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README 100644 19.14kB
callid.c 100644 4.69kB
callid.h 100644 1.45kB
config.h 100644 2.85kB
defs.h 100644 1.15kB
dlg.c 100644 23.55kB
dlg.h 100644 4.57kB
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h_table.c 100644 10.52kB
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lock.c 100644 7.69kB
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sip_msg.c 100644 23.52kB
sip_msg.h 100644 1.37kB
t_cancel.c 100644 6.11kB
t_cancel.h 100644 2.53kB
t_dlg.c 100644 1.2kB
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t_fifo.c 100644 26kB
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t_funcs.c 100644 9.48kB
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t_fwd.c 100644 16.86kB
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t_hooks.c 100644 5.7kB
t_hooks.h 100644 8.55kB
t_lookup.c 100644 40.81kB
t_lookup.h 100644 3.21kB
t_msgbuilder.c 100644 19.14kB
t_msgbuilder.h 100644 2.95kB
t_reply.c 100644 53.92kB
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t_stats.c 100644 5.91kB
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test.c 100644 1.97kB
timer.c 100644 16.41kB
timer.h 100644 4.54kB
tm.c 100644 26.39kB
tm_load.c 100644 5.11kB
tm_load.h 100644 3.32kB
uac.c 100644 9.67kB
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tm Module Jiri Kuthan FhG FOKUS Edited by Jiri Kuthan Copyright � 2003 FhG FOKUS _________________________________________________________ Table of Contents 1. User's Guide 1.1. Overview 1.2. Dependencies 1.2.1. SER Modules 1.2.2. External Libraries or Applications 1.3. Exported Parameters 1.3.1. fr_timer (integer) 1.3.2. fr_inv_timer (integer) 1.3.3. wt_timer (integer) 1.3.4. delete_timer (integer) 1.3.5. retr_timer1p1 (integer) 1.3.6. retr_timer1p2 (integer) 1.3.7. retr_timer1p3 (integer) 1.3.8. retr_timer2 (integer) 1.3.9. noisy_ctimer (integer) 1.4. Exported Functions 1.4.1. t_relay_to_udp(ip, port), t_relay_to_tcp(ip, port) 1.4.2. t_relay() 1.4.3. t_on_negative(reply_route) 1.4.4. append_branch() 1.4.5. t_newtran() 1.4.6. t_reply(code, reason_phrase) 1.4.7. t_lookup_request() 1.4.8. t_retransmit_reply() 1.4.9. t_release() 1.4.10. t_forward_nonack(ip, port) 1.4.11. External Usage of TM 1.4.12. Known Issues 2. Developer's Guide 2.1. Defines 2.2. Functions 2.2.1. register_tmcb(cb_type, cb_func) 2.2.2. load_tm(*import_structure) 3. Frequently Asked Questions List of Examples 1-1. Set fr_timer parameter 1-2. Set fr_inv_timer parameter 1-3. Set wt_timer parameter 1-4. Set delete_timer parameter 1-5. Set retr_timer1p1 parameter 1-6. Set retr_timer1p2 parameter 1-7. Set retr_timer1p4 parameter 1-8. Set retr_timer2 parameter 1-9. Set noisy_ctimer parameter 1-10. t_relay_to_udp usage 1-11. t_relay usage 1-12. t_on_negative usage 1-13. append_branch usage 1-14. t_newtran usage 1-15. t_reply usage 1-16. t_lookup_request usage 1-17. t_retransmit_reply usage 1-18. t_release usage 1-19. t_forward_nonack usage _________________________________________________________ Chapter 1. User's Guide 1.1. Overview TM module enables stateful processing of SIP transactions. The main use of stateful logic, which is costly in terms of memory and CPU, is some services inherently need state. For example, transaction-based accounting (module acc) needs to process transaction state as opposed to individual messages, and any kinds of forking must be implemented statefully. Other use of stateful processing is it trading CPU caused by retransmission processing for memory. That makes however only sense if CPU consumption per request is huge. For example, if you want to avoid costly DNS resolution for every retransmission of a request to an unresolvable destination, use stateful mode. Then, only the initial message burdens server by DNS queries, subsequent retransmissions will be dropped and will not result in more processes blocked by DNS resolution. The price is more memory consumption and higher processing latency. From user's perspective, there are these major functions : t_relay, t_relay_to_udp and t_relay_to_tcp. All of them setup transaction state, absorb retransmissions from upstream, generate downstream retransmissions and correlate replies to requests. t_relay forwards to current URI (be it original request's URI or a URI changed by some of URI-modifying functions, such as sethost). t_relay_to_udp and t_relay_to_tcp forward to a specific address over UDP or TCP respectively. In general, if TM is used, it copies clones of received SIP messages in shared memory. That costs the memory and also CPU time (memcpys, lookups, shmem locks, etc.) Note that non-TM functions operate over the received message in private memory, that means that any core operations will have no effect on statefully processed messages after creating the transactional state. For example, calling record_route after t_relay is pretty useless, as the RR is added to privately held message whereas its TM clone is being forwarded. TM is quite big and uneasy to program--lot of mutexes, shared memory access, malloc & free, timers--you really need to be careful when you do anything. To simplify TM programming, there is the instrument of callbacks. The callback mechanisms allow programmers to register their functions to specific event. See t_hooks.h for a list of possible events. Other things programmers may want to know is UAC--it is a very simplistic code which allows you to generate your own transactions. Particularly useful for things like NOTIFYs or IM gateways. The UAC takes care of all the transaction machinery: retransmissions , FR timeouts, forking, etc. See t_uac prototype in uac.h for more details. Who wants to see the transaction result may register for a callback. _________________________________________________________ 1.2. Dependencies 1.2.1. SER Modules The following modules must be loaded before this module: * No dependencies on other SER modules. _________________________________________________________ 1.2.2. External Libraries or Applications The following libraries or applications must be installed before running SER with this module loaded: * None. _________________________________________________________ 1.3. Exported Parameters 1.3.1. fr_timer (integer) Timer which hits if no final reply for a request or ACK for a negative INVITE reply arrives (in seconds). Default value is 30 seconds. Example 1-1. Set fr_timer parameter ... modparam("tm", "fr_timer", 10) ... _________________________________________________________ 1.3.2. fr_inv_timer (integer) Timer which hits if no final reply for an INVITE arrives after a provisional message was received (in seconds). Default value is 120 seconds. Example 1-2. Set fr_inv_timer parameter ... modparam("tm", "fr_inv_timer", 200) ... _________________________________________________________ 1.3.3. wt_timer (integer) Time for which a transaction stays in memory to absorb delayed messages after it completed; also, when this timer hits, retransmission of local cancels is stopped (a puristic but complex behavior would be not to enter wait state until local branches are finished by a final reply or FR timer--we simplified). Default value is 5 seconds. Example 1-3. Set wt_timer parameter ... modparam("tm", "wt_timer", 10) ... _________________________________________________________ 1.3.4. delete_timer (integer) Time after which a to-be-deleted transaction currently ref-ed by a process will be tried to be deleted again. Default value is 2 seconds. Example 1-4. Set delete_timer parameter ... modparam("tm", "delete_timer", 5) ... _________________________________________________________ 1.3.5. retr_timer1p1 (integer) Retransmission period. Default value is 1 second. Example 1-5. Set retr_timer1p1 parameter ... modparam("tm", "retr_timer1p1", 2) ... _________________________________________________________ 1.3.6. retr_timer1p2 (integer) Retransmission period. Default value is 2 * retr_timer1p1 second. Example 1-6. Set retr_timer1p2 parameter ... modparam("tm", "retr_timer1p2", 4) ... _________________________________________________________ 1.3.7. retr_timer1p3 (integer) Retransmission period. Default value is 4 * retr_timer1p1 second. Example 1-7. Set retr_timer1p4 parameter ... modparam("tm", "retr_timer1p3", 8) ... _________________________________________________________ 1.3.8. retr_timer2 (integer) Maximum retransmission period. Default value is 4 seconds. Example 1-8. Set retr_timer2 parameter ... modparam("tm", "retr_timer2", 8) ... _________________________________________________________ 1.3.9. noisy_ctimer (integer) If set, on FR timer INVITE transactions will be explicitly canceled if possible, silently dropped otherwise. Preferably, it is turned off to allow very long ringing. This behavior is overridden if a request is forked, or some functionality explicitly turned it off for a transaction (like acc does to avoid unaccounted transactions due to expired timer). Default value is 0 (false). Example 1-9. Set noisy_ctimer parameter ... modparam("tm", "noisy_ctimer", 1) ... _________________________________________________________ 1.4. Exported Functions 1.4.1. t_relay_to_udp(ip, port), t_relay_to_tcp(ip, port) Relay a message statefully to a fixed destination. This along with t_relay is the function most users want to use--all other are mostly for programming. Programmers interested in writing TM logic should review how t_relay is implemented in tm.c and how TM callbacks work. Meaning of the parameters is as follows: * ip - IP address where the message should be sent. * port - Port number. Example 1-10. t_relay_to_udp usage ... t_relay_to_udp("", "5060"); ... _________________________________________________________ 1.4.2. t_relay() Relay a message statefully to destination indicated in current URI. (If the original URI was rewritten by UsrLoc, RR, strip/prefix, etc., the new URI will be taken). Returns a negative value on failure--you may still want to send a negative reply upstream statelessly not to leave upstream UAC in lurch. Example 1-11. t_relay usage ... if (!t_relay()) { sl_reply_error(); break; }; ... _________________________________________________________ 1.4.3. t_on_negative(reply_route) Sets reply routing block, to which control is passed after a transaction completed with a negative result but before sending a final reply. In the referred block, you can either start a new branch (good for services such as forward_on_no_reply) or send a final reply on your own (good for example for message silo, which received a negative reply from upstream and wants to tell upstream "202 I will take care of it"). Note that the set of command which are usable within reply_routes is strictly limited to rewriting URI, initiating new branches, logging, and sending stateful replies (t_reply). Any other commands may result in unpredictable behavior and possible server failure. Note that whenever reply_route is entered, uri is reset to value which it had on relaying. If it temporarily changed during a reply_route processing, subsequent reply_route will ignore the changed value and use again the original one. Meaning of the parameters is as follows: * reply_route - Reply route block to be called. Example 1-12. t_on_negative usage ... route { t_on_negative("1"); t_relay(); } reply_route[1] { revert_uri(); setuser("voicemail"); append_branch(); } ... See test/onr.cfg for a more complex example of combination of serial with parallel forking. _________________________________________________________ 1.4.4. append_branch() Similarly to t_fork_to, it extends destination set by a new entry. The difference is that current URI is taken as new entry. Example 1-13. append_branch usage ... set_user("john"); t_fork(); set_user("alice"); t_fork(); t_relay(); ... _________________________________________________________ 1.4.5. t_newtran() Creates a new transaction, returns a negative value on error. This is the only way a script can add a new transaction in an atomic way. Typically, it is used to deploy a UAS. Example 1-14. t_newtran usage ... if (t_newtran()) { log("UAS logic"); t_reply("999","hello"); } else sl_reply_error(); ... See test/uas.cfg for more examples. _________________________________________________________ 1.4.6. t_reply(code, reason_phrase) Sends a stateful reply after a transaction has been established. See t_newtran for usage. Meaning of the parameters is as follows: * code - Reply code number. * reason_phrase - Reason string. Example 1-15. t_reply usage ... t_reply("404", "Not found"); ... _________________________________________________________ 1.4.7. t_lookup_request() Checks if a transaction exists. Returns a positive value if so, negative otherwise. Most likely you will not want to use it, as a typical application of a looku-up is to introduce a new transaction if none was found. However this is safely (atomically) done using t_newtran. Example 1-16. t_lookup_request usage ... if (t_lookup_request()) { ... }; ... _________________________________________________________ 1.4.8. t_retransmit_reply() Retransmits a reply sent previously by UAS transaction. Example 1-17. t_retransmit_reply usage ... t_retransmit_reply(); ... _________________________________________________________ 1.4.9. t_release() Remove transaction from memory (it will be first put on a wait timer to absorb delayed messages). Example 1-18. t_release usage ... t_release(); ... _________________________________________________________ 1.4.10. t_forward_nonack(ip, port) mainly for internal usage--forward a non-ACK request statefully. Meaning of the parameters is as follows: * ip - IP address where the message should be sent. * port - Port number. Example 1-19. t_forward_nonack usage ... t_forward_nonack("", "5060"); ... _________________________________________________________ 1.4.11. External Usage of TM There are applications which would like to generate SIP transactions without too big involvement in SIP stack, transaction management, etc. An example of such an application is sending instant messages from a website. To address needs of such apps, SER accepts requests for new transactions via fifo pipes too. If you want to enable this feature, start FIFO server with configuration option. fifo="/tmp/ser_fifo" Then, an application can easily launch a new transaction by writing a transaction request to this named pipe. The request must follow very simple format, which is :t_uac_from:[<file_name>]\n <method>\n <sender's uri>\n <dst uri>\n <CR_separated_headers>\n <body>\n .\n \n (Filename is to where a report will be dumped. ser assumes /tmp as file's directory.) Note the the request write must be atomic, otherwise it might get intermixed with writes from other writers. You can easily use it via Unix command-line tools, see the following example: [jiri@bat jiri]$ cat > /tmp/ser_fifo :t_uac_from:xxx MESSAGE header:value foo:bar bznk:hjhjk p_header: p_value body body body yet body end of body . or cat test/transaction.fifo > /tmp/ser_fifo _________________________________________________________ 1.4.12. Known Issues * We don't have authentication merging on forking. * Local ACK/CANCELs copy'n'pastes Route and ignores deleted Routes. * 6xx should be delayed. * Possibly, performance could be improved by not parsing non-INVITEs, as they do not be replied with 100, and do not result in ACK/CANCELs, and other things which take parsing. However, we need to rethink whether we don't need parsed headers later for something else. Remember, when we now conserver a request in sh_mem, we can't apply any pkg_mem operations to it any more. (that might be redesigned too). * Another performance improvement may be achieved by not parsing CSeq in replies until reply branch matches branch of an INVITE/CANCEL in transaction table. * t_replicate should be done more cleanly--Vias, Routes, etc. should be removed from a message prior to replicating it (well, does not matter any longer so much as there is a new replication module). * SNMP support (as nobody cares about SNMP, in particular for TM, I will drop this item soon). _________________________________________________________ Chapter 2. Developer's Guide The module does not provide any sort of API to use in other SER modules. _________________________________________________________ 2.1. Defines * ACK_TAG enables stricter matching of acknowledgments including to-tags. Without it, to-tags are ignored. It is disabled by default for two reasons: + It eliminates an unlikely race condition in which transaction's to-tag is being rewritten by a 200 OK whereas an ACK is being looked up by to-tag. + It makes UACs happy who set wrong to-tags. It should not make a difference, as there may be only one negative reply sent upstream and 200/ACKs are not matched as they constitute another transaction. It will make no difference at all when the new magic cookie matching is enabled anyway. * CANCEL_TAG similarly enables strict matching of CANCELs including to-tags--act of mercy to UACs, who screw up the to-tags (however, it still depends on how forgiving the downstream UAS is). Like with ACK_TAG, all this complex transactions matching goes with RFC3261's magic cookie away anyway. _________________________________________________________ 2.2. Functions 2.2.1. register_tmcb(cb_type, cb_func) For programmatic use only--register a function to be called back on an event. See t_hooks.h for more details. Meaning of the parameters is as follows: * cb_type - Callback type. * cb_func - Callback function. _________________________________________________________ 2.2.2. load_tm(*import_structure) For programmatic use only--import exported TM functions. See the acc module for an example of use. Meaning of the parameters is as follows: * import_structure - Pointer to the import structure. _________________________________________________________ Chapter 3. Frequently Asked Questions 3.1. Where can I find more about SER? 3.2. Where can I post a question about this module? 3.3. How can I report a bug? 3.1. Where can I find more about SER? Take a look at 3.2. Where can I post a question about this module? First at all check if your question was already answered on one of our mailing lists: * * E-mails regarding any stable version should be sent to <> and e-mail regarding development versions or CVS snapshots should be send to <>. If you want to keep the mail private, send it to <>. 3.3. How can I report a bug? Please follow the guidelines provided at: