/* $NetBSD: function.c,v 1.79.6.1 2023/08/04 13:09:17 martin Exp $ */ /*- * Copyright (c) 1990, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * Cimarron D. Taylor of the University of California, Berkeley. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #ifndef lint #if 0 static char sccsid[] = "from: @(#)function.c 8.10 (Berkeley) 5/4/95"; #else __RCSID("$NetBSD: function.c,v 1.79.6.1 2023/08/04 13:09:17 martin Exp $"); #endif #endif /* not lint */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "find.h" #define COMPARE(a, b) { \ switch (plan->flags) { \ case F_EQUAL: \ return (a == b); \ case F_LESSTHAN: \ return (a < b); \ case F_GREATER: \ return (a > b); \ default: \ abort(); \ } \ } static int64_t find_parsenum(PLAN *, const char *, const char *, char *); static void run_f_exec(PLAN *); int f_always_true(PLAN *, FTSENT *); int f_amin(PLAN *, FTSENT *); int f_anewer(PLAN *, FTSENT *); int f_asince(PLAN *, FTSENT *); int f_atime(PLAN *, FTSENT *); int f_cmin(PLAN *, FTSENT *); int f_cnewer(PLAN *, FTSENT *); int f_csince(PLAN *, FTSENT *); int f_ctime(PLAN *, FTSENT *); int f_delete(PLAN *, FTSENT *); int f_empty(PLAN *, FTSENT *); int f_exec(PLAN *, FTSENT *); int f_execdir(PLAN *, FTSENT *); int f_false(PLAN *, FTSENT *); int f_flags(PLAN *, FTSENT *); int f_fprint(PLAN *, FTSENT *); int f_fstype(PLAN *, FTSENT *); int f_group(PLAN *, FTSENT *); int f_iname(PLAN *, FTSENT *); int f_inum(PLAN *, FTSENT *); int f_links(PLAN *, FTSENT *); int f_ls(PLAN *, FTSENT *); int f_mindepth(PLAN *, FTSENT *); int f_maxdepth(PLAN *, FTSENT *); int f_mmin(PLAN *, FTSENT *); int f_mtime(PLAN *, FTSENT *); int f_name(PLAN *, FTSENT *); int f_newer(PLAN *, FTSENT *); /* * Unimplemented Gnu findutils options * int f_newerBB(PLAN *, FTSENT *); int f_newerBa(PLAN *, FTSENT *); int f_newerBc(PLAN *, FTSENT *); int f_newerBm(PLAN *, FTSENT *); int f_newerBt(PLAN *, FTSENT *); int f_neweraB(PLAN *, FTSENT *); int f_newerac(PLAN *, FTSENT *); int f_neweram(PLAN *, FTSENT *); int f_newerca(PLAN *, FTSENT *); int f_newercm(PLAN *, FTSENT *); int f_newercB(PLAN *, FTSENT *); int f_newermB(PLAN *, FTSENT *); int f_newerma(PLAN *, FTSENT *); int f_newermc(PLAN *, FTSENT *); * */ int f_nogroup(PLAN *, FTSENT *); int f_nouser(PLAN *, FTSENT *); int f_path(PLAN *, FTSENT *); int f_perm(PLAN *, FTSENT *); int f_print(PLAN *, FTSENT *); int f_print0(PLAN *, FTSENT *); int f_printx(PLAN *, FTSENT *); int f_prune(PLAN *, FTSENT *); int f_regex(PLAN *, FTSENT *); int f_since(PLAN *, FTSENT *); int f_size(PLAN *, FTSENT *); int f_type(PLAN *, FTSENT *); int f_user(PLAN *, FTSENT *); int f_not(PLAN *, FTSENT *); int f_or(PLAN *, FTSENT *); static PLAN *c_regex_common(char ***, int, enum ntype, bool); static PLAN *palloc(enum ntype, int (*)(PLAN *, FTSENT *)); extern int dotfd; extern FTS *tree; extern time_t now; /* * find_parsenum -- * Parse a string of the form [+-]# and return the value. */ static int64_t find_parsenum(PLAN *plan, const char *option, const char *vp, char *endch) { int64_t value; const char *str; char *endchar; /* Pointer to character ending conversion. */ /* Determine comparison from leading + or -. */ str = vp; switch (*str) { case '+': ++str; plan->flags = F_GREATER; break; case '-': ++str; plan->flags = F_LESSTHAN; break; default: plan->flags = F_EQUAL; break; } /* * Convert the string with strtol(). Note, if strtol() returns zero * and endchar points to the beginning of the string we know we have * a syntax error. */ value = strtoll(str, &endchar, 10); if (value == 0 && endchar == str) errx(1, "%s: %s: illegal numeric value", option, vp); if (endchar[0] && (endch == NULL || endchar[0] != *endch)) errx(1, "%s: %s: illegal trailing character", option, vp); if (endch) *endch = endchar[0]; return (value); } /* * find_parsedate -- * * Validate the timestamp argument or report an error */ static time_t find_parsedate(PLAN *plan, const char *option, const char *vp) { time_t timestamp; errno = 0; timestamp = parsedate(vp, NULL, NULL); if (timestamp == -1 && errno != 0) errx(1, "%s: %s: invalid timestamp value", option, vp); return timestamp; } /* * The value of n for the inode times (atime, ctime, and mtime) is a range, * i.e. n matches from (n - 1) to n 24 hour periods. This interacts with * -n, such that "-mtime -1" would be less than 0 days, which isn't what the * user wanted. Correct so that -1 is "less than 1". */ #define TIME_CORRECT(p, ttype) \ if ((p)->type == ttype && (p)->flags == F_LESSTHAN) \ ++((p)->t_data); /* * -amin n functions -- * * True if the difference between the file access time and the * current time is n 1 minute periods. */ int f_amin(PLAN *plan, FTSENT *entry) { COMPARE((now - entry->fts_statp->st_atime + SECSPERMIN - 1) / SECSPERMIN, plan->t_data); } PLAN * c_amin(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_AMIN, f_amin); new->t_data = find_parsenum(new, opt, arg, NULL); TIME_CORRECT(new, N_AMIN); return (new); } /* * -anewer file functions -- * * True if the current file has been accessed more recently * than the access time of the file named by the pathname * file. */ int f_anewer(PLAN *plan, FTSENT *entry) { return timespeccmp(&entry->fts_statp->st_atim, &plan->ts_data, >); } PLAN * c_anewer(char ***argvp, int isok, char *opt) { char *filename = **argvp; PLAN *new; struct stat sb; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; if (stat(filename, &sb)) err(1, "%s: %s", opt, filename); new = palloc(N_ANEWER, f_anewer); new->ts_data = sb.st_atim; return (new); } /* * -asince "timestamp" functions -- * * True if the file access time is greater than the timestamp value */ int f_asince(PLAN *plan, FTSENT *entry) { COMPARE(entry->fts_statp->st_atime, plan->t_data); } PLAN * c_asince(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_ASINCE, f_asince); new->t_data = find_parsedate(new, opt, arg); new->flags = F_GREATER; return (new); } /* * -atime n functions -- * * True if the difference between the file access time and the * current time is n 24 hour periods. */ int f_atime(PLAN *plan, FTSENT *entry) { COMPARE((now - entry->fts_statp->st_atime + SECSPERDAY - 1) / SECSPERDAY, plan->t_data); } PLAN * c_atime(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_ATIME, f_atime); new->t_data = find_parsenum(new, opt, arg, NULL); TIME_CORRECT(new, N_ATIME); return (new); } /* * -cmin n functions -- * * True if the difference between the last change of file * status information and the current time is n 24 hour periods. */ int f_cmin(PLAN *plan, FTSENT *entry) { COMPARE((now - entry->fts_statp->st_ctime + SECSPERMIN - 1) / SECSPERMIN, plan->t_data); } PLAN * c_cmin(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_CMIN, f_cmin); new->t_data = find_parsenum(new, opt, arg, NULL); TIME_CORRECT(new, N_CMIN); return (new); } /* * -cnewer file functions -- * * True if the current file has been changed more recently * than the changed time of the file named by the pathname * file. */ int f_cnewer(PLAN *plan, FTSENT *entry) { return timespeccmp(&entry->fts_statp->st_ctim, &plan->ts_data, >); } PLAN * c_cnewer(char ***argvp, int isok, char *opt) { char *filename = **argvp; PLAN *new; struct stat sb; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; if (stat(filename, &sb)) err(1, "%s: %s ", opt, filename); new = palloc(N_CNEWER, f_cnewer); new->ts_data = sb.st_ctim; return (new); } /* * -csince "timestamp" functions -- * * True if the file status change time is greater than the timestamp value */ int f_csince(PLAN *plan, FTSENT *entry) { COMPARE(entry->fts_statp->st_ctime, plan->t_data); } PLAN * c_csince(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_CSINCE, f_csince); new->t_data = find_parsedate(new, opt, arg); new->flags = F_GREATER; return (new); } /* * -ctime n functions -- * * True if the difference between the last change of file * status information and the current time is n 24 hour periods. */ int f_ctime(PLAN *plan, FTSENT *entry) { COMPARE((now - entry->fts_statp->st_ctime + SECSPERDAY - 1) / SECSPERDAY, plan->t_data); } PLAN * c_ctime(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_CTIME, f_ctime); new->t_data = find_parsenum(new, opt, arg, NULL); TIME_CORRECT(new, N_CTIME); return (new); } /* * -delete functions -- * * Always true. Makes its best shot and continues on regardless. */ int f_delete(PLAN *plan __unused, FTSENT *entry) { /* ignore these from fts */ if (strcmp(entry->fts_accpath, ".") == 0 || strcmp(entry->fts_accpath, "..") == 0) return 1; /* sanity check */ if (isdepth == 0 || /* depth off */ (ftsoptions & FTS_NOSTAT) || /* not stat()ing */ !(ftsoptions & FTS_PHYSICAL) || /* physical off */ (ftsoptions & FTS_LOGICAL)) /* or finally, logical on */ errx(1, "-delete: insecure options got turned on"); /* Potentially unsafe - do not accept relative paths whatsoever */ if (entry->fts_level > 0 && strchr(entry->fts_accpath, '/') != NULL) errx(1, "-delete: %s: relative path potentially not safe", entry->fts_accpath); /* Turn off user immutable bits if running as root */ if ((entry->fts_statp->st_flags & (UF_APPEND|UF_IMMUTABLE)) && !(entry->fts_statp->st_flags & (SF_APPEND|SF_IMMUTABLE)) && geteuid() == 0) chflags(entry->fts_accpath, entry->fts_statp->st_flags &= ~(UF_APPEND|UF_IMMUTABLE)); /* rmdir directories, unlink everything else */ if (S_ISDIR(entry->fts_statp->st_mode)) { if (rmdir(entry->fts_accpath) < 0 && errno != ENOTEMPTY) warn("-delete: rmdir(%s)", entry->fts_path); } else { if (unlink(entry->fts_accpath) < 0) warn("-delete: unlink(%s)", entry->fts_path); } /* "succeed" */ return 1; } PLAN * c_delete(char ***argvp __unused, int isok, char *opt) { ftsoptions &= ~FTS_NOSTAT; /* no optimize */ ftsoptions |= FTS_PHYSICAL; /* disable -follow */ ftsoptions &= ~FTS_LOGICAL; /* disable -follow */ isoutput = 1; /* possible output */ isdepth = 1; /* -depth implied */ return palloc(N_DELETE, f_delete); } /* * -depth functions -- * * Always true, causes descent of the directory hierarchy to be done * so that all entries in a directory are acted on before the directory * itself. */ int f_always_true(PLAN *plan, FTSENT *entry) { return (1); } PLAN * c_depth(char ***argvp, int isok, char *opt) { isdepth = 1; return (palloc(N_DEPTH, f_always_true)); } /* * -empty functions -- * * True if the file or directory is empty */ int f_empty(PLAN *plan, FTSENT *entry) { if (S_ISREG(entry->fts_statp->st_mode) && entry->fts_statp->st_size == 0) return (1); if (S_ISDIR(entry->fts_statp->st_mode)) { struct dirent *dp; int empty; DIR *dir; empty = 1; dir = opendir(entry->fts_accpath); if (dir == NULL) return (0); for (dp = readdir(dir); dp; dp = readdir(dir)) if (dp->d_name[0] != '.' || (dp->d_name[1] != '\0' && (dp->d_name[1] != '.' || dp->d_name[2] != '\0'))) { empty = 0; break; } closedir(dir); return (empty); } return (0); } PLAN * c_empty(char ***argvp, int isok, char *opt) { ftsoptions &= ~FTS_NOSTAT; return (palloc(N_EMPTY, f_empty)); } /* * [-exec | -ok] utility [arg ... ] ; functions -- * [-exec | -ok] utility [arg ... ] {} + functions -- * * If the end of the primary expression is delimited by a * semicolon: true if the executed utility returns a zero value * as exit status. If "{}" occurs anywhere, it gets replaced by * the current pathname. * * If the end of the primary expression is delimited by a plus * sign: always true. Pathnames for which the primary is * evaluated shall be aggregated into sets. The utility will be * executed once per set, with "{}" replaced by the entire set of * pathnames (as if xargs). "{}" must appear last. * * The current directory for the execution of utility is the same * as the current directory when the find utility was started. * * The primary -ok is different in that it requests affirmation * of the user before executing the utility. */ int f_exec(PLAN *plan, FTSENT *entry) { size_t cnt; int l; pid_t pid; int status; if (plan->flags & F_PLUSSET) { /* * Confirm sufficient buffer space, then copy the path * to the buffer. */ l = strlen(entry->fts_path); if (plan->ep_p + l < plan->ep_ebp) { plan->ep_bxp[plan->ep_narg++] = strcpy(plan->ep_p, entry->fts_path); plan->ep_p += l + 1; if (plan->ep_narg == plan->ep_maxargs) run_f_exec(plan); } else { /* * Without sufficient space to copy in the next * argument, run the command to empty out the * buffer before re-attepting the copy. */ run_f_exec(plan); if ((plan->ep_p + l < plan->ep_ebp)) { plan->ep_bxp[plan->ep_narg++] = strcpy(plan->ep_p, entry->fts_path); plan->ep_p += l + 1; } else errx(1, "insufficient space for argument"); } return (1); } else { for (cnt = 0; plan->e_argv[cnt]; ++cnt) if (plan->e_len[cnt]) brace_subst(plan->e_orig[cnt], &plan->e_argv[cnt], entry->fts_path, &plan->e_len[cnt]); if (plan->flags & F_NEEDOK && !queryuser(plan->e_argv)) return (0); /* Don't mix output of command with find output. */ fflush(stdout); fflush(stderr); switch (pid = vfork()) { case -1: err(1, "vfork"); /* NOTREACHED */ case 0: /* change dir back from where we started */ if (!(ftsoptions & FTS_NOCHDIR) && fchdir(dotfd)) { warn("chdir"); _exit(1); } execvp(plan->e_argv[0], plan->e_argv); warn("%s", plan->e_argv[0]); _exit(1); } pid = waitpid(pid, &status, 0); return (pid != -1 && WIFEXITED(status) && !WEXITSTATUS(status)); } } static void run_f_exec(PLAN *plan) { pid_t pid; int rval, status; /* Ensure arg list is null terminated. */ plan->ep_bxp[plan->ep_narg] = NULL; /* Don't mix output of command with find output. */ fflush(stdout); fflush(stderr); switch (pid = vfork()) { case -1: err(1, "vfork"); /* NOTREACHED */ case 0: /* change dir back from where we started */ if (!(ftsoptions & FTS_NOCHDIR) && fchdir(dotfd)) { warn("chdir"); _exit(1); } execvp(plan->e_argv[0], plan->e_argv); warn("%s", plan->e_argv[0]); _exit(1); } /* Clear out the argument list. */ plan->ep_narg = 0; plan->ep_bxp[plan->ep_narg] = NULL; /* As well as the argument buffer. */ plan->ep_p = plan->ep_bbp; *plan->ep_p = '\0'; pid = waitpid(pid, &status, 0); if (WIFEXITED(status)) rval = WEXITSTATUS(status); else rval = -1; /* * If we have a non-zero exit status, preserve it so find(1) can * later exit with it. */ if (rval) plan->ep_rval = rval; } /* * c_exec -- * build three parallel arrays, one with pointers to the strings passed * on the command line, one with (possibly duplicated) pointers to the * argv array, and one with integer values that are lengths of the * strings, but also flags meaning that the string has to be massaged. * * If -exec ... {} +, use only the first array, but make it large * enough to hold 5000 args (cf. src/usr.bin/xargs/xargs.c for a * discussion), and then allocate ARG_MAX - 4K of space for args. */ PLAN * c_exec(char ***argvp, int isok, char *opt) { PLAN *new; /* node returned */ size_t cnt; int brace, lastbrace; char **argv, **ap, *p; isoutput = 1; new = palloc(N_EXEC, f_exec); if (isok) new->flags |= F_NEEDOK; /* * Terminate if we encounter an arg exactly equal to ";", or an * arg exactly equal to "+" following an arg exactly equal to * "{}". */ for (ap = argv = *argvp, brace = 0;; ++ap) { if (!*ap) errx(1, "%s: no terminating \";\" or \"+\"", opt); lastbrace = brace; brace = 0; if (strcmp(*ap, "{}") == 0) brace = 1; if (strcmp(*ap, ";") == 0) break; if (strcmp(*ap, "+") == 0 && lastbrace) { new->flags |= F_PLUSSET; break; } } /* * POSIX says -ok ... {} + "need not be supported," and it does * not make much sense anyway. */ if (new->flags & F_NEEDOK && new->flags & F_PLUSSET) errx(1, "%s: terminating \"+\" not permitted.", opt); if (new->flags & F_PLUSSET) { size_t c, bufsize; cnt = ap - *argvp - 1; /* units are words */ new->ep_maxargs = ARG_MAX / (sizeof (char *) + 16); if (new->ep_maxargs > 5000) new->ep_maxargs = 5000; new->e_argv = emalloc((cnt + new->ep_maxargs) * sizeof(*new->e_argv)); /* We start stuffing arguments after the user's last one. */ new->ep_bxp = &new->e_argv[cnt]; new->ep_narg = 0; /* * Count up the space of the user's arguments, and * subtract that from what we allocate. */ #define MAXARG (ARG_MAX - 4 * 1024) for (argv = *argvp, c = 0, cnt = 0; argv < ap; ++argv, ++cnt) { c += strlen(*argv) + 1; if (c >= MAXARG) errx(1, "Arguments too long"); new->e_argv[cnt] = *argv; } if (c + new->ep_maxargs * sizeof (char *) >= MAXARG) errx(1, "Arguments too long"); bufsize = MAXARG - c - new->ep_maxargs * sizeof (char *); /* * Allocate, and then initialize current, base, and * end pointers. */ new->ep_p = new->ep_bbp = emalloc(bufsize + 1); new->ep_ebp = new->ep_bbp + bufsize - 1; new->ep_rval = 0; } else { /* !F_PLUSSET */ cnt = ap - *argvp + 1; new->e_argv = emalloc(cnt * sizeof(*new->e_argv)); new->e_orig = emalloc(cnt * sizeof(*new->e_orig)); new->e_len = emalloc(cnt * sizeof(*new->e_len)); for (argv = *argvp, cnt = 0; argv < ap; ++argv, ++cnt) { new->e_orig[cnt] = *argv; for (p = *argv; *p; ++p) if (p[0] == '{' && p[1] == '}') { new->e_argv[cnt] = emalloc(MAXPATHLEN); new->e_len[cnt] = MAXPATHLEN; break; } if (!*p) { new->e_argv[cnt] = *argv; new->e_len[cnt] = 0; } } new->e_orig[cnt] = NULL; } new->e_argv[cnt] = NULL; *argvp = argv + 1; return (new); } /* * -execdir utility [arg ... ] ; functions -- * * True if the executed utility returns a zero value as exit status. * The end of the primary expression is delimited by a semicolon. If * "{}" occurs anywhere, it gets replaced by the unqualified pathname. * The current directory for the execution of utility is the same as * the directory where the file lives. */ int f_execdir(PLAN *plan, FTSENT *entry) { size_t cnt; pid_t pid; int status; char *file; /* XXX - if file/dir ends in '/' this will not work -- can it? */ if ((file = strrchr(entry->fts_path, '/'))) file++; else file = entry->fts_path; for (cnt = 0; plan->e_argv[cnt]; ++cnt) if (plan->e_len[cnt]) brace_subst(plan->e_orig[cnt], &plan->e_argv[cnt], file, &plan->e_len[cnt]); /* don't mix output of command with find output */ fflush(stdout); fflush(stderr); switch (pid = vfork()) { case -1: err(1, "fork"); /* NOTREACHED */ case 0: execvp(plan->e_argv[0], plan->e_argv); warn("%s", plan->e_argv[0]); _exit(1); } pid = waitpid(pid, &status, 0); return (pid != -1 && WIFEXITED(status) && !WEXITSTATUS(status)); } /* * c_execdir -- * build three parallel arrays, one with pointers to the strings passed * on the command line, one with (possibly duplicated) pointers to the * argv array, and one with integer values that are lengths of the * strings, but also flags meaning that the string has to be massaged. */ PLAN * c_execdir(char ***argvp, int isok, char *opt) { PLAN *new; /* node returned */ size_t cnt; char **argv, **ap, *p; ftsoptions &= ~FTS_NOSTAT; isoutput = 1; new = palloc(N_EXECDIR, f_execdir); for (ap = argv = *argvp;; ++ap) { if (!*ap) errx(1, "%s: no terminating \";\"", opt); if (**ap == ';') break; } cnt = ap - *argvp + 1; new->e_argv = emalloc(cnt * sizeof(*new->e_argv)); new->e_orig = emalloc(cnt * sizeof(*new->e_orig)); new->e_len = emalloc(cnt * sizeof(*new->e_len)); for (argv = *argvp, cnt = 0; argv < ap; ++argv, ++cnt) { new->e_orig[cnt] = *argv; for (p = *argv; *p; ++p) if (p[0] == '{' && p[1] == '}') { new->e_argv[cnt] = emalloc(MAXPATHLEN); new->e_len[cnt] = MAXPATHLEN; break; } if (!*p) { new->e_argv[cnt] = *argv; new->e_len[cnt] = 0; } } new->e_argv[cnt] = new->e_orig[cnt] = NULL; *argvp = argv + 1; return (new); } PLAN * c_exit(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; /* not technically true, but otherwise '-print' is implied */ isoutput = 1; new = palloc(N_EXIT, f_always_true); if (arg) { (*argvp)++; new->exit_val = find_parsenum(new, opt, arg, NULL); } else new->exit_val = 0; return (new); } /* * -false function */ int f_false(PLAN *plan, FTSENT *entry) { return (0); } PLAN * c_false(char ***argvp, int isok, char *opt) { return (palloc(N_FALSE, f_false)); } /* * -flags [-]flags functions -- */ int f_flags(PLAN *plan, FTSENT *entry) { uint32_t flags; flags = entry->fts_statp->st_flags; if (plan->flags == F_ATLEAST) return ((plan->f_data | flags) == flags); else return (flags == plan->f_data); /* NOTREACHED */ } PLAN * c_flags(char ***argvp, int isok, char *opt) { char *flags = **argvp; PLAN *new; u_long flagset; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_FLAGS, f_flags); if (*flags == '-') { new->flags = F_ATLEAST; ++flags; } flagset = 0; if ((strcmp(flags, "none") != 0) && (string_to_flags(&flags, &flagset, NULL) != 0)) errx(1, "%s: %s: illegal flags string", opt, flags); new->f_data = flagset; return (new); } /* * -follow functions -- * * Always true, causes symbolic links to be followed on a global * basis. */ PLAN * c_follow(char ***argvp, int isok, char *opt) { ftsoptions &= ~FTS_PHYSICAL; ftsoptions |= FTS_LOGICAL; return (palloc(N_FOLLOW, f_always_true)); } /* -fprint functions -- * * Causes the current pathame to be written to the defined output file. */ int f_fprint(PLAN *plan, FTSENT *entry) { if (-1 == fprintf(plan->fprint_file, "%s\n", entry->fts_path)) warn("fprintf"); return(1); /* no descriptors are closed; they will be closed by operating system when this find command exits. */ } PLAN * c_fprint(char ***argvp, int isok, char *opt) { PLAN *new; isoutput = 1; /* do not assume -print */ new = palloc(N_FPRINT, f_fprint); if (NULL == (new->fprint_file = fopen(**argvp, "w"))) err(1, "%s: %s: cannot create file", opt, **argvp); (*argvp)++; return (new); } /* * -fstype functions -- * * True if the file is of a certain type. */ int f_fstype(PLAN *plan, FTSENT *entry) { static dev_t curdev; /* need a guaranteed illegal dev value */ static int first = 1; struct statvfs sb; static short val; static char fstype[sizeof(sb.f_fstypename)]; char *p, save[2]; memset(&save, 0, sizeof save); /* XXX gcc */ /* Only check when we cross mount point. */ if (first || curdev != entry->fts_statp->st_dev) { curdev = entry->fts_statp->st_dev; /* * Statfs follows symlinks; find wants the link's file system, * not where it points. */ if (entry->fts_info == FTS_SL || entry->fts_info == FTS_SLNONE) { if ((p = strrchr(entry->fts_accpath, '/')) != NULL) ++p; else p = entry->fts_accpath; save[0] = p[0]; p[0] = '.'; save[1] = p[1]; p[1] = '\0'; } else p = NULL; if (statvfs(entry->fts_accpath, &sb)) err(1, "%s", entry->fts_accpath); if (p) { p[0] = save[0]; p[1] = save[1]; } first = 0; /* * Further tests may need both of these values, so * always copy both of them. */ val = sb.f_flag; strlcpy(fstype, sb.f_fstypename, sizeof(fstype)); } switch (plan->flags) { case F_MTFLAG: return (val & plan->mt_data); case F_MTTYPE: return (strncmp(fstype, plan->c_data, sizeof(fstype)) == 0); default: abort(); } } PLAN * c_fstype(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_FSTYPE, f_fstype); switch (*arg) { case 'l': if (!strcmp(arg, "local")) { new->flags = F_MTFLAG; new->mt_data = MNT_LOCAL; return (new); } break; case 'r': if (!strcmp(arg, "rdonly")) { new->flags = F_MTFLAG; new->mt_data = MNT_RDONLY; return (new); } break; } new->flags = F_MTTYPE; new->c_data = arg; return (new); } /* * -group gname functions -- * * True if the file belongs to the group gname. If gname is numeric and * an equivalent of the getgrnam() function does not return a valid group * name, gname is taken as a group ID. */ int f_group(PLAN *plan, FTSENT *entry) { COMPARE(entry->fts_statp->st_gid, plan->g_data); } PLAN * c_group(char ***argvp, int isok, char *opt) { char *gname = **argvp; PLAN *new; struct group *g; gid_t gid; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_GROUP, f_group); g = getgrnam(gname); if (g == NULL) { if (atoi(gname) == 0 && gname[0] != '0' && strcmp(gname, "+0") && strcmp(gname, "-0")) errx(1, "%s: %s: no such group", opt, gname); gid = find_parsenum(new, "-group", gname, NULL); } else { new->flags = F_EQUAL; gid = g->gr_gid; } new->g_data = gid; return (new); } /* * -inum n functions -- * * True if the file has inode # n. */ int f_inum(PLAN *plan, FTSENT *entry) { COMPARE(entry->fts_statp->st_ino, plan->i_data); } PLAN * c_inum(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_INUM, f_inum); new->i_data = find_parsenum(new, opt, arg, NULL); return (new); } /* * -links n functions -- * * True if the file has n links. */ int f_links(PLAN *plan, FTSENT *entry) { COMPARE(entry->fts_statp->st_nlink, plan->l_data); } PLAN * c_links(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_LINKS, f_links); new->l_data = (nlink_t)find_parsenum(new, opt, arg, NULL); return (new); } /* * -ls functions -- * * Always true - prints the current entry to stdout in "ls" format. */ int f_ls(PLAN *plan, FTSENT *entry) { printlong(entry->fts_path, entry->fts_accpath, entry->fts_statp); return (1); } PLAN * c_ls(char ***argvp, int isok, char *opt) { ftsoptions &= ~FTS_NOSTAT; isoutput = 1; return (palloc(N_LS, f_ls)); } /* * - maxdepth n functions -- * * True if the current search depth is less than or equal to the * maximum depth specified */ int f_maxdepth(PLAN *plan, FTSENT *entry) { extern FTS *tree; if (entry->fts_level >= plan->max_data) fts_set(tree, entry, FTS_SKIP); return (entry->fts_level <= plan->max_data); } PLAN * c_maxdepth(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; new = palloc(N_MAXDEPTH, f_maxdepth); new->max_data = atoi(arg); return (new); } /* * - mindepth n functions -- * * True if the current search depth is greater than or equal to the * minimum depth specified */ int f_mindepth(PLAN *plan, FTSENT *entry) { return (entry->fts_level >= plan->min_data); } PLAN * c_mindepth(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; new = palloc(N_MINDEPTH, f_mindepth); new->min_data = atoi(arg); return (new); } /* * -mmin n functions -- * * True if the difference between the file modification time and the * current time is n 24 hour periods. */ int f_mmin(PLAN *plan, FTSENT *entry) { COMPARE((now - entry->fts_statp->st_mtime + SECSPERMIN - 1) / SECSPERMIN, plan->t_data); } PLAN * c_mmin(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_MMIN, f_mmin); new->t_data = find_parsenum(new, opt, arg, NULL); TIME_CORRECT(new, N_MMIN); return (new); } /* * -mtime n functions -- * * True if the difference between the file modification time and the * current time is n 24 hour periods. */ int f_mtime(PLAN *plan, FTSENT *entry) { COMPARE((now - entry->fts_statp->st_mtime + SECSPERDAY - 1) / SECSPERDAY, plan->t_data); } PLAN * c_mtime(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_MTIME, f_mtime); new->t_data = find_parsenum(new, opt, arg, NULL); TIME_CORRECT(new, N_MTIME); return (new); } /* * -name functions -- * * True if the basename of the filename being examined * matches pattern using Pattern Matching Notation S3.14 */ int f_name(PLAN *plan, FTSENT *entry) { return (!fnmatch(plan->c_data, entry->fts_name, 0)); } PLAN * c_name(char ***argvp, int isok, char *opt) { char *pattern = **argvp; PLAN *new; (*argvp)++; new = palloc(N_NAME, f_name); new->c_data = pattern; return (new); } /* * -iname functions -- * * Similar to -name, but does case insensitive matching * */ int f_iname(PLAN *plan, FTSENT *entry) { return (!fnmatch(plan->c_data, entry->fts_name, FNM_CASEFOLD)); } PLAN * c_iname(char ***argvp, int isok, char *opt) { char *pattern = **argvp; PLAN *new; (*argvp)++; new = palloc(N_INAME, f_iname); new->c_data = pattern; return (new); } /* * -newer file functions -- * * True if the current file has been modified more recently * than the modification time of the file named by the pathname * file. */ int f_newer(PLAN *plan, FTSENT *entry) { return timespeccmp(&entry->fts_statp->st_mtim, &plan->ts_data, >); } PLAN * c_newer(char ***argvp, int isok, char *opt) { char *filename = **argvp; PLAN *new; struct stat sb; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; if (stat(filename, &sb)) err(1, "%s: %s", opt, filename); new = palloc(N_NEWER, f_newer); new->ts_data = sb.st_mtim; return (new); } /* * -nogroup functions -- * * True if file belongs to a user ID for which the equivalent * of the getgrnam() 9.2.1 [POSIX.1] function returns NULL. */ int f_nogroup(PLAN *plan, FTSENT *entry) { return (group_from_gid(entry->fts_statp->st_gid, 1) ? 0 : 1); } PLAN * c_nogroup(char ***argvp, int isok, char *opt) { ftsoptions &= ~FTS_NOSTAT; return (palloc(N_NOGROUP, f_nogroup)); } /* * -nouser functions -- * * True if file belongs to a user ID for which the equivalent * of the getpwuid() 9.2.2 [POSIX.1] function returns NULL. */ int f_nouser(PLAN *plan, FTSENT *entry) { return (user_from_uid(entry->fts_statp->st_uid, 1) ? 0 : 1); } PLAN * c_nouser(char ***argvp, int isok, char *opt) { ftsoptions &= ~FTS_NOSTAT; return (palloc(N_NOUSER, f_nouser)); } /* * -path functions -- * * True if the path of the filename being examined * matches pattern using Pattern Matching Notation S3.14 */ int f_path(PLAN *plan, FTSENT *entry) { return (!fnmatch(plan->c_data, entry->fts_path, 0)); } PLAN * c_path(char ***argvp, int isok, char *opt) { char *pattern = **argvp; PLAN *new; (*argvp)++; new = palloc(N_NAME, f_path); new->c_data = pattern; return (new); } /* * -perm functions -- * * The mode argument is used to represent file mode bits. If it starts * with a leading digit, it's treated as an octal mode, otherwise as a * symbolic mode. */ int f_perm(PLAN *plan, FTSENT *entry) { mode_t mode; mode = entry->fts_statp->st_mode & (S_ISUID|S_ISGID|S_ISTXT|S_IRWXU|S_IRWXG|S_IRWXO); if (plan->flags == F_ATLEAST) return ((plan->m_data | mode) == mode); else return (mode == plan->m_data); /* NOTREACHED */ } PLAN * c_perm(char ***argvp, int isok, char *opt) { char *perm = **argvp; PLAN *new; mode_t *set; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_PERM, f_perm); if (*perm == '-') { new->flags = F_ATLEAST; ++perm; } if ((set = setmode(perm)) == NULL) err(1, "%s: Cannot set file mode `%s'", opt, perm); new->m_data = getmode(set, 0); free(set); return (new); } /* * -print functions -- * * Always true, causes the current pathame to be written to * standard output. */ int f_print(PLAN *plan, FTSENT *entry) { (void)printf("%s\n", entry->fts_path); return (1); } int f_print0(PLAN *plan, FTSENT *entry) { (void)fputs(entry->fts_path, stdout); (void)fputc('\0', stdout); return (1); } int f_printx(PLAN *plan, FTSENT *entry) { char *cp; for (cp = entry->fts_path; *cp; cp++) { if (*cp == '\'' || *cp == '\"' || *cp == ' ' || *cp == '$' || *cp == '`' || *cp == '\t' || *cp == '\n' || *cp == '\\') fputc('\\', stdout); fputc(*cp, stdout); } fputc('\n', stdout); return (1); } PLAN * c_print(char ***argvp, int isok, char *opt) { isoutput = 1; return (palloc(N_PRINT, f_print)); } PLAN * c_print0(char ***argvp, int isok, char *opt) { isoutput = 1; return (palloc(N_PRINT0, f_print0)); } PLAN * c_printx(char ***argvp, int isok, char *opt) { isoutput = 1; return (palloc(N_PRINTX, f_printx)); } /* * -prune functions -- * * Prune a portion of the hierarchy. */ int f_prune(PLAN *plan, FTSENT *entry) { if (fts_set(tree, entry, FTS_SKIP)) err(1, "%s", entry->fts_path); return (1); } PLAN * c_prune(char ***argvp, int isok, char *opt) { return (palloc(N_PRUNE, f_prune)); } /* * -regex regexp (and related) functions -- * * True if the complete file path matches the regular expression regexp. * For -regex, regexp is a case-sensitive (basic) regular expression. * For -iregex, regexp is a case-insensitive (basic) regular expression. */ int f_regex(PLAN *plan, FTSENT *entry) { return (regexec(&plan->regexp_data, entry->fts_path, 0, NULL, 0) == 0); } static PLAN * c_regex_common(char ***argvp, int isok, enum ntype type, bool icase) { char errbuf[LINE_MAX]; regex_t reg; char *regexp = **argvp; char *lineregexp; PLAN *new; int rv; size_t len; (*argvp)++; len = strlen(regexp) + 1 + 6; lineregexp = malloc(len); /* max needed */ if (lineregexp == NULL) err(1, NULL); snprintf(lineregexp, len, "^%s(%s%s)$", (regcomp_flags & REG_EXTENDED) ? "" : "\\", regexp, (regcomp_flags & REG_EXTENDED) ? "" : "\\"); rv = regcomp(®, lineregexp, REG_NOSUB|regcomp_flags| (icase ? REG_ICASE : 0)); free(lineregexp); if (rv != 0) { regerror(rv, ®, errbuf, sizeof errbuf); errx(1, "regexp %s: %s", regexp, errbuf); } new = palloc(type, f_regex); new->regexp_data = reg; return (new); } PLAN * c_regex(char ***argvp, int isok, char *opt) { return (c_regex_common(argvp, isok, N_REGEX, false)); } PLAN * c_iregex(char ***argvp, int isok, char *opt) { return (c_regex_common(argvp, isok, N_IREGEX, true)); } /* * -since "timestamp" functions -- * * True if the file modification time is greater than the timestamp value */ int f_since(PLAN *plan, FTSENT *entry) { COMPARE(entry->fts_statp->st_mtime, plan->t_data); } PLAN * c_since(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_SINCE, f_since); new->t_data = find_parsedate(new, opt, arg); new->flags = F_GREATER; return (new); } /* * -size n[c] functions -- * * True if the file size in bytes, divided by an implementation defined * value and rounded up to the next integer, is n. If n is followed by * a c, the size is in bytes. */ #define FIND_SIZE 512 static int divsize = 1; int f_size(PLAN *plan, FTSENT *entry) { off_t size; size = divsize ? (entry->fts_statp->st_size + FIND_SIZE - 1) / FIND_SIZE : entry->fts_statp->st_size; COMPARE(size, plan->o_data); } PLAN * c_size(char ***argvp, int isok, char *opt) { char *arg = **argvp; PLAN *new; char endch; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_SIZE, f_size); endch = 'c'; new->o_data = find_parsenum(new, opt, arg, &endch); if (endch == 'c') divsize = 0; return (new); } /* * -type c functions -- * * True if the type of the file is c, where c is b, c, d, p, f or w * for block special file, character special file, directory, FIFO, * regular file or whiteout respectively. */ int f_type(PLAN *plan, FTSENT *entry) { return ((entry->fts_statp->st_mode & S_IFMT) == plan->m_data); } PLAN * c_type(char ***argvp, int isok, char *opt) { char *typestring = **argvp; PLAN *new; mode_t mask = (mode_t)0; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; switch (typestring[0]) { case 'b': mask = S_IFBLK; break; case 'c': mask = S_IFCHR; break; case 'd': mask = S_IFDIR; break; case 'f': mask = S_IFREG; break; case 'l': mask = S_IFLNK; break; case 'p': mask = S_IFIFO; break; case 's': mask = S_IFSOCK; break; #ifdef S_IFWHT case 'W': case 'w': mask = S_IFWHT; #ifdef FTS_WHITEOUT ftsoptions |= FTS_WHITEOUT; #endif break; #endif /* S_IFWHT */ default: errx(1, "%s: %s: unknown type", opt, typestring); } new = palloc(N_TYPE, f_type); new->m_data = mask; return (new); } /* * -user uname functions -- * * True if the file belongs to the user uname. If uname is numeric and * an equivalent of the getpwnam() S9.2.2 [POSIX.1] function does not * return a valid user name, uname is taken as a user ID. */ int f_user(PLAN *plan, FTSENT *entry) { COMPARE(entry->fts_statp->st_uid, plan->u_data); } PLAN * c_user(char ***argvp, int isok, char *opt) { char *username = **argvp; PLAN *new; struct passwd *p; uid_t uid; (*argvp)++; ftsoptions &= ~FTS_NOSTAT; new = palloc(N_USER, f_user); p = getpwnam(username); if (p == NULL) { if (atoi(username) == 0 && username[0] != '0' && strcmp(username, "+0") && strcmp(username, "-0")) errx(1, "%s: %s: no such user", opt, username); uid = find_parsenum(new, opt, username, NULL); } else { new->flags = F_EQUAL; uid = p->pw_uid; } new->u_data = uid; return (new); } /* * -xdev functions -- * * Always true, causes find not to descend past directories that have a * different device ID (st_dev, see stat() S5.6.2 [POSIX.1]) */ PLAN * c_xdev(char ***argvp, int isok, char *opt) { ftsoptions |= FTS_XDEV; return (palloc(N_XDEV, f_always_true)); } /* * ( expression ) functions -- * * True if expression is true. */ int f_expr(PLAN *plan, FTSENT *entry) { PLAN *p; int state; state = 0; for (p = plan->p_data[0]; p && (state = (p->eval)(p, entry)); p = p->next); return (state); } /* * N_OPENPAREN and N_CLOSEPAREN nodes are temporary place markers. They are * eliminated during phase 2 of find_formplan() --- the '(' node is converted * to a N_EXPR node containing the expression and the ')' node is discarded. */ PLAN * c_openparen(char ***argvp, int isok, char *opt) { return (palloc(N_OPENPAREN, (int (*)(PLAN *, FTSENT *))-1)); } PLAN * c_closeparen(char ***argvp, int isok, char *opt) { return (palloc(N_CLOSEPAREN, (int (*)(PLAN *, FTSENT *))-1)); } /* * ! expression functions -- * * Negation of a primary; the unary NOT operator. */ int f_not(PLAN *plan, FTSENT *entry) { PLAN *p; int state; state = 0; for (p = plan->p_data[0]; p && (state = (p->eval)(p, entry)); p = p->next); return (!state); } PLAN * c_not(char ***argvp, int isok, char *opt) { return (palloc(N_NOT, f_not)); } /* * expression -o expression functions -- * * Alternation of primaries; the OR operator. The second expression is * not evaluated if the first expression is true. */ int f_or(PLAN *plan, FTSENT *entry) { PLAN *p; int state; state = 0; for (p = plan->p_data[0]; p && (state = (p->eval)(p, entry)); p = p->next); if (state) return (1); for (p = plan->p_data[1]; p && (state = (p->eval)(p, entry)); p = p->next); return (state); } PLAN * c_or(char ***argvp, int isok, char *opt) { return (palloc(N_OR, f_or)); } PLAN * c_null(char ***argvp, int isok, char *opt) { return (NULL); } /* * plan_cleanup -- * Check and see if the specified plan has any residual state, * and if so, clean it up as appropriate. * * At the moment, only N_EXEC has state. Two kinds: 1) * lists of files to feed to subprocesses 2) State on exit * statusses of past subprocesses. */ /* ARGSUSED1 */ int plan_cleanup(PLAN *plan, void *arg) { if (plan->type==N_EXEC && plan->ep_narg) run_f_exec(plan); return plan->ep_rval; /* Passed save exit-status up chain */ } static PLAN * palloc(enum ntype t, int (*f)(PLAN *, FTSENT *)) { PLAN *new; if ((new = malloc(sizeof(PLAN))) == NULL) err(1, NULL); memset(new, 0, sizeof(PLAN)); new->type = t; new->eval = f; return (new); }