/* Copyright (C) 2005-2009 Michel de Boer This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include #include #include "log.h" #include "events.h" #include "timekeeper.h" #include "transaction.h" #include "transaction_mgr.h" #include "user.h" #include "util.h" #include "audits/memman.h" extern t_event_queue *evq_sender; extern t_event_queue *evq_trans_layer; extern t_transaction_mgr *transaction_mgr; string trans_state2str(t_trans_state s) { switch(s) { case TS_NULL: return "TS_NULL"; case TS_CALLING: return "TS_CALLING"; case TS_TRYING: return "TS_TRYING"; case TS_PROCEEDING: return "TS_PROCEEDING"; case TS_COMPLETED: return "TS_COMPLETED"; case TS_CONFIRMED: return "TS_CONFIRMED"; case TS_TERMINATED: return "TS_TERMINATED"; } return "UNKNOWN"; } /////////////////////////////////////////////////////////// // RFC 3261 17 // General transaction /////////////////////////////////////////////////////////// t_mutex t_transaction::mtx_class; t_tid t_transaction::next_id = 1; t_transaction::t_transaction(t_request *r, unsigned short _tuid) { mtx_class.lock(); id = next_id++; if (next_id == 65535) next_id = 1; mtx_class.unlock(); state = TS_NULL; request = (t_request *)r->copy(); final = NULL; tuid = _tuid; } t_transaction::~t_transaction() { MEMMAN_DELETE(request); delete request; if (final != NULL) { MEMMAN_DELETE(final); delete final; } for (list::iterator i = provisional.begin(); i != provisional.end(); i++) { MEMMAN_DELETE(*i); delete *i; } } t_tid t_transaction::get_id(void) const { return id; } void t_transaction::process_provisional(t_response *r) { provisional.push_back((t_response *)r->copy()); } void t_transaction::process_final(t_response *r) { final = (t_response *)r->copy(); } void t_transaction::process_response(t_response *r) { if (r->is_provisional()) { process_provisional(r); } else { process_final(r); } } t_trans_state t_transaction::get_state(void) const { return state; } void t_transaction::set_tuid(unsigned short _tuid) { tuid = _tuid; } t_method t_transaction::get_method(void) const { return request->method; } string t_transaction::get_to_tag(void) { string tag; tag = request->hdr_to.tag; if (tag.size() > 0) return tag; if (to_tag.size() > 0) return to_tag; to_tag = random_token(TAG_LEN); return to_tag; } // RCF 3261 section 8.2.6.2 t_response *t_transaction::create_response(int code, string reason) { t_response *r; r = request->create_response(code, reason); // NOTE: 100 Trying does not establish a dialog if (code != R_100_TRYING) { r->hdr_to.set_tag(get_to_tag()); } return r; } /////////////////////////////////////////////////////////// // RFC 3261 17.1 // Client transaction /////////////////////////////////////////////////////////// t_trans_client::t_trans_client(t_request *r, const t_ip_port &ip_port, unsigned short _tuid) : t_transaction(r, _tuid), dst_ip_port(ip_port) { // Send request evq_sender->push_network(r, dst_ip_port); } // RFC 3261 17.1.3, 8.2.6.2 // Section 17.1.3 states that only the branch and CSeq method should match. // This can lead to the following problem however: // // 1) A response matches a BYE request, but has a wrong call id. // 2) As the response matches the request, the transaction finishes. // 3) Then the response is delivered to the TU which tries to match the // response to a dialog. // 4) As the call id is wrong, no match is found an the response is discarded. // 5) Now the TU keeps waiting forever for a response on the BYE // // By taking the call id into account here, this scenario is prevented. // When a call id is wrong, the BYE request will be retransmitted due to // timeouts until the transaction times out completely and a 408 is sent // to the TU. // // Same problem can occur when tags do not match, so tag is take into account // as well. So tags are take into account as well. bool t_trans_client::match(t_response *r) const { t_via &req_top_via = request->hdr_via.via_list.front(); t_via &resp_top_via = r->hdr_via.via_list.front(); return (req_top_via.branch == resp_top_via.branch && request->hdr_cseq.method == r->hdr_cseq.method && request->hdr_call_id.call_id == r->hdr_call_id.call_id && request->hdr_from.tag == r->hdr_from.tag && (request->hdr_to.tag.empty() || request->hdr_to.tag == r->hdr_to.tag)); } // An ICMP error matches a transaction when the destination IP address/port // of the packet that caused the ICMP error equals the destination // IP address/port of the transaction. Other information of the packet causing // the ICMP error is not available. // In theory when multiple transactions are open for the same destination, the // wrong transaction may process the ICMP error. In practice this should rarely // happen as the destination will be unreachable for all those transactions. // If it happens a transaction gets aborted. bool t_trans_client::match(const t_icmp_msg &icmp) const { return (dst_ip_port.ipaddr == icmp.ipaddr && dst_ip_port.port == icmp.port); } bool t_trans_client::match(const string &branch, const t_method &cseq_method) const { t_via &req_top_via = request->hdr_via.via_list.front(); return (req_top_via.branch == branch && request->hdr_cseq.method == cseq_method); } void t_trans_client::process_provisional(t_response *r) { // Set the to_tag, such that an internally genrated answer (when needed) // will have the correct tag. // An INVITE transaction may receive provisional responses with // different to-tags. Only the first to-tag will be kept and an // internally generated response will match this tag. if (!r->hdr_to.tag.empty() && to_tag.empty()) { to_tag = r->hdr_to.tag; } t_transaction::process_provisional(r); } /////////////////////////////////////////////////////////// // RFC 3261 17.1.1 // Client INVITE transaction /////////////////////////////////////////////////////////// void t_tc_invite::start_timer_A(void) { timer_A = transaction_mgr->start_timer(duration_A, TIMER_A, id); // Double duration for a next start duration_A = 2 * duration_A; } void t_tc_invite::start_timer_B(void) { timer_B = transaction_mgr->start_timer(DURATION_B, TIMER_B, id); } void t_tc_invite::start_timer_D(void) { // RFC 3261 17.1.1.2 // For reliable transport timer D must be set to zero seconds. if (dst_ip_port.transport == "udp") { timer_D = transaction_mgr->start_timer(DURATION_D, TIMER_D, id); } else { timer_D = transaction_mgr->start_timer(0, TIMER_D, id); } } void t_tc_invite::stop_timer_A(void) { if (timer_A) { transaction_mgr->stop_timer(timer_A); timer_A = 0; } } void t_tc_invite::stop_timer_B(void) { if (timer_B) { transaction_mgr->stop_timer(timer_B); timer_B = 0; } } void t_tc_invite::stop_timer_D(void) { if (timer_D) { transaction_mgr->stop_timer(timer_D); timer_D = 0; } } t_tc_invite::t_tc_invite(t_request *r, const t_ip_port &ip_port, unsigned short _tuid) : t_trans_client(r, ip_port, _tuid) { assert(r->method == INVITE); ack = NULL; duration_A = DURATION_A; state = TS_CALLING; // RFC 3261 17.1.1.2 // Start timer A for unreliable transports. if (ip_port.transport == "udp") start_timer_A(); // RFC 3261 17.1.1.2 // Start timer B for all transports start_timer_B(); timer_D = 0; } t_tc_invite::~t_tc_invite() { if (ack != NULL) { MEMMAN_DELETE(ack); delete ack; } stop_timer_A(); stop_timer_B(); stop_timer_D(); } void t_tc_invite::process_provisional(t_response *r) { assert(r->is_provisional()); switch (state) { case TS_CALLING: stop_timer_A(); stop_timer_B(); // fall through case TS_PROCEEDING: t_trans_client::process_provisional(r); state = TS_PROCEEDING; // Report to TU evq_trans_layer->push_user(r, tuid, id); break; default: // Discard provisional response in other states break; } } void t_tc_invite::process_final(t_response *r) { assert(r->is_final()); t_ip_port ip_port; switch (state) { case TS_CALLING: stop_timer_A(); stop_timer_B(); // fall through case TS_PROCEEDING: t_trans_client::process_final(r); if (r->is_success()) { state = TS_TERMINATED; } else { // RFC 3261 17.1.1.3 // construct ACK ack = new t_request(ACK); MEMMAN_NEW(ack); ack->uri = request->uri; ack->hdr_call_id = request->hdr_call_id; ack->hdr_from = request->hdr_from; ack->hdr_to = r->hdr_to; ack->hdr_via.add_via( request->hdr_via.via_list.front()); ack->hdr_cseq.set_seqnr(request->hdr_cseq.seqnr); ack->hdr_cseq.set_method(ACK); ack->hdr_route = request->hdr_route; ack->hdr_max_forwards.set_max_forwards(MAX_FORWARDS); SET_HDR_USER_AGENT(ack->hdr_user_agent) // RFC 3261 22.1 // Duplicate Authorization and Proxy-Authorization // headers from INVITE if the credentials in the // INVITE are accepted. if (r->code != R_401_UNAUTHORIZED && r->code != R_407_PROXY_AUTH_REQUIRED) { ack->hdr_authorization = request->hdr_authorization; ack->hdr_proxy_authorization = request->hdr_proxy_authorization; } // RFC 3263 4 // ACK for non-2xx SIP responses to INVITE MUST be sent t // to the same host. request->get_current_destination(ip_port); ack->set_destination(ip_port); // Send ACK evq_sender->push_network(ack, dst_ip_port); start_timer_D(); state = TS_COMPLETED; } // Report to TU evq_trans_layer->push_user(r, tuid, id); break; case TS_COMPLETED: // A failure has been received. So 2XX is not // expected anymore. Discard 2XX. if (r->is_success()) { break; } // Retransmit ACK evq_sender->push_network(ack, dst_ip_port); break; default: break; } } void t_tc_invite::process_icmp(const t_icmp_msg &icmp) { log_file->write_report("ICMP error received.", "t_tc_invite::process_icmp"); process_failure(FAIL_TRANSPORT); } void t_tc_invite::process_failure(t_failure failure) { t_response *r; switch(state) { case TS_CALLING: stop_timer_A(); stop_timer_B(); switch (failure) { case FAIL_TRANSPORT: // A transport failure indicates a kind of network problem. // So the server is not available. Generate an internal // 503 Service Unavailable repsponse to notify the TU. r = create_response(R_503_SERVICE_UNAVAILABLE); break; case FAIL_TIMEOUT: r = create_response(R_408_REQUEST_TIMEOUT); break; default: log_file->write_header("t_tc_invite::process_failure", LOG_NORMAL, LOG_WARNING); log_file->write_raw("Unknown type of failure: "); log_file->write_raw((int)failure); log_file->write_endl(); log_file->write_footer(); r = create_response(R_400_BAD_REQUEST); break; } log_file->write_header("t_tc_invite::process_failure", LOG_NORMAL, LOG_INFO); log_file->write_raw("Transaction failed.\n\n"); log_file->write_raw("Send internal:\n"); log_file->write_raw(r->encode()); log_file->write_footer(); evq_trans_layer->push_user(r, tuid, id); MEMMAN_DELETE(r); delete r; state = TS_TERMINATED; break; default: // In other states a response has been received already, // so this failure seems to be a mismatch. Discard. break; } } void t_tc_invite::timeout(t_sip_timer t) { t_response *r; assert (t == TIMER_A || t == TIMER_B || t == TIMER_D); switch (state) { case TS_CALLING: switch (t) { case TIMER_A: // Resend request evq_sender->push_network(request, dst_ip_port); start_timer_A(); break; case TIMER_B: stop_timer_A(); timer_B = 0; // Report timer expiry to TU r = create_response(R_408_REQUEST_TIMEOUT); log_file->write_header("t_tc_invite::timeout", LOG_NORMAL, LOG_INFO); log_file->write_raw("Timer B expired.\n\n"); log_file->write_raw("Send internal:\n"); log_file->write_raw(r->encode()); log_file->write_footer(); evq_trans_layer->push_user(r, tuid, id); MEMMAN_DELETE(r); delete r; state = TS_TERMINATED; break; default: // Ignore expiry of other timers. // Other timers should have been stopped. break; } break; case TS_COMPLETED: switch (t) { case TIMER_D: timer_D = 0; state = TS_TERMINATED; break; default: // Ignore expiry of other timers. // Other timers should have been stopped. break; } break; default: // Ignore timer expiries in other states // Other timers should have been stopped. break; } } void t_tc_invite::abort(void) { t_response *r; switch (state) { case TS_PROCEEDING: r = create_response(R_408_REQUEST_TIMEOUT, "Request Aborted"); log_file->write_header("t_tc_invite::abort", LOG_NORMAL, LOG_INFO); log_file->write_raw("Invite transaction aborted.\n\n"); log_file->write_raw("Send internal:\n"); log_file->write_raw(r->encode()); log_file->write_footer(); evq_trans_layer->push_user(r, tuid, id); MEMMAN_DELETE(r); delete r; state = TS_TERMINATED; break; default: // Ignore abortion in other states. // In other states the request can be terminated in // a normal way. break; } } /////////////////////////////////////////////////////////// // RFC 3261 17.1.2 // Client non-INVITE transaction /////////////////////////////////////////////////////////// void t_tc_non_invite::start_timer_E(void) { if (state == TS_PROCEEDING) duration_E = DURATION_T2; timer_E = transaction_mgr->start_timer(duration_E, TIMER_E, id); duration_E = 2 * duration_E; if (duration_E > DURATION_T2) duration_E = DURATION_T2; } void t_tc_non_invite::start_timer_F(void) { timer_F = transaction_mgr->start_timer(DURATION_F, TIMER_F, id); } void t_tc_non_invite::start_timer_K(void) { // RFC 3261 17.1.2.2 // For reliable transports set timer K to zero seconds. if (dst_ip_port.transport == "udp") { timer_K = transaction_mgr->start_timer(DURATION_K, TIMER_K, id); } else { timer_K = transaction_mgr->start_timer(0, TIMER_K, id); } } void t_tc_non_invite::stop_timer_E(void) { if (timer_E) { transaction_mgr->stop_timer(timer_E); timer_E = 0; } } void t_tc_non_invite::stop_timer_F(void) { if (timer_F) { transaction_mgr->stop_timer(timer_F); timer_F = 0; } } void t_tc_non_invite::stop_timer_K(void) { if (timer_K) { transaction_mgr->stop_timer(timer_K); timer_K = 0; } } t_tc_non_invite::t_tc_non_invite(t_request *r, const t_ip_port &ip_port, unsigned short _tuid) : t_trans_client(r, ip_port, _tuid) { assert(r->method != INVITE); state = TS_TRYING; duration_E = DURATION_E; // RFC 3261 17.1.2.2 // Start timer E for unreliable transports. if (ip_port.transport == "udp") start_timer_E(); // RFC 3261 17.1.2.2 // Start timer F for all transports. start_timer_F(); timer_K = 0; } t_tc_non_invite::~t_tc_non_invite() { stop_timer_E(); stop_timer_F(); stop_timer_K(); } void t_tc_non_invite::process_provisional(t_response *r) { assert(r->is_provisional()); switch (state) { case TS_TRYING: case TS_PROCEEDING: t_trans_client::process_provisional(r); state = TS_PROCEEDING; // Report to TU evq_trans_layer->push_user(r, tuid, id); break; default: // Discard provisional response in other states break; } } void t_tc_non_invite::process_final(t_response *r) { assert(r->is_final()); switch (state) { case TS_TRYING: case TS_PROCEEDING: t_trans_client::process_final(r); stop_timer_E(); stop_timer_F(); // Report to TU evq_trans_layer->push_user(r, tuid, id); start_timer_K(); state = TS_COMPLETED; break; case TS_COMPLETED: // The received response is a retransmission. // AS the final response is already received this // retransmission can be discarded. // fall through default: break; } } void t_tc_non_invite::process_icmp(const t_icmp_msg &icmp) { log_file->write_report("ICMP error received.", "t_tc_non_invite::process_icmp"); process_failure(FAIL_TRANSPORT); } void t_tc_non_invite::process_failure(t_failure failure) { t_response *r; switch(state) { case TS_TRYING: stop_timer_E(); stop_timer_F(); switch (failure) { case FAIL_TRANSPORT: // A transport failure indicates a kind of network problem. // So the server is not available. Generate an internal // 503 Service Unavailable repsponse to notify the TU. r = create_response(R_503_SERVICE_UNAVAILABLE); break; case FAIL_TIMEOUT: r = create_response(R_408_REQUEST_TIMEOUT); break; default: log_file->write_header("t_tc_non_invite::process_failure", LOG_NORMAL, LOG_WARNING); log_file->write_raw("Unknown type of failure: "); log_file->write_raw((int)failure); log_file->write_endl(); log_file->write_footer(); r = create_response(R_400_BAD_REQUEST); break; } log_file->write_header("t_tc_non_invite::process_failure", LOG_NORMAL, LOG_INFO); log_file->write_raw("Transaction failed.\n\n"); log_file->write_raw("Send internal:\n"); log_file->write_raw(r->encode()); log_file->write_footer(); evq_trans_layer->push_user(r, tuid, id); MEMMAN_DELETE(r); delete r; state = TS_TERMINATED; break; default: // In other states a response has been received already, // so this failure seems to be a mismatch. Discard. break; } } void t_tc_non_invite::timeout(t_sip_timer t) { t_response *r; assert (t == TIMER_E || t == TIMER_F || t == TIMER_K); switch (state) { case TS_TRYING: case TS_PROCEEDING: switch (t) { case TIMER_E: // Resend request evq_sender->push_network(request, dst_ip_port); start_timer_E(); break; case TIMER_F: timer_F = 0; stop_timer_E(); // Report timer expiry to TU r = create_response(R_408_REQUEST_TIMEOUT); log_file->write_header("t_tc_non_invite::timeout", LOG_NORMAL, LOG_INFO); log_file->write_raw("Timer F expired.\n\n"); log_file->write_raw("Send internal:\n"); log_file->write_raw(r->encode()); log_file->write_footer(); evq_trans_layer->push_user(r, tuid, id); MEMMAN_DELETE(r); delete r; state = TS_TERMINATED; break; default: // Ignore expiry of other timers. // Other timers should have been stopped. break; } break; case TS_COMPLETED: switch (t) { case TIMER_K: timer_K = 0; state = TS_TERMINATED; break; default: // Ignore expiry of other timers. // Other timers should have been stopped. break; } default: // Ignore timer expiries in other states // Other timers should have been stopped. break; } } void t_tc_non_invite::abort(void) { t_response *r; switch (state) { case TS_TRYING: case TS_PROCEEDING: stop_timer_E(); stop_timer_F(); r = create_response(R_408_REQUEST_TIMEOUT, "Request Aborted"); log_file->write_header("t_tc_non_invite::abort", LOG_NORMAL, LOG_INFO); log_file->write_raw("Non-invite transaction aborted.\n\n"); log_file->write_raw("Send internal:\n"); log_file->write_raw(r->encode()); log_file->write_footer(); evq_trans_layer->push_user(r, tuid, id); MEMMAN_DELETE(r); delete r; state = TS_TERMINATED; break; default: // Ignore abortion in other states. // In other states the request can be terminated in // a normal way. break; } } /////////////////////////////////////////////////////////// // RFC 3261 17.2 // Server transaction /////////////////////////////////////////////////////////// t_trans_server::t_trans_server(t_request *r, unsigned short _tuid) : t_transaction(r, _tuid), resp_100_trying_sent(false) { t_trans_server *t; t_tid tid_cancel = 0; // Report to TU if (request->method == CANCEL) { t = transaction_mgr->find_cancel_target(r); if (t) tid_cancel = t->get_id(); evq_trans_layer->push_user_cancel(r, tuid, id, tid_cancel); } else { evq_trans_layer->push_user(r, tuid, id); } } void t_trans_server::process_provisional(t_response *r) { t_ip_port ip_port; if (r->code == R_100_TRYING && resp_100_trying_sent) { // Send 100 Trying only once return; } t_transaction::process_provisional(r); r->get_destination(ip_port); if (ip_port.ipaddr == 0) { // The response cannot be sent. state = TS_TERMINATED; // Report failure to TU evq_trans_layer->push_failure(FAIL_TRANSPORT, id); } else { // Send response evq_sender->push_network(r, ip_port); if (r->code == R_100_TRYING) { resp_100_trying_sent = true; } } } void t_trans_server::process_final(t_response *r) { t_ip_port ip_port; t_transaction::process_final(r); r->get_destination(ip_port); if (ip_port.ipaddr == 0) { // The response cannot be sent. state = TS_TERMINATED; // Report failure to TU evq_trans_layer->push_failure(FAIL_TRANSPORT, id); } else { // Send response evq_sender->push_network(r, ip_port); } } void t_trans_server::process_retransmission(void) { // nothing to do } // RFC 3261 17.2.3 // NOTE: retransmission of an incoming INVITE for which a 2XX response // has been sent already is checked by the TU. // see dialog::is_invite_retrans bool t_trans_server::match(t_request *r, bool cancel) const { t_via &orig_top_via = request->hdr_via.via_list.front(); t_via &recv_top_via = r->hdr_via.via_list.front(); if (recv_top_via.rfc3261_compliant()) { if (orig_top_via.branch != recv_top_via.branch) return false; if (orig_top_via.host != recv_top_via.host) return false; if (orig_top_via.port != recv_top_via.port) return false; switch(r->method) { case ACK: // return (request->hdr_cseq.method == INVITE); return (request->method == INVITE); break; case CANCEL: if (!cancel) { // return (request->hdr_cseq.method == // r->hdr_cseq.method); return (request->method == r->method); } // The target of CANCEL cannot be a CANCEL request // return (request->hdr_cseq.method != CANCEL); return (request->method != CANCEL); break; default: // return (request->hdr_cseq.method == // r->hdr_cseq.method); return (request->method == r->method); break; } } // Matching rules for backward compatibiliy with RFC 2543 // TODO: verify rules for matching via headers switch (r->method) { case INVITE: return (request->method == INVITE && request->uri.sip_match(r->uri) && request->hdr_to.tag == r->hdr_to.tag && request->hdr_from.tag == r->hdr_from.tag && request->hdr_call_id.call_id == r->hdr_call_id.call_id && request->hdr_cseq.seqnr == r->hdr_cseq.seqnr && orig_top_via.host == recv_top_via.host && orig_top_via.port == recv_top_via.port); break; case ACK: return (request->method == INVITE && request->uri.sip_match(r->uri) && request->hdr_from.tag == r->hdr_from.tag && request->hdr_call_id.call_id == r->hdr_call_id.call_id && request->hdr_cseq.seqnr == r->hdr_cseq.seqnr && orig_top_via.host == recv_top_via.host && orig_top_via.port == recv_top_via.port && final != NULL && final->hdr_to.tag == r->hdr_to.tag); break; case CANCEL: if (cancel) { return (request->uri.sip_match(r->uri) && request->hdr_from.tag == r->hdr_from.tag && request->hdr_call_id.call_id == r->hdr_call_id.call_id && request->hdr_cseq.seqnr == r->hdr_cseq.seqnr && request->hdr_cseq.method != CANCEL && orig_top_via.host == recv_top_via.host && orig_top_via.port == recv_top_via.port); } // fall through default: return (request->uri.sip_match(r->uri) && request->hdr_from.tag == r->hdr_from.tag && request->hdr_call_id.call_id == r->hdr_call_id.call_id && request->hdr_cseq == r->hdr_cseq && orig_top_via.host == recv_top_via.host && orig_top_via.port == recv_top_via.port); break; } // Should not get here return false; } bool t_trans_server::match(t_request *r) const { return match(r, false); } bool t_trans_server::match_cancel(t_request *r) const { assert(r->method == CANCEL); return match(r, true); } /////////////////////////////////////////////////////////// // RFC 3261 17.2.1 // Server INVITE transaction /////////////////////////////////////////////////////////// void t_ts_invite::start_timer_G(void) { timer_G = transaction_mgr->start_timer(duration_G, TIMER_G, id); duration_G = 2 * duration_G; if (duration_G > DURATION_T2) duration_G = DURATION_T2; } void t_ts_invite::start_timer_H(void) { timer_H = transaction_mgr->start_timer(DURATION_H, TIMER_H, id); } void t_ts_invite::start_timer_I(void) { // RFC 17.2.1 // Set timer I to T4 seconds for unreliable transports and to 0 for // reliable transports. if (request->src_ip_port.transport == "udp") { timer_I = transaction_mgr->start_timer(DURATION_I, TIMER_I, id); } else { timer_I = transaction_mgr->start_timer(0, TIMER_I, id); } } void t_ts_invite::stop_timer_G(void) { if (timer_G) { transaction_mgr->stop_timer(timer_G); timer_G = 0; } } void t_ts_invite::stop_timer_H(void) { if (timer_H) { transaction_mgr->stop_timer(timer_H); timer_H = 0; } } void t_ts_invite::stop_timer_I(void) { if (timer_I) { transaction_mgr->stop_timer(timer_I); timer_I = 0; } } t_ts_invite::t_ts_invite(t_request *r, unsigned short _tuid) : t_trans_server(r, _tuid) { assert(r->method == INVITE); state = TS_PROCEEDING; ack = NULL; timer_G = 0; timer_H = 0; timer_I = 0; duration_G = DURATION_G; } t_ts_invite::~t_ts_invite() { if (ack != NULL) { MEMMAN_DELETE(ack); delete ack; } stop_timer_G(); stop_timer_H(); stop_timer_I(); } void t_ts_invite::process_provisional(t_response *r) { assert(r->is_provisional()); switch (state) { case TS_PROCEEDING: t_trans_server::process_provisional(r); break; default: // TU should not send a provisional response // in other states. assert(false); break; } } void t_ts_invite::process_final(t_response *r) { assert(r->is_final()); switch (state) { case TS_PROCEEDING: t_trans_server::process_final(r); if (r->is_success()) { state = TS_TERMINATED; } else { // RFC 3261 17.2.1 // Start timer G for unreliable transports. if (request->src_ip_port.transport == "udp") { start_timer_G(); } // RFC 3261 17.2.1 // Start timer H for all transports start_timer_H(); state = TS_COMPLETED; } break; default: // No final responses are expected anymore. Discard. break; } } void t_ts_invite::process_retransmission(void) { t_ip_port ip_port; switch (state) { case TS_PROCEEDING: // Retransmit the latest provisional response (if present) t_trans_server::process_retransmission(); if (provisional.size() > 0) { t_response *r = provisional.back(); r->get_destination(ip_port); if (ip_port.ipaddr == 0) { // The response cannot be sent. state = TS_TERMINATED; // Report failure to TU evq_trans_layer->push_failure( FAIL_TRANSPORT, id); } else { // Send response evq_sender->push_network(r, ip_port); } } break; case TS_COMPLETED: // Retransmit the final response t_trans_server::process_retransmission(); final->get_destination(ip_port); if (ip_port.ipaddr == 0) { // The response cannot be sent. state = TS_TERMINATED; // Report failure to TU evq_trans_layer->push_failure(FAIL_TRANSPORT, id); } else { // Send response evq_sender->push_network(final, ip_port); } break; default: // Retransmissions should not happen in other states. // Discard. break; } } void t_ts_invite::timeout(t_sip_timer t) { t_ip_port ip_port; assert(t == TIMER_G || t == TIMER_I || t == TIMER_H); switch (state) { case TS_COMPLETED: switch (t) { case TIMER_G: timer_G = 0; // Retransmit the final response final->get_destination(ip_port); if (ip_port.ipaddr == 0) { // The response cannot be sent. stop_timer_H(); state = TS_TERMINATED; // Report failure to TU evq_trans_layer->push_failure( FAIL_TRANSPORT, id); } else { // Send response evq_sender->push_network(final, ip_port); start_timer_G(); } break; case TIMER_H: timer_H = 0; stop_timer_G(); state = TS_TERMINATED; // Report timer expiry to TU evq_trans_layer->push_failure(FAIL_TIMEOUT, id); break; default: // No other timers should be running. Discard. break; } break; case TS_CONFIRMED: switch (t) { case TIMER_I: timer_I = 0; state = TS_TERMINATED; break; default: // No other timers should be running. Discard. break; } default: // In other states no timers should be running. break; } } void t_ts_invite::acknowledge(t_request *ack_request) { assert(ack_request->method == ACK); switch (state) { case TS_COMPLETED: ack = (t_request *)ack_request->copy(); stop_timer_G(); stop_timer_H(); start_timer_I(); state = TS_CONFIRMED; // Report TU // ACK should not be reported to TU for non-2xx // evq_trans_layer->push_user(ack_request, tuid, id); break; default: // ACK is not expected in other states. Discard; break; } } /////////////////////////////////////////////////////////// // RFC 3261 17.2.2 // Server non-INVITE transaction /////////////////////////////////////////////////////////// void t_ts_non_invite::start_timer_J(void) { // RFC 3261 17.2.2 // For unreliable transports set timer J to 64*T1, for reliable // transports set it to 0. if (request->src_ip_port.transport == "udp") { timer_J = transaction_mgr->start_timer(DURATION_J, TIMER_J, id); } else { timer_J = transaction_mgr->start_timer(0, TIMER_J, id); } } void t_ts_non_invite::stop_timer_J(void) { if (timer_J) { transaction_mgr->stop_timer(timer_J); timer_J = 0; } } t_ts_non_invite::t_ts_non_invite(t_request *r, unsigned short _tuid) : t_trans_server(r, _tuid) { assert(r->method != INVITE); timer_J = 0; state = TS_TRYING; } t_ts_non_invite::~t_ts_non_invite() { stop_timer_J(); } void t_ts_non_invite::process_provisional(t_response *r) { assert(r->is_provisional()); switch (state) { case TS_TRYING: case TS_PROCEEDING: t_trans_server::process_provisional(r); state = TS_PROCEEDING; break; default: // TU should not send a provisional response // in other states. assert(false); break; } } void t_ts_non_invite::process_final(t_response *r) { assert(r->is_final()); switch (state) { case TS_TRYING: case TS_PROCEEDING: t_trans_server::process_final(r); start_timer_J(); state = TS_COMPLETED; break; default: // No final responses are expected anymore. Discard. break; } } void t_ts_non_invite::process_retransmission(void) { t_ip_port ip_port; t_response *r; switch (state) { case TS_PROCEEDING: // Retransmit the latest provisional response t_trans_server::process_retransmission(); r = provisional.back(); r->get_destination(ip_port); if (ip_port.ipaddr == 0) { // The response cannot be sent. state = TS_TERMINATED; // Report failure to TU evq_trans_layer->push_failure(FAIL_TRANSPORT, id); } else { // Send response evq_sender->push_network(r, ip_port); } break; case TS_COMPLETED: // Retransmit the final response t_trans_server::process_retransmission(); final->get_destination(ip_port); if (ip_port.ipaddr == 0) { // The response cannot be sent. stop_timer_J(); state = TS_TERMINATED; // Report failure to TU evq_trans_layer->push_failure(FAIL_TRANSPORT, id); } else { // Send response evq_sender->push_network(final, ip_port); } break; default: // Retransmissions should not happen in other states. // Discard. break; } } void t_ts_non_invite::timeout(t_sip_timer t) { assert (t == TIMER_J); switch (state) { case TS_COMPLETED: switch (t) { case TIMER_J: timer_J = 0; state = TS_TERMINATED; break; default: break; } default: break; } }