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promise
OpenXG-RAN
Commits
b44e15fd
Commit
b44e15fd
authored
Jan 17, 2019
by
yilmazt
Browse files
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Plain Diff
More warning removals but nr_dlschsim still not working
parent
86531d2e
Changes
15
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Showing
15 changed files
with
616 additions
and
617 deletions
+616
-617
openair1/PHY/CODING/coding_defs.h
openair1/PHY/CODING/coding_defs.h
+2
-2
openair1/PHY/CODING/nrLDPC_encoder/ldpc_encoder2.c
openair1/PHY/CODING/nrLDPC_encoder/ldpc_encoder2.c
+3
-3
openair1/PHY/CODING/nrLDPC_encoder/ldpc_generate_coefficient.c
...ir1/PHY/CODING/nrLDPC_encoder/ldpc_generate_coefficient.c
+3
-0
openair1/PHY/CODING/nrPolar_tools/nr_polar_decoder.c
openair1/PHY/CODING/nrPolar_tools/nr_polar_decoder.c
+1
-1
openair1/PHY/CODING/nrPolar_tools/nr_polar_encoder.c
openair1/PHY/CODING/nrPolar_tools/nr_polar_encoder.c
+1
-1
openair1/PHY/CODING/nr_rate_matching.c
openair1/PHY/CODING/nr_rate_matching.c
+6
-4
openair1/PHY/INIT/nr_init.c
openair1/PHY/INIT/nr_init.c
+2
-2
openair1/PHY/NR_TRANSPORT/nr_dci.c
openair1/PHY/NR_TRANSPORT/nr_dci.c
+1
-1
openair1/PHY/NR_TRANSPORT/nr_dlsch_coding.c
openair1/PHY/NR_TRANSPORT/nr_dlsch_coding.c
+2
-1
openair1/PHY/NR_TRANSPORT/nr_pbch.c
openair1/PHY/NR_TRANSPORT/nr_pbch.c
+2
-2
openair1/PHY/NR_TRANSPORT/nr_sss.c
openair1/PHY/NR_TRANSPORT/nr_sss.c
+1
-1
openair1/PHY/NR_UE_TRANSPORT/nr_dlsch_decoding.c
openair1/PHY/NR_UE_TRANSPORT/nr_dlsch_decoding.c
+2
-1
openair1/PHY/NR_UE_TRANSPORT/nr_prach.c
openair1/PHY/NR_UE_TRANSPORT/nr_prach.c
+3
-2
openair1/PHY/NR_UE_TRANSPORT/pucch_nr.c
openair1/PHY/NR_UE_TRANSPORT/pucch_nr.c
+16
-15
openair1/SIMULATION/NR_PHY/dlschsim.c
openair1/SIMULATION/NR_PHY/dlschsim.c
+571
-581
No files found.
openair1/PHY/CODING/coding_defs.h
View file @
b44e15fd
...
...
@@ -387,6 +387,8 @@ unsigned int crc12 (unsigned char * inptr, int bitlen);
@param inPtr Pointer to input byte stream
@param bitlen length of inputs in bits*/
unsigned
int
crc8
(
unsigned
char
*
inptr
,
int
bitlen
);
int
check_crc
(
uint8_t
*
decoded_bytes
,
uint32_t
n
,
uint32_t
F
,
uint8_t
crc_type
);
/*!\fn void phy_viterbi_dot11_sse2(int8_t *y, uint8_t *decoded_bytes, uint16_t n,int offset,int traceback)
\brief This routine performs a SIMD optmized Viterbi decoder for the 802.11 64-state convolutional code. It can be
...
...
@@ -441,8 +443,6 @@ int32_t rate_matching_lte(uint32_t N_coded,
uint8_t
*
inPtr
,
uint32_t
off
);
void
crcTableInit
(
void
);
unsigned
int
crcbit
(
unsigned
char
*
inputptr
,
int
octetlen
,
unsigned
int
poly
);
int16_t
reverseBits
(
int32_t
,
int32_t
);
...
...
openair1/PHY/CODING/nrLDPC_encoder/ldpc_encoder2.c
View file @
b44e15fd
...
...
@@ -201,7 +201,7 @@ void encode_parity_check_part_optim(uint8_t *c,uint8_t *d, short BG,short Zc,sho
int
ldpc_encoder_optim
(
unsigned
char
*
test_input
,
unsigned
char
*
channel_input
,
short
block_length
,
short
BG
,
time_stats_t
*
tinput
,
time_stats_t
*
tprep
,
time_stats_t
*
tparity
,
time_stats_t
*
toutput
)
{
short
Zc
,
Kb
,
nrows
,
ncols
;
short
Zc
,
Kb
=
0
,
nrows
=
0
,
ncols
=
0
;
int
i
,
i1
;
int
no_punctured_columns
,
removed_bit
;
...
...
@@ -320,7 +320,7 @@ int ldpc_encoder_optim(unsigned char *test_input,unsigned char *channel_input,sh
int
ldpc_encoder_optim_8seg
(
unsigned
char
**
test_input
,
unsigned
char
**
channel_input
,
short
block_length
,
short
BG
,
int
n_segments
,
time_stats_t
*
tinput
,
time_stats_t
*
tprep
,
time_stats_t
*
tparity
,
time_stats_t
*
toutput
)
{
short
Zc
,
Kb
,
nrows
,
ncols
;
short
Zc
,
Kb
=
0
,
nrows
=
0
,
ncols
=
0
;
int
i
,
i1
,
j
;
int
no_punctured_columns
,
removed_bit
;
//Table of possible lifting sizes
...
...
@@ -520,7 +520,7 @@ int ldpc_encoder_optim_8seg(unsigned char **test_input,unsigned char **channel_i
int
ldpc_encoder_optim_8seg_multi
(
unsigned
char
**
test_input
,
unsigned
char
**
channel_input
,
short
block_length
,
short
BG
,
int
n_segments
,
unsigned
int
macro_num
,
time_stats_t
*
tinput
,
time_stats_t
*
tprep
,
time_stats_t
*
tparity
,
time_stats_t
*
toutput
)
{
short
Zc
,
Kb
,
nrows
,
ncols
;
short
Zc
,
Kb
=
0
,
nrows
=
0
,
ncols
=
0
;
int
i
,
i1
,
j
;
int
no_punctured_columns
,
removed_bit
;
//Table of possible lifting sizes
...
...
openair1/PHY/CODING/nrLDPC_encoder/ldpc_generate_coefficient.c
View file @
b44e15fd
...
...
@@ -444,6 +444,9 @@ int ldpc_encoder_orig(unsigned char *test_input,unsigned char *channel_input,sho
no_shift_values
=
(
short
*
)
no_shift_values_BG2
;
pointer_shift_values
=
(
short
*
)
pointer_shift_values_BG2
;
}
else
{
AssertFatal
(
0
,
"BG %d is not supported yet
\n
"
,
BG
);
}
no_punctured_columns
=
(
int
)((
nrows
-
2
)
*
Zc
+
block_length
-
block_length
*
3
)
/
Zc
;
removed_bit
=
(
nrows
-
no_punctured_columns
-
2
)
*
Zc
+
block_length
-
(
block_length
*
3
);
...
...
openair1/PHY/CODING/nrPolar_tools/nr_polar_decoder.c
View file @
b44e15fd
...
...
@@ -1119,7 +1119,7 @@ uint32_t polar_decoder_int16(int16_t *input,
int
len
=
polarParams
->
payloadBits
;
int
len_mod64
=
len
&
63
;
//
int len_mod64=len&63;
int
crclen
=
polarParams
->
crcParityBits
;
uint64_t
rxcrc
=
B
[
0
]
&
((
1
<<
crclen
)
-
1
);
uint32_t
crc
;
...
...
openair1/PHY/CODING/nrPolar_tools/nr_polar_encoder.c
View file @
b44e15fd
...
...
@@ -402,7 +402,7 @@ void polar_encoder_fast(uint64_t *A,
AssertFatal
(
bitlen
<
129
,
"support for payloads <= 128 bits
\n
"
);
AssertFatal
(
polarParams
->
crcParityBits
==
24
,
"support for 24-bit crc only for now
\n
"
);
int
bitlen0
=
bitlen
;
//
int bitlen0=bitlen;
uint64_t
tcrc
=
0
;
...
...
openair1/PHY/CODING/nr_rate_matching.c
View file @
b44e15fd
...
...
@@ -78,7 +78,7 @@ uint32_t nr_rate_matching_ldpc(uint8_t Ilbrm,
{
uint8_t
Cprime
;
uint32_t
Ncb
,
E
,
ind
,
k
,
Nref
,
N
;
uint8_t
*
e2
;
//
uint8_t *e2;
AssertFatal
(
Nl
>
0
,
"Nl is 0
\n
"
);
AssertFatal
(
Qm
>
0
,
"Qm is 0
\n
"
);
...
...
@@ -110,7 +110,7 @@ uint32_t nr_rate_matching_ldpc(uint8_t Ilbrm,
printf
(
"nr_rate_matching: E %d, k0 %d Cprime %d modcprime %d
\n
"
,
E
,
ind
,
Cprime
,((
G
/
(
Nl
*
Qm
))
%
Cprime
));
#endif
e2
=
e
;
//
e2 = e;
k
=
0
;
...
...
@@ -120,7 +120,8 @@ uint32_t nr_rate_matching_ldpc(uint8_t Ilbrm,
printf
(
"RM_TX k%d Ind: %d (%d)
\n
"
,
k
,
ind
,
w
[
ind
]);
#endif
if
(
w
[
ind
]
!=
NR_NULL
)
e2
[
k
++
]
=
w
[
ind
];
//if (w[ind] != NR_NULL) e2[k++]=w[ind];
if
(
w
[
ind
]
!=
NR_NULL
)
e
[
k
++
]
=
w
[
ind
];
}
while
(
k
<
E
)
{
...
...
@@ -130,7 +131,8 @@ uint32_t nr_rate_matching_ldpc(uint8_t Ilbrm,
printf
(
"RM_TX k%d Ind: %d (%d)
\n
"
,
k
,
ind
,
w
[
ind
]);
#endif
if
(
w
[
ind
]
!=
NR_NULL
)
e2
[
k
++
]
=
w
[
ind
];
//if (w[ind] != NR_NULL) e2[k++]=w[ind];
if
(
w
[
ind
]
!=
NR_NULL
)
e
[
k
++
]
=
w
[
ind
];
}
}
...
...
openair1/PHY/INIT/nr_init.c
View file @
b44e15fd
...
...
@@ -314,8 +314,8 @@ void phy_config_request(PHY_Config_t *phy_config) {
void
phy_free_nr_gNB
(
PHY_VARS_gNB
*
gNB
)
{
//
NR_DL_FRAME_PARMS* const fp = &gNB->frame_parms;
nfapi_nr_config_request_t
*
cfg
=
&
gNB
->
gNB_config
;
//
NR_DL_FRAME_PARMS* const fp = &gNB->frame_parms;
//
nfapi_nr_config_request_t *cfg = &gNB->gNB_config;
NR_gNB_COMMON
*
const
common_vars
=
&
gNB
->
common_vars
;
LTE_eNB_PUSCH
**
const
pusch_vars
=
gNB
->
pusch_vars
;
LTE_eNB_SRS
*
const
srs_vars
=
gNB
->
srs_vars
;
...
...
openair1/PHY/NR_TRANSPORT/nr_dci.c
View file @
b44e15fd
...
...
@@ -170,7 +170,7 @@ uint8_t nr_generate_dci_top(NR_gNB_PDCCH pdcch_vars,
int16_t
mod_dmrs
[
NR_MAX_CSET_DURATION
][
NR_MAX_PDCCH_DMRS_LENGTH
>>
1
];
// 3 for the max coreset duration
uint8_t
idx
=
0
;
uint16_t
a
;
//
uint16_t a;
int
k
,
l
,
k_prime
,
dci_idx
,
dmrs_idx
;
nr_cce_t
cce
;
nr_reg_t
reg
;
...
...
openair1/PHY/NR_TRANSPORT/nr_dlsch_coding.c
View file @
b44e15fd
...
...
@@ -379,7 +379,8 @@ int nr_dlsch_encoding(unsigned char *a,
}
printf("\n");*/
ldpc_encoder_optim_8seg
(
dlsch
->
harq_processes
[
harq_pid
]
->
c
,
d_tmp
,
Kr
,
BG
,
dlsch
->
harq_processes
[
harq_pid
]
->
C
,
NULL
,
NULL
,
NULL
,
NULL
);
//ldpc_encoder_optim_8seg(dlsch->harq_processes[harq_pid]->c,d_tmp,Kr,BG,dlsch->harq_processes[harq_pid]->C,NULL,NULL,NULL,NULL);
ldpc_encoder_optim_8seg
(
dlsch
->
harq_processes
[
harq_pid
]
->
c
,
dlsch
->
harq_processes
[
harq_pid
]
->
d
,
Kr
,
BG
,
dlsch
->
harq_processes
[
harq_pid
]
->
C
,
NULL
,
NULL
,
NULL
,
NULL
);
//stop_meas(te_stats);
//printf("end ldpc encoder -- output\n");
...
...
openair1/PHY/NR_TRANSPORT/nr_pbch.c
View file @
b44e15fd
...
...
@@ -53,7 +53,7 @@ int nr_generate_pbch_dmrs(uint32_t *gold_pbch_dmrs,
NR_DL_FRAME_PARMS
*
frame_parms
)
{
int
k
,
l
;
int16_t
a
;
//
int16_t a;
int16_t
mod_dmrs
[
NR_PBCH_DMRS_LENGTH
<<
1
];
uint8_t
idx
=
0
;
uint8_t
nushift
=
config
->
sch_config
.
physical_cell_id
.
value
&
3
;
...
...
@@ -240,7 +240,7 @@ int nr_generate_pbch(NR_gNB_PBCH *pbch,
{
int
k
,
l
,
m
;
int16_t
a
;
//
int16_t a;
int16_t
mod_pbch_e
[
NR_POLAR_PBCH_E
];
uint8_t
idx
=
0
;
uint16_t
M
;
...
...
openair1/PHY/NR_TRANSPORT/nr_sss.c
View file @
b44e15fd
...
...
@@ -33,7 +33,7 @@ int nr_generate_sss( int16_t *d_sss,
int
i
,
k
,
l
;
int
m0
,
m1
;
int
Nid
,
Nid1
,
Nid2
;
int16_t
a
;
//
int16_t a;
int16_t
x0
[
NR_SSS_LENGTH
],
x1
[
NR_SSS_LENGTH
];
const
int
x0_initial
[
7
]
=
{
1
,
0
,
0
,
0
,
0
,
0
,
0
};
const
int
x1_initial
[
7
]
=
{
1
,
0
,
0
,
0
,
0
,
0
,
0
};
...
...
openair1/PHY/NR_UE_TRANSPORT/nr_dlsch_decoding.c
View file @
b44e15fd
...
...
@@ -35,6 +35,7 @@
#include "PHY/CODING/coding_extern.h"
#include "PHY/CODING/coding_defs.h"
#include "PHY/NR_TRANSPORT/nr_transport_common_proto.h"
#include "PHY/NR_UE_TRANSPORT/nr_transport_proto_ue.h"
#include "PHY/NR_TRANSPORT/nr_dlsch.h"
#include "SCHED_NR_UE/defs.h"
#include "SIMULATION/TOOLS/sim.h"
...
...
@@ -190,7 +191,7 @@ void nr_dlsch_unscrambling(int16_t* llr,
}
uint32_t
nr_dlsch_decoding
(
PHY_VARS_NR_UE
*
phy_vars_ue
,
uint32_t
nr_dlsch_decoding
(
PHY_VARS_NR_UE
*
phy_vars_ue
,
short
*
dlsch_llr
,
NR_DL_FRAME_PARMS
*
frame_parms
,
NR_UE_DLSCH_t
*
dlsch
,
...
...
openair1/PHY/NR_UE_TRANSPORT/nr_prach.c
View file @
b44e15fd
...
...
@@ -40,6 +40,7 @@
//#include "PHY/defs_nr_common.h"
#include "PHY/defs_nr_UE.h"
#include "PHY/NR_UE_TRANSPORT/nr_prach.h"
#include "PHY/NR_UE_TRANSPORT/nr_transport_proto_ue.h"
//#include "PHY/extern.h"
//#include "LAYER2/MAC/extern.h"
//#include "PHY/NR_UE_TRANSPORT/pucch_nr.h"
...
...
@@ -582,7 +583,7 @@ int32_t generate_nr_prach( PHY_VARS_NR_UE *ue, uint8_t eNB_id, uint8_t subframe,
int16_t
amp
=
ue
->
prach_vars
[
eNB_id
]
->
amp
;
int16_t
Ncp
;
uint8_t
n_ra_prb
;
uint16_t
NCS
;
uint16_t
NCS
=
0
;
uint16_t
*
prach_root_sequence_map
;
uint16_t
preamble_offset
,
preamble_shift
;
uint16_t
preamble_index0
,
n_shift_ra
,
n_shift_ra_bar
;
...
...
@@ -599,7 +600,7 @@ int32_t generate_nr_prach( PHY_VARS_NR_UE *ue, uint8_t eNB_id, uint8_t subframe,
int32_t
Xu_re
,
Xu_im
;
uint16_t
offset
,
offset2
;
int
prach_start
;
int
i
,
prach_len
;
int
i
,
prach_len
=
0
;
uint16_t
first_nonzero_root_idx
=
0
;
#if defined(EXMIMO) || defined(OAI_USRP)
...
...
openair1/PHY/NR_UE_TRANSPORT/pucch_nr.c
View file @
b44e15fd
...
...
@@ -36,6 +36,7 @@
//#include "PHY/extern.h"
//#include "LAYER2/MAC/extern.h"
#include "PHY/NR_UE_TRANSPORT/pucch_nr.h"
#include "PHY/NR_UE_TRANSPORT/nr_transport_proto_ue.h"
#include "common/utils/LOG/log.h"
#include "common/utils/LOG/vcd_signal_dumper.h"
...
...
@@ -129,7 +130,7 @@ double nr_cyclic_shift_hopping(PHY_VARS_NR_UE *ue,
*/
// alpha_init initialized to 2*PI/12=0.5235987756
double
alpha
=
0
.
5235987756
;
uint
16
_t
c_init
=
ue
->
pucch_config_common_nr
->
hoppingId
;
// we initialize c_init again to calculate n_cs
uint
32
_t
c_init
=
ue
->
pucch_config_common_nr
->
hoppingId
;
// we initialize c_init again to calculate n_cs
#ifdef DEBUG_NR_PUCCH_TX
// initialization to be removed
...
...
@@ -236,8 +237,8 @@ void nr_generate_pucch0(PHY_VARS_NR_UE *ue,
/*
* Implementing TS 38.211 Subclause 6.3.2.3.2 Mapping to physical resources FIXME!
*/
int32_t
*
txptr
;
uint32_t
re_offset
;
//
int32_t *txptr;
uint32_t
re_offset
=
0
;
for
(
int
l
=
0
;
l
<
nrofSymbols
;
l
++
)
{
if
((
startingPRB
<
(
frame_parms
->
N_RB_DL
>>
1
))
&&
((
frame_parms
->
N_RB_DL
&
1
)
==
0
))
{
// if number RBs in bandwidth is even and current PRB is lower band
re_offset
=
((
l
+
startingSymbolIndex
)
*
frame_parms
->
ofdm_symbol_size
)
+
(
12
*
startingPRB
)
+
frame_parms
->
first_carrier_offset
;
...
...
@@ -254,7 +255,7 @@ void nr_generate_pucch0(PHY_VARS_NR_UE *ue,
if
((
startingPRB
==
(
frame_parms
->
N_RB_DL
>>
1
))
&&
((
frame_parms
->
N_RB_DL
&
1
)
==
1
))
{
// if number RBs in bandwidth is odd and current PRB contains DC
re_offset
=
((
l
+
startingSymbolIndex
)
*
frame_parms
->
ofdm_symbol_size
)
+
(
12
*
startingPRB
)
+
frame_parms
->
first_carrier_offset
;
}
txptr
=
&
txdataF
[
0
][
re_offset
];
//
txptr = &txdataF[0][re_offset];
for
(
int
n
=
0
;
n
<
12
;
n
++
){
if
((
n
==
6
)
&&
(
startingPRB
==
(
frame_parms
->
N_RB_DL
>>
1
))
&&
((
frame_parms
->
N_RB_DL
&
1
)
==
1
))
{
// if number RBs in bandwidth is odd and current PRB contains DC, we need to recalculate the offset when n=6 (for second half PRB)
...
...
@@ -299,7 +300,7 @@ void nr_generate_pucch1(PHY_VARS_NR_UE *ue,
*
*/
// complex-valued symbol d_re, d_im containing complex-valued symbol d(0):
int16_t
d_re
,
d_im
;
int16_t
d_re
=
0
,
d_im
=
0
;
if
(
nr_bit
==
1
)
{
// using BPSK if M_bit=1 according to TC 38.211 Subclause 5.1.2
d_re
=
(
payload
&
1
)
==
0
?
(
int16_t
)(((
int32_t
)
amp
*
ONE_OVER_SQRT2
)
>>
15
)
:
-
(
int16_t
)(((
int32_t
)
amp
*
ONE_OVER_SQRT2
)
>>
15
);
d_im
=
(
payload
&
1
)
==
0
?
(
int16_t
)(((
int32_t
)
amp
*
ONE_OVER_SQRT2
)
>>
15
)
:
-
(
int16_t
)(((
int32_t
)
amp
*
ONE_OVER_SQRT2
)
>>
15
);
...
...
@@ -371,8 +372,8 @@ void nr_generate_pucch1(PHY_VARS_NR_UE *ue,
/*
* Implementing TS 38.211 Subclause 6.3.2.4.2 Mapping to physical resources
*/
int32_t
*
txptr
;
uint32_t
re_offset
;
//
int32_t *txptr;
uint32_t
re_offset
=
0
;
int
i
=
0
;
#define MAX_SIZE_Z 168 // this value has to be calculated from mprime*12*table_6_3_2_4_1_1_N_SF_mprime_PUCCH_1_noHop[pucch_symbol_length]+m*12+n
int16_t
z_re
[
MAX_SIZE_Z
],
z_im
[
MAX_SIZE_Z
];
...
...
@@ -552,7 +553,7 @@ void nr_generate_pucch1(PHY_VARS_NR_UE *ue,
}
txptr
=
&
txdataF
[
0
][
re_offset
];
//
txptr = &txdataF[0][re_offset];
for
(
int
n
=
0
;
n
<
12
;
n
++
){
if
((
n
==
6
)
&&
(
startingPRB
==
(
frame_parms
->
N_RB_DL
>>
1
))
&&
((
frame_parms
->
N_RB_DL
&
1
)
==
1
))
{
// if number RBs in bandwidth is odd and current PRB contains DC, we need to recalculate the offset when n=6 (for second half PRB)
...
...
@@ -904,7 +905,7 @@ void nr_uci_encoding(uint64_t payload,
// L is the CRC size
uint8_t
L
;
// E is the rate matching output sequence length as given in TS 38.212 subclause 6.3.1.4.1
uint16_t
E
,
E_init
;
uint16_t
E
=
0
,
E_init
;
if
(
fmt
==
pucch_format2_nr
)
E
=
16
*
nrofSymbols
*
nrofPRB
;
if
(
fmt
==
pucch_format3_nr
){
E_init
=
(
is_pi_over_2_bpsk_enabled
==
0
)
?
24
:
12
;
...
...
@@ -1061,8 +1062,8 @@ void nr_generate_pucch2(PHY_VARS_NR_UE *ue,
/*
* Implementing TS 38.211 Subclause 6.3.2.5.3 Mapping to physical resources
*/
int32_t
*
txptr
;
uint32_t
re_offset
;
//
int32_t *txptr;
uint32_t
re_offset
=
0
;
uint32_t
x1
,
x2
,
s
=
0
;
int
i
=
0
;
int
m
=
0
;
...
...
@@ -1086,7 +1087,7 @@ void nr_generate_pucch2(PHY_VARS_NR_UE *ue,
if
(((
rb
+
startingPRB
)
==
(
frame_parms
->
N_RB_DL
>>
1
))
&&
((
frame_parms
->
N_RB_DL
&
1
)
==
1
))
{
// if number RBs in bandwidth is odd and current PRB contains DC
re_offset
=
((
l
+
startingSymbolIndex
)
*
frame_parms
->
ofdm_symbol_size
)
+
(
12
*
(
rb
+
startingPRB
))
+
frame_parms
->
first_carrier_offset
;
}
txptr
=
&
txdataF
[
0
][
re_offset
];
//
txptr = &txdataF[0][re_offset];
int
k
=
0
;
int
kk
=
0
;
for
(
int
n
=
0
;
n
<
12
;
n
++
){
...
...
@@ -1408,8 +1409,8 @@ void nr_generate_pucch3_4(PHY_VARS_NR_UE *ue,
//int16_t *r_u_v_alpha_delta_im = malloc(sizeof(int16_t)*12*nrofPRB);
// Next we proceed to mapping to physical resources according to TS 38.211, subclause 6.3.2.6.5 dor PUCCH formats 3 and 4 and subclause 6.4.1.3.3.2 for DM-RS
int32_t
*
txptr
;
uint32_t
re_offset
;
//
int32_t *txptr;
uint32_t
re_offset
=
0
;
//uint32_t x1, x2, s=0;
// intraSlotFrequencyHopping
// uint8_t intraSlotFrequencyHopping = 0;
...
...
@@ -1513,7 +1514,7 @@ void nr_generate_pucch3_4(PHY_VARS_NR_UE *ue,
#ifdef DEBUG_NR_PUCCH_TX
printf
(
"re_offset=%d,(rb+startingPRB)=%d
\n
"
,
re_offset
,(
rb
+
startingPRB
));
#endif
txptr
=
&
txdataF
[
0
][
re_offset
];
//
txptr = &txdataF[0][re_offset];
for
(
int
n
=
0
;
n
<
12
;
n
++
){
if
((
n
==
6
)
&&
((
rb
+
startingPRB
)
==
(
frame_parms
->
N_RB_DL
>>
1
))
&&
((
frame_parms
->
N_RB_DL
&
1
)
==
1
))
{
// if number RBs in bandwidth is odd and current PRB contains DC, we need to recalculate the offset when n=6 (for second half PRB)
...
...
openair1/SIMULATION/NR_PHY/dlschsim.c
View file @
b44e15fd
...
...
@@ -36,14 +36,14 @@
#include "PHY/defs_nr_common.h"
#include "PHY/defs_nr_UE.h"
#include "PHY/defs_gNB.h"
#include "PHY/INIT/phy_init.h"
#include "PHY/NR_REFSIG/refsig_defs_ue.h"
#include "PHY/NR_REFSIG/nr_mod_table.h"
#include "PHY/MODULATION/modulation_eNB.h"
#include "PHY/MODULATION/modulation_UE.h"
#include "PHY/INIT/phy_init.h"
#include "PHY/NR_TRANSPORT/nr_transport.h"
#include "PHY/NR_UE_TRANSPORT/nr_transport_proto_ue.h"
#include "PHY/NR_TRANSPORT/nr_dlsch.h"
#include "PHY/NR_UE_TRANSPORT/nr_transport_proto_ue.h"
#include "SCHED_NR/sched_nr.h"
...
...
@@ -52,627 +52,617 @@
//#include "UTIL/LISTS/list.h"
//#include "common/ran_context.h"
//#define DEBUG_DLSCHSIM
PHY_VARS_gNB
*
gNB
;
PHY_VARS_NR_UE
*
UE
;
RAN_CONTEXT_t
RC
;
double
cpuf
;
// dummy functions
int
nfapi_mode
=
0
;
int
nfapi_mode
=
0
;
int
oai_nfapi_hi_dci0_req
(
nfapi_hi_dci0_request_t
*
hi_dci0_req
)
{
return
(
0
);
return
(
0
);
}
int
oai_nfapi_tx_req
(
nfapi_tx_request_t
*
tx_req
)
{
return
(
0
);
return
(
0
);
}
int
oai_nfapi_dl_config_req
(
nfapi_dl_config_request_t
*
dl_config_req
)
{
return
(
0
);
return
(
0
);
}
int
oai_nfapi_ul_config_req
(
nfapi_ul_config_request_t
*
ul_config_req
)
{
return
(
0
);
return
(
0
);
}
int
oai_nfapi_nr_dl_config_req
(
nfapi_nr_dl_config_request_t
*
dl_config_req
)
{
return
(
0
);
return
(
0
);
}
uint32_t
from_nrarfcn
(
int
nr_bandP
,
uint32_t
dl_earfcn
)
{
return
(
0
);
uint32_t
from_nrarfcn
(
int
nr_bandP
,
uint32_t
dl_earfcn
)
{
return
(
0
);
}
int32_t
get_uldl_offset
(
int
eutra_bandP
)
{
return
(
0
);
return
(
0
);
}
NR_IF_Module_t
*
NR_IF_Module_init
(
int
Mod_id
)
{
return
(
NULL
);
NR_IF_Module_t
*
NR_IF_Module_init
(
int
Mod_id
)
{
return
(
NULL
);
}
void
exit_function
(
const
char
*
file
,
const
char
*
function
,
const
int
line
,
const
char
*
s
)
{
const
char
*
msg
=
s
==
NULL
?
"no comment"
:
s
;
printf
(
"Exiting at: %s:%d %s(), %s
\n
"
,
file
,
line
,
function
,
msg
);
exit
(
-
1
);
void
exit_function
(
const
char
*
file
,
const
char
*
function
,
const
int
line
,
const
char
*
s
)
{
const
char
*
msg
=
s
==
NULL
?
"no comment"
:
s
;
printf
(
"Exiting at: %s:%d %s(), %s
\n
"
,
file
,
line
,
function
,
msg
);
exit
(
-
1
);
}
// needed for some functions
PHY_VARS_NR_UE
*
PHY_vars_UE_g
[
1
][
1
]
=
{{
NULL
}
};
uint16_t
n_rnti
=
0x1234
;
PHY_VARS_NR_UE
*
PHY_vars_UE_g
[
1
][
1
]
=
{
{
NULL
}
};
uint16_t
n_rnti
=
0x1234
;
char
quantize
(
double
D
,
double
x
,
unsigned
char
B
)
{
double
qxd
;
short
maxlev
;
qxd
=
floor
(
x
/
D
);
maxlev
=
1
<<
(
B
-
1
);
//(char)(pow(2,B-1));
char
quantize
(
double
D
,
double
x
,
unsigned
char
B
)
{
double
qxd
;
short
maxlev
;
qxd
=
floor
(
x
/
D
);
maxlev
=
1
<<
(
B
-
1
);
//(char)(pow(2,B-1));
//printf("x=%f,qxd=%f,maxlev=%d\n",x,qxd, maxlev);
//printf("x=%f,qxd=%f,maxlev=%d\n",x,qxd, maxlev);
if
(
qxd
<=
-
maxlev
)
qxd
=
-
maxlev
;
else
if
(
qxd
>=
maxlev
)
qxd
=
maxlev
-
1
;
if
(
qxd
<=
-
maxlev
)
qxd
=
-
maxlev
;
else
if
(
qxd
>=
maxlev
)
qxd
=
maxlev
-
1
;
return
((
char
)
qxd
);
return
((
char
)
qxd
);
}
int
main
(
int
argc
,
char
**
argv
)
{
char
c
;
int
i
;
//,j,l,aa;
double
SNR
,
SNR_lin
,
snr0
=-
2
.
0
,
snr1
=
2
.
0
;
double
snr_step
=
0
.
1
;
uint8_t
snr1set
=
0
;
int
**
txdata
;
double
**
s_re
,
**
s_im
,
**
r_re
,
**
r_im
;
// int sync_pos, sync_pos_slot;
// FILE *rx_frame_file;
FILE
*
output_fd
=
NULL
;
uint8_t
write_output_file
=
0
;
// int subframe_offset;
// char fname[40], vname[40];
int
trial
,
n_trials
=
1
,
n_errors
=
0
,
n_false_positive
=
0
;
uint8_t
transmission_mode
=
1
,
n_tx
=
1
,
n_rx
=
1
;
uint16_t
Nid_cell
=
0
;
channel_desc_t
*
gNB2UE
;
uint8_t
extended_prefix_flag
=
0
;
int8_t
interf1
=-
21
,
interf2
=-
21
;
FILE
*
input_fd
=
NULL
,
*
pbch_file_fd
=
NULL
;
//char input_val_str[50],input_val_str2[50];
//uint16_t NB_RB=25;
SCM_t
channel_model
=
AWGN
;
//Rayleigh1_anticorr;
uint8_t
N_RB_DL
=
106
,
mu
=
1
;
unsigned
char
frame_type
=
0
;
unsigned
char
pbch_phase
=
0
;
int
frame
=
0
,
subframe
=
0
;
int
frame_length_complex_samples
;
//int frame_length_complex_samples_no_prefix;
NR_DL_FRAME_PARMS
*
frame_parms
;
//nfapi_nr_config_request_t *gNB_config;
uint8_t
Kmimo
=
0
;
uint32_t
Nsoft
=
0
;
double
sigma
;
unsigned
char
qbits
=
8
;
int
ret
;
//int run_initial_sync=0;
int
loglvl
=
OAILOG_WARNING
;
float
target_error_rate
=
0
.
01
;
uint16_t
nb_symb_sch
=
12
;
uint16_t
nb_rb
=
50
;
uint8_t
Imcs
=
9
;
cpuf
=
get_cpu_freq_GHz
();
if
(
load_configmodule
(
argc
,
argv
)
==
0
)
{
exit_fun
(
"[SOFTMODEM] Error, configuration module init failed
\n
"
);
}
//logInit();
randominit
(
0
);
while
((
c
=
getopt
(
argc
,
argv
,
"df:hpg:i:j:n:l:m:r:s:S:y:z:N:F:R:P:"
))
!=
-
1
)
{
switch
(
c
)
{
case
'f'
:
write_output_file
=
1
;
output_fd
=
fopen
(
optarg
,
"w"
);
if
(
output_fd
==
NULL
)
{
printf
(
"Error opening %s
\n
"
,
optarg
);
exit
(
-
1
);
}
break
;
case
'd'
:
frame_type
=
1
;
break
;
case
'g'
:
switch
((
char
)
*
optarg
)
{
case
'A'
:
channel_model
=
SCM_A
;
break
;
case
'B'
:
channel_model
=
SCM_B
;
break
;
case
'C'
:
channel_model
=
SCM_C
;
break
;
case
'D'
:
channel_model
=
SCM_D
;
break
;
case
'E'
:
channel_model
=
EPA
;
break
;
case
'F'
:
channel_model
=
EVA
;
break
;
case
'G'
:
channel_model
=
ETU
;
break
;
default:
msg
(
"Unsupported channel model!
\n
"
);
exit
(
-
1
);
}
break
;
case
'i'
:
interf1
=
atoi
(
optarg
);
break
;
case
'j'
:
interf2
=
atoi
(
optarg
);
break
;
case
'n'
:
n_trials
=
atoi
(
optarg
);
break
;
case
's'
:
snr0
=
atof
(
optarg
);
msg
(
"Setting SNR0 to %f
\n
"
,
snr0
);
break
;
case
'S'
:
snr1
=
atof
(
optarg
);
snr1set
=
1
;
msg
(
"Setting SNR1 to %f
\n
"
,
snr1
);
break
;
case
'p'
:
extended_prefix_flag
=
1
;
break
;
/*
case 'r':
ricean_factor = pow(10,-.1*atof(optarg));
if (ricean_factor>1) {
printf("Ricean factor must be between 0 and 1\n");
exit(-1);
}
break;
*/
case
'y'
:
n_tx
=
atoi
(
optarg
);
if
((
n_tx
==
0
)
||
(
n_tx
>
2
))
{
msg
(
"Unsupported number of tx antennas %d
\n
"
,
n_tx
);
exit
(
-
1
);
}
break
;
case
'z'
:
n_rx
=
atoi
(
optarg
);
if
((
n_rx
==
0
)
||
(
n_rx
>
2
))
{
msg
(
"Unsupported number of rx antennas %d
\n
"
,
n_rx
);
exit
(
-
1
);
}
break
;
case
'N'
:
Nid_cell
=
atoi
(
optarg
);
break
;
case
'R'
:
N_RB_DL
=
atoi
(
optarg
);
break
;
case
'F'
:
input_fd
=
fopen
(
optarg
,
"r"
);
if
(
input_fd
==
NULL
)
{
printf
(
"Problem with filename %s
\n
"
,
optarg
);
exit
(
-
1
);
}
break
;
case
'P'
:
pbch_phase
=
atoi
(
optarg
);
if
(
pbch_phase
>
3
)
printf
(
"Illegal PBCH phase (0-3) got %d
\n
"
,
pbch_phase
);
break
;
case
'm'
:
Imcs
=
atoi
(
optarg
);
break
;
case
'l'
:
nb_symb_sch
=
atoi
(
optarg
);
break
;
case
'r'
:
nb_rb
=
atoi
(
optarg
);
break
;
case
'x'
:
transmission_mode
=
atoi
(
optarg
);
break
;
default:
case
'h'
:
printf
(
"%s -h(elp) -p(extended_prefix) -N cell_id -f output_filename -F input_filename -g channel_model -n n_frames -t Delayspread -s snr0 -S snr1 -x transmission_mode -y TXant -z RXant -i Intefrence0 -j Interference1 -A interpolation_file -C(alibration offset dB) -N CellId
\n
"
,
argv
[
0
]);
printf
(
"-h This message
\n
"
);
printf
(
"-p Use extended prefix mode
\n
"
);
printf
(
"-d Use TDD
\n
"
);
printf
(
"-n Number of frames to simulate
\n
"
);
printf
(
"-s Starting SNR, runs from SNR0 to SNR0 + 5 dB. If n_frames is 1 then just SNR is simulated
\n
"
);
printf
(
"-S Ending SNR, runs from SNR0 to SNR1
\n
"
);
printf
(
"-t Delay spread for multipath channel
\n
"
);
printf
(
"-g [A,B,C,D,E,F,G] Use 3GPP SCM (A,B,C,D) or 36-101 (E-EPA,F-EVA,G-ETU) models (ignores delay spread and Ricean factor)
\n
"
);
printf
(
"-x Transmission mode (1,2,6 for the moment)
\n
"
);
printf
(
"-y Number of TX antennas used in eNB
\n
"
);
printf
(
"-z Number of RX antennas used in UE
\n
"
);
printf
(
"-i Relative strength of first intefering eNB (in dB) - cell_id mod 3 = 1
\n
"
);
printf
(
"-j Relative strength of second intefering eNB (in dB) - cell_id mod 3 = 2
\n
"
);
printf
(
"-N Nid_cell
\n
"
);
printf
(
"-R N_RB_DL
\n
"
);
printf
(
"-O oversampling factor (1,2,4,8,16)
\n
"
);
printf
(
"-A Interpolation_filname Run with Abstraction to generate Scatter plot using interpolation polynomial in file
\n
"
);
// printf("-C Generate Calibration information for Abstraction (effective SNR adjustment to remove Pe bias w.r.t. AWGN)\n");
printf
(
"-f Output filename (.txt format) for Pe/SNR results
\n
"
);
printf
(
"-F Input filename (.txt format) for RX conformance testing
\n
"
);
exit
(
-
1
);
break
;
}
}
logInit
();
set_glog
(
loglvl
);
T_stdout
=
1
;
if
(
snr1set
==
0
)
snr1
=
snr0
+
10
;
gNB2UE
=
new_channel_desc_scm
(
n_tx
,
n_rx
,
channel_model
,
61.44e6
,
//N_RB2sampling_rate(N_RB_DL),
40e6
,
//N_RB2channel_bandwidth(N_RB_DL),
0
,
0
,
0
);
if
(
gNB2UE
==
NULL
)
{
msg
(
"Problem generating channel model. Exiting.
\n
"
);
exit
(
-
1
);
}
RC
.
gNB
=
(
PHY_VARS_gNB
**
*
)
malloc
(
sizeof
(
PHY_VARS_gNB
**
));
RC
.
gNB
[
0
]
=
(
PHY_VARS_gNB
**
)
malloc
(
sizeof
(
PHY_VARS_gNB
*
));
RC
.
gNB
[
0
][
0
]
=
malloc
(
sizeof
(
PHY_VARS_gNB
));
gNB
=
RC
.
gNB
[
0
][
0
];
//gNB_config = &gNB->gNB_config;
frame_parms
=
&
gNB
->
frame_parms
;
//to be initialized I suppose (maybe not necessary for PBCH)
frame_parms
->
nb_antennas_tx
=
n_tx
;
frame_parms
->
nb_antennas_rx
=
n_rx
;
frame_parms
->
N_RB_DL
=
N_RB_DL
;
crcTableInit
();
nr_phy_config_request_sim
(
gNB
,
N_RB_DL
,
N_RB_DL
,
mu
);
phy_init_nr_gNB
(
gNB
,
0
,
0
);
//init_eNB_afterRU();
frame_length_complex_samples
=
frame_parms
->
samples_per_subframe
;
//frame_length_complex_samples_no_prefix = frame_parms->samples_per_subframe_wCP;
s_re
=
malloc
(
2
*
sizeof
(
double
*
));
s_im
=
malloc
(
2
*
sizeof
(
double
*
));
r_re
=
malloc
(
2
*
sizeof
(
double
*
));
r_im
=
malloc
(
2
*
sizeof
(
double
*
));
txdata
=
malloc
(
2
*
sizeof
(
int
*
));
for
(
i
=
0
;
i
<
2
;
i
++
)
{
s_re
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
s_re
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
s_im
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
s_im
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
r_re
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
r_re
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
r_im
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
r_im
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
txdata
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
int
));
bzero
(
r_re
[
i
],
frame_length_complex_samples
*
sizeof
(
int
));
}
if
(
pbch_file_fd
!=
NULL
)
{
load_pbch_desc
(
pbch_file_fd
);
}
/* for (int k=0; k<2; k++) {
// Create transport channel structures for 2 transport blocks (MIMO)
for (i=0; i<2; i++) {
gNB->dlsch[k][i] = new_gNB_dlsch(Kmimo,8,Nsoft,0,frame_parms,gNB_config);
if (!gNB->dlsch[k][i]) {
printf("Can't get eNB dlsch structures\n");
exit(-1);
}
gNB->dlsch[k][i]->Nsoft = 10;
gNB->dlsch[k][i]->rnti = n_rnti+k;
}
}*/
//configure UE
UE
=
malloc
(
sizeof
(
PHY_VARS_NR_UE
));
memcpy
(
&
UE
->
frame_parms
,
frame_parms
,
sizeof
(
NR_DL_FRAME_PARMS
));
//phy_init_nr_top(frame_parms);
if
(
init_nr_ue_signal
(
UE
,
1
,
0
)
!=
0
)
{
printf
(
"Error at UE NR initialisation
\n
"
);
exit
(
-
1
);
}
//nr_init_frame_parms_ue(&UE->frame_parms);
//init_nr_ue_transport(UE, 0);
for
(
int
sf
=
0
;
sf
<
2
;
sf
++
)
{
for
(
i
=
0
;
i
<
2
;
i
++
)
{
UE
->
dlsch
[
sf
][
0
][
i
]
=
new_nr_ue_dlsch
(
Kmimo
,
8
,
Nsoft
,
5
,
N_RB_DL
,
0
);
if
(
!
UE
->
dlsch
[
sf
][
0
][
i
])
{
printf
(
"Can't get ue dlsch structures
\n
"
);
exit
(
-
1
);
}
UE
->
dlsch
[
sf
][
0
][
i
]
->
rnti
=
n_rnti
;
}
}
UE
->
dlsch_SI
[
0
]
=
new_nr_ue_dlsch
(
1
,
1
,
Nsoft
,
5
,
N_RB_DL
,
0
);
UE
->
dlsch_ra
[
0
]
=
new_nr_ue_dlsch
(
1
,
1
,
Nsoft
,
5
,
N_RB_DL
,
0
);
unsigned
char
harq_pid
=
0
;
//dlsch->harq_ids[subframe];
NR_gNB_DLSCH_t
*
dlsch
=
gNB
->
dlsch
[
0
][
0
];
nfapi_nr_dl_config_dlsch_pdu_rel15_t
*
rel15
=
&
dlsch
->
harq_processes
[
harq_pid
]
->
dlsch_pdu
.
dlsch_pdu_rel15
;
//time_stats_t *rm_stats, *te_stats, *i_stats;
uint8_t
is_crnti
=
0
,
llr8_flag
=
0
;
unsigned
int
TBS
=
8424
;
unsigned
int
available_bits
;
uint8_t
nb_re_dmrs
=
6
;
uint16_t
length_dmrs
=
1
;
unsigned
char
mod_order
;
uint8_t
Nl
=
1
;
uint8_t
rvidx
=
0
;
dlsch
->
rnti
=
1
;
/*dlsch->harq_processes[0]->mcs = Imcs;
dlsch->harq_processes[0]->rvidx = rvidx;*/
//printf("dlschsim harqid %d nb_rb %d, mscs %d\n",dlsch->harq_ids[subframe],
// dlsch->harq_processes[0]->nb_rb,dlsch->harq_processes[0]->mcs,dlsch->harq_processes[0]->Nl);
mod_order
=
nr_get_Qm
(
Imcs
,
1
);
available_bits
=
nr_get_G
(
nb_rb
,
nb_symb_sch
,
nb_re_dmrs
,
length_dmrs
,
mod_order
,
1
);
TBS
=
nr_compute_tbs
(
Imcs
,
nb_rb
,
nb_symb_sch
,
nb_re_dmrs
,
length_dmrs
,
Nl
);
printf
(
"available bits %d TBS %d mod_order %d
\n
"
,
available_bits
,
TBS
,
mod_order
);
//dlsch->harq_ids[subframe]= 0;
rel15
->
n_prb
=
nb_rb
;
rel15
->
nb_symbols
=
nb_symb_sch
;
rel15
->
modulation_order
=
mod_order
;
rel15
->
nb_layers
=
Nl
;
rel15
->
nb_re_dmrs
=
nb_re_dmrs
;
rel15
->
transport_block_size
=
TBS
;
double
*
modulated_input
=
malloc16
(
sizeof
(
double
)
*
16
*
68
*
384
);
short
*
channel_output_fixed
=
malloc16
(
sizeof
(
short
)
*
16
*
68
*
384
);
short
*
channel_output_uncoded
=
malloc16
(
sizeof
(
unsigned
short
)
*
16
*
68
*
384
);
double
errors_bit_uncoded
=
0
;
unsigned
char
*
estimated_output
;
unsigned
char
*
estimated_output_bit
;
unsigned
char
*
test_input_bit
;
unsigned
int
errors_bit
=
0
;
test_input_bit
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
16
*
68
*
384
);
estimated_output
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
16
*
68
*
384
);
estimated_output_bit
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
16
*
68
*
384
);
NR_UE_DLSCH_t
*
dlsch0_ue
=
UE
->
dlsch
[
UE
->
current_thread_id
[
subframe
]][
0
][
0
];
NR_DL_UE_HARQ_t
*
harq_process
=
dlsch0_ue
->
harq_processes
[
harq_pid
];
harq_process
->
mcs
=
Imcs
;
harq_process
->
Nl
=
Nl
;
harq_process
->
nb_rb
=
nb_rb
;
harq_process
->
Qm
=
mod_order
;
harq_process
->
rvidx
=
rvidx
;
printf
(
"harq process ue mcs = %d Qm = %d, symb %d
\n
"
,
harq_process
->
mcs
,
harq_process
->
Qm
,
nb_symb_sch
);
unsigned
char
*
test_input
;
test_input
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
TBS
/
8
);
for
(
i
=
0
;
i
<
TBS
/
8
;
i
++
)
test_input
[
i
]
=
(
unsigned
char
)
rand
();
estimated_output
=
harq_process
->
b
;
/*for (int i=0; i<TBS/8; i++)
printf("test input[%d]=%d \n",i,test_input[i]);*/
//printf("crc32: [0]->0x%08x\n",crc24c(test_input, 32));
// generate signal
if
(
input_fd
==
NULL
)
{
nr_dlsch_encoding
(
test_input
,
subframe
,
dlsch
,
frame_parms
);
}
for
(
SNR
=
snr0
;
SNR
<
snr1
;
SNR
+=
snr_step
)
{
n_errors
=
0
;
n_false_positive
=
0
;
for
(
trial
=
0
;
trial
<
n_trials
;
trial
++
)
{
errors_bit_uncoded
=
0
;
for
(
i
=
0
;
i
<
available_bits
;
i
++
)
{
#ifdef DEBUG_CODER
char
c
;
int
i
;
//,j,l,aa;
double
SNR
,
SNR_lin
,
snr0
=
-
2
.
0
,
snr1
=
2
.
0
;
double
snr_step
=
0
.
1
;
uint8_t
snr1set
=
0
;
int
**
txdata
;
double
**
s_re
,
**
s_im
,
**
r_re
,
**
r_im
;
// int sync_pos, sync_pos_slot;
// FILE *rx_frame_file;
FILE
*
output_fd
=
NULL
;
uint8_t
write_output_file
=
0
;
// int subframe_offset;
// char fname[40], vname[40];
int
trial
,
n_trials
=
1
,
n_errors
=
0
,
n_false_positive
=
0
;
uint8_t
transmission_mode
=
1
,
n_tx
=
1
,
n_rx
=
1
;
uint16_t
Nid_cell
=
0
;
channel_desc_t
*
gNB2UE
;
uint8_t
extended_prefix_flag
=
0
;
int8_t
interf1
=
-
21
,
interf2
=
-
21
;
FILE
*
input_fd
=
NULL
,
*
pbch_file_fd
=
NULL
;
//char input_val_str[50],input_val_str2[50];
//uint16_t NB_RB=25;
SCM_t
channel_model
=
AWGN
;
//Rayleigh1_anticorr;
uint8_t
N_RB_DL
=
106
,
mu
=
1
;
unsigned
char
frame_type
=
0
;
unsigned
char
pbch_phase
=
0
;
int
frame
=
0
,
subframe
=
0
;
int
frame_length_complex_samples
;
//int frame_length_complex_samples_no_prefix;
NR_DL_FRAME_PARMS
*
frame_parms
;
//nfapi_nr_config_request_t *gNB_config;
uint8_t
Kmimo
=
0
;
uint32_t
Nsoft
=
0
;
double
sigma
;
unsigned
char
qbits
=
8
;
int
ret
;
//int run_initial_sync=0;
int
loglvl
=
OAILOG_WARNING
;
float
target_error_rate
=
0
.
01
;
uint16_t
nb_symb_sch
=
12
;
uint16_t
nb_rb
=
50
;
uint8_t
Imcs
=
9
;
cpuf
=
get_cpu_freq_GHz
();
if
(
load_configmodule
(
argc
,
argv
)
==
0
)
{
exit_fun
(
"[SOFTMODEM] Error, configuration module init failed
\n
"
);
}
//logInit();
randominit
(
0
);
while
((
c
=
getopt
(
argc
,
argv
,
"df:hpg:i:j:n:l:m:r:s:S:y:z:N:F:R:P:"
))
!=
-
1
)
{
switch
(
c
)
{
case
'f'
:
write_output_file
=
1
;
output_fd
=
fopen
(
optarg
,
"w"
);
if
(
output_fd
==
NULL
)
{
printf
(
"Error opening %s
\n
"
,
optarg
);
exit
(
-
1
);
}
break
;
case
'd'
:
frame_type
=
1
;
break
;
case
'g'
:
switch
((
char
)
*
optarg
)
{
case
'A'
:
channel_model
=
SCM_A
;
break
;
case
'B'
:
channel_model
=
SCM_B
;
break
;
case
'C'
:
channel_model
=
SCM_C
;
break
;
case
'D'
:
channel_model
=
SCM_D
;
break
;
case
'E'
:
channel_model
=
EPA
;
break
;
case
'F'
:
channel_model
=
EVA
;
break
;
case
'G'
:
channel_model
=
ETU
;
break
;
default:
msg
(
"Unsupported channel model!
\n
"
);
exit
(
-
1
);
}
break
;
case
'i'
:
interf1
=
atoi
(
optarg
);
break
;
case
'j'
:
interf2
=
atoi
(
optarg
);
break
;
case
'n'
:
n_trials
=
atoi
(
optarg
);
break
;
case
's'
:
snr0
=
atof
(
optarg
);
msg
(
"Setting SNR0 to %f
\n
"
,
snr0
);
break
;
case
'S'
:
snr1
=
atof
(
optarg
);
snr1set
=
1
;
msg
(
"Setting SNR1 to %f
\n
"
,
snr1
);
break
;
case
'p'
:
extended_prefix_flag
=
1
;
break
;
/*
case 'r':
ricean_factor = pow(10,-.1*atof(optarg));
if (ricean_factor>1) {
printf("Ricean factor must be between 0 and 1\n");
exit(-1);
}
break;
*/
case
'y'
:
n_tx
=
atoi
(
optarg
);
if
((
n_tx
==
0
)
||
(
n_tx
>
2
))
{
msg
(
"Unsupported number of tx antennas %d
\n
"
,
n_tx
);
exit
(
-
1
);
}
break
;
case
'z'
:
n_rx
=
atoi
(
optarg
);
if
((
n_rx
==
0
)
||
(
n_rx
>
2
))
{
msg
(
"Unsupported number of rx antennas %d
\n
"
,
n_rx
);
exit
(
-
1
);
}
break
;
case
'N'
:
Nid_cell
=
atoi
(
optarg
);
break
;
case
'R'
:
N_RB_DL
=
atoi
(
optarg
);
break
;
case
'F'
:
input_fd
=
fopen
(
optarg
,
"r"
);
if
(
input_fd
==
NULL
)
{
printf
(
"Problem with filename %s
\n
"
,
optarg
);
exit
(
-
1
);
}
break
;
case
'P'
:
pbch_phase
=
atoi
(
optarg
);
if
(
pbch_phase
>
3
)
printf
(
"Illegal PBCH phase (0-3) got %d
\n
"
,
pbch_phase
);
break
;
case
'm'
:
Imcs
=
atoi
(
optarg
);
break
;
case
'l'
:
nb_symb_sch
=
atoi
(
optarg
);
break
;
case
'r'
:
nb_rb
=
atoi
(
optarg
);
break
;
case
'x'
:
transmission_mode
=
atoi
(
optarg
);
break
;
default:
case
'h'
:
printf
(
"%s -h(elp) -p(extended_prefix) -N cell_id -f output_filename -F input_filename -g channel_model -n n_frames -t Delayspread -s snr0 -S snr1 -x transmission_mode -y TXant -z RXant -i Intefrence0 -j Interference1 -A interpolation_file -C(alibration offset dB) -N CellId
\n
"
,
argv
[
0
]);
printf
(
"-h This message
\n
"
);
printf
(
"-p Use extended prefix mode
\n
"
);
printf
(
"-d Use TDD
\n
"
);
printf
(
"-n Number of frames to simulate
\n
"
);
printf
(
"-s Starting SNR, runs from SNR0 to SNR0 + 5 dB. If n_frames is 1 then just SNR is simulated
\n
"
);
printf
(
"-S Ending SNR, runs from SNR0 to SNR1
\n
"
);
printf
(
"-t Delay spread for multipath channel
\n
"
);
printf
(
"-g [A,B,C,D,E,F,G] Use 3GPP SCM (A,B,C,D) or 36-101 (E-EPA,F-EVA,G-ETU) models (ignores delay spread and Ricean factor)
\n
"
);
printf
(
"-x Transmission mode (1,2,6 for the moment)
\n
"
);
printf
(
"-y Number of TX antennas used in eNB
\n
"
);
printf
(
"-z Number of RX antennas used in UE
\n
"
);
printf
(
"-i Relative strength of first intefering eNB (in dB) - cell_id mod 3 = 1
\n
"
);
printf
(
"-j Relative strength of second intefering eNB (in dB) - cell_id mod 3 = 2
\n
"
);
printf
(
"-N Nid_cell
\n
"
);
printf
(
"-R N_RB_DL
\n
"
);
printf
(
"-O oversampling factor (1,2,4,8,16)
\n
"
);
printf
(
"-A Interpolation_filname Run with Abstraction to generate Scatter plot using interpolation polynomial in file
\n
"
);
// printf("-C Generate Calibration information for Abstraction (effective SNR adjustment to remove Pe bias w.r.t. AWGN)\n");
printf
(
"-f Output filename (.txt format) for Pe/SNR results
\n
"
);
printf
(
"-F Input filename (.txt format) for RX conformance testing
\n
"
);
exit
(
-
1
);
break
;
}
}
logInit
();
set_glog
(
loglvl
);
T_stdout
=
1
;
if
(
snr1set
==
0
)
snr1
=
snr0
+
10
;
gNB2UE
=
new_channel_desc_scm
(
n_tx
,
n_rx
,
channel_model
,
61.44e6
,
//N_RB2sampling_rate(N_RB_DL),
40e6
,
//N_RB2channel_bandwidth(N_RB_DL),
0
,
0
,
0
);
if
(
gNB2UE
==
NULL
)
{
msg
(
"Problem generating channel model. Exiting.
\n
"
);
exit
(
-
1
);
}
RC
.
gNB
=
(
PHY_VARS_gNB
**
*
)
malloc
(
sizeof
(
PHY_VARS_gNB
**
));
RC
.
gNB
[
0
]
=
(
PHY_VARS_gNB
**
)
malloc
(
sizeof
(
PHY_VARS_gNB
*
));
RC
.
gNB
[
0
][
0
]
=
malloc
(
sizeof
(
PHY_VARS_gNB
));
gNB
=
RC
.
gNB
[
0
][
0
];
//gNB_config = &gNB->gNB_config;
frame_parms
=
&
gNB
->
frame_parms
;
//to be initialized I suppose (maybe not necessary for PBCH)
frame_parms
->
nb_antennas_tx
=
n_tx
;
frame_parms
->
nb_antennas_rx
=
n_rx
;
frame_parms
->
N_RB_DL
=
N_RB_DL
;
crcTableInit
();
nr_phy_config_request_sim
(
gNB
,
N_RB_DL
,
N_RB_DL
,
mu
);
phy_init_nr_gNB
(
gNB
,
0
,
0
);
//init_eNB_afterRU();
frame_length_complex_samples
=
frame_parms
->
samples_per_subframe
;
//frame_length_complex_samples_no_prefix = frame_parms->samples_per_subframe_wCP;
s_re
=
malloc
(
2
*
sizeof
(
double
*
));
s_im
=
malloc
(
2
*
sizeof
(
double
*
));
r_re
=
malloc
(
2
*
sizeof
(
double
*
));
r_im
=
malloc
(
2
*
sizeof
(
double
*
));
txdata
=
malloc
(
2
*
sizeof
(
int
*
));
for
(
i
=
0
;
i
<
2
;
i
++
)
{
s_re
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
s_re
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
s_im
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
s_im
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
r_re
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
r_re
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
r_im
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
double
));
bzero
(
r_im
[
i
],
frame_length_complex_samples
*
sizeof
(
double
));
txdata
[
i
]
=
malloc
(
frame_length_complex_samples
*
sizeof
(
int
));
bzero
(
r_re
[
i
],
frame_length_complex_samples
*
sizeof
(
int
));
}
if
(
pbch_file_fd
!=
NULL
)
{
load_pbch_desc
(
pbch_file_fd
);
}
/* for (int k=0; k<2; k++) {
// Create transport channel structures for 2 transport blocks (MIMO)
for (i=0; i<2; i++) {
gNB->dlsch[k][i] = new_gNB_dlsch(Kmimo,8,Nsoft,0,frame_parms,gNB_config);
if (!gNB->dlsch[k][i]) {
printf("Can't get eNB dlsch structures\n");
exit(-1);
}
gNB->dlsch[k][i]->Nsoft = 10;
gNB->dlsch[k][i]->rnti = n_rnti+k;
}
}*/
//configure UE
UE
=
malloc
(
sizeof
(
PHY_VARS_NR_UE
));
memcpy
(
&
UE
->
frame_parms
,
frame_parms
,
sizeof
(
NR_DL_FRAME_PARMS
));
//phy_init_nr_top(frame_parms);
if
(
init_nr_ue_signal
(
UE
,
1
,
0
)
!=
0
)
{
printf
(
"Error at UE NR initialisation
\n
"
);
exit
(
-
1
);
}
//nr_init_frame_parms_ue(&UE->frame_parms);
//init_nr_ue_transport(UE, 0);
for
(
int
sf
=
0
;
sf
<
2
;
sf
++
)
{
for
(
i
=
0
;
i
<
2
;
i
++
)
{
UE
->
dlsch
[
sf
][
0
][
i
]
=
new_nr_ue_dlsch
(
Kmimo
,
8
,
Nsoft
,
5
,
N_RB_DL
,
0
);
if
(
!
UE
->
dlsch
[
sf
][
0
][
i
])
{
printf
(
"Can't get ue dlsch structures
\n
"
);
exit
(
-
1
);
}
UE
->
dlsch
[
sf
][
0
][
i
]
->
rnti
=
n_rnti
;
}
}
UE
->
dlsch_SI
[
0
]
=
new_nr_ue_dlsch
(
1
,
1
,
Nsoft
,
5
,
N_RB_DL
,
0
);
UE
->
dlsch_ra
[
0
]
=
new_nr_ue_dlsch
(
1
,
1
,
Nsoft
,
5
,
N_RB_DL
,
0
);
unsigned
char
harq_pid
=
0
;
//dlsch->harq_ids[subframe];
NR_gNB_DLSCH_t
*
dlsch
=
gNB
->
dlsch
[
0
][
0
];
nfapi_nr_dl_config_dlsch_pdu_rel15_t
*
rel15
=
&
dlsch
->
harq_processes
[
harq_pid
]
->
dlsch_pdu
.
dlsch_pdu_rel15
;
//time_stats_t *rm_stats, *te_stats, *i_stats;
uint8_t
is_crnti
=
0
,
llr8_flag
=
0
;
unsigned
int
TBS
=
8424
;
unsigned
int
available_bits
;
uint8_t
nb_re_dmrs
=
6
;
uint16_t
length_dmrs
=
1
;
unsigned
char
mod_order
;
uint8_t
Nl
=
1
;
uint8_t
rvidx
=
0
;
dlsch
->
rnti
=
1
;
/*dlsch->harq_processes[0]->mcs = Imcs;
dlsch->harq_processes[0]->rvidx = rvidx;*/
//printf("dlschsim harqid %d nb_rb %d, mscs %d\n",dlsch->harq_ids[subframe],
// dlsch->harq_processes[0]->nb_rb,dlsch->harq_processes[0]->mcs,dlsch->harq_processes[0]->Nl);
mod_order
=
nr_get_Qm
(
Imcs
,
1
);
available_bits
=
nr_get_G
(
nb_rb
,
nb_symb_sch
,
nb_re_dmrs
,
length_dmrs
,
mod_order
,
1
);
TBS
=
nr_compute_tbs
(
Imcs
,
nb_rb
,
nb_symb_sch
,
nb_re_dmrs
,
length_dmrs
,
Nl
);
printf
(
"available bits %d TBS %d mod_order %d
\n
"
,
available_bits
,
TBS
,
mod_order
);
//dlsch->harq_ids[subframe]= 0;
rel15
->
n_prb
=
nb_rb
;
rel15
->
nb_symbols
=
nb_symb_sch
;
rel15
->
modulation_order
=
mod_order
;
rel15
->
nb_layers
=
Nl
;
rel15
->
nb_re_dmrs
=
nb_re_dmrs
;
rel15
->
transport_block_size
=
TBS
;
double
*
modulated_input
=
malloc16
(
sizeof
(
double
)
*
16
*
68
*
384
);
short
*
channel_output_fixed
=
malloc16
(
sizeof
(
short
)
*
16
*
68
*
384
);
short
*
channel_output_uncoded
=
malloc16
(
sizeof
(
unsigned
short
)
*
16
*
68
*
384
);
double
errors_bit_uncoded
=
0
;
unsigned
char
*
estimated_output
;
unsigned
char
*
estimated_output_bit
;
unsigned
char
*
test_input_bit
;
unsigned
int
errors_bit
=
0
;
test_input_bit
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
16
*
68
*
384
);
estimated_output
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
16
*
68
*
384
);
estimated_output_bit
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
16
*
68
*
384
);
NR_UE_DLSCH_t
*
dlsch0_ue
=
UE
->
dlsch
[
UE
->
current_thread_id
[
subframe
]][
0
][
0
];
NR_DL_UE_HARQ_t
*
harq_process
=
dlsch0_ue
->
harq_processes
[
harq_pid
];
harq_process
->
mcs
=
Imcs
;
harq_process
->
Nl
=
Nl
;
harq_process
->
nb_rb
=
nb_rb
;
harq_process
->
Qm
=
mod_order
;
harq_process
->
rvidx
=
rvidx
;
printf
(
"harq process ue mcs = %d Qm = %d, symb %d
\n
"
,
harq_process
->
mcs
,
harq_process
->
Qm
,
nb_symb_sch
);
unsigned
char
*
test_input
;
test_input
=
(
unsigned
char
*
)
malloc16
(
sizeof
(
unsigned
char
)
*
TBS
/
8
);
for
(
i
=
0
;
i
<
TBS
/
8
;
i
++
)
test_input
[
i
]
=
(
unsigned
char
)
rand
();
estimated_output
=
harq_process
->
b
;
#ifdef DEBUG_DLSCHSIM
for
(
i
=
0
;
i
<
TBS
/
8
;
i
++
)
printf
(
"test_input[i]=%d
\n
"
,
test_input
[
i
]);
#endif
/*for (int i=0; i<TBS/8; i++)
printf("test input[%d]=%d \n",i,test_input[i]);*/
//printf("crc32: [0]->0x%08x\n",crc24c(test_input, 32));
// generate signal
if
(
input_fd
==
NULL
)
{
nr_dlsch_encoding
(
test_input
,
subframe
,
dlsch
,
frame_parms
);
}
if
((
i
&
0xf
)
==
0
)
printf
(
"
\n
e %d..%d: "
,
i
,
i
+
15
);
for
(
SNR
=
snr0
;
SNR
<
snr1
;
SNR
+=
snr_step
)
{
n_errors
=
0
;
n_false_positive
=
0
;
for
(
trial
=
0
;
trial
<
n_trials
;
trial
++
)
{
errors_bit_uncoded
=
0
;
for
(
i
=
0
;
i
<
available_bits
;
i
++
)
{
#ifdef DEBUG_CODER
if
((
i
&
0xf
)
==
0
)
printf
(
"
\n
e %d..%d: "
,
i
,
i
+
15
);
#endif
//if (i<16)
// printf("encoder output f[%d] = %d\n",i,dlsch->harq_processes[0]->f[i]);
if
(
dlsch
->
harq_processes
[
0
]
->
f
[
i
]
==
0
)
modulated_input
[
i
]
=
1
.
0
;
///sqrt(2); //QPSK
else
modulated_input
[
i
]
=-
1
.
0
;
///sqrt(2);
//if (i<16) printf("modulated_input[%d] = %d\n",i,modulated_input[i]);
//SNR =10;
SNR_lin
=
pow
(
10
,
SNR
/
10
.
0
);
sigma
=
1
.
0
/
sqrt
(
2
*
SNR_lin
);
channel_output_fixed
[
i
]
=
(
short
)
quantize
(
sigma
/
4
.
0
/
4
.
0
,
modulated_input
[
i
]
+
sigma
*
gaussdouble
(
0
.
0
,
1
.
0
),
qbits
);
//channel_output_fixed[i] = (char)quantize8bit(sigma/4.0,(2.0*modulated_input[i]) - 1.0 + sigma*gaussdouble(0.0,1.0));
//printf("llr[%d]=%d\n",i,channel_output_fixed[i]);
//printf("channel_output_fixed[%d]: %d\n",i,channel_output_fixed[i]);
//channel_output_fixed[i] = (char)quantize(1,channel_output_fixed[i],qbits);
//if (i<16) printf("channel_output_fixed[%d] = %d\n",i,channel_output_fixed[i]);
//Uncoded BER
if
(
channel_output_fixed
[
i
]
<
0
)
channel_output_uncoded
[
i
]
=
1
;
//QPSK demod
else
channel_output_uncoded
[
i
]
=
0
;
if
(
channel_output_uncoded
[
i
]
!=
dlsch
->
harq_processes
[
harq_pid
]
->
f
[
i
])
errors_bit_uncoded
=
errors_bit_uncoded
+
1
;
}
//if (errors_bit_uncoded>10)
//printf("errors bits uncoded %f\n", errors_bit_uncoded);
//if (i<16)
// printf("encoder output f[%d] = %d\n",i,dlsch->harq_processes[0]->f[i]);
if
(
dlsch
->
harq_processes
[
0
]
->
f
[
i
]
==
0
)
modulated_input
[
i
]
=
1
.
0
;
///sqrt(2); //QPSK
else
modulated_input
[
i
]
=
-
1
.
0
;
///sqrt(2);
//if (i<16) printf("modulated_input[%d] = %d\n",i,modulated_input[i]);
//SNR =10;
SNR_lin
=
pow
(
10
,
SNR
/
10
.
0
);
sigma
=
1
.
0
/
sqrt
(
2
*
SNR_lin
);
channel_output_fixed
[
i
]
=
(
short
)
quantize
(
sigma
/
4
.
0
/
4
.
0
,
modulated_input
[
i
]
+
sigma
*
gaussdouble
(
0
.
0
,
1
.
0
),
qbits
);
//channel_output_fixed[i] = (char)quantize8bit(sigma/4.0,(2.0*modulated_input[i]) - 1.0 + sigma*gaussdouble(0.0,1.0));
//printf("llr[%d]=%d\n",i,channel_output_fixed[i]);
//printf("channel_output_fixed[%d]: %d\n",i,channel_output_fixed[i]);
//channel_output_fixed[i] = (char)quantize(1,channel_output_fixed[i],qbits);
//if (i<16) printf("channel_output_fixed[%d] = %d\n",i,channel_output_fixed[i]);
//Uncoded BER
if
(
channel_output_fixed
[
i
]
<
0
)
channel_output_uncoded
[
i
]
=
1
;
//QPSK demod
else
channel_output_uncoded
[
i
]
=
0
;
if
(
channel_output_uncoded
[
i
]
!=
dlsch
->
harq_processes
[
harq_pid
]
->
f
[
i
])
errors_bit_uncoded
=
errors_bit_uncoded
+
1
;
}
//if (errors_bit_uncoded>10)
//printf("errors bits uncoded %f\n", errors_bit_uncoded);
#ifdef DEBUG_CODER
printf
(
"
\n
"
);
exit
(
-
1
);
printf
(
"
\n
"
);
exit
(
-
1
);
#endif
ret
=
nr_dlsch_decoding
(
UE
,
channel_output_fixed
,
&
UE
->
frame_parms
,
dlsch0_ue
,
dlsch0_ue
->
harq_processes
[
0
],
frame
,
nb_symb_sch
,
subframe
,
harq_pid
,
is_crnti
,
llr8_flag
);
if
(
ret
>
dlsch0_ue
->
max_ldpc_iterations
)
n_errors
++
;
//count errors
errors_bit
=
0
;
for
(
i
=
0
;
i
<
TBS
;
i
++
)
{
estimated_output_bit
[
i
]
=
(
estimated_output
[
i
/
8
]
&
(
1
<<
(
i
&
7
)))
>>
(
i
&
7
);
test_input_bit
[
i
]
=
(
test_input
[
i
/
8
]
&
(
1
<<
(
i
&
7
)))
>>
(
i
&
7
);
// Further correct for multiple segments
if
(
estimated_output_bit
[
i
]
!=
test_input_bit
[
i
])
{
errors_bit
++
;
//printf("estimated bits error occurs @%d ",i);
}
}
if
(
errors_bit
>
0
)
{
n_false_positive
++
;
if
(
n_trials
==
1
)
printf
(
"
\n
errors_bit %d (trial %d)
\n
"
,
errors_bit
,
trial
);
}
}
printf
(
"SNR %f, BLER %f (false positive %f)
\n
"
,
SNR
,(
float
)
n_errors
/
(
float
)
n_trials
,(
float
)
n_false_positive
/
(
float
)
n_trials
);
if
((
float
)
n_errors
/
(
float
)
n_trials
<
target_error_rate
)
break
;
}
/*LOG_M("txsigF0.m","txsF0", gNB->common_vars.txdataF[0],frame_length_complex_samples_no_prefix,1,1);
if (gNB->frame_parms.nb_antennas_tx>1)
LOG_M("txsigF1.m","txsF1", gNB->common_vars.txdataF[1],frame_length_complex_samples_no_prefix,1,1);*/
//TODO: loop over slots
/*for (aa=0; aa<gNB->frame_parms.nb_antennas_tx; aa++) {
if (gNB_config->subframe_config.dl_cyclic_prefix_type.value == 1) {
PHY_ofdm_mod(gNB->common_vars.txdataF[aa],
txdata[aa],
frame_parms->ofdm_symbol_size,
12,
frame_parms->nb_prefix_samples,
CYCLIC_PREFIX);
} else {
nr_normal_prefix_mod(gNB->common_vars.txdataF[aa],
txdata[aa],
14,
frame_parms);
}
}
LOG_M("txsig0.m","txs0", txdata[0],frame_length_complex_samples,1,1);
if (gNB->frame_parms.nb_antennas_tx>1)
LOG_M("txsig1.m","txs1", txdata[1],frame_length_complex_samples,1,1);
for (i=0; i<frame_length_complex_samples; i++) {
for (aa=0; aa<frame_parms->nb_antennas_tx; aa++) {
r_re[aa][i] = ((double)(((short *)txdata[aa]))[(i<<1)]);
r_im[aa][i] = ((double)(((short *)txdata[aa]))[(i<<1)+1]);
}
}*/
for
(
i
=
0
;
i
<
2
;
i
++
)
{
printf
(
"gNB %d
\n
"
,
i
);
free_gNB_dlsch
(
gNB
->
dlsch
[
0
][
i
]);
printf
(
"UE %d
\n
"
,
i
);
free_nr_ue_dlsch
(
UE
->
dlsch
[
UE
->
current_thread_id
[
subframe
]][
0
][
i
]);
}
for
(
i
=
0
;
i
<
2
;
i
++
)
{
free
(
s_re
[
i
]);
free
(
s_im
[
i
]);
free
(
r_re
[
i
]);
free
(
r_im
[
i
]);
free
(
txdata
[
i
]);
}
free
(
s_re
);
free
(
s_im
);
free
(
r_re
);
free
(
r_im
);
free
(
txdata
);
if
(
output_fd
)
fclose
(
output_fd
);
if
(
input_fd
)
fclose
(
input_fd
);
return
(
n_errors
);
ret
=
nr_dlsch_decoding
(
UE
,
channel_output_fixed
,
&
UE
->
frame_parms
,
dlsch0_ue
,
dlsch0_ue
->
harq_processes
[
0
],
frame
,
nb_symb_sch
,
subframe
,
harq_pid
,
is_crnti
,
llr8_flag
);
if
(
ret
>
dlsch0_ue
->
max_ldpc_iterations
)
n_errors
++
;
//count errors
errors_bit
=
0
;
for
(
i
=
0
;
i
<
TBS
;
i
++
)
{
estimated_output_bit
[
i
]
=
(
dlsch0_ue
->
harq_processes
[
0
]
->
b
[
i
/
8
]
&
(
1
<<
(
i
&
7
)))
>>
(
i
&
7
);
test_input_bit
[
i
]
=
(
test_input
[
i
/
8
]
&
(
1
<<
(
i
&
7
)))
>>
(
i
&
7
);
// Further correct for multiple segments
if
(
estimated_output_bit
[
i
]
!=
test_input_bit
[
i
])
{
errors_bit
++
;
//printf("estimated bits error occurs @%d ",i);
}
}
if
(
errors_bit
>
0
)
{
n_false_positive
++
;
if
(
n_trials
==
1
)
printf
(
"errors_bit %d (trial %d)
\n
"
,
errors_bit
,
trial
);
}
}
printf
(
"SNR %f, BLER %f (false positive %f)
\n
"
,
SNR
,
(
float
)
n_errors
/
(
float
)
n_trials
,
(
float
)
n_false_positive
/
(
float
)
n_trials
);
if
((
float
)
n_errors
/
(
float
)
n_trials
<
target_error_rate
)
break
;
}
/*LOG_M("txsigF0.m","txsF0", gNB->common_vars.txdataF[0],frame_length_complex_samples_no_prefix,1,1);
if (gNB->frame_parms.nb_antennas_tx>1)
LOG_M("txsigF1.m","txsF1", gNB->common_vars.txdataF[1],frame_length_complex_samples_no_prefix,1,1);*/
//TODO: loop over slots
/*for (aa=0; aa<gNB->frame_parms.nb_antennas_tx; aa++) {
if (gNB_config->subframe_config.dl_cyclic_prefix_type.value == 1) {
PHY_ofdm_mod(gNB->common_vars.txdataF[aa],
txdata[aa],
frame_parms->ofdm_symbol_size,
12,
frame_parms->nb_prefix_samples,
CYCLIC_PREFIX);
} else {
nr_normal_prefix_mod(gNB->common_vars.txdataF[aa],
txdata[aa],
14,
frame_parms);
}
}
LOG_M("txsig0.m","txs0", txdata[0],frame_length_complex_samples,1,1);
if (gNB->frame_parms.nb_antennas_tx>1)
LOG_M("txsig1.m","txs1", txdata[1],frame_length_complex_samples,1,1);
for (i=0; i<frame_length_complex_samples; i++) {
for (aa=0; aa<frame_parms->nb_antennas_tx; aa++) {
r_re[aa][i] = ((double)(((short *)txdata[aa]))[(i<<1)]);
r_im[aa][i] = ((double)(((short *)txdata[aa]))[(i<<1)+1]);
}
}*/
for
(
i
=
0
;
i
<
2
;
i
++
)
{
printf
(
"gNB %d
\n
"
,
i
);
free_gNB_dlsch
(
gNB
->
dlsch
[
0
][
i
]);
printf
(
"UE %d
\n
"
,
i
);
free_nr_ue_dlsch
(
UE
->
dlsch
[
UE
->
current_thread_id
[
subframe
]][
0
][
i
]);
}
for
(
i
=
0
;
i
<
2
;
i
++
)
{
free
(
s_re
[
i
]);
free
(
s_im
[
i
]);
free
(
r_re
[
i
]);
free
(
r_im
[
i
]);
free
(
txdata
[
i
]);
}
free
(
s_re
);
free
(
s_im
);
free
(
r_re
);
free
(
r_im
);
free
(
txdata
);
if
(
output_fd
)
fclose
(
output_fd
);
if
(
input_fd
)
fclose
(
input_fd
);
return
(
n_errors
);
}
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