HardenedBSD/usr.sbin/rpc.yppasswdd/yppasswdd_main.c

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Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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/*
* Copyright (c) 1995, 1996
* Bill Paul <wpaul@ctr.columbia.edu>. All rights reserved.
*
* 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. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by Bill Paul.
* 4. Neither the name of the author nor the names of any co-contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY Bill Paul 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 Bill Paul 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.
*/
#ifndef lint
static const char rcsid[] =
1999-08-28 03:35:59 +02:00
"$FreeBSD$";
#endif /* not lint */
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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#include "yppasswd.h"
#include <stdio.h>
#include <sys/types.h>
#include <stdlib.h> /* getenv, exit */
#include <unistd.h>
#include <string.h>
#include <sys/param.h>
#include <rpc/pmap_clnt.h> /* for pmap_unset */
#include <string.h> /* strcmp */
#include <signal.h>
#include <fcntl.h>
#include <sys/ioctl.h>
#include <sys/stat.h>
#ifdef __cplusplus
#include <sysent.h> /* getdtablesize, open */
#endif /* __cplusplus */
#include <memory.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <syslog.h>
#include <err.h>
#include <errno.h>
#include <rpcsvc/yp.h>
struct dom_binding {};
#include <rpcsvc/ypclnt.h>
#include "yppasswdd_extern.h"
#include "yppasswd_private.h"
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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#include "ypxfr_extern.h"
#ifndef SIG_PF
#define SIG_PF void(*)(int)
#endif
#ifdef DEBUG
#define RPC_SVC_FG
#endif
#define _RPCSVC_CLOSEDOWN 120
int _rpcpmstart = 0; /* Started by a port monitor ? */
static int _rpcfdtype;
/* Whether Stream or Datagram ? */
/* States a server can be in wrt request */
#define _IDLE 0
#define _SERVED 1
#define _SERVING 2
extern int _rpcsvcstate; /* Set when a request is serviced */
char *progname = "rpc.yppasswdd";
char *yp_dir = _PATH_YP;
char *passfile_default = _PATH_YP "master.passwd";
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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char *passfile;
char *yppasswd_domain = NULL;
int no_chsh = 0;
int no_chfn = 0;
int allow_additions = 0;
int multidomain = 0;
int verbose = 0;
int resvport = 1;
int inplace = 0;
char *sockname = YP_SOCKNAME;
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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static void terminate(sig)
int sig;
{
svc_unregister(YPPASSWDPROG, YPPASSWDVERS);
svc_unregister(MASTER_YPPASSWDPROG, MASTER_YPPASSWDVERS);
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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unlink(sockname);
exit(0);
}
static void reload(sig)
int sig;
{
load_securenets();
}
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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static void
closedown(int sig)
{
if (_rpcsvcstate == _IDLE) {
extern fd_set svc_fdset;
static int size;
int i, openfd;
if (_rpcfdtype == SOCK_DGRAM) {
unlink(sockname);
exit(0);
}
if (size == 0) {
size = getdtablesize();
}
for (i = 0, openfd = 0; i < size && openfd < 2; i++)
if (FD_ISSET(i, &svc_fdset))
openfd++;
if (openfd <= 1) {
unlink(sockname);
exit(0);
}
}
if (_rpcsvcstate == _SERVED)
_rpcsvcstate = _IDLE;
(void) signal(SIGALRM, (SIG_PF) closedown);
(void) alarm(_RPCSVC_CLOSEDOWN/2);
}
static void usage()
{
fprintf(stderr, "%s\n%s\n",
"usage: rpc.yppasswdd [-t master.passwd file] [-d domain] [-p path] [-s]",
" [-f] [-m] [-i] [-a] [-v] [-u] [-h]");
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
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exit(1);
}
int
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
main(argc, argv)
int argc;
char *argv[];
{
register SVCXPRT *transp = NULL;
int sock;
int proto = 0;
struct sockaddr_in saddr;
int asize = sizeof (saddr);
int ch;
char *mastername;
char myname[MAXHOSTNAMELEN + 2];
extern int debug;
debug = 1;
while ((ch = getopt(argc, argv, "t:d:p:sfamuivh")) != -1) {
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
switch(ch) {
case 't':
passfile_default = optarg;
break;
case 'd':
yppasswd_domain = optarg;
break;
case 's':
no_chsh++;
break;
case 'f':
no_chfn++;
break;
case 'p':
yp_dir = optarg;
break;
case 'a':
allow_additions++;
break;
case 'm':
multidomain++;
break;
case 'i':
inplace++;
break;
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
case 'v':
verbose++;
break;
case 'u':
resvport = 0;
break;
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
default:
case 'h':
usage();
break;
}
}
if (yppasswd_domain == NULL) {
if (yp_get_default_domain(&yppasswd_domain)) {
yp_error("no domain specified and system domain \
name isn't set -- aborting");
usage();
}
}
load_securenets();
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
if (getrpcport("localhost", YPPROG, YPVERS, IPPROTO_UDP) <= 0) {
1996-10-23 17:42:37 +02:00
yp_error("no ypserv processes registered with local portmap");
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
yp_error("this host is not an NIS server -- aborting");
exit(1);
}
if ((mastername = ypxfr_get_master(yppasswd_domain, "passwd.byname",
"localhost",0)) == NULL) {
1996-10-23 17:42:37 +02:00
yp_error("can't get name of NIS master server for domain %s",
yppasswd_domain);
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
exit(1);
}
if (gethostname((char *)&myname, sizeof(myname)) == -1) {
yp_error("can't get local hostname: %s", strerror(errno));
exit(1);
}
1999-03-16 02:23:09 +01:00
if (strncasecmp(mastername, (char *)&myname, sizeof(myname))) {
1996-10-23 17:42:37 +02:00
yp_error("master of %s is %s, but we are %s",
"passwd.byname", mastername, myname);
yp_error("this host is not the NIS master server for \
the %s domain -- aborting", yppasswd_domain);
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
exit(1);
}
debug = 0;
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
if (getsockname(0, (struct sockaddr *)&saddr, &asize) == 0) {
int ssize = sizeof (int);
if (saddr.sin_family != AF_INET)
exit(1);
if (getsockopt(0, SOL_SOCKET, SO_TYPE,
(char *)&_rpcfdtype, &ssize) == -1)
exit(1);
sock = 0;
_rpcpmstart = 1;
proto = 0;
openlog("rpc.yppasswdd", LOG_PID, LOG_DAEMON);
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
} else {
if (!debug) {
if (daemon(0,0)) {
err(1,"cannot fork");
}
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
}
openlog("rpc.yppasswdd", LOG_PID, LOG_DAEMON);
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
sock = RPC_ANYSOCK;
(void) pmap_unset(YPPASSWDPROG, YPPASSWDVERS);
(void) pmap_unset(MASTER_YPPASSWDPROG, MASTER_YPPASSWDVERS);
unlink(sockname);
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
}
if ((_rpcfdtype == 0) || (_rpcfdtype == SOCK_DGRAM)) {
transp = svcudp_create(sock);
if (transp == NULL) {
yp_error("cannot create udp service.");
exit(1);
}
if (!_rpcpmstart)
proto = IPPROTO_UDP;
if (!svc_register(transp, YPPASSWDPROG, YPPASSWDVERS, yppasswdprog_1, proto)) {
yp_error("unable to register (YPPASSWDPROG, YPPASSWDVERS, udp).");
exit(1);
}
}
if ((_rpcfdtype == 0) || (_rpcfdtype == SOCK_STREAM)) {
transp = svctcp_create(sock, 0, 0);
if (transp == NULL) {
yp_error("cannot create tcp service.");
exit(1);
}
if (!_rpcpmstart)
proto = IPPROTO_TCP;
if (!svc_register(transp, YPPASSWDPROG, YPPASSWDVERS, yppasswdprog_1, proto)) {
yp_error("unable to register (YPPASSWDPROG, YPPASSWDVERS, tcp).");
exit(1);
}
}
unlink(sockname);
Bring in a hybrid of SunSoft's transport-independent RPC (TI-RPC) and associated changes that had to happen to make this possible as well as bugs fixed along the way. Bring in required TLI library routines to support this. Since we don't support TLI we've essentially copied what NetBSD has done, adding a thin layer to emulate direct the TLI calls into BSD socket calls. This is mostly from Sun's tirpc release that was made in 1994, however some fixes were backported from the 1999 release (supposedly only made available after this porting effort was underway). The submitter has agreed to continue on and bring us up to the 1999 release. Several key features are introduced with this update: Client calls are thread safe. (1999 code has server side thread safe) Updated, a more modern interface. Many userland updates were done to bring the code up to par with the recent RPC API. There is an update to the pthreads library, a function pthread_main_np() was added to emulate a function of Sun's threads library. While we're at it, bring in NetBSD's lockd, it's been far too long of a wait. New rpcbind(8) replaces portmap(8) (supporting communication over an authenticated Unix-domain socket, and by default only allowing set and unset requests over that channel). It's much more secure than the old portmapper. Umount(8), mountd(8), mount_nfs(8), nfsd(8) have also been upgraded to support TI-RPC and to support IPV6. Umount(8) is also fixed to unmount pathnames longer than 80 chars, which are currently truncated by the Kernel statfs structure. Submitted by: Martin Blapp <mb@imp.ch> Manpage review: ru Secure RPC implemented by: wpaul
2001-03-19 13:50:13 +01:00
if (svc_create(yppasswdprog_1, YPPASSWDPROG, YPPASSWDVERS,
"netpath") == 0) {
(void) fprintf(stderr,
"%s: unable to create service\n", argv[0]);
exit(1);
}
if (svc_create(master_yppasswdprog_1, MASTER_YPPASSWDPROG,
MASTER_YPPASSWDVERS, "netpath") == 0) {
(void) fprintf(stderr,
"%s: unable to create service\n", argv[0]);
exit(1);
}
if (transp == NULL) {
yp_error("cannot create AF_LOCAL service.");
exit(1);
}
if (!svc_register(transp, MASTER_YPPASSWDPROG, MASTER_YPPASSWDVERS, master_yppasswdprog_1, 0)) {
yp_error("unable to register (MASTER_YPPASSWDPROG, MASTER_YPPASSWDVERS, unix).");
exit(1);
}
/* Only root may connect() to the AF_UNIX link. */
if (chmod(sockname, 0))
err(1, "chmod of %s failed", sockname);
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
if (transp == (SVCXPRT *)NULL) {
yp_error("could not create a handle");
exit(1);
}
if (_rpcpmstart) {
(void) signal(SIGALRM, (SIG_PF) closedown);
(void) alarm(_RPCSVC_CLOSEDOWN/2);
}
/* set up resource limits and block signals */
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
pw_init();
/* except SIGCHLD, which we need to catch */
install_reaper(1);
signal(SIGTERM, (SIG_PF) terminate);
signal(SIGHUP, (SIG_PF) reload);
svc_run();
Import new rpc.yppasswdd. (Note: accompanying changes to passwd(1) and chpass(1) are on the way too.) This version supports all the features of the old one and adds several new ones: - Supports real multi-domain operation (optional, can be turned on with a command-line flag). This means you can actually have several different domains all served from one NIS server and allow users in any of the supported domains to change their passwords. The old yppasswdd only allowed changing passwords in the domain that was set as the system default domain name on the NIS master server. The new one can change passwords in any domain by trying to match the user information passed to it against all the passwd maps it can find. This is something of a hack, but the yppasswd.x protocol definiton does not allow for a domain to be passwd as an argument to rpc.yppasswdd, so the server has no choice but to grope around for a likely match. Since this method can fail if the same user exists in two domains, this feature is off by default. If the feature is turned on and the server becomes confused by duplicate entries, it will abort the update. - Does not require NIS client services to be available. NIS servers do _NOT_ necessarily have to be configured as NIS clients in order to function: the ypserv, ypxfr and yppush programs I've written recently will operate fine even if the system domain name isn't set, ypbind isn't running and there are no magic '+' entries in any of the /etc files. Now rpc.yppasswdd is the same way. The old yppasswdd would not work like this because it depended on getpwent(3) and friends to look up users: this will obviously only work if the system where yppasswdd is running is configured as an NIS client. The new rpc.yppasswdd doesn't use getpwent(3) at all: instead it searches through the master.passwd map databases directly. This also makes it easier for it to handle multiple domains. - Allows the superuser on the NIS master server to change any user's password without requiring password authentication. rpc.yppasswdd creates a UNIX domain socket (/var/run/ypsock) which it monitors using the same svc_run() loop used to handle incoming RPC requests. It also clears all the permission bits for /var/run/ypsock; since this socket is owned by root, this prevents anyone except root from successfully connect()ing to it. (Using a UNIX domain socket also prevents IP spoofing attacks.) By building code into passwd(1) and chpass(1) to take advantage of this 'trusted' channel, the superuser can use them to send private requests to rpc.yppasswdd. - Allows the superuser on the NIS master to use chpass(1) to update _all_ of a user's master.passwd information. The UNIX domain access point accepts a full master.passwd style structure (along with a domain name and other information), which allows the superuser to update all of a user's master.passwd information in the NIS master.passwd maps. Normal users on NIS clients are still only allowed to change their full name and shell information with chpass. - Allows the superuser on the NIS master to _add_ records to the NIS master.passwd maps using chpass(1). This feature is also switchable with a command-line flag and is off by default.
1996-02-12 16:09:01 +01:00
yp_error("svc_run returned");
exit(1);
/* NOTREACHED */
}