Let's disable category here since we don't care about its formatting here.
In any case, every test relying on logging output validation should
always explicitly state the config to avoid issues in the future if
default values change.
Change-Id: I7f9c56313cfaa74ebe666f44763a83d8102f5484
Related: OS#5034
All vectors should be valid, since they were generated by an MS.
As can be seen, osmo-pcu fails to decode one of the vectors.
Change-Id: I37a2ddd394eeffa1cae0f3e419eeee0200a57fcf
OS#4955
Change-Id: Ib5677048f5668185ffe752f97c97d5612eee4d72
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
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
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
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
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
When both TBFs (Dl, Ul), are detached, ms_detach_tbf() will call
ms_start_timer() which will hold a reference of the MS (ms_ref()) and
wait for X seconds (VTY config, T=-2030, 60 seconds by default) before
unrefing the MS, which will trigger ms_update_status() finally (ref==0)
and will in turn call cb.ms_idle(), which will tell the ms_storage to
free the MS.
This mechanism is used to keep MS objects around for a certain time so
that when new TBFs are established, we have cached interesting
information about the MS, ready to use.
However, in AllocTest, tons of MS are allocated in a loop calling a
function (such as test_alloc_b_ul_dl()). In that function, a BTS is
allocated in the stack and at the end of the function BTS::cleanup() is
called due to implicit destructor, which ends up calling
ms_storage::cleanup() which removes all MS from its list and frees them
*if they are not idle*. The problem here, is that due to T=-2030, an
extra reference is hold and hence the ms is not considered idle
(ms_is_idle() checks ms->ref==0). As a result, the MS is never freed,
because we don't use libosmocore mainloop here (and in any case, it
would take 60 seconds to free it).
By setting the timeout of T=-2030 to 0, ms_start_timer will avoid using
the timer and will also avoid holding the extra reference, hence
allowing ms_storage to free the object during cleanup().
This fix really helps in improving performance for AllocTest specially
after MS object contains a rate_ctr. As tons of MS objects were left
alive, they stood in the rate_ctr single per-process queue, making the
test last crazy amount of time and spending 50% of the time or more
iterating the list full of MS related rate counters.
Change-Id: I6b6ebe8903e4fe76da5e09b02b6ef28542007b6c
It is expected that the tbf object is freed at any moment in time, for
instance if osmo-pcu drops PCUIF connection with osmo-bts. I couldn't
find any reason why it would e dangerous to free the tbf, so let's
remove this message.
related: OS#4779
Change-Id: I4ab5ccaa5bf6257b18d8fd5ba06baab083821817
As we integrate osmo-pcu more and more with libosmocore features, it
becomes really hard to use them since libosmocore relies heavily on C
specific compilation features, which are not available in old C++
compilers (such as designated initializers for complex types in FSMs).
GprsMs is right now a quite simple object since initial design of
osmo-pcu made it optional and most of the logic was placed and stored
duplicated in TBF objects. However, that's changing as we introduce more
features, with the GprsMS class getting more weight. Hence, let's move
it now to be a C struct in order to be able to easily use libosmocore
features there, such as FSMs.
Some helper classes which GprsMs uses are also mostly move to C since
they are mostly structs with methods, so there's no point in having
duplicated APIs for C++ and C for such simple cases.
For some more complex classes, like (ul_,dl_)tbf, C API bindings are
added where needed so that GprsMs can use functionalitites from that
class. Most of those APIs can be kept afterwards and drop the C++ ones
since they provide no benefit in general.
Change-Id: I0b50e3367aaad9dcada76da97b438e452c8b230c
According to:
* 3GPP TS 44.060 version 16.0.0 "9.3.1a Delayed release of downlink Temporary Block Flow"
* 3GPP TS 44.064 version 16.0.0 "6.4.2.2 Unconfirmed Information (UI) Dummy command"
LLC UI Dummy frames are to be used when there no more data to send, only
in order to delay the release of a TBF. Hence, while not incorrect per
se, makes no sense to send those LLC UI Dummy frames inserted into
rlcmac blocks which already contain other LLC frames, since the MS in
that case is already being kept active.
It only makes sense to send those LLC UI Dummy frames when we have
nothing else to send, that is, alone inside a RLCMAC block without other
LLC frames.
Related: OS#4849
Change-Id: Ifae1a7b2b3dfad8df19585063088ba0df2749c8f
In previous status, if USF for GPRS-only MS was selected, then EGPRS
TBFs were skipped and either a GPRS TBF was selected or a Dummy Block
was sent. That means the behavior was unfair towards EGPRS TBFs, because
sometimes they were skipped in favor of GPRS ones.
This patch imporves the situation in the above mentioned USF scenario, by
first, under specific conditions, allowing selection of an EGPRS TBF and
then forcing it to transmit in EGPRS-GMSK (MCS1-4) so that the
USF-targeted MS can still decode the USF, while at the same time
providing more fairness by allowing the EGPRS TBF to transmit data.
The specific conditions mentioned above are, mainly, related to the fact
that once a DL data block has been sent, and hence a BSN was assigned to
it, it cannot be retransmitted later using another MCS, since lower
MCS1-4 wouldn't be able to contain higher MCS RLC payload.
The set of conditions could be expanded in the future by also selecting
the EGPRS TBF if retransmition is required and the block to be
retransmitted was originally transmitted as MCS1-4.
Related: OS#4544
Change-Id: I9af23e175435fe9ae7b0e4119ad52fcd4707b9ca
There's actually 3 errors:
* Its value should be updated, not the pointer itself
* Value should be increased, not decreased
* bitvec_read_field() API is already advancing it, no need to do it
Fixes: OS#4838
Change-Id: I009abc373794e148091e637ffee80c6461960945
The assumption that TLLI 0x00000000 is invalid and can be used
as the initializer is wrong. Similar to TMSI, 0x00000000 is a
perfectly valid value, while 0xffffffff is reserved - use it.
According to 3GPP TS 23.003, section 2.4, a TMSI/P-TMSI with
all 32 bits equal to 1 is special and shall not be allocated by
the network. The reason is that it must be stored on the SIM,
where 'ff'O represents the erased state. According to section
2.6 of the same document, a local/foreign TLLI is derived from
P-TMSI, so the same rule applies to TLLI.
I manually checked and corrected all occurances of 'tlli' in the
code. The test expectations have been adjusted with this command:
$ find tests/ -name "*.err" | xargs sed -i "s/0x00000000/0xffffffff/g"
so there should be no behavior change. The only exception is
the 'TypesTest', where TLLI 0xffffffff is being encoded and
expected in the hexdump, so I regenerated the test output.
Change-Id: Ie89fab75ecc1d8b5e238d3ff214ea7ac830b68b5
Related: OS#4844
BTS simply notifies the PCU about the supported MCS, and PCU is
responsible for providing correct data formatting supported for the BTS
and the target MS.
Related: OS#4544
Change-Id: Ifcf23771bd23afc64ca6fea38948f98f2d134ecb
For instance if PCU received DL data to be sent to an MS from an SGSN,
and the MS is not currently cached in the PCU (because there's no TBF
active for it), it will page it and transmit the DL data to it.
The SGSN is capable of sending (EGPRS) MS Class information in that same
DL data message, so it's the one responsible for providing that
information if not available at the PCU.
In the PCU if we don't have information about that MS and SGSN didn't
provide us information about it, we cannot assume the MS is going to be
EGPRS capable and even less expecting a specific EGPRS MS class.
So let's drop this code.
Related: OS#4544
Change-Id: Icce66cadb51af25ae0c3b3719940eccb548fe33b
Some tests were wrong (TypesTest) and required modification, since they
were setting a EGPRS MS but then expecting a GPRS assignment.
Change-Id: I9d3ee21c765054a36bd22352e48bde5ffca9225a
Take into account the MCS values supported by the BTS. In osmo-bts,
in general all MCS are enabled if "mode egprs" is selected in BSC,
and none otherwise.
Change-Id: Ie8f0215ba17da1e545e98bec9325c02f1e8efaea
This way everytime any program or test initiates a BTS object, the
bts_data structure has the same values.
Change-Id: Iffd6eecb1f08bda0091f45e2ef7c9c63b42e10b3
If SGSN provides us with MS class information upon DL data, let's use it
and set it in an already existing MS object if not yet known.
Also remove all unneeded code passing ms_class to append_data() which
would simply try to (again) set the ms_class.
Change-Id: I4979c9344bffd3ba7657bbab94981d233eab801f
Before this patch, it would always allocate all TBFs on the first TRX
until all TFIs were filled, then second, and so on. But it would
actually fail around 8th MS requesting an UL TBF because despite a TFI
was successfuly assigned, because all USFs were already exhausted for
that PDCH.
Related: OS#1775
Change-Id: Iccfc8acfbfdc258ed16cc5af01f12b376fe73b72
Avoid passing tons of params to internal helper function
tbf_nel_dl_assignment() in order to either fetch again the ms object or
create a new one. Let's instead create the ms function earlier if needed
and fill it with all the discovered information prior to calling the
helper function. This provides cleaner code and also better log output.
This way we also avoid trying to fill the MS twice and unneeded
getter+setter for TA.
tbf::imsi(): There' always an ms, so simply forward call to
ms()->imsi().
We can also get rid of assign_imsi, since the modified code is the only
place where it's used and there's already some code in place there to
update the MS. We instead merge it with set_imsi and keep the
duplication code to catch possible bugs from callers.
Move merge_and_clear_ms from tbf class to GprsMS, where it really
belongs.
Change-Id: Id18098bac3cff26fc4a8d2f419e21641a1f4c83b
The BTS field will be used in code paths after next patch changes,
otherwise the test fails accessing the NULL pointer.
Change-Id: I5098292bdafa9f4f70fef1a053b80a33deca722c
This is another step forward towards a more clear data model where a TBF
always has a MS object (which may be lacking some information, and at a
later point when more information is found, it may actually be a
duplicated MS object and hence one duplicate removed and the TBF moved
to the object being kept).
This helps for instance in removing duplicated information stored in
the TBF which is really per MS, like ms_class, ta, etc. Since there's
always a MS object there's no need to keep a duplicate in both classes
in case there's no MS object.
It can already be seen looking at unit test logging that this kind of
data model already provides better information.
Some unit test parts were needed to adapt to the new model too.
Change-Id: I3cdf4d53e222777d5a2bf4c5aad3a7414105f14c
Return an interface to the window base class so that the tbf base class
can access the common window methods, such as set_ws(). It will be used
in next commit to get rid of duplicated function enable_egprs in both
dl_tbf and ul_tbf subclasses.
The user of the function can then decide to access more specific
functionaltiites of the window class by static casting it to the
specific direction (which is known by the caller since it operates on a
ul_tbf or a dl_tbf).
Change-Id: Ia2e1decf91be1184668e28297c2126affb9c7ae4
In those cases since a string pointer was passed, it always printed
"single" instead of whatever really was being used, since the string
pointer was not NULL.
Change-Id: Idab7d18e8f519e10fc3df4007634661c46f9256d
In general we want to see explicitly the kind of requested allocation at
the start. The MS class is not needed since it's printed in the previous
log line in any case.
Change-Id: I9eb0a592c15be96da9d140ff373c1afead76b18c
Add support of the second NSVC in the info indication.
Add support to update a previous NS configuration.
Allow to update of a NS-VC while the NSE is still available over the
second.
Depends-on: I917f25ebd1239eae5855d973ced15b93731e33a0 (libosmocore)
Depends-on: I3a0cd305fd73b3cb9ec70246ec15ac70b83e57f2 (libosmocore)
Depends-on: I5a2bb95d05d06d909347e2fb084a446ead888cb3 (libosmocore)
Depends-on: I54f110acc3acccb362f6e554324d08cc42b7c328 (libosmocore)
Depends-on: Ia00753a64b7622a0864341f51ea49b6963543755 (libosmocore)
Depends-on: Ic8f6f8aca10da23a18fab8870be7806065a34b47 (libosmocore)
Depends-on: I5f67e6a9bf4cb322bd169061fee0a528012ed54d (libosmocore)
Change-Id: I589ebaa2a2b7de55b7e4e975d8fd6412dd5f214b
Output of all diag in different lines is really confusing, since the
user reads a timeout ocurred and then later in another line something
like "Downlink ACK was received" while no GSMTAP message shows any ACK.
Change-Id: I6a7d79c16c930f0712bc73b308409ececb1946ba