// L2TPNS PPP Stuff char const *cvs_id_ppp = "$Id: ppp.c,v 1.103 2007/01/25 12:36:48 bodea Exp $"; #include #include #include #include #include #include "l2tpns.h" #include "constants.h" #include "plugin.h" #include "util.h" #include "tbf.h" #include "cluster.h" extern tunnelt *tunnel; extern bundlet *bundle; extern fragmentationt *frag; extern sessiont *session; extern radiust *radius; extern int tunfd; extern char hostname[]; extern uint32_t eth_tx; extern time_t time_now; extern configt *config; static int add_lcp_auth(uint8_t *b, int size, int authtype); static bundleidt new_bundle(void); static int epdiscmp(epdist, epdist); static void setepdis(epdist *, epdist); static void ipcp_open(sessionidt s, tunnelidt t); // Process PAP messages void processpap(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { char user[MAXUSER]; char pass[MAXPASS]; uint16_t hl; uint16_t r; CSTAT(processpap); LOG_HEX(5, "PAP", p, l); if (l < 4) { LOG(1, s, t, "Short PAP %u bytes\n", l); STAT(tunnel_rx_errors); sessionshutdown(s, "Short PAP packet.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } if ((hl = ntohs(*(uint16_t *) (p + 2))) > l) { LOG(1, s, t, "Length mismatch PAP %u/%u\n", hl, l); STAT(tunnel_rx_errors); sessionshutdown(s, "PAP length mismatch.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } l = hl; if (*p != 1) { LOG(1, s, t, "Unexpected PAP code %d\n", *p); STAT(tunnel_rx_errors); sessionshutdown(s, "Unexpected PAP code.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } if (session[s].ppp.phase != Authenticate) { LOG(2, s, t, "PAP ignored in %s phase\n", ppp_phase(session[s].ppp.phase)); return; } { uint8_t *b = p; b += 4; user[0] = pass[0] = 0; if (*b && *b < sizeof(user)) { memcpy(user, b + 1, *b); user[*b] = 0; b += 1 + *b; if (*b && *b < sizeof(pass)) { memcpy(pass, b + 1, *b); pass[*b] = 0; } } LOG(3, s, t, "PAP login %s/%s\n", user, pass); } if (session[s].ip || !(r = radiusnew(s))) { // respond now, either no RADIUS available or already authenticated uint8_t b[MAXETHER]; uint8_t id = p[1]; uint8_t *p = makeppp(b, sizeof(b), 0, 0, s, t, PPPPAP, 0, 0, 0); if (!p) return; if (session[s].ip) *p = 2; // ACK else *p = 3; // cant authorise p[1] = id; *(uint16_t *) (p + 2) = htons(5); // length p[4] = 0; // no message tunnelsend(b, 5 + (p - b), t); // send it if (session[s].ip) { LOG(3, s, t, "Already an IP allocated: %s (%d)\n", fmtaddr(htonl(session[s].ip), 0), session[s].ip_pool_index); } else { LOG(1, s, t, "No RADIUS session available to authenticate session...\n"); sessionshutdown(s, "No free RADIUS sessions.", CDN_UNAVAILABLE, TERM_SERVICE_UNAVAILABLE); } } else { // Run PRE_AUTH plugins struct param_pre_auth packet = { &tunnel[t], &session[s], strdup(user), strdup(pass), PPPPAP, 1 }; run_plugins(PLUGIN_PRE_AUTH, &packet); if (!packet.continue_auth) { LOG(3, s, t, "A plugin rejected PRE_AUTH\n"); if (packet.username) free(packet.username); if (packet.password) free(packet.password); return; } strncpy(session[s].user, packet.username, sizeof(session[s].user) - 1); strncpy(radius[r].pass, packet.password, sizeof(radius[r].pass) - 1); free(packet.username); free(packet.password); radius[r].id = p[1]; LOG(3, s, t, "Sending login for %s/%s to RADIUS\n", user, pass); radiussend(r, RADIUSAUTH); } } // Process CHAP messages void processchap(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { uint16_t r; uint16_t hl; CSTAT(processchap); LOG_HEX(5, "CHAP", p, l); if (l < 4) { LOG(1, s, t, "Short CHAP %u bytes\n", l); STAT(tunnel_rx_errors); sessionshutdown(s, "Short CHAP packet.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } if ((hl = ntohs(*(uint16_t *) (p + 2))) > l) { LOG(1, s, t, "Length mismatch CHAP %u/%u\n", hl, l); STAT(tunnel_rx_errors); sessionshutdown(s, "CHAP length mismatch.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } l = hl; if (*p != 2) { LOG(1, s, t, "Unexpected CHAP response code %d\n", *p); STAT(tunnel_rx_errors); sessionshutdown(s, "CHAP length mismatch.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } if (session[s].ppp.phase != Authenticate) { LOG(2, s, t, "CHAP ignored in %s phase\n", ppp_phase(session[s].ppp.phase)); return; } r = sess_local[s].radius; if (!r) { LOG(3, s, t, "Unexpected CHAP message\n"); // Some modems (Netgear DM602, possibly others) persist in using CHAP even // after ACKing our ConfigReq for PAP. if (sess_local[s].lcp_authtype == AUTHPAP && config->radius_authtypes & AUTHCHAP) { sess_local[s].lcp_authtype = AUTHCHAP; sendchap(s, t); } return; } if (p[1] != radius[r].id) { LOG(1, s, t, "Wrong CHAP response ID %d (should be %d) (%d)\n", p[1], radius[r].id, r); STAT(tunnel_rx_errors); sessionshutdown(s, "Unexpected CHAP response ID.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } if (l < 5 || p[4] != 16) { LOG(1, s, t, "Bad CHAP response length %d\n", l < 5 ? -1 : p[4]); STAT(tunnel_rx_errors); sessionshutdown(s, "Bad CHAP response length.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } l -= 5; p += 5; if (l < 16 || l - 16 >= sizeof(session[s].user)) { LOG(1, s, t, "CHAP user too long %d\n", l - 16); STAT(tunnel_rx_errors); sessionshutdown(s, "CHAP username too long.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } // Run PRE_AUTH plugins { struct param_pre_auth packet = { &tunnel[t], &session[s], NULL, NULL, PPPCHAP, 1 }; packet.password = calloc(17, 1); memcpy(packet.password, p, 16); p += 16; l -= 16; packet.username = calloc(l + 1, 1); memcpy(packet.username, p, l); run_plugins(PLUGIN_PRE_AUTH, &packet); if (!packet.continue_auth) { LOG(3, s, t, "A plugin rejected PRE_AUTH\n"); if (packet.username) free(packet.username); if (packet.password) free(packet.password); return; } strncpy(session[s].user, packet.username, sizeof(session[s].user) - 1); memcpy(radius[r].pass, packet.password, 16); free(packet.username); free(packet.password); } radius[r].chap = 1; LOG(3, s, t, "CHAP login %s\n", session[s].user); radiussend(r, RADIUSAUTH); } static void dumplcp(uint8_t *p, int l) { int x = l - 4; uint8_t *o = (p + 4); LOG_HEX(5, "PPP LCP Packet", p, l); LOG(4, 0, 0, "PPP LCP Packet type %d (%s len %d)\n", *p, ppp_code((int)*p), ntohs( ((uint16_t *) p)[1]) ); LOG(4, 0, 0, "Length: %d\n", l); if (*p != ConfigReq && *p != ConfigRej && *p != ConfigAck) return; while (x > 2) { int type = o[0]; int length = o[1]; if (length < 2) { LOG(4, 0, 0, " Option length is %d...\n", length); break; } if (type == 0) { LOG(4, 0, 0, " Option type is 0...\n"); x -= length; o += length; continue; } switch (type) { case 1: // Maximum-Receive-Unit if (length == 4) LOG(4, 0, 0, " %s %d\n", ppp_lcp_option(type), ntohs(*(uint16_t *)(o + 2))); else LOG(4, 0, 0, " %s odd length %d\n", ppp_lcp_option(type), length); break; case 2: // Async-Control-Character-Map if (length == 6) { uint32_t asyncmap = ntohl(*(uint32_t *)(o + 2)); LOG(4, 0, 0, " %s %x\n", ppp_lcp_option(type), asyncmap); } else LOG(4, 0, 0, " %s odd length %d\n", ppp_lcp_option(type), length); break; case 3: // Authentication-Protocol if (length == 4) { int proto = ntohs(*(uint16_t *)(o + 2)); LOG(4, 0, 0, " %s 0x%x (%s)\n", ppp_lcp_option(type), proto, proto == PPPPAP ? "PAP" : "UNSUPPORTED"); } else if (length == 5) { int proto = ntohs(*(uint16_t *)(o + 2)); int algo = *(o + 4); LOG(4, 0, 0, " %s 0x%x 0x%x (%s)\n", ppp_lcp_option(type), proto, algo, (proto == PPPCHAP && algo == 5) ? "CHAP MD5" : "UNSUPPORTED"); } else LOG(4, 0, 0, " %s odd length %d\n", ppp_lcp_option(type), length); break; case 4: // Quality-Protocol { uint32_t qp = ntohl(*(uint32_t *)(o + 2)); LOG(4, 0, 0, " %s %x\n", ppp_lcp_option(type), qp); } break; case 5: // Magic-Number if (length == 6) { uint32_t magicno = ntohl(*(uint32_t *)(o + 2)); LOG(4, 0, 0, " %s %x\n", ppp_lcp_option(type), magicno); } else LOG(4, 0, 0, " %s odd length %d\n", ppp_lcp_option(type), length); break; case 7: // Protocol-Field-Compression case 8: // Address-And-Control-Field-Compression LOG(4, 0, 0, " %s\n", ppp_lcp_option(type)); break; default: LOG(2, 0, 0, " Unknown PPP LCP Option type %d\n", type); break; } x -= length; o += length; } } void lcp_open(sessionidt s, tunnelidt t) { // transition to Authentication or Network phase: session[s].ppp.phase = sess_local[s].lcp_authtype ? Authenticate : Network; LOG(3, s, t, "LCP: Opened, phase %s\n", ppp_phase(session[s].ppp.phase)); // LCP now Opened change_state(s, lcp, Opened); if (session[s].ppp.phase == Authenticate) { if (sess_local[s].lcp_authtype == AUTHCHAP) sendchap(s, t); } else { if (session[s].bundle && bundle[session[s].bundle].num_of_links > 1) { sessionidt first_ses = bundle[session[s].bundle].members[0]; LOG(3, s, t, "MPPP: Skipping IPCP negotiation for session:%d, first session of bundle is:%d\n", s, first_ses); session[s].ip = session[first_ses].ip; session[s].dns1 = session[first_ses].dns1; session[s].dns2 = session[first_ses].dns2; session[s].session_timeout = session[first_ses].session_timeout; ipcp_open(s, t); } else { // This-Layer-Up sendipcp(s, t); change_state(s, ipcp, RequestSent); // move to passive state for IPv6 (if configured), CCP if (config->ipv6_prefix.s6_addr[0]) change_state(s, ipv6cp, Stopped); else change_state(s, ipv6cp, Closed); change_state(s, ccp, Stopped); } } } static void lcp_restart(sessionidt s) { session[s].ppp.phase = Establish; // This-Layer-Down change_state(s, ipcp, Dead); change_state(s, ipv6cp, Dead); change_state(s, ccp, Dead); } static uint8_t *ppp_conf_rej(sessionidt s, uint8_t *buf, size_t blen, uint16_t mtype, uint8_t **response, uint8_t *queued, uint8_t *packet, uint8_t *option) { if (!*response || **response != ConfigRej) { queued = *response = makeppp(buf, blen, packet, 2, s, session[s].tunnel, mtype, 0, 0, 0); if (!queued) return 0; *queued = ConfigRej; queued += 4; } if ((queued - buf + option[1]) > blen) { LOG(2, s, session[s].tunnel, "PPP overflow for ConfigRej (proto %u, option %u).\n", mtype, *option); return 0; } memcpy(queued, option, option[1]); return queued + option[1]; } static uint8_t *ppp_conf_nak(sessionidt s, uint8_t *buf, size_t blen, uint16_t mtype, uint8_t **response, uint8_t *queued, uint8_t *packet, uint8_t *option, uint8_t *value, size_t vlen) { int *nak_sent; switch (mtype) { case PPPLCP: nak_sent = &sess_local[s].lcp.nak_sent; break; case PPPIPCP: nak_sent = &sess_local[s].ipcp.nak_sent; break; case PPPIPV6CP: nak_sent = &sess_local[s].ipv6cp.nak_sent; break; default: return 0; // ? } if (*response && **response != ConfigNak) { if (*nak_sent < config->ppp_max_failure) // reject queued return queued; return ppp_conf_rej(s, buf, blen, mtype, response, 0, packet, option); } if (!*response) { if (*nak_sent >= config->ppp_max_failure) return ppp_conf_rej(s, buf, blen, mtype, response, 0, packet, option); queued = *response = makeppp(buf, blen, packet, 2, s, session[s].tunnel, mtype, 0, 0, 0); if (!queued) return 0; (*nak_sent)++; *queued = ConfigNak; queued += 4; } if ((queued - buf + vlen + 2) > blen) { LOG(2, s, session[s].tunnel, "PPP overflow for ConfigNak (proto %u, option %u).\n", mtype, *option); return 0; } *queued++ = *option; *queued++ = vlen + 2; memcpy(queued, value, vlen); return queued + vlen; } static void ppp_code_rej(sessionidt s, tunnelidt t, uint16_t proto, char *pname, uint8_t *p, uint16_t l, uint8_t *buf, size_t size) { uint8_t *q; int mru = session[s].mru; if (mru < MINMTU) mru = MINMTU; if (mru > size) mru = size; l += 4; if (l > mru) l = mru; q = makeppp(buf, size, 0, 0, s, t, proto, 0, 0, 0); if (!q) return; *q = CodeRej; *(q + 1) = ++sess_local[s].lcp_ident; *(uint16_t *)(q + 2) = htons(l); memcpy(q + 4, p, l - 4); LOG(2, s, t, "Unexpected %s code %s\n", pname, ppp_code(*p)); LOG(3, s, t, "%s: send %s\n", pname, ppp_code(*q)); if (config->debug > 3) dumplcp(q, l); tunnelsend(buf, l + (q - buf), t); } // Process LCP messages void processlcp(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { uint8_t b[MAXETHER]; uint8_t *q = NULL; uint16_t hl; CSTAT(processlcp); LOG_HEX(5, "LCP", p, l); if (l < 4) { LOG(1, s, t, "Short LCP %d bytes\n", l); STAT(tunnel_rx_errors); return ; } if ((hl = ntohs(*(uint16_t *) (p + 2))) > l) { LOG(1, s, t, "Length mismatch LCP %u/%u\n", hl, l); STAT(tunnel_rx_errors); return ; } l = hl; if (session[s].die) // going down... return; LOG((*p == EchoReq || *p == EchoReply) ? 4 : 3, s, t, "LCP: recv %s\n", ppp_code(*p)); if (config->debug > 3) dumplcp(p, l); if (*p == ConfigAck) { int x = l - 4; uint8_t *o = (p + 4); int authtype = 0; while (x > 2) { int type = o[0]; int length = o[1]; if (length == 0 || type == 0 || x < length) break; switch (type) { case 3: // Authentication-Protocol { int proto = ntohs(*(uint16_t *)(o + 2)); if (proto == PPPPAP) authtype = AUTHPAP; else if (proto == PPPCHAP && *(o + 4) == 5) authtype = AUTHCHAP; } break; } x -= length; o += length; } if (!session[s].ip && authtype) sess_local[s].lcp_authtype = authtype; switch (session[s].ppp.lcp) { case RequestSent: initialise_restart_count(s, lcp); change_state(s, lcp, AckReceived); break; case AckReceived: case Opened: LOG(2, s, t, "LCP: ConfigAck in state %s? Sending ConfigReq\n", ppp_state(session[s].ppp.lcp)); if (session[s].ppp.lcp == Opened) lcp_restart(s); sendlcp(s, t); change_state(s, lcp, RequestSent); break; case AckSent: lcp_open(s, t); break; default: LOG(2, s, t, "LCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.lcp)); } } else if (*p == ConfigReq) { int x = l - 4; uint8_t *o = (p + 4); uint8_t *response = 0; static uint8_t asyncmap[4] = { 0, 0, 0, 0 }; // all zero static uint8_t authproto[5]; int changed = 0; while (x > 2) { int type = o[0]; int length = o[1]; if (length == 0 || type == 0 || x < length) break; switch (type) { case 1: // Maximum-Receive-Unit { uint16_t mru = ntohs(*(uint16_t *)(o + 2)); if (mru >= MINMTU) { session[s].mru = mru; changed++; break; } LOG(3, s, t, " Remote requesting MRU of %u. Rejecting.\n", mru); mru = htons(MRU); q = ppp_conf_nak(s, b, sizeof(b), PPPLCP, &response, q, p, o, (uint8_t *) &mru, sizeof(mru)); } break; case 2: // Async-Control-Character-Map if (!ntohl(*(uint32_t *)(o + 2))) // all bits zero is OK break; LOG(3, s, t, " Remote requesting asyncmap. Rejecting.\n"); q = ppp_conf_nak(s, b, sizeof(b), PPPLCP, &response, q, p, o, asyncmap, sizeof(asyncmap)); break; case 3: // Authentication-Protocol { int proto = ntohs(*(uint16_t *)(o + 2)); char proto_name[] = "0x0000"; int alen; if (proto == PPPPAP) { if (config->radius_authtypes & AUTHPAP) { sess_local[s].lcp_authtype = AUTHPAP; break; } strcpy(proto_name, "PAP"); } else if (proto == PPPCHAP) { if (config->radius_authtypes & AUTHCHAP && *(o + 4) == 5) // MD5 { sess_local[s].lcp_authtype = AUTHCHAP; break; } strcpy(proto_name, "CHAP"); } else sprintf(proto_name, "%#4.4x", proto); LOG(3, s, t, " Remote requesting %s authentication. Rejecting.\n", proto_name); alen = add_lcp_auth(authproto, sizeof(authproto), config->radius_authprefer); if (alen < 2) break; // paranoia q = ppp_conf_nak(s, b, sizeof(b), PPPLCP, &response, q, p, o, authproto + 2, alen - 2); if (q && *response == ConfigNak && config->radius_authtypes != config->radius_authprefer) { // alternate type alen = add_lcp_auth(authproto, sizeof(authproto), config->radius_authtypes & ~config->radius_authprefer); if (alen < 2) break; q = ppp_conf_nak(s, b, sizeof(b), PPPLCP, &response, q, p, o, authproto + 2, alen - 2); } break; } break; case 4: // Quality-Protocol case 5: // Magic-Number case 7: // Protocol-Field-Compression case 8: // Address-And-Control-Field-Compression break; case 17: // Multilink Max-Receive-Reconstructed-Unit { uint16_t mrru = ntohs(*(uint16_t *)(o + 2)); session[s].mrru = mrru; changed++; LOG(3, s, t, " Received PPP LCP option MRRU: %d\n",mrru); } break; case 18: // Multilink Short Sequence Number Header Format { session[s].mssf = 1; changed++; LOG(3, s, t, " Received PPP LCP option MSSN format\n"); } break; case 19: // Multilink Endpoint Discriminator { uint8_t epdis_class = o[2]; int addr; session[s].epdis.addr_class = epdis_class; session[s].epdis.length = length - 3; if (session[s].epdis.length > 20) { LOG(1, s, t, "Error: received EndDis Address Length more than 20: %d\n", session[s].epdis.length); session[s].epdis.length = 20; } for (addr = 0; addr < session[s].epdis.length; addr++) session[s].epdis.address[addr] = o[3+addr]; changed++; switch (epdis_class) { case LOCALADDR: LOG(3, s, t, " Received PPP LCP option Multilink EndDis Local Address Class: %d\n",epdis_class); break; case IPADDR: LOG(3, s, t, " Received PPP LCP option Multilink EndDis IP Address Class: %d\n",epdis_class); break; case IEEEMACADDR: LOG(3, s, t, " Received PPP LCP option Multilink EndDis IEEE MAC Address Class: %d\n",epdis_class); break; case PPPMAGIC: LOG(3, s, t, " Received PPP LCP option Multilink EndDis PPP Magic No Class: %d\n",epdis_class); break; case PSNDN: LOG(3, s, t, " Received PPP LCP option Multilink EndDis PSND No Class: %d\n",epdis_class); break; default: LOG(3, s, t, " Received PPP LCP option Multilink EndDis NULL Class %d\n",epdis_class); } } break; default: // Reject any unknown options LOG(3, s, t, " Rejecting unknown PPP LCP option %d\n", type); q = ppp_conf_rej(s, b, sizeof(b), PPPLCP, &response, q, p, o); } x -= length; o += length; } if (changed) cluster_send_session(s); if (response) { l = q - response; // LCP packet length *((uint16_t *) (response + 2)) = htons(l); // update header } else { // Send packet back as ConfigAck response = makeppp(b, sizeof(b), p, l, s, t, PPPLCP, 0, 0, 0); if (!response) return; *response = ConfigAck; } switch (session[s].ppp.lcp) { case Closed: response = makeppp(b, sizeof(b), p, 2, s, t, PPPLCP, 0, 0, 0); if (!response) return; *response = TerminateAck; *((uint16_t *) (response + 2)) = htons(l = 4); break; case Stopped: initialise_restart_count(s, lcp); sendlcp(s, t); if (*response == ConfigAck) change_state(s, lcp, AckSent); else change_state(s, lcp, RequestSent); break; case RequestSent: if (*response == ConfigAck) change_state(s, lcp, AckSent); break; case AckReceived: if (*response == ConfigAck) lcp_open(s, t); break; case Opened: lcp_restart(s); sendlcp(s, t); /* fallthrough */ case AckSent: if (*response == ConfigAck) change_state(s, lcp, AckSent); else change_state(s, lcp, RequestSent); break; default: LOG(2, s, t, "LCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.lcp)); return; } LOG(3, s, t, "LCP: send %s\n", ppp_code(*response)); if (config->debug > 3) dumplcp(response, l); tunnelsend(b, l + (response - b), t); } else if (*p == ConfigNak || *p == ConfigRej) { int x = l - 4; uint8_t *o = (p + 4); int authtype = -1; while (x > 2) { int type = o[0]; int length = o[1]; if (length == 0 || type == 0 || x < length) break; switch (type) { case 1: // Maximum-Receive-Unit if (*p == ConfigNak) { if (length < 4) break; sess_local[s].ppp_mru = ntohs(*(uint16_t *)(o + 2)); LOG(3, s, t, " Remote requested MRU of %u\n", sess_local[s].ppp_mru); } else { sess_local[s].ppp_mru = 0; LOG(3, s, t, " Remote rejected MRU negotiation\n"); } break; case 3: // Authentication-Protocol if (authtype > 0) break; if (*p == ConfigNak) { int proto; if (length < 4) break; proto = ntohs(*(uint16_t *)(o + 2)); if (proto == PPPPAP) { authtype = config->radius_authtypes & AUTHPAP; LOG(3, s, t, " Remote requested PAP authentication...%sing\n", authtype ? "accept" : "reject"); } else if (proto == PPPCHAP && length > 4 && *(o + 4) == 5) { authtype = config->radius_authtypes & AUTHCHAP; LOG(3, s, t, " Remote requested CHAP authentication...%sing\n", authtype ? "accept" : "reject"); } else { LOG(3, s, t, " Rejecting unsupported authentication %#4x\n", proto); } } else { LOG(2, s, t, "LCP: remote rejected auth negotiation\n"); authtype = 0; // shutdown } break; case 5: // Magic-Number session[s].magic = 0; if (*p == ConfigNak) { if (length < 6) break; session[s].magic = ntohl(*(uint32_t *)(o + 2)); } if (session[s].magic) LOG(3, s, t, " Remote requested magic-no %x\n", session[s].magic); else LOG(3, s, t, " Remote rejected magic-no\n"); cluster_send_session(s); break; case 17: // Multilink Max-Receive-Reconstructed-Unit { if (*p == ConfigNak) { sess_local[s].mp_mrru = ntohs(*(uint16_t *)(o + 2)); LOG(3, s, t, " Remote requested MRRU of %u\n", sess_local[s].mp_mrru); } else { sess_local[s].mp_mrru = 0; LOG(3, s, t, " Remote rejected MRRU negotiation\n"); } } break; case 18: // Multilink Short Sequence Number Header Format { if (*p == ConfigNak) { sess_local[s].mp_mssf = 0; LOG(3, s, t, " Remote requested Naked mssf\n"); } else { sess_local[s].mp_mssf = 0; LOG(3, s, t, " Remote rejected mssf\n"); } } break; case 19: // Multilink Endpoint Discriminator { if (*p == ConfigNak) { LOG(2, s, t, " Remote should not configNak Endpoint Dis!\n"); } else { sess_local[s].mp_epdis = 0; LOG(3, s, t, " Remote rejected Endpoint Discriminator\n"); } } break; default: LOG(2, s, t, "LCP: remote sent %s for type %u?\n", ppp_code(*p), type); sessionshutdown(s, "Unable to negotiate LCP.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } x -= length; o += length; } if (!authtype) { sessionshutdown(s, "Unsupported authentication.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } if (authtype > 0) sess_local[s].lcp_authtype = authtype; switch (session[s].ppp.lcp) { case Closed: case Stopped: { uint8_t *response = makeppp(b, sizeof(b), p, 2, s, t, PPPLCP, 0, 0, 0); if (!response) return; *response = TerminateAck; *((uint16_t *) (response + 2)) = htons(l = 4); LOG(3, s, t, "LCP: send %s\n", ppp_code(*response)); if (config->debug > 3) dumplcp(response, l); tunnelsend(b, l + (response - b), t); } break; case RequestSent: case AckSent: initialise_restart_count(s, lcp); sendlcp(s, t); break; case AckReceived: LOG(2, s, t, "LCP: ConfigNak in state %s? Sending ConfigReq\n", ppp_state(session[s].ppp.lcp)); sendlcp(s, t); break; case Opened: lcp_restart(s); sendlcp(s, t); break; default: LOG(2, s, t, "LCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.lcp)); return; } } else if (*p == TerminateReq) { switch (session[s].ppp.lcp) { case Closed: case Stopped: case Closing: case Stopping: case RequestSent: case AckReceived: case AckSent: break; case Opened: lcp_restart(s); zero_restart_count(s, lcp); change_state(s, lcp, Closing); break; default: LOG(2, s, t, "LCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.lcp)); return; } *p = TerminateAck; // send ack q = makeppp(b, sizeof(b), p, l, s, t, PPPLCP, 0, 0, 0); if (!q) return; LOG(3, s, t, "LCP: send %s\n", ppp_code(*q)); if (config->debug > 3) dumplcp(q, l); tunnelsend(b, l + (q - b), t); // send it } else if (*p == ProtocolRej) { uint16_t proto = 0; if (l > 4) { proto = *(p+4); if (l > 5 && !(proto & 1)) { proto <<= 8; proto |= *(p+5); } } if (proto == PPPIPV6CP) { LOG(3, s, t, "IPv6 rejected\n"); change_state(s, ipv6cp, Closed); } else { LOG(3, s, t, "LCP protocol reject: 0x%04X\n", proto); } } else if (*p == EchoReq) { *p = EchoReply; // reply *(uint32_t *) (p + 4) = htonl(session[s].magic); // our magic number q = makeppp(b, sizeof(b), p, l, s, t, PPPLCP, 0, 0, 0); if (!q) return; LOG(4, s, t, "LCP: send %s\n", ppp_code(*q)); if (config->debug > 3) dumplcp(q, l); tunnelsend(b, l + (q - b), t); // send it } else if (*p == EchoReply) { // Ignore it, last_packet time is set earlier than this. } else if (*p != CodeRej) { ppp_code_rej(s, t, PPPLCP, "LCP", p, l, b, sizeof(b)); } } int join_bundle(sessionidt s) { // Search for a bundle to join bundleidt i; bundleidt b; for (i = 1; i < MAXBUNDLE; i++) { if (bundle[i].state != BUNDLEFREE) { if (epdiscmp(session[s].epdis,bundle[i].epdis) && !strcmp(session[s].user, bundle[i].user)) { session[s].bundle = i; bundle[i].mrru = session[s].mrru; bundle[i].mssf = session[s].mssf; if (session[s].epdis.length > 0) setepdis(&bundle[i].epdis, session[s].epdis); strcpy(bundle[i].user, session[s].user); bundle[i].members[bundle[i].num_of_links] = s; bundle[i].num_of_links++; LOG(3, s, session[s].tunnel, "MPPP: Bundling additional line in bundle (%d), lines:%d\n",i,bundle[i].num_of_links); return i; } } } // No previously created bundle was found for this session, so create a new one if (!(b = new_bundle())) return 0; session[s].bundle = b; bundle[b].mrru = session[s].mrru; bundle[b].mssf = session[s].mssf; if (session[s].epdis.length > 0) setepdis(&bundle[b].epdis, session[s].epdis); strcpy(bundle[b].user, session[s].user); bundle[b].members[0] = s; LOG(3, s, session[s].tunnel, "MPPP: Created a new bundle (%d)\n", b); return b; } static int epdiscmp(epdist ep1, epdist ep2) { int ad; if (ep1.length != ep2.length) return 0; if (ep1.addr_class != ep2.addr_class) return 0; for (ad = 0; ad < ep1.length; ad++) if (ep1.address[ad] != ep2.address[ad]) return 0; return 1; } static void setepdis(epdist *ep1, epdist ep2) { int ad; ep1->length = ep2.length; ep1->addr_class = ep2.addr_class; for (ad = 0; ad < ep2.length; ad++) ep1->address[ad] = ep2.address[ad]; } static bundleidt new_bundle() { bundleidt i; for (i = 1; i < MAXBUNDLE; i++) { if (bundle[i].state == BUNDLEFREE) { LOG(4, 0, 0, "MPPP: Assigning bundle ID %d\n", i); bundle[i].num_of_links = 1; bundle[i].last_check = time_now; // Initialize last_check value bundle[i].state = BUNDLEOPEN; bundle[i].current_ses = -1; // This is to enforce the first session 0 to be used at first if (i > config->cluster_highest_bundleid) config->cluster_highest_bundleid = i; return i; } } LOG(0, 0, 0, "MPPP: Can't find a free bundle! There shouldn't be this many in use!\n"); return 0; } static void ipcp_open(sessionidt s, tunnelidt t) { LOG(3, s, t, "IPCP: Opened, session is now active\n"); change_state(s, ipcp, Opened); if (!(session[s].walled_garden || session[s].flags & SESSION_STARTED)) { uint16_t r = radiusnew(s); if (r) { radiussend(r, RADIUSSTART); // send radius start // don't send further Start records if IPCP is restarted session[s].flags |= SESSION_STARTED; cluster_send_session(s); } } // start IPv6 if configured and still in passive state if (session[s].ppp.ipv6cp == Stopped) { sendipv6cp(s, t); change_state(s, ipv6cp, RequestSent); } } // Process IPCP messages void processipcp(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { uint8_t b[MAXETHER]; uint8_t *q = 0; uint16_t hl; CSTAT(processipcp); LOG_HEX(5, "IPCP", p, l); if (l < 4) { LOG(1, s, t, "Short IPCP %d bytes\n", l); STAT(tunnel_rx_errors); return ; } if ((hl = ntohs(*(uint16_t *) (p + 2))) > l) { LOG(1, s, t, "Length mismatch IPCP %u/%u\n", hl, l); STAT(tunnel_rx_errors); return ; } l = hl; if (session[s].ppp.phase < Network) { LOG(2, s, t, "IPCP %s ignored in %s phase\n", ppp_code(*p), ppp_phase(session[s].ppp.phase)); return; } LOG(3, s, t, "IPCP: recv %s\n", ppp_code(*p)); if (*p == ConfigAck) { switch (session[s].ppp.ipcp) { case RequestSent: initialise_restart_count(s, ipcp); change_state(s, ipcp, AckReceived); break; case AckReceived: case Opened: LOG(2, s, t, "IPCP: ConfigAck in state %s? Sending ConfigReq\n", ppp_state(session[s].ppp.ipcp)); sendipcp(s, t); change_state(s, ipcp, RequestSent); break; case AckSent: ipcp_open(s, t); break; default: LOG(2, s, t, "IPCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ipcp)); } } else if (*p == ConfigReq) { uint8_t *response = 0; uint8_t *o = p + 4; int length = l - 4; int gotip = 0; in_addr_t addr; while (length > 2) { if (!o[1] || o[1] > length) return; switch (*o) { case 3: // ip address gotip++; // seen address if (o[1] != 6) return; addr = htonl(session[s].ip); if (memcmp(o + 2, &addr, (sizeof addr))) { uint8_t *oq = q; q = ppp_conf_nak(s, b, sizeof(b), PPPIPCP, &response, q, p, o, (uint8_t *) &addr, sizeof(addr)); if (!q || (q != oq && *response == ConfigRej)) { sessionshutdown(s, "Can't negotiate IPCP.", CDN_ADMIN_DISC, TERM_USER_ERROR); return; } } break; case 129: // primary DNS if (o[1] != 6) return; addr = htonl(session[s].dns1); if (memcmp(o + 2, &addr, (sizeof addr))) { q = ppp_conf_nak(s, b, sizeof(b), PPPIPCP, &response, q, p, o, (uint8_t *) &addr, sizeof(addr)); if (!q) return; } break; case 131: // secondary DNS if (o[1] != 6) return; addr = htonl(session[s].dns2); if (memcmp(o + 2, &addr, sizeof(addr))) { q = ppp_conf_nak(s, b, sizeof(b), PPPIPCP, &response, q, p, o, (uint8_t *) &addr, sizeof(addr)); if (!q) return; } break; default: LOG(2, s, t, " Rejecting PPP IPCP Option type %d\n", *o); q = ppp_conf_rej(s, b, sizeof(b), PPPIPCP, &response, q, p, o); if (!q) return; } length -= o[1]; o += o[1]; } if (response) { l = q - response; // IPCP packet length *((uint16_t *) (response + 2)) = htons(l); // update header } else if (gotip) { // Send packet back as ConfigAck response = makeppp(b, sizeof(b), p, l, s, t, PPPIPCP, 0, 0, 0); if (!response) return; *response = ConfigAck; } else { LOG(1, s, t, "No IP in IPCP request\n"); STAT(tunnel_rx_errors); return; } switch (session[s].ppp.ipcp) { case Closed: response = makeppp(b, sizeof(b), p, 2, s, t, PPPIPCP, 0, 0, 0); if (!response) return; *response = TerminateAck; *((uint16_t *) (response + 2)) = htons(l = 4); break; case Stopped: initialise_restart_count(s, ipcp); sendipcp(s, t); if (*response == ConfigAck) change_state(s, ipcp, AckSent); else change_state(s, ipcp, RequestSent); break; case RequestSent: if (*response == ConfigAck) change_state(s, ipcp, AckSent); break; case AckReceived: if (*response == ConfigAck) ipcp_open(s, t); break; case Opened: initialise_restart_count(s, ipcp); sendipcp(s, t); /* fallthrough */ case AckSent: if (*response == ConfigAck) change_state(s, ipcp, AckSent); else change_state(s, ipcp, RequestSent); break; default: LOG(2, s, t, "IPCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ipcp)); return; } LOG(3, s, t, "IPCP: send %s\n", ppp_code(*response)); tunnelsend(b, l + (response - b), t); } else if (*p == TerminateReq) { switch (session[s].ppp.ipcp) { case Closed: case Stopped: case Closing: case Stopping: case RequestSent: case AckReceived: case AckSent: break; case Opened: zero_restart_count(s, ipcp); change_state(s, ipcp, Closing); break; default: LOG(2, s, t, "IPCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ipcp)); return; } *p = TerminateAck; // send ack q = makeppp(b, sizeof(b), p, l, s, t, PPPIPCP, 0, 0, 0); if (!q) return; LOG(3, s, t, "IPCP: send %s\n", ppp_code(*q)); tunnelsend(b, l + (q - b), t); // send it } else if (*p != CodeRej) { ppp_code_rej(s, t, PPPIPCP, "IPCP", p, l, b, sizeof(b)); } } static void ipv6cp_open(sessionidt s, tunnelidt t) { LOG(3, s, t, "IPV6CP: Opened\n"); change_state(s, ipv6cp, Opened); if (session[s].ipv6prefixlen) route6set(s, session[s].ipv6route, session[s].ipv6prefixlen, 1); // Send an initial RA (TODO: Should we send these regularly?) send_ipv6_ra(s, t, NULL); } // Process IPV6CP messages void processipv6cp(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { uint8_t b[MAXETHER]; uint8_t *q = 0; uint16_t hl; CSTAT(processipv6cp); LOG_HEX(5, "IPV6CP", p, l); if (l < 4) { LOG(1, s, t, "Short IPV6CP %d bytes\n", l); STAT(tunnel_rx_errors); return ; } if ((hl = ntohs(*(uint16_t *) (p + 2))) > l) { LOG(1, s, t, "Length mismatch IPV6CP %u/%u\n", hl, l); STAT(tunnel_rx_errors); return ; } l = hl; if (session[s].ppp.phase < Network) { LOG(2, s, t, "IPV6CP %s ignored in %s phase\n", ppp_code(*p), ppp_phase(session[s].ppp.phase)); return; } LOG(3, s, t, "IPV6CP: recv %s\n", ppp_code(*p)); if (!session[s].ip) { LOG(3, s, t, "IPV6CP: no IPv4 address (IPCP in state %s)\n", ppp_state(session[s].ppp.ipcp)); return; // need IPCP to complete... } if (*p == ConfigAck) { switch (session[s].ppp.ipv6cp) { case RequestSent: initialise_restart_count(s, ipv6cp); change_state(s, ipv6cp, AckReceived); break; case AckReceived: case Opened: LOG(2, s, t, "IPV6CP: ConfigAck in state %s? Sending ConfigReq\n", ppp_state(session[s].ppp.ipv6cp)); sendipv6cp(s, t); change_state(s, ipv6cp, RequestSent); break; case AckSent: ipv6cp_open(s, t); break; default: LOG(2, s, t, "IPV6CP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ipv6cp)); } } else if (*p == ConfigReq) { uint8_t *response = 0; uint8_t *o = p + 4; int length = l - 4; int gotip = 0; uint8_t ident[8]; while (length > 2) { if (!o[1] || o[1] > length) return; switch (*o) { case 1: // interface identifier gotip++; // seen address if (o[1] != 10) return; *(uint32_t *) ident = htonl(session[s].ip); *(uint32_t *) (ident + 4) = 0; if (memcmp(o + 2, ident, sizeof(ident))) { q = ppp_conf_nak(s, b, sizeof(b), PPPIPV6CP, &response, q, p, o, ident, sizeof(ident)); if (!q) return; } break; default: LOG(2, s, t, " Rejecting PPP IPV6CP Option type %d\n", *o); q = ppp_conf_rej(s, b, sizeof(b), PPPIPV6CP, &response, q, p, o); if (!q) return; } length -= o[1]; o += o[1]; } if (response) { l = q - response; // IPV6CP packet length *((uint16_t *) (response + 2)) = htons(l); // update header } else if (gotip) { // Send packet back as ConfigAck response = makeppp(b, sizeof(b), p, l, s, t, PPPIPV6CP, 0, 0, 0); if (!response) return; *response = ConfigAck; } else { LOG(1, s, t, "No interface identifier in IPV6CP request\n"); STAT(tunnel_rx_errors); return; } switch (session[s].ppp.ipv6cp) { case Closed: response = makeppp(b, sizeof(b), p, 2, s, t, PPPIPV6CP, 0, 0, 0); if (!response) return; *response = TerminateAck; *((uint16_t *) (response + 2)) = htons(l = 4); break; case Stopped: initialise_restart_count(s, ipv6cp); sendipv6cp(s, t); if (*response == ConfigAck) change_state(s, ipv6cp, AckSent); else change_state(s, ipv6cp, RequestSent); break; case RequestSent: if (*response == ConfigAck) change_state(s, ipv6cp, AckSent); break; case AckReceived: if (*response == ConfigAck) ipv6cp_open(s, t); break; case Opened: initialise_restart_count(s, ipv6cp); sendipv6cp(s, t); /* fallthrough */ case AckSent: if (*response == ConfigAck) change_state(s, ipv6cp, AckSent); else change_state(s, ipv6cp, RequestSent); break; default: LOG(2, s, t, "IPV6CP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ipv6cp)); return; } LOG(3, s, t, "IPV6CP: send %s\n", ppp_code(*response)); tunnelsend(b, l + (response - b), t); } else if (*p == TerminateReq) { switch (session[s].ppp.ipv6cp) { case Closed: case Stopped: case Closing: case Stopping: case RequestSent: case AckReceived: case AckSent: break; case Opened: zero_restart_count(s, ipv6cp); change_state(s, ipv6cp, Closing); break; default: LOG(2, s, t, "IPV6CP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ipv6cp)); return; } *p = TerminateAck; // send ack q = makeppp(b, sizeof(b), p, l, s, t, PPPIPV6CP, 0, 0, 0); if (!q) return; LOG(3, s, t, "IPV6CP: send %s\n", ppp_code(*q)); tunnelsend(b, l + (q - b), t); // send it } else if (*p != CodeRej) { ppp_code_rej(s, t, PPPIPV6CP, "IPV6CP", p, l, b, sizeof(b)); } } // process IP packet received // // This MUST be called with at least 4 byte behind 'p'. // (i.e. this routine writes to p[-4]). void processipin(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { in_addr_t ip; CSTAT(processipin); LOG_HEX(5, "IP", p, l); if (l < 20) { LOG(1, s, t, "IP packet too short %d\n", l); STAT(tunnel_rx_errors); return ; } ip = ntohl(*(uint32_t *)(p + 12)); if (l > MAXETHER) { LOG(1, s, t, "IP packet too long %d\n", l); STAT(tunnel_rx_errors); return ; } if (session[s].ppp.phase != Network || session[s].ppp.ipcp != Opened) return; if (!session[s].bundle || bundle[session[s].bundle].num_of_links < 2) // FIXME: { // no spoof (do sessionbyip to handled statically routed subnets) if (ip != session[s].ip && sessionbyip(htonl(ip)) != s) { LOG(4, s, t, "Dropping packet with spoofed IP %s\n", fmtaddr(htonl(ip), 0)); return; } } // run access-list if any if (session[s].filter_in && !ip_filter(p, l, session[s].filter_in - 1)) return; // adjust MSS on SYN and SYN,ACK packets with options if ((ntohs(*(uint16_t *) (p + 6)) & 0x1fff) == 0 && p[9] == IPPROTO_TCP) // first tcp fragment { int ihl = (p[0] & 0xf) * 4; // length of IP header if (l >= ihl + 20 && (p[ihl + 13] & TCP_FLAG_SYN) && ((p[ihl + 12] >> 4) > 5)) adjust_tcp_mss(s, t, p, l, p + ihl); } // Add on the tun header p -= 4; *(uint32_t *) p = htonl(PKTIP); l += 4; if (session[s].tbf_in) { // Are we throttling this session? if (config->cluster_iam_master) tbf_queue_packet(session[s].tbf_in, p, l); else master_throttle_packet(session[s].tbf_in, p, l); return; } // send to ethernet if (tun_write(p, l) < 0) { STAT(tun_tx_errors); LOG(0, s, t, "Error writing %d bytes to TUN device: %s (tunfd=%d, p=%p)\n", l, strerror(errno), tunfd, p); return; } p += 4; l -= 4; if (session[s].snoop_ip && session[s].snoop_port) { // Snooping this session snoop_send_packet(p, l, session[s].snoop_ip, session[s].snoop_port); } increment_counter(&session[s].cin, &session[s].cin_wrap, l); session[s].cin_delta += l; session[s].pin++; sess_local[s].cin += l; sess_local[s].pin++; eth_tx += l; STAT(tun_tx_packets); INC_STAT(tun_tx_bytes, l); } // process Multilink PPP packet received void processmpin(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { bundleidt b = session[s].bundle; uint8_t begin_frame; uint8_t end_frame; uint32_t seq_num; uint32_t offset; if (!b) { LOG(3, s, t, "MPPP: Invalid bundle id: 0\n"); return; } begin_frame = (*p & 0x80); end_frame = (*p & 0x40); if (session[s].mssf) { // Get 12 bit for seq number uint16_t short_seq_num = ntohs((*(uint16_t *) p) & 0xFF0F); uint16_t short_seq_num2 = short_seq_num >> 4; p += 2; l -= 2; seq_num = short_seq_num2; // After this point the pointer should be advanced 2 bytes LOG(3, s, t, "MPPP: 12 bits, sequence number: %d, short1: %d, short2: %d\n",seq_num, short_seq_num, short_seq_num2); } else { // Get 24 bit for seq number p++; seq_num = ntohl((*(uint32_t *) p) & 0xFFFFFF00); seq_num = seq_num >> 8; p += 3; l -= 4; // After this point the pointer should be advanced 4 bytes LOG(4, s, t, "MPPP: 24 bits sequence number:%d\n",seq_num); } if (seq_num - bundle[b].offset < 0) { bundle[b].offset = 0; bundle[b].pending_frag = 0; } offset = bundle[b].offset; if (begin_frame) { // Check for previous non-assembled frames int error = 0; if (bundle[b].pending_frag) { uint32_t fn = bundle[b].seq_num_m - offset; uint16_t cur_len; bundle[b].pending_frag = 0; // Check for array indexes if (fn < 0 || fn > MAXFRAGNUM) { LOG(2, s, t, "ERROR: Index out of range fn:%d, bundle:%d\n",fn,b); return; } if (seq_num-offset < 0 || seq_num-offset > MAXFRAGNUM) { LOG(2, s, t, "ERROR: Index out of range fn(last):%d, bundle:%d\n",fn,b); return; } ///////////////////////////////////////////////////// cur_len = 4; // This is set to 4 to leave 4 bytes for function processipin for (fn = bundle[b].seq_num_m - offset; fn < seq_num - offset; fn++) { if (!frag[b].fragment[fn].length) { LOG(4, s, t, "MPPP: Found lost fragment while reassembling frame %d in (%d,%d)\n",fn, bundle[b].seq_num_m-offset, seq_num-offset); error = 1; break; } if (cur_len + frag[b].fragment[fn].length > MAXETHER) { LOG(2, s, t, "MPPP: ERROR: very long frame after assembling %d\n", frag[b].fragment[fn].length+cur_len); error = 1; break; } memcpy(frag[b].reassembled_frame+cur_len, frag[b].fragment[fn].data, frag[b].fragment[fn].length); cur_len += frag[b].fragment[fn].length; frag[b].fragment[fn].length = 0; // Indicates that this fragment has been consumed // This is usefull for compression memset(frag[b].fragment[fn].data, 0, sizeof(frag[b].fragment[fn].data)); } if (!error) { frag[b].re_frame_len = cur_len; // Process the resassembled frame LOG(4, s, t, "MPPP: Process the reassembled frame, len=%d\n",cur_len); processmpframe(s, t, frag[b].reassembled_frame, frag[b].re_frame_len, 1); // Set reassembled frame length to zero after processing it frag[b].re_frame_len = 0; memset(frag[b].reassembled_frame, 0, sizeof(frag[b].reassembled_frame)); } } ////////////////////////////////////////// bundle[b].seq_num_m = seq_num; if (end_frame) { // Both bits are set LOG(4, s, t, "MPPP: Both bits are set (Begin and End).\n"); processmpframe(s, t, p, l, 0); // The maximum number of fragments is 1500 if (seq_num - bundle[b].offset >= 1400) { bundle[b].offset = seq_num; LOG(4, s, t, "MPPP: Setting offset to: %d\n",bundle[b].offset); } } else { bundle[b].pending_frag = 1; // End bit is clear LOG(4, s, t, "MPPP: Push to receive buffer\n"); // Push to the receive buffer // Array indexes checking if (seq_num-offset < 0 || seq_num-offset >= MAXFRAGNUM) { LOG(2, s, t, "ERROR: Index out of range, push to receive buffer(1) seq:%d, offset:%d, bundle:%d\n",seq_num,offset,b); return; } // Perform length checking if (l > MAXFRAGLEN) { LOG(2, s, t, "MPPP: ERROR: very long fragment length (1)\n"); return; } frag[b].fragment[seq_num - offset].length = l; memcpy(frag[b].fragment[seq_num - offset].data, p, l); } } else { LOG(4, s, t, "MPPP: Push to receive buffer\n"); // Push to the receive buffer // Array indexes checking if (seq_num-offset < 0 || seq_num-offset >= MAXFRAGNUM) { LOG(2, s, t, "ERROR: Index out of range, push to receive buffer(2) seq:%d, offset:%d, bundle:%d\n",seq_num,offset,b); return; } // Perform length checking if (l > MAXFRAGLEN) { LOG(2, s, t, "MPPP: ERROR: very long fragment length (2).\n"); return; } frag[b].fragment[seq_num - offset].length = l; memcpy(frag[b].fragment[seq_num - offset].data, p, l); } } // process IPv6 packet received // // This MUST be called with at least 4 byte behind 'p'. // (i.e. this routine writes to p[-4]). void processipv6in(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { struct in6_addr ip; in_addr_t ipv4; CSTAT(processipv6in); LOG_HEX(5, "IPv6", p, l); ip = *(struct in6_addr *) (p + 8); ipv4 = ntohl(*(uint32_t *)(p + 16)); if (l > MAXETHER) { LOG(1, s, t, "IP packet too long %d\n", l); STAT(tunnel_rx_errors); return ; } if (session[s].ppp.phase != Network || session[s].ppp.ipv6cp != Opened) return; // no spoof if (ipv4 != session[s].ip && memcmp(&config->ipv6_prefix, &ip, 8) && sessionbyipv6(ip) != s) { char str[INET6_ADDRSTRLEN]; LOG(5, s, t, "Dropping packet with spoofed IP %s\n", inet_ntop(AF_INET6, &ip, str, INET6_ADDRSTRLEN)); return; } // Check if it's a Router Solicition message. if (*(p + 6) == 58 && *(p + 7) == 255 && *(p + 24) == 0xFF && *(p + 25) == 2 && *(uint32_t *)(p + 26) == 0 && *(uint32_t *)(p + 30) == 0 && *(uint32_t *)(p + 34) == 0 && *(p + 38) == 0 && *(p + 39) == 2 && *(p + 40) == 133) { LOG(3, s, t, "Got IPv6 RS\n"); send_ipv6_ra(s, t, &ip); return; } // Add on the tun header p -= 4; *(uint32_t *) p = htonl(PKTIPV6); l += 4; // Are we throttled and a slave? if (session[s].tbf_in && !config->cluster_iam_master) { // Pass it to the master for handling. master_throttle_packet(session[s].tbf_in, p, l); return; } // Are we throttled and a master?? if (session[s].tbf_in && config->cluster_iam_master) { // Actually handle the throttled packets. tbf_queue_packet(session[s].tbf_in, p, l); return; } // send to ethernet if (tun_write(p, l) < 0) { STAT(tun_tx_errors); LOG(0, s, t, "Error writing %d bytes to TUN device: %s (tunfd=%d, p=%p)\n", l, strerror(errno), tunfd, p); return; } p += 4; l -= 4; if (session[s].snoop_ip && session[s].snoop_port) { // Snooping this session snoop_send_packet(p, l, session[s].snoop_ip, session[s].snoop_port); } increment_counter(&session[s].cin, &session[s].cin_wrap, l); session[s].cin_delta += l; session[s].pin++; sess_local[s].cin += l; sess_local[s].pin++; eth_tx += l; STAT(tun_tx_packets); INC_STAT(tun_tx_bytes, l); } // // Helper routine for the TBF filters. // Used to send queued data in from the user. // void send_ipin(sessionidt s, uint8_t *buf, int len) { LOG_HEX(5, "IP in throttled", buf, len); if (write(tunfd, buf, len) < 0) { STAT(tun_tx_errors); LOG(0, 0, 0, "Error writing %d bytes to TUN device: %s (tunfd=%d, p=%p)\n", len, strerror(errno), tunfd, buf); return; } buf += 4; len -= 4; if (session[s].snoop_ip && session[s].snoop_port) { // Snooping this session snoop_send_packet(buf, len, session[s].snoop_ip, session[s].snoop_port); } // Increment packet counters increment_counter(&session[s].cin, &session[s].cin_wrap, len); session[s].cin_delta += len; session[s].pin++; sess_local[s].cin += len; sess_local[s].pin++; eth_tx += len; STAT(tun_tx_packets); INC_STAT(tun_tx_bytes, len - 4); } // Process CCP messages void processccp(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l) { uint8_t b[MAXETHER]; uint8_t *q; CSTAT(processccp); LOG_HEX(5, "CCP", p, l); if (session[s].ppp.phase < Network) { LOG(2, s, t, "CCP %s ignored in %s phase\n", ppp_code(*p), ppp_phase(session[s].ppp.phase)); return; } if (l < 1) { LOG(1, s, t, "Short CCP packet\n"); STAT(tunnel_rx_errors); } LOG(4, s, t, "CCP: recv %s\n", ppp_code(*p)); if (*p == ConfigAck) { switch (session[s].ppp.ccp) { case RequestSent: initialise_restart_count(s, ccp); change_state(s, ccp, AckReceived); break; case AckReceived: case Opened: LOG(2, s, t, "CCP: ConfigAck in state %s? Sending ConfigReq\n", ppp_state(session[s].ppp.ccp)); sendccp(s, t); change_state(s, ccp, RequestSent); break; case AckSent: LOG(3, s, t, "CCP: Opened\n"); change_state(s, ccp, Opened); break; default: LOG(2, s, t, "CCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ccp)); } } else if (*p == ConfigReq) { if (l < 6) // accept no compression *p = ConfigAck; else // compression requested--reject *p = ConfigRej; q = makeppp(b, sizeof(b), p, l, s, t, PPPCCP, 0, 0, 0); if (!q) return; switch (session[s].ppp.ccp) { case Closed: q = makeppp(b, sizeof(b), p, 2, s, t, PPPCCP, 0, 0, 0); if (!q) return; *q = TerminateAck; *((uint16_t *) (q + 2)) = htons(l = 4); break; case Stopped: initialise_restart_count(s, ccp); sendccp(s, t); if (*q == ConfigAck) change_state(s, ccp, AckSent); else change_state(s, ccp, RequestSent); break; case RequestSent: if (*q == ConfigAck) change_state(s, ccp, AckSent); break; case AckReceived: if (*q == ConfigAck) change_state(s, ccp, Opened); break; case Opened: initialise_restart_count(s, ccp); sendccp(s, t); /* fallthrough */ case AckSent: if (*q == ConfigAck) change_state(s, ccp, AckSent); else change_state(s, ccp, RequestSent); break; default: LOG(2, s, t, "CCP: ignoring %s in state %s\n", ppp_code(*p), ppp_state(session[s].ppp.ccp)); return; } LOG(4, s, t, "CCP: send %s\n", ppp_code(*q)); tunnelsend(b, l + (q - b), t); } else if (*p == TerminateReq) { *p = TerminateAck; q = makeppp(b, sizeof(b), p, l, s, t, PPPCCP, 0, 0, 0); if (!q) return; LOG(3, s, t, "CCP: send %s\n", ppp_code(*q)); tunnelsend(b, l + (q - b), t); change_state(s, ccp, Stopped); } else if (*p != CodeRej) { ppp_code_rej(s, t, PPPCCP, "CCP", p, l, b, sizeof(b)); } } // send a CHAP challenge void sendchap(sessionidt s, tunnelidt t) { uint8_t b[MAXETHER]; uint16_t r; uint8_t *q; CSTAT(sendchap); r = radiusnew(s); if (!r) { LOG(1, s, t, "No RADIUS to send challenge\n"); STAT(tunnel_tx_errors); return; } LOG(1, s, t, "Send CHAP challenge\n"); radius[r].chap = 1; // CHAP not PAP radius[r].id++; if (radius[r].state != RADIUSCHAP) radius[r].try = 0; radius[r].state = RADIUSCHAP; radius[r].retry = backoff(radius[r].try++); if (radius[r].try > 5) { sessionshutdown(s, "CHAP timeout.", CDN_ADMIN_DISC, TERM_REAUTHENTICATION_FAILURE); STAT(tunnel_tx_errors); return ; } q = makeppp(b, sizeof(b), 0, 0, s, t, PPPCHAP, 0, 0, 0); if (!q) return; *q = 1; // challenge q[1] = radius[r].id; // ID q[4] = 16; // value size (size of challenge) memcpy(q + 5, radius[r].auth, 16); // challenge strcpy((char *) q + 21, hostname); // our name *(uint16_t *) (q + 2) = htons(strlen(hostname) + 21); // length tunnelsend(b, strlen(hostname) + 21 + (q - b), t); // send it } // fill in a L2TP message with a PPP frame, // returns start of PPP frame uint8_t *makeppp(uint8_t *b, int size, uint8_t *p, int l, sessionidt s, tunnelidt t, uint16_t mtype, uint8_t prio, bundleidt bid, uint8_t mp_bits) { uint16_t hdr = 0x0002; // L2TP with no options uint16_t type = mtype; uint8_t *start = b; if (size < 16) // Need more space than this!! { LOG(0, s, t, "makeppp buffer too small for L2TP header (size=%d)\n", size); return NULL; } if (prio) hdr |= 0x0100; // set priority bit *(uint16_t *) (b + 0) = htons(hdr); *(uint16_t *) (b + 2) = htons(tunnel[t].far); // tunnel *(uint16_t *) (b + 4) = htons(session[s].far); // session b += 6; // Check whether this session is part of multilink if (bid) { if (bundle[bid].num_of_links > 1) type = PPPMP; // Change PPP message type to the PPPMP else bid = 0; } if (type == PPPLCP || !(session[s].flags & SESSION_ACFC)) { *(uint16_t *) b = htons(0xFF03); // HDLC header b += 2; } if (type < 0x100 && session[s].flags & SESSION_PFC) { *b++ = type; } else { *(uint16_t *) b = htons(type); b += 2; } if (bid) { // Set the sequence number and (B)egin (E)nd flags if (session[s].mssf) { // Set the multilink bits uint16_t bits_send = mp_bits; *(uint16_t *) b = htons((bundle[bid].seq_num_t & 0xFF0F)|bits_send); b += 2; } else { *(uint32_t *) b = htonl(bundle[bid].seq_num_t); // Set the multilink bits *b = mp_bits; b += 4; } bundle[bid].seq_num_t++; // Add the message type if this fragment has the begin bit set if (mp_bits & MP_BEGIN) { //*b++ = mtype; // The next two lines are instead of this *(uint16_t *) b = htons(mtype); // Message type b += 2; } } if ((b - start) + l > size) { LOG(2, s, t, "makeppp would overflow buffer (size=%d, header+payload=%d)\n", size, (b - start) + l); return NULL; } // Copy the payload if (p && l) memcpy(b, p, l); return b; } static int add_lcp_auth(uint8_t *b, int size, int authtype) { int len = 0; if ((authtype == AUTHCHAP && size < 5) || size < 4) return 0; *b++ = 3; // Authentication-Protocol if (authtype == AUTHCHAP) { len = *b++ = 5; // length *(uint16_t *) b = htons(PPPCHAP); b += 2; *b++ = 5; // MD5 } else if (authtype == AUTHPAP) { len = *b++ = 4; // length *(uint16_t *) b = htons(PPPPAP); b += 2; } else { LOG(0, 0, 0, "add_lcp_auth called with unsupported auth type %d\n", authtype); } return len; } // Send LCP ConfigReq for MRU, authentication type and magic no void sendlcp(sessionidt s, tunnelidt t) { uint8_t b[500], *q, *l; int authtype = sess_local[s].lcp_authtype; if (!(q = makeppp(b, sizeof(b), NULL, 0, s, t, PPPLCP, 0, 0, 0))) return; LOG(3, s, t, "LCP: send ConfigReq%s%s%s including MP options\n", authtype ? " (" : "", authtype ? (authtype == AUTHCHAP ? "CHAP" : "PAP") : "", authtype ? ")" : ""); l = q; *l++ = ConfigReq; *l++ = ++sess_local[s].lcp_ident; // ID l += 2; //Save space for length if (sess_local[s].ppp_mru) { *l++ = 1; *l++ = 4; // Maximum-Receive-Unit (length 4) *(uint16_t *) l = htons(sess_local[s].ppp_mru); l += 2; } if (authtype) l += add_lcp_auth(l, sizeof(b) - (l - b), authtype); if (session[s].magic) { *l++ = 5; *l++ = 6; // Magic-Number (length 6) *(uint32_t *) l = htonl(session[s].magic); l += 4; } if (sess_local[s].mp_mrru) { *l++ = 17; *l++ = 4; // Multilink Max-Receive-Reconstructed-Unit (length 4) *(uint16_t *) l = htons(sess_local[s].mp_mrru); l += 2; } if (sess_local[s].mp_epdis) { *l++ = 19; *l++ = 7; // Multilink Endpoint Discriminator (length 7) *l++ = IPADDR; // Endpoint Discriminator class *(uint32_t *) l = htonl(sess_local[s].mp_epdis); l += 4; } *(uint16_t *)(q + 2) = htons(l - q); // Length LOG_HEX(5, "PPPLCP", q, l - q); if (config->debug > 3) dumplcp(q, l - q); tunnelsend(b, (l - b), t); restart_timer(s, lcp); } // Send CCP request for no compression void sendccp(sessionidt s, tunnelidt t) { uint8_t b[500], *q; if (!(q = makeppp(b, sizeof(b), NULL, 0, s, t, PPPCCP, 0, 0, 0))) return; LOG(3, s, t, "CCP: send ConfigReq (no compression)\n"); *q = ConfigReq; *(q + 1) = ++sess_local[s].lcp_ident; // ID *(uint16_t *)(q + 2) = htons(4); // Length LOG_HEX(5, "PPPCCP", q, 4); tunnelsend(b, (q - b) + 4 , t); restart_timer(s, ccp); } // Reject unknown/unconfigured protocols void protoreject(sessionidt s, tunnelidt t, uint8_t *p, uint16_t l, uint16_t proto) { uint8_t buf[MAXETHER]; uint8_t *q; int mru = session[s].mru; if (mru < MINMTU) mru = MINMTU; if (mru > sizeof(buf)) mru = sizeof(buf); l += 6; if (l > mru) l = mru; q = makeppp(buf, sizeof(buf), 0, 0, s, t, PPPLCP, 0, 0, 0); if (!q) return; *q = ProtocolRej; *(q + 1) = ++sess_local[s].lcp_ident; *(uint16_t *)(q + 2) = htons(l); *(uint16_t *)(q + 4) = htons(proto); memcpy(q + 6, p, l - 6); if (proto == PPPIPV6CP) LOG(3, s, t, "LCP: send ProtocolRej (IPV6CP: not configured)\n"); else LOG(2, s, t, "LCP: sent ProtocolRej (0x%04X: unsupported)\n", proto); tunnelsend(buf, l + (q - buf), t); }