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wangjie
OpenXG-RAN
Commits
feabf022
Commit
feabf022
authored
Aug 11, 2014
by
Raymond Knopp
Browse files
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git-svn-id:
http://svn.eurecom.fr/openair4G/trunk@5701
818b1a75-f10b-46b9-bf7c-635c3b92a50f
parent
a7721ae2
Changes
1
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1 changed file
with
213 additions
and
192 deletions
+213
-192
targets/RT/USER/lte-softmodem.c
targets/RT/USER/lte-softmodem.c
+213
-192
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targets/RT/USER/lte-softmodem.c
View file @
feabf022
...
...
@@ -183,10 +183,10 @@ pthread_mutex_t sync_mutex;
#endif
#endif
pthread_attr_t
attr_eNB_proc_tx
[
10
];
pthread_attr_t
attr_eNB_proc_rx
[
10
];
struct
sched_param
sched_param_eNB_proc_tx
[
10
];
struct
sched_param
sched_param_eNB_proc_rx
[
10
];
pthread_attr_t
attr_eNB_proc_tx
[
MAX_NUM_CCs
][
10
];
pthread_attr_t
attr_eNB_proc_rx
[
MAX_NUM_CCs
][
10
];
struct
sched_param
sched_param_eNB_proc_tx
[
MAX_NUM_CCs
][
10
];
struct
sched_param
sched_param_eNB_proc_rx
[
MAX_NUM_CCs
][
10
];
#ifdef XFORMS
static
pthread_t
thread2
;
//xforms
...
...
@@ -424,7 +424,7 @@ static void *scope_thread(void *arg) {
# ifdef ENABLE_XFORMS_WRITE_STATS
len
=
# endif
dump_eNB_stats
(
PHY_vars_eNB_g
[
0
],
stats_buffer
,
0
);
dump_eNB_stats
(
PHY_vars_eNB_g
[
0
]
[
0
]
,
stats_buffer
,
0
);
fl_set_object_label
(
form_stats
->
stats_text
,
stats_buffer
);
# ifdef ENABLE_XFORMS_WRITE_STATS
rewind
(
eNB_stats
);
...
...
@@ -432,7 +432,7 @@ static void *scope_thread(void *arg) {
# endif
for
(
UE_id
=
0
;
UE_id
<
scope_enb_num_ue
;
UE_id
++
)
{
phy_scope_eNB
(
form_enb
[
UE_id
],
PHY_vars_eNB_g
[
eNB_id
],
PHY_vars_eNB_g
[
eNB_id
]
[
0
]
,
UE_id
);
}
...
...
@@ -844,20 +844,21 @@ static void * eNB_thread_tx(void *param) {
vcd_signal_dumper_dump_variable_by_name
(
VCD_SIGNAL_DUMPER_VARIABLES_SLOT_NUMBER_ENB
,
proc
->
subframe
*
2
);
if
(
oai_exit
)
break
;
if
((((
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
.
frame_type
==
TDD
)
&&
(
subframe_select
(
&
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
,
proc
->
subframe_tx
)
==
SF_DL
))
||
(
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
.
frame_type
==
FDD
)))
{
phy_procedures_eNB_TX
(
proc
->
subframe
,
PHY_vars_eNB_g
[
0
],
0
,
no_relay
,
NULL
);
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
);
}
if
((
subframe_select
(
&
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
,
proc
->
subframe_tx
)
==
SF_S
))
{
phy_procedures_eNB_TX
(
proc
->
subframe
,
PHY_vars_eNB_g
[
0
],
0
,
no_relay
,
NULL
);
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
);
}
do_OFDM_mod
(
proc
->
subframe_tx
,
PHY_vars_eNB_g
[
0
]);
do_OFDM_mod
(
proc
->
subframe_tx
,
PHY_vars_eNB_g
[
0
]
[
proc
->
CC_id
]
);
if
(
pthread_mutex_lock
(
&
proc
->
mutex_tx
)
!=
0
)
{
printf
(
"[openair][SCHED][eNB] error locking mutex for eNB TX proc %d
\n
"
,
proc
->
subframe
);
...
...
@@ -900,7 +901,6 @@ static void * eNB_thread_rx(void *param) {
//unsigned long cpuid;
eNB_proc_t
*
proc
=
(
eNB_proc_t
*
)
param
;
int
i
;
// RTIME time_in,time_out;
#ifdef RTAI
RT_TASK
*
task
;
...
...
@@ -964,12 +964,12 @@ static void * eNB_thread_rx(void *param) {
if
(
oai_exit
)
break
;
if
((((
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
.
frame_type
==
TDD
)
&&
(
subframe_select
(
&
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
,
proc
->
subframe_rx
)
==
SF_UL
))
||
(
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
.
frame_type
==
FDD
))){
phy_procedures_eNB_RX
(
proc
->
subframe
,
PHY_vars_eNB_g
[
0
],
0
,
no_relay
);
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
);
}
if
((
subframe_select
(
&
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
,
proc
->
subframe_rx
)
==
SF_S
)){
phy_procedures_eNB_S_RX
(
proc
->
subframe
,
PHY_vars_eNB_g
[
0
],
0
,
no_relay
);
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
);
}
if
(
pthread_mutex_lock
(
&
proc
->
mutex_rx
)
!=
0
)
{
...
...
@@ -1014,97 +1014,103 @@ static void * eNB_thread_rx(void *param) {
void
init_eNB_proc
()
{
int
i
;
for
(
i
=
0
;
i
<
10
;
i
++
)
{
pthread_attr_init
(
&
attr_eNB_proc_tx
[
i
]);
pthread_attr_setstacksize
(
&
attr_eNB_proc_tx
[
i
],
OPENAIR_THREAD_STACK_SIZE
);
//attr_dlsch_threads.priority = 1;
sched_param_eNB_proc_tx
[
i
].
sched_priority
=
sched_get_priority_max
(
SCHED_FIFO
)
-
1
;
//OPENAIR_THREAD_PRIORITY;
pthread_attr_setschedparam
(
&
attr_eNB_proc_tx
[
i
],
&
sched_param_eNB_proc_tx
);
pthread_attr_setschedpolicy
(
&
attr_eNB_proc_tx
[
i
],
SCHED_FIFO
);
pthread_attr_init
(
&
attr_eNB_proc_rx
[
i
]);
pthread_attr_setstacksize
(
&
attr_eNB_proc_rx
[
i
],
OPENAIR_THREAD_STACK_SIZE
);
//attr_dlsch_threads.priority = 1;
sched_param_eNB_proc_rx
[
i
].
sched_priority
=
sched_get_priority_max
(
SCHED_FIFO
)
-
1
;
//OPENAIR_THREAD_PRIORITY;
pthread_attr_setschedparam
(
&
attr_eNB_proc_rx
[
i
],
&
sched_param_eNB_proc_rx
);
pthread_attr_setschedpolicy
(
&
attr_eNB_proc_rx
[
i
],
SCHED_FIFO
);
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
instance_cnt_tx
=-
1
;
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
instance_cnt_rx
=-
1
;
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
subframe
=
i
;
pthread_mutex_init
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
mutex_tx
,
NULL
);
pthread_mutex_init
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
mutex_rx
,
NULL
);
pthread_cond_init
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
cond_tx
,
NULL
);
pthread_cond_init
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
cond_rx
,
NULL
);
pthread_create
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
pthread_tx
,
NULL
,
eNB_thread_tx
,(
void
*
)
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
]);
pthread_create
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
pthread_rx
,
NULL
,
eNB_thread_rx
,(
void
*
)
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
]);
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
frame_tx
=
0
;
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
frame_rx
=
0
;
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
);
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
{
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
;
#ifndef USRP
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
subframe_rx
=
(
i
+
9
)
%
10
;
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
subframe_tx
=
(
i
+
1
)
%
10
;
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
;
#else
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
subframe_rx
=
i
;
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
subframe_tx
=
(
i
+
2
)
%
10
;
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
;
#endif
}
}
}
#ifndef USRP
// 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
//PHY_vars_eNB_g[0]->proc[0].frame_rx = 1023;
PHY_vars_eNB_g
[
0
]
->
proc
[
9
].
frame_tx
=
1
;
PHY_vars_eNB_g
[
0
]
->
proc
[
0
].
frame_tx
=
1
;
//PHY_vars_eNB_g[0]
[CC_id]
->proc[0].frame_rx = 1023;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
9
].
frame_tx
=
1
;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
0
].
frame_tx
=
1
;
#else
// 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
PHY_vars_eNB_g
[
0
]
->
proc
[
8
].
frame_tx
=
1
;
PHY_vars_eNB_g
[
0
]
->
proc
[
9
].
frame_tx
=
1
;
PHY_vars_eNB_g
[
0
]
->
proc
[
0
].
frame_tx
=
1
;
// 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
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
8
].
frame_tx
=
1
;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
9
].
frame_tx
=
1
;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
0
].
frame_tx
=
1
;
#endif
}
}
}
void
kill_eNB_proc
()
{
int
i
;
int
*
status_tx
,
*
status_rx
;
int
CC_id
;
for
(
i
=
0
;
i
<
10
;
i
++
)
{
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
for
(
i
=
0
;
i
<
10
;
i
++
)
{
#ifdef DEBUG_THREADS
printf
(
"Killing TX thread %d
\n
"
,
i
);
printf
(
"Killing TX CC_id %d thread %d
\n
"
,
CC_id
,
i
);
#endif
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
instance_cnt_tx
=
0
;
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
cond_tx
);
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
instance_cnt_tx
=
0
;
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
cond_tx
);
#ifdef DEBUG_THREADS
printf
(
"Joining eNB TX thread %d..."
,
i
);
printf
(
"Joining eNB TX CC_id %d thread %d..."
,
CC_id
,
i
);
#endif
pthread_join
(
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
pthread_tx
,(
void
**
)
status_tx
);
pthread_join
(
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
pthread_tx
,(
void
**
)
status_tx
);
#ifdef DEBUG_THREADS
if
(
status_tx
)
printf
(
"status %d..."
,
*
status_tx
);
if
(
status_tx
)
printf
(
"status %d..."
,
*
status_tx
);
#endif
#ifdef DEBUG_THREADS
printf
(
"Killing RX thread %d
\n
"
,
i
);
printf
(
"Killing RX CC_id %d thread %d
\n
"
,
CC_id
,
i
);
#endif
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
instance_cnt_rx
=
0
;
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
cond_rx
);
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
instance_cnt_rx
=
0
;
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
cond_rx
);
#ifdef DEBUG_THREADS
printf
(
"Joining eNB RX thread %d..."
,
i
);
printf
(
"Joining eNB RX CC_id %d thread %d..."
,
CC_id
,
i
);
#endif
pthread_join
(
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
pthread_rx
,(
void
**
)
status_rx
);
pthread_join
(
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
pthread_rx
,(
void
**
)
status_rx
);
#ifdef DEBUG_THREADS
if
(
status_rx
)
printf
(
"status %d..."
,
*
status_rx
);
if
(
status_rx
)
printf
(
"status %d..."
,
*
status_rx
);
#endif
pthread_mutex_destroy
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
mutex_tx
);
pthread_mutex_destroy
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
mutex_rx
);
pthread_cond_destroy
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
cond_tx
);
pthread_cond_destroy
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
i
].
cond_rx
);
}
pthread_mutex_destroy
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
mutex_tx
);
pthread_mutex_destroy
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
mutex_rx
);
pthread_cond_destroy
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
cond_tx
);
pthread_cond_destroy
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
i
].
cond_rx
);
}
}
...
...
@@ -1127,6 +1133,7 @@ static void *eNB_thread(void *arg)
unsigned
char
slot
=
1
;
#endif
int
frame
=
0
;
int
CC_id
;
RTIME
time_in
,
time_diff
;
...
...
@@ -1136,13 +1143,13 @@ static void *eNB_thread(void *arg)
int
mbox_target
=
0
,
mbox_current
=
0
;
int
hw_slot
,
delay_cnt
;
int
diff
;
int
i
;
int
ret
;
#else
unsigned
int
rx_cnt
=
0
;
unsigned
int
tx_cnt
=
tx_delay
;
// int tx_offset;
int
CC_id
;
hw_subframe
=
0
;
...
...
@@ -1349,55 +1356,57 @@ static void *eNB_thread(void *arg)
if
(
multi_thread
==
0
)
{
if
((
slot
&
1
)
==
0
)
{
LOG_I
(
PHY
,
"[eNB] Single thread slot %d
\n
"
,
slot
);
phy_procedures_eNB_lte
((
2
+
(
slot
>>
1
))
%
10
,
PHY_vars_eNB_g
[
0
],
0
,
no_relay
,
NULL
);
do_OFDM_mod
((
2
+
(
slot
>>
1
))
%
10
,
PHY_vars_eNB_g
[
0
]);
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
{
phy_procedures_eNB_lte
((
2
+
(
slot
>>
1
))
%
10
,
PHY_vars_eNB_g
[
0
][
CC_id
],
0
,
no_relay
,
NULL
);
do_OFDM_mod
((
2
+
(
slot
>>
1
))
%
10
,
PHY_vars_eNB_g
[
0
][
CC_id
]);
}
}
}
else
{
// multi-thread > 0
if
((
slot
&
1
)
==
1
)
{
sf
=
((
slot
>>
1
)
+
1
)
%
10
;
// LOG_I(PHY,"[eNB] Multithread slot %d (IC %d)\n",slot,PHY_vars_eNB_g[0]->proc[sf].instance_cnt);
if
(
pthread_mutex_lock
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
mutex_tx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_mutex_lock for eNB TX thread %d (IC %d)
\n
"
,
sf
,
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
instance_cnt_tx
);
}
else
{
// LOG_I(PHY,"[eNB] Waking up eNB process %d (IC %d)\n",sf,PHY_vars_eNB_g[0]->proc[sf].instance_cnt);
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
instance_cnt_tx
++
;
pthread_mutex_unlock
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
mutex_tx
);
if
(
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
instance_cnt_tx
==
0
)
{
if
(
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
cond_tx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_cond_signal for eNB TX thread %d
\n
"
,
sf
);
}
// LOG_I(PHY,"[eNB] Multithread slot %d (IC %d)\n",slot,PHY_vars_eNB_g[0][CC_id]->proc[sf].instance_cnt);
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
{
if
(
pthread_mutex_lock
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
mutex_tx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_mutex_lock for eNB TX thread %d (IC %d)
\n
"
,
sf
,
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
instance_cnt_tx
);
}
else
{
LOG_W
(
PHY
,
"[eNB] Frame %d, eNB TX thread %d busy!!
\n
"
,
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
frame_tx
,
sf
);
oai_exit
=
1
;
}
}
if
(
pthread_mutex_lock
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
mutex_rx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_mutex_lock for eNB RX thread %d (IC %d)
\n
"
,
sf
,
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
instance_cnt_rx
);
}
else
{
// LOG_I(PHY,"[eNB] Waking up eNB process %d (IC %d)\n",sf,PHY_vars_eNB_g[0]->proc[sf].instance_cnt);
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
instance_cnt_rx
++
;
pthread_mutex_unlock
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
mutex_rx
);
if
(
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
instance_cnt_rx
==
0
)
{
if
(
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
cond_rx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_cond_signal for eNB RX thread %d
\n
"
,
sf
);
// LOG_I(PHY,"[eNB] Waking up eNB process %d (IC %d)\n",sf,PHY_vars_eNB_g[0][CC_id]->proc[sf].instance_cnt);
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
instance_cnt_tx
++
;
pthread_mutex_unlock
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
mutex_tx
);
if
(
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
instance_cnt_tx
==
0
)
{
if
(
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
cond_tx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_cond_signal for eNB TX thread %d
\n
"
,
sf
);
}
}
else
{
LOG_W
(
PHY
,
"[eNB] Frame %d, eNB TX thread %d busy!!
\n
"
,
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
frame_tx
,
sf
);
oai_exit
=
1
;
}
}
if
(
pthread_mutex_lock
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
mutex_rx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_mutex_lock for eNB RX thread %d (IC %d)
\n
"
,
sf
,
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
instance_cnt_rx
);
}
else
{
LOG_W
(
PHY
,
"[eNB] Frame %d, eNB RX thread %d busy!!
\n
"
,
PHY_vars_eNB_g
[
0
]
->
proc
[
sf
].
frame_rx
,
sf
);
oai_exit
=
1
;
// LOG_I(PHY,"[eNB] Waking up eNB process %d (IC %d)\n",sf,PHY_vars_eNB_g[0][CC_id]->proc[sf].instance_cnt);
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
instance_cnt_rx
++
;
pthread_mutex_unlock
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
mutex_rx
);
if
(
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
instance_cnt_rx
==
0
)
{
if
(
pthread_cond_signal
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
cond_rx
)
!=
0
)
{
LOG_E
(
PHY
,
"[eNB] ERROR pthread_cond_signal for eNB RX thread %d
\n
"
,
sf
);
}
}
else
{
LOG_W
(
PHY
,
"[eNB] Frame %d, eNB RX thread %d busy!!
\n
"
,
PHY_vars_eNB_g
[
0
][
CC_id
]
->
proc
[
sf
].
frame_rx
,
sf
);
oai_exit
=
1
;
}
}
}
}
}
}
#ifndef RTAI
//pthread_mutex_lock(&tti_mutex);
#endif
...
...
@@ -1507,7 +1516,7 @@ static void *UE_thread(void *arg) {
if
(
is_synchronized
)
{
//this is the mbox counter that indicates the start of the frame
rx_offset_mbox
=
(
PHY_vars_UE_g
[
0
]
->
rx_offset
*
150
)
/
(
10
*
PHY_vars_UE_g
[
0
]
->
lte_frame_parms
.
samples_per_tti
);
rx_offset_mbox
=
(
PHY_vars_UE_g
[
0
]
[
0
]
->
rx_offset
*
150
)
/
(
10
*
PHY_vars_UE_g
[
0
]
[
0
]
->
lte_frame_parms
.
samples_per_tti
);
//this is the mbox counter where we should be
mbox_target
=
(((((
slot
+
1
)
%
20
)
*
15
+
1
)
>>
1
)
+
rx_offset_mbox
+
1
)
%
150
;
// round up to the next multiple of two (mbox counter from express MIMO gives only even numbers)
...
...
@@ -1583,7 +1592,7 @@ static void *UE_thread(void *arg) {
next_slot
=
(
slot
+
3
)
%
LTE_SLOTS_PER_FRAME
;
if
(
is_synchronized
)
{
phy_procedures_UE_lte
(
last_slot
,
next_slot
,
PHY_vars_UE_g
[
0
],
0
,
0
,
mode
,
0
,
NULL
);
phy_procedures_UE_lte
(
last_slot
,
next_slot
,
PHY_vars_UE_g
[
0
]
[
0
]
,
0
,
0
,
mode
,
0
,
NULL
);
}
else
{
// we are not yet synchronized
...
...
@@ -1595,7 +1604,7 @@ static void *UE_thread(void *arg) {
// rt_sleep_ns(FRAME_PERIOD);
// LOG_D(HW,"after sleep\n");
if
(
initial_sync
(
PHY_vars_UE_g
[
0
],
mode
)
==
0
)
{
if
(
initial_sync
(
PHY_vars_UE_g
[
0
]
[
0
]
,
mode
)
==
0
)
{
/*
lte_adjust_synch(&PHY_vars_UE_g[0]->lte_frame_parms,
PHY_vars_UE_g[0],
...
...
@@ -1618,7 +1627,7 @@ static void *UE_thread(void *arg) {
//LOG_D(HW,"Before openair0_start_rt_acquisition \n");
openair0_start_rt_acquisition
(
card
);
hw_slot_offset
=
(
PHY_vars_UE_g
[
0
]
->
rx_offset
<<
1
)
/
PHY_vars_UE_g
[
0
]
->
lte_frame_parms
.
samples_per_tti
;
hw_slot_offset
=
(
PHY_vars_UE_g
[
0
]
[
0
]
->
rx_offset
<<
1
)
/
PHY_vars_UE_g
[
0
]
[
0
]
->
lte_frame_parms
.
samples_per_tti
;
LOG_D
(
HW
,
"Got synch: hw_slot_offset %d
\n
"
,
hw_slot_offset
);
}
}
...
...
@@ -1866,7 +1875,7 @@ int main(int argc, char **argv) {
void
*
status
;
#endif
int
CC_id
;
uint16_t
Nid_cell
=
0
;
uint8_t
cooperation_flag
=
0
,
transmission_mode
=
1
,
abstraction_flag
=
0
;
#ifndef OPENAIR2
...
...
@@ -2052,85 +2061,96 @@ int main(int argc, char **argv) {
// N_ZC = (prach_fmt <4)?839:139;
if
(
UE_flag
==
1
)
{
PHY_vars_UE_g
=
malloc
(
sizeof
(
PHY_VARS_UE
*
));
PHY_vars_UE_g
[
0
]
=
init_lte_UE
(
frame_parms
,
UE_id
,
abstraction_flag
,
transmission_mode
);
#ifndef OPENAIR2
for
(
i
=
0
;
i
<
NUMBER_OF_eNB_MAX
;
i
++
)
{
PHY_vars_UE_g
[
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_ACK_Index
=
beta_ACK
;
PHY_vars_UE_g
[
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_RI_Index
=
beta_RI
;
PHY_vars_UE_g
[
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_CQI_Index
=
beta_CQI
;
PHY_vars_UE_g
=
malloc
(
sizeof
(
PHY_VARS_UE
**
));
PHY_vars_UE_g
[
0
]
=
malloc
(
sizeof
(
PHY_VARS_UE
*
)
*
MAX_NUM_CCs
);
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
{
PHY_vars_UE_g
[
CC_id
][
0
]
=
init_lte_UE
(
frame_parms
,
UE_id
,
abstraction_flag
,
transmission_mode
);
PHY_vars_UE_g
[
0
]
->
scheduling_request_config
[
i
].
sr_PUCCH_ResourceIndex
=
UE_id
;
PHY_vars_UE_g
[
0
]
->
scheduling_request_config
[
i
].
sr_ConfigIndex
=
7
+
(
UE_id
%
3
);
PHY_vars_UE_g
[
0
]
->
scheduling_request_config
[
i
].
dsr_TransMax
=
sr_n4
;
}
#ifndef OPENAIR2
for
(
i
=
0
;
i
<
NUMBER_OF_eNB_MAX
;
i
++
)
{
PHY_vars_UE_g
[
CC_id
][
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_ACK_Index
=
beta_ACK
;
PHY_vars_UE_g
[
CC_id
][
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_RI_Index
=
beta_RI
;
PHY_vars_UE_g
[
CC_id
][
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_CQI_Index
=
beta_CQI
;
PHY_vars_UE_g
[
CC_id
][
0
]
->
scheduling_request_config
[
i
].
sr_PUCCH_ResourceIndex
=
UE_id
;
PHY_vars_UE_g
[
CC_id
][
0
]
->
scheduling_request_config
[
i
].
sr_ConfigIndex
=
7
+
(
UE_id
%
3
);
PHY_vars_UE_g
[
CC_id
][
0
]
->
scheduling_request_config
[
i
].
dsr_TransMax
=
sr_n4
;
}
#endif
compute_prach_seq
(
&
PHY_vars_UE_g
[
0
]
->
lte_frame_parms
.
prach_config_common
,
PHY_vars_UE_g
[
0
]
->
lte_frame_parms
.
frame_type
,
PHY_vars_UE_g
[
0
]
->
X_u
);
PHY_vars_UE_g
[
0
]
->
lte_ue_pdcch_vars
[
0
]
->
crnti
=
0x1234
;
compute_prach_seq
(
&
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
lte_frame_parms
.
prach_config_common
,
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
lte_frame_parms
.
frame_type
,
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
X_u
);
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
lte_ue_pdcch_vars
[
0
]
->
crnti
=
0x1234
;
#ifndef OPENAIR2
PHY_vars_UE_g
[
0
]
->
lte_ue_pdcch_vars
[
0
]
->
crnti
=
0x1235
;
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
lte_ue_pdcch_vars
[
0
]
->
crnti
=
0x1235
;
#endif
NB_UE_INST
=
1
;
NB_INST
=
1
;
openair_daq_vars
.
manual_timing_advance
=
0
;
//openair_daq_vars.timing_advance = TIMING_ADVANCE_HW;
openair_daq_vars
.
rx_gain_mode
=
DAQ_AGC_ON
;
openair_daq_vars
.
auto_freq_correction
=
0
;
openair_daq_vars
.
use_ia_receiver
=
0
;
for
(
i
=
0
;
i
<
4
;
i
++
)
{
PHY_vars_UE_g
[
0
]
->
rx_gain_max
[
i
]
=
rxg_max
[
i
];
// PHY_vars_UE_g[0]->rx_gain_med[i] = rxg_med[i];
// PHY_vars_UE_g[0]->rx_gain_byp[i] = rxg_byp[i];
PHY_vars_UE_g
[
CC_id
][
0
]
->
rx_gain_max
[
i
]
=
rxg_max
[
i
];
// PHY_vars_UE_g[
CC_id][
0]->rx_gain_med[i] = rxg_med[i];
// PHY_vars_UE_g[
CC_id][
0]->rx_gain_byp[i] = rxg_byp[i];
}
if
((
mode
==
normal_txrx
)
||
(
mode
==
rx_calib_ue
)
||
(
mode
==
no_L2_connect
)
||
(
mode
==
debug_prach
))
{
for
(
i
=
0
;
i
<
4
;
i
++
)
openair0_cfg
.
rxg_mode
[
i
]
=
max_gain
;
PHY_vars_UE_g
[
0
]
->
rx_total_gain_dB
=
PHY_vars_UE_g
[
0
]
->
rx_gain_max
[
0
]
+
(
int
)
rx_gain
-
30
;
//-30 because it was calibrated with a 30dB gain
PHY_vars_UE_g
[
CC_id
][
0
]
->
rx_total_gain_dB
=
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
rx_gain_max
[
0
]
+
(
int
)
rx_gain
-
30
;
//-30 because it was calibrated with a 30dB gain
}
else
if
((
mode
==
rx_calib_ue_med
))
{
for
(
i
=
0
;
i
<
4
;
i
++
)
openair0_cfg
.
rxg_mode
[
i
]
=
med_gain
;
PHY_vars_UE_g
[
0
]
->
rx_total_gain_dB
=
PHY_vars_UE_g
[
0
]
->
rx_gain_med
[
0
]
+
(
int
)
rx_gain
-
30
;
//-30 because it was calibrated with a 30dB gain;
PHY_vars_UE_g
[
CC_id
][
0
]
->
rx_total_gain_dB
=
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
rx_gain_med
[
0
]
+
(
int
)
rx_gain
-
30
;
//-30 because it was calibrated with a 30dB gain;
}
else
if
((
mode
==
rx_calib_ue_byp
))
{
for
(
i
=
0
;
i
<
4
;
i
++
)
openair0_cfg
.
rxg_mode
[
i
]
=
byp_gain
;
PHY_vars_UE_g
[
0
]
->
rx_total_gain_dB
=
PHY_vars_UE_g
[
0
]
->
rx_gain_byp
[
0
]
+
(
int
)
rx_gain
-
30
;
//-30 because it was calibrated with a 30dB gain;
PHY_vars_UE_g
[
CC_id
][
0
]
->
rx_total_gain_dB
=
PHY_vars_UE_g
[
CC_id
]
[
0
]
->
rx_gain_byp
[
0
]
+
(
int
)
rx_gain
-
30
;
//-30 because it was calibrated with a 30dB gain;
}
PHY_vars_UE_g
[
0
]
->
tx_power_max_dBm
=
tx_max_power
;
PHY_vars_UE_g
[
CC_id
][
0
]
->
tx_power_max_dBm
=
tx_max_power
;
}
NB_UE_INST
=
1
;
NB_INST
=
1
;
openair_daq_vars
.
manual_timing_advance
=
0
;
//openair_daq_vars.timing_advance = TIMING_ADVANCE_HW;
openair_daq_vars
.
rx_gain_mode
=
DAQ_AGC_ON
;
openair_daq_vars
.
auto_freq_correction
=
0
;
openair_daq_vars
.
use_ia_receiver
=
0
;
// printf("tx_max_power = %d -> amp %d\n",tx_max_power,get_tx_amp(tx_max_power,tx_max_power));
}
else
{
//this is eNB
PHY_vars_eNB_g
=
malloc
(
sizeof
(
PHY_VARS_eNB
*
));
PHY_vars_eNB_g
[
0
]
=
init_lte_eNB
(
frame_parms
,
eNB_id
,
Nid_cell
,
cooperation_flag
,
transmission_mode
,
abstraction_flag
);
PHY_vars_eNB_g
=
malloc
(
sizeof
(
PHY_VARS_eNB
**
));
PHY_vars_eNB_g
[
0
]
=
malloc
(
sizeof
(
PHY_VARS_eNB
*
));
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
{
PHY_vars_eNB_g
[
0
][
CC_id
]
=
init_lte_eNB
(
frame_parms
,
eNB_id
,
Nid_cell
,
cooperation_flag
,
transmission_mode
,
abstraction_flag
);
#ifndef OPENAIR2
for
(
i
=
0
;
i
<
NUMBER_OF_UE_MAX
;
i
++
)
{
PHY_vars_eNB_g
[
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_ACK_Index
=
beta_ACK
;
PHY_vars_eNB_g
[
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_RI_Index
=
beta_RI
;
PHY_vars_eNB_g
[
0
]
->
pusch_config_dedicated
[
i
].
betaOffset_CQI_Index
=
beta_CQI
;
PHY_vars_eNB_g
[
0
]
->
scheduling_request_config
[
i
].
sr_PUCCH_ResourceIndex
=
i
;
PHY_vars_eNB_g
[
0
]
->
scheduling_request_config
[
i
].
sr_ConfigIndex
=
7
+
(
i
%
3
);
PHY_vars_eNB_g
[
0
]
->
scheduling_request_config
[
i
].
dsr_TransMax
=
sr_n4
;
}
for
(
i
=
0
;
i
<
NUMBER_OF_UE_MAX
;
i
++
)
{
PHY_vars_eNB_g
[
0
][
CC_id
]
->
pusch_config_dedicated
[
i
].
betaOffset_ACK_Index
=
beta_ACK
;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
pusch_config_dedicated
[
i
].
betaOffset_RI_Index
=
beta_RI
;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
pusch_config_dedicated
[
i
].
betaOffset_CQI_Index
=
beta_CQI
;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
scheduling_request_config
[
i
].
sr_PUCCH_ResourceIndex
=
i
;
PHY_vars_eNB_g
[
0
][
CC_id
]
->
scheduling_request_config
[
i
].
sr_ConfigIndex
=
7
+
(
i
%
3
);
PHY_vars_eNB_g
[
0
][
CC_id
]
->
scheduling_request_config
[
i
].
dsr_TransMax
=
sr_n4
;
}
#endif
compute_prach_seq
(
&
PHY_vars_eNB_g
[
0
][
CC_id
]
->
lte_frame_parms
.
prach_config_common
,
PHY_vars_eNB_g
[
0
][
CC_id
]
->
lte_frame_parms
.
frame_type
,
PHY_vars_eNB_g
[
0
][
CC_id
]
->
X_u
);
compute_prach_seq
(
&
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
.
prach_config_common
,
PHY_vars_eNB_g
[
0
]
->
lte_frame_parms
.
frame_type
,
PHY_vars_eNB_g
[
0
]
->
X_u
);
PHY_vars_eNB_g
[
0
][
CC_id
]
->
rx_total_gain_eNB_dB
=
rxg_max
[
0
]
+
(
int
)
rx_gain
-
30
;
//was measured at rxgain=30;
}
NB_eNB_INST
=
1
;
NB_INST
=
1
;
...
...
@@ -2140,7 +2160,6 @@ int main(int argc, char **argv) {
openair_daq_vars
.
target_ue_ul_mcs
=
6
;
// set eNB to max gain
PHY_vars_eNB_g
[
0
]
->
rx_total_gain_eNB_dB
=
rxg_max
[
0
]
+
(
int
)
rx_gain
-
30
;
//was measured at rxgain=30;
for
(
i
=
0
;
i
<
4
;
i
++
)
openair0_cfg
.
rxg_mode
[
i
]
=
max_gain
;
}
...
...
@@ -2257,24 +2276,26 @@ int main(int argc, char **argv) {
// connect the TX/RX buffers
if
(
UE_flag
==
1
)
{
setup_ue_buffers
(
PHY_vars_UE_g
[
0
],
frame_parms
,
ant_offset
);
printf
(
"Setting UE buffer to all-RX
\n
"
);
// Set LSBs for antenna switch (ExpressMIMO)
for
(
i
=
0
;
i
<
frame_parms
->
samples_per_tti
*
10
;
i
++
)
for
(
aa
=
0
;
aa
<
frame_parms
->
nb_antennas_tx
;
aa
++
)
PHY_vars_UE_g
[
0
]
->
lte_ue_common_vars
.
txdata
[
aa
][
i
]
=
0x00010001
;
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
{
setup_ue_buffers
(
PHY_vars_UE_g
[
CC_id
][
0
],
frame_parms
,
ant_offset
);
printf
(
"Setting UE buffer to all-RX
\n
"
);
// Set LSBs for antenna switch (ExpressMIMO)
for
(
i
=
0
;
i
<
frame_parms
->
samples_per_tti
*
10
;
i
++
)
for
(
aa
=
0
;
aa
<
frame_parms
->
nb_antennas_tx
;
aa
++
)
PHY_vars_UE_g
[
CC_id
][
0
]
->
lte_ue_common_vars
.
txdata
[
aa
][
i
]
=
0x00010001
;
}
//p_exmimo_config->framing.tdd_config = TXRXSWITCH_TESTRX;
}
else
{
setup_eNB_buffers
(
PHY_vars_eNB_g
[
0
],
frame_parms
,
ant_offset
);
printf
(
"Setting eNB buffer to all-RX
\n
"
);
// Set LSBs for antenna switch (ExpressMIMO)
for
(
i
=
0
;
i
<
frame_parms
->
samples_per_tti
*
10
;
i
++
)
for
(
aa
=
0
;
aa
<
frame_parms
->
nb_antennas_tx
;
aa
++
)
PHY_vars_eNB_g
[
0
]
->
lte_eNB_common_vars
.
txdata
[
0
][
aa
][
i
]
=
0x00010001
;
for
(
CC_id
=
0
;
CC_id
<
MAX_NUM_CCs
;
CC_id
++
)
{
setup_eNB_buffers
(
PHY_vars_eNB_g
[
CC_id
][
0
],
frame_parms
,
ant_offset
);
printf
(
"Setting eNB buffer to all-RX
\n
"
);
// Set LSBs for antenna switch (ExpressMIMO)
for
(
i
=
0
;
i
<
frame_parms
->
samples_per_tti
*
10
;
i
++
)
for
(
aa
=
0
;
aa
<
frame_parms
->
nb_antennas_tx
;
aa
++
)
PHY_vars_eNB_g
[
CC_id
][
0
]
->
lte_eNB_common_vars
.
txdata
[
0
][
aa
][
i
]
=
0x00010001
;
}
}
#ifndef USRP
openair0_dump_config
(
card
);
#endif
...
...
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