echo x - Makefile.ansi sed '/^X/s///' > Makefile.ansi << '/' XCC=exec cc XCFLAGS= -c -O -D_MINIX -D_POSIX_SOURCE X X Xall: X @$(CC) $(CFLAGS) *.c X X Xclean: X @rm -rf *.o *.s *.bak X / echo x - Makefile.kr sed '/^X/s///' > Makefile.kr << '/' XCC=exec cc XCFLAGS= -c -O -LIB -D_MINIX -D_POSIX_SOURCE X X Xall: X @$(CC) $(CFLAGS) _[a-l]*.c X @$(CC) $(CFLAGS) _[m-z]*.c X X Xclean: X @rm -rf *.o *.s *.bak X / echo x - _access.c sed '/^X/s///' > _access.c << '/' X#include X#define access _access X#include X XPUBLIC int access(name, mode) X_CONST char *name; Xint mode; X{ X message m; X X m.m3_i2 = mode; X _loadname(name, &m); X return(_syscall(FS, ACCESS, &m)); X} / echo x - _alarm.c sed '/^X/s///' > _alarm.c << '/' X#include X#define alarm _alarm X#include X XPUBLIC unsigned int alarm(sec) Xunsigned int sec; X{ X message m; X X m.m1_i1 = (int) sec; X return( (unsigned) _syscall(MM, ALARM, &m)); X} / echo x - _brk.c sed '/^X/s///' > _brk.c << '/' X#include X#define brk _brk X#define sbrk _sbrk X#include X Xextern char *_brksize; X X/* Both OSF/1 and SYSVR4 man pages specify that brk(2) returns int. X * However, BSD4.3 specifies that brk() returns char*. POSIX omits X * discussion of brk() on the grounds that it imposes a memory X * model on an architecture. X */ XPUBLIC int brk(addr) Xchar *addr; X{ X message m; X X m.m1_p1 = addr; X if (_syscall(MM, BRK, &m) < 0) return(-1); X _brksize = m.m2_p1; X return(0); X} X X XPUBLIC char *sbrk(incr) Xint incr; X{ X char *newsize, *oldsize; X X oldsize = _brksize; X newsize = _brksize + incr; X if (incr > 0 && newsize < oldsize || incr < 0 && newsize > oldsize) X return( (char *) -1); X if (brk(newsize) == 0) X return(oldsize); X else X return( (char *) -1); X} / echo x - _chdir.c sed '/^X/s///' > _chdir.c << '/' X#include X#define chdir _chdir X#include X XPUBLIC int chdir(name) X_CONST char *name; X{ X message m; X X _loadname(name, &m); X return(_syscall(FS, CHDIR, &m)); X} / echo x - _chmod.c sed '/^X/s///' > _chmod.c << '/' X#include X#define chmod _chmod X#include X XPUBLIC int chmod(name, mode) X_CONST char *name; XMode_t mode; X{ X message m; X X m.m3_i2 = mode; X _loadname(name, &m); X return(_syscall(FS, CHMOD, &m)); X} / echo x - _chown.c sed '/^X/s///' > _chown.c << '/' X#include X#define chown _chown X#include X#include X XPUBLIC int chown(name, owner, grp) X_CONST char *name; XUid_t owner; XGid_t grp; X{ X message m; X X m.m1_i1 = strlen(name) + 1; X m.m1_i2 = owner; X m.m1_i3 = grp; X m.m1_p1 = (char *) name; X return(_syscall(FS, CHOWN, &m)); X} / echo x - _chroot.c sed '/^X/s///' > _chroot.c << '/' X#include X#define chroot _chroot X#include X XPUBLIC int chroot(name) X_CONST char *name; X{ X message m; X X _loadname(name, &m); X return(_syscall(FS, CHROOT, &m)); X} / echo x - _close.c sed '/^X/s///' > _close.c << '/' X#include X#define close _close X#include X XPUBLIC int close(fd) Xint fd; X{ X message m; X X m.m1_i1 = fd; X return(_syscall(FS, CLOSE, &m)); X} / echo x - _creat.c sed '/^X/s///' > _creat.c << '/' X#include X#define creat _creat X#include X XPUBLIC int creat(name, mode) X_CONST char *name; XMode_t mode; X{ X message m; X X m.m3_i2 = mode; X _loadname(name, &m); X return(_syscall(FS, CREAT, &m)); X} / echo x - _dup.c sed '/^X/s///' > _dup.c << '/' X#include X#define dup _dup X#define fcntl _fcntl X#include X#include X XPUBLIC int dup(fd) Xint fd; X{ X return(fcntl(fd, F_DUPFD, 0)); X} / echo x - _dup2.c sed '/^X/s///' > _dup2.c << '/' X#include X#define close _close X#define dup2 _dup2 X#define fcntl _fcntl X#include X#include X XPUBLIC int dup2(fd, fd2) Xint fd, fd2; X{ X/* The behavior of dup2 is defined by POSIX in 6.2.1.2 as almost, but not X * quite the same as fcntl. X */ X X if (fd2 < 0 || fd2 > OPEN_MAX) { X errno = EBADF; X return(-1); X } X X /* Check to see if fildes is valid. */ X if (fcntl(fd, F_GETFL) < 0) { X /* 'fd' is not valid. */ X return(-1); X } else { X /* 'fd' is valid. */ X if (fd == fd2) return(fd2); X close(fd2); X return(fcntl(fd, F_DUPFD, fd2)); X } X} / echo x - _exec.c sed '/^X/s///' > _exec.c << '/' X#include X#define execl _execl X#define execle _execle X#define execv _execv X#define execve _execve X#define sbrk _sbrk X#include X#include X#include X#include X Xextern char **environ; X X#define PTRSIZE (sizeof(char *)) X X#ifdef _ANSI XPUBLIC int execl(const char *name, const char *arg, ...) X#else XPUBLIC int execl(name) Xchar *name; X#endif X{ X va_list argp; X int result; X X va_start(argp, name); X X /* The following cast of argp is not portable. Doing it right by copying X * the args to a true array will cost as much as ARG_MAX bytes of space. X */ X result = execve(name, (char **) argp, environ); X va_end(argp); X return(result); X} X X X#ifdef _ANSI XPUBLIC int execle(const char *name, const char *arg, ...) X#else XPUBLIC int execle(name) Xchar *name; X#endif X{ X va_list argp; X char **p; X int result; X X va_start(argp, name); X X /* The following cast of argp is not portable, as for execl(). */ X p = (char **) argp; X while (*p++ != NIL_PTR) X ; /* null statement */ X result = execve(name, (char **) argp, (char **) *p); X va_end(argp); X return(result); X} X X XPUBLIC int execv(name, argv) X_CONST char *name; Xchar * _CONST argv[]; X{ X return(execve(name, argv, environ)); X} X X XPUBLIC int execve(path, argv, envp) X_CONST char *path; /* pointer to name of file to be executed */ Xchar * _CONST argv[]; /* pointer to argument array */ Xchar * _CONST envp[]; /* pointer to environment */ X{ X int i, j; X X /* Count the argument pointers and environment pointers. */ X i = 0; X while (argv[i] != NULL) i++; X j = 0; X while (envp[j] != NULL) j++; X X return(__execve(path, argv, envp, i, j)); X} X X XPUBLIC int __execve(path, argv, envp, nargs, nenvps) X_CONST char *path; /* pointer to name of file to be executed */ Xchar * _CONST argv[]; /* pointer to argument array */ Xchar * _CONST envp[]; /* pointer to environment */ Xint nargs; /* number of args */ Xint nenvps; /* number of environment strings */ X{ X/* This is split off from execve to be called from execvp, so execvp does not X * have to allocate up to ARG_MAX bytes just to prepend "sh" to the arg array. X */ X X char *hp, **ap, *p; X int i, stackbytes, npointers, overflow, temp; X char *stack; X message m; X X /* Decide how big a stack is needed. Be paranoid about overflow. */ X overflow = FALSE; X npointers = 1 + nargs + 1 + nenvps + 1; /* 1's for argc and NULLs */ X stackbytes = nargs + nenvps; /* 1 byte for each null in strings */ X if (nargs < 0 || nenvps < 0 || stackbytes < nargs || npointers < stackbytes) X overflow = TRUE; X for (i = PTRSIZE; i != 0; i--) { X temp = stackbytes + npointers; X if (temp < stackbytes) overflow = TRUE; X stackbytes = temp; X } X ap = (char **) argv; X for (i = 0; i < nargs; i++) { X temp = stackbytes + strlen(*ap++); X if (temp < stackbytes) overflow = TRUE; X stackbytes = temp; X } X ap = (char **) envp; X for (i = 0; i < nenvps; i++) { X temp = stackbytes + strlen(*ap++); X if (temp < stackbytes) overflow = TRUE; X stackbytes = temp; X } X temp = stackbytes + PTRSIZE - 1; X if (temp < stackbytes) overflow = TRUE; X stackbytes = (temp / PTRSIZE) * PTRSIZE; X X /* Check for overflow before committing sbrk. */ X if (overflow) { X errno = E2BIG; X return(-1); X } X X /* Allocate the stack. */ X stack = sbrk(stackbytes); X if (stack == (char *) -1) { X errno = E2BIG; X return(-1); X } X X /* Prepare the stack vector and argc. */ X ap = (char **) stack; X hp = &stack[npointers * PTRSIZE]; X *ap++ = (char *) nargs; X X /* Prepare the argument pointers and strings. */ X for (i = 0; i < nargs; i++) { X *ap++ = (char *) (hp - stack); X p = *argv++; X while ( (*hp++ = *p++) != 0) X ; X } X *ap++ = (char *) NULL; X X /* Prepare the environment pointers and strings. */ X for (i = 0; i < nenvps; i++) { X *ap++ = (char *) (hp - stack); X p = *envp++; X while ( (*hp++ = *p++) != 0) X ; X } X *ap++ = (char *) NULL; X X /* Do the real work. */ X m.m1_i1 = strlen(path) + 1; X m.m1_i2 = stackbytes; X m.m1_p1 = (char *) path; X m.m1_p2 = stack; X (void) _syscall(MM, EXEC, &m); X X /* The exec failed. */ X sbrk(-stackbytes); X return(m.m_type); X} / echo x - _execn.c sed '/^X/s///' > _execn.c << '/' X#include X#include X X#define PTRSIZE sizeof(char *) X_PROTOTYPE( int _execn, (char * name)); X XPUBLIC int _execn(name) Xchar *name; /* pointer to file to be exec'd */ X{ X/* Special version used when there are no args and no environment. This call X * is principally used by INIT, to avoid having to allocate ARG_MAX. X */ X X PRIVATE char stack[3 * PTRSIZE]; X message m; X X m.m1_i1 = strlen(name) + 1; X m.m1_i2 = sizeof(stack); X m.m1_p1 = name; X m.m1_p2 = stack; X (void) _syscall(MM, EXEC, &m); X} / echo x - _exit.c sed '/^X/s///' > _exit.c << '/' X#include X#include X XPUBLIC void _exit(status) Xint status; X{ X message m; X X m.m1_i1 = status; X _syscall(MM, EXIT, &m); X} / echo x - _fcntl.c sed '/^X/s///' > _fcntl.c << '/' X#include X#define fcntl _fcntl X#include X#include X X#if _ANSI XPUBLIC int fcntl(int fd, int cmd, ...) X#else XPUBLIC int fcntl(fd, cmd) Xint fd; Xint cmd; X#endif X{ X va_list argp; X message m; X X va_start(argp, cmd); X X /* Set up for the sensible case where there is no variable parameter. This X * covers F_GETFD, F_GETFL and invalid commands. X */ X m.m1_i3 = 0; X m.m1_p1 = NIL_PTR; X X /* Adjust for the stupid cases. */ X switch(cmd) { X case F_DUPFD: X case F_SETFD: X case F_SETFL: X m.m1_i3 = va_arg(argp, int); X break; X case F_GETLK: X case F_SETLK: X case F_SETLKW: X m.m1_p1 = (char *) va_arg(argp, struct flock *); X break; X } X X /* Clean up and make the system call. */ X va_end(argp); X m.m1_i1 = fd; X m.m1_i2 = cmd; X return(_syscall(FS, FCNTL, &m)); X} / echo x - _fork.c sed '/^X/s///' > _fork.c << '/' X#include X#define fork _fork X#include X XPUBLIC pid_t fork() X{ X message m; X X return(_syscall(MM, FORK, &m)); X} / echo x - _fpathconf.c sed '/^X/s///' > _fpathconf.c << '/' X/* POSIX fpathconf (Sec. 5.7.1) Author: Andy Tanenbaum */ X X#include X#define fstat _fstat X#define fpathconf _fpathconf X#include X#include X#include X#include X XPUBLIC long fpathconf(fd, name) Xint fd; /* file descriptor being interrogated */ Xint name; /* property being inspected */ X{ X/* POSIX allows some of the values in to be increased at X * run time. The pathconf and fpathconf functions allow these values X * to be checked at run time. MINIX does not use this facility. X * The run-time limits are those given in . X */ X X struct stat stbuf; X X switch(name) { X case _PC_LINK_MAX: X /* Fstat the file. If that fails, return -1. */ X if (fstat(fd, &stbuf) != 0) return(-1); X if (S_ISDIR(stbuf.st_mode)) X return(1L); /* no links to directories */ X else X return( (long) LINK_MAX); X X case _PC_MAX_CANON: X return( (long) MAX_CANON); X X case _PC_MAX_INPUT: X return( (long) MAX_INPUT); X X case _PC_NAME_MAX: X return( (long) NAME_MAX); X X case _PC_PATH_MAX: X return( (long) PATH_MAX); X X case _PC_PIPE_BUF: X return( (long) PIPE_BUF); X X case _PC_CHOWN_RESTRICTED: X return( (long) _POSIX_CHOWN_RESTRICTED); X X case _PC_NO_TRUNC: X return( (long) _POSIX_NO_TRUNC); X X case _PC_VDISABLE: X return( (long) _POSIX_VDISABLE); X X default: X errno = EINVAL; X return(-1); X } X} / echo x - _fstat.c sed '/^X/s///' > _fstat.c << '/' X#include X#define fstat _fstat X#include X XPUBLIC int fstat(fd, buffer) Xint fd; Xstruct stat *buffer; X{ X message m; X X m.m1_i1 = fd; X m.m1_p1 = (char *) buffer; X return(_syscall(FS, FSTAT, &m)); X} / echo x - _getcwd.c sed '/^X/s///' > _getcwd.c << '/' X/* getcwd - get current working directory Author: Terrence W. Holm */ X X/* Directly derived from Adri Koppes' pwd(1). X * Modified by Andy Tanenbaum for POSIX (29 Oct. 1989) X */ X X#include X#define getcwd _getcwd X#include X#include X#include X#include X#include X X#define DIRECT_SIZE (sizeof (struct direct)) X XFORWARD _PROTOTYPE( void go_back, (char *path) ); X Xchar *getcwd(buffer, size) Xchar *buffer; Xsize_t size; X/* Get current working directory. */ X{ X int same_device, found, fd; X char *r, path[PATH_MAX + 1], temp_name[NAME_MAX + 1]; X struct stat current, parent, dir_entry; X struct direct d; X X if (buffer == (char *) NULL || size <= 0) { X errno = EINVAL; X return( (char *) NULL); X } X path[0] = '\0'; X X /* Get the inode for the current directory */ X if (stat(".", ¤t) < 0) return( (char *) NULL); X if ( (current.st_mode & S_IFMT) != S_IFDIR) return( (char *) NULL); X X /* Run backwards up the directory tree, grabbing dir names on the way. */ X while (1) { X same_device = 0; X found = 0; X X /* Get the inode for the parent directory */ X if (chdir("..") < 0) return( (char *) NULL); X if (stat(".", &parent) < 0) return( (char *) NULL); X if ( (parent.st_mode & S_IFMT) != S_IFDIR) return( (char *) NULL); X if (current.st_dev == parent.st_dev) same_device = 1; X X /* At the root, "." is the same as ".." */ X if (same_device && current.st_ino == parent.st_ino) break; X X /* Search the parent directory for the current entry */ X if ( (fd = open(".", O_RDONLY)) < 0) return( (char *) NULL); X while (!found && read(fd, (char *)&d, DIRECT_SIZE) == DIRECT_SIZE) { X if (d.d_ino == 0L) continue; /* empty slot */ X if (same_device) { X if (current.st_ino == d.d_ino) found = 1; X } else { X temp_name[0] = '\0'; X strncat(temp_name, d.d_name, NAME_MAX); X if (stat(temp_name, &dir_entry) < 0) { X close(fd); X go_back(path); X return( (char *) NULL); X } X if (current.st_dev == dir_entry.st_dev && X current.st_ino == dir_entry.st_ino) X found = 1; X } X } X X close(fd); X if (!found) { X go_back(path); X return( (char *) NULL); X } X if (strlen(path) + NAME_MAX + 1 > PATH_MAX) { X errno = ERANGE; X go_back(path); X return( (char *) NULL); X } X strcat(path, "/"); X strncat(path, d.d_name, NAME_MAX); X current.st_dev = parent.st_dev; X current.st_ino = parent.st_ino; X } X X /* Copy the reversed path name into */ X if (strlen(path) + 1 > size) { X errno = ERANGE; X go_back(path); X return( (char *) NULL); X } X if (strlen(path) == 0) { X strcpy(buffer, "/"); X return(buffer); X } X *buffer = '\0'; X while ( (r = strrchr(path, '/')) != (char *) NULL) { X strcat(buffer, r); X *r = '\0'; X } X return(chdir(buffer) ? (char *) NULL : buffer); X} X XPRIVATE void go_back(path) Xchar *path; X{ X/* If getcwd() gets in trouble and can't complete normally, reverse the X * path built so far and change there so we end up in the directory that X * we started in. X */ X X char *r; X X while ( (r = strrchr(path, '/')) != (char *) NULL) { X chdir(r+1); X *r = '\0'; X } X} / echo x - _getegid.c sed '/^X/s///' > _getegid.c << '/' X#include X#define getegid _getegid X#include X XPUBLIC gid_t getegid() X{ X message m; X X /* POSIX says that this function is always successful and that no X * return value is reserved to indicate an error. Minix syscalls X * are not always successful and Minix returns the unreserved value X * (gid_t) -1 when there is an error. X */ X if (_syscall(MM, GETGID, &m) < 0) return ( (gid_t) -1); X return( (gid_t) m.m2_i1); X} / echo x - _geteuid.c sed '/^X/s///' > _geteuid.c << '/' X#include X#define geteuid _geteuid X#include X XPUBLIC uid_t geteuid() X{ X message m; X X /* POSIX says that this function is always successful and that no X * return value is reserved to indicate an error. Minix syscalls X * are not always successful and Minix returns the unreserved value X * (uid_t) -1 when there is an error. X */ X if (_syscall(MM, GETUID, &m) < 0) return ( (uid_t) -1); X return( (uid_t) m.m2_i1); X} / echo x - _getgid.c sed '/^X/s///' > _getgid.c << '/' X#include X#define getgid _getgid X#include X XPUBLIC gid_t getgid() X{ X message m; X X return( (gid_t) _syscall(MM, GETGID, &m)); X} / echo x - _getgroups.c sed '/^X/s///' > _getgroups.c << '/' X/* getgroups.c POSIX 4.2.3 X * int getgroups(gidsetsize, grouplist); X * X * This call relates to suplementary group ids, which are not X * supported in MINIX. X */ X X#include X#define getgroups _getgroups X#include X#include X XPUBLIC int getgroups(gidsetsize, grouplist) Xint gidsetsize; Xgid_t grouplist[]; X{ X return(0); X} / echo x - _getpid.c sed '/^X/s///' > _getpid.c << '/' X#include X#define getpid _getpid X#include X XPUBLIC pid_t getpid() X{ X message m; X X return(_syscall(MM, GETPID, &m)); X} / echo x - _getppid.c sed '/^X/s///' > _getppid.c << '/' X#include X#define getppid _getppid X#include X XPUBLIC pid_t getppid() X{ X message m; X X /* POSIX says that this function is always successful and that no X * return value is reserved to indicate an error. Minix syscalls X * are not always successful and Minix returns the reserved value X * (pid_t) -1 when there is an error. X */ X if (_syscall(MM, GETPID, &m) < 0) return ( (pid_t) -1); X return( (pid_t) m.m2_i1); X} / echo x - _getuid.c sed '/^X/s///' > _getuid.c << '/' X#include X#define getuid _getuid X#include X XPUBLIC uid_t getuid() X{ X message m; X X return( (uid_t) _syscall(MM, GETUID, &m)); X} / echo x - _gtty.c sed '/^X/s///' > _gtty.c << '/' X#include X#define gtty _gtty X#define ioctl _ioctl X#include X XPUBLIC int gtty(fd, argp) Xint fd; Xstruct sgttyb *argp; X{ X return(ioctl(fd, TIOCGETP, argp)); X} / echo x - _ioctl.c sed '/^X/s///' > _ioctl.c << '/' X#include X#define ioctl _ioctl X#include X#include X XPUBLIC int ioctl(fd, request, argp) Xint fd; Xint request; Xstruct sgttyb *argp; X{ X int n; X long erase, kill, intr, quit, xon, xoff, eof, brk, speed; X struct tchars *argt; X message m; X X m.TTY_LINE = fd; X m.TTY_REQUEST = request; X X switch(request) { X case TIOCSETP: X erase = argp->sg_erase & BYTE; X kill = argp->sg_kill & BYTE; X speed = ((argp->sg_ospeed & BYTE) << 8) | (argp->sg_ispeed & BYTE); X m.TTY_SPEK = (speed << 16) | (erase << 8) | kill; X m.TTY_FLAGS = argp->sg_flags; X return(_syscall(FS, IOCTL, &m)); X X case TIOCSETC: X argt = (struct tchars * /* kludge */) argp; X intr = argt->t_intrc & BYTE; X quit = argt->t_quitc & BYTE; X xon = argt->t_startc & BYTE; X xoff = argt->t_stopc & BYTE; X eof = argt->t_eofc & BYTE; X brk = argt->t_brkc & BYTE; /* not used at the moment */ X m.TTY_SPEK = (intr<<24) | (quit<<16) | (xon<<8) | (xoff<<0); X m.TTY_FLAGS = (eof<<8) | (brk<<0); X return(_syscall(FS, IOCTL, &m)); X X case TIOCGETP: X n = _syscall(FS, IOCTL, &m); X argp->sg_erase = (m.TTY_SPEK >> 8) & BYTE; X argp->sg_kill = (m.TTY_SPEK >> 0) & BYTE; X argp->sg_flags = m.TTY_FLAGS & 0xFFFFL; X speed = (m.TTY_SPEK >> 16) & 0xFFFFL; X argp->sg_ispeed = speed & BYTE; X argp->sg_ospeed = (speed >> 8) & BYTE; X return(n); X X case TIOCGETC: X n = _syscall(FS, IOCTL, &m); X argt = (struct tchars *) argp; X argt->t_intrc = (m.TTY_SPEK >> 24) & BYTE; X argt->t_quitc = (m.TTY_SPEK >> 16) & BYTE; X argt->t_startc = (m.TTY_SPEK >> 8) & BYTE; X argt->t_stopc = (m.TTY_SPEK >> 0) & BYTE; X argt->t_eofc = (m.TTY_FLAGS >> 8) & BYTE; X argt->t_brkc = (m.TTY_FLAGS >> 0) & BYTE; X return(n); X X case TIOCFLUSH: X m.TTY_FLAGS = (int /* kludge */) argp; X return(_syscall(FS, IOCTL, &m)); X X default: X m.ADDRESS = (char *) argp; X return(_syscall(FS, IOCTL, &m)); X } X} / echo x - _isatty.c sed '/^X/s///' > _isatty.c << '/' X#include X#define isatty _isatty X#include X#include X#include X XPUBLIC int isatty(fd) Xint fd; X{ X message m; X X m.TTY_REQUEST = TIOCGETP; X m.TTY_LINE = fd; X if (_syscall(FS, IOCTL, &m) < 0) return(0); X return(1); X} / echo x - _kill.c sed '/^X/s///' > _kill.c << '/' X#include X#define kill _kill X#include X XPUBLIC int kill(proc, sig) Xint proc; /* which process is to be sent the signal */ Xint sig; /* signal number */ X{ X message m; X X m.m1_i1 = proc; X m.m1_i2 = sig; X return(_syscall(MM, KILL, &m)); X} / echo x - _link.c sed '/^X/s///' > _link.c << '/' X#include X#define link _link X#include X#include X XPUBLIC int link(name, name2) X_CONST char *name, *name2; X{ X message m; X X m.m1_i1 = strlen(name) + 1; X m.m1_i2 = strlen(name2) + 1; X m.m1_p1 = (char *) name; X m.m1_p2 = (char *) name2; X return(_syscall(FS, LINK, &m)); X} / echo x - _lseek.c sed '/^X/s///' > _lseek.c << '/' X#include X#define lseek _lseek X#include X XPUBLIC off_t lseek(fd, offset, whence) Xint fd; Xoff_t offset; Xint whence; X{ X message m; X X m.m2_i1 = fd; X m.m2_l1 = offset; X m.m2_i2 = whence; X if (_syscall(FS, LSEEK, &m) < 0) return( (off_t) -1); X return( (off_t) m.m2_l1); X} / echo x - _mkdir.c sed '/^X/s///' > _mkdir.c << '/' X#include X#define mkdir _mkdir X#include X#include X XPUBLIC int mkdir(name, mode) X_CONST char *name; XMode_t mode; X{ X message m; X X m.m1_i1 = strlen(name) + 1; X m.m1_i2 = mode; X m.m1_p1 = (char *) name; X return(_syscall(FS, MKDIR, &m)); X} / echo x - _mkfifo.c sed '/^X/s///' > _mkfifo.c << '/' X#include X#define mkfifo _mkfifo X#define mknod4 _mknod4 X#include X#include X XPUBLIC int mkfifo(name, mode) X_CONST char *name; XMode_t mode; X{ X return mknod4(name, mode | S_IFIFO, (Dev_t) 0, (long) 0); X} / echo x - _mknod.c sed '/^X/s///' > _mknod.c << '/' X#include X#define mknod _mknod X#define mknod4 _mknod4 X#include X XPUBLIC int mknod(name, mode, dev) X_CONST char *name; XMode_t mode; XDev_t dev; X{ X return mknod4(name, mode, dev, (long) 0); X} / echo x - _mknod4.c sed '/^X/s///' > _mknod4.c << '/' X#include X#define mknod4 _mknod4 X#include X#include X#include X XPUBLIC int mknod4(name, mode, dev, size) X_CONST char *name; XMode_t mode; XDev_t dev; Xlong size; X{ X message m; X X m.m1_i1 = strlen(name) + 1; X m.m1_i2 = mode; X m.m1_i3 = dev; X m.m1_p1 = (char *) name; X if (sizeof(char *) == 2 && size > 0xFFFF) size = 0; X m.m1_p2 = (char *) ((int) size); X return(_syscall(FS, MKNOD, &m)); X} / echo x - _mktemp.c sed '/^X/s///' > _mktemp.c << '/' X/* mktemp - make a name for a temporary file */ X X#include X#define access _access X#define getpid _getpid X#define mktemp _mktemp X#include X XPUBLIC char *mktemp(template) Xchar *template; X{ X register int k; X register char *p; X register pid_t pid; X X pid = getpid(); /* get process id as semi-unique number */ X p = template; X while (*p != 0) p++; /* find end of string */ X X /* Replace XXXXXX at end of template with a letter, then as many of the X * trailing digits of the pid as fit. X */ X while (*--p == 'X') { X *p = '0' + (pid % 10); X pid /= 10; X } X if (*++p != 0) { X for (k = 'a'; k <= 'z'; k++) { X *p = k; X if (access(template, F_OK) < 0) return(template); X } X } X return("/"); X} / echo x - _mount.c sed '/^X/s///' > _mount.c << '/' X#include X#define mount _mount X#include X#include X XPUBLIC int mount(special, name, rwflag) Xchar *name, *special; Xint rwflag; X{ X message m; X X m.m1_i1 = strlen(special) + 1; X m.m1_i2 = strlen(name) + 1; X m.m1_i3 = rwflag; X m.m1_p1 = special; X m.m1_p2 = name; X return(_syscall(FS, MOUNT, &m)); X} / echo x - _open.c sed '/^X/s///' > _open.c << '/' X#include X#define open _open X#include X#include X#include X X#if _ANSI XPUBLIC int open(const char *name, int flags, ...) X#else XPUBLIC int open(name, flags) X_CONST char *name; Xint flags; X#endif X{ X va_list argp; X message m; X X va_start(argp, flags); X if (flags & O_CREAT) { X m.m1_i1 = strlen(name) + 1; X m.m1_i2 = flags; X m.m1_i3 = va_arg(argp, Mode_t); X m.m1_p1 = (char *) name; X } else { X _loadname(name, &m); X m.m3_i2 = flags; X } X va_end(argp); X return (_syscall(FS, OPEN, &m)); X} / echo x - _pathconf.c sed '/^X/s///' > _pathconf.c << '/' X/* POSIX pathconf (Sec. 5.7.1) Author: Andy Tanenbaum */ X X#include X#define close _close X#define open _open X#define pathconf _pathconf X#include X#include X#include X XPUBLIC long pathconf(path, name) X_CONST char *path; /* name of file being interrogated */ Xint name; /* property being inspected */ X{ X/* POSIX allows some of the values in to be increased at X * run time. The pathconf and fpathconf functions allow these values X * to be checked at run time. MINIX does not use this facility. X * The run-time limits are those given in . X */ X X int fd; X long val; X X if ( (fd = open(path, O_RDONLY)) < 0) return(-1L); X val = fpathconf(fd, name); X close(fd); X return(val); X} / echo x - _pause.c sed '/^X/s///' > _pause.c << '/' X#include X#define pause _pause X#include X XPUBLIC int pause() X{ X message m; X X return(_syscall(MM, PAUSE, &m)); X} / echo x - _pipe.c sed '/^X/s///' > _pipe.c << '/' X#include X#define pipe _pipe X#include X XPUBLIC int pipe(fild) Xint fild[2]; X{ X message m; X X if (_syscall(FS, PIPE, &m) < 0) return(-1); X fild[0] = m.m1_i1; X fild[1] = m.m1_i2; X return(0); X} / echo x - _ptrace.c sed '/^X/s///' > _ptrace.c << '/' X#include X#define ptrace _ptrace X#include X XPUBLIC long ptrace(req, pid, addr, data) Xint req; Xpid_t pid; Xlong addr; Xlong data; X{ X message m; X X m.m2_i1 = pid; X m.m2_i2 = req; X m.m2_l1 = addr; X m.m2_l2 = data; X if (_syscall(MM, PTRACE, &m) < 0) return(-1); X X /* There was no error, but -1 is a legal return value. Clear errno if X * necessary to distinguish this case. _syscall has set errno to nonzero X * for the error case. X */ X if (m.m2_l2 == -1) errno = 0; X return(m.m2_l2); X} / echo x - _read.c sed '/^X/s///' > _read.c << '/' X#include X#define read _read X#include X XPUBLIC ssize_t read(fd, buffer, nbytes) Xint fd; Xvoid *buffer; Xsize_t nbytes; X{ X message m; X X m.m1_i1 = fd; X m.m1_i2 = nbytes; X m.m1_p1 = (char *) buffer; X return(_syscall(FS, READ, &m)); X} / echo x - _rename.c sed '/^X/s///' > _rename.c << '/' X#include X#define rename _rename X#include X#include X XPUBLIC int rename(name, name2) X_CONST char *name, *name2; X{ X message m; X X m.m1_i1 = strlen(name) + 1; X m.m1_i2 = strlen(name2) + 1; X m.m1_p1 = (char *) name; X m.m1_p2 = (char *) name2; X return(_syscall(FS, RENAME, &m)); X} / echo x - _rmdir.c sed '/^X/s///' > _rmdir.c << '/' X#include X#define rmdir _rmdir X#include X XPUBLIC int rmdir(name) X_CONST char *name; X{ X message m; X X _loadname(name, &m); X return(_syscall(FS, RMDIR, &m)); X} / echo x - _setgid.c sed '/^X/s///' > _setgid.c << '/' X#include X#define setgid _setgid X#include X XPUBLIC int setgid(grp) Xgid_t grp; X{ X message m; X X m.m1_i1 = (int) grp; X return(_syscall(MM, SETGID, &m)); X} / echo x - _setuid.c sed '/^X/s///' > _setuid.c << '/' X#include X#define setuid _setuid X#include X XPUBLIC int setuid(usr) XUid_t usr; X{ X message m; X X m.m1_i1 = usr; X return(_syscall(MM, SETUID, &m)); X} / echo x - _sigaction.c sed '/^X/s///' > _sigaction.c << '/' X#include X#define sigaction _sigaction X#include X#include X X_PROTOTYPE(int __sigreturn, (void)); X XPUBLIC int sigaction(sig, act, oact) Xint sig; X_CONST struct sigaction *act; Xstruct sigaction *oact; X{ X message m; X X m.m1_i2 = sig; X X /* XXX - yet more type puns because message struct is short of types. */ X m.m1_p1 = (char *) act; X m.m1_p2 = (char *) oact; X m.m1_p3 = (char *) __sigreturn; X X return(_syscall(MM, SIGACTION, &m)); X} / echo x - _sigpending.c sed '/^X/s///' > _sigpending.c << '/' X#include X#define sigpending _sigpending X#include X XPUBLIC int sigpending(set) Xsigset_t *set; X{ X message m; X X if (_syscall(MM, SIGPENDING, &m) < 0) return(-1); X *set = (sigset_t) m.m2_l1; X return(m.m_type); X} / echo x - _sigprocmask.c sed '/^X/s///' > _sigprocmask.c << '/' X#include X#define sigprocmask _sigprocmask X#include X XPUBLIC int sigprocmask(how, set, oset) Xint how; X_CONST sigset_t *set; Xsigset_t *oset; X{ X message m; X X if (set == (sigset_t *) NULL) { X m.m2_i1 = SIG_INQUIRE; X m.m2_l1 = 0; X } else { X m.m2_i1 = how; X m.m2_l1 = (long) *set; X } X if (_syscall(MM, SIGPROCMASK, &m) < 0) return(-1); X if (oset != (sigset_t *) NULL) *oset = (sigset_t) (m.m2_l1); X return(m.m_type); X} / echo x - _sigreturn.c sed '/^X/s///' > _sigreturn.c << '/' X#include X#define sigfillset _sigfillset X#define sigjmp _sigjmp X#define sigprocmask _sigprocmask X#define sigreturn _sigreturn X#include X#include X#include X X_PROTOTYPE( int sigjmp, (jmp_buf jb, int retval)); X X#if (_SETJMP_SAVES_REGS == 0) X/* 'sigreturn' using a short format jmp_buf (no registers saved). */ XPUBLIC int sigjmp(jb, retval) Xjmp_buf jb; Xint retval; X{ X struct sigcontext sc; X X sc.sc_flags = jb[0].__flags; X sc.sc_mask = jb[0].__mask; X X#if (CHIP == INTEL) X sc.sc_pc = (int) jb[0].__pc; X sc.sc_sp = (int) jb[0].__sp; X sc.sc_fp = (int) jb[0].__lb; X#endif X X#if (CHIP == M68000) X sc.sc_pc = (long) jb[0].__pc; X sc.sc_sp = (long) jb[0].__sp; X sc.sc_fp = (long) jb[0].__lb; X#endif X X sc.sc_retreg = retval; X return sigreturn(&sc); X} X#endif X XPUBLIC int sigreturn(scp) Xregister struct sigcontext *scp; X{ X sigset_t set; X X /* The message can't be on the stack, because the stack will vanish out X * from under us. The send part of sendrec will succeed, but when X * a message is sent to restart the current process, who knows what will X * be in the place formerly occupied by the message? X */ X static message m; X X /* Protect against race conditions by blocking all interrupts. */ X sigfillset(&set); /* splhi */ X sigprocmask(SIG_SETMASK, &set, (sigset_t *) NULL); X X m.m2_l1 = scp->sc_mask; X m.m2_i2 = scp->sc_flags; X m.m2_p1 = (char *) scp; X return(_syscall(MM, SIGRETURN, &m)); /* normally this doesn't return */ X} / echo x - _sigset.c sed '/^X/s///' > _sigset.c << '/' X#include X/* XXX - these have to be hidden because signal() uses them and signal() is X * ANSI and not POSIX. It would be surely be better to use macros for the X * library and system uses, and perhaps macros as well as functions for the X * POSIX user interface. The macros would not need underlines. It may be X * inconvenient to match the exact semantics of the current functions X * because the interface is bloated by reporting errors. For library and X * system uses, the signal number is mostly already known to be valid X * before the sigset-changing routines are called. X */ X#define sigaddset _sigaddset X#define sigdelset _sigdelset X#define sigemptyset _sigemptyset X#define sigfillset _sigfillset X#define sigismember _sigismember X#include X X/* Low bit of signal masks. */ X#define SIGBIT_0 ((sigset_t) 1) X X/* Mask of valid signals (0 - _NSIG). Assume the shift doesn't overflow. */ X#define SIGMASK ((SIGBIT_0 << (_NSIG + 1)) - 1) X X#define sigisvalid(signo) ((unsigned) (signo) <= _NSIG) X XPUBLIC int sigaddset(set, signo) Xsigset_t *set; Xint signo; X{ X if (!sigisvalid(signo)) { X errno = EINVAL; X return -1; X } X *set |= SIGBIT_0 << signo; X return 0; X} X XPUBLIC int sigdelset(set, signo) Xsigset_t *set; Xint signo; X{ X if (!sigisvalid(signo)) { X errno = EINVAL; X return -1; X } X *set &= ~(SIGBIT_0 << signo); X return 0; X} X XPUBLIC int sigemptyset(set) Xsigset_t *set; X{ X *set = 0; X return 0; X} X XPUBLIC int sigfillset(set) Xsigset_t *set; X{ X *set = SIGMASK; X return 0; X} X XPUBLIC int sigismember(set, signo) Xsigset_t *set; Xint signo; X{ X if (!sigisvalid(signo)) { X errno = EINVAL; X return -1; X } X if (*set & (SIGBIT_0 << signo)) X return 1; X return 0; X} / echo x - _sigsetjmp.c sed '/^X/s///' > _sigsetjmp.c << '/' X#include X#include X#include X XPUBLIC void siglongjmp(env, val) Xsigjmp_buf env; Xint val; X{ X if (env[0].__flags & SC_SIGCONTEXT) X longjmp(env, val); X else X _longjmp(env, val); X} / echo x - _sigsuspend.c sed '/^X/s///' > _sigsuspend.c << '/' X#include X#define sigsuspend _sigsuspend X#include X XPUBLIC int sigsuspend(set) X_CONST sigset_t *set; X{ X message m; X X m.m2_l1 = (long) *set; X return(_syscall(MM, SIGSUSPEND, &m)); X} / echo x - _sleep.c sed '/^X/s///' > _sleep.c << '/' X/* sleep(3) X * X * Sleep(n) pauses for 'n' seconds by scheduling an alarm interrupt. X * X * Changed to conform with POSIX Terrence W. Holm Oct. 1988 X */ X X#include X#define sleep _sleep X#include X#include X XFORWARD _PROTOTYPE( void _alfun, (int signo) ); X XPRIVATE void _alfun(signo) Xint signo; X{ X/* Dummy signal handler used with sleep() below. */ X} X XPUBLIC unsigned sleep(secs) Xunsigned secs; X{ X unsigned current_secs; X unsigned remaining_secs; X struct sigaction act, oact; X sigset_t ss; X X if (secs == 0) return(0); X X current_secs = alarm(0); /* is there currently an alarm? */ X X if (current_secs == 0 || current_secs > secs) { X act.sa_flags = 0; X act.sa_mask = 0; X act.sa_handler = _alfun; X sigaction(SIGALRM, &act, &oact); X X alarm(secs); X sigemptyset(&ss); X sigsuspend(&ss); X remaining_secs = alarm(0); X X sigaction(SIGALRM, &oact, (struct sigaction *) NULL); X X if (current_secs > secs) X alarm(current_secs - (secs - remaining_secs)); X X return(remaining_secs); X } X X /* Current_secs <= secs, ie. alarm should occur before secs. */ X X alarm(current_secs); X pause(); X remaining_secs = alarm(0); X X alarm(remaining_secs); X X return(secs - (current_secs - remaining_secs)); X} / echo x - _stat.c sed '/^X/s///' > _stat.c << '/' X#include X#define stat _stat X#include X#include X XPUBLIC int stat(name, buffer) X_CONST char *name; Xstruct stat *buffer; X{ X message m; X X m.m1_i1 = strlen(name) + 1; X m.m1_p1 = (char *) name; X m.m1_p2 = (char *) buffer; X return(_syscall(FS, STAT, &m)); X} / echo x - _stime.c sed '/^X/s///' > _stime.c << '/' X#include X#define stime _stime X#include X#include X XPUBLIC int stime(top) Xlong *top; X{ X message m; X X m.m2_l1 = *top; X return(_syscall(FS, STIME, &m)); X} / echo x - _stty.c sed '/^X/s///' > _stty.c << '/' X#include X#define ioctl _ioctl X#define stty _stty X#include X XPUBLIC int stty(fd, argp) Xint fd; Xstruct sgttyb *argp; X{ X return ioctl(fd, TIOCSETP, argp); X} / echo x - _sync.c sed '/^X/s///' > _sync.c << '/' X#include X#define sync _sync X#include X XPUBLIC int sync() X{ X message m; X X return(_syscall(FS, SYNC, &m)); X} / echo x - _time.c sed '/^X/s///' > _time.c << '/' X#include X#define time _time X#include X XPUBLIC time_t time(tp) Xtime_t *tp; X{ X message m; X X if (_syscall(FS, TIME, &m) < 0) return( (time_t) -1); X if (tp != (time_t *) 0) *tp = m.m2_l1; X return(m.m2_l1); X} / echo x - _times.c sed '/^X/s///' > _times.c << '/' X#include X#define times _times X#include X#include X XPUBLIC clock_t times(buf) Xstruct tms *buf; X{ X message m; X X m.m4_l5 = 0; /* return this if system is pre-1.6 */ X if (_syscall(FS, TIMES, &m) < 0) return( (clock_t) -1); X buf->tms_utime = m.m4_l1; X buf->tms_stime = m.m4_l2; X buf->tms_cutime = m.m4_l3; X buf->tms_cstime = m.m4_l4; X return(m.m4_l5); X} / echo x - _umask.c sed '/^X/s///' > _umask.c << '/' X#include X#define umask _umask X#include X XPUBLIC mode_t umask(complmode) XMode_t complmode; X{ X message m; X X m.m1_i1 = complmode; X return( (mode_t) _syscall(FS, UMASK, &m)); X} / echo x - _umount.c sed '/^X/s///' > _umount.c << '/' X#include X#define umount _umount X#include X XPUBLIC int umount(name) X_CONST char *name; X{ X message m; X X _loadname(name, &m); X return(_syscall(FS, UMOUNT, &m)); X} / echo x - _uname.c sed '/^X/s///' > _uname.c << '/' X/* uname - get system name Author: Earl Chew */ X X/* The system name is read from the file /etc/uname. This should be X * world readable but only writeable by system administrators. The X * file contains lines of text. Lines beginning with # are treated X * as comments. All other lines contain information to be read into X * the uname structure. The sequence of the lines matches the sequence X * in which the structure components are declared: X * X * system name Minix X * node name waddles X * release name 1.5 X * version 10 X * machine name IBM_PC X * serial number N/A X */ X X#include X#include X#include X#define uname _uname X#include X#include X X X#ifndef UFILENAME X#define UFILENAME "/etc/uname" X#endif X Xstruct buffer { X char buf[1024]; X char *bp; X char *ep; X}; X X_PROTOTYPE(int __upart, (int fd, struct buffer *b, char *s, size_t n)); X X Xint __upart(fd, b, s, n) Xint fd; Xstruct buffer *b; Xchar *s; Xsize_t n; X{ X register int c; X register char *p; X char *e; X X e = &s[n]; X do { X p = s; X do { X if (b->bp >= b->ep) { X if ((c = read(fd, b->buf, sizeof b->buf)) <= 0) { X if (p == s) X return -1; X else { X b->buf[0] = '\n'; X c = 1; X } X } X b->bp = b->buf; X b->ep = b->buf + c; X } X c = *b->bp++; X if (p < e) *p++ = c; X } while (c != '\n'); X p[-1] = 0; X } while (s[0] == '#'); X return 0; X} X Xint uname(up) Xstruct utsname *up; X{ X static int ufd = -1; X int r; X struct buffer buf; X X if (ufd != -1) { X errno = EBUSY; X return -1; X } X if ((ufd = open(UFILENAME, O_RDONLY)) < 0) { X errno = EACCES; X return -1; X } X r = 0; X buf.bp = buf.ep = buf.buf; X if (__upart(ufd, &buf, up->sysname, sizeof(up->sysname)) || X __upart(ufd, &buf, up->nodename, sizeof(up->nodename)) || X __upart(ufd, &buf, up->release, sizeof(up->release)) || X __upart(ufd, &buf, up->version, sizeof(up->version)) || X __upart(ufd, &buf, up->machine, sizeof(up->machine)) || X __upart(ufd, &buf, up->idnumber, sizeof(up->idnumber))) { X errno = EIO; X r = -1; X } X (void) close(ufd); X ufd = -1; X return r; X} / echo x - _unlink.c sed '/^X/s///' > _unlink.c << '/' X#include X#define unlink _unlink X#include X XPUBLIC int unlink(name) X_CONST char *name; X{ X message m; X X _loadname(name, &m); X return(_syscall(FS, UNLINK, &m)); X} / echo x - _utime.c sed '/^X/s///' > _utime.c << '/' X/* utime(2) for POSIX Authors: Terrence W. Holm & Edwin L. Froese */ X X#include X#define time _time X#define utime _utime X#include X#include X#include X#include X XPUBLIC int utime(name, timp) X_CONST char *name; X_CONST struct utimbuf *timp; X{ X time_t current_time; X message m; X X if (timp == (struct utimbuf *) NULL) { X current_time = time( (time_t *) NULL); X m.m2_l1 = current_time; X m.m2_l2 = current_time; X } else { X m.m2_l1 = timp->actime; X m.m2_l2 = timp->modtime; X } X m.m2_i1 = strlen(name) + 1; X m.m2_p1 = (char *) name; X return(_syscall(FS, UTIME, &m)); X} / echo x - _wait.c sed '/^X/s///' > _wait.c << '/' X#include X#define wait _wait X#include X XPUBLIC pid_t wait(status) Xint *status; X{ X message m; X X if (_syscall(MM, WAIT, &m) < 0) return(-1); X if (status != 0) *status = m.m2_i1; X return(m.m_type); X} / echo x - _waitpid.c sed '/^X/s///' > _waitpid.c << '/' X#include X#define waitpid _waitpid X#include X XPUBLIC pid_t waitpid(pid, status, options) Xpid_t pid; Xint *status; Xint options; X{ X message m; X X m.m1_i1 = pid; X m.m1_i2 = options; X if (_syscall(MM, WAITPID, &m) < 0) return(-1); X if (status != 0) *status = m.m2_i1; X return m.m_type; X} / echo x - _write.c sed '/^X/s///' > _write.c << '/' X#include X#define write _write X#include X XPUBLIC ssize_t write(fd, buffer, nbytes) Xint fd; X_CONST void *buffer; Xsize_t nbytes; X{ X message m; X X m.m1_i1 = fd; X m.m1_i2 = nbytes; X m.m1_p1 = (char *) buffer; X return(_syscall(FS, WRITE, &m)); X} /