/* * Copyright (c) 1998-2007 The TCPDUMP project * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that: (1) source code * distributions retain the above copyright notice and this paragraph * in its entirety, and (2) distributions including binary code include * the above copyright notice and this paragraph in its entirety in * the documentation or other materials provided with the distribution. * THIS SOFTWARE IS PROVIDED ``AS IS'' AND * WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, WITHOUT * LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE. * * Original code by Carles Kishimoto * * Expansion and refactoring by Rick Jones */ /* \summary: sFlow protocol printer */ /* specification: http://www.sflow.org/developers/specifications.php */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include "netdissect.h" #include "extract.h" #include "addrtoname.h" /* * sFlow datagram * * 0 1 2 3 * 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * | Sflow version (2,4,5) | * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * | IP version (1 for IPv4 | 2 for IPv6) | * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * | IP Address AGENT (4 or 16 bytes) | * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * | Sub agent ID | * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * | Datagram sequence number | * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * | Switch uptime in ms | * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * | num samples in datagram | * +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * */ struct sflow_datagram_t { uint8_t version[4]; uint8_t ip_version[4]; uint8_t agent[4]; uint8_t agent_id[4]; uint8_t seqnum[4]; uint8_t uptime[4]; uint8_t samples[4]; }; struct sflow_sample_header { uint8_t format[4]; uint8_t len[4]; }; #define SFLOW_FLOW_SAMPLE 1 #define SFLOW_COUNTER_SAMPLE 2 #define SFLOW_EXPANDED_FLOW_SAMPLE 3 #define SFLOW_EXPANDED_COUNTER_SAMPLE 4 static const struct tok sflow_format_values[] = { { SFLOW_FLOW_SAMPLE, "flow sample" }, { SFLOW_COUNTER_SAMPLE, "counter sample" }, { SFLOW_EXPANDED_FLOW_SAMPLE, "expanded flow sample" }, { SFLOW_EXPANDED_COUNTER_SAMPLE, "expanded counter sample" }, { 0, NULL} }; struct sflow_flow_sample_t { uint8_t seqnum[4]; uint8_t typesource[4]; uint8_t rate[4]; uint8_t pool[4]; uint8_t drops[4]; uint8_t in_interface[4]; uint8_t out_interface[4]; uint8_t records[4]; }; struct sflow_expanded_flow_sample_t { uint8_t seqnum[4]; uint8_t type[4]; uint8_t index[4]; uint8_t rate[4]; uint8_t pool[4]; uint8_t drops[4]; uint8_t in_interface_format[4]; uint8_t in_interface_value[4]; uint8_t out_interface_format[4]; uint8_t out_interface_value[4]; uint8_t records[4]; }; #define SFLOW_FLOW_RAW_PACKET 1 #define SFLOW_FLOW_ETHERNET_FRAME 2 #define SFLOW_FLOW_IPV4_DATA 3 #define SFLOW_FLOW_IPV6_DATA 4 #define SFLOW_FLOW_EXTENDED_SWITCH_DATA 1001 #define SFLOW_FLOW_EXTENDED_ROUTER_DATA 1002 #define SFLOW_FLOW_EXTENDED_GATEWAY_DATA 1003 #define SFLOW_FLOW_EXTENDED_USER_DATA 1004 #define SFLOW_FLOW_EXTENDED_URL_DATA 1005 #define SFLOW_FLOW_EXTENDED_MPLS_DATA 1006 #define SFLOW_FLOW_EXTENDED_NAT_DATA 1007 #define SFLOW_FLOW_EXTENDED_MPLS_TUNNEL 1008 #define SFLOW_FLOW_EXTENDED_MPLS_VC 1009 #define SFLOW_FLOW_EXTENDED_MPLS_FEC 1010 #define SFLOW_FLOW_EXTENDED_MPLS_LVP_FEC 1011 #define SFLOW_FLOW_EXTENDED_VLAN_TUNNEL 1012 static const struct tok sflow_flow_type_values[] = { { SFLOW_FLOW_RAW_PACKET, "Raw packet"}, { SFLOW_FLOW_ETHERNET_FRAME, "Ethernet frame"}, { SFLOW_FLOW_IPV4_DATA, "IPv4 Data"}, { SFLOW_FLOW_IPV6_DATA, "IPv6 Data"}, { SFLOW_FLOW_EXTENDED_SWITCH_DATA, "Extended Switch data"}, { SFLOW_FLOW_EXTENDED_ROUTER_DATA, "Extended Router data"}, { SFLOW_FLOW_EXTENDED_GATEWAY_DATA, "Extended Gateway data"}, { SFLOW_FLOW_EXTENDED_USER_DATA, "Extended User data"}, { SFLOW_FLOW_EXTENDED_URL_DATA, "Extended URL data"}, { SFLOW_FLOW_EXTENDED_MPLS_DATA, "Extended MPLS data"}, { SFLOW_FLOW_EXTENDED_NAT_DATA, "Extended NAT data"}, { SFLOW_FLOW_EXTENDED_MPLS_TUNNEL, "Extended MPLS tunnel"}, { SFLOW_FLOW_EXTENDED_MPLS_VC, "Extended MPLS VC"}, { SFLOW_FLOW_EXTENDED_MPLS_FEC, "Extended MPLS FEC"}, { SFLOW_FLOW_EXTENDED_MPLS_LVP_FEC, "Extended MPLS LVP FEC"}, { SFLOW_FLOW_EXTENDED_VLAN_TUNNEL, "Extended VLAN Tunnel"}, { 0, NULL} }; #define SFLOW_HEADER_PROTOCOL_ETHERNET 1 #define SFLOW_HEADER_PROTOCOL_IPV4 11 #define SFLOW_HEADER_PROTOCOL_IPV6 12 static const struct tok sflow_flow_raw_protocol_values[] = { { SFLOW_HEADER_PROTOCOL_ETHERNET, "Ethernet"}, { SFLOW_HEADER_PROTOCOL_IPV4, "IPv4"}, { SFLOW_HEADER_PROTOCOL_IPV6, "IPv6"}, { 0, NULL} }; struct sflow_expanded_flow_raw_t { uint8_t protocol[4]; uint8_t length[4]; uint8_t stripped_bytes[4]; uint8_t header_size[4]; }; struct sflow_ethernet_frame_t { uint8_t length[4]; uint8_t src_mac[8]; uint8_t dst_mac[8]; uint8_t type[4]; }; struct sflow_extended_switch_data_t { uint8_t src_vlan[4]; uint8_t src_pri[4]; uint8_t dst_vlan[4]; uint8_t dst_pri[4]; }; struct sflow_counter_record_t { uint8_t format[4]; uint8_t length[4]; }; struct sflow_flow_record_t { uint8_t format[4]; uint8_t length[4]; }; struct sflow_counter_sample_t { uint8_t seqnum[4]; uint8_t typesource[4]; uint8_t records[4]; }; struct sflow_expanded_counter_sample_t { uint8_t seqnum[4]; uint8_t type[4]; uint8_t index[4]; uint8_t records[4]; }; #define SFLOW_COUNTER_GENERIC 1 #define SFLOW_COUNTER_ETHERNET 2 #define SFLOW_COUNTER_TOKEN_RING 3 #define SFLOW_COUNTER_BASEVG 4 #define SFLOW_COUNTER_VLAN 5 #define SFLOW_COUNTER_PROCESSOR 1001 static const struct tok sflow_counter_type_values[] = { { SFLOW_COUNTER_GENERIC, "Generic counter"}, { SFLOW_COUNTER_ETHERNET, "Ethernet counter"}, { SFLOW_COUNTER_TOKEN_RING, "Token ring counter"}, { SFLOW_COUNTER_BASEVG, "100 BaseVG counter"}, { SFLOW_COUNTER_VLAN, "Vlan counter"}, { SFLOW_COUNTER_PROCESSOR, "Processor counter"}, { 0, NULL} }; #define SFLOW_IFACE_DIRECTION_UNKNOWN 0 #define SFLOW_IFACE_DIRECTION_FULLDUPLEX 1 #define SFLOW_IFACE_DIRECTION_HALFDUPLEX 2 #define SFLOW_IFACE_DIRECTION_IN 3 #define SFLOW_IFACE_DIRECTION_OUT 4 static const struct tok sflow_iface_direction_values[] = { { SFLOW_IFACE_DIRECTION_UNKNOWN, "unknown"}, { SFLOW_IFACE_DIRECTION_FULLDUPLEX, "full-duplex"}, { SFLOW_IFACE_DIRECTION_HALFDUPLEX, "half-duplex"}, { SFLOW_IFACE_DIRECTION_IN, "in"}, { SFLOW_IFACE_DIRECTION_OUT, "out"}, { 0, NULL} }; struct sflow_generic_counter_t { uint8_t ifindex[4]; uint8_t iftype[4]; uint8_t ifspeed[8]; uint8_t ifdirection[4]; uint8_t ifstatus[4]; uint8_t ifinoctets[8]; uint8_t ifinunicastpkts[4]; uint8_t ifinmulticastpkts[4]; uint8_t ifinbroadcastpkts[4]; uint8_t ifindiscards[4]; uint8_t ifinerrors[4]; uint8_t ifinunkownprotos[4]; uint8_t ifoutoctets[8]; uint8_t ifoutunicastpkts[4]; uint8_t ifoutmulticastpkts[4]; uint8_t ifoutbroadcastpkts[4]; uint8_t ifoutdiscards[4]; uint8_t ifouterrors[4]; uint8_t ifpromiscmode[4]; }; struct sflow_ethernet_counter_t { uint8_t alignerrors[4]; uint8_t fcserrors[4]; uint8_t single_collision_frames[4]; uint8_t multiple_collision_frames[4]; uint8_t test_errors[4]; uint8_t deferred_transmissions[4]; uint8_t late_collisions[4]; uint8_t excessive_collisions[4]; uint8_t mac_transmit_errors[4]; uint8_t carrier_sense_errors[4]; uint8_t frame_too_longs[4]; uint8_t mac_receive_errors[4]; uint8_t symbol_errors[4]; }; struct sflow_100basevg_counter_t { uint8_t in_highpriority_frames[4]; uint8_t in_highpriority_octets[8]; uint8_t in_normpriority_frames[4]; uint8_t in_normpriority_octets[8]; uint8_t in_ipmerrors[4]; uint8_t in_oversized[4]; uint8_t in_data_errors[4]; uint8_t in_null_addressed_frames[4]; uint8_t out_highpriority_frames[4]; uint8_t out_highpriority_octets[8]; uint8_t transitioninto_frames[4]; uint8_t hc_in_highpriority_octets[8]; uint8_t hc_in_normpriority_octets[8]; uint8_t hc_out_highpriority_octets[8]; }; struct sflow_vlan_counter_t { uint8_t vlan_id[4]; uint8_t octets[8]; uint8_t unicast_pkt[4]; uint8_t multicast_pkt[4]; uint8_t broadcast_pkt[4]; uint8_t discards[4]; }; static int print_sflow_counter_generic(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_generic_counter_t *sflow_gen_counter; if (len < sizeof(struct sflow_generic_counter_t)) return 1; sflow_gen_counter = (const struct sflow_generic_counter_t *)pointer; ND_TCHECK(*sflow_gen_counter); ND_PRINT((ndo, "\n\t ifindex %u, iftype %u, ifspeed %" PRIu64 ", ifdirection %u (%s)", EXTRACT_BE_U_4(sflow_gen_counter->ifindex), EXTRACT_BE_U_4(sflow_gen_counter->iftype), EXTRACT_BE_U_8(sflow_gen_counter->ifspeed), EXTRACT_BE_U_4(sflow_gen_counter->ifdirection), tok2str(sflow_iface_direction_values, "Unknown", EXTRACT_BE_U_4(sflow_gen_counter->ifdirection)))); ND_PRINT((ndo, "\n\t ifstatus %u, adminstatus: %s, operstatus: %s", EXTRACT_BE_U_4(sflow_gen_counter->ifstatus), EXTRACT_BE_U_4(sflow_gen_counter->ifstatus)&1 ? "up" : "down", (EXTRACT_BE_U_4(sflow_gen_counter->ifstatus)>>1)&1 ? "up" : "down")); ND_PRINT((ndo, "\n\t In octets %" PRIu64 ", unicast pkts %u, multicast pkts %u, broadcast pkts %u, discards %u", EXTRACT_BE_U_8(sflow_gen_counter->ifinoctets), EXTRACT_BE_U_4(sflow_gen_counter->ifinunicastpkts), EXTRACT_BE_U_4(sflow_gen_counter->ifinmulticastpkts), EXTRACT_BE_U_4(sflow_gen_counter->ifinbroadcastpkts), EXTRACT_BE_U_4(sflow_gen_counter->ifindiscards))); ND_PRINT((ndo, "\n\t In errors %u, unknown protos %u", EXTRACT_BE_U_4(sflow_gen_counter->ifinerrors), EXTRACT_BE_U_4(sflow_gen_counter->ifinunkownprotos))); ND_PRINT((ndo, "\n\t Out octets %" PRIu64 ", unicast pkts %u, multicast pkts %u, broadcast pkts %u, discards %u", EXTRACT_BE_U_8(sflow_gen_counter->ifoutoctets), EXTRACT_BE_U_4(sflow_gen_counter->ifoutunicastpkts), EXTRACT_BE_U_4(sflow_gen_counter->ifoutmulticastpkts), EXTRACT_BE_U_4(sflow_gen_counter->ifoutbroadcastpkts), EXTRACT_BE_U_4(sflow_gen_counter->ifoutdiscards))); ND_PRINT((ndo, "\n\t Out errors %u, promisc mode %u", EXTRACT_BE_U_4(sflow_gen_counter->ifouterrors), EXTRACT_BE_U_4(sflow_gen_counter->ifpromiscmode))); return 0; trunc: return 1; } static int print_sflow_counter_ethernet(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_ethernet_counter_t *sflow_eth_counter; if (len < sizeof(struct sflow_ethernet_counter_t)) return 1; sflow_eth_counter = (const struct sflow_ethernet_counter_t *)pointer; ND_TCHECK(*sflow_eth_counter); ND_PRINT((ndo, "\n\t align errors %u, fcs errors %u, single collision %u, multiple collision %u, test error %u", EXTRACT_BE_U_4(sflow_eth_counter->alignerrors), EXTRACT_BE_U_4(sflow_eth_counter->fcserrors), EXTRACT_BE_U_4(sflow_eth_counter->single_collision_frames), EXTRACT_BE_U_4(sflow_eth_counter->multiple_collision_frames), EXTRACT_BE_U_4(sflow_eth_counter->test_errors))); ND_PRINT((ndo, "\n\t deferred %u, late collision %u, excessive collision %u, mac trans error %u", EXTRACT_BE_U_4(sflow_eth_counter->deferred_transmissions), EXTRACT_BE_U_4(sflow_eth_counter->late_collisions), EXTRACT_BE_U_4(sflow_eth_counter->excessive_collisions), EXTRACT_BE_U_4(sflow_eth_counter->mac_transmit_errors))); ND_PRINT((ndo, "\n\t carrier error %u, frames too long %u, mac receive errors %u, symbol errors %u", EXTRACT_BE_U_4(sflow_eth_counter->carrier_sense_errors), EXTRACT_BE_U_4(sflow_eth_counter->frame_too_longs), EXTRACT_BE_U_4(sflow_eth_counter->mac_receive_errors), EXTRACT_BE_U_4(sflow_eth_counter->symbol_errors))); return 0; trunc: return 1; } static int print_sflow_counter_token_ring(netdissect_options *ndo _U_, const u_char *pointer _U_, u_int len _U_) { return 0; } static int print_sflow_counter_basevg(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_100basevg_counter_t *sflow_100basevg_counter; if (len < sizeof(struct sflow_100basevg_counter_t)) return 1; sflow_100basevg_counter = (const struct sflow_100basevg_counter_t *)pointer; ND_TCHECK(*sflow_100basevg_counter); ND_PRINT((ndo, "\n\t in high prio frames %u, in high prio octets %" PRIu64, EXTRACT_BE_U_4(sflow_100basevg_counter->in_highpriority_frames), EXTRACT_BE_U_8(sflow_100basevg_counter->in_highpriority_octets))); ND_PRINT((ndo, "\n\t in norm prio frames %u, in norm prio octets %" PRIu64, EXTRACT_BE_U_4(sflow_100basevg_counter->in_normpriority_frames), EXTRACT_BE_U_8(sflow_100basevg_counter->in_normpriority_octets))); ND_PRINT((ndo, "\n\t in ipm errors %u, oversized %u, in data errors %u, null addressed frames %u", EXTRACT_BE_U_4(sflow_100basevg_counter->in_ipmerrors), EXTRACT_BE_U_4(sflow_100basevg_counter->in_oversized), EXTRACT_BE_U_4(sflow_100basevg_counter->in_data_errors), EXTRACT_BE_U_4(sflow_100basevg_counter->in_null_addressed_frames))); ND_PRINT((ndo, "\n\t out high prio frames %u, out high prio octets %" PRIu64 ", trans into frames %u", EXTRACT_BE_U_4(sflow_100basevg_counter->out_highpriority_frames), EXTRACT_BE_U_8(sflow_100basevg_counter->out_highpriority_octets), EXTRACT_BE_U_4(sflow_100basevg_counter->transitioninto_frames))); ND_PRINT((ndo, "\n\t in hc high prio octets %" PRIu64 ", in hc norm prio octets %" PRIu64 ", out hc high prio octets %" PRIu64, EXTRACT_BE_U_8(sflow_100basevg_counter->hc_in_highpriority_octets), EXTRACT_BE_U_8(sflow_100basevg_counter->hc_in_normpriority_octets), EXTRACT_BE_U_8(sflow_100basevg_counter->hc_out_highpriority_octets))); return 0; trunc: return 1; } static int print_sflow_counter_vlan(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_vlan_counter_t *sflow_vlan_counter; if (len < sizeof(struct sflow_vlan_counter_t)) return 1; sflow_vlan_counter = (const struct sflow_vlan_counter_t *)pointer; ND_TCHECK(*sflow_vlan_counter); ND_PRINT((ndo, "\n\t vlan_id %u, octets %" PRIu64 ", unicast_pkt %u, multicast_pkt %u, broadcast_pkt %u, discards %u", EXTRACT_BE_U_4(sflow_vlan_counter->vlan_id), EXTRACT_BE_U_8(sflow_vlan_counter->octets), EXTRACT_BE_U_4(sflow_vlan_counter->unicast_pkt), EXTRACT_BE_U_4(sflow_vlan_counter->multicast_pkt), EXTRACT_BE_U_4(sflow_vlan_counter->broadcast_pkt), EXTRACT_BE_U_4(sflow_vlan_counter->discards))); return 0; trunc: return 1; } struct sflow_processor_counter_t { uint8_t five_sec_util[4]; uint8_t one_min_util[4]; uint8_t five_min_util[4]; uint8_t total_memory[8]; uint8_t free_memory[8]; }; static int print_sflow_counter_processor(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_processor_counter_t *sflow_processor_counter; if (len < sizeof(struct sflow_processor_counter_t)) return 1; sflow_processor_counter = (const struct sflow_processor_counter_t *)pointer; ND_TCHECK(*sflow_processor_counter); ND_PRINT((ndo, "\n\t 5sec %u, 1min %u, 5min %u, total_mem %" PRIu64 ", total_mem %" PRIu64, EXTRACT_BE_U_4(sflow_processor_counter->five_sec_util), EXTRACT_BE_U_4(sflow_processor_counter->one_min_util), EXTRACT_BE_U_4(sflow_processor_counter->five_min_util), EXTRACT_BE_U_8(sflow_processor_counter->total_memory), EXTRACT_BE_U_8(sflow_processor_counter->free_memory))); return 0; trunc: return 1; } static int sflow_print_counter_records(netdissect_options *ndo, const u_char *pointer, u_int len, u_int records) { u_int nrecords; const u_char *tptr; u_int tlen; u_int counter_type; u_int counter_len; u_int enterprise; const struct sflow_counter_record_t *sflow_counter_record; nrecords = records; tptr = pointer; tlen = len; while (nrecords > 0) { /* do we have the "header?" */ if (tlen < sizeof(struct sflow_counter_record_t)) return 1; sflow_counter_record = (const struct sflow_counter_record_t *)tptr; ND_TCHECK(*sflow_counter_record); enterprise = EXTRACT_BE_U_4(sflow_counter_record->format); counter_type = enterprise & 0x0FFF; enterprise = enterprise >> 20; counter_len = EXTRACT_BE_U_4(sflow_counter_record->length); ND_PRINT((ndo, "\n\t enterprise %u, %s (%u) length %u", enterprise, (enterprise == 0) ? tok2str(sflow_counter_type_values,"Unknown",counter_type) : "Unknown", counter_type, counter_len)); tptr += sizeof(struct sflow_counter_record_t); tlen -= sizeof(struct sflow_counter_record_t); if (tlen < counter_len) return 1; if (enterprise == 0) { switch (counter_type) { case SFLOW_COUNTER_GENERIC: if (print_sflow_counter_generic(ndo, tptr, tlen)) return 1; break; case SFLOW_COUNTER_ETHERNET: if (print_sflow_counter_ethernet(ndo, tptr, tlen)) return 1; break; case SFLOW_COUNTER_TOKEN_RING: if (print_sflow_counter_token_ring(ndo, tptr,tlen)) return 1; break; case SFLOW_COUNTER_BASEVG: if (print_sflow_counter_basevg(ndo, tptr, tlen)) return 1; break; case SFLOW_COUNTER_VLAN: if (print_sflow_counter_vlan(ndo, tptr, tlen)) return 1; break; case SFLOW_COUNTER_PROCESSOR: if (print_sflow_counter_processor(ndo, tptr, tlen)) return 1; break; default: if (ndo->ndo_vflag <= 1) print_unknown_data(ndo, tptr, "\n\t\t", counter_len); break; } } tptr += counter_len; tlen -= counter_len; nrecords--; } return 0; trunc: return 1; } static int sflow_print_counter_sample(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_counter_sample_t *sflow_counter_sample; u_int nrecords; u_int typesource; u_int type; u_int index; if (len < sizeof(struct sflow_counter_sample_t)) return 1; sflow_counter_sample = (const struct sflow_counter_sample_t *)pointer; ND_TCHECK(*sflow_counter_sample); typesource = EXTRACT_BE_U_4(sflow_counter_sample->typesource); nrecords = EXTRACT_BE_U_4(sflow_counter_sample->records); type = typesource >> 24; index = typesource & 0x0FFF; ND_PRINT((ndo, " seqnum %u, type %u, idx %u, records %u", EXTRACT_BE_U_4(sflow_counter_sample->seqnum), type, index, nrecords)); return sflow_print_counter_records(ndo, pointer + sizeof(struct sflow_counter_sample_t), len - sizeof(struct sflow_counter_sample_t), nrecords); trunc: return 1; } static int sflow_print_expanded_counter_sample(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_expanded_counter_sample_t *sflow_expanded_counter_sample; u_int nrecords; if (len < sizeof(struct sflow_expanded_counter_sample_t)) return 1; sflow_expanded_counter_sample = (const struct sflow_expanded_counter_sample_t *)pointer; ND_TCHECK(*sflow_expanded_counter_sample); nrecords = EXTRACT_BE_U_4(sflow_expanded_counter_sample->records); ND_PRINT((ndo, " seqnum %u, type %u, idx %u, records %u", EXTRACT_BE_U_4(sflow_expanded_counter_sample->seqnum), EXTRACT_BE_U_4(sflow_expanded_counter_sample->type), EXTRACT_BE_U_4(sflow_expanded_counter_sample->index), nrecords)); return sflow_print_counter_records(ndo, pointer + sizeof(struct sflow_expanded_counter_sample_t), len - sizeof(struct sflow_expanded_counter_sample_t), nrecords); trunc: return 1; } static int print_sflow_raw_packet(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_expanded_flow_raw_t *sflow_flow_raw; if (len < sizeof(struct sflow_expanded_flow_raw_t)) return 1; sflow_flow_raw = (const struct sflow_expanded_flow_raw_t *)pointer; ND_TCHECK(*sflow_flow_raw); ND_PRINT((ndo, "\n\t protocol %s (%u), length %u, stripped bytes %u, header_size %u", tok2str(sflow_flow_raw_protocol_values,"Unknown",EXTRACT_BE_U_4(sflow_flow_raw->protocol)), EXTRACT_BE_U_4(sflow_flow_raw->protocol), EXTRACT_BE_U_4(sflow_flow_raw->length), EXTRACT_BE_U_4(sflow_flow_raw->stripped_bytes), EXTRACT_BE_U_4(sflow_flow_raw->header_size))); /* QUESTION - should we attempt to print the raw header itself? assuming of course there is wnough data present to do so... */ return 0; trunc: return 1; } static int print_sflow_ethernet_frame(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_ethernet_frame_t *sflow_ethernet_frame; if (len < sizeof(struct sflow_ethernet_frame_t)) return 1; sflow_ethernet_frame = (const struct sflow_ethernet_frame_t *)pointer; ND_TCHECK(*sflow_ethernet_frame); ND_PRINT((ndo, "\n\t frame len %u, type %u", EXTRACT_BE_U_4(sflow_ethernet_frame->length), EXTRACT_BE_U_4(sflow_ethernet_frame->type))); return 0; trunc: return 1; } static int print_sflow_extended_switch_data(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_extended_switch_data_t *sflow_extended_sw_data; if (len < sizeof(struct sflow_extended_switch_data_t)) return 1; sflow_extended_sw_data = (const struct sflow_extended_switch_data_t *)pointer; ND_TCHECK(*sflow_extended_sw_data); ND_PRINT((ndo, "\n\t src vlan %u, src pri %u, dst vlan %u, dst pri %u", EXTRACT_BE_U_4(sflow_extended_sw_data->src_vlan), EXTRACT_BE_U_4(sflow_extended_sw_data->src_pri), EXTRACT_BE_U_4(sflow_extended_sw_data->dst_vlan), EXTRACT_BE_U_4(sflow_extended_sw_data->dst_pri))); return 0; trunc: return 1; } static int sflow_print_flow_records(netdissect_options *ndo, const u_char *pointer, u_int len, u_int records) { u_int nrecords; const u_char *tptr; u_int tlen; u_int flow_type; u_int enterprise; u_int flow_len; const struct sflow_flow_record_t *sflow_flow_record; nrecords = records; tptr = pointer; tlen = len; while (nrecords > 0) { /* do we have the "header?" */ if (tlen < sizeof(struct sflow_flow_record_t)) return 1; sflow_flow_record = (const struct sflow_flow_record_t *)tptr; ND_TCHECK(*sflow_flow_record); /* so, the funky encoding means we cannot blythly mask-off bits, we must also check the enterprise. */ enterprise = EXTRACT_BE_U_4(sflow_flow_record->format); flow_type = enterprise & 0x0FFF; enterprise = enterprise >> 12; flow_len = EXTRACT_BE_U_4(sflow_flow_record->length); ND_PRINT((ndo, "\n\t enterprise %u %s (%u) length %u", enterprise, (enterprise == 0) ? tok2str(sflow_flow_type_values,"Unknown",flow_type) : "Unknown", flow_type, flow_len)); tptr += sizeof(struct sflow_flow_record_t); tlen -= sizeof(struct sflow_flow_record_t); if (tlen < flow_len) return 1; if (enterprise == 0) { switch (flow_type) { case SFLOW_FLOW_RAW_PACKET: if (print_sflow_raw_packet(ndo, tptr, tlen)) return 1; break; case SFLOW_FLOW_EXTENDED_SWITCH_DATA: if (print_sflow_extended_switch_data(ndo, tptr, tlen)) return 1; break; case SFLOW_FLOW_ETHERNET_FRAME: if (print_sflow_ethernet_frame(ndo, tptr, tlen)) return 1; break; /* FIXME these need a decoder */ case SFLOW_FLOW_IPV4_DATA: case SFLOW_FLOW_IPV6_DATA: case SFLOW_FLOW_EXTENDED_ROUTER_DATA: case SFLOW_FLOW_EXTENDED_GATEWAY_DATA: case SFLOW_FLOW_EXTENDED_USER_DATA: case SFLOW_FLOW_EXTENDED_URL_DATA: case SFLOW_FLOW_EXTENDED_MPLS_DATA: case SFLOW_FLOW_EXTENDED_NAT_DATA: case SFLOW_FLOW_EXTENDED_MPLS_TUNNEL: case SFLOW_FLOW_EXTENDED_MPLS_VC: case SFLOW_FLOW_EXTENDED_MPLS_FEC: case SFLOW_FLOW_EXTENDED_MPLS_LVP_FEC: case SFLOW_FLOW_EXTENDED_VLAN_TUNNEL: break; default: if (ndo->ndo_vflag <= 1) print_unknown_data(ndo, tptr, "\n\t\t", flow_len); break; } } tptr += flow_len; tlen -= flow_len; nrecords--; } return 0; trunc: return 1; } static int sflow_print_flow_sample(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_flow_sample_t *sflow_flow_sample; u_int nrecords; u_int typesource; u_int type; u_int index; if (len < sizeof(struct sflow_flow_sample_t)) return 1; sflow_flow_sample = (const struct sflow_flow_sample_t *)pointer; ND_TCHECK(*sflow_flow_sample); typesource = EXTRACT_BE_U_4(sflow_flow_sample->typesource); nrecords = EXTRACT_BE_U_4(sflow_flow_sample->records); type = typesource >> 24; index = typesource & 0x0FFF; ND_PRINT((ndo, " seqnum %u, type %u, idx %u, rate %u, pool %u, drops %u, input %u output %u records %u", EXTRACT_BE_U_4(sflow_flow_sample->seqnum), type, index, EXTRACT_BE_U_4(sflow_flow_sample->rate), EXTRACT_BE_U_4(sflow_flow_sample->pool), EXTRACT_BE_U_4(sflow_flow_sample->drops), EXTRACT_BE_U_4(sflow_flow_sample->in_interface), EXTRACT_BE_U_4(sflow_flow_sample->out_interface), nrecords)); return sflow_print_flow_records(ndo, pointer + sizeof(struct sflow_flow_sample_t), len - sizeof(struct sflow_flow_sample_t), nrecords); trunc: return 1; } static int sflow_print_expanded_flow_sample(netdissect_options *ndo, const u_char *pointer, u_int len) { const struct sflow_expanded_flow_sample_t *sflow_expanded_flow_sample; u_int nrecords; if (len < sizeof(struct sflow_expanded_flow_sample_t)) return 1; sflow_expanded_flow_sample = (const struct sflow_expanded_flow_sample_t *)pointer; ND_TCHECK(*sflow_expanded_flow_sample); nrecords = EXTRACT_BE_U_4(sflow_expanded_flow_sample->records); ND_PRINT((ndo, " seqnum %u, type %u, idx %u, rate %u, pool %u, drops %u, records %u", EXTRACT_BE_U_4(sflow_expanded_flow_sample->seqnum), EXTRACT_BE_U_4(sflow_expanded_flow_sample->type), EXTRACT_BE_U_4(sflow_expanded_flow_sample->index), EXTRACT_BE_U_4(sflow_expanded_flow_sample->rate), EXTRACT_BE_U_4(sflow_expanded_flow_sample->pool), EXTRACT_BE_U_4(sflow_expanded_flow_sample->drops), EXTRACT_BE_U_4(sflow_expanded_flow_sample->records))); return sflow_print_flow_records(ndo, pointer + sizeof(struct sflow_expanded_flow_sample_t), len - sizeof(struct sflow_expanded_flow_sample_t), nrecords); trunc: return 1; } void sflow_print(netdissect_options *ndo, const u_char *pptr, u_int len) { const struct sflow_datagram_t *sflow_datagram; const struct sflow_sample_header *sflow_sample; const u_char *tptr; u_int tlen; uint32_t sflow_sample_type, sflow_sample_len; uint32_t nsamples; tptr = pptr; tlen = len; sflow_datagram = (const struct sflow_datagram_t *)pptr; ND_TCHECK(*sflow_datagram); /* * Sanity checking of the header. */ if (EXTRACT_BE_U_4(sflow_datagram->version) != 5) { ND_PRINT((ndo, "sFlow version %u packet not supported", EXTRACT_BE_U_4(sflow_datagram->version))); return; } if (ndo->ndo_vflag < 1) { ND_PRINT((ndo, "sFlowv%u, %s agent %s, agent-id %u, length %u", EXTRACT_BE_U_4(sflow_datagram->version), EXTRACT_BE_U_4(sflow_datagram->ip_version) == 1 ? "IPv4" : "IPv6", ipaddr_string(ndo, sflow_datagram->agent), EXTRACT_BE_U_4(sflow_datagram->agent_id), len)); return; } /* ok they seem to want to know everything - lets fully decode it */ nsamples=EXTRACT_BE_U_4(sflow_datagram->samples); ND_PRINT((ndo, "sFlowv%u, %s agent %s, agent-id %u, seqnum %u, uptime %u, samples %u, length %u", EXTRACT_BE_U_4(sflow_datagram->version), EXTRACT_BE_U_4(sflow_datagram->ip_version) == 1 ? "IPv4" : "IPv6", ipaddr_string(ndo, sflow_datagram->agent), EXTRACT_BE_U_4(sflow_datagram->agent_id), EXTRACT_BE_U_4(sflow_datagram->seqnum), EXTRACT_BE_U_4(sflow_datagram->uptime), nsamples, len)); /* skip Common header */ tptr += sizeof(struct sflow_datagram_t); tlen -= sizeof(struct sflow_datagram_t); while (nsamples > 0 && tlen > 0) { sflow_sample = (const struct sflow_sample_header *)tptr; ND_TCHECK(*sflow_sample); sflow_sample_type = (EXTRACT_BE_U_4(sflow_sample->format)&0x0FFF); sflow_sample_len = EXTRACT_BE_U_4(sflow_sample->len); if (tlen < sizeof(struct sflow_sample_header)) goto trunc; tptr += sizeof(struct sflow_sample_header); tlen -= sizeof(struct sflow_sample_header); ND_PRINT((ndo, "\n\t%s (%u), length %u,", tok2str(sflow_format_values, "Unknown", sflow_sample_type), sflow_sample_type, sflow_sample_len)); /* basic sanity check */ if (sflow_sample_type == 0 || sflow_sample_len ==0) { return; } if (tlen < sflow_sample_len) goto trunc; /* did we capture enough for fully decoding the sample ? */ ND_TCHECK_LEN(tptr, sflow_sample_len); switch(sflow_sample_type) { case SFLOW_FLOW_SAMPLE: if (sflow_print_flow_sample(ndo, tptr, tlen)) goto trunc; break; case SFLOW_COUNTER_SAMPLE: if (sflow_print_counter_sample(ndo, tptr,tlen)) goto trunc; break; case SFLOW_EXPANDED_FLOW_SAMPLE: if (sflow_print_expanded_flow_sample(ndo, tptr, tlen)) goto trunc; break; case SFLOW_EXPANDED_COUNTER_SAMPLE: if (sflow_print_expanded_counter_sample(ndo, tptr,tlen)) goto trunc; break; default: if (ndo->ndo_vflag <= 1) print_unknown_data(ndo, tptr, "\n\t ", sflow_sample_len); break; } tptr += sflow_sample_len; tlen -= sflow_sample_len; nsamples--; } return; trunc: ND_PRINT((ndo, "[|SFLOW]")); } /* * Local Variables: * c-style: whitesmith * c-basic-offset: 4 * End: */