/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* Copyright (c) 1983, 1984, 1985, 1986, 1987, 1988, 1989 AT&T */ /* All Rights Reserved */ /* * University Copyright- Copyright (c) 1982, 1986, 1988 * The Regents of the University of California * All Rights Reserved * * University Acknowledgment- Portions of this document are derived from * software developed by the University of California, Berkeley, and its * contributors. */ /* * rpcb_svc_com.c * The commom server procedure for the rpcbind. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef PORTMAP #include #include #endif /* PORTMAP */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "rpcbind.h" static bool_t xdr_opaque_parms(); char *getowner(); static ulong_t forward_register(); static void handle_reply(); static int netbufcmp(); static int free_slot_by_xid(); static int free_slot_by_index(); static int check_rmtcalls(); static void netbuffree(); static void find_versions(); static struct netbuf *netbufdup(); static rpcblist_ptr find_service(); static int add_pmaplist(RPCB *); int del_pmaplist(RPCB *); void delete_rbl(rpcblist_ptr); static char *nullstring = ""; static int rpcb_rmtcalls; /* * Set a mapping of program, version, netid */ /* ARGSUSED */ bool_t * rpcbproc_set_com(regp, rqstp, transp, rpcbversnum) RPCB *regp; struct svc_req *rqstp; /* Not used here */ SVCXPRT *transp; int rpcbversnum; { static bool_t ans; char owner[64]; #ifdef RPCBIND_DEBUG fprintf(stderr, "RPCB_SET request for (%lu, %lu, %s, %s) : ", regp->r_prog, regp->r_vers, regp->r_netid, regp->r_addr); #endif ans = map_set(regp, getowner(transp, owner)); #ifdef RPCBIND_DEBUG fprintf(stderr, "%s\n", ans == TRUE ? "succeeded" : "failed"); #endif /* XXX: should have used some defined constant here */ rpcbs_set((ulong_t)(rpcbversnum - 2), ans); return (&ans); } bool_t map_set(regp, owner) RPCB *regp; char *owner; { RPCB reg, *a; rpcblist_ptr rbl, fnd; reg = *regp; /* * check to see if already used * find_service returns a hit even if * the versions don't match, so check for it */ fnd = find_service(reg.r_prog, reg.r_vers, reg.r_netid); if (fnd && (fnd->rpcb_map.r_vers == reg.r_vers)) { if (strcmp(fnd->rpcb_map.r_addr, reg.r_addr) == 0) /* * if these match then it is already * registered so just say "OK". */ return (TRUE); else { /* * Check if server is up. If so, return FALSE. * If not, cleanup old registrations for the * program and register the new server. */ if (is_bound(fnd->rpcb_map.r_netid, fnd->rpcb_map.r_addr)) return (FALSE); delete_prog(reg.r_prog); fnd = NULL; } } /* * add to the end of the list */ rbl = (rpcblist_ptr) malloc((uint_t)sizeof (RPCBLIST)); if (rbl == (rpcblist_ptr)NULL) { return (FALSE); } a = &(rbl->rpcb_map); a->r_prog = reg.r_prog; a->r_vers = reg.r_vers; a->r_netid = strdup(reg.r_netid); a->r_addr = strdup(reg.r_addr); a->r_owner = strdup(owner); if (a->r_addr == NULL || a->r_netid == NULL|| a->r_owner == NULL) { delete_rbl(rbl); return (FALSE); } rbl->rpcb_next = (rpcblist_ptr)NULL; if (list_rbl == NULL) { list_rbl = rbl; } else { for (fnd = list_rbl; fnd->rpcb_next; fnd = fnd->rpcb_next) ; fnd->rpcb_next = rbl; } #ifdef PORTMAP (void) add_pmaplist(regp); #endif return (TRUE); } /* * Unset a mapping of program, version, netid */ /* ARGSUSED */ bool_t * rpcbproc_unset_com(regp, rqstp, transp, rpcbversnum) RPCB *regp; struct svc_req *rqstp; /* Not used here */ SVCXPRT *transp; int rpcbversnum; { static bool_t ans; char owner[64]; #ifdef RPCBIND_DEBUG fprintf(stderr, "RPCB_UNSET request for (%lu, %lu, %s) : ", regp->r_prog, regp->r_vers, regp->r_netid); #endif ans = map_unset(regp, getowner(transp, owner)); #ifdef RPCBIND_DEBUG fprintf(stderr, "%s\n", ans == TRUE ? "succeeded" : "failed"); #endif /* XXX: should have used some defined constant here */ rpcbs_unset((ulong_t)(rpcbversnum - 2), ans); return (&ans); } bool_t map_unset(regp, owner) RPCB *regp; char *owner; { #ifdef PORTMAP int ans = 0; #endif rpcblist_ptr rbl, next, prev = NULL; if (owner == NULL) return (0); for (rbl = list_rbl; rbl != NULL; rbl = next) { next = rbl->rpcb_next; if ((rbl->rpcb_map.r_prog != regp->r_prog) || (rbl->rpcb_map.r_vers != regp->r_vers) || (regp->r_netid[0] && strcasecmp(regp->r_netid, rbl->rpcb_map.r_netid))) { /* prev moves forwards */ prev = rbl; continue; } /* * Check whether appropriate uid. Unset only * if superuser or the owner itself. */ if (strcmp(owner, "superuser") && strcmp(rbl->rpcb_map.r_owner, owner)) return (0); /* prev stays */ #ifdef PORTMAP ans = 1; #endif delete_rbl(rbl); if (prev == NULL) list_rbl = next; else prev->rpcb_next = next; } #ifdef PORTMAP if (ans) (void) del_pmaplist(regp); #endif /* * We return 1 either when the entry was not there or it * was able to unset it. It can come to this point only if * at least one of the conditions is true. */ return (1); } void delete_rbl(rpcblist_ptr rbl) { free(rbl->rpcb_map.r_addr); free(rbl->rpcb_map.r_netid); free(rbl->rpcb_map.r_owner); free(rbl); } void delete_prog(prog) unsigned long prog; { rpcblist_ptr rbl, next, prev = NULL; for (rbl = list_rbl; rbl != NULL; rbl = next) { next = rbl->rpcb_next; if (rbl->rpcb_map.r_prog != prog || is_bound(rbl->rpcb_map.r_netid, rbl->rpcb_map.r_addr)) { prev = rbl; continue; } #ifdef PORTMAP (void) del_pmaplist(&rbl->rpcb_map); #endif delete_rbl(rbl); if (prev == NULL) list_rbl = next; else prev->rpcb_next = next; } } /*ARGSUSED*/ char ** rpcbproc_getaddr_com(regp, rqstp, transp, rpcbversnum, verstype) RPCB *regp; struct svc_req *rqstp; /* Not used here */ SVCXPRT *transp; ulong_t rpcbversnum; ulong_t verstype; { static char *uaddr; char *saddr = NULL; rpcblist_ptr fnd; struct netconfig *trans_conf; /* transport netconfig */ /* * There is a potential window at startup during which rpcbind * service has been established over IPv6 but not over IPv4. If an * IPv4 request comes in during that window, the IP code will map * it into IPv6. We could patch up the request so that it looks * like IPv4 (so that rpcbind returns an IPv4 uaddr to the caller), * but that requires some non-trivial code and it's hard to test. * Instead, drop the request on the floor and force the caller to * retransmit. By the time rpcbind sees the retransmission, IPv4 * service should be in place and it should see the request as * IPv4, as desired. */ trans_conf = rpcbind_get_conf(transp->xp_netid); if (strcmp(trans_conf->nc_protofmly, NC_INET6) == 0) { struct sockaddr_in6 *rmtaddr; rmtaddr = (struct sockaddr_in6 *)transp->xp_rtaddr.buf; if (IN6_IS_ADDR_V4MAPPED(&rmtaddr->sin6_addr)) { syslog(LOG_DEBUG, "IPv4 GETADDR request mapped to IPv6: ignoring"); return (NULL); } } if (uaddr && uaddr[0]) free((void *) uaddr); fnd = find_service(regp->r_prog, regp->r_vers, transp->xp_netid); if (fnd && ((verstype == RPCB_ALLVERS) || (regp->r_vers == fnd->rpcb_map.r_vers))) { if (*(regp->r_addr) != '\0') { /* may contain a hint about */ saddr = regp->r_addr; /* the interface that we */ } /* should use */ if (!(uaddr = mergeaddr(transp, transp->xp_netid, fnd->rpcb_map.r_addr, saddr))) { /* Try whatever we have */ uaddr = strdup(fnd->rpcb_map.r_addr); } else if (!uaddr[0]) { /* * The server died. Unset all versions of this prog. */ delete_prog(regp->r_prog); uaddr = nullstring; } } else { uaddr = nullstring; } #ifdef RPCBIND_DEBUG fprintf(stderr, "getaddr: %s\n", uaddr); #endif /* XXX: should have used some defined constant here */ rpcbs_getaddr(rpcbversnum - 2, regp->r_prog, regp->r_vers, transp->xp_netid, uaddr); return (&uaddr); } /* VARARGS */ ulong_t * rpcbproc_gettime_com() { static time_t curtime; (void) time(&curtime); return ((ulong_t *)&curtime); } /* * Convert uaddr to taddr. Should be used only by * local servers/clients. (kernel level stuff only) */ /* ARGSUSED */ struct netbuf * rpcbproc_uaddr2taddr_com(uaddrp, rqstp, transp, rpcbversnum) char **uaddrp; struct svc_req *rqstp; /* Not used here */ SVCXPRT *transp; int rpcbversnum; /* Not used here */ { struct netconfig *nconf; static struct netbuf nbuf; static struct netbuf *taddr; if (taddr) { free((void *) taddr->buf); free((void *) taddr); } if (((nconf = rpcbind_get_conf(transp->xp_netid)) == NULL) || ((taddr = uaddr2taddr(nconf, *uaddrp)) == NULL)) { (void) memset((char *)&nbuf, 0, sizeof (struct netbuf)); return (&nbuf); } return (taddr); } /* * Convert taddr to uaddr. Should be used only by * local servers/clients. (kernel level stuff only) */ /* ARGSUSED */ char ** rpcbproc_taddr2uaddr_com(taddr, rqstp, transp, rpcbversnum) struct netbuf *taddr; struct svc_req *rqstp; /* Not used here */ SVCXPRT *transp; int rpcbversnum; /* unused */ { static char *uaddr; struct netconfig *nconf; #ifdef CHEW_FDS int fd; if ((fd = open("/dev/null", O_RDONLY)) == -1) { uaddr = (char *)strerror(errno); return (&uaddr); } #endif /* CHEW_FDS */ if (uaddr && uaddr[0]) free((void *) uaddr); if (((nconf = rpcbind_get_conf(transp->xp_netid)) == NULL) || ((uaddr = taddr2uaddr(nconf, taddr)) == NULL)) { uaddr = nullstring; } return (&uaddr); } /* * Stuff for the rmtcall service */ struct encap_parms { ulong_t arglen; char *args; }; static bool_t xdr_encap_parms(xdrs, epp) XDR *xdrs; struct encap_parms *epp; { return (xdr_bytes(xdrs, &(epp->args), (uint_t *)&(epp->arglen), ~0)); } struct r_rmtcall_args { ulong_t rmt_prog; ulong_t rmt_vers; ulong_t rmt_proc; int rmt_localvers; /* whether to send port # or uaddr */ char *rmt_uaddr; struct encap_parms rmt_args; }; /* * XDR remote call arguments. It ignores the address part. * written for XDR_DECODE direction only */ static bool_t xdr_rmtcall_args(xdrs, cap) register XDR *xdrs; register struct r_rmtcall_args *cap; { /* does not get the address or the arguments */ if (xdr_u_long(xdrs, &(cap->rmt_prog)) && xdr_u_long(xdrs, &(cap->rmt_vers)) && xdr_u_long(xdrs, &(cap->rmt_proc))) { return (xdr_encap_parms(xdrs, &(cap->rmt_args))); } return (FALSE); } /* * XDR remote call results along with the address. Ignore * program number, version number and proc number. * Written for XDR_ENCODE direction only. */ static bool_t xdr_rmtcall_result(xdrs, cap) register XDR *xdrs; register struct r_rmtcall_args *cap; { bool_t result; #ifdef PORTMAP if (cap->rmt_localvers == PMAPVERS) { int h1, h2, h3, h4, p1, p2; ulong_t port; /* interpret the universal address for TCP/IP */ if (sscanf(cap->rmt_uaddr, "%d.%d.%d.%d.%d.%d", &h1, &h2, &h3, &h4, &p1, &p2) != 6) return (FALSE); port = ((p1 & 0xff) << 8) + (p2 & 0xff); result = xdr_u_long(xdrs, &port); } else #endif if ((cap->rmt_localvers == RPCBVERS) || (cap->rmt_localvers == RPCBVERS4)) { result = xdr_wrapstring(xdrs, &(cap->rmt_uaddr)); } else { return (FALSE); } if (result == TRUE) return (xdr_encap_parms(xdrs, &(cap->rmt_args))); return (FALSE); } /* * only worries about the struct encap_parms part of struct r_rmtcall_args. * The arglen must already be set!! */ static bool_t xdr_opaque_parms(xdrs, cap) XDR *xdrs; struct r_rmtcall_args *cap; { return (xdr_opaque(xdrs, cap->rmt_args.args, cap->rmt_args.arglen)); } struct rmtcallfd_list { int fd; SVCXPRT *xprt; char *netid; struct rmtcallfd_list *next; }; static struct rmtcallfd_list *rmthead; static struct rmtcallfd_list *rmttail; int create_rmtcall_fd(nconf) struct netconfig *nconf; { int fd; struct rmtcallfd_list *rmt; SVCXPRT *xprt; if ((fd = t_open(nconf->nc_device, O_RDWR, NULL)) == -1) { if (debugging) fprintf(stderr, "create_rmtcall_fd: couldn't open \"%s\" (errno %d, t_errno %d)\n", nconf->nc_device, errno, t_errno); return (-1); } if (t_bind(fd, (struct t_bind *)0, (struct t_bind *)0) == -1) { if (debugging) fprintf(stderr, "create_rmtcall_fd: couldn't bind to fd for \"%s\" (errno %d, t_errno %d)\n", nconf->nc_device, errno, t_errno); return (-1); } xprt = svc_tli_create(fd, 0, (struct t_bind *)0, 0, 0); if (xprt == NULL) { if (debugging) fprintf(stderr, "create_rmtcall_fd: svc_tli_create failed\n"); return (-1); } rmt = (struct rmtcallfd_list *)malloc((uint_t) sizeof (struct rmtcallfd_list)); if (rmt == NULL) { syslog(LOG_ERR, "create_rmtcall_fd: no memory!"); return (-1); } rmt->xprt = xprt; rmt->netid = strdup(nconf->nc_netid); xprt->xp_netid = rmt->netid; rmt->fd = fd; rmt->next = NULL; if (rmthead == NULL) { rmthead = rmt; rmttail = rmt; } else { rmttail->next = rmt; rmttail = rmt; } #if defined(DEBUG_RMTCALL) && defined(PORTMAP) if (debugging) { struct sockaddr_in *sin; struct netbuf *nb; nb = &xprt->xp_ltaddr; sin = (struct sockaddr_in *)nb->buf; fprintf(stderr, "create_rmtcall_fd %d, port %d\n", fd, sin->sin_port); } #endif return (fd); } static int find_rmtcallfd_by_netid(netid) char *netid; { struct rmtcallfd_list *rmt; for (rmt = rmthead; rmt != NULL; rmt = rmt->next) { if (strcmp(netid, rmt->netid) == 0) { return (rmt->fd); } } return (-1); } static SVCXPRT * find_rmtcallxprt_by_fd(fd) int fd; { struct rmtcallfd_list *rmt; for (rmt = rmthead; rmt != NULL; rmt = rmt->next) { if (fd == rmt->fd) { return (rmt->xprt); } } return (NULL); } /* * Call a remote procedure service. This procedure is very quiet when things * go wrong. The proc is written to support broadcast rpc. In the broadcast * case, a machine should shut-up instead of complain, lest the requestor be * overrun with complaints at the expense of not hearing a valid reply. * When receiving a request and verifying that the service exists, we * * receive the request * * open a new TLI endpoint on the same transport on which we received * the original request * * remember the original request's XID (which requires knowing the format * of the svc_dg_data structure) * * forward the request, with a new XID, to the requested service, * remembering the XID used to send this request (for later use in * reassociating the answer with the original request), the requestor's * address, the file descriptor on which the forwarded request is * made and the service's address. * * mark the file descriptor on which we anticipate receiving a reply from * the service and one to select for in our private svc_run procedure * * At some time in the future, a reply will be received from the service to * which we forwarded the request. At that time, we detect that the socket * used was for forwarding (by looking through the finfo structures to see * whether the fd corresponds to one of those) and call handle_reply() to * * receive the reply * * bundle the reply, along with the service's universal address * * create a SVCXPRT structure and use a version of svc_sendreply * that allows us to specify the reply XID and destination, send the reply * to the original requestor. */ #define RPC_BUF_MAX 65536 /* can be raised if required */ /* * This is from ../ypcmd/yp_b.h * It does not appear in */ #define YPBINDPROG ((ulong_t)100007) #define YPBINDPROC_SETDOM ((ulong_t)2) void rpcbproc_callit_com(rqstp, transp, reply_type, versnum) struct svc_req *rqstp; SVCXPRT *transp; ulong_t reply_type; /* which proc number */ ulong_t versnum; /* which vers was called */ { register rpcblist_ptr rbl; struct netconfig *nconf; struct netbuf *caller; struct r_rmtcall_args a; char *buf_alloc = NULL; char *outbuf_alloc = NULL; char buf[RPC_BUF_MAX], outbuf[RPC_BUF_MAX]; struct netbuf *na = (struct netbuf *)NULL; struct t_info tinfo; struct t_unitdata tu_data; struct rpc_msg call_msg; struct svc_dg_data *bd; int outlen; uint_t sendsz; XDR outxdr; AUTH *auth; int fd = -1; char *uaddr; struct nd_mergearg ma; int stat; if (t_getinfo(transp->xp_fd, &tinfo) == -1) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); return; } if (tinfo.servtype != T_CLTS) return; /* Only datagram type accepted */ sendsz = __rpc_get_t_size(0, tinfo.tsdu); if (sendsz == 0) { /* data transfer not supported */ if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); return; } /* * Should be multiple of 4 for XDR. */ sendsz = ((sendsz + 3) / 4) * 4; if (sendsz > RPC_BUF_MAX) { #ifdef notyet buf_alloc = alloca(sendsz); /* not in IDR2? */ #else buf_alloc = malloc(sendsz); #endif /* notyet */ if (buf_alloc == NULL) { if (debugging) fprintf(stderr, "rpcbproc_callit_com: No Memory!\n"); if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); return; } a.rmt_args.args = buf_alloc; } else { a.rmt_args.args = buf; } call_msg.rm_xid = 0; /* For error checking purposes */ ma.m_uaddr = NULL; if (!svc_getargs(transp, (xdrproc_t)xdr_rmtcall_args, (char *)&a)) { if (reply_type == RPCBPROC_INDIRECT) svcerr_decode(transp); if (debugging) fprintf(stderr, "rpcbproc_callit_com: svc_getargs failed\n"); goto error; } if (!allow_indirect) goto error; caller = svc_getrpccaller(transp); #ifdef RPCBIND_DEBUG uaddr = taddr2uaddr(rpcbind_get_conf(transp->xp_netid), caller); fprintf(stderr, "%s %s request for (%lu, %lu, %lu, %s) from %s : ", versnum == PMAPVERS ? "pmap_rmtcall" : versnum == RPCBVERS ? "rpcb_rmtcall" : versnum == RPCBVERS4 ? "rpcb_indirect" : "unknown", reply_type == RPCBPROC_INDIRECT ? "indirect" : "callit", a.rmt_prog, a.rmt_vers, a.rmt_proc, transp->xp_netid, uaddr ? uaddr : "unknown"); if (uaddr) free((void *) uaddr); #endif /* * Disallow calling rpcbind for certain procedures. * Allow calling NULLPROC - per man page on rpcb_rmtcall(). * switch is in alphabetical order. */ if (a.rmt_proc != NULLPROC) { switch (a.rmt_prog) { case KEY_PROG: if (debugging) fprintf(stderr, "rpcbind: rejecting KEY_PROG(%d)\n", a.rmt_proc); goto error; case MOUNTPROG: if (a.rmt_proc != MOUNTPROC_MNT) break; /* * In Solaris 2.6, the host-based accesss control * is done by the NFS server on each request. * Prior to 2.6 we rely on mountd. */ if (debugging) fprintf(stderr, "rpcbind: rejecting MOUNTPROG(%d)\n", a.rmt_proc); goto error; case NFS_ACL_PROGRAM: if (debugging) fprintf(stderr, "rpcbind: rejecting NFS_ACL_PROGRAM(%d)\n", a.rmt_proc); goto error; case NFS_PROGRAM: /* also NFS3_PROGRAM */ if (debugging) fprintf(stderr, "rpcbind: rejecting NFS_PROGRAM(%d)\n", a.rmt_proc); goto error; case RPCBPROG: /* * Disallow calling rpcbind for certain procedures. * Luckily Portmap set/unset/callit also have same * procedure numbers. So, will not check for those. */ switch (a.rmt_proc) { case RPCBPROC_SET: case RPCBPROC_UNSET: case RPCBPROC_CALLIT: case RPCBPROC_INDIRECT: if (reply_type == RPCBPROC_INDIRECT) svcerr_weakauth(transp); /* XXX */ if (debugging) fprintf(stderr, "rpcbproc_callit_com: calling RPCBPROG procs SET, UNSET, CALLIT, or INDIRECT \ not allowed \n"); goto error; default: /* * Ideally, we should have called rpcb_service() * or pmap_service() with appropriate parameters * instead of going about in a roundabout * manner. Hopefully, this case should happen * rarely. */ break; } break; case RQUOTAPROG: if (debugging) fprintf(stderr, "rpcbind: rejecting RQUOTAPROG(%d)\n", a.rmt_proc); goto error; case YPPASSWDPROG: if (debugging) fprintf(stderr, "rpcbind: rejecting YPPASSWDPROG(%d)\n", a.rmt_proc); goto error; case YPU_PROG: if (debugging) fprintf(stderr, "rpcbind: rejecting YPU_PROG(%d)\n", a.rmt_proc); goto error; case YPBINDPROG: if (a.rmt_proc != YPBINDPROC_SETDOM) break; if (debugging) fprintf(stderr, "rpcbind: rejecting YPBINDPROG(%d)\n", a.rmt_proc); goto error; case YPPROG: switch (a.rmt_proc) { case YPPROC_FIRST: case YPPROC_NEXT: case YPPROC_MATCH: case YPPROC_ALL: if (debugging) fprintf(stderr, "rpcbind: rejecting YPPROG(%d)\n", a.rmt_proc); goto error; default: break; } break; default: break; } } rbl = find_service(a.rmt_prog, a.rmt_vers, transp->xp_netid); rpcbs_rmtcall(versnum - 2, reply_type, a.rmt_prog, a.rmt_vers, a.rmt_proc, transp->xp_netid, rbl); if (rbl == (rpcblist_ptr)NULL) { #ifdef RPCBIND_DEBUG fprintf(stderr, "not found\n"); #endif if (reply_type == RPCBPROC_INDIRECT) svcerr_noprog(transp); goto error; } if (rbl->rpcb_map.r_vers != a.rmt_vers) { #ifdef RPCBIND_DEBUG fprintf(stderr, "version not found\n"); #endif if (reply_type == RPCBPROC_INDIRECT) { ulong_t vers_low, vers_high; find_versions(a.rmt_prog, transp->xp_netid, &vers_low, &vers_high); svcerr_progvers(transp, vers_low, vers_high); } goto error; } #ifdef RPCBIND_DEBUG fprintf(stderr, "found at uaddr %s\n", rbl->rpcb_map.r_addr); #endif /* * Check whether this entry is valid and a server is present * Mergeaddr() returns NULL if no such entry is present, and * returns "" if the entry was present but the server is not * present (i.e., it crashed). */ if (reply_type == RPCBPROC_INDIRECT) { uaddr = mergeaddr(transp, transp->xp_netid, rbl->rpcb_map.r_addr, NULL); if ((uaddr == (char *)NULL) || uaddr[0] == '\0') { svcerr_noprog(transp); goto error; } else { free((void *) uaddr); } } nconf = rpcbind_get_conf(transp->xp_netid); if (nconf == (struct netconfig *)NULL) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); if (debugging) fprintf(stderr, "rpcbproc_callit_com: rpcbind_get_conf failed\n"); goto error; } ma.c_uaddr = taddr2uaddr(nconf, caller); ma.s_uaddr = rbl->rpcb_map.r_addr; /* * A mergeaddr operation allocates a string, which it stores in * ma.m_uaddr. It's passed to forward_register() and is * eventually freed by free_slot_*(). */ stat = netdir_options(nconf, ND_MERGEADDR, 0, (char *)&ma); free((void *) ma.c_uaddr); if (stat) (void) syslog(LOG_ERR, "netdir_merge failed for %s: %s", nconf->nc_netid, netdir_sperror()); #ifdef ND_DEBUG fprintf(stderr, "rpcbproc_callit_com: s_uaddr = %s, c_uaddr = %s, merged m_uaddr = %s\n", ma.s_uaddr, ma.c_uaddr, ma.m_uaddr); #endif if ((fd = find_rmtcallfd_by_netid(nconf->nc_netid)) == -1) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); free((void *) ma.m_uaddr); ma.m_uaddr = NULL; goto error; } bd = get_svc_dg_data(transp); call_msg.rm_xid = forward_register(bd->su_xid, caller, fd, ma.m_uaddr, reply_type, versnum); if (call_msg.rm_xid == 0) { /* * A duplicate request for the slow server. Let's not * beat on it any more. */ if (debugging) fprintf(stderr, "rpcbproc_callit_com: duplicate request\n"); free((void *) ma.m_uaddr); ma.m_uaddr = NULL; goto error; } else if (call_msg.rm_xid == (uint32_t)-1) { /* forward_register failed. Perhaps no memory. */ if (debugging) fprintf(stderr, "rpcbproc_callit_com: forward_register failed\n"); free((void *) ma.m_uaddr); ma.m_uaddr = NULL; goto error; } #ifdef DEBUG_RMTCALL fprintf(stderr, "rpcbproc_callit_com: original XID %x, new XID %x\n", bd->su_xid, call_msg.rm_xid); #endif call_msg.rm_direction = CALL; call_msg.rm_call.cb_rpcvers = RPC_MSG_VERSION; call_msg.rm_call.cb_prog = a.rmt_prog; call_msg.rm_call.cb_vers = a.rmt_vers; if (sendsz > RPC_BUF_MAX) { #ifdef notyet outbuf_alloc = alloca(sendsz); /* not in IDR2? */ #else outbuf_alloc = malloc(sendsz); #endif /* notyet */ if (outbuf_alloc == NULL) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); if (debugging) fprintf(stderr, "rpcbproc_callit_com: No memory!\n"); goto error; } xdrmem_create(&outxdr, outbuf_alloc, sendsz, XDR_ENCODE); } else { xdrmem_create(&outxdr, outbuf, sendsz, XDR_ENCODE); } if (!xdr_callhdr(&outxdr, &call_msg)) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); if (debugging) fprintf(stderr, "rpcbproc_callit_com: xdr_callhdr failed\n"); goto error; } if (!xdr_u_long(&outxdr, &(a.rmt_proc))) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); if (debugging) fprintf(stderr, "rpcbproc_callit_com: xdr_u_long failed\n"); goto error; } if (rqstp->rq_cred.oa_flavor == AUTH_NULL) { auth = authnone_create(); } else if (rqstp->rq_cred.oa_flavor == AUTH_SYS) { struct authsys_parms *au; au = (struct authsys_parms *)rqstp->rq_clntcred; auth = authsys_create(au->aup_machname, au->aup_uid, au->aup_gid, au->aup_len, au->aup_gids); if (auth == NULL) /* fall back */ auth = authnone_create(); } else { /* we do not support any other authentication scheme */ if (debugging) fprintf(stderr, "rpcbproc_callit_com: oa_flavor != AUTH_NONE and oa_flavor != AUTH_SYS\n"); if (reply_type == RPCBPROC_INDIRECT) svcerr_weakauth(transp); /* XXX too strong.. */ goto error; } if (auth == NULL) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); if (debugging) fprintf(stderr, "rpcbproc_callit_com: authwhatever_create returned NULL\n"); goto error; } if (!AUTH_MARSHALL(auth, &outxdr)) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); AUTH_DESTROY(auth); if (debugging) fprintf(stderr, "rpcbproc_callit_com: AUTH_MARSHALL failed\n"); goto error; } AUTH_DESTROY(auth); if (!xdr_opaque_parms(&outxdr, &a)) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); if (debugging) fprintf(stderr, "rpcbproc_callit_com: xdr_opaque_parms failed\n"); goto error; } outlen = (int)XDR_GETPOS(&outxdr); if (outbuf_alloc) tu_data.udata.buf = outbuf_alloc; else tu_data.udata.buf = outbuf; tu_data.udata.len = outlen; tu_data.opt.len = 0; na = uaddr2taddr(nconf, ma.m_uaddr); if (!na) { if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); goto error; } tu_data.addr = *na; if (t_sndudata(fd, &tu_data) == -1) { if (debugging) fprintf(stderr, "rpcbproc_callit_com: t_sndudata failed: t_errno %d, errno %d\n", t_errno, errno); if (reply_type == RPCBPROC_INDIRECT) svcerr_systemerr(transp); goto error; } goto out; error: if ((call_msg.rm_xid != 0) && (ma.m_uaddr != NULL)) (void) free_slot_by_xid(call_msg.rm_xid, ma.m_uaddr); out: if (buf_alloc) free((void *) buf_alloc); if (outbuf_alloc) free((void *) outbuf_alloc); if (na) netdir_free((char *)na, ND_ADDR); } #define NFORWARD 64 #define MAXTIME_OFF 300 /* 5 minutes */ struct finfo { int flag; #define FINFO_ACTIVE 0x1 ulong_t caller_xid; struct netbuf *caller_addr; ulong_t forward_xid; int forward_fd; char *uaddr; ulong_t reply_type; ulong_t versnum; time_t time; }; static struct finfo FINFO[NFORWARD]; /* * Makes an entry into the FIFO for the given request. * If duplicate request, returns a 0, else returns the xid of its call. */ static ulong_t forward_register(caller_xid, caller_addr, forward_fd, uaddr, reply_type, versnum) ulong_t caller_xid; struct netbuf *caller_addr; int forward_fd; char *uaddr; ulong_t reply_type; ulong_t versnum; { int i; int j = 0; time_t min_time, time_now; static ulong_t lastxid; int entry = -1; min_time = FINFO[0].time; time_now = time((time_t *)0); /* * initialization: once this has happened, lastxid will * - always be a multiple of NFORWARD (which has to be a power of 2), * - never be 0 again, * - never be (ulong_t)(-NFORWARD) * when entering or returning from this function. */ if (lastxid == 0) { lastxid = time_now * NFORWARD; /* * avoid lastxid wraparound to 0, * and generating a forward_xid of -1 */ if (lastxid >= (ulong_t)(-NFORWARD)) lastxid = NFORWARD; } /* * Check if it is an duplicate entry. Then, * try to find an empty slot. If not available, then * use the slot with the earliest time. */ for (i = 0; i < NFORWARD; i++) { if (FINFO[i].flag & FINFO_ACTIVE) { if ((FINFO[i].caller_xid == caller_xid) && (FINFO[i].reply_type == reply_type) && (FINFO[i].versnum == versnum) && (!netbufcmp(FINFO[i].caller_addr, caller_addr))) { FINFO[i].time = time((time_t *)0); return (0); /* Duplicate entry */ } else { /* Should we wait any longer */ if ((time_now - FINFO[i].time) > MAXTIME_OFF) (void) free_slot_by_index(i); } } if (entry == -1) { if ((FINFO[i].flag & FINFO_ACTIVE) == 0) { entry = i; } else if (FINFO[i].time < min_time) { j = i; min_time = FINFO[i].time; } } } if (entry != -1) { /* use this empty slot */ j = entry; } else { (void) free_slot_by_index(j); } if ((FINFO[j].caller_addr = netbufdup(caller_addr)) == NULL) { return ((ulong_t)-1); } rpcb_rmtcalls++; /* no of pending calls */ FINFO[j].flag = FINFO_ACTIVE; FINFO[j].reply_type = reply_type; FINFO[j].versnum = versnum; FINFO[j].time = time_now; FINFO[j].caller_xid = caller_xid; FINFO[j].forward_fd = forward_fd; /* * Though uaddr is not allocated here, it will still be freed * from free_slot_*(). */ FINFO[j].uaddr = uaddr; lastxid = lastxid + NFORWARD; /* avoid lastxid wraparound to 0, and generating a forward_xid of -1 */ if (lastxid >= (ulong_t)(-NFORWARD)) lastxid = NFORWARD; FINFO[j].forward_xid = lastxid + j; /* encode slot */ return (FINFO[j].forward_xid); /* forward on this xid */ } static struct finfo * forward_find(reply_xid, uaddr) ulong_t reply_xid; char *uaddr; { int i; i = reply_xid % NFORWARD; if (i < 0) i += NFORWARD; if ((FINFO[i].flag & FINFO_ACTIVE) && (strcmp(FINFO[i].uaddr, uaddr) == 0) && (FINFO[i].forward_xid == reply_xid)) { return (&FINFO[i]); } return (NULL); } static int free_slot_by_xid(xid, uaddr) ulong_t xid; char *uaddr; { int entry; if (forward_find(xid, uaddr)) { entry = xid % NFORWARD; if (entry < 0) entry += NFORWARD; return (free_slot_by_index(entry)); } return (0); } static int free_slot_by_index(index) int index; { struct finfo *fi; fi = &FINFO[index]; if (fi->flag & FINFO_ACTIVE) { netbuffree(fi->caller_addr); free((void *) fi->uaddr); fi->flag &= ~FINFO_ACTIVE; rpcb_rmtcalls--; return (1); } return (0); } static int netbufcmp(n1, n2) struct netbuf *n1, *n2; { return ((n1->len != n2->len) || memcmp(n1->buf, n2->buf, n1->len)); } static struct netbuf * netbufdup(ap) register struct netbuf *ap; { register struct netbuf *np; np = (struct netbuf *) malloc(sizeof (struct netbuf) + ap->len); if (np) { np->maxlen = np->len = ap->len; np->buf = ((char *)np) + sizeof (struct netbuf); (void) memcpy(np->buf, ap->buf, ap->len); } return (np); } static void netbuffree(ap) register struct netbuf *ap; { free((void *) ap); } /* * active_fd is used to determine whether an entry in svc_pollfd is: * 1. not a forward fd (should be polled) * 2. an active forward fd (should be polled) * 3. an inactive forward fd (should not be polled) */ static bool_t active_fd(fd) int fd; { int i; time_t time_now; if (find_rmtcallxprt_by_fd(fd) == (SVCXPRT *)NULL) return (TRUE); if (rpcb_rmtcalls == 0) return (FALSE); time_now = time((time_t *)0); for (i = 0; i < NFORWARD; i++) if (FINFO[i].forward_fd == fd) { if (FINFO[i].flag & FINFO_ACTIVE) { /* Should we wait any longer */ if ((time_now - FINFO[i].time) > MAXTIME_OFF) (void) free_slot_by_index(i); else return (TRUE); } } return (FALSE); } #define MASKVAL (POLLIN | POLLPRI | POLLRDNORM | POLLRDBAND) void my_svc_run() { size_t nfds; struct pollfd pollfds[FD_SETSIZE]; int poll_ret, check_ret; #ifdef SVC_RUN_DEBUG int i; #endif register struct pollfd *p; for (;;) { { register pollfd_t *in; register int n; /* loop counter */ /* * compress the sparse svc_pollfd strcutre * into pollfds */ memset(pollfds, 0, sizeof (pollfds)); p = pollfds; for (in = svc_pollfd, n = 0; n < svc_max_pollfd; n++, in++) { if ((in->fd >= 0) && active_fd(in->fd)) { p->fd = in->fd; p->events = MASKVAL; p->revents = 0; p++; } } nfds = p - pollfds; } poll_ret = 0; #ifdef SVC_RUN_DEBUG if (debugging) { fprintf(stderr, "polling for read on fd < "); for (i = 0, p = pollfds; i < nfds; i++, p++) if (p->events) fprintf(stderr, "%d ", p->fd); fprintf(stderr, ">\n"); } #endif switch (poll_ret = poll(pollfds, nfds, INFTIM)) { case -1: /* * We ignore all errors, continuing with the assumption * that it was set by the signal handlers (or any * other outside event) and not caused by poll(). * If it was our refresh signal, call the refresh * function. */ if (sigrefresh) { sigrefresh = 0; rpcb_check_init(); } case 0: continue; default: #ifdef SVC_RUN_DEBUG if (debugging) { fprintf(stderr, "poll returned read fds < "); for (i = 0, p = pollfds; i < nfds; i++, p++) if (p->revents) fprintf(stderr, "%d ", p->fd); fprintf(stderr, ">\n"); } #endif /* * If we found as many replies on callback fds * as the number of descriptors selectable which * poll() returned, there can be no more so we * don't call svc_getreq_poll. Otherwise, there * must be another so we must call svc_getreq_poll. */ if ((check_ret = check_rmtcalls(pollfds, nfds)) == poll_ret) continue; svc_getreq_poll(pollfds, poll_ret-check_ret); } } } static int check_rmtcalls(pfds, nfds) struct pollfd *pfds; int nfds; { int j, ncallbacks_found = 0; SVCXPRT *xprt; /* * This fd will not be polled if rpcb_rmtcalls == 0 */ if (rpcb_rmtcalls == 0) return (0); for (j = 0; j < nfds; j++) { if ((xprt = find_rmtcallxprt_by_fd(pfds[j].fd)) != NULL) { if (pfds[j].revents) { ncallbacks_found++; #ifdef DEBUG_RMTCALL if (debugging) fprintf(stderr, "my_svc_run: polled on forwarding fd %d, netid %s - calling handle_reply\n", pfds[j].fd, xprt->xp_netid); #endif handle_reply(pfds[j].fd, xprt); pfds[j].revents = 0; } } } return (ncallbacks_found); } static void xprt_set_caller(xprt, fi) SVCXPRT *xprt; struct finfo *fi; { struct svc_dg_data *bd; *(svc_getrpccaller(xprt)) = *(fi->caller_addr); bd = get_svc_dg_data(xprt); bd->su_xid = fi->caller_xid; /* set xid on reply */ } /* * Call svcerr_systemerr() only if RPCBVERS4 */ static void send_svcsyserr(xprt, fi) SVCXPRT *xprt; struct finfo *fi; { if (fi->reply_type == RPCBPROC_INDIRECT) { xprt_set_caller(xprt, fi); svcerr_systemerr(xprt); } } static void handle_reply(fd, xprt) int fd; SVCXPRT *xprt; { XDR reply_xdrs; struct rpc_msg reply_msg; struct rpc_err reply_error; char *buffer; struct finfo *fi = NULL; int inlen, pos, len, res, i; struct r_rmtcall_args a; struct t_unitdata *tr_data = NULL, *tu_data; struct netconfig *nconf = NULL; char *uaddr = NULL; nconf = rpcbind_get_conf(xprt->xp_netid); if (nconf == NULL) { #ifdef SVC_RUN_DEBUG if (debugging) fprintf(stderr, "handle_reply: null xp_netid\n"); #endif goto done; } /* * If this fd is not active on the forward list, ignore it * If the svc_pollfd structure has multiple settings * of the same fd, then it will enter handle_reply() for the first one, * set FINFO_ACTIVE false and then get another call to handle_reply() * with the same, now inactive, fd. */ for (i = 0; i < NFORWARD; i++) { if ((FINFO[i].forward_fd == fd) && (FINFO[i].flag & FINFO_ACTIVE)) break; } if (i == NFORWARD) { #ifdef SVC_RUN_DEBUG if (debugging) { fprintf(stderr, "Unsolicited message on rmtcall fd\n"); } #endif return; } reply_msg.rm_xid = 0; /* for easier error handling */ tr_data = (struct t_unitdata *)t_alloc(fd, T_UNITDATA, T_ADDR | T_UDATA); if (tr_data == (struct t_unitdata *)NULL) { if (debugging) fprintf(stderr, "handle_reply: t_alloc T_UNITDATA failed\n"); goto done; } do { int moreflag; moreflag = 0; if (errno == EINTR) errno = 0; res = t_rcvudata(fd, tr_data, &moreflag); if (moreflag & T_MORE) { /* Drop this packet - we have no more space. */ if (debugging) fprintf(stderr, "handle_reply: recvd packet with T_MORE flag set\n"); goto done; } } while (res < 0 && (t_errno == TSYSERR && errno == EINTR)); if (res < 0) { if (t_errno == TLOOK) { if (debugging) fprintf(stderr, "handle_reply: t_rcvudata returned %d, t_errno TLOOK\n", res); (void) t_rcvuderr(fd, (struct t_uderr *)NULL); } if (debugging) fprintf(stderr, "handle_reply: t_rcvudata returned %d, t_errno %d, errno %d\n", res, t_errno, errno); goto done; } inlen = tr_data->udata.len; uaddr = taddr2uaddr(nconf, &tr_data->addr); if (uaddr == NULL) goto done; #ifdef DEBUG_MORE if (debugging) fprintf(stderr, "handle_reply: t_rcvudata received %d-byte packet from %s\n", inlen, uaddr); #endif buffer = tr_data->udata.buf; if (buffer == (char *)NULL) { goto done; } reply_msg.acpted_rply.ar_verf = _null_auth; reply_msg.acpted_rply.ar_results.where = 0; reply_msg.acpted_rply.ar_results.proc = (xdrproc_t)xdr_void; xdrmem_create(&reply_xdrs, buffer, (uint_t)inlen, XDR_DECODE); if (!xdr_replymsg(&reply_xdrs, &reply_msg)) { if (debugging) (void) fprintf(stderr, "handle_reply: xdr_replymsg failed\n"); goto done; } fi = forward_find((ulong_t)reply_msg.rm_xid, uaddr); if (fi == NULL) goto done; #ifdef SVC_RUN_DEBUG if (debugging) { fprintf(stderr, "handle_reply: reply xid: %d fi addr: %x\n", reply_msg.rm_xid, fi); } #endif __seterr_reply(&reply_msg, &reply_error); if (reply_error.re_status != RPC_SUCCESS) { if (debugging) (void) fprintf(stderr, "handle_reply: %s\n", clnt_sperrno(reply_error.re_status)); send_svcsyserr(xprt, fi); goto done; } pos = XDR_GETPOS(&reply_xdrs); len = inlen - pos; a.rmt_args.args = &buffer[pos]; a.rmt_args.arglen = len; a.rmt_uaddr = fi->uaddr; a.rmt_localvers = fi->versnum; xprt_set_caller(xprt, fi); /* XXX hack */ tu_data = &(get_svc_dg_data(xprt)->su_tudata); tu_data->addr = xprt->xp_rtaddr; #ifdef SVC_RUN_DEBUG if (uaddr) free((void *) uaddr); uaddr = taddr2uaddr(nconf, svc_getrpccaller(xprt)); if (debugging) { fprintf(stderr, "handle_reply: forwarding address %s to %s\n", a.rmt_uaddr, uaddr ? uaddr : "unknown"); } #endif svc_sendreply(xprt, (xdrproc_t)xdr_rmtcall_result, (char *)&a); done: if (uaddr) free((void *) uaddr); if (tr_data) t_free((char *)tr_data, T_UNITDATA); if ((fi == NULL) || (reply_msg.rm_xid == 0)) { #ifdef SVC_RUN_DEBUG if (debugging) { fprintf(stderr, "handle_reply: NULL xid on exit!\n"); } #endif } else (void) free_slot_by_xid((ulong_t)reply_msg.rm_xid, fi->uaddr); } static void find_versions(prog, netid, lowvp, highvp) ulong_t prog; /* Program Number */ char *netid; /* Transport Provider token */ ulong_t *lowvp; /* Low version number */ ulong_t *highvp; /* High version number */ { register rpcblist_ptr rbl; int lowv = 0; int highv = 0; for (rbl = list_rbl; rbl != NULL; rbl = rbl->rpcb_next) { if ((rbl->rpcb_map.r_prog != prog) || ((rbl->rpcb_map.r_netid != NULL) && (strcasecmp(rbl->rpcb_map.r_netid, netid) != 0))) continue; if (lowv == 0) { highv = rbl->rpcb_map.r_vers; lowv = highv; } else if (rbl->rpcb_map.r_vers < lowv) { lowv = rbl->rpcb_map.r_vers; } else if (rbl->rpcb_map.r_vers > highv) { highv = rbl->rpcb_map.r_vers; } } *lowvp = lowv; *highvp = highv; } /* * returns the item with the given program, version number and netid. * If that version number is not found, it returns the item with that * program number, so that address is now returned to the caller. The * caller when makes a call to this program, version number, the call * will fail and it will return with PROGVERS_MISMATCH. The user can * then determine the highest and the lowest version number for this * program using clnt_geterr() and use those program version numbers. * * Returns the RPCBLIST for the given prog, vers and netid */ static rpcblist_ptr find_service(prog, vers, netid) ulong_t prog; /* Program Number */ ulong_t vers; /* Version Number */ char *netid; /* Transport Provider token */ { register rpcblist_ptr hit = NULL; register rpcblist_ptr rbl; for (rbl = list_rbl; rbl != NULL; rbl = rbl->rpcb_next) { if ((rbl->rpcb_map.r_prog != prog) || ((rbl->rpcb_map.r_netid != NULL) && (strcasecmp(rbl->rpcb_map.r_netid, netid) != 0))) continue; hit = rbl; if (rbl->rpcb_map.r_vers == vers) break; } return (hit); } /* * If the caller is from our zone and we know * who it is, we return the uid. */ uid_t rpcb_caller_uid(SVCXPRT *transp) { ucred_t *uc = alloca(ucred_size()); static zoneid_t myzone = MIN_ZONEID - 1; uid_t uid; if (myzone == MIN_ZONEID - 1) myzone = getzoneid(); if (svc_getcallerucred(transp, &uc) != 0 || (ucred_getzoneid(uc)) != myzone) { return (-1); } else { return (ucred_geteuid(uc)); } } /* * Copies the name associated with the uid of the caller and returns * a pointer to it. Similar to getwd(). */ char * getowner(transp, owner) SVCXPRT *transp; char *owner; { uid_t uid = rpcb_caller_uid(transp); switch (uid) { case -1: return (strcpy(owner, "unknown")); case 0: return (strcpy(owner, "superuser")); default: (void) sprintf(owner, "%u", uid); return (owner); } } #ifdef PORTMAP /* * Add this to the pmap list only if it is UDP or TCP. */ static int add_pmaplist(arg) RPCB *arg; { pmap pmap; pmaplist *pml; int h1, h2, h3, h4, p1, p2; if (strcmp(arg->r_netid, udptrans) == 0) { /* It is UDP! */ pmap.pm_prot = IPPROTO_UDP; } else if (strcmp(arg->r_netid, tcptrans) == 0) { /* It is TCP */ pmap.pm_prot = IPPROTO_TCP; } else /* Not a IP protocol */ return (0); /* interpret the universal address for TCP/IP */ if (sscanf(arg->r_addr, "%d.%d.%d.%d.%d.%d", &h1, &h2, &h3, &h4, &p1, &p2) != 6) return (0); pmap.pm_port = ((p1 & 0xff) << 8) + (p2 & 0xff); pmap.pm_prog = arg->r_prog; pmap.pm_vers = arg->r_vers; /* * add to END of list */ pml = (pmaplist *) malloc((uint_t)sizeof (pmaplist)); if (pml == NULL) { (void) syslog(LOG_ERR, "rpcbind: no memory!\n"); return (1); } pml->pml_map = pmap; pml->pml_next = NULL; if (list_pml == NULL) { list_pml = pml; } else { pmaplist *fnd; /* Attach to the end of the list */ for (fnd = list_pml; fnd->pml_next; fnd = fnd->pml_next) ; fnd->pml_next = pml; } return (0); } /* * Delete this from the pmap list only if it is UDP or TCP. */ int del_pmaplist(RPCB *arg) { register pmaplist *pml; pmaplist *prevpml, *fnd; long prot; if (strcmp(arg->r_netid, udptrans) == 0) { /* It is UDP! */ prot = IPPROTO_UDP; } else if (strcmp(arg->r_netid, tcptrans) == 0) { /* It is TCP */ prot = IPPROTO_TCP; } else if (arg->r_netid[0] == NULL) { prot = 0; /* Remove all occurrences */ } else { /* Not a IP protocol */ return (0); } for (prevpml = NULL, pml = list_pml; pml; /* cstyle */) { if ((pml->pml_map.pm_prog != arg->r_prog) || (pml->pml_map.pm_vers != arg->r_vers) || (prot && (pml->pml_map.pm_prot != prot))) { /* both pml & prevpml move forwards */ prevpml = pml; pml = pml->pml_next; continue; } /* found it; pml moves forward, prevpml stays */ fnd = pml; pml = pml->pml_next; if (prevpml == NULL) list_pml = pml; else prevpml->pml_next = pml; free((void *) fnd); } return (0); } #endif /* PORTMAP */