This way, we don't open a socket and do the IPA handshake in the event
the request is already cached.
Related: SYS#4909
Change-Id: Ib1ea85e1196c8b9dc40c8837ab5d4a54f2a1f2d4
Older versions of osmo_ctrl_conn_alloc() may not properly initialize
write_queue.bfd.fd to -1, which means if osmo_sock_init2_ofd() failed
during nacc_fsm_alloc(), the destructor would wrongly enter the conditon
where the whole structure is set and unregister the unregistered fd.
Related: libosmocore Change-Id I98f744d2880fbb883719cdf1d3eb31f2b22a13b6
Related: SYS#4909
Change-Id: I253bd9087b1f7ab039aa1127e9dc586f5106905a
A new nacc_fsm is introduced per MS object, with its partner priv
structure struct nacc_fsm_ctx, which exists and is available in the MS
object only during the duration of the NACC procedure.
The NACC context is created on an MS whenever a Pkt Cell Change
Notification is received on Uplink RLCMAC, which asks for neighbor
information of a given ARFCN+BSIC.
First, the target ARFCN+BSIC needs to be translated into a CGI-PS
(RAC+CI) address. That's done by asking the BSC through the Neighbour
Resolution Service available in osmo-bsc using the CTRL interface.
Once the CGI-PS of the target cell is known, PCU starts a RIM RAN-INFO
request against the SGSN (which will route the request as needed), and
wait for a response containing the SI bits from the target cell.
After the SI are received, the scheduler is instructed to eventually
poll a TBF for the MS originating the CCN, so that we can send the SI
encapsulated into multiple Packet Neighbor Cell Data messages on the
downlink.
One all the SI bits are sent, the scheduler is instructed to send a
Packet Cell Change Continue message.
Once the message above has been sent, the FSM autodestroys itself.
Caches are also introduced in this patch which allows for re-using
recently known translations ARFCN+BSIC -> CGI-PS and CGI-PS -> SI_INFO
respectively.
Change-Id: Id35f40d05f3e081f32fddbf1fa34cb338db452ca
This also changes the vty configuration. If only timeout has been
configured for ns the new configuration is compatible.
For further information see:
https://osmocom.org/projects/libosmocore/wiki/Network_service_(NS)
Depends-on: I8c3f2afecc74b78f7f914f7dce166cbcb63444eb (libosmocore)
Change-Id: I14af821a8d1fda670643c3d5f81299a3abf3c583
All gprs_ns2 enums have now GPRS_NS2 as prefix.
Depends-on: I548ff12f7277cbb7e1a630a3dc02b738ce89be72 (libosmocore)
Change-Id: Ifdc7956318c07d680feab33c22bc2c6f20927bf9
Sine we don't yet implement properly all resegmentation of blocks from
same MCS family type, when requiring a GMSK DL block (due to GPRS+EGPRS
multiplexing limitations) we need to skip retransmitions, otherwise we'd
be incorrectly picking a DL block which was already built with a
potentially higher MCS value.
The "DL_PRIO_NEW_DATA" prio serves two purposes:
* There's new data to send
* There's some nacked data to be retransmitted
The 2nd purpose has, later on, more priority over the 1st one when the tbf
is selected (see gprs_rlcmac_dl_tbf::take_next_bsn()).
Until now we were handling correctly the case where the tbf was skipped
in case the prio was to resend unacked data (DL_PRIO_SENT_DATA), but
was incorrectly selected when it'd send nacked data. Let's fix it by
specifically checking w->resend_needed() < 0.
Change-Id: I253de8e1a190a9adb56160f38892c9e43e2c0272
Under some circumstances, it could happen that a DL TBF is created as a
GPRS TBF due to not yet having enough information of the MS, and only
after the TBF is created the PCU gains that information and upgrades the
MS mode to "EGPRS". Hence, there's the possibility to run into a
situation where a GPRS TBF is attached to a EGPRS MS.
It may also happen sometimes that despite the TBF and the MS be EGPRS,
there's need to further limit the DL MCS to use, eg. MCS1-4 (GMSK).
As a result, when asking for the current DL (M)CS to use, we must tell
the MS which kind of limitations we want to apply. The later reasoning
was already implemented when GPRS+EGPRS multiplexing was added, but the
former was not being checked. Hence, by further spreading through the
call stack the "req_kind_mode" we match both cases.
Related: OS#4973
Change-Id: Ic0276ce045660713129f0c72f1158a3321c5977f
The TBF can sometimes be detached from an MS, for eg. when switching
from one MS object to another due to them being merged after we found
duplicate objects upon receiving new information from it, but that
change is instantaneous so it shouldn't be a problem. The only other way
where an MS can be detached from an MS is during the end of its (or the
MS) life, where it is not sending data anymore.
Hence, it is safe to drop those checks for MS not being null. Those
being trigger, it should be considered a bug.
Change-Id: If292a53a09a64664031e756bff4735b9c6ee8651
It could happen as of current implementation that a TBF was created as
GPRS due to the MS being non-egprs, and later on the MS was upgraded to
EGPRS due to newly received information from the MS.
Hence, in order to infer if the data block is EGPRS or GPRS, let's
better check for the TBF info, which is the one really mandating the
kind of dl block to generate.
Change-Id: I49720fb3a69ca972cd1973de937ac8ee77615431
MS is always assigned to a BTS, since it's set during MS constructor.
Hence, the check removed in this patch would never hold true (and if it
did, it'd be a bug).
Change-Id: I86a71c64623f7bec031226938a54306148370ffb
it was noticed that gprs_pcu_get_bts_by_cgi_ps() sometimes failed to
return the BTS even if the CGI-PS fields matched, probably due to memcmp
checking too padding bytes which may not be zero-initialized in one of
the two memory regions being checked. Let's be on the safe side and use
libosmocore APIs to check them.
Depends: libosmocore.git Change-Id I00e329bc5be8674b30267dec238e7656ddfc21db
Change-Id: I7c8ee2c447634e45b367bb8f84adf0140ae48591
This code doesn't do anything yet app-related with the received RIM
messages, but already provides the initial infrastructure to handle them
in the future, and does first checkings.
Related: SYS#5103
Change-Id: Ia0ade0e97ea781ec655439c008b6cefaf3e90dec
This patch doesn't really tests whether osmo-pcu can work on a multi-bts
environment, but it prepares the data structures to be able to do so at
any later point in time.
Change-Id: I6b10913f46c19d438c4e250a436a7446694b725a
There's no real point in using C++ there, and using C++ makes the
compiler fail to use llist_head in multi-bts patches added later due to:
"""
'offsetof' within non-standard-layout type is conditionally-supported
"""
Change-Id: I8965b5cc5a713e64788b5b6aa183d3035341ddbb
There's no real use of C++ in that file, and it causes problems when
using llist_head entry macros in future patches adding initial support
for multiple BTS in PCU object, so let's move it to plain C.
Change-Id: Ic771a89fd78b5e66151a5384f0ff6a8895589466
Those files are not really being used other than for calling
get_current_fn() which is just a placeholder to call
bts_current_frame_number on the global bts object.
Change-Id: I6d50a8c15c1de5e2a308a24b313a7776f94ae54f
The bts_init/cleanup functions were kept during the C and C++ structure
merge process to make the patch simpler. It's not needed anymore,
let's move all the destructor logic into one function and keep that
together.
Change-Id: I73a9457d5c92f62261561ef6afe392953576aec4
Before, we used tho have a BTs object split into 2 parts, a C
gprs_rlcmac_bts struct and a C++ BTS struct, and "bts_data" naming was
used to distinguish them in variable names. Nowadays the struct is
finally combined into one, so there's no point in using this "bts_data"
terminology, we use always "bts".
Change-Id: I9852bf439292d1abc70711bea65698b21bde0ee8
There's no BTS single global object anymore, get rid of those APIs. Move
users to use "pcu->bts", which will evolve to a linked list in the
future.
Change-Id: I9cf762b0d3cb9e2cc3582727e07fa82c8e183ec5
Previous work on BTS class started to get stuff out of the C++ struct
into a C struct (BTS -> struct gprs_glcmac_bts) so that some parts of
it were accessible from C code. Doing so, however, ended up being messy
too, since all code needs to be switching from one object to another,
which actually refer to the same logical component.
Let's instead rejoin the structures and make sure the struct is
accessible and usable from both C and C++ code by rewriting all methods
to be C compatible and converting 3 allocated suboject as pointers.
This way BTS can internally still use those C++ objects while providing
a clean APi to both C and C++ code.
Change-Id: I7d12c896c5ded659ca9d3bff4cf3a3fc857db9dd
Both values (optionally) set (forced) by VTY and the values received
from PCUIF were stored in the same variable, meaning that for instance
the PCUIF values wouldn't really be used if someone applied eg "no cs"
during runtime.
This commit does something similar to what was already done for the
max_(m)cs fields. We store PCUIF values in one place and VTY ones in
another place, and then trigger a bts object internal process to find
out exactly which initial CS should it be using.
Change-Id: I80a6ba401f9c0c85bdf6e0cc99a9d2008d31e1b0
Currently the BTS object (and gprs_rlcmac_bts struct) are used to hold
both PCU global fields and BTS specific fields, all mangled together.
The BTS is even accessed in lots of places by means of a singleton.
This patch introduces a new struct gprs_pcu object aimed at holding all
global state, and several fields are already moved from BTS to it. The
new object can be accessed as global variable "the_pcu", reusing and
including an already exisitng "the_pcu" global variable only used for
bssgp related purposes so far.
This is only a first step towards having a complete split global pcu and
BTS, some fields are still kept in BTS and will be moved over follow-up
smaller patches in the future (since this patch is already quite big).
So far, the code still only supports one BTS, which can be accessed
using the_pcu->bts. In the future that field will be replaced with a
list, and the BTS singletons will be removed.
The cur_fn output changes in TbfTest are actually a side effect fix,
since the singleton main_bts() now points internally to the_pcu->bts,
hence the same we allocate and assign in the test. Beforehand, "the_bts"
was allocated in the stack while main_bts() still returned an unrelated
singleton BTS object instance.
Related: OS#4935
Change-Id: I88e3c6471b80245ce3798223f1a61190f14aa840
When allocating multiple slots for a UE the following example
is not allowed 'UU----UU' for a UE class 12.
The time slot number can not roll over 7 and move to 0.
44.060 or 45.002 only specifies contigous however it was unclear
it this is an allowed pattern.
Only the example 45.002 B.3 in release 12 cleared this up.
It gives an example for a multi slot class 5 UE which has 7 possible
configuration this means the rolled over is not allowed.
Multislot class type 2 UE doesn't have this limitation.
Further if a UE supports 8 time slots this is not a limitation because
the window size (45.002 B.1) can include all time slots.
Releated: SYS#5073
Change-Id: I16019bdbe741b37b83b62749b840a3b7f4ddc6c7
Under some platforms (RPI4, ARM) container older ASan, it will log false
positive log errors which will make unit test fail because then output
changes:
"""
pcu_l1_if.cpp:847:2: runtime error: member access within misaligned address 0xb3f0b78c for type 'struct GprsMs', which requires 8 byte alignment
"""
The pointer is indeed misaligned, but it's not actually a bug, because
the pointer is never derreferenced. That happens during
llist_for_each_entry operation where it does cast the pointer but it
only checks if the list has actually reached the end.
To workaround the issue, simply defer casting it by using llist_for_each
instead, where the pointer is assigned only in the case it really points
to a GprsMS struct.
Change-Id: I149fb42706501eb33f9c6fe48f76a03ddee5954a
Unfortunately, RACH.ind on the PCU interface contains no Uplink
measurements: neiter RSSI nor C/I. In order to avoid sending
garbage, let's zero-initialize 'struct pcu_l1_meas'.
Change-Id: I8c3210c428da17d23d798f3ef9df941ded6e162a
Fixes: CID#216512