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canghaiwuhen
OpenXG-RAN
Commits
232f56b9
Commit
232f56b9
authored
Jun 26, 2017
by
fnabet
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prepare for rebase from 2017.w25
parent
bc2a9318
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openair1/SCHED/phy_procedures_lte_ue.c
openair1/SCHED/phy_procedures_lte_ue.c
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openair1/SCHED/phy_procedures_lte_ue.c
View file @
232f56b9
...
@@ -4937,6 +4937,509 @@ int phy_procedures_UE_RX(PHY_VARS_UE *ue,UE_rxtx_proc_t *proc,uint8_t eNB_id,uin
...
@@ -4937,6 +4937,509 @@ int phy_procedures_UE_RX(PHY_VARS_UE *ue,UE_rxtx_proc_t *proc,uint8_t eNB_id,uin
return
(
0
);
return
(
0
);
}
}
static
int
phy_procedures_UE_RX_new
(
PHY_VARS_UE
*
ue
,
UE_rxtx_proc_t
*
proc
,
uint8_t
eNB_id
,
uint8_t
abstraction_flag
,
runmode_t
mode
,
relaying_type_t
r_type
,
PHY_VARS_RN
*
phy_vars_rn
)
{
int
l
,
l2
;
int
pmch_flag
=
0
;
int
frame_rx
=
proc
->
frame_rx
;
int
subframe_rx
=
proc
->
subframe_rx
;
uint8_t
pilot0
;
uint8_t
pilot1
;
uint8_t
slot0
;
uint8_t
slot1
;
uint8_t
first_ofdm_sym
;
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_UE_RX
,
VCD_FUNCTION_IN
);
#if T_TRACER
T
(
T_UE_PHY_DL_TICK
,
T_INT
(
ue
->
Mod_id
),
T_INT
(
frame_rx
%
1024
),
T_INT
(
subframe_rx
));
#endif
T
(
T_UE_PHY_INPUT_SIGNAL
,
T_INT
(
ue
->
Mod_id
),
T_INT
(
frame_rx
%
1024
),
T_INT
(
subframe_rx
),
T_INT
(
0
),
T_BUFFER
(
&
ue
->
common_vars
.
rxdata
[
0
][
subframe_rx
*
ue
->
frame_parms
.
samples_per_tti
],
ue
->
frame_parms
.
samples_per_tti
*
4
));
// start timers
LOG_I
(
PHY
,
" ****** start RX-Chain for AbsSubframe %d.%d ******
\n
"
,
frame_rx
%
1024
,
subframe_rx
);
start_meas
(
&
ue
->
phy_proc_rx
[
subframe_rx
&
0x1
]);
start_meas
(
&
ue
->
generic_stat
);
pmch_flag
=
is_pmch_subframe
(
frame_rx
,
subframe_rx
,
&
ue
->
frame_parms
)
?
1
:
0
;
// deactivate reception until we scan pdcch
if
(
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
])
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
]
->
active
=
0
;
if
(
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
1
])
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
1
]
->
active
=
0
;
if
(
ue
->
dlsch_SI
[
eNB_id
])
ue
->
dlsch_SI
[
eNB_id
]
->
active
=
0
;
if
(
ue
->
dlsch_p
[
eNB_id
])
ue
->
dlsch_p
[
eNB_id
]
->
active
=
0
;
if
(
ue
->
dlsch_ra
[
eNB_id
])
ue
->
dlsch_ra
[
eNB_id
]
->
active
=
0
;
if
(
subframe_select
(
&
ue
->
frame_parms
,
subframe_rx
)
==
SF_S
)
{
// S-subframe, do first 5 symbols only
l2
=
5
;
}
else
if
(
pmch_flag
==
1
)
{
// do first 2 symbols only
l2
=
1
;
}
else
{
// normal subframe, last symbol to be processed is the first of the second slot
l2
=
(
ue
->
frame_parms
.
symbols_per_tti
/
2
)
-
1
;
}
int
prev_subframe_rx
=
(
subframe_rx
-
1
)
<
0
?
9
:
(
subframe_rx
-
1
);
if
(
subframe_select
(
&
ue
->
frame_parms
,
prev_subframe_rx
)
!=
SF_DL
)
{
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// RX processing of symbols l=0...l2
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
first_ofdm_sym
=
0
;
}
else
{
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// RX processing of symbols l=1...l2 (l=0 is done in last scheduling epoch)
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
first_ofdm_sym
=
1
;
}
slot0
=
(
subframe_rx
<<
1
);
slot1
=
(
subframe_rx
<<
1
)
+
1
;
pilot0
=
0
;
if
(
ue
->
frame_parms
.
Ncp
==
0
)
{
// normal prefix
pilot1
=
4
;
}
else
{
// extended prefix
pilot1
=
3
;
}
//LOG_I(PHY,"Set available channelEst to 0 AbsSubframe %d.%d \n",frame_rx,subframe_rx);
//LOG_I(PHY,"Set available llrs slot1 to 0 AbsSubframe %d.%d \n",frame_rx,subframe_rx);
//LOG_I(PHY,"Set available dci info slot0 to 0 AbsSubframe %d.%d \n",frame_rx,subframe_rx);
proc
->
chan_est_pilot0_slot1_available
=
0
;
proc
->
llr_slot1_available
=
0
;
proc
->
dci_slot0_available
=
0
;
proc
->
first_symbol_available
=
0
;
#ifdef UE_SLOT_PARALLELISATION
//LOG_I(PHY,"fep slot1 thread : instance_cnt %d \n",
// proc->instance_cnt_fep_slot1);
proc
->
instance_cnt_fep_slot1
++
;
if
(
proc
->
instance_cnt_fep_slot1
==
0
)
{
LOG_I
(
PHY
,
"unblock fep slot1 thread blocked on cond_fep_slot1 : instance_cnt_fep_slot1 %d
\n
"
,
proc
->
instance_cnt_fep_slot1
);
if
(
pthread_cond_signal
(
&
proc
->
cond_fep_slot1
)
!=
0
)
{
LOG_E
(
PHY
,
"[SCHED][UE %d] ERROR pthread_cond_signal for UE FEP slot1 thread
\n
"
,
ue
->
Mod_id
);
exit_fun
(
"nothing to add"
);
}
}
else
{
LOG_E
(
PHY
,
"[SCHED][UE %d] UE RX thread busy (IC %d)!!
\n
"
,
ue
->
Mod_id
,
proc
->
instance_cnt_fep_slot1
);
if
(
proc
->
instance_cnt_fep_slot1
>
2
)
exit_fun
(
"instance_cnt_fep_slot1 > 2"
);
}
AssertFatal
(
pthread_cond_signal
(
&
proc
->
cond_fep_slot1
)
==
0
,
""
);
AssertFatal
(
pthread_mutex_unlock
(
&
proc
->
mutex_fep_slot1
)
==
0
,
""
);
#endif
/**** FFT Slot0 + Slot1 ****/
// I- start main thread for FFT/ChanEst symbol: 0/1 --> 7
// 1- perform FFT for pilot ofdm symbols first (ofdmSym7 ofdmSym4 or (ofdmSym6 ofdmSym3))
LOG_I
(
PHY
,
"FFT symbol %d slot %d
\n
"
,
pilot0
,
slot1
);
front_end_fft
(
ue
,
pilot0
,
slot1
,
0
,
0
);
LOG_I
(
PHY
,
"FFT symbol %d slot %d
\n
"
,
pilot1
,
slot0
);
front_end_fft
(
ue
,
pilot1
,
slot0
,
0
,
0
);
LOG_I
(
PHY
,
"ChanEst symbol %d slot %d
\n
"
,
pilot1
,
slot0
);
front_end_chanEst
(
ue
,
pilot1
,
slot0
,
0
);
LOG_I
(
PHY
,
"ChanEst symbol %d slot %d
\n
"
,
pilot0
,
slot1
);
front_end_chanEst
(
ue
,
pilot0
,
slot1
,
0
);
proc
->
chan_est_pilot0_slot1_available
=
1
;
LOG_I
(
PHY
,
"Set available channelEst to 1 AbsSubframe %d.%d
\n
"
,
frame_rx
,
subframe_rx
);
// 2- perform FFT for other ofdm symbols other than pilots
for
(
l
=
first_ofdm_sym
;
l
<=
l2
;
l
++
)
{
if
(
(
l
!=
pilot0
)
&&
(
l
!=
pilot1
))
{
LOG_I
(
PHY
,
"FFT symbol %d slot %d
\n
"
,
l
,
slot0
);
start_meas
(
&
ue
->
ofdm_demod_stats
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_UE_SLOT_FEP
,
VCD_FUNCTION_IN
);
front_end_fft
(
ue
,
l
,
slot0
,
0
,
0
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_UE_SLOT_FEP
,
VCD_FUNCTION_OUT
);
stop_meas
(
&
ue
->
ofdm_demod_stats
);
}
}
// for l=1..l2
// 3- perform Channel Estimation for slot0
for
(
l
=
first_ofdm_sym
;
l
<=
l2
;
l
++
)
{
if
(
(
l
!=
pilot0
)
&&
(
l
!=
pilot1
))
{
LOG_I
(
PHY
,
"ChanEst symbol %d slot %d
\n
"
,
l
,
slot0
);
front_end_chanEst
(
ue
,
l
,
slot0
,
0
);
}
ue_measurement_procedures
(
l
-
1
,
ue
,
proc
,
eNB_id
,(
subframe_rx
<<
1
),
abstraction_flag
,
mode
);
}
// PDCCH decoding
if
(
ue_pdcch_procedures
(
eNB_id
,
ue
,
proc
,
abstraction_flag
)
==
-
1
)
{
LOG_E
(
PHY
,
"[UE %d] Frame %d, subframe %d: Error in pdcch procedures
\n
"
,
ue
->
Mod_id
,
frame_rx
,
subframe_rx
);
return
(
-
1
);
}
LOG_I
(
PHY
,
"num_pdcch_symbols %d
\n
"
,
ue
->
pdcch_vars
[
subframe_rx
&
0x1
][
eNB_id
]
->
num_pdcch_symbols
);
LOG_I
(
PHY
,
"Set available dci slot0 to 1 AbsSubframe %d.%d
\n
"
,
frame_rx
%
1024
,
subframe_rx
);
proc
->
dci_slot0_available
=
1
;
// If this is PMCH, call procedures and return
if
(
pmch_flag
==
1
)
{
ue_pmch_procedures
(
ue
,
proc
,
eNB_id
,
abstraction_flag
);
return
0
;
}
#if 1
// II- start slave thread for FFT/ChanEst
// do first symbol of next downlink subframe for channel estimation
int
next_subframe_rx
=
(
1
+
subframe_rx
)
%
10
;
uint8_t
next_subframe_slot0
=
next_subframe_rx
<<
1
;
// 1- perform FFT for pilot ofdm symbols first (ofdmSym0 next subframe ofdmSym11)
if
(
subframe_select
(
&
ue
->
frame_parms
,
next_subframe_rx
)
!=
SF_UL
)
{
LOG_I
(
PHY
,
"FFT symbol %d slot %d
\n
"
,
pilot0
,
next_subframe_slot0
);
front_end_fft
(
ue
,
pilot0
,
next_subframe_slot0
,
0
,
0
);
}
LOG_I
(
PHY
,
"FFT symbol %d slot %d
\n
"
,
pilot1
,
slot1
);
front_end_fft
(
ue
,
pilot1
,
slot1
,
0
,
0
);
// 2- perform FFT for other ofdm symbols other than pilots
for
(
l
=
1
;
l
<
ue
->
frame_parms
.
symbols_per_tti
>>
1
;
l
++
)
{
if
(
(
l
!=
pilot0
)
&&
(
l
!=
pilot1
))
{
LOG_I
(
PHY
,
"FFT symbol %d slot %d
\n
"
,
l
,
slot1
);
start_meas
(
&
ue
->
ofdm_demod_stats
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_UE_SLOT_FEP
,
VCD_FUNCTION_IN
);
front_end_fft
(
ue
,
l
,
slot1
,
0
,
0
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_UE_SLOT_FEP
,
VCD_FUNCTION_OUT
);
stop_meas
(
&
ue
->
ofdm_demod_stats
);
}
}
// for l=1..l2
// 3- perform Channel Estimation for slot1
for
(
l
=
1
;
l
<
ue
->
frame_parms
.
symbols_per_tti
>>
1
;
l
++
)
{
if
(
l
==
pilot0
)
{
//wait until channel estimation for pilot0/slot1 is available
uint32_t
wait
=
0
;
while
(
proc
->
chan_est_pilot0_slot1_available
==
0
)
{
wait
++
;
}
}
LOG_I
(
PHY
,
"ChanEst symbol %d slot %d
\n
"
,
l
,
slot1
);
front_end_chanEst
(
ue
,
l
,
slot1
,
0
);
ue_measurement_procedures
(
l
-
1
,
ue
,
proc
,
eNB_id
,
1
+
(
subframe_rx
<<
1
),
abstraction_flag
,
mode
);
}
LOG_I
(
PHY
,
"ChanEst symbol %d slot %d
\n
"
,
0
,
next_subframe_slot0
);
front_end_chanEst
(
ue
,
pilot0
,
next_subframe_slot0
,
0
);
if
(
(
subframe_rx
==
0
)
&&
(
ue
->
decode_MIB
==
1
))
{
ue_pbch_procedures
(
eNB_id
,
ue
,
proc
,
abstraction_flag
);
}
#endif
stop_meas
(
&
ue
->
generic_stat
);
//printf("------Front-End PROC [SFN %d]: %5.2f ------\n",subframe_rx,ue->generic_stat.p_time/(cpuf*1000.0));
/**** End Subframe FFT-ChannelEst ****/
/**** Pdsch Procedure Slot0 + Slot1 ****/
// start main thread for Pdsch Procedure (slot0)
// do procedures for C-RNTI
//LOG_I(PHY,"AbsSubframe %d.%d Pdsch Procedure (slot0)\n",frame_rx%1024,subframe_rx);
//LOG_I(PHY,"AbsSubframe %d.%d Pdsch Procedure PDSCH Active %d \n",frame_rx%1024,subframe_rx, ue->dlsch[subframe_rx&0x1][0][0]->active);
start_meas
(
&
ue
->
generic_stat
);
if
(
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
]
->
active
==
1
)
{
LOG_I
(
PHY
,
"AbsSubframe %d.%d Pdsch Procedure PDSCH
\n
"
,
frame_rx
%
1024
,
subframe_rx
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC
,
VCD_FUNCTION_IN
);
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
PDSCH
,
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
],
NULL
,
ue
->
pdcch_vars
[
subframe_rx
&
0x1
][
eNB_id
]
->
num_pdcch_symbols
,
ue
->
frame_parms
.
symbols_per_tti
>>
1
,
abstraction_flag
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC
,
VCD_FUNCTION_OUT
);
}
// do procedures for SI-RNTI
if
((
ue
->
dlsch_SI
[
eNB_id
])
&&
(
ue
->
dlsch_SI
[
eNB_id
]
->
active
==
1
))
{
LOG_I
(
PHY
,
"AbsSubframe %d.%d Pdsch Procedure SI-PDSCH
\n
"
,
frame_rx
%
1024
,
subframe_rx
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC_SI
,
VCD_FUNCTION_IN
);
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
SI_PDSCH
,
ue
->
dlsch_SI
[
eNB_id
],
NULL
,
ue
->
pdcch_vars
[
subframe_rx
&
0x1
][
eNB_id
]
->
num_pdcch_symbols
,
ue
->
frame_parms
.
symbols_per_tti
>>
1
,
abstraction_flag
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC_SI
,
VCD_FUNCTION_OUT
);
}
// do procedures for SI-RNTI
if
((
ue
->
dlsch_p
[
eNB_id
])
&&
(
ue
->
dlsch_p
[
eNB_id
]
->
active
==
1
))
{
LOG_I
(
PHY
,
"AbsSubframe %d.%d Pdsch Procedure P-PDSCH
\n
"
,
frame_rx
%
1024
,
subframe_rx
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC_P
,
VCD_FUNCTION_IN
);
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
P_PDSCH
,
ue
->
dlsch_p
[
eNB_id
],
NULL
,
ue
->
pdcch_vars
[
subframe_rx
&
0x1
][
eNB_id
]
->
num_pdcch_symbols
,
ue
->
frame_parms
.
symbols_per_tti
>>
1
,
abstraction_flag
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC_P
,
VCD_FUNCTION_OUT
);
}
// do procedures for RA-RNTI
if
((
ue
->
dlsch_ra
[
eNB_id
])
&&
(
ue
->
dlsch_ra
[
eNB_id
]
->
active
==
1
))
{
LOG_I
(
PHY
,
"AbsSubframe %d.%d Pdsch Procedure RA-PDSCH
\n
"
,
frame_rx
%
1024
,
subframe_rx
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC_RA
,
VCD_FUNCTION_IN
);
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
RA_PDSCH
,
ue
->
dlsch_ra
[
eNB_id
],
NULL
,
ue
->
pdcch_vars
[
subframe_rx
&
0x1
][
eNB_id
]
->
num_pdcch_symbols
,
ue
->
frame_parms
.
symbols_per_tti
>>
1
,
abstraction_flag
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC_RA
,
VCD_FUNCTION_OUT
);
}
stop_meas
(
&
ue
->
generic_stat
);
//printf("------LLR-Slot0 [SFN %d]: %5.2f ------\n",subframe_rx,ue->generic_stat.p_time/(cpuf*1000.0));
#if 1
// start slave thread for Pdsch Procedure (slot1)
// do procedures for C-RNTI
if
(
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
]
->
active
==
1
)
{
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC
,
VCD_FUNCTION_IN
);
start_meas
(
&
ue
->
pdsch_procedures_stat
);
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
PDSCH
,
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
],
NULL
,
1
+
(
ue
->
frame_parms
.
symbols_per_tti
>>
1
),
ue
->
frame_parms
.
symbols_per_tti
-
1
,
abstraction_flag
);
stop_meas
(
&
ue
->
pdsch_procedures_stat
);
}
// do procedures for SI-RNTI
if
((
ue
->
dlsch_SI
[
eNB_id
])
&&
(
ue
->
dlsch_SI
[
eNB_id
]
->
active
==
1
))
{
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
SI_PDSCH
,
ue
->
dlsch_SI
[
eNB_id
],
NULL
,
1
+
(
ue
->
frame_parms
.
symbols_per_tti
>>
1
),
ue
->
frame_parms
.
symbols_per_tti
-
1
,
abstraction_flag
);
}
// do procedures for P-RNTI
if
((
ue
->
dlsch_p
[
eNB_id
])
&&
(
ue
->
dlsch_p
[
eNB_id
]
->
active
==
1
))
{
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
P_PDSCH
,
ue
->
dlsch_p
[
eNB_id
],
NULL
,
1
+
(
ue
->
frame_parms
.
symbols_per_tti
>>
1
),
ue
->
frame_parms
.
symbols_per_tti
-
1
,
abstraction_flag
);
}
// do procedures for RA-RNTI
if
((
ue
->
dlsch_ra
[
eNB_id
])
&&
(
ue
->
dlsch_ra
[
eNB_id
]
->
active
==
1
))
{
ue_pdsch_procedures
(
ue
,
proc
,
eNB_id
,
RA_PDSCH
,
ue
->
dlsch_ra
[
eNB_id
],
NULL
,
1
+
(
ue
->
frame_parms
.
symbols_per_tti
>>
1
),
ue
->
frame_parms
.
symbols_per_tti
-
1
,
abstraction_flag
);
}
proc
->
llr_slot1_available
=
1
;
#endif
start_meas
(
&
ue
->
generic_stat
);
// wait until llr on slot1 are available
uint32_t
wait
=
0
;
while
(
proc
->
llr_slot1_available
==
0
)
{
//wait until channel estimation for pilot0/slot1 is available
usleep
(
1
);
wait
++
;
}
stop_meas
(
&
ue
->
generic_stat
);
//printf("------ Waiting for LLR-Slot1 [SFN %d]: %5.2f ------\n",subframe_rx,ue->generic_stat.p_time/(cpuf*1000.0));
LOG_I
(
PHY
,
"==> Start Turbo Decoder wait %d
\n
"
,
wait
);
// Start Turbo decoder
if
(
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
]
->
active
==
1
)
{
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC
,
VCD_FUNCTION_IN
);
start_meas
(
&
ue
->
dlsch_procedures_stat
);
ue_dlsch_procedures
(
ue
,
proc
,
eNB_id
,
PDSCH
,
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
0
],
ue
->
dlsch
[
subframe_rx
&
0x1
][
eNB_id
][
1
],
&
ue
->
dlsch_errors
[
eNB_id
],
mode
,
abstraction_flag
);
stop_meas
(
&
ue
->
dlsch_procedures_stat
);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PDSCH_PROC
,
VCD_FUNCTION_OUT
);
}
// do procedures for SI-RNTI
if
((
ue
->
dlsch_SI
[
eNB_id
])
&&
(
ue
->
dlsch_SI
[
eNB_id
]
->
active
==
1
))
{
ue_dlsch_procedures
(
ue
,
proc
,
eNB_id
,
SI_PDSCH
,
ue
->
dlsch_SI
[
eNB_id
],
NULL
,
&
ue
->
dlsch_SI_errors
[
eNB_id
],
mode
,
abstraction_flag
);
ue
->
dlsch_SI
[
eNB_id
]
->
active
=
0
;
}
// do procedures for P-RNTI
if
((
ue
->
dlsch_p
[
eNB_id
])
&&
(
ue
->
dlsch_p
[
eNB_id
]
->
active
==
1
))
{
ue_dlsch_procedures
(
ue
,
proc
,
eNB_id
,
P_PDSCH
,
ue
->
dlsch_p
[
eNB_id
],
NULL
,
&
ue
->
dlsch_p_errors
[
eNB_id
],
mode
,
abstraction_flag
);
ue
->
dlsch_p
[
eNB_id
]
->
active
=
0
;
}
// do procedures for RA-RNTI
if
((
ue
->
dlsch_ra
[
eNB_id
])
&&
(
ue
->
dlsch_ra
[
eNB_id
]
->
active
==
1
))
{
ue_dlsch_procedures
(
ue
,
proc
,
eNB_id
,
RA_PDSCH
,
ue
->
dlsch_ra
[
eNB_id
],
NULL
,
&
ue
->
dlsch_ra_errors
[
eNB_id
],
mode
,
abstraction_flag
);
ue
->
dlsch_ra
[
eNB_id
]
->
active
=
0
;
}
//printf("------ Turbo Decoding [SFN %d]: %5.2f ------\n",subframe_rx,ue->dlsch_procedures_stat.p_time/(cpuf*1000.0));
/**** End Pdsch processing for this subframe ****/
if
(
subframe_rx
==
9
)
{
if
(
frame_rx
%
10
==
0
)
{
if
((
ue
->
dlsch_received
[
eNB_id
]
-
ue
->
dlsch_received_last
[
eNB_id
])
!=
0
)
ue
->
dlsch_fer
[
eNB_id
]
=
(
100
*
(
ue
->
dlsch_errors
[
eNB_id
]
-
ue
->
dlsch_errors_last
[
eNB_id
]))
/
(
ue
->
dlsch_received
[
eNB_id
]
-
ue
->
dlsch_received_last
[
eNB_id
]);
ue
->
dlsch_errors_last
[
eNB_id
]
=
ue
->
dlsch_errors
[
eNB_id
];
ue
->
dlsch_received_last
[
eNB_id
]
=
ue
->
dlsch_received
[
eNB_id
];
}
ue
->
bitrate
[
eNB_id
]
=
(
ue
->
total_TBS
[
eNB_id
]
-
ue
->
total_TBS_last
[
eNB_id
])
*
100
;
ue
->
total_TBS_last
[
eNB_id
]
=
ue
->
total_TBS
[
eNB_id
];
LOG_D
(
PHY
,
"[UE %d] Calculating bitrate Frame %d: total_TBS = %d, total_TBS_last = %d, bitrate %f kbits
\n
"
,
ue
->
Mod_id
,
frame_rx
,
ue
->
total_TBS
[
eNB_id
],
ue
->
total_TBS_last
[
eNB_id
],(
float
)
ue
->
bitrate
[
eNB_id
]
/
1000
.
0
);
#if UE_AUTOTEST_TRACE
if
((
frame_rx
%
100
==
0
))
{
LOG_I
(
PHY
,
"[UE %d] AUTOTEST Metric : UE_DLSCH_BITRATE = %5.2f kbps (frame = %d)
\n
"
,
ue
->
Mod_id
,
(
float
)
ue
->
bitrate
[
eNB_id
]
/
1000
.
0
,
frame_rx
);
}
#endif
}
//printf("after tubo until end of Rx %5.2f \n",ue->generic_stat.p_time/(cpuf*1000.0));
#ifdef EMOS
phy_procedures_emos_UE_RX
(
ue
,
slot
,
eNB_id
);
#endif
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME
(
VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_UE_RX
,
VCD_FUNCTION_OUT
);
stop_meas
(
&
ue
->
phy_proc_rx
[
subframe_rx
&
0x1
]);
//printf("------FULL RX PROC [SFN %d]: %5.2f ------\n",subframe_rx,ue->phy_proc_rx[subframe_rx&0x1].p_time/(cpuf*1000.0));
LOG_I
(
PHY
,
" ****** end RX-Chain for AbsSubframe %d.%d ******
\n
"
,
frame_rx
%
1024
,
subframe_rx
);
return
(
0
);
}
#if defined(Rel10) || defined(Rel14)
#if defined(Rel10) || defined(Rel14)
int
phy_procedures_RN_UE_RX
(
uint8_t
slot_rx
,
uint8_t
next_slot
,
relaying_type_t
r_type
)
int
phy_procedures_RN_UE_RX
(
uint8_t
slot_rx
,
uint8_t
next_slot
,
relaying_type_t
r_type
)
...
...
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