Commit ee9f8d8f authored by Raphael Defosseux's avatar Raphael Defosseux

Merge remote-tracking branch 'origin/iris_hw_new' into develop_integration_2018_w51

parents 101ed012 6c41b6d7
...@@ -551,6 +551,15 @@ set(TPLIB_ETHERNET_SOURCE ...@@ -551,6 +551,15 @@ set(TPLIB_ETHERNET_SOURCE
) )
add_library(oai_eth_transpro MODULE ${TPLIB_ETHERNET_SOURCE} ) add_library(oai_eth_transpro MODULE ${TPLIB_ETHERNET_SOURCE} )
include_directories("${OPENAIR_TARGETS}/ARCH/IRIS/USERSPACE/LIB/")
set(option_HWIRISLIB_lib "-l SoapySDR")
set(HWLIB_IRIS_SOURCE
${OPENAIR_TARGETS}/ARCH/IRIS/USERSPACE/LIB/iris_lib.cpp
)
add_library(oai_irisdevif MODULE ${HWLIB_IRIS_SOURCE})
target_include_directories(oai_irisdevif PRIVATE /usr/local/lib/SoapySDR/modules0.6/)
target_link_libraries(oai_irisdevif SoapySDR)
include_directories("${OPENAIR_TARGETS}/ARCH/mobipass/") include_directories("${OPENAIR_TARGETS}/ARCH/mobipass/")
set(TPLIB_MOBIPASS_SOURCE set(TPLIB_MOBIPASS_SOURCE
${OPENAIR_TARGETS}/ARCH/mobipass/interface.c ${OPENAIR_TARGETS}/ARCH/mobipass/interface.c
...@@ -1786,6 +1795,15 @@ include_directories(${CRYPTO_INCLUDE_DIRS}) ...@@ -1786,6 +1795,15 @@ include_directories(${CRYPTO_INCLUDE_DIRS})
if (${RF_BOARD} STREQUAL "OAI_USRP") if (${RF_BOARD} STREQUAL "OAI_USRP")
find_package(Boost REQUIRED) find_package(Boost REQUIRED)
include_directories(${LIBBOOST_INCLUDE_DIR}) include_directories(${LIBBOOST_INCLUDE_DIR})
elseif (${RF_BOARD} STREQUAL "OAI_IRIS")
include_directories("${OPENAIR_TARGETS}/ARCH/IRIS/USERSPACE/LIB/")
include_directories("/usr/local/include/")
set(HW_SOURCE ${HW_SOURCE}
${OPENAIR_TARGETS}/ARCH/IRIS/USERSPACE/LIB/iris_lib.cpp)
LINK_DIRECTORIES("/usr/local/lib")
set(option_HW_lib "-lSoapySDR -rdynamic -ldl")
endif (${RF_BOARD} STREQUAL "OAI_USRP") endif (${RF_BOARD} STREQUAL "OAI_USRP")
pkg_search_module(OPENPGM openpgm-5.1 openpgm-5.2) pkg_search_module(OPENPGM openpgm-5.1 openpgm-5.2)
......
...@@ -107,7 +107,7 @@ Options ...@@ -107,7 +107,7 @@ Options
Rel8 limits the implementation to 3GPP Release 8 version Rel8 limits the implementation to 3GPP Release 8 version
Rel10 limits the implementation to 3GPP Release 10 version Rel10 limits the implementation to 3GPP Release 10 version
-w | --hardware -w | --hardware
EXMIMO, USRP, BLADERF, ETHERNET, LMSSDR, None (Default) EXMIMO, USRP, BLADERF, ETHERNET, LMSSDR, IRIS, None (Default)
Adds this RF board support (in external packages installation and in compilation) Adds this RF board support (in external packages installation and in compilation)
-t | --transport protocol -t | --transport protocol
ETHERNET , None ETHERNET , None
...@@ -231,7 +231,7 @@ function main() { ...@@ -231,7 +231,7 @@ function main() {
-w | --hardware) -w | --hardware)
HW="$2" #"${i#*=}" HW="$2" #"${i#*=}"
# Use OAI_USRP as the key word USRP is used inside UHD driver # Use OAI_USRP as the key word USRP is used inside UHD driver
if [ "$HW" != "BLADERF" -a "$HW" != "USRP" -a "$HW" != "LMSSDR" -a "$HW" != "None" -a "$HW" != "EXMIMO" ] ; then if [ "$HW" != "BLADERF" -a "$HW" != "USRP" -a "$HW" != "LMSSDR" -a "$HW" != "None" -a "$HW" != "EXMIMO" -a "$HW" != "IRIS" ] ; then
echo_fatal "Unknown HW type $HW will exit..." echo_fatal "Unknown HW type $HW will exit..."
else else
if [ "$HW" == "USRP" ] ; then if [ "$HW" == "USRP" ] ; then
...@@ -243,6 +243,9 @@ function main() { ...@@ -243,6 +243,9 @@ function main() {
if [ "$HW" == "LMSSDR" ] ; then if [ "$HW" == "LMSSDR" ] ; then
HW="OAI_LMSSDR" HW="OAI_LMSSDR"
fi fi
if [ "$HW" == "IRIS" ] ; then
HW="OAI_IRIS"
fi
echo_info "Setting hardware to: $HW" echo_info "Setting hardware to: $HW"
fi fi
shift 2;; shift 2;;
...@@ -414,7 +417,9 @@ function main() { ...@@ -414,7 +417,9 @@ function main() {
DEADLINE_SCHEDULER_FLAG_USER="False" DEADLINE_SCHEDULER_FLAG_USER="False"
elif [ "$HW" = "OAI_BLADERF" ] ; then elif [ "$HW" = "OAI_BLADERF" ] ; then
DEADLINE_SCHEDULER_FLAG_USER="False" DEADLINE_SCHEDULER_FLAG_USER="False"
elif [ "$HW" = "OAI_LMSSDR" ] ; then elif [ "$HW" = "OAI_LMSSDR" ] ; then
DEADLINE_SCHEDULER_FLAG_USER="False"
elif [ "$HW" = "OAI_IRIS" ] ; then
DEADLINE_SCHEDULER_FLAG_USER="False" DEADLINE_SCHEDULER_FLAG_USER="False"
elif [ "$HW" = "None" ] ; then elif [ "$HW" = "None" ] ; then
DEADLINE_SCHEDULER_FLAG_USER="False" DEADLINE_SCHEDULER_FLAG_USER="False"
...@@ -484,6 +489,13 @@ function main() { ...@@ -484,6 +489,13 @@ function main() {
flash_firmware_bladerf flash_firmware_bladerf
fi fi
fi fi
if [ "$HW" == "OAI_IRIS" ] ; then
echo_info "installing packages for IRIS support"
check_install_soapy
#if [ ! "$DISABLE_HARDWARE_DEPENDENCY" == "True" ]; then
# flash_firmware_iris
#fi
fi
echo_info "installing protobuf/protobuf-c for flexran agent support" echo_info "installing protobuf/protobuf-c for flexran agent support"
install_protobuf_from_source install_protobuf_from_source
install_protobuf_c_from_source install_protobuf_c_from_source
...@@ -759,6 +771,14 @@ function main() { ...@@ -759,6 +771,14 @@ function main() {
ln -sf liboai_lmssdrdevif.so liboai_device.so ln -sf liboai_lmssdrdevif.so liboai_device.so
ln -sf $dbin/liboai_lmssdrdevif.so.$REL $dbin/liboai_device.so ln -sf $dbin/liboai_lmssdrdevif.so.$REL $dbin/liboai_device.so
echo_info "liboai_device.so is linked to LMSSDR device library" echo_info "liboai_device.so is linked to LMSSDR device library"
elif [ "$HW" == "OAI_IRIS" ] ; then
compilations \
$build_dir oai_irisdevif \
liboai_irisdevif.so $dbin/liboai_irisdevif.so.$REL
ln -s liboai_irisdevif.so liboai_device.so
ln -s $dbin/liboai_irisdevif.so.$REL $dbin/liboai_device.so
echo_info "liboai_device.so is linked to IRIS device library"
else else
echo_info "liboai_device.so is not linked to any device library" echo_info "liboai_device.so is not linked to any device library"
fi fi
......
...@@ -379,6 +379,74 @@ check_install_lmssdr_driver(){ ...@@ -379,6 +379,74 @@ check_install_lmssdr_driver(){
} }
install_soapy_from_source(){
soapy_install_log=$OPENAIR_DIR/cmake_targets/log/soapy_install_log.txt
echo_info "\nInstalling Soapy EcoSystem from source. The log file for Soapy installation is here: $soapy_install_log "
(
cd /tmp
echo "Downloading SoapySDR"
rm -rf /tmp/soapysdr
git clone https://github.com/pothosware/SoapySDR.git
cd soapysdr
#git checkout tags/release_003_010_001_001
mkdir -p build
cd build
$CMAKE ../
echo "Compiling SoapySDR"
make -j`nproc`
$SUDO make install
$SUDO ldconfig
cd /tmp
echo "Downloading SoapyRemote"
rm -rf /tmp/soapyremote
git clone https://github.com/pothosware/SoapyRemote.git
cd soapyremote
#git checkout tags/release_003_010_001_001
mkdir -p build
cd build
cmake ../
echo "Compiling SoapyRemote"
make -j`nproc`
$SUDO make install
$SUDO ldconfig
) >& $soapy_install_log
}
install_soapy_iris_from_source(){
iris_install_log=$OPENAIR_DIR/cmake_targets/log/iris_install_log.txt
echo_info "\nInstalling Iris driver from source. The log file for Iris driver installation is here: $iris_install_log "
(
cd /tmp
echo "Downloading SoapyIris"
rm -rf /tmp/sklk-soapyiris
git clone https://github.com/skylarkwireless/sklk-soapyiris.git
cd sklk-soapyiris
mkdir -p build
cd build
cmake ../
echo "Compiling SoapyIris"
make -j`nproc`
$SUDO make install
$SUDO ldconfig
) >& $iris_install_log
}
check_install_soapy () {
#if [[ "$OS_DISTRO" == "ubuntu" ]]; then
#first we remove old installation
$SUDO apt-get remove -y soapysdr soapysdr-server libsoapysdr-dev python-soapysdr python3-soapysdr soapysdr-module-remote || true
$SUDO add-apt-repository -y ppa:myriadrf/drivers
$SUDO apt-get update
$SUDO apt-get install -y soapysdr soapysdr-server libsoapysdr-dev python-soapysdr python3-soapysdr soapysdr-module-remote
#elif [[ "$OS_BASEDISTRO" == "fedora" ]]; then
# $SUDO $INSTALLER -y install software-properties-common python3-software-properties python-software-properties subversion git python3 python-numpy python3-numpy cmake swig python-dev
# install_soapy_from_source
#fi
install_soapy_iris_from_source
}
check_install_additional_tools (){ check_install_additional_tools (){
$SUDO $INSTALLER update -y $SUDO $INSTALLER update -y
if [[ "$OS_DISTRO" == "ubuntu" ]]; then if [[ "$OS_DISTRO" == "ubuntu" ]]; then
......
...@@ -48,7 +48,7 @@ int set_device(openair0_device *device) { ...@@ -48,7 +48,7 @@ int set_device(openair0_device *device) {
case USRP_B200_DEV: case USRP_B200_DEV:
printf("[%s] has loaded USRP B200 device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU")); printf("[%s] has loaded USRP B200 device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU"));
break; break;
case USRP_X300_DEV: case USRP_X300_DEV:
printf("[%s] has loaded USRP X300 device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU")); printf("[%s] has loaded USRP X300 device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU"));
break; break;
case BLADERF_DEV: case BLADERF_DEV:
...@@ -57,6 +57,9 @@ case USRP_X300_DEV: ...@@ -57,6 +57,9 @@ case USRP_X300_DEV:
case LMSSDR_DEV: case LMSSDR_DEV:
printf("[%s] has loaded LMSSDR device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU")); printf("[%s] has loaded LMSSDR device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU"));
break; break;
case IRIS_DEV:
printf("[%s] has loaded Iris device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU"));
break;
case NONE_DEV: case NONE_DEV:
printf("[%s] has not loaded a HW device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU")); printf("[%s] has not loaded a HW device.\n",((device->host_type == RAU_HOST) ? "RAU": "RRU"));
break; break;
......
...@@ -95,6 +95,8 @@ typedef enum { ...@@ -95,6 +95,8 @@ typedef enum {
BLADERF_DEV, BLADERF_DEV,
/*!\brief device is LMSSDR (SoDeRa)*/ /*!\brief device is LMSSDR (SoDeRa)*/
LMSSDR_DEV, LMSSDR_DEV,
/*!\brief device is Iris */
IRIS_DEV,
/*!\brief device is NONE*/ /*!\brief device is NONE*/
NONE_DEV, NONE_DEV,
MAX_RF_DEV_TYPE MAX_RF_DEV_TYPE
......
IRIS_OBJ += $(OPENAIR_TARGETS)/ARCH/IRIS/USERSPACE/LIB/iris_lib.o
IRIS_FILE_OBJ += $(OPENAIR_TARGETS)/ARCH/IRIS/USERSPACE/LIB/iris_lib.cpp
IRIS_CFLAGS += -I$(OPENAIR_TARGETS)/ARCH/COMMON -I$(OPENAIR_TARGETS)/ARCH/IRIS/USERSPACE/LIB/ -I$(OPENAIR_TARGETS)/COMMON
/** iris_lib.cpp
*
* \authors: Rahman Doost-Mohammady : doost@rice.edu
* Clay Shepard : cws@rice.edu
*/
#include <string.h>
#include <pthread.h>
#include <unistd.h>
#include <stdio.h>
#include <SoapySDR/Device.hpp>
#include <SoapySDR/Formats.hpp>
#include <SoapySDR/Time.hpp>
//#include <boost/format.hpp>
#include <iostream>
#include <complex>
#include <fstream>
#include <cmath>
#include <time.h>
#include <limits>
#include "common/utils/LOG/log_extern.h"
#include "common_lib.h"
#include <chrono>
#ifdef __SSE4_1__
# include <smmintrin.h>
#endif
#ifdef __AVX2__
# include <immintrin.h>
#endif
#define MOVE_DC
#define SAMPLE_RATE_DOWN 1
/*! \brief Iris Configuration */
typedef struct {
// --------------------------------
// variables for Iris configuration
// --------------------------------
//! Iris device pointer
std::vector<SoapySDR::Device *> iris;
int device_num;
int rx_num_channels;
int tx_num_channels;
//create a send streamer and a receive streamer
//! Iris TX Stream
std::vector<SoapySDR::Stream *> txStream;
//! Iris RX Stream
std::vector<SoapySDR::Stream *> rxStream;
//! Sampling rate
double sample_rate;
//! time offset between transmiter timestamp and receiver timestamp;
double tdiff;
//! TX forward samples.
int tx_forward_nsamps; //166 for 20Mhz
// --------------------------------
// Debug and output control
// --------------------------------
//! Number of underflows
int num_underflows;
//! Number of overflows
int num_overflows;
//! Number of sequential errors
int num_seq_errors;
//! tx count
int64_t tx_count;
//! rx count
int64_t rx_count;
//! timestamp of RX packet
openair0_timestamp rx_timestamp;
} iris_state_t;
/*! \brief Called to start the Iris lime transceiver. Return 0 if OK, < 0 if error
@param device pointer to the device structure specific to the RF hardware target
*/
static int trx_iris_start(openair0_device *device) {
iris_state_t *s = (iris_state_t *) device->priv;
long long timeNs = s->iris[0]->getHardwareTime("") + 500000;
int flags = 0;
//flags |= SOAPY_SDR_HAS_TIME;
int r;
for (r = 0; r < s->device_num; r++) {
int ret = s->iris[r]->activateStream(s->rxStream[r], flags, timeNs, 0);
int ret2 = s->iris[r]->activateStream(s->txStream[r]);
if (ret < 0 | ret2 < 0)
return -1;
}
return 0;
}
/*! \brief Stop Iris
* \param card refers to the hardware index to use
*/
int trx_iris_stop(openair0_device *device) {
iris_state_t *s = (iris_state_t *) device->priv;
int r;
for (r = 0; r < s->device_num; r++) {
s->iris[r]->deactivateStream(s->txStream[r]);
s->iris[r]->deactivateStream(s->rxStream[r]);
}
return (0);
}
/*! \brief Terminate operation of the Iris lime transceiver -- free all associated resources
* \param device the hardware to use
*/
static void trx_iris_end(openair0_device *device) {
LOG_I(HW, "Closing Iris device.\n");
trx_iris_stop(device);
iris_state_t *s = (iris_state_t *) device->priv;
int r;
for (r = 0; r < s->device_num; r++) {
s->iris[r]->closeStream(s->txStream[r]);
s->iris[r]->closeStream(s->rxStream[r]);
SoapySDR::Device::unmake(s->iris[r]);
}
}
/*! \brief Called to send samples to the Iris 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 antenna_id index of the antenna if the device has multiple anteannas
@param flags flags must be set to TRUE if timestamp parameter needs to be applied
*/
static int
trx_iris_write(openair0_device *device, openair0_timestamp timestamp, void **buff, int nsamps, int cc, int flags) {
using namespace std::chrono;
static long long int loop = 0;
static long time_min = 0, time_max = 0, time_avg = 0;
struct timespec tp_start, tp_end;
long time_diff;
int ret = 0, ret_i = 0;
int flag = 0;
iris_state_t *s = (iris_state_t *) device->priv;
int nsamps2; // aligned to upper 32 or 16 byte boundary
#if defined(__x86_64) || defined(__i386__)
#ifdef __AVX2__
nsamps2 = (nsamps+7)>>3;
__m256i buff_tx[2][nsamps2];
#else
nsamps2 = (nsamps+3)>>2;
__m128i buff_tx[2][nsamps2];
#endif
#endif
// bring RX data into 12 LSBs for softmodem RX
for (int i=0; i<cc; i++) {
for (int j=0; j<nsamps2; j++) {
#if defined(__x86_64__) || defined(__i386__)
#ifdef __AVX2__
buff_tx[i][j] = _mm256_slli_epi16(((__m256i *)buff[i])[j],4);
#else
buff_tx[i][j] = _mm_slli_epi16(((__m128i *)buff[i])[j],4);
#endif
#endif
}
}
clock_gettime(CLOCK_MONOTONIC_RAW, &tp_start);
// This hack was added by cws to help keep packets flowing
if (flags)
flag |= SOAPY_SDR_HAS_TIME;
else {
long long tempHack = s->iris[0]->getHardwareTime("");
return nsamps;
}
if (flags == 2 || flags == 1) { // start of burst
} else if (flags == 3 | flags == 4) {
flag |= SOAPY_SDR_END_BURST;
}
long long timeNs = SoapySDR::ticksToTimeNs(timestamp, s->sample_rate / SAMPLE_RATE_DOWN);
uint32_t *samps[2]; //= (uint32_t **)buff;
int r;
int m = s->tx_num_channels;
for (r = 0; r < s->device_num; r++) {
int samples_sent = 0;
samps[0] = (uint32_t *) buff_tx[m * r];
if (cc % 2 == 0)
samps[1] = (uint32_t *) buff_tx[m * r + 1]; //cws: it seems another thread can clobber these, so we need to save them locally.
#ifdef IRIS_DEBUG
int i;
for (i = 200; i < 216; i++)
printf("%d, ",((int16_t)(samps[0][i]>>16))>>4);
printf("\n");
//printf("\nHardware time before write: %lld, tx_time_stamp: %lld\n", s->iris[0]->getHardwareTime(""), timeNs);
#endif
ret = s->iris[r]->writeStream(s->txStream[r], (void **) samps, (size_t)(nsamps), flag, timeNs, 1000000);
if (ret < 0)
printf("Unable to write stream!\n");
else
samples_sent = ret;
if (samples_sent != nsamps)
printf("[xmit] tx samples %d != %d\n", samples_sent, nsamps);
}
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 antenna_id Index of antenna for which to receive samples
* \returns the number of sample read
*/
static int trx_iris_read(openair0_device *device, openair0_timestamp *ptimestamp, void **buff, int nsamps, int cc) {
int ret = 0;
static long long nextTime;
static bool nextTimeValid = false;
iris_state_t *s = (iris_state_t *) device->priv;
bool time_set = false;
long long timeNs = 0;
int flags;
int samples_received;
uint32_t *samps[2]; //= (uint32_t **)buff;
int r;
int m = s->rx_num_channels;
int nsamps2; // aligned to upper 32 or 16 byte boundary
#if defined(__x86_64) || defined(__i386__)
#ifdef __AVX2__
nsamps2 = (nsamps+7)>>3;
__m256i buff_tmp[2][nsamps2];
#else
nsamps2 = (nsamps+3)>>2;
__m128i buff_tmp[2][nsamps2];
#endif
#endif
for (r = 0; r < s->device_num; r++) {
flags = 0;
samples_received = 0;
samps[0] = (uint32_t *) buff_tmp[m * r];
if (cc % 2 == 0)
samps[1] = (uint32_t *) buff_tmp[m * r + 1];
flags = 0;
ret = s->iris[r]->readStream(s->rxStream[r], (void **) samps, (size_t)(nsamps), flags,
timeNs, 1000000);
if (ret < 0) {
if (ret == SOAPY_SDR_TIME_ERROR)
printf("[recv] Time Error in tx stream!\n");
else if (ret == SOAPY_SDR_OVERFLOW | (flags & SOAPY_SDR_END_ABRUPT))
printf("[recv] Overflow occured!\n");
else if (ret == SOAPY_SDR_TIMEOUT)
printf("[recv] Timeout occured!\n");
else if (ret == SOAPY_SDR_STREAM_ERROR)
printf("[recv] Stream (tx) error occured!\n");
else if (ret == SOAPY_SDR_CORRUPTION)
printf("[recv] Bad packet occured!\n");
break;
} else
samples_received = ret;
if (r == 0) {
if (samples_received == ret) // first batch
{
if (flags & SOAPY_SDR_HAS_TIME) {
s->rx_timestamp = SoapySDR::timeNsToTicks(timeNs, s->sample_rate / SAMPLE_RATE_DOWN);
*ptimestamp = s->rx_timestamp;
nextTime = timeNs;
nextTimeValid = true;
time_set = true;
//printf("1) time set %llu \n", *ptimestamp);
}
}
}
if (r == 0) {
if (samples_received == nsamps) {
if (flags & SOAPY_SDR_HAS_TIME) {
s->rx_timestamp = SoapySDR::timeNsToTicks(nextTime, s->sample_rate / SAMPLE_RATE_DOWN);
*ptimestamp = s->rx_timestamp;
nextTime = timeNs;
nextTimeValid = true;
time_set = true;
}
} else if (samples_received < nsamps)
printf("[recv] received %d samples out of %d\n", samples_received, nsamps);
s->rx_count += samples_received;
if (s->sample_rate != 0 && nextTimeValid) {
if (!time_set) {
s->rx_timestamp = SoapySDR::timeNsToTicks(nextTime, s->sample_rate / SAMPLE_RATE_DOWN);
*ptimestamp = s->rx_timestamp;
//printf("2) time set %llu, nextTime will be %llu \n", *ptimestamp, nextTime);
}
nextTime += SoapySDR::ticksToTimeNs(samples_received, s->sample_rate / SAMPLE_RATE_DOWN);
}
}
// bring RX data into 12 LSBs for softmodem RX
for (int i=0; i<cc; i++) {
for (int j=0; j<nsamps2; j++) {
#if defined(__x86_64__) || defined(__i386__)
#ifdef __AVX2__
((__m256i *)buff[i])[j] = _mm256_srai_epi16(buff_tmp[i][j],4);
#else
((__m128i *)buff[i])[j] = _mm_srai_epi16(buff_tmp[i][j],4);
#endif
#endif
}
}
}
return samples_received;
}
/*! \brief Get current timestamp of Iris
* \param device the hardware to use
*/
openair0_timestamp get_iris_time(openair0_device *device) {
iris_state_t *s = (iris_state_t *) device->priv;
return SoapySDR::timeNsToTicks(s->iris[0]->getHardwareTime(""), s->sample_rate);
}
/*! \brief Compares two variables within precision
* \param a first variable
* \param b second variable
*/
static bool is_equal(double a, double b) {
return std::fabs(a - b) < std::numeric_limits<double>::epsilon();
}
void *set_freq_thread(void *arg) {
openair0_device *device = (openair0_device *) arg;
iris_state_t *s = (iris_state_t *) device->priv;
int r, i;
printf("Setting Iris TX Freq %f, RX Freq %f\n", device->openair0_cfg[0].tx_freq[0],
device->openair0_cfg[0].rx_freq[0]);
// add check for the number of channels in the cfg
for (r = 0; r < s->device_num; r++) {
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_RX); i++) {
if (i < s->rx_num_channels)
s->iris[r]->setFrequency(SOAPY_SDR_RX, i, "RF", device->openair0_cfg[0].rx_freq[i]);
}
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_TX); i++) {
if (i < s->tx_num_channels)
s->iris[r]->setFrequency(SOAPY_SDR_TX, i, "RF", device->openair0_cfg[0].tx_freq[i]);
}
}
}
/*! \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_iris_set_freq(openair0_device *device, openair0_config_t *openair0_cfg, int dont_block) {
iris_state_t *s = (iris_state_t *) device->priv;
pthread_t f_thread;
if (dont_block)
pthread_create(&f_thread, NULL, set_freq_thread, (void *) device);
else {
int r, i;
for (r = 0; r < s->device_num; r++) {
printf("Setting Iris TX Freq %f, RX Freq %f\n", openair0_cfg[0].tx_freq[0], openair0_cfg[0].rx_freq[0]);
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_RX); i++) {
if (i < s->rx_num_channels) {
s->iris[r]->setFrequency(SOAPY_SDR_RX, i, "RF", openair0_cfg[0].rx_freq[i]);
}
}
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_TX); i++) {
if (i < s->tx_num_channels) {
s->iris[r]->setFrequency(SOAPY_SDR_TX, i, "RF", openair0_cfg[0].tx_freq[i]);
}
}
}
}
return (0);
}
/*! \brief Set Gains (TX/RX)
* \param device the hardware to use
* \param openair0_cfg RF frontend parameters set by application
* \returns 0 in success
*/
int trx_iris_set_gains(openair0_device *device,
openair0_config_t *openair0_cfg) {
iris_state_t *s = (iris_state_t *) device->priv;
int r;
for (r = 0; r < s->device_num; r++) {
s->iris[r]->setGain(SOAPY_SDR_RX, 0, openair0_cfg[0].rx_gain[0]);
s->iris[r]->setGain(SOAPY_SDR_TX, 0, openair0_cfg[0].tx_gain[0]);
s->iris[r]->setGain(SOAPY_SDR_RX, 1, openair0_cfg[0].rx_gain[1]);
s->iris[r]->setGain(SOAPY_SDR_TX, 1, openair0_cfg[0].tx_gain[1]);
}
return (0);
}
/*! \brief Iris RX calibration table */
rx_gain_calib_table_t calib_table_iris[] = {
{3500000000.0, 83},
{2660000000.0, 83},
{2580000000.0, 83},
{2300000000.0, 83},
{1880000000.0, 83},
{816000000.0, 83},
{-1, 0}};
/*! \brief Set RX gain offset
* \param openair0_cfg RF frontend parameters set by application
* \param chain_index RF chain to apply settings to
* \returns 0 in success
*/
void set_rx_gain_offset(openair0_config_t *openair0_cfg, int chain_index, int bw_gain_adjust) {
int i = 0;
// loop through calibration table to find best adjustment factor for RX frequency
double min_diff = 6e9, diff, gain_adj = 0.0;
if (bw_gain_adjust == 1) {
switch ((int) openair0_cfg[0].sample_rate) {
case 30720000:
break;
case 23040000:
gain_adj = 1.25;
break;
case 15360000:
gain_adj = 3.0;
break;
case 7680000:
gain_adj = 6.0;
break;
case 3840000:
gain_adj = 9.0;
break;
case 1920000:
gain_adj = 12.0;
break;
default:
printf("unknown sampling rate %d\n", (int) openair0_cfg[0].sample_rate);
exit(-1);
break;
}
}
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 + gain_adj;
}
i++;
}
}
/*! \brief print the Iris statistics
* \param device the hardware to use
* \returns 0 on success
*/
int trx_iris_get_stats(openair0_device *device) {
return (0);
}
/*! \brief Reset the Iris statistics
* \param device the hardware to use
* \returns 0 on success
*/
int trx_iris_reset_stats(openair0_device *device) {
return (0);
}
extern "C" {
/*! \brief Initialize Openair Iris target. It returns 0 if OK
* \param device the hardware to use
* \param openair0_cfg RF frontend parameters set by application
*/
int device_init(openair0_device *device, openair0_config_t *openair0_cfg) {
size_t i, r, card;
int bw_gain_adjust = 0;
openair0_cfg[0].rx_gain_calib_table = calib_table_iris;
iris_state_t *s = (iris_state_t *) malloc(sizeof(iris_state_t));
memset(s, 0, sizeof(iris_state_t));
std::string devFE("DEV");
std::string cbrsFE("CBRS");
std::string wireFormat("WIRE");
// Initialize Iris device
device->openair0_cfg = openair0_cfg;
SoapySDR::Kwargs args;
args["driver"] = "iris";
char *iris_addrs = device->openair0_cfg[0].sdr_addrs;
if (iris_addrs == NULL)
{
s->iris.push_back(SoapySDR::Device::make(args));
}
else
{
char *serial = strtok(iris_addrs, ",");
while (serial != NULL) {
LOG_I(HW, "Attempting to open Iris device %s\n", serial);
args["serial"] = serial;
s->iris.push_back(SoapySDR::Device::make(args));
serial = strtok(NULL, ",");
}
}
s->device_num = s->iris.size();
device->type = IRIS_DEV;
switch ((int) openair0_cfg[0].sample_rate) {
case 30720000:
//openair0_cfg[0].samples_per_packet = 1024;
openair0_cfg[0].tx_sample_advance = 115;
openair0_cfg[0].tx_bw = 20e6;
openair0_cfg[0].rx_bw = 20e6;
break;
case 23040000:
//openair0_cfg[0].samples_per_packet = 1024;
openair0_cfg[0].tx_sample_advance = 113;
openair0_cfg[0].tx_bw = 15e6;
openair0_cfg[0].rx_bw = 15e6;
break;
case 15360000:
//openair0_cfg[0].samples_per_packet = 1024;
openair0_cfg[0].tx_sample_advance = 60;
openair0_cfg[0].tx_bw = 10e6;
openair0_cfg[0].rx_bw = 10e6;
break;
case 7680000:
//openair0_cfg[0].samples_per_packet = 1024;
openair0_cfg[0].tx_sample_advance = 30;
openair0_cfg[0].tx_bw = 5e6;
openair0_cfg[0].rx_bw = 5e6;
break;
case 1920000:
//openair0_cfg[0].samples_per_packet = 1024;
openair0_cfg[0].tx_sample_advance = 20;
openair0_cfg[0].tx_bw = 1.4e6;
openair0_cfg[0].rx_bw = 1.4e6;
break;
default:
printf("Error: unknown sampling rate %f\n", openair0_cfg[0].sample_rate);
exit(-1);
break;
}
printf("tx_sample_advance %d\n", openair0_cfg[0].tx_sample_advance);
s->rx_num_channels = openair0_cfg[0].rx_num_channels;
s->tx_num_channels = openair0_cfg[0].tx_num_channels;
if ((s->rx_num_channels == 1 || s->rx_num_channels == 2) && (s->tx_num_channels == 1 || s->tx_num_channels == 2))
printf("Enabling %d rx and %d tx channel(s) on each device...\n", s->rx_num_channels, s->tx_num_channels);
else {
printf("Invalid rx or tx number of channels (%d, %d)\n", s->rx_num_channels, s->tx_num_channels);
exit(-1);
}
for (r = 0; r < s->device_num; r++) {
//this is unnecessary -- it will set the correct master clock based on sample rate
/*switch ((int) openair0_cfg[0].sample_rate) {
case 1920000:
s->iris[r]->setMasterClockRate(256 * openair0_cfg[0].sample_rate);
break;
case 3840000:
s->iris[r]->setMasterClockRate(128 * openair0_cfg[0].sample_rate);
break;
case 7680000:
s->iris[r]->setMasterClockRate(64 * openair0_cfg[0].sample_rate);
break;
case 15360000:
s->iris[r]->setMasterClockRate(32 * openair0_cfg[0].sample_rate);
break;
case 30720000:
s->iris[r]->setMasterClockRate(16 * openair0_cfg[0].sample_rate);
break;
default:
printf("Error: unknown sampling rate %f\n", openair0_cfg[0].sample_rate);
exit(-1);
break;
}*/
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_RX); i++) {
if (i < s->rx_num_channels) {
s->iris[r]->setSampleRate(SOAPY_SDR_RX, i, openair0_cfg[0].sample_rate / SAMPLE_RATE_DOWN);
#ifdef MOVE_DC
printf("Moving DC out of main carrier for rx...\n");
s->iris[r]->setFrequency(SOAPY_SDR_RX, i, "RF", openair0_cfg[0].rx_freq[i]-.75*openair0_cfg[0].sample_rate);
s->iris[r]->setFrequency(SOAPY_SDR_RX, i, "BB", .75*openair0_cfg[0].sample_rate);
#else
s->iris[r]->setFrequency(SOAPY_SDR_RX, i, "RF", openair0_cfg[0].rx_freq[i]);
#endif
set_rx_gain_offset(&openair0_cfg[0], i, bw_gain_adjust);
//s->iris[r]->setGain(SOAPY_SDR_RX, i, openair0_cfg[0].rx_gain[i] - openair0_cfg[0].rx_gain_offset[i]);
printf("rx gain offset: %f, rx_gain: %f, tx_tgain: %f\n", openair0_cfg[0].rx_gain_offset[i], openair0_cfg[0].rx_gain[i], openair0_cfg[0].tx_gain[i]);
if (s->iris[r]->getHardwareInfo()["frontend"].compare(devFE) != 0) {
s->iris[r]->setGain(SOAPY_SDR_RX, i, "LNA", openair0_cfg[0].rx_gain[i] - openair0_cfg[0].rx_gain_offset[i]);
//s->iris[r]->setGain(SOAPY_SDR_RX, i, "LNA", 0);
s->iris[r]->setGain(SOAPY_SDR_RX, i, "LNA1", 30);
s->iris[r]->setGain(SOAPY_SDR_RX, i, "LNA2", 17);
s->iris[r]->setGain(SOAPY_SDR_RX, i, "TIA", 7);
s->iris[r]->setGain(SOAPY_SDR_RX, i, "PGA", 18);
s->iris[r]->setGain(SOAPY_SDR_RX, i, "ATTN", 0);
} else {
s->iris[r]->setGain(SOAPY_SDR_RX, i, "LNA", openair0_cfg[0].rx_gain[i] - openair0_cfg[0].rx_gain_offset[i]); // [0,30]
s->iris[r]->setGain(SOAPY_SDR_RX, i, "TIA", 7); // [0,12,6]
s->iris[r]->setGain(SOAPY_SDR_RX, i, "PGA", 18); // [-12,19,1]
//s->iris[r]->setGain(SOAPY_SDR_RX, i, 50); // [-12,19,1]
}
s->iris[r]->setDCOffsetMode(SOAPY_SDR_RX, i, true); // move somewhere else
}
}
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_TX); i++) {
if (i < s->tx_num_channels) {
s->iris[r]->setSampleRate(SOAPY_SDR_TX, i, openair0_cfg[0].sample_rate / SAMPLE_RATE_DOWN);
#ifdef MOVE_DC
printf("Moving DC out of main carrier for tx...\n");
s->iris[r]->setFrequency(SOAPY_SDR_TX, i, "RF", openair0_cfg[0].tx_freq[i]-.75*openair0_cfg[0].sample_rate);
s->iris[r]->setFrequency(SOAPY_SDR_TX, i, "BB", .75*openair0_cfg[0].sample_rate);
#else
s->iris[r]->setFrequency(SOAPY_SDR_TX, i, "RF", openair0_cfg[0].tx_freq[i]);
#endif
if (s->iris[r]->getHardwareInfo()["frontend"].compare(devFE) == 0) {
s->iris[r]->setGain(SOAPY_SDR_TX, i, "PAD", openair0_cfg[0].tx_gain[i]);
//s->iris[r]->setGain(SOAPY_SDR_TX, i, "PAD", 50);
s->iris[r]->setGain(SOAPY_SDR_TX, i, "IAMP", 12);
//s->iris[r]->writeSetting("TX_ENABLE_DELAY", "0");
//s->iris[r]->writeSetting("TX_DISABLE_DELAY", "100");
} else {
s->iris[r]->setGain(SOAPY_SDR_TX, i, "PAD", openair0_cfg[0].tx_gain[i]);
s->iris[r]->setGain(SOAPY_SDR_TX, i, "ATTN", 0); // [-18, 0, 6] dB
s->iris[r]->setGain(SOAPY_SDR_TX, i, "IAMP", 6); // [-12, 12, 1] dB
//s->iris[r]->setGain(SOAPY_SDR_TX, i, "PAD", 44); //openair0_cfg[0].tx_gain[i]);
//s->iris[r]->setGain(SOAPY_SDR_TX, i, "PAD", 35); // [0, 52, 1] dB
//s->iris[r]->setGain(SOAPY_SDR_TX, i, "PA1", 17); // 17 ??? dB
s->iris[r]->setGain(SOAPY_SDR_TX, i, "PA2", 0); // [0, 17, 17] dB
//s->iris[r]->setGain(SOAPY_SDR_TX, i, "PA3", 20); // 33 ??? dB
s->iris[r]->writeSetting("TX_ENABLE_DELAY", "0");
s->iris[r]->writeSetting("TX_DISABLE_DELAY", "100");
}
// if (openair0_cfg[0].duplex_mode == 0) {
// printf("\nFDD: Enable TX antenna override\n");
// s->iris[r]->writeSetting(SOAPY_SDR_TX, i, "TX_ENB_OVERRIDE",
// "true"); // From Josh: forces tx switching to be on always transmit regardless of bursts
// }
}
}
printf("Actual master clock: %fMHz...\n", (s->iris[r]->getMasterClockRate() / 1e6));
int tx_filt_bw = openair0_cfg[0].tx_bw;
int rx_filt_bw = openair0_cfg[0].rx_bw;
#ifdef MOVE_DC //the filter is centered around the carrier, so we have to expand it if we have moved the DC tone.
tx_filt_bw *= 3;
rx_filt_bw *= 3;
#endif
/* Setting TX/RX BW */
for (i = 0; i < s->tx_num_channels; i++) {
if (i < s->iris[r]->getNumChannels(SOAPY_SDR_TX)) {
s->iris[r]->setBandwidth(SOAPY_SDR_TX, i, tx_filt_bw);
printf("Setting tx bandwidth on channel %lu/%lu: BW %f (readback %f)\n", i,
s->iris[r]->getNumChannels(SOAPY_SDR_TX), tx_filt_bw / 1e6,
s->iris[r]->getBandwidth(SOAPY_SDR_TX, i) / 1e6);
}
}
for (i = 0; i < s->rx_num_channels; i++) {
if (i < s->iris[r]->getNumChannels(SOAPY_SDR_RX)) {
s->iris[r]->setBandwidth(SOAPY_SDR_RX, i, rx_filt_bw);
printf("Setting rx bandwidth on channel %lu/%lu : BW %f (readback %f)\n", i,
s->iris[r]->getNumChannels(SOAPY_SDR_RX), rx_filt_bw / 1e6,
s->iris[r]->getBandwidth(SOAPY_SDR_RX, i) / 1e6);
}
}
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_TX); i++) {
if (i < s->tx_num_channels) {
printf("\nUsing SKLK calibration...\n");
s->iris[r]->writeSetting(SOAPY_SDR_TX, i, "CALIBRATE", "SKLK");
}
}
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_RX); i++) {
if (i < s->rx_num_channels) {
printf("\nUsing SKLK calibration...\n");
s->iris[r]->writeSetting(SOAPY_SDR_RX, i, "CALIBRATE", "SKLK");
}
}
if (s->iris[r]->getHardwareInfo()["frontend"].compare(devFE) == 0) {
for (i = 0; i < s->iris[r]->getNumChannels(SOAPY_SDR_RX); i++) {
if (openair0_cfg[0].duplex_mode == 0) {
printf("\nFDD: Setting receive antenna to %s\n", s->iris[r]->listAntennas(SOAPY_SDR_RX, i)[1].c_str());
if (i < s->rx_num_channels)
s->iris[r]->setAntenna(SOAPY_SDR_RX, i, "RX");
} else {
printf("\nTDD: Setting receive antenna to %s\n", s->iris[r]->listAntennas(SOAPY_SDR_RX, i)[0].c_str());
if (i < s->rx_num_channels)
s->iris[r]->setAntenna(SOAPY_SDR_RX, i, "TRX");
}
}
}
//s->iris[r]->writeSetting("TX_SW_DELAY", std::to_string(
// -openair0_cfg[0].tx_sample_advance)); //should offset switching to compensate for RF path (Lime) delay -- this will eventually be automated
// create tx & rx streamer
//const SoapySDR::Kwargs &arg = SoapySDR::Kwargs();
std::map <std::string, std::string> rxStreamArgs;
rxStreamArgs["WIRE"] = SOAPY_SDR_CS16;
std::vector <size_t> channels;
for (i = 0; i < s->rx_num_channels; i++)
if (i < s->iris[r]->getNumChannels(SOAPY_SDR_RX))
channels.push_back(i);
s->rxStream.push_back(s->iris[r]->setupStream(SOAPY_SDR_RX, SOAPY_SDR_CS16, channels));//, rxStreamArgs));
std::vector <size_t> tx_channels = {};
for (i = 0; i < s->tx_num_channels; i++)
if (i < s->iris[r]->getNumChannels(SOAPY_SDR_TX))
tx_channels.push_back(i);
s->txStream.push_back(s->iris[r]->setupStream(SOAPY_SDR_TX, SOAPY_SDR_CS16, tx_channels)); //, arg));
//s->iris[r]->setHardwareTime(0, "");
std::cout << "Front end detected: " << s->iris[r]->getHardwareInfo()["frontend"] << "\n";
for (i = 0; i < s->rx_num_channels; i++) {
if (i < s->iris[r]->getNumChannels(SOAPY_SDR_RX)) {
printf("RX Channel %lu\n", i);
printf("Actual RX sample rate: %fMSps...\n", (s->iris[r]->getSampleRate(SOAPY_SDR_RX, i) / 1e6));
printf("Actual RX frequency: %fGHz...\n", (s->iris[r]->getFrequency(SOAPY_SDR_RX, i) / 1e9));
printf("Actual RX gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_RX, i)));
printf("Actual RX LNA gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_RX, i, "LNA")));
printf("Actual RX PGA gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_RX, i, "PGA")));
printf("Actual RX TIA gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_RX, i, "TIA")));
if (s->iris[r]->getHardwareInfo()["frontend"].compare(devFE) != 0) {
printf("Actual RX LNA1 gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_RX, i, "LNA1")));
printf("Actual RX LNA2 gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_RX, i, "LNA2")));
}
printf("Actual RX bandwidth: %fM...\n", (s->iris[r]->getBandwidth(SOAPY_SDR_RX, i) / 1e6));
printf("Actual RX antenna: %s...\n", (s->iris[r]->getAntenna(SOAPY_SDR_RX, i).c_str()));
}
}
for (i = 0; i < s->tx_num_channels; i++) {
if (i < s->iris[r]->getNumChannels(SOAPY_SDR_TX)) {
printf("TX Channel %lu\n", i);
printf("Actual TX sample rate: %fMSps...\n", (s->iris[r]->getSampleRate(SOAPY_SDR_TX, i) / 1e6));
printf("Actual TX frequency: %fGHz...\n", (s->iris[r]->getFrequency(SOAPY_SDR_TX, i) / 1e9));
printf("Actual TX gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_TX, i)));
printf("Actual TX PAD gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_TX, i, "PAD")));
printf("Actual TX IAMP gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_TX, i, "IAMP")));
if (s->iris[r]->getHardwareInfo()["frontend"].compare(devFE) != 0) {
printf("Actual TX PA1 gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_TX, i, "PA1")));
printf("Actual TX PA2 gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_TX, i, "PA2")));
printf("Actual TX PA3 gain: %f...\n", (s->iris[r]->getGain(SOAPY_SDR_TX, i, "PA3")));
}
printf("Actual TX bandwidth: %fM...\n", (s->iris[r]->getBandwidth(SOAPY_SDR_TX, i) / 1e6));
printf("Actual TX antenna: %s...\n", (s->iris[r]->getAntenna(SOAPY_SDR_TX, i).c_str()));
}
}
}
s->iris[0]->writeSetting("SYNC_DELAYS", "");
for (r = 0; r < s->device_num; r++)
s->iris[r]->setHardwareTime(0, "TRIGGER");
s->iris[0]->writeSetting("TRIGGER_GEN", "");
for (r = 0; r < s->device_num; r++)
printf("Device timestamp: %f...\n", (s->iris[r]->getHardwareTime("TRIGGER") / 1e9));
device->priv = s;
device->trx_start_func = trx_iris_start;
device->trx_write_func = trx_iris_write;
device->trx_read_func = trx_iris_read;
device->trx_get_stats_func = trx_iris_get_stats;
device->trx_reset_stats_func = trx_iris_reset_stats;
device->trx_end_func = trx_iris_end;
device->trx_stop_func = trx_iris_stop;
device->trx_set_freq_func = trx_iris_set_freq;
device->trx_set_gains_func = trx_iris_set_gains;
device->openair0_cfg = openair0_cfg;
s->sample_rate = openair0_cfg[0].sample_rate;
// TODO:
// init tx_forward_nsamps based iris_time_offset ex
if (is_equal(s->sample_rate, (double) 30.72e6))
s->tx_forward_nsamps = 176;
if (is_equal(s->sample_rate, (double) 15.36e6))
s->tx_forward_nsamps = 90;
if (is_equal(s->sample_rate, (double) 7.68e6))
s->tx_forward_nsamps = 50;
LOG_I(HW, "Finished initializing %d Iris device(s).\n", s->device_num);
fflush(stdout);
return 0;
}
}
/*@}*/
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 = 208; mnc = 92; 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 = "TDD";
tdd_config = 3;
tdd_config_s = 0;
prefix_type = "NORMAL";
eutra_band = 38;
downlink_frequency = 2580000000L;
uplink_frequency_offset = 0;
Nid_cell = 10;
N_RB_DL = 25;
Nid_cell_mbsfn = 0;
nb_antenna_ports = 1;
nb_antennas_tx = 1;
nb_antennas_rx = 1;
tx_gain = 52; # [~50 for DEV-FE, ~30 for CBRS-FE]
rx_gain = 115; # [115 for DEV-FE, 90 for CBRS-FE]
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 = 32;
pdsch_referenceSignalPower = -30;
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 = -70;
pusch_alpha = "AL1";
pucch_p0_Nominal = -96;
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 = -96;
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 = "127.0.0.20";
ipv6 = "fe80::d65d:dfff:fe1d:f4d4";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
ENB_INTERFACE_NAME_FOR_S1_MME = "eno1";
ENB_IPV4_ADDRESS_FOR_S1_MME = "127.0.0.10/8";
ENB_INTERFACE_NAME_FOR_S1U = "enp5s0";
ENB_IPV4_ADDRESS_FOR_S1U = "127.0.0.10/8";
ENB_PORT_FOR_S1U = 2152; # Spec 2152
ENB_IPV4_ADDRESS_FOR_X2C = "127.0.0.10/8";
ENB_PORT_FOR_X2C = 36422; # Spec 36422
};
}
);
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 = 0
att_rx = 0;
bands = [7];
max_pdschReferenceSignalPower = -27;
max_rxgain = 125;
eNB_instances = [0];
#sdr_addrs = "RF3C000025";
}
);
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_RU_L1_TRX_SPLIT";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
log_config :
{
global_log_level ="info";
global_log_verbosity ="medium";
hw_log_level ="info";
hw_log_verbosity ="medium";
phy_log_level ="info";
phy_log_verbosity ="medium";
mac_log_level ="info";
mac_log_verbosity ="high";
rlc_log_level ="info";
rlc_log_verbosity ="medium";
pdcp_log_level ="info";
pdcp_log_verbosity ="medium";
rrc_log_level ="info";
rrc_log_verbosity ="medium";
};
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 = 208; mnc = 92; 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 = "TDD";
tdd_config = 1;
tdd_config_s = 0;
prefix_type = "NORMAL";
eutra_band = 42;
downlink_frequency = 3500000000L;
uplink_frequency_offset = 0;
Nid_cell = 10;
N_RB_DL = 25;
Nid_cell_mbsfn = 0;
nb_antenna_ports = 1;
nb_antennas_tx = 1;
nb_antennas_rx = 1;
tx_gain = 48; # [~50 for DEV-FE, ~30 for CBRS-FE]
rx_gain = 80; # [115 for DEV-FE, 90 for CBRS-FE]
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 = 32;
pdsch_referenceSignalPower = -30;
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 = -70;
pusch_alpha = "AL1";
pucch_p0_Nominal = -96;
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 = -96;
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 = "127.0.0.20";
ipv6 = "fe80::d65d:dfff:fe1d:f4d4";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
ENB_INTERFACE_NAME_FOR_S1_MME = "eno1";
ENB_IPV4_ADDRESS_FOR_S1_MME = "127.0.0.10/8";
ENB_INTERFACE_NAME_FOR_S1U = "enp5s0";
ENB_IPV4_ADDRESS_FOR_S1U = "127.0.0.10/8";
ENB_PORT_FOR_S1U = 2152; # Spec 2152
ENB_IPV4_ADDRESS_FOR_X2C = "127.0.0.10/8";
ENB_PORT_FOR_X2C = 36422; # Spec 36422
};
}
);
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 = 44; #apparently this is being used as tx_gain...
att_rx = 0; #apparently max_rxgain - att_rx -83 is what is used for rx_gain (at least for 5 MHz)
bands = [7];
max_pdschReferenceSignalPower = -27;
max_rxgain = 107;
eNB_instances = [0];
#sdr_addrs = "RF3E000025";
}
);
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_RU_L1_TRX_SPLIT";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
log_config :
{
global_log_level ="info";
global_log_verbosity ="medium";
hw_log_level ="info";
hw_log_verbosity ="medium";
phy_log_level ="info";
phy_log_verbosity ="medium";
mac_log_level ="info";
mac_log_verbosity ="high";
rlc_log_level ="info";
rlc_log_verbosity ="medium";
pdcp_log_level ="info";
pdcp_log_verbosity ="medium";
rrc_log_level ="info";
rrc_log_verbosity ="medium";
};
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 = 208; mnc = 92; 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 = 2660000000L;
uplink_frequency_offset = -120000000;
Nid_cell = 10;
N_RB_DL = 25;
Nid_cell_mbsfn = 0;
nb_antenna_ports = 1;
nb_antennas_tx = 1;
nb_antennas_rx = 1;
tx_gain = 52; # [~50 for DEV-FE, ~30 for CBRS-FE]
rx_gain = 115; # [115 for DEV-FE, 90 for CBRS-FE]
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 = 32;
pdsch_referenceSignalPower = -30;
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 = -70;
pusch_alpha = "AL1";
pucch_p0_Nominal = -96;
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 = -96;
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 = "127.0.0.20";
ipv6 = "fe80::d65d:dfff:fe1d:f4d4";
active = "yes";
preference = "ipv4";
}
);
NETWORK_INTERFACES :
{
ENB_INTERFACE_NAME_FOR_S1_MME = "lo";
ENB_IPV4_ADDRESS_FOR_S1_MME = "127.0.0.10/8";
ENB_INTERFACE_NAME_FOR_S1U = "lo";
ENB_IPV4_ADDRESS_FOR_S1U = "127.0.0.10/8";
ENB_PORT_FOR_S1U = 2152; # Spec 2152
ENB_IPV4_ADDRESS_FOR_X2C = "127.0.0.10/8";
ENB_PORT_FOR_X2C = 36422; # Spec 36422
};
}
);
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 = 0
att_rx = 0;
bands = [7];
max_pdschReferenceSignalPower = -27;
max_rxgain = 125;
eNB_instances = [0];
sdr_addrs = "RF3E000028";
}
);
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_RU_L1_TRX_SPLIT";
#two option for worker "WORKER_DISABLE" or "WORKER_ENABLE"
worker_config = "WORKER_ENABLE";
}
);
log_config :
{
global_log_level ="info";
global_log_verbosity ="medium";
hw_log_level ="info";
hw_log_verbosity ="medium";
phy_log_level ="info";
phy_log_verbosity ="medium";
mac_log_level ="info";
mac_log_verbosity ="high";
rlc_log_level ="info";
rlc_log_verbosity ="medium";
pdcp_log_level ="info";
pdcp_log_verbosity ="medium";
rrc_log_level ="info";
rrc_log_verbosity ="medium";
};
...@@ -761,9 +761,9 @@ void rx_rf(RU_t *ru,int *frame,int *subframe) { ...@@ -761,9 +761,9 @@ void rx_rf(RU_t *ru,int *frame,int *subframe) {
proc->timestamp_rx = ts-ru->ts_offset; proc->timestamp_rx = ts-ru->ts_offset;
// AssertFatal(rxs == fp->samples_per_tti, // AssertFatal(rxs == fp->samples_per_tti,
// "rx_rf: Asked for %d samples, got %d from USRP\n",fp->samples_per_tti,rxs); // "rx_rf: Asked for %d samples, got %d from SDR\n",fp->samples_per_tti,rxs);
if(rxs != fp->samples_per_tti){ if(rxs != fp->samples_per_tti){
LOG_E(PHY,"rx_rf: Asked for %d samples, got %d from USRP\n",fp->samples_per_tti,rxs); LOG_E(PHY,"rx_rf: Asked for %d samples, got %d from SDR\n",fp->samples_per_tti,rxs);
late_control=STATE_BURST_TERMINATE; late_control=STATE_BURST_TERMINATE;
} }
......
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