CI: remove cppcheck, cleanup in build and license checks
Remove cppcheck. For those who want to use it, it's now in tools/cppcheck/,
and likely easier to use locally.
Clean up some code for CI build and license check. Remove global variable.
We don't enforce cppcheck through the CI, although it's there since
years. It runs on Ubuntu 18/20, so it's old. For folks, it's likely not
discoverable on how to run it locally. Let's make a fresh start.
This removes cppcheck from all CI-related code. Instead, it adds it
under tools/cppcheck/, including documentation on how to run it locally,
bare-matel or in docker.
Signed-off-by: Robert Schmidt <robert.schmidt@openairinterface.org>
Miscellaneous code improvements
- A fix in a yaml config file as reported by @Abdo-Gaber
- proper positioning of static functions in a couple of gNB scheduler
files
- some effort to split NR from LTE code in compilation
- harmonization of macros for unused variables
Add SIB 3,4 support, configurable SIB2 and refactor CU/DU SIB management
This MR makes neighbour and inter-frequency configuration drive how
SIB2/SIB3/SIB4 are built and sent from CU to DUs. It standardizes SIB
payloads as byte_array_t with typed SIB IDs across RRC, F1AP and MAC,
reducing ad‑hoc buffer handling. Neighbour parsing, validation and
lookup are tightened.
Changes
- Minor refactor to gNB neighbour parsing and storage (shared PLMN
extraction, safer allocation, etc).
- Represent SIB containers uniformly as byte_array_t plus nr_sib_type_t,
and adapt F1AP, MAC and RRC users to the new container API.
- Make SIB2 cell-reselection information fully config-driven with
explicit bounds checking and SIB2 ASN.1 building from that config.
- Generate SIB3 intra-frequency neighbours from the per-cell neighbour
list and propagate them from CU to DU over F1, with MAC
decoding/attaching them to SystemInformation.
- Generate SIB4 inter-frequency neighbours from a new frequency_list
plus neighbour SIB3/SIB4 offsets, and propagate them from CU to DU
over F1, with MAC decoding/attaching them.
- Add basic ASN.1 round-trip tests for SIB2/SIB3/SIB4 and SIB4 range
checks, and update RRC docs to describe the neighbour/inter-frequency
configuration model.
Testing:
1. in gNB conf file:
cu_sibs = (2, 3, 4);
2. Update neighbour config file with SIB3/SIB4 conf:
(see documentation)
3. run gNB and UE as usual
---
Logs & configs: see MR on Gitlab
Expand RRC usage and handover documentation to describe the two-level
neighbour configuration layout, lookup-key semantics,
and config-time SIB4 grouping behaviour. Expand the example config
to include a `frequency_list` block and per-neighbour SIB3/SIB4
offset fields. Add SIB2 config example.
Update handover-tutorial.md to describe the same nested model and
note that F1 and N2 handover share the same serving-cell keyed
mapping.
Add documentation about SIB3/SIB4 and MeasGaps implementation
in OAI with stress on the shared neighbour configuration data model.
Update FEATURE_SET.
Thread-pool support for TX symbol processing.
This MR adds thread-pool support for TX symbol processing. It allows modulation
/mapping/layer-precoding to run in parallel and offers a speedup of around 3
compared to single-thread execution. This is particularly important for large
bandwidths and 4 or more TX antenna ports where the precoding operation is quite
computationally-intensive.
Please see the description of !3489 for the performance comparison results and
the nr_dlsim timing measurements.
Extend the performance tuning section of documentation
to include explanation on the `--L1s.L1_num_tx_sym_per_thread` option
and on the AMD EPYC core complex behavior
Remove a lot of unused code, defines, and config options
Remove unused header files and defines.
Slightly clean up gnb_config.c by removing all _IDX variables. Remove
these unused parameters:
- MACRLCs.[0].num_cc
- MACRLCs.[0].local_n_portc
- MACRLCs.[0].remove_n_portc
- MACRLCs.[0].remote_s_portc
- MACRLCs.[0].remote_s_portd
- L1s.[0].num_cc
- L1s.[0].local_n_portc
Update doc: split RUNMODEM.md, clarify USRP-specific workarounds
This reworks the documentation:
- split up RUNMODEM.md into separate documents for gNB, UE, NTN
- explains USRP workaround and patches
- makes a standalone UE doc file that explains UE-specific configuration
& modes
- better explains physical simulators
- adds a document on tracy
- cleanup
Extend UICC configuration parsing to provide: routing_indicator,
protection_scheme, home_network_public_key, and home_network_public_key_id.
Use the protection_scheme value to decide what SUCI Profile Scheme to
apply during SUCI generation. Add support for Profile Scheme A which
provides ECIES-based encryption using Curve25519 and X9.63 KDF as outlined
in TS 33.501 Section C.3.4.1 Profile A.
When a configuration file specifies an unsupported Profile Scheme,
the NAS layer triggers a fatal error. This occurs either because
Profile Scheme B is unimplemented or the build uses OpenSSL < 3.0,
which lacks Curve25519 and X9.63 KDF support, ensuring users are
informed of the incompatibility.
Split out to make a standalone NTN configuratio page that would be
easier to find. I only modify the headings in the new file and write an
introductory sentence of the tutorial, the rest is unchanged.
- all RAN code, CI code, configuration files, dockerfiles, in CSSL v1.0
- all deployment code (openshift, charts, ancillary files like shell
scripts), in MIT
- documentation in CC-BY-4.0
- exceptions might apply and are listed in NOTICE
- there is a new LICENSES folder with all licenses
- CONTRIBUTIONS.md has been updated accordingly
For automated changes based on OAI PL v1.1:
perl -i~ -0pe 's/\/\*.*Licensed to the OpenAirInterface.*openairinterface.org\n#?/\/*\n * SPDX-License-Identifier: LicenseRef-CSSL-1.0\n/s' **/*.{c,h,cpp}
perl -i~ -0pe 's/\/\*.*Licensed to the OpenAirInterface.*openairinterface.org\n#?/\/*\n * SPDX-License-Identifier: LicenseRef-CSSL-1.0\n/s' **/*.ts
perl -i~ -0pe 's/<!--.*Licensed to the OpenAirInterface.*openairinterface.org\n.*-->/<!-- SPDX-License-Identifier: LicenseRef-CSSL-1.0 -->/s' **/*.xml
The rest (cmake, files with missing license, cmake) manually.
Fix Delta MCS mode, reimplement UL power control
This change set fixes the "delta-MCS" mode, and reimplements the UL power
control loops at gNB, i.e., for PUSCH and PUCCH. It further adds new T traces
to log PUSCH/PUCCH power infrmation, and cleans up code.
The "delta-MCS" mode in OAI refers to configuring a UE with deltaMCS in the
PUSCH-PowerControl IE (see TS 38.331). In this mode, the UE adjusts the PUSCH
power for transmissions to take into account for MCS (see TS 38.213 Sec. 7.1).
In other words, the target SNR can be set to a somewhat low value, and the UE
will still use the right power for UL transmissions. Note that the spec only
foresees this adjustment of UL power when using one layer. In contrast, in the
"normal" mode, the gNB sends TPC commands to keep a UE at a fixed target SNR
(default: 20dB), regardless of the MCS or number of layers. Future work is
planned to completely remove this fixed target SNR, which is not done in this
MR yet.
Further, there is a new power control loop implementation. Prior to this MR, on
each UL transmissions, the gNB uses the SNR to decide about TPC sent to a UE in
the next transmissions. The new implementation relies on averaging the SNR, and
a "TPC in flight" average to account for the slow reaction of the average SNR.
The sum of both quantities is the current SNR that is used by the UE. See the
commit messages or documentation for more information.
Further cleanup to group data (e.g., power control configuration, refactoring of
code to save space, ...) is done. Two new T traces GNB_MAC_PUSCH_POWER_CONTROL
and GNB_MAC_PUCCH_POWER_CONTROL are added; documentation exists to explain how
to graphically plot corresponding graphs.
Introduce UE NAS Simulator
This MR introduces a simple standalone tester for 5G UE NAS signaling and NGAP
messages. It connects to the AMF to perform NGAP and NAS encoding/decoding and
validates the UE Registration and PDU Session Establishment processes without
the overhead of a full Radio Access Network (PHY/MAC/RLC).
The motivation for this tester is as follows,
- This tester is a lightweight, deterministic tool to test the UE NAS layer
directly.
- Developers can easily inject specific NAS messages depending on the use-case.
- Developers can validate custom NAS/NGAP messages without the need to implement
complete RRC/MAC etc procedures.
Start the 5G Core network to test the UE NAS simulator. The compiling and
testing procedure is described below.
To compile:
mkdir build && cd build && cmake .. -GNinja && ninja nr-ue-nas-simulator-test
To run:
LD_LIBRARY_PATH=. ./tests/nr-ue-nas-simulator/nr-ue-nas-simulator-test -O ../tests/nr-ue-nas-simulator/test.conf
Remove old CUDA LDPC implementation
A new implementation is under way in !3955. To simplify the MR, remove the old
LDPC CUDA implementation in a first step.
Introduce new data structures to track the average SNR and RSSI, and
that allow to dynamically modify the target SNR (per UE) as well as
continuously get TPC updates based on the average SNR. The target SNR is
per power control loop (which a future commit will extend to use for
PUCCH).
Concretely, it maintains an average of measured SNR and RSSI. It also
updates "tpc_in_flight", which tracks TPC changes that don't show up in
the average yet. For instance, imagine that the target SNR of 15 changes
to 20. Three successive TPC commands need to be sent (+3, +1, +1), but
it will take time to show up in the average SNR. To account for this,
tpc_in_flight is updated by the TPCs sent, and an average will make it
go down back to zero at the same pace as the average SNR approaches the
target SNR. The sum of average SNR and tpc_in_flight sums up to the
actual, current SNR, which approximates the target SNR.
The SNR is kept within -1<=targetSNR<=+2dB to avoid too many TPC
changes.
The current average SNR (sum of average SNR and tpc_in_flight) is used
to continuously get TPC updates, taking into account recent TPCs sent,
the difference to target SNR, and RSSI.
If there is DTX, tpc_in_flight is modified to artificially introduce TPC
commands which increase the currently used SNR of the UE. This is
temporary, as tpc_in_flight eventually will go back to zero. If the DTX
was due to sudden SNR drop (e.g., higher path loss), this will allow to
quickly adapt the UE's SNR to new conditions.
The periodical logs are extended to not only show the current SNR, but
also the difference from the target for better analysis.
Co-authored-by: Maxime Elkael <m.elkael@northeastern.edu>
* Option to build ldpc_cuda was remaining in the build script
* Build script option to build ldpc_cuda was still used in CI
* Mentions of ldpc_cuda were remaining in the documentation
Note: In the documentation, the example of ldpctest usage that was
loading ldpc_cuda was replaced by an example in which it is loading
ldpc_orig even though this is pointless as it makes ldpctest compare
ldpc_orig with ldpc_orig. On the other hand, it is the only library
other than the default ldpc that uses the former interface.
Remove OSD, some scripts, oaisim references
The README says:
It is just generating the XML file and it is placing it in
$(OPENAIR_TARGETS)/SIMU/EXAMPLE/OSD/WEBXML/ or http://localhost/xmlfile/
so that the oaisim could pars and run the simulation/emulation
oaisim does not exist anymore, and corresponding simulation cannot be done.
Also, it requires XAMPP and similar technologies, that I think nobody uses
in the context of OAI.
Remove also most references to oaisim.
Remove some scripts that are likely not used by anybody, or straight useless.
Adjust ssPBCH_BlockPower in FHI7.2 configs
ssPBCH_BlockPower is the average EPRE of the resources elements that carry
secondary synchronization signals in dBm. In OAI, the SSB is the same level
as all the rest, so we can compute ssPBCH_BlockPower from RU TX power and
bandwidth using:
ssPBCH_BlockPower = P_TX(dBm) − 10 x log10(N_RB x 12)
where:
- P_TX is the RU transmit power
- 24 dBm for indoor RUs (configurable on the RU)
- 35 dBm for outdoor RUs (configurable on the RU)
- N_RB is the number of resource blocks for the configured bandwidth
- 12 corresponds to the number of subcarriers per RB
[FHI72] Fix long PRACH format
The problem was that xran_is_prach_slot() compared if the current slot is the
scheduled one. However, this becomes irrelevant if long PRACH format used.
Successfully tested end-to-end the PRACH index 7 with TDD DDDDDDDSUU and Benetel
v2.0.5.
Fix for NTN phy-test mode
- Corrected the initialisation of ntn params changed flag. Before this change on
UE, Phy-test was not running in NTN mode.
- Removed the assert wrt slot > 64 to run FR2-NTN in phy-test
- SIB2, 19 required only in SA mode like SIB1
- Introduced new method to schedule a slot in UL/DL in Phy-test mode. Dmod/ Umod
option in the command line with a value.
- This ensures that the slot n (in slots per frame) will be scheduled if
n % value == 0
- For ex: --Dmod 1 means every slot will be scheduled
- --Dmod 2 means every 2nd slot will be scheduled, like 0,2,4,6 until the
slots per frame 1.
- this can be used for testing FDD FR2 where slots go beyond 64 which is a
limitation of -D/-U option.
Only static long PRACH configuration verified, i.e. PRACH C-plane
is ignored by the RU.
Note: Introducing `N_ZC` and `num_prbu` parameters is needed for testing
with xran F release. However, in the K release, this information is
stored in xran_rx_packet_ctl struct.