lib/libutil/login_cap.c

1.8  itojun /*	$NetBSD: login_cap.c,v 1.8 2000/10/12 00:19:57 itojun Exp $	*/
1.1     mjl
1.1     mjl /*-
1.1     mjl  * Copyright (c) 1995,1997 Berkeley Software Design, Inc. All rights reserved.
1.1     mjl  *
1.1     mjl  * Redistribution and use in source and binary forms, with or without
1.1     mjl  * modification, are permitted provided that the following conditions
1.1     mjl  * are met:
1.1     mjl  * 1. Redistributions of source code must retain the above copyright
1.1     mjl  *    notice, this list of conditions and the following disclaimer.
1.1     mjl  * 2. Redistributions in binary form must reproduce the above copyright
1.1     mjl  *    notice, this list of conditions and the following disclaimer in the
1.1     mjl  *    documentation and/or other materials provided with the distribution.
1.1     mjl  * 3. All advertising materials mentioning features or use of this software
1.1     mjl  *    must display the following acknowledgement:
1.1     mjl  *	This product includes software developed by Berkeley Software Design,
1.1     mjl  *	Inc.
1.1     mjl  * 4. The name of Berkeley Software Design, Inc.  may not be used to endorse
1.1     mjl  *    or promote products derived from this software without specific prior
1.1     mjl  *    written permission.
1.1     mjl  *
1.1     mjl  * THIS SOFTWARE IS PROVIDED BY BERKELEY SOFTWARE DESIGN, INC. ``AS IS'' AND
1.1     mjl  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1     mjl  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1     mjl  * ARE DISCLAIMED.  IN NO EVENT SHALL BERKELEY SOFTWARE DESIGN, INC. BE LIABLE
1.1     mjl  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1     mjl  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1     mjl  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1     mjl  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1     mjl  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1     mjl  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1     mjl  * SUCH DAMAGE.
1.1     mjl  *
1.1     mjl  *	BSDI login_cap.c,v 2.13 1998/02/07 03:17:05 prb Exp
1.1     mjl  */
1.6      ad
1.6      ad #include <sys/cdefs.h>
1.6      ad #if defined(LIBC_SCCS) && !defined(lint)
1.8  itojun __RCSID("$NetBSD: login_cap.c,v 1.8 2000/10/12 00:19:57 itojun Exp $");
1.6      ad #endif /* LIBC_SCCS and not lint */
1.1     mjl
1.1     mjl #include <sys/types.h>
1.1     mjl #include <sys/stat.h>
1.1     mjl #include <sys/time.h>
1.1     mjl #include <sys/resource.h>
1.1     mjl
1.4     mjl #include <ctype.h>
1.1     mjl #include <err.h>
1.1     mjl #include <errno.h>
1.1     mjl #include <fcntl.h>
1.1     mjl #include <limits.h>
1.1     mjl #include <login_cap.h>
1.1     mjl #include <paths.h>
1.1     mjl #include <pwd.h>
1.1     mjl #include <stdio.h>
1.1     mjl #include <stdlib.h>
1.1     mjl #include <string.h>
1.1     mjl #include <syslog.h>
1.1     mjl #include <unistd.h>
1.7      ad #include <util.h>
1.1     mjl
1.6      ad static char	*classfiles[] = { _PATH_LOGIN_CONF, 0 };
1.1     mjl
1.6      ad static void	setuserpath(login_cap_t *, char *);
1.6      ad static u_quad_t	multiply(u_quad_t, u_quad_t);
1.6      ad static u_quad_t	strtolimit(char *, char **, int);
1.6      ad static u_quad_t	strtosize(char *, char **, int);
1.6      ad static int	gsetrl(login_cap_t *, int, char *, int type);
1.6      ad static int	setuserenv(login_cap_t *);
1.6      ad static int	isinfinite(const char *);
1.1     mjl
1.1     mjl login_cap_t *
1.6      ad login_getclass(char *class)
1.1     mjl {
1.1     mjl 	login_cap_t *lc;
1.1     mjl 	int res;
1.1     mjl
1.1     mjl 	for (res = 0; classfiles[res]; ++res)
1.1     mjl 		if (secure_path(classfiles[res]) < 0)
1.1     mjl 			return (0);
1.1     mjl
1.1     mjl 	if ((lc = malloc(sizeof(login_cap_t))) == NULL) {
1.1     mjl 		syslog(LOG_ERR, "%s:%d malloc: %m", __FILE__, __LINE__);
1.1     mjl 		return (0);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	lc->lc_cap = 0;
1.1     mjl 	lc->lc_style = 0;
1.1     mjl
1.1     mjl 	if (class == NULL || class[0] == '\0')
1.1     mjl 		class = LOGIN_DEFCLASS;
1.1     mjl
1.1     mjl     	if ((lc->lc_class = strdup(class)) == NULL) {
1.1     mjl 		syslog(LOG_ERR, "%s:%d strdup: %m", __FILE__, __LINE__);
1.1     mjl 		free(lc);
1.1     mjl 		return (0);
1.1     mjl 	}
1.1     mjl
1.8  itojun 	if ((res = cgetent(&lc->lc_cap, classfiles, lc->lc_class)) != 0) {
1.1     mjl 		lc->lc_cap = 0;
1.1     mjl 		switch (res) {
1.1     mjl 		case 1:
1.1     mjl 			syslog(LOG_ERR, "%s: couldn't resolve 'tc'",
1.1     mjl 				lc->lc_class);
1.1     mjl 			break;
1.1     mjl 		case -1:
1.1     mjl 			if ((res = open(classfiles[0], 0)) >= 0)
1.1     mjl 				close(res);
1.1     mjl 			if (strcmp(lc->lc_class, LOGIN_DEFCLASS) == NULL &&
1.1     mjl 			    res < 0)
1.1     mjl 				return (lc);
1.1     mjl 			syslog(LOG_ERR, "%s: unknown class", lc->lc_class);
1.1     mjl 			break;
1.1     mjl 		case -2:
1.1     mjl 			syslog(LOG_ERR, "%s: getting class information: %m",
1.1     mjl 				lc->lc_class);
1.1     mjl 			break;
1.1     mjl 		case -3:
1.1     mjl 			syslog(LOG_ERR, "%s: 'tc' reference loop",
1.1     mjl 				lc->lc_class);
1.1     mjl 			break;
1.1     mjl 		default:
1.1     mjl 			syslog(LOG_ERR, "%s: unexpected cgetent error",
1.1     mjl 				lc->lc_class);
1.1     mjl 			break;
1.1     mjl 		}
1.1     mjl 		free(lc->lc_class);
1.1     mjl 		free(lc);
1.1     mjl 		return (0);
1.1     mjl 	}
1.1     mjl 	return (lc);
1.1     mjl }
1.1     mjl
1.4     mjl login_cap_t *
1.6      ad login_getpwclass(const struct passwd *pwd)
1.4     mjl {
1.4     mjl 	return login_getclass(pwd ? pwd->pw_class : NULL);
1.4     mjl }
1.4     mjl
1.1     mjl char *
1.6      ad login_getcapstr(login_cap_t *lc, char *cap, char *def, char *e)
1.1     mjl {
1.1     mjl 	char *res;
1.1     mjl 	int status;
1.1     mjl
1.1     mjl 	errno = 0;
1.1     mjl
1.2     mjl 	if (!lc || !lc->lc_cap)
1.1     mjl 		return (def);
1.1     mjl
1.1     mjl 	switch (status = cgetstr(lc->lc_cap, cap, &res)) {
1.1     mjl 	case -1:
1.1     mjl 		return (def);
1.1     mjl 	case -2:
1.1     mjl 		syslog(LOG_ERR, "%s: getting capability %s: %m",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		return (e);
1.1     mjl 	default:
1.1     mjl 		if (status >= 0)
1.1     mjl 			return (res);
1.1     mjl 		syslog(LOG_ERR, "%s: unexpected error with capability %s",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		return (e);
1.1     mjl 	}
1.1     mjl }
1.1     mjl
1.1     mjl quad_t
1.6      ad login_getcaptime(login_cap_t *lc, char *cap, quad_t def, quad_t e)
1.1     mjl {
1.1     mjl 	char *ep;
1.1     mjl 	char *res, *sres;
1.1     mjl 	int status;
1.1     mjl 	quad_t q, r;
1.1     mjl
1.1     mjl 	errno = 0;
1.2     mjl 	if (!lc || !lc->lc_cap)
1.1     mjl 		return (def);
1.1     mjl
1.1     mjl 	switch (status = cgetstr(lc->lc_cap, cap, &res)) {
1.1     mjl 	case -1:
1.1     mjl 		return (def);
1.1     mjl 	case -2:
1.1     mjl 		syslog(LOG_ERR, "%s: getting capability %s: %m",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	default:
1.1     mjl 		if (status >= 0)
1.1     mjl 			break;
1.1     mjl 		syslog(LOG_ERR, "%s: unexpected error with capability %s",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	}
1.1     mjl
1.5     mjl 	if (isinfinite(res))
1.1     mjl 		return (RLIM_INFINITY);
1.1     mjl
1.1     mjl 	errno = 0;
1.1     mjl
1.1     mjl 	q = 0;
1.1     mjl 	sres = res;
1.1     mjl 	while (*res) {
1.1     mjl 		r = strtoq(res, &ep, 0);
1.1     mjl 		if (!ep || ep == res ||
1.1     mjl 		    ((r == QUAD_MIN || r == QUAD_MAX) && errno == ERANGE)) {
1.1     mjl invalid:
1.1     mjl 			syslog(LOG_ERR, "%s:%s=%s: invalid time",
1.1     mjl 			    lc->lc_class, cap, sres);
1.1     mjl 			errno = ERANGE;
1.1     mjl 			return (e);
1.1     mjl 		}
1.1     mjl 		switch (*ep++) {
1.1     mjl 		case '\0':
1.1     mjl 			--ep;
1.1     mjl 			break;
1.1     mjl 		case 's': case 'S':
1.1     mjl 			break;
1.1     mjl 		case 'm': case 'M':
1.1     mjl 			r *= 60;
1.1     mjl 			break;
1.1     mjl 		case 'h': case 'H':
1.1     mjl 			r *= 60 * 60;
1.1     mjl 			break;
1.1     mjl 		case 'd': case 'D':
1.1     mjl 			r *= 60 * 60 * 24;
1.1     mjl 			break;
1.1     mjl 		case 'w': case 'W':
1.1     mjl 			r *= 60 * 60 * 24 * 7;
1.1     mjl 			break;
1.1     mjl 		case 'y': case 'Y':	/* Pretty absurd */
1.1     mjl 			r *= 60 * 60 * 24 * 365;
1.1     mjl 			break;
1.1     mjl 		default:
1.1     mjl 			goto invalid;
1.1     mjl 		}
1.1     mjl 		res = ep;
1.1     mjl 		q += r;
1.1     mjl 	}
1.1     mjl 	return (q);
1.1     mjl }
1.1     mjl
1.1     mjl quad_t
1.6      ad login_getcapnum(login_cap_t *lc, char *cap, quad_t def, quad_t e)
1.1     mjl {
1.1     mjl 	char *ep;
1.1     mjl 	char *res;
1.1     mjl 	int status;
1.1     mjl 	quad_t q;
1.1     mjl
1.1     mjl 	errno = 0;
1.2     mjl 	if (!lc || !lc->lc_cap)
1.1     mjl 		return (def);
1.1     mjl
1.1     mjl 	switch (status = cgetstr(lc->lc_cap, cap, &res)) {
1.1     mjl 	case -1:
1.1     mjl 		return (def);
1.1     mjl 	case -2:
1.1     mjl 		syslog(LOG_ERR, "%s: getting capability %s: %m",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	default:
1.1     mjl 		if (status >= 0)
1.1     mjl 			break;
1.1     mjl 		syslog(LOG_ERR, "%s: unexpected error with capability %s",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	}
1.1     mjl
1.5     mjl 	if (isinfinite(res))
1.1     mjl 		return (RLIM_INFINITY);
1.1     mjl
1.1     mjl 	errno = 0;
1.1     mjl     	q = strtoq(res, &ep, 0);
1.1     mjl 	if (!ep || ep == res || ep[0] ||
1.1     mjl 	    ((q == QUAD_MIN || q == QUAD_MAX) && errno == ERANGE)) {
1.1     mjl 		syslog(LOG_ERR, "%s:%s=%s: invalid number",
1.1     mjl 		    lc->lc_class, cap, res);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	}
1.1     mjl 	return (q);
1.1     mjl }
1.1     mjl
1.1     mjl quad_t
1.6      ad login_getcapsize(login_cap_t *lc, char *cap, quad_t def, quad_t e)
1.1     mjl {
1.1     mjl 	char *ep;
1.1     mjl 	char *res;
1.1     mjl 	int status;
1.1     mjl 	quad_t q;
1.1     mjl
1.1     mjl 	errno = 0;
1.1     mjl
1.2     mjl 	if (!lc || !lc->lc_cap)
1.1     mjl 		return (def);
1.1     mjl
1.1     mjl 	switch (status = cgetstr(lc->lc_cap, cap, &res)) {
1.1     mjl 	case -1:
1.1     mjl 		return (def);
1.1     mjl 	case -2:
1.1     mjl 		syslog(LOG_ERR, "%s: getting capability %s: %m",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	default:
1.1     mjl 		if (status >= 0)
1.1     mjl 			break;
1.1     mjl 		syslog(LOG_ERR, "%s: unexpected error with capability %s",
1.1     mjl 		    lc->lc_class, cap);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	errno = 0;
1.1     mjl 	q = strtolimit(res, &ep, 0);
1.1     mjl 	if (!ep || ep == res || (ep[0] && ep[1]) ||
1.1     mjl 	    ((q == QUAD_MIN || q == QUAD_MAX) && errno == ERANGE)) {
1.1     mjl 		syslog(LOG_ERR, "%s:%s=%s: invalid size",
1.1     mjl 		    lc->lc_class, cap, res);
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (e);
1.1     mjl 	}
1.1     mjl 	return (q);
1.1     mjl }
1.1     mjl
1.1     mjl int
1.6      ad login_getcapbool(login_cap_t *lc, char *cap, u_int def)
1.1     mjl {
1.2     mjl 	if (!lc || !lc->lc_cap)
1.1     mjl 		return (def);
1.1     mjl
1.1     mjl 	return (cgetcap(lc->lc_cap, cap, ':') != NULL);
1.1     mjl }
1.1     mjl
1.1     mjl void
1.6      ad login_close(login_cap_t *lc)
1.1     mjl {
1.1     mjl 	if (lc) {
1.1     mjl 		if (lc->lc_class)
1.1     mjl 			free(lc->lc_class);
1.1     mjl 		if (lc->lc_cap)
1.1     mjl 			free(lc->lc_cap);
1.1     mjl 		if (lc->lc_style)
1.1     mjl 			free(lc->lc_style);
1.1     mjl 		free(lc);
1.1     mjl 	}
1.1     mjl }
1.1     mjl
1.7      ad #define	R_CTIME	1
1.7      ad #define	R_CSIZE	2
1.7      ad #define	R_CNUMB	3
1.1     mjl
1.1     mjl static struct {
1.1     mjl 	int	what;
1.1     mjl 	int	type;
1.1     mjl 	char *	name;
1.1     mjl } r_list[] = {
1.7      ad 	{ RLIMIT_CPU,		R_CTIME, "cputime", },
1.7      ad 	{ RLIMIT_FSIZE,		R_CSIZE, "filesize", },
1.7      ad 	{ RLIMIT_DATA,		R_CSIZE, "datasize", },
1.7      ad 	{ RLIMIT_STACK,		R_CSIZE, "stacksize", },
1.7      ad 	{ RLIMIT_RSS,		R_CSIZE, "memoryuse", },
1.7      ad 	{ RLIMIT_MEMLOCK,	R_CSIZE, "memorylocked", },
1.7      ad 	{ RLIMIT_NPROC,		R_CNUMB, "maxproc", },
1.7      ad 	{ RLIMIT_NOFILE,	R_CNUMB, "openfiles", },
1.7      ad 	{ RLIMIT_CORE,		R_CSIZE, "coredumpsize", },
1.1     mjl 	{ -1, 0, 0 }
1.1     mjl };
1.1     mjl
1.1     mjl static int
1.6      ad gsetrl(login_cap_t *lc, int what, char *name, int type)
1.1     mjl {
1.1     mjl 	struct rlimit rl;
1.1     mjl 	struct rlimit r;
1.1     mjl 	char name_cur[32];
1.1     mjl 	char name_max[32];
1.1     mjl
1.1     mjl 	sprintf(name_cur, "%s-cur", name);
1.1     mjl 	sprintf(name_max, "%s-max", name);
1.1     mjl
1.1     mjl 	if (getrlimit(what, &r)) {
1.1     mjl 		syslog(LOG_ERR, "getting resource limit: %m");
1.1     mjl 		return (-1);
1.1     mjl 	}
1.1     mjl
1.1     mjl #define	RCUR	r.rlim_cur
1.1     mjl #define	RMAX	r.rlim_max
1.1     mjl
1.1     mjl 	switch (type) {
1.7      ad 	case R_CTIME:
1.1     mjl 		RCUR = login_getcaptime(lc, name, RCUR, RCUR);
1.1     mjl 		RMAX = login_getcaptime(lc, name, RMAX, RMAX);
1.1     mjl 		rl.rlim_cur = login_getcaptime(lc, name_cur, RCUR, RCUR);
1.1     mjl 		rl.rlim_max = login_getcaptime(lc, name_max, RMAX, RMAX);
1.1     mjl 		break;
1.7      ad 	case R_CSIZE:
1.1     mjl 		RCUR = login_getcapsize(lc, name, RCUR, RCUR);
1.1     mjl 		RMAX = login_getcapsize(lc, name, RMAX, RMAX);
1.1     mjl 		rl.rlim_cur = login_getcapsize(lc, name_cur, RCUR, RCUR);
1.1     mjl 		rl.rlim_max = login_getcapsize(lc, name_max, RMAX, RMAX);
1.1     mjl 		break;
1.7      ad 	case R_CNUMB:
1.1     mjl 		RCUR = login_getcapnum(lc, name, RCUR, RCUR);
1.1     mjl 		RMAX = login_getcapnum(lc, name, RMAX, RMAX);
1.1     mjl 		rl.rlim_cur = login_getcapnum(lc, name_cur, RCUR, RCUR);
1.1     mjl 		rl.rlim_max = login_getcapnum(lc, name_max, RMAX, RMAX);
1.1     mjl 		break;
1.1     mjl 	default:
1.1     mjl 		return (-1);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	if (setrlimit(what, &rl)) {
1.1     mjl 		syslog(LOG_ERR, "%s: setting resource limit %s: %m",
1.1     mjl 		    lc->lc_class, name);
1.1     mjl 		return (-1);
1.1     mjl 	}
1.1     mjl #undef	RCUR
1.1     mjl #undef	RMAX
1.1     mjl 	return (0);
1.1     mjl }
1.1     mjl
1.4     mjl static int
1.6      ad setuserenv(login_cap_t *lc)
1.4     mjl {
1.4     mjl 	char *stop = ", \t";
1.4     mjl 	int i, count;
1.4     mjl 	char *ptr;
1.4     mjl 	char **res;
1.4     mjl 	char *str = login_getcapstr(lc, "setenv", NULL, NULL);
1.4     mjl
1.8  itojun 	if (str == NULL || *str == '\0')
1.4     mjl 		return 0;
1.4     mjl
1.4     mjl 	/* count the sub-strings */
1.4     mjl 	for (i = 1, ptr = str; *ptr; i++) {
1.4     mjl 		ptr += strcspn(ptr, stop);
1.4     mjl 		if (*ptr)
1.4     mjl 			ptr++;
1.8  itojun 	}
1.4     mjl
1.4     mjl 	/* allocate ptr array and string */
1.4     mjl 	count = i;
1.8  itojun 	res = malloc(count * sizeof(char *) + strlen(str) + 1);
1.4     mjl
1.8  itojun 	if (!res)
1.4     mjl 		return -1;
1.4     mjl
1.4     mjl 	ptr = (char *)res + count * sizeof(char *);
1.4     mjl 	strcpy(ptr, str);
1.4     mjl
1.4     mjl 	/* split string */
1.4     mjl 	for (i = 0; *ptr && i < count; i++) {
1.4     mjl 		res[i] = ptr;
1.4     mjl 		ptr += strcspn(ptr, stop);
1.4     mjl 		if (*ptr)
1.4     mjl 			*ptr++ = '\0';
1.8  itojun 	}
1.4     mjl
1.4     mjl 	res[i] = NULL;
1.4     mjl
1.4     mjl 	for (i = 0; i < count && res[i]; i++) {
1.4     mjl 		if (*res[i] != '\0') {
1.6      ad 			if ((ptr = strchr(res[i], '=')) != NULL)
1.4     mjl 				*ptr++ = '\0';
1.4     mjl 			else
1.4     mjl 				ptr = "";
1.4     mjl 			setenv(res[i], ptr, 1);
1.4     mjl 		}
1.4     mjl 	}
1.4     mjl
1.5     mjl 	free(res);
1.4     mjl 	return 0;
1.4     mjl }
1.4     mjl
1.1     mjl int
1.6      ad setclasscontext(char *class, u_int flags)
1.1     mjl {
1.1     mjl 	int ret;
1.1     mjl 	login_cap_t *lc;
1.1     mjl
1.1     mjl 	flags &= LOGIN_SETRESOURCES | LOGIN_SETPRIORITY | LOGIN_SETUMASK |
1.1     mjl 	    LOGIN_SETPATH;
1.1     mjl
1.1     mjl 	lc = login_getclass(class);
1.1     mjl 	ret = lc ? setusercontext(lc, NULL, 0, flags) : -1;
1.1     mjl 	login_close(lc);
1.1     mjl 	return (ret);
1.1     mjl }
1.1     mjl
1.1     mjl int
1.6      ad setusercontext(login_cap_t *lc, struct passwd *pwd, uid_t uid, u_int flags)
1.1     mjl {
1.1     mjl 	login_cap_t *flc;
1.1     mjl 	quad_t p;
1.1     mjl 	int i;
1.1     mjl
1.1     mjl 	flc = NULL;
1.1     mjl
1.3     mjl 	if (!lc)
1.3     mjl 		flc = lc = login_getclass(pwd ? pwd->pw_class : NULL);
1.1     mjl
1.1     mjl 	/*
1.1     mjl 	 * Without the pwd entry being passed we cannot set either
1.1     mjl 	 * the group or the login.  We could complain about it.
1.1     mjl 	 */
1.1     mjl 	if (pwd == NULL)
1.1     mjl 		flags &= ~(LOGIN_SETGROUP|LOGIN_SETLOGIN);
1.1     mjl
1.1     mjl 	if (flags & LOGIN_SETRESOURCES)
1.1     mjl 		for (i = 0; r_list[i].name; ++i)
1.1     mjl 			if (gsetrl(lc, r_list[i].what, r_list[i].name,
1.1     mjl 			    r_list[i].type))
1.1     mjl 				/* XXX - call syslog()? */;
1.1     mjl
1.1     mjl 	if (flags & LOGIN_SETPRIORITY) {
1.1     mjl 		p = login_getcapnum(lc, "priority", 0LL, 0LL);
1.1     mjl
1.1     mjl 		if (setpriority(PRIO_PROCESS, 0, (int)p) < 0)
1.1     mjl 			syslog(LOG_ERR, "%s: setpriority: %m", lc->lc_class);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	if (flags & LOGIN_SETUMASK) {
1.1     mjl 		p = login_getcapnum(lc, "umask", (quad_t) LOGIN_DEFUMASK,
1.1     mjl 												   (quad_t) LOGIN_DEFUMASK);
1.1     mjl 		umask((mode_t)p);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	if (flags & LOGIN_SETGROUP) {
1.1     mjl 		if (setgid(pwd->pw_gid) < 0) {
1.1     mjl 			syslog(LOG_ERR, "setgid(%d): %m", pwd->pw_gid);
1.1     mjl 			login_close(flc);
1.1     mjl 			return (-1);
1.1     mjl 		}
1.1     mjl
1.1     mjl 		if (initgroups(pwd->pw_name, pwd->pw_gid) < 0) {
1.1     mjl 			syslog(LOG_ERR, "initgroups(%s,%d): %m",
1.1     mjl 			    pwd->pw_name, pwd->pw_gid);
1.1     mjl 			login_close(flc);
1.1     mjl 			return (-1);
1.1     mjl 		}
1.1     mjl 	}
1.1     mjl
1.1     mjl 	if (flags & LOGIN_SETLOGIN)
1.1     mjl 		if (setlogin(pwd->pw_name) < 0) {
1.1     mjl 			syslog(LOG_ERR, "setlogin(%s) failure: %m",
1.1     mjl 			    pwd->pw_name);
1.1     mjl 			login_close(flc);
1.1     mjl 			return (-1);
1.1     mjl 		}
1.1     mjl
1.1     mjl 	if (flags & LOGIN_SETUSER)
1.1     mjl 		if (setuid(uid) < 0) {
1.1     mjl 			syslog(LOG_ERR, "setuid(%d): %m", uid);
1.1     mjl 			login_close(flc);
1.1     mjl 			return (-1);
1.1     mjl 		}
1.4     mjl
1.4     mjl 	if (flags & LOGIN_SETENV)
1.4     mjl 		setuserenv(lc);
1.1     mjl
1.1     mjl 	if (flags & LOGIN_SETPATH)
1.1     mjl 		setuserpath(lc, pwd ? pwd->pw_dir : "");
1.1     mjl
1.1     mjl 	login_close(flc);
1.1     mjl 	return (0);
1.1     mjl }
1.1     mjl
1.1     mjl static void
1.6      ad setuserpath(login_cap_t *lc, char *home)
1.1     mjl {
1.1     mjl 	size_t hlen, plen;
1.1     mjl 	int cnt = 0;
1.1     mjl 	char *path;
1.1     mjl 	char *p, *q;
1.1     mjl
1.1     mjl 	hlen = strlen(home);
1.1     mjl
1.1     mjl 	p = path = login_getcapstr(lc, "path", NULL, NULL);
1.1     mjl 	if (p) {
1.1     mjl 		while (*p)
1.1     mjl 			if (*p++ == '~')
1.1     mjl 				++cnt;
1.1     mjl 		plen = (p - path) + cnt * (hlen + 1) + 1;
1.1     mjl 		p = path;
1.1     mjl 		q = path = malloc(plen);
1.1     mjl 		if (q) {
1.1     mjl 			while (*p) {
1.1     mjl 				p += strspn(p, " \t");
1.1     mjl 				if (*p == '\0')
1.1     mjl 					break;
1.1     mjl 				plen = strcspn(p, " \t");
1.1     mjl 				if (hlen == 0 && *p == '~') {
1.1     mjl 					p += plen;
1.1     mjl 					continue;
1.1     mjl 				}
1.1     mjl 				if (q != path)
1.1     mjl 					*q++ = ':';
1.1     mjl 				if (*p == '~') {
1.1     mjl 					strcpy(q, home);
1.1     mjl 					q += hlen;
1.1     mjl 					++p;
1.1     mjl 					--plen;
1.1     mjl 				}
1.1     mjl 				memcpy(q, p, plen);
1.1     mjl 				p += plen;
1.1     mjl 				q += plen;
1.1     mjl 			}
1.1     mjl 			*q = '\0';
1.1     mjl 		} else
1.1     mjl 			path = _PATH_DEFPATH;
1.1     mjl 	} else
1.1     mjl 		path = _PATH_DEFPATH;
1.1     mjl 	if (setenv("PATH", path, 1))
1.1     mjl 		warn("could not set PATH");
1.1     mjl }
1.1     mjl
1.1     mjl /*
1.1     mjl  * Convert an expression of the following forms
1.1     mjl  * 	1) A number.
1.1     mjl  *	2) A number followed by a b (mult by 512).
1.1     mjl  *	3) A number followed by a k (mult by 1024).
1.1     mjl  *	5) A number followed by a m (mult by 1024 * 1024).
1.1     mjl  *	6) A number followed by a g (mult by 1024 * 1024 * 1024).
1.1     mjl  *	7) A number followed by a t (mult by 1024 * 1024 * 1024 * 1024).
1.1     mjl  *	8) Two or more numbers (with/without k,b,m,g, or t).
1.1     mjl  *	   seperated by x (also * for backwards compatibility), specifying
1.1     mjl  *	   the product of the indicated values.
1.1     mjl  */
1.6      ad static u_quad_t
1.6      ad strtosize(char *str, char **endptr, int radix)
1.1     mjl {
1.1     mjl 	u_quad_t num, num2;
1.1     mjl 	char *expr, *expr2;
1.1     mjl
1.1     mjl 	errno = 0;
1.1     mjl 	num = strtouq(str, &expr, radix);
1.1     mjl 	if (errno || expr == str) {
1.1     mjl 		if (endptr)
1.1     mjl 			*endptr = expr;
1.1     mjl 		return (num);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	switch(*expr) {
1.1     mjl 	case 'b': case 'B':
1.1     mjl 		num = multiply(num, (u_quad_t)512);
1.1     mjl 		++expr;
1.1     mjl 		break;
1.1     mjl 	case 'k': case 'K':
1.1     mjl 		num = multiply(num, (u_quad_t)1024);
1.1     mjl 		++expr;
1.1     mjl 		break;
1.1     mjl 	case 'm': case 'M':
1.1     mjl 		num = multiply(num, (u_quad_t)1024 * 1024);
1.1     mjl 		++expr;
1.1     mjl 		break;
1.1     mjl 	case 'g': case 'G':
1.1     mjl 		num = multiply(num, (u_quad_t)1024 * 1024 * 1024);
1.1     mjl 		++expr;
1.1     mjl 		break;
1.1     mjl 	case 't': case 'T':
1.1     mjl 		num = multiply(num, (u_quad_t)1024 * 1024);
1.1     mjl 		num = multiply(num, (u_quad_t)1024 * 1024);
1.1     mjl 		++expr;
1.1     mjl 		break;
1.1     mjl 	}
1.1     mjl
1.1     mjl 	if (errno)
1.1     mjl 		goto erange;
1.1     mjl
1.1     mjl 	switch(*expr) {
1.1     mjl 	case '*':			/* Backward compatible. */
1.1     mjl 	case 'x':
1.1     mjl 		num2 = strtosize(expr+1, &expr2, radix);
1.1     mjl 		if (errno) {
1.1     mjl 			expr = expr2;
1.1     mjl 			goto erange;
1.1     mjl 		}
1.1     mjl
1.1     mjl 		if (expr2 == expr + 1) {
1.1     mjl 			if (endptr)
1.1     mjl 				*endptr = expr;
1.1     mjl 			return (num);
1.1     mjl 		}
1.1     mjl 		expr = expr2;
1.1     mjl 		num = multiply(num, num2);
1.1     mjl 		if (errno)
1.1     mjl 			goto erange;
1.1     mjl 		break;
1.1     mjl 	}
1.1     mjl 	if (endptr)
1.1     mjl 		*endptr = expr;
1.1     mjl 	return (num);
1.1     mjl erange:
1.1     mjl 	if (endptr)
1.1     mjl 		*endptr = expr;
1.1     mjl 	errno = ERANGE;
1.1     mjl 	return (UQUAD_MAX);
1.1     mjl }
1.1     mjl
1.6      ad static u_quad_t
1.6      ad strtolimit(char *str, char **endptr, int radix)
1.1     mjl {
1.5     mjl 	if (isinfinite(str)) {
1.1     mjl 		if (endptr)
1.1     mjl 			*endptr = str + strlen(str);
1.1     mjl 		return ((u_quad_t)RLIM_INFINITY);
1.1     mjl 	}
1.1     mjl 	return (strtosize(str, endptr, radix));
1.5     mjl }
1.5     mjl
1.5     mjl static int
1.5     mjl isinfinite(const char *s)
1.5     mjl {
1.5     mjl 	static const char *infs[] = {
1.5     mjl 		"infinity",
1.5     mjl 		"inf",
1.5     mjl 		"unlimited",
1.5     mjl 		"unlimit",
1.5     mjl 		NULL
1.5     mjl 	};
1.5     mjl 	const char **i;
1.5     mjl
1.8  itojun 	for (i = infs; *i; i++) {
1.5     mjl 		if (!strcasecmp(s, *i))
1.5     mjl 			return 1;
1.5     mjl 	}
1.5     mjl 	return 0;
1.1     mjl }
1.1     mjl
1.1     mjl static u_quad_t
1.6      ad multiply(u_quad_t n1, u_quad_t n2)
1.1     mjl {
1.1     mjl 	static int bpw = 0;
1.1     mjl 	u_quad_t m;
1.1     mjl 	u_quad_t r;
1.1     mjl 	int b1, b2;
1.1     mjl
1.1     mjl 	/*
1.1     mjl 	 * Get rid of the simple cases
1.1     mjl 	 */
1.1     mjl 	if (n1 == 0 || n2 == 0)
1.1     mjl 		return (0);
1.1     mjl 	if (n1 == 1)
1.1     mjl 		return (n2);
1.1     mjl 	if (n2 == 1)
1.1     mjl 		return (n1);
1.1     mjl
1.1     mjl 	/*
1.1     mjl 	 * sizeof() returns number of bytes needed for storage.
1.1     mjl 	 * This may be different from the actual number of useful bits.
1.1     mjl 	 */
1.1     mjl 	if (!bpw) {
1.1     mjl 		bpw = sizeof(u_quad_t) * 8;
1.1     mjl 		while (((u_quad_t)1 << (bpw-1)) == 0)
1.1     mjl 			--bpw;
1.1     mjl 	}
1.1     mjl
1.1     mjl 	/*
1.1     mjl 	 * First check the magnitude of each number.  If the sum of the
1.1     mjl 	 * magnatude is way to high, reject the number.  (If this test
1.1     mjl 	 * is not done then the first multiply below may overflow.)
1.1     mjl 	 */
1.1     mjl 	for (b1 = bpw; (((u_quad_t)1 << (b1-1)) & n1) == 0; --b1)
1.1     mjl 		;
1.1     mjl 	for (b2 = bpw; (((u_quad_t)1 << (b2-1)) & n2) == 0; --b2)
1.1     mjl 		;
1.1     mjl 	if (b1 + b2 - 2 > bpw) {
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (UQUAD_MAX);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	/*
1.1     mjl 	 * Decompose the multiplication to be:
1.1     mjl 	 * h1 = n1 & ~1
1.1     mjl 	 * h2 = n2 & ~1
1.1     mjl 	 * l1 = n1 & 1
1.1     mjl 	 * l2 = n2 & 1
1.1     mjl 	 * (h1 + l1) * (h2 + l2)
1.1     mjl 	 * (h1 * h2) + (h1 * l2) + (l1 * h2) + (l1 * l2)
1.1     mjl 	 *
1.1     mjl 	 * Since h1 && h2 do not have the low bit set, we can then say:
1.1     mjl 	 *
1.1     mjl 	 * (h1>>1 * h2>>1 * 4) + ...
1.1     mjl 	 *
1.1     mjl 	 * So if (h1>>1 * h2>>1) > (1<<(bpw - 2)) then the result will
1.1     mjl 	 * overflow.
1.1     mjl 	 *
1.1     mjl 	 * Finally, if MAX - ((h1 * l2) + (l1 * h2) + (l1 * l2)) < (h1*h2)
1.1     mjl 	 * then adding in residual amout will cause an overflow.
1.1     mjl 	 */
1.1     mjl
1.1     mjl 	m = (n1 >> 1) * (n2 >> 1);
1.1     mjl
1.1     mjl 	if (m >= ((u_quad_t)1 << (bpw-2))) {
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (UQUAD_MAX);
1.1     mjl 	}
1.1     mjl
1.1     mjl 	m *= 4;
1.1     mjl
1.1     mjl 	r = (n1 & n2 & 1)
1.1     mjl 	  + (n2 & 1) * (n1 & ~(u_quad_t)1)
1.1     mjl 	  + (n1 & 1) * (n2 & ~(u_quad_t)1);
1.1     mjl
1.1     mjl 	if ((u_quad_t)(m + r) < m) {
1.1     mjl 		errno = ERANGE;
1.1     mjl 		return (UQUAD_MAX);
1.1     mjl 	}
1.1     mjl 	m += r;
1.1     mjl
1.1     mjl 	return (m);
1.1     mjl }