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Elphel
x393
Commits
6bafd2c5
Commit
6bafd2c5
authored
Apr 26, 2015
by
Andrey Filippov
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working on simulation modules for axi_hp
parent
e878fd92
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axi_hp_rd.v
simulation_modules/axi_hp_rd.v
+73
-0
axi_hp_wr.v
simulation_modules/axi_hp_wr.v
+375
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simulation_modules/axi_hp_rd.v
0 → 100644
View file @
6bafd2c5
/*******************************************************************************
* Module: axi_hp_rd
* Date:2015-04-25
* Author: andrey
* Description: Simplified model of AXI_HP read channel (64-bit only)
*
* Copyright (c) 2015 <set up in Preferences-Verilog/VHDL Editor-Templates> .
* axi_hp_rd.v is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* axi_hp_rd.v is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/> .
*******************************************************************************/
`timescale
1
ns
/
1
ps
module
axi_hp_rd
#(
parameter
[
1
:
0
]
HP_PORT
=
0
)(
// AXI signals
input
aclk
,
output
aresetn
,
// do not use?
// read address
input
[
31
:
0
]
araddr
,
input
arvalid
,
output
arready
,
input
[
5
:
0
]
arid
,
input
[
1
:
0
]
arlock
,
input
[
3
:
0
]
arcache
,
input
[
2
:
0
]
arprot
,
input
[
3
:
0
]
arlen
,
input
[
2
:
0
]
arsize
,
input
[
1
:
0
]
arburst
,
input
[
3
:
0
]
arqos
,
// read data
output
[
63
:
0
]
rdata
,
output
rvalid
,
input
rready
,
output
[
5
:
0
]
rid
,
output
rlast
,
output
[
2
:
0
]
rresp
,
// PL extra (non-AXI) signals
output
[
7
:
0
]
rcount
,
output
[
2
:
0
]
racount
,
input
rdissuecap1en
,
// Simulation signals - use same aclk
output
[
31
:
0
]
sim_rd_address
,
output
[
5
:
0
]
sim_rid
,
output
sim_rd_valid
,
input
sim_rd_ready
,
input
[
63
:
0
]
sim_rd_data
,
input
[
31
:
0
]
reg_addr
,
input
reg_wr
,
input
reg_rd
,
input
[
31
:
0
]
reg_din
,
output
[
31
:
0
]
reg_dout
)
;
localparam
AFI_BASECTRL
=
32'hf8008000
+
(
HP
<
PORT
<<
12
)
;
localparam
AFI_RDCHAN_CTRL
=
AFI_BASECTRL
+
'h00
;
localparam
AFI_RDCHAN_ISSUINGCAP
=
AFI_BASECTRL
+
'h4
;
localparam
AFI_RDQOS
=
AFI_BASECTRL
+
'h8
;
localparam
AFI_RDDATAFIFO_LEVEL
=
AFI_BASECTRL
+
'hc
;
localparam
AFI_RDDEBUG
=
AFI_BASECTRL
+
'h10
;
endmodule
simulation_modules/axi_hp_wr.v
0 → 100644
View file @
6bafd2c5
/*******************************************************************************
* Module: axi_hp_wr
* Date:2015-04-25
* Author: andrey
* Description: Simplified model of AXI_HP write channel (64-bit only)
*
* Copyright (c) 2015 <set up in Preferences-Verilog/VHDL Editor-Templates> .
* axi_hp_wr.v is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* axi_hp_wr.v is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/> .
*******************************************************************************/
`timescale
1
ns
/
1
ps
module
axi_hp_wr
#(
parameter
[
1
:
0
]
HP_PORT
=
0
)
(
input
rst
,
// AXI signals
input
aclk
,
output
aresetn
,
// do not use?
// write address
input
[
31
:
0
]
awaddr
,
input
awvalid
,
output
awready
,
input
[
5
:
0
]
awid
,
input
[
1
:
0
]
awlock
,
// verify the corerct values are here
input
[
3
:
0
]
awcache
,
// verify the corerct values are here
input
[
2
:
0
]
awprot
,
// verify the corerct values are here
input
[
3
:
0
]
awlen
,
input
[
2
:
0
]
awsize
,
input
[
1
:
0
]
awburst
,
input
[
3
:
0
]
awqos
,
// verify the correct values are here
// write data
input
[
63
:
0
]
wdata
,
input
wvalid
,
output
wready
,
input
[
5
:
0
]
wid
,
input
wlast
,
input
[
7
:
0
]
wstrb
,
// write response
output
bvalid
,
input
bready
,
output
[
5
:
0
]
bid
,
output
[
1
:
0
]
bresp
,
// PL extra (non-AXI) signals
output
[
7
:
0
]
wcount
,
output
[
5
:
0
]
wacount
,
// racount has only 3 bits
input
wrissuecap1en
,
// do not use yet
// Simulation signals - use same aclk
output
[
31
:
0
]
sim_wr_address
,
output
[
5
:
0
]
sim_wid
,
output
sim_wr_valid
,
// ready to provide simulation data
input
sim_wr_ready
,
// simulation may pause this channel by keeping this signal inactive
output
[
63
:
0
]
sim_wr_data
,
output
[
7
:
0
]
sim_wr_stb
,
input
[
3
:
0
]
sim_bresp_latency
,
// latency in writeing data outside of the module
output
[
2
:
0
]
sim_wr_cap
,
output
[
3
:
0
]
sim_wr_qos
,
input
[
31
:
0
]
reg_addr
,
input
reg_wr
,
input
reg_rd
,
input
[
31
:
0
]
reg_din
,
output
[
31
:
0
]
reg_dout
)
;
// localparam ADDRESS_BITS=32;
localparam
AFI_BASECTRL
=
32'hf8008000
+
(
HP_PORT
<<
12
)
;
localparam
AFI_WRCHAN_CTRL
=
AFI_BASECTRL
+
'h14
;
localparam
AFI_WRCHAN_ISSUINGCAP
=
AFI_BASECTRL
+
'h18
;
localparam
AFI_WRQOS
=
AFI_BASECTRL
+
'h1c
;
localparam
AFI_WRDATAFIFO_LEVEL
=
AFI_BASECTRL
+
'h20
;
localparam
AFI_WRDEBUG
=
AFI_BASECTRL
+
'h24
;
// SuppressThisWarning VEditor - not yet used
localparam
VALID_AWLOCK
=
2'b0
;
// TODO
localparam
VALID_AWCACHE
=
4'b0
;
//
localparam
VALID_AWPROT
=
3'b0
;
localparam
VALID_AWLOCK_MASK
=
2'b11
;
// TODO
localparam
VALID_AWCACHE_MASK
=
4'b1111
;
//
localparam
VALID_AWPROT_MASK
=
3'b111
;
reg
[
3
:
0
]
WrDataThreshold
=
'hf
;
reg
[
1
:
0
]
WrCmdReleaseMode
=
0
;
reg
QosHeadOfCmdQEn
=
0
;
reg
FabricOutCmdEn
=
0
;
reg
FabricQosEn
=
1
;
reg
en32BitEn
=
0
;
// verify it i 0
reg
[
2
:
0
]
wrIssueCap1
=
0
;
reg
[
2
:
0
]
wrIssueCap0
=
7
;
reg
[
3
:
0
]
staticQos
=
0
;
wire
[
3
:
0
]
wr_qos_in
;
wire
[
3
:
0
]
wr_qos_out
;
wire
aw_nempty
;
wire
w_nempty
;
wire
enough_data
;
// enough data to start a new burst
wire
[
11
:
3
]
next_wr_address
;
// bits that are incrtemented in 64-bit mode (higher are kept according to AXI 4KB inc. limit)
reg
[
31
:
0
]
write_address
;
wire
fifo_wd_rd
;
// read data fifo
wire
last_confirmed_write
;
wire
[
5
:
0
]
awid_out
;
// verify it matches wid_out when outputting data
wire
[
1
:
0
]
awburst_out
;
wire
[
2
:
0
]
awsize_out
;
// verify it is 3'h3
wire
[
3
:
0
]
awlen_out
;
wire
[
31
:
0
]
awaddr_out
;
wire
[
5
:
0
]
wid_out
;
wire
[
7
:
0
]
wstrb_out
;
wire
[
63
:
0
]
wdata_out
;
reg
fifo_data_we_d
;
reg
fifo_addr_we_d
;
reg
[
3
:
0
]
write_left
;
reg
[
1
:
0
]
wburst
;
// registered burst type
reg
[
3
:
0
]
wlen
;
// registered awlen type (for wrapped over transfers)
wire
start_write_burst_w
;
wire
write_in_progress_w
;
// should go inactive last confirmed upstream cycle
reg
write_in_progress
;
reg
[
7
:
0
]
num_full_data
=
0
;
// Number of full data bursts in FIFO
wire
[
5
:
0
]
wresp_num_in_fifo
;
reg
was_wresp_re
=
0
;
wire
wresp_re
;
// documentation sais : "When set, allows the priority of a transaction at the head of the WrCmdQ to be promoted if higher
// priority transactions are backed up behind it." Whqt about demotion? Assuming it is not demoted
assign
sim_wr_qos
=
(
QosHeadOfCmdQEn
&&
(
wr_qos_in
>
wr_qos_out
))
?
wr_qos_in
:
wr_qos_out
;
assign
sim_wr_cap
=
(
FabricOutCmdEn
&&
wrissuecap1en
)
?
wrIssueCap1
:
wrIssueCap0
;
assign
wr_qos_in
=
FabricQosEn
?
(
awqos
&
{
4
{
awvalid
}}
)
:
staticQos
;
//awqos & {4{awvalid}}
assign
aresetn
=
~
rst
;
// probably not needed at all - docs say "do not use"
// Only supported control register fields
assign
reg_dout
=
(
reg_rd
&&
(
reg_addr
==
AFI_WRDATAFIFO_LEVEL
))
?
{
24'b0
,
wcount
}:
(
(
reg_rd
&&
(
reg_addr
==
AFI_WRCHAN_CTRL
))
?
{
20'b0
,
WrDataThreshold
,
2'b0
,
WrCmdReleaseMode
,
QosHeadOfCmdQEn
,
FabricOutCmdEn
,
FabricQosEn
,
en32BitEn
}:
(
(
reg_rd
&&
(
reg_addr
==
AFI_WRCHAN_ISSUINGCAP
))
?
{
25'b0
,
wrIssueCap1
,
1'b0
,
wrIssueCap0
}:
(
(
reg_rd
&&
(
reg_addr
==
AFI_WRQOS
))
?
{
28'b0
,
staticQos
}:
32'bz
)))
;
always
@
(
posedge
aclk
or
posedge
rst
)
begin
if
(
rst
)
begin
WrDataThreshold
<=
'hf
;
WrCmdReleaseMode
<=
0
;
QosHeadOfCmdQEn
<=
0
;
FabricOutCmdEn
<=
0
;
FabricQosEn
<=
1
;
en32BitEn
<=
0
;
end
else
if
(
reg_wr
&&
(
reg_addr
==
AFI_WRCHAN_CTRL
))
begin
WrDataThreshold
<=
reg_din
[
11
:
8
]
;
WrCmdReleaseMode
<=
reg_din
[
5
:
4
]
;
QosHeadOfCmdQEn
<=
reg_din
[
3
]
;
FabricOutCmdEn
<=
reg_din
[
2
]
;
FabricQosEn
<=
reg_din
[
1
]
;
en32BitEn
<=
reg_din
[
0
]
;
end
if
(
rst
)
begin
wrIssueCap1
<=
0
;
wrIssueCap0
<=
7
;
end
else
if
(
reg_wr
&&
(
reg_addr
==
AFI_WRCHAN_ISSUINGCAP
))
begin
wrIssueCap1
<=
reg_din
[
6
:
4
]
;
wrIssueCap0
<=
reg_din
[
2
:
0
]
;
end
if
(
rst
)
begin
staticQos
<=
0
;
end
else
if
(
reg_wr
&&
(
reg_addr
==
AFI_WRQOS
))
begin
staticQos
<=
reg_din
[
3
:
0
]
;
end
end
// generate ready signals for address and data
assign
wready
=
!
wcount
[
7
]
&&
(
!
(
&
wcount
[
6
:
0
])
||
!
fifo_data_we_d
)
;
always
@
(
posedge
rst
or
posedge
aclk
)
begin
if
(
rst
)
fifo_data_we_d
<=
0
;
else
fifo_data_we_d
<=
wready
&&
wvalid
;
end
assign
awready
=
!
wacount
[
5
]
&&
(
!
(
&
wacount
[
4
:
0
])
||
!
fifo_addr_we_d
)
;
always
@
(
posedge
rst
or
posedge
aclk
)
begin
if
(
rst
)
fifo_addr_we_d
<=
0
;
else
fifo_addr_we_d
<=
awready
&&
awvalid
;
end
// Count full data bursts ready in FIFO
always
@
(
posedge
rst
or
posedge
aclk
)
begin
if
(
rst
)
num_full_data
<=
0
;
else
if
(
wvalid
&&
wready
&&
wlast
&&
!
start_write_burst_w
)
num_full_data
<=
num_full_data
+
1
;
else
if
(
!
(
wvalid
&&
wready
&&
wlast
)
&&
start_write_burst_w
)
num_full_data
<=
num_full_data
-
1
;
end
assign
sim_wr_address
=
write_address
;
assign
enough_data
=|
num_full_data
||
((
WrCmdReleaseMode
==
2'b01
)
&&
(
wcount
>
{
4'b0
,
WrDataThreshold
}
))
;
assign
fifo_wd_rd
=
write_in_progress
&&
w_nempty
&&
sim_wr_ready
;
assign
sim_wr_valid
=
write_in_progress
&&
w_nempty
;
// for continuing writes
assign
last_confirmed_write
=
(
write_left
==
0
)
&&
fifo_wd_rd
;
assign
start_write_burst_w
=
aw_nempty
&&
enough_data
&&
(
!
write_in_progress
||
last_confirmed_write
)
;
assign
write_in_progress_w
=
(
aw_nempty
&&
enough_data
)
||
(
write_in_progress
&&
!
last_confirmed_write
)
;
// AXI: Bursts should not cross 4KB boundaries (... and to limit size of the address incrementer)
// in 64 bit mode - low 3 bits are preserved, next 9 are incremented
assign
next_wr_address
[
11
:
3
]
=
wburst
[
1
]
?
(
wburst
[
0
]
?
{
9'bx
}:
((
write_address
[
11
:
3
]
+
1
)
&
{
5'h1f
,
~
wlen
[
3
:
0
]
}
))
:
(
wburst
[
0
]
?
(
write_address
[
11
:
3
]
+
1
)
:
(
write_address
[
11
:
3
]))
;
assign
sim_wr_data
=
wdata_out
;
assign
sim_wid
=
wid_out
;
assign
sim_wr_stb
=
wstrb_out
;
always
@
(
posedge
aclk
)
begin
if
(
start_write_burst_w
)
begin
if
(
awid_out
!=
wid_out
)
begin
$
display
(
"%m: at time %t ERROR: awid=%h, awid=%h"
,
$
time
,
awid_out
,
wid_out
)
;
$
stop
;
end
if
(
awsize_out
!=
3'h3
)
begin
$
display
(
"%m: at time %t ERROR: awsize_out=%h, currently only 'h3 (8 bytes) is valid"
,
$
time
,
awsize_out
)
;
$
stop
;
end
end
if
(
awvalid
&&
awready
)
begin
if
(((
awlock
^
VALID_AWLOCK
)
&
VALID_AWLOCK_MASK
)
!=
0
)
begin
$
display
(
"%m: at time %t ERROR: awlock = %h, valid %h with mask %h"
,
$
time
,
awlock
,
VALID_AWLOCK
,
VALID_AWLOCK_MASK
)
;
$
stop
;
end
if
(((
awcache
^
VALID_AWCACHE
)
&
VALID_AWCACHE_MASK
)
!=
0
)
begin
$
display
(
"%m: at time %t ERROR: awcache = %h, valid %h with mask %h"
,
$
time
,
awcache
,
VALID_AWCACHE
,
VALID_AWCACHE_MASK
)
;
$
stop
;
end
if
(((
awprot
^
VALID_AWPROT
)
&
VALID_AWPROT_MASK
)
!=
0
)
begin
$
display
(
"%m: at time %t ERROR: awprot = %h, valid %h with mask %h"
,
$
time
,
awprot
,
VALID_AWPROT
,
VALID_AWPROT_MASK
)
;
$
stop
;
end
end
end
always
@
(
posedge
aclk
or
posedge
rst
)
begin
if
(
rst
)
wburst
[
1
:
0
]
<=
0
;
else
if
(
start_write_burst_w
)
wburst
[
1
:
0
]
<=
awburst_out
[
1
:
0
]
;
if
(
rst
)
wlen
[
3
:
0
]
<=
0
;
else
if
(
start_write_burst_w
)
wlen
[
3
:
0
]
<=
awlen_out
[
3
:
0
]
;
if
(
rst
)
write_in_progress
<=
0
;
else
write_in_progress
<=
write_in_progress_w
;
if
(
rst
)
write_left
<=
0
;
else
if
(
start_write_burst_w
)
write_left
<=
awlen_out
[
3
:
0
]
;
// precedence over inc
else
if
(
fifo_wd_rd
)
write_left
<=
write_left
-
1
;
//SuppressThisWarning ISExst Result of 32-bit expression is truncated to fit in 4-bit target.
if
(
rst
)
write_address
<=
32'bx
;
else
if
(
start_write_burst_w
)
write_address
<=
awaddr_out
;
// precedence over inc
else
if
(
fifo_wd_rd
)
write_address
<=
{
write_address
[
31
:
12
]
,
next_wr_address
[
11
:
3
]
,
write_address
[
2
:
0
]
};
end
fifo_same_clock_fill
#(
.
DATA_WIDTH
(
51
)
,.
DATA_DEPTH
(
5
))
// read - 4, write - 32?
waddr_i
(
.
rst
(
rst
)
,
.
clk
(
aclk
)
,
.
sync_rst
(
1'b0
)
,
.
we
(
awvalid
&&
awready
)
,
.
re
(
start_write_burst_w
)
,
.
data_in
(
{
awid
[
5
:
0
]
,
awburst
[
1
:
0
]
,
awsize
[
2
:
0
]
,
awlen
[
3
:
0
]
,
awaddr
[
31
:
0
]
,
wr_qos_in
[
3
:
0
]
}
)
,
.
data_out
(
{
awid_out
[
5
:
0
]
,
awburst_out
[
1
:
0
]
,
awsize_out
[
2
:
0
]
,
awlen_out
[
3
:
0
]
,
awaddr_out
[
31
:
0
]
,
wr_qos_out
[
3
:
0
]
}
)
,
.
nempty
(
aw_nempty
)
,
.
half_full
()
,
//aw_half_full),
.
under
()
,
//waddr_under), // output reg
.
over
()
,
//waddr_over), // output reg
.
wcount
()
,
//waddr_wcount), // output[3:0] reg
.
rcount
()
,
//waddr_rcount), // output[3:0] reg
.
num_in_fifo
(
wacount
)
// output[3:0]
)
;
fifo_same_clock_fill
#(
.
DATA_WIDTH
(
78
)
,.
DATA_DEPTH
(
7
))
wdata_i
(
.
rst
(
rst
)
,
.
clk
(
aclk
)
,
.
sync_rst
(
1'b0
)
,
.
we
(
wvalid
&&
wready
)
,
.
re
(
fifo_wd_rd
)
,
//start_write_burst_w), // wrong
.
data_in
(
{
wid
[
5
:
0
]
,
wstrb
[
7
:
0
]
,
wdata
[
63
:
0
]
}
)
,
.
data_out
(
{
wid_out
[
5
:
0
]
,
wstrb_out
[
7
:
0
]
,
wdata_out
[
63
:
0
]
}
)
,
.
nempty
(
w_nempty
)
,
.
half_full
()
,
//w_half_full),
.
under
()
,
//wdata_under), // output reg
.
over
()
,
//wdata_over), // output reg
.
wcount
()
,
//wdata_wcount), // output[3:0] reg
.
rcount
()
,
//wdata_rcount), // output[3:0] reg
.
num_in_fifo
(
wcount
)
// output[3:0]
)
;
// **** Write responce channel ****
wire
[
1
:
0
]
bresp_value
=
2'b0
;
wire
[
1
:
0
]
bresp_in
;
wire
fifo_wd_rd_dly
;
wire
[
5
:
0
]
bid_in
;
// input [ 3:0] sim_bresp_latency, // latency in writeing data outside of the module
dly_16
#(
.
WIDTH
(
1
)
)
bresp_dly_16_i
(
.
clk
(
aclk
)
,
// input
.
rst
(
rst
)
,
// input
.
dly
(
sim_bresp_latency
[
3
:
0
])
,
// input[3:0]
.
din
(
fifo_wd_rd
)
,
// input[0:0]
.
dout
(
fifo_wd_rd_dly
)
// output[0:0]
)
;
// first FIFO for bresp - latency outside of the module
fifo_same_clock_fill
#(
.
DATA_WIDTH
(
8
)
,.
DATA_DEPTH
(
5
))
wresp_ext_i
(
.
rst
(
rst
)
,
.
clk
(
aclk
)
,
.
sync_rst
(
1'b0
)
,
.
we
(
fifo_wd_rd
)
,
.
re
(
fifo_wd_rd_dly
)
,
// not allowing RE next cycle after bvalid
.
data_in
(
{
wid_out
[
5
:
0
]
,
bresp_value
[
1
:
0
]
}
)
,
.
data_out
(
{
bid_in
[
5
:
0
]
,
bresp_in
[
1
:
0
]
}
)
,
.
nempty
()
,
.
half_full
()
,
//),
.
under
()
,
//wresp_under), // output reg
.
over
()
,
//wresp_over), // output reg
.
wcount
()
,
//wresp_wcount), // output[3:0] reg
.
rcount
()
,
//wresp_rcount), // output[3:0] reg
.
num_in_fifo
()
// wresp_num_in_fifo) // output[3:0]
)
;
assign
wresp_re
=
bready
&&
bvalid
&&
!
was_wresp_re
;
always
@
(
posedge
rst
or
posedge
aclk
)
begin
if
(
rst
)
was_wresp_re
<=
0
;
else
was_wresp_re
<=
wresp_re
;
end
assign
bvalid
=|
wresp_num_in_fifo
[
5
:
1
]
||
!
was_wresp_re
;
// second wresp FIFO (does it exist in the actual module)?
fifo_same_clock_fill
#(
.
DATA_WIDTH
(
8
)
,.
DATA_DEPTH
(
5
))
wresp_i
(
.
rst
(
rst
)
,
.
clk
(
aclk
)
,
.
sync_rst
(
1'b0
)
,
.
we
(
fifo_wd_rd_dly
)
,
.
re
(
wresp_re
)
,
// not allowing RE next cycle after bvalid
.
data_in
(
{
bid_in
[
5
:
0
]
,
bresp_in
[
1
:
0
]
}
)
,
.
data_out
(
{
bid
[
5
:
0
]
,
bresp
[
1
:
0
]
}
)
,
.
nempty
()
,
//bvalid),
.
half_full
()
,
//),
.
under
()
,
//wresp_under), // output reg
.
over
()
,
//wresp_over), // output reg
.
wcount
()
,
//wresp_wcount), // output[3:0] reg
.
rcount
()
,
//wresp_rcount), // output[3:0] reg
.
num_in_fifo
(
wresp_num_in_fifo
)
// wresp_num_in_fifo) // output[3:0]
)
;
endmodule
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