git add for merge

parents 03d354ef 362da7c9
#/*
# * Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
# * contributor license agreements. See the NOTICE file distributed with
# * this work for additional information regarding copyright ownership.
# * The OpenAirInterface Software Alliance licenses this file to You under
# * the OAI Public License, Version 1.1 (the "License"); you may not use this file
# * except in compliance with the License.
# * You may obtain a copy of the License at
# *
# * http://www.openairinterface.org/?page_id=698
# *
# * Unless required by applicable law or agreed to in writing, software
# * distributed under the License is distributed on an "AS IS" BASIS,
# * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# * See the License for the specific language governing permissions and
# * limitations under the License.
# *-------------------------------------------------------------------------------
# * For more information about the OpenAirInterface (OAI) Software Alliance:
# * contact@openairinterface.org
# */
#---------------------------------------------------------------------
# Python for CI of OAI-eNB + COTS-UE
#
# Required Python Version
# Python 3.x
#
# Required Python Package
# pexpect
#---------------------------------------------------------------------
#-----------------------------------------------------------
# Version
#-----------------------------------------------------------
Version = '0.2'
#-----------------------------------------------------------
# Constants
#-----------------------------------------------------------
ALL_PROCESSES_OK = 0
ENB_PROCESS_FAILED = -1
ENB_PROCESS_OK = +1
ENB_PROCESS_SEG_FAULT = -11
ENB_PROCESS_ASSERTION = -12
ENB_PROCESS_REALTIME_ISSUE = -13
ENB_PROCESS_NOLOGFILE_TO_ANALYZE = -14
ENB_PROCESS_SLAVE_RRU_NOT_SYNCED = -15
HSS_PROCESS_FAILED = -2
HSS_PROCESS_OK = +2
MME_PROCESS_FAILED = -3
MME_PROCESS_OK = +3
SPGW_PROCESS_FAILED = -4
SPGW_PROCESS_OK = +4
UE_IP_ADDRESS_ISSUE = -5
OAI_UE_PROCESS_NOLOGFILE_TO_ANALYZE = -20
OAI_UE_PROCESS_COULD_NOT_SYNC = -21
OAI_UE_PROCESS_ASSERTION = -22
OAI_UE_PROCESS_FAILED = -23
OAI_UE_PROCESS_NO_TUNNEL_INTERFACE = -24
OAI_UE_PROCESS_SEG_FAULT = -25
OAI_UE_PROCESS_OK = +6
UE_STATUS_DETACHED = 0
UE_STATUS_DETACHING = 1
UE_STATUS_ATTACHING = 2
UE_STATUS_ATTACHED = 3
X2_HO_REQ_STATE__IDLE = 0
X2_HO_REQ_STATE__TARGET_RECEIVES_REQ = 1
X2_HO_REQ_STATE__TARGET_RRC_RECFG_COMPLETE = 2
X2_HO_REQ_STATE__TARGET_SENDS_SWITCH_REQ = 3
X2_HO_REQ_STATE__SOURCE_RECEIVES_REQ_ACK = 10
#/*
# * Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
# * contributor license agreements. See the NOTICE file distributed with
# * this work for additional information regarding copyright ownership.
# * The OpenAirInterface Software Alliance licenses this file to You under
# * the OAI Public License, Version 1.1 (the "License"); you may not use this file
# * except in compliance with the License.
# * You may obtain a copy of the License at
# *
# * http://www.openairinterface.org/?page_id=698
# *
# * Unless required by applicable law or agreed to in writing, software
# * distributed under the License is distributed on an "AS IS" BASIS,
# * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# * See the License for the specific language governing permissions and
# * limitations under the License.
# *-------------------------------------------------------------------------------
# * For more information about the OpenAirInterface (OAI) Software Alliance:
# * contact@openairinterface.org
# */
#---------------------------------------------------------------------
# Python for CI of OAI-eNB + COTS-UE
#
# Required Python Version
# Python 3.x
#
# Required Python Package
# pexpect
#---------------------------------------------------------------------
#-----------------------------------------------------------
# Import
#-----------------------------------------------------------
import sys # arg
import re # reg
import logging
import os
import time
import signal
from multiprocessing import Process, Lock, SimpleQueue
#-----------------------------------------------------------
# OAI Testing modules
#-----------------------------------------------------------
import sshconnection as SSH
import helpreadme as HELP
import constants as CONST
import html
#-----------------------------------------------------------
# Class Declaration
#-----------------------------------------------------------
class EPCManagement():
def __init__(self):
self.IPAddress = ''
self.UserName = ''
self.Password = ''
self.SourceCodePath = ''
self.Type = ''
self.PcapFileName = ''
self.htmlObj = None
self.testCase_id = ''
self.MmeIPAddress = ''
self.containerPrefix = 'prod'
#-----------------------------------------------------------
# Setter and Getters on Public Members
#-----------------------------------------------------------
def SetIPAddress(self, ipaddress):
self.IPAddress = ipaddress
def GetIPAddress(self):
return self.IPAddress
def SetUserName(self, username):
self.UserName = username
def GetUserName(self):
return self.UserName
def SetPassword(self, password):
self.Password = password
def GetPassword(self):
return self.Password
def SetSourceCodePath(self, sourcecodepath):
self.SourceCodePath = sourcecodepath
def GetSourceCodePath(self):
return self.SourceCodePath
def SetType(self, kind):
self.Type = kind
def GetType(self):
return self.Type
def SetHtmlObj(self, obj):
self.htmlObj = obj
def SetTestCase_id(self, idx):
self.testCase_id = idx
def GetMmeIPAddress(self):
return self.MmeIPAddress
def SetContainerPrefix(self, prefix):
self.containerPrefix = prefix
#-----------------------------------------------------------
# EPC management functions
#-----------------------------------------------------------
def InitializeHSS(self):
if self.IPAddress == '' or self.UserName == '' or self.Password == '' or self.SourceCodePath == '' or self.Type == '':
HELP.GenericHelp(CONST.Version)
HELP.EPCSrvHelp(self.IPAddress, self.UserName, self.Password, self.SourceCodePath, self.Type)
sys.exit('Insufficient EPC Parameters')
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
logging.debug('Using the OAI EPC Release 14 Cassandra-based HSS in Docker')
mySSH.command('if [ -d ' + self.SourceCodePath + '/scripts ]; then echo ' + self.Password + ' | sudo -S rm -Rf ' + self.SourceCodePath + '/scripts ; fi', '\$', 5)
mySSH.command('mkdir -p ' + self.SourceCodePath + '/scripts', '\$', 5)
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-hss /bin/bash -c "nohup tshark -i eth0 -i eth1 -w /tmp/hss_check_run.pcap 2>&1 > /dev/null"', '\$', 5)
time.sleep(5)
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-hss /bin/bash -c "nohup ./bin/oai_hss -j ./etc/hss_rel14.json --reloadkey true > hss_check_run.log 2>&1"', '\$', 5)
elif re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
logging.debug('Using the OAI EPC Release 14 Cassandra-based HSS')
mySSH.command('cd ' + self.SourceCodePath + '/scripts', '\$', 5)
logging.debug('\u001B[1m Launching tshark on all interfaces \u001B[0m')
self.PcapFileName = 'epc_' + self.testCase_id + '.pcap'
mySSH.command('echo ' + self.Password + ' | sudo -S rm -f ' + self.PcapFileName, '\$', 5)
mySSH.command('echo $USER; nohup sudo tshark -f "tcp port not 22 and port not 53" -i any -w ' + self.SourceCodePath + '/scripts/' + self.PcapFileName + ' > /tmp/tshark.log 2>&1 &', self.UserName, 5)
mySSH.command('echo ' + self.Password + ' | sudo -S mkdir -p logs', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S rm -f hss_' + self.testCase_id + '.log logs/hss*.*', '\$', 5)
mySSH.command('echo "oai_hss -j /usr/local/etc/oai/hss_rel14.json" > ./my-hss.sh', '\$', 5)
mySSH.command('chmod 755 ./my-hss.sh', '\$', 5)
mySSH.command('sudo daemon --unsafe --name=hss_daemon --chdir=' + self.SourceCodePath + '/scripts -o ' + self.SourceCodePath + '/scripts/hss_' + self.testCase_id + '.log ./my-hss.sh', '\$', 5)
elif re.match('OAI', self.Type, re.IGNORECASE):
logging.debug('Using the OAI EPC HSS')
mySSH.command('cd ' + self.SourceCodePath, '\$', 5)
mySSH.command('source oaienv', '\$', 5)
mySSH.command('cd scripts', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S ./run_hss 2>&1 | stdbuf -o0 awk \'{ print strftime("[%Y/%m/%d %H:%M:%S] ",systime()) $0 }\' | stdbuf -o0 tee -a hss_' + self.testCase_id + '.log &', 'Core state: 2 -> 3', 35)
elif re.match('ltebox', self.Type, re.IGNORECASE):
logging.debug('Using the ltebox simulated HSS')
mySSH.command('if [ -d ' + self.SourceCodePath + '/scripts ]; then echo ' + self.Password + ' | sudo -S rm -Rf ' + self.SourceCodePath + '/scripts ; fi', '\$', 5)
mySSH.command('mkdir -p ' + self.SourceCodePath + '/scripts', '\$', 5)
mySSH.command('cd /opt/hss_sim0609', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S rm -f hss.log', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S echo "Starting sudo session" && sudo su -c "screen -dm -S simulated_hss ./starthss"', '\$', 5)
else:
logging.error('This option should not occur!')
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Type, 'OK', CONST.ALL_PROCESSES_OK)
def InitializeMME(self):
if self.IPAddress == '' or self.UserName == '' or self.Password == '' or self.SourceCodePath == '' or self.Type == '':
HELP.GenericHelp(CONST.Version)
HELP.EPCSrvHelp(self.IPAddress, self.UserName, self.Password, self.SourceCodePath, self.Type)
sys.exit('Insufficient EPC Parameters')
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
logging.debug('Using the OAI EPC Release 14 MME in Docker')
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-mme /bin/bash -c "nohup tshark -i eth0 -i lo:s10 -w /tmp/mme_check_run.pcap 2>&1 > /dev/null"', '\$', 5)
time.sleep(5)
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-mme /bin/bash -c "nohup ./bin/oai_mme -c ./etc/mme.conf > mme_check_run.log 2>&1"', '\$', 5)
elif re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
logging.debug('Using the OAI EPC Release 14 MME')
mySSH.command('cd ' + self.SourceCodePath + '/scripts', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S rm -f mme_' + self.testCase_id + '.log', '\$', 5)
mySSH.command('echo "./run_mme --config-file /usr/local/etc/oai/mme.conf --set-virt-if" > ./my-mme.sh', '\$', 5)
mySSH.command('chmod 755 ./my-mme.sh', '\$', 5)
mySSH.command('sudo daemon --unsafe --name=mme_daemon --chdir=' + self.SourceCodePath + '/scripts -o ' + self.SourceCodePath + '/scripts/mme_' + self.testCase_id + '.log ./my-mme.sh', '\$', 5)
elif re.match('OAI', self.Type, re.IGNORECASE):
mySSH.command('cd ' + self.SourceCodePath, '\$', 5)
mySSH.command('source oaienv', '\$', 5)
mySSH.command('cd scripts', '\$', 5)
mySSH.command('stdbuf -o0 hostname', '\$', 5)
result = re.search('hostname\\\\r\\\\n(?P<host_name>[a-zA-Z0-9\-\_]+)\\\\r\\\\n', mySSH.getBefore())
if result is None:
logging.debug('\u001B[1;37;41m Hostname Not Found! \u001B[0m')
sys.exit(1)
host_name = result.group('host_name')
mySSH.command('echo ' + self.Password + ' | sudo -S ./run_mme 2>&1 | stdbuf -o0 tee -a mme_' + self.testCase_id + '.log &', 'MME app initialization complete', 100)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cd /opt/ltebox/tools', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S ./start_mme', '\$', 5)
else:
logging.error('This option should not occur!')
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Type, 'OK', CONST.ALL_PROCESSES_OK)
def SetMmeIPAddress(self):
# Not an error if we don't need an EPC
if self.IPAddress == '' or self.UserName == '' or self.Password == '' or self.SourceCodePath == '' or self.Type == '':
return
if self.IPAddress == 'none':
return
# Only in case of Docker containers, MME IP address is not the EPC HOST IP address
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
mySSH.command('docker inspect --format="MME_IP_ADDR = {{range .NetworkSettings.Networks}}{{.IPAddress}}{{end}}" ' + self.containerPrefix + '-oai-mme', '\$', 5)
result = re.search('MME_IP_ADDR = (?P<mme_ip_addr>[0-9\.]+)', mySSH.getBefore())
if result is not None:
self.MmeIPAddress = result.group('mme_ip_addr')
logging.debug('MME IP Address is ' + self.MmeIPAddress)
mySSH.close()
else:
self.MmeIPAddress = self.IPAddress
def InitializeSPGW(self):
if self.IPAddress == '' or self.UserName == '' or self.Password == '' or self.SourceCodePath == '' or self.Type == '':
HELP.GenericHelp(CONST.Version)
HELP.EPCSrvHelp(self.IPAddress, self.UserName, self.Password, self.SourceCodePath, self.Type)
sys.exit('Insufficient EPC Parameters')
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
logging.debug('Using the OAI EPC Release 14 SPGW-CUPS in Docker')
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-spgwc /bin/bash -c "nohup tshark -i eth0 -i lo:p5c -i lo:s5c -w /tmp/spgwc_check_run.pcap 2>&1 > /dev/null"', '\$', 5)
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-spgwu-tiny /bin/bash -c "nohup tshark -i eth0 -w /tmp/spgwu_check_run.pcap 2>&1 > /dev/null"', '\$', 5)
time.sleep(5)
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-spgwc /bin/bash -c "nohup ./bin/oai_spgwc -o -c ./etc/spgw_c.conf > spgwc_check_run.log 2>&1"', '\$', 5)
time.sleep(5)
mySSH.command('docker exec -d ' + self.containerPrefix + '-oai-spgwu-tiny /bin/bash -c "nohup ./bin/oai_spgwu -o -c ./etc/spgw_u.conf > spgwu_check_run.log 2>&1"', '\$', 5)
elif re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
logging.debug('Using the OAI EPC Release 14 SPGW-CUPS')
mySSH.command('cd ' + self.SourceCodePath + '/scripts', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S rm -f spgwc_' + self.testCase_id + '.log spgwu_' + self.testCase_id + '.log', '\$', 5)
mySSH.command('echo "spgwc -c /usr/local/etc/oai/spgw_c.conf" > ./my-spgwc.sh', '\$', 5)
mySSH.command('chmod 755 ./my-spgwc.sh', '\$', 5)
mySSH.command('sudo daemon --unsafe --name=spgwc_daemon --chdir=' + self.SourceCodePath + '/scripts -o ' + self.SourceCodePath + '/scripts/spgwc_' + self.testCase_id + '.log ./my-spgwc.sh', '\$', 5)
time.sleep(5)
mySSH.command('echo "spgwu -c /usr/local/etc/oai/spgw_u.conf" > ./my-spgwu.sh', '\$', 5)
mySSH.command('chmod 755 ./my-spgwu.sh', '\$', 5)
mySSH.command('sudo daemon --unsafe --name=spgwu_daemon --chdir=' + self.SourceCodePath + '/scripts -o ' + self.SourceCodePath + '/scripts/spgwu_' + self.testCase_id + '.log ./my-spgwu.sh', '\$', 5)
elif re.match('OAI', self.Type, re.IGNORECASE):
mySSH.command('cd ' + self.SourceCodePath, '\$', 5)
mySSH.command('source oaienv', '\$', 5)
mySSH.command('cd scripts', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S ./run_spgw 2>&1 | stdbuf -o0 tee -a spgw_' + self.testCase_id + '.log &', 'Initializing SPGW-APP task interface: DONE', 30)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cd /opt/ltebox/tools', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S ./start_xGw', '\$', 5)
else:
logging.error('This option should not occur!')
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Type, 'OK', CONST.ALL_PROCESSES_OK)
def CheckHSSProcess(self, status_queue):
try:
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-hss /bin/bash -c "ps aux | grep oai_hss"', '\$', 5)
else:
mySSH.command('stdbuf -o0 ps -aux | grep --color=never hss | grep -v grep', '\$', 5)
if re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE) or re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
result = re.search('oai_hss -j', mySSH.getBefore())
elif re.match('OAI', self.Type, re.IGNORECASE):
result = re.search('\/bin\/bash .\/run_', mySSH.getBefore())
elif re.match('ltebox', self.Type, re.IGNORECASE):
result = re.search('hss_sim s6as diam_hss', mySSH.getBefore())
else:
logging.error('This should not happen!')
if result is None:
logging.debug('\u001B[1;37;41m HSS Process Not Found! \u001B[0m')
status_queue.put(CONST.HSS_PROCESS_FAILED)
else:
status_queue.put(CONST.HSS_PROCESS_OK)
mySSH.close()
except:
os.kill(os.getppid(),signal.SIGUSR1)
def CheckMMEProcess(self, status_queue):
try:
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-mme /bin/bash -c "ps aux | grep oai_mme"', '\$', 5)
else:
mySSH.command('stdbuf -o0 ps -aux | grep --color=never mme | grep -v grep', '\$', 5)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
result = re.search('oai_mme -c ', mySSH.getBefore())
elif re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
result = re.search('mme -c', mySSH.getBefore())
elif re.match('OAI', self.Type, re.IGNORECASE):
result = re.search('\/bin\/bash .\/run_', mySSH.getBefore())
elif re.match('ltebox', self.Type, re.IGNORECASE):
result = re.search('mme', mySSH.getBefore())
else:
logging.error('This should not happen!')
if result is None:
logging.debug('\u001B[1;37;41m MME Process Not Found! \u001B[0m')
status_queue.put(CONST.MME_PROCESS_FAILED)
else:
status_queue.put(CONST.MME_PROCESS_OK)
mySSH.close()
except:
os.kill(os.getppid(),signal.SIGUSR1)
def CheckSPGWProcess(self, status_queue):
try:
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwc /bin/bash -c "ps aux | grep oai_spgwc"', '\$', 5)
result = re.search('oai_spgwc -o -c ', mySSH.getBefore())
if result is not None:
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwu-tiny /bin/bash -c "ps aux | grep oai_spgwu"', '\$', 5)
result = re.search('oai_spgwu -o -c ', mySSH.getBefore())
elif re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('stdbuf -o0 ps -aux | grep --color=never spgw | grep -v grep', '\$', 5)
result = re.search('spgwu -c ', mySSH.getBefore())
elif re.match('OAI', self.Type, re.IGNORECASE):
mySSH.command('stdbuf -o0 ps -aux | grep --color=never spgw | grep -v grep', '\$', 5)
result = re.search('\/bin\/bash .\/run_', mySSH.getBefore())
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('stdbuf -o0 ps -aux | grep --color=never xGw | grep -v grep', '\$', 5)
result = re.search('xGw', mySSH.getBefore())
else:
logging.error('This should not happen!')
if result is None:
logging.debug('\u001B[1;37;41m SPGW Process Not Found! \u001B[0m')
status_queue.put(CONST.SPGW_PROCESS_FAILED)
else:
status_queue.put(CONST.SPGW_PROCESS_OK)
mySSH.close()
except:
os.kill(os.getppid(),signal.SIGUSR1)
def TerminateHSS(self):
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-hss /bin/bash -c "killall --signal SIGINT oai_hss tshark"', '\$', 5)
time.sleep(2)
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-hss /bin/bash -c "ps aux | grep oai_hss"', '\$', 5)
result = re.search('oai_hss -j ', mySSH.getBefore())
if result is not None:
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-hss /bin/bash -c "killall --signal SIGKILL oai_hss"', '\$', 5)
elif re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGINT oai_hss || true', '\$', 5)
time.sleep(2)
mySSH.command('stdbuf -o0 ps -aux | grep hss | grep -v grep', '\$', 5)
result = re.search('oai_hss -j', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGKILL oai_hss || true', '\$', 5)
mySSH.command('rm -f ' + self.SourceCodePath + '/scripts/my-hss.sh', '\$', 5)
elif re.match('OAI', self.Type, re.IGNORECASE):
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGINT run_hss oai_hss || true', '\$', 5)
time.sleep(2)
mySSH.command('stdbuf -o0 ps -aux | grep hss | grep -v grep', '\$', 5)
result = re.search('\/bin\/bash .\/run_', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGKILL run_hss oai_hss || true', '\$', 5)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cd ' + self.SourceCodePath, '\$', 5)
mySSH.command('cd scripts', '\$', 5)
time.sleep(1)
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGKILL hss_sim', '\$', 5)
else:
logging.error('This should not happen!')
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('N/A', 'OK', CONST.ALL_PROCESSES_OK)
def TerminateMME(self):
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-mme /bin/bash -c "killall --signal SIGINT oai_mme tshark"', '\$', 5)
time.sleep(2)
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-mme /bin/bash -c "ps aux | grep oai_mme"', '\$', 5)
result = re.search('oai_mme -c ', mySSH.getBefore())
if result is not None:
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-mme /bin/bash -c "killall --signal SIGKILL oai_mme"', '\$', 5)
elif re.match('OAI', self.Type, re.IGNORECASE) or re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGINT run_mme mme || true', '\$', 5)
time.sleep(2)
mySSH.command('stdbuf -o0 ps -aux | grep mme | grep -v grep', '\$', 5)
result = re.search('mme -c', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGKILL run_mme mme || true', '\$', 5)
mySSH.command('rm -f ' + self.SourceCodePath + '/scripts/my-mme.sh', '\$', 5)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cd /opt/ltebox/tools', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S ./stop_mme', '\$', 5)
else:
logging.error('This should not happen!')
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('N/A', 'OK', CONST.ALL_PROCESSES_OK)
def TerminateSPGW(self):
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwc /bin/bash -c "killall --signal SIGINT oai_spgwc tshark"', '\$', 5)
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwu-tiny /bin/bash -c "killall --signal SIGINT oai_spgwu tshark"', '\$', 5)
time.sleep(2)
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwc /bin/bash -c "ps aux | grep oai_spgwc"', '\$', 5)
result = re.search('oai_spgwc -o -c ', mySSH.getBefore())
if result is not None:
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwc /bin/bash -c "killall --signal SIGKILL oai_spgwc"', '\$', 5)
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwu-tiny /bin/bash -c "ps aux | grep oai_spgwu"', '\$', 5)
result = re.search('oai_spgwu -o -c ', mySSH.getBefore())
if result is not None:
mySSH.command('docker exec -it ' + self.containerPrefix + '-oai-spgwu-tiny /bin/bash -c "killall --signal SIGKILL oai_spgwu"', '\$', 5)
elif re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGINT spgwc spgwu || true', '\$', 5)
time.sleep(2)
mySSH.command('stdbuf -o0 ps -aux | grep spgw | grep -v grep', '\$', 5)
result = re.search('spgwc -c |spgwu -c ', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGKILL spgwc spgwu || true', '\$', 5)
mySSH.command('rm -f ' + self.SourceCodePath + '/scripts/my-spgw*.sh', '\$', 5)
mySSH.command('stdbuf -o0 ps -aux | grep tshark | grep -v grep', '\$', 5)
result = re.search('-w ', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGINT tshark || true', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S chmod 666 ' + self.SourceCodePath + '/scripts/*.pcap', '\$', 5)
elif re.match('OAI', self.Type, re.IGNORECASE):
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGINT run_spgw spgw || true', '\$', 5)
time.sleep(2)
mySSH.command('stdbuf -o0 ps -aux | grep spgw | grep -v grep', '\$', 5)
result = re.search('\/bin\/bash .\/run_', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + self.Password + ' | sudo -S killall --signal SIGKILL run_spgw spgw || true', '\$', 5)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cd /opt/ltebox/tools', '\$', 5)
mySSH.command('echo ' + self.Password + ' | sudo -S ./stop_xGw', '\$', 5)
else:
logging.error('This should not happen!')
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('N/A', 'OK', CONST.ALL_PROCESSES_OK)
def LogCollectHSS(self):
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
mySSH.command('cd ' + self.SourceCodePath + '/scripts', '\$', 5)
mySSH.command('rm -f hss.log.zip', '\$', 5)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker cp ' + self.containerPrefix + '-oai-hss:/openair-hss/hss_check_run.log .', '\$', 60)
mySSH.command('docker cp ' + self.containerPrefix + '-oai-hss:/tmp/hss_check_run.pcap .', '\$', 60)
mySSH.command('zip hss.log.zip hss_check_run.*', '\$', 60)
elif re.match('OAI', self.Type, re.IGNORECASE) or re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('zip hss.log.zip hss*.log', '\$', 60)
mySSH.command('echo ' + self.Password + ' | sudo -S rm hss*.log', '\$', 5)
if re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('zip hss.log.zip logs/hss*.* *.pcap', '\$', 60)
mySSH.command('echo ' + self.Password + ' | sudo -S rm -f logs/hss*.* *.pcap', '\$', 5)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cp /opt/hss_sim0609/hss.log .', '\$', 60)
mySSH.command('zip hss.log.zip hss.log', '\$', 60)
else:
logging.error('This option should not occur!')
mySSH.close()
def LogCollectMME(self):
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
mySSH.command('cd ' + self.SourceCodePath + '/scripts', '\$', 5)
mySSH.command('rm -f mme.log.zip', '\$', 5)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker cp ' + self.containerPrefix + '-oai-mme:/openair-mme/mme_check_run.log .', '\$', 60)
mySSH.command('docker cp ' + self.containerPrefix + '-oai-mme:/tmp/mme_check_run.pcap .', '\$', 60)
mySSH.command('zip mme.log.zip mme_check_run.*', '\$', 60)
elif re.match('OAI', self.Type, re.IGNORECASE) or re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('zip mme.log.zip mme*.log', '\$', 60)
mySSH.command('echo ' + self.Password + ' | sudo -S rm mme*.log', '\$', 5)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cp /opt/ltebox/var/log/*Log.0 .', '\$', 5)
mySSH.command('zip mme.log.zip mmeLog.0 s1apcLog.0 s1apsLog.0 s11cLog.0 libLog.0 s1apCodecLog.0', '\$', 60)
else:
logging.error('This option should not occur!')
mySSH.close()
def LogCollectSPGW(self):
mySSH = SSH.SSHConnection()
mySSH.open(self.IPAddress, self.UserName, self.Password)
mySSH.command('cd ' + self.SourceCodePath + '/scripts', '\$', 5)
mySSH.command('rm -f spgw.log.zip', '\$', 5)
if re.match('OAI-Rel14-Docker', self.Type, re.IGNORECASE):
mySSH.command('docker cp ' + self.containerPrefix + '-oai-spgwc:/openair-spgwc/spgwc_check_run.log .', '\$', 60)
mySSH.command('docker cp ' + self.containerPrefix + '-oai-spgwu-tiny:/openair-spgwu-tiny/spgwu_check_run.log .', '\$', 60)
mySSH.command('docker cp ' + self.containerPrefix + '-oai-spgwc:/tmp/spgwc_check_run.pcap .', '\$', 60)
mySSH.command('docker cp ' + self.containerPrefix + '-oai-spgwu-tiny:/tmp/spgwu_check_run.pcap .', '\$', 60)
mySSH.command('zip spgw.log.zip spgw*_check_run.*', '\$', 60)
elif re.match('OAI', self.Type, re.IGNORECASE) or re.match('OAI-Rel14-CUPS', self.Type, re.IGNORECASE):
mySSH.command('zip spgw.log.zip spgw*.log', '\$', 60)
mySSH.command('echo ' + self.Password + ' | sudo -S rm spgw*.log', '\$', 5)
elif re.match('ltebox', self.Type, re.IGNORECASE):
mySSH.command('cp /opt/ltebox/var/log/xGwLog.0 .', '\$', 5)
mySSH.command('zip spgw.log.zip xGwLog.0', '\$', 60)
else:
logging.error('This option should not occur!')
mySSH.close()
#/*
# * Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
# * contributor license agreements. See the NOTICE file distributed with
# * this work for additional information regarding copyright ownership.
# * The OpenAirInterface Software Alliance licenses this file to You under
# * the OAI Public License, Version 1.1 (the "License"); you may not use this file
# * except in compliance with the License.
# * You may obtain a copy of the License at
# *
# * http://www.openairinterface.org/?page_id=698
# *
# * Unless required by applicable law or agreed to in writing, software
# * distributed under the License is distributed on an "AS IS" BASIS,
# * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# * See the License for the specific language governing permissions and
# * limitations under the License.
# *-------------------------------------------------------------------------------
# * For more information about the OpenAirInterface (OAI) Software Alliance:
# * contact@openairinterface.org
# */
#---------------------------------------------------------------------
# Python for CI of OAI-eNB + COTS-UE
#
# Required Python Version
# Python 3.x
#
# Required Python Package
# pexpect
#---------------------------------------------------------------------
#-----------------------------------------------------------
# Functions Declaration
#-----------------------------------------------------------
def GenericHelp(vers):
print('----------------------------------------------------------------------------------------------------------------------')
print('main.py Ver: ' + vers)
print('----------------------------------------------------------------------------------------------------------------------')
print('python main.py [options]')
print(' --help Show this help.')
print(' --mode=[Mode]')
print(' TesteNB')
print(' InitiateHtml, FinalizeHtml')
print(' TerminateeNB, TerminateUE, TerminateHSS, TerminateMME, TerminateSPGW')
print(' LogCollectBuild, LogCollecteNB, LogCollectHSS, LogCollectMME, LogCollectSPGW, LogCollectPing, LogCollectIperf')
def GitSrvHelp(repository,branch,commit,mergeallow,targetbranch):
print(' --ranRepository=[OAI RAN Repository URL] -- ' + repository)
print(' --ranBranch=[OAI RAN Repository Branch] -- ' + branch)
print(' --ranCommitID=[OAI RAN Repository Commit SHA-1] -- ' + commit)
print(' --ranAllowMerge=[Allow Merge Request (with target branch) (true or false)] -- ' + mergeallow)
print(' --ranTargetBranch=[Target Branch in case of a Merge Request] -- ' + targetbranch)
def eNBSrvHelp(ipaddr, username, password, sourcepath):
print(' --eNBIPAddress=[eNB\'s IP Address] -- ' + ipaddr)
print(' --eNBUserName=[eNB\'s Login User Name] -- ' + username)
print(' --eNBPassword=[eNB\'s Login Password] -- ' + password)
print(' --eNBSourceCodePath=[eNB\'s Source Code Path] -- ' + sourcepath)
def OAIUESrvHelp(ipaddr, username, password, sourcepath):
print(' --UEIPAddress=[UE\'s IP Address] -- ' + ipaddr)
print(' --UEUserName=[UE\'s Login User Name] -- ' + username)
print(' --UEPassword=[UE\'s Login Password] -- ' + password)
print(' --UESourceCodePath=[UE\'s Source Code Path] -- ' + sourcepath)
def EPCSrvHelp(ipaddr, username, password, sourcepath, epctype):
print(' --EPCIPAddress=[EPC\'s IP Address] -- ' + ipaddr)
print(' --EPCUserName=[EPC\'s Login User Name] -- ' + username)
print(' --EPCPassword=[EPC\'s Login Password] -- ' + password)
print(' --EPCSourceCodePath=[EPC\'s Source Code Path] -- ' + sourcepath)
print(' --EPCType=[EPC\'s Type: OAI or ltebox or OAI-Rel14-CUPS] -- ' + epctype)
def ADBSrvHelp(ipaddr, username, password):
print(' --ADBIPAddress=[ADB\'s IP Address] -- ' + ipaddr)
print(' --ADBUserName=[ADB\'s Login User Name] -- ' + username)
print(' --ADBPassword=[ADB\'s Login Password] -- ' + password)
def XmlHelp(filename):
print(' --XMLTestFile=[XML Test File to be run] -- ' + filename)
print(' Note: multiple xml files can be specified (--XMLFile=File1 ... --XMLTestFile=FileN) when HTML headers are created ("InitiateHtml" mode)')
#/*
# * Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
# * contributor license agreements. See the NOTICE file distributed with
# * this work for additional information regarding copyright ownership.
# * The OpenAirInterface Software Alliance licenses this file to You under
# * the OAI Public License, Version 1.1 (the "License"); you may not use this file
# * except in compliance with the License.
# * You may obtain a copy of the License at
# *
# * http://www.openairinterface.org/?page_id=698
# *
# * Unless required by applicable law or agreed to in writing, software
# * distributed under the License is distributed on an "AS IS" BASIS,
# * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# * See the License for the specific language governing permissions and
# * limitations under the License.
# *-------------------------------------------------------------------------------
# * For more information about the OpenAirInterface (OAI) Software Alliance:
# * contact@openairinterface.org
# */
#---------------------------------------------------------------------
# Python for CI of OAI-eNB + COTS-UE
#
# Required Python Version
# Python 3.x
#
# Required Python Package
# pexpect
#---------------------------------------------------------------------
#-----------------------------------------------------------
# Import
#-----------------------------------------------------------
import sys # arg
import re # reg
import logging
import os
import time
import subprocess
from multiprocessing import Process, Lock, SimpleQueue
import constants as CONST
#-----------------------------------------------------------
# Class Declaration
#-----------------------------------------------------------
class HTMLManagement():
def __init__(self):
self.htmlFile = ''
self.htmlHeaderCreated = False
self.htmlFooterCreated = False
self.ranRepository = ''
self.ranBranch = ''
self.ranCommitID = ''
self.ranAllowMerge = False
self.ranTargetBranch = ''
self.nbTestXMLfiles = 0
self.htmlTabRefs = []
self.htmlTabNames = []
self.htmlTabIcons = []
self.testXMLfiles = []
self.htmleNBFailureMsg = ''
self.htmlUEFailureMsg = ''
self.startTime = int(round(time.time() * 1000))
self.testCase_id = ''
self.desc = ''
self.OsVersion = ['', '']
self.KernelVersion = ['', '']
self.UhdVersion = ['', '']
self.UsrpBoard = ['', '']
self.CpuNb = ['', '']
self.CpuModel = ['', '']
self.CpuMHz = ['', '']
#-----------------------------------------------------------
# Setters and Getters
#-----------------------------------------------------------
def SethtmlUEFailureMsg(self,huefa):
self.htmlUEFailureMsg = huefa
def GethtmlUEFailureMsg(self):
return self.htmlUEFailureMsg
def SetHmleNBFailureMsg(self, msg):
self.htmleNBFailureMsg = msg
def Setdesc(self, dsc):
self.desc = dsc
def SetstartTime(self, sttime):
self.startTime = sttime
def SettestCase_id(self, tcid):
self.testCase_id = tcid
def GettestCase_id(self):
return self.testCase_id
def SetranRepository(self, repository):
self.ranRepository = repository
def SetranAllowMerge(self, merge):
self.ranAllowMerge = merge
def SetranBranch(self, branch):
self.ranBranch = branch
def SetranCommitID(self, commitid):
self.ranCommitID = commitid
def SetranTargetBranch(self, tbranch):
self.ranTargetBranch = tbranch
def SethtmlUEConnected(self, nbUEs):
if nbUEs > 0:
self.htmlUEConnected = nbUEs
else:
self.htmlUEConnected = 1
def SethtmlNb_Smartphones(self, nbUEs):
self.htmlNb_Smartphones = nbUEs
def SethtmlNb_CATM_Modules(self, nbUEs):
self.htmlNb_CATM_Modules = nbUEs
def SetnbTestXMLfiles(self, nb):
self.nbTestXMLfiles = nb
def GetnbTestXMLfiles(self):
return self.nbTestXMLfiles
def SettestXMLfiles(self, xmlFile):
self.testXMLfiles.append(xmlFile)
def SethtmlTabRefs(self, tabRef):
self.htmlTabRefs.append(tabRef)
def SethtmlTabNames(self, tabName):
self.htmlTabNames.append(tabName)
def SethtmlTabIcons(self, tabIcon):
self.htmlTabIcons.append(tabIcon)
def SetOsVersion(self, version, idx):
self.OsVersion[idx] = version
def SetKernelVersion(self, version, idx):
self.KernelVersion[idx] = version
def SetUhdVersion(self, version, idx):
self.UhdVersion[idx] = version
def SetUsrpBoard(self, version, idx):
self.UsrpBoard[idx] = version
def SetCpuNb(self, nb, idx):
self.CpuNb[idx] = nb
def SetCpuModel(self, model, idx):
self.CpuModel[idx] = model
def SetCpuMHz(self, freq, idx):
self.CpuMHz[idx] = freq
#-----------------------------------------------------------
# HTML structure creation functions
#-----------------------------------------------------------
def CreateHtmlHeader(self, ADBIPAddress):
if (not self.htmlHeaderCreated):
logging.debug('\u001B[1m----------------------------------------\u001B[0m')
logging.debug('\u001B[1m Creating HTML header \u001B[0m')
logging.debug('\u001B[1m----------------------------------------\u001B[0m')
self.htmlFile = open('test_results.html', 'w')
self.htmlFile.write('<!DOCTYPE html>\n')
self.htmlFile.write('<html class="no-js" lang="en-US">\n')
self.htmlFile.write('<head>\n')
self.htmlFile.write(' <meta name="viewport" content="width=device-width, initial-scale=1">\n')
self.htmlFile.write(' <link rel="stylesheet" href="https://maxcdn.bootstrapcdn.com/bootstrap/3.3.7/css/bootstrap.min.css">\n')
self.htmlFile.write(' <script src="https://ajax.googleapis.com/ajax/libs/jquery/3.3.1/jquery.min.js"></script>\n')
self.htmlFile.write(' <script src="https://maxcdn.bootstrapcdn.com/bootstrap/3.3.7/js/bootstrap.min.js"></script>\n')
self.htmlFile.write(' <title>Test Results for TEMPLATE_JOB_NAME job build #TEMPLATE_BUILD_ID</title>\n')
self.htmlFile.write('</head>\n')
self.htmlFile.write('<body><div class="container">\n')
self.htmlFile.write(' <br>\n')
self.htmlFile.write(' <table style="border-collapse: collapse; border: none;">\n')
self.htmlFile.write(' <tr style="border-collapse: collapse; border: none;">\n')
self.htmlFile.write(' <td style="border-collapse: collapse; border: none;">\n')
self.htmlFile.write(' <a href="http://www.openairinterface.org/">\n')
self.htmlFile.write(' <img src="http://www.openairinterface.org/wp-content/uploads/2016/03/cropped-oai_final_logo2.png" alt="" border="none" height=50 width=150>\n')
self.htmlFile.write(' </img>\n')
self.htmlFile.write(' </a>\n')
self.htmlFile.write(' </td>\n')
self.htmlFile.write(' <td style="border-collapse: collapse; border: none; vertical-align: center;">\n')
self.htmlFile.write(' <b><font size = "6">Job Summary -- Job: TEMPLATE_JOB_NAME -- Build-ID: TEMPLATE_BUILD_ID</font></b>\n')
self.htmlFile.write(' </td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' </table>\n')
self.htmlFile.write(' <br>\n')
self.htmlFile.write(' <div class="alert alert-info"><strong> <span class="glyphicon glyphicon-dashboard"></span> TEMPLATE_STAGE_NAME</strong></div>\n')
self.htmlFile.write(' <table border = "1">\n')
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-time"></span> Build Start Time (UTC) </td>\n')
self.htmlFile.write(' <td>TEMPLATE_BUILD_TIME</td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-cloud-upload"></span> GIT Repository </td>\n')
self.htmlFile.write(' <td><a href="' + self.ranRepository + '">' + self.ranRepository + '</a></td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-wrench"></span> Job Trigger </td>\n')
if (self.ranAllowMerge):
self.htmlFile.write(' <td>Merge-Request</td>\n')
else:
self.htmlFile.write(' <td>Push to Branch</td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' <tr>\n')
if (self.ranAllowMerge):
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-log-out"></span> Source Branch </td>\n')
else:
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-tree-deciduous"></span> Branch</td>\n')
self.htmlFile.write(' <td>' + self.ranBranch + '</td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' <tr>\n')
if (self.ranAllowMerge):
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-tag"></span> Source Commit ID </td>\n')
else:
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-tag"></span> Commit ID </td>\n')
self.htmlFile.write(' <td>' + self.ranCommitID + '</td>\n')
self.htmlFile.write(' </tr>\n')
if self.ranAllowMerge != '':
commit_message = subprocess.check_output("git log -n1 --pretty=format:\"%s\" " + self.ranCommitID, shell=True, universal_newlines=True)
commit_message = commit_message.strip()
self.htmlFile.write(' <tr>\n')
if (self.ranAllowMerge):
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-comment"></span> Source Commit Message </td>\n')
else:
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-comment"></span> Commit Message </td>\n')
self.htmlFile.write(' <td>' + commit_message + '</td>\n')
self.htmlFile.write(' </tr>\n')
if (self.ranAllowMerge):
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" > <span class="glyphicon glyphicon-log-in"></span> Target Branch </td>\n')
if (self.ranTargetBranch == ''):
self.htmlFile.write(' <td>develop</td>\n')
else:
self.htmlFile.write(' <td>' + self.ranTargetBranch + '</td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' </table>\n')
if (ADBIPAddress != 'none'):
self.htmlFile.write(' <h2><span class="glyphicon glyphicon-phone"></span> <span class="glyphicon glyphicon-menu-right"></span> ' + str(self.htmlNb_Smartphones) + ' UE(s) is(are) connected to ADB bench server</h2>\n')
self.htmlFile.write(' <h2><span class="glyphicon glyphicon-phone"></span> <span class="glyphicon glyphicon-menu-right"></span> ' + str(self.htmlNb_CATM_Modules) + ' CAT-M UE(s) is(are) connected to bench server</h2>\n')
else:
self.htmlUEConnected = 1
self.htmlFile.write(' <h2><span class="glyphicon glyphicon-phone"></span> <span class="glyphicon glyphicon-menu-right"></span> 1 OAI UE(s) is(are) connected to CI bench</h2>\n')
self.htmlFile.write(' <br>\n')
self.htmlFile.write(' <ul class="nav nav-pills">\n')
count = 0
while (count < self.nbTestXMLfiles):
pillMsg = ' <li><a data-toggle="pill" href="#'
pillMsg += self.htmlTabRefs[count]
pillMsg += '">'
pillMsg += '__STATE_' + self.htmlTabNames[count] + '__'
pillMsg += self.htmlTabNames[count]
pillMsg += ' <span class="glyphicon glyphicon-'
pillMsg += self.htmlTabIcons[count]
pillMsg += '"></span></a></li>\n'
self.htmlFile.write(pillMsg)
count += 1
self.htmlFile.write(' </ul>\n')
self.htmlFile.write(' <div class="tab-content">\n')
self.htmlFile.close()
def CreateHtmlTabHeader(self):
if (not self.htmlHeaderCreated):
if (not os.path.isfile('test_results.html')):
self.CreateHtmlHeader('none')
self.htmlFile = open('test_results.html', 'a')
if (self.nbTestXMLfiles == 1):
self.htmlFile.write(' <div id="' + self.htmlTabRefs[0] + '" class="tab-pane fade">\n')
self.htmlFile.write(' <h3>Test Summary for <span class="glyphicon glyphicon-file"></span> ' + self.testXMLfiles[0] + '</h3>\n')
else:
self.htmlFile.write(' <div id="build-tab" class="tab-pane fade">\n')
self.htmlFile.write(' <table class="table" border = "1">\n')
self.htmlFile.write(' <tr bgcolor = "#33CCFF" >\n')
self.htmlFile.write(' <th>Relative Time (ms)</th>\n')
self.htmlFile.write(' <th>Test Id</th>\n')
self.htmlFile.write(' <th>Test Desc</th>\n')
self.htmlFile.write(' <th>Test Options</th>\n')
self.htmlFile.write(' <th>Test Status</th>\n')
i = 0
while (i < self.htmlUEConnected):
self.htmlFile.write(' <th>UE' + str(i) + ' Status</th>\n')
i += 1
self.htmlFile.write(' </tr>\n')
self.htmlFile.close()
self.htmlHeaderCreated = True
def CreateHtmlTabFooter(self, passStatus):
if ((not self.htmlFooterCreated) and (self.htmlHeaderCreated)):
self.htmlFile = open('test_results.html', 'a')
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <th bgcolor = "#33CCFF" colspan=3>Final Tab Status</th>\n')
if passStatus:
self.htmlFile.write(' <th bgcolor = "green" colspan=' + str(2 + self.htmlUEConnected) + '><font color="white">PASS <span class="glyphicon glyphicon-ok"></span> </font></th>\n')
else:
self.htmlFile.write(' <th bgcolor = "red" colspan=' + str(2 + self.htmlUEConnected) + '><font color="white">FAIL <span class="glyphicon glyphicon-remove"></span> </font></th>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' </table>\n')
self.htmlFile.write(' </div>\n')
self.htmlFile.close()
time.sleep(1)
if passStatus:
cmd = "sed -i -e 's/__STATE_" + self.htmlTabNames[0] + "__//' test_results.html"
subprocess.run(cmd, shell=True)
else:
cmd = "sed -i -e 's/__STATE_" + self.htmlTabNames[0] + "__/<span class=\"glyphicon glyphicon-remove\"><\/span>/' test_results.html"
subprocess.run(cmd, shell=True)
self.htmlFooterCreated = False
def CreateHtmlFooter(self, passStatus):
if (os.path.isfile('test_results.html')):
self.htmlFile = open('test_results.html', 'a')
self.htmlFile.write('</div>\n')
self.htmlFile.write(' <p></p>\n')
self.htmlFile.write(' <table class="table table-condensed">\n')
machines = [ 'eNB', 'UE' ]
for machine in machines:
if machine == 'eNB':
idx = 0
else:
idx = 1
if self.OsVersion[idx] == '':
continue
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <th colspan=8>' + str('eNB') + ' Server Characteristics</th>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td>OS Version</td>\n')
self.htmlFile.write(' <td><span class="label label-default">' + self.OsVersion[idx] + '</span></td>\n')
self.htmlFile.write(' <td>Kernel Version</td>\n')
self.htmlFile.write(' <td><span class="label label-default">' + self.KernelVersion[idx] + '</span></td>\n')
self.htmlFile.write(' <td>UHD Version</td>\n')
self.htmlFile.write(' <td><span class="label label-default">' + self.UhdVersion[idx] + '</span></td>\n')
self.htmlFile.write(' <td>USRP Board</td>\n')
self.htmlFile.write(' <td><span class="label label-default">' + self.UsrpBoard[idx] + '</span></td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td>Nb CPUs</td>\n')
self.htmlFile.write(' <td><span class="label label-default">' + self.CpuNb[idx] + '</span></td>\n')
self.htmlFile.write(' <td>CPU Model Name</td>\n')
self.htmlFile.write(' <td><span class="label label-default">' + self.CpuModel[idx] + '</span></td>\n')
self.htmlFile.write(' <td>CPU Frequency</td>\n')
self.htmlFile.write(' <td><span class="label label-default">' + self.CpuMHz[idx] + '</span></td>\n')
self.htmlFile.write(' <td></td>\n')
self.htmlFile.write(' <td></td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <th colspan=5 bgcolor = "#33CCFF">Final Status</th>\n')
if passStatus:
self.htmlFile.write(' <th colspan=3 bgcolor="green"><font color="white">PASS <span class="glyphicon glyphicon-ok"></span></font></th>\n')
else:
self.htmlFile.write(' <th colspan=3 bgcolor="red"><font color="white">FAIL <span class="glyphicon glyphicon-remove"></span> </font></th>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.write(' </table>\n')
self.htmlFile.write(' <p></p>\n')
self.htmlFile.write(' <div class="well well-lg">End of Test Report -- Copyright <span class="glyphicon glyphicon-copyright-mark"></span> 2018 <a href="http://www.openairinterface.org/">OpenAirInterface</a>. All Rights Reserved.</div>\n')
self.htmlFile.write('</div></body>\n')
self.htmlFile.write('</html>\n')
self.htmlFile.close()
def CreateHtmlRetrySeparator(self, cntnumfails):
if ((not self.htmlFooterCreated) and (self.htmlHeaderCreated)):
self.htmlFile = open('test_results.html', 'a')
self.htmlFile.write(' <tr bgcolor = "#F0F0F0" >\n')
self.htmlFile.write(' <td colspan=' + str(5+self.htmlUEConnected) + '><b> ---- Try Run #' + str(cntnumfails) + ' ---- </b></td>\n')
self.htmlFile.write(' </tr>\n')
self.htmlFile.close()
def CreateHtmlTestRow(self, options, status, processesStatus, machine='eNB'):
if (self.htmlFooterCreated or (not self.htmlHeaderCreated)):
return
self.htmlFile = open('test_results.html', 'a')
currentTime = int(round(time.time() * 1000)) - self.startTime
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" >' + format(currentTime / 1000, '.1f') + '</td>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" >' + self.testCase_id + '</td>\n')
self.htmlFile.write(' <td>' + self.desc + '</td>\n')
self.htmlFile.write(' <td>' + str(options) + '</td>\n')
if (str(status) == 'OK'):
self.htmlFile.write(' <td bgcolor = "lightgreen" >' + str(status) + '</td>\n')
elif (str(status) == 'KO'):
if (processesStatus == 0):
self.htmlFile.write(' <td bgcolor = "lightcoral" >' + str(status) + '</td>\n')
elif (processesStatus == CONST.ENB_PROCESS_FAILED):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - eNB process not found</td>\n')
elif (processesStatus == CONST.OAI_UE_PROCESS_FAILED):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - OAI UE process not found</td>\n')
elif (processesStatus == CONST.ENB_PROCESS_SEG_FAULT) or (processesStatus == CONST.OAI_UE_PROCESS_SEG_FAULT):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - ' + machine + ' process ended in Segmentation Fault</td>\n')
elif (processesStatus == CONST.ENB_PROCESS_ASSERTION) or (processesStatus == CONST.OAI_UE_PROCESS_ASSERTION):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - ' + machine + ' process ended in Assertion</td>\n')
elif (processesStatus == CONST.ENB_PROCESS_REALTIME_ISSUE):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - ' + machine + ' process faced Real Time issue(s)</td>\n')
elif (processesStatus == CONST.ENB_PROCESS_NOLOGFILE_TO_ANALYZE) or (processesStatus == CONST.OAI_UE_PROCESS_NOLOGFILE_TO_ANALYZE):
self.htmlFile.write(' <td bgcolor = "orange" >OK?</td>\n')
elif (processesStatus == CONST.ENB_PROCESS_SLAVE_RRU_NOT_SYNCED):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - ' + machine + ' Slave RRU could not synch</td>\n')
elif (processesStatus == CONST.OAI_UE_PROCESS_COULD_NOT_SYNC):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - UE could not sync</td>\n')
elif (processesStatus == CONST.HSS_PROCESS_FAILED):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - HSS process not found</td>\n')
elif (processesStatus == CONST.MME_PROCESS_FAILED):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - MME process not found</td>\n')
elif (processesStatus == CONST.SPGW_PROCESS_FAILED):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - SPGW process not found</td>\n')
elif (processesStatus == CONST.UE_IP_ADDRESS_ISSUE):
self.htmlFile.write(' <td bgcolor = "lightcoral" >KO - Could not retrieve UE IP address</td>\n')
else:
self.htmlFile.write(' <td bgcolor = "lightcoral" >' + str(status) + '</td>\n')
else:
self.htmlFile.write(' <td bgcolor = "orange" >' + str(status) + '</td>\n')
if (len(str(self.htmleNBFailureMsg)) > 2):
cellBgColor = 'white'
result = re.search('ended with|faced real time issues', self.htmleNBFailureMsg)
if result is not None:
cellBgColor = 'red'
else:
result = re.search('showed|Reestablishment|Could not copy eNB logfile', self.htmleNBFailureMsg)
if result is not None:
cellBgColor = 'orange'
self.htmlFile.write(' <td bgcolor = "' + cellBgColor + '" colspan=' + str(self.htmlUEConnected) + '><pre style="background-color:' + cellBgColor + '">' + self.htmleNBFailureMsg + '</pre></td>\n')
self.htmleNBFailureMsg = ''
elif (len(str(self.htmlUEFailureMsg)) > 2):
cellBgColor = 'white'
result = re.search('ended with|faced real time issues', self.htmlUEFailureMsg)
if result is not None:
cellBgColor = 'red'
else:
result = re.search('showed|Could not copy UE logfile|oaitun_ue1 interface is either NOT mounted or NOT configured', self.htmlUEFailureMsg)
if result is not None:
cellBgColor = 'orange'
self.htmlFile.write(' <td bgcolor = "' + cellBgColor + '" colspan=' + str(self.htmlUEConnected) + '><pre style="background-color:' + cellBgColor + '">' + self.htmlUEFailureMsg + '</pre></td>\n')
self.htmlUEFailureMsg = ''
else:
i = 0
while (i < self.htmlUEConnected):
self.htmlFile.write(' <td>-</td>\n')
i += 1
self.htmlFile.write(' </tr>\n')
self.htmlFile.close()
def CreateHtmlTestRowQueue(self, options, status, ue_status, ue_queue):
if ((not self.htmlFooterCreated) and (self.htmlHeaderCreated)):
self.htmlFile = open('test_results.html', 'a')
currentTime = int(round(time.time() * 1000)) - self.startTime
addOrangeBK = False
self.htmlFile.write(' <tr>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" >' + format(currentTime / 1000, '.1f') + '</td>\n')
self.htmlFile.write(' <td bgcolor = "lightcyan" >' + self.testCase_id + '</td>\n')
self.htmlFile.write(' <td>' + self.desc + '</td>\n')
self.htmlFile.write(' <td>' + str(options) + '</td>\n')
if (str(status) == 'OK'):
self.htmlFile.write(' <td bgcolor = "lightgreen" >' + str(status) + '</td>\n')
elif (str(status) == 'KO'):
self.htmlFile.write(' <td bgcolor = "lightcoral" >' + str(status) + '</td>\n')
else:
addOrangeBK = True
self.htmlFile.write(' <td bgcolor = "orange" >' + str(status) + '</td>\n')
i = 0
while (i < self.htmlUEConnected):
if (i < ue_status):
if (not ue_queue.empty()):
if (addOrangeBK):
self.htmlFile.write(' <td bgcolor = "orange" >' + str(ue_queue.get()).replace('white', 'orange') + '</td>\n')
else:
self.htmlFile.write(' <td>' + str(ue_queue.get()) + '</td>\n')
else:
self.htmlFile.write(' <td>-</td>\n')
else:
self.htmlFile.write(' <td>-</td>\n')
i += 1
self.htmlFile.write(' </tr>\n')
self.htmlFile.close()
#/*
# * Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
# * contributor license agreements. See the NOTICE file distributed with
# * this work for additional information regarding copyright ownership.
# * The OpenAirInterface Software Alliance licenses this file to You under
# * the OAI Public License, Version 1.1 (the "License"); you may not use this file
# * except in compliance with the License.
# * You may obtain a copy of the License at
# *
# * http://www.openairinterface.org/?page_id=698
# *
# * Unless required by applicable law or agreed to in writing, software
# * distributed under the License is distributed on an "AS IS" BASIS,
# * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# * See the License for the specific language governing permissions and
# * limitations under the License.
# *-------------------------------------------------------------------------------
# * For more information about the OpenAirInterface (OAI) Software Alliance:
# * contact@openairinterface.org
# */
#---------------------------------------------------------------------
# Python for CI of OAI-eNB + COTS-UE
#
# Required Python Version
# Python 3.x
#
# Required Python Package
# pexpect
#---------------------------------------------------------------------
#-----------------------------------------------------------
# Import
#-----------------------------------------------------------
import sys # arg
import re # reg
import logging
import os
import time
from multiprocessing import Process, Lock, SimpleQueue
#-----------------------------------------------------------
# OAI Testing modules
#-----------------------------------------------------------
import sshconnection as SSH
import epc
import helpreadme as HELP
import constants as CONST
import html
#-----------------------------------------------------------
# Class Declaration
#-----------------------------------------------------------
class RANManagement():
def __init__(self):
self.prematureExit = False
self.ranRepository = ''
self.ranBranch = ''
self.ranAllowMerge = False
self.ranCommitID = ''
self.ranTargetBranch = ''
self.eNBIPAddress = ''
self.eNBUserName = ''
self.eNBPassword = ''
self.eNBSourceCodePath = ''
self.eNB1IPAddress = ''
self.eNB1UserName = ''
self.eNB1Password = ''
self.eNB1SourceCodePath = ''
self.eNB2IPAddress = ''
self.eNB2UserName = ''
self.eNB2Password = ''
self.eNB2SourceCodePath = ''
self.Build_eNB_args = ''
self.backgroundBuild = False
self.backgroundBuildTestId = ['', '', '']
self.Build_eNB_forced_workspace_cleanup = False
self.Initialize_eNB_args = ''
self.air_interface = 'lte'
self.eNB_instance = ''
self.eNB_serverId = ''
self.eNBLogFiles = ['', '', '']
self.eNBOptions = ['', '', '']
self.eNBmbmsEnables = [False, False, False]
self.eNBstatuses = [-1, -1, -1]
self.flexranCtrlInstalled = False
self.flexranCtrlStarted = False
self.testCase_id = ''
self.epcPcapFile = ''
self.htmlObj = None
self.epcObj = None
#-----------------------------------------------------------
# Setters and Getters on Public members
#-----------------------------------------------------------
def SetHtmlObj(self, obj):
self.htmlObj = obj
def SetEpcObj(self, obj):
self.epcObj = obj
def SetflexranCtrlInstalled(self,fxrctin):
self.flexranCtrlInstalled = fxrctin
def GetflexranCtrlInstalled(self):
return self.flexranCtrlInstalled
def SetflexranCtrlStarted(self,fxrctst):
self.flexranCtrlStarted = fxrctst
def GetflexranCtrlStarted(self):
return self.flexranCtrlStarted
def SetpStatus(self, pSt):
self.pStatus = pSt
def SetranRepository(self, repository):
self.ranRepository = repository
def GetranRepository(self):
return self.ranRepository
def SetranBranch(self, branch):
self.ranBranch = branch
def GetranBranch(self):
return self.ranBranch
def SetranCommitID(self, commitid):
self.ranCommitID = commitid
def GetranCommitID(self):
return self.ranCommitID
def SeteNB_serverId(self, enbsrvid):
self.eNB_serverId = enbsrvid
def GeteNB_serverId(self):
return self.eNB_serverId
def SeteNBIPAddress(self, enbip):
self.eNBIPAddress = enbip
def GeteNBIPAddress(self):
return self.eNBIPAddress
def SeteNBUserName(self, enbusr):
self.eNBUserName = enbusr
def GeteNBUserName(self):
return self.eNBUserName
def SeteNBPassword(self, enbpw):
self.eNBPassword = enbpw
def GeteNBPassword(self):
return self.eNBPassword
def SeteNBSourceCodePath(self, enbcodepath):
self.eNBSourceCodePath = enbcodepath
def GeteNBSourceCodePath(self):
return self.eNBSourceCodePath
def SetranAllowMerge(self, merge):
self.ranAllowMerge = merge
def GetranAllowMerge(self):
return self.ranAllowMerge
def SetranTargetBranch(self, tbranch):
self.ranTargetBranch = tbranch
def GetranTargetBranch(self):
return self.ranTargetBranch
def SetBuild_eNB_args(self, enbbuildarg):
self.Build_eNB_args = enbbuildarg
def GetBuild_eNB_args(self):
return self.Build_eNB_args
def SetInitialize_eNB_args(self, initenbarg):
self.Initialize_eNB_args = initenbarg
def GetInitialize_eNB_args(self):
return self.Initialize_eNB_args
def SetbackgroundBuild(self, bkbuild):
self.backgroundBuild = bkbuild
def GetbackgroundBuild(self):
return self.backgroundBuild
def SetbackgroundBuildTestId(self, bkbuildid):
self.backgroundBuildTestId = bkbuildid
def GetbackgroundBuildTestId(self):
return self.backgroundBuildTestId
def SetBuild_eNB_forced_workspace_cleanup(self, fcdwspclean):
self.Build_eNB_forced_workspace_cleanup = fcdwspclean
def GetBuild_eNB_forced_workspace_cleanup(self):
return self.Build_eNB_forced_workspace_cleanup
def Setair_interface(self, airif):
self.air_interface = airif
def Getair_interface(self):
return self.air_interface
def SeteNB_instance(self, enbinst):
self.eNB_instance = enbinst
def GeteNB_instance(self):
return self.eNB_instance
def SeteNBLogFile(self, enblog, idx):
self.eNBLogFiles[idx] = enblog
def GeteNBLogFile(self, idx):
return self.eNBLogFiles[idx]
def GeteNBmbmsEnable(self, idx):
return self.eNBmbmsEnables[idx]
def SeteNB1IPAddress(self,enb1ip):
self.eNB1IPAddress = enb1ip
def GeteNB1IPAddress(self):
return self.eNB1IPAddress
def SeteNB1UserName(self, enb1usr):
self.eNB1UserName = enb1usr
def GeteNB1UserName(self):
return self.eNB1UserName
def SeteNB1Password(self, enb1pw):
self.eNB1Password = enb1pw
def GeteNB1Password(self):
return self.eNB1Password
def SeteNB1SourceCodePath(self, enb1codepath):
self.eNB1SourceCodePath = enb1codepath
def GeteNB1SourceCodePath(self):
return self.eNB1SourceCodePath
def SeteNB2IPAddress(self, enb2ip):
self.eNB2IPAddress = enb2ip
def GeteNB2IPAddress(self):
return self.eNB2IPAddress
def SeteNB2UserName(self, enb2usr):
self.eNB2UserName = enb2usr
def GeteNB2UserName(self):
return self.eNB2UserName
def SeteNB2Password(self, enb2pw):
self.eNB2Password = enb2pw
def GeteNB2Password(self):
return self.eNB2Password
def SeteNB2SourceCodePath(self, enb2codepath):
self.eNB2SourceCodePath = enb2codepath
def GeteNB2SourceCodePath(self):
return self.eNB2SourceCodePath
def SetprematureExit(self, premex):
self.prematureExit = premex
def GetprematureExit(self):
return self.prematureExit
#-----------------------------------------------------------
# RAN management functions
#-----------------------------------------------------------
def BuildeNB(self):
if self.ranRepository == '' or self.ranBranch == '' or self.ranCommitID == '':
HELP.GenericHelp(CONST.Version)
sys.exit('Insufficient Parameter')
if self.eNB_serverId == '0':
lIpAddr = self.eNBIPAddress
lUserName = self.eNBUserName
lPassWord = self.eNBPassword
lSourcePath = self.eNBSourceCodePath
elif self.eNB_serverId == '1':
lIpAddr = self.eNB1IPAddress
lUserName = self.eNB1UserName
lPassWord = self.eNB1Password
lSourcePath = self.eNB1SourceCodePath
elif self.eNB_serverId == '2':
lIpAddr = self.eNB2IPAddress
lUserName = self.eNB2UserName
lPassWord = self.eNB2Password
lSourcePath = self.eNB2SourceCodePath
if lIpAddr == '' or lUserName == '' or lPassWord == '' or lSourcePath == '':
HELP.GenericHelp(CONST.Version)
sys.exit('Insufficient Parameter')
mySSH = SSH.SSHConnection()
mySSH.open(lIpAddr, lUserName, lPassWord)
# Check if we build an 5G-NR gNB or an LTE eNB
result = re.search('--gNB', self.Build_eNB_args)
if result is not None:
self.air_interface = 'nr'
else:
self.air_interface = 'lte'
# Worakround for some servers, we need to erase completely the workspace
if self.Build_eNB_forced_workspace_cleanup:
mySSH.command('echo ' + lPassWord + ' | sudo -S rm -Rf ' + lSourcePath, '\$', 15)
if self.htmlObj is not None:
self.testCase_id = self.htmlObj.GettestCase_id()
else:
self.testCase_id = '000000'
# on RedHat/CentOS .git extension is mandatory
result = re.search('([a-zA-Z0-9\:\-\.\/])+\.git', self.ranRepository)
if result is not None:
full_ran_repo_name = self.ranRepository
else:
full_ran_repo_name = self.ranRepository + '.git'
mySSH.command('mkdir -p ' + lSourcePath, '\$', 5)
mySSH.command('cd ' + lSourcePath, '\$', 5)
mySSH.command('if [ ! -e .git ]; then stdbuf -o0 git clone ' + full_ran_repo_name + ' .; else stdbuf -o0 git fetch --prune; fi', '\$', 600)
# Raphael: here add a check if git clone or git fetch went smoothly
mySSH.command('git config user.email "jenkins@openairinterface.org"', '\$', 5)
mySSH.command('git config user.name "OAI Jenkins"', '\$', 5)
# Checking the BUILD INFO file
if not self.backgroundBuild:
mySSH.command('ls *.txt', '\$', 5)
result = re.search('LAST_BUILD_INFO', mySSH.getBefore())
if result is not None:
mismatch = False
mySSH.command('grep SRC_COMMIT LAST_BUILD_INFO.txt', '\$', 2)
result = re.search(self.ranCommitID, mySSH.getBefore())
if result is None:
mismatch = True
mySSH.command('grep MERGED_W_TGT_BRANCH LAST_BUILD_INFO.txt', '\$', 2)
if (self.ranAllowMerge):
result = re.search('YES', mySSH.getBefore())
if result is None:
mismatch = True
mySSH.command('grep TGT_BRANCH LAST_BUILD_INFO.txt', '\$', 2)
if self.ranTargetBranch == '':
result = re.search('develop', mySSH.getBefore())
else:
result = re.search(self.ranTargetBranch, mySSH.getBefore())
if result is None:
mismatch = True
else:
result = re.search('NO', mySSH.getBefore())
if result is None:
mismatch = True
if not mismatch:
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Build_eNB_args, 'OK', CONST.ALL_PROCESSES_OK)
return
mySSH.command('echo ' + lPassWord + ' | sudo -S git clean -x -d -ff', '\$', 30)
# if the commit ID is provided use it to point to it
if self.ranCommitID != '':
mySSH.command('git checkout -f ' + self.ranCommitID, '\$', 5)
# if the branch is not develop, then it is a merge request and we need to do
# the potential merge. Note that merge conflicts should already been checked earlier
if (self.ranAllowMerge):
if self.ranTargetBranch == '':
if (self.ranBranch != 'develop') and (self.ranBranch != 'origin/develop'):
mySSH.command('git merge --ff origin/develop -m "Temporary merge for CI"', '\$', 5)
else:
logging.debug('Merging with the target branch: ' + self.ranTargetBranch)
mySSH.command('git merge --ff origin/' + self.ranTargetBranch + ' -m "Temporary merge for CI"', '\$', 5)
mySSH.command('source oaienv', '\$', 5)
mySSH.command('cd cmake_targets', '\$', 5)
mySSH.command('mkdir -p log', '\$', 5)
mySSH.command('chmod 777 log', '\$', 5)
# no need to remove in log (git clean did the trick)
if self.backgroundBuild:
mySSH.command('echo "./build_oai ' + self.Build_eNB_args + '" > ./my-lte-softmodem-build.sh', '\$', 5)
mySSH.command('chmod 775 ./my-lte-softmodem-build.sh', '\$', 5)
mySSH.command('echo ' + lPassWord + ' | sudo -S -E daemon --inherit --unsafe --name=build_enb_daemon --chdir=' + lSourcePath + '/cmake_targets -o ' + lSourcePath + '/cmake_targets/compile_oai_enb.log ./my-lte-softmodem-build.sh', '\$', 5)
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Build_eNB_args, 'OK', CONST.ALL_PROCESSES_OK)
self.backgroundBuildTestId[int(self.eNB_instance)] = self.testCase_id
return
mySSH.command('stdbuf -o0 ./build_oai ' + self.Build_eNB_args + ' 2>&1 | stdbuf -o0 tee compile_oai_enb.log', 'Bypassing the Tests|build have failed', 1500)
mySSH.close()
self.checkBuildeNB(lIpAddr, lUserName, lPassWord, lSourcePath, self.testCase_id)
def WaitBuildeNBisFinished(self):
if self.eNB_serverId == '0':
lIpAddr = self.eNBIPAddress
lUserName = self.eNBUserName
lPassWord = self.eNBPassword
lSourcePath = self.eNBSourceCodePath
elif self.eNB_serverId == '1':
lIpAddr = self.eNB1IPAddress
lUserName = self.eNB1UserName
lPassWord = self.eNB1Password
lSourcePath = self.eNB1SourceCodePath
elif self.eNB_serverId == '2':
lIpAddr = self.eNB2IPAddress
lUserName = self.eNB2UserName
lPassWord = self.eNB2Password
lSourcePath = self.eNB2SourceCodePath
if lIpAddr == '' or lUserName == '' or lPassWord == '' or lSourcePath == '':
HELP.GenericHelp(CONST.Version)
sys.exit('Insufficient Parameter')
mySSH = SSH.SSHConnection()
mySSH.open(lIpAddr, lUserName, lPassWord)
count = 40
buildOAIprocess = True
while (count > 0) and buildOAIprocess:
mySSH.command('ps aux | grep --color=never build_ | grep -v grep', '\$', 3)
result = re.search('build_oai', mySSH.getBefore())
if result is None:
buildOAIprocess = False
else:
count -= 1
time.sleep(30)
mySSH.close()
self.checkBuildeNB(lIpAddr, lUserName, lPassWord, lSourcePath, self.backgroundBuildTestId[int(self.eNB_instance)])
def checkBuildeNB(self, lIpAddr, lUserName, lPassWord, lSourcePath, testcaseId):
if self.htmlObj is not None:
self.htmlObj.SettestCase_id(testcaseId)
mySSH = SSH.SSHConnection()
mySSH.open(lIpAddr, lUserName, lPassWord)
mySSH.command('cd ' + lSourcePath + '/cmake_targets', '\$', 3)
mySSH.command('ls ran_build/build', '\$', 3)
mySSH.command('ls ran_build/build', '\$', 3)
if self.air_interface == 'nr':
nodeB_prefix = 'g'
else:
nodeB_prefix = 'e'
buildStatus = True
result = re.search(self.air_interface + '-softmodem', mySSH.getBefore())
if result is None:
buildStatus = False
else:
# Generating a BUILD INFO file
mySSH.command('echo "SRC_BRANCH: ' + self.ranBranch + '" > ../LAST_BUILD_INFO.txt', '\$', 2)
mySSH.command('echo "SRC_COMMIT: ' + self.ranCommitID + '" >> ../LAST_BUILD_INFO.txt', '\$', 2)
if (self.ranAllowMerge):
mySSH.command('echo "MERGED_W_TGT_BRANCH: YES" >> ../LAST_BUILD_INFO.txt', '\$', 2)
if self.ranTargetBranch == '':
mySSH.command('echo "TGT_BRANCH: develop" >> ../LAST_BUILD_INFO.txt', '\$', 2)
else:
mySSH.command('echo "TGT_BRANCH: ' + self.ranTargetBranch + '" >> ../LAST_BUILD_INFO.txt', '\$', 2)
else:
mySSH.command('echo "MERGED_W_TGT_BRANCH: NO" >> ../LAST_BUILD_INFO.txt', '\$', 2)
mySSH.command('mkdir -p build_log_' + testcaseId, '\$', 5)
mySSH.command('mv log/* ' + 'build_log_' + testcaseId, '\$', 5)
mySSH.command('mv compile_oai_enb.log ' + 'build_log_' + testcaseId, '\$', 5)
if self.eNB_serverId != '0':
mySSH.command('cd cmake_targets', '\$', 5)
mySSH.command('if [ -e tmp_build' + testcaseId + '.zip ]; then rm -f tmp_build' + testcaseId + '.zip; fi', '\$', 5)
mySSH.command('zip -r -qq tmp_build' + testcaseId + '.zip build_log_' + testcaseId, '\$', 5)
mySSH.close()
if (os.path.isfile('./tmp_build' + testcaseId + '.zip')):
os.remove('./tmp_build' + testcaseId + '.zip')
mySSH.copyin(lIpAddr, lUserName, lPassWord, lSourcePath + '/cmake_targets/tmp_build' + testcaseId + '.zip', '.')
if (os.path.isfile('./tmp_build' + testcaseId + '.zip')):
mySSH.copyout(self.eNBIPAddress, self.eNBUserName, self.eNBPassword, './tmp_build' + testcaseId + '.zip', self.eNBSourceCodePath + '/cmake_targets/.')
os.remove('./tmp_build' + testcaseId + '.zip')
mySSH.open(self.eNBIPAddress, self.eNBUserName, self.eNBPassword)
mySSH.command('cd ' + self.eNBSourceCodePath + '/cmake_targets', '\$', 5)
mySSH.command('unzip -qq -DD tmp_build' + testcaseId + '.zip', '\$', 5)
mySSH.command('rm -f tmp_build' + testcaseId + '.zip', '\$', 5)
mySSH.close()
else:
mySSH.close()
if buildStatus:
logging.info('\u001B[1m Building OAI ' + nodeB_prefix + 'NB Pass\u001B[0m')
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Build_eNB_args, 'OK', CONST.ALL_PROCESSES_OK)
else:
logging.error('\u001B[1m Building OAI ' + nodeB_prefix + 'NB Failed\u001B[0m')
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Build_eNB_args, 'KO', CONST.ALL_PROCESSES_OK)
self.htmlObj.CreateHtmlTabFooter(False)
sys.exit(1)
def InitializeeNB(self):
if self.eNB_serverId == '0':
lIpAddr = self.eNBIPAddress
lUserName = self.eNBUserName
lPassWord = self.eNBPassword
lSourcePath = self.eNBSourceCodePath
elif self.eNB_serverId == '1':
lIpAddr = self.eNB1IPAddress
lUserName = self.eNB1UserName
lPassWord = self.eNB1Password
lSourcePath = self.eNB1SourceCodePath
elif self.eNB_serverId == '2':
lIpAddr = self.eNB2IPAddress
lUserName = self.eNB2UserName
lPassWord = self.eNB2Password
lSourcePath = self.eNB2SourceCodePath
if lIpAddr == '' or lUserName == '' or lPassWord == '' or lSourcePath == '':
HELP.GenericHelp(CONST.Version)
sys.exit('Insufficient Parameter')
if self.htmlObj is not None:
self.testCase_id = self.htmlObj.GettestCase_id()
else:
self.testCase_id = '000000'
mySSH = SSH.SSHConnection()
if (self.pStatus < 0):
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow(self.Initialize_eNB_args, 'KO', self.pStatus)
self.htmlObj.CreateHtmlTabFooter(False)
sys.exit(1)
# If tracer options is on, running tshark on EPC side and capture traffic b/ EPC and eNB
result = re.search('T_stdout', str(self.Initialize_eNB_args))
if (result is not None) and (self.epcObj is not None):
localEpcIpAddr = self.epcObj.GetIPAddress()
localEpcUserName = self.epcObj.GetUserName()
localEpcPassword = self.epcObj.GetPassword()
mySSH.open(localEpcIpAddr, localEpcUserName, localEpcPassword)
mySSH.command('ip addr show | awk -f /tmp/active_net_interfaces.awk | egrep -v "lo|tun"', '\$', 5)
result = re.search('interfaceToUse=(?P<eth_interface>[a-zA-Z0-9\-\_]+)done', mySSH.getBefore())
if result is not None:
eth_interface = result.group('eth_interface')
logging.debug('\u001B[1m Launching tshark on interface ' + eth_interface + '\u001B[0m')
self.epcPcapFile = 'enb_' + self.testCase_id + '_s1log.pcap'
mySSH.command('echo ' + localEpcPassword + ' | sudo -S rm -f /tmp/' + self.epcPcapFile , '\$', 5)
mySSH.command('echo $USER; nohup sudo tshark -f "host ' + lIpAddr +'" -i ' + eth_interface + ' -w /tmp/' + self.epcPcapFile + ' > /tmp/tshark.log 2>&1 &', localEpcUserName, 5)
mySSH.close()
mySSH.open(lIpAddr, lUserName, lPassWord)
mySSH.command('cd ' + lSourcePath, '\$', 5)
# Initialize_eNB_args usually start with -O and followed by the location in repository
full_config_file = self.Initialize_eNB_args.replace('-O ','')
extra_options = ''
extIdx = full_config_file.find('.conf')
if (extIdx > 0):
extra_options = full_config_file[extIdx + 5:]
# if tracer options is on, compiling and running T Tracer
result = re.search('T_stdout', str(extra_options))
if result is not None:
logging.debug('\u001B[1m Compiling and launching T Tracer\u001B[0m')
mySSH.command('cd common/utils/T/tracer', '\$', 5)
mySSH.command('make', '\$', 10)
mySSH.command('echo $USER; nohup ./record -d ../T_messages.txt -o ' + lSourcePath + '/cmake_targets/enb_' + self.testCase_id + '_record.raw -ON -off VCD -off HEAVY -off LEGACY_GROUP_TRACE -off LEGACY_GROUP_DEBUG > ' + lSourcePath + '/cmake_targets/enb_' + self.testCase_id + '_record.log 2>&1 &', lUserName, 5)
mySSH.command('cd ' + lSourcePath, '\$', 5)
full_config_file = full_config_file[:extIdx + 5]
config_path, config_file = os.path.split(full_config_file)
else:
sys.exit('Insufficient Parameter')
ci_full_config_file = config_path + '/ci-' + config_file
rruCheck = False
result = re.search('^rru|^rcc|^du.band', str(config_file))
if result is not None:
rruCheck = True
# do not reset board twice in IF4.5 case
result = re.search('^rru|^enb|^du.band', str(config_file))
if result is not None:
mySSH.command('echo ' + lPassWord + ' | sudo -S uhd_find_devices', '\$', 60)
result = re.search('type: b200', mySSH.getBefore())
if result is not None:
logging.debug('Found a B2xx device --> resetting it')
mySSH.command('echo ' + lPassWord + ' | sudo -S b2xx_fx3_utils --reset-device', '\$', 10)
# Reloading FGPA bin firmware
mySSH.command('echo ' + lPassWord + ' | sudo -S uhd_find_devices', '\$', 60)
# Make a copy and adapt to EPC / eNB IP addresses
mySSH.command('cp ' + full_config_file + ' ' + ci_full_config_file, '\$', 5)
if self.epcObj is not None:
localMmeIpAddr = self.epcObj.GetMmeIPAddress()
mySSH.command('sed -i -e \'s/CI_MME_IP_ADDR/' + localMmeIpAddr + '/\' ' + ci_full_config_file, '\$', 2);
mySSH.command('sed -i -e \'s/CI_ENB_IP_ADDR/' + lIpAddr + '/\' ' + ci_full_config_file, '\$', 2);
mySSH.command('sed -i -e \'s/CI_RCC_IP_ADDR/' + self.eNBIPAddress + '/\' ' + ci_full_config_file, '\$', 2);
mySSH.command('sed -i -e \'s/CI_RRU1_IP_ADDR/' + self.eNB1IPAddress + '/\' ' + ci_full_config_file, '\$', 2);
mySSH.command('sed -i -e \'s/CI_RRU2_IP_ADDR/' + self.eNB2IPAddress + '/\' ' + ci_full_config_file, '\$', 2);
if self.flexranCtrlInstalled and self.flexranCtrlStarted:
mySSH.command('sed -i -e \'s/FLEXRAN_ENABLED.*;/FLEXRAN_ENABLED = "yes";/\' ' + ci_full_config_file, '\$', 2);
else:
mySSH.command('sed -i -e \'s/FLEXRAN_ENABLED.*;/FLEXRAN_ENABLED = "no";/\' ' + ci_full_config_file, '\$', 2);
self.eNBmbmsEnables[int(self.eNB_instance)] = False
mySSH.command('grep enable_enb_m2 ' + ci_full_config_file, '\$', 2);
result = re.search('yes', mySSH.getBefore())
if result is not None:
self.eNBmbmsEnables[int(self.eNB_instance)] = True
logging.debug('\u001B[1m MBMS is enabled on this eNB\u001B[0m')
result = re.search('noS1', str(self.Initialize_eNB_args))
eNBinNoS1 = False
if result is not None:
eNBinNoS1 = True
logging.debug('\u001B[1m eNB is in noS1 configuration \u001B[0m')
# Launch eNB with the modified config file
mySSH.command('source oaienv', '\$', 5)
mySSH.command('cd cmake_targets', '\$', 5)
mySSH.command('echo "ulimit -c unlimited && ./ran_build/build/' + self.air_interface + '-softmodem -O ' + lSourcePath + '/' + ci_full_config_file + extra_options + '" > ./my-lte-softmodem-run' + str(self.eNB_instance) + '.sh', '\$', 5)
mySSH.command('chmod 775 ./my-lte-softmodem-run' + str(self.eNB_instance) + '.sh', '\$', 5)
mySSH.command('echo ' + lPassWord + ' | sudo -S rm -Rf enb_' + self.testCase_id + '.log', '\$', 5)
mySSH.command('hostnamectl','\$', 5)
result = re.search('CentOS Linux 7', mySSH.getBefore())
if result is not None:
mySSH.command('echo $USER; nohup sudo ./my-lte-softmodem-run' + str(self.eNB_instance) + '.sh > ' + lSourcePath + '/cmake_targets/enb_' + self.testCase_id + '.log 2>&1 &', lUserName, 10)
else:
mySSH.command('echo ' + lPassWord + ' | sudo -S -E daemon --inherit --unsafe --name=enb' + str(self.eNB_instance) + '_daemon --chdir=' + lSourcePath + '/cmake_targets -o ' + lSourcePath + '/cmake_targets/enb_' + self.testCase_id + '.log ./my-lte-softmodem-run' + str(self.eNB_instance) + '.sh', '\$', 5)
self.eNBLogFiles[int(self.eNB_instance)] = 'enb_' + self.testCase_id + '.log'
if extra_options != '':
self.eNBOptions[int(self.eNB_instance)] = extra_options
time.sleep(6)
doLoop = True
loopCounter = 20
enbDidSync = False
while (doLoop):
loopCounter = loopCounter - 1
if (loopCounter == 0):
# In case of T tracer recording, we may need to kill it
result = re.search('T_stdout', str(self.Initialize_eNB_args))
if result is not None:
mySSH.command('killall --signal SIGKILL record', '\$', 5)
mySSH.close()
doLoop = False
logging.error('\u001B[1;37;41m eNB logging system did not show got sync! \u001B[0m')
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('-O ' + config_file + extra_options, 'KO', CONST.ALL_PROCESSES_OK)
# In case of T tracer recording, we need to kill tshark on EPC side
result = re.search('T_stdout', str(self.Initialize_eNB_args))
if (result is not None) and (self.epcObj is not None):
localEpcIpAddr = self.epcObj.GetIPAddress()
localEpcUserName = self.epcObj.GetUserName()
localEpcPassword = self.epcObj.GetPassword()
mySSH.open(localEpcIpAddr, localEpcUserName, localEpcPassword)
logging.debug('\u001B[1m Stopping tshark \u001B[0m')
mySSH.command('echo ' + localEpcPassword + ' | sudo -S killall --signal SIGKILL tshark', '\$', 5)
if self.epcPcapFile != '':
time.sleep(0.5)
mySSH.command('echo ' + localEpcPassword + ' | sudo -S chmod 666 /tmp/' + self.epcPcapFile, '\$', 5)
mySSH.close()
time.sleep(1)
if self.epcPcapFile != '':
copyin_res = mySSH.copyin(localEpcIpAddr, localEpcUserName, localEpcPassword, '/tmp/' + self.epcPcapFile, '.')
if (copyin_res == 0):
mySSH.copyout(lIpAddr, lUserName, lPassWord, self.epcPcapFile, lSourcePath + '/cmake_targets/.')
self.prematureExit = True
return
else:
mySSH.command('stdbuf -o0 cat enb_' + self.testCase_id + '.log | egrep --text --color=never -i "wait|sync|Starting"', '\$', 4)
if rruCheck:
result = re.search('wait RUs', mySSH.getBefore())
else:
result = re.search('got sync|Starting F1AP at CU', mySSH.getBefore())
if result is None:
time.sleep(6)
else:
doLoop = False
enbDidSync = True
time.sleep(10)
if enbDidSync and eNBinNoS1:
mySSH.command('ifconfig oaitun_enb1', '\$', 4)
mySSH.command('ifconfig oaitun_enb1', '\$', 4)
result = re.search('inet addr:1|inet 1', mySSH.getBefore())
if result is not None:
logging.debug('\u001B[1m oaitun_enb1 interface is mounted and configured\u001B[0m')
else:
logging.error('\u001B[1m oaitun_enb1 interface is either NOT mounted or NOT configured\u001B[0m')
if self.eNBmbmsEnables[int(self.eNB_instance)]:
mySSH.command('ifconfig oaitun_enm1', '\$', 4)
result = re.search('inet addr', mySSH.getBefore())
if result is not None:
logging.debug('\u001B[1m oaitun_enm1 interface is mounted and configured\u001B[0m')
else:
logging.error('\u001B[1m oaitun_enm1 interface is either NOT mounted or NOT configured\u001B[0m')
if enbDidSync:
self.eNBstatuses[int(self.eNB_instance)] = int(self.eNB_serverId)
mySSH.close()
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('-O ' + config_file + extra_options, 'OK', CONST.ALL_PROCESSES_OK)
logging.debug('\u001B[1m Initialize eNB Completed\u001B[0m')
def CheckeNBProcess(self, status_queue):
try:
# At least the instance 0 SHALL be on!
if self.eNBstatuses[0] == 0:
lIpAddr = self.eNBIPAddress
lUserName = self.eNBUserName
lPassWord = self.eNBPassword
elif self.eNBstatuses[0] == 1:
lIpAddr = self.eNB1IPAddress
lUserName = self.eNB1UserName
lPassWord = self.eNB1Password
elif self.eNBstatuses[0] == 2:
lIpAddr = self.eNB2IPAddress
lUserName = self.eNB2UserName
lPassWord = self.eNB2Password
else:
lIpAddr = self.eNBIPAddress
lUserName = self.eNBUserName
lPassWord = self.eNBPassword
mySSH = SSH.SSHConnection()
mySSH.open(lIpAddr, lUserName, lPassWord)
mySSH.command('stdbuf -o0 ps -aux | grep --color=never ' + self.air_interface + '-softmodem | grep -v grep', '\$', 5)
result = re.search(self.air_interface + '-softmodem', mySSH.getBefore())
if result is None:
logging.debug('\u001B[1;37;41m eNB Process Not Found! \u001B[0m')
status_queue.put(CONST.ENB_PROCESS_FAILED)
else:
status_queue.put(CONST.ENB_PROCESS_OK)
mySSH.close()
except:
os.kill(os.getppid(),signal.SIGUSR1)
def TerminateeNB(self):
if self.eNB_serverId == '0':
lIpAddr = self.eNBIPAddress
lUserName = self.eNBUserName
lPassWord = self.eNBPassword
lSourcePath = self.eNBSourceCodePath
elif self.eNB_serverId == '1':
lIpAddr = self.eNB1IPAddress
lUserName = self.eNB1UserName
lPassWord = self.eNB1Password
lSourcePath = self.eNB1SourceCodePath
elif self.eNB_serverId == '2':
lIpAddr = self.eNB2IPAddress
lUserName = self.eNB2UserName
lPassWord = self.eNB2Password
lSourcePath = self.eNB2SourceCodePath
if lIpAddr == '' or lUserName == '' or lPassWord == '' or lSourcePath == '':
HELP.GenericHelp(CONST.Version)
sys.exit('Insufficient Parameter')
mySSH = SSH.SSHConnection()
mySSH.open(lIpAddr, lUserName, lPassWord)
mySSH.command('cd ' + lSourcePath + '/cmake_targets', '\$', 5)
if self.air_interface == 'lte':
nodeB_prefix = 'e'
else:
nodeB_prefix = 'g'
mySSH.command('stdbuf -o0 ps -aux | grep --color=never softmodem | grep -v grep', '\$', 5)
result = re.search('-softmodem', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + lPassWord + ' | sudo -S daemon --name=enb' + str(self.eNB_instance) + '_daemon --stop', '\$', 5)
mySSH.command('echo ' + lPassWord + ' | sudo -S killall --signal SIGINT -r .*-softmodem || true', '\$', 5)
time.sleep(10)
mySSH.command('stdbuf -o0 ps -aux | grep --color=never softmodem | grep -v grep', '\$', 5)
result = re.search('-softmodem', mySSH.getBefore())
if result is not None:
mySSH.command('echo ' + lPassWord + ' | sudo -S killall --signal SIGKILL -r .*-softmodem || true', '\$', 5)
time.sleep(5)
mySSH.command('rm -f my-lte-softmodem-run' + str(self.eNB_instance) + '.sh', '\$', 5)
mySSH.close()
# If tracer options is on, stopping tshark on EPC side
result = re.search('T_stdout', str(self.Initialize_eNB_args))
if (result is not None) and (self.epcObj is not None):
localEpcIpAddr = self.epcObj.GetIPAddress()
localEpcUserName = self.epcObj.GetUserName()
localEpcPassword = self.epcObj.GetPassword()
mySSH.open(localEpcIpAddr, localEpcUserName, localEpcPassword)
logging.debug('\u001B[1m Stopping tshark \u001B[0m')
mySSH.command('echo ' + localEpcPassword + ' | sudo -S killall --signal SIGKILL tshark', '\$', 5)
time.sleep(1)
if self.epcPcapFile != '':
mySSH.command('echo ' + localEpcPassword + ' | sudo -S chmod 666 /tmp/' + self.epcPcapFile, '\$', 5)
mySSH.copyin(localEpcIpAddr, localEpcUserName, localEpcPassword, '/tmp/' + self.epcPcapFile, '.')
mySSH.copyout(lIpAddr, lUserName, lPassWord, self.epcPcapFile, lSourcePath + '/cmake_targets/.')
mySSH.close()
logging.debug('\u001B[1m Replaying RAW record file\u001B[0m')
mySSH.open(lIpAddr, lUserName, lPassWord)
mySSH.command('cd ' + lSourcePath + '/common/utils/T/tracer/', '\$', 5)
enbLogFile = self.eNBLogFiles[int(self.eNB_instance)]
raw_record_file = enbLogFile.replace('.log', '_record.raw')
replay_log_file = enbLogFile.replace('.log', '_replay.log')
extracted_txt_file = enbLogFile.replace('.log', '_extracted_messages.txt')
extracted_log_file = enbLogFile.replace('.log', '_extracted_messages.log')
mySSH.command('./extract_config -i ' + lSourcePath + '/cmake_targets/' + raw_record_file + ' > ' + lSourcePath + '/cmake_targets/' + extracted_txt_file, '\$', 5)
mySSH.command('echo $USER; nohup ./replay -i ' + lSourcePath + '/cmake_targets/' + raw_record_file + ' > ' + lSourcePath + '/cmake_targets/' + replay_log_file + ' 2>&1 &', lUserName, 5)
mySSH.command('./textlog -d ' + lSourcePath + '/cmake_targets/' + extracted_txt_file + ' -no-gui -ON -full > ' + lSourcePath + '/cmake_targets/' + extracted_log_file, '\$', 5)
mySSH.close()
mySSH.copyin(lIpAddr, lUserName, lPassWord, lSourcePath + '/cmake_targets/' + extracted_log_file, '.')
logging.debug('\u001B[1m Analyzing eNB replay logfile \u001B[0m')
logStatus = self.AnalyzeLogFile_eNB(extracted_log_file)
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('N/A', 'OK', CONST.ALL_PROCESSES_OK)
self.eNBLogFiles[int(self.eNB_instance)] = ''
else:
analyzeFile = False
if self.eNBLogFiles[int(self.eNB_instance)] != '':
analyzeFile = True
fileToAnalyze = self.eNBLogFiles[int(self.eNB_instance)]
self.eNBLogFiles[int(self.eNB_instance)] = ''
if analyzeFile:
copyin_res = mySSH.copyin(lIpAddr, lUserName, lPassWord, lSourcePath + '/cmake_targets/' + fileToAnalyze, '.')
if (copyin_res == -1):
logging.debug('\u001B[1;37;41m Could not copy ' + nodeB_prefix + 'NB logfile to analyze it! \u001B[0m')
if self.htmlObj is not None:
self.htmlObj.SetHmleNBFailureMsg('Could not copy ' + nodeB_prefix + 'NB logfile to analyze it!')
self.htmlObj.CreateHtmlTestRow('N/A', 'KO', CONST.ENB_PROCESS_NOLOGFILE_TO_ANALYZE)
self.eNBmbmsEnables[int(self.eNB_instance)] = False
return
if self.eNB_serverId != '0':
mySSH.copyout(self.eNBIPAddress, self.eNBUserName, self.eNBPassword, './' + fileToAnalyze, self.eNBSourceCodePath + '/cmake_targets/')
logging.debug('\u001B[1m Analyzing ' + nodeB_prefix + 'NB logfile \u001B[0m ' + fileToAnalyze)
logStatus = self.AnalyzeLogFile_eNB(fileToAnalyze)
if (logStatus < 0):
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('N/A', 'KO', logStatus)
self.preamtureExit = True
self.eNBmbmsEnables[int(self.eNB_instance)] = False
return
else:
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('N/A', 'OK', CONST.ALL_PROCESSES_OK)
else:
if self.htmlObj is not None:
self.htmlObj.CreateHtmlTestRow('N/A', 'OK', CONST.ALL_PROCESSES_OK)
self.eNBmbmsEnables[int(self.eNB_instance)] = False
self.eNBstatuses[int(self.eNB_instance)] = -1
def LogCollecteNB(self):
mySSH = SSH.SSHConnection()
mySSH.open(self.eNBIPAddress, self.eNBUserName, self.eNBPassword)
mySSH.command('cd ' + self.eNBSourceCodePath, '\$', 5)
mySSH.command('cd cmake_targets', '\$', 5)
mySSH.command('echo ' + self.eNBPassword + ' | sudo -S rm -f enb.log.zip', '\$', 5)
mySSH.command('echo ' + self.eNBPassword + ' | sudo -S zip enb.log.zip enb*.log core* enb_*record.raw enb_*.pcap enb_*txt', '\$', 60)
mySSH.command('echo ' + self.eNBPassword + ' | sudo -S rm enb*.log core* enb_*record.raw enb_*.pcap enb_*txt', '\$', 5)
mySSH.close()
def AnalyzeLogFile_eNB(self, eNBlogFile):
if (not os.path.isfile('./' + eNBlogFile)):
return -1
enb_log_file = open('./' + eNBlogFile, 'r')
exitSignalReceived = False
foundAssertion = False
msgAssertion = ''
msgLine = 0
foundSegFault = False
foundRealTimeIssue = False
rrcSetupComplete = 0
rrcReleaseRequest = 0
rrcReconfigRequest = 0
rrcReconfigComplete = 0
rrcReestablishRequest = 0
rrcReestablishComplete = 0
rrcReestablishReject = 0
rlcDiscardBuffer = 0
rachCanceledProcedure = 0
uciStatMsgCount = 0
pdcpFailure = 0
ulschFailure = 0
ulschReceiveOK = 0
gnbRxTxWakeUpFailure = 0
cdrxActivationMessageCount = 0
dropNotEnoughRBs = 0
mbmsRequestMsg = 0
htmleNBFailureMsg = ''
isRRU = False
isSlave = False
slaveReceivesFrameResyncCmd = False
X2HO_state = CONST.X2_HO_REQ_STATE__IDLE
X2HO_inNbProcedures = 0
X2HO_outNbProcedures = 0
for line in enb_log_file.readlines():
if X2HO_state == CONST.X2_HO_REQ_STATE__IDLE:
result = re.search('target eNB Receives X2 HO Req X2AP_HANDOVER_REQ', str(line))
if result is not None:
X2HO_state = CONST.X2_HO_REQ_STATE__TARGET_RECEIVES_REQ
result = re.search('source eNB receives the X2 HO ACK X2AP_HANDOVER_REQ_ACK', str(line))
if result is not None:
X2HO_state = CONST.X2_HO_REQ_STATE__SOURCE_RECEIVES_REQ_ACK
if X2HO_state == CONST.X2_HO_REQ_STATE__TARGET_RECEIVES_REQ:
result = re.search('Received LTE_RRCConnectionReconfigurationComplete from UE', str(line))
if result is not None:
X2HO_state = CONST.X2_HO_REQ_STATE__TARGET_RRC_RECFG_COMPLETE
if X2HO_state == CONST.X2_HO_REQ_STATE__TARGET_RRC_RECFG_COMPLETE:
result = re.search('issue rrc_eNB_send_PATH_SWITCH_REQ', str(line))
if result is not None:
X2HO_state = CONST.X2_HO_REQ_STATE__TARGET_SENDS_SWITCH_REQ
if X2HO_state == CONST.X2_HO_REQ_STATE__TARGET_SENDS_SWITCH_REQ:
result = re.search('received path switch ack S1AP_PATH_SWITCH_REQ_ACK', str(line))
if result is not None:
X2HO_state = CONST.X2_HO_REQ_STATE__IDLE
X2HO_inNbProcedures += 1
if X2HO_state == CONST.X2_HO_REQ_STATE__SOURCE_RECEIVES_REQ_ACK:
result = re.search('source eNB receives the X2 UE CONTEXT RELEASE X2AP_UE_CONTEXT_RELEASE', str(line))
if result is not None:
X2HO_state = CONST.X2_HO_REQ_STATE__IDLE
X2HO_outNbProcedures += 1
if self.eNBOptions[int(self.eNB_instance)] != '':
res1 = re.search('max_rxgain (?P<requested_option>[0-9]+)', self.eNBOptions[int(self.eNB_instance)])
res2 = re.search('max_rxgain (?P<applied_option>[0-9]+)', str(line))
if res1 is not None and res2 is not None:
requested_option = int(res1.group('requested_option'))
applied_option = int(res2.group('applied_option'))
if requested_option == applied_option:
htmleNBFailureMsg += '<span class="glyphicon glyphicon-ok-circle"></span> Command line option(s) correctly applied <span class="glyphicon glyphicon-arrow-right"></span> ' + self.eNBOptions[int(self.eNB_instance)] + '\n\n'
else:
htmleNBFailureMsg += '<span class="glyphicon glyphicon-ban-circle"></span> Command line option(s) NOT applied <span class="glyphicon glyphicon-arrow-right"></span> ' + self.eNBOptions[int(self.eNB_instance)] + '\n\n'
result = re.search('Exiting OAI softmodem', str(line))
if result is not None:
exitSignalReceived = True
result = re.search('[Ss]egmentation [Ff]ault', str(line))
if result is not None and not exitSignalReceived:
foundSegFault = True
result = re.search('[Cc]ore [dD]ump', str(line))
if result is not None and not exitSignalReceived:
foundSegFault = True
result = re.search('./ran_build/build/lte-softmodem', str(line))
if result is not None and not exitSignalReceived:
foundSegFault = True
result = re.search('[Aa]ssertion', str(line))
if result is not None and not exitSignalReceived:
foundAssertion = True
result = re.search('LLL', str(line))
if result is not None and not exitSignalReceived:
foundRealTimeIssue = True
if foundAssertion and (msgLine < 3):
msgLine += 1
msgAssertion += str(line)
result = re.search('Setting function for RU', str(line))
if result is not None:
isRRU = True
if isRRU:
result = re.search('RU 0 is_slave=yes', str(line))
if result is not None:
isSlave = True
if isSlave:
result = re.search('Received RRU_frame_resynch command', str(line))
if result is not None:
slaveReceivesFrameResyncCmd = True
result = re.search('LTE_RRCConnectionSetupComplete from UE', str(line))
if result is not None:
rrcSetupComplete += 1
result = re.search('Generate LTE_RRCConnectionRelease|Generate RRCConnectionRelease', str(line))
if result is not None:
rrcReleaseRequest += 1
result = re.search('Generate LTE_RRCConnectionReconfiguration', str(line))
if result is not None:
rrcReconfigRequest += 1
result = re.search('LTE_RRCConnectionReconfigurationComplete from UE rnti', str(line))
if result is not None:
rrcReconfigComplete += 1
result = re.search('LTE_RRCConnectionReestablishmentRequest', str(line))
if result is not None:
rrcReestablishRequest += 1
result = re.search('LTE_RRCConnectionReestablishmentComplete', str(line))
if result is not None:
rrcReestablishComplete += 1
result = re.search('LTE_RRCConnectionReestablishmentReject', str(line))
if result is not None:
rrcReestablishReject += 1
result = re.search('CDRX configuration activated after RRC Connection', str(line))
if result is not None:
cdrxActivationMessageCount += 1
result = re.search('uci->stat', str(line))
if result is not None:
uciStatMsgCount += 1
result = re.search('PDCP.*Out of Resources.*reason', str(line))
if result is not None:
pdcpFailure += 1
result = re.search('could not wakeup gNB rxtx process', str(line))
if result is not None:
gnbRxTxWakeUpFailure += 1
result = re.search('ULSCH in error in round|ULSCH 0 in error', str(line))
if result is not None:
ulschFailure += 1
result = re.search('ULSCH received ok', str(line))
if result is not None:
ulschReceiveOK += 1
result = re.search('BAD all_segments_received', str(line))
if result is not None:
rlcDiscardBuffer += 1
result = re.search('Canceled RA procedure for UE rnti', str(line))
if result is not None:
rachCanceledProcedure += 1
result = re.search('dropping, not enough RBs', str(line))
if result is not None:
dropNotEnoughRBs += 1
if self.eNBmbmsEnables[int(self.eNB_instance)]:
result = re.search('MBMS USER-PLANE.*Requesting.*bytes from RLC', str(line))
if result is not None:
mbmsRequestMsg += 1
enb_log_file.close()
logging.debug(' File analysis completed')
if self.air_interface == 'lte':
nodeB_prefix = 'e'
else:
nodeB_prefix = 'g'
if self.air_interface == 'nr':
if ulschReceiveOK > 0:
statMsg = nodeB_prefix + 'NB showed ' + str(ulschReceiveOK) + ' "ULSCH received ok" message(s)'
logging.debug('\u001B[1;30;43m ' + statMsg + ' \u001B[0m')
htmleNBFailureMsg += statMsg + '\n'
if gnbRxTxWakeUpFailure > 0:
statMsg = nodeB_prefix + 'NB showed ' + str(gnbRxTxWakeUpFailure) + ' "could not wakeup gNB rxtx process" message(s)'
logging.debug('\u001B[1;30;43m ' + statMsg + ' \u001B[0m')
htmleNBFailureMsg += statMsg + '\n'
if uciStatMsgCount > 0:
statMsg = nodeB_prefix + 'NB showed ' + str(uciStatMsgCount) + ' "uci->stat" message(s)'
logging.debug('\u001B[1;30;43m ' + statMsg + ' \u001B[0m')
htmleNBFailureMsg += statMsg + '\n'
if pdcpFailure > 0:
statMsg = nodeB_prefix + 'NB showed ' + str(pdcpFailure) + ' "PDCP Out of Resources" message(s)'
logging.debug('\u001B[1;30;43m ' + statMsg + ' \u001B[0m')
htmleNBFailureMsg += statMsg + '\n'
if ulschFailure > 0:
statMsg = nodeB_prefix + 'NB showed ' + str(ulschFailure) + ' "ULSCH in error in round" message(s)'
logging.debug('\u001B[1;30;43m ' + statMsg + ' \u001B[0m')
htmleNBFailureMsg += statMsg + '\n'
if dropNotEnoughRBs > 0:
statMsg = 'eNB showed ' + str(dropNotEnoughRBs) + ' "dropping, not enough RBs" message(s)'
logging.debug('\u001B[1;30;43m ' + statMsg + ' \u001B[0m')
htmleNBFailureMsg += statMsg + '\n'
if rrcSetupComplete > 0:
rrcMsg = nodeB_prefix + 'NB completed ' + str(rrcSetupComplete) + ' RRC Connection Setup(s)'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
rrcMsg = ' -- ' + str(rrcSetupComplete) + ' were completed'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if rrcReleaseRequest > 0:
rrcMsg = nodeB_prefix + 'NB requested ' + str(rrcReleaseRequest) + ' RRC Connection Release(s)'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if rrcReconfigRequest > 0 or rrcReconfigComplete > 0:
rrcMsg = nodeB_prefix + 'NB requested ' + str(rrcReconfigRequest) + ' RRC Connection Reconfiguration(s)'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
rrcMsg = ' -- ' + str(rrcReconfigComplete) + ' were completed'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if rrcReestablishRequest > 0 or rrcReestablishComplete > 0 or rrcReestablishReject > 0:
rrcMsg = nodeB_prefix + 'NB requested ' + str(rrcReestablishRequest) + ' RRC Connection Reestablishment(s)'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
rrcMsg = ' -- ' + str(rrcReestablishComplete) + ' were completed'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
rrcMsg = ' -- ' + str(rrcReestablishReject) + ' were rejected'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if self.eNBmbmsEnables[int(self.eNB_instance)]:
if mbmsRequestMsg > 0:
rrcMsg = 'eNB requested ' + str(mbmsRequestMsg) + ' times the RLC for MBMS USER-PLANE'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if X2HO_inNbProcedures > 0:
rrcMsg = 'eNB completed ' + str(X2HO_inNbProcedures) + ' X2 Handover Connection procedure(s)'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if X2HO_outNbProcedures > 0:
rrcMsg = 'eNB completed ' + str(X2HO_outNbProcedures) + ' X2 Handover Release procedure(s)'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if self.eNBOptions[int(self.eNB_instance)] != '':
res1 = re.search('drx_Config_present prSetup', self.eNBOptions[int(self.eNB_instance)])
if res1 is not None:
if cdrxActivationMessageCount > 0:
rrcMsg = 'eNB activated the CDRX Configuration for ' + str(cdrxActivationMessageCount) + ' time(s)'
logging.debug('\u001B[1;30;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
else:
rrcMsg = 'eNB did NOT ACTIVATE the CDRX Configuration'
logging.debug('\u001B[1;37;43m ' + rrcMsg + ' \u001B[0m')
htmleNBFailureMsg += rrcMsg + '\n'
if rachCanceledProcedure > 0:
rachMsg = nodeB_prefix + 'NB cancelled ' + str(rachCanceledProcedure) + ' RA procedure(s)'
logging.debug('\u001B[1;30;43m ' + rachMsg + ' \u001B[0m')
htmleNBFailureMsg += rachMsg + '\n'
if isRRU:
if isSlave:
if slaveReceivesFrameResyncCmd:
rruMsg = 'Slave RRU received the RRU_frame_resynch command from RAU'
logging.debug('\u001B[1;30;43m ' + rruMsg + ' \u001B[0m')
htmleNBFailureMsg += rruMsg + '\n'
else:
rruMsg = 'Slave RRU DID NOT receive the RRU_frame_resynch command from RAU'
logging.debug('\u001B[1;37;41m ' + rruMsg + ' \u001B[0m')
htmleNBFailureMsg += rruMsg + '\n'
self.prematureExit(True)
return CONST.ENB_PROCESS_SLAVE_RRU_NOT_SYNCED
if foundSegFault:
logging.debug('\u001B[1;37;41m ' + nodeB_prefix + 'NB ended with a Segmentation Fault! \u001B[0m')
if self.htmlObj is not None:
self.htmlObj.SetHmleNBFailureMsg(htmleNBFailureMsg)
return CONST.ENB_PROCESS_SEG_FAULT
if foundAssertion:
logging.debug('\u001B[1;37;41m ' + nodeB_prefix + 'NB ended with an assertion! \u001B[0m')
htmleNBFailureMsg += msgAssertion
if self.htmlObj is not None:
self.htmlObj.SetHmleNBFailureMsg(htmleNBFailureMsg)
return CONST.ENB_PROCESS_ASSERTION
if foundRealTimeIssue:
logging.debug('\u001B[1;37;41m ' + nodeB_prefix + 'NB faced real time issues! \u001B[0m')
htmleNBFailureMsg += nodeB_prefix + 'NB faced real time issues!\n'
#return CONST.ENB_PROCESS_REALTIME_ISSUE
if rlcDiscardBuffer > 0:
rlcMsg = nodeB_prefix + 'NB RLC discarded ' + str(rlcDiscardBuffer) + ' buffer(s)'
logging.debug('\u001B[1;37;41m ' + rlcMsg + ' \u001B[0m')
htmleNBFailureMsg += rlcMsg + '\n'
if self.htmlObj is not None:
self.htmlObj.SetHmleNBFailureMsg(htmleNBFailureMsg)
return CONST.ENB_PROCESS_REALTIME_ISSUE
if self.htmlObj is not None:
self.htmlObj.SetHmleNBFailureMsg(htmleNBFailureMsg)
return 0
#/*
# * Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
# * contributor license agreements. See the NOTICE file distributed with
# * this work for additional information regarding copyright ownership.
# * The OpenAirInterface Software Alliance licenses this file to You under
# * the OAI Public License, Version 1.1 (the "License"); you may not use this file
# * except in compliance with the License.
# * You may obtain a copy of the License at
# *
# * http://www.openairinterface.org/?page_id=698
# *
# * Unless required by applicable law or agreed to in writing, software
# * distributed under the License is distributed on an "AS IS" BASIS,
# * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# * See the License for the specific language governing permissions and
# * limitations under the License.
# *-------------------------------------------------------------------------------
# * For more information about the OpenAirInterface (OAI) Software Alliance:
# * contact@openairinterface.org
# */
#---------------------------------------------------------------------
# Python for CI of OAI-eNB + COTS-UE
#
# Required Python Version
# Python 3.x
#
# Required Python Package
# pexpect
#---------------------------------------------------------------------
#-----------------------------------------------------------
# Import
#-----------------------------------------------------------
import pexpect # pexpect
import logging
import time # sleep
import re
import sys
#-----------------------------------------------------------
# Class Declaration
#-----------------------------------------------------------
class SSHConnection():
def __init__(self):
self.ssh = ''
self.picocom_closure = False
def disablePicocomClosure(self):
self.picocom_closure = False
def enablePicocomClosure(self):
self.picocom_closure = True
def open(self, ipaddress, username, password):
extraSshOptions = ''
count = 0
connect_status = False
if ipaddress == '192.168.18.197':
extraSshOptions = ' -o UserKnownHostsFile=/dev/null -o StrictHostKeyChecking=no'
while count < 4:
self.ssh = pexpect.spawn('ssh', [username + '@' + ipaddress + extraSshOptions], timeout = 5)
self.sshresponse = self.ssh.expect(['Are you sure you want to continue connecting (yes/no)?', 'password:', 'Last login', pexpect.EOF, pexpect.TIMEOUT])
if self.sshresponse == 0:
self.ssh.sendline('yes')
self.sshresponse = self.ssh.expect(['password:', username + '@'])
if self.sshresponse == 0:
self.ssh.sendline(password)
self.sshresponse = self.ssh.expect(['\$', 'Permission denied', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if self.sshresponse == 0:
count = 10
connect_status = True
else:
logging.debug('self.sshresponse = ' + str(self.sshresponse))
elif self.sshresponse == 1:
self.ssh.sendline(password)
self.sshresponse = self.ssh.expect(['\$', 'Permission denied', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if self.sshresponse == 0:
count = 10
connect_status = True
else:
logging.debug('self.sshresponse = ' + str(self.sshresponse))
elif self.sshresponse == 2:
# Checking if we are really on the remote client defined by its IP address
self.command('stdbuf -o0 ifconfig | egrep --color=never "inet addr:|inet "', '\$', 5)
result = re.search(str(ipaddress), str(self.ssh.before))
if result is None:
self.close()
else:
count = 10
connect_status = True
else:
# debug output
logging.debug(str(self.ssh.before))
logging.debug('self.sshresponse = ' + str(self.sshresponse))
# adding a tempo when failure
if not connect_status:
time.sleep(1)
count += 1
if connect_status:
pass
else:
sys.exit('SSH Connection Failed')
def command(self, commandline, expectedline, timeout):
logging.debug(commandline)
self.ssh.timeout = timeout
self.ssh.sendline(commandline)
self.sshresponse = self.ssh.expect([expectedline, pexpect.EOF, pexpect.TIMEOUT])
if self.sshresponse == 0:
return 0
elif self.sshresponse == 1:
logging.debug('\u001B[1;37;41m Unexpected EOF \u001B[0m')
logging.debug('Expected Line : ' + expectedline)
logging.debug(str(self.ssh.before))
sys.exit(self.sshresponse)
elif self.sshresponse == 2:
logging.debug('\u001B[1;37;41m Unexpected TIMEOUT \u001B[0m')
logging.debug('Expected Line : ' + expectedline)
result = re.search('ping |iperf |picocom', str(commandline))
if result is None:
logging.debug(str(self.ssh.before))
sys.exit(self.sshresponse)
else:
return -1
else:
logging.debug('\u001B[1;37;41m Unexpected Others \u001B[0m')
logging.debug('Expected Line : ' + expectedline)
sys.exit(self.sshresponse)
def close(self):
self.ssh.timeout = 5
self.ssh.sendline('exit')
self.sshresponse = self.ssh.expect([pexpect.EOF, pexpect.TIMEOUT])
if self.sshresponse == 0:
pass
elif self.sshresponse == 1:
if not self.picocom_closure:
logging.debug('\u001B[1;37;41m Unexpected TIMEOUT during closing\u001B[0m')
else:
logging.debug('\u001B[1;37;41m Unexpected Others during closing\u001B[0m')
def copyin(self, ipaddress, username, password, source, destination):
count = 0
copy_status = False
logging.debug('scp '+ username + '@' + ipaddress + ':' + source + ' ' + destination)
while count < 10:
scp_spawn = pexpect.spawn('scp '+ username + '@' + ipaddress + ':' + source + ' ' + destination, timeout = 100)
scp_response = scp_spawn.expect(['Are you sure you want to continue connecting (yes/no)?', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if scp_response == 0:
scp_spawn.sendline('yes')
scp_spawn.expect('password:')
scp_spawn.sendline(password)
scp_response = scp_spawn.expect(['\$', 'Permission denied', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if scp_response == 0:
count = 10
copy_status = True
else:
logging.debug('1 - scp_response = ' + str(scp_response))
elif scp_response == 1:
scp_spawn.sendline(password)
scp_response = scp_spawn.expect(['\$', 'Permission denied', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if scp_response == 0 or scp_response == 3:
count = 10
copy_status = True
else:
logging.debug('2 - scp_response = ' + str(scp_response))
elif scp_response == 2:
count = 10
copy_status = True
else:
logging.debug('3 - scp_response = ' + str(scp_response))
# adding a tempo when failure
if not copy_status:
time.sleep(1)
count += 1
if copy_status:
return 0
else:
return -1
def copyout(self, ipaddress, username, password, source, destination):
count = 0
copy_status = False
logging.debug('scp ' + source + ' ' + username + '@' + ipaddress + ':' + destination)
while count < 4:
scp_spawn = pexpect.spawn('scp ' + source + ' ' + username + '@' + ipaddress + ':' + destination, timeout = 100)
scp_response = scp_spawn.expect(['Are you sure you want to continue connecting (yes/no)?', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if scp_response == 0:
scp_spawn.sendline('yes')
scp_spawn.expect('password:')
scp_spawn.sendline(password)
scp_response = scp_spawn.expect(['\$', 'Permission denied', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if scp_response == 0:
count = 10
copy_status = True
else:
logging.debug('1 - scp_response = ' + str(scp_response))
elif scp_response == 1:
scp_spawn.sendline(password)
scp_response = scp_spawn.expect(['\$', 'Permission denied', 'password:', pexpect.EOF, pexpect.TIMEOUT])
if scp_response == 0 or scp_response == 3:
count = 10
copy_status = True
else:
logging.debug('2 - scp_response = ' + str(scp_response))
elif scp_response == 2:
count = 10
copy_status = True
else:
logging.debug('3 - scp_response = ' + str(scp_response))
# adding a tempo when failure
if not copy_status:
time.sleep(1)
count += 1
if copy_status:
pass
else:
sys.exit('SCP failed')
def getBefore(self):
return str(self.ssh.before)
...@@ -2825,6 +2825,7 @@ target_link_libraries(smallblocktest ...@@ -2825,6 +2825,7 @@ target_link_libraries(smallblocktest
m pthread ${ATLAS_LIBRARIES} dl m pthread ${ATLAS_LIBRARIES} dl
) )
<<<<<<< HEAD
################################################### ###################################################
# For CUDA library # For CUDA library
################################################### ###################################################
...@@ -2833,10 +2834,15 @@ CUDA_ADD_LIBRARY(LDPC_CU ...@@ -2833,10 +2834,15 @@ CUDA_ADD_LIBRARY(LDPC_CU
) )
CUDA_ADD_CUFFT_TO_TARGET(LDPC_CU) CUDA_ADD_CUFFT_TO_TARGET(LDPC_CU)
cuda_add_executable(ldpctest cuda_add_executable(ldpctest
=======
add_executable(ldpctest
${PHY_NR_CODINGIF}
>>>>>>> origin/develop
${OPENAIR1_DIR}/PHY/CODING/TESTBENCH/ldpctest.c ${OPENAIR1_DIR}/PHY/CODING/TESTBENCH/ldpctest.c
${T_SOURCE} ${T_SOURCE}
${SHLIB_LOADER_SOURCES} ${SHLIB_LOADER_SOURCES}
) )
<<<<<<< HEAD
target_link_libraries(ldpctest -ldl target_link_libraries(ldpctest -ldl
-Wl,--start-group -Wl,--start-group
...@@ -2851,6 +2857,8 @@ target_link_libraries(ldpctest -ldl ...@@ -2851,6 +2857,8 @@ target_link_libraries(ldpctest -ldl
# ${T_SOURCE} # ${T_SOURCE}
# ${SHLIB_LOADER_SOURCES} # ${SHLIB_LOADER_SOURCES}
# ) # )
=======
>>>>>>> origin/develop
add_dependencies( ldpctest ldpc_orig ldpc_optim ldpc_optim8seg ldpc ) add_dependencies( ldpctest ldpc_orig ldpc_optim ldpc_optim8seg ldpc )
target_link_libraries(ldpctest target_link_libraries(ldpctest
......
#!/bin/bash
# use UP and DOWN arrow keys to scroll the view displayed by timeplot
while read -n 1 key
do
case "$key" in
'B' )
kill -SIGUSR1 `ps aux|grep timeplot|grep -v grep|grep -v sh|tr -s ' ' :|cut -f 2 -d :`
;;
'A' )
kill -SIGUSR2 `ps aux|grep timeplot|grep -v grep|grep -v sh|tr -s ' ' :|cut -f 2 -d :`
;;
esac
done
<table style="border-collapse: collapse; border: none;">
<tr style="border-collapse: collapse; border: none;">
<td style="border-collapse: collapse; border: none;">
<a href="http://www.openairinterface.org/">
<img src="./images/oai_final_logo.png" alt="" border=3 height=50 width=150>
</img>
</a>
</td>
<td style="border-collapse: collapse; border: none; vertical-align: center;">
<b><font size = "5">L2 nFAPI Simulator (no S1 Mode / 2-host deployment)</font></b>
</td>
</tr>
</table>
## Table of Contents ##
1. [Environment](#1-environment)
2. [Retrieve the OAI eNB-UE source code](#2-retrieve-the-oai-enb-ue-source-code)
3. [Setup of the USIM information in UE folder](#3-setup-of-the-usim-information-in-ue-folder)
4. [Setup of the Configuration files](#4-setup-of-the-configuration-files)
1. [The eNB Configuration file](#41-the-enb-configuration-file)
2. [The UE Configuration file](#42-the-ue-configuration-file)
5. [Build OAI UE and eNodeB](#5-build-oai-ue-and-enodeb)
6. [Start the eNB](#6-start-the-enb)
7. [Start the UE](#7-start-the-ue)
8. [Test with ping](#8-test-with-ping)
9. [Limitations](#9-limitations)
# 1. Environment #
You may not have access to an EPC or you don't want to hassle to deploy one.
2 servers are used in this deployment. You can use Virtual Machines instead of each server; like it is done in the CI process.
* Machine B contains the OAI eNB executable (`lte-softmodem`)
* Machine C contains the OAI UE(s) executable (`lte-uesoftmodem`)
Example of L2 nFAPI Simulator testing environment:
<img src="./images/L2-sim-noS1-2-host-deployment.png" alt="" border=3>
Note that the IP addresses are indicative and need to be adapted to your environment.
# 2. Retrieve the OAI eNB-UE source code #
At the time of writing, the tag used in the `develop` branch to do this documentation was `2020.w16`.
The tutorial should be valid for the `master` branch tags such as `v1.2.0` or `v1.2.1`. But you may face issues that could be fixed in newer `develop` tags.
Please try to use the same commit ID on both eNB/UE hosts.
```bash
$ ssh sudousername@machineB
git clone https://gitlab.eurecom.fr/oai/openairinterface5g.git enb_folder
cd enb_folder
git checkout develop
```
```bash
$ ssh sudousername@machineC
git clone https://gitlab.eurecom.fr/oai/openairinterface5g.git ue_folder
cd ue_folder
git checkout develop
```
# 3. Setup of the USIM information in UE folder #
```bash
$ ssh sudousername@machineC
cd ue_folder
# Edit openair3/NAS/TOOLS/ue_eurecom_test_sfr.conf with your preferred editor
```
Edit the USIM information within this file in order to match the HSS database. They **HAVE TO** match:
* PLMN+MSIN and IMSI of users table of HSS database **SHALL** be the same.
* OPC of this file and OPC of users table of HSS database **SHALL** be the same.
* USIM_API_K of this file and the key of users table of HSS database **SHALL** be the same.
When testing multiple UEs, it is necessary to add other UEs information like described below for 2 Users. Only UE0 (first UE) information is written in the original file.
```
UE0:
{
USER: {
IMEI="356113022094149";
MANUFACTURER="EURECOM";
MODEL="LTE Android PC";
PIN="0000";
};
SIM: {
MSIN="0000000001"; // <-- Modify here
USIM_API_K="8baf473f2f8fd09487cccbd7097c6862";
OPC="e734f8734007d6c5ce7a0508809e7e9c";
MSISDN="33611123456";
};
...
};
// Copy the UE0 and edit
UE1: // <- Edit here
{
USER: {
IMEI="356113022094149";
MANUFACTURER="EURECOM";
MODEL="LTE Android PC";
PIN="0000";
};
SIM: {
MSIN="0000000002"; // <-- Modify here
USIM_API_K="8baf473f2f8fd09487cccbd7097c6862";
OPC="e734f8734007d6c5ce7a0508809e7e9c";
MSISDN="33611123456";
};
...
};
```
You can repeat the operation for as many users you want to test with.
# 4. Setup of the Configuration files #
**CAUTION: both proposed configuration files resides in the ci-scripts realm. You can copy them but you CANNOT push any modification on these 2 files as part of an MR without informing the CI team.**
## 4.1. The eNB Configuration file ##
```bash
$ ssh sudousername@machineB
cd enb_folder
# Edit ci-scripts/conf_files/rcc.band7.tm1.nfapi.conf with your preferred editor
```
First verify the nFAPI interface setup on the physical ethernet interface of machineB and put the proper IP addresses for both hosts.
```
MACRLCs = (
{
num_cc = 1;
local_s_if_name = "ens3"; // <-- HERE
remote_s_address = "192.168.122.169"; // <-- HERE
local_s_address = "192.168.122.31"; // <-- HERE
local_s_portc = 50001;
remote_s_portc = 50000;
local_s_portd = 50011;
remote_s_portd = 50010;
tr_s_preference = "nfapi";
tr_n_preference = "local_RRC";
}
);
```
If you are testing more than 16 UEs, a proper setting on the RUs is necessary. **Note that this part is NOT present in the original configuration file**.
```
RUs = (
{
local_rf = "yes"
nb_tx = 1
nb_rx = 1
att_tx = 20
att_rx = 0;
bands = [38];
max_pdschReferenceSignalPower = -23;
max_rxgain = 116;
eNB_instances = [0];
}
);
```
Last, the S1 interface shall be properly set.
```
////////// MME parameters:
mme_ip_address = ( { ipv4 = "CI_MME_IP_ADDR"; // replace with 192.168.122.195
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
ENB_INTERFACE_NAME_FOR_S1_MME = "ens3"; // replace with the proper interface name
ENB_IPV4_ADDRESS_FOR_S1_MME = "CI_ENB_IP_ADDR"; // replace with 192.168.122.31
ENB_INTERFACE_NAME_FOR_S1U = "ens3"; // replace with the proper interface name
ENB_IPV4_ADDRESS_FOR_S1U = "CI_ENB_IP_ADDR"; // replace with 192.168.122.31
ENB_PORT_FOR_S1U = 2152; # Spec 2152
ENB_IPV4_ADDRESS_FOR_X2C = "CI_ENB_IP_ADDR"; // replace with 192.168.122.31
ENB_PORT_FOR_X2C = 36422; # Spec 36422
};
```
## 4.2. The UE Configuration file ##
```bash
$ ssh sudousername@machineB
cd ue_folder
# Edit ci-scripts/conf_files/ue.nfapi.conf with your preferred editor
```
Verify the nFAPI interface setup on the loopback interface.
```
L1s = (
{
num_cc = 1;
tr_n_preference = "nfapi";
local_n_if_name = "ens3"; // <- HERE
remote_n_address = "192.168.122.31"; // <- HERE
local_n_address = "192.168.122.169"; // <- HERE
local_n_portc = 50000;
remote_n_portc = 50001;
local_n_portd = 50010;
remote_n_portd = 50011;
}
);
```
# 5. Build OAI UE and eNodeB #
See [Build documentation](./BUILD.md).
# 6. Start the eNB #
In the first terminal (the one you used to build the eNB):
```bash
$ ssh sudousername@machineB
cd enb_folder/cmake_targets
sudo -E ./ran_build/build/lte-softmodem -O ../ci-scripts/conf_files/rcc.band7.tm1.nfapi.conf --noS1 > enb.log 2>&1
sleep 10
ifconfig
ens3 Link encap:Ethernet HWaddr XX:XX:XX:XX:XX:XX
inet addr:192.168.122.31 Bcast:192.168.122.255 Mask:255.255.255.0
....
oaitun_enb1 Link encap:UNSPEC HWaddr 00-00-00-00-00-00-00-00-00-00-00-00-00-00-00-00
inet addr:10.0.1.1 P-t-P:192.172.0.2 Mask:255.255.255.0
....
```
If you don't use redirection, you can test but many logs are printed on the console and this may affect performance of the L2-nFAPI simulator.
We do recommend the redirection in steady mode once your setup is correct.
# 7. Start the UE #
In the second terminal (the one you used to build the UE):
```bash
$ ssh sudousername@machineC
cd ue_folder/cmake_targets
# Test 64 UEs, 1 thread in FDD mode
sudo -E ./ran_build/build/lte-uesoftmodem -O ../ci-scripts/conf_files/ue.nfapi.conf --noS1 --L2-emul 3 --num-ues 64 --nums_ue_thread 1 --nokrnmod 1 > ue.log 2>&1
# Test 64 UEs, 1 thread in TDD mode
sudo -E ./ran_build/build/lte-uesoftmodem -O ../ci-scripts/conf_files/ue.nfapi.conf --noS1 --L2-emul 3 --num-ues 64 --nums_ue_thread 1 --nokrnmod 1 -T 1 > ue.log 2>&1
# The "-T 1" option means TDD config
```
- The number of UEs can set by using `--num-ues` option and the maximum UE number is 255 (with the `--mu*` options, otherwise 16).
- The number of threads can set with the `--nums-ue-thread`. This number **SHALL NOT** be greater than the number of UEs.
* At the time of writing, it seems to be enough to run on a single thread.
- The `--nokrnmod 1` option makes use of the preferred and supported tunnel interface.
- How many UE that can be tested depends on hardware (server , PC, etc) performance in your environment.
For example, running with 4 UEs:
```bash
$ ssh sudousername@machineC
cd ue_folder/cmake_targets
sudo -E ./ran_build/build/lte-uesoftmodem -O ../ci-scripts/conf_files/ue.nfapi.conf --noS1 --L2-emul 3 --num-ues 64 --nums_ue_thread 1 --nokrnmod 1 > ue.log 2>&1
sleep 10
ifconfig
ens3 Link encap:Ethernet HWaddr XX:XX:XX:XX:XX:XX
inet addr:192.168.122.169 Bcast:192.168.122.255 Mask:255.255.255.0
....
oaitun_ue1 Link encap:UNSPEC HWaddr 00-00-00-00-00-00-00-00-00-00-00-00-00-00-00-00
inet addr:10.0.1.2 P-t-P:192.172.0.2 Mask:255.255.255.0
....
oaitun_ue2 Link encap:UNSPEC HWaddr 00-00-00-00-00-00-00-00-00-00-00-00-00-00-00-00
inet addr:10.0.1.3 P-t-P:192.172.0.3 Mask:255.255.255.0
....
oaitun_ue3 Link encap:UNSPEC HWaddr 00-00-00-00-00-00-00-00-00-00-00-00-00-00-00-00
inet addr:10.0.1.4 P-t-P:192.172.0.4 Mask:255.255.255.0
....
oaitun_ue4 Link encap:UNSPEC HWaddr 00-00-00-00-00-00-00-00-00-00-00-00-00-00-00-00
inet addr:10.0.1.5 P-t-P:192.172.0.5 Mask:255.255.255.0
....
oaitun_uem1 Link encap:UNSPEC HWaddr 00-00-00-00-00-00-00-00-00-00-00-00-00-00-00-00
inet addr:10.0.2.2 P-t-P:10.0.2.2 Mask:255.255.255.0
....
....
```
Having the 4 oaitun_ue tunnel interfaces up and with an allocated address means the connection with EPC went alright.
# 8. Test with ping #
In a third terminal, after around 10 seconds, the UE(s) shall be connected to the eNB: Check with ifconfig
```bash
$ ssh sudousername@machineB
# Ping UE1 IP address based on the EPC pool used: in this example:
ping -I oaitun_enb1 -c 20 10.0.1.2
# Ping UE4 IP address based on the EPC pool used: in this example:
ping -I oaitun_enb1 -c 20 10.0.1.5
```
Ping from the UE side:
```bash
$ ssh sudousername@machineC
ping -I oaitun_ue1 -c 20 10.0.1.1
ping -I oaitun_ue3 -c 20 10.0.1.1
```
iperf operations can also be performed.
DL traffic:
```bash
$ ssh sudousername@machineC
iperf -B 10.0.1.2 -u -s -i 1 -fm -p 5002
$ ssh sudousername@machineB
iperf -c 10.0.1.2 -u -t 30 -b 3M -i 1 -fm -B 10.0.1.1 -p 5002
```
UL traffic:
```bash
$ ssh sudousername@machineB
iperf -B 10.0.1.1 -u -s -i 1 -fm -p 5002
$ ssh sudousername@machineC
iperf -c 10.0.1.1 -u -t 30 -b 2M -i 1 -fm -B 10.0.1.2 -p 5002
```
# 9. Limitations #
----
[oai wiki home](https://gitlab.eurecom.fr/oai/openairinterface5g/wikis/home)
[oai softmodem features](FEATURE_SET.md)
[oai softmodem build procedure](BUILD.md)
[L2 nfapi simulator](L2NFAPI.md)
# OpenAirInterface for SystemX
# Terminology
****This document use the 5G terminology****
**Central Unit (CU):** It is a logical node that includes the gNB
functions like Transfer of user data, Mobility control, Radio access
network sharing, Positioning, Session Management etc., except those
functions allocated exclusively to the DU. CU controls the operation of
DUs over front-haul (Fs) interface. A central unit (CU) may also be
known as BBU/REC/RCC/C-RAN/V-RAN/VNF
**Distributed Unit (DU):** This logical node includes a subset of the
gNB functions, depending on the functional split option. Its operation
is controlled by the CU. Distributed Unit (DU) also known with other
names like RRH/RRU/RE/RU/PNF.
In OpenAir code, the terminology is often RU and BBU.
# OpenAirUsage
## EPC and general environment
### OAI EPC
Use the stable OAI EPC, that can run in one machine (VM or standalone)
Draft description:
<https://open-cells.com/index.php/2017/08/22/all-in-one-openairinterface-august-22nd/>
## Standalone 4G
EPC+eNB on one machine, the UE can be commercial or OAI UE.
### USRP B210
Main current issue: traffic is good only on coaxial link between UE and
eNB (probably power management issue).
### Simulated RF
Running eNB+UE both OAI can be done over a virtual RF link.
The UE current status is that threads synchronization is implicit in
some cases. As the RF simulator is very quick, a “sleep()” is required
in the UE main loop
(line 1744, targets/RT/USER/lte-ue.c).
Running also the UE in the same machine is possible with simulated RF.
Running in same machine is simpler, offers about infinite speed for
virtual RF samples transmission.
A specific configuration is required because the EPC Sgi interface has
the same IP tunnel end point as the UE.
So, we have to create a network namespace for the UE and to route data
in/out of the namespace.
```bash
ip netns delete aNameSpace 2&gt; /dev/null
ip link delete v-eth1 2&gt; /dev/null
ip netns add aNameSpace
ip link add v-eth1 type veth peer name v-peer1
ip link set v-peer1 netns aNameSpace
ip addr add 10.200.1.1/24 dev v-eth1
ip link set v-eth1 up
iptables -t nat -A POSTROUTING -s 10.200.1.0/255.255.255.0 -o enp0s31f6 \
-j MASQUERADE
iptables -A FORWARD -i enp0s31f6 -o v-eth1 -j ACCEPT
iptables -A FORWARD -o enp0s31f6 -i v-eth1 -j ACCEPT
ip netns exec aNameSpace ip link set dev lo up
ip netns exec aNameSpace ip addr add 10.200.1.2/24 dev v-peer1
ip netns exec aNameSpace ip link set v-peer1 up
ip netns exec aNameSpace bash
```
After the last command, the Linux shell is in the new namespace, ready
to run the UE.
To make user plan traffic, the traffic generator has to run in the same
namespace
```bash
ip netns exec aNameSpace bash
```
The traffic genenrator has to specify the interface:
```bash
route add default oaitun_ue1
```
or specify the outgoing route in the traffic generator (like option “-I”
in ping command).
## Split 6 DL 4G
The contract describes to reuse the uplink existing if4p5 and to develop
is this work the downlink “functional split 6”.
The customer required after signature to develop also the uplink
functional split 6. This is accepted, as long as the whole work is
research with no delivery completeness warranty.
### Simulation
To be able to verify the new features and to help in all future
developments, Open Cells added and improved the Rf board simulator
during this contract.
We added the channel modeling simulation, that offer to simulate various
3GPP defined channels.
### Main loop
The main log is in RF simulator is in
`targets/RT/USER/lte-ru.c and targets/RT/USER/lte-enb.c`
As this piece of SW is very complex and doesn’t meet our goals
(functional split 6), a cleaned version replaces these 2 files in
executables/ocp-main.c (openair1/SCHED/prach\_procedures.c is also
replaced by this new file as it only launching the RACH actual work in a
way not compatible with our FS6).
The main loop cadences the I/Q samples reception, signal processing and
I/Q samples sending.
The main loop uses extensively function pointers to call the right
processing function depending on the split case.
A lot of OAI reduntant global variables contains the same semantic data: time,frame, subframe.
The reworked main loop take care of a uniq variable that comes directly from harware: RF board sampling number.
To use OAI, we need to set all OAI variables that derivates from this timestamp value. The function setAllfromTS() implements this.
### Splitted main level
When FS6 is actived, a main loop for DU (du_fs6()) a main loop for CU case replaces the uniq eNB main loop.
Each of these main loops calls initialization of OAI LTE data and the FS6 transport layer initialization.
Then, it runs a infinite loop on: set time, call UL and DL. The time comes from the RF board, so the DU sends the time to the CU.
This is enough for RF board dialog, but the FS6 is higher in SW layers,
we need to cut higher functions inside downlink and uplink procedures.
As much as possible, the FS6 code is in the directory OPENAIR_DIR/executables. When a given OAI piece of code is small or need complex changes, it is reworked in the file fs6-main.c. The functions naming keeps the OAI function name, adding suffix _fromsplit() or _tosplit().
When this organization would lead to large code copy, it is better to insert modifications in OAI code. This is done in two files:
- openair1/SCHED/phy_procedures_lte_eNb.c: to send signaling channels computation results
- the function sendFs6Ulharq() centralizes all signaling channels forwarding to CU
- openair1/PHY/LTE_TRANSPORT/ulsch_decoding.c: to deal with FS6 user plane split
- sendFs6Ul() is used once to forward user plane to CU
### DownLink
The main procedure is phy\_procedures\_eNB\_TX()
This is building the common channels (beacon, multi-UE signaling).
The FS6 split breaks this function into pieces:
* The multi-UE signals, built by common\_signal\_procedures(),
subframe2harq\_pid(), generate\_dci\_top(), subframe2harq\_pid()
* These functions run in the DU, nevertheless all context has to be sent
(it is also needed partially for UL spitting)
* Run in the DU also to meet the requirement of pushing
in DU the data encoded with large redundancy (&gt;3 redundancy)
* the per UE data: pdsch\_procedures() needs further splitting:
* dlsch\_encoding\_all() that makes the encoding: turbo code
and lte\_rate\_matching\_turbo() that will be in the DU (some
unlikely cases can reach redundancy up to x3, when MCS is very
low (negative SINR cases)).
* dlsch\_encoding() output needs to be transmitted between the
DU and the CU for functional split 6.
* dlsch\_scrambling() that will go in the DU
* dlsch\_modulation() that will go in the DU
The du user plane data is made of expanded bit in OAI at FS6 split level. 1 pair of functions compact back these bits into 8bits/byte before sending data and expand it again in the DU data reception (functions: fs6Dl(un)pack()).
### Uplink
The uplink require configuration that is part of the DL transmission.
It interprets the signalling to extract the RACH and the per UE data
channels.
Ocp-main.c:rxtx() calls directly the entry procedure
phy\_procedures\_eNB\_uespec\_RX() calls:
* rx\_ulsch() that demodulate and extract soft bits per UE.
* This function runs in the DU
* the output data will be processes in the DU, so it needs to be
transmitted to the DU
* ulsch\_decoding() that do lte\_rate\_matching\_turbo\_rx()
sub\_block\_deinterleaving\_turbo()
then turbo decode that is in the CU
* fill\_ulsch\_cqi\_indication() fill\_crc\_indication() , fill\_rx\_indication()
* DU performs the signal processing of each channel data, prepare and sent to the CU the computed result
* Random access channel detection runs in the DU
* the DU reports to the CU only the detected temprary identifier for RACH response
### signaling data in each direction (UL and DL)
* each LTE channel needs to be propagated between CU and DU
* the simplest are the almost static data such as PSS/SSS, that need only static eNB parameters and primary information (frame numbering)
* all the other channels require data transmission CU to DU and DU to CU
* the general design push all the low level processing for these channels in the DU
* the CU interface transports only signal processing results (UL) or configuration to create the RF signal (DL case)
* HARQ is detected in the DU, then only the ACK or NACK is reported to CU
* the CU have to control the power and MCS (modulation and coding scheme)
* the DU performs the signal processing and report only the decoded data like the CQI
* as the DU performas the modulation, scrambling and puncturing, each data packet is associated with the LTE parameters required for these features
* in DL, the CU associates the control parameters and the user plane data
* in UL, the CU sends upfront the scheduled UL data to the DU. So, the DU have the required knowledge to decode the next subframes in time.
### UDP transport layer
A general UDP transport layer is in executables/transport\_split.c
Linux offers a UDP socket builtin timeout, that we use.
In and out buffers are memory zones that contains compacted
(concatenated) UDP chunks.
For output, sendSubFrame() sends each UDP chunk
For input, receiveSubFrame() collects all UDP chunks for a group (a
subframe in OAI LTE case). It returns in the following cases:
- all chunks are received
- a timeout expired
- a chunk from the next subframe already arrived
### Functional split 6 usage
The ocp cleaned main hale to be used: run ocp-softmodem instead of
lte-softmodem.
The functionality and parameters is the same, enhanced with FS6 mode.
The end line option “--split73” enables the fs6 (also called split 7.3) mode and decided to be cu or du.
Example:
```bash
./ocp-softmodem -O $OPENAIR_DIR/enb.fs6.example.conf --rfsim --log_config.phy_log_level debug --split73 cu:127.0.0.1
```
Run the CU init of the split 6 eNB, that will call du on 127.0.0.1 address
```bash
./ocp-softmodem -O $OPENAIR_DIR/enb.fs6.example.conf --rfsim --log_config.phy_log_level debug --split73 du:127.0.0.1
```
will run the du, calling the cu on 127.0.0.1
If the CU and the DU are not on the same machine, the remote address of each side need to be specified as per this example
```bash
./ocp-softmodem -O $OPENAIR_DIR/enb.fs6.example.conf --rfsim --log_config.phy_log_level debug --split73 du:192.168.1.55
```
runs the functional split 6 DU
```bash
./lte-uesoftmodem -C 2685000000 -r 50 --rfsim --rfsimulator.serveraddr 192.168.1.1 -d
```
Runs the UE (to have the UE signal scope, compile it with make uescope)
CU+DU+UE can run with option `--noS1` to avoid to use a EPC and/or with `--rfsim` to simulate RF board
## 5G and F1
Today 5G achievement is limited to physical layer.
The available modulation is 40MHz, that require one X310 or N300 for the
gNB and a X310 or N300 for the nrUE.
### Usage with X310
Linux configuration:
<https://files.ettus.com/manual/page_usrp_x3x0_config.html>
We included most of this configuration included in OAI source code.
Remain to set the NIC (network interface card) MTU to 9000 (jumbo
frames).
### Running 5G
Usage with RFsimulator:
**gNB**
```bash
sudo RFSIMULATOR=server ./nr-softmodem -O \
../../../targets/PROJECTS/GENERIC-LTE-EPC/CONF/gnb.band78.tm1.106PRB.usrpn300.conf \
--parallel-config PARALLEL\_SINGLE\_THREAD
```
**nrUE**
```bash
sudo RFSIMULATOR=127.0.0.1 ./nr-uesoftmodem --numerology 1 -r 106 -C \
3510000000 -d
```
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Author and copyright: Laurent Thomas, open-cells.com
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include <stdint.h>
#include <common/utils/LOG/log.h>
#include <common/utils/system.h>
#include <common/config/config_userapi.h>
#include <targets/RT/USER/lte-softmodem.h>
#include <openair1/PHY/defs_eNB.h>
#include <openair1/PHY/phy_extern.h>
#include <nfapi/oai_integration/vendor_ext.h>
#include <openair1/SCHED/fapi_l1.h>
#include <openair1/PHY/INIT/phy_init.h>
#include <openair2/LAYER2/MAC/mac_extern.h>
#include <openair1/PHY/LTE_REFSIG/lte_refsig.h>
#include <nfapi/oai_integration/nfapi_pnf.h>
#include <executables/split_headers.h>
#include <nfapi/oai_integration/vendor_ext.h>
#include <openair1/PHY/INIT/lte_init.c>
#include <openair1/PHY/LTE_ESTIMATION/lte_estimation.h>
#include <executables/split_headers.h>
#include <openair1/PHY/CODING/coding_extern.h>
#include <threadPool/thread-pool.h>
#include <emmintrin.h>
#define FS6_BUF_SIZE 1000*1000
static UDPsock_t sockFS6;
int sum(uint8_t *b, int s) {
int sum=0;
for (int i=0; i < s; i++)
sum+=b[i];
return sum;
}
static inline int cmpintRev(const void *a, const void *b) {
uint64_t *aa=(uint64_t *)a;
uint64_t *bb=(uint64_t *)b;
return (int)(*bb-*aa);
}
static inline void printMeas2(char *txt, Meas *M, int period, bool MaxMin) {
if (M->iterations%period == 0 ) {
char txt2[512];
sprintf(txt2,"%s avg=%" PRIu64 " iterations=%" PRIu64 " %s=%"
PRIu64 ":%" PRIu64 ":%" PRIu64 ":%" PRIu64 ":%" PRIu64 ":%" PRIu64 ":%" PRIu64 ":%" PRIu64 ":%" PRIu64 ":%" PRIu64 "\n",
txt,
M->sum/M->iterations,
M->iterations,
MaxMin?"max":"min",
M->maxArray[1],M->maxArray[2], M->maxArray[3],M->maxArray[4], M->maxArray[5],
M->maxArray[6],M->maxArray[7], M->maxArray[8],M->maxArray[9],M->maxArray[10]);
#if T_TRACER
LOG_W(PHY,"%s",txt2);
#else
printf("%s",txt2);
#endif
}
}
static inline void updateTimesReset(uint64_t start, Meas *M, int period, bool MaxMin, char *txt) {
if (start!=0) {
uint64_t end=rdtsc();
long long diff=(end-start)/(cpuf*1000);
M->maxArray[0]=diff;
M->sum+=diff;
M->iterations++;
if ( MaxMin)
qsort(M->maxArray, 11, sizeof(uint64_t), cmpint);
else
qsort(M->maxArray, 11, sizeof(uint64_t), cmpintRev);
printMeas2(txt,M,period, MaxMin);
if (M->iterations%period == 0 ) {
bzero(M,sizeof(*M));
if (!MaxMin)
for (int i=0; i<11; i++)
M->maxArray[i]=INT_MAX;
}
}
}
static inline void measTransportTime(uint64_t DuSend, uint64_t CuMicroSec, Meas *M, int period, bool MaxMin, char *txt) {
if (DuSend!=0) {
uint64_t end=rdtsc();
long long diff=(end-DuSend)/(cpuf*1000)-CuMicroSec;
M->maxArray[0]=diff;
M->sum+=diff;
M->iterations++;
if ( MaxMin)
qsort(M->maxArray, 11, sizeof(uint64_t), cmpint);
else
qsort(M->maxArray, 11, sizeof(uint64_t), cmpintRev);
printMeas2(txt,M,period, MaxMin);
if (M->iterations%period == 0 ) {
bzero(M,sizeof(*M));
if (!MaxMin)
for (int i=0; i<11; i++)
M->maxArray[i]=INT_MAX;
}
}
}
#define ceil16_bytes(a) ((((a+15)/16)*16)/8)
static void fs6Dlunpack(void *out, void *in, int szUnpacked) {
static uint64_t *lut=NULL;
if (!lut) {
lut=(uint64_t *) malloc(sizeof(*lut)*256);
for (int i=0; i <256; i++)
for (int j=0; j<8; j++)
((uint8_t *)(lut+i))[7-j]=(i>>j)&1;
}
int64_t *out_64 = (int64_t *)out;
int sz=ceil16_bytes(szUnpacked);
for (int i=0; i<sz; i++)
out_64[i]=lut[((uint8_t *)in)[i]];
return;
}
static void fs6Dlpack(void *out, void *in, int szUnpacked) {
__m128i zeros=_mm_set1_epi8(0);
__m128i shuffle=_mm_set_epi8(8,9,10,11,12,13,14,15,0,1,2,3,4,5,6,7);
const int loop=ceil16_bytes(szUnpacked)/sizeof(uint16_t);
__m128i *iter=(__m128i *)in;
for (int i=0; i < loop; i++) {
__m128i tmp=_mm_shuffle_epi8(_mm_cmpgt_epi8(*iter++,zeros),shuffle);
((uint16_t *)out)[i]=(uint16_t)_mm_movemask_epi8(tmp);
}
}
void prach_eNB_tosplit(uint8_t *bufferZone, int bufSize, PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc) {
fs6_ul_t *header=(fs6_ul_t *) commonUDPdata(bufferZone);
if (is_prach_subframe(&eNB->frame_parms, proc->frame_prach,proc->subframe_prach)<=0)
return;
RU_t *ru;
int aa=0;
int ru_aa;
for (int i=0; i<eNB->num_RU; i++) {
ru=eNB->RU_list[i];
for (ru_aa=0,aa=0; ru_aa<ru->nb_rx; ru_aa++,aa++) {
eNB->prach_vars.rxsigF[0][aa] = eNB->RU_list[i]->prach_rxsigF[ru_aa];
int ce_level;
for (ce_level=0; ce_level<4; ce_level++)
eNB->prach_vars_br.rxsigF[ce_level][aa] = eNB->RU_list[i]->prach_rxsigF_br[ce_level][ru_aa];
}
}
ocp_rx_prach(eNB,
proc,
eNB->RU_list[0],
header->max_preamble,
header->max_preamble_energy,
header->max_preamble_delay,
header->avg_preamble_energy,
proc->frame_prach,
0,
false
);
// run PRACH detection for CE-level 0 only for now when br_flag is set
/* fixme: seems not operational and may overwrite regular LTE prach detection
* OAI code can call is sequence
rx_prach(eNB,
eNB->RU_list[0],
header->max_preamble,
header->max_preamble_energy,
header->max_preamble_delay,
header->avg_preamble_energy,
frame,
0,
true
);
*/
LOG_D(PHY,"RACH detection index 0: max preamble: %u, energy: %u, delay: %u, avg energy: %u\n",
header->max_preamble[0],
header->max_preamble_energy[0],
header->max_preamble_delay[0],
header->avg_preamble_energy[0]
);
return;
}
void prach_eNB_fromsplit(uint8_t *bufferZone, int bufSize, PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc) {
fs6_ul_t *header=(fs6_ul_t *) commonUDPdata(bufferZone);
uint16_t *max_preamble=header->max_preamble;
uint16_t *max_preamble_energy=header->max_preamble_energy;
uint16_t *max_preamble_delay=header->max_preamble_delay;
uint16_t *avg_preamble_energy=header->avg_preamble_energy;
int subframe=proc->subframe_prach;
int frame=proc->frame_prach;
// Fixme: not clear why we call twice with "br" and without
int br_flag=0;
if (br_flag==1) {
int prach_mask;
prach_mask = is_prach_subframe (&eNB->frame_parms, proc->frame_prach_br, proc->subframe_prach_br);
eNB->UL_INFO.rach_ind_br.rach_indication_body.preamble_list = eNB->preamble_list_br;
int ind = 0;
int ce_level = 0;
/* Save for later, it doesn't work
for (int ind=0,ce_level=0;ce_level<4;ce_level++) {
if ((eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_CElevel_enable[ce_level]==1)&&
(prach_mask&(1<<(1+ce_level)) > 0) && // prach is active and CE level has finished its repetitions
(eNB->prach_vars_br.repetition_number[ce_level]==
eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_numRepetitionPerPreambleAttempt[ce_level])) {
*/
if (eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_CElevel_enable[0] == 1) {
if ((eNB->prach_energy_counter == 100) && (max_preamble_energy[0] > eNB->measurements.prach_I0 + eNB->prach_DTX_threshold_emtc[0])) {
eNB->UL_INFO.rach_ind_br.rach_indication_body.number_of_preambles++;
eNB->preamble_list_br[ind].preamble_rel8.timing_advance = max_preamble_delay[ind]; //
eNB->preamble_list_br[ind].preamble_rel8.preamble = max_preamble[ind];
// note: fid is implicitly 0 here, this is the rule for eMTC RA-RNTI from 36.321, Section 5.1.4
eNB->preamble_list_br[ind].preamble_rel8.rnti = 1 + subframe + (60*(eNB->prach_vars_br.first_frame[ce_level] % 40));
eNB->preamble_list_br[ind].instance_length = 0; //don't know exactly what this is
eNB->preamble_list_br[ind].preamble_rel13.rach_resource_type = 1 + ce_level; // CE Level
LOG_I (PHY, "Filling NFAPI indication for RACH %d CELevel %d (mask %x) : TA %d, Preamble %d, rnti %x, rach_resource_type %d\n",
ind,
ce_level,
prach_mask,
eNB->preamble_list_br[ind].preamble_rel8.timing_advance,
eNB->preamble_list_br[ind].preamble_rel8.preamble, eNB->preamble_list_br[ind].preamble_rel8.rnti, eNB->preamble_list_br[ind].preamble_rel13.rach_resource_type);
}
}
/*
ind++;
}
} */// ce_level
} else if ((eNB->prach_energy_counter == 100) &&
(max_preamble_energy[0] > eNB->measurements.prach_I0+eNB->prach_DTX_threshold)) {
LOG_I(PHY,"[eNB %d/%d][RAPROC] Frame %d, subframe %d Initiating RA procedure with preamble %d, energy %d.%d dB, delay %d\n",
eNB->Mod_id,
eNB->CC_id,
frame,
subframe,
max_preamble[0],
max_preamble_energy[0]/10,
max_preamble_energy[0]%10,
max_preamble_delay[0]);
pthread_mutex_lock(&eNB->UL_INFO_mutex);
eNB->UL_INFO.rach_ind.rach_indication_body.number_of_preambles = 1;
eNB->UL_INFO.rach_ind.rach_indication_body.preamble_list = &eNB->preamble_list[0];
eNB->UL_INFO.rach_ind.rach_indication_body.tl.tag = NFAPI_RACH_INDICATION_BODY_TAG;
eNB->UL_INFO.rach_ind.header.message_id = NFAPI_RACH_INDICATION;
eNB->UL_INFO.rach_ind.sfn_sf = frame<<4 | subframe;
eNB->preamble_list[0].preamble_rel8.tl.tag = NFAPI_PREAMBLE_REL8_TAG;
eNB->preamble_list[0].preamble_rel8.timing_advance = max_preamble_delay[0];
eNB->preamble_list[0].preamble_rel8.preamble = max_preamble[0];
eNB->preamble_list[0].preamble_rel8.rnti = 1+subframe; // note: fid is implicitly 0 here
eNB->preamble_list[0].preamble_rel13.rach_resource_type = 0;
eNB->preamble_list[0].instance_length = 0; //don't know exactly what this is
if (NFAPI_MODE==NFAPI_MODE_PNF) { // If NFAPI PNF then we need to send the message to the VNF
LOG_D(PHY,"Filling NFAPI indication for RACH : SFN_SF:%d TA %d, Preamble %d, rnti %x, rach_resource_type %d\n",
NFAPI_SFNSF2DEC(eNB->UL_INFO.rach_ind.sfn_sf),
eNB->preamble_list[0].preamble_rel8.timing_advance,
eNB->preamble_list[0].preamble_rel8.preamble,
eNB->preamble_list[0].preamble_rel8.rnti,
eNB->preamble_list[0].preamble_rel13.rach_resource_type);
oai_nfapi_rach_ind(&eNB->UL_INFO.rach_ind);
eNB->UL_INFO.rach_ind.rach_indication_body.number_of_preambles = 0;
}
pthread_mutex_unlock(&eNB->UL_INFO_mutex);
} // max_preamble_energy > prach_I0 + 100
else {
eNB->measurements.prach_I0 = ((eNB->measurements.prach_I0*900)>>10) + ((avg_preamble_energy[0]*124)>>10);
if (eNB->prach_energy_counter < 100)
eNB->prach_energy_counter++;
}
}
void sendFs6Ulharq(enum pckType type, int UEid, PHY_VARS_eNB *eNB, LTE_eNB_UCI *uci, int frame, int subframe, uint8_t *harq_ack, uint8_t tdd_mapping_mode, uint16_t tdd_multiplexing_mask,
uint16_t rnti,
int32_t stat) {
static int current_fsf=-1;
int fsf=frame*16+subframe;
uint8_t *bufferZone=eNB->FS6bufferZone;
commonUDP_t *FirstUDPheader=(commonUDP_t *) bufferZone;
// move to the end
uint8_t *firstFreeByte=bufferZone;
int curBlock=0;
if ( current_fsf != fsf ) {
for (int i=0; i < FirstUDPheader->nbBlocks; i++) {
AssertFatal( ((commonUDP_t *) firstFreeByte)->blockID==curBlock,"");
firstFreeByte+=alignedSize(firstFreeByte);
curBlock++;
}
commonUDP_t *newUDPheader=(commonUDP_t *) firstFreeByte;
FirstUDPheader->nbBlocks++;
newUDPheader->blockID=curBlock;
newUDPheader->contentBytes=sizeof(fs6_ul_t)+sizeof(fs6_ul_uespec_uci_t);
hULUEuci(newUDPheader)->type=fs6ULcch;
hULUEuci(newUDPheader)->nb_active_ue=0;
} else
for (int i=0; i < FirstUDPheader->nbBlocks-1; i++) {
AssertFatal( ((commonUDP_t *) firstFreeByte)->blockID==curBlock,"");
firstFreeByte+=alignedSize(firstFreeByte);
curBlock++;
}
LOG_D(PHY,"FS6 du, block: %d: adding ul harq/sr: %d, rnti: %d, ueid: %d\n",
curBlock, type, rnti, UEid);
commonUDP_t *newUDPheader=(commonUDP_t *) firstFreeByte;
fs6_ul_uespec_uci_element_t *tmp=(fs6_ul_uespec_uci_element_t *)(hULUEuci(newUDPheader)+1);
tmp+=hULUEuci(newUDPheader)->nb_active_ue;
tmp->type=type;
tmp->UEid=UEid;
tmp->frame=frame;
tmp->subframe=subframe;
if (uci != NULL)
memcpy(&tmp->uci, uci, sizeof(*uci));
else
tmp->uci.ue_id=0xFFFF;
if (harq_ack != NULL)
memcpy(tmp->harq_ack, harq_ack, 4);
tmp->tdd_mapping_mode=tdd_mapping_mode;
tmp->tdd_multiplexing_mask=tdd_multiplexing_mask;
tmp->n0_subband_power_dB=eNB->measurements.n0_subband_power_dB[0][0];
tmp->rnti=rnti;
tmp->stat=stat;
hULUEuci(newUDPheader)->nb_active_ue++;
newUDPheader->contentBytes+=sizeof(fs6_ul_uespec_uci_element_t);
}
void sendFs6Ul(PHY_VARS_eNB *eNB, int UE_id, int harq_pid, int segmentID, int16_t *data, int dataLen, int r_offset) {
uint8_t *bufferZone=eNB->FS6bufferZone;
commonUDP_t *FirstUDPheader=(commonUDP_t *) bufferZone;
// move to the end
uint8_t *firstFreeByte=bufferZone;
int curBlock=0;
for (int i=0; i < FirstUDPheader->nbBlocks; i++) {
AssertFatal( ((commonUDP_t *) firstFreeByte)->blockID==curBlock,"");
firstFreeByte+=alignedSize(firstFreeByte);
curBlock++;
}
commonUDP_t *newUDPheader=(commonUDP_t *) firstFreeByte;
FirstUDPheader->nbBlocks++;
newUDPheader->blockID=curBlock;
newUDPheader->contentBytes=sizeof(fs6_ul_t)+sizeof(fs6_ul_uespec_t) + dataLen;
hULUE(newUDPheader)->type=fs6ULsch;
hULUE(newUDPheader)->UE_id=UE_id;
hULUE(newUDPheader)->harq_id=harq_pid;
memcpy(hULUE(newUDPheader)->ulsch_power,
eNB->pusch_vars[UE_id]->ulsch_power,
sizeof(int)*2);
hULUE(newUDPheader)->cqi_crc_status=eNB->ulsch[UE_id]->harq_processes[harq_pid]->cqi_crc_status;
hULUE(newUDPheader)->O_ACK=eNB->ulsch[UE_id]->harq_processes[harq_pid]->O_ACK;
memcpy(hULUE(newUDPheader)->o_ACK, eNB->ulsch[UE_id]->harq_processes[harq_pid]->o_ACK,
sizeof(eNB->ulsch[UE_id]->harq_processes[harq_pid]->o_ACK));
hULUE(newUDPheader)->ta=lte_est_timing_advance_pusch(eNB, UE_id);
hULUE(newUDPheader)->segment=segmentID;
memcpy(hULUE(newUDPheader)->o, eNB->ulsch[UE_id]->harq_processes[harq_pid]->o,
sizeof(eNB->ulsch[UE_id]->harq_processes[harq_pid]->o));
memcpy(hULUE(newUDPheader)+1, data, dataLen);
hULUE(newUDPheader)->segLen=dataLen;
hULUE(newUDPheader)->r_offset=r_offset;
hULUE(newUDPheader)->G=eNB->ulsch[UE_id]->harq_processes[harq_pid]->G;
}
void pusch_procedures_tosplit(uint8_t *bufferZone, int bufSize, PHY_VARS_eNB *eNB,L1_rxtx_proc_t *proc) {
uint32_t harq_pid;
LTE_DL_FRAME_PARMS *fp=&eNB->frame_parms;
const int subframe = proc->subframe_rx;
const int frame = proc->frame_rx;
for (int i = 0; i < NUMBER_OF_UE_MAX; i++) {
LTE_eNB_ULSCH_t *ulsch = eNB->ulsch[i];
if (ulsch->ue_type > NOCE)
harq_pid = 0;
else
harq_pid= subframe2harq_pid(&eNB->frame_parms,frame,subframe);
LTE_UL_eNB_HARQ_t *ulsch_harq = ulsch->harq_processes[harq_pid];
if (ulsch->rnti>0)
LOG_D(PHY,"eNB->ulsch[%d]->harq_processes[harq_pid:%d] SFN/SF:%04d%d: PUSCH procedures, UE %d/%x ulsch_harq[status:%d SFN/SF:%04d%d active: %d handled:%d]\n",
i, harq_pid, frame,subframe,i,ulsch->rnti,
ulsch_harq->status, ulsch_harq->frame, ulsch_harq->subframe, ulsch_harq->status, ulsch_harq->handled);
if ((ulsch) &&
(ulsch->rnti>0) &&
(ulsch_harq->status == ACTIVE) &&
((ulsch_harq->frame == frame) || (ulsch_harq->repetition_number >1) ) &&
((ulsch_harq->subframe == subframe) || (ulsch_harq->repetition_number >1) ) &&
(ulsch_harq->handled == 0)) {
// UE has ULSCH scheduling
for (int rb=0;
rb<=ulsch_harq->nb_rb;
rb++) {
int rb2 = rb+ulsch_harq->first_rb;
eNB->rb_mask_ul[rb2>>5] |= (1<<(rb2&31));
}
LOG_D(PHY,"[eNB %d] frame %d, subframe %d: Scheduling ULSCH Reception for UE %d \n",
eNB->Mod_id, frame, subframe, i);
uint8_t nPRS= fp->pusch_config_common.ul_ReferenceSignalsPUSCH.nPRS[subframe<<1];
ulsch->cyclicShift = (ulsch_harq->n_DMRS2 +
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.cyclicShift +
nPRS)%12;
AssertFatal(ulsch_harq->TBS>0,"illegal TBS %d\n",ulsch_harq->TBS);
LOG_D(PHY,
"[eNB %d][PUSCH %d] Frame %d Subframe %d Demodulating PUSCH: dci_alloc %d, rar_alloc %d, round %d, first_rb %d, nb_rb %d, Qm %d, TBS %d, rv %d, cyclic_shift %d (n_DMRS2 %d, cyclicShift_common %d, ), O_ACK %d, beta_cqi %d \n",
eNB->Mod_id,harq_pid,frame,subframe,
ulsch_harq->dci_alloc,
ulsch_harq->rar_alloc,
ulsch_harq->round,
ulsch_harq->first_rb,
ulsch_harq->nb_rb,
ulsch_harq->Qm,
ulsch_harq->TBS,
ulsch_harq->rvidx,
ulsch->cyclicShift,
ulsch_harq->n_DMRS2,
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.cyclicShift,
ulsch_harq->O_ACK,
ulsch->beta_offset_cqi_times8);
start_meas(&eNB->ulsch_demodulation_stats);
eNB->FS6bufferZone=bufferZone;
rx_ulsch(eNB, proc, i);
stop_meas(&eNB->ulsch_demodulation_stats);
// TBD: add datablock for transmission
start_meas(&eNB->ulsch_decoding_stats);
ulsch_decoding(eNB,proc,
i,
0, // control_only_flag
ulsch_harq->V_UL_DAI,
ulsch_harq->nb_rb>20 ? 1 : 0);
stop_meas(&eNB->ulsch_decoding_stats);
}
}
}
void phy_procedures_eNB_uespec_RX_tosplit(uint8_t *bufferZone, int bufSize, PHY_VARS_eNB *eNB,L1_rxtx_proc_t *proc) {
//RX processing for ue-specific resources
LTE_DL_FRAME_PARMS *fp = &eNB->frame_parms;
const int subframe = proc->subframe_rx;
const int frame = proc->frame_rx;
/* TODO: use correct rxdata */
if ((fp->frame_type == TDD) && (subframe_select(fp,subframe)!=SF_UL)) return;
LOG_D (PHY, "[eNB %d] Frame %d: Doing phy_procedures_eNB_uespec_RX(%d)\n", eNB->Mod_id, frame, subframe);
eNB->rb_mask_ul[0] = 0;
eNB->rb_mask_ul[1] = 0;
eNB->rb_mask_ul[2] = 0;
eNB->rb_mask_ul[3] = 0;
// Fix me here, these should be locked
eNB->UL_INFO.rx_ind.rx_indication_body.number_of_pdus = 0;
eNB->UL_INFO.crc_ind.crc_indication_body.number_of_crcs = 0;
// Call SRS first since all others depend on presence of SRS or lack thereof
srs_procedures (eNB, proc);
eNB->first_run_I0_measurements = 0;
uci_procedures (eNB, proc);
if (NFAPI_MODE==NFAPI_MONOLITHIC || NFAPI_MODE==NFAPI_MODE_PNF) { // If PNF or monolithic
pusch_procedures_tosplit(bufferZone, bufSize, eNB,proc);
}
lte_eNB_I0_measurements (eNB, subframe, 0, eNB->first_run_I0_measurements);
int min_I0=1000,max_I0=0;
if ((frame==0) && (subframe==4)) {
for (int i=0; i<eNB->frame_parms.N_RB_UL; i++) {
if (i==(eNB->frame_parms.N_RB_UL>>1) - 1) i+=2;
if (eNB->measurements.n0_subband_power_tot_dB[i]<min_I0)
min_I0 = eNB->measurements.n0_subband_power_tot_dB[i];
if (eNB->measurements.n0_subband_power_tot_dB[i]>max_I0)
max_I0 = eNB->measurements.n0_subband_power_tot_dB[i];
}
LOG_I (PHY, "max_I0 %d, min_I0 %d\n", max_I0, min_I0);
}
return;
}
void fill_rx_indication_from_split(uint8_t *bufferZone, PHY_VARS_eNB *eNB,int UE_id,int frame,int subframe, ul_propagation_t *ul_propa) {
nfapi_rx_indication_pdu_t *pdu;
int timing_advance_update;
uint32_t harq_pid;
if (eNB->ulsch[UE_id]->ue_type > 0)
harq_pid = 0;
else
harq_pid = subframe2harq_pid (&eNB->frame_parms,
frame, subframe);
pthread_mutex_lock(&eNB->UL_INFO_mutex);
eNB->UL_INFO.rx_ind.sfn_sf = frame<<4| subframe;
eNB->UL_INFO.rx_ind.rx_indication_body.tl.tag = NFAPI_RX_INDICATION_BODY_TAG;
pdu = &eNB->UL_INFO.rx_ind.rx_indication_body.rx_pdu_list[eNB->UL_INFO.rx_ind.rx_indication_body.number_of_pdus];
// pdu->rx_ue_information.handle = eNB->ulsch[UE_id]->handle;
pdu->rx_ue_information.tl.tag = NFAPI_RX_UE_INFORMATION_TAG;
pdu->rx_ue_information.rnti = eNB->ulsch[UE_id]->rnti;
pdu->rx_indication_rel8.tl.tag = NFAPI_RX_INDICATION_REL8_TAG;
pdu->rx_indication_rel8.length = eNB->ulsch[UE_id]->harq_processes[harq_pid]->TBS>>3;
pdu->rx_indication_rel8.offset = 1; // DJP - I dont understand - but broken unless 1 ???? 0; // filled in at the end of the UL_INFO formation
pdu->data = eNB->ulsch[UE_id]->harq_processes[harq_pid]->decodedBytes;
// estimate timing advance for MAC
timing_advance_update = ul_propa[UE_id].ta;
// if (timing_advance_update > 10) { dump_ulsch(eNB,frame,subframe,UE_id); exit(-1);}
// if (timing_advance_update < -10) { dump_ulsch(eNB,frame,subframe,UE_id); exit(-1);}
switch (eNB->frame_parms.N_RB_DL) {
case 6: /* nothing to do */
break;
case 15:
timing_advance_update /= 2;
break;
case 25:
timing_advance_update /= 4;
break;
case 50:
timing_advance_update /= 8;
break;
case 75:
timing_advance_update /= 12;
break;
case 100:
timing_advance_update /= 16;
break;
default:
abort ();
}
// put timing advance command in 0..63 range
timing_advance_update += 31;
if (timing_advance_update < 0)
timing_advance_update = 0;
if (timing_advance_update > 63)
timing_advance_update = 63;
pdu->rx_indication_rel8.timing_advance = timing_advance_update;
// estimate UL_CQI for MAC (from antenna port 0 only)
int SNRtimes10 = dB_fixed_times10(eNB->pusch_vars[UE_id]->ulsch_power[0]) - 10 * eNB->measurements.n0_subband_power_dB[0][0];
if (SNRtimes10 < -640)
pdu->rx_indication_rel8.ul_cqi = 0;
else if (SNRtimes10 > 635)
pdu->rx_indication_rel8.ul_cqi = 255;
else
pdu->rx_indication_rel8.ul_cqi = (640 + SNRtimes10) / 5;
LOG_D(PHY,"[PUSCH %d] Frame %d Subframe %d Filling RX_indication with SNR %d (%d), timing_advance %d (update %d)\n",
harq_pid,frame,subframe,SNRtimes10,pdu->rx_indication_rel8.ul_cqi,pdu->rx_indication_rel8.timing_advance,
timing_advance_update);
eNB->UL_INFO.rx_ind.rx_indication_body.number_of_pdus++;
eNB->UL_INFO.rx_ind.sfn_sf = frame<<4 | subframe;
pthread_mutex_unlock(&eNB->UL_INFO_mutex);
}
void pusch_procedures_fromsplit(uint8_t *bufferZone, int bufSize, PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc, ul_propagation_t *ul_propa) {
//LTE_DL_FRAME_PARMS *fp=&eNB->frame_parms;
const int subframe = proc->subframe_rx;
const int frame = proc->frame_rx;
uint32_t harq_pid;
uint32_t harq_pid0 = subframe2harq_pid(&eNB->frame_parms,frame,subframe);
for (int i = 0; i < NUMBER_OF_UE_MAX; i++) {
LTE_eNB_ULSCH_t *ulsch = eNB->ulsch[i];
if (ulsch->ue_type > NOCE) harq_pid = 0;
else harq_pid=harq_pid0;
LTE_UL_eNB_HARQ_t *ulsch_harq = ulsch->harq_processes[harq_pid];
if (ulsch->rnti>0)
LOG_D(PHY,"eNB->ulsch[%d]->harq_processes[harq_pid:%d] SFN/SF:%04d%d: PUSCH procedures, UE %d/%x ulsch_harq[status:%d SFN/SF:%04d%d handled:%d]\n",
i, harq_pid, frame,subframe,i,ulsch->rnti,
ulsch_harq->status, ulsch_harq->frame, ulsch_harq->subframe, ulsch_harq->handled);
if ((ulsch) &&
(ulsch->rnti>0) &&
(ulsch_harq->status == ACTIVE) &&
(ulsch_harq->frame == frame) &&
(ulsch_harq->subframe == subframe) &&
(ulsch_harq->handled == 0)) {
// UE has ULSCH scheduling
for (int rb=0;
rb<=ulsch_harq->nb_rb;
rb++) {
int rb2 = rb+ulsch_harq->first_rb;
eNB->rb_mask_ul[rb2>>5] |= (1<<(rb2&31));
}
start_meas(&eNB->ulsch_decoding_stats);
// This is a new packet, so compute quantities regarding segmentation
ulsch_harq->B = ulsch_harq->TBS+24;
lte_segmentation(NULL,
NULL,
ulsch_harq->B,
&ulsch_harq->C,
&ulsch_harq->Cplus,
&ulsch_harq->Cminus,
&ulsch_harq->Kplus,
&ulsch_harq->Kminus,
&ulsch_harq->F);
ulsch_decoding_data(eNB, proc, i, harq_pid,
ulsch_harq->nb_rb>20 ? 1 : 0);
stop_meas(&eNB->ulsch_decoding_stats);
} // if ((ulsch) &&
// (ulsch->rnti>0) &&
// (ulsch_harq->status == ACTIVE))
else if ((ulsch) &&
(ulsch->rnti>0) &&
(ulsch_harq->status == ACTIVE) &&
(ulsch_harq->frame == frame) &&
(ulsch_harq->subframe == subframe) &&
(ulsch_harq->handled == 1)) {
// this harq process is stale, kill it, this 1024 frames later (10s), consider reducing that
ulsch_harq->status = SCH_IDLE;
ulsch_harq->handled = 0;
ulsch->harq_mask &= ~(1 << harq_pid);
LOG_W (PHY, "Removing stale ULSCH config for UE %x harq_pid %d (harq_mask is now 0x%2.2x)\n", ulsch->rnti, harq_pid, ulsch->harq_mask);
}
} // for (i=0; i<NUMBER_OF_UE_MAX; i++)
while (proc->nbDecode > 0) {
notifiedFIFO_elt_t *req=pullTpool(proc->respDecode, proc->threadPool);
postDecode(proc, req);
delNotifiedFIFO_elt(req);
}
}
void recvFs6Ul(uint8_t *bufferZone, int nbBlocks, PHY_VARS_eNB *eNB, ul_propagation_t *ul_propa) {
void *bufPtr=bufferZone;
for (int i=0; i < nbBlocks; i++) { //nbBlocks is the actual received blocks
if ( ((commonUDP_t *)bufPtr)->contentBytes > sizeof(fs6_ul_t) ) {
int type=hULUE(bufPtr)->type;
if ( type == fs6ULsch) {
LTE_eNB_ULSCH_t *ulsch =eNB->ulsch[hULUE(bufPtr)->UE_id];
LTE_UL_eNB_HARQ_t *ulsch_harq=ulsch->harq_processes[hULUE(bufPtr)->harq_id];
memcpy(ulsch_harq->eUL+hULUE(bufPtr)->r_offset,
hULUE(bufPtr)+1,
hULUE(bufPtr)->segLen);
memcpy(eNB->pusch_vars[hULUE(bufPtr)->UE_id]->ulsch_power,
hULUE(bufPtr)->ulsch_power,
sizeof(int)*2);
ulsch_harq->G=hULUE(bufPtr)->G;
ulsch_harq->cqi_crc_status=hULUE(bufPtr)->cqi_crc_status;
//ulsch_harq->O_ACK= hULUE(bufPtr)->O_ACK;
memcpy(ulsch_harq->o_ACK, hULUE(bufPtr)->o_ACK,
sizeof(ulsch_harq->o_ACK));
memcpy(ulsch_harq->o,hULUE(bufPtr)->o, sizeof(ulsch_harq->o));
ul_propa[hULUE(bufPtr)->UE_id].ta=hULUE(bufPtr)->ta;
LOG_D(PHY,"Received ulsch data for: rnti:%x, cqi_crc_status %d O_ACK: %d, segment: %d, seglen: %d \n",
ulsch->rnti, ulsch_harq->cqi_crc_status, ulsch_harq->O_ACK,hULUE(bufPtr)->segment, hULUE(bufPtr)->segLen);
} else if ( type == fs6ULcch ) {
int nb_uci=hULUEuci(bufPtr)->nb_active_ue;
fs6_ul_uespec_uci_element_t *tmp=(fs6_ul_uespec_uci_element_t *)(hULUEuci(bufPtr)+1);
for (int j=0; j < nb_uci ; j++) {
LOG_D(PHY,"FS6 cu, block: %d/%d: received ul harq/sr: %d, rnti: %d, ueid: %d\n",
i, j, type, tmp->rnti, tmp->UEid);
eNB->measurements.n0_subband_power_dB[0][0]=tmp->n0_subband_power_dB;
if (tmp->uci.ue_id != 0xFFFF)
memcpy(&eNB->uci_vars[tmp->UEid],&tmp->uci, sizeof(tmp->uci));
if ( tmp->type == fs6ULindicationHarq )
fill_uci_harq_indication (tmp->UEid, eNB, &eNB->uci_vars[tmp->UEid],
tmp->frame, tmp->subframe, tmp->harq_ack,
tmp->tdd_mapping_mode, tmp->tdd_multiplexing_mask);
else if ( tmp->type == fs6ULindicationSr )
fill_sr_indication(tmp->UEid, eNB,tmp->rnti,tmp->frame,tmp->subframe,tmp->stat);
else
LOG_E(PHY, "Split FS6: impossible UL harq type\n");
tmp++;
}
} else
LOG_E(PHY, "FS6 ul packet type impossible\n" );
}
bufPtr+=alignedSize(bufPtr);
}
}
void phy_procedures_eNB_uespec_RX_fromsplit(uint8_t *bufferZone, int nbBlocks,PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc) {
// The configuration arrived in Dl, so we can extract the UL data
ul_propagation_t ul_propa[NUMBER_OF_UE_MAX];
recvFs6Ul(bufferZone, nbBlocks, eNB, ul_propa);
// dirty memory allocation in OAI...
for (int i = 0; i < NUMBER_OF_UCI_VARS_MAX; i++)
if ( eNB->uci_vars[i].frame == proc->frame_rx &&
eNB->uci_vars[i].subframe == proc->subframe_rx )
eNB->uci_vars[i].active=0;
pusch_procedures_fromsplit(bufferZone, nbBlocks, eNB, proc, ul_propa);
}
void rcvFs6DL(uint8_t *bufferZone, int nbBlocks, PHY_VARS_eNB *eNB, int frame, int subframe) {
void *bufPtr=bufferZone;
for (int i=0; i < nbBlocks; i++) { //nbBlocks is the actual received blocks
if ( ((commonUDP_t *)bufPtr)->contentBytes > sizeof(fs6_dl_t) ) {
int type=hDLUE(bufPtr)->type;
if ( type == fs6DlConfig) {
int curUE=hDLUE(bufPtr)->UE_id;
LTE_eNB_DLSCH_t *dlsch0 = eNB->dlsch[curUE][0];
LTE_DL_eNB_HARQ_t *dlsch_harq=dlsch0->harq_processes[hDLUE(bufPtr)->harq_pid];
#ifdef PHY_TX_THREAD
dlsch0->active[subframe] = 1;
#else
dlsch0->active = 1;
#endif
dlsch0->harq_ids[frame%2][subframe]=hDLUE(bufPtr)->harq_pid;
dlsch0->rnti=hDLUE(bufPtr)->rnti;
dlsch0->sqrt_rho_a=hDLUE(bufPtr)->sqrt_rho_a;
dlsch0->sqrt_rho_b=hDLUE(bufPtr)->sqrt_rho_b;
dlsch_harq->nb_rb=hDLUE(bufPtr)->nb_rb;
memcpy(dlsch_harq->rb_alloc, hDLUE(bufPtr)->rb_alloc, sizeof(hDLUE(bufPtr)->rb_alloc));
dlsch_harq->Qm=hDLUE(bufPtr)->Qm;
dlsch_harq->Nl=hDLUE(bufPtr)->Nl;
dlsch_harq->pdsch_start=hDLUE(bufPtr)->pdsch_start;
#ifdef PHY_TX_THREAD
dlsch_harq->CEmode = hDLUE(bufPtr)->CEmode;
dlsch_harq->i0=hDLUE(bufPtr)->i0;
dlsch_harq->sib1_br_flag=hDLUE(bufPtr)->sib1_br_flag;
#else
dlsch0->i0=hDLUE(bufPtr)->i0;
dlsch0->sib1_br_flag=hDLUE(bufPtr)->sib1_br_flag;
#endif
fs6Dlunpack(dlsch_harq->eDL,
hDLUE(bufPtr)+1, hDLUE(bufPtr)->dataLen);
LOG_D(PHY,"received %d bits, in harq id: %di fsf: %d.%d, sum %d\n",
hDLUE(bufPtr)->dataLen, hDLUE(bufPtr)->harq_pid, frame, subframe, sum(dlsch_harq->eDL, hDLUE(bufPtr)->dataLen));
} else if (type == fs6UlConfig) {
int nbUE=(((commonUDP_t *)bufPtr)->contentBytes - sizeof(fs6_dl_t)) / sizeof( fs6_dl_ulsched_t ) ;
#define cpyVal(a) memcpy(&ulsch_harq->a,&hTxULUE(bufPtr)->a, sizeof(ulsch_harq->a))
for ( int i=0; i < nbUE; i++ ) {
int curUE=hTxULUE(bufPtr)->UE_id;
LTE_eNB_ULSCH_t *ulsch = eNB->ulsch[curUE];
LTE_UL_eNB_HARQ_t *ulsch_harq=ulsch->harq_processes[hTxULUE(bufPtr)->harq_pid];
ulsch->ue_type=hTxULUE(bufPtr)->ue_type;
ulsch->harq_mask=hTxULUE(bufPtr)->harq_mask;
ulsch->Mlimit=hTxULUE(bufPtr)->Mlimit;
ulsch->max_turbo_iterations=hTxULUE(bufPtr)->max_turbo_iterations;
ulsch->bundling=hTxULUE(bufPtr)->bundling;
ulsch->beta_offset_cqi_times8=hTxULUE(bufPtr)->beta_offset_cqi_times8;
ulsch->beta_offset_ri_times8=hTxULUE(bufPtr)->beta_offset_ri_times8;
ulsch->beta_offset_harqack_times8=hTxULUE(bufPtr)->beta_offset_harqack_times8;
ulsch->Msg3_active=hTxULUE(bufPtr)->Msg3_active;
ulsch->cyclicShift=hTxULUE(bufPtr)->cyclicShift;
ulsch->cooperation_flag=hTxULUE(bufPtr)->cooperation_flag;
ulsch->num_active_cba_groups=hTxULUE(bufPtr)->num_active_cba_groups;
memcpy(ulsch->cba_rnti,hTxULUE(bufPtr)->cba_rnti,sizeof(ulsch->cba_rnti));//NUM_MAX_CBA_GROUP];
ulsch->rnti=hTxULUE(bufPtr)->rnti;
ulsch_harq->nb_rb=hTxULUE(bufPtr)->nb_rb;
ulsch_harq->handled=0;
ulsch_harq->status = ACTIVE;
ulsch_harq->frame = frame;
ulsch_harq->subframe = subframe;
ulsch_harq->first_rb=hTxULUE(bufPtr)->first_rb;
ulsch_harq->O_RI=hTxULUE(bufPtr)->O_RI;
ulsch_harq->Or1=hTxULUE(bufPtr)->Or1;
ulsch_harq->Msc_initial=hTxULUE(bufPtr)->Msc_initial;
ulsch_harq->Nsymb_initial=hTxULUE(bufPtr)->Nsymb_initial;
ulsch_harq->V_UL_DAI=hTxULUE(bufPtr)->V_UL_DAI;
ulsch_harq->Qm=hTxULUE(bufPtr)->Qm;
ulsch_harq->srs_active=hTxULUE(bufPtr)->srs_active;
ulsch_harq->TBS=hTxULUE(bufPtr)->TBS;
ulsch_harq->Nsymb_pusch=hTxULUE(bufPtr)->Nsymb_pusch;
cpyVal(dci_alloc);
cpyVal(rar_alloc);
cpyVal(status);
cpyVal(Msg3_flag);
cpyVal(phich_active);
cpyVal(phich_ACK);
cpyVal(previous_first_rb);
cpyVal(B);
cpyVal(G);
//cpyVal(o);
cpyVal(uci_format);
cpyVal(Or2);
cpyVal(o_RI);
cpyVal(o_ACK);
cpyVal(O_ACK);
//cpyVal(q);
cpyVal(o_RCC);
cpyVal(q_ACK);
cpyVal(q_RI);
cpyVal(RTC);
cpyVal(ndi);
cpyVal(round);
cpyVal(rvidx);
cpyVal(Nl);
cpyVal(n_DMRS);
cpyVal(previous_n_DMRS);
cpyVal(n_DMRS2);
cpyVal(delta_TF);
cpyVal(repetition_number );
cpyVal(total_number_of_repetitions);
LOG_D(PHY,"Received request to perform ulsch for: rnti:%d, fsf: %d/%d, O_ACK: %d\n",
ulsch->rnti, frame, subframe, ulsch_harq->O_ACK);
}
} else if ( type == fs6ULConfigCCH ) {
fs6_dl_uespec_ulcch_element_t *tmp=(fs6_dl_uespec_ulcch_element_t *)(hTxULcch(bufPtr)+1);
for (int i=0; i< hTxULcch(bufPtr)->nb_active_ue; i++ )
memcpy(&eNB->uci_vars[tmp->UE_id], &tmp->cch_vars, sizeof(tmp->cch_vars));
} else
LOG_E(PHY, "Impossible block in fs6 DL\n");
}
bufPtr+=alignedSize(bufPtr);
}
}
void phy_procedures_eNB_TX_fromsplit(uint8_t *bufferZone, int nbBlocks, PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc, int do_meas ) {
LTE_DL_FRAME_PARMS *fp=&eNB->frame_parms;
int subframe=proc->subframe_tx;
int frame=proc->frame_tx;
//LTE_UL_eNB_HARQ_t *ulsch_harq;
eNB->pdcch_vars[subframe&1].num_pdcch_symbols=hDL(bufferZone)->num_pdcch_symbols;
eNB->pdcch_vars[subframe&1].num_dci=hDL(bufferZone)->num_dci;
uint8_t num_mdci = eNB->mpdcch_vars[subframe&1].num_dci = hDL(bufferZone)->num_mdci;
eNB->pbch_configured=true;
memcpy(eNB->pbch_pdu,hDL(bufferZone)->pbch_pdu, 4);
// Remove all scheduled DL, we will populate from the CU sending
for (int UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) {
LTE_eNB_DLSCH_t *dlsch0 = eNB->dlsch[UE_id][0];
if ( dlsch0 && dlsch0->rnti>0 ) {
#ifdef PHY_TX_THREAD
dlsch0->active[subframe] = 0;
#else
dlsch0->active = 0;
#endif
}
}
rcvFs6DL(bufferZone, nbBlocks, eNB, frame, subframe);
if (do_meas==1) {
start_meas(&eNB->phy_proc_tx);
start_meas(&eNB->dlsch_common_and_dci);
}
// clear the transmit data array for the current subframe
for (int aa = 0; aa < fp->nb_antenna_ports_eNB; aa++) {
memset (&eNB->common_vars.txdataF[aa][subframe * fp->ofdm_symbol_size * (fp->symbols_per_tti)],
0, fp->ofdm_symbol_size * (fp->symbols_per_tti) * sizeof (int32_t));
}
if (NFAPI_MODE==NFAPI_MONOLITHIC || NFAPI_MODE==NFAPI_MODE_PNF) {
if (is_pmch_subframe(frame,subframe,fp)) {
pmch_procedures(eNB,proc);
} else {
// this is not a pmch subframe, so generate PSS/SSS/PBCH
common_signal_procedures(eNB,frame, subframe);
}
}
// clear previous allocation information for all UEs
for (int i = 0; i < NUMBER_OF_UE_MAX; i++) {
//if (eNB->dlsch[i][0])
//eNB->dlsch[i][0]->subframe_tx[subframe] = 0;
}
if (NFAPI_MODE==NFAPI_MONOLITHIC || NFAPI_MODE==NFAPI_MODE_PNF) {
for (int i=0; i< hDL(bufferZone)->num_dci; i++)
eNB->pdcch_vars[subframe&1].dci_alloc[i]=hDL(bufferZone)->dci_alloc[i];
LOG_D (PHY, "Frame %d, subframe %d: Calling generate_dci_top (pdcch) (num_dci %" PRIu8 ")\n", frame, subframe, hDL(bufferZone)->num_dci);
generate_dci_top(hDL(bufferZone)->num_pdcch_symbols,
hDL(bufferZone)->num_dci,
&eNB->pdcch_vars[subframe&1].dci_alloc[0],
0,
hDL(bufferZone)->amp,
fp,
eNB->common_vars.txdataF,
subframe);
if (num_mdci > 0) {
LOG_D (PHY, "[eNB %" PRIu8 "] Frame %d, subframe %d: Calling generate_mdci_top (mpdcch) (num_dci %" PRIu8 ")\n", eNB->Mod_id, frame, subframe, num_mdci);
generate_mdci_top (eNB, frame, subframe, AMP, eNB->common_vars.txdataF);
}
}
for (int UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) {
LTE_eNB_DLSCH_t *dlsch0 = eNB->dlsch[UE_id][0];
LTE_eNB_DLSCH_t *dlsch1 = eNB->dlsch[UE_id][1];
if ((dlsch0)&&(dlsch0->rnti>0)&&
#ifdef PHY_TX_THREAD
(dlsch0->active[subframe] == 1)
#else
(dlsch0->active == 1)
#endif
) {
uint64_t sum=0;
for ( int i= subframe * fp->ofdm_symbol_size * (fp->symbols_per_tti);
i< (subframe+1) * fp->ofdm_symbol_size * (fp->symbols_per_tti);
i++)
sum+=((int32_t *)(eNB->common_vars.txdataF[0]))[i];
LOG_D(PHY,"frame: %d, subframe: %d, sum of dlsch mod v1: %lx\n", frame, subframe, sum);
int harq_pid=dlsch0->harq_ids[frame%2][subframe];
pdsch_procedures(eNB,
proc,
harq_pid,
dlsch0,
dlsch1);
}
}
eNB->phich_vars[subframe&1]=hDL(bufferZone)->phich_vars;
generate_phich_top(eNB,
proc,
AMP);
}
#define cpyToDu(a) hTxULUE(newUDPheader)->a=ulsch->a
#define cpyToDuHarq(a) hTxULUE(newUDPheader)->a=ulsch_harq->a
#define memcpyToDuHarq(a) memcpy(&hTxULUE(newUDPheader)->a,&ulsch_harq->a, sizeof(ulsch_harq->a));
void appendFs6TxULUE(uint8_t *bufferZone, LTE_DL_FRAME_PARMS *fp, int curUE, LTE_eNB_ULSCH_t *ulsch, int frame, int subframe) {
commonUDP_t *FirstUDPheader=(commonUDP_t *) bufferZone;
// move to the end
uint8_t *firstFreeByte=bufferZone;
int curBlock=0;
for (int i=0; i < FirstUDPheader->nbBlocks; i++) {
AssertFatal( ((commonUDP_t *) firstFreeByte)->blockID==curBlock,"");
firstFreeByte+=alignedSize(firstFreeByte);
curBlock++;
}
commonUDP_t *newUDPheader=(commonUDP_t *) firstFreeByte;
FirstUDPheader->nbBlocks++;
newUDPheader->blockID=curBlock;
newUDPheader->contentBytes=sizeof(fs6_dl_t)+sizeof(fs6_dl_ulsched_t);
// We skip the fs6 DL header, that is populated by caller
// This header will be duplicated during sending
hTxULUE(newUDPheader)->type=fs6UlConfig;
hTxULUE(newUDPheader)->UE_id=curUE;
int harq_pid;
if (ulsch->ue_type > NOCE)
// LTE-M case
harq_pid = 0;
else
harq_pid = subframe2harq_pid(fp, frame, subframe);
LTE_UL_eNB_HARQ_t *ulsch_harq=ulsch->harq_processes[harq_pid];
hTxULUE(newUDPheader)->harq_pid=harq_pid;
cpyToDu(ue_type);
cpyToDu(harq_mask);
cpyToDu(Mlimit);
cpyToDu(max_turbo_iterations);
cpyToDu(bundling);
cpyToDu(beta_offset_cqi_times8);
cpyToDu(beta_offset_ri_times8);
cpyToDu(beta_offset_harqack_times8);
cpyToDu(Msg3_active);
cpyToDu(cyclicShift);
cpyToDu(cooperation_flag);
cpyToDu(num_active_cba_groups);
memcpy(hTxULUE(newUDPheader)->cba_rnti,ulsch->cba_rnti,sizeof(ulsch->cba_rnti));//NUM_MAX_CBA_GROUP];
cpyToDu(rnti);
cpyToDuHarq(nb_rb);
cpyToDuHarq(Msc_initial);
cpyToDuHarq(Nsymb_initial);
cpyToDuHarq(O_RI);
cpyToDuHarq(Or1);
cpyToDuHarq(first_rb);
cpyToDuHarq(V_UL_DAI);
cpyToDuHarq(Qm);
cpyToDuHarq(srs_active);
cpyToDuHarq(TBS);
cpyToDuHarq(Nsymb_pusch);
memcpyToDuHarq(dci_alloc);
memcpyToDuHarq(rar_alloc);
memcpyToDuHarq(status);
memcpyToDuHarq(Msg3_flag);
memcpyToDuHarq(phich_active);
memcpyToDuHarq(phich_ACK);
memcpyToDuHarq(previous_first_rb);
memcpyToDuHarq(B);
memcpyToDuHarq(G);
//memcpyToDuHarq(o);
memcpyToDuHarq(uci_format);
memcpyToDuHarq(Or2);
memcpyToDuHarq(o_RI);
memcpyToDuHarq(o_ACK);
memcpyToDuHarq(O_ACK);
//memcpyToDuHarq(q);
memcpyToDuHarq(o_RCC);
memcpyToDuHarq(q_ACK);
memcpyToDuHarq(q_RI);
memcpyToDuHarq(RTC);
memcpyToDuHarq(ndi);
memcpyToDuHarq(round);
memcpyToDuHarq(rvidx);
memcpyToDuHarq(Nl);
memcpyToDuHarq(n_DMRS);
memcpyToDuHarq(previous_n_DMRS);
memcpyToDuHarq(n_DMRS2);
memcpyToDuHarq(delta_TF);
memcpyToDuHarq(repetition_number );
memcpyToDuHarq(total_number_of_repetitions);
LOG_D(PHY,"Added request to perform ulsch for: rnti:%x, fsf: %d/%d\n", ulsch->rnti, frame, subframe);
}
void appendFs6DLUE(uint8_t *bufferZone, LTE_DL_FRAME_PARMS *fp, int UE_id, int8_t harq_pid, LTE_eNB_DLSCH_t *dlsch0, LTE_DL_eNB_HARQ_t *harqData, int frame, int subframe) {
commonUDP_t *FirstUDPheader=(commonUDP_t *) bufferZone;
// move to the end
uint8_t *firstFreeByte=bufferZone;
int curBlock=0;
for (int i=0; i < FirstUDPheader->nbBlocks; i++) {
AssertFatal( ((commonUDP_t *) firstFreeByte)->blockID==curBlock,"");
firstFreeByte+=alignedSize(firstFreeByte);
curBlock++;
}
int UEdataLen= get_G(fp,
harqData->nb_rb,
harqData->rb_alloc,
harqData->Qm,
harqData->Nl,
harqData->pdsch_start,
frame,subframe,
0);
AssertFatal(firstFreeByte+ceil16_bytes(UEdataLen)+sizeof(fs6_dl_t) <= bufferZone+FS6_BUF_SIZE, "");
commonUDP_t *newUDPheader=(commonUDP_t *) firstFreeByte;
FirstUDPheader->nbBlocks++;
newUDPheader->blockID=curBlock;
newUDPheader->contentBytes=sizeof(fs6_dl_t)+sizeof(fs6_dl_uespec_t) + ceil16_bytes(UEdataLen);
// We skip the fs6 DL header, that is populated by caller
// This header will be duplicated during sending
hDLUE(newUDPheader)->type=fs6DlConfig;
hDLUE(newUDPheader)->UE_id=UE_id;
hDLUE(newUDPheader)->harq_pid=harq_pid;
hDLUE(newUDPheader)->rnti=dlsch0->rnti;
hDLUE(newUDPheader)->sqrt_rho_a=dlsch0->sqrt_rho_a;
hDLUE(newUDPheader)->sqrt_rho_b=dlsch0->sqrt_rho_b;
hDLUE(newUDPheader)->nb_rb=harqData->nb_rb;
memcpy(hDLUE(newUDPheader)->rb_alloc, harqData->rb_alloc, sizeof(harqData->rb_alloc));
hDLUE(newUDPheader)->Qm=harqData->Qm;
hDLUE(newUDPheader)->Nl=harqData->Nl;
hDLUE(newUDPheader)->pdsch_start=harqData->pdsch_start;
#ifdef PHY_TX_THREAD
hDLUE(newUDPheader)->CEmode=harqData->CEmode;
hDLUE(newUDPheader)->i0=harqData->i0;
hDLUE(newUDPheader)->sib1_br_flag=harqData->sib1_br_flag;
#else
hDLUE(newUDPheader)->i0=dlsch0->i0;
hDLUE(newUDPheader)->sib1_br_flag=dlsch0->sib1_br_flag;
#endif
hDLUE(newUDPheader)->dataLen=UEdataLen;
fs6Dlpack(hDLUE(newUDPheader)+1, harqData->eDL, UEdataLen);
LOG_D(PHY,"sending %d bits, in harq id: %di fsf: %d.%d, sum %d\n",
UEdataLen, harq_pid, frame, subframe, sum(harqData->eDL, UEdataLen));
//for (int i=0; i < UEdataLen; i++)
//LOG_D(PHY,"buffer ei[%d]:%hhx\n", i, ( (uint8_t *)(hDLUE(newUDPheader)+1) )[i]);
}
void appendFs6DLUEcch(uint8_t *bufferZone, PHY_VARS_eNB *eNB, int frame, int subframe) {
commonUDP_t *FirstUDPheader=(commonUDP_t *) bufferZone;
// move to the end
uint8_t *firstFreeByte=bufferZone;
int curBlock=0;
for (int i=0; i < FirstUDPheader->nbBlocks; i++) {
AssertFatal( ((commonUDP_t *) firstFreeByte)->blockID==curBlock,"");
firstFreeByte+=alignedSize(firstFreeByte);
curBlock++;
}
commonUDP_t *newUDPheader=(commonUDP_t *) firstFreeByte;
bool first_UE=true;
for (int i = 0; i < NUMBER_OF_UCI_VARS_MAX; i++) {
LTE_eNB_UCI *uci = &(eNB->uci_vars[i]);
if ((uci->active == 1) && (uci->frame == frame) && (uci->subframe == subframe)) {
LOG_D(PHY,"Frame %d, subframe %d: adding uci procedures (type %d) for %d \n",
frame,
subframe,
uci->type,
i);
if ( first_UE ) {
FirstUDPheader->nbBlocks++;
newUDPheader->blockID=curBlock;
newUDPheader->contentBytes=sizeof(fs6_dl_t)+sizeof(fs6_dl_uespec_ulcch_t);
hTxULcch(newUDPheader)->type=fs6ULConfigCCH;
hTxULcch(newUDPheader)->nb_active_ue=0;
first_UE=false;
}
fs6_dl_uespec_ulcch_element_t *tmp=(fs6_dl_uespec_ulcch_element_t *)(hTxULcch(newUDPheader)+1);
tmp+=hTxULcch(newUDPheader)->nb_active_ue;
tmp->UE_id=i;
memcpy(&tmp->cch_vars,uci, sizeof(tmp->cch_vars));
hTxULcch(newUDPheader)->nb_active_ue++;
newUDPheader->contentBytes+=sizeof(fs6_dl_uespec_ulcch_element_t);
}
}
}
void phy_procedures_eNB_TX_tosplit(uint8_t *bufferZone, PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc, int do_meas, uint8_t *buf, int bufSize) {
int frame=proc->frame_tx;
int subframe=proc->subframe_tx;
LTE_DL_FRAME_PARMS *fp=&eNB->frame_parms;
if ((fp->frame_type == TDD) && (subframe_select (fp, subframe) == SF_UL)) {
LOG_W(HW,"no sending in eNB_TX\n");
return;
}
// clear previous allocation information for all UEs
for (int i = 0; i < NUMBER_OF_UE_MAX; i++) {
//if (eNB->dlsch[i][0])
//eNB->dlsch[i][0]->subframe_tx[subframe] = 0;
}
// Send to DU the UL scheduled for future UL subframe
for (int i=0; i<NUMBER_OF_UE_MAX; i++) {
int harq_pid;
LTE_eNB_ULSCH_t *ulsch = eNB->ulsch[i];
if (ulsch == NULL)
continue;
if (ulsch->ue_type > NOCE)
harq_pid = 0;
else
harq_pid= subframe2harq_pid(&eNB->frame_parms,frame,subframe);
LTE_UL_eNB_HARQ_t *ulsch_harq = ulsch->harq_processes[harq_pid];
if (ulsch->rnti>0) {
LOG_D(PHY,"check in UL scheduled harq %d: rnti %d, tx frame %d/%d, ulsch: %d, %d/%d (handled: %d)\n",
harq_pid, ulsch->rnti, frame, subframe, ulsch_harq->status, ulsch_harq->frame, ulsch_harq->subframe, ulsch_harq->handled);
}
for (int k=0; k<8; k++) {
ulsch_harq = ulsch->harq_processes[k];
if (ulsch_harq == NULL)
continue;
if ((ulsch->rnti>0) &&
(ulsch_harq->status == ACTIVE) &&
(ulsch_harq->frame == frame) &&
(ulsch_harq->subframe == subframe) &&
(ulsch_harq->handled == 0)
)
appendFs6TxULUE(bufferZone,
fp,
i,
ulsch,
frame,
subframe
);
}
}
appendFs6DLUEcch(bufferZone,
eNB,
frame,
subframe
);
uint8_t num_pdcch_symbols = eNB->pdcch_vars[subframe&1].num_pdcch_symbols;
uint8_t num_dci = eNB->pdcch_vars[subframe&1].num_dci;
uint8_t num_mdci = eNB->mpdcch_vars[subframe&1].num_dci;
memcpy(hDL(bufferZone)->pbch_pdu,eNB->pbch_pdu,4);
if ( num_dci <= 8 )
LOG_D(PHY,"num_pdcch_symbols %"PRIu8",number dci %"PRIu8"\n",num_pdcch_symbols, num_dci);
else {
LOG_E(PHY, "Num dci too large for current FS6 implementation, reducing to 8 dci (was %d)\n", num_dci);
num_dci=8;
}
if (NFAPI_MODE==NFAPI_MONOLITHIC || NFAPI_MODE==NFAPI_MODE_PNF) {
hDL(bufferZone)->num_pdcch_symbols=num_pdcch_symbols;
hDL(bufferZone)->num_dci=num_dci;
hDL(bufferZone)->num_mdci=num_mdci;
hDL(bufferZone)->amp=AMP;
for (int i=0; i< hDL(bufferZone)->num_dci; i++)
hDL(bufferZone)->dci_alloc[i]=eNB->pdcch_vars[subframe&1].dci_alloc[i];
LOG_D(PHY, "pbch configured: %d\n", eNB->pbch_configured);
}
if (do_meas==1) stop_meas(&eNB->dlsch_common_and_dci);
if (do_meas==1) start_meas(&eNB->dlsch_ue_specific);
for (int UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) {
LTE_eNB_DLSCH_t *dlsch0 = eNB->dlsch[UE_id][0];
if ((dlsch0)&&(dlsch0->rnti>0)&&
#ifdef PHY_TX_THREAD
(dlsch0->active[subframe] == 1)
#else
(dlsch0->active == 1)
#endif
) {
// get harq_pid
int harq_pid = dlsch0->harq_ids[frame%2][subframe];
AssertFatal(harq_pid>=0,"harq_pid is negative\n");
if (harq_pid>=8) {
if (dlsch0->ue_type == NOCE)
LOG_E(PHY,"harq_pid:%d corrupt must be 0-7 UE_id:%d frame:%d subframe:%d rnti:%x [ %1d.%1d.%1d.%1d.%1d.%1d.%1d.%1d\n", harq_pid,UE_id,frame,subframe,dlsch0->rnti,
dlsch0->harq_ids[frame%2][0],
dlsch0->harq_ids[frame%2][1],
dlsch0->harq_ids[frame%2][2],
dlsch0->harq_ids[frame%2][3],
dlsch0->harq_ids[frame%2][4],
dlsch0->harq_ids[frame%2][5],
dlsch0->harq_ids[frame%2][6],
dlsch0->harq_ids[frame%2][7]);
} else {
if (dlsch_procedures(eNB,
proc,
harq_pid,
dlsch0,
&eNB->UE_stats[(uint32_t)UE_id])) {
// data in: dlsch0 harq_processes[harq_pid]->e
/* length
get_G(fp,
dlsch_harq->nb_rb,
dlsch_harq->rb_alloc,
dlsch_harq->Qm,
dlsch_harq->Nl,
dlsch_harq->pdsch_start,
frame,subframe,
0)
need harq_pid
*/
LTE_DL_eNB_HARQ_t *dlsch_harq=dlsch0->harq_processes[harq_pid];
appendFs6DLUE(bufferZone,
fp,
UE_id,
harq_pid,
dlsch0,
dlsch_harq,
frame,
subframe
);
}
}
} else if ((dlsch0)&&(dlsch0->rnti>0)&&
#ifdef PHY_TX_THREAD
(dlsch0->active[subframe] == 0)
#else
(dlsch0->active == 0)
#endif
) {
// clear subframe TX flag since UE is not scheduled for PDSCH in this subframe (so that we don't look for PUCCH later)
//dlsch0->subframe_tx[subframe]=0;
}
}
hDL(bufferZone)->phich_vars=eNB->phich_vars[subframe&1];
if (do_meas==1) stop_meas(&eNB->dlsch_ue_specific);
if (do_meas==1) stop_meas(&eNB->phy_proc_tx);
// MBMS is not working in OAI
if (hDL(bufferZone)->num_mdci) abort();
return;
}
void *DL_du_fs6(void *arg) {
RU_t *ru=(RU_t *)arg;
static uint64_t lastTS;
L1_rxtx_proc_t L1proc= {0};
// We pick the global thread pool from the legacy code global vars
L1proc.threadPool=RC.eNB[0][0]->proc.L1_proc.threadPool;
L1proc.respEncode=RC.eNB[0][0]->proc.L1_proc.respEncode;
L1proc.respDecode=RC.eNB[0][0]->proc.L1_proc.respDecode;
initStaticTime(begingWait);
initStaticTime(begingProcessing);
initRefTimes(fullLoop);
initRefTimes(DuHigh);
initRefTimes(DuLow);
initRefTimes(transportTime);
while (1) {
for (int i=0; i<ru->num_eNB; i++) {
initBufferZone(bufferZone);
pickStaticTime(begingWait);
int nb_blocks=receiveSubFrame(&sockFS6, bufferZone, sizeof(bufferZone), CTsentCUv0 );
updateTimesReset(begingWait, &fullLoop, 1000, false, "DU wait CU");
if (nb_blocks > 0) {
if ( lastTS+ru->eNB_list[i]->frame_parms.samples_per_tti < hUDP(bufferZone)->timestamp) {
LOG_E(HW,"Missed a subframe: expecting: %lu, received %lu\n",
lastTS+ru->eNB_list[i]->frame_parms.samples_per_tti,
hUDP(bufferZone)->timestamp);
} else if ( lastTS+ru->eNB_list[i]->frame_parms.samples_per_tti > hUDP(bufferZone)->timestamp) {
LOG_E(HW,"Received a subframe in past time from CU (dropping it): expecting: %lu, received %lu\n",
lastTS+ru->eNB_list[i]->frame_parms.samples_per_tti,
hUDP(bufferZone)->timestamp);
}
pickStaticTime(begingProcessing);
lastTS=hUDP(bufferZone)->timestamp;
setAllfromTS(hUDP(bufferZone)->timestamp - sf_ahead*ru->eNB_list[i]->frame_parms.samples_per_tti, &L1proc);
measTransportTime(hDL(bufferZone)->DuClock, hDL(bufferZone)->CuSpentMicroSec,
&transportTime, 1000, false, "Transport time, to CU + from CU for one subframe");
phy_procedures_eNB_TX_fromsplit( bufferZone, nb_blocks, ru->eNB_list[i], &L1proc, 1);
updateTimesReset(begingProcessing, &DuHigh, 1000, false, "DU high layer1 processing for DL");
} else
LOG_E(PHY,"DL not received for subframe\n");
}
pickStaticTime(begingProcessing);
feptx_prec(ru, L1proc.frame_tx,L1proc.subframe_tx );
feptx_ofdm(ru, L1proc.frame_tx,L1proc.subframe_tx );
ocp_tx_rf(ru, &L1proc);
updateTimesReset(begingProcessing, &DuLow, 1000, false, "DU low layer1 processing for DL");
if ( IS_SOFTMODEM_RFSIM )
return NULL;
}
return NULL;
}
void UL_du_fs6(RU_t *ru, L1_rxtx_proc_t *proc) {
initStaticTime(begingWait);
initRefTimes(fullLoop);
pickStaticTime(begingWait);
rx_rf(ru, proc);
updateTimesReset(begingWait, &fullLoop, 1000, false, "DU wait USRP");
// front end processing: convert from time domain to frequency domain
// fills rxdataF buffer
fep_full(ru, proc->subframe_rx);
// Fixme: datamodel issue
PHY_VARS_eNB *eNB = RC.eNB[0][0];
if (NFAPI_MODE==NFAPI_MODE_PNF) {
// I am a PNF and I need to let nFAPI know that we have a (sub)frame tick
//add_subframe(&frame, &subframe, 4);
//oai_subframe_ind(proc->frame_tx, proc->subframe_tx);
oai_subframe_ind(proc->frame_rx, proc->subframe_rx);
}
initBufferZone(bufferZone);
hUDP(bufferZone)->timestamp=proc->timestamp_rx;
prach_eNB_tosplit(bufferZone, FS6_BUF_SIZE, eNB, proc );
if (NFAPI_MODE==NFAPI_MONOLITHIC || NFAPI_MODE==NFAPI_MODE_PNF) {
phy_procedures_eNB_uespec_RX_tosplit(bufferZone, FS6_BUF_SIZE, eNB, proc );
}
if (hUDP(bufferZone)->nbBlocks==0) {
hUDP(bufferZone)->nbBlocks=1; // We have to send the signaling, even is there is no user plan data (no UE)
hUDP(bufferZone)->blockID=0;
hUDP(bufferZone)->contentBytes=sizeof(fs6_ul_t);
}
for (int i=0; i<ru->num_eNB; i++) {
sendSubFrame(&sockFS6, bufferZone, sizeof(fs6_ul_t), CTsentDUv0);
}
}
void DL_cu_fs6(RU_t *ru, L1_rxtx_proc_t *proc, uint64_t DuClock, uint64_t startCycle) {
initRefTimes(CUprocessing);
// Fixme: datamodel issue
PHY_VARS_eNB *eNB = RC.eNB[0][0];
pthread_mutex_lock(&eNB->UL_INFO_mutex);
eNB->UL_INFO.frame = proc->frame_rx;
eNB->UL_INFO.subframe = proc->subframe_rx;
eNB->UL_INFO.module_id = eNB->Mod_id;
eNB->UL_INFO.CC_id = eNB->CC_id;
eNB->if_inst->UL_indication(&eNB->UL_INFO, proc);
pthread_mutex_unlock(&eNB->UL_INFO_mutex);
initBufferZone(bufferZone);
phy_procedures_eNB_TX_tosplit(bufferZone, eNB, proc, 1, bufferZone, FS6_BUF_SIZE);
hUDP(bufferZone)->timestamp=proc->timestamp_tx;
if (hUDP(bufferZone)->nbBlocks==0) {
hUDP(bufferZone)->nbBlocks=1; // We have to send the signaling, even is there is no user plan data (no UE)
hUDP(bufferZone)->blockID=0;
hUDP(bufferZone)->contentBytes=sizeof(fs6_dl_t);
}
hDL(bufferZone)->DuClock=DuClock;
hDL(bufferZone)->CuSpentMicroSec=(rdtsc()-startCycle)/(cpuf*1000);
updateTimesReset(startCycle, &CUprocessing, 1000, true,"CU entire processing from recv to send");
sendSubFrame(&sockFS6, bufferZone, sizeof(fs6_dl_t), CTsentCUv0 );
return;
}
void UL_cu_fs6(RU_t *ru, L1_rxtx_proc_t *proc, uint64_t *TS, uint64_t *DuClock, uint64_t *startProcessing) {
initBufferZone(bufferZone);
initStaticTime(begingWait);
initRefTimes(fullLoop);
pickStaticTime(begingWait);
int nb_blocks=receiveSubFrame(&sockFS6, bufferZone, sizeof(bufferZone), CTsentDUv0 );
* DuClock=hUDP(bufferZone)->senderClock;
* startProcessing=rdtsc();
updateTimesReset(begingWait, &fullLoop, 1000, false, "CU wait DU");
if (nb_blocks ==0) {
LOG_W(PHY, "CU lost a subframe\n");
return;
}
if (nb_blocks != hUDP(bufferZone)->nbBlocks )
LOG_W(PHY, "received %d blocks for %d expected\n", nb_blocks, hUDP(bufferZone)->nbBlocks);
if ( *TS != hUDP(bufferZone)->timestamp ) {
LOG_W(HW, "CU received time: %lu instead of %lu expected\n", hUDP(bufferZone)->timestamp, *TS);
*TS=hUDP(bufferZone)->timestamp;
}
setAllfromTS(hUDP(bufferZone)->timestamp, proc);
PHY_VARS_eNB *eNB = RC.eNB[0][0];
if (is_prach_subframe(&eNB->frame_parms, proc->frame_prach,proc->subframe_prach)>0)
prach_eNB_fromsplit(bufferZone, sizeof(bufferZone), eNB, proc);
release_UE_in_freeList(eNB->Mod_id);
if (NFAPI_MODE==NFAPI_MONOLITHIC || NFAPI_MODE==NFAPI_MODE_PNF) {
phy_procedures_eNB_uespec_RX_fromsplit(bufferZone, nb_blocks, eNB, proc);
}
}
void *cu_fs6(void *arg) {
setbuf(stdout, NULL);
setbuf(stderr, NULL);
RU_t *ru = (RU_t *)arg;
//RU_proc_t *proc = &ru->proc;
fill_rf_config(ru,ru->rf_config_file);
init_frame_parms(ru->frame_parms,1);
phy_init_RU(ru);
wait_sync("ru_thread");
char remoteIP[1024];
strncpy(remoteIP,get_softmodem_params()->split73+3, 1023); //three first char should be cu: or du:
char port_def[256]=DU_PORT;
for (int i=0; i <1000; i++)
if (remoteIP[i]==':') {
strncpy(port_def,remoteIP+i+1,255);
remoteIP[i]=0;
break;
}
AssertFatal(createUDPsock(NULL, CU_PORT, remoteIP, port_def, &sockFS6), "");
L1_rxtx_proc_t L1proc= {0};
// We pick the global thread pool from the legacy code global vars
L1proc.threadPool=RC.eNB[0][0]->proc.L1_proc.threadPool;
L1proc.respEncode=RC.eNB[0][0]->proc.L1_proc.respEncode;
L1proc.respDecode=RC.eNB[0][0]->proc.L1_proc.respDecode;
uint64_t timeStamp=0;
initStaticTime(begingWait);
initStaticTime(begingWait2);
initRefTimes(waitDUAndProcessingUL);
initRefTimes(makeSendDL);
initRefTimes(fullLoop);
uint64_t DuClock=0, startProcessing=0;
while(1) {
timeStamp+=ru->frame_parms->samples_per_tti;
updateTimesReset(begingWait, &fullLoop, 1000, true, "CU for full SubFrame (must be less 1ms)");
pickStaticTime(begingWait);
UL_cu_fs6(ru, &L1proc, &timeStamp, &DuClock, &startProcessing);
updateTimesReset(begingWait, &waitDUAndProcessingUL, 1000, true,"CU Time in wait Rx + Ul processing");
pickStaticTime(begingWait2);
DL_cu_fs6(ru, &L1proc, DuClock, startProcessing);
updateTimesReset(begingWait2, &makeSendDL, 1000, true,"CU Time in DL build+send");
}
return NULL;
}
void *du_fs6(void *arg) {
setbuf(stdout, NULL);
setbuf(stderr, NULL);
RU_t *ru = (RU_t *)arg;
//RU_proc_t *proc = &ru->proc;
fill_rf_config(ru,ru->rf_config_file);
init_frame_parms(ru->frame_parms,1);
phy_init_RU(ru);
init_rf(ru);
wait_sync("ru_thread");
char remoteIP[1024];
strncpy(remoteIP,get_softmodem_params()->split73+3,1023); //three first char should be cu: or du:
char port_def[256]=CU_PORT;
for (int i=0; i <1000; i++)
if (remoteIP[i]==':') {
strncpy(port_def,remoteIP+i+1,255);
remoteIP[i]=0;
break;
}
AssertFatal(createUDPsock(NULL, DU_PORT, remoteIP, port_def, &sockFS6), "");
if (ru->rfdevice.trx_start_func(&ru->rfdevice) != 0)
LOG_E(HW,"Could not start the RF device\n");
else
LOG_I(PHY,"RU %d rf device ready\n",ru->idx);
initStaticTime(begingWait);
initRefTimes(waitRxAndProcessingUL);
initRefTimes(fullLoop);
pthread_t t;
if ( !IS_SOFTMODEM_RFSIM )
threadCreate(&t, DL_du_fs6, (void *)ru, "MainDuTx", -1, OAI_PRIORITY_RT_MAX);
L1_rxtx_proc_t L1proc= {0};
// We pick the global thread pool from the legacy code global vars
L1proc.threadPool=RC.eNB[0][0]->proc.L1_proc.threadPool;
L1proc.respEncode=RC.eNB[0][0]->proc.L1_proc.respEncode;
L1proc.respDecode=RC.eNB[0][0]->proc.L1_proc.respDecode;
while(!oai_exit) {
updateTimesReset(begingWait, &fullLoop, 1000, true,"DU for full SubFrame (must be less 1ms)");
pickStaticTime(begingWait);
UL_du_fs6(ru, &L1proc);
if ( IS_SOFTMODEM_RFSIM )
DL_du_fs6((void *)ru);
updateTimesReset(begingWait, &waitRxAndProcessingUL, 1000, true,"DU Time in wait Rx + Ul processing");
}
ru->rfdevice.trx_end_func(&ru->rfdevice);
LOG_I(PHY,"RU %d rf device stopped\n",ru->idx);
return NULL;
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Author and copyright: Laurent Thomas, open-cells.com
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
/*
* This file replaces
* targets/RT/USER/lte-softmodem.c
* targets/RT/USER/rt_wrapper.c
* targets/RT/USER/lte-ru.c
* targets/RT/USER/lte-enb.c
* targets/RT/USER/ru_control.c
* openair1/SCHED/prach_procedures.c
* The merger of OpenAir central code to this branch
* should check if these 3 files are modified and analyze if code code has to be copied in here
*/
#define _GNU_SOURCE
#include <pthread.h>
#include <common/utils/LOG/log.h>
#include <common/utils/system.h>
#include <common/utils/assertions.h>
static int DEFBANDS[] = {7};
static int DEFENBS[] = {0};
#include <common/config/config_userapi.h>
#include <targets/RT/USER/lte-softmodem.h>
#include <openair1/PHY/defs_eNB.h>
#include <openair1/PHY/phy_extern.h>
#include <nfapi/oai_integration/vendor_ext.h>
#include <openair1/SCHED/fapi_l1.h>
#include <openair1/PHY/INIT/phy_init.h>
#include <openair2/LAYER2/MAC/mac_extern.h>
#include <openair1/PHY/LTE_REFSIG/lte_refsig.h>
#include <nfapi/oai_integration/nfapi_pnf.h>
#include <executables/split_headers.h>
#include <common/utils/threadPool/thread-pool.h>
#include <openair2/ENB_APP/NB_IoT_interface.h>
#include <common/utils/load_module_shlib.h>
#include <targets/COMMON/create_tasks.h>
#include <openair1/PHY/TOOLS/phy_scope_interface.h>
#include <openair2/UTIL/OPT/opt.h>
#include <openair1/SIMULATION/TOOLS/sim.h>
#include <openair1/PHY/phy_vars.h>
#include <openair1/SCHED/sched_common_vars.h>
#include <openair2/LAYER2/MAC/mac_vars.h>
#include <openair2/RRC/LTE/rrc_vars.h>
pthread_cond_t nfapi_sync_cond;
pthread_mutex_t nfapi_sync_mutex;
int nfapi_sync_var=-1; //!< protected by mutex \ref nfapi_sync_mutex
pthread_cond_t sync_cond;
pthread_mutex_t sync_mutex;
int sync_var=-1; //!< protected by mutex \ref sync_mutex.
int config_sync_var=-1;
volatile int oai_exit = 0;
double cpuf;
uint16_t sf_ahead=4;
int otg_enabled;
uint64_t downlink_frequency[MAX_NUM_CCs][4];
int32_t uplink_frequency_offset[MAX_NUM_CCs][4];
int split73;
char * split73_config;
int split73;
static void *ru_thread( void *param );
void kill_RU_proc(RU_t *ru) {
}
void kill_eNB_proc(int inst) {
}
void free_transport(PHY_VARS_eNB *eNB) {
}
void reset_opp_meas(void) {
}
extern void phy_free_RU(RU_t *);
void exit_function(const char *file, const char *function, const int line, const char *s) {
if (s != NULL) {
printf("%s:%d %s() Exiting OAI softmodem: %s\n",file,line, function, s);
}
close_log_mem();
oai_exit = 1;
if (RC.ru == NULL)
exit(-1); // likely init not completed, prevent crash or hang, exit now...
for (int ru_id=0; ru_id<RC.nb_RU; ru_id++) {
if (RC.ru[ru_id] && RC.ru[ru_id]->rfdevice.trx_end_func) {
RC.ru[ru_id]->rfdevice.trx_end_func(&RC.ru[ru_id]->rfdevice);
RC.ru[ru_id]->rfdevice.trx_end_func = NULL;
}
if (RC.ru[ru_id] && RC.ru[ru_id]->ifdevice.trx_end_func) {
RC.ru[ru_id]->ifdevice.trx_end_func(&RC.ru[ru_id]->ifdevice);
RC.ru[ru_id]->ifdevice.trx_end_func = NULL;
}
}
sleep(1); //allow lte-softmodem threads to exit first
exit(1);
}
// Fixme: there are many mistakes in the datamodel and in redondant variables
// TDD is also mode complex
void setAllfromTS(uint64_t TS, L1_rxtx_proc_t *proc) {
for (int i=0; i < RC.nb_inst; i++) {
for (int j=0; j<RC.nb_CC[i]; j++) {
LTE_DL_FRAME_PARMS *fp=&RC.eNB[i][j]->frame_parms;
uint64_t TStx=TS+(sf_ahead)*fp->samples_per_tti;
uint64_t TSrach=TS;//-fp->samples_per_tti;
proc->timestamp_rx= TS;
proc->timestamp_tx= TStx;
proc->subframe_rx= (TS / fp->samples_per_tti)%10;
proc->subframe_prach=(TSrach / fp->samples_per_tti)%10;
proc->subframe_prach_br=(TSrach / fp->samples_per_tti)%10;
proc->frame_rx= (TS / (fp->samples_per_tti*10))&1023;
proc->frame_prach= (TSrach / (fp->samples_per_tti*10))&1023;
proc->frame_prach_br=(TSrach / (fp->samples_per_tti*10))&1023;
proc->frame_tx= (TStx / (fp->samples_per_tti*10))&1023;
proc->subframe_tx= (TStx / fp->samples_per_tti)%10;
}
}
return;
}
void init_RU_proc(RU_t *ru) {
pthread_t t;
switch(split73) {
case SPLIT73_CU:
threadCreate(&t, cu_fs6, (void *)ru, "MainCu", -1, OAI_PRIORITY_RT_MAX);
break;
case SPLIT73_DU:
threadCreate(&t, du_fs6, (void *)ru, "MainDuRx", -1, OAI_PRIORITY_RT_MAX);
break;
default:
threadCreate(&t, ru_thread, (void *)ru, "MainRu", -1, OAI_PRIORITY_RT_MAX);
}
}
// Create per UE structures
void init_transport(PHY_VARS_eNB *eNB) {
LTE_DL_FRAME_PARMS *fp = &eNB->frame_parms;
LOG_I(PHY, "Initialise transport\n");
for (int i=0; i<NUMBER_OF_UE_MAX; i++) {
LOG_D(PHY,"Allocating Transport Channel Buffers for DLSCH, UE %d\n",i);
for (int j=0; j<2; j++) {
AssertFatal( (eNB->dlsch[i][j] = new_eNB_dlsch(1,8,NSOFT,fp->N_RB_DL,0,fp)) != NULL,
"Can't get eNB dlsch structures for UE %d \n", i);
eNB->dlsch[i][j]->rnti=0;
LOG_D(PHY,"dlsch[%d][%d] => %p rnti:%d\n",i,j,eNB->dlsch[i][j], eNB->dlsch[i][j]->rnti);
}
LOG_D(PHY,"Allocating Transport Channel Buffer for ULSCH, UE %d\n",i);
AssertFatal((eNB->ulsch[1+i] = new_eNB_ulsch(MAX_TURBO_ITERATIONS,fp->N_RB_UL, 0)) != NULL,
"Can't get eNB ulsch structures\n");
// this is the transmission mode for the signalling channels
// this will be overwritten with the real transmission mode by the RRC once the UE is connected
eNB->transmission_mode[i] = fp->nb_antenna_ports_eNB==1 ? 1 : 2;
}
// ULSCH for RA
AssertFatal( (eNB->ulsch[0] = new_eNB_ulsch(MAX_TURBO_ITERATIONS, fp->N_RB_UL, 0)) !=NULL,
"Can't get eNB ulsch structures\n");
eNB->dlsch_SI = new_eNB_dlsch(1,8,NSOFT,fp->N_RB_DL, 0, fp);
LOG_D(PHY,"eNB %d.%d : SI %p\n",eNB->Mod_id,eNB->CC_id,eNB->dlsch_SI);
eNB->dlsch_ra = new_eNB_dlsch(1,8,NSOFT,fp->N_RB_DL, 0, fp);
LOG_D(PHY,"eNB %d.%d : RA %p\n",eNB->Mod_id,eNB->CC_id,eNB->dlsch_ra);
eNB->dlsch_MCH = new_eNB_dlsch(1,8,NSOFT,fp->N_RB_DL, 0, fp);
LOG_D(PHY,"eNB %d.%d : MCH %p\n",eNB->Mod_id,eNB->CC_id,eNB->dlsch_MCH);
eNB->rx_total_gain_dB=130;
for(int i=0; i<NUMBER_OF_UE_MAX; i++)
eNB->mu_mimo_mode[i].dl_pow_off = 2;
eNB->check_for_total_transmissions = 0;
eNB->check_for_MUMIMO_transmissions = 0;
eNB->FULL_MUMIMO_transmissions = 0;
eNB->check_for_SUMIMO_transmissions = 0;
fp->pucch_config_common.deltaPUCCH_Shift = 1;
}
void init_eNB_afterRU(void) {
for (int inst=0; inst<RC.nb_inst; inst++) {
for (int CC_id=0; CC_id<RC.nb_CC[inst]; CC_id++) {
PHY_VARS_eNB *eNB = RC.eNB[inst][CC_id];
phy_init_lte_eNB(eNB,0,0);
eNB->frame_parms.nb_antennas_rx = 0;
eNB->frame_parms.nb_antennas_tx = 0;
eNB->prach_vars.rxsigF[0] = (int16_t **)malloc16(64*sizeof(int16_t *));
for (int ce_level=0; ce_level<4; ce_level++) {
eNB->prach_vars_br.rxsigF[ce_level] = (int16_t **)malloc16(64*sizeof(int16_t *));
}
for (int ru_id=0,aa=0; ru_id<eNB->num_RU; ru_id++) {
eNB->frame_parms.nb_antennas_rx += eNB->RU_list[ru_id]->nb_rx;
eNB->frame_parms.nb_antennas_tx += eNB->RU_list[ru_id]->nb_tx;
AssertFatal(eNB->RU_list[ru_id]->common.rxdataF!=NULL,
"RU %d : common.rxdataF is NULL\n",
eNB->RU_list[ru_id]->idx);
AssertFatal(eNB->RU_list[ru_id]->prach_rxsigF!=NULL,
"RU %d : prach_rxsigF is NULL\n",
eNB->RU_list[ru_id]->idx);
for (int i=0; i<eNB->RU_list[ru_id]->nb_rx; aa++,i++) {
LOG_I(PHY,"Attaching RU %d antenna %d to eNB antenna %d\n",eNB->RU_list[ru_id]->idx,i,aa);
eNB->prach_vars.rxsigF[0][aa] = eNB->RU_list[ru_id]->prach_rxsigF[i];
for (int ce_level=0; ce_level<4; ce_level++)
eNB->prach_vars_br.rxsigF[ce_level][aa] = eNB->RU_list[ru_id]->prach_rxsigF_br[ce_level][i];
eNB->common_vars.rxdataF[aa] = eNB->RU_list[ru_id]->common.rxdataF[i];
}
}
AssertFatal( eNB->frame_parms.nb_antennas_rx > 0 && eNB->frame_parms.nb_antennas_rx < 4, "");
AssertFatal( eNB->frame_parms.nb_antennas_tx > 0 && eNB->frame_parms.nb_antennas_rx < 4, "");
LOG_I(PHY,"inst %d, CC_id %d : nb_antennas_rx %d\n",inst,CC_id,eNB->frame_parms.nb_antennas_rx);
init_transport(eNB);
//init_precoding_weights(RC.eNB[inst][CC_id]);
}
}
}
void init_eNB(int single_thread_flag,int wait_for_sync) {
AssertFatal(RC.eNB != NULL,"RC.eNB must have been allocated\n");
for (int inst=0; inst<RC.nb_L1_inst; inst++) {
AssertFatal(RC.eNB[inst] != NULL,"RC.eNB[%d] must have been allocated\n", inst);
for (int CC_id=0; CC_id<RC.nb_L1_CC[inst]; CC_id++) {
AssertFatal(RC.eNB[inst][CC_id] != NULL,"RC.eNB[%d][%d] must have been allocated\n", inst, CC_id);
PHY_VARS_eNB *eNB = RC.eNB[inst][CC_id];
eNB->abstraction_flag = 0;
eNB->single_thread_flag = single_thread_flag;
AssertFatal((eNB->if_inst = IF_Module_init(inst))!=NULL,"Cannot register interface");
eNB->if_inst->schedule_response = schedule_response;
eNB->if_inst->PHY_config_req = phy_config_request;
memset((void *)&eNB->UL_INFO,0,sizeof(eNB->UL_INFO));
memset((void *)&eNB->Sched_INFO,0,sizeof(eNB->Sched_INFO));
pthread_mutex_init( &eNB->UL_INFO_mutex, NULL);
LOG_I(PHY,"Setting indication lists\n");
eNB->UL_INFO.rx_ind.rx_indication_body.rx_pdu_list = eNB->rx_pdu_list;
eNB->UL_INFO.crc_ind.crc_indication_body.crc_pdu_list = eNB->crc_pdu_list;
eNB->UL_INFO.sr_ind.sr_indication_body.sr_pdu_list = eNB->sr_pdu_list;
eNB->UL_INFO.harq_ind.harq_indication_body.harq_pdu_list = eNB->harq_pdu_list;
eNB->UL_INFO.cqi_ind.cqi_indication_body.cqi_pdu_list = eNB->cqi_pdu_list;
eNB->UL_INFO.cqi_ind.cqi_indication_body.cqi_raw_pdu_list = eNB->cqi_raw_pdu_list;
eNB->prach_energy_counter = 0;
}
}
SET_LOG_DEBUG(PRACH);
}
void stop_eNB(int nb_inst) {
for (int inst=0; inst<nb_inst; inst++) {
LOG_I(PHY,"Killing eNB %d processing threads\n",inst);
kill_eNB_proc(inst);
}
}
// this is for RU with local RF unit
void fill_rf_config(RU_t *ru, char *rf_config_file) {
int i;
LTE_DL_FRAME_PARMS *fp = ru->frame_parms;
openair0_config_t *cfg = &ru->openair0_cfg;
//printf("////////////////numerology in config = %d\n",numerology);
int numerology = get_softmodem_params()->numerology;
if(fp->N_RB_DL == 100) {
if(numerology == 0) {
if (fp->threequarter_fs) {
cfg->sample_rate=23.04e6;
cfg->samples_per_frame = 230400;
cfg->tx_bw = 10e6;
cfg->rx_bw = 10e6;
} else {
cfg->sample_rate=30.72e6;
cfg->samples_per_frame = 307200;
cfg->tx_bw = 10e6;
cfg->rx_bw = 10e6;
}
} else if(numerology == 1) {
cfg->sample_rate=61.44e6;
cfg->samples_per_frame = 307200;
cfg->tx_bw = 20e6;
cfg->rx_bw = 20e6;
} else if(numerology == 2) {
cfg->sample_rate=122.88e6;
cfg->samples_per_frame = 307200;
cfg->tx_bw = 40e6;
cfg->rx_bw = 40e6;
} else {
LOG_E(PHY,"Wrong input for numerology %d\n setting to 20MHz normal CP configuration",numerology);
cfg->sample_rate=30.72e6;
cfg->samples_per_frame = 307200;
cfg->tx_bw = 10e6;
cfg->rx_bw = 10e6;
}
} else if(fp->N_RB_DL == 50) {
cfg->sample_rate=15.36e6;
cfg->samples_per_frame = 153600;
cfg->tx_bw = 5e6;
cfg->rx_bw = 5e6;
} else if (fp->N_RB_DL == 25) {
cfg->sample_rate=7.68e6;
cfg->samples_per_frame = 76800;
cfg->tx_bw = 2.5e6;
cfg->rx_bw = 2.5e6;
} else if (fp->N_RB_DL == 6) {
cfg->sample_rate=1.92e6;
cfg->samples_per_frame = 19200;
cfg->tx_bw = 1.5e6;
cfg->rx_bw = 1.5e6;
} else AssertFatal(1==0,"Unknown N_RB_DL %d\n",fp->N_RB_DL);
if (fp->frame_type==TDD)
cfg->duplex_mode = duplex_mode_TDD;
else //FDD
cfg->duplex_mode = duplex_mode_FDD;
cfg->Mod_id = 0;
cfg->num_rb_dl=fp->N_RB_DL;
cfg->tx_num_channels=ru->nb_tx;
cfg->rx_num_channels=ru->nb_rx;
cfg->clock_source=get_softmodem_params()->clock_source;
for (i=0; i<ru->nb_tx; i++) {
cfg->tx_freq[i] = (double)fp->dl_CarrierFreq;
cfg->rx_freq[i] = (double)fp->ul_CarrierFreq;
cfg->tx_gain[i] = (double)ru->att_tx;
cfg->rx_gain[i] = ru->max_rxgain-(double)ru->att_rx;
cfg->configFilename = rf_config_file;
LOG_I(PHY,"channel %d, Setting tx_gain offset %f, rx_gain offset %f, tx_freq %f, rx_freq %f\n",
i, cfg->tx_gain[i],
cfg->rx_gain[i],
cfg->tx_freq[i],
cfg->rx_freq[i]);
}
}
/* this function maps the RU tx and rx buffers to the available rf chains.
Each rf chain is is addressed by the card number and the chain on the card. The
rf_map specifies for each antenna port, on which rf chain the mapping should start. Multiple
antennas are mapped to successive RF chains on the same card. */
int setup_RU_buffers(RU_t *ru) {
//uint16_t N_TA_offset = 0;
LTE_DL_FRAME_PARMS *frame_parms;
AssertFatal(ru, "ru is NULL");
frame_parms = ru->frame_parms;
LOG_I(PHY,"setup_RU_buffers: frame_parms = %p\n",frame_parms);
if (frame_parms->frame_type == TDD) {
if (frame_parms->N_RB_DL == 100) {
ru->N_TA_offset = 624;
} else if (frame_parms->N_RB_DL == 50) {
ru->N_TA_offset = 624/2;
ru->sf_extension /= 2;
ru->end_of_burst_delay /= 2;
} else if (frame_parms->N_RB_DL == 25) {
ru->N_TA_offset = 624/4;
ru->sf_extension /= 4;
ru->end_of_burst_delay /= 4;
} else {
LOG_E(PHY,"not handled, todo\n");
exit(1);
}
} else {
ru->N_TA_offset = 0;
ru->sf_extension = 0;
ru->end_of_burst_delay = 0;
}
return(0);
}
void init_precoding_weights(PHY_VARS_eNB *eNB) {
int layer,ru_id,aa,re,ue,tb;
LTE_DL_FRAME_PARMS *fp=&eNB->frame_parms;
RU_t *ru;
LTE_eNB_DLSCH_t *dlsch;
// init precoding weigths
for (ue=0; ue<NUMBER_OF_UE_MAX; ue++) {
for (tb=0; tb<2; tb++) {
dlsch = eNB->dlsch[ue][tb];
for (layer=0; layer<4; layer++) {
int nb_tx=0;
for (ru_id=0; ru_id<RC.nb_RU; ru_id++) {
ru = RC.ru[ru_id];
nb_tx+=ru->nb_tx;
}
dlsch->ue_spec_bf_weights[layer] = (int32_t **)malloc16(nb_tx*sizeof(int32_t *));
for (aa=0; aa<nb_tx; aa++) {
dlsch->ue_spec_bf_weights[layer][aa] = (int32_t *)malloc16(fp->ofdm_symbol_size*sizeof(int32_t));
for (re=0; re<fp->ofdm_symbol_size; re++) {
dlsch->ue_spec_bf_weights[layer][aa][re] = 0x00007fff;
}
}
}
}
}
}
void ocp_rx_prach(PHY_VARS_eNB *eNB,
L1_rxtx_proc_t *proc,
RU_t *ru,
uint16_t *max_preamble,
uint16_t *max_preamble_energy,
uint16_t *max_preamble_delay,
uint16_t *avg_preamble_energy,
uint16_t Nf,
uint8_t tdd_mapindex,
uint8_t br_flag) {
int i;
int prach_mask=0;
if (br_flag == 0) {
rx_prach0(eNB,ru,proc->frame_prach, proc->subframe_prach,
max_preamble,max_preamble_energy,max_preamble_delay,avg_preamble_energy,Nf,tdd_mapindex,0,0);
} else { // This is procedure for eMTC, basically handling the repetitions
prach_mask = is_prach_subframe(&eNB->frame_parms,proc->frame_prach_br,proc->subframe_prach_br);
for (i=0; i<4; i++) {
if ((eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_CElevel_enable[i]==1) &&
((prach_mask&(1<<(i+1))) > 0)) { // check that prach CE level is active now
// if first reception in group of repetitions store frame for later (in RA-RNTI for Msg2)
if (eNB->prach_vars_br.repetition_number[i]==0) eNB->prach_vars_br.first_frame[i]=proc->frame_prach_br;
// increment repetition number
eNB->prach_vars_br.repetition_number[i]++;
// do basic PRACH reception
rx_prach0(eNB,ru,proc->frame_prach, proc->subframe_prach_br,
max_preamble,max_preamble_energy,max_preamble_delay,avg_preamble_energy,Nf,tdd_mapindex,1,i);
// if last repetition, clear counter
if (eNB->prach_vars_br.repetition_number[i] == eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_numRepetitionPerPreambleAttempt[i]) {
eNB->prach_vars_br.repetition_number[i]=0;
}
}
} /* for i ... */
} /* else br_flag == 0 */
}
void prach_procedures_ocp(PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc, int br_flag) {
uint16_t max_preamble[4],max_preamble_energy[4],max_preamble_delay[4],avg_preamble_energy[4];
RU_t *ru;
int aa=0;
int ru_aa;
for (int i=0; i<eNB->num_RU; i++) {
ru=eNB->RU_list[i];
for (ru_aa=0,aa=0; ru_aa<ru->nb_rx; ru_aa++,aa++) {
eNB->prach_vars.rxsigF[0][aa] = eNB->RU_list[i]->prach_rxsigF[ru_aa];
int ce_level;
if (br_flag==1)
for (ce_level=0; ce_level<4; ce_level++)
eNB->prach_vars_br.rxsigF[ce_level][aa] = eNB->RU_list[i]->prach_rxsigF_br[ce_level][ru_aa];
}
}
// run PRACH detection for CE-level 0 only for now when br_flag is set
ocp_rx_prach(eNB,
proc,
eNB->RU_list[0],
&max_preamble[0],
&max_preamble_energy[0],
&max_preamble_delay[0],
&avg_preamble_energy[0],
proc->frame_prach,
0
,br_flag
);
LOG_D(PHY,"RACH detection index 0: max preamble: %u, energy: %u, delay: %u, avg energy: %u\n",
max_preamble[0],
max_preamble_energy[0],
max_preamble_delay[0],
avg_preamble_energy[0]
);
if (br_flag==1) {
int prach_mask;
prach_mask = is_prach_subframe (&eNB->frame_parms, proc->frame_prach_br, proc->subframe_prach_br);
eNB->UL_INFO.rach_ind_br.rach_indication_body.preamble_list = eNB->preamble_list_br;
int ind = 0;
int ce_level = 0;
/* Save for later, it doesn't work
for (int ind=0,ce_level=0;ce_level<4;ce_level++) {
if ((eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_CElevel_enable[ce_level]==1)&&
(prach_mask&(1<<(1+ce_level)) > 0) && // prach is active and CE level has finished its repetitions
(eNB->prach_vars_br.repetition_number[ce_level]==
eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_numRepetitionPerPreambleAttempt[ce_level])) {
*/
if (eNB->frame_parms.prach_emtc_config_common.prach_ConfigInfo.prach_CElevel_enable[0] == 1) {
if ((eNB->prach_energy_counter == 100) && (max_preamble_energy[0] > eNB->measurements.prach_I0 + eNB->prach_DTX_threshold_emtc[0])) {
eNB->UL_INFO.rach_ind_br.rach_indication_body.number_of_preambles++;
eNB->preamble_list_br[ind].preamble_rel8.timing_advance = max_preamble_delay[ind]; //
eNB->preamble_list_br[ind].preamble_rel8.preamble = max_preamble[ind];
// note: fid is implicitly 0 here, this is the rule for eMTC RA-RNTI from 36.321, Section 5.1.4
eNB->preamble_list_br[ind].preamble_rel8.rnti = 1 + proc->subframe_prach + (60*(eNB->prach_vars_br.first_frame[ce_level] % 40));
eNB->preamble_list_br[ind].instance_length = 0; //don't know exactly what this is
eNB->preamble_list_br[ind].preamble_rel13.rach_resource_type = 1 + ce_level; // CE Level
LOG_I (PHY, "Filling NFAPI indication for RACH %d CELevel %d (mask %x) : TA %d, Preamble %d, rnti %x, rach_resource_type %d\n",
ind,
ce_level,
prach_mask,
eNB->preamble_list_br[ind].preamble_rel8.timing_advance,
eNB->preamble_list_br[ind].preamble_rel8.preamble, eNB->preamble_list_br[ind].preamble_rel8.rnti, eNB->preamble_list_br[ind].preamble_rel13.rach_resource_type);
}
}
/*
ind++;
}
} */// ce_level
} else if ((eNB->prach_energy_counter == 100) &&
(max_preamble_energy[0] > eNB->measurements.prach_I0+eNB->prach_DTX_threshold)) {
LOG_I(PHY,"[eNB %d/%d][RAPROC] Frame %d, subframe %d Initiating RA procedure with preamble %d, energy %d.%d dB, delay %d\n",
eNB->Mod_id,
eNB->CC_id,
proc->frame_prach,
proc->subframe_prach,
max_preamble[0],
max_preamble_energy[0]/10,
max_preamble_energy[0]%10,
max_preamble_delay[0]);
pthread_mutex_lock(&eNB->UL_INFO_mutex);
eNB->UL_INFO.rach_ind.rach_indication_body.number_of_preambles = 1;
eNB->UL_INFO.rach_ind.rach_indication_body.preamble_list = &eNB->preamble_list[0];
eNB->UL_INFO.rach_ind.rach_indication_body.tl.tag = NFAPI_RACH_INDICATION_BODY_TAG;
eNB->UL_INFO.rach_ind.header.message_id = NFAPI_RACH_INDICATION;
eNB->UL_INFO.rach_ind.sfn_sf = proc->frame_prach<<4 | proc->subframe_prach;
eNB->preamble_list[0].preamble_rel8.tl.tag = NFAPI_PREAMBLE_REL8_TAG;
eNB->preamble_list[0].preamble_rel8.timing_advance = max_preamble_delay[0];
eNB->preamble_list[0].preamble_rel8.preamble = max_preamble[0];
eNB->preamble_list[0].preamble_rel8.rnti = 1+proc->subframe_prach; // note: fid is implicitly 0 here
eNB->preamble_list[0].preamble_rel13.rach_resource_type = 0;
eNB->preamble_list[0].instance_length = 0; //don't know exactly what this is
if (NFAPI_MODE==NFAPI_MODE_PNF) { // If NFAPI PNF then we need to send the message to the VNF
LOG_D(PHY,"Filling NFAPI indication for RACH : SFN_SF:%d TA %d, Preamble %d, rnti %x, rach_resource_type %d\n",
NFAPI_SFNSF2DEC(eNB->UL_INFO.rach_ind.sfn_sf),
eNB->preamble_list[0].preamble_rel8.timing_advance,
eNB->preamble_list[0].preamble_rel8.preamble,
eNB->preamble_list[0].preamble_rel8.rnti,
eNB->preamble_list[0].preamble_rel13.rach_resource_type);
oai_nfapi_rach_ind(&eNB->UL_INFO.rach_ind);
eNB->UL_INFO.rach_ind.rach_indication_body.number_of_preambles = 0;
}
pthread_mutex_unlock(&eNB->UL_INFO_mutex);
} // max_preamble_energy > prach_I0 + 100
else {
eNB->measurements.prach_I0 = ((eNB->measurements.prach_I0*900)>>10) + ((avg_preamble_energy[0]*124)>>10);
if (eNB->prach_energy_counter < 100)
eNB->prach_energy_counter++;
}
} // else br_flag
void prach_eNB(PHY_VARS_eNB *eNB, L1_rxtx_proc_t *proc, int frame,int subframe) {
// check if we have to detect PRACH first
if (is_prach_subframe(&eNB->frame_parms, frame,subframe)>0) {
prach_procedures_ocp(eNB, proc, 0);
prach_procedures_ocp(eNB, proc, 1);
}
}
static inline int rxtx(PHY_VARS_eNB *eNB,L1_rxtx_proc_t *proc, char *thread_name) {
AssertFatal( eNB !=NULL, "");
if (NFAPI_MODE==NFAPI_MODE_PNF) {
// I am a PNF and I need to let nFAPI know that we have a (sub)frame tick
//add_subframe(&frame, &subframe, 4);
//oai_subframe_ind(proc->frame_tx, proc->subframe_tx);
oai_subframe_ind(proc->frame_rx, proc->subframe_rx);
}
AssertFatal( !(NFAPI_MODE==NFAPI_MODE_PNF &&
eNB->pdcch_vars[proc->subframe_tx&1].num_pdcch_symbols == 0), "");
prach_eNB(eNB,proc,proc->frame_rx,proc->subframe_rx);
release_UE_in_freeList(eNB->Mod_id);
// UE-specific RX processing for subframe n
if (NFAPI_MODE==NFAPI_MONOLITHIC || NFAPI_MODE==NFAPI_MODE_PNF) {
phy_procedures_eNB_uespec_RX(eNB, proc);
}
pthread_mutex_lock(&eNB->UL_INFO_mutex);
eNB->UL_INFO.frame = proc->frame_rx;
eNB->UL_INFO.subframe = proc->subframe_rx;
eNB->UL_INFO.module_id = eNB->Mod_id;
eNB->UL_INFO.CC_id = eNB->CC_id;
eNB->if_inst->UL_indication(&eNB->UL_INFO, proc);
pthread_mutex_unlock(&eNB->UL_INFO_mutex);
phy_procedures_eNB_TX(eNB, proc, 1);
return(0);
}
void rx_rf(RU_t *ru, L1_rxtx_proc_t *proc) {
LTE_DL_FRAME_PARMS *fp = ru->frame_parms;
void *rxp[ru->nb_rx];
unsigned int rxs;
int i;
openair0_timestamp ts=0, timestamp_rx;
static openair0_timestamp old_ts=0;
for (i=0; i<ru->nb_rx; i++)
//receive in the next slot
rxp[i] = (void *)&ru->common.rxdata[i][((proc->subframe_rx+1)%10)*fp->samples_per_tti];
rxs = ru->rfdevice.trx_read_func(&ru->rfdevice,
&ts,
rxp,
fp->samples_per_tti,
ru->nb_rx);
timestamp_rx = ts-ru->ts_offset;
// AssertFatal(rxs == fp->samples_per_tti,
// "rx_rf: Asked for %d samples, got %d from SDR\n",fp->samples_per_tti,rxs);
if(rxs != fp->samples_per_tti) {
LOG_E(PHY,"rx_rf: Asked for %d samples, got %d from SDR\n",fp->samples_per_tti,rxs);
#if defined(USRP_REC_PLAY)
exit_fun("Exiting IQ record/playback");
#else
//exit_fun( "problem receiving samples" );
LOG_E(PHY, "problem receiving samples");
#endif
}
if (old_ts != 0 && timestamp_rx - old_ts != fp->samples_per_tti) {
LOG_E(HW,"impossible shift in rx stream, rx: %ld, previous rx distance: %ld, should be %d\n", timestamp_rx, proc->timestamp_rx - old_ts, fp->samples_per_tti);
//ru->ts_offset += (proc->timestamp_rx - old_ts - fp->samples_per_tti);
//proc->timestamp_rx = ts-ru->ts_offset;
}
old_ts=timestamp_rx;
setAllfromTS(timestamp_rx, proc);
}
void ocp_tx_rf(RU_t *ru, L1_rxtx_proc_t *proc) {
LTE_DL_FRAME_PARMS *fp = ru->frame_parms;
void *txp[ru->nb_tx];
int i;
lte_subframe_t SF_type = subframe_select(fp,proc->subframe_tx%10);
lte_subframe_t prevSF_type = subframe_select(fp,(proc->subframe_tx+9)%10);
int sf_extension = 0;
if ((SF_type == SF_DL) ||
(SF_type == SF_S)) {
int siglen=fp->samples_per_tti,flags=1;
if (SF_type == SF_S) {
/* end_of_burst_delay is used to stop TX only "after a while".
* If we stop right after effective signal, with USRP B210 and
* B200mini, we observe a high EVM on the S subframe (on the
* PSS).
* A value of 400 (for 30.72MHz) solves this issue. This is
* the default.
*/
siglen = (fp->ofdm_symbol_size + fp->nb_prefix_samples0)
+ (fp->dl_symbols_in_S_subframe - 1) * (fp->ofdm_symbol_size + fp->nb_prefix_samples)
+ ru->end_of_burst_delay;
flags=3; // end of burst
}
if (fp->frame_type == TDD &&
SF_type == SF_DL &&
prevSF_type == SF_UL) {
flags = 2; // start of burst
sf_extension = ru->sf_extension;
}
#if defined(__x86_64) || defined(__i386__)
#ifdef __AVX2__
sf_extension = (sf_extension)&0xfffffff8;
#else
sf_extension = (sf_extension)&0xfffffffc;
#endif
#elif defined(__arm__)
sf_extension = (sf_extension)&0xfffffffc;
#endif
for (i=0; i<ru->nb_tx; i++)
txp[i] = (void *)&ru->common.txdata[i][(proc->subframe_tx*fp->samples_per_tti)-sf_extension];
/* add fail safe for late command end */
// prepare tx buffer pointers
ru->rfdevice.trx_write_func(&ru->rfdevice,
proc->timestamp_tx+ru->ts_offset-ru->openair0_cfg.tx_sample_advance-sf_extension,
txp,
siglen+sf_extension,
ru->nb_tx,
flags);
LOG_D(PHY,"[TXPATH] RU %d tx_rf, writing to TS %llu, frame %d, subframe %d\n",ru->idx,
(long long unsigned int)proc->timestamp_tx,proc->frame_tx,proc->subframe_tx);
}
return;
}
static void *ru_thread( void *param ) {
setbuf(stdout, NULL);
setbuf(stderr, NULL);
RU_t *ru = (RU_t *)param;
L1_rxtx_proc_t L1proc= {0};
// We pick the global thread pool from the legacy code global vars
L1proc.threadPool=RC.eNB[0][0]->proc.L1_proc.threadPool;
L1proc.respEncode=RC.eNB[0][0]->proc.L1_proc.respEncode;
L1proc.respDecode=RC.eNB[0][0]->proc.L1_proc.respDecode;
if (ru->if_south == LOCAL_RF) { // configure RF parameters only
fill_rf_config(ru,ru->rf_config_file);
init_frame_parms(ru->frame_parms,1);
phy_init_RU(ru);
init_rf(ru);
}
AssertFatal(setup_RU_buffers(ru)==0, "Exiting, cannot initialize RU Buffers\n");
LOG_I(PHY, "Signaling main thread that RU %d is ready\n",ru->idx);
wait_sync("ru_thread");
// Start RF device if any
if (ru->rfdevice.trx_start_func(&ru->rfdevice) != 0)
LOG_E(HW,"Could not start the RF device\n");
else LOG_I(PHY,"RU %d rf device ready\n",ru->idx);
// This is a forever while loop, it loops over subframes which are scheduled by incoming samples from HW devices
while (!oai_exit) {
// synchronization on input FH interface, acquire signals/data and block
rx_rf(ru, &L1proc);
// do RX front-end processing (frequency-shift, dft) if needed
fep_full(ru, L1proc.subframe_rx);
// At this point, all information for subframe has been received on FH interface
// If this proc is to provide synchronization, do so
// Fixme: not used
// wakeup_slaves(proc);
for (int i=0; i<ru->num_eNB; i++) {
char string[20];
sprintf(string,"Incoming RU %d",ru->idx);
if (rxtx(ru->eNB_list[i],&L1proc,string) < 0)
LOG_E(PHY,"eNB %d CC_id %d failed during execution\n",
ru->eNB_list[i]->Mod_id,ru->eNB_list[i]->CC_id);
}
// do TX front-end processing if needed (precoding and/or IDFTs)
feptx_prec(ru, L1proc.frame_tx, L1proc.subframe_tx);
// do OFDM if needed
feptx_ofdm(ru, L1proc.frame_tx, L1proc.subframe_tx);
// do outgoing fronthaul (south) if needed
ocp_tx_rf(ru, &L1proc);
}
LOG_W(PHY,"Exiting ru_thread \n");
ru->rfdevice.trx_end_func(&ru->rfdevice);
LOG_I(PHY,"RU %d rf device stopped\n",ru->idx);
return NULL;
}
int init_rf(RU_t *ru) {
char name[256];
pthread_getname_np(pthread_self(),name, 255);
pthread_setname_np(pthread_self(),"UHD for OAI");
int ret=openair0_device_load(&ru->rfdevice,&ru->openair0_cfg);
pthread_setname_np(pthread_self(),name);
return ret;
}
void init_RU(char *rf_config_file, int send_dmrssync) {
RU_t *ru;
PHY_VARS_eNB *eNB0= (PHY_VARS_eNB *)NULL;
int i;
int CC_id;
// read in configuration file)
LOG_I(PHY,"configuring RU from file\n");
LOG_I(PHY,"number of L1 instances %d, number of RU %d, number of CPU cores %d\n",
RC.nb_L1_inst,RC.nb_RU,get_nprocs());
if (RC.nb_CC != 0)
for (i=0; i<RC.nb_L1_inst; i++)
for (CC_id=0; CC_id<RC.nb_CC[i]; CC_id++)
RC.eNB[i][CC_id]->num_RU=0;
LOG_D(PHY,"Process RUs RC.nb_RU:%d\n",RC.nb_RU);
for (int ru_id=0; ru_id<RC.nb_RU; ru_id++) {
LOG_D(PHY,"Process RC.ru[%d]\n",ru_id);
ru = RC.ru[ru_id];
ru->rf_config_file = rf_config_file;
ru->idx = ru_id;
ru->ts_offset = 0;
if (ru->is_slave == 1) {
ru->in_synch = 0;
ru->generate_dmrs_sync = 0;
} else {
ru->in_synch = 1;
ru->generate_dmrs_sync=send_dmrssync;
}
ru->cmd = EMPTY;
ru->south_out_cnt= 0;
// ru->generate_dmrs_sync = (ru->is_slave == 0) ? 1 : 0;
if (ru->generate_dmrs_sync == 1) {
generate_ul_ref_sigs();
ru->dmrssync = (int16_t *)malloc16_clear(ru->frame_parms->ofdm_symbol_size*2*sizeof(int16_t));
}
ru->wakeup_L1_sleeptime = 2000;
ru->wakeup_L1_sleep_cnt_max = 3;
if (ru->num_eNB > 0) {
LOG_D(PHY, "%s() RC.ru[%d].num_eNB:%d ru->eNB_list[0]:%p RC.eNB[0][0]:%p rf_config_file:%s\n",
__FUNCTION__, ru_id, ru->num_eNB, ru->eNB_list[0], RC.eNB[0][0], ru->rf_config_file);
AssertFatal(ru->eNB_list[0], "ru->eNB_list is not initialized\n");
} else {
LOG_E(PHY,"Wrong data model, assigning eNB 0, carrier 0 to RU 0\n");
ru->eNB_list[0] = RC.eNB[0][0];
ru->num_eNB=1;
}
eNB0 = ru->eNB_list[0];
// datamodel error in regular OAI: a RU uses one single eNB carrier parameters!
ru->frame_parms = &eNB0->frame_parms;
for (i=0; i<ru->num_eNB; i++) {
eNB0 = ru->eNB_list[i];
int ruIndex=eNB0->num_RU++;
eNB0->RU_list[ruIndex] = ru;
}
} // for ru_id
}
void stop_RU(int nb_ru) {
for (int inst = 0; inst < nb_ru; inst++) {
LOG_I(PHY, "Stopping RU %d processing threads\n", inst);
kill_RU_proc(RC.ru[inst]);
}
}
/* --------------------------------------------------------*/
/* from here function to use configuration module */
static int DEFBFW[] = {0x00007fff};
void RCconfig_RU(void) {
paramdef_t RUParams[] = RUPARAMS_DESC;
paramlist_def_t RUParamList = {CONFIG_STRING_RU_LIST,NULL,0};
config_getlist( &RUParamList,RUParams,sizeof(RUParams)/sizeof(paramdef_t), NULL);
if ( RUParamList.numelt == 0 ) {
LOG_W(PHY, "Calling RCconfig_RU while no ru\n");
RC.nb_RU = 0;
return;
} // setting != NULL
if ( RC.ru != NULL ) {
LOG_W(PHY, "Calling RCconfig_RU twice (nb ru=%d), ignoring the second call data structure is %p\n",
RUParamList.numelt,RC.ru);
return;
}
RC.ru = (RU_t **)malloc(RC.nb_RU*sizeof(RU_t *));
for (int j = 0; j < RC.nb_RU; j++) {
RC.ru[j] = (RU_t *)calloc(sizeof(RU_t), 1);
RC.ru[j]->idx = j;
LOG_I(PHY,"Creating RC.ru[%d]:%p\n", j, RC.ru[j]);
RC.ru[j]->if_timing = synch_to_ext_device;
paramdef_t *vals=RUParamList.paramarray[j];
if (RC.nb_L1_inst >0)
RC.ru[j]->num_eNB = vals[RU_ENB_LIST_IDX].numelt;
else
RC.ru[j]->num_eNB = 0;
for (int i=0; i<RC.ru[j]->num_eNB; i++)
RC.ru[j]->eNB_list[i] = RC.eNB[vals[RU_ENB_LIST_IDX].iptr[i]][0];
if (config_isparamset(vals, RU_SDR_ADDRS)) {
RC.ru[j]->openair0_cfg.sdr_addrs = strdup(*(vals[RU_SDR_ADDRS].strptr));
}
if (config_isparamset(vals, RU_SDR_CLK_SRC)) {
char *paramVal=*(vals[RU_SDR_CLK_SRC].strptr);
LOG_D(PHY, "RU clock source set as %s\n", paramVal);
if (strcmp(paramVal, "internal") == 0) {
RC.ru[j]->openair0_cfg.clock_source = internal;
} else if (strcmp(paramVal, "external") == 0) {
RC.ru[j]->openair0_cfg.clock_source = external;
} else if (strcmp(paramVal, "gpsdo") == 0) {
RC.ru[j]->openair0_cfg.clock_source = gpsdo;
} else {
LOG_E(PHY, "Erroneous RU clock source in the provided configuration file: '%s'\n", paramVal);
}
}
if (strcmp(*(vals[RU_LOCAL_RF_IDX].strptr), "yes") == 0) {
if ( !(config_isparamset(vals,RU_LOCAL_IF_NAME_IDX)) ) {
RC.ru[j]->if_south = LOCAL_RF;
RC.ru[j]->function = eNodeB_3GPP;
LOG_I(PHY, "Setting function for RU %d to eNodeB_3GPP\n",j);
} else {
RC.ru[j]->eth_params.local_if_name = strdup(*(vals[RU_LOCAL_IF_NAME_IDX].strptr));
RC.ru[j]->eth_params.my_addr = strdup(*(vals[RU_LOCAL_ADDRESS_IDX].strptr));
RC.ru[j]->eth_params.remote_addr = strdup(*(vals[RU_REMOTE_ADDRESS_IDX].strptr));
RC.ru[j]->eth_params.my_portc = *(vals[RU_LOCAL_PORTC_IDX].uptr);
RC.ru[j]->eth_params.remote_portc = *(vals[RU_REMOTE_PORTC_IDX].uptr);
RC.ru[j]->eth_params.my_portd = *(vals[RU_LOCAL_PORTD_IDX].uptr);
RC.ru[j]->eth_params.remote_portd = *(vals[RU_REMOTE_PORTD_IDX].uptr);
}
RC.ru[j]->max_pdschReferenceSignalPower = *(vals[RU_MAX_RS_EPRE_IDX].uptr);;
RC.ru[j]->max_rxgain = *(vals[RU_MAX_RXGAIN_IDX].uptr);
RC.ru[j]->num_bands = vals[RU_BAND_LIST_IDX].numelt;
/* sf_extension is in unit of samples for 30.72MHz here, has to be scaled later */
RC.ru[j]->sf_extension = *(vals[RU_SF_EXTENSION_IDX].uptr);
RC.ru[j]->end_of_burst_delay = *(vals[RU_END_OF_BURST_DELAY_IDX].uptr);
for (int i=0; i<RC.ru[j]->num_bands; i++) RC.ru[j]->band[i] = vals[RU_BAND_LIST_IDX].iptr[i];
} else {
LOG_I(PHY,"RU %d: Transport %s\n",j,*(vals[RU_TRANSPORT_PREFERENCE_IDX].strptr));
RC.ru[j]->eth_params.local_if_name = strdup(*(vals[RU_LOCAL_IF_NAME_IDX].strptr));
RC.ru[j]->eth_params.my_addr = strdup(*(vals[RU_LOCAL_ADDRESS_IDX].strptr));
RC.ru[j]->eth_params.remote_addr = strdup(*(vals[RU_REMOTE_ADDRESS_IDX].strptr));
RC.ru[j]->eth_params.my_portc = *(vals[RU_LOCAL_PORTC_IDX].uptr);
RC.ru[j]->eth_params.remote_portc = *(vals[RU_REMOTE_PORTC_IDX].uptr);
RC.ru[j]->eth_params.my_portd = *(vals[RU_LOCAL_PORTD_IDX].uptr);
RC.ru[j]->eth_params.remote_portd = *(vals[RU_REMOTE_PORTD_IDX].uptr);
} /* strcmp(local_rf, "yes") != 0 */
RC.ru[j]->nb_tx = *(vals[RU_NB_TX_IDX].uptr);
RC.ru[j]->nb_rx = *(vals[RU_NB_RX_IDX].uptr);
RC.ru[j]->att_tx = *(vals[RU_ATT_TX_IDX].uptr);
RC.ru[j]->att_rx = *(vals[RU_ATT_RX_IDX].uptr);
}// j=0..num_rus
return;
}
static void get_options(void) {
CONFIG_SETRTFLAG(CONFIG_NOEXITONHELP);
get_common_options(SOFTMODEM_ENB_BIT);
CONFIG_CLEARRTFLAG(CONFIG_NOEXITONHELP);
if ( !(CONFIG_ISFLAGSET(CONFIG_ABORT)) ) {
memset((void *)&RC,0,sizeof(RC));
/* Read RC configuration file */
RCConfig();
NB_eNB_INST = RC.nb_inst;
printf("Configuration: nb_rrc_inst %d, nb_L1_inst %d, nb_ru %d\n",NB_eNB_INST,RC.nb_L1_inst,RC.nb_RU);
if (!IS_SOFTMODEM_NONBIOT) {
load_NB_IoT();
printf(" nb_nbiot_rrc_inst %d, nb_nbiot_L1_inst %d, nb_nbiot_macrlc_inst %d\n",
RC.nb_nb_iot_rrc_inst, RC.nb_nb_iot_L1_inst, RC.nb_nb_iot_macrlc_inst);
} else {
printf("All Nb-IoT instances disabled\n");
RC.nb_nb_iot_rrc_inst=RC.nb_nb_iot_L1_inst=RC.nb_nb_iot_macrlc_inst=0;
}
}
}
void set_default_frame_parms(LTE_DL_FRAME_PARMS *frame_parms[MAX_NUM_CCs]) {
int CC_id;
for (CC_id=0; CC_id<MAX_NUM_CCs; CC_id++) {
frame_parms[CC_id] = (LTE_DL_FRAME_PARMS *) malloc(sizeof(LTE_DL_FRAME_PARMS));
/* Set some default values that may be overwritten while reading options */
frame_parms[CC_id]->frame_type = FDD;
frame_parms[CC_id]->tdd_config = 3;
frame_parms[CC_id]->tdd_config_S = 0;
frame_parms[CC_id]->N_RB_DL = 100;
frame_parms[CC_id]->N_RB_UL = 100;
frame_parms[CC_id]->Ncp = NORMAL;
frame_parms[CC_id]->Ncp_UL = NORMAL;
frame_parms[CC_id]->Nid_cell = 0;
frame_parms[CC_id]->num_MBSFN_config = 0;
frame_parms[CC_id]->nb_antenna_ports_eNB = 1;
frame_parms[CC_id]->nb_antennas_tx = 1;
frame_parms[CC_id]->nb_antennas_rx = 1;
frame_parms[CC_id]->nushift = 0;
frame_parms[CC_id]->phich_config_common.phich_resource = oneSixth;
frame_parms[CC_id]->phich_config_common.phich_duration = normal;
// UL RS Config
frame_parms[CC_id]->pusch_config_common.ul_ReferenceSignalsPUSCH.cyclicShift = 0;//n_DMRS1 set to 0
frame_parms[CC_id]->pusch_config_common.ul_ReferenceSignalsPUSCH.groupHoppingEnabled = 0;
frame_parms[CC_id]->pusch_config_common.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled = 0;
frame_parms[CC_id]->pusch_config_common.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH = 0;
frame_parms[CC_id]->prach_config_common.rootSequenceIndex=22;
frame_parms[CC_id]->prach_config_common.prach_ConfigInfo.zeroCorrelationZoneConfig=1;
frame_parms[CC_id]->prach_config_common.prach_ConfigInfo.prach_ConfigIndex=0;
frame_parms[CC_id]->prach_config_common.prach_ConfigInfo.highSpeedFlag=0;
frame_parms[CC_id]->prach_config_common.prach_ConfigInfo.prach_FreqOffset=0;
// downlink_frequency[CC_id][0] = 2680000000; // Use float to avoid issue with frequency over 2^31.
// downlink_frequency[CC_id][1] = downlink_frequency[CC_id][0];
// downlink_frequency[CC_id][2] = downlink_frequency[CC_id][0];
// downlink_frequency[CC_id][3] = downlink_frequency[CC_id][0];
//printf("Downlink for CC_id %d frequency set to %u\n", CC_id, downlink_frequency[CC_id][0]);
frame_parms[CC_id]->dl_CarrierFreq=downlink_frequency[CC_id][0];
}
}
void init_pdcp(void) {
if (!NODE_IS_DU(RC.rrc[0]->node_type)) {
pdcp_layer_init();
uint32_t pdcp_initmask = (IS_SOFTMODEM_NOS1) ?
(PDCP_USE_NETLINK_BIT | LINK_ENB_PDCP_TO_IP_DRIVER_BIT) : LINK_ENB_PDCP_TO_GTPV1U_BIT;
if (IS_SOFTMODEM_NOS1)
pdcp_initmask = pdcp_initmask | ENB_NAS_USE_TUN_BIT | SOFTMODEM_NOKRNMOD_BIT ;
pdcp_initmask = pdcp_initmask | ENB_NAS_USE_TUN_W_MBMS_BIT;
if ( split73!=SPLIT73_DU)
pdcp_module_init(pdcp_initmask);
if (NODE_IS_CU(RC.rrc[0]->node_type)) {
pdcp_set_rlc_data_req_func((send_rlc_data_req_func_t)proto_agent_send_rlc_data_req);
} else {
pdcp_set_rlc_data_req_func((send_rlc_data_req_func_t) rlc_data_req);
pdcp_set_pdcp_data_ind_func((pdcp_data_ind_func_t) pdcp_data_ind);
}
} else {
pdcp_set_pdcp_data_ind_func((pdcp_data_ind_func_t) proto_agent_send_pdcp_data_ind);
}
}
static void wait_nfapi_init(char *thread_name) {
printf( "waiting for NFAPI PNF connection and population of global structure (%s)\n",thread_name);
pthread_mutex_lock( &nfapi_sync_mutex );
while (nfapi_sync_var<0)
pthread_cond_wait( &nfapi_sync_cond, &nfapi_sync_mutex );
pthread_mutex_unlock(&nfapi_sync_mutex);
printf( "NFAPI: got sync (%s)\n", thread_name);
}
void terminate_task(module_id_t mod_id, task_id_t from, task_id_t to) {
LOG_I(ENB_APP, "sending TERMINATE_MESSAGE from task %s (%d) to task %s (%d)\n",
itti_get_task_name(from), from, itti_get_task_name(to), to);
MessageDef *msg;
msg = itti_alloc_new_message (from, TERMINATE_MESSAGE);
itti_send_msg_to_task (to, ENB_MODULE_ID_TO_INSTANCE(mod_id), msg);
}
int stop_L1L2(module_id_t enb_id) {
LOG_W(ENB_APP, "stopping lte-softmodem\n");
if (!RC.ru) {
LOG_UI(ENB_APP, "no RU configured\n");
return -1;
}
/* these tasks need to pick up new configuration */
terminate_task(enb_id, TASK_ENB_APP, TASK_RRC_ENB);
oai_exit = 1;
LOG_I(ENB_APP, "calling kill_RU_proc() for instance %d\n", enb_id);
kill_RU_proc(RC.ru[enb_id]);
LOG_I(ENB_APP, "calling kill_eNB_proc() for instance %d\n", enb_id);
kill_eNB_proc(enb_id);
oai_exit = 0;
for (int cc_id = 0; cc_id < RC.nb_CC[enb_id]; cc_id++) {
free_transport(RC.eNB[enb_id][cc_id]);
phy_free_lte_eNB(RC.eNB[enb_id][cc_id]);
}
phy_free_RU(RC.ru[enb_id]);
free_lte_top();
return 0;
}
/*
* Restart the lte-softmodem after it has been soft-stopped with stop_L1L2()
*/
int restart_L1L2(module_id_t enb_id) {
RU_t *ru = RC.ru[enb_id];
MessageDef *msg_p = NULL;
LOG_W(ENB_APP, "restarting lte-softmodem\n");
/* block threads */
pthread_mutex_lock(&sync_mutex);
sync_var = -1;
pthread_mutex_unlock(&sync_mutex);
RC.ru_mask |= (1 << ru->idx);
/* copy the changed frame parameters to the RU */
/* TODO this should be done for all RUs associated to this eNB */
memcpy(&ru->frame_parms, &RC.eNB[enb_id][0]->frame_parms, sizeof(LTE_DL_FRAME_PARMS));
/* reset the list of connected UEs in the MAC, since in this process with
* loose all UEs (have to reconnect) */
init_UE_info(&RC.mac[enb_id]->UE_info);
LOG_I(ENB_APP, "attempting to create ITTI tasks\n");
// No more rrc thread, as many race conditions are hidden behind
rrc_enb_init();
itti_mark_task_ready(TASK_RRC_ENB);
/* pass a reconfiguration request which will configure everything down to
* RC.eNB[i][j]->frame_parms, too */
msg_p = itti_alloc_new_message(TASK_ENB_APP, RRC_CONFIGURATION_REQ);
RRC_CONFIGURATION_REQ(msg_p) = RC.rrc[enb_id]->configuration;
itti_send_msg_to_task(TASK_RRC_ENB, ENB_MODULE_ID_TO_INSTANCE(enb_id), msg_p);
/* TODO XForms might need to be restarted, but it is currently (09/02/18)
* broken, so we cannot test it */
init_RU_proc(ru);
ru->rf_map.card = 0;
ru->rf_map.chain = 0; /* CC_id + chain_offset;*/
init_eNB_afterRU();
printf("Sending sync to all threads\n");
pthread_mutex_lock(&sync_mutex);
sync_var=0;
pthread_cond_broadcast(&sync_cond);
pthread_mutex_unlock(&sync_mutex);
return 0;
}
int main ( int argc, char **argv ) {
int i;
int CC_id = 0;
int node_type = ngran_eNB;
AssertFatal(load_configmodule(argc,argv,0), "[SOFTMODEM] Error, configuration module init failed\n");
logInit();
printf("Reading in command-line options\n");
get_options ();
AssertFatal(!CONFIG_ISFLAGSET(CONFIG_ABORT),"Getting configuration failed\n");
EPC_MODE_ENABLED = !IS_SOFTMODEM_NOS1;
#if T_TRACER
T_Config_Init();
#endif
configure_linux();
cpuf=get_cpu_freq_GHz();
set_taus_seed (0);
if (opp_enabled ==1)
reset_opp_meas();
itti_init(TASK_MAX, THREAD_MAX, MESSAGES_ID_MAX, tasks_info, messages_info);
init_opt();
#ifndef PACKAGE_VERSION
# define PACKAGE_VERSION "UNKNOWN-EXPERIMENTAL"
#endif
LOG_I(HW, "Version: %s\n", PACKAGE_VERSION);
/* Read configuration */
if (RC.nb_inst > 0) {
// Allocate memory from RC variable
read_config_and_init();
} else {
printf("RC.nb_inst = 0, Initializing L1\n");
RCconfig_L1();
}
/* We need to read RU configuration before FlexRAN starts so it knows what
* splits to report. Actual RU start comes later. */
if (RC.nb_RU > 0 && NFAPI_MODE != NFAPI_MODE_VNF) {
RCconfig_RU();
LOG_I(PHY,
"number of L1 instances %d, number of RU %d, number of CPU cores %d\n",
RC.nb_L1_inst, RC.nb_RU, get_nprocs());
}
if ( strlen(get_softmodem_params()->split73) > 0 ) {
char tmp[1024]={0};
strncpy(tmp,get_softmodem_params()->split73, 1023);
tmp[2]=0;
if ( strncasecmp(tmp,"cu", 2)==0 )
split73=SPLIT73_CU;
else if ( strncasecmp(tmp,"du", 2)==0 )
split73=SPLIT73_DU;
else
AssertFatal(false,"split73 syntax: <cu|du>:<remote ip addr>[:<ip port>] (string found: %s) \n",get_softmodem_params()->split73);
}
if (RC.nb_inst > 0) {
/* Start the agent. If it is turned off in the configuration, it won't start */
for (i = 0; i < RC.nb_inst; i++) {
flexran_agent_start(i);
}
/* initializes PDCP and sets correct RLC Request/PDCP Indication callbacks
* for monolithic/F1 modes */
init_pdcp();
AssertFatal(create_tasks(1)==0,"cannot create ITTI tasks\n");
for (int enb_id = 0; enb_id < RC.nb_inst; enb_id++) {
MessageDef *msg_p = itti_alloc_new_message (TASK_ENB_APP, RRC_CONFIGURATION_REQ);
RRC_CONFIGURATION_REQ(msg_p) = RC.rrc[enb_id]->configuration;
itti_send_msg_to_task (TASK_RRC_ENB, ENB_MODULE_ID_TO_INSTANCE(enb_id), msg_p);
}
node_type = RC.rrc[0]->node_type;
}
if (RC.nb_inst > 0 && NODE_IS_CU(node_type)) {
protocol_ctxt_t ctxt;
ctxt.module_id = 0 ;
ctxt.instance = 0;
ctxt.rnti = 0;
ctxt.enb_flag = 1;
ctxt.frame = 0;
ctxt.subframe = 0;
pdcp_run(&ctxt);
}
/* start threads if only L1 or not a CU */
if (RC.nb_inst == 0 || !NODE_IS_CU(node_type) || NFAPI_MODE == NFAPI_MODE_PNF || NFAPI_MODE == NFAPI_MODE_VNF) {
// init UE_PF_PO and mutex lock
pthread_mutex_init(&ue_pf_po_mutex, NULL);
memset (&UE_PF_PO[0][0], 0, sizeof(UE_PF_PO_t)*MAX_MOBILES_PER_ENB*MAX_NUM_CCs);
pthread_cond_init(&sync_cond,NULL);
pthread_mutex_init(&sync_mutex, NULL);
if (NFAPI_MODE!=NFAPI_MONOLITHIC) {
LOG_I(ENB_APP,"NFAPI*** - mutex and cond created - will block shortly for completion of PNF connection\n");
pthread_cond_init(&sync_cond,NULL);
pthread_mutex_init(&sync_mutex, NULL);
}
if (NFAPI_MODE==NFAPI_MODE_VNF) {// VNF
#if defined(PRE_SCD_THREAD)
init_ru_vnf(); // ru pointer is necessary for pre_scd.
#endif
wait_nfapi_init("main?");
}
LOG_I(ENB_APP,"START MAIN THREADS\n");
// start the main threads
number_of_cards = 1;
printf("RC.nb_L1_inst:%d\n", RC.nb_L1_inst);
if (RC.nb_L1_inst > 0) {
printf("Initializing eNB threads single_thread_flag:%d wait_for_sync:%d\n",
get_softmodem_params()->single_thread_flag,
get_softmodem_params()->wait_for_sync);
init_eNB(get_softmodem_params()->single_thread_flag,
get_softmodem_params()->wait_for_sync);
}
for (int x=0; x < RC.nb_L1_inst; x++)
for (int CC_id=0; CC_id<RC.nb_L1_CC[x]; CC_id++) {
L1_rxtx_proc_t *L1proc= &RC.eNB[x][CC_id]->proc.L1_proc;
L1proc->threadPool=(tpool_t *)malloc(sizeof(tpool_t));
L1proc->respEncode=(notifiedFIFO_t *) malloc(sizeof(notifiedFIFO_t));
L1proc->respDecode=(notifiedFIFO_t *) malloc(sizeof(notifiedFIFO_t));
if ( strlen(get_softmodem_params()->threadPoolConfig) > 0 )
initTpool(get_softmodem_params()->threadPoolConfig, L1proc->threadPool, true);
else
initTpool("n", L1proc->threadPool, true);
initNotifiedFIFO(L1proc->respEncode);
initNotifiedFIFO(L1proc->respDecode);
}
}
printf("About to Init RU threads RC.nb_RU:%d\n", RC.nb_RU);
// RU thread and some L1 procedure aren't necessary in VNF or L2 FAPI simulator.
// but RU thread deals with pre_scd and this is necessary in VNF and simulator.
// some initialization is necessary and init_ru_vnf do this.
if (RC.nb_RU >0 && NFAPI_MODE!=NFAPI_MODE_VNF) {
printf("Initializing RU threads\n");
init_RU(get_softmodem_params()->rf_config_file,
get_softmodem_params()->send_dmrs_sync);
for (int ru_id=0; ru_id<RC.nb_RU; ru_id++) {
RC.ru[ru_id]->rf_map.card=0;
RC.ru[ru_id]->rf_map.chain=CC_id+(get_softmodem_params()->chain_offset);
LOG_I(PHY,"Starting ru_thread %d\n",ru_id);
init_RU_proc(RC.ru[ru_id]);
}
config_sync_var=0;
if (NFAPI_MODE==NFAPI_MODE_PNF) { // PNF
wait_nfapi_init("main?");
}
LOG_I(ENB_APP,"RC.nb_RU:%d\n", RC.nb_RU);
// once all RUs are ready intiailize the rest of the eNBs ((dependence on final RU parameters after configuration)
printf("ALL RUs ready - init eNBs\n");
if (NFAPI_MODE!=NFAPI_MODE_PNF && NFAPI_MODE!=NFAPI_MODE_VNF) {
LOG_I(ENB_APP,"Not NFAPI mode - call init_eNB_afterRU()\n");
init_eNB_afterRU();
} else {
LOG_I(ENB_APP,"NFAPI mode - DO NOT call init_eNB_afterRU()\n");
}
LOG_UI(ENB_APP,"ALL RUs ready - ALL eNBs ready\n");
// connect the TX/RX buffers
sleep(1); /* wait for thread activation */
LOG_I(ENB_APP,"Sending sync to all threads\n");
pthread_mutex_lock(&sync_mutex);
sync_var=0;
pthread_cond_broadcast(&sync_cond);
pthread_mutex_unlock(&sync_mutex);
config_check_unknown_cmdlineopt(CONFIG_CHECKALLSECTIONS);
}
create_tasks_mbms(1);
// wait for end of program
LOG_UI(ENB_APP,"TYPE <CTRL-C> TO TERMINATE\n");
// CI -- Flushing the std outputs for the previous marker to show on the eNB / DU / CU log file
fflush(stdout);
fflush(stderr);
// end of CI modifications
//getchar();
if(IS_SOFTMODEM_DOFORMS)
load_softscope("enb");
itti_wait_tasks_end();
oai_exit=1;
LOG_I(ENB_APP,"oai_exit=%d\n",oai_exit);
// stop threads
if (RC.nb_inst == 0 || !NODE_IS_CU(node_type)) {
if(IS_SOFTMODEM_DOFORMS)
end_forms();
LOG_I(ENB_APP,"stopping MODEM threads\n");
stop_eNB(NB_eNB_INST);
stop_RU(RC.nb_RU);
/* release memory used by the RU/eNB threads (incomplete), after all
* threads have been stopped (they partially use the same memory) */
for (int inst = 0; inst < NB_eNB_INST; inst++) {
for (int cc_id = 0; cc_id < RC.nb_CC[inst]; cc_id++) {
free_transport(RC.eNB[inst][cc_id]);
phy_free_lte_eNB(RC.eNB[inst][cc_id]);
}
}
for (int inst = 0; inst < RC.nb_RU; inst++) {
phy_free_RU(RC.ru[inst]);
}
free_lte_top();
end_configmodule();
pthread_cond_destroy(&sync_cond);
pthread_mutex_destroy(&sync_mutex);
pthread_cond_destroy(&nfapi_sync_cond);
pthread_mutex_destroy(&nfapi_sync_mutex);
pthread_mutex_destroy(&ue_pf_po_mutex);
for(int ru_id=0; ru_id<RC.nb_RU; ru_id++) {
if (RC.ru[ru_id]->rfdevice.trx_end_func) {
RC.ru[ru_id]->rfdevice.trx_end_func(&RC.ru[ru_id]->rfdevice);
RC.ru[ru_id]->rfdevice.trx_end_func = NULL;
}
if (RC.ru[ru_id]->ifdevice.trx_end_func) {
RC.ru[ru_id]->ifdevice.trx_end_func(&RC.ru[ru_id]->ifdevice);
RC.ru[ru_id]->ifdevice.trx_end_func = NULL;
}
}
}
terminate_opt();
logClean();
printf("Bye.\n");
return 0;
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Author and copyright: Laurent Thomas, open-cells.com
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef __SPLIT_HEADERS_H
#define __SPLIT_HEADERS_H
#include <stdint.h>
#include <stdbool.h>
#include <openair1/PHY/defs_eNB.h>
#define CU_PORT "7878"
#define DU_PORT "8787"
#define SPLIT73_CU 1
#define SPLIT73_DU 2
extern int split73;
#define MTU 65536
#define UDP_TIMEOUT 900000L // in micro second (struct timeval, NOT struct timespec)
// linux may timeout for a much longer time (up to 10ms)
#define blockAlign 32 //bytes to align memory for SIMD copy (256 bits vectors)
// FS6 transport configuration and handler
typedef struct {
char *sourceIP;
char *sourcePort;
char *destIP;
char *destPort;
struct addrinfo *destAddr;
int sockHandler;
} UDPsock_t;
#define CTsentCUv0 0xA500
#define CTsentDUv0 0x5A00
// Main FS6 transport layer header
// All packets starts with this header
typedef struct commonUDP_s {
uint64_t timestamp; // id of the group (subframe for LTE)
uint16_t nbBlocks; // total number of blocks for this timestamp
uint16_t blockID; // id: 0..nbBocks-1
uint16_t contentType; // defines the content format
uint16_t contentBytes; // will be sent in a UDP packet, so must be < 2^16 bytes
uint64_t senderClock;
} commonUDP_t;
// FS6 UL common header (DU to CU)
// gives the RACH detection data and is always sent to inform the CU that a subframe arrived
typedef struct {
uint16_t max_preamble[4];
uint16_t max_preamble_energy[4];
uint16_t max_preamble_delay[4];
uint16_t avg_preamble_energy[4];
} fs6_ul_t;
// FS6 DL common header (CU to DU)
// gives the DCI configuration from each subframe
typedef struct {
uint8_t pbch_pdu[4];
int num_pdcch_symbols;
int num_dci;
DCI_ALLOC_t dci_alloc[8];
int num_mdci;
int amp;
LTE_eNB_PHICH phich_vars;
uint64_t DuClock;
uint64_t CuSpentMicroSec;
} fs6_dl_t;
// a value to type all sub packets,
// to detect errors, and to be able to extend to other versions
// the first byte of each sub structure should match one of these values
enum pckType {
fs6UlConfig=25,
fs6DlConfig=26,
fs6ULConfigCCH=27,
fs6ULsch=28,
fs6ULcch=29,
fs6ULindicationHarq=40,
fs6ULindicationSr=41,
};
// CU to DU definition of a future UL subframe decode
// defines a UE future data plane
typedef struct {
enum pckType type:8;
uint16_t UE_id;
int8_t harq_pid;
UE_type_t ue_type;
uint8_t dci_alloc;
uint8_t rar_alloc;
SCH_status_t status;
uint8_t Msg3_flag;
uint8_t subframe;
uint32_t frame;
uint8_t handled;
uint8_t phich_active;
uint8_t phich_ACK;
uint16_t previous_first_rb;
uint32_t B;
uint32_t G;
UCI_format_t uci_format;
uint8_t Or2;
uint8_t o_RI[2];
uint8_t o_ACK[4];
uint8_t O_ACK;
uint8_t o_RCC;
int16_t q_ACK[MAX_ACK_PAYLOAD];
int16_t q_RI[MAX_RI_PAYLOAD];
uint32_t RTC[MAX_NUM_ULSCH_SEGMENTS];
uint8_t ndi;
uint8_t round;
uint8_t rvidx;
uint8_t Nl;
uint8_t n_DMRS;
uint8_t previous_n_DMRS;
uint8_t n_DMRS2;
int32_t delta_TF;
uint32_t repetition_number ;
uint32_t total_number_of_repetitions;
uint16_t harq_mask;
uint16_t nb_rb;
uint8_t Qm;
uint16_t first_rb;
uint8_t O_RI;
uint8_t Or1;
uint16_t Msc_initial;
uint8_t Nsymb_initial;
uint8_t V_UL_DAI;
uint8_t srs_active;
uint32_t TBS;
uint8_t Nsymb_pusch;
uint8_t Mlimit;
uint8_t max_turbo_iterations;
uint8_t bundling;
uint16_t beta_offset_cqi_times8;
uint16_t beta_offset_ri_times8;
uint16_t beta_offset_harqack_times8;
uint8_t Msg3_active;
uint16_t rnti;
uint8_t cyclicShift;
uint8_t cooperation_flag;
uint8_t num_active_cba_groups;
uint16_t cba_rnti[4];//NUM_MAX_CBA_GROUP];
} fs6_dl_ulsched_t;
// CU to DU defintion of a DL packet for a given UE
// The data itself is padded at the end of this structure
typedef struct {
enum pckType type:8;
int UE_id;
int8_t harq_pid;
uint16_t rnti;
int16_t sqrt_rho_a;
int16_t sqrt_rho_b;
CEmode_t CEmode:8;
uint16_t nb_rb;
uint8_t Qm;
int8_t Nl;
uint8_t pdsch_start;
uint8_t sib1_br_flag;
uint16_t i0;
uint32_t rb_alloc[4];
int dataLen;
} fs6_dl_uespec_t;
// CU to DU definition of CCH channel
typedef struct {
int16_t UE_id;
LTE_eNB_UCI cch_vars;
} fs6_dl_uespec_ulcch_element_t;
// header to group all UE CCH channels definitions in one UDP packet
typedef struct {
enum pckType type:8;
int16_t nb_active_ue;
} fs6_dl_uespec_ulcch_t;
// code internal, not transmitted as this
typedef struct {
int ta;
} ul_propagation_t;
// One UE UL data, data plane, UE data appended after the header
typedef struct {
enum pckType type:8;
short UE_id;
uint8_t harq_id;
uint8_t segment;
int segLen;
int r_offset;
int G;
int ulsch_power[2];
uint8_t o_ACK[4];
uint8_t O_ACK;
int ta;
uint8_t o[MAX_CQI_BYTES];
uint8_t cqi_crc_status;
} fs6_ul_uespec_t;
// UL UCI (control plane), per UE
typedef struct {
enum pckType type:8;
int UEid;
int frame;
int subframe;
LTE_eNB_UCI uci;
uint8_t harq_ack[4];
uint8_t tdd_mapping_mode;
uint16_t tdd_multiplexing_mask;
unsigned short n0_subband_power_dB;
uint16_t rnti;
int32_t stat;
} fs6_ul_uespec_uci_element_t;
// all segments UCI grouped in one UDP packet
typedef struct {
enum pckType type:8;
int16_t nb_active_ue;
} fs6_ul_uespec_uci_t;
bool createUDPsock (char *sourceIP, char *sourcePort, char *destIP, char *destPort, UDPsock_t *result);
int receiveSubFrame(UDPsock_t *sock, void *bufferZone, int bufferSize, uint16_t contentType);
int sendSubFrame(UDPsock_t *sock, void *bufferZone, ssize_t secondHeaderSize, uint16_t contentType);
#define initBufferZone(xBuf) \
uint8_t xBuf[FS6_BUF_SIZE]; \
((commonUDP_t *)xBuf)->nbBlocks=0;
#define hUDP(xBuf) ((commonUDP_t *)xBuf)
#define hDL(xBuf) ((fs6_dl_t*)(((commonUDP_t *)xBuf)+1))
#define hUL(xBuf) ((fs6_ul_t*)(((commonUDP_t *)xBuf)+1))
#define hDLUE(xBuf) ((fs6_dl_uespec_t*) (((fs6_dl_t*)(((commonUDP_t *)xBuf)+1))+1))
#define hTxULUE(xBuf) ((fs6_dl_ulsched_t*) (((fs6_dl_t*)(((commonUDP_t *)xBuf)+1))+1))
#define hTxULcch(xBuf) ((fs6_dl_uespec_ulcch_t*) (((fs6_dl_t*)(((commonUDP_t *)xBuf)+1))+1))
#define hULUE(xBuf) ((fs6_ul_uespec_t*) (((fs6_ul_t*)(((commonUDP_t *)xBuf)+1))+1))
#define hULUEuci(xBuf) ((fs6_ul_uespec_uci_t*) (((fs6_ul_t*)(((commonUDP_t *)xBuf)+1))+1))
static inline size_t alignedSize(uint8_t *ptr) {
commonUDP_t *header=(commonUDP_t *) ptr;
return ((header->contentBytes+sizeof(commonUDP_t)+blockAlign-1)/blockAlign)*blockAlign;
}
static inline void *commonUDPdata(uint8_t *ptr) {
return (void *) (((commonUDP_t *)ptr)+1);
}
void setAllfromTS(uint64_t TS, L1_rxtx_proc_t *proc);
void sendFs6Ulharq(enum pckType type, int UEid, PHY_VARS_eNB *eNB,LTE_eNB_UCI *uci, int frame, int subframe, uint8_t *harq_ack, uint8_t tdd_mapping_mode, uint16_t tdd_multiplexing_mask,
uint16_t rnti, int32_t stat);
void sendFs6Ul(PHY_VARS_eNB *eNB, int UE_id, int harq_pid, int segmentID, int16_t *data, int dataLen, int r_offset);
void *cu_fs6(void *arg);
void *du_fs6(void *arg);
void fill_rf_config(RU_t *ru, char *rf_config_file);
int init_rf(RU_t *ru);
void rx_rf(RU_t *ru, L1_rxtx_proc_t *proc);
void tx_rf(RU_t *ru, L1_rxtx_proc_t *proc);
void common_signal_procedures (PHY_VARS_eNB *eNB,int frame, int subframe);
void pmch_procedures(PHY_VARS_eNB *eNB,L1_rxtx_proc_t *proc);
bool dlsch_procedures(PHY_VARS_eNB *eNB,
L1_rxtx_proc_t *proc,
int harq_pid,
LTE_eNB_DLSCH_t *dlsch,
LTE_eNB_UE_stats *ue_stats) ;
void postDecode(L1_rxtx_proc_t *proc, notifiedFIFO_elt_t *req);
void pdsch_procedures(PHY_VARS_eNB *eNB,
L1_rxtx_proc_t *proc,
int harq_pid,
LTE_eNB_DLSCH_t *dlsch,
LTE_eNB_DLSCH_t *dlsch1);
void srs_procedures(PHY_VARS_eNB *eNB,L1_rxtx_proc_t *proc);
void uci_procedures(PHY_VARS_eNB *eNB,
L1_rxtx_proc_t *proc);
void ocp_rx_prach(PHY_VARS_eNB *eNB,
L1_rxtx_proc_t *proc,
RU_t *ru,
uint16_t *max_preamble,
uint16_t *max_preamble_energy,
uint16_t *max_preamble_delay,
uint16_t *avg_preamble_energy,
uint16_t Nf,
uint8_t tdd_mapindex,
uint8_t br_flag);
void rx_prach0(PHY_VARS_eNB *eNB,
RU_t *ru,
int frame_prach,
int subframe,
uint16_t *max_preamble,
uint16_t *max_preamble_energy,
uint16_t *max_preamble_delay,
uint16_t *avg_preamble_energy,
uint16_t Nf,
uint8_t tdd_mapindex,
uint8_t br_flag,
uint8_t ce_level
);
void ocp_tx_rf(RU_t *ru, L1_rxtx_proc_t *proc);
// mistakes in main OAI
void phy_init_RU(RU_t *);
void fep_full(RU_t *ru, int subframe);
void feptx_prec(RU_t *ru,int frame,int subframe);
void feptx_ofdm(RU_t *ru, int frame, int subframe);
void oai_subframe_ind(uint16_t sfn, uint16_t sf);
extern uint16_t sf_ahead;
#endif
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Author and copyright: Laurent Thomas, open-cells.com
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include <executables/split_headers.h>
#include <sys/types.h> /* See NOTES */
#include <sys/socket.h>
#include <netinet/in.h>
#include <netinet/udp.h>
#include <netdb.h>
#include <targets/RT/USER/lte-softmodem.h>
bool createUDPsock (char *sourceIP, char *sourcePort, char *destIP, char *destPort, UDPsock_t *result) {
struct addrinfo hints= {0}, *servinfo, *p;
hints.ai_family = AF_UNSPEC;
hints.ai_socktype = SOCK_DGRAM;
hints.ai_flags = AI_PASSIVE;
int status;
if ((status = getaddrinfo(sourceIP, sourcePort, &hints, &servinfo)) != 0) {
LOG_E(GTPU,"getaddrinfo error: %s\n", gai_strerror(status));
return false;
}
// loop through all the results and bind to the first we can
for(p = servinfo; p != NULL; p = p->ai_next) {
if ((result->sockHandler = socket(p->ai_family, p->ai_socktype,
p->ai_protocol)) == -1) {
LOG_W(GTPU,"socket: %s\n", strerror(errno));
continue;
}
if (bind(result->sockHandler, p->ai_addr, p->ai_addrlen) == -1) {
close(result->sockHandler);
LOG_W(GTPU,"bind: %s\n", strerror(errno));
continue;
}
break; // if we get here, we must have connected successfully
}
if (p == NULL) {
// looped off the end of the list with no successful bind
LOG_E(GTPU,"failed to bind socket: %s %s \n",sourceIP,sourcePort);
return false;
}
freeaddrinfo(servinfo); // all done with this structure
if ((status = getaddrinfo(destIP, destPort, &hints, &servinfo)) != 0) {
LOG_E(GTPU,"getaddrinfo error: %s\n", gai_strerror(status));
return false;
}
if (servinfo) {
result->destAddr=servinfo;
} else {
LOG_E(PHY,"No valid UDP addr: %s:%s\n",destIP, destPort);
return false;
}
int enable=1;
AssertFatal(setsockopt(result->sockHandler, SOL_SOCKET, SO_REUSEADDR, &enable, sizeof(enable))==0,"");
struct timeval tv= {0,UDP_TIMEOUT};
if (IS_SOFTMODEM_RFSIM)
tv.tv_sec=2; //debug: wait 2 seconds for human understanding
AssertFatal(setsockopt(result->sockHandler, SOL_SOCKET, SO_RCVTIMEO,&tv,sizeof(tv)) ==0,"");
// Make a send/recv buffer larger than a a couple of subframe
// so the kernel will store for us in and out paquets
int buff=1000*1000*10;
AssertFatal ( setsockopt(result->sockHandler, SOL_SOCKET, SO_SNDBUF, &buff, sizeof(buff)) == 0, "");
AssertFatal ( setsockopt(result->sockHandler, SOL_SOCKET, SO_RCVBUF, &buff, sizeof(buff)) == 0, "");
return true;
}
// sock: udp socket
// bufferZone: a reception area of bufferSize
int receiveSubFrame(UDPsock_t *sock, void *bufferZone, int bufferSize, uint16_t contentType) {
int rcved=0;
commonUDP_t *bufOrigin=(commonUDP_t *)bufferZone;
static uint8_t crossData[65536];
static int crossDataSize=0;
if (crossDataSize) {
LOG_D(HW,"copy a block received in previous subframe\n");
memcpy(bufferZone, crossData, crossDataSize);
rcved=1;
bufferZone+=crossDataSize;
crossDataSize=0;
}
do {
//read all subframe data from the control unit
int ret=recv(sock->sockHandler, bufferZone, bufferSize, 0);
if ( ret==-1) {
if ( errno == EWOULDBLOCK || errno== EINTR ) {
LOG_I(HW,"Received: Timeout, subframe incomplete\n");
return rcved;
} else {
LOG_E(HW,"Critical issue in socket: %s\n", strerror(errno));
return -1;
}
} else {
if (hUDP(bufferZone)->contentType != contentType)
abort();
if (rcved && bufOrigin->timestamp != hUDP(bufferZone)->timestamp ) {
if ( hUDP(bufferZone)->timestamp > bufOrigin->timestamp ) {
LOG_W(HW,"Received data for TS: %lu before end of TS : %lu completion\n",
hUDP(bufferZone)->timestamp,
bufOrigin->timestamp);
memcpy(crossData, bufferZone, ret );
crossDataSize=ret;
return rcved;
} else {
LOG_W(HW,"Dropping late packet\n");
continue;
}
}
rcved++;
bufferZone+=ret;
}
LOG_D(HW,"Received: blocks: %d/%d, size %d, TS: %lu\n",
rcved, bufOrigin->nbBlocks, ret, bufOrigin->timestamp);
} while ( rcved == 0 || rcved < bufOrigin->nbBlocks );
return rcved;
}
int sendSubFrame(UDPsock_t *sock, void *bufferZone, ssize_t secondHeaderSize, uint16_t contentType) {
commonUDP_t *UDPheader=(commonUDP_t *)bufferZone ;
UDPheader->contentType=contentType;
UDPheader->senderClock=rdtsc();
int nbBlocks=UDPheader->nbBlocks;
int blockId=0;
if (nbBlocks <= 0 ) {
LOG_E(PHY,"FS6: can't send blocks: %d\n", nbBlocks);
return 0;
}
do {
if (blockId > 0 ) {
commonUDP_t *currentHeader=(commonUDP_t *)bufferZone;
currentHeader->timestamp=UDPheader->timestamp;
currentHeader->nbBlocks=UDPheader->nbBlocks;
currentHeader->blockID=blockId;
currentHeader->contentType=UDPheader->contentType;
memcpy(commonUDPdata((void *)currentHeader), commonUDPdata(bufferZone), secondHeaderSize);
}
blockId++;
int sz=alignedSize(bufferZone);
// Let's use the first address returned by getaddrinfo()
int ret=sendto(sock->sockHandler, bufferZone, sz, 0,
sock->destAddr->ai_addr, sock->destAddr->ai_addrlen);
if ( ret != sz )
LOG_W(HW,"Wrote socket doesn't return size %d (val: %d, errno:%d, %s)\n",
sz, ret, errno, strerror(errno));
LOG_D(HW,"Sent: TS: %lu, blocks %d/%d, block size : %d \n",
UDPheader->timestamp, UDPheader->nbBlocks-nbBlocks, UDPheader->nbBlocks, sz);
bufferZone+=sz;
nbBlocks--;
} while (nbBlocks);
return 0;
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
/* Lookup tables for 3GPP scrambling/unscrambling */
/* Author R. Knopp / EURECOM / OpenAirInterface.org */
#ifndef __SCRAMBLING_LUTS__C__
#define __SCRAMBLING_LUTS__C__
#include "PHY/impl_defs_nr.h"
#include "PHY/sse_intrin.h"
__m64 byte2m64_re[256];
__m64 byte2m64_im[256];
void init_byte2m64(void) {
for (int s=0;s<256;s++) {
byte2m64_re[s] = _mm_insert_pi16(byte2m64_re[s],(1-2*(s&1)),0);
byte2m64_im[s] = _mm_insert_pi16(byte2m64_im[s],(1-2*((s>>1)&1)),0);
byte2m64_re[s] = _mm_insert_pi16(byte2m64_re[s],(1-2*((s>>2)&1)),1);
byte2m64_im[s] = _mm_insert_pi16(byte2m64_im[s],(1-2*((s>>3)&1)),1);
byte2m64_re[s] = _mm_insert_pi16(byte2m64_re[s],(1-2*((s>>4)&1)),2);
byte2m64_im[s] = _mm_insert_pi16(byte2m64_im[s],(1-2*((s>>5)&1)),2);
byte2m64_re[s] = _mm_insert_pi16(byte2m64_re[s],(1-2*((s>>6)&1)),3);
byte2m64_im[s] = _mm_insert_pi16(byte2m64_im[s],(1-2*((s>>7)&1)),3);
printf("init_scrambling_luts: s %x (%d) ((%d,%d),(%d,%d),(%d,%d),(%d,%d))\n",
((uint16_t*)&s)[0],
(1-2*(s&1)),
((int16_t*)&byte2m64_re[s])[0],((int16_t*)&byte2m64_im[s])[0],
((int16_t*)&byte2m64_re[s])[1],((int16_t*)&byte2m64_im[s])[1],
((int16_t*)&byte2m64_re[s])[2],((int16_t*)&byte2m64_im[s])[2],
((int16_t*)&byte2m64_re[s])[3],((int16_t*)&byte2m64_im[s])[3]);
}
}
void init_scrambling_luts(void) {
init_byte2m64();
}
#endif
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
/*! \file PHY/NR_TRANSPORT/nr_dci_tools_common.c
* \brief
* \author
* \date 2020
* \version 0.1
* \company Eurecom
* \email:
* \note
* \warning
*/
#include "nr_dci.h"
void nr_group_sequence_hopping (pucch_GroupHopping_t PUCCH_GroupHopping,
uint32_t n_id,
uint8_t n_hop,
int nr_tti_tx,
uint8_t *u,
uint8_t *v) {
/*
* Implements TS 38.211 subclause 6.3.2.2.1 Group and sequence hopping
* The following variables are set by higher layers:
* - PUCCH_GroupHopping:
* - n_id: higher-layer parameter hoppingId
* - n_hop: frequency hopping index
* if intra-slot frequency hopping is disabled by the higher-layer parameter PUCCH-frequency-hopping
* n_hop=0
* if frequency hopping is enabled by the higher-layer parameter PUCCH-frequency-hopping
* n_hop=0 for the first hop
* n_hop=1 for the second hop
*/
// depending on the value of the PUCCH_GroupHopping, we will obtain different values for u,v
//pucch_GroupHopping_t PUCCH_GroupHopping = ue->pucch_config_common_nr->pucch_GroupHopping; // from higher layers FIXME!!!
// n_id defined as per TS 38.211 subclause 6.3.2.2.1 (is given by the higher-layer parameter hoppingId)
// it is hoppingId from PUCCH-ConfigCommon:
// Cell-Specific scrambling ID for group hoppping and sequence hopping if enabled
// Corresponds to L1 parameter 'HoppingID' (see 38.211, section 6.3.2.2) BIT STRING (SIZE (10))
//uint16_t n_id = ue->pucch_config_common_nr->hoppingId; // from higher layers FIXME!!!
#ifdef DEBUG_NR_PUCCH_TX
printf("\t\t [nr_group_sequence_hopping] PUCCH_GroupHopping=%u, n_id=%u \n",PUCCH_GroupHopping,n_id);
#endif
uint8_t f_ss=0,f_gh=0;
*u=0;
*v=0;
uint32_t c_init = 0;
uint32_t x1,s; // TS 38.211 Subclause 5.2.1
int l = 32, minShift = ((2*nr_tti_tx+n_hop)<<3);
int tmpShift =0;
#ifdef DEBUG_NR_PUCCH_TX
printf("\t\t [nr_group_sequence_hopping] calculating u,v -> ");
#endif
if (PUCCH_GroupHopping == neither) { // PUCCH_GroupHopping 'neither'
f_ss = n_id%30;
}
if (PUCCH_GroupHopping == enable) { // PUCCH_GroupHopping 'enabled'
c_init = floor(n_id/30); // we initialize c_init to calculate u,v according to 6.3.2.2.1 of 38.211
s = lte_gold_generic(&x1, &c_init, 1); // TS 38.211 Subclause 5.2.1
for (int m=0; m<8; m++) {
while(minShift >= l) {
s = lte_gold_generic(&x1, &c_init, 0);
l = l+32;
}
tmpShift = (minShift&((1<<5)-1)); //minShift%32;
f_gh = f_gh + ((1<<m)*((uint8_t)((s>>tmpShift)&1)));
minShift ++;
}
f_gh = f_gh%30;
f_ss = n_id%30;
/* for (int m=0; m<8; m++){
f_gh = f_gh + ((1<<m)*((uint8_t)((s>>(8*(2*nr_tti_tx+n_hop)+m))&1))); // Not sure we have to use nr_tti_tx FIXME!!!
}
f_gh = f_gh%30;
f_ss = n_id%30;*/
}
if (PUCCH_GroupHopping == disable) { // PUCCH_GroupHopping 'disabled'
c_init = (1<<5)*floor(n_id/30)+(n_id%30); // we initialize c_init to calculate u,v
s = lte_gold_generic(&x1, &c_init, 1); // TS 38.211 Subclause 5.2.1
f_ss = n_id%30;
l = 32, minShift = (2*nr_tti_tx+n_hop);
while(minShift >= l) {
s = lte_gold_generic(&x1, &c_init, 0);
l = l+32;
}
tmpShift = (minShift&((1<<5)-1)); //minShift%32;
*v = (uint8_t)((s>>tmpShift)&1);
// *v = (uint8_t)((s>>(2*nr_tti_tx+n_hop))&1); // Not sure we have to use nr_tti_tx FIXME!!!
}
*u = (f_gh+f_ss)%30;
#ifdef DEBUG_NR_PUCCH_TX
printf("%d,%d\n",*u,*v);
#endif
}
double nr_cyclic_shift_hopping(uint32_t n_id,
uint8_t m0,
uint8_t mcs,
uint8_t lnormal,
uint8_t lprime,
int nr_tti_tx) {
/*
* Implements TS 38.211 subclause 6.3.2.2.2 Cyclic shift hopping
* - n_id: higher-layer parameter hoppingId
* - m0: provided by higher layer parameter PUCCH-F0-F1-initial-cyclic-shift of PUCCH-F0-resource-config
* - mcs: mcs=0 except for PUCCH format 0 when it depends on information to be transmitted according to TS 38.213 subclause 9.2
* - lnormal: lnormal is the OFDM symbol number in the PUCCH transmission where l=0 corresponds to the first OFDM symbol of the PUCCH transmission
* - lprime: lprime is the index of the OFDM symbol in the slot that corresponds to the first OFDM symbol of the PUCCH transmission in the slot given by [5, TS 38.213]
*/
// alpha_init initialized to 2*PI/12=0.5235987756
double alpha = 0.5235987756;
uint32_t c_init = n_id; // we initialize c_init again to calculate n_cs
uint32_t x1,s = lte_gold_generic(&x1, &c_init, 1); // TS 38.211 Subclause 5.2.1
uint8_t n_cs=0;
int l = 32, minShift = (14*8*nr_tti_tx )+ 8*(lnormal+lprime);
int tmpShift =0;
#ifdef DEBUG_NR_PUCCH_TX
printf("\t\t [nr_cyclic_shift_hopping] calculating alpha (cyclic shift) using c_init=%u -> \n",c_init);
#endif
for (int m=0; m<8; m++) {
while(minShift >= l) {
s = lte_gold_generic(&x1, &c_init, 0);
l = l+32;
}
tmpShift = (minShift&((1<<5)-1)); //minShift%32;
minShift ++;
n_cs = n_cs+((1<<m)*((uint8_t)((s>>tmpShift)&1)));
// calculating n_cs (Not sure we have to use nr_tti_tx FIXME!!!)
// n_cs = n_cs+((1<<m)*((uint8_t)((s>>((14*8*nr_tti_tx) + 8*(lnormal+lprime) + m))&1)));
}
alpha = (alpha * (double)((m0+mcs+n_cs)%12));
#ifdef DEBUG_NR_PUCCH_TX
printf("n_cs=%d -> %lf\n",n_cs,alpha);
#endif
return(alpha);
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
/*! \file openair1/PHY/CODING/coding_nr_load.c
* \brief: load library implementing coding/decoding algorithms
* \author Francois TABURET
* \date 2020
* \version 0.1
* \company NOKIA BellLabs France
* \email: francois.taburet@nokia-bell-labs.com
* \note
* \warning
*/
#define _GNU_SOURCE
#include <sys/types.h>
#include <stdlib.h>
#include <malloc.h>
#include "assertions.h"
#include "common/utils/LOG/log.h"
#define OAIDFTS_LOADER
#include "tools_defs.h"
#include "common/config/config_userapi.h"
#include "common/utils/load_module_shlib.h"
/* function description array, to be used when loading the dfts/idfts lib */
static loader_shlibfunc_t shlib_fdesc[2];
static char *arg[64]={"phytest","-O","cmdlineonly::dbgl0"};
int load_dftslib(void) {
char *ptr = (char*)config_get_if();
if ( ptr==NULL ) {// phy simulators, config module possibly not loaded
load_configmodule(3,(char **)arg,CONFIG_ENABLECMDLINEONLY) ;
logInit();
}
shlib_fdesc[0].fname = "dft";
shlib_fdesc[1].fname = "idft";
int ret=load_module_shlib("dfts",shlib_fdesc,sizeof(shlib_fdesc)/sizeof(loader_shlibfunc_t),NULL);
AssertFatal( (ret >= 0),"Error loading dftsc decoder");
dft = (dftfunc_t)shlib_fdesc[0].fptr;
idft = (idftfunc_t)shlib_fdesc[1].fptr;
return 0;
}
This source diff could not be displayed because it is too large. You can view the blob instead.
RLC AM
======
- 36.322 5.4 Re-establishment procedure
when possible, reassemble RLC SDUs from any byte segments of AMD PDUs
with SN < VR(MR) in the receiving side, remove RLC headers when doing
so and deliver all reassembled RLC SDUs to upper layer in ascending order
of the RLC SN, if not delivered before;
- 36.322 5.2.3 Status reporting
delay triggering the STATUS report until x < VR(MS) or x >= VR(MR)
- 36.322 5.1.3.2.3 Actions when a RLC data PDU is placed in the reception
buffer
[...] and in-sequence byte segments of the AMD PDU with SN = VR(R) [...]
- use SOstart/SOend in NACK reporting, do not NACK full PDU if
parts of it have been received
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include "rlc.h"
int decode_t_reordering(int v)
{
static int tab[32] = {
0, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85,
90, 95, 100, 110, 120, 130, 140, 150, 160, 170, 180, 190, 200, 1600
};
if (v < 0 || v > 31) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
return tab[v];
}
int decode_t_status_prohibit(int v)
{
static int tab[62] = {
0, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90,
95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165,
170, 175, 180, 185, 190, 195, 200, 205, 210, 215, 220, 225, 230, 235, 240,
245, 250, 300, 350, 400, 450, 500, 800, 1000, 1200, 1600, 2000, 2400
};
if (v < 0 || v > 61) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
return tab[v];
}
int decode_t_poll_retransmit(int v)
{
static int tab[59] = {
5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95,
100, 105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165, 170,
175, 180, 185, 190, 195, 200, 205, 210, 215, 220, 225, 230, 235, 240, 245,
250, 300, 350, 400, 450, 500, 800, 1000, 2000, 4000
};
if (v < 0 || v > 58) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
return tab[v];
}
int decode_poll_pdu(int v)
{
static int tab[8] = {
4, 8, 16, 32, 64, 128, 256, -1 /* -1 means infinity */
};
if (v < 0 || v > 7) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
return tab[v];
}
int decode_poll_byte(int v)
{
static int tab[15] = {
25, 50, 75, 100, 125, 250, 375, 500, 750, 1000, 1250, 1500, 2000, 3000,
-1 /* -1 means infinity */
};
if (v < 0 || v > 14) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if (tab[v] == -1) return -1;
return tab[v] * 1024;
}
int decode_max_retx_threshold(int v)
{
static int tab[8] = {
1, 2, 3, 4, 6, 8, 16, 32
};
if (v < 0 || v > 7) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
return tab[v];
}
int decode_sn_field_length(int v)
{
static int tab[2] = {
5, 10
};
if (v < 0 || v > 1) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
return tab[v];
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef _ASN1_UTILS_H_
#define _ASN1_UTILS_H_
int decode_t_reordering(int v);
int decode_t_status_prohibit(int v);
int decode_t_poll_retransmit(int v);
int decode_poll_pdu(int v);
int decode_poll_byte(int v);
int decode_max_retx_threshold(int v);
int decode_sn_field_length(int v);
#endif /* _ASN1_UTILS_H_ */
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include "rlc_entity.h"
#include <stdlib.h>
#include "rlc_entity_am.h"
#include "rlc_entity_um.h"
#include "LOG/log.h"
rlc_entity_t *new_rlc_entity_am(
int rx_maxsize,
int tx_maxsize,
void (*deliver_sdu)(void *deliver_sdu_data, struct rlc_entity_t *entity,
char *buf, int size),
void *deliver_sdu_data,
void (*sdu_successful_delivery)(void *sdu_successful_delivery_data,
struct rlc_entity_t *entity,
int sdu_id),
void *sdu_successful_delivery_data,
void (*max_retx_reached)(void *max_retx_reached_data,
struct rlc_entity_t *entity),
void *max_retx_reached_data,
int t_reordering,
int t_status_prohibit,
int t_poll_retransmit,
int poll_pdu,
int poll_byte,
int max_retx_threshold)
{
rlc_entity_am_t *ret;
ret = calloc(1, sizeof(rlc_entity_am_t));
if (ret == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
ret->common.recv_pdu = rlc_entity_am_recv_pdu;
ret->common.buffer_status = rlc_entity_am_buffer_status;
ret->common.generate_pdu = rlc_entity_am_generate_pdu;
ret->common.recv_sdu = rlc_entity_am_recv_sdu;
ret->common.set_time = rlc_entity_am_set_time;
ret->common.discard_sdu = rlc_entity_am_discard_sdu;
ret->common.reestablishment = rlc_entity_am_reestablishment;
ret->common.delete = rlc_entity_am_delete;
ret->common.deliver_sdu = deliver_sdu;
ret->common.deliver_sdu_data = deliver_sdu_data;
ret->common.sdu_successful_delivery = sdu_successful_delivery;
ret->common.sdu_successful_delivery_data = sdu_successful_delivery_data;
ret->common.max_retx_reached = max_retx_reached;
ret->common.max_retx_reached_data = max_retx_reached_data;
ret->rx_maxsize = rx_maxsize;
ret->tx_maxsize = tx_maxsize;
ret->t_reordering = t_reordering;
ret->t_status_prohibit = t_status_prohibit;
ret->t_poll_retransmit = t_poll_retransmit;
ret->poll_pdu = poll_pdu;
ret->poll_byte = poll_byte;
ret->max_retx_threshold = max_retx_threshold;
return (rlc_entity_t *)ret;
}
rlc_entity_t *new_rlc_entity_um(
int rx_maxsize,
int tx_maxsize,
void (*deliver_sdu)(void *deliver_sdu_data, struct rlc_entity_t *entity,
char *buf, int size),
void *deliver_sdu_data,
int t_reordering,
int sn_field_length)
{
rlc_entity_um_t *ret;
ret = calloc(1, sizeof(rlc_entity_um_t));
if (ret == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
ret->common.recv_pdu = rlc_entity_um_recv_pdu;
ret->common.buffer_status = rlc_entity_um_buffer_status;
ret->common.generate_pdu = rlc_entity_um_generate_pdu;
ret->common.recv_sdu = rlc_entity_um_recv_sdu;
ret->common.set_time = rlc_entity_um_set_time;
ret->common.discard_sdu = rlc_entity_um_discard_sdu;
ret->common.reestablishment = rlc_entity_um_reestablishment;
ret->common.delete = rlc_entity_um_delete;
ret->common.deliver_sdu = deliver_sdu;
ret->common.deliver_sdu_data = deliver_sdu_data;
ret->sn_field_length = sn_field_length;
ret->rx_maxsize = rx_maxsize;
ret->tx_maxsize = tx_maxsize;
ret->t_reordering = t_reordering;
if (sn_field_length == 5)
ret->sn_modulus = 32;
else if (sn_field_length == 10)
ret->sn_modulus = 1024;
else {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
ret->window_size = ret->sn_modulus / 2;
return (rlc_entity_t *)ret;
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef _RLC_ENTITY_H_
#define _RLC_ENTITY_H_
#include <stdint.h>
#define SDU_MAX 16000 /* maximum PDCP SDU size is 8188, let's take more */
typedef struct {
int status_size;
int tx_size;
int retx_size;
} rlc_entity_buffer_status_t;
typedef struct rlc_entity_t {
/* functions provided by the RLC module */
void (*recv_pdu)(struct rlc_entity_t *entity, char *buffer, int size);
rlc_entity_buffer_status_t (*buffer_status)(
struct rlc_entity_t *entity, int maxsize);
int (*generate_pdu)(struct rlc_entity_t *entity, char *buffer, int size);
void (*recv_sdu)(struct rlc_entity_t *entity, char *buffer, int size,
int sdu_id);
void (*set_time)(struct rlc_entity_t *entity, uint64_t now);
void (*discard_sdu)(struct rlc_entity_t *entity, int sdu_id);
void (*reestablishment)(struct rlc_entity_t *entity);
void (*delete)(struct rlc_entity_t *entity);
/* callbacks provided to the RLC module */
void (*deliver_sdu)(void *deliver_sdu_data, struct rlc_entity_t *entity,
char *buf, int size);
void *deliver_sdu_data;
void (*sdu_successful_delivery)(void *sdu_successful_delivery_data,
struct rlc_entity_t *entity,
int sdu_id);
void *sdu_successful_delivery_data;
void (*max_retx_reached)(void *max_retx_reached_data,
struct rlc_entity_t *entity);
void *max_retx_reached_data;
} rlc_entity_t;
rlc_entity_t *new_rlc_entity_am(
int rx_maxsize,
int tx_maxsize,
void (*deliver_sdu)(void *deliver_sdu_data, struct rlc_entity_t *entity,
char *buf, int size),
void *deliver_sdu_data,
void (*sdu_successful_delivery)(void *sdu_successful_delivery_data,
struct rlc_entity_t *entity,
int sdu_id),
void *sdu_successful_delivery_data,
void (*max_retx_reached)(void *max_retx_reached_data,
struct rlc_entity_t *entity),
void *max_retx_reached_data,
int t_reordering,
int t_status_prohibit,
int t_poll_retransmit,
int poll_pdu,
int poll_byte,
int max_retx_threshold);
rlc_entity_t *new_rlc_entity_um(
int rx_maxsize,
int tx_maxsize,
void (*deliver_sdu)(void *deliver_sdu_data, struct rlc_entity_t *entity,
char *buf, int size),
void *deliver_sdu_data,
int t_reordering,
int sn_field_length);
#endif /* _RLC_ENTITY_H_ */
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include "rlc_entity_am.h"
#include "rlc_pdu.h"
#include <stdlib.h>
#include <string.h>
#include "LOG/log.h"
/*************************************************************************/
/* PDU RX functions */
/*************************************************************************/
static int modulus_rx(rlc_entity_am_t *entity, int a)
{
/* as per 36.322 7.1, modulus base is vr(r) and modulus is 1024 for rx */
int r = a - entity->vr_r;
if (r < 0) r += 1024;
return r;
}
/* used in both RX and TX processing */
static int modulus_tx(rlc_entity_am_t *entity, int a)
{
/* as per 36.322 7.1, modulus base is vt(a) and modulus is 1024 for tx */
int r = a - entity->vt_a;
if (r < 0) r += 1024;
return r;
}
static int sn_in_recv_window(void *_entity, int sn)
{
rlc_entity_am_t *entity = _entity;
int mod_sn = modulus_rx(entity, sn);
/* we simplify vr(r)<=sn<vr(mr). base is vr(r) and vr(mr) = vr(r) + 512 */
return mod_sn < 512;
}
static int sn_compare_rx(void *_entity, int a, int b)
{
rlc_entity_am_t *entity = _entity;
return modulus_rx(entity, a) - modulus_rx(entity, b);
}
/* used in both RX and TX processing */
static int sn_compare_tx(void *_entity, int a, int b)
{
rlc_entity_am_t *entity = _entity;
return modulus_tx(entity, a) - modulus_tx(entity, b);
}
static int segment_already_received(rlc_entity_am_t *entity,
int sn, int so, int data_size)
{
/* TODO: optimize */
rlc_rx_pdu_segment_t *l = entity->rx_list;
while (l != NULL) {
if (l->sn == sn && l->so <= so &&
l->so + l->size - l->data_offset >= so + data_size)
return 1;
l = l->next;
}
return 0;
}
static int rlc_am_segment_full(rlc_entity_am_t *entity, int sn)
{
rlc_rx_pdu_segment_t *l = entity->rx_list;
int last_byte;
int new_last_byte;
last_byte = -1;
while (l != NULL) {
if (l->sn == sn)
break;
l = l->next;
}
while (l != NULL && l->sn == sn) {
if (l->so > last_byte + 1)
return 0;
if (l->is_last)
return 1;
new_last_byte = l->so + l->size - l->data_offset - 1;
if (new_last_byte > last_byte)
last_byte = new_last_byte;
l = l->next;
}
return 0;
}
/* return 1 if the new segment has some data to consume, 0 if not */
static int rlc_am_reassemble_next_segment(rlc_am_reassemble_t *r)
{
int rf;
int sn;
r->sdu_offset = r->start->data_offset;
rlc_pdu_decoder_init(&r->dec, r->start->data, r->start->size);
rlc_pdu_decoder_get_bits(&r->dec, 1); /* dc */
rf = rlc_pdu_decoder_get_bits(&r->dec, 1);
rlc_pdu_decoder_get_bits(&r->dec, 1); /* p */
r->fi = rlc_pdu_decoder_get_bits(&r->dec, 2);
r->e = rlc_pdu_decoder_get_bits(&r->dec, 1);
sn = rlc_pdu_decoder_get_bits(&r->dec, 10);
if (rf) {
rlc_pdu_decoder_get_bits(&r->dec, 1); /* lsf */
r->so = rlc_pdu_decoder_get_bits(&r->dec, 15);
} else {
r->so = 0;
}
if (r->e) {
r->e = rlc_pdu_decoder_get_bits(&r->dec, 1);
r->sdu_len = rlc_pdu_decoder_get_bits(&r->dec, 11);
} else
r->sdu_len = r->start->size - r->sdu_offset;
/* new sn: read starts from PDU byte 0 */
if (sn != r->sn) {
r->pdu_byte = 0;
r->sn = sn;
}
r->data_pos = r->start->data_offset + r->pdu_byte - r->so;
/* TODO: remove this check, it is useless, data has been validated before */
if (r->pdu_byte < r->so) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
/* if pdu_byte is not in [so .. so+len-1] then all bytes from this segment
* have already been consumed
*/
if (r->pdu_byte >= r->so + r->start->size - r->start->data_offset)
return 0;
/* go to correct SDU */
while (r->pdu_byte >= r->so + (r->sdu_offset - r->start->data_offset) + r->sdu_len) {
r->sdu_offset += r->sdu_len;
if (r->e) {
r->e = rlc_pdu_decoder_get_bits(&r->dec, 1);
r->sdu_len = rlc_pdu_decoder_get_bits(&r->dec, 11);
} else {
r->sdu_len = r->start->size - r->sdu_offset;
}
}
return 1;
}
static void rlc_am_reassemble(rlc_entity_am_t *entity)
{
rlc_am_reassemble_t *r = &entity->reassemble;
while (r->start != NULL) {
if (r->sdu_pos >= SDU_MAX) {
/* TODO: proper error handling (discard PDUs with current sn from
* reassembly queue? something else?)
*/
LOG_E(RLC, "%s:%d:%s: bad RLC PDU\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
r->sdu[r->sdu_pos] = r->start->data[r->data_pos];
r->sdu_pos++;
r->data_pos++;
r->pdu_byte++;
if (r->data_pos == r->sdu_offset + r->sdu_len) {
/* all bytes of SDU are consumed, check if SDU is fully there.
* It is if the data pointer is not at the end of the PDU segment
* or if 'fi' & 1 == 0
*/
if (r->data_pos != r->start->size ||
(r->fi & 1) == 0) {
/* SDU is full - deliver to higher layer */
entity->common.deliver_sdu(entity->common.deliver_sdu_data,
(rlc_entity_t *)entity,
r->sdu, r->sdu_pos);
r->sdu_pos = 0;
}
if (r->data_pos != r->start->size) {
/* not at the end, process next SDU */
r->sdu_offset += r->sdu_len;
if (r->e) {
r->e = rlc_pdu_decoder_get_bits(&r->dec, 1);
r->sdu_len = rlc_pdu_decoder_get_bits(&r->dec, 11);
} else
r->sdu_len = r->start->size - r->sdu_offset;
} else {
/* all bytes are consumend, go to next segment not already fully
* processed, if any
*/
do {
rlc_rx_pdu_segment_t *e = r->start;
entity->rx_size -= e->size;
r->start = r->start->next;
rlc_rx_free_pdu_segment(e);
} while (r->start != NULL && !rlc_am_reassemble_next_segment(r));
}
}
}
}
static void rlc_am_reception_actions(rlc_entity_am_t *entity,
rlc_rx_pdu_segment_t *pdu_segment)
{
int x = pdu_segment->sn;
int vr_ms;
int vr_r;
if (modulus_rx(entity, x) >= modulus_rx(entity, entity->vr_h))
entity->vr_h = (x + 1) % 1024;
vr_ms = entity->vr_ms;
while (rlc_am_segment_full(entity, vr_ms))
vr_ms = (vr_ms + 1) % 1024;
entity->vr_ms = vr_ms;
if (x == entity->vr_r) {
vr_r = entity->vr_r;
while (rlc_am_segment_full(entity, vr_r)) {
/* move segments with sn=vr(r) from rx list to end of reassembly list */
while (entity->rx_list != NULL && entity->rx_list->sn == vr_r) {
rlc_rx_pdu_segment_t *e = entity->rx_list;
entity->rx_list = e->next;
e->next = NULL;
if (entity->reassemble.start == NULL) {
entity->reassemble.start = e;
/* the list was empty, we need to init decoder */
entity->reassemble.sn = -1;
if (!rlc_am_reassemble_next_segment(&entity->reassemble)) {
/* TODO: proper error recovery (or remove the test, it should not happen) */
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
} else {
entity->reassemble.end->next = e;
}
entity->reassemble.end = e;
}
/* update vr_r */
vr_r = (vr_r + 1) % 1024;
}
entity->vr_r = vr_r;
}
rlc_am_reassemble(entity);
if (entity->t_reordering_start) {
int vr_x = entity->vr_x;
if (vr_x < entity->vr_r) vr_x += 1024;
if (vr_x == entity->vr_r || vr_x > entity->vr_r + 512)
entity->t_reordering_start = 0;
}
if (entity->t_reordering_start == 0) {
if (sn_compare_rx(entity, entity->vr_h, entity->vr_r) > 0) {
entity->t_reordering_start = entity->t_current;
entity->vr_x = entity->vr_h;
}
}
}
static void process_received_ack(rlc_entity_am_t *entity, int sn)
{
rlc_tx_pdu_segment_t head;
rlc_tx_pdu_segment_t *cur;
rlc_tx_pdu_segment_t *prev;
/* put all PDUs from wait and retransmit lists with SN < 'sn' to ack_list */
/* process wait list */
head.next = entity->wait_list;
prev = &head;
cur = entity->wait_list;
while (cur != NULL) {
if (sn_compare_tx(entity, cur->sn, sn) < 0) {
/* remove from wait list */
prev->next = cur->next;
/* put the PDU in the ack list */
entity->ack_list = rlc_tx_pdu_list_add(sn_compare_tx, entity,
entity->ack_list, cur);
cur = prev->next;
} else {
prev = cur;
cur = cur->next;
}
}
entity->wait_list = head.next;
/* process retransmit list */
head.next = entity->retransmit_list;
prev = &head;
cur = entity->retransmit_list;
while (cur != NULL) {
if (sn_compare_tx(entity, cur->sn, sn) < 0) {
/* dec. retx_count in case we put this segment back in retransmit list
* in 'process_received_nack'
*/
cur->retx_count--;
/* remove from retransmit list */
prev->next = cur->next;
/* put the PDU in the ack list */
entity->ack_list = rlc_tx_pdu_list_add(sn_compare_tx, entity,
entity->ack_list, cur);
cur = prev->next;
} else {
prev = cur;
cur = cur->next;
}
}
entity->retransmit_list = head.next;
}
static void consider_retransmission(rlc_entity_am_t *entity,
rlc_tx_pdu_segment_t *cur)
{
cur->retx_count++;
/* let's report max RETX reached for all retx_count >= max_retx_threshold
* (specs say to report if retx_count == max_retx_threshold).
* Upper layers should react (radio link failure), so no big deal actually.
*/
if (cur->retx_count >= entity->max_retx_threshold) {
entity->common.max_retx_reached(entity->common.max_retx_reached_data,
(rlc_entity_t *)entity);
}
/* let's put in retransmit list even if we are over max_retx_threshold.
* upper layers should deal with this condition, internally it's better
* for the RLC code to keep going with this segment (we only remove
* a segment that was ACKed)
*/
entity->retransmit_list = rlc_tx_pdu_list_add(sn_compare_tx, entity,
entity->retransmit_list, cur);
}
static int so_overlap(int s1, int e1, int s2, int e2)
{
if (s1 < s2) {
if (e1 == -1 || e1 >= s2)
return 1;
return 0;
}
if (e2 == -1 || s1 <= e2)
return 1;
return 0;
}
static void process_received_nack(rlc_entity_am_t *entity, int sn,
int so_start, int so_end)
{
/* put all PDU segments with SN == 'sn' and with an overlapping so start/end
* to the retransmit list
* source lists are ack list and wait list.
* Not sure if we should consider wait list, isn't the other end supposed
* to only NACK SNs lower than the ACK SN sent in the status PDU, in which
* case all potential PDU segments should all be in ack list when calling
* the current function? in doubt let's accept anything and thus process
* also wait list.
*/
rlc_tx_pdu_segment_t head;
rlc_tx_pdu_segment_t *cur;
rlc_tx_pdu_segment_t *prev;
/* check that VT(A) <= sn < VT(S) */
if (!(sn_compare_tx(entity, entity->vt_a, sn) <= 0 &&
sn_compare_tx(entity, sn, entity->vt_s) < 0))
return;
/* process wait list */
head.next = entity->wait_list;
prev = &head;
cur = entity->wait_list;
while (cur != NULL) {
if (cur->sn == sn &&
so_overlap(so_start, so_end, cur->so, cur->so + cur->data_size - 1)) {
/* remove from wait list */
prev->next = cur->next;
/* consider the PDU segment for retransmission */
consider_retransmission(entity, cur);
cur = prev->next;
} else {
prev = cur;
cur = cur->next;
}
}
entity->wait_list = head.next;
/* process ack list */
head.next = entity->ack_list;
prev = &head;
cur = entity->ack_list;
while (cur != NULL) {
if (cur->sn == sn &&
so_overlap(so_start, so_end, cur->so, cur->so + cur->data_size - 1)) {
/* remove from ack list */
prev->next = cur->next;
/* consider the PDU segment for retransmission */
consider_retransmission(entity, cur);
cur = prev->next;
} else {
prev = cur;
cur = cur->next;
}
}
entity->ack_list = head.next;
}
int tx_pdu_in_ack_list_full(rlc_tx_pdu_segment_t *pdu)
{
int sn = pdu->sn;
int last_byte = -1;
int new_last_byte;
int is_last_seen = 0;
while (pdu != NULL && pdu->sn == sn) {
if (pdu->so > last_byte + 1) return 0;
if (pdu->is_last)
is_last_seen = 1;
new_last_byte = pdu->so + pdu->data_size - 1;
if (new_last_byte > last_byte)
last_byte = new_last_byte;
pdu = pdu->next;
}
return is_last_seen == 1;
}
int tx_pdu_in_ack_list_size(rlc_tx_pdu_segment_t *pdu)
{
int sn = pdu->sn;
int ret = 0;
while (pdu != NULL && pdu->sn == sn) {
ret += pdu->data_size;
pdu = pdu->next;
}
return ret;
}
void ack_sdu_bytes(rlc_sdu_t *start, int start_byte, int sdu_size)
{
rlc_sdu_t *cur = start;
int remaining_size = sdu_size;
while (remaining_size) {
int cursize = cur->size - start_byte;
if (cursize > remaining_size)
cursize = remaining_size;
cur->acked_bytes += cursize;
remaining_size -= cursize;
/* start_byte is only meaningful for the 1st SDU, then it is 0 */
start_byte = 0;
cur = cur->next;
}
}
rlc_tx_pdu_segment_t *tx_list_remove_sn(rlc_tx_pdu_segment_t *list, int sn)
{
rlc_tx_pdu_segment_t head;
rlc_tx_pdu_segment_t *cur;
rlc_tx_pdu_segment_t *prev;
head.next = list;
cur = list;
prev = &head;
while (cur != NULL) {
if (cur->sn == sn) {
prev->next = cur->next;
rlc_tx_free_pdu(cur);
cur = prev->next;
} else {
prev = cur;
cur = cur->next;
}
}
return head.next;
}
void cleanup_sdu_list(rlc_entity_am_t *entity)
{
rlc_sdu_t head;
rlc_sdu_t *cur;
rlc_sdu_t *prev;
/* remove fully acked SDUs, indicate successful delivery to upper layer */
head.next = entity->tx_list;
cur = entity->tx_list;
prev = &head;
while (cur != NULL) {
if (cur->acked_bytes == cur->size) {
prev->next = cur->next;
entity->tx_size -= cur->size;
entity->common.sdu_successful_delivery(
entity->common.sdu_successful_delivery_data,
(rlc_entity_t *)entity, cur->upper_layer_id);
rlc_free_sdu(cur);
entity->tx_end = prev;
cur = prev->next;
} else {
entity->tx_end = cur;
prev = cur;
cur = cur->next;
}
}
entity->tx_list = head.next;
/* if tx_end == head then it means that the list is now empty */
if (entity->tx_end == &head)
entity->tx_end = NULL;
}
static void finalize_ack_nack_processing(rlc_entity_am_t *entity)
{
int sn;
rlc_tx_pdu_segment_t *cur = entity->ack_list;
int pdu_size;
if (cur == NULL)
return;
/* Remove full PDUs and ack the SDU bytes they cover. Start from SN == VT(A)
* and process increasing SNs until end of list or missing ACK or PDU not
* fully ACKed.
*/
while (cur != NULL && cur->sn == entity->vt_a &&
tx_pdu_in_ack_list_full(cur)) {
sn = cur->sn;
entity->vt_a = (entity->vt_a + 1) % 1024;
pdu_size = tx_pdu_in_ack_list_size(cur);
ack_sdu_bytes(cur->start_sdu, cur->sdu_start_byte, pdu_size);
while (cur != NULL && cur->sn == sn)
cur = cur->next;
entity->ack_list = tx_list_remove_sn(entity->ack_list, sn);
}
cleanup_sdu_list(entity);
}
void rlc_entity_am_recv_pdu(rlc_entity_t *_entity, char *buffer, int size)
{
#define R(d) do { if (rlc_pdu_decoder_in_error(&d)) goto err; } while (0)
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
rlc_pdu_decoder_t decoder;
rlc_pdu_decoder_t data_decoder;
rlc_pdu_decoder_t control_decoder;
int dc;
int rf;
int p = 0;
int fi;
int e;
int sn;
int lsf;
int so;
int cpt;
int e1;
int e2;
int ack_sn;
int nack_sn;
int so_start;
int so_end;
int control_e1;
int control_e2;
int data_e;
int data_li;
int packet_count;
int data_size;
int data_start;
int indicated_data_size;
rlc_rx_pdu_segment_t *pdu_segment;
rlc_pdu_decoder_init(&decoder, buffer, size);
dc = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
if (dc == 0) goto control;
/* data PDU */
rf = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
p = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
fi = rlc_pdu_decoder_get_bits(&decoder, 2); R(decoder);
e = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
sn = rlc_pdu_decoder_get_bits(&decoder, 10); R(decoder);
/* dicard PDU if rx buffer is full */
if (entity->rx_size + size > entity->rx_maxsize) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, RX buffer full\n",
__FILE__, __LINE__, __FUNCTION__);
goto discard;
}
if (!sn_in_recv_window(entity, sn)) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, sn out of window (sn %d vr_r %d)\n",
__FILE__, __LINE__, __FUNCTION__,
sn, entity->vr_r);
goto discard;
}
if (rf) {
lsf = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
so = rlc_pdu_decoder_get_bits(&decoder, 15); R(decoder);
} else {
lsf = 1;
so = 0;
}
packet_count = 1;
/* go to start of data */
indicated_data_size = 0;
data_decoder = decoder;
data_e = e;
while (data_e) {
data_e = rlc_pdu_decoder_get_bits(&data_decoder, 1); R(data_decoder);
data_li = rlc_pdu_decoder_get_bits(&data_decoder, 11); R(data_decoder);
if (data_li == 0) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, li == 0\n",
__FILE__, __LINE__, __FUNCTION__);
goto discard;
}
indicated_data_size += data_li;
packet_count++;
}
rlc_pdu_decoder_align(&data_decoder);
data_start = data_decoder.byte;
data_size = size - data_start;
if (data_size <= 0) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, wrong data size (sum of LI %d data size %d)\n",
__FILE__, __LINE__, __FUNCTION__,
indicated_data_size, data_size);
goto discard;
}
if (indicated_data_size >= data_size) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, bad LIs (sum of LI %d data size %d)\n",
__FILE__, __LINE__, __FUNCTION__,
indicated_data_size, data_size);
goto discard;
}
/* discard segment if all the bytes of the segment are already there */
if (segment_already_received(entity, sn, so, data_size)) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, already received\n",
__FILE__, __LINE__, __FUNCTION__);
goto discard;
}
char *fi_str[] = {
"first byte: YES last byte: YES",
"first byte: YES last byte: NO",
"first byte: NO last byte: YES",
"first byte: NO last byte: NO",
};
LOG_D(RLC, "found %d packets, data size %d data start %d [fi %d %s] (sn %d) (p %d)\n",
packet_count, data_size, data_decoder.byte, fi, fi_str[fi], sn, p);
/* put in pdu reception list */
entity->rx_size += size;
pdu_segment = rlc_rx_new_pdu_segment(sn, so, size, lsf, buffer, data_start);
entity->rx_list = rlc_rx_pdu_segment_list_add(sn_compare_rx, entity,
entity->rx_list, pdu_segment);
/* do reception actions (36.322 5.1.3.2.3) */
rlc_am_reception_actions(entity, pdu_segment);
if (p) {
/* 36.322 5.2.3 says status triggering should be delayed
* until x < VR(MS) or x >= VR(MR). This is not clear (what
* is x then? we keep the same?). So let's trigger no matter what.
*/
int vr_mr = (entity->vr_r + 512) % 1024;
entity->status_triggered = 1;
if (!(sn_compare_rx(entity, sn, entity->vr_ms) < 0 ||
sn_compare_rx(entity, sn, vr_mr) >= 0)) {
LOG_D(RLC, "%s:%d:%s: warning: STATUS trigger should be delayed, according to specs\n",
__FILE__, __LINE__, __FUNCTION__);
}
}
return;
control:
cpt = rlc_pdu_decoder_get_bits(&decoder, 3); R(decoder);
if (cpt != 0) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, CPT not 0 (%d)\n",
__FILE__, __LINE__, __FUNCTION__, cpt);
goto discard;
}
ack_sn = rlc_pdu_decoder_get_bits(&decoder, 10); R(decoder);
e1 = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
/* let's try to parse the control PDU once to check consistency */
control_decoder = decoder;
control_e1 = e1;
while (control_e1) {
rlc_pdu_decoder_get_bits(&control_decoder, 10); R(control_decoder); /* NACK_SN */
control_e1 = rlc_pdu_decoder_get_bits(&control_decoder, 1); R(control_decoder);
control_e2 = rlc_pdu_decoder_get_bits(&control_decoder, 1); R(control_decoder);
if (control_e2) {
rlc_pdu_decoder_get_bits(&control_decoder, 15); R(control_decoder); /* SOstart */
rlc_pdu_decoder_get_bits(&control_decoder, 15); R(control_decoder); /* SOend */
}
}
/* 36.322 5.2.2.2 says to stop t_poll_retransmit if a ACK or NACK is
* received for the SN 'poll_sn'
*/
if (sn_compare_tx(entity, entity->poll_sn, ack_sn) < 0)
entity->t_poll_retransmit_start = 0;
/* at this point, accept the PDU even if the actual values
* may be incorrect (eg. if so_start > so_end)
*/
process_received_ack(entity, ack_sn);
while (e1) {
nack_sn = rlc_pdu_decoder_get_bits(&decoder, 10); R(decoder);
e1 = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
e2 = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
if (e2) {
so_start = rlc_pdu_decoder_get_bits(&decoder, 15); R(decoder);
so_end = rlc_pdu_decoder_get_bits(&decoder, 15); R(decoder);
if (so_end < so_start) {
LOG_W(RLC, "%s:%d:%s: warning, bad so start/end, NACK the whole PDU (sn %d)\n",
__FILE__, __LINE__, __FUNCTION__, nack_sn);
so_start = 0;
so_end = -1;
}
/* special value 0x7fff indicates 'all bytes to the end' */
if (so_end == 0x7fff)
so_end = -1;
} else {
so_start = 0;
so_end = -1;
}
process_received_nack(entity, nack_sn, so_start, so_end);
/* 36.322 5.2.2.2 says to stop t_poll_retransmit if a ACK or NACK is
* received for the SN 'poll_sn'
*/
if (entity->poll_sn == nack_sn)
entity->t_poll_retransmit_start = 0;
}
finalize_ack_nack_processing(entity);
return;
err:
LOG_W(RLC, "%s:%d:%s: error decoding PDU, discarding\n", __FILE__, __LINE__, __FUNCTION__);
goto discard;
discard:
if (p)
entity->status_triggered = 1;
#undef R
}
/*************************************************************************/
/* TX functions */
/*************************************************************************/
static int pdu_size(rlc_entity_am_t *entity, rlc_tx_pdu_segment_t *pdu)
{
int header_size;
int sdu_count;
int data_size;
int li_bits;
rlc_sdu_t *sdu;
header_size = 2;
if (pdu->is_segment)
header_size += 2;
data_size = pdu->data_size;
sdu = pdu->start_sdu;
sdu_count = 1;
data_size -= sdu->size - pdu->sdu_start_byte;
sdu = sdu->next;
while (data_size > 0) {
sdu_count++;
data_size -= sdu->size;
sdu = sdu->next;
}
li_bits = 12 * (sdu_count - 1);
header_size += (li_bits + 7) / 8;
return header_size + pdu->data_size;
}
static int header_size(int sdu_count)
{
int bits = 16 + 12 * (sdu_count - 1);
/* padding if we have to */
return (bits + 7) / 8;
}
typedef struct {
int sdu_count;
int data_size;
int header_size;
} tx_pdu_size_t;
static tx_pdu_size_t compute_new_pdu_size(rlc_entity_am_t *entity, int maxsize)
{
tx_pdu_size_t ret;
int sdu_count;
int sdu_size;
int pdu_data_size;
rlc_sdu_t *sdu;
int vt_ms = (entity->vt_a + 512) % 1024;
ret.sdu_count = 0;
ret.data_size = 0;
ret.header_size = 0;
/* sn out of window? nothing to do */
if (!(sn_compare_tx(entity, entity->vt_s, entity->vt_a) >= 0 &&
sn_compare_tx(entity, entity->vt_s, vt_ms) < 0))
return ret;
/* TX PDU - let's make the biggest PDU we can with the SDUs we have */
sdu_count = 0;
pdu_data_size = 0;
sdu = entity->tx_list;
while (sdu != NULL) {
/* include SDU only if it has not been fully included in PDUs already */
if (sdu->next_byte != sdu->size) {
int new_header_size = header_size(sdu_count + 1);
/* if we cannot put new header + at least 1 byte of data then over */
if (new_header_size + pdu_data_size + 1 > maxsize)
break;
sdu_count++;
/* only include the bytes of this SDU not included in PDUs already */
sdu_size = sdu->size - sdu->next_byte;
/* don't feed more than 'maxsize' bytes */
if (new_header_size + pdu_data_size + sdu_size > maxsize)
sdu_size = maxsize - new_header_size - pdu_data_size;
pdu_data_size += sdu_size;
/* if we put more than 2^11-1 bytes then the LI field cannot be used,
* so this is the last SDU we can put
*/
if (sdu_size > 2047)
break;
}
sdu = sdu->next;
}
if (sdu_count) {
ret.sdu_count = sdu_count;
ret.data_size = pdu_data_size;
ret.header_size = header_size(sdu_count);
}
return ret;
}
static int status_size(rlc_entity_am_t *entity, int maxsize)
{
/* let's count bits */
int bits = 15; /* minimum size is 15 (header+ack_sn+e1) */
int sn;
maxsize *= 8;
if (bits > maxsize) {
LOG_W(RLC, "%s:%d:%s: warning: cannot generate status PDU, not enough room\n",
__FILE__, __LINE__, __FUNCTION__);
return 0;
}
/* each NACK adds 12 bits */
sn = entity->vr_r;
while (bits + 12 <= maxsize && sn_compare_rx(entity, sn, entity->vr_ms) < 0) {
if (!(rlc_am_segment_full(entity, sn)))
bits += 12;
sn = (sn + 1) % 1024;
}
return (bits + 7) / 8;
}
static int generate_status(rlc_entity_am_t *entity, char *buffer, int size)
{
/* let's count bits */
int bits = 15; /* minimum size is 15 (header+ack_sn+e1) */
int sn;
rlc_pdu_encoder_t encoder;
int has_nack = 0;
int ack;
rlc_pdu_encoder_init(&encoder, buffer, size);
size *= 8;
if (bits > size) {
LOG_W(RLC, "%s:%d:%s: warning: cannot generate status PDU, not enough room\n",
__FILE__, __LINE__, __FUNCTION__);
return 0;
}
/* header */
rlc_pdu_encoder_put_bits(&encoder, 0, 1); /* D/C */
rlc_pdu_encoder_put_bits(&encoder, 0, 3); /* CPT */
/* reserve room for ACK (it will be set after putting the NACKs) */
rlc_pdu_encoder_put_bits(&encoder, 0, 10);
/* at this point, ACK is VR(R) */
ack = entity->vr_r;
/* each NACK adds 12 bits */
sn = entity->vr_r;
while (bits + 12 <= size && sn_compare_rx(entity, sn, entity->vr_ms) < 0) {
if (!(rlc_am_segment_full(entity, sn))) {
/* put previous e1 (is 1) */
rlc_pdu_encoder_put_bits(&encoder, 1, 1);
/* if previous was NACK, put previous e2 (0, we don't do 'so' thing) */
if (has_nack)
rlc_pdu_encoder_put_bits(&encoder, 0, 1);
/* put NACKed sn */
rlc_pdu_encoder_put_bits(&encoder, sn, 10);
has_nack = 1;
bits += 12;
} else {
/* this sn is full and we put all NACKs before it, use it for ACK */
ack = (sn + 1) % 1024;
}
sn = (sn + 1) % 1024;
}
/* go to highest full sn+1 for ACK, VR(MS) is the limit */
while (sn_compare_rx(entity, sn, entity->vr_ms) < 0 &&
rlc_am_segment_full(entity, sn)) {
ack = (sn + 1) % 1024;
sn = (sn + 1) % 1024;
}
/* at this point, if last put was NACK then put 2 bits else put 1 bit */
if (has_nack)
rlc_pdu_encoder_put_bits(&encoder, 0, 2);
else
rlc_pdu_encoder_put_bits(&encoder, 0, 1);
rlc_pdu_encoder_align(&encoder);
/* let's put the ACK */
buffer[0] |= ack >> 6;
buffer[1] |= (ack & 0x3f) << 2;
/* reset the trigger */
entity->status_triggered = 0;
/* start t_status_prohibit */
entity->t_status_prohibit_start = entity->t_current;
return encoder.byte;
}
int transmission_buffer_empty(rlc_entity_am_t *entity)
{
rlc_sdu_t *sdu;
/* is transmission buffer empty? */
sdu = entity->tx_list;
while (sdu != NULL) {
if (sdu->next_byte != sdu->size)
return 0;
sdu = sdu->next;
}
return 1;
}
int check_poll_after_pdu_assembly(rlc_entity_am_t *entity)
{
int retransmission_buffer_empty;
int window_stalling;
int vt_ms;
/* is retransmission buffer empty? */
if (entity->retransmit_list == NULL)
retransmission_buffer_empty = 1;
else
retransmission_buffer_empty = 0;
/* is window stalling? */
vt_ms = (entity->vt_a + 512) % 1024;
if (!(sn_compare_tx(entity, entity->vt_s, entity->vt_a) >= 0 &&
sn_compare_tx(entity, entity->vt_s, vt_ms) < 0))
window_stalling = 1;
else
window_stalling = 0;
return (transmission_buffer_empty(entity) && retransmission_buffer_empty) ||
window_stalling;
}
void include_poll(rlc_entity_am_t *entity, char *buffer)
{
/* set the P bit to 1 */
buffer[0] |= 0x20;
entity->pdu_without_poll = 0;
entity->byte_without_poll = 0;
/* set POLL_SN to VT(S) - 1 */
entity->poll_sn = (entity->vt_s + 1023) % 1024;
/* start t_poll_retransmit */
entity->t_poll_retransmit_start = entity->t_current;
}
static int serialize_pdu(rlc_entity_am_t *entity, char *buffer, int bufsize,
rlc_tx_pdu_segment_t *pdu, int p)
{
int first_sdu_full;
int last_sdu_full;
int sdu_next_byte;
rlc_sdu_t *sdu;
int i;
int cursize;
rlc_pdu_encoder_t encoder;
int fi;
int e;
int li;
char *out;
int outpos;
int sdu_count;
int header_size;
int sdu_start_byte;
first_sdu_full = pdu->sdu_start_byte == 0;
/* is last SDU full? (and also compute sdu_count) */
last_sdu_full = 1;
sdu = pdu->start_sdu;
sdu_next_byte = pdu->sdu_start_byte;
cursize = 0;
sdu_count = 0;
while (cursize != pdu->data_size) {
int sdu_size = sdu->size - sdu_next_byte;
sdu_count++;
if (cursize + sdu_size > pdu->data_size) {
last_sdu_full = 0;
break;
}
cursize += sdu_size;
sdu = sdu->next;
sdu_next_byte = 0;
}
/* generate header */
rlc_pdu_encoder_init(&encoder, buffer, bufsize);
rlc_pdu_encoder_put_bits(&encoder, 1, 1); /* D/C: 1 = data */
rlc_pdu_encoder_put_bits(&encoder, pdu->is_segment, 1); /* RF */
rlc_pdu_encoder_put_bits(&encoder, 0, 1); /* P: reserve, set later */
fi = 0;
if (!first_sdu_full)
fi |= 0x02;
if (!last_sdu_full)
fi |= 0x01;
rlc_pdu_encoder_put_bits(&encoder, fi, 2); /* FI */
/* to understand the logic for Es and LIs:
* If we have:
* 1 SDU: E=0
*
* 2 SDUs: E=1
* then: E=0 LI(sdu[0])
*
* 3 SDUs: E=1
* then: E=1 LI(sdu[0])
* then: E=0 LI(sdu[1])
*
* 4 SDUs: E=1
* then: E=1 LI(sdu[0])
* then: E=1 LI(sdu[1])
* then: E=0 LI(sdu[2])
*/
if (sdu_count >= 2)
e = 1;
else
e = 0;
rlc_pdu_encoder_put_bits(&encoder, e, 1); /* E */
rlc_pdu_encoder_put_bits(&encoder, pdu->sn, 10); /* SN */
if (pdu->is_segment) {
rlc_pdu_encoder_put_bits(&encoder, pdu->is_last, 1); /* LSF */
rlc_pdu_encoder_put_bits(&encoder, pdu->so, 15); /* SO */
}
/* put LIs */
sdu = pdu->start_sdu;
/* first SDU */
li = sdu->size - pdu->sdu_start_byte;
/* put E+LI only if at least 2 SDUs */
if (sdu_count >= 2) {
/* E is 1 if at least 3 SDUs */
if (sdu_count >= 3)
e = 1;
else
e = 0;
rlc_pdu_encoder_put_bits(&encoder, e, 1); /* E */
rlc_pdu_encoder_put_bits(&encoder, li, 11); /* LI */
}
/* next SDUs, but not the last (no LI for the last) */
sdu = sdu->next;
for (i = 2; i < sdu_count; i++, sdu = sdu->next) {
if (i != sdu_count - 1)
e = 1;
else
e = 0;
li = sdu->size;
rlc_pdu_encoder_put_bits(&encoder, e, 1); /* E */
rlc_pdu_encoder_put_bits(&encoder, li, 11); /* LI */
}
rlc_pdu_encoder_align(&encoder);
header_size = encoder.byte;
/* generate data */
out = buffer + header_size;
sdu = pdu->start_sdu;
sdu_start_byte = pdu->sdu_start_byte;
outpos = 0;
for (i = 0; i < sdu_count; i++, sdu = sdu->next) {
li = sdu->size - sdu_start_byte;
if (outpos + li >= pdu->data_size)
li = pdu->data_size - outpos;
memcpy(out+outpos, sdu->data + sdu_start_byte, li);
outpos += li;
sdu_start_byte = 0;
}
if (p)
include_poll(entity, buffer);
return header_size + pdu->data_size;
}
static int generate_tx_pdu(rlc_entity_am_t *entity, char *buffer, int bufsize)
{
int vt_ms;
tx_pdu_size_t pdu_size;
rlc_sdu_t *sdu;
int i;
int cursize;
int p;
rlc_tx_pdu_segment_t *pdu;
/* sn out of window? do nothing */
vt_ms = (entity->vt_a + 512) % 1024;
if (!(sn_compare_tx(entity, entity->vt_s, entity->vt_a) >= 0 &&
sn_compare_tx(entity, entity->vt_s, vt_ms) < 0))
return 0;
pdu_size = compute_new_pdu_size(entity, bufsize);
if (pdu_size.sdu_count == 0)
return 0;
pdu = rlc_tx_new_pdu();
pdu->sn = entity->vt_s;
entity->vt_s = (entity->vt_s + 1) % 1024;
/* go to first SDU (skip those already fully processed) */
sdu = entity->tx_list;
while (sdu->next_byte == sdu->size)
sdu = sdu->next;
pdu->start_sdu = sdu;
pdu->sdu_start_byte = sdu->next_byte;
pdu->so = 0;
pdu->is_segment = 0;
pdu->is_last = 1;
/* to conform to specs' logic, put -1 (specs say "for 1st retransmission
* put 0 otherwise increase", let's put -1 and always increase when the
* segment goes to retransmit list)
*/
pdu->retx_count = -1;
/* reserve SDU bytes */
cursize = 0;
for (i = 0; i < pdu_size.sdu_count; i++, sdu = sdu->next) {
int sdu_size = sdu->size - sdu->next_byte;
if (cursize + sdu_size > pdu_size.data_size)
sdu_size = pdu_size.data_size - cursize;
sdu->next_byte += sdu_size;
cursize += sdu_size;
}
pdu->data_size = cursize;
/* put PDU at the end of the wait list */
entity->wait_list = rlc_tx_pdu_list_append(entity->wait_list, pdu);
/* polling actions for a new PDU */
entity->pdu_without_poll++;
entity->byte_without_poll += pdu_size.data_size;
if ((entity->poll_pdu != -1 &&
entity->pdu_without_poll >= entity->poll_pdu) ||
(entity->poll_byte != -1 &&
entity->byte_without_poll >= entity->poll_byte))
p = 1;
else
p = check_poll_after_pdu_assembly(entity);
if (entity->force_poll) {
p = 1;
entity->force_poll = 0;
}
return serialize_pdu(entity, buffer, bufsize, pdu, p);
}
static void resegment(rlc_tx_pdu_segment_t *pdu, int size)
{
rlc_tx_pdu_segment_t *new_pdu;
rlc_sdu_t *sdu;
int sdu_count;
int pdu_header_size;
int pdu_data_size;
int sdu_pos;
int sdu_bytes_to_take;
/* PDU segment too big, cut in two parts so that first part fits into
* size bytes (including header)
*/
sdu = pdu->start_sdu;
pdu_data_size = 0;
sdu_pos = pdu->sdu_start_byte;
sdu_count = 0;
while (1) {
/* can we put a new header and at least one byte of data? */
/* header has 2 more bytes for SO */
pdu_header_size = 2 + header_size(sdu_count + 1);
if (pdu_header_size + pdu_data_size + 1 > size) {
/* no we can't, stop here */
break;
}
/* yes we can, go ahead */
sdu_count++;
sdu_bytes_to_take = sdu->size - sdu_pos;
if (pdu_header_size + pdu_data_size + sdu_bytes_to_take > size) {
sdu_bytes_to_take = size - (pdu_header_size + pdu_data_size);
}
sdu_pos += sdu_bytes_to_take;
if (sdu_pos == sdu->size) {
sdu = sdu->next;
sdu_pos = 0;
}
pdu_data_size += sdu_bytes_to_take;
}
new_pdu = rlc_tx_new_pdu();
pdu->is_segment = 1;
*new_pdu = *pdu;
new_pdu->so = pdu->so + pdu_data_size;
new_pdu->data_size = pdu->data_size - pdu_data_size;
new_pdu->start_sdu = sdu;
new_pdu->sdu_start_byte = sdu_pos;
pdu->is_last = 0;
pdu->data_size = pdu_data_size;
pdu->next = new_pdu;
}
static int generate_retx_pdu(rlc_entity_am_t *entity, char *buffer, int size)
{
rlc_tx_pdu_segment_t *pdu;
int orig_size;
int p;
pdu = entity->retransmit_list;
orig_size = pdu_size(entity, pdu);
if (orig_size > size) {
/* we can't resegment if size is less than 5
* (4 bytes for header, 1 byte for data)
*/
if (size < 5)
return 0;
resegment(pdu, size);
}
/* remove from retransmit list and put in wait list */
entity->retransmit_list = pdu->next;
entity->wait_list = rlc_tx_pdu_list_add(sn_compare_tx, entity,
entity->wait_list, pdu);
p = check_poll_after_pdu_assembly(entity);
if (entity->force_poll) {
p = 1;
entity->force_poll = 0;
}
return serialize_pdu(entity, buffer, orig_size, pdu, p);
}
static int status_to_report(rlc_entity_am_t *entity)
{
return entity->status_triggered &&
(entity->t_status_prohibit_start == 0 ||
entity->t_current - entity->t_status_prohibit_start >
entity->t_status_prohibit);
}
static int retx_pdu_size(rlc_entity_am_t *entity, int maxsize)
{
int size;
if (entity->retransmit_list == NULL)
return 0;
size = pdu_size(entity, entity->retransmit_list);
if (size <= maxsize)
return size;
/* we can segment head of retransmist list if maxsize is large enough
* to hold a PDU segment with at least 1 data byte (so 5 bytes: 4 bytes
* header + 1 byte data)
*/
if (maxsize < 5)
return 0;
/* a later segmentation of the head of retransmit list will generate a pdu
* of maximum size 'maxsize' (can be less)
*/
return maxsize;
}
rlc_entity_buffer_status_t rlc_entity_am_buffer_status(
rlc_entity_t *_entity, int maxsize)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
rlc_entity_buffer_status_t ret;
tx_pdu_size_t tx_size;
/* status PDU, if we have to */
if (status_to_report(entity))
ret.status_size = status_size(entity, maxsize);
else
ret.status_size = 0;
/* TX PDU */
/* todo: if an SDU has size >2047 in the tx list then processing
* stops and computed size will not be accurate. Change the computation
* to be more accurate (if needed).
*/
tx_size = compute_new_pdu_size(entity, maxsize);
ret.tx_size = tx_size.data_size + tx_size.header_size;
/* reTX PDU */
/* todo: report size of all available data, not just first PDU */
ret.retx_size = retx_pdu_size(entity, maxsize);
return ret;
}
int rlc_entity_am_generate_pdu(rlc_entity_t *_entity, char *buffer, int size)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
int ret;
if (status_to_report(entity)) {
ret = generate_status(entity, buffer, size);
if (ret != 0)
return ret;
}
if (entity->retransmit_list != NULL) {
ret = generate_retx_pdu(entity, buffer, size);
if (ret != 0)
return ret;
}
return generate_tx_pdu(entity, buffer, size);
}
/*************************************************************************/
/* SDU RX functions */
/*************************************************************************/
void rlc_entity_am_recv_sdu(rlc_entity_t *_entity, char *buffer, int size,
int sdu_id)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
rlc_sdu_t *sdu;
if (size > SDU_MAX) {
LOG_E(RLC, "%s:%d:%s: fatal: SDU size too big (%d bytes)\n",
__FILE__, __LINE__, __FUNCTION__, size);
exit(1);
}
if (entity->tx_size + size > entity->tx_maxsize) {
LOG_D(RLC, "%s:%d:%s: warning: SDU rejected, SDU buffer full\n",
__FILE__, __LINE__, __FUNCTION__);
return;
}
entity->tx_size += size;
sdu = rlc_new_sdu(buffer, size, sdu_id);
rlc_sdu_list_add(&entity->tx_list, &entity->tx_end, sdu);
}
/*************************************************************************/
/* time/timers */
/*************************************************************************/
static void check_t_poll_retransmit(rlc_entity_am_t *entity)
{
rlc_tx_pdu_segment_t head;
rlc_tx_pdu_segment_t *cur;
rlc_tx_pdu_segment_t *prev;
int sn;
/* 36.322 5.2.2.3 */
/* did t_poll_retransmit expire? */
if (entity->t_poll_retransmit_start == 0 ||
entity->t_current <= entity->t_poll_retransmit_start +
entity->t_poll_retransmit)
return;
/* stop timer */
entity->t_poll_retransmit_start = 0;
/* 36.322 5.2.2.3 says:
*
* - include a poll in a RLC data PDU as described in section 5.2.2.1
*
* That does not seem to be conditional. So we forcefully will send
* a poll as soon as we generate a PDU.
* Hopefully this interpretation is correct. In the worst case we generate
* more polling than necessary, but it's not a big deal. When
* 't_poll_retransmit' expires it means we didn't receive a status report,
* meaning a bad radio link, so things are quite bad at this point and
* asking again for a poll won't hurt much more.
*/
entity->force_poll = 1;
LOG_D(RLC, "%s:%d:%s: warning: t_poll_retransmit expired\n",
__FILE__, __LINE__, __FUNCTION__);
/* do we meet conditions of 36.322 5.2.2.3? */
if (!check_poll_after_pdu_assembly(entity))
return;
/* search wait list for PDU with SN = VT(S)-1 */
sn = (entity->vt_s + 1023) % 1024;
head.next = entity->wait_list;
cur = entity->wait_list;
prev = &head;
while (cur != NULL) {
if (cur->sn == sn)
break;
prev = cur;
cur = cur->next;
}
/* PDU with SN = VT(S)-1 not found?, take the head of wait list */
if (cur == NULL) {
cur = entity->wait_list;
prev = &head;
sn = cur->sn;
}
/* 36.322 says "PDU", not "PDU segment", so let's retransmit all
* PDU segments with this SN
*/
while (cur != NULL && cur->sn == sn) {
prev->next = cur->next;
entity->wait_list = head.next;
/* put in retransmit list */
consider_retransmission(entity, cur);
cur = prev->next;
}
}
static void check_t_reordering(rlc_entity_am_t *entity)
{
int sn;
/* is t_reordering running and if yes has it expired? */
if (entity->t_reordering_start == 0 ||
entity->t_current <= entity->t_reordering_start + entity->t_reordering)
return;
/* stop timer */
entity->t_reordering_start = 0;
LOG_D(RLC, "%s:%d:%s: t_reordering expired\n", __FILE__, __LINE__, __FUNCTION__);
/* update VR(MS) to first SN >= VR(X) for which not all PDU segments
* have been received
*/
sn = entity->vr_x;
while (rlc_am_segment_full(entity, sn))
sn = (sn + 1) % 1024;
entity->vr_ms = sn;
if (sn_compare_rx(entity, entity->vr_h, entity->vr_ms) > 0) {
entity->t_reordering_start = entity->t_current;
entity->vr_x = entity->vr_h;
}
/* trigger STATUS report */
entity->status_triggered = 1;
}
void rlc_entity_am_set_time(rlc_entity_t *_entity, uint64_t now)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
entity->t_current = now;
check_t_poll_retransmit(entity);
check_t_reordering(entity);
/* t_status_prohibit is handled by generate_status */
}
/*************************************************************************/
/* discard/re-establishment/delete */
/*************************************************************************/
void rlc_entity_am_discard_sdu(rlc_entity_t *_entity, int sdu_id)
{
/* implements 36.322 5.3 */
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
rlc_sdu_t head;
rlc_sdu_t *cur;
rlc_sdu_t *prev;
head.next = entity->tx_list;
cur = entity->tx_list;
prev = &head;
while (cur != NULL && cur->upper_layer_id != sdu_id) {
prev = cur;
cur = cur->next;
}
/* if sdu_id not found or some bytes have already been 'PDU-ized'
* then do nothing
*/
if (cur == NULL || cur->next_byte != 0)
return;
/* remove SDU from tx_list */
prev->next = cur->next;
entity->tx_list = head.next;
if (entity->tx_end == cur) {
if (prev != &head)
entity->tx_end = prev;
else
entity->tx_end = NULL;
}
rlc_free_sdu(cur);
}
static void free_pdu_segment_list(rlc_tx_pdu_segment_t *l)
{
rlc_tx_pdu_segment_t *cur;
while (l != NULL) {
cur = l;
l = l->next;
rlc_tx_free_pdu(cur);
}
}
static void clear_entity(rlc_entity_am_t *entity)
{
rlc_rx_pdu_segment_t *cur_rx;
rlc_sdu_t *cur_tx;
entity->vr_r = 0;
entity->vr_x = 0;
entity->vr_ms = 0;
entity->vr_h = 0;
entity->status_triggered = 0;
entity->vt_a = 0;
entity->vt_s = 0;
entity->poll_sn = 0;
entity->pdu_without_poll = 0;
entity->byte_without_poll = 0;
entity->force_poll = 0;
entity->t_current = 0;
entity->t_reordering_start = 0;
entity->t_status_prohibit_start = 0;
entity->t_poll_retransmit_start = 0;
cur_rx = entity->rx_list;
while (cur_rx != NULL) {
rlc_rx_pdu_segment_t *p = cur_rx;
cur_rx = cur_rx->next;
rlc_rx_free_pdu_segment(p);
}
entity->rx_list = NULL;
entity->rx_size = 0;
memset(&entity->reassemble, 0, sizeof(rlc_am_reassemble_t));
cur_tx = entity->tx_list;
while (cur_tx != NULL) {
rlc_sdu_t *p = cur_tx;
cur_tx = cur_tx->next;
rlc_free_sdu(p);
}
entity->tx_list = NULL;
entity->tx_end = NULL;
entity->tx_size = 0;
free_pdu_segment_list(entity->wait_list);
free_pdu_segment_list(entity->retransmit_list);
free_pdu_segment_list(entity->ack_list);
entity->wait_list = NULL;
entity->retransmit_list = NULL;
entity->ack_list = NULL;
}
void rlc_entity_am_reestablishment(rlc_entity_t *_entity)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
/* 36.322 5.4 says to deliver SDUs if possible.
* Let's not do that, it makes the code simpler.
* TODO: change this behavior if wanted/needed.
*/
clear_entity(entity);
}
void rlc_entity_am_delete(rlc_entity_t *_entity)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
clear_entity(entity);
free(entity);
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef _RLC_ENTITY_AM_H_
#define _RLC_ENTITY_AM_H_
#include <stdint.h>
#include "rlc_entity.h"
#include "rlc_pdu.h"
#include "rlc_sdu.h"
/*
* Here comes some documentation to understand the reassembly
* logic in the code and the fields in the structure rlc_am_reassemble_t.
*
* Inside RLC, we deal with SDUs, PDUs and PDU segments.
* SDUs are packets coming from upper layer.
* A PDU is made of a header and a payload.
* In the payload there are SDUs.
* First SDU and last SDU in a PDU may be incomplete.
* PDU segments exist in case of retransmissions when the MAC
* layer asks for less data than previously, in which case
* only part of the previous PDU is sent.
*
* This is PDU data (just bytes):
* ---------------------------------------------------------
* | PDU data |
* ---------------------------------------------------------
* It contains SDUs, like:
* ---------------------------------------------------------
* | SDU 1 | SDU 2 | [...] | SDU n |
* ---------------------------------------------------------
* SDU 1 may be only the end of an SDU from which previous bytes were
* transmitted in previous PDUs.
* SDU n may be only the start of an SDU, that is more bytes from
* this SDU may be sent in successive PDUs.
*
* At front of the PDU data, we have a header:
* --------------- ---------------------------------------------------------
* | PDU header | | SDU 1 | SDU 2 | [...] | SDU n |
* --------------- ---------------------------------------------------------
* PDU header describes PDU data (most notably lengths).
*
* A PDU segment is a part of a PDU. For example, from this PDU data:
* ---------------------------------------------------------
* | SDU 1 | SDU 2 | [...] | SDU n |
* ---------------------------------------------------------
* We can extract the following PDU segment (data part only):
* ----------------------
* | PDU segment data |
* ----------------------
* This PDU segment would contain the end of SDU 2 above and some SDUs up to,
* let's say SDU x (x is 5 below).
*
* In front of a transmitted PDU segment, we have a header,
* containing the important variable 'so' (segment offset) that gives
* the index of the first byte of the segment in the original PDU.
* -------------- ----------------------
* | seg. header| | PDU segment data |
* -------------- ----------------------
*
* Let's now explain the data structure rlc_am_reassemble_t.
*
* In the structure rlc_am_reassemble_t, the fields fi, e, sn and so
* are coming from the PDU segment header and the semantics is the
* one of the RLC specs.
*
* The currently processed PDU segment is stored in 'start'.
* We have 'start->s->data_offset' and 'start->s->size'.
* start->s->data_offset is the index of the start of the data in the
* PDU segment. That is if the header is of length 3 bytes
* then start->s->data_offset is 3.
* start->s->size is the total length of the PDU segment,
* including header.
* The size of actual data bytes in the PDU segment is thus
* start->s->size - start->s->data_offset.
*
* The field sdu_len is the length of the current SDU being
* processed.
*
* The field sdu_offset is the starting point of the
* current SDU being processed (starting from beginning
* of PDU segment, including header).
*
* The field data_pos is the current read pointer. 0 points to
* the beginning of the PDU segment (including header).
*
* The field pdu_byte points to the current byte in the original
* PDU (not the PDU segment). It starts at 0 when we start
* processing a new PDU (when a new 'sn' is seen) and always
* increases after each byte processed. This is tha variable
* that is used to know if the next PDU segment will be used
* or not and if yes, starting from which data byte (see
* function rlc_am_reassemble_next_segment).
*
* 'so' is important and points to the byte in the original PDU
* that is the first byte of the PDU segment.
*
* For example, let's take this PDU segment data from above:
* ----------------------
* | PDU segment data |
* ----------------------
* Let's say it is decomposed as:
* ----------------------
* |222|33|4444|55555555|
* ----------------------
* It contains SDUs 2, 3, 4, and 5.
* SDU 2 is 3 bytes, SDU 3 is 2 bytes, SDU 4 is 4 bytes, SDU 5 is 8 bytes.
*
* Let's suppose that the original PDU starts with:
* ----------------
* |1111111|222222|
* ----------------
*
* (In this example, in the PDU segment, SDU 2 is not full,
* we only have its end.)
*
* Then 'so' is 13 (SDU 1 is 7 bytes, head of SDU 2 is 6 bytes).
*
* Let's continue with our PDU segment data.
* Let's say we are current processing SDU 4.
* Let's say the read pointer (variable 'data_pos') is there:
* ----------------------
* |222|33|4444|55555555|
* ----------------------
* ^
* read pointer (data_pos)
*
* Then:
* - sdu_len is 4
* - sdu_offset is 5 + [PDU segment header length]
* (it points to the beginning of SDU 4, starting
* from the head of the PDU segment, that is
* 3 bytes for SDU 2, 2 bytes for SDU 3, and the
* PDU segment header length)
* - start->s->data_offset is [PDU segment header length]
* - pdu_byte is 20
* (13 bytes from beginning of original PDU,
* 3 bytes for SDU 2, 2 bytes for SDU 3, then 2 bytes for SDU 4)
* - data_pos = read pointer = 7 + [PDU segment header length]
*
* To finish this description, in the code, a PDU is simply
* seen as a PDU segment with 'so' = 0 (and is_last == 1 (lsf in the specs),
* but this variable is not used by the reassembly logic).
*
* And for [PDU segment header length] we use start->s->data_offset.
*
* To recap, here is an illustration of the various variables
* and what starting point they use. In the figures, the start
* of the variable name is aligned to the byte it refers to.
* + is used to show the starting point.
*
* Let's put the PDU segment back into the original PDU.
* And let's show the values for when the read pointer
* is on the second byte of SDU 4 (as above).
*
* +++++++++++++++ so
* +++++++++++++++++++++++ pdu_byte
* ---------------------------------------------------------
* | SDU 1| SDU 2..222|33|4444|55555555| [...] | SDU n |
* ---------------------------------------------------------
*
* And now the PDU segment with header.
*
*
* ++++ sdu_len
* ++++++++++++++++++++++ sdu_offset
* +++++++++++++++++++++++ data_pos
* +++++++++++++++ start->s->data_offset
* +++++++++++++++++++++++++++++++++++++ start->s->size
* -------------- ----------------------
* | seg. header| |222|33|4444|55555555|
* -------------- ----------------------
*
* We see three case for the starting point:
* - start of original PDU (without any header)
* - start of header of current PDU segment
* - start of current SDU (for sdu_len)
*/
typedef struct {
rlc_rx_pdu_segment_t *start; /* start of list */
rlc_rx_pdu_segment_t *end; /* end of list (last element) */
int pos; /* byte to get from current buffer */
char sdu[SDU_MAX]; /* sdu is reassembled here */
int sdu_pos; /* next byte to put in sdu */
/* decoder of current PDU */
rlc_pdu_decoder_t dec;
int fi;
int e;
int sn;
int so;
int sdu_len;
int sdu_offset;
int data_pos;
int pdu_byte;
} rlc_am_reassemble_t;
typedef struct {
rlc_entity_t common;
/* configuration */
int t_reordering;
int t_status_prohibit;
int t_poll_retransmit;
int poll_pdu; /* -1 means infinity */
int poll_byte; /* -1 means infinity */
int max_retx_threshold;
/* runtime rx */
int vr_r;
int vr_x;
int vr_ms;
int vr_h;
int status_triggered;
/* runtime tx */
int vt_a;
int vt_s;
int poll_sn;
int pdu_without_poll;
int byte_without_poll;
int force_poll;
/* set to the latest know time by the user of the module. Unit: ms */
uint64_t t_current;
/* timers (stores the TTI of activation, 0 means not active) */
uint64_t t_reordering_start;
uint64_t t_status_prohibit_start;
uint64_t t_poll_retransmit_start;
/* rx management */
rlc_rx_pdu_segment_t *rx_list;
int rx_size;
int rx_maxsize;
/* reassembly management */
rlc_am_reassemble_t reassemble;
/* tx management */
rlc_sdu_t *tx_list;
rlc_sdu_t *tx_end;
int tx_size;
int tx_maxsize;
rlc_tx_pdu_segment_t *wait_list;
rlc_tx_pdu_segment_t *retransmit_list;
rlc_tx_pdu_segment_t *ack_list;
} rlc_entity_am_t;
void rlc_entity_am_recv_sdu(rlc_entity_t *entity, char *buffer, int size,
int sdu_id);
void rlc_entity_am_recv_pdu(rlc_entity_t *entity, char *buffer, int size);
rlc_entity_buffer_status_t rlc_entity_am_buffer_status(
rlc_entity_t *entity, int maxsize);
int rlc_entity_am_generate_pdu(rlc_entity_t *entity, char *buffer, int size);
void rlc_entity_am_set_time(rlc_entity_t *entity, uint64_t now);
void rlc_entity_am_discard_sdu(rlc_entity_t *entity, int sdu_id);
void rlc_entity_am_reestablishment(rlc_entity_t *entity);
void rlc_entity_am_delete(rlc_entity_t *entity);
#endif /* _RLC_ENTITY_AM_H_ */
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include "rlc_entity_um.h"
#include "rlc_pdu.h"
#include <stdlib.h>
#include <string.h>
#include "LOG/log.h"
/*************************************************************************/
/* PDU RX functions */
/*************************************************************************/
static int modulus_rx(rlc_entity_um_t *entity, int a)
{
/* as per 36.322 7.1, modulus base is vr(uh)-window_size and modulus is
* 2^sn_field_length (which is 'sn_modulus' in rlc_entity_um_t)
*/
int r = a - (entity->vr_uh - entity->window_size);
if (r < 0) r += entity->sn_modulus;
return r % entity->sn_modulus;
}
static int sn_compare_rx(void *_entity, int a, int b)
{
rlc_entity_um_t *entity = _entity;
return modulus_rx(entity, a) - modulus_rx(entity, b);
}
static int sn_in_recv_window(void *_entity, int sn)
{
rlc_entity_um_t *entity = _entity;
int mod_sn = modulus_rx(entity, sn);
/* we simplify (VR(UH) - UM_Window_Size) <= SN < VR(UH), base is
* (VR(UH) - UM_Window_Size) and VR(UH) = base + window_size
*/
return mod_sn < entity->window_size;
}
/* return 1 if a PDU with SN == 'sn' is in the rx list, 0 otherwise */
static int rlc_um_pdu_received(rlc_entity_um_t *entity, int sn)
{
rlc_rx_pdu_segment_t *cur = entity->rx_list;
while (cur != NULL) {
if (cur->sn == sn)
return 1;
cur = cur->next;
}
return 0;
}
static int less_than_vr_ur(rlc_entity_um_t *entity, int sn)
{
return sn_compare_rx(entity, sn, entity->vr_ur) < 0;
}
static int outside_of_reordering_window(rlc_entity_um_t *entity, int sn)
{
return !sn_in_recv_window(entity, sn);
}
static int less_than_vr_uh(rlc_entity_um_t *entity, int sn)
{
return sn_compare_rx(entity, sn, entity->vr_uh) < 0;
}
static void rlc_um_reassemble_pdu(rlc_entity_um_t *entity,
rlc_rx_pdu_segment_t *pdu)
{
rlc_um_reassemble_t *r = &entity->reassemble;
int fi;
int e;
int sn;
int data_pos;
int sdu_len;
int sdu_offset;
sdu_offset = pdu->data_offset;
rlc_pdu_decoder_init(&r->dec, pdu->data, pdu->size);
if (entity->sn_field_length == 10)
rlc_pdu_decoder_get_bits(&r->dec, 3);
fi = rlc_pdu_decoder_get_bits(&r->dec, 2);
e = rlc_pdu_decoder_get_bits(&r->dec, 1);
sn = rlc_pdu_decoder_get_bits(&r->dec, entity->sn_field_length);
if (e) {
e = rlc_pdu_decoder_get_bits(&r->dec, 1);
sdu_len = rlc_pdu_decoder_get_bits(&r->dec, 11);
} else
sdu_len = pdu->size - sdu_offset;
/* discard current SDU being reassembled if bad SN or bad FI */
if (sn != (r->sn + 1) % entity->sn_modulus ||
!(fi & 0x02)) {
if (r->sdu_pos)
LOG_D(RLC, "%s:%d:%s: warning: discard partially reassembled SDU\n",
__FILE__, __LINE__, __FUNCTION__);
r->sdu_pos = 0;
}
/* if the head of the SDU is missing, still process the PDU
* but remember to discard the reassembled SDU later on (the
* head has not been received).
* The head is missing if sdu_pos == 0 and fi says the PDU does not
* start an SDU.
*/
if (r->sdu_pos == 0 && (fi & 0x02))
r->sdu_head_missing = 1;
r->sn = sn;
data_pos = pdu->data_offset;
while (1) {
if (r->sdu_pos >= SDU_MAX) {
/* TODO: proper error handling (discard PDUs with current sn from
* reassembly queue? something else?)
*/
LOG_E(RLC, "%s:%d:%s: bad RLC PDU\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
r->sdu[r->sdu_pos] = pdu->data[data_pos];
r->sdu_pos++;
data_pos++;
if (data_pos == sdu_offset + sdu_len) {
/* all bytes of SDU are consumed, check if SDU is fully there.
* It is if the data pointer is not at the end of the PDU segment
* or if 'fi' & 1 == 0
*/
if (data_pos != pdu->size || (fi & 1) == 0) {
/* time to discard the SDU if we didn't receive the head */
if (r->sdu_head_missing) {
LOG_D(RLC, "%s:%d:%s: warning: discard SDU, head not received\n",
__FILE__, __LINE__, __FUNCTION__);
r->sdu_head_missing = 0;
} else {
/* SDU is full - deliver to higher layer */
entity->common.deliver_sdu(entity->common.deliver_sdu_data,
(rlc_entity_t *)entity,
r->sdu, r->sdu_pos);
}
r->sdu_pos = 0;
}
/* done with PDU? */
if (data_pos == pdu->size)
break;
/* not at the end of PDU, process next SDU */
sdu_offset += sdu_len;
if (e) {
e = rlc_pdu_decoder_get_bits(&r->dec, 1);
sdu_len = rlc_pdu_decoder_get_bits(&r->dec, 11);
} else
sdu_len = pdu->size - sdu_offset;
}
}
}
static void rlc_um_reassemble(rlc_entity_um_t *entity,
int (*check_sn)(rlc_entity_um_t *entity, int sn))
{
rlc_rx_pdu_segment_t *cur;
/* process all PDUs from head of rx list until all is processed or
* the SN is not valid anymore with respect to 'check_sn'
*/
while (entity->rx_list != NULL && check_sn(entity, entity->rx_list->sn)) {
cur = entity->rx_list;
rlc_um_reassemble_pdu(entity, cur);
entity->rx_size -= cur->size;
entity->rx_list = cur->next;
rlc_rx_free_pdu_segment(cur);
}
}
static void rlc_um_reception_actions(rlc_entity_um_t *entity,
rlc_rx_pdu_segment_t *pdu_segment)
{
if (!sn_in_recv_window(entity, pdu_segment->sn)) {
entity->vr_uh = (pdu_segment->sn + 1) % entity->sn_modulus;
rlc_um_reassemble(entity, outside_of_reordering_window);
if (!sn_in_recv_window(entity, entity->vr_ur))
entity->vr_ur = (entity->vr_uh - entity->window_size
+ entity->sn_modulus) % entity->sn_modulus;
}
if (rlc_um_pdu_received(entity, entity->vr_ur)) {
do {
entity->vr_ur = (entity->vr_ur + 1) % entity->sn_modulus;
} while (rlc_um_pdu_received(entity, entity->vr_ur));
rlc_um_reassemble(entity, less_than_vr_ur);
}
if (entity->t_reordering_start) {
if (sn_compare_rx(entity, entity->vr_ux, entity->vr_ur) <= 0 ||
(!sn_in_recv_window(entity, entity->vr_ux) &&
entity->vr_ux != entity->vr_uh))
entity->t_reordering_start = 0;
}
if (entity->t_reordering_start == 0) {
if (sn_compare_rx(entity, entity->vr_uh, entity->vr_ur) > 0) {
entity->t_reordering_start = entity->t_current;
entity->vr_ux = entity->vr_uh;
}
}
}
void rlc_entity_um_recv_pdu(rlc_entity_t *_entity, char *buffer, int size)
{
#define R(d) do { if (rlc_pdu_decoder_in_error(&d)) goto err; } while (0)
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
rlc_pdu_decoder_t decoder;
rlc_pdu_decoder_t data_decoder;
int e;
int sn;
int data_e;
int data_li;
int packet_count;
int data_size;
int data_start;
int indicated_data_size;
rlc_rx_pdu_segment_t *pdu_segment;
rlc_pdu_decoder_init(&decoder, buffer, size);
if (entity->sn_field_length == 10) {
rlc_pdu_decoder_get_bits(&decoder, 3); R(decoder); /* R1 */
}
rlc_pdu_decoder_get_bits(&decoder, 2); R(decoder); /* FI */
e = rlc_pdu_decoder_get_bits(&decoder, 1); R(decoder);
sn = rlc_pdu_decoder_get_bits(&decoder, entity->sn_field_length); R(decoder);
/* dicard PDU if rx buffer is full */
if (entity->rx_size + size > entity->rx_maxsize) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, RX buffer full\n",
__FILE__, __LINE__, __FUNCTION__);
return;
}
/* discard according to 36.322 5.1.2.2.2 */
if ((sn_compare_rx(entity, entity->vr_ur, sn) < 0 &&
sn_compare_rx(entity, sn, entity->vr_uh) < 0 &&
rlc_um_pdu_received(entity, sn)) ||
(sn_compare_rx(entity, entity->vr_uh - entity->window_size, sn) <= 0 &&
sn_compare_rx(entity, sn, entity->vr_ur) < 0)) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU (sn %d vr(ur) %d vr(uh) %d)\n",
__FILE__, __LINE__, __FUNCTION__,
sn, entity->vr_ur, entity->vr_uh);
return;
}
packet_count = 1;
/* go to start of data */
indicated_data_size = 0;
data_decoder = decoder;
data_e = e;
while (data_e) {
data_e = rlc_pdu_decoder_get_bits(&data_decoder, 1); R(data_decoder);
data_li = rlc_pdu_decoder_get_bits(&data_decoder, 11); R(data_decoder);
if (data_li == 0) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, li == 0\n",
__FILE__, __LINE__, __FUNCTION__);
return;
}
indicated_data_size += data_li;
packet_count++;
}
rlc_pdu_decoder_align(&data_decoder);
data_start = data_decoder.byte;
data_size = size - data_start;
if (data_size <= 0) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, wrong data size (sum of LI %d data size %d)\n",
__FILE__, __LINE__, __FUNCTION__,
indicated_data_size, data_size);
return;
}
if (indicated_data_size >= data_size) {
LOG_D(RLC, "%s:%d:%s: warning: discard PDU, bad LIs (sum of LI %d data size %d)\n",
__FILE__, __LINE__, __FUNCTION__,
indicated_data_size, data_size);
return;
}
/* put in pdu reception list */
entity->rx_size += size;
pdu_segment = rlc_rx_new_pdu_segment(sn, 0, size, 1, buffer, data_start);
entity->rx_list = rlc_rx_pdu_segment_list_add(sn_compare_rx, entity,
entity->rx_list, pdu_segment);
/* do reception actions (36.322 5.1.2.2.3) */
rlc_um_reception_actions(entity, pdu_segment);
return;
err:
LOG_D(RLC, "%s:%d:%s: error decoding PDU, discarding\n", __FILE__, __LINE__, __FUNCTION__);
#undef R
}
/*************************************************************************/
/* TX functions */
/*************************************************************************/
typedef struct {
int sdu_count;
int data_size;
int header_size;
int last_sdu_is_full;
int first_sdu_length;
} tx_pdu_size_t;
static int header_size(int sn_field_length, int sdu_count)
{
int bits = 8 + 8 * (sn_field_length == 10) + 12 * (sdu_count - 1);
/* padding if we have to */
return (bits + 7) / 8;
}
static tx_pdu_size_t tx_pdu_size(rlc_entity_um_t *entity, int maxsize)
{
tx_pdu_size_t ret;
int sdu_count;
int sdu_size;
int pdu_data_size;
rlc_sdu_t *sdu;
ret.sdu_count = 0;
ret.data_size = 0;
ret.header_size = 0;
ret.last_sdu_is_full = 1;
ret.first_sdu_length = 0;
/* TX PDU - let's make the biggest PDU we can with the SDUs we have */
sdu_count = 0;
pdu_data_size = 0;
sdu = entity->tx_list;
while (sdu != NULL) {
int new_header_size = header_size(entity->sn_field_length, sdu_count+1);
/* if we cannot put new header + at least 1 byte of data then over */
if (new_header_size + pdu_data_size >= maxsize)
break;
sdu_count++;
/* only include the bytes of this SDU not included in PDUs already */
sdu_size = sdu->size - sdu->next_byte;
/* don't feed more than 'maxsize' bytes */
if (new_header_size + pdu_data_size + sdu_size > maxsize) {
sdu_size = maxsize - new_header_size - pdu_data_size;
ret.last_sdu_is_full = 0;
}
if (sdu_count == 1)
ret.first_sdu_length = sdu_size;
pdu_data_size += sdu_size;
/* if we put more than 2^11-1 bytes then the LI field cannot be used,
* so this is the last SDU we can put
*/
if (sdu_size > 2047)
break;
sdu = sdu->next;
}
if (sdu_count) {
ret.sdu_count = sdu_count;
ret.data_size = pdu_data_size;
ret.header_size = header_size(entity->sn_field_length, sdu_count);
}
return ret;
}
rlc_entity_buffer_status_t rlc_entity_um_buffer_status(
rlc_entity_t *_entity, int maxsize)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
rlc_entity_buffer_status_t ret;
tx_pdu_size_t tx_size;
ret.status_size = 0;
/* todo: if an SDU has size >2047 in the tx list then processing
* stops and computed size will not be accurate. Change the computation
* to be more accurate (if needed).
*/
tx_size = tx_pdu_size(entity, maxsize);
ret.tx_size = tx_size.data_size + tx_size.header_size;
ret.retx_size = 0;
return ret;
}
int rlc_entity_um_generate_pdu(rlc_entity_t *_entity, char *buffer, int size)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
tx_pdu_size_t pdu_size;
rlc_sdu_t *sdu;
int i;
int cursize;
int first_sdu_full;
int last_sdu_full;
rlc_pdu_encoder_t encoder;
int fi;
int e;
int li;
char *out;
int outpos;
int first_sdu_start_byte;
int sdu_start_byte;
pdu_size = tx_pdu_size(entity, size);
if (pdu_size.sdu_count == 0)
return 0;
sdu = entity->tx_list;
first_sdu_start_byte = sdu->next_byte;
/* reserve SDU bytes */
cursize = 0;
for (i = 0; i < pdu_size.sdu_count; i++, sdu = sdu->next) {
int sdu_size = sdu->size - sdu->next_byte;
if (cursize + sdu_size > pdu_size.data_size)
sdu_size = pdu_size.data_size - cursize;
sdu->next_byte += sdu_size;
cursize += sdu_size;
}
first_sdu_full = first_sdu_start_byte == 0;
last_sdu_full = pdu_size.last_sdu_is_full;
/* generate header */
rlc_pdu_encoder_init(&encoder, buffer, size);
if (entity->sn_field_length == 10)
rlc_pdu_encoder_put_bits(&encoder, 0, 3); /* R1 */
fi = 0;
if (!first_sdu_full)
fi |= 0x02;
if (!last_sdu_full)
fi |= 0x01;
rlc_pdu_encoder_put_bits(&encoder, fi, 2); /* FI */
/* see the AM code to understand the logic for Es and LIs */
if (pdu_size.sdu_count >= 2)
e = 1;
else
e = 0;
rlc_pdu_encoder_put_bits(&encoder, e, 1); /* E */
if (entity->sn_field_length == 10)
rlc_pdu_encoder_put_bits(&encoder, entity->vt_us, 10); /* SN */
else
rlc_pdu_encoder_put_bits(&encoder, entity->vt_us, 5); /* SN */
/* put LIs */
sdu = entity->tx_list;
/* first SDU */
li = pdu_size.first_sdu_length;
/* put E+LI only if at least 2 SDUs */
if (pdu_size.sdu_count >= 2) {
/* E is 1 if at least 3 SDUs */
if (pdu_size.sdu_count >= 3)
e = 1;
else
e = 0;
rlc_pdu_encoder_put_bits(&encoder, e, 1); /* E */
rlc_pdu_encoder_put_bits(&encoder, li, 11); /* LI */
}
/* next SDUs, but not the last (no LI for the last) */
sdu = sdu->next;
for (i = 2; i < pdu_size.sdu_count; i++, sdu = sdu->next) {
if (i != pdu_size.sdu_count - 1)
e = 1;
else
e = 0;
li = sdu->size;
rlc_pdu_encoder_put_bits(&encoder, e, 1); /* E */
rlc_pdu_encoder_put_bits(&encoder, li, 11); /* LI */
}
rlc_pdu_encoder_align(&encoder);
/* generate data */
out = buffer + pdu_size.header_size;
sdu = entity->tx_list;
sdu_start_byte = first_sdu_start_byte;
outpos = 0;
for (i = 0; i < pdu_size.sdu_count; i++, sdu = sdu->next) {
li = sdu->size - sdu_start_byte;
if (outpos + li >= pdu_size.data_size)
li = pdu_size.data_size - outpos;
memcpy(out+outpos, sdu->data + sdu_start_byte, li);
outpos += li;
sdu_start_byte = 0;
}
/* cleanup sdu list */
while (entity->tx_list != NULL &&
entity->tx_list->size == entity->tx_list->next_byte) {
rlc_sdu_t *c = entity->tx_list;
/* release SDU bytes */
entity->tx_size -= c->size;
entity->tx_list = c->next;
rlc_free_sdu(c);
}
if (entity->tx_list == NULL)
entity->tx_end = NULL;
/* update VT(US) */
entity->vt_us = (entity->vt_us + 1) % entity->sn_modulus;
return pdu_size.header_size + pdu_size.data_size;
}
/*************************************************************************/
/* SDU RX functions */
/*************************************************************************/
void rlc_entity_um_recv_sdu(rlc_entity_t *_entity, char *buffer, int size,
int sdu_id)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
rlc_sdu_t *sdu;
if (size > SDU_MAX) {
LOG_E(RLC, "%s:%d:%s: fatal: SDU size too big (%d bytes)\n",
__FILE__, __LINE__, __FUNCTION__, size);
exit(1);
}
if (entity->tx_size + size > entity->tx_maxsize) {
LOG_D(RLC, "%s:%d:%s: warning: SDU rejected, SDU buffer full\n",
__FILE__, __LINE__, __FUNCTION__);
return;
}
entity->tx_size += size;
sdu = rlc_new_sdu(buffer, size, sdu_id);
rlc_sdu_list_add(&entity->tx_list, &entity->tx_end, sdu);
}
/*************************************************************************/
/* time/timers */
/*************************************************************************/
static void check_t_reordering(rlc_entity_um_t *entity)
{
int sn;
/* is t_reordering running and if yes has it expired? */
if (entity->t_reordering_start == 0 ||
entity->t_current <= entity->t_reordering_start + entity->t_reordering)
return;
/* stop timer */
entity->t_reordering_start = 0;
LOG_D(RLC, "%s:%d:%s: t_reordering expired\n", __FILE__, __LINE__, __FUNCTION__);
/* update VR(UR) to first SN >= VR(UX) of PDU not received
*/
sn = entity->vr_ux;
while (rlc_um_pdu_received(entity, sn))
sn = (sn + 1) % entity->sn_modulus;
entity->vr_ur = sn;
rlc_um_reassemble(entity, less_than_vr_ur);
if (sn_compare_rx(entity, entity->vr_uh, entity->vr_ur) > 0) {
entity->t_reordering_start = entity->t_current;
entity->vr_ux = entity->vr_uh;
}
}
void rlc_entity_um_set_time(rlc_entity_t *_entity, uint64_t now)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
entity->t_current = now;
check_t_reordering(entity);
}
/*************************************************************************/
/* discard/re-establishment/delete */
/*************************************************************************/
void rlc_entity_um_discard_sdu(rlc_entity_t *_entity, int sdu_id)
{
/* implements 36.322 5.3 */
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
rlc_sdu_t head;
rlc_sdu_t *cur;
rlc_sdu_t *prev;
head.next = entity->tx_list;
cur = entity->tx_list;
prev = &head;
while (cur != NULL && cur->upper_layer_id != sdu_id) {
prev = cur;
cur = cur->next;
}
/* if sdu_id not found or some bytes have already been 'PDU-ized'
* then do nothing
*/
if (cur == NULL || cur->next_byte != 0)
return;
/* remove SDU from tx_list */
prev->next = cur->next;
entity->tx_list = head.next;
if (entity->tx_end == cur) {
if (prev != &head)
entity->tx_end = prev;
else
entity->tx_end = NULL;
}
rlc_free_sdu(cur);
}
static void clear_entity(rlc_entity_um_t *entity)
{
rlc_rx_pdu_segment_t *cur_rx;
rlc_sdu_t *cur_tx;
entity->vr_ur = 0;
entity->vr_ux = 0;
entity->vr_uh = 0;
entity->vt_us = 0;
entity->t_current = 0;
entity->t_reordering_start = 0;
cur_rx = entity->rx_list;
while (cur_rx != NULL) {
rlc_rx_pdu_segment_t *p = cur_rx;
cur_rx = cur_rx->next;
rlc_rx_free_pdu_segment(p);
}
entity->rx_list = NULL;
entity->rx_size = 0;
memset(&entity->reassemble, 0, sizeof(rlc_um_reassemble_t));
cur_tx = entity->tx_list;
while (cur_tx != NULL) {
rlc_sdu_t *p = cur_tx;
cur_tx = cur_tx->next;
rlc_free_sdu(p);
}
entity->tx_list = NULL;
entity->tx_end = NULL;
entity->tx_size = 0;
}
void rlc_entity_um_reestablishment(rlc_entity_t *_entity)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
rlc_um_reassemble(entity, less_than_vr_uh);
clear_entity(entity);
}
void rlc_entity_um_delete(rlc_entity_t *_entity)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
clear_entity(entity);
free(entity);
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef _RLC_ENTITY_UM_H_
#define _RLC_ENTITY_UM_H_
#include "rlc_entity.h"
#include "rlc_pdu.h"
#include "rlc_sdu.h"
typedef struct {
char sdu[SDU_MAX]; /* sdu is reassembled here */
int sdu_pos; /* next byte to put in sdu */
/* decoder of current PDU */
rlc_pdu_decoder_t dec;
int sn;
int sdu_head_missing;
} rlc_um_reassemble_t;
typedef struct {
rlc_entity_t common;
/* configuration */
int t_reordering;
int sn_field_length;
int sn_modulus; /* 1024 for sn_field_length == 10, 32 for 5 */
int window_size; /* 512 for sn_field_length == 10, 16 for 5 */
/* runtime rx */
int vr_ur;
int vr_ux;
int vr_uh;
/* runtime tx */
int vt_us;
/* set to the latest know time by the user of the module. Unit: ms */
uint64_t t_current;
/* timers (stores the TTI of activation, 0 means not active) */
uint64_t t_reordering_start;
/* rx management */
rlc_rx_pdu_segment_t *rx_list;
int rx_size;
int rx_maxsize;
/* reassembly management */
rlc_um_reassemble_t reassemble;
/* tx management */
rlc_sdu_t *tx_list;
rlc_sdu_t *tx_end;
int tx_size;
int tx_maxsize;
} rlc_entity_um_t;
void rlc_entity_um_recv_sdu(rlc_entity_t *_entity, char *buffer, int size,
int sdu_id);
void rlc_entity_um_recv_pdu(rlc_entity_t *entity, char *buffer, int size);
rlc_entity_buffer_status_t rlc_entity_um_buffer_status(
rlc_entity_t *entity, int maxsize);
int rlc_entity_um_generate_pdu(rlc_entity_t *_entity, char *buffer, int size);
void rlc_entity_um_set_time(rlc_entity_t *entity, uint64_t now);
void rlc_entity_um_discard_sdu(rlc_entity_t *entity, int sdu_id);
void rlc_entity_um_reestablishment(rlc_entity_t *entity);
void rlc_entity_um_delete(rlc_entity_t *entity);
#endif /* _RLC_ENTITY_UM_H_ */
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
/* from openair */
#include "rlc.h"
#include "pdcp.h"
/* from new rlc module */
#include "asn1_utils.h"
#include "rlc_ue_manager.h"
#include "rlc_entity.h"
#include <stdint.h>
static rlc_ue_manager_t *rlc_ue_manager;
/* TODO: handle time a bit more properly */
static uint64_t rlc_current_time;
static int rlc_current_time_last_frame;
static int rlc_current_time_last_subframe;
void mac_rlc_data_ind (
const module_id_t module_idP,
const rnti_t rntiP,
const eNB_index_t eNB_index,
const frame_t frameP,
const eNB_flag_t enb_flagP,
const MBMS_flag_t MBMS_flagP,
const logical_chan_id_t channel_idP,
char *buffer_pP,
const tb_size_t tb_sizeP,
num_tb_t num_tbP,
crc_t *crcs_pP)
{
rlc_ue_t *ue;
rlc_entity_t *rb;
int rnti;
int channel_id;
if (enb_flagP == 1 && module_idP != 0) {
LOG_E(RLC, "%s:%d:%s: fatal, module_id must be 0 for eNB\n",
__FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if (/*module_idP != 0 ||*/ eNB_index != 0 /*|| enb_flagP != 1 || MBMS_flagP != 0*/) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if (enb_flagP)
T(T_ENB_RLC_MAC_UL, T_INT(module_idP), T_INT(rntiP),
T_INT(channel_idP), T_INT(tb_sizeP));
/* TODO: better handle mbms, maybe we should not change rnti here */
if (!enb_flagP && MBMS_flagP) {
rnti = 0xfffd;
/* TODO: handle channel_id properly */
if (channel_idP != 5) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
channel_id = 7;
} else {
rnti = rntiP;
channel_id = channel_idP;
}
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rnti);
switch (channel_id) {
case 1 ... 2: rb = ue->srb[channel_id - 1]; break;
case 3 ... 7: rb = ue->drb[channel_id - 3]; break;
default: rb = NULL; break;
}
if (rb != NULL) {
rb->set_time(rb, rlc_current_time);
rb->recv_pdu(rb, buffer_pP, tb_sizeP);
} else {
LOG_E(RLC, "%s:%d:%s: fatal: no RB found (rnti %d channel ID %d)\n",
__FILE__, __LINE__, __FUNCTION__, rnti, channel_id);
exit(1);
}
rlc_manager_unlock(rlc_ue_manager);
}
tbs_size_t mac_rlc_data_req(
const module_id_t module_idP,
const rnti_t rntiP,
const eNB_index_t eNB_index,
const frame_t frameP,
const eNB_flag_t enb_flagP,
const MBMS_flag_t MBMS_flagP,
const logical_chan_id_t channel_idP,
const tb_size_t tb_sizeP,
char *buffer_pP,
const uint32_t sourceL2Id,
const uint32_t destinationL2Id
)
{
int ret;
rlc_ue_t *ue;
rlc_entity_t *rb;
int maxsize;
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rntiP);
switch (channel_idP) {
case 1 ... 2: rb = ue->srb[channel_idP - 1]; break;
case 3 ... 7: rb = ue->drb[channel_idP - 3]; break;
default: rb = NULL; break;
}
if (MBMS_flagP == MBMS_FLAG_YES) {
if (channel_idP >= 1 && channel_idP <= 5)
rb = ue->drb[channel_idP - 1];
else
rb = NULL;
}
if (rb != NULL) {
rb->set_time(rb, rlc_current_time);
maxsize = tb_sizeP;
ret = rb->generate_pdu(rb, buffer_pP, maxsize);
} else {
LOG_E(RLC, "%s:%d:%s: fatal: data req for unknown RB\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
ret = 0;
}
rlc_manager_unlock(rlc_ue_manager);
if (enb_flagP)
T(T_ENB_RLC_MAC_DL, T_INT(module_idP), T_INT(rntiP),
T_INT(channel_idP), T_INT(ret));
return ret;
}
mac_rlc_status_resp_t mac_rlc_status_ind(
const module_id_t module_idP,
const rnti_t rntiP,
const eNB_index_t eNB_index,
const frame_t frameP,
const sub_frame_t subframeP,
const eNB_flag_t enb_flagP,
const MBMS_flag_t MBMS_flagP,
const logical_chan_id_t channel_idP,
const uint32_t sourceL2Id,
const uint32_t destinationL2Id
)
{
rlc_ue_t *ue;
mac_rlc_status_resp_t ret;
rlc_entity_t *rb;
/* TODO: handle time a bit more properly */
if (rlc_current_time_last_frame != frameP ||
rlc_current_time_last_subframe != subframeP) {
rlc_current_time++;
rlc_current_time_last_frame = frameP;
rlc_current_time_last_subframe = subframeP;
}
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rntiP);
switch (channel_idP) {
case 1 ... 2: rb = ue->srb[channel_idP - 1]; break;
case 3 ... 7: rb = ue->drb[channel_idP - 3]; break;
default: rb = NULL; break;
}
if (MBMS_flagP == MBMS_FLAG_YES) {
if (channel_idP >= 1 && channel_idP <= 5)
rb = ue->drb[channel_idP - 1];
else
rb = NULL;
}
if (rb != NULL) {
rlc_entity_buffer_status_t buf_stat;
rb->set_time(rb, rlc_current_time);
/* 36.321 deals with BSR values up to 3000000 bytes, after what it
* reports '> 3000000' (table 6.1.3.1-2). Passing 4000000 is thus
* more than enough.
*/
buf_stat = rb->buffer_status(rb, 4000000);
ret.bytes_in_buffer = buf_stat.status_size
+ buf_stat.retx_size
+ buf_stat.tx_size;
} else {
ret.bytes_in_buffer = 0;
}
rlc_manager_unlock(rlc_ue_manager);
ret.pdus_in_buffer = 0;
/* TODO: creation time may be important (unit: frame, as it seems) */
ret.head_sdu_creation_time = 0;
ret.head_sdu_remaining_size_to_send = 0;
ret.head_sdu_is_segmented = 0;
return ret;
}
rlc_buffer_occupancy_t mac_rlc_get_buffer_occupancy_ind(
const module_id_t module_idP,
const rnti_t rntiP,
const eNB_index_t eNB_index,
const frame_t frameP,
const sub_frame_t subframeP,
const eNB_flag_t enb_flagP,
const logical_chan_id_t channel_idP)
{
rlc_ue_t *ue;
rlc_buffer_occupancy_t ret;
rlc_entity_t *rb;
if (enb_flagP) {
LOG_E(RLC, "Tx mac_rlc_get_buffer_occupancy_ind function is not implemented for eNB LcId=%u\n", channel_idP);
exit(1);
}
/* TODO: handle time a bit more properly */
if (rlc_current_time_last_frame != frameP ||
rlc_current_time_last_subframe != subframeP) {
rlc_current_time++;
rlc_current_time_last_frame = frameP;
rlc_current_time_last_subframe = subframeP;
}
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rntiP);
switch (channel_idP) {
case 1 ... 2: rb = ue->srb[channel_idP - 1]; break;
case 3 ... 7: rb = ue->drb[channel_idP - 3]; break;
default: rb = NULL; break;
}
if (rb != NULL) {
rlc_entity_buffer_status_t buf_stat;
rb->set_time(rb, rlc_current_time);
/* 36.321 deals with BSR values up to 3000000 bytes, after what it
* reports '> 3000000' (table 6.1.3.1-2). Passing 4000000 is thus
* more than enough.
*/
buf_stat = rb->buffer_status(rb, 4000000);
ret = buf_stat.status_size
+ buf_stat.retx_size
+ buf_stat.tx_size;
} else {
ret = 0;
}
rlc_manager_unlock(rlc_ue_manager);
return ret;
}
int oai_emulation;
rlc_op_status_t rlc_data_req (const protocol_ctxt_t *const ctxt_pP,
const srb_flag_t srb_flagP,
const MBMS_flag_t MBMS_flagP,
const rb_id_t rb_idP,
const mui_t muiP,
confirm_t confirmP,
sdu_size_t sdu_sizeP,
mem_block_t *sdu_pP,
const uint32_t *const sourceL2Id,
const uint32_t *const destinationL2Id
)
{
int rnti = ctxt_pP->rnti;
rlc_ue_t *ue;
rlc_entity_t *rb;
if (MBMS_flagP == MBMS_FLAG_YES)
rnti = 0xfffd;
LOG_D(RLC, "%s rnti %d srb_flag %d rb_id %d mui %d confirm %d sdu_size %d MBMS_flag %d\n",
__FUNCTION__, rnti, srb_flagP, (int)rb_idP, muiP, confirmP, sdu_sizeP,
MBMS_flagP);
if (ctxt_pP->enb_flag)
T(T_ENB_RLC_DL, T_INT(ctxt_pP->module_id),
T_INT(ctxt_pP->rnti), T_INT(rb_idP), T_INT(sdu_sizeP));
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rnti);
rb = NULL;
if (srb_flagP) {
if (rb_idP >= 1 && rb_idP <= 2)
rb = ue->srb[rb_idP - 1];
} else {
if (rb_idP >= 1 && rb_idP <= 5)
rb = ue->drb[rb_idP - 1];
}
if( MBMS_flagP == MBMS_FLAG_YES) {
if (rb_idP >= 1 && rb_idP <= 5)
rb = ue->drb[rb_idP - 1];
}
if (rb != NULL) {
rb->set_time(rb, rlc_current_time);
rb->recv_sdu(rb, (char *)sdu_pP->data, sdu_sizeP, muiP);
} else {
LOG_E(RLC, "%s:%d:%s: fatal: SDU sent to unknown RB\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
rlc_manager_unlock(rlc_ue_manager);
free_mem_block(sdu_pP, __func__);
return RLC_OP_STATUS_OK;
}
int rlc_module_init(int enb_flag)
{
static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER;
static int inited = 0;
if (pthread_mutex_lock(&lock)) abort();
if (inited) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
inited = 1;
rlc_ue_manager = new_rlc_ue_manager(enb_flag);
if (pthread_mutex_unlock(&lock)) abort();
return 0;
}
void rlc_util_print_hex_octets(comp_name_t componentP, unsigned char *dataP, const signed long sizeP)
{
}
#include "common/ran_context.h"
extern RAN_CONTEXT_t RC;
static void deliver_sdu(void *_ue, rlc_entity_t *entity, char *buf, int size)
{
rlc_ue_t *ue = _ue;
int is_srb;
int rb_id;
protocol_ctxt_t ctx;
mem_block_t *memblock;
int i;
int is_enb;
int is_mbms;
/* TODO: be sure it's fine to check rnti for MBMS */
is_mbms = ue->rnti == 0xfffd;
/* is it SRB? */
for (i = 0; i < 2; i++) {
if (entity == ue->srb[i]) {
is_srb = 1;
rb_id = i+1;
goto rb_found;
}
}
/* maybe DRB? */
for (i = 0; i < 5; i++) {
if (entity == ue->drb[i]) {
is_srb = 0;
rb_id = i+1;
goto rb_found;
}
}
LOG_E(RLC, "%s:%d:%s: fatal, no RB found for ue %d\n",
__FILE__, __LINE__, __FUNCTION__, ue->rnti);
exit(1);
rb_found:
LOG_D(RLC, "%s:%d:%s: delivering SDU (rnti %d is_srb %d rb_id %d) size %d",
__FILE__, __LINE__, __FUNCTION__, ue->rnti, is_srb, rb_id, size);
memblock = get_free_mem_block(size, __func__);
if (memblock == NULL) {
LOG_E(RLC, "%s:%d:%s: ERROR: get_free_mem_block failed\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
memcpy(memblock->data, buf, size);
/* unused fields? */
ctx.instance = ue->module_id;
ctx.frame = 0;
ctx.subframe = 0;
ctx.eNB_index = 0;
ctx.configured = 1;
ctx.brOption = 0;
/* used fields? */
ctx.module_id = ue->module_id;
ctx.rnti = ue->rnti;
is_enb = rlc_manager_get_enb_flag(rlc_ue_manager);
ctx.enb_flag = is_enb;
if (is_enb) {
T(T_ENB_RLC_UL,
T_INT(0 /*ctxt_pP->module_id*/),
T_INT(ue->rnti), T_INT(rb_id), T_INT(size));
const ngran_node_t type = RC.rrc[0 /*ctxt_pP->module_id*/]->node_type;
AssertFatal(type != ngran_eNB_CU && type != ngran_ng_eNB_CU && type != ngran_gNB_CU,
"Can't be CU, bad node type %d\n", type);
if (NODE_IS_DU(type) && is_srb == 1) {
MessageDef *msg = itti_alloc_new_message(TASK_RLC_ENB, F1AP_UL_RRC_MESSAGE);
F1AP_UL_RRC_MESSAGE(msg).rnti = ue->rnti;
F1AP_UL_RRC_MESSAGE(msg).srb_id = rb_id;
F1AP_UL_RRC_MESSAGE(msg).rrc_container = (unsigned char *)buf;
F1AP_UL_RRC_MESSAGE(msg).rrc_container_length = size;
itti_send_msg_to_task(TASK_DU_F1, ENB_MODULE_ID_TO_INSTANCE(0 /*ctxt_pP->module_id*/), msg);
return;
}
}
if (!get_pdcp_data_ind_func()(&ctx, is_srb, is_mbms, rb_id, size, memblock, NULL, NULL)) {
LOG_E(RLC, "%s:%d:%s: ERROR: pdcp_data_ind failed (is_srb %d rb_id %d rnti %d)\n",
__FILE__, __LINE__, __FUNCTION__,
is_srb, rb_id, ue->rnti);
/* what to do in case of failure? for the moment: nothing */
}
}
static void successful_delivery(void *_ue, rlc_entity_t *entity, int sdu_id)
{
rlc_ue_t *ue = _ue;
int i;
int is_srb;
int rb_id;
MessageDef *msg;
int is_enb;
/* is it SRB? */
for (i = 0; i < 2; i++) {
if (entity == ue->srb[i]) {
is_srb = 1;
rb_id = i+1;
goto rb_found;
}
}
/* maybe DRB? */
for (i = 0; i < 5; i++) {
if (entity == ue->drb[i]) {
is_srb = 0;
rb_id = i+1;
goto rb_found;
}
}
LOG_E(RLC, "%s:%d:%s: fatal, no RB found for ue %d\n",
__FILE__, __LINE__, __FUNCTION__, ue->rnti);
exit(1);
rb_found:
LOG_D(RLC, "sdu %d was successfully delivered on %s %d\n",
sdu_id,
is_srb ? "SRB" : "DRB",
rb_id);
/* TODO: do something for DRBs? */
if (is_srb == 0)
return;
is_enb = rlc_manager_get_enb_flag(rlc_ue_manager);
if (!is_enb)
return;
msg = itti_alloc_new_message(TASK_RLC_ENB, RLC_SDU_INDICATION);
RLC_SDU_INDICATION(msg).rnti = ue->rnti;
RLC_SDU_INDICATION(msg).is_successful = 1;
RLC_SDU_INDICATION(msg).srb_id = rb_id;
RLC_SDU_INDICATION(msg).message_id = sdu_id;
/* TODO: accept more than 1 instance? here we send to instance id 0 */
itti_send_msg_to_task(TASK_RRC_ENB, 0, msg);
}
static void max_retx_reached(void *_ue, rlc_entity_t *entity)
{
rlc_ue_t *ue = _ue;
int i;
int is_srb;
int rb_id;
MessageDef *msg;
int is_enb;
/* is it SRB? */
for (i = 0; i < 2; i++) {
if (entity == ue->srb[i]) {
is_srb = 1;
rb_id = i+1;
goto rb_found;
}
}
/* maybe DRB? */
for (i = 0; i < 5; i++) {
if (entity == ue->drb[i]) {
is_srb = 0;
rb_id = i+1;
goto rb_found;
}
}
LOG_E(RLC, "%s:%d:%s: fatal, no RB found for ue %d\n",
__FILE__, __LINE__, __FUNCTION__, ue->rnti);
exit(1);
rb_found:
LOG_D(RLC, "max RETX reached on %s %d\n",
is_srb ? "SRB" : "DRB",
rb_id);
/* TODO: do something for DRBs? */
if (is_srb == 0)
return;
is_enb = rlc_manager_get_enb_flag(rlc_ue_manager);
if (!is_enb)
return;
msg = itti_alloc_new_message(TASK_RLC_ENB, RLC_SDU_INDICATION);
RLC_SDU_INDICATION(msg).rnti = ue->rnti;
RLC_SDU_INDICATION(msg).is_successful = 0;
RLC_SDU_INDICATION(msg).srb_id = rb_id;
RLC_SDU_INDICATION(msg).message_id = -1;
/* TODO: accept more than 1 instance? here we send to instance id 0 */
itti_send_msg_to_task(TASK_RRC_ENB, 0, msg);
}
static void add_srb(int rnti, int module_id, struct LTE_SRB_ToAddMod *s)
{
rlc_entity_t *rlc_am;
rlc_ue_t *ue;
struct LTE_SRB_ToAddMod__rlc_Config *r = s->rlc_Config;
struct LTE_SRB_ToAddMod__logicalChannelConfig *l = s->logicalChannelConfig;
int srb_id = s->srb_Identity;
int logical_channel_group;
int t_reordering;
int t_status_prohibit;
int t_poll_retransmit;
int poll_pdu;
int poll_byte;
int max_retx_threshold;
if (srb_id != 1 && srb_id != 2) {
LOG_E(RLC, "%s:%d:%s: fatal, bad srb id %d\n",
__FILE__, __LINE__, __FUNCTION__, srb_id);
exit(1);
}
switch (l->present) {
case LTE_SRB_ToAddMod__logicalChannelConfig_PR_explicitValue:
logical_channel_group = *l->choice.explicitValue.ul_SpecificParameters->logicalChannelGroup;
break;
case LTE_SRB_ToAddMod__logicalChannelConfig_PR_defaultValue:
/* default value from 36.331 9.2.1 */
logical_channel_group = 0;
break;
default:
LOG_E(RLC, "%s:%d:%s: fatal error\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
/* TODO: accept other values? */
if (logical_channel_group != 0) {
LOG_E(RLC, "%s:%d:%s: fatal error\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
switch (r->present) {
case LTE_SRB_ToAddMod__rlc_Config_PR_explicitValue: {
struct LTE_RLC_Config__am *am;
if (r->choice.explicitValue.present != LTE_RLC_Config_PR_am) {
LOG_E(RLC, "%s:%d:%s: fatal error, must be RLC AM\n",
__FILE__, __LINE__, __FUNCTION__);
exit(1);
}
am = &r->choice.explicitValue.choice.am;
t_reordering = decode_t_reordering(am->dl_AM_RLC.t_Reordering);
t_status_prohibit = decode_t_status_prohibit(am->dl_AM_RLC.t_StatusProhibit);
t_poll_retransmit = decode_t_poll_retransmit(am->ul_AM_RLC.t_PollRetransmit);
poll_pdu = decode_poll_pdu(am->ul_AM_RLC.pollPDU);
poll_byte = decode_poll_byte(am->ul_AM_RLC.pollByte);
max_retx_threshold = decode_max_retx_threshold(am->ul_AM_RLC.maxRetxThreshold);
break;
}
case LTE_SRB_ToAddMod__rlc_Config_PR_defaultValue:
/* default values from 36.331 9.2.1 */
t_reordering = 35;
t_status_prohibit = 0;
t_poll_retransmit = 45;
poll_pdu = -1;
poll_byte = -1;
max_retx_threshold = 4;
break;
default:
LOG_E(RLC, "%s:%d:%s: fatal error\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rnti);
ue->module_id = module_id;
if (ue->srb[srb_id-1] != NULL) {
LOG_D(RLC, "%s:%d:%s: warning SRB %d already exist for ue %d, do nothing\n",
__FILE__, __LINE__, __FUNCTION__, srb_id, rnti);
} else {
rlc_am = new_rlc_entity_am(100000,
100000,
deliver_sdu, ue,
successful_delivery, ue,
max_retx_reached, ue,
t_reordering, t_status_prohibit,
t_poll_retransmit,
poll_pdu, poll_byte, max_retx_threshold);
rlc_ue_add_srb_rlc_entity(ue, srb_id, rlc_am);
LOG_D(RLC, "%s:%d:%s: added srb %d to ue %d\n",
__FILE__, __LINE__, __FUNCTION__, srb_id, rnti);
}
rlc_manager_unlock(rlc_ue_manager);
}
static void add_drb_am(int rnti, int module_id, struct LTE_DRB_ToAddMod *s)
{
rlc_entity_t *rlc_am;
rlc_ue_t *ue;
struct LTE_RLC_Config *r = s->rlc_Config;
struct LTE_LogicalChannelConfig *l = s->logicalChannelConfig;
int drb_id = s->drb_Identity;
int channel_id = *s->logicalChannelIdentity;
int logical_channel_group;
int t_reordering;
int t_status_prohibit;
int t_poll_retransmit;
int poll_pdu;
int poll_byte;
int max_retx_threshold;
if (!(drb_id >= 1 && drb_id <= 5)) {
LOG_E(RLC, "%s:%d:%s: fatal, bad srb id %d\n",
__FILE__, __LINE__, __FUNCTION__, drb_id);
exit(1);
}
if (channel_id != drb_id + 2) {
LOG_E(RLC, "%s:%d:%s: todo, remove this limitation\n",
__FILE__, __LINE__, __FUNCTION__);
exit(1);
}
logical_channel_group = *l->ul_SpecificParameters->logicalChannelGroup;
/* TODO: accept other values? */
if (logical_channel_group != 1) {
LOG_E(RLC, "%s:%d:%s: fatal error\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
switch (r->present) {
case LTE_RLC_Config_PR_am: {
struct LTE_RLC_Config__am *am;
am = &r->choice.am;
t_reordering = decode_t_reordering(am->dl_AM_RLC.t_Reordering);
t_status_prohibit = decode_t_status_prohibit(am->dl_AM_RLC.t_StatusProhibit);
t_poll_retransmit = decode_t_poll_retransmit(am->ul_AM_RLC.t_PollRetransmit);
poll_pdu = decode_poll_pdu(am->ul_AM_RLC.pollPDU);
poll_byte = decode_poll_byte(am->ul_AM_RLC.pollByte);
max_retx_threshold = decode_max_retx_threshold(am->ul_AM_RLC.maxRetxThreshold);
break;
}
default:
LOG_E(RLC, "%s:%d:%s: fatal error\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rnti);
ue->module_id = module_id;
if (ue->drb[drb_id-1] != NULL) {
LOG_D(RLC, "%s:%d:%s: warning DRB %d already exist for ue %d, do nothing\n",
__FILE__, __LINE__, __FUNCTION__, drb_id, rnti);
} else {
rlc_am = new_rlc_entity_am(1000000,
1000000,
deliver_sdu, ue,
successful_delivery, ue,
max_retx_reached, ue,
t_reordering, t_status_prohibit,
t_poll_retransmit,
poll_pdu, poll_byte, max_retx_threshold);
rlc_ue_add_drb_rlc_entity(ue, drb_id, rlc_am);
LOG_D(RLC, "%s:%d:%s: added drb %d to ue %d\n",
__FILE__, __LINE__, __FUNCTION__, drb_id, rnti);
}
rlc_manager_unlock(rlc_ue_manager);
}
static void add_drb_um(int rnti, int module_id, struct LTE_DRB_ToAddMod *s)
{
rlc_entity_t *rlc_um;
rlc_ue_t *ue;
struct LTE_RLC_Config *r = s->rlc_Config;
struct LTE_LogicalChannelConfig *l = s->logicalChannelConfig;
int drb_id = s->drb_Identity;
int channel_id = *s->logicalChannelIdentity;
int logical_channel_group;
int t_reordering;
int sn_field_length;
if (!(drb_id >= 1 && drb_id <= 5)) {
LOG_E(RLC, "%s:%d:%s: fatal, bad srb id %d\n",
__FILE__, __LINE__, __FUNCTION__, drb_id);
exit(1);
}
if (channel_id != drb_id + 2) {
LOG_E(RLC, "%s:%d:%s: todo, remove this limitation\n",
__FILE__, __LINE__, __FUNCTION__);
exit(1);
}
logical_channel_group = *l->ul_SpecificParameters->logicalChannelGroup;
/* TODO: accept other values? */
if (logical_channel_group != 1) {
LOG_E(RLC, "%s:%d:%s: fatal error\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
switch (r->present) {
case LTE_RLC_Config_PR_um_Bi_Directional: {
struct LTE_RLC_Config__um_Bi_Directional *um;
um = &r->choice.um_Bi_Directional;
t_reordering = decode_t_reordering(um->dl_UM_RLC.t_Reordering);
if (um->dl_UM_RLC.sn_FieldLength != um->ul_UM_RLC.sn_FieldLength) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
sn_field_length = decode_sn_field_length(um->dl_UM_RLC.sn_FieldLength);
break;
}
default:
LOG_E(RLC, "%s:%d:%s: fatal error\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, rnti);
ue->module_id = module_id;
if (ue->drb[drb_id-1] != NULL) {
LOG_D(RLC, "%s:%d:%s: warning DRB %d already exist for ue %d, do nothing\n",
__FILE__, __LINE__, __FUNCTION__, drb_id, rnti);
} else {
rlc_um = new_rlc_entity_um(1000000,
1000000,
deliver_sdu, ue,
t_reordering,
sn_field_length);
rlc_ue_add_drb_rlc_entity(ue, drb_id, rlc_um);
LOG_D(RLC, "%s:%d:%s: added drb %d to ue %d\n",
__FILE__, __LINE__, __FUNCTION__, drb_id, rnti);
}
rlc_manager_unlock(rlc_ue_manager);
}
static void add_drb(int rnti, int module_id, struct LTE_DRB_ToAddMod *s)
{
switch (s->rlc_Config->present) {
case LTE_RLC_Config_PR_am:
add_drb_am(rnti, module_id, s);
break;
case LTE_RLC_Config_PR_um_Bi_Directional:
add_drb_um(rnti, module_id, s);
break;
default:
LOG_E(RLC, "%s:%d:%s: fatal: unhandled DRB type\n",
__FILE__, __LINE__, __FUNCTION__);
exit(1);
}
}
rlc_op_status_t rrc_rlc_config_asn1_req (const protocol_ctxt_t * const ctxt_pP,
const LTE_SRB_ToAddModList_t * const srb2add_listP,
const LTE_DRB_ToAddModList_t * const drb2add_listP,
const LTE_DRB_ToReleaseList_t * const drb2release_listP,
const LTE_PMCH_InfoList_r9_t * const pmch_InfoList_r9_pP,
const uint32_t sourceL2Id,
const uint32_t destinationL2Id
)
{
int rnti = ctxt_pP->rnti;
int module_id = ctxt_pP->module_id;
int i;
int j;
if (ctxt_pP->enb_flag == 1 &&
(ctxt_pP->module_id != 0 || ctxt_pP->instance != 0)) {
LOG_E(RLC, "%s: module_id != 0 or instance != 0 not handled for eNB\n",
__FUNCTION__);
exit(1);
}
if (0 /*||
ctxt_pP->instance != 0 || ctxt_pP->eNB_index != 0 ||
ctxt_pP->configured != 1 || ctxt_pP->brOption != 0 */) {
LOG_E(RLC, "%s: ctxt_pP not handled (%d %d %d %d %d %d)\n", __FUNCTION__,
ctxt_pP->enb_flag , ctxt_pP->module_id, ctxt_pP->instance,
ctxt_pP->eNB_index, ctxt_pP->configured, ctxt_pP->brOption);
exit(1);
}
if (pmch_InfoList_r9_pP != NULL) {
int mbms_rnti = 0xfffd;
LTE_MBMS_SessionInfoList_r9_t *mbms_SessionInfoList_r9_p = NULL;
LTE_MBMS_SessionInfo_r9_t *MBMS_SessionInfo_p = NULL;
mbms_session_id_t mbms_session_id;
mbms_service_id_t mbms_service_id;
rb_id_t drb_id = 0;
logical_chan_id_t lc_id = 0;
//LTE_DRB_Identity_t drb_id = 0;
//LTE_DRB_Identity_t* pdrb_id = NULL;
for (i=0; i<pmch_InfoList_r9_pP->list.count; i++) {
mbms_SessionInfoList_r9_p = &(pmch_InfoList_r9_pP->list.array[i]->mbms_SessionInfoList_r9);
for (j=0; j<mbms_SessionInfoList_r9_p->list.count; j++) {
MBMS_SessionInfo_p = mbms_SessionInfoList_r9_p->list.array[j];
if (0/*MBMS_SessionInfo_p->sessionId_r9*/)
mbms_session_id = MBMS_SessionInfo_p->sessionId_r9->buf[0];
else
mbms_session_id = MBMS_SessionInfo_p->logicalChannelIdentity_r9;
lc_id = mbms_session_id;
mbms_service_id = MBMS_SessionInfo_p->tmgi_r9.serviceId_r9.buf[2]; //serviceId is 3-octet string
// mbms_service_id = j;
#if 0
/* TODO: check if this code should stay there
* as it is both enb and ue cases do the same thing
*/
// can set the mch_id = i
if (ctxt_pP->enb_flag) {
drb_id = (mbms_service_id * LTE_maxSessionPerPMCH ) + mbms_session_id;//+ (LTE_maxDRB + 3) * MAX_MOBILES_PER_ENB; // 1
} else {
drb_id = (mbms_service_id * LTE_maxSessionPerPMCH ) + mbms_session_id; // + (LTE_maxDRB + 3); // 15
}
#endif
drb_id = (mbms_service_id * LTE_maxSessionPerPMCH ) + mbms_session_id;
LOG_I(RLC, PROTOCOL_CTXT_FMT" CONFIG REQ MBMS ASN1 LC ID %u RB ID %u SESSION ID %u SERVICE ID %u, mbms_rnti %x\n",
PROTOCOL_CTXT_ARGS(ctxt_pP),
lc_id,
(int)drb_id,
mbms_session_id,
mbms_service_id,
mbms_rnti
);
rlc_entity_t *rlc_um;
rlc_ue_t *ue;
//drb_id = rb_id;
rlc_manager_lock(rlc_ue_manager);
ue = rlc_manager_get_ue(rlc_ue_manager, mbms_rnti);
if (ue->drb[drb_id-1] != NULL) {
LOG_D(RLC, "%s:%d:%s: warning DRB %d already exist for ue %d, do nothing\n",
__FILE__, __LINE__, __FUNCTION__, (int)drb_id, mbms_rnti);
} else {
rlc_um = new_rlc_entity_um(1000000,
1000000,
deliver_sdu, ue,
0,//LTE_T_Reordering_ms0,//t_reordering,
5//LTE_SN_FieldLength_size5//sn_field_length
);
rlc_ue_add_drb_rlc_entity(ue, drb_id, rlc_um);
LOG_D(RLC, "%s:%d:%s: added drb %d to ue %d\n",
__FILE__, __LINE__, __FUNCTION__, (int)drb_id, mbms_rnti);
}
rlc_manager_unlock(rlc_ue_manager);
}
}
}
if (drb2release_listP != NULL) {
LOG_E(RLC, "%s:%d:%s: TODO\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if (srb2add_listP != NULL) {
for (i = 0; i < srb2add_listP->list.count; i++) {
add_srb(rnti, module_id, srb2add_listP->list.array[i]);
}
}
if (drb2add_listP != NULL) {
for (i = 0; i < drb2add_listP->list.count; i++) {
add_drb(rnti, module_id, drb2add_listP->list.array[i]);
}
}
return RLC_OP_STATUS_OK;
}
rlc_op_status_t rrc_rlc_config_req (
const protocol_ctxt_t* const ctxt_pP,
const srb_flag_t srb_flagP,
const MBMS_flag_t mbms_flagP,
const config_action_t actionP,
const rb_id_t rb_idP,
const rlc_info_t rlc_infoP)
{
rlc_ue_t *ue;
int i;
if (mbms_flagP) {
LOG_E(RLC, "%s:%d:%s: todo (mbms not supported)\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if (actionP != CONFIG_ACTION_REMOVE) {
LOG_E(RLC, "%s:%d:%s: todo (only CONFIG_ACTION_REMOVE supported)\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if (ctxt_pP->module_id) {
LOG_E(RLC, "%s:%d:%s: todo (only module_id 0 supported)\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if ((srb_flagP && !(rb_idP >= 1 && rb_idP <= 2)) ||
(!srb_flagP && !(rb_idP >= 1 && rb_idP <= 5))) {
LOG_E(RLC, "%s:%d:%s: bad rb_id (%d) (is_srb %d)\n", __FILE__, __LINE__, __FUNCTION__, (int)rb_idP, srb_flagP);
exit(1);
}
rlc_manager_lock(rlc_ue_manager);
LOG_D(RLC, "%s:%d:%s: remove rb %d (is_srb %d) for UE %d\n", __FILE__, __LINE__, __FUNCTION__, (int)rb_idP, srb_flagP, ctxt_pP->rnti);
ue = rlc_manager_get_ue(rlc_ue_manager, ctxt_pP->rnti);
if (srb_flagP) {
if (ue->srb[rb_idP-1] != NULL) {
ue->srb[rb_idP-1]->delete(ue->srb[rb_idP-1]);
ue->srb[rb_idP-1] = NULL;
} else
LOG_W(RLC, "removing non allocated SRB %d, do nothing\n", (int)rb_idP);
} else {
if (ue->drb[rb_idP-1] != NULL) {
ue->drb[rb_idP-1]->delete(ue->drb[rb_idP-1]);
ue->drb[rb_idP-1] = NULL;
} else
LOG_W(RLC, "removing non allocated DRB %d, do nothing\n", (int)rb_idP);
}
/* remove UE if it has no more RB configured */
for (i = 0; i < 2; i++)
if (ue->srb[i] != NULL)
break;
if (i == 2) {
for (i = 0; i < 5; i++)
if (ue->drb[i] != NULL)
break;
if (i == 5)
rlc_manager_remove_ue(rlc_ue_manager, ctxt_pP->rnti);
}
rlc_manager_unlock(rlc_ue_manager);
return RLC_OP_STATUS_OK;
}
void rrc_rlc_register_rrc (rrc_data_ind_cb_t rrc_data_indP, rrc_data_conf_cb_t rrc_data_confP)
{
/* nothing to do */
}
rlc_op_status_t rrc_rlc_remove_ue (const protocol_ctxt_t* const x)
{
LOG_D(RLC, "%s:%d:%s: remove UE %d\n", __FILE__, __LINE__, __FUNCTION__, x->rnti);
rlc_manager_lock(rlc_ue_manager);
rlc_manager_remove_ue(rlc_ue_manager, x->rnti);
rlc_manager_unlock(rlc_ue_manager);
return RLC_OP_STATUS_OK;
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include "rlc_pdu.h"
#include <stdlib.h>
#include <string.h>
#include "LOG/log.h"
/**************************************************************************/
/* RX PDU segment and segment list */
/**************************************************************************/
rlc_rx_pdu_segment_t *rlc_rx_new_pdu_segment(int sn, int so, int size,
int is_last, char *data, int data_offset)
{
rlc_rx_pdu_segment_t *ret = malloc(sizeof(rlc_rx_pdu_segment_t));
if (ret == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
ret->sn = sn;
ret->so = so;
ret->size = size;
ret->is_last = is_last;
ret->next = NULL;
ret->data = malloc(size);
if (ret->data == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
memcpy(ret->data, data, size);
ret->data_offset = data_offset;
return ret;
}
void rlc_rx_free_pdu_segment(rlc_rx_pdu_segment_t *pdu_segment)
{
free(pdu_segment->data);
free(pdu_segment);
}
rlc_rx_pdu_segment_t *rlc_rx_pdu_segment_list_add(
int (*sn_compare)(void *, int, int), void *sn_compare_data,
rlc_rx_pdu_segment_t *list, rlc_rx_pdu_segment_t *pdu_segment)
{
rlc_rx_pdu_segment_t head;
rlc_rx_pdu_segment_t *cur;
rlc_rx_pdu_segment_t *prev;
head.next = list;
cur = list;
prev = &head;
/* order is by 'sn', if 'sn' is the same then order is by 'so' */
while (cur != NULL) {
/* check if 'pdu_segment' is before 'cur' in the list */
if (sn_compare(sn_compare_data, cur->sn, pdu_segment->sn) > 0 ||
(cur->sn == pdu_segment->sn && cur->so > pdu_segment->so)) {
break;
}
prev = cur;
cur = cur->next;
}
prev->next = pdu_segment;
pdu_segment->next = cur;
return head.next;
}
/**************************************************************************/
/* TX PDU management */
/**************************************************************************/
rlc_tx_pdu_segment_t *rlc_tx_new_pdu(void)
{
rlc_tx_pdu_segment_t *ret = calloc(1, sizeof(rlc_tx_pdu_segment_t));
if (ret == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
ret->retx_count = -1;
return ret;
}
void rlc_tx_free_pdu(rlc_tx_pdu_segment_t *pdu)
{
free(pdu);
}
rlc_tx_pdu_segment_t *rlc_tx_pdu_list_append(rlc_tx_pdu_segment_t *list,
rlc_tx_pdu_segment_t *pdu)
{
rlc_tx_pdu_segment_t head;
rlc_tx_pdu_segment_t *cur;
head.next = list;
cur = &head;
while (cur->next != NULL) {
cur = cur->next;
}
cur->next = pdu;
return head.next;
}
rlc_tx_pdu_segment_t *rlc_tx_pdu_list_add(
int (*sn_compare)(void *, int, int), void *sn_compare_data,
rlc_tx_pdu_segment_t *list, rlc_tx_pdu_segment_t *pdu_segment)
{
rlc_tx_pdu_segment_t head;
rlc_tx_pdu_segment_t *cur;
rlc_tx_pdu_segment_t *prev;
head.next = list;
cur = list;
prev = &head;
/* order is by 'sn', if 'sn' is the same then order is by 'so' */
while (cur != NULL) {
/* check if 'pdu_segment' is before 'cur' in the list */
if (sn_compare(sn_compare_data, cur->sn, pdu_segment->sn) > 0 ||
(cur->sn == pdu_segment->sn && cur->so > pdu_segment->so)) {
break;
}
prev = cur;
cur = cur->next;
}
prev->next = pdu_segment;
pdu_segment->next = cur;
return head.next;
}
/**************************************************************************/
/* PDU decoder */
/**************************************************************************/
void rlc_pdu_decoder_init(rlc_pdu_decoder_t *decoder, char *buffer, int size)
{
decoder->error = 0;
decoder->byte = 0;
decoder->bit = 0;
decoder->buffer = buffer;
decoder->size = size;
}
static int get_bit(rlc_pdu_decoder_t *decoder)
{
int ret;
if (decoder->byte >= decoder->size) {
decoder->error = 1;
return 0;
}
ret = (decoder->buffer[decoder->byte] >> (7 - decoder->bit)) & 1;
decoder->bit++;
if (decoder->bit == 8) {
decoder->bit = 0;
decoder->byte++;
}
return ret;
}
int rlc_pdu_decoder_get_bits(rlc_pdu_decoder_t *decoder, int count)
{
int ret = 0;
int i;
if (count > 31) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
for (i = 0; i < count; i++) {
ret <<= 1;
ret |= get_bit(decoder);
if (decoder->error) return -1;
}
return ret;
}
void rlc_pdu_decoder_align(rlc_pdu_decoder_t *decoder)
{
if (decoder->bit) {
decoder->bit = 0;
decoder->byte++;
}
}
/**************************************************************************/
/* PDU encoder */
/**************************************************************************/
void rlc_pdu_encoder_init(rlc_pdu_encoder_t *encoder, char *buffer, int size)
{
encoder->byte = 0;
encoder->bit = 0;
encoder->buffer = buffer;
encoder->size = size;
}
static void put_bit(rlc_pdu_encoder_t *encoder, int bit)
{
if (encoder->byte == encoder->size) {
LOG_E(RLC, "%s:%d:%s: fatal, buffer full\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
encoder->buffer[encoder->byte] <<= 1;
if (bit)
encoder->buffer[encoder->byte] |= 1;
encoder->bit++;
if (encoder->bit == 8) {
encoder->bit = 0;
encoder->byte++;
}
}
void rlc_pdu_encoder_put_bits(rlc_pdu_encoder_t *encoder, int value, int count)
{
int i;
int x;
if (count > 31) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
x = 1 << (count - 1);
for (i = 0; i < count; i++, x >>= 1)
put_bit(encoder, value & x);
}
void rlc_pdu_encoder_align(rlc_pdu_encoder_t *encoder)
{
while (encoder->bit)
put_bit(encoder, 0);
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef _RLC_PDU_H_
#define _RLC_PDU_H_
/**************************************************************************/
/* RX PDU segment and segment list */
/**************************************************************************/
typedef struct rlc_rx_pdu_segment_t {
int sn;
int so;
int size;
int is_last;
char *data;
int data_offset;
struct rlc_rx_pdu_segment_t *next;
} rlc_rx_pdu_segment_t;
rlc_rx_pdu_segment_t *rlc_rx_new_pdu_segment(int sn, int so, int size,
int is_last, char *data, int data_offset);
void rlc_rx_free_pdu_segment(rlc_rx_pdu_segment_t *pdu_segment);
rlc_rx_pdu_segment_t *rlc_rx_pdu_segment_list_add(
int (*sn_compare)(void *, int, int), void *sn_compare_data,
rlc_rx_pdu_segment_t *list, rlc_rx_pdu_segment_t *pdu_segment);
/**************************************************************************/
/* TX PDU management */
/**************************************************************************/
typedef struct rlc_tx_pdu_segment_t {
int sn;
void *start_sdu; /* real type is rlc_sdu_t * */
int sdu_start_byte; /* starting byte in 'start_sdu' */
int so; /* starting byte of the segment in full PDU */
int data_size; /* number of data bytes (exclude header) */
int is_segment;
int is_last;
int retx_count;
struct rlc_tx_pdu_segment_t *next;
} rlc_tx_pdu_segment_t;
rlc_tx_pdu_segment_t *rlc_tx_new_pdu(void);
void rlc_tx_free_pdu(rlc_tx_pdu_segment_t *pdu);
rlc_tx_pdu_segment_t *rlc_tx_pdu_list_append(rlc_tx_pdu_segment_t *list,
rlc_tx_pdu_segment_t *pdu);
rlc_tx_pdu_segment_t *rlc_tx_pdu_list_add(
int (*sn_compare)(void *, int, int), void *sn_compare_data,
rlc_tx_pdu_segment_t *list, rlc_tx_pdu_segment_t *pdu_segment);
/**************************************************************************/
/* PDU decoder */
/**************************************************************************/
typedef struct {
int error;
int byte; /* next byte to decode */
int bit; /* next bit in next byte to decode */
char *buffer;
int size;
} rlc_pdu_decoder_t;
void rlc_pdu_decoder_init(rlc_pdu_decoder_t *decoder, char *buffer, int size);
#define rlc_pdu_decoder_in_error(d) ((d)->error == 1)
int rlc_pdu_decoder_get_bits(rlc_pdu_decoder_t *decoder, int count);
void rlc_pdu_decoder_align(rlc_pdu_decoder_t *decoder);
/**************************************************************************/
/* PDU encoder */
/**************************************************************************/
typedef struct {
int byte; /* next byte to encode */
int bit; /* next bit in next byte to encode */
char *buffer;
int size;
} rlc_pdu_encoder_t;
void rlc_pdu_encoder_init(rlc_pdu_encoder_t *encoder, char *buffer, int size);
void rlc_pdu_encoder_put_bits(rlc_pdu_encoder_t *encoder, int value, int count);
void rlc_pdu_encoder_align(rlc_pdu_encoder_t *encoder);
#endif /* _RLC_PDU_H_ */
...@@ -19,44 +19,50 @@ ...@@ -19,44 +19,50 @@
* contact@openairinterface.org * contact@openairinterface.org
*/ */
/*! \file PHY/NR_TRANSPORT/nr_dci_tools_common.c #include "rlc_sdu.h"
* \brief
* \author
* \date 2018
* \version 0.1
* \company Eurecom
* \email:
* \note
* \warning
*/
#include "nr_dci.h" #include <stdlib.h>
#include <string.h>
//#define DEBUG_FILL_DCI #include "LOG/log.h"
#include "nr_dlsch.h" rlc_sdu_t *rlc_new_sdu(char *buffer, int size, int upper_layer_id)
{
rlc_sdu_t *ret = calloc(1, sizeof(rlc_sdu_t));
if (ret == NULL)
goto oom;
ret->upper_layer_id = upper_layer_id;
void get_coreset_rballoc(uint8_t *FreqDomainResource,int *n_rb,int *rb_offset) { ret->data = malloc(size);
if (ret->data == NULL)
goto oom;
uint8_t count=0, start=0, start_set=0; memcpy(ret->data, buffer, size);
uint64_t bitmap = (((uint64_t)FreqDomainResource[0])<<37)| ret->size = size;
(((uint64_t)FreqDomainResource[1])<<29)|
(((uint64_t)FreqDomainResource[2])<<21)|
(((uint64_t)FreqDomainResource[3])<<13)|
(((uint64_t)FreqDomainResource[4])<<5)|
(((uint64_t)FreqDomainResource[5])>>3);
for (int i=0; i<45; i++) return ret;
if ((bitmap>>(44-i))&1) {
count++; oom:
if (!start_set) { LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
start = i; exit(1);
start_set = 1;
}
}
*rb_offset = 6*start;
*n_rb = 6*count;
} }
void rlc_free_sdu(rlc_sdu_t *sdu)
{
free(sdu->data);
free(sdu);
}
void rlc_sdu_list_add(rlc_sdu_t **list, rlc_sdu_t **end, rlc_sdu_t *sdu)
{
if (*list == NULL) {
*list = sdu;
*end = sdu;
return;
}
(*end)->next = sdu;
*end = sdu;
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef _RLC_SDU_H_
#define _RLC_SDU_H_
typedef struct rlc_sdu_t {
int upper_layer_id;
char *data;
int size;
/* next_byte indicates the starting byte to use to construct a new PDU */
int next_byte;
int acked_bytes;
struct rlc_sdu_t *next;
} rlc_sdu_t;
rlc_sdu_t *rlc_new_sdu(char *buffer, int size, int upper_layer_id);
void rlc_free_sdu(rlc_sdu_t *sdu);
void rlc_sdu_list_add(rlc_sdu_t **list, rlc_sdu_t **end, rlc_sdu_t *sdu);
#endif /* _RLC_SDU_H_ */
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#include "rlc_ue_manager.h"
#include <pthread.h>
#include <stdlib.h>
#include <string.h>
#include "LOG/log.h"
typedef struct {
pthread_mutex_t lock;
rlc_ue_t **ue_list;
int ue_count;
int enb_flag;
} rlc_ue_manager_internal_t;
rlc_ue_manager_t *new_rlc_ue_manager(int enb_flag)
{
rlc_ue_manager_internal_t *ret;
ret = calloc(1, sizeof(rlc_ue_manager_internal_t));
if (ret == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
if (pthread_mutex_init(&ret->lock, NULL)) abort();
ret->enb_flag = enb_flag;
return ret;
}
int rlc_manager_get_enb_flag(rlc_ue_manager_t *_m)
{
rlc_ue_manager_internal_t *m = _m;
return m->enb_flag;
}
void rlc_manager_lock(rlc_ue_manager_t *_m)
{
rlc_ue_manager_internal_t *m = _m;
if (pthread_mutex_lock(&m->lock)) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
}
void rlc_manager_unlock(rlc_ue_manager_t *_m)
{
rlc_ue_manager_internal_t *m = _m;
if (pthread_mutex_unlock(&m->lock)) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
}
/* must be called with lock acquired */
rlc_ue_t *rlc_manager_get_ue(rlc_ue_manager_t *_m, int rnti)
{
/* TODO: optimze */
rlc_ue_manager_internal_t *m = _m;
int i;
for (i = 0; i < m->ue_count; i++)
if (m->ue_list[i]->rnti == rnti)
return m->ue_list[i];
LOG_D(RLC, "%s:%d:%s: new UE %d\n", __FILE__, __LINE__, __FUNCTION__, rnti);
m->ue_count++;
m->ue_list = realloc(m->ue_list, sizeof(rlc_ue_t *) * m->ue_count);
if (m->ue_list == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
m->ue_list[m->ue_count-1] = calloc(1, sizeof(rlc_ue_t));
if (m->ue_list[m->ue_count-1] == NULL) {
LOG_E(RLC, "%s:%d:%s: out of memory\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
m->ue_list[m->ue_count-1]->rnti = rnti;
return m->ue_list[m->ue_count-1];
}
/* must be called with lock acquired */
void rlc_manager_remove_ue(rlc_ue_manager_t *_m, int rnti)
{
rlc_ue_manager_internal_t *m = _m;
rlc_ue_t *ue;
int i;
int j;
for (i = 0; i < m->ue_count; i++)
if (m->ue_list[i]->rnti == rnti)
break;
if (i == m->ue_count) {
LOG_D(RLC, "%s:%d:%s: warning: ue %d not found\n",
__FILE__, __LINE__, __FUNCTION__,
rnti);
return;
}
ue = m->ue_list[i];
for (j = 0; j < 2; j++)
if (ue->srb[j] != NULL)
ue->srb[j]->delete(ue->srb[j]);
for (j = 0; j < 5; j++)
if (ue->drb[j] != NULL)
ue->drb[j]->delete(ue->drb[j]);
free(ue);
m->ue_count--;
if (m->ue_count == 0) {
free(m->ue_list);
m->ue_list = NULL;
return;
}
memmove(&m->ue_list[i], &m->ue_list[i+1],
(m->ue_count - i) * sizeof(rlc_ue_t *));
m->ue_list = realloc(m->ue_list, m->ue_count * sizeof(rlc_ue_t *));
if (m->ue_list == NULL) {
LOG_E(RLC, "%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
}
/* must be called with lock acquired */
void rlc_ue_add_srb_rlc_entity(rlc_ue_t *ue, int srb_id, rlc_entity_t *entity)
{
if (srb_id < 1 || srb_id > 2) {
LOG_E(RLC, "%s:%d:%s: fatal, bad srb id\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
srb_id--;
if (ue->srb[srb_id] != NULL) {
LOG_E(RLC, "%s:%d:%s: fatal, srb already present\n",
__FILE__, __LINE__, __FUNCTION__);
exit(1);
}
ue->srb[srb_id] = entity;
}
/* must be called with lock acquired */
void rlc_ue_add_drb_rlc_entity(rlc_ue_t *ue, int drb_id, rlc_entity_t *entity)
{
if (drb_id < 1 || drb_id > 5) {
LOG_E(RLC, "%s:%d:%s: fatal, bad drb id\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
drb_id--;
if (ue->drb[drb_id] != NULL) {
LOG_E(RLC, "%s:%d:%s: fatal, drb already present\n",
__FILE__, __LINE__, __FUNCTION__);
exit(1);
}
ue->drb[drb_id] = entity;
}
/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
#ifndef _RLC_UE_MANAGER_H_
#define _RLC_UE_MANAGER_H_
#include "rlc_entity.h"
typedef void rlc_ue_manager_t;
typedef struct rlc_ue_t {
int rnti;
int module_id; /* necesarry for the L2 simulator - not clean, to revise */
rlc_entity_t *srb[2];
rlc_entity_t *drb[5];
} rlc_ue_t;
/***********************************************************************/
/* manager functions */
/***********************************************************************/
rlc_ue_manager_t *new_rlc_ue_manager(int enb_flag);
int rlc_manager_get_enb_flag(rlc_ue_manager_t *m);
void rlc_manager_lock(rlc_ue_manager_t *m);
void rlc_manager_unlock(rlc_ue_manager_t *m);
rlc_ue_t *rlc_manager_get_ue(rlc_ue_manager_t *m, int rnti);
void rlc_manager_remove_ue(rlc_ue_manager_t *m, int rnti);
/***********************************************************************/
/* ue functions */
/***********************************************************************/
void rlc_ue_add_srb_rlc_entity(rlc_ue_t *ue, int srb_id, rlc_entity_t *entity);
void rlc_ue_add_drb_rlc_entity(rlc_ue_t *ue, int drb_id, rlc_entity_t *entity);
#endif /* _RLC_UE_MANAGER_H_ */
#ifndef _LOG_H_
#define _LOG_H_
#include <stdio.h>
#define LOG_E(x, ...) printf(__VA_ARGS__)
#define LOG_D(x, ...) printf(__VA_ARGS__)
#define LOG_W(x, ...) printf(__VA_ARGS__)
#endif /* _LOG_H_ */
CC=gcc
CFLAGS=-Wall -g --coverage -I.
LIB=rlc_entity.o rlc_entity_am.o rlc_entity_um.o rlc_pdu.o rlc_sdu.o
tests:
@./run_tests.sh
all: clean_run $(TEST).run
%.run: $(TEST).bin
#valgrind ./$(TEST).bin > $(TEST).run_pre 2> $(TEST).valgrind
./$(TEST).bin > $(TEST).run_pre
grep ^TEST $(TEST).run_pre > $(TEST).run
gunzip -c $(TEST).txt.gz > $(TEST).txt
diff -q $(TEST).txt $(TEST).run
$(TEST).bin: $(TEST).o $(LIB)
$(CC) $(CFLAGS) -o $@ $^
%.o: ../%.c
$(CC) $(CFLAGS) -I.. -c -o $@ $<
$(TEST).o: test.c
$(CC) $(CFLAGS) -c -o $@ $< -DTEST='"$(TEST).h"'
clean_run:
rm -f $(TEST).run $(TEST).bin $(TEST).o
clean:
rm -f *.o *.bin *.run *.run_pre *.gcov *.gcda *.gcno test*.txt a.out \
*.valgrind
To run tests, simply type: make
Each test is made of:
testXX.h definition of the test
testXX.txt.gz compressed expected output of the test
At runtime, we generate:
testXX.run actual output of the test
test.c is the test driving program.
Only the output lines of the test program starting with "TEST" are
stored into testXX.txt and testXX.run.
A test is considered a success if testXX.txt and testXX.run are equal.
Only failed tests are reported.
How to define a new test?
1 - get the ID
Look in the file run_tests.sh, the variable test_count gives you
the number of existing tests. The ID of your test has to be
test_count + 1.
2 - create files
Create the file test<ID>.h containing the test, then generate test<ID>.run
by running 'make all TEST=test<ID>' and copy test<ID>.run to test<ID>.txt.
Then compress this file (gzip -9 test<ID>.txt). Be sure that the output
is correct, of course.
For the file names, replace <ID> by the actual number of the test.
For example, if your test ID is 47, then name the files test47.h and
test47.txt. And run 'make all TEST=test47' to generate test47.run.
The available instructions for a test are described at the top of test.c.
/* gcc -Wall make_pdu.c -I.. ../rlc_pdu.c */
#include "rlc_pdu.h"
#include <stdio.h>
int main(void)
{
char out[100];
rlc_pdu_encoder_t e;
int i;
rlc_pdu_encoder_init(&e, out, 100);
rlc_pdu_encoder_put_bits(&e, 0, 1); // D/C
rlc_pdu_encoder_put_bits(&e, 0, 3); // CPT
rlc_pdu_encoder_put_bits(&e, 0, 10); // ack_sn
rlc_pdu_encoder_put_bits(&e, 1, 1); // e1
rlc_pdu_encoder_put_bits(&e, 10, 10); // nack_sn
rlc_pdu_encoder_put_bits(&e, 0, 1); // e1
rlc_pdu_encoder_put_bits(&e, 0, 1); // e2
rlc_pdu_encoder_align(&e);
for (i = 0; i < e.byte; i++) printf(" %2.2x", (unsigned char)e.buffer[i]);
printf("\n");
return 0;
}
#!/bin/sh
test_count=45
for i in `seq $test_count`
do
make all TEST=test$i >/dev/null 2>/dev/null
if [ $? != 0 ]
then
echo TEST $i FAILURE
fi
done
#include "../rlc_entity.h"
#include "../rlc_entity_am.h"
#include "../rlc_entity_um.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <inttypes.h>
#include <sys/wait.h>
#include <unistd.h>
/*
* ENB_AM <rx_maxsize> <tx_maxsize> <t_reordering> <t_status_prohibit>
* <t_poll_retransmit> <poll_pdu> <poll_byte> <max_retx_threshold>
* create the eNB RLC AM entity with given parameters
*
* UE_AM <rx_maxsize> <tx_maxsize> <t_reordering> <t_status_prohibit>
* <t_poll_retransmit> <poll_pdu> <poll_byte> <max_retx_threshold>
* create the UE RLC AM entity with given parameters
*
* ENB_UM <rx_maxsize> <tx_maxsize> <t_reordering> <sn_field_length>
* create the eNB RLC UM entity with given parameters
*
* UE_UM <rx_maxsize> <tx_maxsize> <t_reordering> <sn_field_length>
* create the UE RLC UM entity with given parameters
*
* TIME <time>
* following actions to be performed at time <time>
* <time> starts at 1
* You must end your test definition with a line 'TIME, -1'.
*
* ENB_SDU <id> <size>
* send an SDU to eNB with id <i> and size <size>
* the SDU is [00 01 ... ff 01 ...]
* (ie. start byte is 00 then we increment for each byte, loop if needed)
*
* UE_SDU <id> <size>
* same as ENB_SDU but the SDU is sent to the UE
*
* ENB_PDU <size> <'size' bytes>
* send a custom PDU from eNB to UE (eNB does not see this PDU at all)
*
* UE_PDU <size> <'size' bytes>
* send a custom PDU from UE to eNB (UE does not see this PDU at all)
*
* ENB_PDU_SIZE <size>
* set 'enb_pdu_size'
*
* UE_PDU_SIZE <size>
* set 'ue_pdu_size'
*
* ENB_RECV_FAILS <fails>
* set the 'enb_recv_fails' flag to <fails>
* (1: recv will fail, 0: recv will succeed)
*
* UE_RECV_FAILS <fails>
* same as ENB_RECV_FAILS but for 'ue_recv_fails'
*
* MUST_FAIL
* to be used as first command after the first TIME to indicate
* that the test must fail (ie. exit with non zero, crash not allowed)
*
* ENB_BUFFER_STATUS
* call buffer_status for eNB and print result
*
* UE_BUFFER_STATUS
* call buffer_status for UE and print result
*
* ENB_DISCARD_SDU <sdu ID>
* discards given SDU
*
* UE_DISCARD_SDU <sdu ID>
* discards given SDU
*
* RE_ESTABLISH
* re-establish both eNB and UE
*/
enum action {
ENB_AM, UE_AM,
ENB_UM, UE_UM,
TIME, ENB_SDU, UE_SDU, ENB_PDU, UE_PDU,
ENB_PDU_SIZE, UE_PDU_SIZE,
ENB_RECV_FAILS, UE_RECV_FAILS,
MUST_FAIL,
ENB_BUFFER_STATUS, UE_BUFFER_STATUS,
ENB_DISCARD_SDU, UE_DISCARD_SDU,
RE_ESTABLISH
};
int test[] = {
/* TEST is defined at compilation time */
#include TEST
};
void deliver_sdu_enb_am(void *deliver_sdu_data, struct rlc_entity_t *_entity,
char *buf, int size)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
printf("TEST: ENB: %"PRIu64": deliver SDU size %d [",
entity->t_current, size);
for (int i = 0; i < size; i++) printf(" %2.2x", (unsigned char)buf[i]);
printf("]\n");
}
void deliver_sdu_enb_um(void *deliver_sdu_data, struct rlc_entity_t *_entity,
char *buf, int size)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
printf("TEST: ENB: %"PRIu64": deliver SDU size %d [",
entity->t_current, size);
for (int i = 0; i < size; i++) printf(" %2.2x", (unsigned char)buf[i]);
printf("]\n");
}
void successful_delivery_enb(void *successful_delivery_data,
rlc_entity_t *_entity, int sdu_id)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
printf("TEST: ENB: %"PRIu64": SDU %d was successfully delivered.\n",
entity->t_current, sdu_id);
}
void max_retx_reached_enb(void *max_retx_reached_data, rlc_entity_t *_entity)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
printf("TEST: ENB: %"PRIu64": max RETX reached! radio link failure!\n",
entity->t_current);
exit(1);
}
void deliver_sdu_ue_am(void *deliver_sdu_data, struct rlc_entity_t *_entity,
char *buf, int size)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
printf("TEST: UE: %"PRIu64": deliver SDU size %d [",
entity->t_current, size);
for (int i = 0; i < size; i++) printf(" %2.2x", (unsigned char)buf[i]);
printf("]\n");
}
void deliver_sdu_ue_um(void *deliver_sdu_data, struct rlc_entity_t *_entity,
char *buf, int size)
{
rlc_entity_um_t *entity = (rlc_entity_um_t *)_entity;
printf("TEST: UE: %"PRIu64": deliver SDU size %d [",
entity->t_current, size);
for (int i = 0; i < size; i++) printf(" %2.2x", (unsigned char)buf[i]);
printf("]\n");
}
void successful_delivery_ue(void *successful_delivery_data,
rlc_entity_t *_entity, int sdu_id)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
printf("TEST: UE: %"PRIu64": SDU %d was successfully delivered.\n",
entity->t_current, sdu_id);
}
void max_retx_reached_ue(void *max_retx_reached_data, rlc_entity_t *_entity)
{
rlc_entity_am_t *entity = (rlc_entity_am_t *)_entity;
printf("TEST: UE: %"PRIu64", max RETX reached! radio link failure!\n",
entity->t_current);
exit(1);
}
int test_main(void)
{
rlc_entity_t *enb = NULL;
rlc_entity_t *ue = NULL;
int i;
int k;
char *sdu;
char *pdu;
rlc_entity_buffer_status_t buffer_status;
int enb_do_buffer_status = 0;
int ue_do_buffer_status = 0;
int size;
int pos;
int next_byte_enb = 0;
int next_byte_ue = 0;
int enb_recv_fails = 0;
int ue_recv_fails = 0;
int enb_pdu_size = 1000;
int ue_pdu_size = 1000;
sdu = malloc(16001);
pdu = malloc(3000);
if (sdu == NULL || pdu == NULL) {
printf("out of memory\n");
exit(1);
}
for (i = 0; i < 16001; i++)
sdu[i] = i & 255;
pos = 0;
if (test[pos] != TIME) {
printf("%s:%d:%s: fatal\n", __FILE__, __LINE__, __FUNCTION__);
exit(1);
}
for (i = 1; i < 1000; i++) {
if (i == test[pos+1]) {
pos += 2;
while (test[pos] != TIME)
switch (test[pos]) {
default: printf("fatal: unknown action\n"); exit(1);
case ENB_AM:
enb = new_rlc_entity_am(test[pos+1], test[pos+2],
deliver_sdu_enb_am, NULL,
successful_delivery_enb, NULL,
max_retx_reached_enb, NULL,
test[pos+3], test[pos+4], test[pos+5],
test[pos+6], test[pos+7], test[pos+8]);
pos += 9;
break;
case UE_AM:
ue = new_rlc_entity_am(test[pos+1], test[pos+2],
deliver_sdu_ue_am, NULL,
successful_delivery_ue, NULL,
max_retx_reached_ue, NULL,
test[pos+3], test[pos+4], test[pos+5],
test[pos+6], test[pos+7], test[pos+8]);
pos += 9;
break;
case ENB_UM:
enb = new_rlc_entity_um(test[pos+1], test[pos+2],
deliver_sdu_enb_um, NULL,
test[pos+3], test[pos+4]);
pos += 5;
break;
case UE_UM:
ue = new_rlc_entity_um(test[pos+1], test[pos+2],
deliver_sdu_ue_um, NULL,
test[pos+3], test[pos+4]);
pos += 5;
break;
case ENB_SDU:
for (k = 0; k < test[pos+2]; k++, next_byte_enb++)
sdu[k] = next_byte_enb;
printf("TEST: ENB: %d: recv_sdu (id %d): size %d: [",
i, test[pos+1], test[pos+2]);
for (k = 0; k < test[pos+2]; k++)
printf(" %2.2x", (unsigned char)sdu[k]);
printf("]\n");
enb->recv_sdu(enb, sdu, test[pos+2], test[pos+1]);
pos += 3;
break;
case UE_SDU:
for (k = 0; k < test[pos+2]; k++, next_byte_ue++)
sdu[k] = next_byte_ue;
printf("TEST: UE: %d: recv_sdu (id %d): size %d: [",
i, test[pos+1], test[pos+2]);
for (k = 0; k < test[pos+2]; k++)
printf(" %2.2x", (unsigned char)sdu[k]);
printf("]\n");
ue->recv_sdu(ue, sdu, test[pos+2], test[pos+1]);
pos += 3;
break;
case ENB_PDU:
for (k = 0; k < test[pos+1]; k++)
pdu[k] = test[pos+2+k];
printf("TEST: ENB: %d: custom PDU: size %d: [", i, test[pos+1]);
for (k = 0; k < test[pos+1]; k++) printf(" %2.2x", (unsigned char)pdu[k]);
printf("]\n");
if (!ue_recv_fails)
ue->recv_pdu(ue, pdu, test[pos+1]);
pos += 2 + test[pos+1];
break;
case UE_PDU:
for (k = 0; k < test[pos+1]; k++)
pdu[k] = test[pos+2+k];
printf("TEST: UE: %d: custom PDU: size %d: [", i, test[pos+1]);
for (k = 0; k < test[pos+1]; k++) printf(" %2.2x", (unsigned char)pdu[k]);
printf("]\n");
if (!enb_recv_fails)
enb->recv_pdu(enb, pdu, test[pos+1]);
pos += 2 + test[pos+1];
break;
case ENB_PDU_SIZE:
enb_pdu_size = test[pos+1];
pos += 2;
break;
case UE_PDU_SIZE:
ue_pdu_size = test[pos+1];
pos += 2;
break;
case ENB_RECV_FAILS:
enb_recv_fails = test[pos+1];
pos += 2;
break;
case UE_RECV_FAILS:
ue_recv_fails = test[pos+1];
pos += 2;
break;
case MUST_FAIL:
/* do nothing, only used by caller */
pos++;
break;
case ENB_BUFFER_STATUS:
enb_do_buffer_status = 1;
pos++;
break;
case UE_BUFFER_STATUS:
ue_do_buffer_status = 1;
pos++;
break;
case ENB_DISCARD_SDU:
printf("TEST: ENB: %d: discard SDU %d\n", i, test[pos+1]);
enb->discard_sdu(enb, test[pos+1]);
pos += 2;
break;
case UE_DISCARD_SDU:
printf("TEST: UE: %d: discard SDU %d\n", i, test[pos+1]);
ue->discard_sdu(ue, test[pos+1]);
pos += 2;
break;
case RE_ESTABLISH:
printf("TEST: %d: re-establish eNB and UE\n", i);
enb->reestablishment(enb);
ue->reestablishment(ue);
pos++;
break;
}
}
enb->set_time(enb, i);
ue->set_time(ue, i);
if (enb_do_buffer_status) {
enb_do_buffer_status = 0;
buffer_status = enb->buffer_status(enb, enb_pdu_size);
printf("TEST: ENB: %d: buffer_status: status_size %d tx_size %d retx_size %d\n",
i,
buffer_status.status_size,
buffer_status.tx_size,
buffer_status.retx_size);
}
size = enb->generate_pdu(enb, pdu, enb_pdu_size);
if (size) {
printf("TEST: ENB: %d: generate_pdu: size %d: [", i, size);
for (k = 0; k < size; k++) printf(" %2.2x", (unsigned char)pdu[k]);
printf("]\n");
if (!ue_recv_fails)
ue->recv_pdu(ue, pdu, size);
}
if (ue_do_buffer_status) {
ue_do_buffer_status = 0;
buffer_status = ue->buffer_status(ue, ue_pdu_size);
printf("TEST: UE: %d: buffer_status: status_size %d tx_size %d retx_size %d\n",
i,
buffer_status.status_size,
buffer_status.tx_size,
buffer_status.retx_size);
}
size = ue->generate_pdu(ue, pdu, ue_pdu_size);
if (size) {
printf("TEST: UE: %d: generate_pdu: size %d: [", i, size);
for (k = 0; k < size; k++) printf(" %2.2x", (unsigned char)pdu[k]);
printf("]\n");
if (!enb_recv_fails)
enb->recv_pdu(enb, pdu, size);
}
}
enb->delete(enb);
ue->delete(ue);
free(sdu);
free(pdu);
return 0;
}
void usage(void)
{
printf("options:\n");
printf(" -no-fork\n");
printf(" don't fork (to ease debugging with gdb)\n");
exit(0);
}
int main(int n, char **v)
{
int must_fail = 0;
int son;
int status;
int i;
int no_fork = 0;
for (i = 1; i < n; i++) {
if (!strcmp(v[i], "-no-fork")) { no_fork = 1; continue; }
usage();
}
if (test[2] == MUST_FAIL)
must_fail = 1;
if (no_fork) return test_main();
son = fork();
if (son == -1) {
perror("fork");
return 1;
}
if (son == 0)
return test_main();
if (wait(&status) == -1) {
perror("wait");
return 1;
}
/* child must quit properly */
if (!WIFEXITED(status))
return 1;
/* child must fail if expected to */
if (must_fail && WEXITSTATUS(status) == 0)
return 1;
/* child must not fail if not expected to */
if (!must_fail && WEXITSTATUS(status))
return 1;
return 0;
}
/*
* basic am test:
* at time 1, eNB receives an SDU of 10 bytes
* at time 10, UE receives an SDU of 5 bytes
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
UE_BUFFER_STATUS,
TIME, 10,
UE_SDU, 0, 5,
TIME, -1
/*
* rlc am test resegmentation of PDU segment with several SDUs
* eNB sends 3 SDUs [1..10] [11.20] [21..30], not received
* eNB retx with smaller PDUs, not received
* eNB retx with still smaller PDUs, not received
* then reception on, all passes
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_SDU, 0, 10,
ENB_SDU, 1, 10,
ENB_SDU, 2, 10,
TIME, 2,
ENB_PDU_SIZE, 25,
TIME, 48,
ENB_PDU_SIZE, 15,
TIME, 100,
UE_RECV_FAILS, 0,
ENB_RECV_FAILS, 0,
TIME, -1
/*
* rlc am test function rlc_am_reassemble_next_segment
* in r->pdu_byte >= r->so + (r->sdu_offset - r->start->data_offset)
* + r->sdu_len
* when case 'if (r->e)' is false
* eNB sends 3 SDUs [1..10] [11.20] [21..30], not received
* eNB retx with smaller PDUs, not received
* eNB retx with still smaller PDUs, not received
* then UE reception on
* then custom PDUs, first a small part of head of original PDU
* then a bigger part, covering the first part
* so that the beginning of this part triggers the 'while'
* then eNB reception on, all passes
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_SDU, 0, 10,
ENB_SDU, 1, 10,
ENB_SDU, 2, 10,
TIME, 2,
ENB_PDU_SIZE, 25,
TIME, 48,
ENB_PDU_SIZE, 15,
TIME, 95,
ENB_BUFFER_STATUS,
TIME, 99,
UE_RECV_FAILS, 0,
ENB_PDU, 14, 0xe0, 0x00, 0x00, 0x00, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09,
ENB_PDU, 25, 0xec, 0x00, 0x00, 0x00, 0x00, 0xa0, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12,
TIME, 100,
ENB_RECV_FAILS, 0,
TIME, 134,
UE_BUFFER_STATUS,
TIME, -1
/*
* rlc am test function rlc_am_reassemble_next_segment
* in r->pdu_byte >= r->so + (r->sdu_offset - r->start->data_offset)
* + r->sdu_len
* when case 'if (r->e)' is true
* eNB sends 4 SDUs [1..5] [6..10] [11.20] [21..30], not received
* eNB retx with smaller PDUs, not received
* eNB retx with still smaller PDUs, not received
* then UE reception on
* then custom PDUs, first a small part of head of original PDU
* then a bigger part, covering the first part
* so that the beginning of this part triggers the 'while'
* then eNB reception on, all passes
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_SDU, 0, 5,
ENB_SDU, 1, 5,
ENB_SDU, 2, 10,
ENB_SDU, 3, 10,
TIME, 2,
ENB_PDU_SIZE, 25,
TIME, 48,
ENB_PDU_SIZE, 15,
TIME, 99,
UE_RECV_FAILS, 0,
ENB_PDU, 15, 0xec, 0x00, 0x00, 0x00, 0x00, 0x50, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08,
ENB_PDU, 25, 0xec, 0x00, 0x00, 0x00, 0x80, 0x50, 0x05, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11,
TIME, 100,
ENB_RECV_FAILS, 0,
TIME, -1
/*
* rlc am test function process_received_ack with something in
* the retransmit_list to put in the ack_list
* eNB sends 4 PDUs, not received
* eNB retransmits 4th PDU, received, ACKed with NACKs for PDU 1, 2, 3
* UE receives custom PDU for 1, 2, 3, 4 (they are not sent by eNB)
* (4 resent to have the P bit set)
* UE sends ACK for all, eNB puts from retransmit_list to ack_list
*
* Maybe not very realistic (custom PDUs).
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_PDU_SIZE, 12,
ENB_SDU, 0, 10,
ENB_SDU, 1, 10,
ENB_SDU, 2, 10,
ENB_SDU, 3, 10,
TIME, 10,
UE_RECV_FAILS, 0,
ENB_RECV_FAILS, 0,
TIME, 87,
ENB_PDU, 12, 0x80, 0x00, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09,
ENB_PDU, 12, 0x80, 0x01, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13,
ENB_PDU, 12, 0x80, 0x02, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d,
ENB_PDU, 12, 0xa0, 0x03, 0x1e, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27,
TIME, -1
/*
* rlc am test max_retx_reached
* eNB sends PDU, never received
*/
TIME, 1,
MUST_FAIL,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_SDU, 0, 10,
TIME, -1
/*
* rlc am test so_overlap
* eNB sends PDU, not received
* then PDU is segmented in 3 parts, part 1 & 3 not received,
* then we generate a fake control PDU from UE to eNB that
* contains NACK with so_start/so_end being inside part 2.
*
* code to generate fake control PDU:
* rlc_pdu_encoder_init(&e, out, 100);
* rlc_pdu_encoder_put_bits(&e, 0, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 0, 3); // CPT
* rlc_pdu_encoder_put_bits(&e, 2, 10); // ack_sn
* rlc_pdu_encoder_put_bits(&e, 1, 1); // e1
* rlc_pdu_encoder_put_bits(&e, 1, 10); // nack_sn
* rlc_pdu_encoder_put_bits(&e, 0, 1); // e1
* rlc_pdu_encoder_put_bits(&e, 1, 1); // e2
* rlc_pdu_encoder_put_bits(&e, 14, 15); // so_start
* rlc_pdu_encoder_put_bits(&e, 16, 15); // so_end
* rlc_pdu_encoder_align(&e);
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 8,
ENB_RECV_FAILS, 1,
TIME, 2,
UE_RECV_FAILS, 1,
ENB_SDU, 1, 30,
TIME, 20,
ENB_PDU_SIZE, 14,
TIME, 48,
UE_RECV_FAILS, 0,
TIME, 49,
UE_RECV_FAILS, 1,
TIME, 50,
UE_RECV_FAILS, 0,
TIME, 60,
ENB_RECV_FAILS, 0,
UE_PDU, 8, 0x00, 0x0a, 0x00, 0xa0, 0x03, 0x80, 0x08, 0x00,
TIME, 70,
UE_RECV_FAILS, 0,
TIME, -1
/*
* rlc am test process_received_nack
* Same events as for test15 except the fake control PDU
* does not ACK anything (ack_sn = 0) so that PDU in the
* wait_list are not transfered into the ack_list and
* we cover the case:
* } else {
* prev = cur;
* cur = cur->next;
* }
* for the wait_list case.
*
* code to generate fake control PDU:
* rlc_pdu_encoder_init(&e, out, 100);
* rlc_pdu_encoder_put_bits(&e, 0, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 0, 3); // CPT
* rlc_pdu_encoder_put_bits(&e, 0, 10); // ack_sn
* rlc_pdu_encoder_put_bits(&e, 1, 1); // e1
* rlc_pdu_encoder_put_bits(&e, 1, 10); // nack_sn
* rlc_pdu_encoder_put_bits(&e, 0, 1); // e1
* rlc_pdu_encoder_put_bits(&e, 1, 1); // e2
* rlc_pdu_encoder_put_bits(&e, 14, 15); // so_start
* rlc_pdu_encoder_put_bits(&e, 16, 15); // so_end
* rlc_pdu_encoder_align(&e);
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 8,
ENB_RECV_FAILS, 1,
TIME, 2,
UE_RECV_FAILS, 1,
ENB_SDU, 1, 30,
TIME, 20,
ENB_PDU_SIZE, 14,
TIME, 48,
UE_RECV_FAILS, 0,
TIME, 49,
UE_RECV_FAILS, 1,
TIME, 50,
UE_RECV_FAILS, 0,
TIME, 60,
ENB_RECV_FAILS, 0,
UE_PDU, 8, 0x00, 0x02, 0x00, 0xa0, 0x03, 0x80, 0x08, 0x00,
TIME, 70,
UE_RECV_FAILS, 0,
TIME, -1
/*
* rlc am test function process_received_nack
* case 'check that VT(A) <= sn < VT(S)'
* eNB sends PDU, not received, resends segmented
* we generate a fake control PDU containing nack_sn == 10,
* to fail the 'check ...' and cover the return.
*
* code to generate fake control PDU:
* rlc_pdu_encoder_init(&e, out, 100);
* rlc_pdu_encoder_put_bits(&e, 0, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 0, 3); // CPT
* rlc_pdu_encoder_put_bits(&e, 0, 10); // ack_sn
* rlc_pdu_encoder_put_bits(&e, 1, 1); // e1
* rlc_pdu_encoder_put_bits(&e, 10, 10); // nack_sn
* rlc_pdu_encoder_put_bits(&e, 0, 1); // e1
* rlc_pdu_encoder_put_bits(&e, 0, 1); // e2
* rlc_pdu_encoder_align(&e);
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 30,
ENB_RECV_FAILS, 1,
TIME, 20,
ENB_PDU_SIZE, 14,
TIME, 60,
ENB_RECV_FAILS, 0,
UE_PDU, 4, 0x00, 0x02, 0x05, 0x00,
TIME, -1
/*
* test rlc am simulate rx pdu buffer full
* eNB sends too big PDU to UE, rejected because buffer full
*/
TIME, 1,
MUST_FAIL,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 10, 10, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
TIME, -1
/*
* test rlc am bad PDU
* eNB sends custom PDUs to UE, all of them are wrong for a reason or another
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
/* data PDU, LI == 0
* rlc_pdu_encoder_put_bits(&e, 1, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 0, 1); // RF
* rlc_pdu_encoder_put_bits(&e, 0, 1); // P
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 1, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 10); // SN
* rlc_pdu_encoder_put_bits(&e, 0, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 11); // LI
*/
ENB_PDU, 4, 0x84, 0x00, 0x00, 0x00,
/* data PDU, no data
* rlc_pdu_encoder_put_bits(&e, 1, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 0, 1); // RF
* rlc_pdu_encoder_put_bits(&e, 0, 1); // P
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 0, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 10); // SN
*/
ENB_PDU, 2, 0x80, 0x00,
/* data PDU, LI == 2 > data size == 1
* rlc_pdu_encoder_put_bits(&e, 1, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 0, 1); // RF
* rlc_pdu_encoder_put_bits(&e, 0, 1); // P
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 1, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 10); // SN
* rlc_pdu_encoder_put_bits(&e, 0, 1); // E
* rlc_pdu_encoder_put_bits(&e, 2, 11); // LI
* rlc_pdu_encoder_align(&e);
* rlc_pdu_encoder_put_bits(&e, 0, 8); // 1 byte of data
*/
ENB_PDU, 5, 0x84, 0x00, 0x00, 0x20, 0x00,
/* control PDU, CPT != 0
* rlc_pdu_encoder_put_bits(&e, 0, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 2, 3); // CPT
*/
ENB_PDU, 1, 0x20,
/* data PDU, but only 1 byte
* rlc_pdu_encoder_put_bits(&e, 1, 1); // D/C
* rlc_pdu_encoder_put_bits(&e, 0, 1); // RF
* rlc_pdu_encoder_put_bits(&e, 0, 1); // P
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 1, 1); // E
*/
ENB_PDU, 1, 0x84,
TIME, -1
/*
* basic am test:
* at time 1, eNB receives an SDU of 16000 bytes
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 16000,
TIME, -1
/*
* rlc am test full tx window
* for that eNB sends a lot of small PDUs
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 513,
ENB_PDU_SIZE, 3,
ENB_RECV_FAILS, 1,
ENB_BUFFER_STATUS,
TIME, 511,
UE_BUFFER_STATUS,
TIME, 512,
UE_BUFFER_STATUS,
TIME, 513,
UE_BUFFER_STATUS,
TIME, 557,
ENB_BUFFER_STATUS,
TIME, 558,
ENB_BUFFER_STATUS,
TIME, 559,
ENB_BUFFER_STATUS,
TIME, 600,
ENB_BUFFER_STATUS,
ENB_RECV_FAILS, 0,
TIME, -1
/*
* rlc am test big SDU (size > 2047)
* first generate SDU with exactly 2047 bytes
* later on generate SDU with exactly 2048 bytes
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 20,
ENB_SDU, 1, 2047,
ENB_SDU, 2, 20,
ENB_PDU_SIZE, 2200,
TIME, 10,
ENB_SDU, 3, 20,
ENB_SDU, 4, 2048,
ENB_SDU, 5, 20,
TIME, -1
/*
* am test: ask for retx with TX buffer too small
* then ask for status with buffer too small
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 100,
UE_RECV_FAILS, 1,
TIME, 47,
ENB_PDU_SIZE, 4,
ENB_BUFFER_STATUS,
UE_BUFFER_STATUS,
TIME, 48,
ENB_PDU_SIZE, 1000,
UE_PDU_SIZE, 1,
UE_BUFFER_STATUS,
UE_RECV_FAILS, 0,
TIME, 49,
UE_BUFFER_STATUS,
TIME, 50,
UE_PDU_SIZE, 1000,
UE_BUFFER_STATUS,
TIME, -1
/*
* am test: basic test with poll_byte == 1
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, 1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, 1, 4,
ENB_SDU, 0, 30,
ENB_PDU_SIZE, 10,
TIME, -1
/*
* am test: basic test with poll_pdu == 2
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, 2, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, 2, -1, 4,
ENB_SDU, 0, 50,
ENB_PDU_SIZE, 10,
TIME, -1
/*
* am test: reject SDU because not enough room in rx buffer
*/
TIME, 1,
ENB_AM, 10, 10, 35, 0, 45, -1, -1, 4,
UE_AM, 10, 10, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 50,
TIME, -1
/*
* am test: test function check_t_poll_retransmit
* case 'PDU with SN = VT(S)-1 not found?'
* eNB sends some PDUs, UE receives none
* then UE receives the first retransmitted PDU and nothing more
* until poll retransmit occurs again in the eNB to trigger the case
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
UE_RECV_FAILS, 1,
TIME, 2,
ENB_SDU, 1, 10,
TIME, 3,
ENB_SDU, 2, 10,
TIME, 4,
ENB_SDU, 3, 10,
TIME, 50,
UE_RECV_FAILS, 0,
TIME, 51,
UE_RECV_FAILS, 1,
TIME, 100,
UE_RECV_FAILS, 0,
TIME, -1
/*
* am test: test function check_t_poll_retransmit
* case 'do we meet conditions of 36.322 5.2.2.3?'
* eNB sends one PDU, UE does not receive
* just before calling check_t_poll_retransmit, eNB receives a new SDU
* for the function 'check_poll_after_pdu_assembly' to fail
* then UE receives all what eNB sends
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
UE_RECV_FAILS, 1,
TIME, 47,
ENB_SDU, 1, 10,
UE_RECV_FAILS, 0,
TIME, -1
/*
* am test: test function check_t_reordering,
* case 'update VR(MS) to first SN >= VR(X) for which not
* all PDU segments have been received'
* eNB sends 3 PDUs, first not received, two others received
* later on, everything is received
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
UE_RECV_FAILS, 1,
TIME, 2,
UE_RECV_FAILS, 0,
ENB_SDU, 1, 10,
TIME, 3,
ENB_SDU, 2, 10,
TIME, -1
/*
* am test: test function check_t_reordering,
* case 'VR(H) > VR(MS)'
* eNB sends 4 PDUs, only 1st and 3rd are received
* later on, everything is received
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
UE_RECV_FAILS, 1,
TIME, 2,
UE_RECV_FAILS, 0,
ENB_SDU, 1, 10,
TIME, 3,
UE_RECV_FAILS, 1,
ENB_SDU, 2, 10,
TIME, 4,
UE_RECV_FAILS, 0,
ENB_SDU, 3, 10,
TIME, -1
/*
* basic am test:
* at time 1, eNB receives an SDU of 16001 bytes
*/
TIME, 1,
MUST_FAIL,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 16001,
TIME, -1
/*
* am test: test function generate_status
* enter the while loop 'go to highest full sn+1 for ACK'
* eNB sends several PDUs, only the last is received
* UE sends status PDU of a chosen size that let the code enter the while
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 70,
ENB_PDU_SIZE, 12,
UE_RECV_FAILS, 1,
TIME, 7,
UE_RECV_FAILS, 0,
UE_PDU_SIZE, 12,
TIME, -1
/*
* um test: several SDUs in a PDU (field length 5 bits)
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
ENB_SDU, 0, 10,
ENB_SDU, 1, 20,
ENB_SDU, 2, 30,
TIME, -1
/*
* um test: several SDUs in a PDU (field length 10 bits)
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 10,
UE_UM, 100000, 100000, 35, 10,
ENB_SDU, 0, 10,
ENB_SDU, 1, 20,
ENB_SDU, 2, 30,
TIME, -1
/*
* um test: test function rlc_um_reassemble_pdu, discard SDU
* case '!(fi & 0x02'
* eNB sends 33 PDUs covering 1 SDU, only PDU 0 received (with SN=0 and FI=1)
* then eNB sends 1 PDU covering 1 SDU (so SN=1 and FI=0 for this one)
* received by UE
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
ENB_SDU, 0, 33,
ENB_PDU_SIZE, 2,
TIME, 2,
UE_RECV_FAILS, 1,
TIME, 34,
UE_RECV_FAILS, 0,
ENB_SDU, 1, 1,
TIME, -1
/*
* um test: trigger some cases in rlc_um_reception_actions
* eNB sends several PDUs, only the beginning PDUs and ending PDUs are
* received. Middle PDUs are not.
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
ENB_SDU, 0, 40,
ENB_PDU_SIZE, 2,
TIME, 2,
UE_RECV_FAILS, 1,
TIME, 8,
UE_RECV_FAILS, 0,
TIME, -1
/*
* um: discard PDU because rx buffer full
* eNB sends a PDU too big
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 10, 10, 35, 5,
ENB_SDU, 0, 40,
TIME, -1
/*
* um: discard according to 36.322 5.1.2.2.2
* eNB sends many PDUs. 1st is received, then not, then again.
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
ENB_SDU, 0, 33,
ENB_PDU_SIZE, 2,
TIME, 2,
UE_RECV_FAILS, 1,
TIME, 22,
UE_RECV_FAILS, 0,
TIME, -1
/*
* um: some wrong PDUs
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
/* LI == 0
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 1, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 5); // SN
* rlc_pdu_encoder_put_bits(&e, 0, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 11); // LI
*/
ENB_PDU, 3, 0x20, 0x00, 0x00,
/* no data
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 0, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 5); // SN
*/
ENB_PDU, 1, 0x00,
/* LI == 2 >= data_size == 1
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 1, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 5); // SN
* rlc_pdu_encoder_put_bits(&e, 0, 1); // E
* rlc_pdu_encoder_put_bits(&e, 2, 11); // LI
* rlc_pdu_encoder_align(&e);
* rlc_pdu_encoder_put_bits(&e, 0, 8); // 1 byte of data
*/
ENB_PDU, 4, 0x20, 0x00, 0x20, 0x00,
/* PDU with E == 1 but has size 1 byte only (truncated PDU)
* rlc_pdu_encoder_put_bits(&e, 0, 2); // FI
* rlc_pdu_encoder_put_bits(&e, 1, 1); // E
* rlc_pdu_encoder_put_bits(&e, 0, 5); // SN
*/
ENB_PDU, 1, 0x20,
TIME, -1
/*
* um: test some cases of functions tx_pdu_size and rlc_entity_um_generate_pdu
* eNB has too much data to fit in one PDU
* then later eNB wants to send an SDU of size > 2047
* then later eNB sends several SDUs in one PDU
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
ENB_PDU_SIZE, 2050,
ENB_SDU, 0, 1500,
ENB_SDU, 1, 1500,
ENB_SDU, 2, 10,
TIME, 10,
ENB_SDU, 3, 2048,
ENB_SDU, 4, 10,
TIME, 20,
ENB_SDU, 5, 10,
ENB_SDU, 6, 10,
ENB_SDU, 7, 10,
ENB_SDU, 8, 10,
TIME, -1
/*
* um: SDU too big
*/
TIME, 1,
MUST_FAIL,
ENB_UM, 10, 10, 35, 5,
UE_UM, 100, 100, 35, 5,
ENB_SDU, 0, 16001,
TIME, -1
/*
* basic um test: UE field length 5 bits
* at time 1, eNB receives an SDU of 10 bytes
* at time 10, UE receives an SDU of 5 bytes
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
ENB_SDU, 0, 10,
TIME, 10,
UE_SDU, 0, 5,
TIME, -1
/*
* um: not enough room in SDU list
*/
TIME, 1,
ENB_UM, 10, 10, 35, 5,
UE_UM, 100, 100, 35, 5,
ENB_SDU, 0, 20,
ENB_BUFFER_STATUS,
TIME, -1
/*
* um: test function check_t_reordering
* eNB sends PDUs, UE receives some and some not
*/
TIME, 1,
ENB_UM, 10000, 10000, 35, 5,
UE_UM, 10000, 10000, 35, 5,
ENB_SDU, 0, 10,
ENB_SDU, 1, 10,
ENB_SDU, 2, 10,
ENB_SDU, 3, 10,
ENB_SDU, 4, 10,
ENB_SDU, 5, 10,
ENB_SDU, 6, 10,
ENB_SDU, 7, 10,
ENB_SDU, 8, 10,
ENB_SDU, 9, 10,
ENB_SDU, 10, 10,
ENB_SDU, 11, 10,
ENB_SDU, 12, 10,
ENB_SDU, 13, 10,
ENB_SDU, 14, 10,
ENB_SDU, 15, 10,
ENB_SDU, 16, 10,
ENB_SDU, 17, 10,
ENB_SDU, 18, 10,
ENB_SDU, 19, 10,
ENB_SDU, 20, 10,
ENB_SDU, 21, 10,
ENB_SDU, 22, 10,
ENB_SDU, 23, 10,
ENB_SDU, 24, 10,
ENB_SDU, 25, 10,
ENB_PDU_SIZE, 40,
TIME, 2,
UE_RECV_FAILS, 1,
TIME, 3,
UE_RECV_FAILS, 0,
TIME, 6,
UE_RECV_FAILS, 1,
TIME, 7,
UE_RECV_FAILS, 0,
TIME, 8,
UE_RECV_FAILS, 1,
TIME, -1
/*
* am test: test rlc_entity_am_discard_sdu
* eNB and UE get some SDU, later on some are discarded
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
ENB_SDU, 1, 10,
ENB_SDU, 2, 10,
ENB_SDU, 3, 10,
ENB_PDU_SIZE, 23,
TIME, 2,
ENB_DISCARD_SDU, 0,
ENB_DISCARD_SDU, 2,
ENB_DISCARD_SDU, 3,
ENB_DISCARD_SDU, 1,
TIME, 10,
UE_SDU, 0, 5,
UE_SDU, 1, 5,
UE_SDU, 2, 5,
UE_SDU, 3, 5,
UE_SDU, 4, 5,
UE_SDU, 5, 5,
UE_PDU_SIZE, 13,
TIME, 12,
UE_DISCARD_SDU, 3,
UE_DISCARD_SDU, 1,
UE_DISCARD_SDU, 0,
UE_DISCARD_SDU, 5,
UE_DISCARD_SDU, 4,
UE_DISCARD_SDU, 2,
TIME, 30,
UE_SDU, 6, 5,
UE_DISCARD_SDU, 6,
TIME, 31,
UE_SDU, 7, 8,
TIME, -1
/*
* um test: test rlc_entity_um_discard_sdu
* eNB and UE get some SDU, later on some are discarded
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 10,
UE_UM, 100000, 100000, 35, 10,
ENB_SDU, 0, 10,
ENB_SDU, 1, 10,
ENB_SDU, 2, 10,
ENB_SDU, 3, 10,
ENB_PDU_SIZE, 23,
TIME, 2,
ENB_DISCARD_SDU, 0,
ENB_DISCARD_SDU, 2,
ENB_DISCARD_SDU, 3,
ENB_DISCARD_SDU, 1,
TIME, 10,
UE_SDU, 0, 5,
UE_SDU, 1, 5,
UE_SDU, 2, 5,
UE_SDU, 3, 5,
UE_SDU, 4, 5,
UE_SDU, 5, 5,
UE_PDU_SIZE, 13,
TIME, 12,
UE_DISCARD_SDU, 3,
UE_DISCARD_SDU, 1,
UE_DISCARD_SDU, 0,
UE_DISCARD_SDU, 5,
UE_DISCARD_SDU, 4,
UE_DISCARD_SDU, 2,
TIME, 30,
UE_SDU, 6, 5,
UE_DISCARD_SDU, 6,
TIME, 31,
UE_SDU, 7, 8,
TIME, -1
/*
* am: test function rlc_entity_am_reestablishment
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
RE_ESTABLISH,
TIME, 2,
ENB_SDU, 0, 10,
RE_ESTABLISH,
TIME, 3,
ENB_SDU, 0, 40,
ENB_PDU_SIZE, 14,
UE_RECV_FAILS, 1,
TIME, 4,
UE_RECV_FAILS, 0,
TIME, 10,
RE_ESTABLISH,
TIME, -1
/*
* um: test function rlc_entity_am_reestablishment
* and also the function clear_entity, case 'while (cur_rx != NULL)'
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 5,
UE_UM, 100000, 100000, 35, 5,
RE_ESTABLISH,
TIME, 2,
ENB_SDU, 0, 10,
RE_ESTABLISH,
TIME, 3,
ENB_SDU, 0, 10,
ENB_SDU, 0, 10,
ENB_SDU, 0, 10,
ENB_SDU, 0, 10,
ENB_PDU_SIZE, 14,
TIME, 5,
UE_RECV_FAILS, 1,
TIME, 6,
UE_RECV_FAILS, 0,
TIME, 10,
RE_ESTABLISH,
TIME, 998,
ENB_SDU, 0, 10,
ENB_SDU, 0, 10,
UE_RECV_FAILS, 1,
TIME, 999,
UE_RECV_FAILS, 0,
TIME, -1
/*
* basic um test: UE field length 10 bits
* at time 1, eNB receives an SDU of 10 bytes
* at time 10, UE receives an SDU of 5 bytes
*/
TIME, 1,
ENB_UM, 100000, 100000, 35, 10,
UE_UM, 100000, 100000, 35, 10,
ENB_SDU, 0, 10,
TIME, 10,
UE_SDU, 0, 5,
TIME, -1
/*
* rlc am test function segment_already_received
* eNB sends SDU [1..900], not received
* eNB retx with smaller PDUs [1..600] [601..900]
* [1..600] is received but ACK/NACK not
* eNB retx with still smaller PDUs [1..400] [401..600] [601..900]
* all is received, ACKs/NACKs go through
*
* this test will fail if NACK mechanism uses SOstart/SOend
* (not implemented for the moment)
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_SDU, 0, 900,
TIME, 2,
ENB_PDU_SIZE, 600,
UE_RECV_FAILS, 0,
TIME, 48,
UE_RECV_FAILS, 1,
ENB_PDU_SIZE, 400,
TIME, 90,
UE_RECV_FAILS, 0,
ENB_RECV_FAILS, 0,
TIME, -1
/*
* rlc am test function rlc_am_segment_full
* eNB sends SDU [1..900], not received
* eNB retx with smaller PDUs [1..600] [601..900]
* nothing received
* eNB retx with still smaller PDUs [1..400] [401..600] [601..900]
* [401..600] received, ACK goes through
* link clean, all goes through
*
* this test will fail if NACK mechanism uses SOstart/SOend
* (not implemented for the moment)
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_SDU, 0, 900,
TIME, 2,
ENB_PDU_SIZE, 600,
TIME, 48,
ENB_PDU_SIZE, 400,
TIME, 95,
UE_RECV_FAILS, 0,
ENB_RECV_FAILS, 0,
TIME, -1
/*
* basic am test:
* at time 1, eNB receives 10 SDUs of 10 bytes
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
ENB_SDU, 0, 10,
ENB_SDU, 1, 10,
ENB_SDU, 2, 10,
ENB_SDU, 3, 10,
ENB_SDU, 4, 10,
ENB_SDU, 5, 10,
ENB_SDU, 6, 10,
ENB_SDU, 7, 10,
ENB_SDU, 8, 10,
ENB_SDU, 9, 10,
TIME, -1
/*
* rlc am test function rlc_am_reassemble_next_segment
* case 'if pdu_byte is not in [so .. so+len-1]'
* eNB sends SDU [1..30], not received
* eNB retx with smaller PDUs [1..21] [22..30], not received
* eNB retx with still smaller PDUs [1..11] [12..21] [22..30], not received
* custom PDU [12..21] sent to UE, received
* custom PDU [1..21] sent to UE, received
*
* Not sure if in a real setup [12..21] is sent and then [1..21] is sent.
* In the current RLC implementation, this is impossible. If we send [12..21]
* it means [1..21] has been split and so we won't sent it later on.
* Maybe with HARQ retransmissions in PHY/MAC in bad radio conditions?
*
* this test will fail if NACK mechanism uses SOstart/SOend
* (not implemented for the moment)
*/
TIME, 1,
ENB_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_AM, 100000, 100000, 35, 0, 45, -1, -1, 4,
UE_RECV_FAILS, 1,
ENB_RECV_FAILS, 1,
ENB_SDU, 0, 30,
TIME, 2,
ENB_PDU_SIZE, 25,
TIME, 48,
ENB_PDU_SIZE, 15,
TIME, 100,
UE_RECV_FAILS, 0,
ENB_RECV_FAILS, 0,
ENB_PDU, 14, 0xd8, 0x00, 0x00, 0x0b, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14,
TIME, 101,
ENB_PDU, 25, 0xe8, 0x00, 0x00, 0x00, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14,
TIME, -1
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