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Elphel
x393
Commits
0f61407f
Commit
0f61407f
authored
Dec 13, 2017
by
Andrey Filippov
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added DSP control and signal paths
parent
83f0444a
Changes
1
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179 additions
and
108 deletions
+179
-108
phase_rotator.v
dsp/phase_rotator.v
+179
-108
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dsp/phase_rotator.v
View file @
0f61407f
...
@@ -51,7 +51,7 @@ module phase_rotator#(
...
@@ -51,7 +51,7 @@ module phase_rotator#(
input
signed
[
SHIFT_WIDTH
-
1
:
0
]
shift_h
,
//!< subpixel shift horizontal
input
signed
[
SHIFT_WIDTH
-
1
:
0
]
shift_h
,
//!< subpixel shift horizontal
input
signed
[
SHIFT_WIDTH
-
1
:
0
]
shift_v
,
//!< subpixel shift vertical
input
signed
[
SHIFT_WIDTH
-
1
:
0
]
shift_v
,
//!< subpixel shift vertical
// input data CC,CS,SC,SS in column scan order (matching DTT)
// input data CC,CS,SC,SS in column scan order (matching DTT)
input
signed
[
FD_WIDTH
-
1
:
0
]
fd_din
,
//!< frequency domain data in
input
signed
[
FD_WIDTH
-
1
:
0
]
fd_din
,
//!< frequency domain data in
, LATENCY=3 from start
output
reg
signed
[
FD_WIDTH
-
1
:
0
]
fd_out
,
//!< frequency domain data in
output
reg
signed
[
FD_WIDTH
-
1
:
0
]
fd_out
,
//!< frequency domain data in
output
reg
pre_first_out
,
//!< 1 cycle before output data valid
output
reg
pre_first_out
,
//!< 1 cycle before output data valid
output
reg
fd_dv
//!< output data valid
output
reg
fd_dv
//!< output data valid
...
@@ -64,21 +64,16 @@ module phase_rotator#(
...
@@ -64,21 +64,16 @@ module phase_rotator#(
// Signed subpixel shifts in the range [-0.5,0.5) are converted to sign and [0,0.5] and both limits are fit to the same slot as
// Signed subpixel shifts in the range [-0.5,0.5) are converted to sign and [0,0.5] and both limits are fit to the same slot as
// the shift -0.5 : cos((i+0.5)/16*pi), -sin((i+0.5)/16*pi) for i=0..7 is symmetrical around the center (odd for sine, even - cosine)
// the shift -0.5 : cos((i+0.5)/16*pi), -sin((i+0.5)/16*pi) for i=0..7 is symmetrical around the center (odd for sine, even - cosine)
// ROM input MSB - 0- cos, 1 - sin, 3 LSB s - index (0..7). Signs for cos and sin are passed to DSPs
// ROM input MSB - 0- cos, 1 - sin, 3 LSB s - index (0..7). Signs for cos and sin are passed to DSPs
// shift i ROM A[8:3] ROM A[2:0] sign cos sign sin
// shift i sin ROM[9] ROM A[8:3] ROM A[2:0] sign cos sign sin
// 1000000 (-0.5) 000 0 000 0 1
// 1000000 (-0.5) nnn 0 1 0 ~nnn 0 1
// 001 0 001 0 1
// nnn 1 1 0 nnn 0 1
// 010 0 010 0 1
// 011 0 011 0 1
// 100 0 011 1 1
// 101 0 010 1 1
// 110 0 001 1 1
// 111 0 000 1 1
//
//
// 1xxxxxx (<0) nnn
-xxxxxx nnn 0 1
// 1xxxxxx (<0) nnn
s s
-xxxxxx nnn 0 1
//
//
// 0000000 (==0) nnn 0 100 0 0
// 0000000 (==0) nnn 0 0 0 0 0 0
// nnn 1 0 0 1 0 0
//
//
// 0xxxxxx (>0) nnn
xxxxxx nnn 0 0
// 0xxxxxx (>0) nnn
s s
xxxxxx nnn 0 0
reg
[
5
:
0
]
start_d
;
// delayed versions of start (TODO: adjust length)
reg
[
5
:
0
]
start_d
;
// delayed versions of start (TODO: adjust length)
reg
[
7
:
0
]
cntr_h
;
// input sample counter
reg
[
7
:
0
]
cntr_h
;
// input sample counter
...
@@ -87,7 +82,7 @@ module phase_rotator#(
...
@@ -87,7 +82,7 @@ module phase_rotator#(
wire
run_v
;
wire
run_v
;
wire
run_hv
=
run_h
||
run_v
;
wire
run_hv
=
run_h
||
run_v
;
reg
[
2
:
0
]
hv_index
;
// horizontal/vertical index
reg
[
2
:
0
]
hv_index
;
// horizontal/vertical index
reg
[
1
:
0
]
hv
_phase
;
//
// reg [16:0] dsp
_phase; //
reg
hv_sin
;
// 0 - cos, 1 - sin
reg
hv_sin
;
// 0 - cos, 1 - sin
reg
[
SHIFT_WIDTH
-
1
:
0
]
shift_hr
;
reg
[
SHIFT_WIDTH
-
1
:
0
]
shift_hr
;
...
@@ -95,13 +90,16 @@ module phase_rotator#(
...
@@ -95,13 +90,16 @@ module phase_rotator#(
reg
[
SHIFT_WIDTH
-
1
:
0
]
shift_vr
;
reg
[
SHIFT_WIDTH
-
1
:
0
]
shift_vr
;
reg
[
SHIFT_WIDTH
-
1
:
0
]
shift_hv
;
// combined horizonta and vertical shifts to match cntr_mux;
reg
[
SHIFT_WIDTH
-
1
:
0
]
shift_hv
;
// combined horizonta and vertical shifts to match cntr_mux;
reg
sign_cs
;
// sign for cos / sin, feed to DSP
reg
sign_cs
;
// sign for cos / sin, feed to DSP
wire
sign_cs_d
;
// sign_cs delayed by 3 clocks
reg
[
1
:
0
]
sign_cs_r
;
// sign_cs delayed by 5 clocks
reg
[
SHIFT_WIDTH
-
2
:
0
]
rom_a_shift
;
// ~shift absolute value
reg
[
SHIFT_WIDTH
-
2
:
0
]
rom_a_shift
;
// ~shift absolute value
reg
[
2
:
0
]
rom_a_indx
;
// rom index (hor/vert)
reg
[
2
:
0
]
rom_a_indx
;
// rom index (hor/vert)
reg
rom_a_sin
;
// rom cos =0; sin = 1
reg
rom_a_sin
;
// rom cos =0; sin = 1
wire
[
SHIFT_WIDTH
+
2
:
0
]
rom_a
=
{
rom_a_sin
,
rom_a_shift
,
rom_a_indx
};
wire
[
SHIFT_WIDTH
+
2
:
0
]
rom_a
=
{
rom_a_sin
,
rom_a_shift
,
rom_a_indx
};
wire
shift_ends_0
=
shift_hv
[
SHIFT_WIDTH
-
2
:
0
]
==
0
;
wire
shift_ends_0
=
shift_hv
[
SHIFT_WIDTH
-
2
:
0
]
==
0
;
reg
[
1
:
0
]
rom_re_regen
;
reg
[
2
:
0
]
rom_re_regen
;
wire
signed
[
DSP_B_WIDTH
-
1
:
0
]
cos_sin_w
;
wire
signed
[
DSP_B_WIDTH
-
1
:
0
]
cos_sin_w
;
wire
mux_v
=
run_v
&&
cntr_v
[
1
]
;
always
@
(
posedge
clk
)
begin
always
@
(
posedge
clk
)
begin
if
(
rst
)
start_d
<=
0
;
if
(
rst
)
start_d
<=
0
;
...
@@ -109,31 +107,35 @@ module phase_rotator#(
...
@@ -109,31 +107,35 @@ module phase_rotator#(
if
(
start
)
shift_hr
<=
shift_h
;
if
(
start
)
shift_hr
<=
shift_h
;
if
(
start
)
shift_v0
<=
shift_v
;
if
(
start
)
shift_v0
<=
shift_v
;
if
(
start_d
[
5
])
shift_vr
<=
shift_v0
;
if
(
start_d
[
3
])
shift_vr
<=
shift_v0
;
if
(
rst
)
run_h
<=
0
;
if
(
rst
)
run_h
<=
0
;
else
if
(
start
_d
[
0
])
run_h
<=
1
;
else
if
(
start
)
run_h
<=
1
;
else
if
(
&
cntr_h
)
run_h
<=
0
;
else
if
(
&
cntr_h
)
run_h
<=
0
;
if
(
!
run_h
)
cntr_h
<=
0
;
if
(
!
run_h
)
cntr_h
<=
0
;
else
cntr_h
<=
cntr_h
+
1
;
else
cntr_h
<=
cntr_h
+
1
;
if
(
!
run_hv
)
hv_phase
<=
0
;
//
if (!run_hv) hv_phase <= 0;
else
hv_phase
<=
hv_phase
+
1
;
//
else hv_phase <= hv_phase + 1;
// combine horizontal and vertical counters and shifts to feed to ROM
// combine horizontal and vertical counters and shifts to feed to ROM
hv_index
<=
(
run_v
&&
cntr_v
[
1
])
?
cntr_v
[
4
:
2
]
:
cntr_h
[
7
:
5
]
;
// input data "down first" (transposed)
hv_index
<=
mux_v
?
cntr_v
[
4
:
2
]
:
cntr_h
[
7
:
5
]
;
// input data "down first" (transposed)
hv_sin
<=
(
run_v
&&
cntr_v
[
1
])
?
cntr_v
[
0
]
:
cntr_h
[
0
]
;
hv_sin
<=
mux_v
?
cntr_v
[
0
]
:
cntr_h
[
0
]
;
shift_hv
<=
(
run_v
&&
cntr_v
[
1
])
?
shift_vr
:
shift_hr
;
shift_hv
<=
mux_v
?
shift_vr
:
shift_hr
;
// convert index, shift to ROM address
// convert index, shift to ROM address
rom_a_indx
<=
shift_ends_0
?
(
shift_hv
[
SHIFT_WIDTH
-
1
]
?{
1'b0
,
hv_index
[
2
]
?~
hv_index
[
1
:
0
]
:
hv_index
[
1
:
0
]
}:
3'h4
)
:
hv_index
;
rom_a_indx
<=
shift_ends_0
?
(
shift_hv
[
SHIFT_WIDTH
-
1
]
?
(
{
3
{~
hv_sin
}}
^
hv_index
)
:
+{
2'b0
,
hv_sin
}
)
:
hv_index
;
rom_a_shift
<=
shift_hv
[
SHIFT_WIDTH
-
1
]
?
-
shift_hv
[
SHIFT_WIDTH
-
2
:
0
]
:
shift_hv
[
SHIFT_WIDTH
-
2
:
0
]
;
rom_a_shift
<=
shift_hv
[
SHIFT_WIDTH
-
1
]
?
-
shift_hv
[
SHIFT_WIDTH
-
2
:
0
]
:
shift_hv
[
SHIFT_WIDTH
-
2
:
0
]
;
rom_a_sin
<=
hv_sin
;
rom_a_sin
<=
shift_ends_0
?
shift_hv
[
SHIFT_WIDTH
-
1
]
:
hv_sin
;
sign_cs
<=
shift_hv
[
SHIFT_WIDTH
-
1
]
&
(
hv_sin
|
(
shift_ends_0
&
hv_index
[
2
]))
;
// sign_cs <= shift_hv[SHIFT_WIDTH-1] & ( hv_sin | (shift_ends_0 & hv_index[2]));
sign_cs
<=
shift_hv
[
SHIFT_WIDTH
-
1
]
&
hv_sin
;
rom_re_regen
<=
{
rom_re_regen
[
1
:
0
]
,
run_hv
};
rom_re_regen
<=
{
rom_re_regen
[
0
]
,
run_hv
};
sign_cs_r
<=
{
sign_cs_r
[
0
]
,
sign_cs_d
};
end
end
...
@@ -148,6 +150,18 @@ module phase_rotator#(
...
@@ -148,6 +150,18 @@ module phase_rotator#(
.
dout
(
{
run_v
,
cntr_v
}
)
// output[0:0]
.
dout
(
{
run_v
,
cntr_v
}
)
// output[0:0]
)
;
)
;
dly_var
#(
.
WIDTH
(
1
)
,
.
DLY_WIDTH
(
4
)
)
dly_cntrv_i
(
.
clk
(
clk
)
,
// input
.
rst
(
rst
)
,
// input
.
dly
(
4'h2
)
,
// input[3:0]
.
din
(
sign_cs
)
,
// input[0:0]
.
dout
(
sign_cs_d
)
// output[0:0]
)
;
ram18tp_var_w_var_r
#(
ram18tp_var_w_var_r
#(
.
REGISTERS_A
(
1
)
,
.
REGISTERS_A
(
1
)
,
.
REGISTERS_B
(
1
)
,
.
REGISTERS_B
(
1
)
,
...
@@ -160,8 +174,8 @@ module phase_rotator#(
...
@@ -160,8 +174,8 @@ module phase_rotator#(
.
clk_a
(
clk
)
,
// input
.
clk_a
(
clk
)
,
// input
.
addr_a
(
rom_a
)
,
// input[9:0]
.
addr_a
(
rom_a
)
,
// input[9:0]
.
en_a
(
rom_re_regen
[
0
])
,
// input
.
en_a
(
rom_re_regen
[
1
])
,
// input
.
regen_a
(
rom_re_regen
[
1
])
,
// input
.
regen_a
(
rom_re_regen
[
2
])
,
// input
.
we_a
(
1'b0
)
,
// input
.
we_a
(
1'b0
)
,
// input
.
data_out_a
(
cos_sin_w
)
,
// output[17:0]
.
data_out_a
(
cos_sin_w
)
,
// output[17:0]
.
data_in_a
(
18'b0
)
,
// input[17:0]
.
data_in_a
(
18'b0
)
,
// input[17:0]
...
@@ -174,6 +188,64 @@ module phase_rotator#(
...
@@ -174,6 +188,64 @@ module phase_rotator#(
.
data_in_b
(
18'b0
)
// input[17:0]
.
data_in_b
(
18'b0
)
// input[17:0]
)
;
)
;
// Registers for DSP control
reg
ceb1_1
,
ceb1_2
,
ceb1_3
,
ceb1_4
;
reg
ceb2_1
,
ceb2_2
,
ceb2_3
,
ceb2_4
;
reg
selb_1
,
selb_2
,
selb_3
,
selb_4
;
wire
signed
[
DSP_A_WIDTH
-
1
:
0
]
ain_34
=
pout_1
[
DSP_P_WIDTH
-
1
-:
FD_WIDTH
]
;
// bit select from pout_1
wire
signed
[
DSP_A_WIDTH
-
1
:
0
]
din_34
=
pout_2
[
DSP_P_WIDTH
-
1
-:
FD_WIDTH
]
;
// bit select from pout_1
reg
cea1_1
,
cea1_2
,
cea1_3
,
cea1_4
;
reg
cea2_1
,
cea2_2
,
ced_3
,
ced_4
;
reg
sela_1
,
sela_2
,
end_3
,
end_4
;
reg
cead_1
,
cead_2
,
cead_3
,
cead_4
;
reg
negm_1
,
negm_2
,
negm_3
,
negm_4
;
reg
accum_1
,
accum_2
,
accum_3
,
accum_4
;
wire
signed
[
DSP_P_WIDTH
-
1
:
0
]
pout_1
;
wire
signed
[
DSP_P_WIDTH
-
1
:
0
]
pout_2
;
wire
signed
[
DSP_P_WIDTH
-
1
:
0
]
pout_3
;
wire
signed
[
DSP_P_WIDTH
-
1
:
0
]
pout_4
;
reg
omux_sel
;
wire
pre_dv
=
|
ph
[
16
:
13
]
;
reg
[
16
:
0
]
ph
;
// DSP pre phase,
always
@
(
posedge
clk
)
begin
if
(
rst
)
ph
<=
0
;
else
ph
<=
{
ph
[
15
:
0
]
,
run_h
&
~
cntr_h
[
0
]
&
cntr_h
[
1
]
};
cea1_1
<=
ph
[
0
]
;
cea2_1
<=
ph
[
2
]
;
cea1_2
<=
ph
[
1
]
;
cea2_2
<=
ph
[
3
]
;
ceb1_1
<=
ph
[
3
]
;
ceb2_1
<=
ph
[
2
]
;
ceb1_2
<=
ph
[
2
]
|
ph
[
3
]
;
ceb2_2
<=
ph
[
3
]
;
cead_1
<=
|
ph
[
5
:
2
]
;
cead_2
<=
|
ph
[
6
:
3
]
;
// 1 cycle ahead
sela_1
<=
ph
[
2
]
|
ph
[
4
]
;
sela_2
<=
ph
[
3
]
|
ph
[
5
]
;
selb_1
<=
ph
[
2
]
|
ph
[
5
]
;
selb_2
<=
ph
[
3
]
|
ph
[
6
]
;
// 0 1 0 0
negm_1
<=
(
ph
[
3
]
^
sign_cs_d
)
|
(
~
ph
[
4
]
^
sign_cs_d
)
|
(
ph
[
5
]
^
sign_cs_r
[
1
])
|
(
ph
[
6
]
^
sign_cs_r
[
1
])
;
negm_2
<=
(
ph
[
4
]
^
sign_cs_d
)
|
(
~
ph
[
5
]
^
sign_cs_d
)
|
(
ph
[
6
]
^
sign_cs_r
[
1
])
|
(
ph
[
7
]
^
sign_cs_r
[
1
])
;
accum_1
<=
ph
[
4
]
|
ph
[
6
]
;
accum_2
<=
ph
[
5
]
|
ph
[
7
]
;
// vertical shift DSPs
cea1_3
<=
ph
[
6
]
;
ced_3
<=
ph
[
7
]
;
cea1_4
<=
ph
[
8
]
;
ced_4
<=
ph
[
9
]
;
ceb1_3
<=
ph
[
9
]
;
ceb2_3
<=
ph
[
8
]
;
ceb1_4
<=
ph
[
8
]
|
ph
[
9
]
;
ceb2_4
<=
ph
[
9
]
;
cead_3
<=
|
ph
[
11
:
8
]
;
cead_4
<=
|
ph
[
12
:
9
]
;
// 1 cycle ahead
end_3
<=
ph
[
10
]
|
ph
[
8
]
;
end_4
<=
ph
[
11
]
|
ph
[
9
]
;
selb_3
<=
ph
[
8
]
|
ph
[
11
]
;
selb_4
<=
ph
[
9
]
|
ph
[
12
]
;
negm_4
<=
(
ph
[
9
]
^
sign_cs_d
)
|
(
~
ph
[
10
]
^
sign_cs_d
)
|
(
ph
[
11
]
^
sign_cs_r
[
1
])
|
(
ph
[
12
]
^
sign_cs_r
[
1
])
;
negm_3
<=
(
ph
[
10
]
^
sign_cs_d
)
|
(
~
ph
[
11
]
^
sign_cs_d
)
|
(
ph
[
12
]
^
sign_cs_r
[
1
])
|
(
ph
[
13
]
^
sign_cs_r
[
1
])
;
accum_3
<=
ph
[
10
]
|
ph
[
12
]
;
accum_4
<=
ph
[
11
]
|
ph
[
13
]
;
omux_sel
<=
ph
[
13
]
|
ph
[
15
]
;
fd_dv
<=
pre_dv
;
if
(
pre_dv
)
fd_out
<=
omux_sel
?
pout_4
[
DSP_P_WIDTH
-
1
-:
FD_WIDTH
]
:
pout_3
[
DSP_P_WIDTH
-
1
-:
FD_WIDTH
]
;
pre_first_out
<=
ph
[
12
]
;
end
/*
output reg signed [FD_WIDTH-1:0] fd_out, //!< frequency domain data in
*/
// horizontal shift stage
// horizontal shift stage
dsp_ma_preadd
#(
dsp_ma_preadd
#(
...
@@ -183,25 +255,25 @@ module phase_rotator#(
...
@@ -183,25 +255,25 @@ module phase_rotator#(
.
A_INPUT
(
"DIRECT"
)
,
.
A_INPUT
(
"DIRECT"
)
,
.
B_INPUT
(
"DIRECT"
)
.
B_INPUT
(
"DIRECT"
)
)
dsp_1_i
(
)
dsp_1_i
(
.
clk
()
,
// input
.
clk
(
clk
)
,
// input
.
rst
()
,
// input
.
rst
(
rst
)
,
// input
.
bin
(
)
,
// input[17:0] signed
.
bin
(
cos_sin_w
)
,
// input[17:0] signed
.
ceb1
()
,
// input
.
ceb1
(
ceb1_1
)
,
// input
.
ceb2
()
,
// input
.
ceb2
(
ceb2_1
)
,
// input
.
selb
()
,
// input
.
selb
(
selb_1
)
,
// input
.
ain
()
,
// input[24:0] signed
.
ain
(
fd_din
)
,
// input[24:0] signed
.
cea1
()
,
// input
.
cea1
(
cea1_1
)
,
// input
.
cea2
()
,
// input
.
cea2
(
cea2_1
)
,
// input
.
din
()
,
// input[24:0] signed
.
din
(
25'b0
)
,
// input[24:0] signed
.
ced
()
,
// input
.
ced
(
1'b0
)
,
// input
.
cead
()
,
// input
.
cead
(
cead_1
)
,
// input
.
sela
()
,
// input
.
sela
(
sela_1
)
,
// input
.
en_a
()
,
// input
.
en_a
(
1'b1
)
,
// input
.
en_d
()
,
// input
.
en_d
(
1'b0
)
,
// input
.
sub_a
()
,
// input
.
sub_a
(
1'b0
)
,
// input
.
neg_m
()
,
// input
.
neg_m
(
negm_1
)
,
// input
.
accum
()
,
// input
.
accum
(
accum_1
)
,
// input
.
pout
()
// output[47:0] signed
.
pout
(
pout_1
)
// output[47:0] signed
)
;
)
;
dsp_ma_preadd
#(
dsp_ma_preadd
#(
...
@@ -211,25 +283,25 @@ module phase_rotator#(
...
@@ -211,25 +283,25 @@ module phase_rotator#(
.
A_INPUT
(
"DIRECT"
)
,
.
A_INPUT
(
"DIRECT"
)
,
.
B_INPUT
(
"CASCADE"
)
.
B_INPUT
(
"CASCADE"
)
)
dsp_2_i
(
)
dsp_2_i
(
.
clk
()
,
// input
.
clk
(
clk
)
,
// input
.
rst
()
,
// input
.
rst
(
rst
)
,
// input
.
bin
(
)
,
// input[17:0] signed
.
bin
(
cos_sin_w
)
,
// input[17:0] signed
.
ceb1
()
,
// input
.
ceb1
(
ceb1_2
)
,
// input
.
ceb2
()
,
// input
.
ceb2
(
ceb2_2
)
,
// input
.
selb
()
,
// input
.
selb
(
selb_2
)
,
// input
.
ain
()
,
// input[24:0] signed
.
ain
(
fd_din
)
,
// input[24:0] signed
.
cea1
()
,
// input
.
cea1
(
cea1_2
)
,
// input
.
cea2
()
,
// input
.
cea2
(
cea2_2
)
,
// input
.
din
()
,
// input[24:0] signed
.
din
(
25'b0
)
,
// input[24:0] signed
.
ced
()
,
// input
.
ced
(
1'b0
)
,
// input
.
cead
()
,
// input
.
cead
(
cead_2
)
,
// input
.
sela
()
,
// input
.
sela
(
sela_2
)
,
// input
.
en_a
()
,
// input
.
en_a
(
1'b1
)
,
// input
.
en_d
()
,
// input
.
en_d
(
1'b0
)
,
// input
.
sub_a
()
,
// input
.
sub_a
(
1'b0
)
,
// input
.
neg_m
()
,
// input
.
neg_m
(
negm_2
)
,
// input
.
accum
()
,
// input
.
accum
(
accum_2
)
,
// input
.
pout
()
// output[47:0] signed
.
pout
(
pout_2
)
// output[47:0] signed
)
;
)
;
// vertical shift stage
// vertical shift stage
...
@@ -241,25 +313,25 @@ module phase_rotator#(
...
@@ -241,25 +313,25 @@ module phase_rotator#(
.
A_INPUT
(
"DIRECT"
)
,
.
A_INPUT
(
"DIRECT"
)
,
.
B_INPUT
(
"DIRECT"
)
.
B_INPUT
(
"DIRECT"
)
)
dsp_3_i
(
)
dsp_3_i
(
.
clk
()
,
// input
.
clk
(
clk
)
,
// input
.
rst
()
,
// input
.
rst
(
rst
)
,
// input
.
bin
(
)
,
// input[17:0] signed
.
bin
(
cos_sin_w
)
,
// input[17:0] signed
.
ceb1
()
,
// input
.
ceb1
(
ceb1_3
)
,
// input
.
ceb2
()
,
// input
.
ceb2
(
ceb2_3
)
,
// input
.
selb
()
,
// input
.
selb
(
selb_3
)
,
// input
.
ain
()
,
// input[24:0] signed
.
ain
(
ain_34
)
,
// input[24:0] signed
.
cea1
()
,
// input
.
cea1
(
cea1_3
)
,
// input
.
cea2
()
,
// input
.
cea2
(
1'b0
)
,
// input
.
din
()
,
// input[24:0] signed
.
din
(
din_34
)
,
// input[24:0] signed
.
ced
()
,
// input
.
ced
(
ced_3
)
,
// input
.
cead
()
,
// input
.
cead
(
cead_3
)
,
// input
.
sela
()
,
// input
.
sela
(
1'b0
)
,
// input
.
en_a
()
,
// input
.
en_a
(
~
end_3
)
,
// input
.
en_d
()
,
// input
.
en_d
(
end_3
)
,
// input
.
sub_a
()
,
// input
.
sub_a
(
1'b0
)
,
// input
.
neg_m
()
,
// input
.
neg_m
(
negm_3
)
,
// input
.
accum
()
,
// input
.
accum
(
accum_3
)
,
// input
.
pout
()
// output[47:0] signed
.
pout
(
pout_3
)
// output[47:0] signed
)
;
)
;
dsp_ma_preadd
#(
dsp_ma_preadd
#(
...
@@ -269,27 +341,26 @@ module phase_rotator#(
...
@@ -269,27 +341,26 @@ module phase_rotator#(
.
A_INPUT
(
"DIRECT"
)
,
.
A_INPUT
(
"DIRECT"
)
,
.
B_INPUT
(
"CASCADE"
)
.
B_INPUT
(
"CASCADE"
)
)
dsp_4_i
(
)
dsp_4_i
(
.
clk
()
,
// input
.
clk
(
clk
)
,
// input
.
rst
()
,
// input
.
rst
(
rst
)
,
// input
.
bin
(
)
,
// input[17:0] signed
.
bin
(
cos_sin_w
)
,
// input[17:0] signed
.
ceb1
()
,
// input
.
ceb1
(
ceb1_4
)
,
// input
.
ceb2
()
,
// input
.
ceb2
(
ceb2_4
)
,
// input
.
selb
()
,
// input
.
selb
(
selb_4
)
,
// input
.
ain
()
,
// input[24:0] signed
.
ain
(
ain_34
)
,
// input[24:0] signed
.
cea1
()
,
// input
.
cea1
(
cea1_4
)
,
// input
.
cea2
()
,
// input
.
cea2
(
1'b0
)
,
// input
.
din
()
,
// input[24:0] signed
.
din
(
din_34
)
,
// input[24:0] signed
.
ced
()
,
// input
.
ced
(
ced_4
)
,
// input
.
cead
()
,
// input
.
cead
(
cead_4
)
,
// input
.
sela
()
,
// input
.
sela
(
1'b0
)
,
// input
.
en_a
()
,
// input
.
en_a
(
~
end_4
)
,
// input
.
en_d
()
,
// input
.
en_d
(
end_4
)
,
// input
.
sub_a
()
,
// input
.
sub_a
(
1'b0
)
,
// input
.
neg_m
()
,
// input
.
neg_m
(
negm_4
)
,
// input
.
accum
()
,
// input
.
accum
(
accum_4
)
,
// input
.
pout
()
// output[47:0] signed
.
pout
(
pout_4
)
// output[47:0] signed
)
;
)
;
endmodule
endmodule
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