During inter-BSC incoming handover, there is no previous lchan to be
switched, so this event always comes in the READY state of
lchan_rtp_fsm. No need to complain about that and confuse log readers.
Related: SYS#5864
Change-Id: I96fd53b8c8da621a40bd65f85070eabd030cc875
lchan->activate.info.ch_mode_rate should remain unchanged, it is the
immutable request data. However, for VAMOS, we will want to
automatically see that the chan_mode is chosen correctly.
As a first step, place a mutable ch_mode_rate copy at
lchan->activate.ch_mode_rate, i.e. not in .activate.info, but in
.activate. Use that everywhere.
This is mostly a non-functional change, preparing for a subsequent patch
that adds handling of VAMOS shadow lchans.
As side effect of adding lchan_activate_set_ch_mode_rate_and_mr_config()
after MODE_MODIF_ACK (enabling the voice stream after a channel mode
modify), fix AMR config: the call to lchan_mr_config() was missing.
Change-Id: Icc9cc7481b3984fdca34eef49ea91ad3388c06fe
Both VAMOS- and non-VAMOS speech modes should result in indentical voice
handling. So make sure that all chan_modes are converted to non-vamos
before comparing / evaluating in switch statements.
Change-Id: I791e7966b1f8eaa3299a8a46abeb313cf5136e0b
I noticed during testing that an lchan used as TCH/F in fact still had
its channel mode set to Signalling -- because on Assignment, the Speech
mode used to be placed in the *previous* lchan and the new lchan was
never updated after the Activ ACK. This is unbearable confusion which I
complained about numerous times, so far mostly for cosmetic reasons. But
implementing re-assignment properly actually requires this to be cleaned
up.
Keep all volatile chan mode settings in lchan->activate.* or
lchan->modify.*, and only update lchan->* members when an ACK has been
received for those settings. So a failed request keeps a sane state.
Make sure that those settings are in fact updated in the proper lchan,
upon an ACK, so that subsequent re-assignment or mode-modify know the
accurate lchan state.
Related are upcoming patches that sort out the AMR multirate
configuration in a similar fashion, see
Iebac2dc26412d877e5364f90d6f2ed7a7952351e
Ia7519d2fa9e7f0b61b222d27d077bde4660c40b9
Ie57f9d0e3912632903d9740291225bfd1634ed47.
Related: SYS#5315 OS#4940 OS#3787 OS#3833
Change-Id: Ie0da36124d73efc28a8809b63d7c96e2167fc412
Change lchan_set_last_error() to macro so that the error log reflects
where the error was encountered.
Change-Id: I571fdf2d418c52d120215cf19e57a3c96d67af07
This is needed to be able to force MGW to provide an IPv4 address during
MDCX, since IPACC protocol on the BTS side only supports IPv4, but one
may need IPv6 side at the same time on the core side.
By moving the IPACC MDCX request to a later step, the BSC gains
knowledge of the local address on each side (BTS, MGW), and if they
don't match (ie. BTS uses IPv4 and MGW uses IPv6), it can then get MGW
to offer an IPv4 address during MGCP MDCX containing the BTS IPv4
address. At that point, the MGW can see the mismatch and provide an IPv4
address in the MGCP MDCX ACK, which can then finally be communicated to
the BTS during IPACC MDCX phase.
Previous order:
BSC -> MGW: CRCX
BSC <- MGW: CRCX ACK (get MGW local IP addr)
BSC -> BTS: IPACC CRCX
BSC <- BTS: IPACC CRCX ACK (get BTS local IP addr)
BSC -> BTS: IPACC MDCX (set MGW IP addr)
BSC <- BTS: IPACC MDCX ACK
BSC -> MGW: MDCX (set BTS IP addr)
BSC <- MGW: MDCX ACK
New order:
BSC -> MGW: CRCX
BSC <- MGW: CRCX ACK (get MGCP local IPv6 addr)
BSC -> BTS: IPACC CRCX
BSC <- BTS: IPACC CRCX ACK (get BTS local IPv4 addr)
BSC -> MGW: MDCX (set BTS IPv4 addr)
BSC <- MGW: MDCX ACK (here MGW changes its local addr to IPv4)
BSC -> BTS: IPACC MDCX (set MGW IPv4 addr)
BSC <- BTS: IPACC MDCX ACK
Change-Id: I4de5ea5c94c1482c9cb0b6386997a942edc60e32
IPACC protocol supports only IPv4 addresses, so make sure if an IPv6
address (or whatever malformed address) is caught is not sent without
noticing. Prior to this patch, faulty addresses would be sent over the
wire as 255.255.255.255 (-1 returned from inet_addr()).
Change-Id: Iee84e8b40cdede1cacd8e8a9e26dda0d85383ec8
When the BTS is is not an ipaccess BTS, the BTS can only be an E1 bts.
In that case E1 endpoints must be used and there will be no RTP stream
setup towards the BTS.
Change-Id: I4f1f39bf90b0a7c9ea448dab255daf99cd36bb4a
Related: OS#2547
The functions lchan_rtp_fsm_timer_cb() and lchan_rtp_fsm_cleanup() only
used in lchan_rtp_fsm.c, lets make them static.
Change-Id: I31940aff166ccd7a9612574536674e4e483a3cb9
Place all code related to the object into the related file.
Having all the data model in one file made sense in early stage of
development to make progress quickly, but nowadays it hurts more than
helps, due to constantly growing size and more and more bits being
added to the model, gaining in complexity.
Currently, having lots of different objects mixed up in gsm_data.h is a hole
of despair, where nobody can make any sense were to properly put new stuff
in, ending up with functions related to same object in different files
or with wrong prefixes, declarations of non-existing functions, etc.
because people cannot make up their mind on strict relation to objects
in the data model.
Splitting them in files really helps finding code operating on a
specific object and helping with logically splitting in the future.
Change-Id: I00c15f5285b5c1a0109279b7ab192d5467a04ece
In the state LCHAN_RTP_ST_WAIT_MGW_ENDPOINT_CONFIGURED, the event
LCHAN_RTP_EV_ROLLBACK is allowed and also handled in the action
callback, which causes a change to LCHAN_RTP_ST_ROLLBACK. However,
LCHAN_RTP_ST_ROLLBACK is missing from the out_state_mask.
Change-Id: Ifca3892901c8389beee6e4f0fea03c33cfbdc265
Make various internally used timers negative, to indicate that they are
Osmocom specific. A follow-up patch will make them configurable.
Change-Id: I6f8be40ea54a3083f4b21ab938cc1723fc67c2ef
osmo-mgw.git also includes fixes of the MGW endpoint FSM, for example
I92a9944acc96398acd6649f9c3c5badec5dd6dcc.
Depends: I9a3effd38e72841529df6c135c077116981dea36 (osmo-mgw)
Change-Id: I03e6b48d9b0a5370310d5f56809259ff7909cf9d
Move the T_defs API to libosmocore as osmo_tdefs: remove the local T_defs API
and use libosmocore's osmo_tdef* API instead.
The root reason is moving the mgw_endpoint_fsm to libosmo-mgcp-client to be
able to use it in osmo-msc for inter-MSC handover.
When adding osmo_tdef, the new concept of timer groups was added to the API. It
would make sense to apply group names here as well, but do not modify the VTY
configuration for timers. The future might bring separate groups (or not).
Depends: Ibd6b1ed7f1bd6e1f2e0fde53352055a4468f23e5 (libosmocore)
Change-Id: I66674a5d8403d820038762888c846bae10ceac58
Previously LCHAN_RTP_EV_IPACC_MDCX_ACK was not permitted for
LCHAN_RTP_ST_ESTABLISHED state in lchan FSM. However this message is
normal in case of LCLS loop closed via IPA (as opposed to MGCP). Let's
permit this message and log it to make debug output easier to read.
Change-Id: Ib642df799f3405c4d707eb57b2ebc84386d7f03f
Related: OS#2487
Fix crash after AMR configuration fails.
The crash is due to an assertion that finds a non-NULL conn in the lchan, when
re-using an lchan that has failed in AMR configuration earlier on. That is
because the AMR config still happens in state UNUSED.
DCHAN ERROR lchan(0-0-2-TCH_F_TCH_H_PDCH-0)[0x6120000066a0]{UNUSED}: (type=TCH_F) lchan allocation failed in state UNUSED: Can not generate multirate configuration IE
...
DCHAN DEBUG lchan(0-0-2-TCH_F_TCH_H_PDCH-0)[0x6120000066a0]{UNUSED}: (type=TCH_F) After failure handling, already in state UNUSED
...
...
DCHAN DEBUG lchan(0-0-2-TCH_F_TCH_H_PDCH-0)[0x6120000066a0]{UNUSED}: Received Event LCHAN_EV_ACTIVATE (lchan_fsm.c:324)
Assert failed !lchan->conn ../../../../src/osmo-bsc/src/osmo-bsc/lchan_fsm.c:491
The FSM design idea is that when returning to the UNUSED state, all lchan state
is cleared. However, when calling lchan_activate(), a failure may happen still
in state UNUSED, so that we don't transition *back* to UNUSED properly.
So, first transition out of UNUSED before failures can happen. (Other ways to
solve this would be to invoke lchan clearing even if already in UNUSED, but
semantically, transitioning first makes more sense.)
Upon LCHAN_EV_ACTIVATE, just remember the lchan_activate_info and transition to
WAIT_TS_READY, so that on lchan_fail(), we can normally transition back to
UNUSED and clear the lchan.
Move the initial lchan activation code to lchan_fsm_wait_ts_ready_onenter().
Also, there is a bit of duplication of members of the lchan->activate (lchan
state) and the lchan_activate_info (passed to lchan_activate()) structs. The
fix for this also removes the dup:
Add struct lchan_activate_info as child struct at lchan->activate.info, drop
the other lchan->activate members that would dup .info.*. Move struct
lchan_activate_info declaration to gsm_data.h.
Apply the new '.info' member struct throughout the code.
Related: OS#3737
Change-Id: Ide665b10fa3f4583059c55346db8da833959e3cc
When lchan_rtp_fsm instance is allcoated with
osmo_fsm_inst_alloc_child(..., LCHAN_EV_RTP_RELEASED) we already let fsm
code to take care of sending that event ito the parent when the fsm is
terminated (but only if freeing cause is not OSMO_FSM_TERM_PARENT).
The lchan_rtp_fsm cleanup() callback, which is called immediatelly before
sending to the parent the event defined during osmo_gsm_install_alloc_child(),
currently also sends that same event, which ends up in a duplicated
event being sent as shown in log files below.
Let's only send the event in cleanup() if we are in the
cause=OSMO_FSM_TERM_PARENT scenario, to make sure parent always receives the
event, but only once.
20181128193707326 DAS osmo-bsc/assignment_fsm.c:127 assignment(conn4_0-0-6-TCH_F_PDCHasPDCH-0)[0x6120000024a0]{WAIT_LCHAN_ACTIVE}: (bts=0,trx=0,ts=6,ss=0) Assignment failed
20181128193707326 DAS osmo-bsc/assignment_fsm.c:128 assignment(conn4_0-0-6-TCH_F_PDCHasPDCH-0)[0x6120000024a0]{WAIT_LCHAN_ACTIVE}: Terminating (cause = OSMO_FSM_TERM_ERROR)
20181128193707326 DAS osmo-bsc/assignment_fsm.c:128 assignment(conn4_0-0-6-TCH_F_PDCHasPDCH-0)[0x6120000024a0]{WAIT_LCHAN_ACTIVE}: Removing from parent SUBSCR_CONN(conn4)[0x612000002920]
20181128193707326 DCHAN osmo-bsc/lchan_fsm.c:1333 lchan_rtp(0-0-6-TCH_F_PDCH-0)[0x612000002320]{WAIT_MGW_ENDPOINT_AVAILABLE}: Received Event LCHAN_RTP_EV_ROLLBACK
20181128193707326 DCHAN osmo-bsc/lchan_rtp_fsm.c:193 lchan_rtp(0-0-6-TCH_F_PDCH-0)[0x612000002320]{WAIT_MGW_ENDPOINT_AVAILABLE}: Terminating (cause = OSMO_FSM_TERM_REQUEST)
20181128193707326 DCHAN osmo-bsc/lchan_rtp_fsm.c:193 lchan_rtp(0-0-6-TCH_F_PDCH-0)[0x612000002320]{WAIT_MGW_ENDPOINT_AVAILABLE}: Removing from parent lchan(0-0-6-TCH_F_PDCH-0)[0x6120000039a0]
20181128193707326 DRSL osmo-bsc/mgw_endpoint_fsm.c:441 mgw-endpoint(conn4)[0x6120000021a0]{WAIT_MGW_RESPONSE}: (rtpbridge/*@mgw) CI[0] to-BTS: DLCX :0: notify=NULL
20181128193707326 DRSL osmo-bsc/mgw_endpoint_fsm.c:482 mgw-endpoint(conn4)[0x6120000021a0]{WAIT_MGW_RESPONSE}: (rtpbridge/*@mgw) CI[0] to-BTS: DLCX :0: Scheduling
20181128193707326 DCHAN osmo-bsc/lchan_rtp_fsm.c:742 lchan(0-0-6-TCH_F_PDCH-0)[0x6120000039a0]{WAIT_TS_READY}: Received Event LCHAN_EV_RTP_RELEASED
20181128193707326 DCHAN osmo-bsc/lchan_rtp_fsm.c:193 lchan_rtp(0-0-6-TCH_F_PDCH-0)[0x612000002320]{WAIT_MGW_ENDPOINT_AVAILABLE}: Freeing instance
20181128193707327 DCHAN fsm.c:381 lchan_rtp(0-0-6-TCH_F_PDCH-0)[0x612000002320]{WAIT_MGW_ENDPOINT_AVAILABLE}: Deallocated
20181128193707327 DCHAN osmo-bsc/lchan_rtp_fsm.c:193 lchan(0-0-6-TCH_F_PDCH-0)[0x6120000039a0]{WAIT_TS_READY}: Received Event LCHAN_EV_RTP_RELEASED
20181128193707330 DCHAN osmo-bsc/lchan_fsm.c:1347 lchan(0-0-6-TCH_F_PDCH-0)[0x6120000039a0]{WAIT_TS_READY}: transition to state WAIT_RLL_RTP_RELEASED not permitted!
20181128193707330 DAS osmo-bsc/assignment_fsm.c:128 assignment(conn4_0-0-6-TCH_F_PDCHasPDCH-0)[0x6120000024a0]{WAIT_LCHAN_ACTIVE}: Freeing instance
20181128193707330 DAS fsm.c:381 assignment(conn4_0-0-6-TCH_F_PDCHasPDCH-0)[0x6120000024a0]{WAIT_LCHAN_ACTIVE}: Deallocated
Change-Id: I3e95a21e5a5ec6c35b1ab20b7a642fd7eb81e556
Put all lchan release related flags and settings in a sub-struct named
'release' to better indicate what those fields are for. There is no functional
change.
Change-Id: Icfddc6010e5d7c309f1a7ed3526b5b635ffeaf11
Use libosmo-mgcp-client's new X-Osmo-IGN header to indicate that CallIDs are
allowed to mismatch.
Add VTY commands 'msc' / 'mgw x-osmo-ign call-id' and 'no mgw x-osmo-ign' to
switch this behavior explicitly.
For SCCPlite MSCs, unless a specific config was issued, always send
'X-Osmo-IGN: C' by default, to ignore CallID mismatches.
Depends: Id7ae275ffde8ea9389270cfe3db087ee8db00b51 (osmo-mgw)
Change-Id: I257ad574d8060fef19afce9798bd8a5a7f8c99fe
Release and Rollback events are allowed but unhandled in states
WAIT_MGW_CONFIGURED and ROLLBACK, and hence would result in an assertion. Add
handling in these states.
Change-Id: Iab233c592384902098644eee27bb8445fde3aa6f
In cases where a codec has no fixed (IANA) payload type number, a
dynamically coosen payload type number is used. For the route between
BSC and MSC 3GPP as designated certain payload type numbers. However,
beond that, those payload type numbers may not necessarly apply. The
RTP communication between BTS and BSC still might run on a completely
different payload type number.
libosmo-netif contains a header file which payload type numbers
shall be used. Lets use those in order to signal the same payload type
numbers as we actually use in the RTP packets to the MGW.
Change-Id: I507a1b1446c8f140b2950d73cf737797604c1ac3
Related: OS#2728
Related: OS#3384