// $Id: DNS.cc 6885 2009-08-20 04:37:55Z vern $ // // See the file "COPYING" in the main distribution directory for copyright. #include "config.h" #include #include #include #include #include "NetVar.h" #include "DNS.h" #include "Sessions.h" #include "Event.h" DNS_Interpreter::DNS_Interpreter(Analyzer* arg_analyzer) { analyzer = arg_analyzer; } int DNS_Interpreter::ParseMessage(const u_char* data, int len, int is_query) { int hdr_len = sizeof(DNS_RawMsgHdr); if ( len < hdr_len ) { analyzer->Weird("DNS_truncated_len_lt_hdr_len"); return 0; } DNS_MsgInfo msg((DNS_RawMsgHdr*) data, is_query); if ( dns_message ) { val_list* vl = new val_list(); vl->append(analyzer->BuildConnVal()); vl->append(new Val(is_query, TYPE_BOOL)); vl->append(msg.BuildHdrVal()); vl->append(new Val(len, TYPE_COUNT)); analyzer->ConnectionEvent(dns_message, vl); } // There is a great deal of non-DNS traffic that runs on port 53. // This should weed out most of it. if ( dns_max_queries > 0 && msg.qdcount > dns_max_queries ) { analyzer->Weird("DNS_Conn_count_too_large"); EndMessage(&msg); return 0; } const u_char* msg_start = data; // needed for interpreting compression data += hdr_len; len -= hdr_len; if ( ! ParseQuestions(&msg, data, len, msg_start) ) { EndMessage(&msg); return 0; } if ( ! ParseAnswers(&msg, msg.ancount, DNS_ANSWER, data, len, msg_start) ) { EndMessage(&msg); return 0; } AddrVal server(analyzer->Conn()->RespAddr()); int skip_auth = dns_skip_all_auth; int skip_addl = dns_skip_all_addl; if ( msg.ancount > 0 ) { // We did an answer, so can potentially skip auth/addl. skip_auth = skip_auth || msg.nscount == 0 || dns_skip_auth->Lookup(&server); skip_addl = skip_addl || msg.arcount == 0 || dns_skip_addl->Lookup(&server); } if ( skip_auth && skip_addl ) { // No point doing further work parsing the message. EndMessage(&msg); return 1; } msg.skip_event = skip_auth; if ( ! ParseAnswers(&msg, msg.nscount, DNS_AUTHORITY, data, len, msg_start) ) { EndMessage(&msg); return 0; } if ( skip_addl ) { // No point doing further work parsing the message. EndMessage(&msg); return 1; } msg.skip_event = skip_addl; if ( ! ParseAnswers(&msg, msg.arcount, DNS_ADDITIONAL, data, len, msg_start) ) { EndMessage(&msg); return 0; } EndMessage(&msg); return 1; } int DNS_Interpreter::EndMessage(DNS_MsgInfo* msg) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); analyzer->ConnectionEvent(dns_end, vl); return 1; } int DNS_Interpreter::ParseQuestions(DNS_MsgInfo* msg, const u_char*& data, int& len, const u_char* msg_start) { int n = msg->qdcount; if ( n == 0 ) { // Generate event here because we won't go into ParseQuestion. EventHandlerPtr dns_event = msg->rcode == DNS_CODE_OK ? dns_query_reply : dns_rejected; BroString* question_name = new BroString(""); SendReplyOrRejectEvent(msg, dns_event, data, len, question_name); return 1; } while ( n > 0 && ParseQuestion(msg, data, len, msg_start) ) --n; return n == 0; } int DNS_Interpreter::ParseAnswers(DNS_MsgInfo* msg, int n, DNS_AnswerType atype, const u_char*& data, int& len, const u_char* msg_start) { msg->answer_type = atype; while ( n > 0 && ParseAnswer(msg, data, len, msg_start) ) --n; return n == 0; } int DNS_Interpreter::ParseQuestion(DNS_MsgInfo* msg, const u_char*& data, int& len, const u_char* msg_start) { u_char name[513]; int name_len = sizeof(name) - 1; u_char* name_end = ExtractName(data, len, name, name_len, msg_start); if ( ! name_end ) return 0; if ( len < int(sizeof(short)) * 2 ) { analyzer->Weird("DNS_truncated_quest_too_short"); return 0; } EventHandlerPtr dns_event = 0; if ( msg->QR == 0 ) dns_event = dns_request; else if ( msg->QR == 1 && msg->ancount == 0 && msg->nscount == 0 && msg->arcount == 0 ) // Service rejected in some fashion, and it won't be reported // via a returned RR because there aren't any. dns_event = dns_rejected; else dns_event = dns_query_reply; if ( dns_event && ! msg->skip_event ) { BroString* question_name = new BroString(name, name_end - name, 1); SendReplyOrRejectEvent(msg, dns_event, data, len, question_name); } else { // Consume the unused type/class. (void) ExtractShort(data, len); (void) ExtractShort(data, len); } return 1; } int DNS_Interpreter::ParseAnswer(DNS_MsgInfo* msg, const u_char*& data, int& len, const u_char* msg_start) { u_char name[513]; int name_len = sizeof(name) - 1; u_char* name_end = ExtractName(data, len, name, name_len, msg_start); if ( ! name_end ) return 0; if ( len < int(sizeof(short)) * 2 ) { analyzer->Weird("DNS_truncated_ans_too_short"); return 0; } // Note that the exact meaning of some of these fields will be // re-interpreted by other, more adventurous RR types. Unref(msg->query_name); msg->query_name = new StringVal(new BroString(name, name_end - name, 1)); msg->atype = RR_Type(ExtractShort(data, len)); msg->aclass = ExtractShort(data, len); msg->ttl = ExtractLong(data, len); int rdlength = ExtractShort(data, len); if ( rdlength > len ) { analyzer->Weird("DNS_truncated_RR_rdlength_lt_len"); return 0; } int status; switch ( msg->atype ) { case TYPE_A: status = ParseRR_A(msg, data, len, rdlength); break; case TYPE_A6: case TYPE_AAAA: status = ParseRR_AAAA(msg, data, len, rdlength); break; case TYPE_NS: case TYPE_CNAME: case TYPE_PTR: status = ParseRR_Name(msg, data, len, rdlength, msg_start); break; case TYPE_SOA: status = ParseRR_SOA(msg, data, len, rdlength, msg_start); break; case TYPE_WKS: status = ParseRR_WKS(msg, data, len, rdlength); break; case TYPE_HINFO: status = ParseRR_HINFO(msg, data, len, rdlength); break; case TYPE_MX: status = ParseRR_MX(msg, data, len, rdlength, msg_start); break; case TYPE_TXT: status = ParseRR_TXT(msg, data, len, rdlength, msg_start); break; case TYPE_NBS: status = ParseRR_NBS(msg, data, len, rdlength, msg_start); break; case TYPE_SRV: status = ParseRR_SRV(msg, data, len, rdlength, msg_start); break; case TYPE_EDNS: status = ParseRR_EDNS(msg, data, len, rdlength, msg_start); break; case TYPE_TSIG: status = ParseRR_TSIG(msg, data, len, rdlength, msg_start); break; default: analyzer->Weird("DNS_RR_unknown_type"); data += rdlength; len -= rdlength; status = 1; break; } return status; } u_char* DNS_Interpreter::ExtractName(const u_char*& data, int& len, u_char* name, int name_len, const u_char* msg_start) { u_char* name_start = name; while ( ExtractLabel(data, len, name, name_len, msg_start) ) ; int n = name - name_start; if ( n >= 255 ) analyzer->Weird("DNS_NAME_too_long"); if ( n >= 2 && name[-1] == '.' ) { // Remove trailing dot. --name; name[0] = 0; } // Convert labels to lower case for consistency. for ( u_char* np = name_start; np < name; ++np ) if ( isupper(*np) ) *np = tolower(*np); return name; } int DNS_Interpreter::ExtractLabel(const u_char*& data, int& len, u_char*& name, int& name_len, const u_char* msg_start) { if ( len <= 0 ) return 0; const u_char* orig_data = data; int label_len = data[0]; ++data; --len; if ( len <= 0 ) return 0; if ( label_len == 0 ) // Found terminating label. return 0; if ( (label_len & 0xc0) == 0xc0 ) { unsigned short offset = (label_len & ~0xc0) << 8; offset |= *data; ++data; --len; if ( offset >= orig_data - msg_start ) { // (You'd think that actually the offset should be // at least 6 bytes below our current position: // 2 bytes for a non-trivial label, plus 4 bytes for // its class and type, which presumably are between // our current location and the instance of the label. // But actually this turns out not to be the case - // sometimes compression points to compression.) analyzer->Weird("DNS_label_forward_compress_offset"); return 0; } // Recursively resolve name. const u_char* recurse_data = msg_start + offset; int recurse_max_len = orig_data - recurse_data; u_char* name_end = ExtractName(recurse_data, recurse_max_len, name, name_len, msg_start); name_len -= name_end - name; name = name_end; return 0; } if ( label_len > len ) { analyzer->Weird("DNS_label_len_gt_pkt"); data += len; // consume the rest of the packet len = 0; return 0; } if ( label_len > 63 ) { analyzer->Weird("DNS_label_too_long"); return 0; } if ( label_len >= name_len ) { analyzer->Weird("DNS_label_len_gt_name_len"); return 0; } memcpy(name, data, label_len); name[label_len] = '.'; name += label_len + 1; name_len -= label_len + 1; data += label_len; len -= label_len; return 1; } uint16 DNS_Interpreter::ExtractShort(const u_char*& data, int& len) { if ( len < 2 ) return 0; uint16 val; val = data[0] << 8; ++data; --len; val |= data[0]; ++data; --len; return val; } uint32 DNS_Interpreter::ExtractLong(const u_char*& data, int& len) { if ( len < 4 ) return 0; uint32 val; val = data[0] << 24; val |= data[1] << 16; val |= data[2] << 8; val |= data[3]; data += sizeof(val); len -= sizeof(val); return val; } int DNS_Interpreter::ParseRR_Name(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { const u_char* data_start = data; u_char name[513]; int name_len = sizeof(name) - 1; u_char* name_end = ExtractName(data, len, name, name_len, msg_start); if ( ! name_end ) return 0; if ( data - data_start != rdlength ) { analyzer->Weird("DNS_RR_length_mismatch"); } EventHandlerPtr reply_event; switch ( msg->atype ) { case TYPE_NS: reply_event = dns_NS_reply; break; case TYPE_CNAME: case TYPE_AAAA: case TYPE_A6: reply_event = dns_CNAME_reply; break; case TYPE_PTR: reply_event = dns_PTR_reply; break; default: analyzer->Conn()->Internal("DNS_RR_bad_name"); reply_event = 0; } if ( reply_event && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildAnswerVal()); vl->append(new StringVal(new BroString(name, name_end - name, 1))); analyzer->ConnectionEvent(reply_event, vl); } return 1; } int DNS_Interpreter::ParseRR_SOA(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { const u_char* data_start = data; u_char mname[513]; int mname_len = sizeof(mname) - 1; u_char* mname_end = ExtractName(data, len, mname, mname_len, msg_start); if ( ! mname_end ) return 0; u_char rname[513]; int rname_len = sizeof(rname) - 1; u_char* rname_end = ExtractName(data, len, rname, rname_len, msg_start); if ( ! rname_end ) return 0; if ( len < 20 ) return 0; uint32 serial = ExtractLong(data, len); uint32 refresh = ExtractLong(data, len); uint32 retry = ExtractLong(data, len); uint32 expire = ExtractLong(data, len); uint32 minimum = ExtractLong(data, len); if ( data - data_start != rdlength ) analyzer->Weird("DNS_RR_length_mismatch"); if ( dns_SOA_reply && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildAnswerVal()); RecordVal* r = new RecordVal(dns_soa); r->Assign(0, new StringVal(new BroString(mname, mname_end - mname, 1))); r->Assign(1, new StringVal(new BroString(rname, rname_end - rname, 1))); r->Assign(2, new Val(serial, TYPE_COUNT)); r->Assign(3, new IntervalVal(double(refresh), Seconds)); r->Assign(4, new IntervalVal(double(retry), Seconds)); r->Assign(5, new IntervalVal(double(expire), Seconds)); r->Assign(6, new IntervalVal(double(minimum), Seconds)); vl->append(r); analyzer->ConnectionEvent(dns_SOA_reply, vl); } return 1; } int DNS_Interpreter::ParseRR_MX(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { const u_char* data_start = data; int preference = ExtractShort(data, len); u_char name[513]; int name_len = sizeof(name) - 1; u_char* name_end = ExtractName(data, len, name, name_len, msg_start); if ( ! name_end ) return 0; if ( data - data_start != rdlength ) analyzer->Weird("DNS_RR_length_mismatch"); if ( dns_MX_reply && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildAnswerVal()); vl->append(new StringVal(new BroString(name, name_end - name, 1))); vl->append(new Val(preference, TYPE_COUNT)); analyzer->ConnectionEvent(dns_MX_reply, vl); } return 1; } int DNS_Interpreter::ParseRR_NBS(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { data += rdlength; len -= rdlength; return 1; } int DNS_Interpreter::ParseRR_SRV(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { const u_char* data_start = data; unsigned int priority = ExtractShort(data, len); unsigned int weight = ExtractShort(data, len); unsigned int port = ExtractShort(data, len); u_char name[513]; int name_len = sizeof(name) - 1; u_char* name_end = ExtractName(data, len, name, name_len, msg_start); if ( ! name_end ) return 0; *name_end = 0; // terminate name so we can use it in snprintf() if ( data - data_start != rdlength ) analyzer->Weird("DNS_RR_length_mismatch"); // The following is just a placeholder. char buf[2048]; safe_snprintf(buf, sizeof(buf), "SRV %s priority=%d weight=%d port=%d", name, priority, weight, port); return 1; } int DNS_Interpreter::ParseRR_EDNS(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { // We need a pair-value set mechanism here to dump useful information // out to the policy side of the house if rdlength > 0. if ( dns_EDNS_addl && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildEDNS_Val()); analyzer->ConnectionEvent(dns_EDNS_addl, vl); } // Currently EDNS supports the movement of type:data pairs // in the RR_DATA section. Here's where we should put together // a corresponding mechanism. if ( rdlength > 0 ) { // deal with data data += rdlength; len -= rdlength; } else { // no data, move on data += rdlength; len -= rdlength; } return 1; } int DNS_Interpreter::ParseRR_TSIG(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { const u_char* data_start = data; u_char alg_name[1024]; int alg_name_len = sizeof(alg_name) - 1; u_char* alg_name_end = ExtractName(data, len, alg_name, alg_name_len, msg_start); if ( ! alg_name_end ) return 0; uint32 sign_time_sec = ExtractLong(data, len); unsigned int sign_time_msec = ExtractShort(data, len); unsigned int fudge = ExtractShort(data, len); u_char request_MAC[16]; memcpy(request_MAC, data, sizeof(request_MAC)); // Here we adjust the size of the requested MAC + u_int16_t // for length. See RFC 2845, sec 2.3. int n = sizeof(request_MAC) + sizeof(u_int16_t); data += n; len -= n; unsigned int orig_id = ExtractShort(data, len); unsigned int rr_error = ExtractShort(data, len); msg->tsig = new TSIG_DATA; msg->tsig->alg_name = new BroString(alg_name, alg_name_end - alg_name, 1); msg->tsig->sig = new BroString(request_MAC, sizeof(request_MAC), 1); msg->tsig->time_s = sign_time_sec; msg->tsig->time_ms = sign_time_msec; msg->tsig->fudge = fudge; msg->tsig->orig_id = orig_id; msg->tsig->rr_error = rr_error; val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildTSIG_Val()); analyzer->ConnectionEvent(dns_TSIG_addl, vl); return 1; } int DNS_Interpreter::ParseRR_A(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength) { if ( rdlength != 4 ) { analyzer->Weird("DNS_RR_bad_length"); return 0; } uint32 addr = ExtractLong(data, len); if ( dns_A_reply && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildAnswerVal()); vl->append(new AddrVal(htonl(addr))); analyzer->ConnectionEvent(dns_A_reply, vl); } return 1; } int DNS_Interpreter::ParseRR_AAAA(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength) { // We need to parse an IPv6 address, high-order byte first. // ### Currently, we fake an A reply rather than an AAAA reply, // since for the latter we won't be able to express the full // address (unless Bro was compiled for IPv6 addresses). We do // this fake by using just the bottom 4 bytes of the IPv6 address. uint32 addr[4]; int i; for ( i = 0; i < 4; ++i ) { addr[i] = ntohl(ExtractLong(data, len)); if ( len < 0 ) { analyzer->Weird("DNS_AAAA_neg_length"); return 0; } } // Currently, dns_AAAA_reply is treated like dns_A_reply, since // IPv6 addresses are not generally processed. This needs to be // fixed. ### if ( dns_A_reply && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildAnswerVal()); vl->append(new AddrVal(htonl(addr[3]))); analyzer->ConnectionEvent(dns_A_reply, vl); } #if 0 alternative AAAA code from Chris if ( dns_AAAA_reply && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildAnswerVal()); #ifdef BROv6 // FIXME: might need to htonl the addr first vl->append(new AddrVal(addr)); #else vl->append(new AddrVal((uint32)0x0000)); #endif char addrstr[INET6_ADDRSTRLEN]; inet_ntop(AF_INET6, addr, addrstr, INET6_ADDRSTRLEN); vl->append(new StringVal(addrstr)); analyzer->ConnectionEvent(dns_AAAA_reply, vl); } #endif return 1; } int DNS_Interpreter::ParseRR_WKS(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength) { data += rdlength; len -= rdlength; return 1; } int DNS_Interpreter::ParseRR_HINFO(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength) { data += rdlength; len -= rdlength; return 1; } int DNS_Interpreter::ParseRR_TXT(DNS_MsgInfo* msg, const u_char*& data, int& len, int rdlength, const u_char* msg_start) { int name_len = data[0]; char* name = new char[name_len]; memcpy(name, data+1, name_len); data += rdlength; len -= rdlength; if ( dns_TXT_reply && ! msg->skip_event ) { val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(msg->BuildAnswerVal()); vl->append(new StringVal(name_len, name)); analyzer->ConnectionEvent(dns_TXT_reply, vl); } delete [] name; return 1; } void DNS_Interpreter::SendReplyOrRejectEvent(DNS_MsgInfo* msg, EventHandlerPtr event, const u_char*& data, int& len, BroString* question_name) { RR_Type qtype = RR_Type(ExtractShort(data, len)); int qclass = ExtractShort(data, len); val_list* vl = new val_list; vl->append(analyzer->BuildConnVal()); vl->append(msg->BuildHdrVal()); vl->append(new StringVal(question_name)); vl->append(new Val(qtype, TYPE_COUNT)); vl->append(new Val(qclass, TYPE_COUNT)); analyzer->ConnectionEvent(event, vl); } DNS_MsgInfo::DNS_MsgInfo(DNS_RawMsgHdr* hdr, int arg_is_query) { //### Need to fix alignment if hdr is misaligned (not on a short // boundary). unsigned short flags = ntohs(hdr->flags); QR = (flags & 0x8000) != 0; opcode = (flags & 0x7800) >> 11; AA = (flags & 0x0400) != 0; TC = (flags & 0x0200) != 0; RD = (flags & 0x0100) != 0; RA = (flags & 0x0080) != 0; Z = (flags & 0x0070) >> 4; rcode = (flags & 0x000f); qdcount = ntohs(hdr->qdcount); ancount = ntohs(hdr->ancount); nscount = ntohs(hdr->nscount); arcount = ntohs(hdr->arcount); id = ntohs(hdr->id); is_query = arg_is_query; query_name = 0; atype = TYPE_ALL; aclass = 0; ttl = 0; answer_type = DNS_QUESTION; skip_event = 0; } DNS_MsgInfo::~DNS_MsgInfo() { Unref(query_name); } Val* DNS_MsgInfo::BuildHdrVal() { RecordVal* r = new RecordVal(dns_msg); r->Assign(0, new Val(id, TYPE_COUNT)); r->Assign(1, new Val(opcode, TYPE_COUNT)); r->Assign(2, new Val(rcode, TYPE_COUNT)); r->Assign(3, new Val(QR, TYPE_BOOL)); r->Assign(4, new Val(AA, TYPE_BOOL)); r->Assign(5, new Val(TC, TYPE_BOOL)); r->Assign(6, new Val(RD, TYPE_BOOL)); r->Assign(7, new Val(RA, TYPE_BOOL)); r->Assign(8, new Val(Z, TYPE_COUNT)); r->Assign(9, new Val(qdcount, TYPE_COUNT)); r->Assign(10, new Val(ancount, TYPE_COUNT)); r->Assign(11, new Val(nscount, TYPE_COUNT)); r->Assign(12, new Val(arcount, TYPE_COUNT)); return r; } Val* DNS_MsgInfo::BuildAnswerVal() { RecordVal* r = new RecordVal(dns_answer); Ref(query_name); r->Assign(0, new Val(int(answer_type), TYPE_COUNT)); r->Assign(1, query_name); r->Assign(2, new Val(atype, TYPE_COUNT)); r->Assign(3, new Val(aclass, TYPE_COUNT)); r->Assign(4, new IntervalVal(double(ttl), Seconds)); return r; } Val* DNS_MsgInfo::BuildEDNS_Val() { // We have to treat the additional record type in EDNS differently // than a regular resource record. RecordVal* r = new RecordVal(dns_edns_additional); Ref(query_name); r->Assign(0, new Val(int(answer_type), TYPE_COUNT)); r->Assign(1, query_name); // type = 0x29 or 41 = EDNS r->Assign(2, new Val(atype, TYPE_COUNT)); // sender's UDP payload size, per RFC 2671 4.3 r->Assign(3, new Val(aclass, TYPE_COUNT)); // Need to break the TTL field into three components: // initial: [------------- ttl (32) ---------------------] // after: [DO][ ext rcode (7)][ver # (8)][ Z field (16)] unsigned int ercode = (ttl >> 24) & 0xff; unsigned int version = (ttl >> 16) & 0xff; // unsigned int DO = ttl & 0x8000; // "DNSSEC OK" - RFC 3225 unsigned int z = ttl & 0xffff; unsigned int return_error = (ercode << 8) | rcode; r->Assign(4, new Val(return_error, TYPE_COUNT)); r->Assign(5, new Val(version, TYPE_COUNT)); r->Assign(6, new Val(z, TYPE_COUNT)); r->Assign(7, new IntervalVal(double(ttl), Seconds)); r->Assign(8, new Val(is_query, TYPE_COUNT)); return r; } Val* DNS_MsgInfo::BuildTSIG_Val() { RecordVal* r = new RecordVal(dns_tsig_additional); double rtime = tsig->time_s + tsig->time_ms / 1000.0; Ref(query_name); // r->Assign(0, new Val(int(answer_type), TYPE_COUNT)); r->Assign(0, query_name); r->Assign(1, new Val(int(answer_type), TYPE_COUNT)); r->Assign(2, new StringVal(tsig->alg_name)); r->Assign(3, new StringVal(tsig->sig)); r->Assign(4, new Val(rtime, TYPE_TIME)); r->Assign(5, new Val(double(tsig->fudge), TYPE_TIME)); r->Assign(6, new Val(tsig->orig_id, TYPE_COUNT)); r->Assign(7, new Val(tsig->rr_error, TYPE_COUNT)); r->Assign(8, new Val(is_query, TYPE_COUNT)); delete tsig; tsig = 0; return r; } Contents_DNS::Contents_DNS(Connection* conn, bool orig, DNS_Interpreter* arg_interp) : TCP_SupportAnalyzer(AnalyzerTag::Contents_DNS, conn, orig) { interp = arg_interp; msg_buf = 0; buf_n = msg_size = 0; state = DNS_LEN_HI; } Contents_DNS::~Contents_DNS() { delete msg_buf; } void Contents_DNS::Flush() { if ( buf_n > 0 ) { // Deliver partial message. interp->ParseMessage(msg_buf, buf_n, true); msg_size = 0; } } void Contents_DNS::DeliverStream(int len, const u_char* data, bool orig) { if ( state == DNS_LEN_HI ) { msg_size = (*data) << 8; state = DNS_LEN_LO; ++data; --len; if ( len == 0 ) return; } if ( state == DNS_LEN_LO ) { msg_size += *data; state = DNS_MESSAGE_BUFFER; buf_n = 0; if ( msg_buf ) { if ( buf_len < msg_size ) { buf_len = msg_size; msg_buf = (u_char*) safe_realloc((void*) msg_buf, buf_len); } } else { buf_len = msg_size; msg_buf = (u_char*) safe_malloc(buf_len); } ++data; --len; if ( len == 0 ) return; } if ( state != DNS_MESSAGE_BUFFER ) Conn()->Internal("state inconsistency in Contents_DNS::DeliverStream"); int n; for ( n = 0; buf_n < msg_size && n < len; ++n ) msg_buf[buf_n++] = data[n]; if ( buf_n < msg_size ) // Haven't filled up the message buffer yet, no more to do. return; ForwardPacket(msg_size, msg_buf, orig, -1, 0, 0); buf_n = 0; state = DNS_LEN_HI; if ( n < len ) // More data to munch on. DeliverStream(len - n, data + n, orig); } DNS_Analyzer::DNS_Analyzer(Connection* conn) : TCP_ApplicationAnalyzer(AnalyzerTag::DNS, conn) { interp = new DNS_Interpreter(this); contents_dns_orig = contents_dns_resp = 0; did_session_done = 0; if ( Conn()->ConnTransport() == TRANSPORT_TCP ) { contents_dns_orig = new Contents_DNS(conn, true, interp); contents_dns_resp = new Contents_DNS(conn, false, interp); AddSupportAnalyzer(contents_dns_orig); AddSupportAnalyzer(contents_dns_resp); } else { ADD_ANALYZER_TIMER(&DNS_Analyzer::ExpireTimer, network_time + dns_session_timeout, 1, TIMER_DNS_EXPIRE); } } DNS_Analyzer::~DNS_Analyzer() { delete interp; } void DNS_Analyzer::Init() { } void DNS_Analyzer::Done() { TCP_ApplicationAnalyzer::Done(); if ( Conn()->ConnTransport() == TRANSPORT_UDP && ! did_session_done ) Event(udp_session_done); else interp->Timeout(); } void DNS_Analyzer::DeliverPacket(int len, const u_char* data, bool orig, int seq, const IP_Hdr* ip, int caplen) { TCP_ApplicationAnalyzer::DeliverPacket(len, data, orig, seq, ip, caplen); if ( orig ) { if ( ! interp->ParseMessage(data, len, 1) && non_dns_request ) { val_list* vl = new val_list; vl->append(BuildConnVal()); vl->append(new StringVal(len, (const char*) data)); ConnectionEvent(non_dns_request, vl); } } else interp->ParseMessage(data, len, 0); } void DNS_Analyzer::ConnectionClosed(TCP_Endpoint* endpoint, TCP_Endpoint* peer, int gen_event) { TCP_ApplicationAnalyzer::ConnectionClosed(endpoint, peer, gen_event); assert(contents_dns_orig && contents_dns_resp); contents_dns_orig->Flush(); contents_dns_resp->Flush(); } void DNS_Analyzer::ExpireTimer(double t) { // The - 1.0 in the following is to allow 1 second for the // common case of a single request followed by a single reply, // so we don't needlessly set the timer twice in that case. if ( t - Conn()->LastTime() >= dns_session_timeout - 1.0 || terminating ) { Event(connection_timeout); sessions->Remove(Conn()); } else ADD_ANALYZER_TIMER(&DNS_Analyzer::ExpireTimer, t + dns_session_timeout, 1, TIMER_DNS_EXPIRE); }