lte-softmodem.c 116 KB
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/*******************************************************************************
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    OpenAirInterface 
    Copyright(c) 1999 - 2014 Eurecom
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    OpenAirInterface is free software: you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.
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    OpenAirInterface 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 General Public License for more details.
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    You should have received a copy of the GNU General Public License
    along with OpenAirInterface.The full GNU General Public License is 
    included in this distribution in the file called "COPYING". If not, 
    see <http://www.gnu.org/licenses/>.
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   Contact Information
   OpenAirInterface Admin: openair_admin@eurecom.fr
   OpenAirInterface Tech : openair_tech@eurecom.fr
   OpenAirInterface Dev  : openair4g-devel@eurecom.fr
  
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   Address      : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
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*******************************************************************************/
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/*! \file lte-softmodem.c
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 * \brief main program to control HW and scheduling
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 * \author R. Knopp, F. Kaltenberger, Navid Nikaein
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 * \date 2012
 * \version 0.1
 * \company Eurecom
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 * \email: knopp@eurecom.fr,florian.kaltenberger@eurecom.fr, navid.nikaein@eurecom.fr
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 * \note
 * \warning
 */
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#define _GNU_SOURCE
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#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include <sys/ioctl.h>
#include <sys/types.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <sched.h>
#include <signal.h>
#include <execinfo.h>
#include <getopt.h>

#include "rt_wrapper.h"
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#undef MALLOC //there are two conflicting definitions, so we better make sure we don't use it at all

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#ifdef USRP
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static int hw_subframe;
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#endif
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#include "assertions.h"
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#ifdef EMOS
#include <gps.h>
#endif

#include "PHY/types.h"
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#include "PHY/defs.h"
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#undef MALLOC //there are two conflicting definitions, so we better make sure we don't use it at all
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//#undef FRAME_LENGTH_COMPLEX_SAMPLES //there are two conflicting definitions, so we better make sure we don't use it at all
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#ifndef USRP
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#include "openair0_lib.h"
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#else
#include "../../ARCH/COMMON/common_lib.h"
#endif

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//#undef FRAME_LENGTH_COMPLEX_SAMPLES //there are two conflicting definitions, so we better make sure we don't use it at all
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#include "PHY/vars.h"
#include "MAC_INTERFACE/vars.h"
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//#include "SCHED/defs.h"
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#include "SCHED/vars.h"
#include "LAYER2/MAC/vars.h"

#include "../../SIMU/USER/init_lte.h"

#ifdef EMOS
#include "SCHED/phy_procedures_emos.h"
#endif

#ifdef OPENAIR2
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#include "otg_tx.h"
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#include "LAYER2/MAC/defs.h"
#include "LAYER2/MAC/vars.h"
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#include "LAYER2/MAC/proto.h"
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#ifndef CELLULAR
#include "RRC/LITE/vars.h"
#endif
#include "PHY_INTERFACE/vars.h"
#endif

#ifdef SMBV
#include "PHY/TOOLS/smbv.h"
unsigned short config_frames[4] = {2,9,11,13};
#endif
#include "UTIL/LOG/log_extern.h"
#include "UTIL/OTG/otg.h"
#include "UTIL/OTG/otg_vars.h"
#include "UTIL/MATH/oml.h"
#include "UTIL/LOG/vcd_signal_dumper.h"
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#include "enb_config.h"
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#if defined(ENABLE_ITTI)
# include "intertask_interface_init.h"
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# include "create_tasks.h"
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# if defined(ENABLE_USE_MME)
#   include "s1ap_eNB.h"
# endif
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#endif

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#ifdef XFORMS
#include "PHY/TOOLS/lte_phy_scope.h"
#include "stats.h"
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#endif

#define FRAME_PERIOD    100000000ULL
#define DAQ_PERIOD      66667ULL

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#define DEBUG_THREADS 1

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//#define USRP_DEBUG 1

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struct timing_info_t {
  //unsigned int frame, hw_slot, last_slot, next_slot;
  RTIME time_min, time_max, time_avg, time_last, time_now;
  //unsigned int mbox0, mbox1, mbox2, mbox_target;
  unsigned int n_samples;
} timing_info;

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extern int16_t* sync_corr_ue0;
extern int16_t prach_ifft[4][1024*2];
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int init_dlsch_threads(void);
void cleanup_dlsch_threads(void);
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int32_t init_rx_pdsch_thread(void);
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void cleanup_rx_pdsch_thread(void);
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openair0_config_t openair0_cfg[MAX_CARDS];
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int32_t *rxdata;
int32_t *txdata;
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int setup_ue_buffers(PHY_VARS_UE **phy_vars_ue, openair0_config_t *openair0_cfg, openair0_rf_map rf_map[MAX_NUM_CCs]);
int setup_eNB_buffers(PHY_VARS_eNB **phy_vars_eNB, openair0_config_t *openair0_cfg, openair0_rf_map rf_map[MAX_NUM_CCs]);
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#ifdef XFORMS
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// current status is that every UE has a DL scope for a SINGLE eNB (eNB_id=0)
// at eNB 0, an UL scope for every UE 
FD_lte_phy_scope_ue  *form_ue[NUMBER_OF_UE_MAX];
FD_lte_phy_scope_enb *form_enb[NUMBER_OF_UE_MAX];
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FD_stats_form                  *form_stats=NULL,*form_stats_l2=NULL;
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char title[255];
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unsigned char                   scope_enb_num_ue = 1;
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#endif //XFORMS

#ifdef RTAI
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static SEM                     *mutex;
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//static CND *cond;

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static long                      main_eNB_thread;
static long                      main_ue_thread;
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#ifdef USRP
static SEM *sync_sem; // to sync rx & tx streaming
#endif
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//static int sync_thread;
#else
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pthread_t                       main_eNB_thread;
pthread_t                       main_ue_thread;
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pthread_attr_t                  attr_dlsch_threads;
struct sched_param              sched_param_dlsch;
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#ifdef USRP
pthread_cond_t sync_cond;
pthread_mutex_t sync_mutex;
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#endif
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#endif
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RTIME T0;
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pthread_attr_t                  attr_UE_init_synch;
pthread_attr_t                  attr_UE_thread_tx;
pthread_attr_t                  attr_UE_thread_rx;
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pthread_attr_t                  attr_eNB_proc_tx[MAX_NUM_CCs][10];
pthread_attr_t                  attr_eNB_proc_rx[MAX_NUM_CCs][10];
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struct sched_param              sched_param_UE_init_synch;
struct sched_param              sched_param_UE_thread_tx;
struct sched_param              sched_param_UE_thread_rx;
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struct sched_param              sched_param_eNB_proc_tx[MAX_NUM_CCs][10];
struct sched_param              sched_param_eNB_proc_rx[MAX_NUM_CCs][10];
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#ifdef XFORMS
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static pthread_t                forms_thread; //xforms
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#endif
#ifdef EMOS
static pthread_t                thread3; //emos
#endif
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#ifdef SPECTRA
static pthread_t sensing_thread;
#endif

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openair0_device openair0;
openair0_timestamp timestamp;

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/*
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  static int instance_cnt=-1; //0 means worker is busy, -1 means its free
  int instance_cnt_ptr_kern,*instance_cnt_ptr_user;
  int pci_interface_ptr_kern;
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*/
//extern unsigned int bigphys_top;
//extern unsigned int mem_base;

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int                             card = 0;
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#if defined(ENABLE_ITTI)
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static volatile int             start_eNB = 0;
static volatile int             start_UE = 0;
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#endif
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volatile int                    oai_exit = 0;

//static int                      time_offset[4] = {-138,-138,-138,-138};
//static int                      time_offset[4] = {-145,-145,-145,-145};
static int                      time_offset[4] = {0,0,0,0};

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static char                     UE_flag=0;
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static uint8_t                  eNB_id=0,UE_id=0;
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//uint32_t                        carrier_freq[MAX_NUM_CCs][4] =           {{1907600000,1907600000,1907600000,1907600000}}; /* For UE! */
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static uint32_t                 downlink_frequency[MAX_NUM_CCs][4] =     {{1907600000,1907600000,1907600000,1907600000},
									  {1907600000,1907600000,1907600000,1907600000}};
static int32_t                  uplink_frequency_offset[MAX_NUM_CCs][4]= {{0,0,0,0},{0,0,0,0}};
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openair0_rf_map rf_map[MAX_NUM_CCs];
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static char                    *conf_config_file_name = NULL;
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#if defined(ENABLE_ITTI)
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static char                    *itti_dump_file = NULL;
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#endif

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#ifndef USRP
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double tx_gain[MAX_NUM_CCs][4] = {{20,20,0,0},{20,20,0,0}};
double rx_gain[MAX_NUM_CCs][4] = {{20,20,0,0},{20,20,0,0}};
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// these are for EXMIMO2 target only
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/*
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static unsigned int             rxg_max[4] =    {133,133,133,133};
static unsigned int             rxg_med[4] =    {127,127,127,127};
static unsigned int             rxg_byp[4] =    {120,120,120,120};
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*/
// these are for EXMIMO2 card 39
static unsigned int             rxg_max[4] =    {128,128,128,126};
static unsigned int             rxg_med[4] =    {122,123,123,120};
static unsigned int             rxg_byp[4] =    {116,117,116,116};
static unsigned int             nf_max[4] =    {7,9,16,12};
static unsigned int             nf_med[4] =    {12,13,22,17};
static unsigned int             nf_byp[4] =    {15,20,29,23};
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static rx_gain_t                rx_gain_mode[MAX_NUM_CCs][4] = {{max_gain,max_gain,max_gain,max_gain},{max_gain,max_gain,max_gain,max_gain}};
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#else
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double tx_gain[MAX_NUM_CCs][4] = {{120,0,0,0}};
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double rx_gain[MAX_NUM_CCs][4] = {{125,0,0,0}};
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#endif
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double sample_rate=30.72e6;
double bw = 14e6;
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static int                      tx_max_power[MAX_NUM_CCs] =  {0,0};
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#ifdef USRP
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char ref[128] = "internal";
char channels[128] = "0";

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unsigned int samples_per_frame = 307200;
unsigned int samples_per_packets = 2048; // samples got every recv or send
unsigned int tx_forward_nsamps;
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int sf_bounds_5[10]    = {8, 15, 23, 30, 38, 45, 53, 60, 68, 75};
int sf_bounds_5_tx[10] = {4, 11, 19, 26, 34, 41, 49, 56, 64, 71};

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int sf_bounds_10[10] = {8, 15, 23, 30, 38, 45, 53, 60, 68, 75};
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int sf_bounds_10_tx[10] = {4, 11, 19, 26, 34, 41, 49, 56, 64, 71};

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int sf_bounds_20[10] = {15, 30, 45, 60, 75, 90, 105, 120, 135, 150};
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int sf_bounds_20_tx[10] = {7, 22, 37, 52, 67, 82, 97, 112, 127, 142};

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int *sf_bounds;
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int *sf_bounds_tx;

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int max_cnt;
int tx_delay;

#endif
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/*
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  uint32_t rf_mode_max[4]     = {55759,55759,55759,55759};
  uint32_t rf_mode_med[4]     = {39375,39375,39375,39375};
  uint32_t rf_mode_byp[4]     = {22991,22991,22991,22991};
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*/
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//static uint32_t                      rf_mode[4] =        {MY_RF_MODE,0,0,0};
//static uint32_t                      rf_local[4] =       {8255000,8255000,8255000,8255000}; // UE zepto
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//{8254617, 8254617, 8254617, 8254617}; //eNB khalifa
//{8255067,8254810,8257340,8257340}; // eNB PETRONAS
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//static uint32_t                      rf_vcocal[4] =      {910,910,910,910};
//static uint32_t                      rf_vcocal_850[4] =  {2015, 2015, 2015, 2015};
//static uint32_t                      rf_rxdc[4] =        {32896,32896,32896,32896};
//static uint32_t                      rxgain[4] =         {20,20,20,20};
//static uint32_t                      txgain[4] =         {20,20,20,20};
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static runmode_t                mode;
static int                      rx_input_level_dBm;
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static int                      online_log_messages=0;
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#ifdef XFORMS
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extern int                      otg_enabled;
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static char                     do_forms=0;
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#else
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int                             otg_enabled;
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#endif
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//int                             number_of_cards =   1;
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#ifndef USRP
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static int                      mbox_bounds[20] =   {8,16,24,30,38,46,54,60,68,76,84,90,98,106,114,120,128,136,144, 0}; ///boundaries of slots in terms ob mbox counter rounded up to even numbers
//static int                      mbox_bounds[20] =   {6,14,22,28,36,44,52,58,66,74,82,88,96,104,112,118,126,134,142, 148}; ///boundaries of slots in terms ob mbox counter rounded up to even numbers
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#endif
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static LTE_DL_FRAME_PARMS      *frame_parms[MAX_NUM_CCs];
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int multi_thread=1;
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uint32_t target_dl_mcs = 28; //maximum allowed mcs
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uint32_t target_ul_mcs = 10;
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int16_t           glog_level=LOG_DEBUG;
int16_t           glog_verbosity=LOG_MED;
int16_t           hw_log_level=LOG_DEBUG;
int16_t           hw_log_verbosity=LOG_MED;
int16_t           phy_log_level=LOG_DEBUG;
int16_t           phy_log_verbosity=LOG_MED;
int16_t           mac_log_level=LOG_DEBUG;
int16_t           mac_log_verbosity=LOG_MED;
int16_t           rlc_log_level=LOG_DEBUG;
int16_t           rlc_log_verbosity=LOG_MED;
int16_t           pdcp_log_level=LOG_DEBUG;
int16_t           pdcp_log_verbosity=LOG_MED;
int16_t           rrc_log_level=LOG_DEBUG;
int16_t           rrc_log_verbosity=LOG_MED;

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unsigned int build_rflocal(int txi, int txq, int rxi, int rxq)
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{
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  return (txi + (txq<<6) + (rxi<<12) + (rxq<<18));
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}
unsigned int build_rfdc(int dcoff_i_rxfe, int dcoff_q_rxfe)
{
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  return (dcoff_i_rxfe + (dcoff_q_rxfe<<8));
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}

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#if !defined(ENABLE_ITTI)
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void signal_handler(int sig)
{
  void *array[10];
  size_t size;

  if (sig==SIGSEGV) {
    // get void*'s for all entries on the stack
    size = backtrace(array, 10);
    
    // print out all the frames to stderr
    fprintf(stderr, "Error: signal %d:\n", sig);
    backtrace_symbols_fd(array, size, 2);
    exit(-1);
  }
  else {
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    printf("trying to exit gracefully...\n"); 
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    oai_exit = 1;
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  }
}
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#endif
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void exit_fun(const char* s)
{
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  if (s != NULL) {
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    printf("%s %s() Exiting: %s\n",__FILE__, __FUNCTION__, s);
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  }

  oai_exit = 1;

#if defined(ENABLE_ITTI)
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  itti_terminate_tasks (TASK_UNKNOWN);
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#endif
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  //rt_sleep_ns(FRAME_PERIOD);

  //exit (-1);
}

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static int latency_target_fd = -1;
static int32_t latency_target_value = 0;
/* Latency trick - taken from cyclictest.c 
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 * if the file /dev/cpu_dma_latency exists,
 * open it and write a zero into it. This will tell
 * the power management system not to transition to
 * a high cstate (in fact, the system acts like idle=poll)
 * When the fd to /dev/cpu_dma_latency is closed, the behavior
 * goes back to the system default.
 *
 * Documentation/power/pm_qos_interface.txt
 */
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static void set_latency_target(void)
{
  struct stat s;
  int ret;
  if (stat("/dev/cpu_dma_latency", &s) == 0) {
    latency_target_fd = open("/dev/cpu_dma_latency", O_RDWR);
    if (latency_target_fd == -1)
      return;
    ret = write(latency_target_fd, &latency_target_value, 4);
    if (ret == 0) {
      printf("# error setting cpu_dma_latency to %d!: %s\n", latency_target_value, strerror(errno));
      close(latency_target_fd);
      return;
    }
    printf("# /dev/cpu_dma_latency set to %dus\n", latency_target_value);
  }
}
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#ifdef XFORMS
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void reset_stats(FL_OBJECT *button, long arg) {
  int i,j,k;
  PHY_VARS_eNB *phy_vars_eNB = PHY_vars_eNB_g[0][0];
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  for (i=0;i<NUMBER_OF_UE_MAX;i++) {
    for (k=0;k<8;k++) {//harq_processes
      for (j=0;j<phy_vars_eNB->dlsch_eNB[i][0]->Mdlharq;j++) {
	phy_vars_eNB->eNB_UE_stats[i].dlsch_NAK[k][j]=0;
	phy_vars_eNB->eNB_UE_stats[i].dlsch_ACK[k][j]=0;
	phy_vars_eNB->eNB_UE_stats[i].dlsch_trials[k][j]=0;
      }
      phy_vars_eNB->eNB_UE_stats[i].dlsch_l2_errors[k]=0;
      phy_vars_eNB->eNB_UE_stats[i].ulsch_errors[k]=0;
      phy_vars_eNB->eNB_UE_stats[i].ulsch_consecutive_errors=0;
      for (j=0;j<phy_vars_eNB->ulsch_eNB[i]->Mdlharq;j++) {
	phy_vars_eNB->eNB_UE_stats[i].ulsch_decoding_attempts[k][j]=0;
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      phy_vars_eNB->eNB_UE_stats[i].ulsch_decoding_attempts_last[k][j]=0;
      phy_vars_eNB->eNB_UE_stats[i].ulsch_round_errors[k][j]=0;
      phy_vars_eNB->eNB_UE_stats[i].ulsch_round_fer[k][j]=0;
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      }
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    }
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    phy_vars_eNB->eNB_UE_stats[i].dlsch_sliding_cnt=0;
    phy_vars_eNB->eNB_UE_stats[i].dlsch_NAK_round0=0;
    phy_vars_eNB->eNB_UE_stats[i].dlsch_mcs_offset=0;
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  }
}

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static void *scope_thread(void *arg) {
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  char stats_buffer[16384];
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# ifdef ENABLE_XFORMS_WRITE_STATS
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  FILE *UE_stats, *eNB_stats;
  int len = 0;
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# endif
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  struct sched_param sched_param;
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  sched_param.sched_priority = sched_get_priority_min(SCHED_FIFO)+1; 
  sched_setscheduler(0, SCHED_FIFO,&sched_param);
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  printf("Scope thread has priority %d\n",sched_param.sched_priority);
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# ifdef ENABLE_XFORMS_WRITE_STATS
  if (UE_flag==1) 
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    UE_stats  = fopen("UE_stats.txt", "w");
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  else 
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    eNB_stats = fopen("eNB_stats.txt", "w");
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#endif
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  while (!oai_exit) {
    if (UE_flag==1) {
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# ifdef ENABLE_XFORMS_WRITE_STATS
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      len =
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# endif
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	dump_ue_stats (PHY_vars_UE_g[0][0], stats_buffer, 0, mode,rx_input_level_dBm);
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      fl_set_object_label(form_stats->stats_text, stats_buffer);
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      phy_scope_UE(form_ue[UE_id], 
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		   PHY_vars_UE_g[UE_id][0],
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		   eNB_id,
		   UE_id,7);
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    } else {
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# ifdef ENABLE_XFORMS_WRITE_STATS
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      len =
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# endif
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      dump_eNB_l2_stats (stats_buffer, 0);
      fl_set_object_label(form_stats_l2->stats_text, stats_buffer);
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# ifdef ENABLE_XFORMS_WRITE_STATS
      len =
# endif
	dump_eNB_stats (PHY_vars_eNB_g[0][0], stats_buffer, 0);
      fl_set_object_label(form_stats->stats_text, stats_buffer);

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      for(UE_id=0;UE_id<scope_enb_num_ue;UE_id++) {
	phy_scope_eNB(form_enb[UE_id], 
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		      PHY_vars_eNB_g[eNB_id][0],
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		      UE_id);
      }
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    }
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    //printf("doing forms\n");
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    //usleep(100000); // 100 ms
    sleep(1);
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  }
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  printf("%s",stats_buffer);
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# ifdef ENABLE_XFORMS_WRITE_STATS
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  if (UE_flag==1) {
    if (UE_stats) {
      rewind (UE_stats);
      fwrite (stats_buffer, 1, len, UE_stats);
      fclose (UE_stats);
    }
  }
  else {
    if (eNB_stats) {
      rewind (eNB_stats);
      fwrite (stats_buffer, 1, len, eNB_stats);
      fclose (eNB_stats);
    }
  }
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# endif
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  pthread_exit((void*)arg);
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}
#endif

#ifdef EMOS
#define NO_ESTIMATES_DISK 100 //No. of estimates that are aquired before dumped to disk

void *emos_thread (void *arg)
{
  char c;
  char *fifo2file_buffer, *fifo2file_ptr;

  int fifo, counter=0, bytes;

  FILE  *dumpfile_id;
  char  dumpfile_name[1024];
  time_t starttime_tmp;
  struct tm starttime;
  
  int channel_buffer_size;
  
  time_t timer;
  struct tm *now;

  struct gps_data_t *gps_data = NULL;
  struct gps_fix_t dummy_gps_data;
567 568 569 570 571 572 573

  struct sched_param sched_param;
  
  sched_param.sched_priority = sched_get_priority_max(SCHED_FIFO)-1; 
  sched_setscheduler(0, SCHED_FIFO,&sched_param);
  
  printf("EMOS thread has priority %d\n",sched_param.sched_priority);
574 575 576 577 578 579 580 581 582 583 584 585 586 587 588 589 590 591 592 593 594 595
 
  timer = time(NULL);
  now = localtime(&timer);

  memset(&dummy_gps_data,1,sizeof(struct gps_fix_t));
  
  gps_data = gps_open("127.0.0.1","2947");
  if (gps_data == NULL) 
    {
      printf("[EMOS] Could not open GPS\n");
      //exit(-1);
    }
#if GPSD_API_MAJOR_VERSION>=4
  else if (gps_stream(gps_data, WATCH_ENABLE,NULL) != 0)
#else
  else if (gps_query(gps_data, "w+x") != 0)
#endif
    {
      //sprintf(tmptxt,"Error sending command to GPS, gps_data = %x", gps_data);
      printf("[EMOS] Error sending command to GPS\n");
      //exit(-1);
    }
596 597
  else 
    printf("[EMOS] Opened GPS, gps_data=%p\n");
598 599 600 601 602 603 604 605 606 607 608 609 610 611 612 613 614 615 616 617 618 619 620 621 622 623 624 625 626 627 628 629 630 631 632 633 634 635 636 637 638 639 640 641 642
  
  if (UE_flag==0)
    channel_buffer_size = sizeof(fifo_dump_emos_eNB);
  else
    channel_buffer_size = sizeof(fifo_dump_emos_UE);

  // allocate memory for NO_FRAMES_DISK channes estimations
  fifo2file_buffer = malloc(NO_ESTIMATES_DISK*channel_buffer_size);
  fifo2file_ptr = fifo2file_buffer;

  if (fifo2file_buffer == NULL)
    {
      printf("[EMOS] Cound not allocate memory for fifo2file_buffer\n");
      exit(EXIT_FAILURE);
    }

  if ((fifo = open(CHANSOUNDER_FIFO_DEV, O_RDONLY)) < 0)
    {
      fprintf(stderr, "[EMOS] Error opening the fifo\n");
      exit(EXIT_FAILURE);
    }


  time(&starttime_tmp);
  localtime_r(&starttime_tmp,&starttime);
  snprintf(dumpfile_name,1024,"/tmp/%s_data_%d%02d%02d_%02d%02d%02d.EMOS",
	   (UE_flag==0) ? "eNB" : "UE",
	   1900+starttime.tm_year, starttime.tm_mon+1, starttime.tm_mday, starttime.tm_hour, starttime.tm_min, starttime.tm_sec);

  dumpfile_id = fopen(dumpfile_name,"w");
  if (dumpfile_id == NULL)
    {
      fprintf(stderr, "[EMOS] Error opening dumpfile %s\n",dumpfile_name);
      exit(EXIT_FAILURE);
    }


  printf("[EMOS] starting dump, channel_buffer_size=%d ...\n",channel_buffer_size);
  while (!oai_exit)
    {
      bytes = rtf_read_timed(fifo, fifo2file_ptr, channel_buffer_size,100);
      if (bytes==0)
	continue;

      /*
643
	if (UE_flag==0)
644
	printf("eNB: count %d, frame %d, read: %d bytes from the fifo\n",counter, ((fifo_dump_emos_eNB*)fifo2file_ptr)->frame_tx,bytes);
645
	else
646 647 648 649 650 651 652 653 654 655 656 657 658 659 660 661 662 663 664 665 666 667 668 669 670 671 672 673 674 675 676 677 678 679 680 681 682 683 684 685 686 687 688 689 690 691 692 693 694 695 696 697 698 699 700 701 702 703 704 705 706
	printf("UE: count %d, frame %d, read: %d bytes from the fifo\n",counter, ((fifo_dump_emos_UE*)fifo2file_ptr)->frame_rx,bytes);
      */

      fifo2file_ptr += channel_buffer_size;
      counter ++;

      if (counter == NO_ESTIMATES_DISK)
        {
          //reset stuff
          fifo2file_ptr = fifo2file_buffer;
          counter = 0;

          //flush buffer to disk
	  if (UE_flag==0)
	    printf("[EMOS] eNB: count %d, frame %d, flushing buffer to disk\n",
		   counter, ((fifo_dump_emos_eNB*)fifo2file_ptr)->frame_tx);
	  else
	    printf("[EMOS] UE: count %d, frame %d, flushing buffer to disk\n",
		   counter, ((fifo_dump_emos_UE*)fifo2file_ptr)->frame_rx);


          if (fwrite(fifo2file_buffer, sizeof(char), NO_ESTIMATES_DISK*channel_buffer_size, dumpfile_id) != NO_ESTIMATES_DISK*channel_buffer_size)
            {
              fprintf(stderr, "[EMOS] Error writing to dumpfile\n");
              exit(EXIT_FAILURE);
            }
	  if (gps_data)
	    {
	      if (gps_poll(gps_data) != 0) {
		printf("[EMOS] problem polling data from gps\n");
	      }
	      else {
		printf("[EMOS] lat %g, lon %g\n",gps_data->fix.latitude,gps_data->fix.longitude);
	      }
	      if (fwrite(&(gps_data->fix), sizeof(char), sizeof(struct gps_fix_t), dumpfile_id) != sizeof(struct gps_fix_t))
		{
		  printf("[EMOS] Error writing to dumpfile, stopping recording\n");
		  exit(EXIT_FAILURE);
		}
	    }
	  else
	    {
	      printf("[EMOS] WARNING: No GPS data available, storing dummy packet\n");
	      if (fwrite(&(dummy_gps_data), sizeof(char), sizeof(struct gps_fix_t), dumpfile_id) != sizeof(struct gps_fix_t))
		{
		  printf("[EMOS] Error writing to dumpfile, stopping recording\n");
		  exit(EXIT_FAILURE);
		}
	    } 
        }
    }
  
  free(fifo2file_buffer);
  fclose(dumpfile_id);
  close(fifo);
  
  pthread_exit((void*) arg);

}
#endif

707 708 709 710 711 712 713 714 715 716 717 718 719
#ifdef SPECTRA
void *sensing (void *arg)
{
  struct sched_param sched_param;
  
  sched_param.sched_priority = sched_get_priority_max(SCHED_FIFO)-1; 
  sched_setscheduler(0, SCHED_FIFO,&sched_param);
  
  printf("[SPECTRA] sensing thread started with priority %d\n",sched_param.sched_priority);
 
  while (oai_exit==0) {

    
720 721 722
    openair0_cfg[0].rx_freq[2]+= 5e6;
    if (openair0_cfg[0].rx_freq[2] >= 750000000)
      openair0_cfg[0].rx_freq[2] = 727500000;
723 724
    

725
    //LOG_I(HW,"[SPECTRA] changing frequency to %u \n",(uint32_t)openair0_cfg[1].rx_freq[0]);
726 727 728

    openair0_reconfig(&openair0_cfg[0]);

729
    usleep(200000);
730 731 732 733 734 735 736 737 738 739
    //sleep(1);
    
  }

  pthread_exit((void*) arg);

}
#endif


740
#if defined(ENABLE_ITTI)
741 742 743 744 745 746 747 748 749 750 751 752 753 754 755 756 757 758
static void wait_system_ready (char *message, volatile int *start_flag)
{
  /* Wait for eNB application initialization to be complete (eNB registration to MME) */
  {
    static char *indicator[] = {".    ", "..   ", "...  ", ".... ", ".....",
                                " ....", "  ...", "   ..", "    .", "     "};
    int i = 0;

    while ((!oai_exit) && (*start_flag == 0)) {
      LOG_N(EMU, message, indicator[i]);
      i = (i + 1) % (sizeof(indicator) / sizeof(indicator[0]));
      usleep(200000);
    }
    LOG_D(EMU,"\n");
  }
}
#endif

759
#if defined(ENABLE_ITTI)
760
void *l2l1_task(void *arg)
761
{
762 763 764 765 766
  MessageDef *message_p = NULL;
  int         result;

  itti_set_task_real_time(TASK_L2L1);
  itti_mark_task_ready(TASK_L2L1);
767

768 769
  if (UE_flag == 0) {
    /* Wait for the initialize message */
770
    do {
771 772 773 774
      if (message_p != NULL) {
	result = itti_free (ITTI_MSG_ORIGIN_ID(message_p), message_p);
	AssertFatal (result == EXIT_SUCCESS, "Failed to free memory (%d)!\n", result);
      }
775 776 777
      itti_receive_msg (TASK_L2L1, &message_p);

      switch (ITTI_MSG_ID(message_p)) {
778 779 780 781 782 783 784 785 786 787 788 789 790 791
      case INITIALIZE_MESSAGE:
	/* Start eNB thread */
	LOG_D(EMU, "L2L1 TASK received %s\n", ITTI_MSG_NAME(message_p));
	start_eNB = 1;
	break;

      case TERMINATE_MESSAGE:
	oai_exit=1;
	itti_exit_task ();
	break;

      default:
	LOG_E(EMU, "Received unexpected message %s\n", ITTI_MSG_NAME(message_p));
	break;
792
      }
793 794 795 796 797 798 799 800 801 802 803 804 805 806 807 808 809 810 811 812 813 814
    } while (ITTI_MSG_ID(message_p) != INITIALIZE_MESSAGE);
    result = itti_free (ITTI_MSG_ORIGIN_ID(message_p), message_p);
    AssertFatal (result == EXIT_SUCCESS, "Failed to free memory (%d)!\n", result);
  }

  do {
    // Wait for a message
    itti_receive_msg (TASK_L2L1, &message_p);

    switch (ITTI_MSG_ID(message_p)) {
    case TERMINATE_MESSAGE:
      oai_exit=1;
      itti_exit_task ();
      break;

    case ACTIVATE_MESSAGE:
      start_UE = 1;
      break;

    case DEACTIVATE_MESSAGE:
      start_UE = 0;
      break;
815

816 817 818 819 820 821 822 823 824 825 826 827
    case MESSAGE_TEST:
      LOG_I(EMU, "Received %s\n", ITTI_MSG_NAME(message_p));
      break;

    default:
      LOG_E(EMU, "Received unexpected message %s\n", ITTI_MSG_NAME(message_p));
      break;
    }

    result = itti_free (ITTI_MSG_ORIGIN_ID(message_p), message_p);
    AssertFatal (result == EXIT_SUCCESS, "Failed to free memory (%d)!\n", result);
  } while(1);
828

829
  return NULL;
830 831 832
}
#endif

833

834
void do_OFDM_mod_rt(int subframe,PHY_VARS_eNB *phy_vars_eNB) {
835 836 837 838

  unsigned int aa,slot_offset, slot_offset_F;
  int dummy_tx_b[7680*4] __attribute__((aligned(16)));
  int i, tx_offset;
839
  int slot_sizeF = (phy_vars_eNB->lte_frame_parms.ofdm_symbol_size)*
840
    ((phy_vars_eNB->lte_frame_parms.Ncp==1) ? 6 : 7);
841 842 843

  slot_offset_F = (subframe<<1)*slot_sizeF;
    
844 845
  slot_offset = subframe*phy_vars_eNB->lte_frame_parms.samples_per_tti;

846 847
  if ((subframe_select(&phy_vars_eNB->lte_frame_parms,subframe)==SF_DL)||
      ((subframe_select(&phy_vars_eNB->lte_frame_parms,subframe)==SF_S))) {
848
    //	  LOG_D(HW,"Frame %d: Generating slot %d\n",frame,next_slot);
849

850
    
851 852 853 854 855 856 857 858 859 860
    for (aa=0; aa<phy_vars_eNB->lte_frame_parms.nb_antennas_tx; aa++) {
      if (phy_vars_eNB->lte_frame_parms.Ncp == EXTENDED){ 
	PHY_ofdm_mod(&phy_vars_eNB->lte_eNB_common_vars.txdataF[0][aa][slot_offset_F],
		     dummy_tx_b,
		     phy_vars_eNB->lte_frame_parms.log2_symbol_size,
		     6,
		     phy_vars_eNB->lte_frame_parms.nb_prefix_samples,
		     phy_vars_eNB->lte_frame_parms.twiddle_ifft,
		     phy_vars_eNB->lte_frame_parms.rev,
		     CYCLIC_PREFIX);
861 862 863 864 865 866 867 868
	PHY_ofdm_mod(&phy_vars_eNB->lte_eNB_common_vars.txdataF[0][aa][slot_offset_F+slot_sizeF],
		     dummy_tx_b+(phy_vars_eNB->lte_frame_parms.samples_per_tti>>1),
		     phy_vars_eNB->lte_frame_parms.log2_symbol_size,
		     6,
		     phy_vars_eNB->lte_frame_parms.nb_prefix_samples,
		     phy_vars_eNB->lte_frame_parms.twiddle_ifft,
		     phy_vars_eNB->lte_frame_parms.rev,
		     CYCLIC_PREFIX);
869 870 871 872 873 874
      }
      else {
	normal_prefix_mod(&phy_vars_eNB->lte_eNB_common_vars.txdataF[0][aa][slot_offset_F],
			  dummy_tx_b,
			  7,
			  &(phy_vars_eNB->lte_frame_parms));
875 876 877 878
	normal_prefix_mod(&phy_vars_eNB->lte_eNB_common_vars.txdataF[0][aa][slot_offset_F+slot_sizeF],
			  dummy_tx_b+(phy_vars_eNB->lte_frame_parms.samples_per_tti>>1),
			  7,
			  &(phy_vars_eNB->lte_frame_parms));
879
      }
880 881

      for (i=0; i<phy_vars_eNB->lte_frame_parms.samples_per_tti; i++) {
882 883 884 885 886 887 888 889 890 891 892 893 894 895 896 897 898
	tx_offset = (int)slot_offset+time_offset[aa]+i;
	if (tx_offset<0)
	  tx_offset += LTE_NUMBER_OF_SUBFRAMES_PER_FRAME*phy_vars_eNB->lte_frame_parms.samples_per_tti;
	if (tx_offset>=(LTE_NUMBER_OF_SUBFRAMES_PER_FRAME*phy_vars_eNB->lte_frame_parms.samples_per_tti))
	  tx_offset -= LTE_NUMBER_OF_SUBFRAMES_PER_FRAME*phy_vars_eNB->lte_frame_parms.samples_per_tti;
	((short*)&phy_vars_eNB->lte_eNB_common_vars.txdata[0][aa][tx_offset])[0]=
	  ((short*)dummy_tx_b)[2*i]<<4;
	((short*)&phy_vars_eNB->lte_eNB_common_vars.txdata[0][aa][tx_offset])[1]=
	  ((short*)dummy_tx_b)[2*i+1]<<4;
      }
    }
  }
}


int eNB_thread_tx_status[10];
static void * eNB_thread_tx(void *param) {
899 900 901

  //unsigned long cpuid;
  eNB_proc_t *proc = (eNB_proc_t*)param;
902
  //  RTIME time_in,time_out;
903 904
#ifdef RTAI
  RT_TASK *task;
905
  char task_name[8];
906
#endif
907 908

 
909

910 911 912 913 914
#if defined(ENABLE_ITTI)
  /* Wait for eNB application initialization to be complete (eNB registration to MME) */
  wait_system_ready ("Waiting for eNB application to be ready %s\r", &start_eNB);
#endif

915
#ifdef RTAI
916
  sprintf(task_name,"TXC%dS%d",proc->CC_id,proc->subframe);
917 918 919
  task = rt_task_init_schmod(nam2num(task_name), 0, 0, 0, SCHED_FIFO, 0xF);

  if (task==NULL) {
920
    LOG_E(PHY,"[SCHED][eNB] Problem starting eNB_proc_TX thread_index %d (%s)!!!!\n",proc->subframe,task_name);
921 922 923
    return 0;
  }
  else {
924 925
    LOG_I(PHY,"[SCHED][eNB] eNB TX thread CC %d SF %d started with id %p\n",
	  proc->CC_id,
926
	  proc->subframe,
927
	  task);
928
  }
929
#else
930
  //  LOG_I(PHY,
931 932
  printf("[SCHED][eNB] eNB TX thread %d started on CPU %d\n",
	 proc->subframe,sched_getcpu());
933 934 935 936 937 938 939 940 941 942 943 944
#endif

  mlockall(MCL_CURRENT | MCL_FUTURE);

  //rt_set_runnable_on_cpuid(task,1);
  //cpuid = rtai_cpuid();

#ifdef HARD_RT
  rt_make_hard_real_time();
#endif

  while (!oai_exit){
945
    
946
    vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_TX0+(2*proc->subframe),0);
947 948
    
    
949 950
    //LOG_I(PHY,"Locking mutex for eNB proc %d (IC %d,mutex %p)\n",proc->subframe,proc->instance_cnt,&proc->mutex);
    //    printf("Locking mutex for eNB proc %d (subframe_tx %d))\n",proc->subframe,proc->subframe_tx);
951

952 953
    if (pthread_mutex_lock(&proc->mutex_tx) != 0) {
      LOG_E(PHY,"[SCHED][eNB] error locking mutex for eNB TX proc %d\n",proc->subframe);
954
      oai_exit=1;
955 956
    }
    else {
957
      
958 959
      while (proc->instance_cnt_tx < 0) {
	//	LOG_I(PHY,"Waiting and unlocking mutex for eNB proc %d (IC %d,lock %d)\n",proc->subframe,proc->instance_cnt,pthread_mutex_trylock(&proc->mutex));
960
	//printf("Waiting and unlocking mutex for eNB proc %d (subframe_tx %d)\n",proc->subframe,subframe_tx);
961
	
962
	pthread_cond_wait(&proc->cond_tx,&proc->mutex_tx);
963
      }
964 965 966
      //      LOG_I(PHY,"Waking up and unlocking mutex for eNB proc %d\n",proc->subframe);
      if (pthread_mutex_unlock(&proc->mutex_tx) != 0) {	
	LOG_E(PHY,"[SCHED][eNB] error unlocking mutex for eNB TX proc %d\n",proc->subframe);
967
	oai_exit=1;
968 969
      }
    }
970
    vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_TX0+(2*proc->subframe),1);    
971
    vcd_signal_dumper_dump_variable_by_name(VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_TX_ENB, proc->frame_tx);
972
    
973
    if (oai_exit) break;
974

975 976 977 978 979 980 981
    
    if ((((PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms.frame_type == TDD)&&
	  (subframe_select(&PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms,proc->subframe_tx)==SF_DL))||
	 (PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms.frame_type == FDD))) {
      
      phy_procedures_eNB_TX(proc->subframe,PHY_vars_eNB_g[0][proc->CC_id],0,no_relay,NULL);
      
982
    }
983 984
    if ((subframe_select(&PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms,proc->subframe_tx)==SF_S)) {
      phy_procedures_eNB_TX(proc->subframe,PHY_vars_eNB_g[0][proc->CC_id],0,no_relay,NULL);
985
    }
986
    
987
    
988
    do_OFDM_mod_rt(proc->subframe_tx,PHY_vars_eNB_g[0][proc->CC_id]);  
989
    
990 991
    if (pthread_mutex_lock(&proc->mutex_tx) != 0) {
      printf("[openair][SCHED][eNB] error locking mutex for eNB TX proc %d\n",proc->subframe);
992
    }
993 994
    else {
      proc->instance_cnt_tx--;
995
      
996 997 998 999
      if (pthread_mutex_unlock(&proc->mutex_tx) != 0) {	
	printf("[openair][SCHED][eNB] error unlocking mutex for eNB TX proc %d\n",proc->subframe);
      }
    }
1000

1001
    
1002 1003 1004
    proc->frame_tx++;
    if (proc->frame_tx==1024)
      proc->frame_tx=0;
1005

1006
  }    
1007 1008 1009 1010
  vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_TX0+(2*proc->subframe),0);        
#ifdef HARD_RT
  rt_make_soft_real_time();
#endif
1011
  
1012 1013 1014 1015 1016 1017 1018 1019 1020 1021
#ifdef DEBUG_THREADS
  printf("Exiting eNB thread TX %d\n",proc->subframe);
#endif
  // clean task
#ifdef RTAI
  rt_task_delete(task);
#else
  eNB_thread_tx_status[proc->subframe]=0;
  pthread_exit(&eNB_thread_tx_status[proc->subframe]);
#endif
1022
  
1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035
#ifdef DEBUG_THREADS
  printf("Exiting eNB TX thread %d\n",proc->subframe);
#endif
}

int eNB_thread_rx_status[10];
static void * eNB_thread_rx(void *param) {

  //unsigned long cpuid;
  eNB_proc_t *proc = (eNB_proc_t*)param;
  //  RTIME time_in,time_out;
#ifdef RTAI
  RT_TASK *task;
1036
  char task_name[8];
1037 1038 1039 1040 1041 1042 1043 1044
#endif

#if defined(ENABLE_ITTI)
  /* Wait for eNB application initialization to be complete (eNB registration to MME) */
  wait_system_ready ("Waiting for eNB application to be ready %s\r", &start_eNB);
#endif

#ifdef RTAI
1045
  sprintf(task_name,"RXC%1dS%1d",proc->CC_id,proc->subframe);
1046 1047 1048 1049 1050 1051 1052
  task = rt_task_init_schmod(nam2num(task_name), 0, 0, 0, SCHED_FIFO, 0xF);

  if (task==NULL) {
    LOG_E(PHY,"[SCHED][eNB] Problem starting eNB_proc_RX thread_index %d (%s)!!!!\n",proc->subframe,task_name);
    return 0;
  }
  else {
1053 1054
    LOG_I(PHY,"[SCHED][eNB] eNB RX thread CC_id %d SF %d started with id %p\n", /*  on CPU %d*/
	  proc->CC_id,
1055
	  proc->subframe,
1056
	  task); /*,rtai_cpuid()*/
1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074
  }
#else
  LOG_I(PHY,"[SCHED][eNB] eNB RX thread %d started on CPU %d\n",
	proc->subframe,sched_getcpu());
#endif

  mlockall(MCL_CURRENT | MCL_FUTURE);

  //rt_set_runnable_on_cpuid(task,1);
  //cpuid = rtai_cpuid();

#ifdef HARD_RT
  rt_make_hard_real_time();
#endif

  while (!oai_exit){

    vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_RX0+(2*proc->subframe),0);
1075
    
1076 1077 1078 1079 1080 1081 1082 1083 1084 1085
    //    LOG_I(PHY,"Locking mutex for eNB proc %d (IC %d,mutex %p)\n",proc->subframe,proc->instance_cnt,&proc->mutex);
    if (pthread_mutex_lock(&proc->mutex_rx) != 0) {
      LOG_E(PHY,"[SCHED][eNB] error locking mutex for eNB RX proc %d\n",proc->subframe);
    }
    else {
        
      while (proc->instance_cnt_rx < 0) {
	//	LOG_I(PHY,"Waiting and unlocking mutex for eNB proc %d (IC %d,lock %d)\n",proc->subframe,proc->instance_cnt,pthread_mutex_trylock(&proc->mutex));

	pthread_cond_wait(&proc->cond_rx,&proc->mutex_rx);
1086
      }
1087 1088 1089
      //      LOG_I(PHY,"Waking up and unlocking mutex for eNB proc %d\n",proc->subframe);
      if (pthread_mutex_unlock(&proc->mutex_rx) != 0) {	
	LOG_E(PHY,"[SCHED][eNB] error unlocking mutex for eNB RX proc %d\n",proc->subframe);
1090 1091
      }
    }
1092
    vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_RX0+(2*proc->subframe),1);    
1093
    vcd_signal_dumper_dump_variable_by_name(VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_RX_ENB, proc->frame_rx);
1094 1095 1096

    if (oai_exit) break;
    
1097 1098 1099
    if ((((PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms.frame_type == TDD )&&(subframe_select(&PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms,proc->subframe_rx)==SF_UL)) ||
	 (PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms.frame_type == FDD))){
      phy_procedures_eNB_RX(proc->subframe,PHY_vars_eNB_g[0][proc->CC_id],0,no_relay);
1100
    }
1101 1102
    if ((subframe_select(&PHY_vars_eNB_g[0][proc->CC_id]->lte_frame_parms,proc->subframe_rx)==SF_S)){
      phy_procedures_eNB_S_RX(proc->subframe,PHY_vars_eNB_g[0][proc->CC_id],0,no_relay);
1103 1104 1105 1106
    }
      
    if (pthread_mutex_lock(&proc->mutex_rx) != 0) {
      printf("[openair][SCHED][eNB] error locking mutex for eNB RX proc %d\n",proc->subframe);
1107 1108
    }
    else {
1109
      proc->instance_cnt_rx--;
1110
      
1111 1112
      if (pthread_mutex_unlock(&proc->mutex_rx) != 0) {	
	printf("[openair][SCHED][eNB] error unlocking mutex for eNB RX proc %d\n",proc->subframe);
1113 1114
      }
    }
1115 1116 1117 1118

    proc->frame_rx++;
    if (proc->frame_rx==1024)
      proc->frame_rx=0;
1119
    
1120 1121
  }
  vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_RX0+(2*proc->subframe),0);        
1122
#ifdef HARD_RT
1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134
  rt_make_soft_real_time();
#endif

#ifdef DEBUG_THREADS
  printf("Exiting eNB thread RX %d\n",proc->subframe);
#endif
  // clean task
#ifdef RTAI
  rt_task_delete(task);
#else
  eNB_thread_rx_status[proc->subframe]=0;
  pthread_exit(&eNB_thread_rx_status[proc->subframe]);
1135 1136
#endif

1137 1138 1139
#ifdef DEBUG_THREADS
  printf("Exiting eNB RX thread %d\n",proc->subframe);
#endif
1140 1141 1142 1143
}



1144

1145
void init_eNB_proc(void) {
1146 1147

  int i;
1148 1149 1150 1151 1152 1153 1154 1155 1156 1157 1158 1159 1160 1161 1162 1163 1164 1165
  int CC_id;

  for (CC_id=0;CC_id<MAX_NUM_CCs;CC_id++) {
    for (i=0;i<10;i++) {
      pthread_attr_init (&attr_eNB_proc_tx[CC_id][i]);
      pthread_attr_setstacksize(&attr_eNB_proc_tx[CC_id][i],OPENAIR_THREAD_STACK_SIZE);
      //attr_dlsch_threads.priority = 1;
      sched_param_eNB_proc_tx[CC_id][i].sched_priority = sched_get_priority_max(SCHED_FIFO)-1; //OPENAIR_THREAD_PRIORITY;
      pthread_attr_setschedparam  (&attr_eNB_proc_tx[CC_id][i], &sched_param_eNB_proc_tx[CC_id][i]);
      pthread_attr_setschedpolicy (&attr_eNB_proc_tx[CC_id][i], SCHED_FIFO);
      
      pthread_attr_init (&attr_eNB_proc_rx[CC_id][i]);
      pthread_attr_setstacksize(&attr_eNB_proc_rx[CC_id][i],OPENAIR_THREAD_STACK_SIZE);
      //attr_dlsch_threads.priority = 1;
      sched_param_eNB_proc_rx[CC_id][i].sched_priority = sched_get_priority_max(SCHED_FIFO)-1; //OPENAIR_THREAD_PRIORITY;
      pthread_attr_setschedparam  (&attr_eNB_proc_rx[CC_id][i], &sched_param_eNB_proc_rx[CC_id][i]);
      pthread_attr_setschedpolicy (&attr_eNB_proc_rx[CC_id][i], SCHED_FIFO);
      
1166 1167 1168 1169 1170 1171 1172 1173 1174 1175 1176 1177
      PHY_vars_eNB_g[0][CC_id]->proc[i].instance_cnt_tx=-1;
      PHY_vars_eNB_g[0][CC_id]->proc[i].instance_cnt_rx=-1;
      PHY_vars_eNB_g[0][CC_id]->proc[i].subframe=i;
      PHY_vars_eNB_g[0][CC_id]->proc[i].CC_id = CC_id;
      pthread_mutex_init(&PHY_vars_eNB_g[0][CC_id]->proc[i].mutex_tx,NULL);
      pthread_mutex_init(&PHY_vars_eNB_g[0][CC_id]->proc[i].mutex_rx,NULL);
      pthread_cond_init(&PHY_vars_eNB_g[0][CC_id]->proc[i].cond_tx,NULL);
      pthread_cond_init(&PHY_vars_eNB_g[0][CC_id]->proc[i].cond_rx,NULL);
      pthread_create(&PHY_vars_eNB_g[0][CC_id]->proc[i].pthread_tx,NULL,eNB_thread_tx,(void*)&PHY_vars_eNB_g[0][CC_id]->proc[i]);
      pthread_create(&PHY_vars_eNB_g[0][CC_id]->proc[i].pthread_rx,NULL,eNB_thread_rx,(void*)&PHY_vars_eNB_g[0][CC_id]->proc[i]);
      PHY_vars_eNB_g[0][CC_id]->proc[i].frame_tx = 0;
      PHY_vars_eNB_g[0][CC_id]->proc[i].frame_rx = 0;
1178
#ifndef USRP
1179 1180
      PHY_vars_eNB_g[0][CC_id]->proc[i].subframe_rx = (i+9)%10;
      PHY_vars_eNB_g[0][CC_id]->proc[i].subframe_tx = (i+1)%10;
1181
#else
1182 1183
      PHY_vars_eNB_g[0][CC_id]->proc[i].subframe_rx = i;
      PHY_vars_eNB_g[0][CC_id]->proc[i].subframe_tx = (i+2)%10;
1184
#endif
1185 1186 1187
    }
  
  
1188
#ifndef USRP
1189 1190
    // TX processes subframe + 1, RX subframe -1
    // Note this inialization is because the first process awoken for frame 0 is number 1 and so processes 9 and 0 have to start with frame 1
1191
    
1192
    //PHY_vars_eNB_g[0][CC_id]->proc[0].frame_rx = 1023;
1193 1194
    PHY_vars_eNB_g[0][CC_id]->proc[9].frame_tx = 1;
    PHY_vars_eNB_g[0][CC_id]->proc[0].frame_tx = 1;
1195
#else
1196 1197
    // TX processes subframe +2, RX subframe
    // Note this inialization is because the first process awoken for frame 0 is number 1 and so processes 8,9 and 0 have to start with frame 1
1198
    //    PHY_vars_eNB_g[0][CC_id]->proc[7].frame_tx = 1;
1199 1200
    PHY_vars_eNB_g[0][CC_id]->proc[8].frame_tx = 1;
    PHY_vars_eNB_g[0][CC_id]->proc[9].frame_tx = 1;