL', there is no known way, directly or
indirectly, to perform the wanted conversion.
Triangulation is achieved by providing for each character set a
conversion from and to UCS-4 encoded ISO 10646. Using ISO 10646 as an
intermediate representation it is possible to "triangulate" (i.e.,
convert with an intermediate representation).
There is no inherent requirement to provide a conversion to
ISO 10646 for a new character set, and it is also possible to provide
other conversions where neither source nor destination character set is
ISO 10646. The existing set of conversions is simply meant to cover all
conversions that might be of interest.
All currently available conversions use the triangulation method
above, making conversion run unnecessarily slow. If, for example,
somebody often needs the conversion from ISO-2022-JP to EUC-JP, a
quicker solution would involve direct conversion between the two
character sets, skipping the input to ISO 10646 first. The two
character sets of interest are much more similar to each other than to
ISO 10646.
In such a situation one easily can write a new conversion and
provide it as a better alternative. The GNU C Library `iconv'
implementation would automatically use the module implementing the
conversion if it is specified to be more efficient.
6.5.4.1 Format of `gconv-modules' files
.......................................
All information about the available conversions comes from a file named
`gconv-modules', which can be found in any of the directories along the
`GCONV_PATH'. The `gconv-modules' files are line-oriented text files,
where each of the lines has one of the following formats:
* If the first non-whitespace character is a `#' the line contains
only comments and is ignored.
* Lines starting with `alias' define an alias name for a character
set. Two more words are expected on the line. The first word
defines the alias name, and the second defines the original name
of the character set. The effect is that it is possible to use
the alias name in the FROMSET or TOSET parameters of `iconv_open'
and achieve the same result as when using the real character set
name.
This is quite important as a character set has often many different
names. There is normally an official name but this need not
correspond to the most popular name. Beside this many character
sets have special names that are somehow constructed. For
example, all character sets specified by the ISO have an alias of
the form `ISO-IR-NNN' where NNN is the registration number. This
allows programs that know about the registration number to
construct character set names and use them in `iconv_open' calls.
More on the available names and aliases follows below.
* Lines starting with `module' introduce an available conversion
module. These lines must contain three or four more words.
The first word specifies the source character set, the second word
the destination character set of conversion implemented in this
module, and the third word is the name of the loadable module.
The filename is constructed by appending the usual shared object
suffix (normally `.so') and this file is then supposed to be found
in the same directory the `gconv-modules' file is in. The last
word on the line, which is optional, is a numeric value
representing the cost of the conversion. If this word is missing,
a cost of 1 is assumed. The numeric value itself does not matter
that much; what counts are the relative values of the sums of
costs for all possible conversion paths. Below is a more precise
description of the use of the cost value.
Returning to the example above where one has written a module to
directly convert from ISO-2022-JP to EUC-JP and back. All that has to
be done is to put the new module, let its name be ISO2022JP-EUCJP.so,
in a directory and add a file `gconv-modules' with the following
content in the same directory:
module ISO-2022-JP// EUC-JP// ISO2022JP-EUCJP 1
module EUC-JP// ISO-2022-JP// ISO2022JP-EUCJP 1
To see why this is sufficient, it is necessary to understand how the
conversion used by `iconv' (and described in the descriptor) is
selected. The approach to this problem is quite simple.
At the first call of the `iconv_open' function the program reads all
available `gconv-modules' files and builds up two tables: one
containing all the known aliases and another that contains the
information about the conversions and which shared object implements
them.
6.5.4.2 Finding the conversion path in `iconv'
..............................................
The set of available conversions form a directed graph with weighted
edges. The weights on the edges are the costs specified in the
`gconv-modules' files. The `iconv_open' function uses an algorithm
suitable for search for the best path in such a graph and so constructs
a list of conversions that must be performed in succession to get the
transformation from the source to the destination character set.
Explaining why the above `gconv-modules' files allows the `iconv'
implementation to resolve the specific ISO-2022-JP to EUC-JP conversion
module instead of the conversion coming with the library itself is
straightforward. Since the latter conversion takes two steps (from
ISO-2022-JP to ISO 10646 and then from ISO 10646 to EUC-JP), the cost
is 1+1 = 2. The above `gconv-modules' file, however, specifies that
the new conversion modules can perform this conversion with only the
cost of 1.
A mysterious item about the `gconv-modules' file above (and also the
file coming with the GNU C Library) are the names of the character sets
specified in the `module' lines. Why do almost all the names end in
`//'? And this is not all: the names can actually be regular
expressions. At this point in time this mystery should not be
revealed, unless you have the relevant spell-casting materials: ashes
from an original DOS 6.2 boot disk burnt in effigy, a crucifix blessed
by St. Emacs, assorted herbal roots from Central America, sand from
Cebu, etc. Sorry! *The part of the implementation where this is used
is not yet finished. For now please simply follow the existing
examples. It'll become clearer once it is. -drepper*
A last remark about the `gconv-modules' is about the names not
ending with `//'. A character set named `INTERNAL' is often mentioned.
From the discussion above and the chosen name it should have become
clear that this is the name for the representation used in the
intermediate step of the triangulation. We have said that this is UCS-4
but actually that is not quite right. The UCS-4 specification also
includes the specification of the byte ordering used. Since a UCS-4
value consists of four bytes, a stored value is affected by byte
ordering. The internal representation is _not_ the same as UCS-4 in
case the byte ordering of the processor (or at least the running
process) is not the same as the one required for UCS-4. This is done
for performance reasons as one does not want to perform unnecessary
byte-swapping operations if one is not interested in actually seeing
the result in UCS-4. To avoid trouble with endianness, the internal
representation consistently is named `INTERNAL' even on big-endian
systems where the representations are identical.
6.5.4.3 `iconv' module data structures
......................................
So far this section has described how modules are located and considered
to be used. What remains to be described is the interface of the
modules so that one can write new ones. This section describes the
interface as it is in use in January 1999. The interface will change a
bit in the future but, with luck, only in an upwardly compatible way.
The definitions necessary to write new modules are publicly available
in the non-standard header `gconv.h'. The following text, therefore,
describes the definitions from this header file. First, however, it is
necessary to get an overview.
From the perspective of the user of `iconv' the interface is quite
simple: the `iconv_open' function returns a handle that can be used in
calls to `iconv', and finally the handle is freed with a call to
`iconv_close'. The problem is that the handle has to be able to
represent the possibly long sequences of conversion steps and also the
state of each conversion since the handle is all that is passed to the
`iconv' function. Therefore, the data structures are really the
elements necessary to understanding the implementation.
We need two different kinds of data structures. The first describes
the conversion and the second describes the state etc. There are
really two type definitions like this in `gconv.h'.
-- Data type: struct __gconv_step
This data structure describes one conversion a module can perform.
For each function in a loaded module with conversion functions
there is exactly one object of this type. This object is shared
by all users of the conversion (i.e., this object does not contain
any information corresponding to an actual conversion; it only
describes the conversion itself).
`struct __gconv_loaded_object *__shlib_handle'
`const char *__modname'
`int __counter'
All these elements of the structure are used internally in
the C library to coordinate loading and unloading the shared.
One must not expect any of the other elements to be available
or initialized.
`const char *__from_name'
`const char *__to_name'
`__from_name' and `__to_name' contain the names of the source
and destination character sets. They can be used to identify
the actual conversion to be carried out since one module
might implement conversions for more than one character set
and/or direction.
`gconv_fct __fct'
`gconv_init_fct __init_fct'
`gconv_end_fct __end_fct'
These elements contain pointers to the functions in the
loadable module. The interface will be explained below.
`int __min_needed_from'
`int __max_needed_from'
`int __min_needed_to'
`int __max_needed_to;'
These values have to be supplied in the init function of the
module. The `__min_needed_from' value specifies how many
bytes a character of the source character set at least needs.
The `__max_needed_from' specifies the maximum value that also
includes possible shift sequences.
The `__min_needed_to' and `__max_needed_to' values serve the
same purpose as `__min_needed_from' and `__max_needed_from'
but this time for the destination character set.
It is crucial that these values be accurate since otherwise
the conversion functions will have problems or not work at
all.
`int __stateful'
This element must also be initialized by the init function.
`int __stateful' is nonzero if the source character set is
stateful. Otherwise it is zero.
`void *__data'
This element can be used freely by the conversion functions
in the module. `void *__data' can be used to communicate
extra information from one call to another. `void *__data'
need not be initialized if not needed at all. If `void
*__data' element is assigned a pointer to dynamically
allocated memory (presumably in the init function) it has to
be made sure that the end function deallocates the memory.
Otherwise the application will leak memory.
It is important to be aware that this data structure is
shared by all users of this specification conversion and
therefore the `__data' element must not contain data specific
to one specific use of the conversion function.
-- Data type: struct __gconv_step_data
This is the data structure that contains the information specific
to each use of the conversion functions.
`char *__outbuf'
`char *__outbufend'
These elements specify the output buffer for the conversion
step. The `__outbuf' element points to the beginning of the
buffer, and `__outbufend' points to the byte following the
last byte in the buffer. The conversion function must not
assume anything about the size of the buffer but it can be
safely assumed the there is room for at least one complete
character in the output buffer.
Once the conversion is finished, if the conversion is the
last step, the `__outbuf' element must be modified to point
after the last byte written into the buffer to signal how
much output is available. If this conversion step is not the
last one, the element must not be modified. The
`__outbufend' element must not be modified.
`int __is_last'
This element is nonzero if this conversion step is the last
one. This information is necessary for the recursion. See
the description of the conversion function internals below.
This element must never be modified.
`int __invocation_counter'
The conversion function can use this element to see how many
calls of the conversion function already happened. Some
character sets require a certain prolog when generating
output, and by comparing this value with zero, one can find
out whether it is the first call and whether, therefore, the
prolog should be emitted. This element must never be
modified.
`int __internal_use'
This element is another one rarely used but needed in certain
situations. It is assigned a nonzero value in case the
conversion functions are used to implement `mbsrtowcs' et.al.
(i.e., the function is not used directly through the `iconv'
interface).
This sometimes makes a difference as it is expected that the
`iconv' functions are used to translate entire texts while the
`mbsrtowcs' functions are normally used only to convert single
strings and might be used multiple times to convert entire
texts.
But in this situation we would have problem complying with
some rules of the character set specification. Some
character sets require a prolog, which must appear exactly
once for an entire text. If a number of `mbsrtowcs' calls
are used to convert the text, only the first call must add
the prolog. However, because there is no communication
between the different calls of `mbsrtowcs', the conversion
functions have no possibility to find this out. The
situation is different for sequences of `iconv' calls since
the handle allows access to the needed information.
The `int __internal_use' element is mostly used together with
`__invocation_counter' as follows:
if (!data->__internal_use
&& data->__invocation_counter == 0)
/* Emit prolog. */
...
This element must never be modified.
`mbstate_t *__statep'
The `__statep' element points to an object of type `mbstate_t'
(*note Keeping the state::). The conversion of a stateful
character set must use the object pointed to by `__statep' to
store information about the conversion state. The `__statep'
element itself must never be modified.
`mbstate_t __state'
This element must _never_ be used directly. It is only part
of this structure to have the needed space allocated.
6.5.4.4 `iconv' module interfaces
.................................
With the knowledge about the data structures we now can describe the
conversion function itself. To understand the interface a bit of
knowledge is necessary about the functionality in the C library that
loads the objects with the conversions.
It is often the case that one conversion is used more than once
(i.e., there are several `iconv_open' calls for the same set of
character sets during one program run). The `mbsrtowcs' et.al.
functions in the GNU C Library also use the `iconv' functionality, which
increases the number of uses of the same functions even more.
Because of this multiple use of conversions, the modules do not get
loaded exclusively for one conversion. Instead a module once loaded can
be used by an arbitrary number of `iconv' or `mbsrtowcs' calls at the
same time. The splitting of the information between conversion-
function-specific information and conversion data makes this possible.
The last section showed the two data structures used to do this.
This is of course also reflected in the interface and semantics of
the functions that the modules must provide. There are three functions
that must have the following names:
`gconv_init'
The `gconv_init' function initializes the conversion function
specific data structure. This very same object is shared by all
conversions that use this conversion and, therefore, no state
information about the conversion itself must be stored in here.
If a module implements more than one conversion, the `gconv_init'
function will be called multiple times.
`gconv_end'
The `gconv_end' function is responsible for freeing all resources
allocated by the `gconv_init' function. If there is nothing to do,
this function can be missing. Special care must be taken if the
module implements more than one conversion and the `gconv_init'
function does not allocate the same resources for all conversions.
`gconv'
This is the actual conversion function. It is called to convert
one block of text. It gets passed the conversion step information
initialized by `gconv_init' and the conversion data, specific to
this use of the conversion functions.
There are three data types defined for the three module interface
functions and these define the interface.
-- Data type: int (*__gconv_init_fct) (struct __gconv_step *)
This specifies the interface of the initialization function of the
module. It is called exactly once for each conversion the module
implements.
As explained in the description of the `struct __gconv_step' data
structure above the initialization function has to initialize
parts of it.
`__min_needed_from'
`__max_needed_from'
`__min_needed_to'
`__max_needed_to'
These elements must be initialized to the exact numbers of
the minimum and maximum number of bytes used by one character
in the source and destination character sets, respectively.
If the characters all have the same size, the minimum and
maximum values are the same.
`__stateful'
This element must be initialized to a nonzero value if the
source character set is stateful. Otherwise it must be zero.
If the initialization function needs to communicate some
information to the conversion function, this communication can
happen using the `__data' element of the `__gconv_step' structure.
But since this data is shared by all the conversions, it must not
be modified by the conversion function. The example below shows
how this can be used.
#define MIN_NEEDED_FROM 1
#define MAX_NEEDED_FROM 4
#define MIN_NEEDED_TO 4
#define MAX_NEEDED_TO 4
int
gconv_init (struct __gconv_step *step)
{
/* Determine which direction. */
struct iso2022jp_data *new_data;
enum direction dir = illegal_dir;
enum variant var = illegal_var;
int result;
if (__strcasecmp (step->__from_name, "ISO-2022-JP//") == 0)
{
dir = from_iso2022jp;
var = iso2022jp;
}
else if (__strcasecmp (step->__to_name, "ISO-2022-JP//") == 0)
{
dir = to_iso2022jp;
var = iso2022jp;
}
else if (__strcasecmp (step->__from_name, "ISO-2022-JP-2//") == 0)
{
dir = from_iso2022jp;
var = iso2022jp2;
}
else if (__strcasecmp (step->__to_name, "ISO-2022-JP-2//") == 0)
{
dir = to_iso2022jp;
var = iso2022jp2;
}
result = __GCONV_NOCONV;
if (dir != illegal_dir)
{
new_data = (struct iso2022jp_data *)
malloc (sizeof (struct iso2022jp_data));
result = __GCONV_NOMEM;
if (new_data != NULL)
{
new_data->dir = dir;
new_data->var = var;
step->__data = new_data;
if (dir == from_iso2022jp)
{
step->__min_needed_from = MIN_NEEDED_FROM;
step->__max_needed_from = MAX_NEEDED_FROM;
step->__min_needed_to = MIN_NEEDED_TO;
step->__max_needed_to = MAX_NEEDED_TO;
}
else
{
step->__min_needed_from = MIN_NEEDED_TO;
step->__max_needed_from = MAX_NEEDED_TO;
step->__min_needed_to = MIN_NEEDED_FROM;
step->__max_needed_to = MAX_NEEDED_FROM + 2;
}
/* Yes, this is a stateful encoding. */
step->__stateful = 1;
result = __GCONV_OK;
}
}
return result;
}
The function first checks which conversion is wanted. The module
from which this function is taken implements four different
conversions; which one is selected can be determined by comparing
the names. The comparison should always be done without paying
attention to the case.
Next, a data structure, which contains the necessary information
about which conversion is selected, is allocated. The data
structure `struct iso2022jp_data' is locally defined since,
outside the module, this data is not used at all. Please note
that if all four conversions this modules supports are requested
there are four data blocks.
One interesting thing is the initialization of the `__min_' and
`__max_' elements of the step data object. A single ISO-2022-JP
character can consist of one to four bytes. Therefore the
`MIN_NEEDED_FROM' and `MAX_NEEDED_FROM' macros are defined this
way. The output is always the `INTERNAL' character set (aka
UCS-4) and therefore each character consists of exactly four
bytes. For the conversion from `INTERNAL' to ISO-2022-JP we have
to take into account that escape sequences might be necessary to
switch the character sets. Therefore the `__max_needed_to'
element for this direction gets assigned `MAX_NEEDED_FROM + 2'.
This takes into account the two bytes needed for the escape
sequences to single the switching. The asymmetry in the maximum
values for the two directions can be explained easily: when
reading ISO-2022-JP text, escape sequences can be handled alone
(i.e., it is not necessary to process a real character since the
effect of the escape sequence can be recorded in the state
information). The situation is different for the other direction.
Since it is in general not known which character comes next, one
cannot emit escape sequences to change the state in advance. This
means the escape sequences that have to be emitted together with
the next character. Therefore one needs more room than only for
the character itself.
The possible return values of the initialization function are:
`__GCONV_OK'
The initialization succeeded
`__GCONV_NOCONV'
The requested conversion is not supported in the module.
This can happen if the `gconv-modules' file has errors.
`__GCONV_NOMEM'
Memory required to store additional information could not be
allocated.
The function called before the module is unloaded is significantly
easier. It often has nothing at all to do; in which case it can be left
out completely.
-- Data type: void (*__gconv_end_fct) (struct gconv_step *)
The task of this function is to free all resources allocated in the
initialization function. Therefore only the `__data' element of
the object pointed to by the argument is of interest. Continuing
the example from the initialization function, the finalization
function looks like this:
void
gconv_end (struct __gconv_step *data)
{
free (data->__data);
}
The most important function is the conversion function itself, which
can get quite complicated for complex character sets. But since this
is not of interest here, we will only describe a possible skeleton for
the conversion function.
-- Data type: int (*__gconv_fct) (struct __gconv_step *, struct
__gconv_step_data *, const char **, const char *, size_t *,
int)
The conversion function can be called for two basic reason: to
convert text or to reset the state. From the description of the
`iconv' function it can be seen why the flushing mode is
necessary. What mode is selected is determined by the sixth
argument, an integer. This argument being nonzero means that
flushing is selected.
Common to both modes is where the output buffer can be found. The
information about this buffer is stored in the conversion step
data. A pointer to this information is passed as the second
argument to this function. The description of the `struct
__gconv_step_data' structure has more information on the
conversion step data.
What has to be done for flushing depends on the source character
set. If the source character set is not stateful, nothing has to
be done. Otherwise the function has to emit a byte sequence to
bring the state object into the initial state. Once this all
happened the other conversion modules in the chain of conversions
have to get the same chance. Whether another step follows can be
determined from the `__is_last' element of the step data structure
to which the first parameter points.
The more interesting mode is when actual text has to be converted.
The first step in this case is to convert as much text as possible
from the input buffer and store the result in the output buffer.
The start of the input buffer is determined by the third argument,
which is a pointer to a pointer variable referencing the beginning
of the buffer. The fourth argument is a pointer to the byte right
after the last byte in the buffer.
The conversion has to be performed according to the current state
if the character set is stateful. The state is stored in an
object pointed to by the `__statep' element of the step data
(second argument). Once either the input buffer is empty or the
output buffer is full the conversion stops. At this point, the
pointer variable referenced by the third parameter must point to
the byte following the last processed byte (i.e., if all of the
input is consumed, this pointer and the fourth parameter have the
same value).
What now happens depends on whether this step is the last one. If
it is the last step, the only thing that has to be done is to
update the `__outbuf' element of the step data structure to point
after the last written byte. This update gives the caller the
information on how much text is available in the output buffer.
In addition, the variable pointed to by the fifth parameter, which
is of type `size_t', must be incremented by the number of
characters (_not bytes_) that were converted in a non-reversible
way. Then, the function can return.
In case the step is not the last one, the later conversion
functions have to get a chance to do their work. Therefore, the
appropriate conversion function has to be called. The information
about the functions is stored in the conversion data structures,
passed as the first parameter. This information and the step data
are stored in arrays, so the next element in both cases can be
found by simple pointer arithmetic:
int
gconv (struct __gconv_step *step, struct __gconv_step_data *data,
const char **inbuf, const char *inbufend, size_t *written,
int do_flush)
{
struct __gconv_step *next_step = step + 1;
struct __gconv_step_data *next_data = data + 1;
...
The `next_step' pointer references the next step information and
`next_data' the next data record. The call of the next function
therefore will look similar to this:
next_step->__fct (next_step, next_data, &outerr, outbuf,
written, 0)
But this is not yet all. Once the function call returns the
conversion function might have some more to do. If the return
value of the function is `__GCONV_EMPTY_INPUT', more room is
available in the output buffer. Unless the input buffer is empty
the conversion, functions start all over again and process the
rest of the input buffer. If the return value is not
`__GCONV_EMPTY_INPUT', something went wrong and we have to recover
from this.
A requirement for the conversion function is that the input buffer
pointer (the third argument) always point to the last character
that was put in converted form into the output buffer. This is
trivially true after the conversion performed in the current step,
but if the conversion functions deeper downstream stop
prematurely, not all characters from the output buffer are
consumed and, therefore, the input buffer pointers must be backed
off to the right position.
Correcting the input buffers is easy to do if the input and output
character sets have a fixed width for all characters. In this
situation we can compute how many characters are left in the
output buffer and, therefore, can correct the input buffer pointer
appropriately with a similar computation. Things are getting
tricky if either character set has characters represented with
variable length byte sequences, and it gets even more complicated
if the conversion has to take care of the state. In these cases
the conversion has to be performed once again, from the known
state before the initial conversion (i.e., if necessary the state
of the conversion has to be reset and the conversion loop has to be
executed again). The difference now is that it is known how much
input must be created, and the conversion can stop before
converting the first unused character. Once this is done the
input buffer pointers must be updated again and the function can
return.
One final thing should be mentioned. If it is necessary for the
conversion to know whether it is the first invocation (in case a
prolog has to be emitted), the conversion function should
increment the `__invocation_counter' element of the step data
structure just before returning to the caller. See the
description of the `struct __gconv_step_data' structure above for
more information on how this can be used.
The return value must be one of the following values:
`__GCONV_EMPTY_INPUT'
All input was consumed and there is room left in the output
buffer.
`__GCONV_FULL_OUTPUT'
No more room in the output buffer. In case this is not the
last step this value is propagated down from the call of the
next conversion function in the chain.
`__GCONV_INCOMPLETE_INPUT'
The input buffer is not entirely empty since it contains an
incomplete character sequence.
The following example provides a framework for a conversion
function. In case a new conversion has to be written the holes in
this implementation have to be filled and that is it.
int
gconv (struct __gconv_step *step, struct __gconv_step_data *data,
const char **inbuf, const char *inbufend, size_t *written,
int do_flush)
{
struct __gconv_step *next_step = step + 1;
struct __gconv_step_data *next_data = data + 1;
gconv_fct fct = next_step->__fct;
int status;
/* If the function is called with no input this means we have
to reset to the initial state. The possibly partly
converted input is dropped. */
if (do_flush)
{
status = __GCONV_OK;
/* Possible emit a byte sequence which put the state object
into the initial state. */
/* Call the steps down the chain if there are any but only
if we successfully emitted the escape sequence. */
if (status == __GCONV_OK && ! data->__is_last)
status = fct (next_step, next_data, NULL, NULL,
written, 1);
}
else
{
/* We preserve the initial values of the pointer variables. */
const char *inptr = *inbuf;
char *outbuf = data->__outbuf;
char *outend = data->__outbufend;
char *outptr;
do
{
/* Remember the start value for this round. */
inptr = *inbuf;
/* The outbuf buffer is empty. */
outptr = outbuf;
/* For stateful encodings the state must be safe here. */
/* Run the conversion loop. `status' is set
appropriately afterwards. */
/* If this is the last step, leave the loop. There is
nothing we can do. */
if (data->__is_last)
{
/* Store information about how many bytes are
available. */
data->__outbuf = outbuf;
/* If any non-reversible conversions were performed,
add the number to `*written'. */
break;
}
/* Write out all output that was produced. */
if (outbuf > outptr)
{
const char *outerr = data->__outbuf;
int result;
result = fct (next_step, next_data, &outerr,
outbuf, written, 0);
if (result != __GCONV_EMPTY_INPUT)
{
if (outerr != outbuf)
{
/* Reset the input buffer pointer. We
document here the complex case. */
size_t nstatus;
/* Reload the pointers. */
*inbuf = inptr;
outbuf = outptr;
/* Possibly reset the state. */
/* Redo the conversion, but this time
the end of the output buffer is at
`outerr'. */
}
/* Change the status. */
status = result;
}
else
/* All the output is consumed, we can make
another run if everything was ok. */
if (status == __GCONV_FULL_OUTPUT)
status = __GCONV_OK;
}
}
while (status == __GCONV_OK);
/* We finished one use of this step. */
++data->__invocation_counter;
}
return status;
}
This information should be sufficient to write new modules. Anybody
doing so should also take a look at the available source code in the
GNU C Library sources. It contains many examples of working and
optimized modules.

File: libc.info, Node: Locales, Next: Message Translation, Prev: Character Set Handling, Up: Top
7 Locales and Internationalization
**********************************
Different countries and cultures have varying conventions for how to
communicate. These conventions range from very simple ones, such as the
format for representing dates and times, to very complex ones, such as
the language spoken.
"Internationalization" of software means programming it to be able
to adapt to the user's favorite conventions. In ISO C,
internationalization works by means of "locales". Each locale
specifies a collection of conventions, one convention for each purpose.
The user chooses a set of conventions by specifying a locale (via
environment variables).
All programs inherit the chosen locale as part of their environment.
Provided the programs are written to obey the choice of locale, they
will follow the conventions preferred by the user.
* Menu:
* Effects of Locale:: Actions affected by the choice of
locale.
* Choosing Locale:: How the user specifies a locale.
* Locale Categories:: Different purposes for which you can
select a locale.
* Setting the Locale:: How a program specifies the locale
with library functions.
* Standard Locales:: Locale names available on all systems.
* Locale Information:: How to access the information for the locale.
* Formatting Numbers:: A dedicated function to format numbers.
* Yes-or-No Questions:: Check a Response against the locale.

File: libc.info, Node: Effects of Locale, Next: Choosing Locale, Up: Locales
7.1 What Effects a Locale Has
=============================
Each locale specifies conventions for several purposes, including the
following:
* What multibyte character sequences are valid, and how they are
interpreted (*note Character Set Handling::).
* Classification of which characters in the local character set are
considered alphabetic, and upper- and lower-case conversion
conventions (*note Character Handling::).
* The collating sequence for the local language and character set
(*note Collation Functions::).
* Formatting of numbers and currency amounts (*note General
Numeric::).
* Formatting of dates and times (*note Formatting Calendar Time::).
* What language to use for output, including error messages (*note
Message Translation::).
* What language to use for user answers to yes-or-no questions
(*note Yes-or-No Questions::).
* What language to use for more complex user input. (The C library
doesn't yet help you implement this.)
Some aspects of adapting to the specified locale are handled
automatically by the library subroutines. For example, all your program
needs to do in order to use the collating sequence of the chosen locale
is to use `strcoll' or `strxfrm' to compare strings.
Other aspects of locales are beyond the comprehension of the library.
For example, the library can't automatically translate your program's
output messages into other languages. The only way you can support
output in the user's favorite language is to program this more or less
by hand. The C library provides functions to handle translations for
multiple languages easily.
This chapter discusses the mechanism by which you can modify the
current locale. The effects of the current locale on specific library
functions are discussed in more detail in the descriptions of those
functions.

File: libc.info, Node: Choosing Locale, Next: Locale Categories, Prev: Effects of Locale, Up: Locales
7.2 Choosing a Locale
=====================
The simplest way for the user to choose a locale is to set the
environment variable `LANG'. This specifies a single locale to use for
all purposes. For example, a user could specify a hypothetical locale
named `espana-castellano' to use the standard conventions of most of
Spain.
The set of locales supported depends on the operating system you are
using, and so do their names. We can't make any promises about what
locales will exist, except for one standard locale called `C' or
`POSIX'. Later we will describe how to construct locales.
A user also has the option of specifying different locales for
different purposes--in effect, choosing a mixture of multiple locales.
For example, the user might specify the locale `espana-castellano'
for most purposes, but specify the locale `usa-english' for currency
formatting. This might make sense if the user is a Spanish-speaking
American, working in Spanish, but representing monetary amounts in US
dollars.
Note that both locales `espana-castellano' and `usa-english', like
all locales, would include conventions for all of the purposes to which
locales apply. However, the user can choose to use each locale for a
particular subset of those purposes.

File: libc.info, Node: Locale Categories, Next: Setting the Locale, Prev: Choosing Locale, Up: Locales
7.3 Categories of Activities that Locales Affect
================================================
The purposes that locales serve are grouped into "categories", so that
a user or a program can choose the locale for each category
independently. Here is a table of categories; each name is both an
environment variable that a user can set, and a macro name that you can
use as an argument to `setlocale'.
`LC_COLLATE'
This category applies to collation of strings (functions `strcoll'
and `strxfrm'); see *note Collation Functions::.
`LC_CTYPE'
This category applies to classification and conversion of
characters, and to multibyte and wide characters; see *note
Character Handling::, and *note Character Set Handling::.
`LC_MONETARY'
This category applies to formatting monetary values; see *note
General Numeric::.
`LC_NUMERIC'
This category applies to formatting numeric values that are not
monetary; see *note General Numeric::.
`LC_TIME'
This category applies to formatting date and time values; see
*note Formatting Calendar Time::.
`LC_MESSAGES'
This category applies to selecting the language used in the user
interface for message translation (*note The Uniforum approach::;
*note Message catalogs a la X/Open::) and contains regular
expressions for affirmative and negative responses.
`LC_ALL'
This is not an environment variable; it is only a macro that you
can use with `setlocale' to set a single locale for all purposes.
Setting this environment variable overwrites all selections by the
other `LC_*' variables or `LANG'.
`LANG'
If this environment variable is defined, its value specifies the
locale to use for all purposes except as overridden by the
variables above.
When developing the message translation functions it was felt that
the functionality provided by the variables above is not sufficient.
For example, it should be possible to specify more than one locale name.
Take a Swedish user who better speaks German than English, and a program
whose messages are output in English by default. It should be possible
to specify that the first choice of language is Swedish, the second
German, and if this also fails to use English. This is possible with
the variable `LANGUAGE'. For further description of this GNU extension
see *note Using gettextized software::.

File: libc.info, Node: Setting the Locale, Next: Standard Locales, Prev: Locale Categories, Up: Locales
7.4 How Programs Set the Locale
===============================
A C program inherits its locale environment variables when it starts up.
This happens automatically. However, these variables do not
automatically control the locale used by the library functions, because
ISO C says that all programs start by default in the standard `C'
locale. To use the locales specified by the environment, you must call
`setlocale'. Call it as follows:
setlocale (LC_ALL, "");
to select a locale based on the user choice of the appropriate
environment variables.
You can also use `setlocale' to specify a particular locale, for
general use or for a specific category.
The symbols in this section are defined in the header file
`locale.h'.
-- Function: char * setlocale (int CATEGORY, const char *LOCALE)
Preliminary: | MT-Unsafe const:locale env | AS-Unsafe init lock
heap corrupt | AC-Unsafe init corrupt lock mem fd | *Note POSIX
Safety Concepts::.
The function `setlocale' sets the current locale for category
CATEGORY to LOCALE. A list of all the locales the system provides
can be created by running
locale -a
If CATEGORY is `LC_ALL', this specifies the locale for all
purposes. The other possible values of CATEGORY specify an single
purpose (*note Locale Categories::).
You can also use this function to find out the current locale by
passing a null pointer as the LOCALE argument. In this case,
`setlocale' returns a string that is the name of the locale
currently selected for category CATEGORY.
The string returned by `setlocale' can be overwritten by subsequent
calls, so you should make a copy of the string (*note Copying and
Concatenation::) if you want to save it past any further calls to
`setlocale'. (The standard library is guaranteed never to call
`setlocale' itself.)
You should not modify the string returned by `setlocale'. It might
be the same string that was passed as an argument in a previous
call to `setlocale'. One requirement is that the CATEGORY must be
the same in the call the string was returned and the one when the
string is passed in as LOCALE parameter.
When you read the current locale for category `LC_ALL', the value
encodes the entire combination of selected locales for all
categories. In this case, the value is not just a single locale
name. In fact, we don't make any promises about what it looks
like. But if you specify the same "locale name" with `LC_ALL' in
a subsequent call to `setlocale', it restores the same combination
of locale selections.
To be sure you can use the returned string encoding the currently
selected locale at a later time, you must make a copy of the
string. It is not guaranteed that the returned pointer remains
valid over time.
When the LOCALE argument is not a null pointer, the string returned
by `setlocale' reflects the newly-modified locale.
If you specify an empty string for LOCALE, this means to read the
appropriate environment variable and use its value to select the
locale for CATEGORY.
If a nonempty string is given for LOCALE, then the locale of that
name is used if possible.
If you specify an invalid locale name, `setlocale' returns a null
pointer and leaves the current locale unchanged.
The path used for finding locale data can be set using the `LOCPATH'
environment variable. The default path for finding locale data is
system specific. It is computed from the value given as the prefix
while configuring the C library. This value normally is `/usr' or `/'.
For the former the complete path is:
/usr/lib/locale
Here is an example showing how you might use `setlocale' to
temporarily switch to a new locale.
#include <stddef.h>
#include <locale.h>
#include <stdlib.h>
#include <string.h>
void
with_other_locale (char *new_locale,
void (*subroutine) (int),
int argument)
{
char *old_locale, *saved_locale;
/* Get the name of the current locale. */
old_locale = setlocale (LC_ALL, NULL);
/* Copy the name so it won't be clobbered by `setlocale'. */
saved_locale = strdup (old_locale);
if (saved_locale == NULL)
fatal ("Out of memory");
/* Now change the locale and do some stuff with it. */
setlocale (LC_ALL, new_locale);
(*subroutine) (argument);
/* Restore the original locale. */
setlocale (LC_ALL, saved_locale);
free (saved_locale);
}
*Portability Note:* Some ISO C systems may define additional locale
categories, and future versions of the library will do so. For
portability, assume that any symbol beginning with `LC_' might be
defined in `locale.h'.

File: libc.info, Node: Standard Locales, Next: Locale Information, Prev: Setting the Locale, Up: Locales
7.5 Standard Locales
====================
The only locale names you can count on finding on all operating systems
are these three standard ones:
`"C"'
This is the standard C locale. The attributes and behavior it
provides are specified in the ISO C standard. When your program
starts up, it initially uses this locale by default.
`"POSIX"'
This is the standard POSIX locale. Currently, it is an alias for
the standard C locale.
`""'
The empty name says to select a locale based on environment
variables. *Note Locale Categories::.
Defining and installing named locales is normally a responsibility of
the system administrator at your site (or the person who installed the
GNU C Library). It is also possible for the user to create private
locales. All this will be discussed later when describing the tool to
do so.
If your program needs to use something other than the `C' locale, it
will be more portable if you use whatever locale the user specifies
with the environment, rather than trying to specify some non-standard
locale explicitly by name. Remember, different machines might have
different sets of locales installed.

File: libc.info, Node: Locale Information, Next: Formatting Numbers, Prev: Standard Locales, Up: Locales
7.6 Accessing Locale Information
================================
There are several ways to access locale information. The simplest way
is to let the C library itself do the work. Several of the functions
in this library implicitly access the locale data, and use what
information is provided by the currently selected locale. This is how
the locale model is meant to work normally.
As an example take the `strftime' function, which is meant to nicely
format date and time information (*note Formatting Calendar Time::).
Part of the standard information contained in the `LC_TIME' category is
the names of the months. Instead of requiring the programmer to take
care of providing the translations the `strftime' function does this
all by itself. `%A' in the format string is replaced by the
appropriate weekday name of the locale currently selected by `LC_TIME'.
This is an easy example, and wherever possible functions do things
automatically in this way.
But there are quite often situations when there is simply no function
to perform the task, or it is simply not possible to do the work
automatically. For these cases it is necessary to access the
information in the locale directly. To do this the C library provides
two functions: `localeconv' and `nl_langinfo'. The former is part of
ISO C and therefore portable, but has a brain-damaged interface. The
second is part of the Unix interface and is portable in as far as the
system follows the Unix standards.
* Menu:
* The Lame Way to Locale Data:: ISO C's `localeconv'.
* The Elegant and Fast Way:: X/Open's `nl_langinfo'.

File: libc.info, Node: The Lame Way to Locale Data, Next: The Elegant and Fast Way, Up: Locale Information
7.6.1 `localeconv': It is portable but ...
------------------------------------------
Together with the `setlocale' function the ISO C people invented the
`localeconv' function. It is a masterpiece of poor design. It is
expensive to use, not extendable, and not generally usable as it
provides access to only `LC_MONETARY' and `LC_NUMERIC' related
information. Nevertheless, if it is applicable to a given situation it
should be used since it is very portable. The function `strfmon'
formats monetary amounts according to the selected locale using this
information.
-- Function: struct lconv * localeconv (void)
Preliminary: | MT-Unsafe race:localeconv locale | AS-Unsafe |
AC-Safe | *Note POSIX Safety Concepts::.
The `localeconv' function returns a pointer to a structure whose
components contain information about how numeric and monetary
values should be formatted in the current locale.
You should not modify the structure or its contents. The
structure might be overwritten by subsequent calls to
`localeconv', or by calls to `setlocale', but no other function in
the library overwrites this value.
-- Data Type: struct lconv
`localeconv''s return value is of this data type. Its elements are
described in the following subsections.
If a member of the structure `struct lconv' has type `char', and the
value is `CHAR_MAX', it means that the current locale has no value for
that parameter.
* Menu:
* General Numeric:: Parameters for formatting numbers and
currency amounts.
* Currency Symbol:: How to print the symbol that identifies an
amount of money (e.g. `$').
* Sign of Money Amount:: How to print the (positive or negative) sign
for a monetary amount, if one exists.

File: libc.info, Node: General Numeric, Next: Currency Symbol, Up: The Lame Way to Locale Data
7.6.1.1 Generic Numeric Formatting Parameters
.............................................
These are the standard members of `struct lconv'; there may be others.
`char *decimal_point'
`char *mon_decimal_point'
These are the decimal-point separators used in formatting
non-monetary and monetary quantities, respectively. In the `C'
locale, the value of `decimal_point' is `"."', and the value of
`mon_decimal_point' is `""'.
`char *thousands_sep'
`char *mon_thousands_sep'
These are the separators used to delimit groups of digits to the
left of the decimal point in formatting non-monetary and monetary
quantities, respectively. In the `C' locale, both members have a
value of `""' (the empty string).
`char *grouping'
`char *mon_grouping'
These are strings that specify how to group the digits to the left
of the decimal point. `grouping' applies to non-monetary
quantities and `mon_grouping' applies to monetary quantities. Use
either `thousands_sep' or `mon_thousands_sep' to separate the digit
groups.
Each member of these strings is to be interpreted as an integer
value of type `char'. Successive numbers (from left to right)
give the sizes of successive groups (from right to left, starting
at the decimal point.) The last member is either `0', in which
case the previous member is used over and over again for all the
remaining groups, or `CHAR_MAX', in which case there is no more
grouping--or, put another way, any remaining digits form one large
group without separators.
For example, if `grouping' is `"\04\03\02"', the correct grouping
for the number `123456787654321' is `12', `34', `56', `78', `765',
`4321'. This uses a group of 4 digits at the end, preceded by a
group of 3 digits, preceded by groups of 2 digits (as many as
needed). With a separator of `,', the number would be printed as
`12,34,56,78,765,4321'.
A value of `"\03"' indicates repeated groups of three digits, as
normally used in the U.S.
In the standard `C' locale, both `grouping' and `mon_grouping'
have a value of `""'. This value specifies no grouping at all.
`char int_frac_digits'
`char frac_digits'
These are small integers indicating how many fractional digits (to
the right of the decimal point) should be displayed in a monetary
value in international and local formats, respectively. (Most
often, both members have the same value.)
In the standard `C' locale, both of these members have the value
`CHAR_MAX', meaning "unspecified". The ISO standard doesn't say
what to do when you find this value; we recommend printing no
fractional digits. (This locale also specifies the empty string
for `mon_decimal_point', so printing any fractional digits would be
confusing!)

File: libc.info, Node: Currency Symbol, Next: Sign of Money Amount, Prev: General Numeric, Up: The Lame Way to Locale Data
7.6.1.2 Printing the Currency Symbol
....................................
These members of the `struct lconv' structure specify how to print the
symbol to identify a monetary value--the international analog of `$'
for US dollars.
Each country has two standard currency symbols. The "local currency
symbol" is used commonly within the country, while the "international
currency symbol" is used internationally to refer to that country's
currency when it is necessary to indicate the country unambiguously.
For example, many countries use the dollar as their monetary unit,
and when dealing with international currencies it's important to specify
that one is dealing with (say) Canadian dollars instead of U.S. dollars
or Australian dollars. But when the context is known to be Canada,
there is no need to make this explicit--dollar amounts are implicitly
assumed to be in Canadian dollars.
`char *currency_symbol'
The local currency symbol for the selected locale.
In the standard `C' locale, this member has a value of `""' (the
empty string), meaning "unspecified". The ISO standard doesn't
say what to do when you find this value; we recommend you simply
print the empty string as you would print any other string pointed
to by this variable.
`char *int_curr_symbol'
The international currency symbol for the selected locale.
The value of `int_curr_symbol' should normally consist of a
three-letter abbreviation determined by the international standard
`ISO 4217 Codes for the Representation of Currency and Funds',
followed by a one-character separator (often a space).
In the standard `C' locale, this member has a value of `""' (the
empty string), meaning "unspecified". We recommend you simply
print the empty string as you would print any other string pointed
to by this variable.
`char p_cs_precedes'
`char n_cs_precedes'
`char int_p_cs_precedes'
`char int_n_cs_precedes'
These members are `1' if the `currency_symbol' or
`int_curr_symbol' strings should precede the value of a monetary
amount, or `0' if the strings should follow the value. The
`p_cs_precedes' and `int_p_cs_precedes' members apply to positive
amounts (or zero), and the `n_cs_precedes' and `int_n_cs_precedes'
members apply to negative amounts.
In the standard `C' locale, all of these members have a value of
`CHAR_MAX', meaning "unspecified". The ISO standard doesn't say
what to do when you find this value. We recommend printing the
currency symbol before the amount, which is right for most
countries. In other words, treat all nonzero values alike in
these members.
The members with the `int_' prefix apply to the `int_curr_symbol'
while the other two apply to `currency_symbol'.
`char p_sep_by_space'
`char n_sep_by_space'
`char int_p_sep_by_space'
`char int_n_sep_by_space'
These members are `1' if a space should appear between the
`currency_symbol' or `int_curr_symbol' strings and the amount, or
`0' if no space should appear. The `p_sep_by_space' and
`int_p_sep_by_space' members apply to positive amounts (or zero),
and the `n_sep_by_space' and `int_n_sep_by_space' members apply to
negative amounts.
In the standard `C' locale, all of these members have a value of
`CHAR_MAX', meaning "unspecified". The ISO standard doesn't say
what you should do when you find this value; we suggest you treat
it as 1 (print a space). In other words, treat all nonzero values
alike in these members.
The members with the `int_' prefix apply to the `int_curr_symbol'
while the other two apply to `currency_symbol'. There is one
specialty with the `int_curr_symbol', though. Since all legal
values contain a space at the end the string one either printf
this space (if the currency symbol must appear in front and must
be separated) or one has to avoid printing this character at all
(especially when at the end of the string).

File: libc.info, Node: Sign of Money Amount, Prev: Currency Symbol, Up: The Lame Way to Locale Data
7.6.1.3 Printing the Sign of a Monetary Amount
..............................................
These members of the `struct lconv' structure specify how to print the
sign (if any) of a monetary value.
`char *positive_sign'
`char *negative_sign'
These are strings used to indicate positive (or zero) and negative
monetary quantities, respectively.
In the standard `C' locale, both of these members have a value of
`""' (the empty string), meaning "unspecified".
The ISO standard doesn't say what to do when you find this value;
we recommend printing `positive_sign' as you find it, even if it is
empty. For a negative value, print `negative_sign' as you find it
unless both it and `positive_sign' are empty, in which case print
`-' instead. (Failing to indicate the sign at all seems rather
unreasonable.)
`char p_sign_posn'
`char n_sign_posn'
`char int_p_sign_posn'
`char int_n_sign_posn'
These members are small integers that indicate how to position the
sign for nonnegative and negative monetary quantities,
respectively. (The string used by the sign is what was specified
with `positive_sign' or `negative_sign'.) The possible values are
as follows:
`0'
The currency symbol and quantity should be surrounded by
parentheses.
`1'
Print the sign string before the quantity and currency symbol.
`2'
Print the sign string after the quantity and currency symbol.
`3'
Print the sign string right before the currency symbol.
`4'
Print the sign string right after the currency symbol.
`CHAR_MAX'
"Unspecified". Both members have this value in the standard
`C' locale.
The ISO standard doesn't say what you should do when the value is
`CHAR_MAX'. We recommend you print the sign after the currency
symbol.
The members with the `int_' prefix apply to the `int_curr_symbol'
while the other two apply to `currency_symbol'.

File: libc.info, Node: The Elegant and Fast Way, Prev: The Lame Way to Locale Data, Up: Locale Information
7.6.2 Pinpoint Access to Locale Data
------------------------------------
When writing the X/Open Portability Guide the authors realized that the
`localeconv' function is not enough to provide reasonable access to
locale information. The information which was meant to be available in
the locale (as later specified in the POSIX.1 standard) requires more
ways to access it. Therefore the `nl_langinfo' function was introduced.
-- Function: char * nl_langinfo (nl_item ITEM)
Preliminary: | MT-Safe locale | AS-Safe | AC-Safe | *Note POSIX
Safety Concepts::.
The `nl_langinfo' function can be used to access individual
elements of the locale categories. Unlike the `localeconv'
function, which returns all the information, `nl_langinfo' lets
the caller select what information it requires. This is very fast
and it is not a problem to call this function multiple times.
A second advantage is that in addition to the numeric and monetary
formatting information, information from the `LC_TIME' and
`LC_MESSAGES' categories is available.
The type `nl_type' is defined in `nl_types.h'. The argument ITEM
is a numeric value defined in the header `langinfo.h'. The X/Open
standard defines the following values:
`CODESET'
`nl_langinfo' returns a string with the name of the coded
character set used in the selected locale.
`ABDAY_1'
`ABDAY_2'
`ABDAY_3'
`ABDAY_4'
`ABDAY_5'
`ABDAY_6'
`ABDAY_7'
`nl_langinfo' returns the abbreviated weekday name. `ABDAY_1'
corresponds to Sunday.
`DAY_1'
`DAY_2'
`DAY_3'
`DAY_4'
`DAY_5'
`DAY_6'
`DAY_7'
Similar to `ABDAY_1' etc., but here the return value is the
unabbreviated weekday name.
`ABMON_1'
`ABMON_2'
`ABMON_3'
`ABMON_4'
`ABMON_5'
`ABMON_6'
`ABMON_7'
`ABMON_8'
`ABMON_9'
`ABMON_10'
`ABMON_11'
`ABMON_12'
The return value is abbreviated name of the month. `ABMON_1'
corresponds to January.
`MON_1'
`MON_2'
`MON_3'
`MON_4'
`MON_5'
`MON_6'
`MON_7'
`MON_8'
`MON_9'
`MON_10'
`MON_11'
`MON_12'
Similar to `ABMON_1' etc., but here the month names are not
abbreviated. Here the first value `MON_1' also corresponds
to January.
`AM_STR'
`PM_STR'
The return values are strings which can be used in the
representation of time as an hour from 1 to 12 plus an am/pm
specifier.
Note that in locales which do not use this time representation
these strings might be empty, in which case the am/pm format
cannot be used at all.
`D_T_FMT'
The return value can be used as a format string for
`strftime' to represent time and date in a locale-specific
way.
`D_FMT'
The return value can be used as a format string for
`strftime' to represent a date in a locale-specific way.
`T_FMT'
The return value can be used as a format string for
`strftime' to represent time in a locale-specific way.
`T_FMT_AMPM'
The return value can be used as a format string for
`strftime' to represent time in the am/pm format.
Note that if the am/pm format does not make any sense for the
selected locale, the return value might be the same as the
one for `T_FMT'.
`ERA'
The return value represents the era used in the current
locale.
Most locales do not define this value. An example of a
locale which does define this value is the Japanese one. In
Japan, the traditional representation of dates includes the
name of the era corresponding to the then-emperor's reign.
Normally it should not be necessary to use this value
directly. Specifying the `E' modifier in their format
strings causes the `strftime' functions to use this
information. The format of the returned string is not
specified, and therefore you should not assume knowledge of
it on different systems.
`ERA_YEAR'
The return value gives the year in the relevant era of the
locale. As for `ERA' it should not be necessary to use this
value directly.
`ERA_D_T_FMT'
This return value can be used as a format string for
`strftime' to represent dates and times in a locale-specific
era-based way.
`ERA_D_FMT'
This return value can be used as a format string for
`strftime' to represent a date in a locale-specific era-based
way.
`ERA_T_FMT'
This return value can be used as a format string for
`strftime' to represent time in a locale-specific era-based
way.
`ALT_DIGITS'
The return value is a representation of up to 100 values used
to represent the values 0 to 99. As for `ERA' this value is
not intended to be used directly, but instead indirectly
through the `strftime' function. When the modifier `O' is
used in a format which would otherwise use numerals to
represent hours, minutes, seconds, weekdays, months, or
weeks, the appropriate value for the locale is used instead.
`INT_CURR_SYMBOL'
The same as the value returned by `localeconv' in the
`int_curr_symbol' element of the `struct lconv'.
`CURRENCY_SYMBOL'
`CRNCYSTR'
The same as the value returned by `localeconv' in the
`currency_symbol' element of the `struct lconv'.
`CRNCYSTR' is a deprecated alias still required by Unix98.
`MON_DECIMAL_POINT'
The same as the value returned by `localeconv' in the
`mon_decimal_point' element of the `struct lconv'.
`MON_THOUSANDS_SEP'
The same as the value returned by `localeconv' in the
`mon_thousands_sep' element of the `struct lconv'.
`MON_GROUPING'
The same as the value returned by `localeconv' in the
`mon_grouping' element of the `struct lconv'.
`POSITIVE_SIGN'
The same as the value returned by `localeconv' in the
`positive_sign' element of the `struct lconv'.
`NEGATIVE_SIGN'
The same as the value returned by `localeconv' in the
`negative_sign' element of the `struct lconv'.
`INT_FRAC_DIGITS'
The same as the value returned by `localeconv' in the
`int_frac_digits' element of the `struct lconv'.
`FRAC_DIGITS'
The same as the value returned by `localeconv' in the
`frac_digits' element of the `struct lconv'.
`P_CS_PRECEDES'
The same as the value returned by `localeconv' in the
`p_cs_precedes' element of the `struct lconv'.
`P_SEP_BY_SPACE'
The same as the value returned by `localeconv' in the
`p_sep_by_space' element of the `struct lconv'.
`N_CS_PRECEDES'
The same as the value returned by `localeconv' in the
`n_cs_precedes' element of the `struct lconv'.
`N_SEP_BY_SPACE'
The same as the value returned by `localeconv' in the
`n_sep_by_space' element of the `struct lconv'.
`P_SIGN_POSN'
The same as the value returned by `localeconv' in the
`p_sign_posn' element of the `struct lconv'.
`N_SIGN_POSN'
The same as the value returned by `localeconv' in the
`n_sign_posn' element of the `struct lconv'.
`INT_P_CS_PRECEDES'
The same as the value returned by `localeconv' in the
`int_p_cs_precedes' element of the `struct lconv'.
`INT_P_SEP_BY_SPACE'
The same as the value returned by `localeconv' in the
`int_p_sep_by_space' element of the `struct lconv'.
`INT_N_CS_PRECEDES'
The same as the value returned by `localeconv' in the
`int_n_cs_precedes' element of the `struct lconv'.
`INT_N_SEP_BY_SPACE'
The same as the value returned by `localeconv' in the
`int_n_sep_by_space' element of the `struct lconv'.
`INT_P_SIGN_POSN'
The same as the value returned by `localeconv' in the
`int_p_sign_posn' element of the `struct lconv'.
`INT_N_SIGN_POSN'
The same as the value returned by `localeconv' in the
`int_n_sign_posn' element of the `struct lconv'.
`DECIMAL_POINT'
`RADIXCHAR'
The same as the value returned by `localeconv' in the
`decimal_point' element of the `struct lconv'.
The name `RADIXCHAR' is a deprecated alias still used in
Unix98.
`THOUSANDS_SEP'
`THOUSEP'
The same as the value returned by `localeconv' in the
`thousands_sep' element of the `struct lconv'.
The name `THOUSEP' is a deprecated alias still used in Unix98.
`GROUPING'
The same as the value returned by `localeconv' in the
`grouping' element of the `struct lconv'.
`YESEXPR'
The return value is a regular expression which can be used
with the `regex' function to recognize a positive response to
a yes/no question. The GNU C Library provides the `rpmatch'
function for easier handling in applications.
`NOEXPR'
The return value is a regular expression which can be used
with the `regex' function to recognize a negative response to
a yes/no question.
`YESSTR'
The return value is a locale-specific translation of the
positive response to a yes/no question.
Using this value is deprecated since it is a very special
case of message translation, and is better handled by the
message translation functions (*note Message Translation::).
The use of this symbol is deprecated. Instead message
translation should be used.
`NOSTR'
The return value is a locale-specific translation of the
negative response to a yes/no question. What is said for
`YESSTR' is also true here.
The use of this symbol is deprecated. Instead message
translation should be used.
The file `langinfo.h' defines a lot more symbols but none of them
is official. Using them is not portable, and the format of the
return values might change. Therefore we recommended you not use
them.
Note that the return value for any valid argument can be used for
in all situations (with the possible exception of the am/pm time
formatting codes). If the user has not selected any locale for the
appropriate category, `nl_langinfo' returns the information from
the `"C"' locale. It is therefore possible to use this function as
shown in the example below.
If the argument ITEM is not valid, a pointer to an empty string is
returned.
An example of `nl_langinfo' usage is a function which has to print a
given date and time in a locale-specific way. At first one might think
that, since `strftime' internally uses the locale information, writing
something like the following is enough:
size_t
i18n_time_n_data (char *s, size_t len, const struct tm *tp)
{
return strftime (s, len, "%X %D", tp);
}
The format contains no weekday or month names and therefore is
internationally usable. Wrong! The output produced is something like
`"hh:mm:ss MM/DD/YY"'. This format is only recognizable in the USA.
Other countries use different formats. Therefore the function should
be rewritten like this:
size_t
i18n_time_n_data (char *s, size_t len, const struct tm *tp)
{
return strftime (s, len, nl_langinfo (D_T_FMT), tp);
}
Now it uses the date and time format of the locale selected when the
program runs. If the user selects the locale correctly there should
never be a misunderstanding over the time and date format.

File: libc.info, Node: Formatting Numbers, Next: Yes-or-No Questions, Prev: Locale Information, Up: Locales
7.7 A dedicated function to format numbers
==========================================
We have seen that the structure returned by `localeconv' as well as the
values given to `nl_langinfo' allow you to retrieve the various pieces
of locale-specific information to format numbers and monetary amounts.
We have also seen that the underlying rules are quite complex.
Therefore the X/Open standards introduce a function which uses such
locale information, making it easier for the user to format numbers
according to these rules.
-- Function: ssize_t strfmon (char *S, size_t MAXSIZE, const char
*FORMAT, ...)
Preliminary: | MT-Safe locale | AS-Unsafe heap | AC-Unsafe mem |
*Note POSIX Safety Concepts::.
The `strfmon' function is similar to the `strftime' function in
that it takes a buffer, its size, a format string, and values to
write into the buffer as text in a form specified by the format
string. Like `strftime', the function also returns the number of
bytes written into the buffer.
There are two differences: `strfmon' can take more than one
argument, and, of course, the format specification is different.
Like `strftime', the format string consists of normal text, which
is output as is, and format specifiers, which are indicated by a
`%'. Immediately after the `%', you can optionally specify
various flags and formatting information before the main
formatting character, in a similar way to `printf':
* Immediately following the `%' there can be one or more of the
following flags:
`=F'
The single byte character F is used for this field as
the numeric fill character. By default this character
is a space character. Filling with this character is
only performed if a left precision is specified. It is
not just to fill to the given field width.
`^'
The number is printed without grouping the digits
according to the rules of the current locale. By
default grouping is enabled.
`+', `('
At most one of these flags can be used. They select
which format to represent the sign of a currency amount.
By default, and if `+' is given, the locale equivalent
of +/- is used. If `(' is given, negative amounts are
enclosed in parentheses. The exact format is determined
by the values of the `LC_MONETARY' category of the
locale selected at program runtime.
`!'
The output will not contain the currency symbol.
`-'
The output will be formatted left-justified instead of
right-justified if it does not fill the entire field
width.
The next part of a specification is an optional field width. If no
width is specified 0 is taken. During output, the function first
determines how much space is required. If it requires at least as
many characters as given by the field width, it is output using as
much space as necessary. Otherwise, it is extended to use the
full width by filling with the space character. The presence or
absence of the `-' flag determines the side at which such padding
occurs. If present, the spaces are added at the right making the
output left-justified, and vice versa.
So far the format looks familiar, being similar to the `printf' and
`strftime' formats. However, the next two optional fields
introduce something new. The first one is a `#' character followed
by a decimal digit string. The value of the digit string
specifies the number of _digit_ positions to the left of the
decimal point (or equivalent). This does _not_ include the
grouping character when the `^' flag is not given. If the space
needed to print the number does not fill the whole width, the
field is padded at the left side with the fill character, which
can be selected using the `=' flag and by default is a space. For
example, if the field width is selected as 6 and the number is
123, the fill character is `*' the result will be `***123'.
The second optional field starts with a `.' (period) and consists
of another decimal digit string. Its value describes the number of
characters printed after the decimal point. The default is
selected from the current locale (`frac_digits',
`int_frac_digits', see *note General Numeric::). If the exact
representation needs more digits than given by the field width,
the displayed value is rounded. If the number of fractional
digits is selected to be zero, no decimal point is printed.
As a GNU extension, the `strfmon' implementation in the GNU C
Library allows an optional `L' next as a format modifier. If this
modifier is given, the argument is expected to be a `long double'
instead of a `double' value.
Finally, the last component is a format specifier. There are three
specifiers defined:
`i'
Use the locale's rules for formatting an international
currency value.
`n'
Use the locale's rules for formatting a national currency
value.
`%'
Place a `%' in the output. There must be no flag, width
specifier or modifier given, only `%%' is allowed.
As for `printf', the function reads the format string from left to
right and uses the values passed to the function following the
format string. The values are expected to be either of type
`double' or `long double', depending on the presence of the
modifier `L'. The result is stored in the buffer pointed to by S.
At most MAXSIZE characters are stored.
The return value of the function is the number of characters
stored in S, including the terminating `NULL' byte. If the number
of characters stored would exceed MAXSIZE, the function returns -1
and the content of the buffer S is unspecified. In this case
`errno' is set to `E2BIG'.
A few examples should make clear how the function works. It is
assumed that all the following pieces of code are executed in a program
which uses the USA locale (`en_US'). The simplest form of the format
is this:
strfmon (buf, 100, "@%n@%n@%n@", 123.45, -567.89, 12345.678);
The output produced is
"@$123.45@-$567.89@$12,345.68@"
We can notice several things here. First, the widths of the output
numbers are different. We have not specified a width in the format
string, and so this is no wonder. Second, the third number is printed
using thousands separators. The thousands separator for the `en_US'
locale is a comma. The number is also rounded. .678 is rounded to .68
since the format does not specify a precision and the default value in
the locale is 2. Finally, note that the national currency symbol is
printed since `%n' was used, not `i'. The next example shows how we
can align the output.
strfmon (buf, 100, "@%=*11n@%=*11n@%=*11n@", 123.45, -567.89, 12345.678);
The output this time is:
"@ $123.45@ -$567.89@ $12,345.68@"
Two things stand out. Firstly, all fields have the same width
(eleven characters) since this is the width given in the format and
since no number required more characters to be printed. The second
important point is that the fill character is not used. This is
correct since the white space was not used to achieve a precision given
by a `#' modifier, but instead to fill to the given width. The
difference becomes obvious if we now add a width specification.
strfmon (buf, 100, "@%=*11#5n@%=*11#5n@%=*11#5n@",
123.45, -567.89, 12345.678);
The output is
"@ $***123.45@-$***567.89@ $12,456.68@"
Here we can see that all the currency symbols are now aligned, and
that the space between the currency sign and the number is filled with
the selected fill character. Note that although the width is selected
to be 5 and 123.45 has three digits left of the decimal point, the
space is filled with three asterisks. This is correct since, as
explained above, the width does not include the positions used to store
thousands separators. One last example should explain the remaining
functionality.
strfmon (buf, 100, "@%=0(16#5.3i@%=0(16#5.3i@%=0(16#5.3i@",
123.45, -567.89, 12345.678);
This rather complex format string produces the following output:
"@ USD 000123,450 @(USD 000567.890)@ USD 12,345.678 @"
The most noticeable change is the alternative way of representing
negative numbers. In financial circles this is often done using
parentheses, and this is what the `(' flag selected. The fill
character is now `0'. Note that this `0' character is not regarded as
a numeric zero, and therefore the first and second numbers are not
printed using a thousands separator. Since we used the format
specifier `i' instead of `n', the international form of the currency
symbol is used. This is a four letter string, in this case `"USD "'.
The last point is that since the precision right of the decimal point
is selected to be three, the first and second numbers are printed with
an extra zero at the end and the third number is printed without
rounding.

File: libc.info, Node: Yes-or-No Questions, Prev: Formatting Numbers, Up: Locales
7.8 Yes-or-No Questions
=======================
Some non GUI programs ask a yes-or-no question. If the messages
(especially the questions) are translated into foreign languages, be
sure that you localize the answers too. It would be very bad habit to
ask a question in one language and request the answer in another, often
English.
The GNU C Library contains `rpmatch' to give applications easy
access to the corresponding locale definitions.
-- Function: int rpmatch (const char *RESPONSE)
Preliminary: | MT-Safe locale | AS-Unsafe corrupt heap lock dlopen
| AC-Unsafe corrupt lock mem fd | *Note POSIX Safety Concepts::.
The function `rpmatch' checks the string in RESPONSE whether or
not it is a correct yes-or-no answer and if yes, which one. The
check uses the `YESEXPR' and `NOEXPR' data in the `LC_MESSAGES'
category of the currently selected locale. The return value is as
follows:
`1'
The user entered an affirmative answer.
`0'
The user entered a negative answer.
`-1'
The answer matched neither the `YESEXPR' nor the `NOEXPR'
regular expression.
This function is not standardized but available beside in the GNU
C Library at least also in the IBM AIX library.
This function would normally be used like this:
...
/* Use a safe default. */
_Bool doit = false;
fputs (gettext ("Do you really want to do this? "), stdout);
fflush (stdout);
/* Prepare the `getline' call. */
line = NULL;
len = 0;
while (getline (&line, &len, stdin) >= 0)
{
/* Check the response. */
int res = rpmatch (line);
if (res >= 0)
{
/* We got a definitive answer. */
if (res > 0)
doit = true;
break;
}
}
/* Free what `getline' allocated. */
free (line);
Note that the loop continues until a read error is detected or until
a definitive (positive or negative) answer is read.

File: libc.info, Node: Message Translation, Next: Searching and Sorting, Prev: Locales, Up: Top
8 Message Translation
*********************
The program's interface with the user should be designed to ease the
user's task. One way to ease the user's task is to use messages in
whatever language the user prefers.
Printing messages in different languages can be implemented in
different ways. One could add all the different languages in the
source code and choose among the variants every time a message has to
be printed. This is certainly not a good solution since extending the
set of languages is cumbersome (the code must be changed) and the code
itself can become really big with dozens of message sets.
A better solution is to keep the message sets for each language in
separate files which are loaded at runtime depending on the language
selection of the user.
The GNU C Library provides two different sets of functions to support
message translation. The problem is that neither of the interfaces is
officially defined by the POSIX standard. The `catgets' family of
functions is defined in the X/Open standard but this is derived from
industry decisions and therefore not necessarily based on reasonable
decisions.
As mentioned above the message catalog handling provides easy
extendibility by using external data files which contain the message
translations. I.e., these files contain for each of the messages used
in the program a translation for the appropriate language. So the tasks
of the message handling functions are
* locate the external data file with the appropriate translations
* load the data and make it possible to address the messages
* map a given key to the translated message
The two approaches mainly differ in the implementation of this last
step. Decisions made in the last step influence the rest of the design.
* Menu:
* Message catalogs a la X/Open:: The `catgets' family of functions.
* The Uniforum approach:: The `gettext' family of functions.

File: libc.info, Node: Message catalogs a la X/Open, Next: The Uniforum approach, Up: Message Translation
8.1 X/Open Message Catalog Handling
===================================
The `catgets' functions are based on the simple scheme:
Associate every message to translate in the source code with a
unique identifier. To retrieve a message from a catalog file
solely the identifier is used.
This means for the author of the program that s/he will have to make
sure the meaning of the identifier in the program code and in the
message catalogs are always the same.
Before a message can be translated the catalog file must be located.
The user of the program must be able to guide the responsible function
to find whatever catalog the user wants. This is separated from what
the programmer had in mind.
All the types, constants and functions for the `catgets' functions
are defined/declared in the `nl_types.h' header file.
* Menu:
* The catgets Functions:: The `catgets' function family.
* The message catalog files:: Format of the message catalog files.
* The gencat program:: How to generate message catalogs files which
can be used by the functions.
* Common Usage:: How to use the `catgets' interface.