Commit 47d3c9f7 authored by yankuo's avatar yankuo

add OXGRF support

parent 82597e7e
......@@ -2359,7 +2359,7 @@ if (${T_TRACER})
nr_ulschsim ldpctest polartest smallblocktest cu_test du_test
#all "add_library" definitions
ITTI lte_rrc nr_rrc s1ap x2ap m2ap m3ap f1ap
params_libconfig oai_usrpdevif oai_bladerfdevif oai_lmssdrdevif oai_iqplayer
params_libconfig oai_usrpdevif oai_bladerfdevif oai_lmssdrdevif oai_iqplayer oai_oxgrfdevif
oai_eth_transpro oai_mobipass coding HASHTABLE UTIL OMG_SUMO
SECURITY SCHED_LIB SCHED_NR_LIB SCHED_RU_LIB SCHED_UE_LIB SCHED_NR_UE_LIB default_sched remote_sched RAL
NFAPI_COMMON_LIB NFAPI_LIB NFAPI_PNF_LIB NFAPI_VNF_LIB NFAPI_USER_LIB
......
......@@ -93,7 +93,7 @@ Options:
--UE-gen-nvram [output path]
Specify gen_nvram_path (default \"$gen_nvram_path\")
-w | --hardware
USRP, BLADERF, LMSSDR, IRIS, SIMU, AW2SORI, None (Default)
USRP, BLADERF, LMSSDR, IRIS, SIMU, AW2SORI, OXGRF, None (Default)
Adds this RF board support (in external packages installation and in compilation)
-t | --transport
Selects the transport protocol type, options: None, Ethernet, benetel4g, benetel5g
......@@ -272,7 +272,7 @@ function main() {
shift;;
-w | --hardware)
case "$2" in
"USRP" | "BLADERF" | "LMSSDR" | "IRIS")
"USRP" | "BLADERF" | "LMSSDR" | "IRIS" | "OXGRF")
HW="OAI_"$2
TARGET_LIST="$TARGET_LIST oai_${2,,}devif" # ,, makes lowercase
CMAKE_CMD="$CMAKE_CMD -DOAI_$2=ON"
......@@ -457,6 +457,10 @@ function main() {
flash_firmware_bladerf
fi
fi
if [ "$HW" == "OAI_OXGRF" ] ; then
echo_info "installing packages for OXGRF support"
#check_install_oxgrf_driver
fi
if [ "$HW" == "OAI_IRIS" ] ; then
echo_info "installing packages for IRIS support"
check_install_soapy
......
......@@ -400,6 +400,34 @@ install_usrp_uhd_driver() {
fi
}
check_install_oxgrf_driver() {
#if modinfo riffa > /dev/null 2>&1
if modinfo xdma > /dev/null 2>&1
then
echo_success "OXGRF driver has loaded."
else
git clone https://github.com/v3best/riffa /tmp/riffa
if [ $? -ne 0 ]; then
echo_fatal "OXGRF driver download failed, please check your net connection."
else
cd /tmp/riffa/driver/linux
make && $SUDO make install
echo_success "OXGRF driver install success, please restart your PC later."
fi
git clone https://github.com/v3best/liboxgrf /tmp/liboxgrf
if [ $? -ne 0 ]; then
echo_fatal "OXGRF API download failed, please check your net connection."
else
cd /tmp/liboxgrf
mkdir build
cd build
cmake ../
make && $SUDO make install && $SUDO ldconfig
echo_success "OXGRF API install success, please restart your PC later."
fi
fi
}
install_bladerf_driver_from_source(){
bladerf_install_log=$OPENAIR_DIR/cmake_targets/log/bladerf_install_log.txt
echo_info "\nInstalling BladeRF driver from sources. The log file for BladeRF driver installation is here: $bladerf_install_log "
......
......@@ -73,6 +73,7 @@
#define CONFIG_HLP_PRB "Set the PRB, valid values: 6, 25, 50, 100 \n"
#define CONFIG_HLP_DLSHIFT "dynamic shift for LLR compuation for TM3/4 (default 0)\n"
#define CONFIG_HLP_USRP_ARGS "set the arguments to identify USRP (same syntax as in UHD)\n"
#define CONFIG_HLP_OXGRF_ARGS "set the arguments to identify OXGRF\n"
#define CONFIG_HLP_DMAMAP "use DMA memory mapping\n"
#define CONFIG_HLP_TDD "Set hardware to TDD mode (default: FDD). Used only with -U (otherwise set in config file).\n"
#define CONFIG_HLP_TADV "Set timing_advance\n"
......@@ -104,6 +105,7 @@
{"r" , CONFIG_HLP_PRB, 0, .u8ptr=&(frame_parms[0]->N_RB_DL), .defintval=25, TYPE_UINT8, 0}, \
{"dlsch-demod-shift", CONFIG_HLP_DLSHIFT, 0, .iptr=(int32_t *)&dlsch_demod_shift, .defintval=0, TYPE_INT, 0}, \
{"usrp-args", CONFIG_HLP_USRP_ARGS, 0, .strptr=&usrp_args, .defstrval="type=b200",TYPE_STRING, 0}, \
{"oxgrf-args", CONFIG_HLP_OXGRF_ARGS, 0, .strptr=&oxgrf_args, .defstrval="dev=pciex:0",TYPE_STRING, 0}, \
{"mmapped-dma", CONFIG_HLP_DMAMAP, PARAMFLAG_BOOL, .uptr=&mmapped_dma, .defintval=0, TYPE_INT, 0}, \
{"T" , CONFIG_HLP_TDD, PARAMFLAG_BOOL, .iptr=&tddflag, .defintval=0, TYPE_INT, 0}, \
{"A", CONFIG_HLP_TADV, 0, .iptr=&(timingadv), .defintval=0, TYPE_INT, 0}, \
......
......@@ -159,6 +159,8 @@ int transmission_mode=1;
char *usrp_args=NULL;
char *usrp_clksrc=NULL;
char *oxgrf_args=NULL;
THREAD_STRUCT thread_struct;
/* struct for ethernet specific parameters given in eNB conf file */
eth_params_t *eth_params;
......@@ -470,6 +472,7 @@ void init_openair0(LTE_DL_FRAME_PARMS *frame_parms,int rxgain) {
}
if (usrp_args) openair0_cfg[card].sdr_addrs = usrp_args;
if (oxgrf_args) openair0_cfg[card].sdr_addrs = oxgrf_args;
}
}
......
......@@ -103,6 +103,8 @@
#define CONFIG_HLP_TX_SUBDEV "set the arguments to select tx_subdev (same syntax as in UHD)\n"
#define CONFIG_HLP_RX_SUBDEV "set the arguments to select rx_subdev (same syntax as in UHD)\n"
#define CONFIG_HLP_OXGRF_ARGS "set the arguments to identify OXGRF\n"
#define CONFIG_HLP_FLOG "Enable online log \n"
#define CONFIG_HLP_LOGL "Set the global log level, valid options: (4:trace, 3:debug, 2:info, 1:warn, (0:error))\n"
#define CONFIG_HLP_LOGV "Set the global log verbosity \n"
......
......@@ -120,6 +120,7 @@ int vcdflag = 0;
double rx_gain_off = 0.0;
char *usrp_args = NULL;
char *oxgrf_args = NULL;
char *tx_subdev = NULL;
char *rx_subdev = NULL;
char *rrc_config_path = NULL;
......@@ -363,6 +364,7 @@ void init_openair0(void) {
openair0_cfg[card].configFilename = get_softmodem_params()->rf_config_file;
if (usrp_args) openair0_cfg[card].sdr_addrs = usrp_args;
if (oxgrf_args) openair0_cfg[card].sdr_addrs = oxgrf_args;
if (tx_subdev) openair0_cfg[card].tx_subdev = tx_subdev;
if (rx_subdev) openair0_cfg[card].rx_subdev = rx_subdev;
......
......@@ -31,6 +31,7 @@
// clang-format off
#define CMDLINE_NRUEPARAMS_DESC { \
{"usrp-args", CONFIG_HLP_USRP_ARGS, 0, .strptr=&usrp_args, .defstrval="type=b200", TYPE_STRING, 0}, \
{"oxgrf-args", CONFIG_HLP_OXGRF_ARGS, 0, .strptr=&oxgrf_args, .defstrval="dev=pciex:0", TYPE_STRING, 0}, \
{"tx_subdev", CONFIG_HLP_TX_SUBDEV, 0, .strptr=&tx_subdev, .defstrval=NULL, TYPE_STRING, 0}, \
{"rx_subdev", CONFIG_HLP_RX_SUBDEV, 0, .strptr=&rx_subdev, .defstrval=NULL, TYPE_STRING, 0}, \
{"single-thread-disable", CONFIG_HLP_NOSNGLT, PARAMFLAG_BOOL, .iptr=&single_thread_flag, .defintval=1, TYPE_INT, 0}, \
......
......@@ -43,6 +43,7 @@
* @defgroup _GENERIC_PHY_RF_INTERFACE_ Generic PHY - RF Interface
* @defgroup _USRP_PHY_RF_INTERFACE_ PHY - USRP RF Interface
* @defgroup _BLADERF_PHY_RF_INTERFACE_ PHY - BLADERF RF Interface
* @defgroup _OXGRF_PHY_RF_INTERFACE_ PHY - OXGRF RF Interface
* @defgroup _LMSSDR_PHY_RF_INTERFACE_ PHY - LMSSDR RF Interface
* @}
* @}
......
......@@ -32,3 +32,8 @@ add_boolean_option(OAI_USRP OFF "Activate OAI's USRP driver" OFF)
if(OAI_USRP)
add_subdirectory(USRP)
endif()
add_boolean_option(OAI_OXGRF OFF "Activate OAI's OXGRF driver" OFF)
if(OAI_OXGRF)
add_subdirectory(OXGRF)
endif()
......@@ -44,7 +44,7 @@
#include "executables/softmodem-common.h"
const char *const devtype_names[MAX_RF_DEV_TYPE] =
{"", "USRP B200", "USRP X300", "USRP N300", "USRP X400", "BLADERF", "LMSSDR", "IRIS", "No HW", "UEDv2", "RFSIMULATOR"};
{"", "USRP B200", "USRP X300", "USRP N300", "USRP X400", "BLADERF", "OXGRF", "LMSSDR", "IRIS", "No HW", "UEDv2", "RFSIMULATOR"};
const char *get_devname(int devtype) {
if (devtype < MAX_RF_DEV_TYPE && devtype !=MIN_RF_DEV_TYPE )
......
......@@ -93,6 +93,8 @@ typedef enum {
USRP_X400_DEV,
/*!\brief device is BLADE RF*/
BLADERF_DEV,
/*!\brief device is OXGRF pcie*/
OXGRF_DEV,
/*!\brief device is LMSSDR (SoDeRa)*/
LMSSDR_DEV,
/*!\brief device is Iris */
......
find_library(oxgrf_ss NAMES oxgrf_ss)
add_library(oai_oxgrfdevif MODULE oxgrf_lib.c)
target_link_libraries(oai_oxgrfdevif PRIVATE oxgrf_ss)
target_link_libraries(oai_oxgrfdevif PRIVATE UTIL)
set_target_properties(oai_oxgrfdevif PROPERTIES LIBRARY_OUTPUT_DIRECTORY ${CMAKE_BINARY_DIR})
add_custom_command(TARGET oai_oxgrfdevif POST_BUILD
COMMAND ${CMAKE_COMMAND} -E create_symlink liboai_oxgrfdevif.so liboai_device.so
WORKING_DIRECTORY ${CMAKE_BINARY_DIR})
/*
* 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 1.0 (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
*/
/** oxgrf_lib.c
*
* Author: eric
* base on bladerf_lib.c
*/
#pragma GCC optimize(3, "Ofast", "inline")
#include <stdio.h>
#include <stdlib.h>
#include <stdbool.h>
#include <unistd.h>
#include <string.h>
#include <inttypes.h>
#include <math.h>
#include "oxgrf_lib.h"
#include "rf_helper.h"
#include "common/utils/LOG/log.h"
/** @addtogroup _OXGRF_PHY_RF_INTERFACE_
* @{
*/
#include "openair1/PHY/sse_intrin.h"
//! Number of OXGRF devices
int num_devices = 0;
static bool running = false;
#define BUFFER_SIZE (122880 * 100 * sizeof(int))
#define NCHAN_PER_DEV 4
static void *cache_buf[NCHAN_PER_DEV];
static void *iq_buf[NCHAN_PER_DEV];
static uint32_t remain = 0;
static uint32_t RX_MTU = 30720;
static uint8_t shift = 2;
static inline int channel_to_mask(int channel_count)
{
uint8_t ch_mask;
switch (channel_count) {
case 4:
ch_mask = 0xf;break;
case 3:
ch_mask = 0x7;break;
case 2:
ch_mask = 0x3;break;
case 1:
ch_mask = 0x1;break;
default:
ch_mask = 0x1;break;
}
return ch_mask;
}
/*! \brief get current timestamp
*\param device the hardware to use
*\returns timestamp of OXGRF
*/
openair0_timestamp trx_get_timestamp(openair0_device *device) {
return 0;
}
/*! \brief Start oxgrf
* \param device the hardware to use
* \returns 0 on success
*/
int trx_oxgrf_start(openair0_device *device) {
LOG_I(HW, "[oxgrf] Start oxgrf ...\n");
running = true;
return 0;
}
/*! \brief Called to send samples to the oxgrf RF target
\param device pointer to the device structure specific to the RF hardware target
\param timestamp The timestamp at whicch the first sample MUST be sent
\param buff Buffer which holds the samples
\param nsamps number of samples to be sent
\param cc index of the component carrier
\param flags Ignored for the moment
\returns 0 on success
*/
static int trx_oxgrf_write(openair0_device *device,openair0_timestamp timestamp, void **buff, int nsamps, int cc, int flags) {
int status;
oxgrf_state_t *oxgrf = (oxgrf_state_t*)device->priv;
uint32_t trx_flags = 0;
radio_tx_burst_flag_t flags_burst = (radio_tx_burst_flag_t) (flags & 0xf);
if (flags_burst == TX_BURST_START) {
trx_flags = 0;
} else if (flags_burst == TX_BURST_END) {
trx_flags = 1;
} else if (flags_burst == TX_BURST_START_AND_END) {
trx_flags = 1;
} else if (flags_burst == TX_BURST_MIDDLE) {
trx_flags = 0;
}
for(int i = 0; i < cc; i++) {
int len = nsamps * 2;
int16_t *iq = buff[i];
#if defined(__x86_64) || defined(__i386__)
__m256i a, *b;
while (len >= 16) {
a = *(__m256i *)&iq[0];
b = (__m256i *)&iq[0];
*b = simde_mm256_slli_epi16(a, 4);
iq += 16;
len -= 16;
}
#elif defined(__arm__) || defined(__aarch64__)
int16x8_t a, *b;
while (len >= 8) {
a = *(int16x8_t *)&iq[0];
b = (int16x8_t *)&iq[0];
*b = vshlq_n_s16(a, 4);
iq += 8;
len -= 8;
}
#endif
/* remaining data */
while (len != 0) {
iq[0] <<= 4;
iq++;
len--;
}
}
status = oxgrf_write_samples_multiport(oxgrf->dev, (const void **)buff, nsamps, channel_to_mask(cc), timestamp, trx_flags);
if (status < 0) {
oxgrf->num_tx_errors++;
LOG_E(HW, "[oxgrf] Failed to TX samples\n");
exit(-1);
}
//LOG_D(HW, "Provided TX timestamp: %u, nsamps: %u\n", ptimestamp, nsamps);
oxgrf->tx_current_ts = timestamp;
oxgrf->tx_nsamps += nsamps;
oxgrf->tx_count++;
return nsamps;
}
/*! \brief Receive samples from hardware.
* Read \ref nsamps samples from each channel to buffers. buff[0] is the array for
* the first channel. *ptimestamp is the time at which the first sample
* was received.
* \param device the hardware to use
* \param[out] ptimestamp the time at which the first sample was received.
* \param[out] buff An array of pointers to buffers for received samples. The buffers must be large enough to hold the number of samples \ref nsamps.
* \param nsamps Number of samples. One sample is 2 byte I + 2 byte Q => 4 byte.
* \param cc Index of component carrier
* \returns number of samples read
*/
static int trx_oxgrf_read(openair0_device *device, openair0_timestamp *ptimestamp, void **buff, int nsamps, int cc) {
int status;
oxgrf_state_t *oxgrf = (oxgrf_state_t *)device->priv;
uint64_t timestamp = 0UL;
retry:
if(remain == 0) {
int recv = 0;
timestamp = 0UL;
if(nsamps % RX_MTU) {
recv = (nsamps / RX_MTU + 1) * RX_MTU;
status = oxgrf_read_samples_multiport(oxgrf->dev, iq_buf, recv, channel_to_mask(cc), &timestamp);
if (status < 0) {
LOG_E(HW, "[oxgrf] Failed to read samples %d\n", nsamps);
oxgrf->num_rx_errors++;
exit(-1);
}
for(int i = 0; i < cc; i++)
memcpy(buff[i], iq_buf[i], nsamps * 4);
if(recv > nsamps) {
for(int i = 0; i < cc; i++)
memcpy(cache_buf[i], iq_buf[i] + nsamps * 4, (recv - nsamps) * 4);
remain = recv - nsamps;
}
} else {
recv = nsamps;
status = oxgrf_read_samples_multiport(oxgrf->dev, buff, recv, channel_to_mask(cc), &timestamp);
if (status < 0) {
LOG_E(HW, "[oxgrf] Failed to read samples %d\n", nsamps);
oxgrf->num_rx_errors++;
exit(-1);
}
}
*(uint64_t *)ptimestamp = timestamp;
oxgrf->rx_current_ts = timestamp + nsamps;
//LOG_D(HW, "case 0: Current RX timestamp %"PRIu64", hw ts %"PRIu64", nsamps %u, remain %u, recv: %u\n", *ptimestamp, timestamp, nsamps, remain, recv);
} else if(remain >= nsamps) {
for(int i = 0; i < cc; i++)
memcpy(buff[i], cache_buf[i], nsamps * 4);
remain -= nsamps;
if(remain > 0) {
for(int i = 0; i < cc; i++)
memmove(cache_buf[i], cache_buf[i] + nsamps * 4, remain * 4);
}
*(uint64_t *)ptimestamp = oxgrf->rx_current_ts;
oxgrf->rx_current_ts += nsamps;
//LOG_D(HW, "case 1: Current RX timestamp %"PRIu64", nsamps %u, remain %u\n", *ptimestamp, nsamps, remain);
} else {
int recv;
if(remain + RX_MTU >= nsamps)
recv = RX_MTU;
else
recv = (nsamps / RX_MTU + 1) * RX_MTU;
timestamp = 0UL;
status = oxgrf_read_samples_multiport(oxgrf->dev, iq_buf, recv, channel_to_mask(cc), &timestamp);
if (status < 0) {
LOG_E(HW, "[oxgrf] Failed to read samples %d\n", nsamps);
oxgrf->num_rx_errors++;
exit(-1);
}
if(timestamp != (oxgrf->rx_current_ts + remain)) {
int overflow = timestamp - (oxgrf->rx_current_ts + remain);
LOG_W(HW, "Rx overflow %u samples\n", overflow);
//remain += overflow;
remain = 0;
goto retry;
}
for(int i = 0; i < cc; i++)
memcpy(cache_buf[i] + remain * 4, iq_buf[i], recv * 4);
for(int i = 0; i < cc; i++)
memcpy(buff[i], cache_buf[i], nsamps * 4);
remain = recv + remain - nsamps;
for(int i = 0; i < cc; i++)
memmove(cache_buf[i], cache_buf[i] + nsamps * 4, remain * 4);
*(uint64_t *)ptimestamp = oxgrf->rx_current_ts;
oxgrf->rx_current_ts += nsamps;
//LOG_D(HW, "case 2: Current RX timestamp %"PRIu64", hw ts %"PRIu64", nsamps %u, remain %u, recv: %u\n", *ptimestamp, timestamp, nsamps, remain, recv);
}
for(int i = 0; i < cc; i++) {
int len = nsamps * 2;
int16_t *iq = buff[i];
#if defined(__x86_64__) || defined(__i386__)
__m256i a, *b;
while (len >= 16) {
a = *(__m256i *)&iq[0];
b = (__m256i *)&iq[0];
*b = simde_mm256_srai_epi16(a, shift);
iq += 16;
len -= 16;
}
#elif defined(__arm__) || defined(__aarch64__)
int16x8_t a, *b;
while (len >= 8) {
a = *(int16x8_t *)&iq[0];
b = (int16x8_t *)&iq[0];
*b = vshrq_n_s16(a, shift);
iq += 8;
len -= 8;
}
#endif
/* remaining data */
while (len != 0) {
iq[0] >>= shift;
iq++;
len--;
}
}
//LOG_D(HW, "Current RX timestamp %"PRIu64", nsamps %u\n", *ptimestamp, nsamps);
oxgrf->rx_nsamps += nsamps;
oxgrf->rx_count++;
return nsamps;
}
/*! \brief Terminate operation of the oxgrf transceiver -- free all associated resources
* \param device the hardware to use
*/
void trx_oxgrf_end(openair0_device *device) {
oxgrf_state_t *oxgrf = (oxgrf_state_t*)device->priv;
if(!running)
return;
running = false;
LOG_I(HW, ">>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>\n");
for(int i = 0; i < oxgrf->tx_num_channels; i++) {
uint32_t count = 0;
oxgrf_get_channel_event(oxgrf->dev, TX_CHANNEL_TIMEOUT, i+1, &count);
LOG_I(HW, "[oxgrf] TX%d Channel timeout: %u\n", i+1, count);
}
for(int i = 0; i < oxgrf->rx_num_channels; i++) {
uint32_t count = 0;
oxgrf_get_channel_event(oxgrf->dev, RX_CHANNEL_OVERFLOW, i+1, &count);
LOG_I(HW, "[oxgrf] RX%d Channel overflow: %u\n", i+1, count);
}
LOG_I(HW, "<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<\n");
oxgrf_close_device(oxgrf->dev);
return;
}
/*! \brief print the oxgrf statistics
* \param device the hardware to use
* \returns 0 on success
*/
int trx_oxgrf_get_stats(openair0_device* device) {
return(0);
}
/*! \brief Reset the oxgrf statistics
* \param device the hardware to use
* \returns 0 on success
*/
int trx_oxgrf_reset_stats(openair0_device* device) {
return(0);
}
/*! \brief Stop oxgrf
* \param card the hardware to use
* \returns 0 in success
*/
int trx_oxgrf_stop(openair0_device* device) {
return(0);
}
/*! \brief Set frequencies (TX/RX)
* \param device the hardware to use
* \param openair0_cfg RF frontend parameters set by application
* \param dummy dummy variable not used
* \returns 0 in success
*/
int trx_oxgrf_set_freq(openair0_device* device, openair0_config_t *openair0_cfg) {
int status;
oxgrf_state_t *oxgrf = (oxgrf_state_t *)device->priv;
if(oxgrf->tx_lo_freq != openair0_cfg->tx_freq[0]) {
if ((status = oxgrf_set_tx_lo_freq(oxgrf->dev, 0, (uint64_t)(openair0_cfg->tx_freq[0]))) < 0) {
LOG_E(HW, "[oxgrf] Failed to set TX frequency\n");
} else {
LOG_I(HW, "[oxgrf] set TX frequency to %lu\n",(uint64_t)(openair0_cfg->tx_freq[0]));
oxgrf->tx_lo_freq = openair0_cfg->tx_freq[0];
}
}
if(oxgrf->rx_lo_freq != openair0_cfg->rx_freq[0]) {
if ((status = oxgrf_set_rx_lo_freq(oxgrf->dev, 0, (uint64_t)(openair0_cfg->rx_freq[0]))) < 0) {
LOG_E(HW, "[oxgrf] Failed to set RX frequency\n");
} else {
LOG_I(HW, "[oxgrf] set RX frequency to %lu\n",(uint64_t)(openair0_cfg->rx_freq[0]));
oxgrf->rx_lo_freq = openair0_cfg->rx_freq[0];
}
}
return(0);
}
/*! \brief calibration table for OXGRF */
rx_gain_calib_table_t calib_table_oxgrf[] = {
{3500000000.0, 72.0},
{2660000000.0, 72.0},
{2300000000.0, 72.0},
{1880000000.0, 72.0},
{816000000.0, 72.0},
{-1,0}
};
/*! \brief set RX gain offset from calibration table
* \param openair0_cfg RF frontend parameters set by application
* \param chain_index RF chain ID
*/
void set_rx_gain_offset(openair0_config_t *openair0_cfg, int chain_index) {
int i = 0;
// loop through calibration table to find best adjustment factor for RX frequency
double min_diff = 6e9, diff;
while (openair0_cfg->rx_gain_calib_table[i].freq > 0) {
diff = fabs(openair0_cfg->rx_freq[chain_index] - openair0_cfg->rx_gain_calib_table[i].freq);
printf("cal %d: freq %f, offset %f, diff %f\n",
i,
openair0_cfg->rx_gain_calib_table[i].freq,
openair0_cfg->rx_gain_calib_table[i].offset, diff);
if (min_diff > diff) {
min_diff = diff;
openair0_cfg->rx_gain_offset[chain_index] = openair0_cfg->rx_gain_calib_table[i].offset;
}
i++;
}
}
/*! \brief Set Gains (TX/RX)
* \param device the hardware to use
* \param openair0_cfg openair0 Config structure
* \returns 0 in success
*/
int trx_oxgrf_set_gains(openair0_device* device, openair0_config_t *openair0_cfg) {
int ret = 0;
oxgrf_state_t *oxgrf = (oxgrf_state_t *)device->priv;
if (openair0_cfg->rx_gain[0] > 65+openair0_cfg->rx_gain_offset[0]) {
LOG_E(HW, "[oxgrf] Reduce RX Gain 0 by %f dB\n", openair0_cfg->rx_gain[0] - openair0_cfg->rx_gain_offset[0] - 65);
return -1;
}
if ((ret = oxgrf_set_rx1_rf_gain(oxgrf->dev, 0, (uint32_t)(openair0_cfg->rx_gain[0] - openair0_cfg->rx_gain_offset[0]))) < 0) {
LOG_I(HW, "[oxgrf] Failed to set RX1 gain\n");
} else
LOG_I(HW, "[oxgrf] set RX1 gain to %u\n",(uint32_t)(openair0_cfg->rx_gain[0]));
if(oxgrf->rx_num_channels > 1) {
if ((ret = oxgrf_set_rx2_rf_gain(oxgrf->dev, 0, (uint32_t)(openair0_cfg->rx_gain[1] - openair0_cfg->rx_gain_offset[0]))) < 0) {
LOG_E(HW, "[oxgrf] Failed to set RX2 gain\n");
} else
LOG_I(HW, "[oxgrf] set RX gain to %u\n",(uint32_t)(openair0_cfg->rx_gain[1]));
}
#if 0
if ((ret = oxgrf_set_tx1_attenuation(oxgrf->dev, 0, openair0_cfg->tx_gain[0] * 1000)) < 0) {
LOG_E(HW, "[oxgrf] Failed to set TX1 gain\n");
} else
LOG_I(HW, "[oxgrf] set the TX1 gain to %d\n", 90 - (uint32_t)openair0_cfg->tx_gain[0]);
if(oxgrf->tx_num_channels > 1) {
if ((ret = oxgrf_set_tx2_attenuation(oxgrf->dev, 0, openair0_cfg->tx_gain[1] * 1000)) < 0) {
LOG_E(HW, "[oxgrf] Failed to set TX2 gain\n");
} else
LOG_I(HW, "[oxgrf] set the TX2 gain to %d\n", 90 - (uint32_t)openair0_cfg->tx_gain[1]);
}
#endif
return(ret);
}
/*! \brief Initialize Openair oxgrf target. It returns 0 if OK
* \param device the hardware to use
* \param openair0_cfg RF frontend parameters set by application
* \returns 0 on success
*/
int device_init(openair0_device *device, openair0_config_t *openair0_cfg) {
int status;
oxgrf_state_t *oxgrf = (oxgrf_state_t*)malloc(sizeof(oxgrf_state_t));
memset(oxgrf, 0, sizeof(oxgrf_state_t));
LOG_I(HW, "[oxgrf] openair0_cfg[0].sdr_addrs == '%s'\n", openair0_cfg[0].sdr_addrs);
LOG_I(HW, "[oxgrf] openair0_cfg[0].rx_num_channels == '%d'\n", openair0_cfg[0].rx_num_channels);
LOG_I(HW, "[oxgrf] openair0_cfg[0].tx_num_channels == '%d'\n", openair0_cfg[0].tx_num_channels);
openair0_cfg[0].rx_gain_calib_table = calib_table_oxgrf;
set_rx_gain_offset(openair0_cfg, 0);
if(oxgrf->rx_num_channels > 1)
set_rx_gain_offset(openair0_cfg, 1);
openair0_cfg->iq_txshift = 0;
openair0_cfg->iq_rxrescale = 15; /*not sure*/ //FIXME: adjust to oxgrf
oxgrf->sample_rate = (unsigned int)openair0_cfg->sample_rate;
LOG_I(HW, "[oxgrf] sampling_rate %d\n", oxgrf->sample_rate);
oxgrf->rx_num_channels = openair0_cfg[0].rx_num_channels;
oxgrf->tx_num_channels = openair0_cfg[0].tx_num_channels;
RX_MTU = openair0_cfg->sample_rate / 1000 / 2;
if(RX_MTU > 30720)
RX_MTU = 30720;
else if(!(RX_MTU % 5760))
RX_MTU = 5760;
bool rx_ant = true;
bool pa_status = false;
int auxdac1 = 0;
char args[64];
if (openair0_cfg[0].sdr_addrs == NULL) {
strcpy(args, "dev=pciex:0");
} else {
strcpy(args, openair0_cfg[0].sdr_addrs);
}
char dev_str[64];
const char dev_arg[] = "dev=";
char *dev_ptr = strstr(args, dev_arg);
if(dev_ptr) {
copy_subdev_string(dev_str, dev_ptr + strlen(dev_arg));
remove_substring(args, dev_arg);
remove_substring(args, dev_str);
LOG_I(HW, "[oxgrf] Using %s\n", dev_str);
}
const char auxdac1_arg[] = "auxdac1=";
char auxdac1_str[64] = {0};
char *auxdac1_ptr = strstr(args, auxdac1_arg);
if(auxdac1_ptr) {
copy_subdev_string(auxdac1_str, auxdac1_ptr + strlen(auxdac1_arg));
remove_substring(args, auxdac1_arg);
remove_substring(args, auxdac1_str);
auxdac1 = atoi(auxdac1_str);
LOG_I(HW, "[oxgrf] Setting auxdac1:%u\n", auxdac1);
}
const char pa_arg[] = "pa=";
char pa_str[64] = {0};
char *pa_ptr = strstr(args, pa_arg);
if(pa_ptr) {
copy_subdev_string(pa_str, pa_ptr + strlen(pa_arg));
remove_substring(args, pa_arg);
remove_substring(args, pa_str);
pa_status = !strcmp(pa_str, "enabled");
LOG_I(HW, "[oxgrf] PA Status:%s\n", pa_status?"Enabled":"Disabled");
}
const char ant_arg[] = "rx_ant=";
char ant_str[64] = {0};
char *ant_ptr = strstr(args, ant_arg);
if(ant_ptr) {
copy_subdev_string(ant_str, ant_ptr + strlen(ant_arg));
remove_substring(args, ant_arg);
remove_substring(args, ant_str);
rx_ant = strcmp(ant_str, "trx");
}
char dstring[128];
if(RX_MTU < 30720) {
sprintf(dstring, ",nsamples_recv_frame:%u", RX_MTU);
strcat(dev_str, dstring);
}
if ((oxgrf->dev = oxgrf_open_device(dev_str)) == NULL ) {
LOG_E(HW, "[oxgrf] Failed to open oxgrf\n");
free(oxgrf);
return -1;
}
uint32_t model = 0;
oxgrf_get_model_version(oxgrf->dev, &model);
model &= 0xffff;
if(model == 550) {
oxgrf->BoardType = Y550;
shift = 4;
LOG_I(HW, "[oxgrf] device type: Y%d\n", model);
} else if(model == 230) {
oxgrf->BoardType = Y230;
shift = 4;
LOG_I(HW, "[oxgrf] device type: Y%d\n", model);
} else if(model == 380) {
oxgrf->BoardType = Y380;
shift = 4;
LOG_I(HW, "[oxgrf] device type: Y%d\n", model);
} else if(model == 590) {
oxgrf->BoardType = Y590;
shift = 2;
LOG_I(HW, "[oxgrf] device type: Y%d\n", model);
} else if(model == 7400) {
oxgrf->BoardType = IQX7400;
shift = 2;
LOG_I(HW, "[oxgrf] device type: IQX%d\n", model);
} else if(model == 7402) {
oxgrf->BoardType = IQX7402;
shift = 2;
LOG_I(HW, "[oxgrf] device type: IQX%d(Split Mode)\n", model - 2);
} else if(model == 6000 || model == 7000 || model == 7100) {
oxgrf->BoardType = IQX7000;
shift = 4;
LOG_I(HW, "[oxgrf] device type: IQX%d\n", model);
} else {
oxgrf->BoardType = UNKNOWN;
LOG_I(HW, "[oxgrf] device type: unknown\n");
}
if(oxgrf->BoardType == Y230) {
switch ((int)openair0_cfg->sample_rate) {
#if 0
case 61440000:
openair0_cfg->samples_per_packet = 30720;
openair0_cfg->tx_sample_advance = 80;
openair0_cfg[0].tx_bw = 40e6;
openair0_cfg[0].rx_bw = 40e6;
break;
case 46080000:
openair0_cfg->samples_per_packet = 23040;
openair0_cfg->tx_sample_advance = 80;
openair0_cfg[0].tx_bw = 40e6;
openair0_cfg[0].rx_bw = 40e6;
break;
#endif
case 30720000:
openair0_cfg->samples_per_packet = 15360;
openair0_cfg->tx_sample_advance = 80;
openair0_cfg[0].tx_bw = 20e6;
openair0_cfg[0].rx_bw = 20e6;
break;
case 23040000:
openair0_cfg->samples_per_packet = 11520;
openair0_cfg->tx_sample_advance = 80;
openair0_cfg[0].tx_bw = 20e6;
openair0_cfg[0].rx_bw = 20e6;
break;
case 15360000:
openair0_cfg->samples_per_packet = 7680;
openair0_cfg->tx_sample_advance = 52;
openair0_cfg[0].tx_bw = 10e6;
openair0_cfg[0].rx_bw = 10e6;
break;
case 7680000:
openair0_cfg->samples_per_packet = 7680;
openair0_cfg->tx_sample_advance = 34;
openair0_cfg[0].tx_bw = 5e6;
openair0_cfg[0].rx_bw = 5e6;
break;
case 1920000:
openair0_cfg->samples_per_packet = 1920;
openair0_cfg->tx_sample_advance = 9;
openair0_cfg[0].tx_bw = 1.25e6;
openair0_cfg[0].rx_bw = 1.25e6;
break;
default:
LOG_I(HW, "[oxgrf] Error: unknown sampling rate %f\n", openair0_cfg->sample_rate);
free(oxgrf);
exit(-1);
break;
}
}
if(oxgrf->BoardType == Y380
|| oxgrf->BoardType == Y550
|| oxgrf->BoardType == Y590
|| oxgrf->BoardType == IQX7000
|| oxgrf->BoardType == IQX7402
|| oxgrf->BoardType == IQX7400) {
switch ((int)openair0_cfg->sample_rate) {
case 122880000:
openair0_cfg->samples_per_packet = 30720;
openair0_cfg->tx_sample_advance = 80;
openair0_cfg[0].tx_bw = 100e6;
openair0_cfg[0].rx_bw = 100e6;
break;
case 61440000:
openair0_cfg->samples_per_packet = 30720;
openair0_cfg->tx_sample_advance = 80;
openair0_cfg[0].tx_bw = 40e6;
openair0_cfg[0].rx_bw = 40e6;
break;
case 30720000:
openair0_cfg->samples_per_packet = 15360;
openair0_cfg->tx_sample_advance = 80;
openair0_cfg[0].tx_bw = 20e6;
openair0_cfg[0].rx_bw = 20e6;
break;
case 15360000:
openair0_cfg->samples_per_packet = 15360;
openair0_cfg->tx_sample_advance = 52;
openair0_cfg[0].tx_bw = 10e6;
openair0_cfg[0].rx_bw = 10e6;
break;
case 7680000:
openair0_cfg->samples_per_packet = 7680;
openair0_cfg->tx_sample_advance = 34;
openair0_cfg[0].tx_bw = 5e6;
openair0_cfg[0].rx_bw = 5e6;
break;
case 1920000:
openair0_cfg->samples_per_packet = 1920;
openair0_cfg->tx_sample_advance = 9;
openair0_cfg[0].tx_bw = 1.25e6;
openair0_cfg[0].rx_bw = 1.25e6;
break;
default:
LOG_I(HW, "[oxgrf] Error: unknown sampling rate %f\n", openair0_cfg->sample_rate);
free(oxgrf);
exit(-1);
break;
}
}
LOG_I(HW, "[oxgrf] Initializing openair0_device\n");
switch (openair0_cfg[0].clock_source) {
case external:
LOG_I(HW, "[oxgrf] clock_source: external\n");
oxgrf_set_ref_clock (oxgrf->dev, 0, EXTERNAL_REFERENCE);
oxgrf_set_pps_select (oxgrf->dev, 0, PPS_EXTERNAL_EN);
break;
case gpsdo:
LOG_I(HW, "[oxgrf] clock_source: gpsdo\n");
break;
case internal:
default:
oxgrf_set_ref_clock (oxgrf->dev, 0, INTERNAL_REFERENCE);
oxgrf_set_pps_select (oxgrf->dev, 0, PPS_INTERNAL_EN);
//oxgrf_set_vco_select (oxgrf->dev, 0, AUXDAC1);
LOG_I(HW, "[oxgrf] clock_source: internal\n");
break;
}
oxgrf_set_auxdac1 (oxgrf->dev, 0, auxdac1);
if (pa_status) {
oxgrf_set_duplex_select (oxgrf->dev, 0, FDD);
oxgrf_set_trxsw_fpga_enable(oxgrf->dev, 0, 1);
oxgrf_set_rx_ant_enable (oxgrf->dev, 0, 0);
} else if (openair0_cfg->duplex_mode == duplex_mode_TDD && !rx_ant) {
oxgrf_set_duplex_select (oxgrf->dev, 0, TDD);
oxgrf_set_trxsw_fpga_enable(oxgrf->dev, 0, 1);
oxgrf_set_rx_ant_enable (oxgrf->dev, 0, 0);
} else {
oxgrf_set_duplex_select (oxgrf->dev, 0, FDD);
oxgrf_set_trxsw_fpga_enable(oxgrf->dev, 0, 0);
oxgrf_set_rx_ant_enable (oxgrf->dev, 0, 1);
}
LOG_I(HW, "[oxgrf] RX Ant:%s\n", rx_ant?"Enabled":"Disabled");
oxgrf_set_tx_fir_en_dis (oxgrf->dev, 0, 0);
oxgrf_set_rx_fir_en_dis (oxgrf->dev, 0, 0);
int max_idx = ((oxgrf->rx_num_channels > 2 || oxgrf->tx_num_channels > 2)? 1 : 0);
for(int chip_idx = 0; chip_idx <= max_idx; chip_idx++) {
// RX port Initialize
if ((status = oxgrf_set_rx_lo_freq(oxgrf->dev, chip_idx, (uint64_t)(openair0_cfg->rx_freq[0]))) < 0) {
LOG_E(HW, "[oxgrf] Failed to set RX frequency\n");
} else
LOG_I(HW, "[oxgrf] set RX frequency to %lu\n",(uint64_t)(openair0_cfg->rx_freq[0]));
if ((status = oxgrf_set_rx_sampling_freq(oxgrf->dev, chip_idx, (uint32_t)(openair0_cfg->sample_rate))) < 0) {
LOG_E(HW, "[oxgrf] Failed to set RX sample rate\n");
} else
LOG_I(HW, "[oxgrf] set RX sample rate to %u\n", (uint32_t)(openair0_cfg->sample_rate));
if ((status = oxgrf_set_rx_rf_bandwidth(oxgrf->dev, chip_idx, (uint32_t)(openair0_cfg->rx_bw))) < 0) {
LOG_E(HW, "[oxgrf] Failed to set RX bandwidth\n");
} else
LOG_I(HW, "[oxgrf] set RX bandwidth to %u\n",(uint32_t)(openair0_cfg->rx_bw));
if ((status = oxgrf_set_rx1_gain_control_mode(oxgrf->dev, chip_idx, 0)) < 0){
LOG_E(HW, "[oxgrf] Failed to set RX1 Gain Control Mode\n");
} else
LOG_I(HW, "[oxgrf] set RX1 Gain Control Mode MGC\n");
uint32_t rxgain = openair0_cfg->rx_gain[0] - openair0_cfg->rx_gain_offset[0];
if (rxgain > 30)
rxgain = 60;
else
rxgain *= 2;
if ((status = oxgrf_set_rx1_rf_gain(oxgrf->dev, chip_idx, rxgain)) < 0) {
LOG_I(HW, "[oxgrf] Failed to set RX1 gain\n");
} else
LOG_I(HW, "[oxgrf] set RX1 gain to %u\n", rxgain);
if ((status = oxgrf_set_rx2_gain_control_mode(oxgrf->dev, chip_idx, 0)) < 0){
LOG_E(HW, "[oxgrf] Failed to set RX2 Gain Control Mode\n");
} else
LOG_I(HW, "[oxgrf] set RX2 Gain Control Mode MGC\n");
if ((status = oxgrf_set_rx2_rf_gain(oxgrf->dev, chip_idx, rxgain)) < 0) {
LOG_E(HW, "[oxgrf] Failed to set RX2 gain\n");
} else
LOG_I(HW, "[oxgrf] set RX2 gain to %u\n", rxgain);
// TX port Initialize
if ((status = oxgrf_set_tx_lo_freq(oxgrf->dev, chip_idx, (uint64_t)openair0_cfg->tx_freq[0])) < 0) {
LOG_E(HW, "[oxgrf] Failed to set TX frequency\n");
} else
LOG_I(HW, "[oxgrf] set TX Frequency to %lu\n", (uint64_t)openair0_cfg->tx_freq[0]);
if ((status = oxgrf_set_tx_sampling_freq(oxgrf->dev, chip_idx, (uint32_t)openair0_cfg->sample_rate)) < 0) {
LOG_E(HW, "[oxgrf] Failed to set TX sample rate\n");
} else
LOG_I(HW, "[oxgrf] set TX sampling rate to %u\n", (uint32_t)openair0_cfg->sample_rate);
if ((status = oxgrf_set_tx_rf_bandwidth(oxgrf->dev, chip_idx, (uint32_t)openair0_cfg->tx_bw)) <0) {
LOG_E(HW, "[oxgrf] Failed to set TX bandwidth\n");
} else
LOG_I(HW, "[oxgrf] set TX bandwidth to %u\n", (uint32_t)openair0_cfg->tx_bw);
if ((status = oxgrf_set_tx1_attenuation(oxgrf->dev, chip_idx, openair0_cfg->tx_gain[0] * 1000)) < 0) {
LOG_E(HW, "[oxgrf] Failed to set TX1 gain\n");
} else
LOG_I(HW, "[oxgrf] set the TX1 gain to %d\n", 90 - (uint32_t)openair0_cfg->tx_gain[0]);
if ((status = oxgrf_set_tx2_attenuation(oxgrf->dev, chip_idx, openair0_cfg->tx_gain[1] * 1000)) < 0) {
LOG_E(HW, "[oxgrf] Failed to set TX2 gain\n");
} else
LOG_I(HW, "[oxgrf] set the TX2 gain to %d\n", 90 - (uint32_t)openair0_cfg->tx_gain[1]);
}
uint32_t depth = oxgrf->sample_rate / 10 * sizeof(int) * oxgrf->tx_num_channels;
oxgrf_set_hwbuf_depth(oxgrf->dev, 0, depth);
oxgrf_enable_timestamp(oxgrf->dev, 0, 0);
sleep(2);
oxgrf_enable_timestamp(oxgrf->dev, 0, 1);
sleep(2);
for(int i = 0; i < NCHAN_PER_DEV; i++) {
int ret = posix_memalign((void **)&cache_buf[i], 4096, BUFFER_SIZE);
if(ret) {
LOG_I(HW, "Failed to alloc memory\n");
return -1;
}
ret = posix_memalign((void **)&iq_buf[i], 4096, BUFFER_SIZE);
if(ret) {
LOG_I(HW, "Failed to alloc memory\n");
return -1;
}
}
device->Mod_id = num_devices++;
device->type = OXGRF_DEV;
device->trx_start_func = trx_oxgrf_start;
device->trx_end_func = trx_oxgrf_end;
device->trx_read_func = trx_oxgrf_read;
device->trx_write_func = trx_oxgrf_write;
device->trx_get_stats_func = trx_oxgrf_get_stats;
device->trx_reset_stats_func = trx_oxgrf_reset_stats;
device->trx_stop_func = trx_oxgrf_stop;
device->trx_set_freq_func = trx_oxgrf_set_freq;
device->trx_set_gains_func = trx_oxgrf_set_gains;
device->openair0_cfg = openair0_cfg;
device->priv = (void *)oxgrf;
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 1.0 (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
*/
/** oxgrf_lib.h
*
* Author: eric
* base on bladerf_lib.h
*/
#include "oxgrf_api_ss.h"
#include "common_lib.h"
/** @addtogroup _OXGRF_PHY_RF_INTERFACE_
* @{
*/
typedef enum {
Y230,
Y380,
Y550,
Y590,
IQX6000,
IQX7000,
IQX7100,
IQX7400,
IQX7402, //split
UNKNOWN = -1,
} OXGRFBoardType;
/*! \brief OXGRF specific data structure */
typedef struct {
//! opaque OXGRF device struct. An empty ("") or NULL device identifier will result in the first encountered device being opened (using the first discovered backend)
OXGRF_DESCRIPTOR *dev;
int16_t *rx_buffer;
int16_t *tx_buffer;
//! Sample rate
unsigned int sample_rate;
int rx_num_channels;
int tx_num_channels;
uint64_t tx_lo_freq;
uint64_t rx_lo_freq;
// --------------------------------
// Debug and output control
// --------------------------------
//! Number of underflows
int num_underflows;
//! Number of overflows
int num_overflows;
//! number of RX errors
int num_rx_errors;
//! Number of TX errors
int num_tx_errors;
//! timestamp of current TX
uint64_t tx_current_ts;
//! timestamp of current RX
uint64_t rx_current_ts;
//! number of TX samples
uint64_t tx_nsamps;
//! number of RX samples
uint64_t rx_nsamps;
//! number of TX count
uint64_t tx_count;
//! number of RX count
uint64_t rx_count;
//! timestamp of RX packet
openair0_timestamp rx_timestamp;
OXGRFBoardType BoardType;
} oxgrf_state_t;
/*! \brief get current timestamp
*\param device the hardware to use
*/
openair0_timestamp trx_get_timestamp(openair0_device *device);
/*@}*/
/*
* Copyright 2013-2020 Software Radio Systems Limited
*
* This file is part of srsLTE.
*
* srsLTE is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as
* published by the Free Software Foundation, either version 3 of
* the License, or (at your option) any later version.
*
* srsLTE is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Affero General Public License for more details.
*
* A copy of the GNU Affero General Public License can be found in
* the LICENSE file in the top-level directory of this distribution
* and at http://www.gnu.org/licenses/.
*
*/
#ifndef OXGRF_RF_HELPER_H_
#define OXGRF_RF_HELPER_H_
// A bunch of helper functions to process device arguments
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#define REMOVE_SUBSTRING_WITHCOMAS(S, TOREMOVE) \
remove_substring(S, TOREMOVE ","); \
remove_substring(S, TOREMOVE ", "); \
remove_substring(S, "," TOREMOVE); \
remove_substring(S, ", " TOREMOVE); \
remove_substring(S, TOREMOVE)
static inline void remove_substring(char* s, const char* toremove)
{
while ((s = strstr(s, toremove))) {
memmove(s, s + strlen(toremove), 1 + strlen(s + strlen(toremove)));
}
}
static inline void copy_subdev_string(char* dst, char* src)
{
int n = 0;
int len = (int)strlen(src);
/* Copy until end of string or comma */
while (n < len && src[n] != '\0' && src[n] != ',') {
dst[n] = src[n];
n++;
}
dst[n] = '\0';
}
#endif /* OXGRF_RF_HELPER_H_ */
Active_eNBs = ( "eNB_Eurecom_LTEBox");
# Asn1_verbosity, choice in: none, info, annoying
Asn1_verbosity = "none";
eNBs =
(
{
////////// Identification parameters:
eNB_ID = 0xe00;
cell_type = "CELL_MACRO_ENB";
eNB_name = "eNB_Eurecom_LTEBox";
// Tracking area code, 0x0000 and 0xfffe are reserved values
tracking_area_code = 1;
plmn_list = ( { mcc = 001; mnc = 01; mnc_length = 2; } );
tr_s_preference = "local_mac"
////////// Physical parameters:
component_carriers = (
{
node_function = "eNodeB_3GPP";
node_timing = "synch_to_ext_device";
node_synch_ref = 0;
frame_type = "FDD";
tdd_config = 3;
tdd_config_s = 0;
prefix_type = "NORMAL";
eutra_band = 7;
downlink_frequency = 2680000000L;
uplink_frequency_offset = -120000000;
Nid_cell = 0;
N_RB_DL = 100;
Nid_cell_mbsfn = 0;
nb_antenna_ports = 1;
nb_antennas_tx = 1;
nb_antennas_rx = 1;
tx_gain = 90;
rx_gain = 102;
pbch_repetition = "FALSE";
prach_root = 0;
prach_config_index = 0;
prach_high_speed = "DISABLE";
prach_zero_correlation = 1;
prach_freq_offset = 2;
pucch_delta_shift = 1;
pucch_nRB_CQI = 1;
pucch_nCS_AN = 0;
pucch_n1_AN = 0;
pdsch_referenceSignalPower = 0;
pdsch_p_b = 0;
pusch_n_SB = 1;
pusch_enable64QAM = "DISABLE";
pusch_hoppingMode = "interSubFrame";
pusch_hoppingOffset = 0;
pusch_groupHoppingEnabled = "ENABLE";
pusch_groupAssignment = 0;
pusch_sequenceHoppingEnabled = "DISABLE";
pusch_nDMRS1 = 1;
phich_duration = "NORMAL";
phich_resource = "ONESIXTH";
srs_enable = "DISABLE";
/* srs_BandwidthConfig =;
srs_SubframeConfig =;
srs_ackNackST =;
srs_MaxUpPts =;*/
pusch_p0_Nominal = -96;
pusch_alpha = "AL1";
pucch_p0_Nominal = -104;
msg3_delta_Preamble = 6;
pucch_deltaF_Format1 = "deltaF2";
pucch_deltaF_Format1b = "deltaF3";
pucch_deltaF_Format2 = "deltaF0";
pucch_deltaF_Format2a = "deltaF0";
pucch_deltaF_Format2b = "deltaF0";
rach_numberOfRA_Preambles = 64;
rach_preamblesGroupAConfig = "DISABLE";
/*
rach_sizeOfRA_PreamblesGroupA = ;
rach_messageSizeGroupA = ;
rach_messagePowerOffsetGroupB = ;
*/
rach_powerRampingStep = 4;
rach_preambleInitialReceivedTargetPower = -108;
rach_preambleTransMax = 10;
rach_raResponseWindowSize = 10;
rach_macContentionResolutionTimer = 48;
rach_maxHARQ_Msg3Tx = 4;
pcch_default_PagingCycle = 128;
pcch_nB = "oneT";
bcch_modificationPeriodCoeff = 2;
ue_TimersAndConstants_t300 = 1000;
ue_TimersAndConstants_t301 = 1000;
ue_TimersAndConstants_t310 = 1000;
ue_TimersAndConstants_t311 = 10000;
ue_TimersAndConstants_n310 = 20;
ue_TimersAndConstants_n311 = 1;
ue_TransmissionMode = 1;
}
);
srb1_parameters :
{
# timer_poll_retransmit = (ms) [5, 10, 15, 20,... 250, 300, 350, ... 500]
timer_poll_retransmit = 80;
# timer_reordering = (ms) [0,5, ... 100, 110, 120, ... ,200]
timer_reordering = 35;
# timer_reordering = (ms) [0,5, ... 250, 300, 350, ... ,500]
timer_status_prohibit = 0;
# poll_pdu = [4, 8, 16, 32 , 64, 128, 256, infinity(>10000)]
poll_pdu = 4;
# poll_byte = (kB) [25,50,75,100,125,250,375,500,750,1000,1250,1500,2000,3000,infinity(>10000)]
poll_byte = 99999;
# max_retx_threshold = [1, 2, 3, 4 , 6, 8, 16, 32]
max_retx_threshold = 4;
}
# ------- SCTP definitions
SCTP :
{
# Number of streams to use in input/output
SCTP_INSTREAMS = 2;
SCTP_OUTSTREAMS = 2;
};
////////// MME parameters:
mme_ip_address = ( { ipv4 = "192.168.0.80";
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
enable_measurement_reports = "no";
///X2
enable_x2 = "no";
t_reloc_prep = 1000; /* unit: millisecond */
tx2_reloc_overall = 2000; /* unit: millisecond */
t_dc_prep = 1000; /* unit: millisecond */
t_dc_overall = 2000; /* unit: millisecond */
NETWORK_INTERFACES :
{
ENB_INTERFACE_NAME_FOR_S1_MME = "eno2";
ENB_IPV4_ADDRESS_FOR_S1_MME = "192.168.0.202/24";
ENB_INTERFACE_NAME_FOR_S1U = "eno2";
ENB_IPV4_ADDRESS_FOR_S1U = "192.168.0.202/24";
ENB_PORT_FOR_S1U = 2152; # Spec 2152
ENB_IPV4_ADDRESS_FOR_X2C = "192.168.0.202/24";
ENB_PORT_FOR_X2C = 36422; # Spec 36422
};
}
);
MACRLCs = (
{
num_cc = 1;
tr_s_preference = "local_L1";
tr_n_preference = "local_RRC";
puSch10xSnr = 200;
puCch10xSnr = 200;
}
);
L1s = (
{
num_cc = 1;
tr_n_preference = "local_mac";
}
);
RUs = (
{
local_rf = "yes"
nb_tx = 1
nb_rx = 1
att_tx = 0
att_rx = 3;
bands = [7];
max_pdschReferenceSignalPower = -27;
max_rxgain = 102;
eNB_instances = [0];
sdr_addrs = "dev=pciex:0,auxdac1=1620";
clock_src = "internal";
}
);
THREAD_STRUCT = (
{
#three config for level of parallelism "PARALLEL_SINGLE_THREAD", "PARALLEL_RU_L1_SPLIT", or "PARALLEL_RU_L1_TRX_SPLIT"
parallel_config = "PARALLEL_SINGLE_THREAD";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
log_config :
{
global_log_level ="info";
hw_log_level ="info";
phy_log_level ="info";
mac_log_level ="info";
rlc_log_level ="info";
pdcp_log_level ="info";
rrc_log_level ="info";
};
Active_eNBs = ( "eNB-Eurecom-LTEBox");
# Asn1_verbosity, choice in: none, info, annoying
Asn1_verbosity = "none";
eNBs =
(
{
////////// Identification parameters:
eNB_ID = 0xe00;
cell_type = "CELL_MACRO_ENB";
eNB_name = "eNB-Eurecom-LTEBox";
// Tracking area code, 0x0000 and 0xfffe are reserved values
tracking_area_code = 1;
plmn_list = ( { mcc = 001; mnc = 01; mnc_length = 2; } );
tr_s_preference = "local_mac"
////////// Physical parameters:
component_carriers = (
{
node_function = "3GPP_eNODEB";
node_timing = "synch_to_ext_device";
node_synch_ref = 0;
frame_type = "FDD";
tdd_config = 3;
tdd_config_s = 0;
prefix_type = "NORMAL";
eutra_band = 7;
downlink_frequency = 2685000000L;
uplink_frequency_offset = -120000000;
Nid_cell = 0;
N_RB_DL = 50;
Nid_cell_mbsfn = 0;
nb_antenna_ports = 1;
nb_antennas_tx = 1;
nb_antennas_rx = 1;
tx_gain = 89;
rx_gain = 102;
pbch_repetition = "FALSE";
prach_root = 0;
prach_config_index = 0;
prach_high_speed = "DISABLE";
prach_zero_correlation = 1;
prach_freq_offset = 2;
pucch_delta_shift = 1;
pucch_nRB_CQI = 0;
pucch_nCS_AN = 0;
pucch_n1_AN = 0;
pdsch_referenceSignalPower = -27;
pdsch_p_b = 0;
pusch_n_SB = 1;
pusch_enable64QAM = "DISABLE";
pusch_hoppingMode = "interSubFrame";
pusch_hoppingOffset = 0;
pusch_groupHoppingEnabled = "ENABLE";
pusch_groupAssignment = 0;
pusch_sequenceHoppingEnabled = "DISABLE";
pusch_nDMRS1 = 1;
phich_duration = "NORMAL";
phich_resource = "ONESIXTH";
srs_enable = "DISABLE";
/* srs_BandwidthConfig =;
srs_SubframeConfig =;
srs_ackNackST =;
srs_MaxUpPts =;*/
pusch_p0_Nominal = -96;
pusch_alpha = "AL1";
pucch_p0_Nominal = -104;
msg3_delta_Preamble = 6;
pucch_deltaF_Format1 = "deltaF2";
pucch_deltaF_Format1b = "deltaF3";
pucch_deltaF_Format2 = "deltaF0";
pucch_deltaF_Format2a = "deltaF0";
pucch_deltaF_Format2b = "deltaF0";
rach_numberOfRA_Preambles = 64;
rach_preamblesGroupAConfig = "DISABLE";
/*
rach_sizeOfRA_PreamblesGroupA = ;
rach_messageSizeGroupA = ;
rach_messagePowerOffsetGroupB = ;
*/
rach_powerRampingStep = 4;
rach_preambleInitialReceivedTargetPower = -108;
rach_preambleTransMax = 10;
rach_raResponseWindowSize = 10;
rach_macContentionResolutionTimer = 48;
rach_maxHARQ_Msg3Tx = 4;
pcch_default_PagingCycle = 128;
pcch_nB = "oneT";
bcch_modificationPeriodCoeff = 2;
ue_TimersAndConstants_t300 = 1000;
ue_TimersAndConstants_t301 = 1000;
ue_TimersAndConstants_t310 = 1000;
ue_TimersAndConstants_t311 = 10000;
ue_TimersAndConstants_n310 = 20;
ue_TimersAndConstants_n311 = 1;
ue_TransmissionMode = 1;
//Parameters for SIB18
rxPool_sc_CP_Len = "normal";
rxPool_sc_Period = "sf40";
rxPool_data_CP_Len = "normal";
rxPool_ResourceConfig_prb_Num = 20;
rxPool_ResourceConfig_prb_Start = 5;
rxPool_ResourceConfig_prb_End = 44;
rxPool_ResourceConfig_offsetIndicator_present = "prSmall";
rxPool_ResourceConfig_offsetIndicator_choice = 0;
rxPool_ResourceConfig_subframeBitmap_present = "prBs40";
rxPool_ResourceConfig_subframeBitmap_choice_bs_buf = "00000000000000000000";
rxPool_ResourceConfig_subframeBitmap_choice_bs_size = 5;
rxPool_ResourceConfig_subframeBitmap_choice_bs_bits_unused = 0;
/* rxPool_dataHoppingConfig_hoppingParameter = 0;
rxPool_dataHoppingConfig_numSubbands = "ns1";
rxPool_dataHoppingConfig_rbOffset = 0;
rxPool_commTxResourceUC-ReqAllowed = "TRUE";
*/
// Parameters for SIB19
discRxPool_cp_Len = "normal"
discRxPool_discPeriod = "rf32"
discRxPool_numRetx = 1;
discRxPool_numRepetition = 2;
discRxPool_ResourceConfig_prb_Num = 5;
discRxPool_ResourceConfig_prb_Start = 3;
discRxPool_ResourceConfig_prb_End = 21;
discRxPool_ResourceConfig_offsetIndicator_present = "prSmall";
discRxPool_ResourceConfig_offsetIndicator_choice = 0;
discRxPool_ResourceConfig_subframeBitmap_present = "prBs40";
discRxPool_ResourceConfig_subframeBitmap_choice_bs_buf = "f0ffffffff";
discRxPool_ResourceConfig_subframeBitmap_choice_bs_size = 5;
discRxPool_ResourceConfig_subframeBitmap_choice_bs_bits_unused = 0;
}
);
srb1_parameters :
{
# timer_poll_retransmit = (ms) [5, 10, 15, 20,... 250, 300, 350, ... 500]
timer_poll_retransmit = 80;
# timer_reordering = (ms) [0,5, ... 100, 110, 120, ... ,200]
timer_reordering = 35;
# timer_reordering = (ms) [0,5, ... 250, 300, 350, ... ,500]
timer_status_prohibit = 0;
# poll_pdu = [4, 8, 16, 32 , 64, 128, 256, infinity(>10000)]
poll_pdu = 4;
# poll_byte = (kB) [25,50,75,100,125,250,375,500,750,1000,1250,1500,2000,3000,infinity(>10000)]
poll_byte = 99999;
# max_retx_threshold = [1, 2, 3, 4 , 6, 8, 16, 32]
max_retx_threshold = 4;
}
# ------- SCTP definitions
SCTP :
{
# Number of streams to use in input/output
SCTP_INSTREAMS = 2;
SCTP_OUTSTREAMS = 2;
};
////////// MME parameters:
mme_ip_address = ( { ipv4 = "127.0.1.100";
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
enable_measurement_reports = "no";
///X2
enable_x2 = "yes";
t_reloc_prep = 1000; /* unit: millisecond */
tx2_reloc_overall = 2000; /* unit: millisecond */
t_dc_prep = 1000; /* unit: millisecond */
t_dc_overall = 2000; /* unit: millisecond */
NETWORK_INTERFACES :
{
ENB_INTERFACE_NAME_FOR_S1_MME = "lo";
ENB_IPV4_ADDRESS_FOR_S1_MME = "127.0.1.1/24";
ENB_INTERFACE_NAME_FOR_S1U = "lo";
ENB_IPV4_ADDRESS_FOR_S1U = "127.0.1.1/24";
ENB_PORT_FOR_S1U = 2152; # Spec 2152
ENB_IPV4_ADDRESS_FOR_X2C = "127.0.1.1/24";
ENB_PORT_FOR_X2C = 36422; # Spec 36422
};
}
);
DU = (
{
DU_INTERFACE_NAME_FOR_F1U = "lo";
DU_IPV4_ADDRESS_FOR_F1U = "127.0.0.1/16";
DU_PORT_FOR_F1U = 22100;
F1_U_DU_TRANSPORT_TYPE = "TCP";
}
);
CU = (
{
CU_INTERFACE_NAME_FOR_F1U = "lo";
CU_IPV4_ADDRESS_FOR_F1U = "127.0.0.1"; //Address to search the DU
CU_PORT_FOR_F1U = 22100;
F1_U_CU_TRANSPORT_TYPE = "TCP"; // One of TCP/UDP/SCTP
DU_TYPE = "LTE";
}//,
// {
// CU_INTERFACE_NAME_FOR_F1U = "eth0";
// CU_IPV4_ADDRESS_FOR_F1U = "10.64.93.142"; //Address to search the DU
// CU_PORT_FOR_F1U = 2211;
// F1_U_CU_TRANSPORT_TYPE = "TCP"; // One of TCP/UDP/SCTP
// DU_TYPE = "WiFi";
// }
);
CU_BALANCING = "ALL";
MACRLCs = (
{
num_cc = 1;
tr_s_preference = "local_L1";
tr_n_preference = "local_RRC";
phy_test_mode = 0;
puSch10xSnr = 200;
puCch10xSnr = 200;
}
);
L1s = (
{
num_cc = 1;
tr_n_preference = "local_mac";
}
);
RUs = (
{
local_rf = "yes"
nb_tx = 1
nb_rx = 1
att_tx = 5
att_rx = 10;
bands = [7];
max_pdschReferenceSignalPower = -27;
max_rxgain = 102;
eNB_instances = [0];
sdr_addrs = "dev=pciex:0,auxdac1=1620";
clock_src = "internal";
}
);
NETWORK_CONTROLLER :
{
FLEXRAN_ENABLED = "no";
FLEXRAN_INTERFACE_NAME = "lo";
FLEXRAN_IPV4_ADDRESS = "127.0.0.1";
FLEXRAN_PORT = 2210;
FLEXRAN_CACHE = "/mnt/oai_agent_cache";
FLEXRAN_AWAIT_RECONF = "no";
};
THREAD_STRUCT = (
{
#three config for level of parallelism "PARALLEL_SINGLE_THREAD", "PARALLEL_RU_L1_SPLIT", or "PARALLEL_RU_L1_TRX_SPLIT"
parallel_config = "PARALLEL_SINGLE_THREAD";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
/*
#example config for rfsimulator
rfsimulator :
{
serveraddr = "enb";
serverport = "4043";
options = ("saviq");
modelname = "AWGN";
IQfile = "/tmp/rfsimulator.iqs";
};
*/
log_config :
{
global_log_level ="info";
hw_log_level ="info";
phy_log_level ="info";
mac_log_level ="info";
rlc_log_level ="info";
pdcp_log_level ="info";
rrc_log_level ="info";
};
Active_gNBs = ( "gNB-Eurecom-5GNRBox");
# Asn1_verbosity, choice in: none, info, annoying
Asn1_verbosity = "none";
gNBs =
(
{
////////// Identification parameters:
gNB_ID = 0xe01;
cell_type = "CELL_MACRO_GNB";
gNB_name = "gNB-Eurecom-5GNRBox";
// Tracking area code, 0x0000 and 0xfffe are reserved values
tracking_area_code = 1;
plmn_list = ({mcc = 001; mnc = 01; mnc_length = 2;});
tr_s_preference = "local_mac"
////////// Physical parameters:
pusch_TargetSNRx10 = 200;
pucch_TargetSNRx10 = 200;
servingCellConfigCommon = (
{
#spCellConfigCommon
physCellId = 0;
# downlinkConfigCommon
#frequencyInfoDL
# this is 3600 MHz + 84 PRBs@30kHz SCS (same as initial BWP)
absoluteFrequencySSB = 641272; //641032; #641968; 641968=start of ssb at 3600MHz + 82 RBs 641032=center of SSB at center of cell
dl_frequencyBand = 78;
# this is 3600 MHz
dl_absoluteFrequencyPointA = 640000;
#scs-SpecificCarrierList
dl_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
dl_subcarrierSpacing = 1;
dl_carrierBandwidth = 106;
#initialDownlinkBWP
#genericParameters
# this is RBstart=84,L=13 (275*(L-1))+RBstart
initialDLBWPlocationAndBandwidth = 6368;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialDLBWPsubcarrierSpacing = 1;
#pdcch-ConfigCommon
initialDLBWPcontrolResourceSetZero = 0;
initialDLBWPsearchSpaceZero = 0;
#uplinkConfigCommon
#frequencyInfoUL
ul_frequencyBand = 78;
#scs-SpecificCarrierList
ul_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
ul_subcarrierSpacing = 1;
ul_carrierBandwidth = 106;
pMax = 20;
#initialUplinkBWP
#genericParameters
initialULBWPlocationAndBandwidth = 6368;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialULBWPsubcarrierSpacing = 1;
#rach-ConfigCommon
#rach-ConfigGeneric
prach_ConfigurationIndex = 98;
#prach_msg1_FDM
#0 = one, 1=two, 2=four, 3=eight
prach_msg1_FDM = 0;
prach_msg1_FrequencyStart = 0;
zeroCorrelationZoneConfig = 13;
preambleReceivedTargetPower = -100;
#preamblTransMax (0...10) = (3,4,5,6,7,8,10,20,50,100,200)
preambleTransMax = 6;
#powerRampingStep
# 0=dB0,1=dB2,2=dB4,3=dB6
powerRampingStep = 1;
#ra_ReponseWindow
#1,2,4,8,10,20,40,80
ra_ResponseWindow = 5;
#ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR
#1=oneeighth,2=onefourth,3=half,4=one,5=two,6=four,7=eight,8=sixteen
ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR = 4;
#oneHalf (0..15) 4,8,12,16,...60,64
ssb_perRACH_OccasionAndCB_PreamblesPerSSB = 14; //15;
#ra_ContentionResolutionTimer
#(0..7) 8,16,24,32,40,48,56,64
ra_ContentionResolutionTimer = 7;
rsrp_ThresholdSSB = 19;
#prach-RootSequenceIndex_PR
#1 = 839, 2 = 139
prach_RootSequenceIndex_PR = 2;
prach_RootSequenceIndex = 1;
# SCS for msg1, can only be 15 for 30 kHz < 6 GHz, takes precendence over the one derived from prach-ConfigIndex
#
msg1_SubcarrierSpacing = 1,
# restrictedSetConfig
# 0=unrestricted, 1=restricted type A, 2=restricted type B
restrictedSetConfig = 0,
msg3_DeltaPreamble = 1;
p0_NominalWithGrant =-90;
# pucch-ConfigCommon setup :
# pucchGroupHopping
# 0 = neither, 1= group hopping, 2=sequence hopping
pucchGroupHopping = 0;
hoppingId = 40;
p0_nominal = -90;
# ssb_PositionsInBurs_BitmapPR
# 1=short, 2=medium, 3=long
ssb_PositionsInBurst_PR = 2;
ssb_PositionsInBurst_Bitmap = 1; #0x80;
# ssb_periodicityServingCell
# 0 = ms5, 1=ms10, 2=ms20, 3=ms40, 4=ms80, 5=ms160, 6=spare2, 7=spare1
ssb_periodicityServingCell = 2;
# dmrs_TypeA_position
# 0 = pos2, 1 = pos3
dmrs_TypeA_Position = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
subcarrierSpacing = 1;
#tdd-UL-DL-ConfigurationCommon
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
referenceSubcarrierSpacing = 1;
# pattern1
# dl_UL_TransmissionPeriodicity
# 0=ms0p5, 1=ms0p625, 2=ms1, 3=ms1p25, 4=ms2, 5=ms2p5, 6=ms5, 7=ms10
dl_UL_TransmissionPeriodicity = 6;
nrofDownlinkSlots = 7; //8; //7;
nrofDownlinkSymbols = 6; //0; //6;
nrofUplinkSlots = 2;
nrofUplinkSymbols = 4; //0; //4;
ssPBCH_BlockPower = -25;
}
);
# ------- SCTP definitions
SCTP :
{
# Number of streams to use in input/output
SCTP_INSTREAMS = 2;
SCTP_OUTSTREAMS = 2;
};
////////// MME parameters:
amf_ip_address = ( { ipv4 = "127.0.1.100";
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
///X2
enable_x2 = "yes";
t_reloc_prep = 1000; /* unit: millisecond */
tx2_reloc_overall = 2000; /* unit: millisecond */
t_dc_prep = 1000; /* unit: millisecond */
t_dc_overall = 2000; /* unit: millisecond */
target_enb_x2_ip_address = (
{ ipv4 = "127.0.1.1";
ipv6 = "192:168:30::17";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
GNB_INTERFACE_NAME_FOR_NG_AMF = "lo";
GNB_IPV4_ADDRESS_FOR_NG_AMF = "127.0.1.2/24";
GNB_INTERFACE_NAME_FOR_NGU = "lo";
GNB_IPV4_ADDRESS_FOR_NGU = "127.0.1.2/24";
GNB_PORT_FOR_S1U = 2152; # Spec 2152
GNB_IPV4_ADDRESS_FOR_X2C = "127.0.1.2/24";
GNB_PORT_FOR_X2C = 36422; # Spec 36422
};
}
);
MACRLCs = (
{
num_cc = 1;
tr_s_preference = "local_L1";
tr_n_preference = "local_RRC";
}
);
L1s = (
{
num_cc = 1;
tr_n_preference = "local_mac";
}
);
RUs = (
{
local_rf = "yes"
nb_tx = 1
nb_rx = 1
att_tx = 5
att_rx = 10;
bands = [7];
max_pdschReferenceSignalPower = -27;
max_rxgain = 102;
eNB_instances = [0];
sdr_addrs = "dev=pciex:0,auxdac1=1620";
clock_src = "internal";
}
);
THREAD_STRUCT = (
{
#three config for level of parallelism "PARALLEL_SINGLE_THREAD", "PARALLEL_RU_L1_SPLIT", or "PARALLEL_RU_L1_TRX_SPLIT"
parallel_config = "PARALLEL_SINGLE_THREAD";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
security = {
# preferred ciphering algorithms
# the first one of the list that an UE supports in chosen
# valid values: nea0, nea1, nea2, nea3
ciphering_algorithms = ( "nea0", "nea2" );
# preferred integrity algorithms
# the first one of the list that an UE supports in chosen
# valid values: nia0, nia1, nia2, nia3
integrity_algorithms = ( "nia0" );
};
log_config :
{
global_log_level ="info";
hw_log_level ="info";
phy_log_level ="info";
mac_log_level ="info";
rlc_log_level ="info";
pdcp_log_level ="info";
rrc_log_level ="info";
};
Active_gNBs = ( "gNB-OAI");
# Asn1_verbosity, choice in: none, info, annoying
Asn1_verbosity = "none";
gNBs =
(
{
////////// Identification parameters:
gNB_ID = 0xe00;
gNB_name = "gNB-OAI";
// Tracking area code, 0x0000 and 0xfffe are reserved values
tracking_area_code = 1;
plmn_list = ({ mcc = 001; mnc = 01; mnc_length = 2; snssaiList = ({ sst = 1; }); });
nr_cellid = 12345678L;
////////// Physical parameters:
pdsch_AntennaPorts_XP = 2;
pusch_AntennaPorts = 2;
do_CSIRS = 1;
do_SRS = 1;
ul_prbblacklist = "51,52,53,54"
servingCellConfigCommon = (
{
#spCellConfigCommon
physCellId = 0;
# downlinkConfigCommon
#frequencyInfoDL
# this is 3300.60 MHz + 53*12*30e-3 MHz = 3319.68
absoluteFrequencySSB = 621312; # 641280
dl_frequencyBand = 78;
# this is 3300.60 MHz
dl_absoluteFrequencyPointA = 620040; # 640008
#scs-SpecificCarrierList
dl_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
dl_subcarrierSpacing = 1;
dl_carrierBandwidth = 106;
#initialDownlinkBWP
#genericParameters
# this is RBstart=27,L=48 (275*(L-1))+RBstart
initialDLBWPlocationAndBandwidth = 28875; # 6366 12925 12956 28875 12952
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialDLBWPsubcarrierSpacing = 1;
#pdcch-ConfigCommon
initialDLBWPcontrolResourceSetZero = 12;
initialDLBWPsearchSpaceZero = 0;
#uplinkConfigCommon
#frequencyInfoUL
ul_frequencyBand = 78;
#scs-SpecificCarrierList
ul_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
ul_subcarrierSpacing = 1;
ul_carrierBandwidth = 106;
pMax = 20;
#initialUplinkBWP
#genericParameters
initialULBWPlocationAndBandwidth = 28875;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialULBWPsubcarrierSpacing = 1;
#rach-ConfigCommon
#rach-ConfigGeneric
prach_ConfigurationIndex = 98;
#prach_msg1_FDM
#0 = one, 1=two, 2=four, 3=eight
prach_msg1_FDM = 0;
prach_msg1_FrequencyStart = 0;
zeroCorrelationZoneConfig = 12;
preambleReceivedTargetPower = -96;
#preamblTransMax (0...10) = (3,4,5,6,7,8,10,20,50,100,200)
preambleTransMax = 6;
#powerRampingStep
# 0=dB0,1=dB2,2=dB4,3=dB6
powerRampingStep = 1;
#ra_ReponseWindow
#1,2,4,8,10,20,40,80
ra_ResponseWindow = 4;
#ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR
#1=oneeighth,2=onefourth,3=half,4=one,5=two,6=four,7=eight,8=sixteen
ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR = 3;
#oneHalf (0..15) 4,8,12,16,...60,64
ssb_perRACH_OccasionAndCB_PreamblesPerSSB = 15;
#ra_ContentionResolutionTimer
#(0..7) 8,16,24,32,40,48,56,64
ra_ContentionResolutionTimer = 7;
rsrp_ThresholdSSB = 19;
#prach-RootSequenceIndex_PR
#1 = 839, 2 = 139
prach_RootSequenceIndex_PR = 2;
prach_RootSequenceIndex = 1;
# SCS for msg1, can only be 15 for 30 kHz < 6 GHz, takes precendence over the one derived from prach-ConfigIndex
#
msg1_SubcarrierSpacing = 1,
# restrictedSetConfig
# 0=unrestricted, 1=restricted type A, 2=restricted type B
restrictedSetConfig = 0,
msg3_DeltaPreamble = 1;
p0_NominalWithGrant =-90;
# pucch-ConfigCommon setup :
# pucchGroupHopping
# 0 = neither, 1= group hopping, 2=sequence hopping
pucchGroupHopping = 0;
hoppingId = 40;
p0_nominal = -70;
# ssb_PositionsInBurs_BitmapPR
# 1=short, 2=medium, 3=long
ssb_PositionsInBurst_PR = 2;
ssb_PositionsInBurst_Bitmap = 1;
# ssb_periodicityServingCell
# 0 = ms5, 1=ms10, 2=ms20, 3=ms40, 4=ms80, 5=ms160, 6=spare2, 7=spare1
ssb_periodicityServingCell = 2;
# dmrs_TypeA_position
# 0 = pos2, 1 = pos3
dmrs_TypeA_Position = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
subcarrierSpacing = 1;
#tdd-UL-DL-ConfigurationCommon
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
referenceSubcarrierSpacing = 1;
# pattern1
# dl_UL_TransmissionPeriodicity
# 0=ms0p5, 1=ms0p625, 2=ms1, 3=ms1p25, 4=ms2, 5=ms2p5, 6=ms5, 7=ms10
dl_UL_TransmissionPeriodicity = 6;
nrofDownlinkSlots = 7;
nrofDownlinkSymbols = 6;
nrofUplinkSlots = 2;
nrofUplinkSymbols = 4;
ssPBCH_BlockPower = -25;
}
);
# ------- SCTP definitions
SCTP :
{
# Number of streams to use in input/output
SCTP_INSTREAMS = 2;
SCTP_OUTSTREAMS = 2;
};
////////// AMF parameters:
amf_ip_address = ( { ipv4 = "192.168.0.80"; #"192.168.70.132";
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
GNB_INTERFACE_NAME_FOR_NG_AMF = "demo-oai";
GNB_IPV4_ADDRESS_FOR_NG_AMF = "192.168.0.202"; #"192.168.70.129/24";
GNB_INTERFACE_NAME_FOR_NGU = "demo-oai";
GNB_IPV4_ADDRESS_FOR_NGU = "192.168.0.202"; #"192.168.70.129/24";
GNB_PORT_FOR_S1U = 2152; # Spec 2152
};
}
);
MACRLCs = (
{
num_cc = 1;
tr_s_preference = "local_L1";
tr_n_preference = "local_RRC";
pusch_TargetSNRx10 = 300;
pucch_TargetSNRx10 = 300;
pusch_FailureThres = 1000;
ulsch_max_frame_inactivity = 0;
}
);
L1s = (
{
num_cc = 1;
tr_n_preference = "local_mac";
prach_dtx_threshold = 120;
#pucch0_dtx_threshold = 120;
}
);
RUs = (
{
local_rf = "yes"
nb_tx = 2
nb_rx = 2
att_tx = 0
att_rx = 0;
bands = [78];
max_pdschReferenceSignalPower = -27;
max_rxgain = 102;
eNB_instances = [0];
##beamforming 1x2 matrix: 1 layer x 2 antennas
bf_weights = [0x00007fff, 0x0000];
#clock_src = "internal";
sdr_addrs = "dev=pciex:0,auxdac1=1630";
}
);
THREAD_STRUCT = (
{
#three config for level of parallelism "PARALLEL_SINGLE_THREAD", "PARALLEL_RU_L1_SPLIT", or "PARALLEL_RU_L1_TRX_SPLIT"
parallel_config = "PARALLEL_SINGLE_THREAD";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
rfsimulator :
{
serveraddr = "server";
serverport = "4043";
options = (); #("saviq"); or/and "chanmod"
modelname = "AWGN";
IQfile = "/tmp/rfsimulator.iqs";
};
security = {
# preferred ciphering algorithms
# the first one of the list that an UE supports in chosen
# valid values: nea0, nea1, nea2, nea3
ciphering_algorithms = ( "nea0" );
# preferred integrity algorithms
# the first one of the list that an UE supports in chosen
# valid values: nia0, nia1, nia2, nia3
integrity_algorithms = ( "nia2", "nia0" );
# setting 'drb_ciphering' to "no" disables ciphering for DRBs, no matter
# what 'ciphering_algorithms' configures; same thing for 'drb_integrity'
drb_ciphering = "yes";
drb_integrity = "no";
};
log_config :
{
global_log_level ="info";
hw_log_level ="info";
phy_log_level ="info";
mac_log_level ="info";
rlc_log_level ="info";
pdcp_log_level ="info";
rrc_log_level ="info";
ngap_log_level ="debug";
f1ap_log_level ="debug";
};
Active_gNBs = ( "gNB-OAI");
# Asn1_verbosity, choice in: none, info, annoying
Asn1_verbosity = "none";
gNBs =
(
{
////////// Identification parameters:
gNB_ID = 0xe00;
gNB_name = "gNB-OAI";
// Tracking area code, 0x0000 and 0xfffe are reserved values
tracking_area_code = 1;
plmn_list = ({ mcc = 001; mnc = 01; mnc_length = 2; snssaiList = ({ sst = 1; }) });
nr_cellid = 12345678L;
////////// Physical parameters:
do_CSIRS = 1;
do_SRS = 1;
servingCellConfigCommon = (
{
#spCellConfigCommon
physCellId = 0;
# downlinkConfigCommon
#frequencyInfoDL
# this is 3600 MHz + 43 PRBs@30kHz SCS (same as initial BWP)
absoluteFrequencySSB = 641280;
dl_frequencyBand = 78;
# this is 3600 MHz
dl_absoluteFrequencyPointA = 640008;
#scs-SpecificCarrierList
dl_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
dl_subcarrierSpacing = 1;
dl_carrierBandwidth = 106;
#initialDownlinkBWP
#genericParameters
# this is RBstart=27,L=48 (275*(L-1))+RBstart
initialDLBWPlocationAndBandwidth = 28875; # 6366 12925 12956 28875 12952
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialDLBWPsubcarrierSpacing = 1;
#pdcch-ConfigCommon
initialDLBWPcontrolResourceSetZero = 12;
initialDLBWPsearchSpaceZero = 0;
#uplinkConfigCommon
#frequencyInfoUL
ul_frequencyBand = 78;
#scs-SpecificCarrierList
ul_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
ul_subcarrierSpacing = 1;
ul_carrierBandwidth = 106;
pMax = 20;
#initialUplinkBWP
#genericParameters
initialULBWPlocationAndBandwidth = 28875;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialULBWPsubcarrierSpacing = 1;
#rach-ConfigCommon
#rach-ConfigGeneric
prach_ConfigurationIndex = 98;
#prach_msg1_FDM
#0 = one, 1=two, 2=four, 3=eight
prach_msg1_FDM = 0;
prach_msg1_FrequencyStart = 0;
zeroCorrelationZoneConfig = 13;
preambleReceivedTargetPower = -96;
#preamblTransMax (0...10) = (3,4,5,6,7,8,10,20,50,100,200)
preambleTransMax = 6;
#powerRampingStep
# 0=dB0,1=dB2,2=dB4,3=dB6
powerRampingStep = 1;
#ra_ReponseWindow
#1,2,4,8,10,20,40,80
ra_ResponseWindow = 4;
#ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR
#1=oneeighth,2=onefourth,3=half,4=one,5=two,6=four,7=eight,8=sixteen
ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR = 4;
#oneHalf (0..15) 4,8,12,16,...60,64
ssb_perRACH_OccasionAndCB_PreamblesPerSSB = 14;
#ra_ContentionResolutionTimer
#(0..7) 8,16,24,32,40,48,56,64
ra_ContentionResolutionTimer = 7;
rsrp_ThresholdSSB = 19;
#prach-RootSequenceIndex_PR
#1 = 839, 2 = 139
prach_RootSequenceIndex_PR = 2;
prach_RootSequenceIndex = 1;
# SCS for msg1, can only be 15 for 30 kHz < 6 GHz, takes precendence over the one derived from prach-ConfigIndex
#
msg1_SubcarrierSpacing = 1,
# restrictedSetConfig
# 0=unrestricted, 1=restricted type A, 2=restricted type B
restrictedSetConfig = 0,
msg3_DeltaPreamble = 1;
p0_NominalWithGrant =-90;
# pucch-ConfigCommon setup :
# pucchGroupHopping
# 0 = neither, 1= group hopping, 2=sequence hopping
pucchGroupHopping = 0;
hoppingId = 40;
p0_nominal = -90;
# ssb_PositionsInBurs_BitmapPR
# 1=short, 2=medium, 3=long
ssb_PositionsInBurst_PR = 2;
ssb_PositionsInBurst_Bitmap = 1;
# ssb_periodicityServingCell
# 0 = ms5, 1=ms10, 2=ms20, 3=ms40, 4=ms80, 5=ms160, 6=spare2, 7=spare1
ssb_periodicityServingCell = 2;
# dmrs_TypeA_position
# 0 = pos2, 1 = pos3
dmrs_TypeA_Position = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
subcarrierSpacing = 1;
#tdd-UL-DL-ConfigurationCommon
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
referenceSubcarrierSpacing = 1;
# pattern1
# dl_UL_TransmissionPeriodicity
# 0=ms0p5, 1=ms0p625, 2=ms1, 3=ms1p25, 4=ms2, 5=ms2p5, 6=ms5, 7=ms10
dl_UL_TransmissionPeriodicity = 6;
nrofDownlinkSlots = 7;
nrofDownlinkSymbols = 6;
nrofUplinkSlots = 2;
nrofUplinkSymbols = 4;
ssPBCH_BlockPower = -25;
}
);
# ------- SCTP definitions
SCTP :
{
# Number of streams to use in input/output
SCTP_INSTREAMS = 2;
SCTP_OUTSTREAMS = 2;
};
////////// AMF parameters:
amf_ip_address = ( { ipv4 = "192.168.70.132";
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
GNB_INTERFACE_NAME_FOR_NG_AMF = "eno2";
GNB_IPV4_ADDRESS_FOR_NG_AMF = "192.168.0.202/24";
GNB_INTERFACE_NAME_FOR_NGU = "eno2";
GNB_IPV4_ADDRESS_FOR_NGU = "192.168.0.202/24";
GNB_PORT_FOR_S1U = 2152; # Spec 2152
};
}
);
MACRLCs = (
{
num_cc = 1;
tr_s_preference = "local_L1";
tr_n_preference = "local_RRC";
pusch_TargetSNRx10 = 150;
pucch_TargetSNRx10 = 200;
ulsch_max_frame_inactivity = 0;
}
);
L1s = (
{
num_cc = 1;
tr_n_preference = "local_mac";
prach_dtx_threshold = 120;
pucch0_dtx_threshold = 100;
ofdm_offset_divisor = 8; #set this to UINT_MAX for offset 0
}
);
RUs = (
{
local_rf = "yes"
nb_tx = 1
nb_rx = 1
att_tx = 0;
att_rx = 0;
bands = [78];
max_pdschReferenceSignalPower = -27;
max_rxgain = 102;
eNB_instances = [0];
#beamforming 1x4 matrix:
bf_weights = [0x00007fff, 0x0000, 0x0000, 0x0000];
sdr_addrs = "dev=pciex:0,auxdac1=1660";
clock_src = "internal";
}
);
THREAD_STRUCT = (
{
#three config for level of parallelism "PARALLEL_SINGLE_THREAD", "PARALLEL_RU_L1_SPLIT", or "PARALLEL_RU_L1_TRX_SPLIT"
parallel_config = "PARALLEL_SINGLE_THREAD";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
rfsimulator :
{
serveraddr = "server";
serverport = "4043";
options = (); #("saviq"); or/and "chanmod"
modelname = "AWGN";
IQfile = "/tmp/rfsimulator.iqs";
};
security = {
# preferred ciphering algorithms
# the first one of the list that an UE supports in chosen
# valid values: nea0, nea1, nea2, nea3
ciphering_algorithms = ( "nea0" );
# preferred integrity algorithms
# the first one of the list that an UE supports in chosen
# valid values: nia0, nia1, nia2, nia3
integrity_algorithms = ( "nia2", "nia0" );
# setting 'drb_ciphering' to "no" disables ciphering for DRBs, no matter
# what 'ciphering_algorithms' configures; same thing for 'drb_integrity'
drb_ciphering = "yes";
drb_integrity = "no";
};
log_config :
{
global_log_level ="info";
hw_log_level ="info";
phy_log_level ="info";
mac_log_level ="info";
rlc_log_level ="info";
pdcp_log_level ="info";
rrc_log_level ="info";
ngap_log_level ="debug";
f1ap_log_level ="debug";
};
Active_gNBs = ( "gNB-OAI");
# Asn1_verbosity, choice in: none, info, annoying
Asn1_verbosity = "none";
gNBs =
(
{
////////// Identification parameters:
gNB_ID = 0xe00;
gNB_name = "gNB-OAI";
// Tracking area code, 0x0000 and 0xfffe are reserved values
tracking_area_code = 1;
plmn_list = ({ mcc = 001; mnc = 01; mnc_length = 2; snssaiList = ({ sst = 1; }); });
nr_cellid = 12345678L;
////////// Physical parameters:
pdsch_AntennaPorts_XP = 2;
pusch_AntennaPorts = 2;
do_CSIRS = 1;
do_SRS = 1;
ul_prbblacklist = "135,136,137,138"
servingCellConfigCommon = (
{
#spCellConfigCommon
physCellId = 0;
# downlinkConfigCommon
#frequencyInfoDL
# this is 3300.24 + 134*12*30e3 = 3348.48 MHz (5G NR GSCN: 7741)
absoluteFrequencySSB = 623232;
dl_frequencyBand = 78;
# this is 3300.24 MHz
dl_absoluteFrequencyPointA = 620016;
#scs-SpecificCarrierList
dl_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
dl_subcarrierSpacing = 1;
dl_carrierBandwidth = 273;
#initialDownlinkBWP
#genericParameters
initialDLBWPlocationAndBandwidth = 1099;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialDLBWPsubcarrierSpacing = 1;
#pdcch-ConfigCommon
initialDLBWPcontrolResourceSetZero = 12;
initialDLBWPsearchSpaceZero = 0;
#uplinkConfigCommon
#frequencyInfoUL
ul_frequencyBand = 78;
#scs-SpecificCarrierList
ul_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
ul_subcarrierSpacing = 1;
ul_carrierBandwidth = 273;
pMax = 20;
#initialUplinkBWP
#genericParameters
initialULBWPlocationAndBandwidth = 1099;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialULBWPsubcarrierSpacing = 1;
#rach-ConfigCommon
#rach-ConfigGeneric
prach_ConfigurationIndex = 98;
#prach_msg1_FDM
#0 = one, 1=two, 2=four, 3=eight
prach_msg1_FDM = 0;
prach_msg1_FrequencyStart = 0;
zeroCorrelationZoneConfig = 12;
preambleReceivedTargetPower = -90;
#preamblTransMax (0...10) = (3,4,5,6,7,8,10,20,50,100,200)
preambleTransMax = 6;
#powerRampingStep
# 0=dB0,1=dB2,2=dB4,3=dB6
powerRampingStep = 1;
#ra_ReponseWindow
#1,2,4,8,10,20,40,80
ra_ResponseWindow = 4;
#ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR
#1=oneeighth,2=onefourth,3=half,4=one,5=two,6=four,7=eight,8=sixteen
ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR = 3;
#oneHalf (0..15) 4,8,12,16,...60,64
ssb_perRACH_OccasionAndCB_PreamblesPerSSB = 15;
#ra_ContentionResolutionTimer
#(0..7) 8,16,24,32,40,48,56,64
ra_ContentionResolutionTimer = 7;
rsrp_ThresholdSSB = 19;
#prach-RootSequenceIndex_PR
#1 = 839, 2 = 139
prach_RootSequenceIndex_PR = 2;
prach_RootSequenceIndex = 1;
# SCS for msg1, can only be 15 for 30 kHz < 6 GHz, takes precendence over the one derived from prach-ConfigIndex
#
msg1_SubcarrierSpacing = 1,
# restrictedSetConfig
# 0=unrestricted, 1=restricted type A, 2=restricted type B
restrictedSetConfig = 0,
msg3_DeltaPreamble = 1;
p0_NominalWithGrant =-90;
# pucch-ConfigCommon setup :
# pucchGroupHopping
# 0 = neither, 1= group hopping, 2=sequence hopping
pucchGroupHopping = 0;
hoppingId = 40;
p0_nominal = -70;
# ssb_PositionsInBurs_BitmapPR
# 1=short, 2=medium, 3=long
ssb_PositionsInBurst_PR = 2;
ssb_PositionsInBurst_Bitmap = 1;
# ssb_periodicityServingCell
# 0 = ms5, 1=ms10, 2=ms20, 3=ms40, 4=ms80, 5=ms160, 6=spare2, 7=spare1
ssb_periodicityServingCell = 2;
# dmrs_TypeA_position
# 0 = pos2, 1 = pos3
dmrs_TypeA_Position = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
subcarrierSpacing = 1;
#tdd-UL-DL-ConfigurationCommon
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
referenceSubcarrierSpacing = 1;
# pattern1
# dl_UL_TransmissionPeriodicity
# 0=ms0p5, 1=ms0p625, 2=ms1, 3=ms1p25, 4=ms2, 5=ms2p5, 6=ms5, 7=ms10
dl_UL_TransmissionPeriodicity = 6;
nrofDownlinkSlots = 7;
nrofDownlinkSymbols = 6;
nrofUplinkSlots = 2;
nrofUplinkSymbols = 4;
ssPBCH_BlockPower = -5;
}
);
# ------- SCTP definitions
SCTP :
{
# Number of streams to use in input/output
SCTP_INSTREAMS = 2;
SCTP_OUTSTREAMS = 2;
};
////////// AMF parameters:
amf_ip_address = ( { ipv4 = "192.168.0.80";
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
GNB_INTERFACE_NAME_FOR_NG_AMF = "demo-oai";
GNB_IPV4_ADDRESS_FOR_NG_AMF = "192.168.0.201/24";
GNB_INTERFACE_NAME_FOR_NGU = "demo-oai";
GNB_IPV4_ADDRESS_FOR_NGU = "192.168.0.201/24";
GNB_PORT_FOR_S1U = 2152; # Spec 2152
};
}
);
MACRLCs = (
{
num_cc = 1;
tr_s_preference = "local_L1";
tr_n_preference = "local_RRC";
pusch_TargetSNRx10 = 300;
pucch_TargetSNRx10 = 300;
pusch_FailureThres = 1000;
ulsch_max_frame_inactivity = 0;
ul_max_mcs = 28;
}
);
L1s = (
{
num_cc = 1;
tr_n_preference = "local_mac";
prach_dtx_threshold = 120;
pucch0_dtx_threshold = 80;
}
);
RUs = (
{
local_rf = "yes"
nb_tx = 2
nb_rx = 2
att_tx = 0
att_rx = 0;
bands = [78];
max_pdschReferenceSignalPower = -27;
max_rxgain = 102;
eNB_instances = [0];
##beamforming 1x2 matrix: 1 layer x 2 antennas
bf_weights = [0x00007fff, 0x0000];
#clock_src = "internal";
sdr_addrs = "dev=pciex:0,auxdac1=1630";
}
);
THREAD_STRUCT = (
{
#three config for level of parallelism "PARALLEL_SINGLE_THREAD", "PARALLEL_RU_L1_SPLIT", or "PARALLEL_RU_L1_TRX_SPLIT"
parallel_config = "PARALLEL_SINGLE_THREAD";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
rfsimulator :
{
serveraddr = "server";
serverport = "4043";
options = (); #("saviq"); or/and "chanmod"
modelname = "AWGN";
IQfile = "/tmp/rfsimulator.iqs";
};
security = {
# preferred ciphering algorithms
# the first one of the list that an UE supports in chosen
# valid values: nea0, nea1, nea2, nea3
ciphering_algorithms = ( "nea0" );
# preferred integrity algorithms
# the first one of the list that an UE supports in chosen
# valid values: nia0, nia1, nia2, nia3
integrity_algorithms = ( "nia2", "nia0" );
# setting 'drb_ciphering' to "no" disables ciphering for DRBs, no matter
# what 'ciphering_algorithms' configures; same thing for 'drb_integrity'
drb_ciphering = "yes";
drb_integrity = "no";
};
log_config :
{
global_log_level ="info";
hw_log_level ="info";
phy_log_level ="info";
mac_log_level ="info";
rlc_log_level ="info";
pdcp_log_level ="info";
rrc_log_level ="info";
ngap_log_level ="debug";
f1ap_log_level ="debug";
};
Active_gNBs = ( "gNB-OAI");
# Asn1_verbosity, choice in: none, info, annoying
Asn1_verbosity = "none";
gNBs =
(
{
////////// Identification parameters:
gNB_ID = 0xe00;
gNB_name = "gNB-OAI";
// Tracking area code, 0x0000 and 0xfffe are reserved values
tracking_area_code = 1;
plmn_list = ({ mcc = 001; mnc = 01; mnc_length = 2; snssaiList = ({ sst = 1; }); });
nr_cellid = 12345678L;
////////// Physical parameters:
ssb_SubcarrierOffset = 0;
pdsch_AntennaPorts_XP = 1;
pusch_AntennaPorts = 1;
do_CSIRS = 1;
ul_prbblacklist = "135,136,137,138"
servingCellConfigCommon = (
{
#spCellConfigCommon
physCellId = 0;
# downlinkConfigCommon
#frequencyInfoDL
# this is 3300.24 + 134*12*30e3 = 3348.48 MHz (5G NR GSCN: 7741)
absoluteFrequencySSB = 623232;
dl_frequencyBand = 78;
# this is 3300.24 MHz
dl_absoluteFrequencyPointA = 620016;
#scs-SpecificCarrierList
dl_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
dl_subcarrierSpacing = 1;
dl_carrierBandwidth = 273;
#initialDownlinkBWP
#genericParameters
initialDLBWPlocationAndBandwidth = 1099;
#
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialDLBWPsubcarrierSpacing = 1;
#pdcch-ConfigCommon
initialDLBWPcontrolResourceSetZero = 12;
initialDLBWPsearchSpaceZero = 10;
#uplinkConfigCommon
#frequencyInfoUL
ul_frequencyBand = 78;
#scs-SpecificCarrierList
ul_offstToCarrier = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
ul_subcarrierSpacing = 1;
ul_carrierBandwidth = 273;
pMax = 20;
#initialUplinkBWP
#genericParameters
initialULBWPlocationAndBandwidth = 1099;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
initialULBWPsubcarrierSpacing = 1;
#rach-ConfigCommon
#rach-ConfigGeneric
prach_ConfigurationIndex = 98;
#prach_msg1_FDM
#0 = one, 1=two, 2=four, 3=eight
prach_msg1_FDM = 0;
prach_msg1_FrequencyStart = 0;
zeroCorrelationZoneConfig = 12;
preambleReceivedTargetPower = -90;
#preamblTransMax (0...10) = (3,4,5,6,7,8,10,20,50,100,200)
preambleTransMax = 6;
#powerRampingStep
# 0=dB0,1=dB2,2=dB4,3=dB6
powerRampingStep = 1;
#ra_ReponseWindow
#1,2,4,8,10,20,40,80
ra_ResponseWindow = 4;
#ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR
#1=oneeighth,2=onefourth,3=half,4=one,5=two,6=four,7=eight,8=sixteen
ssb_perRACH_OccasionAndCB_PreamblesPerSSB_PR = 3;
#oneHalf (0..15) 4,8,12,16,...60,64
ssb_perRACH_OccasionAndCB_PreamblesPerSSB = 15;
#ra_ContentionResolutionTimer
#(0..7) 8,16,24,32,40,48,56,64
ra_ContentionResolutionTimer = 7;
rsrp_ThresholdSSB = 19;
#prach-RootSequenceIndex_PR
#1 = 839, 2 = 139
prach_RootSequenceIndex_PR = 2;
prach_RootSequenceIndex = 1;
# SCS for msg1, can only be 15 for 30 kHz < 6 GHz, takes precendence over the one derived from prach-ConfigIndex
#
msg1_SubcarrierSpacing = 1,
# restrictedSetConfig
# 0=unrestricted, 1=restricted type A, 2=restricted type B
restrictedSetConfig = 0,
msg3_DeltaPreamble = 1;
p0_NominalWithGrant =-90;
# pucch-ConfigCommon setup :
# pucchGroupHopping
# 0 = neither, 1= group hopping, 2=sequence hopping
pucchGroupHopping = 0;
hoppingId = 40;
p0_nominal = -70;
# ssb_PositionsInBurs_BitmapPR
# 1=short, 2=medium, 3=long
ssb_PositionsInBurst_PR = 2;
ssb_PositionsInBurst_Bitmap = 1;
# ssb_periodicityServingCell
# 0 = ms5, 1=ms10, 2=ms20, 3=ms40, 4=ms80, 5=ms160, 6=spare2, 7=spare1
ssb_periodicityServingCell = 2;
# dmrs_TypeA_position
# 0 = pos2, 1 = pos3
dmrs_TypeA_Position = 0;
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
subcarrierSpacing = 1;
#tdd-UL-DL-ConfigurationCommon
# subcarrierSpacing
# 0=kHz15, 1=kHz30, 2=kHz60, 3=kHz120
referenceSubcarrierSpacing = 1;
# pattern1
# dl_UL_TransmissionPeriodicity
# 0=ms0p5, 1=ms0p625, 2=ms1, 3=ms1p25, 4=ms2, 5=ms2p5, 6=ms5, 7=ms10
dl_UL_TransmissionPeriodicity = 6;
nrofDownlinkSlots = 7;
nrofDownlinkSymbols = 6;
nrofUplinkSlots = 2;
nrofUplinkSymbols = 4;
ssPBCH_BlockPower = -5;
}
);
# ------- SCTP definitions
SCTP :
{
# Number of streams to use in input/output
SCTP_INSTREAMS = 2;
SCTP_OUTSTREAMS = 2;
};
////////// AMF parameters:
amf_ip_address = ( { ipv4 = "192.168.0.80";
ipv6 = "192:168:30::17";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
GNB_INTERFACE_NAME_FOR_NG_AMF = "demo-oai";
GNB_IPV4_ADDRESS_FOR_NG_AMF = "192.168.0.201/24";
GNB_INTERFACE_NAME_FOR_NGU = "demo-oai";
GNB_IPV4_ADDRESS_FOR_NGU = "192.168.0.201/24";
GNB_PORT_FOR_S1U = 2152; # Spec 2152
};
}
);
MACRLCs = (
{
num_cc = 1;
tr_s_preference = "local_L1";
tr_n_preference = "local_RRC";
pusch_TargetSNRx10 = 300;
pucch_TargetSNRx10 = 300;
pusch_FailureThres = 1000;
ulsch_max_frame_inactivity = 0;
# ul_max_mcs = 28;
}
);
L1s = (
{
num_cc = 1;
tr_n_preference = "local_mac";
prach_dtx_threshold = 120;
pucch0_dtx_threshold = 80;
}
);
RUs = (
{
local_rf = "yes"
nb_tx = 1;
nb_rx = 1;
att_tx = 0;
att_rx = 0;
bands = [78];
max_pdschReferenceSignalPower = -27;
max_rxgain = 102;
eNB_instances = [0];
##beamforming 1x2 matrix: 1 layer x 2 antennas
bf_weights = [0x00007fff, 0x0000];
#clock_src = "internal";
sdr_addrs = "dev=pciex:0,auxdac1=1630";
}
);
THREAD_STRUCT = (
{
#three config for level of parallelism "PARALLEL_SINGLE_THREAD", "PARALLEL_RU_L1_SPLIT", or "PARALLEL_RU_L1_TRX_SPLIT"
parallel_config = "PARALLEL_SINGLE_THREAD";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
rfsimulator :
{
serveraddr = "server";
serverport = "4043";
options = (); #("saviq"); or/and "chanmod"
modelname = "AWGN";
IQfile = "/tmp/rfsimulator.iqs";
};
security = {
# preferred ciphering algorithms
# the first one of the list that an UE supports in chosen
# valid values: nea0, nea1, nea2, nea3
ciphering_algorithms = ( "nea0" );
# preferred integrity algorithms
# the first one of the list that an UE supports in chosen
# valid values: nia0, nia1, nia2, nia3
integrity_algorithms = ( "nia2", "nia0" );
# setting 'drb_ciphering' to "no" disables ciphering for DRBs, no matter
# what 'ciphering_algorithms' configures; same thing for 'drb_integrity'
drb_ciphering = "yes";
drb_integrity = "no";
};
log_config :
{
global_log_level ="info";
hw_log_level ="info";
phy_log_level ="info";
mac_log_level ="info";
rlc_log_level ="info";
pdcp_log_level ="info";
rrc_log_level ="info";
ngap_log_level ="debug";
f1ap_log_level ="debug";
};
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