/* * Copyright (c) 1983, 1988, 1993 * The Regents of the University of California. All rights reserved. * * %sccs.include.redist.c% */ #ifndef lint static char sccsid[] = "@(#)route.c 8.6 (Berkeley) 04/28/95"; #endif /* not lint */ #include #include #include #include #include #include #include #define KERNEL #include #undef KERNEL #include #include #include #include #include #include #include #include #include "netstat.h" #define kget(p, d) (kread((u_long)(p), (char *)&(d), sizeof (d))) /* * Definitions for showing gateway flags. */ struct bits { short b_mask; char b_val; } bits[] = { { RTF_UP, 'U' }, { RTF_GATEWAY, 'G' }, { RTF_HOST, 'H' }, { RTF_REJECT, 'R' }, { RTF_DYNAMIC, 'D' }, { RTF_MODIFIED, 'M' }, { RTF_DONE, 'd' }, /* Completed -- for routing messages only */ { RTF_MASK, 'm' }, /* Mask Present -- for routing messages only */ { RTF_CLONING, 'C' }, { RTF_XRESOLVE, 'X' }, { RTF_LLINFO, 'L' }, { RTF_STATIC, 'S' }, { RTF_PROTO1, '1' }, { RTF_PROTO2, '2' }, { 0 } }; static union { struct sockaddr u_sa; u_short u_data[128]; } pt_u; int do_rtent = 0; struct rtentry rtentry; struct radix_node rnode; struct radix_mask rmask; int NewTree = 0; static struct sockaddr *kgetsa __P((struct sockaddr *)); static void p_tree __P((struct radix_node *)); static void p_rtnode __P(()); static void ntreestuff __P(()); static void np_rtentry __P((struct rt_msghdr *)); static void p_sockaddr __P((struct sockaddr *, struct sockaddr *, int, int)); static void p_flags __P((int, char *)); static void p_rtentry __P((struct rtentry *)); /* * Print routing tables. */ void routepr(rtree) u_long rtree; { struct radix_node_head *rnh, head; int i; printf("Routing tables\n"); if (Aflag == 0 && NewTree) ntreestuff(); else { if (rtree == 0) { printf("rt_tables: symbol not in namelist\n"); return; } kget(rtree, rt_tables); for (i = 0; i <= AF_MAX; i++) { if ((rnh = rt_tables[i]) == 0) continue; kget(rnh, head); if (i == AF_UNSPEC) { if (Aflag && af == 0) { printf("Netmasks:\n"); p_tree(head.rnh_treetop); } } else if (af == AF_UNSPEC || af == i) { pr_family(i); do_rtent = 1; pr_rthdr(); p_tree(head.rnh_treetop); } } } } /* * Print address family header before a section of the routing table. */ void pr_family(af) int af; { char *afname; switch (af) { case AF_INET: afname = "Internet"; break; case AF_NS: afname = "XNS"; break; case AF_ISO: afname = "ISO"; break; case AF_CCITT: afname = "X.25"; break; default: afname = NULL; break; } if (afname) printf("\n%s:\n", afname); else printf("\nProtocol Family %d:\n", af); } /* column widths; each followed by one space */ #define WID_DST 16 /* width of destination column */ #define WID_GW 18 /* width of gateway column */ /* * Print header for routing table columns. */ void pr_rthdr() { if (Aflag) printf("%-8.8s ","Address"); printf("%-*.*s %-*.*s %-6.6s %6.6s%8.8s %s\n", WID_DST, WID_DST, "Destination", WID_GW, WID_GW, "Gateway", "Flags", "Refs", "Use", "Interface"); } static struct sockaddr * kgetsa(dst) register struct sockaddr *dst; { kget(dst, pt_u.u_sa); if (pt_u.u_sa.sa_len > sizeof (pt_u.u_sa)) kread((u_long)dst, (char *)pt_u.u_data, pt_u.u_sa.sa_len); return (&pt_u.u_sa); } static void p_tree(rn) struct radix_node *rn; { again: kget(rn, rnode); if (rnode.rn_b < 0) { if (Aflag) printf("%-8.8x ", rn); if (rnode.rn_flags & RNF_ROOT) { if (Aflag) printf("(root node)%s", rnode.rn_dupedkey ? " =>\n" : "\n"); } else if (do_rtent) { kget(rn, rtentry); p_rtentry(&rtentry); if (Aflag) p_rtnode(); } else { p_sockaddr(kgetsa((struct sockaddr *)rnode.rn_key), NULL, 0, 44); putchar('\n'); } if (rn = rnode.rn_dupedkey) goto again; } else { if (Aflag && do_rtent) { printf("%-8.8x ", rn); p_rtnode(); } rn = rnode.rn_r; p_tree(rnode.rn_l); p_tree(rn); } } char nbuf[20]; static void p_rtnode() { struct radix_mask *rm = rnode.rn_mklist; if (rnode.rn_b < 0) { if (rnode.rn_mask) { printf("\t mask "); p_sockaddr(kgetsa((struct sockaddr *)rnode.rn_mask), NULL, 0, -1); } else if (rm == 0) return; } else { sprintf(nbuf, "(%d)", rnode.rn_b); printf("%6.6s %8.8x : %8.8x", nbuf, rnode.rn_l, rnode.rn_r); } while (rm) { kget(rm, rmask); sprintf(nbuf, " %d refs, ", rmask.rm_refs); printf(" mk = %8.8x {(%d),%s", rm, -1 - rmask.rm_b, rmask.rm_refs ? nbuf : " "); if (rmask.rm_flags & RNF_NORMAL) { struct radix_node rnode_aux; printf(" , "); kget(rmask.rm_leaf, rnode_aux); p_sockaddr(kgetsa((struct sockaddr *)rnode_aux.rn_mask), NULL, 0, -1); } else p_sockaddr(kgetsa((struct sockaddr *)rmask.rm_mask), NULL, 0, -1); putchar('}'); if (rm = rmask.rm_mklist) printf(" ->"); } putchar('\n'); } static void ntreestuff() { size_t needed; int mib[6]; char *buf, *next, *lim; register struct rt_msghdr *rtm; mib[0] = CTL_NET; mib[1] = PF_ROUTE; mib[2] = 0; mib[3] = 0; mib[4] = NET_RT_DUMP; mib[5] = 0; if (sysctl(mib, 6, NULL, &needed, NULL, 0) < 0) { perror("route-sysctl-estimate"); exit(1);} if ((buf = malloc(needed)) == 0) { printf("out of space\n"); exit(1);} if (sysctl(mib, 6, buf, &needed, NULL, 0) < 0) { perror("sysctl of routing table"); exit(1);} lim = buf + needed; for (next = buf; next < lim; next += rtm->rtm_msglen) { rtm = (struct rt_msghdr *)next; np_rtentry(rtm); } } static void np_rtentry(rtm) register struct rt_msghdr *rtm; { register struct sockaddr *sa = (struct sockaddr *)(rtm + 1); #ifdef notdef static int masks_done, banner_printed; #endif static int old_af; int af = 0, interesting = RTF_UP | RTF_GATEWAY | RTF_HOST; #ifdef notdef /* for the moment, netmasks are skipped over */ if (!banner_printed) { printf("Netmasks:\n"); banner_printed = 1; } if (masks_done == 0) { if (rtm->rtm_addrs != RTA_DST ) { masks_done = 1; af = sa->sa_family; } } else #endif af = sa->sa_family; if (af != old_af) { pr_family(af); old_af = af; } if (rtm->rtm_addrs == RTA_DST) p_sockaddr(sa, NULL, 0, 36); else { p_sockaddr(sa, NULL, rtm->rtm_flags, 16); if (sa->sa_len == 0) sa->sa_len = sizeof(long); sa = (struct sockaddr *)(sa->sa_len + (char *)sa); p_sockaddr(sa, NULL, 0, 18); } p_flags(rtm->rtm_flags & interesting, "%-6.6s "); putchar('\n'); } static void p_sockaddr(sa, mask, flags, width) struct sockaddr *sa, *mask; int flags, width; { char workbuf[128], *cplim; register char *cp = workbuf; switch(sa->sa_family) { case AF_INET: { register struct sockaddr_in *sin = (struct sockaddr_in *)sa; if (sin->sin_addr.s_addr == INADDR_ANY) cp = "default"; else if (flags & RTF_HOST) cp = routename(sin->sin_addr.s_addr); else if (mask) cp = netname(sin->sin_addr.s_addr, ntohl(((struct sockaddr_in *)mask) ->sin_addr.s_addr)); else cp = netname(sin->sin_addr.s_addr, 0L); break; } case AF_NS: cp = ns_print(sa); break; case AF_LINK: { register struct sockaddr_dl *sdl = (struct sockaddr_dl *)sa; if (sdl->sdl_nlen == 0 && sdl->sdl_alen == 0 && sdl->sdl_slen == 0) (void) sprintf(workbuf, "link#%d", sdl->sdl_index); else switch (sdl->sdl_type) { case IFT_ETHER: { register int i; register u_char *lla = (u_char *)sdl->sdl_data + sdl->sdl_nlen; cplim = ""; for (i = 0; i < sdl->sdl_alen; i++, lla++) { cp += sprintf(cp, "%s%x", cplim, *lla); cplim = ":"; } cp = workbuf; break; } default: cp = link_ntoa(sdl); break; } break; } default: { register u_char *s = (u_char *)sa->sa_data, *slim; slim = sa->sa_len + (u_char *) sa; cplim = cp + sizeof(workbuf) - 6; cp += sprintf(cp, "(%d)", sa->sa_family); while (s < slim && cp < cplim) { cp += sprintf(cp, " %02x", *s++); if (s < slim) cp += sprintf(cp, "%02x", *s++); } cp = workbuf; } } if (width < 0 ) printf("%s ", cp); else { if (nflag) printf("%-*s ", width, cp); else printf("%-*.*s ", width, width, cp); } } static void p_flags(f, format) register int f; char *format; { char name[33], *flags; register struct bits *p = bits; for (flags = name; p->b_mask; p++) if (p->b_mask & f) *flags++ = p->b_val; *flags = '\0'; printf(format, name); } static void p_rtentry(rt) register struct rtentry *rt; { static struct ifnet ifnet, *lastif; static char name[16]; register struct sockaddr *sa; struct sockaddr addr, mask; if (!(sa = kgetsa(rt_key(rt)))) bzero(&addr, sizeof addr); else addr = *sa; if (!rt_mask(rt) || !(sa = kgetsa(rt_mask(rt)))) bzero(&mask, sizeof mask); else mask = *sa; p_sockaddr(&addr, &mask, rt->rt_flags, WID_DST); p_sockaddr(kgetsa(rt->rt_gateway), NULL, RTF_HOST, WID_GW); p_flags(rt->rt_flags, "%-6.6s "); printf("%6d %8d ", rt->rt_refcnt, rt->rt_use); if (rt->rt_ifp) { if (rt->rt_ifp != lastif) { kget(rt->rt_ifp, ifnet); kread((u_long)ifnet.if_name, name, 16); lastif = rt->rt_ifp; } printf(" %.15s%d%s", name, ifnet.if_unit, rt->rt_nodes[0].rn_dupedkey ? " =>" : ""); } putchar('\n'); } char * routename(in) u_long in; { register char *cp; static char line[MAXHOSTNAMELEN + 1]; struct hostent *hp; static char domain[MAXHOSTNAMELEN + 1]; static int first = 1; if (first) { first = 0; if (gethostname(domain, MAXHOSTNAMELEN) == 0 && (cp = index(domain, '.'))) (void) strcpy(domain, cp + 1); else domain[0] = 0; } cp = 0; if (!nflag) { hp = gethostbyaddr((char *)&in, sizeof (struct in_addr), AF_INET); if (hp) { if ((cp = index(hp->h_name, '.')) && !strcmp(cp + 1, domain)) *cp = 0; cp = hp->h_name; } } if (cp) strncpy(line, cp, sizeof(line) - 1); else { #define C(x) ((x) & 0xff) in = ntohl(in); sprintf(line, "%u.%u.%u.%u", C(in >> 24), C(in >> 16), C(in >> 8), C(in)); } return (line); } static u_long forgemask(a) u_long a; { u_long m; if (IN_CLASSA(a)) m = IN_CLASSA_NET; else if (IN_CLASSB(a)) m = IN_CLASSB_NET; else m = IN_CLASSC_NET; return (m); } static void domask(dst, addr, mask) char *dst; u_long addr, mask; { register int b, i; if (!mask || (forgemask(addr) == mask)) { *dst = '\0'; return; } i = 0; for (b = 0; b < 32; b++) if (mask & (1 << b)) { register int bb; i = b; for (bb = b+1; bb < 32; bb++) if (!(mask & (1 << bb))) { i = -1; /* noncontig */ break; } break; } if (i == -1) sprintf(dst, "&0x%lx", mask); else sprintf(dst, "/%d", 32-i); } /* * Return the name of the network whose address is given. * The address is assumed to be that of a net or subnet, not a host. */ char * netname(in, mask) u_long in, mask; { char *cp = 0; static char line[MAXHOSTNAMELEN + 1]; struct netent *np = 0; u_long net, omask; register u_long i; int subnetshift; i = ntohl(in); omask = mask; if (!nflag && i) { if (mask == 0) { switch (mask = forgemask(i)) { case IN_CLASSA_NET: subnetshift = 8; break; case IN_CLASSB_NET: subnetshift = 8; break; case IN_CLASSC_NET: subnetshift = 4; break; default: abort(); } /* * If there are more bits than the standard mask * would suggest, subnets must be in use. * Guess at the subnet mask, assuming reasonable * width subnet fields. */ while (i &~ mask) mask = (long)mask >> subnetshift; } net = i & mask; while ((mask & 1) == 0) mask >>= 1, net >>= 1; np = getnetbyaddr(net, AF_INET); if (np) cp = np->n_name; } if (cp) strncpy(line, cp, sizeof(line) - 1); else if ((i & 0xffffff) == 0) sprintf(line, "%u", C(i >> 24)); else if ((i & 0xffff) == 0) sprintf(line, "%u.%u", C(i >> 24) , C(i >> 16)); else if ((i & 0xff) == 0) sprintf(line, "%u.%u.%u", C(i >> 24), C(i >> 16), C(i >> 8)); else sprintf(line, "%u.%u.%u.%u", C(i >> 24), C(i >> 16), C(i >> 8), C(i)); domask(line+strlen(line), i, omask); return (line); } /* * Print routing statistics */ void rt_stats(off) u_long off; { struct rtstat rtstat; if (off == 0) { printf("rtstat: symbol not in namelist\n"); return; } kread(off, (char *)&rtstat, sizeof (rtstat)); printf("routing:\n"); printf("\t%u bad routing redirect%s\n", rtstat.rts_badredirect, plural(rtstat.rts_badredirect)); printf("\t%u dynamically created route%s\n", rtstat.rts_dynamic, plural(rtstat.rts_dynamic)); printf("\t%u new gateway%s due to redirects\n", rtstat.rts_newgateway, plural(rtstat.rts_newgateway)); printf("\t%u destination%s found unreachable\n", rtstat.rts_unreach, plural(rtstat.rts_unreach)); printf("\t%u use%s of a wildcard route\n", rtstat.rts_wildcard, plural(rtstat.rts_wildcard)); } short ns_nullh[] = {0,0,0}; short ns_bh[] = {-1,-1,-1}; char * ns_print(sa) register struct sockaddr *sa; { register struct sockaddr_ns *sns = (struct sockaddr_ns*)sa; struct ns_addr work; union { union ns_net net_e; u_long long_e; } net; u_short port; static char mybuf[50], cport[10], chost[25]; char *host = ""; register char *p; register u_char *q; work = sns->sns_addr; port = ntohs(work.x_port); work.x_port = 0; net.net_e = work.x_net; if (ns_nullhost(work) && net.long_e == 0) { if (port ) { sprintf(mybuf, "*.%xH", port); upHex(mybuf); } else sprintf(mybuf, "*.*"); return (mybuf); } if (bcmp(ns_bh, work.x_host.c_host, 6) == 0) { host = "any"; } else if (bcmp(ns_nullh, work.x_host.c_host, 6) == 0) { host = "*"; } else { q = work.x_host.c_host; sprintf(chost, "%02x%02x%02x%02x%02x%02xH", q[0], q[1], q[2], q[3], q[4], q[5]); for (p = chost; *p == '0' && p < chost + 12; p++) continue; host = p; } if (port) sprintf(cport, ".%xH", htons(port)); else *cport = 0; sprintf(mybuf,"%xH.%s%s", ntohl(net.long_e), host, cport); upHex(mybuf); return(mybuf); } char * ns_phost(sa) struct sockaddr *sa; { register struct sockaddr_ns *sns = (struct sockaddr_ns *)sa; struct sockaddr_ns work; static union ns_net ns_zeronet; char *p; work = *sns; work.sns_addr.x_port = 0; work.sns_addr.x_net = ns_zeronet; p = ns_print((struct sockaddr *)&work); if (strncmp("0H.", p, 3) == 0) p += 3; return(p); } void upHex(p0) char *p0; { register char *p = p0; for (; *p; p++) switch (*p) { case 'a': case 'b': case 'c': case 'd': case 'e': case 'f': *p += ('A' - 'a'); } }